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authorSon HO2023-11-10 18:21:06 +0100
committerGitHub2023-11-10 18:21:06 +0100
commit587f1ebc0178acb19029d3fc9a729c197082aba7 (patch)
treef29805e5426f9f3fabe12d3fdadda96a1e987880
parent7fc7c82aa61d782b335e7cf37231fd9998cd0d89 (diff)
parentd300be95c28ff3147bb6f6a65992df5b9b571bdf (diff)
Merge pull request #44 from AeneasVerif/son_traits_types
Add support for traits
-rw-r--r--.github/workflows/ci.yml17
-rw-r--r--Makefile131
-rw-r--r--backends/coq/Primitives.v419
-rw-r--r--backends/fstar/Primitives.fst464
-rw-r--r--backends/hol4/primitivesScript.sml26
-rw-r--r--backends/hol4/primitivesTheory.sig120
-rw-r--r--backends/lean/Base/Arith/Base.lean12
-rw-r--r--backends/lean/Base/Arith/Int.lean15
-rw-r--r--backends/lean/Base/Arith/Scalar.lean13
-rw-r--r--backends/lean/Base/IList/IList.lean39
-rw-r--r--backends/lean/Base/Primitives.lean4
-rw-r--r--backends/lean/Base/Primitives/Alloc.lean37
-rw-r--r--backends/lean/Base/Primitives/Array.lean394
-rw-r--r--backends/lean/Base/Primitives/ArraySlice.lean553
-rw-r--r--backends/lean/Base/Primitives/Base.lean11
-rw-r--r--backends/lean/Base/Primitives/CoreOps.lean37
-rw-r--r--backends/lean/Base/Primitives/Range.lean2
-rw-r--r--backends/lean/Base/Primitives/Scalar.lean127
-rw-r--r--backends/lean/Base/Primitives/Vec.lean94
-rw-r--r--backends/lean/Base/Progress/Progress.lean29
-rw-r--r--backends/lean/Base/Utils.lean75
-rw-r--r--compiler/AssociatedTypes.ml681
-rw-r--r--compiler/Assumed.ml381
-rw-r--r--compiler/Config.ml31
-rw-r--r--compiler/Contexts.ml127
-rw-r--r--compiler/Driver.ml56
-rw-r--r--compiler/Extract.ml3424
-rw-r--r--compiler/ExtractBase.ml828
-rw-r--r--compiler/ExtractBuiltin.ml648
-rw-r--r--compiler/ExtractTypes.ml2477
-rw-r--r--compiler/FunsAnalysis.ml57
-rw-r--r--compiler/Interpreter.ml259
-rw-r--r--compiler/InterpreterBorrows.ml3
-rw-r--r--compiler/InterpreterBorrowsCore.ml16
-rw-r--r--compiler/InterpreterExpansion.ml59
-rw-r--r--compiler/InterpreterExpressions.ml195
-rw-r--r--compiler/InterpreterLoopsJoinCtxs.ml18
-rw-r--r--compiler/InterpreterLoopsMatchCtxs.ml19
-rw-r--r--compiler/InterpreterPaths.ml66
-rw-r--r--compiler/InterpreterPaths.mli11
-rw-r--r--compiler/InterpreterProjectors.ml15
-rw-r--r--compiler/InterpreterStatements.ml770
-rw-r--r--compiler/InterpreterStatements.mli9
-rw-r--r--compiler/InterpreterUtils.ml124
-rw-r--r--compiler/Invariants.ml82
-rw-r--r--compiler/LlbcAst.ml1
-rw-r--r--compiler/LlbcAstUtils.ml40
-rw-r--r--compiler/Logging.ml8
-rw-r--r--compiler/PrePasses.ml6
-rw-r--r--compiler/Print.ml184
-rw-r--r--compiler/PrintPure.ml272
-rw-r--r--compiler/Pure.ml194
-rw-r--r--compiler/PureMicroPasses.ml211
-rw-r--r--compiler/PureTypeCheck.ml62
-rw-r--r--compiler/PureUtils.ml190
-rw-r--r--compiler/ReorderDecls.ml8
-rw-r--r--compiler/Substitute.ml493
-rw-r--r--compiler/SymbolicAst.ml33
-rw-r--r--compiler/SymbolicToPure.ml830
-rw-r--r--compiler/SynthesizeSymbolic.ml38
-rw-r--r--compiler/Translate.ml672
-rw-r--r--compiler/TranslateCore.ml79
-rw-r--r--compiler/TypesAnalysis.ml36
-rw-r--r--compiler/Values.ml4
-rw-r--r--compiler/dune5
-rw-r--r--flake.lock137
-rw-r--r--flake.nix21
-rw-r--r--tests/coq/array/Array.v470
-rw-r--r--tests/coq/array/Array_Funs.v467
-rw-r--r--tests/coq/array/Array_Types.v14
-rw-r--r--tests/coq/array/Primitives.v419
-rw-r--r--tests/coq/array/_CoqProject3
-rw-r--r--tests/coq/betree/BetreeMain_Funs.v1075
-rw-r--r--tests/coq/betree/BetreeMain_Opaque.v18
-rw-r--r--tests/coq/betree/BetreeMain_Types.v92
-rw-r--r--tests/coq/betree/Primitives.v419
-rw-r--r--tests/coq/hashmap/Hashmap_Funs.v520
-rw-r--r--tests/coq/hashmap/Hashmap_Types.v30
-rw-r--r--tests/coq/hashmap/Primitives.v419
-rw-r--r--tests/coq/hashmap_on_disk/HashmapMain_Funs.v610
-rw-r--r--tests/coq/hashmap_on_disk/HashmapMain_Opaque.v8
-rw-r--r--tests/coq/hashmap_on_disk/HashmapMain_Types.v32
-rw-r--r--tests/coq/hashmap_on_disk/Primitives.v419
-rw-r--r--tests/coq/misc/Constants.v66
-rw-r--r--tests/coq/misc/External_Funs.v39
-rw-r--r--tests/coq/misc/External_Opaque.v8
-rw-r--r--tests/coq/misc/External_Types.v2
-rw-r--r--tests/coq/misc/Loops.v412
-rw-r--r--tests/coq/misc/NoNestedBorrows.v319
-rw-r--r--tests/coq/misc/Paper.v67
-rw-r--r--tests/coq/misc/PoloniusList.v22
-rw-r--r--tests/coq/misc/Primitives.v419
-rw-r--r--tests/coq/traits/Makefile23
-rw-r--r--tests/coq/traits/Primitives.v822
-rw-r--r--tests/coq/traits/Traits.v520
-rw-r--r--tests/coq/traits/_CoqProject7
-rw-r--r--tests/fstar/array/Array.Clauses.Template.fst5
-rw-r--r--tests/fstar/array/Array.Funs.fst348
-rw-r--r--tests/fstar/array/Array.Types.fst4
-rw-r--r--tests/fstar/array/Primitives.fst464
-rw-r--r--tests/fstar/betree/BetreeMain.Clauses.Template.fst60
-rw-r--r--tests/fstar/betree/BetreeMain.Clauses.fst90
-rw-r--r--tests/fstar/betree/BetreeMain.Funs.fst1129
-rw-r--r--tests/fstar/betree/BetreeMain.Opaque.fsti18
-rw-r--r--tests/fstar/betree/BetreeMain.Types.fsti50
-rw-r--r--tests/fstar/betree/Primitives.fst464
-rw-r--r--tests/fstar/betree_back_stateful/BetreeMain.Clauses.Template.fst60
-rw-r--r--tests/fstar/betree_back_stateful/BetreeMain.Clauses.fst90
-rw-r--r--tests/fstar/betree_back_stateful/BetreeMain.Funs.fst1377
-rw-r--r--tests/fstar/betree_back_stateful/BetreeMain.Opaque.fsti18
-rw-r--r--tests/fstar/betree_back_stateful/BetreeMain.Types.fsti50
-rw-r--r--tests/fstar/betree_back_stateful/Primitives.fst464
-rw-r--r--tests/fstar/hashmap/Hashmap.Clauses.Template.fst26
-rw-r--r--tests/fstar/hashmap/Hashmap.Clauses.fst24
-rw-r--r--tests/fstar/hashmap/Hashmap.Funs.fst498
-rw-r--r--tests/fstar/hashmap/Hashmap.Properties.fst1648
-rw-r--r--tests/fstar/hashmap/Hashmap.Properties.fsti100
-rw-r--r--tests/fstar/hashmap/Hashmap.Types.fst14
-rw-r--r--tests/fstar/hashmap/Primitives.fst464
-rw-r--r--tests/fstar/hashmap_on_disk/HashmapMain.Clauses.Template.fst38
-rw-r--r--tests/fstar/hashmap_on_disk/HashmapMain.Clauses.fst32
-rw-r--r--tests/fstar/hashmap_on_disk/HashmapMain.Funs.fst575
-rw-r--r--tests/fstar/hashmap_on_disk/HashmapMain.Opaque.fsti8
-rw-r--r--tests/fstar/hashmap_on_disk/HashmapMain.Properties.fst20
-rw-r--r--tests/fstar/hashmap_on_disk/HashmapMain.Types.fsti16
-rw-r--r--tests/fstar/hashmap_on_disk/Primitives.fst464
-rw-r--r--tests/fstar/misc/Constants.fst52
-rw-r--r--tests/fstar/misc/External.Funs.fst38
-rw-r--r--tests/fstar/misc/External.Opaque.fsti8
-rw-r--r--tests/fstar/misc/External.Types.fsti2
-rw-r--r--tests/fstar/misc/Loops.Clauses.Template.fst3
-rw-r--r--tests/fstar/misc/Loops.Clauses.fst2
-rw-r--r--tests/fstar/misc/Loops.Funs.fst392
-rw-r--r--tests/fstar/misc/Loops.Types.fst4
-rw-r--r--tests/fstar/misc/NoNestedBorrows.fst278
-rw-r--r--tests/fstar/misc/Paper.fst65
-rw-r--r--tests/fstar/misc/PoloniusList.fst18
-rw-r--r--tests/fstar/misc/Primitives.fst464
-rw-r--r--tests/fstar/traits/Makefile49
-rw-r--r--tests/fstar/traits/Primitives.fst729
-rw-r--r--tests/fstar/traits/Traits.fst371
-rw-r--r--tests/hol4/betree/betreeMain_FunsScript.sml12
-rw-r--r--tests/hol4/betree/betreeMain_FunsTheory.sig14
-rw-r--r--tests/hol4/hashmap/hashmap_FunsScript.sml10
-rw-r--r--tests/hol4/hashmap/hashmap_FunsTheory.sig12
-rw-r--r--tests/hol4/hashmap/hashmap_PropertiesScript.sml2
-rw-r--r--tests/hol4/hashmap_on_disk/hashmapMain_FunsScript.sml10
-rw-r--r--tests/hol4/hashmap_on_disk/hashmapMain_FunsTheory.sig12
-rw-r--r--tests/hol4/misc-constants/constantsScript.sml10
-rw-r--r--tests/hol4/misc-constants/constantsTheory.sig12
-rw-r--r--tests/lean/Array.lean436
-rw-r--r--tests/lean/Array/Funs.lean360
-rw-r--r--tests/lean/Array/Types.lean8
-rw-r--r--tests/lean/BetreeMain/Funs.lean88
-rw-r--r--tests/lean/Constants.lean43
-rw-r--r--tests/lean/External/Funs.lean16
-rw-r--r--tests/lean/Hashmap/Funs.lean223
-rw-r--r--tests/lean/Hashmap/Properties.lean17
-rw-r--r--tests/lean/Hashmap/Types.lean2
-rw-r--r--tests/lean/HashmapMain/Funs.lean232
-rw-r--r--tests/lean/HashmapMain/Types.lean2
-rw-r--r--tests/lean/Loops.lean630
-rw-r--r--tests/lean/Loops/Funs.lean612
-rw-r--r--tests/lean/Loops/Types.lean13
-rw-r--r--tests/lean/NoNestedBorrows.lean158
-rw-r--r--tests/lean/Paper.lean48
-rw-r--r--tests/lean/Traits.lean383
-rw-r--r--tests/lean/lakefile.lean1
168 files changed, 25526 insertions, 13173 deletions
diff --git a/.github/workflows/ci.yml b/.github/workflows/ci.yml
index 664dc674..6b5aacf0 100644
--- a/.github/workflows/ci.yml
+++ b/.github/workflows/ci.yml
@@ -15,5 +15,20 @@ jobs:
- run: nix build -L .#checks.x86_64-linux.aeneas-tests
- run: nix build -L .#checks.x86_64-linux.aeneas-verify-fstar
- run: nix build -L .#checks.x86_64-linux.aeneas-verify-coq
- #- run: nix build -L .#checks.x86_64-linux.aeneas-verify-lean
- run: nix build -L .#checks.x86_64-linux.aeneas-verify-hol4
+ # Lean doesn't work with Nix
+ #- run: nix build -L .#checks.x86_64-linux.aeneas-verify-lean
+ lean: # Lean isn't supported by Nix, so we put it in a different job
+ runs-on: [ubuntu-latest]
+ steps:
+ # Install curl
+ - run: sudo apt update && sudo apt install curl
+ # Install Elan (https://leanprover-community.github.io/install/linux.html) and Lean in
+ # non-interactive mode:
+ - run: curl https://raw.githubusercontent.com/leanprover/elan/master/elan-init.sh -sSf | bash -s -- -y
+ # Checkout the repo and download it to the runner
+ - name: Checkout
+ uses: actions/checkout@v4
+ # Verify - note that we need to update the environment with `source` so
+ # that the lake binary is in the path.
+ - run: source ~/.profile && cd tests/lean && make
diff --git a/Makefile b/Makefile
index a0111b37..4660ac83 100644
--- a/Makefile
+++ b/Makefile
@@ -27,7 +27,7 @@ CHARON_TESTS_POLONIUS_DIR ?= $(CHARON_HOME)/tests-polonius
# The path to the Aeneas executable to run the tests - we need the ability to
# change this path for the Nix package.
-AENEAS_EXE ?= bin/aeneas.exe
+AENEAS_EXE ?= bin/aeneas
# The user can specify additional translation options for Aeneas.
# By default we do:
@@ -71,9 +71,12 @@ build-lib:
.PHONY: build-bin-dir
build-bin-dir: build-driver build-lib
mkdir -p bin
- cp -f compiler/_build/default/driver.exe bin/aeneas.exe
+ cp -f compiler/_build/default/driver.exe bin/aeneas
cp -f compiler/_build/default/driver.exe bin/aeneas.cmxs
- cp -rf backends bin
+ mkdir -p bin/backends/fstar
+ mkdir -p bin/backends/coq
+ cp -rf backends/fstar/*.fst* bin/backends/fstar/
+ cp -rf backends/coq/*.v bin/backends/coq/
.PHONY: doc
doc:
@@ -85,13 +88,13 @@ clean:
# Test the project by translating test files to F*
.PHONY: tests
-tests: trans-no_nested_borrows trans-paper \
- trans-hashmap trans-hashmap_main \
- trans-external trans-constants \
- transp-polonius_list transp-betree_main \
- test-transp-betree_main \
- trans-loops \
- trans-array # TODO: generalize to all backends
+tests: test-no_nested_borrows test-paper \
+ test-hashmap test-hashmap_main \
+ test-external test-constants \
+ testp-polonius_list testp-betree_main \
+ ctest-testp-betree_main \
+ test-loops \
+ test-array test-traits # TODO: generalize to all backends
# Verify the F* files generated by the translation
.PHONY: verify
@@ -114,51 +117,65 @@ AENEAS_CMD = $(AENEAS_EXE) $(CHARON_TEST_DIR)/llbc/$(FILE).llbc -dest tests/$(BA
# Add specific options to some tests
-trans-no_nested_borrows trans-paper: \
- OPTIONS += -test-units -test-trans-units -no-split-files -no-state
-trans-no_nested_borrows trans-paper: SUBDIR := misc
+test-no_nested_borrows test-paper: \
+ OPTIONS += -test-trans-units
+test-no_nested_borrows test-paper: SUBDIR := misc
tfstar-no_nested_borrows tfstar-paper:
tlean-no_nested_borrows: SUBDIR :=
tlean-paper: SUBDIR :=
thol4-no_nested_borrows: SUBDIR := misc-no_nested_borrows
thol4-paper: SUBDIR := misc-paper
-trans-array: OPTIONS += -no-state
-trans-array: SUBDIR := array
-tfstar-array: OPTIONS += -decreases-clauses -template-clauses
+test-array: OPTIONS +=
+test-array: SUBDIR := array
+tfstar-array: OPTIONS += -decreases-clauses -template-clauses -split-files
tcoq-array: OPTIONS += -use-fuel
tlean-array: SUBDIR :=
tlean-array: OPTIONS +=
thol4-array: OPTIONS +=
+test-traits: OPTIONS +=
+test-traits: SUBDIR := traits
+tfstar-traits: OPTIONS += -decreases-clauses -template-clauses
+tcoq-traits: OPTIONS +=
+tlean-traits: SUBDIR :=
+tlean-traits: OPTIONS +=
+thol4-traits: OPTIONS +=
+
# TODO: activate the arrays for all the backends
thol4-array:
echo "Ignoring the array test for HOL4"
-trans-loops: OPTIONS += -no-state
-trans-loops: SUBDIR := misc
-tfstar-loops: OPTIONS += -decreases-clauses -template-clauses
-tcoq-loops: OPTIONS += -use-fuel -no-split-files
+# TODO: activate the traits for all the backends
+thol4-traits:
+ echo "Ignoring the traits test for HOL4"
+
+test-loops: OPTIONS +=
+test-loops: SUBDIR := misc
+tfstar-loops: OPTIONS += -decreases-clauses -template-clauses -split-files
+tcoq-loops: OPTIONS += -use-fuel
tlean-loops: SUBDIR :=
thol4-loops: SUBDIR := misc-loops
-trans-hashmap: OPTIONS += -no-state -test-trans-units
-trans-hashmap: SUBDIR := hashmap
+# TODO: reactivate -test-trans-units
+test-hashmap: OPTIONS += -split-files
+test-hashmap: SUBDIR := hashmap
tfstar-hashmap: OPTIONS += -decreases-clauses -template-clauses
tcoq-hashmap: OPTIONS += -use-fuel
tlean-hashmap: SUBDIR :=
tlean-hashmap: OPTIONS += -no-gen-lib-entry # We add a custom import in the Hashmap.lean file: we do not want to overwrite it
thol4-hashmap: OPTIONS +=
-trans-hashmap_main: OPTIONS += -test-trans-units
-trans-hashmap_main: SUBDIR := hashmap_on_disk
+# TODO: reactivate -test-trans-units
+test-hashmap_main: OPTIONS += -state -split-files
+test-hashmap_main: SUBDIR := hashmap_on_disk
tfstar-hashmap_main: OPTIONS += -decreases-clauses -template-clauses
tcoq-hashmap_main: OPTIONS += -use-fuel
tlean-hashmap_main: SUBDIR :=
thol4-hashmap_main: OPTIONS +=
-transp-polonius_list: OPTIONS += -test-units -test-trans-units -no-split-files -no-state
-transp-polonius_list: SUBDIR := misc
+testp-polonius_list: OPTIONS += -test-trans-units
+testp-polonius_list: SUBDIR := misc
tfstarp-polonius_list: OPTIONS +=
tcoqp-polonius_list: OPTIONS +=
tleanp-polonius_list: SUBDIR :=
@@ -166,8 +183,8 @@ tleanp-polonius_list: OPTIONS +=
thol4p-polonius_list: SUBDIR := misc-polonius_list
thol4p-polonius_list: OPTIONS +=
-trans-constants: OPTIONS += -test-units -test-trans-units -no-split-files -no-state
-trans-constants: SUBDIR := misc
+test-constants: OPTIONS += -test-trans-units
+test-constants: SUBDIR := misc
tfstar-constants: OPTIONS +=
tcoq-constants: OPTIONS +=
tlean-constants: SUBDIR :=
@@ -175,8 +192,8 @@ tlean-constants: OPTIONS +=
thol4-constants: SUBDIR := misc-constants
thol4-constants: OPTIONS +=
-trans-external: OPTIONS += -test-trans-units
-trans-external: SUBDIR := misc
+test-external: OPTIONS += -test-trans-units -state -split-files
+test-external: SUBDIR := misc
tfstar-external: OPTIONS +=
tcoq-external: OPTIONS +=
tlean-external: SUBDIR :=
@@ -185,25 +202,25 @@ thol4-external: SUBDIR := misc-external
thol4-external: OPTIONS +=
BETREE_FSTAR_OPTIONS = -decreases-clauses -template-clauses
-transp-betree_main: OPTIONS += -backward-no-state-update -test-trans-units
-transp-betree_main: SUBDIR:=betree
+testp-betree_main: OPTIONS += -backward-no-state-update -test-trans-units -state -split-files
+testp-betree_main: SUBDIR:=betree
tfstarp-betree_main: OPTIONS += $(BETREE_FSTAR_OPTIONS)
tcoqp-betree_main: OPTIONS += -use-fuel
tleanp-betree_main: SUBDIR :=
tleanp-betree_main: OPTIONS +=
thol4-betree_main: OPTIONS +=
-# Additional test on the betree: translate it without `-backward-no-state-update`.
+# Additional, *c*ustom test on the betree: translate it without `-backward-no-state-update`.
# This generates very ugly code, but is good to test the translation.
-.PHONY: test-transp-betree_main
-test-transp-betree_main: transp-betree_main
-test-transp-betree_main: OPTIONS += -backend fstar -test-trans-units
-test-transp-betree_main: OPTIONS += $(BETREE_FSTAR_OPTIONS)
-test-transp-betree_main: BACKEND_SUBDIR := "fstar"
-test-transp-betree_main: SUBDIR:=betree_back_stateful
-test-transp-betree_main: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR)
-test-transp-betree_main: FILE = betree_main
-test-transp-betree_main:
+.PHONY: ctest-testp-betree_main
+ctest-testp-betree_main: testp-betree_main
+ctest-testp-betree_main: OPTIONS += -backend fstar -test-trans-units -state -split-files
+ctest-testp-betree_main: OPTIONS += $(BETREE_FSTAR_OPTIONS)
+ctest-testp-betree_main: BACKEND_SUBDIR := "fstar"
+ctest-testp-betree_main: SUBDIR:=betree_back_stateful
+ctest-testp-betree_main: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR)
+ctest-testp-betree_main: FILE = betree_main
+ctest-testp-betree_main:
$(AENEAS_CMD)
# Generic rules to extract the LLBC from a rust file
@@ -220,20 +237,20 @@ gen-llbcp-%: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR)
gen-llbcp-%:
$(CHARON_CMD)
-# Generic rules to test the translation of an LLBC file.
+# Generic rules to test the testlation of an LLBC file.
# Note that the files requiring the Polonius borrow-checker are generated
# in the tests-polonius subdirectory.
-.PHONY: trans-%
-trans-%: CHARON_TEST_DIR = $(CHARON_TESTS_REGULAR_DIR)
-trans-%: FILE = $*
-trans-%: gen-llbc-% tfstar-% tcoq-% tlean-% thol4-%
+.PHONY: test-%
+test-%: CHARON_TEST_DIR = $(CHARON_TESTS_REGULAR_DIR)
+test-%: FILE = $*
+test-%: gen-llbc-% tfstar-% tcoq-% tlean-% thol4-%
echo "# Test $* done"
# "p" stands for "Polonius"
-.PHONY: transp-%
-transp-%: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR)
-transp-%: FILE = $*
-transp-%: gen-llbcp-% tfstarp-% tcoqp-% tleanp-% thol4p-%
+.PHONY: testp-%
+testp-%: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR)
+testp-%: FILE = $*
+testp-%: gen-llbcp-% tfstarp-% tcoqp-% tleanp-% thol4p-%
echo "# Test $* done"
.PHONY: tfstar-%
@@ -276,17 +293,25 @@ tleanp-%: BACKEND_SUBDIR := lean
tleanp-%:
$(AENEAS_CMD)
+# TODO: reactivate HOL4 once traits are parameterized by their associated types
.PHONY: thol4-%
thol4-%: OPTIONS += -backend hol4
thol4-%: BACKEND_SUBDIR := hol4
thol4-%:
- $(AENEAS_CMD)
+ echo Ignoring the $* test for HOL4
+#thol4-%:
+# $(AENEAS_CMD)
+
+# TODO: reactivate HOL4 once traits are parameterized by their associated types
.PHONY: thol4p-%
thol4p-%: OPTIONS += -backend hol4
thol4p-%: BACKEND_SUBDIR := hol4
thol4p-%:
- $(AENEAS_CMD)
+ echo Ignoring the $* test for HOL4
+
+#thol4p-%:
+# $(AENEAS_CMD)
# Nix - TODO: add the lean tests
.PHONY: nix
diff --git a/backends/coq/Primitives.v b/backends/coq/Primitives.v
index 71a2d9c3..85e38f01 100644
--- a/backends/coq/Primitives.v
+++ b/backends/coq/Primitives.v
@@ -63,13 +63,15 @@ Check (if true then Return (1 + 2) else Fail_ Failure)%global = 3.
(*** Misc *)
-
Definition string := Coq.Strings.String.string.
Definition char := Coq.Strings.Ascii.ascii.
Definition char_of_byte := Coq.Strings.Ascii.ascii_of_byte.
-Definition mem_replace_fwd (a : Type) (x : a) (y : a) : a := x .
-Definition mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+Definition core_mem_replace (a : Type) (x : a) (y : a) : a := x .
+Definition core_mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+
+Record mut_raw_ptr (T : Type) := { mut_raw_ptr_v : T }.
+Record const_raw_ptr (T : Type) := { const_raw_ptr_v : T }.
(*** Scalars *)
@@ -394,12 +396,89 @@ Notation "x s< y" := (scalar_ltb x y) (at level 80) : Primitives_scope.
Notation "x s>= y" := (scalar_geb x y) (at level 80) : Primitives_scope.
Notation "x s> y" := (scalar_gtb x y) (at level 80) : Primitives_scope.
-(*** Range *)
-Record range (T : Type) := mk_range {
- start: T;
- end_: T;
+(** Constants *)
+Definition core_u8_max := u8_max %u32.
+Definition core_u16_max := u16_max %u32.
+Definition core_u32_max := u32_max %u32.
+Definition core_u64_max := u64_max %u64.
+Definition core_u128_max := u64_max %u128.
+Axiom core_usize_max : usize. (** TODO *)
+Definition core_i8_max := i8_max %i32.
+Definition core_i16_max := i16_max %i32.
+Definition core_i32_max := i32_max %i32.
+Definition core_i64_max := i64_max %i64.
+Definition core_i128_max := i64_max %i128.
+Axiom core_isize_max : isize. (** TODO *)
+
+(*** core::ops *)
+
+(* Trait declaration: [core::ops::index::Index] *)
+Record core_ops_index_Index (Self Idx : Type) := mk_core_ops_index_Index {
+ core_ops_index_Index_Output : Type;
+ core_ops_index_Index_index : Self -> Idx -> result core_ops_index_Index_Output;
+}.
+Arguments mk_core_ops_index_Index {_ _}.
+Arguments core_ops_index_Index_Output {_ _}.
+Arguments core_ops_index_Index_index {_ _}.
+
+(* Trait declaration: [core::ops::index::IndexMut] *)
+Record core_ops_index_IndexMut (Self Idx : Type) := mk_core_ops_index_IndexMut {
+ core_ops_index_IndexMut_indexInst : core_ops_index_Index Self Idx;
+ core_ops_index_IndexMut_index_mut : Self -> Idx -> result core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output);
+ core_ops_index_IndexMut_index_mut_back : Self -> Idx -> core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output) -> result Self;
+}.
+Arguments mk_core_ops_index_IndexMut {_ _}.
+Arguments core_ops_index_IndexMut_indexInst {_ _}.
+Arguments core_ops_index_IndexMut_index_mut {_ _}.
+Arguments core_ops_index_IndexMut_index_mut_back {_ _}.
+
+(* Trait declaration [core::ops::deref::Deref] *)
+Record core_ops_deref_Deref (Self : Type) := mk_core_ops_deref_Deref {
+ core_ops_deref_Deref_target : Type;
+ core_ops_deref_Deref_deref : Self -> result core_ops_deref_Deref_target;
+}.
+Arguments mk_core_ops_deref_Deref {_}.
+Arguments core_ops_deref_Deref_target {_}.
+Arguments core_ops_deref_Deref_deref {_}.
+
+(* Trait declaration [core::ops::deref::DerefMut] *)
+Record core_ops_deref_DerefMut (Self : Type) := mk_core_ops_deref_DerefMut {
+ core_ops_deref_DerefMut_derefInst : core_ops_deref_Deref Self;
+ core_ops_deref_DerefMut_deref_mut : Self -> result core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target);
+ core_ops_deref_DerefMut_deref_mut_back : Self -> core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target) -> result Self;
}.
-Arguments mk_range {_}.
+Arguments mk_core_ops_deref_DerefMut {_}.
+Arguments core_ops_deref_DerefMut_derefInst {_}.
+Arguments core_ops_deref_DerefMut_deref_mut {_}.
+Arguments core_ops_deref_DerefMut_deref_mut_back {_}.
+
+Record core_ops_range_Range (T : Type) := mk_core_ops_range_Range {
+ core_ops_range_Range_start : T;
+ core_ops_range_Range_end_ : T;
+}.
+Arguments mk_core_ops_range_Range {_}.
+Arguments core_ops_range_Range_start {_}.
+Arguments core_ops_range_Range_end_ {_}.
+
+(*** [alloc] *)
+
+Definition alloc_boxed_Box_deref (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut_back (T : Type) (_ : T) (x : T) : result T := Return x.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefInst (Self : Type) : core_ops_deref_Deref Self := {|
+ core_ops_deref_Deref_target := Self;
+ core_ops_deref_Deref_deref := alloc_boxed_Box_deref Self;
+|}.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefMutInst (Self : Type) : core_ops_deref_DerefMut Self := {|
+ core_ops_deref_DerefMut_derefInst := alloc_boxed_Box_coreOpsDerefInst Self;
+ core_ops_deref_DerefMut_deref_mut := alloc_boxed_Box_deref_mut Self;
+ core_ops_deref_DerefMut_deref_mut_back := alloc_boxed_Box_deref_mut_back Self;
+|}.
+
(*** Arrays *)
Definition array T (n : usize) := { l: list T | Z.of_nat (length l) = to_Z n}.
@@ -419,51 +498,50 @@ Qed.
(* TODO: finish the definitions *)
Axiom mk_array : forall (T : Type) (n : usize) (l : list T), array T n.
-Axiom array_index_shared : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_fwd : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_back : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
+(* For initialization *)
+Axiom array_repeat : forall (T : Type) (n : usize) (x : T), array T n.
+
+Axiom array_index_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
+Axiom array_update_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
(*** Slice *)
Definition slice T := { l: list T | Z.of_nat (length l) <= usize_max}.
Axiom slice_len : forall (T : Type) (s : slice T), usize.
-Axiom slice_index_shared : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_fwd : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_back : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
+Axiom slice_index_usize : forall (T : Type) (x : slice T) (i : usize), result T.
+Axiom slice_update_usize : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
(*** Subslices *)
-Axiom array_to_slice_shared : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_fwd : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_back : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+Axiom array_to_slice : forall (T : Type) (n : usize) (x : array T n), result (slice T).
+Axiom array_from_slice : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+
+Axiom array_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize), result (slice T).
+Axiom array_update_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize) (ns : slice T), result (array T n).
-Axiom array_subslice_shared: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_fwd: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_back: forall (T : Type) (n : usize) (x : array T n) (r : range usize) (ns : slice T), result (array T n).
-Axiom slice_subslice_shared: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_fwd: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_back: forall (T : Type) (x : slice T) (r : range usize) (ns : slice T), result (slice T).
+Axiom slice_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize), result (slice T).
+Axiom slice_update_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize) (ns : slice T), result (slice T).
(*** Vectors *)
-Definition vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
+Definition alloc_vec_Vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
-Definition vec_to_list {T: Type} (v: vec T) : list T := proj1_sig v.
+Definition alloc_vec_Vec_to_list {T: Type} (v: alloc_vec_Vec T) : list T := proj1_sig v.
-Definition vec_length {T: Type} (v: vec T) : Z := Z.of_nat (length (vec_to_list v)).
+Definition alloc_vec_Vec_length {T: Type} (v: alloc_vec_Vec T) : Z := Z.of_nat (length (alloc_vec_Vec_to_list v)).
-Definition vec_new (T: Type) : vec T := (exist _ [] le_0_usize_max).
+Definition alloc_vec_Vec_new (T: Type) : alloc_vec_Vec T := (exist _ [] le_0_usize_max).
-Lemma vec_len_in_usize {T} (v: vec T) : usize_min <= vec_length v <= usize_max.
+Lemma alloc_vec_Vec_len_in_usize {T} (v: alloc_vec_Vec T) : usize_min <= alloc_vec_Vec_length v <= usize_max.
Proof.
- unfold vec_length, usize_min.
+ unfold alloc_vec_Vec_length, usize_min.
split.
- lia.
- apply (proj2_sig v).
Qed.
-Definition vec_len (T: Type) (v: vec T) : usize :=
- exist _ (vec_length v) (vec_len_in_usize v).
+Definition alloc_vec_Vec_len (T: Type) (v: alloc_vec_Vec T) : usize :=
+ exist _ (alloc_vec_Vec_length v) (alloc_vec_Vec_len_in_usize v).
Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
: list A :=
@@ -474,50 +552,271 @@ Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
| S m => x :: (list_update t m a)
end end.
-Definition vec_bind {A B} (v: vec A) (f: list A -> result (list B)) : result (vec B) :=
- l <- f (vec_to_list v) ;
+Definition alloc_vec_Vec_bind {A B} (v: alloc_vec_Vec A) (f: list A -> result (list B)) : result (alloc_vec_Vec B) :=
+ l <- f (alloc_vec_Vec_to_list v) ;
match sumbool_of_bool (scalar_le_max Usize (Z.of_nat (length l))) with
| left H => Return (exist _ l (scalar_le_max_valid _ _ H))
| right _ => Fail_ Failure
end.
(* The **forward** function shouldn't be used *)
-Definition vec_push_fwd (T: Type) (v: vec T) (x: T) : unit := tt.
+Definition alloc_vec_Vec_push_fwd (T: Type) (v: alloc_vec_Vec T) (x: T) : unit := tt.
-Definition vec_push_back (T: Type) (v: vec T) (x: T) : result (vec T) :=
- vec_bind v (fun l => Return (l ++ [x])).
+Definition alloc_vec_Vec_push (T: Type) (v: alloc_vec_Vec T) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l => Return (l ++ [x])).
(* The **forward** function shouldn't be used *)
-Definition vec_insert_fwd (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
+Definition alloc_vec_Vec_insert_fwd (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result unit :=
+ if to_Z i <? alloc_vec_Vec_length v then Return tt else Fail_ Failure.
-Definition vec_insert_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
+Definition alloc_vec_Vec_insert (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l =>
if to_Z i <? Z.of_nat (length l)
then Return (list_update l (usize_to_nat i) x)
else Fail_ Failure).
-(* The **backward** function shouldn't be used *)
-Definition vec_index_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
- end.
-
-Definition vec_index_back (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
-
-(* The **backward** function shouldn't be used *)
-Definition vec_index_mut_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
+(* Helper *)
+Axiom alloc_vec_Vec_index_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result T.
+
+(* Helper *)
+Axiom alloc_vec_Vec_update_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result (alloc_vec_Vec T).
+
+(* Trait declaration: [core::slice::index::private_slice_index::Sealed] *)
+Definition core_slice_index_private_slice_index_Sealed (self : Type) := unit.
+
+(* Trait declaration: [core::slice::index::SliceIndex] *)
+Record core_slice_index_SliceIndex (Self T : Type) := mk_core_slice_index_SliceIndex {
+ core_slice_index_SliceIndex_sealedInst : core_slice_index_private_slice_index_Sealed Self;
+ core_slice_index_SliceIndex_Output : Type;
+ core_slice_index_SliceIndex_get : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut_back : Self -> T -> option core_slice_index_SliceIndex_Output -> result T;
+ core_slice_index_SliceIndex_get_unchecked : Self -> const_raw_ptr T -> result (const_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_unchecked_mut : Self -> mut_raw_ptr T -> result (mut_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_index : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut_back : Self -> T -> core_slice_index_SliceIndex_Output -> result T;
+}.
+Arguments mk_core_slice_index_SliceIndex {_ _}.
+Arguments core_slice_index_SliceIndex_sealedInst {_ _}.
+Arguments core_slice_index_SliceIndex_Output {_ _}.
+Arguments core_slice_index_SliceIndex_get {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut_back {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut_back {_ _}.
+
+(* [core::slice::index::[T]::index]: forward function *)
+Definition core_slice_index_Slice_index
+ (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (s : slice T) (i : Idx) : result inst.(core_slice_index_SliceIndex_Output) :=
+ x <- inst.(core_slice_index_SliceIndex_get) i s;
+ match x with
+ | None => Fail_ Failure
+ | Some x => Return x
end.
-Definition vec_index_mut_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
- if to_Z i <? Z.of_nat (length l)
- then Return (list_update l (usize_to_nat i) x)
- else Fail_ Failure).
+(* [core::slice::index::Range:::get]: forward function *)
+Axiom core_slice_index_Range_get : forall (T : Type) (i : core_ops_range_Range usize) (s : slice T), result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: forward function *)
+Axiom core_slice_index_Range_get_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: backward function 0 *)
+Axiom core_slice_index_Range_get_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> option (slice T) -> result (slice T).
+
+(* [core::slice::index::Range::get_unchecked]: forward function *)
+Definition core_slice_index_Range_get_unchecked
+ (T : Type) :
+ core_ops_range_Range usize -> const_raw_ptr (slice T) -> result (const_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::get_unchecked_mut]: forward function *)
+Definition core_slice_index_Range_get_unchecked_mut
+ (T : Type) :
+ core_ops_range_Range usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::index]: forward function *)
+Axiom core_slice_index_Range_index :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: forward function *)
+Axiom core_slice_index_Range_index_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: backward function 0 *)
+Axiom core_slice_index_Range_index_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> slice T -> result (slice T).
+
+(* [core::slice::index::[T]::index_mut]: forward function *)
+Axiom core_slice_index_Slice_index_mut :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> result inst.(core_slice_index_SliceIndex_Output).
+
+(* [core::slice::index::[T]::index_mut]: backward function 0 *)
+Axiom core_slice_index_Slice_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> inst.(core_slice_index_SliceIndex_Output) -> result (slice T).
+
+(* [core::array::[T; N]::index]: forward function *)
+Axiom core_array_Array_index :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_Index (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: forward function *)
+Axiom core_array_Array_index_mut :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: backward function 0 *)
+Axiom core_array_Array_index_mut_back :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx) (x : inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output)), result (array T N).
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (slice T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := core_slice_index_Slice_index T Idx inst;
+|}.
+
+(* Trait implementation: [core::slice::index::private_slice_index::Range] *)
+Definition core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) := tt.
+
+(* Trait implementation: [core::slice::index::Range] *)
+Definition core_slice_index_Range_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := slice T;
+ core_slice_index_SliceIndex_get := core_slice_index_Range_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_Range_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_Range_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_Range_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_Range_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_Range_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_Range_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_Range_index_mut_back T;
+|}.
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (slice T) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_slice_index_Slice_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := core_slice_index_Slice_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := core_slice_index_Slice_index_mut_back T Idx inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_Index (slice T) Idx) :
+ core_ops_index_Index (array T N) Idx := {|
+ core_ops_index_Index_Output := inst.(core_ops_index_Index_Output);
+ core_ops_index_Index_index := core_array_Array_index T Idx N inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexMutInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_IndexMut (slice T) Idx) :
+ core_ops_index_IndexMut (array T N) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_array_Array_coreopsindexIndexInst T Idx N inst.(core_ops_index_IndexMut_indexInst);
+ core_ops_index_IndexMut_index_mut := core_array_Array_index_mut T Idx N inst;
+ core_ops_index_IndexMut_index_mut_back := core_array_Array_index_mut_back T Idx N inst;
+|}.
+
+(* [core::slice::index::usize::get]: forward function *)
+Axiom core_slice_index_usize_get : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: forward function *)
+Axiom core_slice_index_usize_get_mut : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: backward function 0 *)
+Axiom core_slice_index_usize_get_mut_back :
+ forall (T : Type), usize -> slice T -> option T -> result (slice T).
+
+(* [core::slice::index::usize::get_unchecked]: forward function *)
+Axiom core_slice_index_usize_get_unchecked :
+ forall (T : Type), usize -> const_raw_ptr (slice T) -> result (const_raw_ptr T).
+
+(* [core::slice::index::usize::get_unchecked_mut]: forward function *)
+Axiom core_slice_index_usize_get_unchecked_mut :
+ forall (T : Type), usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr T).
+
+(* [core::slice::index::usize::index]: forward function *)
+Axiom core_slice_index_usize_index : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: forward function *)
+Axiom core_slice_index_usize_index_mut : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: backward function 0 *)
+Axiom core_slice_index_usize_index_mut_back :
+ forall (T : Type), usize -> slice T -> T -> result (slice T).
+
+(* Trait implementation: [core::slice::index::private_slice_index::usize] *)
+Definition core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize := tt.
+
+(* Trait implementation: [core::slice::index::usize] *)
+Definition core_slice_index_usize_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex usize (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := T;
+ core_slice_index_SliceIndex_get := core_slice_index_usize_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_usize_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_usize_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_usize_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_usize_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_usize_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_usize_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_usize_index_mut_back T;
+|}.
+
+(* [alloc::vec::Vec::index]: forward function *)
+Axiom alloc_vec_Vec_index : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: forward function *)
+Axiom alloc_vec_Vec_index_mut : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: backward function 0 *)
+Axiom alloc_vec_Vec_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx) (x : inst.(core_slice_index_SliceIndex_Output)), result (alloc_vec_Vec T).
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (alloc_vec_Vec T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := alloc_vec_Vec_index T Idx inst;
+|}.
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (alloc_vec_Vec T) Idx := {|
+ core_ops_index_IndexMut_indexInst := alloc_vec_Vec_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := alloc_vec_Vec_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := alloc_vec_Vec_index_mut_back T Idx inst;
+|}.
+
+(*** Theorems *)
+
+Axiom alloc_vec_Vec_index_mut_back_eq : forall {a : Type} (v : alloc_vec_Vec a) (i : usize) (x : a),
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x =
+ alloc_vec_Vec_update_usize v i x.
End Primitives.
diff --git a/backends/fstar/Primitives.fst b/backends/fstar/Primitives.fst
index 9db82069..3297803c 100644
--- a/backends/fstar/Primitives.fst
+++ b/backends/fstar/Primitives.fst
@@ -55,8 +55,12 @@ type string = string
let is_zero (n: nat) : bool = n = 0
let decrease (n: nat{n > 0}) : nat = n - 1
-let mem_replace_fwd (a : Type0) (x : a) (y : a) : a = x
-let mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+let core_mem_replace (a : Type0) (x : a) (y : a) : a = x
+let core_mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+
+// We don't really use raw pointers for now
+type mut_raw_ptr (t : Type0) = { v : t }
+type const_raw_ptr (t : Type0) = { v : t }
(*** Scalars *)
/// Rem.: most of the following code was partially generated
@@ -100,6 +104,11 @@ type scalar_ty =
| U64
| U128
+let is_unsigned = function
+ | Isize | I8 | I16 | I32 | I64 | I128 -> false
+ | Usize | U8 | U16 | U32 | U64 | U128 -> true
+
+
let scalar_min (ty : scalar_ty) : int =
match ty with
| Isize -> isize_min
@@ -162,6 +171,15 @@ let scalar_sub (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scala
let scalar_mul (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
mk_scalar ty (x * y)
+let scalar_lxor (#ty : scalar_ty { is_unsigned ty && ty <> Usize })
+ (x : scalar ty) (y : scalar ty) : scalar ty =
+ match ty with
+ | U8 -> FStar.UInt.logxor #8 x y
+ | U16 -> FStar.UInt.logxor #16 x y
+ | U32 -> FStar.UInt.logxor #32 x y
+ | U64 -> FStar.UInt.logxor #64 x y
+ | U128 -> FStar.UInt.logxor #128 x y
+
(** Cast an integer from a [src_ty] to a [tgt_ty] *)
// TODO: check the semantics of casts in Rust
let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) =
@@ -169,17 +187,44 @@ let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) :
/// The scalar types
type isize : eqtype = scalar Isize
-type i8 : eqtype = scalar I8
-type i16 : eqtype = scalar I16
-type i32 : eqtype = scalar I32
-type i64 : eqtype = scalar I64
-type i128 : eqtype = scalar I128
+type i8 : eqtype = scalar I8
+type i16 : eqtype = scalar I16
+type i32 : eqtype = scalar I32
+type i64 : eqtype = scalar I64
+type i128 : eqtype = scalar I128
type usize : eqtype = scalar Usize
-type u8 : eqtype = scalar U8
-type u16 : eqtype = scalar U16
-type u32 : eqtype = scalar U32
-type u64 : eqtype = scalar U64
-type u128 : eqtype = scalar U128
+type u8 : eqtype = scalar U8
+type u16 : eqtype = scalar U16
+type u32 : eqtype = scalar U32
+type u64 : eqtype = scalar U64
+type u128 : eqtype = scalar U128
+
+
+let core_isize_min : isize = isize_min
+let core_isize_max : isize = isize_max
+let core_i8_min : i8 = i8_min
+let core_i8_max : i8 = i8_max
+let core_i16_min : i16 = i16_min
+let core_i16_max : i16 = i16_max
+let core_i32_min : i32 = i32_min
+let core_i32_max : i32 = i32_max
+let core_i64_min : i64 = i64_min
+let core_i64_max : i64 = i64_max
+let core_i128_min : i128 = i128_min
+let core_i128_max : i128 = i128_max
+
+let core_usize_min : usize = usize_min
+let core_usize_max : usize = usize_max
+let core_u8_min : u8 = u8_min
+let core_u8_max : u8 = u8_max
+let core_u16_min : u16 = u16_min
+let core_u16_max : u16 = u16_max
+let core_u32_min : u32 = u32_min
+let core_u32_max : u32 = u32_max
+let core_u64_min : u64 = u64_min
+let core_u64_max : u64 = u64_max
+let core_u128_min : u128 = u128_min
+let core_u128_max : u128 = u128_max
/// Negation
let isize_neg = scalar_neg #Isize
@@ -231,7 +276,7 @@ let u32_add = scalar_add #U32
let u64_add = scalar_add #U64
let u128_add = scalar_add #U128
-/// Substraction
+/// Subtraction
let isize_sub = scalar_sub #Isize
let i8_sub = scalar_sub #I8
let i16_sub = scalar_sub #I16
@@ -259,12 +304,65 @@ let u32_mul = scalar_mul #U32
let u64_mul = scalar_mul #U64
let u128_mul = scalar_mul #U128
-(*** Range *)
-type range (a : Type0) = {
+/// Logical operators, defined for unsigned types only, so far
+let u8_xor = scalar_lxor #U8
+let u16_xor = scalar_lxor #U16
+let u32_xor = scalar_lxor #U32
+let u64_xor = scalar_lxor #U64
+let u128_xor = scalar_lxor #U128
+
+(*** core::ops *)
+
+// Trait declaration: [core::ops::index::Index]
+noeq type core_ops_index_Index (self idx : Type0) = {
+ output : Type0;
+ index : self → idx → result output
+}
+
+// Trait declaration: [core::ops::index::IndexMut]
+noeq type core_ops_index_IndexMut (self idx : Type0) = {
+ indexInst : core_ops_index_Index self idx;
+ index_mut : self → idx → result indexInst.output;
+ index_mut_back : self → idx → indexInst.output → result self;
+}
+
+// Trait declaration [core::ops::deref::Deref]
+noeq type core_ops_deref_Deref (self : Type0) = {
+ target : Type0;
+ deref : self → result target;
+}
+
+// Trait declaration [core::ops::deref::DerefMut]
+noeq type core_ops_deref_DerefMut (self : Type0) = {
+ derefInst : core_ops_deref_Deref self;
+ deref_mut : self → result derefInst.target;
+ deref_mut_back : self → derefInst.target → result self;
+}
+
+type core_ops_range_Range (a : Type0) = {
start : a;
end_ : a;
}
+(*** [alloc] *)
+
+let alloc_boxed_Box_deref (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut_back (t : Type) (_ : t) (x : t) : result t = Return x
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefInst (self : Type0) : core_ops_deref_Deref self = {
+ target = self;
+ deref = alloc_boxed_Box_deref self;
+}
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefMutInst (self : Type0) : core_ops_deref_DerefMut self = {
+ derefInst = alloc_boxed_Box_coreOpsDerefInst self;
+ deref_mut = alloc_boxed_Box_deref_mut self;
+ deref_mut_back = alloc_boxed_Box_deref_mut_back self;
+}
+
(*** Array *)
type array (a : Type0) (n : usize) = s:list a{length s = n}
@@ -278,15 +376,11 @@ let mk_array (a : Type0) (n : usize)
normalize_term_spec (FStar.List.Tot.length l);
l
-let array_index_shared (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let array_index_mut_fwd (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
+let array_index_usize (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let array_index_mut_back (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
+let array_update_usize (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
if i < length x then Return (list_update x i nx)
else Fail Failure
@@ -295,55 +389,54 @@ type slice (a : Type0) = s:list a{length s <= usize_max}
let slice_len (a : Type0) (s : slice a) : usize = length s
-let slice_index_shared (a : Type0) (x : slice a) (i : usize) : result a =
+let slice_index_usize (a : Type0) (x : slice a) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let slice_index_mut_fwd (a : Type0) (x : slice a) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let slice_index_mut_back (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
+let slice_update_usize (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
if i < length x then Return (list_update x i nx)
else Fail Failure
(*** Subslices *)
-let array_to_slice_shared (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_fwd (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_back (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
+let array_to_slice (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
+let array_from_slice (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
if length s = n then Return s
else Fail Failure
// TODO: finish the definitions below (there lacks [List.drop] and [List.take] in the standard library *)
-let array_subslice_shared (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
- admit()
-
-let array_subslice_mut_fwd (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
+let array_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let array_subslice_mut_back (a : Type0) (n : usize) (x : array a n) (r : range usize) (ns : slice a) : result (array a n) =
+let array_update_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) (ns : slice a) : result (array a n) =
admit()
-let slice_subslice_shared (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let array_repeat (a : Type0) (n : usize) (x : a) : array a n =
admit()
-let slice_subslice_mut_fwd (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let slice_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let slice_subslice_mut_back (a : Type0) (x : slice a) (r : range usize) (ns : slice a) : result (slice a) =
+let slice_update_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) (ns : slice a) : result (slice a) =
admit()
(*** Vector *)
-type vec (a : Type0) = v:list a{length v <= usize_max}
+type alloc_vec_Vec (a : Type0) = v:list a{length v <= usize_max}
-let vec_new (a : Type0) : vec a = assert_norm(length #a [] == 0); []
-let vec_len (a : Type0) (v : vec a) : usize = length v
+let alloc_vec_Vec_new (a : Type0) : alloc_vec_Vec a = assert_norm(length #a [] == 0); []
+let alloc_vec_Vec_len (a : Type0) (v : alloc_vec_Vec a) : usize = length v
+
+// Helper
+let alloc_vec_Vec_index_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) : result a =
+ if i < length v then Return (index v i) else Fail Failure
+// Helper
+let alloc_vec_Vec_update_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
// The **forward** function shouldn't be used
-let vec_push_fwd (a : Type0) (v : vec a) (x : a) : unit = ()
-let vec_push_back (a : Type0) (v : vec a) (x : a) :
- Pure (result (vec a))
+let alloc_vec_Vec_push_fwd (a : Type0) (v : alloc_vec_Vec a) (x : a) : unit = ()
+let alloc_vec_Vec_push (a : Type0) (v : alloc_vec_Vec a) (x : a) :
+ Pure (result (alloc_vec_Vec a))
(requires True)
(ensures (fun res ->
match res with
@@ -358,18 +451,279 @@ let vec_push_back (a : Type0) (v : vec a) (x : a) :
else Fail Failure
// The **forward** function shouldn't be used
-let vec_insert_fwd (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
+let alloc_vec_Vec_insert_fwd (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result unit =
if i < length v then Return () else Fail Failure
-let vec_insert_back (a : Type0) (v : vec a) (i : usize) (x : a) : result (vec a) =
+let alloc_vec_Vec_insert (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
if i < length v then Return (list_update v i x) else Fail Failure
-// The **backward** function shouldn't be used
-let vec_index_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_back (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
- if i < length v then Return () else Fail Failure
+// Trait declaration: [core::slice::index::private_slice_index::Sealed]
+type core_slice_index_private_slice_index_Sealed (self : Type0) = unit
+
+// Trait declaration: [core::slice::index::SliceIndex]
+noeq type core_slice_index_SliceIndex (self t : Type0) = {
+ sealedInst : core_slice_index_private_slice_index_Sealed self;
+ output : Type0;
+ get : self → t → result (option output);
+ get_mut : self → t → result (option output);
+ get_mut_back : self → t → option output → result t;
+ get_unchecked : self → const_raw_ptr t → result (const_raw_ptr output);
+ get_unchecked_mut : self → mut_raw_ptr t → result (mut_raw_ptr output);
+ index : self → t → result output;
+ index_mut : self → t → result output;
+ index_mut_back : self → t → output → result t;
+}
-let vec_index_mut_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_mut_back (a : Type0) (v : vec a) (i : usize) (nx : a) : result (vec a) =
- if i < length v then Return (list_update v i nx) else Fail Failure
+// [core::slice::index::[T]::index]: forward function
+let core_slice_index_Slice_index
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (s : slice t) (i : idx) : result inst.output =
+ let* x = inst.get i s in
+ match x with
+ | None -> Fail Failure
+ | Some x -> Return x
+
+// [core::slice::index::Range:::get]: forward function
+let core_slice_index_Range_get (t : Type0) (i : core_ops_range_Range usize) (s : slice t) :
+ result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: forward function
+let core_slice_index_Range_get_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: backward function 0
+let core_slice_index_Range_get_mut_back
+ (t : Type0) :
+ core_ops_range_Range usize → slice t → option (slice t) → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_unchecked]: forward function
+let core_slice_index_Range_get_unchecked
+ (t : Type0) :
+ core_ops_range_Range usize → const_raw_ptr (slice t) → result (const_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::get_unchecked_mut]: forward function
+let core_slice_index_Range_get_unchecked_mut
+ (t : Type0) :
+ core_ops_range_Range usize → mut_raw_ptr (slice t) → result (mut_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::index]: forward function
+let core_slice_index_Range_index
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: forward function
+let core_slice_index_Range_index_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: backward function 0
+let core_slice_index_Range_index_mut_back
+ (t : Type0) : core_ops_range_Range usize → slice t → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::[T]::index_mut]: forward function
+let core_slice_index_Slice_index_mut
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → result inst.output =
+ admit () //
+
+// [core::slice::index::[T]::index_mut]: backward function 0
+let core_slice_index_Slice_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → inst.output → result (slice t) =
+ admit () // TODO
+
+// [core::array::[T; N]::index]: forward function
+let core_array_Array_index
+ (t idx : Type0) (n : usize) (inst : core_ops_index_Index (slice t) idx)
+ (a : array t n) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: forward function
+let core_array_Array_index_mut
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) : result inst.indexInst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: backward function 0
+let core_array_Array_index_mut_back
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) (x : inst.indexInst.output) : result (array t n) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (slice t) idx = {
+ output = inst.output;
+ index = core_slice_index_Slice_index t idx inst;
+}
+
+// Trait implementation: [core::slice::index::private_slice_index::Range]
+let core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) = ()
+
+// Trait implementation: [core::slice::index::Range]
+let core_slice_index_Range_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ output = slice t;
+ get = core_slice_index_Range_get t;
+ get_mut = core_slice_index_Range_get_mut t;
+ get_mut_back = core_slice_index_Range_get_mut_back t;
+ get_unchecked = core_slice_index_Range_get_unchecked t;
+ get_unchecked_mut = core_slice_index_Range_get_unchecked_mut t;
+ index = core_slice_index_Range_index t;
+ index_mut = core_slice_index_Range_index_mut t;
+ index_mut_back = core_slice_index_Range_index_mut_back t;
+}
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (slice t) idx = {
+ indexInst = core_slice_index_Slice_coreopsindexIndexInst t idx inst;
+ index_mut = core_slice_index_Slice_index_mut t idx inst;
+ index_mut_back = core_slice_index_Slice_index_mut_back t idx inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_Index (slice t) idx) :
+ core_ops_index_Index (array t n) idx = {
+ output = inst.output;
+ index = core_array_Array_index t idx n inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexMutInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_IndexMut (slice t) idx) :
+ core_ops_index_IndexMut (array t n) idx = {
+ indexInst = core_array_Array_coreopsindexIndexInst t idx n inst.indexInst;
+ index_mut = core_array_Array_index_mut t idx n inst;
+ index_mut_back = core_array_Array_index_mut_back t idx n inst;
+}
+
+// [core::slice::index::usize::get]: forward function
+let core_slice_index_usize_get
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: forward function
+let core_slice_index_usize_get_mut
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: backward function 0
+let core_slice_index_usize_get_mut_back
+ (t : Type0) : usize → slice t → option t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked]: forward function
+let core_slice_index_usize_get_unchecked
+ (t : Type0) : usize → const_raw_ptr (slice t) → result (const_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked_mut]: forward function
+let core_slice_index_usize_get_unchecked_mut
+ (t : Type0) : usize → mut_raw_ptr (slice t) → result (mut_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::index]: forward function
+let core_slice_index_usize_index (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: forward function
+let core_slice_index_usize_index_mut (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: backward function 0
+let core_slice_index_usize_index_mut_back
+ (t : Type0) : usize → slice t → t → result (slice t) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::private_slice_index::usize]
+let core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize = ()
+
+// Trait implementation: [core::slice::index::usize]
+let core_slice_index_usize_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex usize (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ output = t;
+ get = core_slice_index_usize_get t;
+ get_mut = core_slice_index_usize_get_mut t;
+ get_mut_back = core_slice_index_usize_get_mut_back t;
+ get_unchecked = core_slice_index_usize_get_unchecked t;
+ get_unchecked_mut = core_slice_index_usize_get_unchecked_mut t;
+ index = core_slice_index_usize_index t;
+ index_mut = core_slice_index_usize_index_mut t;
+ index_mut_back = core_slice_index_usize_index_mut_back t;
+}
+
+// [alloc::vec::Vec::index]: forward function
+let alloc_vec_Vec_index (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: forward function
+let alloc_vec_Vec_index_mut (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: backward function 0
+let alloc_vec_Vec_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) (x : inst.output) : result (alloc_vec_Vec t) =
+ admit () // TODO
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (alloc_vec_Vec t) idx = {
+ output = inst.output;
+ index = alloc_vec_Vec_index t idx inst;
+}
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (alloc_vec_Vec t) idx = {
+ indexInst = alloc_vec_Vec_coreopsindexIndexInst t idx inst;
+ index_mut = alloc_vec_Vec_index_mut t idx inst;
+ index_mut_back = alloc_vec_Vec_index_mut_back t idx inst;
+}
+
+(*** Theorems *)
+
+let alloc_vec_Vec_index_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_back_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) :
+ Lemma (
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x ==
+ alloc_vec_Vec_update_usize v i x)
+ [SMTPat (alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x)]
+ =
+ admit()
diff --git a/backends/hol4/primitivesScript.sml b/backends/hol4/primitivesScript.sml
index 82da4de9..916988be 100644
--- a/backends/hol4/primitivesScript.sml
+++ b/backends/hol4/primitivesScript.sml
@@ -555,6 +555,32 @@ Proof
QED
val _ = evalLib.add_unfold_thm "mk_isize_unfold"
+(** Constants *)
+val core_i8_min_def = Define ‘core_i8_min = int_to_i8 i8_min’
+val core_i8_max_def = Define ‘core_i8_max = int_to_i8 i8_max’
+val core_i16_min_def = Define ‘core_i16_min = int_to_i16 i16_min’
+val core_i16_max_def = Define ‘core_i16_max = int_to_i16 i16_max’
+val core_i32_min_def = Define ‘core_i32_min = int_to_i32 i32_min’
+val core_i32_max_def = Define ‘core_i32_max = int_to_i32 i32_max’
+val core_i64_min_def = Define ‘core_i64_min = int_to_i64 i64_min’
+val core_i64_max_def = Define ‘core_i64_max = int_to_i64 i64_max’
+val core_i128_min_def = Define ‘core_i128_min = int_to_i128 i128_min’
+val core_i128_max_def = Define ‘core_i128_max = int_to_i128 i128_max’
+val core_isize_min_def = Define ‘core_isize_min = int_to_isize isize_min’
+val core_isize_max_def = Define ‘core_isize_max = int_to_isize isize_max’
+val core_u8_min_def = Define ‘core_u8_min = int_to_u8 0’
+val core_u8_max_def = Define ‘core_u8_max = int_to_u8 u8_max’
+val core_u16_min_def = Define ‘core_u16_min = int_to_u16 0’
+val core_u16_max_def = Define ‘core_u16_max = int_to_u16 u16_max’
+val core_u32_min_def = Define ‘core_u32_min = int_to_u32 0’
+val core_u32_max_def = Define ‘core_u32_max = int_to_u32 u32_max’
+val core_u64_min_def = Define ‘core_u64_min = int_to_u64 0’
+val core_u64_max_def = Define ‘core_u64_max = int_to_u64 u64_max’
+val core_u128_min_def = Define ‘core_u128_min = int_to_u128 0’
+val core_u128_max_def = Define ‘core_u128_max = int_to_u128 u128_max’
+val core_usize_min_def = Define ‘core_usize_min = int_to_usize 0’
+val core_usize_max_def = Define ‘core_usize_max = int_to_usize usize_max’
+
val isize_neg_def = Define ‘isize_neg x = mk_isize (- (isize_to_int x))’
val i8_neg_def = Define ‘i8_neg x = mk_i8 (- (i8_to_int x))’
val i16_neg_def = Define ‘i16_neg x = mk_i16 (- (i16_to_int x))’
diff --git a/backends/hol4/primitivesTheory.sig b/backends/hol4/primitivesTheory.sig
index 6660b02d..4ae6bb3e 100644
--- a/backends/hol4/primitivesTheory.sig
+++ b/backends/hol4/primitivesTheory.sig
@@ -46,6 +46,30 @@ sig
(* Definitions *)
val bind_def : thm
+ val core_i128_max_def : thm
+ val core_i128_min_def : thm
+ val core_i16_max_def : thm
+ val core_i16_min_def : thm
+ val core_i32_max_def : thm
+ val core_i32_min_def : thm
+ val core_i64_max_def : thm
+ val core_i64_min_def : thm
+ val core_i8_max_def : thm
+ val core_i8_min_def : thm
+ val core_isize_max_def : thm
+ val core_isize_min_def : thm
+ val core_u128_max_def : thm
+ val core_u128_min_def : thm
+ val core_u16_max_def : thm
+ val core_u16_min_def : thm
+ val core_u32_max_def : thm
+ val core_u32_min_def : thm
+ val core_u64_max_def : thm
+ val core_u64_min_def : thm
+ val core_u8_max_def : thm
+ val core_u8_min_def : thm
+ val core_usize_max_def : thm
+ val core_usize_min_def : thm
val error_BIJ : thm
val error_CASE : thm
val error_TY_DEF : thm
@@ -566,6 +590,102 @@ sig
monad_bind x f =
case x of Return y => f y | Fail e => Fail e | Diverge => Diverge
+ [core_i128_max_def] Definition
+
+ ⊢ core_i128_max = int_to_i128 i128_max
+
+ [core_i128_min_def] Definition
+
+ ⊢ core_i128_min = int_to_i128 i128_min
+
+ [core_i16_max_def] Definition
+
+ ⊢ core_i16_max = int_to_i16 i16_max
+
+ [core_i16_min_def] Definition
+
+ ⊢ core_i16_min = int_to_i16 i16_min
+
+ [core_i32_max_def] Definition
+
+ ⊢ core_i32_max = int_to_i32 i32_max
+
+ [core_i32_min_def] Definition
+
+ ⊢ core_i32_min = int_to_i32 i32_min
+
+ [core_i64_max_def] Definition
+
+ ⊢ core_i64_max = int_to_i64 i64_max
+
+ [core_i64_min_def] Definition
+
+ ⊢ core_i64_min = int_to_i64 i64_min
+
+ [core_i8_max_def] Definition
+
+ ⊢ core_i8_max = int_to_i8 i8_max
+
+ [core_i8_min_def] Definition
+
+ ⊢ core_i8_min = int_to_i8 i8_min
+
+ [core_isize_max_def] Definition
+
+ ⊢ core_isize_max = int_to_isize isize_max
+
+ [core_isize_min_def] Definition
+
+ ⊢ core_isize_min = int_to_isize isize_min
+
+ [core_u128_max_def] Definition
+
+ ⊢ core_u128_max = int_to_u128 u128_max
+
+ [core_u128_min_def] Definition
+
+ ⊢ core_u128_min = int_to_u128 0
+
+ [core_u16_max_def] Definition
+
+ ⊢ core_u16_max = int_to_u16 u16_max
+
+ [core_u16_min_def] Definition
+
+ ⊢ core_u16_min = int_to_u16 0
+
+ [core_u32_max_def] Definition
+
+ ⊢ core_u32_max = int_to_u32 u32_max
+
+ [core_u32_min_def] Definition
+
+ ⊢ core_u32_min = int_to_u32 0
+
+ [core_u64_max_def] Definition
+
+ ⊢ core_u64_max = int_to_u64 u64_max
+
+ [core_u64_min_def] Definition
+
+ ⊢ core_u64_min = int_to_u64 0
+
+ [core_u8_max_def] Definition
+
+ ⊢ core_u8_max = int_to_u8 u8_max
+
+ [core_u8_min_def] Definition
+
+ ⊢ core_u8_min = int_to_u8 0
+
+ [core_usize_max_def] Definition
+
+ ⊢ core_usize_max = int_to_usize usize_max
+
+ [core_usize_min_def] Definition
+
+ ⊢ core_usize_min = int_to_usize 0
+
[error_BIJ] Definition
⊢ (∀a. num2error (error2num a) = a) ∧
diff --git a/backends/lean/Base/Arith/Base.lean b/backends/lean/Base/Arith/Base.lean
index 9c11ed45..8ada4171 100644
--- a/backends/lean/Base/Arith/Base.lean
+++ b/backends/lean/Base/Arith/Base.lean
@@ -57,4 +57,16 @@ theorem int_pos_ind (p : Int → Prop) :
-- TODO: there is probably something more general to do
theorem nat_zero_eq_int_zero : (0 : Nat) = (0 : Int) := by simp
+-- This is mostly used in termination proofs
+theorem to_int_to_nat_lt (x y : ℤ) (h0 : 0 ≤ x) (h1 : x < y) :
+ ↑(x.toNat) < y := by
+ simp [*]
+
+-- This is mostly used in termination proofs
+theorem to_int_sub_to_nat_lt (x y : ℤ) (x' : ℕ)
+ (h0 : ↑x' ≤ x) (h1 : x - ↑x' < y) :
+ ↑(x.toNat - x') < y := by
+ have : 0 ≤ x := by linarith
+ simp [Int.toNat_sub_of_le, *]
+
end Arith
diff --git a/backends/lean/Base/Arith/Int.lean b/backends/lean/Base/Arith/Int.lean
index 3359ecdb..a57f8bb1 100644
--- a/backends/lean/Base/Arith/Int.lean
+++ b/backends/lean/Base/Arith/Int.lean
@@ -162,7 +162,7 @@ def introInstances (declToUnfold : Name) (lookup : Expr → MetaM (Option Expr))
-- Add a declaration
let nval ← Utils.addDeclTac name e type (asLet := false)
-- Simplify to unfold the declaration to unfold (i.e., the projector)
- Utils.simpAt [declToUnfold] [] [] (Tactic.Location.targets #[mkIdent name] false)
+ Utils.simpAt true [declToUnfold] [] [] (Location.targets #[mkIdent name] false)
-- Return the new value
pure nval
@@ -240,7 +240,7 @@ def intTac (splitGoalConjs : Bool) (extraPreprocess : Tactic.TacticM Unit) : Ta
-- the goal. I think before leads to a smaller proof term?
Tactic.allGoals (intTacPreprocess extraPreprocess)
-- More preprocessing
- Tactic.allGoals (Utils.tryTac (Utils.simpAt [] [``nat_zero_eq_int_zero] [] .wildcard))
+ Tactic.allGoals (Utils.tryTac (Utils.simpAt true [] [``nat_zero_eq_int_zero] [] .wildcard))
-- Split the conjunctions in the goal
if splitGoalConjs then Tactic.allGoals (Utils.repeatTac Utils.splitConjTarget)
-- Call linarith
@@ -270,6 +270,17 @@ elab "int_tac" args:(" split_goal"?): tactic =>
let split := args.raw.getArgs.size > 0
intTac split (do pure ())
+-- For termination proofs
+syntax "int_decr_tac" : tactic
+macro_rules
+ | `(tactic| int_decr_tac) =>
+ `(tactic|
+ simp_wf;
+ -- TODO: don't use a macro (namespace problems)
+ (first | apply Arith.to_int_to_nat_lt
+ | apply Arith.to_int_sub_to_nat_lt) <;>
+ simp_all <;> int_tac)
+
example (x : Int) (h0: 0 ≤ x) (h1: x ≠ 0) : 0 < x := by
int_tac_preprocess
linarith
diff --git a/backends/lean/Base/Arith/Scalar.lean b/backends/lean/Base/Arith/Scalar.lean
index 47751c8a..2342cce6 100644
--- a/backends/lean/Base/Arith/Scalar.lean
+++ b/backends/lean/Base/Arith/Scalar.lean
@@ -17,7 +17,7 @@ def scalarTacExtraPreprocess : Tactic.TacticM Unit := do
add (← mkAppM ``Scalar.cMax_bound #[.const ``ScalarTy.Usize []])
add (← mkAppM ``Scalar.cMax_bound #[.const ``ScalarTy.Isize []])
-- Reveal the concrete bounds, simplify calls to [ofInt]
- Utils.simpAt [``Scalar.min, ``Scalar.max, ``Scalar.cMin, ``Scalar.cMax,
+ Utils.simpAt true [``Scalar.min, ``Scalar.max, ``Scalar.cMin, ``Scalar.cMax,
``I8.min, ``I16.min, ``I32.min, ``I64.min, ``I128.min,
``I8.max, ``I16.max, ``I32.max, ``I64.max, ``I128.max,
``U8.min, ``U16.min, ``U32.min, ``U64.min, ``U128.min,
@@ -36,6 +36,17 @@ def scalarTac (splitGoalConjs : Bool) : Tactic.TacticM Unit := do
elab "scalar_tac" : tactic =>
scalarTac false
+-- For termination proofs
+syntax "scalar_decr_tac" : tactic
+macro_rules
+ | `(tactic| scalar_decr_tac) =>
+ `(tactic|
+ simp_wf;
+ -- TODO: don't use a macro (namespace problems)
+ (first | apply Arith.to_int_to_nat_lt
+ | apply Arith.to_int_sub_to_nat_lt) <;>
+ simp_all <;> scalar_tac)
+
instance (ty : ScalarTy) : HasIntProp (Scalar ty) where
-- prop_ty is inferred
prop := λ x => And.intro x.hmin x.hmax
diff --git a/backends/lean/Base/IList/IList.lean b/backends/lean/Base/IList/IList.lean
index a940da25..f71f2de2 100644
--- a/backends/lean/Base/IList/IList.lean
+++ b/backends/lean/Base/IList/IList.lean
@@ -112,7 +112,13 @@ def pairwise_rel
section Lemmas
-variable {α : Type u}
+variable {α : Type u}
+
+def ireplicate {α : Type u} (i : ℤ) (x : α) : List α :=
+ if i ≤ 0 then []
+ else x :: ireplicate (i - 1) x
+termination_by ireplicate i x => i.toNat
+decreasing_by int_decr_tac
@[simp] theorem update_nil : update ([] : List α) i y = [] := by simp [update]
@[simp] theorem update_zero_cons : update ((x :: tl) : List α) 0 y = y :: tl := by simp [update]
@@ -129,6 +135,10 @@ variable {α : Type u}
@[simp] theorem slice_nil : slice i j ([] : List α) = [] := by simp [slice]
@[simp] theorem slice_zero : slice 0 0 (ls : List α) = [] := by cases ls <;> simp [slice]
+@[simp] theorem ireplicate_zero : ireplicate 0 x = [] := by rw [ireplicate]; simp
+@[simp] theorem ireplicate_nzero_cons (hne : 0 < i) : ireplicate i x = x :: ireplicate (i - 1) x := by
+ rw [ireplicate]; simp [*]; intro; linarith
+
@[simp]
theorem slice_nzero_cons (i j : Int) (x : α) (tl : List α) (hne : i ≠ 0) : slice i j ((x :: tl) : List α) = slice (i - 1) (j - 1) tl :=
match tl with
@@ -144,6 +154,33 @@ theorem slice_nzero_cons (i j : Int) (x : α) (tl : List α) (hne : i ≠ 0) : s
conv at this => lhs; simp [slice, *]
simp [*, slice]
+@[simp]
+theorem ireplicate_replicate {α : Type u} (l : ℤ) (x : α) (h : 0 ≤ l) :
+ ireplicate l x = replicate l.toNat x :=
+ if hz: l = 0 then by
+ simp [*]
+ else by
+ have : 0 < l := by int_tac
+ have hr := ireplicate_replicate (l - 1) x (by int_tac)
+ simp [*]
+ have hl : l.toNat = .succ (l.toNat - 1) := by
+ cases hl: l.toNat <;> simp_all
+ conv => rhs; rw[hl]
+termination_by ireplicate_replicate l x h => l.toNat
+decreasing_by int_decr_tac
+
+@[simp]
+theorem ireplicate_len {α : Type u} (l : ℤ) (x : α) (h : 0 ≤ l) :
+ (ireplicate l x).len = l :=
+ if hz: l = 0 then by
+ simp [*]
+ else by
+ have : 0 < l := by int_tac
+ have hr := ireplicate_len (l - 1) x (by int_tac)
+ simp [*]
+termination_by ireplicate_len l x h => l.toNat
+decreasing_by int_decr_tac
+
theorem len_eq_length (ls : List α) : ls.len = ls.length := by
induction ls
. rfl
diff --git a/backends/lean/Base/Primitives.lean b/backends/lean/Base/Primitives.lean
index 6b7b0792..613b6076 100644
--- a/backends/lean/Base/Primitives.lean
+++ b/backends/lean/Base/Primitives.lean
@@ -1,4 +1,6 @@
import Base.Primitives.Base
import Base.Primitives.Scalar
-import Base.Primitives.Array
+import Base.Primitives.ArraySlice
import Base.Primitives.Vec
+import Base.Primitives.Alloc
+import Base.Primitives.CoreOps
diff --git a/backends/lean/Base/Primitives/Alloc.lean b/backends/lean/Base/Primitives/Alloc.lean
new file mode 100644
index 00000000..34590499
--- /dev/null
+++ b/backends/lean/Base/Primitives/Alloc.lean
@@ -0,0 +1,37 @@
+import Lean
+import Base.Primitives.Base
+import Base.Primitives.CoreOps
+
+open Primitives
+open Result
+
+namespace alloc
+
+namespace boxed -- alloc.boxed
+
+namespace Box -- alloc.boxed.Box
+
+def deref (T : Type) (x : T) : Result T := ret x
+def deref_mut (T : Type) (x : T) : Result T := ret x
+def deref_mut_back (T : Type) (_ : T) (x : T) : Result T := ret x
+
+/-- Trait instance -/
+def coreOpsDerefInst (Self : Type) :
+ core.ops.deref.Deref Self := {
+ Target := Self
+ deref := deref Self
+}
+
+/-- Trait instance -/
+def coreOpsDerefMutInst (Self : Type) :
+ core.ops.deref.DerefMut Self := {
+ derefInst := coreOpsDerefInst Self
+ deref_mut := deref_mut Self
+ deref_mut_back := deref_mut_back Self
+}
+
+end Box -- alloc.boxed.Box
+
+end boxed -- alloc.boxed
+
+end alloc
diff --git a/backends/lean/Base/Primitives/Array.lean b/backends/lean/Base/Primitives/Array.lean
deleted file mode 100644
index 6c95fd78..00000000
--- a/backends/lean/Base/Primitives/Array.lean
+++ /dev/null
@@ -1,394 +0,0 @@
-/- Arrays/slices -/
-import Lean
-import Lean.Meta.Tactic.Simp
-import Init.Data.List.Basic
-import Mathlib.Tactic.RunCmd
-import Mathlib.Tactic.Linarith
-import Base.IList
-import Base.Primitives.Scalar
-import Base.Primitives.Range
-import Base.Arith
-import Base.Progress.Base
-
-namespace Primitives
-
-open Result Error
-
-def Array (α : Type u) (n : Usize) := { l : List α // l.length = n.val }
-
-instance (a : Type u) (n : Usize) : Arith.HasIntProp (Array a n) where
- prop_ty := λ v => v.val.len = n.val
- prop := λ ⟨ _, l ⟩ => by simp[Scalar.max, List.len_eq_length, *]
-
-instance {α : Type u} {n : Usize} (p : Array α n → Prop) : Arith.HasIntProp (Subtype p) where
- prop_ty := λ x => p x
- prop := λ x => x.property
-
-@[simp]
-abbrev Array.length {α : Type u} {n : Usize} (v : Array α n) : Int := v.val.len
-
-@[simp]
-abbrev Array.v {α : Type u} {n : Usize} (v : Array α n) : List α := v.val
-
-example {α: Type u} {n : Usize} (v : Array α n) : v.length ≤ Scalar.max ScalarTy.Usize := by
- scalar_tac
-
-def Array.make (α : Type u) (n : Usize) (init : List α) (hl : init.len = n.val := by decide) :
- Array α n := ⟨ init, by simp [← List.len_eq_length]; apply hl ⟩
-
-example : Array Int (Usize.ofInt 2) := Array.make Int (Usize.ofInt 2) [0, 1]
-
-@[simp]
-abbrev Array.index {α : Type u} {n : Usize} [Inhabited α] (v : Array α n) (i : Int) : α :=
- v.val.index i
-
-@[simp]
-abbrev Array.slice {α : Type u} {n : Usize} [Inhabited α] (v : Array α n) (i j : Int) : List α :=
- v.val.slice i j
-
-def Array.index_shared (α : Type u) (n : Usize) (v: Array α n) (i: Usize) : Result α :=
- match v.val.indexOpt i.val with
- | none => fail .arrayOutOfBounds
- | some x => ret x
-
-/- In the theorems below: we don't always need the `∃ ..`, but we use one
- so that `progress` introduces an opaque variable and an equality. This
- helps control the context.
- -/
-
-@[pspec]
-theorem Array.index_shared_spec {α : Type u} {n : Usize} [Inhabited α] (v: Array α n) (i: Usize)
- (hbound : i.val < v.length) :
- ∃ x, v.index_shared α n i = ret x ∧ x = v.val.index i.val := by
- simp only [index_shared]
- -- TODO: dependent rewrite
- have h := List.indexOpt_eq_index v.val i.val (by scalar_tac) (by simp [*])
- simp [*]
-
--- This shouldn't be used
-def Array.index_shared_back (α : Type u) (n : Usize) (v: Array α n) (i: Usize) (_: α) : Result Unit :=
- if i.val < List.length v.val then
- .ret ()
- else
- .fail arrayOutOfBounds
-
-def Array.index_mut (α : Type u) (n : Usize) (v: Array α n) (i: Usize) : Result α :=
- match v.val.indexOpt i.val with
- | none => fail .arrayOutOfBounds
- | some x => ret x
-
-@[pspec]
-theorem Array.index_mut_spec {α : Type u} {n : Usize} [Inhabited α] (v: Array α n) (i: Usize)
- (hbound : i.val < v.length) :
- ∃ x, v.index_mut α n i = ret x ∧ x = v.val.index i.val := by
- simp only [index_mut]
- -- TODO: dependent rewrite
- have h := List.indexOpt_eq_index v.val i.val (by scalar_tac) (by simp [*])
- simp [*]
-
-def Array.index_mut_back (α : Type u) (n : Usize) (v: Array α n) (i: Usize) (x: α) : Result (Array α n) :=
- match v.val.indexOpt i.val with
- | none => fail .arrayOutOfBounds
- | some _ =>
- .ret ⟨ v.val.update i.val x, by have := v.property; simp [*] ⟩
-
-@[pspec]
-theorem Array.index_mut_back_spec {α : Type u} {n : Usize} (v: Array α n) (i: Usize) (x : α)
- (hbound : i.val < v.length) :
- ∃ nv, v.index_mut_back α n i x = ret nv ∧
- nv.val = v.val.update i.val x
- := by
- simp only [index_mut_back]
- have h := List.indexOpt_bounds v.val i.val
- split
- . simp_all [length]; cases h <;> scalar_tac
- . simp_all
-
-def Slice (α : Type u) := { l : List α // l.length ≤ Usize.max }
-
-instance (a : Type u) : Arith.HasIntProp (Slice a) where
- prop_ty := λ v => 0 ≤ v.val.len ∧ v.val.len ≤ Scalar.max ScalarTy.Usize
- prop := λ ⟨ _, l ⟩ => by simp[Scalar.max, List.len_eq_length, *]
-
-instance {α : Type u} (p : Slice α → Prop) : Arith.HasIntProp (Subtype p) where
- prop_ty := λ x => p x
- prop := λ x => x.property
-
-@[simp]
-abbrev Slice.length {α : Type u} (v : Slice α) : Int := v.val.len
-
-@[simp]
-abbrev Slice.v {α : Type u} (v : Slice α) : List α := v.val
-
-example {a: Type u} (v : Slice a) : v.length ≤ Scalar.max ScalarTy.Usize := by
- scalar_tac
-
-def Slice.new (α : Type u): Slice α := ⟨ [], by apply Scalar.cMax_suffices .Usize; simp ⟩
-
--- TODO: very annoying that the α is an explicit parameter
-def Slice.len (α : Type u) (v : Slice α) : Usize :=
- Usize.ofIntCore v.val.len (by scalar_tac) (by scalar_tac)
-
-@[simp]
-theorem Slice.len_val {α : Type u} (v : Slice α) : (Slice.len α v).val = v.length :=
- by rfl
-
-@[simp]
-abbrev Slice.index {α : Type u} [Inhabited α] (v: Slice α) (i: Int) : α :=
- v.val.index i
-
-@[simp]
-abbrev Slice.slice {α : Type u} [Inhabited α] (s : Slice α) (i j : Int) : List α :=
- s.val.slice i j
-
-def Slice.index_shared (α : Type u) (v: Slice α) (i: Usize) : Result α :=
- match v.val.indexOpt i.val with
- | none => fail .arrayOutOfBounds
- | some x => ret x
-
-/- In the theorems below: we don't always need the `∃ ..`, but we use one
- so that `progress` introduces an opaque variable and an equality. This
- helps control the context.
- -/
-
-@[pspec]
-theorem Slice.index_shared_spec {α : Type u} [Inhabited α] (v: Slice α) (i: Usize)
- (hbound : i.val < v.length) :
- ∃ x, v.index_shared α i = ret x ∧ x = v.val.index i.val := by
- simp only [index_shared]
- -- TODO: dependent rewrite
- have h := List.indexOpt_eq_index v.val i.val (by scalar_tac) (by simp [*])
- simp [*]
-
--- This shouldn't be used
-def Slice.index_shared_back (α : Type u) (v: Slice α) (i: Usize) (_: α) : Result Unit :=
- if i.val < List.length v.val then
- .ret ()
- else
- .fail arrayOutOfBounds
-
-def Slice.index_mut (α : Type u) (v: Slice α) (i: Usize) : Result α :=
- match v.val.indexOpt i.val with
- | none => fail .arrayOutOfBounds
- | some x => ret x
-
-@[pspec]
-theorem Slice.index_mut_spec {α : Type u} [Inhabited α] (v: Slice α) (i: Usize)
- (hbound : i.val < v.length) :
- ∃ x, v.index_mut α i = ret x ∧ x = v.val.index i.val := by
- simp only [index_mut]
- -- TODO: dependent rewrite
- have h := List.indexOpt_eq_index v.val i.val (by scalar_tac) (by simp [*])
- simp [*]
-
-def Slice.index_mut_back (α : Type u) (v: Slice α) (i: Usize) (x: α) : Result (Slice α) :=
- match v.val.indexOpt i.val with
- | none => fail .arrayOutOfBounds
- | some _ =>
- .ret ⟨ v.val.update i.val x, by have := v.property; simp [*] ⟩
-
-@[pspec]
-theorem Slice.index_mut_back_spec {α : Type u} (v: Slice α) (i: Usize) (x : α)
- (hbound : i.val < v.length) :
- ∃ nv, v.index_mut_back α i x = ret nv ∧
- nv.val = v.val.update i.val x
- := by
- simp only [index_mut_back]
- have h := List.indexOpt_bounds v.val i.val
- split
- . simp_all [length]; cases h <;> scalar_tac
- . simp_all
-
-/- Array to slice/subslices -/
-
-/- We could make this function not use the `Result` type. By making it monadic, we
- push the user to use the `Array.to_slice_shared_spec` spec theorem below (through the
- `progress` tactic), meaning `Array.to_slice_shared` should be considered as opaque.
- All what the spec theorem reveals is that the "representative" lists are the same. -/
-def Array.to_slice_shared (α : Type u) (n : Usize) (v : Array α n) : Result (Slice α) :=
- ret ⟨ v.val, by simp [← List.len_eq_length]; scalar_tac ⟩
-
-@[pspec]
-theorem Array.to_slice_shared_spec {α : Type u} {n : Usize} (v : Array α n) :
- ∃ s, to_slice_shared α n v = ret s ∧ v.val = s.val := by simp [to_slice_shared]
-
-def Array.to_slice_mut (α : Type u) (n : Usize) (v : Array α n) : Result (Slice α) :=
- to_slice_shared α n v
-
-@[pspec]
-theorem Array.to_slice_mut_spec {α : Type u} {n : Usize} (v : Array α n) :
- ∃ s, Array.to_slice_shared α n v = ret s ∧ v.val = s.val := to_slice_shared_spec v
-
-def Array.to_slice_mut_back (α : Type u) (n : Usize) (_ : Array α n) (s : Slice α) : Result (Array α n) :=
- if h: s.val.len = n.val then
- ret ⟨ s.val, by simp [← List.len_eq_length, *] ⟩
- else fail panic
-
-@[pspec]
-theorem Array.to_slice_mut_back_spec {α : Type u} {n : Usize} (a : Array α n) (ns : Slice α) (h : ns.val.len = n.val) :
- ∃ na, to_slice_mut_back α n a ns = ret na ∧ na.val = ns.val
- := by simp [to_slice_mut_back, *]
-
-def Array.subslice_shared (α : Type u) (n : Usize) (a : Array α n) (r : Range Usize) : Result (Slice α) :=
- -- TODO: not completely sure here
- if r.start.val < r.end_.val ∧ r.end_.val ≤ a.val.len then
- ret ⟨ a.val.slice r.start.val r.end_.val,
- by
- simp [← List.len_eq_length]
- have := a.val.slice_len_le r.start.val r.end_.val
- scalar_tac ⟩
- else
- fail panic
-
-@[pspec]
-theorem Array.subslice_shared_spec {α : Type u} {n : Usize} [Inhabited α] (a : Array α n) (r : Range Usize)
- (h0 : r.start.val < r.end_.val) (h1 : r.end_.val ≤ a.val.len) :
- ∃ s, subslice_shared α n a r = ret s ∧
- s.val = a.val.slice r.start.val r.end_.val ∧
- (∀ i, 0 ≤ i → i + r.start.val < r.end_.val → s.val.index i = a.val.index (r.start.val + i))
- := by
- simp [subslice_shared, *]
- intro i _ _
- have := List.index_slice r.start.val r.end_.val i a.val (by scalar_tac) (by scalar_tac) (by trivial) (by scalar_tac)
- simp [*]
-
-def Array.subslice_mut (α : Type u) (n : Usize) (a : Array α n) (r : Range Usize) : Result (Slice α) :=
- Array.subslice_shared α n a r
-
-@[pspec]
-theorem Array.subslice_mut_spec {α : Type u} {n : Usize} [Inhabited α] (a : Array α n) (r : Range Usize)
- (h0 : r.start.val < r.end_.val) (h1 : r.end_.val ≤ a.val.len) :
- ∃ s, subslice_mut α n a r = ret s ∧
- s.val = a.slice r.start.val r.end_.val ∧
- (∀ i, 0 ≤ i → i + r.start.val < r.end_.val → s.val.index i = a.val.index (r.start.val + i))
- := subslice_shared_spec a r h0 h1
-
-def Array.subslice_mut_back (α : Type u) (n : Usize) (a : Array α n) (r : Range Usize) (s : Slice α) : Result (Array α n) :=
- -- TODO: not completely sure here
- if h: r.start.val < r.end_.val ∧ r.end_.val ≤ a.length ∧ s.val.len = r.end_.val - r.start.val then
- let s_beg := a.val.itake r.start.val
- let s_end := a.val.idrop r.end_.val
- have : s_beg.len = r.start.val := by
- apply List.itake_len
- . simp_all; scalar_tac
- . scalar_tac
- have : s_end.len = a.val.len - r.end_.val := by
- apply List.idrop_len
- . scalar_tac
- . scalar_tac
- let na := s_beg.append (s.val.append s_end)
- have : na.len = a.val.len := by simp [*]
- ret ⟨ na, by simp_all [← List.len_eq_length]; scalar_tac ⟩
- else
- fail panic
-
--- TODO: it is annoying to write `.val` everywhere. We could leverage coercions,
--- but: some symbols like `+` are already overloaded to be notations for monadic
--- operations/
--- We should introduce special symbols for the monadic arithmetic operations
--- (the use will never write those symbols directly).
-@[pspec]
-theorem Array.subslice_mut_back_spec {α : Type u} {n : Usize} [Inhabited α] (a : Array α n) (r : Range Usize) (s : Slice α)
- (_ : r.start.val < r.end_.val) (_ : r.end_.val ≤ a.length) (_ : s.length = r.end_.val - r.start.val) :
- ∃ na, subslice_mut_back α n a r s = ret na ∧
- (∀ i, 0 ≤ i → i < r.start.val → na.index i = a.index i) ∧
- (∀ i, r.start.val ≤ i → i < r.end_.val → na.index i = s.index (i - r.start.val)) ∧
- (∀ i, r.end_.val ≤ i → i < n.val → na.index i = a.index i) := by
- simp [subslice_mut_back, *]
- have h := List.replace_slice_index r.start.val r.end_.val a.val s.val
- (by scalar_tac) (by scalar_tac) (by scalar_tac) (by scalar_tac)
- simp [List.replace_slice] at h
- have ⟨ h0, h1, h2 ⟩ := h
- clear h
- split_conjs
- . intro i _ _
- have := h0 i (by int_tac) (by int_tac)
- simp [*]
- . intro i _ _
- have := h1 i (by int_tac) (by int_tac)
- simp [*]
- . intro i _ _
- have := h2 i (by int_tac) (by int_tac)
- simp [*]
-
-def Slice.subslice_shared (α : Type u) (s : Slice α) (r : Range Usize) : Result (Slice α) :=
- -- TODO: not completely sure here
- if r.start.val < r.end_.val ∧ r.end_.val ≤ s.length then
- ret ⟨ s.val.slice r.start.val r.end_.val,
- by
- simp [← List.len_eq_length]
- have := s.val.slice_len_le r.start.val r.end_.val
- scalar_tac ⟩
- else
- fail panic
-
-@[pspec]
-theorem Slice.subslice_shared_spec {α : Type u} [Inhabited α] (s : Slice α) (r : Range Usize)
- (h0 : r.start.val < r.end_.val) (h1 : r.end_.val ≤ s.val.len) :
- ∃ ns, subslice_shared α s r = ret ns ∧
- ns.val = s.slice r.start.val r.end_.val ∧
- (∀ i, 0 ≤ i → i + r.start.val < r.end_.val → ns.index i = s.index (r.start.val + i))
- := by
- simp [subslice_shared, *]
- intro i _ _
- have := List.index_slice r.start.val r.end_.val i s.val (by scalar_tac) (by scalar_tac) (by trivial) (by scalar_tac)
- simp [*]
-
-def Slice.subslice_mut (α : Type u) (s : Slice α) (r : Range Usize) : Result (Slice α) :=
- Slice.subslice_shared α s r
-
-@[pspec]
-theorem Slice.subslice_mut_spec {α : Type u} [Inhabited α] (s : Slice α) (r : Range Usize)
- (h0 : r.start.val < r.end_.val) (h1 : r.end_.val ≤ s.val.len) :
- ∃ ns, subslice_mut α s r = ret ns ∧
- ns.val = s.slice r.start.val r.end_.val ∧
- (∀ i, 0 ≤ i → i + r.start.val < r.end_.val → ns.index i = s.index (r.start.val + i))
- := subslice_shared_spec s r h0 h1
-
-attribute [pp_dot] List.len List.length List.index -- use the dot notation when printing
-set_option pp.coercions false -- do not print coercions with ↑ (this doesn't parse)
-
-def Slice.subslice_mut_back (α : Type u) (s : Slice α) (r : Range Usize) (ss : Slice α) : Result (Slice α) :=
- -- TODO: not completely sure here
- if h: r.start.val < r.end_.val ∧ r.end_.val ≤ s.length ∧ ss.val.len = r.end_.val - r.start.val then
- let s_beg := s.val.itake r.start.val
- let s_end := s.val.idrop r.end_.val
- have : s_beg.len = r.start.val := by
- apply List.itake_len
- . simp_all; scalar_tac
- . scalar_tac
- have : s_end.len = s.val.len - r.end_.val := by
- apply List.idrop_len
- . scalar_tac
- . scalar_tac
- let ns := s_beg.append (ss.val.append s_end)
- have : ns.len = s.val.len := by simp [*]
- ret ⟨ ns, by simp_all [← List.len_eq_length]; scalar_tac ⟩
- else
- fail panic
-
-@[pspec]
-theorem Slice.subslice_mut_back_spec {α : Type u} [Inhabited α] (a : Slice α) (r : Range Usize) (ss : Slice α)
- (_ : r.start.val < r.end_.val) (_ : r.end_.val ≤ a.length) (_ : ss.length = r.end_.val - r.start.val) :
- ∃ na, subslice_mut_back α a r ss = ret na ∧
- (∀ i, 0 ≤ i → i < r.start.val → na.index i = a.index i) ∧
- (∀ i, r.start.val ≤ i → i < r.end_.val → na.index i = ss.index (i - r.start.val)) ∧
- (∀ i, r.end_.val ≤ i → i < a.length → na.index i = a.index i) := by
- simp [subslice_mut_back, *]
- have h := List.replace_slice_index r.start.val r.end_.val a.val ss.val
- (by scalar_tac) (by scalar_tac) (by scalar_tac) (by scalar_tac)
- simp [List.replace_slice, *] at h
- have ⟨ h0, h1, h2 ⟩ := h
- clear h
- split_conjs
- . intro i _ _
- have := h0 i (by int_tac) (by int_tac)
- simp [*]
- . intro i _ _
- have := h1 i (by int_tac) (by int_tac)
- simp [*]
- . intro i _ _
- have := h2 i (by int_tac) (by int_tac)
- simp [*]
-
-end Primitives
diff --git a/backends/lean/Base/Primitives/ArraySlice.lean b/backends/lean/Base/Primitives/ArraySlice.lean
new file mode 100644
index 00000000..cfc9a6b2
--- /dev/null
+++ b/backends/lean/Base/Primitives/ArraySlice.lean
@@ -0,0 +1,553 @@
+/- Arrays/Slices -/
+import Lean
+import Lean.Meta.Tactic.Simp
+import Init.Data.List.Basic
+import Mathlib.Tactic.RunCmd
+import Mathlib.Tactic.Linarith
+import Base.IList
+import Base.Primitives.Scalar
+import Base.Primitives.Range
+import Base.Primitives.CoreOps
+import Base.Arith
+import Base.Progress.Base
+
+namespace Primitives
+
+open Result Error core.ops.range
+
+def Array (α : Type u) (n : Usize) := { l : List α // l.length = n.val }
+
+instance (a : Type u) (n : Usize) : Arith.HasIntProp (Array a n) where
+ prop_ty := λ v => v.val.len = n.val
+ prop := λ ⟨ _, l ⟩ => by simp[Scalar.max, List.len_eq_length, *]
+
+instance {α : Type u} {n : Usize} (p : Array α n → Prop) : Arith.HasIntProp (Subtype p) where
+ prop_ty := λ x => p x
+ prop := λ x => x.property
+
+@[simp]
+abbrev Array.length {α : Type u} {n : Usize} (v : Array α n) : Int := v.val.len
+
+@[simp]
+abbrev Array.v {α : Type u} {n : Usize} (v : Array α n) : List α := v.val
+
+example {α: Type u} {n : Usize} (v : Array α n) : v.length ≤ Scalar.max ScalarTy.Usize := by
+ scalar_tac
+
+def Array.make (α : Type u) (n : Usize) (init : List α) (hl : init.len = n.val := by decide) :
+ Array α n := ⟨ init, by simp [← List.len_eq_length]; apply hl ⟩
+
+example : Array Int (Usize.ofInt 2) := Array.make Int (Usize.ofInt 2) [0, 1]
+
+@[simp]
+abbrev Array.index_s {α : Type u} {n : Usize} [Inhabited α] (v : Array α n) (i : Int) : α :=
+ v.val.index i
+
+@[simp]
+abbrev Array.slice {α : Type u} {n : Usize} [Inhabited α] (v : Array α n) (i j : Int) : List α :=
+ v.val.slice i j
+
+def Array.index_usize (α : Type u) (n : Usize) (v: Array α n) (i: Usize) : Result α :=
+ match v.val.indexOpt i.val with
+ | none => fail .arrayOutOfBounds
+ | some x => ret x
+
+-- For initialization
+def Array.repeat (α : Type u) (n : Usize) (x : α) : Array α n :=
+ ⟨ List.ireplicate n.val x, by have h := n.hmin; simp_all [Scalar.min] ⟩
+
+@[pspec]
+theorem Array.repeat_spec {α : Type u} (n : Usize) (x : α) :
+ ∃ a, Array.repeat α n x = a ∧ a.val = List.ireplicate n.val x := by
+ simp [Array.repeat]
+
+/- In the theorems below: we don't always need the `∃ ..`, but we use one
+ so that `progress` introduces an opaque variable and an equality. This
+ helps control the context.
+ -/
+
+@[pspec]
+theorem Array.index_usize_spec {α : Type u} {n : Usize} [Inhabited α] (v: Array α n) (i: Usize)
+ (hbound : i.val < v.length) :
+ ∃ x, v.index_usize α n i = ret x ∧ x = v.val.index i.val := by
+ simp only [index_usize]
+ -- TODO: dependent rewrite
+ have h := List.indexOpt_eq_index v.val i.val (by scalar_tac) (by simp [*])
+ simp [*]
+
+def Array.update_usize (α : Type u) (n : Usize) (v: Array α n) (i: Usize) (x: α) : Result (Array α n) :=
+ match v.val.indexOpt i.val with
+ | none => fail .arrayOutOfBounds
+ | some _ =>
+ .ret ⟨ v.val.update i.val x, by have := v.property; simp [*] ⟩
+
+@[pspec]
+theorem Array.update_usize_spec {α : Type u} {n : Usize} (v: Array α n) (i: Usize) (x : α)
+ (hbound : i.val < v.length) :
+ ∃ nv, v.update_usize α n i x = ret nv ∧
+ nv.val = v.val.update i.val x
+ := by
+ simp only [update_usize]
+ have h := List.indexOpt_bounds v.val i.val
+ split
+ . simp_all [length]; cases h <;> scalar_tac
+ . simp_all
+
+def Slice (α : Type u) := { l : List α // l.length ≤ Usize.max }
+
+instance (a : Type u) : Arith.HasIntProp (Slice a) where
+ prop_ty := λ v => 0 ≤ v.val.len ∧ v.val.len ≤ Scalar.max ScalarTy.Usize
+ prop := λ ⟨ _, l ⟩ => by simp[Scalar.max, List.len_eq_length, *]
+
+instance {α : Type u} (p : Slice α → Prop) : Arith.HasIntProp (Subtype p) where
+ prop_ty := λ x => p x
+ prop := λ x => x.property
+
+@[simp]
+abbrev Slice.length {α : Type u} (v : Slice α) : Int := v.val.len
+
+@[simp]
+abbrev Slice.v {α : Type u} (v : Slice α) : List α := v.val
+
+example {a: Type u} (v : Slice a) : v.length ≤ Scalar.max ScalarTy.Usize := by
+ scalar_tac
+
+def Slice.new (α : Type u): Slice α := ⟨ [], by apply Scalar.cMax_suffices .Usize; simp ⟩
+
+-- TODO: very annoying that the α is an explicit parameter
+def Slice.len (α : Type u) (v : Slice α) : Usize :=
+ Usize.ofIntCore v.val.len (by scalar_tac) (by scalar_tac)
+
+@[simp]
+theorem Slice.len_val {α : Type u} (v : Slice α) : (Slice.len α v).val = v.length :=
+ by rfl
+
+@[simp]
+abbrev Slice.index_s {α : Type u} [Inhabited α] (v: Slice α) (i: Int) : α :=
+ v.val.index i
+
+@[simp]
+abbrev Slice.slice {α : Type u} [Inhabited α] (s : Slice α) (i j : Int) : List α :=
+ s.val.slice i j
+
+def Slice.index_usize (α : Type u) (v: Slice α) (i: Usize) : Result α :=
+ match v.val.indexOpt i.val with
+ | none => fail .arrayOutOfBounds
+ | some x => ret x
+
+/- In the theorems below: we don't always need the `∃ ..`, but we use one
+ so that `progress` introduces an opaque variable and an equality. This
+ helps control the context.
+ -/
+
+@[pspec]
+theorem Slice.index_usize_spec {α : Type u} [Inhabited α] (v: Slice α) (i: Usize)
+ (hbound : i.val < v.length) :
+ ∃ x, v.index_usize α i = ret x ∧ x = v.val.index i.val := by
+ simp only [index_usize]
+ -- TODO: dependent rewrite
+ have h := List.indexOpt_eq_index v.val i.val (by scalar_tac) (by simp [*])
+ simp [*]
+
+-- This shouldn't be used
+def Slice.index_shared_back (α : Type u) (v: Slice α) (i: Usize) (_: α) : Result Unit :=
+ if i.val < List.length v.val then
+ .ret ()
+ else
+ .fail arrayOutOfBounds
+
+def Slice.update_usize (α : Type u) (v: Slice α) (i: Usize) (x: α) : Result (Slice α) :=
+ match v.val.indexOpt i.val with
+ | none => fail .arrayOutOfBounds
+ | some _ =>
+ .ret ⟨ v.val.update i.val x, by have := v.property; simp [*] ⟩
+
+@[pspec]
+theorem Slice.update_usize_spec {α : Type u} (v: Slice α) (i: Usize) (x : α)
+ (hbound : i.val < v.length) :
+ ∃ nv, v.update_usize α i x = ret nv ∧
+ nv.val = v.val.update i.val x
+ := by
+ simp only [update_usize]
+ have h := List.indexOpt_bounds v.val i.val
+ split
+ . simp_all [length]; cases h <;> scalar_tac
+ . simp_all
+
+/- Array to slice/subslices -/
+
+/- We could make this function not use the `Result` type. By making it monadic, we
+ push the user to use the `Array.to_slice_spec` spec theorem below (through the
+ `progress` tactic), meaning `Array.to_slice` should be considered as opaque.
+ All what the spec theorem reveals is that the "representative" lists are the same. -/
+def Array.to_slice (α : Type u) (n : Usize) (v : Array α n) : Result (Slice α) :=
+ ret ⟨ v.val, by simp [← List.len_eq_length]; scalar_tac ⟩
+
+@[pspec]
+theorem Array.to_slice_spec {α : Type u} {n : Usize} (v : Array α n) :
+ ∃ s, to_slice α n v = ret s ∧ v.val = s.val := by simp [to_slice]
+
+def Array.from_slice (α : Type u) (n : Usize) (_ : Array α n) (s : Slice α) : Result (Array α n) :=
+ if h: s.val.len = n.val then
+ ret ⟨ s.val, by simp [← List.len_eq_length, *] ⟩
+ else fail panic
+
+@[pspec]
+theorem Array.from_slice_spec {α : Type u} {n : Usize} (a : Array α n) (ns : Slice α) (h : ns.val.len = n.val) :
+ ∃ na, from_slice α n a ns = ret na ∧ na.val = ns.val
+ := by simp [from_slice, *]
+
+def Array.subslice (α : Type u) (n : Usize) (a : Array α n) (r : Range Usize) : Result (Slice α) :=
+ -- TODO: not completely sure here
+ if r.start.val < r.end_.val ∧ r.end_.val ≤ a.val.len then
+ ret ⟨ a.val.slice r.start.val r.end_.val,
+ by
+ simp [← List.len_eq_length]
+ have := a.val.slice_len_le r.start.val r.end_.val
+ scalar_tac ⟩
+ else
+ fail panic
+
+@[pspec]
+theorem Array.subslice_spec {α : Type u} {n : Usize} [Inhabited α] (a : Array α n) (r : Range Usize)
+ (h0 : r.start.val < r.end_.val) (h1 : r.end_.val ≤ a.val.len) :
+ ∃ s, subslice α n a r = ret s ∧
+ s.val = a.val.slice r.start.val r.end_.val ∧
+ (∀ i, 0 ≤ i → i + r.start.val < r.end_.val → s.val.index i = a.val.index (r.start.val + i))
+ := by
+ simp [subslice, *]
+ intro i _ _
+ have := List.index_slice r.start.val r.end_.val i a.val (by scalar_tac) (by scalar_tac) (by trivial) (by scalar_tac)
+ simp [*]
+
+def Array.update_subslice (α : Type u) (n : Usize) (a : Array α n) (r : Range Usize) (s : Slice α) : Result (Array α n) :=
+ -- TODO: not completely sure here
+ if h: r.start.val < r.end_.val ∧ r.end_.val ≤ a.length ∧ s.val.len = r.end_.val - r.start.val then
+ let s_beg := a.val.itake r.start.val
+ let s_end := a.val.idrop r.end_.val
+ have : s_beg.len = r.start.val := by
+ apply List.itake_len
+ . simp_all; scalar_tac
+ . scalar_tac
+ have : s_end.len = a.val.len - r.end_.val := by
+ apply List.idrop_len
+ . scalar_tac
+ . scalar_tac
+ let na := s_beg.append (s.val.append s_end)
+ have : na.len = a.val.len := by simp [*]
+ ret ⟨ na, by simp_all [← List.len_eq_length]; scalar_tac ⟩
+ else
+ fail panic
+
+-- TODO: it is annoying to write `.val` everywhere. We could leverage coercions,
+-- but: some symbols like `+` are already overloaded to be notations for monadic
+-- operations/
+-- We should introduce special symbols for the monadic arithmetic operations
+-- (the use will never write those symbols directly).
+@[pspec]
+theorem Array.update_subslice_spec {α : Type u} {n : Usize} [Inhabited α] (a : Array α n) (r : Range Usize) (s : Slice α)
+ (_ : r.start.val < r.end_.val) (_ : r.end_.val ≤ a.length) (_ : s.length = r.end_.val - r.start.val) :
+ ∃ na, update_subslice α n a r s = ret na ∧
+ (∀ i, 0 ≤ i → i < r.start.val → na.index_s i = a.index_s i) ∧
+ (∀ i, r.start.val ≤ i → i < r.end_.val → na.index_s i = s.index_s (i - r.start.val)) ∧
+ (∀ i, r.end_.val ≤ i → i < n.val → na.index_s i = a.index_s i) := by
+ simp [update_subslice, *]
+ have h := List.replace_slice_index r.start.val r.end_.val a.val s.val
+ (by scalar_tac) (by scalar_tac) (by scalar_tac) (by scalar_tac)
+ simp [List.replace_slice] at h
+ have ⟨ h0, h1, h2 ⟩ := h
+ clear h
+ split_conjs
+ . intro i _ _
+ have := h0 i (by int_tac) (by int_tac)
+ simp [*]
+ . intro i _ _
+ have := h1 i (by int_tac) (by int_tac)
+ simp [*]
+ . intro i _ _
+ have := h2 i (by int_tac) (by int_tac)
+ simp [*]
+
+def Slice.subslice (α : Type u) (s : Slice α) (r : Range Usize) : Result (Slice α) :=
+ -- TODO: not completely sure here
+ if r.start.val < r.end_.val ∧ r.end_.val ≤ s.length then
+ ret ⟨ s.val.slice r.start.val r.end_.val,
+ by
+ simp [← List.len_eq_length]
+ have := s.val.slice_len_le r.start.val r.end_.val
+ scalar_tac ⟩
+ else
+ fail panic
+
+@[pspec]
+theorem Slice.subslice_spec {α : Type u} [Inhabited α] (s : Slice α) (r : Range Usize)
+ (h0 : r.start.val < r.end_.val) (h1 : r.end_.val ≤ s.val.len) :
+ ∃ ns, subslice α s r = ret ns ∧
+ ns.val = s.slice r.start.val r.end_.val ∧
+ (∀ i, 0 ≤ i → i + r.start.val < r.end_.val → ns.index_s i = s.index_s (r.start.val + i))
+ := by
+ simp [subslice, *]
+ intro i _ _
+ have := List.index_slice r.start.val r.end_.val i s.val (by scalar_tac) (by scalar_tac) (by trivial) (by scalar_tac)
+ simp [*]
+
+attribute [pp_dot] List.len List.length List.index -- use the dot notation when printing
+set_option pp.coercions false -- do not print coercions with ↑ (this doesn't parse)
+
+def Slice.update_subslice (α : Type u) (s : Slice α) (r : Range Usize) (ss : Slice α) : Result (Slice α) :=
+ -- TODO: not completely sure here
+ if h: r.start.val < r.end_.val ∧ r.end_.val ≤ s.length ∧ ss.val.len = r.end_.val - r.start.val then
+ let s_beg := s.val.itake r.start.val
+ let s_end := s.val.idrop r.end_.val
+ have : s_beg.len = r.start.val := by
+ apply List.itake_len
+ . simp_all; scalar_tac
+ . scalar_tac
+ have : s_end.len = s.val.len - r.end_.val := by
+ apply List.idrop_len
+ . scalar_tac
+ . scalar_tac
+ let ns := s_beg.append (ss.val.append s_end)
+ have : ns.len = s.val.len := by simp [*]
+ ret ⟨ ns, by simp_all [← List.len_eq_length]; scalar_tac ⟩
+ else
+ fail panic
+
+@[pspec]
+theorem Slice.update_subslice_spec {α : Type u} [Inhabited α] (a : Slice α) (r : Range Usize) (ss : Slice α)
+ (_ : r.start.val < r.end_.val) (_ : r.end_.val ≤ a.length) (_ : ss.length = r.end_.val - r.start.val) :
+ ∃ na, update_subslice α a r ss = ret na ∧
+ (∀ i, 0 ≤ i → i < r.start.val → na.index_s i = a.index_s i) ∧
+ (∀ i, r.start.val ≤ i → i < r.end_.val → na.index_s i = ss.index_s (i - r.start.val)) ∧
+ (∀ i, r.end_.val ≤ i → i < a.length → na.index_s i = a.index_s i) := by
+ simp [update_subslice, *]
+ have h := List.replace_slice_index r.start.val r.end_.val a.val ss.val
+ (by scalar_tac) (by scalar_tac) (by scalar_tac) (by scalar_tac)
+ simp [List.replace_slice, *] at h
+ have ⟨ h0, h1, h2 ⟩ := h
+ clear h
+ split_conjs
+ . intro i _ _
+ have := h0 i (by int_tac) (by int_tac)
+ simp [*]
+ . intro i _ _
+ have := h1 i (by int_tac) (by int_tac)
+ simp [*]
+ . intro i _ _
+ have := h2 i (by int_tac) (by int_tac)
+ simp [*]
+
+/- Trait declaration: [core::slice::index::private_slice_index::Sealed] -/
+structure core.slice.index.private_slice_index.Sealed (Self : Type) where
+
+/- Trait declaration: [core::slice::index::SliceIndex] -/
+structure core.slice.index.SliceIndex (Self T : Type) where
+ sealedInst : core.slice.index.private_slice_index.Sealed Self
+ Output : Type
+ get : Self → T → Result (Option Output)
+ get_mut : Self → T → Result (Option Output)
+ get_mut_back : Self → T → Option Output → Result T
+ get_unchecked : Self → ConstRawPtr T → Result (ConstRawPtr Output)
+ get_unchecked_mut : Self → MutRawPtr T → Result (MutRawPtr Output)
+ index : Self → T → Result Output
+ index_mut : Self → T → Result Output
+ index_mut_back : Self → T → Output → Result T
+
+/- [core::slice::index::[T]::index]: forward function -/
+def core.slice.index.Slice.index
+ (T I : Type) (inst : core.slice.index.SliceIndex I (Slice T))
+ (slice : Slice T) (i : I) : Result inst.Output := do
+ let x ← inst.get i slice
+ match x with
+ | none => fail panic
+ | some x => ret x
+
+/- [core::slice::index::Range:::get]: forward function -/
+def core.slice.index.Range.get (T : Type) (i : Range Usize) (slice : Slice T) :
+ Result (Option (Slice T)) :=
+ sorry -- TODO
+
+/- [core::slice::index::Range::get_mut]: forward function -/
+def core.slice.index.Range.get_mut
+ (T : Type) : Range Usize → Slice T → Result (Option (Slice T)) :=
+ sorry -- TODO
+
+/- [core::slice::index::Range::get_mut]: backward function 0 -/
+def core.slice.index.Range.get_mut_back
+ (T : Type) :
+ Range Usize → Slice T → Option (Slice T) → Result (Slice T) :=
+ sorry -- TODO
+
+/- [core::slice::index::Range::get_unchecked]: forward function -/
+def core.slice.index.Range.get_unchecked
+ (T : Type) :
+ Range Usize → ConstRawPtr (Slice T) → Result (ConstRawPtr (Slice T)) :=
+ -- Don't know what the model should be - for now we always fail to make
+ -- sure code which uses it fails
+ fun _ _ => fail panic
+
+/- [core::slice::index::Range::get_unchecked_mut]: forward function -/
+def core.slice.index.Range.get_unchecked_mut
+ (T : Type) :
+ Range Usize → MutRawPtr (Slice T) → Result (MutRawPtr (Slice T)) :=
+ -- Don't know what the model should be - for now we always fail to make
+ -- sure code which uses it fails
+ fun _ _ => fail panic
+
+/- [core::slice::index::Range::index]: forward function -/
+def core.slice.index.Range.index
+ (T : Type) : Range Usize → Slice T → Result (Slice T) :=
+ sorry -- TODO
+
+/- [core::slice::index::Range::index_mut]: forward function -/
+def core.slice.index.Range.index_mut
+ (T : Type) : Range Usize → Slice T → Result (Slice T) :=
+ sorry -- TODO
+
+/- [core::slice::index::Range::index_mut]: backward function 0 -/
+def core.slice.index.Range.index_mut_back
+ (T : Type) : Range Usize → Slice T → Slice T → Result (Slice T) :=
+ sorry -- TODO
+
+/- [core::slice::index::[T]::index_mut]: forward function -/
+def core.slice.index.Slice.index_mut
+ (T I : Type) (inst : core.slice.index.SliceIndex I (Slice T)) :
+ Slice T → I → Result inst.Output :=
+ sorry -- TODO
+
+/- [core::slice::index::[T]::index_mut]: backward function 0 -/
+def core.slice.index.Slice.index_mut_back
+ (T I : Type) (inst : core.slice.index.SliceIndex I (Slice T)) :
+ Slice T → I → inst.Output → Result (Slice T) :=
+ sorry -- TODO
+
+/- [core::array::[T; N]::index]: forward function -/
+def core.array.Array.index
+ (T I : Type) (N : Usize) (inst : core.ops.index.Index (Slice T) I)
+ (a : Array T N) (i : I) : Result inst.Output :=
+ sorry -- TODO
+
+/- [core::array::[T; N]::index_mut]: forward function -/
+def core.array.Array.index_mut
+ (T I : Type) (N : Usize) (inst : core.ops.index.IndexMut (Slice T) I)
+ (a : Array T N) (i : I) : Result inst.indexInst.Output :=
+ sorry -- TODO
+
+/- [core::array::[T; N]::index_mut]: backward function 0 -/
+def core.array.Array.index_mut_back
+ (T I : Type) (N : Usize) (inst : core.ops.index.IndexMut (Slice T) I)
+ (a : Array T N) (i : I) (x : inst.indexInst.Output) : Result (Array T N) :=
+ sorry -- TODO
+
+/- Trait implementation: [core::slice::index::[T]] -/
+def core.slice.index.Slice.coreopsindexIndexInst (T I : Type)
+ (inst : core.slice.index.SliceIndex I (Slice T)) :
+ core.ops.index.Index (Slice T) I := {
+ Output := inst.Output
+ index := core.slice.index.Slice.index T I inst
+}
+
+/- Trait implementation: [core::slice::index::private_slice_index::Range] -/
+def core.slice.index.private_slice_index.Range.coresliceindexprivate_slice_indexSealedInst
+ : core.slice.index.private_slice_index.Sealed (Range Usize) := {}
+
+/- Trait implementation: [core::slice::index::Range] -/
+def core.slice.index.Range.coresliceindexSliceIndexInst (T : Type) :
+ core.slice.index.SliceIndex (Range Usize) (Slice T) := {
+ sealedInst :=
+ core.slice.index.private_slice_index.Range.coresliceindexprivate_slice_indexSealedInst
+ Output := Slice T
+ get := core.slice.index.Range.get T
+ get_mut := core.slice.index.Range.get_mut T
+ get_mut_back := core.slice.index.Range.get_mut_back T
+ get_unchecked := core.slice.index.Range.get_unchecked T
+ get_unchecked_mut := core.slice.index.Range.get_unchecked_mut T
+ index := core.slice.index.Range.index T
+ index_mut := core.slice.index.Range.index_mut T
+ index_mut_back := core.slice.index.Range.index_mut_back T
+}
+
+/- Trait implementation: [core::slice::index::[T]] -/
+def core.slice.index.Slice.coreopsindexIndexMutInst (T I : Type)
+ (inst : core.slice.index.SliceIndex I (Slice T)) :
+ core.ops.index.IndexMut (Slice T) I := {
+ indexInst := core.slice.index.Slice.coreopsindexIndexInst T I inst
+ index_mut := core.slice.index.Slice.index_mut T I inst
+ index_mut_back := core.slice.index.Slice.index_mut_back T I inst
+}
+
+/- Trait implementation: [core::array::[T; N]] -/
+def core.array.Array.coreopsindexIndexInst (T I : Type) (N : Usize)
+ (inst : core.ops.index.Index (Slice T) I) :
+ core.ops.index.Index (Array T N) I := {
+ Output := inst.Output
+ index := core.array.Array.index T I N inst
+}
+
+/- Trait implementation: [core::array::[T; N]] -/
+def core.array.Array.coreopsindexIndexMutInst (T I : Type) (N : Usize)
+ (inst : core.ops.index.IndexMut (Slice T) I) :
+ core.ops.index.IndexMut (Array T N) I := {
+ indexInst := core.array.Array.coreopsindexIndexInst T I N inst.indexInst
+ index_mut := core.array.Array.index_mut T I N inst
+ index_mut_back := core.array.Array.index_mut_back T I N inst
+}
+
+/- [core::slice::index::usize::get]: forward function -/
+def core.slice.index.Usize.get
+ (T : Type) : Usize → Slice T → Result (Option T) :=
+ sorry -- TODO
+
+/- [core::slice::index::usize::get_mut]: forward function -/
+def core.slice.index.Usize.get_mut
+ (T : Type) : Usize → Slice T → Result (Option T) :=
+ sorry -- TODO
+
+/- [core::slice::index::usize::get_mut]: backward function 0 -/
+def core.slice.index.Usize.get_mut_back
+ (T : Type) : Usize → Slice T → Option T → Result (Slice T) :=
+ sorry -- TODO
+
+/- [core::slice::index::usize::get_unchecked]: forward function -/
+def core.slice.index.Usize.get_unchecked
+ (T : Type) : Usize → ConstRawPtr (Slice T) → Result (ConstRawPtr T) :=
+ sorry -- TODO
+
+/- [core::slice::index::usize::get_unchecked_mut]: forward function -/
+def core.slice.index.Usize.get_unchecked_mut
+ (T : Type) : Usize → MutRawPtr (Slice T) → Result (MutRawPtr T) :=
+ sorry -- TODO
+
+/- [core::slice::index::usize::index]: forward function -/
+def core.slice.index.Usize.index (T : Type) : Usize → Slice T → Result T :=
+ sorry -- TODO
+
+/- [core::slice::index::usize::index_mut]: forward function -/
+def core.slice.index.Usize.index_mut (T : Type) : Usize → Slice T → Result T :=
+ sorry -- TODO
+
+/- [core::slice::index::usize::index_mut]: backward function 0 -/
+def core.slice.index.Usize.index_mut_back
+ (T : Type) : Usize → Slice T → T → Result (Slice T) :=
+ sorry -- TODO
+
+/- Trait implementation: [core::slice::index::private_slice_index::usize] -/
+def core.slice.index.private_slice_index.usize.coresliceindexprivate_slice_indexSealedInst
+ : core.slice.index.private_slice_index.Sealed Usize := {}
+
+/- Trait implementation: [core::slice::index::usize] -/
+def core.slice.index.usize.coresliceindexSliceIndexInst (T : Type) :
+ core.slice.index.SliceIndex Usize (Slice T) := {
+ sealedInst := core.slice.index.private_slice_index.usize.coresliceindexprivate_slice_indexSealedInst
+ Output := T
+ get := core.slice.index.Usize.get T
+ get_mut := core.slice.index.Usize.get_mut T
+ get_mut_back := core.slice.index.Usize.get_mut_back T
+ get_unchecked := core.slice.index.Usize.get_unchecked T
+ get_unchecked_mut := core.slice.index.Usize.get_unchecked_mut T
+ index := core.slice.index.Usize.index T
+ index_mut := core.slice.index.Usize.index_mut T
+ index_mut_back := core.slice.index.Usize.index_mut_back T
+}
+
+end Primitives
diff --git a/backends/lean/Base/Primitives/Base.lean b/backends/lean/Base/Primitives/Base.lean
index 7c0fa3bb..7fc33251 100644
--- a/backends/lean/Base/Primitives/Base.lean
+++ b/backends/lean/Base/Primitives/Base.lean
@@ -120,11 +120,18 @@ def Result.attach {α: Type} (o : Result α): Result { x : α // o = ret x } :=
-- MISC --
----------
-@[simp] def mem.replace (a : Type) (x : a) (_ : a) : a := x
-@[simp] def mem.replace_back (a : Type) (_ : a) (y : a) : a := y
+@[simp] def core.mem.replace (a : Type) (x : a) (_ : a) : a := x
+@[simp] def core.mem.replace_back (a : Type) (_ : a) (y : a) : a := y
/-- Aeneas-translated function -- useful to reduce non-recursive definitions.
Use with `simp [ aeneas ]` -/
register_simp_attr aeneas
+-- We don't really use raw pointers for now
+structure MutRawPtr (T : Type) where
+ v : T
+
+structure ConstRawPtr (T : Type) where
+ v : T
+
end Primitives
diff --git a/backends/lean/Base/Primitives/CoreOps.lean b/backends/lean/Base/Primitives/CoreOps.lean
new file mode 100644
index 00000000..da458f66
--- /dev/null
+++ b/backends/lean/Base/Primitives/CoreOps.lean
@@ -0,0 +1,37 @@
+import Lean
+import Base.Primitives.Base
+
+open Primitives
+open Result
+
+namespace core.ops
+
+namespace index -- core.ops.index
+
+/- Trait declaration: [core::ops::index::Index] -/
+structure Index (Self Idx : Type) where
+ Output : Type
+ index : Self → Idx → Result Output
+
+/- Trait declaration: [core::ops::index::IndexMut] -/
+structure IndexMut (Self Idx : Type) where
+ indexInst : Index Self Idx
+ index_mut : Self → Idx → Result indexInst.Output
+ index_mut_back : Self → Idx → indexInst.Output → Result Self
+
+end index -- core.ops.index
+
+namespace deref -- core.ops.deref
+
+structure Deref (Self : Type) where
+ Target : Type
+ deref : Self → Result Target
+
+structure DerefMut (Self : Type) where
+ derefInst : Deref Self
+ deref_mut : Self → Result derefInst.Target
+ deref_mut_back : Self → derefInst.Target → Result Self
+
+end deref -- core.ops.deref
+
+end core.ops
diff --git a/backends/lean/Base/Primitives/Range.lean b/backends/lean/Base/Primitives/Range.lean
index 26cbee42..a268bcba 100644
--- a/backends/lean/Base/Primitives/Range.lean
+++ b/backends/lean/Base/Primitives/Range.lean
@@ -11,7 +11,7 @@ import Base.Progress.Base
namespace Primitives
-structure Range (α : Type u) where
+structure core.ops.range.Range (α : Type u) where
mk ::
start: α
end_: α
diff --git a/backends/lean/Base/Primitives/Scalar.lean b/backends/lean/Base/Primitives/Scalar.lean
index 55227a9f..ec9665a5 100644
--- a/backends/lean/Base/Primitives/Scalar.lean
+++ b/backends/lean/Base/Primitives/Scalar.lean
@@ -230,6 +230,20 @@ def Scalar.cMax (ty : ScalarTy) : Int :=
| .Usize => Scalar.max .U32
| _ => Scalar.max ty
+theorem Scalar.min_lt_max (ty : ScalarTy) : Scalar.min ty < Scalar.max ty := by
+ cases ty <;> simp [Scalar.min, Scalar.max]
+ . simp [Isize.min, Isize.max]
+ have h1 := Isize.refined_min.property
+ have h2 := Isize.refined_max.property
+ cases h1 <;> cases h2 <;> simp [*]
+ . simp [Usize.max]
+ have h := Usize.refined_max.property
+ cases h <;> simp [*]
+
+theorem Scalar.min_le_max (ty : ScalarTy) : Scalar.min ty ≤ Scalar.max ty := by
+ have := Scalar.min_lt_max ty
+ int_tac
+
theorem Scalar.cMin_bound ty : Scalar.min ty ≤ Scalar.cMin ty := by
cases ty <;> simp [Scalar.min, Scalar.max, Scalar.cMin, Scalar.cMax] at *
have h := Isize.refined_min.property
@@ -395,6 +409,34 @@ def Scalar.cast {src_ty : ScalarTy} (tgt_ty : ScalarTy) (x : Scalar src_ty) : Re
@[reducible] def U64 := Scalar .U64
@[reducible] def U128 := Scalar .U128
+-- TODO: reducible?
+@[reducible] def core_isize_min : Isize := Scalar.ofInt Isize.min (by simp [Scalar.min, Scalar.max]; apply (Scalar.min_le_max .Isize))
+@[reducible] def core_isize_max : Isize := Scalar.ofInt Isize.max (by simp [Scalar.min, Scalar.max]; apply (Scalar.min_le_max .Isize))
+@[reducible] def core_i8_min : I8 := Scalar.ofInt I8.min
+@[reducible] def core_i8_max : I8 := Scalar.ofInt I8.max
+@[reducible] def core_i16_min : I16 := Scalar.ofInt I16.min
+@[reducible] def core_i16_max : I16 := Scalar.ofInt I16.max
+@[reducible] def core_i32_min : I32 := Scalar.ofInt I32.min
+@[reducible] def core_i32_max : I32 := Scalar.ofInt I32.max
+@[reducible] def core_i64_min : I64 := Scalar.ofInt I64.min
+@[reducible] def core_i64_max : I64 := Scalar.ofInt I64.max
+@[reducible] def core_i128_min : I128 := Scalar.ofInt I128.min
+@[reducible] def core_i128_max : I128 := Scalar.ofInt I128.max
+
+-- TODO: reducible?
+@[reducible] def core_usize_min : Usize := Scalar.ofInt Usize.min
+@[reducible] def core_usize_max : Usize := Scalar.ofInt Usize.max (by simp [Scalar.min, Scalar.max]; apply (Scalar.min_le_max .Usize))
+@[reducible] def core_u8_min : U8 := Scalar.ofInt U8.min
+@[reducible] def core_u8_max : U8 := Scalar.ofInt U8.max
+@[reducible] def core_u16_min : U16 := Scalar.ofInt U16.min
+@[reducible] def core_u16_max : U16 := Scalar.ofInt U16.max
+@[reducible] def core_u32_min : U32 := Scalar.ofInt U32.min
+@[reducible] def core_u32_max : U32 := Scalar.ofInt U32.max
+@[reducible] def core_u64_min : U64 := Scalar.ofInt U64.min
+@[reducible] def core_u64_max : U64 := Scalar.ofInt U64.max
+@[reducible] def core_u128_min : U128 := Scalar.ofInt U128.min
+@[reducible] def core_u128_max : U128 := Scalar.ofInt U128.max
+
-- TODO: below: not sure this is the best way.
-- Should we rather overload operations like +, -, etc.?
-- Also, it is possible to automate the generation of those definitions
@@ -861,33 +903,33 @@ theorem Scalar.rem_unsigned_spec {ty} (s: ¬ ty.isSigned) (x : Scalar ty) {y : S
-- ofIntCore
-- TODO: typeclass?
-@[reducible] def Isize.ofIntCore := @Scalar.ofIntCore .Isize
-@[reducible] def I8.ofIntCore := @Scalar.ofIntCore .I8
-@[reducible] def I16.ofIntCore := @Scalar.ofIntCore .I16
-@[reducible] def I32.ofIntCore := @Scalar.ofIntCore .I32
-@[reducible] def I64.ofIntCore := @Scalar.ofIntCore .I64
-@[reducible] def I128.ofIntCore := @Scalar.ofIntCore .I128
-@[reducible] def Usize.ofIntCore := @Scalar.ofIntCore .Usize
-@[reducible] def U8.ofIntCore := @Scalar.ofIntCore .U8
-@[reducible] def U16.ofIntCore := @Scalar.ofIntCore .U16
-@[reducible] def U32.ofIntCore := @Scalar.ofIntCore .U32
-@[reducible] def U64.ofIntCore := @Scalar.ofIntCore .U64
-@[reducible] def U128.ofIntCore := @Scalar.ofIntCore .U128
+def Isize.ofIntCore := @Scalar.ofIntCore .Isize
+def I8.ofIntCore := @Scalar.ofIntCore .I8
+def I16.ofIntCore := @Scalar.ofIntCore .I16
+def I32.ofIntCore := @Scalar.ofIntCore .I32
+def I64.ofIntCore := @Scalar.ofIntCore .I64
+def I128.ofIntCore := @Scalar.ofIntCore .I128
+def Usize.ofIntCore := @Scalar.ofIntCore .Usize
+def U8.ofIntCore := @Scalar.ofIntCore .U8
+def U16.ofIntCore := @Scalar.ofIntCore .U16
+def U32.ofIntCore := @Scalar.ofIntCore .U32
+def U64.ofIntCore := @Scalar.ofIntCore .U64
+def U128.ofIntCore := @Scalar.ofIntCore .U128
-- ofInt
-- TODO: typeclass?
-@[reducible] def Isize.ofInt := @Scalar.ofInt .Isize
-@[reducible] def I8.ofInt := @Scalar.ofInt .I8
-@[reducible] def I16.ofInt := @Scalar.ofInt .I16
-@[reducible] def I32.ofInt := @Scalar.ofInt .I32
-@[reducible] def I64.ofInt := @Scalar.ofInt .I64
-@[reducible] def I128.ofInt := @Scalar.ofInt .I128
-@[reducible] def Usize.ofInt := @Scalar.ofInt .Usize
-@[reducible] def U8.ofInt := @Scalar.ofInt .U8
-@[reducible] def U16.ofInt := @Scalar.ofInt .U16
-@[reducible] def U32.ofInt := @Scalar.ofInt .U32
-@[reducible] def U64.ofInt := @Scalar.ofInt .U64
-@[reducible] def U128.ofInt := @Scalar.ofInt .U128
+abbrev Isize.ofInt := @Scalar.ofInt .Isize
+abbrev I8.ofInt := @Scalar.ofInt .I8
+abbrev I16.ofInt := @Scalar.ofInt .I16
+abbrev I32.ofInt := @Scalar.ofInt .I32
+abbrev I64.ofInt := @Scalar.ofInt .I64
+abbrev I128.ofInt := @Scalar.ofInt .I128
+abbrev Usize.ofInt := @Scalar.ofInt .Usize
+abbrev U8.ofInt := @Scalar.ofInt .U8
+abbrev U16.ofInt := @Scalar.ofInt .U16
+abbrev U32.ofInt := @Scalar.ofInt .U32
+abbrev U64.ofInt := @Scalar.ofInt .U64
+abbrev U128.ofInt := @Scalar.ofInt .U128
postfix:max "#isize" => Isize.ofInt
postfix:max "#i8" => I8.ofInt
@@ -905,9 +947,46 @@ postfix:max "#u128" => U128.ofInt
-- Testing the notations
example : Result Usize := 0#usize + 1#usize
+-- TODO: factor those lemmas out
@[simp] theorem Scalar.ofInt_val_eq {ty} (h : Scalar.min ty ≤ x ∧ x ≤ Scalar.max ty) : (Scalar.ofInt x h).val = x := by
simp [Scalar.ofInt, Scalar.ofIntCore]
+@[simp] theorem Isize.ofInt_val_eq (h : Scalar.min ScalarTy.Isize ≤ x ∧ x ≤ Scalar.max ScalarTy.Isize) : (Isize.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem I8.ofInt_val_eq (h : Scalar.min ScalarTy.I8 ≤ x ∧ x ≤ Scalar.max ScalarTy.I8) : (I8.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem I16.ofInt_val_eq (h : Scalar.min ScalarTy.I16 ≤ x ∧ x ≤ Scalar.max ScalarTy.I16) : (I16.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem I32.ofInt_val_eq (h : Scalar.min ScalarTy.I32 ≤ x ∧ x ≤ Scalar.max ScalarTy.I32) : (I32.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem I64.ofInt_val_eq (h : Scalar.min ScalarTy.I64 ≤ x ∧ x ≤ Scalar.max ScalarTy.I64) : (I64.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem I128.ofInt_val_eq (h : Scalar.min ScalarTy.I128 ≤ x ∧ x ≤ Scalar.max ScalarTy.I128) : (I128.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem Usize.ofInt_val_eq (h : Scalar.min ScalarTy.Usize ≤ x ∧ x ≤ Scalar.max ScalarTy.Usize) : (Usize.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem U8.ofInt_val_eq (h : Scalar.min ScalarTy.U8 ≤ x ∧ x ≤ Scalar.max ScalarTy.U8) : (U8.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem U16.ofInt_val_eq (h : Scalar.min ScalarTy.U16 ≤ x ∧ x ≤ Scalar.max ScalarTy.U16) : (U16.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem U32.ofInt_val_eq (h : Scalar.min ScalarTy.U32 ≤ x ∧ x ≤ Scalar.max ScalarTy.U32) : (U32.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem U64.ofInt_val_eq (h : Scalar.min ScalarTy.U64 ≤ x ∧ x ≤ Scalar.max ScalarTy.U64) : (U64.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
+@[simp] theorem U128.ofInt_val_eq (h : Scalar.min ScalarTy.U128 ≤ x ∧ x ≤ Scalar.max ScalarTy.U128) : (U128.ofInt x h).val = x := by
+ apply Scalar.ofInt_val_eq h
+
-- Comparisons
instance {ty} : LT (Scalar ty) where
lt a b := LT.lt a.val b.val
diff --git a/backends/lean/Base/Primitives/Vec.lean b/backends/lean/Base/Primitives/Vec.lean
index c4c4d9f2..bbed6082 100644
--- a/backends/lean/Base/Primitives/Vec.lean
+++ b/backends/lean/Base/Primitives/Vec.lean
@@ -6,7 +6,7 @@ import Mathlib.Tactic.RunCmd
import Mathlib.Tactic.Linarith
import Base.IList
import Base.Primitives.Scalar
-import Base.Primitives.Array
+import Base.Primitives.ArraySlice
import Base.Arith
import Base.Progress.Base
@@ -14,6 +14,8 @@ namespace Primitives
open Result Error
+namespace alloc.vec
+
def Vec (α : Type u) := { l : List α // l.length ≤ Usize.max }
instance (a : Type u) : Arith.HasIntProp (Vec a) where
@@ -79,7 +81,7 @@ theorem Vec.insert_spec {α : Type u} (v: Vec α) (i: Usize) (x: α)
∃ nv, v.insert α i x = ret nv ∧ nv.val = v.val.update i.val x := by
simp [insert, *]
-def Vec.index_shared (α : Type u) (v: Vec α) (i: Usize) : Result α :=
+def Vec.index_usize {α : Type u} (v: Vec α) (i: Usize) : Result α :=
match v.val.indexOpt i.val with
| none => fail .arrayOutOfBounds
| some x => ret x
@@ -90,51 +92,83 @@ def Vec.index_shared (α : Type u) (v: Vec α) (i: Usize) : Result α :=
-/
@[pspec]
-theorem Vec.index_shared_spec {α : Type u} [Inhabited α] (v: Vec α) (i: Usize)
- (hbound : i.val < v.length) :
- ∃ x, v.index_shared α i = ret x ∧ x = v.val.index i.val := by
- simp only [index_shared]
- -- TODO: dependent rewrite
- have h := List.indexOpt_eq_index v.val i.val (by scalar_tac) (by simp [*])
- simp [*]
-
--- This shouldn't be used
-def Vec.index_back (α : Type u) (v: Vec α) (i: Usize) (_: α) : Result Unit :=
- if i.val < List.length v.val then
- .ret ()
- else
- .fail arrayOutOfBounds
-
-def Vec.index_mut (α : Type u) (v: Vec α) (i: Usize) : Result α :=
- match v.val.indexOpt i.val with
- | none => fail .arrayOutOfBounds
- | some x => ret x
-
-@[pspec]
-theorem Vec.index_mut_spec {α : Type u} [Inhabited α] (v: Vec α) (i: Usize)
+theorem Vec.index_usize_spec {α : Type u} [Inhabited α] (v: Vec α) (i: Usize)
(hbound : i.val < v.length) :
- ∃ x, v.index_mut α i = ret x ∧ x = v.val.index i.val := by
- simp only [index_mut]
+ ∃ x, v.index_usize i = ret x ∧ x = v.val.index i.val := by
+ simp only [index_usize]
-- TODO: dependent rewrite
have h := List.indexOpt_eq_index v.val i.val (by scalar_tac) (by simp [*])
simp [*]
-def Vec.index_mut_back (α : Type u) (v: Vec α) (i: Usize) (x: α) : Result (Vec α) :=
+def Vec.update_usize {α : Type u} (v: Vec α) (i: Usize) (x: α) : Result (Vec α) :=
match v.val.indexOpt i.val with
| none => fail .arrayOutOfBounds
| some _ =>
.ret ⟨ v.val.update i.val x, by have := v.property; simp [*] ⟩
@[pspec]
-theorem Vec.index_mut_back_spec {α : Type u} (v: Vec α) (i: Usize) (x : α)
+theorem Vec.update_usize_spec {α : Type u} (v: Vec α) (i: Usize) (x : α)
(hbound : i.val < v.length) :
- ∃ nv, v.index_mut_back α i x = ret nv ∧
+ ∃ nv, v.update_usize i x = ret nv ∧
nv.val = v.val.update i.val x
:= by
- simp only [index_mut_back]
+ simp only [update_usize]
have h := List.indexOpt_bounds v.val i.val
split
. simp_all [length]; cases h <;> scalar_tac
. simp_all
+/- [alloc::vec::Vec::index]: forward function -/
+def Vec.index (T I : Type) (inst : core.slice.index.SliceIndex I (Slice T))
+ (self : Vec T) (i : I) : Result inst.Output :=
+ sorry -- TODO
+
+/- [alloc::vec::Vec::index_mut]: forward function -/
+def Vec.index_mut (T I : Type) (inst : core.slice.index.SliceIndex I (Slice T))
+ (self : Vec T) (i : I) : Result inst.Output :=
+ sorry -- TODO
+
+/- [alloc::vec::Vec::index_mut]: backward function 0 -/
+def Vec.index_mut_back
+ (T I : Type) (inst : core.slice.index.SliceIndex I (Slice T))
+ (self : Vec T) (i : I) (x : inst.Output) : Result (alloc.vec.Vec T) :=
+ sorry -- TODO
+
+/- Trait implementation: [alloc::vec::Vec] -/
+def Vec.coreopsindexIndexInst (T I : Type)
+ (inst : core.slice.index.SliceIndex I (Slice T)) :
+ core.ops.index.Index (alloc.vec.Vec T) I := {
+ Output := inst.Output
+ index := Vec.index T I inst
+}
+
+/- Trait implementation: [alloc::vec::Vec] -/
+def Vec.coreopsindexIndexMutInst (T I : Type)
+ (inst : core.slice.index.SliceIndex I (Slice T)) :
+ core.ops.index.IndexMut (alloc.vec.Vec T) I := {
+ indexInst := Vec.coreopsindexIndexInst T I inst
+ index_mut := Vec.index_mut T I inst
+ index_mut_back := Vec.index_mut_back T I inst
+}
+
+@[simp]
+theorem Vec.index_slice_index {α : Type} (v : Vec α) (i : Usize) :
+ Vec.index α Usize (core.slice.index.usize.coresliceindexSliceIndexInst α) v i =
+ Vec.index_usize v i :=
+ sorry
+
+@[simp]
+theorem Vec.index_mut_slice_index {α : Type} (v : Vec α) (i : Usize) :
+ Vec.index_mut α Usize (core.slice.index.usize.coresliceindexSliceIndexInst α) v i =
+ Vec.index_usize v i :=
+ sorry
+
+@[simp]
+theorem Vec.index_mut_back_slice_index {α : Type} (v : Vec α) (i : Usize) (x : α) :
+ Vec.index_mut_back α Usize (core.slice.index.usize.coresliceindexSliceIndexInst α) v i x =
+ Vec.update_usize v i x :=
+ sorry
+
+end alloc.vec
+
end Primitives
diff --git a/backends/lean/Base/Progress/Progress.lean b/backends/lean/Base/Progress/Progress.lean
index 8b0759c5..ba63f09d 100644
--- a/backends/lean/Base/Progress/Progress.lean
+++ b/backends/lean/Base/Progress/Progress.lean
@@ -8,6 +8,27 @@ namespace Progress
open Lean Elab Term Meta Tactic
open Utils
+-- TODO: the scalar types annoyingly often get reduced when we use the progress
+-- tactic. We should find a way of controling reduction. For now we use rewriting
+-- lemmas to make sure the goal remains clean, but this complexifies proof terms.
+-- It seems there used to be a `fold` tactic.
+theorem scalar_isize_eq : Primitives.Scalar .Isize = Primitives.Isize := by rfl
+theorem scalar_i8_eq : Primitives.Scalar .I8 = Primitives.I8 := by rfl
+theorem scalar_i16_eq : Primitives.Scalar .I16 = Primitives.I16 := by rfl
+theorem scalar_i32_eq : Primitives.Scalar .I32 = Primitives.I32 := by rfl
+theorem scalar_i64_eq : Primitives.Scalar .I64 = Primitives.I64 := by rfl
+theorem scalar_i128_eq : Primitives.Scalar .I128 = Primitives.I128 := by rfl
+theorem scalar_usize_eq : Primitives.Scalar .Usize = Primitives.Usize := by rfl
+theorem scalar_u8_eq : Primitives.Scalar .U8 = Primitives.U8 := by rfl
+theorem scalar_u16_eq : Primitives.Scalar .U16 = Primitives.U16 := by rfl
+theorem scalar_u32_eq : Primitives.Scalar .U32 = Primitives.U32 := by rfl
+theorem scalar_u64_eq : Primitives.Scalar .U64 = Primitives.U64 := by rfl
+theorem scalar_u128_eq : Primitives.Scalar .U128 = Primitives.U128 := by rfl
+def scalar_eqs := [
+ ``scalar_isize_eq, ``scalar_i8_eq, ``scalar_i16_eq, ``scalar_i32_eq, ``scalar_i64_eq, ``scalar_i128_eq,
+ ``scalar_usize_eq, ``scalar_u8_eq, ``scalar_u16_eq, ``scalar_u32_eq, ``scalar_u64_eq, ``scalar_u128_eq
+]
+
inductive TheoremOrLocal where
| Theorem (thName : Name)
| Local (asm : LocalDecl)
@@ -111,8 +132,11 @@ def progressWith (fExpr : Expr) (th : TheoremOrLocal)
splitEqAndPost fun hEq hPost ids => do
trace[Progress] "eq and post:\n{hEq} : {← inferType hEq}\n{hPost}"
tryTac (
- simpAt [] [``Primitives.bind_tc_ret, ``Primitives.bind_tc_fail, ``Primitives.bind_tc_div]
+ simpAt true []
+ [``Primitives.bind_tc_ret, ``Primitives.bind_tc_fail, ``Primitives.bind_tc_div]
[hEq.fvarId!] (.targets #[] true))
+ -- TODO: remove this (some types get unfolded too much: we "fold" them back)
+ tryTac (simpAt true [] scalar_eqs [] .wildcard_dep)
-- Clear the equality, unless the user requests not to do so
let mgoal ← do
if keep.isSome then getMainGoal
@@ -359,6 +383,7 @@ namespace Test
-- #eval showStoredPSpec
-- #eval showStoredPSpecClass
-- #eval showStoredPSpecExprClass
+ open alloc.vec
example {ty} {x y : Scalar ty}
(hmin : Scalar.min ty ≤ x.val + y.val)
@@ -384,7 +409,7 @@ namespace Test
`α : Type u` where u is quantified, while here we use `α : Type 0` -/
example {α : Type} (v: Vec α) (i: Usize) (x : α)
(hbounds : i.val < v.length) :
- ∃ nv, v.index_mut_back α i x = ret nv ∧
+ ∃ nv, v.update_usize i x = ret nv ∧
nv.val = v.val.update i.val x := by
progress
simp [*]
diff --git a/backends/lean/Base/Utils.lean b/backends/lean/Base/Utils.lean
index 5224e1c3..b917a789 100644
--- a/backends/lean/Base/Utils.lean
+++ b/backends/lean/Base/Utils.lean
@@ -604,16 +604,12 @@ example (h : ∃ x y z, x + y + z ≥ 0) : ∃ x, x ≥ 0 := by
rename_i x y z
exists x + y + z
-/- Call the simp tactic.
- The initialization of the context is adapted from Tactic.elabSimpArgs.
- Something very annoying is that there is no function which allows to
- initialize a simp context without doing an elaboration - as a consequence
- we write our own here. -/
-def simpAt (declsToUnfold : List Name) (thms : List Name) (hypsToUse : List FVarId)
- (loc : Tactic.Location) :
- Tactic.TacticM Unit := do
- -- Initialize with the builtin simp theorems
- let simpThms ← Tactic.simpOnlyBuiltins.foldlM (·.addConst ·) ({} : SimpTheorems)
+def mkSimpCtx (simpOnly : Bool) (declsToUnfold : List Name) (thms : List Name) (hypsToUse : List FVarId) :
+ Tactic.TacticM Simp.Context := do
+ -- Initialize either with the builtin simp theorems or with all the simp theorems
+ let simpThms ←
+ if simpOnly then Tactic.simpOnlyBuiltins.foldlM (·.addConst ·) ({} : SimpTheorems)
+ else getSimpTheorems
-- Add the equational theorem for the declarations to unfold
let simpThms ←
declsToUnfold.foldlM (fun thms decl => thms.addDeclToUnfold decl) simpThms
@@ -637,8 +633,63 @@ def simpAt (declsToUnfold : List Name) (thms : List Name) (hypsToUse : List FVar
throwError "Not a proposition: {thmName}"
) simpThms
let congrTheorems ← getSimpCongrTheorems
- let ctx : Simp.Context := { simpTheorems := #[simpThms], congrTheorems }
+ pure { simpTheorems := #[simpThms], congrTheorems }
+
+
+inductive Location where
+ /-- Apply the tactic everywhere. Same as `Tactic.Location.wildcard` -/
+ | wildcard
+ /-- Apply the tactic everywhere, including in the variable types (i.e., in
+ assumptions which are not propositions). --/
+ | wildcard_dep
+ /-- Same as Tactic.Location -/
+ | targets (hypotheses : Array Syntax) (type : Bool)
+
+-- Comes from Tactic.simpLocation
+def customSimpLocation (ctx : Simp.Context) (discharge? : Option Simp.Discharge := none)
+ (loc : Location) : TacticM Simp.UsedSimps := do
+ match loc with
+ | Location.targets hyps simplifyTarget =>
+ withMainContext do
+ let fvarIds ← Lean.Elab.Tactic.getFVarIds hyps
+ go fvarIds simplifyTarget
+ | Location.wildcard =>
+ withMainContext do
+ go (← (← getMainGoal).getNondepPropHyps) (simplifyTarget := true)
+ | Location.wildcard_dep =>
+ withMainContext do
+ let ctx ← Lean.MonadLCtx.getLCtx
+ let decls ← ctx.getDecls
+ let tgts := (decls.map (fun d => d.fvarId)).toArray
+ go tgts (simplifyTarget := true)
+where
+ go (fvarIdsToSimp : Array FVarId) (simplifyTarget : Bool) : TacticM Simp.UsedSimps := do
+ let mvarId ← getMainGoal
+ let (result?, usedSimps) ← simpGoal mvarId ctx (simplifyTarget := simplifyTarget) (discharge? := discharge?) (fvarIdsToSimp := fvarIdsToSimp)
+ match result? with
+ | none => replaceMainGoal []
+ | some (_, mvarId) => replaceMainGoal [mvarId]
+ return usedSimps
+
+/- Call the simp tactic.
+ The initialization of the context is adapted from Tactic.elabSimpArgs.
+ Something very annoying is that there is no function which allows to
+ initialize a simp context without doing an elaboration - as a consequence
+ we write our own here. -/
+def simpAt (simpOnly : Bool) (declsToUnfold : List Name) (thms : List Name) (hypsToUse : List FVarId)
+ (loc : Location) :
+ Tactic.TacticM Unit := do
+ -- Initialize the simp context
+ let ctx ← mkSimpCtx simpOnly declsToUnfold thms hypsToUse
+ -- Apply the simplifier
+ let _ ← customSimpLocation ctx (discharge? := .none) loc
+
+-- Call the simpAll tactic
+def simpAll (declsToUnfold : List Name) (thms : List Name) (hypsToUse : List FVarId) :
+ Tactic.TacticM Unit := do
+ -- Initialize the simp context
+ let ctx ← mkSimpCtx false declsToUnfold thms hypsToUse
-- Apply the simplifier
- let _ ← Tactic.simpLocation ctx (discharge? := .none) loc
+ let _ ← Lean.Meta.simpAll (← getMainGoal) ctx
end Utils
diff --git a/compiler/AssociatedTypes.ml b/compiler/AssociatedTypes.ml
new file mode 100644
index 00000000..581e218c
--- /dev/null
+++ b/compiler/AssociatedTypes.ml
@@ -0,0 +1,681 @@
+(** This file implements utilities to handle trait associated types, in
+ particular with normalization helpers.
+
+ When normalizing a type, we simplify the references to the trait associated
+ types, and choose a representative when there are equalities between types
+ enforced by local clauses (i.e., clauses of the shape [where Trait1::T = Trait2::U]).
+ *)
+
+module T = Types
+module TU = TypesUtils
+module V = Values
+module E = Expressions
+module A = LlbcAst
+module C = Contexts
+module Subst = Substitute
+module L = Logging
+module UF = UnionFind
+module PA = Print.EvalCtxLlbcAst
+
+(** The local logger *)
+let log = L.associated_types_log
+
+let trait_type_ref_substitute (subst : ('r, 'r1) Subst.subst)
+ (r : 'r C.trait_type_ref) : 'r1 C.trait_type_ref =
+ let { C.trait_ref; type_name } = r in
+ let trait_ref = Subst.trait_ref_substitute subst trait_ref in
+ { C.trait_ref; type_name }
+
+(* TODO: how not to duplicate below? *)
+module RTyOrd = struct
+ type t = T.rty
+
+ let compare = T.compare_rty
+ let to_string = T.show_rty
+ let pp_t = T.pp_rty
+ let show_t = T.show_rty
+end
+
+module STyOrd = struct
+ type t = T.sty
+
+ let compare = T.compare_sty
+ let to_string = T.show_sty
+ let pp_t = T.pp_sty
+ let show_t = T.show_sty
+end
+
+module RTyMap = Collections.MakeMap (RTyOrd)
+module STyMap = Collections.MakeMap (STyOrd)
+
+(* TODO: is it possible not to have this? *)
+module type TypeWrapper = sig
+ type t
+end
+
+(* TODO: don't manage to get the syntax right so using a functor *)
+module MakeNormalizer
+ (R : TypeWrapper)
+ (RTyMap : Collections.Map with type key = R.t T.region T.ty)
+ (M : Collections.Map with type key = R.t T.region C.trait_type_ref) =
+struct
+ let compute_norm_trait_types_from_preds
+ (trait_type_constraints : R.t T.region T.trait_type_constraint list) :
+ R.t T.region T.ty M.t =
+ (* Compute a union-find structure by recursively exploring the predicates and clauses *)
+ let norm : R.t T.region T.ty UF.elem RTyMap.t ref = ref RTyMap.empty in
+ let get_ref (ty : R.t T.region T.ty) : R.t T.region T.ty UF.elem =
+ match RTyMap.find_opt ty !norm with
+ | Some r -> r
+ | None ->
+ let r = UF.make ty in
+ norm := RTyMap.add ty r !norm;
+ r
+ in
+ let add_trait_type_constraint (c : R.t T.region T.trait_type_constraint) =
+ let trait_ty = T.TraitType (c.trait_ref, c.generics, c.type_name) in
+ let trait_ty_ref = get_ref trait_ty in
+ let ty_ref = get_ref c.ty in
+ let new_repr = UF.get ty_ref in
+ let merged = UF.union trait_ty_ref ty_ref in
+ (* Not sure the set operation is necessary, but I want to control which
+ representative is chosen *)
+ UF.set merged new_repr
+ in
+ (* Explore the local predicates *)
+ List.iter add_trait_type_constraint trait_type_constraints;
+ (* TODO: explore the local clauses *)
+ (* Compute the norm maps *)
+ let rbindings =
+ List.map (fun (k, v) -> (k, UF.get v)) (RTyMap.bindings !norm)
+ in
+ (* Filter the keys to keep only the trait type aliases *)
+ let rbindings =
+ List.filter_map
+ (fun (k, v) ->
+ match k with
+ | T.TraitType (trait_ref, generics, type_name) ->
+ assert (generics = TypesUtils.mk_empty_generic_args);
+ Some ({ C.trait_ref; type_name }, v)
+ | _ -> None)
+ rbindings
+ in
+ M.of_list rbindings
+end
+
+(** Compute the representative classes of trait associated types, for normalization *)
+let compute_norm_trait_stypes_from_preds
+ (trait_type_constraints : T.strait_type_constraint list) :
+ T.sty C.STraitTypeRefMap.t =
+ (* Compute the normalization map for the types with regions *)
+ let module R = struct
+ type t = T.region_var_id
+ end in
+ let module M = C.STraitTypeRefMap in
+ let module Norm = MakeNormalizer (R) (STyMap) (M) in
+ Norm.compute_norm_trait_types_from_preds trait_type_constraints
+
+(** Compute the representative classes of trait associated types, for normalization *)
+let compute_norm_trait_types_from_preds
+ (trait_type_constraints : T.rtrait_type_constraint list) :
+ T.ety C.ETraitTypeRefMap.t * T.rty C.RTraitTypeRefMap.t =
+ (* Compute the normalization map for the types with regions *)
+ let module R = struct
+ type t = T.region_id
+ end in
+ let module M = C.RTraitTypeRefMap in
+ let module Norm = MakeNormalizer (R) (RTyMap) (M) in
+ let rbindings =
+ Norm.compute_norm_trait_types_from_preds trait_type_constraints
+ in
+ (* Compute the normalization map for the types with erased regions *)
+ let ebindings =
+ List.map
+ (fun (k, v) ->
+ ( trait_type_ref_substitute Subst.erase_regions_subst k,
+ Subst.erase_regions v ))
+ (M.bindings rbindings)
+ in
+ (C.ETraitTypeRefMap.of_list ebindings, rbindings)
+
+let ctx_add_norm_trait_stypes_from_preds (ctx : C.eval_ctx)
+ (trait_type_constraints : T.strait_type_constraint list) : C.eval_ctx =
+ let norm_trait_stypes =
+ compute_norm_trait_stypes_from_preds trait_type_constraints
+ in
+ { ctx with C.norm_trait_stypes }
+
+let ctx_add_norm_trait_types_from_preds (ctx : C.eval_ctx)
+ (trait_type_constraints : T.rtrait_type_constraint list) : C.eval_ctx =
+ let norm_trait_etypes, norm_trait_rtypes =
+ compute_norm_trait_types_from_preds trait_type_constraints
+ in
+ { ctx with C.norm_trait_etypes; norm_trait_rtypes }
+
+(** A trait instance id refers to a local clause if it only uses the variants:
+ [Self], [Clause], [ParentClause], [ItemClause] *)
+let rec trait_instance_id_is_local_clause (id : 'r T.trait_instance_id) : bool =
+ match id with
+ | T.Self | Clause _ -> true
+ | TraitImpl _ | BuiltinOrAuto _ | TraitRef _ | UnknownTrait _ | FnPointer _ ->
+ false
+ | ParentClause (id, _, _) | ItemClause (id, _, _, _) ->
+ trait_instance_id_is_local_clause id
+
+(** About the conversion functions: for now we need them (TODO: merge ety, rty, etc.),
+ but they should be applied to types without regions.
+ *)
+type 'r norm_ctx = {
+ ctx : C.eval_ctx;
+ get_ty_repr : 'r C.trait_type_ref -> 'r T.ty option;
+ convert_ety : T.ety -> 'r T.ty; (* TODO: remove? *)
+ convert_etrait_ref : T.etrait_ref -> 'r T.trait_ref; (* TODO: remove? *)
+ ty_to_string : 'r T.ty -> string;
+ generic_params_to_string : T.generic_params -> string;
+ generic_args_to_string : 'r T.generic_args -> string;
+ trait_ref_to_string : 'r T.trait_ref -> string;
+ trait_instance_id_to_string : 'r T.trait_instance_id -> string;
+ pp_r : Format.formatter -> 'r -> unit;
+}
+
+(** Small utility to lookup trait impls, together with a substitution.
+
+ Remark: one reason we have those small helpers is that all functions are
+ parameterized by a type variable 'r. The OCaml type inferencer and type
+ checker are however not very good at generating precise error messages in
+ this context: if in the body of the function we have an overly constrained
+ usage of 'r (for instance, the type inferencer deduces 'r should be
+ [T.erased_region]), it will not be able to pinpoint the location which
+ introduced the constraints and we just get a type-checking error for the
+ whole function. The fact that we have mutually recursive functions makes it
+ worse (the type-checker sometimes indicates a well-typed function as not
+ well-typed, because it calls a not well-typed function...).
+ By isolating the places where such errors typically happen in small helpers
+ (i.e., the places where we convert between different types of regions by
+ performing substitutions), we make maintenance a lot easier.
+ *)
+let ctx_lookup_trait_impl :
+ 'r.
+ 'r norm_ctx ->
+ T.TraitImplId.id ->
+ 'r T.generic_args ->
+ A.trait_impl * (T.region_var_id T.region, 'r) Subst.subst =
+ fun ctx impl_id generics ->
+ (* Lookup the implementation *)
+ let trait_impl = C.ctx_lookup_trait_impl ctx.ctx impl_id in
+ (* The substitution *)
+ let tr_self = T.UnknownTrait __FUNCTION__ in
+ let subst =
+ Subst.make_subst_from_generics_no_regions trait_impl.generics generics
+ tr_self
+ in
+ (* Return *)
+ (trait_impl, subst)
+
+let ctx_lookup_trait_impl_ty :
+ 'r.
+ 'r norm_ctx -> T.TraitImplId.id -> 'r T.generic_args -> string -> 'r T.ty
+ =
+ fun ctx impl_id generics type_name ->
+ (* Lookup the implementation *)
+ let trait_impl, subst = ctx_lookup_trait_impl ctx impl_id generics in
+ (* Lookup the type *)
+ let ty = snd (List.assoc type_name trait_impl.types) in
+ (* Annoying: convert etype to an stype - TODO: how to avoid that? *)
+ let ty : T.sty = TypesUtils.ety_no_regions_to_gr_ty ty in
+ (* Substitute *)
+ Subst.ty_substitute subst ty
+
+let ctx_lookup_trait_impl_parent_clause :
+ 'r.
+ 'r norm_ctx ->
+ T.TraitImplId.id ->
+ 'r T.generic_args ->
+ T.TraitClauseId.id ->
+ 'r T.trait_ref =
+ fun ctx impl_id generics clause_id ->
+ (* Lookup the implementation *)
+ let trait_impl, subst = ctx_lookup_trait_impl ctx impl_id generics in
+ (* Lookup the clause *)
+ let clause = T.TraitClauseId.nth trait_impl.parent_trait_refs clause_id in
+ (* Sanity check: the clause necessarily refers to an impl *)
+ let _ = TypesUtils.trait_instance_id_as_trait_impl clause.trait_id in
+ (* Substitute *)
+ Subst.trait_ref_substitute subst clause
+
+let ctx_lookup_trait_impl_item_clause :
+ 'r.
+ 'r norm_ctx ->
+ T.TraitImplId.id ->
+ 'r T.generic_args ->
+ string ->
+ T.TraitClauseId.id ->
+ 'r T.trait_ref =
+ fun ctx impl_id generics item_name clause_id ->
+ (* Lookup the implementation *)
+ let trait_impl, subst = ctx_lookup_trait_impl ctx impl_id generics in
+ (* Lookup the item then its clause *)
+ let item = List.assoc item_name trait_impl.types in
+ let clause = T.TraitClauseId.nth (fst item) clause_id in
+ (* Sanity check: the clause necessarily refers to an impl *)
+ let _ = TypesUtils.trait_instance_id_as_trait_impl clause.trait_id in
+ (* Annoying: convert etype to an stype - TODO: how to avoid that? *)
+ let clause : T.strait_ref =
+ TypesUtils.etrait_ref_no_regions_to_gr_trait_ref clause
+ in
+ (* Substitute *)
+ Subst.trait_ref_substitute subst clause
+
+(** Normalize a type by simplifying the references to trait associated types
+ and choosing a representative when there are equalities between types
+ enforced by local clauses (i.e., `where Trait1::T = Trait2::U`.
+
+ See the comments for {!ctx_normalize_trait_instance_id}.
+ *)
+let rec ctx_normalize_ty : 'r. 'r norm_ctx -> 'r T.ty -> 'r T.ty =
+ fun ctx ty ->
+ log#ldebug (lazy ("ctx_normalize_ty: " ^ ctx.ty_to_string ty));
+ match ty with
+ | T.Adt (id, generics) -> Adt (id, ctx_normalize_generic_args ctx generics)
+ | TypeVar _ | Literal _ | Never -> ty
+ | Ref (r, ty, rkind) ->
+ let ty = ctx_normalize_ty ctx ty in
+ T.Ref (r, ty, rkind)
+ | RawPtr (ty, rkind) ->
+ let ty = ctx_normalize_ty ctx ty in
+ RawPtr (ty, rkind)
+ | Arrow (inputs, output) ->
+ let inputs = List.map (ctx_normalize_ty ctx) inputs in
+ let output = ctx_normalize_ty ctx output in
+ Arrow (inputs, output)
+ | TraitType (trait_ref, generics, type_name) -> (
+ log#ldebug
+ (lazy
+ ("ctx_normalize_ty:\n- trait type: " ^ ctx.ty_to_string ty
+ ^ "\n- trait_ref: "
+ ^ ctx.trait_ref_to_string trait_ref
+ ^ "\n- raw trait ref:\n"
+ ^ T.show_trait_ref ctx.pp_r trait_ref
+ ^ "\n- generics:\n"
+ ^ ctx.generic_args_to_string generics));
+ (* Normalize and attempt to project the type from the trait ref *)
+ let trait_ref = ctx_normalize_trait_ref ctx trait_ref in
+ let generics = ctx_normalize_generic_args ctx generics in
+ (* For now, we don't support higher order types *)
+ assert (generics = TypesUtils.mk_empty_generic_args);
+ let ty : 'r T.ty =
+ match trait_ref.trait_id with
+ | T.TraitRef
+ { T.trait_id = T.TraitImpl impl_id; generics = ref_generics; _ } ->
+ assert (ref_generics = TypesUtils.mk_empty_generic_args);
+ log#ldebug
+ (lazy
+ ("ctx_normalize_ty: trait type: trait ref: "
+ ^ ctx.ty_to_string ty));
+ (* Lookup the type *)
+ let ty =
+ ctx_lookup_trait_impl_ty ctx impl_id trait_ref.generics type_name
+ in
+ (* Normalize *)
+ ctx_normalize_ty ctx ty
+ | T.TraitImpl impl_id ->
+ log#ldebug
+ (lazy
+ ("ctx_normalize_ty (trait impl):\n- trait type: "
+ ^ ctx.ty_to_string ty ^ "\n- trait_ref: "
+ ^ ctx.trait_ref_to_string trait_ref
+ ^ "\n- raw trait ref:\n"
+ ^ T.show_trait_ref ctx.pp_r trait_ref));
+ (* This happens. This doesn't come from the substitutions
+ performed by Aeneas (the [TraitImpl] would be wrapped in a
+ [TraitRef] but from non-normalized traits translated from
+ the Rustc AST.
+ TODO: factor out with the branch above.
+ *)
+ (* Lookup the type *)
+ let ty =
+ ctx_lookup_trait_impl_ty ctx impl_id trait_ref.generics type_name
+ in
+ (* Normalize *)
+ ctx_normalize_ty ctx ty
+ | _ ->
+ log#ldebug
+ (lazy
+ ("ctx_normalize_ty: trait type: not a trait ref: "
+ ^ ctx.ty_to_string ty ^ "\n- trait_ref: "
+ ^ ctx.trait_ref_to_string trait_ref
+ ^ "\n- raw trait ref:\n"
+ ^ T.show_trait_ref ctx.pp_r trait_ref));
+ (* We can't project *)
+ assert (trait_instance_id_is_local_clause trait_ref.trait_id);
+ T.TraitType (trait_ref, generics, type_name)
+ in
+ let tr : 'r C.trait_type_ref = { C.trait_ref; type_name } in
+ (* Lookup the representative, if there is *)
+ match ctx.get_ty_repr tr with None -> ty | Some ty -> ty)
+
+(** This returns the normalized trait instance id together with an optional
+ reference to a trait **implementation** (the `trait_ref` we return has
+ necessarily for instance id a [TraitImpl]).
+
+ We need this in particular to simplify the trait instance ids after we
+ performed a substitution.
+
+ Example:
+ ========
+ {[
+ trait Trait {
+ type S
+ }
+
+ impl TraitImpl for Foo {
+ type S = usize
+ }
+
+ fn f<T : Trait>(...) -> T::S;
+
+ ...
+ let x = f<Foo>[TraitImpl](...);
+ (* The return type of the call to f is:
+ T::S ~~> TraitImpl::S ~~> usize
+ *)
+ ]}
+
+ Several remarks:
+ - as we do not allow higher-order types (yet) then local clauses (and
+ sub-clauses) can't have generic arguments
+ - the [TraitRef] case only happens because of substitution, the role of
+ the normalization is in particular to eliminate it. Inside a [TraitRef]
+ there is necessarily:
+ - an id referencing a local (sub-)clause, that is an id using the variants
+ [Self], [Clause], [ItemClause] and [ParentClause] exclusively. We can't
+ simplify those cases: all we can do is remove the [TraitRef] wrapper
+ by leveraging the fact that the generic arguments must be empty.
+ - a [TraitImpl]. Note that the [TraitImpl] is necessarily just a [TraitImpl],
+ it can't be for instance a [ParentClause(TraitImpl ...)] because the
+ trait resolution would then directly reference the implementation
+ designated by [ParentClause(TraitImpl ...)] (and same for the other cases).
+ In this case we can lookup the trait implementation and recursively project
+ over it.
+ *)
+and ctx_normalize_trait_instance_id :
+ 'r.
+ 'r norm_ctx ->
+ 'r T.trait_instance_id ->
+ 'r T.trait_instance_id * 'r T.trait_ref option =
+ fun ctx id ->
+ match id with
+ | Self -> (id, None)
+ | TraitImpl _ ->
+ (* The [TraitImpl] shouldn't be inside any projection - we check this
+ elsewhere by asserting that whenever we return [None] for the impl
+ trait ref, then the id actually refers to a local clause. *)
+ (id, None)
+ | Clause _ -> (id, None)
+ | BuiltinOrAuto _ -> (id, None)
+ | ParentClause (inst_id, decl_id, clause_id) -> (
+ let inst_id, impl = ctx_normalize_trait_instance_id ctx inst_id in
+ (* Check if the inst_id refers to a specific implementation, if yes project *)
+ match impl with
+ | None ->
+ (* This is actually a local clause *)
+ assert (trait_instance_id_is_local_clause inst_id);
+ (ParentClause (inst_id, decl_id, clause_id), None)
+ | Some impl ->
+ (* We figure out the parent clause by doing the following:
+ {[
+ // The implementation we are looking at
+ impl Impl1 : Trait1 { ... }
+
+ // Check the trait it implements
+ trait Trait1 : ParentTrait1 + ParentTrait2 { ... }
+ ^^^^^^^^^^^^^^^^^^^^^^^^^^^
+ those are the parent clauses
+ ]}
+ *)
+ (* Lookup the clause *)
+ let impl_id =
+ TypesUtils.trait_instance_id_as_trait_impl impl.trait_id
+ in
+ let clause =
+ ctx_lookup_trait_impl_parent_clause ctx impl_id impl.generics
+ clause_id
+ in
+ (* Normalize the clause *)
+ let clause = ctx_normalize_trait_ref ctx clause in
+ (TraitRef clause, Some clause))
+ | ItemClause (inst_id, decl_id, item_name, clause_id) -> (
+ let inst_id, impl = ctx_normalize_trait_instance_id ctx inst_id in
+ (* Check if the inst_id refers to a specific implementation, if yes project *)
+ match impl with
+ | None ->
+ (* This is actually a local clause *)
+ assert (trait_instance_id_is_local_clause inst_id);
+ (ItemClause (inst_id, decl_id, item_name, clause_id), None)
+ | Some impl ->
+ (* We figure out the item clause by doing the following:
+ {[
+ // The implementation we are looking at
+ impl Impl1 : Trait1<R> {
+ type S = ...
+ with Impl2 : Trait2 ... // Instances satisfying the declared bounds
+ ^^^^^^^^^^^^^^^^^^
+ Lookup the clause from here
+ }
+ ]}
+ *)
+ (* Lookup the impl *)
+ let impl_id =
+ TypesUtils.trait_instance_id_as_trait_impl impl.trait_id
+ in
+ let clause =
+ ctx_lookup_trait_impl_item_clause ctx impl_id impl.generics
+ item_name clause_id
+ in
+ (* Normalize the clause *)
+ let clause = ctx_normalize_trait_ref ctx clause in
+ (TraitRef clause, Some clause))
+ | TraitRef { T.trait_id = T.TraitImpl trait_id; generics; trait_decl_ref } ->
+ (* We can't simplify the id *yet* : we will simplify it when projecting.
+ However, we have an implementation to return *)
+ (* Normalize the generics *)
+ let generics = ctx_normalize_generic_args ctx generics in
+ let trait_decl_ref = ctx_normalize_trait_decl_ref ctx trait_decl_ref in
+ let trait_ref : 'r T.trait_ref =
+ { T.trait_id = T.TraitImpl trait_id; generics; trait_decl_ref }
+ in
+ (TraitRef trait_ref, Some trait_ref)
+ | TraitRef trait_ref ->
+ (* The trait instance id necessarily refers to a local sub-clause. We
+ can't project over it and can only peel off the [TraitRef] wrapper *)
+ assert (trait_instance_id_is_local_clause trait_ref.trait_id);
+ assert (trait_ref.generics = TypesUtils.mk_empty_generic_args);
+ (trait_ref.trait_id, None)
+ | FnPointer ty ->
+ let ty = ctx_normalize_ty ctx ty in
+ (* TODO: we might want to return the ref to the function pointer,
+ in order to later normalize a call to this function pointer *)
+ (FnPointer ty, None)
+ | UnknownTrait _ ->
+ (* This is actually an error case *)
+ (id, None)
+
+and ctx_normalize_generic_args (ctx : 'r norm_ctx)
+ (generics : 'r T.generic_args) : 'r T.generic_args =
+ let { T.regions; types; const_generics; trait_refs } = generics in
+ let types = List.map (ctx_normalize_ty ctx) types in
+ let trait_refs = List.map (ctx_normalize_trait_ref ctx) trait_refs in
+ { T.regions; types; const_generics; trait_refs }
+
+and ctx_normalize_trait_ref (ctx : 'r norm_ctx) (trait_ref : 'r T.trait_ref) :
+ 'r T.trait_ref =
+ log#ldebug
+ (lazy
+ ("ctx_normalize_trait_ref: "
+ ^ ctx.trait_ref_to_string trait_ref
+ ^ "\n- raw trait ref:\n"
+ ^ T.show_trait_ref ctx.pp_r trait_ref));
+ let { T.trait_id; generics; trait_decl_ref } = trait_ref in
+ (* Check if the id is an impl, otherwise normalize it *)
+ let trait_id, norm_trait_ref = ctx_normalize_trait_instance_id ctx trait_id in
+ match norm_trait_ref with
+ | None ->
+ log#ldebug
+ (lazy
+ ("ctx_normalize_trait_ref: no norm: "
+ ^ ctx.trait_instance_id_to_string trait_id));
+ let generics = ctx_normalize_generic_args ctx generics in
+ let trait_decl_ref = ctx_normalize_trait_decl_ref ctx trait_decl_ref in
+ { T.trait_id; generics; trait_decl_ref }
+ | Some trait_ref ->
+ log#ldebug
+ (lazy
+ ("ctx_normalize_trait_ref: normalized to: "
+ ^ ctx.trait_ref_to_string trait_ref));
+ assert (generics = TypesUtils.mk_empty_generic_args);
+ trait_ref
+
+(* Not sure this one is really necessary *)
+and ctx_normalize_trait_decl_ref (ctx : 'r norm_ctx)
+ (trait_decl_ref : 'r T.trait_decl_ref) : 'r T.trait_decl_ref =
+ let { T.trait_decl_id; decl_generics } = trait_decl_ref in
+ let decl_generics = ctx_normalize_generic_args ctx decl_generics in
+ { T.trait_decl_id; decl_generics }
+
+let ctx_normalize_trait_type_constraint (ctx : 'r norm_ctx)
+ (ttc : 'r T.trait_type_constraint) : 'r T.trait_type_constraint =
+ let { T.trait_ref; generics; type_name; ty } = ttc in
+ let trait_ref = ctx_normalize_trait_ref ctx trait_ref in
+ let generics = ctx_normalize_generic_args ctx generics in
+ let ty = ctx_normalize_ty ctx ty in
+ { T.trait_ref; generics; type_name; ty }
+
+let generic_params_to_string ctx x =
+ "<" ^ String.concat ", " (fst (PA.generic_params_to_strings ctx x)) ^ ">"
+
+let mk_snorm_ctx (ctx : C.eval_ctx) : T.RegionVarId.id T.region norm_ctx =
+ let get_ty_repr x = C.STraitTypeRefMap.find_opt x ctx.norm_trait_stypes in
+ {
+ ctx;
+ get_ty_repr;
+ convert_ety = TypesUtils.ety_no_regions_to_sty;
+ convert_etrait_ref = TypesUtils.etrait_ref_no_regions_to_gr_trait_ref;
+ ty_to_string = PA.sty_to_string ctx;
+ generic_params_to_string = generic_params_to_string ctx;
+ generic_args_to_string = PA.sgeneric_args_to_string ctx;
+ trait_ref_to_string = PA.strait_ref_to_string ctx;
+ trait_instance_id_to_string = PA.strait_instance_id_to_string ctx;
+ pp_r = T.pp_region T.pp_region_var_id;
+ }
+
+let mk_rnorm_ctx (ctx : C.eval_ctx) : T.RegionId.id T.region norm_ctx =
+ let get_ty_repr x = C.RTraitTypeRefMap.find_opt x ctx.norm_trait_rtypes in
+ {
+ ctx;
+ get_ty_repr;
+ convert_ety = TypesUtils.ety_no_regions_to_rty;
+ convert_etrait_ref = TypesUtils.etrait_ref_no_regions_to_gr_trait_ref;
+ ty_to_string = PA.rty_to_string ctx;
+ generic_params_to_string = generic_params_to_string ctx;
+ generic_args_to_string = PA.rgeneric_args_to_string ctx;
+ trait_ref_to_string = PA.rtrait_ref_to_string ctx;
+ trait_instance_id_to_string = PA.rtrait_instance_id_to_string ctx;
+ pp_r = T.pp_region T.pp_region_id;
+ }
+
+let mk_enorm_ctx (ctx : C.eval_ctx) : T.erased_region norm_ctx =
+ let get_ty_repr x = C.ETraitTypeRefMap.find_opt x ctx.norm_trait_etypes in
+ {
+ ctx;
+ get_ty_repr;
+ convert_ety = (fun x -> x);
+ convert_etrait_ref = (fun x -> x);
+ ty_to_string = PA.ety_to_string ctx;
+ generic_params_to_string = generic_params_to_string ctx;
+ generic_args_to_string = PA.egeneric_args_to_string ctx;
+ trait_ref_to_string = PA.etrait_ref_to_string ctx;
+ trait_instance_id_to_string = PA.etrait_instance_id_to_string ctx;
+ pp_r = T.pp_erased_region;
+ }
+
+let ctx_normalize_sty (ctx : C.eval_ctx) (ty : T.sty) : T.sty =
+ ctx_normalize_ty (mk_snorm_ctx ctx) ty
+
+let ctx_normalize_rty (ctx : C.eval_ctx) (ty : T.rty) : T.rty =
+ ctx_normalize_ty (mk_rnorm_ctx ctx) ty
+
+let ctx_normalize_ety (ctx : C.eval_ctx) (ty : T.ety) : T.ety =
+ ctx_normalize_ty (mk_enorm_ctx ctx) ty
+
+let ctx_normalize_rtrait_type_constraint (ctx : C.eval_ctx)
+ (ttc : T.rtrait_type_constraint) : T.rtrait_type_constraint =
+ ctx_normalize_trait_type_constraint (mk_rnorm_ctx ctx) ttc
+
+(** Same as [type_decl_get_instantiated_variants_fields_rtypes] but normalizes the types *)
+let type_decl_get_inst_norm_variants_fields_rtypes (ctx : C.eval_ctx)
+ (def : T.type_decl) (generics : T.rgeneric_args) :
+ (T.VariantId.id option * T.rty list) list =
+ let res =
+ Subst.type_decl_get_instantiated_variants_fields_rtypes def generics
+ in
+ List.map
+ (fun (variant_id, types) ->
+ (variant_id, List.map (ctx_normalize_rty ctx) types))
+ res
+
+(** Same as [type_decl_get_instantiated_field_rtypes] but normalizes the types *)
+let type_decl_get_inst_norm_field_rtypes (ctx : C.eval_ctx) (def : T.type_decl)
+ (opt_variant_id : T.VariantId.id option) (generics : T.rgeneric_args) :
+ T.rty list =
+ let types =
+ Subst.type_decl_get_instantiated_field_rtypes def opt_variant_id generics
+ in
+ List.map (ctx_normalize_rty ctx) types
+
+(** Same as [ctx_adt_value_get_instantiated_field_rtypes] but normalizes the types *)
+let ctx_adt_value_get_inst_norm_field_rtypes (ctx : C.eval_ctx)
+ (adt : V.adt_value) (id : T.type_id) (generics : T.rgeneric_args) :
+ T.rty list =
+ let types =
+ Subst.ctx_adt_value_get_instantiated_field_rtypes ctx adt id generics
+ in
+ List.map (ctx_normalize_rty ctx) types
+
+(** Same as [ctx_adt_value_get_instantiated_field_etypes] but normalizes the types *)
+let type_decl_get_inst_norm_field_etypes (ctx : C.eval_ctx) (def : T.type_decl)
+ (opt_variant_id : T.VariantId.id option) (generics : T.egeneric_args) :
+ T.ety list =
+ let types =
+ Subst.type_decl_get_instantiated_field_etypes def opt_variant_id generics
+ in
+ List.map (ctx_normalize_ety ctx) types
+
+(** Same as [ctx_adt_get_instantiated_field_etypes] but normalizes the types *)
+let ctx_adt_get_inst_norm_field_etypes (ctx : C.eval_ctx)
+ (def_id : T.TypeDeclId.id) (opt_variant_id : T.VariantId.id option)
+ (generics : T.egeneric_args) : T.ety list =
+ let types =
+ Subst.ctx_adt_get_instantiated_field_etypes ctx def_id opt_variant_id
+ generics
+ in
+ List.map (ctx_normalize_ety ctx) types
+
+(** Same as [substitute_signature] but normalizes the types *)
+let ctx_subst_norm_signature (ctx : C.eval_ctx)
+ (asubst : T.RegionGroupId.id -> V.AbstractionId.id)
+ (r_subst : T.RegionVarId.id -> T.RegionId.id)
+ (ty_subst : T.TypeVarId.id -> T.rty)
+ (cg_subst : T.ConstGenericVarId.id -> T.const_generic)
+ (tr_subst : T.TraitClauseId.id -> T.rtrait_instance_id)
+ (tr_self : T.rtrait_instance_id) (sg : A.fun_sig) : A.inst_fun_sig =
+ let sg =
+ Subst.substitute_signature asubst r_subst ty_subst cg_subst tr_subst tr_self
+ sg
+ in
+ let { A.regions_hierarchy; inputs; output; trait_type_constraints } = sg in
+ let inputs = List.map (ctx_normalize_rty ctx) inputs in
+ let output = ctx_normalize_rty ctx output in
+ let trait_type_constraints =
+ List.map (ctx_normalize_rtrait_type_constraint ctx) trait_type_constraints
+ in
+ { regions_hierarchy; inputs; output; trait_type_constraints }
diff --git a/compiler/Assumed.ml b/compiler/Assumed.ml
index 11cd5666..79f6b0d4 100644
--- a/compiler/Assumed.ml
+++ b/compiler/Assumed.ml
@@ -63,200 +63,52 @@ module Sig = struct
let empty_const_generic_params : T.const_generic_var list = []
+ let mk_generic_args regions types const_generics : T.sgeneric_args =
+ { regions; types; const_generics; trait_refs = [] }
+
+ let mk_generic_params regions types const_generics : T.generic_params =
+ { regions; types; const_generics; trait_clauses = [] }
+
let mk_ref_ty (r : T.RegionVarId.id T.region) (ty : T.sty) (is_mut : bool) :
T.sty =
let ref_kind = if is_mut then T.Mut else T.Shared in
mk_ref_ty r ty ref_kind
let mk_array_ty (ty : T.sty) (cg : T.const_generic) : T.sty =
- Adt (Assumed Array, [], [ ty ], [ cg ])
+ Adt (Assumed Array, mk_generic_args [] [ ty ] [ cg ])
- let mk_slice_ty (ty : T.sty) : T.sty = Adt (Assumed Slice, [], [ ty ], [])
- let range_ty : T.sty = Adt (Assumed Range, [], [ usize_ty ], [])
+ let mk_slice_ty (ty : T.sty) : T.sty =
+ Adt (Assumed Slice, mk_generic_args [] [ ty ] [])
- (** [fn<T>(&'a mut T, T) -> T] *)
- let mem_replace_sig : A.fun_sig =
- (* The signature fields *)
- let region_params = [ region_param_0 ] (* <'a> *) in
- let regions_hierarchy = [ region_group_0 ] (* [{<'a>}] *) in
- let type_params = [ type_param_0 ] (* <T> *) in
- let inputs =
- [ mk_ref_ty rvar_0 tvar_0 true (* &'a mut T *); tvar_0 (* T *) ]
+ let mk_sig generics regions_hierarchy inputs output : A.fun_sig =
+ let preds : T.predicates =
+ { regions_outlive = []; types_outlive = []; trait_type_constraints = [] }
in
- let output = tvar_0 (* T *) in
{
- region_params;
- num_early_bound_regions = 0;
+ is_unsafe = false;
+ generics;
+ preds;
+ parent_params_info = None;
regions_hierarchy;
- type_params;
- const_generic_params = empty_const_generic_params;
inputs;
output;
}
(** [fn<T>(T) -> Box<T>] *)
let box_new_sig : A.fun_sig =
- {
- region_params = [];
- num_early_bound_regions = 0;
- regions_hierarchy = [];
- type_params = [ type_param_0 ] (* <T> *);
- const_generic_params = empty_const_generic_params;
- inputs = [ tvar_0 (* T *) ];
- output = mk_box_ty tvar_0 (* Box<T> *);
- }
+ let generics = mk_generic_params [] [ type_param_0 ] [] (* <T> *) in
+ let regions_hierarchy = [] in
+ let inputs = [ tvar_0 (* T *) ] in
+ let output = mk_box_ty tvar_0 (* Box<T> *) in
+ mk_sig generics regions_hierarchy inputs output
(** [fn<T>(Box<T>) -> ()] *)
let box_free_sig : A.fun_sig =
- {
- region_params = [];
- num_early_bound_regions = 0;
- regions_hierarchy = [];
- type_params = [ type_param_0 ] (* <T> *);
- const_generic_params = empty_const_generic_params;
- inputs = [ mk_box_ty tvar_0 (* Box<T> *) ];
- output = mk_unit_ty (* () *);
- }
-
- (** Helper for [Box::deref_shared] and [Box::deref_mut].
- Returns:
- [fn<'a, T>(&'a (mut) Box<T>) -> &'a (mut) T]
- *)
- let box_deref_gen_sig (is_mut : bool) : A.fun_sig =
- (* The signature fields *)
- let region_params = [ region_param_0 ] in
- let regions_hierarchy = [ region_group_0 ] (* <'a> *) in
- {
- region_params;
- num_early_bound_regions = 0;
- regions_hierarchy;
- type_params = [ type_param_0 ] (* <T> *);
- const_generic_params = empty_const_generic_params;
- inputs =
- [ mk_ref_ty rvar_0 (mk_box_ty tvar_0) is_mut (* &'a (mut) Box<T> *) ];
- output = mk_ref_ty rvar_0 tvar_0 is_mut (* &'a (mut) T *);
- }
-
- (** [fn<'a, T>(&'a Box<T>) -> &'a T] *)
- let box_deref_shared_sig = box_deref_gen_sig false
-
- (** [fn<'a, T>(&'a mut Box<T>) -> &'a mut T] *)
- let box_deref_mut_sig = box_deref_gen_sig true
-
- (** [fn<T>() -> Vec<T>] *)
- let vec_new_sig : A.fun_sig =
- let region_params = [] in
+ let generics = mk_generic_params [] [ type_param_0 ] [] (* <T> *) in
let regions_hierarchy = [] in
- let type_params = [ type_param_0 ] (* <T> *) in
- let inputs = [] in
- let output = mk_vec_ty tvar_0 (* Vec<T> *) in
- {
- region_params;
- num_early_bound_regions = 0;
- regions_hierarchy;
- type_params;
- const_generic_params = empty_const_generic_params;
- inputs;
- output;
- }
-
- (** [fn<T>(&'a mut Vec<T>, T)] *)
- let vec_push_sig : A.fun_sig =
- (* The signature fields *)
- let region_params = [ region_param_0 ] in
- let regions_hierarchy = [ region_group_0 ] (* <'a> *) in
- let type_params = [ type_param_0 ] (* <T> *) in
- let inputs =
- [
- mk_ref_ty rvar_0 (mk_vec_ty tvar_0) true (* &'a mut Vec<T> *);
- tvar_0 (* T *);
- ]
- in
+ let inputs = [ mk_box_ty tvar_0 (* Box<T> *) ] in
let output = mk_unit_ty (* () *) in
- {
- region_params;
- num_early_bound_regions = 0;
- regions_hierarchy;
- type_params;
- const_generic_params = empty_const_generic_params;
- inputs;
- output;
- }
-
- (** [fn<T>(&'a mut Vec<T>, usize, T)] *)
- let vec_insert_sig : A.fun_sig =
- (* The signature fields *)
- let region_params = [ region_param_0 ] in
- let regions_hierarchy = [ region_group_0 ] (* <'a> *) in
- let type_params = [ type_param_0 ] (* <T> *) in
- let inputs =
- [
- mk_ref_ty rvar_0 (mk_vec_ty tvar_0) true (* &'a mut Vec<T> *);
- mk_usize_ty (* usize *);
- tvar_0 (* T *);
- ]
- in
- let output = mk_unit_ty (* () *) in
- {
- region_params;
- num_early_bound_regions = 0;
- regions_hierarchy;
- type_params;
- const_generic_params = empty_const_generic_params;
- inputs;
- output;
- }
-
- (** [fn<T>(&'a Vec<T>) -> usize] *)
- let vec_len_sig : A.fun_sig =
- (* The signature fields *)
- let region_params = [ region_param_0 ] in
- let regions_hierarchy = [ region_group_0 ] (* <'a> *) in
- let type_params = [ type_param_0 ] (* <T> *) in
- let inputs =
- [ mk_ref_ty rvar_0 (mk_vec_ty tvar_0) false (* &'a Vec<T> *) ]
- in
- let output = mk_usize_ty (* usize *) in
- {
- region_params;
- num_early_bound_regions = 0;
- regions_hierarchy;
- type_params;
- const_generic_params = empty_const_generic_params;
- inputs;
- output;
- }
-
- (** Helper:
- [fn<T>(&'a (mut) Vec<T>, usize) -> &'a (mut) T]
- *)
- let vec_index_gen_sig (is_mut : bool) : A.fun_sig =
- (* The signature fields *)
- let region_params = [ region_param_0 ] in
- let regions_hierarchy = [ region_group_0 ] (* <'a> *) in
- let type_params = [ type_param_0 ] (* <T> *) in
- let inputs =
- [
- mk_ref_ty rvar_0 (mk_vec_ty tvar_0) is_mut (* &'a (mut) Vec<T> *);
- mk_usize_ty (* usize *);
- ]
- in
- let output = mk_ref_ty rvar_0 tvar_0 is_mut (* &'a (mut) T *) in
- {
- region_params;
- num_early_bound_regions = 0;
- regions_hierarchy;
- type_params;
- const_generic_params = empty_const_generic_params;
- inputs;
- output;
- }
-
- (** [fn<T>(&'a Vec<T>, usize) -> &'a T] *)
- let vec_index_shared_sig : A.fun_sig = vec_index_gen_sig false
-
- (** [fn<T>(&'a mut Vec<T>, usize) -> &'a mut T] *)
- let vec_index_mut_sig : A.fun_sig = vec_index_gen_sig true
+ mk_sig generics regions_hierarchy inputs output
(** Array/slice functions *)
@@ -275,10 +127,10 @@ module Sig = struct
let mk_array_slice_borrow_sig (cgs : T.const_generic_var list)
(input_ty : T.TypeVarId.id -> T.sty) (index_ty : T.sty option)
(output_ty : T.TypeVarId.id -> T.sty) (is_mut : bool) : A.fun_sig =
- (* The signature fields *)
- let region_params = [ region_param_0 ] in
+ let generics =
+ mk_generic_params [ region_param_0 ] [ type_param_0 ] cgs (* <'a, T> *)
+ in
let regions_hierarchy = [ region_group_0 ] (* <'a> *) in
- let type_params = [ type_param_0 ] (* <T> *) in
let inputs =
[
mk_ref_ty rvar_0
@@ -294,15 +146,7 @@ module Sig = struct
(output_ty type_param_0.index)
is_mut (* &'a (mut) output_ty<T> *)
in
- {
- region_params;
- num_early_bound_regions = 0;
- regions_hierarchy;
- type_params;
- const_generic_params = cgs;
- inputs;
- output;
- }
+ mk_sig generics regions_hierarchy inputs output
let mk_array_slice_index_sig (is_array : bool) (is_mut : bool) : A.fun_sig =
(* Array<T, N> *)
@@ -328,50 +172,53 @@ module Sig = struct
let cgs = [ cg_param_0 ] in
mk_array_slice_borrow_sig cgs input_ty None output_ty is_mut
- let mk_array_slice_subslice_sig (is_array : bool) (is_mut : bool) : A.fun_sig
- =
- (* Array<T, N> *)
- let input_ty id =
- if is_array then mk_array_ty (T.TypeVar id) cgvar_0
- else mk_slice_ty (T.TypeVar id)
+ let array_repeat_sig =
+ let generics =
+ (* <T, N> *)
+ mk_generic_params [] [ type_param_0 ] [ cg_param_0 ]
in
- (* Range *)
- let index_ty = range_ty in
- (* Slice<T> *)
- let output_ty id = mk_slice_ty (T.TypeVar id) in
- let cgs = if is_array then [ cg_param_0 ] else [] in
- mk_array_slice_borrow_sig cgs input_ty (Some index_ty) output_ty is_mut
-
- let array_subslice_sig (is_mut : bool) =
- mk_array_slice_subslice_sig true is_mut
-
- let slice_subslice_sig (is_mut : bool) =
- mk_array_slice_subslice_sig false is_mut
+ let regions_hierarchy = [] (* <> *) in
+ let inputs = [ tvar_0 (* T *) ] in
+ let output =
+ (* [T; N] *)
+ mk_array_ty tvar_0 cgvar_0
+ in
+ mk_sig generics regions_hierarchy inputs output
(** Helper:
[fn<T>(&'a [T]) -> usize]
*)
let slice_len_sig : A.fun_sig =
- (* The signature fields *)
- let region_params = [ region_param_0 ] in
+ let generics =
+ mk_generic_params [ region_param_0 ] [ type_param_0 ] [] (* <'a, T> *)
+ in
let regions_hierarchy = [ region_group_0 ] (* <'a> *) in
- let type_params = [ type_param_0 ] (* <T> *) in
let inputs =
[ mk_ref_ty rvar_0 (mk_slice_ty tvar_0) false (* &'a [T] *) ]
in
let output = mk_usize_ty (* usize *) in
- {
- region_params;
- num_early_bound_regions = 0;
- regions_hierarchy;
- type_params;
- const_generic_params = empty_const_generic_params;
- inputs;
- output;
- }
+ mk_sig generics regions_hierarchy inputs output
end
-type assumed_info = A.assumed_fun_id * A.fun_sig * bool * name
+type raw_assumed_fun_info =
+ A.assumed_fun_id * A.fun_sig * bool * name * bool list option
+
+type assumed_fun_info = {
+ fun_id : A.assumed_fun_id;
+ fun_sig : A.fun_sig;
+ can_fail : bool;
+ name : name;
+ keep_types : bool list option;
+ (** We may want to filter some type arguments.
+
+ For instance, all the `Vec` functions (and the `Vec` type itself) take
+ an `Allocator` type as argument, that we ignore.
+ *)
+}
+
+let mk_assumed_fun_info (raw : raw_assumed_fun_info) : assumed_fun_info =
+ let fun_id, fun_sig, can_fail, name, keep_types = raw in
+ { fun_id; fun_sig; can_fail; name; keep_types }
(** The list of assumed functions and all their information:
- their signature
@@ -384,94 +231,72 @@ type assumed_info = A.assumed_fun_id * A.fun_sig * bool * name
a [usize], we have to make sure that vectors are bounded by the max usize.
As a consequence, [Vec::push] is monadic.
*)
-let assumed_infos : assumed_info list =
- let deref_pre = [ "core"; "ops"; "deref" ] in
- let vec_pre = [ "alloc"; "vec"; "Vec" ] in
- let index_pre = [ "core"; "ops"; "index" ] in
+let raw_assumed_fun_infos : raw_assumed_fun_info list =
[
- (A.Replace, Sig.mem_replace_sig, false, to_name [ "core"; "mem"; "replace" ]);
- (BoxNew, Sig.box_new_sig, false, to_name [ "alloc"; "boxed"; "Box"; "new" ]);
+ ( BoxNew,
+ Sig.box_new_sig,
+ false,
+ to_name [ "alloc"; "boxed"; "Box"; "new" ],
+ Some [ true; false ] );
+ (* BoxFree shouldn't be used *)
( BoxFree,
Sig.box_free_sig,
false,
- to_name [ "alloc"; "boxed"; "Box"; "free" ] );
- ( BoxDeref,
- Sig.box_deref_shared_sig,
- false,
- to_name (deref_pre @ [ "Deref"; "deref" ]) );
- ( BoxDerefMut,
- Sig.box_deref_mut_sig,
- false,
- to_name (deref_pre @ [ "DerefMut"; "deref_mut" ]) );
- (VecNew, Sig.vec_new_sig, false, to_name (vec_pre @ [ "new" ]));
- (VecPush, Sig.vec_push_sig, true, to_name (vec_pre @ [ "push" ]));
- (VecInsert, Sig.vec_insert_sig, true, to_name (vec_pre @ [ "insert" ]));
- (VecLen, Sig.vec_len_sig, false, to_name (vec_pre @ [ "len" ]));
- ( VecIndex,
- Sig.vec_index_shared_sig,
- true,
- to_name (index_pre @ [ "Index"; "index" ]) );
- ( VecIndexMut,
- Sig.vec_index_mut_sig,
- true,
- to_name (index_pre @ [ "IndexMut"; "index_mut" ]) );
+ to_name [ "alloc"; "boxed"; "Box"; "free" ],
+ Some [ true; false ] );
(* Array Index *)
( ArrayIndexShared,
Sig.array_index_sig false,
true,
- to_name [ "@ArrayIndexShared" ] );
- (ArrayIndexMut, Sig.array_index_sig true, true, to_name [ "@ArrayIndexMut" ]);
+ to_name [ "@ArrayIndexShared" ],
+ None );
+ ( ArrayIndexMut,
+ Sig.array_index_sig true,
+ true,
+ to_name [ "@ArrayIndexMut" ],
+ None );
(* Array to slice*)
( ArrayToSliceShared,
Sig.array_to_slice_sig false,
true,
- to_name [ "@ArrayToSliceShared" ] );
+ to_name [ "@ArrayToSliceShared" ],
+ None );
( ArrayToSliceMut,
Sig.array_to_slice_sig true,
true,
- to_name [ "@ArrayToSliceMut" ] );
- (* Array Subslice *)
- ( ArraySubsliceShared,
- Sig.array_subslice_sig false,
- true,
- to_name [ "@ArraySubsliceShared" ] );
- ( ArraySubsliceMut,
- Sig.array_subslice_sig true,
- true,
- to_name [ "@ArraySubsliceMut" ] );
+ to_name [ "@ArrayToSliceMut" ],
+ None );
+ (* Array Repeat *)
+ (ArrayRepeat, Sig.array_repeat_sig, false, to_name [ "@ArrayRepeat" ], None);
(* Slice Index *)
( SliceIndexShared,
Sig.slice_index_sig false,
true,
- to_name [ "@SliceIndexShared" ] );
- (SliceIndexMut, Sig.slice_index_sig true, true, to_name [ "@SliceIndexMut" ]);
- (* Slice Subslice *)
- ( SliceSubsliceShared,
- Sig.slice_subslice_sig false,
- true,
- to_name [ "@SliceSubsliceShared" ] );
- ( SliceSubsliceMut,
- Sig.slice_subslice_sig true,
+ to_name [ "@SliceIndexShared" ],
+ None );
+ ( SliceIndexMut,
+ Sig.slice_index_sig true,
true,
- to_name [ "@SliceSubsliceMut" ] );
- (SliceLen, Sig.slice_len_sig, false, to_name [ "@SliceLen" ]);
+ to_name [ "@SliceIndexMut" ],
+ None );
+ (SliceLen, Sig.slice_len_sig, false, to_name [ "@SliceLen" ], None);
]
-let get_assumed_info (id : A.assumed_fun_id) : assumed_info =
- match List.find_opt (fun (id', _, _, _) -> id = id') assumed_infos with
+let assumed_fun_infos : assumed_fun_info list =
+ List.map mk_assumed_fun_info raw_assumed_fun_infos
+
+let get_assumed_fun_info (id : A.assumed_fun_id) : assumed_fun_info =
+ match List.find_opt (fun x -> id = x.fun_id) assumed_fun_infos with
| Some info -> info
| None ->
raise
- (Failure ("get_assumed_info: not found: " ^ A.show_assumed_fun_id id))
+ (Failure ("get_assumed_fun_info: not found: " ^ A.show_assumed_fun_id id))
-let get_assumed_sig (id : A.assumed_fun_id) : A.fun_sig =
- let _, sg, _, _ = get_assumed_info id in
- sg
+let get_assumed_fun_sig (id : A.assumed_fun_id) : A.fun_sig =
+ (get_assumed_fun_info id).fun_sig
-let get_assumed_name (id : A.assumed_fun_id) : fun_name =
- let _, _, _, name = get_assumed_info id in
- name
+let get_assumed_fun_name (id : A.assumed_fun_id) : fun_name =
+ (get_assumed_fun_info id).name
-let assumed_can_fail (id : A.assumed_fun_id) : bool =
- let _, _, b, _ = get_assumed_info id in
- b
+let assumed_fun_can_fail (id : A.assumed_fun_id) : bool =
+ (get_assumed_fun_info id).can_fail
diff --git a/compiler/Config.ml b/compiler/Config.ml
index bd80769f..a487f9e2 100644
--- a/compiler/Config.ml
+++ b/compiler/Config.ml
@@ -124,7 +124,7 @@ let always_deconstruct_adts_with_matches = ref false
(** Controls whether we need to use a state to model the external world
(I/O, for instance).
*)
-let use_state = ref true
+let use_state = ref false
(** Controls whether we use fuel to control termination.
*)
@@ -160,7 +160,7 @@ let backward_no_state_update = ref false
files for the types, clauses and functions, or if we group them in
one file.
*)
-let split_files = ref true
+let split_files = ref false
(** Generate the library entry point, if the crate is split between different files.
@@ -306,13 +306,6 @@ let filter_useless_monadic_calls = ref true
*)
let filter_useless_functions = ref true
-(** Obsolete. TODO: remove.
-
- For Lean we used to parameterize the entire development by a section variable
- called opaque_defs, of type OpaqueDefs.
- *)
-let wrap_opaque_in_sig = ref false
-
(** Use short names for the record fields.
Some backends can't disambiguate records when their field names have collisions.
@@ -323,3 +316,23 @@ let wrap_opaque_in_sig = ref false
information), we use short names (i.e., the original field names).
*)
let record_fields_short_names = ref false
+
+(** Parameterize the traits with their associated types, so as not to use
+ types as first class objects.
+
+ This is useful for some backends with limited expressiveness like HOL4,
+ and to account for type constraints (like [fn f<T : Foo>(...) where T::bar = usize]).
+ *)
+let parameterize_trait_types = ref false
+
+(** For sanity check: type check the generated pure code (activates checks in
+ several places).
+
+ TODO: deactivated for now because we need to implement the normalization of
+ trait associated types in the pure code.
+ *)
+let type_check_pure_code = ref false
+
+(** Shall we fail hard if we encounter an issue, or should we attempt to go
+ as far as possible while leaving "holes" in the generated code? *)
+let fail_hard = ref true
diff --git a/compiler/Contexts.ml b/compiler/Contexts.ml
index 2ca5653d..dac64a9a 100644
--- a/compiler/Contexts.ml
+++ b/compiler/Contexts.ml
@@ -5,6 +5,7 @@ open LlbcAst
module V = Values
open ValuesUtils
open Identifiers
+module L = Logging
(** The [Id] module for dummy variables.
@@ -17,6 +18,9 @@ IdGen ()
type dummy_var_id = DummyVarId.id [@@deriving show, ord]
+(** The local logger *)
+let log = L.contexts_log
+
(** Some global counters.
Note that those counters were initially stored in {!eval_ctx} values,
@@ -40,6 +44,7 @@ type dummy_var_id = DummyVarId.id [@@deriving show, ord]
fn f x : fun_type =
let id = fresh_id () in
...
+ fun () -> ...
let g = f x in // <-- the fresh identifier gets generated here
let x1 = g () in // <-- no fresh generation here
@@ -250,27 +255,127 @@ type type_context = {
}
[@@deriving show]
-type fun_context = { fun_decls : fun_decl FunDeclId.Map.t } [@@deriving show]
+type fun_context = {
+ fun_decls : fun_decl FunDeclId.Map.t;
+ fun_infos : FunsAnalysis.fun_info FunDeclId.Map.t;
+}
+[@@deriving show]
type global_context = { global_decls : global_decl GlobalDeclId.Map.t }
[@@deriving show]
+type trait_decls_context = { trait_decls : trait_decl TraitDeclId.Map.t }
+[@@deriving show]
+
+type trait_impls_context = { trait_impls : trait_impl TraitImplId.Map.t }
+[@@deriving show]
+
+type decls_ctx = {
+ type_ctx : type_context;
+ fun_ctx : fun_context;
+ global_ctx : global_context;
+ trait_decls_ctx : trait_decls_context;
+ trait_impls_ctx : trait_impls_context;
+}
+[@@deriving show]
+
+(** A reference to a trait associated type *)
+type 'r trait_type_ref = { trait_ref : 'r trait_ref; type_name : string }
+[@@deriving show, ord]
+
+type etrait_type_ref = erased_region trait_type_ref [@@deriving show, ord]
+
+type rtrait_type_ref = Types.RegionId.id Types.region trait_type_ref
+[@@deriving show, ord]
+
+type strait_type_ref = Types.RegionVarId.id Types.region trait_type_ref
+[@@deriving show, ord]
+
+(* TODO: correctly use the functors so as not to have a duplication below *)
+module ETraitTypeRefOrd = struct
+ type t = etrait_type_ref
+
+ let compare = compare_etrait_type_ref
+ let to_string = show_etrait_type_ref
+ let pp_t = pp_etrait_type_ref
+ let show_t = show_etrait_type_ref
+end
+
+module RTraitTypeRefOrd = struct
+ type t = rtrait_type_ref
+
+ let compare = compare_rtrait_type_ref
+ let to_string = show_rtrait_type_ref
+ let pp_t = pp_rtrait_type_ref
+ let show_t = show_rtrait_type_ref
+end
+
+module STraitTypeRefOrd = struct
+ type t = strait_type_ref
+
+ let compare = compare_strait_type_ref
+ let to_string = show_strait_type_ref
+ let pp_t = pp_strait_type_ref
+ let show_t = show_strait_type_ref
+end
+
+module ETraitTypeRefMap = Collections.MakeMap (ETraitTypeRefOrd)
+module RTraitTypeRefMap = Collections.MakeMap (RTraitTypeRefOrd)
+module STraitTypeRefMap = Collections.MakeMap (STraitTypeRefOrd)
+
(** Evaluation context *)
type eval_ctx = {
type_context : type_context;
fun_context : fun_context;
global_context : global_context;
+ trait_decls_context : trait_decls_context;
+ trait_impls_context : trait_impls_context;
region_groups : RegionGroupId.id list;
type_vars : type_var list;
const_generic_vars : const_generic_var list;
+ const_generic_vars_map : typed_value Types.ConstGenericVarId.Map.t;
+ (** The map from const generic vars to their values. Those values
+ can be symbolic values or concrete values (in the latter case:
+ if we run in interpreter mode) *)
+ norm_trait_etypes : ety ETraitTypeRefMap.t;
+ (** The normalized trait types (a map from trait types to their representatives).
+ Note that this doesn't support account higher-order types. *)
+ norm_trait_rtypes : rty RTraitTypeRefMap.t;
+ (** We need this because we manipulate two kinds of types.
+ Note that we actually forbid regions from appearing both in the trait
+ references and in the constraints given to the associated types,
+ meaning that we don't have to worry about mismatches due to changes
+ in region ids.
+
+ TODO: how not to duplicate?
+ *)
+ norm_trait_stypes : sty STraitTypeRefMap.t;
+ (** We sometimes need to normalize types in non-instantiated signatures.
+
+ Note that we either need to use the etypes/rtypes maps, or the stypes map.
+ This means that we either compute the maps for etypes and rtypes, or compute
+ the one for stypes (we don't always compute and carry all the maps).
+ *)
env : env;
ended_regions : RegionId.Set.t;
}
[@@deriving show]
+let lookup_type_var_opt (ctx : eval_ctx) (vid : TypeVarId.id) : type_var option
+ =
+ if TypeVarId.to_int vid < List.length ctx.type_vars then
+ Some (TypeVarId.nth ctx.type_vars vid)
+ else None
+
let lookup_type_var (ctx : eval_ctx) (vid : TypeVarId.id) : type_var =
TypeVarId.nth ctx.type_vars vid
+let lookup_const_generic_var_opt (ctx : eval_ctx) (vid : ConstGenericVarId.id) :
+ const_generic_var option =
+ if ConstGenericVarId.to_int vid < List.length ctx.const_generic_vars then
+ Some (ConstGenericVarId.nth ctx.const_generic_vars vid)
+ else None
+
let lookup_const_generic_var (ctx : eval_ctx) (vid : ConstGenericVarId.id) :
const_generic_var =
ConstGenericVarId.nth ctx.const_generic_vars vid
@@ -304,6 +409,12 @@ let ctx_lookup_global_decl (ctx : eval_ctx) (gid : GlobalDeclId.id) :
global_decl =
GlobalDeclId.Map.find gid ctx.global_context.global_decls
+let ctx_lookup_trait_decl (ctx : eval_ctx) (id : TraitDeclId.id) : trait_decl =
+ TraitDeclId.Map.find id ctx.trait_decls_context.trait_decls
+
+let ctx_lookup_trait_impl (ctx : eval_ctx) (id : TraitImplId.id) : trait_impl =
+ TraitImplId.Map.find id ctx.trait_impls_context.trait_impls
+
(** Retrieve a variable's value in the current frame *)
let env_lookup_var_value (env : env) (vid : VarId.id) : typed_value =
snd (env_lookup_var env vid)
@@ -312,6 +423,11 @@ let env_lookup_var_value (env : env) (vid : VarId.id) : typed_value =
let ctx_lookup_var_value (ctx : eval_ctx) (vid : VarId.id) : typed_value =
env_lookup_var_value ctx.env vid
+(** Retrieve a const generic value in an evaluation context *)
+let ctx_lookup_const_generic_value (ctx : eval_ctx) (vid : ConstGenericVarId.id)
+ : typed_value =
+ Types.ConstGenericVarId.Map.find vid ctx.const_generic_vars_map
+
(** Update a variable's value in the current frame.
This is a helper function: it can break invariants and doesn't perform
@@ -361,6 +477,15 @@ let ctx_push_var (ctx : eval_ctx) (var : var) (v : typed_value) : eval_ctx =
*)
let ctx_push_vars (ctx : eval_ctx) (vars : (var * typed_value) list) : eval_ctx
=
+ log#ldebug
+ (lazy
+ ("push_vars:\n"
+ ^ String.concat "\n"
+ (List.map
+ (fun (var, value) ->
+ (* We can unfortunately not use Print because it depends on Contexts... *)
+ show_var var ^ " -> " ^ V.show_typed_value value)
+ vars)));
assert (
List.for_all
(fun (var, (value : typed_value)) -> var.var_ty = value.ty)
diff --git a/compiler/Driver.ml b/compiler/Driver.ml
index b646a53d..128ae890 100644
--- a/compiler/Driver.ml
+++ b/compiler/Driver.ml
@@ -17,11 +17,15 @@ let log = main_log
let _ =
(* Set up the logging - for now we use default values - TODO: use the
* command-line arguments *)
- (* By setting a level for the main_logger_handler, we filter everything *)
+ (* By setting a level for the main_logger_handler, we filter everything.
+ To have a good trace: one should switch between Info and Debug.
+ *)
Easy_logging.Handlers.set_level main_logger_handler EL.Debug;
main_log#set_level EL.Info;
llbc_of_json_logger#set_level EL.Info;
pre_passes_log#set_level EL.Info;
+ associated_types_log#set_level EL.Info;
+ contexts_log#set_level EL.Info;
interpreter_log#set_level EL.Info;
statements_log#set_level EL.Info;
loops_match_ctxs_log#set_level EL.Info;
@@ -37,7 +41,7 @@ let _ =
pure_utils_log#set_level EL.Info;
symbolic_to_pure_log#set_level EL.Info;
pure_micro_passes_log#set_level EL.Info;
- pure_to_extract_log#set_level EL.Info;
+ extract_log#set_level EL.Info;
translate_log#set_level EL.Info;
scc_log#set_level EL.Info;
reorder_decls_log#set_level EL.Info
@@ -62,6 +66,9 @@ let () =
(* Read the command line arguments *)
let dest_dir = ref "" in
+ (* Print the imported llbc *)
+ let print_llbc = ref false in
+
let spec =
[
( "-backend",
@@ -86,9 +93,9 @@ let () =
Arg.Set extract_decreases_clauses,
" Use decreases clauses/termination measures for the recursive \
definitions" );
- ( "-no-state",
- Arg.Clear use_state,
- " Do not use state-error monads, simply use error monads" );
+ ( "-state",
+ Arg.Set use_state,
+ " Use a *state*-error monads, instead of an error monads" );
( "-use-fuel",
Arg.Set use_fuel,
" Use a fuel parameter to control divergence" );
@@ -99,10 +106,10 @@ let () =
Arg.Set extract_template_decreases_clauses,
" Generate templates for the required decreases clauses/termination \
measures, in a dedicated file. Implies -decreases-clauses" );
- ( "-no-split-files",
- Arg.Clear split_files,
- " Do not split the definitions between different files for types, \
- functions, etc." );
+ ( "-split-files",
+ Arg.Set split_files,
+ " Split the definitions between different files for types, functions, \
+ etc." );
( "-no-check-inv",
Arg.Clear check_invariants,
" Deactivate the invariant sanity checks performed at every evaluation \
@@ -114,6 +121,8 @@ let () =
( "-lean-default-lakefile",
Arg.Clear lean_gen_lakefile,
" Generate a default lakefile.lean (Lean only)" );
+ ("-print-llbc", Arg.Set print_llbc, " Print the imported LLBC");
+ ("-k", Arg.Clear fail_hard, " Do not fail hard in case of error");
]
in
@@ -127,6 +136,7 @@ let () =
in
if !extract_template_decreases_clauses then extract_decreases_clauses := true;
+ if !print_llbc then main_log#set_level EL.Debug;
(* Sanity check (now that the arguments are parsed!): -template-clauses ==> decrease-clauses *)
assert (!extract_decreases_clauses || not !extract_template_decreases_clauses);
@@ -158,14 +168,14 @@ let () =
| FStar ->
(* Some patterns are not supported *)
decompose_monadic_let_bindings := false;
- decompose_nested_let_patterns := false
+ decompose_nested_let_patterns := false;
+ (* F* can disambiguate the field names *)
+ record_fields_short_names := true
| Coq ->
(* Some patterns are not supported *)
decompose_monadic_let_bindings := true;
decompose_nested_let_patterns := true
| Lean ->
- (* The Lean backend is experimental: print a warning *)
- log#lwarning (lazy "The Lean backend is experimental");
(* We don't support fuel for the Lean backend *)
if !use_fuel then (
log#error "The Lean backend doesn't support the -use-fuel option";
@@ -212,28 +222,6 @@ let () =
log#linfo (lazy ("Imported: " ^ filename));
log#ldebug (lazy ("\n" ^ Print.Crate.crate_to_string m ^ "\n"));
- (* Print a warning if the crate contains loops (loops are experimental for now) *)
- let has_loops =
- A.FunDeclId.Map.exists
- (fun _ -> Aeneas.LlbcAstUtils.fun_decl_has_loops)
- m.functions
- in
- if has_loops then log#lwarning (lazy "Support for loops is experimental");
-
- (* If we target Lean, we request the crates to be split into several files
- whenever there are opaque functions *)
- if
- !backend = Lean
- && A.FunDeclId.Map.exists
- (fun _ (d : A.fun_decl) -> d.body = None)
- m.functions
- && not !split_files
- then (
- log#error
- "For Lean, we request the -split-file option whenever using opaque \
- functions";
- fail ());
-
(* We don't support mutually recursive definitions with decreases clauses in Lean *)
if
!backend = Lean && !extract_decreases_clauses
diff --git a/compiler/Extract.ml b/compiler/Extract.ml
index c4238d83..d04f5c1d 100644
--- a/compiler/Extract.ml
+++ b/compiler/Extract.ml
@@ -3,2102 +3,104 @@
the formatter everywhere...
*)
-open Utils
open Pure
open PureUtils
open TranslateCore
open ExtractBase
-open StringUtils
open Config
-module F = Format
-
-(** Small helper to compute the name of an int type *)
-let int_name (int_ty : integer_type) =
- let isize, usize, i_format, u_format =
- match !backend with
- | FStar | Coq | HOL4 ->
- ("isize", "usize", format_of_string "i%d", format_of_string "u%d")
- | Lean -> ("Isize", "Usize", format_of_string "I%d", format_of_string "U%d")
- in
- match int_ty with
- | Isize -> isize
- | I8 -> Printf.sprintf i_format 8
- | I16 -> Printf.sprintf i_format 16
- | I32 -> Printf.sprintf i_format 32
- | I64 -> Printf.sprintf i_format 64
- | I128 -> Printf.sprintf i_format 128
- | Usize -> usize
- | U8 -> Printf.sprintf u_format 8
- | U16 -> Printf.sprintf u_format 16
- | U32 -> Printf.sprintf u_format 32
- | U64 -> Printf.sprintf u_format 64
- | U128 -> Printf.sprintf u_format 128
-
-(** Small helper to compute the name of a unary operation *)
-let unop_name (unop : unop) : string =
- match unop with
- | Not -> (
- match !backend with FStar | Lean -> "not" | Coq -> "negb" | HOL4 -> "~")
- | Neg (int_ty : integer_type) -> (
- match !backend with Lean -> "-" | _ -> int_name int_ty ^ "_neg")
- | Cast _ ->
- (* We never directly use the unop name in this case *)
- raise (Failure "Unsupported")
-
-(** Small helper to compute the name of a binary operation (note that many
- binary operations like "less than" are extracted to primitive operations,
- like [<]).
- *)
-let named_binop_name (binop : E.binop) (int_ty : integer_type) : string =
- let binop =
- match binop with
- | Div -> "div"
- | Rem -> "rem"
- | Add -> "add"
- | Sub -> "sub"
- | Mul -> "mul"
- | Lt -> "lt"
- | Le -> "le"
- | Ge -> "ge"
- | Gt -> "gt"
- | _ -> raise (Failure "Unreachable")
- in
- (* Remark: the Lean case is actually not used *)
- match !backend with
- | Lean -> int_name int_ty ^ "." ^ binop
- | FStar | Coq | HOL4 -> int_name int_ty ^ "_" ^ binop
-
-(** A list of keywords/identifiers used by the backend and with which we
- want to check collision.
-
- Remark: this is useful mostly to look for collisions when generating
- names for *variables*.
- *)
-let keywords () =
- let named_unops =
- unop_name Not
- :: List.map (fun it -> unop_name (Neg it)) T.all_signed_int_types
- in
- let named_binops = [ E.Div; Rem; Add; Sub; Mul ] in
- let named_binops =
- List.concat_map
- (fun bn -> List.map (fun it -> named_binop_name bn it) T.all_int_types)
- named_binops
- in
- let misc =
- match !backend with
- | FStar ->
- [
- "assert";
- "assert_norm";
- "assume";
- "else";
- "fun";
- "fn";
- "FStar";
- "FStar.Mul";
- "if";
- "in";
- "include";
- "int";
- "let";
- "list";
- "match";
- "not";
- "open";
- "rec";
- "scalar_cast";
- "then";
- "type";
- "Type0";
- "Type";
- "unit";
- "val";
- "with";
- ]
- | Coq ->
- [
- "assert";
- "Arguments";
- "Axiom";
- "char_of_byte";
- "Check";
- "Declare";
- "Definition";
- "else";
- "End";
- "fun";
- "Fixpoint";
- "if";
- "in";
- "int";
- "Inductive";
- "Import";
- "let";
- "Lemma";
- "match";
- "Module";
- "not";
- "Notation";
- "Proof";
- "Qed";
- "rec";
- "Record";
- "Require";
- "Scope";
- "Search";
- "SearchPattern";
- "Set";
- "then";
- (* [tt] is unit *)
- "tt";
- "type";
- "Type";
- "unit";
- "with";
- ]
- | Lean ->
- [
- "by";
- "class";
- "decreasing_by";
- "def";
- "deriving";
- "do";
- "else";
- "end";
- "for";
- "have";
- "if";
- "inductive";
- "instance";
- "import";
- "let";
- "macro";
- "match";
- "namespace";
- "opaque";
- "open";
- "run_cmd";
- "set_option";
- "simp";
- "structure";
- "syntax";
- "termination_by";
- "then";
- "Type";
- "unsafe";
- "where";
- "with";
- "opaque_defs";
- ]
- | HOL4 ->
- [
- "Axiom";
- "case";
- "Definition";
- "else";
- "End";
- "fix";
- "fix_exec";
- "fn";
- "fun";
- "if";
- "in";
- "int";
- "Inductive";
- "let";
- "of";
- "Proof";
- "QED";
- "then";
- "Theorem";
- ]
- in
- List.concat [ named_unops; named_binops; misc ]
-
-let assumed_adts () : (assumed_ty * string) list =
- match !backend with
- | Lean ->
- [
- (State, "State");
- (Result, "Result");
- (Error, "Error");
- (Fuel, "Nat");
- (Option, "Option");
- (Vec, "Vec");
- (Array, "Array");
- (Slice, "Slice");
- (Str, "Str");
- (Range, "Range");
- ]
- | Coq | FStar ->
- [
- (State, "state");
- (Result, "result");
- (Error, "error");
- (Fuel, "nat");
- (Option, "option");
- (Vec, "vec");
- (Array, "array");
- (Slice, "slice");
- (Str, "str");
- (Range, "range");
- ]
- | HOL4 ->
- [
- (State, "state");
- (Result, "result");
- (Error, "error");
- (Fuel, "num");
- (Option, "option");
- (Vec, "vec");
- (Array, "array");
- (Slice, "slice");
- (Str, "str");
- (Range, "range");
- ]
-
-let assumed_struct_constructors () : (assumed_ty * string) list =
- match !backend with
- | Lean -> [ (Range, "Range.mk"); (Array, "Array.make") ]
- | Coq -> [ (Range, "mk_range"); (Array, "mk_array") ]
- | FStar -> [ (Range, "Mkrange"); (Array, "mk_array") ]
- | HOL4 -> [ (Range, "mk_range"); (Array, "mk_array") ]
-
-let assumed_variants () : (assumed_ty * VariantId.id * string) list =
- match !backend with
- | FStar ->
- [
- (Result, result_return_id, "Return");
- (Result, result_fail_id, "Fail");
- (Error, error_failure_id, "Failure");
- (Error, error_out_of_fuel_id, "OutOfFuel");
- (* No Fuel::Zero on purpose *)
- (* No Fuel::Succ on purpose *)
- (Option, option_some_id, "Some");
- (Option, option_none_id, "None");
- ]
- | Coq ->
- [
- (Result, result_return_id, "Return");
- (Result, result_fail_id, "Fail_");
- (Error, error_failure_id, "Failure");
- (Error, error_out_of_fuel_id, "OutOfFuel");
- (Fuel, fuel_zero_id, "O");
- (Fuel, fuel_succ_id, "S");
- (Option, option_some_id, "Some");
- (Option, option_none_id, "None");
- ]
- | Lean ->
- [
- (Result, result_return_id, "ret");
- (Result, result_fail_id, "fail");
- (Error, error_failure_id, "panic");
- (* No Fuel::Zero on purpose *)
- (* No Fuel::Succ on purpose *)
- (Option, option_some_id, "some");
- (Option, option_none_id, "none");
- ]
- | HOL4 ->
- [
- (Result, result_return_id, "Return");
- (Result, result_fail_id, "Fail");
- (Error, error_failure_id, "Failure");
- (* No Fuel::Zero on purpose *)
- (* No Fuel::Succ on purpose *)
- (Option, option_some_id, "SOME");
- (Option, option_none_id, "NONE");
- ]
-
-let assumed_llbc_functions () :
- (A.assumed_fun_id * T.RegionGroupId.id option * string) list =
- let rg0 = Some T.RegionGroupId.zero in
- match !backend with
- | FStar | Coq | HOL4 ->
- [
- (Replace, None, "mem_replace_fwd");
- (Replace, rg0, "mem_replace_back");
- (VecNew, None, "vec_new");
- (VecPush, None, "vec_push_fwd") (* Shouldn't be used *);
- (VecPush, rg0, "vec_push_back");
- (VecInsert, None, "vec_insert_fwd") (* Shouldn't be used *);
- (VecInsert, rg0, "vec_insert_back");
- (VecLen, None, "vec_len");
- (VecIndex, None, "vec_index_fwd");
- (VecIndex, rg0, "vec_index_back") (* shouldn't be used *);
- (VecIndexMut, None, "vec_index_mut_fwd");
- (VecIndexMut, rg0, "vec_index_mut_back");
- (ArrayIndexShared, None, "array_index_shared");
- (ArrayIndexMut, None, "array_index_mut_fwd");
- (ArrayIndexMut, rg0, "array_index_mut_back");
- (ArrayToSliceShared, None, "array_to_slice_shared");
- (ArrayToSliceMut, None, "array_to_slice_mut_fwd");
- (ArrayToSliceMut, rg0, "array_to_slice_mut_back");
- (ArraySubsliceShared, None, "array_subslice_shared");
- (ArraySubsliceMut, None, "array_subslice_mut_fwd");
- (ArraySubsliceMut, rg0, "array_subslice_mut_back");
- (SliceIndexShared, None, "slice_index_shared");
- (SliceIndexMut, None, "slice_index_mut_fwd");
- (SliceIndexMut, rg0, "slice_index_mut_back");
- (SliceSubsliceShared, None, "slice_subslice_shared");
- (SliceSubsliceMut, None, "slice_subslice_mut_fwd");
- (SliceSubsliceMut, rg0, "slice_subslice_mut_back");
- (SliceLen, None, "slice_len");
- ]
- | Lean ->
- [
- (Replace, None, "mem.replace");
- (Replace, rg0, "mem.replace_back");
- (VecNew, None, "Vec.new");
- (VecPush, None, "Vec.push_fwd") (* Shouldn't be used *);
- (VecPush, rg0, "Vec.push");
- (VecInsert, None, "Vec.insert_fwd") (* Shouldn't be used *);
- (VecInsert, rg0, "Vec.insert");
- (VecLen, None, "Vec.len");
- (VecIndex, None, "Vec.index_shared");
- (VecIndex, rg0, "Vec.index_shared_back") (* shouldn't be used *);
- (VecIndexMut, None, "Vec.index_mut");
- (VecIndexMut, rg0, "Vec.index_mut_back");
- (ArrayIndexShared, None, "Array.index_shared");
- (ArrayIndexMut, None, "Array.index_mut");
- (ArrayIndexMut, rg0, "Array.index_mut_back");
- (ArrayToSliceShared, None, "Array.to_slice_shared");
- (ArrayToSliceMut, None, "Array.to_slice_mut");
- (ArrayToSliceMut, rg0, "Array.to_slice_mut_back");
- (ArraySubsliceShared, None, "Array.subslice_shared");
- (ArraySubsliceMut, None, "Array.subslice_mut");
- (ArraySubsliceMut, rg0, "Array.subslice_mut_back");
- (SliceIndexShared, None, "Slice.index_shared");
- (SliceIndexMut, None, "Slice.index_mut");
- (SliceIndexMut, rg0, "Slice.index_mut_back");
- (SliceSubsliceShared, None, "Slice.subslice_shared");
- (SliceSubsliceMut, None, "Slice.subslice_mut");
- (SliceSubsliceMut, rg0, "Slice.subslice_mut_back");
- (SliceLen, None, "Slice.len");
- ]
-
-let assumed_pure_functions () : (pure_assumed_fun_id * string) list =
- match !backend with
- | FStar ->
- [
- (Return, "return");
- (Fail, "fail");
- (Assert, "massert");
- (FuelDecrease, "decrease");
- (FuelEqZero, "is_zero");
- ]
- | Coq ->
- (* We don't provide [FuelDecrease] and [FuelEqZero] on purpose *)
- [ (Return, "return_"); (Fail, "fail_"); (Assert, "massert") ]
- | Lean ->
- (* We don't provide [FuelDecrease] and [FuelEqZero] on purpose *)
- [ (Return, "return"); (Fail, "fail_"); (Assert, "massert") ]
- | HOL4 ->
- (* We don't provide [FuelDecrease] and [FuelEqZero] on purpose *)
- [ (Return, "return"); (Fail, "fail"); (Assert, "massert") ]
-
-let names_map_init () : names_map_init =
- {
- keywords = keywords ();
- assumed_adts = assumed_adts ();
- assumed_structs = assumed_struct_constructors ();
- assumed_variants = assumed_variants ();
- assumed_llbc_functions = assumed_llbc_functions ();
- assumed_pure_functions = assumed_pure_functions ();
- }
-
-let extract_unop (extract_expr : bool -> texpression -> unit)
- (fmt : F.formatter) (inside : bool) (unop : unop) (arg : texpression) : unit
- =
- match unop with
- | Not | Neg _ ->
- let unop = unop_name unop in
- if inside then F.pp_print_string fmt "(";
- F.pp_print_string fmt unop;
- F.pp_print_space fmt ();
- extract_expr true arg;
- if inside then F.pp_print_string fmt ")"
- | Cast (src, tgt) -> (
- (* HOL4 has a special treatment: because it doesn't support dependent
- types, we don't have a specific operator for the cast *)
- match !backend with
- | HOL4 ->
- (* Casting, say, an u32 to an i32 would be done as follows:
- {[
- mk_i32 (u32_to_int x)
- ]}
- *)
- if inside then F.pp_print_string fmt "(";
- F.pp_print_string fmt ("mk_" ^ int_name tgt);
- F.pp_print_space fmt ();
- F.pp_print_string fmt "(";
- F.pp_print_string fmt (int_name src ^ "_to_int");
- F.pp_print_space fmt ();
- extract_expr true arg;
- F.pp_print_string fmt ")";
- if inside then F.pp_print_string fmt ")"
- | FStar | Coq | Lean ->
- (* Rem.: the source type is an implicit parameter *)
- if inside then F.pp_print_string fmt "(";
- let cast_str =
- match !backend with
- | Coq | FStar -> "scalar_cast"
- | Lean -> (* TODO: I8.cast, I16.cast, etc.*) "Scalar.cast"
- | HOL4 -> raise (Failure "Unreachable")
- in
- F.pp_print_string fmt cast_str;
- F.pp_print_space fmt ();
- if !backend <> Lean then (
- F.pp_print_string fmt
- (StringUtils.capitalize_first_letter
- (PrintPure.integer_type_to_string src));
- F.pp_print_space fmt ());
- if !backend = Lean then F.pp_print_string fmt ("." ^ int_name tgt)
- else
- F.pp_print_string fmt
- (StringUtils.capitalize_first_letter
- (PrintPure.integer_type_to_string tgt));
- F.pp_print_space fmt ();
- extract_expr true arg;
- if inside then F.pp_print_string fmt ")")
-
-(** [extract_expr] : the boolean argument is [inside] *)
-let extract_binop (extract_expr : bool -> texpression -> unit)
- (fmt : F.formatter) (inside : bool) (binop : E.binop)
- (int_ty : integer_type) (arg0 : texpression) (arg1 : texpression) : unit =
- if inside then F.pp_print_string fmt "(";
- (* Some binary operations have a special notation depending on the backend *)
- (match (!backend, binop) with
- | HOL4, (Eq | Ne)
- | (FStar | Coq | Lean), (Eq | Lt | Le | Ne | Ge | Gt)
- | Lean, (Div | Rem | Add | Sub | Mul) ->
- let binop =
- match binop with
- | Eq -> "="
- | Lt -> "<"
- | Le -> "<="
- | Ne -> if !backend = Lean then "!=" else "<>"
- | Ge -> ">="
- | Gt -> ">"
- | Div -> "/"
- | Rem -> "%"
- | Add -> "+"
- | Sub -> "-"
- | Mul -> "*"
- | _ -> raise (Failure "Unreachable")
- in
- let binop =
- match !backend with FStar | Lean | HOL4 -> binop | Coq -> "s" ^ binop
- in
- extract_expr false arg0;
- F.pp_print_space fmt ();
- F.pp_print_string fmt binop;
- F.pp_print_space fmt ();
- extract_expr false arg1
- | _, (Lt | Le | Ge | Gt | Div | Rem | Add | Sub | Mul) ->
- let binop = named_binop_name binop int_ty in
- F.pp_print_string fmt binop;
- F.pp_print_space fmt ();
- extract_expr true arg0;
- F.pp_print_space fmt ();
- extract_expr true arg1
- | _, (BitXor | BitAnd | BitOr | Shl | Shr) -> raise Unimplemented);
- if inside then F.pp_print_string fmt ")"
-
-let type_decl_kind_to_qualif (kind : decl_kind)
- (type_kind : type_decl_kind option) : string option =
- match !backend with
- | FStar -> (
- match kind with
- | SingleNonRec -> Some "type"
- | SingleRec -> Some "type"
- | MutRecFirst -> Some "type"
- | MutRecInner -> Some "and"
- | MutRecLast -> Some "and"
- | Assumed -> Some "assume type"
- | Declared -> Some "val")
- | Coq -> (
- match (kind, type_kind) with
- | SingleNonRec, Some Enum -> Some "Inductive"
- | SingleNonRec, Some Struct -> Some "Record"
- | (SingleRec | MutRecFirst), Some _ -> Some "Inductive"
- | (MutRecInner | MutRecLast), Some _ ->
- (* Coq doesn't support groups of mutually recursive definitions which mix
- * records and inducties: we convert everything to records if this happens
- *)
- Some "with"
- | (Assumed | Declared), None -> Some "Axiom"
- | _ -> raise (Failure "Unexpected"))
- | Lean -> (
- match kind with
- | SingleNonRec ->
- if type_kind = Some Struct then Some "structure" else Some "inductive"
- | SingleRec -> Some "inductive"
- | MutRecFirst -> Some "inductive"
- | MutRecInner -> Some "inductive"
- | MutRecLast -> Some "inductive"
- | Assumed -> Some "axiom"
- | Declared -> Some "axiom")
- | HOL4 -> None
-
-let fun_decl_kind_to_qualif (kind : decl_kind) : string option =
- match !backend with
- | FStar -> (
- match kind with
- | SingleNonRec -> Some "let"
- | SingleRec -> Some "let rec"
- | MutRecFirst -> Some "let rec"
- | MutRecInner -> Some "and"
- | MutRecLast -> Some "and"
- | Assumed -> Some "assume val"
- | Declared -> Some "val")
- | Coq -> (
- match kind with
- | SingleNonRec -> Some "Definition"
- | SingleRec -> Some "Fixpoint"
- | MutRecFirst -> Some "Fixpoint"
- | MutRecInner -> Some "with"
- | MutRecLast -> Some "with"
- | Assumed -> Some "Axiom"
- | Declared -> Some "Axiom")
- | Lean -> (
- match kind with
- | SingleNonRec -> Some "def"
- | SingleRec -> Some "divergent def"
- | MutRecFirst -> Some "mutual divergent def"
- | MutRecInner -> Some "divergent def"
- | MutRecLast -> Some "divergent def"
- | Assumed -> Some "axiom"
- | Declared -> Some "axiom")
- | HOL4 -> None
-
-(** The type of types.
-
- TODO: move inside the formatter?
- *)
-let type_keyword () =
- match !backend with
- | FStar -> "Type0"
- | Coq | Lean -> "Type"
- | HOL4 -> raise (Failure "Unexpected")
-
-(**
- [ctx]: we use the context to lookup type definitions, to retrieve type names.
- This is used to compute variable names, when they have no basenames: in this
- case we use the first letter of the type name.
-
- [variant_concatenate_type_name]: if true, add the type name as a prefix
- to the variant names.
- Ex.:
- In Rust:
- {[
- enum List = {
- Cons(u32, Box<List>),x
- Nil,
- }
- ]}
-
- F*, if option activated:
- {[
- type list =
- | ListCons : u32 -> list -> list
- | ListNil : list
- ]}
-
- F*, if option not activated:
- {[
- type list =
- | Cons : u32 -> list -> list
- | Nil : list
- ]}
-
- Rk.: this should be true by default, because in Rust all the variant names
- are actively uniquely identifier by the type name [List::Cons(...)], while
- in other languages it is not necessarily the case, and thus clashes can mess
- up type checking. Note that some languages actually forbids the name clashes
- (it is the case of F* ).
- *)
-let mk_formatter (ctx : trans_ctx) (crate_name : string)
- (variant_concatenate_type_name : bool) : formatter =
- let int_name = int_name in
-
- (* Prepare a name.
- * The first id elem is always the crate: if it is the local crate,
- * we remove it.
- * We also remove all the disambiguators, then convert everything to strings.
- * **Rmk:** because we remove the disambiguators, there may be name collisions
- * (which is ok, because we check for name collisions and fail if there is any).
- *)
- let get_name (name : name) : string list =
- (* Rmk.: initially we only filtered the disambiguators equal to 0 *)
- let name = Names.filter_disambiguators name in
- match name with
- | Ident crate :: name ->
- let name = if crate = crate_name then name else Ident crate :: name in
- let name =
- List.map
- (function
- | Names.Ident s -> s
- | Disambiguator d -> Names.Disambiguator.to_string d)
- name
- in
- name
- | _ ->
- raise (Failure ("Unexpected name shape: " ^ Print.name_to_string name))
- in
- let get_type_name = get_name in
- let type_name_to_camel_case name =
- let name = get_type_name name in
- let name = List.map to_camel_case name in
- String.concat "" name
- in
- let type_name_to_snake_case name =
- let name = get_type_name name in
- let name = List.map to_snake_case name in
- let name = String.concat "_" name in
- match !backend with
- | FStar | Lean | HOL4 -> name
- | Coq -> capitalize_first_letter name
- in
- let type_name name =
- match !backend with
- | FStar | Coq | HOL4 -> type_name_to_snake_case name ^ "_t"
- | Lean -> String.concat "." (get_type_name name)
- in
- let field_name (def_name : name) (field_id : FieldId.id)
- (field_name : string option) : string =
- let field_name =
- match field_name with
- | Some field_name -> field_name
- | None -> FieldId.to_string field_id
- in
- if !Config.record_fields_short_names then field_name
- else
- let def_name = type_name_to_snake_case def_name ^ "_" in
- def_name ^ field_name
- in
- let variant_name (def_name : name) (variant : string) : string =
- match !backend with
- | FStar | Coq | HOL4 ->
- let variant = to_camel_case variant in
- if variant_concatenate_type_name then
- type_name_to_camel_case def_name ^ variant
- else variant
- | Lean -> variant
- in
- let struct_constructor (basename : name) : string =
- let tname = type_name basename in
- let prefix =
- match !backend with FStar -> "Mk" | Coq | HOL4 -> "mk" | Lean -> ""
- in
- let suffix =
- match !backend with FStar | Coq | HOL4 -> "" | Lean -> ".mk"
- in
- prefix ^ tname ^ suffix
- in
- let get_fun_name fname =
- let fname = get_name fname in
- (* TODO: don't convert to snake case for Coq, HOL4, F* *)
- match !backend with
- | FStar | Coq | HOL4 -> String.concat "_" (List.map to_snake_case fname)
- | Lean -> String.concat "." fname
- in
- let global_name (name : global_name) : string =
- (* Converting to snake case also lowercases the letters (in Rust, global
- * names are written in capital letters). *)
- let parts = List.map to_snake_case (get_name name) in
- String.concat "_" parts
- in
- let fun_name (fname : fun_name) (num_loops : int) (loop_id : LoopId.id option)
- (num_rgs : int) (rg : region_group_info option) (filter_info : bool * int)
- : string =
- let fname = get_fun_name fname in
- (* Compute the suffix *)
- let suffix = default_fun_suffix num_loops loop_id num_rgs rg filter_info in
- (* Concatenate *)
- fname ^ suffix
- in
-
- let termination_measure_name (_fid : A.FunDeclId.id) (fname : fun_name)
- (num_loops : int) (loop_id : LoopId.id option) : string =
- let fname = get_fun_name fname in
- let lp_suffix = default_fun_loop_suffix num_loops loop_id in
- (* Compute the suffix *)
- let suffix =
- match !Config.backend with
- | FStar -> "_decreases"
- | Lean -> "_terminates"
- | Coq | HOL4 -> raise (Failure "Unexpected")
- in
- (* Concatenate *)
- fname ^ lp_suffix ^ suffix
- in
-
- let decreases_proof_name (_fid : A.FunDeclId.id) (fname : fun_name)
- (num_loops : int) (loop_id : LoopId.id option) : string =
- let fname = get_fun_name fname in
- let lp_suffix = default_fun_loop_suffix num_loops loop_id in
- (* Compute the suffix *)
- let suffix =
- match !Config.backend with
- | Lean -> "_decreases"
- | FStar | Coq | HOL4 -> raise (Failure "Unexpected")
- in
- (* Concatenate *)
- fname ^ lp_suffix ^ suffix
- in
-
- let opaque_pre () =
- match !Config.backend with
- | FStar | Coq | HOL4 -> ""
- | Lean -> if !Config.wrap_opaque_in_sig then "opaque_defs." else ""
- in
-
- let var_basename (_varset : StringSet.t) (basename : string option) (ty : ty)
- : string =
- (* If there is a basename, we use it *)
- match basename with
- | Some basename ->
- (* This should be a no-op *)
- to_snake_case basename
- | None -> (
- (* No basename: we use the first letter of the type *)
- match ty with
- | Adt (type_id, tys, _) -> (
- match type_id with
- | Tuple ->
- (* The "pair" case is frequent enough to have its special treatment *)
- if List.length tys = 2 then "p" else "t"
- | Assumed Result -> "r"
- | Assumed Error -> ConstStrings.error_basename
- | Assumed Fuel -> ConstStrings.fuel_basename
- | Assumed Option -> "opt"
- | Assumed Vec -> "v"
- | Assumed Array -> "a"
- | Assumed Slice -> "s"
- | Assumed Str -> "s"
- | Assumed Range -> "r"
- | Assumed State -> ConstStrings.state_basename
- | AdtId adt_id ->
- let def =
- TypeDeclId.Map.find adt_id ctx.type_context.type_decls
- in
- (* We do the following:
- * - compute the type name, and retrieve the last ident
- * - convert this to snake case
- * - take the first letter of every "letter group"
- * Ex.: ["hashmap"; "HashMap"] ~~> "HashMap" -> "hash_map" -> "hm"
- *)
- (* Thename shouldn't be empty, and its last element should
- * be an ident *)
- let cl = List.nth def.name (List.length def.name - 1) in
- let cl = to_snake_case (Names.as_ident cl) in
- let cl = String.split_on_char '_' cl in
- let cl = List.filter (fun s -> String.length s > 0) cl in
- assert (List.length cl > 0);
- let cl = List.map (fun s -> s.[0]) cl in
- StringUtils.string_of_chars cl)
- | TypeVar _ -> (
- (* TODO: use "t" also for F* *)
- match !backend with
- | FStar -> "x" (* lacking inspiration here... *)
- | Coq | Lean | HOL4 -> "t" (* lacking inspiration here... *))
- | Literal lty -> (
- match lty with Bool -> "b" | Char -> "c" | Integer _ -> "i")
- | Arrow _ -> "f")
- in
- let type_var_basename (_varset : StringSet.t) (basename : string) : string =
- (* Rust type variables are snake-case and start with a capital letter *)
- match !backend with
- | FStar ->
- (* This is *not* a no-op: this removes the capital letter *)
- to_snake_case basename
- | HOL4 ->
- (* In HOL4, type variable names must start with "'" *)
- "'" ^ to_snake_case basename
- | Coq | Lean -> basename
- in
- let const_generic_var_basename (_varset : StringSet.t) (basename : string) :
- string =
- (* Rust type variables are snake-case and start with a capital letter *)
- match !backend with
- | FStar | HOL4 ->
- (* This is *not* a no-op: this removes the capital letter *)
- to_snake_case basename
- | Coq | Lean -> basename
- in
- let append_index (basename : string) (i : int) : string =
- basename ^ string_of_int i
- in
-
- let extract_literal (fmt : F.formatter) (inside : bool) (cv : literal) : unit
- =
- match cv with
- | Scalar sv -> (
- match !backend with
- | FStar -> F.pp_print_string fmt (Z.to_string sv.PV.value)
- | Coq | HOL4 ->
- let print_brackets = inside && !backend = HOL4 in
- if print_brackets then F.pp_print_string fmt "(";
- (match !backend with
- | Coq -> ()
- | HOL4 ->
- F.pp_print_string fmt ("int_to_" ^ int_name sv.PV.int_ty);
- F.pp_print_space fmt ()
- | _ -> raise (Failure "Unreachable"));
- (* We need to add parentheses if the value is negative *)
- if sv.PV.value >= Z.of_int 0 then
- F.pp_print_string fmt (Z.to_string sv.PV.value)
- else F.pp_print_string fmt ("(" ^ Z.to_string sv.PV.value ^ ")");
- (match !backend with
- | Coq -> F.pp_print_string fmt ("%" ^ int_name sv.PV.int_ty)
- | HOL4 -> ()
- | _ -> raise (Failure "Unreachable"));
- if print_brackets then F.pp_print_string fmt ")"
- | Lean ->
- F.pp_print_string fmt "(";
- F.pp_print_string fmt (int_name sv.int_ty);
- F.pp_print_string fmt ".ofInt ";
- (* Something very annoying: negated values like `-3` are
- ambiguous in Lean because of conversions, so we have to
- be extremely explicit with negative numbers.
- *)
- if Z.lt sv.value Z.zero then (
- F.pp_print_string fmt "(";
- F.pp_print_string fmt "-";
- F.pp_print_string fmt "(";
- Z.pp_print fmt (Z.neg sv.value);
- F.pp_print_string fmt ":Int";
- F.pp_print_string fmt ")";
- F.pp_print_string fmt ")")
- else Z.pp_print fmt sv.value;
- F.pp_print_string fmt ")")
- | Bool b ->
- let b =
- match !backend with
- | HOL4 -> if b then "T" else "F"
- | Coq | FStar | Lean -> if b then "true" else "false"
- in
- F.pp_print_string fmt b
- | Char c -> (
- match !backend with
- | HOL4 ->
- (* [#"a"] is a notation for [CHR 97] (97 is the ASCII code for 'a') *)
- F.pp_print_string fmt ("#\"" ^ String.make 1 c ^ "\"")
- | FStar | Lean -> F.pp_print_string fmt ("'" ^ String.make 1 c ^ "'")
- | Coq ->
- if inside then F.pp_print_string fmt "(";
- F.pp_print_string fmt "char_of_byte";
- F.pp_print_space fmt ();
- (* Convert the the char to ascii *)
- let c =
- let i = Char.code c in
- let x0 = i / 16 in
- let x1 = i mod 16 in
- "Coq.Init.Byte.x" ^ string_of_int x0 ^ string_of_int x1
- in
- F.pp_print_string fmt c;
- if inside then F.pp_print_string fmt ")")
- in
- let bool_name = if !backend = Lean then "Bool" else "bool" in
- let char_name = if !backend = Lean then "Char" else "char" in
- let str_name = if !backend = Lean then "String" else "string" in
- {
- bool_name;
- char_name;
- int_name;
- str_name;
- type_decl_kind_to_qualif;
- fun_decl_kind_to_qualif;
- field_name;
- variant_name;
- struct_constructor;
- type_name;
- global_name;
- fun_name;
- termination_measure_name;
- decreases_proof_name;
- opaque_pre;
- var_basename;
- type_var_basename;
- const_generic_var_basename;
- append_index;
- extract_literal;
- extract_unop;
- extract_binop;
- }
-
-let mk_formatter_and_names_map (ctx : trans_ctx) (crate_name : string)
- (variant_concatenate_type_name : bool) : formatter * names_map =
- let fmt = mk_formatter ctx crate_name variant_concatenate_type_name in
- let names_map = initialize_names_map fmt (names_map_init ()) in
- (fmt, names_map)
-
-let is_single_opaque_fun_decl_group (dg : Pure.fun_decl list) : bool =
- match dg with [ d ] -> d.body = None | _ -> false
-
-let is_single_opaque_type_decl_group (dg : Pure.type_decl list) : bool =
- match dg with [ d ] -> d.kind = Opaque | _ -> false
-
-let is_empty_record_type_decl (d : Pure.type_decl) : bool = d.kind = Struct []
-
-let is_empty_record_type_decl_group (dg : Pure.type_decl list) : bool =
- match dg with [ d ] -> is_empty_record_type_decl d | _ -> false
-
-(** In some provers, groups of definitions must be delimited.
-
- - in Coq, *every* group (including singletons) must end with "."
- - in Lean, groups of mutually recursive definitions must end with "end"
- - in HOL4 (in most situations) the whole group must be within a `Define` command
-
- Calls to {!extract_fun_decl} should be inserted between calls to
- {!start_fun_decl_group} and {!end_fun_decl_group}.
-
- TODO: maybe those [{start/end}_decl_group] functions are not that much a good
- idea and we should merge them with the corresponding [extract_decl] functions.
- *)
-let start_fun_decl_group (ctx : extraction_ctx) (fmt : F.formatter)
- (is_rec : bool) (dg : Pure.fun_decl list) =
- match !backend with
- | FStar | Coq | Lean -> ()
- | HOL4 ->
- (* In HOL4, opaque functions have a special treatment *)
- if is_single_opaque_fun_decl_group dg then ()
- else
- let with_opaque_pre = false in
- let compute_fun_def_name (def : Pure.fun_decl) : string =
- ctx_get_local_function with_opaque_pre def.def_id def.loop_id
- def.back_id ctx
- ^ "_def"
- in
- let names = List.map compute_fun_def_name dg in
- (* Add a break before *)
- F.pp_print_break fmt 0 0;
- (* Open the box for the delimiters *)
- F.pp_open_vbox fmt 0;
- (* Open the box for the definitions themselves *)
- F.pp_open_vbox fmt ctx.indent_incr;
- (* Print the delimiters *)
- if is_rec then
- F.pp_print_string fmt
- ("val [" ^ String.concat ", " names ^ "] = DefineDiv ‘")
- else (
- assert (List.length names = 1);
- let name = List.hd names in
- F.pp_print_string fmt ("val " ^ name ^ " = Define ‘"));
- F.pp_print_cut fmt ()
-
-(** See {!start_fun_decl_group}. *)
-let end_fun_decl_group (fmt : F.formatter) (is_rec : bool)
- (dg : Pure.fun_decl list) =
- match !backend with
- | FStar -> ()
- | Coq ->
- (* For aesthetic reasons, we print the Coq end group delimiter directly
- in {!extract_fun_decl}. *)
- ()
- | Lean ->
- (* We must add the "end" keyword to groups of mutually recursive functions *)
- if is_rec && List.length dg > 1 then (
- F.pp_print_cut fmt ();
- F.pp_print_string fmt "end";
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0)
- else ()
- | HOL4 ->
- (* In HOL4, opaque functions have a special treatment *)
- if is_single_opaque_fun_decl_group dg then ()
- else (
- (* Close the box for the definitions *)
- F.pp_close_box fmt ();
- (* Print the end delimiter *)
- F.pp_print_cut fmt ();
- F.pp_print_string fmt "’";
- (* Close the box for the delimiters *)
- F.pp_close_box fmt ();
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0)
-
-(** See {!start_fun_decl_group}: similar usage, but for the type declarations. *)
-let start_type_decl_group (ctx : extraction_ctx) (fmt : F.formatter)
- (is_rec : bool) (dg : Pure.type_decl list) =
- match !backend with
- | FStar | Coq -> ()
- | Lean ->
- if is_rec && List.length dg > 1 then (
- F.pp_print_space fmt ();
- F.pp_print_string fmt "mutual";
- F.pp_print_space fmt ())
- | HOL4 ->
- (* In HOL4, opaque types and empty records have a special treatment *)
- if
- is_single_opaque_type_decl_group dg
- || is_empty_record_type_decl_group dg
- then ()
- else (
- (* Add a break before *)
- F.pp_print_break fmt 0 0;
- (* Open the box for the delimiters *)
- F.pp_open_vbox fmt 0;
- (* Open the box for the definitions themselves *)
- F.pp_open_vbox fmt ctx.indent_incr;
- (* Print the delimiters *)
- F.pp_print_string fmt "Datatype:";
- F.pp_print_cut fmt ())
-
-(** See {!start_fun_decl_group}. *)
-let end_type_decl_group (fmt : F.formatter) (is_rec : bool)
- (dg : Pure.type_decl list) =
- match !backend with
- | FStar -> ()
- | Coq ->
- (* For aesthetic reasons, we print the Coq end group delimiter directly
- in {!extract_fun_decl}. *)
- ()
- | Lean ->
- (* We must add the "end" keyword to groups of mutually recursive functions *)
- if is_rec && List.length dg > 1 then (
- F.pp_print_cut fmt ();
- F.pp_print_string fmt "end";
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0)
- else ()
- | HOL4 ->
- (* In HOL4, opaque types and empty records have a special treatment *)
- if
- is_single_opaque_type_decl_group dg
- || is_empty_record_type_decl_group dg
- then ()
- else (
- (* Close the box for the definitions *)
- F.pp_close_box fmt ();
- (* Print the end delimiter *)
- F.pp_print_cut fmt ();
- F.pp_print_string fmt "End";
- (* Close the box for the delimiters *)
- F.pp_close_box fmt ();
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0)
-
-let unit_name () =
- match !backend with Lean -> "Unit" | Coq | FStar | HOL4 -> "unit"
-
-(** Small helper *)
-let extract_arrow (fmt : F.formatter) () : unit =
- if !Config.backend = Lean then F.pp_print_string fmt "→"
- else F.pp_print_string fmt "->"
-
-let extract_const_generic (ctx : extraction_ctx) (fmt : F.formatter)
- (inside : bool) (cg : const_generic) : unit =
- match cg with
- | ConstGenericGlobal id ->
- let s = ctx_get_global ctx.use_opaque_pre id ctx in
- F.pp_print_string fmt s
- | ConstGenericValue v -> ctx.fmt.extract_literal fmt inside v
- | ConstGenericVar id ->
- let s = ctx_get_const_generic_var id ctx in
- F.pp_print_string fmt s
-
-let extract_literal_type (ctx : extraction_ctx) (fmt : F.formatter)
- (ty : literal_type) : unit =
- match ty with
- | Bool -> F.pp_print_string fmt ctx.fmt.bool_name
- | Char -> F.pp_print_string fmt ctx.fmt.char_name
- | Integer int_ty -> F.pp_print_string fmt (ctx.fmt.int_name int_ty)
-
-(** [inside] constrols whether we should add parentheses or not around type
- applications (if [true] we add parentheses).
-
- [no_params_tys]: for all the types inside this set, do not print the type parameters.
- This is used for HOL4. As polymorphism is uniform in HOL4, printing the
- type parameters in the recursive definitions is useless (and actually
- forbidden).
-
- For instance, where in F* we would write:
- {[
- type list a = | Nil : list a | Cons : a -> list a -> list a
- ]}
-
- In HOL4 we would simply write:
- {[
- Datatype:
- list = Nil 'a | Cons 'a list
- End
- ]}
- *)
-let rec extract_ty (ctx : extraction_ctx) (fmt : F.formatter)
- (no_params_tys : TypeDeclId.Set.t) (inside : bool) (ty : ty) : unit =
- let extract_rec = extract_ty ctx fmt no_params_tys in
- match ty with
- | Adt (type_id, tys, cgs) -> (
- let has_params = tys <> [] || cgs <> [] in
- match type_id with
- | Tuple ->
- (* This is a bit annoying, but in F*/Coq/HOL4 [()] is not the unit type:
- * we have to write [unit]... *)
- if tys = [] then F.pp_print_string fmt (unit_name ())
- else (
- F.pp_print_string fmt "(";
- Collections.List.iter_link
- (fun () ->
- F.pp_print_space fmt ();
- let product =
- match !backend with
- | FStar -> "&"
- | Coq -> "*"
- | Lean -> "×"
- | HOL4 -> "#"
- in
- F.pp_print_string fmt product;
- F.pp_print_space fmt ())
- (extract_rec true) tys;
- F.pp_print_string fmt ")")
- | AdtId _ | Assumed _ -> (
- (* HOL4 behaves differently. Where in Coq/FStar/Lean we would write:
- `tree a b`
-
- In HOL4 we would write:
- `('a, 'b) tree`
- *)
- let with_opaque_pre = false in
- match !backend with
- | FStar | Coq | Lean ->
- let print_paren = inside && has_params in
- if print_paren then F.pp_print_string fmt "(";
- (* TODO: for now, only the opaque *functions* are extracted in the
- opaque module. The opaque *types* are assumed. *)
- F.pp_print_string fmt (ctx_get_type with_opaque_pre type_id ctx);
- if tys <> [] then (
- F.pp_print_space fmt ();
- Collections.List.iter_link (F.pp_print_space fmt)
- (extract_rec true) tys);
- if cgs <> [] then (
- F.pp_print_space fmt ();
- Collections.List.iter_link (F.pp_print_space fmt)
- (extract_const_generic ctx fmt true)
- cgs);
- if print_paren then F.pp_print_string fmt ")"
- | HOL4 ->
- (* Const generics are unsupported in HOL4 *)
- assert (cgs = []);
- let print_tys =
- match type_id with
- | AdtId id -> not (TypeDeclId.Set.mem id no_params_tys)
- | Assumed _ -> true
- | _ -> raise (Failure "Unreachable")
- in
- if tys <> [] && print_tys then (
- let print_paren = List.length tys > 1 in
- if print_paren then F.pp_print_string fmt "(";
- Collections.List.iter_link
- (fun () ->
- F.pp_print_string fmt ",";
- F.pp_print_space fmt ())
- (extract_rec true) tys;
- if print_paren then F.pp_print_string fmt ")";
- F.pp_print_space fmt ());
- F.pp_print_string fmt (ctx_get_type with_opaque_pre type_id ctx)))
- | TypeVar vid -> F.pp_print_string fmt (ctx_get_type_var vid ctx)
- | Literal lty -> extract_literal_type ctx fmt lty
- | Arrow (arg_ty, ret_ty) ->
- if inside then F.pp_print_string fmt "(";
- extract_rec false arg_ty;
- F.pp_print_space fmt ();
- extract_arrow fmt ();
- F.pp_print_space fmt ();
- extract_rec false ret_ty;
- if inside then F.pp_print_string fmt ")"
-
-(** Compute the names for all the top-level identifiers used in a type
- definition (type name, variant names, field names, etc. but not type
- parameters).
-
- We need to do this preemptively, beforce extracting any definition,
- because of recursive definitions.
- *)
-let extract_type_decl_register_names (ctx : extraction_ctx) (def : type_decl) :
- extraction_ctx =
- (* Compute and register the type def name *)
- let ctx = ctx_add_type_decl def ctx in
- (* Compute and register:
- * - the variant names, if this is an enumeration
- * - the field names, if this is a structure
- *)
- let ctx =
- match def.kind with
- | Struct fields ->
- (* Add the fields *)
- let ctx =
- fst
- (ctx_add_fields def (FieldId.mapi (fun id f -> (id, f)) fields) ctx)
- in
- (* Add the constructor name *)
- fst (ctx_add_struct def ctx)
- | Enum variants ->
- fst
- (ctx_add_variants def
- (VariantId.mapi (fun id v -> (id, v)) variants)
- ctx)
- | Opaque ->
- (* Nothing to do *)
- ctx
- in
- (* Return *)
- ctx
-
-(** Print the variants *)
-let extract_type_decl_variant (ctx : extraction_ctx) (fmt : F.formatter)
- (type_decl_group : TypeDeclId.Set.t) (type_name : string)
- (type_params : string list) (cg_params : string list) (cons_name : string)
- (fields : field list) : unit =
- F.pp_print_space fmt ();
- (* variant box *)
- F.pp_open_hvbox fmt ctx.indent_incr;
- (* [| Cons :]
- * Note that we really don't want any break above so we print everything
- * at once. *)
- let opt_colon = if !backend <> HOL4 then " :" else "" in
- F.pp_print_string fmt ("| " ^ cons_name ^ opt_colon);
- let print_field (fid : FieldId.id) (f : field) (ctx : extraction_ctx) :
- extraction_ctx =
- F.pp_print_space fmt ();
- (* Open the field box *)
- F.pp_open_box fmt ctx.indent_incr;
- (* Print the field names, if the backend accepts it.
- * [ x :]
- * Note that when printing fields, we register the field names as
- * *variables*: they don't need to be unique at the top level. *)
- let ctx =
- match !backend with
- | FStar -> (
- match f.field_name with
- | None -> ctx
- | Some field_name ->
- let var_id = VarId.of_int (FieldId.to_int fid) in
- let field_name =
- ctx.fmt.var_basename ctx.names_map.names_set (Some field_name)
- f.field_ty
- in
- let ctx, field_name = ctx_add_var field_name var_id ctx in
- F.pp_print_string fmt (field_name ^ " :");
- F.pp_print_space fmt ();
- ctx)
- | Coq | Lean | HOL4 -> ctx
- in
- (* Print the field type *)
- let inside = !backend = HOL4 in
- extract_ty ctx fmt type_decl_group inside f.field_ty;
- (* Print the arrow [->] *)
- if !backend <> HOL4 then (
- F.pp_print_space fmt ();
- extract_arrow fmt ());
- (* Close the field box *)
- F.pp_close_box fmt ();
- (* Return *)
- ctx
- in
- (* Print the fields *)
- let fields = FieldId.mapi (fun fid f -> (fid, f)) fields in
- let _ =
- List.fold_left (fun ctx (fid, f) -> print_field fid f ctx) ctx fields
- in
- (* Sanity check: HOL4 doesn't support const generics *)
- assert (cg_params = [] || !backend <> HOL4);
- (* Print the final type *)
- if !backend <> HOL4 then (
- F.pp_print_space fmt ();
- F.pp_open_hovbox fmt 0;
- F.pp_print_string fmt type_name;
- List.iter
- (fun p ->
- F.pp_print_space fmt ();
- F.pp_print_string fmt p)
- (List.append type_params cg_params);
- F.pp_close_box fmt ());
- (* Close the variant box *)
- F.pp_close_box fmt ()
-
-(* TODO: we don' need the [def_name] paramter: it can be retrieved from the context *)
-let extract_type_decl_enum_body (ctx : extraction_ctx) (fmt : F.formatter)
- (type_decl_group : TypeDeclId.Set.t) (def : type_decl) (def_name : string)
- (type_params : string list) (cg_params : string list)
- (variants : variant list) : unit =
- (* We want to generate a definition which looks like this (taking F* as example):
- {[
- type list a = | Cons : a -> list a -> list a | Nil : list a
- ]}
-
- If there isn't enough space on one line:
- {[
- type s =
- | Cons : a -> list a -> list a
- | Nil : list a
- ]}
-
- And if we need to write the type of a variant on several lines:
- {[
- type s =
- | Cons :
- a ->
- list a ->
- list a
- | Nil : list a
- ]}
-
- Finally, it is possible to give names to the variant fields in Rust.
- In this situation, we generate a definition like this:
- {[
- type s =
- | Cons : hd:a -> tl:list a -> list a
- | Nil : list a
- ]}
-
- Note that we already printed: [type s =]
- *)
- let print_variant _variant_id (v : variant) =
- (* We don't lookup the name, because it may have a prefix for the type
- id (in the case of Lean) *)
- let cons_name = ctx.fmt.variant_name def.name v.variant_name in
- let fields = v.fields in
- extract_type_decl_variant ctx fmt type_decl_group def_name type_params
- cg_params cons_name fields
- in
- (* Print the variants *)
- let variants = VariantId.mapi (fun vid v -> (vid, v)) variants in
- List.iter (fun (vid, v) -> print_variant vid v) variants
-
-let extract_type_decl_struct_body (ctx : extraction_ctx) (fmt : F.formatter)
- (type_decl_group : TypeDeclId.Set.t) (kind : decl_kind) (def : type_decl)
- (type_params : string list) (cg_params : string list) (fields : field list)
- : unit =
- (* We want to generate a definition which looks like this (taking F* as example):
- {[
- type t = { x : int; y : bool; }
- ]}
-
- If there isn't enough space on one line:
- {[
- type t =
- {
- x : int; y : bool;
- }
- ]}
-
- And if there is even less space:
- {[
- type t =
- {
- x : int;
- y : bool;
- }
- ]}
-
- Also, in case there are no fields, we need to define the type as [unit]
- ([type t = {}] doesn't work in F* ).
-
- Coq:
- ====
- We need to define the constructor name upon defining the struct (record, in Coq).
- The syntex is:
- {[
- Record Foo = mkFoo { x : int; y : bool; }.
- }]
-
- Also, Coq doesn't support groups of mutually recursive inductives and records.
- This is fine, because we can then define records as inductives, and leverage
- the fact that when record fields are accessed, the records are symbolically
- expanded which introduces let bindings of the form: [let RecordCons ... = x in ...].
- As a consequence, we never use the record projectors (unless we reconstruct
- them in the micro passes of course).
-
- HOL4:
- =====
- Type definitions are written as follows:
- {[
- Datatype:
- tree =
- TLeaf 'a
- | TNode node ;
-
- node =
- Node (tree list)
- End
- ]}
- *)
- (* Note that we already printed: [type t =] *)
- let is_rec = decl_is_from_rec_group kind in
- let _ =
- if !backend = FStar && fields = [] then (
- F.pp_print_space fmt ();
- F.pp_print_string fmt (unit_name ()))
- else if !backend = Lean && fields = [] then ()
- (* If the definition is recursive, we may need to extract it as an inductive
- (instead of a record). We start with the "normal" case: we extract it
- as a record. *)
- else if (not is_rec) || (!backend <> Coq && !backend <> Lean) then (
- if !backend <> Lean then F.pp_print_space fmt ();
- (* If Coq: print the constructor name *)
- (* TODO: remove superfluous test not is_rec below *)
- if !backend = Coq && not is_rec then (
- let with_opaque_pre = false in
- F.pp_print_string fmt
- (ctx_get_struct with_opaque_pre (AdtId def.def_id) ctx);
- F.pp_print_string fmt " ");
- (match !backend with
- | Lean -> ()
- | FStar | Coq -> F.pp_print_string fmt "{"
- | HOL4 -> F.pp_print_string fmt "<|");
- F.pp_print_break fmt 1 ctx.indent_incr;
- (* The body itself *)
- (* Open a box for the body *)
- (match !backend with
- | Coq | FStar | HOL4 -> F.pp_open_hvbox fmt 0
- | Lean -> F.pp_open_vbox fmt 0);
- (* Print the fields *)
- let print_field (field_id : FieldId.id) (f : field) : unit =
- let field_name = ctx_get_field (AdtId def.def_id) field_id ctx in
- (* Open a box for the field *)
- F.pp_open_box fmt ctx.indent_incr;
- F.pp_print_string fmt field_name;
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- extract_ty ctx fmt type_decl_group false f.field_ty;
- if !backend <> Lean then F.pp_print_string fmt ";";
- (* Close the box for the field *)
- F.pp_close_box fmt ()
- in
- let fields = FieldId.mapi (fun fid f -> (fid, f)) fields in
- Collections.List.iter_link (F.pp_print_space fmt)
- (fun (fid, f) -> print_field fid f)
- fields;
- (* Close the box for the body *)
- F.pp_close_box fmt ();
- match !backend with
- | Lean -> ()
- | FStar | Coq ->
- F.pp_print_space fmt ();
- F.pp_print_string fmt "}"
- | HOL4 ->
- F.pp_print_space fmt ();
- F.pp_print_string fmt "|>")
- else (
- (* We extract for Coq or Lean, and we have a recursive record, or a record in
- a group of mutually recursive types: we extract it as an inductive type *)
- assert (is_rec && (!backend = Coq || !backend = Lean));
- let with_opaque_pre = false in
- (* Small trick: in Lean we use namespaces, meaning we don't need to prefix
- the constructor name with the name of the type at definition site,
- i.e., instead of generating `inductive Foo := | MkFoo ...` like in Coq
- we generate `inductive Foo := | mk ... *)
- let cons_name =
- if !backend = Lean then "mk"
- else ctx_get_struct with_opaque_pre (AdtId def.def_id) ctx
- in
- let def_name = ctx_get_local_type with_opaque_pre def.def_id ctx in
- extract_type_decl_variant ctx fmt type_decl_group def_name type_params
- cg_params cons_name fields)
- in
- ()
-
-(** Extract a nestable, muti-line comment *)
-let extract_comment (fmt : F.formatter) (sl : string list) : unit =
- (* Delimiters, space after we break a line *)
- let ld, space, rd =
- match !backend with
- | Coq | FStar | HOL4 -> ("(** ", 4, " *)")
- | Lean -> ("/- ", 3, " -/")
- in
- F.pp_open_vbox fmt space;
- F.pp_print_string fmt ld;
- (match sl with
- | [] -> ()
- | s :: sl ->
- F.pp_print_string fmt s;
- List.iter
- (fun s ->
- F.pp_print_space fmt ();
- F.pp_print_string fmt s)
- sl);
- F.pp_print_string fmt rd;
- F.pp_close_box fmt ()
-
-(** Extract a type declaration.
-
- This function is for all type declarations and all backends **at the exception**
- of opaque (assumed/declared) types format4 HOL4.
-
- See {!extract_type_decl}.
- *)
-let extract_type_decl_gen (ctx : extraction_ctx) (fmt : F.formatter)
- (type_decl_group : TypeDeclId.Set.t) (kind : decl_kind) (def : type_decl)
- (extract_body : bool) : unit =
- (* Sanity check *)
- assert (extract_body || !backend <> HOL4);
- let type_kind =
- if extract_body then
- match def.kind with
- | Struct _ -> Some Struct
- | Enum _ -> Some Enum
- | Opaque -> None
- else None
- in
- (* If in Coq and the declaration is opaque, it must have the shape:
- [Axiom Ident : forall (T0 ... Tn : Type) (N0 : ...) ... (Nn : ...), ... -> ... -> ...].
-
- The boolean [is_opaque_coq] is used to detect this case.
- *)
- let is_opaque = type_kind = None in
- let is_opaque_coq = !backend = Coq && is_opaque in
- let use_forall =
- is_opaque_coq && (def.type_params <> [] || def.const_generic_params <> [])
- in
- (* Retrieve the definition name *)
- let with_opaque_pre = false in
- let def_name = ctx_get_local_type with_opaque_pre def.def_id ctx in
- (* Add the type and const generic params - note that we need those bindings only for the
- * body translation (they are not top-level) *)
- let ctx_body, type_params, cg_params =
- ctx_add_type_const_generic_params def.type_params def.const_generic_params
- ctx
- in
- let ty_cg_params = List.append type_params cg_params in
- (* Add a break before *)
- if !backend <> HOL4 || not (decl_is_first_from_group kind) then
- F.pp_print_break fmt 0 0;
- (* Print a comment to link the extracted type to its original rust definition *)
- extract_comment fmt [ "[" ^ Print.name_to_string def.name ^ "]" ];
- F.pp_print_break fmt 0 0;
- (* Open a box for the definition, so that whenever possible it gets printed on
- * one line. Note however that in the case of Lean line breaks are important
- * for parsing: we thus use a hovbox. *)
- (match !backend with
- | Coq | FStar | HOL4 -> F.pp_open_hvbox fmt 0
- | Lean -> F.pp_open_vbox fmt 0);
- (* Open a box for "type TYPE_NAME (TYPE_PARAMS CONST_GEN_PARAMS) =" *)
- F.pp_open_hovbox fmt ctx.indent_incr;
- (* > "type TYPE_NAME" *)
- let qualif = ctx.fmt.type_decl_kind_to_qualif kind type_kind in
- (match qualif with
- | Some qualif -> F.pp_print_string fmt (qualif ^ " " ^ def_name)
- | None -> F.pp_print_string fmt def_name);
- (* HOL4 doesn't support const generics *)
- assert (cg_params = [] || !backend <> HOL4);
- (* Print the type/const generic parameters *)
- if ty_cg_params <> [] && !backend <> HOL4 then (
- if use_forall then (
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- F.pp_print_string fmt "forall");
- (* Print the type parameters *)
- if type_params <> [] then (
- F.pp_print_space fmt ();
- F.pp_print_string fmt "(";
- List.iter
- (fun s ->
- F.pp_print_string fmt s;
- F.pp_print_space fmt ())
- type_params;
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- F.pp_print_string fmt (type_keyword () ^ ")"));
- (* Print the const generic parameters *)
- List.iter
- (fun (var : const_generic_var) ->
- F.pp_print_space fmt ();
- F.pp_print_string fmt "(";
- let n = ctx_get_const_generic_var var.index ctx in
- F.pp_print_string fmt n;
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- extract_literal_type ctx fmt var.ty;
- F.pp_print_string fmt ")")
- def.const_generic_params);
- (* Print the "=" if we extract the body*)
- if extract_body then (
- F.pp_print_space fmt ();
- let eq =
- match !backend with
- | FStar -> "="
- | Coq -> ":="
- | Lean ->
- if type_kind = Some Struct && kind = SingleNonRec then "where"
- else ":="
- | HOL4 -> "="
- in
- F.pp_print_string fmt eq)
- else (
- (* Otherwise print ": Type", unless it is the HOL4 backend (in
- which case we declare the type with `new_type`) *)
- if use_forall then F.pp_print_string fmt ","
- else (
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":");
- F.pp_print_space fmt ();
- F.pp_print_string fmt (type_keyword ()));
- (* Close the box for "type TYPE_NAME (TYPE_PARAMS) =" *)
- F.pp_close_box fmt ();
- (if extract_body then
- match def.kind with
- | Struct fields ->
- extract_type_decl_struct_body ctx_body fmt type_decl_group kind def
- type_params cg_params fields
- | Enum variants ->
- extract_type_decl_enum_body ctx_body fmt type_decl_group def def_name
- type_params cg_params variants
- | Opaque -> raise (Failure "Unreachable"));
- (* Add the definition end delimiter *)
- if !backend = HOL4 && decl_is_not_last_from_group kind then (
- F.pp_print_space fmt ();
- F.pp_print_string fmt ";")
- else if !backend = Coq && decl_is_last_from_group kind then (
- (* This is actually an end of group delimiter. For aesthetic reasons
- we print it here instead of in {!end_type_decl_group}. *)
- F.pp_print_cut fmt ();
- F.pp_print_string fmt ".");
- (* Close the box for the definition *)
- F.pp_close_box fmt ();
- (* Add breaks to insert new lines between definitions *)
- if !backend <> HOL4 || decl_is_not_last_from_group kind then
- F.pp_print_break fmt 0 0
-
-(** Extract an opaque type declaration to HOL4.
-
- Remark (SH): having to treat this specific case separately is very annoying,
- but I could not find a better way.
- *)
-let extract_type_decl_hol4_opaque (ctx : extraction_ctx) (fmt : F.formatter)
- (def : type_decl) : unit =
- (* Retrieve the definition name *)
- let with_opaque_pre = false in
- let def_name = ctx_get_local_type with_opaque_pre def.def_id ctx in
- (* Generic parameters are unsupported *)
- assert (def.const_generic_params = []);
- (* Count the number of parameters *)
- let num_params = List.length def.type_params in
- (* Generate the declaration *)
- F.pp_print_space fmt ();
- F.pp_print_string fmt
- ("val _ = new_type (\"" ^ def_name ^ "\", " ^ string_of_int num_params ^ ")");
- F.pp_print_space fmt ()
-
-(** Extract an empty record type declaration to HOL4.
-
- Empty records are not supported in HOL4, so we extract them as type
- abbreviations to the unit type.
-
- Remark (SH): having to treat this specific case separately is very annoying,
- but I could not find a better way.
- *)
-let extract_type_decl_hol4_empty_record (ctx : extraction_ctx)
- (fmt : F.formatter) (def : type_decl) : unit =
- (* Retrieve the definition name *)
- let with_opaque_pre = false in
- let def_name = ctx_get_local_type with_opaque_pre def.def_id ctx in
- (* Sanity check *)
- assert (def.type_params = []);
- assert (def.const_generic_params = []);
- (* Generate the declaration *)
- F.pp_print_space fmt ();
- F.pp_print_string fmt ("Type " ^ def_name ^ " = “: unit”");
- F.pp_print_space fmt ()
-
-(** Extract a type declaration.
-
- Note that all the names used for extraction should already have been
- registered.
-
- This function should be inserted between calls to {!start_type_decl_group}
- and {!end_type_decl_group}.
- *)
-let extract_type_decl (ctx : extraction_ctx) (fmt : F.formatter)
- (type_decl_group : TypeDeclId.Set.t) (kind : decl_kind) (def : type_decl) :
- unit =
- let extract_body =
- match kind with
- | SingleNonRec | SingleRec | MutRecFirst | MutRecInner | MutRecLast -> true
- | Assumed | Declared -> false
- in
- if extract_body then
- if !backend = HOL4 && is_empty_record_type_decl def then
- extract_type_decl_hol4_empty_record ctx fmt def
- else extract_type_decl_gen ctx fmt type_decl_group kind def extract_body
- else
- match !backend with
- | FStar | Coq | Lean ->
- extract_type_decl_gen ctx fmt type_decl_group kind def extract_body
- | HOL4 -> extract_type_decl_hol4_opaque ctx fmt def
-
-(** Auxiliary function.
-
- Generate [Arguments] instructions in Coq.
- *)
-let extract_type_decl_coq_arguments (ctx : extraction_ctx) (fmt : F.formatter)
- (kind : decl_kind) (decl : type_decl) : unit =
- assert (!backend = Coq);
- (* Generating the [Arguments] instructions is useful only if there are type parameters *)
- if decl.type_params = [] && decl.const_generic_params = [] then ()
- else
- (* Add the type params - note that we need those bindings only for the
- * body translation (they are not top-level) *)
- let _ctx_body, type_params, cg_params =
- ctx_add_type_const_generic_params decl.type_params
- decl.const_generic_params ctx
- in
- (* Auxiliary function to extract an [Arguments Cons {T} _ _.] instruction *)
- let extract_arguments_info (cons_name : string) (fields : 'a list) : unit =
- (* Add a break before *)
- F.pp_print_break fmt 0 0;
- (* Open a box *)
- F.pp_open_hovbox fmt ctx.indent_incr;
- (* Small utility *)
- let print_vars () =
- List.iter
- (fun (var : string) ->
- F.pp_print_space fmt ();
- F.pp_print_string fmt ("{" ^ var ^ "}"))
- (List.append type_params cg_params)
- in
- let print_fields () =
- List.iter
- (fun _ ->
- F.pp_print_space fmt ();
- F.pp_print_string fmt "_")
- fields
- in
- F.pp_print_break fmt 0 0;
- F.pp_print_string fmt "Arguments";
- F.pp_print_space fmt ();
- F.pp_print_string fmt cons_name;
- print_vars ();
- print_fields ();
- F.pp_print_string fmt ".";
-
- (* Close the box *)
- F.pp_close_box fmt ()
- in
-
- (* Generate the [Arguments] instruction *)
- match decl.kind with
- | Opaque -> ()
- | Struct fields ->
- let adt_id = AdtId decl.def_id in
- (* Generate the instruction for the record constructor *)
- let with_opaque_pre = false in
- let cons_name = ctx_get_struct with_opaque_pre adt_id ctx in
- extract_arguments_info cons_name fields;
- (* Generate the instruction for the record projectors, if there are *)
- let is_rec = decl_is_from_rec_group kind in
- if not is_rec then
- FieldId.iteri
- (fun fid _ ->
- let cons_name = ctx_get_field adt_id fid ctx in
- extract_arguments_info cons_name [])
- fields;
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0
- | Enum variants ->
- (* Generate the instructions *)
- VariantId.iteri
- (fun vid (v : variant) ->
- let cons_name = ctx_get_variant (AdtId decl.def_id) vid ctx in
- extract_arguments_info cons_name v.fields)
- variants;
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0
-
-(** Auxiliary function.
-
- Generate field projectors in Coq.
-
- Sometimes we extract records as inductives in Coq: when this happens we
- have to define the field projectors afterwards.
- *)
-let extract_type_decl_record_field_projectors (ctx : extraction_ctx)
- (fmt : F.formatter) (kind : decl_kind) (decl : type_decl) : unit =
- assert (!backend = Coq);
- match decl.kind with
- | Opaque | Enum _ -> ()
- | Struct fields ->
- (* Records are extracted as inductives only if they are recursive *)
- let is_rec = decl_is_from_rec_group kind in
- if is_rec then
- (* Add the type params *)
- let ctx, type_params, cg_params =
- ctx_add_type_const_generic_params decl.type_params
- decl.const_generic_params ctx
- in
- let ctx, record_var = ctx_add_var "x" (VarId.of_int 0) ctx in
- let ctx, field_var = ctx_add_var "x" (VarId.of_int 1) ctx in
- let with_opaque_pre = false in
- let def_name = ctx_get_local_type with_opaque_pre decl.def_id ctx in
- let cons_name =
- ctx_get_struct with_opaque_pre (AdtId decl.def_id) ctx
- in
- let extract_field_proj (field_id : FieldId.id) (_ : field) : unit =
- F.pp_print_space fmt ();
- (* Outer box for the projector definition *)
- F.pp_open_hvbox fmt 0;
- (* Inner box for the projector definition *)
- F.pp_open_hvbox fmt ctx.indent_incr;
- (* Open a box for the [Definition PROJ ... :=] *)
- F.pp_open_hovbox fmt ctx.indent_incr;
- F.pp_print_string fmt "Definition";
- F.pp_print_space fmt ();
- let field_name = ctx_get_field (AdtId decl.def_id) field_id ctx in
- F.pp_print_string fmt field_name;
- F.pp_print_space fmt ();
- (* Print the type parameters *)
- if type_params <> [] then (
- F.pp_print_string fmt "{";
- List.iter
- (fun p ->
- F.pp_print_string fmt p;
- F.pp_print_space fmt ())
- type_params;
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- F.pp_print_string fmt "Type}";
- F.pp_print_space fmt ());
- (* Print the const generic parameters *)
- if cg_params <> [] then
- List.iter
- (fun (v : const_generic_var) ->
- F.pp_print_string fmt "{";
- let n = ctx_get_const_generic_var v.index ctx in
- F.pp_print_string fmt n;
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- extract_literal_type ctx fmt v.ty;
- F.pp_print_string fmt "}";
- F.pp_print_space fmt ())
- decl.const_generic_params;
- (* Print the record parameter *)
- F.pp_print_string fmt "(";
- F.pp_print_string fmt record_var;
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- F.pp_print_string fmt def_name;
- List.iter
- (fun p ->
- F.pp_print_space fmt ();
- F.pp_print_string fmt p)
- type_params;
- F.pp_print_string fmt ")";
- (* *)
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":=";
- (* Close the box for the [Definition PROJ ... :=] *)
- F.pp_close_box fmt ();
- F.pp_print_space fmt ();
- (* Open a box for the whole match *)
- F.pp_open_hvbox fmt 0;
- (* Open a box for the [match ... with] *)
- F.pp_open_hovbox fmt ctx.indent_incr;
- F.pp_print_string fmt "match";
- F.pp_print_space fmt ();
- F.pp_print_string fmt record_var;
- F.pp_print_space fmt ();
- F.pp_print_string fmt "with";
- (* Close the box for the [match ... with] *)
- F.pp_close_box fmt ();
-
- (* Open a box for the branch *)
- F.pp_open_hovbox fmt ctx.indent_incr;
- (* Print the match branch *)
- F.pp_print_space fmt ();
- F.pp_print_string fmt "|";
- F.pp_print_space fmt ();
- F.pp_print_string fmt cons_name;
- FieldId.iteri
- (fun id _ ->
- F.pp_print_space fmt ();
- if field_id = id then F.pp_print_string fmt field_var
- else F.pp_print_string fmt "_")
- fields;
- F.pp_print_space fmt ();
- F.pp_print_string fmt "=>";
- F.pp_print_space fmt ();
- F.pp_print_string fmt field_var;
- (* Close the box for the branch *)
- F.pp_close_box fmt ();
- (* Print the [end] *)
- F.pp_print_space fmt ();
- F.pp_print_string fmt "end";
- (* Close the box for the whole match *)
- F.pp_close_box fmt ();
- (* Close the inner box projector *)
- F.pp_close_box fmt ();
- (* If Coq: end the definition with a "." *)
- if !backend = Coq then (
- F.pp_print_cut fmt ();
- F.pp_print_string fmt ".");
- (* Close the outer box projector *)
- F.pp_close_box fmt ();
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0
- in
-
- let extract_proj_notation (field_id : FieldId.id) (_ : field) : unit =
- F.pp_print_space fmt ();
- (* Outer box for the projector definition *)
- F.pp_open_hvbox fmt 0;
- (* Inner box for the projector definition *)
- F.pp_open_hovbox fmt ctx.indent_incr;
- let ctx, record_var = ctx_add_var "x" (VarId.of_int 0) ctx in
- F.pp_print_string fmt "Notation";
- F.pp_print_space fmt ();
- let field_name = ctx_get_field (AdtId decl.def_id) field_id ctx in
- F.pp_print_string fmt ("\"" ^ record_var ^ " .(" ^ field_name ^ ")\"");
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":=";
- F.pp_print_space fmt ();
- F.pp_print_string fmt "(";
- F.pp_print_string fmt field_name;
- F.pp_print_space fmt ();
- F.pp_print_string fmt record_var;
- F.pp_print_string fmt ")";
- F.pp_print_space fmt ();
- F.pp_print_string fmt "(at level 9)";
- (* Close the inner box projector *)
- F.pp_close_box fmt ();
- (* If Coq: end the definition with a "." *)
- if !backend = Coq then (
- F.pp_print_cut fmt ();
- F.pp_print_string fmt ".");
- (* Close the outer box projector *)
- F.pp_close_box fmt ();
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0
- in
-
- let extract_field_proj_and_notation (field_id : FieldId.id)
- (field : field) : unit =
- extract_field_proj field_id field;
- extract_proj_notation field_id field
- in
-
- FieldId.iteri extract_field_proj_and_notation fields
-
-(** Extract extra information for a type (e.g., [Arguments] instructions in Coq).
-
- Note that all the names used for extraction should already have been
- registered.
- *)
-let extract_type_decl_extra_info (ctx : extraction_ctx) (fmt : F.formatter)
- (kind : decl_kind) (decl : type_decl) : unit =
- match !backend with
- | FStar | Lean | HOL4 -> ()
- | Coq ->
- extract_type_decl_coq_arguments ctx fmt kind decl;
- extract_type_decl_record_field_projectors ctx fmt kind decl
-
-(** Extract the state type declaration. *)
-let extract_state_type (fmt : F.formatter) (ctx : extraction_ctx)
- (kind : decl_kind) : unit =
- (* Add a break before *)
- F.pp_print_break fmt 0 0;
- (* Print a comment *)
- extract_comment fmt [ "The state type used in the state-error monad" ];
- F.pp_print_break fmt 0 0;
- (* Open a box for the definition, so that whenever possible it gets printed on
- * one line *)
- F.pp_open_hvbox fmt 0;
- (* Retrieve the name *)
- let state_name = ctx_get_assumed_type State ctx in
- (* The syntax for Lean and Coq is almost identical. *)
- let print_axiom () =
- let axiom =
- match !backend with
- | Coq -> "Axiom"
- | Lean -> "axiom"
- | FStar | HOL4 -> raise (Failure "Unexpected")
- in
- F.pp_print_string fmt axiom;
- F.pp_print_space fmt ();
- F.pp_print_string fmt state_name;
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- F.pp_print_string fmt "Type";
- if !backend = Coq then F.pp_print_string fmt "."
- in
- (* The kind should be [Assumed] or [Declared] *)
- (match kind with
- | SingleNonRec | SingleRec | MutRecFirst | MutRecInner | MutRecLast ->
- raise (Failure "Unexpected")
- | Assumed -> (
- match !backend with
- | FStar ->
- F.pp_print_string fmt "assume";
- F.pp_print_space fmt ();
- F.pp_print_string fmt "type";
- F.pp_print_space fmt ();
- F.pp_print_string fmt state_name;
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- F.pp_print_string fmt "Type0"
- | HOL4 ->
- F.pp_print_string fmt ("val _ = new_type (\"" ^ state_name ^ "\", 0)")
- | Coq | Lean -> print_axiom ())
- | Declared -> (
- match !backend with
- | FStar ->
- F.pp_print_string fmt "val";
- F.pp_print_space fmt ();
- F.pp_print_string fmt state_name;
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- F.pp_print_string fmt "Type0"
- | HOL4 ->
- F.pp_print_string fmt ("val _ = new_type (\"" ^ state_name ^ "\", 0)")
- | Coq | Lean -> print_axiom ()));
- (* Close the box for the definition *)
- F.pp_close_box fmt ();
- (* Add breaks to insert new lines between definitions *)
- F.pp_print_break fmt 0 0
+include ExtractTypes
(** Compute the names for all the pure functions generated from a rust function
(forward function and backward functions).
*)
-let extract_fun_decl_register_names (ctx : extraction_ctx) (keep_fwd : bool)
+let extract_fun_decl_register_names (ctx : extraction_ctx)
(has_decreases_clause : fun_decl -> bool) (def : pure_fun_translation) :
extraction_ctx =
- let (fwd, loop_fwds), back_ls = def in
- (* Register the decrease clauses, if necessary *)
- let register_decreases ctx def =
- if has_decreases_clause def then
- (* Add the termination measure *)
- let ctx = ctx_add_termination_measure def ctx in
- (* Add the decreases proof for Lean only *)
- match !Config.backend with
- | Coq | FStar -> ctx
- | HOL4 -> raise (Failure "Unexpected")
- | Lean -> ctx_add_decreases_proof def ctx
- else ctx
- in
- let ctx = List.fold_left register_decreases ctx (fwd :: loop_fwds) in
- let register_fun ctx f = ctx_add_fun_decl (keep_fwd, def) f ctx in
- let register_funs ctx fl = List.fold_left register_fun ctx fl in
- (* Register the forward functions' names *)
- let ctx = register_funs ctx (fwd :: loop_fwds) in
- (* Register the backward functions' names *)
- let ctx =
- List.fold_left
- (fun ctx (back, loop_backs) ->
- let ctx = register_fun ctx back in
- register_funs ctx loop_backs)
- ctx back_ls
- in
-
- (* Return *)
- ctx
+ (* Ignore the trait methods **declarations** (rem.: we do not ignore the trait
+ method implementations): we do not need to refer to them directly. We will
+ only use their type for the fields of the records we generate for the trait
+ declarations *)
+ match def.fwd.f.kind with
+ | TraitMethodDecl _ -> ctx
+ | _ -> (
+ (* Check if the function is builtin *)
+ let builtin =
+ let open ExtractBuiltin in
+ let funs_map = builtin_funs_map () in
+ let sname = name_to_simple_name def.fwd.f.basename in
+ SimpleNameMap.find_opt sname funs_map
+ in
+ (* Use the builtin names if necessary *)
+ match builtin with
+ | Some (filter_info, info) ->
+ (* Register the filtering information, if there is *)
+ let ctx =
+ match filter_info with
+ | Some keep ->
+ {
+ ctx with
+ funs_filter_type_args_map =
+ FunDeclId.Map.add def.fwd.f.def_id keep
+ ctx.funs_filter_type_args_map;
+ }
+ | _ -> ctx
+ in
+ let backs = List.map (fun f -> f.f) def.backs in
+ let funs = if def.keep_fwd then def.fwd.f :: backs else backs in
+ List.fold_left
+ (fun ctx (f : fun_decl) ->
+ let open ExtractBuiltin in
+ let fun_id =
+ (Pure.FunId (Regular f.def_id), f.loop_id, f.back_id)
+ in
+ let fun_info =
+ List.find_opt
+ (fun (x : builtin_fun_info) -> x.rg = f.back_id)
+ info
+ in
+ match fun_info with
+ | Some fun_info ->
+ ctx_add (FunId (FromLlbc fun_id)) fun_info.extract_name ctx
+ | None ->
+ raise
+ (Failure
+ ("Not found: "
+ ^ Names.name_to_string f.basename
+ ^ ", "
+ ^ Print.option_to_string Pure.show_loop_id f.loop_id
+ ^ Print.option_to_string Pure.show_region_group_id
+ f.back_id)))
+ ctx funs
+ | None ->
+ let fwd = def.fwd in
+ let backs = def.backs in
+ (* Register the decrease clauses, if necessary *)
+ let register_decreases ctx def =
+ if has_decreases_clause def then
+ (* Add the termination measure *)
+ let ctx = ctx_add_termination_measure def ctx in
+ (* Add the decreases proof for Lean only *)
+ match !Config.backend with
+ | Coq | FStar -> ctx
+ | HOL4 -> raise (Failure "Unexpected")
+ | Lean -> ctx_add_decreases_proof def ctx
+ else ctx
+ in
+ let ctx =
+ List.fold_left register_decreases ctx (fwd.f :: fwd.loops)
+ in
+ let register_fun ctx f = ctx_add_fun_decl def f ctx in
+ let register_funs ctx fl = List.fold_left register_fun ctx fl in
+ (* Register the names of the forward functions *)
+ let ctx =
+ if def.keep_fwd then register_funs ctx (fwd.f :: fwd.loops) else ctx
+ in
+ (* Register the names of the backward functions *)
+ List.fold_left
+ (fun ctx { f = back; loops = loop_backs } ->
+ let ctx = register_fun ctx back in
+ register_funs ctx loop_backs)
+ ctx backs)
(** Simply add the global name to the context. *)
let extract_global_decl_register_names (ctx : extraction_ctx)
@@ -2122,11 +124,11 @@ let extract_adt_g_value
(inside : bool) (variant_id : VariantId.id option) (field_values : 'v list)
(ty : ty) : extraction_ctx =
match ty with
- | Adt (Tuple, type_args, cg_args) ->
+ | Adt (Tuple, generics) ->
(* Tuple *)
(* For now, we only support fully applied tuple constructors *)
- assert (List.length type_args = List.length field_values);
- assert (cg_args = []);
+ assert (List.length generics.types = List.length field_values);
+ assert (generics.const_generics = [] && generics.trait_refs = []);
(* This is very annoying: in Coq, we can't write [()] for the value of
type [unit], we have to write [tt]. *)
if !backend = Coq && field_values = [] then (
@@ -2144,7 +146,7 @@ let extract_adt_g_value
in
F.pp_print_string fmt ")";
ctx)
- | Adt (adt_id, _, _) ->
+ | Adt (adt_id, _) ->
(* "Regular" ADT *)
(* If we are generating a pattern for a let-binding and we target Lean,
@@ -2172,18 +174,14 @@ let extract_adt_g_value
* [{ field0=...; ...; fieldn=...; }] in case of structures.
*)
let cons =
- (* The ADT shouldn't be opaque *)
- let with_opaque_pre = false in
match variant_id with
| Some vid -> (
(* In the case of Lean, we might have to add the type name as a prefix *)
match (!backend, adt_id) with
| Lean, Assumed _ ->
- ctx_get_type with_opaque_pre adt_id ctx
- ^ "."
- ^ ctx_get_variant adt_id vid ctx
+ ctx_get_type adt_id ctx ^ "." ^ ctx_get_variant adt_id vid ctx
| _ -> ctx_get_variant adt_id vid ctx)
- | None -> ctx_get_struct with_opaque_pre adt_id ctx
+ | None -> ctx_get_struct adt_id ctx
in
let use_parentheses = inside && field_values <> [] in
if use_parentheses then F.pp_print_string fmt "(";
@@ -2202,8 +200,33 @@ let extract_adt_g_value
(* Extract globals in the same way as variables *)
let extract_global (ctx : extraction_ctx) (fmt : F.formatter)
(id : A.GlobalDeclId.id) : unit =
- let with_opaque_pre = ctx.use_opaque_pre in
- F.pp_print_string fmt (ctx_get_global with_opaque_pre id ctx)
+ F.pp_print_string fmt (ctx_get_global id ctx)
+
+(* Filter the generics of a function if it is builtin *)
+let fun_builtin_filter_types (id : FunDeclId.id) (types : 'a list)
+ (ctx : extraction_ctx) : ('a list, 'a list * string) Result.result =
+ match FunDeclId.Map.find_opt id ctx.funs_filter_type_args_map with
+ | None -> Result.Ok types
+ | Some filter ->
+ if List.length filter <> List.length types then (
+ let decl = FunDeclId.Map.find id ctx.trans_funs in
+ let err =
+ "Ill-formed builtin information for function "
+ ^ Names.name_to_string decl.fwd.f.basename
+ ^ ": "
+ ^ string_of_int (List.length filter)
+ ^ " filtering arguments provided for "
+ ^ string_of_int (List.length types)
+ ^ " type arguments"
+ in
+ log#serror err;
+ Result.Error (types, err))
+ else
+ let types = List.combine filter types in
+ let types =
+ List.filter_map (fun (b, ty) -> if b then Some ty else None) types
+ in
+ Result.Ok types
(** [inside]: see {!extract_ty}.
@@ -2218,7 +241,7 @@ let rec extract_typed_pattern (ctx : extraction_ctx) (fmt : F.formatter)
ctx
| PatVar (v, _) ->
let vname =
- ctx.fmt.var_basename ctx.names_map.names_set v.basename v.ty
+ ctx.fmt.var_basename ctx.names_maps.names_map.names_set v.basename v.ty
in
let ctx, vname = ctx_add_var vname v.id ctx in
F.pp_print_string fmt vname;
@@ -2249,6 +272,9 @@ let rec extract_texpression (ctx : extraction_ctx) (fmt : F.formatter)
| Var var_id ->
let var_name = ctx_get_var var_id ctx in
F.pp_print_string fmt var_name
+ | CVar var_id ->
+ let var_name = ctx_get_const_generic_var var_id ctx in
+ F.pp_print_string fmt var_name
| Const cv -> ctx.fmt.extract_literal fmt inside cv
| App _ ->
let app, args = destruct_apps e in
@@ -2279,14 +305,26 @@ and extract_App (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool)
(* Top-level qualifier *)
match qualif.id with
| FunOrOp fun_id ->
- extract_function_call ctx fmt inside fun_id qualif.type_args
- qualif.const_generic_args args
+ extract_function_call ctx fmt inside fun_id qualif.generics args
| Global global_id -> extract_global ctx fmt global_id
| AdtCons adt_cons_id ->
- extract_adt_cons ctx fmt inside adt_cons_id qualif.type_args
- qualif.const_generic_args args
+ extract_adt_cons ctx fmt inside adt_cons_id qualif.generics args
| Proj proj ->
- extract_field_projector ctx fmt inside app proj qualif.type_args args)
+ extract_field_projector ctx fmt inside app proj qualif.generics args
+ | TraitConst (trait_ref, generics, const_name) ->
+ let use_brackets = generics <> empty_generic_args in
+ if use_brackets then F.pp_print_string fmt "(";
+ extract_trait_ref ctx fmt TypeDeclId.Set.empty false trait_ref;
+ extract_generic_args ctx fmt TypeDeclId.Set.empty generics;
+ let name =
+ ctx_get_trait_const trait_ref.trait_decl_ref.trait_decl_id
+ const_name ctx
+ in
+ let add_brackets (s : string) =
+ if !backend = Coq then "(" ^ s ^ ")" else s
+ in
+ if use_brackets then F.pp_print_string fmt ")";
+ F.pp_print_string fmt ("." ^ add_brackets name))
| _ ->
(* "Regular" expression *)
(* Open parentheses *)
@@ -2309,8 +347,8 @@ and extract_App (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool)
(** Subcase of the app case: function call *)
and extract_function_call (ctx : extraction_ctx) (fmt : F.formatter)
- (inside : bool) (fid : fun_or_op_id) (type_args : ty list)
- (cg_args : const_generic list) (args : texpression list) : unit =
+ (inside : bool) (fid : fun_or_op_id) (generics : generic_args)
+ (args : texpression list) : unit =
match (fid, args) with
| Unop unop, [ arg ] ->
(* A unop can have *at most* one argument (the result can't be a function!).
@@ -2327,24 +365,124 @@ and extract_function_call (ctx : extraction_ctx) (fmt : F.formatter)
if inside then F.pp_print_string fmt "(";
(* Open a box for the function call *)
F.pp_open_hovbox fmt ctx.indent_incr;
- (* Print the function name *)
- let with_opaque_pre = ctx.use_opaque_pre in
- let fun_name = ctx_get_function with_opaque_pre fun_id ctx in
- F.pp_print_string fmt fun_name;
- (* Sanity check: HOL4 doesn't support const generics *)
- assert (cg_args = [] || !backend <> HOL4);
- (* Print the type parameters, if the backend is not HOL4 *)
- if !backend <> HOL4 then (
- List.iter
- (fun ty ->
- F.pp_print_space fmt ();
- extract_ty ctx fmt TypeDeclId.Set.empty true ty)
- type_args;
- List.iter
- (fun cg ->
+ (* Print the function name.
+
+ For the function name: the id is not the same depending on whether
+ we call a trait method and a "regular" function (remark: trait
+ method *implementations* are considered as regular functions here;
+ only calls to method of traits which are parameterized in a where
+ clause have a special treatment.
+
+ Remark: the reason why trait method declarations have a special
+ treatment is that, as traits are extracted to records, we may
+ allow collisions between trait item names and some other names,
+ while we do not allow collisions between function names.
+
+ # Impl trait refs:
+ ==================
+ When the trait ref refers to an impl, in
+ [InterpreterStatement.eval_transparent_function_call_symbolic] we
+ replace the call to the trait impl method to a call to the function
+ which implements the trait method (that is, we "forget" that we
+ called a trait method, and treat it as a regular function call).
+
+ # Provided trait methods:
+ =========================
+ Calls to provided trait methods also have a special treatment.
+ For now, we do not allow overriding provided trait methods (methods
+ for which a default implementation is provided in the trait declaration).
+ Whenever we translate a provided trait method, we translate it once as
+ a function which takes a trait ref as input. We have to handle this
+ case below.
+
+ With an example, if in Rust we write:
+ {[
+ fn Foo {
+ fn f(&self) -> u32; // Required
+ fn ret_true(&self) -> bool { true } // Provided
+ }
+ ]}
+
+ We generate:
+ {[
+ structure Foo (Self : Type) = {
+ f : Self -> result u32
+ }
+
+ let ret_true (Self : Type) (self_clause : Foo Self) (self : Self) : result bool =
+ true
+ ]}
+ *)
+ (match fun_id with
+ | FromLlbc
+ (TraitMethod (trait_ref, method_name, _fun_decl_id), lp_id, rg_id) ->
+ (* We have to check whether the trait method is required or provided *)
+ let trait_decl_id = trait_ref.trait_decl_ref.trait_decl_id in
+ let trait_decl =
+ TraitDeclId.Map.find trait_decl_id ctx.trans_trait_decls
+ in
+ let method_id =
+ PureUtils.trait_decl_get_method trait_decl method_name
+ in
+
+ if not method_id.is_provided then (
+ (* Required method *)
+ assert (lp_id = None);
+ extract_trait_ref ctx fmt TypeDeclId.Set.empty true trait_ref;
+ let fun_name =
+ ctx_get_trait_method trait_ref.trait_decl_ref.trait_decl_id
+ method_name rg_id ctx
+ in
+ let add_brackets (s : string) =
+ if !backend = Coq then "(" ^ s ^ ")" else s
+ in
+ F.pp_print_string fmt ("." ^ add_brackets fun_name))
+ else
+ (* Provided method: we see it as a regular function call, and use
+ the function name *)
+ let fun_id =
+ FromLlbc (FunId (Regular method_id.id), lp_id, rg_id)
+ in
+ let fun_name = ctx_get_function fun_id ctx in
+ F.pp_print_string fmt fun_name;
+
+ (* Note that we do not need to print the generics for the trait
+ declaration: they are always implicit as they can be deduced
+ from the trait self clause.
+
+ Print the trait ref (to instantate the self clause) *)
F.pp_print_space fmt ();
- extract_const_generic ctx fmt true cg)
- cg_args);
+ extract_trait_ref ctx fmt TypeDeclId.Set.empty true trait_ref
+ | _ ->
+ let fun_name = ctx_get_function fun_id ctx in
+ F.pp_print_string fmt fun_name);
+
+ (* Sanity check: HOL4 doesn't support const generics *)
+ assert (generics.const_generics = [] || !backend <> HOL4);
+ (* Print the generics.
+
+ We might need to filter some of the type arguments, if the type
+ is builtin (for instance, we filter the global allocator type
+ argument for `Vec::new`).
+ *)
+ let types =
+ match fun_id with
+ | FromLlbc (FunId (Regular id), _, _) ->
+ fun_builtin_filter_types id generics.types ctx
+ | _ -> Result.Ok generics.types
+ in
+ (match types with
+ | Ok types ->
+ extract_generic_args ctx fmt TypeDeclId.Set.empty
+ { generics with types }
+ | Error (types, err) ->
+ extract_generic_args ctx fmt TypeDeclId.Set.empty
+ { generics with types };
+ if !Config.fail_hard then raise (Failure err)
+ else
+ F.pp_print_string fmt
+ "(\"ERROR: ill-formed builtin: invalid number of filtering \
+ arguments\")");
(* Print the arguments *)
List.iter
(fun ve ->
@@ -2366,9 +504,9 @@ and extract_function_call (ctx : extraction_ctx) (fmt : F.formatter)
(** Subcase of the app case: ADT constructor *)
and extract_adt_cons (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool)
- (adt_cons : adt_cons_id) (type_args : ty list)
- (cg_args : const_generic list) (args : texpression list) : unit =
- let e_ty = Adt (adt_cons.adt_id, type_args, cg_args) in
+ (adt_cons : adt_cons_id) (generics : generic_args) (args : texpression list)
+ : unit =
+ let e_ty = Adt (adt_cons.adt_id, generics) in
let is_single_pat = false in
let _ =
extract_adt_g_value
@@ -2382,7 +520,7 @@ and extract_adt_cons (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool)
(** Subcase of the app case: ADT field projector. *)
and extract_field_projector (ctx : extraction_ctx) (fmt : F.formatter)
(inside : bool) (original_app : texpression) (proj : projection)
- (_proj_type_params : ty list) (args : texpression list) : unit =
+ (_generics : generic_args) (args : texpression list) : unit =
(* We isolate the first argument (if there is), in order to pretty print the
* projection ([x.field] instead of [MkAdt?.field x] *)
match args with
@@ -2734,9 +872,7 @@ and extract_StructUpdate (ctx : extraction_ctx) (fmt : F.formatter)
let extract_as_unit =
match (!backend, supd.struct_id) with
| HOL4, AdtId adt_id ->
- let d =
- TypeDeclId.Map.find adt_id ctx.trans_ctx.type_context.type_decls
- in
+ let d = TypeDeclId.Map.find adt_id ctx.trans_ctx.type_ctx.type_decls in
d.kind = Struct []
| _ -> false
in
@@ -2835,17 +971,17 @@ and extract_StructUpdate (ctx : extraction_ctx) (fmt : F.formatter)
F.pp_open_hvbox fmt ctx.indent_incr;
let need_paren = inside in
if need_paren then F.pp_print_string fmt "(";
- (* Open the box for `Array.mk T N [` *)
+ (* Open the box for `Array.replicate T N [` *)
F.pp_open_hovbox fmt ctx.indent_incr;
(* Print the array constructor *)
- let cs = ctx_get_struct false (Assumed Array) ctx in
+ let cs = ctx_get_struct (Assumed Array) ctx in
F.pp_print_string fmt cs;
(* Print the parameters *)
- let _, tys, cgs = ty_as_adt e_ty in
- let ty = Collections.List.to_cons_nil tys in
+ let _, generics = ty_as_adt e_ty in
+ let ty = Collections.List.to_cons_nil generics.types in
F.pp_print_space fmt ();
extract_ty ctx fmt TypeDeclId.Set.empty true ty;
- let cg = Collections.List.to_cons_nil cgs in
+ let cg = Collections.List.to_cons_nil generics.const_generics in
F.pp_print_space fmt ();
extract_const_generic ctx fmt true cg;
F.pp_print_space fmt ();
@@ -2872,17 +1008,15 @@ and extract_StructUpdate (ctx : extraction_ctx) (fmt : F.formatter)
F.pp_close_box fmt ()
| _ -> raise (Failure "Unreachable")
-(** Insert a space, if necessary *)
-let insert_req_space (fmt : F.formatter) (space : bool ref) : unit =
- if !space then space := false else F.pp_print_space fmt ()
-
(** A small utility to print the parameters of a function signature.
We return two contexts:
- - the context augmented with bindings for the type parameters
- - the context augmented with bindings for the type parameters *and*
+ - the context augmented with bindings for the generics
+ - the context augmented with bindings for the generics *and*
bindings for the input values
+ We also return names for the type parameters, const generics, etc.
+
TODO: do we really need the first one? We should probably always use
the second one.
It comes from the fact that when we print the input values for the
@@ -2890,57 +1024,40 @@ let insert_req_space (fmt : F.formatter) (space : bool ref) : unit =
patterns, not the variables). We should figure a cleaner way.
*)
let extract_fun_parameters (space : bool ref) (ctx : extraction_ctx)
- (fmt : F.formatter) (def : fun_decl) : extraction_ctx * extraction_ctx =
+ (fmt : F.formatter) (def : fun_decl) :
+ extraction_ctx * extraction_ctx * string list =
+ (* First, add the associated types and constants if the function is a method
+ in a trait declaration.
+
+ About the order: we want to make sure the names are reserved for
+ those (variable names might collide with them but it is ok, we will add
+ suffixes to the variables).
+
+ TODO: micro-pass to update what happens when calling trait provided
+ functions.
+ *)
+ let ctx, trait_decl =
+ match def.kind with
+ | TraitMethodProvided (decl_id, _) ->
+ let trait_decl = T.TraitDeclId.Map.find decl_id ctx.trans_trait_decls in
+ let ctx, _ = ctx_add_trait_self_clause ctx in
+ let ctx = { ctx with is_provided_method = true } in
+ (ctx, Some trait_decl)
+ | _ -> (ctx, None)
+ in
(* Add the type parameters - note that we need those bindings only for the
* body translation (they are not top-level) *)
- let ctx, type_params, cg_params =
- ctx_add_type_const_generic_params def.signature.type_params
- def.signature.const_generic_params ctx
+ let ctx, type_params, cg_params, trait_clauses =
+ ctx_add_generic_params def.signature.generics ctx
in
- (* Print the parameters - rem.: we should have filtered the functions
- * with no input parameters *)
- (* The type parameters.
-
- Note that in HOL4 we don't print the type parameters.
- *)
- if (type_params <> [] || cg_params <> []) && !backend <> HOL4 then (
- (* Open a box for the type and const generic parameters *)
- F.pp_open_hovbox fmt 0;
- (* The type parameters *)
- if type_params <> [] then (
- insert_req_space fmt space;
- F.pp_print_string fmt "(";
- List.iter
- (fun (p : type_var) ->
- let pname = ctx_get_type_var p.index ctx in
- F.pp_print_string fmt pname;
- F.pp_print_space fmt ())
- def.signature.type_params;
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- let type_keyword =
- match !backend with
- | FStar -> "Type0"
- | Coq | Lean -> "Type"
- | HOL4 -> raise (Failure "Unreachable")
- in
- F.pp_print_string fmt (type_keyword ^ ")"));
- (* The const generic parameters *)
- if cg_params <> [] then
- List.iter
- (fun (p : const_generic_var) ->
- let pname = ctx_get_const_generic_var p.index ctx in
- insert_req_space fmt space;
- F.pp_print_string fmt "(";
- F.pp_print_string fmt pname;
- F.pp_print_space fmt ();
- F.pp_print_string fmt ":";
- F.pp_print_space fmt ();
- extract_literal_type ctx fmt p.ty;
- F.pp_print_string fmt ")")
- def.signature.const_generic_params;
- (* Close the box for the type parameters *)
- F.pp_close_box fmt ());
+ (* Print the generics *)
+ (* Open a box for the generics *)
+ F.pp_open_hovbox fmt 0;
+ (let space = Some space in
+ extract_generic_params ctx fmt TypeDeclId.Set.empty ~space ~trait_decl
+ def.signature.generics type_params cg_params trait_clauses);
+ (* Close the box for the generics *)
+ F.pp_close_box fmt ();
(* The input parameters - note that doing this adds bindings to the context *)
let ctx_body =
match def.body with
@@ -2963,7 +1080,7 @@ let extract_fun_parameters (space : bool ref) (ctx : extraction_ctx)
ctx)
ctx body.inputs_lvs
in
- (ctx, ctx_body)
+ (ctx, ctx_body, List.concat [ type_params; cg_params; trait_clauses ])
(** A small utility to print the types of the input parameters in the form:
[u32 -> list u32 -> ...]
@@ -2982,6 +1099,11 @@ let extract_fun_input_parameters_types (ctx : extraction_ctx)
in
List.iter extract_param def.signature.inputs
+let extract_fun_inputs_output_parameters_types (ctx : extraction_ctx)
+ (fmt : F.formatter) (def : fun_decl) : unit =
+ extract_fun_input_parameters_types ctx fmt def;
+ extract_ty ctx fmt TypeDeclId.Set.empty false def.signature.output
+
let assert_backend_supports_decreases_clauses () =
match !backend with
| FStar | Lean -> ()
@@ -3032,7 +1154,7 @@ let extract_template_fstar_decreases_clause (ctx : extraction_ctx)
F.pp_print_space fmt ();
(* Extract the parameters *)
let space = ref true in
- let _, _ = extract_fun_parameters space ctx fmt def in
+ let _, _, _ = extract_fun_parameters space ctx fmt def in
insert_req_space fmt space;
F.pp_print_string fmt ":";
(* Print the signature *)
@@ -3094,7 +1216,7 @@ let extract_template_lean_termination_and_decreasing (ctx : extraction_ctx)
F.pp_print_space fmt ();
(* Extract the parameters *)
let space = ref true in
- let _, ctx_body = extract_fun_parameters space ctx fmt def in
+ let _, ctx_body, _ = extract_fun_parameters space ctx fmt def in
(* Print the ":=" *)
F.pp_print_space fmt ();
F.pp_print_string fmt ":=";
@@ -3164,7 +1286,7 @@ let extract_fun_comment (ctx : extraction_ctx) (fmt : F.formatter)
(def : fun_decl) : unit =
let { keep_fwd; num_backs } =
PureUtils.RegularFunIdMap.find
- (A.Regular def.def_id, def.loop_id, def.back_id)
+ (Pure.FunId (Regular def.def_id), def.loop_id, def.back_id)
ctx.fun_name_info
in
let comment_pre = "[" ^ Print.fun_name_to_string def.basename ^ "]: " in
@@ -3205,10 +1327,8 @@ let extract_fun_decl_gen (ctx : extraction_ctx) (fmt : F.formatter)
(kind : decl_kind) (has_decreases_clause : bool) (def : fun_decl) : unit =
assert (not def.is_global_decl_body);
(* Retrieve the function name *)
- let with_opaque_pre = false in
let def_name =
- ctx_get_local_function with_opaque_pre def.def_id def.loop_id def.back_id
- ctx
+ ctx_get_local_function def.def_id def.loop_id def.back_id ctx
in
(* Add a break before *)
if !backend <> HOL4 || not (decl_is_first_from_group kind) then
@@ -3234,23 +1354,15 @@ let extract_fun_decl_gen (ctx : extraction_ctx) (fmt : F.formatter)
*)
let is_opaque_coq = !backend = Coq && is_opaque in
let use_forall =
- is_opaque_coq
- && (def.signature.type_params <> []
- || def.signature.const_generic_params <> [])
+ is_opaque_coq && def.signature.generics <> empty_generic_params
in
- (* Print the qualifier ("assume", etc.).
-
- if `wrap_opaque_in_sig`: we generate a record of assumed funcions.
- TODO: this is obsolete.
- *)
- (if not (!Config.wrap_opaque_in_sig && (kind = Assumed || kind = Declared))
- then
- let qualif = ctx.fmt.fun_decl_kind_to_qualif kind in
- match qualif with
- | Some qualif ->
- F.pp_print_string fmt qualif;
- F.pp_print_space fmt ()
- | None -> ());
+ (* Print the qualifier ("assume", etc.). *)
+ let qualif = ctx.fmt.fun_decl_kind_to_qualif kind in
+ (match qualif with
+ | Some qualif ->
+ F.pp_print_string fmt qualif;
+ F.pp_print_space fmt ()
+ | None -> ());
F.pp_print_string fmt def_name;
F.pp_print_space fmt ();
if use_forall then (
@@ -3262,7 +1374,7 @@ let extract_fun_decl_gen (ctx : extraction_ctx) (fmt : F.formatter)
(* Open a box for "(PARAMS) :" *)
F.pp_open_hovbox fmt 0;
let space = ref true in
- let ctx, ctx_body = extract_fun_parameters space ctx fmt def in
+ let ctx, ctx_body, all_params = extract_fun_parameters space ctx fmt def in
(* Print the return type - note that we have to be careful when
* printing the input values for the decrease clause, because
* it introduces bindings in the context... We thus "forget"
@@ -3310,20 +1422,13 @@ let extract_fun_decl_gen (ctx : extraction_ctx) (fmt : F.formatter)
(* The name of the decrease clause *)
let decr_name = ctx_get_termination_measure def.def_id def.loop_id ctx in
F.pp_print_string fmt decr_name;
- (* Print the type/const generic parameters - TODO: we do this many
+ (* Print the generic parameters - TODO: we do this many
times, we should have a helper to factor it out *)
List.iter
- (fun (p : type_var) ->
- let pname = ctx_get_type_var p.index ctx in
+ (fun (name : string) ->
F.pp_print_space fmt ();
- F.pp_print_string fmt pname)
- def.signature.type_params;
- List.iter
- (fun (p : const_generic_var) ->
- let pname = ctx_get_const_generic_var p.index ctx in
- F.pp_print_space fmt ();
- F.pp_print_string fmt pname)
- def.signature.const_generic_params;
+ F.pp_print_string fmt name)
+ all_params;
(* Print the input values: we have to be careful here to print
* only the input values which are in common with the *forward*
* function (the additional input values "given back" to the
@@ -3410,19 +1515,12 @@ let extract_fun_decl_gen (ctx : extraction_ctx) (fmt : F.formatter)
(* Open the box for [DECREASES] *)
F.pp_open_hovbox fmt ctx.indent_incr;
F.pp_print_string fmt terminates_name;
- (* Print the type/const generic params - TODO: factor out *)
+ (* Print the generic params - TODO: factor out *)
List.iter
- (fun (p : type_var) ->
- let pname = ctx_get_type_var p.index ctx in
+ (fun (name : string) ->
F.pp_print_space fmt ();
- F.pp_print_string fmt pname)
- def.signature.type_params;
- List.iter
- (fun (p : const_generic_var) ->
- let pname = ctx_get_const_generic_var p.index ctx in
- F.pp_print_space fmt ();
- F.pp_print_string fmt pname)
- def.signature.const_generic_params;
+ F.pp_print_string fmt name)
+ all_params;
(* Print the variables *)
List.iter
(fun v ->
@@ -3475,18 +1573,13 @@ let extract_fun_decl_gen (ctx : extraction_ctx) (fmt : F.formatter)
let extract_fun_decl_hol4_opaque (ctx : extraction_ctx) (fmt : F.formatter)
(def : fun_decl) : unit =
(* Retrieve the definition name *)
- let with_opaque_pre = false in
let def_name =
- ctx_get_local_function with_opaque_pre def.def_id def.loop_id def.back_id
- ctx
+ ctx_get_local_function def.def_id def.loop_id def.back_id ctx
in
- assert (def.signature.const_generic_params = []);
+ assert (def.signature.generics.const_generics = []);
(* Add the type/const gen parameters - note that we need those bindings
only for the generation of the type (they are not top-level) *)
- let ctx, _, _ =
- ctx_add_type_const_generic_params def.signature.type_params
- def.signature.const_generic_params ctx
- in
+ let ctx, _, _, _ = ctx_add_generic_params def.signature.generics ctx in
(* Add breaks to insert new lines between definitions *)
F.pp_print_break fmt 0 0;
(* Open a box for the whole definition *)
@@ -3635,8 +1728,13 @@ let extract_global_decl_hol4_opaque (ctx : extraction_ctx) (fmt : F.formatter)
(* Print the type *)
F.pp_open_hovbox fmt 0;
extract_ty ctx fmt TypeDeclId.Set.empty false ty;
+ (* Close the definition *)
+ F.pp_print_string fmt ")";
+ F.pp_close_box fmt ();
+ (* Close the definition box *)
F.pp_close_box fmt ();
- (* Close the definition boxe *) F.pp_close_box fmt ()
+ (* Add a line *)
+ F.pp_print_space fmt ()
(** Extract a global declaration.
@@ -3662,21 +1760,19 @@ let extract_global_decl (ctx : extraction_ctx) (fmt : F.formatter)
(global : A.global_decl) (body : fun_decl) (interface : bool) : unit =
assert body.is_global_decl_body;
assert (Option.is_none body.back_id);
- assert (List.length body.signature.inputs = 0);
+ assert (body.signature.inputs = []);
assert (List.length body.signature.doutputs = 1);
- assert (List.length body.signature.type_params = 0);
- assert (List.length body.signature.const_generic_params = 0);
+ assert (body.signature.generics = empty_generic_params);
(* Add a break then the name of the corresponding LLBC declaration *)
F.pp_print_break fmt 0 0;
extract_comment fmt [ "[" ^ Print.global_name_to_string global.name ^ "]" ];
F.pp_print_space fmt ();
- let with_opaque_pre = false in
- let decl_name = ctx_get_global with_opaque_pre global.def_id ctx in
+ let decl_name = ctx_get_global global.def_id ctx in
let body_name =
- ctx_get_function with_opaque_pre
- (FromLlbc (Regular global.body_id, None, None))
+ ctx_get_function
+ (FromLlbc (Pure.FunId (Regular global.body_id), None, None))
ctx
in
@@ -3713,6 +1809,807 @@ let extract_global_decl (ctx : extraction_ctx) (fmt : F.formatter)
(* Add a break to insert lines between declarations *)
F.pp_print_break fmt 0 0
+(** Similar to {!extract_trait_decl_register_names} *)
+let extract_trait_decl_register_parent_clause_names (ctx : extraction_ctx)
+ (trait_decl : trait_decl)
+ (builtin_info : ExtractBuiltin.builtin_trait_decl_info option) :
+ extraction_ctx =
+ (* Compute the clause names *)
+ let clause_names =
+ match builtin_info with
+ | None ->
+ List.map
+ (fun (c : trait_clause) ->
+ let name = ctx.fmt.trait_parent_clause_name trait_decl c in
+ (* Add a prefix if necessary *)
+ let name =
+ if !Config.record_fields_short_names then name
+ else ctx.fmt.trait_decl_name trait_decl ^ name
+ in
+ (c.clause_id, name))
+ trait_decl.parent_clauses
+ | Some info ->
+ List.map
+ (fun (c, name) -> (c.clause_id, name))
+ (List.combine trait_decl.parent_clauses info.parent_clauses)
+ in
+ (* Register the names *)
+ List.fold_left
+ (fun ctx (cid, cname) ->
+ ctx_add (TraitParentClauseId (trait_decl.def_id, cid)) cname ctx)
+ ctx clause_names
+
+(** Similar to {!extract_trait_decl_register_names} *)
+let extract_trait_decl_register_constant_names (ctx : extraction_ctx)
+ (trait_decl : trait_decl)
+ (builtin_info : ExtractBuiltin.builtin_trait_decl_info option) :
+ extraction_ctx =
+ let consts = trait_decl.consts in
+ (* Compute the names *)
+ let constant_names =
+ match builtin_info with
+ | None ->
+ List.map
+ (fun (item_name, _) ->
+ let name = ctx.fmt.trait_const_name trait_decl item_name in
+ (* Add a prefix if necessary *)
+ let name =
+ if !Config.record_fields_short_names then name
+ else ctx.fmt.trait_decl_name trait_decl ^ name
+ in
+ (item_name, name))
+ consts
+ | Some info ->
+ let const_map = StringMap.of_list info.consts in
+ List.map
+ (fun (item_name, _) ->
+ (item_name, StringMap.find item_name const_map))
+ consts
+ in
+ (* Register the names *)
+ List.fold_left
+ (fun ctx (item_name, name) ->
+ ctx_add (TraitItemId (trait_decl.def_id, item_name)) name ctx)
+ ctx constant_names
+
+(** Similar to {!extract_trait_decl_register_names} *)
+let extract_trait_decl_type_names (ctx : extraction_ctx)
+ (trait_decl : trait_decl)
+ (builtin_info : ExtractBuiltin.builtin_trait_decl_info option) :
+ extraction_ctx =
+ let types = trait_decl.types in
+ (* Compute the names *)
+ let type_names =
+ match builtin_info with
+ | None ->
+ let compute_type_name (item_name : string) : string =
+ let type_name = ctx.fmt.trait_type_name trait_decl item_name in
+ if !Config.record_fields_short_names then type_name
+ else ctx.fmt.trait_decl_name trait_decl ^ type_name
+ in
+ let compute_clause_name (item_name : string) (clause : trait_clause) :
+ TraitClauseId.id * string =
+ let name =
+ ctx.fmt.trait_type_clause_name trait_decl item_name clause
+ in
+ (* Add a prefix if necessary *)
+ let name =
+ if !Config.record_fields_short_names then name
+ else ctx.fmt.trait_decl_name trait_decl ^ name
+ in
+ (clause.clause_id, name)
+ in
+ List.map
+ (fun (item_name, (item_clauses, _)) ->
+ (* Type name *)
+ let type_name = compute_type_name item_name in
+ (* Clause names *)
+ let clauses =
+ List.map (compute_clause_name item_name) item_clauses
+ in
+ (item_name, (type_name, clauses)))
+ types
+ | Some info ->
+ let type_map = StringMap.of_list info.types in
+ List.map
+ (fun (item_name, (item_clauses, _)) ->
+ let type_name, clauses_info = StringMap.find item_name type_map in
+ let clauses =
+ List.map
+ (fun (clause, clause_name) -> (clause.clause_id, clause_name))
+ (List.combine item_clauses clauses_info)
+ in
+ (item_name, (type_name, clauses)))
+ types
+ in
+ (* Register the names *)
+ List.fold_left
+ (fun ctx (item_name, (type_name, clauses)) ->
+ let ctx =
+ ctx_add (TraitItemId (trait_decl.def_id, item_name)) type_name ctx
+ in
+ List.fold_left
+ (fun ctx (clause_id, clause_name) ->
+ ctx_add
+ (TraitItemClauseId (trait_decl.def_id, item_name, clause_id))
+ clause_name ctx)
+ ctx clauses)
+ ctx type_names
+
+(** Similar to {!extract_trait_decl_register_names} *)
+let extract_trait_decl_method_names (ctx : extraction_ctx)
+ (trait_decl : trait_decl)
+ (builtin_info : ExtractBuiltin.builtin_trait_decl_info option) :
+ extraction_ctx =
+ let required_methods = trait_decl.required_methods in
+ (* Compute the names *)
+ let method_names =
+ (* We add one field per required forward/backward function *)
+ let get_funs_for_id (id : fun_decl_id) : fun_decl list =
+ let trans : pure_fun_translation = FunDeclId.Map.find id ctx.trans_funs in
+ List.map (fun f -> f.f) (trans.fwd :: trans.backs)
+ in
+ match builtin_info with
+ | None ->
+ (* We add one field per required forward/backward function *)
+ let compute_item_names (item_name : string) (id : fun_decl_id) :
+ string * (RegionGroupId.id option * string) list =
+ let compute_fun_name (f : fun_decl) : RegionGroupId.id option * string
+ =
+ (* We do something special to reuse the [ctx_compute_fun_decl]
+ function. TODO: make it cleaner. *)
+ let basename : name = [ Ident item_name ] in
+ let f = { f with basename } in
+ let trans = A.FunDeclId.Map.find f.def_id ctx.trans_funs in
+ let name = ctx_compute_fun_name trans f ctx in
+ (* Add a prefix if necessary *)
+ let name =
+ if !Config.record_fields_short_names then name
+ else ctx.fmt.trait_decl_name trait_decl ^ "_" ^ name
+ in
+ (f.back_id, name)
+ in
+ let funs = get_funs_for_id id in
+ (item_name, List.map compute_fun_name funs)
+ in
+ List.map (fun (name, id) -> compute_item_names name id) required_methods
+ | Some info ->
+ let funs_map = StringMap.of_list info.methods in
+ List.map
+ (fun (item_name, fun_id) ->
+ let open ExtractBuiltin in
+ let info = StringMap.find item_name funs_map in
+ let trans_funs = get_funs_for_id fun_id in
+ let find (trans_fun : fun_decl) =
+ let info =
+ List.find_opt
+ (fun (info : builtin_fun_info) -> info.rg = trans_fun.back_id)
+ info
+ in
+ match info with
+ | Some info -> (info.rg, info.extract_name)
+ | None ->
+ let err =
+ "Ill-formed builtin information for trait decl \""
+ ^ Names.name_to_string trait_decl.name
+ ^ "\", method \"" ^ item_name
+ ^ "\": could not find name for region "
+ ^ Print.option_to_string Pure.show_region_group_id
+ trans_fun.back_id
+ in
+ log#serror err;
+ if !Config.fail_hard then raise (Failure err)
+ else (trans_fun.back_id, "%ERROR_BUILTIN_NAME_NOT_FOUND%")
+ in
+ let rg_with_name_list = List.map find trans_funs in
+ (item_name, rg_with_name_list))
+ required_methods
+ in
+ (* Register the names *)
+ List.fold_left
+ (fun ctx (item_name, funs) ->
+ (* We add one field per required forward/backward function *)
+ List.fold_left
+ (fun ctx (rg, fun_name) ->
+ ctx_add
+ (TraitMethodId (trait_decl.def_id, item_name, rg))
+ fun_name ctx)
+ ctx funs)
+ ctx method_names
+
+(** Similar to {!extract_type_decl_register_names} *)
+let extract_trait_decl_register_names (ctx : extraction_ctx)
+ (trait_decl : trait_decl) : extraction_ctx =
+ (* Lookup the information if this is a builtin trait *)
+ let open ExtractBuiltin in
+ let sname = name_to_simple_name trait_decl.name in
+ let builtin_info =
+ SimpleNameMap.find_opt sname (builtin_trait_decls_map ())
+ in
+ let ctx =
+ let trait_name, trait_constructor =
+ match builtin_info with
+ | None ->
+ ( ctx.fmt.trait_decl_name trait_decl,
+ ctx.fmt.trait_decl_constructor trait_decl )
+ | Some info -> (info.extract_name, info.constructor)
+ in
+ let ctx = ctx_add (TraitDeclId trait_decl.def_id) trait_name ctx in
+ ctx_add (TraitDeclConstructorId trait_decl.def_id) trait_constructor ctx
+ in
+ (* Parent clauses *)
+ let ctx =
+ extract_trait_decl_register_parent_clause_names ctx trait_decl builtin_info
+ in
+ (* Constants *)
+ let ctx =
+ extract_trait_decl_register_constant_names ctx trait_decl builtin_info
+ in
+ (* Types *)
+ let ctx = extract_trait_decl_type_names ctx trait_decl builtin_info in
+ (* Required methods *)
+ let ctx = extract_trait_decl_method_names ctx trait_decl builtin_info in
+ ctx
+
+(** Similar to {!extract_type_decl_register_names} *)
+let extract_trait_impl_register_names (ctx : extraction_ctx)
+ (trait_impl : trait_impl) : extraction_ctx =
+ let decl_id = trait_impl.impl_trait.trait_decl_id in
+ let trait_decl = TraitDeclId.Map.find decl_id ctx.trans_trait_decls in
+ (* Check if the trait implementation is builtin *)
+ let builtin_info =
+ let open ExtractBuiltin in
+ let type_sname = name_to_simple_name trait_impl.name in
+ let trait_sname = name_to_simple_name trait_decl.name in
+ SimpleNamePairMap.find_opt (type_sname, trait_sname)
+ (builtin_trait_impls_map ())
+ in
+ (* Register some builtin information (if necessary) *)
+ let ctx, builtin_info =
+ match builtin_info with
+ | None -> (ctx, None)
+ | Some (filter, info) ->
+ let ctx =
+ match filter with
+ | None -> ctx
+ | Some filter ->
+ {
+ ctx with
+ trait_impls_filter_type_args_map =
+ TraitImplId.Map.add trait_impl.def_id filter
+ ctx.trait_impls_filter_type_args_map;
+ }
+ in
+ (ctx, Some info)
+ in
+
+ (* For now we do not support overriding provided methods *)
+ assert (trait_impl.provided_methods = []);
+ (* Everything is taken care of by {!extract_trait_decl_register_names} *but*
+ the name of the implementation itself *)
+ (* Compute the name *)
+ let name =
+ match builtin_info with
+ | None -> ctx.fmt.trait_impl_name trait_decl trait_impl
+ | Some name -> name
+ in
+ ctx_add (TraitImplId trait_impl.def_id) name ctx
+
+(** Small helper.
+
+ The type `ty` is to be understood in a very general sense.
+ *)
+let extract_trait_item (ctx : extraction_ctx) (fmt : F.formatter)
+ (item_name : string) (separator : string) (ty : unit -> unit) : unit =
+ F.pp_print_space fmt ();
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ F.pp_print_string fmt item_name;
+ F.pp_print_space fmt ();
+ (* ":" or "=" *)
+ F.pp_print_string fmt separator;
+ ty ();
+ (match !Config.backend with Lean -> () | _ -> F.pp_print_string fmt ";");
+ F.pp_close_box fmt ()
+
+let extract_trait_decl_item (ctx : extraction_ctx) (fmt : F.formatter)
+ (item_name : string) (ty : unit -> unit) : unit =
+ extract_trait_item ctx fmt item_name ":" ty
+
+let extract_trait_impl_item (ctx : extraction_ctx) (fmt : F.formatter)
+ (item_name : string) (ty : unit -> unit) : unit =
+ let assign = match !Config.backend with Lean | Coq -> ":=" | _ -> "=" in
+ extract_trait_item ctx fmt item_name assign ty
+
+(** Small helper - TODO: move *)
+let generic_params_drop_prefix ~(drop_trait_clauses : bool)
+ (g1 : generic_params) (g2 : generic_params) : generic_params =
+ let open Collections.List in
+ let types = drop (length g1.types) g2.types in
+ let const_generics = drop (length g1.const_generics) g2.const_generics in
+ let trait_clauses =
+ if drop_trait_clauses then drop (length g1.trait_clauses) g2.trait_clauses
+ else g2.trait_clauses
+ in
+ { types; const_generics; trait_clauses }
+
+(** Small helper.
+
+ Extract the items for a method in a trait decl.
+ *)
+let extract_trait_decl_method_items (ctx : extraction_ctx) (fmt : F.formatter)
+ (decl : trait_decl) (item_name : string) (id : fun_decl_id) : unit =
+ (* Lookup the definition *)
+ let trans = A.FunDeclId.Map.find id ctx.trans_funs in
+ (* Extract the items *)
+ let funs = if trans.keep_fwd then trans.fwd :: trans.backs else trans.backs in
+ let extract_method (f : fun_and_loops) =
+ let f = f.f in
+ let fun_name = ctx_get_trait_method decl.def_id item_name f.back_id ctx in
+ let ty () =
+ (* Extract the generics *)
+ (* We need to add the generics specific to the method, by removing those
+ which actually apply to the trait decl *)
+ let generics =
+ let drop_trait_clauses = false in
+ generic_params_drop_prefix ~drop_trait_clauses decl.generics
+ f.signature.generics
+ in
+ let ctx, type_params, cg_params, trait_clauses =
+ ctx_add_generic_params generics ctx
+ in
+ let backend_uses_forall =
+ match !backend with Coq | Lean -> true | FStar | HOL4 -> false
+ in
+ let generics_not_empty = generics <> empty_generic_params in
+ let use_forall = generics_not_empty && backend_uses_forall in
+ let use_arrows = generics_not_empty && not backend_uses_forall in
+ let use_forall_use_sep = false in
+ extract_generic_params ctx fmt TypeDeclId.Set.empty ~use_forall
+ ~use_forall_use_sep ~use_arrows generics type_params cg_params
+ trait_clauses;
+ if use_forall then F.pp_print_string fmt ",";
+ (* Extract the inputs and output *)
+ F.pp_print_space fmt ();
+ extract_fun_inputs_output_parameters_types ctx fmt f
+ in
+ extract_trait_decl_item ctx fmt fun_name ty
+ in
+ List.iter extract_method funs
+
+(** Extract a trait declaration *)
+let extract_trait_decl (ctx : extraction_ctx) (fmt : F.formatter)
+ (decl : trait_decl) : unit =
+ (* Retrieve the trait name *)
+ let decl_name = ctx_get_trait_decl decl.def_id ctx in
+ (* Add a break before *)
+ F.pp_print_break fmt 0 0;
+ (* Print a comment to link the extracted type to its original rust definition *)
+ extract_comment fmt
+ [ "Trait declaration: [" ^ Print.name_to_string decl.name ^ "]" ];
+ F.pp_print_break fmt 0 0;
+ (* Open two outer boxes for the definition, so that whenever possible it gets printed on
+ one line and indents are correct.
+
+ There is just an exception with Lean: in this backend, line breaks are important
+ for the parsing, so we always open a vertical box.
+ *)
+ if !Config.backend = Lean then F.pp_open_vbox fmt ctx.indent_incr
+ else (
+ F.pp_open_hvbox fmt 0;
+ F.pp_open_hvbox fmt ctx.indent_incr);
+
+ (* `struct Trait (....) =` *)
+ (* Open the box for the name + generics *)
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ let qualif =
+ Option.get (ctx.fmt.type_decl_kind_to_qualif SingleNonRec (Some Struct))
+ in
+ (* When checking if the trait declaration is empty: we ignore the provided
+ methods, because for now they are extracted separately *)
+ let is_empty = trait_decl_is_empty { decl with provided_methods = [] } in
+ if !backend = FStar && not is_empty then (
+ F.pp_print_string fmt "noeq";
+ F.pp_print_space fmt ());
+ F.pp_print_string fmt qualif;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt decl_name;
+ (* Print the generics *)
+ let generics = decl.generics in
+ (* Add the type and const generic params - note that we need those bindings only for the
+ * body translation (they are not top-level) *)
+ let ctx, type_params, cg_params, trait_clauses =
+ ctx_add_generic_params generics ctx
+ in
+ extract_generic_params ctx fmt TypeDeclId.Set.empty generics type_params
+ cg_params trait_clauses;
+
+ F.pp_print_space fmt ();
+ if is_empty && !backend = FStar then (
+ F.pp_print_string fmt "= unit";
+ (* Outer box *)
+ F.pp_close_box fmt ())
+ else if is_empty && !backend = Coq then (
+ (* Coq is not very good at infering constructors *)
+ let cons = ctx_get_trait_constructor decl.def_id ctx in
+ F.pp_print_string fmt (":= " ^ cons ^ "{}.");
+ (* Outer box *)
+ F.pp_close_box fmt ())
+ else (
+ (match !backend with
+ | Lean -> F.pp_print_string fmt "where"
+ | FStar -> F.pp_print_string fmt "= {"
+ | Coq ->
+ let cons = ctx_get_trait_constructor decl.def_id ctx in
+ F.pp_print_string fmt (":= " ^ cons ^ " {")
+ | _ -> F.pp_print_string fmt "{");
+
+ (* Close the box for the name + generics *)
+ F.pp_close_box fmt ();
+
+ (*
+ * Extract the items
+ *)
+
+ (* The constants *)
+ List.iter
+ (fun (name, (ty, _)) ->
+ let item_name = ctx_get_trait_const decl.def_id name ctx in
+ let ty () =
+ let inside = false in
+ F.pp_print_space fmt ();
+ extract_ty ctx fmt TypeDeclId.Set.empty inside ty
+ in
+ extract_trait_decl_item ctx fmt item_name ty)
+ decl.consts;
+
+ (* The types *)
+ List.iter
+ (fun (name, (clauses, _)) ->
+ (* Extract the type *)
+ let item_name = ctx_get_trait_type decl.def_id name ctx in
+ let ty () =
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt (type_keyword ())
+ in
+ extract_trait_decl_item ctx fmt item_name ty;
+ (* Extract the clauses *)
+ List.iter
+ (fun clause ->
+ let item_name =
+ ctx_get_trait_item_clause decl.def_id name clause.clause_id ctx
+ in
+ let ty () =
+ F.pp_print_space fmt ();
+ extract_trait_clause_type ctx fmt TypeDeclId.Set.empty clause
+ in
+ extract_trait_decl_item ctx fmt item_name ty)
+ clauses)
+ decl.types;
+
+ (* The parent clauses - note that the parent clauses may refer to the types
+ and const generics: for this reason we extract them *after* *)
+ List.iter
+ (fun clause ->
+ let item_name =
+ ctx_get_trait_parent_clause decl.def_id clause.clause_id ctx
+ in
+ let ty () =
+ F.pp_print_space fmt ();
+ extract_trait_clause_type ctx fmt TypeDeclId.Set.empty clause
+ in
+ extract_trait_decl_item ctx fmt item_name ty)
+ decl.parent_clauses;
+
+ (* The required methods *)
+ List.iter
+ (fun (name, id) -> extract_trait_decl_method_items ctx fmt decl name id)
+ decl.required_methods;
+
+ (* Close the outer boxes for the definition *)
+ if !Config.backend <> Lean then F.pp_close_box fmt ();
+ (* Close the brackets *)
+ match !Config.backend with
+ | Lean -> ()
+ | Coq ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "}."
+ | _ ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "}");
+ F.pp_close_box fmt ();
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0
+
+(** Generate the [Arguments] instructions for the trait declarationsin Coq, so
+ that we don't have to provide the implicit arguments when projecting the fields. *)
+let extract_trait_decl_coq_arguments (ctx : extraction_ctx) (fmt : F.formatter)
+ (decl : trait_decl) : unit =
+ (* Generating the [Arguments] instructions is useful only if there are parameters *)
+ let num_params =
+ List.length decl.generics.types
+ + List.length decl.generics.const_generics
+ + List.length decl.generics.trait_clauses
+ in
+ if num_params > 0 then (
+ (* The constructor *)
+ let cons_name = ctx_get_trait_constructor decl.def_id ctx in
+ extract_coq_arguments_instruction ctx fmt cons_name num_params;
+ (* The constants *)
+ List.iter
+ (fun (name, _) ->
+ let item_name = ctx_get_trait_const decl.def_id name ctx in
+ extract_coq_arguments_instruction ctx fmt item_name num_params)
+ decl.consts;
+ (* The types *)
+ List.iter
+ (fun (name, (clauses, _)) ->
+ (* The type *)
+ let item_name = ctx_get_trait_type decl.def_id name ctx in
+ extract_coq_arguments_instruction ctx fmt item_name num_params;
+ (* The type clauses *)
+ List.iter
+ (fun clause ->
+ let item_name =
+ ctx_get_trait_item_clause decl.def_id name clause.clause_id ctx
+ in
+ extract_coq_arguments_instruction ctx fmt item_name num_params)
+ clauses)
+ decl.types;
+ (* The parent clauses *)
+ List.iter
+ (fun clause ->
+ let item_name =
+ ctx_get_trait_parent_clause decl.def_id clause.clause_id ctx
+ in
+ extract_coq_arguments_instruction ctx fmt item_name num_params)
+ decl.parent_clauses;
+ (* The required methods *)
+ List.iter
+ (fun (item_name, id) ->
+ (* Lookup the definition *)
+ let trans = A.FunDeclId.Map.find id ctx.trans_funs in
+ (* Extract the items *)
+ let funs =
+ if trans.keep_fwd then trans.fwd :: trans.backs else trans.backs
+ in
+ let extract_for_method (f : fun_and_loops) =
+ let f = f.f in
+ let item_name =
+ ctx_get_trait_method decl.def_id item_name f.back_id ctx
+ in
+ extract_coq_arguments_instruction ctx fmt item_name num_params
+ in
+ List.iter extract_for_method funs)
+ decl.required_methods;
+ (* Add a space *)
+ F.pp_print_space fmt ())
+
+(** See {!extract_trait_decl_coq_arguments} *)
+let extract_trait_decl_extra_info (ctx : extraction_ctx) (fmt : F.formatter)
+ (trait_decl : trait_decl) : unit =
+ match !backend with
+ | Coq -> extract_trait_decl_coq_arguments ctx fmt trait_decl
+ | _ -> ()
+
+(** Small helper.
+
+ Extract the items for a method in a trait impl.
+ *)
+let extract_trait_impl_method_items (ctx : extraction_ctx) (fmt : F.formatter)
+ (impl : trait_impl) (item_name : string) (id : fun_decl_id)
+ (impl_generics : string list * string list * string list) : unit =
+ let trait_decl_id = impl.impl_trait.trait_decl_id in
+ (* Lookup the definition *)
+ let trans = A.FunDeclId.Map.find id ctx.trans_funs in
+ (* Extract the items *)
+ let funs = if trans.keep_fwd then trans.fwd :: trans.backs else trans.backs in
+ let extract_method (f : fun_and_loops) =
+ let f = f.f in
+ let fun_name = ctx_get_trait_method trait_decl_id item_name f.back_id ctx in
+ let ty () =
+ (* Filter the generics if the method is a builtin *)
+ let i_tys, _, _ = impl_generics in
+ let impl_types, i_tys, f_tys =
+ match FunDeclId.Map.find_opt f.def_id ctx.funs_filter_type_args_map with
+ | None -> (impl.generics.types, i_tys, f.signature.generics.types)
+ | Some filter ->
+ let filter_list filter ls =
+ let ls = List.combine filter ls in
+ List.filter_map (fun (b, ty) -> if b then Some ty else None) ls
+ in
+ let impl_types = impl.generics.types in
+ let impl_filter =
+ Collections.List.prefix (List.length impl_types) filter
+ in
+ let i_tys = i_tys in
+ let i_filter = Collections.List.prefix (List.length i_tys) filter in
+ ( filter_list impl_filter impl_types,
+ filter_list i_filter i_tys,
+ filter_list filter f.signature.generics.types )
+ in
+ let f_generics = { f.signature.generics with types = f_tys } in
+ (* Extract the generics - we need to quantify over the generics which
+ are specific to the method, and call it will all the generics
+ (trait impl + method generics) *)
+ let f_generics =
+ let drop_trait_clauses = true in
+ generic_params_drop_prefix ~drop_trait_clauses
+ { impl.generics with types = impl_types }
+ f_generics
+ in
+ (* Register and print the quantified generics *)
+ let ctx, f_tys, f_cgs, f_tcs = ctx_add_generic_params f_generics ctx in
+ let use_forall = f_generics <> empty_generic_params in
+ extract_generic_params ctx fmt TypeDeclId.Set.empty ~use_forall f_generics
+ f_tys f_cgs f_tcs;
+ if use_forall then F.pp_print_string fmt ",";
+ (* Extract the function call *)
+ F.pp_print_space fmt ();
+ let fun_name = ctx_get_local_function f.def_id None f.back_id ctx in
+ F.pp_print_string fmt fun_name;
+ let all_generics =
+ let _, i_cgs, i_tcs = impl_generics in
+ List.concat [ i_tys; f_tys; i_cgs; f_cgs; i_tcs; f_tcs ]
+ in
+
+ (* Filter the generics if the function is builtin *)
+ List.iter
+ (fun p ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt p)
+ all_generics
+ in
+ extract_trait_impl_item ctx fmt fun_name ty
+ in
+ List.iter extract_method funs
+
+(** Extract a trait implementation *)
+let extract_trait_impl (ctx : extraction_ctx) (fmt : F.formatter)
+ (impl : trait_impl) : unit =
+ log#ldebug (lazy ("extract_trait_impl: " ^ Names.name_to_string impl.name));
+ (* Retrieve the impl name *)
+ let impl_name = ctx_get_trait_impl impl.def_id ctx in
+ (* Add a break before *)
+ F.pp_print_break fmt 0 0;
+ (* Print a comment to link the extracted type to its original rust definition *)
+ extract_comment fmt
+ [ "Trait implementation: [" ^ Print.name_to_string impl.name ^ "]" ];
+ F.pp_print_break fmt 0 0;
+
+ (* Open two outer boxes for the definition, so that whenever possible it gets printed on
+ one line and indents are correct.
+
+ There is just an exception with Lean: in this backend, line breaks are important
+ for the parsing, so we always open a vertical box.
+ *)
+ if !Config.backend = Lean then (
+ F.pp_open_vbox fmt 0;
+ F.pp_open_vbox fmt ctx.indent_incr)
+ else (
+ F.pp_open_hvbox fmt 0;
+ F.pp_open_hvbox fmt ctx.indent_incr);
+
+ (* `let (....) : Trait ... =` *)
+ (* Open the box for the name + generics *)
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ (match ctx.fmt.fun_decl_kind_to_qualif SingleNonRec with
+ | Some qualif ->
+ F.pp_print_string fmt qualif;
+ F.pp_print_space fmt ()
+ | None -> ());
+ F.pp_print_string fmt impl_name;
+
+ (* Print the generics *)
+ (* Add the type and const generic params - note that we need those bindings only for the
+ * body translation (they are not top-level) *)
+ let ctx, type_params, cg_params, trait_clauses =
+ ctx_add_generic_params impl.generics ctx
+ in
+ let all_generics = (type_params, cg_params, trait_clauses) in
+ extract_generic_params ctx fmt TypeDeclId.Set.empty impl.generics type_params
+ cg_params trait_clauses;
+
+ (* Print the type *)
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ extract_trait_decl_ref ctx fmt TypeDeclId.Set.empty false impl.impl_trait;
+
+ (* When checking if the trait impl is empty: we ignore the provided
+ methods, because for now they are extracted separately *)
+ let is_empty = trait_impl_is_empty { impl with provided_methods = [] } in
+
+ F.pp_print_space fmt ();
+ if is_empty && !Config.backend = FStar then (
+ F.pp_print_string fmt "= ()";
+ (* Outer box *)
+ F.pp_close_box fmt ())
+ else if is_empty && !Config.backend = Coq then (
+ (* Coq is not very good at infering constructors *)
+ let cons = ctx_get_trait_constructor impl.impl_trait.trait_decl_id ctx in
+ F.pp_print_string fmt (":= " ^ cons ^ ".");
+ (* Outer box *)
+ F.pp_close_box fmt ())
+ else (
+ if !Config.backend = Lean then F.pp_print_string fmt ":= {"
+ else if !Config.backend = Coq then F.pp_print_string fmt ":= {|"
+ else F.pp_print_string fmt "= {";
+
+ (* Close the box for the name + generics *)
+ F.pp_close_box fmt ();
+
+ (*
+ * Extract the items
+ *)
+ let trait_decl_id = impl.impl_trait.trait_decl_id in
+
+ (* The constants *)
+ List.iter
+ (fun (name, (_, id)) ->
+ let item_name = ctx_get_trait_const trait_decl_id name ctx in
+ let ty () =
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt (ctx_get_global id ctx)
+ in
+
+ extract_trait_impl_item ctx fmt item_name ty)
+ impl.consts;
+
+ (* The types *)
+ List.iter
+ (fun (name, (trait_refs, ty)) ->
+ (* Extract the type *)
+ let item_name = ctx_get_trait_type trait_decl_id name ctx in
+ let ty () =
+ F.pp_print_space fmt ();
+ extract_ty ctx fmt TypeDeclId.Set.empty false ty
+ in
+ extract_trait_impl_item ctx fmt item_name ty;
+ (* Extract the clauses *)
+ TraitClauseId.iteri
+ (fun clause_id trait_ref ->
+ let item_name =
+ ctx_get_trait_item_clause trait_decl_id name clause_id ctx
+ in
+ let ty () =
+ F.pp_print_space fmt ();
+ extract_trait_ref ctx fmt TypeDeclId.Set.empty false trait_ref
+ in
+ extract_trait_impl_item ctx fmt item_name ty)
+ trait_refs)
+ impl.types;
+
+ (* The parent clauses *)
+ TraitClauseId.iteri
+ (fun clause_id trait_ref ->
+ let item_name =
+ ctx_get_trait_parent_clause trait_decl_id clause_id ctx
+ in
+ let ty () =
+ F.pp_print_space fmt ();
+ extract_trait_ref ctx fmt TypeDeclId.Set.empty false trait_ref
+ in
+ extract_trait_impl_item ctx fmt item_name ty)
+ impl.parent_trait_refs;
+
+ (* The required methods *)
+ List.iter
+ (fun (name, id) ->
+ extract_trait_impl_method_items ctx fmt impl name id all_generics)
+ impl.required_methods;
+
+ (* Close the outer boxes for the definition, as well as the brackets *)
+ F.pp_close_box fmt ();
+ if !backend = Coq then (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "|}.")
+ else if (not (!backend = FStar)) || not is_empty then (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "}"));
+ F.pp_close_box fmt ();
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0
+
(** Extract a unit test, if the function is a unit function (takes no
parameters, returns unit).
@@ -3735,8 +2632,7 @@ let extract_unit_test_if_unit_fun (ctx : extraction_ctx) (fmt : F.formatter)
(* Check if this is a unit function *)
let sg = def.signature in
if
- sg.type_params = []
- && sg.const_generic_params = []
+ sg.generics = empty_generic_params
&& (sg.inputs = [ mk_unit_ty ] || sg.inputs = [])
&& sg.output = mk_result_ty mk_unit_ty
then (
@@ -3756,12 +2652,8 @@ let extract_unit_test_if_unit_fun (ctx : extraction_ctx) (fmt : F.formatter)
F.pp_print_string fmt "assert_norm";
F.pp_print_space fmt ();
F.pp_print_string fmt "(";
- (* Note that if the function is opaque, the unit test will fail
- because the normalizer will get stuck *)
- let with_opaque_pre = ctx.use_opaque_pre in
let fun_name =
- ctx_get_local_function with_opaque_pre def.def_id def.loop_id
- def.back_id ctx
+ ctx_get_local_function def.def_id def.loop_id def.back_id ctx
in
F.pp_print_string fmt fun_name;
if sg.inputs <> [] then (
@@ -3776,12 +2668,8 @@ let extract_unit_test_if_unit_fun (ctx : extraction_ctx) (fmt : F.formatter)
F.pp_print_string fmt "Check";
F.pp_print_space fmt ();
F.pp_print_string fmt "(";
- (* Note that if the function is opaque, the unit test will fail
- because the normalizer will get stuck *)
- let with_opaque_pre = ctx.use_opaque_pre in
let fun_name =
- ctx_get_local_function with_opaque_pre def.def_id def.loop_id
- def.back_id ctx
+ ctx_get_local_function def.def_id def.loop_id def.back_id ctx
in
F.pp_print_string fmt fun_name;
if sg.inputs <> [] then (
@@ -3793,12 +2681,8 @@ let extract_unit_test_if_unit_fun (ctx : extraction_ctx) (fmt : F.formatter)
F.pp_print_string fmt "#assert";
F.pp_print_space fmt ();
F.pp_print_string fmt "(";
- (* Note that if the function is opaque, the unit test will fail
- because the normalizer will get stuck *)
- let with_opaque_pre = ctx.use_opaque_pre in
let fun_name =
- ctx_get_local_function with_opaque_pre def.def_id def.loop_id
- def.back_id ctx
+ ctx_get_local_function def.def_id def.loop_id def.back_id ctx
in
F.pp_print_string fmt fun_name;
if sg.inputs <> [] then (
@@ -3812,12 +2696,8 @@ let extract_unit_test_if_unit_fun (ctx : extraction_ctx) (fmt : F.formatter)
| HOL4 ->
F.pp_print_string fmt "val _ = assert_return (";
F.pp_print_string fmt "“";
- (* Note that if the function is opaque, the unit test will fail
- because the normalizer will get stuck *)
- let with_opaque_pre = ctx.use_opaque_pre in
let fun_name =
- ctx_get_local_function with_opaque_pre def.def_id def.loop_id
- def.back_id ctx
+ ctx_get_local_function def.def_id def.loop_id def.back_id ctx
in
F.pp_print_string fmt fun_name;
if sg.inputs <> [] then (
diff --git a/compiler/ExtractBase.ml b/compiler/ExtractBase.ml
index d733c763..31b1a447 100644
--- a/compiler/ExtractBase.ml
+++ b/compiler/ExtractBase.ml
@@ -5,9 +5,10 @@ open TranslateCore
module C = Contexts
module RegionVarId = T.RegionVarId
module F = Format
+open ExtractBuiltin
(** The local logger *)
-let log = L.pure_to_extract_log
+let log = L.extract_log
type region_group_info = {
id : RegionGroupId.id;
@@ -21,8 +22,8 @@ type region_group_info = {
*)
}
-module StringSet = Collections.MakeSet (Collections.OrderedString)
-module StringMap = Collections.MakeMap (Collections.OrderedString)
+module StringSet = Collections.StringSet
+module StringMap = Collections.StringMap
type name = Names.name
type type_name = Names.type_name
@@ -77,6 +78,7 @@ type decl_kind =
F*: [val x : Type0]
Coq: [Axiom x : Type.]
*)
+[@@deriving show]
(** Return [true] if the declaration is the last from its group of declarations.
@@ -111,9 +113,9 @@ let decl_is_first_from_group (kind : decl_kind) : bool =
let decl_is_not_last_from_group (kind : decl_kind) : bool =
not (decl_is_last_from_group kind)
-(* TODO: this should a module we give to a functor! *)
+type type_decl_kind = Enum | Struct [@@deriving show]
-type type_decl_kind = Enum | Struct
+(* TODO: this should be a module we give to a functor! *)
(** A formatter's role is twofold:
1. Come up with name suggestions.
@@ -125,6 +127,9 @@ type type_decl_kind = Enum | Struct
snake case, adding prefixes/suffixes, etc.
2. Format some specific terms, like constants.
+
+ TODO: unclear that this is useful now that all the backends are so much
+ entangled in Extract.ml
*)
type formatter = {
bool_name : string;
@@ -239,37 +244,14 @@ type formatter = {
the same purpose as in {!field:fun_name}.
- loop identifier, if this is for a loop
*)
- opaque_pre : unit -> string;
- (** TODO: obsolete, remove.
-
- The prefix to use for opaque definitions.
-
- We need this because for some backends like Lean and Coq, we group
- opaque definitions in module signatures, meaning that using those
- definitions requires to prefix them with a module parameter name (such
- as "opaque_defs.").
-
- For instance, if we have an opaque function [f : int -> int], which
- is used by the non-opaque function [g], we would generate (in Coq):
- {[
- (* The module signature declaring the opaque definitions *)
- module type OpaqueDefs = {
- f_fwd : int -> int
- ... (* Other definitions *)
- }
-
- (* The definitions generated for the non-opaque definitions *)
- module Funs (opaque: OpaqueDefs) = {
- let g ... =
- ...
- opaque_defs.f_fwd
- ...
- }
- ]}
-
- Upon using [f] in [g], we don't directly use the the name "f_fwd",
- but prefix it with the "opaque_defs." identifier.
- *)
+ trait_decl_name : trait_decl -> string;
+ trait_impl_name : trait_decl -> trait_impl -> string;
+ trait_decl_constructor : trait_decl -> string;
+ trait_parent_clause_name : trait_decl -> trait_clause -> string;
+ trait_const_name : trait_decl -> string -> string;
+ trait_type_name : trait_decl -> string -> string;
+ trait_method_name : trait_decl -> string -> string;
+ trait_type_clause_name : trait_decl -> string -> trait_clause -> string;
var_basename : StringSet.t -> string option -> ty -> string;
(** Generates a variable basename.
@@ -288,6 +270,14 @@ type formatter = {
(** Generates a type variable basename. *)
const_generic_var_basename : StringSet.t -> string -> string;
(** Generates a const generic variable basename. *)
+ trait_self_clause_basename : string;
+ trait_clause_basename : StringSet.t -> trait_clause -> string;
+ (** Return a base name for a trait clause. We might add a suffix to prevent
+ collisions.
+
+ In the traduction we explicitely manipulate the trait clause instances,
+ that is we introduce one input variable for each trait clause.
+ *)
append_index : string -> int -> string;
(** Appends an index to a name - we use this to generate unique
names: when doing so, the role of the formatter is just to concatenate
@@ -396,10 +386,60 @@ type id =
| TypeVarId of TypeVarId.id
| ConstGenericVarId of ConstGenericVarId.id
| VarId of VarId.id
+ | TraitDeclId of TraitDeclId.id
+ | TraitImplId of TraitImplId.id
+ | LocalTraitClauseId of TraitClauseId.id
+ | TraitDeclConstructorId of TraitDeclId.id
+ | TraitMethodId of TraitDeclId.id * string * T.RegionGroupId.id option
+ (** Something peculiar with trait methods: because we have to take into
+ account forward/backward functions, we may need to generate fields
+ items per method.
+ *)
+ | TraitItemId of TraitDeclId.id * string
+ (** A trait associated item which is not a method *)
+ | TraitParentClauseId of TraitDeclId.id * TraitClauseId.id
+ | TraitItemClauseId of TraitDeclId.id * string * TraitClauseId.id
+ | TraitSelfClauseId
+ (** Specifically for the clause: [Self : Trait].
+
+ For now, we forbid provided methods (methods in trait declarations
+ with a default implementation) from being overriden in trait implementations.
+ We extract trait provided methods such that they take an instance of
+ the trait as input: this instance is given by the trait self clause.
+
+ For instance:
+ {[
+ //
+ // Rust
+ //
+ trait ToU64 {
+ fn to_u64(&self) -> u64;
+
+ // Provided method
+ fn is_pos(&self) -> bool {
+ self.to_u64() > 0
+ }
+ }
+
+ //
+ // Generated code
+ //
+ struct ToU64 (T : Type) {
+ to_u64 : T -> u64;
+ }
+
+ // The trait self clause
+ // vvvvvvvvvvvvvvvvvvvvvv
+ let is_pos (T : Type) (trait_self : ToU64 T) (self : T) : bool =
+ trait_self.to_u64 self > 0
+ ]}
+ *)
| UnknownId
(** Used for stored various strings like keywords, definitions which
should always be in context, etc. and which can't be linked to one
of the above.
+
+ TODO: rename to "keyword"
*)
[@@deriving show, ord]
@@ -429,69 +469,64 @@ type names_map = {
precisely which identifiers are mapped to the same name...
*)
names_set : StringSet.t;
- opaque_ids : IdSet.t;
- (** TODO: this is obsolete. Remove.
+}
- The set of opaque definitions.
+let empty_names_map : names_map =
+ {
+ id_to_name = IdMap.empty;
+ name_to_id = StringMap.empty;
+ names_set = StringSet.empty;
+ }
- See {!formatter.opaque_pre} for detailed explanations about why
- we need to know which definitions are opaque to compute names.
+(** Small helper to report name collision *)
+let report_name_collision (id_to_string : id -> string) (id1 : id) (id2 : id)
+ (name : string) : unit =
+ let id1 = "\n- " ^ id_to_string id1 in
+ let id2 = "\n- " ^ id_to_string id2 in
+ let err =
+ "Name clash detected: the following identifiers are bound to the same name \
+ \"" ^ name ^ "\":" ^ id1 ^ id2
+ ^ "\nYou may want to rename some of your definitions, or report an issue."
+ in
+ log#serror err;
+ (* If we fail hard on errors, raise an exception *)
+ if !Config.fail_hard then raise (Failure err)
- Also note that the opaque ids don't contain the ids of the assumed
- definitions. In practice, assumed definitions are opaque_defs. However, they
- are not grouped in the opaque module, meaning we never need to
- prefix them (with, say, "opaque_defs."): we thus consider them as non-opaque
- with regards to the names map.
- *)
-}
+let names_map_get_id_from_name (name : string) (nm : names_map) : id option =
+ StringMap.find_opt name nm.name_to_id
-let names_map_add (id_to_string : id -> string) (is_opaque : bool) (id : id)
- (name : string) (nm : names_map) : names_map =
- (* Check if there is a clash *)
- (match StringMap.find_opt name nm.name_to_id with
+let names_map_check_collision (id_to_string : id -> string) (id : id)
+ (name : string) (nm : names_map) : unit =
+ match names_map_get_id_from_name name nm with
| None -> () (* Ok *)
| Some clash ->
(* There is a clash: print a nice debugging message for the user *)
- let id1 = "\n- " ^ id_to_string clash in
- let id2 = "\n- " ^ id_to_string id in
- let err =
- "Name clash detected: the following identifiers are bound to the same \
- name \"" ^ name ^ "\":" ^ id1 ^ id2
- in
- log#serror err;
- raise (Failure err));
- (* Sanity check *)
- assert (not (StringSet.mem name nm.names_set));
+ report_name_collision id_to_string clash id name
+
+(** Insert bindings in a names map without checking for collisions *)
+let names_map_add_unchecked (id : id) (name : string) (nm : names_map) :
+ names_map =
(* Insert *)
let id_to_name = IdMap.add id name nm.id_to_name in
let name_to_id = StringMap.add name id nm.name_to_id in
let names_set = StringSet.add name nm.names_set in
- let opaque_ids =
- if is_opaque then IdSet.add id nm.opaque_ids else nm.opaque_ids
- in
- { id_to_name; name_to_id; names_set; opaque_ids }
-
-let names_map_add_assumed_type (id_to_string : id -> string) (id : assumed_ty)
- (name : string) (nm : names_map) : names_map =
- let is_opaque = false in
- names_map_add id_to_string is_opaque (TypeId (Assumed id)) name nm
-
-let names_map_add_assumed_struct (id_to_string : id -> string) (id : assumed_ty)
- (name : string) (nm : names_map) : names_map =
- let is_opaque = false in
- names_map_add id_to_string is_opaque (StructId (Assumed id)) name nm
+ { id_to_name; name_to_id; names_set }
-let names_map_add_assumed_variant (id_to_string : id -> string)
- (id : assumed_ty) (variant_id : VariantId.id) (name : string)
+let names_map_add (id_to_string : id -> string) (id : id) (name : string)
(nm : names_map) : names_map =
- let is_opaque = false in
- names_map_add id_to_string is_opaque
- (VariantId (Assumed id, variant_id))
- name nm
-
-let names_map_add_function (id_to_string : id -> string) (is_opaque : bool)
- (fid : fun_id) (name : string) (nm : names_map) : names_map =
- names_map_add id_to_string is_opaque (FunId fid) name nm
+ (* Check if there is a clash *)
+ names_map_check_collision id_to_string id name nm;
+ (* Sanity check *)
+ if StringSet.mem name nm.names_set then (
+ let err =
+ "Error when registering the name for id: " ^ id_to_string id
+ ^ ":\nThe chosen name is already in the names set: " ^ name
+ in
+ log#serror err;
+ (* If we fail hard on errors, raise an exception *)
+ if !Config.fail_hard then raise (Failure err));
+ (* Insert *)
+ names_map_add_unchecked id name nm
(** The unsafe names map stores mappings from identifiers to names which might
collide. For some backends and some names, it might be acceptable to have
@@ -503,6 +538,8 @@ let names_map_add_function (id_to_string : id -> string) (is_opaque : bool)
*)
type unsafe_names_map = { id_to_name : string IdMap.t }
+let empty_unsafe_names_map = { id_to_name = IdMap.empty }
+
let unsafe_names_map_add (id : id) (name : string) (nm : unsafe_names_map) :
unsafe_names_map =
{ id_to_name = IdMap.add id name nm.id_to_name }
@@ -541,6 +578,24 @@ let basename_to_unique (names_set : StringSet.t)
type fun_name_info = { keep_fwd : bool; num_backs : int }
+type names_maps = {
+ names_map : names_map;
+ (** The map for id to names, where we forbid name collisions
+ (ex.: we always forbid function name collisions). *)
+ unsafe_names_map : unsafe_names_map;
+ (** The map for id to names, where we allow name collisions
+ (ex.: we might allow record field name collisions). *)
+ strict_names_map : names_map;
+ (** This map is a sub-map of [names_map]. For the ids in this map we also
+ forbid collisions with names in the [unsafe_names_map].
+
+ We do so for keywords for instance, but also for types (in a dependently
+ typed language, we might have an issue if the field of a record has, say,
+ the name "u32", and another field of the same record refers to "u32"
+ (for instance in its type).
+ *)
+}
+
(** Extraction context.
Note that the extraction context contains information coming from the
@@ -549,24 +604,12 @@ type fun_name_info = { keep_fwd : bool; num_backs : int }
functions, etc.
*)
type extraction_ctx = {
+ crate : A.crate;
trans_ctx : trans_ctx;
- names_map : names_map;
- (** The map for id to names, where we forbid name collisions
- (ex.: we always forbid function name collisions). *)
- unsafe_names_map : unsafe_names_map;
- (** The map for id to names, where we allow name collisions
- (ex.: we might allow record field name collisions). *)
+ names_maps : names_maps;
fmt : formatter;
indent_incr : int;
(** The indent increment we insert whenever we need to indent more *)
- use_opaque_pre : bool;
- (** Do we use the "opaque_defs." prefix for the opaque definitions?
-
- Opaque function definitions might refer opaque types: if we are in the
- opaque module, we musn't use the "opaque_defs." prefix, otherwise we
- use it.
- Also see {!names_map.opaque_ids}.
- *)
use_dep_ite : bool;
(** For Lean: do we use dependent-if then else expressions?
@@ -586,6 +629,29 @@ type extraction_ctx = {
in case a Rust function only has one backward translation
and we filter the forward function because it returns unit.
*)
+ trait_decl_id : trait_decl_id option;
+ (** If we are extracting a trait declaration, identifies it *)
+ is_provided_method : bool;
+ trans_types : Pure.type_decl Pure.TypeDeclId.Map.t;
+ trans_funs : pure_fun_translation A.FunDeclId.Map.t;
+ functions_with_decreases_clause : PureUtils.FunLoopIdSet.t;
+ trans_trait_decls : Pure.trait_decl Pure.TraitDeclId.Map.t;
+ trans_trait_impls : Pure.trait_impl Pure.TraitImplId.Map.t;
+ types_filter_type_args_map : bool list TypeDeclId.Map.t;
+ (** The map to filter the type arguments for the builtin type
+ definitions.
+
+ We need this for type `Vec`, for instance, which takes a useless
+ (in the context of the type translation) type argument for the
+ allocator which is used, and which we want to remove.
+
+ TODO: it would be cleaner to filter those types in a micro-pass,
+ rather than at code generation time.
+ *)
+ funs_filter_type_args_map : bool list FunDeclId.Map.t;
+ (** Same as {!types_filter_type_args_map}, but for functions *)
+ trait_impls_filter_type_args_map : bool list TraitImplId.Map.t;
+ (** Same as {!types_filter_type_args_map}, but for trait implementations *)
}
(** Debugging function, used when communicating name collisions to the user,
@@ -593,9 +659,16 @@ type extraction_ctx = {
instance).
*)
let id_to_string (id : id) (ctx : extraction_ctx) : string =
- let global_decls = ctx.trans_ctx.global_context.global_decls in
- let fun_decls = ctx.trans_ctx.fun_context.fun_decls in
- let type_decls = ctx.trans_ctx.type_context.type_decls in
+ let global_decls = ctx.trans_ctx.global_ctx.global_decls in
+ let fun_decls = ctx.trans_ctx.fun_ctx.fun_decls in
+ let type_decls = ctx.trans_ctx.type_ctx.type_decls in
+ let trait_decls = ctx.trans_ctx.trait_decls_ctx.trait_decls in
+ let trait_decl_id_to_string (id : A.TraitDeclId.id) : string =
+ let trait_name =
+ Print.fun_name_to_string (A.TraitDeclId.Map.find id trait_decls).name
+ in
+ "trait_decl: " ^ trait_name ^ " (id: " ^ A.TraitDeclId.to_string id ^ ")"
+ in
(* TODO: factorize the pretty-printing with what is in PrintPure *)
let get_type_name (id : type_id) : string =
match id with
@@ -614,10 +687,17 @@ let id_to_string (id : id) (ctx : extraction_ctx) : string =
| FromLlbc (fid, lp_id, rg_id) ->
let fun_name =
match fid with
- | Regular fid ->
+ | FunId (Regular fid) ->
Print.fun_name_to_string
(A.FunDeclId.Map.find fid fun_decls).name
- | Assumed aid -> A.show_assumed_fun_id aid
+ | FunId (Assumed aid) -> A.show_assumed_fun_id aid
+ | TraitMethod (trait_ref, method_name, _) ->
+ (* Shouldn't happen *)
+ if !Config.fail_hard then raise (Failure "Unexpected")
+ else
+ "Trait method: decl: "
+ ^ TraitDeclId.to_string trait_ref.trait_decl_ref.trait_decl_id
+ ^ ", method_name: " ^ method_name
in
let lp_kind =
@@ -673,12 +753,16 @@ let id_to_string (id : id) (ctx : extraction_ctx) : string =
if variant_id = error_failure_id then "@error::Failure"
else if variant_id = error_out_of_fuel_id then "@error::OutOfFuel"
else raise (Failure "Unreachable")
- | Assumed Option ->
- if variant_id = option_some_id then "@option::Some"
- else if variant_id = option_none_id then "@option::None"
+ | Assumed Fuel ->
+ if variant_id = fuel_zero_id then "@fuel::0"
+ else if variant_id = fuel_succ_id then "@fuel::Succ"
else raise (Failure "Unreachable")
- | Assumed (State | Vec | Fuel | Array | Slice | Str | Range) ->
- raise (Failure "Unreachable")
+ | Assumed (State | Array | Slice | Str | RawPtr _) ->
+ raise
+ (Failure
+ ("Unreachable: variant id ("
+ ^ VariantId.to_string variant_id
+ ^ ") for " ^ show_type_id id))
| AdtId id -> (
let def = TypeDeclId.Map.find id type_decls in
match def.kind with
@@ -693,8 +777,7 @@ let id_to_string (id : id) (ctx : extraction_ctx) : string =
match id with
| Tuple -> raise (Failure "Unreachable")
| Assumed
- ( State | Result | Error | Fuel | Option | Vec | Array | Slice | Str
- | Range ) ->
+ (State | Result | Error | Fuel | Array | Slice | Str | RawPtr _) ->
(* We can't directly have access to the fields of those types *)
raise (Failure "Unreachable")
| AdtId id -> (
@@ -716,134 +799,265 @@ let id_to_string (id : id) (ctx : extraction_ctx) : string =
| ConstGenericVarId id ->
"const_generic_var_id: " ^ ConstGenericVarId.to_string id
| VarId id -> "var_id: " ^ VarId.to_string id
+ | TraitDeclId id -> "trait_decl_id: " ^ TraitDeclId.to_string id
+ | TraitImplId id -> "trait_impl_id: " ^ TraitImplId.to_string id
+ | LocalTraitClauseId id ->
+ "local_trait_clause_id: " ^ TraitClauseId.to_string id
+ | TraitDeclConstructorId id ->
+ "trait_decl_constructor: " ^ trait_decl_id_to_string id
+ | TraitParentClauseId (id, clause_id) ->
+ "trait_parent_clause_id: " ^ trait_decl_id_to_string id ^ ", clause_id: "
+ ^ TraitClauseId.to_string clause_id
+ | TraitItemClauseId (id, item_name, clause_id) ->
+ "trait_item_clause_id: " ^ trait_decl_id_to_string id ^ ", item name: "
+ ^ item_name ^ ", clause_id: "
+ ^ TraitClauseId.to_string clause_id
+ | TraitItemId (id, name) ->
+ "trait_item_id: " ^ trait_decl_id_to_string id ^ ", type name: " ^ name
+ | TraitMethodId (trait_decl_id, fun_name, rg_id) ->
+ let fwd_back_kind =
+ match rg_id with
+ | None -> "forward"
+ | Some rg_id -> "backward " ^ RegionGroupId.to_string rg_id
+ in
+ trait_decl_id_to_string trait_decl_id
+ ^ ", method name (" ^ fwd_back_kind ^ "): " ^ fun_name
+ | TraitSelfClauseId -> "trait_self_clause"
+
+(** Return [true] if we are strict on collisions for this id (i.e., we forbid
+ collisions even with the ids in the unsafe names map) *)
+let strict_collisions (id : id) : bool =
+ match id with UnknownId | TypeId _ -> true | _ -> false
(** We might not check for collisions for some specific ids (ex.: field names) *)
let allow_collisions (id : id) : bool =
match id with
- | FieldId (_, _) -> !Config.record_fields_short_names
+ | FieldId _ | TraitItemClauseId _ | TraitParentClauseId _ | TraitItemId _
+ | TraitMethodId _ ->
+ !Config.record_fields_short_names
+ | FunId (Pure _ | FromLlbc (FunId (Assumed _), _, _)) ->
+ (* We map several assumed functions to the same id *)
+ true
| _ -> false
-let ctx_add (is_opaque : bool) (id : id) (name : string) (ctx : extraction_ctx)
- : extraction_ctx =
- (* We do not use the same name map if we allow/disallow collisions *)
+(** The [id_to_string] function to print nice debugging messages if there are
+ collisions *)
+let names_maps_add (id_to_string : id -> string) (id : id) (name : string)
+ (nm : names_maps) : names_maps =
+ (* We do not use the same name map if we allow/disallow collisions.
+ We notably use it for field names: some backends like Lean can use the
+ type information to disambiguate field projections.
+
+ Remark: we still need to check that those "unsafe" ids don't collide with
+ the ids that we mark as "strict on collision".
+
+ For instance, we don't allow naming a field "let". We enforce this by
+ not checking collision between ids for which we permit collisions (ex.:
+ between fields), but still checking collisions between those ids and the
+ others (ex.: fields and keywords).
+ *)
if allow_collisions id then (
- assert (not is_opaque);
+ (* Check with the ids which are considered to be strict on collisions *)
+ names_map_check_collision id_to_string id name nm.strict_names_map;
{
- ctx with
- unsafe_names_map = unsafe_names_map_add id name ctx.unsafe_names_map;
+ nm with
+ unsafe_names_map = unsafe_names_map_add id name nm.unsafe_names_map;
})
else
- (* The id_to_string function to print nice debugging messages if there are
- * collisions *)
- let id_to_string (id : id) : string = id_to_string id ctx in
- let names_map =
- names_map_add id_to_string is_opaque id name ctx.names_map
+ (* Remark: if we are strict on collisions:
+ - we add the id to the strict collisions map
+ - we check that the id doesn't collide with the unsafe map
+ TODO: we might not check that:
+ - a user defined function doesn't collide with an assumed function
+ - two trait decl items don't collide with each other
+ *)
+ let strict_names_map =
+ if strict_collisions id then
+ names_map_add id_to_string id name nm.strict_names_map
+ else nm.strict_names_map
in
- { ctx with names_map }
+ let names_map = names_map_add id_to_string id name nm.names_map in
+ { nm with strict_names_map; names_map }
+
+let ctx_add (id : id) (name : string) (ctx : extraction_ctx) : extraction_ctx =
+ let id_to_string (id : id) : string = id_to_string id ctx in
+ let names_maps = names_maps_add id_to_string id name ctx.names_maps in
+ { ctx with names_maps }
-(** [with_opaque_pre]: if [true] and the definition is opaque, add the opaque prefix *)
-let ctx_get (with_opaque_pre : bool) (id : id) (ctx : extraction_ctx) : string =
+(** The [id_to_string] function to print nice debugging messages if there are
+ collisions *)
+let names_maps_get (id_to_string : id -> string) (id : id) (nm : names_maps) :
+ string =
(* We do not use the same name map if we allow/disallow collisions *)
- if allow_collisions id then IdMap.find id ctx.unsafe_names_map.id_to_name
+ let map_to_string (m : string IdMap.t) : string =
+ "[\n"
+ ^ String.concat ","
+ (List.map
+ (fun (id, n) -> "\n " ^ id_to_string id ^ " -> " ^ n)
+ (IdMap.bindings m))
+ ^ "\n]"
+ in
+ if allow_collisions id then (
+ let m = nm.unsafe_names_map.id_to_name in
+ match IdMap.find_opt id m with
+ | Some s -> s
+ | None ->
+ let err =
+ "Could not find: " ^ id_to_string id ^ "\nNames map:\n"
+ ^ map_to_string m
+ in
+ log#serror err;
+ if !Config.fail_hard then raise (Failure err)
+ else "(%%%ERROR: unknown identifier\": " ^ id_to_string id ^ "\"%%%)")
else
- match IdMap.find_opt id ctx.names_map.id_to_name with
- | Some s ->
- let is_opaque = IdSet.mem id ctx.names_map.opaque_ids in
- if with_opaque_pre && is_opaque then ctx.fmt.opaque_pre () ^ s else s
+ let m = nm.names_map.id_to_name in
+ match IdMap.find_opt id m with
+ | Some s -> s
| None ->
- log#serror ("Could not find: " ^ id_to_string id ctx);
- raise Not_found
+ let err =
+ "Could not find: " ^ id_to_string id ^ "\nNames map:\n"
+ ^ map_to_string m
+ in
+ log#serror err;
+ if !Config.fail_hard then raise (Failure err)
+ else "(ERROR: \"" ^ id_to_string id ^ "\")"
+
+let ctx_get (id : id) (ctx : extraction_ctx) : string =
+ let id_to_string (id : id) : string = id_to_string id ctx in
+ names_maps_get id_to_string id ctx.names_maps
+
+let names_maps_add_assumed_type (id_to_string : id -> string) (id : assumed_ty)
+ (name : string) (nm : names_maps) : names_maps =
+ names_maps_add id_to_string (TypeId (Assumed id)) name nm
+
+let names_maps_add_assumed_struct (id_to_string : id -> string)
+ (id : assumed_ty) (name : string) (nm : names_maps) : names_maps =
+ names_maps_add id_to_string (StructId (Assumed id)) name nm
-let ctx_get_global (with_opaque_pre : bool) (id : A.GlobalDeclId.id)
+let names_maps_add_assumed_variant (id_to_string : id -> string)
+ (id : assumed_ty) (variant_id : VariantId.id) (name : string)
+ (nm : names_maps) : names_maps =
+ names_maps_add id_to_string (VariantId (Assumed id, variant_id)) name nm
+
+let names_maps_add_function (id_to_string : id -> string) (fid : fun_id)
+ (name : string) (nm : names_maps) : names_maps =
+ names_maps_add id_to_string (FunId fid) name nm
+
+let ctx_get_global (id : A.GlobalDeclId.id) (ctx : extraction_ctx) : string =
+ ctx_get (GlobalId id) ctx
+
+let ctx_get_function (id : fun_id) (ctx : extraction_ctx) : string =
+ ctx_get (FunId id) ctx
+
+let ctx_get_local_function (id : A.FunDeclId.id) (lp : LoopId.id option)
+ (rg : RegionGroupId.id option) (ctx : extraction_ctx) : string =
+ ctx_get_function (FromLlbc (FunId (Regular id), lp, rg)) ctx
+
+let ctx_get_type (id : type_id) (ctx : extraction_ctx) : string =
+ assert (id <> Tuple);
+ ctx_get (TypeId id) ctx
+
+let ctx_get_local_type (id : TypeDeclId.id) (ctx : extraction_ctx) : string =
+ ctx_get_type (AdtId id) ctx
+
+let ctx_get_assumed_type (id : assumed_ty) (ctx : extraction_ctx) : string =
+ ctx_get_type (Assumed id) ctx
+
+let ctx_get_trait_constructor (id : trait_decl_id) (ctx : extraction_ctx) :
+ string =
+ ctx_get (TraitDeclConstructorId id) ctx
+
+let ctx_get_trait_self_clause (ctx : extraction_ctx) : string =
+ ctx_get TraitSelfClauseId ctx
+
+let ctx_get_trait_decl (id : trait_decl_id) (ctx : extraction_ctx) : string =
+ ctx_get (TraitDeclId id) ctx
+
+let ctx_get_trait_impl (id : trait_impl_id) (ctx : extraction_ctx) : string =
+ ctx_get (TraitImplId id) ctx
+
+let ctx_get_trait_item (id : trait_decl_id) (item_name : string)
(ctx : extraction_ctx) : string =
- ctx_get with_opaque_pre (GlobalId id) ctx
+ ctx_get (TraitItemId (id, item_name)) ctx
-let ctx_get_function (with_opaque_pre : bool) (id : fun_id)
+let ctx_get_trait_const (id : trait_decl_id) (item_name : string)
(ctx : extraction_ctx) : string =
- ctx_get with_opaque_pre (FunId id) ctx
+ ctx_get_trait_item id item_name ctx
-let ctx_get_local_function (with_opaque_pre : bool) (id : A.FunDeclId.id)
- (lp : LoopId.id option) (rg : RegionGroupId.id option)
+let ctx_get_trait_type (id : trait_decl_id) (item_name : string)
(ctx : extraction_ctx) : string =
- ctx_get_function with_opaque_pre (FromLlbc (Regular id, lp, rg)) ctx
+ ctx_get_trait_item id item_name ctx
-let ctx_get_type (with_opaque_pre : bool) (id : type_id) (ctx : extraction_ctx)
- : string =
- assert (id <> Tuple);
- ctx_get with_opaque_pre (TypeId id) ctx
+let ctx_get_trait_method (id : trait_decl_id) (item_name : string)
+ (rg_id : T.RegionGroupId.id option) (ctx : extraction_ctx) : string =
+ ctx_get (TraitMethodId (id, item_name, rg_id)) ctx
-let ctx_get_local_type (with_opaque_pre : bool) (id : TypeDeclId.id)
+let ctx_get_trait_parent_clause (id : trait_decl_id) (clause : trait_clause_id)
(ctx : extraction_ctx) : string =
- ctx_get_type with_opaque_pre (AdtId id) ctx
+ ctx_get (TraitParentClauseId (id, clause)) ctx
-let ctx_get_assumed_type (id : assumed_ty) (ctx : extraction_ctx) : string =
- (* In practice, the assumed types are opaque. However, assumed types
- are never grouped in the opaque module, meaning we never need to
- prefix them: we thus consider them as non-opaque with regards to the
- names map.
- *)
- let is_opaque = false in
- ctx_get_type is_opaque (Assumed id) ctx
+let ctx_get_trait_item_clause (id : trait_decl_id) (item : string)
+ (clause : trait_clause_id) (ctx : extraction_ctx) : string =
+ ctx_get (TraitItemClauseId (id, item, clause)) ctx
let ctx_get_var (id : VarId.id) (ctx : extraction_ctx) : string =
- let is_opaque = false in
- ctx_get is_opaque (VarId id) ctx
+ ctx_get (VarId id) ctx
let ctx_get_type_var (id : TypeVarId.id) (ctx : extraction_ctx) : string =
- let is_opaque = false in
- ctx_get is_opaque (TypeVarId id) ctx
+ ctx_get (TypeVarId id) ctx
let ctx_get_const_generic_var (id : ConstGenericVarId.id) (ctx : extraction_ctx)
: string =
- let is_opaque = false in
- ctx_get is_opaque (ConstGenericVarId id) ctx
+ ctx_get (ConstGenericVarId id) ctx
+
+let ctx_get_local_trait_clause (id : TraitClauseId.id) (ctx : extraction_ctx) :
+ string =
+ ctx_get (LocalTraitClauseId id) ctx
let ctx_get_field (type_id : type_id) (field_id : FieldId.id)
(ctx : extraction_ctx) : string =
- let is_opaque = false in
- ctx_get is_opaque (FieldId (type_id, field_id)) ctx
+ ctx_get (FieldId (type_id, field_id)) ctx
-let ctx_get_struct (with_opaque_pre : bool) (def_id : type_id)
- (ctx : extraction_ctx) : string =
- ctx_get with_opaque_pre (StructId def_id) ctx
+let ctx_get_struct (def_id : type_id) (ctx : extraction_ctx) : string =
+ ctx_get (StructId def_id) ctx
let ctx_get_variant (def_id : type_id) (variant_id : VariantId.id)
(ctx : extraction_ctx) : string =
- let is_opaque = false in
- ctx_get is_opaque (VariantId (def_id, variant_id)) ctx
+ ctx_get (VariantId (def_id, variant_id)) ctx
let ctx_get_decreases_proof (def_id : A.FunDeclId.id)
(loop_id : LoopId.id option) (ctx : extraction_ctx) : string =
- let is_opaque = false in
- ctx_get is_opaque (DecreasesProofId (Regular def_id, loop_id)) ctx
+ ctx_get (DecreasesProofId (Regular def_id, loop_id)) ctx
let ctx_get_termination_measure (def_id : A.FunDeclId.id)
(loop_id : LoopId.id option) (ctx : extraction_ctx) : string =
- let is_opaque = false in
- ctx_get is_opaque (TerminationMeasureId (Regular def_id, loop_id)) ctx
+ ctx_get (TerminationMeasureId (Regular def_id, loop_id)) ctx
(** Generate a unique type variable name and add it to the context *)
let ctx_add_type_var (basename : string) (id : TypeVarId.id)
(ctx : extraction_ctx) : extraction_ctx * string =
- let is_opaque = false in
- let name = ctx.fmt.type_var_basename ctx.names_map.names_set basename in
let name =
- basename_to_unique ctx.names_map.names_set ctx.fmt.append_index name
+ ctx.fmt.type_var_basename ctx.names_maps.names_map.names_set basename
+ in
+ let name =
+ basename_to_unique ctx.names_maps.names_map.names_set ctx.fmt.append_index
+ name
in
- let ctx = ctx_add is_opaque (TypeVarId id) name ctx in
+ let ctx = ctx_add (TypeVarId id) name ctx in
(ctx, name)
(** Generate a unique const generic variable name and add it to the context *)
let ctx_add_const_generic_var (basename : string) (id : ConstGenericVarId.id)
(ctx : extraction_ctx) : extraction_ctx * string =
- let is_opaque = false in
let name =
- ctx.fmt.const_generic_var_basename ctx.names_map.names_set basename
+ ctx.fmt.const_generic_var_basename ctx.names_maps.names_map.names_set
+ basename
in
let name =
- basename_to_unique ctx.names_map.names_set ctx.fmt.append_index name
+ basename_to_unique ctx.names_maps.names_map.names_set ctx.fmt.append_index
+ name
in
- let ctx = ctx_add is_opaque (ConstGenericVarId id) name ctx in
+ let ctx = ctx_add (ConstGenericVarId id) name ctx in
(ctx, name)
(** See {!ctx_add_type_var} *)
@@ -856,11 +1070,31 @@ let ctx_add_type_vars (vars : (string * TypeVarId.id) list)
(** Generate a unique variable name and add it to the context *)
let ctx_add_var (basename : string) (id : VarId.id) (ctx : extraction_ctx) :
extraction_ctx * string =
- let is_opaque = false in
let name =
- basename_to_unique ctx.names_map.names_set ctx.fmt.append_index basename
+ basename_to_unique ctx.names_maps.names_map.names_set ctx.fmt.append_index
+ basename
in
- let ctx = ctx_add is_opaque (VarId id) name ctx in
+ let ctx = ctx_add (VarId id) name ctx in
+ (ctx, name)
+
+(** Generate a unique variable name for the trait self clause and add it to the context *)
+let ctx_add_trait_self_clause (ctx : extraction_ctx) : extraction_ctx * string =
+ let basename = ctx.fmt.trait_self_clause_basename in
+ let name =
+ basename_to_unique ctx.names_maps.names_map.names_set ctx.fmt.append_index
+ basename
+ in
+ let ctx = ctx_add TraitSelfClauseId name ctx in
+ (ctx, name)
+
+(** Generate a unique trait clause name and add it to the context *)
+let ctx_add_local_trait_clause (basename : string) (id : TraitClauseId.id)
+ (ctx : extraction_ctx) : extraction_ctx * string =
+ let name =
+ basename_to_unique ctx.names_maps.names_map.names_set ctx.fmt.append_index
+ basename
+ in
+ let ctx = ctx_add (LocalTraitClauseId id) name ctx in
(ctx, name)
(** See {!ctx_add_var} *)
@@ -868,7 +1102,9 @@ let ctx_add_vars (vars : var list) (ctx : extraction_ctx) :
extraction_ctx * string list =
List.fold_left_map
(fun ctx (v : var) ->
- let name = ctx.fmt.var_basename ctx.names_map.names_set v.basename v.ty in
+ let name =
+ ctx.fmt.var_basename ctx.names_maps.names_map.names_set v.basename v.ty
+ in
ctx_add_var name v.id ctx)
ctx vars
@@ -885,142 +1121,105 @@ let ctx_add_const_generic_params (vars : const_generic_var list)
ctx_add_const_generic_var var.name var.index ctx)
ctx vars
-let ctx_add_type_const_generic_params (tvars : type_var list)
- (cgvars : const_generic_var list) (ctx : extraction_ctx) :
- extraction_ctx * string list * string list =
- let ctx, tys = ctx_add_type_params tvars ctx in
- let ctx, cgs = ctx_add_const_generic_params cgvars ctx in
- (ctx, tys, cgs)
-
-let ctx_add_type_decl_struct (def : type_decl) (ctx : extraction_ctx) :
- extraction_ctx * string =
- assert (match def.kind with Struct _ -> true | _ -> false);
- let is_opaque = false in
- let cons_name = ctx.fmt.struct_constructor def.name in
- let ctx = ctx_add is_opaque (StructId (AdtId def.def_id)) cons_name ctx in
- (ctx, cons_name)
-
-let ctx_add_type_decl (def : type_decl) (ctx : extraction_ctx) : extraction_ctx
- =
- let is_opaque = def.kind = Opaque in
- let def_name = ctx.fmt.type_name def.name in
- let ctx = ctx_add is_opaque (TypeId (AdtId def.def_id)) def_name ctx in
- ctx
-
-let ctx_add_field (def : type_decl) (field_id : FieldId.id) (field : field)
- (ctx : extraction_ctx) : extraction_ctx * string =
- let is_opaque = false in
- let name = ctx.fmt.field_name def.name field_id field.field_name in
- let ctx = ctx_add is_opaque (FieldId (AdtId def.def_id, field_id)) name ctx in
- (ctx, name)
-
-let ctx_add_fields (def : type_decl) (fields : (FieldId.id * field) list)
+let ctx_add_local_trait_clauses (clauses : trait_clause list)
(ctx : extraction_ctx) : extraction_ctx * string list =
List.fold_left_map
- (fun ctx (vid, v) -> ctx_add_field def vid v ctx)
- ctx fields
-
-let ctx_add_variant (def : type_decl) (variant_id : VariantId.id)
- (variant : variant) (ctx : extraction_ctx) : extraction_ctx * string =
- let is_opaque = false in
- let name = ctx.fmt.variant_name def.name variant.variant_name in
- (* Add the type name prefix for Lean *)
- let name =
- if !Config.backend = Lean then
- let type_name = ctx.fmt.type_name def.name in
- type_name ^ "." ^ name
- else name
- in
- let ctx =
- ctx_add is_opaque (VariantId (AdtId def.def_id, variant_id)) name ctx
- in
- (ctx, name)
-
-let ctx_add_variants (def : type_decl)
- (variants : (VariantId.id * variant) list) (ctx : extraction_ctx) :
- extraction_ctx * string list =
- List.fold_left_map
- (fun ctx (vid, v) -> ctx_add_variant def vid v ctx)
- ctx variants
+ (fun ctx (c : trait_clause) ->
+ let basename =
+ ctx.fmt.trait_clause_basename ctx.names_maps.names_map.names_set c
+ in
+ ctx_add_local_trait_clause basename c.clause_id ctx)
+ ctx clauses
-let ctx_add_struct (def : type_decl) (ctx : extraction_ctx) :
- extraction_ctx * string =
- assert (match def.kind with Struct _ -> true | _ -> false);
- let is_opaque = false in
- let name = ctx.fmt.struct_constructor def.name in
- let ctx = ctx_add is_opaque (StructId (AdtId def.def_id)) name ctx in
- (ctx, name)
+(** Returns the lists of names for:
+ - the type variables
+ - the const generic variables
+ - the trait clauses
+ *)
+let ctx_add_generic_params (generics : generic_params) (ctx : extraction_ctx) :
+ extraction_ctx * string list * string list * string list =
+ let { types; const_generics; trait_clauses } = generics in
+ let ctx, tys = ctx_add_type_params types ctx in
+ let ctx, cgs = ctx_add_const_generic_params const_generics ctx in
+ let ctx, tcs = ctx_add_local_trait_clauses trait_clauses ctx in
+ (ctx, tys, cgs, tcs)
let ctx_add_decreases_proof (def : fun_decl) (ctx : extraction_ctx) :
extraction_ctx =
- let is_opaque = false in
let name =
ctx.fmt.decreases_proof_name def.def_id def.basename def.num_loops
def.loop_id
in
- ctx_add is_opaque
- (DecreasesProofId (Regular def.def_id, def.loop_id))
- name ctx
+ ctx_add (DecreasesProofId (Regular def.def_id, def.loop_id)) name ctx
let ctx_add_termination_measure (def : fun_decl) (ctx : extraction_ctx) :
extraction_ctx =
- let is_opaque = false in
let name =
ctx.fmt.termination_measure_name def.def_id def.basename def.num_loops
def.loop_id
in
- ctx_add is_opaque
- (TerminationMeasureId (Regular def.def_id, def.loop_id))
- name ctx
+ ctx_add (TerminationMeasureId (Regular def.def_id, def.loop_id)) name ctx
let ctx_add_global_decl_and_body (def : A.global_decl) (ctx : extraction_ctx) :
extraction_ctx =
(* TODO: update once the body id can be an option *)
- let is_opaque = false in
- let name = ctx.fmt.global_name def.name in
let decl = GlobalId def.def_id in
- let body = FunId (FromLlbc (Regular def.body_id, None, None)) in
- let ctx = ctx_add is_opaque decl (name ^ "_c") ctx in
- let ctx = ctx_add is_opaque body (name ^ "_body") ctx in
- ctx
-let ctx_add_fun_decl (trans_group : bool * pure_fun_translation)
- (def : fun_decl) (ctx : extraction_ctx) : extraction_ctx =
- (* Sanity check: the function should not be a global body - those are handled
- * separately *)
- assert (not def.is_global_decl_body);
+ (* Check if the global corresponds to an assumed global that we should map
+ to a custom definition in our standard library (for instance, happens
+ with "core::num::usize::MAX") *)
+ let sname = name_to_simple_name def.name in
+ match SimpleNameMap.find_opt sname builtin_globals_map with
+ | Some name ->
+ (* Yes: register the custom binding *)
+ ctx_add decl name ctx
+ | None ->
+ (* Not the case: "standard" registration *)
+ let name = ctx.fmt.global_name def.name in
+ let body = FunId (FromLlbc (FunId (Regular def.body_id), None, None)) in
+ let ctx = ctx_add decl (name ^ "_c") ctx in
+ let ctx = ctx_add body (name ^ "_body") ctx in
+ ctx
+
+let ctx_compute_fun_name (trans_group : pure_fun_translation) (def : fun_decl)
+ (ctx : extraction_ctx) : string =
(* Lookup the LLBC def to compute the region group information *)
let def_id = def.def_id in
- let llbc_def =
- A.FunDeclId.Map.find def_id ctx.trans_ctx.fun_context.fun_decls
- in
+ let llbc_def = A.FunDeclId.Map.find def_id ctx.trans_ctx.fun_ctx.fun_decls in
let sg = llbc_def.signature in
let num_rgs = List.length sg.regions_hierarchy in
- let keep_fwd, (_, backs) = trans_group in
+ let { keep_fwd; fwd = _; backs } = trans_group in
let num_backs = List.length backs in
let rg_info =
match def.back_id with
| None -> None
| Some rg_id ->
let rg = T.RegionGroupId.nth sg.regions_hierarchy rg_id in
- let regions =
+ let region_names =
List.map
- (fun rid -> T.RegionVarId.nth sg.region_params rid)
+ (fun rid -> (T.RegionVarId.nth sg.generics.regions rid).name)
rg.regions
in
- let region_names =
- List.map (fun (r : T.region_var) -> r.name) regions
- in
Some { id = rg_id; region_names }
in
- let is_opaque = def.body = None in
(* Add the function name *)
- let def_name =
- ctx.fmt.fun_name def.basename def.num_loops def.loop_id num_rgs rg_info
- (keep_fwd, num_backs)
- in
- let fun_id = (A.Regular def_id, def.loop_id, def.back_id) in
- let ctx = ctx_add is_opaque (FunId (FromLlbc fun_id)) def_name ctx in
+ ctx.fmt.fun_name def.basename def.num_loops def.loop_id num_rgs rg_info
+ (keep_fwd, num_backs)
+
+(* TODO: move to Extract *)
+let ctx_add_fun_decl (trans_group : pure_fun_translation) (def : fun_decl)
+ (ctx : extraction_ctx) : extraction_ctx =
+ (* Sanity check: the function should not be a global body - those are handled
+ * separately *)
+ assert (not def.is_global_decl_body);
+ (* Lookup the LLBC def to compute the region group information *)
+ let def_id = def.def_id in
+ let { keep_fwd; fwd = _; backs } = trans_group in
+ let num_backs = List.length backs in
+ (* Add the function name *)
+ let def_name = ctx_compute_fun_name trans_group def ctx in
+ let fun_id = (Pure.FunId (Regular def_id), def.loop_id, def.back_id) in
+ let ctx = ctx_add (FunId (FromLlbc fun_id)) def_name ctx in
(* Add the name info *)
{
ctx with
@@ -1039,9 +1238,10 @@ type names_map_init = {
assumed_pure_functions : (pure_assumed_fun_id * string) list;
}
-(** Initialize a names map with a proper set of keywords/names coming from the
+(** Initialize names maps with a proper set of keywords/names coming from the
target language/prover. *)
-let initialize_names_map (fmt : formatter) (init : names_map_init) : names_map =
+let initialize_names_maps (fmt : formatter) (init : names_map_init) : names_maps
+ =
let int_names = List.map fmt.int_name T.all_int_types in
let keywords =
List.concat
@@ -1049,20 +1249,30 @@ let initialize_names_map (fmt : formatter) (init : names_map_init) : names_map =
[ fmt.bool_name; fmt.char_name; fmt.str_name ]; int_names; init.keywords;
]
in
- let names_set = StringSet.of_list keywords in
- let name_to_id =
- StringMap.of_list (List.map (fun x -> (x, UnknownId)) keywords)
- in
- let opaque_ids = IdSet.empty in
+ let names_set = StringSet.empty in
+ let name_to_id = StringMap.empty in
(* We fist initialize [id_to_name] as empty, because the id of a keyword is [UnknownId].
* Also note that we don't need this mapping for keywords: we insert keywords only
* to check collisions. *)
let id_to_name = IdMap.empty in
- let nm = { id_to_name; name_to_id; names_set; opaque_ids } in
+ let names_map = { id_to_name; name_to_id; names_set } in
+ let unsafe_names_map = empty_unsafe_names_map in
+ let strict_names_map = empty_names_map in
(* For debugging - we are creating bindings for assumed types and functions, so
* it is ok if we simply use the "show" function (those aren't simply identified
* by numbers) *)
let id_to_string = show_id in
+ (* Add the keywords as strict collisions *)
+ let strict_names_map =
+ List.fold_left
+ (fun nm name ->
+ (* There is duplication in the keywords so we don't check the collisions
+ while registering them (what is important is that there are no collisions
+ between keywords and user-defined identifiers) *)
+ names_map_add_unchecked UnknownId name nm)
+ strict_names_map keywords
+ in
+ let nm = { names_map; unsafe_names_map; strict_names_map } in
(* Then we add:
* - the assumed types
* - the assumed struct constructors
@@ -1072,37 +1282,31 @@ let initialize_names_map (fmt : formatter) (init : names_map_init) : names_map =
let nm =
List.fold_left
(fun nm (type_id, name) ->
- names_map_add_assumed_type id_to_string type_id name nm)
+ names_maps_add_assumed_type id_to_string type_id name nm)
nm init.assumed_adts
in
let nm =
List.fold_left
(fun nm (type_id, name) ->
- names_map_add_assumed_struct id_to_string type_id name nm)
+ names_maps_add_assumed_struct id_to_string type_id name nm)
nm init.assumed_structs
in
let nm =
List.fold_left
(fun nm (type_id, variant_id, name) ->
- names_map_add_assumed_variant id_to_string type_id variant_id name nm)
+ names_maps_add_assumed_variant id_to_string type_id variant_id name nm)
nm init.assumed_variants
in
let assumed_functions =
List.map
- (fun (fid, rg, name) -> (FromLlbc (A.Assumed fid, None, rg), name))
+ (fun (fid, rg, name) ->
+ (FromLlbc (Pure.FunId (Assumed fid), None, rg), name))
init.assumed_llbc_functions
@ List.map (fun (fid, name) -> (Pure fid, name)) init.assumed_pure_functions
in
let nm =
- (* In practice, the assumed function are opaque. However, assumed functions
- are never grouped in the opaque module, meaning we never need to
- prefix them: we thus consider them as non-opaque with regards to the
- names map.
- *)
- let is_opaque = false in
List.fold_left
- (fun nm (fid, name) ->
- names_map_add_function id_to_string is_opaque fid name nm)
+ (fun nm (fid, name) -> names_maps_add_function id_to_string fid name nm)
nm assumed_functions
in
(* Return *)
@@ -1150,22 +1354,20 @@ let default_fun_suffix (num_loops : int) (loop_id : LoopId.id option)
let rg_suff =
(* TODO: make all the backends match what is done for Lean *)
match rg with
- | None -> (
- match !Config.backend with
- | FStar | Coq | HOL4 -> "_fwd"
- | Lean ->
- (* In order to avoid name conflicts:
- * - if the forward is eliminated, we add the suffix "_fwd" (it won't be used)
- * - otherwise, no suffix (because the backward functions will have a suffix)
- *)
- if num_backs = 1 && not keep_fwd then "_fwd" else "")
+ | None ->
+ if
+ (* In order to avoid name conflicts:
+ * - if the forward is eliminated, we add the suffix "_fwd" (it won't be used)
+ * - otherwise, no suffix (because the backward functions will have a suffix)
+ *)
+ num_backs = 1 && not keep_fwd
+ then "_fwd"
+ else ""
| Some rg ->
assert (num_region_groups > 0 && num_backs > 0);
if num_backs = 1 then
(* Exactly one backward function *)
- match !Config.backend with
- | FStar | Coq | HOL4 -> if not keep_fwd then "_fwd_back" else "_back"
- | Lean -> if not keep_fwd then "" else "_back"
+ if not keep_fwd then "" else "_back"
else if
(* Several region groups/backward functions:
- if all the regions in the group have names, we use those names
diff --git a/compiler/ExtractBuiltin.ml b/compiler/ExtractBuiltin.ml
new file mode 100644
index 00000000..a54ab604
--- /dev/null
+++ b/compiler/ExtractBuiltin.ml
@@ -0,0 +1,648 @@
+(** This file declares external identifiers that we catch to map them to
+ definitions coming from the standard libraries in our backends.
+
+ TODO: there misses trait **implementations**
+ *)
+
+open Names
+open Config
+
+type simple_name = string list [@@deriving show, ord]
+
+let name_to_simple_name (s : name) : simple_name =
+ (* We simply ignore the disambiguators *)
+ List.filter_map (function Ident id -> Some id | Disambiguator _ -> None) s
+
+(** Small helper which cuts a string at the occurrences of "::" *)
+let string_to_simple_name (s : string) : simple_name =
+ (* No function to split by using string separator?? *)
+ let name = String.split_on_char ':' s in
+ List.filter (fun s -> s <> "") name
+
+module SimpleNameOrd = struct
+ type t = simple_name
+
+ let compare = compare_simple_name
+ let to_string = show_simple_name
+ let pp_t = pp_simple_name
+ let show_t = show_simple_name
+end
+
+module SimpleNameMap = Collections.MakeMap (SimpleNameOrd)
+module SimpleNameSet = Collections.MakeSet (SimpleNameOrd)
+
+(** Small utility to memoize some computations *)
+let mk_memoized (f : unit -> 'a) : unit -> 'a =
+ let r = ref None in
+ let g () =
+ match !r with
+ | Some x -> x
+ | None ->
+ let x = f () in
+ r := Some x;
+ x
+ in
+ g
+
+(** Switch between two values depending on the target backend.
+
+ We often compute the same value (typically: a name) if the target
+ is F*, Coq or HOL4, and a different value if the target is Lean.
+ *)
+let backend_choice (fstar_coq_hol4 : 'a) (lean : 'a) : 'a =
+ match !backend with Coq | FStar | HOL4 -> fstar_coq_hol4 | Lean -> lean
+
+let builtin_globals : (string * string) list =
+ [
+ (* Min *)
+ ("core::num::usize::MIN", "core_usize_min");
+ ("core::num::u8::MIN", "core_u8_min");
+ ("core::num::u16::MIN", "core_u16_min");
+ ("core::num::u32::MIN", "core_u32_min");
+ ("core::num::u64::MIN", "core_u64_min");
+ ("core::num::u128::MIN", "core_u128_min");
+ ("core::num::isize::MIN", "core_isize_min");
+ ("core::num::i8::MIN", "core_i8_min");
+ ("core::num::i16::MIN", "core_i16_min");
+ ("core::num::i32::MIN", "core_i32_min");
+ ("core::num::i64::MIN", "core_i64_min");
+ ("core::num::i128::MIN", "core_i128_min");
+ (* Max *)
+ ("core::num::usize::MAX", "core_usize_max");
+ ("core::num::u8::MAX", "core_u8_max");
+ ("core::num::u16::MAX", "core_u16_max");
+ ("core::num::u32::MAX", "core_u32_max");
+ ("core::num::u64::MAX", "core_u64_max");
+ ("core::num::u128::MAX", "core_u128_max");
+ ("core::num::isize::MAX", "core_isize_max");
+ ("core::num::i8::MAX", "core_i8_max");
+ ("core::num::i16::MAX", "core_i16_max");
+ ("core::num::i32::MAX", "core_i32_max");
+ ("core::num::i64::MAX", "core_i64_max");
+ ("core::num::i128::MAX", "core_i128_max");
+ ]
+
+let builtin_globals_map : string SimpleNameMap.t =
+ SimpleNameMap.of_list
+ (List.map (fun (x, y) -> (string_to_simple_name x, y)) builtin_globals)
+
+type builtin_variant_info = { fields : (string * string) list }
+[@@deriving show]
+
+type builtin_enum_variant_info = {
+ rust_variant_name : string;
+ extract_variant_name : string;
+ fields : string list option;
+}
+[@@deriving show]
+
+type builtin_type_body_info =
+ | Struct of string * (string * string) list
+ (* The constructor name and the map for the field names *)
+ | Enum of builtin_enum_variant_info list
+(* For every variant, a map for the field names *)
+[@@deriving show]
+
+type builtin_type_info = {
+ rust_name : string list;
+ extract_name : string;
+ keep_params : bool list option;
+ (** We might want to filter some of the type parameters.
+
+ For instance, `Vec` type takes a type parameter for the allocator,
+ which we want to ignore.
+ *)
+ body_info : builtin_type_body_info option;
+}
+[@@deriving show]
+
+type type_variant_kind =
+ | KOpaque
+ | KStruct of (string * string) list
+ (* TODO: handle the tuple case *)
+ | KEnum (* TODO *)
+
+let mk_struct_constructor (type_name : string) : string =
+ let prefix =
+ match !backend with FStar -> "Mk" | Coq | HOL4 -> "mk" | Lean -> ""
+ in
+ let suffix = match !backend with FStar | Coq | HOL4 -> "" | Lean -> ".mk" in
+ prefix ^ type_name ^ suffix
+
+(** The assumed types.
+
+ The optional list of booleans is filtering information for the type
+ parameters. For instance, in the case of the `Vec` functions, there is
+ a type parameter for the allocator to use, which we want to filter.
+ *)
+let builtin_types () : builtin_type_info list =
+ let mk_type (rust_name : string list) ?(keep_params : bool list option = None)
+ ?(kind : type_variant_kind = KOpaque) () : builtin_type_info =
+ let extract_name =
+ let sep = backend_choice "_" "." in
+ String.concat sep rust_name
+ in
+ let body_info : builtin_type_body_info option =
+ match kind with
+ | KOpaque -> None
+ | KStruct fields ->
+ let fields =
+ List.map
+ (fun (rname, name) ->
+ ( rname,
+ match !backend with
+ | FStar | Lean -> name
+ | Coq | HOL4 -> extract_name ^ "_" ^ name ))
+ fields
+ in
+ let constructor = mk_struct_constructor extract_name in
+ Some (Struct (constructor, fields))
+ | KEnum -> raise (Failure "TODO")
+ in
+ { rust_name; extract_name; keep_params; body_info }
+ in
+
+ [
+ (* Alloc *)
+ mk_type [ "alloc"; "alloc"; "Global" ] ();
+ (* Vec *)
+ mk_type [ "alloc"; "vec"; "Vec" ] ~keep_params:(Some [ true; false ]) ();
+ (* Range *)
+ mk_type
+ [ "core"; "ops"; "range"; "Range" ]
+ ~kind:(KStruct [ ("start", "start"); ("end", "end_") ])
+ ();
+ (* Option
+
+ This one is more custom because we use the standard "option" type from
+ the target backend.
+ *)
+ {
+ rust_name = [ "core"; "option"; "Option" ];
+ extract_name =
+ (match !backend with
+ | Lean -> "Option"
+ | Coq | FStar | HOL4 -> "option");
+ keep_params = None;
+ body_info =
+ Some
+ (Enum
+ [
+ {
+ rust_variant_name = "None";
+ extract_variant_name =
+ (match !backend with
+ | FStar | Coq -> "None"
+ | Lean -> "none"
+ | HOL4 -> "NONE");
+ fields = None;
+ };
+ {
+ rust_variant_name = "Some";
+ extract_variant_name =
+ (match !backend with
+ | FStar | Coq -> "Some"
+ | Lean -> "some"
+ | HOL4 -> "SOME");
+ fields = None;
+ };
+ ]);
+ };
+ ]
+
+let mk_builtin_types_map () =
+ SimpleNameMap.of_list
+ (List.map (fun info -> (info.rust_name, info)) (builtin_types ()))
+
+let builtin_types_map = mk_memoized mk_builtin_types_map
+
+type builtin_fun_info = {
+ rg : Types.RegionGroupId.id option;
+ extract_name : string;
+}
+[@@deriving show]
+
+(** The assumed functions.
+
+ The optional list of booleans is filtering information for the type
+ parameters. For instance, in the case of the `Vec` functions, there is
+ a type parameter for the allocator to use, which we want to filter.
+ *)
+let builtin_funs () :
+ (string list * bool list option * builtin_fun_info list) list =
+ let rg0 = Some Types.RegionGroupId.zero in
+ (* Small utility *)
+ let mk_fun (name : string list) (extract_name : string list option)
+ (filter : bool list option) (with_back : bool) (back_no_suffix : bool) :
+ string list * bool list option * builtin_fun_info list =
+ let extract_name =
+ match extract_name with None -> name | Some name -> name
+ in
+ let basename =
+ match !backend with
+ | FStar | Coq | HOL4 -> String.concat "_" extract_name
+ | Lean -> String.concat "." extract_name
+ in
+ let fwd_suffix = if with_back && back_no_suffix then "_fwd" else "" in
+ let fwd = [ { rg = None; extract_name = basename ^ fwd_suffix } ] in
+ let back_suffix = if with_back && back_no_suffix then "" else "_back" in
+ let back =
+ if with_back then [ { rg = rg0; extract_name = basename ^ back_suffix } ]
+ else []
+ in
+ (name, filter, fwd @ back)
+ in
+ [
+ mk_fun [ "core"; "mem"; "replace" ] None None true false;
+ mk_fun [ "alloc"; "vec"; "Vec"; "new" ] None None false false;
+ mk_fun
+ [ "alloc"; "vec"; "Vec"; "push" ]
+ None
+ (Some [ true; false ])
+ true true;
+ mk_fun
+ [ "alloc"; "vec"; "Vec"; "insert" ]
+ None
+ (Some [ true; false ])
+ true true;
+ mk_fun
+ [ "alloc"; "vec"; "Vec"; "len" ]
+ None
+ (Some [ true; false ])
+ true false;
+ mk_fun
+ [ "alloc"; "vec"; "Vec"; "index" ]
+ None
+ (Some [ true; true; false ])
+ true false;
+ mk_fun
+ [ "alloc"; "vec"; "Vec"; "index_mut" ]
+ None
+ (Some [ true; true; false ])
+ true false;
+ mk_fun
+ [ "alloc"; "boxed"; "Box"; "deref" ]
+ None
+ (Some [ true; false ])
+ true false;
+ mk_fun
+ [ "alloc"; "boxed"; "Box"; "deref_mut" ]
+ None
+ (Some [ true; false ])
+ true false;
+ (* TODO: fix the same like "[T]" below *)
+ mk_fun
+ [ "core"; "slice"; "index"; "[T]"; "index" ]
+ (Some [ "core"; "slice"; "index"; "Slice"; "index" ])
+ None true false;
+ mk_fun
+ [ "core"; "slice"; "index"; "[T]"; "index_mut" ]
+ (Some [ "core"; "slice"; "index"; "Slice"; "index_mut" ])
+ None true false;
+ mk_fun
+ [ "core"; "array"; "[T; N]"; "index" ]
+ (Some [ "core"; "array"; "Array"; "index" ])
+ None true false;
+ mk_fun
+ [ "core"; "array"; "[T; N]"; "index_mut" ]
+ (Some [ "core"; "array"; "Array"; "index_mut" ])
+ None true false;
+ mk_fun [ "core"; "slice"; "index"; "Range"; "get" ] None None true false;
+ mk_fun [ "core"; "slice"; "index"; "Range"; "get_mut" ] None None true false;
+ mk_fun [ "core"; "slice"; "index"; "Range"; "index" ] None None true false;
+ mk_fun
+ [ "core"; "slice"; "index"; "Range"; "index_mut" ]
+ None None true false;
+ mk_fun
+ [ "core"; "slice"; "index"; "Range"; "get_unchecked" ]
+ None None false false;
+ mk_fun
+ [ "core"; "slice"; "index"; "Range"; "get_unchecked_mut" ]
+ None None false false;
+ mk_fun
+ [ "core"; "slice"; "index"; "usize"; "get" ]
+ (Some [ "core"; "slice"; "index"; "Usize"; "get" ])
+ None true false;
+ mk_fun
+ [ "core"; "slice"; "index"; "usize"; "get_mut" ]
+ (Some [ "core"; "slice"; "index"; "Usize"; "get_mut" ])
+ None true false;
+ mk_fun
+ [ "core"; "slice"; "index"; "usize"; "get_unchecked" ]
+ (Some [ "core"; "slice"; "index"; "Usize"; "get_unchecked" ])
+ None false false;
+ mk_fun
+ [ "core"; "slice"; "index"; "usize"; "get_unchecked_mut" ]
+ (Some [ "core"; "slice"; "index"; "Usize"; "get_unchecked_mut" ])
+ None false false;
+ mk_fun
+ [ "core"; "slice"; "index"; "usize"; "index" ]
+ (Some [ "core"; "slice"; "index"; "Usize"; "index" ])
+ None true false;
+ mk_fun
+ [ "core"; "slice"; "index"; "usize"; "index_mut" ]
+ (Some [ "core"; "slice"; "index"; "Usize"; "index_mut" ])
+ None true false;
+ ]
+
+let mk_builtin_funs_map () =
+ SimpleNameMap.of_list
+ (List.map
+ (fun (name, filter, info) -> (name, (filter, info)))
+ (builtin_funs ()))
+
+let builtin_funs_map = mk_memoized mk_builtin_funs_map
+
+type effect_info = { can_fail : bool; stateful : bool }
+
+let builtin_fun_effects =
+ let int_names =
+ [
+ "usize";
+ "u8";
+ "u16";
+ "u32";
+ "u64";
+ "u128";
+ "isize";
+ "i8";
+ "i16";
+ "i32";
+ "i64";
+ "i128";
+ ]
+ in
+ let int_ops =
+ [ "wrapping_add"; "wrapping_sub"; "rotate_left"; "rotate_right" ]
+ in
+ let int_funs =
+ List.map
+ (fun int_name ->
+ List.map (fun op -> "core::num::" ^ int_name ^ "::" ^ op) int_ops)
+ int_names
+ in
+ let int_funs = List.concat int_funs in
+ let no_fail_no_state_funs =
+ [
+ (* TODO: redundancy with the funs information below *)
+ "alloc::vec::Vec::new";
+ "alloc::vec::Vec::len";
+ "alloc::boxed::Box::deref";
+ "alloc::boxed::Box::deref_mut";
+ "core::mem::replace";
+ "core::mem::take";
+ ]
+ @ int_funs
+ in
+ let no_fail_no_state_funs =
+ List.map
+ (fun n -> (n, { can_fail = false; stateful = false }))
+ no_fail_no_state_funs
+ in
+ let no_state_funs =
+ [
+ (* TODO: redundancy with the funs information below *)
+ "alloc::vec::Vec::push";
+ "alloc::vec::Vec::index";
+ "alloc::vec::Vec::index_mut";
+ "alloc::vec::Vec::index_mut_back";
+ ]
+ in
+ let no_state_funs =
+ List.map (fun n -> (n, { can_fail = true; stateful = false })) no_state_funs
+ in
+ no_fail_no_state_funs @ no_state_funs
+
+let builtin_fun_effects_map =
+ SimpleNameMap.of_list
+ (List.map (fun (n, x) -> (string_to_simple_name n, x)) builtin_fun_effects)
+
+type builtin_trait_decl_info = {
+ rust_name : string;
+ extract_name : string;
+ constructor : string;
+ parent_clauses : string list;
+ consts : (string * string) list;
+ types : (string * (string * string list)) list;
+ (** Every type has:
+ - a Rust name
+ - an extraction name
+ - a list of clauses *)
+ methods : (string * builtin_fun_info list) list;
+}
+[@@deriving show]
+
+let builtin_trait_decls_info () =
+ let rg0 = Some Types.RegionGroupId.zero in
+ let mk_trait (rust_name : string list) ?(extract_name : string option = None)
+ ?(parent_clauses : string list = []) ?(types : string list = [])
+ ?(methods : (string * bool) list = []) () : builtin_trait_decl_info =
+ let extract_name =
+ match extract_name with
+ | Some n -> n
+ | None -> (
+ match !backend with
+ | Coq | FStar | HOL4 -> String.concat "_" rust_name
+ | Lean -> String.concat "." rust_name)
+ in
+ let constructor = mk_struct_constructor extract_name in
+ let consts = [] in
+ let types =
+ let mk_type item_name =
+ let type_name =
+ match !backend with
+ | Coq | FStar | HOL4 -> extract_name ^ "_" ^ item_name
+ | Lean -> item_name
+ in
+ let clauses = [] in
+ (item_name, (type_name, clauses))
+ in
+ List.map mk_type types
+ in
+ let methods =
+ let mk_method (item_name, with_back) =
+ (* TODO: factor out with builtin_funs_info *)
+ let basename =
+ match !backend with
+ | Coq | FStar | HOL4 -> extract_name ^ "_" ^ item_name
+ | Lean -> item_name
+ in
+ let back_no_suffix = false in
+ let fwd_suffix = if with_back && back_no_suffix then "_fwd" else "" in
+ let fwd = [ { rg = None; extract_name = basename ^ fwd_suffix } ] in
+ let back_suffix = if with_back && back_no_suffix then "" else "_back" in
+ let back =
+ if with_back then
+ [ { rg = rg0; extract_name = basename ^ back_suffix } ]
+ else []
+ in
+ (item_name, fwd @ back)
+ in
+ List.map mk_method methods
+ in
+ let rust_name = String.concat "::" rust_name in
+ {
+ rust_name;
+ extract_name;
+ constructor;
+ parent_clauses;
+ consts;
+ types;
+ methods;
+ }
+ in
+ [
+ (* Deref *)
+ mk_trait
+ [ "core"; "ops"; "deref"; "Deref" ]
+ ~types:[ "Target" ]
+ ~methods:[ ("deref", true) ]
+ ();
+ (* DerefMut *)
+ mk_trait
+ [ "core"; "ops"; "deref"; "DerefMut" ]
+ ~parent_clauses:[ backend_choice "deref_inst" "derefInst" ]
+ ~methods:[ ("deref_mut", true) ]
+ ();
+ (* Index *)
+ mk_trait
+ [ "core"; "ops"; "index"; "Index" ]
+ ~types:[ "Output" ]
+ ~methods:[ ("index", true) ]
+ ();
+ (* IndexMut *)
+ mk_trait
+ [ "core"; "ops"; "index"; "IndexMut" ]
+ ~parent_clauses:[ backend_choice "index_inst" "indexInst" ]
+ ~methods:[ ("index_mut", true) ]
+ ();
+ (* Sealed *)
+ mk_trait [ "core"; "slice"; "index"; "private_slice_index"; "Sealed" ] ();
+ (* SliceIndex *)
+ mk_trait
+ [ "core"; "slice"; "index"; "SliceIndex" ]
+ ~parent_clauses:[ backend_choice "sealed_inst" "sealedInst" ]
+ ~types:[ "Output" ]
+ ~methods:
+ [
+ ("get", true);
+ ("get_mut", true);
+ ("get_unchecked", false);
+ ("get_unchecked_mut", false);
+ ("index", true);
+ ("index_mut", true);
+ ]
+ ();
+ ]
+
+let mk_builtin_trait_decls_map () =
+ SimpleNameMap.of_list
+ (List.map
+ (fun info -> (string_to_simple_name info.rust_name, info))
+ (builtin_trait_decls_info ()))
+
+let builtin_trait_decls_map = mk_memoized mk_builtin_trait_decls_map
+
+(* TODO: generalize this.
+
+ For now, the key is:
+ - name of the impl (ex.: "alloc.boxed.Boxed")
+ - name of the implemented trait (ex.: "core.ops.deref.Deref"
+*)
+type simple_name_pair = simple_name * simple_name [@@deriving show, ord]
+
+module SimpleNamePairOrd = struct
+ type t = simple_name_pair
+
+ let compare = compare_simple_name_pair
+ let to_string = show_simple_name_pair
+ let pp_t = pp_simple_name_pair
+ let show_t = show_simple_name_pair
+end
+
+module SimpleNamePairMap = Collections.MakeMap (SimpleNamePairOrd)
+
+let builtin_trait_impls_info () :
+ ((string list * string list) * (bool list option * string)) list =
+ let fmt (type_name : string list)
+ ?(extract_type_name : string list option = None)
+ (trait_name : string list) ?(filter : bool list option = None) () :
+ (string list * string list) * (bool list option * string) =
+ let name =
+ let trait_name = String.concat "" trait_name ^ "Inst" in
+ let sep = backend_choice "_" "." in
+ let type_name =
+ match extract_type_name with
+ | Some type_name -> type_name
+ | None -> type_name
+ in
+ String.concat sep type_name ^ sep ^ trait_name
+ in
+ ((type_name, trait_name), (filter, name))
+ in
+ (* TODO: fix the names like "[T]" below *)
+ [
+ (* core::ops::Deref<alloc::boxed::Box<T>> *)
+ fmt [ "alloc"; "boxed"; "Box" ] [ "core"; "ops"; "deref"; "Deref" ] ();
+ (* core::ops::DerefMut<alloc::boxed::Box<T>> *)
+ fmt [ "alloc"; "boxed"; "Box" ] [ "core"; "ops"; "deref"; "DerefMut" ] ();
+ (* core::ops::index::Index<[T], I> *)
+ fmt
+ [ "core"; "slice"; "index"; "[T]" ]
+ ~extract_type_name:(Some [ "core"; "slice"; "index"; "Slice" ])
+ [ "core"; "ops"; "index"; "Index" ]
+ ();
+ (* core::ops::index::IndexMut<[T], I> *)
+ fmt
+ [ "core"; "slice"; "index"; "[T]" ]
+ ~extract_type_name:(Some [ "core"; "slice"; "index"; "Slice" ])
+ [ "core"; "ops"; "index"; "IndexMut" ]
+ ();
+ (* core::slice::index::private_slice_index::Sealed<Range<usize>> *)
+ fmt
+ [ "core"; "slice"; "index"; "private_slice_index"; "Range" ]
+ [ "core"; "slice"; "index"; "private_slice_index"; "Sealed" ]
+ ();
+ (* core::slice::index::SliceIndex<Range<usize>, [T]> *)
+ fmt
+ [ "core"; "slice"; "index"; "Range" ]
+ [ "core"; "slice"; "index"; "SliceIndex" ]
+ ();
+ (* core::ops::index::Index<[T; N], I> *)
+ fmt
+ [ "core"; "array"; "[T; N]" ]
+ ~extract_type_name:(Some [ "core"; "array"; "Array" ])
+ [ "core"; "ops"; "index"; "Index" ]
+ ();
+ (* core::ops::index::IndexMut<[T; N], I> *)
+ fmt
+ [ "core"; "array"; "[T; N]" ]
+ ~extract_type_name:(Some [ "core"; "array"; "Array" ])
+ [ "core"; "ops"; "index"; "IndexMut" ]
+ ();
+ (* core::slice::index::private_slice_index::Sealed<usize> *)
+ fmt
+ [ "core"; "slice"; "index"; "private_slice_index"; "usize" ]
+ [ "core"; "slice"; "index"; "private_slice_index"; "Sealed" ]
+ ();
+ (* core::slice::index::SliceIndex<usize, [T]> *)
+ fmt
+ [ "core"; "slice"; "index"; "usize" ]
+ [ "core"; "slice"; "index"; "SliceIndex" ]
+ ();
+ (* core::ops::index::Index<Vec<T>, T> *)
+ fmt [ "alloc"; "vec"; "Vec" ]
+ [ "core"; "ops"; "index"; "Index" ]
+ ~filter:(Some [ true; true; false ])
+ ();
+ (* core::ops::index::IndexMut<Vec<T>, T> *)
+ fmt [ "alloc"; "vec"; "Vec" ]
+ [ "core"; "ops"; "index"; "IndexMut" ]
+ ~filter:(Some [ true; true; false ])
+ ();
+ ]
+
+let mk_builtin_trait_impls_map () =
+ SimpleNamePairMap.of_list (builtin_trait_impls_info ())
+
+let builtin_trait_impls_map = mk_memoized mk_builtin_trait_impls_map
diff --git a/compiler/ExtractTypes.ml b/compiler/ExtractTypes.ml
new file mode 100644
index 00000000..77f76bb4
--- /dev/null
+++ b/compiler/ExtractTypes.ml
@@ -0,0 +1,2477 @@
+(** The generic extraction *)
+(* Turn the whole module into a functor: it is very annoying to carry the
+ the formatter everywhere...
+*)
+
+open Pure
+open PureUtils
+open TranslateCore
+open ExtractBase
+open StringUtils
+open Config
+module F = Format
+
+(** Small helper to compute the name of an int type *)
+let int_name (int_ty : integer_type) =
+ let isize, usize, i_format, u_format =
+ match !backend with
+ | FStar | Coq | HOL4 ->
+ ("isize", "usize", format_of_string "i%d", format_of_string "u%d")
+ | Lean -> ("Isize", "Usize", format_of_string "I%d", format_of_string "U%d")
+ in
+ match int_ty with
+ | Isize -> isize
+ | I8 -> Printf.sprintf i_format 8
+ | I16 -> Printf.sprintf i_format 16
+ | I32 -> Printf.sprintf i_format 32
+ | I64 -> Printf.sprintf i_format 64
+ | I128 -> Printf.sprintf i_format 128
+ | Usize -> usize
+ | U8 -> Printf.sprintf u_format 8
+ | U16 -> Printf.sprintf u_format 16
+ | U32 -> Printf.sprintf u_format 32
+ | U64 -> Printf.sprintf u_format 64
+ | U128 -> Printf.sprintf u_format 128
+
+(** Small helper to compute the name of a unary operation *)
+let unop_name (unop : unop) : string =
+ match unop with
+ | Not -> (
+ match !backend with FStar | Lean -> "not" | Coq -> "negb" | HOL4 -> "~")
+ | Neg (int_ty : integer_type) -> (
+ match !backend with Lean -> "-" | _ -> int_name int_ty ^ "_neg")
+ | Cast _ ->
+ (* We never directly use the unop name in this case *)
+ raise (Failure "Unsupported")
+
+(** Small helper to compute the name of a binary operation (note that many
+ binary operations like "less than" are extracted to primitive operations,
+ like [<]).
+ *)
+let named_binop_name (binop : E.binop) (int_ty : integer_type) : string =
+ let binop =
+ match binop with
+ | Div -> "div"
+ | Rem -> "rem"
+ | Add -> "add"
+ | Sub -> "sub"
+ | Mul -> "mul"
+ | Lt -> "lt"
+ | Le -> "le"
+ | Ge -> "ge"
+ | Gt -> "gt"
+ | BitXor -> "xor"
+ | BitAnd -> "and"
+ | BitOr -> "or"
+ | Shl -> "lsl"
+ | Shr ->
+ "asr"
+ (* NOTE: make sure arithmetic shift right is implemented, i.e. OCaml's asr operator, not lsr *)
+ | _ -> raise (Failure "Unreachable")
+ in
+ (* Remark: the Lean case is actually not used *)
+ match !backend with
+ | Lean -> int_name int_ty ^ "." ^ binop
+ | FStar | Coq | HOL4 -> int_name int_ty ^ "_" ^ binop
+
+(** A list of keywords/identifiers used by the backend and with which we
+ want to check collision.
+
+ Remark: this is useful mostly to look for collisions when generating
+ names for *variables*.
+ *)
+let keywords () =
+ let named_unops =
+ unop_name Not
+ :: List.map (fun it -> unop_name (Neg it)) T.all_signed_int_types
+ in
+ let named_binops = [ E.Div; Rem; Add; Sub; Mul ] in
+ let named_binops =
+ List.concat_map
+ (fun bn -> List.map (fun it -> named_binop_name bn it) T.all_int_types)
+ named_binops
+ in
+ let misc =
+ match !backend with
+ | FStar ->
+ [
+ "assert";
+ "assert_norm";
+ "assume";
+ "else";
+ "fun";
+ "fn";
+ "FStar";
+ "FStar.Mul";
+ "if";
+ "in";
+ "include";
+ "int";
+ "let";
+ "list";
+ "match";
+ "open";
+ "rec";
+ "scalar_cast";
+ "then";
+ "type";
+ "Type0";
+ "Type";
+ "unit";
+ "val";
+ "with";
+ ]
+ | Coq ->
+ [
+ "assert";
+ "Arguments";
+ "Axiom";
+ "char_of_byte";
+ "Check";
+ "Declare";
+ "Definition";
+ "else";
+ "End";
+ "fun";
+ "Fixpoint";
+ "if";
+ "in";
+ "int";
+ "Inductive";
+ "Import";
+ "let";
+ "Lemma";
+ "match";
+ "Module";
+ "not";
+ "Notation";
+ "Proof";
+ "Qed";
+ "rec";
+ "Record";
+ "Require";
+ "Scope";
+ "Search";
+ "SearchPattern";
+ "Set";
+ "then";
+ (* [tt] is unit *)
+ "tt";
+ "type";
+ "Type";
+ "unit";
+ "with";
+ ]
+ | Lean ->
+ [
+ "by";
+ "class";
+ "decreasing_by";
+ "def";
+ "deriving";
+ "do";
+ "else";
+ "end";
+ "for";
+ "have";
+ "if";
+ "inductive";
+ "instance";
+ "import";
+ "let";
+ "macro";
+ "match";
+ "namespace";
+ "opaque";
+ "open";
+ "run_cmd";
+ "set_option";
+ "simp";
+ "structure";
+ "syntax";
+ "termination_by";
+ "then";
+ "Type";
+ "unsafe";
+ "where";
+ "with";
+ "opaque_defs";
+ ]
+ | HOL4 ->
+ [
+ "Axiom";
+ "case";
+ "Definition";
+ "else";
+ "End";
+ "fix";
+ "fix_exec";
+ "fn";
+ "fun";
+ "if";
+ "in";
+ "int";
+ "Inductive";
+ "let";
+ "of";
+ "Proof";
+ "QED";
+ "then";
+ "Theorem";
+ ]
+ in
+ List.concat [ named_unops; named_binops; misc ]
+
+let assumed_adts () : (assumed_ty * string) list =
+ match !backend with
+ | Lean ->
+ [
+ (State, "State");
+ (Result, "Result");
+ (Error, "Error");
+ (Fuel, "Nat");
+ (Array, "Array");
+ (Slice, "Slice");
+ (Str, "Str");
+ (RawPtr Mut, "MutRawPtr");
+ (RawPtr Const, "ConstRawPtr");
+ ]
+ | Coq | FStar | HOL4 ->
+ [
+ (State, "state");
+ (Result, "result");
+ (Error, "error");
+ (Fuel, if !backend = HOL4 then "num" else "nat");
+ (Array, "array");
+ (Slice, "slice");
+ (Str, "str");
+ (RawPtr Mut, "mut_raw_ptr");
+ (RawPtr Const, "const_raw_ptr");
+ ]
+
+let assumed_struct_constructors () : (assumed_ty * string) list =
+ match !backend with
+ | Lean -> [ (Array, "Array.make") ]
+ | Coq -> [ (Array, "mk_array") ]
+ | FStar -> [ (Array, "mk_array") ]
+ | HOL4 -> [ (Array, "mk_array") ]
+
+let assumed_variants () : (assumed_ty * VariantId.id * string) list =
+ match !backend with
+ | FStar ->
+ [
+ (Result, result_return_id, "Return");
+ (Result, result_fail_id, "Fail");
+ (Error, error_failure_id, "Failure");
+ (Error, error_out_of_fuel_id, "OutOfFuel");
+ (* No Fuel::Zero on purpose *)
+ (* No Fuel::Succ on purpose *)
+ ]
+ | Coq ->
+ [
+ (Result, result_return_id, "Return");
+ (Result, result_fail_id, "Fail_");
+ (Error, error_failure_id, "Failure");
+ (Error, error_out_of_fuel_id, "OutOfFuel");
+ (Fuel, fuel_zero_id, "O");
+ (Fuel, fuel_succ_id, "S");
+ ]
+ | Lean ->
+ [
+ (Result, result_return_id, "ret");
+ (Result, result_fail_id, "fail");
+ (Error, error_failure_id, "panic");
+ (* No Fuel::Zero on purpose *)
+ (* No Fuel::Succ on purpose *)
+ ]
+ | HOL4 ->
+ [
+ (Result, result_return_id, "Return");
+ (Result, result_fail_id, "Fail");
+ (Error, error_failure_id, "Failure");
+ (* No Fuel::Zero on purpose *)
+ (* No Fuel::Succ on purpose *)
+ ]
+
+let assumed_llbc_functions () :
+ (A.assumed_fun_id * T.RegionGroupId.id option * string) list =
+ let rg0 = Some T.RegionGroupId.zero in
+ match !backend with
+ | FStar | Coq | HOL4 ->
+ [
+ (ArrayIndexShared, None, "array_index_usize");
+ (ArrayIndexMut, None, "array_index_usize");
+ (ArrayIndexMut, rg0, "array_update_usize");
+ (ArrayToSliceShared, None, "array_to_slice");
+ (ArrayToSliceMut, None, "array_to_slice");
+ (ArrayToSliceMut, rg0, "array_from_slice");
+ (ArrayRepeat, None, "array_repeat");
+ (SliceIndexShared, None, "slice_index_usize");
+ (SliceIndexMut, None, "slice_index_usize");
+ (SliceIndexMut, rg0, "slice_update_usize");
+ (SliceLen, None, "slice_len");
+ ]
+ | Lean ->
+ [
+ (ArrayIndexShared, None, "Array.index_usize");
+ (ArrayIndexMut, None, "Array.index_usize");
+ (ArrayIndexMut, rg0, "Array.update_usize");
+ (ArrayToSliceShared, None, "Array.to_slice");
+ (ArrayToSliceMut, None, "Array.to_slice");
+ (ArrayToSliceMut, rg0, "Array.from_slice");
+ (ArrayRepeat, None, "Array.repeat");
+ (SliceIndexShared, None, "Slice.index_usize");
+ (SliceIndexMut, None, "Slice.index_usize");
+ (SliceIndexMut, rg0, "Slice.update_usize");
+ (SliceLen, None, "Slice.len");
+ ]
+
+let assumed_pure_functions () : (pure_assumed_fun_id * string) list =
+ match !backend with
+ | FStar ->
+ [
+ (Return, "return");
+ (Fail, "fail");
+ (Assert, "massert");
+ (FuelDecrease, "decrease");
+ (FuelEqZero, "is_zero");
+ ]
+ | Coq ->
+ (* We don't provide [FuelDecrease] and [FuelEqZero] on purpose *)
+ [ (Return, "return_"); (Fail, "fail_"); (Assert, "massert") ]
+ | Lean ->
+ (* We don't provide [FuelDecrease] and [FuelEqZero] on purpose *)
+ [ (Return, "return"); (Fail, "fail_"); (Assert, "massert") ]
+ | HOL4 ->
+ (* We don't provide [FuelDecrease] and [FuelEqZero] on purpose *)
+ [ (Return, "return"); (Fail, "fail"); (Assert, "massert") ]
+
+let names_map_init () : names_map_init =
+ {
+ keywords = keywords ();
+ assumed_adts = assumed_adts ();
+ assumed_structs = assumed_struct_constructors ();
+ assumed_variants = assumed_variants ();
+ assumed_llbc_functions = assumed_llbc_functions ();
+ assumed_pure_functions = assumed_pure_functions ();
+ }
+
+let extract_unop (extract_expr : bool -> texpression -> unit)
+ (fmt : F.formatter) (inside : bool) (unop : unop) (arg : texpression) : unit
+ =
+ match unop with
+ | Not | Neg _ ->
+ let unop = unop_name unop in
+ if inside then F.pp_print_string fmt "(";
+ F.pp_print_string fmt unop;
+ F.pp_print_space fmt ();
+ extract_expr true arg;
+ if inside then F.pp_print_string fmt ")"
+ | Cast (src, tgt) -> (
+ (* HOL4 has a special treatment: because it doesn't support dependent
+ types, we don't have a specific operator for the cast *)
+ match !backend with
+ | HOL4 ->
+ (* Casting, say, an u32 to an i32 would be done as follows:
+ {[
+ mk_i32 (u32_to_int x)
+ ]}
+ *)
+ if inside then F.pp_print_string fmt "(";
+ F.pp_print_string fmt ("mk_" ^ int_name tgt);
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "(";
+ F.pp_print_string fmt (int_name src ^ "_to_int");
+ F.pp_print_space fmt ();
+ extract_expr true arg;
+ F.pp_print_string fmt ")";
+ if inside then F.pp_print_string fmt ")"
+ | FStar | Coq | Lean ->
+ (* Rem.: the source type is an implicit parameter *)
+ if inside then F.pp_print_string fmt "(";
+ let cast_str =
+ match !backend with
+ | Coq | FStar -> "scalar_cast"
+ | Lean -> (* TODO: I8.cast, I16.cast, etc.*) "Scalar.cast"
+ | HOL4 -> raise (Failure "Unreachable")
+ in
+ F.pp_print_string fmt cast_str;
+ F.pp_print_space fmt ();
+ if !backend <> Lean then (
+ F.pp_print_string fmt
+ (StringUtils.capitalize_first_letter
+ (PrintPure.integer_type_to_string src));
+ F.pp_print_space fmt ());
+ if !backend = Lean then F.pp_print_string fmt ("." ^ int_name tgt)
+ else
+ F.pp_print_string fmt
+ (StringUtils.capitalize_first_letter
+ (PrintPure.integer_type_to_string tgt));
+ F.pp_print_space fmt ();
+ extract_expr true arg;
+ if inside then F.pp_print_string fmt ")")
+
+(** [extract_expr] : the boolean argument is [inside] *)
+let extract_binop (extract_expr : bool -> texpression -> unit)
+ (fmt : F.formatter) (inside : bool) (binop : E.binop)
+ (int_ty : integer_type) (arg0 : texpression) (arg1 : texpression) : unit =
+ if inside then F.pp_print_string fmt "(";
+ (* Some binary operations have a special notation depending on the backend *)
+ (match (!backend, binop) with
+ | HOL4, (Eq | Ne)
+ | (FStar | Coq | Lean), (Eq | Lt | Le | Ne | Ge | Gt)
+ | Lean, (Div | Rem | Add | Sub | Mul) ->
+ let binop =
+ match binop with
+ | Eq -> "="
+ | Lt -> "<"
+ | Le -> "<="
+ | Ne -> if !backend = Lean then "!=" else "<>"
+ | Ge -> ">="
+ | Gt -> ">"
+ | Div -> "/"
+ | Rem -> "%"
+ | Add -> "+"
+ | Sub -> "-"
+ | Mul -> "*"
+ | _ -> raise (Failure "Unreachable")
+ in
+ let binop =
+ match !backend with FStar | Lean | HOL4 -> binop | Coq -> "s" ^ binop
+ in
+ extract_expr false arg0;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt binop;
+ F.pp_print_space fmt ();
+ extract_expr false arg1
+ | _ ->
+ let binop = named_binop_name binop int_ty in
+ F.pp_print_string fmt binop;
+ F.pp_print_space fmt ();
+ extract_expr true arg0;
+ F.pp_print_space fmt ();
+ extract_expr true arg1);
+ if inside then F.pp_print_string fmt ")"
+
+let type_decl_kind_to_qualif (kind : decl_kind)
+ (type_kind : type_decl_kind option) : string option =
+ match !backend with
+ | FStar -> (
+ match kind with
+ | SingleNonRec -> Some "type"
+ | SingleRec -> Some "type"
+ | MutRecFirst -> Some "type"
+ | MutRecInner -> Some "and"
+ | MutRecLast -> Some "and"
+ | Assumed -> Some "assume type"
+ | Declared -> Some "val")
+ | Coq -> (
+ match (kind, type_kind) with
+ | SingleNonRec, Some Enum -> Some "Inductive"
+ | SingleNonRec, Some Struct -> Some "Record"
+ | (SingleRec | MutRecFirst), Some _ -> Some "Inductive"
+ | (MutRecInner | MutRecLast), Some _ ->
+ (* Coq doesn't support groups of mutually recursive definitions which mix
+ * records and inducties: we convert everything to records if this happens
+ *)
+ Some "with"
+ | (Assumed | Declared), None -> Some "Axiom"
+ | SingleNonRec, None ->
+ (* This is for traits *)
+ Some "Record"
+ | _ ->
+ raise
+ (Failure
+ ("Unexpected: (" ^ show_decl_kind kind ^ ", "
+ ^ Print.option_to_string show_type_decl_kind type_kind
+ ^ ")")))
+ | Lean -> (
+ match kind with
+ | SingleNonRec ->
+ if type_kind = Some Struct then Some "structure" else Some "inductive"
+ | SingleRec -> Some "inductive"
+ | MutRecFirst -> Some "inductive"
+ | MutRecInner -> Some "inductive"
+ | MutRecLast -> Some "inductive"
+ | Assumed -> Some "axiom"
+ | Declared -> Some "axiom")
+ | HOL4 -> None
+
+let fun_decl_kind_to_qualif (kind : decl_kind) : string option =
+ match !backend with
+ | FStar -> (
+ match kind with
+ | SingleNonRec -> Some "let"
+ | SingleRec -> Some "let rec"
+ | MutRecFirst -> Some "let rec"
+ | MutRecInner -> Some "and"
+ | MutRecLast -> Some "and"
+ | Assumed -> Some "assume val"
+ | Declared -> Some "val")
+ | Coq -> (
+ match kind with
+ | SingleNonRec -> Some "Definition"
+ | SingleRec -> Some "Fixpoint"
+ | MutRecFirst -> Some "Fixpoint"
+ | MutRecInner -> Some "with"
+ | MutRecLast -> Some "with"
+ | Assumed -> Some "Axiom"
+ | Declared -> Some "Axiom")
+ | Lean -> (
+ match kind with
+ | SingleNonRec -> Some "def"
+ | SingleRec -> Some "divergent def"
+ | MutRecFirst -> Some "mutual divergent def"
+ | MutRecInner -> Some "divergent def"
+ | MutRecLast -> Some "divergent def"
+ | Assumed -> Some "axiom"
+ | Declared -> Some "axiom")
+ | HOL4 -> None
+
+(** The type of types.
+
+ TODO: move inside the formatter?
+ *)
+let type_keyword () =
+ match !backend with
+ | FStar -> "Type0"
+ | Coq | Lean -> "Type"
+ | HOL4 -> raise (Failure "Unexpected")
+
+(**
+ [ctx]: we use the context to lookup type definitions, to retrieve type names.
+ This is used to compute variable names, when they have no basenames: in this
+ case we use the first letter of the type name.
+
+ [variant_concatenate_type_name]: if true, add the type name as a prefix
+ to the variant names.
+ Ex.:
+ In Rust:
+ {[
+ enum List = {
+ Cons(u32, Box<List>),x
+ Nil,
+ }
+ ]}
+
+ F*, if option activated:
+ {[
+ type list =
+ | ListCons : u32 -> list -> list
+ | ListNil : list
+ ]}
+
+ F*, if option not activated:
+ {[
+ type list =
+ | Cons : u32 -> list -> list
+ | Nil : list
+ ]}
+
+ Rk.: this should be true by default, because in Rust all the variant names
+ are actively uniquely identifier by the type name [List::Cons(...)], while
+ in other languages it is not necessarily the case, and thus clashes can mess
+ up type checking. Note that some languages actually forbids the name clashes
+ (it is the case of F* ).
+ *)
+let mk_formatter (ctx : trans_ctx) (crate_name : string)
+ (variant_concatenate_type_name : bool) : formatter =
+ let int_name = int_name in
+
+ (* Prepare a name.
+ * The first id elem is always the crate: if it is the local crate,
+ * we remove it.
+ * We also remove all the disambiguators, then convert everything to strings.
+ * **Rmk:** because we remove the disambiguators, there may be name collisions
+ * (which is ok, because we check for name collisions and fail if there is any).
+ *)
+ let get_name (name : name) : string list =
+ (* Rmk.: initially we only filtered the disambiguators equal to 0 *)
+ let name = Names.filter_disambiguators name in
+ match name with
+ | Ident crate :: name ->
+ let name = if crate = crate_name then name else Ident crate :: name in
+ let name =
+ List.map
+ (function
+ | Names.Ident s -> s
+ | Disambiguator d -> Names.Disambiguator.to_string d)
+ name
+ in
+ name
+ | _ ->
+ raise (Failure ("Unexpected name shape: " ^ Print.name_to_string name))
+ in
+ let flatten_name (name : string list) : string =
+ match !backend with
+ | FStar | Coq | HOL4 -> String.concat "_" name
+ | Lean -> String.concat "." name
+ in
+ let get_type_name = get_name in
+ let get_type_name_no_suffix name =
+ match !backend with
+ | FStar | Coq | HOL4 -> String.concat "_" (get_type_name name)
+ | Lean -> String.concat "." (get_type_name name)
+ in
+ let type_name name =
+ match !backend with
+ | FStar ->
+ StringUtils.lowercase_first_letter (get_type_name_no_suffix name ^ "_t")
+ | Coq | HOL4 -> get_type_name_no_suffix name ^ "_t"
+ | Lean -> get_type_name_no_suffix name
+ in
+ let field_name (def_name : name) (field_id : FieldId.id)
+ (field_name : string option) : string =
+ let field_name_s =
+ match field_name with
+ | Some field_name -> field_name
+ | None ->
+ (* TODO: extract structs with no field names to tuples *)
+ FieldId.to_string field_id
+ in
+ if !Config.record_fields_short_names then
+ if field_name = None then (* TODO: this is a bit ugly *)
+ "_" ^ field_name_s
+ else field_name_s
+ else
+ let def_name = get_type_name_no_suffix def_name ^ "_" ^ field_name_s in
+ match !backend with
+ | Lean | HOL4 -> def_name
+ | Coq | FStar -> StringUtils.lowercase_first_letter def_name
+ in
+ let variant_name (def_name : name) (variant : string) : string =
+ match !backend with
+ | FStar | Coq | HOL4 ->
+ let variant = to_camel_case variant in
+ if variant_concatenate_type_name then
+ StringUtils.capitalize_first_letter
+ (get_type_name_no_suffix def_name ^ "_" ^ variant)
+ else variant
+ | Lean -> variant
+ in
+ let struct_constructor (basename : name) : string =
+ let tname = type_name basename in
+ ExtractBuiltin.mk_struct_constructor tname
+ in
+ let get_fun_name fname =
+ let fname = get_name fname in
+ (* TODO: don't convert to snake case for Coq, HOL4, F* *)
+ let fname = flatten_name fname in
+ match !backend with
+ | FStar | Coq | HOL4 -> StringUtils.lowercase_first_letter fname
+ | Lean -> fname
+ in
+ let global_name (name : global_name) : string =
+ (* Converting to snake case also lowercases the letters (in Rust, global
+ * names are written in capital letters). *)
+ let parts = List.map to_snake_case (get_name name) in
+ String.concat "_" parts
+ in
+ let fun_name (fname : fun_name) (num_loops : int) (loop_id : LoopId.id option)
+ (num_rgs : int) (rg : region_group_info option) (filter_info : bool * int)
+ : string =
+ let fname = get_fun_name fname in
+ (* Compute the suffix *)
+ let suffix = default_fun_suffix num_loops loop_id num_rgs rg filter_info in
+ (* Concatenate *)
+ fname ^ suffix
+ in
+
+ let trait_decl_name (trait_decl : trait_decl) : string =
+ type_name trait_decl.name
+ in
+
+ let trait_impl_name (trait_decl : trait_decl) (trait_impl : trait_impl) :
+ string =
+ (* TODO: provisional: we concatenate the trait impl name (which is its type)
+ with the trait decl name *)
+ let trait_decl =
+ let name = trait_decl.name in
+ let name = get_type_name_no_suffix name ^ "Inst" in
+ (* Remove the occurrences of '.' *)
+ String.concat "" (String.split_on_char '.' name)
+ in
+ let name = flatten_name (get_type_name trait_impl.name @ [ trait_decl ]) in
+ match !backend with
+ | FStar -> StringUtils.lowercase_first_letter name
+ | Coq | HOL4 | Lean -> name
+ in
+
+ let trait_decl_constructor (trait_decl : trait_decl) : string =
+ let name = trait_decl_name trait_decl in
+ ExtractBuiltin.mk_struct_constructor name
+ in
+
+ let trait_parent_clause_name (trait_decl : trait_decl) (clause : trait_clause)
+ : string =
+ (* TODO: improve - it would be better to not use indices *)
+ let clause = "parent_clause_" ^ TraitClauseId.to_string clause.clause_id in
+ if !Config.record_fields_short_names then clause
+ else trait_decl_name trait_decl ^ "_" ^ clause
+ in
+ let trait_type_name (trait_decl : trait_decl) (item : string) : string =
+ let name =
+ if !Config.record_fields_short_names then item
+ else trait_decl_name trait_decl ^ "_" ^ item
+ in
+ (* Constants are usually all capital letters.
+ Some backends do not support field names starting with a capital letter,
+ and it may be weird to lowercase everything (especially as it may lead
+ to more name collisions): we add a prefix when necessary.
+ For instance, it gives: "U" -> "tU"
+ Note that for some backends we prepend the type name (because those backends
+ can't disambiguate fields coming from different ADTs if they have the same
+ names), and thus don't need to add a prefix starting with a lowercase.
+ *)
+ match !backend with FStar -> "t" ^ name | Coq | Lean | HOL4 -> name
+ in
+ let trait_const_name (trait_decl : trait_decl) (item : string) : string =
+ let name =
+ if !Config.record_fields_short_names then item
+ else trait_decl_name trait_decl ^ "_" ^ item
+ in
+ (* See [trait_type_name] *)
+ match !backend with FStar -> "c" ^ name | Coq | Lean | HOL4 -> name
+ in
+ let trait_method_name (trait_decl : trait_decl) (item : string) : string =
+ if !Config.record_fields_short_names then item
+ else trait_decl_name trait_decl ^ "_" ^ item
+ in
+ let trait_type_clause_name (trait_decl : trait_decl) (item : string)
+ (clause : trait_clause) : string =
+ (* TODO: improve - it would be better to not use indices *)
+ trait_type_name trait_decl item
+ ^ "_clause_"
+ ^ TraitClauseId.to_string clause.clause_id
+ in
+
+ let termination_measure_name (_fid : A.FunDeclId.id) (fname : fun_name)
+ (num_loops : int) (loop_id : LoopId.id option) : string =
+ let fname = get_fun_name fname in
+ let lp_suffix = default_fun_loop_suffix num_loops loop_id in
+ (* Compute the suffix *)
+ let suffix =
+ match !Config.backend with
+ | FStar -> "_decreases"
+ | Lean -> "_terminates"
+ | Coq | HOL4 -> raise (Failure "Unexpected")
+ in
+ (* Concatenate *)
+ fname ^ lp_suffix ^ suffix
+ in
+
+ let decreases_proof_name (_fid : A.FunDeclId.id) (fname : fun_name)
+ (num_loops : int) (loop_id : LoopId.id option) : string =
+ let fname = get_fun_name fname in
+ let lp_suffix = default_fun_loop_suffix num_loops loop_id in
+ (* Compute the suffix *)
+ let suffix =
+ match !Config.backend with
+ | Lean -> "_decreases"
+ | FStar | Coq | HOL4 -> raise (Failure "Unexpected")
+ in
+ (* Concatenate *)
+ fname ^ lp_suffix ^ suffix
+ in
+
+ let var_basename (_varset : StringSet.t) (basename : string option) (ty : ty)
+ : string =
+ (* Small helper to derive var names from ADT type names.
+
+ We do the following:
+ - convert the type name to snake case
+ - take the first letter of every "letter group"
+ Ex.: "HashMap" -> "hash_map" -> "hm"
+ *)
+ let name_from_type_ident (name : string) : string =
+ let cl = to_snake_case name in
+ let cl = String.split_on_char '_' cl in
+ let cl = List.filter (fun s -> String.length s > 0) cl in
+ assert (List.length cl > 0);
+ let cl = List.map (fun s -> s.[0]) cl in
+ StringUtils.string_of_chars cl
+ in
+ (* If there is a basename, we use it *)
+ match basename with
+ | Some basename ->
+ (* This should be a no-op *)
+ to_snake_case basename
+ | None -> (
+ (* No basename: we use the first letter of the type *)
+ match ty with
+ | Adt (type_id, generics) -> (
+ match type_id with
+ | Tuple ->
+ (* The "pair" case is frequent enough to have its special treatment *)
+ if List.length generics.types = 2 then "p" else "t"
+ | Assumed Result -> "r"
+ | Assumed Error -> ConstStrings.error_basename
+ | Assumed Fuel -> ConstStrings.fuel_basename
+ | Assumed Array -> "a"
+ | Assumed Slice -> "s"
+ | Assumed Str -> "s"
+ | Assumed State -> ConstStrings.state_basename
+ | Assumed (RawPtr _) -> "p"
+ | AdtId adt_id ->
+ let def = TypeDeclId.Map.find adt_id ctx.type_ctx.type_decls in
+ (* Derive the var name from the last ident of the type name
+ * Ex.: ["hashmap"; "HashMap"] ~~> "HashMap" -> "hash_map" -> "hm"
+ *)
+ (* The name shouldn't be empty, and its last element should
+ * be an ident *)
+ let cl = List.nth def.name (List.length def.name - 1) in
+ name_from_type_ident (Names.as_ident cl))
+ | TypeVar _ -> (
+ (* TODO: use "t" also for F* *)
+ match !backend with
+ | FStar -> "x" (* lacking inspiration here... *)
+ | Coq | Lean | HOL4 -> "t" (* lacking inspiration here... *))
+ | Literal lty -> (
+ match lty with Bool -> "b" | Char -> "c" | Integer _ -> "i")
+ | Arrow _ -> "f"
+ | TraitType (_, _, name) -> name_from_type_ident name)
+ in
+ let type_var_basename (_varset : StringSet.t) (basename : string) : string =
+ (* Rust type variables are snake-case and start with a capital letter *)
+ match !backend with
+ | FStar ->
+ (* This is *not* a no-op: this removes the capital letter *)
+ to_snake_case basename
+ | HOL4 ->
+ (* In HOL4, type variable names must start with "'" *)
+ "'" ^ to_snake_case basename
+ | Coq | Lean -> basename
+ in
+ let const_generic_var_basename (_varset : StringSet.t) (basename : string) :
+ string =
+ (* Rust type variables are snake-case and start with a capital letter *)
+ match !backend with
+ | FStar | HOL4 ->
+ (* This is *not* a no-op: this removes the capital letter *)
+ to_snake_case basename
+ | Coq | Lean -> basename
+ in
+ let trait_clause_basename (_varset : StringSet.t) (_clause : trait_clause) :
+ string =
+ (* TODO: actually use the clause to derive the name *)
+ "inst"
+ in
+ let trait_self_clause_basename = "self_clause" in
+ let append_index (basename : string) (i : int) : string =
+ basename ^ string_of_int i
+ in
+
+ let extract_literal (fmt : F.formatter) (inside : bool) (cv : literal) : unit
+ =
+ match cv with
+ | Scalar sv -> (
+ match !backend with
+ | FStar -> F.pp_print_string fmt (Z.to_string sv.PV.value)
+ | Coq | HOL4 | Lean ->
+ let print_brackets = inside && !backend = HOL4 in
+ if print_brackets then F.pp_print_string fmt "(";
+ (match !backend with
+ | Coq | Lean -> ()
+ | HOL4 ->
+ F.pp_print_string fmt ("int_to_" ^ int_name sv.PV.int_ty);
+ F.pp_print_space fmt ()
+ | _ -> raise (Failure "Unreachable"));
+ (* We need to add parentheses if the value is negative *)
+ if sv.PV.value >= Z.of_int 0 then
+ F.pp_print_string fmt (Z.to_string sv.PV.value)
+ else if !backend = Lean then
+ (* TODO: parsing issues with Lean because there are ambiguous
+ interpretations between int values and nat values *)
+ F.pp_print_string fmt
+ ("(-(" ^ Z.to_string (Z.neg sv.PV.value) ^ ":Int))")
+ else F.pp_print_string fmt ("(" ^ Z.to_string sv.PV.value ^ ")");
+ (match !backend with
+ | Coq ->
+ let iname = int_name sv.PV.int_ty in
+ F.pp_print_string fmt ("%" ^ iname)
+ | Lean ->
+ let iname = String.lowercase_ascii (int_name sv.PV.int_ty) in
+ F.pp_print_string fmt ("#" ^ iname)
+ | HOL4 -> ()
+ | _ -> raise (Failure "Unreachable"));
+ if print_brackets then F.pp_print_string fmt ")")
+ | Bool b ->
+ let b =
+ match !backend with
+ | HOL4 -> if b then "T" else "F"
+ | Coq | FStar | Lean -> if b then "true" else "false"
+ in
+ F.pp_print_string fmt b
+ | Char c -> (
+ match !backend with
+ | HOL4 ->
+ (* [#"a"] is a notation for [CHR 97] (97 is the ASCII code for 'a') *)
+ F.pp_print_string fmt ("#\"" ^ String.make 1 c ^ "\"")
+ | FStar | Lean -> F.pp_print_string fmt ("'" ^ String.make 1 c ^ "'")
+ | Coq ->
+ if inside then F.pp_print_string fmt "(";
+ F.pp_print_string fmt "char_of_byte";
+ F.pp_print_space fmt ();
+ (* Convert the the char to ascii *)
+ let c =
+ let i = Char.code c in
+ let x0 = i / 16 in
+ let x1 = i mod 16 in
+ "Coq.Init.Byte.x" ^ string_of_int x0 ^ string_of_int x1
+ in
+ F.pp_print_string fmt c;
+ if inside then F.pp_print_string fmt ")")
+ in
+ let bool_name = if !backend = Lean then "Bool" else "bool" in
+ let char_name = if !backend = Lean then "Char" else "char" in
+ let str_name = if !backend = Lean then "String" else "string" in
+ {
+ bool_name;
+ char_name;
+ int_name;
+ str_name;
+ type_decl_kind_to_qualif;
+ fun_decl_kind_to_qualif;
+ field_name;
+ variant_name;
+ struct_constructor;
+ type_name;
+ global_name;
+ fun_name;
+ termination_measure_name;
+ decreases_proof_name;
+ trait_decl_name;
+ trait_impl_name;
+ trait_decl_constructor;
+ trait_parent_clause_name;
+ trait_const_name;
+ trait_type_name;
+ trait_method_name;
+ trait_type_clause_name;
+ var_basename;
+ type_var_basename;
+ const_generic_var_basename;
+ trait_self_clause_basename;
+ trait_clause_basename;
+ append_index;
+ extract_literal;
+ extract_unop;
+ extract_binop;
+ }
+
+let mk_formatter_and_names_maps (ctx : trans_ctx) (crate_name : string)
+ (variant_concatenate_type_name : bool) : formatter * names_maps =
+ let fmt = mk_formatter ctx crate_name variant_concatenate_type_name in
+ let names_maps = initialize_names_maps fmt (names_map_init ()) in
+ (fmt, names_maps)
+
+let is_single_opaque_fun_decl_group (dg : Pure.fun_decl list) : bool =
+ match dg with [ d ] -> d.body = None | _ -> false
+
+let is_single_opaque_type_decl_group (dg : Pure.type_decl list) : bool =
+ match dg with [ d ] -> d.kind = Opaque | _ -> false
+
+let is_empty_record_type_decl (d : Pure.type_decl) : bool = d.kind = Struct []
+
+let is_empty_record_type_decl_group (dg : Pure.type_decl list) : bool =
+ match dg with [ d ] -> is_empty_record_type_decl d | _ -> false
+
+(** In some provers, groups of definitions must be delimited.
+
+ - in Coq, *every* group (including singletons) must end with "."
+ - in Lean, groups of mutually recursive definitions must end with "end"
+ - in HOL4 (in most situations) the whole group must be within a `Define` command
+
+ Calls to {!extract_fun_decl} should be inserted between calls to
+ {!start_fun_decl_group} and {!end_fun_decl_group}.
+
+ TODO: maybe those [{start/end}_decl_group] functions are not that much a good
+ idea and we should merge them with the corresponding [extract_decl] functions.
+ *)
+let start_fun_decl_group (ctx : extraction_ctx) (fmt : F.formatter)
+ (is_rec : bool) (dg : Pure.fun_decl list) =
+ match !backend with
+ | FStar | Coq | Lean -> ()
+ | HOL4 ->
+ (* In HOL4, opaque functions have a special treatment *)
+ if is_single_opaque_fun_decl_group dg then ()
+ else
+ let compute_fun_def_name (def : Pure.fun_decl) : string =
+ ctx_get_local_function def.def_id def.loop_id def.back_id ctx ^ "_def"
+ in
+ let names = List.map compute_fun_def_name dg in
+ (* Add a break before *)
+ F.pp_print_break fmt 0 0;
+ (* Open the box for the delimiters *)
+ F.pp_open_vbox fmt 0;
+ (* Open the box for the definitions themselves *)
+ F.pp_open_vbox fmt ctx.indent_incr;
+ (* Print the delimiters *)
+ if is_rec then
+ F.pp_print_string fmt
+ ("val [" ^ String.concat ", " names ^ "] = DefineDiv ‘")
+ else (
+ assert (List.length names = 1);
+ let name = List.hd names in
+ F.pp_print_string fmt ("val " ^ name ^ " = Define ‘"));
+ F.pp_print_cut fmt ()
+
+(** See {!start_fun_decl_group}. *)
+let end_fun_decl_group (fmt : F.formatter) (is_rec : bool)
+ (dg : Pure.fun_decl list) =
+ match !backend with
+ | FStar -> ()
+ | Coq ->
+ (* For aesthetic reasons, we print the Coq end group delimiter directly
+ in {!extract_fun_decl}. *)
+ ()
+ | Lean ->
+ (* We must add the "end" keyword to groups of mutually recursive functions *)
+ if is_rec && List.length dg > 1 then (
+ F.pp_print_cut fmt ();
+ F.pp_print_string fmt "end";
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0)
+ else ()
+ | HOL4 ->
+ (* In HOL4, opaque functions have a special treatment *)
+ if is_single_opaque_fun_decl_group dg then ()
+ else (
+ (* Close the box for the definitions *)
+ F.pp_close_box fmt ();
+ (* Print the end delimiter *)
+ F.pp_print_cut fmt ();
+ F.pp_print_string fmt "’";
+ (* Close the box for the delimiters *)
+ F.pp_close_box fmt ();
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0)
+
+(** See {!start_fun_decl_group}: similar usage, but for the type declarations. *)
+let start_type_decl_group (ctx : extraction_ctx) (fmt : F.formatter)
+ (is_rec : bool) (dg : Pure.type_decl list) =
+ match !backend with
+ | FStar | Coq -> ()
+ | Lean ->
+ if is_rec && List.length dg > 1 then (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "mutual";
+ F.pp_print_space fmt ())
+ | HOL4 ->
+ (* In HOL4, opaque types and empty records have a special treatment *)
+ if
+ is_single_opaque_type_decl_group dg
+ || is_empty_record_type_decl_group dg
+ then ()
+ else (
+ (* Add a break before *)
+ F.pp_print_break fmt 0 0;
+ (* Open the box for the delimiters *)
+ F.pp_open_vbox fmt 0;
+ (* Open the box for the definitions themselves *)
+ F.pp_open_vbox fmt ctx.indent_incr;
+ (* Print the delimiters *)
+ F.pp_print_string fmt "Datatype:";
+ F.pp_print_cut fmt ())
+
+(** See {!start_fun_decl_group}. *)
+let end_type_decl_group (fmt : F.formatter) (is_rec : bool)
+ (dg : Pure.type_decl list) =
+ match !backend with
+ | FStar -> ()
+ | Coq ->
+ (* For aesthetic reasons, we print the Coq end group delimiter directly
+ in {!extract_fun_decl}. *)
+ ()
+ | Lean ->
+ (* We must add the "end" keyword to groups of mutually recursive functions *)
+ if is_rec && List.length dg > 1 then (
+ F.pp_print_cut fmt ();
+ F.pp_print_string fmt "end";
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0)
+ else ()
+ | HOL4 ->
+ (* In HOL4, opaque types and empty records have a special treatment *)
+ if
+ is_single_opaque_type_decl_group dg
+ || is_empty_record_type_decl_group dg
+ then ()
+ else (
+ (* Close the box for the definitions *)
+ F.pp_close_box fmt ();
+ (* Print the end delimiter *)
+ F.pp_print_cut fmt ();
+ F.pp_print_string fmt "End";
+ (* Close the box for the delimiters *)
+ F.pp_close_box fmt ();
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0)
+
+let unit_name () =
+ match !backend with Lean -> "Unit" | Coq | FStar | HOL4 -> "unit"
+
+(** Small helper *)
+let extract_arrow (fmt : F.formatter) () : unit =
+ if !Config.backend = Lean then F.pp_print_string fmt "→"
+ else F.pp_print_string fmt "->"
+
+let extract_const_generic (ctx : extraction_ctx) (fmt : F.formatter)
+ (inside : bool) (cg : const_generic) : unit =
+ match cg with
+ | ConstGenericGlobal id ->
+ let s = ctx_get_global id ctx in
+ F.pp_print_string fmt s
+ | ConstGenericValue v -> ctx.fmt.extract_literal fmt inside v
+ | ConstGenericVar id ->
+ let s = ctx_get_const_generic_var id ctx in
+ F.pp_print_string fmt s
+
+let extract_literal_type (ctx : extraction_ctx) (fmt : F.formatter)
+ (ty : literal_type) : unit =
+ match ty with
+ | Bool -> F.pp_print_string fmt ctx.fmt.bool_name
+ | Char -> F.pp_print_string fmt ctx.fmt.char_name
+ | Integer int_ty -> F.pp_print_string fmt (ctx.fmt.int_name int_ty)
+
+(** [inside] constrols whether we should add parentheses or not around type
+ applications (if [true] we add parentheses).
+
+ [no_params_tys]: for all the types inside this set, do not print the type parameters.
+ This is used for HOL4. As polymorphism is uniform in HOL4, printing the
+ type parameters in the recursive definitions is useless (and actually
+ forbidden).
+
+ For instance, where in F* we would write:
+ {[
+ type list a = | Nil : list a | Cons : a -> list a -> list a
+ ]}
+
+ In HOL4 we would simply write:
+ {[
+ Datatype:
+ list = Nil 'a | Cons 'a list
+ End
+ ]}
+ *)
+let rec extract_ty (ctx : extraction_ctx) (fmt : F.formatter)
+ (no_params_tys : TypeDeclId.Set.t) (inside : bool) (ty : ty) : unit =
+ let extract_rec = extract_ty ctx fmt no_params_tys in
+ match ty with
+ | Adt (type_id, generics) -> (
+ let has_params = generics <> empty_generic_args in
+ match type_id with
+ | Tuple ->
+ (* This is a bit annoying, but in F*/Coq/HOL4 [()] is not the unit type:
+ * we have to write [unit]... *)
+ if generics.types = [] then F.pp_print_string fmt (unit_name ())
+ else (
+ F.pp_print_string fmt "(";
+ Collections.List.iter_link
+ (fun () ->
+ F.pp_print_space fmt ();
+ let product =
+ match !backend with
+ | FStar -> "&"
+ | Coq -> "*"
+ | Lean -> "×"
+ | HOL4 -> "#"
+ in
+ F.pp_print_string fmt product;
+ F.pp_print_space fmt ())
+ (extract_rec true) generics.types;
+ F.pp_print_string fmt ")")
+ | AdtId _ | Assumed _ -> (
+ (* HOL4 behaves differently. Where in Coq/FStar/Lean we would write:
+ `tree a b`
+
+ In HOL4 we would write:
+ `('a, 'b) tree`
+ *)
+ match !backend with
+ | FStar | Coq | Lean ->
+ let print_paren = inside && has_params in
+ if print_paren then F.pp_print_string fmt "(";
+ (* TODO: for now, only the opaque *functions* are extracted in the
+ opaque module. The opaque *types* are assumed. *)
+ F.pp_print_string fmt (ctx_get_type type_id ctx);
+ (* We might need to filter the type arguments, if the type
+ is builtin (for instance, we filter the global allocator type
+ argument for `Vec`). *)
+ let generics =
+ match type_id with
+ | AdtId id -> (
+ match
+ TypeDeclId.Map.find_opt id ctx.types_filter_type_args_map
+ with
+ | None -> generics
+ | Some filter ->
+ let types = List.combine filter generics.types in
+ let types =
+ List.filter_map
+ (fun (b, ty) -> if b then Some ty else None)
+ types
+ in
+ { generics with types })
+ | _ -> generics
+ in
+ extract_generic_args ctx fmt no_params_tys generics;
+ if print_paren then F.pp_print_string fmt ")"
+ | HOL4 ->
+ let { types; const_generics; trait_refs } = generics in
+ (* Const generics are not supported in HOL4 *)
+ assert (const_generics = []);
+ let print_tys =
+ match type_id with
+ | AdtId id -> not (TypeDeclId.Set.mem id no_params_tys)
+ | Assumed _ -> true
+ | _ -> raise (Failure "Unreachable")
+ in
+ if types <> [] && print_tys then (
+ let print_paren = List.length types > 1 in
+ if print_paren then F.pp_print_string fmt "(";
+ Collections.List.iter_link
+ (fun () ->
+ F.pp_print_string fmt ",";
+ F.pp_print_space fmt ())
+ (extract_rec true) types;
+ if print_paren then F.pp_print_string fmt ")";
+ F.pp_print_space fmt ());
+ F.pp_print_string fmt (ctx_get_type type_id ctx);
+ if trait_refs <> [] then (
+ F.pp_print_space fmt ();
+ Collections.List.iter_link (F.pp_print_space fmt)
+ (extract_trait_ref ctx fmt no_params_tys true)
+ trait_refs)))
+ | TypeVar vid -> F.pp_print_string fmt (ctx_get_type_var vid ctx)
+ | Literal lty -> extract_literal_type ctx fmt lty
+ | Arrow (arg_ty, ret_ty) ->
+ if inside then F.pp_print_string fmt "(";
+ extract_rec false arg_ty;
+ F.pp_print_space fmt ();
+ extract_arrow fmt ();
+ F.pp_print_space fmt ();
+ extract_rec false ret_ty;
+ if inside then F.pp_print_string fmt ")"
+ | TraitType (trait_ref, generics, type_name) -> (
+ if !parameterize_trait_types then raise (Failure "Unimplemented")
+ else
+ let type_name =
+ ctx_get_trait_type trait_ref.trait_decl_ref.trait_decl_id type_name
+ ctx
+ in
+ let add_brackets (s : string) =
+ if !backend = Coq then "(" ^ s ^ ")" else s
+ in
+ (* There may be a special treatment depending on the instance id.
+ See the comments for {!extract_trait_instance_id_with_dot}.
+ TODO: there should be a cleaner way to do. The annoying thing
+ here is that if we project directly over the self clause, then
+ we have to be careful (we may not have to print the "Self.").
+ Otherwise, we can directly call {!extract_trait_ref}.
+ *)
+ match trait_ref.trait_id with
+ | Self ->
+ assert (generics = empty_generic_args);
+ assert (trait_ref.generics = empty_generic_args);
+ extract_trait_instance_id_with_dot ctx fmt no_params_tys false
+ trait_ref.trait_id;
+ F.pp_print_string fmt type_name
+ | _ ->
+ (* HOL4 doesn't have 1st class types *)
+ assert (!backend <> HOL4);
+ let use_brackets = generics <> empty_generic_args in
+ if use_brackets then F.pp_print_string fmt "(";
+ extract_trait_ref ctx fmt no_params_tys false trait_ref;
+ extract_generic_args ctx fmt no_params_tys generics;
+ if use_brackets then F.pp_print_string fmt ")";
+ F.pp_print_string fmt ("." ^ add_brackets type_name))
+
+and extract_trait_ref (ctx : extraction_ctx) (fmt : F.formatter)
+ (no_params_tys : TypeDeclId.Set.t) (inside : bool) (tr : trait_ref) : unit =
+ let use_brackets = tr.generics <> empty_generic_args && inside in
+ if use_brackets then F.pp_print_string fmt "(";
+ (* We may need to filter the parameters if the trait is builtin *)
+ let generics =
+ match tr.trait_id with
+ | TraitImpl id -> (
+ match
+ TraitImplId.Map.find_opt id ctx.trait_impls_filter_type_args_map
+ with
+ | None -> tr.generics
+ | Some filter ->
+ let types =
+ List.filter_map
+ (fun (b, x) -> if b then Some x else None)
+ (List.combine filter tr.generics.types)
+ in
+ { tr.generics with types })
+ | _ -> tr.generics
+ in
+ extract_trait_instance_id ctx fmt no_params_tys inside tr.trait_id;
+ extract_generic_args ctx fmt no_params_tys generics;
+ if use_brackets then F.pp_print_string fmt ")"
+
+and extract_trait_decl_ref (ctx : extraction_ctx) (fmt : F.formatter)
+ (no_params_tys : TypeDeclId.Set.t) (inside : bool) (tr : trait_decl_ref) :
+ unit =
+ let use_brackets = tr.decl_generics <> empty_generic_args && inside in
+ let name = ctx_get_trait_decl tr.trait_decl_id ctx in
+ if use_brackets then F.pp_print_string fmt "(";
+ F.pp_print_string fmt name;
+ (* There is something subtle here: the trait obligations for the implemented
+ trait are put inside the parent clauses, so we must ignore them here *)
+ let generics = { tr.decl_generics with trait_refs = [] } in
+ extract_generic_args ctx fmt no_params_tys generics;
+ if use_brackets then F.pp_print_string fmt ")"
+
+and extract_generic_args (ctx : extraction_ctx) (fmt : F.formatter)
+ (no_params_tys : TypeDeclId.Set.t) (generics : generic_args) : unit =
+ let { types; const_generics; trait_refs } = generics in
+ if !backend <> HOL4 then (
+ if types <> [] then (
+ F.pp_print_space fmt ();
+ Collections.List.iter_link (F.pp_print_space fmt)
+ (extract_ty ctx fmt no_params_tys true)
+ types);
+ if const_generics <> [] then (
+ assert (!backend <> HOL4);
+ F.pp_print_space fmt ();
+ Collections.List.iter_link (F.pp_print_space fmt)
+ (extract_const_generic ctx fmt true)
+ const_generics));
+ if trait_refs <> [] then (
+ F.pp_print_space fmt ();
+ Collections.List.iter_link (F.pp_print_space fmt)
+ (extract_trait_ref ctx fmt no_params_tys true)
+ trait_refs)
+
+(** We sometimes need to ignore references to `Self` when generating the
+ code, espcially when we project associated items. For this reason we
+ have a special function for the cases where we project from an instance
+ id (e.g., `<Self as Foo>::foo` - note that in the extracted code, the
+ projections are often written with a dot '.').
+ *)
+and extract_trait_instance_id_with_dot (ctx : extraction_ctx)
+ (fmt : F.formatter) (no_params_tys : TypeDeclId.Set.t) (inside : bool)
+ (id : trait_instance_id) : unit =
+ match id with
+ | Self ->
+ (* There are two situations:
+ - we are extracting a declared item and need to refer to another
+ item (for instance, we are extracting a method signature and
+ need to refer to an associated type).
+ We directly refer to the other item (we extract trait declarations
+ as structures, so we can refer to their fields)
+ - we are extracting a provided method for a trait declaration. We
+ refer to the item in the self trait clause (see {!SelfTraitClauseId}).
+
+ Remark: we can't get there for trait *implementations* because then the
+ types should have been normalized.
+ *)
+ if ctx.is_provided_method then
+ (* Provided method: use the trait self clause *)
+ let self_clause = ctx_get_trait_self_clause ctx in
+ F.pp_print_string fmt (self_clause ^ ".")
+ else
+ (* Declaration: nothing to print, we will directly refer to
+ the item. *)
+ ()
+ | _ ->
+ (* Other cases *)
+ extract_trait_instance_id ctx fmt no_params_tys inside id;
+ F.pp_print_string fmt "."
+
+and extract_trait_instance_id (ctx : extraction_ctx) (fmt : F.formatter)
+ (no_params_tys : TypeDeclId.Set.t) (inside : bool) (id : trait_instance_id)
+ : unit =
+ let add_brackets (s : string) = if !backend = Coq then "(" ^ s ^ ")" else s in
+ match id with
+ | Self ->
+ (* This has a specific treatment depending on the item we're extracting
+ (associated type, etc.). We should have caught this elsewhere. *)
+ if !Config.fail_hard then
+ raise (Failure "Unexpected occurrence of `Self`")
+ else F.pp_print_string fmt "ERROR(\"Unexpected Self\")"
+ | TraitImpl id ->
+ let name = ctx_get_trait_impl id ctx in
+ F.pp_print_string fmt name
+ | Clause id ->
+ let name = ctx_get_local_trait_clause id ctx in
+ F.pp_print_string fmt name
+ | ParentClause (inst_id, decl_id, clause_id) ->
+ (* Use the trait decl id to lookup the name *)
+ let name = ctx_get_trait_parent_clause decl_id clause_id ctx in
+ extract_trait_instance_id_with_dot ctx fmt no_params_tys true inst_id;
+ F.pp_print_string fmt (add_brackets name)
+ | ItemClause (inst_id, decl_id, item_name, clause_id) ->
+ (* Use the trait decl id to lookup the name *)
+ let name = ctx_get_trait_item_clause decl_id item_name clause_id ctx in
+ extract_trait_instance_id_with_dot ctx fmt no_params_tys true inst_id;
+ F.pp_print_string fmt (add_brackets name)
+ | TraitRef trait_ref ->
+ extract_trait_ref ctx fmt no_params_tys inside trait_ref
+ | UnknownTrait _ ->
+ (* This is an error case *)
+ raise (Failure "Unexpected")
+
+(** Compute the names for all the top-level identifiers used in a type
+ definition (type name, variant names, field names, etc. but not type
+ parameters).
+
+ We need to do this preemptively, beforce extracting any definition,
+ because of recursive definitions.
+ *)
+let extract_type_decl_register_names (ctx : extraction_ctx) (def : type_decl) :
+ extraction_ctx =
+ (* Lookup the builtin information, if there is *)
+ let open ExtractBuiltin in
+ let sname = name_to_simple_name def.name in
+ let info = SimpleNameMap.find_opt sname (builtin_types_map ()) in
+ (* Register the filtering information, if there is *)
+ let ctx =
+ match info with
+ | Some { keep_params = Some keep; _ } ->
+ {
+ ctx with
+ types_filter_type_args_map =
+ TypeDeclId.Map.add def.def_id keep ctx.types_filter_type_args_map;
+ }
+ | _ -> ctx
+ in
+ (* Compute and register the type def name *)
+ let def_name =
+ match info with
+ | None -> ctx.fmt.type_name def.name
+ | Some info -> info.extract_name
+ in
+ let ctx = ctx_add (TypeId (AdtId def.def_id)) def_name ctx in
+ (* Compute and register:
+ * - the variant names, if this is an enumeration
+ * - the field names, if this is a structure
+ *)
+ let ctx =
+ match def.kind with
+ | Struct fields ->
+ (* Compute the names *)
+ let field_names, cons_name =
+ match info with
+ | None | Some { body_info = None; _ } ->
+ let field_names =
+ FieldId.mapi
+ (fun fid (field : field) ->
+ (fid, ctx.fmt.field_name def.name fid field.field_name))
+ fields
+ in
+ let cons_name = ctx.fmt.struct_constructor def.name in
+ (field_names, cons_name)
+ | Some { body_info = Some (Struct (cons_name, field_names)); _ } ->
+ let field_names =
+ FieldId.mapi
+ (fun fid (field : field) ->
+ let rust_name = Option.get field.field_name in
+ let name =
+ snd (List.find (fun (n, _) -> n = rust_name) field_names)
+ in
+ (fid, name))
+ fields
+ in
+ (field_names, cons_name)
+ | Some info ->
+ raise
+ (Failure
+ ("Invalid builtin information: "
+ ^ show_builtin_type_info info))
+ in
+ (* Add the fields *)
+ let ctx =
+ List.fold_left
+ (fun ctx (fid, name) ->
+ ctx_add (FieldId (AdtId def.def_id, fid)) name ctx)
+ ctx field_names
+ in
+ (* Add the constructor name *)
+ ctx_add (StructId (AdtId def.def_id)) cons_name ctx
+ | Enum variants ->
+ let variant_names =
+ match info with
+ | None ->
+ VariantId.mapi
+ (fun variant_id (variant : variant) ->
+ let name =
+ ctx.fmt.variant_name def.name variant.variant_name
+ in
+ (* Add the type name prefix for Lean *)
+ let name =
+ if !Config.backend = Lean then
+ let type_name = ctx.fmt.type_name def.name in
+ type_name ^ "." ^ name
+ else name
+ in
+ (variant_id, name))
+ variants
+ | Some { body_info = Some (Enum variant_infos); _ } ->
+ (* We need to compute the map from variant to variant *)
+ let variant_map =
+ StringMap.of_list
+ (List.map
+ (fun (info : builtin_enum_variant_info) ->
+ (info.rust_variant_name, info.extract_variant_name))
+ variant_infos)
+ in
+ VariantId.mapi
+ (fun variant_id (variant : variant) ->
+ (variant_id, StringMap.find variant.variant_name variant_map))
+ variants
+ | _ -> raise (Failure "Invalid builtin information")
+ in
+ List.fold_left
+ (fun ctx (vid, vname) ->
+ ctx_add (VariantId (AdtId def.def_id, vid)) vname ctx)
+ ctx variant_names
+ | Opaque ->
+ (* Nothing to do *)
+ ctx
+ in
+ (* Return *)
+ ctx
+
+(** Print the variants *)
+let extract_type_decl_variant (ctx : extraction_ctx) (fmt : F.formatter)
+ (type_decl_group : TypeDeclId.Set.t) (type_name : string)
+ (type_params : string list) (cg_params : string list) (cons_name : string)
+ (fields : field list) : unit =
+ F.pp_print_space fmt ();
+ (* variant box *)
+ F.pp_open_hvbox fmt ctx.indent_incr;
+ (* [| Cons :]
+ * Note that we really don't want any break above so we print everything
+ * at once. *)
+ let opt_colon = if !backend <> HOL4 then " :" else "" in
+ F.pp_print_string fmt ("| " ^ cons_name ^ opt_colon);
+ let print_field (fid : FieldId.id) (f : field) (ctx : extraction_ctx) :
+ extraction_ctx =
+ F.pp_print_space fmt ();
+ (* Open the field box *)
+ F.pp_open_box fmt ctx.indent_incr;
+ (* Print the field names, if the backend accepts it.
+ * [ x :]
+ * Note that when printing fields, we register the field names as
+ * *variables*: they don't need to be unique at the top level. *)
+ let ctx =
+ match !backend with
+ | FStar -> (
+ match f.field_name with
+ | None -> ctx
+ | Some field_name ->
+ let var_id = VarId.of_int (FieldId.to_int fid) in
+ let field_name =
+ ctx.fmt.var_basename ctx.names_maps.names_map.names_set
+ (Some field_name) f.field_ty
+ in
+ let ctx, field_name = ctx_add_var field_name var_id ctx in
+ F.pp_print_string fmt (field_name ^ " :");
+ F.pp_print_space fmt ();
+ ctx)
+ | Coq | Lean | HOL4 -> ctx
+ in
+ (* Print the field type *)
+ let inside = !backend = HOL4 in
+ extract_ty ctx fmt type_decl_group inside f.field_ty;
+ (* Print the arrow [->] *)
+ if !backend <> HOL4 then (
+ F.pp_print_space fmt ();
+ extract_arrow fmt ());
+ (* Close the field box *)
+ F.pp_close_box fmt ();
+ (* Return *)
+ ctx
+ in
+ (* Print the fields *)
+ let fields = FieldId.mapi (fun fid f -> (fid, f)) fields in
+ let _ =
+ List.fold_left (fun ctx (fid, f) -> print_field fid f ctx) ctx fields
+ in
+ (* Sanity check: HOL4 doesn't support const generics *)
+ assert (cg_params = [] || !backend <> HOL4);
+ (* Print the final type *)
+ if !backend <> HOL4 then (
+ F.pp_print_space fmt ();
+ F.pp_open_hovbox fmt 0;
+ F.pp_print_string fmt type_name;
+ List.iter
+ (fun p ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt p)
+ (List.append type_params cg_params);
+ F.pp_close_box fmt ());
+ (* Close the variant box *)
+ F.pp_close_box fmt ()
+
+(* TODO: we don' need the [def_name] paramter: it can be retrieved from the context *)
+let extract_type_decl_enum_body (ctx : extraction_ctx) (fmt : F.formatter)
+ (type_decl_group : TypeDeclId.Set.t) (def : type_decl) (def_name : string)
+ (type_params : string list) (cg_params : string list)
+ (variants : variant list) : unit =
+ (* We want to generate a definition which looks like this (taking F* as example):
+ {[
+ type list a = | Cons : a -> list a -> list a | Nil : list a
+ ]}
+
+ If there isn't enough space on one line:
+ {[
+ type s =
+ | Cons : a -> list a -> list a
+ | Nil : list a
+ ]}
+
+ And if we need to write the type of a variant on several lines:
+ {[
+ type s =
+ | Cons :
+ a ->
+ list a ->
+ list a
+ | Nil : list a
+ ]}
+
+ Finally, it is possible to give names to the variant fields in Rust.
+ In this situation, we generate a definition like this:
+ {[
+ type s =
+ | Cons : hd:a -> tl:list a -> list a
+ | Nil : list a
+ ]}
+
+ Note that we already printed: [type s =]
+ *)
+ let print_variant _variant_id (v : variant) =
+ (* We don't lookup the name, because it may have a prefix for the type
+ id (in the case of Lean) *)
+ let cons_name = ctx.fmt.variant_name def.name v.variant_name in
+ let fields = v.fields in
+ extract_type_decl_variant ctx fmt type_decl_group def_name type_params
+ cg_params cons_name fields
+ in
+ (* Print the variants *)
+ let variants = VariantId.mapi (fun vid v -> (vid, v)) variants in
+ List.iter (fun (vid, v) -> print_variant vid v) variants
+
+let extract_type_decl_struct_body (ctx : extraction_ctx) (fmt : F.formatter)
+ (type_decl_group : TypeDeclId.Set.t) (kind : decl_kind) (def : type_decl)
+ (type_params : string list) (cg_params : string list) (fields : field list)
+ : unit =
+ (* We want to generate a definition which looks like this (taking F* as example):
+ {[
+ type t = { x : int; y : bool; }
+ ]}
+
+ If there isn't enough space on one line:
+ {[
+ type t =
+ {
+ x : int; y : bool;
+ }
+ ]}
+
+ And if there is even less space:
+ {[
+ type t =
+ {
+ x : int;
+ y : bool;
+ }
+ ]}
+
+ Also, in case there are no fields, we need to define the type as [unit]
+ ([type t = {}] doesn't work in F* ).
+
+ Coq:
+ ====
+ We need to define the constructor name upon defining the struct (record, in Coq).
+ The syntex is:
+ {[
+ Record Foo = mkFoo { x : int; y : bool; }.
+ }]
+
+ Also, Coq doesn't support groups of mutually recursive inductives and records.
+ This is fine, because we can then define records as inductives, and leverage
+ the fact that when record fields are accessed, the records are symbolically
+ expanded which introduces let bindings of the form: [let RecordCons ... = x in ...].
+ As a consequence, we never use the record projectors (unless we reconstruct
+ them in the micro passes of course).
+
+ HOL4:
+ =====
+ Type definitions are written as follows:
+ {[
+ Datatype:
+ tree =
+ TLeaf 'a
+ | TNode node ;
+
+ node =
+ Node (tree list)
+ End
+ ]}
+ *)
+ (* Note that we already printed: [type t =] *)
+ let is_rec = decl_is_from_rec_group kind in
+ let _ =
+ if !backend = FStar && fields = [] then (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt (unit_name ()))
+ else if !backend = Lean && fields = [] then ()
+ (* If the definition is recursive, we may need to extract it as an inductive
+ (instead of a record). We start with the "normal" case: we extract it
+ as a record. *)
+ else if (not is_rec) || (!backend <> Coq && !backend <> Lean) then (
+ if !backend <> Lean then F.pp_print_space fmt ();
+ (* If Coq: print the constructor name *)
+ (* TODO: remove superfluous test not is_rec below *)
+ if !backend = Coq && not is_rec then (
+ F.pp_print_string fmt (ctx_get_struct (AdtId def.def_id) ctx);
+ F.pp_print_string fmt " ");
+ (match !backend with
+ | Lean -> ()
+ | FStar | Coq -> F.pp_print_string fmt "{"
+ | HOL4 -> F.pp_print_string fmt "<|");
+ F.pp_print_break fmt 1 ctx.indent_incr;
+ (* The body itself *)
+ (* Open a box for the body *)
+ (match !backend with
+ | Coq | FStar | HOL4 -> F.pp_open_hvbox fmt 0
+ | Lean -> F.pp_open_vbox fmt 0);
+ (* Print the fields *)
+ let print_field (field_id : FieldId.id) (f : field) : unit =
+ let field_name = ctx_get_field (AdtId def.def_id) field_id ctx in
+ (* Open a box for the field *)
+ F.pp_open_box fmt ctx.indent_incr;
+ F.pp_print_string fmt field_name;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ extract_ty ctx fmt type_decl_group false f.field_ty;
+ if !backend <> Lean then F.pp_print_string fmt ";";
+ (* Close the box for the field *)
+ F.pp_close_box fmt ()
+ in
+ let fields = FieldId.mapi (fun fid f -> (fid, f)) fields in
+ Collections.List.iter_link (F.pp_print_space fmt)
+ (fun (fid, f) -> print_field fid f)
+ fields;
+ (* Close the box for the body *)
+ F.pp_close_box fmt ();
+ match !backend with
+ | Lean -> ()
+ | FStar | Coq ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "}"
+ | HOL4 ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "|>")
+ else (
+ (* We extract for Coq or Lean, and we have a recursive record, or a record in
+ a group of mutually recursive types: we extract it as an inductive type *)
+ assert (is_rec && (!backend = Coq || !backend = Lean));
+ (* Small trick: in Lean we use namespaces, meaning we don't need to prefix
+ the constructor name with the name of the type at definition site,
+ i.e., instead of generating `inductive Foo := | MkFoo ...` like in Coq
+ we generate `inductive Foo := | mk ... *)
+ let cons_name =
+ if !backend = Lean then "mk" else ctx_get_struct (AdtId def.def_id) ctx
+ in
+ let def_name = ctx_get_local_type def.def_id ctx in
+ extract_type_decl_variant ctx fmt type_decl_group def_name type_params
+ cg_params cons_name fields)
+ in
+ ()
+
+(** Extract a nestable, muti-line comment *)
+let extract_comment (fmt : F.formatter) (sl : string list) : unit =
+ (* Delimiters, space after we break a line *)
+ let ld, space, rd =
+ match !backend with
+ | Coq | FStar | HOL4 -> ("(** ", 4, " *)")
+ | Lean -> ("/- ", 3, " -/")
+ in
+ F.pp_open_vbox fmt space;
+ F.pp_print_string fmt ld;
+ (match sl with
+ | [] -> ()
+ | s :: sl ->
+ F.pp_print_string fmt s;
+ List.iter
+ (fun s ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt s)
+ sl);
+ F.pp_print_string fmt rd;
+ F.pp_close_box fmt ()
+
+let extract_trait_clause_type (ctx : extraction_ctx) (fmt : F.formatter)
+ (no_params_tys : TypeDeclId.Set.t) (clause : trait_clause) : unit =
+ let trait_name = ctx_get_trait_decl clause.trait_id ctx in
+ F.pp_print_string fmt trait_name;
+ extract_generic_args ctx fmt no_params_tys clause.generics
+
+(** Insert a space, if necessary *)
+let insert_req_space (fmt : F.formatter) (space : bool ref) : unit =
+ if !space then space := false else F.pp_print_space fmt ()
+
+(** Extract the trait self clause.
+
+ We add the trait self clause for provided methods (see {!TraitSelfClauseId}).
+ *)
+let extract_trait_self_clause (insert_req_space : unit -> unit)
+ (ctx : extraction_ctx) (fmt : F.formatter) (trait_decl : trait_decl)
+ (params : string list) : unit =
+ insert_req_space ();
+ F.pp_print_string fmt "(";
+ let self_clause = ctx_get_trait_self_clause ctx in
+ F.pp_print_string fmt self_clause;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ let trait_id = ctx_get_trait_decl trait_decl.def_id ctx in
+ F.pp_print_string fmt trait_id;
+ List.iter
+ (fun p ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt p)
+ params;
+ F.pp_print_string fmt ")"
+
+(**
+ - [trait_decl]: if [Some], it means we are extracting the generics for a provided
+ method and need to insert a trait self clause (see {!TraitSelfClauseId}).
+ *)
+let extract_generic_params (ctx : extraction_ctx) (fmt : F.formatter)
+ (no_params_tys : TypeDeclId.Set.t) ?(use_forall = false)
+ ?(use_forall_use_sep = true) ?(use_arrows = false)
+ ?(as_implicits : bool = false) ?(space : bool ref option = None)
+ ?(trait_decl : trait_decl option = None) (generics : generic_params)
+ (type_params : string list) (cg_params : string list)
+ (trait_clauses : string list) : unit =
+ let all_params = List.concat [ type_params; cg_params; trait_clauses ] in
+ (* HOL4 doesn't support const generics *)
+ assert (cg_params = [] || !backend <> HOL4);
+ let left_bracket (implicit : bool) =
+ if implicit && !backend <> FStar then F.pp_print_string fmt "{"
+ else F.pp_print_string fmt "("
+ in
+ let right_bracket (implicit : bool) =
+ if implicit && !backend <> FStar then F.pp_print_string fmt "}"
+ else F.pp_print_string fmt ")"
+ in
+ let print_implicit_symbol (implicit : bool) =
+ if implicit && !backend = FStar then F.pp_print_string fmt "#" else ()
+ in
+ let insert_req_space () =
+ match space with
+ | None -> F.pp_print_space fmt ()
+ | Some space -> insert_req_space fmt space
+ in
+ (* Print the type/const generic parameters *)
+ if all_params <> [] then (
+ if use_forall then (
+ if use_forall_use_sep then (
+ insert_req_space ();
+ F.pp_print_string fmt ":");
+ insert_req_space ();
+ F.pp_print_string fmt "forall");
+ (* Small helper - we may need to split the parameters *)
+ let print_generics (as_implicits : bool) (type_params : string list)
+ (const_generics : const_generic_var list)
+ (trait_clauses : trait_clause list) : unit =
+ (* Note that in HOL4 we don't print the type parameters. *)
+ if !backend <> HOL4 then (
+ (* Print the type parameters *)
+ if type_params <> [] then (
+ insert_req_space ();
+ (* ( *)
+ left_bracket as_implicits;
+ List.iter
+ (fun s ->
+ print_implicit_symbol as_implicits;
+ F.pp_print_string fmt s;
+ F.pp_print_space fmt ())
+ type_params;
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt (type_keyword ());
+ (* ) *)
+ right_bracket as_implicits;
+ if use_arrows then (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "->"));
+ (* Print the const generic parameters *)
+ List.iter
+ (fun (var : const_generic_var) ->
+ insert_req_space ();
+ (* ( *)
+ left_bracket as_implicits;
+ let n = ctx_get_const_generic_var var.index ctx in
+ print_implicit_symbol as_implicits;
+ F.pp_print_string fmt n;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ extract_literal_type ctx fmt var.ty;
+ (* ) *)
+ right_bracket as_implicits;
+ if use_arrows then (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "->"))
+ const_generics);
+ (* Print the trait clauses *)
+ List.iter
+ (fun (clause : trait_clause) ->
+ insert_req_space ();
+ (* ( *)
+ left_bracket as_implicits;
+ let n = ctx_get_local_trait_clause clause.clause_id ctx in
+ print_implicit_symbol as_implicits;
+ F.pp_print_string fmt n;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ extract_trait_clause_type ctx fmt no_params_tys clause;
+ (* ) *)
+ right_bracket as_implicits;
+ if use_arrows then (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "->"))
+ trait_clauses
+ in
+ (* If we extract the generics for a provided method for a trait declaration
+ (indicated by the trait decl given as input), we need to split the generics:
+ - we print the generics for the trait decl
+ - we print the trait self clause
+ - we print the generics for the trait method
+ *)
+ match trait_decl with
+ | None ->
+ print_generics as_implicits type_params generics.const_generics
+ generics.trait_clauses
+ | Some trait_decl ->
+ (* Split the generics between the generics specific to the trait decl
+ and those specific to the trait method *)
+ let open Collections.List in
+ let dtype_params, mtype_params =
+ split_at type_params (length trait_decl.generics.types)
+ in
+ let dcgs, mcgs =
+ split_at generics.const_generics
+ (length trait_decl.generics.const_generics)
+ in
+ let dtrait_clauses, mtrait_clauses =
+ split_at generics.trait_clauses
+ (length trait_decl.generics.trait_clauses)
+ in
+ (* Extract the trait decl generics - note that we can always deduce
+ those parameters from the trait self clause: for this reason
+ they are always implicit *)
+ print_generics true dtype_params dcgs dtrait_clauses;
+ (* Extract the trait self clause *)
+ let params =
+ concat
+ [
+ dtype_params;
+ map
+ (fun (cg : const_generic_var) ->
+ ctx_get_const_generic_var cg.index ctx)
+ dcgs;
+ map
+ (fun c -> ctx_get_local_trait_clause c.clause_id ctx)
+ dtrait_clauses;
+ ]
+ in
+ extract_trait_self_clause insert_req_space ctx fmt trait_decl params;
+ (* Extract the method generics *)
+ print_generics as_implicits mtype_params mcgs mtrait_clauses)
+
+(** Extract a type declaration.
+
+ This function is for all type declarations and all backends **at the exception**
+ of opaque (assumed/declared) types format4 HOL4.
+
+ See {!extract_type_decl}.
+ *)
+let extract_type_decl_gen (ctx : extraction_ctx) (fmt : F.formatter)
+ (type_decl_group : TypeDeclId.Set.t) (kind : decl_kind) (def : type_decl)
+ (extract_body : bool) : unit =
+ (* Sanity check *)
+ assert (extract_body || !backend <> HOL4);
+ let type_kind =
+ if extract_body then
+ match def.kind with
+ | Struct _ -> Some Struct
+ | Enum _ -> Some Enum
+ | Opaque -> None
+ else None
+ in
+ (* If in Coq and the declaration is opaque, it must have the shape:
+ [Axiom Ident : forall (T0 ... Tn : Type) (N0 : ...) ... (Nn : ...), ... -> ... -> ...].
+
+ The boolean [is_opaque_coq] is used to detect this case.
+ *)
+ let is_opaque = type_kind = None in
+ let is_opaque_coq = !backend = Coq && is_opaque in
+ let use_forall = is_opaque_coq && def.generics <> empty_generic_params in
+ (* Retrieve the definition name *)
+ let def_name = ctx_get_local_type def.def_id ctx in
+ (* Add the type and const generic params - note that we need those bindings only for the
+ * body translation (they are not top-level) *)
+ let ctx_body, type_params, cg_params, trait_clauses =
+ ctx_add_generic_params def.generics ctx
+ in
+ (* Add a break before *)
+ if !backend <> HOL4 || not (decl_is_first_from_group kind) then
+ F.pp_print_break fmt 0 0;
+ (* Print a comment to link the extracted type to its original rust definition *)
+ extract_comment fmt [ "[" ^ Print.name_to_string def.name ^ "]" ];
+ F.pp_print_break fmt 0 0;
+ (* Open a box for the definition, so that whenever possible it gets printed on
+ * one line. Note however that in the case of Lean line breaks are important
+ * for parsing: we thus use a hovbox. *)
+ (match !backend with
+ | Coq | FStar | HOL4 -> F.pp_open_hvbox fmt 0
+ | Lean -> F.pp_open_vbox fmt 0);
+ (* Open a box for "type TYPE_NAME (TYPE_PARAMS CONST_GEN_PARAMS) =" *)
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ (* > "type TYPE_NAME" *)
+ let qualif = ctx.fmt.type_decl_kind_to_qualif kind type_kind in
+ (match qualif with
+ | Some qualif -> F.pp_print_string fmt (qualif ^ " " ^ def_name)
+ | None -> F.pp_print_string fmt def_name);
+ (* HOL4 doesn't support const generics, and type definitions in HOL4 don't
+ support trait clauses *)
+ assert ((cg_params = [] && trait_clauses = []) || !backend <> HOL4);
+ (* Print the generic parameters *)
+ extract_generic_params ctx_body fmt type_decl_group ~use_forall def.generics
+ type_params cg_params trait_clauses;
+ (* Print the "=" if we extract the body*)
+ if extract_body then (
+ F.pp_print_space fmt ();
+ let eq =
+ match !backend with
+ | FStar -> "="
+ | Coq -> ":="
+ | Lean ->
+ if type_kind = Some Struct && kind = SingleNonRec then "where"
+ else ":="
+ | HOL4 -> "="
+ in
+ F.pp_print_string fmt eq)
+ else (
+ (* Otherwise print ": Type", unless it is the HOL4 backend (in
+ which case we declare the type with `new_type`) *)
+ if use_forall then F.pp_print_string fmt ","
+ else (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":");
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt (type_keyword ()));
+ (* Close the box for "type TYPE_NAME (TYPE_PARAMS) =" *)
+ F.pp_close_box fmt ();
+ (if extract_body then
+ match def.kind with
+ | Struct fields ->
+ extract_type_decl_struct_body ctx_body fmt type_decl_group kind def
+ type_params cg_params fields
+ | Enum variants ->
+ extract_type_decl_enum_body ctx_body fmt type_decl_group def def_name
+ type_params cg_params variants
+ | Opaque -> raise (Failure "Unreachable"));
+ (* Add the definition end delimiter *)
+ if !backend = HOL4 && decl_is_not_last_from_group kind then (
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ";")
+ else if !backend = Coq && decl_is_last_from_group kind then (
+ (* This is actually an end of group delimiter. For aesthetic reasons
+ we print it here instead of in {!end_type_decl_group}. *)
+ F.pp_print_cut fmt ();
+ F.pp_print_string fmt ".");
+ (* Close the box for the definition *)
+ F.pp_close_box fmt ();
+ (* Add breaks to insert new lines between definitions *)
+ if !backend <> HOL4 || decl_is_not_last_from_group kind then
+ F.pp_print_break fmt 0 0
+
+(** Extract an opaque type declaration to HOL4.
+
+ Remark (SH): having to treat this specific case separately is very annoying,
+ but I could not find a better way.
+ *)
+let extract_type_decl_hol4_opaque (ctx : extraction_ctx) (fmt : F.formatter)
+ (def : type_decl) : unit =
+ (* Retrieve the definition name *)
+ let def_name = ctx_get_local_type def.def_id ctx in
+ (* Generic parameters are unsupported *)
+ assert (def.generics.const_generics = []);
+ (* Trait clauses on type definitions are unsupported *)
+ assert (def.generics.trait_clauses = []);
+ (* Types *)
+ (* Count the number of parameters *)
+ let num_params = List.length def.generics.types in
+ (* Generate the declaration *)
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt
+ ("val _ = new_type (\"" ^ def_name ^ "\", " ^ string_of_int num_params ^ ")");
+ F.pp_print_space fmt ()
+
+(** Extract an empty record type declaration to HOL4.
+
+ Empty records are not supported in HOL4, so we extract them as type
+ abbreviations to the unit type.
+
+ Remark (SH): having to treat this specific case separately is very annoying,
+ but I could not find a better way.
+ *)
+let extract_type_decl_hol4_empty_record (ctx : extraction_ctx)
+ (fmt : F.formatter) (def : type_decl) : unit =
+ (* Retrieve the definition name *)
+ let def_name = ctx_get_local_type def.def_id ctx in
+ (* Sanity check *)
+ assert (def.generics = empty_generic_params);
+ (* Generate the declaration *)
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ("Type " ^ def_name ^ " = “: unit”");
+ F.pp_print_space fmt ()
+
+(** Extract a type declaration.
+
+ Note that all the names used for extraction should already have been
+ registered.
+
+ This function should be inserted between calls to {!start_type_decl_group}
+ and {!end_type_decl_group}.
+ *)
+let extract_type_decl (ctx : extraction_ctx) (fmt : F.formatter)
+ (type_decl_group : TypeDeclId.Set.t) (kind : decl_kind) (def : type_decl) :
+ unit =
+ let extract_body =
+ match kind with
+ | SingleNonRec | SingleRec | MutRecFirst | MutRecInner | MutRecLast -> true
+ | Assumed | Declared -> false
+ in
+ if extract_body then
+ if !backend = HOL4 && is_empty_record_type_decl def then
+ extract_type_decl_hol4_empty_record ctx fmt def
+ else extract_type_decl_gen ctx fmt type_decl_group kind def extract_body
+ else
+ match !backend with
+ | FStar | Coq | Lean ->
+ extract_type_decl_gen ctx fmt type_decl_group kind def extract_body
+ | HOL4 -> extract_type_decl_hol4_opaque ctx fmt def
+
+(** Generate a [Argument] instruction in Coq to allow omitting implicit
+ arguments for variants, fields, etc..
+
+ For instance, provided we have this definition:
+ {[
+ Inductive result A :=
+ | Return : A -> result A
+ | Fail_ : error -> result A.
+ ]}
+
+ We may want to generate those instructions:
+ {[
+ Arguments Return {_} a.
+ Arguments Fail_ {_}.
+ ]}
+ *)
+let extract_coq_arguments_instruction (ctx : extraction_ctx) (fmt : F.formatter)
+ (cons_name : string) (num_implicit_params : int) : unit =
+ (* Add a break before *)
+ F.pp_print_break fmt 0 0;
+ (* Open a box *)
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ F.pp_print_break fmt 0 0;
+ F.pp_print_string fmt "Arguments";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt cons_name;
+ (* Print the type/const params and the trait clauses (`{T}`) *)
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "{";
+ Collections.List.iter_times num_implicit_params (fun () ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "_");
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "}.";
+
+ (* Close the box *)
+ F.pp_close_box fmt ()
+
+(** Auxiliary function.
+
+ Generate [Arguments] instructions in Coq for type definitions.
+ *)
+let extract_type_decl_coq_arguments (ctx : extraction_ctx) (fmt : F.formatter)
+ (kind : decl_kind) (decl : type_decl) : unit =
+ assert (!backend = Coq);
+ (* Generating the [Arguments] instructions is useful only if there are parameters *)
+ let num_params =
+ List.length decl.generics.types
+ + List.length decl.generics.const_generics
+ + List.length decl.generics.trait_clauses
+ in
+ if num_params = 0 then ()
+ else
+ (* Generate the [Arguments] instruction *)
+ match decl.kind with
+ | Opaque -> ()
+ | Struct fields ->
+ let adt_id = AdtId decl.def_id in
+ (* Generate the instruction for the record constructor *)
+ let cons_name = ctx_get_struct adt_id ctx in
+ extract_coq_arguments_instruction ctx fmt cons_name num_params;
+ (* Generate the instruction for the record projectors, if there are *)
+ let is_rec = decl_is_from_rec_group kind in
+ if not is_rec then
+ FieldId.iteri
+ (fun fid _ ->
+ let cons_name = ctx_get_field adt_id fid ctx in
+ extract_coq_arguments_instruction ctx fmt cons_name num_params)
+ fields;
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0
+ | Enum variants ->
+ (* Generate the instructions *)
+ VariantId.iteri
+ (fun vid (_ : variant) ->
+ let cons_name = ctx_get_variant (AdtId decl.def_id) vid ctx in
+ extract_coq_arguments_instruction ctx fmt cons_name num_params)
+ variants;
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0
+
+(** Auxiliary function.
+
+ Generate field projectors in Coq.
+
+ Sometimes we extract records as inductives in Coq: when this happens we
+ have to define the field projectors afterwards.
+ *)
+let extract_type_decl_record_field_projectors (ctx : extraction_ctx)
+ (fmt : F.formatter) (kind : decl_kind) (decl : type_decl) : unit =
+ assert (!backend = Coq);
+ match decl.kind with
+ | Opaque | Enum _ -> ()
+ | Struct fields ->
+ (* Records are extracted as inductives only if they are recursive *)
+ let is_rec = decl_is_from_rec_group kind in
+ if is_rec then
+ (* Add the type params *)
+ let ctx, type_params, cg_params, trait_clauses =
+ ctx_add_generic_params decl.generics ctx
+ in
+ let ctx, record_var = ctx_add_var "x" (VarId.of_int 0) ctx in
+ let ctx, field_var = ctx_add_var "x" (VarId.of_int 1) ctx in
+ let def_name = ctx_get_local_type decl.def_id ctx in
+ let cons_name = ctx_get_struct (AdtId decl.def_id) ctx in
+ let extract_field_proj (field_id : FieldId.id) (_ : field) : unit =
+ F.pp_print_space fmt ();
+ (* Outer box for the projector definition *)
+ F.pp_open_hvbox fmt 0;
+ (* Inner box for the projector definition *)
+ F.pp_open_hvbox fmt ctx.indent_incr;
+ (* Open a box for the [Definition PROJ ... :=] *)
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ F.pp_print_string fmt "Definition";
+ F.pp_print_space fmt ();
+ let field_name = ctx_get_field (AdtId decl.def_id) field_id ctx in
+ F.pp_print_string fmt field_name;
+ (* Print the generics *)
+ let as_implicits = true in
+ extract_generic_params ctx fmt TypeDeclId.Set.empty ~as_implicits
+ decl.generics type_params cg_params trait_clauses;
+ (* Print the record parameter *)
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "(";
+ F.pp_print_string fmt record_var;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt def_name;
+ List.iter
+ (fun p ->
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt p)
+ type_params;
+ F.pp_print_string fmt ")";
+ (* *)
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":=";
+ (* Close the box for the [Definition PROJ ... :=] *)
+ F.pp_close_box fmt ();
+ F.pp_print_space fmt ();
+ (* Open a box for the whole match *)
+ F.pp_open_hvbox fmt 0;
+ (* Open a box for the [match ... with] *)
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ F.pp_print_string fmt "match";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt record_var;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "with";
+ (* Close the box for the [match ... with] *)
+ F.pp_close_box fmt ();
+
+ (* Open a box for the branch *)
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ (* Print the match branch *)
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "|";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt cons_name;
+ FieldId.iteri
+ (fun id _ ->
+ F.pp_print_space fmt ();
+ if field_id = id then F.pp_print_string fmt field_var
+ else F.pp_print_string fmt "_")
+ fields;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "=>";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt field_var;
+ (* Close the box for the branch *)
+ F.pp_close_box fmt ();
+ (* Print the [end] *)
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "end";
+ (* Close the box for the whole match *)
+ F.pp_close_box fmt ();
+ (* Close the inner box projector *)
+ F.pp_close_box fmt ();
+ (* If Coq: end the definition with a "." *)
+ if !backend = Coq then (
+ F.pp_print_cut fmt ();
+ F.pp_print_string fmt ".");
+ (* Close the outer box projector *)
+ F.pp_close_box fmt ();
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0
+ in
+
+ let extract_proj_notation (field_id : FieldId.id) (_ : field) : unit =
+ F.pp_print_space fmt ();
+ (* Outer box for the projector definition *)
+ F.pp_open_hvbox fmt 0;
+ (* Inner box for the projector definition *)
+ F.pp_open_hovbox fmt ctx.indent_incr;
+ let ctx, record_var = ctx_add_var "x" (VarId.of_int 0) ctx in
+ F.pp_print_string fmt "Notation";
+ F.pp_print_space fmt ();
+ let field_name = ctx_get_field (AdtId decl.def_id) field_id ctx in
+ F.pp_print_string fmt ("\"" ^ record_var ^ " .(" ^ field_name ^ ")\"");
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":=";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "(";
+ F.pp_print_string fmt field_name;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt record_var;
+ F.pp_print_string fmt ")";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "(at level 9)";
+ (* Close the inner box projector *)
+ F.pp_close_box fmt ();
+ (* If Coq: end the definition with a "." *)
+ if !backend = Coq then (
+ F.pp_print_cut fmt ();
+ F.pp_print_string fmt ".");
+ (* Close the outer box projector *)
+ F.pp_close_box fmt ();
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0
+ in
+
+ let extract_field_proj_and_notation (field_id : FieldId.id)
+ (field : field) : unit =
+ extract_field_proj field_id field;
+ extract_proj_notation field_id field
+ in
+
+ FieldId.iteri extract_field_proj_and_notation fields
+
+(** Extract extra information for a type (e.g., [Arguments] instructions in Coq).
+
+ Note that all the names used for extraction should already have been
+ registered.
+ *)
+let extract_type_decl_extra_info (ctx : extraction_ctx) (fmt : F.formatter)
+ (kind : decl_kind) (decl : type_decl) : unit =
+ match !backend with
+ | FStar | Lean | HOL4 -> ()
+ | Coq ->
+ extract_type_decl_coq_arguments ctx fmt kind decl;
+ extract_type_decl_record_field_projectors ctx fmt kind decl
+
+(** Extract the state type declaration. *)
+let extract_state_type (fmt : F.formatter) (ctx : extraction_ctx)
+ (kind : decl_kind) : unit =
+ (* Add a break before *)
+ F.pp_print_break fmt 0 0;
+ (* Print a comment *)
+ extract_comment fmt [ "The state type used in the state-error monad" ];
+ F.pp_print_break fmt 0 0;
+ (* Open a box for the definition, so that whenever possible it gets printed on
+ * one line *)
+ F.pp_open_hvbox fmt 0;
+ (* Retrieve the name *)
+ let state_name = ctx_get_assumed_type State ctx in
+ (* The syntax for Lean and Coq is almost identical. *)
+ let print_axiom () =
+ let axiom =
+ match !backend with
+ | Coq -> "Axiom"
+ | Lean -> "axiom"
+ | FStar | HOL4 -> raise (Failure "Unexpected")
+ in
+ F.pp_print_string fmt axiom;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt state_name;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "Type";
+ if !backend = Coq then F.pp_print_string fmt "."
+ in
+ (* The kind should be [Assumed] or [Declared] *)
+ (match kind with
+ | SingleNonRec | SingleRec | MutRecFirst | MutRecInner | MutRecLast ->
+ raise (Failure "Unexpected")
+ | Assumed -> (
+ match !backend with
+ | FStar ->
+ F.pp_print_string fmt "assume";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "type";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt state_name;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "Type0"
+ | HOL4 ->
+ F.pp_print_string fmt ("val _ = new_type (\"" ^ state_name ^ "\", 0)")
+ | Coq | Lean -> print_axiom ())
+ | Declared -> (
+ match !backend with
+ | FStar ->
+ F.pp_print_string fmt "val";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt state_name;
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt ":";
+ F.pp_print_space fmt ();
+ F.pp_print_string fmt "Type0"
+ | HOL4 ->
+ F.pp_print_string fmt ("val _ = new_type (\"" ^ state_name ^ "\", 0)")
+ | Coq | Lean -> print_axiom ()));
+ (* Close the box for the definition *)
+ F.pp_close_box fmt ();
+ (* Add breaks to insert new lines between definitions *)
+ F.pp_print_break fmt 0 0
diff --git a/compiler/FunsAnalysis.ml b/compiler/FunsAnalysis.ml
index b72fa078..e17ea16f 100644
--- a/compiler/FunsAnalysis.ml
+++ b/compiler/FunsAnalysis.ml
@@ -57,12 +57,26 @@ let analyze_module (m : crate) (funs_map : fun_decl FunDeclId.Map.t)
let stateful = ref false in
let can_diverge = ref false in
let is_rec = ref false in
+ let group_has_builtin_info = ref false in
+
+ (* We have some specialized knowledge of some library functions; we don't
+ have any more custom treatment than this, and these functions can be modeled
+ suitably in Primitives.fst, rather than special-casing for them all the
+ way. *)
+ let get_builtin_info (f : fun_decl) : ExtractBuiltin.effect_info option =
+ let open ExtractBuiltin in
+ let name = name_to_simple_name f.name in
+ SimpleNameMap.find_opt name builtin_fun_effects_map
+ in
+ (* JP: Why not use a reduce visitor here with a tuple of the values to be
+ computed? *)
let visit_fun (f : fun_decl) : unit =
let obj =
object (self)
inherit [_] iter_statement as super
method may_fail b = can_fail := !can_fail || b
+ method maybe_stateful b = stateful := !stateful || b
method! visit_Assert env a =
self#may_fail true;
@@ -70,14 +84,14 @@ let analyze_module (m : crate) (funs_map : fun_decl FunDeclId.Map.t)
method! visit_rvalue _env rv =
match rv with
- | Use _ | Ref _ | Global _ | Discriminant _ | Aggregate _ -> ()
+ | Use _ | RvRef _ | Global _ | Discriminant _ | Aggregate _ -> ()
| UnaryOp (uop, _) -> can_fail := EU.unop_can_fail uop || !can_fail
| BinaryOp (bop, _, _) ->
can_fail := EU.binop_can_fail bop || !can_fail
method! visit_Call env call =
- (match call.func with
- | Regular id ->
+ (match call.func.func with
+ | FunId (Regular id) ->
if FunDeclId.Set.mem id fun_ids then (
can_diverge := true;
is_rec := true)
@@ -86,9 +100,14 @@ let analyze_module (m : crate) (funs_map : fun_decl FunDeclId.Map.t)
self#may_fail info.can_fail;
stateful := !stateful || info.stateful;
can_diverge := !can_diverge || info.can_diverge
- | Assumed id ->
+ | FunId (Assumed id) ->
(* None of the assumed functions can diverge nor are considered stateful *)
- can_fail := !can_fail || Assumed.assumed_can_fail id);
+ can_fail := !can_fail || Assumed.assumed_fun_can_fail id
+ | TraitMethod _ ->
+ (* We consider trait functions can fail, but can not diverge and are not stateful.
+ TODO: this may cause issues if we use use a fuel parameter.
+ *)
+ can_fail := true);
super#visit_Call env call
method! visit_Panic env =
@@ -102,11 +121,21 @@ let analyze_module (m : crate) (funs_map : fun_decl FunDeclId.Map.t)
in
(* Sanity check: global bodies don't contain stateful calls *)
assert ((not f.is_global_decl_body) || not !stateful);
+ let builtin_info = get_builtin_info f in
+ let has_builtin_info = builtin_info <> None in
+ group_has_builtin_info := !group_has_builtin_info || has_builtin_info;
match f.body with
| None ->
- (* Opaque function: we consider they fail by default *)
- obj#may_fail true;
- stateful := (not f.is_global_decl_body) && use_state
+ let info_can_fail, info_stateful =
+ match builtin_info with
+ | None -> (true, use_state)
+ | Some { can_fail; stateful } -> (can_fail, stateful)
+ in
+ obj#may_fail info_can_fail;
+ obj#maybe_stateful
+ (if f.is_global_decl_body then false
+ else if not use_state then false
+ else info_stateful)
| Some body -> obj#visit_statement () body.body
in
List.iter visit_fun d;
@@ -114,12 +143,17 @@ let analyze_module (m : crate) (funs_map : fun_decl FunDeclId.Map.t)
* groups containing globals contain exactly one declaration *)
let is_global_decl_body = List.exists (fun f -> f.is_global_decl_body) d in
assert ((not is_global_decl_body) || List.length d = 1);
+ assert ((not !group_has_builtin_info) || List.length d = 1);
(* We ignore on purpose functions that cannot fail and consider they *can*
* fail: the result of the analysis is not used yet to adjust the translation
* so that the functions which syntactically can't fail don't use an error monad.
- * However, we do keep the result of the analysis for global bodies.
+ * However, we do keep the result of the analysis for global bodies and for
+ * builtin functions which are marked as non-fallible.
* *)
- can_fail := (not is_global_decl_body) || !can_fail;
+ can_fail :=
+ if is_global_decl_body then !can_fail
+ else if !group_has_builtin_info then !can_fail
+ else true;
{
can_fail = !can_fail;
stateful = !stateful;
@@ -141,7 +175,8 @@ let analyze_module (m : crate) (funs_map : fun_decl FunDeclId.Map.t)
let rec analyze_decl_groups (decls : declaration_group list) : unit =
match decls with
| [] -> ()
- | Type _ :: decls' -> analyze_decl_groups decls'
+ | (Type _ | TraitDecl _ | TraitImpl _) :: decls' ->
+ analyze_decl_groups decls'
| Fun decl :: decls' ->
analyze_fun_decl_group decl;
analyze_decl_groups decls'
diff --git a/compiler/Interpreter.ml b/compiler/Interpreter.ml
index 154c5a21..24ff4808 100644
--- a/compiler/Interpreter.ml
+++ b/compiler/Interpreter.ml
@@ -12,55 +12,165 @@ module SA = SymbolicAst
(** The local logger *)
let log = L.interpreter_log
-let compute_type_fun_global_contexts (m : A.crate) :
- C.type_context * C.fun_context * C.global_context =
- let type_decls_list, _, _ = split_declarations m.declarations in
+let compute_contexts (m : A.crate) : C.decls_ctx =
+ let type_decls_list, _, _, _, _ = split_declarations m.declarations in
let type_decls = m.types in
let fun_decls = m.functions in
let global_decls = m.globals in
- let type_decls_groups, _funs_defs_groups, _globals_defs_groups =
+ let trait_decls = m.trait_decls in
+ let trait_impls = m.trait_impls in
+ let type_decls_groups, _, _, _, _ =
split_declarations_to_group_maps m.declarations
in
let type_infos =
TypesAnalysis.analyze_type_declarations type_decls type_decls_list
in
- let type_context = { C.type_decls_groups; type_decls; type_infos } in
- let fun_context = { C.fun_decls } in
- let global_context = { C.global_decls } in
- (type_context, fun_context, global_context)
-
-let initialize_eval_context (type_context : C.type_context)
- (fun_context : C.fun_context) (global_context : C.global_context)
- (region_groups : T.RegionGroupId.id list) (type_vars : T.type_var list)
- (const_generic_vars : T.const_generic_var list) : C.eval_ctx =
- C.reset_global_counters ();
- {
- C.type_context;
- C.fun_context;
- C.global_context;
- C.region_groups;
- C.type_vars;
- C.const_generic_vars;
- C.env = [ C.Frame ];
- C.ended_regions = T.RegionId.Set.empty;
- }
+ let type_ctx = { C.type_decls_groups; type_decls; type_infos } in
+ let fun_infos =
+ FunsAnalysis.analyze_module m fun_decls global_decls !Config.use_state
+ in
+ let fun_ctx = { C.fun_decls; fun_infos } in
+ let global_ctx = { C.global_decls } in
+ let trait_decls_ctx = { C.trait_decls } in
+ let trait_impls_ctx = { C.trait_impls } in
+ { C.type_ctx; fun_ctx; global_ctx; trait_decls_ctx; trait_impls_ctx }
+
+(** Small helper.
+
+ Normalize an instantiated function signature provided we used this signature
+ to compute a normalization map (for the associated types) and that we added
+ it in the context.
+ *)
+let normalize_inst_fun_sig (ctx : C.eval_ctx) (sg : A.inst_fun_sig) :
+ A.inst_fun_sig =
+ let { A.regions_hierarchy = _; trait_type_constraints = _; inputs; output } =
+ sg
+ in
+ let norm = AssociatedTypes.ctx_normalize_rty ctx in
+ let inputs = List.map norm inputs in
+ let output = norm output in
+ { sg with A.inputs; output }
+
+(** Instantiate a function signature for a symbolic execution.
+
+ We return a new context because we compute and add the type normalization
+ map in the same step.
+
+ **WARNING**: this doesn't normalize the types. This step has to be done
+ separately. Remark: we need to normalize essentially because of the where
+ clauses (we are not considering a function call, so we don't need to
+ normalize because a trait clause was instantiated with a specific trait ref).
+ *)
+let symbolic_instantiate_fun_sig (ctx : C.eval_ctx) (sg : A.fun_sig)
+ (kind : A.fun_kind) : C.eval_ctx * A.inst_fun_sig =
+ let tr_self =
+ match kind with
+ | RegularKind | TraitMethodImpl _ -> T.UnknownTrait __FUNCTION__
+ | TraitMethodDecl _ | TraitMethodProvided _ -> T.Self
+ in
+ let generics =
+ let { T.regions; types; const_generics; trait_clauses } = sg.generics in
+ let regions = List.map (fun _ -> T.Erased) regions in
+ let types = List.map (fun (v : T.type_var) -> T.TypeVar v.T.index) types in
+ let const_generics =
+ List.map
+ (fun (v : T.const_generic_var) -> T.ConstGenericVar v.T.index)
+ const_generics
+ in
+ (* Annoying that we have to generate this substitution here *)
+ let r_subst _ = raise (Failure "Unexpected region") in
+ let ty_subst = Subst.make_type_subst_from_vars sg.generics.types types in
+ let cg_subst =
+ Subst.make_const_generic_subst_from_vars sg.generics.const_generics
+ const_generics
+ in
+ (* TODO: some clauses may use the types of other clauses, so we may have to
+ reorder them.
+
+ Example:
+ If in Rust we write:
+ {[
+ pub fn use_get<'a, T: Get>(x: &'a mut T) -> u32
+ where
+ T::Item: ToU32,
+ {
+ x.get().to_u32()
+ }
+ ]}
+
+ In LLBC we get:
+ {[
+ fn demo::use_get<'a, T>(@1: &'a mut (T)) -> u32
+ where
+ [@TraitClause0]: demo::Get<T>,
+ [@TraitClause1]: demo::ToU32<@TraitClause0::Item>, // HERE
+ {
+ ... // Omitted
+ }
+ ]}
+ *)
+ (* We will need to update the trait refs map while we perform the instantiations *)
+ let mk_tr_subst
+ (tr_map : T.erased_region T.trait_instance_id T.TraitClauseId.Map.t)
+ clause_id : T.erased_region T.trait_instance_id =
+ match T.TraitClauseId.Map.find_opt clause_id tr_map with
+ | Some tr -> tr
+ | None -> raise (Failure "Local trait clause not found")
+ in
+ let mk_subst tr_map =
+ let tr_subst = mk_tr_subst tr_map in
+ { Subst.r_subst; ty_subst; cg_subst; tr_subst; tr_self }
+ in
+ let _, trait_refs =
+ List.fold_left_map
+ (fun tr_map (c : T.trait_clause) ->
+ let subst = mk_subst tr_map in
+ let { T.trait_id = trait_decl_id; generics; _ } = c in
+ let generics = Subst.generic_args_substitute subst generics in
+ let trait_decl_ref = { T.trait_decl_id; decl_generics = generics } in
+ (* Note that because we directly refer to the clause, we give it
+ empty generics *)
+ let trait_id = T.Clause c.clause_id in
+ let trait_ref =
+ {
+ T.trait_id;
+ generics = TypesUtils.mk_empty_generic_args;
+ trait_decl_ref;
+ }
+ in
+ (* Update the traits map *)
+ let tr_map = T.TraitClauseId.Map.add c.T.clause_id trait_id tr_map in
+ (tr_map, trait_ref))
+ T.TraitClauseId.Map.empty trait_clauses
+ in
+ { T.regions; types; const_generics; trait_refs }
+ in
+ let inst_sg = instantiate_fun_sig ctx generics tr_self sg in
+ (* Compute the normalization maps *)
+ let ctx =
+ AssociatedTypes.ctx_add_norm_trait_types_from_preds ctx
+ inst_sg.trait_type_constraints
+ in
+ (* Normalize the signature *)
+ let inst_sg = normalize_inst_fun_sig ctx inst_sg in
+ (* Return *)
+ (ctx, inst_sg)
(** Initialize an evaluation context to execute a function.
- Introduces local variables initialized in the following manner:
- - input arguments are initialized as symbolic values
- - the remaining locals are initialized as [⊥]
- Abstractions are introduced for the regions present in the function
- signature.
-
- We return:
- - the initialized evaluation context
- - the list of symbolic values introduced for the input values
- - the instantiated function signature
+ Introduces local variables initialized in the following manner:
+ - input arguments are initialized as symbolic values
+ - the remaining locals are initialized as [⊥]
+ Abstractions are introduced for the regions present in the function
+ signature.
+
+ We return:
+ - the initialized evaluation context
+ - the list of symbolic values introduced for the input values
+ - the instantiated function signature
*)
-let initialize_symbolic_context_for_fun (type_context : C.type_context)
- (fun_context : C.fun_context) (global_context : C.global_context)
- (fdef : A.fun_decl) : C.eval_ctx * V.symbolic_value list * A.inst_fun_sig =
+let initialize_symbolic_context_for_fun (ctx : C.decls_ctx) (fdef : A.fun_decl)
+ : C.eval_ctx * V.symbolic_value list * A.inst_fun_sig =
(* The abstractions are not initialized the same way as for function
* calls: they contain *loan* projectors, because they "provide" us
* with the input values (which behave as if they had been returned
@@ -78,19 +188,15 @@ let initialize_symbolic_context_for_fun (type_context : C.type_context)
List.map (fun (g : T.region_var_group) -> g.id) sg.regions_hierarchy
in
let ctx =
- initialize_eval_context type_context fun_context global_context
- region_groups sg.type_params sg.const_generic_params
+ initialize_eval_context ctx region_groups sg.generics.types
+ sg.generics.const_generics
in
- (* Instantiate the signature *)
- let type_params =
- List.map (fun (v : T.type_var) -> T.TypeVar v.T.index) sg.type_params
+ (* Instantiate the signature. This updates the context because we compute
+ at the same time the normalization map for the associated types.
+ *)
+ let ctx, inst_sg =
+ symbolic_instantiate_fun_sig ctx fdef.signature fdef.kind
in
- let cg_params =
- List.map
- (fun (v : T.const_generic_var) -> T.ConstGenericVar v.T.index)
- sg.const_generic_params
- in
- let inst_sg = instantiate_fun_sig type_params cg_params sg in
(* Create fresh symbolic values for the inputs *)
let input_svs =
List.map (fun ty -> mk_fresh_symbolic_value V.SynthInput ty) inst_sg.inputs
@@ -165,15 +271,9 @@ let evaluate_function_symbolic_synthesize_backward_from_return
* an instantiation of the signature, so that we use fresh
* region ids for the return abstractions. *)
let sg = fdef.signature in
- let type_params =
- List.map (fun (v : T.type_var) -> T.TypeVar v.T.index) sg.type_params
- in
- let cg_params =
- List.map
- (fun (v : T.const_generic_var) -> T.ConstGenericVar v.T.index)
- sg.const_generic_params
+ let _, ret_inst_sg =
+ symbolic_instantiate_fun_sig ctx fdef.signature fdef.kind
in
- let ret_inst_sg = instantiate_fun_sig type_params cg_params sg in
let ret_rty = ret_inst_sg.output in
(* Move the return value out of the return variable *)
let pop_return_value = is_regular_return in
@@ -347,19 +447,14 @@ let evaluate_function_symbolic_synthesize_backward_from_return
for the synthesis)
- the symbolic AST generated by the symbolic execution
*)
-let evaluate_function_symbolic (synthesize : bool)
- (type_context : C.type_context) (fun_context : C.fun_context)
- (global_context : C.global_context) (fdef : A.fun_decl) :
- V.symbolic_value list * SA.expression option =
+let evaluate_function_symbolic (synthesize : bool) (ctx : C.decls_ctx)
+ (fdef : A.fun_decl) : V.symbolic_value list * SA.expression option =
(* Debug *)
let name_to_string () = Print.fun_name_to_string fdef.A.name in
log#ldebug (lazy ("evaluate_function_symbolic: " ^ name_to_string ()));
(* Create the evaluation context *)
- let ctx, input_svs, inst_sg =
- initialize_symbolic_context_for_fun type_context fun_context global_context
- fdef
- in
+ let ctx, input_svs, inst_sg = initialize_symbolic_context_for_fun ctx fdef in
(* Create the continuation to finish the evaluation *)
let config = C.mk_config C.SymbolicMode in
@@ -488,7 +583,8 @@ module Test = struct
(** Test a unit function (taking no arguments) by evaluating it in an empty
environment.
*)
- let test_unit_function (crate : A.crate) (fid : A.FunDeclId.id) : unit =
+ let test_unit_function (crate : A.crate) (decls_ctx : C.decls_ctx)
+ (fid : A.FunDeclId.id) : unit =
(* Retrieve the function declaration *)
let fdef = A.FunDeclId.Map.find fid crate.functions in
let body = Option.get fdef.body in
@@ -498,17 +594,11 @@ module Test = struct
(lazy ("test_unit_function: " ^ Print.fun_name_to_string fdef.A.name));
(* Sanity check - *)
- assert (List.length fdef.A.signature.region_params = 0);
- assert (List.length fdef.A.signature.type_params = 0);
+ assert (fdef.A.signature.generics = TypesUtils.mk_empty_generic_params);
assert (body.A.arg_count = 0);
(* Create the evaluation context *)
- let type_context, fun_context, global_context =
- compute_type_fun_global_contexts crate
- in
- let ctx =
- initialize_eval_context type_context fun_context global_context [] [] []
- in
+ let ctx = initialize_eval_context decls_ctx [] [] [] in
(* Insert the (uninitialized) local variables *)
let ctx = C.ctx_push_uninitialized_vars ctx body.A.locals in
@@ -536,9 +626,7 @@ module Test = struct
(no parameters, no arguments) - TODO: move *)
let fun_decl_is_transparent_unit (def : A.fun_decl) : bool =
Option.is_some def.body
- && def.A.signature.region_params = []
- && def.A.signature.type_params = []
- && def.A.signature.const_generic_params = []
+ && def.A.signature.generics = TypesUtils.mk_empty_generic_params
&& def.A.signature.inputs = []
(** Test all the unit functions in a list of function definitions *)
@@ -548,24 +636,9 @@ module Test = struct
(fun _ -> fun_decl_is_transparent_unit)
crate.functions
in
+ let decls_ctx = compute_contexts crate in
let test_unit_fun _ (def : A.fun_decl) : unit =
- test_unit_function crate def.A.def_id
+ test_unit_function crate decls_ctx def.A.def_id
in
A.FunDeclId.Map.iter test_unit_fun unit_funs
-
- (** Execute the symbolic interpreter on a function. *)
- let test_function_symbolic (synthesize : bool) (type_context : C.type_context)
- (fun_context : C.fun_context) (global_context : C.global_context)
- (fdef : A.fun_decl) : unit =
- (* Debug *)
- log#ldebug
- (lazy ("test_function_symbolic: " ^ Print.fun_name_to_string fdef.A.name));
-
- (* Evaluate *)
- let _ =
- evaluate_function_symbolic synthesize type_context fun_context
- global_context fdef
- in
-
- ()
end
diff --git a/compiler/InterpreterBorrows.ml b/compiler/InterpreterBorrows.ml
index 4d67a4e4..e97795a1 100644
--- a/compiler/InterpreterBorrows.ml
+++ b/compiler/InterpreterBorrows.ml
@@ -452,7 +452,8 @@ let give_back_symbolic_value (_config : C.config)
| V.SynthInputGivenBack | SynthRetGivenBack | FunCallGivenBack | LoopGivenBack
->
()
- | FunCallRet | SynthInput | Global | LoopOutput | LoopJoin | Aggregate ->
+ | FunCallRet | SynthInput | Global | LoopOutput | LoopJoin | Aggregate
+ | ConstGeneric | TraitConst ->
raise (Failure "Unreachable"));
(* Store the given-back value as a meta-value for synthesis purposes *)
let mv = nsv in
diff --git a/compiler/InterpreterBorrowsCore.ml b/compiler/InterpreterBorrowsCore.ml
index bf083aa4..e7da045c 100644
--- a/compiler/InterpreterBorrowsCore.ml
+++ b/compiler/InterpreterBorrowsCore.ml
@@ -100,15 +100,18 @@ let rec compare_rtys (default : bool) (combine : bool -> bool -> bool)
(compare_regions : T.RegionId.id T.region -> T.RegionId.id T.region -> bool)
(ty1 : T.rty) (ty2 : T.rty) : bool =
let compare = compare_rtys default combine compare_regions in
+ (* Normalize the associated types *)
match (ty1, ty2) with
| T.Literal lit1, T.Literal lit2 ->
assert (lit1 = lit2);
default
- | T.Adt (id1, regions1, tys1, cgs1), T.Adt (id2, regions2, tys2, cgs2) ->
+ | T.Adt (id1, generics1), T.Adt (id2, generics2) ->
assert (id1 = id2);
(* There are no regions in the const generics, so we ignore them,
but we still check they are the same, for sanity *)
- assert (cgs1 = cgs2);
+ assert (generics1.const_generics = generics2.const_generics);
+
+ (* We also ignore the trait refs *)
(* The check for the ADTs is very crude: we simply compare the arguments
* two by two.
@@ -123,14 +126,14 @@ let rec compare_rtys (default : bool) (combine : bool -> bool -> bool)
* this check would still be a reasonable conservative approximation. *)
(* Check the region parameters *)
- let regions = List.combine regions1 regions2 in
+ let regions = List.combine generics1.regions generics2.regions in
let params_b =
List.fold_left
(fun b (r1, r2) -> combine b (compare_regions r1 r2))
default regions
in
(* Check the type parameters *)
- let tys = List.combine tys1 tys2 in
+ let tys = List.combine generics1.types generics2.types in
let tys_b =
List.fold_left
(fun b (ty1, ty2) -> combine b (compare ty1 ty2))
@@ -150,6 +153,11 @@ let rec compare_rtys (default : bool) (combine : bool -> bool -> bool)
| T.TypeVar id1, T.TypeVar id2 ->
assert (id1 = id2);
default
+ | T.TraitType _, T.TraitType _ ->
+ (* The types should have been normalized. If after normalization we
+ get trait types, we can consider them as variables *)
+ assert (ty1 = ty2);
+ default
| _ ->
log#lerror
(lazy
diff --git a/compiler/InterpreterExpansion.ml b/compiler/InterpreterExpansion.ml
index 81e73e3e..b267bb51 100644
--- a/compiler/InterpreterExpansion.ml
+++ b/compiler/InterpreterExpansion.ml
@@ -9,6 +9,7 @@ module V = Values
module E = Expressions
module C = Contexts
module Subst = Substitute
+module Assoc = AssociatedTypes
module L = Logging
open TypesUtils
module Inv = Invariants
@@ -204,7 +205,7 @@ let apply_symbolic_expansion_non_borrow (config : C.config)
apply_symbolic_expansion_to_avalues config allow_reborrows original_sv
expansion ctx
-(** Compute the expansion of a non-assumed (i.e.: not [Option], [Box], etc.)
+(** Compute the expansion of a non-assumed (i.e.: not [Box], etc.)
adt value.
The function might return a list of values if the symbolic value to expand
@@ -214,18 +215,15 @@ let apply_symbolic_expansion_non_borrow (config : C.config)
doesn't allow the expansion of enumerations *containing several variants*.
*)
let compute_expanded_symbolic_non_assumed_adt_value (expand_enumerations : bool)
- (kind : V.sv_kind) (def_id : T.TypeDeclId.id)
- (regions : T.RegionId.id T.region list) (types : T.rty list)
- (cgs : T.const_generic list) (ctx : C.eval_ctx) : V.symbolic_expansion list
- =
+ (kind : V.sv_kind) (def_id : T.TypeDeclId.id) (generics : T.rgeneric_args)
+ (ctx : C.eval_ctx) : V.symbolic_expansion list =
(* Lookup the definition and check if it is an enumeration with several
* variants *)
let def = C.ctx_lookup_type_decl ctx def_id in
- assert (List.length regions = List.length def.T.region_params);
+ assert (List.length generics.regions = List.length def.T.generics.regions);
(* Retrieve, for every variant, the list of its instantiated field types *)
let variants_fields_types =
- Subst.type_decl_get_instantiated_variants_fields_rtypes def regions types
- cgs
+ Assoc.type_decl_get_inst_norm_variants_fields_rtypes ctx def generics
in
(* Check if there is strictly more than one variant *)
if List.length variants_fields_types > 1 && not expand_enumerations then
@@ -243,17 +241,6 @@ let compute_expanded_symbolic_non_assumed_adt_value (expand_enumerations : bool)
(* Initialize all the expanded values of all the variants *)
List.map initialize variants_fields_types
-(** Compute the expansion of an Option value.
- *)
-let compute_expanded_symbolic_option_value (expand_enumerations : bool)
- (kind : V.sv_kind) (ty : T.rty) : V.symbolic_expansion list =
- assert expand_enumerations;
- let some_se =
- V.SeAdt (Some T.option_some_id, [ mk_fresh_symbolic_value kind ty ])
- in
- let none_se = V.SeAdt (Some T.option_none_id, []) in
- [ none_se; some_se ]
-
let compute_expanded_symbolic_tuple_value (kind : V.sv_kind)
(field_types : T.rty list) : V.symbolic_expansion =
(* Generate the field values *)
@@ -280,17 +267,14 @@ let compute_expanded_symbolic_box_value (kind : V.sv_kind) (boxed_ty : T.rty) :
doesn't allow the expansion of enumerations *containing several variants*.
*)
let compute_expanded_symbolic_adt_value (expand_enumerations : bool)
- (kind : V.sv_kind) (adt_id : T.type_id)
- (regions : T.RegionId.id T.region list) (types : T.rty list)
- (cgs : T.const_generic list) (ctx : C.eval_ctx) : V.symbolic_expansion list
- =
- match (adt_id, regions, types) with
+ (kind : V.sv_kind) (adt_id : T.type_id) (generics : T.rgeneric_args)
+ (ctx : C.eval_ctx) : V.symbolic_expansion list =
+ match (adt_id, generics.regions, generics.types) with
| T.AdtId def_id, _, _ ->
compute_expanded_symbolic_non_assumed_adt_value expand_enumerations kind
- def_id regions types cgs ctx
- | T.Tuple, [], _ -> [ compute_expanded_symbolic_tuple_value kind types ]
- | T.Assumed T.Option, [], [ ty ] ->
- compute_expanded_symbolic_option_value expand_enumerations kind ty
+ def_id generics ctx
+ | T.Tuple, [], _ ->
+ [ compute_expanded_symbolic_tuple_value kind generics.types ]
| T.Assumed T.Box, [], [ boxed_ty ] ->
[ compute_expanded_symbolic_box_value kind boxed_ty ]
| _ ->
@@ -543,12 +527,12 @@ let expand_symbolic_value_no_branching (config : C.config)
fun cf ctx ->
match rty with
(* ADTs *)
- | T.Adt (adt_id, regions, types, cgs) ->
+ | T.Adt (adt_id, generics) ->
(* Compute the expanded value *)
let allow_branching = false in
let seel =
compute_expanded_symbolic_adt_value allow_branching sv.sv_kind adt_id
- regions types cgs ctx
+ generics ctx
in
(* There should be exacly one branch *)
let see = Collections.List.to_cons_nil seel in
@@ -600,12 +584,12 @@ let expand_symbolic_adt (config : C.config) (sv : V.symbolic_value)
(* Execute *)
match rty with
(* ADTs *)
- | T.Adt (adt_id, regions, types, cgs) ->
+ | T.Adt (adt_id, generics) ->
let allow_branching = true in
(* Compute the expanded value *)
let seel =
compute_expanded_symbolic_adt_value allow_branching sv.sv_kind adt_id
- regions types cgs ctx
+ generics ctx
in
(* Apply *)
let seel = List.map (fun see -> (Some see, cf_branches)) seel in
@@ -679,7 +663,7 @@ let greedy_expand_symbolics_with_borrows (config : C.config) : cm_fun =
^ symbolic_value_to_string ctx sv));
let cc : cm_fun =
match sv.V.sv_ty with
- | T.Adt (AdtId def_id, _, _, _) ->
+ | T.Adt (AdtId def_id, _) ->
(* {!expand_symbolic_value_no_branching} checks if there are branchings,
* but we prefer to also check it here - this leads to cleaner messages
* and debugging *)
@@ -704,16 +688,17 @@ let greedy_expand_symbolics_with_borrows (config : C.config) : cm_fun =
[config]): "
^ Print.name_to_string def.name))
else expand_symbolic_value_no_branching config sv None
- | T.Adt ((Tuple | Assumed Box), _, _, _) | T.Ref (_, _, _) ->
+ | T.Adt ((Tuple | Assumed Box), _) | T.Ref (_, _, _) ->
(* Ok *)
expand_symbolic_value_no_branching config sv None
- | T.Adt (Assumed (Vec | Option | Array | Slice | Str | Range), _, _, _)
- ->
+ | T.Adt (Assumed (Array | Slice | Str), _) ->
(* We can't expand those *)
raise
(Failure
"Attempted to greedily expand an ADT which can't be expanded ")
- | T.TypeVar _ | T.Literal _ | Never -> raise (Failure "Unreachable")
+ | T.TypeVar _ | T.Literal _ | Never | T.TraitType _ | T.Arrow _
+ | T.RawPtr _ ->
+ raise (Failure "Unreachable")
in
(* Compose and continue *)
comp cc expand cf ctx
diff --git a/compiler/InterpreterExpressions.ml b/compiler/InterpreterExpressions.ml
index 8b2070c6..245f3b77 100644
--- a/compiler/InterpreterExpressions.ml
+++ b/compiler/InterpreterExpressions.ml
@@ -7,6 +7,7 @@ module E = Expressions
open Utils
module C = Contexts
module Subst = Substitute
+module Assoc = AssociatedTypes
module L = Logging
open TypesUtils
open ValuesUtils
@@ -141,11 +142,19 @@ let rec copy_value (allow_adt_copy : bool) (config : C.config)
| V.Adt av ->
(* Sanity check *)
(match v.V.ty with
- | T.Adt (T.Assumed (T.Box | Vec), _, _, _) ->
+ | T.Adt (T.Assumed T.Box, _) ->
raise (Failure "Can't copy an assumed value other than Option")
- | T.Adt (T.AdtId _, _, _, _) -> assert allow_adt_copy
- | T.Adt ((T.Assumed Option | T.Tuple), _, _, _) -> () (* Ok *)
- | T.Adt (T.Assumed (Slice | T.Array), [], [ ty ], []) ->
+ | T.Adt (T.AdtId _, _) as ty ->
+ assert (allow_adt_copy || ty_is_primitively_copyable ty)
+ | T.Adt (T.Tuple, _) -> () (* Ok *)
+ | T.Adt
+ ( T.Assumed (Slice | T.Array),
+ {
+ regions = [];
+ types = [ ty ];
+ const_generics = [];
+ trait_refs = [];
+ } ) ->
assert (ty_is_primitively_copyable ty)
| _ -> raise (Failure "Unreachable"));
let ctx, fields =
@@ -230,17 +239,16 @@ let prepare_eval_operand_reorganize (config : C.config) (op : E.operand) :
let prepare : cm_fun =
fun cf ctx ->
match op with
- | Expressions.Constant (ty, cv) ->
+ | E.Constant _ ->
(* No need to reorganize the context *)
- literal_to_typed_value (TypesUtils.ty_as_literal ty) cv |> ignore;
cf ctx
- | Expressions.Copy p ->
+ | E.Copy p ->
(* Access the value *)
let access = Read in
(* Expand the symbolic values, if necessary *)
let expand_prim_copy = true in
access_rplace_reorganize config expand_prim_copy access p cf ctx
- | Expressions.Move p ->
+ | E.Move p ->
(* Access the value *)
let access = Move in
let expand_prim_copy = false in
@@ -260,9 +268,71 @@ let eval_operand_no_reorganize (config : C.config) (op : E.operand)
^ "\n- ctx:\n" ^ eval_ctx_to_string ctx ^ "\n"));
(* Evaluate *)
match op with
- | Expressions.Constant (ty, cv) ->
- cf (literal_to_typed_value (TypesUtils.ty_as_literal ty) cv) ctx
- | Expressions.Copy p ->
+ | E.Constant cv -> (
+ match cv.value with
+ | E.CLiteral lit ->
+ cf (literal_to_typed_value (TypesUtils.ty_as_literal cv.ty) lit) ctx
+ | E.CTraitConst (trait_ref, generics, const_name) -> (
+ assert (generics = TypesUtils.mk_empty_generic_args);
+ match trait_ref.trait_id with
+ | T.TraitImpl _ ->
+ (* This shouldn't happen: if we refer to a concrete implementation, we
+ should directly refer to the top-level constant *)
+ raise (Failure "Unreachable")
+ | _ -> (
+ (* We refer to a constant defined in a local clause: simply
+ introduce a fresh symbolic value *)
+ let ctx0 = ctx in
+ (* Lookup the trait declaration to retrieve the type of the symbolic value *)
+ let trait_decl =
+ C.ctx_lookup_trait_decl ctx
+ trait_ref.trait_decl_ref.trait_decl_id
+ in
+ let _, (ty, _) =
+ List.find (fun (name, _) -> name = const_name) trait_decl.consts
+ in
+ (* Introduce a fresh symbolic value *)
+ let v = mk_fresh_symbolic_typed_value_from_ety V.TraitConst ty in
+ (* Continue the evaluation *)
+ let e = cf v ctx in
+ (* We have to wrap the generated expression *)
+ match e with
+ | None -> None
+ | Some e ->
+ Some
+ (SymbolicAst.IntroSymbolic
+ ( ctx0,
+ None,
+ value_as_symbolic v.value,
+ SymbolicAst.TraitConstValue
+ (trait_ref, generics, const_name),
+ e ))))
+ | E.CVar vid -> (
+ let ctx0 = ctx in
+ (* Lookup the const generic value *)
+ let cv = C.ctx_lookup_const_generic_value ctx vid in
+ (* Copy the value *)
+ let allow_adt_copy = false in
+ let ctx, v = copy_value allow_adt_copy config ctx cv in
+ (* Continue *)
+ let e = cf v ctx in
+ (* We have to wrap the generated expression *)
+ match e with
+ | None -> None
+ | Some e ->
+ (* If we are synthesizing a symbolic AST, it means that we are in symbolic
+ mode: the value of the const generic is necessarily symbolic. *)
+ assert (is_symbolic cv.V.value);
+ (* *)
+ Some
+ (SymbolicAst.IntroSymbolic
+ ( ctx0,
+ None,
+ value_as_symbolic v.value,
+ SymbolicAst.ConstGenericValue vid,
+ e )))
+ | E.CFnPtr _ -> raise (Failure "TODO"))
+ | E.Copy p ->
(* Access the value *)
let access = Read in
let cc = read_place access p in
@@ -283,7 +353,7 @@ let eval_operand_no_reorganize (config : C.config) (op : E.operand)
in
(* Compose and apply *)
comp cc copy cf ctx
- | Expressions.Move p ->
+ | E.Move p ->
(* Access the value *)
let access = Move in
let cc = read_place access p in
@@ -358,7 +428,7 @@ let eval_unary_op_concrete (config : C.config) (unop : E.unop) (op : E.operand)
match mk_scalar sv.int_ty i with
| Error _ -> cf (Error EPanic)
| Ok sv -> cf (Ok { v with V.value = V.Literal (PV.Scalar sv) }))
- | E.Cast (src_ty, tgt_ty), V.Literal (PV.Scalar sv) -> (
+ | E.Cast (E.CastInteger (src_ty, tgt_ty)), V.Literal (PV.Scalar sv) -> (
assert (src_ty = sv.int_ty);
let i = sv.PV.value in
match mk_scalar tgt_ty i with
@@ -384,7 +454,7 @@ let eval_unary_op_symbolic (config : C.config) (unop : E.unop) (op : E.operand)
match (unop, v.V.ty) with
| E.Not, (T.Literal Bool as lty) -> lty
| E.Neg, (T.Literal (Integer _) as lty) -> lty
- | E.Cast (_, tgt_ty), _ -> T.Literal (Integer tgt_ty)
+ | E.Cast (E.CastInteger (_, tgt_ty)), _ -> T.Literal (Integer tgt_ty)
| _ -> raise (Failure "Invalid input for unop")
in
let res_sv =
@@ -653,73 +723,46 @@ let eval_rvalue_aggregate (config : C.config)
fun ctx ->
(* Match on the aggregate kind *)
match aggregate_kind with
- | E.AggregatedTuple ->
- let tys = List.map (fun (v : V.typed_value) -> v.V.ty) values in
- let v = V.Adt { variant_id = None; field_values = values } in
- let ty = T.Adt (T.Tuple, [], tys, []) in
- let aggregated : V.typed_value = { V.value = v; ty } in
- (* Call the continuation *)
- cf aggregated ctx
- | E.AggregatedOption (variant_id, ty) ->
- (* Sanity check *)
- if variant_id = T.option_none_id then assert (values = [])
- else if variant_id = T.option_some_id then
- assert (List.length values = 1)
- else raise (Failure "Unreachable");
- (* Construt the value *)
- let aty = T.Adt (T.Assumed T.Option, [], [ ty ], []) in
- let av : V.adt_value =
- { V.variant_id = Some variant_id; V.field_values = values }
- in
- let aggregated : V.typed_value = { V.value = Adt av; ty = aty } in
- (* Call the continuation *)
- cf aggregated ctx
- | E.AggregatedAdt (def_id, opt_variant_id, regions, types, cgs) ->
- (* Sanity checks *)
- let type_decl = C.ctx_lookup_type_decl ctx def_id in
- assert (List.length type_decl.region_params = List.length regions);
- let expected_field_types =
- Subst.ctx_adt_get_instantiated_field_etypes ctx def_id opt_variant_id
- types cgs
- in
- assert (
- expected_field_types
- = List.map (fun (v : V.typed_value) -> v.V.ty) values);
- (* Construct the value *)
- let av : V.adt_value =
- { V.variant_id = opt_variant_id; V.field_values = values }
- in
- let aty = T.Adt (T.AdtId def_id, regions, types, cgs) in
- let aggregated : V.typed_value = { V.value = Adt av; ty = aty } in
- (* Call the continuation *)
- cf aggregated ctx
- | E.AggregatedRange ety ->
- (* There should be two fields exactly *)
- let v0, v1 =
- match values with
- | [ v0; v1 ] -> (v0, v1)
- | _ -> raise (Failure "Unreachable")
- in
- (* Ranges are parametric over the type of indices. For now we only
- support scalars, which can be of any type *)
- assert (literal_type_is_integer (ty_as_literal ety));
- assert (v0.ty = ety);
- assert (v1.ty = ety);
- (* Construct the value *)
- let av : V.adt_value =
- { V.variant_id = None; V.field_values = values }
- in
- let aty = T.Adt (T.Assumed T.Range, [], [ ety ], []) in
- let aggregated : V.typed_value = { V.value = Adt av; ty = aty } in
- (* Call the continuation *)
- cf aggregated ctx
+ | E.AggregatedAdt (type_id, opt_variant_id, generics) -> (
+ match type_id with
+ | Tuple ->
+ let tys = List.map (fun (v : V.typed_value) -> v.V.ty) values in
+ let v = V.Adt { variant_id = None; field_values = values } in
+ let generics = TypesUtils.mk_generic_args [] tys [] [] in
+ let ty = T.Adt (T.Tuple, generics) in
+ let aggregated : V.typed_value = { V.value = v; ty } in
+ (* Call the continuation *)
+ cf aggregated ctx
+ | AdtId def_id ->
+ (* Sanity checks *)
+ let type_decl = C.ctx_lookup_type_decl ctx def_id in
+ assert (
+ List.length type_decl.generics.regions
+ = List.length generics.regions);
+ let expected_field_types =
+ Assoc.ctx_adt_get_inst_norm_field_etypes ctx def_id opt_variant_id
+ generics
+ in
+ assert (
+ expected_field_types
+ = List.map (fun (v : V.typed_value) -> v.V.ty) values);
+ (* Construct the value *)
+ let av : V.adt_value =
+ { V.variant_id = opt_variant_id; V.field_values = values }
+ in
+ let aty = T.Adt (T.AdtId def_id, generics) in
+ let aggregated : V.typed_value = { V.value = Adt av; ty = aty } in
+ (* Call the continuation *)
+ cf aggregated ctx
+ | Assumed _ -> raise (Failure "Unreachable"))
| E.AggregatedArray (ety, cg) -> (
(* Sanity check: all the values have the proper type *)
assert (List.for_all (fun (v : V.typed_value) -> v.V.ty = ety) values);
(* Sanity check: the number of values is consistent with the length *)
let len = (literal_as_scalar (const_generic_as_literal cg)).value in
assert (len = Z.of_int (List.length values));
- let ty = T.Adt (T.Assumed T.Array, [], [ ety ], [ cg ]) in
+ let generics = TypesUtils.mk_generic_args [] [ ety ] [ cg ] [] in
+ let ty = T.Adt (T.Assumed T.Array, generics) in
(* In order to generate a better AST, we introduce a symbolic
value equal to the array. The reason is that otherwise, the
array we introduce here might be duplicated in the generated
@@ -752,7 +795,7 @@ let eval_rvalue_not_global (config : C.config) (rvalue : E.rvalue)
(* Delegate to the proper auxiliary function *)
match rvalue with
| E.Use op -> comp_wrap (eval_operand config op) ctx
- | E.Ref (p, bkind) -> comp_wrap (eval_rvalue_ref config p bkind) ctx
+ | E.RvRef (p, bkind) -> comp_wrap (eval_rvalue_ref config p bkind) ctx
| E.UnaryOp (unop, op) -> eval_unary_op config unop op cf ctx
| E.BinaryOp (binop, op1, op2) -> eval_binary_op config binop op1 op2 cf ctx
| E.Aggregate (aggregate_kind, ops) ->
diff --git a/compiler/InterpreterLoopsJoinCtxs.ml b/compiler/InterpreterLoopsJoinCtxs.ml
index bf88e055..6d3ecb18 100644
--- a/compiler/InterpreterLoopsJoinCtxs.ml
+++ b/compiler/InterpreterLoopsJoinCtxs.ml
@@ -554,9 +554,15 @@ let join_ctxs (loop_id : V.LoopId.id) (fixed_ids : ids_sets) (ctx0 : C.eval_ctx)
C.type_context;
fun_context;
global_context;
+ trait_decls_context;
+ trait_impls_context;
region_groups;
type_vars;
const_generic_vars;
+ const_generic_vars_map;
+ norm_trait_etypes;
+ norm_trait_rtypes;
+ norm_trait_stypes;
env = _;
ended_regions = ended_regions0;
} =
@@ -566,9 +572,15 @@ let join_ctxs (loop_id : V.LoopId.id) (fixed_ids : ids_sets) (ctx0 : C.eval_ctx)
C.type_context = _;
fun_context = _;
global_context = _;
+ trait_decls_context = _;
+ trait_impls_context = _;
region_groups = _;
type_vars = _;
const_generic_vars = _;
+ const_generic_vars_map = _;
+ norm_trait_etypes = _;
+ norm_trait_rtypes = _;
+ norm_trait_stypes = _;
env = _;
ended_regions = ended_regions1;
} =
@@ -580,9 +592,15 @@ let join_ctxs (loop_id : V.LoopId.id) (fixed_ids : ids_sets) (ctx0 : C.eval_ctx)
C.type_context;
fun_context;
global_context;
+ trait_decls_context;
+ trait_impls_context;
region_groups;
type_vars;
const_generic_vars;
+ const_generic_vars_map;
+ norm_trait_etypes;
+ norm_trait_rtypes;
+ norm_trait_stypes;
env;
ended_regions;
}
diff --git a/compiler/InterpreterLoopsMatchCtxs.ml b/compiler/InterpreterLoopsMatchCtxs.ml
index 9248e513..8cab546e 100644
--- a/compiler/InterpreterLoopsMatchCtxs.ml
+++ b/compiler/InterpreterLoopsMatchCtxs.ml
@@ -149,20 +149,25 @@ let rec match_types (match_distinct_types : 'r T.ty -> 'r T.ty -> 'r T.ty)
(match_regions : 'r -> 'r -> 'r) (ty0 : 'r T.ty) (ty1 : 'r T.ty) : 'r T.ty =
let match_rec = match_types match_distinct_types match_regions in
match (ty0, ty1) with
- | Adt (id0, regions0, tys0, cgs0), Adt (id1, regions1, tys1, cgs1) ->
+ | Adt (id0, generics0), Adt (id1, generics1) ->
assert (id0 = id1);
- assert (cgs0 = cgs1);
+ assert (generics0.const_generics = generics1.const_generics);
+ assert (generics0.trait_refs = generics1.trait_refs);
let id = id0 in
- let cgs = cgs1 in
+ let const_generics = generics1.const_generics in
+ let trait_refs = generics1.trait_refs in
let regions =
List.map
(fun (id0, id1) -> match_regions id0 id1)
- (List.combine regions0 regions1)
+ (List.combine generics0.regions generics1.regions)
in
- let tys =
- List.map (fun (ty0, ty1) -> match_rec ty0 ty1) (List.combine tys0 tys1)
+ let types =
+ List.map
+ (fun (ty0, ty1) -> match_rec ty0 ty1)
+ (List.combine generics0.types generics1.types)
in
- Adt (id, regions, tys, cgs)
+ let generics = { T.regions; types; const_generics; trait_refs } in
+ Adt (id, generics)
| TypeVar vid0, TypeVar vid1 ->
assert (vid0 = vid1);
let vid = vid0 in
diff --git a/compiler/InterpreterPaths.ml b/compiler/InterpreterPaths.ml
index 04dc8892..2a277c91 100644
--- a/compiler/InterpreterPaths.ml
+++ b/compiler/InterpreterPaths.ml
@@ -3,6 +3,7 @@ module V = Values
module E = Expressions
module C = Contexts
module Subst = Substitute
+module Assoc = AssociatedTypes
module L = Logging
open Cps
open ValuesUtils
@@ -95,16 +96,14 @@ let rec access_projection (access : projection_access) (ctx : C.eval_ctx)
| pe :: p' -> (
(* Match on the projection element and the value *)
match (pe, v.V.value, v.V.ty) with
- | ( Field (((ProjAdt (_, _) | ProjOption _) as proj_kind), field_id),
+ | ( Field ((ProjAdt (_, _) as proj_kind), field_id),
V.Adt adt,
- T.Adt (type_id, _, _, _) ) -> (
+ T.Adt (type_id, _) ) -> (
(* Check consistency *)
(match (proj_kind, type_id) with
| ProjAdt (def_id, opt_variant_id), T.AdtId def_id' ->
assert (def_id = def_id');
assert (opt_variant_id = adt.variant_id)
- | ProjOption variant_id, T.Assumed T.Option ->
- assert (Some variant_id = adt.variant_id)
| _ -> raise (Failure "Unreachable"));
(* Actually project *)
let fv = T.FieldId.nth adt.field_values field_id in
@@ -119,8 +118,7 @@ let rec access_projection (access : projection_access) (ctx : C.eval_ctx)
let updated = { v with value = nadt } in
Ok (ctx, { res with updated }))
(* Tuples *)
- | Field (ProjTuple arity, field_id), V.Adt adt, T.Adt (T.Tuple, _, _, _)
- -> (
+ | Field (ProjTuple arity, field_id), V.Adt adt, T.Adt (T.Tuple, _) -> (
assert (arity = List.length adt.field_values);
let fv = T.FieldId.nth adt.field_values field_id in
(* Project *)
@@ -136,7 +134,7 @@ let rec access_projection (access : projection_access) (ctx : C.eval_ctx)
Ok (ctx, { res with updated })
(* If we reach Bottom, it may mean we need to expand an uninitialized
* enumeration value *))
- | Field ((ProjAdt (_, _) | ProjTuple _ | ProjOption _), _), V.Bottom, _ ->
+ | Field ((ProjAdt (_, _) | ProjTuple _), _), V.Bottom, _ ->
Error (FailBottom (1 + List.length p', pe, v.ty))
(* Symbolic value: needs to be expanded *)
| _, Symbolic sp, _ ->
@@ -145,9 +143,9 @@ let rec access_projection (access : projection_access) (ctx : C.eval_ctx)
(* Box dereferencement *)
| ( DerefBox,
Adt { variant_id = None; field_values = [ bv ] },
- T.Adt (T.Assumed T.Box, _, _, _) ) -> (
- (* We allow moving inside of boxes. In practice, this kind of
- * manipulations should happen only inside unsage code, so
+ T.Adt (T.Assumed T.Box, _) ) -> (
+ (* We allow moving outside of boxes. In practice, this kind of
+ * manipulations should happen only inside unsafe code, so
* it shouldn't happen due to user code, and we leverage it
* when implementing box dereferencement for the concrete
* interpreter *)
@@ -357,45 +355,32 @@ let write_place (access : access_kind) (p : E.place) (nv : V.typed_value)
| Error e -> raise (Failure ("Unreachable: " ^ show_path_fail_kind e))
| Ok ctx -> ctx
-let compute_expanded_bottom_adt_value (tyctx : T.type_decl T.TypeDeclId.Map.t)
+let compute_expanded_bottom_adt_value (ctx : C.eval_ctx)
(def_id : T.TypeDeclId.id) (opt_variant_id : T.VariantId.id option)
- (regions : T.erased_region list) (types : T.ety list)
- (cgs : T.const_generic list) : V.typed_value =
+ (generics : T.egeneric_args) : V.typed_value =
(* Lookup the definition and check if it is an enumeration - it
should be an enumeration if and only if the projection element
is a field projection with *some* variant id. Retrieve the list
of fields at the same time. *)
- let def = T.TypeDeclId.Map.find def_id tyctx in
- assert (List.length regions = List.length def.T.region_params);
+ let def = C.ctx_lookup_type_decl ctx def_id in
+ assert (List.length generics.regions = List.length def.T.generics.regions);
(* Compute the field types *)
let field_types =
- Subst.type_decl_get_instantiated_field_etypes def opt_variant_id types cgs
+ Assoc.type_decl_get_inst_norm_field_etypes ctx def opt_variant_id generics
in
(* Initialize the expanded value *)
let fields = List.map mk_bottom field_types in
let av = V.Adt { variant_id = opt_variant_id; field_values = fields } in
- let ty = T.Adt (T.AdtId def_id, regions, types, cgs) in
+ let ty = T.Adt (T.AdtId def_id, generics) in
{ V.value = av; V.ty }
-let compute_expanded_bottom_option_value (variant_id : T.VariantId.id)
- (param_ty : T.ety) : V.typed_value =
- (* Note that the variant can be [Some] or [None]: we expand bottom values
- * when writing to fields or setting discriminants *)
- let field_values =
- if variant_id = T.option_some_id then [ mk_bottom param_ty ]
- else if variant_id = T.option_none_id then []
- else raise (Failure "Unreachable")
- in
- let av = V.Adt { variant_id = Some variant_id; field_values } in
- let ty = T.Adt (T.Assumed T.Option, [], [ param_ty ], []) in
- { V.value = av; ty }
-
let compute_expanded_bottom_tuple_value (field_types : T.ety list) :
V.typed_value =
(* Generate the field values *)
let fields = List.map mk_bottom field_types in
let v = V.Adt { variant_id = None; field_values = fields } in
- let ty = T.Adt (T.Tuple, [], field_types, []) in
+ let generics = TypesUtils.mk_generic_args [] field_types [] [] in
+ let ty = T.Adt (T.Tuple, generics) in
{ V.value = v; V.ty }
(** Auxiliary helper to expand {!V.Bottom} values.
@@ -447,19 +432,18 @@ let expand_bottom_value_from_projection (access : access_kind) (p : E.place)
match (pe, ty) with
(* "Regular" ADTs *)
| ( Field (ProjAdt (def_id, opt_variant_id), _),
- T.Adt (T.AdtId def_id', regions, types, cgs) ) ->
+ T.Adt (T.AdtId def_id', generics) ) ->
assert (def_id = def_id');
- compute_expanded_bottom_adt_value ctx.type_context.type_decls def_id
- opt_variant_id regions types cgs
- (* Option *)
- | ( Field (ProjOption variant_id, _),
- T.Adt (T.Assumed T.Option, [], [ ty ], []) ) ->
- compute_expanded_bottom_option_value variant_id ty
+ compute_expanded_bottom_adt_value ctx def_id opt_variant_id generics
(* Tuples *)
- | Field (ProjTuple arity, _), T.Adt (T.Tuple, [], tys, []) ->
- assert (arity = List.length tys);
+ | ( Field (ProjTuple arity, _),
+ T.Adt
+ ( T.Tuple,
+ { T.regions = []; types; const_generics = []; trait_refs = [] } ) )
+ ->
+ assert (arity = List.length types);
(* Generate the field values *)
- compute_expanded_bottom_tuple_value tys
+ compute_expanded_bottom_tuple_value types
| _ ->
raise
(Failure
diff --git a/compiler/InterpreterPaths.mli b/compiler/InterpreterPaths.mli
index 4a9f3b41..0ff8063f 100644
--- a/compiler/InterpreterPaths.mli
+++ b/compiler/InterpreterPaths.mli
@@ -3,6 +3,7 @@ module V = Values
module E = Expressions
module C = Contexts
module Subst = Substitute
+module Assoc = AssociatedTypes
module L = Logging
open Cps
open InterpreterExpansion
@@ -56,18 +57,12 @@ val compute_expanded_bottom_tuple_value : T.ety list -> V.typed_value
(** Compute an expanded ADT ⊥ value *)
val compute_expanded_bottom_adt_value :
- T.type_decl T.TypeDeclId.Map.t ->
+ C.eval_ctx ->
T.TypeDeclId.id ->
T.VariantId.id option ->
- T.erased_region list ->
- T.ety list ->
- T.const_generic list ->
+ T.egeneric_args ->
V.typed_value
-(** Compute an expanded [Option] ⊥ value *)
-val compute_expanded_bottom_option_value :
- T.VariantId.id -> T.ety -> V.typed_value
-
(** Drop (end) outer loans at a given place, which should be seen as an l-value
(we will write to it later, but need to drop the loans before writing).
diff --git a/compiler/InterpreterProjectors.ml b/compiler/InterpreterProjectors.ml
index faed066b..9e0c2b75 100644
--- a/compiler/InterpreterProjectors.ml
+++ b/compiler/InterpreterProjectors.ml
@@ -3,6 +3,7 @@ module V = Values
module E = Expressions
module C = Contexts
module Subst = Substitute
+module Assoc = AssociatedTypes
module L = Logging
open TypesUtils
open InterpreterUtils
@@ -24,12 +25,12 @@ let rec apply_proj_borrows_on_shared_borrow (ctx : C.eval_ctx)
else
match (v.V.value, ty) with
| V.Literal _, T.Literal _ -> []
- | V.Adt adt, T.Adt (id, region_params, tys, cgs) ->
+ | V.Adt adt, T.Adt (id, generics) ->
(* Retrieve the types of the fields *)
let field_types =
- Subst.ctx_adt_value_get_instantiated_field_rtypes ctx adt id
- region_params tys cgs
+ Assoc.ctx_adt_value_get_inst_norm_field_rtypes ctx adt id generics
in
+
(* Project over the field values *)
let fields_types = List.combine adt.V.field_values field_types in
let proj_fields =
@@ -103,11 +104,10 @@ let rec apply_proj_borrows (check_symbolic_no_ended : bool) (ctx : C.eval_ctx)
let value : V.avalue =
match (v.V.value, ty) with
| V.Literal _, T.Literal _ -> V.AIgnored
- | V.Adt adt, T.Adt (id, region_params, tys, cgs) ->
+ | V.Adt adt, T.Adt (id, generics) ->
(* Retrieve the types of the fields *)
let field_types =
- Subst.ctx_adt_value_get_instantiated_field_rtypes ctx adt id
- region_params tys cgs
+ Assoc.ctx_adt_value_get_inst_norm_field_rtypes ctx adt id generics
in
(* Project over the field values *)
let fields_types = List.combine adt.V.field_values field_types in
@@ -268,8 +268,7 @@ let apply_proj_loans_on_symbolic_expansion (regions : T.RegionId.Set.t)
let (value, ty) : V.avalue * T.rty =
match (see, original_sv_ty) with
| SeLiteral _, T.Literal _ -> (V.AIgnored, original_sv_ty)
- | SeAdt (variant_id, field_values), T.Adt (_id, _region_params, _tys, _cgs)
- ->
+ | SeAdt (variant_id, field_values), T.Adt (_id, _generics) ->
(* Project over the field values *)
let field_values =
List.map
diff --git a/compiler/InterpreterStatements.ml b/compiler/InterpreterStatements.ml
index 045c4484..e0c4703b 100644
--- a/compiler/InterpreterStatements.ml
+++ b/compiler/InterpreterStatements.ml
@@ -10,13 +10,13 @@ open TypesUtils
open ValuesUtils
module Inv = Invariants
module S = SynthesizeSymbolic
-open Utils
open Cps
open InterpreterUtils
open InterpreterProjectors
open InterpreterExpansion
open InterpreterPaths
open InterpreterExpressions
+module PCtx = Print.EvalCtxLlbcAst
(** The local logger *)
let log = L.statements_log
@@ -232,9 +232,7 @@ let set_discriminant (config : C.config) (p : E.place)
let update_value cf (v : V.typed_value) : m_fun =
fun ctx ->
match (v.V.ty, v.V.value) with
- | ( T.Adt
- (((T.AdtId _ | T.Assumed T.Option) as type_id), regions, types, cgs),
- V.Adt av ) -> (
+ | T.Adt ((T.AdtId _ as type_id), generics), V.Adt av -> (
(* There are two situations:
- either the discriminant is already the proper one (in which case we
don't do anything)
@@ -251,28 +249,17 @@ let set_discriminant (config : C.config) (p : E.place)
let bottom_v =
match type_id with
| T.AdtId def_id ->
- compute_expanded_bottom_adt_value
- ctx.type_context.type_decls def_id (Some variant_id)
- regions types cgs
- | T.Assumed T.Option ->
- assert (regions = []);
- compute_expanded_bottom_option_value variant_id
- (Collections.List.to_cons_nil types)
+ compute_expanded_bottom_adt_value ctx def_id
+ (Some variant_id) generics
| _ -> raise (Failure "Unreachable")
in
assign_to_place config bottom_v p (cf Unit) ctx)
- | ( T.Adt
- (((T.AdtId _ | T.Assumed T.Option) as type_id), regions, types, cgs),
- V.Bottom ) ->
+ | T.Adt ((T.AdtId _ as type_id), generics), V.Bottom ->
let bottom_v =
match type_id with
| T.AdtId def_id ->
- compute_expanded_bottom_adt_value ctx.type_context.type_decls
- def_id (Some variant_id) regions types cgs
- | T.Assumed T.Option ->
- assert (regions = []);
- compute_expanded_bottom_option_value variant_id
- (Collections.List.to_cons_nil types)
+ compute_expanded_bottom_adt_value ctx def_id (Some variant_id)
+ generics
| _ -> raise (Failure "Unreachable")
in
assign_to_place config bottom_v p (cf Unit) ctx
@@ -301,24 +288,34 @@ let ctx_push_frame (ctx : C.eval_ctx) : C.eval_ctx =
let push_frame : cm_fun = fun cf ctx -> cf (ctx_push_frame ctx)
(** Small helper: compute the type of the return value for a specific
- instantiation of a non-local function.
+ instantiation of an assumed function.
*)
-let get_non_local_function_return_type (fid : A.assumed_fun_id)
- (region_params : T.erased_region list) (type_params : T.ety list)
- (const_generic_params : T.const_generic list) : T.ety =
+let get_assumed_function_return_type (ctx : C.eval_ctx) (fid : A.assumed_fun_id)
+ (generics : T.egeneric_args) : T.ety =
+ assert (generics.trait_refs = []);
(* [Box::free] has a special treatment *)
- match (fid, region_params, type_params, const_generic_params) with
- | A.BoxFree, [], [ _ ], [] -> mk_unit_ty
+ match fid with
+ | BoxFree ->
+ assert (generics.regions = []);
+ assert (List.length generics.types = 1);
+ assert (generics.const_generics = []);
+ mk_unit_ty
| _ ->
(* Retrieve the function's signature *)
- let sg = Assumed.get_assumed_sig fid in
+ let sg = Assumed.get_assumed_fun_sig fid in
(* Instantiate the return type *)
- let tsubst = Subst.make_type_subst_from_vars sg.type_params type_params in
- let cgsubst =
- Subst.make_const_generic_subst_from_vars sg.const_generic_params
- const_generic_params
+ (* There shouldn't be any reference to Self *)
+ let tr_self : T.erased_region T.trait_instance_id =
+ T.UnknownTrait __FUNCTION__
+ in
+ let { Subst.r_subst = _; ty_subst; cg_subst; tr_subst; tr_self } =
+ Subst.make_esubst_from_generics sg.generics generics tr_self
+ in
+ let ty =
+ Subst.erase_regions_substitute_types ty_subst cg_subst tr_subst tr_self
+ sg.output
in
- Subst.erase_regions_substitute_types tsubst cgsubst sg.output
+ Assoc.ctx_normalize_ety ctx ty
let move_return_value (config : C.config) (pop_return_value : bool)
(cf : V.typed_value option -> m_fun) : m_fun =
@@ -418,19 +415,14 @@ let pop_frame_assign (config : C.config) (dest : E.place) : cm_fun =
in
comp cf_pop cf_assign
-(** Auxiliary function - see {!eval_non_local_function_call} *)
-let eval_replace_concrete (_config : C.config)
- (_region_params : T.erased_region list) (_type_params : T.ety list)
- (_cg_params : T.const_generic list) : cm_fun =
- fun _cf _ctx -> raise Unimplemented
-
-(** Auxiliary function - see {!eval_non_local_function_call} *)
-let eval_box_new_concrete (config : C.config)
- (region_params : T.erased_region list) (type_params : T.ety list)
- (cg_params : T.const_generic list) : cm_fun =
+(** Auxiliary function - see {!eval_assumed_function_call} *)
+let eval_box_new_concrete (config : C.config) (generics : T.egeneric_args) :
+ cm_fun =
fun cf ctx ->
(* Check and retrieve the arguments *)
- match (region_params, type_params, cg_params, ctx.env) with
+ match
+ (generics.regions, generics.types, generics.const_generics, ctx.env)
+ with
| ( [],
[ boxed_ty ],
[],
@@ -448,7 +440,8 @@ let eval_box_new_concrete (config : C.config)
(* Create the new box *)
let cf_create cf (moved_input_value : V.typed_value) : m_fun =
(* Create the box value *)
- let box_ty = T.Adt (T.Assumed T.Box, [], [ boxed_ty ], []) in
+ let generics = TypesUtils.mk_generic_args_from_types [ boxed_ty ] in
+ let box_ty = T.Adt (T.Assumed T.Box, generics) in
let box_v =
V.Adt { variant_id = None; field_values = [ moved_input_value ] }
in
@@ -466,71 +459,7 @@ let eval_box_new_concrete (config : C.config)
comp cf_move cf_create cf ctx
| _ -> raise (Failure "Inconsistent state")
-(** Auxiliary function which factorizes code to evaluate [std::Deref::deref]
- and [std::DerefMut::deref_mut] - see {!eval_non_local_function_call} *)
-let eval_box_deref_mut_or_shared_concrete (config : C.config)
- (region_params : T.erased_region list) (type_params : T.ety list)
- (cg_params : T.const_generic list) (is_mut : bool) : cm_fun =
- fun cf ctx ->
- (* Check the arguments *)
- match (region_params, type_params, cg_params, ctx.env) with
- | ( [],
- [ boxed_ty ],
- [],
- Var (VarBinder input_var, input_value)
- :: Var (_ret_var, _)
- :: C.Frame :: _ ) ->
- (* Required type checking. We must have:
- - input_value.ty = & (mut) Box<ty>
- - boxed_ty = ty
- for some ty
- *)
- (let _, input_ty, ref_kind = ty_get_ref input_value.V.ty in
- assert (match ref_kind with T.Shared -> not is_mut | T.Mut -> is_mut);
- let input_ty = ty_get_box input_ty in
- assert (input_ty = boxed_ty));
-
- (* Borrow the boxed value *)
- let p =
- { E.var_id = input_var.C.index; projection = [ E.Deref; E.DerefBox ] }
- in
- let borrow_kind = if is_mut then E.Mut else E.Shared in
- let rv = E.Ref (p, borrow_kind) in
- let cf_borrow = eval_rvalue_not_global config rv in
-
- (* Move the borrow to its destination *)
- let cf_move cf res : m_fun =
- match res with
- | Error EPanic ->
- (* We can't get there by borrowing a value *)
- raise (Failure "Unreachable")
- | Ok borrowed_value ->
- (* Move and continue *)
- let destp = mk_place_from_var_id E.VarId.zero in
- assign_to_place config borrowed_value destp cf
- in
-
- (* Compose and apply *)
- comp cf_borrow cf_move cf ctx
- | _ -> raise (Failure "Inconsistent state")
-
-(** Auxiliary function - see {!eval_non_local_function_call} *)
-let eval_box_deref_concrete (config : C.config)
- (region_params : T.erased_region list) (type_params : T.ety list)
- (cg_params : T.const_generic list) : cm_fun =
- let is_mut = false in
- eval_box_deref_mut_or_shared_concrete config region_params type_params
- cg_params is_mut
-
-(** Auxiliary function - see {!eval_non_local_function_call} *)
-let eval_box_deref_mut_concrete (config : C.config)
- (region_params : T.erased_region list) (type_params : T.ety list)
- (cg_params : T.const_generic list) : cm_fun =
- let is_mut = true in
- eval_box_deref_mut_or_shared_concrete config region_params type_params
- cg_params is_mut
-
-(** Auxiliary function - see {!eval_non_local_function_call}.
+(** Auxiliary function - see {!eval_assumed_function_call}.
[Box::free] is not handled the same way as the other assumed functions:
- in the regular case, whenever we need to evaluate an assumed function,
@@ -549,11 +478,10 @@ let eval_box_deref_mut_concrete (config : C.config)
It thus updates the box value (by calling {!drop_value}) and updates
the destination (by setting it to [()]).
*)
-let eval_box_free (config : C.config) (region_params : T.erased_region list)
- (type_params : T.ety list) (cg_params : T.const_generic list)
+let eval_box_free (config : C.config) (generics : T.egeneric_args)
(args : E.operand list) (dest : E.place) : cm_fun =
fun cf ctx ->
- match (region_params, type_params, cg_params, args) with
+ match (generics.regions, generics.types, generics.const_generics, args) with
| [], [ boxed_ty ], [], [ E.Move input_box_place ] ->
(* Required type checking *)
let input_box = InterpreterPaths.read_place Write input_box_place ctx in
@@ -570,26 +498,24 @@ let eval_box_free (config : C.config) (region_params : T.erased_region list)
cc cf ctx
| _ -> raise (Failure "Inconsistent state")
-(** Auxiliary function - see {!eval_non_local_function_call} *)
-let eval_vec_function_concrete (_config : C.config) (_fid : A.assumed_fun_id)
- (_region_params : T.erased_region list) (_type_params : T.ety list)
- (_cg_params : T.const_generic list) : cm_fun =
- fun _cf _ctx -> raise Unimplemented
-
(** Evaluate a non-local function call in concrete mode *)
-let eval_non_local_function_call_concrete (config : C.config)
- (fid : A.assumed_fun_id) (region_params : T.erased_region list)
- (type_params : T.ety list) (cg_params : T.const_generic list)
- (args : E.operand list) (dest : E.place) : cm_fun =
+let eval_assumed_function_call_concrete (config : C.config)
+ (fid : A.assumed_fun_id) (call : A.call) : cm_fun =
+ let generics = call.func.generics in
+ let args = call.args in
+ let dest = call.dest in
+ (* Sanity check: we don't fully handle the const generic vars environment
+ in concrete mode yet *)
+ assert (generics.const_generics = []);
(* There are two cases (and this is extremely annoying):
- the function is not box_free
- the function is box_free
See {!eval_box_free}
*)
match fid with
- | A.BoxFree ->
+ | BoxFree ->
(* Degenerate case: box_free *)
- eval_box_free config region_params type_params cg_params args dest
+ eval_box_free config generics args dest
| _ ->
(* "Normal" case: not box_free *)
(* Evaluate the operands *)
@@ -604,16 +530,14 @@ let eval_non_local_function_call_concrete (config : C.config)
* but it made it less clear where the computed values came from,
* so we reversed the modifications. *)
let cf_eval_call cf (args_vl : V.typed_value list) : m_fun =
+ fun ctx ->
(* Push the stack frame: we initialize the frame with the return variable,
and one variable per input argument *)
let cc = push_frame in
(* Create and push the return variable *)
let ret_vid = E.VarId.zero in
- let ret_ty =
- get_non_local_function_return_type fid region_params type_params
- cg_params
- in
+ let ret_ty = get_assumed_function_return_type ctx fid generics in
let ret_var = mk_var ret_vid (Some "@return") ret_ty in
let cc = comp cc (push_uninitialized_var ret_var) in
@@ -630,24 +554,12 @@ let eval_non_local_function_call_concrete (config : C.config)
* access to a body. *)
let cf_eval_body : cm_fun =
match fid with
- | A.Replace ->
- eval_replace_concrete config region_params type_params cg_params
- | BoxNew ->
- eval_box_new_concrete config region_params type_params cg_params
- | BoxDeref ->
- eval_box_deref_concrete config region_params type_params cg_params
- | BoxDerefMut ->
- eval_box_deref_mut_concrete config region_params type_params
- cg_params
+ | BoxNew -> eval_box_new_concrete config generics
| BoxFree ->
(* Should have been treated above *) raise (Failure "Unreachable")
- | VecNew | VecPush | VecInsert | VecLen | VecIndex | VecIndexMut ->
- eval_vec_function_concrete config fid region_params type_params
- cg_params
| ArrayIndexShared | ArrayIndexMut | ArrayToSliceShared
- | ArrayToSliceMut | ArraySubsliceShared | ArraySubsliceMut
- | SliceIndexShared | SliceIndexMut | SliceSubsliceShared
- | SliceSubsliceMut | SliceLen ->
+ | ArrayToSliceMut | ArrayRepeat | SliceIndexShared | SliceIndexMut
+ | SliceLen ->
raise (Failure "Unimplemented")
in
@@ -657,50 +569,11 @@ let eval_non_local_function_call_concrete (config : C.config)
let cc = comp cc (pop_frame_assign config dest) in
(* Continue *)
- cc cf
+ cc cf ctx
in
(* Compose and apply *)
comp cf_eval_ops cf_eval_call
-let instantiate_fun_sig (type_params : T.ety list)
- (cg_params : T.const_generic list) (sg : A.fun_sig) : A.inst_fun_sig =
- (* Generate fresh abstraction ids and create a substitution from region
- * group ids to abstraction ids *)
- let rg_abs_ids_bindings =
- List.map
- (fun rg ->
- let abs_id = C.fresh_abstraction_id () in
- (rg.T.id, abs_id))
- sg.regions_hierarchy
- in
- let asubst_map : V.AbstractionId.id T.RegionGroupId.Map.t =
- List.fold_left
- (fun mp (rg_id, abs_id) -> T.RegionGroupId.Map.add rg_id abs_id mp)
- T.RegionGroupId.Map.empty rg_abs_ids_bindings
- in
- let asubst (rg_id : T.RegionGroupId.id) : V.AbstractionId.id =
- T.RegionGroupId.Map.find rg_id asubst_map
- in
- (* Generate fresh regions and their substitutions *)
- let _, rsubst, _ = Subst.fresh_regions_with_substs sg.region_params in
- (* Generate the type substitution
- * Note that we need the substitution to map the type variables to
- * {!rty} types (not {!ety}). In order to do that, we convert the
- * type parameters to types with regions. This is possible only
- * if those types don't contain any regions.
- * This is a current limitation of the analysis: there is still some
- * work to do to properly handle full type parametrization.
- * *)
- let rtype_params = List.map ety_no_regions_to_rty type_params in
- let tsubst = Subst.make_type_subst_from_vars sg.type_params rtype_params in
- let cgsubst =
- Subst.make_const_generic_subst_from_vars sg.const_generic_params cg_params
- in
- (* Substitute the signature *)
- let inst_sig = Subst.substitute_signature asubst rsubst tsubst cgsubst sg in
- (* Return *)
- inst_sig
-
(** Helper
Create abstractions (with no avalues, which have to be inserted afterwards)
@@ -836,7 +709,7 @@ let rec eval_statement (config : C.config) (st : A.statement) : st_cm_fun =
match rvalue with
| E.Global _ -> raise (Failure "Unreachable")
| E.Use _
- | E.Ref (_, (E.Shared | E.Mut | E.TwoPhaseMut | E.Shallow))
+ | E.RvRef (_, (E.Shared | E.Mut | E.TwoPhaseMut | E.Shallow))
| E.UnaryOp _ | E.BinaryOp _ | E.Discriminant _
| E.Aggregate _ ->
let rp = rvalue_get_place rvalue in
@@ -893,7 +766,15 @@ and eval_global (config : C.config) (dest : E.place) (gid : LA.GlobalDeclId.id)
match config.mode with
| ConcreteMode ->
(* Treat the evaluation of the global as a call to the global body (without arguments) *)
- (eval_local_function_call_concrete config global.body_id [] [] [] [] dest)
+ let func =
+ {
+ E.func = FunId (Regular global.body_id);
+ generics = TypesUtils.mk_empty_generic_args;
+ trait_and_method_generic_args = None;
+ }
+ in
+ let call = { A.func; args = []; dest } in
+ (eval_transparent_function_call_concrete config global.body_id call)
cf ctx
| SymbolicMode ->
(* Generate a fresh symbolic value. In the translation, this fresh symbolic value will be
@@ -1037,128 +918,374 @@ and eval_switch (config : C.config) (switch : A.switch) : st_cm_fun =
(** Evaluate a function call (auxiliary helper for [eval_statement]) *)
and eval_function_call (config : C.config) (call : A.call) : st_cm_fun =
- (* There are two cases:
+ (* There are several cases:
- this is a local function, in which case we execute its body
- - this is a non-local function, in which case there is a special treatment
+ - this is an assumed function, in which case there is a special treatment
+ - this is a trait method
*)
- match call.func with
- | A.Regular fid ->
- eval_local_function_call config fid call.region_args call.type_args
- call.const_generic_args call.args call.dest
- | A.Assumed fid ->
- eval_non_local_function_call config fid call.region_args call.type_args
- call.const_generic_args call.args call.dest
+ match config.mode with
+ | C.ConcreteMode -> eval_function_call_concrete config call
+ | C.SymbolicMode -> eval_function_call_symbolic config call
-(** Evaluate a local (i.e., non-assumed) function call in concrete mode *)
-and eval_local_function_call_concrete (config : C.config) (fid : A.FunDeclId.id)
- (_region_args : T.erased_region list) (type_args : T.ety list)
- (cg_args : T.const_generic list) (args : E.operand list) (dest : E.place) :
- st_cm_fun =
+and eval_function_call_concrete (config : C.config) (call : A.call) : st_cm_fun
+ =
fun cf ctx ->
- (* Retrieve the (correctly instantiated) body *)
- let def = C.ctx_lookup_fun_decl ctx fid in
- (* We can evaluate the function call only if it is not opaque *)
- let body =
- match def.body with
- | None ->
- raise
- (Failure
- ("Can't evaluate a call to an opaque function: "
- ^ Print.name_to_string def.name))
- | Some body -> body
- in
- let tsubst =
- Subst.make_type_subst_from_vars def.A.signature.type_params type_args
- in
- let cgsubst =
- Subst.make_const_generic_subst_from_vars
- def.A.signature.const_generic_params cg_args
- in
- let locals, body_st = Subst.fun_body_substitute_in_body tsubst cgsubst body in
-
- (* Evaluate the input operands *)
- assert (List.length args = body.A.arg_count);
- let cc = eval_operands config args in
-
- (* Push a frame delimiter - we use {!comp_transmit} to transmit the result
- * of the operands evaluation from above to the functions afterwards, while
- * ignoring it in this function *)
- let cc = comp_transmit cc push_frame in
-
- (* Compute the initial values for the local variables *)
- (* 1. Push the return value *)
- let ret_var, locals =
- match locals with
- | ret_ty :: locals -> (ret_ty, locals)
- | _ -> raise (Failure "Unreachable")
- in
- let input_locals, locals =
- Collections.List.split_at locals body.A.arg_count
- in
+ match call.func.func with
+ | FunId (Regular fid) ->
+ eval_transparent_function_call_concrete config fid call cf ctx
+ | FunId (Assumed fid) ->
+ (* Continue - note that we do as if the function call has been successful,
+ * by giving {!Unit} to the continuation, because we place us in the case
+ * where we haven't panicked. Of course, the translation needs to take the
+ * panic case into account... *)
+ eval_assumed_function_call_concrete config fid call (cf Unit) ctx
+ | TraitMethod _ -> raise (Failure "Unimplemented")
+
+and eval_function_call_symbolic (config : C.config) (call : A.call) : st_cm_fun
+ =
+ match call.func.func with
+ | FunId (Regular _) | TraitMethod _ ->
+ eval_transparent_function_call_symbolic config call
+ | FunId (Assumed fid) -> eval_assumed_function_call_symbolic config fid call
- let cc = comp_transmit cc (push_var ret_var (mk_bottom ret_var.var_ty)) in
-
- (* 2. Push the input values *)
- let cf_push_inputs cf args =
- let inputs = List.combine input_locals args in
- (* Note that this function checks that the variables and their values
- * have the same type (this is important) *)
- push_vars inputs cf
- in
- let cc = comp cc cf_push_inputs in
-
- (* 3. Push the remaining local variables (initialized as {!Bottom}) *)
- let cc = comp cc (push_uninitialized_vars locals) in
+(** Evaluate a local (i.e., non-assumed) function call in concrete mode *)
+and eval_transparent_function_call_concrete (config : C.config)
+ (fid : A.FunDeclId.id) (call : A.call) : st_cm_fun =
+ let generics = call.func.generics in
+ let args = call.A.args in
+ let dest = call.A.dest in
+ (* Sanity check: we don't fully handle the const generic vars environment
+ in concrete mode yet *)
+ assert (generics.const_generics = []);
+ fun cf ctx ->
+ (* Retrieve the (correctly instantiated) body *)
+ let def = C.ctx_lookup_fun_decl ctx fid in
+ (* We can evaluate the function call only if it is not opaque *)
+ let body =
+ match def.body with
+ | None ->
+ raise
+ (Failure
+ ("Can't evaluate a call to an opaque function: "
+ ^ Print.name_to_string def.name))
+ | Some body -> body
+ in
+ (* TODO: we need to normalize the types if we want to correctly support traits *)
+ assert (generics.trait_refs = []);
+ (* There shouldn't be any reference to Self *)
+ let tr_self = T.UnknownTrait __FUNCTION__ in
+ let subst =
+ Subst.make_esubst_from_generics def.A.signature.generics generics tr_self
+ in
+ let locals, body_st = Subst.fun_body_substitute_in_body subst body in
+
+ (* Evaluate the input operands *)
+ assert (List.length args = body.A.arg_count);
+ let cc = eval_operands config args in
+
+ (* Push a frame delimiter - we use {!comp_transmit} to transmit the result
+ * of the operands evaluation from above to the functions afterwards, while
+ * ignoring it in this function *)
+ let cc = comp_transmit cc push_frame in
+
+ (* Compute the initial values for the local variables *)
+ (* 1. Push the return value *)
+ let ret_var, locals =
+ match locals with
+ | ret_ty :: locals -> (ret_ty, locals)
+ | _ -> raise (Failure "Unreachable")
+ in
+ let input_locals, locals =
+ Collections.List.split_at locals body.A.arg_count
+ in
- (* Execute the function body *)
- let cc = comp cc (eval_function_body config body_st) in
+ let cc = comp_transmit cc (push_var ret_var (mk_bottom ret_var.var_ty)) in
- (* Pop the stack frame and move the return value to its destination *)
- let cf_finish cf res =
- match res with
- | Panic -> cf Panic
- | Return ->
- (* Pop the stack frame, retrieve the return value, move it to
- * its destination and continue *)
- pop_frame_assign config dest (cf Unit)
- | Break _ | Continue _ | Unit | LoopReturn _ | EndEnterLoop _
- | EndContinue _ ->
- raise (Failure "Unreachable")
- in
- let cc = comp cc cf_finish in
+ (* 2. Push the input values *)
+ let cf_push_inputs cf args =
+ let inputs = List.combine input_locals args in
+ (* Note that this function checks that the variables and their values
+ * have the same type (this is important) *)
+ push_vars inputs cf
+ in
+ let cc = comp cc cf_push_inputs in
+
+ (* 3. Push the remaining local variables (initialized as {!Bottom}) *)
+ let cc = comp cc (push_uninitialized_vars locals) in
+
+ (* Execute the function body *)
+ let cc = comp cc (eval_function_body config body_st) in
+
+ (* Pop the stack frame and move the return value to its destination *)
+ let cf_finish cf res =
+ match res with
+ | Panic -> cf Panic
+ | Return ->
+ (* Pop the stack frame, retrieve the return value, move it to
+ * its destination and continue *)
+ pop_frame_assign config dest (cf Unit)
+ | Break _ | Continue _ | Unit | LoopReturn _ | EndEnterLoop _
+ | EndContinue _ ->
+ raise (Failure "Unreachable")
+ in
+ let cc = comp cc cf_finish in
- (* Continue *)
- cc cf ctx
+ (* Continue *)
+ cc cf ctx
(** Evaluate a local (i.e., non-assumed) function call in symbolic mode *)
-and eval_local_function_call_symbolic (config : C.config) (fid : A.FunDeclId.id)
- (region_args : T.erased_region list) (type_args : T.ety list)
- (cg_args : T.const_generic list) (args : E.operand list) (dest : E.place) :
- st_cm_fun =
+and eval_transparent_function_call_symbolic (config : C.config) (call : A.call)
+ : st_cm_fun =
fun cf ctx ->
- (* Retrieve the (correctly instantiated) signature *)
- let def = C.ctx_lookup_fun_decl ctx fid in
- let sg = def.A.signature in
- (* Instantiate the signature and introduce fresh abstraction and region ids
- * while doing so *)
- let inst_sg = instantiate_fun_sig type_args cg_args sg in
+ (* Instantiate the signature and introduce fresh abstractions and region ids while doing so.
+
+ We perform some manipulations when instantiating the signature.
+
+ # Trait impl calls
+ ==================
+ In particular, we have a special treatment of trait method calls when
+ the trait ref is a known impl.
+
+ For instance:
+ {[
+ trait HasValue {
+ fn has_value(&self) -> bool;
+ }
+
+ impl<T> HasValue for Option<T> {
+ fn has_value(&self) {
+ match self {
+ None => false,
+ Some(_) => true,
+ }
+ }
+ }
+
+ fn option_has_value<T>(x: &Option<T>) -> bool {
+ x.has_value()
+ }
+ ]}
+
+ The generated code looks like this:
+ {[
+ structure HasValue (Self : Type) = {
+ has_value : Self -> result bool
+ }
+
+ let OptionHasValueImpl.has_value (Self : Type) (self : Self) : result bool =
+ match self with
+ | None => false
+ | Some _ => true
+
+ let OptionHasValueInstance (T : Type) : HasValue (Option T) = {
+ has_value = OptionHasValueInstance.has_value
+ }
+ ]}
+
+ In [option_has_value], we don't want to refer to the [has_value] method
+ of the instance of [HasValue] for [Option<T>]. We want to refer directly
+ to the function which implements [has_value] for [Option<T>].
+ That is, instead of generating this:
+ {[
+ let option_has_value (T : Type) (x : Option T) : result bool =
+ (OptionHasValueInstance T).has_value x
+ ]}
+
+ We want to generate this:
+ {[
+ let option_has_value (T : Type) (x : Option T) : result bool =
+ OptionHasValueImpl.has_value T x
+ ]}
+
+ # Provided trait methods
+ ========================
+ Calls to provided trait methods also have a special treatment because
+ for now we forbid overriding provided trait methods in the trait implementations,
+ which means that whenever we call a provided trait method, we do not refer
+ to a trait clause but directly to the method provided in the trait declaration.
+ *)
+ let func, generics, def, inst_sg =
+ match call.func.func with
+ | FunId (Regular fid) ->
+ let def = C.ctx_lookup_fun_decl ctx fid in
+ log#ldebug
+ (lazy
+ ("fun call:\n- call: " ^ call_to_string ctx call
+ ^ "\n- call.generics:\n"
+ ^ egeneric_args_to_string ctx call.func.generics
+ ^ "\n- def.signature:\n"
+ ^ fun_sig_to_string ctx def.A.signature));
+ let tr_self = T.UnknownTrait __FUNCTION__ in
+ let inst_sg =
+ instantiate_fun_sig ctx call.func.generics tr_self def.A.signature
+ in
+ (call.func.func, call.func.generics, def, inst_sg)
+ | FunId (Assumed _) ->
+ (* Unreachable: must be a transparent function *)
+ raise (Failure "Unreachable")
+ | TraitMethod (trait_ref, method_name, _) -> (
+ log#ldebug
+ (lazy
+ ("trait method call:\n- call: " ^ call_to_string ctx call
+ ^ "\n- method name: " ^ method_name ^ "\n- call.generics:\n"
+ ^ egeneric_args_to_string ctx call.func.generics
+ ^ "\n- trait and method generics:\n"
+ ^ egeneric_args_to_string ctx
+ (Option.get call.func.trait_and_method_generic_args)));
+ (* When instantiating, we need to group the generics for the trait ref
+ and the method *)
+ let generics = Option.get call.func.trait_and_method_generic_args in
+ (* Lookup the trait method signature - there are several possibilities
+ depending on whethere we call a top-level trait method impl or the
+ method from a local clause *)
+ match trait_ref.trait_id with
+ | TraitImpl impl_id -> (
+ (* Lookup the trait impl *)
+ let trait_impl = C.ctx_lookup_trait_impl ctx impl_id in
+ log#ldebug
+ (lazy ("trait impl: " ^ trait_impl_to_string ctx trait_impl));
+ (* First look in the required methods *)
+ let method_id =
+ List.find_opt
+ (fun (s, _) -> s = method_name)
+ trait_impl.required_methods
+ in
+ match method_id with
+ | Some (_, id) ->
+ (* This is a required method *)
+ let method_def = C.ctx_lookup_fun_decl ctx id in
+ (* Instantiate *)
+ let tr_self =
+ T.TraitRef (etrait_ref_no_regions_to_gr_trait_ref trait_ref)
+ in
+ let inst_sg =
+ instantiate_fun_sig ctx generics tr_self
+ method_def.A.signature
+ in
+ (* Also update the function identifier: we want to forget
+ the fact that we called a trait method, and treat it as
+ a regular function call to the top-level function
+ which implements the method. In order to do this properly,
+ we also need to update the generics.
+ *)
+ let func = E.FunId (Regular id) in
+ (func, generics, method_def, inst_sg)
+ | None ->
+ (* If not found, lookup the methods provided by the trait *declaration*
+ (remember: for now, we forbid overriding provided methods) *)
+ assert (trait_impl.provided_methods = []);
+ let trait_decl =
+ C.ctx_lookup_trait_decl ctx
+ trait_ref.trait_decl_ref.trait_decl_id
+ in
+ let _, method_id =
+ List.find
+ (fun (s, _) -> s = method_name)
+ trait_decl.provided_methods
+ in
+ let method_id = Option.get method_id in
+ let method_def = C.ctx_lookup_fun_decl ctx method_id in
+ (* For the instantiation we have to do something peculiar
+ because the method was defined for the trait declaration.
+ We have to group:
+ - the parameters given to the trait decl reference
+ - the parameters given to the method itself
+ For instance:
+ {[
+ trait Foo<T> {
+ fn f<U>(...) { ... }
+ }
+
+ fn g<G>(x : G) where Clause0: Foo<G, bool>
+ {
+ x.f::<u32>(...) // The arguments to f are: <G, bool, u32>
+ }
+ ]}
+ *)
+ let all_generics =
+ TypesUtils.merge_generic_args
+ trait_ref.trait_decl_ref.decl_generics call.func.generics
+ in
+ log#ldebug
+ (lazy
+ ("provided method call:" ^ "\n- method name: " ^ method_name
+ ^ "\n- all_generics:\n"
+ ^ egeneric_args_to_string ctx all_generics
+ ^ "\n- parent params info: "
+ ^ Print.option_to_string A.show_params_info
+ method_def.signature.parent_params_info));
+ let tr_self =
+ T.TraitRef (etrait_ref_no_regions_to_gr_trait_ref trait_ref)
+ in
+ let inst_sg =
+ instantiate_fun_sig ctx all_generics tr_self
+ method_def.A.signature
+ in
+ (call.func.func, call.func.generics, method_def, inst_sg))
+ | _ ->
+ (* We are using a local clause - we lookup the trait decl *)
+ let trait_decl =
+ C.ctx_lookup_trait_decl ctx trait_ref.trait_decl_ref.trait_decl_id
+ in
+ (* Lookup the method decl in the required *and* the provided methods *)
+ let _, method_id =
+ let provided =
+ List.filter_map
+ (fun (id, f) ->
+ match f with None -> None | Some f -> Some (id, f))
+ trait_decl.provided_methods
+ in
+ List.find
+ (fun (s, _) -> s = method_name)
+ (List.append trait_decl.required_methods provided)
+ in
+ let method_def = C.ctx_lookup_fun_decl ctx method_id in
+ log#ldebug (lazy ("method:\n" ^ fun_decl_to_string ctx method_def));
+ (* Instantiate *)
+ let tr_self = T.TraitRef trait_ref in
+ let tr_self =
+ TypesUtils.etrait_instance_id_no_regions_to_gr_trait_instance_id
+ tr_self
+ in
+ let inst_sg =
+ instantiate_fun_sig ctx generics tr_self method_def.A.signature
+ in
+ (call.func.func, call.func.generics, method_def, inst_sg))
+ in
(* Sanity check *)
- assert (List.length args = List.length def.A.signature.inputs);
+ assert (List.length call.args = List.length def.A.signature.inputs);
(* Evaluate the function call *)
- eval_function_call_symbolic_from_inst_sig config (A.Regular fid) inst_sg
- region_args type_args cg_args args dest cf ctx
+ eval_function_call_symbolic_from_inst_sig config func inst_sg generics
+ call.args call.dest cf ctx
(** Evaluate a function call in symbolic mode by using the function signature.
This allows us to factorize the evaluation of local and non-local function
calls in symbolic mode: only their signatures matter.
+
+ The [self_trait_ref] trait ref refers to [Self]. We use it when calling
+ a provided trait method, because those methods have a special treatment:
+ we dot not group them with the required trait methods, and forbid (for now)
+ overriding them. We treat them as regular method, which take an additional
+ trait ref as input.
*)
and eval_function_call_symbolic_from_inst_sig (config : C.config)
- (fid : A.fun_id) (inst_sg : A.inst_fun_sig)
- (_region_args : T.erased_region list) (type_args : T.ety list)
- (cg_args : T.const_generic list) (args : E.operand list) (dest : E.place) :
+ (fid : A.fun_id_or_trait_method_ref) (inst_sg : A.inst_fun_sig)
+ (generics : T.egeneric_args) (args : E.operand list) (dest : E.place) :
st_cm_fun =
fun cf ctx ->
+ log#ldebug
+ (lazy
+ ("eval_function_call_symbolic_from_inst_sig:\n- fid: "
+ ^ fun_id_or_trait_method_ref_to_string ctx fid
+ ^ "\n- inst_sg:\n"
+ ^ inst_fun_sig_to_string ctx inst_sg
+ ^ "\n- call.generics:\n"
+ ^ egeneric_args_to_string ctx generics
+ ^ "\n- args:\n"
+ ^ String.concat ", " (List.map (operand_to_string ctx) args)
+ ^ "\n- dest:\n" ^ place_to_string ctx dest));
+
(* Generate a fresh symbolic value for the return value *)
let ret_sv_ty = inst_sg.A.output in
let ret_spc = mk_fresh_symbolic_value V.FunCallRet ret_sv_ty in
@@ -1224,8 +1351,8 @@ and eval_function_call_symbolic_from_inst_sig (config : C.config)
let expr = cf ctx in
(* Synthesize the symbolic AST *)
- S.synthesize_regular_function_call fid call_id ctx abs_ids type_args cg_args
- args args_places ret_spc dest_place expr
+ S.synthesize_regular_function_call fid call_id ctx abs_ids generics args
+ args_places ret_spc dest_place expr
in
let cc = comp cc cf_call in
@@ -1286,17 +1413,18 @@ and eval_function_call_symbolic_from_inst_sig (config : C.config)
cc (cf Unit) ctx
(** Evaluate a non-local function call in symbolic mode *)
-and eval_non_local_function_call_symbolic (config : C.config)
- (fid : A.assumed_fun_id) (region_args : T.erased_region list)
- (type_args : T.ety list) (cg_args : T.const_generic list)
- (args : E.operand list) (dest : E.place) : st_cm_fun =
+and eval_assumed_function_call_symbolic (config : C.config)
+ (fid : A.assumed_fun_id) (call : A.call) : st_cm_fun =
fun cf ctx ->
+ let generics = call.func.generics in
+ let args = call.args in
+ let dest = call.dest in
(* Sanity check: make sure the type parameters don't contain regions -
* this is a current limitation of our synthesis *)
assert (
List.for_all
(fun ty -> not (ty_has_borrows ctx.type_context.type_infos ty))
- type_args);
+ generics.types);
(* There are two cases (and this is extremely annoying):
- the function is not box_free
@@ -1304,10 +1432,10 @@ and eval_non_local_function_call_symbolic (config : C.config)
See {!eval_box_free}
*)
match fid with
- | A.BoxFree ->
+ | BoxFree ->
(* Degenerate case: box_free - note that this is not really a function
* call: no need to call a "synthesize_..." function *)
- eval_box_free config region_args type_args cg_args args dest (cf Unit) ctx
+ eval_box_free config generics args dest (cf Unit) ctx
| _ ->
(* "Normal" case: not box_free *)
(* In symbolic mode, the behaviour of a function call is completely defined
@@ -1315,59 +1443,19 @@ and eval_non_local_function_call_symbolic (config : C.config)
* instantiated signatures, and delegate the work to an auxiliary function *)
let inst_sig =
match fid with
- | A.BoxFree ->
+ | BoxFree ->
(* should have been treated above *)
raise (Failure "Unreachable")
| _ ->
- instantiate_fun_sig type_args cg_args (Assumed.get_assumed_sig fid)
+ (* There shouldn't be any reference to Self *)
+ let tr_self = T.UnknownTrait __FUNCTION__ in
+ instantiate_fun_sig ctx generics tr_self
+ (Assumed.get_assumed_fun_sig fid)
in
(* Evaluate the function call *)
- eval_function_call_symbolic_from_inst_sig config (A.Assumed fid) inst_sig
- region_args type_args cg_args args dest cf ctx
-
-(** Evaluate a non-local (i.e, assumed) function call such as [Box::deref]
- (auxiliary helper for [eval_statement]) *)
-and eval_non_local_function_call (config : C.config) (fid : A.assumed_fun_id)
- (region_args : T.erased_region list) (type_args : T.ety list)
- (cg_args : T.const_generic list) (args : E.operand list) (dest : E.place) :
- st_cm_fun =
- fun cf ctx ->
- (* Debug *)
- log#ldebug
- (lazy
- (let type_args =
- "[" ^ String.concat ", " (List.map (ety_to_string ctx) type_args) ^ "]"
- in
- let args =
- "[" ^ String.concat ", " (List.map (operand_to_string ctx) args) ^ "]"
- in
- let dest = place_to_string ctx dest in
- "eval_non_local_function_call:\n- fid:" ^ A.show_assumed_fun_id fid
- ^ "\n- type_args: " ^ type_args ^ "\n- args: " ^ args ^ "\n- dest: "
- ^ dest));
-
- match config.mode with
- | C.ConcreteMode ->
- eval_non_local_function_call_concrete config fid region_args type_args
- cg_args args dest (cf Unit) ctx
- | C.SymbolicMode ->
- eval_non_local_function_call_symbolic config fid region_args type_args
- cg_args args dest cf ctx
-
-(** Evaluate a local (i.e, not assumed) function call (auxiliary helper for
- [eval_statement]) *)
-and eval_local_function_call (config : C.config) (fid : A.FunDeclId.id)
- (region_args : T.erased_region list) (type_args : T.ety list)
- (cg_args : T.const_generic list) (args : E.operand list) (dest : E.place) :
- st_cm_fun =
- match config.mode with
- | ConcreteMode ->
- eval_local_function_call_concrete config fid region_args type_args cg_args
- args dest
- | SymbolicMode ->
- eval_local_function_call_symbolic config fid region_args type_args cg_args
- args dest
+ eval_function_call_symbolic_from_inst_sig config (FunId (Assumed fid))
+ inst_sig generics args dest cf ctx
(** Evaluate a statement seen as a function body *)
and eval_function_body (config : C.config) (body : A.statement) : st_cm_fun =
diff --git a/compiler/InterpreterStatements.mli b/compiler/InterpreterStatements.mli
index 814bc964..e65758ae 100644
--- a/compiler/InterpreterStatements.mli
+++ b/compiler/InterpreterStatements.mli
@@ -25,15 +25,6 @@ open InterpreterExpressions
*)
val pop_frame : C.config -> bool -> (V.typed_value option -> m_fun) -> m_fun
-(** Instantiate a function signature, introducing **fresh** abstraction ids and
- region ids. This is mostly used in preparation of function calls, when
- evaluating in symbolic mode of course.
-
- Note: there are no region parameters, because they should be erased.
- *)
-val instantiate_fun_sig :
- T.ety list -> T.const_generic list -> LA.fun_sig -> LA.inst_fun_sig
-
(** Helper.
Create a list of abstractions from a list of regions groups, and insert
diff --git a/compiler/InterpreterUtils.ml b/compiler/InterpreterUtils.ml
index 7bd37550..6e08e553 100644
--- a/compiler/InterpreterUtils.ml
+++ b/compiler/InterpreterUtils.ml
@@ -10,6 +10,11 @@ open TypesUtils
module PA = Print.EvalCtxLlbcAst
open Cps
+(* TODO: we should probably rename the file to ContextsUtils *)
+
+(** The local logger *)
+let log = L.interpreter_log
+
(** Some utilities *)
(** Auxiliary function - call a function which requires a continuation,
@@ -38,6 +43,20 @@ let typed_value_to_string = PA.typed_value_to_string
let typed_avalue_to_string = PA.typed_avalue_to_string
let place_to_string = PA.place_to_string
let operand_to_string = PA.operand_to_string
+let egeneric_args_to_string = PA.egeneric_args_to_string
+let rtrait_instance_id_to_string = PA.rtrait_instance_id_to_string
+let fun_sig_to_string = PA.fun_sig_to_string
+let inst_fun_sig_to_string = PA.inst_fun_sig_to_string
+
+let fun_id_or_trait_method_ref_to_string =
+ PA.fun_id_or_trait_method_ref_to_string
+
+let fun_decl_to_string = PA.fun_decl_to_string
+let call_to_string = PA.call_to_string
+
+let trait_impl_to_string ctx =
+ PA.trait_impl_to_string { ctx with type_vars = []; const_generic_vars = [] }
+
let statement_to_string ctx = PA.statement_to_string ctx "" " "
let statement_to_string_with_tab ctx = PA.statement_to_string ctx " " " "
let env_elem_to_string ctx = PA.env_elem_to_string ctx "" " "
@@ -255,7 +274,8 @@ let value_has_ret_symbolic_value_with_borrow_under_mut (ctx : C.eval_ctx)
raise Found
else ()
| V.SynthInput | V.SynthInputGivenBack | V.FunCallGivenBack
- | V.SynthRetGivenBack | V.Global | V.LoopGivenBack | V.Aggregate ->
+ | V.SynthRetGivenBack | V.Global | V.LoopGivenBack | V.Aggregate
+ | V.ConstGeneric | V.TraitConst ->
()
end
in
@@ -272,7 +292,7 @@ let rvalue_get_place (rv : E.rvalue) : E.place option =
match rv with
| Use (Copy p | Move p) -> Some p
| Use (Constant _) -> None
- | Ref (p, _) -> Some p
+ | RvRef (p, _) -> Some p
| UnaryOp _ | BinaryOp _ | Global _ | Discriminant _ | Aggregate _ -> None
(** See {!ValuesUtils.symbolic_value_has_borrows} *)
@@ -403,3 +423,103 @@ let compute_contexts_ids (ctxl : C.eval_ctx list) : ids_sets * ids_to_values =
(** Compute the sets of ids found in a context. *)
let compute_context_ids (ctx : C.eval_ctx) : ids_sets * ids_to_values =
compute_contexts_ids [ ctx ]
+
+(** **WARNING**: this function doesn't compute the normalized types
+ (for the trait type aliases). This should be computed afterwards.
+ *)
+let initialize_eval_context (ctx : C.decls_ctx)
+ (region_groups : T.RegionGroupId.id list) (type_vars : T.type_var list)
+ (const_generic_vars : T.const_generic_var list) : C.eval_ctx =
+ C.reset_global_counters ();
+ let const_generic_vars_map =
+ T.ConstGenericVarId.Map.of_list
+ (List.map
+ (fun (cg : T.const_generic_var) ->
+ let ty = TypesUtils.ety_no_regions_to_rty (T.Literal cg.ty) in
+ let cv = mk_fresh_symbolic_typed_value V.ConstGeneric ty in
+ (cg.index, cv))
+ const_generic_vars)
+ in
+ {
+ C.type_context = ctx.type_ctx;
+ C.fun_context = ctx.fun_ctx;
+ C.global_context = ctx.global_ctx;
+ C.trait_decls_context = ctx.trait_decls_ctx;
+ C.trait_impls_context = ctx.trait_impls_ctx;
+ C.region_groups;
+ C.type_vars;
+ C.const_generic_vars;
+ C.const_generic_vars_map;
+ C.norm_trait_etypes = C.ETraitTypeRefMap.empty (* Empty for now *);
+ C.norm_trait_rtypes = C.RTraitTypeRefMap.empty (* Empty for now *);
+ C.norm_trait_stypes = C.STraitTypeRefMap.empty (* Empty for now *);
+ C.env = [ C.Frame ];
+ C.ended_regions = T.RegionId.Set.empty;
+ }
+
+(** Instantiate a function signature, introducing **fresh** abstraction ids and
+ region ids. This is mostly used in preparation of function calls (when
+ evaluating in symbolic mode).
+
+ Note: there are no region parameters, because they should be erased.
+ *)
+let instantiate_fun_sig (ctx : C.eval_ctx) (generics : T.egeneric_args)
+ (tr_self : T.rtrait_instance_id) (sg : A.fun_sig) : A.inst_fun_sig =
+ log#ldebug
+ (lazy
+ ("instantiate_fun_sig:" ^ "\n- generics: "
+ ^ egeneric_args_to_string ctx generics
+ ^ "\n- tr_self: "
+ ^ rtrait_instance_id_to_string ctx tr_self
+ ^ "\n- sg: " ^ fun_sig_to_string ctx sg));
+ (* Generate fresh abstraction ids and create a substitution from region
+ * group ids to abstraction ids *)
+ let rg_abs_ids_bindings =
+ List.map
+ (fun rg ->
+ let abs_id = C.fresh_abstraction_id () in
+ (rg.T.id, abs_id))
+ sg.regions_hierarchy
+ in
+ let asubst_map : V.AbstractionId.id T.RegionGroupId.Map.t =
+ List.fold_left
+ (fun mp (rg_id, abs_id) -> T.RegionGroupId.Map.add rg_id abs_id mp)
+ T.RegionGroupId.Map.empty rg_abs_ids_bindings
+ in
+ let asubst (rg_id : T.RegionGroupId.id) : V.AbstractionId.id =
+ T.RegionGroupId.Map.find rg_id asubst_map
+ in
+ (* Generate fresh regions and their substitutions *)
+ let _, rsubst, _ = Subst.fresh_regions_with_substs sg.generics.regions in
+ (* Generate the type substitution
+ * Note that we need the substitution to map the type variables to
+ * {!rty} types (not {!ety}). In order to do that, we convert the
+ * type parameters to types with regions. This is possible only
+ * if those types don't contain any regions.
+ * This is a current limitation of the analysis: there is still some
+ * work to do to properly handle full type parametrization.
+ * *)
+ let rtype_params = List.map ety_no_regions_to_rty generics.types in
+ let tsubst = Subst.make_type_subst_from_vars sg.generics.types rtype_params in
+ let cgsubst =
+ Subst.make_const_generic_subst_from_vars sg.generics.const_generics
+ generics.const_generics
+ in
+ (* TODO: something annoying with the trait ref subst: we need to use region
+ types, but the arguments use erased regions. For now we use the fact
+ that no regions should appear inside. In the future: we should merge
+ ety and rty. *)
+ let trait_refs =
+ List.map TypesUtils.etrait_ref_no_regions_to_gr_trait_ref
+ generics.trait_refs
+ in
+ let tr_subst =
+ Subst.make_trait_subst_from_clauses sg.generics.trait_clauses trait_refs
+ in
+ (* Substitute the signature *)
+ let inst_sig =
+ AssociatedTypes.ctx_subst_norm_signature ctx asubst rsubst tsubst cgsubst
+ tr_subst tr_self sg
+ in
+ (* Return *)
+ inst_sig
diff --git a/compiler/Invariants.ml b/compiler/Invariants.ml
index f29c7f88..5c8ec7af 100644
--- a/compiler/Invariants.ml
+++ b/compiler/Invariants.ml
@@ -7,6 +7,7 @@ module V = Values
module E = Expressions
module C = Contexts
module Subst = Substitute
+module Assoc = AssociatedTypes
module A = LlbcAst
module L = Logging
open Cps
@@ -406,13 +407,14 @@ let check_typing_invariant (ctx : C.eval_ctx) : unit =
(match (tv.V.value, tv.V.ty) with
| V.Literal cv, T.Literal ty -> check_literal_type cv ty
(* ADT case *)
- | V.Adt av, T.Adt (T.AdtId def_id, regions, tys, cgs) ->
+ | V.Adt av, T.Adt (T.AdtId def_id, generics) ->
(* Retrieve the definition to check the variant id, the number of
* parameters, etc. *)
let def = C.ctx_lookup_type_decl ctx def_id in
(* Check the number of parameters *)
- assert (List.length regions = List.length def.region_params);
- assert (List.length tys = List.length def.type_params);
+ assert (
+ List.length generics.regions = List.length def.generics.regions);
+ assert (List.length generics.types = List.length def.generics.types);
(* Check that the variant id is consistent *)
(match (av.V.variant_id, def.T.kind) with
| Some variant_id, T.Enum variants ->
@@ -421,8 +423,8 @@ let check_typing_invariant (ctx : C.eval_ctx) : unit =
| _ -> raise (Failure "Erroneous typing"));
(* Check that the field types are correct *)
let field_types =
- Subst.type_decl_get_instantiated_field_etypes def av.V.variant_id
- tys cgs
+ Assoc.type_decl_get_inst_norm_field_etypes ctx def av.V.variant_id
+ generics
in
let fields_with_types =
List.combine av.V.field_values field_types
@@ -431,34 +433,31 @@ let check_typing_invariant (ctx : C.eval_ctx) : unit =
(fun ((v, ty) : V.typed_value * T.ety) -> assert (v.V.ty = ty))
fields_with_types
(* Tuple case *)
- | V.Adt av, T.Adt (T.Tuple, regions, tys, cgs) ->
- assert (regions = []);
- assert (cgs = []);
+ | V.Adt av, T.Adt (T.Tuple, generics) ->
+ assert (generics.regions = []);
+ assert (generics.const_generics = []);
assert (av.V.variant_id = None);
(* Check that the fields have the proper values - and check that there
* are as many fields as field types at the same time *)
- let fields_with_types = List.combine av.V.field_values tys in
+ let fields_with_types =
+ List.combine av.V.field_values generics.types
+ in
List.iter
(fun ((v, ty) : V.typed_value * T.ety) -> assert (v.V.ty = ty))
fields_with_types
(* Assumed type case *)
- | V.Adt av, T.Adt (T.Assumed aty_id, regions, tys, cgs) -> (
- assert (av.V.variant_id = None || aty_id = T.Option);
- match (aty_id, av.V.field_values, regions, tys, cgs) with
+ | V.Adt av, T.Adt (T.Assumed aty_id, generics) -> (
+ assert (av.V.variant_id = None);
+ match
+ ( aty_id,
+ av.V.field_values,
+ generics.regions,
+ generics.types,
+ generics.const_generics )
+ with
(* Box *)
- | T.Box, [ inner_value ], [], [ inner_ty ], []
- | T.Option, [ inner_value ], [], [ inner_ty ], [] ->
+ | T.Box, [ inner_value ], [], [ inner_ty ], [] ->
assert (inner_value.V.ty = inner_ty)
- | T.Option, _, [], [ _ ], [] ->
- (* Option::None: nothing to check *)
- ()
- | T.Vec, fvs, [], [ vec_ty ], [] ->
- List.iter
- (fun (v : V.typed_value) -> assert (v.ty = vec_ty))
- fvs
- | T.Range, [ v0; v1 ], [], [ inner_ty ], [] ->
- assert (v0.V.ty = inner_ty);
- assert (v1.V.ty = inner_ty)
| T.Array, inner_values, _, [ inner_ty ], [ cg ] ->
(* *)
assert (
@@ -520,14 +519,17 @@ let check_typing_invariant (ctx : C.eval_ctx) : unit =
(* Check the current pair (value, type) *)
(match (atv.V.value, atv.V.ty) with
(* ADT case *)
- | V.AAdt av, T.Adt (T.AdtId def_id, regions, tys, cgs) ->
+ | V.AAdt av, T.Adt (T.AdtId def_id, generics) ->
(* Retrieve the definition to check the variant id, the number of
* parameters, etc. *)
let def = C.ctx_lookup_type_decl ctx def_id in
(* Check the number of parameters *)
- assert (List.length regions = List.length def.region_params);
- assert (List.length tys = List.length def.type_params);
- assert (List.length cgs = List.length def.const_generic_params);
+ assert (
+ List.length generics.regions = List.length def.generics.regions);
+ assert (List.length generics.types = List.length def.generics.types);
+ assert (
+ List.length generics.const_generics
+ = List.length def.generics.const_generics);
(* Check that the variant id is consistent *)
(match (av.V.variant_id, def.T.kind) with
| Some variant_id, T.Enum variants ->
@@ -536,8 +538,8 @@ let check_typing_invariant (ctx : C.eval_ctx) : unit =
| _ -> raise (Failure "Erroneous typing"));
(* Check that the field types are correct *)
let field_types =
- Subst.type_decl_get_instantiated_field_rtypes def av.V.variant_id
- regions tys cgs
+ Assoc.type_decl_get_inst_norm_field_rtypes ctx def av.V.variant_id
+ generics
in
let fields_with_types =
List.combine av.V.field_values field_types
@@ -546,20 +548,28 @@ let check_typing_invariant (ctx : C.eval_ctx) : unit =
(fun ((v, ty) : V.typed_avalue * T.rty) -> assert (v.V.ty = ty))
fields_with_types
(* Tuple case *)
- | V.AAdt av, T.Adt (T.Tuple, regions, tys, cgs) ->
- assert (regions = []);
- assert (cgs = []);
+ | V.AAdt av, T.Adt (T.Tuple, generics) ->
+ assert (generics.regions = []);
+ assert (generics.const_generics = []);
assert (av.V.variant_id = None);
(* Check that the fields have the proper values - and check that there
* are as many fields as field types at the same time *)
- let fields_with_types = List.combine av.V.field_values tys in
+ let fields_with_types =
+ List.combine av.V.field_values generics.types
+ in
List.iter
(fun ((v, ty) : V.typed_avalue * T.rty) -> assert (v.V.ty = ty))
fields_with_types
(* Assumed type case *)
- | V.AAdt av, T.Adt (T.Assumed aty_id, regions, tys, cgs) -> (
+ | V.AAdt av, T.Adt (T.Assumed aty_id, generics) -> (
assert (av.V.variant_id = None);
- match (aty_id, av.V.field_values, regions, tys, cgs) with
+ match
+ ( aty_id,
+ av.V.field_values,
+ generics.regions,
+ generics.types,
+ generics.const_generics )
+ with
(* Box *)
| T.Box, [ boxed_value ], [], [ boxed_ty ], [] ->
assert (boxed_value.V.ty = boxed_ty)
diff --git a/compiler/LlbcAst.ml b/compiler/LlbcAst.ml
index f4d26e18..2db859b2 100644
--- a/compiler/LlbcAst.ml
+++ b/compiler/LlbcAst.ml
@@ -11,6 +11,7 @@ type abs_region_groups = (AbstractionId.id, RegionId.id) g_region_groups
(** A function signature, after instantiation *)
type inst_fun_sig = {
regions_hierarchy : abs_region_groups;
+ trait_type_constraints : rtrait_type_constraint list;
inputs : rty list;
output : rty;
}
diff --git a/compiler/LlbcAstUtils.ml b/compiler/LlbcAstUtils.ml
index 1111c297..0ab4ed94 100644
--- a/compiler/LlbcAstUtils.ml
+++ b/compiler/LlbcAstUtils.ml
@@ -5,10 +5,46 @@ let lookup_fun_sig (fun_id : fun_id) (fun_decls : fun_decl FunDeclId.Map.t) :
fun_sig =
match fun_id with
| Regular id -> (FunDeclId.Map.find id fun_decls).signature
- | Assumed aid -> Assumed.get_assumed_sig aid
+ | Assumed aid -> Assumed.get_assumed_fun_sig aid
let lookup_fun_name (fun_id : fun_id) (fun_decls : fun_decl FunDeclId.Map.t) :
Names.fun_name =
match fun_id with
| Regular id -> (FunDeclId.Map.find id fun_decls).name
- | Assumed aid -> Assumed.get_assumed_name aid
+ | Assumed aid -> Assumed.get_assumed_fun_name aid
+
+(** Return the opaque declarations found in the crate, which are also *not builtin*.
+
+ [filter_assumed]: if [true], do not consider as opaque the external definitions
+ that we will map to definitions from the standard library.
+
+ Remark: the list of functions also contains the list of opaque global bodies.
+ *)
+let crate_get_opaque_non_builtin_decls (k : crate) (filter_assumed : bool) :
+ T.type_decl list * fun_decl list =
+ let open ExtractBuiltin in
+ let is_opaque_fun (d : fun_decl) : bool =
+ let sname = name_to_simple_name d.name in
+ d.body = None
+ (* Something to pay attention to: we must ignore trait method *declarations*
+ (which don't have a body but must not be considered as opaque) *)
+ && (match d.kind with TraitMethodDecl _ -> false | _ -> true)
+ && ((not filter_assumed)
+ || (not (SimpleNameMap.mem sname builtin_globals_map))
+ && not (SimpleNameMap.mem sname (builtin_funs_map ())))
+ in
+ let is_opaque_type (d : T.type_decl) : bool =
+ let sname = name_to_simple_name d.name in
+ d.kind = T.Opaque
+ && ((not filter_assumed)
+ || not (SimpleNameMap.mem sname (builtin_types_map ())))
+ in
+ (* Note that by checking the function bodies we also the globals *)
+ ( List.filter is_opaque_type (T.TypeDeclId.Map.values k.types),
+ List.filter is_opaque_fun (FunDeclId.Map.values k.functions) )
+
+(** Return true if the crate contains opaque declarations, ignoring the assumed
+ definitions. *)
+let crate_has_opaque_non_builtin_decls (k : crate) (filter_assumed : bool) :
+ bool =
+ crate_get_opaque_non_builtin_decls k filter_assumed <> ([], [])
diff --git a/compiler/Logging.ml b/compiler/Logging.ml
index 9dc1f5e3..721655b8 100644
--- a/compiler/Logging.ml
+++ b/compiler/Logging.ml
@@ -9,6 +9,9 @@ let pre_passes_log = L.get_logger "MainLogger.PrePasses"
(** Logger for Translate *)
let translate_log = L.get_logger "MainLogger.Translate"
+(** Logger for Contexts *)
+let contexts_log = L.get_logger "MainLogger.Contexts"
+
(** Logger for PureUtils *)
let pure_utils_log = L.get_logger "MainLogger.PureUtils"
@@ -19,7 +22,7 @@ let symbolic_to_pure_log = L.get_logger "MainLogger.SymbolicToPure"
let pure_micro_passes_log = L.get_logger "MainLogger.PureMicroPasses"
(** Logger for ExtractBase *)
-let pure_to_extract_log = L.get_logger "MainLogger.ExtractBase"
+let extract_log = L.get_logger "MainLogger.ExtractBase"
(** Logger for Interpreter *)
let interpreter_log = L.get_logger "MainLogger.Interpreter"
@@ -57,6 +60,9 @@ let borrows_log = L.get_logger "MainLogger.Interpreter.Borrows"
(** Logger for Invariants *)
let invariants_log = L.get_logger "MainLogger.Interpreter.Invariants"
+(** Logger for AssociatedTypes *)
+let associated_types_log = L.get_logger "MainLogger.AssociatedTypes"
+
(** Logger for SCC *)
let scc_log = L.get_logger "MainLogger.Graph.SCC"
diff --git a/compiler/PrePasses.ml b/compiler/PrePasses.ml
index b348ba1d..ee06fa07 100644
--- a/compiler/PrePasses.ml
+++ b/compiler/PrePasses.ml
@@ -107,8 +107,8 @@ let remove_useless_cf_merges (crate : A.crate) (f : A.fun_decl) : A.fun_decl =
false
| Assign (_, rv) -> (
match rv with
- | Use _ | Ref _ -> not must_end_with_exit
- | Aggregate (AggregatedTuple, []) -> not must_end_with_exit
+ | Use _ | RvRef _ -> not must_end_with_exit
+ | Aggregate (AggregatedAdt (Tuple, _, _), []) -> not must_end_with_exit
| _ -> false)
| FakeRead _ | Drop _ | Nop -> not must_end_with_exit
| Panic | Return -> true
@@ -376,7 +376,7 @@ let remove_shallow_borrows (crate : A.crate) (f : A.fun_decl) : A.fun_decl =
method! visit_Assign env p rv =
match (p.projection, rv) with
- | [], E.Ref (_, E.Shallow) ->
+ | [], E.RvRef (_, E.Shallow) ->
(* Filter *)
filtered := E.VarId.Set.add p.var_id !filtered;
Nop
diff --git a/compiler/Print.ml b/compiler/Print.ml
index 9aa73d7c..7f0d95ff 100644
--- a/compiler/Print.ml
+++ b/compiler/Print.ml
@@ -21,6 +21,9 @@ module Values = struct
type_decl_id_to_string : T.TypeDeclId.id -> string;
const_generic_var_id_to_string : T.ConstGenericVarId.id -> string;
global_decl_id_to_string : T.GlobalDeclId.id -> string;
+ trait_decl_id_to_string : T.TraitDeclId.id -> string;
+ trait_impl_id_to_string : T.TraitImplId.id -> string;
+ trait_clause_id_to_string : T.TraitClauseId.id -> string;
adt_variant_to_string : T.TypeDeclId.id -> T.VariantId.id -> string;
var_id_to_string : E.VarId.id -> string;
adt_field_names :
@@ -34,6 +37,9 @@ module Values = struct
PT.type_decl_id_to_string = fmt.type_decl_id_to_string;
PT.const_generic_var_id_to_string = fmt.const_generic_var_id_to_string;
PT.global_decl_id_to_string = fmt.global_decl_id_to_string;
+ PT.trait_decl_id_to_string = fmt.trait_decl_id_to_string;
+ PT.trait_impl_id_to_string = fmt.trait_impl_id_to_string;
+ PT.trait_clause_id_to_string = fmt.trait_clause_id_to_string;
}
let value_to_rtype_formatter (fmt : value_formatter) : PT.rtype_formatter =
@@ -43,6 +49,9 @@ module Values = struct
PT.type_decl_id_to_string = fmt.type_decl_id_to_string;
PT.const_generic_var_id_to_string = fmt.const_generic_var_id_to_string;
PT.global_decl_id_to_string = fmt.global_decl_id_to_string;
+ PT.trait_decl_id_to_string = fmt.trait_decl_id_to_string;
+ PT.trait_impl_id_to_string = fmt.trait_impl_id_to_string;
+ PT.trait_clause_id_to_string = fmt.trait_clause_id_to_string;
}
let value_to_stype_formatter (fmt : value_formatter) : PT.stype_formatter =
@@ -52,6 +61,9 @@ module Values = struct
PT.type_decl_id_to_string = fmt.type_decl_id_to_string;
PT.const_generic_var_id_to_string = fmt.const_generic_var_id_to_string;
PT.global_decl_id_to_string = fmt.global_decl_id_to_string;
+ PT.trait_decl_id_to_string = fmt.trait_decl_id_to_string;
+ PT.trait_impl_id_to_string = fmt.trait_impl_id_to_string;
+ PT.trait_clause_id_to_string = fmt.trait_clause_id_to_string;
}
let var_id_to_string (id : E.VarId.id) : string =
@@ -86,10 +98,10 @@ module Values = struct
List.map (typed_value_to_string fmt) av.field_values
in
match v.ty with
- | T.Adt (T.Tuple, _, _, _) ->
+ | T.Adt (T.Tuple, _) ->
(* Tuple *)
"(" ^ String.concat ", " field_values ^ ")"
- | T.Adt (T.AdtId def_id, _, _, _) ->
+ | T.Adt (T.AdtId def_id, _) ->
(* "Regular" ADT *)
let adt_ident =
match av.variant_id with
@@ -111,21 +123,10 @@ module Values = struct
let field_values = String.concat " " field_values in
adt_ident ^ " { " ^ field_values ^ " }"
else adt_ident
- | T.Adt (T.Assumed aty, _, _, _) -> (
+ | T.Adt (T.Assumed aty, _) -> (
(* Assumed type *)
match (aty, field_values) with
| Box, [ bv ] -> "@Box(" ^ bv ^ ")"
- | Option, _ ->
- if av.variant_id = Some T.option_some_id then
- "@Option::Some("
- ^ Collections.List.to_cons_nil field_values
- ^ ")"
- else if av.variant_id = Some T.option_none_id then (
- assert (field_values = []);
- "@Option::None")
- else raise (Failure "Unreachable")
- | Range, _ -> "@Range{ " ^ String.concat ", " field_values ^ "}"
- | Vec, _ -> "@Vec[" ^ String.concat ", " field_values ^ "]"
| Array, _ ->
(* Happens when we aggregate values *)
"@Array[" ^ String.concat ", " field_values ^ "]"
@@ -201,10 +202,10 @@ module Values = struct
List.map (typed_avalue_to_string fmt) av.field_values
in
match v.ty with
- | T.Adt (T.Tuple, _, _, _) ->
+ | T.Adt (T.Tuple, _) ->
(* Tuple *)
"(" ^ String.concat ", " field_values ^ ")"
- | T.Adt (T.AdtId def_id, _, _, _) ->
+ | T.Adt (T.AdtId def_id, _) ->
(* "Regular" ADT *)
let adt_ident =
match av.variant_id with
@@ -226,7 +227,7 @@ module Values = struct
let field_values = String.concat " " field_values in
adt_ident ^ " { " ^ field_values ^ " }"
else adt_ident
- | T.Adt (T.Assumed aty, _, _, _) -> (
+ | T.Adt (T.Assumed aty, _) -> (
(* Assumed type *)
match (aty, field_values) with
| Box, [ bv ] -> "@Box(" ^ bv ^ ")"
@@ -347,6 +348,18 @@ module Values = struct
^ "}" ^ "{regions="
^ T.RegionId.Set.to_string None abs.regions
^ "}" ^ " {\n" ^ avs ^ "\n" ^ indent ^ "}"
+
+ let inst_fun_sig_to_string (fmt : value_formatter) (sg : LlbcAst.inst_fun_sig)
+ : string =
+ (* TODO: print the trait type constraints? *)
+ let ty_fmt = value_to_rtype_formatter fmt in
+ let ty_to_string = PT.ty_to_string ty_fmt in
+
+ let inputs =
+ "(" ^ String.concat ", " (List.map ty_to_string sg.inputs) ^ ")"
+ in
+ let output = ty_to_string sg.output in
+ inputs ^ " -> " ^ output
end
module PV = Values (* local module *)
@@ -452,6 +465,9 @@ module Contexts = struct
PV.adt_variant_to_string = fmt.adt_variant_to_string;
PV.var_id_to_string = fmt.var_id_to_string;
PV.adt_field_names = fmt.adt_field_names;
+ PV.trait_decl_id_to_string = fmt.trait_decl_id_to_string;
+ PV.trait_impl_id_to_string = fmt.trait_impl_id_to_string;
+ PV.trait_clause_id_to_string = fmt.trait_clause_id_to_string;
}
let ast_to_value_formatter (fmt : PA.ast_formatter) : PV.value_formatter =
@@ -463,20 +479,27 @@ module Contexts = struct
let ctx_to_rtype_formatter (fmt : ctx_formatter) : PT.rtype_formatter =
PV.value_to_rtype_formatter fmt
+ let ctx_to_stype_formatter (fmt : ctx_formatter) : PT.stype_formatter =
+ PV.value_to_stype_formatter fmt
+
let eval_ctx_to_ctx_formatter (ctx : C.eval_ctx) : ctx_formatter =
- (* We shouldn't use rvar_to_string *)
- let rvar_to_string _r =
- raise (Failure "Unexpected use of rvar_to_string")
+ let rvar_to_string r =
+ (* In theory we shouldn't use rvar_to_string, but it can happen
+ when printing definitions for instance... *)
+ T.RegionVarId.to_string r
in
let r_to_string r = PT.region_id_to_string r in
let type_var_id_to_string vid =
- let v = C.lookup_type_var ctx vid in
- v.name
+ (* The context may be invalid *)
+ match C.lookup_type_var_opt ctx vid with
+ | None -> T.TypeVarId.to_string vid
+ | Some v -> v.name
in
let const_generic_var_id_to_string vid =
- let v = C.lookup_const_generic_var ctx vid in
- v.name
+ match C.lookup_const_generic_var_opt ctx vid with
+ | None -> T.ConstGenericVarId.to_string vid
+ | Some v -> v.name
in
let type_decl_id_to_string def_id =
let def = C.ctx_lookup_type_decl ctx def_id in
@@ -486,6 +509,15 @@ module Contexts = struct
let def = C.ctx_lookup_global_decl ctx def_id in
name_to_string def.name
in
+ let trait_decl_id_to_string def_id =
+ let def = C.ctx_lookup_trait_decl ctx def_id in
+ name_to_string def.name
+ in
+ let trait_impl_id_to_string def_id =
+ let def = C.ctx_lookup_trait_impl ctx def_id in
+ name_to_string def.name
+ in
+ let trait_clause_id_to_string id = PT.trait_clause_id_to_pretty_string id in
let adt_variant_to_string =
PT.type_ctx_to_adt_variant_to_string_fun ctx.type_context.type_decls
in
@@ -506,6 +538,9 @@ module Contexts = struct
adt_variant_to_string;
var_id_to_string;
adt_field_names;
+ trait_decl_id_to_string;
+ trait_impl_id_to_string;
+ trait_clause_id_to_string;
}
let eval_ctx_to_ast_formatter (ctx : C.eval_ctx) : PA.ast_formatter =
@@ -521,6 +556,15 @@ module Contexts = struct
let def = C.ctx_lookup_global_decl ctx def_id in
global_name_to_string def.name
in
+ let trait_decl_id_to_string def_id =
+ let def = C.ctx_lookup_trait_decl ctx def_id in
+ name_to_string def.name
+ in
+ let trait_impl_id_to_string def_id =
+ let def = C.ctx_lookup_trait_impl ctx def_id in
+ name_to_string def.name
+ in
+ let trait_clause_id_to_string id = PT.trait_clause_id_to_pretty_string id in
{
rvar_to_string = ctx_fmt.PV.rvar_to_string;
r_to_string = ctx_fmt.PV.r_to_string;
@@ -533,6 +577,9 @@ module Contexts = struct
adt_field_to_string;
fun_decl_id_to_string;
global_decl_id_to_string;
+ trait_decl_id_to_string;
+ trait_impl_id_to_string;
+ trait_clause_id_to_string;
}
(** Split an [env] at every occurrence of [Frame], eliminating those elements.
@@ -608,6 +655,68 @@ module EvalCtxLlbcAst = struct
let fmt = PC.ctx_to_rtype_formatter fmt in
PT.rty_to_string fmt t
+ let sty_to_string (ctx : C.eval_ctx) (t : T.sty) : string =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_stype_formatter fmt in
+ PT.sty_to_string fmt t
+
+ let generic_params_to_strings (ctx : C.eval_ctx) (x : T.generic_params) :
+ string list * string list =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_stype_formatter fmt in
+ PT.generic_params_to_strings fmt x
+
+ let egeneric_args_to_string (ctx : C.eval_ctx) (x : T.egeneric_args) : string
+ =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_etype_formatter fmt in
+ PT.egeneric_args_to_string fmt x
+
+ let rgeneric_args_to_string (ctx : C.eval_ctx) (x : T.rgeneric_args) : string
+ =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_rtype_formatter fmt in
+ PT.rgeneric_args_to_string fmt x
+
+ let sgeneric_args_to_string (ctx : C.eval_ctx) (x : T.sgeneric_args) : string
+ =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_stype_formatter fmt in
+ PT.sgeneric_args_to_string fmt x
+
+ let etrait_ref_to_string (ctx : C.eval_ctx) (x : T.etrait_ref) : string =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_etype_formatter fmt in
+ PT.etrait_ref_to_string fmt x
+
+ let rtrait_ref_to_string (ctx : C.eval_ctx) (x : T.rtrait_ref) : string =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_rtype_formatter fmt in
+ PT.rtrait_ref_to_string fmt x
+
+ let strait_ref_to_string (ctx : C.eval_ctx) (x : T.strait_ref) : string =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_stype_formatter fmt in
+ PT.strait_ref_to_string fmt x
+
+ let etrait_instance_id_to_string (ctx : C.eval_ctx) (x : T.etrait_instance_id)
+ : string =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_etype_formatter fmt in
+ PT.etrait_instance_id_to_string fmt x
+
+ let rtrait_instance_id_to_string (ctx : C.eval_ctx) (x : T.rtrait_instance_id)
+ : string =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_rtype_formatter fmt in
+ PT.rtrait_instance_id_to_string fmt x
+
+ let strait_instance_id_to_string (ctx : C.eval_ctx) (x : T.strait_instance_id)
+ : string =
+ let fmt = PC.eval_ctx_to_ctx_formatter ctx in
+ let fmt = PC.ctx_to_stype_formatter fmt in
+ PT.strait_instance_id_to_string fmt x
+
let borrow_content_to_string (ctx : C.eval_ctx) (bc : V.borrow_content) :
string =
let fmt = PC.eval_ctx_to_ctx_formatter ctx in
@@ -653,11 +762,38 @@ module EvalCtxLlbcAst = struct
let fmt = PC.eval_ctx_to_ast_formatter ctx in
PE.operand_to_string fmt op
+ let call_to_string (ctx : C.eval_ctx) (call : A.call) : string =
+ let fmt = PC.eval_ctx_to_ast_formatter ctx in
+ PA.call_to_string fmt "" call
+
+ let fun_decl_to_string (ctx : C.eval_ctx) (f : A.fun_decl) : string =
+ let fmt = PC.eval_ctx_to_ast_formatter ctx in
+ PA.fun_decl_to_string fmt "" " " f
+
+ let fun_sig_to_string (ctx : C.eval_ctx) (x : A.fun_sig) : string =
+ let fmt = PC.eval_ctx_to_ast_formatter ctx in
+ PA.fun_sig_to_string fmt "" " " x
+
+ let inst_fun_sig_to_string (ctx : C.eval_ctx) (x : LlbcAst.inst_fun_sig) :
+ string =
+ let fmt = PC.eval_ctx_to_ast_formatter ctx in
+ let fmt = PC.ast_to_value_formatter fmt in
+ PV.inst_fun_sig_to_string fmt x
+
+ let fun_id_or_trait_method_ref_to_string (ctx : C.eval_ctx)
+ (x : E.fun_id_or_trait_method_ref) : string =
+ let fmt = PC.eval_ctx_to_ast_formatter ctx in
+ PE.fun_id_or_trait_method_ref_to_string fmt x "..."
+
let statement_to_string (ctx : C.eval_ctx) (indent : string)
(indent_incr : string) (e : A.statement) : string =
let fmt = PC.eval_ctx_to_ast_formatter ctx in
PA.statement_to_string fmt indent indent_incr e
+ let trait_impl_to_string (ctx : C.eval_ctx) (timpl : A.trait_impl) : string =
+ let fmt = PC.eval_ctx_to_ast_formatter ctx in
+ PA.trait_impl_to_string fmt " " " " timpl
+
let env_elem_to_string (ctx : C.eval_ctx) (indent : string)
(indent_incr : string) (ev : C.env_elem) : string =
let fmt = PC.eval_ctx_to_ctx_formatter ctx in
diff --git a/compiler/PrintPure.ml b/compiler/PrintPure.ml
index cfb63ec2..ec75fcfd 100644
--- a/compiler/PrintPure.ml
+++ b/compiler/PrintPure.ml
@@ -8,6 +8,9 @@ type type_formatter = {
type_decl_id_to_string : TypeDeclId.id -> string;
const_generic_var_id_to_string : ConstGenericVarId.id -> string;
global_decl_id_to_string : GlobalDeclId.id -> string;
+ trait_decl_id_to_string : TraitDeclId.id -> string;
+ trait_impl_id_to_string : TraitImplId.id -> string;
+ trait_clause_id_to_string : TraitClauseId.id -> string;
}
type value_formatter = {
@@ -18,6 +21,9 @@ type value_formatter = {
adt_variant_to_string : TypeDeclId.id -> VariantId.id -> string;
var_id_to_string : VarId.id -> string;
adt_field_names : TypeDeclId.id -> VariantId.id option -> string list option;
+ trait_decl_id_to_string : TraitDeclId.id -> string;
+ trait_impl_id_to_string : TraitImplId.id -> string;
+ trait_clause_id_to_string : TraitClauseId.id -> string;
}
let value_to_type_formatter (fmt : value_formatter) : type_formatter =
@@ -26,6 +32,9 @@ let value_to_type_formatter (fmt : value_formatter) : type_formatter =
type_decl_id_to_string = fmt.type_decl_id_to_string;
const_generic_var_id_to_string = fmt.const_generic_var_id_to_string;
global_decl_id_to_string = fmt.global_decl_id_to_string;
+ trait_decl_id_to_string = fmt.trait_decl_id_to_string;
+ trait_impl_id_to_string = fmt.trait_impl_id_to_string;
+ trait_clause_id_to_string = fmt.trait_clause_id_to_string;
}
(* TODO: we need to store which variables we have encountered so far, and
@@ -42,6 +51,9 @@ type ast_formatter = {
adt_field_names : TypeDeclId.id -> VariantId.id option -> string list option;
fun_decl_id_to_string : FunDeclId.id -> string;
global_decl_id_to_string : GlobalDeclId.id -> string;
+ trait_decl_id_to_string : TraitDeclId.id -> string;
+ trait_impl_id_to_string : TraitImplId.id -> string;
+ trait_clause_id_to_string : TraitClauseId.id -> string;
}
let ast_to_value_formatter (fmt : ast_formatter) : value_formatter =
@@ -53,6 +65,9 @@ let ast_to_value_formatter (fmt : ast_formatter) : value_formatter =
adt_variant_to_string = fmt.adt_variant_to_string;
var_id_to_string = fmt.var_id_to_string;
adt_field_names = fmt.adt_field_names;
+ trait_decl_id_to_string = fmt.trait_decl_id_to_string;
+ trait_impl_id_to_string = fmt.trait_impl_id_to_string;
+ trait_clause_id_to_string = fmt.trait_clause_id_to_string;
}
let ast_to_type_formatter (fmt : ast_formatter) : type_formatter =
@@ -70,31 +85,51 @@ let literal_type_to_string = Print.PrimitiveValues.literal_type_to_string
let scalar_value_to_string = Print.PrimitiveValues.scalar_value_to_string
let literal_to_string = Print.PrimitiveValues.literal_to_string
+(* Remark: not using generic_params on purpose, because we may use parameters
+ which either come from LLBC or from pure, and the [generic_params] type
+ for those ASTs is not the same. Note that it works because we actually don't
+ need to know the trait clauses to print the AST: we can thus ignore them.
+*)
let mk_type_formatter (type_decls : T.type_decl TypeDeclId.Map.t)
(global_decls : A.global_decl GlobalDeclId.Map.t)
- (type_params : type_var list)
+ (trait_decls : A.trait_decl TraitDeclId.Map.t)
+ (trait_impls : A.trait_impl TraitImplId.Map.t) (type_params : type_var list)
(const_generic_params : const_generic_var list) : type_formatter =
let type_var_id_to_string vid =
- let var = T.TypeVarId.nth type_params vid in
+ let var = TypeVarId.nth type_params vid in
type_var_to_string var
in
let const_generic_var_id_to_string vid =
- let var = T.ConstGenericVarId.nth const_generic_params vid in
+ let var = ConstGenericVarId.nth const_generic_params vid in
const_generic_var_to_string var
in
let type_decl_id_to_string def_id =
- let def = T.TypeDeclId.Map.find def_id type_decls in
+ let def = TypeDeclId.Map.find def_id type_decls in
name_to_string def.name
in
let global_decl_id_to_string def_id =
- let def = T.GlobalDeclId.Map.find def_id global_decls in
+ let def = GlobalDeclId.Map.find def_id global_decls in
+ name_to_string def.name
+ in
+ let trait_decl_id_to_string def_id =
+ let def = TraitDeclId.Map.find def_id trait_decls in
+ name_to_string def.name
+ in
+ let trait_impl_id_to_string def_id =
+ let def = TraitImplId.Map.find def_id trait_impls in
name_to_string def.name
in
+ let trait_clause_id_to_string id =
+ Print.PT.trait_clause_id_to_pretty_string id
+ in
{
type_var_id_to_string;
type_decl_id_to_string;
const_generic_var_id_to_string;
global_decl_id_to_string;
+ trait_decl_id_to_string;
+ trait_impl_id_to_string;
+ trait_clause_id_to_string;
}
(* TODO: there is a bit of duplication with Print.fun_decl_to_ast_formatter.
@@ -106,19 +141,21 @@ let mk_type_formatter (type_decls : T.type_decl TypeDeclId.Map.t)
let mk_ast_formatter (type_decls : T.type_decl TypeDeclId.Map.t)
(fun_decls : A.fun_decl FunDeclId.Map.t)
(global_decls : A.global_decl GlobalDeclId.Map.t)
- (type_params : type_var list)
+ (trait_decls : A.trait_decl TraitDeclId.Map.t)
+ (trait_impls : A.trait_impl TraitImplId.Map.t) (type_params : type_var list)
(const_generic_params : const_generic_var list) : ast_formatter =
- let type_var_id_to_string vid =
- let var = T.TypeVarId.nth type_params vid in
- type_var_to_string var
- in
- let const_generic_var_id_to_string vid =
- let var = T.ConstGenericVarId.nth const_generic_params vid in
- const_generic_var_to_string var
- in
- let type_decl_id_to_string def_id =
- let def = T.TypeDeclId.Map.find def_id type_decls in
- name_to_string def.name
+ let ({
+ type_var_id_to_string;
+ type_decl_id_to_string;
+ const_generic_var_id_to_string;
+ global_decl_id_to_string;
+ trait_decl_id_to_string;
+ trait_impl_id_to_string;
+ trait_clause_id_to_string;
+ }
+ : type_formatter) =
+ mk_type_formatter type_decls global_decls trait_decls trait_impls
+ type_params const_generic_params
in
let adt_variant_to_string =
Print.Types.type_ctx_to_adt_variant_to_string_fun type_decls
@@ -137,10 +174,6 @@ let mk_ast_formatter (type_decls : T.type_decl TypeDeclId.Map.t)
let def = FunDeclId.Map.find def_id fun_decls in
fun_name_to_string def.name
in
- let global_decl_id_to_string def_id =
- let def = GlobalDeclId.Map.find def_id global_decls in
- global_name_to_string def.name
- in
{
type_var_id_to_string;
const_generic_var_id_to_string;
@@ -151,6 +184,9 @@ let mk_ast_formatter (type_decls : T.type_decl TypeDeclId.Map.t)
adt_field_to_string;
fun_decl_id_to_string;
global_decl_id_to_string;
+ trait_decl_id_to_string;
+ trait_impl_id_to_string;
+ trait_clause_id_to_string;
}
let assumed_ty_to_string (aty : assumed_ty) : string =
@@ -159,12 +195,11 @@ let assumed_ty_to_string (aty : assumed_ty) : string =
| Result -> "Result"
| Error -> "Error"
| Fuel -> "Fuel"
- | Option -> "Option"
- | Vec -> "Vec"
| Array -> "Array"
| Slice -> "Slice"
| Str -> "Str"
- | Range -> "Range"
+ | RawPtr Mut -> "MutRawPtr"
+ | RawPtr Const -> "ConstRawPtr"
let type_id_to_string (fmt : type_formatter) (id : type_id) : string =
match id with
@@ -182,20 +217,18 @@ let const_generic_to_string (fmt : type_formatter) (cg : T.const_generic) :
let rec ty_to_string (fmt : type_formatter) (inside : bool) (ty : ty) : string =
match ty with
- | Adt (id, tys, cgs) -> (
- let tys = List.map (ty_to_string fmt false) tys in
- let cgs = List.map (const_generic_to_string fmt) cgs in
- let params = List.append tys cgs in
+ | Adt (id, generics) -> (
match id with
| Tuple ->
- assert (cgs = []);
- "(" ^ String.concat " * " tys ^ ")"
+ let generics = generic_args_to_strings fmt false generics in
+ "(" ^ String.concat " * " generics ^ ")"
| AdtId _ | Assumed _ ->
- let params_s =
- if params = [] then "" else " " ^ String.concat " " params
+ let generics = generic_args_to_strings fmt true generics in
+ let generics_s =
+ if generics = [] then "" else " " ^ String.concat " " generics
in
- let ty_s = type_id_to_string fmt id ^ params_s in
- if params <> [] && inside then "(" ^ ty_s ^ ")" else ty_s)
+ let ty_s = type_id_to_string fmt id ^ generics_s in
+ if generics <> [] && inside then "(" ^ ty_s ^ ")" else ty_s)
| TypeVar tv -> fmt.type_var_id_to_string tv
| Literal lty -> literal_type_to_string lty
| Arrow (arg_ty, ret_ty) ->
@@ -203,6 +236,71 @@ let rec ty_to_string (fmt : type_formatter) (inside : bool) (ty : ty) : string =
ty_to_string fmt true arg_ty ^ " -> " ^ ty_to_string fmt false ret_ty
in
if inside then "(" ^ ty ^ ")" else ty
+ | TraitType (trait_ref, generics, type_name) ->
+ let trait_ref = trait_ref_to_string fmt false trait_ref in
+ let s =
+ if generics = empty_generic_args then trait_ref ^ "::" ^ type_name
+ else
+ let generics = generic_args_to_string fmt generics in
+ "(" ^ trait_ref ^ " " ^ generics ^ ")::" ^ type_name
+ in
+ if inside then "(" ^ s ^ ")" else s
+
+and generic_args_to_strings (fmt : type_formatter) (inside : bool)
+ (generics : generic_args) : string list =
+ let tys = List.map (ty_to_string fmt inside) generics.types in
+ let cgs = List.map (const_generic_to_string fmt) generics.const_generics in
+ let trait_refs =
+ List.map (trait_ref_to_string fmt inside) generics.trait_refs
+ in
+ List.concat [ tys; cgs; trait_refs ]
+
+and generic_args_to_string (fmt : type_formatter) (generics : generic_args) :
+ string =
+ String.concat " " (generic_args_to_strings fmt true generics)
+
+and trait_ref_to_string (fmt : type_formatter) (inside : bool) (tr : trait_ref)
+ : string =
+ let trait_id = trait_instance_id_to_string fmt false tr.trait_id in
+ let generics = generic_args_to_string fmt tr.generics in
+ let s = trait_id ^ generics in
+ if tr.generics = empty_generic_args || not inside then s else "(" ^ s ^ ")"
+
+and trait_instance_id_to_string (fmt : type_formatter) (inside : bool)
+ (id : trait_instance_id) : string =
+ match id with
+ | Self -> "Self"
+ | TraitImpl id -> fmt.trait_impl_id_to_string id
+ | Clause id -> fmt.trait_clause_id_to_string id
+ | ParentClause (inst_id, _decl_id, clause_id) ->
+ let inst_id = trait_instance_id_to_string fmt false inst_id in
+ let clause_id = fmt.trait_clause_id_to_string clause_id in
+ "parent(" ^ inst_id ^ ")::" ^ clause_id
+ | ItemClause (inst_id, _decl_id, item_name, clause_id) ->
+ let inst_id = trait_instance_id_to_string fmt false inst_id in
+ let clause_id = fmt.trait_clause_id_to_string clause_id in
+ "(" ^ inst_id ^ ")::" ^ item_name ^ "::[" ^ clause_id ^ "]"
+ | TraitRef tr -> trait_ref_to_string fmt inside tr
+ | UnknownTrait msg -> "UNKNOWN(" ^ msg ^ ")"
+
+let trait_clause_to_string (fmt : type_formatter) (clause : trait_clause) :
+ string =
+ let clause_id = fmt.trait_clause_id_to_string clause.clause_id in
+ let trait_id = fmt.trait_decl_id_to_string clause.trait_id in
+ let generics = generic_args_to_strings fmt true clause.generics in
+ let generics =
+ if generics = [] then "" else " " ^ String.concat " " generics
+ in
+ "[" ^ clause_id ^ "]: " ^ trait_id ^ generics
+
+let generic_params_to_strings (fmt : type_formatter) (generics : generic_params)
+ : string list =
+ let tys = List.map type_var_to_string generics.types in
+ let cgs = List.map const_generic_var_to_string generics.const_generics in
+ let trait_clauses =
+ List.map (trait_clause_to_string fmt) generics.trait_clauses
+ in
+ List.concat [ tys; cgs; trait_clauses ]
let field_to_string fmt inside (f : field) : string =
match f.field_name with
@@ -217,11 +315,10 @@ let variant_to_string fmt (v : variant) : string =
^ ")"
let type_decl_to_string (fmt : type_formatter) (def : type_decl) : string =
- let types = def.type_params in
let name = name_to_string def.name in
let params =
- if types = [] then ""
- else " " ^ String.concat " " (List.map type_var_to_string types)
+ if def.generics = empty_generic_params then ""
+ else " " ^ String.concat " " (generic_params_to_strings fmt def.generics)
in
match def.kind with
| Struct fields ->
@@ -256,10 +353,6 @@ let rec mprojection_to_string (fmt : ast_formatter) (inside : string)
| pe :: p' -> (
let s = mprojection_to_string fmt inside p' in
match pe.pkind with
- | E.ProjOption variant_id ->
- assert (variant_id = T.option_some_id);
- assert (pe.field_id = T.FieldId.zero);
- "(" ^ s ^ "as Option::Some)." ^ T.FieldId.to_string pe.field_id
| E.ProjTuple _ -> "(" ^ s ^ ")." ^ T.FieldId.to_string pe.field_id
| E.ProjAdt (adt_id, opt_variant_id) -> (
let field_name =
@@ -294,11 +387,9 @@ let adt_variant_to_string (fmt : value_formatter) (adt_id : type_id)
| Assumed aty -> (
(* Assumed type *)
match aty with
- | State | Array | Slice | Str ->
+ | State | Array | Slice | Str | RawPtr _ ->
(* Those types are opaque: we can't get there *)
raise (Failure "Unreachable")
- | Vec -> "@Vec"
- | Range -> "@Range"
| Result ->
let variant_id = Option.get variant_id in
if variant_id = result_return_id then "@Result::Return"
@@ -314,13 +405,7 @@ let adt_variant_to_string (fmt : value_formatter) (adt_id : type_id)
let variant_id = Option.get variant_id in
if variant_id = fuel_zero_id then "@Fuel::Zero"
else if variant_id = fuel_succ_id then "@Fuel::Succ"
- else raise (Failure "Unreachable: improper variant id for fuel type")
- | Option ->
- let variant_id = Option.get variant_id in
- if variant_id = option_some_id then "@Option::Some "
- else if variant_id = option_none_id then "@Option::None"
- else
- raise (Failure "Unreachable: improper variant id for result type"))
+ else raise (Failure "Unreachable: improper variant id for fuel type"))
let adt_field_to_string (fmt : value_formatter) (adt_id : type_id)
(field_id : FieldId.id) : string =
@@ -337,11 +422,10 @@ let adt_field_to_string (fmt : value_formatter) (adt_id : type_id)
| Assumed aty -> (
(* Assumed type *)
match aty with
- | Range -> FieldId.to_string field_id
- | State | Fuel | Vec | Array | Slice | Str ->
+ | State | Fuel | Array | Slice | Str ->
(* Opaque types: we can't get there *)
raise (Failure "Unreachable")
- | Result | Error | Option ->
+ | Result | Error | RawPtr _ ->
(* Enumerations: we can't get there *)
raise (Failure "Unreachable"))
@@ -353,10 +437,10 @@ let adt_g_value_to_string (fmt : value_formatter)
(field_values : 'v list) (ty : ty) : string =
let field_values = List.map value_to_string field_values in
match ty with
- | Adt (Tuple, _, _) ->
+ | Adt (Tuple, _) ->
(* Tuple *)
"(" ^ String.concat ", " field_values ^ ")"
- | Adt (AdtId def_id, _, _) ->
+ | Adt (AdtId def_id, _) ->
(* "Regular" ADT *)
let adt_ident =
match variant_id with
@@ -378,10 +462,10 @@ let adt_g_value_to_string (fmt : value_formatter)
let field_values = String.concat " " field_values in
adt_ident ^ " { " ^ field_values ^ " }"
else adt_ident
- | Adt (Assumed aty, _, _) -> (
+ | Adt (Assumed aty, _) -> (
(* Assumed type *)
match aty with
- | State ->
+ | State | RawPtr _ ->
(* This type is opaque: we can't get there *)
raise (Failure "Unreachable")
| Result ->
@@ -412,31 +496,13 @@ let adt_g_value_to_string (fmt : value_formatter)
| [ v ] -> "@Fuel::Succ " ^ v
| _ -> raise (Failure "@Fuel::Succ takes exactly one value")
else raise (Failure "Unreachable: improper variant id for fuel type")
- | Option ->
- let variant_id = Option.get variant_id in
- if variant_id = option_some_id then
- match field_values with
- | [ v ] -> "@Option::Some " ^ v
- | _ -> raise (Failure "Option::Some takes exactly one value")
- else if variant_id = option_none_id then (
- assert (field_values = []);
- "@Option::None")
- else
- raise (Failure "Unreachable: improper variant id for result type")
- | Vec | Array | Slice | Str ->
+ | Array | Slice | Str ->
assert (variant_id = None);
let field_values =
List.mapi (fun i v -> string_of_int i ^ " -> " ^ v) field_values
in
let id = assumed_ty_to_string aty in
- id ^ " [" ^ String.concat "; " field_values ^ "]"
- | Range ->
- assert (variant_id = None);
- let field_values =
- List.mapi (fun i v -> string_of_int i ^ " -> " ^ v) field_values
- in
- let id = assumed_ty_to_string aty in
- id ^ " {" ^ String.concat "; " field_values ^ "}")
+ id ^ " [" ^ String.concat "; " field_values ^ "]")
| _ ->
let fmt = value_to_type_formatter fmt in
raise
@@ -464,10 +530,10 @@ let rec typed_pattern_to_string (fmt : ast_formatter) (v : typed_pattern) :
let fun_sig_to_string (fmt : ast_formatter) (sg : fun_sig) : string =
let ty_fmt = ast_to_type_formatter fmt in
- let type_params = List.map type_var_to_string sg.type_params in
+ let generics = generic_params_to_strings ty_fmt sg.generics in
let inputs = List.map (ty_to_string ty_fmt false) sg.inputs in
let output = ty_to_string ty_fmt false sg.output in
- let all_types = List.concat [ type_params; inputs; [ output ] ] in
+ let all_types = List.concat [ generics; inputs; [ output ] ] in
String.concat " -> " all_types
let inst_fun_sig_to_string (fmt : ast_formatter) (sg : inst_fun_sig) : string =
@@ -495,28 +561,16 @@ let fun_suffix (lp_id : LoopId.id option) (rg_id : T.RegionGroupId.id option) :
let llbc_assumed_fun_id_to_string (fid : A.assumed_fun_id) : string =
match fid with
- | A.Replace -> "core::mem::replace"
- | A.BoxNew -> "alloc::boxed::Box::new"
- | A.BoxDeref -> "core::ops::deref::Deref::deref"
- | A.BoxDerefMut -> "core::ops::deref::DerefMut::deref_mut"
- | A.BoxFree -> "alloc::alloc::box_free"
- | A.VecNew -> "alloc::vec::Vec::new"
- | A.VecPush -> "alloc::vec::Vec::push"
- | A.VecInsert -> "alloc::vec::Vec::insert"
- | A.VecLen -> "alloc::vec::Vec::len"
- | A.VecIndex -> "core::ops::index::Index<alloc::vec::Vec>::index"
- | A.VecIndexMut -> "core::ops::index::IndexMut<alloc::vec::Vec>::index_mut"
+ | BoxNew -> "alloc::boxed::Box::new"
+ | BoxFree -> "alloc::alloc::box_free"
| ArrayIndexShared -> "@ArrayIndexShared"
| ArrayIndexMut -> "@ArrayIndexMut"
| ArrayToSliceShared -> "@ArrayToSliceShared"
| ArrayToSliceMut -> "@ArrayToSliceMut"
- | ArraySubsliceShared -> "@ArraySubsliceShared"
- | ArraySubsliceMut -> "@ArraySubsliceMut"
+ | ArrayRepeat -> "@ArrayRepeat"
| SliceLen -> "@SliceLen"
| SliceIndexShared -> "@SliceIndexShared"
| SliceIndexMut -> "@SliceIndexMut"
- | SliceSubsliceShared -> "@SliceSubsliceShared"
- | SliceSubsliceMut -> "@SliceSubsliceMut"
let pure_assumed_fun_id_to_string (fid : pure_assumed_fun_id) : string =
match fid with
@@ -531,8 +585,11 @@ let regular_fun_id_to_string (fmt : ast_formatter) (fun_id : fun_id) : string =
| FromLlbc (fid, lp_id, rg_id) ->
let f =
match fid with
- | Regular fid -> fmt.fun_decl_id_to_string fid
- | Assumed fid -> llbc_assumed_fun_id_to_string fid
+ | FunId (Regular fid) -> fmt.fun_decl_id_to_string fid
+ | FunId (Assumed fid) -> llbc_assumed_fun_id_to_string fid
+ | TraitMethod (trait_ref, method_name, _) ->
+ let fmt = ast_to_type_formatter fmt in
+ trait_ref_to_string fmt true trait_ref ^ "." ^ method_name
in
f ^ fun_suffix lp_id rg_id
| Pure fid -> pure_assumed_fun_id_to_string fid
@@ -559,9 +616,8 @@ let fun_or_op_id_to_string (fmt : ast_formatter) (fun_id : fun_or_op_id) :
let rec texpression_to_string (fmt : ast_formatter) (inside : bool)
(indent : string) (indent_incr : string) (e : texpression) : string =
match e.e with
- | Var var_id ->
- let s = fmt.var_id_to_string var_id in
- if inside then "(" ^ s ^ ")" else s
+ | Var var_id -> fmt.var_id_to_string var_id
+ | CVar cg_id -> fmt.const_generic_var_id_to_string cg_id
| Const cv -> literal_to_string cv
| App _ ->
(* Recursively destruct the app, to have a pair (app, arguments list) *)
@@ -632,10 +688,11 @@ and app_to_string (fmt : ast_formatter) (inside : bool) (indent : string)
(* There are two possibilities: either the [app] is an instantiated,
* top-level qualifier (function, ADT constructore...), or it is a "regular"
* expression *)
- let app, tys =
+ let app, generics =
match app.e with
| Qualif qualif ->
(* Qualifier case *)
+ let ty_fmt = ast_to_type_formatter fmt in
(* Convert the qualifier identifier *)
let qualif_s =
match qualif.id with
@@ -654,12 +711,17 @@ and app_to_string (fmt : ast_formatter) (inside : bool) (indent : string)
let field_s = adt_field_to_string value_fmt adt_id field_id in
(* Adopting an F*-like syntax *)
ConstStrings.constructor_prefix ^ adt_s ^ "?." ^ field_s
+ | TraitConst (trait_ref, generics, const_name) ->
+ let trait_ref = trait_ref_to_string ty_fmt true trait_ref in
+ let generics_s = generic_args_to_string ty_fmt generics in
+ if generics <> empty_generic_args then
+ "(" ^ trait_ref ^ generics_s ^ ")." ^ const_name
+ else trait_ref ^ "." ^ const_name
in
(* Convert the type instantiation *)
- let ty_fmt = ast_to_type_formatter fmt in
- let tys = List.map (ty_to_string ty_fmt true) qualif.type_args in
+ let generics = generic_args_to_strings ty_fmt true qualif.generics in
(* *)
- (qualif_s, tys)
+ (qualif_s, generics)
| _ ->
(* "Regular" expression case *)
let inside = args <> [] || (args = [] && inside) in
@@ -674,7 +736,7 @@ and app_to_string (fmt : ast_formatter) (inside : bool) (indent : string)
texpression_to_string fmt inside indent1 indent_incr
in
let args = List.map arg_to_string args in
- let all_args = List.append tys args in
+ let all_args = List.append generics args in
(* Put together *)
let e =
if all_args = [] then app else app ^ " " ^ String.concat " " all_args
diff --git a/compiler/Pure.ml b/compiler/Pure.ml
index ac4ca081..e6a3dab5 100644
--- a/compiler/Pure.ml
+++ b/compiler/Pure.ml
@@ -13,6 +13,9 @@ module FieldId = T.FieldId
module SymbolicValueId = V.SymbolicValueId
module FunDeclId = A.FunDeclId
module GlobalDeclId = A.GlobalDeclId
+module TraitDeclId = T.TraitDeclId
+module TraitImplId = T.TraitImplId
+module TraitClauseId = T.TraitClauseId
(** We redefine identifiers for loop: in {!Values}, the identifiers are global
(they monotonically increase across functions) while in {!module:Pure} we want
@@ -21,8 +24,6 @@ module GlobalDeclId = A.GlobalDeclId
module LoopId =
IdGen ()
-type loop_id = LoopId.id [@@deriving show, ord]
-
(** We give an identifier to every phase of the synthesis (forward, backward
for group of regions 0, etc.) *)
module SynthPhaseId =
@@ -37,6 +38,16 @@ module ConstGenericVarId = T.ConstGenericVarId
type integer_type = T.integer_type [@@deriving show, ord]
type const_generic_var = T.const_generic_var [@@deriving show, ord]
type const_generic = T.const_generic [@@deriving show, ord]
+type const_generic_var_id = T.const_generic_var_id [@@deriving show, ord]
+type trait_decl_id = T.trait_decl_id [@@deriving show, ord]
+type trait_impl_id = T.trait_impl_id [@@deriving show, ord]
+type trait_clause_id = T.trait_clause_id [@@deriving show, ord]
+type trait_item_name = T.trait_item_name [@@deriving show, ord]
+type global_decl_id = T.global_decl_id [@@deriving show, ord]
+type fun_decl_id = A.fun_decl_id [@@deriving show, ord]
+type loop_id = LoopId.id [@@deriving show, ord]
+type region_group_id = T.region_group_id [@@deriving show, ord]
+type mutability = Mut | Const [@@deriving show, ord]
(** The assumed types for the pure AST.
@@ -59,12 +70,17 @@ type assumed_ty =
| Result
| Error
| Fuel
- | Vec
- | Option
| Array
| Slice
| Str
- | Range
+ | RawPtr of mutability
+ (** The bool
+ Raw pointers don't make sense in the pure world, but we don't know
+ how to translate them yet and we have to handle some functions which
+ use raw pointers in their signature (for instance some trait declarations
+ for the slices). For now, we use a dedicated type to "mark" the raw pointers,
+ and make sure that those functions are actually not used in the translation.
+ *)
[@@deriving show, ord]
(* TODO: we should never directly manipulate [Return] and [Fail], but rather
@@ -176,6 +192,14 @@ class ['self] iter_ty_base =
inherit! [_] T.iter_const_generic
inherit! [_] PV.iter_literal_type
method visit_type_var_id : 'env -> type_var_id -> unit = fun _ _ -> ()
+ method visit_trait_decl_id : 'env -> trait_decl_id -> unit = fun _ _ -> ()
+ method visit_trait_impl_id : 'env -> trait_impl_id -> unit = fun _ _ -> ()
+
+ method visit_trait_clause_id : 'env -> trait_clause_id -> unit =
+ fun _ _ -> ()
+
+ method visit_trait_item_name : 'env -> trait_item_name -> unit =
+ fun _ _ -> ()
end
(** Ancestor for map visitor for [ty] *)
@@ -185,6 +209,18 @@ class ['self] map_ty_base =
inherit! [_] T.map_const_generic
inherit! [_] PV.map_literal_type
method visit_type_var_id : 'env -> type_var_id -> type_var_id = fun _ x -> x
+
+ method visit_trait_decl_id : 'env -> trait_decl_id -> trait_decl_id =
+ fun _ x -> x
+
+ method visit_trait_impl_id : 'env -> trait_impl_id -> trait_impl_id =
+ fun _ x -> x
+
+ method visit_trait_clause_id : 'env -> trait_clause_id -> trait_clause_id =
+ fun _ x -> x
+
+ method visit_trait_item_name : 'env -> trait_item_name -> trait_item_name =
+ fun _ x -> x
end
(** Ancestor for reduce visitor for [ty] *)
@@ -194,6 +230,18 @@ class virtual ['self] reduce_ty_base =
inherit! [_] T.reduce_const_generic
inherit! [_] PV.reduce_literal_type
method visit_type_var_id : 'env -> type_var_id -> 'a = fun _ _ -> self#zero
+
+ method visit_trait_decl_id : 'env -> trait_decl_id -> 'a =
+ fun _ _ -> self#zero
+
+ method visit_trait_impl_id : 'env -> trait_impl_id -> 'a =
+ fun _ _ -> self#zero
+
+ method visit_trait_clause_id : 'env -> trait_clause_id -> 'a =
+ fun _ _ -> self#zero
+
+ method visit_trait_item_name : 'env -> trait_item_name -> 'a =
+ fun _ _ -> self#zero
end
(** Ancestor for mapreduce visitor for [ty] *)
@@ -205,10 +253,24 @@ class virtual ['self] mapreduce_ty_base =
method visit_type_var_id : 'env -> type_var_id -> type_var_id * 'a =
fun _ x -> (x, self#zero)
+
+ method visit_trait_decl_id : 'env -> trait_decl_id -> trait_decl_id * 'a =
+ fun _ x -> (x, self#zero)
+
+ method visit_trait_impl_id : 'env -> trait_impl_id -> trait_impl_id * 'a =
+ fun _ x -> (x, self#zero)
+
+ method visit_trait_clause_id
+ : 'env -> trait_clause_id -> trait_clause_id * 'a =
+ fun _ x -> (x, self#zero)
+
+ method visit_trait_item_name
+ : 'env -> trait_item_name -> trait_item_name * 'a =
+ fun _ x -> (x, self#zero)
end
type ty =
- | Adt of type_id * ty list * const_generic list
+ | Adt of type_id * generic_args
(** {!Adt} encodes ADTs and tuples and assumed types.
TODO: what about the ended regions? (ADTs may be parameterized
@@ -219,8 +281,38 @@ type ty =
| TypeVar of type_var_id
| Literal of literal_type
| Arrow of ty * ty
+ | TraitType of trait_ref * generic_args * string
+ (** The string is for the name of the associated type *)
+
+and trait_ref = {
+ trait_id : trait_instance_id;
+ generics : generic_args;
+ trait_decl_ref : trait_decl_ref;
+}
+
+and trait_decl_ref = {
+ trait_decl_id : trait_decl_id;
+ decl_generics : generic_args; (* The name: annoying field collisions... *)
+}
+
+and generic_args = {
+ types : ty list;
+ const_generics : const_generic list;
+ trait_refs : trait_ref list;
+}
+
+and trait_instance_id =
+ | Self
+ | TraitImpl of trait_impl_id
+ | Clause of trait_clause_id
+ | ParentClause of trait_instance_id * trait_decl_id * trait_clause_id
+ | ItemClause of
+ trait_instance_id * trait_decl_id * trait_item_name * trait_clause_id
+ | TraitRef of trait_ref
+ | UnknownTrait of string
[@@deriving
show,
+ ord,
visitors
{
name = "iter_ty";
@@ -264,12 +356,37 @@ type type_decl_kind = Struct of field list | Enum of variant list | Opaque
type type_var = T.type_var [@@deriving show]
+type trait_clause = {
+ clause_id : trait_clause_id;
+ trait_id : trait_decl_id;
+ generics : generic_args;
+}
+[@@deriving show]
+
+type generic_params = {
+ types : type_var list;
+ const_generics : const_generic_var list;
+ trait_clauses : trait_clause list;
+}
+[@@deriving show]
+
+type trait_type_constraint = {
+ trait_ref : trait_ref;
+ generics : generic_args;
+ type_name : trait_item_name;
+ ty : ty;
+}
+[@@deriving show, ord]
+
+type predicates = { trait_type_constraints : trait_type_constraint list }
+[@@deriving show]
+
type type_decl = {
def_id : TypeDeclId.id;
name : name;
- type_params : type_var list;
- const_generic_params : const_generic_var list;
+ generics : generic_params;
kind : type_decl_kind;
+ preds : predicates;
}
[@@deriving show]
@@ -420,8 +537,15 @@ type pure_assumed_fun_id =
| FuelEqZero (** Test if some fuel is equal to 0 - TODO: ugly *)
[@@deriving show, ord]
+type fun_id_or_trait_method_ref =
+ | FunId of A.fun_id
+ | TraitMethod of trait_ref * string * fun_decl_id
+ (** The fun decl id is not really needed and here for convenience purposes *)
+[@@deriving show, ord]
+
(** A function id for a non-assumed function *)
-type regular_fun_id = A.fun_id * LoopId.id option * T.RegionGroupId.id option
+type regular_fun_id =
+ fun_id_or_trait_method_ref * LoopId.id option * T.RegionGroupId.id option
[@@deriving show, ord]
(** A function identifier *)
@@ -457,23 +581,20 @@ type projection = { adt_id : type_id; field_id : FieldId.id } [@@deriving show]
type qualif_id =
| FunOrOp of fun_or_op_id (** A function or an operation *)
- | Global of GlobalDeclId.id
+ | Global of global_decl_id
| AdtCons of adt_cons_id (** A function or ADT constructor identifier *)
| Proj of projection (** Field projector *)
+ | TraitConst of trait_ref * generic_args * string
+ (** A trait associated constant *)
[@@deriving show]
-(** An instantiated qualified.
+(** An instantiated qualifier.
Note that for now we have a clear separation between types and expressions,
- which explains why we have the [type_params] field: a function or ADT
+ which explains why we have the [generics] field: a function or ADT
constructor is always fully instantiated.
*)
-type qualif = {
- id : qualif_id;
- type_args : ty list;
- const_generic_args : const_generic list;
-}
-[@@deriving show]
+type qualif = { id : qualif_id; generics : generic_args } [@@deriving show]
type field_id = FieldId.id [@@deriving show, ord]
type var_id = VarId.id [@@deriving show, ord]
@@ -536,6 +657,7 @@ class virtual ['self] mapreduce_expression_base =
*)
type expression =
| Var of var_id (** a variable *)
+ | CVar of const_generic_var_id (** a const generic var *)
| Const of literal
| App of texpression * texpression
(** Application of a function to an argument.
@@ -787,11 +909,11 @@ type fun_sig_info = {
- etc.
*)
type fun_sig = {
- type_params : type_var list;
- const_generic_params : const_generic_var list;
+ generics : generic_params;
(** TODO: we should analyse the signature to make the type parameters implicit whenever possible *)
+ preds : predicates;
inputs : ty list;
- (** The input types.
+ (** The types of the inputs.
Note that those input types take into account the [fuel] parameter,
if the function uses fuel for termination, and the [state] parameter,
@@ -861,8 +983,11 @@ type fun_body = {
}
[@@deriving show]
+type fun_kind = A.fun_kind [@@deriving show]
+
type fun_decl = {
def_id : FunDeclId.id;
+ kind : fun_kind;
num_loops : int;
(** The number of loops in the parent forward function (basically the number
of loops appearing in the original Rust functions, unless some loops are
@@ -882,3 +1007,30 @@ type fun_decl = {
body : fun_body option;
}
[@@deriving show]
+
+type trait_decl = {
+ def_id : trait_decl_id;
+ name : name;
+ generics : generic_params;
+ preds : predicates;
+ parent_clauses : trait_clause list;
+ consts : (trait_item_name * (ty * global_decl_id option)) list;
+ types : (trait_item_name * (trait_clause list * ty option)) list;
+ required_methods : (trait_item_name * fun_decl_id) list;
+ provided_methods : (trait_item_name * fun_decl_id option) list;
+}
+[@@deriving show]
+
+type trait_impl = {
+ def_id : trait_impl_id;
+ name : name;
+ impl_trait : trait_decl_ref;
+ generics : generic_params;
+ preds : predicates;
+ parent_trait_refs : trait_ref list;
+ consts : (trait_item_name * (ty * global_decl_id)) list;
+ types : (trait_item_name * (trait_ref list * ty)) list;
+ required_methods : (trait_item_name * fun_decl_id) list;
+ provided_methods : (trait_item_name * fun_decl_id) list;
+}
+[@@deriving show]
diff --git a/compiler/PureMicroPasses.ml b/compiler/PureMicroPasses.ml
index b6025df4..f3e6cbe2 100644
--- a/compiler/PureMicroPasses.ml
+++ b/compiler/PureMicroPasses.ml
@@ -376,8 +376,7 @@ let compute_pretty_names (def : fun_decl) : fun_decl =
let ty = e.ty in
let ctx, e =
match e.e with
- | Var _ -> (* Nothing to do *) (ctx, e.e)
- | Const _ -> (* Nothing to do *) (ctx, e.e)
+ | Var _ | CVar _ | Const _ -> (* Nothing to do *) (ctx, e.e)
| App (app, arg) ->
let ctx, app = update_texpression app ctx in
let ctx, arg = update_texpression arg ctx in
@@ -584,13 +583,10 @@ let intro_struct_updates (ctx : trans_ctx) (def : fun_decl) : fun_decl =
| Qualif
{
id = AdtCons { adt_id = AdtId adt_id; variant_id = None };
- type_args = _;
- const_generic_args = _;
+ generics = _;
} ->
(* Lookup the def *)
- let decl =
- TypeDeclId.Map.find adt_id ctx.type_context.type_decls
- in
+ let decl = TypeDeclId.Map.find adt_id ctx.type_ctx.type_decls in
(* Check that there are as many arguments as there are fields - note
that the def should have a body (otherwise we couldn't use the
constructor) *)
@@ -599,8 +595,7 @@ let intro_struct_updates (ctx : trans_ctx) (def : fun_decl) : fun_decl =
(* Check if the definition is recursive *)
let is_rec =
match
- TypeDeclId.Map.find adt_id
- ctx.type_context.type_decls_groups
+ TypeDeclId.Map.find adt_id ctx.type_ctx.type_decls_groups
with
| NonRec _ -> false
| Rec _ -> true
@@ -682,8 +677,8 @@ let inline_useless_var_reassignments (inline_named : bool) (inline_pure : bool)
| _ -> false
in
(* And either:
- * 2.1 the right-expression is a variable or a global *)
- let var_or_global = is_var re || is_global re in
+ * 2.1 the right-expression is a variable, a global or a const generic var *)
+ let var_or_global = is_var re || is_cvar re || is_global re in
(* Or:
* 2.2 the right-expression is a constant value, an ADT value,
* a projection or a primitive function call *and* the flag
@@ -767,10 +762,10 @@ let inline_useless_var_reassignments (inline_named : bool) (inline_pure : bool)
In this situation, we can remove the call [f@fwd x].
*)
let expression_contains_child_call_in_all_paths (ctx : trans_ctx)
- (id0 : A.fun_id) (lp_id0 : LoopId.id option)
- (rg_id0 : T.RegionGroupId.id option) (tys0 : ty list)
+ (id0 : fun_id_or_trait_method_ref) (lp_id0 : LoopId.id option)
+ (rg_id0 : T.RegionGroupId.id option) (generics0 : generic_args)
(args0 : texpression list) (e : texpression) : bool =
- let check_call (fun_id1 : fun_or_op_id) (tys1 : ty list)
+ let check_call (fun_id1 : fun_or_op_id) (generics1 : generic_args)
(args1 : texpression list) : bool =
(* Check the fun_ids, to see if call1's function is a child of call0's function *)
match fun_id1 with
@@ -793,7 +788,12 @@ let expression_contains_child_call_in_all_paths (ctx : trans_ctx)
(* We need to use the regions hierarchy *)
(* First, lookup the signature of the LLBC function *)
let sg =
- LlbcAstUtils.lookup_fun_sig id0 ctx.fun_context.fun_decls
+ let id0 =
+ match id0 with
+ | FunId fun_id -> fun_id
+ | TraitMethod (_, _, fun_decl_id) -> Regular fun_decl_id
+ in
+ LlbcAstUtils.lookup_fun_sig id0 ctx.fun_ctx.fun_decls
in
(* Compute the set of ancestors of the function in call1 *)
let call1_ancestors =
@@ -817,8 +817,8 @@ let expression_contains_child_call_in_all_paths (ctx : trans_ctx)
let input_eq (v0, v1) =
PureUtils.remove_meta v0 = PureUtils.remove_meta v1
in
- (* Compare the input types and the prefix of the input arguments *)
- tys0 = tys1 && List.for_all input_eq args
+ (* Compare the generics and the prefix of the input arguments *)
+ generics0 = generics1 && List.for_all input_eq args
else (* Not a child *)
false
else (* Not the same function *)
@@ -834,7 +834,7 @@ let expression_contains_child_call_in_all_paths (ctx : trans_ctx)
method! visit_texpression env e =
match e.e with
- | Var _ | Const _ -> fun _ -> false
+ | Var _ | CVar _ | Const _ -> fun _ -> false
| StructUpdate _ ->
(* There shouldn't be monadic calls in structure updates - also
note that by returning [false] we are conservative: we might
@@ -844,8 +844,8 @@ let expression_contains_child_call_in_all_paths (ctx : trans_ctx)
| Let (_, _, re, e) -> (
match opt_destruct_function_call re with
| None -> fun () -> self#visit_texpression env e ()
- | Some (func1, tys1, args1) ->
- let call_is_child = check_call func1 tys1 args1 in
+ | Some (func1, generics1, args1) ->
+ let call_is_child = check_call func1 generics1 args1 in
if call_is_child then fun () -> true
else fun () -> self#visit_texpression env e ())
| App _ -> (
@@ -930,7 +930,7 @@ let filter_useless (filter_monadic_calls : bool) (ctx : trans_ctx)
method! visit_expression env e =
match e with
- | Var _ | Const _ | App _ | Qualif _
+ | Var _ | CVar _ | Const _ | App _ | Qualif _
| Switch (_, _)
| Meta (_, _)
| StructUpdate _ | Abs _ ->
@@ -1086,13 +1086,12 @@ let simplify_aggregates (ctx : trans_ctx) (def : fun_decl) : fun_decl =
| Qualif
{
id = AdtCons { adt_id = AdtId adt_id; variant_id = None };
- type_args;
- const_generic_args;
+ generics;
} ->
(* This is a struct *)
(* Retrieve the definiton, to find how many fields there are *)
let adt_decl =
- TypeDeclId.Map.find adt_id ctx.type_context.type_decls
+ TypeDeclId.Map.find adt_id ctx.type_ctx.type_decls
in
let fields =
match adt_decl.kind with
@@ -1108,7 +1107,7 @@ let simplify_aggregates (ctx : trans_ctx) (def : fun_decl) : fun_decl =
* [x.field] for some variable [x], and where the projection
* is for the proper ADT *)
let to_var_proj (i : int) (arg : texpression) :
- (ty list * const_generic list * var_id) option =
+ (generic_args * var_id) option =
match arg.e with
| App (proj, x) -> (
match (proj.e, x.e) with
@@ -1116,16 +1115,14 @@ let simplify_aggregates (ctx : trans_ctx) (def : fun_decl) : fun_decl =
{
id =
Proj { adt_id = AdtId proj_adt_id; field_id };
- type_args = proj_type_args;
- const_generic_args = proj_const_generic_args;
+ generics = proj_generics;
},
Var v ) ->
(* We check that this is the proper ADT, and the proper field *)
if
proj_adt_id = adt_id
&& FieldId.to_int field_id = i
- then
- Some (proj_type_args, proj_const_generic_args, v)
+ then Some (proj_generics, v)
else None
| _ -> None)
| _ -> None
@@ -1136,14 +1133,13 @@ let simplify_aggregates (ctx : trans_ctx) (def : fun_decl) : fun_decl =
if List.length args = num_fields then
(* Check that this is the same variable we project from -
* note that we checked above that there is at least one field *)
- let (_, _, x), end_args = Collections.List.pop args in
- if List.for_all (fun (_, _, y) -> y = x) end_args then (
+ let (_, x), end_args = Collections.List.pop args in
+ if List.for_all (fun (_, y) -> y = x) end_args then (
(* We can substitute *)
(* Sanity check: all types correct *)
assert (
List.for_all
- (fun (tys, cgs, _) ->
- tys = type_args && cgs = const_generic_args)
+ (fun (generics1, _) -> generics1 = generics)
args);
{ e with e = Var x })
else super#visit_texpression env e
@@ -1162,8 +1158,7 @@ let simplify_aggregates (ctx : trans_ctx) (def : fun_decl) : fun_decl =
| ( Qualif
{
id = Proj { adt_id = AdtId proj_adt_id; field_id };
- type_args = _;
- const_generic_args = _;
+ generics = _;
},
Var v ) ->
(* We check that this is the proper ADT, and the proper field *)
@@ -1361,8 +1356,8 @@ let decompose_loops (def : fun_decl) : fun_decl * fun_decl list =
let loop_sig =
{
- type_params = fun_sig.type_params;
- const_generic_params = fun_sig.const_generic_params;
+ generics = fun_sig.generics;
+ preds = fun_sig.preds;
inputs = inputs_tys;
output;
doutputs;
@@ -1427,6 +1422,7 @@ let decompose_loops (def : fun_decl) : fun_decl * fun_decl list =
let loop_def =
{
def_id = def.def_id;
+ kind = def.kind;
num_loops;
loop_id = Some loop.loop_id;
back_id = def.back_id;
@@ -1466,13 +1462,12 @@ let decompose_loops (def : fun_decl) : fun_decl * fun_decl list =
In such situation, we can remove the forward function definition
altogether.
*)
-let keep_forward (trans : pure_fun_translation) : bool =
- let (fwd, _), backs = trans in
+let keep_forward (fwd : fun_and_loops) (backs : fun_and_loops list) : bool =
(* Note that at this point, the output types are no longer seen as tuples:
* they should be lists of length 1. *)
if
!Config.filter_useless_functions
- && fwd.signature.output = mk_result_ty mk_unit_ty
+ && fwd.f.signature.output = mk_result_ty mk_unit_ty
&& backs <> []
then false
else true
@@ -1518,7 +1513,7 @@ let unit_vars_to_unit (def : fun_decl) : fun_decl =
function calls, and when translating end abstractions. Here, we can do
something simpler, in one micro-pass.
*)
-let eliminate_box_functions (_ctx : trans_ctx) (def : fun_decl) : fun_decl =
+let eliminate_box_functions (ctx : trans_ctx) (def : fun_decl) : fun_decl =
(* The map visitor *)
let obj =
object
@@ -1527,30 +1522,44 @@ let eliminate_box_functions (_ctx : trans_ctx) (def : fun_decl) : fun_decl =
method! visit_texpression env e =
match opt_destruct_function_call e with
| Some (fun_id, _tys, args) -> (
+ (* Below, when dealing with the arguments: we consider the very
+ * general case, where functions could be boxed (meaning we
+ * could have: [box_new f x])
+ * *)
match fun_id with
- | Fun (FromLlbc (A.Assumed aid, _lp_id, rg_id)) -> (
- (* Below, when dealing with the arguments: we consider the very
- * general case, where functions could be boxed (meaning we
- * could have: [box_new f x])
- * *)
+ | Fun (FromLlbc (FunId (Assumed aid), _lp_id, rg_id)) -> (
match (aid, rg_id) with
- | A.BoxNew, _ ->
+ | BoxNew, _ ->
assert (rg_id = None);
let arg, args = Collections.List.pop args in
mk_apps arg args
- | A.BoxDeref, None ->
+ | BoxFree, _ ->
+ assert (args = []);
+ mk_unit_rvalue
+ | ( ( SliceIndexShared | SliceIndexMut | ArrayIndexShared
+ | ArrayIndexMut | ArrayToSliceShared | ArrayToSliceMut
+ | ArrayRepeat | SliceLen ),
+ _ ) ->
+ super#visit_texpression env e)
+ | Fun (FromLlbc (FunId (Regular fid), _lp_id, rg_id)) -> (
+ (* Lookup the function name *)
+ let def = FunDeclId.Map.find fid ctx.fun_ctx.fun_decls in
+ match
+ (Names.name_no_disambiguators_to_string def.name, rg_id)
+ with
+ | "alloc::boxed::Box::deref", None ->
(* [Box::deref] forward is the identity *)
let arg, args = Collections.List.pop args in
mk_apps arg args
- | A.BoxDeref, Some _ ->
+ | "alloc::boxed::Box::deref", Some _ ->
(* [Box::deref] backward is [()] (doesn't give back anything) *)
assert (args = []);
mk_unit_rvalue
- | A.BoxDerefMut, None ->
+ | "alloc::boxed::Box::deref_mut", None ->
(* [Box::deref_mut] forward is the identity *)
let arg, args = Collections.List.pop args in
mk_apps arg args
- | A.BoxDerefMut, Some _ ->
+ | "alloc::boxed::Box::deref_mut", Some _ ->
(* [Box::deref_mut] back is almost the identity:
* let box_deref_mut (x_init : t) (x_back : t) : t = x_back
* *)
@@ -1560,17 +1569,7 @@ let eliminate_box_functions (_ctx : trans_ctx) (def : fun_decl) : fun_decl =
| _ -> raise (Failure "Unreachable")
in
mk_apps arg args
- | A.BoxFree, _ ->
- assert (args = []);
- mk_unit_rvalue
- | ( ( A.Replace | VecNew | VecPush | VecInsert | VecLen
- | VecIndex | VecIndexMut | ArraySubsliceShared
- | ArraySubsliceMut | SliceIndexShared | SliceIndexMut
- | SliceSubsliceShared | SliceSubsliceMut | ArrayIndexShared
- | ArrayIndexMut | ArrayToSliceShared | ArrayToSliceMut
- | SliceLen ),
- _ ) ->
- super#visit_texpression env e)
+ | _ -> super#visit_texpression env e)
| _ -> super#visit_texpression env e)
| _ -> super#visit_texpression env e
end
@@ -1914,7 +1913,7 @@ let apply_end_passes_to_def (ctx : trans_ctx) (def : fun_decl) : fun_decl =
[ctx]: used only for printing.
*)
let apply_passes_to_def (ctx : trans_ctx) (def : fun_decl) :
- (fun_decl * fun_decl list) option =
+ fun_and_loops option =
(* Debug *)
log#ldebug
(lazy
@@ -1955,9 +1954,9 @@ let apply_passes_to_def (ctx : trans_ctx) (def : fun_decl) :
let def, loops = decompose_loops def in
(* Apply the remaining passes *)
- let def = apply_end_passes_to_def ctx def in
+ let f = apply_end_passes_to_def ctx def in
let loops = List.map (apply_end_passes_to_def ctx) loops in
- Some (def, loops)
+ Some { f; loops }
(** Small utility for {!filter_loop_inputs} *)
let filter_prefix (keep : bool list) (ls : 'a list) : 'a list =
@@ -1983,8 +1982,8 @@ end
module FunLoopIdMap = Collections.MakeMap (FunLoopIdOrderedType)
(** Filter the useless loop input parameters. *)
-let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
- (bool * pure_fun_translation) list =
+let filter_loop_inputs (transl : pure_fun_translation list) :
+ pure_fun_translation list =
(* We need to explore groups of mutually recursive functions. In order
to compute which parameters are useless, we need to explore the
functions by groups of mutually recursive definitions.
@@ -2002,10 +2001,11 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
(List.concat
(List.concat
(List.map
- (fun (_, ((fwd, loops_fwd), backs)) ->
- [ fwd :: loops_fwd ]
+ (fun { fwd; backs; _ } ->
+ [ fwd.f :: fwd.loops ]
:: List.map
- (fun (back, loops_back) -> [ back :: loops_back ])
+ (fun { f = back; loops = loops_back } ->
+ [ back :: loops_back ])
backs)
transl)))
in
@@ -2030,7 +2030,6 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
additional parameters.
*)
let used_map = ref FunLoopIdMap.empty in
- let fun_id_to_fun_loop_id (fid, loop_id, _) = (fid, loop_id) in
(* We start by computing the filtering information, for each function *)
let compute_one_filter_info (decl : fun_decl) =
@@ -2051,7 +2050,7 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
let inputs_set = VarId.Set.of_list (List.map var_get_id inputs_prefix) in
assert (Option.is_some decl.loop_id);
- let fun_id = (A.Regular decl.def_id, decl.loop_id) in
+ let fun_id = (E.Regular decl.def_id, decl.loop_id) in
let set_used vid =
used := List.map (fun (vid', b) -> (vid', b || vid = vid')) !used
@@ -2075,8 +2074,8 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
match e_app.e with
| Qualif qualif -> (
match qualif.id with
- | FunOrOp (Fun (FromLlbc fun_id')) ->
- if fun_id_to_fun_loop_id fun_id' = fun_id then (
+ | FunOrOp (Fun (FromLlbc (FunId fun_id', loop_id', _))) ->
+ if (fun_id', loop_id') = fun_id then (
(* For each argument, check if it is exactly the original
input parameter. Note that there shouldn't be partial
applications of loop functions: the number of arguments
@@ -2135,22 +2134,15 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
(* We then apply the filtering to all the function definitions at once *)
let filter_in_one (decl : fun_decl) : fun_decl =
(* Filter the function signature *)
- let fun_id = (A.Regular decl.def_id, decl.loop_id, decl.back_id) in
+ let fun_id = (E.Regular decl.def_id, decl.loop_id) in
let decl =
- match FunLoopIdMap.find_opt (fun_id_to_fun_loop_id fun_id) !used_map with
+ match FunLoopIdMap.find_opt fun_id !used_map with
| None -> (* Nothing to filter *) decl
| Some used_info ->
let num_filtered =
List.length (List.filter (fun b -> not b) used_info)
in
- let {
- type_params;
- const_generic_params;
- inputs;
- output;
- doutputs;
- info;
- } =
+ let { generics; preds; inputs; output; doutputs; info } =
decl.signature
in
let {
@@ -2178,16 +2170,7 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
effect_info;
}
in
- let signature =
- {
- type_params;
- const_generic_params;
- inputs;
- output;
- doutputs;
- info;
- }
- in
+ let signature = { generics; preds; inputs; output; doutputs; info } in
{ decl with signature }
in
@@ -2201,9 +2184,7 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
let { inputs; inputs_lvs; body } = body in
let inputs, inputs_lvs =
- match
- FunLoopIdMap.find_opt (fun_id_to_fun_loop_id fun_id) !used_map
- with
+ match FunLoopIdMap.find_opt fun_id !used_map with
| None -> (* Nothing to filter *) (inputs, inputs_lvs)
| Some used_info ->
let inputs = filter_prefix used_info inputs in
@@ -2223,11 +2204,10 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
match e_app.e with
| Qualif qualif -> (
match qualif.id with
- | FunOrOp (Fun (FromLlbc fun_id)) -> (
+ | FunOrOp (Fun (FromLlbc (FunId fun_id, loop_id, _)))
+ -> (
match
- FunLoopIdMap.find_opt
- (fun_id_to_fun_loop_id fun_id)
- !used_map
+ FunLoopIdMap.find_opt (fun_id, loop_id) !used_map
with
| None -> super#visit_texpression env e
| Some used_info ->
@@ -2267,13 +2247,13 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
in
let transl =
List.map
- (fun (b, (fwd, backs)) ->
- let filter_fun_and_loops (f, fl) =
- (filter_in_one f, List.map filter_in_one fl)
+ (fun trans ->
+ let filter_fun_and_loops f =
+ { f = filter_in_one f.f; loops = List.map filter_in_one f.loops }
in
- let fwd = filter_fun_and_loops fwd in
- let backs = List.map filter_fun_and_loops backs in
- (b, (fwd, backs)))
+ let fwd = filter_fun_and_loops trans.fwd in
+ let backs = List.map filter_fun_and_loops trans.backs in
+ { trans with fwd; backs })
transl
in
@@ -2294,18 +2274,17 @@ let filter_loop_inputs (transl : (bool * pure_fun_translation) list) :
but convenient.
*)
let apply_passes_to_pure_fun_translations (ctx : trans_ctx)
- (transl : (fun_decl * fun_decl list) list) :
- (bool * pure_fun_translation) list =
- let apply_to_one (trans : fun_decl * fun_decl list) :
- bool * pure_fun_translation =
+ (transl : (fun_decl * fun_decl list) list) : pure_fun_translation list =
+ let apply_to_one (trans : fun_decl * fun_decl list) : pure_fun_translation =
(* Apply the passes to the individual functions *)
- let forward, backwards = trans in
- let forward = Option.get (apply_passes_to_def ctx forward) in
- let backwards = List.filter_map (apply_passes_to_def ctx) backwards in
- let trans = (forward, backwards) in
+ let fwd, backs = trans in
+ let fwd = Option.get (apply_passes_to_def ctx fwd) in
+ let backs = List.filter_map (apply_passes_to_def ctx) backs in
(* Compute whether we need to filter the forward function or not *)
- (keep_forward trans, trans)
+ let keep_fwd = keep_forward fwd backs in
+ { keep_fwd; fwd; backs }
in
+
let transl = List.map apply_to_one transl in
(* Filter the useless inputs in the loop functions *)
diff --git a/compiler/PureTypeCheck.ml b/compiler/PureTypeCheck.ml
index 8d28bb8a..2ad942bb 100644
--- a/compiler/PureTypeCheck.ml
+++ b/compiler/PureTypeCheck.ml
@@ -9,17 +9,19 @@ open PureUtils
of fields is fixed: it shouldn't be used for arrays, slices, etc.
*)
let get_adt_field_types (type_decls : type_decl TypeDeclId.Map.t)
- (type_id : type_id) (variant_id : VariantId.id option) (tys : ty list)
- (cgs : const_generic list) : ty list =
+ (type_id : type_id) (variant_id : VariantId.id option)
+ (generics : generic_args) : ty list =
match type_id with
| Tuple ->
(* Tuple *)
+ assert (generics.const_generics = []);
+ assert (generics.trait_refs = []);
assert (variant_id = None);
- tys
+ generics.types
| AdtId def_id ->
(* "Regular" ADT *)
let def = TypeDeclId.Map.find def_id type_decls in
- type_decl_get_instantiated_fields_types def variant_id tys cgs
+ type_decl_get_instantiated_fields_types def variant_id generics
| Assumed aty -> (
(* Assumed type *)
match aty with
@@ -27,14 +29,14 @@ let get_adt_field_types (type_decls : type_decl TypeDeclId.Map.t)
(* This type is opaque *)
raise (Failure "Unreachable: opaque type")
| Result ->
- let ty = Collections.List.to_cons_nil tys in
+ let ty = Collections.List.to_cons_nil generics.types in
let variant_id = Option.get variant_id in
if variant_id = result_return_id then [ ty ]
else if variant_id = result_fail_id then [ mk_error_ty ]
else
raise (Failure "Unreachable: improper variant id for result type")
| Error ->
- assert (tys = []);
+ assert (generics = empty_generic_args);
let variant_id = Option.get variant_id in
assert (
variant_id = error_failure_id || variant_id = error_out_of_fuel_id);
@@ -44,18 +46,7 @@ let get_adt_field_types (type_decls : type_decl TypeDeclId.Map.t)
if variant_id = fuel_zero_id then []
else if variant_id = fuel_succ_id then [ mk_fuel_ty ]
else raise (Failure "Unreachable: improper variant id for fuel type")
- | Option ->
- let ty = Collections.List.to_cons_nil tys in
- let variant_id = Option.get variant_id in
- if variant_id = option_some_id then [ ty ]
- else if variant_id = option_none_id then []
- else
- raise (Failure "Unreachable: improper variant id for option type")
- | Range ->
- let ty = Collections.List.to_cons_nil tys in
- assert (variant_id = None);
- [ ty; ty ]
- | Vec | Array | Slice | Str ->
+ | Array | Slice | Str | RawPtr _ ->
(* Array: when not symbolic values (for instance, because of aggregates),
the array expressions are introduced as struct updates *)
raise (Failure "Attempting to access the fields of an opaque type"))
@@ -65,6 +56,9 @@ type tc_ctx = {
global_decls : A.global_decl A.GlobalDeclId.Map.t;
(** The global declarations *)
env : ty VarId.Map.t; (** Environment from variables to types *)
+ const_generics : ty T.ConstGenericVarId.Map.t;
+ (** The types of the const generics *)
+ (* TODO: add trait type constraints *)
}
let check_literal (v : literal) (ty : literal_type) : unit =
@@ -86,12 +80,13 @@ let rec check_typed_pattern (ctx : tc_ctx) (v : typed_pattern) : tc_ctx =
{ ctx with env }
| PatAdt av ->
(* Compute the field types *)
- let type_id, tys, cgs = ty_as_adt v.ty in
+ let type_id, generics = ty_as_adt v.ty in
let field_tys =
- get_adt_field_types ctx.type_decls type_id av.variant_id tys cgs
+ get_adt_field_types ctx.type_decls type_id av.variant_id generics
in
let check_value (ctx : tc_ctx) (ty : ty) (v : typed_pattern) : tc_ctx =
if ty <> v.ty then (
+ (* TODO: we need to normalize the types *)
log#serror
("check_typed_pattern: not the same types:" ^ "\n- ty: "
^ show_ty ty ^ "\n- v.ty: " ^ show_ty v.ty);
@@ -115,6 +110,9 @@ let rec check_texpression (ctx : tc_ctx) (e : texpression) : unit =
match VarId.Map.find_opt var_id ctx.env with
| None -> ()
| Some ty -> assert (ty = e.ty))
+ | CVar cg_id ->
+ let ty = T.ConstGenericVarId.Map.find cg_id ctx.const_generics in
+ assert (ty = e.ty)
| Const cv -> check_literal cv (ty_as_literal e.ty)
| App (app, arg) ->
let input_ty, output_ty = destruct_arrow app.ty in
@@ -133,35 +131,34 @@ let rec check_texpression (ctx : tc_ctx) (e : texpression) : unit =
match qualif.id with
| FunOrOp _ -> () (* TODO *)
| Global _ -> () (* TODO *)
+ | TraitConst _ -> () (* TODO *)
| Proj { adt_id = proj_adt_id; field_id } ->
(* Note we can only project fields of structures (not enumerations) *)
(* Deconstruct the projector type *)
let adt_ty, field_ty = destruct_arrow e.ty in
- let adt_id, adt_type_args, adt_cg_args = ty_as_adt adt_ty in
+ let adt_id, adt_generics = ty_as_adt adt_ty in
(* Check the ADT type *)
assert (adt_id = proj_adt_id);
- assert (adt_type_args = qualif.type_args);
- assert (adt_cg_args = qualif.const_generic_args);
+ assert (adt_generics = qualif.generics);
(* Retrieve and check the expected field type *)
let variant_id = None in
let expected_field_tys =
get_adt_field_types ctx.type_decls proj_adt_id variant_id
- qualif.type_args qualif.const_generic_args
+ qualif.generics
in
let expected_field_ty = FieldId.nth expected_field_tys field_id in
assert (expected_field_ty = field_ty)
| AdtCons id -> (
let expected_field_tys =
get_adt_field_types ctx.type_decls id.adt_id id.variant_id
- qualif.type_args qualif.const_generic_args
+ qualif.generics
in
let field_tys, adt_ty = destruct_arrows e.ty in
assert (expected_field_tys = field_tys);
match adt_ty with
- | Adt (type_id, tys, cgs) ->
+ | Adt (type_id, generics) ->
assert (type_id = id.adt_id);
- assert (tys = qualif.type_args);
- assert (cgs = qualif.const_generic_args)
+ assert (generics = qualif.generics)
| _ -> raise (Failure "Unreachable")))
| Let (monadic, pat, re, e_next) ->
let expected_pat_ty = if monadic then destruct_result re.ty else re.ty in
@@ -207,15 +204,14 @@ let rec check_texpression (ctx : tc_ctx) (e : texpression) : unit =
| Some ty -> assert (ty = e.ty));
(* Check the fields *)
(* Retrieve and check the expected field type *)
- let adt_id, adt_type_args, adt_cg_args = ty_as_adt e.ty in
+ let adt_id, adt_generics = ty_as_adt e.ty in
assert (adt_id = supd.struct_id);
(* The id can only be: a custom type decl or an array *)
match adt_id with
| AdtId _ ->
let variant_id = None in
let expected_field_tys =
- get_adt_field_types ctx.type_decls adt_id variant_id adt_type_args
- adt_cg_args
+ get_adt_field_types ctx.type_decls adt_id variant_id adt_generics
in
List.iter
(fun (fid, fe) ->
@@ -224,7 +220,9 @@ let rec check_texpression (ctx : tc_ctx) (e : texpression) : unit =
check_texpression ctx fe)
supd.updates
| Assumed Array ->
- let expected_field_ty = Collections.List.to_cons_nil adt_type_args in
+ let expected_field_ty =
+ Collections.List.to_cons_nil adt_generics.types
+ in
List.iter
(fun (_, fe) ->
assert (expected_field_ty = fe.ty);
diff --git a/compiler/PureUtils.ml b/compiler/PureUtils.ml
index 1c8d8921..3aeabffe 100644
--- a/compiler/PureUtils.ml
+++ b/compiler/PureUtils.ml
@@ -89,14 +89,31 @@ let mk_mplace (var_id : E.VarId.id) (name : string option)
(projection : mprojection) : mplace =
{ var_id; name; projection }
+let empty_generic_params : generic_params =
+ { types = []; const_generics = []; trait_clauses = [] }
+
+let empty_generic_args : generic_args =
+ { types = []; const_generics = []; trait_refs = [] }
+
+let mk_generic_args_from_types (types : ty list) : generic_args =
+ { types; const_generics = []; trait_refs = [] }
+
+type subst = {
+ ty_subst : TypeVarId.id -> ty;
+ cg_subst : ConstGenericVarId.id -> const_generic;
+ tr_subst : TraitClauseId.id -> trait_instance_id;
+ tr_self : trait_instance_id;
+}
+
(** Type substitution *)
-let ty_substitute (tsubst : TypeVarId.id -> ty)
- (cgsubst : ConstGenericVarId.id -> const_generic) (ty : ty) : ty =
+let ty_substitute (subst : subst) (ty : ty) : ty =
let obj =
object
inherit [_] map_ty
- method! visit_TypeVar _ var_id = tsubst var_id
- method! visit_ConstGenericVar _ var_id = cgsubst var_id
+ method! visit_TypeVar _ var_id = subst.ty_subst var_id
+ method! visit_ConstGenericVar _ var_id = subst.cg_subst var_id
+ method! visit_Clause _ id = subst.tr_subst id
+ method! visit_Self _ = subst.tr_self
end
in
obj#visit_ty () ty
@@ -115,6 +132,18 @@ let make_const_generic_subst (vars : const_generic_var list)
(cgs : const_generic list) : ConstGenericVarId.id -> const_generic =
Substitute.make_const_generic_subst_from_vars vars cgs
+let make_trait_subst (clauses : trait_clause list) (refs : trait_ref list) :
+ TraitClauseId.id -> trait_instance_id =
+ let clauses = List.map (fun x -> x.clause_id) clauses in
+ let refs = List.map (fun x -> TraitRef x) refs in
+ let ls = List.combine clauses refs in
+ let mp =
+ List.fold_left
+ (fun mp (k, v) -> TraitClauseId.Map.add k v mp)
+ TraitClauseId.Map.empty ls
+ in
+ fun id -> TraitClauseId.Map.find id mp
+
(** Retrieve the list of fields for the given variant of a {!type:Aeneas.Pure.type_decl}.
Raises [Invalid_argument] if the arguments are incorrect.
@@ -135,20 +164,27 @@ let type_decl_get_fields (def : type_decl)
- def: " ^ show_type_decl def ^ "\n- opt_variant_id: "
^ opt_variant_id))
+let make_subst_from_generics (params : generic_params) (args : generic_args)
+ (tr_self : trait_instance_id) : subst =
+ let ty_subst = make_type_subst params.types args.types in
+ let cg_subst =
+ make_const_generic_subst params.const_generics args.const_generics
+ in
+ let tr_subst = make_trait_subst params.trait_clauses args.trait_refs in
+ { ty_subst; cg_subst; tr_subst; tr_self }
+
(** Instantiate the type variables for the chosen variant in an ADT definition,
and return the list of the types of its fields *)
let type_decl_get_instantiated_fields_types (def : type_decl)
- (opt_variant_id : VariantId.id option) (types : ty list)
- (cgs : const_generic list) : ty list =
- let ty_subst = make_type_subst def.type_params types in
- let cg_subst = make_const_generic_subst def.const_generic_params cgs in
+ (opt_variant_id : VariantId.id option) (generics : generic_args) : ty list =
+ (* There shouldn't be any reference to Self *)
+ let tr_self = UnknownTrait __FUNCTION__ in
+ let subst = make_subst_from_generics def.generics generics tr_self in
let fields = type_decl_get_fields def opt_variant_id in
- List.map (fun f -> ty_substitute ty_subst cg_subst f.field_ty) fields
+ List.map (fun f -> ty_substitute subst f.field_ty) fields
-let fun_sig_substitute (tsubst : TypeVarId.id -> ty)
- (cgsubst : ConstGenericVarId.id -> const_generic) (sg : fun_sig) :
- inst_fun_sig =
- let subst = ty_substitute tsubst cgsubst in
+let fun_sig_substitute (subst : subst) (sg : fun_sig) : inst_fun_sig =
+ let subst = ty_substitute subst in
let inputs = List.map subst sg.inputs in
let output = subst sg.output in
let doutputs = List.map subst sg.doutputs in
@@ -164,7 +200,8 @@ let fun_sig_substitute (tsubst : TypeVarId.id -> ty)
*)
let rec let_group_requires_parentheses (e : texpression) : bool =
match e.e with
- | Var _ | Const _ | App _ | Abs _ | Qualif _ | StructUpdate _ -> false
+ | Var _ | CVar _ | Const _ | App _ | Abs _ | Qualif _ | StructUpdate _ ->
+ false
| Let (monadic, _, _, next_e) ->
if monadic then true else let_group_requires_parentheses next_e
| Switch (_, _) -> false
@@ -184,15 +221,18 @@ let is_var (e : texpression) : bool =
let as_var (e : texpression) : VarId.id =
match e.e with Var v -> v | _ -> raise (Failure "Unreachable")
+let is_cvar (e : texpression) : bool =
+ match e.e with CVar _ -> true | _ -> false
+
let is_global (e : texpression) : bool =
match e.e with Qualif { id = Global _; _ } -> true | _ -> false
let is_const (e : texpression) : bool =
match e.e with Const _ -> true | _ -> false
-let ty_as_adt (ty : ty) : type_id * ty list * const_generic list =
+let ty_as_adt (ty : ty) : type_id * generic_args =
match ty with
- | Adt (id, tys, cgs) -> (id, tys, cgs)
+ | Adt (id, generics) -> (id, generics)
| _ -> raise (Failure "Unreachable")
(** Remove the external occurrences of {!Meta} *)
@@ -290,28 +330,30 @@ let destruct_qualif_app (e : texpression) : qualif * texpression list =
(** Destruct an expression into a function call, if possible *)
let opt_destruct_function_call (e : texpression) :
- (fun_or_op_id * ty list * texpression list) option =
+ (fun_or_op_id * generic_args * texpression list) option =
match opt_destruct_qualif_app e with
| None -> None
| Some (qualif, args) -> (
match qualif.id with
- | FunOrOp fun_id -> Some (fun_id, qualif.type_args, args)
+ | FunOrOp fun_id -> Some (fun_id, qualif.generics, args)
| _ -> None)
let opt_destruct_result (ty : ty) : ty option =
match ty with
- | Adt (Assumed Result, tys, cgs) ->
- assert (cgs = []);
- Some (Collections.List.to_cons_nil tys)
+ | Adt (Assumed Result, generics) ->
+ assert (generics.const_generics = []);
+ assert (generics.trait_refs = []);
+ Some (Collections.List.to_cons_nil generics.types)
| _ -> None
let destruct_result (ty : ty) : ty = Option.get (opt_destruct_result ty)
let opt_destruct_tuple (ty : ty) : ty list option =
match ty with
- | Adt (Tuple, tys, cgs) ->
- assert (cgs = []);
- Some tys
+ | Adt (Tuple, generics) ->
+ assert (generics.const_generics = []);
+ assert (generics.trait_refs = []);
+ Some generics.types
| _ -> None
let mk_abs (x : typed_pattern) (e : texpression) : texpression =
@@ -383,14 +425,16 @@ let mk_switch (scrut : texpression) (sb : switch_body) : texpression =
- if there is > one type: wrap them in a tuple
*)
let mk_simpl_tuple_ty (tys : ty list) : ty =
- match tys with [ ty ] -> ty | _ -> Adt (Tuple, tys, [])
+ match tys with
+ | [ ty ] -> ty
+ | _ -> Adt (Tuple, mk_generic_args_from_types tys)
let mk_bool_ty : ty = Literal Bool
-let mk_unit_ty : ty = Adt (Tuple, [], [])
+let mk_unit_ty : ty = Adt (Tuple, empty_generic_args)
let mk_unit_rvalue : texpression =
let id = AdtCons { adt_id = Tuple; variant_id = None } in
- let qualif = { id; type_args = []; const_generic_args = [] } in
+ let qualif = { id; generics = empty_generic_args } in
let e = Qualif qualif in
let ty = mk_unit_ty in
{ e; ty }
@@ -430,7 +474,7 @@ let mk_simpl_tuple_pattern (vl : typed_pattern list) : typed_pattern =
| [ v ] -> v
| _ ->
let tys = List.map (fun (v : typed_pattern) -> v.ty) vl in
- let ty = Adt (Tuple, tys, []) in
+ let ty = Adt (Tuple, mk_generic_args_from_types tys) in
let value = PatAdt { variant_id = None; field_values = vl } in
{ value; ty }
@@ -441,11 +485,11 @@ let mk_simpl_tuple_texpression (vl : texpression list) : texpression =
| _ ->
(* Compute the types of the fields, and the type of the tuple constructor *)
let tys = List.map (fun (v : texpression) -> v.ty) vl in
- let ty = Adt (Tuple, tys, []) in
+ let ty = Adt (Tuple, mk_generic_args_from_types tys) in
let ty = mk_arrows tys ty in
(* Construct the tuple constructor qualifier *)
let id = AdtCons { adt_id = Tuple; variant_id = None } in
- let qualif = { id; type_args = tys; const_generic_args = [] } in
+ let qualif = { id; generics = mk_generic_args_from_types tys } in
(* Put everything together *)
let cons = { e = Qualif qualif; ty } in
mk_apps cons vl
@@ -463,32 +507,36 @@ let ty_as_integer (t : ty) : T.integer_type =
let ty_as_literal (t : ty) : T.literal_type =
match t with Literal ty -> ty | _ -> raise (Failure "Unreachable")
-let mk_state_ty : ty = Adt (Assumed State, [], [])
-let mk_result_ty (ty : ty) : ty = Adt (Assumed Result, [ ty ], [])
-let mk_error_ty : ty = Adt (Assumed Error, [], [])
-let mk_fuel_ty : ty = Adt (Assumed Fuel, [], [])
+let mk_state_ty : ty = Adt (Assumed State, empty_generic_args)
+
+let mk_result_ty (ty : ty) : ty =
+ Adt (Assumed Result, mk_generic_args_from_types [ ty ])
+
+let mk_error_ty : ty = Adt (Assumed Error, empty_generic_args)
+let mk_fuel_ty : ty = Adt (Assumed Fuel, empty_generic_args)
let mk_error (error : VariantId.id) : texpression =
let ty = mk_error_ty in
let id = AdtCons { adt_id = Assumed Error; variant_id = Some error } in
- let qualif = { id; type_args = []; const_generic_args = [] } in
+ let qualif = { id; generics = empty_generic_args } in
let e = Qualif qualif in
{ e; ty }
let unwrap_result_ty (ty : ty) : ty =
match ty with
- | Adt (Assumed Result, [ ty ], cgs) ->
- assert (cgs = []);
+ | Adt
+ (Assumed Result, { types = [ ty ]; const_generics = []; trait_refs = [] })
+ ->
ty
| _ -> raise (Failure "not a result type")
let mk_result_fail_texpression (error : texpression) (ty : ty) : texpression =
let type_args = [ ty ] in
- let ty = Adt (Assumed Result, type_args, []) in
+ let ty = Adt (Assumed Result, mk_generic_args_from_types type_args) in
let id =
AdtCons { adt_id = Assumed Result; variant_id = Some result_fail_id }
in
- let qualif = { id; type_args; const_generic_args = [] } in
+ let qualif = { id; generics = mk_generic_args_from_types type_args } in
let cons_e = Qualif qualif in
let cons_ty = mk_arrow error.ty ty in
let cons = { e = cons_e; ty = cons_ty } in
@@ -501,11 +549,11 @@ let mk_result_fail_texpression_with_error_id (error : VariantId.id) (ty : ty) :
let mk_result_return_texpression (v : texpression) : texpression =
let type_args = [ v.ty ] in
- let ty = Adt (Assumed Result, type_args, []) in
+ let ty = Adt (Assumed Result, mk_generic_args_from_types type_args) in
let id =
AdtCons { adt_id = Assumed Result; variant_id = Some result_return_id }
in
- let qualif = { id; type_args; const_generic_args = [] } in
+ let qualif = { id; generics = mk_generic_args_from_types type_args } in
let cons_e = Qualif qualif in
let cons_ty = mk_arrow v.ty ty in
let cons = { e = cons_e; ty = cons_ty } in
@@ -514,7 +562,7 @@ let mk_result_return_texpression (v : texpression) : texpression =
(** Create a [Fail err] pattern which captures the error *)
let mk_result_fail_pattern (error_pat : pattern) (ty : ty) : typed_pattern =
let error_pat : typed_pattern = { value = error_pat; ty = mk_error_ty } in
- let ty = Adt (Assumed Result, [ ty ], []) in
+ let ty = Adt (Assumed Result, mk_generic_args_from_types [ ty ]) in
let value =
PatAdt { variant_id = Some result_fail_id; field_values = [ error_pat ] }
in
@@ -526,7 +574,7 @@ let mk_result_fail_pattern_ignore_error (ty : ty) : typed_pattern =
mk_result_fail_pattern error_pat ty
let mk_result_return_pattern (v : typed_pattern) : typed_pattern =
- let ty = Adt (Assumed Result, [ v.ty ], []) in
+ let ty = Adt (Assumed Result, mk_generic_args_from_types [ v.ty ]) in
let value =
PatAdt { variant_id = Some result_return_id; field_values = [ v ] }
in
@@ -561,11 +609,11 @@ let rec typed_pattern_to_texpression (pat : typed_pattern) : texpression option
let fields_values = List.map (fun e -> Option.get e) fields in
(* Retrieve the type id and the type args from the pat type (simpler this way *)
- let adt_id, type_args, const_generic_args = ty_as_adt pat.ty in
+ let adt_id, generics = ty_as_adt pat.ty in
(* Create the constructor *)
let qualif_id = AdtCons { adt_id; variant_id = av.variant_id } in
- let qualif = { id = qualif_id; type_args; const_generic_args } in
+ let qualif = { id = qualif_id; generics } in
let cons_e = Qualif qualif in
let field_tys =
List.map (fun (v : texpression) -> v.ty) fields_values
@@ -577,3 +625,55 @@ let rec typed_pattern_to_texpression (pat : typed_pattern) : texpression option
Some (mk_apps cons fields_values).e
in
match e_opt with None -> None | Some e -> Some { e; ty = pat.ty }
+
+type trait_decl_method_decl_id = { is_provided : bool; id : fun_decl_id }
+
+let trait_decl_get_method (trait_decl : trait_decl) (method_name : string) :
+ trait_decl_method_decl_id =
+ (* First look in the required methods *)
+ let method_id =
+ List.find_opt (fun (s, _) -> s = method_name) trait_decl.required_methods
+ in
+ match method_id with
+ | Some (_, id) -> { is_provided = false; id }
+ | None ->
+ (* Must be a provided method *)
+ let _, id =
+ List.find (fun (s, _) -> s = method_name) trait_decl.provided_methods
+ in
+ { is_provided = true; id = Option.get id }
+
+let trait_decl_is_empty (trait_decl : trait_decl) : bool =
+ let {
+ def_id = _;
+ name = _;
+ generics = _;
+ preds = _;
+ parent_clauses;
+ consts;
+ types;
+ required_methods;
+ provided_methods;
+ } =
+ trait_decl
+ in
+ parent_clauses = [] && consts = [] && types = [] && required_methods = []
+ && provided_methods = []
+
+let trait_impl_is_empty (trait_impl : trait_impl) : bool =
+ let {
+ def_id = _;
+ name = _;
+ impl_trait = _;
+ generics = _;
+ preds = _;
+ parent_trait_refs;
+ consts;
+ types;
+ required_methods;
+ provided_methods;
+ } =
+ trait_impl
+ in
+ parent_trait_refs = [] && consts = [] && types = [] && required_methods = []
+ && provided_methods = []
diff --git a/compiler/ReorderDecls.ml b/compiler/ReorderDecls.ml
index fc4744bc..10b68da3 100644
--- a/compiler/ReorderDecls.ml
+++ b/compiler/ReorderDecls.ml
@@ -38,14 +38,16 @@ let compute_body_fun_deps (e : texpression) : FunIdSet.t =
method! visit_qualif _ id =
match id.id with
- | FunOrOp (Unop _ | Binop _) | Global _ | AdtCons _ | Proj _ -> ()
+ | FunOrOp (Unop _ | Binop _)
+ | Global _ | AdtCons _ | Proj _ | TraitConst _ ->
+ ()
| FunOrOp (Fun fid) -> (
match fid with
| Pure _ -> ()
| FromLlbc (fid, lp_id, rg_id) -> (
match fid with
- | Assumed _ -> ()
- | Regular fid ->
+ | FunId (Assumed _) -> ()
+ | TraitMethod (_, _, fid) | FunId (Regular fid) ->
let id = { def_id = fid; lp_id; rg_id } in
ids := FunIdSet.add id !ids))
end
diff --git a/compiler/Substitute.ml b/compiler/Substitute.ml
index 38850243..23f618e2 100644
--- a/compiler/Substitute.ml
+++ b/compiler/Substitute.ml
@@ -9,51 +9,70 @@ module E = Expressions
module A = LlbcAst
module C = Contexts
-(** Substitute types variables and regions in a type. *)
-let ty_substitute (rsubst : 'r1 -> 'r2) (tsubst : T.TypeVarId.id -> 'r2 T.ty)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (ty : 'r1 T.ty) :
- 'r2 T.ty =
- let open T in
- let visitor =
- object
- inherit [_] map_ty
- method visit_'r _ r = rsubst r
- method! visit_TypeVar _ id = tsubst id
+type ('r1, 'r2) subst = {
+ r_subst : 'r1 -> 'r2;
+ ty_subst : T.TypeVarId.id -> 'r2 T.ty;
+ cg_subst : T.ConstGenericVarId.id -> T.const_generic;
+ (** Substitution from *local* trait clause to trait instance *)
+ tr_subst : T.TraitClauseId.id -> 'r2 T.trait_instance_id;
+ (** Substitution for the [Self] trait instance *)
+ tr_self : 'r2 T.trait_instance_id;
+}
+
+let ty_substitute_visitor (subst : ('r1, 'r2) subst) =
+ object
+ inherit [_] T.map_ty
+ method visit_'r _ r = subst.r_subst r
+ method! visit_TypeVar _ id = subst.ty_subst id
- method! visit_type_var_id _ _ =
- (* We should never get here because we reimplemented [visit_TypeVar] *)
- raise (Failure "Unexpected")
+ method! visit_type_var_id _ _ =
+ (* We should never get here because we reimplemented [visit_TypeVar] *)
+ raise (Failure "Unexpected")
- method! visit_ConstGenericVar _ id = cgsubst id
+ method! visit_ConstGenericVar _ id = subst.cg_subst id
- method! visit_const_generic_var_id _ _ =
- (* We should never get here because we reimplemented [visit_Var] *)
- raise (Failure "Unexpected")
- end
- in
+ method! visit_const_generic_var_id _ _ =
+ (* We should never get here because we reimplemented [visit_Var] *)
+ raise (Failure "Unexpected")
- visitor#visit_ty () ty
+ method! visit_Clause _ id = subst.tr_subst id
+ method! visit_Self _ = subst.tr_self
+ end
-let rty_substitute (rsubst : T.RegionId.id -> T.RegionId.id)
- (tsubst : T.TypeVarId.id -> T.rty)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (ty : T.rty) : T.rty =
- let rsubst r =
- match r with T.Static -> T.Static | T.Var rid -> T.Var (rsubst rid)
- in
- ty_substitute rsubst tsubst cgsubst ty
+(** Substitute types variables and regions in a type.
-let ety_substitute (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (ty : T.ety) : T.ety =
- let rsubst r = r in
- ty_substitute rsubst tsubst cgsubst ty
+ **IMPORTANT**: this doesn't normalize the types.
+ *)
+let ty_substitute (subst : ('r1, 'r2) subst) (ty : 'r1 T.ty) : 'r2 T.ty =
+ let visitor = ty_substitute_visitor subst in
+ visitor#visit_ty () ty
+
+(** **IMPORTANT**: this doesn't normalize the types. *)
+let trait_ref_substitute (subst : ('r1, 'r2) subst) (tr : 'r1 T.trait_ref) :
+ 'r2 T.trait_ref =
+ let visitor = ty_substitute_visitor subst in
+ visitor#visit_trait_ref () tr
+
+(** **IMPORTANT**: this doesn't normalize the types. *)
+let generic_args_substitute (subst : ('r1, 'r2) subst) (g : 'r1 T.generic_args)
+ : 'r2 T.generic_args =
+ let visitor = ty_substitute_visitor subst in
+ visitor#visit_generic_args () g
+
+let erase_regions_subst : ('r, T.erased_region) subst =
+ {
+ r_subst = (fun _ -> T.Erased);
+ ty_subst = (fun vid -> T.TypeVar vid);
+ cg_subst = (fun id -> T.ConstGenericVar id);
+ tr_subst = (fun id -> T.Clause id);
+ tr_self = T.Self;
+ }
(** Convert an {!T.rty} to an {!T.ety} by erasing the region variables *)
-let erase_regions (ty : T.rty) : T.ety =
- ty_substitute
- (fun _ -> T.Erased)
- (fun vid -> T.TypeVar vid)
- (fun id -> T.ConstGenericVar id)
- ty
+let erase_regions (ty : 'r T.ty) : T.ety = ty_substitute erase_regions_subst ty
+
+let trait_ref_erase_regions (tr : 'r T.trait_ref) : T.etrait_ref =
+ trait_ref_substitute erase_regions_subst tr
(** Generate fresh regions for region variables.
@@ -78,18 +97,20 @@ let fresh_regions_with_substs (region_vars : T.region_var list) :
(* Generate the substitution from region var id to region *)
let rid_subst id = T.RegionVarId.Map.find id rid_map in
(* Generate the substitution from region to region *)
- let rsubst r =
+ let r_subst r =
match r with T.Static -> T.Static | T.Var id -> T.Var (rid_subst id)
in
(* Return *)
- (fresh_region_ids, rid_subst, rsubst)
+ (fresh_region_ids, rid_subst, r_subst)
-(** Erase the regions in a type and substitute the type variables *)
-let erase_regions_substitute_types (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic)
- (ty : 'r T.region T.ty) : T.ety =
- let rsubst (_ : 'r T.region) : T.erased_region = T.Erased in
- ty_substitute rsubst tsubst cgsubst ty
+(** Erase the regions in a type and perform a substitution *)
+let erase_regions_substitute_types (ty_subst : T.TypeVarId.id -> T.ety)
+ (cg_subst : T.ConstGenericVarId.id -> T.const_generic)
+ (tr_subst : T.TraitClauseId.id -> T.etrait_instance_id)
+ (tr_self : T.etrait_instance_id) (ty : 'r T.ty) : T.ety =
+ let r_subst (_ : 'r) : T.erased_region = T.Erased in
+ let subst = { r_subst; ty_subst; cg_subst; tr_subst; tr_self } in
+ ty_substitute subst ty
(** Create a region substitution from a list of region variable ids and a list of
regions (with which to substitute the region variable ids *)
@@ -146,16 +167,81 @@ let make_const_generic_subst_from_vars (vars : T.const_generic_var list)
(List.map (fun (x : T.const_generic_var) -> x.T.index) vars)
cgs
-(** Instantiate the type variables in an ADT definition, and return, for
- every variant, the list of the types of its fields *)
-let type_decl_get_instantiated_variants_fields_rtypes (def : T.type_decl)
- (regions : T.RegionId.id T.region list) (types : T.rty list)
- (cgs : T.const_generic list) : (T.VariantId.id option * T.rty list) list =
- let r_subst = make_region_subst_from_vars def.T.region_params regions in
- let ty_subst = make_type_subst_from_vars def.T.type_params types in
+(** Create a trait substitution from a list of trait clause ids and a list of
+ trait refs *)
+let make_trait_subst (clause_ids : T.TraitClauseId.id list)
+ (trs : 'r T.trait_ref list) : T.TraitClauseId.id -> 'r T.trait_instance_id =
+ let ls = List.combine clause_ids trs in
+ let mp =
+ List.fold_left
+ (fun mp (k, v) -> T.TraitClauseId.Map.add k (T.TraitRef v) mp)
+ T.TraitClauseId.Map.empty ls
+ in
+ fun id -> T.TraitClauseId.Map.find id mp
+
+let make_trait_subst_from_clauses (clauses : T.trait_clause list)
+ (trs : 'r T.trait_ref list) : T.TraitClauseId.id -> 'r T.trait_instance_id =
+ make_trait_subst
+ (List.map (fun (x : T.trait_clause) -> x.T.clause_id) clauses)
+ trs
+
+let make_subst_from_generics (params : T.generic_params)
+ (args : 'r T.region T.generic_args)
+ (tr_self : 'r T.region T.trait_instance_id) :
+ (T.region_var_id T.region, 'r T.region) subst =
+ let r_subst = make_region_subst_from_vars params.T.regions args.T.regions in
+ let ty_subst = make_type_subst_from_vars params.T.types args.T.types in
let cg_subst =
- make_const_generic_subst_from_vars def.T.const_generic_params cgs
+ make_const_generic_subst_from_vars params.T.const_generics
+ args.T.const_generics
+ in
+ let tr_subst =
+ make_trait_subst_from_clauses params.T.trait_clauses args.T.trait_refs
+ in
+ { r_subst; ty_subst; cg_subst; tr_subst; tr_self }
+
+let make_subst_from_generics_no_regions :
+ 'r.
+ T.generic_params ->
+ 'r T.generic_args ->
+ 'r T.trait_instance_id ->
+ (T.region_var_id T.region, 'r) subst =
+ fun params args tr_self ->
+ let r_subst _ = raise (Failure "Unexpected region") in
+ let ty_subst = make_type_subst_from_vars params.T.types args.T.types in
+ let cg_subst =
+ make_const_generic_subst_from_vars params.T.const_generics
+ args.T.const_generics
+ in
+ let tr_subst =
+ make_trait_subst_from_clauses params.T.trait_clauses args.T.trait_refs
+ in
+ { r_subst; ty_subst; cg_subst; tr_subst; tr_self }
+
+let make_esubst_from_generics (params : T.generic_params)
+ (generics : T.egeneric_args) (tr_self : T.etrait_instance_id) =
+ let r_subst _ = T.Erased in
+ let ty_subst = make_type_subst_from_vars params.types generics.T.types in
+ let cg_subst =
+ make_const_generic_subst_from_vars params.const_generics
+ generics.T.const_generics
+ in
+ let tr_subst =
+ make_trait_subst_from_clauses params.trait_clauses generics.T.trait_refs
in
+ { r_subst; ty_subst; cg_subst; tr_subst; tr_self }
+
+(** Instantiate the type variables in an ADT definition, and return, for
+ every variant, the list of the types of its fields.
+
+ **IMPORTANT**: this function doesn't normalize the types, you may want to
+ use the [AssociatedTypes] equivalent instead.
+*)
+let type_decl_get_instantiated_variants_fields_rtypes (def : T.type_decl)
+ (generics : T.rgeneric_args) : (T.VariantId.id option * T.rty list) list =
+ (* There shouldn't be any reference to Self *)
+ let tr_self = T.UnknownTrait __FUNCTION__ in
+ let subst = make_subst_from_generics def.T.generics generics tr_self in
let (variants_fields : (T.VariantId.id option * T.field list) list) =
match def.T.kind with
| T.Enum variants ->
@@ -171,191 +257,220 @@ let type_decl_get_instantiated_variants_fields_rtypes (def : T.type_decl)
in
List.map
(fun (id, fields) ->
- ( id,
- List.map
- (fun f -> ty_substitute r_subst ty_subst cg_subst f.T.field_ty)
- fields ))
+ (id, List.map (fun f -> ty_substitute subst f.T.field_ty) fields))
variants_fields
(** Instantiate the type variables in an ADT definition, and return the list
- of types of the fields for the chosen variant *)
+ of types of the fields for the chosen variant.
+
+ **IMPORTANT**: this function doesn't normalize the types, you may want to
+ use the [AssociatedTypes] equivalent instead.
+*)
let type_decl_get_instantiated_field_rtypes (def : T.type_decl)
- (opt_variant_id : T.VariantId.id option)
- (regions : T.RegionId.id T.region list) (types : T.rty list)
- (cgs : T.const_generic list) : T.rty list =
- let r_subst = make_region_subst_from_vars def.T.region_params regions in
- let ty_subst = make_type_subst_from_vars def.T.type_params types in
- let cg_subst =
- make_const_generic_subst_from_vars def.T.const_generic_params cgs
- in
+ (opt_variant_id : T.VariantId.id option) (generics : T.rgeneric_args) :
+ T.rty list =
+ (* For now, check that there are no clauses - otherwise we might need
+ to normalize the types *)
+ assert (def.generics.trait_clauses = []);
+ (* There shouldn't be any reference to Self *)
+ let tr_self = T.UnknownTrait __FUNCTION__ in
+ let subst = make_subst_from_generics def.T.generics generics tr_self in
let fields = TU.type_decl_get_fields def opt_variant_id in
- List.map
- (fun f -> ty_substitute r_subst ty_subst cg_subst f.T.field_ty)
- fields
+ List.map (fun f -> ty_substitute subst f.T.field_ty) fields
(** Return the types of the properly instantiated ADT's variant, provided a
- context *)
+ context.
+
+ **IMPORTANT**: this function doesn't normalize the types, you may want to
+ use the [AssociatedTypes] equivalent instead.
+*)
let ctx_adt_get_instantiated_field_rtypes (ctx : C.eval_ctx)
(def_id : T.TypeDeclId.id) (opt_variant_id : T.VariantId.id option)
- (regions : T.RegionId.id T.region list) (types : T.rty list)
- (cgs : T.const_generic list) : T.rty list =
+ (generics : T.rgeneric_args) : T.rty list =
let def = C.ctx_lookup_type_decl ctx def_id in
- type_decl_get_instantiated_field_rtypes def opt_variant_id regions types cgs
+ type_decl_get_instantiated_field_rtypes def opt_variant_id generics
(** Return the types of the properly instantiated ADT value (note that
- here, ADT is understood in its broad meaning: ADT, assumed value or tuple) *)
+ here, ADT is understood in its broad meaning: ADT, assumed value or tuple).
+
+ **IMPORTANT**: this function doesn't normalize the types, you may want to
+ use the [AssociatedTypes] equivalent instead.
+ *)
let ctx_adt_value_get_instantiated_field_rtypes (ctx : C.eval_ctx)
- (adt : V.adt_value) (id : T.type_id)
- (region_params : T.RegionId.id T.region list) (type_params : T.rty list)
- (cg_params : T.const_generic list) : T.rty list =
+ (adt : V.adt_value) (id : T.type_id) (generics : T.rgeneric_args) :
+ T.rty list =
match id with
| T.AdtId id ->
(* Retrieve the types of the fields *)
- ctx_adt_get_instantiated_field_rtypes ctx id adt.V.variant_id
- region_params type_params cg_params
+ ctx_adt_get_instantiated_field_rtypes ctx id adt.V.variant_id generics
| T.Tuple ->
- assert (List.length region_params = 0);
- type_params
+ assert (generics.regions = []);
+ generics.types
| T.Assumed aty -> (
match aty with
- | T.Box | T.Vec ->
- assert (List.length region_params = 0);
- assert (List.length type_params = 1);
- assert (List.length cg_params = 0);
- type_params
- | T.Option ->
- assert (List.length region_params = 0);
- assert (List.length type_params = 1);
- assert (List.length cg_params = 0);
- if adt.V.variant_id = Some T.option_some_id then type_params
- else if adt.V.variant_id = Some T.option_none_id then []
- else raise (Failure "Unreachable")
- | T.Range ->
- assert (List.length region_params = 0);
- assert (List.length type_params = 1);
- assert (List.length cg_params = 0);
- type_params
+ | T.Box ->
+ assert (generics.regions = []);
+ assert (List.length generics.types = 1);
+ assert (generics.const_generics = []);
+ generics.types
| T.Array | T.Slice | T.Str ->
(* Those types don't have fields *)
raise (Failure "Unreachable"))
(** Instantiate the type variables in an ADT definition, and return the list
- of types of the fields for the chosen variant *)
+ of types of the fields for the chosen variant.
+
+ **IMPORTANT**: this function doesn't normalize the types, you may want to
+ use the [AssociatedTypes] equivalent instead.
+*)
let type_decl_get_instantiated_field_etypes (def : T.type_decl)
- (opt_variant_id : T.VariantId.id option) (types : T.ety list)
- (cgs : T.const_generic list) : T.ety list =
- let ty_subst = make_type_subst_from_vars def.T.type_params types in
- let cg_subst =
- make_const_generic_subst_from_vars def.T.const_generic_params cgs
+ (opt_variant_id : T.VariantId.id option) (generics : T.egeneric_args) :
+ T.ety list =
+ (* For now, check that there are no clauses - otherwise we might need
+ to normalize the types *)
+ assert (def.generics.trait_clauses = []);
+ (* There shouldn't be any reference to Self *)
+ let tr_self : T.erased_region T.trait_instance_id =
+ T.UnknownTrait __FUNCTION__
+ in
+ let { r_subst = _; ty_subst; cg_subst; tr_subst; tr_self } =
+ make_esubst_from_generics def.T.generics generics tr_self
in
let fields = TU.type_decl_get_fields def opt_variant_id in
List.map
- (fun f -> erase_regions_substitute_types ty_subst cg_subst f.T.field_ty)
+ (fun (f : T.field) ->
+ erase_regions_substitute_types ty_subst cg_subst tr_subst tr_self
+ f.T.field_ty)
fields
(** Return the types of the properly instantiated ADT's variant, provided a
- context *)
+ context.
+
+ **IMPORTANT**: this function doesn't normalize the types, you may want to
+ use the [AssociatedTypes] equivalent instead.
+ *)
let ctx_adt_get_instantiated_field_etypes (ctx : C.eval_ctx)
(def_id : T.TypeDeclId.id) (opt_variant_id : T.VariantId.id option)
- (types : T.ety list) (cgs : T.const_generic list) : T.ety list =
+ (generics : T.egeneric_args) : T.ety list =
let def = C.ctx_lookup_type_decl ctx def_id in
- type_decl_get_instantiated_field_etypes def opt_variant_id types cgs
+ type_decl_get_instantiated_field_etypes def opt_variant_id generics
-let statement_substitute_visitor (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) =
+let statement_substitute_visitor
+ (subst : (T.erased_region, T.erased_region) subst) =
+ (* Keep in synch with [ty_substitute_visitor] *)
object
inherit [_] A.map_statement
- method! visit_ety _ ty = ety_substitute tsubst cgsubst ty
- method! visit_ConstGenericVar _ id = cgsubst id
+ method! visit_'r _ r = subst.r_subst r
+ method! visit_TypeVar _ id = subst.ty_subst id
+
+ method! visit_type_var_id _ _ =
+ (* We should never get here because we reimplemented [visit_TypeVar] *)
+ raise (Failure "Unexpected")
+
+ method! visit_ConstGenericVar _ id = subst.cg_subst id
method! visit_const_generic_var_id _ _ =
(* We should never get here because we reimplemented [visit_Var] *)
raise (Failure "Unexpected")
+
+ method! visit_Clause _ id = subst.tr_subst id
+ method! visit_Self _ = subst.tr_self
end
(** Apply a type substitution to a place *)
-let place_substitute (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (p : E.place) :
- E.place =
+let place_substitute (subst : (T.erased_region, T.erased_region) subst)
+ (p : E.place) : E.place =
(* There is in fact nothing to do *)
- (statement_substitute_visitor tsubst cgsubst)#visit_place () p
+ (statement_substitute_visitor subst)#visit_place () p
(** Apply a type substitution to an operand *)
-let operand_substitute (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (op : E.operand) :
- E.operand =
- (statement_substitute_visitor tsubst cgsubst)#visit_operand () op
+let operand_substitute (subst : (T.erased_region, T.erased_region) subst)
+ (op : E.operand) : E.operand =
+ (statement_substitute_visitor subst)#visit_operand () op
(** Apply a type substitution to an rvalue *)
-let rvalue_substitute (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (rv : E.rvalue) :
- E.rvalue =
- (statement_substitute_visitor tsubst cgsubst)#visit_rvalue () rv
+let rvalue_substitute (subst : (T.erased_region, T.erased_region) subst)
+ (rv : E.rvalue) : E.rvalue =
+ (statement_substitute_visitor subst)#visit_rvalue () rv
(** Apply a type substitution to an assertion *)
-let assertion_substitute (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (a : A.assertion) :
- A.assertion =
- (statement_substitute_visitor tsubst cgsubst)#visit_assertion () a
+let assertion_substitute (subst : (T.erased_region, T.erased_region) subst)
+ (a : A.assertion) : A.assertion =
+ (statement_substitute_visitor subst)#visit_assertion () a
(** Apply a type substitution to a call *)
-let call_substitute (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (call : A.call) :
- A.call =
- (statement_substitute_visitor tsubst cgsubst)#visit_call () call
+let call_substitute (subst : (T.erased_region, T.erased_region) subst)
+ (call : A.call) : A.call =
+ (statement_substitute_visitor subst)#visit_call () call
(** Apply a type substitution to a statement *)
-let statement_substitute (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (st : A.statement) :
- A.statement =
- (statement_substitute_visitor tsubst cgsubst)#visit_statement () st
+let statement_substitute (subst : (T.erased_region, T.erased_region) subst)
+ (st : A.statement) : A.statement =
+ (statement_substitute_visitor subst)#visit_statement () st
(** Apply a type substitution to a function body. Return the local variables
and the body. *)
-let fun_body_substitute_in_body (tsubst : T.TypeVarId.id -> T.ety)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (body : A.fun_body) :
+let fun_body_substitute_in_body
+ (subst : (T.erased_region, T.erased_region) subst) (body : A.fun_body) :
A.var list * A.statement =
- let rsubst r = r in
let locals =
List.map
- (fun (v : A.var) ->
- { v with A.var_ty = ty_substitute rsubst tsubst cgsubst v.A.var_ty })
+ (fun (v : A.var) -> { v with A.var_ty = ty_substitute subst v.A.var_ty })
body.A.locals
in
- let body = statement_substitute tsubst cgsubst body.body in
+ let body = statement_substitute subst body.body in
(locals, body)
-(** Substitute a function signature *)
+let trait_type_constraint_substitute (subst : ('r1, 'r2) subst)
+ (ttc : 'r1 T.trait_type_constraint) : 'r2 T.trait_type_constraint =
+ let { T.trait_ref; generics; type_name; ty } = ttc in
+ let visitor = ty_substitute_visitor subst in
+ let trait_ref = visitor#visit_trait_ref () trait_ref in
+ let generics = visitor#visit_generic_args () generics in
+ let ty = visitor#visit_ty () ty in
+ { T.trait_ref; generics; type_name; ty }
+
+(** Substitute a function signature.
+
+ **IMPORTANT:** this function doesn't normalize the types.
+ *)
let substitute_signature (asubst : T.RegionGroupId.id -> V.AbstractionId.id)
- (rsubst : T.RegionVarId.id -> T.RegionId.id)
- (tsubst : T.TypeVarId.id -> T.rty)
- (cgsubst : T.ConstGenericVarId.id -> T.const_generic) (sg : A.fun_sig) :
- A.inst_fun_sig =
- let rsubst' (r : T.RegionVarId.id T.region) : T.RegionId.id T.region =
- match r with T.Static -> T.Static | T.Var rid -> T.Var (rsubst rid)
+ (r_subst : T.RegionVarId.id -> T.RegionId.id)
+ (ty_subst : T.TypeVarId.id -> T.rty)
+ (cg_subst : T.ConstGenericVarId.id -> T.const_generic)
+ (tr_subst : T.TraitClauseId.id -> T.rtrait_instance_id)
+ (tr_self : T.rtrait_instance_id) (sg : A.fun_sig) : A.inst_fun_sig =
+ let r_subst' (r : T.RegionVarId.id T.region) : T.RegionId.id T.region =
+ match r with T.Static -> T.Static | T.Var rid -> T.Var (r_subst rid)
in
- let inputs = List.map (ty_substitute rsubst' tsubst cgsubst) sg.A.inputs in
- let output = ty_substitute rsubst' tsubst cgsubst sg.A.output in
+ let subst = { r_subst = r_subst'; ty_subst; cg_subst; tr_subst; tr_self } in
+ let inputs = List.map (ty_substitute subst) sg.A.inputs in
+ let output = ty_substitute subst sg.A.output in
let subst_region_group (rg : T.region_var_group) : A.abs_region_group =
let id = asubst rg.id in
- let regions = List.map rsubst rg.regions in
+ let regions = List.map r_subst rg.regions in
let parents = List.map asubst rg.parents in
{ id; regions; parents }
in
let regions_hierarchy = List.map subst_region_group sg.A.regions_hierarchy in
- { A.regions_hierarchy; inputs; output }
+ let trait_type_constraints =
+ List.map
+ (trait_type_constraint_substitute subst)
+ sg.preds.trait_type_constraints
+ in
+ { A.inputs; output; regions_hierarchy; trait_type_constraints }
-(** Substitute type variable identifiers in a type *)
-let ty_substitute_ids (tsubst : T.TypeVarId.id -> T.TypeVarId.id)
- (cgsubst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id) (ty : 'r T.ty)
+(** Substitute variable identifiers in a type *)
+let ty_substitute_ids (ty_subst : T.TypeVarId.id -> T.TypeVarId.id)
+ (cg_subst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id) (ty : 'r T.ty)
: 'r T.ty =
let open T in
let visitor =
object
inherit [_] map_ty
method visit_'r _ r = r
- method! visit_type_var_id _ id = tsubst id
- method! visit_const_generic_var_id _ id = cgsubst id
+ method! visit_type_var_id _ id = ty_subst id
+ method! visit_const_generic_var_id _ id = cg_subst id
end
in
@@ -371,10 +486,10 @@ let ty_substitute_ids (tsubst : T.TypeVarId.id -> T.TypeVarId.id)
[visit_'r] if we define a class which visits objects of types [ety] and [rty]
while inheriting a class which visit [ty]...
*)
-let subst_ids_visitor (rsubst : T.RegionId.id -> T.RegionId.id)
+let subst_ids_visitor (r_subst : T.RegionId.id -> T.RegionId.id)
(rvsubst : T.RegionVarId.id -> T.RegionVarId.id)
- (tsubst : T.TypeVarId.id -> T.TypeVarId.id)
- (cgsubst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
+ (ty_subst : T.TypeVarId.id -> T.TypeVarId.id)
+ (cg_subst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
(ssubst : V.SymbolicValueId.id -> V.SymbolicValueId.id)
(bsubst : V.BorrowId.id -> V.BorrowId.id)
(asubst : V.AbstractionId.id -> V.AbstractionId.id) =
@@ -383,10 +498,10 @@ let subst_ids_visitor (rsubst : T.RegionId.id -> T.RegionId.id)
inherit [_] T.map_ty
method visit_'r _ r =
- match r with T.Static -> T.Static | T.Var rid -> T.Var (rsubst rid)
+ match r with T.Static -> T.Static | T.Var rid -> T.Var (r_subst rid)
- method! visit_type_var_id _ id = tsubst id
- method! visit_const_generic_var_id _ id = cgsubst id
+ method! visit_type_var_id _ id = ty_subst id
+ method! visit_const_generic_var_id _ id = cg_subst id
end
in
@@ -395,7 +510,7 @@ let subst_ids_visitor (rsubst : T.RegionId.id -> T.RegionId.id)
inherit [_] C.map_env
method! visit_borrow_id _ bid = bsubst bid
method! visit_loan_id _ bid = bsubst bid
- method! visit_ety _ ty = ty_substitute_ids tsubst cgsubst ty
+ method! visit_ety _ ty = ty_substitute_ids ty_subst cg_subst ty
method! visit_rty env ty = subst_rty#visit_ty env ty
method! visit_symbolic_value_id _ id = ssubst id
@@ -405,7 +520,7 @@ let subst_ids_visitor (rsubst : T.RegionId.id -> T.RegionId.id)
(** We *do* visit meta-values *)
method! visit_mvalue env v = self#visit_typed_value env v
- method! visit_region_id _ id = rsubst id
+ method! visit_region_id _ id = r_subst id
method! visit_region_var_id _ id = rvsubst id
method! visit_abstraction_id _ id = asubst id
end
@@ -425,20 +540,20 @@ let subst_ids_visitor (rsubst : T.RegionId.id -> T.RegionId.id)
method visit_env (env : C.env) : C.env = visitor#visit_env () env
end
-let typed_value_subst_ids (rsubst : T.RegionId.id -> T.RegionId.id)
+let typed_value_subst_ids (r_subst : T.RegionId.id -> T.RegionId.id)
(rvsubst : T.RegionVarId.id -> T.RegionVarId.id)
- (tsubst : T.TypeVarId.id -> T.TypeVarId.id)
- (cgsubst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
+ (ty_subst : T.TypeVarId.id -> T.TypeVarId.id)
+ (cg_subst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
(ssubst : V.SymbolicValueId.id -> V.SymbolicValueId.id)
(bsubst : V.BorrowId.id -> V.BorrowId.id) (v : V.typed_value) :
V.typed_value =
let asubst _ = raise (Failure "Unreachable") in
- (subst_ids_visitor rsubst rvsubst tsubst cgsubst ssubst bsubst asubst)
+ (subst_ids_visitor r_subst rvsubst ty_subst cg_subst ssubst bsubst asubst)
#visit_typed_value v
-let typed_value_subst_rids (rsubst : T.RegionId.id -> T.RegionId.id)
+let typed_value_subst_rids (r_subst : T.RegionId.id -> T.RegionId.id)
(v : V.typed_value) : V.typed_value =
- typed_value_subst_ids rsubst
+ typed_value_subst_ids r_subst
(fun x -> x)
(fun x -> x)
(fun x -> x)
@@ -446,41 +561,41 @@ let typed_value_subst_rids (rsubst : T.RegionId.id -> T.RegionId.id)
(fun x -> x)
v
-let typed_avalue_subst_ids (rsubst : T.RegionId.id -> T.RegionId.id)
+let typed_avalue_subst_ids (r_subst : T.RegionId.id -> T.RegionId.id)
(rvsubst : T.RegionVarId.id -> T.RegionVarId.id)
- (tsubst : T.TypeVarId.id -> T.TypeVarId.id)
- (cgsubst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
+ (ty_subst : T.TypeVarId.id -> T.TypeVarId.id)
+ (cg_subst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
(ssubst : V.SymbolicValueId.id -> V.SymbolicValueId.id)
(bsubst : V.BorrowId.id -> V.BorrowId.id) (v : V.typed_avalue) :
V.typed_avalue =
let asubst _ = raise (Failure "Unreachable") in
- (subst_ids_visitor rsubst rvsubst tsubst cgsubst ssubst bsubst asubst)
+ (subst_ids_visitor r_subst rvsubst ty_subst cg_subst ssubst bsubst asubst)
#visit_typed_avalue v
-let abs_subst_ids (rsubst : T.RegionId.id -> T.RegionId.id)
+let abs_subst_ids (r_subst : T.RegionId.id -> T.RegionId.id)
(rvsubst : T.RegionVarId.id -> T.RegionVarId.id)
- (tsubst : T.TypeVarId.id -> T.TypeVarId.id)
- (cgsubst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
+ (ty_subst : T.TypeVarId.id -> T.TypeVarId.id)
+ (cg_subst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
(ssubst : V.SymbolicValueId.id -> V.SymbolicValueId.id)
(bsubst : V.BorrowId.id -> V.BorrowId.id)
(asubst : V.AbstractionId.id -> V.AbstractionId.id) (x : V.abs) : V.abs =
- (subst_ids_visitor rsubst rvsubst tsubst cgsubst ssubst bsubst asubst)
+ (subst_ids_visitor r_subst rvsubst ty_subst cg_subst ssubst bsubst asubst)
#visit_abs x
-let env_subst_ids (rsubst : T.RegionId.id -> T.RegionId.id)
+let env_subst_ids (r_subst : T.RegionId.id -> T.RegionId.id)
(rvsubst : T.RegionVarId.id -> T.RegionVarId.id)
- (tsubst : T.TypeVarId.id -> T.TypeVarId.id)
- (cgsubst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
+ (ty_subst : T.TypeVarId.id -> T.TypeVarId.id)
+ (cg_subst : T.ConstGenericVarId.id -> T.ConstGenericVarId.id)
(ssubst : V.SymbolicValueId.id -> V.SymbolicValueId.id)
(bsubst : V.BorrowId.id -> V.BorrowId.id)
(asubst : V.AbstractionId.id -> V.AbstractionId.id) (x : C.env) : C.env =
- (subst_ids_visitor rsubst rvsubst tsubst cgsubst ssubst bsubst asubst)
+ (subst_ids_visitor r_subst rvsubst ty_subst cg_subst ssubst bsubst asubst)
#visit_env x
-let typed_avalue_subst_rids (rsubst : T.RegionId.id -> T.RegionId.id)
+let typed_avalue_subst_rids (r_subst : T.RegionId.id -> T.RegionId.id)
(x : V.typed_avalue) : V.typed_avalue =
let asubst _ = raise (Failure "Unreachable") in
- (subst_ids_visitor rsubst
+ (subst_ids_visitor r_subst
(fun x -> x)
(fun x -> x)
(fun x -> x)
@@ -490,9 +605,9 @@ let typed_avalue_subst_rids (rsubst : T.RegionId.id -> T.RegionId.id)
#visit_typed_avalue
x
-let env_subst_rids (rsubst : T.RegionId.id -> T.RegionId.id) (x : C.env) : C.env
- =
- (subst_ids_visitor rsubst
+let env_subst_rids (r_subst : T.RegionId.id -> T.RegionId.id) (x : C.env) :
+ C.env =
+ (subst_ids_visitor r_subst
(fun x -> x)
(fun x -> x)
(fun x -> x)
diff --git a/compiler/SymbolicAst.ml b/compiler/SymbolicAst.ml
index 7dc94dcd..4df8fec7 100644
--- a/compiler/SymbolicAst.ml
+++ b/compiler/SymbolicAst.ml
@@ -29,7 +29,7 @@ type mplace = {
[@@deriving show]
type call_id =
- | Fun of A.fun_id * V.FunCallId.id
+ | Fun of A.fun_id_or_trait_method_ref * V.FunCallId.id
(** A "regular" function (i.e., a function which is not a primitive operation) *)
| Unop of E.unop
| Binop of E.binop
@@ -43,10 +43,7 @@ type call = {
borrows (we need to perform lookups).
*)
abstractions : V.AbstractionId.id list;
- (* TODO: rename to "...args" *)
- type_params : T.ety list;
- (* TODO: rename to "...args" *)
- const_generic_params : T.const_generic list;
+ generics : T.egeneric_args;
args : V.typed_value list;
args_places : mplace option list; (** Meta information *)
dest : V.symbolic_value;
@@ -79,6 +76,9 @@ class ['self] iter_expression_base =
method visit_loop_id : 'env -> V.loop_id -> unit = fun _ _ -> ()
method visit_variant_id : 'env -> variant_id -> unit = fun _ _ -> ()
+ method visit_const_generic_var_id : 'env -> T.const_generic_var_id -> unit =
+ fun _ _ -> ()
+
method visit_symbolic_value_id : 'env -> V.symbolic_value_id -> unit =
fun _ _ -> ()
@@ -120,6 +120,9 @@ class ['self] iter_expression_base =
method visit_symbolic_expansion : 'env -> V.symbolic_expansion -> unit =
fun _ _ -> ()
+
+ method visit_etrait_ref : 'env -> T.etrait_ref -> unit = fun _ _ -> ()
+ method visit_egeneric_args : 'env -> T.egeneric_args -> unit = fun _ _ -> ()
end
(** **Rem.:** here, {!expression} is not at all equivalent to the expressions
@@ -171,14 +174,15 @@ type expression =
* expression
(** We introduce a new symbolic value, equal to some other value.
- This is used for instance when reorganizing the environment to compute
- fixed points: we duplicate some shared symbolic values to destructure
- the shared values, in order to make the environment a bit more general
- (while losing precision of course).
+ This is used for instance when reorganizing the environment to compute
+ fixed points: we duplicate some shared symbolic values to destructure
+ the shared values, in order to make the environment a bit more general
+ (while losing precision of course). We also use it to introduce symbolic
+ values when evaluating constant generics, or trait constants.
- The context is the evaluation context from before introducing the new
- value. It has the same purpose as for the {!Return} case.
- *)
+ The context is the evaluation context from before introducing the new
+ value. It has the same purpose as for the {!Return} case.
+ *)
| ForwardEnd of
Contexts.eval_ctx
* V.typed_value symbolic_value_id_map option
@@ -253,6 +257,11 @@ and value_aggregate =
| SingleValue of V.typed_value (** Regular case *)
| Array of V.typed_value list
(** This is used when introducing array aggregates *)
+ | ConstGenericValue of T.const_generic_var_id
+ (** This is used when evaluating a const generic value: in the interpreter,
+ we introduce a fresh symbolic value. *)
+ | TraitConstValue of T.etrait_ref * T.egeneric_args * string
+ (** A trait constant value *)
[@@deriving
show,
visitors
diff --git a/compiler/SymbolicToPure.ml b/compiler/SymbolicToPure.ml
index 3512270a..2ce8c706 100644
--- a/compiler/SymbolicToPure.ml
+++ b/compiler/SymbolicToPure.ml
@@ -4,6 +4,7 @@ open Pure
open PureUtils
module Id = Identifiers
module C = Contexts
+module A = LlbcAst
module S = SymbolicAst
module TA = TypesAnalysis
module L = Logging
@@ -52,6 +53,9 @@ type fun_context = {
type global_context = { llbc_global_decls : A.global_decl A.GlobalDeclId.Map.t }
[@@deriving show]
+type trait_decls_context = A.trait_decl A.TraitDeclId.Map.t [@@deriving show]
+type trait_impls_context = A.trait_impl A.TraitImplId.Map.t [@@deriving show]
+
(** Whenever we translate a function call or an ended abstraction, we
store the related information (this is useful when translating ended
children abstractions).
@@ -106,8 +110,7 @@ type loop_info = {
loop_id : LoopId.id;
input_vars : var list;
input_svl : V.symbolic_value list;
- type_args : ty list;
- const_generic_args : const_generic list;
+ generics : generic_args;
forward_inputs : texpression list option;
(** The forward inputs are initialized at [None] *)
forward_output_no_state_no_result : var option;
@@ -120,6 +123,8 @@ type bs_ctx = {
type_context : type_context;
fun_context : fun_context;
global_context : global_context;
+ trait_decls_ctx : trait_decls_context;
+ trait_impls_ctx : trait_impls_context;
fun_decl : A.fun_decl;
bid : T.RegionGroupId.id option; (** TODO: rename *)
sg : fun_sig;
@@ -201,34 +206,11 @@ type bs_ctx = {
}
[@@deriving show]
-let type_check_pattern (ctx : bs_ctx) (v : typed_pattern) : unit =
- let env = VarId.Map.empty in
- let ctx =
- {
- PureTypeCheck.type_decls = ctx.type_context.type_decls;
- global_decls = ctx.global_context.llbc_global_decls;
- env;
- }
- in
- let _ = PureTypeCheck.check_typed_pattern ctx v in
- ()
-
-let type_check_texpression (ctx : bs_ctx) (e : texpression) : unit =
- let env = VarId.Map.empty in
- let ctx =
- {
- PureTypeCheck.type_decls = ctx.type_context.type_decls;
- global_decls = ctx.global_context.llbc_global_decls;
- env;
- }
- in
- PureTypeCheck.check_texpression ctx e
-
(* TODO: move *)
let bs_ctx_to_ast_formatter (ctx : bs_ctx) : Print.Ast.ast_formatter =
Print.Ast.decls_and_fun_decl_to_ast_formatter ctx.type_context.llbc_type_decls
ctx.fun_context.llbc_fun_decls ctx.global_context.llbc_global_decls
- ctx.fun_decl
+ ctx.trait_decls_ctx ctx.trait_impls_ctx ctx.fun_decl
let bs_ctx_to_ctx_formatter (ctx : bs_ctx) : Print.Contexts.ctx_formatter =
let rvar_to_string = Print.Types.region_var_id_to_string in
@@ -246,16 +228,25 @@ let bs_ctx_to_ctx_formatter (ctx : bs_ctx) : Print.Contexts.ctx_formatter =
adt_variant_to_string = ast_fmt.adt_variant_to_string;
var_id_to_string;
adt_field_names = ast_fmt.adt_field_names;
+ trait_decl_id_to_string = ast_fmt.trait_decl_id_to_string;
+ trait_impl_id_to_string = ast_fmt.trait_impl_id_to_string;
+ trait_clause_id_to_string = ast_fmt.trait_clause_id_to_string;
}
let bs_ctx_to_pp_ast_formatter (ctx : bs_ctx) : PrintPure.ast_formatter =
- let type_params = ctx.fun_decl.signature.type_params in
- let cg_params = ctx.fun_decl.signature.const_generic_params in
+ let generics = ctx.fun_decl.signature.generics in
let type_decls = ctx.type_context.llbc_type_decls in
let fun_decls = ctx.fun_context.llbc_fun_decls in
let global_decls = ctx.global_context.llbc_global_decls in
- PrintPure.mk_ast_formatter type_decls fun_decls global_decls type_params
- cg_params
+ PrintPure.mk_ast_formatter type_decls fun_decls global_decls
+ ctx.trait_decls_ctx ctx.trait_impls_ctx generics.types
+ generics.const_generics
+
+let ctx_egeneric_args_to_string (ctx : bs_ctx) (args : T.egeneric_args) : string
+ =
+ let fmt = bs_ctx_to_ctx_formatter ctx in
+ let fmt = Print.PC.ctx_to_etype_formatter fmt in
+ Print.PT.egeneric_args_to_string fmt args
let symbolic_value_to_string (ctx : bs_ctx) (sv : V.symbolic_value) : string =
let fmt = bs_ctx_to_ctx_formatter ctx in
@@ -277,12 +268,11 @@ let rty_to_string (ctx : bs_ctx) (ty : T.rty) : string =
Print.PT.rty_to_string fmt ty
let type_decl_to_string (ctx : bs_ctx) (def : type_decl) : string =
- let type_params = def.type_params in
- let cg_params = def.const_generic_params in
let type_decls = ctx.type_context.llbc_type_decls in
let global_decls = ctx.global_context.llbc_global_decls in
let fmt =
- PrintPure.mk_type_formatter type_decls global_decls type_params cg_params
+ PrintPure.mk_type_formatter type_decls global_decls ctx.trait_decls_ctx
+ ctx.trait_impls_ctx def.generics.types def.generics.const_generics
in
PrintPure.type_decl_to_string fmt def
@@ -291,26 +281,27 @@ let texpression_to_string (ctx : bs_ctx) (e : texpression) : string =
PrintPure.texpression_to_string fmt false "" " " e
let fun_sig_to_string (ctx : bs_ctx) (sg : fun_sig) : string =
- let type_params = sg.type_params in
- let cg_params = sg.const_generic_params in
+ let type_params = sg.generics.types in
+ let cg_params = sg.generics.const_generics in
let type_decls = ctx.type_context.llbc_type_decls in
let fun_decls = ctx.fun_context.llbc_fun_decls in
let global_decls = ctx.global_context.llbc_global_decls in
let fmt =
- PrintPure.mk_ast_formatter type_decls fun_decls global_decls type_params
- cg_params
+ PrintPure.mk_ast_formatter type_decls fun_decls global_decls
+ ctx.trait_decls_ctx ctx.trait_impls_ctx type_params cg_params
in
PrintPure.fun_sig_to_string fmt sg
let fun_decl_to_string (ctx : bs_ctx) (def : Pure.fun_decl) : string =
- let type_params = def.signature.type_params in
- let cg_params = def.signature.const_generic_params in
+ let generics = def.signature.generics in
+ let type_params = generics.types in
+ let cg_params = generics.const_generics in
let type_decls = ctx.type_context.llbc_type_decls in
let fun_decls = ctx.fun_context.llbc_fun_decls in
let global_decls = ctx.global_context.llbc_global_decls in
let fmt =
- PrintPure.mk_ast_formatter type_decls fun_decls global_decls type_params
- cg_params
+ PrintPure.mk_ast_formatter type_decls fun_decls global_decls
+ ctx.trait_decls_ctx ctx.trait_impls_ctx type_params cg_params
in
PrintPure.fun_decl_to_string fmt def
@@ -328,17 +319,18 @@ let abs_to_string (ctx : bs_ctx) (abs : V.abs) : string =
Print.Values.abs_to_string fmt verbose indent indent_incr abs
let get_instantiated_fun_sig (fun_id : A.fun_id)
- (back_id : T.RegionGroupId.id option) (tys : ty list)
- (cgs : const_generic list) (ctx : bs_ctx) : inst_fun_sig =
+ (back_id : T.RegionGroupId.id option) (generics : generic_args)
+ (ctx : bs_ctx) : inst_fun_sig =
(* Lookup the non-instantiated function signature *)
let sg =
(RegularFunIdNotLoopMap.find (fun_id, back_id) ctx.fun_context.fun_sigs).sg
in
(* Create the substitution *)
- let tsubst = make_type_subst sg.type_params tys in
- let cgsubst = make_const_generic_subst sg.const_generic_params cgs in
+ (* There shouldn't be any reference to Self *)
+ let tr_self = UnknownTrait __FUNCTION__ in
+ let subst = make_subst_from_generics sg.generics generics tr_self in
(* Apply *)
- fun_sig_substitute tsubst cgsubst sg
+ fun_sig_substitute subst sg
let bs_ctx_lookup_llbc_type_decl (id : TypeDeclId.id) (ctx : bs_ctx) :
T.type_decl =
@@ -351,77 +343,128 @@ let bs_ctx_lookup_llbc_fun_decl (id : A.FunDeclId.id) (ctx : bs_ctx) :
(* TODO: move *)
let bs_ctx_lookup_local_function_sig (def_id : A.FunDeclId.id)
(back_id : T.RegionGroupId.id option) (ctx : bs_ctx) : fun_sig =
- let id = (A.Regular def_id, back_id) in
+ let id = (E.Regular def_id, back_id) in
(RegularFunIdNotLoopMap.find id ctx.fun_context.fun_sigs).sg
-let bs_ctx_register_forward_call (call_id : V.FunCallId.id) (forward : S.call)
- (args : texpression list) (ctx : bs_ctx) : bs_ctx =
- let calls = ctx.calls in
- assert (not (V.FunCallId.Map.mem call_id calls));
- let info =
- { forward; forward_inputs = args; backwards = T.RegionGroupId.Map.empty }
- in
- let calls = V.FunCallId.Map.add call_id info calls in
- { ctx with calls }
-
-(** [back_args]: the *additional* list of inputs received by the backward function *)
-let bs_ctx_register_backward_call (abs : V.abs) (call_id : V.FunCallId.id)
- (back_id : T.RegionGroupId.id) (back_args : texpression list) (ctx : bs_ctx)
- : bs_ctx * fun_or_op_id =
- (* Insert the abstraction in the call informations *)
- let info = V.FunCallId.Map.find call_id ctx.calls in
- assert (not (T.RegionGroupId.Map.mem back_id info.backwards));
- let backwards =
- T.RegionGroupId.Map.add back_id (abs, back_args) info.backwards
- in
- let info = { info with backwards } in
- let calls = V.FunCallId.Map.add call_id info ctx.calls in
- (* Insert the abstraction in the abstractions map *)
- let abstractions = ctx.abstractions in
- assert (not (V.AbstractionId.Map.mem abs.abs_id abstractions));
- let abstractions =
- V.AbstractionId.Map.add abs.abs_id (abs, back_args) abstractions
- in
- (* Retrieve the fun_id *)
- let fun_id =
- match info.forward.call_id with
- | S.Fun (fid, _) -> Fun (FromLlbc (fid, None, Some back_id))
- | S.Unop _ | S.Binop _ -> raise (Failure "Unreachable")
- in
- (* Update the context and return *)
- ({ ctx with calls; abstractions }, fun_id)
+(* Some generic translation functions (we need to translate different "flavours"
+ of types: sty, forward types, backward types, etc.) *)
+let rec translate_generic_args (translate_ty : 'r T.ty -> ty)
+ (generics : 'r T.generic_args) : generic_args =
+ (* We ignore the regions: if they didn't cause trouble for the symbolic execution,
+ then everything's fine *)
+ let types = List.map translate_ty generics.types in
+ let const_generics = generics.const_generics in
+ let trait_refs =
+ List.map (translate_trait_ref translate_ty) generics.trait_refs
+ in
+ { types; const_generics; trait_refs }
+
+and translate_trait_ref (translate_ty : 'r T.ty -> ty) (tr : 'r T.trait_ref) :
+ trait_ref =
+ let trait_id = translate_trait_instance_id translate_ty tr.trait_id in
+ let generics = translate_generic_args translate_ty tr.generics in
+ let trait_decl_ref =
+ translate_trait_decl_ref translate_ty tr.trait_decl_ref
+ in
+ { trait_id; generics; trait_decl_ref }
+
+and translate_trait_decl_ref (translate_ty : 'r T.ty -> ty)
+ (tr : 'r T.trait_decl_ref) : trait_decl_ref =
+ let decl_generics = translate_generic_args translate_ty tr.decl_generics in
+ { trait_decl_id = tr.trait_decl_id; decl_generics }
+
+and translate_trait_instance_id (translate_ty : 'r T.ty -> ty)
+ (id : 'r T.trait_instance_id) : trait_instance_id =
+ let translate_trait_instance_id = translate_trait_instance_id translate_ty in
+ match id with
+ | T.Self -> Self
+ | TraitImpl id -> TraitImpl id
+ | BuiltinOrAuto _ ->
+ (* We should have eliminated those in the prepasses *)
+ raise (Failure "Unreachable")
+ | Clause id -> Clause id
+ | ParentClause (inst_id, decl_id, clause_id) ->
+ let inst_id = translate_trait_instance_id inst_id in
+ ParentClause (inst_id, decl_id, clause_id)
+ | ItemClause (inst_id, decl_id, item_name, clause_id) ->
+ let inst_id = translate_trait_instance_id inst_id in
+ ItemClause (inst_id, decl_id, item_name, clause_id)
+ | TraitRef tr -> TraitRef (translate_trait_ref translate_ty tr)
+ | FnPointer _ -> raise (Failure "TODO")
+ | UnknownTrait s -> raise (Failure ("Unknown trait found: " ^ s))
let rec translate_sty (ty : T.sty) : ty =
let translate = translate_sty in
match ty with
- | T.Adt (type_id, regions, tys, cgs) -> (
- (* Can't translate types with regions for now *)
- assert (regions = []);
- let tys = List.map translate tys in
+ | T.Adt (type_id, generics) -> (
+ let generics = translate_sgeneric_args generics in
match type_id with
- | T.AdtId adt_id -> Adt (AdtId adt_id, tys, cgs)
- | T.Tuple -> mk_simpl_tuple_ty tys
+ | T.AdtId adt_id -> Adt (AdtId adt_id, generics)
+ | T.Tuple ->
+ assert (generics.const_generics = []);
+ mk_simpl_tuple_ty generics.types
| T.Assumed aty -> (
match aty with
- | T.Vec -> Adt (Assumed Vec, tys, cgs)
- | T.Option -> Adt (Assumed Option, tys, cgs)
| T.Box -> (
(* Eliminate the boxes *)
- match tys with
+ match generics.types with
| [ ty ] -> ty
| _ ->
raise
(Failure
"Box/vec/option type with incorrect number of arguments")
)
- | T.Array -> Adt (Assumed Array, tys, cgs)
- | T.Slice -> Adt (Assumed Slice, tys, cgs)
- | T.Str -> Adt (Assumed Str, tys, cgs)
- | T.Range -> Adt (Assumed Range, tys, cgs)))
+ | T.Array -> Adt (Assumed Array, generics)
+ | T.Slice -> Adt (Assumed Slice, generics)
+ | T.Str -> Adt (Assumed Str, generics)))
| TypeVar vid -> TypeVar vid
| Literal ty -> Literal ty
| Never -> raise (Failure "Unreachable")
| Ref (_, rty, _) -> translate rty
+ | RawPtr (ty, rkind) ->
+ let mut = match rkind with Mut -> Mut | Shared -> Const in
+ let ty = translate ty in
+ let generics = { types = [ ty ]; const_generics = []; trait_refs = [] } in
+ Adt (Assumed (RawPtr mut), generics)
+ | TraitType (trait_ref, generics, type_name) ->
+ let trait_ref = translate_strait_ref trait_ref in
+ let generics = translate_sgeneric_args generics in
+ TraitType (trait_ref, generics, type_name)
+ | Arrow _ -> raise (Failure "TODO")
+
+and translate_sgeneric_args (generics : T.sgeneric_args) : generic_args =
+ translate_generic_args translate_sty generics
+
+and translate_strait_ref (tr : T.strait_ref) : trait_ref =
+ translate_trait_ref translate_sty tr
+
+and translate_strait_instance_id (id : T.strait_instance_id) : trait_instance_id
+ =
+ translate_trait_instance_id translate_sty id
+
+let translate_trait_clause (clause : T.trait_clause) : trait_clause =
+ let { T.clause_id; meta = _; trait_id; generics } = clause in
+ let generics = translate_sgeneric_args generics in
+ { clause_id; trait_id; generics }
+
+let translate_strait_type_constraint (ttc : T.strait_type_constraint) :
+ trait_type_constraint =
+ let { T.trait_ref; generics; type_name; ty } = ttc in
+ let trait_ref = translate_strait_ref trait_ref in
+ let generics = translate_sgeneric_args generics in
+ let ty = translate_sty ty in
+ { trait_ref; generics; type_name; ty }
+
+let translate_predicates (preds : T.predicates) : predicates =
+ let trait_type_constraints =
+ List.map translate_strait_type_constraint preds.trait_type_constraints
+ in
+ { trait_type_constraints }
+
+let translate_generic_params (generics : T.generic_params) : generic_params =
+ let { T.regions = _; types; const_generics; trait_clauses } = generics in
+ let trait_clauses = List.map translate_trait_clause trait_clauses in
+ { types; const_generics; trait_clauses }
let translate_field (f : T.field) : field =
let field_name = f.field_name in
@@ -452,15 +495,16 @@ let translate_type_decl_kind (kind : T.type_decl_kind) : type_decl_kind =
point of moving this definition for now.
*)
let translate_type_decl (def : T.type_decl) : type_decl =
- (* Translate *)
let def_id = def.T.def_id in
let name = def.name in
+ let { T.regions; types; const_generics; trait_clauses } = def.generics in
(* Can't translate types with regions for now *)
- assert (def.region_params = []);
- let type_params = def.type_params in
- let const_generic_params = def.const_generic_params in
+ assert (regions = []);
+ let trait_clauses = List.map translate_trait_clause trait_clauses in
+ let generics = { types; const_generics; trait_clauses } in
let kind = translate_type_decl_kind def.T.kind in
- { def_id; name; type_params; const_generic_params; kind }
+ let preds = translate_predicates def.preds in
+ { def_id; name; generics; kind; preds }
let translate_type_id (id : T.type_id) : type_id =
match id with
@@ -468,12 +512,9 @@ let translate_type_id (id : T.type_id) : type_id =
| T.Assumed aty ->
let aty =
match aty with
- | T.Vec -> Vec
- | T.Option -> Option
| T.Array -> Array
| T.Slice -> Slice
| T.Str -> Str
- | T.Range -> Range
| T.Box ->
(* Boxes have to be eliminated: this type id shouldn't
be translated *)
@@ -488,28 +529,26 @@ let translate_type_id (id : T.type_id) : type_id =
let rec translate_fwd_ty (type_infos : TA.type_infos) (ty : 'r T.ty) : ty =
let translate = translate_fwd_ty type_infos in
match ty with
- | T.Adt (type_id, regions, tys, cgs) -> (
- (* Can't translate types with regions for now *)
- assert (regions = []);
- (* Translate the type parameters *)
- let t_tys = List.map translate tys in
+ | T.Adt (type_id, generics) -> (
+ let t_generics = translate_fwd_generic_args type_infos generics in
(* Eliminate boxes and simplify tuples *)
match type_id with
- | AdtId _
- | T.Assumed (T.Vec | T.Option | T.Array | T.Slice | T.Str | T.Range) ->
- (* No general parametricity for now *)
- assert (not (List.exists (TypesUtils.ty_has_borrows type_infos) tys));
+ | AdtId _ | T.Assumed (T.Array | T.Slice | T.Str) ->
let type_id = translate_type_id type_id in
- Adt (type_id, t_tys, cgs)
+ Adt (type_id, t_generics)
| Tuple ->
(* Note that if there is exactly one type, [mk_simpl_tuple_ty] is the
identity *)
- mk_simpl_tuple_ty t_tys
+ mk_simpl_tuple_ty t_generics.types
| T.Assumed T.Box -> (
(* We eliminate boxes *)
(* No general parametricity for now *)
- assert (not (List.exists (TypesUtils.ty_has_borrows type_infos) tys));
- match t_tys with
+ assert (
+ not
+ (List.exists
+ (TypesUtils.ty_has_borrows type_infos)
+ generics.types));
+ match t_generics.types with
| [ bty ] -> bty
| _ ->
raise
@@ -520,12 +559,40 @@ let rec translate_fwd_ty (type_infos : TA.type_infos) (ty : 'r T.ty) : ty =
| Never -> raise (Failure "Unreachable")
| Literal lty -> Literal lty
| Ref (_, rty, _) -> translate rty
+ | RawPtr (ty, rkind) ->
+ let mut = match rkind with Mut -> Mut | Shared -> Const in
+ let ty = translate ty in
+ let generics = { types = [ ty ]; const_generics = []; trait_refs = [] } in
+ Adt (Assumed (RawPtr mut), generics)
+ | TraitType (trait_ref, generics, type_name) ->
+ let trait_ref = translate_fwd_trait_ref type_infos trait_ref in
+ let generics = translate_fwd_generic_args type_infos generics in
+ TraitType (trait_ref, generics, type_name)
+ | Arrow _ -> raise (Failure "TODO")
+
+and translate_fwd_generic_args (type_infos : TA.type_infos)
+ (generics : 'r T.generic_args) : generic_args =
+ translate_generic_args (translate_fwd_ty type_infos) generics
+
+and translate_fwd_trait_ref (type_infos : TA.type_infos) (tr : 'r T.trait_ref) :
+ trait_ref =
+ translate_trait_ref (translate_fwd_ty type_infos) tr
+
+and translate_fwd_trait_instance_id (type_infos : TA.type_infos)
+ (id : 'r T.trait_instance_id) : trait_instance_id =
+ translate_trait_instance_id (translate_fwd_ty type_infos) id
(** Simply calls [translate_fwd_ty] *)
let ctx_translate_fwd_ty (ctx : bs_ctx) (ty : 'r T.ty) : ty =
let type_infos = ctx.type_context.type_infos in
translate_fwd_ty type_infos ty
+(** Simply calls [translate_fwd_generic_args] *)
+let ctx_translate_fwd_generic_args (ctx : bs_ctx) (generics : 'r T.generic_args)
+ : generic_args =
+ let type_infos = ctx.type_context.type_infos in
+ translate_fwd_generic_args type_infos generics
+
(** Translate a type, when some regions may have ended.
We return an option, because the translated type may be empty.
@@ -538,30 +605,40 @@ let rec translate_back_ty (type_infos : TA.type_infos)
(* A small helper for "leave" types *)
let wrap ty = if inside_mut then Some ty else None in
match ty with
- | T.Adt (type_id, _, tys, cgs) -> (
+ | T.Adt (type_id, generics) -> (
match type_id with
- | T.AdtId _
- | Assumed (T.Vec | T.Option | T.Array | T.Slice | T.Str | T.Range) ->
- (* Don't accept ADTs (which are not tuples) with borrows for now *)
- assert (not (TypesUtils.ty_has_borrows type_infos ty));
+ | T.AdtId _ | Assumed (T.Array | T.Slice | T.Str) ->
let type_id = translate_type_id type_id in
if inside_mut then
- let tys_t = List.filter_map translate tys in
- Some (Adt (type_id, tys_t, cgs))
- else None
+ (* We do not want to filter anything, so we translate the generics
+ as "forward" types *)
+ let generics = translate_fwd_generic_args type_infos generics in
+ Some (Adt (type_id, generics))
+ else
+ (* If not inside a mutable reference: check if at least one
+ of the generics contains a mutable reference (i.e., is not
+ translated to `None`. If yes, keep the whole type, and
+ translate all the generics as "forward" types (the backward
+ function will extract the proper information from the ADT value)
+ *)
+ let types = List.filter_map translate generics.types in
+ if types <> [] then
+ let generics = translate_fwd_generic_args type_infos generics in
+ Some (Adt (type_id, generics))
+ else None
| Assumed T.Box -> (
(* Don't accept ADTs (which are not tuples) with borrows for now *)
assert (not (TypesUtils.ty_has_borrows type_infos ty));
(* Eliminate the box *)
- match tys with
+ match generics.types with
| [ bty ] -> translate bty
| _ ->
raise
(Failure "Unreachable: boxes receive exactly one type parameter")
)
| T.Tuple -> (
- (* Tuples can contain borrows (which we eliminated) *)
- let tys_t = List.filter_map translate tys in
+ (* Tuples can contain borrows (which we eliminate) *)
+ let tys_t = List.filter_map translate generics.types in
match tys_t with
| [] -> None
| _ ->
@@ -582,6 +659,17 @@ let rec translate_back_ty (type_infos : TA.type_infos)
if keep_region r then
translate_back_ty type_infos keep_region inside_mut rty
else None)
+ | RawPtr _ ->
+ (* TODO: not sure what to do here *)
+ None
+ | TraitType (trait_ref, generics, type_name) ->
+ assert (generics.regions = []);
+ (* Translate the trait ref and the generics as "forward" generics -
+ we do not want to filter any type *)
+ let trait_ref = translate_fwd_trait_ref type_infos trait_ref in
+ let generics = translate_fwd_generic_args type_infos generics in
+ Some (TraitType (trait_ref, generics, type_name))
+ | Arrow _ -> raise (Failure "TODO")
(** Simply calls [translate_back_ty] *)
let ctx_translate_back_ty (ctx : bs_ctx) (keep_region : 'r -> bool)
@@ -589,6 +677,80 @@ let ctx_translate_back_ty (ctx : bs_ctx) (keep_region : 'r -> bool)
let type_infos = ctx.type_context.type_infos in
translate_back_ty type_infos keep_region inside_mut ty
+let mk_type_check_ctx (ctx : bs_ctx) : PureTypeCheck.tc_ctx =
+ let const_generics =
+ T.ConstGenericVarId.Map.of_list
+ (List.map
+ (fun (cg : T.const_generic_var) ->
+ (cg.index, ctx_translate_fwd_ty ctx (T.Literal cg.ty)))
+ ctx.sg.generics.const_generics)
+ in
+ let env = VarId.Map.empty in
+ {
+ PureTypeCheck.type_decls = ctx.type_context.type_decls;
+ global_decls = ctx.global_context.llbc_global_decls;
+ env;
+ const_generics;
+ }
+
+let type_check_pattern (ctx : bs_ctx) (v : typed_pattern) : unit =
+ let ctx = mk_type_check_ctx ctx in
+ let _ = PureTypeCheck.check_typed_pattern ctx v in
+ ()
+
+let type_check_texpression (ctx : bs_ctx) (e : texpression) : unit =
+ if !Config.type_check_pure_code then
+ let ctx = mk_type_check_ctx ctx in
+ PureTypeCheck.check_texpression ctx e
+
+let translate_fun_id_or_trait_method_ref (ctx : bs_ctx)
+ (id : A.fun_id_or_trait_method_ref) : fun_id_or_trait_method_ref =
+ match id with
+ | FunId fun_id -> FunId fun_id
+ | TraitMethod (trait_ref, method_name, fun_decl_id) ->
+ let type_infos = ctx.type_context.type_infos in
+ let trait_ref = translate_fwd_trait_ref type_infos trait_ref in
+ TraitMethod (trait_ref, method_name, fun_decl_id)
+
+let bs_ctx_register_forward_call (call_id : V.FunCallId.id) (forward : S.call)
+ (args : texpression list) (ctx : bs_ctx) : bs_ctx =
+ let calls = ctx.calls in
+ assert (not (V.FunCallId.Map.mem call_id calls));
+ let info =
+ { forward; forward_inputs = args; backwards = T.RegionGroupId.Map.empty }
+ in
+ let calls = V.FunCallId.Map.add call_id info calls in
+ { ctx with calls }
+
+(** [back_args]: the *additional* list of inputs received by the backward function *)
+let bs_ctx_register_backward_call (abs : V.abs) (call_id : V.FunCallId.id)
+ (back_id : T.RegionGroupId.id) (back_args : texpression list) (ctx : bs_ctx)
+ : bs_ctx * fun_or_op_id =
+ (* Insert the abstraction in the call informations *)
+ let info = V.FunCallId.Map.find call_id ctx.calls in
+ assert (not (T.RegionGroupId.Map.mem back_id info.backwards));
+ let backwards =
+ T.RegionGroupId.Map.add back_id (abs, back_args) info.backwards
+ in
+ let info = { info with backwards } in
+ let calls = V.FunCallId.Map.add call_id info ctx.calls in
+ (* Insert the abstraction in the abstractions map *)
+ let abstractions = ctx.abstractions in
+ assert (not (V.AbstractionId.Map.mem abs.abs_id abstractions));
+ let abstractions =
+ V.AbstractionId.Map.add abs.abs_id (abs, back_args) abstractions
+ in
+ (* Retrieve the fun_id *)
+ let fun_id =
+ match info.forward.call_id with
+ | S.Fun (fid, _) ->
+ let fid = translate_fun_id_or_trait_method_ref ctx fid in
+ Fun (FromLlbc (fid, None, Some back_id))
+ | S.Unop _ | S.Binop _ -> raise (Failure "Unreachable")
+ in
+ (* Update the context and return *)
+ ({ ctx with calls; abstractions }, fun_id)
+
(** List the ancestors of an abstraction *)
let list_ancestor_abstractions_ids (ctx : bs_ctx) (abs : V.abs)
(call_id : V.FunCallId.id) : V.AbstractionId.id list =
@@ -642,10 +804,10 @@ let mk_fuel_input_as_list (ctx : bs_ctx) (info : fun_effect_info) :
(** Small utility. *)
let get_fun_effect_info (fun_infos : FA.fun_info A.FunDeclId.Map.t)
- (fun_id : A.fun_id) (lid : V.LoopId.id option)
+ (fun_id : A.fun_id_or_trait_method_ref) (lid : V.LoopId.id option)
(gid : T.RegionGroupId.id option) : fun_effect_info =
match fun_id with
- | A.Regular fid ->
+ | TraitMethod (_, _, fid) | FunId (Regular fid) ->
let info = A.FunDeclId.Map.find fid fun_infos in
let stateful_group = info.stateful in
let stateful =
@@ -658,10 +820,10 @@ let get_fun_effect_info (fun_infos : FA.fun_info A.FunDeclId.Map.t)
can_diverge = info.can_diverge;
is_rec = info.is_rec || Option.is_some lid;
}
- | A.Assumed aid ->
+ | FunId (Assumed aid) ->
assert (lid = None);
{
- can_fail = Assumed.assumed_can_fail aid;
+ can_fail = Assumed.assumed_fun_can_fail aid;
stateful_group = false;
stateful = false;
can_diverge = false;
@@ -673,12 +835,14 @@ let get_fun_effect_info (fun_infos : FA.fun_info A.FunDeclId.Map.t)
Note that the function also takes a list of names for the inputs, and
computes, for every output for the backward functions, a corresponding
name (outputs for backward functions come from borrows in the inputs
- of the forward function) which we use as hints to generate pretty names.
+ of the forward function) which we use as hints to generate pretty names
+ in the extracted code.
*)
-let translate_fun_sig (fun_infos : FA.fun_info A.FunDeclId.Map.t)
- (fun_id : A.fun_id) (type_infos : TA.type_infos) (sg : A.fun_sig)
- (input_names : string option list) (bid : T.RegionGroupId.id option) :
- fun_sig_named_outputs =
+let translate_fun_sig (decls_ctx : C.decls_ctx) (fun_id : A.fun_id)
+ (sg : A.fun_sig) (input_names : string option list)
+ (bid : T.RegionGroupId.id option) : fun_sig_named_outputs =
+ let fun_infos = decls_ctx.fun_ctx.fun_infos in
+ let type_infos = decls_ctx.type_ctx.type_infos in
(* Retrieve the list of parent backward functions *)
let gid, parents =
match bid with
@@ -689,7 +853,34 @@ let translate_fun_sig (fun_infos : FA.fun_info A.FunDeclId.Map.t)
in
(* Is the function stateful, and can it fail? *)
let lid = None in
- let effect_info = get_fun_effect_info fun_infos fun_id lid bid in
+ let effect_info = get_fun_effect_info fun_infos (FunId fun_id) lid bid in
+ (* We need an evaluation context to normalize the types (to normalize the
+ associated types, etc. - for instance it may happen that the types
+ refer to the types associated to a trait ref, but where the trait ref
+ is a known impl). *)
+ (* Create the context *)
+ let ctx =
+ let region_groups =
+ List.map (fun (g : T.region_var_group) -> g.id) sg.regions_hierarchy
+ in
+ let ctx =
+ InterpreterUtils.initialize_eval_context decls_ctx region_groups
+ sg.generics.types sg.generics.const_generics
+ in
+ (* Compute the normalization map for the *sty* types and add it to the context *)
+ AssociatedTypes.ctx_add_norm_trait_stypes_from_preds ctx
+ sg.preds.trait_type_constraints
+ in
+
+ (* Normalize the signature *)
+ let sg =
+ let ({ A.inputs; output; _ } : A.fun_sig) = sg in
+ let norm = AssociatedTypes.ctx_normalize_sty ctx in
+ let inputs = List.map norm inputs in
+ let output = norm output in
+ { sg with A.inputs; output }
+ in
+
(* List the inputs for:
* - the fuel
* - the forward function
@@ -806,9 +997,8 @@ let translate_fun_sig (fun_infos : FA.fun_info A.FunDeclId.Map.t)
(* Wrap in a result type *)
if effect_info.can_fail then mk_result_ty output else output
in
- (* Type/const generic parameters *)
- let type_params = sg.type_params in
- let const_generic_params = sg.const_generic_params in
+ (* Generic parameters *)
+ let generics = translate_generic_params sg.generics in
(* Return *)
let has_fuel = fuel <> [] in
let num_fwd_inputs_no_state = List.length fwd_inputs in
@@ -836,9 +1026,8 @@ let translate_fun_sig (fun_infos : FA.fun_info A.FunDeclId.Map.t)
effect_info;
}
in
- let sg =
- { type_params; const_generic_params; inputs; output; doutputs; info }
- in
+ let preds = translate_predicates sg.A.preds in
+ let sg = { generics; preds; inputs; output; doutputs; info } in
{ sg; output_names }
let bs_ctx_fresh_state_var (ctx : bs_ctx) : bs_ctx * typed_pattern =
@@ -917,7 +1106,7 @@ let lookup_var_for_symbolic_value (sv : V.symbolic_value) (ctx : bs_ctx) : var =
(** Peel boxes as long as the value is of the form [Box<T>] *)
let rec unbox_typed_value (v : V.typed_value) : V.typed_value =
match (v.value, v.ty) with
- | V.Adt av, T.Adt (T.Assumed T.Box, _, _, _) -> (
+ | V.Adt av, T.Adt (T.Assumed T.Box, _) -> (
match av.field_values with
| [ bv ] -> unbox_typed_value bv
| _ -> raise (Failure "Unreachable"))
@@ -962,16 +1151,16 @@ let rec typed_value_to_texpression (ctx : bs_ctx) (ectx : C.eval_ctx)
let field_values = List.map translate av.field_values in
(* Eliminate the tuple wrapper if it is a tuple with exactly one field *)
match v.ty with
- | T.Adt (T.Tuple, _, _, _) ->
+ | T.Adt (T.Tuple, _) ->
assert (variant_id = None);
mk_simpl_tuple_texpression field_values
| _ ->
- (* Retrieve the type, the translated type arguments and the
- * const generic arguments from the translated type (simpler this way) *)
- let adt_id, type_args, const_generic_args = ty_as_adt ty in
+ (* Retrieve the type and the translated generics from the translated
+ type (simpler this way) *)
+ let adt_id, generics = ty_as_adt ty in
(* Create the constructor *)
let qualif_id = AdtCons { adt_id; variant_id = av.variant_id } in
- let qualif = { id = qualif_id; type_args; const_generic_args } in
+ let qualif = { id = qualif_id; generics } in
let cons_e = Qualif qualif in
let field_tys =
List.map (fun (v : texpression) -> v.ty) field_values
@@ -1038,11 +1227,9 @@ let rec typed_avalue_to_consumed (ctx : bs_ctx) (ectx : C.eval_ctx)
(* Translate the field values *)
let field_values = List.filter_map translate adt_v.field_values in
(* For now, only tuples can contain borrows *)
- let adt_id, _, _, _ = TypesUtils.ty_as_adt av.ty in
+ let adt_id, _ = TypesUtils.ty_as_adt av.ty in
match adt_id with
- | T.AdtId _
- | T.Assumed
- (T.Box | T.Vec | T.Option | T.Array | T.Slice | T.Str | T.Range) ->
+ | T.AdtId _ | T.Assumed (T.Box | T.Array | T.Slice | T.Str) ->
assert (field_values = []);
None
| T.Tuple ->
@@ -1185,11 +1372,9 @@ let rec typed_avalue_to_given_back (mp : mplace option) (av : V.typed_avalue)
(* For now, only tuples can contain borrows - note that if we gave
* something like a [&mut Vec] to a function, we give back the
* vector value upon visiting the "abstraction borrow" node *)
- let adt_id, _, _, _ = TypesUtils.ty_as_adt av.ty in
+ let adt_id, _ = TypesUtils.ty_as_adt av.ty in
match adt_id with
- | T.AdtId _
- | T.Assumed
- (T.Box | T.Vec | T.Option | T.Array | T.Slice | T.Str | T.Range) ->
+ | T.AdtId _ | T.Assumed (T.Box | T.Array | T.Slice | T.Str) ->
assert (field_values = []);
(ctx, None)
| T.Tuple ->
@@ -1457,9 +1642,12 @@ and translate_return_with_loop (loop_id : V.LoopId.id) (is_continue : bool)
and translate_function_call (call : S.call) (e : S.expression) (ctx : bs_ctx) :
texpression =
+ log#ldebug
+ (lazy
+ ("translate_function_call:\n"
+ ^ ctx_egeneric_args_to_string ctx call.generics));
(* Translate the function call *)
- let type_args = List.map (ctx_translate_fwd_ty ctx) call.type_params in
- let const_generic_args = call.const_generic_params in
+ let generics = ctx_translate_fwd_generic_args ctx call.generics in
let args =
let args = List.map (typed_value_to_texpression ctx call.ctx) call.args in
let args_mplaces = List.map translate_opt_mplace call.args_places in
@@ -1475,7 +1663,8 @@ and translate_function_call (call : S.call) (e : S.expression) (ctx : bs_ctx) :
match call.call_id with
| S.Fun (fid, call_id) ->
(* Regular function call *)
- let func = Fun (FromLlbc (fid, None, None)) in
+ let fid_t = translate_fun_id_or_trait_method_ref ctx fid in
+ let func = Fun (FromLlbc (fid_t, None, None)) in
(* Retrieve the effect information about this function (can fail,
* takes a state as input, etc.) *)
let effect_info =
@@ -1525,18 +1714,20 @@ and translate_function_call (call : S.call) (e : S.expression) (ctx : bs_ctx) :
in
(ctx, Unop (Neg int_ty), effect_info, args, None)
| _ -> raise (Failure "Unreachable"))
- | S.Unop (E.Cast (src_ty, tgt_ty)) ->
- (* Note that cast can fail *)
- let effect_info =
- {
- can_fail = true;
- stateful_group = false;
- stateful = false;
- can_diverge = false;
- is_rec = false;
- }
- in
- (ctx, Unop (Cast (src_ty, tgt_ty)), effect_info, args, None)
+ | S.Unop (E.Cast cast_kind) -> (
+ match cast_kind with
+ | CastInteger (src_ty, tgt_ty) ->
+ (* Note that cast can fail *)
+ let effect_info =
+ {
+ can_fail = true;
+ stateful_group = false;
+ stateful = false;
+ can_diverge = false;
+ is_rec = false;
+ }
+ in
+ (ctx, Unop (Cast (src_ty, tgt_ty)), effect_info, args, None))
| S.Binop binop -> (
match args with
| [ arg0; arg1 ] ->
@@ -1561,7 +1752,7 @@ and translate_function_call (call : S.call) (e : S.expression) (ctx : bs_ctx) :
| None -> dest
| Some out_state -> mk_simpl_tuple_pattern [ out_state; dest ]
in
- let func = { id = FunOrOp fun_id; type_args; const_generic_args } in
+ let func = { id = FunOrOp fun_id; generics } in
let input_tys = (List.map (fun (x : texpression) -> x.ty)) args in
let ret_ty =
if effect_info.can_fail then mk_result_ty dest_v.ty else dest_v.ty
@@ -1665,9 +1856,11 @@ and translate_end_abstraction_synth_input (ectx : C.eval_ctx) (abs : V.abs)
(* Group the two lists *)
let variables_values = List.combine given_back_variables consumed_values in
(* Sanity check: the two lists match (same types) *)
- List.iter
- (fun (var, v) -> assert ((var : var).ty = (v : texpression).ty))
- variables_values;
+ (* TODO: normalize the types *)
+ if !Config.type_check_pure_code then
+ List.iter
+ (fun (var, v) -> assert ((var : var).ty = (v : texpression).ty))
+ variables_values;
(* Translate the next expression *)
let next_e = translate_expression e ctx in
(* Generate the assignemnts *)
@@ -1692,8 +1885,7 @@ and translate_end_abstraction_fun_call (ectx : C.eval_ctx) (abs : V.abs)
let effect_info =
get_fun_effect_info ctx.fun_context.fun_infos fun_id None (Some rg_id)
in
- let type_args = List.map (ctx_translate_fwd_ty ctx) call.type_params in
- let const_generic_args = call.const_generic_params in
+ let generics = ctx_translate_fwd_generic_args ctx call.generics in
(* Retrieve the original call and the parent abstractions *)
let _forward, backwards = get_abs_ancestors ctx abs call_id in
(* Retrieve the values consumed when we called the forward function and
@@ -1741,34 +1933,35 @@ and translate_end_abstraction_fun_call (ectx : C.eval_ctx) (abs : V.abs)
| Some nstate -> mk_simpl_tuple_pattern [ nstate; output ]
in
(* Sanity check: there is the proper number of inputs and outputs, and they have the proper type *)
- let _ =
- let inst_sg =
- get_instantiated_fun_sig fun_id (Some rg_id) type_args const_generic_args
- ctx
- in
- log#ldebug
- (lazy
- ("\n- fun_id: " ^ A.show_fun_id fun_id ^ "\n- inputs ("
- ^ string_of_int (List.length inputs)
- ^ "): "
- ^ String.concat ", " (List.map (texpression_to_string ctx) inputs)
- ^ "\n- inst_sg.inputs ("
- ^ string_of_int (List.length inst_sg.inputs)
- ^ "): "
- ^ String.concat ", " (List.map (ty_to_string ctx) inst_sg.inputs)));
- List.iter
- (fun (x, ty) -> assert ((x : texpression).ty = ty))
- (List.combine inputs inst_sg.inputs);
- log#ldebug
- (lazy
- ("\n- outputs: "
- ^ string_of_int (List.length outputs)
- ^ "\n- expected outputs: "
- ^ string_of_int (List.length inst_sg.doutputs)));
- List.iter
- (fun (x, ty) -> assert ((x : typed_pattern).ty = ty))
- (List.combine outputs inst_sg.doutputs)
- in
+ (if (* TODO: normalize the types *) !Config.type_check_pure_code then
+ match fun_id with
+ | FunId fun_id ->
+ let inst_sg =
+ get_instantiated_fun_sig fun_id (Some rg_id) generics ctx
+ in
+ log#ldebug
+ (lazy
+ ("\n- fun_id: " ^ A.show_fun_id fun_id ^ "\n- inputs ("
+ ^ string_of_int (List.length inputs)
+ ^ "): "
+ ^ String.concat ", " (List.map (texpression_to_string ctx) inputs)
+ ^ "\n- inst_sg.inputs ("
+ ^ string_of_int (List.length inst_sg.inputs)
+ ^ "): "
+ ^ String.concat ", " (List.map (ty_to_string ctx) inst_sg.inputs)));
+ List.iter
+ (fun (x, ty) -> assert ((x : texpression).ty = ty))
+ (List.combine inputs inst_sg.inputs);
+ log#ldebug
+ (lazy
+ ("\n- outputs: "
+ ^ string_of_int (List.length outputs)
+ ^ "\n- expected outputs: "
+ ^ string_of_int (List.length inst_sg.doutputs)));
+ List.iter
+ (fun (x, ty) -> assert ((x : typed_pattern).ty = ty))
+ (List.combine outputs inst_sg.doutputs)
+ | _ -> (* TODO: trait methods *) ());
(* Retrieve the function id, and register the function call in the context
* if necessary *)
let ctx, func =
@@ -1788,7 +1981,7 @@ and translate_end_abstraction_fun_call (ectx : C.eval_ctx) (abs : V.abs)
if effect_info.can_fail then mk_result_ty output.ty else output.ty
in
let func_ty = mk_arrows input_tys ret_ty in
- let func = { id = FunOrOp func; type_args; const_generic_args } in
+ let func = { id = FunOrOp func; generics } in
let func = { e = Qualif func; ty = func_ty } in
let call = mk_apps func args in
(* **Optimization**:
@@ -1905,14 +2098,13 @@ and translate_end_abstraction_loop (ectx : C.eval_ctx) (abs : V.abs)
(* Actually the same case as [SynthInput] *)
translate_end_abstraction_synth_input ectx abs e ctx rg_id
| V.LoopCall ->
- let fun_id = A.Regular ctx.fun_decl.A.def_id in
+ let fun_id = E.Regular ctx.fun_decl.A.def_id in
let effect_info =
- get_fun_effect_info ctx.fun_context.fun_infos fun_id (Some vloop_id)
- (Some rg_id)
+ get_fun_effect_info ctx.fun_context.fun_infos (FunId fun_id)
+ (Some vloop_id) (Some rg_id)
in
let loop_info = LoopId.Map.find loop_id ctx.loops in
- let type_args = loop_info.type_args in
- let const_generic_args = loop_info.const_generic_args in
+ let generics = loop_info.generics in
let fwd_inputs = Option.get loop_info.forward_inputs in
(* Retrieve the additional backward inputs. Note that those are actually
the backward inputs of the function we are synthesizing (and that we
@@ -1960,8 +2152,8 @@ and translate_end_abstraction_loop (ectx : C.eval_ctx) (abs : V.abs)
if effect_info.can_fail then mk_result_ty output.ty else output.ty
in
let func_ty = mk_arrows input_tys ret_ty in
- let func = Fun (FromLlbc (fun_id, Some loop_id, Some rg_id)) in
- let func = { id = FunOrOp func; type_args; const_generic_args } in
+ let func = Fun (FromLlbc (FunId fun_id, Some loop_id, Some rg_id)) in
+ let func = { id = FunOrOp func; generics } in
let func = { e = Qualif func; ty = func_ty } in
let call = mk_apps func args in
(* **Optimization**:
@@ -2021,9 +2213,7 @@ and translate_global_eval (gid : A.GlobalDeclId.id) (sval : V.symbolic_value)
(e : S.expression) (ctx : bs_ctx) : texpression =
let ctx, var = fresh_var_for_symbolic_value sval ctx in
let decl = A.GlobalDeclId.Map.find gid ctx.global_context.llbc_global_decls in
- let global_expr =
- { id = Global gid; type_args = []; const_generic_args = [] }
- in
+ let global_expr = { id = Global gid; generics = empty_generic_args } in
(* We use translate_fwd_ty to translate the global type *)
let ty = ctx_translate_fwd_ty ctx decl.ty in
let gval = { e = Qualif global_expr; ty } in
@@ -2037,11 +2227,7 @@ and translate_assertion (ectx : C.eval_ctx) (v : V.typed_value)
let v = typed_value_to_texpression ctx ectx v in
let args = [ v ] in
let func =
- {
- id = FunOrOp (Fun (Pure Assert));
- type_args = [];
- const_generic_args = [];
- }
+ { id = FunOrOp (Fun (Pure Assert)); generics = empty_generic_args }
in
let func_ty = mk_arrow (Literal Bool) mk_unit_ty in
let func = { e = Qualif func; ty = func_ty } in
@@ -2189,7 +2375,7 @@ and translate_ExpandAdt_one_branch (sv : V.symbolic_value)
(branch : S.expression) (ctx : bs_ctx) : texpression =
(* TODO: always introduce a match, and use micro-passes to turn the
the match into a let? *)
- let type_id, _, _, _ = TypesUtils.ty_as_adt sv.V.sv_ty in
+ let type_id, _ = TypesUtils.ty_as_adt sv.V.sv_ty in
let ctx, vars = fresh_vars_for_symbolic_values svl ctx in
let branch = translate_expression branch ctx in
match type_id with
@@ -2224,10 +2410,10 @@ and translate_ExpandAdt_one_branch (sv : V.symbolic_value)
* field.
* We use the [dest] variable in order not to have to recompute
* the type of the result of the projection... *)
- let adt_id, type_args, const_generic_args = ty_as_adt scrutinee.ty in
+ let adt_id, generics = ty_as_adt scrutinee.ty in
let gen_field_proj (field_id : FieldId.id) (dest : var) : texpression =
let proj_kind = { adt_id; field_id } in
- let qualif = { id = Proj proj_kind; type_args; const_generic_args } in
+ let qualif = { id = Proj proj_kind; generics } in
let proj_e = Qualif qualif in
let proj_ty = mk_arrow scrutinee.ty dest.ty in
let proj = { e = proj_e; ty = proj_ty } in
@@ -2259,17 +2445,12 @@ and translate_ExpandAdt_one_branch (sv : V.symbolic_value)
(mk_typed_pattern_from_var var None)
(mk_opt_mplace_texpression scrutinee_mplace scrutinee)
branch
- | T.Assumed (T.Vec | T.Array | T.Slice | T.Str) ->
+ | T.Assumed (T.Array | T.Slice | T.Str) ->
(* We can't expand those values: we can access the fields only
* through the functions provided by the API (note that we don't
* know how to expand values like vectors or arrays, because they have a variable number
* of fields!) *)
raise (Failure "Attempt to expand a non-expandable value")
- | T.Assumed Range -> raise (Failure "Unimplemented")
- | T.Assumed T.Option ->
- (* We shouldn't get there in the "one-branch" case: options have
- * two variants *)
- raise (Failure "Unreachable")
and translate_intro_symbolic (ectx : C.eval_ctx) (p : S.mplace option)
(sv : V.symbolic_value) (v : S.value_aggregate) (e : S.expression)
@@ -2282,8 +2463,9 @@ and translate_intro_symbolic (ectx : C.eval_ctx) (p : S.mplace option)
(* Translate the next expression *)
let next_e = translate_expression e ctx in
- (* Translate the value: there are two cases, depending on whether this
- is a "regular" let-binding or an array aggregate.
+ (* Translate the value: there are several cases, depending on whether this
+ is a "regular" let-binding, an array aggregate, a const generic or
+ a trait associated constant.
*)
let v =
match v with
@@ -2298,6 +2480,14 @@ and translate_intro_symbolic (ectx : C.eval_ctx) (p : S.mplace option)
{ struct_id = Assumed Array; init = None; updates = values }
in
{ e = StructUpdate su; ty = var.ty }
+ | ConstGenericValue cg_id -> { e = CVar cg_id; ty = var.ty }
+ | TraitConstValue (trait_ref, generics, const_name) ->
+ let type_infos = ctx.type_context.type_infos in
+ let trait_ref = translate_fwd_trait_ref type_infos trait_ref in
+ let generics = translate_fwd_generic_args type_infos generics in
+ let qualif_id = TraitConst (trait_ref, generics, const_name) in
+ let qualif = { id = qualif_id; generics = empty_generic_args } in
+ { e = Qualif qualif; ty = var.ty }
in
(* Make the let-binding *)
@@ -2368,9 +2558,9 @@ and translate_forward_end (ectx : C.eval_ctx)
let org_args = args in
(* Lookup the effect info for the loop function *)
- let fid = A.Regular ctx.fun_decl.A.def_id in
+ let fid = E.Regular ctx.fun_decl.A.def_id in
let effect_info =
- get_fun_effect_info ctx.fun_context.fun_infos fid None ctx.bid
+ get_fun_effect_info ctx.fun_context.fun_infos (FunId fid) None ctx.bid
in
(* Introduce a fresh output value for the forward function *)
@@ -2415,14 +2605,8 @@ and translate_forward_end (ectx : C.eval_ctx)
let out_pat = mk_simpl_tuple_pattern out_pats in
let loop_call =
- let fun_id = Fun (FromLlbc (fid, Some loop_id, None)) in
- let func =
- {
- id = FunOrOp fun_id;
- type_args = loop_info.type_args;
- const_generic_args = loop_info.const_generic_args;
- }
- in
+ let fun_id = Fun (FromLlbc (FunId fid, Some loop_id, None)) in
+ let func = { id = FunOrOp fun_id; generics = loop_info.generics } in
let input_tys = (List.map (fun (x : texpression) -> x.ty)) args in
let ret_ty =
if effect_info.can_fail then mk_result_ty out_pat.ty else out_pat.ty
@@ -2541,14 +2725,31 @@ and translate_loop (loop : S.loop) (ctx : bs_ctx) : texpression =
(* Note that we will retrieve the input values later in the [ForwardEnd]
(and will introduce the outputs at that moment, together with the actual
- call to the loop forward function *)
- let type_args =
- List.map (fun (ty : T.type_var) -> TypeVar ty.T.index) ctx.sg.type_params
- in
- let const_generic_args =
- List.map
- (fun (cg : T.const_generic_var) -> T.ConstGenericVar cg.T.index)
- ctx.sg.const_generic_params
+ call to the loop forward function) *)
+ let generics =
+ let { types; const_generics; trait_clauses } = ctx.sg.generics in
+ let types =
+ List.map (fun (ty : T.type_var) -> TypeVar ty.T.index) types
+ in
+ let const_generics =
+ List.map
+ (fun (cg : T.const_generic_var) -> T.ConstGenericVar cg.T.index)
+ const_generics
+ in
+ let trait_refs =
+ List.map
+ (fun (c : trait_clause) ->
+ let trait_decl_ref =
+ { trait_decl_id = c.trait_id; decl_generics = empty_generic_args }
+ in
+ {
+ trait_id = Clause c.clause_id;
+ generics = empty_generic_args;
+ trait_decl_ref;
+ })
+ trait_clauses
+ in
+ { types; const_generics; trait_refs }
in
let loop_info =
@@ -2556,8 +2757,7 @@ and translate_loop (loop : S.loop) (ctx : bs_ctx) : texpression =
loop_id;
input_vars = inputs;
input_svl = loop.input_svalues;
- type_args;
- const_generic_args;
+ generics;
forward_inputs = None;
forward_output_no_state_no_result = None;
}
@@ -2648,8 +2848,7 @@ let wrap_in_match_fuel (fuel0 : VarId.id) (fuel : VarId.id) (body : texpression)
let func =
{
id = FunOrOp (Fun (Pure FuelEqZero));
- type_args = [];
- const_generic_args = [];
+ generics = empty_generic_args;
}
in
let func_ty = mk_arrow mk_fuel_ty mk_bool_ty in
@@ -2661,8 +2860,7 @@ let wrap_in_match_fuel (fuel0 : VarId.id) (fuel : VarId.id) (body : texpression)
let func =
{
id = FunOrOp (Fun (Pure FuelDecrease));
- type_args = [];
- const_generic_args = [];
+ generics = empty_generic_args;
}
in
let func_ty = mk_arrow mk_fuel_ty mk_fuel_ty in
@@ -2727,8 +2925,8 @@ let translate_fun_decl (ctx : bs_ctx) (body : S.expression option) : fun_decl =
| None -> None
| Some body ->
let effect_info =
- get_fun_effect_info ctx.fun_context.fun_infos (Regular def_id) None
- bid
+ get_fun_effect_info ctx.fun_context.fun_infos (FunId (Regular def_id))
+ None bid
in
let body = translate_expression body ctx in
(* Add a match over the fuel, if necessary *)
@@ -2803,10 +3001,12 @@ let translate_fun_decl (ctx : bs_ctx) (body : S.expression option) : fun_decl =
^ "\n- signature.inputs: "
^ String.concat ", " (List.map (ty_to_string ctx) signature.inputs)
));
- assert (
- List.for_all
- (fun (var, ty) -> (var : var).ty = ty)
- (List.combine inputs signature.inputs));
+ (* TODO: we need to normalize the types *)
+ if !Config.type_check_pure_code then
+ assert (
+ List.for_all
+ (fun (var, ty) -> (var : var).ty = ty)
+ (List.combine inputs signature.inputs));
Some { inputs; inputs_lvs; body }
in
@@ -2821,6 +3021,7 @@ let translate_fun_decl (ctx : bs_ctx) (body : S.expression option) : fun_decl =
let def =
{
def_id;
+ kind = def.kind;
num_loops;
loop_id;
back_id = bid;
@@ -2853,8 +3054,7 @@ let translate_type_decls (type_decls : T.type_decl list) : type_decl list =
- optional names for the outputs values (we derive them for the backward
functions)
*)
-let translate_fun_signatures (fun_infos : FA.fun_info A.FunDeclId.Map.t)
- (type_infos : TA.type_infos)
+let translate_fun_signatures (decls_ctx : C.decls_ctx)
(functions : (A.fun_id * string option list * A.fun_sig) list) :
fun_sig_named_outputs RegularFunIdNotLoopMap.t =
(* For every function, translate the signatures of:
@@ -2865,17 +3065,14 @@ let translate_fun_signatures (fun_infos : FA.fun_info A.FunDeclId.Map.t)
(sg : A.fun_sig) : (regular_fun_id_not_loop * fun_sig_named_outputs) list
=
(* The forward function *)
- let fwd_sg =
- translate_fun_sig fun_infos fun_id type_infos sg input_names None
- in
+ let fwd_sg = translate_fun_sig decls_ctx fun_id sg input_names None in
let fwd_id = (fun_id, None) in
(* The backward functions *)
let back_sgs =
List.map
(fun (rg : T.region_var_group) ->
let tsg =
- translate_fun_sig fun_infos fun_id type_infos sg input_names
- (Some rg.id)
+ translate_fun_sig decls_ctx fun_id sg input_names (Some rg.id)
in
let id = (fun_id, Some rg.id) in
(id, tsg))
@@ -2891,3 +3088,94 @@ let translate_fun_signatures (fun_infos : FA.fun_info A.FunDeclId.Map.t)
List.fold_left
(fun m (id, sg) -> RegularFunIdNotLoopMap.add id sg m)
RegularFunIdNotLoopMap.empty translated
+
+let translate_trait_decl (type_infos : TA.type_infos)
+ (trait_decl : A.trait_decl) : trait_decl =
+ let {
+ def_id;
+ name;
+ generics;
+ preds;
+ parent_clauses;
+ consts;
+ types;
+ required_methods;
+ provided_methods;
+ } : A.trait_decl =
+ trait_decl
+ in
+ let generics = translate_generic_params generics in
+ let preds = translate_predicates preds in
+ let parent_clauses = List.map translate_trait_clause parent_clauses in
+ let consts =
+ List.map
+ (fun (name, (ty, id)) -> (name, (translate_fwd_ty type_infos ty, id)))
+ consts
+ in
+ let types =
+ List.map
+ (fun (name, (trait_clauses, ty)) ->
+ ( name,
+ ( List.map translate_trait_clause trait_clauses,
+ Option.map (translate_fwd_ty type_infos) ty ) ))
+ types
+ in
+ {
+ def_id;
+ name;
+ generics;
+ preds;
+ parent_clauses;
+ consts;
+ types;
+ required_methods;
+ provided_methods;
+ }
+
+let translate_trait_impl (type_infos : TA.type_infos)
+ (trait_impl : A.trait_impl) : trait_impl =
+ let {
+ A.def_id;
+ name;
+ impl_trait;
+ generics;
+ preds;
+ parent_trait_refs;
+ consts;
+ types;
+ required_methods;
+ provided_methods;
+ } =
+ trait_impl
+ in
+ let impl_trait =
+ translate_trait_decl_ref (translate_fwd_ty type_infos) impl_trait
+ in
+ let generics = translate_generic_params generics in
+ let preds = translate_predicates preds in
+ let parent_trait_refs = List.map translate_strait_ref parent_trait_refs in
+ let consts =
+ List.map
+ (fun (name, (ty, id)) -> (name, (translate_fwd_ty type_infos ty, id)))
+ consts
+ in
+ let types =
+ List.map
+ (fun (name, (trait_refs, ty)) ->
+ ( name,
+ ( List.map (translate_fwd_trait_ref type_infos) trait_refs,
+ translate_fwd_ty type_infos ty ) ))
+ types
+ in
+ {
+ def_id;
+ name;
+ impl_trait;
+ generics;
+ preds;
+ parent_trait_refs;
+ consts;
+ types;
+ required_methods;
+ provided_methods;
+ }
diff --git a/compiler/SynthesizeSymbolic.ml b/compiler/SynthesizeSymbolic.ml
index 857fea97..9dd65c84 100644
--- a/compiler/SynthesizeSymbolic.ml
+++ b/compiler/SynthesizeSymbolic.ml
@@ -64,7 +64,7 @@ let synthesize_symbolic_expansion (sv : V.symbolic_value)
assert (otherwise_see = None);
(* Return *)
ExpandInt (int_ty, branches, otherwise)
- | T.Adt (_, _, _, _) ->
+ | T.Adt (_, _) ->
(* Branching: it is necessarily an enumeration expansion *)
let get_variant (see : V.symbolic_expansion option) :
T.VariantId.id option * V.symbolic_value list =
@@ -85,7 +85,9 @@ let synthesize_symbolic_expansion (sv : V.symbolic_value)
match ls with
| [ (Some see, exp) ] -> ExpandNoBranch (see, exp)
| _ -> raise (Failure "Ill-formed borrow expansion"))
- | T.TypeVar _ | T.Literal Char | Never ->
+ | T.TypeVar _
+ | T.Literal Char
+ | Never | T.TraitType _ | T.Arrow _ | T.RawPtr _ ->
raise (Failure "Ill-formed symbolic expansion")
in
Some (Expansion (place, sv, expansion))
@@ -97,10 +99,10 @@ let synthesize_symbolic_expansion_no_branching (sv : V.symbolic_value)
synthesize_symbolic_expansion sv place [ Some see ] el
let synthesize_function_call (call_id : call_id) (ctx : Contexts.eval_ctx)
- (abstractions : V.AbstractionId.id list) (type_params : T.ety list)
- (const_generic_params : T.const_generic list) (args : V.typed_value list)
- (args_places : mplace option list) (dest : V.symbolic_value)
- (dest_place : mplace option) (e : expression option) : expression option =
+ (abstractions : V.AbstractionId.id list) (generics : T.egeneric_args)
+ (args : V.typed_value list) (args_places : mplace option list)
+ (dest : V.symbolic_value) (dest_place : mplace option)
+ (e : expression option) : expression option =
Option.map
(fun e ->
let call =
@@ -108,8 +110,7 @@ let synthesize_function_call (call_id : call_id) (ctx : Contexts.eval_ctx)
call_id;
ctx;
abstractions;
- type_params;
- const_generic_params;
+ generics;
args;
dest;
args_places;
@@ -123,28 +124,29 @@ let synthesize_global_eval (gid : A.GlobalDeclId.id) (dest : V.symbolic_value)
(e : expression option) : expression option =
Option.map (fun e -> EvalGlobal (gid, dest, e)) e
-let synthesize_regular_function_call (fun_id : A.fun_id)
+let synthesize_regular_function_call (fun_id : A.fun_id_or_trait_method_ref)
(call_id : V.FunCallId.id) (ctx : Contexts.eval_ctx)
- (abstractions : V.AbstractionId.id list) (type_params : T.ety list)
- (const_generic_params : T.const_generic list) (args : V.typed_value list)
- (args_places : mplace option list) (dest : V.symbolic_value)
- (dest_place : mplace option) (e : expression option) : expression option =
+ (abstractions : V.AbstractionId.id list) (generics : T.egeneric_args)
+ (args : V.typed_value list) (args_places : mplace option list)
+ (dest : V.symbolic_value) (dest_place : mplace option)
+ (e : expression option) : expression option =
synthesize_function_call
(Fun (fun_id, call_id))
- ctx abstractions type_params const_generic_params args args_places dest
- dest_place e
+ ctx abstractions generics args args_places dest dest_place e
let synthesize_unary_op (ctx : Contexts.eval_ctx) (unop : E.unop)
(arg : V.typed_value) (arg_place : mplace option) (dest : V.symbolic_value)
(dest_place : mplace option) (e : expression option) : expression option =
- synthesize_function_call (Unop unop) ctx [] [] [] [ arg ] [ arg_place ] dest
- dest_place e
+ let generics = TypesUtils.mk_empty_generic_args in
+ synthesize_function_call (Unop unop) ctx [] generics [ arg ] [ arg_place ]
+ dest dest_place e
let synthesize_binary_op (ctx : Contexts.eval_ctx) (binop : E.binop)
(arg0 : V.typed_value) (arg0_place : mplace option) (arg1 : V.typed_value)
(arg1_place : mplace option) (dest : V.symbolic_value)
(dest_place : mplace option) (e : expression option) : expression option =
- synthesize_function_call (Binop binop) ctx [] [] [] [ arg0; arg1 ]
+ let generics = TypesUtils.mk_empty_generic_args in
+ synthesize_function_call (Binop binop) ctx [] generics [ arg0; arg1 ]
[ arg0_place; arg1_place ] dest dest_place e
let synthesize_end_abstraction (ctx : Contexts.eval_ctx) (abs : V.abs)
diff --git a/compiler/Translate.ml b/compiler/Translate.ml
index 70ef5e3d..a3d96023 100644
--- a/compiler/Translate.ml
+++ b/compiler/Translate.ml
@@ -5,6 +5,7 @@ module T = Types
module A = LlbcAst
module SA = SymbolicAst
module Micro = PureMicroPasses
+module C = Contexts
open PureUtils
open TranslateCore
@@ -28,18 +29,12 @@ let translate_function_to_symbolics (trans_ctx : trans_ctx) (fdef : A.fun_decl)
("translate_function_to_symbolics: "
^ Print.fun_name_to_string fdef.A.name));
- let { type_context; fun_context; global_context } = trans_ctx in
- let fun_context = { C.fun_decls = fun_context.fun_decls } in
-
match fdef.body with
| None -> None
| Some _ ->
(* Evaluate *)
let synthesize = true in
- let inputs, symb =
- evaluate_function_symbolic synthesize type_context fun_context
- global_context fdef
- in
+ let inputs, symb = evaluate_function_symbolic synthesize trans_ctx fdef in
Some (inputs, Option.get symb)
(** Translate a function, by generating its forward and backward translations.
@@ -57,7 +52,6 @@ let translate_function_to_pure (trans_ctx : trans_ctx)
(lazy
("translate_function_to_pure: " ^ Print.fun_name_to_string fdef.A.name));
- let { type_context; fun_context; global_context } = trans_ctx in
let def_id = fdef.def_id in
(* Compute the symbolic ASTs, if the function is transparent *)
@@ -67,7 +61,7 @@ let translate_function_to_pure (trans_ctx : trans_ctx)
(* Initialize the context *)
let forward_sig =
- RegularFunIdNotLoopMap.find (A.Regular def_id, None) fun_sigs
+ RegularFunIdNotLoopMap.find (E.Regular def_id, None) fun_sigs
in
let sv_to_var = V.SymbolicValueId.Map.empty in
let var_counter = Pure.VarId.generator_zero in
@@ -82,25 +76,25 @@ let translate_function_to_pure (trans_ctx : trans_ctx)
(List.filter_map
(fun (tid, g) ->
match g with Charon.GAst.NonRec _ -> None | Rec _ -> Some tid)
- (T.TypeDeclId.Map.bindings trans_ctx.type_context.type_decls_groups))
+ (T.TypeDeclId.Map.bindings trans_ctx.type_ctx.type_decls_groups))
in
let type_context =
{
- SymbolicToPure.type_infos = type_context.type_infos;
- llbc_type_decls = type_context.type_decls;
+ SymbolicToPure.type_infos = trans_ctx.type_ctx.type_infos;
+ llbc_type_decls = trans_ctx.type_ctx.type_decls;
type_decls = pure_type_decls;
recursive_decls = recursive_type_decls;
}
in
let fun_context =
{
- SymbolicToPure.llbc_fun_decls = fun_context.fun_decls;
+ SymbolicToPure.llbc_fun_decls = trans_ctx.fun_ctx.fun_decls;
fun_sigs;
- fun_infos = fun_context.fun_infos;
+ fun_infos = trans_ctx.fun_ctx.fun_infos;
}
in
let global_context =
- { SymbolicToPure.llbc_global_decls = global_context.global_decls }
+ { SymbolicToPure.llbc_global_decls = trans_ctx.global_ctx.global_decls }
in
(* Compute the set of loops, and find better ids for them (starting at 0).
@@ -148,6 +142,8 @@ let translate_function_to_pure (trans_ctx : trans_ctx)
type_context;
fun_context;
global_context;
+ trait_decls_ctx = trans_ctx.trait_decls_ctx.trait_decls;
+ trait_impls_ctx = trans_ctx.trait_impls_ctx.trait_impls;
fun_decl = fdef;
forward_inputs = [];
(* Empty for now *)
@@ -204,7 +200,7 @@ let translate_function_to_pure (trans_ctx : trans_ctx)
(* Initialize the context - note that the ret_ty is not really
* useful as we don't translate a body *)
let backward_sg =
- RegularFunIdNotLoopMap.find (A.Regular def_id, Some back_id) fun_sigs
+ RegularFunIdNotLoopMap.find (Regular def_id, Some back_id) fun_sigs
in
let ctx = { ctx with bid = Some back_id; sg = backward_sg.sg } in
@@ -215,7 +211,7 @@ let translate_function_to_pure (trans_ctx : trans_ctx)
variables required by the backward function.
*)
let backward_sg =
- RegularFunIdNotLoopMap.find (A.Regular def_id, Some back_id) fun_sigs
+ RegularFunIdNotLoopMap.find (Regular def_id, Some back_id) fun_sigs
in
(* We need to ignore the forward inputs, and the state input (if there is) *)
let backward_inputs =
@@ -274,21 +270,18 @@ let translate_function_to_pure (trans_ctx : trans_ctx)
(* Return *)
(pure_forward, pure_backwards)
+(* TODO: factor out the return type *)
let translate_crate_to_pure (crate : A.crate) :
- trans_ctx * Pure.type_decl list * (bool * pure_fun_translation) list =
+ trans_ctx
+ * Pure.type_decl list
+ * pure_fun_translation list
+ * Pure.trait_decl list
+ * Pure.trait_impl list =
(* Debug *)
log#ldebug (lazy "translate_crate_to_pure");
- (* Compute the type and function contexts *)
- let type_context, fun_context, global_context =
- compute_type_fun_global_contexts crate
- in
- let fun_infos =
- FA.analyze_module crate fun_context.C.fun_decls
- global_context.C.global_decls !Config.use_state
- in
- let fun_context = { fun_decls = fun_context.fun_decls; fun_infos } in
- let trans_ctx = { type_context; fun_context; global_context } in
+ (* Compute the translation context *)
+ let trans_ctx = compute_contexts crate in
(* Translate all the type definitions *)
let type_decls =
@@ -304,9 +297,11 @@ let translate_crate_to_pure (crate : A.crate) :
(* Translate all the function *signatures* *)
let assumed_sigs =
List.map
- (fun (id, sg, _, _) ->
- (A.Assumed id, List.map (fun _ -> None) (sg : A.fun_sig).inputs, sg))
- Assumed.assumed_infos
+ (fun (info : Assumed.assumed_fun_info) ->
+ ( E.Assumed info.fun_id,
+ List.map (fun _ -> None) info.fun_sig.inputs,
+ info.fun_sig ))
+ Assumed.assumed_fun_infos
in
let local_sigs =
List.map
@@ -319,14 +314,11 @@ let translate_crate_to_pure (crate : A.crate) :
(fun (v : A.var) -> v.name)
(LlbcAstUtils.fun_body_get_input_vars body)
in
- (A.Regular fdef.def_id, input_names, fdef.signature))
+ (E.Regular fdef.def_id, input_names, fdef.signature))
(A.FunDeclId.Map.values crate.functions)
in
let sigs = List.append assumed_sigs local_sigs in
- let fun_sigs =
- SymbolicToPure.translate_fun_signatures fun_context.fun_infos
- type_context.type_infos sigs
- in
+ let fun_sigs = SymbolicToPure.translate_fun_signatures trans_ctx sigs in
(* Translate all the *transparent* functions *)
let pure_translations =
@@ -335,28 +327,38 @@ let translate_crate_to_pure (crate : A.crate) :
(A.FunDeclId.Map.values crate.functions)
in
+ (* Translate the trait declarations *)
+ let type_infos = trans_ctx.type_ctx.type_infos in
+ let trait_decls =
+ List.map
+ (SymbolicToPure.translate_trait_decl type_infos)
+ (T.TraitDeclId.Map.values trans_ctx.trait_decls_ctx.trait_decls)
+ in
+
+ (* Translate the trait implementations *)
+ let trait_impls =
+ List.map
+ (SymbolicToPure.translate_trait_impl type_infos)
+ (T.TraitImplId.Map.values trans_ctx.trait_impls_ctx.trait_impls)
+ in
+
(* Apply the micro-passes *)
let pure_translations =
Micro.apply_passes_to_pure_fun_translations trans_ctx pure_translations
in
(* Return *)
- (trans_ctx, type_decls, pure_translations)
-
-(** Extraction context *)
-type gen_ctx = {
- crate : A.crate;
- extract_ctx : ExtractBase.extraction_ctx;
- trans_types : Pure.type_decl Pure.TypeDeclId.Map.t;
- trans_funs : (bool * pure_fun_translation) A.FunDeclId.Map.t;
- functions_with_decreases_clause : PureUtils.FunLoopIdSet.t;
-}
+ (trans_ctx, type_decls, pure_translations, trait_decls, trait_impls)
+
+type gen_ctx = ExtractBase.extraction_ctx
type gen_config = {
extract_types : bool;
extract_decreases_clauses : bool;
extract_template_decreases_clauses : bool;
extract_fun_decls : bool;
+ extract_trait_decls : bool;
+ extract_trait_impls : bool;
extract_transparent : bool;
(** If [true], extract the transparent declarations, otherwise ignore. *)
extract_opaque : bool;
@@ -383,21 +385,23 @@ type gen_config = {
test_trans_unit_functions : bool;
}
-(** Returns the pair: (has opaque type decls, has opaque fun decls) *)
-let module_has_opaque_decls (ctx : gen_ctx) : bool * bool =
- let has_opaque_types =
- Pure.TypeDeclId.Map.exists
- (fun _ (d : Pure.type_decl) ->
- match d.kind with Opaque -> true | _ -> false)
- ctx.trans_types
- in
- let has_opaque_funs =
- A.FunDeclId.Map.exists
- (fun _ ((_, ((t_fwd, _), _)) : bool * pure_fun_translation) ->
- Option.is_none t_fwd.body)
- ctx.trans_funs
+(** Returns the pair: (has opaque type decls, has opaque fun decls).
+
+ [filter_assumed]: if [true], do not consider as opaque the external definitions
+ that we will map to definitions from the standard library.
+ *)
+let crate_has_opaque_non_builtin_decls (ctx : gen_ctx) (filter_assumed : bool) :
+ bool * bool =
+ let types, funs =
+ LlbcAstUtils.crate_get_opaque_non_builtin_decls ctx.crate filter_assumed
in
- (has_opaque_types, has_opaque_funs)
+ log#ldebug
+ (lazy
+ ("Opaque decls:" ^ "\n- types:\n"
+ ^ String.concat ",\n" (List.map T.show_type_decl types)
+ ^ "\n- functions:\n"
+ ^ String.concat ",\n" (List.map A.show_fun_decl funs)));
+ (types <> [], funs <> [])
(** Export a type declaration.
@@ -423,15 +427,19 @@ let export_type (fmt : Format.formatter) (config : gen_config) (ctx : gen_ctx)
(true, kind)
in
(* Extract, if the config instructs to do so (depending on whether the type
- * is opaque or not) *)
- if
+ is opaque or not). Remark: we don't check if the definitions are builtin
+ here but in the function [export_types_group]: the reason is that if one
+ definition in the group is builtin, then we must check that all the
+ definitions are marked builtin *)
+ let extract =
(is_opaque && config.extract_opaque)
|| ((not is_opaque) && config.extract_transparent)
- then (
+ in
+ if extract then (
if extract_decl then
- Extract.extract_type_decl ctx.extract_ctx fmt type_decl_group kind def;
+ Extract.extract_type_decl ctx fmt type_decl_group kind def;
if extract_extra_info then
- Extract.extract_type_decl_extra_info ctx.extract_ctx fmt kind def)
+ Extract.extract_type_decl_extra_info ctx fmt kind def)
(** Export a group of types.
@@ -462,41 +470,58 @@ let export_types_group (fmt : Format.formatter) (config : gen_config)
List.map (fun id -> Pure.TypeDeclId.Map.find id ctx.trans_types) ids
in
- (* Extract the type declarations.
-
- Because some declaration groups are delimited, we wrap the declarations
- between [{start,end}_type_decl_group].
+ (* Check if the definition are builtin - if yes they must be ignored.
+ Note that if one definition in the group is builtin, then all the
+ definitions must be builtin *)
+ let builtin =
+ let open ExtractBuiltin in
+ let types_map = builtin_types_map () in
+ List.map
+ (fun (def : Pure.type_decl) ->
+ let sname = name_to_simple_name def.name in
+ SimpleNameMap.find_opt sname types_map <> None)
+ defs
+ in
- Ex.:
- ====
- When targeting HOL4, the calls to [{start,end}_type_decl_group] would generate
- the [Datatype] and [End] delimiters in the snippet of code below:
+ if List.exists (fun b -> b) builtin then
+ (* Sanity check *)
+ assert (List.for_all (fun b -> b) builtin)
+ else (
+ (* Extract the type declarations.
+
+ Because some declaration groups are delimited, we wrap the declarations
+ between [{start,end}_type_decl_group].
+
+ Ex.:
+ ====
+ When targeting HOL4, the calls to [{start,end}_type_decl_group] would generate
+ the [Datatype] and [End] delimiters in the snippet of code below:
+
+ {[
+ Datatype:
+ tree =
+ TLeaf 'a
+ | TNode node ;
+
+ node =
+ Node (tree list)
+ End
+ ]}
+ *)
+ Extract.start_type_decl_group ctx fmt is_rec defs;
+ List.iteri
+ (fun i def ->
+ let kind = kind_from_index i in
+ export_type_decl kind def)
+ defs;
+ Extract.end_type_decl_group fmt is_rec defs;
- {[
- Datatype:
- tree =
- TLeaf 'a
- | TNode node ;
-
- node =
- Node (tree list)
- End
- ]}
- *)
- Extract.start_type_decl_group ctx.extract_ctx fmt is_rec defs;
- List.iteri
- (fun i def ->
- let kind = kind_from_index i in
- export_type_decl kind def)
- defs;
- Extract.end_type_decl_group fmt is_rec defs;
-
- (* Export the extra information (ex.: [Arguments] instructions in Coq) *)
- List.iteri
- (fun i def ->
- let kind = kind_from_index i in
- export_type_extra_info kind def)
- defs
+ (* Export the extra information (ex.: [Arguments] instructions in Coq) *)
+ List.iteri
+ (fun i def ->
+ let kind = kind_from_index i in
+ export_type_extra_info kind def)
+ defs)
(** Export a global declaration.
@@ -504,26 +529,34 @@ let export_types_group (fmt : Format.formatter) (config : gen_config)
*)
let export_global (fmt : Format.formatter) (config : gen_config) (ctx : gen_ctx)
(id : A.GlobalDeclId.id) : unit =
- let global_decls = ctx.extract_ctx.trans_ctx.global_context.global_decls in
+ let global_decls = ctx.trans_ctx.global_ctx.global_decls in
let global = A.GlobalDeclId.Map.find id global_decls in
- let _, ((body, loop_fwds), body_backs) =
- A.FunDeclId.Map.find global.body_id ctx.trans_funs
- in
- assert (body_backs = []);
- assert (loop_fwds = []);
+ let trans = A.FunDeclId.Map.find global.body_id ctx.trans_funs in
+ assert (trans.fwd.loops = []);
+ assert (trans.backs = []);
+ let body = trans.fwd.f in
let is_opaque = Option.is_none body.Pure.body in
- if
+ (* Check if we extract the global *)
+ let extract =
config.extract_globals
&& (((not is_opaque) && config.extract_transparent)
|| (is_opaque && config.extract_opaque))
- then
+ in
+ (* Check if it is a builtin global - if yes, we ignore it because we
+ map the definition to one in the standard library *)
+ let open ExtractBuiltin in
+ let sname = name_to_simple_name global.name in
+ let extract =
+ extract && SimpleNameMap.find_opt sname builtin_globals_map = None
+ in
+ if extract then
(* We don't wrap global declaration groups between calls to functions
[{start, end}_global_decl_group] (which don't exist): global declaration
groups are always singletons, so the [extract_global_decl] function
takes care of generating the delimiters.
*)
- Extract.extract_global_decl ctx.extract_ctx fmt global body config.interface
+ Extract.extract_global_decl ctx fmt global body config.interface
(** Utility.
@@ -604,14 +637,13 @@ let export_functions_group_scc (fmt : Format.formatter) (config : gen_config)
then
Some
(fun () ->
- Extract.extract_fun_decl ctx.extract_ctx fmt kind has_decr_clause
- def)
+ Extract.extract_fun_decl ctx fmt kind has_decr_clause def)
else None)
decls
in
let extract_defs = List.filter_map (fun x -> x) extract_defs in
if extract_defs <> [] then (
- Extract.start_fun_decl_group ctx.extract_ctx fmt is_rec decls;
+ Extract.start_fun_decl_group ctx fmt is_rec decls;
List.iter (fun f -> f ()) extract_defs;
Extract.end_fun_decl_group fmt is_rec decls)
@@ -621,82 +653,137 @@ let export_functions_group_scc (fmt : Format.formatter) (config : gen_config)
check if the forward and backward functions are mutually recursive.
*)
let export_functions_group (fmt : Format.formatter) (config : gen_config)
- (ctx : gen_ctx) (pure_ls : (bool * pure_fun_translation) list) : unit =
- (* Utility to check a function has a decrease clause *)
- let has_decreases_clause (def : Pure.fun_decl) : bool =
- PureUtils.FunLoopIdSet.mem (def.def_id, def.loop_id)
- ctx.functions_with_decreases_clause
+ (ctx : gen_ctx) (pure_ls : pure_fun_translation list) : unit =
+ (* Check if the definition are builtin - if yes they must be ignored.
+ Note that if one definition in the group is builtin, then all the
+ definitions must be builtin *)
+ let builtin =
+ let open ExtractBuiltin in
+ let funs_map = builtin_funs_map () in
+ List.map
+ (fun (trans : pure_fun_translation) ->
+ let sname = name_to_simple_name trans.fwd.f.basename in
+ SimpleNameMap.find_opt sname funs_map <> None)
+ pure_ls
in
- (* Extract the decrease clauses template bodies *)
- if config.extract_template_decreases_clauses then
- List.iter
- (fun (_, ((fwd, loop_fwds), _)) ->
- (* We only generate decreases clauses for the forward functions, because
- the termination argument should only depend on the forward inputs.
- The backward functions thus use the same decreases clauses as the
- forward function.
-
- Rem.: we might filter backward functions in {!PureMicroPasses}, but
- we don't remove forward functions. Instead, we remember if we should
- filter those functions at extraction time with a boolean (see the
- type of the [pure_ls] input parameter).
- *)
- let extract_decrease decl =
- let has_decr_clause = has_decreases_clause decl in
- if has_decr_clause then
- match !Config.backend with
- | Lean ->
- Extract.extract_template_lean_termination_and_decreasing
- ctx.extract_ctx fmt decl
- | FStar ->
- Extract.extract_template_fstar_decreases_clause ctx.extract_ctx
- fmt decl
- | Coq ->
- raise (Failure "Coq doesn't have decreases/termination clauses")
- | HOL4 ->
- raise
- (Failure "HOL4 doesn't have decreases/termination clauses")
- in
- extract_decrease fwd;
- List.iter extract_decrease loop_fwds)
- pure_ls;
-
- (* Concatenate the function definitions, filtering the useless forward
- * functions. *)
- let decls =
- List.concat
- (List.map
- (fun (keep_fwd, ((fwd, fwd_loops), (back_ls : fun_and_loops list))) ->
- let fwd = if keep_fwd then List.append fwd_loops [ fwd ] else [] in
- let back : Pure.fun_decl list =
- List.concat
- (List.map
- (fun (back, loop_backs) -> List.append loop_backs [ back ])
- back_ls)
- in
- List.append fwd back)
- pure_ls)
- in
+ if List.exists (fun b -> b) builtin then
+ (* Sanity check *)
+ assert (List.for_all (fun b -> b) builtin)
+ else
+ (* Utility to check a function has a decrease clause *)
+ let has_decreases_clause (def : Pure.fun_decl) : bool =
+ PureUtils.FunLoopIdSet.mem (def.def_id, def.loop_id)
+ ctx.functions_with_decreases_clause
+ in
- (* Extract the function definitions *)
- (if config.extract_fun_decls then
- (* Group the mutually recursive definitions *)
- let subgroups = ReorderDecls.group_reorder_fun_decls decls in
+ (* Extract the decrease clauses template bodies *)
+ if config.extract_template_decreases_clauses then
+ List.iter
+ (fun { fwd; _ } ->
+ (* We only generate decreases clauses for the forward functions, because
+ the termination argument should only depend on the forward inputs.
+ The backward functions thus use the same decreases clauses as the
+ forward function.
+
+ Rem.: we might filter backward functions in {!PureMicroPasses}, but
+ we don't remove forward functions. Instead, we remember if we should
+ filter those functions at extraction time with a boolean (see the
+ type of the [pure_ls] input parameter).
+ *)
+ let extract_decrease decl =
+ let has_decr_clause = has_decreases_clause decl in
+ if has_decr_clause then
+ match !Config.backend with
+ | Lean ->
+ Extract.extract_template_lean_termination_and_decreasing ctx
+ fmt decl
+ | FStar ->
+ Extract.extract_template_fstar_decreases_clause ctx fmt decl
+ | Coq ->
+ raise
+ (Failure "Coq doesn't have decreases/termination clauses")
+ | HOL4 ->
+ raise
+ (Failure "HOL4 doesn't have decreases/termination clauses")
+ in
+ extract_decrease fwd.f;
+ List.iter extract_decrease fwd.loops)
+ pure_ls;
+
+ (* Concatenate the function definitions, filtering the useless forward
+ * functions. *)
+ let decls =
+ List.concat
+ (List.map
+ (fun { keep_fwd; fwd; backs } ->
+ let fwd =
+ if keep_fwd then List.append fwd.loops [ fwd.f ] else []
+ in
+ let backs : Pure.fun_decl list =
+ List.concat
+ (List.map
+ (fun back -> List.append back.loops [ back.f ])
+ backs)
+ in
+ List.append fwd backs)
+ pure_ls)
+ in
- (* Extract the subgroups *)
- let export_subgroup (is_rec : bool) (decls : Pure.fun_decl list) : unit =
- export_functions_group_scc fmt config ctx is_rec decls
- in
- List.iter (fun (is_rec, decls) -> export_subgroup is_rec decls) subgroups);
-
- (* Insert unit tests if necessary *)
- if config.test_trans_unit_functions then
- List.iter
- (fun (keep_fwd, ((fwd, _), _)) ->
- if keep_fwd then
- Extract.extract_unit_test_if_unit_fun ctx.extract_ctx fmt fwd)
- pure_ls
+ (* Extract the function definitions *)
+ (if config.extract_fun_decls then
+ (* Group the mutually recursive definitions *)
+ let subgroups = ReorderDecls.group_reorder_fun_decls decls in
+
+ (* Extract the subgroups *)
+ let export_subgroup (is_rec : bool) (decls : Pure.fun_decl list) : unit =
+ export_functions_group_scc fmt config ctx is_rec decls
+ in
+ List.iter (fun (is_rec, decls) -> export_subgroup is_rec decls) subgroups);
+
+ (* Insert unit tests if necessary *)
+ if config.test_trans_unit_functions then
+ List.iter
+ (fun trans ->
+ if trans.keep_fwd then
+ Extract.extract_unit_test_if_unit_fun ctx fmt trans.fwd.f)
+ pure_ls
+
+(** Export a trait declaration. *)
+let export_trait_decl (fmt : Format.formatter) (_config : gen_config)
+ (ctx : gen_ctx) (trait_decl_id : Pure.trait_decl_id) (extract_decl : bool)
+ (extract_extra_info : bool) : unit =
+ let trait_decl = T.TraitDeclId.Map.find trait_decl_id ctx.trans_trait_decls in
+ (* Check if the trait declaration is builtin, in which case we ignore it *)
+ let open ExtractBuiltin in
+ let sname = name_to_simple_name trait_decl.name in
+ if SimpleNameMap.find_opt sname (builtin_trait_decls_map ()) = None then (
+ let ctx = { ctx with trait_decl_id = Some trait_decl.def_id } in
+ if extract_decl then Extract.extract_trait_decl ctx fmt trait_decl;
+ if extract_extra_info then
+ Extract.extract_trait_decl_extra_info ctx fmt trait_decl)
+ else ()
+
+(** Export a trait implementation. *)
+let export_trait_impl (fmt : Format.formatter) (_config : gen_config)
+ (ctx : gen_ctx) (trait_impl_id : Pure.trait_impl_id) : unit =
+ (* Lookup the definition *)
+ let trait_impl = T.TraitImplId.Map.find trait_impl_id ctx.trans_trait_impls in
+ let trait_decl =
+ Pure.TraitDeclId.Map.find trait_impl.impl_trait.trait_decl_id
+ ctx.trans_trait_decls
+ in
+ (* Check if the trait implementation is builtin *)
+ let builtin_info =
+ let open ExtractBuiltin in
+ let type_sname = name_to_simple_name trait_impl.name in
+ let trait_sname = name_to_simple_name trait_decl.name in
+ SimpleNamePairMap.find_opt (type_sname, trait_sname)
+ (builtin_trait_impls_map ())
+ in
+ match builtin_info with
+ | None -> Extract.extract_trait_impl ctx fmt trait_impl
+ | Some _ -> ()
(** A generic utility to generate the extracted definitions: as we may want to
split the definitions between different files (or not), we can control
@@ -712,12 +799,19 @@ let extract_definitions (fmt : Format.formatter) (config : gen_config)
let export_functions_group = export_functions_group fmt config ctx in
let export_global = export_global fmt config ctx in
let export_types_group = export_types_group fmt config ctx in
+ let export_trait_decl_group id =
+ export_trait_decl fmt config ctx id true false
+ in
+ let export_trait_decl_group_extra_info id =
+ export_trait_decl fmt config ctx id false true
+ in
+ let export_trait_impl = export_trait_impl fmt config ctx in
let export_state_type () : unit =
let kind =
if config.interface then ExtractBase.Declared else ExtractBase.Assumed
in
- Extract.extract_state_type fmt ctx.extract_ctx kind
+ Extract.extract_state_type fmt ctx kind
in
let export_decl_group (dg : A.declaration_group) : unit =
@@ -725,11 +819,18 @@ let extract_definitions (fmt : Format.formatter) (config : gen_config)
| Type (NonRec id) ->
if config.extract_types then export_types_group false [ id ]
| Type (Rec ids) -> if config.extract_types then export_types_group true ids
- | Fun (NonRec id) ->
+ | Fun (NonRec id) -> (
(* Lookup *)
let pure_fun = A.FunDeclId.Map.find id ctx.trans_funs in
- (* Translate *)
- export_functions_group [ pure_fun ]
+ (* Special case: we skip trait method *declarations* (we will
+ extract their type directly in the records we generate for
+ the trait declarations themselves, there is no point in having
+ separate type definitions) *)
+ match pure_fun.fwd.f.Pure.kind with
+ | TraitMethodDecl _ -> ()
+ | _ ->
+ (* Translate *)
+ export_functions_group [ pure_fun ])
| Fun (Rec ids) ->
(* General case of mutually recursive functions *)
(* Lookup *)
@@ -739,11 +840,19 @@ let extract_definitions (fmt : Format.formatter) (config : gen_config)
(* Translate *)
export_functions_group pure_funs
| Global id -> export_global id
+ | TraitDecl id ->
+ (* TODO: update to extract groups *)
+ if config.extract_trait_decls && config.extract_transparent then (
+ export_trait_decl_group id;
+ export_trait_decl_group_extra_info id)
+ | TraitImpl id ->
+ if config.extract_trait_impls && config.extract_transparent then
+ export_trait_impl id
in
(* If we need to export the state type: we try to export it after we defined
* the type definitions, because if the user wants to define a model for the
- * type, he might want to reuse those in the state type.
+ * type, they might want to reuse those in the state type.
* More specifically: if we extract functions in the same file as the type,
* we have no choice but to define the state type before the functions,
* because they may reuse this state type: in this case, we define/declare
@@ -752,37 +861,10 @@ let extract_definitions (fmt : Format.formatter) (config : gen_config)
if config.extract_state_type && config.extract_fun_decls then
export_state_type ();
- (* Obsolete: (TODO: remove) For Lean we parameterize the entire development by a section
- variable called opaque_defs, of type OpaqueDefs. The code below emits the type
- definition for OpaqueDefs, which is a structure, in which each field is one of the
- functions marked as Opaque. We emit the `structure ...` bit here, then rely on
- `extract_fun_decl` to be aware of this, and skip the keyword (e.g. "axiom" or "val")
- so as to generate valid syntax for records.
-
- We also generate such a structure only if there actually are opaque definitions. *)
- let wrap_in_sig =
- config.extract_opaque && config.extract_fun_decls
- && !Config.wrap_opaque_in_sig
- &&
- let _, opaque_funs = module_has_opaque_decls ctx in
- opaque_funs
- in
- if wrap_in_sig then (
- (* We change the name of the structure depending on whether we *only*
- extract opaque definitions, or if we extract all definitions *)
- let struct_name =
- if config.extract_transparent then "Definitions" else "OpaqueDefs"
- in
- Format.pp_print_break fmt 0 0;
- Format.pp_open_vbox fmt ctx.extract_ctx.indent_incr;
- Format.pp_print_string fmt ("structure " ^ struct_name ^ " where");
- Format.pp_print_break fmt 0 0);
List.iter export_decl_group ctx.crate.declarations;
if config.extract_state_type && not config.extract_fun_decls then
- export_state_type ();
-
- if wrap_in_sig then Format.pp_close_box fmt ()
+ export_state_type ()
type extract_file_info = {
filename : string;
@@ -904,7 +986,9 @@ let extract_file (config : gen_config) (ctx : gen_ctx) (fi : extract_file_info)
let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
unit =
(* Translate the module to the pure AST *)
- let trans_ctx, trans_types, trans_funs = translate_crate_to_pure crate in
+ let trans_ctx, trans_types, trans_funs, trans_trait_decls, trans_trait_impls =
+ translate_crate_to_pure crate
+ in
(* Initialize the extraction context - for now we extract only to F*.
* We initialize the names map by registering the keywords used in the
@@ -916,41 +1000,27 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
in
(* Initialize the names map (we insert the names of the "primitives"
declarations, and insert the names of the local declarations later) *)
- let mk_formatter_and_names_map = Extract.mk_formatter_and_names_map in
- let fmt, names_map =
- mk_formatter_and_names_map trans_ctx crate.name
+ let fmt, names_maps =
+ Extract.mk_formatter_and_names_maps trans_ctx crate.name
variant_concatenate_type_name
in
- (* Put everything in the context *)
- let ctx =
- {
- ExtractBase.trans_ctx;
- names_map;
- unsafe_names_map = { id_to_name = ExtractBase.IdMap.empty };
- fmt;
- indent_incr = 2;
- use_opaque_pre = !Config.split_files;
- use_dep_ite = !Config.backend = Lean && !Config.extract_decreases_clauses;
- fun_name_info = PureUtils.RegularFunIdMap.empty;
- }
- in
(* We need to compute which functions are recursive, in order to know
* whether we should generate a decrease clause or not. *)
let rec_functions =
List.map
- (fun (_, ((fwd, loop_fwds), _)) ->
- let fwd =
- if fwd.Pure.signature.info.effect_info.is_rec then
- [ (fwd.def_id, None) ]
+ (fun { fwd; _ } ->
+ let fwd_f =
+ if fwd.f.Pure.signature.info.effect_info.is_rec then
+ [ (fwd.f.def_id, None) ]
else []
in
let loop_fwds =
List.map
(fun (def : Pure.fun_decl) -> [ (def.def_id, def.loop_id) ])
- loop_fwds
+ fwd.loops
in
- fwd :: loop_fwds)
+ fwd_f :: loop_fwds)
trans_funs
in
let rec_functions : PureUtils.fun_loop_id list =
@@ -958,22 +1028,70 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
in
let rec_functions = PureUtils.FunLoopIdSet.of_list rec_functions in
- (* Register unique names for all the top-level types, globals and functions.
+ (* Put the translated definitions in maps *)
+ let trans_types =
+ Pure.TypeDeclId.Map.of_list
+ (List.map (fun (d : Pure.type_decl) -> (d.def_id, d)) trans_types)
+ in
+ let trans_funs : pure_fun_translation A.FunDeclId.Map.t =
+ A.FunDeclId.Map.of_list
+ (List.map
+ (fun (trans : pure_fun_translation) -> (trans.fwd.f.def_id, trans))
+ trans_funs)
+ in
+
+ (* Put everything in the context *)
+ let ctx =
+ let trans_trait_decls =
+ T.TraitDeclId.Map.of_list
+ (List.map
+ (fun (d : Pure.trait_decl) -> (d.def_id, d))
+ trans_trait_decls)
+ in
+ let trans_trait_impls =
+ T.TraitImplId.Map.of_list
+ (List.map
+ (fun (d : Pure.trait_impl) -> (d.def_id, d))
+ trans_trait_impls)
+ in
+ {
+ ExtractBase.crate;
+ trans_ctx;
+ names_maps;
+ fmt;
+ indent_incr = 2;
+ use_dep_ite = !Config.backend = Lean && !Config.extract_decreases_clauses;
+ fun_name_info = PureUtils.RegularFunIdMap.empty;
+ trait_decl_id = None (* None by default *);
+ is_provided_method = false (* false by default *);
+ trans_trait_decls;
+ trans_trait_impls;
+ trans_types;
+ trans_funs;
+ functions_with_decreases_clause = rec_functions;
+ types_filter_type_args_map = Pure.TypeDeclId.Map.empty;
+ funs_filter_type_args_map = Pure.FunDeclId.Map.empty;
+ trait_impls_filter_type_args_map = Pure.TraitImplId.Map.empty;
+ }
+ in
+
+ (* Register unique names for all the top-level types, globals, functions...
* Note that the order in which we generate the names doesn't matter:
* we just need to generate a mapping from identifier to name, and make
* sure there are no name clashes. *)
let ctx =
List.fold_left
(fun ctx def -> Extract.extract_type_decl_register_names ctx def)
- ctx trans_types
+ ctx
+ (Pure.TypeDeclId.Map.values trans_types)
in
let ctx =
List.fold_left
- (fun ctx (keep_fwd, defs) ->
+ (fun ctx (trans : pure_fun_translation) ->
(* If requested by the user, register termination measures and decreases
proofs for all the recursive functions *)
- let fwd_def = fst (fst defs) in
+ let fwd_def = trans.fwd.f in
let gen_decr_clause (def : Pure.fun_decl) =
!Config.extract_decreases_clauses
&& PureUtils.FunLoopIdSet.mem
@@ -984,10 +1102,9 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
* those are handled later *)
let is_global = fwd_def.Pure.is_global_decl_body in
if is_global then ctx
- else
- Extract.extract_fun_decl_register_names ctx keep_fwd gen_decr_clause
- defs)
- ctx trans_funs
+ else Extract.extract_fun_decl_register_names ctx gen_decr_clause trans)
+ ctx
+ (A.FunDeclId.Map.values trans_funs)
in
let ctx =
@@ -995,6 +1112,16 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
(A.GlobalDeclId.Map.values crate.globals)
in
+ let ctx =
+ List.fold_left Extract.extract_trait_decl_register_names ctx
+ trans_trait_decls
+ in
+
+ let ctx =
+ List.fold_left Extract.extract_trait_impl_register_names ctx
+ trans_trait_impls
+ in
+
(* Open the output file *)
(* First compute the filename by replacing the extension and converting the
* case (rust module names are snake case) *)
@@ -1023,19 +1150,6 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
(namespace, crate_name, Filename.concat dest_dir crate_name)
in
- (* Put the translated definitions in maps *)
- let trans_types =
- Pure.TypeDeclId.Map.of_list
- (List.map (fun (d : Pure.type_decl) -> (d.def_id, d)) trans_types)
- in
- let trans_funs =
- A.FunDeclId.Map.of_list
- (List.map
- (fun ((keep_fwd, (fd, bdl)) : bool * pure_fun_translation) ->
- ((fst fd).def_id, (keep_fwd, (fd, bdl))))
- trans_funs)
- in
-
let mkdir_if dest_dir =
if not (Sys.file_exists dest_dir) then (
log#linfo (lazy ("Creating missing directory: " ^ dest_dir));
@@ -1091,16 +1205,6 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
in
(* Extract the file(s) *)
- let gen_ctx =
- {
- crate;
- extract_ctx = ctx;
- trans_types;
- trans_funs;
- functions_with_decreases_clause = rec_functions;
- }
- in
-
let module_delimiter =
match !Config.backend with
| FStar -> "."
@@ -1136,6 +1240,8 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
extract_decreases_clauses = !Config.extract_decreases_clauses;
extract_template_decreases_clauses = false;
extract_fun_decls = false;
+ extract_trait_decls = false;
+ extract_trait_impls = false;
extract_transparent = true;
extract_opaque = false;
extract_state_type = false;
@@ -1147,7 +1253,9 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
(* Check if there are opaque types and functions - in which case we need
* to split *)
- let has_opaque_types, has_opaque_funs = module_has_opaque_decls gen_ctx in
+ let has_opaque_types, has_opaque_funs =
+ crate_has_opaque_non_builtin_decls ctx true
+ in
let has_opaque_types = has_opaque_types || !Config.use_state in
(* Extract the types *)
@@ -1168,6 +1276,7 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
{
base_gen_config with
extract_types = true;
+ extract_trait_decls = true;
extract_opaque = true;
extract_state_type = !Config.use_state;
interface = has_opaque_types;
@@ -1186,7 +1295,7 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
custom_includes = [];
}
in
- extract_file types_config gen_ctx file_info;
+ extract_file types_config ctx file_info;
(* Extract the template clauses *)
(if needs_clauses_module && !Config.extract_template_decreases_clauses then
@@ -1214,9 +1323,9 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
custom_includes = [];
}
in
- extract_file template_clauses_config gen_ctx file_info);
+ extract_file template_clauses_config ctx file_info);
- (* Extract the opaque functions, if needed *)
+ (* Extract the opaque declarations, if needed *)
let opaque_funs_module =
if has_opaque_funs then (
(* In the case of Lean we generate a template file *)
@@ -1244,17 +1353,13 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
{
base_gen_config with
extract_fun_decls = true;
+ extract_trait_impls = true;
+ extract_globals = true;
extract_transparent = false;
extract_opaque = true;
interface = true;
}
in
- let gen_ctx =
- {
- gen_ctx with
- extract_ctx = { gen_ctx.extract_ctx with use_opaque_pre = false };
- }
- in
let file_info =
{
filename = opaque_filename;
@@ -1268,7 +1373,7 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
custom_includes = [ types_module ];
}
in
- extract_file opaque_config gen_ctx file_info;
+ extract_file opaque_config ctx file_info;
(* Return the additional dependencies *)
[ opaque_imported_module ])
else []
@@ -1281,6 +1386,7 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
{
base_gen_config with
extract_fun_decls = true;
+ extract_trait_impls = true;
extract_globals = true;
test_trans_unit_functions = !Config.test_trans_unit_functions;
}
@@ -1307,7 +1413,7 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
[ types_module ] @ opaque_funs_module @ clauses_module;
}
in
- extract_file fun_config gen_ctx file_info)
+ extract_file fun_config ctx file_info)
else
let gen_config =
{
@@ -1316,6 +1422,8 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
extract_template_decreases_clauses =
!Config.extract_template_decreases_clauses;
extract_fun_decls = true;
+ extract_trait_decls = true;
+ extract_trait_impls = true;
extract_transparent = true;
extract_opaque = true;
extract_state_type = !Config.use_state;
@@ -1337,7 +1445,7 @@ let translate_crate (filename : string) (dest_dir : string) (crate : A.crate) :
custom_includes = [];
}
in
- extract_file gen_config gen_ctx file_info);
+ extract_file gen_config ctx file_info);
(* Generate the build file *)
match !Config.backend with
diff --git a/compiler/TranslateCore.ml b/compiler/TranslateCore.ml
index ba5e237b..3427fd43 100644
--- a/compiler/TranslateCore.ml
+++ b/compiler/TranslateCore.ml
@@ -10,64 +10,69 @@ module FA = FunsAnalysis
(** The local logger *)
let log = L.translate_log
-type type_context = C.type_context [@@deriving show]
-
-type fun_context = {
- fun_decls : A.fun_decl A.FunDeclId.Map.t;
- fun_infos : FA.fun_info A.FunDeclId.Map.t;
-}
-[@@deriving show]
+type trans_ctx = C.decls_ctx [@@deriving show]
+type fun_and_loops = { f : Pure.fun_decl; loops : Pure.fun_decl list }
+type pure_fun_translation_no_loops = Pure.fun_decl * Pure.fun_decl list
-type global_context = C.global_context [@@deriving show]
+type pure_fun_translation = {
+ keep_fwd : bool;
+ (** Should we extract the forward function?
-type trans_ctx = {
- type_context : type_context;
- fun_context : fun_context;
- global_context : global_context;
+ If the forward function returns `()` and there is exactly one
+ backward function, we may merge the forward into the backward
+ function and thus don't extract the forward function)?
+ *)
+ fwd : fun_and_loops;
+ backs : fun_and_loops list;
}
-type fun_and_loops = Pure.fun_decl * Pure.fun_decl list
-type pure_fun_translation_no_loops = Pure.fun_decl * Pure.fun_decl list
-type pure_fun_translation = fun_and_loops * fun_and_loops list
+let trans_ctx_to_type_formatter (ctx : trans_ctx)
+ (type_params : Pure.type_var list)
+ (const_generic_params : Pure.const_generic_var list) :
+ PrintPure.type_formatter =
+ let type_decls = ctx.type_ctx.type_decls in
+ let global_decls = ctx.global_ctx.global_decls in
+ let trait_decls = ctx.trait_decls_ctx.trait_decls in
+ let trait_impls = ctx.trait_impls_ctx.trait_impls in
+ PrintPure.mk_type_formatter type_decls global_decls trait_decls trait_impls
+ type_params const_generic_params
let type_decl_to_string (ctx : trans_ctx) (def : Pure.type_decl) : string =
- let type_params = def.type_params in
- let cg_params = def.const_generic_params in
- let type_decls = ctx.type_context.type_decls in
- let global_decls = ctx.global_context.global_decls in
+ let generics = def.generics in
let fmt =
- PrintPure.mk_type_formatter type_decls global_decls type_params cg_params
+ trans_ctx_to_type_formatter ctx generics.types generics.const_generics
in
PrintPure.type_decl_to_string fmt def
let type_id_to_string (ctx : trans_ctx) (id : Pure.TypeDeclId.id) : string =
Print.fun_name_to_string
- (Pure.TypeDeclId.Map.find id ctx.type_context.type_decls).name
+ (Pure.TypeDeclId.Map.find id ctx.type_ctx.type_decls).name
+
+let trans_ctx_to_ast_formatter (ctx : trans_ctx)
+ (type_params : Pure.type_var list)
+ (const_generic_params : Pure.const_generic_var list) :
+ PrintPure.ast_formatter =
+ let type_decls = ctx.type_ctx.type_decls in
+ let fun_decls = ctx.fun_ctx.fun_decls in
+ let global_decls = ctx.global_ctx.global_decls in
+ let trait_decls = ctx.trait_decls_ctx.trait_decls in
+ let trait_impls = ctx.trait_impls_ctx.trait_impls in
+ PrintPure.mk_ast_formatter type_decls fun_decls global_decls trait_decls
+ trait_impls type_params const_generic_params
let fun_sig_to_string (ctx : trans_ctx) (sg : Pure.fun_sig) : string =
- let type_params = sg.type_params in
- let cg_params = sg.const_generic_params in
- let type_decls = ctx.type_context.type_decls in
- let fun_decls = ctx.fun_context.fun_decls in
- let global_decls = ctx.global_context.global_decls in
+ let generics = sg.generics in
let fmt =
- PrintPure.mk_ast_formatter type_decls fun_decls global_decls type_params
- cg_params
+ trans_ctx_to_ast_formatter ctx generics.types generics.const_generics
in
PrintPure.fun_sig_to_string fmt sg
let fun_decl_to_string (ctx : trans_ctx) (def : Pure.fun_decl) : string =
- let type_params = def.signature.type_params in
- let cg_params = def.signature.const_generic_params in
- let type_decls = ctx.type_context.type_decls in
- let fun_decls = ctx.fun_context.fun_decls in
- let global_decls = ctx.global_context.global_decls in
+ let generics = def.signature.generics in
let fmt =
- PrintPure.mk_ast_formatter type_decls fun_decls global_decls type_params
- cg_params
+ trans_ctx_to_ast_formatter ctx generics.types generics.const_generics
in
PrintPure.fun_decl_to_string fmt def
let fun_decl_id_to_string (ctx : trans_ctx) (id : A.FunDeclId.id) : string =
- Print.fun_name_to_string
- (A.FunDeclId.Map.find id ctx.fun_context.fun_decls).name
+ Print.fun_name_to_string (A.FunDeclId.Map.find id ctx.fun_ctx.fun_decls).name
diff --git a/compiler/TypesAnalysis.ml b/compiler/TypesAnalysis.ml
index 925f6d39..38d350b1 100644
--- a/compiler/TypesAnalysis.ml
+++ b/compiler/TypesAnalysis.ml
@@ -14,11 +14,10 @@ type expl_info = subtype_info [@@deriving show]
type type_borrows_info = {
contains_static : bool;
- (** Does the type (transitively) contains a static borrow? *)
- contains_borrow : bool;
- (** Does the type (transitively) contains a borrow? *)
+ (** Does the type (transitively) contain a static borrow? *)
+ contains_borrow : bool; (** Does the type (transitively) contain a borrow? *)
contains_nested_borrows : bool;
- (** Does the type (transitively) contains nested borrows? *)
+ (** Does the type (transitively) contain nested borrows? *)
contains_borrow_under_mut : bool;
}
[@@deriving show]
@@ -61,7 +60,7 @@ let initialize_g_type_info (param_infos : 'p) : 'p g_type_info =
let initialize_type_decl_info (def : type_decl) : type_decl_info =
let param_info = { under_borrow = false; under_mut_borrow = false } in
- let param_infos = List.map (fun _ -> param_info) def.type_params in
+ let param_infos = List.map (fun _ -> param_info) def.generics.types in
initialize_g_type_info param_infos
let type_decl_info_to_partial_type_info (info : type_decl_info) :
@@ -122,7 +121,7 @@ let analyze_full_ty (r_is_static : 'r -> bool) (updated : bool ref)
let rec analyze (expl_info : expl_info) (ty_info : partial_type_info)
(ty : 'r ty) : partial_type_info =
match ty with
- | Literal _ | Never -> ty_info
+ | Literal _ | Never | TraitType _ -> ty_info
| TypeVar var_id -> (
(* Update the information for the proper parameter, if necessary *)
match ty_info.param_infos with
@@ -169,22 +168,21 @@ let analyze_full_ty (r_is_static : 'r -> bool) (updated : bool ref)
in
(* Continue exploring *)
analyze expl_info ty_info rty
- | Adt
- ( (Tuple | Assumed (Box | Vec | Option | Slice | Array | Str | Range)),
- _,
- tys,
- _ ) ->
+ | RawPtr (rty, _) ->
+ (* TODO: not sure what to do here *)
+ analyze expl_info ty_info rty
+ | Adt ((Tuple | Assumed (Box | Slice | Array | Str)), generics) ->
(* Nothing to update: just explore the type parameters *)
List.fold_left
(fun ty_info ty -> analyze expl_info ty_info ty)
- ty_info tys
- | Adt (AdtId adt_id, regions, tys, _cgs) ->
+ ty_info generics.types
+ | Adt (AdtId adt_id, generics) ->
(* Lookup the information for this type definition *)
let adt_info = TypeDeclId.Map.find adt_id infos in
(* Update the type info with the information from the adt *)
let ty_info = update_ty_info ty_info adt_info.borrows_info in
(* Check if 'static appears in the region parameters *)
- let found_static = List.exists r_is_static regions in
+ let found_static = List.exists r_is_static generics.regions in
let borrows_info = ty_info.borrows_info in
let borrows_info =
{
@@ -196,7 +194,7 @@ let analyze_full_ty (r_is_static : 'r -> bool) (updated : bool ref)
let ty_info = { ty_info with borrows_info } in
(* For every instantiated type parameter: update the exploration info
* then explore the type *)
- let params_tys = List.combine adt_info.param_infos tys in
+ let params_tys = List.combine adt_info.param_infos generics.types in
let ty_info =
List.fold_left
(fun ty_info (param_info, ty) ->
@@ -235,6 +233,14 @@ let analyze_full_ty (r_is_static : 'r -> bool) (updated : bool ref)
in
(* Return *)
ty_info
+ | Arrow (inputs, output) ->
+ (* Just dive into the arrow *)
+ let ty_info =
+ List.fold_left
+ (fun ty_info ty -> analyze expl_info ty_info ty)
+ ty_info inputs
+ in
+ analyze expl_info ty_info output
in
(* Explore *)
analyze expl_info_init ty_info ty
diff --git a/compiler/Values.ml b/compiler/Values.ml
index d884c319..de27e7a9 100644
--- a/compiler/Values.ml
+++ b/compiler/Values.ml
@@ -52,6 +52,10 @@ type sv_kind =
(** The result of a loop join (when computing loop fixed points) *)
| Aggregate
(** A symbolic value we introduce in place of an aggregate value *)
+ | ConstGeneric
+ (** A symbolic value we introduce when using a const generic as a value *)
+ | TraitConst
+ (** A symbolic value we introduce when evaluating a trait associated constant *)
[@@deriving show, ord]
(** Ancestor for {!symbolic_value} iter visitor *)
diff --git a/compiler/dune b/compiler/dune
index 6785cad4..648c7325 100644
--- a/compiler/dune
+++ b/compiler/dune
@@ -12,6 +12,7 @@
(pps ppx_deriving.show ppx_deriving.ord visitors.ppx))
(libraries charon core_unix unionFind ocamlgraph)
(modules
+ AssociatedTypes
Assumed
Collections
Config
@@ -22,6 +23,8 @@
ExpressionsUtils
Extract
ExtractBase
+ ExtractBuiltin
+ ExtractTypes
FunsAnalysis
Identifiers
InterpreterBorrowsCore
@@ -90,4 +93,4 @@
-g
;-dsource
-warn-error
- -5-8-9-11-14-33-20-21-26-27-39)))
+ -5@8-9-11-14-33-20-21-26-27-39)))
diff --git a/flake.lock b/flake.lock
index 9258bf18..e637bc27 100644
--- a/flake.lock
+++ b/flake.lock
@@ -5,14 +5,14 @@
"crane": "crane",
"flake-utils": "flake-utils",
"nixpkgs": "nixpkgs",
- "rust-overlay": "rust-overlay_2"
+ "rust-overlay": "rust-overlay"
},
"locked": {
- "lastModified": 1691568898,
- "narHash": "sha256-BqKlmpX+tV2VYDZXhIhPbO1v9fbNy1/pzd8AooOXvxE=",
+ "lastModified": 1699619324,
+ "narHash": "sha256-QscTkSBWlmKhODEOavw29MIxOhue9oHdoDXkOmCOgnk=",
"owner": "aeneasverif",
"repo": "charon",
- "rev": "5a81a41bafe18101d368e9ab4af440d7fefeee25",
+ "rev": "7de1d1e7131f20e56b37ce50adbeb7c947f72f44",
"type": "github"
},
"original": {
@@ -23,23 +23,17 @@
},
"crane": {
"inputs": {
- "flake-compat": "flake-compat",
- "flake-utils": [
- "charon",
- "flake-utils"
- ],
"nixpkgs": [
"charon",
"nixpkgs"
- ],
- "rust-overlay": "rust-overlay"
+ ]
},
"locked": {
- "lastModified": 1691423162,
- "narHash": "sha256-cReUZCo83YEEmFcHX8CcOVTZYUrcWgHQO34zxQzy7WI=",
+ "lastModified": 1699548976,
+ "narHash": "sha256-xnpxms0koM8mQpxIup9JnT0F7GrKdvv0QvtxvRuOYR4=",
"owner": "ipetkov",
"repo": "crane",
- "rev": "b5d9d42ea3fa8fea1805d9af1416fe207d0dd1dc",
+ "rev": "6849911446e18e520970cc6b7a691e64ee90d649",
"type": "github"
},
"original": {
@@ -48,32 +42,16 @@
"type": "github"
}
},
- "flake-compat": {
- "flake": false,
- "locked": {
- "lastModified": 1673956053,
- "narHash": "sha256-4gtG9iQuiKITOjNQQeQIpoIB6b16fm+504Ch3sNKLd8=",
- "owner": "edolstra",
- "repo": "flake-compat",
- "rev": "35bb57c0c8d8b62bbfd284272c928ceb64ddbde9",
- "type": "github"
- },
- "original": {
- "owner": "edolstra",
- "repo": "flake-compat",
- "type": "github"
- }
- },
"flake-utils": {
"inputs": {
"systems": "systems"
},
"locked": {
- "lastModified": 1689068808,
- "narHash": "sha256-6ixXo3wt24N/melDWjq70UuHQLxGV8jZvooRanIHXw0=",
+ "lastModified": 1694529238,
+ "narHash": "sha256-zsNZZGTGnMOf9YpHKJqMSsa0dXbfmxeoJ7xHlrt+xmY=",
"owner": "numtide",
"repo": "flake-utils",
- "rev": "919d646de7be200f3bf08cb76ae1f09402b6f9b4",
+ "rev": "ff7b65b44d01cf9ba6a71320833626af21126384",
"type": "github"
},
"original": {
@@ -87,11 +65,11 @@
"systems": "systems_2"
},
"locked": {
- "lastModified": 1681202837,
- "narHash": "sha256-H+Rh19JDwRtpVPAWp64F+rlEtxUWBAQW28eAi3SRSzg=",
+ "lastModified": 1692799911,
+ "narHash": "sha256-3eihraek4qL744EvQXsK1Ha6C3CR7nnT8X2qWap4RNk=",
"owner": "numtide",
"repo": "flake-utils",
- "rev": "cfacdce06f30d2b68473a46042957675eebb3401",
+ "rev": "f9e7cf818399d17d347f847525c5a5a8032e4e44",
"type": "github"
},
"original": {
@@ -104,11 +82,11 @@
"systems": "systems_3"
},
"locked": {
- "lastModified": 1689068808,
- "narHash": "sha256-6ixXo3wt24N/melDWjq70UuHQLxGV8jZvooRanIHXw0=",
+ "lastModified": 1694529238,
+ "narHash": "sha256-zsNZZGTGnMOf9YpHKJqMSsa0dXbfmxeoJ7xHlrt+xmY=",
"owner": "numtide",
"repo": "flake-utils",
- "rev": "919d646de7be200f3bf08cb76ae1f09402b6f9b4",
+ "rev": "ff7b65b44d01cf9ba6a71320833626af21126384",
"type": "github"
},
"original": {
@@ -153,11 +131,11 @@
"nixpkgs": "nixpkgs_2"
},
"locked": {
- "lastModified": 1690839655,
- "narHash": "sha256-285hRt/qzVSMPf34OS187WH4q4edPtb86UJrdZAPtfY=",
+ "lastModified": 1699558636,
+ "narHash": "sha256-N4fyP0An2JBC3PRI0/zSeAapDG4gOYH2D40eHXCOemQ=",
"owner": "fstarlang",
"repo": "fstar",
- "rev": "8f812f3adb7e35810edca22a02016f269c0d1d2a",
+ "rev": "9b60a5b758581edb32488a13e11039db199f89e1",
"type": "github"
},
"original": {
@@ -186,11 +164,11 @@
]
},
"locked": {
- "lastModified": 1688938536,
- "narHash": "sha256-P+uk/ZbY9+StXs5SivB5lT5qUiPWnz5gSozJ3isezWs=",
+ "lastModified": 1699550761,
+ "narHash": "sha256-BNjPd2DuxNCZBeRwcIJH3SZ9/q7+Ny3j8gZDmOvuENs=",
"owner": "hacl-star",
"repo": "hacl-star",
- "rev": "d2f087304c0b59c0486e25ff2f1daec78d92f69b",
+ "rev": "e1a785f7e88bb6668c9beabd4dc292a03c68bb2e",
"type": "github"
},
"original": {
@@ -216,11 +194,11 @@
]
},
"locked": {
- "lastModified": 1690853873,
- "narHash": "sha256-RWmZC/Qp8+l/HsbYk982Jqp+zxqYzzsbP60NEhZktwY=",
+ "lastModified": 1699578804,
+ "narHash": "sha256-ss+mguIO6C1DBiKkw/5C5M2N3TiNirBagQ0CUZxlt1I=",
"owner": "hacl-star",
"repo": "hacl-nix",
- "rev": "11df45d92e34f23a86bde4134114b023ce0cd6a9",
+ "rev": "19d0224fffa227ca6374d173f5dfeb7c2b61cf4a",
"type": "github"
},
"original": {
@@ -245,11 +223,11 @@
]
},
"locked": {
- "lastModified": 1690242065,
- "narHash": "sha256-YCHBlXiQqO5A27f+2p/NdtKKP0GNqNEUTH2tMwtFDkQ=",
+ "lastModified": 1698968585,
+ "narHash": "sha256-x3ZaGrmuKF5+7xaWHu0yDikl4mrawkY5tQnfovgyPh8=",
"owner": "fstarlang",
"repo": "karamel",
- "rev": "ed0c7e432715f95c6b9f4268eb1082eb636356a1",
+ "rev": "a7be2a7c43eca637ceb57fe8f3ffd16fc6627ebd",
"type": "github"
},
"original": {
@@ -287,11 +265,11 @@
"nixpkgs": "nixpkgs_4"
},
"locked": {
- "lastModified": 1691545327,
- "narHash": "sha256-9oAUBNRvZxK8dBuxzH5GGhET5lyolecOHmbwywgyk4s=",
+ "lastModified": 1699614992,
+ "narHash": "sha256-eSxx1UA47oBzpZGc4tIp6YP2qti1Hrc36Yo77XFnXH0=",
"owner": "leanprover",
"repo": "lean4",
- "rev": "e7a1512da8d6f9339766f3a269de56e546757fde",
+ "rev": "5189578a488572b39d102b2e8825bf2a1d2c2b76",
"type": "github"
},
"original": {
@@ -340,11 +318,11 @@
"nixpkgs": "nixpkgs_7"
},
"locked": {
- "lastModified": 1691545327,
- "narHash": "sha256-9oAUBNRvZxK8dBuxzH5GGhET5lyolecOHmbwywgyk4s=",
+ "lastModified": 1699614992,
+ "narHash": "sha256-eSxx1UA47oBzpZGc4tIp6YP2qti1Hrc36Yo77XFnXH0=",
"owner": "leanprover",
"repo": "lean4",
- "rev": "e7a1512da8d6f9339766f3a269de56e546757fde",
+ "rev": "5189578a488572b39d102b2e8825bf2a1d2c2b76",
"type": "github"
},
"original": {
@@ -427,11 +405,11 @@
},
"nixpkgs": {
"locked": {
- "lastModified": 1691472822,
- "narHash": "sha256-XVfYZ2oB3lNPVq6sHCY9WkdQ8lHoIDzzbpg8bB6oBxA=",
+ "lastModified": 1699099776,
+ "narHash": "sha256-X09iKJ27mGsGambGfkKzqvw5esP1L/Rf8H3u3fCqIiU=",
"owner": "NixOS",
"repo": "nixpkgs",
- "rev": "41c7605718399dcfa53dd7083793b6ae3bc969ff",
+ "rev": "85f1ba3e51676fa8cc604a3d863d729026a6b8eb",
"type": "github"
},
"original": {
@@ -474,11 +452,11 @@
},
"nixpkgs_2": {
"locked": {
- "lastModified": 1684385584,
- "narHash": "sha256-O7y0gK8OLIDqz+LaHJJyeu09IGiXlZIS3+JgEzGmmJA=",
+ "lastModified": 1693158576,
+ "narHash": "sha256-aRTTXkYvhXosGx535iAFUaoFboUrZSYb1Ooih/auGp0=",
"owner": "NixOS",
"repo": "nixpkgs",
- "rev": "48a0fb7aab511df92a17cf239c37f2bd2ec9ae3a",
+ "rev": "a999c1cc0c9eb2095729d5aa03e0d8f7ed256780",
"type": "github"
},
"original": {
@@ -587,33 +565,6 @@
"inputs": {
"flake-utils": [
"charon",
- "crane",
- "flake-utils"
- ],
- "nixpkgs": [
- "charon",
- "crane",
- "nixpkgs"
- ]
- },
- "locked": {
- "lastModified": 1691029059,
- "narHash": "sha256-QwVeE9YTgH3LmL7yw2V/hgswL6yorIvYSp4YGI8lZYM=",
- "owner": "oxalica",
- "repo": "rust-overlay",
- "rev": "99df4908445be37ddb2d332580365fce512a7dcf",
- "type": "github"
- },
- "original": {
- "owner": "oxalica",
- "repo": "rust-overlay",
- "type": "github"
- }
- },
- "rust-overlay_2": {
- "inputs": {
- "flake-utils": [
- "charon",
"flake-utils"
],
"nixpkgs": [
@@ -622,11 +573,11 @@
]
},
"locked": {
- "lastModified": 1691547503,
- "narHash": "sha256-l0AIKJucygbDFc2vuAkxmFMjNNJImDd7jYahA88/E+o=",
+ "lastModified": 1699582387,
+ "narHash": "sha256-sPmUXPDl+cEi+zFtM5lnAs7dWOdRn0ptZ4a/qHwvNDk=",
"owner": "oxalica",
"repo": "rust-overlay",
- "rev": "3380f16b39457b49c8186d5e20e7a68ccf4fc96e",
+ "rev": "41f7b0618052430d3a050e8f937030d00a2fcced",
"type": "github"
},
"original": {
diff --git a/flake.nix b/flake.nix
index ebe1e90d..e2b7a796 100644
--- a/flake.nix
+++ b/flake.nix
@@ -92,11 +92,28 @@
cp ${aeneas}/bin/aeneas_driver aeneas.exe
export AENEAS_EXE=./aeneas.exe
- # Run the tests
+ # Copy the tests
+ mkdir tests-copy
+ cp -r tests tests-copy
+
+ # TODO: remove the test files to make sure we regenerate exactly
+ # the files which are checked out (we have to be careful about
+ # files like lakefile.lean, and the user hand-written files)
+
+ # Run the tests - remark: we could remove the file
make tests -j $NIX_BUILD_CORES
+
+ # Check that there are no differences between the generated tests
+ # and the original tests
+ if [[ $(diff -rq tests tests-copy) ]]; then
+ echo "Ok: the regenerated test files are the same as the checked out files"
+ else
+ echo "Error: the regenerated test files differ from the checked out files"
+ exit 1
+ fi
'';
# Tests don't generate anything new as the generated files are
- # versionned, but the installation phase still needs to prodocue
+ # versionned, but the installation phase still needs to produce
# something, otherwise Nix will consider the build has failed.
installPhase = "touch $out";
};
diff --git a/tests/coq/array/Array.v b/tests/coq/array/Array.v
new file mode 100644
index 00000000..825f73e0
--- /dev/null
+++ b/tests/coq/array/Array.v
@@ -0,0 +1,470 @@
+(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *)
+(** [array] *)
+Require Import Primitives.
+Import Primitives.
+Require Import Coq.ZArith.ZArith.
+Require Import List.
+Import ListNotations.
+Local Open Scope Primitives_scope.
+Module Array.
+
+(** [array::AB] *)
+Inductive AB_t := | AB_A : AB_t | AB_B : AB_t.
+
+(** [array::incr]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) *)
+Definition incr (x : u32) : result u32 :=
+ u32_add x 1%u32.
+
+(** [array::array_to_shared_slice_]: forward function *)
+Definition array_to_shared_slice_
+ (T : Type) (s : array T 32%usize) : result (slice T) :=
+ array_to_slice T 32%usize s
+.
+
+(** [array::array_to_mut_slice_]: forward function *)
+Definition array_to_mut_slice_
+ (T : Type) (s : array T 32%usize) : result (slice T) :=
+ array_to_slice T 32%usize s
+.
+
+(** [array::array_to_mut_slice_]: backward function 0 *)
+Definition array_to_mut_slice__back
+ (T : Type) (s : array T 32%usize) (ret : slice T) :
+ result (array T 32%usize)
+ :=
+ array_from_slice T 32%usize s ret
+.
+
+(** [array::array_len]: forward function *)
+Definition array_len (T : Type) (s : array T 32%usize) : result usize :=
+ s0 <- array_to_slice T 32%usize s; let i := slice_len T s0 in Return i
+.
+
+(** [array::shared_array_len]: forward function *)
+Definition shared_array_len (T : Type) (s : array T 32%usize) : result usize :=
+ s0 <- array_to_slice T 32%usize s; let i := slice_len T s0 in Return i
+.
+
+(** [array::shared_slice_len]: forward function *)
+Definition shared_slice_len (T : Type) (s : slice T) : result usize :=
+ let i := slice_len T s in Return i
+.
+
+(** [array::index_array_shared]: forward function *)
+Definition index_array_shared
+ (T : Type) (s : array T 32%usize) (i : usize) : result T :=
+ array_index_usize T 32%usize s i
+.
+
+(** [array::index_array_u32]: forward function *)
+Definition index_array_u32 (s : array u32 32%usize) (i : usize) : result u32 :=
+ array_index_usize u32 32%usize s i
+.
+
+(** [array::index_array_copy]: forward function *)
+Definition index_array_copy (x : array u32 32%usize) : result u32 :=
+ array_index_usize u32 32%usize x 0%usize
+.
+
+(** [array::index_mut_array]: forward function *)
+Definition index_mut_array
+ (T : Type) (s : array T 32%usize) (i : usize) : result T :=
+ array_index_usize T 32%usize s i
+.
+
+(** [array::index_mut_array]: backward function 0 *)
+Definition index_mut_array_back
+ (T : Type) (s : array T 32%usize) (i : usize) (ret : T) :
+ result (array T 32%usize)
+ :=
+ array_update_usize T 32%usize s i ret
+.
+
+(** [array::index_slice]: forward function *)
+Definition index_slice (T : Type) (s : slice T) (i : usize) : result T :=
+ slice_index_usize T s i
+.
+
+(** [array::index_mut_slice]: forward function *)
+Definition index_mut_slice (T : Type) (s : slice T) (i : usize) : result T :=
+ slice_index_usize T s i
+.
+
+(** [array::index_mut_slice]: backward function 0 *)
+Definition index_mut_slice_back
+ (T : Type) (s : slice T) (i : usize) (ret : T) : result (slice T) :=
+ slice_update_usize T s i ret
+.
+
+(** [array::slice_subslice_shared_]: forward function *)
+Definition slice_subslice_shared_
+ (x : slice u32) (y : usize) (z : usize) : result (slice u32) :=
+ core_slice_index_Slice_index u32 (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32) x
+ {| core_ops_range_Range_start := y; core_ops_range_Range_end_ := z |}
+.
+
+(** [array::slice_subslice_mut_]: forward function *)
+Definition slice_subslice_mut_
+ (x : slice u32) (y : usize) (z : usize) : result (slice u32) :=
+ core_slice_index_Slice_index_mut u32 (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32) x
+ {| core_ops_range_Range_start := y; core_ops_range_Range_end_ := z |}
+.
+
+(** [array::slice_subslice_mut_]: backward function 0 *)
+Definition slice_subslice_mut__back
+ (x : slice u32) (y : usize) (z : usize) (ret : slice u32) :
+ result (slice u32)
+ :=
+ core_slice_index_Slice_index_mut_back u32 (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32) x
+ {| core_ops_range_Range_start := y; core_ops_range_Range_end_ := z |} ret
+.
+
+(** [array::array_to_slice_shared_]: forward function *)
+Definition array_to_slice_shared_
+ (x : array u32 32%usize) : result (slice u32) :=
+ array_to_slice u32 32%usize x
+.
+
+(** [array::array_to_slice_mut_]: forward function *)
+Definition array_to_slice_mut_ (x : array u32 32%usize) : result (slice u32) :=
+ array_to_slice u32 32%usize x
+.
+
+(** [array::array_to_slice_mut_]: backward function 0 *)
+Definition array_to_slice_mut__back
+ (x : array u32 32%usize) (ret : slice u32) : result (array u32 32%usize) :=
+ array_from_slice u32 32%usize x ret
+.
+
+(** [array::array_subslice_shared_]: forward function *)
+Definition array_subslice_shared_
+ (x : array u32 32%usize) (y : usize) (z : usize) : result (slice u32) :=
+ core_array_Array_index u32 (core_ops_range_Range usize) 32%usize
+ (core_slice_index_Slice_coreopsindexIndexInst u32 (core_ops_range_Range
+ usize) (core_slice_index_Range_coresliceindexSliceIndexInst u32)) x
+ {| core_ops_range_Range_start := y; core_ops_range_Range_end_ := z |}
+.
+
+(** [array::array_subslice_mut_]: forward function *)
+Definition array_subslice_mut_
+ (x : array u32 32%usize) (y : usize) (z : usize) : result (slice u32) :=
+ core_array_Array_index_mut u32 (core_ops_range_Range usize) 32%usize
+ (core_slice_index_Slice_coreopsindexIndexMutInst u32 (core_ops_range_Range
+ usize) (core_slice_index_Range_coresliceindexSliceIndexInst u32)) x
+ {| core_ops_range_Range_start := y; core_ops_range_Range_end_ := z |}
+.
+
+(** [array::array_subslice_mut_]: backward function 0 *)
+Definition array_subslice_mut__back
+ (x : array u32 32%usize) (y : usize) (z : usize) (ret : slice u32) :
+ result (array u32 32%usize)
+ :=
+ core_array_Array_index_mut_back u32 (core_ops_range_Range usize) 32%usize
+ (core_slice_index_Slice_coreopsindexIndexMutInst u32 (core_ops_range_Range
+ usize) (core_slice_index_Range_coresliceindexSliceIndexInst u32)) x
+ {| core_ops_range_Range_start := y; core_ops_range_Range_end_ := z |} ret
+.
+
+(** [array::index_slice_0]: forward function *)
+Definition index_slice_0 (T : Type) (s : slice T) : result T :=
+ slice_index_usize T s 0%usize
+.
+
+(** [array::index_array_0]: forward function *)
+Definition index_array_0 (T : Type) (s : array T 32%usize) : result T :=
+ array_index_usize T 32%usize s 0%usize
+.
+
+(** [array::index_index_array]: forward function *)
+Definition index_index_array
+ (s : array (array u32 32%usize) 32%usize) (i : usize) (j : usize) :
+ result u32
+ :=
+ a <- array_index_usize (array u32 32%usize) 32%usize s i;
+ array_index_usize u32 32%usize a j
+.
+
+(** [array::update_update_array]: forward function *)
+Definition update_update_array
+ (s : array (array u32 32%usize) 32%usize) (i : usize) (j : usize) :
+ result unit
+ :=
+ a <- array_index_usize (array u32 32%usize) 32%usize s i;
+ a0 <- array_update_usize u32 32%usize a j 0%u32;
+ _ <- array_update_usize (array u32 32%usize) 32%usize s i a0;
+ Return tt
+.
+
+(** [array::array_local_deep_copy]: forward function *)
+Definition array_local_deep_copy (x : array u32 32%usize) : result unit :=
+ Return tt
+.
+
+(** [array::take_array]: forward function *)
+Definition take_array (a : array u32 2%usize) : result unit :=
+ Return tt.
+
+(** [array::take_array_borrow]: forward function *)
+Definition take_array_borrow (a : array u32 2%usize) : result unit :=
+ Return tt
+.
+
+(** [array::take_slice]: forward function *)
+Definition take_slice (s : slice u32) : result unit :=
+ Return tt.
+
+(** [array::take_mut_slice]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) *)
+Definition take_mut_slice (s : slice u32) : result (slice u32) :=
+ Return s.
+
+(** [array::take_all]: forward function *)
+Definition take_all : result unit :=
+ _ <- take_array (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ _ <- take_array_borrow (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ s <- array_to_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ _ <- take_slice s;
+ s0 <- array_to_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ s1 <- take_mut_slice s0;
+ _ <- array_from_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]) s1;
+ Return tt
+.
+
+(** [array::index_array]: forward function *)
+Definition index_array (x : array u32 2%usize) : result u32 :=
+ array_index_usize u32 2%usize x 0%usize
+.
+
+(** [array::index_array_borrow]: forward function *)
+Definition index_array_borrow (x : array u32 2%usize) : result u32 :=
+ array_index_usize u32 2%usize x 0%usize
+.
+
+(** [array::index_slice_u32_0]: forward function *)
+Definition index_slice_u32_0 (x : slice u32) : result u32 :=
+ slice_index_usize u32 x 0%usize
+.
+
+(** [array::index_mut_slice_u32_0]: forward function *)
+Definition index_mut_slice_u32_0 (x : slice u32) : result u32 :=
+ slice_index_usize u32 x 0%usize
+.
+
+(** [array::index_mut_slice_u32_0]: backward function 0 *)
+Definition index_mut_slice_u32_0_back (x : slice u32) : result (slice u32) :=
+ _ <- slice_index_usize u32 x 0%usize; Return x
+.
+
+(** [array::index_all]: forward function *)
+Definition index_all : result u32 :=
+ i <- index_array (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ i0 <- index_array (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ i1 <- u32_add i i0;
+ i2 <- index_array_borrow (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ i3 <- u32_add i1 i2;
+ s <- array_to_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ i4 <- index_slice_u32_0 s;
+ i5 <- u32_add i3 i4;
+ s0 <- array_to_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ i6 <- index_mut_slice_u32_0 s0;
+ i7 <- u32_add i5 i6;
+ s1 <- index_mut_slice_u32_0_back s0;
+ _ <- array_from_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]) s1;
+ Return i7
+.
+
+(** [array::update_array]: forward function *)
+Definition update_array (x : array u32 2%usize) : result unit :=
+ _ <- array_update_usize u32 2%usize x 0%usize 1%u32; Return tt
+.
+
+(** [array::update_array_mut_borrow]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) *)
+Definition update_array_mut_borrow
+ (x : array u32 2%usize) : result (array u32 2%usize) :=
+ array_update_usize u32 2%usize x 0%usize 1%u32
+.
+
+(** [array::update_mut_slice]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) *)
+Definition update_mut_slice (x : slice u32) : result (slice u32) :=
+ slice_update_usize u32 x 0%usize 1%u32
+.
+
+(** [array::update_all]: forward function *)
+Definition update_all : result unit :=
+ _ <- update_array (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ x <- update_array_mut_borrow (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ s <- array_to_slice u32 2%usize x;
+ s0 <- update_mut_slice s;
+ _ <- array_from_slice u32 2%usize x s0;
+ Return tt
+.
+
+(** [array::range_all]: forward function *)
+Definition range_all : result unit :=
+ s <-
+ core_array_Array_index_mut u32 (core_ops_range_Range usize) 4%usize
+ (core_slice_index_Slice_coreopsindexIndexMutInst u32
+ (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32))
+ (mk_array u32 4%usize [ 0%u32; 0%u32; 0%u32; 0%u32 ])
+ {|
+ core_ops_range_Range_start := 1%usize;
+ core_ops_range_Range_end_ := 3%usize
+ |};
+ s0 <- update_mut_slice s;
+ _ <-
+ core_array_Array_index_mut_back u32 (core_ops_range_Range usize) 4%usize
+ (core_slice_index_Slice_coreopsindexIndexMutInst u32
+ (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32))
+ (mk_array u32 4%usize [ 0%u32; 0%u32; 0%u32; 0%u32 ])
+ {|
+ core_ops_range_Range_start := 1%usize;
+ core_ops_range_Range_end_ := 3%usize
+ |} s0;
+ Return tt
+.
+
+(** [array::deref_array_borrow]: forward function *)
+Definition deref_array_borrow (x : array u32 2%usize) : result u32 :=
+ array_index_usize u32 2%usize x 0%usize
+.
+
+(** [array::deref_array_mut_borrow]: forward function *)
+Definition deref_array_mut_borrow (x : array u32 2%usize) : result u32 :=
+ array_index_usize u32 2%usize x 0%usize
+.
+
+(** [array::deref_array_mut_borrow]: backward function 0 *)
+Definition deref_array_mut_borrow_back
+ (x : array u32 2%usize) : result (array u32 2%usize) :=
+ _ <- array_index_usize u32 2%usize x 0%usize; Return x
+.
+
+(** [array::take_array_t]: forward function *)
+Definition take_array_t (a : array AB_t 2%usize) : result unit :=
+ Return tt.
+
+(** [array::non_copyable_array]: forward function *)
+Definition non_copyable_array : result unit :=
+ _ <- take_array_t (mk_array AB_t 2%usize [ AB_A; AB_B ]); Return tt
+.
+
+(** [array::sum]: loop 0: forward function *)
+Fixpoint sum_loop
+ (n : nat) (s : slice u32) (sum0 : u32) (i : usize) : result u32 :=
+ match n with
+ | O => Fail_ OutOfFuel
+ | S n0 =>
+ let i0 := slice_len u32 s in
+ if i s< i0
+ then (
+ i1 <- slice_index_usize u32 s i;
+ sum1 <- u32_add sum0 i1;
+ i2 <- usize_add i 1%usize;
+ sum_loop n0 s sum1 i2)
+ else Return sum0
+ end
+.
+
+(** [array::sum]: forward function *)
+Definition sum (n : nat) (s : slice u32) : result u32 :=
+ sum_loop n s 0%u32 0%usize
+.
+
+(** [array::sum2]: loop 0: forward function *)
+Fixpoint sum2_loop
+ (n : nat) (s : slice u32) (s2 : slice u32) (sum0 : u32) (i : usize) :
+ result u32
+ :=
+ match n with
+ | O => Fail_ OutOfFuel
+ | S n0 =>
+ let i0 := slice_len u32 s in
+ if i s< i0
+ then (
+ i1 <- slice_index_usize u32 s i;
+ i2 <- slice_index_usize u32 s2 i;
+ i3 <- u32_add i1 i2;
+ sum1 <- u32_add sum0 i3;
+ i4 <- usize_add i 1%usize;
+ sum2_loop n0 s s2 sum1 i4)
+ else Return sum0
+ end
+.
+
+(** [array::sum2]: forward function *)
+Definition sum2 (n : nat) (s : slice u32) (s2 : slice u32) : result u32 :=
+ let i := slice_len u32 s in
+ let i0 := slice_len u32 s2 in
+ if negb (i s= i0) then Fail_ Failure else sum2_loop n s s2 0%u32 0%usize
+.
+
+(** [array::f0]: forward function *)
+Definition f0 : result unit :=
+ s <- array_to_slice u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ]);
+ s0 <- slice_update_usize u32 s 0%usize 1%u32;
+ _ <- array_from_slice u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ]) s0;
+ Return tt
+.
+
+(** [array::f1]: forward function *)
+Definition f1 : result unit :=
+ _ <-
+ array_update_usize u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ])
+ 0%usize 1%u32;
+ Return tt
+.
+
+(** [array::f2]: forward function *)
+Definition f2 (i : u32) : result unit :=
+ Return tt.
+
+(** [array::f4]: forward function *)
+Definition f4
+ (x : array u32 32%usize) (y : usize) (z : usize) : result (slice u32) :=
+ core_array_Array_index u32 (core_ops_range_Range usize) 32%usize
+ (core_slice_index_Slice_coreopsindexIndexInst u32 (core_ops_range_Range
+ usize) (core_slice_index_Range_coresliceindexSliceIndexInst u32)) x
+ {| core_ops_range_Range_start := y; core_ops_range_Range_end_ := z |}
+.
+
+(** [array::f3]: forward function *)
+Definition f3 (n : nat) : result u32 :=
+ i <-
+ array_index_usize u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ])
+ 0%usize;
+ _ <- f2 i;
+ let b := array_repeat u32 32%usize 0%u32 in
+ s <- array_to_slice u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ]);
+ s0 <- f4 b 16%usize 18%usize;
+ sum2 n s s0
+.
+
+(** [array::SZ] *)
+Definition sz_body : result usize := Return 32%usize.
+Definition sz_c : usize := sz_body%global.
+
+(** [array::f5]: forward function *)
+Definition f5 (x : array u32 32%usize) : result u32 :=
+ array_index_usize u32 32%usize x 0%usize
+.
+
+(** [array::ite]: forward function *)
+Definition ite : result unit :=
+ s <- array_to_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ s0 <- array_to_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
+ s1 <- index_mut_slice_u32_0_back s0;
+ _ <- array_from_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]) s1;
+ s2 <- index_mut_slice_u32_0_back s;
+ _ <- array_from_slice u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]) s2;
+ Return tt
+.
+
+End Array .
diff --git a/tests/coq/array/Array_Funs.v b/tests/coq/array/Array_Funs.v
deleted file mode 100644
index 6d791873..00000000
--- a/tests/coq/array/Array_Funs.v
+++ /dev/null
@@ -1,467 +0,0 @@
-(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *)
-(** [array]: function definitions *)
-Require Import Primitives.
-Import Primitives.
-Require Import Coq.ZArith.ZArith.
-Require Import List.
-Import ListNotations.
-Local Open Scope Primitives_scope.
-Require Export Array_Types.
-Import Array_Types.
-Module Array_Funs.
-
-(** [array::array_to_shared_slice_]: forward function *)
-Definition array_to_shared_slice__fwd
- (T : Type) (s : array T 32%usize) : result (slice T) :=
- array_to_slice_shared T 32%usize s
-.
-
-(** [array::array_to_mut_slice_]: forward function *)
-Definition array_to_mut_slice__fwd
- (T : Type) (s : array T 32%usize) : result (slice T) :=
- array_to_slice_mut_fwd T 32%usize s
-.
-
-(** [array::array_to_mut_slice_]: backward function 0 *)
-Definition array_to_mut_slice__back
- (T : Type) (s : array T 32%usize) (ret : slice T) :
- result (array T 32%usize)
- :=
- array_to_slice_mut_back T 32%usize s ret
-.
-
-(** [array::array_len]: forward function *)
-Definition array_len_fwd (T : Type) (s : array T 32%usize) : result usize :=
- s0 <- array_to_slice_shared T 32%usize s; let i := slice_len T s0 in Return i
-.
-
-(** [array::shared_array_len]: forward function *)
-Definition shared_array_len_fwd
- (T : Type) (s : array T 32%usize) : result usize :=
- s0 <- array_to_slice_shared T 32%usize s; let i := slice_len T s0 in Return i
-.
-
-(** [array::shared_slice_len]: forward function *)
-Definition shared_slice_len_fwd (T : Type) (s : slice T) : result usize :=
- let i := slice_len T s in Return i
-.
-
-(** [array::index_array_shared]: forward function *)
-Definition index_array_shared_fwd
- (T : Type) (s : array T 32%usize) (i : usize) : result T :=
- array_index_shared T 32%usize s i
-.
-
-(** [array::index_array_u32]: forward function *)
-Definition index_array_u32_fwd
- (s : array u32 32%usize) (i : usize) : result u32 :=
- array_index_shared u32 32%usize s i
-.
-
-(** [array::index_array_generic]: forward function *)
-Definition index_array_generic_fwd
- (N : usize) (s : array u32 N) (i : usize) : result u32 :=
- array_index_shared u32 N s i
-.
-
-(** [array::index_array_generic_call]: forward function *)
-Definition index_array_generic_call_fwd
- (N : usize) (s : array u32 N) (i : usize) : result u32 :=
- index_array_generic_fwd N s i
-.
-
-(** [array::index_array_copy]: forward function *)
-Definition index_array_copy_fwd (x : array u32 32%usize) : result u32 :=
- array_index_shared u32 32%usize x 0%usize
-.
-
-(** [array::index_mut_array]: forward function *)
-Definition index_mut_array_fwd
- (T : Type) (s : array T 32%usize) (i : usize) : result T :=
- array_index_mut_fwd T 32%usize s i
-.
-
-(** [array::index_mut_array]: backward function 0 *)
-Definition index_mut_array_back
- (T : Type) (s : array T 32%usize) (i : usize) (ret : T) :
- result (array T 32%usize)
- :=
- array_index_mut_back T 32%usize s i ret
-.
-
-(** [array::index_slice]: forward function *)
-Definition index_slice_fwd (T : Type) (s : slice T) (i : usize) : result T :=
- slice_index_shared T s i
-.
-
-(** [array::index_mut_slice]: forward function *)
-Definition index_mut_slice_fwd
- (T : Type) (s : slice T) (i : usize) : result T :=
- slice_index_mut_fwd T s i
-.
-
-(** [array::index_mut_slice]: backward function 0 *)
-Definition index_mut_slice_back
- (T : Type) (s : slice T) (i : usize) (ret : T) : result (slice T) :=
- slice_index_mut_back T s i ret
-.
-
-(** [array::slice_subslice_shared_]: forward function *)
-Definition slice_subslice_shared__fwd
- (x : slice u32) (y : usize) (z : usize) : result (slice u32) :=
- slice_subslice_shared u32 x (mk_range y z)
-.
-
-(** [array::slice_subslice_mut_]: forward function *)
-Definition slice_subslice_mut__fwd
- (x : slice u32) (y : usize) (z : usize) : result (slice u32) :=
- slice_subslice_mut_fwd u32 x (mk_range y z)
-.
-
-(** [array::slice_subslice_mut_]: backward function 0 *)
-Definition slice_subslice_mut__back
- (x : slice u32) (y : usize) (z : usize) (ret : slice u32) :
- result (slice u32)
- :=
- slice_subslice_mut_back u32 x (mk_range y z) ret
-.
-
-(** [array::array_to_slice_shared_]: forward function *)
-Definition array_to_slice_shared__fwd
- (x : array u32 32%usize) : result (slice u32) :=
- array_to_slice_shared u32 32%usize x
-.
-
-(** [array::array_to_slice_mut_]: forward function *)
-Definition array_to_slice_mut__fwd
- (x : array u32 32%usize) : result (slice u32) :=
- array_to_slice_mut_fwd u32 32%usize x
-.
-
-(** [array::array_to_slice_mut_]: backward function 0 *)
-Definition array_to_slice_mut__back
- (x : array u32 32%usize) (ret : slice u32) : result (array u32 32%usize) :=
- array_to_slice_mut_back u32 32%usize x ret
-.
-
-(** [array::array_subslice_shared_]: forward function *)
-Definition array_subslice_shared__fwd
- (x : array u32 32%usize) (y : usize) (z : usize) : result (slice u32) :=
- array_subslice_shared u32 32%usize x (mk_range y z)
-.
-
-(** [array::array_subslice_mut_]: forward function *)
-Definition array_subslice_mut__fwd
- (x : array u32 32%usize) (y : usize) (z : usize) : result (slice u32) :=
- array_subslice_mut_fwd u32 32%usize x (mk_range y z)
-.
-
-(** [array::array_subslice_mut_]: backward function 0 *)
-Definition array_subslice_mut__back
- (x : array u32 32%usize) (y : usize) (z : usize) (ret : slice u32) :
- result (array u32 32%usize)
- :=
- array_subslice_mut_back u32 32%usize x (mk_range y z) ret
-.
-
-(** [array::index_slice_0]: forward function *)
-Definition index_slice_0_fwd (T : Type) (s : slice T) : result T :=
- slice_index_shared T s 0%usize
-.
-
-(** [array::index_array_0]: forward function *)
-Definition index_array_0_fwd (T : Type) (s : array T 32%usize) : result T :=
- array_index_shared T 32%usize s 0%usize
-.
-
-(** [array::index_index_array]: forward function *)
-Definition index_index_array_fwd
- (s : array (array u32 32%usize) 32%usize) (i : usize) (j : usize) :
- result u32
- :=
- a <- array_index_shared (array u32 32%usize) 32%usize s i;
- array_index_shared u32 32%usize a j
-.
-
-(** [array::update_update_array]: forward function *)
-Definition update_update_array_fwd
- (s : array (array u32 32%usize) 32%usize) (i : usize) (j : usize) :
- result unit
- :=
- a <- array_index_mut_fwd (array u32 32%usize) 32%usize s i;
- a0 <- array_index_mut_back u32 32%usize a j 0%u32;
- _ <- array_index_mut_back (array u32 32%usize) 32%usize s i a0;
- Return tt
-.
-
-(** [array::array_local_deep_copy]: forward function *)
-Definition array_local_deep_copy_fwd (x : array u32 32%usize) : result unit :=
- Return tt
-.
-
-(** [array::take_array]: forward function *)
-Definition take_array_fwd (a : array u32 2%usize) : result unit :=
- Return tt.
-
-(** [array::take_array_borrow]: forward function *)
-Definition take_array_borrow_fwd (a : array u32 2%usize) : result unit :=
- Return tt
-.
-
-(** [array::take_slice]: forward function *)
-Definition take_slice_fwd (s : slice u32) : result unit :=
- Return tt.
-
-(** [array::take_mut_slice]: merged forward/backward function
- (there is a single backward function, and the forward function returns ()) *)
-Definition take_mut_slice_fwd_back (s : slice u32) : result (slice u32) :=
- Return s
-.
-
-(** [array::take_all]: forward function *)
-Definition take_all_fwd : result unit :=
- _ <- take_array_fwd (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- _ <- take_array_borrow_fwd (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- s <-
- array_to_slice_shared u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- _ <- take_slice_fwd s;
- s0 <-
- array_to_slice_mut_fwd u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- s1 <- take_mut_slice_fwd_back s0;
- _ <-
- array_to_slice_mut_back u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ])
- s1;
- Return tt
-.
-
-(** [array::index_array]: forward function *)
-Definition index_array_fwd (x : array u32 2%usize) : result u32 :=
- array_index_shared u32 2%usize x 0%usize
-.
-
-(** [array::index_array_borrow]: forward function *)
-Definition index_array_borrow_fwd (x : array u32 2%usize) : result u32 :=
- array_index_shared u32 2%usize x 0%usize
-.
-
-(** [array::index_slice_u32_0]: forward function *)
-Definition index_slice_u32_0_fwd (x : slice u32) : result u32 :=
- slice_index_shared u32 x 0%usize
-.
-
-(** [array::index_mut_slice_u32_0]: forward function *)
-Definition index_mut_slice_u32_0_fwd (x : slice u32) : result u32 :=
- slice_index_shared u32 x 0%usize
-.
-
-(** [array::index_mut_slice_u32_0]: backward function 0 *)
-Definition index_mut_slice_u32_0_back (x : slice u32) : result (slice u32) :=
- _ <- slice_index_shared u32 x 0%usize; Return x
-.
-
-(** [array::index_all]: forward function *)
-Definition index_all_fwd : result u32 :=
- i <- index_array_fwd (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- i0 <- index_array_fwd (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- i1 <- u32_add i i0;
- i2 <- index_array_borrow_fwd (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- i3 <- u32_add i1 i2;
- s <-
- array_to_slice_shared u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- i4 <- index_slice_u32_0_fwd s;
- i5 <- u32_add i3 i4;
- s0 <-
- array_to_slice_mut_fwd u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- i6 <- index_mut_slice_u32_0_fwd s0;
- i7 <- u32_add i5 i6;
- s1 <- index_mut_slice_u32_0_back s0;
- _ <-
- array_to_slice_mut_back u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ])
- s1;
- Return i7
-.
-
-(** [array::update_array]: forward function *)
-Definition update_array_fwd (x : array u32 2%usize) : result unit :=
- _ <- array_index_mut_back u32 2%usize x 0%usize 1%u32; Return tt
-.
-
-(** [array::update_array_mut_borrow]: merged forward/backward function
- (there is a single backward function, and the forward function returns ()) *)
-Definition update_array_mut_borrow_fwd_back
- (x : array u32 2%usize) : result (array u32 2%usize) :=
- array_index_mut_back u32 2%usize x 0%usize 1%u32
-.
-
-(** [array::update_mut_slice]: merged forward/backward function
- (there is a single backward function, and the forward function returns ()) *)
-Definition update_mut_slice_fwd_back (x : slice u32) : result (slice u32) :=
- slice_index_mut_back u32 x 0%usize 1%u32
-.
-
-(** [array::update_all]: forward function *)
-Definition update_all_fwd : result unit :=
- _ <- update_array_fwd (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- x <-
- update_array_mut_borrow_fwd_back (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- s <- array_to_slice_mut_fwd u32 2%usize x;
- s0 <- update_mut_slice_fwd_back s;
- _ <- array_to_slice_mut_back u32 2%usize x s0;
- Return tt
-.
-
-(** [array::range_all]: forward function *)
-Definition range_all_fwd : result unit :=
- s <-
- array_subslice_mut_fwd u32 4%usize
- (mk_array u32 4%usize [ 0%u32; 0%u32; 0%u32; 0%u32 ]) (mk_range 1%usize
- 3%usize);
- s0 <- update_mut_slice_fwd_back s;
- _ <-
- array_subslice_mut_back u32 4%usize
- (mk_array u32 4%usize [ 0%u32; 0%u32; 0%u32; 0%u32 ]) (mk_range 1%usize
- 3%usize) s0;
- Return tt
-.
-
-(** [array::deref_array_borrow]: forward function *)
-Definition deref_array_borrow_fwd (x : array u32 2%usize) : result u32 :=
- array_index_shared u32 2%usize x 0%usize
-.
-
-(** [array::deref_array_mut_borrow]: forward function *)
-Definition deref_array_mut_borrow_fwd (x : array u32 2%usize) : result u32 :=
- array_index_shared u32 2%usize x 0%usize
-.
-
-(** [array::deref_array_mut_borrow]: backward function 0 *)
-Definition deref_array_mut_borrow_back
- (x : array u32 2%usize) : result (array u32 2%usize) :=
- _ <- array_index_shared u32 2%usize x 0%usize; Return x
-.
-
-(** [array::take_array_t]: forward function *)
-Definition take_array_t_fwd (a : array T_t 2%usize) : result unit :=
- Return tt.
-
-(** [array::non_copyable_array]: forward function *)
-Definition non_copyable_array_fwd : result unit :=
- _ <- take_array_t_fwd (mk_array T_t 2%usize [ TA; TB ]); Return tt
-.
-
-(** [array::sum]: loop 0: forward function *)
-Fixpoint sum_loop_fwd
- (n : nat) (s : slice u32) (sum : u32) (i : usize) : result u32 :=
- match n with
- | O => Fail_ OutOfFuel
- | S n0 =>
- let i0 := slice_len u32 s in
- if i s< i0
- then (
- i1 <- slice_index_shared u32 s i;
- sum0 <- u32_add sum i1;
- i2 <- usize_add i 1%usize;
- sum_loop_fwd n0 s sum0 i2)
- else Return sum
- end
-.
-
-(** [array::sum]: forward function *)
-Definition sum_fwd (n : nat) (s : slice u32) : result u32 :=
- sum_loop_fwd n s 0%u32 0%usize
-.
-
-(** [array::sum2]: loop 0: forward function *)
-Fixpoint sum2_loop_fwd
- (n : nat) (s : slice u32) (s2 : slice u32) (sum : u32) (i : usize) :
- result u32
- :=
- match n with
- | O => Fail_ OutOfFuel
- | S n0 =>
- let i0 := slice_len u32 s in
- if i s< i0
- then (
- i1 <- slice_index_shared u32 s i;
- i2 <- slice_index_shared u32 s2 i;
- i3 <- u32_add i1 i2;
- sum0 <- u32_add sum i3;
- i4 <- usize_add i 1%usize;
- sum2_loop_fwd n0 s s2 sum0 i4)
- else Return sum
- end
-.
-
-(** [array::sum2]: forward function *)
-Definition sum2_fwd (n : nat) (s : slice u32) (s2 : slice u32) : result u32 :=
- let i := slice_len u32 s in
- let i0 := slice_len u32 s2 in
- if negb (i s= i0) then Fail_ Failure else sum2_loop_fwd n s s2 0%u32 0%usize
-.
-
-(** [array::f0]: forward function *)
-Definition f0_fwd : result unit :=
- s <-
- array_to_slice_mut_fwd u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ]);
- s0 <- slice_index_mut_back u32 s 0%usize 1%u32;
- _ <-
- array_to_slice_mut_back u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ])
- s0;
- Return tt
-.
-
-(** [array::f1]: forward function *)
-Definition f1_fwd : result unit :=
- _ <-
- array_index_mut_back u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ])
- 0%usize 1%u32;
- Return tt
-.
-
-(** [array::f2]: forward function *)
-Definition f2_fwd (i : u32) : result unit :=
- Return tt.
-
-(** [array::f4]: forward function *)
-Definition f4_fwd
- (x : array u32 32%usize) (y : usize) (z : usize) : result (slice u32) :=
- array_subslice_shared u32 32%usize x (mk_range y z)
-.
-
-(** [array::f3]: forward function *)
-Definition f3_fwd (n : nat) : result u32 :=
- i <-
- array_index_shared u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ])
- 0%usize;
- _ <- f2_fwd i;
- s <-
- array_to_slice_shared u32 2%usize (mk_array u32 2%usize [ 1%u32; 2%u32 ]);
- s0 <-
- f4_fwd
- (mk_array u32 32%usize [
- 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32;
- 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32;
- 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32; 0%u32;
- 0%u32; 0%u32
- ]) 16%usize 18%usize;
- sum2_fwd n s s0
-.
-
-(** [array::ite]: forward function *)
-Definition ite_fwd : result unit :=
- s <-
- array_to_slice_mut_fwd u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- s0 <-
- array_to_slice_mut_fwd u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ]);
- s1 <- index_mut_slice_u32_0_back s0;
- _ <-
- array_to_slice_mut_back u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ])
- s1;
- s2 <- index_mut_slice_u32_0_back s;
- _ <-
- array_to_slice_mut_back u32 2%usize (mk_array u32 2%usize [ 0%u32; 0%u32 ])
- s2;
- Return tt
-.
-
-End Array_Funs .
diff --git a/tests/coq/array/Array_Types.v b/tests/coq/array/Array_Types.v
deleted file mode 100644
index 7be6dc9b..00000000
--- a/tests/coq/array/Array_Types.v
+++ /dev/null
@@ -1,14 +0,0 @@
-(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *)
-(** [array]: type definitions *)
-Require Import Primitives.
-Import Primitives.
-Require Import Coq.ZArith.ZArith.
-Require Import List.
-Import ListNotations.
-Local Open Scope Primitives_scope.
-Module Array_Types.
-
-(** [array::T] *)
-Inductive T_t := | TA : T_t | TB : T_t.
-
-End Array_Types .
diff --git a/tests/coq/array/Primitives.v b/tests/coq/array/Primitives.v
index 71a2d9c3..85e38f01 100644
--- a/tests/coq/array/Primitives.v
+++ b/tests/coq/array/Primitives.v
@@ -63,13 +63,15 @@ Check (if true then Return (1 + 2) else Fail_ Failure)%global = 3.
(*** Misc *)
-
Definition string := Coq.Strings.String.string.
Definition char := Coq.Strings.Ascii.ascii.
Definition char_of_byte := Coq.Strings.Ascii.ascii_of_byte.
-Definition mem_replace_fwd (a : Type) (x : a) (y : a) : a := x .
-Definition mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+Definition core_mem_replace (a : Type) (x : a) (y : a) : a := x .
+Definition core_mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+
+Record mut_raw_ptr (T : Type) := { mut_raw_ptr_v : T }.
+Record const_raw_ptr (T : Type) := { const_raw_ptr_v : T }.
(*** Scalars *)
@@ -394,12 +396,89 @@ Notation "x s< y" := (scalar_ltb x y) (at level 80) : Primitives_scope.
Notation "x s>= y" := (scalar_geb x y) (at level 80) : Primitives_scope.
Notation "x s> y" := (scalar_gtb x y) (at level 80) : Primitives_scope.
-(*** Range *)
-Record range (T : Type) := mk_range {
- start: T;
- end_: T;
+(** Constants *)
+Definition core_u8_max := u8_max %u32.
+Definition core_u16_max := u16_max %u32.
+Definition core_u32_max := u32_max %u32.
+Definition core_u64_max := u64_max %u64.
+Definition core_u128_max := u64_max %u128.
+Axiom core_usize_max : usize. (** TODO *)
+Definition core_i8_max := i8_max %i32.
+Definition core_i16_max := i16_max %i32.
+Definition core_i32_max := i32_max %i32.
+Definition core_i64_max := i64_max %i64.
+Definition core_i128_max := i64_max %i128.
+Axiom core_isize_max : isize. (** TODO *)
+
+(*** core::ops *)
+
+(* Trait declaration: [core::ops::index::Index] *)
+Record core_ops_index_Index (Self Idx : Type) := mk_core_ops_index_Index {
+ core_ops_index_Index_Output : Type;
+ core_ops_index_Index_index : Self -> Idx -> result core_ops_index_Index_Output;
+}.
+Arguments mk_core_ops_index_Index {_ _}.
+Arguments core_ops_index_Index_Output {_ _}.
+Arguments core_ops_index_Index_index {_ _}.
+
+(* Trait declaration: [core::ops::index::IndexMut] *)
+Record core_ops_index_IndexMut (Self Idx : Type) := mk_core_ops_index_IndexMut {
+ core_ops_index_IndexMut_indexInst : core_ops_index_Index Self Idx;
+ core_ops_index_IndexMut_index_mut : Self -> Idx -> result core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output);
+ core_ops_index_IndexMut_index_mut_back : Self -> Idx -> core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output) -> result Self;
+}.
+Arguments mk_core_ops_index_IndexMut {_ _}.
+Arguments core_ops_index_IndexMut_indexInst {_ _}.
+Arguments core_ops_index_IndexMut_index_mut {_ _}.
+Arguments core_ops_index_IndexMut_index_mut_back {_ _}.
+
+(* Trait declaration [core::ops::deref::Deref] *)
+Record core_ops_deref_Deref (Self : Type) := mk_core_ops_deref_Deref {
+ core_ops_deref_Deref_target : Type;
+ core_ops_deref_Deref_deref : Self -> result core_ops_deref_Deref_target;
+}.
+Arguments mk_core_ops_deref_Deref {_}.
+Arguments core_ops_deref_Deref_target {_}.
+Arguments core_ops_deref_Deref_deref {_}.
+
+(* Trait declaration [core::ops::deref::DerefMut] *)
+Record core_ops_deref_DerefMut (Self : Type) := mk_core_ops_deref_DerefMut {
+ core_ops_deref_DerefMut_derefInst : core_ops_deref_Deref Self;
+ core_ops_deref_DerefMut_deref_mut : Self -> result core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target);
+ core_ops_deref_DerefMut_deref_mut_back : Self -> core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target) -> result Self;
}.
-Arguments mk_range {_}.
+Arguments mk_core_ops_deref_DerefMut {_}.
+Arguments core_ops_deref_DerefMut_derefInst {_}.
+Arguments core_ops_deref_DerefMut_deref_mut {_}.
+Arguments core_ops_deref_DerefMut_deref_mut_back {_}.
+
+Record core_ops_range_Range (T : Type) := mk_core_ops_range_Range {
+ core_ops_range_Range_start : T;
+ core_ops_range_Range_end_ : T;
+}.
+Arguments mk_core_ops_range_Range {_}.
+Arguments core_ops_range_Range_start {_}.
+Arguments core_ops_range_Range_end_ {_}.
+
+(*** [alloc] *)
+
+Definition alloc_boxed_Box_deref (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut_back (T : Type) (_ : T) (x : T) : result T := Return x.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefInst (Self : Type) : core_ops_deref_Deref Self := {|
+ core_ops_deref_Deref_target := Self;
+ core_ops_deref_Deref_deref := alloc_boxed_Box_deref Self;
+|}.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefMutInst (Self : Type) : core_ops_deref_DerefMut Self := {|
+ core_ops_deref_DerefMut_derefInst := alloc_boxed_Box_coreOpsDerefInst Self;
+ core_ops_deref_DerefMut_deref_mut := alloc_boxed_Box_deref_mut Self;
+ core_ops_deref_DerefMut_deref_mut_back := alloc_boxed_Box_deref_mut_back Self;
+|}.
+
(*** Arrays *)
Definition array T (n : usize) := { l: list T | Z.of_nat (length l) = to_Z n}.
@@ -419,51 +498,50 @@ Qed.
(* TODO: finish the definitions *)
Axiom mk_array : forall (T : Type) (n : usize) (l : list T), array T n.
-Axiom array_index_shared : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_fwd : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_back : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
+(* For initialization *)
+Axiom array_repeat : forall (T : Type) (n : usize) (x : T), array T n.
+
+Axiom array_index_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
+Axiom array_update_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
(*** Slice *)
Definition slice T := { l: list T | Z.of_nat (length l) <= usize_max}.
Axiom slice_len : forall (T : Type) (s : slice T), usize.
-Axiom slice_index_shared : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_fwd : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_back : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
+Axiom slice_index_usize : forall (T : Type) (x : slice T) (i : usize), result T.
+Axiom slice_update_usize : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
(*** Subslices *)
-Axiom array_to_slice_shared : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_fwd : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_back : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+Axiom array_to_slice : forall (T : Type) (n : usize) (x : array T n), result (slice T).
+Axiom array_from_slice : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+
+Axiom array_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize), result (slice T).
+Axiom array_update_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize) (ns : slice T), result (array T n).
-Axiom array_subslice_shared: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_fwd: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_back: forall (T : Type) (n : usize) (x : array T n) (r : range usize) (ns : slice T), result (array T n).
-Axiom slice_subslice_shared: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_fwd: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_back: forall (T : Type) (x : slice T) (r : range usize) (ns : slice T), result (slice T).
+Axiom slice_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize), result (slice T).
+Axiom slice_update_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize) (ns : slice T), result (slice T).
(*** Vectors *)
-Definition vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
+Definition alloc_vec_Vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
-Definition vec_to_list {T: Type} (v: vec T) : list T := proj1_sig v.
+Definition alloc_vec_Vec_to_list {T: Type} (v: alloc_vec_Vec T) : list T := proj1_sig v.
-Definition vec_length {T: Type} (v: vec T) : Z := Z.of_nat (length (vec_to_list v)).
+Definition alloc_vec_Vec_length {T: Type} (v: alloc_vec_Vec T) : Z := Z.of_nat (length (alloc_vec_Vec_to_list v)).
-Definition vec_new (T: Type) : vec T := (exist _ [] le_0_usize_max).
+Definition alloc_vec_Vec_new (T: Type) : alloc_vec_Vec T := (exist _ [] le_0_usize_max).
-Lemma vec_len_in_usize {T} (v: vec T) : usize_min <= vec_length v <= usize_max.
+Lemma alloc_vec_Vec_len_in_usize {T} (v: alloc_vec_Vec T) : usize_min <= alloc_vec_Vec_length v <= usize_max.
Proof.
- unfold vec_length, usize_min.
+ unfold alloc_vec_Vec_length, usize_min.
split.
- lia.
- apply (proj2_sig v).
Qed.
-Definition vec_len (T: Type) (v: vec T) : usize :=
- exist _ (vec_length v) (vec_len_in_usize v).
+Definition alloc_vec_Vec_len (T: Type) (v: alloc_vec_Vec T) : usize :=
+ exist _ (alloc_vec_Vec_length v) (alloc_vec_Vec_len_in_usize v).
Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
: list A :=
@@ -474,50 +552,271 @@ Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
| S m => x :: (list_update t m a)
end end.
-Definition vec_bind {A B} (v: vec A) (f: list A -> result (list B)) : result (vec B) :=
- l <- f (vec_to_list v) ;
+Definition alloc_vec_Vec_bind {A B} (v: alloc_vec_Vec A) (f: list A -> result (list B)) : result (alloc_vec_Vec B) :=
+ l <- f (alloc_vec_Vec_to_list v) ;
match sumbool_of_bool (scalar_le_max Usize (Z.of_nat (length l))) with
| left H => Return (exist _ l (scalar_le_max_valid _ _ H))
| right _ => Fail_ Failure
end.
(* The **forward** function shouldn't be used *)
-Definition vec_push_fwd (T: Type) (v: vec T) (x: T) : unit := tt.
+Definition alloc_vec_Vec_push_fwd (T: Type) (v: alloc_vec_Vec T) (x: T) : unit := tt.
-Definition vec_push_back (T: Type) (v: vec T) (x: T) : result (vec T) :=
- vec_bind v (fun l => Return (l ++ [x])).
+Definition alloc_vec_Vec_push (T: Type) (v: alloc_vec_Vec T) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l => Return (l ++ [x])).
(* The **forward** function shouldn't be used *)
-Definition vec_insert_fwd (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
+Definition alloc_vec_Vec_insert_fwd (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result unit :=
+ if to_Z i <? alloc_vec_Vec_length v then Return tt else Fail_ Failure.
-Definition vec_insert_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
+Definition alloc_vec_Vec_insert (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l =>
if to_Z i <? Z.of_nat (length l)
then Return (list_update l (usize_to_nat i) x)
else Fail_ Failure).
-(* The **backward** function shouldn't be used *)
-Definition vec_index_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
- end.
-
-Definition vec_index_back (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
-
-(* The **backward** function shouldn't be used *)
-Definition vec_index_mut_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
+(* Helper *)
+Axiom alloc_vec_Vec_index_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result T.
+
+(* Helper *)
+Axiom alloc_vec_Vec_update_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result (alloc_vec_Vec T).
+
+(* Trait declaration: [core::slice::index::private_slice_index::Sealed] *)
+Definition core_slice_index_private_slice_index_Sealed (self : Type) := unit.
+
+(* Trait declaration: [core::slice::index::SliceIndex] *)
+Record core_slice_index_SliceIndex (Self T : Type) := mk_core_slice_index_SliceIndex {
+ core_slice_index_SliceIndex_sealedInst : core_slice_index_private_slice_index_Sealed Self;
+ core_slice_index_SliceIndex_Output : Type;
+ core_slice_index_SliceIndex_get : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut_back : Self -> T -> option core_slice_index_SliceIndex_Output -> result T;
+ core_slice_index_SliceIndex_get_unchecked : Self -> const_raw_ptr T -> result (const_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_unchecked_mut : Self -> mut_raw_ptr T -> result (mut_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_index : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut_back : Self -> T -> core_slice_index_SliceIndex_Output -> result T;
+}.
+Arguments mk_core_slice_index_SliceIndex {_ _}.
+Arguments core_slice_index_SliceIndex_sealedInst {_ _}.
+Arguments core_slice_index_SliceIndex_Output {_ _}.
+Arguments core_slice_index_SliceIndex_get {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut_back {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut_back {_ _}.
+
+(* [core::slice::index::[T]::index]: forward function *)
+Definition core_slice_index_Slice_index
+ (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (s : slice T) (i : Idx) : result inst.(core_slice_index_SliceIndex_Output) :=
+ x <- inst.(core_slice_index_SliceIndex_get) i s;
+ match x with
+ | None => Fail_ Failure
+ | Some x => Return x
end.
-Definition vec_index_mut_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
- if to_Z i <? Z.of_nat (length l)
- then Return (list_update l (usize_to_nat i) x)
- else Fail_ Failure).
+(* [core::slice::index::Range:::get]: forward function *)
+Axiom core_slice_index_Range_get : forall (T : Type) (i : core_ops_range_Range usize) (s : slice T), result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: forward function *)
+Axiom core_slice_index_Range_get_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: backward function 0 *)
+Axiom core_slice_index_Range_get_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> option (slice T) -> result (slice T).
+
+(* [core::slice::index::Range::get_unchecked]: forward function *)
+Definition core_slice_index_Range_get_unchecked
+ (T : Type) :
+ core_ops_range_Range usize -> const_raw_ptr (slice T) -> result (const_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::get_unchecked_mut]: forward function *)
+Definition core_slice_index_Range_get_unchecked_mut
+ (T : Type) :
+ core_ops_range_Range usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::index]: forward function *)
+Axiom core_slice_index_Range_index :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: forward function *)
+Axiom core_slice_index_Range_index_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: backward function 0 *)
+Axiom core_slice_index_Range_index_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> slice T -> result (slice T).
+
+(* [core::slice::index::[T]::index_mut]: forward function *)
+Axiom core_slice_index_Slice_index_mut :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> result inst.(core_slice_index_SliceIndex_Output).
+
+(* [core::slice::index::[T]::index_mut]: backward function 0 *)
+Axiom core_slice_index_Slice_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> inst.(core_slice_index_SliceIndex_Output) -> result (slice T).
+
+(* [core::array::[T; N]::index]: forward function *)
+Axiom core_array_Array_index :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_Index (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: forward function *)
+Axiom core_array_Array_index_mut :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: backward function 0 *)
+Axiom core_array_Array_index_mut_back :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx) (x : inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output)), result (array T N).
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (slice T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := core_slice_index_Slice_index T Idx inst;
+|}.
+
+(* Trait implementation: [core::slice::index::private_slice_index::Range] *)
+Definition core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) := tt.
+
+(* Trait implementation: [core::slice::index::Range] *)
+Definition core_slice_index_Range_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := slice T;
+ core_slice_index_SliceIndex_get := core_slice_index_Range_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_Range_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_Range_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_Range_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_Range_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_Range_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_Range_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_Range_index_mut_back T;
+|}.
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (slice T) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_slice_index_Slice_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := core_slice_index_Slice_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := core_slice_index_Slice_index_mut_back T Idx inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_Index (slice T) Idx) :
+ core_ops_index_Index (array T N) Idx := {|
+ core_ops_index_Index_Output := inst.(core_ops_index_Index_Output);
+ core_ops_index_Index_index := core_array_Array_index T Idx N inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexMutInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_IndexMut (slice T) Idx) :
+ core_ops_index_IndexMut (array T N) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_array_Array_coreopsindexIndexInst T Idx N inst.(core_ops_index_IndexMut_indexInst);
+ core_ops_index_IndexMut_index_mut := core_array_Array_index_mut T Idx N inst;
+ core_ops_index_IndexMut_index_mut_back := core_array_Array_index_mut_back T Idx N inst;
+|}.
+
+(* [core::slice::index::usize::get]: forward function *)
+Axiom core_slice_index_usize_get : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: forward function *)
+Axiom core_slice_index_usize_get_mut : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: backward function 0 *)
+Axiom core_slice_index_usize_get_mut_back :
+ forall (T : Type), usize -> slice T -> option T -> result (slice T).
+
+(* [core::slice::index::usize::get_unchecked]: forward function *)
+Axiom core_slice_index_usize_get_unchecked :
+ forall (T : Type), usize -> const_raw_ptr (slice T) -> result (const_raw_ptr T).
+
+(* [core::slice::index::usize::get_unchecked_mut]: forward function *)
+Axiom core_slice_index_usize_get_unchecked_mut :
+ forall (T : Type), usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr T).
+
+(* [core::slice::index::usize::index]: forward function *)
+Axiom core_slice_index_usize_index : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: forward function *)
+Axiom core_slice_index_usize_index_mut : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: backward function 0 *)
+Axiom core_slice_index_usize_index_mut_back :
+ forall (T : Type), usize -> slice T -> T -> result (slice T).
+
+(* Trait implementation: [core::slice::index::private_slice_index::usize] *)
+Definition core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize := tt.
+
+(* Trait implementation: [core::slice::index::usize] *)
+Definition core_slice_index_usize_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex usize (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := T;
+ core_slice_index_SliceIndex_get := core_slice_index_usize_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_usize_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_usize_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_usize_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_usize_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_usize_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_usize_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_usize_index_mut_back T;
+|}.
+
+(* [alloc::vec::Vec::index]: forward function *)
+Axiom alloc_vec_Vec_index : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: forward function *)
+Axiom alloc_vec_Vec_index_mut : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: backward function 0 *)
+Axiom alloc_vec_Vec_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx) (x : inst.(core_slice_index_SliceIndex_Output)), result (alloc_vec_Vec T).
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (alloc_vec_Vec T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := alloc_vec_Vec_index T Idx inst;
+|}.
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (alloc_vec_Vec T) Idx := {|
+ core_ops_index_IndexMut_indexInst := alloc_vec_Vec_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := alloc_vec_Vec_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := alloc_vec_Vec_index_mut_back T Idx inst;
+|}.
+
+(*** Theorems *)
+
+Axiom alloc_vec_Vec_index_mut_back_eq : forall {a : Type} (v : alloc_vec_Vec a) (i : usize) (x : a),
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x =
+ alloc_vec_Vec_update_usize v i x.
End Primitives.
diff --git a/tests/coq/array/_CoqProject b/tests/coq/array/_CoqProject
index f33cefe6..87d8fc3d 100644
--- a/tests/coq/array/_CoqProject
+++ b/tests/coq/array/_CoqProject
@@ -3,6 +3,5 @@
-arg -w
-arg all
-Array_Funs.v
Primitives.v
-Array_Types.v
+Array.v
diff --git a/tests/coq/betree/BetreeMain_Funs.v b/tests/coq/betree/BetreeMain_Funs.v
index 1e457433..261e8270 100644
--- a/tests/coq/betree/BetreeMain_Funs.v
+++ b/tests/coq/betree/BetreeMain_Funs.v
@@ -13,41 +13,41 @@ Import BetreeMain_Opaque.
Module BetreeMain_Funs.
(** [betree_main::betree::load_internal_node]: forward function *)
-Definition betree_load_internal_node_fwd
+Definition betree_load_internal_node
(id : u64) (st : state) :
- result (state * (Betree_list_t (u64 * Betree_message_t)))
+ result (state * (betree_List_t (u64 * betree_Message_t)))
:=
- betree_utils_load_internal_node_fwd id st
+ betree_utils_load_internal_node id st
.
(** [betree_main::betree::store_internal_node]: forward function *)
-Definition betree_store_internal_node_fwd
- (id : u64) (content : Betree_list_t (u64 * Betree_message_t)) (st : state) :
+Definition betree_store_internal_node
+ (id : u64) (content : betree_List_t (u64 * betree_Message_t)) (st : state) :
result (state * unit)
:=
- p <- betree_utils_store_internal_node_fwd id content st;
+ p <- betree_utils_store_internal_node id content st;
let (st0, _) := p in
Return (st0, tt)
.
(** [betree_main::betree::load_leaf_node]: forward function *)
-Definition betree_load_leaf_node_fwd
- (id : u64) (st : state) : result (state * (Betree_list_t (u64 * u64))) :=
- betree_utils_load_leaf_node_fwd id st
+Definition betree_load_leaf_node
+ (id : u64) (st : state) : result (state * (betree_List_t (u64 * u64))) :=
+ betree_utils_load_leaf_node id st
.
(** [betree_main::betree::store_leaf_node]: forward function *)
-Definition betree_store_leaf_node_fwd
- (id : u64) (content : Betree_list_t (u64 * u64)) (st : state) :
+Definition betree_store_leaf_node
+ (id : u64) (content : betree_List_t (u64 * u64)) (st : state) :
result (state * unit)
:=
- p <- betree_utils_store_leaf_node_fwd id content st;
+ p <- betree_utils_store_leaf_node id content st;
let (st0, _) := p in
Return (st0, tt)
.
(** [betree_main::betree::fresh_node_id]: forward function *)
-Definition betree_fresh_node_id_fwd (counter : u64) : result u64 :=
+Definition betree_fresh_node_id (counter : u64) : result u64 :=
_ <- u64_add counter 1%u64; Return counter
.
@@ -57,1142 +57,1121 @@ Definition betree_fresh_node_id_back (counter : u64) : result u64 :=
.
(** [betree_main::betree::NodeIdCounter::{0}::new]: forward function *)
-Definition betree_node_id_counter_new_fwd : result Betree_node_id_counter_t :=
- Return {| Betree_node_id_counter_next_node_id := 0%u64 |}
+Definition betree_NodeIdCounter_new : result betree_NodeIdCounter_t :=
+ Return {| betree_NodeIdCounter_next_node_id := 0%u64 |}
.
(** [betree_main::betree::NodeIdCounter::{0}::fresh_id]: forward function *)
-Definition betree_node_id_counter_fresh_id_fwd
- (self : Betree_node_id_counter_t) : result u64 :=
- _ <- u64_add self.(Betree_node_id_counter_next_node_id) 1%u64;
- Return self.(Betree_node_id_counter_next_node_id)
+Definition betree_NodeIdCounter_fresh_id
+ (self : betree_NodeIdCounter_t) : result u64 :=
+ _ <- u64_add self.(betree_NodeIdCounter_next_node_id) 1%u64;
+ Return self.(betree_NodeIdCounter_next_node_id)
.
(** [betree_main::betree::NodeIdCounter::{0}::fresh_id]: backward function 0 *)
-Definition betree_node_id_counter_fresh_id_back
- (self : Betree_node_id_counter_t) : result Betree_node_id_counter_t :=
- i <- u64_add self.(Betree_node_id_counter_next_node_id) 1%u64;
- Return {| Betree_node_id_counter_next_node_id := i |}
+Definition betree_NodeIdCounter_fresh_id_back
+ (self : betree_NodeIdCounter_t) : result betree_NodeIdCounter_t :=
+ i <- u64_add self.(betree_NodeIdCounter_next_node_id) 1%u64;
+ Return {| betree_NodeIdCounter_next_node_id := i |}
.
-(** [core::num::u64::{9}::MAX] *)
-Definition core_num_u64_max_body : result u64 :=
- Return 18446744073709551615%u64
-.
-Definition core_num_u64_max_c : u64 := core_num_u64_max_body%global.
-
(** [betree_main::betree::upsert_update]: forward function *)
-Definition betree_upsert_update_fwd
- (prev : option u64) (st : Betree_upsert_fun_state_t) : result u64 :=
+Definition betree_upsert_update
+ (prev : option u64) (st : betree_UpsertFunState_t) : result u64 :=
match prev with
| None =>
match st with
- | BetreeUpsertFunStateAdd v => Return v
- | BetreeUpsertFunStateSub i => Return 0%u64
+ | Betree_UpsertFunState_Add v => Return v
+ | Betree_UpsertFunState_Sub i => Return 0%u64
end
| Some prev0 =>
match st with
- | BetreeUpsertFunStateAdd v =>
- margin <- u64_sub core_num_u64_max_c prev0;
- if margin s>= v then u64_add prev0 v else Return core_num_u64_max_c
- | BetreeUpsertFunStateSub v =>
+ | Betree_UpsertFunState_Add v =>
+ margin <- u64_sub core_u64_max prev0;
+ if margin s>= v then u64_add prev0 v else Return core_u64_max
+ | Betree_UpsertFunState_Sub v =>
if prev0 s>= v then u64_sub prev0 v else Return 0%u64
end
end
.
(** [betree_main::betree::List::{1}::len]: forward function *)
-Fixpoint betree_list_len_fwd
- (T : Type) (n : nat) (self : Betree_list_t T) : result u64 :=
+Fixpoint betree_List_len
+ (T : Type) (n : nat) (self : betree_List_t T) : result u64 :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match self with
- | BetreeListCons t tl => i <- betree_list_len_fwd T n0 tl; u64_add 1%u64 i
- | BetreeListNil => Return 0%u64
+ | Betree_List_Cons t tl => i <- betree_List_len T n0 tl; u64_add 1%u64 i
+ | Betree_List_Nil => Return 0%u64
end
end
.
(** [betree_main::betree::List::{1}::split_at]: forward function *)
-Fixpoint betree_list_split_at_fwd
- (T : Type) (n : nat) (self : Betree_list_t T) (n0 : u64) :
- result ((Betree_list_t T) * (Betree_list_t T))
+Fixpoint betree_List_split_at
+ (T : Type) (n : nat) (self : betree_List_t T) (n0 : u64) :
+ result ((betree_List_t T) * (betree_List_t T))
:=
match n with
| O => Fail_ OutOfFuel
| S n1 =>
if n0 s= 0%u64
- then Return (BetreeListNil, self)
+ then Return (Betree_List_Nil, self)
else
match self with
- | BetreeListCons hd tl =>
+ | Betree_List_Cons hd tl =>
i <- u64_sub n0 1%u64;
- p <- betree_list_split_at_fwd T n1 tl i;
+ p <- betree_List_split_at T n1 tl i;
let (ls0, ls1) := p in
let l := ls0 in
- Return (BetreeListCons hd l, ls1)
- | BetreeListNil => Fail_ Failure
+ Return (Betree_List_Cons hd l, ls1)
+ | Betree_List_Nil => Fail_ Failure
end
end
.
(** [betree_main::betree::List::{1}::push_front]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition betree_list_push_front_fwd_back
- (T : Type) (self : Betree_list_t T) (x : T) : result (Betree_list_t T) :=
- let tl := mem_replace_fwd (Betree_list_t T) self BetreeListNil in
+Definition betree_List_push_front
+ (T : Type) (self : betree_List_t T) (x : T) : result (betree_List_t T) :=
+ let tl := core_mem_replace (betree_List_t T) self Betree_List_Nil in
let l := tl in
- Return (BetreeListCons x l)
+ Return (Betree_List_Cons x l)
.
(** [betree_main::betree::List::{1}::pop_front]: forward function *)
-Definition betree_list_pop_front_fwd
- (T : Type) (self : Betree_list_t T) : result T :=
- let ls := mem_replace_fwd (Betree_list_t T) self BetreeListNil in
+Definition betree_List_pop_front
+ (T : Type) (self : betree_List_t T) : result T :=
+ let ls := core_mem_replace (betree_List_t T) self Betree_List_Nil in
match ls with
- | BetreeListCons x tl => Return x
- | BetreeListNil => Fail_ Failure
+ | Betree_List_Cons x tl => Return x
+ | Betree_List_Nil => Fail_ Failure
end
.
(** [betree_main::betree::List::{1}::pop_front]: backward function 0 *)
-Definition betree_list_pop_front_back
- (T : Type) (self : Betree_list_t T) : result (Betree_list_t T) :=
- let ls := mem_replace_fwd (Betree_list_t T) self BetreeListNil in
+Definition betree_List_pop_front_back
+ (T : Type) (self : betree_List_t T) : result (betree_List_t T) :=
+ let ls := core_mem_replace (betree_List_t T) self Betree_List_Nil in
match ls with
- | BetreeListCons x tl => Return tl
- | BetreeListNil => Fail_ Failure
+ | Betree_List_Cons x tl => Return tl
+ | Betree_List_Nil => Fail_ Failure
end
.
(** [betree_main::betree::List::{1}::hd]: forward function *)
-Definition betree_list_hd_fwd (T : Type) (self : Betree_list_t T) : result T :=
+Definition betree_List_hd (T : Type) (self : betree_List_t T) : result T :=
match self with
- | BetreeListCons hd l => Return hd
- | BetreeListNil => Fail_ Failure
+ | Betree_List_Cons hd l => Return hd
+ | Betree_List_Nil => Fail_ Failure
end
.
(** [betree_main::betree::List::{2}::head_has_key]: forward function *)
-Definition betree_list_head_has_key_fwd
- (T : Type) (self : Betree_list_t (u64 * T)) (key : u64) : result bool :=
+Definition betree_List_head_has_key
+ (T : Type) (self : betree_List_t (u64 * T)) (key : u64) : result bool :=
match self with
- | BetreeListCons hd l => let (i, _) := hd in Return (i s= key)
- | BetreeListNil => Return false
+ | Betree_List_Cons hd l => let (i, _) := hd in Return (i s= key)
+ | Betree_List_Nil => Return false
end
.
(** [betree_main::betree::List::{2}::partition_at_pivot]: forward function *)
-Fixpoint betree_list_partition_at_pivot_fwd
- (T : Type) (n : nat) (self : Betree_list_t (u64 * T)) (pivot : u64) :
- result ((Betree_list_t (u64 * T)) * (Betree_list_t (u64 * T)))
+Fixpoint betree_List_partition_at_pivot
+ (T : Type) (n : nat) (self : betree_List_t (u64 * T)) (pivot : u64) :
+ result ((betree_List_t (u64 * T)) * (betree_List_t (u64 * T)))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match self with
- | BetreeListCons hd tl =>
+ | Betree_List_Cons hd tl =>
let (i, t) := hd in
if i s>= pivot
- then Return (BetreeListNil, BetreeListCons (i, t) tl)
+ then Return (Betree_List_Nil, Betree_List_Cons (i, t) tl)
else (
- p <- betree_list_partition_at_pivot_fwd T n0 tl pivot;
+ p <- betree_List_partition_at_pivot T n0 tl pivot;
let (ls0, ls1) := p in
let l := ls0 in
- Return (BetreeListCons (i, t) l, ls1))
- | BetreeListNil => Return (BetreeListNil, BetreeListNil)
+ Return (Betree_List_Cons (i, t) l, ls1))
+ | Betree_List_Nil => Return (Betree_List_Nil, Betree_List_Nil)
end
end
.
(** [betree_main::betree::Leaf::{3}::split]: forward function *)
-Definition betree_leaf_split_fwd
- (n : nat) (self : Betree_leaf_t) (content : Betree_list_t (u64 * u64))
- (params : Betree_params_t) (node_id_cnt : Betree_node_id_counter_t)
+Definition betree_Leaf_split
+ (n : nat) (self : betree_Leaf_t) (content : betree_List_t (u64 * u64))
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(st : state) :
- result (state * Betree_internal_t)
+ result (state * betree_Internal_t)
:=
p <-
- betree_list_split_at_fwd (u64 * u64) n content
- params.(Betree_params_split_size);
+ betree_List_split_at (u64 * u64) n content
+ params.(betree_Params_split_size);
let (content0, content1) := p in
- p0 <- betree_list_hd_fwd (u64 * u64) content1;
+ p0 <- betree_List_hd (u64 * u64) content1;
let (pivot, _) := p0 in
- id0 <- betree_node_id_counter_fresh_id_fwd node_id_cnt;
- node_id_cnt0 <- betree_node_id_counter_fresh_id_back node_id_cnt;
- id1 <- betree_node_id_counter_fresh_id_fwd node_id_cnt0;
- p1 <- betree_store_leaf_node_fwd id0 content0 st;
+ id0 <- betree_NodeIdCounter_fresh_id node_id_cnt;
+ node_id_cnt0 <- betree_NodeIdCounter_fresh_id_back node_id_cnt;
+ id1 <- betree_NodeIdCounter_fresh_id node_id_cnt0;
+ p1 <- betree_store_leaf_node id0 content0 st;
let (st0, _) := p1 in
- p2 <- betree_store_leaf_node_fwd id1 content1 st0;
+ p2 <- betree_store_leaf_node id1 content1 st0;
let (st1, _) := p2 in
- let n0 := BetreeNodeLeaf
+ let n0 := Betree_Node_Leaf
{|
- Betree_leaf_id := id0;
- Betree_leaf_size := params.(Betree_params_split_size)
+ betree_Leaf_id := id0;
+ betree_Leaf_size := params.(betree_Params_split_size)
|} in
- let n1 := BetreeNodeLeaf
+ let n1 := Betree_Node_Leaf
{|
- Betree_leaf_id := id1;
- Betree_leaf_size := params.(Betree_params_split_size)
+ betree_Leaf_id := id1;
+ betree_Leaf_size := params.(betree_Params_split_size)
|} in
- Return (st1, mkBetree_internal_t self.(Betree_leaf_id) pivot n0 n1)
+ Return (st1, mkbetree_Internal_t self.(betree_Leaf_id) pivot n0 n1)
.
(** [betree_main::betree::Leaf::{3}::split]: backward function 2 *)
-Definition betree_leaf_split_back
- (n : nat) (self : Betree_leaf_t) (content : Betree_list_t (u64 * u64))
- (params : Betree_params_t) (node_id_cnt : Betree_node_id_counter_t)
+Definition betree_Leaf_split_back
+ (n : nat) (self : betree_Leaf_t) (content : betree_List_t (u64 * u64))
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(st : state) :
- result Betree_node_id_counter_t
+ result betree_NodeIdCounter_t
:=
p <-
- betree_list_split_at_fwd (u64 * u64) n content
- params.(Betree_params_split_size);
+ betree_List_split_at (u64 * u64) n content
+ params.(betree_Params_split_size);
let (content0, content1) := p in
- _ <- betree_list_hd_fwd (u64 * u64) content1;
- id0 <- betree_node_id_counter_fresh_id_fwd node_id_cnt;
- node_id_cnt0 <- betree_node_id_counter_fresh_id_back node_id_cnt;
- id1 <- betree_node_id_counter_fresh_id_fwd node_id_cnt0;
- p0 <- betree_store_leaf_node_fwd id0 content0 st;
+ _ <- betree_List_hd (u64 * u64) content1;
+ id0 <- betree_NodeIdCounter_fresh_id node_id_cnt;
+ node_id_cnt0 <- betree_NodeIdCounter_fresh_id_back node_id_cnt;
+ id1 <- betree_NodeIdCounter_fresh_id node_id_cnt0;
+ p0 <- betree_store_leaf_node id0 content0 st;
let (st0, _) := p0 in
- _ <- betree_store_leaf_node_fwd id1 content1 st0;
- betree_node_id_counter_fresh_id_back node_id_cnt0
+ _ <- betree_store_leaf_node id1 content1 st0;
+ betree_NodeIdCounter_fresh_id_back node_id_cnt0
.
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: forward function *)
-Fixpoint betree_node_lookup_first_message_for_key_fwd
- (n : nat) (key : u64) (msgs : Betree_list_t (u64 * Betree_message_t)) :
- result (Betree_list_t (u64 * Betree_message_t))
+Fixpoint betree_Node_lookup_first_message_for_key
+ (n : nat) (key : u64) (msgs : betree_List_t (u64 * betree_Message_t)) :
+ result (betree_List_t (u64 * betree_Message_t))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match msgs with
- | BetreeListCons x next_msgs =>
+ | Betree_List_Cons x next_msgs =>
let (i, m) := x in
if i s>= key
- then Return (BetreeListCons (i, m) next_msgs)
- else betree_node_lookup_first_message_for_key_fwd n0 key next_msgs
- | BetreeListNil => Return BetreeListNil
+ then Return (Betree_List_Cons (i, m) next_msgs)
+ else betree_Node_lookup_first_message_for_key n0 key next_msgs
+ | Betree_List_Nil => Return Betree_List_Nil
end
end
.
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: backward function 0 *)
-Fixpoint betree_node_lookup_first_message_for_key_back
- (n : nat) (key : u64) (msgs : Betree_list_t (u64 * Betree_message_t))
- (ret : Betree_list_t (u64 * Betree_message_t)) :
- result (Betree_list_t (u64 * Betree_message_t))
+Fixpoint betree_Node_lookup_first_message_for_key_back
+ (n : nat) (key : u64) (msgs : betree_List_t (u64 * betree_Message_t))
+ (ret : betree_List_t (u64 * betree_Message_t)) :
+ result (betree_List_t (u64 * betree_Message_t))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match msgs with
- | BetreeListCons x next_msgs =>
+ | Betree_List_Cons x next_msgs =>
let (i, m) := x in
if i s>= key
then Return ret
else (
next_msgs0 <-
- betree_node_lookup_first_message_for_key_back n0 key next_msgs ret;
- Return (BetreeListCons (i, m) next_msgs0))
- | BetreeListNil => Return ret
+ betree_Node_lookup_first_message_for_key_back n0 key next_msgs ret;
+ Return (Betree_List_Cons (i, m) next_msgs0))
+ | Betree_List_Nil => Return ret
end
end
.
(** [betree_main::betree::Node::{5}::apply_upserts]: forward function *)
-Fixpoint betree_node_apply_upserts_fwd
- (n : nat) (msgs : Betree_list_t (u64 * Betree_message_t)) (prev : option u64)
+Fixpoint betree_Node_apply_upserts
+ (n : nat) (msgs : betree_List_t (u64 * betree_Message_t)) (prev : option u64)
(key : u64) (st : state) :
result (state * u64)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- b <- betree_list_head_has_key_fwd Betree_message_t msgs key;
+ b <- betree_List_head_has_key betree_Message_t msgs key;
if b
then (
- msg <- betree_list_pop_front_fwd (u64 * Betree_message_t) msgs;
+ msg <- betree_List_pop_front (u64 * betree_Message_t) msgs;
let (_, m) := msg in
match m with
- | BetreeMessageInsert i => Fail_ Failure
- | BetreeMessageDelete => Fail_ Failure
- | BetreeMessageUpsert s =>
- v <- betree_upsert_update_fwd prev s;
- msgs0 <- betree_list_pop_front_back (u64 * Betree_message_t) msgs;
- betree_node_apply_upserts_fwd n0 msgs0 (Some v) key st
+ | Betree_Message_Insert i => Fail_ Failure
+ | Betree_Message_Delete => Fail_ Failure
+ | Betree_Message_Upsert s =>
+ v <- betree_upsert_update prev s;
+ msgs0 <- betree_List_pop_front_back (u64 * betree_Message_t) msgs;
+ betree_Node_apply_upserts n0 msgs0 (Some v) key st
end)
else (
- p <- core_option_option_unwrap_fwd u64 prev st;
+ p <- core_option_Option_unwrap u64 prev st;
let (st0, v) := p in
_ <-
- betree_list_push_front_fwd_back (u64 * Betree_message_t) msgs (key,
- BetreeMessageInsert v);
+ betree_List_push_front (u64 * betree_Message_t) msgs (key,
+ Betree_Message_Insert v);
Return (st0, v))
end
.
(** [betree_main::betree::Node::{5}::apply_upserts]: backward function 0 *)
-Fixpoint betree_node_apply_upserts_back
- (n : nat) (msgs : Betree_list_t (u64 * Betree_message_t)) (prev : option u64)
+Fixpoint betree_Node_apply_upserts_back
+ (n : nat) (msgs : betree_List_t (u64 * betree_Message_t)) (prev : option u64)
(key : u64) (st : state) :
- result (Betree_list_t (u64 * Betree_message_t))
+ result (betree_List_t (u64 * betree_Message_t))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- b <- betree_list_head_has_key_fwd Betree_message_t msgs key;
+ b <- betree_List_head_has_key betree_Message_t msgs key;
if b
then (
- msg <- betree_list_pop_front_fwd (u64 * Betree_message_t) msgs;
+ msg <- betree_List_pop_front (u64 * betree_Message_t) msgs;
let (_, m) := msg in
match m with
- | BetreeMessageInsert i => Fail_ Failure
- | BetreeMessageDelete => Fail_ Failure
- | BetreeMessageUpsert s =>
- v <- betree_upsert_update_fwd prev s;
- msgs0 <- betree_list_pop_front_back (u64 * Betree_message_t) msgs;
- betree_node_apply_upserts_back n0 msgs0 (Some v) key st
+ | Betree_Message_Insert i => Fail_ Failure
+ | Betree_Message_Delete => Fail_ Failure
+ | Betree_Message_Upsert s =>
+ v <- betree_upsert_update prev s;
+ msgs0 <- betree_List_pop_front_back (u64 * betree_Message_t) msgs;
+ betree_Node_apply_upserts_back n0 msgs0 (Some v) key st
end)
else (
- p <- core_option_option_unwrap_fwd u64 prev st;
+ p <- core_option_Option_unwrap u64 prev st;
let (_, v) := p in
- betree_list_push_front_fwd_back (u64 * Betree_message_t) msgs (key,
- BetreeMessageInsert v))
+ betree_List_push_front (u64 * betree_Message_t) msgs (key,
+ Betree_Message_Insert v))
end
.
(** [betree_main::betree::Node::{5}::lookup_in_bindings]: forward function *)
-Fixpoint betree_node_lookup_in_bindings_fwd
- (n : nat) (key : u64) (bindings : Betree_list_t (u64 * u64)) :
+Fixpoint betree_Node_lookup_in_bindings
+ (n : nat) (key : u64) (bindings : betree_List_t (u64 * u64)) :
result (option u64)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match bindings with
- | BetreeListCons hd tl =>
+ | Betree_List_Cons hd tl =>
let (i, i0) := hd in
if i s= key
then Return (Some i0)
else
if i s> key
then Return None
- else betree_node_lookup_in_bindings_fwd n0 key tl
- | BetreeListNil => Return None
+ else betree_Node_lookup_in_bindings n0 key tl
+ | Betree_List_Nil => Return None
end
end
.
(** [betree_main::betree::Internal::{4}::lookup_in_children]: forward function *)
-Fixpoint betree_internal_lookup_in_children_fwd
- (n : nat) (self : Betree_internal_t) (key : u64) (st : state) :
+Fixpoint betree_Internal_lookup_in_children
+ (n : nat) (self : betree_Internal_t) (key : u64) (st : state) :
result (state * (option u64))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- if key s< self.(Betree_internal_pivot)
- then betree_node_lookup_fwd n0 self.(Betree_internal_left) key st
- else betree_node_lookup_fwd n0 self.(Betree_internal_right) key st
+ if key s< self.(betree_Internal_pivot)
+ then betree_Node_lookup n0 self.(betree_Internal_left) key st
+ else betree_Node_lookup n0 self.(betree_Internal_right) key st
end
(** [betree_main::betree::Internal::{4}::lookup_in_children]: backward function 0 *)
-with betree_internal_lookup_in_children_back
- (n : nat) (self : Betree_internal_t) (key : u64) (st : state) :
- result Betree_internal_t
+with betree_Internal_lookup_in_children_back
+ (n : nat) (self : betree_Internal_t) (key : u64) (st : state) :
+ result betree_Internal_t
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- if key s< self.(Betree_internal_pivot)
+ if key s< self.(betree_Internal_pivot)
then (
- n1 <- betree_node_lookup_back n0 self.(Betree_internal_left) key st;
- Return (mkBetree_internal_t self.(Betree_internal_id)
- self.(Betree_internal_pivot) n1 self.(Betree_internal_right)))
+ n1 <- betree_Node_lookup_back n0 self.(betree_Internal_left) key st;
+ Return (mkbetree_Internal_t self.(betree_Internal_id)
+ self.(betree_Internal_pivot) n1 self.(betree_Internal_right)))
else (
- n1 <- betree_node_lookup_back n0 self.(Betree_internal_right) key st;
- Return (mkBetree_internal_t self.(Betree_internal_id)
- self.(Betree_internal_pivot) self.(Betree_internal_left) n1))
+ n1 <- betree_Node_lookup_back n0 self.(betree_Internal_right) key st;
+ Return (mkbetree_Internal_t self.(betree_Internal_id)
+ self.(betree_Internal_pivot) self.(betree_Internal_left) n1))
end
(** [betree_main::betree::Node::{5}::lookup]: forward function *)
-with betree_node_lookup_fwd
- (n : nat) (self : Betree_node_t) (key : u64) (st : state) :
+with betree_Node_lookup
+ (n : nat) (self : betree_Node_t) (key : u64) (st : state) :
result (state * (option u64))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match self with
- | BetreeNodeInternal node =>
- p <- betree_load_internal_node_fwd node.(Betree_internal_id) st;
+ | Betree_Node_Internal node =>
+ p <- betree_load_internal_node node.(betree_Internal_id) st;
let (st0, msgs) := p in
- pending <- betree_node_lookup_first_message_for_key_fwd n0 key msgs;
+ pending <- betree_Node_lookup_first_message_for_key n0 key msgs;
match pending with
- | BetreeListCons p0 l =>
+ | Betree_List_Cons p0 l =>
let (k, msg) := p0 in
if k s<> key
then (
- p1 <- betree_internal_lookup_in_children_fwd n0 node key st0;
- let (st1, opt) := p1 in
+ p1 <- betree_Internal_lookup_in_children n0 node key st0;
+ let (st1, o) := p1 in
_ <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
- (BetreeListCons (k, msg) l);
- Return (st1, opt))
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
+ (Betree_List_Cons (k, msg) l);
+ Return (st1, o))
else
match msg with
- | BetreeMessageInsert v =>
+ | Betree_Message_Insert v =>
_ <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
- (BetreeListCons (k, BetreeMessageInsert v) l);
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
+ (Betree_List_Cons (k, Betree_Message_Insert v) l);
Return (st0, Some v)
- | BetreeMessageDelete =>
+ | Betree_Message_Delete =>
_ <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
- (BetreeListCons (k, BetreeMessageDelete) l);
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
+ (Betree_List_Cons (k, Betree_Message_Delete) l);
Return (st0, None)
- | BetreeMessageUpsert ufs =>
- p1 <- betree_internal_lookup_in_children_fwd n0 node key st0;
+ | Betree_Message_Upsert ufs =>
+ p1 <- betree_Internal_lookup_in_children n0 node key st0;
let (st1, v) := p1 in
p2 <-
- betree_node_apply_upserts_fwd n0 (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1;
+ betree_Node_apply_upserts n0 (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1;
let (st2, v0) := p2 in
- node0 <- betree_internal_lookup_in_children_back n0 node key st0;
+ node0 <- betree_Internal_lookup_in_children_back n0 node key st0;
pending0 <-
- betree_node_apply_upserts_back n0 (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1;
+ betree_Node_apply_upserts_back n0 (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1;
msgs0 <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
pending0;
p3 <-
- betree_store_internal_node_fwd node0.(Betree_internal_id) msgs0
- st2;
+ betree_store_internal_node node0.(betree_Internal_id) msgs0 st2;
let (st3, _) := p3 in
Return (st3, Some v0)
end
- | BetreeListNil =>
- p0 <- betree_internal_lookup_in_children_fwd n0 node key st0;
- let (st1, opt) := p0 in
+ | Betree_List_Nil =>
+ p0 <- betree_Internal_lookup_in_children n0 node key st0;
+ let (st1, o) := p0 in
_ <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
- BetreeListNil;
- Return (st1, opt)
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
+ Betree_List_Nil;
+ Return (st1, o)
end
- | BetreeNodeLeaf node =>
- p <- betree_load_leaf_node_fwd node.(Betree_leaf_id) st;
+ | Betree_Node_Leaf node =>
+ p <- betree_load_leaf_node node.(betree_Leaf_id) st;
let (st0, bindings) := p in
- opt <- betree_node_lookup_in_bindings_fwd n0 key bindings;
- Return (st0, opt)
+ o <- betree_Node_lookup_in_bindings n0 key bindings;
+ Return (st0, o)
end
end
(** [betree_main::betree::Node::{5}::lookup]: backward function 0 *)
-with betree_node_lookup_back
- (n : nat) (self : Betree_node_t) (key : u64) (st : state) :
- result Betree_node_t
+with betree_Node_lookup_back
+ (n : nat) (self : betree_Node_t) (key : u64) (st : state) :
+ result betree_Node_t
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match self with
- | BetreeNodeInternal node =>
- p <- betree_load_internal_node_fwd node.(Betree_internal_id) st;
+ | Betree_Node_Internal node =>
+ p <- betree_load_internal_node node.(betree_Internal_id) st;
let (st0, msgs) := p in
- pending <- betree_node_lookup_first_message_for_key_fwd n0 key msgs;
+ pending <- betree_Node_lookup_first_message_for_key n0 key msgs;
match pending with
- | BetreeListCons p0 l =>
+ | Betree_List_Cons p0 l =>
let (k, msg) := p0 in
if k s<> key
then (
_ <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
- (BetreeListCons (k, msg) l);
- node0 <- betree_internal_lookup_in_children_back n0 node key st0;
- Return (BetreeNodeInternal node0))
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
+ (Betree_List_Cons (k, msg) l);
+ node0 <- betree_Internal_lookup_in_children_back n0 node key st0;
+ Return (Betree_Node_Internal node0))
else
match msg with
- | BetreeMessageInsert v =>
+ | Betree_Message_Insert v =>
_ <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
- (BetreeListCons (k, BetreeMessageInsert v) l);
- Return (BetreeNodeInternal node)
- | BetreeMessageDelete =>
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
+ (Betree_List_Cons (k, Betree_Message_Insert v) l);
+ Return (Betree_Node_Internal node)
+ | Betree_Message_Delete =>
_ <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
- (BetreeListCons (k, BetreeMessageDelete) l);
- Return (BetreeNodeInternal node)
- | BetreeMessageUpsert ufs =>
- p1 <- betree_internal_lookup_in_children_fwd n0 node key st0;
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
+ (Betree_List_Cons (k, Betree_Message_Delete) l);
+ Return (Betree_Node_Internal node)
+ | Betree_Message_Upsert ufs =>
+ p1 <- betree_Internal_lookup_in_children n0 node key st0;
let (st1, v) := p1 in
p2 <-
- betree_node_apply_upserts_fwd n0 (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1;
+ betree_Node_apply_upserts n0 (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1;
let (st2, _) := p2 in
- node0 <- betree_internal_lookup_in_children_back n0 node key st0;
+ node0 <- betree_Internal_lookup_in_children_back n0 node key st0;
pending0 <-
- betree_node_apply_upserts_back n0 (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1;
+ betree_Node_apply_upserts_back n0 (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1;
msgs0 <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
pending0;
_ <-
- betree_store_internal_node_fwd node0.(Betree_internal_id) msgs0
- st2;
- Return (BetreeNodeInternal node0)
+ betree_store_internal_node node0.(betree_Internal_id) msgs0 st2;
+ Return (Betree_Node_Internal node0)
end
- | BetreeListNil =>
+ | Betree_List_Nil =>
_ <-
- betree_node_lookup_first_message_for_key_back n0 key msgs
- BetreeListNil;
- node0 <- betree_internal_lookup_in_children_back n0 node key st0;
- Return (BetreeNodeInternal node0)
+ betree_Node_lookup_first_message_for_key_back n0 key msgs
+ Betree_List_Nil;
+ node0 <- betree_Internal_lookup_in_children_back n0 node key st0;
+ Return (Betree_Node_Internal node0)
end
- | BetreeNodeLeaf node =>
- p <- betree_load_leaf_node_fwd node.(Betree_leaf_id) st;
+ | Betree_Node_Leaf node =>
+ p <- betree_load_leaf_node node.(betree_Leaf_id) st;
let (_, bindings) := p in
- _ <- betree_node_lookup_in_bindings_fwd n0 key bindings;
- Return (BetreeNodeLeaf node)
+ _ <- betree_Node_lookup_in_bindings n0 key bindings;
+ Return (Betree_Node_Leaf node)
end
end
.
(** [betree_main::betree::Node::{5}::filter_messages_for_key]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint betree_node_filter_messages_for_key_fwd_back
- (n : nat) (key : u64) (msgs : Betree_list_t (u64 * Betree_message_t)) :
- result (Betree_list_t (u64 * Betree_message_t))
+Fixpoint betree_Node_filter_messages_for_key
+ (n : nat) (key : u64) (msgs : betree_List_t (u64 * betree_Message_t)) :
+ result (betree_List_t (u64 * betree_Message_t))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match msgs with
- | BetreeListCons p l =>
+ | Betree_List_Cons p l =>
let (k, m) := p in
if k s= key
then (
msgs0 <-
- betree_list_pop_front_back (u64 * Betree_message_t) (BetreeListCons
+ betree_List_pop_front_back (u64 * betree_Message_t) (Betree_List_Cons
(k, m) l);
- betree_node_filter_messages_for_key_fwd_back n0 key msgs0)
- else Return (BetreeListCons (k, m) l)
- | BetreeListNil => Return BetreeListNil
+ betree_Node_filter_messages_for_key n0 key msgs0)
+ else Return (Betree_List_Cons (k, m) l)
+ | Betree_List_Nil => Return Betree_List_Nil
end
end
.
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: forward function *)
-Fixpoint betree_node_lookup_first_message_after_key_fwd
- (n : nat) (key : u64) (msgs : Betree_list_t (u64 * Betree_message_t)) :
- result (Betree_list_t (u64 * Betree_message_t))
+Fixpoint betree_Node_lookup_first_message_after_key
+ (n : nat) (key : u64) (msgs : betree_List_t (u64 * betree_Message_t)) :
+ result (betree_List_t (u64 * betree_Message_t))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match msgs with
- | BetreeListCons p next_msgs =>
+ | Betree_List_Cons p next_msgs =>
let (k, m) := p in
if k s= key
- then betree_node_lookup_first_message_after_key_fwd n0 key next_msgs
- else Return (BetreeListCons (k, m) next_msgs)
- | BetreeListNil => Return BetreeListNil
+ then betree_Node_lookup_first_message_after_key n0 key next_msgs
+ else Return (Betree_List_Cons (k, m) next_msgs)
+ | Betree_List_Nil => Return Betree_List_Nil
end
end
.
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: backward function 0 *)
-Fixpoint betree_node_lookup_first_message_after_key_back
- (n : nat) (key : u64) (msgs : Betree_list_t (u64 * Betree_message_t))
- (ret : Betree_list_t (u64 * Betree_message_t)) :
- result (Betree_list_t (u64 * Betree_message_t))
+Fixpoint betree_Node_lookup_first_message_after_key_back
+ (n : nat) (key : u64) (msgs : betree_List_t (u64 * betree_Message_t))
+ (ret : betree_List_t (u64 * betree_Message_t)) :
+ result (betree_List_t (u64 * betree_Message_t))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match msgs with
- | BetreeListCons p next_msgs =>
+ | Betree_List_Cons p next_msgs =>
let (k, m) := p in
if k s= key
then (
next_msgs0 <-
- betree_node_lookup_first_message_after_key_back n0 key next_msgs ret;
- Return (BetreeListCons (k, m) next_msgs0))
+ betree_Node_lookup_first_message_after_key_back n0 key next_msgs ret;
+ Return (Betree_List_Cons (k, m) next_msgs0))
else Return ret
- | BetreeListNil => Return ret
+ | Betree_List_Nil => Return ret
end
end
.
(** [betree_main::betree::Node::{5}::apply_to_internal]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition betree_node_apply_to_internal_fwd_back
- (n : nat) (msgs : Betree_list_t (u64 * Betree_message_t)) (key : u64)
- (new_msg : Betree_message_t) :
- result (Betree_list_t (u64 * Betree_message_t))
+Definition betree_Node_apply_to_internal
+ (n : nat) (msgs : betree_List_t (u64 * betree_Message_t)) (key : u64)
+ (new_msg : betree_Message_t) :
+ result (betree_List_t (u64 * betree_Message_t))
:=
- msgs0 <- betree_node_lookup_first_message_for_key_fwd n key msgs;
- b <- betree_list_head_has_key_fwd Betree_message_t msgs0 key;
+ msgs0 <- betree_Node_lookup_first_message_for_key n key msgs;
+ b <- betree_List_head_has_key betree_Message_t msgs0 key;
if b
then
match new_msg with
- | BetreeMessageInsert i =>
- msgs1 <- betree_node_filter_messages_for_key_fwd_back n key msgs0;
+ | Betree_Message_Insert i =>
+ msgs1 <- betree_Node_filter_messages_for_key n key msgs0;
msgs2 <-
- betree_list_push_front_fwd_back (u64 * Betree_message_t) msgs1 (key,
- BetreeMessageInsert i);
- betree_node_lookup_first_message_for_key_back n key msgs msgs2
- | BetreeMessageDelete =>
- msgs1 <- betree_node_filter_messages_for_key_fwd_back n key msgs0;
+ betree_List_push_front (u64 * betree_Message_t) msgs1 (key,
+ Betree_Message_Insert i);
+ betree_Node_lookup_first_message_for_key_back n key msgs msgs2
+ | Betree_Message_Delete =>
+ msgs1 <- betree_Node_filter_messages_for_key n key msgs0;
msgs2 <-
- betree_list_push_front_fwd_back (u64 * Betree_message_t) msgs1 (key,
- BetreeMessageDelete);
- betree_node_lookup_first_message_for_key_back n key msgs msgs2
- | BetreeMessageUpsert s =>
- p <- betree_list_hd_fwd (u64 * Betree_message_t) msgs0;
+ betree_List_push_front (u64 * betree_Message_t) msgs1 (key,
+ Betree_Message_Delete);
+ betree_Node_lookup_first_message_for_key_back n key msgs msgs2
+ | Betree_Message_Upsert s =>
+ p <- betree_List_hd (u64 * betree_Message_t) msgs0;
let (_, m) := p in
match m with
- | BetreeMessageInsert prev =>
- v <- betree_upsert_update_fwd (Some prev) s;
- msgs1 <- betree_list_pop_front_back (u64 * Betree_message_t) msgs0;
+ | Betree_Message_Insert prev =>
+ v <- betree_upsert_update (Some prev) s;
+ msgs1 <- betree_List_pop_front_back (u64 * betree_Message_t) msgs0;
msgs2 <-
- betree_list_push_front_fwd_back (u64 * Betree_message_t) msgs1 (key,
- BetreeMessageInsert v);
- betree_node_lookup_first_message_for_key_back n key msgs msgs2
- | BetreeMessageDelete =>
- v <- betree_upsert_update_fwd None s;
- msgs1 <- betree_list_pop_front_back (u64 * Betree_message_t) msgs0;
+ betree_List_push_front (u64 * betree_Message_t) msgs1 (key,
+ Betree_Message_Insert v);
+ betree_Node_lookup_first_message_for_key_back n key msgs msgs2
+ | Betree_Message_Delete =>
+ v <- betree_upsert_update None s;
+ msgs1 <- betree_List_pop_front_back (u64 * betree_Message_t) msgs0;
msgs2 <-
- betree_list_push_front_fwd_back (u64 * Betree_message_t) msgs1 (key,
- BetreeMessageInsert v);
- betree_node_lookup_first_message_for_key_back n key msgs msgs2
- | BetreeMessageUpsert ufs =>
- msgs1 <- betree_node_lookup_first_message_after_key_fwd n key msgs0;
+ betree_List_push_front (u64 * betree_Message_t) msgs1 (key,
+ Betree_Message_Insert v);
+ betree_Node_lookup_first_message_for_key_back n key msgs msgs2
+ | Betree_Message_Upsert ufs =>
+ msgs1 <- betree_Node_lookup_first_message_after_key n key msgs0;
msgs2 <-
- betree_list_push_front_fwd_back (u64 * Betree_message_t) msgs1 (key,
- BetreeMessageUpsert s);
+ betree_List_push_front (u64 * betree_Message_t) msgs1 (key,
+ Betree_Message_Upsert s);
msgs3 <-
- betree_node_lookup_first_message_after_key_back n key msgs0 msgs2;
- betree_node_lookup_first_message_for_key_back n key msgs msgs3
+ betree_Node_lookup_first_message_after_key_back n key msgs0 msgs2;
+ betree_Node_lookup_first_message_for_key_back n key msgs msgs3
end
end
else (
msgs1 <-
- betree_list_push_front_fwd_back (u64 * Betree_message_t) msgs0 (key,
- new_msg);
- betree_node_lookup_first_message_for_key_back n key msgs msgs1)
+ betree_List_push_front (u64 * betree_Message_t) msgs0 (key, new_msg);
+ betree_Node_lookup_first_message_for_key_back n key msgs msgs1)
.
(** [betree_main::betree::Node::{5}::apply_messages_to_internal]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint betree_node_apply_messages_to_internal_fwd_back
- (n : nat) (msgs : Betree_list_t (u64 * Betree_message_t))
- (new_msgs : Betree_list_t (u64 * Betree_message_t)) :
- result (Betree_list_t (u64 * Betree_message_t))
+Fixpoint betree_Node_apply_messages_to_internal
+ (n : nat) (msgs : betree_List_t (u64 * betree_Message_t))
+ (new_msgs : betree_List_t (u64 * betree_Message_t)) :
+ result (betree_List_t (u64 * betree_Message_t))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match new_msgs with
- | BetreeListCons new_msg new_msgs_tl =>
+ | Betree_List_Cons new_msg new_msgs_tl =>
let (i, m) := new_msg in
- msgs0 <- betree_node_apply_to_internal_fwd_back n0 msgs i m;
- betree_node_apply_messages_to_internal_fwd_back n0 msgs0 new_msgs_tl
- | BetreeListNil => Return msgs
+ msgs0 <- betree_Node_apply_to_internal n0 msgs i m;
+ betree_Node_apply_messages_to_internal n0 msgs0 new_msgs_tl
+ | Betree_List_Nil => Return msgs
end
end
.
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: forward function *)
-Fixpoint betree_node_lookup_mut_in_bindings_fwd
- (n : nat) (key : u64) (bindings : Betree_list_t (u64 * u64)) :
- result (Betree_list_t (u64 * u64))
+Fixpoint betree_Node_lookup_mut_in_bindings
+ (n : nat) (key : u64) (bindings : betree_List_t (u64 * u64)) :
+ result (betree_List_t (u64 * u64))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match bindings with
- | BetreeListCons hd tl =>
+ | Betree_List_Cons hd tl =>
let (i, i0) := hd in
if i s>= key
- then Return (BetreeListCons (i, i0) tl)
- else betree_node_lookup_mut_in_bindings_fwd n0 key tl
- | BetreeListNil => Return BetreeListNil
+ then Return (Betree_List_Cons (i, i0) tl)
+ else betree_Node_lookup_mut_in_bindings n0 key tl
+ | Betree_List_Nil => Return Betree_List_Nil
end
end
.
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: backward function 0 *)
-Fixpoint betree_node_lookup_mut_in_bindings_back
- (n : nat) (key : u64) (bindings : Betree_list_t (u64 * u64))
- (ret : Betree_list_t (u64 * u64)) :
- result (Betree_list_t (u64 * u64))
+Fixpoint betree_Node_lookup_mut_in_bindings_back
+ (n : nat) (key : u64) (bindings : betree_List_t (u64 * u64))
+ (ret : betree_List_t (u64 * u64)) :
+ result (betree_List_t (u64 * u64))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match bindings with
- | BetreeListCons hd tl =>
+ | Betree_List_Cons hd tl =>
let (i, i0) := hd in
if i s>= key
then Return ret
else (
- tl0 <- betree_node_lookup_mut_in_bindings_back n0 key tl ret;
- Return (BetreeListCons (i, i0) tl0))
- | BetreeListNil => Return ret
+ tl0 <- betree_Node_lookup_mut_in_bindings_back n0 key tl ret;
+ Return (Betree_List_Cons (i, i0) tl0))
+ | Betree_List_Nil => Return ret
end
end
.
(** [betree_main::betree::Node::{5}::apply_to_leaf]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition betree_node_apply_to_leaf_fwd_back
- (n : nat) (bindings : Betree_list_t (u64 * u64)) (key : u64)
- (new_msg : Betree_message_t) :
- result (Betree_list_t (u64 * u64))
+Definition betree_Node_apply_to_leaf
+ (n : nat) (bindings : betree_List_t (u64 * u64)) (key : u64)
+ (new_msg : betree_Message_t) :
+ result (betree_List_t (u64 * u64))
:=
- bindings0 <- betree_node_lookup_mut_in_bindings_fwd n key bindings;
- b <- betree_list_head_has_key_fwd u64 bindings0 key;
+ bindings0 <- betree_Node_lookup_mut_in_bindings n key bindings;
+ b <- betree_List_head_has_key u64 bindings0 key;
if b
then (
- hd <- betree_list_pop_front_fwd (u64 * u64) bindings0;
+ hd <- betree_List_pop_front (u64 * u64) bindings0;
match new_msg with
- | BetreeMessageInsert v =>
- bindings1 <- betree_list_pop_front_back (u64 * u64) bindings0;
- bindings2 <-
- betree_list_push_front_fwd_back (u64 * u64) bindings1 (key, v);
- betree_node_lookup_mut_in_bindings_back n key bindings bindings2
- | BetreeMessageDelete =>
- bindings1 <- betree_list_pop_front_back (u64 * u64) bindings0;
- betree_node_lookup_mut_in_bindings_back n key bindings bindings1
- | BetreeMessageUpsert s =>
+ | Betree_Message_Insert v =>
+ bindings1 <- betree_List_pop_front_back (u64 * u64) bindings0;
+ bindings2 <- betree_List_push_front (u64 * u64) bindings1 (key, v);
+ betree_Node_lookup_mut_in_bindings_back n key bindings bindings2
+ | Betree_Message_Delete =>
+ bindings1 <- betree_List_pop_front_back (u64 * u64) bindings0;
+ betree_Node_lookup_mut_in_bindings_back n key bindings bindings1
+ | Betree_Message_Upsert s =>
let (_, i) := hd in
- v <- betree_upsert_update_fwd (Some i) s;
- bindings1 <- betree_list_pop_front_back (u64 * u64) bindings0;
- bindings2 <-
- betree_list_push_front_fwd_back (u64 * u64) bindings1 (key, v);
- betree_node_lookup_mut_in_bindings_back n key bindings bindings2
+ v <- betree_upsert_update (Some i) s;
+ bindings1 <- betree_List_pop_front_back (u64 * u64) bindings0;
+ bindings2 <- betree_List_push_front (u64 * u64) bindings1 (key, v);
+ betree_Node_lookup_mut_in_bindings_back n key bindings bindings2
end)
else
match new_msg with
- | BetreeMessageInsert v =>
- bindings1 <-
- betree_list_push_front_fwd_back (u64 * u64) bindings0 (key, v);
- betree_node_lookup_mut_in_bindings_back n key bindings bindings1
- | BetreeMessageDelete =>
- betree_node_lookup_mut_in_bindings_back n key bindings bindings0
- | BetreeMessageUpsert s =>
- v <- betree_upsert_update_fwd None s;
- bindings1 <-
- betree_list_push_front_fwd_back (u64 * u64) bindings0 (key, v);
- betree_node_lookup_mut_in_bindings_back n key bindings bindings1
+ | Betree_Message_Insert v =>
+ bindings1 <- betree_List_push_front (u64 * u64) bindings0 (key, v);
+ betree_Node_lookup_mut_in_bindings_back n key bindings bindings1
+ | Betree_Message_Delete =>
+ betree_Node_lookup_mut_in_bindings_back n key bindings bindings0
+ | Betree_Message_Upsert s =>
+ v <- betree_upsert_update None s;
+ bindings1 <- betree_List_push_front (u64 * u64) bindings0 (key, v);
+ betree_Node_lookup_mut_in_bindings_back n key bindings bindings1
end
.
(** [betree_main::betree::Node::{5}::apply_messages_to_leaf]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint betree_node_apply_messages_to_leaf_fwd_back
- (n : nat) (bindings : Betree_list_t (u64 * u64))
- (new_msgs : Betree_list_t (u64 * Betree_message_t)) :
- result (Betree_list_t (u64 * u64))
+Fixpoint betree_Node_apply_messages_to_leaf
+ (n : nat) (bindings : betree_List_t (u64 * u64))
+ (new_msgs : betree_List_t (u64 * betree_Message_t)) :
+ result (betree_List_t (u64 * u64))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match new_msgs with
- | BetreeListCons new_msg new_msgs_tl =>
+ | Betree_List_Cons new_msg new_msgs_tl =>
let (i, m) := new_msg in
- bindings0 <- betree_node_apply_to_leaf_fwd_back n0 bindings i m;
- betree_node_apply_messages_to_leaf_fwd_back n0 bindings0 new_msgs_tl
- | BetreeListNil => Return bindings
+ bindings0 <- betree_Node_apply_to_leaf n0 bindings i m;
+ betree_Node_apply_messages_to_leaf n0 bindings0 new_msgs_tl
+ | Betree_List_Nil => Return bindings
end
end
.
(** [betree_main::betree::Internal::{4}::flush]: forward function *)
-Fixpoint betree_internal_flush_fwd
- (n : nat) (self : Betree_internal_t) (params : Betree_params_t)
- (node_id_cnt : Betree_node_id_counter_t)
- (content : Betree_list_t (u64 * Betree_message_t)) (st : state) :
- result (state * (Betree_list_t (u64 * Betree_message_t)))
+Fixpoint betree_Internal_flush
+ (n : nat) (self : betree_Internal_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 * betree_Message_t)) (st : state) :
+ result (state * (betree_List_t (u64 * betree_Message_t)))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
p <-
- betree_list_partition_at_pivot_fwd Betree_message_t n0 content
- self.(Betree_internal_pivot);
+ betree_List_partition_at_pivot betree_Message_t n0 content
+ self.(betree_Internal_pivot);
let (msgs_left, msgs_right) := p in
- len_left <- betree_list_len_fwd (u64 * Betree_message_t) n0 msgs_left;
- if len_left s>= params.(Betree_params_min_flush_size)
+ len_left <- betree_List_len (u64 * betree_Message_t) n0 msgs_left;
+ if len_left s>= params.(betree_Params_min_flush_size)
then (
p0 <-
- betree_node_apply_messages_fwd n0 self.(Betree_internal_left) params
+ betree_Node_apply_messages n0 self.(betree_Internal_left) params
node_id_cnt msgs_left st;
let (st0, _) := p0 in
p1 <-
- betree_node_apply_messages_back n0 self.(Betree_internal_left) params
+ betree_Node_apply_messages_back n0 self.(betree_Internal_left) params
node_id_cnt msgs_left st;
let (_, node_id_cnt0) := p1 in
- len_right <- betree_list_len_fwd (u64 * Betree_message_t) n0 msgs_right;
- if len_right s>= params.(Betree_params_min_flush_size)
+ len_right <- betree_List_len (u64 * betree_Message_t) n0 msgs_right;
+ if len_right s>= params.(betree_Params_min_flush_size)
then (
p2 <-
- betree_node_apply_messages_fwd n0 self.(Betree_internal_right) params
+ betree_Node_apply_messages n0 self.(betree_Internal_right) params
node_id_cnt0 msgs_right st0;
let (st1, _) := p2 in
_ <-
- betree_node_apply_messages_back n0 self.(Betree_internal_right)
+ betree_Node_apply_messages_back n0 self.(betree_Internal_right)
params node_id_cnt0 msgs_right st0;
- Return (st1, BetreeListNil))
+ Return (st1, Betree_List_Nil))
else Return (st0, msgs_right))
else (
p0 <-
- betree_node_apply_messages_fwd n0 self.(Betree_internal_right) params
+ betree_Node_apply_messages n0 self.(betree_Internal_right) params
node_id_cnt msgs_right st;
let (st0, _) := p0 in
_ <-
- betree_node_apply_messages_back n0 self.(Betree_internal_right) params
+ betree_Node_apply_messages_back n0 self.(betree_Internal_right) params
node_id_cnt msgs_right st;
Return (st0, msgs_left))
end
(** [betree_main::betree::Internal::{4}::flush]: backward function 0 *)
-with betree_internal_flush_back
- (n : nat) (self : Betree_internal_t) (params : Betree_params_t)
- (node_id_cnt : Betree_node_id_counter_t)
- (content : Betree_list_t (u64 * Betree_message_t)) (st : state) :
- result (Betree_internal_t * Betree_node_id_counter_t)
+with betree_Internal_flush_back
+ (n : nat) (self : betree_Internal_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 * betree_Message_t)) (st : state) :
+ result (betree_Internal_t * betree_NodeIdCounter_t)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
p <-
- betree_list_partition_at_pivot_fwd Betree_message_t n0 content
- self.(Betree_internal_pivot);
+ betree_List_partition_at_pivot betree_Message_t n0 content
+ self.(betree_Internal_pivot);
let (msgs_left, msgs_right) := p in
- len_left <- betree_list_len_fwd (u64 * Betree_message_t) n0 msgs_left;
- if len_left s>= params.(Betree_params_min_flush_size)
+ len_left <- betree_List_len (u64 * betree_Message_t) n0 msgs_left;
+ if len_left s>= params.(betree_Params_min_flush_size)
then (
p0 <-
- betree_node_apply_messages_fwd n0 self.(Betree_internal_left) params
+ betree_Node_apply_messages n0 self.(betree_Internal_left) params
node_id_cnt msgs_left st;
let (st0, _) := p0 in
p1 <-
- betree_node_apply_messages_back n0 self.(Betree_internal_left) params
+ betree_Node_apply_messages_back n0 self.(betree_Internal_left) params
node_id_cnt msgs_left st;
let (n1, node_id_cnt0) := p1 in
- len_right <- betree_list_len_fwd (u64 * Betree_message_t) n0 msgs_right;
- if len_right s>= params.(Betree_params_min_flush_size)
+ len_right <- betree_List_len (u64 * betree_Message_t) n0 msgs_right;
+ if len_right s>= params.(betree_Params_min_flush_size)
then (
p2 <-
- betree_node_apply_messages_back n0 self.(Betree_internal_right)
+ betree_Node_apply_messages_back n0 self.(betree_Internal_right)
params node_id_cnt0 msgs_right st0;
let (n2, node_id_cnt1) := p2 in
- Return (mkBetree_internal_t self.(Betree_internal_id)
- self.(Betree_internal_pivot) n1 n2, node_id_cnt1))
+ Return (mkbetree_Internal_t self.(betree_Internal_id)
+ self.(betree_Internal_pivot) n1 n2, node_id_cnt1))
else
- Return (mkBetree_internal_t self.(Betree_internal_id)
- self.(Betree_internal_pivot) n1 self.(Betree_internal_right),
+ Return (mkbetree_Internal_t self.(betree_Internal_id)
+ self.(betree_Internal_pivot) n1 self.(betree_Internal_right),
node_id_cnt0))
else (
p0 <-
- betree_node_apply_messages_back n0 self.(Betree_internal_right) params
+ betree_Node_apply_messages_back n0 self.(betree_Internal_right) params
node_id_cnt msgs_right st;
let (n1, node_id_cnt0) := p0 in
- Return (mkBetree_internal_t self.(Betree_internal_id)
- self.(Betree_internal_pivot) self.(Betree_internal_left) n1,
+ Return (mkbetree_Internal_t self.(betree_Internal_id)
+ self.(betree_Internal_pivot) self.(betree_Internal_left) n1,
node_id_cnt0))
end
(** [betree_main::betree::Node::{5}::apply_messages]: forward function *)
-with betree_node_apply_messages_fwd
- (n : nat) (self : Betree_node_t) (params : Betree_params_t)
- (node_id_cnt : Betree_node_id_counter_t)
- (msgs : Betree_list_t (u64 * Betree_message_t)) (st : state) :
+with betree_Node_apply_messages
+ (n : nat) (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 * betree_Message_t)) (st : state) :
result (state * unit)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match self with
- | BetreeNodeInternal node =>
- p <- betree_load_internal_node_fwd node.(Betree_internal_id) st;
+ | Betree_Node_Internal node =>
+ p <- betree_load_internal_node node.(betree_Internal_id) st;
let (st0, content) := p in
- content0 <-
- betree_node_apply_messages_to_internal_fwd_back n0 content msgs;
- num_msgs <- betree_list_len_fwd (u64 * Betree_message_t) n0 content0;
- if num_msgs s>= params.(Betree_params_min_flush_size)
+ content0 <- betree_Node_apply_messages_to_internal n0 content msgs;
+ num_msgs <- betree_List_len (u64 * betree_Message_t) n0 content0;
+ if num_msgs s>= params.(betree_Params_min_flush_size)
then (
- p0 <-
- betree_internal_flush_fwd n0 node params node_id_cnt content0 st0;
+ p0 <- betree_Internal_flush n0 node params node_id_cnt content0 st0;
let (st1, content1) := p0 in
p1 <-
- betree_internal_flush_back n0 node params node_id_cnt content0 st0;
+ betree_Internal_flush_back n0 node params node_id_cnt content0 st0;
let (node0, _) := p1 in
p2 <-
- betree_store_internal_node_fwd node0.(Betree_internal_id) content1
- st1;
+ betree_store_internal_node node0.(betree_Internal_id) content1 st1;
let (st2, _) := p2 in
Return (st2, tt))
else (
p0 <-
- betree_store_internal_node_fwd node.(Betree_internal_id) content0 st0;
+ betree_store_internal_node node.(betree_Internal_id) content0 st0;
let (st1, _) := p0 in
Return (st1, tt))
- | BetreeNodeLeaf node =>
- p <- betree_load_leaf_node_fwd node.(Betree_leaf_id) st;
+ | Betree_Node_Leaf node =>
+ p <- betree_load_leaf_node node.(betree_Leaf_id) st;
let (st0, content) := p in
- content0 <- betree_node_apply_messages_to_leaf_fwd_back n0 content msgs;
- len <- betree_list_len_fwd (u64 * u64) n0 content0;
- i <- u64_mul 2%u64 params.(Betree_params_split_size);
+ content0 <- betree_Node_apply_messages_to_leaf n0 content msgs;
+ len <- betree_List_len (u64 * u64) n0 content0;
+ i <- u64_mul 2%u64 params.(betree_Params_split_size);
if len s>= i
then (
- p0 <- betree_leaf_split_fwd n0 node content0 params node_id_cnt st0;
+ p0 <- betree_Leaf_split n0 node content0 params node_id_cnt st0;
let (st1, _) := p0 in
- p1 <-
- betree_store_leaf_node_fwd node.(Betree_leaf_id) BetreeListNil st1;
+ p1 <- betree_store_leaf_node node.(betree_Leaf_id) Betree_List_Nil st1;
let (st2, _) := p1 in
Return (st2, tt))
else (
- p0 <- betree_store_leaf_node_fwd node.(Betree_leaf_id) content0 st0;
+ p0 <- betree_store_leaf_node node.(betree_Leaf_id) content0 st0;
let (st1, _) := p0 in
Return (st1, tt))
end
end
(** [betree_main::betree::Node::{5}::apply_messages]: backward function 0 *)
-with betree_node_apply_messages_back
- (n : nat) (self : Betree_node_t) (params : Betree_params_t)
- (node_id_cnt : Betree_node_id_counter_t)
- (msgs : Betree_list_t (u64 * Betree_message_t)) (st : state) :
- result (Betree_node_t * Betree_node_id_counter_t)
+with betree_Node_apply_messages_back
+ (n : nat) (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 * betree_Message_t)) (st : state) :
+ result (betree_Node_t * betree_NodeIdCounter_t)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match self with
- | BetreeNodeInternal node =>
- p <- betree_load_internal_node_fwd node.(Betree_internal_id) st;
+ | Betree_Node_Internal node =>
+ p <- betree_load_internal_node node.(betree_Internal_id) st;
let (st0, content) := p in
- content0 <-
- betree_node_apply_messages_to_internal_fwd_back n0 content msgs;
- num_msgs <- betree_list_len_fwd (u64 * Betree_message_t) n0 content0;
- if num_msgs s>= params.(Betree_params_min_flush_size)
+ content0 <- betree_Node_apply_messages_to_internal n0 content msgs;
+ num_msgs <- betree_List_len (u64 * betree_Message_t) n0 content0;
+ if num_msgs s>= params.(betree_Params_min_flush_size)
then (
- p0 <-
- betree_internal_flush_fwd n0 node params node_id_cnt content0 st0;
+ p0 <- betree_Internal_flush n0 node params node_id_cnt content0 st0;
let (st1, content1) := p0 in
p1 <-
- betree_internal_flush_back n0 node params node_id_cnt content0 st0;
+ betree_Internal_flush_back n0 node params node_id_cnt content0 st0;
let (node0, node_id_cnt0) := p1 in
_ <-
- betree_store_internal_node_fwd node0.(Betree_internal_id) content1
- st1;
- Return (BetreeNodeInternal node0, node_id_cnt0))
+ betree_store_internal_node node0.(betree_Internal_id) content1 st1;
+ Return (Betree_Node_Internal node0, node_id_cnt0))
else (
- _ <-
- betree_store_internal_node_fwd node.(Betree_internal_id) content0 st0;
- Return (BetreeNodeInternal node, node_id_cnt))
- | BetreeNodeLeaf node =>
- p <- betree_load_leaf_node_fwd node.(Betree_leaf_id) st;
+ _ <- betree_store_internal_node node.(betree_Internal_id) content0 st0;
+ Return (Betree_Node_Internal node, node_id_cnt))
+ | Betree_Node_Leaf node =>
+ p <- betree_load_leaf_node node.(betree_Leaf_id) st;
let (st0, content) := p in
- content0 <- betree_node_apply_messages_to_leaf_fwd_back n0 content msgs;
- len <- betree_list_len_fwd (u64 * u64) n0 content0;
- i <- u64_mul 2%u64 params.(Betree_params_split_size);
+ content0 <- betree_Node_apply_messages_to_leaf n0 content msgs;
+ len <- betree_List_len (u64 * u64) n0 content0;
+ i <- u64_mul 2%u64 params.(betree_Params_split_size);
if len s>= i
then (
- p0 <- betree_leaf_split_fwd n0 node content0 params node_id_cnt st0;
+ p0 <- betree_Leaf_split n0 node content0 params node_id_cnt st0;
let (st1, new_node) := p0 in
- _ <-
- betree_store_leaf_node_fwd node.(Betree_leaf_id) BetreeListNil st1;
+ _ <- betree_store_leaf_node node.(betree_Leaf_id) Betree_List_Nil st1;
node_id_cnt0 <-
- betree_leaf_split_back n0 node content0 params node_id_cnt st0;
- Return (BetreeNodeInternal new_node, node_id_cnt0))
+ betree_Leaf_split_back n0 node content0 params node_id_cnt st0;
+ Return (Betree_Node_Internal new_node, node_id_cnt0))
else (
- _ <- betree_store_leaf_node_fwd node.(Betree_leaf_id) content0 st0;
- Return (BetreeNodeLeaf
- {| Betree_leaf_id := node.(Betree_leaf_id); Betree_leaf_size := len
+ _ <- betree_store_leaf_node node.(betree_Leaf_id) content0 st0;
+ Return (Betree_Node_Leaf
+ {| betree_Leaf_id := node.(betree_Leaf_id); betree_Leaf_size := len
|}, node_id_cnt))
end
end
.
(** [betree_main::betree::Node::{5}::apply]: forward function *)
-Definition betree_node_apply_fwd
- (n : nat) (self : Betree_node_t) (params : Betree_params_t)
- (node_id_cnt : Betree_node_id_counter_t) (key : u64)
- (new_msg : Betree_message_t) (st : state) :
+Definition betree_Node_apply
+ (n : nat) (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t) (key : u64)
+ (new_msg : betree_Message_t) (st : state) :
result (state * unit)
:=
- let l := BetreeListNil in
+ let l := Betree_List_Nil in
p <-
- betree_node_apply_messages_fwd n self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages n self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st;
let (st0, _) := p in
_ <-
- betree_node_apply_messages_back n self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages_back n self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st;
Return (st0, tt)
.
(** [betree_main::betree::Node::{5}::apply]: backward function 0 *)
-Definition betree_node_apply_back
- (n : nat) (self : Betree_node_t) (params : Betree_params_t)
- (node_id_cnt : Betree_node_id_counter_t) (key : u64)
- (new_msg : Betree_message_t) (st : state) :
- result (Betree_node_t * Betree_node_id_counter_t)
+Definition betree_Node_apply_back
+ (n : nat) (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t) (key : u64)
+ (new_msg : betree_Message_t) (st : state) :
+ result (betree_Node_t * betree_NodeIdCounter_t)
:=
- let l := BetreeListNil in
- betree_node_apply_messages_back n self params node_id_cnt (BetreeListCons
+ let l := Betree_List_Nil in
+ betree_Node_apply_messages_back n self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st
.
(** [betree_main::betree::BeTree::{6}::new]: forward function *)
-Definition betree_be_tree_new_fwd
+Definition betree_BeTree_new
(min_flush_size : u64) (split_size : u64) (st : state) :
- result (state * Betree_be_tree_t)
+ result (state * betree_BeTree_t)
:=
- node_id_cnt <- betree_node_id_counter_new_fwd;
- id <- betree_node_id_counter_fresh_id_fwd node_id_cnt;
- p <- betree_store_leaf_node_fwd id BetreeListNil st;
+ node_id_cnt <- betree_NodeIdCounter_new;
+ id <- betree_NodeIdCounter_fresh_id node_id_cnt;
+ p <- betree_store_leaf_node id Betree_List_Nil st;
let (st0, _) := p in
- node_id_cnt0 <- betree_node_id_counter_fresh_id_back node_id_cnt;
+ node_id_cnt0 <- betree_NodeIdCounter_fresh_id_back node_id_cnt;
Return (st0,
{|
- Betree_be_tree_params :=
+ betree_BeTree_params :=
{|
- Betree_params_min_flush_size := min_flush_size;
- Betree_params_split_size := split_size
+ betree_Params_min_flush_size := min_flush_size;
+ betree_Params_split_size := split_size
|};
- Betree_be_tree_node_id_cnt := node_id_cnt0;
- Betree_be_tree_root :=
- (BetreeNodeLeaf {| Betree_leaf_id := id; Betree_leaf_size := 0%u64 |})
+ betree_BeTree_node_id_cnt := node_id_cnt0;
+ betree_BeTree_root :=
+ (Betree_Node_Leaf
+ {| betree_Leaf_id := id; betree_Leaf_size := 0%u64 |})
|})
.
(** [betree_main::betree::BeTree::{6}::apply]: forward function *)
-Definition betree_be_tree_apply_fwd
- (n : nat) (self : Betree_be_tree_t) (key : u64) (msg : Betree_message_t)
+Definition betree_BeTree_apply
+ (n : nat) (self : betree_BeTree_t) (key : u64) (msg : betree_Message_t)
(st : state) :
result (state * unit)
:=
p <-
- betree_node_apply_fwd n self.(Betree_be_tree_root)
- self.(Betree_be_tree_params) self.(Betree_be_tree_node_id_cnt) key msg st;
+ betree_Node_apply n self.(betree_BeTree_root) self.(betree_BeTree_params)
+ self.(betree_BeTree_node_id_cnt) key msg st;
let (st0, _) := p in
_ <-
- betree_node_apply_back n self.(Betree_be_tree_root)
- self.(Betree_be_tree_params) self.(Betree_be_tree_node_id_cnt) key msg st;
+ betree_Node_apply_back n self.(betree_BeTree_root)
+ self.(betree_BeTree_params) self.(betree_BeTree_node_id_cnt) key msg st;
Return (st0, tt)
.
(** [betree_main::betree::BeTree::{6}::apply]: backward function 0 *)
-Definition betree_be_tree_apply_back
- (n : nat) (self : Betree_be_tree_t) (key : u64) (msg : Betree_message_t)
+Definition betree_BeTree_apply_back
+ (n : nat) (self : betree_BeTree_t) (key : u64) (msg : betree_Message_t)
(st : state) :
- result Betree_be_tree_t
+ result betree_BeTree_t
:=
p <-
- betree_node_apply_back n self.(Betree_be_tree_root)
- self.(Betree_be_tree_params) self.(Betree_be_tree_node_id_cnt) key msg st;
+ betree_Node_apply_back n self.(betree_BeTree_root)
+ self.(betree_BeTree_params) self.(betree_BeTree_node_id_cnt) key msg st;
let (n0, nic) := p in
Return
{|
- Betree_be_tree_params := self.(Betree_be_tree_params);
- Betree_be_tree_node_id_cnt := nic;
- Betree_be_tree_root := n0
+ betree_BeTree_params := self.(betree_BeTree_params);
+ betree_BeTree_node_id_cnt := nic;
+ betree_BeTree_root := n0
|}
.
(** [betree_main::betree::BeTree::{6}::insert]: forward function *)
-Definition betree_be_tree_insert_fwd
- (n : nat) (self : Betree_be_tree_t) (key : u64) (value : u64) (st : state) :
+Definition betree_BeTree_insert
+ (n : nat) (self : betree_BeTree_t) (key : u64) (value : u64) (st : state) :
result (state * unit)
:=
- p <- betree_be_tree_apply_fwd n self key (BetreeMessageInsert value) st;
+ p <- betree_BeTree_apply n self key (Betree_Message_Insert value) st;
let (st0, _) := p in
- _ <- betree_be_tree_apply_back n self key (BetreeMessageInsert value) st;
+ _ <- betree_BeTree_apply_back n self key (Betree_Message_Insert value) st;
Return (st0, tt)
.
(** [betree_main::betree::BeTree::{6}::insert]: backward function 0 *)
-Definition betree_be_tree_insert_back
- (n : nat) (self : Betree_be_tree_t) (key : u64) (value : u64) (st : state) :
- result Betree_be_tree_t
+Definition betree_BeTree_insert_back
+ (n : nat) (self : betree_BeTree_t) (key : u64) (value : u64) (st : state) :
+ result betree_BeTree_t
:=
- betree_be_tree_apply_back n self key (BetreeMessageInsert value) st
+ betree_BeTree_apply_back n self key (Betree_Message_Insert value) st
.
(** [betree_main::betree::BeTree::{6}::delete]: forward function *)
-Definition betree_be_tree_delete_fwd
- (n : nat) (self : Betree_be_tree_t) (key : u64) (st : state) :
+Definition betree_BeTree_delete
+ (n : nat) (self : betree_BeTree_t) (key : u64) (st : state) :
result (state * unit)
:=
- p <- betree_be_tree_apply_fwd n self key BetreeMessageDelete st;
+ p <- betree_BeTree_apply n self key Betree_Message_Delete st;
let (st0, _) := p in
- _ <- betree_be_tree_apply_back n self key BetreeMessageDelete st;
+ _ <- betree_BeTree_apply_back n self key Betree_Message_Delete st;
Return (st0, tt)
.
(** [betree_main::betree::BeTree::{6}::delete]: backward function 0 *)
-Definition betree_be_tree_delete_back
- (n : nat) (self : Betree_be_tree_t) (key : u64) (st : state) :
- result Betree_be_tree_t
+Definition betree_BeTree_delete_back
+ (n : nat) (self : betree_BeTree_t) (key : u64) (st : state) :
+ result betree_BeTree_t
:=
- betree_be_tree_apply_back n self key BetreeMessageDelete st
+ betree_BeTree_apply_back n self key Betree_Message_Delete st
.
(** [betree_main::betree::BeTree::{6}::upsert]: forward function *)
-Definition betree_be_tree_upsert_fwd
- (n : nat) (self : Betree_be_tree_t) (key : u64)
- (upd : Betree_upsert_fun_state_t) (st : state) :
+Definition betree_BeTree_upsert
+ (n : nat) (self : betree_BeTree_t) (key : u64)
+ (upd : betree_UpsertFunState_t) (st : state) :
result (state * unit)
:=
- p <- betree_be_tree_apply_fwd n self key (BetreeMessageUpsert upd) st;
+ p <- betree_BeTree_apply n self key (Betree_Message_Upsert upd) st;
let (st0, _) := p in
- _ <- betree_be_tree_apply_back n self key (BetreeMessageUpsert upd) st;
+ _ <- betree_BeTree_apply_back n self key (Betree_Message_Upsert upd) st;
Return (st0, tt)
.
(** [betree_main::betree::BeTree::{6}::upsert]: backward function 0 *)
-Definition betree_be_tree_upsert_back
- (n : nat) (self : Betree_be_tree_t) (key : u64)
- (upd : Betree_upsert_fun_state_t) (st : state) :
- result Betree_be_tree_t
+Definition betree_BeTree_upsert_back
+ (n : nat) (self : betree_BeTree_t) (key : u64)
+ (upd : betree_UpsertFunState_t) (st : state) :
+ result betree_BeTree_t
:=
- betree_be_tree_apply_back n self key (BetreeMessageUpsert upd) st
+ betree_BeTree_apply_back n self key (Betree_Message_Upsert upd) st
.
(** [betree_main::betree::BeTree::{6}::lookup]: forward function *)
-Definition betree_be_tree_lookup_fwd
- (n : nat) (self : Betree_be_tree_t) (key : u64) (st : state) :
+Definition betree_BeTree_lookup
+ (n : nat) (self : betree_BeTree_t) (key : u64) (st : state) :
result (state * (option u64))
:=
- betree_node_lookup_fwd n self.(Betree_be_tree_root) key st
+ betree_Node_lookup n self.(betree_BeTree_root) key st
.
(** [betree_main::betree::BeTree::{6}::lookup]: backward function 0 *)
-Definition betree_be_tree_lookup_back
- (n : nat) (self : Betree_be_tree_t) (key : u64) (st : state) :
- result Betree_be_tree_t
+Definition betree_BeTree_lookup_back
+ (n : nat) (self : betree_BeTree_t) (key : u64) (st : state) :
+ result betree_BeTree_t
:=
- n0 <- betree_node_lookup_back n self.(Betree_be_tree_root) key st;
+ n0 <- betree_Node_lookup_back n self.(betree_BeTree_root) key st;
Return
{|
- Betree_be_tree_params := self.(Betree_be_tree_params);
- Betree_be_tree_node_id_cnt := self.(Betree_be_tree_node_id_cnt);
- Betree_be_tree_root := n0
+ betree_BeTree_params := self.(betree_BeTree_params);
+ betree_BeTree_node_id_cnt := self.(betree_BeTree_node_id_cnt);
+ betree_BeTree_root := n0
|}
.
(** [betree_main::main]: forward function *)
-Definition main_fwd : result unit :=
+Definition main : result unit :=
Return tt.
(** Unit test for [betree_main::main] *)
-Check (main_fwd )%return.
+Check (main )%return.
End BetreeMain_Funs .
diff --git a/tests/coq/betree/BetreeMain_Opaque.v b/tests/coq/betree/BetreeMain_Opaque.v
index ecd81b9d..eade90de 100644
--- a/tests/coq/betree/BetreeMain_Opaque.v
+++ b/tests/coq/betree/BetreeMain_Opaque.v
@@ -11,29 +11,29 @@ Import BetreeMain_Types.
Module BetreeMain_Opaque.
(** [betree_main::betree_utils::load_internal_node]: forward function *)
-Axiom betree_utils_load_internal_node_fwd
- : u64 -> state -> result (state * (Betree_list_t (u64 * Betree_message_t)))
+Axiom betree_utils_load_internal_node
+ : u64 -> state -> result (state * (betree_List_t (u64 * betree_Message_t)))
.
(** [betree_main::betree_utils::store_internal_node]: forward function *)
-Axiom betree_utils_store_internal_node_fwd
+Axiom betree_utils_store_internal_node
:
- u64 -> Betree_list_t (u64 * Betree_message_t) -> state -> result (state *
+ u64 -> betree_List_t (u64 * betree_Message_t) -> state -> result (state *
unit)
.
(** [betree_main::betree_utils::load_leaf_node]: forward function *)
-Axiom betree_utils_load_leaf_node_fwd
- : u64 -> state -> result (state * (Betree_list_t (u64 * u64)))
+Axiom betree_utils_load_leaf_node
+ : u64 -> state -> result (state * (betree_List_t (u64 * u64)))
.
(** [betree_main::betree_utils::store_leaf_node]: forward function *)
-Axiom betree_utils_store_leaf_node_fwd
- : u64 -> Betree_list_t (u64 * u64) -> state -> result (state * unit)
+Axiom betree_utils_store_leaf_node
+ : u64 -> betree_List_t (u64 * u64) -> state -> result (state * unit)
.
(** [core::option::Option::{0}::unwrap]: forward function *)
-Axiom core_option_option_unwrap_fwd :
+Axiom core_option_Option_unwrap :
forall(T : Type), option T -> state -> result (state * T)
.
diff --git a/tests/coq/betree/BetreeMain_Types.v b/tests/coq/betree/BetreeMain_Types.v
index 4a4e75aa..933a670c 100644
--- a/tests/coq/betree/BetreeMain_Types.v
+++ b/tests/coq/betree/BetreeMain_Types.v
@@ -9,98 +9,98 @@ Local Open Scope Primitives_scope.
Module BetreeMain_Types.
(** [betree_main::betree::List] *)
-Inductive Betree_list_t (T : Type) :=
-| BetreeListCons : T -> Betree_list_t T -> Betree_list_t T
-| BetreeListNil : Betree_list_t T
+Inductive betree_List_t (T : Type) :=
+| Betree_List_Cons : T -> betree_List_t T -> betree_List_t T
+| Betree_List_Nil : betree_List_t T
.
-Arguments BetreeListCons {T} _ _.
-Arguments BetreeListNil {T}.
+Arguments Betree_List_Cons { _ }.
+Arguments Betree_List_Nil { _ }.
(** [betree_main::betree::UpsertFunState] *)
-Inductive Betree_upsert_fun_state_t :=
-| BetreeUpsertFunStateAdd : u64 -> Betree_upsert_fun_state_t
-| BetreeUpsertFunStateSub : u64 -> Betree_upsert_fun_state_t
+Inductive betree_UpsertFunState_t :=
+| Betree_UpsertFunState_Add : u64 -> betree_UpsertFunState_t
+| Betree_UpsertFunState_Sub : u64 -> betree_UpsertFunState_t
.
(** [betree_main::betree::Message] *)
-Inductive Betree_message_t :=
-| BetreeMessageInsert : u64 -> Betree_message_t
-| BetreeMessageDelete : Betree_message_t
-| BetreeMessageUpsert : Betree_upsert_fun_state_t -> Betree_message_t
+Inductive betree_Message_t :=
+| Betree_Message_Insert : u64 -> betree_Message_t
+| Betree_Message_Delete : betree_Message_t
+| Betree_Message_Upsert : betree_UpsertFunState_t -> betree_Message_t
.
(** [betree_main::betree::Leaf] *)
-Record Betree_leaf_t :=
-mkBetree_leaf_t {
- Betree_leaf_id : u64; Betree_leaf_size : u64;
+Record betree_Leaf_t :=
+mkbetree_Leaf_t {
+ betree_Leaf_id : u64; betree_Leaf_size : u64;
}
.
(** [betree_main::betree::Internal] *)
-Inductive Betree_internal_t :=
-| mkBetree_internal_t :
+Inductive betree_Internal_t :=
+| mkbetree_Internal_t :
u64 ->
u64 ->
- Betree_node_t ->
- Betree_node_t ->
- Betree_internal_t
+ betree_Node_t ->
+ betree_Node_t ->
+ betree_Internal_t
(** [betree_main::betree::Node] *)
-with Betree_node_t :=
-| BetreeNodeInternal : Betree_internal_t -> Betree_node_t
-| BetreeNodeLeaf : Betree_leaf_t -> Betree_node_t
+with betree_Node_t :=
+| Betree_Node_Internal : betree_Internal_t -> betree_Node_t
+| Betree_Node_Leaf : betree_Leaf_t -> betree_Node_t
.
-Definition Betree_internal_id (x : Betree_internal_t) :=
- match x with | mkBetree_internal_t x0 _ _ _ => x0 end
+Definition betree_Internal_id (x : betree_Internal_t) :=
+ match x with | mkbetree_Internal_t x0 _ _ _ => x0 end
.
-Notation "x1 .(Betree_internal_id)" := (Betree_internal_id x1) (at level 9).
+Notation "x1 .(betree_Internal_id)" := (betree_Internal_id x1) (at level 9).
-Definition Betree_internal_pivot (x : Betree_internal_t) :=
- match x with | mkBetree_internal_t _ x0 _ _ => x0 end
+Definition betree_Internal_pivot (x : betree_Internal_t) :=
+ match x with | mkbetree_Internal_t _ x0 _ _ => x0 end
.
-Notation "x1 .(Betree_internal_pivot)" := (Betree_internal_pivot x1)
+Notation "x1 .(betree_Internal_pivot)" := (betree_Internal_pivot x1)
(at level 9)
.
-Definition Betree_internal_left (x : Betree_internal_t) :=
- match x with | mkBetree_internal_t _ _ x0 _ => x0 end
+Definition betree_Internal_left (x : betree_Internal_t) :=
+ match x with | mkbetree_Internal_t _ _ x0 _ => x0 end
.
-Notation "x1 .(Betree_internal_left)" := (Betree_internal_left x1) (at level 9)
+Notation "x1 .(betree_Internal_left)" := (betree_Internal_left x1) (at level 9)
.
-Definition Betree_internal_right (x : Betree_internal_t) :=
- match x with | mkBetree_internal_t _ _ _ x0 => x0 end
+Definition betree_Internal_right (x : betree_Internal_t) :=
+ match x with | mkbetree_Internal_t _ _ _ x0 => x0 end
.
-Notation "x1 .(Betree_internal_right)" := (Betree_internal_right x1)
+Notation "x1 .(betree_Internal_right)" := (betree_Internal_right x1)
(at level 9)
.
(** [betree_main::betree::Params] *)
-Record Betree_params_t :=
-mkBetree_params_t {
- Betree_params_min_flush_size : u64; Betree_params_split_size : u64;
+Record betree_Params_t :=
+mkbetree_Params_t {
+ betree_Params_min_flush_size : u64; betree_Params_split_size : u64;
}
.
(** [betree_main::betree::NodeIdCounter] *)
-Record Betree_node_id_counter_t :=
-mkBetree_node_id_counter_t {
- Betree_node_id_counter_next_node_id : u64;
+Record betree_NodeIdCounter_t :=
+mkbetree_NodeIdCounter_t {
+ betree_NodeIdCounter_next_node_id : u64;
}
.
(** [betree_main::betree::BeTree] *)
-Record Betree_be_tree_t :=
-mkBetree_be_tree_t {
- Betree_be_tree_params : Betree_params_t;
- Betree_be_tree_node_id_cnt : Betree_node_id_counter_t;
- Betree_be_tree_root : Betree_node_t;
+Record betree_BeTree_t :=
+mkbetree_BeTree_t {
+ betree_BeTree_params : betree_Params_t;
+ betree_BeTree_node_id_cnt : betree_NodeIdCounter_t;
+ betree_BeTree_root : betree_Node_t;
}
.
diff --git a/tests/coq/betree/Primitives.v b/tests/coq/betree/Primitives.v
index 71a2d9c3..85e38f01 100644
--- a/tests/coq/betree/Primitives.v
+++ b/tests/coq/betree/Primitives.v
@@ -63,13 +63,15 @@ Check (if true then Return (1 + 2) else Fail_ Failure)%global = 3.
(*** Misc *)
-
Definition string := Coq.Strings.String.string.
Definition char := Coq.Strings.Ascii.ascii.
Definition char_of_byte := Coq.Strings.Ascii.ascii_of_byte.
-Definition mem_replace_fwd (a : Type) (x : a) (y : a) : a := x .
-Definition mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+Definition core_mem_replace (a : Type) (x : a) (y : a) : a := x .
+Definition core_mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+
+Record mut_raw_ptr (T : Type) := { mut_raw_ptr_v : T }.
+Record const_raw_ptr (T : Type) := { const_raw_ptr_v : T }.
(*** Scalars *)
@@ -394,12 +396,89 @@ Notation "x s< y" := (scalar_ltb x y) (at level 80) : Primitives_scope.
Notation "x s>= y" := (scalar_geb x y) (at level 80) : Primitives_scope.
Notation "x s> y" := (scalar_gtb x y) (at level 80) : Primitives_scope.
-(*** Range *)
-Record range (T : Type) := mk_range {
- start: T;
- end_: T;
+(** Constants *)
+Definition core_u8_max := u8_max %u32.
+Definition core_u16_max := u16_max %u32.
+Definition core_u32_max := u32_max %u32.
+Definition core_u64_max := u64_max %u64.
+Definition core_u128_max := u64_max %u128.
+Axiom core_usize_max : usize. (** TODO *)
+Definition core_i8_max := i8_max %i32.
+Definition core_i16_max := i16_max %i32.
+Definition core_i32_max := i32_max %i32.
+Definition core_i64_max := i64_max %i64.
+Definition core_i128_max := i64_max %i128.
+Axiom core_isize_max : isize. (** TODO *)
+
+(*** core::ops *)
+
+(* Trait declaration: [core::ops::index::Index] *)
+Record core_ops_index_Index (Self Idx : Type) := mk_core_ops_index_Index {
+ core_ops_index_Index_Output : Type;
+ core_ops_index_Index_index : Self -> Idx -> result core_ops_index_Index_Output;
+}.
+Arguments mk_core_ops_index_Index {_ _}.
+Arguments core_ops_index_Index_Output {_ _}.
+Arguments core_ops_index_Index_index {_ _}.
+
+(* Trait declaration: [core::ops::index::IndexMut] *)
+Record core_ops_index_IndexMut (Self Idx : Type) := mk_core_ops_index_IndexMut {
+ core_ops_index_IndexMut_indexInst : core_ops_index_Index Self Idx;
+ core_ops_index_IndexMut_index_mut : Self -> Idx -> result core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output);
+ core_ops_index_IndexMut_index_mut_back : Self -> Idx -> core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output) -> result Self;
+}.
+Arguments mk_core_ops_index_IndexMut {_ _}.
+Arguments core_ops_index_IndexMut_indexInst {_ _}.
+Arguments core_ops_index_IndexMut_index_mut {_ _}.
+Arguments core_ops_index_IndexMut_index_mut_back {_ _}.
+
+(* Trait declaration [core::ops::deref::Deref] *)
+Record core_ops_deref_Deref (Self : Type) := mk_core_ops_deref_Deref {
+ core_ops_deref_Deref_target : Type;
+ core_ops_deref_Deref_deref : Self -> result core_ops_deref_Deref_target;
+}.
+Arguments mk_core_ops_deref_Deref {_}.
+Arguments core_ops_deref_Deref_target {_}.
+Arguments core_ops_deref_Deref_deref {_}.
+
+(* Trait declaration [core::ops::deref::DerefMut] *)
+Record core_ops_deref_DerefMut (Self : Type) := mk_core_ops_deref_DerefMut {
+ core_ops_deref_DerefMut_derefInst : core_ops_deref_Deref Self;
+ core_ops_deref_DerefMut_deref_mut : Self -> result core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target);
+ core_ops_deref_DerefMut_deref_mut_back : Self -> core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target) -> result Self;
}.
-Arguments mk_range {_}.
+Arguments mk_core_ops_deref_DerefMut {_}.
+Arguments core_ops_deref_DerefMut_derefInst {_}.
+Arguments core_ops_deref_DerefMut_deref_mut {_}.
+Arguments core_ops_deref_DerefMut_deref_mut_back {_}.
+
+Record core_ops_range_Range (T : Type) := mk_core_ops_range_Range {
+ core_ops_range_Range_start : T;
+ core_ops_range_Range_end_ : T;
+}.
+Arguments mk_core_ops_range_Range {_}.
+Arguments core_ops_range_Range_start {_}.
+Arguments core_ops_range_Range_end_ {_}.
+
+(*** [alloc] *)
+
+Definition alloc_boxed_Box_deref (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut_back (T : Type) (_ : T) (x : T) : result T := Return x.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefInst (Self : Type) : core_ops_deref_Deref Self := {|
+ core_ops_deref_Deref_target := Self;
+ core_ops_deref_Deref_deref := alloc_boxed_Box_deref Self;
+|}.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefMutInst (Self : Type) : core_ops_deref_DerefMut Self := {|
+ core_ops_deref_DerefMut_derefInst := alloc_boxed_Box_coreOpsDerefInst Self;
+ core_ops_deref_DerefMut_deref_mut := alloc_boxed_Box_deref_mut Self;
+ core_ops_deref_DerefMut_deref_mut_back := alloc_boxed_Box_deref_mut_back Self;
+|}.
+
(*** Arrays *)
Definition array T (n : usize) := { l: list T | Z.of_nat (length l) = to_Z n}.
@@ -419,51 +498,50 @@ Qed.
(* TODO: finish the definitions *)
Axiom mk_array : forall (T : Type) (n : usize) (l : list T), array T n.
-Axiom array_index_shared : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_fwd : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_back : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
+(* For initialization *)
+Axiom array_repeat : forall (T : Type) (n : usize) (x : T), array T n.
+
+Axiom array_index_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
+Axiom array_update_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
(*** Slice *)
Definition slice T := { l: list T | Z.of_nat (length l) <= usize_max}.
Axiom slice_len : forall (T : Type) (s : slice T), usize.
-Axiom slice_index_shared : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_fwd : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_back : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
+Axiom slice_index_usize : forall (T : Type) (x : slice T) (i : usize), result T.
+Axiom slice_update_usize : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
(*** Subslices *)
-Axiom array_to_slice_shared : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_fwd : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_back : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+Axiom array_to_slice : forall (T : Type) (n : usize) (x : array T n), result (slice T).
+Axiom array_from_slice : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+
+Axiom array_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize), result (slice T).
+Axiom array_update_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize) (ns : slice T), result (array T n).
-Axiom array_subslice_shared: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_fwd: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_back: forall (T : Type) (n : usize) (x : array T n) (r : range usize) (ns : slice T), result (array T n).
-Axiom slice_subslice_shared: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_fwd: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_back: forall (T : Type) (x : slice T) (r : range usize) (ns : slice T), result (slice T).
+Axiom slice_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize), result (slice T).
+Axiom slice_update_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize) (ns : slice T), result (slice T).
(*** Vectors *)
-Definition vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
+Definition alloc_vec_Vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
-Definition vec_to_list {T: Type} (v: vec T) : list T := proj1_sig v.
+Definition alloc_vec_Vec_to_list {T: Type} (v: alloc_vec_Vec T) : list T := proj1_sig v.
-Definition vec_length {T: Type} (v: vec T) : Z := Z.of_nat (length (vec_to_list v)).
+Definition alloc_vec_Vec_length {T: Type} (v: alloc_vec_Vec T) : Z := Z.of_nat (length (alloc_vec_Vec_to_list v)).
-Definition vec_new (T: Type) : vec T := (exist _ [] le_0_usize_max).
+Definition alloc_vec_Vec_new (T: Type) : alloc_vec_Vec T := (exist _ [] le_0_usize_max).
-Lemma vec_len_in_usize {T} (v: vec T) : usize_min <= vec_length v <= usize_max.
+Lemma alloc_vec_Vec_len_in_usize {T} (v: alloc_vec_Vec T) : usize_min <= alloc_vec_Vec_length v <= usize_max.
Proof.
- unfold vec_length, usize_min.
+ unfold alloc_vec_Vec_length, usize_min.
split.
- lia.
- apply (proj2_sig v).
Qed.
-Definition vec_len (T: Type) (v: vec T) : usize :=
- exist _ (vec_length v) (vec_len_in_usize v).
+Definition alloc_vec_Vec_len (T: Type) (v: alloc_vec_Vec T) : usize :=
+ exist _ (alloc_vec_Vec_length v) (alloc_vec_Vec_len_in_usize v).
Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
: list A :=
@@ -474,50 +552,271 @@ Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
| S m => x :: (list_update t m a)
end end.
-Definition vec_bind {A B} (v: vec A) (f: list A -> result (list B)) : result (vec B) :=
- l <- f (vec_to_list v) ;
+Definition alloc_vec_Vec_bind {A B} (v: alloc_vec_Vec A) (f: list A -> result (list B)) : result (alloc_vec_Vec B) :=
+ l <- f (alloc_vec_Vec_to_list v) ;
match sumbool_of_bool (scalar_le_max Usize (Z.of_nat (length l))) with
| left H => Return (exist _ l (scalar_le_max_valid _ _ H))
| right _ => Fail_ Failure
end.
(* The **forward** function shouldn't be used *)
-Definition vec_push_fwd (T: Type) (v: vec T) (x: T) : unit := tt.
+Definition alloc_vec_Vec_push_fwd (T: Type) (v: alloc_vec_Vec T) (x: T) : unit := tt.
-Definition vec_push_back (T: Type) (v: vec T) (x: T) : result (vec T) :=
- vec_bind v (fun l => Return (l ++ [x])).
+Definition alloc_vec_Vec_push (T: Type) (v: alloc_vec_Vec T) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l => Return (l ++ [x])).
(* The **forward** function shouldn't be used *)
-Definition vec_insert_fwd (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
+Definition alloc_vec_Vec_insert_fwd (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result unit :=
+ if to_Z i <? alloc_vec_Vec_length v then Return tt else Fail_ Failure.
-Definition vec_insert_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
+Definition alloc_vec_Vec_insert (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l =>
if to_Z i <? Z.of_nat (length l)
then Return (list_update l (usize_to_nat i) x)
else Fail_ Failure).
-(* The **backward** function shouldn't be used *)
-Definition vec_index_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
- end.
-
-Definition vec_index_back (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
-
-(* The **backward** function shouldn't be used *)
-Definition vec_index_mut_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
+(* Helper *)
+Axiom alloc_vec_Vec_index_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result T.
+
+(* Helper *)
+Axiom alloc_vec_Vec_update_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result (alloc_vec_Vec T).
+
+(* Trait declaration: [core::slice::index::private_slice_index::Sealed] *)
+Definition core_slice_index_private_slice_index_Sealed (self : Type) := unit.
+
+(* Trait declaration: [core::slice::index::SliceIndex] *)
+Record core_slice_index_SliceIndex (Self T : Type) := mk_core_slice_index_SliceIndex {
+ core_slice_index_SliceIndex_sealedInst : core_slice_index_private_slice_index_Sealed Self;
+ core_slice_index_SliceIndex_Output : Type;
+ core_slice_index_SliceIndex_get : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut_back : Self -> T -> option core_slice_index_SliceIndex_Output -> result T;
+ core_slice_index_SliceIndex_get_unchecked : Self -> const_raw_ptr T -> result (const_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_unchecked_mut : Self -> mut_raw_ptr T -> result (mut_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_index : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut_back : Self -> T -> core_slice_index_SliceIndex_Output -> result T;
+}.
+Arguments mk_core_slice_index_SliceIndex {_ _}.
+Arguments core_slice_index_SliceIndex_sealedInst {_ _}.
+Arguments core_slice_index_SliceIndex_Output {_ _}.
+Arguments core_slice_index_SliceIndex_get {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut_back {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut_back {_ _}.
+
+(* [core::slice::index::[T]::index]: forward function *)
+Definition core_slice_index_Slice_index
+ (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (s : slice T) (i : Idx) : result inst.(core_slice_index_SliceIndex_Output) :=
+ x <- inst.(core_slice_index_SliceIndex_get) i s;
+ match x with
+ | None => Fail_ Failure
+ | Some x => Return x
end.
-Definition vec_index_mut_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
- if to_Z i <? Z.of_nat (length l)
- then Return (list_update l (usize_to_nat i) x)
- else Fail_ Failure).
+(* [core::slice::index::Range:::get]: forward function *)
+Axiom core_slice_index_Range_get : forall (T : Type) (i : core_ops_range_Range usize) (s : slice T), result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: forward function *)
+Axiom core_slice_index_Range_get_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: backward function 0 *)
+Axiom core_slice_index_Range_get_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> option (slice T) -> result (slice T).
+
+(* [core::slice::index::Range::get_unchecked]: forward function *)
+Definition core_slice_index_Range_get_unchecked
+ (T : Type) :
+ core_ops_range_Range usize -> const_raw_ptr (slice T) -> result (const_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::get_unchecked_mut]: forward function *)
+Definition core_slice_index_Range_get_unchecked_mut
+ (T : Type) :
+ core_ops_range_Range usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::index]: forward function *)
+Axiom core_slice_index_Range_index :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: forward function *)
+Axiom core_slice_index_Range_index_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: backward function 0 *)
+Axiom core_slice_index_Range_index_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> slice T -> result (slice T).
+
+(* [core::slice::index::[T]::index_mut]: forward function *)
+Axiom core_slice_index_Slice_index_mut :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> result inst.(core_slice_index_SliceIndex_Output).
+
+(* [core::slice::index::[T]::index_mut]: backward function 0 *)
+Axiom core_slice_index_Slice_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> inst.(core_slice_index_SliceIndex_Output) -> result (slice T).
+
+(* [core::array::[T; N]::index]: forward function *)
+Axiom core_array_Array_index :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_Index (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: forward function *)
+Axiom core_array_Array_index_mut :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: backward function 0 *)
+Axiom core_array_Array_index_mut_back :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx) (x : inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output)), result (array T N).
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (slice T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := core_slice_index_Slice_index T Idx inst;
+|}.
+
+(* Trait implementation: [core::slice::index::private_slice_index::Range] *)
+Definition core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) := tt.
+
+(* Trait implementation: [core::slice::index::Range] *)
+Definition core_slice_index_Range_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := slice T;
+ core_slice_index_SliceIndex_get := core_slice_index_Range_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_Range_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_Range_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_Range_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_Range_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_Range_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_Range_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_Range_index_mut_back T;
+|}.
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (slice T) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_slice_index_Slice_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := core_slice_index_Slice_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := core_slice_index_Slice_index_mut_back T Idx inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_Index (slice T) Idx) :
+ core_ops_index_Index (array T N) Idx := {|
+ core_ops_index_Index_Output := inst.(core_ops_index_Index_Output);
+ core_ops_index_Index_index := core_array_Array_index T Idx N inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexMutInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_IndexMut (slice T) Idx) :
+ core_ops_index_IndexMut (array T N) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_array_Array_coreopsindexIndexInst T Idx N inst.(core_ops_index_IndexMut_indexInst);
+ core_ops_index_IndexMut_index_mut := core_array_Array_index_mut T Idx N inst;
+ core_ops_index_IndexMut_index_mut_back := core_array_Array_index_mut_back T Idx N inst;
+|}.
+
+(* [core::slice::index::usize::get]: forward function *)
+Axiom core_slice_index_usize_get : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: forward function *)
+Axiom core_slice_index_usize_get_mut : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: backward function 0 *)
+Axiom core_slice_index_usize_get_mut_back :
+ forall (T : Type), usize -> slice T -> option T -> result (slice T).
+
+(* [core::slice::index::usize::get_unchecked]: forward function *)
+Axiom core_slice_index_usize_get_unchecked :
+ forall (T : Type), usize -> const_raw_ptr (slice T) -> result (const_raw_ptr T).
+
+(* [core::slice::index::usize::get_unchecked_mut]: forward function *)
+Axiom core_slice_index_usize_get_unchecked_mut :
+ forall (T : Type), usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr T).
+
+(* [core::slice::index::usize::index]: forward function *)
+Axiom core_slice_index_usize_index : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: forward function *)
+Axiom core_slice_index_usize_index_mut : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: backward function 0 *)
+Axiom core_slice_index_usize_index_mut_back :
+ forall (T : Type), usize -> slice T -> T -> result (slice T).
+
+(* Trait implementation: [core::slice::index::private_slice_index::usize] *)
+Definition core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize := tt.
+
+(* Trait implementation: [core::slice::index::usize] *)
+Definition core_slice_index_usize_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex usize (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := T;
+ core_slice_index_SliceIndex_get := core_slice_index_usize_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_usize_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_usize_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_usize_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_usize_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_usize_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_usize_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_usize_index_mut_back T;
+|}.
+
+(* [alloc::vec::Vec::index]: forward function *)
+Axiom alloc_vec_Vec_index : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: forward function *)
+Axiom alloc_vec_Vec_index_mut : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: backward function 0 *)
+Axiom alloc_vec_Vec_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx) (x : inst.(core_slice_index_SliceIndex_Output)), result (alloc_vec_Vec T).
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (alloc_vec_Vec T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := alloc_vec_Vec_index T Idx inst;
+|}.
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (alloc_vec_Vec T) Idx := {|
+ core_ops_index_IndexMut_indexInst := alloc_vec_Vec_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := alloc_vec_Vec_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := alloc_vec_Vec_index_mut_back T Idx inst;
+|}.
+
+(*** Theorems *)
+
+Axiom alloc_vec_Vec_index_mut_back_eq : forall {a : Type} (v : alloc_vec_Vec a) (i : usize) (x : a),
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x =
+ alloc_vec_Vec_update_usize v i x.
End Primitives.
diff --git a/tests/coq/hashmap/Hashmap_Funs.v b/tests/coq/hashmap/Hashmap_Funs.v
index e950ba0b..3ca52a9f 100644
--- a/tests/coq/hashmap/Hashmap_Funs.v
+++ b/tests/coq/hashmap/Hashmap_Funs.v
@@ -11,98 +11,101 @@ Import Hashmap_Types.
Module Hashmap_Funs.
(** [hashmap::hash_key]: forward function *)
-Definition hash_key_fwd (k : usize) : result usize :=
+Definition hash_key (k : usize) : result usize :=
Return k.
(** [hashmap::HashMap::{0}::allocate_slots]: loop 0: forward function *)
-Fixpoint hash_map_allocate_slots_loop_fwd
- (T : Type) (n : nat) (slots : vec (List_t T)) (n0 : usize) :
- result (vec (List_t T))
+Fixpoint hashMap_allocate_slots_loop
+ (T : Type) (n : nat) (slots : alloc_vec_Vec (List_t T)) (n0 : usize) :
+ result (alloc_vec_Vec (List_t T))
:=
match n with
| O => Fail_ OutOfFuel
| S n1 =>
if n0 s> 0%usize
then (
- slots0 <- vec_push_back (List_t T) slots ListNil;
+ slots0 <- alloc_vec_Vec_push (List_t T) slots List_Nil;
n2 <- usize_sub n0 1%usize;
- hash_map_allocate_slots_loop_fwd T n1 slots0 n2)
+ hashMap_allocate_slots_loop T n1 slots0 n2)
else Return slots
end
.
(** [hashmap::HashMap::{0}::allocate_slots]: forward function *)
-Definition hash_map_allocate_slots_fwd
- (T : Type) (n : nat) (slots : vec (List_t T)) (n0 : usize) :
- result (vec (List_t T))
+Definition hashMap_allocate_slots
+ (T : Type) (n : nat) (slots : alloc_vec_Vec (List_t T)) (n0 : usize) :
+ result (alloc_vec_Vec (List_t T))
:=
- hash_map_allocate_slots_loop_fwd T n slots n0
+ hashMap_allocate_slots_loop T n slots n0
.
(** [hashmap::HashMap::{0}::new_with_capacity]: forward function *)
-Definition hash_map_new_with_capacity_fwd
+Definition hashMap_new_with_capacity
(T : Type) (n : nat) (capacity : usize) (max_load_dividend : usize)
(max_load_divisor : usize) :
- result (Hash_map_t T)
+ result (HashMap_t T)
:=
- let v := vec_new (List_t T) in
- slots <- hash_map_allocate_slots_fwd T n v capacity;
+ let v := alloc_vec_Vec_new (List_t T) in
+ slots <- hashMap_allocate_slots T n v capacity;
i <- usize_mul capacity max_load_dividend;
i0 <- usize_div i max_load_divisor;
Return
{|
- Hash_map_num_entries := 0%usize;
- Hash_map_max_load_factor := (max_load_dividend, max_load_divisor);
- Hash_map_max_load := i0;
- Hash_map_slots := slots
+ hashMap_num_entries := 0%usize;
+ hashMap_max_load_factor := (max_load_dividend, max_load_divisor);
+ hashMap_max_load := i0;
+ hashMap_slots := slots
|}
.
(** [hashmap::HashMap::{0}::new]: forward function *)
-Definition hash_map_new_fwd (T : Type) (n : nat) : result (Hash_map_t T) :=
- hash_map_new_with_capacity_fwd T n 32%usize 4%usize 5%usize
+Definition hashMap_new (T : Type) (n : nat) : result (HashMap_t T) :=
+ hashMap_new_with_capacity T n 32%usize 4%usize 5%usize
.
(** [hashmap::HashMap::{0}::clear]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint hash_map_clear_loop_fwd_back
- (T : Type) (n : nat) (slots : vec (List_t T)) (i : usize) :
- result (vec (List_t T))
+Fixpoint hashMap_clear_loop
+ (T : Type) (n : nat) (slots : alloc_vec_Vec (List_t T)) (i : usize) :
+ result (alloc_vec_Vec (List_t T))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- let i0 := vec_len (List_t T) slots in
+ let i0 := alloc_vec_Vec_len (List_t T) slots in
if i s< i0
then (
i1 <- usize_add i 1%usize;
- slots0 <- vec_index_mut_back (List_t T) slots i ListNil;
- hash_map_clear_loop_fwd_back T n0 slots0 i1)
+ slots0 <-
+ alloc_vec_Vec_index_mut_back (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ slots i List_Nil;
+ hashMap_clear_loop T n0 slots0 i1)
else Return slots
end
.
(** [hashmap::HashMap::{0}::clear]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hash_map_clear_fwd_back
- (T : Type) (n : nat) (self : Hash_map_t T) : result (Hash_map_t T) :=
- v <- hash_map_clear_loop_fwd_back T n self.(Hash_map_slots) 0%usize;
+Definition hashMap_clear
+ (T : Type) (n : nat) (self : HashMap_t T) : result (HashMap_t T) :=
+ v <- hashMap_clear_loop T n self.(hashMap_slots) 0%usize;
Return
{|
- Hash_map_num_entries := 0%usize;
- Hash_map_max_load_factor := self.(Hash_map_max_load_factor);
- Hash_map_max_load := self.(Hash_map_max_load);
- Hash_map_slots := v
+ hashMap_num_entries := 0%usize;
+ hashMap_max_load_factor := self.(hashMap_max_load_factor);
+ hashMap_max_load := self.(hashMap_max_load);
+ hashMap_slots := v
|}
.
(** [hashmap::HashMap::{0}::len]: forward function *)
-Definition hash_map_len_fwd (T : Type) (self : Hash_map_t T) : result usize :=
- Return self.(Hash_map_num_entries)
+Definition hashMap_len (T : Type) (self : HashMap_t T) : result usize :=
+ Return self.(hashMap_num_entries)
.
(** [hashmap::HashMap::{0}::insert_in_list]: loop 0: forward function *)
-Fixpoint hash_map_insert_in_list_loop_fwd
+Fixpoint hashMap_insert_in_list_loop
(T : Type) (n : nat) (key : usize) (value : T) (ls : List_t T) :
result bool
:=
@@ -110,25 +113,25 @@ Fixpoint hash_map_insert_in_list_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons ckey cvalue tl =>
+ | List_Cons ckey cvalue tl =>
if ckey s= key
then Return false
- else hash_map_insert_in_list_loop_fwd T n0 key value tl
- | ListNil => Return true
+ else hashMap_insert_in_list_loop T n0 key value tl
+ | List_Nil => Return true
end
end
.
(** [hashmap::HashMap::{0}::insert_in_list]: forward function *)
-Definition hash_map_insert_in_list_fwd
+Definition hashMap_insert_in_list
(T : Type) (n : nat) (key : usize) (value : T) (ls : List_t T) :
result bool
:=
- hash_map_insert_in_list_loop_fwd T n key value ls
+ hashMap_insert_in_list_loop T n key value ls
.
(** [hashmap::HashMap::{0}::insert_in_list]: loop 0: backward function 0 *)
-Fixpoint hash_map_insert_in_list_loop_back
+Fixpoint hashMap_insert_in_list_loop_back
(T : Type) (n : nat) (key : usize) (value : T) (ls : List_t T) :
result (List_t T)
:=
@@ -136,259 +139,275 @@ Fixpoint hash_map_insert_in_list_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons ckey cvalue tl =>
+ | List_Cons ckey cvalue tl =>
if ckey s= key
- then Return (ListCons ckey value tl)
+ then Return (List_Cons ckey value tl)
else (
- tl0 <- hash_map_insert_in_list_loop_back T n0 key value tl;
- Return (ListCons ckey cvalue tl0))
- | ListNil => let l := ListNil in Return (ListCons key value l)
+ tl0 <- hashMap_insert_in_list_loop_back T n0 key value tl;
+ Return (List_Cons ckey cvalue tl0))
+ | List_Nil => let l := List_Nil in Return (List_Cons key value l)
end
end
.
(** [hashmap::HashMap::{0}::insert_in_list]: backward function 0 *)
-Definition hash_map_insert_in_list_back
+Definition hashMap_insert_in_list_back
(T : Type) (n : nat) (key : usize) (value : T) (ls : List_t T) :
result (List_t T)
:=
- hash_map_insert_in_list_loop_back T n key value ls
+ hashMap_insert_in_list_loop_back T n key value ls
.
(** [hashmap::HashMap::{0}::insert_no_resize]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hash_map_insert_no_resize_fwd_back
- (T : Type) (n : nat) (self : Hash_map_t T) (key : usize) (value : T) :
- result (Hash_map_t T)
+Definition hashMap_insert_no_resize
+ (T : Type) (n : nat) (self : HashMap_t T) (key : usize) (value : T) :
+ result (HashMap_t T)
:=
- hash <- hash_key_fwd key;
- let i := vec_len (List_t T) self.(Hash_map_slots) in
+ hash <- hash_key key;
+ let i := alloc_vec_Vec_len (List_t T) self.(hashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_mut_fwd (List_t T) self.(Hash_map_slots) hash_mod;
- inserted <- hash_map_insert_in_list_fwd T n key value l;
+ l <-
+ alloc_vec_Vec_index_mut (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod;
+ inserted <- hashMap_insert_in_list T n key value l;
if inserted
then (
- i0 <- usize_add self.(Hash_map_num_entries) 1%usize;
- l0 <- hash_map_insert_in_list_back T n key value l;
- v <- vec_index_mut_back (List_t T) self.(Hash_map_slots) hash_mod l0;
+ i0 <- usize_add self.(hashMap_num_entries) 1%usize;
+ l0 <- hashMap_insert_in_list_back T n key value l;
+ v <-
+ alloc_vec_Vec_index_mut_back (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod l0;
Return
{|
- Hash_map_num_entries := i0;
- Hash_map_max_load_factor := self.(Hash_map_max_load_factor);
- Hash_map_max_load := self.(Hash_map_max_load);
- Hash_map_slots := v
+ hashMap_num_entries := i0;
+ hashMap_max_load_factor := self.(hashMap_max_load_factor);
+ hashMap_max_load := self.(hashMap_max_load);
+ hashMap_slots := v
|})
else (
- l0 <- hash_map_insert_in_list_back T n key value l;
- v <- vec_index_mut_back (List_t T) self.(Hash_map_slots) hash_mod l0;
+ l0 <- hashMap_insert_in_list_back T n key value l;
+ v <-
+ alloc_vec_Vec_index_mut_back (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod l0;
Return
{|
- Hash_map_num_entries := self.(Hash_map_num_entries);
- Hash_map_max_load_factor := self.(Hash_map_max_load_factor);
- Hash_map_max_load := self.(Hash_map_max_load);
- Hash_map_slots := v
+ hashMap_num_entries := self.(hashMap_num_entries);
+ hashMap_max_load_factor := self.(hashMap_max_load_factor);
+ hashMap_max_load := self.(hashMap_max_load);
+ hashMap_slots := v
|})
.
-(** [core::num::u32::{8}::MAX] *)
-Definition core_num_u32_max_body : result u32 := Return 4294967295%u32.
-Definition core_num_u32_max_c : u32 := core_num_u32_max_body%global.
-
(** [hashmap::HashMap::{0}::move_elements_from_list]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint hash_map_move_elements_from_list_loop_fwd_back
- (T : Type) (n : nat) (ntable : Hash_map_t T) (ls : List_t T) :
- result (Hash_map_t T)
+Fixpoint hashMap_move_elements_from_list_loop
+ (T : Type) (n : nat) (ntable : HashMap_t T) (ls : List_t T) :
+ result (HashMap_t T)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons k v tl =>
- ntable0 <- hash_map_insert_no_resize_fwd_back T n0 ntable k v;
- hash_map_move_elements_from_list_loop_fwd_back T n0 ntable0 tl
- | ListNil => Return ntable
+ | List_Cons k v tl =>
+ ntable0 <- hashMap_insert_no_resize T n0 ntable k v;
+ hashMap_move_elements_from_list_loop T n0 ntable0 tl
+ | List_Nil => Return ntable
end
end
.
(** [hashmap::HashMap::{0}::move_elements_from_list]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hash_map_move_elements_from_list_fwd_back
- (T : Type) (n : nat) (ntable : Hash_map_t T) (ls : List_t T) :
- result (Hash_map_t T)
+Definition hashMap_move_elements_from_list
+ (T : Type) (n : nat) (ntable : HashMap_t T) (ls : List_t T) :
+ result (HashMap_t T)
:=
- hash_map_move_elements_from_list_loop_fwd_back T n ntable ls
+ hashMap_move_elements_from_list_loop T n ntable ls
.
(** [hashmap::HashMap::{0}::move_elements]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint hash_map_move_elements_loop_fwd_back
- (T : Type) (n : nat) (ntable : Hash_map_t T) (slots : vec (List_t T))
- (i : usize) :
- result ((Hash_map_t T) * (vec (List_t T)))
+Fixpoint hashMap_move_elements_loop
+ (T : Type) (n : nat) (ntable : HashMap_t T)
+ (slots : alloc_vec_Vec (List_t T)) (i : usize) :
+ result ((HashMap_t T) * (alloc_vec_Vec (List_t T)))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- let i0 := vec_len (List_t T) slots in
+ let i0 := alloc_vec_Vec_len (List_t T) slots in
if i s< i0
then (
- l <- vec_index_mut_fwd (List_t T) slots i;
- let ls := mem_replace_fwd (List_t T) l ListNil in
- ntable0 <- hash_map_move_elements_from_list_fwd_back T n0 ntable ls;
+ l <-
+ alloc_vec_Vec_index_mut (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ slots i;
+ let ls := core_mem_replace (List_t T) l List_Nil in
+ ntable0 <- hashMap_move_elements_from_list T n0 ntable ls;
i1 <- usize_add i 1%usize;
- let l0 := mem_replace_back (List_t T) l ListNil in
- slots0 <- vec_index_mut_back (List_t T) slots i l0;
- hash_map_move_elements_loop_fwd_back T n0 ntable0 slots0 i1)
+ let l0 := core_mem_replace_back (List_t T) l List_Nil in
+ slots0 <-
+ alloc_vec_Vec_index_mut_back (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ slots i l0;
+ hashMap_move_elements_loop T n0 ntable0 slots0 i1)
else Return (ntable, slots)
end
.
(** [hashmap::HashMap::{0}::move_elements]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hash_map_move_elements_fwd_back
- (T : Type) (n : nat) (ntable : Hash_map_t T) (slots : vec (List_t T))
- (i : usize) :
- result ((Hash_map_t T) * (vec (List_t T)))
+Definition hashMap_move_elements
+ (T : Type) (n : nat) (ntable : HashMap_t T)
+ (slots : alloc_vec_Vec (List_t T)) (i : usize) :
+ result ((HashMap_t T) * (alloc_vec_Vec (List_t T)))
:=
- hash_map_move_elements_loop_fwd_back T n ntable slots i
+ hashMap_move_elements_loop T n ntable slots i
.
(** [hashmap::HashMap::{0}::try_resize]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hash_map_try_resize_fwd_back
- (T : Type) (n : nat) (self : Hash_map_t T) : result (Hash_map_t T) :=
- max_usize <- scalar_cast U32 Usize core_num_u32_max_c;
- let capacity := vec_len (List_t T) self.(Hash_map_slots) in
+Definition hashMap_try_resize
+ (T : Type) (n : nat) (self : HashMap_t T) : result (HashMap_t T) :=
+ max_usize <- scalar_cast U32 Usize core_u32_max;
+ let capacity := alloc_vec_Vec_len (List_t T) self.(hashMap_slots) in
n1 <- usize_div max_usize 2%usize;
- let (i, i0) := self.(Hash_map_max_load_factor) in
+ let (i, i0) := self.(hashMap_max_load_factor) in
i1 <- usize_div n1 i;
if capacity s<= i1
then (
i2 <- usize_mul capacity 2%usize;
- ntable <- hash_map_new_with_capacity_fwd T n i2 i i0;
- p <-
- hash_map_move_elements_fwd_back T n ntable self.(Hash_map_slots) 0%usize;
+ ntable <- hashMap_new_with_capacity T n i2 i i0;
+ p <- hashMap_move_elements T n ntable self.(hashMap_slots) 0%usize;
let (ntable0, _) := p in
Return
{|
- Hash_map_num_entries := self.(Hash_map_num_entries);
- Hash_map_max_load_factor := (i, i0);
- Hash_map_max_load := ntable0.(Hash_map_max_load);
- Hash_map_slots := ntable0.(Hash_map_slots)
+ hashMap_num_entries := self.(hashMap_num_entries);
+ hashMap_max_load_factor := (i, i0);
+ hashMap_max_load := ntable0.(hashMap_max_load);
+ hashMap_slots := ntable0.(hashMap_slots)
|})
else
Return
{|
- Hash_map_num_entries := self.(Hash_map_num_entries);
- Hash_map_max_load_factor := (i, i0);
- Hash_map_max_load := self.(Hash_map_max_load);
- Hash_map_slots := self.(Hash_map_slots)
+ hashMap_num_entries := self.(hashMap_num_entries);
+ hashMap_max_load_factor := (i, i0);
+ hashMap_max_load := self.(hashMap_max_load);
+ hashMap_slots := self.(hashMap_slots)
|}
.
(** [hashmap::HashMap::{0}::insert]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hash_map_insert_fwd_back
- (T : Type) (n : nat) (self : Hash_map_t T) (key : usize) (value : T) :
- result (Hash_map_t T)
+Definition hashMap_insert
+ (T : Type) (n : nat) (self : HashMap_t T) (key : usize) (value : T) :
+ result (HashMap_t T)
:=
- self0 <- hash_map_insert_no_resize_fwd_back T n self key value;
- i <- hash_map_len_fwd T self0;
- if i s> self0.(Hash_map_max_load)
- then hash_map_try_resize_fwd_back T n self0
+ self0 <- hashMap_insert_no_resize T n self key value;
+ i <- hashMap_len T self0;
+ if i s> self0.(hashMap_max_load)
+ then hashMap_try_resize T n self0
else Return self0
.
(** [hashmap::HashMap::{0}::contains_key_in_list]: loop 0: forward function *)
-Fixpoint hash_map_contains_key_in_list_loop_fwd
+Fixpoint hashMap_contains_key_in_list_loop
(T : Type) (n : nat) (key : usize) (ls : List_t T) : result bool :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons ckey t tl =>
+ | List_Cons ckey t tl =>
if ckey s= key
then Return true
- else hash_map_contains_key_in_list_loop_fwd T n0 key tl
- | ListNil => Return false
+ else hashMap_contains_key_in_list_loop T n0 key tl
+ | List_Nil => Return false
end
end
.
(** [hashmap::HashMap::{0}::contains_key_in_list]: forward function *)
-Definition hash_map_contains_key_in_list_fwd
+Definition hashMap_contains_key_in_list
(T : Type) (n : nat) (key : usize) (ls : List_t T) : result bool :=
- hash_map_contains_key_in_list_loop_fwd T n key ls
+ hashMap_contains_key_in_list_loop T n key ls
.
(** [hashmap::HashMap::{0}::contains_key]: forward function *)
-Definition hash_map_contains_key_fwd
- (T : Type) (n : nat) (self : Hash_map_t T) (key : usize) : result bool :=
- hash <- hash_key_fwd key;
- let i := vec_len (List_t T) self.(Hash_map_slots) in
+Definition hashMap_contains_key
+ (T : Type) (n : nat) (self : HashMap_t T) (key : usize) : result bool :=
+ hash <- hash_key key;
+ let i := alloc_vec_Vec_len (List_t T) self.(hashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_fwd (List_t T) self.(Hash_map_slots) hash_mod;
- hash_map_contains_key_in_list_fwd T n key l
+ l <-
+ alloc_vec_Vec_index (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod;
+ hashMap_contains_key_in_list T n key l
.
(** [hashmap::HashMap::{0}::get_in_list]: loop 0: forward function *)
-Fixpoint hash_map_get_in_list_loop_fwd
+Fixpoint hashMap_get_in_list_loop
(T : Type) (n : nat) (key : usize) (ls : List_t T) : result T :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons ckey cvalue tl =>
+ | List_Cons ckey cvalue tl =>
if ckey s= key
then Return cvalue
- else hash_map_get_in_list_loop_fwd T n0 key tl
- | ListNil => Fail_ Failure
+ else hashMap_get_in_list_loop T n0 key tl
+ | List_Nil => Fail_ Failure
end
end
.
(** [hashmap::HashMap::{0}::get_in_list]: forward function *)
-Definition hash_map_get_in_list_fwd
+Definition hashMap_get_in_list
(T : Type) (n : nat) (key : usize) (ls : List_t T) : result T :=
- hash_map_get_in_list_loop_fwd T n key ls
+ hashMap_get_in_list_loop T n key ls
.
(** [hashmap::HashMap::{0}::get]: forward function *)
-Definition hash_map_get_fwd
- (T : Type) (n : nat) (self : Hash_map_t T) (key : usize) : result T :=
- hash <- hash_key_fwd key;
- let i := vec_len (List_t T) self.(Hash_map_slots) in
+Definition hashMap_get
+ (T : Type) (n : nat) (self : HashMap_t T) (key : usize) : result T :=
+ hash <- hash_key key;
+ let i := alloc_vec_Vec_len (List_t T) self.(hashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_fwd (List_t T) self.(Hash_map_slots) hash_mod;
- hash_map_get_in_list_fwd T n key l
+ l <-
+ alloc_vec_Vec_index (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod;
+ hashMap_get_in_list T n key l
.
(** [hashmap::HashMap::{0}::get_mut_in_list]: loop 0: forward function *)
-Fixpoint hash_map_get_mut_in_list_loop_fwd
+Fixpoint hashMap_get_mut_in_list_loop
(T : Type) (n : nat) (ls : List_t T) (key : usize) : result T :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons ckey cvalue tl =>
+ | List_Cons ckey cvalue tl =>
if ckey s= key
then Return cvalue
- else hash_map_get_mut_in_list_loop_fwd T n0 tl key
- | ListNil => Fail_ Failure
+ else hashMap_get_mut_in_list_loop T n0 tl key
+ | List_Nil => Fail_ Failure
end
end
.
(** [hashmap::HashMap::{0}::get_mut_in_list]: forward function *)
-Definition hash_map_get_mut_in_list_fwd
+Definition hashMap_get_mut_in_list
(T : Type) (n : nat) (ls : List_t T) (key : usize) : result T :=
- hash_map_get_mut_in_list_loop_fwd T n ls key
+ hashMap_get_mut_in_list_loop T n ls key
.
(** [hashmap::HashMap::{0}::get_mut_in_list]: loop 0: backward function 0 *)
-Fixpoint hash_map_get_mut_in_list_loop_back
+Fixpoint hashMap_get_mut_in_list_loop_back
(T : Type) (n : nat) (ls : List_t T) (key : usize) (ret : T) :
result (List_t T)
:=
@@ -396,196 +415,219 @@ Fixpoint hash_map_get_mut_in_list_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons ckey cvalue tl =>
+ | List_Cons ckey cvalue tl =>
if ckey s= key
- then Return (ListCons ckey ret tl)
+ then Return (List_Cons ckey ret tl)
else (
- tl0 <- hash_map_get_mut_in_list_loop_back T n0 tl key ret;
- Return (ListCons ckey cvalue tl0))
- | ListNil => Fail_ Failure
+ tl0 <- hashMap_get_mut_in_list_loop_back T n0 tl key ret;
+ Return (List_Cons ckey cvalue tl0))
+ | List_Nil => Fail_ Failure
end
end
.
(** [hashmap::HashMap::{0}::get_mut_in_list]: backward function 0 *)
-Definition hash_map_get_mut_in_list_back
+Definition hashMap_get_mut_in_list_back
(T : Type) (n : nat) (ls : List_t T) (key : usize) (ret : T) :
result (List_t T)
:=
- hash_map_get_mut_in_list_loop_back T n ls key ret
+ hashMap_get_mut_in_list_loop_back T n ls key ret
.
(** [hashmap::HashMap::{0}::get_mut]: forward function *)
-Definition hash_map_get_mut_fwd
- (T : Type) (n : nat) (self : Hash_map_t T) (key : usize) : result T :=
- hash <- hash_key_fwd key;
- let i := vec_len (List_t T) self.(Hash_map_slots) in
+Definition hashMap_get_mut
+ (T : Type) (n : nat) (self : HashMap_t T) (key : usize) : result T :=
+ hash <- hash_key key;
+ let i := alloc_vec_Vec_len (List_t T) self.(hashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_mut_fwd (List_t T) self.(Hash_map_slots) hash_mod;
- hash_map_get_mut_in_list_fwd T n l key
+ l <-
+ alloc_vec_Vec_index_mut (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod;
+ hashMap_get_mut_in_list T n l key
.
(** [hashmap::HashMap::{0}::get_mut]: backward function 0 *)
-Definition hash_map_get_mut_back
- (T : Type) (n : nat) (self : Hash_map_t T) (key : usize) (ret : T) :
- result (Hash_map_t T)
+Definition hashMap_get_mut_back
+ (T : Type) (n : nat) (self : HashMap_t T) (key : usize) (ret : T) :
+ result (HashMap_t T)
:=
- hash <- hash_key_fwd key;
- let i := vec_len (List_t T) self.(Hash_map_slots) in
+ hash <- hash_key key;
+ let i := alloc_vec_Vec_len (List_t T) self.(hashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_mut_fwd (List_t T) self.(Hash_map_slots) hash_mod;
- l0 <- hash_map_get_mut_in_list_back T n l key ret;
- v <- vec_index_mut_back (List_t T) self.(Hash_map_slots) hash_mod l0;
+ l <-
+ alloc_vec_Vec_index_mut (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod;
+ l0 <- hashMap_get_mut_in_list_back T n l key ret;
+ v <-
+ alloc_vec_Vec_index_mut_back (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod l0;
Return
{|
- Hash_map_num_entries := self.(Hash_map_num_entries);
- Hash_map_max_load_factor := self.(Hash_map_max_load_factor);
- Hash_map_max_load := self.(Hash_map_max_load);
- Hash_map_slots := v
+ hashMap_num_entries := self.(hashMap_num_entries);
+ hashMap_max_load_factor := self.(hashMap_max_load_factor);
+ hashMap_max_load := self.(hashMap_max_load);
+ hashMap_slots := v
|}
.
(** [hashmap::HashMap::{0}::remove_from_list]: loop 0: forward function *)
-Fixpoint hash_map_remove_from_list_loop_fwd
+Fixpoint hashMap_remove_from_list_loop
(T : Type) (n : nat) (key : usize) (ls : List_t T) : result (option T) :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons ckey t tl =>
+ | List_Cons ckey t tl =>
if ckey s= key
then
- let mv_ls := mem_replace_fwd (List_t T) (ListCons ckey t tl) ListNil in
+ let mv_ls := core_mem_replace (List_t T) (List_Cons ckey t tl) List_Nil
+ in
match mv_ls with
- | ListCons i cvalue tl0 => Return (Some cvalue)
- | ListNil => Fail_ Failure
+ | List_Cons i cvalue tl0 => Return (Some cvalue)
+ | List_Nil => Fail_ Failure
end
- else hash_map_remove_from_list_loop_fwd T n0 key tl
- | ListNil => Return None
+ else hashMap_remove_from_list_loop T n0 key tl
+ | List_Nil => Return None
end
end
.
(** [hashmap::HashMap::{0}::remove_from_list]: forward function *)
-Definition hash_map_remove_from_list_fwd
+Definition hashMap_remove_from_list
(T : Type) (n : nat) (key : usize) (ls : List_t T) : result (option T) :=
- hash_map_remove_from_list_loop_fwd T n key ls
+ hashMap_remove_from_list_loop T n key ls
.
(** [hashmap::HashMap::{0}::remove_from_list]: loop 0: backward function 1 *)
-Fixpoint hash_map_remove_from_list_loop_back
+Fixpoint hashMap_remove_from_list_loop_back
(T : Type) (n : nat) (key : usize) (ls : List_t T) : result (List_t T) :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons ckey t tl =>
+ | List_Cons ckey t tl =>
if ckey s= key
then
- let mv_ls := mem_replace_fwd (List_t T) (ListCons ckey t tl) ListNil in
+ let mv_ls := core_mem_replace (List_t T) (List_Cons ckey t tl) List_Nil
+ in
match mv_ls with
- | ListCons i cvalue tl0 => Return tl0
- | ListNil => Fail_ Failure
+ | List_Cons i cvalue tl0 => Return tl0
+ | List_Nil => Fail_ Failure
end
else (
- tl0 <- hash_map_remove_from_list_loop_back T n0 key tl;
- Return (ListCons ckey t tl0))
- | ListNil => Return ListNil
+ tl0 <- hashMap_remove_from_list_loop_back T n0 key tl;
+ Return (List_Cons ckey t tl0))
+ | List_Nil => Return List_Nil
end
end
.
(** [hashmap::HashMap::{0}::remove_from_list]: backward function 1 *)
-Definition hash_map_remove_from_list_back
+Definition hashMap_remove_from_list_back
(T : Type) (n : nat) (key : usize) (ls : List_t T) : result (List_t T) :=
- hash_map_remove_from_list_loop_back T n key ls
+ hashMap_remove_from_list_loop_back T n key ls
.
(** [hashmap::HashMap::{0}::remove]: forward function *)
-Definition hash_map_remove_fwd
- (T : Type) (n : nat) (self : Hash_map_t T) (key : usize) :
+Definition hashMap_remove
+ (T : Type) (n : nat) (self : HashMap_t T) (key : usize) :
result (option T)
:=
- hash <- hash_key_fwd key;
- let i := vec_len (List_t T) self.(Hash_map_slots) in
+ hash <- hash_key key;
+ let i := alloc_vec_Vec_len (List_t T) self.(hashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_mut_fwd (List_t T) self.(Hash_map_slots) hash_mod;
- x <- hash_map_remove_from_list_fwd T n key l;
+ l <-
+ alloc_vec_Vec_index_mut (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod;
+ x <- hashMap_remove_from_list T n key l;
match x with
| None => Return None
| Some x0 =>
- _ <- usize_sub self.(Hash_map_num_entries) 1%usize; Return (Some x0)
+ _ <- usize_sub self.(hashMap_num_entries) 1%usize; Return (Some x0)
end
.
(** [hashmap::HashMap::{0}::remove]: backward function 0 *)
-Definition hash_map_remove_back
- (T : Type) (n : nat) (self : Hash_map_t T) (key : usize) :
- result (Hash_map_t T)
+Definition hashMap_remove_back
+ (T : Type) (n : nat) (self : HashMap_t T) (key : usize) :
+ result (HashMap_t T)
:=
- hash <- hash_key_fwd key;
- let i := vec_len (List_t T) self.(Hash_map_slots) in
+ hash <- hash_key key;
+ let i := alloc_vec_Vec_len (List_t T) self.(hashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_mut_fwd (List_t T) self.(Hash_map_slots) hash_mod;
- x <- hash_map_remove_from_list_fwd T n key l;
+ l <-
+ alloc_vec_Vec_index_mut (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod;
+ x <- hashMap_remove_from_list T n key l;
match x with
| None =>
- l0 <- hash_map_remove_from_list_back T n key l;
- v <- vec_index_mut_back (List_t T) self.(Hash_map_slots) hash_mod l0;
+ l0 <- hashMap_remove_from_list_back T n key l;
+ v <-
+ alloc_vec_Vec_index_mut_back (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod l0;
Return
{|
- Hash_map_num_entries := self.(Hash_map_num_entries);
- Hash_map_max_load_factor := self.(Hash_map_max_load_factor);
- Hash_map_max_load := self.(Hash_map_max_load);
- Hash_map_slots := v
+ hashMap_num_entries := self.(hashMap_num_entries);
+ hashMap_max_load_factor := self.(hashMap_max_load_factor);
+ hashMap_max_load := self.(hashMap_max_load);
+ hashMap_slots := v
|}
| Some x0 =>
- i0 <- usize_sub self.(Hash_map_num_entries) 1%usize;
- l0 <- hash_map_remove_from_list_back T n key l;
- v <- vec_index_mut_back (List_t T) self.(Hash_map_slots) hash_mod l0;
+ i0 <- usize_sub self.(hashMap_num_entries) 1%usize;
+ l0 <- hashMap_remove_from_list_back T n key l;
+ v <-
+ alloc_vec_Vec_index_mut_back (List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t T))
+ self.(hashMap_slots) hash_mod l0;
Return
{|
- Hash_map_num_entries := i0;
- Hash_map_max_load_factor := self.(Hash_map_max_load_factor);
- Hash_map_max_load := self.(Hash_map_max_load);
- Hash_map_slots := v
+ hashMap_num_entries := i0;
+ hashMap_max_load_factor := self.(hashMap_max_load_factor);
+ hashMap_max_load := self.(hashMap_max_load);
+ hashMap_slots := v
|}
end
.
(** [hashmap::test1]: forward function *)
-Definition test1_fwd (n : nat) : result unit :=
- hm <- hash_map_new_fwd u64 n;
- hm0 <- hash_map_insert_fwd_back u64 n hm 0%usize 42%u64;
- hm1 <- hash_map_insert_fwd_back u64 n hm0 128%usize 18%u64;
- hm2 <- hash_map_insert_fwd_back u64 n hm1 1024%usize 138%u64;
- hm3 <- hash_map_insert_fwd_back u64 n hm2 1056%usize 256%u64;
- i <- hash_map_get_fwd u64 n hm3 128%usize;
+Definition test1 (n : nat) : result unit :=
+ hm <- hashMap_new u64 n;
+ hm0 <- hashMap_insert u64 n hm 0%usize 42%u64;
+ hm1 <- hashMap_insert u64 n hm0 128%usize 18%u64;
+ hm2 <- hashMap_insert u64 n hm1 1024%usize 138%u64;
+ hm3 <- hashMap_insert u64 n hm2 1056%usize 256%u64;
+ i <- hashMap_get u64 n hm3 128%usize;
if negb (i s= 18%u64)
then Fail_ Failure
else (
- hm4 <- hash_map_get_mut_back u64 n hm3 1024%usize 56%u64;
- i0 <- hash_map_get_fwd u64 n hm4 1024%usize;
+ hm4 <- hashMap_get_mut_back u64 n hm3 1024%usize 56%u64;
+ i0 <- hashMap_get u64 n hm4 1024%usize;
if negb (i0 s= 56%u64)
then Fail_ Failure
else (
- x <- hash_map_remove_fwd u64 n hm4 1024%usize;
+ x <- hashMap_remove u64 n hm4 1024%usize;
match x with
| None => Fail_ Failure
| Some x0 =>
if negb (x0 s= 56%u64)
then Fail_ Failure
else (
- hm5 <- hash_map_remove_back u64 n hm4 1024%usize;
- i1 <- hash_map_get_fwd u64 n hm5 0%usize;
+ hm5 <- hashMap_remove_back u64 n hm4 1024%usize;
+ i1 <- hashMap_get u64 n hm5 0%usize;
if negb (i1 s= 42%u64)
then Fail_ Failure
else (
- i2 <- hash_map_get_fwd u64 n hm5 128%usize;
+ i2 <- hashMap_get u64 n hm5 128%usize;
if negb (i2 s= 18%u64)
then Fail_ Failure
else (
- i3 <- hash_map_get_fwd u64 n hm5 1056%usize;
+ i3 <- hashMap_get u64 n hm5 1056%usize;
if negb (i3 s= 256%u64) then Fail_ Failure else Return tt)))
end))
.
diff --git a/tests/coq/hashmap/Hashmap_Types.v b/tests/coq/hashmap/Hashmap_Types.v
index dbde6be9..8529803d 100644
--- a/tests/coq/hashmap/Hashmap_Types.v
+++ b/tests/coq/hashmap/Hashmap_Types.v
@@ -10,27 +10,27 @@ Module Hashmap_Types.
(** [hashmap::List] *)
Inductive List_t (T : Type) :=
-| ListCons : usize -> T -> List_t T -> List_t T
-| ListNil : List_t T
+| List_Cons : usize -> T -> List_t T -> List_t T
+| List_Nil : List_t T
.
-Arguments ListCons {T} _ _ _.
-Arguments ListNil {T}.
+Arguments List_Cons { _ }.
+Arguments List_Nil { _ }.
(** [hashmap::HashMap] *)
-Record Hash_map_t (T : Type) :=
-mkHash_map_t {
- Hash_map_num_entries : usize;
- Hash_map_max_load_factor : (usize * usize);
- Hash_map_max_load : usize;
- Hash_map_slots : vec (List_t T);
+Record HashMap_t (T : Type) :=
+mkHashMap_t {
+ hashMap_num_entries : usize;
+ hashMap_max_load_factor : (usize * usize);
+ hashMap_max_load : usize;
+ hashMap_slots : alloc_vec_Vec (List_t T);
}
.
-Arguments mkHash_map_t {T} _ _ _ _.
-Arguments Hash_map_num_entries {T}.
-Arguments Hash_map_max_load_factor {T}.
-Arguments Hash_map_max_load {T}.
-Arguments Hash_map_slots {T}.
+Arguments mkHashMap_t { _ }.
+Arguments hashMap_num_entries { _ }.
+Arguments hashMap_max_load_factor { _ }.
+Arguments hashMap_max_load { _ }.
+Arguments hashMap_slots { _ }.
End Hashmap_Types .
diff --git a/tests/coq/hashmap/Primitives.v b/tests/coq/hashmap/Primitives.v
index 71a2d9c3..85e38f01 100644
--- a/tests/coq/hashmap/Primitives.v
+++ b/tests/coq/hashmap/Primitives.v
@@ -63,13 +63,15 @@ Check (if true then Return (1 + 2) else Fail_ Failure)%global = 3.
(*** Misc *)
-
Definition string := Coq.Strings.String.string.
Definition char := Coq.Strings.Ascii.ascii.
Definition char_of_byte := Coq.Strings.Ascii.ascii_of_byte.
-Definition mem_replace_fwd (a : Type) (x : a) (y : a) : a := x .
-Definition mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+Definition core_mem_replace (a : Type) (x : a) (y : a) : a := x .
+Definition core_mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+
+Record mut_raw_ptr (T : Type) := { mut_raw_ptr_v : T }.
+Record const_raw_ptr (T : Type) := { const_raw_ptr_v : T }.
(*** Scalars *)
@@ -394,12 +396,89 @@ Notation "x s< y" := (scalar_ltb x y) (at level 80) : Primitives_scope.
Notation "x s>= y" := (scalar_geb x y) (at level 80) : Primitives_scope.
Notation "x s> y" := (scalar_gtb x y) (at level 80) : Primitives_scope.
-(*** Range *)
-Record range (T : Type) := mk_range {
- start: T;
- end_: T;
+(** Constants *)
+Definition core_u8_max := u8_max %u32.
+Definition core_u16_max := u16_max %u32.
+Definition core_u32_max := u32_max %u32.
+Definition core_u64_max := u64_max %u64.
+Definition core_u128_max := u64_max %u128.
+Axiom core_usize_max : usize. (** TODO *)
+Definition core_i8_max := i8_max %i32.
+Definition core_i16_max := i16_max %i32.
+Definition core_i32_max := i32_max %i32.
+Definition core_i64_max := i64_max %i64.
+Definition core_i128_max := i64_max %i128.
+Axiom core_isize_max : isize. (** TODO *)
+
+(*** core::ops *)
+
+(* Trait declaration: [core::ops::index::Index] *)
+Record core_ops_index_Index (Self Idx : Type) := mk_core_ops_index_Index {
+ core_ops_index_Index_Output : Type;
+ core_ops_index_Index_index : Self -> Idx -> result core_ops_index_Index_Output;
+}.
+Arguments mk_core_ops_index_Index {_ _}.
+Arguments core_ops_index_Index_Output {_ _}.
+Arguments core_ops_index_Index_index {_ _}.
+
+(* Trait declaration: [core::ops::index::IndexMut] *)
+Record core_ops_index_IndexMut (Self Idx : Type) := mk_core_ops_index_IndexMut {
+ core_ops_index_IndexMut_indexInst : core_ops_index_Index Self Idx;
+ core_ops_index_IndexMut_index_mut : Self -> Idx -> result core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output);
+ core_ops_index_IndexMut_index_mut_back : Self -> Idx -> core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output) -> result Self;
+}.
+Arguments mk_core_ops_index_IndexMut {_ _}.
+Arguments core_ops_index_IndexMut_indexInst {_ _}.
+Arguments core_ops_index_IndexMut_index_mut {_ _}.
+Arguments core_ops_index_IndexMut_index_mut_back {_ _}.
+
+(* Trait declaration [core::ops::deref::Deref] *)
+Record core_ops_deref_Deref (Self : Type) := mk_core_ops_deref_Deref {
+ core_ops_deref_Deref_target : Type;
+ core_ops_deref_Deref_deref : Self -> result core_ops_deref_Deref_target;
+}.
+Arguments mk_core_ops_deref_Deref {_}.
+Arguments core_ops_deref_Deref_target {_}.
+Arguments core_ops_deref_Deref_deref {_}.
+
+(* Trait declaration [core::ops::deref::DerefMut] *)
+Record core_ops_deref_DerefMut (Self : Type) := mk_core_ops_deref_DerefMut {
+ core_ops_deref_DerefMut_derefInst : core_ops_deref_Deref Self;
+ core_ops_deref_DerefMut_deref_mut : Self -> result core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target);
+ core_ops_deref_DerefMut_deref_mut_back : Self -> core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target) -> result Self;
}.
-Arguments mk_range {_}.
+Arguments mk_core_ops_deref_DerefMut {_}.
+Arguments core_ops_deref_DerefMut_derefInst {_}.
+Arguments core_ops_deref_DerefMut_deref_mut {_}.
+Arguments core_ops_deref_DerefMut_deref_mut_back {_}.
+
+Record core_ops_range_Range (T : Type) := mk_core_ops_range_Range {
+ core_ops_range_Range_start : T;
+ core_ops_range_Range_end_ : T;
+}.
+Arguments mk_core_ops_range_Range {_}.
+Arguments core_ops_range_Range_start {_}.
+Arguments core_ops_range_Range_end_ {_}.
+
+(*** [alloc] *)
+
+Definition alloc_boxed_Box_deref (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut_back (T : Type) (_ : T) (x : T) : result T := Return x.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefInst (Self : Type) : core_ops_deref_Deref Self := {|
+ core_ops_deref_Deref_target := Self;
+ core_ops_deref_Deref_deref := alloc_boxed_Box_deref Self;
+|}.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefMutInst (Self : Type) : core_ops_deref_DerefMut Self := {|
+ core_ops_deref_DerefMut_derefInst := alloc_boxed_Box_coreOpsDerefInst Self;
+ core_ops_deref_DerefMut_deref_mut := alloc_boxed_Box_deref_mut Self;
+ core_ops_deref_DerefMut_deref_mut_back := alloc_boxed_Box_deref_mut_back Self;
+|}.
+
(*** Arrays *)
Definition array T (n : usize) := { l: list T | Z.of_nat (length l) = to_Z n}.
@@ -419,51 +498,50 @@ Qed.
(* TODO: finish the definitions *)
Axiom mk_array : forall (T : Type) (n : usize) (l : list T), array T n.
-Axiom array_index_shared : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_fwd : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_back : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
+(* For initialization *)
+Axiom array_repeat : forall (T : Type) (n : usize) (x : T), array T n.
+
+Axiom array_index_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
+Axiom array_update_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
(*** Slice *)
Definition slice T := { l: list T | Z.of_nat (length l) <= usize_max}.
Axiom slice_len : forall (T : Type) (s : slice T), usize.
-Axiom slice_index_shared : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_fwd : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_back : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
+Axiom slice_index_usize : forall (T : Type) (x : slice T) (i : usize), result T.
+Axiom slice_update_usize : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
(*** Subslices *)
-Axiom array_to_slice_shared : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_fwd : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_back : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+Axiom array_to_slice : forall (T : Type) (n : usize) (x : array T n), result (slice T).
+Axiom array_from_slice : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+
+Axiom array_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize), result (slice T).
+Axiom array_update_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize) (ns : slice T), result (array T n).
-Axiom array_subslice_shared: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_fwd: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_back: forall (T : Type) (n : usize) (x : array T n) (r : range usize) (ns : slice T), result (array T n).
-Axiom slice_subslice_shared: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_fwd: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_back: forall (T : Type) (x : slice T) (r : range usize) (ns : slice T), result (slice T).
+Axiom slice_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize), result (slice T).
+Axiom slice_update_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize) (ns : slice T), result (slice T).
(*** Vectors *)
-Definition vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
+Definition alloc_vec_Vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
-Definition vec_to_list {T: Type} (v: vec T) : list T := proj1_sig v.
+Definition alloc_vec_Vec_to_list {T: Type} (v: alloc_vec_Vec T) : list T := proj1_sig v.
-Definition vec_length {T: Type} (v: vec T) : Z := Z.of_nat (length (vec_to_list v)).
+Definition alloc_vec_Vec_length {T: Type} (v: alloc_vec_Vec T) : Z := Z.of_nat (length (alloc_vec_Vec_to_list v)).
-Definition vec_new (T: Type) : vec T := (exist _ [] le_0_usize_max).
+Definition alloc_vec_Vec_new (T: Type) : alloc_vec_Vec T := (exist _ [] le_0_usize_max).
-Lemma vec_len_in_usize {T} (v: vec T) : usize_min <= vec_length v <= usize_max.
+Lemma alloc_vec_Vec_len_in_usize {T} (v: alloc_vec_Vec T) : usize_min <= alloc_vec_Vec_length v <= usize_max.
Proof.
- unfold vec_length, usize_min.
+ unfold alloc_vec_Vec_length, usize_min.
split.
- lia.
- apply (proj2_sig v).
Qed.
-Definition vec_len (T: Type) (v: vec T) : usize :=
- exist _ (vec_length v) (vec_len_in_usize v).
+Definition alloc_vec_Vec_len (T: Type) (v: alloc_vec_Vec T) : usize :=
+ exist _ (alloc_vec_Vec_length v) (alloc_vec_Vec_len_in_usize v).
Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
: list A :=
@@ -474,50 +552,271 @@ Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
| S m => x :: (list_update t m a)
end end.
-Definition vec_bind {A B} (v: vec A) (f: list A -> result (list B)) : result (vec B) :=
- l <- f (vec_to_list v) ;
+Definition alloc_vec_Vec_bind {A B} (v: alloc_vec_Vec A) (f: list A -> result (list B)) : result (alloc_vec_Vec B) :=
+ l <- f (alloc_vec_Vec_to_list v) ;
match sumbool_of_bool (scalar_le_max Usize (Z.of_nat (length l))) with
| left H => Return (exist _ l (scalar_le_max_valid _ _ H))
| right _ => Fail_ Failure
end.
(* The **forward** function shouldn't be used *)
-Definition vec_push_fwd (T: Type) (v: vec T) (x: T) : unit := tt.
+Definition alloc_vec_Vec_push_fwd (T: Type) (v: alloc_vec_Vec T) (x: T) : unit := tt.
-Definition vec_push_back (T: Type) (v: vec T) (x: T) : result (vec T) :=
- vec_bind v (fun l => Return (l ++ [x])).
+Definition alloc_vec_Vec_push (T: Type) (v: alloc_vec_Vec T) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l => Return (l ++ [x])).
(* The **forward** function shouldn't be used *)
-Definition vec_insert_fwd (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
+Definition alloc_vec_Vec_insert_fwd (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result unit :=
+ if to_Z i <? alloc_vec_Vec_length v then Return tt else Fail_ Failure.
-Definition vec_insert_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
+Definition alloc_vec_Vec_insert (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l =>
if to_Z i <? Z.of_nat (length l)
then Return (list_update l (usize_to_nat i) x)
else Fail_ Failure).
-(* The **backward** function shouldn't be used *)
-Definition vec_index_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
- end.
-
-Definition vec_index_back (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
-
-(* The **backward** function shouldn't be used *)
-Definition vec_index_mut_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
+(* Helper *)
+Axiom alloc_vec_Vec_index_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result T.
+
+(* Helper *)
+Axiom alloc_vec_Vec_update_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result (alloc_vec_Vec T).
+
+(* Trait declaration: [core::slice::index::private_slice_index::Sealed] *)
+Definition core_slice_index_private_slice_index_Sealed (self : Type) := unit.
+
+(* Trait declaration: [core::slice::index::SliceIndex] *)
+Record core_slice_index_SliceIndex (Self T : Type) := mk_core_slice_index_SliceIndex {
+ core_slice_index_SliceIndex_sealedInst : core_slice_index_private_slice_index_Sealed Self;
+ core_slice_index_SliceIndex_Output : Type;
+ core_slice_index_SliceIndex_get : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut_back : Self -> T -> option core_slice_index_SliceIndex_Output -> result T;
+ core_slice_index_SliceIndex_get_unchecked : Self -> const_raw_ptr T -> result (const_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_unchecked_mut : Self -> mut_raw_ptr T -> result (mut_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_index : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut_back : Self -> T -> core_slice_index_SliceIndex_Output -> result T;
+}.
+Arguments mk_core_slice_index_SliceIndex {_ _}.
+Arguments core_slice_index_SliceIndex_sealedInst {_ _}.
+Arguments core_slice_index_SliceIndex_Output {_ _}.
+Arguments core_slice_index_SliceIndex_get {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut_back {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut_back {_ _}.
+
+(* [core::slice::index::[T]::index]: forward function *)
+Definition core_slice_index_Slice_index
+ (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (s : slice T) (i : Idx) : result inst.(core_slice_index_SliceIndex_Output) :=
+ x <- inst.(core_slice_index_SliceIndex_get) i s;
+ match x with
+ | None => Fail_ Failure
+ | Some x => Return x
end.
-Definition vec_index_mut_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
- if to_Z i <? Z.of_nat (length l)
- then Return (list_update l (usize_to_nat i) x)
- else Fail_ Failure).
+(* [core::slice::index::Range:::get]: forward function *)
+Axiom core_slice_index_Range_get : forall (T : Type) (i : core_ops_range_Range usize) (s : slice T), result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: forward function *)
+Axiom core_slice_index_Range_get_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: backward function 0 *)
+Axiom core_slice_index_Range_get_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> option (slice T) -> result (slice T).
+
+(* [core::slice::index::Range::get_unchecked]: forward function *)
+Definition core_slice_index_Range_get_unchecked
+ (T : Type) :
+ core_ops_range_Range usize -> const_raw_ptr (slice T) -> result (const_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::get_unchecked_mut]: forward function *)
+Definition core_slice_index_Range_get_unchecked_mut
+ (T : Type) :
+ core_ops_range_Range usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::index]: forward function *)
+Axiom core_slice_index_Range_index :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: forward function *)
+Axiom core_slice_index_Range_index_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: backward function 0 *)
+Axiom core_slice_index_Range_index_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> slice T -> result (slice T).
+
+(* [core::slice::index::[T]::index_mut]: forward function *)
+Axiom core_slice_index_Slice_index_mut :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> result inst.(core_slice_index_SliceIndex_Output).
+
+(* [core::slice::index::[T]::index_mut]: backward function 0 *)
+Axiom core_slice_index_Slice_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> inst.(core_slice_index_SliceIndex_Output) -> result (slice T).
+
+(* [core::array::[T; N]::index]: forward function *)
+Axiom core_array_Array_index :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_Index (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: forward function *)
+Axiom core_array_Array_index_mut :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: backward function 0 *)
+Axiom core_array_Array_index_mut_back :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx) (x : inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output)), result (array T N).
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (slice T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := core_slice_index_Slice_index T Idx inst;
+|}.
+
+(* Trait implementation: [core::slice::index::private_slice_index::Range] *)
+Definition core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) := tt.
+
+(* Trait implementation: [core::slice::index::Range] *)
+Definition core_slice_index_Range_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := slice T;
+ core_slice_index_SliceIndex_get := core_slice_index_Range_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_Range_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_Range_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_Range_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_Range_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_Range_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_Range_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_Range_index_mut_back T;
+|}.
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (slice T) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_slice_index_Slice_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := core_slice_index_Slice_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := core_slice_index_Slice_index_mut_back T Idx inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_Index (slice T) Idx) :
+ core_ops_index_Index (array T N) Idx := {|
+ core_ops_index_Index_Output := inst.(core_ops_index_Index_Output);
+ core_ops_index_Index_index := core_array_Array_index T Idx N inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexMutInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_IndexMut (slice T) Idx) :
+ core_ops_index_IndexMut (array T N) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_array_Array_coreopsindexIndexInst T Idx N inst.(core_ops_index_IndexMut_indexInst);
+ core_ops_index_IndexMut_index_mut := core_array_Array_index_mut T Idx N inst;
+ core_ops_index_IndexMut_index_mut_back := core_array_Array_index_mut_back T Idx N inst;
+|}.
+
+(* [core::slice::index::usize::get]: forward function *)
+Axiom core_slice_index_usize_get : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: forward function *)
+Axiom core_slice_index_usize_get_mut : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: backward function 0 *)
+Axiom core_slice_index_usize_get_mut_back :
+ forall (T : Type), usize -> slice T -> option T -> result (slice T).
+
+(* [core::slice::index::usize::get_unchecked]: forward function *)
+Axiom core_slice_index_usize_get_unchecked :
+ forall (T : Type), usize -> const_raw_ptr (slice T) -> result (const_raw_ptr T).
+
+(* [core::slice::index::usize::get_unchecked_mut]: forward function *)
+Axiom core_slice_index_usize_get_unchecked_mut :
+ forall (T : Type), usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr T).
+
+(* [core::slice::index::usize::index]: forward function *)
+Axiom core_slice_index_usize_index : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: forward function *)
+Axiom core_slice_index_usize_index_mut : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: backward function 0 *)
+Axiom core_slice_index_usize_index_mut_back :
+ forall (T : Type), usize -> slice T -> T -> result (slice T).
+
+(* Trait implementation: [core::slice::index::private_slice_index::usize] *)
+Definition core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize := tt.
+
+(* Trait implementation: [core::slice::index::usize] *)
+Definition core_slice_index_usize_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex usize (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := T;
+ core_slice_index_SliceIndex_get := core_slice_index_usize_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_usize_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_usize_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_usize_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_usize_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_usize_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_usize_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_usize_index_mut_back T;
+|}.
+
+(* [alloc::vec::Vec::index]: forward function *)
+Axiom alloc_vec_Vec_index : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: forward function *)
+Axiom alloc_vec_Vec_index_mut : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: backward function 0 *)
+Axiom alloc_vec_Vec_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx) (x : inst.(core_slice_index_SliceIndex_Output)), result (alloc_vec_Vec T).
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (alloc_vec_Vec T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := alloc_vec_Vec_index T Idx inst;
+|}.
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (alloc_vec_Vec T) Idx := {|
+ core_ops_index_IndexMut_indexInst := alloc_vec_Vec_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := alloc_vec_Vec_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := alloc_vec_Vec_index_mut_back T Idx inst;
+|}.
+
+(*** Theorems *)
+
+Axiom alloc_vec_Vec_index_mut_back_eq : forall {a : Type} (v : alloc_vec_Vec a) (i : usize) (x : a),
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x =
+ alloc_vec_Vec_update_usize v i x.
End Primitives.
diff --git a/tests/coq/hashmap_on_disk/HashmapMain_Funs.v b/tests/coq/hashmap_on_disk/HashmapMain_Funs.v
index 657d5590..eac78186 100644
--- a/tests/coq/hashmap_on_disk/HashmapMain_Funs.v
+++ b/tests/coq/hashmap_on_disk/HashmapMain_Funs.v
@@ -13,656 +13,668 @@ Import HashmapMain_Opaque.
Module HashmapMain_Funs.
(** [hashmap_main::hashmap::hash_key]: forward function *)
-Definition hashmap_hash_key_fwd (k : usize) : result usize :=
+Definition hashmap_hash_key (k : usize) : result usize :=
Return k.
(** [hashmap_main::hashmap::HashMap::{0}::allocate_slots]: loop 0: forward function *)
-Fixpoint hashmap_hash_map_allocate_slots_loop_fwd
- (T : Type) (n : nat) (slots : vec (Hashmap_list_t T)) (n0 : usize) :
- result (vec (Hashmap_list_t T))
+Fixpoint hashmap_HashMap_allocate_slots_loop
+ (T : Type) (n : nat) (slots : alloc_vec_Vec (hashmap_List_t T)) (n0 : usize)
+ :
+ result (alloc_vec_Vec (hashmap_List_t T))
:=
match n with
| O => Fail_ OutOfFuel
| S n1 =>
if n0 s> 0%usize
then (
- slots0 <- vec_push_back (Hashmap_list_t T) slots HashmapListNil;
+ slots0 <- alloc_vec_Vec_push (hashmap_List_t T) slots Hashmap_List_Nil;
n2 <- usize_sub n0 1%usize;
- hashmap_hash_map_allocate_slots_loop_fwd T n1 slots0 n2)
+ hashmap_HashMap_allocate_slots_loop T n1 slots0 n2)
else Return slots
end
.
(** [hashmap_main::hashmap::HashMap::{0}::allocate_slots]: forward function *)
-Definition hashmap_hash_map_allocate_slots_fwd
- (T : Type) (n : nat) (slots : vec (Hashmap_list_t T)) (n0 : usize) :
- result (vec (Hashmap_list_t T))
+Definition hashmap_HashMap_allocate_slots
+ (T : Type) (n : nat) (slots : alloc_vec_Vec (hashmap_List_t T)) (n0 : usize)
+ :
+ result (alloc_vec_Vec (hashmap_List_t T))
:=
- hashmap_hash_map_allocate_slots_loop_fwd T n slots n0
+ hashmap_HashMap_allocate_slots_loop T n slots n0
.
(** [hashmap_main::hashmap::HashMap::{0}::new_with_capacity]: forward function *)
-Definition hashmap_hash_map_new_with_capacity_fwd
+Definition hashmap_HashMap_new_with_capacity
(T : Type) (n : nat) (capacity : usize) (max_load_dividend : usize)
(max_load_divisor : usize) :
- result (Hashmap_hash_map_t T)
+ result (hashmap_HashMap_t T)
:=
- let v := vec_new (Hashmap_list_t T) in
- slots <- hashmap_hash_map_allocate_slots_fwd T n v capacity;
+ let v := alloc_vec_Vec_new (hashmap_List_t T) in
+ slots <- hashmap_HashMap_allocate_slots T n v capacity;
i <- usize_mul capacity max_load_dividend;
i0 <- usize_div i max_load_divisor;
Return
{|
- Hashmap_hash_map_num_entries := 0%usize;
- Hashmap_hash_map_max_load_factor := (max_load_dividend, max_load_divisor);
- Hashmap_hash_map_max_load := i0;
- Hashmap_hash_map_slots := slots
+ hashmap_HashMap_num_entries := 0%usize;
+ hashmap_HashMap_max_load_factor := (max_load_dividend, max_load_divisor);
+ hashmap_HashMap_max_load := i0;
+ hashmap_HashMap_slots := slots
|}
.
(** [hashmap_main::hashmap::HashMap::{0}::new]: forward function *)
-Definition hashmap_hash_map_new_fwd
- (T : Type) (n : nat) : result (Hashmap_hash_map_t T) :=
- hashmap_hash_map_new_with_capacity_fwd T n 32%usize 4%usize 5%usize
+Definition hashmap_HashMap_new
+ (T : Type) (n : nat) : result (hashmap_HashMap_t T) :=
+ hashmap_HashMap_new_with_capacity T n 32%usize 4%usize 5%usize
.
(** [hashmap_main::hashmap::HashMap::{0}::clear]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint hashmap_hash_map_clear_loop_fwd_back
- (T : Type) (n : nat) (slots : vec (Hashmap_list_t T)) (i : usize) :
- result (vec (Hashmap_list_t T))
+Fixpoint hashmap_HashMap_clear_loop
+ (T : Type) (n : nat) (slots : alloc_vec_Vec (hashmap_List_t T)) (i : usize) :
+ result (alloc_vec_Vec (hashmap_List_t T))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- let i0 := vec_len (Hashmap_list_t T) slots in
+ let i0 := alloc_vec_Vec_len (hashmap_List_t T) slots in
if i s< i0
then (
i1 <- usize_add i 1%usize;
- slots0 <- vec_index_mut_back (Hashmap_list_t T) slots i HashmapListNil;
- hashmap_hash_map_clear_loop_fwd_back T n0 slots0 i1)
+ slots0 <-
+ alloc_vec_Vec_index_mut_back (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ T)) slots i Hashmap_List_Nil;
+ hashmap_HashMap_clear_loop T n0 slots0 i1)
else Return slots
end
.
(** [hashmap_main::hashmap::HashMap::{0}::clear]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hashmap_hash_map_clear_fwd_back
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) :
- result (Hashmap_hash_map_t T)
+Definition hashmap_HashMap_clear
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) :
+ result (hashmap_HashMap_t T)
:=
- v <-
- hashmap_hash_map_clear_loop_fwd_back T n self.(Hashmap_hash_map_slots)
- 0%usize;
+ v <- hashmap_HashMap_clear_loop T n self.(hashmap_HashMap_slots) 0%usize;
Return
{|
- Hashmap_hash_map_num_entries := 0%usize;
- Hashmap_hash_map_max_load_factor :=
- self.(Hashmap_hash_map_max_load_factor);
- Hashmap_hash_map_max_load := self.(Hashmap_hash_map_max_load);
- Hashmap_hash_map_slots := v
+ hashmap_HashMap_num_entries := 0%usize;
+ hashmap_HashMap_max_load_factor := self.(hashmap_HashMap_max_load_factor);
+ hashmap_HashMap_max_load := self.(hashmap_HashMap_max_load);
+ hashmap_HashMap_slots := v
|}
.
(** [hashmap_main::hashmap::HashMap::{0}::len]: forward function *)
-Definition hashmap_hash_map_len_fwd
- (T : Type) (self : Hashmap_hash_map_t T) : result usize :=
- Return self.(Hashmap_hash_map_num_entries)
+Definition hashmap_HashMap_len
+ (T : Type) (self : hashmap_HashMap_t T) : result usize :=
+ Return self.(hashmap_HashMap_num_entries)
.
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: loop 0: forward function *)
-Fixpoint hashmap_hash_map_insert_in_list_loop_fwd
- (T : Type) (n : nat) (key : usize) (value : T) (ls : Hashmap_list_t T) :
+Fixpoint hashmap_HashMap_insert_in_list_loop
+ (T : Type) (n : nat) (key : usize) (value : T) (ls : hashmap_List_t T) :
result bool
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons ckey cvalue tl =>
+ | Hashmap_List_Cons ckey cvalue tl =>
if ckey s= key
then Return false
- else hashmap_hash_map_insert_in_list_loop_fwd T n0 key value tl
- | HashmapListNil => Return true
+ else hashmap_HashMap_insert_in_list_loop T n0 key value tl
+ | Hashmap_List_Nil => Return true
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: forward function *)
-Definition hashmap_hash_map_insert_in_list_fwd
- (T : Type) (n : nat) (key : usize) (value : T) (ls : Hashmap_list_t T) :
+Definition hashmap_HashMap_insert_in_list
+ (T : Type) (n : nat) (key : usize) (value : T) (ls : hashmap_List_t T) :
result bool
:=
- hashmap_hash_map_insert_in_list_loop_fwd T n key value ls
+ hashmap_HashMap_insert_in_list_loop T n key value ls
.
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: loop 0: backward function 0 *)
-Fixpoint hashmap_hash_map_insert_in_list_loop_back
- (T : Type) (n : nat) (key : usize) (value : T) (ls : Hashmap_list_t T) :
- result (Hashmap_list_t T)
+Fixpoint hashmap_HashMap_insert_in_list_loop_back
+ (T : Type) (n : nat) (key : usize) (value : T) (ls : hashmap_List_t T) :
+ result (hashmap_List_t T)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons ckey cvalue tl =>
+ | Hashmap_List_Cons ckey cvalue tl =>
if ckey s= key
- then Return (HashmapListCons ckey value tl)
+ then Return (Hashmap_List_Cons ckey value tl)
else (
- tl0 <- hashmap_hash_map_insert_in_list_loop_back T n0 key value tl;
- Return (HashmapListCons ckey cvalue tl0))
- | HashmapListNil =>
- let l := HashmapListNil in Return (HashmapListCons key value l)
+ tl0 <- hashmap_HashMap_insert_in_list_loop_back T n0 key value tl;
+ Return (Hashmap_List_Cons ckey cvalue tl0))
+ | Hashmap_List_Nil =>
+ let l := Hashmap_List_Nil in Return (Hashmap_List_Cons key value l)
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: backward function 0 *)
-Definition hashmap_hash_map_insert_in_list_back
- (T : Type) (n : nat) (key : usize) (value : T) (ls : Hashmap_list_t T) :
- result (Hashmap_list_t T)
+Definition hashmap_HashMap_insert_in_list_back
+ (T : Type) (n : nat) (key : usize) (value : T) (ls : hashmap_List_t T) :
+ result (hashmap_List_t T)
:=
- hashmap_hash_map_insert_in_list_loop_back T n key value ls
+ hashmap_HashMap_insert_in_list_loop_back T n key value ls
.
(** [hashmap_main::hashmap::HashMap::{0}::insert_no_resize]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hashmap_hash_map_insert_no_resize_fwd_back
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) (key : usize) (value : T)
- :
- result (Hashmap_hash_map_t T)
+Definition hashmap_HashMap_insert_no_resize
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) (key : usize) (value : T) :
+ result (hashmap_HashMap_t T)
:=
- hash <- hashmap_hash_key_fwd key;
- let i := vec_len (Hashmap_list_t T) self.(Hashmap_hash_map_slots) in
+ hash <- hashmap_hash_key key;
+ let i := alloc_vec_Vec_len (hashmap_List_t T) self.(hashmap_HashMap_slots) in
hash_mod <- usize_rem hash i;
l <-
- vec_index_mut_fwd (Hashmap_list_t T) self.(Hashmap_hash_map_slots) hash_mod;
- inserted <- hashmap_hash_map_insert_in_list_fwd T n key value l;
+ alloc_vec_Vec_index_mut (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t T))
+ self.(hashmap_HashMap_slots) hash_mod;
+ inserted <- hashmap_HashMap_insert_in_list T n key value l;
if inserted
then (
- i0 <- usize_add self.(Hashmap_hash_map_num_entries) 1%usize;
- l0 <- hashmap_hash_map_insert_in_list_back T n key value l;
+ i0 <- usize_add self.(hashmap_HashMap_num_entries) 1%usize;
+ l0 <- hashmap_HashMap_insert_in_list_back T n key value l;
v <-
- vec_index_mut_back (Hashmap_list_t T) self.(Hashmap_hash_map_slots)
- hash_mod l0;
+ alloc_vec_Vec_index_mut_back (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ T)) self.(hashmap_HashMap_slots) hash_mod l0;
Return
{|
- Hashmap_hash_map_num_entries := i0;
- Hashmap_hash_map_max_load_factor :=
- self.(Hashmap_hash_map_max_load_factor);
- Hashmap_hash_map_max_load := self.(Hashmap_hash_map_max_load);
- Hashmap_hash_map_slots := v
+ hashmap_HashMap_num_entries := i0;
+ hashmap_HashMap_max_load_factor :=
+ self.(hashmap_HashMap_max_load_factor);
+ hashmap_HashMap_max_load := self.(hashmap_HashMap_max_load);
+ hashmap_HashMap_slots := v
|})
else (
- l0 <- hashmap_hash_map_insert_in_list_back T n key value l;
+ l0 <- hashmap_HashMap_insert_in_list_back T n key value l;
v <-
- vec_index_mut_back (Hashmap_list_t T) self.(Hashmap_hash_map_slots)
- hash_mod l0;
+ alloc_vec_Vec_index_mut_back (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ T)) self.(hashmap_HashMap_slots) hash_mod l0;
Return
{|
- Hashmap_hash_map_num_entries := self.(Hashmap_hash_map_num_entries);
- Hashmap_hash_map_max_load_factor :=
- self.(Hashmap_hash_map_max_load_factor);
- Hashmap_hash_map_max_load := self.(Hashmap_hash_map_max_load);
- Hashmap_hash_map_slots := v
+ hashmap_HashMap_num_entries := self.(hashmap_HashMap_num_entries);
+ hashmap_HashMap_max_load_factor :=
+ self.(hashmap_HashMap_max_load_factor);
+ hashmap_HashMap_max_load := self.(hashmap_HashMap_max_load);
+ hashmap_HashMap_slots := v
|})
.
-(** [core::num::u32::{8}::MAX] *)
-Definition core_num_u32_max_body : result u32 := Return 4294967295%u32.
-Definition core_num_u32_max_c : u32 := core_num_u32_max_body%global.
-
(** [hashmap_main::hashmap::HashMap::{0}::move_elements_from_list]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint hashmap_hash_map_move_elements_from_list_loop_fwd_back
- (T : Type) (n : nat) (ntable : Hashmap_hash_map_t T) (ls : Hashmap_list_t T)
- :
- result (Hashmap_hash_map_t T)
+Fixpoint hashmap_HashMap_move_elements_from_list_loop
+ (T : Type) (n : nat) (ntable : hashmap_HashMap_t T) (ls : hashmap_List_t T) :
+ result (hashmap_HashMap_t T)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons k v tl =>
- ntable0 <- hashmap_hash_map_insert_no_resize_fwd_back T n0 ntable k v;
- hashmap_hash_map_move_elements_from_list_loop_fwd_back T n0 ntable0 tl
- | HashmapListNil => Return ntable
+ | Hashmap_List_Cons k v tl =>
+ ntable0 <- hashmap_HashMap_insert_no_resize T n0 ntable k v;
+ hashmap_HashMap_move_elements_from_list_loop T n0 ntable0 tl
+ | Hashmap_List_Nil => Return ntable
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::move_elements_from_list]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hashmap_hash_map_move_elements_from_list_fwd_back
- (T : Type) (n : nat) (ntable : Hashmap_hash_map_t T) (ls : Hashmap_list_t T)
- :
- result (Hashmap_hash_map_t T)
+Definition hashmap_HashMap_move_elements_from_list
+ (T : Type) (n : nat) (ntable : hashmap_HashMap_t T) (ls : hashmap_List_t T) :
+ result (hashmap_HashMap_t T)
:=
- hashmap_hash_map_move_elements_from_list_loop_fwd_back T n ntable ls
+ hashmap_HashMap_move_elements_from_list_loop T n ntable ls
.
(** [hashmap_main::hashmap::HashMap::{0}::move_elements]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint hashmap_hash_map_move_elements_loop_fwd_back
- (T : Type) (n : nat) (ntable : Hashmap_hash_map_t T)
- (slots : vec (Hashmap_list_t T)) (i : usize) :
- result ((Hashmap_hash_map_t T) * (vec (Hashmap_list_t T)))
+Fixpoint hashmap_HashMap_move_elements_loop
+ (T : Type) (n : nat) (ntable : hashmap_HashMap_t T)
+ (slots : alloc_vec_Vec (hashmap_List_t T)) (i : usize) :
+ result ((hashmap_HashMap_t T) * (alloc_vec_Vec (hashmap_List_t T)))
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- let i0 := vec_len (Hashmap_list_t T) slots in
+ let i0 := alloc_vec_Vec_len (hashmap_List_t T) slots in
if i s< i0
then (
- l <- vec_index_mut_fwd (Hashmap_list_t T) slots i;
- let ls := mem_replace_fwd (Hashmap_list_t T) l HashmapListNil in
- ntable0 <-
- hashmap_hash_map_move_elements_from_list_fwd_back T n0 ntable ls;
+ l <-
+ alloc_vec_Vec_index_mut (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ T)) slots i;
+ let ls := core_mem_replace (hashmap_List_t T) l Hashmap_List_Nil in
+ ntable0 <- hashmap_HashMap_move_elements_from_list T n0 ntable ls;
i1 <- usize_add i 1%usize;
- let l0 := mem_replace_back (Hashmap_list_t T) l HashmapListNil in
- slots0 <- vec_index_mut_back (Hashmap_list_t T) slots i l0;
- hashmap_hash_map_move_elements_loop_fwd_back T n0 ntable0 slots0 i1)
+ let l0 := core_mem_replace_back (hashmap_List_t T) l Hashmap_List_Nil in
+ slots0 <-
+ alloc_vec_Vec_index_mut_back (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ T)) slots i l0;
+ hashmap_HashMap_move_elements_loop T n0 ntable0 slots0 i1)
else Return (ntable, slots)
end
.
(** [hashmap_main::hashmap::HashMap::{0}::move_elements]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hashmap_hash_map_move_elements_fwd_back
- (T : Type) (n : nat) (ntable : Hashmap_hash_map_t T)
- (slots : vec (Hashmap_list_t T)) (i : usize) :
- result ((Hashmap_hash_map_t T) * (vec (Hashmap_list_t T)))
+Definition hashmap_HashMap_move_elements
+ (T : Type) (n : nat) (ntable : hashmap_HashMap_t T)
+ (slots : alloc_vec_Vec (hashmap_List_t T)) (i : usize) :
+ result ((hashmap_HashMap_t T) * (alloc_vec_Vec (hashmap_List_t T)))
:=
- hashmap_hash_map_move_elements_loop_fwd_back T n ntable slots i
+ hashmap_HashMap_move_elements_loop T n ntable slots i
.
(** [hashmap_main::hashmap::HashMap::{0}::try_resize]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hashmap_hash_map_try_resize_fwd_back
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) :
- result (Hashmap_hash_map_t T)
+Definition hashmap_HashMap_try_resize
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) :
+ result (hashmap_HashMap_t T)
:=
- max_usize <- scalar_cast U32 Usize core_num_u32_max_c;
- let capacity := vec_len (Hashmap_list_t T) self.(Hashmap_hash_map_slots) in
+ max_usize <- scalar_cast U32 Usize core_u32_max;
+ let capacity :=
+ alloc_vec_Vec_len (hashmap_List_t T) self.(hashmap_HashMap_slots) in
n1 <- usize_div max_usize 2%usize;
- let (i, i0) := self.(Hashmap_hash_map_max_load_factor) in
+ let (i, i0) := self.(hashmap_HashMap_max_load_factor) in
i1 <- usize_div n1 i;
if capacity s<= i1
then (
i2 <- usize_mul capacity 2%usize;
- ntable <- hashmap_hash_map_new_with_capacity_fwd T n i2 i i0;
+ ntable <- hashmap_HashMap_new_with_capacity T n i2 i i0;
p <-
- hashmap_hash_map_move_elements_fwd_back T n ntable
- self.(Hashmap_hash_map_slots) 0%usize;
+ hashmap_HashMap_move_elements T n ntable self.(hashmap_HashMap_slots)
+ 0%usize;
let (ntable0, _) := p in
Return
{|
- Hashmap_hash_map_num_entries := self.(Hashmap_hash_map_num_entries);
- Hashmap_hash_map_max_load_factor := (i, i0);
- Hashmap_hash_map_max_load := ntable0.(Hashmap_hash_map_max_load);
- Hashmap_hash_map_slots := ntable0.(Hashmap_hash_map_slots)
+ hashmap_HashMap_num_entries := self.(hashmap_HashMap_num_entries);
+ hashmap_HashMap_max_load_factor := (i, i0);
+ hashmap_HashMap_max_load := ntable0.(hashmap_HashMap_max_load);
+ hashmap_HashMap_slots := ntable0.(hashmap_HashMap_slots)
|})
else
Return
{|
- Hashmap_hash_map_num_entries := self.(Hashmap_hash_map_num_entries);
- Hashmap_hash_map_max_load_factor := (i, i0);
- Hashmap_hash_map_max_load := self.(Hashmap_hash_map_max_load);
- Hashmap_hash_map_slots := self.(Hashmap_hash_map_slots)
+ hashmap_HashMap_num_entries := self.(hashmap_HashMap_num_entries);
+ hashmap_HashMap_max_load_factor := (i, i0);
+ hashmap_HashMap_max_load := self.(hashmap_HashMap_max_load);
+ hashmap_HashMap_slots := self.(hashmap_HashMap_slots)
|}
.
(** [hashmap_main::hashmap::HashMap::{0}::insert]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition hashmap_hash_map_insert_fwd_back
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) (key : usize) (value : T)
- :
- result (Hashmap_hash_map_t T)
+Definition hashmap_HashMap_insert
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) (key : usize) (value : T) :
+ result (hashmap_HashMap_t T)
:=
- self0 <- hashmap_hash_map_insert_no_resize_fwd_back T n self key value;
- i <- hashmap_hash_map_len_fwd T self0;
- if i s> self0.(Hashmap_hash_map_max_load)
- then hashmap_hash_map_try_resize_fwd_back T n self0
+ self0 <- hashmap_HashMap_insert_no_resize T n self key value;
+ i <- hashmap_HashMap_len T self0;
+ if i s> self0.(hashmap_HashMap_max_load)
+ then hashmap_HashMap_try_resize T n self0
else Return self0
.
(** [hashmap_main::hashmap::HashMap::{0}::contains_key_in_list]: loop 0: forward function *)
-Fixpoint hashmap_hash_map_contains_key_in_list_loop_fwd
- (T : Type) (n : nat) (key : usize) (ls : Hashmap_list_t T) : result bool :=
+Fixpoint hashmap_HashMap_contains_key_in_list_loop
+ (T : Type) (n : nat) (key : usize) (ls : hashmap_List_t T) : result bool :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons ckey t tl =>
+ | Hashmap_List_Cons ckey t tl =>
if ckey s= key
then Return true
- else hashmap_hash_map_contains_key_in_list_loop_fwd T n0 key tl
- | HashmapListNil => Return false
+ else hashmap_HashMap_contains_key_in_list_loop T n0 key tl
+ | Hashmap_List_Nil => Return false
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::contains_key_in_list]: forward function *)
-Definition hashmap_hash_map_contains_key_in_list_fwd
- (T : Type) (n : nat) (key : usize) (ls : Hashmap_list_t T) : result bool :=
- hashmap_hash_map_contains_key_in_list_loop_fwd T n key ls
+Definition hashmap_HashMap_contains_key_in_list
+ (T : Type) (n : nat) (key : usize) (ls : hashmap_List_t T) : result bool :=
+ hashmap_HashMap_contains_key_in_list_loop T n key ls
.
(** [hashmap_main::hashmap::HashMap::{0}::contains_key]: forward function *)
-Definition hashmap_hash_map_contains_key_fwd
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) (key : usize) :
+Definition hashmap_HashMap_contains_key
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) (key : usize) :
result bool
:=
- hash <- hashmap_hash_key_fwd key;
- let i := vec_len (Hashmap_list_t T) self.(Hashmap_hash_map_slots) in
+ hash <- hashmap_hash_key key;
+ let i := alloc_vec_Vec_len (hashmap_List_t T) self.(hashmap_HashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_fwd (Hashmap_list_t T) self.(Hashmap_hash_map_slots) hash_mod;
- hashmap_hash_map_contains_key_in_list_fwd T n key l
+ l <-
+ alloc_vec_Vec_index (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t T))
+ self.(hashmap_HashMap_slots) hash_mod;
+ hashmap_HashMap_contains_key_in_list T n key l
.
(** [hashmap_main::hashmap::HashMap::{0}::get_in_list]: loop 0: forward function *)
-Fixpoint hashmap_hash_map_get_in_list_loop_fwd
- (T : Type) (n : nat) (key : usize) (ls : Hashmap_list_t T) : result T :=
+Fixpoint hashmap_HashMap_get_in_list_loop
+ (T : Type) (n : nat) (key : usize) (ls : hashmap_List_t T) : result T :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons ckey cvalue tl =>
+ | Hashmap_List_Cons ckey cvalue tl =>
if ckey s= key
then Return cvalue
- else hashmap_hash_map_get_in_list_loop_fwd T n0 key tl
- | HashmapListNil => Fail_ Failure
+ else hashmap_HashMap_get_in_list_loop T n0 key tl
+ | Hashmap_List_Nil => Fail_ Failure
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::get_in_list]: forward function *)
-Definition hashmap_hash_map_get_in_list_fwd
- (T : Type) (n : nat) (key : usize) (ls : Hashmap_list_t T) : result T :=
- hashmap_hash_map_get_in_list_loop_fwd T n key ls
+Definition hashmap_HashMap_get_in_list
+ (T : Type) (n : nat) (key : usize) (ls : hashmap_List_t T) : result T :=
+ hashmap_HashMap_get_in_list_loop T n key ls
.
(** [hashmap_main::hashmap::HashMap::{0}::get]: forward function *)
-Definition hashmap_hash_map_get_fwd
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) (key : usize) :
- result T
- :=
- hash <- hashmap_hash_key_fwd key;
- let i := vec_len (Hashmap_list_t T) self.(Hashmap_hash_map_slots) in
+Definition hashmap_HashMap_get
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) (key : usize) : result T :=
+ hash <- hashmap_hash_key key;
+ let i := alloc_vec_Vec_len (hashmap_List_t T) self.(hashmap_HashMap_slots) in
hash_mod <- usize_rem hash i;
- l <- vec_index_fwd (Hashmap_list_t T) self.(Hashmap_hash_map_slots) hash_mod;
- hashmap_hash_map_get_in_list_fwd T n key l
+ l <-
+ alloc_vec_Vec_index (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t T))
+ self.(hashmap_HashMap_slots) hash_mod;
+ hashmap_HashMap_get_in_list T n key l
.
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: loop 0: forward function *)
-Fixpoint hashmap_hash_map_get_mut_in_list_loop_fwd
- (T : Type) (n : nat) (ls : Hashmap_list_t T) (key : usize) : result T :=
+Fixpoint hashmap_HashMap_get_mut_in_list_loop
+ (T : Type) (n : nat) (ls : hashmap_List_t T) (key : usize) : result T :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons ckey cvalue tl =>
+ | Hashmap_List_Cons ckey cvalue tl =>
if ckey s= key
then Return cvalue
- else hashmap_hash_map_get_mut_in_list_loop_fwd T n0 tl key
- | HashmapListNil => Fail_ Failure
+ else hashmap_HashMap_get_mut_in_list_loop T n0 tl key
+ | Hashmap_List_Nil => Fail_ Failure
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: forward function *)
-Definition hashmap_hash_map_get_mut_in_list_fwd
- (T : Type) (n : nat) (ls : Hashmap_list_t T) (key : usize) : result T :=
- hashmap_hash_map_get_mut_in_list_loop_fwd T n ls key
+Definition hashmap_HashMap_get_mut_in_list
+ (T : Type) (n : nat) (ls : hashmap_List_t T) (key : usize) : result T :=
+ hashmap_HashMap_get_mut_in_list_loop T n ls key
.
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: loop 0: backward function 0 *)
-Fixpoint hashmap_hash_map_get_mut_in_list_loop_back
- (T : Type) (n : nat) (ls : Hashmap_list_t T) (key : usize) (ret : T) :
- result (Hashmap_list_t T)
+Fixpoint hashmap_HashMap_get_mut_in_list_loop_back
+ (T : Type) (n : nat) (ls : hashmap_List_t T) (key : usize) (ret : T) :
+ result (hashmap_List_t T)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons ckey cvalue tl =>
+ | Hashmap_List_Cons ckey cvalue tl =>
if ckey s= key
- then Return (HashmapListCons ckey ret tl)
+ then Return (Hashmap_List_Cons ckey ret tl)
else (
- tl0 <- hashmap_hash_map_get_mut_in_list_loop_back T n0 tl key ret;
- Return (HashmapListCons ckey cvalue tl0))
- | HashmapListNil => Fail_ Failure
+ tl0 <- hashmap_HashMap_get_mut_in_list_loop_back T n0 tl key ret;
+ Return (Hashmap_List_Cons ckey cvalue tl0))
+ | Hashmap_List_Nil => Fail_ Failure
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: backward function 0 *)
-Definition hashmap_hash_map_get_mut_in_list_back
- (T : Type) (n : nat) (ls : Hashmap_list_t T) (key : usize) (ret : T) :
- result (Hashmap_list_t T)
+Definition hashmap_HashMap_get_mut_in_list_back
+ (T : Type) (n : nat) (ls : hashmap_List_t T) (key : usize) (ret : T) :
+ result (hashmap_List_t T)
:=
- hashmap_hash_map_get_mut_in_list_loop_back T n ls key ret
+ hashmap_HashMap_get_mut_in_list_loop_back T n ls key ret
.
(** [hashmap_main::hashmap::HashMap::{0}::get_mut]: forward function *)
-Definition hashmap_hash_map_get_mut_fwd
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) (key : usize) :
- result T
- :=
- hash <- hashmap_hash_key_fwd key;
- let i := vec_len (Hashmap_list_t T) self.(Hashmap_hash_map_slots) in
+Definition hashmap_HashMap_get_mut
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) (key : usize) : result T :=
+ hash <- hashmap_hash_key key;
+ let i := alloc_vec_Vec_len (hashmap_List_t T) self.(hashmap_HashMap_slots) in
hash_mod <- usize_rem hash i;
l <-
- vec_index_mut_fwd (Hashmap_list_t T) self.(Hashmap_hash_map_slots) hash_mod;
- hashmap_hash_map_get_mut_in_list_fwd T n l key
+ alloc_vec_Vec_index_mut (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t T))
+ self.(hashmap_HashMap_slots) hash_mod;
+ hashmap_HashMap_get_mut_in_list T n l key
.
(** [hashmap_main::hashmap::HashMap::{0}::get_mut]: backward function 0 *)
-Definition hashmap_hash_map_get_mut_back
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) (key : usize) (ret : T) :
- result (Hashmap_hash_map_t T)
+Definition hashmap_HashMap_get_mut_back
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) (key : usize) (ret : T) :
+ result (hashmap_HashMap_t T)
:=
- hash <- hashmap_hash_key_fwd key;
- let i := vec_len (Hashmap_list_t T) self.(Hashmap_hash_map_slots) in
+ hash <- hashmap_hash_key key;
+ let i := alloc_vec_Vec_len (hashmap_List_t T) self.(hashmap_HashMap_slots) in
hash_mod <- usize_rem hash i;
l <-
- vec_index_mut_fwd (Hashmap_list_t T) self.(Hashmap_hash_map_slots) hash_mod;
- l0 <- hashmap_hash_map_get_mut_in_list_back T n l key ret;
+ alloc_vec_Vec_index_mut (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t T))
+ self.(hashmap_HashMap_slots) hash_mod;
+ l0 <- hashmap_HashMap_get_mut_in_list_back T n l key ret;
v <-
- vec_index_mut_back (Hashmap_list_t T) self.(Hashmap_hash_map_slots)
- hash_mod l0;
+ alloc_vec_Vec_index_mut_back (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t T))
+ self.(hashmap_HashMap_slots) hash_mod l0;
Return
{|
- Hashmap_hash_map_num_entries := self.(Hashmap_hash_map_num_entries);
- Hashmap_hash_map_max_load_factor :=
- self.(Hashmap_hash_map_max_load_factor);
- Hashmap_hash_map_max_load := self.(Hashmap_hash_map_max_load);
- Hashmap_hash_map_slots := v
+ hashmap_HashMap_num_entries := self.(hashmap_HashMap_num_entries);
+ hashmap_HashMap_max_load_factor := self.(hashmap_HashMap_max_load_factor);
+ hashmap_HashMap_max_load := self.(hashmap_HashMap_max_load);
+ hashmap_HashMap_slots := v
|}
.
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: loop 0: forward function *)
-Fixpoint hashmap_hash_map_remove_from_list_loop_fwd
- (T : Type) (n : nat) (key : usize) (ls : Hashmap_list_t T) :
+Fixpoint hashmap_HashMap_remove_from_list_loop
+ (T : Type) (n : nat) (key : usize) (ls : hashmap_List_t T) :
result (option T)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons ckey t tl =>
+ | Hashmap_List_Cons ckey t tl =>
if ckey s= key
then
let mv_ls :=
- mem_replace_fwd (Hashmap_list_t T) (HashmapListCons ckey t tl)
- HashmapListNil in
+ core_mem_replace (hashmap_List_t T) (Hashmap_List_Cons ckey t tl)
+ Hashmap_List_Nil in
match mv_ls with
- | HashmapListCons i cvalue tl0 => Return (Some cvalue)
- | HashmapListNil => Fail_ Failure
+ | Hashmap_List_Cons i cvalue tl0 => Return (Some cvalue)
+ | Hashmap_List_Nil => Fail_ Failure
end
- else hashmap_hash_map_remove_from_list_loop_fwd T n0 key tl
- | HashmapListNil => Return None
+ else hashmap_HashMap_remove_from_list_loop T n0 key tl
+ | Hashmap_List_Nil => Return None
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: forward function *)
-Definition hashmap_hash_map_remove_from_list_fwd
- (T : Type) (n : nat) (key : usize) (ls : Hashmap_list_t T) :
+Definition hashmap_HashMap_remove_from_list
+ (T : Type) (n : nat) (key : usize) (ls : hashmap_List_t T) :
result (option T)
:=
- hashmap_hash_map_remove_from_list_loop_fwd T n key ls
+ hashmap_HashMap_remove_from_list_loop T n key ls
.
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: loop 0: backward function 1 *)
-Fixpoint hashmap_hash_map_remove_from_list_loop_back
- (T : Type) (n : nat) (key : usize) (ls : Hashmap_list_t T) :
- result (Hashmap_list_t T)
+Fixpoint hashmap_HashMap_remove_from_list_loop_back
+ (T : Type) (n : nat) (key : usize) (ls : hashmap_List_t T) :
+ result (hashmap_List_t T)
:=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | HashmapListCons ckey t tl =>
+ | Hashmap_List_Cons ckey t tl =>
if ckey s= key
then
let mv_ls :=
- mem_replace_fwd (Hashmap_list_t T) (HashmapListCons ckey t tl)
- HashmapListNil in
+ core_mem_replace (hashmap_List_t T) (Hashmap_List_Cons ckey t tl)
+ Hashmap_List_Nil in
match mv_ls with
- | HashmapListCons i cvalue tl0 => Return tl0
- | HashmapListNil => Fail_ Failure
+ | Hashmap_List_Cons i cvalue tl0 => Return tl0
+ | Hashmap_List_Nil => Fail_ Failure
end
else (
- tl0 <- hashmap_hash_map_remove_from_list_loop_back T n0 key tl;
- Return (HashmapListCons ckey t tl0))
- | HashmapListNil => Return HashmapListNil
+ tl0 <- hashmap_HashMap_remove_from_list_loop_back T n0 key tl;
+ Return (Hashmap_List_Cons ckey t tl0))
+ | Hashmap_List_Nil => Return Hashmap_List_Nil
end
end
.
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: backward function 1 *)
-Definition hashmap_hash_map_remove_from_list_back
- (T : Type) (n : nat) (key : usize) (ls : Hashmap_list_t T) :
- result (Hashmap_list_t T)
+Definition hashmap_HashMap_remove_from_list_back
+ (T : Type) (n : nat) (key : usize) (ls : hashmap_List_t T) :
+ result (hashmap_List_t T)
:=
- hashmap_hash_map_remove_from_list_loop_back T n key ls
+ hashmap_HashMap_remove_from_list_loop_back T n key ls
.
(** [hashmap_main::hashmap::HashMap::{0}::remove]: forward function *)
-Definition hashmap_hash_map_remove_fwd
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) (key : usize) :
+Definition hashmap_HashMap_remove
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) (key : usize) :
result (option T)
:=
- hash <- hashmap_hash_key_fwd key;
- let i := vec_len (Hashmap_list_t T) self.(Hashmap_hash_map_slots) in
+ hash <- hashmap_hash_key key;
+ let i := alloc_vec_Vec_len (hashmap_List_t T) self.(hashmap_HashMap_slots) in
hash_mod <- usize_rem hash i;
l <-
- vec_index_mut_fwd (Hashmap_list_t T) self.(Hashmap_hash_map_slots) hash_mod;
- x <- hashmap_hash_map_remove_from_list_fwd T n key l;
+ alloc_vec_Vec_index_mut (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t T))
+ self.(hashmap_HashMap_slots) hash_mod;
+ x <- hashmap_HashMap_remove_from_list T n key l;
match x with
| None => Return None
| Some x0 =>
- _ <- usize_sub self.(Hashmap_hash_map_num_entries) 1%usize;
- Return (Some x0)
+ _ <- usize_sub self.(hashmap_HashMap_num_entries) 1%usize; Return (Some x0)
end
.
(** [hashmap_main::hashmap::HashMap::{0}::remove]: backward function 0 *)
-Definition hashmap_hash_map_remove_back
- (T : Type) (n : nat) (self : Hashmap_hash_map_t T) (key : usize) :
- result (Hashmap_hash_map_t T)
+Definition hashmap_HashMap_remove_back
+ (T : Type) (n : nat) (self : hashmap_HashMap_t T) (key : usize) :
+ result (hashmap_HashMap_t T)
:=
- hash <- hashmap_hash_key_fwd key;
- let i := vec_len (Hashmap_list_t T) self.(Hashmap_hash_map_slots) in
+ hash <- hashmap_hash_key key;
+ let i := alloc_vec_Vec_len (hashmap_List_t T) self.(hashmap_HashMap_slots) in
hash_mod <- usize_rem hash i;
l <-
- vec_index_mut_fwd (Hashmap_list_t T) self.(Hashmap_hash_map_slots) hash_mod;
- x <- hashmap_hash_map_remove_from_list_fwd T n key l;
+ alloc_vec_Vec_index_mut (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t T))
+ self.(hashmap_HashMap_slots) hash_mod;
+ x <- hashmap_HashMap_remove_from_list T n key l;
match x with
| None =>
- l0 <- hashmap_hash_map_remove_from_list_back T n key l;
+ l0 <- hashmap_HashMap_remove_from_list_back T n key l;
v <-
- vec_index_mut_back (Hashmap_list_t T) self.(Hashmap_hash_map_slots)
- hash_mod l0;
+ alloc_vec_Vec_index_mut_back (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ T)) self.(hashmap_HashMap_slots) hash_mod l0;
Return
{|
- Hashmap_hash_map_num_entries := self.(Hashmap_hash_map_num_entries);
- Hashmap_hash_map_max_load_factor :=
- self.(Hashmap_hash_map_max_load_factor);
- Hashmap_hash_map_max_load := self.(Hashmap_hash_map_max_load);
- Hashmap_hash_map_slots := v
+ hashmap_HashMap_num_entries := self.(hashmap_HashMap_num_entries);
+ hashmap_HashMap_max_load_factor :=
+ self.(hashmap_HashMap_max_load_factor);
+ hashmap_HashMap_max_load := self.(hashmap_HashMap_max_load);
+ hashmap_HashMap_slots := v
|}
| Some x0 =>
- i0 <- usize_sub self.(Hashmap_hash_map_num_entries) 1%usize;
- l0 <- hashmap_hash_map_remove_from_list_back T n key l;
+ i0 <- usize_sub self.(hashmap_HashMap_num_entries) 1%usize;
+ l0 <- hashmap_HashMap_remove_from_list_back T n key l;
v <-
- vec_index_mut_back (Hashmap_list_t T) self.(Hashmap_hash_map_slots)
- hash_mod l0;
+ alloc_vec_Vec_index_mut_back (hashmap_List_t T) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ T)) self.(hashmap_HashMap_slots) hash_mod l0;
Return
{|
- Hashmap_hash_map_num_entries := i0;
- Hashmap_hash_map_max_load_factor :=
- self.(Hashmap_hash_map_max_load_factor);
- Hashmap_hash_map_max_load := self.(Hashmap_hash_map_max_load);
- Hashmap_hash_map_slots := v
+ hashmap_HashMap_num_entries := i0;
+ hashmap_HashMap_max_load_factor :=
+ self.(hashmap_HashMap_max_load_factor);
+ hashmap_HashMap_max_load := self.(hashmap_HashMap_max_load);
+ hashmap_HashMap_slots := v
|}
end
.
(** [hashmap_main::hashmap::test1]: forward function *)
-Definition hashmap_test1_fwd (n : nat) : result unit :=
- hm <- hashmap_hash_map_new_fwd u64 n;
- hm0 <- hashmap_hash_map_insert_fwd_back u64 n hm 0%usize 42%u64;
- hm1 <- hashmap_hash_map_insert_fwd_back u64 n hm0 128%usize 18%u64;
- hm2 <- hashmap_hash_map_insert_fwd_back u64 n hm1 1024%usize 138%u64;
- hm3 <- hashmap_hash_map_insert_fwd_back u64 n hm2 1056%usize 256%u64;
- i <- hashmap_hash_map_get_fwd u64 n hm3 128%usize;
+Definition hashmap_test1 (n : nat) : result unit :=
+ hm <- hashmap_HashMap_new u64 n;
+ hm0 <- hashmap_HashMap_insert u64 n hm 0%usize 42%u64;
+ hm1 <- hashmap_HashMap_insert u64 n hm0 128%usize 18%u64;
+ hm2 <- hashmap_HashMap_insert u64 n hm1 1024%usize 138%u64;
+ hm3 <- hashmap_HashMap_insert u64 n hm2 1056%usize 256%u64;
+ i <- hashmap_HashMap_get u64 n hm3 128%usize;
if negb (i s= 18%u64)
then Fail_ Failure
else (
- hm4 <- hashmap_hash_map_get_mut_back u64 n hm3 1024%usize 56%u64;
- i0 <- hashmap_hash_map_get_fwd u64 n hm4 1024%usize;
+ hm4 <- hashmap_HashMap_get_mut_back u64 n hm3 1024%usize 56%u64;
+ i0 <- hashmap_HashMap_get u64 n hm4 1024%usize;
if negb (i0 s= 56%u64)
then Fail_ Failure
else (
- x <- hashmap_hash_map_remove_fwd u64 n hm4 1024%usize;
+ x <- hashmap_HashMap_remove u64 n hm4 1024%usize;
match x with
| None => Fail_ Failure
| Some x0 =>
if negb (x0 s= 56%u64)
then Fail_ Failure
else (
- hm5 <- hashmap_hash_map_remove_back u64 n hm4 1024%usize;
- i1 <- hashmap_hash_map_get_fwd u64 n hm5 0%usize;
+ hm5 <- hashmap_HashMap_remove_back u64 n hm4 1024%usize;
+ i1 <- hashmap_HashMap_get u64 n hm5 0%usize;
if negb (i1 s= 42%u64)
then Fail_ Failure
else (
- i2 <- hashmap_hash_map_get_fwd u64 n hm5 128%usize;
+ i2 <- hashmap_HashMap_get u64 n hm5 128%usize;
if negb (i2 s= 18%u64)
then Fail_ Failure
else (
- i3 <- hashmap_hash_map_get_fwd u64 n hm5 1056%usize;
+ i3 <- hashmap_HashMap_get u64 n hm5 1056%usize;
if negb (i3 s= 256%u64) then Fail_ Failure else Return tt)))
end))
.
(** [hashmap_main::insert_on_disk]: forward function *)
-Definition insert_on_disk_fwd
+Definition insert_on_disk
(n : nat) (key : usize) (value : u64) (st : state) : result (state * unit) :=
- p <- hashmap_utils_deserialize_fwd st;
+ p <- hashmap_utils_deserialize st;
let (st0, hm) := p in
- hm0 <- hashmap_hash_map_insert_fwd_back u64 n hm key value;
- p0 <- hashmap_utils_serialize_fwd hm0 st0;
+ hm0 <- hashmap_HashMap_insert u64 n hm key value;
+ p0 <- hashmap_utils_serialize hm0 st0;
let (st1, _) := p0 in
Return (st1, tt)
.
(** [hashmap_main::main]: forward function *)
-Definition main_fwd : result unit :=
+Definition main : result unit :=
Return tt.
-(** Unit test for [hashmap_main::main] *)
-Check (main_fwd )%return.
-
End HashmapMain_Funs .
diff --git a/tests/coq/hashmap_on_disk/HashmapMain_Opaque.v b/tests/coq/hashmap_on_disk/HashmapMain_Opaque.v
index 2d17cc29..5e376239 100644
--- a/tests/coq/hashmap_on_disk/HashmapMain_Opaque.v
+++ b/tests/coq/hashmap_on_disk/HashmapMain_Opaque.v
@@ -11,13 +11,13 @@ Import HashmapMain_Types.
Module HashmapMain_Opaque.
(** [hashmap_main::hashmap_utils::deserialize]: forward function *)
-Axiom hashmap_utils_deserialize_fwd
- : state -> result (state * (Hashmap_hash_map_t u64))
+Axiom hashmap_utils_deserialize
+ : state -> result (state * (hashmap_HashMap_t u64))
.
(** [hashmap_main::hashmap_utils::serialize]: forward function *)
-Axiom hashmap_utils_serialize_fwd
- : Hashmap_hash_map_t u64 -> state -> result (state * unit)
+Axiom hashmap_utils_serialize
+ : hashmap_HashMap_t u64 -> state -> result (state * unit)
.
End HashmapMain_Opaque .
diff --git a/tests/coq/hashmap_on_disk/HashmapMain_Types.v b/tests/coq/hashmap_on_disk/HashmapMain_Types.v
index 36aaaf25..95e5f35b 100644
--- a/tests/coq/hashmap_on_disk/HashmapMain_Types.v
+++ b/tests/coq/hashmap_on_disk/HashmapMain_Types.v
@@ -9,29 +9,29 @@ Local Open Scope Primitives_scope.
Module HashmapMain_Types.
(** [hashmap_main::hashmap::List] *)
-Inductive Hashmap_list_t (T : Type) :=
-| HashmapListCons : usize -> T -> Hashmap_list_t T -> Hashmap_list_t T
-| HashmapListNil : Hashmap_list_t T
+Inductive hashmap_List_t (T : Type) :=
+| Hashmap_List_Cons : usize -> T -> hashmap_List_t T -> hashmap_List_t T
+| Hashmap_List_Nil : hashmap_List_t T
.
-Arguments HashmapListCons {T} _ _ _.
-Arguments HashmapListNil {T}.
+Arguments Hashmap_List_Cons { _ }.
+Arguments Hashmap_List_Nil { _ }.
(** [hashmap_main::hashmap::HashMap] *)
-Record Hashmap_hash_map_t (T : Type) :=
-mkHashmap_hash_map_t {
- Hashmap_hash_map_num_entries : usize;
- Hashmap_hash_map_max_load_factor : (usize * usize);
- Hashmap_hash_map_max_load : usize;
- Hashmap_hash_map_slots : vec (Hashmap_list_t T);
+Record hashmap_HashMap_t (T : Type) :=
+mkhashmap_HashMap_t {
+ hashmap_HashMap_num_entries : usize;
+ hashmap_HashMap_max_load_factor : (usize * usize);
+ hashmap_HashMap_max_load : usize;
+ hashmap_HashMap_slots : alloc_vec_Vec (hashmap_List_t T);
}
.
-Arguments mkHashmap_hash_map_t {T} _ _ _ _.
-Arguments Hashmap_hash_map_num_entries {T}.
-Arguments Hashmap_hash_map_max_load_factor {T}.
-Arguments Hashmap_hash_map_max_load {T}.
-Arguments Hashmap_hash_map_slots {T}.
+Arguments mkhashmap_HashMap_t { _ }.
+Arguments hashmap_HashMap_num_entries { _ }.
+Arguments hashmap_HashMap_max_load_factor { _ }.
+Arguments hashmap_HashMap_max_load { _ }.
+Arguments hashmap_HashMap_slots { _ }.
(** The state type used in the state-error monad *)
Axiom state : Type.
diff --git a/tests/coq/hashmap_on_disk/Primitives.v b/tests/coq/hashmap_on_disk/Primitives.v
index 71a2d9c3..85e38f01 100644
--- a/tests/coq/hashmap_on_disk/Primitives.v
+++ b/tests/coq/hashmap_on_disk/Primitives.v
@@ -63,13 +63,15 @@ Check (if true then Return (1 + 2) else Fail_ Failure)%global = 3.
(*** Misc *)
-
Definition string := Coq.Strings.String.string.
Definition char := Coq.Strings.Ascii.ascii.
Definition char_of_byte := Coq.Strings.Ascii.ascii_of_byte.
-Definition mem_replace_fwd (a : Type) (x : a) (y : a) : a := x .
-Definition mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+Definition core_mem_replace (a : Type) (x : a) (y : a) : a := x .
+Definition core_mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+
+Record mut_raw_ptr (T : Type) := { mut_raw_ptr_v : T }.
+Record const_raw_ptr (T : Type) := { const_raw_ptr_v : T }.
(*** Scalars *)
@@ -394,12 +396,89 @@ Notation "x s< y" := (scalar_ltb x y) (at level 80) : Primitives_scope.
Notation "x s>= y" := (scalar_geb x y) (at level 80) : Primitives_scope.
Notation "x s> y" := (scalar_gtb x y) (at level 80) : Primitives_scope.
-(*** Range *)
-Record range (T : Type) := mk_range {
- start: T;
- end_: T;
+(** Constants *)
+Definition core_u8_max := u8_max %u32.
+Definition core_u16_max := u16_max %u32.
+Definition core_u32_max := u32_max %u32.
+Definition core_u64_max := u64_max %u64.
+Definition core_u128_max := u64_max %u128.
+Axiom core_usize_max : usize. (** TODO *)
+Definition core_i8_max := i8_max %i32.
+Definition core_i16_max := i16_max %i32.
+Definition core_i32_max := i32_max %i32.
+Definition core_i64_max := i64_max %i64.
+Definition core_i128_max := i64_max %i128.
+Axiom core_isize_max : isize. (** TODO *)
+
+(*** core::ops *)
+
+(* Trait declaration: [core::ops::index::Index] *)
+Record core_ops_index_Index (Self Idx : Type) := mk_core_ops_index_Index {
+ core_ops_index_Index_Output : Type;
+ core_ops_index_Index_index : Self -> Idx -> result core_ops_index_Index_Output;
+}.
+Arguments mk_core_ops_index_Index {_ _}.
+Arguments core_ops_index_Index_Output {_ _}.
+Arguments core_ops_index_Index_index {_ _}.
+
+(* Trait declaration: [core::ops::index::IndexMut] *)
+Record core_ops_index_IndexMut (Self Idx : Type) := mk_core_ops_index_IndexMut {
+ core_ops_index_IndexMut_indexInst : core_ops_index_Index Self Idx;
+ core_ops_index_IndexMut_index_mut : Self -> Idx -> result core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output);
+ core_ops_index_IndexMut_index_mut_back : Self -> Idx -> core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output) -> result Self;
+}.
+Arguments mk_core_ops_index_IndexMut {_ _}.
+Arguments core_ops_index_IndexMut_indexInst {_ _}.
+Arguments core_ops_index_IndexMut_index_mut {_ _}.
+Arguments core_ops_index_IndexMut_index_mut_back {_ _}.
+
+(* Trait declaration [core::ops::deref::Deref] *)
+Record core_ops_deref_Deref (Self : Type) := mk_core_ops_deref_Deref {
+ core_ops_deref_Deref_target : Type;
+ core_ops_deref_Deref_deref : Self -> result core_ops_deref_Deref_target;
+}.
+Arguments mk_core_ops_deref_Deref {_}.
+Arguments core_ops_deref_Deref_target {_}.
+Arguments core_ops_deref_Deref_deref {_}.
+
+(* Trait declaration [core::ops::deref::DerefMut] *)
+Record core_ops_deref_DerefMut (Self : Type) := mk_core_ops_deref_DerefMut {
+ core_ops_deref_DerefMut_derefInst : core_ops_deref_Deref Self;
+ core_ops_deref_DerefMut_deref_mut : Self -> result core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target);
+ core_ops_deref_DerefMut_deref_mut_back : Self -> core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target) -> result Self;
}.
-Arguments mk_range {_}.
+Arguments mk_core_ops_deref_DerefMut {_}.
+Arguments core_ops_deref_DerefMut_derefInst {_}.
+Arguments core_ops_deref_DerefMut_deref_mut {_}.
+Arguments core_ops_deref_DerefMut_deref_mut_back {_}.
+
+Record core_ops_range_Range (T : Type) := mk_core_ops_range_Range {
+ core_ops_range_Range_start : T;
+ core_ops_range_Range_end_ : T;
+}.
+Arguments mk_core_ops_range_Range {_}.
+Arguments core_ops_range_Range_start {_}.
+Arguments core_ops_range_Range_end_ {_}.
+
+(*** [alloc] *)
+
+Definition alloc_boxed_Box_deref (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut_back (T : Type) (_ : T) (x : T) : result T := Return x.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefInst (Self : Type) : core_ops_deref_Deref Self := {|
+ core_ops_deref_Deref_target := Self;
+ core_ops_deref_Deref_deref := alloc_boxed_Box_deref Self;
+|}.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefMutInst (Self : Type) : core_ops_deref_DerefMut Self := {|
+ core_ops_deref_DerefMut_derefInst := alloc_boxed_Box_coreOpsDerefInst Self;
+ core_ops_deref_DerefMut_deref_mut := alloc_boxed_Box_deref_mut Self;
+ core_ops_deref_DerefMut_deref_mut_back := alloc_boxed_Box_deref_mut_back Self;
+|}.
+
(*** Arrays *)
Definition array T (n : usize) := { l: list T | Z.of_nat (length l) = to_Z n}.
@@ -419,51 +498,50 @@ Qed.
(* TODO: finish the definitions *)
Axiom mk_array : forall (T : Type) (n : usize) (l : list T), array T n.
-Axiom array_index_shared : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_fwd : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_back : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
+(* For initialization *)
+Axiom array_repeat : forall (T : Type) (n : usize) (x : T), array T n.
+
+Axiom array_index_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
+Axiom array_update_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
(*** Slice *)
Definition slice T := { l: list T | Z.of_nat (length l) <= usize_max}.
Axiom slice_len : forall (T : Type) (s : slice T), usize.
-Axiom slice_index_shared : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_fwd : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_back : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
+Axiom slice_index_usize : forall (T : Type) (x : slice T) (i : usize), result T.
+Axiom slice_update_usize : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
(*** Subslices *)
-Axiom array_to_slice_shared : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_fwd : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_back : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+Axiom array_to_slice : forall (T : Type) (n : usize) (x : array T n), result (slice T).
+Axiom array_from_slice : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+
+Axiom array_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize), result (slice T).
+Axiom array_update_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize) (ns : slice T), result (array T n).
-Axiom array_subslice_shared: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_fwd: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_back: forall (T : Type) (n : usize) (x : array T n) (r : range usize) (ns : slice T), result (array T n).
-Axiom slice_subslice_shared: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_fwd: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_back: forall (T : Type) (x : slice T) (r : range usize) (ns : slice T), result (slice T).
+Axiom slice_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize), result (slice T).
+Axiom slice_update_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize) (ns : slice T), result (slice T).
(*** Vectors *)
-Definition vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
+Definition alloc_vec_Vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
-Definition vec_to_list {T: Type} (v: vec T) : list T := proj1_sig v.
+Definition alloc_vec_Vec_to_list {T: Type} (v: alloc_vec_Vec T) : list T := proj1_sig v.
-Definition vec_length {T: Type} (v: vec T) : Z := Z.of_nat (length (vec_to_list v)).
+Definition alloc_vec_Vec_length {T: Type} (v: alloc_vec_Vec T) : Z := Z.of_nat (length (alloc_vec_Vec_to_list v)).
-Definition vec_new (T: Type) : vec T := (exist _ [] le_0_usize_max).
+Definition alloc_vec_Vec_new (T: Type) : alloc_vec_Vec T := (exist _ [] le_0_usize_max).
-Lemma vec_len_in_usize {T} (v: vec T) : usize_min <= vec_length v <= usize_max.
+Lemma alloc_vec_Vec_len_in_usize {T} (v: alloc_vec_Vec T) : usize_min <= alloc_vec_Vec_length v <= usize_max.
Proof.
- unfold vec_length, usize_min.
+ unfold alloc_vec_Vec_length, usize_min.
split.
- lia.
- apply (proj2_sig v).
Qed.
-Definition vec_len (T: Type) (v: vec T) : usize :=
- exist _ (vec_length v) (vec_len_in_usize v).
+Definition alloc_vec_Vec_len (T: Type) (v: alloc_vec_Vec T) : usize :=
+ exist _ (alloc_vec_Vec_length v) (alloc_vec_Vec_len_in_usize v).
Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
: list A :=
@@ -474,50 +552,271 @@ Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
| S m => x :: (list_update t m a)
end end.
-Definition vec_bind {A B} (v: vec A) (f: list A -> result (list B)) : result (vec B) :=
- l <- f (vec_to_list v) ;
+Definition alloc_vec_Vec_bind {A B} (v: alloc_vec_Vec A) (f: list A -> result (list B)) : result (alloc_vec_Vec B) :=
+ l <- f (alloc_vec_Vec_to_list v) ;
match sumbool_of_bool (scalar_le_max Usize (Z.of_nat (length l))) with
| left H => Return (exist _ l (scalar_le_max_valid _ _ H))
| right _ => Fail_ Failure
end.
(* The **forward** function shouldn't be used *)
-Definition vec_push_fwd (T: Type) (v: vec T) (x: T) : unit := tt.
+Definition alloc_vec_Vec_push_fwd (T: Type) (v: alloc_vec_Vec T) (x: T) : unit := tt.
-Definition vec_push_back (T: Type) (v: vec T) (x: T) : result (vec T) :=
- vec_bind v (fun l => Return (l ++ [x])).
+Definition alloc_vec_Vec_push (T: Type) (v: alloc_vec_Vec T) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l => Return (l ++ [x])).
(* The **forward** function shouldn't be used *)
-Definition vec_insert_fwd (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
+Definition alloc_vec_Vec_insert_fwd (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result unit :=
+ if to_Z i <? alloc_vec_Vec_length v then Return tt else Fail_ Failure.
-Definition vec_insert_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
+Definition alloc_vec_Vec_insert (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l =>
if to_Z i <? Z.of_nat (length l)
then Return (list_update l (usize_to_nat i) x)
else Fail_ Failure).
-(* The **backward** function shouldn't be used *)
-Definition vec_index_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
- end.
-
-Definition vec_index_back (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
-
-(* The **backward** function shouldn't be used *)
-Definition vec_index_mut_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
+(* Helper *)
+Axiom alloc_vec_Vec_index_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result T.
+
+(* Helper *)
+Axiom alloc_vec_Vec_update_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result (alloc_vec_Vec T).
+
+(* Trait declaration: [core::slice::index::private_slice_index::Sealed] *)
+Definition core_slice_index_private_slice_index_Sealed (self : Type) := unit.
+
+(* Trait declaration: [core::slice::index::SliceIndex] *)
+Record core_slice_index_SliceIndex (Self T : Type) := mk_core_slice_index_SliceIndex {
+ core_slice_index_SliceIndex_sealedInst : core_slice_index_private_slice_index_Sealed Self;
+ core_slice_index_SliceIndex_Output : Type;
+ core_slice_index_SliceIndex_get : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut_back : Self -> T -> option core_slice_index_SliceIndex_Output -> result T;
+ core_slice_index_SliceIndex_get_unchecked : Self -> const_raw_ptr T -> result (const_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_unchecked_mut : Self -> mut_raw_ptr T -> result (mut_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_index : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut_back : Self -> T -> core_slice_index_SliceIndex_Output -> result T;
+}.
+Arguments mk_core_slice_index_SliceIndex {_ _}.
+Arguments core_slice_index_SliceIndex_sealedInst {_ _}.
+Arguments core_slice_index_SliceIndex_Output {_ _}.
+Arguments core_slice_index_SliceIndex_get {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut_back {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut_back {_ _}.
+
+(* [core::slice::index::[T]::index]: forward function *)
+Definition core_slice_index_Slice_index
+ (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (s : slice T) (i : Idx) : result inst.(core_slice_index_SliceIndex_Output) :=
+ x <- inst.(core_slice_index_SliceIndex_get) i s;
+ match x with
+ | None => Fail_ Failure
+ | Some x => Return x
end.
-Definition vec_index_mut_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
- if to_Z i <? Z.of_nat (length l)
- then Return (list_update l (usize_to_nat i) x)
- else Fail_ Failure).
+(* [core::slice::index::Range:::get]: forward function *)
+Axiom core_slice_index_Range_get : forall (T : Type) (i : core_ops_range_Range usize) (s : slice T), result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: forward function *)
+Axiom core_slice_index_Range_get_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: backward function 0 *)
+Axiom core_slice_index_Range_get_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> option (slice T) -> result (slice T).
+
+(* [core::slice::index::Range::get_unchecked]: forward function *)
+Definition core_slice_index_Range_get_unchecked
+ (T : Type) :
+ core_ops_range_Range usize -> const_raw_ptr (slice T) -> result (const_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::get_unchecked_mut]: forward function *)
+Definition core_slice_index_Range_get_unchecked_mut
+ (T : Type) :
+ core_ops_range_Range usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::index]: forward function *)
+Axiom core_slice_index_Range_index :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: forward function *)
+Axiom core_slice_index_Range_index_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: backward function 0 *)
+Axiom core_slice_index_Range_index_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> slice T -> result (slice T).
+
+(* [core::slice::index::[T]::index_mut]: forward function *)
+Axiom core_slice_index_Slice_index_mut :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> result inst.(core_slice_index_SliceIndex_Output).
+
+(* [core::slice::index::[T]::index_mut]: backward function 0 *)
+Axiom core_slice_index_Slice_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> inst.(core_slice_index_SliceIndex_Output) -> result (slice T).
+
+(* [core::array::[T; N]::index]: forward function *)
+Axiom core_array_Array_index :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_Index (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: forward function *)
+Axiom core_array_Array_index_mut :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: backward function 0 *)
+Axiom core_array_Array_index_mut_back :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx) (x : inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output)), result (array T N).
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (slice T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := core_slice_index_Slice_index T Idx inst;
+|}.
+
+(* Trait implementation: [core::slice::index::private_slice_index::Range] *)
+Definition core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) := tt.
+
+(* Trait implementation: [core::slice::index::Range] *)
+Definition core_slice_index_Range_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := slice T;
+ core_slice_index_SliceIndex_get := core_slice_index_Range_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_Range_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_Range_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_Range_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_Range_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_Range_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_Range_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_Range_index_mut_back T;
+|}.
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (slice T) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_slice_index_Slice_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := core_slice_index_Slice_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := core_slice_index_Slice_index_mut_back T Idx inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_Index (slice T) Idx) :
+ core_ops_index_Index (array T N) Idx := {|
+ core_ops_index_Index_Output := inst.(core_ops_index_Index_Output);
+ core_ops_index_Index_index := core_array_Array_index T Idx N inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexMutInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_IndexMut (slice T) Idx) :
+ core_ops_index_IndexMut (array T N) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_array_Array_coreopsindexIndexInst T Idx N inst.(core_ops_index_IndexMut_indexInst);
+ core_ops_index_IndexMut_index_mut := core_array_Array_index_mut T Idx N inst;
+ core_ops_index_IndexMut_index_mut_back := core_array_Array_index_mut_back T Idx N inst;
+|}.
+
+(* [core::slice::index::usize::get]: forward function *)
+Axiom core_slice_index_usize_get : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: forward function *)
+Axiom core_slice_index_usize_get_mut : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: backward function 0 *)
+Axiom core_slice_index_usize_get_mut_back :
+ forall (T : Type), usize -> slice T -> option T -> result (slice T).
+
+(* [core::slice::index::usize::get_unchecked]: forward function *)
+Axiom core_slice_index_usize_get_unchecked :
+ forall (T : Type), usize -> const_raw_ptr (slice T) -> result (const_raw_ptr T).
+
+(* [core::slice::index::usize::get_unchecked_mut]: forward function *)
+Axiom core_slice_index_usize_get_unchecked_mut :
+ forall (T : Type), usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr T).
+
+(* [core::slice::index::usize::index]: forward function *)
+Axiom core_slice_index_usize_index : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: forward function *)
+Axiom core_slice_index_usize_index_mut : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: backward function 0 *)
+Axiom core_slice_index_usize_index_mut_back :
+ forall (T : Type), usize -> slice T -> T -> result (slice T).
+
+(* Trait implementation: [core::slice::index::private_slice_index::usize] *)
+Definition core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize := tt.
+
+(* Trait implementation: [core::slice::index::usize] *)
+Definition core_slice_index_usize_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex usize (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := T;
+ core_slice_index_SliceIndex_get := core_slice_index_usize_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_usize_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_usize_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_usize_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_usize_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_usize_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_usize_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_usize_index_mut_back T;
+|}.
+
+(* [alloc::vec::Vec::index]: forward function *)
+Axiom alloc_vec_Vec_index : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: forward function *)
+Axiom alloc_vec_Vec_index_mut : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: backward function 0 *)
+Axiom alloc_vec_Vec_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx) (x : inst.(core_slice_index_SliceIndex_Output)), result (alloc_vec_Vec T).
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (alloc_vec_Vec T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := alloc_vec_Vec_index T Idx inst;
+|}.
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (alloc_vec_Vec T) Idx := {|
+ core_ops_index_IndexMut_indexInst := alloc_vec_Vec_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := alloc_vec_Vec_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := alloc_vec_Vec_index_mut_back T Idx inst;
+|}.
+
+(*** Theorems *)
+
+Axiom alloc_vec_Vec_index_mut_back_eq : forall {a : Type} (v : alloc_vec_Vec a) (i : usize) (x : a),
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x =
+ alloc_vec_Vec_update_usize v i x.
End Primitives.
diff --git a/tests/coq/misc/Constants.v b/tests/coq/misc/Constants.v
index f1c32730..03653f69 100644
--- a/tests/coq/misc/Constants.v
+++ b/tests/coq/misc/Constants.v
@@ -12,12 +12,8 @@ Module Constants.
Definition x0_body : result u32 := Return 0%u32.
Definition x0_c : u32 := x0_body%global.
-(** [core::num::u32::{8}::MAX] *)
-Definition core_num_u32_max_body : result u32 := Return 4294967295%u32.
-Definition core_num_u32_max_c : u32 := core_num_u32_max_body%global.
-
(** [constants::X1] *)
-Definition x1_body : result u32 := Return core_num_u32_max_c.
+Definition x1_body : result u32 := Return core_u32_max.
Definition x1_c : u32 := x1_body%global.
(** [constants::X2] *)
@@ -25,36 +21,35 @@ Definition x2_body : result u32 := Return 3%u32.
Definition x2_c : u32 := x2_body%global.
(** [constants::incr]: forward function *)
-Definition incr_fwd (n : u32) : result u32 :=
+Definition incr (n : u32) : result u32 :=
u32_add n 1%u32.
(** [constants::X3] *)
-Definition x3_body : result u32 := incr_fwd 32%u32.
+Definition x3_body : result u32 := incr 32%u32.
Definition x3_c : u32 := x3_body%global.
(** [constants::mk_pair0]: forward function *)
-Definition mk_pair0_fwd (x : u32) (y : u32) : result (u32 * u32) :=
- Return (x, y)
-.
+Definition mk_pair0 (x : u32) (y : u32) : result (u32 * u32) :=
+ Return (x, y).
(** [constants::Pair] *)
-Record Pair_t (T1 T2 : Type) := mkPair_t { Pair_x : T1; Pair_y : T2; }.
+Record Pair_t (T1 T2 : Type) := mkPair_t { pair_x : T1; pair_y : T2; }.
-Arguments mkPair_t {T1} {T2} _ _.
-Arguments Pair_x {T1} {T2}.
-Arguments Pair_y {T1} {T2}.
+Arguments mkPair_t { _ _ }.
+Arguments pair_x { _ _ }.
+Arguments pair_y { _ _ }.
(** [constants::mk_pair1]: forward function *)
-Definition mk_pair1_fwd (x : u32) (y : u32) : result (Pair_t u32 u32) :=
- Return {| Pair_x := x; Pair_y := y |}
+Definition mk_pair1 (x : u32) (y : u32) : result (Pair_t u32 u32) :=
+ Return {| pair_x := x; pair_y := y |}
.
(** [constants::P0] *)
-Definition p0_body : result (u32 * u32) := mk_pair0_fwd 0%u32 1%u32.
+Definition p0_body : result (u32 * u32) := mk_pair0 0%u32 1%u32.
Definition p0_c : (u32 * u32) := p0_body%global.
(** [constants::P1] *)
-Definition p1_body : result (Pair_t u32 u32) := mk_pair1_fwd 0%u32 1%u32.
+Definition p1_body : result (Pair_t u32 u32) := mk_pair1 0%u32 1%u32.
Definition p1_c : Pair_t u32 u32 := p1_body%global.
(** [constants::P2] *)
@@ -63,31 +58,31 @@ Definition p2_c : (u32 * u32) := p2_body%global.
(** [constants::P3] *)
Definition p3_body : result (Pair_t u32 u32) :=
- Return {| Pair_x := 0%u32; Pair_y := 1%u32 |}
+ Return {| pair_x := 0%u32; pair_y := 1%u32 |}
.
Definition p3_c : Pair_t u32 u32 := p3_body%global.
(** [constants::Wrap] *)
-Record Wrap_t (T : Type) := mkWrap_t { Wrap_val : T; }.
+Record Wrap_t (T : Type) := mkWrap_t { wrap_value : T; }.
-Arguments mkWrap_t {T} _.
-Arguments Wrap_val {T}.
+Arguments mkWrap_t { _ }.
+Arguments wrap_value { _ }.
(** [constants::Wrap::{0}::new]: forward function *)
-Definition wrap_new_fwd (T : Type) (val : T) : result (Wrap_t T) :=
- Return {| Wrap_val := val |}
+Definition wrap_new (T : Type) (value : T) : result (Wrap_t T) :=
+ Return {| wrap_value := value |}
.
(** [constants::Y] *)
-Definition y_body : result (Wrap_t i32) := wrap_new_fwd i32 2%i32.
+Definition y_body : result (Wrap_t i32) := wrap_new i32 2%i32.
Definition y_c : Wrap_t i32 := y_body%global.
(** [constants::unwrap_y]: forward function *)
-Definition unwrap_y_fwd : result i32 :=
- Return y_c.(Wrap_val).
+Definition unwrap_y : result i32 :=
+ Return y_c.(wrap_value).
(** [constants::YVAL] *)
-Definition yval_body : result i32 := unwrap_y_fwd.
+Definition yval_body : result i32 := unwrap_y.
Definition yval_c : i32 := yval_body%global.
(** [constants::get_z1::Z1] *)
@@ -95,11 +90,11 @@ Definition get_z1_z1_body : result i32 := Return 3%i32.
Definition get_z1_z1_c : i32 := get_z1_z1_body%global.
(** [constants::get_z1]: forward function *)
-Definition get_z1_fwd : result i32 :=
+Definition get_z1 : result i32 :=
Return get_z1_z1_c.
(** [constants::add]: forward function *)
-Definition add_fwd (a : i32) (b : i32) : result i32 :=
+Definition add (a : i32) (b : i32) : result i32 :=
i32_add a b.
(** [constants::Q1] *)
@@ -111,20 +106,19 @@ Definition q2_body : result i32 := Return q1_c.
Definition q2_c : i32 := q2_body%global.
(** [constants::Q3] *)
-Definition q3_body : result i32 := add_fwd q2_c 3%i32.
+Definition q3_body : result i32 := add q2_c 3%i32.
Definition q3_c : i32 := q3_body%global.
(** [constants::get_z2]: forward function *)
-Definition get_z2_fwd : result i32 :=
- i <- get_z1_fwd; i0 <- add_fwd i q3_c; add_fwd q1_c i0
-.
+Definition get_z2 : result i32 :=
+ i <- get_z1; i0 <- add i q3_c; add q1_c i0.
(** [constants::S1] *)
Definition s1_body : result u32 := Return 6%u32.
Definition s1_c : u32 := s1_body%global.
(** [constants::S2] *)
-Definition s2_body : result u32 := incr_fwd s1_c.
+Definition s2_body : result u32 := incr s1_c.
Definition s2_c : u32 := s2_body%global.
(** [constants::S3] *)
@@ -132,7 +126,7 @@ Definition s3_body : result (Pair_t u32 u32) := Return p3_c.
Definition s3_c : Pair_t u32 u32 := s3_body%global.
(** [constants::S4] *)
-Definition s4_body : result (Pair_t u32 u32) := mk_pair1_fwd 7%u32 8%u32.
+Definition s4_body : result (Pair_t u32 u32) := mk_pair1 7%u32 8%u32.
Definition s4_c : Pair_t u32 u32 := s4_body%global.
End Constants .
diff --git a/tests/coq/misc/External_Funs.v b/tests/coq/misc/External_Funs.v
index 28370b2b..018ce13c 100644
--- a/tests/coq/misc/External_Funs.v
+++ b/tests/coq/misc/External_Funs.v
@@ -13,9 +13,9 @@ Import External_Opaque.
Module External_Funs.
(** [external::swap]: forward function *)
-Definition swap_fwd
+Definition swap
(T : Type) (x : T) (y : T) (st : state) : result (state * unit) :=
- p <- core_mem_swap_fwd T x y st;
+ p <- core_mem_swap T x y st;
let (st0, _) := p in
p0 <- core_mem_swap_back0 T x y st st0;
let (st1, _) := p0 in
@@ -29,7 +29,7 @@ Definition swap_back
(T : Type) (x : T) (y : T) (st : state) (st0 : state) :
result (state * (T * T))
:=
- p <- core_mem_swap_fwd T x y st;
+ p <- core_mem_swap T x y st;
let (st1, _) := p in
p0 <- core_mem_swap_back0 T x y st st1;
let (st2, x0) := p0 in
@@ -39,25 +39,27 @@ Definition swap_back
.
(** [external::test_new_non_zero_u32]: forward function *)
-Definition test_new_non_zero_u32_fwd
- (x : u32) (st : state) : result (state * Core_num_nonzero_non_zero_u32_t) :=
- p <- core_num_nonzero_non_zero_u32_new_fwd x st;
- let (st0, opt) := p in
- core_option_option_unwrap_fwd Core_num_nonzero_non_zero_u32_t opt st0
+Definition test_new_non_zero_u32
+ (x : u32) (st : state) : result (state * core_num_nonzero_NonZeroU32_t) :=
+ p <- core_num_nonzero_NonZeroU32_new x st;
+ let (st0, o) := p in
+ core_option_Option_unwrap core_num_nonzero_NonZeroU32_t o st0
.
(** [external::test_vec]: forward function *)
-Definition test_vec_fwd : result unit :=
- let v := vec_new u32 in _ <- vec_push_back u32 v 0%u32; Return tt
+Definition test_vec : result unit :=
+ let v := alloc_vec_Vec_new u32 in
+ _ <- alloc_vec_Vec_push u32 v 0%u32;
+ Return tt
.
(** Unit test for [external::test_vec] *)
-Check (test_vec_fwd )%return.
+Check (test_vec )%return.
(** [external::custom_swap]: forward function *)
-Definition custom_swap_fwd
+Definition custom_swap
(T : Type) (x : T) (y : T) (st : state) : result (state * T) :=
- p <- core_mem_swap_fwd T x y st;
+ p <- core_mem_swap T x y st;
let (st0, _) := p in
p0 <- core_mem_swap_back0 T x y st st0;
let (st1, x0) := p0 in
@@ -71,7 +73,7 @@ Definition custom_swap_back
(T : Type) (x : T) (y : T) (st : state) (ret : T) (st0 : state) :
result (state * (T * T))
:=
- p <- core_mem_swap_fwd T x y st;
+ p <- core_mem_swap T x y st;
let (st1, _) := p in
p0 <- core_mem_swap_back0 T x y st st1;
let (st2, _) := p0 in
@@ -81,9 +83,9 @@ Definition custom_swap_back
.
(** [external::test_custom_swap]: forward function *)
-Definition test_custom_swap_fwd
+Definition test_custom_swap
(x : u32) (y : u32) (st : state) : result (state * unit) :=
- p <- custom_swap_fwd u32 x y st; let (st0, _) := p in Return (st0, tt)
+ p <- custom_swap u32 x y st; let (st0, _) := p in Return (st0, tt)
.
(** [external::test_custom_swap]: backward function 0 *)
@@ -95,9 +97,8 @@ Definition test_custom_swap_back
.
(** [external::test_swap_non_zero]: forward function *)
-Definition test_swap_non_zero_fwd
- (x : u32) (st : state) : result (state * u32) :=
- p <- swap_fwd u32 x 0%u32 st;
+Definition test_swap_non_zero (x : u32) (st : state) : result (state * u32) :=
+ p <- swap u32 x 0%u32 st;
let (st0, _) := p in
p0 <- swap_back u32 x 0%u32 st st0;
let (st1, p1) := p0 in
diff --git a/tests/coq/misc/External_Opaque.v b/tests/coq/misc/External_Opaque.v
index d2ee42d4..80be37e7 100644
--- a/tests/coq/misc/External_Opaque.v
+++ b/tests/coq/misc/External_Opaque.v
@@ -11,7 +11,7 @@ Import External_Types.
Module External_Opaque.
(** [core::mem::swap]: forward function *)
-Axiom core_mem_swap_fwd :
+Axiom core_mem_swap :
forall(T : Type), T -> T -> state -> result (state * unit)
.
@@ -26,12 +26,12 @@ Axiom core_mem_swap_back1 :
.
(** [core::num::nonzero::NonZeroU32::{14}::new]: forward function *)
-Axiom core_num_nonzero_non_zero_u32_new_fwd
- : u32 -> state -> result (state * (option Core_num_nonzero_non_zero_u32_t))
+Axiom core_num_nonzero_NonZeroU32_new
+ : u32 -> state -> result (state * (option core_num_nonzero_NonZeroU32_t))
.
(** [core::option::Option::{0}::unwrap]: forward function *)
-Axiom core_option_option_unwrap_fwd :
+Axiom core_option_Option_unwrap :
forall(T : Type), option T -> state -> result (state * T)
.
diff --git a/tests/coq/misc/External_Types.v b/tests/coq/misc/External_Types.v
index 1883fa6c..9e49ca41 100644
--- a/tests/coq/misc/External_Types.v
+++ b/tests/coq/misc/External_Types.v
@@ -9,7 +9,7 @@ Local Open Scope Primitives_scope.
Module External_Types.
(** [core::num::nonzero::NonZeroU32] *)
-Axiom Core_num_nonzero_non_zero_u32_t : Type.
+Axiom core_num_nonzero_NonZeroU32_t : Type.
(** The state type used in the state-error monad *)
Axiom state : Type.
diff --git a/tests/coq/misc/Loops.v b/tests/coq/misc/Loops.v
index 82e57576..1c0eab17 100644
--- a/tests/coq/misc/Loops.v
+++ b/tests/coq/misc/Loops.v
@@ -9,23 +9,23 @@ Local Open Scope Primitives_scope.
Module Loops.
(** [loops::sum]: loop 0: forward function *)
-Fixpoint sum_loop_fwd (n : nat) (max : u32) (i : u32) (s : u32) : result u32 :=
+Fixpoint sum_loop (n : nat) (max : u32) (i : u32) (s : u32) : result u32 :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
if i s< max
- then (s0 <- u32_add s i; i0 <- u32_add i 1%u32; sum_loop_fwd n0 max i0 s0)
+ then (s0 <- u32_add s i; i0 <- u32_add i 1%u32; sum_loop n0 max i0 s0)
else u32_mul s 2%u32
end
.
(** [loops::sum]: forward function *)
-Definition sum_fwd (n : nat) (max : u32) : result u32 :=
- sum_loop_fwd n max 0%u32 0%u32
+Definition sum (n : nat) (max : u32) : result u32 :=
+ sum_loop n max 0%u32 0%u32
.
(** [loops::sum_with_mut_borrows]: loop 0: forward function *)
-Fixpoint sum_with_mut_borrows_loop_fwd
+Fixpoint sum_with_mut_borrows_loop
(n : nat) (max : u32) (mi : u32) (ms : u32) : result u32 :=
match n with
| O => Fail_ OutOfFuel
@@ -34,18 +34,18 @@ Fixpoint sum_with_mut_borrows_loop_fwd
then (
ms0 <- u32_add ms mi;
mi0 <- u32_add mi 1%u32;
- sum_with_mut_borrows_loop_fwd n0 max mi0 ms0)
+ sum_with_mut_borrows_loop n0 max mi0 ms0)
else u32_mul ms 2%u32
end
.
(** [loops::sum_with_mut_borrows]: forward function *)
-Definition sum_with_mut_borrows_fwd (n : nat) (max : u32) : result u32 :=
- sum_with_mut_borrows_loop_fwd n max 0%u32 0%u32
+Definition sum_with_mut_borrows (n : nat) (max : u32) : result u32 :=
+ sum_with_mut_borrows_loop n max 0%u32 0%u32
.
(** [loops::sum_with_shared_borrows]: loop 0: forward function *)
-Fixpoint sum_with_shared_borrows_loop_fwd
+Fixpoint sum_with_shared_borrows_loop
(n : nat) (max : u32) (i : u32) (s : u32) : result u32 :=
match n with
| O => Fail_ OutOfFuel
@@ -54,87 +54,88 @@ Fixpoint sum_with_shared_borrows_loop_fwd
then (
i0 <- u32_add i 1%u32;
s0 <- u32_add s i0;
- sum_with_shared_borrows_loop_fwd n0 max i0 s0)
+ sum_with_shared_borrows_loop n0 max i0 s0)
else u32_mul s 2%u32
end
.
(** [loops::sum_with_shared_borrows]: forward function *)
-Definition sum_with_shared_borrows_fwd (n : nat) (max : u32) : result u32 :=
- sum_with_shared_borrows_loop_fwd n max 0%u32 0%u32
+Definition sum_with_shared_borrows (n : nat) (max : u32) : result u32 :=
+ sum_with_shared_borrows_loop n max 0%u32 0%u32
.
(** [loops::clear]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Fixpoint clear_loop_fwd_back
- (n : nat) (v : vec u32) (i : usize) : result (vec u32) :=
+Fixpoint clear_loop
+ (n : nat) (v : alloc_vec_Vec u32) (i : usize) : result (alloc_vec_Vec u32) :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
- let i0 := vec_len u32 v in
+ let i0 := alloc_vec_Vec_len u32 v in
if i s< i0
then (
i1 <- usize_add i 1%usize;
- v0 <- vec_index_mut_back u32 v i 0%u32;
- clear_loop_fwd_back n0 v0 i1)
+ v0 <-
+ alloc_vec_Vec_index_mut_back u32 usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst u32) v i 0%u32;
+ clear_loop n0 v0 i1)
else Return v
end
.
(** [loops::clear]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition clear_fwd_back (n : nat) (v : vec u32) : result (vec u32) :=
- clear_loop_fwd_back n v 0%usize
+Definition clear
+ (n : nat) (v : alloc_vec_Vec u32) : result (alloc_vec_Vec u32) :=
+ clear_loop n v 0%usize
.
(** [loops::List] *)
Inductive List_t (T : Type) :=
-| ListCons : T -> List_t T -> List_t T
-| ListNil : List_t T
+| List_Cons : T -> List_t T -> List_t T
+| List_Nil : List_t T
.
-Arguments ListCons {T} _ _.
-Arguments ListNil {T}.
+Arguments List_Cons { _ }.
+Arguments List_Nil { _ }.
(** [loops::list_mem]: loop 0: forward function *)
-Fixpoint list_mem_loop_fwd
- (n : nat) (x : u32) (ls : List_t u32) : result bool :=
+Fixpoint list_mem_loop (n : nat) (x : u32) (ls : List_t u32) : result bool :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons y tl =>
- if y s= x then Return true else list_mem_loop_fwd n0 x tl
- | ListNil => Return false
+ | List_Cons y tl => if y s= x then Return true else list_mem_loop n0 x tl
+ | List_Nil => Return false
end
end
.
(** [loops::list_mem]: forward function *)
-Definition list_mem_fwd (n : nat) (x : u32) (ls : List_t u32) : result bool :=
- list_mem_loop_fwd n x ls
+Definition list_mem (n : nat) (x : u32) (ls : List_t u32) : result bool :=
+ list_mem_loop n x ls
.
(** [loops::list_nth_mut_loop]: loop 0: forward function *)
-Fixpoint list_nth_mut_loop_loop_fwd
+Fixpoint list_nth_mut_loop_loop
(T : Type) (n : nat) (ls : List_t T) (i : u32) : result T :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
then Return x
- else (i0 <- u32_sub i 1%u32; list_nth_mut_loop_loop_fwd T n0 tl i0)
- | ListNil => Fail_ Failure
+ else (i0 <- u32_sub i 1%u32; list_nth_mut_loop_loop T n0 tl i0)
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_mut_loop]: forward function *)
-Definition list_nth_mut_loop_fwd
+Definition list_nth_mut_loop
(T : Type) (n : nat) (ls : List_t T) (i : u32) : result T :=
- list_nth_mut_loop_loop_fwd T n ls i
+ list_nth_mut_loop_loop T n ls i
.
(** [loops::list_nth_mut_loop]: loop 0: backward function 0 *)
@@ -146,14 +147,14 @@ Fixpoint list_nth_mut_loop_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
- then Return (ListCons ret tl)
+ then Return (List_Cons ret tl)
else (
i0 <- u32_sub i 1%u32;
tl0 <- list_nth_mut_loop_loop_back T n0 tl i0 ret;
- Return (ListCons x tl0))
- | ListNil => Fail_ Failure
+ Return (List_Cons x tl0))
+ | List_Nil => Fail_ Failure
end
end
.
@@ -167,46 +168,50 @@ Definition list_nth_mut_loop_back
.
(** [loops::list_nth_shared_loop]: loop 0: forward function *)
-Fixpoint list_nth_shared_loop_loop_fwd
+Fixpoint list_nth_shared_loop_loop
(T : Type) (n : nat) (ls : List_t T) (i : u32) : result T :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
then Return x
- else (i0 <- u32_sub i 1%u32; list_nth_shared_loop_loop_fwd T n0 tl i0)
- | ListNil => Fail_ Failure
+ else (i0 <- u32_sub i 1%u32; list_nth_shared_loop_loop T n0 tl i0)
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_shared_loop]: forward function *)
-Definition list_nth_shared_loop_fwd
+Definition list_nth_shared_loop
(T : Type) (n : nat) (ls : List_t T) (i : u32) : result T :=
- list_nth_shared_loop_loop_fwd T n ls i
+ list_nth_shared_loop_loop T n ls i
.
(** [loops::get_elem_mut]: loop 0: forward function *)
-Fixpoint get_elem_mut_loop_fwd
+Fixpoint get_elem_mut_loop
(n : nat) (x : usize) (ls : List_t usize) : result usize :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons y tl =>
- if y s= x then Return y else get_elem_mut_loop_fwd n0 x tl
- | ListNil => Fail_ Failure
+ | List_Cons y tl => if y s= x then Return y else get_elem_mut_loop n0 x tl
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::get_elem_mut]: forward function *)
-Definition get_elem_mut_fwd
- (n : nat) (slots : vec (List_t usize)) (x : usize) : result usize :=
- l <- vec_index_mut_fwd (List_t usize) slots 0%usize;
- get_elem_mut_loop_fwd n x l
+Definition get_elem_mut
+ (n : nat) (slots : alloc_vec_Vec (List_t usize)) (x : usize) :
+ result usize
+ :=
+ l <-
+ alloc_vec_Vec_index_mut (List_t usize) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t usize))
+ slots 0%usize;
+ get_elem_mut_loop n x l
.
(** [loops::get_elem_mut]: loop 0: backward function 0 *)
@@ -218,50 +223,60 @@ Fixpoint get_elem_mut_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons y tl =>
+ | List_Cons y tl =>
if y s= x
- then Return (ListCons ret tl)
- else (tl0 <- get_elem_mut_loop_back n0 x tl ret; Return (ListCons y tl0))
- | ListNil => Fail_ Failure
+ then Return (List_Cons ret tl)
+ else (
+ tl0 <- get_elem_mut_loop_back n0 x tl ret; Return (List_Cons y tl0))
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::get_elem_mut]: backward function 0 *)
Definition get_elem_mut_back
- (n : nat) (slots : vec (List_t usize)) (x : usize) (ret : usize) :
- result (vec (List_t usize))
+ (n : nat) (slots : alloc_vec_Vec (List_t usize)) (x : usize) (ret : usize) :
+ result (alloc_vec_Vec (List_t usize))
:=
- l <- vec_index_mut_fwd (List_t usize) slots 0%usize;
+ l <-
+ alloc_vec_Vec_index_mut (List_t usize) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t usize))
+ slots 0%usize;
l0 <- get_elem_mut_loop_back n x l ret;
- vec_index_mut_back (List_t usize) slots 0%usize l0
+ alloc_vec_Vec_index_mut_back (List_t usize) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t usize)) slots
+ 0%usize l0
.
(** [loops::get_elem_shared]: loop 0: forward function *)
-Fixpoint get_elem_shared_loop_fwd
+Fixpoint get_elem_shared_loop
(n : nat) (x : usize) (ls : List_t usize) : result usize :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons y tl =>
- if y s= x then Return y else get_elem_shared_loop_fwd n0 x tl
- | ListNil => Fail_ Failure
+ | List_Cons y tl =>
+ if y s= x then Return y else get_elem_shared_loop n0 x tl
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::get_elem_shared]: forward function *)
-Definition get_elem_shared_fwd
- (n : nat) (slots : vec (List_t usize)) (x : usize) : result usize :=
- l <- vec_index_fwd (List_t usize) slots 0%usize;
- get_elem_shared_loop_fwd n x l
+Definition get_elem_shared
+ (n : nat) (slots : alloc_vec_Vec (List_t usize)) (x : usize) :
+ result usize
+ :=
+ l <-
+ alloc_vec_Vec_index (List_t usize) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (List_t usize))
+ slots 0%usize;
+ get_elem_shared_loop n x l
.
(** [loops::id_mut]: forward function *)
-Definition id_mut_fwd (T : Type) (ls : List_t T) : result (List_t T) :=
- Return ls
-.
+Definition id_mut (T : Type) (ls : List_t T) : result (List_t T) :=
+ Return ls.
(** [loops::id_mut]: backward function 0 *)
Definition id_mut_back
@@ -270,31 +285,30 @@ Definition id_mut_back
.
(** [loops::id_shared]: forward function *)
-Definition id_shared_fwd (T : Type) (ls : List_t T) : result (List_t T) :=
+Definition id_shared (T : Type) (ls : List_t T) : result (List_t T) :=
Return ls
.
(** [loops::list_nth_mut_loop_with_id]: loop 0: forward function *)
-Fixpoint list_nth_mut_loop_with_id_loop_fwd
+Fixpoint list_nth_mut_loop_with_id_loop
(T : Type) (n : nat) (i : u32) (ls : List_t T) : result T :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
then Return x
- else (
- i0 <- u32_sub i 1%u32; list_nth_mut_loop_with_id_loop_fwd T n0 i0 tl)
- | ListNil => Fail_ Failure
+ else (i0 <- u32_sub i 1%u32; list_nth_mut_loop_with_id_loop T n0 i0 tl)
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_mut_loop_with_id]: forward function *)
-Definition list_nth_mut_loop_with_id_fwd
+Definition list_nth_mut_loop_with_id
(T : Type) (n : nat) (ls : List_t T) (i : u32) : result T :=
- ls0 <- id_mut_fwd T ls; list_nth_mut_loop_with_id_loop_fwd T n i ls0
+ ls0 <- id_mut T ls; list_nth_mut_loop_with_id_loop T n i ls0
.
(** [loops::list_nth_mut_loop_with_id]: loop 0: backward function 0 *)
@@ -306,14 +320,14 @@ Fixpoint list_nth_mut_loop_with_id_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
- then Return (ListCons ret tl)
+ then Return (List_Cons ret tl)
else (
i0 <- u32_sub i 1%u32;
tl0 <- list_nth_mut_loop_with_id_loop_back T n0 i0 tl ret;
- Return (ListCons x tl0))
- | ListNil => Fail_ Failure
+ Return (List_Cons x tl0))
+ | List_Nil => Fail_ Failure
end
end
.
@@ -323,36 +337,36 @@ Definition list_nth_mut_loop_with_id_back
(T : Type) (n : nat) (ls : List_t T) (i : u32) (ret : T) :
result (List_t T)
:=
- ls0 <- id_mut_fwd T ls;
+ ls0 <- id_mut T ls;
l <- list_nth_mut_loop_with_id_loop_back T n i ls0 ret;
id_mut_back T ls l
.
(** [loops::list_nth_shared_loop_with_id]: loop 0: forward function *)
-Fixpoint list_nth_shared_loop_with_id_loop_fwd
+Fixpoint list_nth_shared_loop_with_id_loop
(T : Type) (n : nat) (i : u32) (ls : List_t T) : result T :=
match n with
| O => Fail_ OutOfFuel
| S n0 =>
match ls with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
then Return x
else (
- i0 <- u32_sub i 1%u32; list_nth_shared_loop_with_id_loop_fwd T n0 i0 tl)
- | ListNil => Fail_ Failure
+ i0 <- u32_sub i 1%u32; list_nth_shared_loop_with_id_loop T n0 i0 tl)
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_shared_loop_with_id]: forward function *)
-Definition list_nth_shared_loop_with_id_fwd
+Definition list_nth_shared_loop_with_id
(T : Type) (n : nat) (ls : List_t T) (i : u32) : result T :=
- ls0 <- id_shared_fwd T ls; list_nth_shared_loop_with_id_loop_fwd T n i ls0
+ ls0 <- id_shared T ls; list_nth_shared_loop_with_id_loop T n i ls0
.
(** [loops::list_nth_mut_loop_pair]: loop 0: forward function *)
-Fixpoint list_nth_mut_loop_pair_loop_fwd
+Fixpoint list_nth_mut_loop_pair_loop
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
@@ -360,27 +374,26 @@ Fixpoint list_nth_mut_loop_pair_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
then Return (x0, x1)
else (
- i0 <- u32_sub i 1%u32;
- list_nth_mut_loop_pair_loop_fwd T n0 tl0 tl1 i0)
- | ListNil => Fail_ Failure
+ i0 <- u32_sub i 1%u32; list_nth_mut_loop_pair_loop T n0 tl0 tl1 i0)
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_mut_loop_pair]: forward function *)
-Definition list_nth_mut_loop_pair_fwd
+Definition list_nth_mut_loop_pair
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
- list_nth_mut_loop_pair_loop_fwd T n ls0 ls1 i
+ list_nth_mut_loop_pair_loop T n ls0 ls1 i
.
(** [loops::list_nth_mut_loop_pair]: loop 0: backward function 0 *)
@@ -392,18 +405,18 @@ Fixpoint list_nth_mut_loop_pair_loop_back'a
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
- then Return (ListCons ret tl0)
+ then Return (List_Cons ret tl0)
else (
i0 <- u32_sub i 1%u32;
tl00 <- list_nth_mut_loop_pair_loop_back'a T n0 tl0 tl1 i0 ret;
- Return (ListCons x0 tl00))
- | ListNil => Fail_ Failure
+ Return (List_Cons x0 tl00))
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
@@ -425,18 +438,18 @@ Fixpoint list_nth_mut_loop_pair_loop_back'b
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
- then Return (ListCons ret tl1)
+ then Return (List_Cons ret tl1)
else (
i0 <- u32_sub i 1%u32;
tl10 <- list_nth_mut_loop_pair_loop_back'b T n0 tl0 tl1 i0 ret;
- Return (ListCons x1 tl10))
- | ListNil => Fail_ Failure
+ Return (List_Cons x1 tl10))
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
@@ -450,7 +463,7 @@ Definition list_nth_mut_loop_pair_back'b
.
(** [loops::list_nth_shared_loop_pair]: loop 0: forward function *)
-Fixpoint list_nth_shared_loop_pair_loop_fwd
+Fixpoint list_nth_shared_loop_pair_loop
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
@@ -458,31 +471,30 @@ Fixpoint list_nth_shared_loop_pair_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
then Return (x0, x1)
else (
- i0 <- u32_sub i 1%u32;
- list_nth_shared_loop_pair_loop_fwd T n0 tl0 tl1 i0)
- | ListNil => Fail_ Failure
+ i0 <- u32_sub i 1%u32; list_nth_shared_loop_pair_loop T n0 tl0 tl1 i0)
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_shared_loop_pair]: forward function *)
-Definition list_nth_shared_loop_pair_fwd
+Definition list_nth_shared_loop_pair
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
- list_nth_shared_loop_pair_loop_fwd T n ls0 ls1 i
+ list_nth_shared_loop_pair_loop T n ls0 ls1 i
.
(** [loops::list_nth_mut_loop_pair_merge]: loop 0: forward function *)
-Fixpoint list_nth_mut_loop_pair_merge_loop_fwd
+Fixpoint list_nth_mut_loop_pair_merge_loop
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
@@ -490,27 +502,27 @@ Fixpoint list_nth_mut_loop_pair_merge_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
then Return (x0, x1)
else (
i0 <- u32_sub i 1%u32;
- list_nth_mut_loop_pair_merge_loop_fwd T n0 tl0 tl1 i0)
- | ListNil => Fail_ Failure
+ list_nth_mut_loop_pair_merge_loop T n0 tl0 tl1 i0)
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_mut_loop_pair_merge]: forward function *)
-Definition list_nth_mut_loop_pair_merge_fwd
+Definition list_nth_mut_loop_pair_merge
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
- list_nth_mut_loop_pair_merge_loop_fwd T n ls0 ls1 i
+ list_nth_mut_loop_pair_merge_loop T n ls0 ls1 i
.
(** [loops::list_nth_mut_loop_pair_merge]: loop 0: backward function 0 *)
@@ -523,19 +535,19 @@ Fixpoint list_nth_mut_loop_pair_merge_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
- then let (t, t0) := ret in Return (ListCons t tl0, ListCons t0 tl1)
+ then let (t, t0) := ret in Return (List_Cons t tl0, List_Cons t0 tl1)
else (
i0 <- u32_sub i 1%u32;
p <- list_nth_mut_loop_pair_merge_loop_back T n0 tl0 tl1 i0 ret;
let (tl00, tl10) := p in
- Return (ListCons x0 tl00, ListCons x1 tl10))
- | ListNil => Fail_ Failure
+ Return (List_Cons x0 tl00, List_Cons x1 tl10))
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
@@ -550,7 +562,7 @@ Definition list_nth_mut_loop_pair_merge_back
.
(** [loops::list_nth_shared_loop_pair_merge]: loop 0: forward function *)
-Fixpoint list_nth_shared_loop_pair_merge_loop_fwd
+Fixpoint list_nth_shared_loop_pair_merge_loop
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
@@ -558,31 +570,31 @@ Fixpoint list_nth_shared_loop_pair_merge_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
then Return (x0, x1)
else (
i0 <- u32_sub i 1%u32;
- list_nth_shared_loop_pair_merge_loop_fwd T n0 tl0 tl1 i0)
- | ListNil => Fail_ Failure
+ list_nth_shared_loop_pair_merge_loop T n0 tl0 tl1 i0)
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_shared_loop_pair_merge]: forward function *)
-Definition list_nth_shared_loop_pair_merge_fwd
+Definition list_nth_shared_loop_pair_merge
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
- list_nth_shared_loop_pair_merge_loop_fwd T n ls0 ls1 i
+ list_nth_shared_loop_pair_merge_loop T n ls0 ls1 i
.
(** [loops::list_nth_mut_shared_loop_pair]: loop 0: forward function *)
-Fixpoint list_nth_mut_shared_loop_pair_loop_fwd
+Fixpoint list_nth_mut_shared_loop_pair_loop
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
@@ -590,27 +602,27 @@ Fixpoint list_nth_mut_shared_loop_pair_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
then Return (x0, x1)
else (
i0 <- u32_sub i 1%u32;
- list_nth_mut_shared_loop_pair_loop_fwd T n0 tl0 tl1 i0)
- | ListNil => Fail_ Failure
+ list_nth_mut_shared_loop_pair_loop T n0 tl0 tl1 i0)
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_mut_shared_loop_pair]: forward function *)
-Definition list_nth_mut_shared_loop_pair_fwd
+Definition list_nth_mut_shared_loop_pair
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
- list_nth_mut_shared_loop_pair_loop_fwd T n ls0 ls1 i
+ list_nth_mut_shared_loop_pair_loop T n ls0 ls1 i
.
(** [loops::list_nth_mut_shared_loop_pair]: loop 0: backward function 0 *)
@@ -622,18 +634,18 @@ Fixpoint list_nth_mut_shared_loop_pair_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
- then Return (ListCons ret tl0)
+ then Return (List_Cons ret tl0)
else (
i0 <- u32_sub i 1%u32;
tl00 <- list_nth_mut_shared_loop_pair_loop_back T n0 tl0 tl1 i0 ret;
- Return (ListCons x0 tl00))
- | ListNil => Fail_ Failure
+ Return (List_Cons x0 tl00))
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
@@ -647,7 +659,7 @@ Definition list_nth_mut_shared_loop_pair_back
.
(** [loops::list_nth_mut_shared_loop_pair_merge]: loop 0: forward function *)
-Fixpoint list_nth_mut_shared_loop_pair_merge_loop_fwd
+Fixpoint list_nth_mut_shared_loop_pair_merge_loop
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
@@ -655,27 +667,27 @@ Fixpoint list_nth_mut_shared_loop_pair_merge_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
then Return (x0, x1)
else (
i0 <- u32_sub i 1%u32;
- list_nth_mut_shared_loop_pair_merge_loop_fwd T n0 tl0 tl1 i0)
- | ListNil => Fail_ Failure
+ list_nth_mut_shared_loop_pair_merge_loop T n0 tl0 tl1 i0)
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_mut_shared_loop_pair_merge]: forward function *)
-Definition list_nth_mut_shared_loop_pair_merge_fwd
+Definition list_nth_mut_shared_loop_pair_merge
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
- list_nth_mut_shared_loop_pair_merge_loop_fwd T n ls0 ls1 i
+ list_nth_mut_shared_loop_pair_merge_loop T n ls0 ls1 i
.
(** [loops::list_nth_mut_shared_loop_pair_merge]: loop 0: backward function 0 *)
@@ -687,19 +699,19 @@ Fixpoint list_nth_mut_shared_loop_pair_merge_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
- then Return (ListCons ret tl0)
+ then Return (List_Cons ret tl0)
else (
i0 <- u32_sub i 1%u32;
tl00 <-
list_nth_mut_shared_loop_pair_merge_loop_back T n0 tl0 tl1 i0 ret;
- Return (ListCons x0 tl00))
- | ListNil => Fail_ Failure
+ Return (List_Cons x0 tl00))
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
@@ -713,7 +725,7 @@ Definition list_nth_mut_shared_loop_pair_merge_back
.
(** [loops::list_nth_shared_mut_loop_pair]: loop 0: forward function *)
-Fixpoint list_nth_shared_mut_loop_pair_loop_fwd
+Fixpoint list_nth_shared_mut_loop_pair_loop
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
@@ -721,27 +733,27 @@ Fixpoint list_nth_shared_mut_loop_pair_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
then Return (x0, x1)
else (
i0 <- u32_sub i 1%u32;
- list_nth_shared_mut_loop_pair_loop_fwd T n0 tl0 tl1 i0)
- | ListNil => Fail_ Failure
+ list_nth_shared_mut_loop_pair_loop T n0 tl0 tl1 i0)
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_shared_mut_loop_pair]: forward function *)
-Definition list_nth_shared_mut_loop_pair_fwd
+Definition list_nth_shared_mut_loop_pair
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
- list_nth_shared_mut_loop_pair_loop_fwd T n ls0 ls1 i
+ list_nth_shared_mut_loop_pair_loop T n ls0 ls1 i
.
(** [loops::list_nth_shared_mut_loop_pair]: loop 0: backward function 1 *)
@@ -753,18 +765,18 @@ Fixpoint list_nth_shared_mut_loop_pair_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
- then Return (ListCons ret tl1)
+ then Return (List_Cons ret tl1)
else (
i0 <- u32_sub i 1%u32;
tl10 <- list_nth_shared_mut_loop_pair_loop_back T n0 tl0 tl1 i0 ret;
- Return (ListCons x1 tl10))
- | ListNil => Fail_ Failure
+ Return (List_Cons x1 tl10))
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
@@ -778,7 +790,7 @@ Definition list_nth_shared_mut_loop_pair_back
.
(** [loops::list_nth_shared_mut_loop_pair_merge]: loop 0: forward function *)
-Fixpoint list_nth_shared_mut_loop_pair_merge_loop_fwd
+Fixpoint list_nth_shared_mut_loop_pair_merge_loop
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
@@ -786,27 +798,27 @@ Fixpoint list_nth_shared_mut_loop_pair_merge_loop_fwd
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
then Return (x0, x1)
else (
i0 <- u32_sub i 1%u32;
- list_nth_shared_mut_loop_pair_merge_loop_fwd T n0 tl0 tl1 i0)
- | ListNil => Fail_ Failure
+ list_nth_shared_mut_loop_pair_merge_loop T n0 tl0 tl1 i0)
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
(** [loops::list_nth_shared_mut_loop_pair_merge]: forward function *)
-Definition list_nth_shared_mut_loop_pair_merge_fwd
+Definition list_nth_shared_mut_loop_pair_merge
(T : Type) (n : nat) (ls0 : List_t T) (ls1 : List_t T) (i : u32) :
result (T * T)
:=
- list_nth_shared_mut_loop_pair_merge_loop_fwd T n ls0 ls1 i
+ list_nth_shared_mut_loop_pair_merge_loop T n ls0 ls1 i
.
(** [loops::list_nth_shared_mut_loop_pair_merge]: loop 0: backward function 0 *)
@@ -818,19 +830,19 @@ Fixpoint list_nth_shared_mut_loop_pair_merge_loop_back
| O => Fail_ OutOfFuel
| S n0 =>
match ls0 with
- | ListCons x0 tl0 =>
+ | List_Cons x0 tl0 =>
match ls1 with
- | ListCons x1 tl1 =>
+ | List_Cons x1 tl1 =>
if i s= 0%u32
- then Return (ListCons ret tl1)
+ then Return (List_Cons ret tl1)
else (
i0 <- u32_sub i 1%u32;
tl10 <-
list_nth_shared_mut_loop_pair_merge_loop_back T n0 tl0 tl1 i0 ret;
- Return (ListCons x1 tl10))
- | ListNil => Fail_ Failure
+ Return (List_Cons x1 tl10))
+ | List_Nil => Fail_ Failure
end
- | ListNil => Fail_ Failure
+ | List_Nil => Fail_ Failure
end
end
.
diff --git a/tests/coq/misc/NoNestedBorrows.v b/tests/coq/misc/NoNestedBorrows.v
index c1c24e00..c7af496f 100644
--- a/tests/coq/misc/NoNestedBorrows.v
+++ b/tests/coq/misc/NoNestedBorrows.v
@@ -9,113 +9,125 @@ Local Open Scope Primitives_scope.
Module NoNestedBorrows.
(** [no_nested_borrows::Pair] *)
-Record Pair_t (T1 T2 : Type) := mkPair_t { Pair_x : T1; Pair_y : T2; }.
+Record Pair_t (T1 T2 : Type) := mkPair_t { pair_x : T1; pair_y : T2; }.
-Arguments mkPair_t {T1} {T2} _ _.
-Arguments Pair_x {T1} {T2}.
-Arguments Pair_y {T1} {T2}.
+Arguments mkPair_t { _ _ }.
+Arguments pair_x { _ _ }.
+Arguments pair_y { _ _ }.
(** [no_nested_borrows::List] *)
Inductive List_t (T : Type) :=
-| ListCons : T -> List_t T -> List_t T
-| ListNil : List_t T
+| List_Cons : T -> List_t T -> List_t T
+| List_Nil : List_t T
.
-Arguments ListCons {T} _ _.
-Arguments ListNil {T}.
+Arguments List_Cons { _ }.
+Arguments List_Nil { _ }.
(** [no_nested_borrows::One] *)
-Inductive One_t (T1 : Type) := | OneOne : T1 -> One_t T1.
+Inductive One_t (T1 : Type) := | One_One : T1 -> One_t T1.
-Arguments OneOne {T1} _.
+Arguments One_One { _ }.
(** [no_nested_borrows::EmptyEnum] *)
-Inductive Empty_enum_t := | EmptyEnumEmpty : Empty_enum_t.
+Inductive EmptyEnum_t := | EmptyEnum_Empty : EmptyEnum_t.
(** [no_nested_borrows::Enum] *)
-Inductive Enum_t := | EnumVariant1 : Enum_t | EnumVariant2 : Enum_t.
+Inductive Enum_t := | Enum_Variant1 : Enum_t | Enum_Variant2 : Enum_t.
(** [no_nested_borrows::EmptyStruct] *)
-Record Empty_struct_t := mkEmpty_struct_t { }.
+Record EmptyStruct_t := mkEmptyStruct_t { }.
(** [no_nested_borrows::Sum] *)
Inductive Sum_t (T1 T2 : Type) :=
-| SumLeft : T1 -> Sum_t T1 T2
-| SumRight : T2 -> Sum_t T1 T2
+| Sum_Left : T1 -> Sum_t T1 T2
+| Sum_Right : T2 -> Sum_t T1 T2
.
-Arguments SumLeft {T1} {T2} _.
-Arguments SumRight {T1} {T2} _.
+Arguments Sum_Left { _ _ }.
+Arguments Sum_Right { _ _ }.
(** [no_nested_borrows::neg_test]: forward function *)
-Definition neg_test_fwd (x : i32) : result i32 :=
+Definition neg_test (x : i32) : result i32 :=
i32_neg x.
(** [no_nested_borrows::add_test]: forward function *)
-Definition add_test_fwd (x : u32) (y : u32) : result u32 :=
+Definition add_test (x : u32) (y : u32) : result u32 :=
u32_add x y.
(** [no_nested_borrows::subs_test]: forward function *)
-Definition subs_test_fwd (x : u32) (y : u32) : result u32 :=
+Definition subs_test (x : u32) (y : u32) : result u32 :=
u32_sub x y.
(** [no_nested_borrows::div_test]: forward function *)
-Definition div_test_fwd (x : u32) (y : u32) : result u32 :=
+Definition div_test (x : u32) (y : u32) : result u32 :=
u32_div x y.
(** [no_nested_borrows::div_test1]: forward function *)
-Definition div_test1_fwd (x : u32) : result u32 :=
+Definition div_test1 (x : u32) : result u32 :=
u32_div x 2%u32.
(** [no_nested_borrows::rem_test]: forward function *)
-Definition rem_test_fwd (x : u32) (y : u32) : result u32 :=
+Definition rem_test (x : u32) (y : u32) : result u32 :=
u32_rem x y.
+(** [no_nested_borrows::mul_test]: forward function *)
+Definition mul_test (x : u32) (y : u32) : result u32 :=
+ u32_mul x y.
+
+(** [no_nested_borrows::CONST0] *)
+Definition const0_body : result usize := usize_add 1%usize 1%usize.
+Definition const0_c : usize := const0_body%global.
+
+(** [no_nested_borrows::CONST1] *)
+Definition const1_body : result usize := usize_mul 2%usize 2%usize.
+Definition const1_c : usize := const1_body%global.
+
(** [no_nested_borrows::cast_test]: forward function *)
-Definition cast_test_fwd (x : u32) : result i32 :=
+Definition cast_test (x : u32) : result i32 :=
scalar_cast U32 I32 x.
(** [no_nested_borrows::test2]: forward function *)
-Definition test2_fwd : result unit :=
+Definition test2 : result unit :=
_ <- u32_add 23%u32 44%u32; Return tt.
(** Unit test for [no_nested_borrows::test2] *)
-Check (test2_fwd )%return.
+Check (test2 )%return.
(** [no_nested_borrows::get_max]: forward function *)
-Definition get_max_fwd (x : u32) (y : u32) : result u32 :=
+Definition get_max (x : u32) (y : u32) : result u32 :=
if x s>= y then Return x else Return y
.
(** [no_nested_borrows::test3]: forward function *)
-Definition test3_fwd : result unit :=
- x <- get_max_fwd 4%u32 3%u32;
- y <- get_max_fwd 10%u32 11%u32;
+Definition test3 : result unit :=
+ x <- get_max 4%u32 3%u32;
+ y <- get_max 10%u32 11%u32;
z <- u32_add x y;
if negb (z s= 15%u32) then Fail_ Failure else Return tt
.
(** Unit test for [no_nested_borrows::test3] *)
-Check (test3_fwd )%return.
+Check (test3 )%return.
(** [no_nested_borrows::test_neg1]: forward function *)
-Definition test_neg1_fwd : result unit :=
+Definition test_neg1 : result unit :=
y <- i32_neg 3%i32; if negb (y s= (-3)%i32) then Fail_ Failure else Return tt
.
(** Unit test for [no_nested_borrows::test_neg1] *)
-Check (test_neg1_fwd )%return.
+Check (test_neg1 )%return.
(** [no_nested_borrows::refs_test1]: forward function *)
-Definition refs_test1_fwd : result unit :=
+Definition refs_test1 : result unit :=
if negb (1%i32 s= 1%i32) then Fail_ Failure else Return tt
.
(** Unit test for [no_nested_borrows::refs_test1] *)
-Check (refs_test1_fwd )%return.
+Check (refs_test1 )%return.
(** [no_nested_borrows::refs_test2]: forward function *)
-Definition refs_test2_fwd : result unit :=
+Definition refs_test2 : result unit :=
if negb (2%i32 s= 2%i32)
then Fail_ Failure
else
@@ -128,85 +140,83 @@ Definition refs_test2_fwd : result unit :=
.
(** Unit test for [no_nested_borrows::refs_test2] *)
-Check (refs_test2_fwd )%return.
+Check (refs_test2 )%return.
(** [no_nested_borrows::test_list1]: forward function *)
-Definition test_list1_fwd : result unit :=
+Definition test_list1 : result unit :=
Return tt.
(** Unit test for [no_nested_borrows::test_list1] *)
-Check (test_list1_fwd )%return.
+Check (test_list1 )%return.
(** [no_nested_borrows::test_box1]: forward function *)
-Definition test_box1_fwd : result unit :=
+Definition test_box1 : result unit :=
let b := 1%i32 in
let x := b in
if negb (x s= 1%i32) then Fail_ Failure else Return tt
.
(** Unit test for [no_nested_borrows::test_box1] *)
-Check (test_box1_fwd )%return.
+Check (test_box1 )%return.
(** [no_nested_borrows::copy_int]: forward function *)
-Definition copy_int_fwd (x : i32) : result i32 :=
+Definition copy_int (x : i32) : result i32 :=
Return x.
(** [no_nested_borrows::test_unreachable]: forward function *)
-Definition test_unreachable_fwd (b : bool) : result unit :=
+Definition test_unreachable (b : bool) : result unit :=
if b then Fail_ Failure else Return tt
.
(** [no_nested_borrows::test_panic]: forward function *)
-Definition test_panic_fwd (b : bool) : result unit :=
+Definition test_panic (b : bool) : result unit :=
if b then Fail_ Failure else Return tt
.
(** [no_nested_borrows::test_copy_int]: forward function *)
-Definition test_copy_int_fwd : result unit :=
- y <- copy_int_fwd 0%i32;
- if negb (0%i32 s= y) then Fail_ Failure else Return tt
+Definition test_copy_int : result unit :=
+ y <- copy_int 0%i32; if negb (0%i32 s= y) then Fail_ Failure else Return tt
.
(** Unit test for [no_nested_borrows::test_copy_int] *)
-Check (test_copy_int_fwd )%return.
+Check (test_copy_int )%return.
(** [no_nested_borrows::is_cons]: forward function *)
-Definition is_cons_fwd (T : Type) (l : List_t T) : result bool :=
- match l with | ListCons t l0 => Return true | ListNil => Return false end
+Definition is_cons (T : Type) (l : List_t T) : result bool :=
+ match l with | List_Cons t l0 => Return true | List_Nil => Return false end
.
(** [no_nested_borrows::test_is_cons]: forward function *)
-Definition test_is_cons_fwd : result unit :=
- let l := ListNil in
- b <- is_cons_fwd i32 (ListCons 0%i32 l);
+Definition test_is_cons : result unit :=
+ let l := List_Nil in
+ b <- is_cons i32 (List_Cons 0%i32 l);
if negb b then Fail_ Failure else Return tt
.
(** Unit test for [no_nested_borrows::test_is_cons] *)
-Check (test_is_cons_fwd )%return.
+Check (test_is_cons )%return.
(** [no_nested_borrows::split_list]: forward function *)
-Definition split_list_fwd
- (T : Type) (l : List_t T) : result (T * (List_t T)) :=
+Definition split_list (T : Type) (l : List_t T) : result (T * (List_t T)) :=
match l with
- | ListCons hd tl => Return (hd, tl)
- | ListNil => Fail_ Failure
+ | List_Cons hd tl => Return (hd, tl)
+ | List_Nil => Fail_ Failure
end
.
(** [no_nested_borrows::test_split_list]: forward function *)
-Definition test_split_list_fwd : result unit :=
- let l := ListNil in
- p <- split_list_fwd i32 (ListCons 0%i32 l);
+Definition test_split_list : result unit :=
+ let l := List_Nil in
+ p <- split_list i32 (List_Cons 0%i32 l);
let (hd, _) := p in
if negb (hd s= 0%i32) then Fail_ Failure else Return tt
.
(** Unit test for [no_nested_borrows::test_split_list] *)
-Check (test_split_list_fwd )%return.
+Check (test_split_list )%return.
(** [no_nested_borrows::choose]: forward function *)
-Definition choose_fwd (T : Type) (b : bool) (x : T) (y : T) : result T :=
+Definition choose (T : Type) (b : bool) (x : T) (y : T) : result T :=
if b then Return x else Return y
.
@@ -217,8 +227,8 @@ Definition choose_back
.
(** [no_nested_borrows::choose_test]: forward function *)
-Definition choose_test_fwd : result unit :=
- z <- choose_fwd i32 true 0%i32 0%i32;
+Definition choose_test : result unit :=
+ z <- choose i32 true 0%i32 0%i32;
z0 <- i32_add z 1%i32;
if negb (z0 s= 1%i32)
then Fail_ Failure
@@ -231,57 +241,56 @@ Definition choose_test_fwd : result unit :=
.
(** Unit test for [no_nested_borrows::choose_test] *)
-Check (choose_test_fwd )%return.
+Check (choose_test )%return.
(** [no_nested_borrows::test_char]: forward function *)
-Definition test_char_fwd : result char :=
- Return (char_of_byte Coq.Init.Byte.x61)
-.
+Definition test_char : result char :=
+ Return (char_of_byte Coq.Init.Byte.x61).
(** [no_nested_borrows::Tree] *)
Inductive Tree_t (T : Type) :=
-| TreeLeaf : T -> Tree_t T
-| TreeNode : T -> Node_elem_t T -> Tree_t T -> Tree_t T
+| Tree_Leaf : T -> Tree_t T
+| Tree_Node : T -> NodeElem_t T -> Tree_t T -> Tree_t T
(** [no_nested_borrows::NodeElem] *)
-with Node_elem_t (T : Type) :=
-| NodeElemCons : Tree_t T -> Node_elem_t T -> Node_elem_t T
-| NodeElemNil : Node_elem_t T
+with NodeElem_t (T : Type) :=
+| NodeElem_Cons : Tree_t T -> NodeElem_t T -> NodeElem_t T
+| NodeElem_Nil : NodeElem_t T
.
-Arguments TreeLeaf {T} _.
-Arguments TreeNode {T} _ _ _.
+Arguments Tree_Leaf { _ }.
+Arguments Tree_Node { _ }.
-Arguments NodeElemCons {T} _ _.
-Arguments NodeElemNil {T}.
+Arguments NodeElem_Cons { _ }.
+Arguments NodeElem_Nil { _ }.
(** [no_nested_borrows::list_length]: forward function *)
-Fixpoint list_length_fwd (T : Type) (l : List_t T) : result u32 :=
+Fixpoint list_length (T : Type) (l : List_t T) : result u32 :=
match l with
- | ListCons t l1 => i <- list_length_fwd T l1; u32_add 1%u32 i
- | ListNil => Return 0%u32
+ | List_Cons t l1 => i <- list_length T l1; u32_add 1%u32 i
+ | List_Nil => Return 0%u32
end
.
(** [no_nested_borrows::list_nth_shared]: forward function *)
-Fixpoint list_nth_shared_fwd (T : Type) (l : List_t T) (i : u32) : result T :=
+Fixpoint list_nth_shared (T : Type) (l : List_t T) (i : u32) : result T :=
match l with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
then Return x
- else (i0 <- u32_sub i 1%u32; list_nth_shared_fwd T tl i0)
- | ListNil => Fail_ Failure
+ else (i0 <- u32_sub i 1%u32; list_nth_shared T tl i0)
+ | List_Nil => Fail_ Failure
end
.
(** [no_nested_borrows::list_nth_mut]: forward function *)
-Fixpoint list_nth_mut_fwd (T : Type) (l : List_t T) (i : u32) : result T :=
+Fixpoint list_nth_mut (T : Type) (l : List_t T) (i : u32) : result T :=
match l with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
then Return x
- else (i0 <- u32_sub i 1%u32; list_nth_mut_fwd T tl i0)
- | ListNil => Fail_ Failure
+ else (i0 <- u32_sub i 1%u32; list_nth_mut T tl i0)
+ | List_Nil => Fail_ Failure
end
.
@@ -289,73 +298,72 @@ Fixpoint list_nth_mut_fwd (T : Type) (l : List_t T) (i : u32) : result T :=
Fixpoint list_nth_mut_back
(T : Type) (l : List_t T) (i : u32) (ret : T) : result (List_t T) :=
match l with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
- then Return (ListCons ret tl)
+ then Return (List_Cons ret tl)
else (
i0 <- u32_sub i 1%u32;
tl0 <- list_nth_mut_back T tl i0 ret;
- Return (ListCons x tl0))
- | ListNil => Fail_ Failure
+ Return (List_Cons x tl0))
+ | List_Nil => Fail_ Failure
end
.
(** [no_nested_borrows::list_rev_aux]: forward function *)
-Fixpoint list_rev_aux_fwd
+Fixpoint list_rev_aux
(T : Type) (li : List_t T) (lo : List_t T) : result (List_t T) :=
match li with
- | ListCons hd tl => list_rev_aux_fwd T tl (ListCons hd lo)
- | ListNil => Return lo
+ | List_Cons hd tl => list_rev_aux T tl (List_Cons hd lo)
+ | List_Nil => Return lo
end
.
(** [no_nested_borrows::list_rev]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition list_rev_fwd_back (T : Type) (l : List_t T) : result (List_t T) :=
- let li := mem_replace_fwd (List_t T) l ListNil in
- list_rev_aux_fwd T li ListNil
+Definition list_rev (T : Type) (l : List_t T) : result (List_t T) :=
+ let li := core_mem_replace (List_t T) l List_Nil in
+ list_rev_aux T li List_Nil
.
(** [no_nested_borrows::test_list_functions]: forward function *)
-Definition test_list_functions_fwd : result unit :=
- let l := ListNil in
- let l0 := ListCons 2%i32 l in
- let l1 := ListCons 1%i32 l0 in
- i <- list_length_fwd i32 (ListCons 0%i32 l1);
+Definition test_list_functions : result unit :=
+ let l := List_Nil in
+ let l0 := List_Cons 2%i32 l in
+ let l1 := List_Cons 1%i32 l0 in
+ i <- list_length i32 (List_Cons 0%i32 l1);
if negb (i s= 3%u32)
then Fail_ Failure
else (
- i0 <- list_nth_shared_fwd i32 (ListCons 0%i32 l1) 0%u32;
+ i0 <- list_nth_shared i32 (List_Cons 0%i32 l1) 0%u32;
if negb (i0 s= 0%i32)
then Fail_ Failure
else (
- i1 <- list_nth_shared_fwd i32 (ListCons 0%i32 l1) 1%u32;
+ i1 <- list_nth_shared i32 (List_Cons 0%i32 l1) 1%u32;
if negb (i1 s= 1%i32)
then Fail_ Failure
else (
- i2 <- list_nth_shared_fwd i32 (ListCons 0%i32 l1) 2%u32;
+ i2 <- list_nth_shared i32 (List_Cons 0%i32 l1) 2%u32;
if negb (i2 s= 2%i32)
then Fail_ Failure
else (
- ls <- list_nth_mut_back i32 (ListCons 0%i32 l1) 1%u32 3%i32;
- i3 <- list_nth_shared_fwd i32 ls 0%u32;
+ ls <- list_nth_mut_back i32 (List_Cons 0%i32 l1) 1%u32 3%i32;
+ i3 <- list_nth_shared i32 ls 0%u32;
if negb (i3 s= 0%i32)
then Fail_ Failure
else (
- i4 <- list_nth_shared_fwd i32 ls 1%u32;
+ i4 <- list_nth_shared i32 ls 1%u32;
if negb (i4 s= 3%i32)
then Fail_ Failure
else (
- i5 <- list_nth_shared_fwd i32 ls 2%u32;
+ i5 <- list_nth_shared i32 ls 2%u32;
if negb (i5 s= 2%i32) then Fail_ Failure else Return tt))))))
.
(** Unit test for [no_nested_borrows::test_list_functions] *)
-Check (test_list_functions_fwd )%return.
+Check (test_list_functions )%return.
(** [no_nested_borrows::id_mut_pair1]: forward function *)
-Definition id_mut_pair1_fwd
- (T1 T2 : Type) (x : T1) (y : T2) : result (T1 * T2) :=
+Definition id_mut_pair1 (T1 T2 : Type) (x : T1) (y : T2) : result (T1 * T2) :=
Return (x, y)
.
@@ -366,8 +374,7 @@ Definition id_mut_pair1_back
.
(** [no_nested_borrows::id_mut_pair2]: forward function *)
-Definition id_mut_pair2_fwd
- (T1 T2 : Type) (p : (T1 * T2)) : result (T1 * T2) :=
+Definition id_mut_pair2 (T1 T2 : Type) (p : (T1 * T2)) : result (T1 * T2) :=
let (t, t0) := p in Return (t, t0)
.
@@ -378,8 +385,7 @@ Definition id_mut_pair2_back
.
(** [no_nested_borrows::id_mut_pair3]: forward function *)
-Definition id_mut_pair3_fwd
- (T1 T2 : Type) (x : T1) (y : T2) : result (T1 * T2) :=
+Definition id_mut_pair3 (T1 T2 : Type) (x : T1) (y : T2) : result (T1 * T2) :=
Return (x, y)
.
@@ -396,8 +402,7 @@ Definition id_mut_pair3_back'b
.
(** [no_nested_borrows::id_mut_pair4]: forward function *)
-Definition id_mut_pair4_fwd
- (T1 T2 : Type) (p : (T1 * T2)) : result (T1 * T2) :=
+Definition id_mut_pair4 (T1 T2 : Type) (p : (T1 * T2)) : result (T1 * T2) :=
let (t, t0) := p in Return (t, t0)
.
@@ -414,101 +419,101 @@ Definition id_mut_pair4_back'b
.
(** [no_nested_borrows::StructWithTuple] *)
-Record Struct_with_tuple_t (T1 T2 : Type) :=
-mkStruct_with_tuple_t {
- Struct_with_tuple_p : (T1 * T2);
+Record StructWithTuple_t (T1 T2 : Type) :=
+mkStructWithTuple_t {
+ structWithTuple_p : (T1 * T2);
}
.
-Arguments mkStruct_with_tuple_t {T1} {T2} _.
-Arguments Struct_with_tuple_p {T1} {T2}.
+Arguments mkStructWithTuple_t { _ _ }.
+Arguments structWithTuple_p { _ _ }.
(** [no_nested_borrows::new_tuple1]: forward function *)
-Definition new_tuple1_fwd : result (Struct_with_tuple_t u32 u32) :=
- Return {| Struct_with_tuple_p := (1%u32, 2%u32) |}
+Definition new_tuple1 : result (StructWithTuple_t u32 u32) :=
+ Return {| structWithTuple_p := (1%u32, 2%u32) |}
.
(** [no_nested_borrows::new_tuple2]: forward function *)
-Definition new_tuple2_fwd : result (Struct_with_tuple_t i16 i16) :=
- Return {| Struct_with_tuple_p := (1%i16, 2%i16) |}
+Definition new_tuple2 : result (StructWithTuple_t i16 i16) :=
+ Return {| structWithTuple_p := (1%i16, 2%i16) |}
.
(** [no_nested_borrows::new_tuple3]: forward function *)
-Definition new_tuple3_fwd : result (Struct_with_tuple_t u64 i64) :=
- Return {| Struct_with_tuple_p := (1%u64, 2%i64) |}
+Definition new_tuple3 : result (StructWithTuple_t u64 i64) :=
+ Return {| structWithTuple_p := (1%u64, 2%i64) |}
.
(** [no_nested_borrows::StructWithPair] *)
-Record Struct_with_pair_t (T1 T2 : Type) :=
-mkStruct_with_pair_t {
- Struct_with_pair_p : Pair_t T1 T2;
+Record StructWithPair_t (T1 T2 : Type) :=
+mkStructWithPair_t {
+ structWithPair_p : Pair_t T1 T2;
}
.
-Arguments mkStruct_with_pair_t {T1} {T2} _.
-Arguments Struct_with_pair_p {T1} {T2}.
+Arguments mkStructWithPair_t { _ _ }.
+Arguments structWithPair_p { _ _ }.
(** [no_nested_borrows::new_pair1]: forward function *)
-Definition new_pair1_fwd : result (Struct_with_pair_t u32 u32) :=
- Return {| Struct_with_pair_p := {| Pair_x := 1%u32; Pair_y := 2%u32 |} |}
+Definition new_pair1 : result (StructWithPair_t u32 u32) :=
+ Return {| structWithPair_p := {| pair_x := 1%u32; pair_y := 2%u32 |} |}
.
(** [no_nested_borrows::test_constants]: forward function *)
-Definition test_constants_fwd : result unit :=
- swt <- new_tuple1_fwd;
- let (i, _) := swt.(Struct_with_tuple_p) in
+Definition test_constants : result unit :=
+ swt <- new_tuple1;
+ let (i, _) := swt.(structWithTuple_p) in
if negb (i s= 1%u32)
then Fail_ Failure
else (
- swt0 <- new_tuple2_fwd;
- let (i0, _) := swt0.(Struct_with_tuple_p) in
+ swt0 <- new_tuple2;
+ let (i0, _) := swt0.(structWithTuple_p) in
if negb (i0 s= 1%i16)
then Fail_ Failure
else (
- swt1 <- new_tuple3_fwd;
- let (i1, _) := swt1.(Struct_with_tuple_p) in
+ swt1 <- new_tuple3;
+ let (i1, _) := swt1.(structWithTuple_p) in
if negb (i1 s= 1%u64)
then Fail_ Failure
else (
- swp <- new_pair1_fwd;
- if negb (swp.(Struct_with_pair_p).(Pair_x) s= 1%u32)
+ swp <- new_pair1;
+ if negb (swp.(structWithPair_p).(pair_x) s= 1%u32)
then Fail_ Failure
else Return tt)))
.
(** Unit test for [no_nested_borrows::test_constants] *)
-Check (test_constants_fwd )%return.
+Check (test_constants )%return.
(** [no_nested_borrows::test_weird_borrows1]: forward function *)
-Definition test_weird_borrows1_fwd : result unit :=
+Definition test_weird_borrows1 : result unit :=
Return tt.
(** Unit test for [no_nested_borrows::test_weird_borrows1] *)
-Check (test_weird_borrows1_fwd )%return.
+Check (test_weird_borrows1 )%return.
(** [no_nested_borrows::test_mem_replace]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition test_mem_replace_fwd_back (px : u32) : result u32 :=
- let y := mem_replace_fwd u32 px 1%u32 in
+Definition test_mem_replace (px : u32) : result u32 :=
+ let y := core_mem_replace u32 px 1%u32 in
if negb (y s= 0%u32) then Fail_ Failure else Return 2%u32
.
(** [no_nested_borrows::test_shared_borrow_bool1]: forward function *)
-Definition test_shared_borrow_bool1_fwd (b : bool) : result u32 :=
+Definition test_shared_borrow_bool1 (b : bool) : result u32 :=
if b then Return 0%u32 else Return 1%u32
.
(** [no_nested_borrows::test_shared_borrow_bool2]: forward function *)
-Definition test_shared_borrow_bool2_fwd : result u32 :=
+Definition test_shared_borrow_bool2 : result u32 :=
Return 0%u32.
(** [no_nested_borrows::test_shared_borrow_enum1]: forward function *)
-Definition test_shared_borrow_enum1_fwd (l : List_t u32) : result u32 :=
- match l with | ListCons i l0 => Return 1%u32 | ListNil => Return 0%u32 end
+Definition test_shared_borrow_enum1 (l : List_t u32) : result u32 :=
+ match l with | List_Cons i l0 => Return 1%u32 | List_Nil => Return 0%u32 end
.
(** [no_nested_borrows::test_shared_borrow_enum2]: forward function *)
-Definition test_shared_borrow_enum2_fwd : result u32 :=
+Definition test_shared_borrow_enum2 : result u32 :=
Return 0%u32.
End NoNestedBorrows .
diff --git a/tests/coq/misc/Paper.v b/tests/coq/misc/Paper.v
index 175a523d..d3852e6b 100644
--- a/tests/coq/misc/Paper.v
+++ b/tests/coq/misc/Paper.v
@@ -10,20 +10,19 @@ Module Paper.
(** [paper::ref_incr]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-Definition ref_incr_fwd_back (x : i32) : result i32 :=
+Definition ref_incr (x : i32) : result i32 :=
i32_add x 1%i32.
(** [paper::test_incr]: forward function *)
-Definition test_incr_fwd : result unit :=
- x <- ref_incr_fwd_back 0%i32;
- if negb (x s= 1%i32) then Fail_ Failure else Return tt
+Definition test_incr : result unit :=
+ x <- ref_incr 0%i32; if negb (x s= 1%i32) then Fail_ Failure else Return tt
.
(** Unit test for [paper::test_incr] *)
-Check (test_incr_fwd )%return.
+Check (test_incr )%return.
(** [paper::choose]: forward function *)
-Definition choose_fwd (T : Type) (b : bool) (x : T) (y : T) : result T :=
+Definition choose (T : Type) (b : bool) (x : T) (y : T) : result T :=
if b then Return x else Return y
.
@@ -34,8 +33,8 @@ Definition choose_back
.
(** [paper::test_choose]: forward function *)
-Definition test_choose_fwd : result unit :=
- z <- choose_fwd i32 true 0%i32 0%i32;
+Definition test_choose : result unit :=
+ z <- choose i32 true 0%i32 0%i32;
z0 <- i32_add z 1%i32;
if negb (z0 s= 1%i32)
then Fail_ Failure
@@ -48,25 +47,25 @@ Definition test_choose_fwd : result unit :=
.
(** Unit test for [paper::test_choose] *)
-Check (test_choose_fwd )%return.
+Check (test_choose )%return.
(** [paper::List] *)
Inductive List_t (T : Type) :=
-| ListCons : T -> List_t T -> List_t T
-| ListNil : List_t T
+| List_Cons : T -> List_t T -> List_t T
+| List_Nil : List_t T
.
-Arguments ListCons {T} _ _.
-Arguments ListNil {T}.
+Arguments List_Cons { _ }.
+Arguments List_Nil { _ }.
(** [paper::list_nth_mut]: forward function *)
-Fixpoint list_nth_mut_fwd (T : Type) (l : List_t T) (i : u32) : result T :=
+Fixpoint list_nth_mut (T : Type) (l : List_t T) (i : u32) : result T :=
match l with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
then Return x
- else (i0 <- u32_sub i 1%u32; list_nth_mut_fwd T tl i0)
- | ListNil => Fail_ Failure
+ else (i0 <- u32_sub i 1%u32; list_nth_mut T tl i0)
+ | List_Nil => Fail_ Failure
end
.
@@ -74,44 +73,44 @@ Fixpoint list_nth_mut_fwd (T : Type) (l : List_t T) (i : u32) : result T :=
Fixpoint list_nth_mut_back
(T : Type) (l : List_t T) (i : u32) (ret : T) : result (List_t T) :=
match l with
- | ListCons x tl =>
+ | List_Cons x tl =>
if i s= 0%u32
- then Return (ListCons ret tl)
+ then Return (List_Cons ret tl)
else (
i0 <- u32_sub i 1%u32;
tl0 <- list_nth_mut_back T tl i0 ret;
- Return (ListCons x tl0))
- | ListNil => Fail_ Failure
+ Return (List_Cons x tl0))
+ | List_Nil => Fail_ Failure
end
.
(** [paper::sum]: forward function *)
-Fixpoint sum_fwd (l : List_t i32) : result i32 :=
+Fixpoint sum (l : List_t i32) : result i32 :=
match l with
- | ListCons x tl => i <- sum_fwd tl; i32_add x i
- | ListNil => Return 0%i32
+ | List_Cons x tl => i <- sum tl; i32_add x i
+ | List_Nil => Return 0%i32
end
.
(** [paper::test_nth]: forward function *)
-Definition test_nth_fwd : result unit :=
- let l := ListNil in
- let l0 := ListCons 3%i32 l in
- let l1 := ListCons 2%i32 l0 in
- x <- list_nth_mut_fwd i32 (ListCons 1%i32 l1) 2%u32;
+Definition test_nth : result unit :=
+ let l := List_Nil in
+ let l0 := List_Cons 3%i32 l in
+ let l1 := List_Cons 2%i32 l0 in
+ x <- list_nth_mut i32 (List_Cons 1%i32 l1) 2%u32;
x0 <- i32_add x 1%i32;
- l2 <- list_nth_mut_back i32 (ListCons 1%i32 l1) 2%u32 x0;
- i <- sum_fwd l2;
+ l2 <- list_nth_mut_back i32 (List_Cons 1%i32 l1) 2%u32 x0;
+ i <- sum l2;
if negb (i s= 7%i32) then Fail_ Failure else Return tt
.
(** Unit test for [paper::test_nth] *)
-Check (test_nth_fwd )%return.
+Check (test_nth )%return.
(** [paper::call_choose]: forward function *)
-Definition call_choose_fwd (p : (u32 * u32)) : result u32 :=
+Definition call_choose (p : (u32 * u32)) : result u32 :=
let (px, py) := p in
- pz <- choose_fwd u32 true px py;
+ pz <- choose u32 true px py;
pz0 <- u32_add pz 1%u32;
p0 <- choose_back u32 true px py pz0;
let (px0, _) := p0 in
diff --git a/tests/coq/misc/PoloniusList.v b/tests/coq/misc/PoloniusList.v
index 54021bdf..4848444f 100644
--- a/tests/coq/misc/PoloniusList.v
+++ b/tests/coq/misc/PoloniusList.v
@@ -10,19 +10,19 @@ Module PoloniusList.
(** [polonius_list::List] *)
Inductive List_t (T : Type) :=
-| ListCons : T -> List_t T -> List_t T
-| ListNil : List_t T
+| List_Cons : T -> List_t T -> List_t T
+| List_Nil : List_t T
.
-Arguments ListCons {T} _ _.
-Arguments ListNil {T}.
+Arguments List_Cons { _ }.
+Arguments List_Nil { _ }.
(** [polonius_list::get_list_at_x]: forward function *)
-Fixpoint get_list_at_x_fwd (ls : List_t u32) (x : u32) : result (List_t u32) :=
+Fixpoint get_list_at_x (ls : List_t u32) (x : u32) : result (List_t u32) :=
match ls with
- | ListCons hd tl =>
- if hd s= x then Return (ListCons hd tl) else get_list_at_x_fwd tl x
- | ListNil => Return ListNil
+ | List_Cons hd tl =>
+ if hd s= x then Return (List_Cons hd tl) else get_list_at_x tl x
+ | List_Nil => Return List_Nil
end
.
@@ -30,11 +30,11 @@ Fixpoint get_list_at_x_fwd (ls : List_t u32) (x : u32) : result (List_t u32) :=
Fixpoint get_list_at_x_back
(ls : List_t u32) (x : u32) (ret : List_t u32) : result (List_t u32) :=
match ls with
- | ListCons hd tl =>
+ | List_Cons hd tl =>
if hd s= x
then Return ret
- else (tl0 <- get_list_at_x_back tl x ret; Return (ListCons hd tl0))
- | ListNil => Return ret
+ else (tl0 <- get_list_at_x_back tl x ret; Return (List_Cons hd tl0))
+ | List_Nil => Return ret
end
.
diff --git a/tests/coq/misc/Primitives.v b/tests/coq/misc/Primitives.v
index 71a2d9c3..85e38f01 100644
--- a/tests/coq/misc/Primitives.v
+++ b/tests/coq/misc/Primitives.v
@@ -63,13 +63,15 @@ Check (if true then Return (1 + 2) else Fail_ Failure)%global = 3.
(*** Misc *)
-
Definition string := Coq.Strings.String.string.
Definition char := Coq.Strings.Ascii.ascii.
Definition char_of_byte := Coq.Strings.Ascii.ascii_of_byte.
-Definition mem_replace_fwd (a : Type) (x : a) (y : a) : a := x .
-Definition mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+Definition core_mem_replace (a : Type) (x : a) (y : a) : a := x .
+Definition core_mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+
+Record mut_raw_ptr (T : Type) := { mut_raw_ptr_v : T }.
+Record const_raw_ptr (T : Type) := { const_raw_ptr_v : T }.
(*** Scalars *)
@@ -394,12 +396,89 @@ Notation "x s< y" := (scalar_ltb x y) (at level 80) : Primitives_scope.
Notation "x s>= y" := (scalar_geb x y) (at level 80) : Primitives_scope.
Notation "x s> y" := (scalar_gtb x y) (at level 80) : Primitives_scope.
-(*** Range *)
-Record range (T : Type) := mk_range {
- start: T;
- end_: T;
+(** Constants *)
+Definition core_u8_max := u8_max %u32.
+Definition core_u16_max := u16_max %u32.
+Definition core_u32_max := u32_max %u32.
+Definition core_u64_max := u64_max %u64.
+Definition core_u128_max := u64_max %u128.
+Axiom core_usize_max : usize. (** TODO *)
+Definition core_i8_max := i8_max %i32.
+Definition core_i16_max := i16_max %i32.
+Definition core_i32_max := i32_max %i32.
+Definition core_i64_max := i64_max %i64.
+Definition core_i128_max := i64_max %i128.
+Axiom core_isize_max : isize. (** TODO *)
+
+(*** core::ops *)
+
+(* Trait declaration: [core::ops::index::Index] *)
+Record core_ops_index_Index (Self Idx : Type) := mk_core_ops_index_Index {
+ core_ops_index_Index_Output : Type;
+ core_ops_index_Index_index : Self -> Idx -> result core_ops_index_Index_Output;
+}.
+Arguments mk_core_ops_index_Index {_ _}.
+Arguments core_ops_index_Index_Output {_ _}.
+Arguments core_ops_index_Index_index {_ _}.
+
+(* Trait declaration: [core::ops::index::IndexMut] *)
+Record core_ops_index_IndexMut (Self Idx : Type) := mk_core_ops_index_IndexMut {
+ core_ops_index_IndexMut_indexInst : core_ops_index_Index Self Idx;
+ core_ops_index_IndexMut_index_mut : Self -> Idx -> result core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output);
+ core_ops_index_IndexMut_index_mut_back : Self -> Idx -> core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output) -> result Self;
+}.
+Arguments mk_core_ops_index_IndexMut {_ _}.
+Arguments core_ops_index_IndexMut_indexInst {_ _}.
+Arguments core_ops_index_IndexMut_index_mut {_ _}.
+Arguments core_ops_index_IndexMut_index_mut_back {_ _}.
+
+(* Trait declaration [core::ops::deref::Deref] *)
+Record core_ops_deref_Deref (Self : Type) := mk_core_ops_deref_Deref {
+ core_ops_deref_Deref_target : Type;
+ core_ops_deref_Deref_deref : Self -> result core_ops_deref_Deref_target;
+}.
+Arguments mk_core_ops_deref_Deref {_}.
+Arguments core_ops_deref_Deref_target {_}.
+Arguments core_ops_deref_Deref_deref {_}.
+
+(* Trait declaration [core::ops::deref::DerefMut] *)
+Record core_ops_deref_DerefMut (Self : Type) := mk_core_ops_deref_DerefMut {
+ core_ops_deref_DerefMut_derefInst : core_ops_deref_Deref Self;
+ core_ops_deref_DerefMut_deref_mut : Self -> result core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target);
+ core_ops_deref_DerefMut_deref_mut_back : Self -> core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target) -> result Self;
}.
-Arguments mk_range {_}.
+Arguments mk_core_ops_deref_DerefMut {_}.
+Arguments core_ops_deref_DerefMut_derefInst {_}.
+Arguments core_ops_deref_DerefMut_deref_mut {_}.
+Arguments core_ops_deref_DerefMut_deref_mut_back {_}.
+
+Record core_ops_range_Range (T : Type) := mk_core_ops_range_Range {
+ core_ops_range_Range_start : T;
+ core_ops_range_Range_end_ : T;
+}.
+Arguments mk_core_ops_range_Range {_}.
+Arguments core_ops_range_Range_start {_}.
+Arguments core_ops_range_Range_end_ {_}.
+
+(*** [alloc] *)
+
+Definition alloc_boxed_Box_deref (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut_back (T : Type) (_ : T) (x : T) : result T := Return x.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefInst (Self : Type) : core_ops_deref_Deref Self := {|
+ core_ops_deref_Deref_target := Self;
+ core_ops_deref_Deref_deref := alloc_boxed_Box_deref Self;
+|}.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefMutInst (Self : Type) : core_ops_deref_DerefMut Self := {|
+ core_ops_deref_DerefMut_derefInst := alloc_boxed_Box_coreOpsDerefInst Self;
+ core_ops_deref_DerefMut_deref_mut := alloc_boxed_Box_deref_mut Self;
+ core_ops_deref_DerefMut_deref_mut_back := alloc_boxed_Box_deref_mut_back Self;
+|}.
+
(*** Arrays *)
Definition array T (n : usize) := { l: list T | Z.of_nat (length l) = to_Z n}.
@@ -419,51 +498,50 @@ Qed.
(* TODO: finish the definitions *)
Axiom mk_array : forall (T : Type) (n : usize) (l : list T), array T n.
-Axiom array_index_shared : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_fwd : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
-Axiom array_index_mut_back : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
+(* For initialization *)
+Axiom array_repeat : forall (T : Type) (n : usize) (x : T), array T n.
+
+Axiom array_index_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
+Axiom array_update_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
(*** Slice *)
Definition slice T := { l: list T | Z.of_nat (length l) <= usize_max}.
Axiom slice_len : forall (T : Type) (s : slice T), usize.
-Axiom slice_index_shared : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_fwd : forall (T : Type) (x : slice T) (i : usize), result T.
-Axiom slice_index_mut_back : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
+Axiom slice_index_usize : forall (T : Type) (x : slice T) (i : usize), result T.
+Axiom slice_update_usize : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
(*** Subslices *)
-Axiom array_to_slice_shared : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_fwd : forall (T : Type) (n : usize) (x : array T n), result (slice T).
-Axiom array_to_slice_mut_back : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+Axiom array_to_slice : forall (T : Type) (n : usize) (x : array T n), result (slice T).
+Axiom array_from_slice : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+
+Axiom array_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize), result (slice T).
+Axiom array_update_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize) (ns : slice T), result (array T n).
-Axiom array_subslice_shared: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_fwd: forall (T : Type) (n : usize) (x : array T n) (r : range usize), result (slice T).
-Axiom array_subslice_mut_back: forall (T : Type) (n : usize) (x : array T n) (r : range usize) (ns : slice T), result (array T n).
-Axiom slice_subslice_shared: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_fwd: forall (T : Type) (x : slice T) (r : range usize), result (slice T).
-Axiom slice_subslice_mut_back: forall (T : Type) (x : slice T) (r : range usize) (ns : slice T), result (slice T).
+Axiom slice_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize), result (slice T).
+Axiom slice_update_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize) (ns : slice T), result (slice T).
(*** Vectors *)
-Definition vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
+Definition alloc_vec_Vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
-Definition vec_to_list {T: Type} (v: vec T) : list T := proj1_sig v.
+Definition alloc_vec_Vec_to_list {T: Type} (v: alloc_vec_Vec T) : list T := proj1_sig v.
-Definition vec_length {T: Type} (v: vec T) : Z := Z.of_nat (length (vec_to_list v)).
+Definition alloc_vec_Vec_length {T: Type} (v: alloc_vec_Vec T) : Z := Z.of_nat (length (alloc_vec_Vec_to_list v)).
-Definition vec_new (T: Type) : vec T := (exist _ [] le_0_usize_max).
+Definition alloc_vec_Vec_new (T: Type) : alloc_vec_Vec T := (exist _ [] le_0_usize_max).
-Lemma vec_len_in_usize {T} (v: vec T) : usize_min <= vec_length v <= usize_max.
+Lemma alloc_vec_Vec_len_in_usize {T} (v: alloc_vec_Vec T) : usize_min <= alloc_vec_Vec_length v <= usize_max.
Proof.
- unfold vec_length, usize_min.
+ unfold alloc_vec_Vec_length, usize_min.
split.
- lia.
- apply (proj2_sig v).
Qed.
-Definition vec_len (T: Type) (v: vec T) : usize :=
- exist _ (vec_length v) (vec_len_in_usize v).
+Definition alloc_vec_Vec_len (T: Type) (v: alloc_vec_Vec T) : usize :=
+ exist _ (alloc_vec_Vec_length v) (alloc_vec_Vec_len_in_usize v).
Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
: list A :=
@@ -474,50 +552,271 @@ Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
| S m => x :: (list_update t m a)
end end.
-Definition vec_bind {A B} (v: vec A) (f: list A -> result (list B)) : result (vec B) :=
- l <- f (vec_to_list v) ;
+Definition alloc_vec_Vec_bind {A B} (v: alloc_vec_Vec A) (f: list A -> result (list B)) : result (alloc_vec_Vec B) :=
+ l <- f (alloc_vec_Vec_to_list v) ;
match sumbool_of_bool (scalar_le_max Usize (Z.of_nat (length l))) with
| left H => Return (exist _ l (scalar_le_max_valid _ _ H))
| right _ => Fail_ Failure
end.
(* The **forward** function shouldn't be used *)
-Definition vec_push_fwd (T: Type) (v: vec T) (x: T) : unit := tt.
+Definition alloc_vec_Vec_push_fwd (T: Type) (v: alloc_vec_Vec T) (x: T) : unit := tt.
-Definition vec_push_back (T: Type) (v: vec T) (x: T) : result (vec T) :=
- vec_bind v (fun l => Return (l ++ [x])).
+Definition alloc_vec_Vec_push (T: Type) (v: alloc_vec_Vec T) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l => Return (l ++ [x])).
(* The **forward** function shouldn't be used *)
-Definition vec_insert_fwd (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
+Definition alloc_vec_Vec_insert_fwd (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result unit :=
+ if to_Z i <? alloc_vec_Vec_length v then Return tt else Fail_ Failure.
-Definition vec_insert_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
+Definition alloc_vec_Vec_insert (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l =>
if to_Z i <? Z.of_nat (length l)
then Return (list_update l (usize_to_nat i) x)
else Fail_ Failure).
-(* The **backward** function shouldn't be used *)
-Definition vec_index_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
- end.
-
-Definition vec_index_back (T: Type) (v: vec T) (i: usize) (x: T) : result unit :=
- if to_Z i <? vec_length v then Return tt else Fail_ Failure.
-
-(* The **backward** function shouldn't be used *)
-Definition vec_index_mut_fwd (T: Type) (v: vec T) (i: usize) : result T :=
- match nth_error (vec_to_list v) (usize_to_nat i) with
- | Some n => Return n
- | None => Fail_ Failure
+(* Helper *)
+Axiom alloc_vec_Vec_index_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result T.
+
+(* Helper *)
+Axiom alloc_vec_Vec_update_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result (alloc_vec_Vec T).
+
+(* Trait declaration: [core::slice::index::private_slice_index::Sealed] *)
+Definition core_slice_index_private_slice_index_Sealed (self : Type) := unit.
+
+(* Trait declaration: [core::slice::index::SliceIndex] *)
+Record core_slice_index_SliceIndex (Self T : Type) := mk_core_slice_index_SliceIndex {
+ core_slice_index_SliceIndex_sealedInst : core_slice_index_private_slice_index_Sealed Self;
+ core_slice_index_SliceIndex_Output : Type;
+ core_slice_index_SliceIndex_get : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut_back : Self -> T -> option core_slice_index_SliceIndex_Output -> result T;
+ core_slice_index_SliceIndex_get_unchecked : Self -> const_raw_ptr T -> result (const_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_unchecked_mut : Self -> mut_raw_ptr T -> result (mut_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_index : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut_back : Self -> T -> core_slice_index_SliceIndex_Output -> result T;
+}.
+Arguments mk_core_slice_index_SliceIndex {_ _}.
+Arguments core_slice_index_SliceIndex_sealedInst {_ _}.
+Arguments core_slice_index_SliceIndex_Output {_ _}.
+Arguments core_slice_index_SliceIndex_get {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut_back {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut_back {_ _}.
+
+(* [core::slice::index::[T]::index]: forward function *)
+Definition core_slice_index_Slice_index
+ (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (s : slice T) (i : Idx) : result inst.(core_slice_index_SliceIndex_Output) :=
+ x <- inst.(core_slice_index_SliceIndex_get) i s;
+ match x with
+ | None => Fail_ Failure
+ | Some x => Return x
end.
-Definition vec_index_mut_back (T: Type) (v: vec T) (i: usize) (x: T) : result (vec T) :=
- vec_bind v (fun l =>
- if to_Z i <? Z.of_nat (length l)
- then Return (list_update l (usize_to_nat i) x)
- else Fail_ Failure).
+(* [core::slice::index::Range:::get]: forward function *)
+Axiom core_slice_index_Range_get : forall (T : Type) (i : core_ops_range_Range usize) (s : slice T), result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: forward function *)
+Axiom core_slice_index_Range_get_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: backward function 0 *)
+Axiom core_slice_index_Range_get_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> option (slice T) -> result (slice T).
+
+(* [core::slice::index::Range::get_unchecked]: forward function *)
+Definition core_slice_index_Range_get_unchecked
+ (T : Type) :
+ core_ops_range_Range usize -> const_raw_ptr (slice T) -> result (const_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::get_unchecked_mut]: forward function *)
+Definition core_slice_index_Range_get_unchecked_mut
+ (T : Type) :
+ core_ops_range_Range usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::index]: forward function *)
+Axiom core_slice_index_Range_index :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: forward function *)
+Axiom core_slice_index_Range_index_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: backward function 0 *)
+Axiom core_slice_index_Range_index_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> slice T -> result (slice T).
+
+(* [core::slice::index::[T]::index_mut]: forward function *)
+Axiom core_slice_index_Slice_index_mut :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> result inst.(core_slice_index_SliceIndex_Output).
+
+(* [core::slice::index::[T]::index_mut]: backward function 0 *)
+Axiom core_slice_index_Slice_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> inst.(core_slice_index_SliceIndex_Output) -> result (slice T).
+
+(* [core::array::[T; N]::index]: forward function *)
+Axiom core_array_Array_index :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_Index (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: forward function *)
+Axiom core_array_Array_index_mut :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: backward function 0 *)
+Axiom core_array_Array_index_mut_back :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx) (x : inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output)), result (array T N).
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (slice T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := core_slice_index_Slice_index T Idx inst;
+|}.
+
+(* Trait implementation: [core::slice::index::private_slice_index::Range] *)
+Definition core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) := tt.
+
+(* Trait implementation: [core::slice::index::Range] *)
+Definition core_slice_index_Range_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := slice T;
+ core_slice_index_SliceIndex_get := core_slice_index_Range_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_Range_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_Range_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_Range_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_Range_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_Range_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_Range_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_Range_index_mut_back T;
+|}.
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (slice T) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_slice_index_Slice_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := core_slice_index_Slice_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := core_slice_index_Slice_index_mut_back T Idx inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_Index (slice T) Idx) :
+ core_ops_index_Index (array T N) Idx := {|
+ core_ops_index_Index_Output := inst.(core_ops_index_Index_Output);
+ core_ops_index_Index_index := core_array_Array_index T Idx N inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexMutInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_IndexMut (slice T) Idx) :
+ core_ops_index_IndexMut (array T N) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_array_Array_coreopsindexIndexInst T Idx N inst.(core_ops_index_IndexMut_indexInst);
+ core_ops_index_IndexMut_index_mut := core_array_Array_index_mut T Idx N inst;
+ core_ops_index_IndexMut_index_mut_back := core_array_Array_index_mut_back T Idx N inst;
+|}.
+
+(* [core::slice::index::usize::get]: forward function *)
+Axiom core_slice_index_usize_get : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: forward function *)
+Axiom core_slice_index_usize_get_mut : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: backward function 0 *)
+Axiom core_slice_index_usize_get_mut_back :
+ forall (T : Type), usize -> slice T -> option T -> result (slice T).
+
+(* [core::slice::index::usize::get_unchecked]: forward function *)
+Axiom core_slice_index_usize_get_unchecked :
+ forall (T : Type), usize -> const_raw_ptr (slice T) -> result (const_raw_ptr T).
+
+(* [core::slice::index::usize::get_unchecked_mut]: forward function *)
+Axiom core_slice_index_usize_get_unchecked_mut :
+ forall (T : Type), usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr T).
+
+(* [core::slice::index::usize::index]: forward function *)
+Axiom core_slice_index_usize_index : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: forward function *)
+Axiom core_slice_index_usize_index_mut : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: backward function 0 *)
+Axiom core_slice_index_usize_index_mut_back :
+ forall (T : Type), usize -> slice T -> T -> result (slice T).
+
+(* Trait implementation: [core::slice::index::private_slice_index::usize] *)
+Definition core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize := tt.
+
+(* Trait implementation: [core::slice::index::usize] *)
+Definition core_slice_index_usize_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex usize (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := T;
+ core_slice_index_SliceIndex_get := core_slice_index_usize_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_usize_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_usize_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_usize_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_usize_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_usize_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_usize_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_usize_index_mut_back T;
+|}.
+
+(* [alloc::vec::Vec::index]: forward function *)
+Axiom alloc_vec_Vec_index : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: forward function *)
+Axiom alloc_vec_Vec_index_mut : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: backward function 0 *)
+Axiom alloc_vec_Vec_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx) (x : inst.(core_slice_index_SliceIndex_Output)), result (alloc_vec_Vec T).
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (alloc_vec_Vec T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := alloc_vec_Vec_index T Idx inst;
+|}.
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (alloc_vec_Vec T) Idx := {|
+ core_ops_index_IndexMut_indexInst := alloc_vec_Vec_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := alloc_vec_Vec_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := alloc_vec_Vec_index_mut_back T Idx inst;
+|}.
+
+(*** Theorems *)
+
+Axiom alloc_vec_Vec_index_mut_back_eq : forall {a : Type} (v : alloc_vec_Vec a) (i : usize) (x : a),
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x =
+ alloc_vec_Vec_update_usize v i x.
End Primitives.
diff --git a/tests/coq/traits/Makefile b/tests/coq/traits/Makefile
new file mode 100644
index 00000000..1a5aee4a
--- /dev/null
+++ b/tests/coq/traits/Makefile
@@ -0,0 +1,23 @@
+# This file was automatically generated - modify ../Makefile.template instead
+# Makefile originally taken from coq-club
+
+%: Makefile.coq phony
+ +make -f Makefile.coq $@
+
+all: Makefile.coq
+ +make -f Makefile.coq all
+
+clean: Makefile.coq
+ +make -f Makefile.coq clean
+ rm -f Makefile.coq
+
+Makefile.coq: _CoqProject Makefile
+ coq_makefile -f _CoqProject | sed 's/$$(COQCHK) $$(COQCHKFLAGS) $$(COQLIBS)/$$(COQCHK) $$(COQCHKFLAGS) $$(subst -Q,-R,$$(COQLIBS))/' > Makefile.coq
+
+_CoqProject: ;
+
+Makefile: ;
+
+phony: ;
+
+.PHONY: all clean phony
diff --git a/tests/coq/traits/Primitives.v b/tests/coq/traits/Primitives.v
new file mode 100644
index 00000000..85e38f01
--- /dev/null
+++ b/tests/coq/traits/Primitives.v
@@ -0,0 +1,822 @@
+Require Import Lia.
+Require Coq.Strings.Ascii.
+Require Coq.Strings.String.
+Require Import Coq.Program.Equality.
+Require Import Coq.ZArith.ZArith.
+Require Import Coq.ZArith.Znat.
+Require Import List.
+Import ListNotations.
+
+Module Primitives.
+
+ (* TODO: use more *)
+Declare Scope Primitives_scope.
+
+(*** Result *)
+
+Inductive error :=
+ | Failure
+ | OutOfFuel.
+
+Inductive result A :=
+ | Return : A -> result A
+ | Fail_ : error -> result A.
+
+Arguments Return {_} a.
+Arguments Fail_ {_}.
+
+Definition bind {A B} (m: result A) (f: A -> result B) : result B :=
+ match m with
+ | Fail_ e => Fail_ e
+ | Return x => f x
+ end.
+
+Definition return_ {A: Type} (x: A) : result A := Return x.
+Definition fail_ {A: Type} (e: error) : result A := Fail_ e.
+
+Notation "x <- c1 ; c2" := (bind c1 (fun x => c2))
+ (at level 61, c1 at next level, right associativity).
+
+(** Monadic assert *)
+Definition massert (b: bool) : result unit :=
+ if b then Return tt else Fail_ Failure.
+
+(** Normalize and unwrap a successful result (used for globals) *)
+Definition eval_result_refl {A} {x} (a: result A) (p: a = Return x) : A :=
+ match a as r return (r = Return x -> A) with
+ | Return a' => fun _ => a'
+ | Fail_ e => fun p' =>
+ False_rect _ (eq_ind (Fail_ e)
+ (fun e : result A =>
+ match e with
+ | Return _ => False
+ | Fail_ e => True
+ end)
+ I (Return x) p')
+ end p.
+
+Notation "x %global" := (eval_result_refl x eq_refl) (at level 40).
+Notation "x %return" := (eval_result_refl x eq_refl) (at level 40).
+
+(* Sanity check *)
+Check (if true then Return (1 + 2) else Fail_ Failure)%global = 3.
+
+(*** Misc *)
+
+Definition string := Coq.Strings.String.string.
+Definition char := Coq.Strings.Ascii.ascii.
+Definition char_of_byte := Coq.Strings.Ascii.ascii_of_byte.
+
+Definition core_mem_replace (a : Type) (x : a) (y : a) : a := x .
+Definition core_mem_replace_back (a : Type) (x : a) (y : a) : a := y .
+
+Record mut_raw_ptr (T : Type) := { mut_raw_ptr_v : T }.
+Record const_raw_ptr (T : Type) := { const_raw_ptr_v : T }.
+
+(*** Scalars *)
+
+Definition i8_min : Z := -128%Z.
+Definition i8_max : Z := 127%Z.
+Definition i16_min : Z := -32768%Z.
+Definition i16_max : Z := 32767%Z.
+Definition i32_min : Z := -2147483648%Z.
+Definition i32_max : Z := 2147483647%Z.
+Definition i64_min : Z := -9223372036854775808%Z.
+Definition i64_max : Z := 9223372036854775807%Z.
+Definition i128_min : Z := -170141183460469231731687303715884105728%Z.
+Definition i128_max : Z := 170141183460469231731687303715884105727%Z.
+Definition u8_min : Z := 0%Z.
+Definition u8_max : Z := 255%Z.
+Definition u16_min : Z := 0%Z.
+Definition u16_max : Z := 65535%Z.
+Definition u32_min : Z := 0%Z.
+Definition u32_max : Z := 4294967295%Z.
+Definition u64_min : Z := 0%Z.
+Definition u64_max : Z := 18446744073709551615%Z.
+Definition u128_min : Z := 0%Z.
+Definition u128_max : Z := 340282366920938463463374607431768211455%Z.
+
+(** The bounds of [isize] and [usize] vary with the architecture. *)
+Axiom isize_min : Z.
+Axiom isize_max : Z.
+Definition usize_min : Z := 0%Z.
+Axiom usize_max : Z.
+
+Open Scope Z_scope.
+
+(** We provide those lemmas to reason about the bounds of [isize] and [usize] *)
+Axiom isize_min_bound : isize_min <= i32_min.
+Axiom isize_max_bound : i32_max <= isize_max.
+Axiom usize_max_bound : u32_max <= usize_max.
+
+Inductive scalar_ty :=
+ | Isize
+ | I8
+ | I16
+ | I32
+ | I64
+ | I128
+ | Usize
+ | U8
+ | U16
+ | U32
+ | U64
+ | U128
+.
+
+Definition scalar_min (ty: scalar_ty) : Z :=
+ match ty with
+ | Isize => isize_min
+ | I8 => i8_min
+ | I16 => i16_min
+ | I32 => i32_min
+ | I64 => i64_min
+ | I128 => i128_min
+ | Usize => usize_min
+ | U8 => u8_min
+ | U16 => u16_min
+ | U32 => u32_min
+ | U64 => u64_min
+ | U128 => u128_min
+end.
+
+Definition scalar_max (ty: scalar_ty) : Z :=
+ match ty with
+ | Isize => isize_max
+ | I8 => i8_max
+ | I16 => i16_max
+ | I32 => i32_max
+ | I64 => i64_max
+ | I128 => i128_max
+ | Usize => usize_max
+ | U8 => u8_max
+ | U16 => u16_max
+ | U32 => u32_max
+ | U64 => u64_max
+ | U128 => u128_max
+end.
+
+(** We use the following conservative bounds to make sure we can compute bound
+ checks in most situations *)
+Definition scalar_min_cons (ty: scalar_ty) : Z :=
+ match ty with
+ | Isize => i32_min
+ | Usize => u32_min
+ | _ => scalar_min ty
+end.
+
+Definition scalar_max_cons (ty: scalar_ty) : Z :=
+ match ty with
+ | Isize => i32_max
+ | Usize => u32_max
+ | _ => scalar_max ty
+end.
+
+Lemma scalar_min_cons_valid : forall ty, scalar_min ty <= scalar_min_cons ty .
+Proof.
+ destruct ty; unfold scalar_min_cons, scalar_min; try lia.
+ - pose isize_min_bound; lia.
+ - apply Z.le_refl.
+Qed.
+
+Lemma scalar_max_cons_valid : forall ty, scalar_max ty >= scalar_max_cons ty .
+Proof.
+ destruct ty; unfold scalar_max_cons, scalar_max; try lia.
+ - pose isize_max_bound; lia.
+ - pose usize_max_bound. lia.
+Qed.
+
+Definition scalar (ty: scalar_ty) : Type :=
+ { x: Z | scalar_min ty <= x <= scalar_max ty }.
+
+Definition to_Z {ty} (x: scalar ty) : Z := proj1_sig x.
+
+(** Bounds checks: we start by using the conservative bounds, to make sure we
+ can compute in most situations, then we use the real bounds (for [isize]
+ and [usize]). *)
+Definition scalar_ge_min (ty: scalar_ty) (x: Z) : bool :=
+ Z.leb (scalar_min_cons ty) x || Z.leb (scalar_min ty) x.
+
+Definition scalar_le_max (ty: scalar_ty) (x: Z) : bool :=
+ Z.leb x (scalar_max_cons ty) || Z.leb x (scalar_max ty).
+
+Lemma scalar_ge_min_valid (ty: scalar_ty) (x: Z) :
+ scalar_ge_min ty x = true -> scalar_min ty <= x .
+Proof.
+ unfold scalar_ge_min.
+ pose (scalar_min_cons_valid ty).
+ lia.
+Qed.
+
+Lemma scalar_le_max_valid (ty: scalar_ty) (x: Z) :
+ scalar_le_max ty x = true -> x <= scalar_max ty .
+Proof.
+ unfold scalar_le_max.
+ pose (scalar_max_cons_valid ty).
+ lia.
+Qed.
+
+Definition scalar_in_bounds (ty: scalar_ty) (x: Z) : bool :=
+ scalar_ge_min ty x && scalar_le_max ty x .
+
+Lemma scalar_in_bounds_valid (ty: scalar_ty) (x: Z) :
+ scalar_in_bounds ty x = true -> scalar_min ty <= x <= scalar_max ty .
+Proof.
+ unfold scalar_in_bounds.
+ intros H.
+ destruct (scalar_ge_min ty x) eqn:Hmin.
+ - destruct (scalar_le_max ty x) eqn:Hmax.
+ + pose (scalar_ge_min_valid ty x Hmin).
+ pose (scalar_le_max_valid ty x Hmax).
+ lia.
+ + inversion H.
+ - inversion H.
+Qed.
+
+Import Sumbool.
+
+Definition mk_scalar (ty: scalar_ty) (x: Z) : result (scalar ty) :=
+ match sumbool_of_bool (scalar_in_bounds ty x) with
+ | left H => Return (exist _ x (scalar_in_bounds_valid _ _ H))
+ | right _ => Fail_ Failure
+ end.
+
+Definition scalar_add {ty} (x y: scalar ty) : result (scalar ty) := mk_scalar ty (to_Z x + to_Z y).
+
+Definition scalar_sub {ty} (x y: scalar ty) : result (scalar ty) := mk_scalar ty (to_Z x - to_Z y).
+
+Definition scalar_mul {ty} (x y: scalar ty) : result (scalar ty) := mk_scalar ty (to_Z x * to_Z y).
+
+Definition scalar_div {ty} (x y: scalar ty) : result (scalar ty) :=
+ if to_Z y =? 0 then Fail_ Failure else
+ mk_scalar ty (to_Z x / to_Z y).
+
+Definition scalar_rem {ty} (x y: scalar ty) : result (scalar ty) := mk_scalar ty (Z.rem (to_Z x) (to_Z y)).
+
+Definition scalar_neg {ty} (x: scalar ty) : result (scalar ty) := mk_scalar ty (-(to_Z x)).
+
+(** Cast an integer from a [src_ty] to a [tgt_ty] *)
+(* TODO: check the semantics of casts in Rust *)
+Definition scalar_cast (src_ty tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) :=
+ mk_scalar tgt_ty (to_Z x).
+
+(** Comparisons *)
+Definition scalar_leb {ty : scalar_ty} (x : scalar ty) (y : scalar ty) : bool :=
+ Z.leb (to_Z x) (to_Z y) .
+
+Definition scalar_ltb {ty : scalar_ty} (x : scalar ty) (y : scalar ty) : bool :=
+ Z.ltb (to_Z x) (to_Z y) .
+
+Definition scalar_geb {ty : scalar_ty} (x : scalar ty) (y : scalar ty) : bool :=
+ Z.geb (to_Z x) (to_Z y) .
+
+Definition scalar_gtb {ty : scalar_ty} (x : scalar ty) (y : scalar ty) : bool :=
+ Z.gtb (to_Z x) (to_Z y) .
+
+Definition scalar_eqb {ty : scalar_ty} (x : scalar ty) (y : scalar ty) : bool :=
+ Z.eqb (to_Z x) (to_Z y) .
+
+Definition scalar_neqb {ty : scalar_ty} (x : scalar ty) (y : scalar ty) : bool :=
+ negb (Z.eqb (to_Z x) (to_Z y)) .
+
+
+(** The scalar types *)
+Definition isize := scalar Isize.
+Definition i8 := scalar I8.
+Definition i16 := scalar I16.
+Definition i32 := scalar I32.
+Definition i64 := scalar I64.
+Definition i128 := scalar I128.
+Definition usize := scalar Usize.
+Definition u8 := scalar U8.
+Definition u16 := scalar U16.
+Definition u32 := scalar U32.
+Definition u64 := scalar U64.
+Definition u128 := scalar U128.
+
+(** Negaion *)
+Definition isize_neg := @scalar_neg Isize.
+Definition i8_neg := @scalar_neg I8.
+Definition i16_neg := @scalar_neg I16.
+Definition i32_neg := @scalar_neg I32.
+Definition i64_neg := @scalar_neg I64.
+Definition i128_neg := @scalar_neg I128.
+
+(** Division *)
+Definition isize_div := @scalar_div Isize.
+Definition i8_div := @scalar_div I8.
+Definition i16_div := @scalar_div I16.
+Definition i32_div := @scalar_div I32.
+Definition i64_div := @scalar_div I64.
+Definition i128_div := @scalar_div I128.
+Definition usize_div := @scalar_div Usize.
+Definition u8_div := @scalar_div U8.
+Definition u16_div := @scalar_div U16.
+Definition u32_div := @scalar_div U32.
+Definition u64_div := @scalar_div U64.
+Definition u128_div := @scalar_div U128.
+
+(** Remainder *)
+Definition isize_rem := @scalar_rem Isize.
+Definition i8_rem := @scalar_rem I8.
+Definition i16_rem := @scalar_rem I16.
+Definition i32_rem := @scalar_rem I32.
+Definition i64_rem := @scalar_rem I64.
+Definition i128_rem := @scalar_rem I128.
+Definition usize_rem := @scalar_rem Usize.
+Definition u8_rem := @scalar_rem U8.
+Definition u16_rem := @scalar_rem U16.
+Definition u32_rem := @scalar_rem U32.
+Definition u64_rem := @scalar_rem U64.
+Definition u128_rem := @scalar_rem U128.
+
+(** Addition *)
+Definition isize_add := @scalar_add Isize.
+Definition i8_add := @scalar_add I8.
+Definition i16_add := @scalar_add I16.
+Definition i32_add := @scalar_add I32.
+Definition i64_add := @scalar_add I64.
+Definition i128_add := @scalar_add I128.
+Definition usize_add := @scalar_add Usize.
+Definition u8_add := @scalar_add U8.
+Definition u16_add := @scalar_add U16.
+Definition u32_add := @scalar_add U32.
+Definition u64_add := @scalar_add U64.
+Definition u128_add := @scalar_add U128.
+
+(** Substraction *)
+Definition isize_sub := @scalar_sub Isize.
+Definition i8_sub := @scalar_sub I8.
+Definition i16_sub := @scalar_sub I16.
+Definition i32_sub := @scalar_sub I32.
+Definition i64_sub := @scalar_sub I64.
+Definition i128_sub := @scalar_sub I128.
+Definition usize_sub := @scalar_sub Usize.
+Definition u8_sub := @scalar_sub U8.
+Definition u16_sub := @scalar_sub U16.
+Definition u32_sub := @scalar_sub U32.
+Definition u64_sub := @scalar_sub U64.
+Definition u128_sub := @scalar_sub U128.
+
+(** Multiplication *)
+Definition isize_mul := @scalar_mul Isize.
+Definition i8_mul := @scalar_mul I8.
+Definition i16_mul := @scalar_mul I16.
+Definition i32_mul := @scalar_mul I32.
+Definition i64_mul := @scalar_mul I64.
+Definition i128_mul := @scalar_mul I128.
+Definition usize_mul := @scalar_mul Usize.
+Definition u8_mul := @scalar_mul U8.
+Definition u16_mul := @scalar_mul U16.
+Definition u32_mul := @scalar_mul U32.
+Definition u64_mul := @scalar_mul U64.
+Definition u128_mul := @scalar_mul U128.
+
+(** Small utility *)
+Definition usize_to_nat (x: usize) : nat := Z.to_nat (to_Z x).
+
+(** Notations *)
+Notation "x %isize" := ((mk_scalar Isize x)%return) (at level 9).
+Notation "x %i8" := ((mk_scalar I8 x)%return) (at level 9).
+Notation "x %i16" := ((mk_scalar I16 x)%return) (at level 9).
+Notation "x %i32" := ((mk_scalar I32 x)%return) (at level 9).
+Notation "x %i64" := ((mk_scalar I64 x)%return) (at level 9).
+Notation "x %i128" := ((mk_scalar I128 x)%return) (at level 9).
+Notation "x %usize" := ((mk_scalar Usize x)%return) (at level 9).
+Notation "x %u8" := ((mk_scalar U8 x)%return) (at level 9).
+Notation "x %u16" := ((mk_scalar U16 x)%return) (at level 9).
+Notation "x %u32" := ((mk_scalar U32 x)%return) (at level 9).
+Notation "x %u64" := ((mk_scalar U64 x)%return) (at level 9).
+Notation "x %u128" := ((mk_scalar U128 x)%return) (at level 9).
+
+Notation "x s= y" := (scalar_eqb x y) (at level 80) : Primitives_scope.
+Notation "x s<> y" := (scalar_neqb x y) (at level 80) : Primitives_scope.
+Notation "x s<= y" := (scalar_leb x y) (at level 80) : Primitives_scope.
+Notation "x s< y" := (scalar_ltb x y) (at level 80) : Primitives_scope.
+Notation "x s>= y" := (scalar_geb x y) (at level 80) : Primitives_scope.
+Notation "x s> y" := (scalar_gtb x y) (at level 80) : Primitives_scope.
+
+(** Constants *)
+Definition core_u8_max := u8_max %u32.
+Definition core_u16_max := u16_max %u32.
+Definition core_u32_max := u32_max %u32.
+Definition core_u64_max := u64_max %u64.
+Definition core_u128_max := u64_max %u128.
+Axiom core_usize_max : usize. (** TODO *)
+Definition core_i8_max := i8_max %i32.
+Definition core_i16_max := i16_max %i32.
+Definition core_i32_max := i32_max %i32.
+Definition core_i64_max := i64_max %i64.
+Definition core_i128_max := i64_max %i128.
+Axiom core_isize_max : isize. (** TODO *)
+
+(*** core::ops *)
+
+(* Trait declaration: [core::ops::index::Index] *)
+Record core_ops_index_Index (Self Idx : Type) := mk_core_ops_index_Index {
+ core_ops_index_Index_Output : Type;
+ core_ops_index_Index_index : Self -> Idx -> result core_ops_index_Index_Output;
+}.
+Arguments mk_core_ops_index_Index {_ _}.
+Arguments core_ops_index_Index_Output {_ _}.
+Arguments core_ops_index_Index_index {_ _}.
+
+(* Trait declaration: [core::ops::index::IndexMut] *)
+Record core_ops_index_IndexMut (Self Idx : Type) := mk_core_ops_index_IndexMut {
+ core_ops_index_IndexMut_indexInst : core_ops_index_Index Self Idx;
+ core_ops_index_IndexMut_index_mut : Self -> Idx -> result core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output);
+ core_ops_index_IndexMut_index_mut_back : Self -> Idx -> core_ops_index_IndexMut_indexInst.(core_ops_index_Index_Output) -> result Self;
+}.
+Arguments mk_core_ops_index_IndexMut {_ _}.
+Arguments core_ops_index_IndexMut_indexInst {_ _}.
+Arguments core_ops_index_IndexMut_index_mut {_ _}.
+Arguments core_ops_index_IndexMut_index_mut_back {_ _}.
+
+(* Trait declaration [core::ops::deref::Deref] *)
+Record core_ops_deref_Deref (Self : Type) := mk_core_ops_deref_Deref {
+ core_ops_deref_Deref_target : Type;
+ core_ops_deref_Deref_deref : Self -> result core_ops_deref_Deref_target;
+}.
+Arguments mk_core_ops_deref_Deref {_}.
+Arguments core_ops_deref_Deref_target {_}.
+Arguments core_ops_deref_Deref_deref {_}.
+
+(* Trait declaration [core::ops::deref::DerefMut] *)
+Record core_ops_deref_DerefMut (Self : Type) := mk_core_ops_deref_DerefMut {
+ core_ops_deref_DerefMut_derefInst : core_ops_deref_Deref Self;
+ core_ops_deref_DerefMut_deref_mut : Self -> result core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target);
+ core_ops_deref_DerefMut_deref_mut_back : Self -> core_ops_deref_DerefMut_derefInst.(core_ops_deref_Deref_target) -> result Self;
+}.
+Arguments mk_core_ops_deref_DerefMut {_}.
+Arguments core_ops_deref_DerefMut_derefInst {_}.
+Arguments core_ops_deref_DerefMut_deref_mut {_}.
+Arguments core_ops_deref_DerefMut_deref_mut_back {_}.
+
+Record core_ops_range_Range (T : Type) := mk_core_ops_range_Range {
+ core_ops_range_Range_start : T;
+ core_ops_range_Range_end_ : T;
+}.
+Arguments mk_core_ops_range_Range {_}.
+Arguments core_ops_range_Range_start {_}.
+Arguments core_ops_range_Range_end_ {_}.
+
+(*** [alloc] *)
+
+Definition alloc_boxed_Box_deref (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut (T : Type) (x : T) : result T := Return x.
+Definition alloc_boxed_Box_deref_mut_back (T : Type) (_ : T) (x : T) : result T := Return x.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefInst (Self : Type) : core_ops_deref_Deref Self := {|
+ core_ops_deref_Deref_target := Self;
+ core_ops_deref_Deref_deref := alloc_boxed_Box_deref Self;
+|}.
+
+(* Trait instance *)
+Definition alloc_boxed_Box_coreOpsDerefMutInst (Self : Type) : core_ops_deref_DerefMut Self := {|
+ core_ops_deref_DerefMut_derefInst := alloc_boxed_Box_coreOpsDerefInst Self;
+ core_ops_deref_DerefMut_deref_mut := alloc_boxed_Box_deref_mut Self;
+ core_ops_deref_DerefMut_deref_mut_back := alloc_boxed_Box_deref_mut_back Self;
+|}.
+
+
+(*** Arrays *)
+Definition array T (n : usize) := { l: list T | Z.of_nat (length l) = to_Z n}.
+
+Lemma le_0_usize_max : 0 <= usize_max.
+Proof.
+ pose (H := usize_max_bound).
+ unfold u32_max in H.
+ lia.
+Qed.
+
+Lemma eqb_imp_eq (x y : Z) : Z.eqb x y = true -> x = y.
+Proof.
+ lia.
+Qed.
+
+(* TODO: finish the definitions *)
+Axiom mk_array : forall (T : Type) (n : usize) (l : list T), array T n.
+
+(* For initialization *)
+Axiom array_repeat : forall (T : Type) (n : usize) (x : T), array T n.
+
+Axiom array_index_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize), result T.
+Axiom array_update_usize : forall (T : Type) (n : usize) (x : array T n) (i : usize) (nx : T), result (array T n).
+
+(*** Slice *)
+Definition slice T := { l: list T | Z.of_nat (length l) <= usize_max}.
+
+Axiom slice_len : forall (T : Type) (s : slice T), usize.
+Axiom slice_index_usize : forall (T : Type) (x : slice T) (i : usize), result T.
+Axiom slice_update_usize : forall (T : Type) (x : slice T) (i : usize) (nx : T), result (slice T).
+
+(*** Subslices *)
+
+Axiom array_to_slice : forall (T : Type) (n : usize) (x : array T n), result (slice T).
+Axiom array_from_slice : forall (T : Type) (n : usize) (x : array T n) (s : slice T), result (array T n).
+
+Axiom array_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize), result (slice T).
+Axiom array_update_subslice: forall (T : Type) (n : usize) (x : array T n) (r : core_ops_range_Range usize) (ns : slice T), result (array T n).
+
+Axiom slice_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize), result (slice T).
+Axiom slice_update_subslice: forall (T : Type) (x : slice T) (r : core_ops_range_Range usize) (ns : slice T), result (slice T).
+
+(*** Vectors *)
+
+Definition alloc_vec_Vec T := { l: list T | Z.of_nat (length l) <= usize_max }.
+
+Definition alloc_vec_Vec_to_list {T: Type} (v: alloc_vec_Vec T) : list T := proj1_sig v.
+
+Definition alloc_vec_Vec_length {T: Type} (v: alloc_vec_Vec T) : Z := Z.of_nat (length (alloc_vec_Vec_to_list v)).
+
+Definition alloc_vec_Vec_new (T: Type) : alloc_vec_Vec T := (exist _ [] le_0_usize_max).
+
+Lemma alloc_vec_Vec_len_in_usize {T} (v: alloc_vec_Vec T) : usize_min <= alloc_vec_Vec_length v <= usize_max.
+Proof.
+ unfold alloc_vec_Vec_length, usize_min.
+ split.
+ - lia.
+ - apply (proj2_sig v).
+Qed.
+
+Definition alloc_vec_Vec_len (T: Type) (v: alloc_vec_Vec T) : usize :=
+ exist _ (alloc_vec_Vec_length v) (alloc_vec_Vec_len_in_usize v).
+
+Fixpoint list_update {A} (l: list A) (n: nat) (a: A)
+ : list A :=
+ match l with
+ | [] => []
+ | x :: t => match n with
+ | 0%nat => a :: t
+ | S m => x :: (list_update t m a)
+end end.
+
+Definition alloc_vec_Vec_bind {A B} (v: alloc_vec_Vec A) (f: list A -> result (list B)) : result (alloc_vec_Vec B) :=
+ l <- f (alloc_vec_Vec_to_list v) ;
+ match sumbool_of_bool (scalar_le_max Usize (Z.of_nat (length l))) with
+ | left H => Return (exist _ l (scalar_le_max_valid _ _ H))
+ | right _ => Fail_ Failure
+ end.
+
+(* The **forward** function shouldn't be used *)
+Definition alloc_vec_Vec_push_fwd (T: Type) (v: alloc_vec_Vec T) (x: T) : unit := tt.
+
+Definition alloc_vec_Vec_push (T: Type) (v: alloc_vec_Vec T) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l => Return (l ++ [x])).
+
+(* The **forward** function shouldn't be used *)
+Definition alloc_vec_Vec_insert_fwd (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result unit :=
+ if to_Z i <? alloc_vec_Vec_length v then Return tt else Fail_ Failure.
+
+Definition alloc_vec_Vec_insert (T: Type) (v: alloc_vec_Vec T) (i: usize) (x: T) : result (alloc_vec_Vec T) :=
+ alloc_vec_Vec_bind v (fun l =>
+ if to_Z i <? Z.of_nat (length l)
+ then Return (list_update l (usize_to_nat i) x)
+ else Fail_ Failure).
+
+(* Helper *)
+Axiom alloc_vec_Vec_index_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result T.
+
+(* Helper *)
+Axiom alloc_vec_Vec_update_usize : forall {T : Type} (v : alloc_vec_Vec T) (i : usize) (x : T), result (alloc_vec_Vec T).
+
+(* Trait declaration: [core::slice::index::private_slice_index::Sealed] *)
+Definition core_slice_index_private_slice_index_Sealed (self : Type) := unit.
+
+(* Trait declaration: [core::slice::index::SliceIndex] *)
+Record core_slice_index_SliceIndex (Self T : Type) := mk_core_slice_index_SliceIndex {
+ core_slice_index_SliceIndex_sealedInst : core_slice_index_private_slice_index_Sealed Self;
+ core_slice_index_SliceIndex_Output : Type;
+ core_slice_index_SliceIndex_get : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut : Self -> T -> result (option core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_mut_back : Self -> T -> option core_slice_index_SliceIndex_Output -> result T;
+ core_slice_index_SliceIndex_get_unchecked : Self -> const_raw_ptr T -> result (const_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_get_unchecked_mut : Self -> mut_raw_ptr T -> result (mut_raw_ptr core_slice_index_SliceIndex_Output);
+ core_slice_index_SliceIndex_index : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut : Self -> T -> result core_slice_index_SliceIndex_Output;
+ core_slice_index_SliceIndex_index_mut_back : Self -> T -> core_slice_index_SliceIndex_Output -> result T;
+}.
+Arguments mk_core_slice_index_SliceIndex {_ _}.
+Arguments core_slice_index_SliceIndex_sealedInst {_ _}.
+Arguments core_slice_index_SliceIndex_Output {_ _}.
+Arguments core_slice_index_SliceIndex_get {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut {_ _}.
+Arguments core_slice_index_SliceIndex_get_mut_back {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked {_ _}.
+Arguments core_slice_index_SliceIndex_get_unchecked_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut {_ _}.
+Arguments core_slice_index_SliceIndex_index_mut_back {_ _}.
+
+(* [core::slice::index::[T]::index]: forward function *)
+Definition core_slice_index_Slice_index
+ (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (s : slice T) (i : Idx) : result inst.(core_slice_index_SliceIndex_Output) :=
+ x <- inst.(core_slice_index_SliceIndex_get) i s;
+ match x with
+ | None => Fail_ Failure
+ | Some x => Return x
+ end.
+
+(* [core::slice::index::Range:::get]: forward function *)
+Axiom core_slice_index_Range_get : forall (T : Type) (i : core_ops_range_Range usize) (s : slice T), result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: forward function *)
+Axiom core_slice_index_Range_get_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (option (slice T)).
+
+(* [core::slice::index::Range::get_mut]: backward function 0 *)
+Axiom core_slice_index_Range_get_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> option (slice T) -> result (slice T).
+
+(* [core::slice::index::Range::get_unchecked]: forward function *)
+Definition core_slice_index_Range_get_unchecked
+ (T : Type) :
+ core_ops_range_Range usize -> const_raw_ptr (slice T) -> result (const_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::get_unchecked_mut]: forward function *)
+Definition core_slice_index_Range_get_unchecked_mut
+ (T : Type) :
+ core_ops_range_Range usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr (slice T)) :=
+ (* Don't know what the model should be - for now we always fail to make
+ sure code which uses it fails *)
+ fun _ _ => Fail_ Failure.
+
+(* [core::slice::index::Range::index]: forward function *)
+Axiom core_slice_index_Range_index :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: forward function *)
+Axiom core_slice_index_Range_index_mut :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> result (slice T).
+
+(* [core::slice::index::Range::index_mut]: backward function 0 *)
+Axiom core_slice_index_Range_index_mut_back :
+ forall (T : Type), core_ops_range_Range usize -> slice T -> slice T -> result (slice T).
+
+(* [core::slice::index::[T]::index_mut]: forward function *)
+Axiom core_slice_index_Slice_index_mut :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> result inst.(core_slice_index_SliceIndex_Output).
+
+(* [core::slice::index::[T]::index_mut]: backward function 0 *)
+Axiom core_slice_index_Slice_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T)),
+ slice T -> Idx -> inst.(core_slice_index_SliceIndex_Output) -> result (slice T).
+
+(* [core::array::[T; N]::index]: forward function *)
+Axiom core_array_Array_index :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_Index (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: forward function *)
+Axiom core_array_Array_index_mut :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx), result inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output).
+
+(* [core::array::[T; N]::index_mut]: backward function 0 *)
+Axiom core_array_Array_index_mut_back :
+ forall (T Idx : Type) (N : usize) (inst : core_ops_index_IndexMut (slice T) Idx)
+ (a : array T N) (i : Idx) (x : inst.(core_ops_index_IndexMut_indexInst).(core_ops_index_Index_Output)), result (array T N).
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (slice T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := core_slice_index_Slice_index T Idx inst;
+|}.
+
+(* Trait implementation: [core::slice::index::private_slice_index::Range] *)
+Definition core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) := tt.
+
+(* Trait implementation: [core::slice::index::Range] *)
+Definition core_slice_index_Range_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := slice T;
+ core_slice_index_SliceIndex_get := core_slice_index_Range_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_Range_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_Range_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_Range_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_Range_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_Range_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_Range_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_Range_index_mut_back T;
+|}.
+
+(* Trait implementation: [core::slice::index::[T]] *)
+Definition core_slice_index_Slice_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (slice T) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_slice_index_Slice_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := core_slice_index_Slice_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := core_slice_index_Slice_index_mut_back T Idx inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_Index (slice T) Idx) :
+ core_ops_index_Index (array T N) Idx := {|
+ core_ops_index_Index_Output := inst.(core_ops_index_Index_Output);
+ core_ops_index_Index_index := core_array_Array_index T Idx N inst;
+|}.
+
+(* Trait implementation: [core::array::[T; N]] *)
+Definition core_array_Array_coreopsindexIndexMutInst (T Idx : Type) (N : usize)
+ (inst : core_ops_index_IndexMut (slice T) Idx) :
+ core_ops_index_IndexMut (array T N) Idx := {|
+ core_ops_index_IndexMut_indexInst := core_array_Array_coreopsindexIndexInst T Idx N inst.(core_ops_index_IndexMut_indexInst);
+ core_ops_index_IndexMut_index_mut := core_array_Array_index_mut T Idx N inst;
+ core_ops_index_IndexMut_index_mut_back := core_array_Array_index_mut_back T Idx N inst;
+|}.
+
+(* [core::slice::index::usize::get]: forward function *)
+Axiom core_slice_index_usize_get : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: forward function *)
+Axiom core_slice_index_usize_get_mut : forall (T : Type), usize -> slice T -> result (option T).
+
+(* [core::slice::index::usize::get_mut]: backward function 0 *)
+Axiom core_slice_index_usize_get_mut_back :
+ forall (T : Type), usize -> slice T -> option T -> result (slice T).
+
+(* [core::slice::index::usize::get_unchecked]: forward function *)
+Axiom core_slice_index_usize_get_unchecked :
+ forall (T : Type), usize -> const_raw_ptr (slice T) -> result (const_raw_ptr T).
+
+(* [core::slice::index::usize::get_unchecked_mut]: forward function *)
+Axiom core_slice_index_usize_get_unchecked_mut :
+ forall (T : Type), usize -> mut_raw_ptr (slice T) -> result (mut_raw_ptr T).
+
+(* [core::slice::index::usize::index]: forward function *)
+Axiom core_slice_index_usize_index : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: forward function *)
+Axiom core_slice_index_usize_index_mut : forall (T : Type), usize -> slice T -> result T.
+
+(* [core::slice::index::usize::index_mut]: backward function 0 *)
+Axiom core_slice_index_usize_index_mut_back :
+ forall (T : Type), usize -> slice T -> T -> result (slice T).
+
+(* Trait implementation: [core::slice::index::private_slice_index::usize] *)
+Definition core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize := tt.
+
+(* Trait implementation: [core::slice::index::usize] *)
+Definition core_slice_index_usize_coresliceindexSliceIndexInst (T : Type) :
+ core_slice_index_SliceIndex usize (slice T) := {|
+ core_slice_index_SliceIndex_sealedInst := core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ core_slice_index_SliceIndex_Output := T;
+ core_slice_index_SliceIndex_get := core_slice_index_usize_get T;
+ core_slice_index_SliceIndex_get_mut := core_slice_index_usize_get_mut T;
+ core_slice_index_SliceIndex_get_mut_back := core_slice_index_usize_get_mut_back T;
+ core_slice_index_SliceIndex_get_unchecked := core_slice_index_usize_get_unchecked T;
+ core_slice_index_SliceIndex_get_unchecked_mut := core_slice_index_usize_get_unchecked_mut T;
+ core_slice_index_SliceIndex_index := core_slice_index_usize_index T;
+ core_slice_index_SliceIndex_index_mut := core_slice_index_usize_index_mut T;
+ core_slice_index_SliceIndex_index_mut_back := core_slice_index_usize_index_mut_back T;
+|}.
+
+(* [alloc::vec::Vec::index]: forward function *)
+Axiom alloc_vec_Vec_index : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: forward function *)
+Axiom alloc_vec_Vec_index_mut : forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx), result inst.(core_slice_index_SliceIndex_Output).
+
+(* [alloc::vec::Vec::index_mut]: backward function 0 *)
+Axiom alloc_vec_Vec_index_mut_back :
+ forall (T Idx : Type) (inst : core_slice_index_SliceIndex Idx (slice T))
+ (Self : alloc_vec_Vec T) (i : Idx) (x : inst.(core_slice_index_SliceIndex_Output)), result (alloc_vec_Vec T).
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_Index (alloc_vec_Vec T) Idx := {|
+ core_ops_index_Index_Output := inst.(core_slice_index_SliceIndex_Output);
+ core_ops_index_Index_index := alloc_vec_Vec_index T Idx inst;
+|}.
+
+(* Trait implementation: [alloc::vec::Vec] *)
+Definition alloc_vec_Vec_coreopsindexIndexMutInst (T Idx : Type)
+ (inst : core_slice_index_SliceIndex Idx (slice T)) :
+ core_ops_index_IndexMut (alloc_vec_Vec T) Idx := {|
+ core_ops_index_IndexMut_indexInst := alloc_vec_Vec_coreopsindexIndexInst T Idx inst;
+ core_ops_index_IndexMut_index_mut := alloc_vec_Vec_index_mut T Idx inst;
+ core_ops_index_IndexMut_index_mut_back := alloc_vec_Vec_index_mut_back T Idx inst;
+|}.
+
+(*** Theorems *)
+
+Axiom alloc_vec_Vec_index_mut_back_eq : forall {a : Type} (v : alloc_vec_Vec a) (i : usize) (x : a),
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x =
+ alloc_vec_Vec_update_usize v i x.
+
+End Primitives.
diff --git a/tests/coq/traits/Traits.v b/tests/coq/traits/Traits.v
new file mode 100644
index 00000000..e104fb66
--- /dev/null
+++ b/tests/coq/traits/Traits.v
@@ -0,0 +1,520 @@
+(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *)
+(** [traits] *)
+Require Import Primitives.
+Import Primitives.
+Require Import Coq.ZArith.ZArith.
+Require Import List.
+Import ListNotations.
+Local Open Scope Primitives_scope.
+Module Traits.
+
+(** Trait declaration: [traits::BoolTrait] *)
+Record BoolTrait_t (Self : Type) := mkBoolTrait_t {
+ BoolTrait_t_get_bool : Self -> result bool;
+}.
+
+Arguments mkBoolTrait_t { _ }.
+Arguments BoolTrait_t_get_bool { _ }.
+
+(** [traits::Bool::{0}::get_bool]: forward function *)
+Definition bool_get_bool (self : bool) : result bool :=
+ Return self.
+
+(** Trait implementation: [traits::Bool::{0}] *)
+Definition Bool_BoolTraitInst : BoolTrait_t bool := {|
+ BoolTrait_t_get_bool := bool_get_bool;
+|}.
+
+(** [traits::BoolTrait::ret_true]: forward function *)
+Definition boolTrait_ret_true
+ {Self : Type} (self_clause : BoolTrait_t Self) (self : Self) : result bool :=
+ Return true
+.
+
+(** [traits::test_bool_trait_bool]: forward function *)
+Definition test_bool_trait_bool (x : bool) : result bool :=
+ b <- bool_get_bool x;
+ if b then boolTrait_ret_true Bool_BoolTraitInst x else Return false
+.
+
+(** [traits::Option::{1}::get_bool]: forward function *)
+Definition option_get_bool (T : Type) (self : option T) : result bool :=
+ match self with | None => Return false | Some t => Return true end
+.
+
+(** Trait implementation: [traits::Option::{1}] *)
+Definition Option_BoolTraitInst (T : Type) : BoolTrait_t (option T) := {|
+ BoolTrait_t_get_bool := option_get_bool T;
+|}.
+
+(** [traits::test_bool_trait_option]: forward function *)
+Definition test_bool_trait_option (T : Type) (x : option T) : result bool :=
+ b <- option_get_bool T x;
+ if b then boolTrait_ret_true (Option_BoolTraitInst T) x else Return false
+.
+
+(** [traits::test_bool_trait]: forward function *)
+Definition test_bool_trait
+ (T : Type) (inst : BoolTrait_t T) (x : T) : result bool :=
+ inst.(BoolTrait_t_get_bool) x
+.
+
+(** Trait declaration: [traits::ToU64] *)
+Record ToU64_t (Self : Type) := mkToU64_t {
+ ToU64_t_to_u64 : Self -> result u64;
+}.
+
+Arguments mkToU64_t { _ }.
+Arguments ToU64_t_to_u64 { _ }.
+
+(** [traits::u64::{2}::to_u64]: forward function *)
+Definition u64_to_u64 (self : u64) : result u64 :=
+ Return self.
+
+(** Trait implementation: [traits::u64::{2}] *)
+Definition u64_ToU64Inst : ToU64_t u64 := {| ToU64_t_to_u64 := u64_to_u64; |}.
+
+(** [traits::Tuple2::{3}::to_u64]: forward function *)
+Definition tuple2_to_u64
+ (A : Type) (inst : ToU64_t A) (self : (A * A)) : result u64 :=
+ let (t, t0) := self in
+ i <- inst.(ToU64_t_to_u64) t;
+ i0 <- inst.(ToU64_t_to_u64) t0;
+ u64_add i i0
+.
+
+(** Trait implementation: [traits::Tuple2::{3}] *)
+Definition Tuple2_ToU64Inst (A : Type) (inst : ToU64_t A) : ToU64_t (A * A)
+ := {|
+ ToU64_t_to_u64 := tuple2_to_u64 A inst;
+|}.
+
+(** [traits::f]: forward function *)
+Definition f (T : Type) (inst : ToU64_t T) (x : (T * T)) : result u64 :=
+ tuple2_to_u64 T inst x
+.
+
+(** [traits::g]: forward function *)
+Definition g (T : Type) (inst : ToU64_t (T * T)) (x : (T * T)) : result u64 :=
+ inst.(ToU64_t_to_u64) x
+.
+
+(** [traits::h0]: forward function *)
+Definition h0 (x : u64) : result u64 :=
+ u64_to_u64 x.
+
+(** [traits::Wrapper] *)
+Record Wrapper_t (T : Type) := mkWrapper_t { wrapper_x : T; }.
+
+Arguments mkWrapper_t { _ }.
+Arguments wrapper_x { _ }.
+
+(** [traits::Wrapper::{4}::to_u64]: forward function *)
+Definition wrapper_to_u64
+ (T : Type) (inst : ToU64_t T) (self : Wrapper_t T) : result u64 :=
+ inst.(ToU64_t_to_u64) self.(wrapper_x)
+.
+
+(** Trait implementation: [traits::Wrapper::{4}] *)
+Definition Wrapper_ToU64Inst (T : Type) (inst : ToU64_t T) : ToU64_t (Wrapper_t
+ T) := {|
+ ToU64_t_to_u64 := wrapper_to_u64 T inst;
+|}.
+
+(** [traits::h1]: forward function *)
+Definition h1 (x : Wrapper_t u64) : result u64 :=
+ wrapper_to_u64 u64 u64_ToU64Inst x
+.
+
+(** [traits::h2]: forward function *)
+Definition h2 (T : Type) (inst : ToU64_t T) (x : Wrapper_t T) : result u64 :=
+ wrapper_to_u64 T inst x
+.
+
+(** Trait declaration: [traits::ToType] *)
+Record ToType_t (Self T : Type) := mkToType_t {
+ ToType_t_to_type : Self -> result T;
+}.
+
+Arguments mkToType_t { _ _ }.
+Arguments ToType_t_to_type { _ _ }.
+
+(** [traits::u64::{5}::to_type]: forward function *)
+Definition u64_to_type (self : u64) : result bool :=
+ Return (self s> 0%u64).
+
+(** Trait implementation: [traits::u64::{5}] *)
+Definition u64_ToTypeInst : ToType_t u64 bool := {|
+ ToType_t_to_type := u64_to_type;
+|}.
+
+(** Trait declaration: [traits::OfType] *)
+Record OfType_t (Self : Type) := mkOfType_t {
+ OfType_t_of_type : forall (T : Type) (inst : ToType_t T Self), T -> result
+ Self;
+}.
+
+Arguments mkOfType_t { _ }.
+Arguments OfType_t_of_type { _ }.
+
+(** [traits::h3]: forward function *)
+Definition h3
+ (T1 T2 : Type) (inst : OfType_t T1) (inst0 : ToType_t T2 T1) (y : T2) :
+ result T1
+ :=
+ inst.(OfType_t_of_type) T2 inst0 y
+.
+
+(** Trait declaration: [traits::OfTypeBis] *)
+Record OfTypeBis_t (Self T : Type) := mkOfTypeBis_t {
+ OfTypeBis_tOfTypeBis_t_parent_clause_0 : ToType_t T Self;
+ OfTypeBis_t_of_type : T -> result Self;
+}.
+
+Arguments mkOfTypeBis_t { _ _ }.
+Arguments OfTypeBis_tOfTypeBis_t_parent_clause_0 { _ _ }.
+Arguments OfTypeBis_t_of_type { _ _ }.
+
+(** [traits::h4]: forward function *)
+Definition h4
+ (T1 T2 : Type) (inst : OfTypeBis_t T1 T2) (inst0 : ToType_t T2 T1) (y : T2) :
+ result T1
+ :=
+ inst.(OfTypeBis_t_of_type) y
+.
+
+(** [traits::TestType] *)
+Record TestType_t (T : Type) := mkTestType_t { testType_0 : T; }.
+
+Arguments mkTestType_t { _ }.
+Arguments testType_0 { _ }.
+
+(** [traits::TestType::{6}::test::TestType1] *)
+Record TestType_test_TestType1_t :=
+mkTestType_test_TestType1_t {
+ testType_test_TestType1_0 : u64;
+}
+.
+
+(** Trait declaration: [traits::TestType::{6}::test::TestTrait] *)
+Record TestType_test_TestTrait_t (Self : Type) := mkTestType_test_TestTrait_t {
+ TestType_test_TestTrait_t_test : Self -> result bool;
+}.
+
+Arguments mkTestType_test_TestTrait_t { _ }.
+Arguments TestType_test_TestTrait_t_test { _ }.
+
+(** [traits::TestType::{6}::test::TestType1::{0}::test]: forward function *)
+Definition testType_test_TestType1_test
+ (self : TestType_test_TestType1_t) : result bool :=
+ Return (self.(testType_test_TestType1_0) s> 1%u64)
+.
+
+(** Trait implementation: [traits::TestType::{6}::test::TestType1::{0}] *)
+Definition TestType_test_TestType1_TestType_test_TestTraitInst :
+ TestType_test_TestTrait_t TestType_test_TestType1_t := {|
+ TestType_test_TestTrait_t_test := testType_test_TestType1_test;
+|}.
+
+(** [traits::TestType::{6}::test]: forward function *)
+Definition testType_test
+ (T : Type) (inst : ToU64_t T) (self : TestType_t T) (x : T) : result bool :=
+ x0 <- inst.(ToU64_t_to_u64) x;
+ if x0 s> 0%u64
+ then testType_test_TestType1_test {| testType_test_TestType1_0 := 0%u64 |}
+ else Return false
+.
+
+(** [traits::BoolWrapper] *)
+Record BoolWrapper_t := mkBoolWrapper_t { boolWrapper_0 : bool; }.
+
+(** [traits::BoolWrapper::{7}::to_type]: forward function *)
+Definition boolWrapper_to_type
+ (T : Type) (inst : ToType_t bool T) (self : BoolWrapper_t) : result T :=
+ inst.(ToType_t_to_type) self.(boolWrapper_0)
+.
+
+(** Trait implementation: [traits::BoolWrapper::{7}] *)
+Definition BoolWrapper_ToTypeInst (T : Type) (inst : ToType_t bool T) :
+ ToType_t BoolWrapper_t T := {|
+ ToType_t_to_type := boolWrapper_to_type T inst;
+|}.
+
+(** [traits::WithConstTy::LEN2] *)
+Definition with_const_ty_len2_body : result usize := Return 32%usize.
+Definition with_const_ty_len2_c : usize := with_const_ty_len2_body%global.
+
+(** Trait declaration: [traits::WithConstTy] *)
+Record WithConstTy_t (Self : Type) (LEN : usize) := mkWithConstTy_t {
+ WithConstTy_tWithConstTy_t_LEN1 : usize;
+ WithConstTy_tWithConstTy_t_LEN2 : usize;
+ WithConstTy_tWithConstTy_t_V : Type;
+ WithConstTy_tWithConstTy_t_W : Type;
+ WithConstTy_tWithConstTy_t_W_clause_0 : ToU64_t WithConstTy_tWithConstTy_t_W;
+ WithConstTy_t_f : WithConstTy_tWithConstTy_t_W -> array u8 LEN -> result
+ WithConstTy_tWithConstTy_t_W;
+}.
+
+Arguments mkWithConstTy_t { _ _ }.
+Arguments WithConstTy_tWithConstTy_t_LEN1 { _ _ }.
+Arguments WithConstTy_tWithConstTy_t_LEN2 { _ _ }.
+Arguments WithConstTy_tWithConstTy_t_V { _ _ }.
+Arguments WithConstTy_tWithConstTy_t_W { _ _ }.
+Arguments WithConstTy_tWithConstTy_t_W_clause_0 { _ _ }.
+Arguments WithConstTy_t_f { _ _ }.
+
+(** [traits::Bool::{8}::LEN1] *)
+Definition bool_len1_body : result usize := Return 12%usize.
+Definition bool_len1_c : usize := bool_len1_body%global.
+
+(** [traits::Bool::{8}::f]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) *)
+Definition bool_f (i : u64) (a : array u8 32%usize) : result u64 :=
+ Return i.
+
+(** Trait implementation: [traits::Bool::{8}] *)
+Definition Bool_WithConstTyInst : WithConstTy_t bool 32%usize := {|
+ WithConstTy_tWithConstTy_t_LEN1 := bool_len1_c;
+ WithConstTy_tWithConstTy_t_LEN2 := with_const_ty_len2_c;
+ WithConstTy_tWithConstTy_t_V := u8;
+ WithConstTy_tWithConstTy_t_W := u64;
+ WithConstTy_tWithConstTy_t_W_clause_0 := u64_ToU64Inst;
+ WithConstTy_t_f := bool_f;
+|}.
+
+(** [traits::use_with_const_ty1]: forward function *)
+Definition use_with_const_ty1
+ (H : Type) (LEN : usize) (inst : WithConstTy_t H LEN) : result usize :=
+ let i := inst.(WithConstTy_tWithConstTy_t_LEN1) in Return i
+.
+
+(** [traits::use_with_const_ty2]: forward function *)
+Definition use_with_const_ty2
+ (H : Type) (LEN : usize) (inst : WithConstTy_t H LEN)
+ (w : inst.(WithConstTy_tWithConstTy_t_W)) :
+ result unit
+ :=
+ Return tt
+.
+
+(** [traits::use_with_const_ty3]: forward function *)
+Definition use_with_const_ty3
+ (H : Type) (LEN : usize) (inst : WithConstTy_t H LEN)
+ (x : inst.(WithConstTy_tWithConstTy_t_W)) :
+ result u64
+ :=
+ inst.(WithConstTy_tWithConstTy_t_W_clause_0).(ToU64_t_to_u64) x
+.
+
+(** [traits::test_where1]: forward function *)
+Definition test_where1 (T : Type) (_x : T) : result unit :=
+ Return tt.
+
+(** [traits::test_where2]: forward function *)
+Definition test_where2
+ (T : Type) (inst : WithConstTy_t T 32%usize) (_x : u32) : result unit :=
+ Return tt
+.
+
+(** [alloc::string::String] *)
+Axiom alloc_string_String_t : Type.
+
+(** Trait declaration: [traits::ParentTrait0] *)
+Record ParentTrait0_t (Self : Type) := mkParentTrait0_t {
+ ParentTrait0_tParentTrait0_t_W : Type;
+ ParentTrait0_t_get_name : Self -> result alloc_string_String_t;
+ ParentTrait0_t_get_w : Self -> result ParentTrait0_tParentTrait0_t_W;
+}.
+
+Arguments mkParentTrait0_t { _ }.
+Arguments ParentTrait0_tParentTrait0_t_W { _ }.
+Arguments ParentTrait0_t_get_name { _ }.
+Arguments ParentTrait0_t_get_w { _ }.
+
+(** Trait declaration: [traits::ParentTrait1] *)
+Record ParentTrait1_t (Self : Type) := mkParentTrait1_t{}.
+
+Arguments mkParentTrait1_t { _ }.
+
+(** Trait declaration: [traits::ChildTrait] *)
+Record ChildTrait_t (Self : Type) := mkChildTrait_t {
+ ChildTrait_tChildTrait_t_parent_clause_0 : ParentTrait0_t Self;
+ ChildTrait_tChildTrait_t_parent_clause_1 : ParentTrait1_t Self;
+}.
+
+Arguments mkChildTrait_t { _ }.
+Arguments ChildTrait_tChildTrait_t_parent_clause_0 { _ }.
+Arguments ChildTrait_tChildTrait_t_parent_clause_1 { _ }.
+
+(** [traits::test_child_trait1]: forward function *)
+Definition test_child_trait1
+ (T : Type) (inst : ChildTrait_t T) (x : T) : result alloc_string_String_t :=
+ inst.(ChildTrait_tChildTrait_t_parent_clause_0).(ParentTrait0_t_get_name) x
+.
+
+(** [traits::test_child_trait2]: forward function *)
+Definition test_child_trait2
+ (T : Type) (inst : ChildTrait_t T) (x : T) :
+ result
+ inst.(ChildTrait_tChildTrait_t_parent_clause_0).(ParentTrait0_tParentTrait0_t_W)
+ :=
+ inst.(ChildTrait_tChildTrait_t_parent_clause_0).(ParentTrait0_t_get_w) x
+.
+
+(** [traits::order1]: forward function *)
+Definition order1
+ (T U : Type) (inst : ParentTrait0_t T) (inst0 : ParentTrait0_t U) :
+ result unit
+ :=
+ Return tt
+.
+
+(** Trait declaration: [traits::ChildTrait1] *)
+Record ChildTrait1_t (Self : Type) := mkChildTrait1_t {
+ ChildTrait1_tChildTrait1_t_parent_clause_0 : ParentTrait1_t Self;
+}.
+
+Arguments mkChildTrait1_t { _ }.
+Arguments ChildTrait1_tChildTrait1_t_parent_clause_0 { _ }.
+
+(** Trait implementation: [traits::usize::{9}] *)
+Definition usize_ParentTrait1Inst : ParentTrait1_t usize := mkParentTrait1_t.
+
+(** Trait implementation: [traits::usize::{10}] *)
+Definition usize_ChildTrait1Inst : ChildTrait1_t usize := {|
+ ChildTrait1_tChildTrait1_t_parent_clause_0 := usize_ParentTrait1Inst;
+|}.
+
+(** Trait declaration: [traits::Iterator] *)
+Record Iterator_t (Self : Type) := mkIterator_t {
+ Iterator_tIterator_t_Item : Type;
+}.
+
+Arguments mkIterator_t { _ }.
+Arguments Iterator_tIterator_t_Item { _ }.
+
+(** Trait declaration: [traits::IntoIterator] *)
+Record IntoIterator_t (Self : Type) := mkIntoIterator_t {
+ IntoIterator_tIntoIterator_t_Item : Type;
+ IntoIterator_tIntoIterator_t_IntoIter : Type;
+ IntoIterator_tIntoIterator_t_IntoIter_clause_0 : Iterator_t
+ IntoIterator_tIntoIterator_t_IntoIter;
+ IntoIterator_t_into_iter : Self -> result
+ IntoIterator_tIntoIterator_t_IntoIter;
+}.
+
+Arguments mkIntoIterator_t { _ }.
+Arguments IntoIterator_tIntoIterator_t_Item { _ }.
+Arguments IntoIterator_tIntoIterator_t_IntoIter { _ }.
+Arguments IntoIterator_tIntoIterator_t_IntoIter_clause_0 { _ }.
+Arguments IntoIterator_t_into_iter { _ }.
+
+(** Trait declaration: [traits::FromResidual] *)
+Record FromResidual_t (Self T : Type) := mkFromResidual_t{}.
+
+Arguments mkFromResidual_t { _ _ }.
+
+(** Trait declaration: [traits::Try] *)
+Record Try_t (Self : Type) := mkTry_t {
+ Try_tTry_t_Residual : Type;
+ Try_tTry_t_parent_clause_0 : FromResidual_t Self Try_tTry_t_Residual;
+}.
+
+Arguments mkTry_t { _ }.
+Arguments Try_tTry_t_Residual { _ }.
+Arguments Try_tTry_t_parent_clause_0 { _ }.
+
+(** Trait declaration: [traits::WithTarget] *)
+Record WithTarget_t (Self : Type) := mkWithTarget_t {
+ WithTarget_tWithTarget_t_Target : Type;
+}.
+
+Arguments mkWithTarget_t { _ }.
+Arguments WithTarget_tWithTarget_t_Target { _ }.
+
+(** Trait declaration: [traits::ParentTrait2] *)
+Record ParentTrait2_t (Self : Type) := mkParentTrait2_t {
+ ParentTrait2_tParentTrait2_t_U : Type;
+ ParentTrait2_tParentTrait2_t_U_clause_0 : WithTarget_t
+ ParentTrait2_tParentTrait2_t_U;
+}.
+
+Arguments mkParentTrait2_t { _ }.
+Arguments ParentTrait2_tParentTrait2_t_U { _ }.
+Arguments ParentTrait2_tParentTrait2_t_U_clause_0 { _ }.
+
+(** Trait declaration: [traits::ChildTrait2] *)
+Record ChildTrait2_t (Self : Type) := mkChildTrait2_t {
+ ChildTrait2_tChildTrait2_t_parent_clause_0 : ParentTrait2_t Self;
+ ChildTrait2_t_convert :
+ (ChildTrait2_tChildTrait2_t_parent_clause_0).(ParentTrait2_tParentTrait2_t_U)
+ -> result
+ (ChildTrait2_tChildTrait2_t_parent_clause_0).(ParentTrait2_tParentTrait2_t_U_clause_0).(WithTarget_tWithTarget_t_Target);
+}.
+
+Arguments mkChildTrait2_t { _ }.
+Arguments ChildTrait2_tChildTrait2_t_parent_clause_0 { _ }.
+Arguments ChildTrait2_t_convert { _ }.
+
+(** Trait implementation: [traits::u32::{11}] *)
+Definition u32_WithTargetInst : WithTarget_t u32 := {|
+ WithTarget_tWithTarget_t_Target := u32;
+|}.
+
+(** Trait implementation: [traits::u32::{12}] *)
+Definition u32_ParentTrait2Inst : ParentTrait2_t u32 := {|
+ ParentTrait2_tParentTrait2_t_U := u32;
+ ParentTrait2_tParentTrait2_t_U_clause_0 := u32_WithTargetInst;
+|}.
+
+(** [traits::u32::{13}::convert]: forward function *)
+Definition u32_convert (x : u32) : result u32 :=
+ Return x.
+
+(** Trait implementation: [traits::u32::{13}] *)
+Definition u32_ChildTrait2Inst : ChildTrait2_t u32 := {|
+ ChildTrait2_tChildTrait2_t_parent_clause_0 := u32_ParentTrait2Inst;
+ ChildTrait2_t_convert := u32_convert;
+|}.
+
+(** [traits::incr_u32]: forward function *)
+Definition incr_u32 (x : u32) : result u32 :=
+ u32_add x 1%u32.
+
+(** Trait declaration: [traits::CFnOnce] *)
+Record CFnOnce_t (Self Args : Type) := mkCFnOnce_t {
+ CFnOnce_tCFnOnce_t_Output : Type;
+ CFnOnce_t_call_once : Self -> Args -> result CFnOnce_tCFnOnce_t_Output;
+}.
+
+Arguments mkCFnOnce_t { _ _ }.
+Arguments CFnOnce_tCFnOnce_t_Output { _ _ }.
+Arguments CFnOnce_t_call_once { _ _ }.
+
+(** Trait declaration: [traits::CFnMut] *)
+Record CFnMut_t (Self Args : Type) := mkCFnMut_t {
+ CFnMut_tCFnMut_t_parent_clause_0 : CFnOnce_t Self Args;
+ CFnMut_t_call_mut : Self -> Args -> result
+ (CFnMut_tCFnMut_t_parent_clause_0).(CFnOnce_tCFnOnce_t_Output);
+ CFnMut_t_call_mut_back : Self -> Args ->
+ (CFnMut_tCFnMut_t_parent_clause_0).(CFnOnce_tCFnOnce_t_Output) -> result
+ Self;
+}.
+
+Arguments mkCFnMut_t { _ _ }.
+Arguments CFnMut_tCFnMut_t_parent_clause_0 { _ _ }.
+Arguments CFnMut_t_call_mut { _ _ }.
+Arguments CFnMut_t_call_mut_back { _ _ }.
+
+(** Trait declaration: [traits::CFn] *)
+Record CFn_t (Self Args : Type) := mkCFn_t {
+ CFn_tCFn_t_parent_clause_0 : CFnMut_t Self Args;
+ CFn_t_call_mut : Self -> Args -> result
+ (CFn_tCFn_t_parent_clause_0).(CFnMut_tCFnMut_t_parent_clause_0).(CFnOnce_tCFnOnce_t_Output);
+}.
+
+Arguments mkCFn_t { _ _ }.
+Arguments CFn_tCFn_t_parent_clause_0 { _ _ }.
+Arguments CFn_t_call_mut { _ _ }.
+
+End Traits .
diff --git a/tests/coq/traits/_CoqProject b/tests/coq/traits/_CoqProject
new file mode 100644
index 00000000..5b6199fc
--- /dev/null
+++ b/tests/coq/traits/_CoqProject
@@ -0,0 +1,7 @@
+# This file was automatically generated - see ../Makefile
+-R . Lib
+-arg -w
+-arg all
+
+Traits.v
+Primitives.v
diff --git a/tests/fstar/array/Array.Clauses.Template.fst b/tests/fstar/array/Array.Clauses.Template.fst
index 8a15e230..06056d61 100644
--- a/tests/fstar/array/Array.Clauses.Template.fst
+++ b/tests/fstar/array/Array.Clauses.Template.fst
@@ -8,11 +8,12 @@ open Array.Types
(** [array::sum]: decreases clause *)
unfold
-let sum_loop_decreases (s : slice u32) (sum : u32) (i : usize) : nat = admit ()
+let sum_loop_decreases (s : slice u32) (sum0 : u32) (i : usize) : nat =
+ admit ()
(** [array::sum2]: decreases clause *)
unfold
-let sum2_loop_decreases (s : slice u32) (s2 : slice u32) (sum : u32)
+let sum2_loop_decreases (s : slice u32) (s2 : slice u32) (sum0 : u32)
(i : usize) : nat =
admit ()
diff --git a/tests/fstar/array/Array.Funs.fst b/tests/fstar/array/Array.Funs.fst
index 7c1d0b09..8f0bfbbd 100644
--- a/tests/fstar/array/Array.Funs.fst
+++ b/tests/fstar/array/Array.Funs.fst
@@ -7,349 +7,369 @@ include Array.Clauses
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
+(** [array::incr]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) *)
+let incr (x : u32) : result u32 =
+ u32_add x 1
+
(** [array::array_to_shared_slice_]: forward function *)
-let array_to_shared_slice__fwd
- (t : Type0) (s : array t 32) : result (slice t) =
- array_to_slice_shared t 32 s
+let array_to_shared_slice_ (t : Type0) (s : array t 32) : result (slice t) =
+ array_to_slice t 32 s
(** [array::array_to_mut_slice_]: forward function *)
-let array_to_mut_slice__fwd (t : Type0) (s : array t 32) : result (slice t) =
- array_to_slice_mut_fwd t 32 s
+let array_to_mut_slice_ (t : Type0) (s : array t 32) : result (slice t) =
+ array_to_slice t 32 s
(** [array::array_to_mut_slice_]: backward function 0 *)
let array_to_mut_slice__back
(t : Type0) (s : array t 32) (ret : slice t) : result (array t 32) =
- array_to_slice_mut_back t 32 s ret
+ array_from_slice t 32 s ret
(** [array::array_len]: forward function *)
-let array_len_fwd (t : Type0) (s : array t 32) : result usize =
- let* s0 = array_to_slice_shared t 32 s in let i = slice_len t s0 in Return i
+let array_len (t : Type0) (s : array t 32) : result usize =
+ let* s0 = array_to_slice t 32 s in let i = slice_len t s0 in Return i
(** [array::shared_array_len]: forward function *)
-let shared_array_len_fwd (t : Type0) (s : array t 32) : result usize =
- let* s0 = array_to_slice_shared t 32 s in let i = slice_len t s0 in Return i
+let shared_array_len (t : Type0) (s : array t 32) : result usize =
+ let* s0 = array_to_slice t 32 s in let i = slice_len t s0 in Return i
(** [array::shared_slice_len]: forward function *)
-let shared_slice_len_fwd (t : Type0) (s : slice t) : result usize =
+let shared_slice_len (t : Type0) (s : slice t) : result usize =
let i = slice_len t s in Return i
(** [array::index_array_shared]: forward function *)
-let index_array_shared_fwd
- (t : Type0) (s : array t 32) (i : usize) : result t =
- array_index_shared t 32 s i
+let index_array_shared (t : Type0) (s : array t 32) (i : usize) : result t =
+ array_index_usize t 32 s i
(** [array::index_array_u32]: forward function *)
-let index_array_u32_fwd (s : array u32 32) (i : usize) : result u32 =
- array_index_shared u32 32 s i
-
-(** [array::index_array_generic]: forward function *)
-let index_array_generic_fwd
- (n : usize) (s : array u32 n) (i : usize) : result u32 =
- array_index_shared u32 n s i
-
-(** [array::index_array_generic_call]: forward function *)
-let index_array_generic_call_fwd
- (n : usize) (s : array u32 n) (i : usize) : result u32 =
- index_array_generic_fwd n s i
+let index_array_u32 (s : array u32 32) (i : usize) : result u32 =
+ array_index_usize u32 32 s i
(** [array::index_array_copy]: forward function *)
-let index_array_copy_fwd (x : array u32 32) : result u32 =
- array_index_shared u32 32 x 0
+let index_array_copy (x : array u32 32) : result u32 =
+ array_index_usize u32 32 x 0
(** [array::index_mut_array]: forward function *)
-let index_mut_array_fwd (t : Type0) (s : array t 32) (i : usize) : result t =
- array_index_mut_fwd t 32 s i
+let index_mut_array (t : Type0) (s : array t 32) (i : usize) : result t =
+ array_index_usize t 32 s i
(** [array::index_mut_array]: backward function 0 *)
let index_mut_array_back
(t : Type0) (s : array t 32) (i : usize) (ret : t) : result (array t 32) =
- array_index_mut_back t 32 s i ret
+ array_update_usize t 32 s i ret
(** [array::index_slice]: forward function *)
-let index_slice_fwd (t : Type0) (s : slice t) (i : usize) : result t =
- slice_index_shared t s i
+let index_slice (t : Type0) (s : slice t) (i : usize) : result t =
+ slice_index_usize t s i
(** [array::index_mut_slice]: forward function *)
-let index_mut_slice_fwd (t : Type0) (s : slice t) (i : usize) : result t =
- slice_index_mut_fwd t s i
+let index_mut_slice (t : Type0) (s : slice t) (i : usize) : result t =
+ slice_index_usize t s i
(** [array::index_mut_slice]: backward function 0 *)
let index_mut_slice_back
(t : Type0) (s : slice t) (i : usize) (ret : t) : result (slice t) =
- slice_index_mut_back t s i ret
+ slice_update_usize t s i ret
(** [array::slice_subslice_shared_]: forward function *)
-let slice_subslice_shared__fwd
+let slice_subslice_shared_
(x : slice u32) (y : usize) (z : usize) : result (slice u32) =
- slice_subslice_shared u32 x (Mkrange y z)
+ core_slice_index_Slice_index u32 (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32) x
+ { start = y; end_ = z }
(** [array::slice_subslice_mut_]: forward function *)
-let slice_subslice_mut__fwd
+let slice_subslice_mut_
(x : slice u32) (y : usize) (z : usize) : result (slice u32) =
- slice_subslice_mut_fwd u32 x (Mkrange y z)
+ core_slice_index_Slice_index_mut u32 (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32) x
+ { start = y; end_ = z }
(** [array::slice_subslice_mut_]: backward function 0 *)
let slice_subslice_mut__back
(x : slice u32) (y : usize) (z : usize) (ret : slice u32) :
result (slice u32)
=
- slice_subslice_mut_back u32 x (Mkrange y z) ret
+ core_slice_index_Slice_index_mut_back u32 (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32) x
+ { start = y; end_ = z } ret
(** [array::array_to_slice_shared_]: forward function *)
-let array_to_slice_shared__fwd (x : array u32 32) : result (slice u32) =
- array_to_slice_shared u32 32 x
+let array_to_slice_shared_ (x : array u32 32) : result (slice u32) =
+ array_to_slice u32 32 x
(** [array::array_to_slice_mut_]: forward function *)
-let array_to_slice_mut__fwd (x : array u32 32) : result (slice u32) =
- array_to_slice_mut_fwd u32 32 x
+let array_to_slice_mut_ (x : array u32 32) : result (slice u32) =
+ array_to_slice u32 32 x
(** [array::array_to_slice_mut_]: backward function 0 *)
let array_to_slice_mut__back
(x : array u32 32) (ret : slice u32) : result (array u32 32) =
- array_to_slice_mut_back u32 32 x ret
+ array_from_slice u32 32 x ret
(** [array::array_subslice_shared_]: forward function *)
-let array_subslice_shared__fwd
+let array_subslice_shared_
(x : array u32 32) (y : usize) (z : usize) : result (slice u32) =
- array_subslice_shared u32 32 x (Mkrange y z)
+ core_array_Array_index u32 (core_ops_range_Range usize) 32
+ (core_slice_index_Slice_coreopsindexIndexInst u32 (core_ops_range_Range
+ usize) (core_slice_index_Range_coresliceindexSliceIndexInst u32)) x
+ { start = y; end_ = z }
(** [array::array_subslice_mut_]: forward function *)
-let array_subslice_mut__fwd
+let array_subslice_mut_
(x : array u32 32) (y : usize) (z : usize) : result (slice u32) =
- array_subslice_mut_fwd u32 32 x (Mkrange y z)
+ core_array_Array_index_mut u32 (core_ops_range_Range usize) 32
+ (core_slice_index_Slice_coreopsindexIndexMutInst u32 (core_ops_range_Range
+ usize) (core_slice_index_Range_coresliceindexSliceIndexInst u32)) x
+ { start = y; end_ = z }
(** [array::array_subslice_mut_]: backward function 0 *)
let array_subslice_mut__back
(x : array u32 32) (y : usize) (z : usize) (ret : slice u32) :
result (array u32 32)
=
- array_subslice_mut_back u32 32 x (Mkrange y z) ret
+ core_array_Array_index_mut_back u32 (core_ops_range_Range usize) 32
+ (core_slice_index_Slice_coreopsindexIndexMutInst u32 (core_ops_range_Range
+ usize) (core_slice_index_Range_coresliceindexSliceIndexInst u32)) x
+ { start = y; end_ = z } ret
(** [array::index_slice_0]: forward function *)
-let index_slice_0_fwd (t : Type0) (s : slice t) : result t =
- slice_index_shared t s 0
+let index_slice_0 (t : Type0) (s : slice t) : result t =
+ slice_index_usize t s 0
(** [array::index_array_0]: forward function *)
-let index_array_0_fwd (t : Type0) (s : array t 32) : result t =
- array_index_shared t 32 s 0
+let index_array_0 (t : Type0) (s : array t 32) : result t =
+ array_index_usize t 32 s 0
(** [array::index_index_array]: forward function *)
-let index_index_array_fwd
+let index_index_array
(s : array (array u32 32) 32) (i : usize) (j : usize) : result u32 =
- let* a = array_index_shared (array u32 32) 32 s i in
- array_index_shared u32 32 a j
+ let* a = array_index_usize (array u32 32) 32 s i in
+ array_index_usize u32 32 a j
(** [array::update_update_array]: forward function *)
-let update_update_array_fwd
+let update_update_array
(s : array (array u32 32) 32) (i : usize) (j : usize) : result unit =
- let* a = array_index_mut_fwd (array u32 32) 32 s i in
- let* a0 = array_index_mut_back u32 32 a j 0 in
- let* _ = array_index_mut_back (array u32 32) 32 s i a0 in
+ let* a = array_index_usize (array u32 32) 32 s i in
+ let* a0 = array_update_usize u32 32 a j 0 in
+ let* _ = array_update_usize (array u32 32) 32 s i a0 in
Return ()
(** [array::array_local_deep_copy]: forward function *)
-let array_local_deep_copy_fwd (x : array u32 32) : result unit =
+let array_local_deep_copy (x : array u32 32) : result unit =
Return ()
(** [array::take_array]: forward function *)
-let take_array_fwd (a : array u32 2) : result unit =
+let take_array (a : array u32 2) : result unit =
Return ()
(** [array::take_array_borrow]: forward function *)
-let take_array_borrow_fwd (a : array u32 2) : result unit =
+let take_array_borrow (a : array u32 2) : result unit =
Return ()
(** [array::take_slice]: forward function *)
-let take_slice_fwd (s : slice u32) : result unit =
+let take_slice (s : slice u32) : result unit =
Return ()
(** [array::take_mut_slice]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let take_mut_slice_fwd_back (s : slice u32) : result (slice u32) =
+let take_mut_slice (s : slice u32) : result (slice u32) =
Return s
(** [array::take_all]: forward function *)
-let take_all_fwd : result unit =
- let* _ = take_array_fwd (mk_array u32 2 [ 0; 0 ]) in
- let* _ = take_array_borrow_fwd (mk_array u32 2 [ 0; 0 ]) in
- let* s = array_to_slice_shared u32 2 (mk_array u32 2 [ 0; 0 ]) in
- let* _ = take_slice_fwd s in
- let* s0 = array_to_slice_mut_fwd u32 2 (mk_array u32 2 [ 0; 0 ]) in
- let* s1 = take_mut_slice_fwd_back s0 in
- let* _ = array_to_slice_mut_back u32 2 (mk_array u32 2 [ 0; 0 ]) s1 in
+let take_all : result unit =
+ let* _ = take_array (mk_array u32 2 [ 0; 0 ]) in
+ let* _ = take_array_borrow (mk_array u32 2 [ 0; 0 ]) in
+ let* s = array_to_slice u32 2 (mk_array u32 2 [ 0; 0 ]) in
+ let* _ = take_slice s in
+ let* s0 = array_to_slice u32 2 (mk_array u32 2 [ 0; 0 ]) in
+ let* s1 = take_mut_slice s0 in
+ let* _ = array_from_slice u32 2 (mk_array u32 2 [ 0; 0 ]) s1 in
Return ()
(** [array::index_array]: forward function *)
-let index_array_fwd (x : array u32 2) : result u32 =
- array_index_shared u32 2 x 0
+let index_array (x : array u32 2) : result u32 =
+ array_index_usize u32 2 x 0
(** [array::index_array_borrow]: forward function *)
-let index_array_borrow_fwd (x : array u32 2) : result u32 =
- array_index_shared u32 2 x 0
+let index_array_borrow (x : array u32 2) : result u32 =
+ array_index_usize u32 2 x 0
(** [array::index_slice_u32_0]: forward function *)
-let index_slice_u32_0_fwd (x : slice u32) : result u32 =
- slice_index_shared u32 x 0
+let index_slice_u32_0 (x : slice u32) : result u32 =
+ slice_index_usize u32 x 0
(** [array::index_mut_slice_u32_0]: forward function *)
-let index_mut_slice_u32_0_fwd (x : slice u32) : result u32 =
- slice_index_shared u32 x 0
+let index_mut_slice_u32_0 (x : slice u32) : result u32 =
+ slice_index_usize u32 x 0
(** [array::index_mut_slice_u32_0]: backward function 0 *)
let index_mut_slice_u32_0_back (x : slice u32) : result (slice u32) =
- let* _ = slice_index_shared u32 x 0 in Return x
+ let* _ = slice_index_usize u32 x 0 in Return x
(** [array::index_all]: forward function *)
-let index_all_fwd : result u32 =
- let* i = index_array_fwd (mk_array u32 2 [ 0; 0 ]) in
- let* i0 = index_array_fwd (mk_array u32 2 [ 0; 0 ]) in
+let index_all : result u32 =
+ let* i = index_array (mk_array u32 2 [ 0; 0 ]) in
+ let* i0 = index_array (mk_array u32 2 [ 0; 0 ]) in
let* i1 = u32_add i i0 in
- let* i2 = index_array_borrow_fwd (mk_array u32 2 [ 0; 0 ]) in
+ let* i2 = index_array_borrow (mk_array u32 2 [ 0; 0 ]) in
let* i3 = u32_add i1 i2 in
- let* s = array_to_slice_shared u32 2 (mk_array u32 2 [ 0; 0 ]) in
- let* i4 = index_slice_u32_0_fwd s in
+ let* s = array_to_slice u32 2 (mk_array u32 2 [ 0; 0 ]) in
+ let* i4 = index_slice_u32_0 s in
let* i5 = u32_add i3 i4 in
- let* s0 = array_to_slice_mut_fwd u32 2 (mk_array u32 2 [ 0; 0 ]) in
- let* i6 = index_mut_slice_u32_0_fwd s0 in
+ let* s0 = array_to_slice u32 2 (mk_array u32 2 [ 0; 0 ]) in
+ let* i6 = index_mut_slice_u32_0 s0 in
let* i7 = u32_add i5 i6 in
let* s1 = index_mut_slice_u32_0_back s0 in
- let* _ = array_to_slice_mut_back u32 2 (mk_array u32 2 [ 0; 0 ]) s1 in
+ let* _ = array_from_slice u32 2 (mk_array u32 2 [ 0; 0 ]) s1 in
Return i7
(** [array::update_array]: forward function *)
-let update_array_fwd (x : array u32 2) : result unit =
- let* _ = array_index_mut_back u32 2 x 0 1 in Return ()
+let update_array (x : array u32 2) : result unit =
+ let* _ = array_update_usize u32 2 x 0 1 in Return ()
(** [array::update_array_mut_borrow]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let update_array_mut_borrow_fwd_back (x : array u32 2) : result (array u32 2) =
- array_index_mut_back u32 2 x 0 1
+let update_array_mut_borrow (x : array u32 2) : result (array u32 2) =
+ array_update_usize u32 2 x 0 1
(** [array::update_mut_slice]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let update_mut_slice_fwd_back (x : slice u32) : result (slice u32) =
- slice_index_mut_back u32 x 0 1
+let update_mut_slice (x : slice u32) : result (slice u32) =
+ slice_update_usize u32 x 0 1
(** [array::update_all]: forward function *)
-let update_all_fwd : result unit =
- let* _ = update_array_fwd (mk_array u32 2 [ 0; 0 ]) in
- let* x = update_array_mut_borrow_fwd_back (mk_array u32 2 [ 0; 0 ]) in
- let* s = array_to_slice_mut_fwd u32 2 x in
- let* s0 = update_mut_slice_fwd_back s in
- let* _ = array_to_slice_mut_back u32 2 x s0 in
+let update_all : result unit =
+ let* _ = update_array (mk_array u32 2 [ 0; 0 ]) in
+ let* x = update_array_mut_borrow (mk_array u32 2 [ 0; 0 ]) in
+ let* s = array_to_slice u32 2 x in
+ let* s0 = update_mut_slice s in
+ let* _ = array_from_slice u32 2 x s0 in
Return ()
(** [array::range_all]: forward function *)
-let range_all_fwd : result unit =
+let range_all : result unit =
let* s =
- array_subslice_mut_fwd u32 4 (mk_array u32 4 [ 0; 0; 0; 0 ]) (Mkrange 1 3)
- in
- let* s0 = update_mut_slice_fwd_back s in
+ core_array_Array_index_mut u32 (core_ops_range_Range usize) 4
+ (core_slice_index_Slice_coreopsindexIndexMutInst u32
+ (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32))
+ (mk_array u32 4 [ 0; 0; 0; 0 ]) { start = 1; end_ = 3 } in
+ let* s0 = update_mut_slice s in
let* _ =
- array_subslice_mut_back u32 4 (mk_array u32 4 [ 0; 0; 0; 0 ]) (Mkrange 1 3)
- s0 in
+ core_array_Array_index_mut_back u32 (core_ops_range_Range usize) 4
+ (core_slice_index_Slice_coreopsindexIndexMutInst u32
+ (core_ops_range_Range usize)
+ (core_slice_index_Range_coresliceindexSliceIndexInst u32))
+ (mk_array u32 4 [ 0; 0; 0; 0 ]) { start = 1; end_ = 3 } s0 in
Return ()
(** [array::deref_array_borrow]: forward function *)
-let deref_array_borrow_fwd (x : array u32 2) : result u32 =
- array_index_shared u32 2 x 0
+let deref_array_borrow (x : array u32 2) : result u32 =
+ array_index_usize u32 2 x 0
(** [array::deref_array_mut_borrow]: forward function *)
-let deref_array_mut_borrow_fwd (x : array u32 2) : result u32 =
- array_index_shared u32 2 x 0
+let deref_array_mut_borrow (x : array u32 2) : result u32 =
+ array_index_usize u32 2 x 0
(** [array::deref_array_mut_borrow]: backward function 0 *)
let deref_array_mut_borrow_back (x : array u32 2) : result (array u32 2) =
- let* _ = array_index_shared u32 2 x 0 in Return x
+ let* _ = array_index_usize u32 2 x 0 in Return x
(** [array::take_array_t]: forward function *)
-let take_array_t_fwd (a : array t_t 2) : result unit =
+let take_array_t (a : array aB_t 2) : result unit =
Return ()
(** [array::non_copyable_array]: forward function *)
-let non_copyable_array_fwd : result unit =
- let* _ = take_array_t_fwd (mk_array t_t 2 [ TA; TB ]) in Return ()
+let non_copyable_array : result unit =
+ let* _ = take_array_t (mk_array aB_t 2 [ AB_A; AB_B ]) in Return ()
(** [array::sum]: loop 0: forward function *)
-let rec sum_loop_fwd
- (s : slice u32) (sum : u32) (i : usize) :
- Tot (result u32) (decreases (sum_loop_decreases s sum i))
+let rec sum_loop
+ (s : slice u32) (sum0 : u32) (i : usize) :
+ Tot (result u32) (decreases (sum_loop_decreases s sum0 i))
=
let i0 = slice_len u32 s in
if i < i0
then
- let* i1 = slice_index_shared u32 s i in
- let* sum0 = u32_add sum i1 in
+ let* i1 = slice_index_usize u32 s i in
+ let* sum1 = u32_add sum0 i1 in
let* i2 = usize_add i 1 in
- sum_loop_fwd s sum0 i2
- else Return sum
+ sum_loop s sum1 i2
+ else Return sum0
(** [array::sum]: forward function *)
-let sum_fwd (s : slice u32) : result u32 =
- sum_loop_fwd s 0 0
+let sum (s : slice u32) : result u32 =
+ sum_loop s 0 0
(** [array::sum2]: loop 0: forward function *)
-let rec sum2_loop_fwd
- (s : slice u32) (s2 : slice u32) (sum : u32) (i : usize) :
- Tot (result u32) (decreases (sum2_loop_decreases s s2 sum i))
+let rec sum2_loop
+ (s : slice u32) (s2 : slice u32) (sum0 : u32) (i : usize) :
+ Tot (result u32) (decreases (sum2_loop_decreases s s2 sum0 i))
=
let i0 = slice_len u32 s in
if i < i0
then
- let* i1 = slice_index_shared u32 s i in
- let* i2 = slice_index_shared u32 s2 i in
+ let* i1 = slice_index_usize u32 s i in
+ let* i2 = slice_index_usize u32 s2 i in
let* i3 = u32_add i1 i2 in
- let* sum0 = u32_add sum i3 in
+ let* sum1 = u32_add sum0 i3 in
let* i4 = usize_add i 1 in
- sum2_loop_fwd s s2 sum0 i4
- else Return sum
+ sum2_loop s s2 sum1 i4
+ else Return sum0
(** [array::sum2]: forward function *)
-let sum2_fwd (s : slice u32) (s2 : slice u32) : result u32 =
+let sum2 (s : slice u32) (s2 : slice u32) : result u32 =
let i = slice_len u32 s in
let i0 = slice_len u32 s2 in
- if not (i = i0) then Fail Failure else sum2_loop_fwd s s2 0 0
+ if not (i = i0) then Fail Failure else sum2_loop s s2 0 0
(** [array::f0]: forward function *)
-let f0_fwd : result unit =
- let* s = array_to_slice_mut_fwd u32 2 (mk_array u32 2 [ 1; 2 ]) in
- let* s0 = slice_index_mut_back u32 s 0 1 in
- let* _ = array_to_slice_mut_back u32 2 (mk_array u32 2 [ 1; 2 ]) s0 in
+let f0 : result unit =
+ let* s = array_to_slice u32 2 (mk_array u32 2 [ 1; 2 ]) in
+ let* s0 = slice_update_usize u32 s 0 1 in
+ let* _ = array_from_slice u32 2 (mk_array u32 2 [ 1; 2 ]) s0 in
Return ()
(** [array::f1]: forward function *)
-let f1_fwd : result unit =
- let* _ = array_index_mut_back u32 2 (mk_array u32 2 [ 1; 2 ]) 0 1 in
- Return ()
+let f1 : result unit =
+ let* _ = array_update_usize u32 2 (mk_array u32 2 [ 1; 2 ]) 0 1 in Return ()
(** [array::f2]: forward function *)
-let f2_fwd (i : u32) : result unit =
+let f2 (i : u32) : result unit =
Return ()
(** [array::f4]: forward function *)
-let f4_fwd (x : array u32 32) (y : usize) (z : usize) : result (slice u32) =
- array_subslice_shared u32 32 x (Mkrange y z)
+let f4 (x : array u32 32) (y : usize) (z : usize) : result (slice u32) =
+ core_array_Array_index u32 (core_ops_range_Range usize) 32
+ (core_slice_index_Slice_coreopsindexIndexInst u32 (core_ops_range_Range
+ usize) (core_slice_index_Range_coresliceindexSliceIndexInst u32)) x
+ { start = y; end_ = z }
(** [array::f3]: forward function *)
-let f3_fwd : result u32 =
- let* i = array_index_shared u32 2 (mk_array u32 2 [ 1; 2 ]) 0 in
- let* _ = f2_fwd i in
- let* s = array_to_slice_shared u32 2 (mk_array u32 2 [ 1; 2 ]) in
- let* s0 =
- f4_fwd
- (mk_array u32 32 [
- 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0; 0;
- 0; 0; 0; 0; 0; 0; 0; 0
- ]) 16 18 in
- sum2_fwd s s0
+let f3 : result u32 =
+ let* i = array_index_usize u32 2 (mk_array u32 2 [ 1; 2 ]) 0 in
+ let* _ = f2 i in
+ let b = array_repeat u32 32 0 in
+ let* s = array_to_slice u32 2 (mk_array u32 2 [ 1; 2 ]) in
+ let* s0 = f4 b 16 18 in
+ sum2 s s0
+
+(** [array::SZ] *)
+let sz_body : result usize = Return 32
+let sz_c : usize = eval_global sz_body
+
+(** [array::f5]: forward function *)
+let f5 (x : array u32 32) : result u32 =
+ array_index_usize u32 32 x 0
(** [array::ite]: forward function *)
-let ite_fwd : result unit =
- let* s = array_to_slice_mut_fwd u32 2 (mk_array u32 2 [ 0; 0 ]) in
- let* s0 = array_to_slice_mut_fwd u32 2 (mk_array u32 2 [ 0; 0 ]) in
+let ite : result unit =
+ let* s = array_to_slice u32 2 (mk_array u32 2 [ 0; 0 ]) in
+ let* s0 = array_to_slice u32 2 (mk_array u32 2 [ 0; 0 ]) in
let* s1 = index_mut_slice_u32_0_back s0 in
- let* _ = array_to_slice_mut_back u32 2 (mk_array u32 2 [ 0; 0 ]) s1 in
+ let* _ = array_from_slice u32 2 (mk_array u32 2 [ 0; 0 ]) s1 in
let* s2 = index_mut_slice_u32_0_back s in
- let* _ = array_to_slice_mut_back u32 2 (mk_array u32 2 [ 0; 0 ]) s2 in
+ let* _ = array_from_slice u32 2 (mk_array u32 2 [ 0; 0 ]) s2 in
Return ()
diff --git a/tests/fstar/array/Array.Types.fst b/tests/fstar/array/Array.Types.fst
index 5e8e81d8..4e8d5566 100644
--- a/tests/fstar/array/Array.Types.fst
+++ b/tests/fstar/array/Array.Types.fst
@@ -5,6 +5,6 @@ open Primitives
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
-(** [array::T] *)
-type t_t = | TA : t_t | TB : t_t
+(** [array::AB] *)
+type aB_t = | AB_A : aB_t | AB_B : aB_t
diff --git a/tests/fstar/array/Primitives.fst b/tests/fstar/array/Primitives.fst
index 9db82069..3297803c 100644
--- a/tests/fstar/array/Primitives.fst
+++ b/tests/fstar/array/Primitives.fst
@@ -55,8 +55,12 @@ type string = string
let is_zero (n: nat) : bool = n = 0
let decrease (n: nat{n > 0}) : nat = n - 1
-let mem_replace_fwd (a : Type0) (x : a) (y : a) : a = x
-let mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+let core_mem_replace (a : Type0) (x : a) (y : a) : a = x
+let core_mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+
+// We don't really use raw pointers for now
+type mut_raw_ptr (t : Type0) = { v : t }
+type const_raw_ptr (t : Type0) = { v : t }
(*** Scalars *)
/// Rem.: most of the following code was partially generated
@@ -100,6 +104,11 @@ type scalar_ty =
| U64
| U128
+let is_unsigned = function
+ | Isize | I8 | I16 | I32 | I64 | I128 -> false
+ | Usize | U8 | U16 | U32 | U64 | U128 -> true
+
+
let scalar_min (ty : scalar_ty) : int =
match ty with
| Isize -> isize_min
@@ -162,6 +171,15 @@ let scalar_sub (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scala
let scalar_mul (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
mk_scalar ty (x * y)
+let scalar_lxor (#ty : scalar_ty { is_unsigned ty && ty <> Usize })
+ (x : scalar ty) (y : scalar ty) : scalar ty =
+ match ty with
+ | U8 -> FStar.UInt.logxor #8 x y
+ | U16 -> FStar.UInt.logxor #16 x y
+ | U32 -> FStar.UInt.logxor #32 x y
+ | U64 -> FStar.UInt.logxor #64 x y
+ | U128 -> FStar.UInt.logxor #128 x y
+
(** Cast an integer from a [src_ty] to a [tgt_ty] *)
// TODO: check the semantics of casts in Rust
let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) =
@@ -169,17 +187,44 @@ let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) :
/// The scalar types
type isize : eqtype = scalar Isize
-type i8 : eqtype = scalar I8
-type i16 : eqtype = scalar I16
-type i32 : eqtype = scalar I32
-type i64 : eqtype = scalar I64
-type i128 : eqtype = scalar I128
+type i8 : eqtype = scalar I8
+type i16 : eqtype = scalar I16
+type i32 : eqtype = scalar I32
+type i64 : eqtype = scalar I64
+type i128 : eqtype = scalar I128
type usize : eqtype = scalar Usize
-type u8 : eqtype = scalar U8
-type u16 : eqtype = scalar U16
-type u32 : eqtype = scalar U32
-type u64 : eqtype = scalar U64
-type u128 : eqtype = scalar U128
+type u8 : eqtype = scalar U8
+type u16 : eqtype = scalar U16
+type u32 : eqtype = scalar U32
+type u64 : eqtype = scalar U64
+type u128 : eqtype = scalar U128
+
+
+let core_isize_min : isize = isize_min
+let core_isize_max : isize = isize_max
+let core_i8_min : i8 = i8_min
+let core_i8_max : i8 = i8_max
+let core_i16_min : i16 = i16_min
+let core_i16_max : i16 = i16_max
+let core_i32_min : i32 = i32_min
+let core_i32_max : i32 = i32_max
+let core_i64_min : i64 = i64_min
+let core_i64_max : i64 = i64_max
+let core_i128_min : i128 = i128_min
+let core_i128_max : i128 = i128_max
+
+let core_usize_min : usize = usize_min
+let core_usize_max : usize = usize_max
+let core_u8_min : u8 = u8_min
+let core_u8_max : u8 = u8_max
+let core_u16_min : u16 = u16_min
+let core_u16_max : u16 = u16_max
+let core_u32_min : u32 = u32_min
+let core_u32_max : u32 = u32_max
+let core_u64_min : u64 = u64_min
+let core_u64_max : u64 = u64_max
+let core_u128_min : u128 = u128_min
+let core_u128_max : u128 = u128_max
/// Negation
let isize_neg = scalar_neg #Isize
@@ -231,7 +276,7 @@ let u32_add = scalar_add #U32
let u64_add = scalar_add #U64
let u128_add = scalar_add #U128
-/// Substraction
+/// Subtraction
let isize_sub = scalar_sub #Isize
let i8_sub = scalar_sub #I8
let i16_sub = scalar_sub #I16
@@ -259,12 +304,65 @@ let u32_mul = scalar_mul #U32
let u64_mul = scalar_mul #U64
let u128_mul = scalar_mul #U128
-(*** Range *)
-type range (a : Type0) = {
+/// Logical operators, defined for unsigned types only, so far
+let u8_xor = scalar_lxor #U8
+let u16_xor = scalar_lxor #U16
+let u32_xor = scalar_lxor #U32
+let u64_xor = scalar_lxor #U64
+let u128_xor = scalar_lxor #U128
+
+(*** core::ops *)
+
+// Trait declaration: [core::ops::index::Index]
+noeq type core_ops_index_Index (self idx : Type0) = {
+ output : Type0;
+ index : self → idx → result output
+}
+
+// Trait declaration: [core::ops::index::IndexMut]
+noeq type core_ops_index_IndexMut (self idx : Type0) = {
+ indexInst : core_ops_index_Index self idx;
+ index_mut : self → idx → result indexInst.output;
+ index_mut_back : self → idx → indexInst.output → result self;
+}
+
+// Trait declaration [core::ops::deref::Deref]
+noeq type core_ops_deref_Deref (self : Type0) = {
+ target : Type0;
+ deref : self → result target;
+}
+
+// Trait declaration [core::ops::deref::DerefMut]
+noeq type core_ops_deref_DerefMut (self : Type0) = {
+ derefInst : core_ops_deref_Deref self;
+ deref_mut : self → result derefInst.target;
+ deref_mut_back : self → derefInst.target → result self;
+}
+
+type core_ops_range_Range (a : Type0) = {
start : a;
end_ : a;
}
+(*** [alloc] *)
+
+let alloc_boxed_Box_deref (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut_back (t : Type) (_ : t) (x : t) : result t = Return x
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefInst (self : Type0) : core_ops_deref_Deref self = {
+ target = self;
+ deref = alloc_boxed_Box_deref self;
+}
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefMutInst (self : Type0) : core_ops_deref_DerefMut self = {
+ derefInst = alloc_boxed_Box_coreOpsDerefInst self;
+ deref_mut = alloc_boxed_Box_deref_mut self;
+ deref_mut_back = alloc_boxed_Box_deref_mut_back self;
+}
+
(*** Array *)
type array (a : Type0) (n : usize) = s:list a{length s = n}
@@ -278,15 +376,11 @@ let mk_array (a : Type0) (n : usize)
normalize_term_spec (FStar.List.Tot.length l);
l
-let array_index_shared (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let array_index_mut_fwd (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
+let array_index_usize (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let array_index_mut_back (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
+let array_update_usize (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
if i < length x then Return (list_update x i nx)
else Fail Failure
@@ -295,55 +389,54 @@ type slice (a : Type0) = s:list a{length s <= usize_max}
let slice_len (a : Type0) (s : slice a) : usize = length s
-let slice_index_shared (a : Type0) (x : slice a) (i : usize) : result a =
+let slice_index_usize (a : Type0) (x : slice a) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let slice_index_mut_fwd (a : Type0) (x : slice a) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let slice_index_mut_back (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
+let slice_update_usize (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
if i < length x then Return (list_update x i nx)
else Fail Failure
(*** Subslices *)
-let array_to_slice_shared (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_fwd (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_back (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
+let array_to_slice (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
+let array_from_slice (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
if length s = n then Return s
else Fail Failure
// TODO: finish the definitions below (there lacks [List.drop] and [List.take] in the standard library *)
-let array_subslice_shared (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
- admit()
-
-let array_subslice_mut_fwd (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
+let array_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let array_subslice_mut_back (a : Type0) (n : usize) (x : array a n) (r : range usize) (ns : slice a) : result (array a n) =
+let array_update_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) (ns : slice a) : result (array a n) =
admit()
-let slice_subslice_shared (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let array_repeat (a : Type0) (n : usize) (x : a) : array a n =
admit()
-let slice_subslice_mut_fwd (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let slice_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let slice_subslice_mut_back (a : Type0) (x : slice a) (r : range usize) (ns : slice a) : result (slice a) =
+let slice_update_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) (ns : slice a) : result (slice a) =
admit()
(*** Vector *)
-type vec (a : Type0) = v:list a{length v <= usize_max}
+type alloc_vec_Vec (a : Type0) = v:list a{length v <= usize_max}
-let vec_new (a : Type0) : vec a = assert_norm(length #a [] == 0); []
-let vec_len (a : Type0) (v : vec a) : usize = length v
+let alloc_vec_Vec_new (a : Type0) : alloc_vec_Vec a = assert_norm(length #a [] == 0); []
+let alloc_vec_Vec_len (a : Type0) (v : alloc_vec_Vec a) : usize = length v
+
+// Helper
+let alloc_vec_Vec_index_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) : result a =
+ if i < length v then Return (index v i) else Fail Failure
+// Helper
+let alloc_vec_Vec_update_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
// The **forward** function shouldn't be used
-let vec_push_fwd (a : Type0) (v : vec a) (x : a) : unit = ()
-let vec_push_back (a : Type0) (v : vec a) (x : a) :
- Pure (result (vec a))
+let alloc_vec_Vec_push_fwd (a : Type0) (v : alloc_vec_Vec a) (x : a) : unit = ()
+let alloc_vec_Vec_push (a : Type0) (v : alloc_vec_Vec a) (x : a) :
+ Pure (result (alloc_vec_Vec a))
(requires True)
(ensures (fun res ->
match res with
@@ -358,18 +451,279 @@ let vec_push_back (a : Type0) (v : vec a) (x : a) :
else Fail Failure
// The **forward** function shouldn't be used
-let vec_insert_fwd (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
+let alloc_vec_Vec_insert_fwd (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result unit =
if i < length v then Return () else Fail Failure
-let vec_insert_back (a : Type0) (v : vec a) (i : usize) (x : a) : result (vec a) =
+let alloc_vec_Vec_insert (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
if i < length v then Return (list_update v i x) else Fail Failure
-// The **backward** function shouldn't be used
-let vec_index_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_back (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
- if i < length v then Return () else Fail Failure
+// Trait declaration: [core::slice::index::private_slice_index::Sealed]
+type core_slice_index_private_slice_index_Sealed (self : Type0) = unit
+
+// Trait declaration: [core::slice::index::SliceIndex]
+noeq type core_slice_index_SliceIndex (self t : Type0) = {
+ sealedInst : core_slice_index_private_slice_index_Sealed self;
+ output : Type0;
+ get : self → t → result (option output);
+ get_mut : self → t → result (option output);
+ get_mut_back : self → t → option output → result t;
+ get_unchecked : self → const_raw_ptr t → result (const_raw_ptr output);
+ get_unchecked_mut : self → mut_raw_ptr t → result (mut_raw_ptr output);
+ index : self → t → result output;
+ index_mut : self → t → result output;
+ index_mut_back : self → t → output → result t;
+}
-let vec_index_mut_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_mut_back (a : Type0) (v : vec a) (i : usize) (nx : a) : result (vec a) =
- if i < length v then Return (list_update v i nx) else Fail Failure
+// [core::slice::index::[T]::index]: forward function
+let core_slice_index_Slice_index
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (s : slice t) (i : idx) : result inst.output =
+ let* x = inst.get i s in
+ match x with
+ | None -> Fail Failure
+ | Some x -> Return x
+
+// [core::slice::index::Range:::get]: forward function
+let core_slice_index_Range_get (t : Type0) (i : core_ops_range_Range usize) (s : slice t) :
+ result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: forward function
+let core_slice_index_Range_get_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: backward function 0
+let core_slice_index_Range_get_mut_back
+ (t : Type0) :
+ core_ops_range_Range usize → slice t → option (slice t) → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_unchecked]: forward function
+let core_slice_index_Range_get_unchecked
+ (t : Type0) :
+ core_ops_range_Range usize → const_raw_ptr (slice t) → result (const_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::get_unchecked_mut]: forward function
+let core_slice_index_Range_get_unchecked_mut
+ (t : Type0) :
+ core_ops_range_Range usize → mut_raw_ptr (slice t) → result (mut_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::index]: forward function
+let core_slice_index_Range_index
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: forward function
+let core_slice_index_Range_index_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: backward function 0
+let core_slice_index_Range_index_mut_back
+ (t : Type0) : core_ops_range_Range usize → slice t → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::[T]::index_mut]: forward function
+let core_slice_index_Slice_index_mut
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → result inst.output =
+ admit () //
+
+// [core::slice::index::[T]::index_mut]: backward function 0
+let core_slice_index_Slice_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → inst.output → result (slice t) =
+ admit () // TODO
+
+// [core::array::[T; N]::index]: forward function
+let core_array_Array_index
+ (t idx : Type0) (n : usize) (inst : core_ops_index_Index (slice t) idx)
+ (a : array t n) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: forward function
+let core_array_Array_index_mut
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) : result inst.indexInst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: backward function 0
+let core_array_Array_index_mut_back
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) (x : inst.indexInst.output) : result (array t n) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (slice t) idx = {
+ output = inst.output;
+ index = core_slice_index_Slice_index t idx inst;
+}
+
+// Trait implementation: [core::slice::index::private_slice_index::Range]
+let core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) = ()
+
+// Trait implementation: [core::slice::index::Range]
+let core_slice_index_Range_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ output = slice t;
+ get = core_slice_index_Range_get t;
+ get_mut = core_slice_index_Range_get_mut t;
+ get_mut_back = core_slice_index_Range_get_mut_back t;
+ get_unchecked = core_slice_index_Range_get_unchecked t;
+ get_unchecked_mut = core_slice_index_Range_get_unchecked_mut t;
+ index = core_slice_index_Range_index t;
+ index_mut = core_slice_index_Range_index_mut t;
+ index_mut_back = core_slice_index_Range_index_mut_back t;
+}
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (slice t) idx = {
+ indexInst = core_slice_index_Slice_coreopsindexIndexInst t idx inst;
+ index_mut = core_slice_index_Slice_index_mut t idx inst;
+ index_mut_back = core_slice_index_Slice_index_mut_back t idx inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_Index (slice t) idx) :
+ core_ops_index_Index (array t n) idx = {
+ output = inst.output;
+ index = core_array_Array_index t idx n inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexMutInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_IndexMut (slice t) idx) :
+ core_ops_index_IndexMut (array t n) idx = {
+ indexInst = core_array_Array_coreopsindexIndexInst t idx n inst.indexInst;
+ index_mut = core_array_Array_index_mut t idx n inst;
+ index_mut_back = core_array_Array_index_mut_back t idx n inst;
+}
+
+// [core::slice::index::usize::get]: forward function
+let core_slice_index_usize_get
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: forward function
+let core_slice_index_usize_get_mut
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: backward function 0
+let core_slice_index_usize_get_mut_back
+ (t : Type0) : usize → slice t → option t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked]: forward function
+let core_slice_index_usize_get_unchecked
+ (t : Type0) : usize → const_raw_ptr (slice t) → result (const_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked_mut]: forward function
+let core_slice_index_usize_get_unchecked_mut
+ (t : Type0) : usize → mut_raw_ptr (slice t) → result (mut_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::index]: forward function
+let core_slice_index_usize_index (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: forward function
+let core_slice_index_usize_index_mut (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: backward function 0
+let core_slice_index_usize_index_mut_back
+ (t : Type0) : usize → slice t → t → result (slice t) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::private_slice_index::usize]
+let core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize = ()
+
+// Trait implementation: [core::slice::index::usize]
+let core_slice_index_usize_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex usize (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ output = t;
+ get = core_slice_index_usize_get t;
+ get_mut = core_slice_index_usize_get_mut t;
+ get_mut_back = core_slice_index_usize_get_mut_back t;
+ get_unchecked = core_slice_index_usize_get_unchecked t;
+ get_unchecked_mut = core_slice_index_usize_get_unchecked_mut t;
+ index = core_slice_index_usize_index t;
+ index_mut = core_slice_index_usize_index_mut t;
+ index_mut_back = core_slice_index_usize_index_mut_back t;
+}
+
+// [alloc::vec::Vec::index]: forward function
+let alloc_vec_Vec_index (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: forward function
+let alloc_vec_Vec_index_mut (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: backward function 0
+let alloc_vec_Vec_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) (x : inst.output) : result (alloc_vec_Vec t) =
+ admit () // TODO
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (alloc_vec_Vec t) idx = {
+ output = inst.output;
+ index = alloc_vec_Vec_index t idx inst;
+}
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (alloc_vec_Vec t) idx = {
+ indexInst = alloc_vec_Vec_coreopsindexIndexInst t idx inst;
+ index_mut = alloc_vec_Vec_index_mut t idx inst;
+ index_mut_back = alloc_vec_Vec_index_mut_back t idx inst;
+}
+
+(*** Theorems *)
+
+let alloc_vec_Vec_index_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_back_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) :
+ Lemma (
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x ==
+ alloc_vec_Vec_update_usize v i x)
+ [SMTPat (alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x)]
+ =
+ admit()
diff --git a/tests/fstar/betree/BetreeMain.Clauses.Template.fst b/tests/fstar/betree/BetreeMain.Clauses.Template.fst
index 823df03a..8722f0bf 100644
--- a/tests/fstar/betree/BetreeMain.Clauses.Template.fst
+++ b/tests/fstar/betree/BetreeMain.Clauses.Template.fst
@@ -8,95 +8,95 @@ open BetreeMain.Types
(** [betree_main::betree::List::{1}::len]: decreases clause *)
unfold
-let betree_list_len_decreases (t : Type0) (self : betree_list_t t) : nat =
+let betree_List_len_decreases (t : Type0) (self : betree_List_t t) : nat =
admit ()
(** [betree_main::betree::List::{1}::split_at]: decreases clause *)
unfold
-let betree_list_split_at_decreases (t : Type0) (self : betree_list_t t)
+let betree_List_split_at_decreases (t : Type0) (self : betree_List_t t)
(n : u64) : nat =
admit ()
(** [betree_main::betree::List::{2}::partition_at_pivot]: decreases clause *)
unfold
-let betree_list_partition_at_pivot_decreases (t : Type0)
- (self : betree_list_t (u64 & t)) (pivot : u64) : nat =
+let betree_List_partition_at_pivot_decreases (t : Type0)
+ (self : betree_List_t (u64 & t)) (pivot : u64) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: decreases clause *)
unfold
-let betree_node_lookup_first_message_for_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_lookup_first_message_for_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::apply_upserts]: decreases clause *)
unfold
-let betree_node_apply_upserts_decreases
- (msgs : betree_list_t (u64 & betree_message_t)) (prev : option u64)
+let betree_Node_apply_upserts_decreases
+ (msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
(key : u64) (st : state) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup_in_bindings]: decreases clause *)
unfold
-let betree_node_lookup_in_bindings_decreases (key : u64)
- (bindings : betree_list_t (u64 & u64)) : nat =
+let betree_Node_lookup_in_bindings_decreases (key : u64)
+ (bindings : betree_List_t (u64 & u64)) : nat =
admit ()
(** [betree_main::betree::Internal::{4}::lookup_in_children]: decreases clause *)
unfold
-let betree_internal_lookup_in_children_decreases (self : betree_internal_t)
+let betree_Internal_lookup_in_children_decreases (self : betree_Internal_t)
(key : u64) (st : state) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup]: decreases clause *)
unfold
-let betree_node_lookup_decreases (self : betree_node_t) (key : u64)
+let betree_Node_lookup_decreases (self : betree_Node_t) (key : u64)
(st : state) : nat =
admit ()
(** [betree_main::betree::Node::{5}::filter_messages_for_key]: decreases clause *)
unfold
-let betree_node_filter_messages_for_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_filter_messages_for_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: decreases clause *)
unfold
-let betree_node_lookup_first_message_after_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_lookup_first_message_after_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::apply_messages_to_internal]: decreases clause *)
unfold
-let betree_node_apply_messages_to_internal_decreases
- (msgs : betree_list_t (u64 & betree_message_t))
- (new_msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_apply_messages_to_internal_decreases
+ (msgs : betree_List_t (u64 & betree_Message_t))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: decreases clause *)
unfold
-let betree_node_lookup_mut_in_bindings_decreases (key : u64)
- (bindings : betree_list_t (u64 & u64)) : nat =
+let betree_Node_lookup_mut_in_bindings_decreases (key : u64)
+ (bindings : betree_List_t (u64 & u64)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::apply_messages_to_leaf]: decreases clause *)
unfold
-let betree_node_apply_messages_to_leaf_decreases
- (bindings : betree_list_t (u64 & u64))
- (new_msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_apply_messages_to_leaf_decreases
+ (bindings : betree_List_t (u64 & u64))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Internal::{4}::flush]: decreases clause *)
unfold
-let betree_internal_flush_decreases (self : betree_internal_t)
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) : nat =
+let betree_Internal_flush_decreases (self : betree_Internal_t)
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) : nat =
admit ()
(** [betree_main::betree::Node::{5}::apply_messages]: decreases clause *)
unfold
-let betree_node_apply_messages_decreases (self : betree_node_t)
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) : nat =
+let betree_Node_apply_messages_decreases (self : betree_Node_t)
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) : nat =
admit ()
diff --git a/tests/fstar/betree/BetreeMain.Clauses.fst b/tests/fstar/betree/BetreeMain.Clauses.fst
index 07484711..cda7b920 100644
--- a/tests/fstar/betree/BetreeMain.Clauses.fst
+++ b/tests/fstar/betree/BetreeMain.Clauses.fst
@@ -8,8 +8,8 @@ open BetreeMain.Types
(*** Well-founded relations *)
(* We had a few issues when proving termination of the mutually recursive functions:
- * - betree_internal_flush
- * - betree_node_apply_messages
+ * - betree_Internal_flush
+ * - betree_Node_apply_messages
*
* The quantity which effectively decreases is:
* (betree_size, messages_length)
@@ -103,108 +103,108 @@ let wf_nat_pair_lem (p0 p1 : nat_pair) :
(** [betree_main::betree::List::{1}::len]: decreases clause *)
unfold
-let betree_list_len_decreases (t : Type0) (self : betree_list_t t) : betree_list_t t =
+let betree_List_len_decreases (t : Type0) (self : betree_List_t t) : betree_List_t t =
self
(** [betree_main::betree::List::{1}::split_at]: decreases clause *)
unfold
-let betree_list_split_at_decreases (t : Type0) (self : betree_list_t t)
+let betree_List_split_at_decreases (t : Type0) (self : betree_List_t t)
(n : u64) : nat =
n
(** [betree_main::betree::List::{2}::partition_at_pivot]: decreases clause *)
unfold
-let betree_list_partition_at_pivot_decreases (t : Type0)
- (self : betree_list_t (u64 & t)) (pivot : u64) : betree_list_t (u64 & t) =
+let betree_List_partition_at_pivot_decreases (t : Type0)
+ (self : betree_List_t (u64 & t)) (pivot : u64) : betree_List_t (u64 & t) =
self
(** [betree_main::betree::Node::{5}::lookup_in_bindings]: decreases clause *)
unfold
-let betree_node_lookup_in_bindings_decreases (key : u64)
- (bindings : betree_list_t (u64 & u64)) : betree_list_t (u64 & u64) =
+let betree_Node_lookup_in_bindings_decreases (key : u64)
+ (bindings : betree_List_t (u64 & u64)) : betree_List_t (u64 & u64) =
bindings
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: decreases clause *)
unfold
-let betree_node_lookup_first_message_for_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_lookup_first_message_for_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Node::{5}::apply_upserts]: decreases clause *)
unfold
-let betree_node_apply_upserts_decreases
- (msgs : betree_list_t (u64 & betree_message_t)) (prev : option u64)
- (key : u64) (st : state) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_apply_upserts_decreases
+ (msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
+ (key : u64) (st : state) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Internal::{4}::lookup_in_children]: decreases clause *)
unfold
-let betree_internal_lookup_in_children_decreases (self : betree_internal_t)
- (key : u64) (st : state) : betree_internal_t =
+let betree_Internal_lookup_in_children_decreases (self : betree_Internal_t)
+ (key : u64) (st : state) : betree_Internal_t =
self
(** [betree_main::betree::Node::{5}::lookup]: decreases clause *)
unfold
-let betree_node_lookup_decreases (self : betree_node_t) (key : u64)
- (st : state) : betree_node_t =
+let betree_Node_lookup_decreases (self : betree_Node_t) (key : u64)
+ (st : state) : betree_Node_t =
self
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: decreases clause *)
unfold
-let betree_node_lookup_mut_in_bindings_decreases (key : u64)
- (bindings : betree_list_t (u64 & u64)) : betree_list_t (u64 & u64) =
+let betree_Node_lookup_mut_in_bindings_decreases (key : u64)
+ (bindings : betree_List_t (u64 & u64)) : betree_List_t (u64 & u64) =
bindings
unfold
-let betree_node_apply_messages_to_leaf_decreases
- (bindings : betree_list_t (u64 & u64))
- (new_msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_apply_messages_to_leaf_decreases
+ (bindings : betree_List_t (u64 & u64))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
new_msgs
(** [betree_main::betree::Node::{5}::filter_messages_for_key]: decreases clause *)
unfold
-let betree_node_filter_messages_for_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_filter_messages_for_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: decreases clause *)
unfold
-let betree_node_lookup_first_message_after_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_lookup_first_message_after_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
-let betree_node_apply_messages_to_internal_decreases
- (msgs : betree_list_t (u64 & betree_message_t))
- (new_msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_apply_messages_to_internal_decreases
+ (msgs : betree_List_t (u64 & betree_Message_t))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
new_msgs
(*** Decrease clauses - nat_pair *)
/// The following decrease clauses use the [nat_pair] definition and the well-founded
/// relation proven above.
-let rec betree_size (bt : betree_node_t) : nat =
+let rec betree_size (bt : betree_Node_t) : nat =
match bt with
- | BetreeNodeInternal node -> 1 + betree_internal_size node
- | BetreeNodeLeaf _ -> 1
+ | Betree_Node_Internal node -> 1 + betree_Internal_size node
+ | Betree_Node_Leaf _ -> 1
-and betree_internal_size (node : betree_internal_t) : nat =
- 1 + betree_size node.betree_internal_left + betree_size node.betree_internal_right
+and betree_Internal_size (node : betree_Internal_t) : nat =
+ 1 + betree_size node.left + betree_size node.right
-let rec betree_list_len (#a : Type0) (ls : betree_list_t a) : nat =
+let rec betree_List_len (#a : Type0) (ls : betree_List_t a) : nat =
match ls with
- | BetreeListCons _ tl -> 1 + betree_list_len tl
- | BetreeListNil -> 0
+ | Betree_List_Cons _ tl -> 1 + betree_List_len tl
+ | Betree_List_Nil -> 0
(** [betree_main::betree::Internal::{4}::flush]: decreases clause *)
unfold
-let betree_internal_flush_decreases (self : betree_internal_t)
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) : nat_pair =
- (|betree_internal_size self, 0|)
+let betree_Internal_flush_decreases (self : betree_Internal_t)
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) : nat_pair =
+ (|betree_Internal_size self, 0|)
(** [betree_main::betree::Node::{5}::apply_messages]: decreases clause *)
unfold
-let betree_node_apply_messages_decreases (self : betree_node_t)
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) : nat_pair =
- (|betree_size self, betree_list_len msgs|)
+let betree_Node_apply_messages_decreases (self : betree_Node_t)
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) : nat_pair =
+ (|betree_size self, betree_List_len msgs|)
diff --git a/tests/fstar/betree/BetreeMain.Funs.fst b/tests/fstar/betree/BetreeMain.Funs.fst
index 847dc865..d2bf5c7c 100644
--- a/tests/fstar/betree/BetreeMain.Funs.fst
+++ b/tests/fstar/betree/BetreeMain.Funs.fst
@@ -9,35 +9,35 @@ include BetreeMain.Clauses
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [betree_main::betree::load_internal_node]: forward function *)
-let betree_load_internal_node_fwd
+let betree_load_internal_node
(id : u64) (st : state) :
- result (state & (betree_list_t (u64 & betree_message_t)))
+ result (state & (betree_List_t (u64 & betree_Message_t)))
=
- betree_utils_load_internal_node_fwd id st
+ betree_utils_load_internal_node id st
(** [betree_main::betree::store_internal_node]: forward function *)
-let betree_store_internal_node_fwd
- (id : u64) (content : betree_list_t (u64 & betree_message_t)) (st : state) :
+let betree_store_internal_node
+ (id : u64) (content : betree_List_t (u64 & betree_Message_t)) (st : state) :
result (state & unit)
=
- let* (st0, _) = betree_utils_store_internal_node_fwd id content st in
+ let* (st0, _) = betree_utils_store_internal_node id content st in
Return (st0, ())
(** [betree_main::betree::load_leaf_node]: forward function *)
-let betree_load_leaf_node_fwd
- (id : u64) (st : state) : result (state & (betree_list_t (u64 & u64))) =
- betree_utils_load_leaf_node_fwd id st
+let betree_load_leaf_node
+ (id : u64) (st : state) : result (state & (betree_List_t (u64 & u64))) =
+ betree_utils_load_leaf_node id st
(** [betree_main::betree::store_leaf_node]: forward function *)
-let betree_store_leaf_node_fwd
- (id : u64) (content : betree_list_t (u64 & u64)) (st : state) :
+let betree_store_leaf_node
+ (id : u64) (content : betree_List_t (u64 & u64)) (st : state) :
result (state & unit)
=
- let* (st0, _) = betree_utils_store_leaf_node_fwd id content st in
+ let* (st0, _) = betree_utils_store_leaf_node id content st in
Return (st0, ())
(** [betree_main::betree::fresh_node_id]: forward function *)
-let betree_fresh_node_id_fwd (counter : u64) : result u64 =
+let betree_fresh_node_id (counter : u64) : result u64 =
let* _ = u64_add counter 1 in Return counter
(** [betree_main::betree::fresh_node_id]: backward function 0 *)
@@ -45,976 +45,909 @@ let betree_fresh_node_id_back (counter : u64) : result u64 =
u64_add counter 1
(** [betree_main::betree::NodeIdCounter::{0}::new]: forward function *)
-let betree_node_id_counter_new_fwd : result betree_node_id_counter_t =
- Return { betree_node_id_counter_next_node_id = 0 }
+let betree_NodeIdCounter_new : result betree_NodeIdCounter_t =
+ Return { next_node_id = 0 }
(** [betree_main::betree::NodeIdCounter::{0}::fresh_id]: forward function *)
-let betree_node_id_counter_fresh_id_fwd
- (self : betree_node_id_counter_t) : result u64 =
- let* _ = u64_add self.betree_node_id_counter_next_node_id 1 in
- Return self.betree_node_id_counter_next_node_id
+let betree_NodeIdCounter_fresh_id
+ (self : betree_NodeIdCounter_t) : result u64 =
+ let* _ = u64_add self.next_node_id 1 in Return self.next_node_id
(** [betree_main::betree::NodeIdCounter::{0}::fresh_id]: backward function 0 *)
-let betree_node_id_counter_fresh_id_back
- (self : betree_node_id_counter_t) : result betree_node_id_counter_t =
- let* i = u64_add self.betree_node_id_counter_next_node_id 1 in
- Return { betree_node_id_counter_next_node_id = i }
-
-(** [core::num::u64::{9}::MAX] *)
-let core_num_u64_max_body : result u64 = Return 18446744073709551615
-let core_num_u64_max_c : u64 = eval_global core_num_u64_max_body
+let betree_NodeIdCounter_fresh_id_back
+ (self : betree_NodeIdCounter_t) : result betree_NodeIdCounter_t =
+ let* i = u64_add self.next_node_id 1 in Return { next_node_id = i }
(** [betree_main::betree::upsert_update]: forward function *)
-let betree_upsert_update_fwd
- (prev : option u64) (st : betree_upsert_fun_state_t) : result u64 =
+let betree_upsert_update
+ (prev : option u64) (st : betree_UpsertFunState_t) : result u64 =
begin match prev with
| None ->
begin match st with
- | BetreeUpsertFunStateAdd v -> Return v
- | BetreeUpsertFunStateSub i -> Return 0
+ | Betree_UpsertFunState_Add v -> Return v
+ | Betree_UpsertFunState_Sub i -> Return 0
end
| Some prev0 ->
begin match st with
- | BetreeUpsertFunStateAdd v ->
- let* margin = u64_sub core_num_u64_max_c prev0 in
- if margin >= v then u64_add prev0 v else Return core_num_u64_max_c
- | BetreeUpsertFunStateSub v ->
+ | Betree_UpsertFunState_Add v ->
+ let* margin = u64_sub core_u64_max prev0 in
+ if margin >= v then u64_add prev0 v else Return core_u64_max
+ | Betree_UpsertFunState_Sub v ->
if prev0 >= v then u64_sub prev0 v else Return 0
end
end
(** [betree_main::betree::List::{1}::len]: forward function *)
-let rec betree_list_len_fwd
- (t : Type0) (self : betree_list_t t) :
- Tot (result u64) (decreases (betree_list_len_decreases t self))
+let rec betree_List_len
+ (t : Type0) (self : betree_List_t t) :
+ Tot (result u64) (decreases (betree_List_len_decreases t self))
=
begin match self with
- | BetreeListCons x tl -> let* i = betree_list_len_fwd t tl in u64_add 1 i
- | BetreeListNil -> Return 0
+ | Betree_List_Cons x tl -> let* i = betree_List_len t tl in u64_add 1 i
+ | Betree_List_Nil -> Return 0
end
(** [betree_main::betree::List::{1}::split_at]: forward function *)
-let rec betree_list_split_at_fwd
- (t : Type0) (self : betree_list_t t) (n : u64) :
- Tot (result ((betree_list_t t) & (betree_list_t t)))
- (decreases (betree_list_split_at_decreases t self n))
+let rec betree_List_split_at
+ (t : Type0) (self : betree_List_t t) (n : u64) :
+ Tot (result ((betree_List_t t) & (betree_List_t t)))
+ (decreases (betree_List_split_at_decreases t self n))
=
if n = 0
- then Return (BetreeListNil, self)
+ then Return (Betree_List_Nil, self)
else
begin match self with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let* i = u64_sub n 1 in
- let* p = betree_list_split_at_fwd t tl i in
+ let* p = betree_List_split_at t tl i in
let (ls0, ls1) = p in
let l = ls0 in
- Return (BetreeListCons hd l, ls1)
- | BetreeListNil -> Fail Failure
+ Return (Betree_List_Cons hd l, ls1)
+ | Betree_List_Nil -> Fail Failure
end
(** [betree_main::betree::List::{1}::push_front]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let betree_list_push_front_fwd_back
- (t : Type0) (self : betree_list_t t) (x : t) : result (betree_list_t t) =
- let tl = mem_replace_fwd (betree_list_t t) self BetreeListNil in
+let betree_List_push_front
+ (t : Type0) (self : betree_List_t t) (x : t) : result (betree_List_t t) =
+ let tl = core_mem_replace (betree_List_t t) self Betree_List_Nil in
let l = tl in
- Return (BetreeListCons x l)
+ Return (Betree_List_Cons x l)
(** [betree_main::betree::List::{1}::pop_front]: forward function *)
-let betree_list_pop_front_fwd (t : Type0) (self : betree_list_t t) : result t =
- let ls = mem_replace_fwd (betree_list_t t) self BetreeListNil in
+let betree_List_pop_front (t : Type0) (self : betree_List_t t) : result t =
+ let ls = core_mem_replace (betree_List_t t) self Betree_List_Nil in
begin match ls with
- | BetreeListCons x tl -> Return x
- | BetreeListNil -> Fail Failure
+ | Betree_List_Cons x tl -> Return x
+ | Betree_List_Nil -> Fail Failure
end
(** [betree_main::betree::List::{1}::pop_front]: backward function 0 *)
-let betree_list_pop_front_back
- (t : Type0) (self : betree_list_t t) : result (betree_list_t t) =
- let ls = mem_replace_fwd (betree_list_t t) self BetreeListNil in
+let betree_List_pop_front_back
+ (t : Type0) (self : betree_List_t t) : result (betree_List_t t) =
+ let ls = core_mem_replace (betree_List_t t) self Betree_List_Nil in
begin match ls with
- | BetreeListCons x tl -> Return tl
- | BetreeListNil -> Fail Failure
+ | Betree_List_Cons x tl -> Return tl
+ | Betree_List_Nil -> Fail Failure
end
(** [betree_main::betree::List::{1}::hd]: forward function *)
-let betree_list_hd_fwd (t : Type0) (self : betree_list_t t) : result t =
+let betree_List_hd (t : Type0) (self : betree_List_t t) : result t =
begin match self with
- | BetreeListCons hd l -> Return hd
- | BetreeListNil -> Fail Failure
+ | Betree_List_Cons hd l -> Return hd
+ | Betree_List_Nil -> Fail Failure
end
(** [betree_main::betree::List::{2}::head_has_key]: forward function *)
-let betree_list_head_has_key_fwd
- (t : Type0) (self : betree_list_t (u64 & t)) (key : u64) : result bool =
+let betree_List_head_has_key
+ (t : Type0) (self : betree_List_t (u64 & t)) (key : u64) : result bool =
begin match self with
- | BetreeListCons hd l -> let (i, _) = hd in Return (i = key)
- | BetreeListNil -> Return false
+ | Betree_List_Cons hd l -> let (i, _) = hd in Return (i = key)
+ | Betree_List_Nil -> Return false
end
(** [betree_main::betree::List::{2}::partition_at_pivot]: forward function *)
-let rec betree_list_partition_at_pivot_fwd
- (t : Type0) (self : betree_list_t (u64 & t)) (pivot : u64) :
- Tot (result ((betree_list_t (u64 & t)) & (betree_list_t (u64 & t))))
- (decreases (betree_list_partition_at_pivot_decreases t self pivot))
+let rec betree_List_partition_at_pivot
+ (t : Type0) (self : betree_List_t (u64 & t)) (pivot : u64) :
+ Tot (result ((betree_List_t (u64 & t)) & (betree_List_t (u64 & t))))
+ (decreases (betree_List_partition_at_pivot_decreases t self pivot))
=
begin match self with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let (i, x) = hd in
if i >= pivot
- then Return (BetreeListNil, BetreeListCons (i, x) tl)
+ then Return (Betree_List_Nil, Betree_List_Cons (i, x) tl)
else
- let* p = betree_list_partition_at_pivot_fwd t tl pivot in
+ let* p = betree_List_partition_at_pivot t tl pivot in
let (ls0, ls1) = p in
let l = ls0 in
- Return (BetreeListCons (i, x) l, ls1)
- | BetreeListNil -> Return (BetreeListNil, BetreeListNil)
+ Return (Betree_List_Cons (i, x) l, ls1)
+ | Betree_List_Nil -> Return (Betree_List_Nil, Betree_List_Nil)
end
(** [betree_main::betree::Leaf::{3}::split]: forward function *)
-let betree_leaf_split_fwd
- (self : betree_leaf_t) (content : betree_list_t (u64 & u64))
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
+let betree_Leaf_split
+ (self : betree_Leaf_t) (content : betree_List_t (u64 & u64))
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(st : state) :
- result (state & betree_internal_t)
+ result (state & betree_Internal_t)
=
- let* p =
- betree_list_split_at_fwd (u64 & u64) content
- params.betree_params_split_size in
+ let* p = betree_List_split_at (u64 & u64) content params.split_size in
let (content0, content1) = p in
- let* p0 = betree_list_hd_fwd (u64 & u64) content1 in
+ let* p0 = betree_List_hd (u64 & u64) content1 in
let (pivot, _) = p0 in
- let* id0 = betree_node_id_counter_fresh_id_fwd node_id_cnt in
- let* node_id_cnt0 = betree_node_id_counter_fresh_id_back node_id_cnt in
- let* id1 = betree_node_id_counter_fresh_id_fwd node_id_cnt0 in
- let* (st0, _) = betree_store_leaf_node_fwd id0 content0 st in
- let* (st1, _) = betree_store_leaf_node_fwd id1 content1 st0 in
- let n = BetreeNodeLeaf
- { betree_leaf_id = id0; betree_leaf_size = params.betree_params_split_size
- } in
- let n0 = BetreeNodeLeaf
- { betree_leaf_id = id1; betree_leaf_size = params.betree_params_split_size
- } in
- Return (st1,
- {
- betree_internal_id = self.betree_leaf_id;
- betree_internal_pivot = pivot;
- betree_internal_left = n;
- betree_internal_right = n0
- })
+ let* id0 = betree_NodeIdCounter_fresh_id node_id_cnt in
+ let* node_id_cnt0 = betree_NodeIdCounter_fresh_id_back node_id_cnt in
+ let* id1 = betree_NodeIdCounter_fresh_id node_id_cnt0 in
+ let* (st0, _) = betree_store_leaf_node id0 content0 st in
+ let* (st1, _) = betree_store_leaf_node id1 content1 st0 in
+ let n = Betree_Node_Leaf { id = id0; size = params.split_size } in
+ let n0 = Betree_Node_Leaf { id = id1; size = params.split_size } in
+ Return (st1, { id = self.id; pivot = pivot; left = n; right = n0 })
(** [betree_main::betree::Leaf::{3}::split]: backward function 2 *)
-let betree_leaf_split_back
- (self : betree_leaf_t) (content : betree_list_t (u64 & u64))
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
+let betree_Leaf_split_back
+ (self : betree_Leaf_t) (content : betree_List_t (u64 & u64))
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(st : state) :
- result betree_node_id_counter_t
+ result betree_NodeIdCounter_t
=
- let* p =
- betree_list_split_at_fwd (u64 & u64) content
- params.betree_params_split_size in
+ let* p = betree_List_split_at (u64 & u64) content params.split_size in
let (content0, content1) = p in
- let* _ = betree_list_hd_fwd (u64 & u64) content1 in
- let* id0 = betree_node_id_counter_fresh_id_fwd node_id_cnt in
- let* node_id_cnt0 = betree_node_id_counter_fresh_id_back node_id_cnt in
- let* id1 = betree_node_id_counter_fresh_id_fwd node_id_cnt0 in
- let* (st0, _) = betree_store_leaf_node_fwd id0 content0 st in
- let* _ = betree_store_leaf_node_fwd id1 content1 st0 in
- betree_node_id_counter_fresh_id_back node_id_cnt0
+ let* _ = betree_List_hd (u64 & u64) content1 in
+ let* id0 = betree_NodeIdCounter_fresh_id node_id_cnt in
+ let* node_id_cnt0 = betree_NodeIdCounter_fresh_id_back node_id_cnt in
+ let* id1 = betree_NodeIdCounter_fresh_id node_id_cnt0 in
+ let* (st0, _) = betree_store_leaf_node id0 content0 st in
+ let* _ = betree_store_leaf_node id1 content1 st0 in
+ betree_NodeIdCounter_fresh_id_back node_id_cnt0
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: forward function *)
-let rec betree_node_lookup_first_message_for_key_fwd
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_lookup_first_message_for_key_decreases key msgs))
+let rec betree_Node_lookup_first_message_for_key
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_lookup_first_message_for_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons x next_msgs ->
+ | Betree_List_Cons x next_msgs ->
let (i, m) = x in
if i >= key
- then Return (BetreeListCons (i, m) next_msgs)
- else betree_node_lookup_first_message_for_key_fwd key next_msgs
- | BetreeListNil -> Return BetreeListNil
+ then Return (Betree_List_Cons (i, m) next_msgs)
+ else betree_Node_lookup_first_message_for_key key next_msgs
+ | Betree_List_Nil -> Return Betree_List_Nil
end
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: backward function 0 *)
-let rec betree_node_lookup_first_message_for_key_back
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t))
- (ret : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_lookup_first_message_for_key_decreases key msgs))
+let rec betree_Node_lookup_first_message_for_key_back
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t))
+ (ret : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_lookup_first_message_for_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons x next_msgs ->
+ | Betree_List_Cons x next_msgs ->
let (i, m) = x in
if i >= key
then Return ret
else
let* next_msgs0 =
- betree_node_lookup_first_message_for_key_back key next_msgs ret in
- Return (BetreeListCons (i, m) next_msgs0)
- | BetreeListNil -> Return ret
+ betree_Node_lookup_first_message_for_key_back key next_msgs ret in
+ Return (Betree_List_Cons (i, m) next_msgs0)
+ | Betree_List_Nil -> Return ret
end
(** [betree_main::betree::Node::{5}::apply_upserts]: forward function *)
-let rec betree_node_apply_upserts_fwd
- (msgs : betree_list_t (u64 & betree_message_t)) (prev : option u64)
+let rec betree_Node_apply_upserts
+ (msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
(key : u64) (st : state) :
Tot (result (state & u64))
- (decreases (betree_node_apply_upserts_decreases msgs prev key st))
+ (decreases (betree_Node_apply_upserts_decreases msgs prev key st))
=
- let* b = betree_list_head_has_key_fwd betree_message_t msgs key in
+ let* b = betree_List_head_has_key betree_Message_t msgs key in
if b
then
- let* msg = betree_list_pop_front_fwd (u64 & betree_message_t) msgs in
+ let* msg = betree_List_pop_front (u64 & betree_Message_t) msgs in
let (_, m) = msg in
begin match m with
- | BetreeMessageInsert i -> Fail Failure
- | BetreeMessageDelete -> Fail Failure
- | BetreeMessageUpsert s ->
- let* v = betree_upsert_update_fwd prev s in
- let* msgs0 = betree_list_pop_front_back (u64 & betree_message_t) msgs in
- betree_node_apply_upserts_fwd msgs0 (Some v) key st
+ | Betree_Message_Insert i -> Fail Failure
+ | Betree_Message_Delete -> Fail Failure
+ | Betree_Message_Upsert s ->
+ let* v = betree_upsert_update prev s in
+ let* msgs0 = betree_List_pop_front_back (u64 & betree_Message_t) msgs in
+ betree_Node_apply_upserts msgs0 (Some v) key st
end
else
- let* (st0, v) = core_option_option_unwrap_fwd u64 prev st in
+ let* (st0, v) = core_option_Option_unwrap u64 prev st in
let* _ =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs (key,
- BetreeMessageInsert v) in
+ betree_List_push_front (u64 & betree_Message_t) msgs (key,
+ Betree_Message_Insert v) in
Return (st0, v)
(** [betree_main::betree::Node::{5}::apply_upserts]: backward function 0 *)
-let rec betree_node_apply_upserts_back
- (msgs : betree_list_t (u64 & betree_message_t)) (prev : option u64)
+let rec betree_Node_apply_upserts_back
+ (msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
(key : u64) (st : state) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_apply_upserts_decreases msgs prev key st))
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_apply_upserts_decreases msgs prev key st))
=
- let* b = betree_list_head_has_key_fwd betree_message_t msgs key in
+ let* b = betree_List_head_has_key betree_Message_t msgs key in
if b
then
- let* msg = betree_list_pop_front_fwd (u64 & betree_message_t) msgs in
+ let* msg = betree_List_pop_front (u64 & betree_Message_t) msgs in
let (_, m) = msg in
begin match m with
- | BetreeMessageInsert i -> Fail Failure
- | BetreeMessageDelete -> Fail Failure
- | BetreeMessageUpsert s ->
- let* v = betree_upsert_update_fwd prev s in
- let* msgs0 = betree_list_pop_front_back (u64 & betree_message_t) msgs in
- betree_node_apply_upserts_back msgs0 (Some v) key st
+ | Betree_Message_Insert i -> Fail Failure
+ | Betree_Message_Delete -> Fail Failure
+ | Betree_Message_Upsert s ->
+ let* v = betree_upsert_update prev s in
+ let* msgs0 = betree_List_pop_front_back (u64 & betree_Message_t) msgs in
+ betree_Node_apply_upserts_back msgs0 (Some v) key st
end
else
- let* (_, v) = core_option_option_unwrap_fwd u64 prev st in
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs (key,
- BetreeMessageInsert v)
+ let* (_, v) = core_option_Option_unwrap u64 prev st in
+ betree_List_push_front (u64 & betree_Message_t) msgs (key,
+ Betree_Message_Insert v)
(** [betree_main::betree::Node::{5}::lookup_in_bindings]: forward function *)
-let rec betree_node_lookup_in_bindings_fwd
- (key : u64) (bindings : betree_list_t (u64 & u64)) :
+let rec betree_Node_lookup_in_bindings
+ (key : u64) (bindings : betree_List_t (u64 & u64)) :
Tot (result (option u64))
- (decreases (betree_node_lookup_in_bindings_decreases key bindings))
+ (decreases (betree_Node_lookup_in_bindings_decreases key bindings))
=
begin match bindings with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let (i, i0) = hd in
if i = key
then Return (Some i0)
- else
- if i > key
- then Return None
- else betree_node_lookup_in_bindings_fwd key tl
- | BetreeListNil -> Return None
+ else if i > key then Return None else betree_Node_lookup_in_bindings key tl
+ | Betree_List_Nil -> Return None
end
(** [betree_main::betree::Internal::{4}::lookup_in_children]: forward function *)
-let rec betree_internal_lookup_in_children_fwd
- (self : betree_internal_t) (key : u64) (st : state) :
+let rec betree_Internal_lookup_in_children
+ (self : betree_Internal_t) (key : u64) (st : state) :
Tot (result (state & (option u64)))
- (decreases (betree_internal_lookup_in_children_decreases self key st))
+ (decreases (betree_Internal_lookup_in_children_decreases self key st))
=
- if key < self.betree_internal_pivot
- then betree_node_lookup_fwd self.betree_internal_left key st
- else betree_node_lookup_fwd self.betree_internal_right key st
+ if key < self.pivot
+ then betree_Node_lookup self.left key st
+ else betree_Node_lookup self.right key st
(** [betree_main::betree::Internal::{4}::lookup_in_children]: backward function 0 *)
-and betree_internal_lookup_in_children_back
- (self : betree_internal_t) (key : u64) (st : state) :
- Tot (result betree_internal_t)
- (decreases (betree_internal_lookup_in_children_decreases self key st))
+and betree_Internal_lookup_in_children_back
+ (self : betree_Internal_t) (key : u64) (st : state) :
+ Tot (result betree_Internal_t)
+ (decreases (betree_Internal_lookup_in_children_decreases self key st))
=
- if key < self.betree_internal_pivot
+ if key < self.pivot
then
- let* n = betree_node_lookup_back self.betree_internal_left key st in
- Return { self with betree_internal_left = n }
+ let* n = betree_Node_lookup_back self.left key st in
+ Return { self with left = n }
else
- let* n = betree_node_lookup_back self.betree_internal_right key st in
- Return { self with betree_internal_right = n }
+ let* n = betree_Node_lookup_back self.right key st in
+ Return { self with right = n }
(** [betree_main::betree::Node::{5}::lookup]: forward function *)
-and betree_node_lookup_fwd
- (self : betree_node_t) (key : u64) (st : state) :
+and betree_Node_lookup
+ (self : betree_Node_t) (key : u64) (st : state) :
Tot (result (state & (option u64)))
- (decreases (betree_node_lookup_decreases self key st))
+ (decreases (betree_Node_lookup_decreases self key st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st0, msgs) = betree_load_internal_node_fwd node.betree_internal_id st
- in
- let* pending = betree_node_lookup_first_message_for_key_fwd key msgs in
+ | Betree_Node_Internal node ->
+ let* (st0, msgs) = betree_load_internal_node node.id st in
+ let* pending = betree_Node_lookup_first_message_for_key key msgs in
begin match pending with
- | BetreeListCons p l ->
+ | Betree_List_Cons p l ->
let (k, msg) = p in
if k <> key
then
- let* (st1, opt) = betree_internal_lookup_in_children_fwd node key st0
- in
+ let* (st1, o) = betree_Internal_lookup_in_children node key st0 in
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, msg) l) in
- Return (st1, opt)
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, msg) l) in
+ Return (st1, o)
else
begin match msg with
- | BetreeMessageInsert v ->
+ | Betree_Message_Insert v ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, BetreeMessageInsert v) l) in
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, Betree_Message_Insert v) l) in
Return (st0, Some v)
- | BetreeMessageDelete ->
+ | Betree_Message_Delete ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, BetreeMessageDelete) l) in
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, Betree_Message_Delete) l) in
Return (st0, None)
- | BetreeMessageUpsert ufs ->
- let* (st1, v) = betree_internal_lookup_in_children_fwd node key st0
- in
+ | Betree_Message_Upsert ufs ->
+ let* (st1, v) = betree_Internal_lookup_in_children node key st0 in
let* (st2, v0) =
- betree_node_apply_upserts_fwd (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1 in
- let* node0 = betree_internal_lookup_in_children_back node key st0 in
+ betree_Node_apply_upserts (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1 in
+ let* node0 = betree_Internal_lookup_in_children_back node key st0 in
let* pending0 =
- betree_node_apply_upserts_back (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1 in
+ betree_Node_apply_upserts_back (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1 in
let* msgs0 =
- betree_node_lookup_first_message_for_key_back key msgs pending0 in
- let* (st3, _) =
- betree_store_internal_node_fwd node0.betree_internal_id msgs0 st2
- in
+ betree_Node_lookup_first_message_for_key_back key msgs pending0 in
+ let* (st3, _) = betree_store_internal_node node0.id msgs0 st2 in
Return (st3, Some v0)
end
- | BetreeListNil ->
- let* (st1, opt) = betree_internal_lookup_in_children_fwd node key st0 in
+ | Betree_List_Nil ->
+ let* (st1, o) = betree_Internal_lookup_in_children node key st0 in
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs BetreeListNil in
- Return (st1, opt)
+ betree_Node_lookup_first_message_for_key_back key msgs Betree_List_Nil
+ in
+ Return (st1, o)
end
- | BetreeNodeLeaf node ->
- let* (st0, bindings) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* opt = betree_node_lookup_in_bindings_fwd key bindings in
- Return (st0, opt)
+ | Betree_Node_Leaf node ->
+ let* (st0, bindings) = betree_load_leaf_node node.id st in
+ let* o = betree_Node_lookup_in_bindings key bindings in
+ Return (st0, o)
end
(** [betree_main::betree::Node::{5}::lookup]: backward function 0 *)
-and betree_node_lookup_back
- (self : betree_node_t) (key : u64) (st : state) :
- Tot (result betree_node_t)
- (decreases (betree_node_lookup_decreases self key st))
+and betree_Node_lookup_back
+ (self : betree_Node_t) (key : u64) (st : state) :
+ Tot (result betree_Node_t)
+ (decreases (betree_Node_lookup_decreases self key st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st0, msgs) = betree_load_internal_node_fwd node.betree_internal_id st
- in
- let* pending = betree_node_lookup_first_message_for_key_fwd key msgs in
+ | Betree_Node_Internal node ->
+ let* (st0, msgs) = betree_load_internal_node node.id st in
+ let* pending = betree_Node_lookup_first_message_for_key key msgs in
begin match pending with
- | BetreeListCons p l ->
+ | Betree_List_Cons p l ->
let (k, msg) = p in
if k <> key
then
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, msg) l) in
- let* node0 = betree_internal_lookup_in_children_back node key st0 in
- Return (BetreeNodeInternal node0)
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, msg) l) in
+ let* node0 = betree_Internal_lookup_in_children_back node key st0 in
+ Return (Betree_Node_Internal node0)
else
begin match msg with
- | BetreeMessageInsert v ->
+ | Betree_Message_Insert v ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, BetreeMessageInsert v) l) in
- Return (BetreeNodeInternal node)
- | BetreeMessageDelete ->
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, Betree_Message_Insert v) l) in
+ Return (Betree_Node_Internal node)
+ | Betree_Message_Delete ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, BetreeMessageDelete) l) in
- Return (BetreeNodeInternal node)
- | BetreeMessageUpsert ufs ->
- let* (st1, v) = betree_internal_lookup_in_children_fwd node key st0
- in
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, Betree_Message_Delete) l) in
+ Return (Betree_Node_Internal node)
+ | Betree_Message_Upsert ufs ->
+ let* (st1, v) = betree_Internal_lookup_in_children node key st0 in
let* (st2, _) =
- betree_node_apply_upserts_fwd (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1 in
- let* node0 = betree_internal_lookup_in_children_back node key st0 in
+ betree_Node_apply_upserts (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1 in
+ let* node0 = betree_Internal_lookup_in_children_back node key st0 in
let* pending0 =
- betree_node_apply_upserts_back (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1 in
+ betree_Node_apply_upserts_back (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1 in
let* msgs0 =
- betree_node_lookup_first_message_for_key_back key msgs pending0 in
- let* _ =
- betree_store_internal_node_fwd node0.betree_internal_id msgs0 st2
- in
- Return (BetreeNodeInternal node0)
+ betree_Node_lookup_first_message_for_key_back key msgs pending0 in
+ let* _ = betree_store_internal_node node0.id msgs0 st2 in
+ Return (Betree_Node_Internal node0)
end
- | BetreeListNil ->
+ | Betree_List_Nil ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs BetreeListNil in
- let* node0 = betree_internal_lookup_in_children_back node key st0 in
- Return (BetreeNodeInternal node0)
+ betree_Node_lookup_first_message_for_key_back key msgs Betree_List_Nil
+ in
+ let* node0 = betree_Internal_lookup_in_children_back node key st0 in
+ Return (Betree_Node_Internal node0)
end
- | BetreeNodeLeaf node ->
- let* (_, bindings) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* _ = betree_node_lookup_in_bindings_fwd key bindings in
- Return (BetreeNodeLeaf node)
+ | Betree_Node_Leaf node ->
+ let* (_, bindings) = betree_load_leaf_node node.id st in
+ let* _ = betree_Node_lookup_in_bindings key bindings in
+ Return (Betree_Node_Leaf node)
end
(** [betree_main::betree::Node::{5}::filter_messages_for_key]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec betree_node_filter_messages_for_key_fwd_back
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_filter_messages_for_key_decreases key msgs))
+let rec betree_Node_filter_messages_for_key
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_filter_messages_for_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons p l ->
+ | Betree_List_Cons p l ->
let (k, m) = p in
if k = key
then
let* msgs0 =
- betree_list_pop_front_back (u64 & betree_message_t) (BetreeListCons (k,
- m) l) in
- betree_node_filter_messages_for_key_fwd_back key msgs0
- else Return (BetreeListCons (k, m) l)
- | BetreeListNil -> Return BetreeListNil
+ betree_List_pop_front_back (u64 & betree_Message_t) (Betree_List_Cons
+ (k, m) l) in
+ betree_Node_filter_messages_for_key key msgs0
+ else Return (Betree_List_Cons (k, m) l)
+ | Betree_List_Nil -> Return Betree_List_Nil
end
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: forward function *)
-let rec betree_node_lookup_first_message_after_key_fwd
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_lookup_first_message_after_key_decreases key msgs))
+let rec betree_Node_lookup_first_message_after_key
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_lookup_first_message_after_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons p next_msgs ->
+ | Betree_List_Cons p next_msgs ->
let (k, m) = p in
if k = key
- then betree_node_lookup_first_message_after_key_fwd key next_msgs
- else Return (BetreeListCons (k, m) next_msgs)
- | BetreeListNil -> Return BetreeListNil
+ then betree_Node_lookup_first_message_after_key key next_msgs
+ else Return (Betree_List_Cons (k, m) next_msgs)
+ | Betree_List_Nil -> Return Betree_List_Nil
end
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: backward function 0 *)
-let rec betree_node_lookup_first_message_after_key_back
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t))
- (ret : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_lookup_first_message_after_key_decreases key msgs))
+let rec betree_Node_lookup_first_message_after_key_back
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t))
+ (ret : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_lookup_first_message_after_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons p next_msgs ->
+ | Betree_List_Cons p next_msgs ->
let (k, m) = p in
if k = key
then
let* next_msgs0 =
- betree_node_lookup_first_message_after_key_back key next_msgs ret in
- Return (BetreeListCons (k, m) next_msgs0)
+ betree_Node_lookup_first_message_after_key_back key next_msgs ret in
+ Return (Betree_List_Cons (k, m) next_msgs0)
else Return ret
- | BetreeListNil -> Return ret
+ | Betree_List_Nil -> Return ret
end
(** [betree_main::betree::Node::{5}::apply_to_internal]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let betree_node_apply_to_internal_fwd_back
- (msgs : betree_list_t (u64 & betree_message_t)) (key : u64)
- (new_msg : betree_message_t) :
- result (betree_list_t (u64 & betree_message_t))
+let betree_Node_apply_to_internal
+ (msgs : betree_List_t (u64 & betree_Message_t)) (key : u64)
+ (new_msg : betree_Message_t) :
+ result (betree_List_t (u64 & betree_Message_t))
=
- let* msgs0 = betree_node_lookup_first_message_for_key_fwd key msgs in
- let* b = betree_list_head_has_key_fwd betree_message_t msgs0 key in
+ let* msgs0 = betree_Node_lookup_first_message_for_key key msgs in
+ let* b = betree_List_head_has_key betree_Message_t msgs0 key in
if b
then
begin match new_msg with
- | BetreeMessageInsert i ->
- let* msgs1 = betree_node_filter_messages_for_key_fwd_back key msgs0 in
+ | Betree_Message_Insert i ->
+ let* msgs1 = betree_Node_filter_messages_for_key key msgs0 in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageInsert i) in
- betree_node_lookup_first_message_for_key_back key msgs msgs2
- | BetreeMessageDelete ->
- let* msgs1 = betree_node_filter_messages_for_key_fwd_back key msgs0 in
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Insert i) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs2
+ | Betree_Message_Delete ->
+ let* msgs1 = betree_Node_filter_messages_for_key key msgs0 in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageDelete) in
- betree_node_lookup_first_message_for_key_back key msgs msgs2
- | BetreeMessageUpsert s ->
- let* p = betree_list_hd_fwd (u64 & betree_message_t) msgs0 in
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Delete) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs2
+ | Betree_Message_Upsert s ->
+ let* p = betree_List_hd (u64 & betree_Message_t) msgs0 in
let (_, m) = p in
begin match m with
- | BetreeMessageInsert prev ->
- let* v = betree_upsert_update_fwd (Some prev) s in
- let* msgs1 = betree_list_pop_front_back (u64 & betree_message_t) msgs0
+ | Betree_Message_Insert prev ->
+ let* v = betree_upsert_update (Some prev) s in
+ let* msgs1 = betree_List_pop_front_back (u64 & betree_Message_t) msgs0
in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageInsert v) in
- betree_node_lookup_first_message_for_key_back key msgs msgs2
- | BetreeMessageDelete ->
- let* v = betree_upsert_update_fwd None s in
- let* msgs1 = betree_list_pop_front_back (u64 & betree_message_t) msgs0
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Insert v) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs2
+ | Betree_Message_Delete ->
+ let* v = betree_upsert_update None s in
+ let* msgs1 = betree_List_pop_front_back (u64 & betree_Message_t) msgs0
in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageInsert v) in
- betree_node_lookup_first_message_for_key_back key msgs msgs2
- | BetreeMessageUpsert ufs ->
- let* msgs1 = betree_node_lookup_first_message_after_key_fwd key msgs0
- in
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Insert v) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs2
+ | Betree_Message_Upsert ufs ->
+ let* msgs1 = betree_Node_lookup_first_message_after_key key msgs0 in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageUpsert s) in
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Upsert s) in
let* msgs3 =
- betree_node_lookup_first_message_after_key_back key msgs0 msgs2 in
- betree_node_lookup_first_message_for_key_back key msgs msgs3
+ betree_Node_lookup_first_message_after_key_back key msgs0 msgs2 in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs3
end
end
else
let* msgs1 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs0 (key,
- new_msg) in
- betree_node_lookup_first_message_for_key_back key msgs msgs1
+ betree_List_push_front (u64 & betree_Message_t) msgs0 (key, new_msg) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs1
(** [betree_main::betree::Node::{5}::apply_messages_to_internal]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec betree_node_apply_messages_to_internal_fwd_back
- (msgs : betree_list_t (u64 & betree_message_t))
- (new_msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_apply_messages_to_internal_decreases msgs new_msgs))
+let rec betree_Node_apply_messages_to_internal
+ (msgs : betree_List_t (u64 & betree_Message_t))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_apply_messages_to_internal_decreases msgs new_msgs))
=
begin match new_msgs with
- | BetreeListCons new_msg new_msgs_tl ->
+ | Betree_List_Cons new_msg new_msgs_tl ->
let (i, m) = new_msg in
- let* msgs0 = betree_node_apply_to_internal_fwd_back msgs i m in
- betree_node_apply_messages_to_internal_fwd_back msgs0 new_msgs_tl
- | BetreeListNil -> Return msgs
+ let* msgs0 = betree_Node_apply_to_internal msgs i m in
+ betree_Node_apply_messages_to_internal msgs0 new_msgs_tl
+ | Betree_List_Nil -> Return msgs
end
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: forward function *)
-let rec betree_node_lookup_mut_in_bindings_fwd
- (key : u64) (bindings : betree_list_t (u64 & u64)) :
- Tot (result (betree_list_t (u64 & u64)))
- (decreases (betree_node_lookup_mut_in_bindings_decreases key bindings))
+let rec betree_Node_lookup_mut_in_bindings
+ (key : u64) (bindings : betree_List_t (u64 & u64)) :
+ Tot (result (betree_List_t (u64 & u64)))
+ (decreases (betree_Node_lookup_mut_in_bindings_decreases key bindings))
=
begin match bindings with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let (i, i0) = hd in
if i >= key
- then Return (BetreeListCons (i, i0) tl)
- else betree_node_lookup_mut_in_bindings_fwd key tl
- | BetreeListNil -> Return BetreeListNil
+ then Return (Betree_List_Cons (i, i0) tl)
+ else betree_Node_lookup_mut_in_bindings key tl
+ | Betree_List_Nil -> Return Betree_List_Nil
end
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: backward function 0 *)
-let rec betree_node_lookup_mut_in_bindings_back
- (key : u64) (bindings : betree_list_t (u64 & u64))
- (ret : betree_list_t (u64 & u64)) :
- Tot (result (betree_list_t (u64 & u64)))
- (decreases (betree_node_lookup_mut_in_bindings_decreases key bindings))
+let rec betree_Node_lookup_mut_in_bindings_back
+ (key : u64) (bindings : betree_List_t (u64 & u64))
+ (ret : betree_List_t (u64 & u64)) :
+ Tot (result (betree_List_t (u64 & u64)))
+ (decreases (betree_Node_lookup_mut_in_bindings_decreases key bindings))
=
begin match bindings with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let (i, i0) = hd in
if i >= key
then Return ret
else
- let* tl0 = betree_node_lookup_mut_in_bindings_back key tl ret in
- Return (BetreeListCons (i, i0) tl0)
- | BetreeListNil -> Return ret
+ let* tl0 = betree_Node_lookup_mut_in_bindings_back key tl ret in
+ Return (Betree_List_Cons (i, i0) tl0)
+ | Betree_List_Nil -> Return ret
end
(** [betree_main::betree::Node::{5}::apply_to_leaf]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let betree_node_apply_to_leaf_fwd_back
- (bindings : betree_list_t (u64 & u64)) (key : u64)
- (new_msg : betree_message_t) :
- result (betree_list_t (u64 & u64))
+let betree_Node_apply_to_leaf
+ (bindings : betree_List_t (u64 & u64)) (key : u64)
+ (new_msg : betree_Message_t) :
+ result (betree_List_t (u64 & u64))
=
- let* bindings0 = betree_node_lookup_mut_in_bindings_fwd key bindings in
- let* b = betree_list_head_has_key_fwd u64 bindings0 key in
+ let* bindings0 = betree_Node_lookup_mut_in_bindings key bindings in
+ let* b = betree_List_head_has_key u64 bindings0 key in
if b
then
- let* hd = betree_list_pop_front_fwd (u64 & u64) bindings0 in
+ let* hd = betree_List_pop_front (u64 & u64) bindings0 in
begin match new_msg with
- | BetreeMessageInsert v ->
- let* bindings1 = betree_list_pop_front_back (u64 & u64) bindings0 in
- let* bindings2 =
- betree_list_push_front_fwd_back (u64 & u64) bindings1 (key, v) in
- betree_node_lookup_mut_in_bindings_back key bindings bindings2
- | BetreeMessageDelete ->
- let* bindings1 = betree_list_pop_front_back (u64 & u64) bindings0 in
- betree_node_lookup_mut_in_bindings_back key bindings bindings1
- | BetreeMessageUpsert s ->
+ | Betree_Message_Insert v ->
+ let* bindings1 = betree_List_pop_front_back (u64 & u64) bindings0 in
+ let* bindings2 = betree_List_push_front (u64 & u64) bindings1 (key, v) in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings2
+ | Betree_Message_Delete ->
+ let* bindings1 = betree_List_pop_front_back (u64 & u64) bindings0 in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings1
+ | Betree_Message_Upsert s ->
let (_, i) = hd in
- let* v = betree_upsert_update_fwd (Some i) s in
- let* bindings1 = betree_list_pop_front_back (u64 & u64) bindings0 in
- let* bindings2 =
- betree_list_push_front_fwd_back (u64 & u64) bindings1 (key, v) in
- betree_node_lookup_mut_in_bindings_back key bindings bindings2
+ let* v = betree_upsert_update (Some i) s in
+ let* bindings1 = betree_List_pop_front_back (u64 & u64) bindings0 in
+ let* bindings2 = betree_List_push_front (u64 & u64) bindings1 (key, v) in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings2
end
else
begin match new_msg with
- | BetreeMessageInsert v ->
- let* bindings1 =
- betree_list_push_front_fwd_back (u64 & u64) bindings0 (key, v) in
- betree_node_lookup_mut_in_bindings_back key bindings bindings1
- | BetreeMessageDelete ->
- betree_node_lookup_mut_in_bindings_back key bindings bindings0
- | BetreeMessageUpsert s ->
- let* v = betree_upsert_update_fwd None s in
- let* bindings1 =
- betree_list_push_front_fwd_back (u64 & u64) bindings0 (key, v) in
- betree_node_lookup_mut_in_bindings_back key bindings bindings1
+ | Betree_Message_Insert v ->
+ let* bindings1 = betree_List_push_front (u64 & u64) bindings0 (key, v) in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings1
+ | Betree_Message_Delete ->
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings0
+ | Betree_Message_Upsert s ->
+ let* v = betree_upsert_update None s in
+ let* bindings1 = betree_List_push_front (u64 & u64) bindings0 (key, v) in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings1
end
(** [betree_main::betree::Node::{5}::apply_messages_to_leaf]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec betree_node_apply_messages_to_leaf_fwd_back
- (bindings : betree_list_t (u64 & u64))
- (new_msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & u64)))
- (decreases (betree_node_apply_messages_to_leaf_decreases bindings new_msgs))
+let rec betree_Node_apply_messages_to_leaf
+ (bindings : betree_List_t (u64 & u64))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & u64)))
+ (decreases (betree_Node_apply_messages_to_leaf_decreases bindings new_msgs))
=
begin match new_msgs with
- | BetreeListCons new_msg new_msgs_tl ->
+ | Betree_List_Cons new_msg new_msgs_tl ->
let (i, m) = new_msg in
- let* bindings0 = betree_node_apply_to_leaf_fwd_back bindings i m in
- betree_node_apply_messages_to_leaf_fwd_back bindings0 new_msgs_tl
- | BetreeListNil -> Return bindings
+ let* bindings0 = betree_Node_apply_to_leaf bindings i m in
+ betree_Node_apply_messages_to_leaf bindings0 new_msgs_tl
+ | Betree_List_Nil -> Return bindings
end
(** [betree_main::betree::Internal::{4}::flush]: forward function *)
-let rec betree_internal_flush_fwd
- (self : betree_internal_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) :
- Tot (result (state & (betree_list_t (u64 & betree_message_t))))
+let rec betree_Internal_flush
+ (self : betree_Internal_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) :
+ Tot (result (state & (betree_List_t (u64 & betree_Message_t))))
(decreases (
- betree_internal_flush_decreases self params node_id_cnt content st))
+ betree_Internal_flush_decreases self params node_id_cnt content st))
=
- let* p =
- betree_list_partition_at_pivot_fwd betree_message_t content
- self.betree_internal_pivot in
+ let* p = betree_List_partition_at_pivot betree_Message_t content self.pivot
+ in
let (msgs_left, msgs_right) = p in
- let* len_left = betree_list_len_fwd (u64 & betree_message_t) msgs_left in
- if len_left >= params.betree_params_min_flush_size
+ let* len_left = betree_List_len (u64 & betree_Message_t) msgs_left in
+ if len_left >= params.min_flush_size
then
let* (st0, _) =
- betree_node_apply_messages_fwd self.betree_internal_left params
- node_id_cnt msgs_left st in
+ betree_Node_apply_messages self.left params node_id_cnt msgs_left st in
let* (_, node_id_cnt0) =
- betree_node_apply_messages_back self.betree_internal_left params
- node_id_cnt msgs_left st in
- let* len_right = betree_list_len_fwd (u64 & betree_message_t) msgs_right in
- if len_right >= params.betree_params_min_flush_size
+ betree_Node_apply_messages_back self.left params node_id_cnt msgs_left st
+ in
+ let* len_right = betree_List_len (u64 & betree_Message_t) msgs_right in
+ if len_right >= params.min_flush_size
then
let* (st1, _) =
- betree_node_apply_messages_fwd self.betree_internal_right params
- node_id_cnt0 msgs_right st0 in
+ betree_Node_apply_messages self.right params node_id_cnt0 msgs_right
+ st0 in
let* _ =
- betree_node_apply_messages_back self.betree_internal_right params
- node_id_cnt0 msgs_right st0 in
- Return (st1, BetreeListNil)
+ betree_Node_apply_messages_back self.right params node_id_cnt0
+ msgs_right st0 in
+ Return (st1, Betree_List_Nil)
else Return (st0, msgs_right)
else
let* (st0, _) =
- betree_node_apply_messages_fwd self.betree_internal_right params
- node_id_cnt msgs_right st in
+ betree_Node_apply_messages self.right params node_id_cnt msgs_right st in
let* _ =
- betree_node_apply_messages_back self.betree_internal_right params
- node_id_cnt msgs_right st in
+ betree_Node_apply_messages_back self.right params node_id_cnt msgs_right
+ st in
Return (st0, msgs_left)
(** [betree_main::betree::Internal::{4}::flush]: backward function 0 *)
-and betree_internal_flush_back
- (self : betree_internal_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) :
- Tot (result (betree_internal_t & betree_node_id_counter_t))
+and betree_Internal_flush_back
+ (self : betree_Internal_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) :
+ Tot (result (betree_Internal_t & betree_NodeIdCounter_t))
(decreases (
- betree_internal_flush_decreases self params node_id_cnt content st))
+ betree_Internal_flush_decreases self params node_id_cnt content st))
=
- let* p =
- betree_list_partition_at_pivot_fwd betree_message_t content
- self.betree_internal_pivot in
+ let* p = betree_List_partition_at_pivot betree_Message_t content self.pivot
+ in
let (msgs_left, msgs_right) = p in
- let* len_left = betree_list_len_fwd (u64 & betree_message_t) msgs_left in
- if len_left >= params.betree_params_min_flush_size
+ let* len_left = betree_List_len (u64 & betree_Message_t) msgs_left in
+ if len_left >= params.min_flush_size
then
let* (st0, _) =
- betree_node_apply_messages_fwd self.betree_internal_left params
- node_id_cnt msgs_left st in
+ betree_Node_apply_messages self.left params node_id_cnt msgs_left st in
let* (n, node_id_cnt0) =
- betree_node_apply_messages_back self.betree_internal_left params
- node_id_cnt msgs_left st in
- let* len_right = betree_list_len_fwd (u64 & betree_message_t) msgs_right in
- if len_right >= params.betree_params_min_flush_size
+ betree_Node_apply_messages_back self.left params node_id_cnt msgs_left st
+ in
+ let* len_right = betree_List_len (u64 & betree_Message_t) msgs_right in
+ if len_right >= params.min_flush_size
then
let* (n0, node_id_cnt1) =
- betree_node_apply_messages_back self.betree_internal_right params
- node_id_cnt0 msgs_right st0 in
- Return
- ({ self with betree_internal_left = n; betree_internal_right = n0 },
- node_id_cnt1)
- else Return ({ self with betree_internal_left = n }, node_id_cnt0)
+ betree_Node_apply_messages_back self.right params node_id_cnt0
+ msgs_right st0 in
+ Return ({ self with left = n; right = n0 }, node_id_cnt1)
+ else Return ({ self with left = n }, node_id_cnt0)
else
let* (n, node_id_cnt0) =
- betree_node_apply_messages_back self.betree_internal_right params
- node_id_cnt msgs_right st in
- Return ({ self with betree_internal_right = n }, node_id_cnt0)
+ betree_Node_apply_messages_back self.right params node_id_cnt msgs_right
+ st in
+ Return ({ self with right = n }, node_id_cnt0)
(** [betree_main::betree::Node::{5}::apply_messages]: forward function *)
-and betree_node_apply_messages_fwd
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) :
+and betree_Node_apply_messages
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) :
Tot (result (state & unit))
(decreases (
- betree_node_apply_messages_decreases self params node_id_cnt msgs st))
+ betree_Node_apply_messages_decreases self params node_id_cnt msgs st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st0, content) =
- betree_load_internal_node_fwd node.betree_internal_id st in
- let* content0 =
- betree_node_apply_messages_to_internal_fwd_back content msgs in
- let* num_msgs = betree_list_len_fwd (u64 & betree_message_t) content0 in
- if num_msgs >= params.betree_params_min_flush_size
+ | Betree_Node_Internal node ->
+ let* (st0, content) = betree_load_internal_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_internal content msgs in
+ let* num_msgs = betree_List_len (u64 & betree_Message_t) content0 in
+ if num_msgs >= params.min_flush_size
then
let* (st1, content1) =
- betree_internal_flush_fwd node params node_id_cnt content0 st0 in
+ betree_Internal_flush node params node_id_cnt content0 st0 in
let* (node0, _) =
- betree_internal_flush_back node params node_id_cnt content0 st0 in
- let* (st2, _) =
- betree_store_internal_node_fwd node0.betree_internal_id content1 st1 in
+ betree_Internal_flush_back node params node_id_cnt content0 st0 in
+ let* (st2, _) = betree_store_internal_node node0.id content1 st1 in
Return (st2, ())
else
- let* (st1, _) =
- betree_store_internal_node_fwd node.betree_internal_id content0 st0 in
+ let* (st1, _) = betree_store_internal_node node.id content0 st0 in
Return (st1, ())
- | BetreeNodeLeaf node ->
- let* (st0, content) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* content0 = betree_node_apply_messages_to_leaf_fwd_back content msgs in
- let* len = betree_list_len_fwd (u64 & u64) content0 in
- let* i = u64_mul 2 params.betree_params_split_size in
+ | Betree_Node_Leaf node ->
+ let* (st0, content) = betree_load_leaf_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_leaf content msgs in
+ let* len = betree_List_len (u64 & u64) content0 in
+ let* i = u64_mul 2 params.split_size in
if len >= i
then
- let* (st1, _) =
- betree_leaf_split_fwd node content0 params node_id_cnt st0 in
- let* (st2, _) =
- betree_store_leaf_node_fwd node.betree_leaf_id BetreeListNil st1 in
+ let* (st1, _) = betree_Leaf_split node content0 params node_id_cnt st0 in
+ let* (st2, _) = betree_store_leaf_node node.id Betree_List_Nil st1 in
Return (st2, ())
else
- let* (st1, _) =
- betree_store_leaf_node_fwd node.betree_leaf_id content0 st0 in
+ let* (st1, _) = betree_store_leaf_node node.id content0 st0 in
Return (st1, ())
end
(** [betree_main::betree::Node::{5}::apply_messages]: backward function 0 *)
-and betree_node_apply_messages_back
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) :
- Tot (result (betree_node_t & betree_node_id_counter_t))
+and betree_Node_apply_messages_back
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) :
+ Tot (result (betree_Node_t & betree_NodeIdCounter_t))
(decreases (
- betree_node_apply_messages_decreases self params node_id_cnt msgs st))
+ betree_Node_apply_messages_decreases self params node_id_cnt msgs st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st0, content) =
- betree_load_internal_node_fwd node.betree_internal_id st in
- let* content0 =
- betree_node_apply_messages_to_internal_fwd_back content msgs in
- let* num_msgs = betree_list_len_fwd (u64 & betree_message_t) content0 in
- if num_msgs >= params.betree_params_min_flush_size
+ | Betree_Node_Internal node ->
+ let* (st0, content) = betree_load_internal_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_internal content msgs in
+ let* num_msgs = betree_List_len (u64 & betree_Message_t) content0 in
+ if num_msgs >= params.min_flush_size
then
let* (st1, content1) =
- betree_internal_flush_fwd node params node_id_cnt content0 st0 in
+ betree_Internal_flush node params node_id_cnt content0 st0 in
let* (node0, node_id_cnt0) =
- betree_internal_flush_back node params node_id_cnt content0 st0 in
- let* _ =
- betree_store_internal_node_fwd node0.betree_internal_id content1 st1 in
- Return (BetreeNodeInternal node0, node_id_cnt0)
+ betree_Internal_flush_back node params node_id_cnt content0 st0 in
+ let* _ = betree_store_internal_node node0.id content1 st1 in
+ Return (Betree_Node_Internal node0, node_id_cnt0)
else
- let* _ =
- betree_store_internal_node_fwd node.betree_internal_id content0 st0 in
- Return (BetreeNodeInternal node, node_id_cnt)
- | BetreeNodeLeaf node ->
- let* (st0, content) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* content0 = betree_node_apply_messages_to_leaf_fwd_back content msgs in
- let* len = betree_list_len_fwd (u64 & u64) content0 in
- let* i = u64_mul 2 params.betree_params_split_size in
+ let* _ = betree_store_internal_node node.id content0 st0 in
+ Return (Betree_Node_Internal node, node_id_cnt)
+ | Betree_Node_Leaf node ->
+ let* (st0, content) = betree_load_leaf_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_leaf content msgs in
+ let* len = betree_List_len (u64 & u64) content0 in
+ let* i = u64_mul 2 params.split_size in
if len >= i
then
let* (st1, new_node) =
- betree_leaf_split_fwd node content0 params node_id_cnt st0 in
- let* _ = betree_store_leaf_node_fwd node.betree_leaf_id BetreeListNil st1
- in
+ betree_Leaf_split node content0 params node_id_cnt st0 in
+ let* _ = betree_store_leaf_node node.id Betree_List_Nil st1 in
let* node_id_cnt0 =
- betree_leaf_split_back node content0 params node_id_cnt st0 in
- Return (BetreeNodeInternal new_node, node_id_cnt0)
+ betree_Leaf_split_back node content0 params node_id_cnt st0 in
+ Return (Betree_Node_Internal new_node, node_id_cnt0)
else
- let* _ = betree_store_leaf_node_fwd node.betree_leaf_id content0 st0 in
- Return (BetreeNodeLeaf { node with betree_leaf_size = len }, node_id_cnt)
+ let* _ = betree_store_leaf_node node.id content0 st0 in
+ Return (Betree_Node_Leaf { node with size = len }, node_id_cnt)
end
(** [betree_main::betree::Node::{5}::apply]: forward function *)
-let betree_node_apply_fwd
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t) (key : u64)
- (new_msg : betree_message_t) (st : state) :
+let betree_Node_apply
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t) (key : u64)
+ (new_msg : betree_Message_t) (st : state) :
result (state & unit)
=
- let l = BetreeListNil in
+ let l = Betree_List_Nil in
let* (st0, _) =
- betree_node_apply_messages_fwd self params node_id_cnt (BetreeListCons
- (key, new_msg) l) st in
+ betree_Node_apply_messages self params node_id_cnt (Betree_List_Cons (key,
+ new_msg) l) st in
let* _ =
- betree_node_apply_messages_back self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages_back self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st in
Return (st0, ())
(** [betree_main::betree::Node::{5}::apply]: backward function 0 *)
-let betree_node_apply_back
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t) (key : u64)
- (new_msg : betree_message_t) (st : state) :
- result (betree_node_t & betree_node_id_counter_t)
+let betree_Node_apply_back
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t) (key : u64)
+ (new_msg : betree_Message_t) (st : state) :
+ result (betree_Node_t & betree_NodeIdCounter_t)
=
- let l = BetreeListNil in
- betree_node_apply_messages_back self params node_id_cnt (BetreeListCons (key,
- new_msg) l) st
+ let l = Betree_List_Nil in
+ betree_Node_apply_messages_back self params node_id_cnt (Betree_List_Cons
+ (key, new_msg) l) st
(** [betree_main::betree::BeTree::{6}::new]: forward function *)
-let betree_be_tree_new_fwd
+let betree_BeTree_new
(min_flush_size : u64) (split_size : u64) (st : state) :
- result (state & betree_be_tree_t)
+ result (state & betree_BeTree_t)
=
- let* node_id_cnt = betree_node_id_counter_new_fwd in
- let* id = betree_node_id_counter_fresh_id_fwd node_id_cnt in
- let* (st0, _) = betree_store_leaf_node_fwd id BetreeListNil st in
- let* node_id_cnt0 = betree_node_id_counter_fresh_id_back node_id_cnt in
+ let* node_id_cnt = betree_NodeIdCounter_new in
+ let* id = betree_NodeIdCounter_fresh_id node_id_cnt in
+ let* (st0, _) = betree_store_leaf_node id Betree_List_Nil st in
+ let* node_id_cnt0 = betree_NodeIdCounter_fresh_id_back node_id_cnt in
Return (st0,
{
- betree_be_tree_params =
- {
- betree_params_min_flush_size = min_flush_size;
- betree_params_split_size = split_size
- };
- betree_be_tree_node_id_cnt = node_id_cnt0;
- betree_be_tree_root =
- (BetreeNodeLeaf { betree_leaf_id = id; betree_leaf_size = 0 })
+ params = { min_flush_size = min_flush_size; split_size = split_size };
+ node_id_cnt = node_id_cnt0;
+ root = (Betree_Node_Leaf { id = id; size = 0 })
})
(** [betree_main::betree::BeTree::{6}::apply]: forward function *)
-let betree_be_tree_apply_fwd
- (self : betree_be_tree_t) (key : u64) (msg : betree_message_t) (st : state) :
+let betree_BeTree_apply
+ (self : betree_BeTree_t) (key : u64) (msg : betree_Message_t) (st : state) :
result (state & unit)
=
let* (st0, _) =
- betree_node_apply_fwd self.betree_be_tree_root self.betree_be_tree_params
- self.betree_be_tree_node_id_cnt key msg st in
+ betree_Node_apply self.root self.params self.node_id_cnt key msg st in
let* _ =
- betree_node_apply_back self.betree_be_tree_root self.betree_be_tree_params
- self.betree_be_tree_node_id_cnt key msg st in
+ betree_Node_apply_back self.root self.params self.node_id_cnt key msg st in
Return (st0, ())
(** [betree_main::betree::BeTree::{6}::apply]: backward function 0 *)
-let betree_be_tree_apply_back
- (self : betree_be_tree_t) (key : u64) (msg : betree_message_t) (st : state) :
- result betree_be_tree_t
+let betree_BeTree_apply_back
+ (self : betree_BeTree_t) (key : u64) (msg : betree_Message_t) (st : state) :
+ result betree_BeTree_t
=
let* (n, nic) =
- betree_node_apply_back self.betree_be_tree_root self.betree_be_tree_params
- self.betree_be_tree_node_id_cnt key msg st in
- Return
- { self with betree_be_tree_node_id_cnt = nic; betree_be_tree_root = n }
+ betree_Node_apply_back self.root self.params self.node_id_cnt key msg st in
+ Return { self with node_id_cnt = nic; root = n }
(** [betree_main::betree::BeTree::{6}::insert]: forward function *)
-let betree_be_tree_insert_fwd
- (self : betree_be_tree_t) (key : u64) (value : u64) (st : state) :
+let betree_BeTree_insert
+ (self : betree_BeTree_t) (key : u64) (value : u64) (st : state) :
result (state & unit)
=
- let* (st0, _) =
- betree_be_tree_apply_fwd self key (BetreeMessageInsert value) st in
- let* _ = betree_be_tree_apply_back self key (BetreeMessageInsert value) st in
+ let* (st0, _) = betree_BeTree_apply self key (Betree_Message_Insert value) st
+ in
+ let* _ = betree_BeTree_apply_back self key (Betree_Message_Insert value) st
+ in
Return (st0, ())
(** [betree_main::betree::BeTree::{6}::insert]: backward function 0 *)
-let betree_be_tree_insert_back
- (self : betree_be_tree_t) (key : u64) (value : u64) (st : state) :
- result betree_be_tree_t
+let betree_BeTree_insert_back
+ (self : betree_BeTree_t) (key : u64) (value : u64) (st : state) :
+ result betree_BeTree_t
=
- betree_be_tree_apply_back self key (BetreeMessageInsert value) st
+ betree_BeTree_apply_back self key (Betree_Message_Insert value) st
(** [betree_main::betree::BeTree::{6}::delete]: forward function *)
-let betree_be_tree_delete_fwd
- (self : betree_be_tree_t) (key : u64) (st : state) : result (state & unit) =
- let* (st0, _) = betree_be_tree_apply_fwd self key BetreeMessageDelete st in
- let* _ = betree_be_tree_apply_back self key BetreeMessageDelete st in
+let betree_BeTree_delete
+ (self : betree_BeTree_t) (key : u64) (st : state) : result (state & unit) =
+ let* (st0, _) = betree_BeTree_apply self key Betree_Message_Delete st in
+ let* _ = betree_BeTree_apply_back self key Betree_Message_Delete st in
Return (st0, ())
(** [betree_main::betree::BeTree::{6}::delete]: backward function 0 *)
-let betree_be_tree_delete_back
- (self : betree_be_tree_t) (key : u64) (st : state) :
- result betree_be_tree_t
- =
- betree_be_tree_apply_back self key BetreeMessageDelete st
+let betree_BeTree_delete_back
+ (self : betree_BeTree_t) (key : u64) (st : state) : result betree_BeTree_t =
+ betree_BeTree_apply_back self key Betree_Message_Delete st
(** [betree_main::betree::BeTree::{6}::upsert]: forward function *)
-let betree_be_tree_upsert_fwd
- (self : betree_be_tree_t) (key : u64) (upd : betree_upsert_fun_state_t)
+let betree_BeTree_upsert
+ (self : betree_BeTree_t) (key : u64) (upd : betree_UpsertFunState_t)
(st : state) :
result (state & unit)
=
- let* (st0, _) =
- betree_be_tree_apply_fwd self key (BetreeMessageUpsert upd) st in
- let* _ = betree_be_tree_apply_back self key (BetreeMessageUpsert upd) st in
+ let* (st0, _) = betree_BeTree_apply self key (Betree_Message_Upsert upd) st
+ in
+ let* _ = betree_BeTree_apply_back self key (Betree_Message_Upsert upd) st in
Return (st0, ())
(** [betree_main::betree::BeTree::{6}::upsert]: backward function 0 *)
-let betree_be_tree_upsert_back
- (self : betree_be_tree_t) (key : u64) (upd : betree_upsert_fun_state_t)
+let betree_BeTree_upsert_back
+ (self : betree_BeTree_t) (key : u64) (upd : betree_UpsertFunState_t)
(st : state) :
- result betree_be_tree_t
+ result betree_BeTree_t
=
- betree_be_tree_apply_back self key (BetreeMessageUpsert upd) st
+ betree_BeTree_apply_back self key (Betree_Message_Upsert upd) st
(** [betree_main::betree::BeTree::{6}::lookup]: forward function *)
-let betree_be_tree_lookup_fwd
- (self : betree_be_tree_t) (key : u64) (st : state) :
+let betree_BeTree_lookup
+ (self : betree_BeTree_t) (key : u64) (st : state) :
result (state & (option u64))
=
- betree_node_lookup_fwd self.betree_be_tree_root key st
+ betree_Node_lookup self.root key st
(** [betree_main::betree::BeTree::{6}::lookup]: backward function 0 *)
-let betree_be_tree_lookup_back
- (self : betree_be_tree_t) (key : u64) (st : state) :
- result betree_be_tree_t
- =
- let* n = betree_node_lookup_back self.betree_be_tree_root key st in
- Return { self with betree_be_tree_root = n }
+let betree_BeTree_lookup_back
+ (self : betree_BeTree_t) (key : u64) (st : state) : result betree_BeTree_t =
+ let* n = betree_Node_lookup_back self.root key st in
+ Return { self with root = n }
(** [betree_main::main]: forward function *)
-let main_fwd : result unit =
+let main : result unit =
Return ()
(** Unit test for [betree_main::main] *)
-let _ = assert_norm (main_fwd = Return ())
+let _ = assert_norm (main = Return ())
diff --git a/tests/fstar/betree/BetreeMain.Opaque.fsti b/tests/fstar/betree/BetreeMain.Opaque.fsti
index c33cf225..c5d0a814 100644
--- a/tests/fstar/betree/BetreeMain.Opaque.fsti
+++ b/tests/fstar/betree/BetreeMain.Opaque.fsti
@@ -7,24 +7,24 @@ include BetreeMain.Types
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [betree_main::betree_utils::load_internal_node]: forward function *)
-val betree_utils_load_internal_node_fwd
- : u64 -> state -> result (state & (betree_list_t (u64 & betree_message_t)))
+val betree_utils_load_internal_node
+ : u64 -> state -> result (state & (betree_List_t (u64 & betree_Message_t)))
(** [betree_main::betree_utils::store_internal_node]: forward function *)
-val betree_utils_store_internal_node_fwd
+val betree_utils_store_internal_node
:
- u64 -> betree_list_t (u64 & betree_message_t) -> state -> result (state &
+ u64 -> betree_List_t (u64 & betree_Message_t) -> state -> result (state &
unit)
(** [betree_main::betree_utils::load_leaf_node]: forward function *)
-val betree_utils_load_leaf_node_fwd
- : u64 -> state -> result (state & (betree_list_t (u64 & u64)))
+val betree_utils_load_leaf_node
+ : u64 -> state -> result (state & (betree_List_t (u64 & u64)))
(** [betree_main::betree_utils::store_leaf_node]: forward function *)
-val betree_utils_store_leaf_node_fwd
- : u64 -> betree_list_t (u64 & u64) -> state -> result (state & unit)
+val betree_utils_store_leaf_node
+ : u64 -> betree_List_t (u64 & u64) -> state -> result (state & unit)
(** [core::option::Option::{0}::unwrap]: forward function *)
-val core_option_option_unwrap_fwd
+val core_option_Option_unwrap
(t : Type0) : option t -> state -> result (state & t)
diff --git a/tests/fstar/betree/BetreeMain.Types.fsti b/tests/fstar/betree/BetreeMain.Types.fsti
index a937c726..9320f6b7 100644
--- a/tests/fstar/betree/BetreeMain.Types.fsti
+++ b/tests/fstar/betree/BetreeMain.Types.fsti
@@ -6,53 +6,47 @@ open Primitives
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [betree_main::betree::List] *)
-type betree_list_t (t : Type0) =
-| BetreeListCons : t -> betree_list_t t -> betree_list_t t
-| BetreeListNil : betree_list_t t
+type betree_List_t (t : Type0) =
+| Betree_List_Cons : t -> betree_List_t t -> betree_List_t t
+| Betree_List_Nil : betree_List_t t
(** [betree_main::betree::UpsertFunState] *)
-type betree_upsert_fun_state_t =
-| BetreeUpsertFunStateAdd : u64 -> betree_upsert_fun_state_t
-| BetreeUpsertFunStateSub : u64 -> betree_upsert_fun_state_t
+type betree_UpsertFunState_t =
+| Betree_UpsertFunState_Add : u64 -> betree_UpsertFunState_t
+| Betree_UpsertFunState_Sub : u64 -> betree_UpsertFunState_t
(** [betree_main::betree::Message] *)
-type betree_message_t =
-| BetreeMessageInsert : u64 -> betree_message_t
-| BetreeMessageDelete : betree_message_t
-| BetreeMessageUpsert : betree_upsert_fun_state_t -> betree_message_t
+type betree_Message_t =
+| Betree_Message_Insert : u64 -> betree_Message_t
+| Betree_Message_Delete : betree_Message_t
+| Betree_Message_Upsert : betree_UpsertFunState_t -> betree_Message_t
(** [betree_main::betree::Leaf] *)
-type betree_leaf_t = { betree_leaf_id : u64; betree_leaf_size : u64; }
+type betree_Leaf_t = { id : u64; size : u64; }
(** [betree_main::betree::Internal] *)
-type betree_internal_t =
+type betree_Internal_t =
{
- betree_internal_id : u64;
- betree_internal_pivot : u64;
- betree_internal_left : betree_node_t;
- betree_internal_right : betree_node_t;
+ id : u64; pivot : u64; left : betree_Node_t; right : betree_Node_t;
}
(** [betree_main::betree::Node] *)
-and betree_node_t =
-| BetreeNodeInternal : betree_internal_t -> betree_node_t
-| BetreeNodeLeaf : betree_leaf_t -> betree_node_t
+and betree_Node_t =
+| Betree_Node_Internal : betree_Internal_t -> betree_Node_t
+| Betree_Node_Leaf : betree_Leaf_t -> betree_Node_t
(** [betree_main::betree::Params] *)
-type betree_params_t =
-{
- betree_params_min_flush_size : u64; betree_params_split_size : u64;
-}
+type betree_Params_t = { min_flush_size : u64; split_size : u64; }
(** [betree_main::betree::NodeIdCounter] *)
-type betree_node_id_counter_t = { betree_node_id_counter_next_node_id : u64; }
+type betree_NodeIdCounter_t = { next_node_id : u64; }
(** [betree_main::betree::BeTree] *)
-type betree_be_tree_t =
+type betree_BeTree_t =
{
- betree_be_tree_params : betree_params_t;
- betree_be_tree_node_id_cnt : betree_node_id_counter_t;
- betree_be_tree_root : betree_node_t;
+ params : betree_Params_t;
+ node_id_cnt : betree_NodeIdCounter_t;
+ root : betree_Node_t;
}
(** The state type used in the state-error monad *)
diff --git a/tests/fstar/betree/Primitives.fst b/tests/fstar/betree/Primitives.fst
index 9db82069..3297803c 100644
--- a/tests/fstar/betree/Primitives.fst
+++ b/tests/fstar/betree/Primitives.fst
@@ -55,8 +55,12 @@ type string = string
let is_zero (n: nat) : bool = n = 0
let decrease (n: nat{n > 0}) : nat = n - 1
-let mem_replace_fwd (a : Type0) (x : a) (y : a) : a = x
-let mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+let core_mem_replace (a : Type0) (x : a) (y : a) : a = x
+let core_mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+
+// We don't really use raw pointers for now
+type mut_raw_ptr (t : Type0) = { v : t }
+type const_raw_ptr (t : Type0) = { v : t }
(*** Scalars *)
/// Rem.: most of the following code was partially generated
@@ -100,6 +104,11 @@ type scalar_ty =
| U64
| U128
+let is_unsigned = function
+ | Isize | I8 | I16 | I32 | I64 | I128 -> false
+ | Usize | U8 | U16 | U32 | U64 | U128 -> true
+
+
let scalar_min (ty : scalar_ty) : int =
match ty with
| Isize -> isize_min
@@ -162,6 +171,15 @@ let scalar_sub (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scala
let scalar_mul (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
mk_scalar ty (x * y)
+let scalar_lxor (#ty : scalar_ty { is_unsigned ty && ty <> Usize })
+ (x : scalar ty) (y : scalar ty) : scalar ty =
+ match ty with
+ | U8 -> FStar.UInt.logxor #8 x y
+ | U16 -> FStar.UInt.logxor #16 x y
+ | U32 -> FStar.UInt.logxor #32 x y
+ | U64 -> FStar.UInt.logxor #64 x y
+ | U128 -> FStar.UInt.logxor #128 x y
+
(** Cast an integer from a [src_ty] to a [tgt_ty] *)
// TODO: check the semantics of casts in Rust
let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) =
@@ -169,17 +187,44 @@ let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) :
/// The scalar types
type isize : eqtype = scalar Isize
-type i8 : eqtype = scalar I8
-type i16 : eqtype = scalar I16
-type i32 : eqtype = scalar I32
-type i64 : eqtype = scalar I64
-type i128 : eqtype = scalar I128
+type i8 : eqtype = scalar I8
+type i16 : eqtype = scalar I16
+type i32 : eqtype = scalar I32
+type i64 : eqtype = scalar I64
+type i128 : eqtype = scalar I128
type usize : eqtype = scalar Usize
-type u8 : eqtype = scalar U8
-type u16 : eqtype = scalar U16
-type u32 : eqtype = scalar U32
-type u64 : eqtype = scalar U64
-type u128 : eqtype = scalar U128
+type u8 : eqtype = scalar U8
+type u16 : eqtype = scalar U16
+type u32 : eqtype = scalar U32
+type u64 : eqtype = scalar U64
+type u128 : eqtype = scalar U128
+
+
+let core_isize_min : isize = isize_min
+let core_isize_max : isize = isize_max
+let core_i8_min : i8 = i8_min
+let core_i8_max : i8 = i8_max
+let core_i16_min : i16 = i16_min
+let core_i16_max : i16 = i16_max
+let core_i32_min : i32 = i32_min
+let core_i32_max : i32 = i32_max
+let core_i64_min : i64 = i64_min
+let core_i64_max : i64 = i64_max
+let core_i128_min : i128 = i128_min
+let core_i128_max : i128 = i128_max
+
+let core_usize_min : usize = usize_min
+let core_usize_max : usize = usize_max
+let core_u8_min : u8 = u8_min
+let core_u8_max : u8 = u8_max
+let core_u16_min : u16 = u16_min
+let core_u16_max : u16 = u16_max
+let core_u32_min : u32 = u32_min
+let core_u32_max : u32 = u32_max
+let core_u64_min : u64 = u64_min
+let core_u64_max : u64 = u64_max
+let core_u128_min : u128 = u128_min
+let core_u128_max : u128 = u128_max
/// Negation
let isize_neg = scalar_neg #Isize
@@ -231,7 +276,7 @@ let u32_add = scalar_add #U32
let u64_add = scalar_add #U64
let u128_add = scalar_add #U128
-/// Substraction
+/// Subtraction
let isize_sub = scalar_sub #Isize
let i8_sub = scalar_sub #I8
let i16_sub = scalar_sub #I16
@@ -259,12 +304,65 @@ let u32_mul = scalar_mul #U32
let u64_mul = scalar_mul #U64
let u128_mul = scalar_mul #U128
-(*** Range *)
-type range (a : Type0) = {
+/// Logical operators, defined for unsigned types only, so far
+let u8_xor = scalar_lxor #U8
+let u16_xor = scalar_lxor #U16
+let u32_xor = scalar_lxor #U32
+let u64_xor = scalar_lxor #U64
+let u128_xor = scalar_lxor #U128
+
+(*** core::ops *)
+
+// Trait declaration: [core::ops::index::Index]
+noeq type core_ops_index_Index (self idx : Type0) = {
+ output : Type0;
+ index : self → idx → result output
+}
+
+// Trait declaration: [core::ops::index::IndexMut]
+noeq type core_ops_index_IndexMut (self idx : Type0) = {
+ indexInst : core_ops_index_Index self idx;
+ index_mut : self → idx → result indexInst.output;
+ index_mut_back : self → idx → indexInst.output → result self;
+}
+
+// Trait declaration [core::ops::deref::Deref]
+noeq type core_ops_deref_Deref (self : Type0) = {
+ target : Type0;
+ deref : self → result target;
+}
+
+// Trait declaration [core::ops::deref::DerefMut]
+noeq type core_ops_deref_DerefMut (self : Type0) = {
+ derefInst : core_ops_deref_Deref self;
+ deref_mut : self → result derefInst.target;
+ deref_mut_back : self → derefInst.target → result self;
+}
+
+type core_ops_range_Range (a : Type0) = {
start : a;
end_ : a;
}
+(*** [alloc] *)
+
+let alloc_boxed_Box_deref (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut_back (t : Type) (_ : t) (x : t) : result t = Return x
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefInst (self : Type0) : core_ops_deref_Deref self = {
+ target = self;
+ deref = alloc_boxed_Box_deref self;
+}
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefMutInst (self : Type0) : core_ops_deref_DerefMut self = {
+ derefInst = alloc_boxed_Box_coreOpsDerefInst self;
+ deref_mut = alloc_boxed_Box_deref_mut self;
+ deref_mut_back = alloc_boxed_Box_deref_mut_back self;
+}
+
(*** Array *)
type array (a : Type0) (n : usize) = s:list a{length s = n}
@@ -278,15 +376,11 @@ let mk_array (a : Type0) (n : usize)
normalize_term_spec (FStar.List.Tot.length l);
l
-let array_index_shared (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let array_index_mut_fwd (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
+let array_index_usize (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let array_index_mut_back (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
+let array_update_usize (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
if i < length x then Return (list_update x i nx)
else Fail Failure
@@ -295,55 +389,54 @@ type slice (a : Type0) = s:list a{length s <= usize_max}
let slice_len (a : Type0) (s : slice a) : usize = length s
-let slice_index_shared (a : Type0) (x : slice a) (i : usize) : result a =
+let slice_index_usize (a : Type0) (x : slice a) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let slice_index_mut_fwd (a : Type0) (x : slice a) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let slice_index_mut_back (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
+let slice_update_usize (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
if i < length x then Return (list_update x i nx)
else Fail Failure
(*** Subslices *)
-let array_to_slice_shared (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_fwd (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_back (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
+let array_to_slice (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
+let array_from_slice (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
if length s = n then Return s
else Fail Failure
// TODO: finish the definitions below (there lacks [List.drop] and [List.take] in the standard library *)
-let array_subslice_shared (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
- admit()
-
-let array_subslice_mut_fwd (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
+let array_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let array_subslice_mut_back (a : Type0) (n : usize) (x : array a n) (r : range usize) (ns : slice a) : result (array a n) =
+let array_update_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) (ns : slice a) : result (array a n) =
admit()
-let slice_subslice_shared (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let array_repeat (a : Type0) (n : usize) (x : a) : array a n =
admit()
-let slice_subslice_mut_fwd (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let slice_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let slice_subslice_mut_back (a : Type0) (x : slice a) (r : range usize) (ns : slice a) : result (slice a) =
+let slice_update_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) (ns : slice a) : result (slice a) =
admit()
(*** Vector *)
-type vec (a : Type0) = v:list a{length v <= usize_max}
+type alloc_vec_Vec (a : Type0) = v:list a{length v <= usize_max}
-let vec_new (a : Type0) : vec a = assert_norm(length #a [] == 0); []
-let vec_len (a : Type0) (v : vec a) : usize = length v
+let alloc_vec_Vec_new (a : Type0) : alloc_vec_Vec a = assert_norm(length #a [] == 0); []
+let alloc_vec_Vec_len (a : Type0) (v : alloc_vec_Vec a) : usize = length v
+
+// Helper
+let alloc_vec_Vec_index_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) : result a =
+ if i < length v then Return (index v i) else Fail Failure
+// Helper
+let alloc_vec_Vec_update_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
// The **forward** function shouldn't be used
-let vec_push_fwd (a : Type0) (v : vec a) (x : a) : unit = ()
-let vec_push_back (a : Type0) (v : vec a) (x : a) :
- Pure (result (vec a))
+let alloc_vec_Vec_push_fwd (a : Type0) (v : alloc_vec_Vec a) (x : a) : unit = ()
+let alloc_vec_Vec_push (a : Type0) (v : alloc_vec_Vec a) (x : a) :
+ Pure (result (alloc_vec_Vec a))
(requires True)
(ensures (fun res ->
match res with
@@ -358,18 +451,279 @@ let vec_push_back (a : Type0) (v : vec a) (x : a) :
else Fail Failure
// The **forward** function shouldn't be used
-let vec_insert_fwd (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
+let alloc_vec_Vec_insert_fwd (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result unit =
if i < length v then Return () else Fail Failure
-let vec_insert_back (a : Type0) (v : vec a) (i : usize) (x : a) : result (vec a) =
+let alloc_vec_Vec_insert (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
if i < length v then Return (list_update v i x) else Fail Failure
-// The **backward** function shouldn't be used
-let vec_index_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_back (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
- if i < length v then Return () else Fail Failure
+// Trait declaration: [core::slice::index::private_slice_index::Sealed]
+type core_slice_index_private_slice_index_Sealed (self : Type0) = unit
+
+// Trait declaration: [core::slice::index::SliceIndex]
+noeq type core_slice_index_SliceIndex (self t : Type0) = {
+ sealedInst : core_slice_index_private_slice_index_Sealed self;
+ output : Type0;
+ get : self → t → result (option output);
+ get_mut : self → t → result (option output);
+ get_mut_back : self → t → option output → result t;
+ get_unchecked : self → const_raw_ptr t → result (const_raw_ptr output);
+ get_unchecked_mut : self → mut_raw_ptr t → result (mut_raw_ptr output);
+ index : self → t → result output;
+ index_mut : self → t → result output;
+ index_mut_back : self → t → output → result t;
+}
-let vec_index_mut_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_mut_back (a : Type0) (v : vec a) (i : usize) (nx : a) : result (vec a) =
- if i < length v then Return (list_update v i nx) else Fail Failure
+// [core::slice::index::[T]::index]: forward function
+let core_slice_index_Slice_index
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (s : slice t) (i : idx) : result inst.output =
+ let* x = inst.get i s in
+ match x with
+ | None -> Fail Failure
+ | Some x -> Return x
+
+// [core::slice::index::Range:::get]: forward function
+let core_slice_index_Range_get (t : Type0) (i : core_ops_range_Range usize) (s : slice t) :
+ result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: forward function
+let core_slice_index_Range_get_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: backward function 0
+let core_slice_index_Range_get_mut_back
+ (t : Type0) :
+ core_ops_range_Range usize → slice t → option (slice t) → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_unchecked]: forward function
+let core_slice_index_Range_get_unchecked
+ (t : Type0) :
+ core_ops_range_Range usize → const_raw_ptr (slice t) → result (const_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::get_unchecked_mut]: forward function
+let core_slice_index_Range_get_unchecked_mut
+ (t : Type0) :
+ core_ops_range_Range usize → mut_raw_ptr (slice t) → result (mut_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::index]: forward function
+let core_slice_index_Range_index
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: forward function
+let core_slice_index_Range_index_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: backward function 0
+let core_slice_index_Range_index_mut_back
+ (t : Type0) : core_ops_range_Range usize → slice t → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::[T]::index_mut]: forward function
+let core_slice_index_Slice_index_mut
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → result inst.output =
+ admit () //
+
+// [core::slice::index::[T]::index_mut]: backward function 0
+let core_slice_index_Slice_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → inst.output → result (slice t) =
+ admit () // TODO
+
+// [core::array::[T; N]::index]: forward function
+let core_array_Array_index
+ (t idx : Type0) (n : usize) (inst : core_ops_index_Index (slice t) idx)
+ (a : array t n) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: forward function
+let core_array_Array_index_mut
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) : result inst.indexInst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: backward function 0
+let core_array_Array_index_mut_back
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) (x : inst.indexInst.output) : result (array t n) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (slice t) idx = {
+ output = inst.output;
+ index = core_slice_index_Slice_index t idx inst;
+}
+
+// Trait implementation: [core::slice::index::private_slice_index::Range]
+let core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) = ()
+
+// Trait implementation: [core::slice::index::Range]
+let core_slice_index_Range_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ output = slice t;
+ get = core_slice_index_Range_get t;
+ get_mut = core_slice_index_Range_get_mut t;
+ get_mut_back = core_slice_index_Range_get_mut_back t;
+ get_unchecked = core_slice_index_Range_get_unchecked t;
+ get_unchecked_mut = core_slice_index_Range_get_unchecked_mut t;
+ index = core_slice_index_Range_index t;
+ index_mut = core_slice_index_Range_index_mut t;
+ index_mut_back = core_slice_index_Range_index_mut_back t;
+}
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (slice t) idx = {
+ indexInst = core_slice_index_Slice_coreopsindexIndexInst t idx inst;
+ index_mut = core_slice_index_Slice_index_mut t idx inst;
+ index_mut_back = core_slice_index_Slice_index_mut_back t idx inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_Index (slice t) idx) :
+ core_ops_index_Index (array t n) idx = {
+ output = inst.output;
+ index = core_array_Array_index t idx n inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexMutInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_IndexMut (slice t) idx) :
+ core_ops_index_IndexMut (array t n) idx = {
+ indexInst = core_array_Array_coreopsindexIndexInst t idx n inst.indexInst;
+ index_mut = core_array_Array_index_mut t idx n inst;
+ index_mut_back = core_array_Array_index_mut_back t idx n inst;
+}
+
+// [core::slice::index::usize::get]: forward function
+let core_slice_index_usize_get
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: forward function
+let core_slice_index_usize_get_mut
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: backward function 0
+let core_slice_index_usize_get_mut_back
+ (t : Type0) : usize → slice t → option t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked]: forward function
+let core_slice_index_usize_get_unchecked
+ (t : Type0) : usize → const_raw_ptr (slice t) → result (const_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked_mut]: forward function
+let core_slice_index_usize_get_unchecked_mut
+ (t : Type0) : usize → mut_raw_ptr (slice t) → result (mut_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::index]: forward function
+let core_slice_index_usize_index (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: forward function
+let core_slice_index_usize_index_mut (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: backward function 0
+let core_slice_index_usize_index_mut_back
+ (t : Type0) : usize → slice t → t → result (slice t) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::private_slice_index::usize]
+let core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize = ()
+
+// Trait implementation: [core::slice::index::usize]
+let core_slice_index_usize_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex usize (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ output = t;
+ get = core_slice_index_usize_get t;
+ get_mut = core_slice_index_usize_get_mut t;
+ get_mut_back = core_slice_index_usize_get_mut_back t;
+ get_unchecked = core_slice_index_usize_get_unchecked t;
+ get_unchecked_mut = core_slice_index_usize_get_unchecked_mut t;
+ index = core_slice_index_usize_index t;
+ index_mut = core_slice_index_usize_index_mut t;
+ index_mut_back = core_slice_index_usize_index_mut_back t;
+}
+
+// [alloc::vec::Vec::index]: forward function
+let alloc_vec_Vec_index (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: forward function
+let alloc_vec_Vec_index_mut (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: backward function 0
+let alloc_vec_Vec_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) (x : inst.output) : result (alloc_vec_Vec t) =
+ admit () // TODO
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (alloc_vec_Vec t) idx = {
+ output = inst.output;
+ index = alloc_vec_Vec_index t idx inst;
+}
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (alloc_vec_Vec t) idx = {
+ indexInst = alloc_vec_Vec_coreopsindexIndexInst t idx inst;
+ index_mut = alloc_vec_Vec_index_mut t idx inst;
+ index_mut_back = alloc_vec_Vec_index_mut_back t idx inst;
+}
+
+(*** Theorems *)
+
+let alloc_vec_Vec_index_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_back_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) :
+ Lemma (
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x ==
+ alloc_vec_Vec_update_usize v i x)
+ [SMTPat (alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x)]
+ =
+ admit()
diff --git a/tests/fstar/betree_back_stateful/BetreeMain.Clauses.Template.fst b/tests/fstar/betree_back_stateful/BetreeMain.Clauses.Template.fst
index 823df03a..8722f0bf 100644
--- a/tests/fstar/betree_back_stateful/BetreeMain.Clauses.Template.fst
+++ b/tests/fstar/betree_back_stateful/BetreeMain.Clauses.Template.fst
@@ -8,95 +8,95 @@ open BetreeMain.Types
(** [betree_main::betree::List::{1}::len]: decreases clause *)
unfold
-let betree_list_len_decreases (t : Type0) (self : betree_list_t t) : nat =
+let betree_List_len_decreases (t : Type0) (self : betree_List_t t) : nat =
admit ()
(** [betree_main::betree::List::{1}::split_at]: decreases clause *)
unfold
-let betree_list_split_at_decreases (t : Type0) (self : betree_list_t t)
+let betree_List_split_at_decreases (t : Type0) (self : betree_List_t t)
(n : u64) : nat =
admit ()
(** [betree_main::betree::List::{2}::partition_at_pivot]: decreases clause *)
unfold
-let betree_list_partition_at_pivot_decreases (t : Type0)
- (self : betree_list_t (u64 & t)) (pivot : u64) : nat =
+let betree_List_partition_at_pivot_decreases (t : Type0)
+ (self : betree_List_t (u64 & t)) (pivot : u64) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: decreases clause *)
unfold
-let betree_node_lookup_first_message_for_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_lookup_first_message_for_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::apply_upserts]: decreases clause *)
unfold
-let betree_node_apply_upserts_decreases
- (msgs : betree_list_t (u64 & betree_message_t)) (prev : option u64)
+let betree_Node_apply_upserts_decreases
+ (msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
(key : u64) (st : state) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup_in_bindings]: decreases clause *)
unfold
-let betree_node_lookup_in_bindings_decreases (key : u64)
- (bindings : betree_list_t (u64 & u64)) : nat =
+let betree_Node_lookup_in_bindings_decreases (key : u64)
+ (bindings : betree_List_t (u64 & u64)) : nat =
admit ()
(** [betree_main::betree::Internal::{4}::lookup_in_children]: decreases clause *)
unfold
-let betree_internal_lookup_in_children_decreases (self : betree_internal_t)
+let betree_Internal_lookup_in_children_decreases (self : betree_Internal_t)
(key : u64) (st : state) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup]: decreases clause *)
unfold
-let betree_node_lookup_decreases (self : betree_node_t) (key : u64)
+let betree_Node_lookup_decreases (self : betree_Node_t) (key : u64)
(st : state) : nat =
admit ()
(** [betree_main::betree::Node::{5}::filter_messages_for_key]: decreases clause *)
unfold
-let betree_node_filter_messages_for_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_filter_messages_for_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: decreases clause *)
unfold
-let betree_node_lookup_first_message_after_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_lookup_first_message_after_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::apply_messages_to_internal]: decreases clause *)
unfold
-let betree_node_apply_messages_to_internal_decreases
- (msgs : betree_list_t (u64 & betree_message_t))
- (new_msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_apply_messages_to_internal_decreases
+ (msgs : betree_List_t (u64 & betree_Message_t))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: decreases clause *)
unfold
-let betree_node_lookup_mut_in_bindings_decreases (key : u64)
- (bindings : betree_list_t (u64 & u64)) : nat =
+let betree_Node_lookup_mut_in_bindings_decreases (key : u64)
+ (bindings : betree_List_t (u64 & u64)) : nat =
admit ()
(** [betree_main::betree::Node::{5}::apply_messages_to_leaf]: decreases clause *)
unfold
-let betree_node_apply_messages_to_leaf_decreases
- (bindings : betree_list_t (u64 & u64))
- (new_msgs : betree_list_t (u64 & betree_message_t)) : nat =
+let betree_Node_apply_messages_to_leaf_decreases
+ (bindings : betree_List_t (u64 & u64))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) : nat =
admit ()
(** [betree_main::betree::Internal::{4}::flush]: decreases clause *)
unfold
-let betree_internal_flush_decreases (self : betree_internal_t)
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) : nat =
+let betree_Internal_flush_decreases (self : betree_Internal_t)
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) : nat =
admit ()
(** [betree_main::betree::Node::{5}::apply_messages]: decreases clause *)
unfold
-let betree_node_apply_messages_decreases (self : betree_node_t)
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) : nat =
+let betree_Node_apply_messages_decreases (self : betree_Node_t)
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) : nat =
admit ()
diff --git a/tests/fstar/betree_back_stateful/BetreeMain.Clauses.fst b/tests/fstar/betree_back_stateful/BetreeMain.Clauses.fst
index 07484711..cda7b920 100644
--- a/tests/fstar/betree_back_stateful/BetreeMain.Clauses.fst
+++ b/tests/fstar/betree_back_stateful/BetreeMain.Clauses.fst
@@ -8,8 +8,8 @@ open BetreeMain.Types
(*** Well-founded relations *)
(* We had a few issues when proving termination of the mutually recursive functions:
- * - betree_internal_flush
- * - betree_node_apply_messages
+ * - betree_Internal_flush
+ * - betree_Node_apply_messages
*
* The quantity which effectively decreases is:
* (betree_size, messages_length)
@@ -103,108 +103,108 @@ let wf_nat_pair_lem (p0 p1 : nat_pair) :
(** [betree_main::betree::List::{1}::len]: decreases clause *)
unfold
-let betree_list_len_decreases (t : Type0) (self : betree_list_t t) : betree_list_t t =
+let betree_List_len_decreases (t : Type0) (self : betree_List_t t) : betree_List_t t =
self
(** [betree_main::betree::List::{1}::split_at]: decreases clause *)
unfold
-let betree_list_split_at_decreases (t : Type0) (self : betree_list_t t)
+let betree_List_split_at_decreases (t : Type0) (self : betree_List_t t)
(n : u64) : nat =
n
(** [betree_main::betree::List::{2}::partition_at_pivot]: decreases clause *)
unfold
-let betree_list_partition_at_pivot_decreases (t : Type0)
- (self : betree_list_t (u64 & t)) (pivot : u64) : betree_list_t (u64 & t) =
+let betree_List_partition_at_pivot_decreases (t : Type0)
+ (self : betree_List_t (u64 & t)) (pivot : u64) : betree_List_t (u64 & t) =
self
(** [betree_main::betree::Node::{5}::lookup_in_bindings]: decreases clause *)
unfold
-let betree_node_lookup_in_bindings_decreases (key : u64)
- (bindings : betree_list_t (u64 & u64)) : betree_list_t (u64 & u64) =
+let betree_Node_lookup_in_bindings_decreases (key : u64)
+ (bindings : betree_List_t (u64 & u64)) : betree_List_t (u64 & u64) =
bindings
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: decreases clause *)
unfold
-let betree_node_lookup_first_message_for_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_lookup_first_message_for_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Node::{5}::apply_upserts]: decreases clause *)
unfold
-let betree_node_apply_upserts_decreases
- (msgs : betree_list_t (u64 & betree_message_t)) (prev : option u64)
- (key : u64) (st : state) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_apply_upserts_decreases
+ (msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
+ (key : u64) (st : state) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Internal::{4}::lookup_in_children]: decreases clause *)
unfold
-let betree_internal_lookup_in_children_decreases (self : betree_internal_t)
- (key : u64) (st : state) : betree_internal_t =
+let betree_Internal_lookup_in_children_decreases (self : betree_Internal_t)
+ (key : u64) (st : state) : betree_Internal_t =
self
(** [betree_main::betree::Node::{5}::lookup]: decreases clause *)
unfold
-let betree_node_lookup_decreases (self : betree_node_t) (key : u64)
- (st : state) : betree_node_t =
+let betree_Node_lookup_decreases (self : betree_Node_t) (key : u64)
+ (st : state) : betree_Node_t =
self
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: decreases clause *)
unfold
-let betree_node_lookup_mut_in_bindings_decreases (key : u64)
- (bindings : betree_list_t (u64 & u64)) : betree_list_t (u64 & u64) =
+let betree_Node_lookup_mut_in_bindings_decreases (key : u64)
+ (bindings : betree_List_t (u64 & u64)) : betree_List_t (u64 & u64) =
bindings
unfold
-let betree_node_apply_messages_to_leaf_decreases
- (bindings : betree_list_t (u64 & u64))
- (new_msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_apply_messages_to_leaf_decreases
+ (bindings : betree_List_t (u64 & u64))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
new_msgs
(** [betree_main::betree::Node::{5}::filter_messages_for_key]: decreases clause *)
unfold
-let betree_node_filter_messages_for_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_filter_messages_for_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: decreases clause *)
unfold
-let betree_node_lookup_first_message_after_key_decreases (key : u64)
- (msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_lookup_first_message_after_key_decreases (key : u64)
+ (msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
-let betree_node_apply_messages_to_internal_decreases
- (msgs : betree_list_t (u64 & betree_message_t))
- (new_msgs : betree_list_t (u64 & betree_message_t)) : betree_list_t (u64 & betree_message_t) =
+let betree_Node_apply_messages_to_internal_decreases
+ (msgs : betree_List_t (u64 & betree_Message_t))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
new_msgs
(*** Decrease clauses - nat_pair *)
/// The following decrease clauses use the [nat_pair] definition and the well-founded
/// relation proven above.
-let rec betree_size (bt : betree_node_t) : nat =
+let rec betree_size (bt : betree_Node_t) : nat =
match bt with
- | BetreeNodeInternal node -> 1 + betree_internal_size node
- | BetreeNodeLeaf _ -> 1
+ | Betree_Node_Internal node -> 1 + betree_Internal_size node
+ | Betree_Node_Leaf _ -> 1
-and betree_internal_size (node : betree_internal_t) : nat =
- 1 + betree_size node.betree_internal_left + betree_size node.betree_internal_right
+and betree_Internal_size (node : betree_Internal_t) : nat =
+ 1 + betree_size node.left + betree_size node.right
-let rec betree_list_len (#a : Type0) (ls : betree_list_t a) : nat =
+let rec betree_List_len (#a : Type0) (ls : betree_List_t a) : nat =
match ls with
- | BetreeListCons _ tl -> 1 + betree_list_len tl
- | BetreeListNil -> 0
+ | Betree_List_Cons _ tl -> 1 + betree_List_len tl
+ | Betree_List_Nil -> 0
(** [betree_main::betree::Internal::{4}::flush]: decreases clause *)
unfold
-let betree_internal_flush_decreases (self : betree_internal_t)
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) : nat_pair =
- (|betree_internal_size self, 0|)
+let betree_Internal_flush_decreases (self : betree_Internal_t)
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) : nat_pair =
+ (|betree_Internal_size self, 0|)
(** [betree_main::betree::Node::{5}::apply_messages]: decreases clause *)
unfold
-let betree_node_apply_messages_decreases (self : betree_node_t)
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) : nat_pair =
- (|betree_size self, betree_list_len msgs|)
+let betree_Node_apply_messages_decreases (self : betree_Node_t)
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) : nat_pair =
+ (|betree_size self, betree_List_len msgs|)
diff --git a/tests/fstar/betree_back_stateful/BetreeMain.Funs.fst b/tests/fstar/betree_back_stateful/BetreeMain.Funs.fst
index 3d08cd3c..08c4f615 100644
--- a/tests/fstar/betree_back_stateful/BetreeMain.Funs.fst
+++ b/tests/fstar/betree_back_stateful/BetreeMain.Funs.fst
@@ -9,35 +9,35 @@ include BetreeMain.Clauses
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [betree_main::betree::load_internal_node]: forward function *)
-let betree_load_internal_node_fwd
+let betree_load_internal_node
(id : u64) (st : state) :
- result (state & (betree_list_t (u64 & betree_message_t)))
+ result (state & (betree_List_t (u64 & betree_Message_t)))
=
- betree_utils_load_internal_node_fwd id st
+ betree_utils_load_internal_node id st
(** [betree_main::betree::store_internal_node]: forward function *)
-let betree_store_internal_node_fwd
- (id : u64) (content : betree_list_t (u64 & betree_message_t)) (st : state) :
+let betree_store_internal_node
+ (id : u64) (content : betree_List_t (u64 & betree_Message_t)) (st : state) :
result (state & unit)
=
- let* (st0, _) = betree_utils_store_internal_node_fwd id content st in
+ let* (st0, _) = betree_utils_store_internal_node id content st in
Return (st0, ())
(** [betree_main::betree::load_leaf_node]: forward function *)
-let betree_load_leaf_node_fwd
- (id : u64) (st : state) : result (state & (betree_list_t (u64 & u64))) =
- betree_utils_load_leaf_node_fwd id st
+let betree_load_leaf_node
+ (id : u64) (st : state) : result (state & (betree_List_t (u64 & u64))) =
+ betree_utils_load_leaf_node id st
(** [betree_main::betree::store_leaf_node]: forward function *)
-let betree_store_leaf_node_fwd
- (id : u64) (content : betree_list_t (u64 & u64)) (st : state) :
+let betree_store_leaf_node
+ (id : u64) (content : betree_List_t (u64 & u64)) (st : state) :
result (state & unit)
=
- let* (st0, _) = betree_utils_store_leaf_node_fwd id content st in
+ let* (st0, _) = betree_utils_store_leaf_node id content st in
Return (st0, ())
(** [betree_main::betree::fresh_node_id]: forward function *)
-let betree_fresh_node_id_fwd (counter : u64) : result u64 =
+let betree_fresh_node_id (counter : u64) : result u64 =
let* _ = u64_add counter 1 in Return counter
(** [betree_main::betree::fresh_node_id]: backward function 0 *)
@@ -45,1208 +45,1123 @@ let betree_fresh_node_id_back (counter : u64) : result u64 =
u64_add counter 1
(** [betree_main::betree::NodeIdCounter::{0}::new]: forward function *)
-let betree_node_id_counter_new_fwd : result betree_node_id_counter_t =
- Return { betree_node_id_counter_next_node_id = 0 }
+let betree_NodeIdCounter_new : result betree_NodeIdCounter_t =
+ Return { next_node_id = 0 }
(** [betree_main::betree::NodeIdCounter::{0}::fresh_id]: forward function *)
-let betree_node_id_counter_fresh_id_fwd
- (self : betree_node_id_counter_t) : result u64 =
- let* _ = u64_add self.betree_node_id_counter_next_node_id 1 in
- Return self.betree_node_id_counter_next_node_id
+let betree_NodeIdCounter_fresh_id
+ (self : betree_NodeIdCounter_t) : result u64 =
+ let* _ = u64_add self.next_node_id 1 in Return self.next_node_id
(** [betree_main::betree::NodeIdCounter::{0}::fresh_id]: backward function 0 *)
-let betree_node_id_counter_fresh_id_back
- (self : betree_node_id_counter_t) : result betree_node_id_counter_t =
- let* i = u64_add self.betree_node_id_counter_next_node_id 1 in
- Return { betree_node_id_counter_next_node_id = i }
-
-(** [core::num::u64::{9}::MAX] *)
-let core_num_u64_max_body : result u64 = Return 18446744073709551615
-let core_num_u64_max_c : u64 = eval_global core_num_u64_max_body
+let betree_NodeIdCounter_fresh_id_back
+ (self : betree_NodeIdCounter_t) : result betree_NodeIdCounter_t =
+ let* i = u64_add self.next_node_id 1 in Return { next_node_id = i }
(** [betree_main::betree::upsert_update]: forward function *)
-let betree_upsert_update_fwd
- (prev : option u64) (st : betree_upsert_fun_state_t) : result u64 =
+let betree_upsert_update
+ (prev : option u64) (st : betree_UpsertFunState_t) : result u64 =
begin match prev with
| None ->
begin match st with
- | BetreeUpsertFunStateAdd v -> Return v
- | BetreeUpsertFunStateSub i -> Return 0
+ | Betree_UpsertFunState_Add v -> Return v
+ | Betree_UpsertFunState_Sub i -> Return 0
end
| Some prev0 ->
begin match st with
- | BetreeUpsertFunStateAdd v ->
- let* margin = u64_sub core_num_u64_max_c prev0 in
- if margin >= v then u64_add prev0 v else Return core_num_u64_max_c
- | BetreeUpsertFunStateSub v ->
+ | Betree_UpsertFunState_Add v ->
+ let* margin = u64_sub core_u64_max prev0 in
+ if margin >= v then u64_add prev0 v else Return core_u64_max
+ | Betree_UpsertFunState_Sub v ->
if prev0 >= v then u64_sub prev0 v else Return 0
end
end
(** [betree_main::betree::List::{1}::len]: forward function *)
-let rec betree_list_len_fwd
- (t : Type0) (self : betree_list_t t) :
- Tot (result u64) (decreases (betree_list_len_decreases t self))
+let rec betree_List_len
+ (t : Type0) (self : betree_List_t t) :
+ Tot (result u64) (decreases (betree_List_len_decreases t self))
=
begin match self with
- | BetreeListCons x tl -> let* i = betree_list_len_fwd t tl in u64_add 1 i
- | BetreeListNil -> Return 0
+ | Betree_List_Cons x tl -> let* i = betree_List_len t tl in u64_add 1 i
+ | Betree_List_Nil -> Return 0
end
(** [betree_main::betree::List::{1}::split_at]: forward function *)
-let rec betree_list_split_at_fwd
- (t : Type0) (self : betree_list_t t) (n : u64) :
- Tot (result ((betree_list_t t) & (betree_list_t t)))
- (decreases (betree_list_split_at_decreases t self n))
+let rec betree_List_split_at
+ (t : Type0) (self : betree_List_t t) (n : u64) :
+ Tot (result ((betree_List_t t) & (betree_List_t t)))
+ (decreases (betree_List_split_at_decreases t self n))
=
if n = 0
- then Return (BetreeListNil, self)
+ then Return (Betree_List_Nil, self)
else
begin match self with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let* i = u64_sub n 1 in
- let* p = betree_list_split_at_fwd t tl i in
+ let* p = betree_List_split_at t tl i in
let (ls0, ls1) = p in
let l = ls0 in
- Return (BetreeListCons hd l, ls1)
- | BetreeListNil -> Fail Failure
+ Return (Betree_List_Cons hd l, ls1)
+ | Betree_List_Nil -> Fail Failure
end
(** [betree_main::betree::List::{1}::push_front]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let betree_list_push_front_fwd_back
- (t : Type0) (self : betree_list_t t) (x : t) : result (betree_list_t t) =
- let tl = mem_replace_fwd (betree_list_t t) self BetreeListNil in
+let betree_List_push_front
+ (t : Type0) (self : betree_List_t t) (x : t) : result (betree_List_t t) =
+ let tl = core_mem_replace (betree_List_t t) self Betree_List_Nil in
let l = tl in
- Return (BetreeListCons x l)
+ Return (Betree_List_Cons x l)
(** [betree_main::betree::List::{1}::pop_front]: forward function *)
-let betree_list_pop_front_fwd (t : Type0) (self : betree_list_t t) : result t =
- let ls = mem_replace_fwd (betree_list_t t) self BetreeListNil in
+let betree_List_pop_front (t : Type0) (self : betree_List_t t) : result t =
+ let ls = core_mem_replace (betree_List_t t) self Betree_List_Nil in
begin match ls with
- | BetreeListCons x tl -> Return x
- | BetreeListNil -> Fail Failure
+ | Betree_List_Cons x tl -> Return x
+ | Betree_List_Nil -> Fail Failure
end
(** [betree_main::betree::List::{1}::pop_front]: backward function 0 *)
-let betree_list_pop_front_back
- (t : Type0) (self : betree_list_t t) : result (betree_list_t t) =
- let ls = mem_replace_fwd (betree_list_t t) self BetreeListNil in
+let betree_List_pop_front_back
+ (t : Type0) (self : betree_List_t t) : result (betree_List_t t) =
+ let ls = core_mem_replace (betree_List_t t) self Betree_List_Nil in
begin match ls with
- | BetreeListCons x tl -> Return tl
- | BetreeListNil -> Fail Failure
+ | Betree_List_Cons x tl -> Return tl
+ | Betree_List_Nil -> Fail Failure
end
(** [betree_main::betree::List::{1}::hd]: forward function *)
-let betree_list_hd_fwd (t : Type0) (self : betree_list_t t) : result t =
+let betree_List_hd (t : Type0) (self : betree_List_t t) : result t =
begin match self with
- | BetreeListCons hd l -> Return hd
- | BetreeListNil -> Fail Failure
+ | Betree_List_Cons hd l -> Return hd
+ | Betree_List_Nil -> Fail Failure
end
(** [betree_main::betree::List::{2}::head_has_key]: forward function *)
-let betree_list_head_has_key_fwd
- (t : Type0) (self : betree_list_t (u64 & t)) (key : u64) : result bool =
+let betree_List_head_has_key
+ (t : Type0) (self : betree_List_t (u64 & t)) (key : u64) : result bool =
begin match self with
- | BetreeListCons hd l -> let (i, _) = hd in Return (i = key)
- | BetreeListNil -> Return false
+ | Betree_List_Cons hd l -> let (i, _) = hd in Return (i = key)
+ | Betree_List_Nil -> Return false
end
(** [betree_main::betree::List::{2}::partition_at_pivot]: forward function *)
-let rec betree_list_partition_at_pivot_fwd
- (t : Type0) (self : betree_list_t (u64 & t)) (pivot : u64) :
- Tot (result ((betree_list_t (u64 & t)) & (betree_list_t (u64 & t))))
- (decreases (betree_list_partition_at_pivot_decreases t self pivot))
+let rec betree_List_partition_at_pivot
+ (t : Type0) (self : betree_List_t (u64 & t)) (pivot : u64) :
+ Tot (result ((betree_List_t (u64 & t)) & (betree_List_t (u64 & t))))
+ (decreases (betree_List_partition_at_pivot_decreases t self pivot))
=
begin match self with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let (i, x) = hd in
if i >= pivot
- then Return (BetreeListNil, BetreeListCons (i, x) tl)
+ then Return (Betree_List_Nil, Betree_List_Cons (i, x) tl)
else
- let* p = betree_list_partition_at_pivot_fwd t tl pivot in
+ let* p = betree_List_partition_at_pivot t tl pivot in
let (ls0, ls1) = p in
let l = ls0 in
- Return (BetreeListCons (i, x) l, ls1)
- | BetreeListNil -> Return (BetreeListNil, BetreeListNil)
+ Return (Betree_List_Cons (i, x) l, ls1)
+ | Betree_List_Nil -> Return (Betree_List_Nil, Betree_List_Nil)
end
(** [betree_main::betree::Leaf::{3}::split]: forward function *)
-let betree_leaf_split_fwd
- (self : betree_leaf_t) (content : betree_list_t (u64 & u64))
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
+let betree_Leaf_split
+ (self : betree_Leaf_t) (content : betree_List_t (u64 & u64))
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(st : state) :
- result (state & betree_internal_t)
+ result (state & betree_Internal_t)
=
- let* p =
- betree_list_split_at_fwd (u64 & u64) content
- params.betree_params_split_size in
+ let* p = betree_List_split_at (u64 & u64) content params.split_size in
let (content0, content1) = p in
- let* p0 = betree_list_hd_fwd (u64 & u64) content1 in
+ let* p0 = betree_List_hd (u64 & u64) content1 in
let (pivot, _) = p0 in
- let* id0 = betree_node_id_counter_fresh_id_fwd node_id_cnt in
- let* node_id_cnt0 = betree_node_id_counter_fresh_id_back node_id_cnt in
- let* id1 = betree_node_id_counter_fresh_id_fwd node_id_cnt0 in
- let* (st0, _) = betree_store_leaf_node_fwd id0 content0 st in
- let* (st1, _) = betree_store_leaf_node_fwd id1 content1 st0 in
- let n = BetreeNodeLeaf
- { betree_leaf_id = id0; betree_leaf_size = params.betree_params_split_size
- } in
- let n0 = BetreeNodeLeaf
- { betree_leaf_id = id1; betree_leaf_size = params.betree_params_split_size
- } in
- Return (st1,
- {
- betree_internal_id = self.betree_leaf_id;
- betree_internal_pivot = pivot;
- betree_internal_left = n;
- betree_internal_right = n0
- })
+ let* id0 = betree_NodeIdCounter_fresh_id node_id_cnt in
+ let* node_id_cnt0 = betree_NodeIdCounter_fresh_id_back node_id_cnt in
+ let* id1 = betree_NodeIdCounter_fresh_id node_id_cnt0 in
+ let* (st0, _) = betree_store_leaf_node id0 content0 st in
+ let* (st1, _) = betree_store_leaf_node id1 content1 st0 in
+ let n = Betree_Node_Leaf { id = id0; size = params.split_size } in
+ let n0 = Betree_Node_Leaf { id = id1; size = params.split_size } in
+ Return (st1, { id = self.id; pivot = pivot; left = n; right = n0 })
(** [betree_main::betree::Leaf::{3}::split]: backward function 0 *)
-let betree_leaf_split_back0
- (self : betree_leaf_t) (content : betree_list_t (u64 & u64))
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
+let betree_Leaf_split_back0
+ (self : betree_Leaf_t) (content : betree_List_t (u64 & u64))
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(st : state) (st0 : state) :
result (state & unit)
=
- let* p =
- betree_list_split_at_fwd (u64 & u64) content
- params.betree_params_split_size in
+ let* p = betree_List_split_at (u64 & u64) content params.split_size in
let (content0, content1) = p in
- let* _ = betree_list_hd_fwd (u64 & u64) content1 in
- let* id0 = betree_node_id_counter_fresh_id_fwd node_id_cnt in
- let* node_id_cnt0 = betree_node_id_counter_fresh_id_back node_id_cnt in
- let* id1 = betree_node_id_counter_fresh_id_fwd node_id_cnt0 in
- let* (st1, _) = betree_store_leaf_node_fwd id0 content0 st in
- let* _ = betree_store_leaf_node_fwd id1 content1 st1 in
+ let* _ = betree_List_hd (u64 & u64) content1 in
+ let* id0 = betree_NodeIdCounter_fresh_id node_id_cnt in
+ let* node_id_cnt0 = betree_NodeIdCounter_fresh_id_back node_id_cnt in
+ let* id1 = betree_NodeIdCounter_fresh_id node_id_cnt0 in
+ let* (st1, _) = betree_store_leaf_node id0 content0 st in
+ let* _ = betree_store_leaf_node id1 content1 st1 in
Return (st0, ())
(** [betree_main::betree::Leaf::{3}::split]: backward function 1 *)
-let betree_leaf_split_back1
- (self : betree_leaf_t) (content : betree_list_t (u64 & u64))
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
+let betree_Leaf_split_back1
+ (self : betree_Leaf_t) (content : betree_List_t (u64 & u64))
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(st : state) (st0 : state) :
result (state & unit)
=
- let* p =
- betree_list_split_at_fwd (u64 & u64) content
- params.betree_params_split_size in
+ let* p = betree_List_split_at (u64 & u64) content params.split_size in
let (content0, content1) = p in
- let* _ = betree_list_hd_fwd (u64 & u64) content1 in
- let* id0 = betree_node_id_counter_fresh_id_fwd node_id_cnt in
- let* node_id_cnt0 = betree_node_id_counter_fresh_id_back node_id_cnt in
- let* id1 = betree_node_id_counter_fresh_id_fwd node_id_cnt0 in
- let* (st1, _) = betree_store_leaf_node_fwd id0 content0 st in
- let* _ = betree_store_leaf_node_fwd id1 content1 st1 in
+ let* _ = betree_List_hd (u64 & u64) content1 in
+ let* id0 = betree_NodeIdCounter_fresh_id node_id_cnt in
+ let* node_id_cnt0 = betree_NodeIdCounter_fresh_id_back node_id_cnt in
+ let* id1 = betree_NodeIdCounter_fresh_id node_id_cnt0 in
+ let* (st1, _) = betree_store_leaf_node id0 content0 st in
+ let* _ = betree_store_leaf_node id1 content1 st1 in
Return (st0, ())
(** [betree_main::betree::Leaf::{3}::split]: backward function 2 *)
-let betree_leaf_split_back2
- (self : betree_leaf_t) (content : betree_list_t (u64 & u64))
- (params : betree_params_t) (node_id_cnt : betree_node_id_counter_t)
+let betree_Leaf_split_back2
+ (self : betree_Leaf_t) (content : betree_List_t (u64 & u64))
+ (params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(st : state) (st0 : state) :
- result (state & betree_node_id_counter_t)
+ result (state & betree_NodeIdCounter_t)
=
- let* p =
- betree_list_split_at_fwd (u64 & u64) content
- params.betree_params_split_size in
+ let* p = betree_List_split_at (u64 & u64) content params.split_size in
let (content0, content1) = p in
- let* _ = betree_list_hd_fwd (u64 & u64) content1 in
- let* id0 = betree_node_id_counter_fresh_id_fwd node_id_cnt in
- let* node_id_cnt0 = betree_node_id_counter_fresh_id_back node_id_cnt in
- let* id1 = betree_node_id_counter_fresh_id_fwd node_id_cnt0 in
- let* (st1, _) = betree_store_leaf_node_fwd id0 content0 st in
- let* _ = betree_store_leaf_node_fwd id1 content1 st1 in
- let* node_id_cnt1 = betree_node_id_counter_fresh_id_back node_id_cnt0 in
+ let* _ = betree_List_hd (u64 & u64) content1 in
+ let* id0 = betree_NodeIdCounter_fresh_id node_id_cnt in
+ let* node_id_cnt0 = betree_NodeIdCounter_fresh_id_back node_id_cnt in
+ let* id1 = betree_NodeIdCounter_fresh_id node_id_cnt0 in
+ let* (st1, _) = betree_store_leaf_node id0 content0 st in
+ let* _ = betree_store_leaf_node id1 content1 st1 in
+ let* node_id_cnt1 = betree_NodeIdCounter_fresh_id_back node_id_cnt0 in
Return (st0, node_id_cnt1)
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: forward function *)
-let rec betree_node_lookup_first_message_for_key_fwd
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_lookup_first_message_for_key_decreases key msgs))
+let rec betree_Node_lookup_first_message_for_key
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_lookup_first_message_for_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons x next_msgs ->
+ | Betree_List_Cons x next_msgs ->
let (i, m) = x in
if i >= key
- then Return (BetreeListCons (i, m) next_msgs)
- else betree_node_lookup_first_message_for_key_fwd key next_msgs
- | BetreeListNil -> Return BetreeListNil
+ then Return (Betree_List_Cons (i, m) next_msgs)
+ else betree_Node_lookup_first_message_for_key key next_msgs
+ | Betree_List_Nil -> Return Betree_List_Nil
end
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: backward function 0 *)
-let rec betree_node_lookup_first_message_for_key_back
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t))
- (ret : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_lookup_first_message_for_key_decreases key msgs))
+let rec betree_Node_lookup_first_message_for_key_back
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t))
+ (ret : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_lookup_first_message_for_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons x next_msgs ->
+ | Betree_List_Cons x next_msgs ->
let (i, m) = x in
if i >= key
then Return ret
else
let* next_msgs0 =
- betree_node_lookup_first_message_for_key_back key next_msgs ret in
- Return (BetreeListCons (i, m) next_msgs0)
- | BetreeListNil -> Return ret
+ betree_Node_lookup_first_message_for_key_back key next_msgs ret in
+ Return (Betree_List_Cons (i, m) next_msgs0)
+ | Betree_List_Nil -> Return ret
end
(** [betree_main::betree::Node::{5}::apply_upserts]: forward function *)
-let rec betree_node_apply_upserts_fwd
- (msgs : betree_list_t (u64 & betree_message_t)) (prev : option u64)
+let rec betree_Node_apply_upserts
+ (msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
(key : u64) (st : state) :
Tot (result (state & u64))
- (decreases (betree_node_apply_upserts_decreases msgs prev key st))
+ (decreases (betree_Node_apply_upserts_decreases msgs prev key st))
=
- let* b = betree_list_head_has_key_fwd betree_message_t msgs key in
+ let* b = betree_List_head_has_key betree_Message_t msgs key in
if b
then
- let* msg = betree_list_pop_front_fwd (u64 & betree_message_t) msgs in
+ let* msg = betree_List_pop_front (u64 & betree_Message_t) msgs in
let (_, m) = msg in
begin match m with
- | BetreeMessageInsert i -> Fail Failure
- | BetreeMessageDelete -> Fail Failure
- | BetreeMessageUpsert s ->
- let* v = betree_upsert_update_fwd prev s in
- let* msgs0 = betree_list_pop_front_back (u64 & betree_message_t) msgs in
- betree_node_apply_upserts_fwd msgs0 (Some v) key st
+ | Betree_Message_Insert i -> Fail Failure
+ | Betree_Message_Delete -> Fail Failure
+ | Betree_Message_Upsert s ->
+ let* v = betree_upsert_update prev s in
+ let* msgs0 = betree_List_pop_front_back (u64 & betree_Message_t) msgs in
+ betree_Node_apply_upserts msgs0 (Some v) key st
end
else
- let* (st0, v) = core_option_option_unwrap_fwd u64 prev st in
+ let* (st0, v) = core_option_Option_unwrap u64 prev st in
let* _ =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs (key,
- BetreeMessageInsert v) in
+ betree_List_push_front (u64 & betree_Message_t) msgs (key,
+ Betree_Message_Insert v) in
Return (st0, v)
(** [betree_main::betree::Node::{5}::apply_upserts]: backward function 0 *)
-let rec betree_node_apply_upserts_back
- (msgs : betree_list_t (u64 & betree_message_t)) (prev : option u64)
+let rec betree_Node_apply_upserts_back
+ (msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
(key : u64) (st : state) (st0 : state) :
- Tot (result (state & (betree_list_t (u64 & betree_message_t))))
- (decreases (betree_node_apply_upserts_decreases msgs prev key st))
+ Tot (result (state & (betree_List_t (u64 & betree_Message_t))))
+ (decreases (betree_Node_apply_upserts_decreases msgs prev key st))
=
- let* b = betree_list_head_has_key_fwd betree_message_t msgs key in
+ let* b = betree_List_head_has_key betree_Message_t msgs key in
if b
then
- let* msg = betree_list_pop_front_fwd (u64 & betree_message_t) msgs in
+ let* msg = betree_List_pop_front (u64 & betree_Message_t) msgs in
let (_, m) = msg in
begin match m with
- | BetreeMessageInsert i -> Fail Failure
- | BetreeMessageDelete -> Fail Failure
- | BetreeMessageUpsert s ->
- let* v = betree_upsert_update_fwd prev s in
- let* msgs0 = betree_list_pop_front_back (u64 & betree_message_t) msgs in
- betree_node_apply_upserts_back msgs0 (Some v) key st st0
+ | Betree_Message_Insert i -> Fail Failure
+ | Betree_Message_Delete -> Fail Failure
+ | Betree_Message_Upsert s ->
+ let* v = betree_upsert_update prev s in
+ let* msgs0 = betree_List_pop_front_back (u64 & betree_Message_t) msgs in
+ betree_Node_apply_upserts_back msgs0 (Some v) key st st0
end
else
- let* (_, v) = core_option_option_unwrap_fwd u64 prev st in
+ let* (_, v) = core_option_Option_unwrap u64 prev st in
let* msgs0 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs (key,
- BetreeMessageInsert v) in
+ betree_List_push_front (u64 & betree_Message_t) msgs (key,
+ Betree_Message_Insert v) in
Return (st0, msgs0)
(** [betree_main::betree::Node::{5}::lookup_in_bindings]: forward function *)
-let rec betree_node_lookup_in_bindings_fwd
- (key : u64) (bindings : betree_list_t (u64 & u64)) :
+let rec betree_Node_lookup_in_bindings
+ (key : u64) (bindings : betree_List_t (u64 & u64)) :
Tot (result (option u64))
- (decreases (betree_node_lookup_in_bindings_decreases key bindings))
+ (decreases (betree_Node_lookup_in_bindings_decreases key bindings))
=
begin match bindings with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let (i, i0) = hd in
if i = key
then Return (Some i0)
- else
- if i > key
- then Return None
- else betree_node_lookup_in_bindings_fwd key tl
- | BetreeListNil -> Return None
+ else if i > key then Return None else betree_Node_lookup_in_bindings key tl
+ | Betree_List_Nil -> Return None
end
(** [betree_main::betree::Internal::{4}::lookup_in_children]: forward function *)
-let rec betree_internal_lookup_in_children_fwd
- (self : betree_internal_t) (key : u64) (st : state) :
+let rec betree_Internal_lookup_in_children
+ (self : betree_Internal_t) (key : u64) (st : state) :
Tot (result (state & (option u64)))
- (decreases (betree_internal_lookup_in_children_decreases self key st))
+ (decreases (betree_Internal_lookup_in_children_decreases self key st))
=
- if key < self.betree_internal_pivot
- then betree_node_lookup_fwd self.betree_internal_left key st
- else betree_node_lookup_fwd self.betree_internal_right key st
+ if key < self.pivot
+ then betree_Node_lookup self.left key st
+ else betree_Node_lookup self.right key st
(** [betree_main::betree::Internal::{4}::lookup_in_children]: backward function 0 *)
-and betree_internal_lookup_in_children_back
- (self : betree_internal_t) (key : u64) (st : state) (st0 : state) :
- Tot (result (state & betree_internal_t))
- (decreases (betree_internal_lookup_in_children_decreases self key st))
+and betree_Internal_lookup_in_children_back
+ (self : betree_Internal_t) (key : u64) (st : state) (st0 : state) :
+ Tot (result (state & betree_Internal_t))
+ (decreases (betree_Internal_lookup_in_children_decreases self key st))
=
- if key < self.betree_internal_pivot
+ if key < self.pivot
then
- let* (st1, n) =
- betree_node_lookup_back self.betree_internal_left key st st0 in
- Return (st1, { self with betree_internal_left = n })
+ let* (st1, n) = betree_Node_lookup_back self.left key st st0 in
+ Return (st1, { self with left = n })
else
- let* (st1, n) =
- betree_node_lookup_back self.betree_internal_right key st st0 in
- Return (st1, { self with betree_internal_right = n })
+ let* (st1, n) = betree_Node_lookup_back self.right key st st0 in
+ Return (st1, { self with right = n })
(** [betree_main::betree::Node::{5}::lookup]: forward function *)
-and betree_node_lookup_fwd
- (self : betree_node_t) (key : u64) (st : state) :
+and betree_Node_lookup
+ (self : betree_Node_t) (key : u64) (st : state) :
Tot (result (state & (option u64)))
- (decreases (betree_node_lookup_decreases self key st))
+ (decreases (betree_Node_lookup_decreases self key st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st0, msgs) = betree_load_internal_node_fwd node.betree_internal_id st
- in
- let* pending = betree_node_lookup_first_message_for_key_fwd key msgs in
+ | Betree_Node_Internal node ->
+ let* (st0, msgs) = betree_load_internal_node node.id st in
+ let* pending = betree_Node_lookup_first_message_for_key key msgs in
begin match pending with
- | BetreeListCons p l ->
+ | Betree_List_Cons p l ->
let (k, msg) = p in
if k <> key
then
- let* (st1, opt) = betree_internal_lookup_in_children_fwd node key st0
- in
+ let* (st1, o) = betree_Internal_lookup_in_children node key st0 in
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, msg) l) in
- Return (st1, opt)
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, msg) l) in
+ Return (st1, o)
else
begin match msg with
- | BetreeMessageInsert v ->
+ | Betree_Message_Insert v ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, BetreeMessageInsert v) l) in
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, Betree_Message_Insert v) l) in
Return (st0, Some v)
- | BetreeMessageDelete ->
+ | Betree_Message_Delete ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, BetreeMessageDelete) l) in
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, Betree_Message_Delete) l) in
Return (st0, None)
- | BetreeMessageUpsert ufs ->
- let* (st1, v) = betree_internal_lookup_in_children_fwd node key st0
- in
+ | Betree_Message_Upsert ufs ->
+ let* (st1, v) = betree_Internal_lookup_in_children node key st0 in
let* (st2, v0) =
- betree_node_apply_upserts_fwd (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1 in
+ betree_Node_apply_upserts (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1 in
let* (st3, node0) =
- betree_internal_lookup_in_children_back node key st0 st2 in
+ betree_Internal_lookup_in_children_back node key st0 st2 in
let* (st4, pending0) =
- betree_node_apply_upserts_back (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st1 st3 in
+ betree_Node_apply_upserts_back (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st1 st3 in
let* msgs0 =
- betree_node_lookup_first_message_for_key_back key msgs pending0 in
- let* (st5, _) =
- betree_store_internal_node_fwd node0.betree_internal_id msgs0 st4
- in
+ betree_Node_lookup_first_message_for_key_back key msgs pending0 in
+ let* (st5, _) = betree_store_internal_node node0.id msgs0 st4 in
Return (st5, Some v0)
end
- | BetreeListNil ->
- let* (st1, opt) = betree_internal_lookup_in_children_fwd node key st0 in
+ | Betree_List_Nil ->
+ let* (st1, o) = betree_Internal_lookup_in_children node key st0 in
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs BetreeListNil in
- Return (st1, opt)
+ betree_Node_lookup_first_message_for_key_back key msgs Betree_List_Nil
+ in
+ Return (st1, o)
end
- | BetreeNodeLeaf node ->
- let* (st0, bindings) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* opt = betree_node_lookup_in_bindings_fwd key bindings in
- Return (st0, opt)
+ | Betree_Node_Leaf node ->
+ let* (st0, bindings) = betree_load_leaf_node node.id st in
+ let* o = betree_Node_lookup_in_bindings key bindings in
+ Return (st0, o)
end
(** [betree_main::betree::Node::{5}::lookup]: backward function 0 *)
-and betree_node_lookup_back
- (self : betree_node_t) (key : u64) (st : state) (st0 : state) :
- Tot (result (state & betree_node_t))
- (decreases (betree_node_lookup_decreases self key st))
+and betree_Node_lookup_back
+ (self : betree_Node_t) (key : u64) (st : state) (st0 : state) :
+ Tot (result (state & betree_Node_t))
+ (decreases (betree_Node_lookup_decreases self key st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st1, msgs) = betree_load_internal_node_fwd node.betree_internal_id st
- in
- let* pending = betree_node_lookup_first_message_for_key_fwd key msgs in
+ | Betree_Node_Internal node ->
+ let* (st1, msgs) = betree_load_internal_node node.id st in
+ let* pending = betree_Node_lookup_first_message_for_key key msgs in
begin match pending with
- | BetreeListCons p l ->
+ | Betree_List_Cons p l ->
let (k, msg) = p in
if k <> key
then
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, msg) l) in
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, msg) l) in
let* (st2, node0) =
- betree_internal_lookup_in_children_back node key st1 st0 in
- Return (st2, BetreeNodeInternal node0)
+ betree_Internal_lookup_in_children_back node key st1 st0 in
+ Return (st2, Betree_Node_Internal node0)
else
begin match msg with
- | BetreeMessageInsert v ->
+ | Betree_Message_Insert v ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, BetreeMessageInsert v) l) in
- Return (st0, BetreeNodeInternal node)
- | BetreeMessageDelete ->
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, Betree_Message_Insert v) l) in
+ Return (st0, Betree_Node_Internal node)
+ | Betree_Message_Delete ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs
- (BetreeListCons (k, BetreeMessageDelete) l) in
- Return (st0, BetreeNodeInternal node)
- | BetreeMessageUpsert ufs ->
- let* (st2, v) = betree_internal_lookup_in_children_fwd node key st1
- in
+ betree_Node_lookup_first_message_for_key_back key msgs
+ (Betree_List_Cons (k, Betree_Message_Delete) l) in
+ Return (st0, Betree_Node_Internal node)
+ | Betree_Message_Upsert ufs ->
+ let* (st2, v) = betree_Internal_lookup_in_children node key st1 in
let* (st3, _) =
- betree_node_apply_upserts_fwd (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st2 in
+ betree_Node_apply_upserts (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st2 in
let* (st4, node0) =
- betree_internal_lookup_in_children_back node key st1 st3 in
+ betree_Internal_lookup_in_children_back node key st1 st3 in
let* (st5, pending0) =
- betree_node_apply_upserts_back (BetreeListCons (k,
- BetreeMessageUpsert ufs) l) v key st2 st4 in
+ betree_Node_apply_upserts_back (Betree_List_Cons (k,
+ Betree_Message_Upsert ufs) l) v key st2 st4 in
let* msgs0 =
- betree_node_lookup_first_message_for_key_back key msgs pending0 in
- let* _ =
- betree_store_internal_node_fwd node0.betree_internal_id msgs0 st5
- in
- Return (st0, BetreeNodeInternal node0)
+ betree_Node_lookup_first_message_for_key_back key msgs pending0 in
+ let* _ = betree_store_internal_node node0.id msgs0 st5 in
+ Return (st0, Betree_Node_Internal node0)
end
- | BetreeListNil ->
+ | Betree_List_Nil ->
let* _ =
- betree_node_lookup_first_message_for_key_back key msgs BetreeListNil in
+ betree_Node_lookup_first_message_for_key_back key msgs Betree_List_Nil
+ in
let* (st2, node0) =
- betree_internal_lookup_in_children_back node key st1 st0 in
- Return (st2, BetreeNodeInternal node0)
+ betree_Internal_lookup_in_children_back node key st1 st0 in
+ Return (st2, Betree_Node_Internal node0)
end
- | BetreeNodeLeaf node ->
- let* (_, bindings) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* _ = betree_node_lookup_in_bindings_fwd key bindings in
- Return (st0, BetreeNodeLeaf node)
+ | Betree_Node_Leaf node ->
+ let* (_, bindings) = betree_load_leaf_node node.id st in
+ let* _ = betree_Node_lookup_in_bindings key bindings in
+ Return (st0, Betree_Node_Leaf node)
end
(** [betree_main::betree::Node::{5}::filter_messages_for_key]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec betree_node_filter_messages_for_key_fwd_back
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_filter_messages_for_key_decreases key msgs))
+let rec betree_Node_filter_messages_for_key
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_filter_messages_for_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons p l ->
+ | Betree_List_Cons p l ->
let (k, m) = p in
if k = key
then
let* msgs0 =
- betree_list_pop_front_back (u64 & betree_message_t) (BetreeListCons (k,
- m) l) in
- betree_node_filter_messages_for_key_fwd_back key msgs0
- else Return (BetreeListCons (k, m) l)
- | BetreeListNil -> Return BetreeListNil
+ betree_List_pop_front_back (u64 & betree_Message_t) (Betree_List_Cons
+ (k, m) l) in
+ betree_Node_filter_messages_for_key key msgs0
+ else Return (Betree_List_Cons (k, m) l)
+ | Betree_List_Nil -> Return Betree_List_Nil
end
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: forward function *)
-let rec betree_node_lookup_first_message_after_key_fwd
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_lookup_first_message_after_key_decreases key msgs))
+let rec betree_Node_lookup_first_message_after_key
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_lookup_first_message_after_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons p next_msgs ->
+ | Betree_List_Cons p next_msgs ->
let (k, m) = p in
if k = key
- then betree_node_lookup_first_message_after_key_fwd key next_msgs
- else Return (BetreeListCons (k, m) next_msgs)
- | BetreeListNil -> Return BetreeListNil
+ then betree_Node_lookup_first_message_after_key key next_msgs
+ else Return (Betree_List_Cons (k, m) next_msgs)
+ | Betree_List_Nil -> Return Betree_List_Nil
end
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: backward function 0 *)
-let rec betree_node_lookup_first_message_after_key_back
- (key : u64) (msgs : betree_list_t (u64 & betree_message_t))
- (ret : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_lookup_first_message_after_key_decreases key msgs))
+let rec betree_Node_lookup_first_message_after_key_back
+ (key : u64) (msgs : betree_List_t (u64 & betree_Message_t))
+ (ret : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_lookup_first_message_after_key_decreases key msgs))
=
begin match msgs with
- | BetreeListCons p next_msgs ->
+ | Betree_List_Cons p next_msgs ->
let (k, m) = p in
if k = key
then
let* next_msgs0 =
- betree_node_lookup_first_message_after_key_back key next_msgs ret in
- Return (BetreeListCons (k, m) next_msgs0)
+ betree_Node_lookup_first_message_after_key_back key next_msgs ret in
+ Return (Betree_List_Cons (k, m) next_msgs0)
else Return ret
- | BetreeListNil -> Return ret
+ | Betree_List_Nil -> Return ret
end
(** [betree_main::betree::Node::{5}::apply_to_internal]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let betree_node_apply_to_internal_fwd_back
- (msgs : betree_list_t (u64 & betree_message_t)) (key : u64)
- (new_msg : betree_message_t) :
- result (betree_list_t (u64 & betree_message_t))
+let betree_Node_apply_to_internal
+ (msgs : betree_List_t (u64 & betree_Message_t)) (key : u64)
+ (new_msg : betree_Message_t) :
+ result (betree_List_t (u64 & betree_Message_t))
=
- let* msgs0 = betree_node_lookup_first_message_for_key_fwd key msgs in
- let* b = betree_list_head_has_key_fwd betree_message_t msgs0 key in
+ let* msgs0 = betree_Node_lookup_first_message_for_key key msgs in
+ let* b = betree_List_head_has_key betree_Message_t msgs0 key in
if b
then
begin match new_msg with
- | BetreeMessageInsert i ->
- let* msgs1 = betree_node_filter_messages_for_key_fwd_back key msgs0 in
+ | Betree_Message_Insert i ->
+ let* msgs1 = betree_Node_filter_messages_for_key key msgs0 in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageInsert i) in
- betree_node_lookup_first_message_for_key_back key msgs msgs2
- | BetreeMessageDelete ->
- let* msgs1 = betree_node_filter_messages_for_key_fwd_back key msgs0 in
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Insert i) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs2
+ | Betree_Message_Delete ->
+ let* msgs1 = betree_Node_filter_messages_for_key key msgs0 in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageDelete) in
- betree_node_lookup_first_message_for_key_back key msgs msgs2
- | BetreeMessageUpsert s ->
- let* p = betree_list_hd_fwd (u64 & betree_message_t) msgs0 in
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Delete) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs2
+ | Betree_Message_Upsert s ->
+ let* p = betree_List_hd (u64 & betree_Message_t) msgs0 in
let (_, m) = p in
begin match m with
- | BetreeMessageInsert prev ->
- let* v = betree_upsert_update_fwd (Some prev) s in
- let* msgs1 = betree_list_pop_front_back (u64 & betree_message_t) msgs0
+ | Betree_Message_Insert prev ->
+ let* v = betree_upsert_update (Some prev) s in
+ let* msgs1 = betree_List_pop_front_back (u64 & betree_Message_t) msgs0
in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageInsert v) in
- betree_node_lookup_first_message_for_key_back key msgs msgs2
- | BetreeMessageDelete ->
- let* v = betree_upsert_update_fwd None s in
- let* msgs1 = betree_list_pop_front_back (u64 & betree_message_t) msgs0
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Insert v) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs2
+ | Betree_Message_Delete ->
+ let* v = betree_upsert_update None s in
+ let* msgs1 = betree_List_pop_front_back (u64 & betree_Message_t) msgs0
in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageInsert v) in
- betree_node_lookup_first_message_for_key_back key msgs msgs2
- | BetreeMessageUpsert ufs ->
- let* msgs1 = betree_node_lookup_first_message_after_key_fwd key msgs0
- in
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Insert v) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs2
+ | Betree_Message_Upsert ufs ->
+ let* msgs1 = betree_Node_lookup_first_message_after_key key msgs0 in
let* msgs2 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs1 (key,
- BetreeMessageUpsert s) in
+ betree_List_push_front (u64 & betree_Message_t) msgs1 (key,
+ Betree_Message_Upsert s) in
let* msgs3 =
- betree_node_lookup_first_message_after_key_back key msgs0 msgs2 in
- betree_node_lookup_first_message_for_key_back key msgs msgs3
+ betree_Node_lookup_first_message_after_key_back key msgs0 msgs2 in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs3
end
end
else
let* msgs1 =
- betree_list_push_front_fwd_back (u64 & betree_message_t) msgs0 (key,
- new_msg) in
- betree_node_lookup_first_message_for_key_back key msgs msgs1
+ betree_List_push_front (u64 & betree_Message_t) msgs0 (key, new_msg) in
+ betree_Node_lookup_first_message_for_key_back key msgs msgs1
(** [betree_main::betree::Node::{5}::apply_messages_to_internal]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec betree_node_apply_messages_to_internal_fwd_back
- (msgs : betree_list_t (u64 & betree_message_t))
- (new_msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & betree_message_t)))
- (decreases (betree_node_apply_messages_to_internal_decreases msgs new_msgs))
+let rec betree_Node_apply_messages_to_internal
+ (msgs : betree_List_t (u64 & betree_Message_t))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & betree_Message_t)))
+ (decreases (betree_Node_apply_messages_to_internal_decreases msgs new_msgs))
=
begin match new_msgs with
- | BetreeListCons new_msg new_msgs_tl ->
+ | Betree_List_Cons new_msg new_msgs_tl ->
let (i, m) = new_msg in
- let* msgs0 = betree_node_apply_to_internal_fwd_back msgs i m in
- betree_node_apply_messages_to_internal_fwd_back msgs0 new_msgs_tl
- | BetreeListNil -> Return msgs
+ let* msgs0 = betree_Node_apply_to_internal msgs i m in
+ betree_Node_apply_messages_to_internal msgs0 new_msgs_tl
+ | Betree_List_Nil -> Return msgs
end
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: forward function *)
-let rec betree_node_lookup_mut_in_bindings_fwd
- (key : u64) (bindings : betree_list_t (u64 & u64)) :
- Tot (result (betree_list_t (u64 & u64)))
- (decreases (betree_node_lookup_mut_in_bindings_decreases key bindings))
+let rec betree_Node_lookup_mut_in_bindings
+ (key : u64) (bindings : betree_List_t (u64 & u64)) :
+ Tot (result (betree_List_t (u64 & u64)))
+ (decreases (betree_Node_lookup_mut_in_bindings_decreases key bindings))
=
begin match bindings with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let (i, i0) = hd in
if i >= key
- then Return (BetreeListCons (i, i0) tl)
- else betree_node_lookup_mut_in_bindings_fwd key tl
- | BetreeListNil -> Return BetreeListNil
+ then Return (Betree_List_Cons (i, i0) tl)
+ else betree_Node_lookup_mut_in_bindings key tl
+ | Betree_List_Nil -> Return Betree_List_Nil
end
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: backward function 0 *)
-let rec betree_node_lookup_mut_in_bindings_back
- (key : u64) (bindings : betree_list_t (u64 & u64))
- (ret : betree_list_t (u64 & u64)) :
- Tot (result (betree_list_t (u64 & u64)))
- (decreases (betree_node_lookup_mut_in_bindings_decreases key bindings))
+let rec betree_Node_lookup_mut_in_bindings_back
+ (key : u64) (bindings : betree_List_t (u64 & u64))
+ (ret : betree_List_t (u64 & u64)) :
+ Tot (result (betree_List_t (u64 & u64)))
+ (decreases (betree_Node_lookup_mut_in_bindings_decreases key bindings))
=
begin match bindings with
- | BetreeListCons hd tl ->
+ | Betree_List_Cons hd tl ->
let (i, i0) = hd in
if i >= key
then Return ret
else
- let* tl0 = betree_node_lookup_mut_in_bindings_back key tl ret in
- Return (BetreeListCons (i, i0) tl0)
- | BetreeListNil -> Return ret
+ let* tl0 = betree_Node_lookup_mut_in_bindings_back key tl ret in
+ Return (Betree_List_Cons (i, i0) tl0)
+ | Betree_List_Nil -> Return ret
end
(** [betree_main::betree::Node::{5}::apply_to_leaf]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let betree_node_apply_to_leaf_fwd_back
- (bindings : betree_list_t (u64 & u64)) (key : u64)
- (new_msg : betree_message_t) :
- result (betree_list_t (u64 & u64))
+let betree_Node_apply_to_leaf
+ (bindings : betree_List_t (u64 & u64)) (key : u64)
+ (new_msg : betree_Message_t) :
+ result (betree_List_t (u64 & u64))
=
- let* bindings0 = betree_node_lookup_mut_in_bindings_fwd key bindings in
- let* b = betree_list_head_has_key_fwd u64 bindings0 key in
+ let* bindings0 = betree_Node_lookup_mut_in_bindings key bindings in
+ let* b = betree_List_head_has_key u64 bindings0 key in
if b
then
- let* hd = betree_list_pop_front_fwd (u64 & u64) bindings0 in
+ let* hd = betree_List_pop_front (u64 & u64) bindings0 in
begin match new_msg with
- | BetreeMessageInsert v ->
- let* bindings1 = betree_list_pop_front_back (u64 & u64) bindings0 in
- let* bindings2 =
- betree_list_push_front_fwd_back (u64 & u64) bindings1 (key, v) in
- betree_node_lookup_mut_in_bindings_back key bindings bindings2
- | BetreeMessageDelete ->
- let* bindings1 = betree_list_pop_front_back (u64 & u64) bindings0 in
- betree_node_lookup_mut_in_bindings_back key bindings bindings1
- | BetreeMessageUpsert s ->
+ | Betree_Message_Insert v ->
+ let* bindings1 = betree_List_pop_front_back (u64 & u64) bindings0 in
+ let* bindings2 = betree_List_push_front (u64 & u64) bindings1 (key, v) in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings2
+ | Betree_Message_Delete ->
+ let* bindings1 = betree_List_pop_front_back (u64 & u64) bindings0 in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings1
+ | Betree_Message_Upsert s ->
let (_, i) = hd in
- let* v = betree_upsert_update_fwd (Some i) s in
- let* bindings1 = betree_list_pop_front_back (u64 & u64) bindings0 in
- let* bindings2 =
- betree_list_push_front_fwd_back (u64 & u64) bindings1 (key, v) in
- betree_node_lookup_mut_in_bindings_back key bindings bindings2
+ let* v = betree_upsert_update (Some i) s in
+ let* bindings1 = betree_List_pop_front_back (u64 & u64) bindings0 in
+ let* bindings2 = betree_List_push_front (u64 & u64) bindings1 (key, v) in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings2
end
else
begin match new_msg with
- | BetreeMessageInsert v ->
- let* bindings1 =
- betree_list_push_front_fwd_back (u64 & u64) bindings0 (key, v) in
- betree_node_lookup_mut_in_bindings_back key bindings bindings1
- | BetreeMessageDelete ->
- betree_node_lookup_mut_in_bindings_back key bindings bindings0
- | BetreeMessageUpsert s ->
- let* v = betree_upsert_update_fwd None s in
- let* bindings1 =
- betree_list_push_front_fwd_back (u64 & u64) bindings0 (key, v) in
- betree_node_lookup_mut_in_bindings_back key bindings bindings1
+ | Betree_Message_Insert v ->
+ let* bindings1 = betree_List_push_front (u64 & u64) bindings0 (key, v) in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings1
+ | Betree_Message_Delete ->
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings0
+ | Betree_Message_Upsert s ->
+ let* v = betree_upsert_update None s in
+ let* bindings1 = betree_List_push_front (u64 & u64) bindings0 (key, v) in
+ betree_Node_lookup_mut_in_bindings_back key bindings bindings1
end
(** [betree_main::betree::Node::{5}::apply_messages_to_leaf]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec betree_node_apply_messages_to_leaf_fwd_back
- (bindings : betree_list_t (u64 & u64))
- (new_msgs : betree_list_t (u64 & betree_message_t)) :
- Tot (result (betree_list_t (u64 & u64)))
- (decreases (betree_node_apply_messages_to_leaf_decreases bindings new_msgs))
+let rec betree_Node_apply_messages_to_leaf
+ (bindings : betree_List_t (u64 & u64))
+ (new_msgs : betree_List_t (u64 & betree_Message_t)) :
+ Tot (result (betree_List_t (u64 & u64)))
+ (decreases (betree_Node_apply_messages_to_leaf_decreases bindings new_msgs))
=
begin match new_msgs with
- | BetreeListCons new_msg new_msgs_tl ->
+ | Betree_List_Cons new_msg new_msgs_tl ->
let (i, m) = new_msg in
- let* bindings0 = betree_node_apply_to_leaf_fwd_back bindings i m in
- betree_node_apply_messages_to_leaf_fwd_back bindings0 new_msgs_tl
- | BetreeListNil -> Return bindings
+ let* bindings0 = betree_Node_apply_to_leaf bindings i m in
+ betree_Node_apply_messages_to_leaf bindings0 new_msgs_tl
+ | Betree_List_Nil -> Return bindings
end
(** [betree_main::betree::Internal::{4}::flush]: forward function *)
-let rec betree_internal_flush_fwd
- (self : betree_internal_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) :
- Tot (result (state & (betree_list_t (u64 & betree_message_t))))
+let rec betree_Internal_flush
+ (self : betree_Internal_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) :
+ Tot (result (state & (betree_List_t (u64 & betree_Message_t))))
(decreases (
- betree_internal_flush_decreases self params node_id_cnt content st))
+ betree_Internal_flush_decreases self params node_id_cnt content st))
=
- let* p =
- betree_list_partition_at_pivot_fwd betree_message_t content
- self.betree_internal_pivot in
+ let* p = betree_List_partition_at_pivot betree_Message_t content self.pivot
+ in
let (msgs_left, msgs_right) = p in
- let* len_left = betree_list_len_fwd (u64 & betree_message_t) msgs_left in
- if len_left >= params.betree_params_min_flush_size
+ let* len_left = betree_List_len (u64 & betree_Message_t) msgs_left in
+ if len_left >= params.min_flush_size
then
let* (st0, _) =
- betree_node_apply_messages_fwd self.betree_internal_left params
- node_id_cnt msgs_left st in
+ betree_Node_apply_messages self.left params node_id_cnt msgs_left st in
let* (st1, (_, node_id_cnt0)) =
- betree_node_apply_messages_back'a self.betree_internal_left params
- node_id_cnt msgs_left st st0 in
+ betree_Node_apply_messages_back'a self.left params node_id_cnt msgs_left
+ st st0 in
let* (st2, ()) =
- betree_node_apply_messages_back1 self.betree_internal_left params
- node_id_cnt msgs_left st st1 in
- let* len_right = betree_list_len_fwd (u64 & betree_message_t) msgs_right in
- if len_right >= params.betree_params_min_flush_size
+ betree_Node_apply_messages_back1 self.left params node_id_cnt msgs_left
+ st st1 in
+ let* len_right = betree_List_len (u64 & betree_Message_t) msgs_right in
+ if len_right >= params.min_flush_size
then
let* (st3, _) =
- betree_node_apply_messages_fwd self.betree_internal_right params
- node_id_cnt0 msgs_right st2 in
+ betree_Node_apply_messages self.right params node_id_cnt0 msgs_right
+ st2 in
let* (st4, (_, _)) =
- betree_node_apply_messages_back'a self.betree_internal_right params
- node_id_cnt0 msgs_right st2 st3 in
+ betree_Node_apply_messages_back'a self.right params node_id_cnt0
+ msgs_right st2 st3 in
let* (st5, ()) =
- betree_node_apply_messages_back1 self.betree_internal_right params
- node_id_cnt0 msgs_right st2 st4 in
- Return (st5, BetreeListNil)
+ betree_Node_apply_messages_back1 self.right params node_id_cnt0
+ msgs_right st2 st4 in
+ Return (st5, Betree_List_Nil)
else Return (st2, msgs_right)
else
let* (st0, _) =
- betree_node_apply_messages_fwd self.betree_internal_right params
- node_id_cnt msgs_right st in
+ betree_Node_apply_messages self.right params node_id_cnt msgs_right st in
let* (st1, (_, _)) =
- betree_node_apply_messages_back'a self.betree_internal_right params
- node_id_cnt msgs_right st st0 in
+ betree_Node_apply_messages_back'a self.right params node_id_cnt
+ msgs_right st st0 in
let* (st2, ()) =
- betree_node_apply_messages_back1 self.betree_internal_right params
- node_id_cnt msgs_right st st1 in
+ betree_Node_apply_messages_back1 self.right params node_id_cnt msgs_right
+ st st1 in
Return (st2, msgs_left)
(** [betree_main::betree::Internal::{4}::flush]: backward function 0 *)
-and betree_internal_flush_back'a
- (self : betree_internal_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) (st0 : state)
+and betree_Internal_flush_back'a
+ (self : betree_Internal_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) (st0 : state)
:
- Tot (result (state & (betree_internal_t & betree_node_id_counter_t)))
+ Tot (result (state & (betree_Internal_t & betree_NodeIdCounter_t)))
(decreases (
- betree_internal_flush_decreases self params node_id_cnt content st))
+ betree_Internal_flush_decreases self params node_id_cnt content st))
=
- let* p =
- betree_list_partition_at_pivot_fwd betree_message_t content
- self.betree_internal_pivot in
+ let* p = betree_List_partition_at_pivot betree_Message_t content self.pivot
+ in
let (msgs_left, msgs_right) = p in
- let* len_left = betree_list_len_fwd (u64 & betree_message_t) msgs_left in
- if len_left >= params.betree_params_min_flush_size
+ let* len_left = betree_List_len (u64 & betree_Message_t) msgs_left in
+ if len_left >= params.min_flush_size
then
let* (st1, _) =
- betree_node_apply_messages_fwd self.betree_internal_left params
- node_id_cnt msgs_left st in
+ betree_Node_apply_messages self.left params node_id_cnt msgs_left st in
let* (st2, (n, node_id_cnt0)) =
- betree_node_apply_messages_back'a self.betree_internal_left params
- node_id_cnt msgs_left st st1 in
+ betree_Node_apply_messages_back'a self.left params node_id_cnt msgs_left
+ st st1 in
let* (st3, ()) =
- betree_node_apply_messages_back1 self.betree_internal_left params
- node_id_cnt msgs_left st st2 in
- let* len_right = betree_list_len_fwd (u64 & betree_message_t) msgs_right in
- if len_right >= params.betree_params_min_flush_size
+ betree_Node_apply_messages_back1 self.left params node_id_cnt msgs_left
+ st st2 in
+ let* len_right = betree_List_len (u64 & betree_Message_t) msgs_right in
+ if len_right >= params.min_flush_size
then
let* (st4, _) =
- betree_node_apply_messages_fwd self.betree_internal_right params
- node_id_cnt0 msgs_right st3 in
+ betree_Node_apply_messages self.right params node_id_cnt0 msgs_right
+ st3 in
let* (st5, (n0, node_id_cnt1)) =
- betree_node_apply_messages_back'a self.betree_internal_right params
- node_id_cnt0 msgs_right st3 st4 in
+ betree_Node_apply_messages_back'a self.right params node_id_cnt0
+ msgs_right st3 st4 in
let* _ =
- betree_node_apply_messages_back1 self.betree_internal_right params
- node_id_cnt0 msgs_right st3 st5 in
- Return (st0,
- ({ self with betree_internal_left = n; betree_internal_right = n0 },
- node_id_cnt1))
- else Return (st0, ({ self with betree_internal_left = n }, node_id_cnt0))
+ betree_Node_apply_messages_back1 self.right params node_id_cnt0
+ msgs_right st3 st5 in
+ Return (st0, ({ self with left = n; right = n0 }, node_id_cnt1))
+ else Return (st0, ({ self with left = n }, node_id_cnt0))
else
let* (st1, _) =
- betree_node_apply_messages_fwd self.betree_internal_right params
- node_id_cnt msgs_right st in
+ betree_Node_apply_messages self.right params node_id_cnt msgs_right st in
let* (st2, (n, node_id_cnt0)) =
- betree_node_apply_messages_back'a self.betree_internal_right params
- node_id_cnt msgs_right st st1 in
+ betree_Node_apply_messages_back'a self.right params node_id_cnt
+ msgs_right st st1 in
let* _ =
- betree_node_apply_messages_back1 self.betree_internal_right params
- node_id_cnt msgs_right st st2 in
- Return (st0, ({ self with betree_internal_right = n }, node_id_cnt0))
+ betree_Node_apply_messages_back1 self.right params node_id_cnt msgs_right
+ st st2 in
+ Return (st0, ({ self with right = n }, node_id_cnt0))
(** [betree_main::betree::Internal::{4}::flush]: backward function 1 *)
-and betree_internal_flush_back1
- (self : betree_internal_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (content : betree_list_t (u64 & betree_message_t)) (st : state) (st0 : state)
+and betree_Internal_flush_back1
+ (self : betree_Internal_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (content : betree_List_t (u64 & betree_Message_t)) (st : state) (st0 : state)
:
Tot (result (state & unit))
(decreases (
- betree_internal_flush_decreases self params node_id_cnt content st))
+ betree_Internal_flush_decreases self params node_id_cnt content st))
=
- let* p =
- betree_list_partition_at_pivot_fwd betree_message_t content
- self.betree_internal_pivot in
+ let* p = betree_List_partition_at_pivot betree_Message_t content self.pivot
+ in
let (msgs_left, msgs_right) = p in
- let* len_left = betree_list_len_fwd (u64 & betree_message_t) msgs_left in
- if len_left >= params.betree_params_min_flush_size
+ let* len_left = betree_List_len (u64 & betree_Message_t) msgs_left in
+ if len_left >= params.min_flush_size
then
let* (st1, _) =
- betree_node_apply_messages_fwd self.betree_internal_left params
- node_id_cnt msgs_left st in
+ betree_Node_apply_messages self.left params node_id_cnt msgs_left st in
let* (st2, (_, node_id_cnt0)) =
- betree_node_apply_messages_back'a self.betree_internal_left params
- node_id_cnt msgs_left st st1 in
+ betree_Node_apply_messages_back'a self.left params node_id_cnt msgs_left
+ st st1 in
let* (st3, ()) =
- betree_node_apply_messages_back1 self.betree_internal_left params
- node_id_cnt msgs_left st st2 in
- let* len_right = betree_list_len_fwd (u64 & betree_message_t) msgs_right in
- if len_right >= params.betree_params_min_flush_size
+ betree_Node_apply_messages_back1 self.left params node_id_cnt msgs_left
+ st st2 in
+ let* len_right = betree_List_len (u64 & betree_Message_t) msgs_right in
+ if len_right >= params.min_flush_size
then
let* (st4, _) =
- betree_node_apply_messages_fwd self.betree_internal_right params
- node_id_cnt0 msgs_right st3 in
+ betree_Node_apply_messages self.right params node_id_cnt0 msgs_right
+ st3 in
let* (st5, (_, _)) =
- betree_node_apply_messages_back'a self.betree_internal_right params
- node_id_cnt0 msgs_right st3 st4 in
+ betree_Node_apply_messages_back'a self.right params node_id_cnt0
+ msgs_right st3 st4 in
let* _ =
- betree_node_apply_messages_back1 self.betree_internal_right params
- node_id_cnt0 msgs_right st3 st5 in
+ betree_Node_apply_messages_back1 self.right params node_id_cnt0
+ msgs_right st3 st5 in
Return (st0, ())
else Return (st0, ())
else
let* (st1, _) =
- betree_node_apply_messages_fwd self.betree_internal_right params
- node_id_cnt msgs_right st in
+ betree_Node_apply_messages self.right params node_id_cnt msgs_right st in
let* (st2, (_, _)) =
- betree_node_apply_messages_back'a self.betree_internal_right params
- node_id_cnt msgs_right st st1 in
+ betree_Node_apply_messages_back'a self.right params node_id_cnt
+ msgs_right st st1 in
let* _ =
- betree_node_apply_messages_back1 self.betree_internal_right params
- node_id_cnt msgs_right st st2 in
+ betree_Node_apply_messages_back1 self.right params node_id_cnt msgs_right
+ st st2 in
Return (st0, ())
(** [betree_main::betree::Node::{5}::apply_messages]: forward function *)
-and betree_node_apply_messages_fwd
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) :
+and betree_Node_apply_messages
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) :
Tot (result (state & unit))
(decreases (
- betree_node_apply_messages_decreases self params node_id_cnt msgs st))
+ betree_Node_apply_messages_decreases self params node_id_cnt msgs st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st0, content) =
- betree_load_internal_node_fwd node.betree_internal_id st in
- let* content0 =
- betree_node_apply_messages_to_internal_fwd_back content msgs in
- let* num_msgs = betree_list_len_fwd (u64 & betree_message_t) content0 in
- if num_msgs >= params.betree_params_min_flush_size
+ | Betree_Node_Internal node ->
+ let* (st0, content) = betree_load_internal_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_internal content msgs in
+ let* num_msgs = betree_List_len (u64 & betree_Message_t) content0 in
+ if num_msgs >= params.min_flush_size
then
let* (st1, content1) =
- betree_internal_flush_fwd node params node_id_cnt content0 st0 in
+ betree_Internal_flush node params node_id_cnt content0 st0 in
let* (st2, (node0, _)) =
- betree_internal_flush_back'a node params node_id_cnt content0 st0 st1
+ betree_Internal_flush_back'a node params node_id_cnt content0 st0 st1
in
- let* (st3, _) =
- betree_store_internal_node_fwd node0.betree_internal_id content1 st2 in
+ let* (st3, _) = betree_store_internal_node node0.id content1 st2 in
Return (st3, ())
else
- let* (st1, _) =
- betree_store_internal_node_fwd node.betree_internal_id content0 st0 in
+ let* (st1, _) = betree_store_internal_node node.id content0 st0 in
Return (st1, ())
- | BetreeNodeLeaf node ->
- let* (st0, content) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* content0 = betree_node_apply_messages_to_leaf_fwd_back content msgs in
- let* len = betree_list_len_fwd (u64 & u64) content0 in
- let* i = u64_mul 2 params.betree_params_split_size in
+ | Betree_Node_Leaf node ->
+ let* (st0, content) = betree_load_leaf_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_leaf content msgs in
+ let* len = betree_List_len (u64 & u64) content0 in
+ let* i = u64_mul 2 params.split_size in
if len >= i
then
- let* (st1, _) =
- betree_leaf_split_fwd node content0 params node_id_cnt st0 in
- let* (st2, _) =
- betree_store_leaf_node_fwd node.betree_leaf_id BetreeListNil st1 in
- betree_leaf_split_back0 node content0 params node_id_cnt st0 st2
+ let* (st1, _) = betree_Leaf_split node content0 params node_id_cnt st0 in
+ let* (st2, _) = betree_store_leaf_node node.id Betree_List_Nil st1 in
+ betree_Leaf_split_back0 node content0 params node_id_cnt st0 st2
else
- let* (st1, _) =
- betree_store_leaf_node_fwd node.betree_leaf_id content0 st0 in
+ let* (st1, _) = betree_store_leaf_node node.id content0 st0 in
Return (st1, ())
end
(** [betree_main::betree::Node::{5}::apply_messages]: backward function 0 *)
-and betree_node_apply_messages_back'a
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) (st0 : state) :
- Tot (result (state & (betree_node_t & betree_node_id_counter_t)))
+and betree_Node_apply_messages_back'a
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) (st0 : state) :
+ Tot (result (state & (betree_Node_t & betree_NodeIdCounter_t)))
(decreases (
- betree_node_apply_messages_decreases self params node_id_cnt msgs st))
+ betree_Node_apply_messages_decreases self params node_id_cnt msgs st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st1, content) =
- betree_load_internal_node_fwd node.betree_internal_id st in
- let* content0 =
- betree_node_apply_messages_to_internal_fwd_back content msgs in
- let* num_msgs = betree_list_len_fwd (u64 & betree_message_t) content0 in
- if num_msgs >= params.betree_params_min_flush_size
+ | Betree_Node_Internal node ->
+ let* (st1, content) = betree_load_internal_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_internal content msgs in
+ let* num_msgs = betree_List_len (u64 & betree_Message_t) content0 in
+ if num_msgs >= params.min_flush_size
then
let* (st2, content1) =
- betree_internal_flush_fwd node params node_id_cnt content0 st1 in
+ betree_Internal_flush node params node_id_cnt content0 st1 in
let* (st3, (node0, node_id_cnt0)) =
- betree_internal_flush_back'a node params node_id_cnt content0 st1 st2
+ betree_Internal_flush_back'a node params node_id_cnt content0 st1 st2
in
- let* _ =
- betree_store_internal_node_fwd node0.betree_internal_id content1 st3 in
- Return (st0, (BetreeNodeInternal node0, node_id_cnt0))
+ let* _ = betree_store_internal_node node0.id content1 st3 in
+ Return (st0, (Betree_Node_Internal node0, node_id_cnt0))
else
- let* _ =
- betree_store_internal_node_fwd node.betree_internal_id content0 st1 in
- Return (st0, (BetreeNodeInternal node, node_id_cnt))
- | BetreeNodeLeaf node ->
- let* (st1, content) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* content0 = betree_node_apply_messages_to_leaf_fwd_back content msgs in
- let* len = betree_list_len_fwd (u64 & u64) content0 in
- let* i = u64_mul 2 params.betree_params_split_size in
+ let* _ = betree_store_internal_node node.id content0 st1 in
+ Return (st0, (Betree_Node_Internal node, node_id_cnt))
+ | Betree_Node_Leaf node ->
+ let* (st1, content) = betree_load_leaf_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_leaf content msgs in
+ let* len = betree_List_len (u64 & u64) content0 in
+ let* i = u64_mul 2 params.split_size in
if len >= i
then
let* (st2, new_node) =
- betree_leaf_split_fwd node content0 params node_id_cnt st1 in
- let* (st3, _) =
- betree_store_leaf_node_fwd node.betree_leaf_id BetreeListNil st2 in
- let* _ = betree_leaf_split_back0 node content0 params node_id_cnt st1 st3
+ betree_Leaf_split node content0 params node_id_cnt st1 in
+ let* (st3, _) = betree_store_leaf_node node.id Betree_List_Nil st2 in
+ let* _ = betree_Leaf_split_back0 node content0 params node_id_cnt st1 st3
in
let* (st4, node_id_cnt0) =
- betree_leaf_split_back2 node content0 params node_id_cnt st1 st0 in
- Return (st4, (BetreeNodeInternal new_node, node_id_cnt0))
+ betree_Leaf_split_back2 node content0 params node_id_cnt st1 st0 in
+ Return (st4, (Betree_Node_Internal new_node, node_id_cnt0))
else
- let* _ = betree_store_leaf_node_fwd node.betree_leaf_id content0 st1 in
- Return (st0, (BetreeNodeLeaf { node with betree_leaf_size = len },
- node_id_cnt))
+ let* _ = betree_store_leaf_node node.id content0 st1 in
+ Return (st0, (Betree_Node_Leaf { node with size = len }, node_id_cnt))
end
(** [betree_main::betree::Node::{5}::apply_messages]: backward function 1 *)
-and betree_node_apply_messages_back1
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t)
- (msgs : betree_list_t (u64 & betree_message_t)) (st : state) (st0 : state) :
+and betree_Node_apply_messages_back1
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t)
+ (msgs : betree_List_t (u64 & betree_Message_t)) (st : state) (st0 : state) :
Tot (result (state & unit))
(decreases (
- betree_node_apply_messages_decreases self params node_id_cnt msgs st))
+ betree_Node_apply_messages_decreases self params node_id_cnt msgs st))
=
begin match self with
- | BetreeNodeInternal node ->
- let* (st1, content) =
- betree_load_internal_node_fwd node.betree_internal_id st in
- let* content0 =
- betree_node_apply_messages_to_internal_fwd_back content msgs in
- let* num_msgs = betree_list_len_fwd (u64 & betree_message_t) content0 in
- if num_msgs >= params.betree_params_min_flush_size
+ | Betree_Node_Internal node ->
+ let* (st1, content) = betree_load_internal_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_internal content msgs in
+ let* num_msgs = betree_List_len (u64 & betree_Message_t) content0 in
+ if num_msgs >= params.min_flush_size
then
let* (st2, content1) =
- betree_internal_flush_fwd node params node_id_cnt content0 st1 in
+ betree_Internal_flush node params node_id_cnt content0 st1 in
let* (st3, (node0, _)) =
- betree_internal_flush_back'a node params node_id_cnt content0 st1 st2
+ betree_Internal_flush_back'a node params node_id_cnt content0 st1 st2
in
- let* _ =
- betree_store_internal_node_fwd node0.betree_internal_id content1 st3 in
- betree_internal_flush_back1 node params node_id_cnt content0 st1 st0
+ let* _ = betree_store_internal_node node0.id content1 st3 in
+ betree_Internal_flush_back1 node params node_id_cnt content0 st1 st0
else
- let* _ =
- betree_store_internal_node_fwd node.betree_internal_id content0 st1 in
+ let* _ = betree_store_internal_node node.id content0 st1 in
Return (st0, ())
- | BetreeNodeLeaf node ->
- let* (st1, content) = betree_load_leaf_node_fwd node.betree_leaf_id st in
- let* content0 = betree_node_apply_messages_to_leaf_fwd_back content msgs in
- let* len = betree_list_len_fwd (u64 & u64) content0 in
- let* i = u64_mul 2 params.betree_params_split_size in
+ | Betree_Node_Leaf node ->
+ let* (st1, content) = betree_load_leaf_node node.id st in
+ let* content0 = betree_Node_apply_messages_to_leaf content msgs in
+ let* len = betree_List_len (u64 & u64) content0 in
+ let* i = u64_mul 2 params.split_size in
if len >= i
then
- let* (st2, _) =
- betree_leaf_split_fwd node content0 params node_id_cnt st1 in
- let* (st3, _) =
- betree_store_leaf_node_fwd node.betree_leaf_id BetreeListNil st2 in
- let* _ = betree_leaf_split_back0 node content0 params node_id_cnt st1 st3
+ let* (st2, _) = betree_Leaf_split node content0 params node_id_cnt st1 in
+ let* (st3, _) = betree_store_leaf_node node.id Betree_List_Nil st2 in
+ let* _ = betree_Leaf_split_back0 node content0 params node_id_cnt st1 st3
in
- betree_leaf_split_back1 node content0 params node_id_cnt st1 st0
+ betree_Leaf_split_back1 node content0 params node_id_cnt st1 st0
else
- let* _ = betree_store_leaf_node_fwd node.betree_leaf_id content0 st1 in
- Return (st0, ())
+ let* _ = betree_store_leaf_node node.id content0 st1 in Return (st0, ())
end
(** [betree_main::betree::Node::{5}::apply]: forward function *)
-let betree_node_apply_fwd
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t) (key : u64)
- (new_msg : betree_message_t) (st : state) :
+let betree_Node_apply
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t) (key : u64)
+ (new_msg : betree_Message_t) (st : state) :
result (state & unit)
=
- let l = BetreeListNil in
+ let l = Betree_List_Nil in
let* (st0, _) =
- betree_node_apply_messages_fwd self params node_id_cnt (BetreeListCons
- (key, new_msg) l) st in
+ betree_Node_apply_messages self params node_id_cnt (Betree_List_Cons (key,
+ new_msg) l) st in
let* (st1, (_, _)) =
- betree_node_apply_messages_back'a self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages_back'a self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st st0 in
- betree_node_apply_messages_back1 self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages_back1 self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st st1
(** [betree_main::betree::Node::{5}::apply]: backward function 0 *)
-let betree_node_apply_back'a
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t) (key : u64)
- (new_msg : betree_message_t) (st : state) (st0 : state) :
- result (state & (betree_node_t & betree_node_id_counter_t))
+let betree_Node_apply_back'a
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t) (key : u64)
+ (new_msg : betree_Message_t) (st : state) (st0 : state) :
+ result (state & (betree_Node_t & betree_NodeIdCounter_t))
=
- let l = BetreeListNil in
+ let l = Betree_List_Nil in
let* (st1, _) =
- betree_node_apply_messages_fwd self params node_id_cnt (BetreeListCons
- (key, new_msg) l) st in
+ betree_Node_apply_messages self params node_id_cnt (Betree_List_Cons (key,
+ new_msg) l) st in
let* (st2, (self0, node_id_cnt0)) =
- betree_node_apply_messages_back'a self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages_back'a self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st st1 in
let* _ =
- betree_node_apply_messages_back1 self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages_back1 self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st st2 in
Return (st0, (self0, node_id_cnt0))
(** [betree_main::betree::Node::{5}::apply]: backward function 1 *)
-let betree_node_apply_back1
- (self : betree_node_t) (params : betree_params_t)
- (node_id_cnt : betree_node_id_counter_t) (key : u64)
- (new_msg : betree_message_t) (st : state) (st0 : state) :
+let betree_Node_apply_back1
+ (self : betree_Node_t) (params : betree_Params_t)
+ (node_id_cnt : betree_NodeIdCounter_t) (key : u64)
+ (new_msg : betree_Message_t) (st : state) (st0 : state) :
result (state & unit)
=
- let l = BetreeListNil in
+ let l = Betree_List_Nil in
let* (st1, _) =
- betree_node_apply_messages_fwd self params node_id_cnt (BetreeListCons
- (key, new_msg) l) st in
+ betree_Node_apply_messages self params node_id_cnt (Betree_List_Cons (key,
+ new_msg) l) st in
let* (st2, (_, _)) =
- betree_node_apply_messages_back'a self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages_back'a self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st st1 in
let* _ =
- betree_node_apply_messages_back1 self params node_id_cnt (BetreeListCons
+ betree_Node_apply_messages_back1 self params node_id_cnt (Betree_List_Cons
(key, new_msg) l) st st2 in
Return (st0, ())
(** [betree_main::betree::BeTree::{6}::new]: forward function *)
-let betree_be_tree_new_fwd
+let betree_BeTree_new
(min_flush_size : u64) (split_size : u64) (st : state) :
- result (state & betree_be_tree_t)
+ result (state & betree_BeTree_t)
=
- let* node_id_cnt = betree_node_id_counter_new_fwd in
- let* id = betree_node_id_counter_fresh_id_fwd node_id_cnt in
- let* (st0, _) = betree_store_leaf_node_fwd id BetreeListNil st in
- let* node_id_cnt0 = betree_node_id_counter_fresh_id_back node_id_cnt in
+ let* node_id_cnt = betree_NodeIdCounter_new in
+ let* id = betree_NodeIdCounter_fresh_id node_id_cnt in
+ let* (st0, _) = betree_store_leaf_node id Betree_List_Nil st in
+ let* node_id_cnt0 = betree_NodeIdCounter_fresh_id_back node_id_cnt in
Return (st0,
{
- betree_be_tree_params =
- {
- betree_params_min_flush_size = min_flush_size;
- betree_params_split_size = split_size
- };
- betree_be_tree_node_id_cnt = node_id_cnt0;
- betree_be_tree_root =
- (BetreeNodeLeaf { betree_leaf_id = id; betree_leaf_size = 0 })
+ params = { min_flush_size = min_flush_size; split_size = split_size };
+ node_id_cnt = node_id_cnt0;
+ root = (Betree_Node_Leaf { id = id; size = 0 })
})
(** [betree_main::betree::BeTree::{6}::apply]: forward function *)
-let betree_be_tree_apply_fwd
- (self : betree_be_tree_t) (key : u64) (msg : betree_message_t) (st : state) :
+let betree_BeTree_apply
+ (self : betree_BeTree_t) (key : u64) (msg : betree_Message_t) (st : state) :
result (state & unit)
=
let* (st0, _) =
- betree_node_apply_fwd self.betree_be_tree_root self.betree_be_tree_params
- self.betree_be_tree_node_id_cnt key msg st in
+ betree_Node_apply self.root self.params self.node_id_cnt key msg st in
let* (st1, (_, _)) =
- betree_node_apply_back'a self.betree_be_tree_root
- self.betree_be_tree_params self.betree_be_tree_node_id_cnt key msg st st0
- in
- betree_node_apply_back1 self.betree_be_tree_root self.betree_be_tree_params
- self.betree_be_tree_node_id_cnt key msg st st1
+ betree_Node_apply_back'a self.root self.params self.node_id_cnt key msg st
+ st0 in
+ betree_Node_apply_back1 self.root self.params self.node_id_cnt key msg st st1
(** [betree_main::betree::BeTree::{6}::apply]: backward function 0 *)
-let betree_be_tree_apply_back
- (self : betree_be_tree_t) (key : u64) (msg : betree_message_t) (st : state)
+let betree_BeTree_apply_back
+ (self : betree_BeTree_t) (key : u64) (msg : betree_Message_t) (st : state)
(st0 : state) :
- result (state & betree_be_tree_t)
+ result (state & betree_BeTree_t)
=
let* (st1, _) =
- betree_node_apply_fwd self.betree_be_tree_root self.betree_be_tree_params
- self.betree_be_tree_node_id_cnt key msg st in
+ betree_Node_apply self.root self.params self.node_id_cnt key msg st in
let* (st2, (n, nic)) =
- betree_node_apply_back'a self.betree_be_tree_root
- self.betree_be_tree_params self.betree_be_tree_node_id_cnt key msg st st1
- in
+ betree_Node_apply_back'a self.root self.params self.node_id_cnt key msg st
+ st1 in
let* _ =
- betree_node_apply_back1 self.betree_be_tree_root self.betree_be_tree_params
- self.betree_be_tree_node_id_cnt key msg st st2 in
- Return (st0,
- { self with betree_be_tree_node_id_cnt = nic; betree_be_tree_root = n })
+ betree_Node_apply_back1 self.root self.params self.node_id_cnt key msg st
+ st2 in
+ Return (st0, { self with node_id_cnt = nic; root = n })
(** [betree_main::betree::BeTree::{6}::insert]: forward function *)
-let betree_be_tree_insert_fwd
- (self : betree_be_tree_t) (key : u64) (value : u64) (st : state) :
+let betree_BeTree_insert
+ (self : betree_BeTree_t) (key : u64) (value : u64) (st : state) :
result (state & unit)
=
- let* (st0, _) =
- betree_be_tree_apply_fwd self key (BetreeMessageInsert value) st in
+ let* (st0, _) = betree_BeTree_apply self key (Betree_Message_Insert value) st
+ in
let* (st1, _) =
- betree_be_tree_apply_back self key (BetreeMessageInsert value) st st0 in
+ betree_BeTree_apply_back self key (Betree_Message_Insert value) st st0 in
Return (st1, ())
(** [betree_main::betree::BeTree::{6}::insert]: backward function 0 *)
-let betree_be_tree_insert_back
- (self : betree_be_tree_t) (key : u64) (value : u64) (st : state)
- (st0 : state) :
- result (state & betree_be_tree_t)
+let betree_BeTree_insert_back
+ (self : betree_BeTree_t) (key : u64) (value : u64) (st : state) (st0 : state)
+ :
+ result (state & betree_BeTree_t)
=
- let* (st1, _) =
- betree_be_tree_apply_fwd self key (BetreeMessageInsert value) st in
+ let* (st1, _) = betree_BeTree_apply self key (Betree_Message_Insert value) st
+ in
let* (_, self0) =
- betree_be_tree_apply_back self key (BetreeMessageInsert value) st st1 in
+ betree_BeTree_apply_back self key (Betree_Message_Insert value) st st1 in
Return (st0, self0)
(** [betree_main::betree::BeTree::{6}::delete]: forward function *)
-let betree_be_tree_delete_fwd
- (self : betree_be_tree_t) (key : u64) (st : state) : result (state & unit) =
- let* (st0, _) = betree_be_tree_apply_fwd self key BetreeMessageDelete st in
- let* (st1, _) = betree_be_tree_apply_back self key BetreeMessageDelete st st0
- in
+let betree_BeTree_delete
+ (self : betree_BeTree_t) (key : u64) (st : state) : result (state & unit) =
+ let* (st0, _) = betree_BeTree_apply self key Betree_Message_Delete st in
+ let* (st1, _) =
+ betree_BeTree_apply_back self key Betree_Message_Delete st st0 in
Return (st1, ())
(** [betree_main::betree::BeTree::{6}::delete]: backward function 0 *)
-let betree_be_tree_delete_back
- (self : betree_be_tree_t) (key : u64) (st : state) (st0 : state) :
- result (state & betree_be_tree_t)
+let betree_BeTree_delete_back
+ (self : betree_BeTree_t) (key : u64) (st : state) (st0 : state) :
+ result (state & betree_BeTree_t)
=
- let* (st1, _) = betree_be_tree_apply_fwd self key BetreeMessageDelete st in
+ let* (st1, _) = betree_BeTree_apply self key Betree_Message_Delete st in
let* (_, self0) =
- betree_be_tree_apply_back self key BetreeMessageDelete st st1 in
+ betree_BeTree_apply_back self key Betree_Message_Delete st st1 in
Return (st0, self0)
(** [betree_main::betree::BeTree::{6}::upsert]: forward function *)
-let betree_be_tree_upsert_fwd
- (self : betree_be_tree_t) (key : u64) (upd : betree_upsert_fun_state_t)
+let betree_BeTree_upsert
+ (self : betree_BeTree_t) (key : u64) (upd : betree_UpsertFunState_t)
(st : state) :
result (state & unit)
=
- let* (st0, _) =
- betree_be_tree_apply_fwd self key (BetreeMessageUpsert upd) st in
+ let* (st0, _) = betree_BeTree_apply self key (Betree_Message_Upsert upd) st
+ in
let* (st1, _) =
- betree_be_tree_apply_back self key (BetreeMessageUpsert upd) st st0 in
+ betree_BeTree_apply_back self key (Betree_Message_Upsert upd) st st0 in
Return (st1, ())
(** [betree_main::betree::BeTree::{6}::upsert]: backward function 0 *)
-let betree_be_tree_upsert_back
- (self : betree_be_tree_t) (key : u64) (upd : betree_upsert_fun_state_t)
+let betree_BeTree_upsert_back
+ (self : betree_BeTree_t) (key : u64) (upd : betree_UpsertFunState_t)
(st : state) (st0 : state) :
- result (state & betree_be_tree_t)
+ result (state & betree_BeTree_t)
=
- let* (st1, _) =
- betree_be_tree_apply_fwd self key (BetreeMessageUpsert upd) st in
+ let* (st1, _) = betree_BeTree_apply self key (Betree_Message_Upsert upd) st
+ in
let* (_, self0) =
- betree_be_tree_apply_back self key (BetreeMessageUpsert upd) st st1 in
+ betree_BeTree_apply_back self key (Betree_Message_Upsert upd) st st1 in
Return (st0, self0)
(** [betree_main::betree::BeTree::{6}::lookup]: forward function *)
-let betree_be_tree_lookup_fwd
- (self : betree_be_tree_t) (key : u64) (st : state) :
+let betree_BeTree_lookup
+ (self : betree_BeTree_t) (key : u64) (st : state) :
result (state & (option u64))
=
- betree_node_lookup_fwd self.betree_be_tree_root key st
+ betree_Node_lookup self.root key st
(** [betree_main::betree::BeTree::{6}::lookup]: backward function 0 *)
-let betree_be_tree_lookup_back
- (self : betree_be_tree_t) (key : u64) (st : state) (st0 : state) :
- result (state & betree_be_tree_t)
+let betree_BeTree_lookup_back
+ (self : betree_BeTree_t) (key : u64) (st : state) (st0 : state) :
+ result (state & betree_BeTree_t)
=
- let* (st1, n) = betree_node_lookup_back self.betree_be_tree_root key st st0
- in
- Return (st1, { self with betree_be_tree_root = n })
+ let* (st1, n) = betree_Node_lookup_back self.root key st st0 in
+ Return (st1, { self with root = n })
(** [betree_main::main]: forward function *)
-let main_fwd : result unit =
+let main : result unit =
Return ()
(** Unit test for [betree_main::main] *)
-let _ = assert_norm (main_fwd = Return ())
+let _ = assert_norm (main = Return ())
diff --git a/tests/fstar/betree_back_stateful/BetreeMain.Opaque.fsti b/tests/fstar/betree_back_stateful/BetreeMain.Opaque.fsti
index c33cf225..c5d0a814 100644
--- a/tests/fstar/betree_back_stateful/BetreeMain.Opaque.fsti
+++ b/tests/fstar/betree_back_stateful/BetreeMain.Opaque.fsti
@@ -7,24 +7,24 @@ include BetreeMain.Types
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [betree_main::betree_utils::load_internal_node]: forward function *)
-val betree_utils_load_internal_node_fwd
- : u64 -> state -> result (state & (betree_list_t (u64 & betree_message_t)))
+val betree_utils_load_internal_node
+ : u64 -> state -> result (state & (betree_List_t (u64 & betree_Message_t)))
(** [betree_main::betree_utils::store_internal_node]: forward function *)
-val betree_utils_store_internal_node_fwd
+val betree_utils_store_internal_node
:
- u64 -> betree_list_t (u64 & betree_message_t) -> state -> result (state &
+ u64 -> betree_List_t (u64 & betree_Message_t) -> state -> result (state &
unit)
(** [betree_main::betree_utils::load_leaf_node]: forward function *)
-val betree_utils_load_leaf_node_fwd
- : u64 -> state -> result (state & (betree_list_t (u64 & u64)))
+val betree_utils_load_leaf_node
+ : u64 -> state -> result (state & (betree_List_t (u64 & u64)))
(** [betree_main::betree_utils::store_leaf_node]: forward function *)
-val betree_utils_store_leaf_node_fwd
- : u64 -> betree_list_t (u64 & u64) -> state -> result (state & unit)
+val betree_utils_store_leaf_node
+ : u64 -> betree_List_t (u64 & u64) -> state -> result (state & unit)
(** [core::option::Option::{0}::unwrap]: forward function *)
-val core_option_option_unwrap_fwd
+val core_option_Option_unwrap
(t : Type0) : option t -> state -> result (state & t)
diff --git a/tests/fstar/betree_back_stateful/BetreeMain.Types.fsti b/tests/fstar/betree_back_stateful/BetreeMain.Types.fsti
index a937c726..9320f6b7 100644
--- a/tests/fstar/betree_back_stateful/BetreeMain.Types.fsti
+++ b/tests/fstar/betree_back_stateful/BetreeMain.Types.fsti
@@ -6,53 +6,47 @@ open Primitives
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [betree_main::betree::List] *)
-type betree_list_t (t : Type0) =
-| BetreeListCons : t -> betree_list_t t -> betree_list_t t
-| BetreeListNil : betree_list_t t
+type betree_List_t (t : Type0) =
+| Betree_List_Cons : t -> betree_List_t t -> betree_List_t t
+| Betree_List_Nil : betree_List_t t
(** [betree_main::betree::UpsertFunState] *)
-type betree_upsert_fun_state_t =
-| BetreeUpsertFunStateAdd : u64 -> betree_upsert_fun_state_t
-| BetreeUpsertFunStateSub : u64 -> betree_upsert_fun_state_t
+type betree_UpsertFunState_t =
+| Betree_UpsertFunState_Add : u64 -> betree_UpsertFunState_t
+| Betree_UpsertFunState_Sub : u64 -> betree_UpsertFunState_t
(** [betree_main::betree::Message] *)
-type betree_message_t =
-| BetreeMessageInsert : u64 -> betree_message_t
-| BetreeMessageDelete : betree_message_t
-| BetreeMessageUpsert : betree_upsert_fun_state_t -> betree_message_t
+type betree_Message_t =
+| Betree_Message_Insert : u64 -> betree_Message_t
+| Betree_Message_Delete : betree_Message_t
+| Betree_Message_Upsert : betree_UpsertFunState_t -> betree_Message_t
(** [betree_main::betree::Leaf] *)
-type betree_leaf_t = { betree_leaf_id : u64; betree_leaf_size : u64; }
+type betree_Leaf_t = { id : u64; size : u64; }
(** [betree_main::betree::Internal] *)
-type betree_internal_t =
+type betree_Internal_t =
{
- betree_internal_id : u64;
- betree_internal_pivot : u64;
- betree_internal_left : betree_node_t;
- betree_internal_right : betree_node_t;
+ id : u64; pivot : u64; left : betree_Node_t; right : betree_Node_t;
}
(** [betree_main::betree::Node] *)
-and betree_node_t =
-| BetreeNodeInternal : betree_internal_t -> betree_node_t
-| BetreeNodeLeaf : betree_leaf_t -> betree_node_t
+and betree_Node_t =
+| Betree_Node_Internal : betree_Internal_t -> betree_Node_t
+| Betree_Node_Leaf : betree_Leaf_t -> betree_Node_t
(** [betree_main::betree::Params] *)
-type betree_params_t =
-{
- betree_params_min_flush_size : u64; betree_params_split_size : u64;
-}
+type betree_Params_t = { min_flush_size : u64; split_size : u64; }
(** [betree_main::betree::NodeIdCounter] *)
-type betree_node_id_counter_t = { betree_node_id_counter_next_node_id : u64; }
+type betree_NodeIdCounter_t = { next_node_id : u64; }
(** [betree_main::betree::BeTree] *)
-type betree_be_tree_t =
+type betree_BeTree_t =
{
- betree_be_tree_params : betree_params_t;
- betree_be_tree_node_id_cnt : betree_node_id_counter_t;
- betree_be_tree_root : betree_node_t;
+ params : betree_Params_t;
+ node_id_cnt : betree_NodeIdCounter_t;
+ root : betree_Node_t;
}
(** The state type used in the state-error monad *)
diff --git a/tests/fstar/betree_back_stateful/Primitives.fst b/tests/fstar/betree_back_stateful/Primitives.fst
index 9db82069..3297803c 100644
--- a/tests/fstar/betree_back_stateful/Primitives.fst
+++ b/tests/fstar/betree_back_stateful/Primitives.fst
@@ -55,8 +55,12 @@ type string = string
let is_zero (n: nat) : bool = n = 0
let decrease (n: nat{n > 0}) : nat = n - 1
-let mem_replace_fwd (a : Type0) (x : a) (y : a) : a = x
-let mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+let core_mem_replace (a : Type0) (x : a) (y : a) : a = x
+let core_mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+
+// We don't really use raw pointers for now
+type mut_raw_ptr (t : Type0) = { v : t }
+type const_raw_ptr (t : Type0) = { v : t }
(*** Scalars *)
/// Rem.: most of the following code was partially generated
@@ -100,6 +104,11 @@ type scalar_ty =
| U64
| U128
+let is_unsigned = function
+ | Isize | I8 | I16 | I32 | I64 | I128 -> false
+ | Usize | U8 | U16 | U32 | U64 | U128 -> true
+
+
let scalar_min (ty : scalar_ty) : int =
match ty with
| Isize -> isize_min
@@ -162,6 +171,15 @@ let scalar_sub (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scala
let scalar_mul (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
mk_scalar ty (x * y)
+let scalar_lxor (#ty : scalar_ty { is_unsigned ty && ty <> Usize })
+ (x : scalar ty) (y : scalar ty) : scalar ty =
+ match ty with
+ | U8 -> FStar.UInt.logxor #8 x y
+ | U16 -> FStar.UInt.logxor #16 x y
+ | U32 -> FStar.UInt.logxor #32 x y
+ | U64 -> FStar.UInt.logxor #64 x y
+ | U128 -> FStar.UInt.logxor #128 x y
+
(** Cast an integer from a [src_ty] to a [tgt_ty] *)
// TODO: check the semantics of casts in Rust
let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) =
@@ -169,17 +187,44 @@ let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) :
/// The scalar types
type isize : eqtype = scalar Isize
-type i8 : eqtype = scalar I8
-type i16 : eqtype = scalar I16
-type i32 : eqtype = scalar I32
-type i64 : eqtype = scalar I64
-type i128 : eqtype = scalar I128
+type i8 : eqtype = scalar I8
+type i16 : eqtype = scalar I16
+type i32 : eqtype = scalar I32
+type i64 : eqtype = scalar I64
+type i128 : eqtype = scalar I128
type usize : eqtype = scalar Usize
-type u8 : eqtype = scalar U8
-type u16 : eqtype = scalar U16
-type u32 : eqtype = scalar U32
-type u64 : eqtype = scalar U64
-type u128 : eqtype = scalar U128
+type u8 : eqtype = scalar U8
+type u16 : eqtype = scalar U16
+type u32 : eqtype = scalar U32
+type u64 : eqtype = scalar U64
+type u128 : eqtype = scalar U128
+
+
+let core_isize_min : isize = isize_min
+let core_isize_max : isize = isize_max
+let core_i8_min : i8 = i8_min
+let core_i8_max : i8 = i8_max
+let core_i16_min : i16 = i16_min
+let core_i16_max : i16 = i16_max
+let core_i32_min : i32 = i32_min
+let core_i32_max : i32 = i32_max
+let core_i64_min : i64 = i64_min
+let core_i64_max : i64 = i64_max
+let core_i128_min : i128 = i128_min
+let core_i128_max : i128 = i128_max
+
+let core_usize_min : usize = usize_min
+let core_usize_max : usize = usize_max
+let core_u8_min : u8 = u8_min
+let core_u8_max : u8 = u8_max
+let core_u16_min : u16 = u16_min
+let core_u16_max : u16 = u16_max
+let core_u32_min : u32 = u32_min
+let core_u32_max : u32 = u32_max
+let core_u64_min : u64 = u64_min
+let core_u64_max : u64 = u64_max
+let core_u128_min : u128 = u128_min
+let core_u128_max : u128 = u128_max
/// Negation
let isize_neg = scalar_neg #Isize
@@ -231,7 +276,7 @@ let u32_add = scalar_add #U32
let u64_add = scalar_add #U64
let u128_add = scalar_add #U128
-/// Substraction
+/// Subtraction
let isize_sub = scalar_sub #Isize
let i8_sub = scalar_sub #I8
let i16_sub = scalar_sub #I16
@@ -259,12 +304,65 @@ let u32_mul = scalar_mul #U32
let u64_mul = scalar_mul #U64
let u128_mul = scalar_mul #U128
-(*** Range *)
-type range (a : Type0) = {
+/// Logical operators, defined for unsigned types only, so far
+let u8_xor = scalar_lxor #U8
+let u16_xor = scalar_lxor #U16
+let u32_xor = scalar_lxor #U32
+let u64_xor = scalar_lxor #U64
+let u128_xor = scalar_lxor #U128
+
+(*** core::ops *)
+
+// Trait declaration: [core::ops::index::Index]
+noeq type core_ops_index_Index (self idx : Type0) = {
+ output : Type0;
+ index : self → idx → result output
+}
+
+// Trait declaration: [core::ops::index::IndexMut]
+noeq type core_ops_index_IndexMut (self idx : Type0) = {
+ indexInst : core_ops_index_Index self idx;
+ index_mut : self → idx → result indexInst.output;
+ index_mut_back : self → idx → indexInst.output → result self;
+}
+
+// Trait declaration [core::ops::deref::Deref]
+noeq type core_ops_deref_Deref (self : Type0) = {
+ target : Type0;
+ deref : self → result target;
+}
+
+// Trait declaration [core::ops::deref::DerefMut]
+noeq type core_ops_deref_DerefMut (self : Type0) = {
+ derefInst : core_ops_deref_Deref self;
+ deref_mut : self → result derefInst.target;
+ deref_mut_back : self → derefInst.target → result self;
+}
+
+type core_ops_range_Range (a : Type0) = {
start : a;
end_ : a;
}
+(*** [alloc] *)
+
+let alloc_boxed_Box_deref (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut_back (t : Type) (_ : t) (x : t) : result t = Return x
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefInst (self : Type0) : core_ops_deref_Deref self = {
+ target = self;
+ deref = alloc_boxed_Box_deref self;
+}
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefMutInst (self : Type0) : core_ops_deref_DerefMut self = {
+ derefInst = alloc_boxed_Box_coreOpsDerefInst self;
+ deref_mut = alloc_boxed_Box_deref_mut self;
+ deref_mut_back = alloc_boxed_Box_deref_mut_back self;
+}
+
(*** Array *)
type array (a : Type0) (n : usize) = s:list a{length s = n}
@@ -278,15 +376,11 @@ let mk_array (a : Type0) (n : usize)
normalize_term_spec (FStar.List.Tot.length l);
l
-let array_index_shared (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let array_index_mut_fwd (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
+let array_index_usize (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let array_index_mut_back (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
+let array_update_usize (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
if i < length x then Return (list_update x i nx)
else Fail Failure
@@ -295,55 +389,54 @@ type slice (a : Type0) = s:list a{length s <= usize_max}
let slice_len (a : Type0) (s : slice a) : usize = length s
-let slice_index_shared (a : Type0) (x : slice a) (i : usize) : result a =
+let slice_index_usize (a : Type0) (x : slice a) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let slice_index_mut_fwd (a : Type0) (x : slice a) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let slice_index_mut_back (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
+let slice_update_usize (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
if i < length x then Return (list_update x i nx)
else Fail Failure
(*** Subslices *)
-let array_to_slice_shared (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_fwd (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_back (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
+let array_to_slice (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
+let array_from_slice (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
if length s = n then Return s
else Fail Failure
// TODO: finish the definitions below (there lacks [List.drop] and [List.take] in the standard library *)
-let array_subslice_shared (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
- admit()
-
-let array_subslice_mut_fwd (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
+let array_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let array_subslice_mut_back (a : Type0) (n : usize) (x : array a n) (r : range usize) (ns : slice a) : result (array a n) =
+let array_update_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) (ns : slice a) : result (array a n) =
admit()
-let slice_subslice_shared (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let array_repeat (a : Type0) (n : usize) (x : a) : array a n =
admit()
-let slice_subslice_mut_fwd (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let slice_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let slice_subslice_mut_back (a : Type0) (x : slice a) (r : range usize) (ns : slice a) : result (slice a) =
+let slice_update_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) (ns : slice a) : result (slice a) =
admit()
(*** Vector *)
-type vec (a : Type0) = v:list a{length v <= usize_max}
+type alloc_vec_Vec (a : Type0) = v:list a{length v <= usize_max}
-let vec_new (a : Type0) : vec a = assert_norm(length #a [] == 0); []
-let vec_len (a : Type0) (v : vec a) : usize = length v
+let alloc_vec_Vec_new (a : Type0) : alloc_vec_Vec a = assert_norm(length #a [] == 0); []
+let alloc_vec_Vec_len (a : Type0) (v : alloc_vec_Vec a) : usize = length v
+
+// Helper
+let alloc_vec_Vec_index_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) : result a =
+ if i < length v then Return (index v i) else Fail Failure
+// Helper
+let alloc_vec_Vec_update_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
// The **forward** function shouldn't be used
-let vec_push_fwd (a : Type0) (v : vec a) (x : a) : unit = ()
-let vec_push_back (a : Type0) (v : vec a) (x : a) :
- Pure (result (vec a))
+let alloc_vec_Vec_push_fwd (a : Type0) (v : alloc_vec_Vec a) (x : a) : unit = ()
+let alloc_vec_Vec_push (a : Type0) (v : alloc_vec_Vec a) (x : a) :
+ Pure (result (alloc_vec_Vec a))
(requires True)
(ensures (fun res ->
match res with
@@ -358,18 +451,279 @@ let vec_push_back (a : Type0) (v : vec a) (x : a) :
else Fail Failure
// The **forward** function shouldn't be used
-let vec_insert_fwd (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
+let alloc_vec_Vec_insert_fwd (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result unit =
if i < length v then Return () else Fail Failure
-let vec_insert_back (a : Type0) (v : vec a) (i : usize) (x : a) : result (vec a) =
+let alloc_vec_Vec_insert (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
if i < length v then Return (list_update v i x) else Fail Failure
-// The **backward** function shouldn't be used
-let vec_index_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_back (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
- if i < length v then Return () else Fail Failure
+// Trait declaration: [core::slice::index::private_slice_index::Sealed]
+type core_slice_index_private_slice_index_Sealed (self : Type0) = unit
+
+// Trait declaration: [core::slice::index::SliceIndex]
+noeq type core_slice_index_SliceIndex (self t : Type0) = {
+ sealedInst : core_slice_index_private_slice_index_Sealed self;
+ output : Type0;
+ get : self → t → result (option output);
+ get_mut : self → t → result (option output);
+ get_mut_back : self → t → option output → result t;
+ get_unchecked : self → const_raw_ptr t → result (const_raw_ptr output);
+ get_unchecked_mut : self → mut_raw_ptr t → result (mut_raw_ptr output);
+ index : self → t → result output;
+ index_mut : self → t → result output;
+ index_mut_back : self → t → output → result t;
+}
-let vec_index_mut_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_mut_back (a : Type0) (v : vec a) (i : usize) (nx : a) : result (vec a) =
- if i < length v then Return (list_update v i nx) else Fail Failure
+// [core::slice::index::[T]::index]: forward function
+let core_slice_index_Slice_index
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (s : slice t) (i : idx) : result inst.output =
+ let* x = inst.get i s in
+ match x with
+ | None -> Fail Failure
+ | Some x -> Return x
+
+// [core::slice::index::Range:::get]: forward function
+let core_slice_index_Range_get (t : Type0) (i : core_ops_range_Range usize) (s : slice t) :
+ result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: forward function
+let core_slice_index_Range_get_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: backward function 0
+let core_slice_index_Range_get_mut_back
+ (t : Type0) :
+ core_ops_range_Range usize → slice t → option (slice t) → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_unchecked]: forward function
+let core_slice_index_Range_get_unchecked
+ (t : Type0) :
+ core_ops_range_Range usize → const_raw_ptr (slice t) → result (const_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::get_unchecked_mut]: forward function
+let core_slice_index_Range_get_unchecked_mut
+ (t : Type0) :
+ core_ops_range_Range usize → mut_raw_ptr (slice t) → result (mut_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::index]: forward function
+let core_slice_index_Range_index
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: forward function
+let core_slice_index_Range_index_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: backward function 0
+let core_slice_index_Range_index_mut_back
+ (t : Type0) : core_ops_range_Range usize → slice t → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::[T]::index_mut]: forward function
+let core_slice_index_Slice_index_mut
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → result inst.output =
+ admit () //
+
+// [core::slice::index::[T]::index_mut]: backward function 0
+let core_slice_index_Slice_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → inst.output → result (slice t) =
+ admit () // TODO
+
+// [core::array::[T; N]::index]: forward function
+let core_array_Array_index
+ (t idx : Type0) (n : usize) (inst : core_ops_index_Index (slice t) idx)
+ (a : array t n) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: forward function
+let core_array_Array_index_mut
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) : result inst.indexInst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: backward function 0
+let core_array_Array_index_mut_back
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) (x : inst.indexInst.output) : result (array t n) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (slice t) idx = {
+ output = inst.output;
+ index = core_slice_index_Slice_index t idx inst;
+}
+
+// Trait implementation: [core::slice::index::private_slice_index::Range]
+let core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) = ()
+
+// Trait implementation: [core::slice::index::Range]
+let core_slice_index_Range_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ output = slice t;
+ get = core_slice_index_Range_get t;
+ get_mut = core_slice_index_Range_get_mut t;
+ get_mut_back = core_slice_index_Range_get_mut_back t;
+ get_unchecked = core_slice_index_Range_get_unchecked t;
+ get_unchecked_mut = core_slice_index_Range_get_unchecked_mut t;
+ index = core_slice_index_Range_index t;
+ index_mut = core_slice_index_Range_index_mut t;
+ index_mut_back = core_slice_index_Range_index_mut_back t;
+}
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (slice t) idx = {
+ indexInst = core_slice_index_Slice_coreopsindexIndexInst t idx inst;
+ index_mut = core_slice_index_Slice_index_mut t idx inst;
+ index_mut_back = core_slice_index_Slice_index_mut_back t idx inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_Index (slice t) idx) :
+ core_ops_index_Index (array t n) idx = {
+ output = inst.output;
+ index = core_array_Array_index t idx n inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexMutInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_IndexMut (slice t) idx) :
+ core_ops_index_IndexMut (array t n) idx = {
+ indexInst = core_array_Array_coreopsindexIndexInst t idx n inst.indexInst;
+ index_mut = core_array_Array_index_mut t idx n inst;
+ index_mut_back = core_array_Array_index_mut_back t idx n inst;
+}
+
+// [core::slice::index::usize::get]: forward function
+let core_slice_index_usize_get
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: forward function
+let core_slice_index_usize_get_mut
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: backward function 0
+let core_slice_index_usize_get_mut_back
+ (t : Type0) : usize → slice t → option t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked]: forward function
+let core_slice_index_usize_get_unchecked
+ (t : Type0) : usize → const_raw_ptr (slice t) → result (const_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked_mut]: forward function
+let core_slice_index_usize_get_unchecked_mut
+ (t : Type0) : usize → mut_raw_ptr (slice t) → result (mut_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::index]: forward function
+let core_slice_index_usize_index (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: forward function
+let core_slice_index_usize_index_mut (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: backward function 0
+let core_slice_index_usize_index_mut_back
+ (t : Type0) : usize → slice t → t → result (slice t) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::private_slice_index::usize]
+let core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize = ()
+
+// Trait implementation: [core::slice::index::usize]
+let core_slice_index_usize_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex usize (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ output = t;
+ get = core_slice_index_usize_get t;
+ get_mut = core_slice_index_usize_get_mut t;
+ get_mut_back = core_slice_index_usize_get_mut_back t;
+ get_unchecked = core_slice_index_usize_get_unchecked t;
+ get_unchecked_mut = core_slice_index_usize_get_unchecked_mut t;
+ index = core_slice_index_usize_index t;
+ index_mut = core_slice_index_usize_index_mut t;
+ index_mut_back = core_slice_index_usize_index_mut_back t;
+}
+
+// [alloc::vec::Vec::index]: forward function
+let alloc_vec_Vec_index (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: forward function
+let alloc_vec_Vec_index_mut (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: backward function 0
+let alloc_vec_Vec_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) (x : inst.output) : result (alloc_vec_Vec t) =
+ admit () // TODO
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (alloc_vec_Vec t) idx = {
+ output = inst.output;
+ index = alloc_vec_Vec_index t idx inst;
+}
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (alloc_vec_Vec t) idx = {
+ indexInst = alloc_vec_Vec_coreopsindexIndexInst t idx inst;
+ index_mut = alloc_vec_Vec_index_mut t idx inst;
+ index_mut_back = alloc_vec_Vec_index_mut_back t idx inst;
+}
+
+(*** Theorems *)
+
+let alloc_vec_Vec_index_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_back_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) :
+ Lemma (
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x ==
+ alloc_vec_Vec_update_usize v i x)
+ [SMTPat (alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x)]
+ =
+ admit()
diff --git a/tests/fstar/hashmap/Hashmap.Clauses.Template.fst b/tests/fstar/hashmap/Hashmap.Clauses.Template.fst
index 640ae783..a1f81666 100644
--- a/tests/fstar/hashmap/Hashmap.Clauses.Template.fst
+++ b/tests/fstar/hashmap/Hashmap.Clauses.Template.fst
@@ -8,55 +8,55 @@ open Hashmap.Types
(** [hashmap::HashMap::{0}::allocate_slots]: decreases clause *)
unfold
-let hash_map_allocate_slots_loop_decreases (t : Type0) (slots : vec (list_t t))
- (n : usize) : nat =
+let hashMap_allocate_slots_loop_decreases (t : Type0)
+ (slots : alloc_vec_Vec (list_t t)) (n : usize) : nat =
admit ()
(** [hashmap::HashMap::{0}::clear]: decreases clause *)
unfold
-let hash_map_clear_loop_decreases (t : Type0) (slots : vec (list_t t))
+let hashMap_clear_loop_decreases (t : Type0) (slots : alloc_vec_Vec (list_t t))
(i : usize) : nat =
admit ()
(** [hashmap::HashMap::{0}::insert_in_list]: decreases clause *)
unfold
-let hash_map_insert_in_list_loop_decreases (t : Type0) (key : usize)
- (value : t) (ls : list_t t) : nat =
+let hashMap_insert_in_list_loop_decreases (t : Type0) (key : usize) (value : t)
+ (ls : list_t t) : nat =
admit ()
(** [hashmap::HashMap::{0}::move_elements_from_list]: decreases clause *)
unfold
-let hash_map_move_elements_from_list_loop_decreases (t : Type0)
- (ntable : hash_map_t t) (ls : list_t t) : nat =
+let hashMap_move_elements_from_list_loop_decreases (t : Type0)
+ (ntable : hashMap_t t) (ls : list_t t) : nat =
admit ()
(** [hashmap::HashMap::{0}::move_elements]: decreases clause *)
unfold
-let hash_map_move_elements_loop_decreases (t : Type0) (ntable : hash_map_t t)
- (slots : vec (list_t t)) (i : usize) : nat =
+let hashMap_move_elements_loop_decreases (t : Type0) (ntable : hashMap_t t)
+ (slots : alloc_vec_Vec (list_t t)) (i : usize) : nat =
admit ()
(** [hashmap::HashMap::{0}::contains_key_in_list]: decreases clause *)
unfold
-let hash_map_contains_key_in_list_loop_decreases (t : Type0) (key : usize)
+let hashMap_contains_key_in_list_loop_decreases (t : Type0) (key : usize)
(ls : list_t t) : nat =
admit ()
(** [hashmap::HashMap::{0}::get_in_list]: decreases clause *)
unfold
-let hash_map_get_in_list_loop_decreases (t : Type0) (key : usize)
+let hashMap_get_in_list_loop_decreases (t : Type0) (key : usize)
(ls : list_t t) : nat =
admit ()
(** [hashmap::HashMap::{0}::get_mut_in_list]: decreases clause *)
unfold
-let hash_map_get_mut_in_list_loop_decreases (t : Type0) (ls : list_t t)
+let hashMap_get_mut_in_list_loop_decreases (t : Type0) (ls : list_t t)
(key : usize) : nat =
admit ()
(** [hashmap::HashMap::{0}::remove_from_list]: decreases clause *)
unfold
-let hash_map_remove_from_list_loop_decreases (t : Type0) (key : usize)
+let hashMap_remove_from_list_loop_decreases (t : Type0) (key : usize)
(ls : list_t t) : nat =
admit ()
diff --git a/tests/fstar/hashmap/Hashmap.Clauses.fst b/tests/fstar/hashmap/Hashmap.Clauses.fst
index d8bb8d20..6c699d05 100644
--- a/tests/fstar/hashmap/Hashmap.Clauses.fst
+++ b/tests/fstar/hashmap/Hashmap.Clauses.fst
@@ -8,54 +8,54 @@ open Hashmap.Types
(** [hashmap::HashMap::allocate_slots]: decreases clause *)
unfold
-let hash_map_allocate_slots_loop_decreases (t : Type0) (slots : vec (list_t t))
- (n : usize) : nat = n
+let hashMap_allocate_slots_loop_decreases (t : Type0)
+ (slots : alloc_vec_Vec (list_t t)) (n : usize) : nat = n
(** [hashmap::HashMap::clear]: decreases clause *)
unfold
-let hash_map_clear_loop_decreases (t : Type0) (slots : vec (list_t t))
+let hashMap_clear_loop_decreases (t : Type0) (slots : alloc_vec_Vec (list_t t))
(i : usize) : nat =
if i < length slots then length slots - i else 0
(** [hashmap::HashMap::insert_in_list]: decreases clause *)
unfold
-let hash_map_insert_in_list_loop_decreases (t : Type0) (key : usize) (value : t)
+let hashMap_insert_in_list_loop_decreases (t : Type0) (key : usize) (value : t)
(ls : list_t t) : list_t t =
ls
(** [hashmap::HashMap::move_elements_from_list]: decreases clause *)
unfold
-let hash_map_move_elements_from_list_loop_decreases (t : Type0)
- (ntable : hash_map_t t) (ls : list_t t) : list_t t =
+let hashMap_move_elements_from_list_loop_decreases (t : Type0)
+ (ntable : hashMap_t t) (ls : list_t t) : list_t t =
ls
(** [hashmap::HashMap::move_elements]: decreases clause *)
unfold
-let hash_map_move_elements_loop_decreases (t : Type0) (ntable : hash_map_t t)
- (slots : vec (list_t t)) (i : usize) : nat =
+let hashMap_move_elements_loop_decreases (t : Type0) (ntable : hashMap_t t)
+ (slots : alloc_vec_Vec (list_t t)) (i : usize) : nat =
if i < length slots then length slots - i else 0
(** [hashmap::HashMap::contains_key_in_list]: decreases clause *)
unfold
-let hash_map_contains_key_in_list_loop_decreases (t : Type0) (key : usize)
+let hashMap_contains_key_in_list_loop_decreases (t : Type0) (key : usize)
(ls : list_t t) : list_t t =
ls
(** [hashmap::HashMap::get_in_list]: decreases clause *)
unfold
-let hash_map_get_in_list_loop_decreases (t : Type0) (key : usize) (ls : list_t t) :
+let hashMap_get_in_list_loop_decreases (t : Type0) (key : usize) (ls : list_t t) :
list_t t =
ls
(** [hashmap::HashMap::get_mut_in_list]: decreases clause *)
unfold
-let hash_map_get_mut_in_list_loop_decreases (t : Type0) (ls : list_t t)
+let hashMap_get_mut_in_list_loop_decreases (t : Type0) (ls : list_t t)
(key : usize) : list_t t =
ls
(** [hashmap::HashMap::remove_from_list]: decreases clause *)
unfold
-let hash_map_remove_from_list_loop_decreases (t : Type0) (key : usize)
+let hashMap_remove_from_list_loop_decreases (t : Type0) (key : usize)
(ls : list_t t) : list_t t =
ls
diff --git a/tests/fstar/hashmap/Hashmap.Funs.fst b/tests/fstar/hashmap/Hashmap.Funs.fst
index f4c13a7b..0e31e364 100644
--- a/tests/fstar/hashmap/Hashmap.Funs.fst
+++ b/tests/fstar/hashmap/Hashmap.Funs.fst
@@ -8,460 +8,486 @@ include Hashmap.Clauses
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [hashmap::hash_key]: forward function *)
-let hash_key_fwd (k : usize) : result usize =
+let hash_key (k : usize) : result usize =
Return k
(** [hashmap::HashMap::{0}::allocate_slots]: loop 0: forward function *)
-let rec hash_map_allocate_slots_loop_fwd
- (t : Type0) (slots : vec (list_t t)) (n : usize) :
- Tot (result (vec (list_t t)))
- (decreases (hash_map_allocate_slots_loop_decreases t slots n))
+let rec hashMap_allocate_slots_loop
+ (t : Type0) (slots : alloc_vec_Vec (list_t t)) (n : usize) :
+ Tot (result (alloc_vec_Vec (list_t t)))
+ (decreases (hashMap_allocate_slots_loop_decreases t slots n))
=
if n > 0
then
- let* slots0 = vec_push_back (list_t t) slots ListNil in
+ let* slots0 = alloc_vec_Vec_push (list_t t) slots List_Nil in
let* n0 = usize_sub n 1 in
- hash_map_allocate_slots_loop_fwd t slots0 n0
+ hashMap_allocate_slots_loop t slots0 n0
else Return slots
(** [hashmap::HashMap::{0}::allocate_slots]: forward function *)
-let hash_map_allocate_slots_fwd
- (t : Type0) (slots : vec (list_t t)) (n : usize) : result (vec (list_t t)) =
- hash_map_allocate_slots_loop_fwd t slots n
+let hashMap_allocate_slots
+ (t : Type0) (slots : alloc_vec_Vec (list_t t)) (n : usize) :
+ result (alloc_vec_Vec (list_t t))
+ =
+ hashMap_allocate_slots_loop t slots n
(** [hashmap::HashMap::{0}::new_with_capacity]: forward function *)
-let hash_map_new_with_capacity_fwd
+let hashMap_new_with_capacity
(t : Type0) (capacity : usize) (max_load_dividend : usize)
(max_load_divisor : usize) :
- result (hash_map_t t)
+ result (hashMap_t t)
=
- let v = vec_new (list_t t) in
- let* slots = hash_map_allocate_slots_fwd t v capacity in
+ let v = alloc_vec_Vec_new (list_t t) in
+ let* slots = hashMap_allocate_slots t v capacity in
let* i = usize_mul capacity max_load_dividend in
let* i0 = usize_div i max_load_divisor in
Return
{
- hash_map_num_entries = 0;
- hash_map_max_load_factor = (max_load_dividend, max_load_divisor);
- hash_map_max_load = i0;
- hash_map_slots = slots
+ num_entries = 0;
+ max_load_factor = (max_load_dividend, max_load_divisor);
+ max_load = i0;
+ slots = slots
}
(** [hashmap::HashMap::{0}::new]: forward function *)
-let hash_map_new_fwd (t : Type0) : result (hash_map_t t) =
- hash_map_new_with_capacity_fwd t 32 4 5
+let hashMap_new (t : Type0) : result (hashMap_t t) =
+ hashMap_new_with_capacity t 32 4 5
(** [hashmap::HashMap::{0}::clear]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec hash_map_clear_loop_fwd_back
- (t : Type0) (slots : vec (list_t t)) (i : usize) :
- Tot (result (vec (list_t t)))
- (decreases (hash_map_clear_loop_decreases t slots i))
+let rec hashMap_clear_loop
+ (t : Type0) (slots : alloc_vec_Vec (list_t t)) (i : usize) :
+ Tot (result (alloc_vec_Vec (list_t t)))
+ (decreases (hashMap_clear_loop_decreases t slots i))
=
- let i0 = vec_len (list_t t) slots in
+ let i0 = alloc_vec_Vec_len (list_t t) slots in
if i < i0
then
let* i1 = usize_add i 1 in
- let* slots0 = vec_index_mut_back (list_t t) slots i ListNil in
- hash_map_clear_loop_fwd_back t slots0 i1
+ let* slots0 =
+ alloc_vec_Vec_index_mut_back (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t)) slots
+ i List_Nil in
+ hashMap_clear_loop t slots0 i1
else Return slots
(** [hashmap::HashMap::{0}::clear]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hash_map_clear_fwd_back
- (t : Type0) (self : hash_map_t t) : result (hash_map_t t) =
- let* v = hash_map_clear_loop_fwd_back t self.hash_map_slots 0 in
- Return { self with hash_map_num_entries = 0; hash_map_slots = v }
+let hashMap_clear (t : Type0) (self : hashMap_t t) : result (hashMap_t t) =
+ let* v = hashMap_clear_loop t self.slots 0 in
+ Return { self with num_entries = 0; slots = v }
(** [hashmap::HashMap::{0}::len]: forward function *)
-let hash_map_len_fwd (t : Type0) (self : hash_map_t t) : result usize =
- Return self.hash_map_num_entries
+let hashMap_len (t : Type0) (self : hashMap_t t) : result usize =
+ Return self.num_entries
(** [hashmap::HashMap::{0}::insert_in_list]: loop 0: forward function *)
-let rec hash_map_insert_in_list_loop_fwd
+let rec hashMap_insert_in_list_loop
(t : Type0) (key : usize) (value : t) (ls : list_t t) :
Tot (result bool)
- (decreases (hash_map_insert_in_list_loop_decreases t key value ls))
+ (decreases (hashMap_insert_in_list_loop_decreases t key value ls))
=
begin match ls with
- | ListCons ckey cvalue tl ->
+ | List_Cons ckey cvalue tl ->
if ckey = key
then Return false
- else hash_map_insert_in_list_loop_fwd t key value tl
- | ListNil -> Return true
+ else hashMap_insert_in_list_loop t key value tl
+ | List_Nil -> Return true
end
(** [hashmap::HashMap::{0}::insert_in_list]: forward function *)
-let hash_map_insert_in_list_fwd
+let hashMap_insert_in_list
(t : Type0) (key : usize) (value : t) (ls : list_t t) : result bool =
- hash_map_insert_in_list_loop_fwd t key value ls
+ hashMap_insert_in_list_loop t key value ls
(** [hashmap::HashMap::{0}::insert_in_list]: loop 0: backward function 0 *)
-let rec hash_map_insert_in_list_loop_back
+let rec hashMap_insert_in_list_loop_back
(t : Type0) (key : usize) (value : t) (ls : list_t t) :
Tot (result (list_t t))
- (decreases (hash_map_insert_in_list_loop_decreases t key value ls))
+ (decreases (hashMap_insert_in_list_loop_decreases t key value ls))
=
begin match ls with
- | ListCons ckey cvalue tl ->
+ | List_Cons ckey cvalue tl ->
if ckey = key
- then Return (ListCons ckey value tl)
+ then Return (List_Cons ckey value tl)
else
- let* tl0 = hash_map_insert_in_list_loop_back t key value tl in
- Return (ListCons ckey cvalue tl0)
- | ListNil -> let l = ListNil in Return (ListCons key value l)
+ let* tl0 = hashMap_insert_in_list_loop_back t key value tl in
+ Return (List_Cons ckey cvalue tl0)
+ | List_Nil -> let l = List_Nil in Return (List_Cons key value l)
end
(** [hashmap::HashMap::{0}::insert_in_list]: backward function 0 *)
-let hash_map_insert_in_list_back
+let hashMap_insert_in_list_back
(t : Type0) (key : usize) (value : t) (ls : list_t t) : result (list_t t) =
- hash_map_insert_in_list_loop_back t key value ls
+ hashMap_insert_in_list_loop_back t key value ls
(** [hashmap::HashMap::{0}::insert_no_resize]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hash_map_insert_no_resize_fwd_back
- (t : Type0) (self : hash_map_t t) (key : usize) (value : t) :
- result (hash_map_t t)
+let hashMap_insert_no_resize
+ (t : Type0) (self : hashMap_t t) (key : usize) (value : t) :
+ result (hashMap_t t)
=
- let* hash = hash_key_fwd key in
- let i = vec_len (list_t t) self.hash_map_slots in
+ let* hash = hash_key key in
+ let i = alloc_vec_Vec_len (list_t t) self.slots in
let* hash_mod = usize_rem hash i in
- let* l = vec_index_mut_fwd (list_t t) self.hash_map_slots hash_mod in
- let* inserted = hash_map_insert_in_list_fwd t key value l in
+ let* l =
+ alloc_vec_Vec_index_mut (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod in
+ let* inserted = hashMap_insert_in_list t key value l in
if inserted
then
- let* i0 = usize_add self.hash_map_num_entries 1 in
- let* l0 = hash_map_insert_in_list_back t key value l in
- let* v = vec_index_mut_back (list_t t) self.hash_map_slots hash_mod l0 in
- Return { self with hash_map_num_entries = i0; hash_map_slots = v }
+ let* i0 = usize_add self.num_entries 1 in
+ let* l0 = hashMap_insert_in_list_back t key value l in
+ let* v =
+ alloc_vec_Vec_index_mut_back (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod l0 in
+ Return { self with num_entries = i0; slots = v }
else
- let* l0 = hash_map_insert_in_list_back t key value l in
- let* v = vec_index_mut_back (list_t t) self.hash_map_slots hash_mod l0 in
- Return { self with hash_map_slots = v }
-
-(** [core::num::u32::{8}::MAX] *)
-let core_num_u32_max_body : result u32 = Return 4294967295
-let core_num_u32_max_c : u32 = eval_global core_num_u32_max_body
+ let* l0 = hashMap_insert_in_list_back t key value l in
+ let* v =
+ alloc_vec_Vec_index_mut_back (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod l0 in
+ Return { self with slots = v }
(** [hashmap::HashMap::{0}::move_elements_from_list]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec hash_map_move_elements_from_list_loop_fwd_back
- (t : Type0) (ntable : hash_map_t t) (ls : list_t t) :
- Tot (result (hash_map_t t))
- (decreases (hash_map_move_elements_from_list_loop_decreases t ntable ls))
+let rec hashMap_move_elements_from_list_loop
+ (t : Type0) (ntable : hashMap_t t) (ls : list_t t) :
+ Tot (result (hashMap_t t))
+ (decreases (hashMap_move_elements_from_list_loop_decreases t ntable ls))
=
begin match ls with
- | ListCons k v tl ->
- let* ntable0 = hash_map_insert_no_resize_fwd_back t ntable k v in
- hash_map_move_elements_from_list_loop_fwd_back t ntable0 tl
- | ListNil -> Return ntable
+ | List_Cons k v tl ->
+ let* ntable0 = hashMap_insert_no_resize t ntable k v in
+ hashMap_move_elements_from_list_loop t ntable0 tl
+ | List_Nil -> Return ntable
end
(** [hashmap::HashMap::{0}::move_elements_from_list]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hash_map_move_elements_from_list_fwd_back
- (t : Type0) (ntable : hash_map_t t) (ls : list_t t) : result (hash_map_t t) =
- hash_map_move_elements_from_list_loop_fwd_back t ntable ls
+let hashMap_move_elements_from_list
+ (t : Type0) (ntable : hashMap_t t) (ls : list_t t) : result (hashMap_t t) =
+ hashMap_move_elements_from_list_loop t ntable ls
(** [hashmap::HashMap::{0}::move_elements]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec hash_map_move_elements_loop_fwd_back
- (t : Type0) (ntable : hash_map_t t) (slots : vec (list_t t)) (i : usize) :
- Tot (result ((hash_map_t t) & (vec (list_t t))))
- (decreases (hash_map_move_elements_loop_decreases t ntable slots i))
+let rec hashMap_move_elements_loop
+ (t : Type0) (ntable : hashMap_t t) (slots : alloc_vec_Vec (list_t t))
+ (i : usize) :
+ Tot (result ((hashMap_t t) & (alloc_vec_Vec (list_t t))))
+ (decreases (hashMap_move_elements_loop_decreases t ntable slots i))
=
- let i0 = vec_len (list_t t) slots in
+ let i0 = alloc_vec_Vec_len (list_t t) slots in
if i < i0
then
- let* l = vec_index_mut_fwd (list_t t) slots i in
- let ls = mem_replace_fwd (list_t t) l ListNil in
- let* ntable0 = hash_map_move_elements_from_list_fwd_back t ntable ls in
+ let* l =
+ alloc_vec_Vec_index_mut (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t)) slots
+ i in
+ let ls = core_mem_replace (list_t t) l List_Nil in
+ let* ntable0 = hashMap_move_elements_from_list t ntable ls in
let* i1 = usize_add i 1 in
- let l0 = mem_replace_back (list_t t) l ListNil in
- let* slots0 = vec_index_mut_back (list_t t) slots i l0 in
- hash_map_move_elements_loop_fwd_back t ntable0 slots0 i1
+ let l0 = core_mem_replace_back (list_t t) l List_Nil in
+ let* slots0 =
+ alloc_vec_Vec_index_mut_back (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t)) slots
+ i l0 in
+ hashMap_move_elements_loop t ntable0 slots0 i1
else Return (ntable, slots)
(** [hashmap::HashMap::{0}::move_elements]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hash_map_move_elements_fwd_back
- (t : Type0) (ntable : hash_map_t t) (slots : vec (list_t t)) (i : usize) :
- result ((hash_map_t t) & (vec (list_t t)))
+let hashMap_move_elements
+ (t : Type0) (ntable : hashMap_t t) (slots : alloc_vec_Vec (list_t t))
+ (i : usize) :
+ result ((hashMap_t t) & (alloc_vec_Vec (list_t t)))
=
- hash_map_move_elements_loop_fwd_back t ntable slots i
+ hashMap_move_elements_loop t ntable slots i
(** [hashmap::HashMap::{0}::try_resize]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hash_map_try_resize_fwd_back
- (t : Type0) (self : hash_map_t t) : result (hash_map_t t) =
- let* max_usize = scalar_cast U32 Usize core_num_u32_max_c in
- let capacity = vec_len (list_t t) self.hash_map_slots in
+let hashMap_try_resize
+ (t : Type0) (self : hashMap_t t) : result (hashMap_t t) =
+ let* max_usize = scalar_cast U32 Usize core_u32_max in
+ let capacity = alloc_vec_Vec_len (list_t t) self.slots in
let* n1 = usize_div max_usize 2 in
- let (i, i0) = self.hash_map_max_load_factor in
+ let (i, i0) = self.max_load_factor in
let* i1 = usize_div n1 i in
if capacity <= i1
then
let* i2 = usize_mul capacity 2 in
- let* ntable = hash_map_new_with_capacity_fwd t i2 i i0 in
- let* (ntable0, _) =
- hash_map_move_elements_fwd_back t ntable self.hash_map_slots 0 in
+ let* ntable = hashMap_new_with_capacity t i2 i i0 in
+ let* (ntable0, _) = hashMap_move_elements t ntable self.slots 0 in
Return
- {
- ntable0
- with
- hash_map_num_entries = self.hash_map_num_entries;
- hash_map_max_load_factor = (i, i0)
+ { ntable0 with num_entries = self.num_entries; max_load_factor = (i, i0)
}
- else Return { self with hash_map_max_load_factor = (i, i0) }
+ else Return { self with max_load_factor = (i, i0) }
(** [hashmap::HashMap::{0}::insert]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hash_map_insert_fwd_back
- (t : Type0) (self : hash_map_t t) (key : usize) (value : t) :
- result (hash_map_t t)
+let hashMap_insert
+ (t : Type0) (self : hashMap_t t) (key : usize) (value : t) :
+ result (hashMap_t t)
=
- let* self0 = hash_map_insert_no_resize_fwd_back t self key value in
- let* i = hash_map_len_fwd t self0 in
- if i > self0.hash_map_max_load
- then hash_map_try_resize_fwd_back t self0
- else Return self0
+ let* self0 = hashMap_insert_no_resize t self key value in
+ let* i = hashMap_len t self0 in
+ if i > self0.max_load then hashMap_try_resize t self0 else Return self0
(** [hashmap::HashMap::{0}::contains_key_in_list]: loop 0: forward function *)
-let rec hash_map_contains_key_in_list_loop_fwd
+let rec hashMap_contains_key_in_list_loop
(t : Type0) (key : usize) (ls : list_t t) :
Tot (result bool)
- (decreases (hash_map_contains_key_in_list_loop_decreases t key ls))
+ (decreases (hashMap_contains_key_in_list_loop_decreases t key ls))
=
begin match ls with
- | ListCons ckey x tl ->
+ | List_Cons ckey x tl ->
if ckey = key
then Return true
- else hash_map_contains_key_in_list_loop_fwd t key tl
- | ListNil -> Return false
+ else hashMap_contains_key_in_list_loop t key tl
+ | List_Nil -> Return false
end
(** [hashmap::HashMap::{0}::contains_key_in_list]: forward function *)
-let hash_map_contains_key_in_list_fwd
+let hashMap_contains_key_in_list
(t : Type0) (key : usize) (ls : list_t t) : result bool =
- hash_map_contains_key_in_list_loop_fwd t key ls
+ hashMap_contains_key_in_list_loop t key ls
(** [hashmap::HashMap::{0}::contains_key]: forward function *)
-let hash_map_contains_key_fwd
- (t : Type0) (self : hash_map_t t) (key : usize) : result bool =
- let* hash = hash_key_fwd key in
- let i = vec_len (list_t t) self.hash_map_slots in
+let hashMap_contains_key
+ (t : Type0) (self : hashMap_t t) (key : usize) : result bool =
+ let* hash = hash_key key in
+ let i = alloc_vec_Vec_len (list_t t) self.slots in
let* hash_mod = usize_rem hash i in
- let* l = vec_index_fwd (list_t t) self.hash_map_slots hash_mod in
- hash_map_contains_key_in_list_fwd t key l
+ let* l =
+ alloc_vec_Vec_index (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod in
+ hashMap_contains_key_in_list t key l
(** [hashmap::HashMap::{0}::get_in_list]: loop 0: forward function *)
-let rec hash_map_get_in_list_loop_fwd
+let rec hashMap_get_in_list_loop
(t : Type0) (key : usize) (ls : list_t t) :
- Tot (result t) (decreases (hash_map_get_in_list_loop_decreases t key ls))
+ Tot (result t) (decreases (hashMap_get_in_list_loop_decreases t key ls))
=
begin match ls with
- | ListCons ckey cvalue tl ->
- if ckey = key
- then Return cvalue
- else hash_map_get_in_list_loop_fwd t key tl
- | ListNil -> Fail Failure
+ | List_Cons ckey cvalue tl ->
+ if ckey = key then Return cvalue else hashMap_get_in_list_loop t key tl
+ | List_Nil -> Fail Failure
end
(** [hashmap::HashMap::{0}::get_in_list]: forward function *)
-let hash_map_get_in_list_fwd
- (t : Type0) (key : usize) (ls : list_t t) : result t =
- hash_map_get_in_list_loop_fwd t key ls
+let hashMap_get_in_list (t : Type0) (key : usize) (ls : list_t t) : result t =
+ hashMap_get_in_list_loop t key ls
(** [hashmap::HashMap::{0}::get]: forward function *)
-let hash_map_get_fwd
- (t : Type0) (self : hash_map_t t) (key : usize) : result t =
- let* hash = hash_key_fwd key in
- let i = vec_len (list_t t) self.hash_map_slots in
+let hashMap_get (t : Type0) (self : hashMap_t t) (key : usize) : result t =
+ let* hash = hash_key key in
+ let i = alloc_vec_Vec_len (list_t t) self.slots in
let* hash_mod = usize_rem hash i in
- let* l = vec_index_fwd (list_t t) self.hash_map_slots hash_mod in
- hash_map_get_in_list_fwd t key l
+ let* l =
+ alloc_vec_Vec_index (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod in
+ hashMap_get_in_list t key l
(** [hashmap::HashMap::{0}::get_mut_in_list]: loop 0: forward function *)
-let rec hash_map_get_mut_in_list_loop_fwd
+let rec hashMap_get_mut_in_list_loop
(t : Type0) (ls : list_t t) (key : usize) :
- Tot (result t) (decreases (hash_map_get_mut_in_list_loop_decreases t ls key))
+ Tot (result t) (decreases (hashMap_get_mut_in_list_loop_decreases t ls key))
=
begin match ls with
- | ListCons ckey cvalue tl ->
- if ckey = key
- then Return cvalue
- else hash_map_get_mut_in_list_loop_fwd t tl key
- | ListNil -> Fail Failure
+ | List_Cons ckey cvalue tl ->
+ if ckey = key then Return cvalue else hashMap_get_mut_in_list_loop t tl key
+ | List_Nil -> Fail Failure
end
(** [hashmap::HashMap::{0}::get_mut_in_list]: forward function *)
-let hash_map_get_mut_in_list_fwd
+let hashMap_get_mut_in_list
(t : Type0) (ls : list_t t) (key : usize) : result t =
- hash_map_get_mut_in_list_loop_fwd t ls key
+ hashMap_get_mut_in_list_loop t ls key
(** [hashmap::HashMap::{0}::get_mut_in_list]: loop 0: backward function 0 *)
-let rec hash_map_get_mut_in_list_loop_back
+let rec hashMap_get_mut_in_list_loop_back
(t : Type0) (ls : list_t t) (key : usize) (ret : t) :
Tot (result (list_t t))
- (decreases (hash_map_get_mut_in_list_loop_decreases t ls key))
+ (decreases (hashMap_get_mut_in_list_loop_decreases t ls key))
=
begin match ls with
- | ListCons ckey cvalue tl ->
+ | List_Cons ckey cvalue tl ->
if ckey = key
- then Return (ListCons ckey ret tl)
+ then Return (List_Cons ckey ret tl)
else
- let* tl0 = hash_map_get_mut_in_list_loop_back t tl key ret in
- Return (ListCons ckey cvalue tl0)
- | ListNil -> Fail Failure
+ let* tl0 = hashMap_get_mut_in_list_loop_back t tl key ret in
+ Return (List_Cons ckey cvalue tl0)
+ | List_Nil -> Fail Failure
end
(** [hashmap::HashMap::{0}::get_mut_in_list]: backward function 0 *)
-let hash_map_get_mut_in_list_back
+let hashMap_get_mut_in_list_back
(t : Type0) (ls : list_t t) (key : usize) (ret : t) : result (list_t t) =
- hash_map_get_mut_in_list_loop_back t ls key ret
+ hashMap_get_mut_in_list_loop_back t ls key ret
(** [hashmap::HashMap::{0}::get_mut]: forward function *)
-let hash_map_get_mut_fwd
- (t : Type0) (self : hash_map_t t) (key : usize) : result t =
- let* hash = hash_key_fwd key in
- let i = vec_len (list_t t) self.hash_map_slots in
+let hashMap_get_mut (t : Type0) (self : hashMap_t t) (key : usize) : result t =
+ let* hash = hash_key key in
+ let i = alloc_vec_Vec_len (list_t t) self.slots in
let* hash_mod = usize_rem hash i in
- let* l = vec_index_mut_fwd (list_t t) self.hash_map_slots hash_mod in
- hash_map_get_mut_in_list_fwd t l key
+ let* l =
+ alloc_vec_Vec_index_mut (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod in
+ hashMap_get_mut_in_list t l key
(** [hashmap::HashMap::{0}::get_mut]: backward function 0 *)
-let hash_map_get_mut_back
- (t : Type0) (self : hash_map_t t) (key : usize) (ret : t) :
- result (hash_map_t t)
+let hashMap_get_mut_back
+ (t : Type0) (self : hashMap_t t) (key : usize) (ret : t) :
+ result (hashMap_t t)
=
- let* hash = hash_key_fwd key in
- let i = vec_len (list_t t) self.hash_map_slots in
+ let* hash = hash_key key in
+ let i = alloc_vec_Vec_len (list_t t) self.slots in
let* hash_mod = usize_rem hash i in
- let* l = vec_index_mut_fwd (list_t t) self.hash_map_slots hash_mod in
- let* l0 = hash_map_get_mut_in_list_back t l key ret in
- let* v = vec_index_mut_back (list_t t) self.hash_map_slots hash_mod l0 in
- Return { self with hash_map_slots = v }
+ let* l =
+ alloc_vec_Vec_index_mut (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod in
+ let* l0 = hashMap_get_mut_in_list_back t l key ret in
+ let* v =
+ alloc_vec_Vec_index_mut_back (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod l0 in
+ Return { self with slots = v }
(** [hashmap::HashMap::{0}::remove_from_list]: loop 0: forward function *)
-let rec hash_map_remove_from_list_loop_fwd
+let rec hashMap_remove_from_list_loop
(t : Type0) (key : usize) (ls : list_t t) :
Tot (result (option t))
- (decreases (hash_map_remove_from_list_loop_decreases t key ls))
+ (decreases (hashMap_remove_from_list_loop_decreases t key ls))
=
begin match ls with
- | ListCons ckey x tl ->
+ | List_Cons ckey x tl ->
if ckey = key
then
- let mv_ls = mem_replace_fwd (list_t t) (ListCons ckey x tl) ListNil in
+ let mv_ls = core_mem_replace (list_t t) (List_Cons ckey x tl) List_Nil in
begin match mv_ls with
- | ListCons i cvalue tl0 -> Return (Some cvalue)
- | ListNil -> Fail Failure
+ | List_Cons i cvalue tl0 -> Return (Some cvalue)
+ | List_Nil -> Fail Failure
end
- else hash_map_remove_from_list_loop_fwd t key tl
- | ListNil -> Return None
+ else hashMap_remove_from_list_loop t key tl
+ | List_Nil -> Return None
end
(** [hashmap::HashMap::{0}::remove_from_list]: forward function *)
-let hash_map_remove_from_list_fwd
+let hashMap_remove_from_list
(t : Type0) (key : usize) (ls : list_t t) : result (option t) =
- hash_map_remove_from_list_loop_fwd t key ls
+ hashMap_remove_from_list_loop t key ls
(** [hashmap::HashMap::{0}::remove_from_list]: loop 0: backward function 1 *)
-let rec hash_map_remove_from_list_loop_back
+let rec hashMap_remove_from_list_loop_back
(t : Type0) (key : usize) (ls : list_t t) :
Tot (result (list_t t))
- (decreases (hash_map_remove_from_list_loop_decreases t key ls))
+ (decreases (hashMap_remove_from_list_loop_decreases t key ls))
=
begin match ls with
- | ListCons ckey x tl ->
+ | List_Cons ckey x tl ->
if ckey = key
then
- let mv_ls = mem_replace_fwd (list_t t) (ListCons ckey x tl) ListNil in
+ let mv_ls = core_mem_replace (list_t t) (List_Cons ckey x tl) List_Nil in
begin match mv_ls with
- | ListCons i cvalue tl0 -> Return tl0
- | ListNil -> Fail Failure
+ | List_Cons i cvalue tl0 -> Return tl0
+ | List_Nil -> Fail Failure
end
else
- let* tl0 = hash_map_remove_from_list_loop_back t key tl in
- Return (ListCons ckey x tl0)
- | ListNil -> Return ListNil
+ let* tl0 = hashMap_remove_from_list_loop_back t key tl in
+ Return (List_Cons ckey x tl0)
+ | List_Nil -> Return List_Nil
end
(** [hashmap::HashMap::{0}::remove_from_list]: backward function 1 *)
-let hash_map_remove_from_list_back
+let hashMap_remove_from_list_back
(t : Type0) (key : usize) (ls : list_t t) : result (list_t t) =
- hash_map_remove_from_list_loop_back t key ls
+ hashMap_remove_from_list_loop_back t key ls
(** [hashmap::HashMap::{0}::remove]: forward function *)
-let hash_map_remove_fwd
- (t : Type0) (self : hash_map_t t) (key : usize) : result (option t) =
- let* hash = hash_key_fwd key in
- let i = vec_len (list_t t) self.hash_map_slots in
+let hashMap_remove
+ (t : Type0) (self : hashMap_t t) (key : usize) : result (option t) =
+ let* hash = hash_key key in
+ let i = alloc_vec_Vec_len (list_t t) self.slots in
let* hash_mod = usize_rem hash i in
- let* l = vec_index_mut_fwd (list_t t) self.hash_map_slots hash_mod in
- let* x = hash_map_remove_from_list_fwd t key l in
+ let* l =
+ alloc_vec_Vec_index_mut (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod in
+ let* x = hashMap_remove_from_list t key l in
begin match x with
| None -> Return None
- | Some x0 ->
- let* _ = usize_sub self.hash_map_num_entries 1 in Return (Some x0)
+ | Some x0 -> let* _ = usize_sub self.num_entries 1 in Return (Some x0)
end
(** [hashmap::HashMap::{0}::remove]: backward function 0 *)
-let hash_map_remove_back
- (t : Type0) (self : hash_map_t t) (key : usize) : result (hash_map_t t) =
- let* hash = hash_key_fwd key in
- let i = vec_len (list_t t) self.hash_map_slots in
+let hashMap_remove_back
+ (t : Type0) (self : hashMap_t t) (key : usize) : result (hashMap_t t) =
+ let* hash = hash_key key in
+ let i = alloc_vec_Vec_len (list_t t) self.slots in
let* hash_mod = usize_rem hash i in
- let* l = vec_index_mut_fwd (list_t t) self.hash_map_slots hash_mod in
- let* x = hash_map_remove_from_list_fwd t key l in
+ let* l =
+ alloc_vec_Vec_index_mut (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod in
+ let* x = hashMap_remove_from_list t key l in
begin match x with
| None ->
- let* l0 = hash_map_remove_from_list_back t key l in
- let* v = vec_index_mut_back (list_t t) self.hash_map_slots hash_mod l0 in
- Return { self with hash_map_slots = v }
+ let* l0 = hashMap_remove_from_list_back t key l in
+ let* v =
+ alloc_vec_Vec_index_mut_back (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod l0 in
+ Return { self with slots = v }
| Some x0 ->
- let* i0 = usize_sub self.hash_map_num_entries 1 in
- let* l0 = hash_map_remove_from_list_back t key l in
- let* v = vec_index_mut_back (list_t t) self.hash_map_slots hash_mod l0 in
- Return { self with hash_map_num_entries = i0; hash_map_slots = v }
+ let* i0 = usize_sub self.num_entries 1 in
+ let* l0 = hashMap_remove_from_list_back t key l in
+ let* v =
+ alloc_vec_Vec_index_mut_back (list_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t t))
+ self.slots hash_mod l0 in
+ Return { self with num_entries = i0; slots = v }
end
(** [hashmap::test1]: forward function *)
-let test1_fwd : result unit =
- let* hm = hash_map_new_fwd u64 in
- let* hm0 = hash_map_insert_fwd_back u64 hm 0 42 in
- let* hm1 = hash_map_insert_fwd_back u64 hm0 128 18 in
- let* hm2 = hash_map_insert_fwd_back u64 hm1 1024 138 in
- let* hm3 = hash_map_insert_fwd_back u64 hm2 1056 256 in
- let* i = hash_map_get_fwd u64 hm3 128 in
+let test1 : result unit =
+ let* hm = hashMap_new u64 in
+ let* hm0 = hashMap_insert u64 hm 0 42 in
+ let* hm1 = hashMap_insert u64 hm0 128 18 in
+ let* hm2 = hashMap_insert u64 hm1 1024 138 in
+ let* hm3 = hashMap_insert u64 hm2 1056 256 in
+ let* i = hashMap_get u64 hm3 128 in
if not (i = 18)
then Fail Failure
else
- let* hm4 = hash_map_get_mut_back u64 hm3 1024 56 in
- let* i0 = hash_map_get_fwd u64 hm4 1024 in
+ let* hm4 = hashMap_get_mut_back u64 hm3 1024 56 in
+ let* i0 = hashMap_get u64 hm4 1024 in
if not (i0 = 56)
then Fail Failure
else
- let* x = hash_map_remove_fwd u64 hm4 1024 in
+ let* x = hashMap_remove u64 hm4 1024 in
begin match x with
| None -> Fail Failure
| Some x0 ->
if not (x0 = 56)
then Fail Failure
else
- let* hm5 = hash_map_remove_back u64 hm4 1024 in
- let* i1 = hash_map_get_fwd u64 hm5 0 in
+ let* hm5 = hashMap_remove_back u64 hm4 1024 in
+ let* i1 = hashMap_get u64 hm5 0 in
if not (i1 = 42)
then Fail Failure
else
- let* i2 = hash_map_get_fwd u64 hm5 128 in
+ let* i2 = hashMap_get u64 hm5 128 in
if not (i2 = 18)
then Fail Failure
else
- let* i3 = hash_map_get_fwd u64 hm5 1056 in
+ let* i3 = hashMap_get u64 hm5 1056 in
if not (i3 = 256) then Fail Failure else Return ()
end
-(** Unit test for [hashmap::test1] *)
-let _ = assert_norm (test1_fwd = Return ())
-
diff --git a/tests/fstar/hashmap/Hashmap.Properties.fst b/tests/fstar/hashmap/Hashmap.Properties.fst
index 49d96cd5..def520f0 100644
--- a/tests/fstar/hashmap/Hashmap.Properties.fst
+++ b/tests/fstar/hashmap/Hashmap.Properties.fst
@@ -272,7 +272,7 @@ type pos_usize = x:usize{x > 0}
type binding (t : Type0) = key & t
-type slots_t (t : Type0) = vec (list_t t)
+type slots_t (t : Type0) = alloc_vec_Vec (list_t t)
/// We represent hash maps as associative lists
type assoc_list (t : Type0) = list (binding t)
@@ -280,8 +280,8 @@ type assoc_list (t : Type0) = list (binding t)
/// Representation function for [list_t]
let rec list_t_v (#t : Type0) (ls : list_t t) : assoc_list t =
match ls with
- | ListNil -> []
- | ListCons k v tl -> (k,v) :: list_t_v tl
+ | List_Nil -> []
+ | List_Cons k v tl -> (k,v) :: list_t_v tl
let list_t_len (#t : Type0) (ls : list_t t) : nat = length (list_t_v ls)
let list_t_index (#t : Type0) (ls : list_t t) (i : nat{i < list_t_len ls}) : binding t =
@@ -305,30 +305,30 @@ let slots_t_al_v (#t : Type0) (slots : slots_t t) : assoc_list t =
/// list per slot). This is the representation we use most, internally. Note that
/// we later introduce a [map_s] representation, which is the one used in the
/// lemmas shown to the user.
-type hash_map_s t = list (slot_s t)
+type hashMap_s t = list (slot_s t)
// TODO: why not always have the condition on the length?
// 'nes': "non-empty slots"
-type hash_map_s_nes (t : Type0) : Type0 =
- hm:hash_map_s t{is_pos_usize (length hm)}
+type hashMap_s_nes (t : Type0) : Type0 =
+ hm:hashMap_s t{is_pos_usize (length hm)}
-/// Representation function for [hash_map_t] as a list of slots
-let hash_map_t_v (#t : Type0) (hm : hash_map_t t) : hash_map_s t =
- map list_t_v hm.hash_map_slots
+/// Representation function for [hashMap_t] as a list of slots
+let hashMap_t_v (#t : Type0) (hm : hashMap_t t) : hashMap_s t =
+ map list_t_v hm.slots
-/// Representation function for [hash_map_t] as an associative list
-let hash_map_t_al_v (#t : Type0) (hm : hash_map_t t) : assoc_list t =
- flatten (hash_map_t_v hm)
+/// Representation function for [hashMap_t] as an associative list
+let hashMap_t_al_v (#t : Type0) (hm : hashMap_t t) : assoc_list t =
+ flatten (hashMap_t_v hm)
// 'nes': "non-empty slots"
-type hash_map_t_nes (t : Type0) : Type0 =
- hm:hash_map_t t{is_pos_usize (length hm.hash_map_slots)}
+type hashMap_t_nes (t : Type0) : Type0 =
+ hm:hashMap_t t{is_pos_usize (length hm.slots)}
-let hash_key (k : key) : hash =
- Return?.v (hash_key_fwd k)
+let hash_key_s (k : key) : hash =
+ Return?.v (hash_key k)
let hash_mod_key (k : key) (len : usize{len > 0}) : hash =
- (hash_key k) % len
+ (hash_key_s k) % len
let not_same_key (#t : Type0) (k : key) (b : binding t) : bool = fst b <> k
let same_key (#t : Type0) (k : key) (b : binding t) : bool = fst b = k
@@ -339,8 +339,8 @@ let same_hash_mod_key (#t : Type0) (len : usize{len > 0}) (h : nat) (b : binding
let binding_neq (#t : Type0) (b0 b1 : binding t) : bool = fst b0 <> fst b1
-let hash_map_t_len_s (#t : Type0) (hm : hash_map_t t) : nat =
- hm.hash_map_num_entries
+let hashMap_t_len_s (#t : Type0) (hm : hashMap_t t) : nat =
+ hm.num_entries
let assoc_list_find (#t : Type0) (k : key) (slot : assoc_list t) : option t =
match find (same_key k) slot with
@@ -354,26 +354,26 @@ let slot_t_find_s (#t : Type0) (k : key) (slot : list_t t) : option t =
slot_s_find k (slot_t_v slot)
// This is a simpler version of the "find" function, which captures the essence
-// of what happens and operates on [hash_map_s].
-let hash_map_s_find
- (#t : Type0) (hm : hash_map_s_nes t)
+// of what happens and operates on [hashMap_s].
+let hashMap_s_find
+ (#t : Type0) (hm : hashMap_s_nes t)
(k : key) : option t =
let i = hash_mod_key k (length hm) in
let slot = index hm i in
slot_s_find k slot
-let hash_map_s_len
- (#t : Type0) (hm : hash_map_s t) :
+let hashMap_s_len
+ (#t : Type0) (hm : hashMap_s t) :
nat =
length (flatten hm)
-// Same as above, but operates on [hash_map_t]
+// Same as above, but operates on [hashMap_t]
// Note that we don't reuse the above function on purpose: converting to a
-// [hash_map_s] then looking up an element is not the same as what we
+// [hashMap_s] then looking up an element is not the same as what we
// wrote below.
-let hash_map_t_find_s
- (#t : Type0) (hm : hash_map_t t{length hm.hash_map_slots > 0}) (k : key) : option t =
- let slots = hm.hash_map_slots in
+let hashMap_t_find_s
+ (#t : Type0) (hm : hashMap_t t{length hm.slots > 0}) (k : key) : option t =
+ let slots = hm.slots in
let i = hash_mod_key k (length slots) in
let slot = index slots i in
slot_t_find_s k slot
@@ -404,74 +404,74 @@ let slots_t_inv (#t : Type0) (slots : slots_t t{length slots <= usize_max}) : Ty
{:pattern index slots i}
slot_t_inv (length slots) i (index slots i)
-let hash_map_s_inv (#t : Type0) (hm : hash_map_s t) : Type0 =
+let hashMap_s_inv (#t : Type0) (hm : hashMap_s t) : Type0 =
length hm <= usize_max /\
length hm > 0 /\
slots_s_inv hm
/// Base invariant for the hashmap (the complete invariant can be temporarily
/// broken between the moment we inserted an element and the moment we resize)
-let hash_map_t_base_inv (#t : Type0) (hm : hash_map_t t) : Type0 =
- let al = hash_map_t_al_v hm in
+let hashMap_t_base_inv (#t : Type0) (hm : hashMap_t t) : Type0 =
+ let al = hashMap_t_al_v hm in
// [num_entries] correctly tracks the number of entries in the table
// Note that it gives us that the length of the slots array is <= usize_max:
// [> length <= usize_max
- // (because hash_map_num_entries has type `usize`)
- hm.hash_map_num_entries = length al /\
+ // (because hashMap_num_entries has type `usize`)
+ hm.num_entries = length al /\
// Slots invariant
- slots_t_inv hm.hash_map_slots /\
+ slots_t_inv hm.slots /\
// The capacity must be > 0 (otherwise we can't resize, because we
// multiply the capacity by two!)
- length hm.hash_map_slots > 0 /\
+ length hm.slots > 0 /\
// Load computation
begin
- let capacity = length hm.hash_map_slots in
- let (dividend, divisor) = hm.hash_map_max_load_factor in
+ let capacity = length hm.slots in
+ let (dividend, divisor) = hm.max_load_factor in
0 < dividend /\ dividend < divisor /\
capacity * dividend >= divisor /\
- hm.hash_map_max_load = (capacity * dividend) / divisor
+ hm.max_load = (capacity * dividend) / divisor
end
/// We often need to frame some values
-let hash_map_t_same_params (#t : Type0) (hm0 hm1 : hash_map_t t) : Type0 =
- length hm0.hash_map_slots = length hm1.hash_map_slots /\
- hm0.hash_map_max_load = hm1.hash_map_max_load /\
- hm0.hash_map_max_load_factor = hm1.hash_map_max_load_factor
+let hashMap_t_same_params (#t : Type0) (hm0 hm1 : hashMap_t t) : Type0 =
+ length hm0.slots = length hm1.slots /\
+ hm0.max_load = hm1.max_load /\
+ hm0.max_load_factor = hm1.max_load_factor
/// The following invariants, etc. are meant to be revealed to the user through
/// the .fsti.
/// Invariant for the hashmap
-let hash_map_t_inv (#t : Type0) (hm : hash_map_t t) : Type0 =
+let hashMap_t_inv (#t : Type0) (hm : hashMap_t t) : Type0 =
// Base invariant
- hash_map_t_base_inv hm /\
+ hashMap_t_base_inv hm /\
// The hash map is either: not overloaded, or we can't resize it
begin
- let (dividend, divisor) = hm.hash_map_max_load_factor in
- hm.hash_map_num_entries <= hm.hash_map_max_load
- || length hm.hash_map_slots * 2 * dividend > usize_max
+ let (dividend, divisor) = hm.max_load_factor in
+ hm.num_entries <= hm.max_load
+ || length hm.slots * 2 * dividend > usize_max
end
(*** .fsti *)
/// We reveal slightly different version of the above functions to the user
-let len_s (#t : Type0) (hm : hash_map_t t) : nat = hash_map_t_len_s hm
+let len_s (#t : Type0) (hm : hashMap_t t) : nat = hashMap_t_len_s hm
-/// This version doesn't take any precondition (contrary to [hash_map_t_find_s])
-let find_s (#t : Type0) (hm : hash_map_t t) (k : key) : option t =
- if length hm.hash_map_slots = 0 then None
- else hash_map_t_find_s hm k
+/// This version doesn't take any precondition (contrary to [hashMap_t_find_s])
+let find_s (#t : Type0) (hm : hashMap_t t) (k : key) : option t =
+ if length hm.slots = 0 then None
+ else hashMap_t_find_s hm k
(*** Overloading *)
-let hash_map_not_overloaded_lem #t hm = ()
+let hashMap_not_overloaded_lem #t hm = ()
(*** allocate_slots *)
/// Auxiliary lemma
val slots_t_all_nil_inv_lem
- (#t : Type0) (slots : vec (list_t t){length slots <= usize_max}) :
- Lemma (requires (forall (i:nat{i < length slots}). index slots i == ListNil))
+ (#t : Type0) (slots : alloc_vec_Vec (list_t t){length slots <= usize_max}) :
+ Lemma (requires (forall (i:nat{i < length slots}). index slots i == List_Nil))
(ensures (slots_t_inv slots))
#push-options "--fuel 1"
@@ -479,8 +479,8 @@ let slots_t_all_nil_inv_lem #t slots = ()
#pop-options
val slots_t_al_v_all_nil_is_empty_lem
- (#t : Type0) (slots : vec (list_t t)) :
- Lemma (requires (forall (i:nat{i < length slots}). index slots i == ListNil))
+ (#t : Type0) (slots : alloc_vec_Vec (list_t t)) :
+ Lemma (requires (forall (i:nat{i < length slots}). index slots i == List_Nil))
(ensures (slots_t_al_v slots == []))
#push-options "--fuel 1"
@@ -492,44 +492,44 @@ let rec slots_t_al_v_all_nil_is_empty_lem #t slots =
slots_t_al_v_all_nil_is_empty_lem #t slots';
assert(slots_t_al_v slots == list_t_v s @ slots_t_al_v slots');
assert(slots_t_al_v slots == list_t_v s);
- assert(index slots 0 == ListNil)
+ assert(index slots 0 == List_Nil)
#pop-options
/// [allocate_slots]
-val hash_map_allocate_slots_fwd_lem
- (t : Type0) (slots : vec (list_t t)) (n : usize) :
+val hashMap_allocate_slots_lem
+ (t : Type0) (slots : alloc_vec_Vec (list_t t)) (n : usize) :
Lemma
(requires (length slots + n <= usize_max))
(ensures (
- match hash_map_allocate_slots_fwd t slots n with
+ match hashMap_allocate_slots t slots n with
| Fail _ -> False
| Return slots' ->
length slots' = length slots + n /\
// We leave the already allocated slots unchanged
(forall (i:nat{i < length slots}). index slots' i == index slots i) /\
// We allocate n additional empty slots
- (forall (i:nat{length slots <= i /\ i < length slots'}). index slots' i == ListNil)))
- (decreases (hash_map_allocate_slots_loop_decreases t slots n))
+ (forall (i:nat{length slots <= i /\ i < length slots'}). index slots' i == List_Nil)))
+ (decreases (hashMap_allocate_slots_loop_decreases t slots n))
#push-options "--fuel 1"
-let rec hash_map_allocate_slots_fwd_lem t slots n =
+let rec hashMap_allocate_slots_lem t slots n =
begin match n with
| 0 -> ()
| _ ->
- begin match vec_push_back (list_t t) slots ListNil with
+ begin match alloc_vec_Vec_push (list_t t) slots List_Nil with
| Fail _ -> ()
| Return slots1 ->
begin match usize_sub n 1 with
| Fail _ -> ()
| Return i ->
- hash_map_allocate_slots_fwd_lem t slots1 i;
- begin match hash_map_allocate_slots_fwd t slots1 i with
+ hashMap_allocate_slots_lem t slots1 i;
+ begin match hashMap_allocate_slots t slots1 i with
| Fail _ -> ()
| Return slots2 ->
assert(length slots1 = length slots + 1);
- assert(slots1 == slots @ [ListNil]); // Triggers patterns
- assert(index slots1 (length slots) == index [ListNil] 0); // Triggers patterns
- assert(index slots1 (length slots) == ListNil)
+ assert(slots1 == slots @ [List_Nil]); // Triggers patterns
+ assert(index slots1 (length slots) == index [List_Nil] 0); // Triggers patterns
+ assert(index slots1 (length slots) == List_Nil)
end
end
end
@@ -538,7 +538,7 @@ let rec hash_map_allocate_slots_fwd_lem t slots n =
(*** new_with_capacity *)
/// Under proper conditions, [new_with_capacity] doesn't fail and returns an empty hash map.
-val hash_map_new_with_capacity_fwd_lem
+val hashMap_new_with_capacity_lem
(t : Type0) (capacity : usize)
(max_load_dividend : usize) (max_load_divisor : usize) :
Lemma
@@ -549,31 +549,31 @@ val hash_map_new_with_capacity_fwd_lem
capacity * max_load_dividend >= max_load_divisor /\
capacity * max_load_dividend <= usize_max))
(ensures (
- match hash_map_new_with_capacity_fwd t capacity max_load_dividend max_load_divisor with
+ match hashMap_new_with_capacity t capacity max_load_dividend max_load_divisor with
| Fail _ -> False
| Return hm ->
// The hash map invariant is satisfied
- hash_map_t_inv hm /\
+ hashMap_t_inv hm /\
// The parameters are correct
- hm.hash_map_max_load_factor = (max_load_dividend, max_load_divisor) /\
- hm.hash_map_max_load = (capacity * max_load_dividend) / max_load_divisor /\
+ hm.max_load_factor = (max_load_dividend, max_load_divisor) /\
+ hm.max_load = (capacity * max_load_dividend) / max_load_divisor /\
// The hash map has the specified capacity - we need to reveal this
- // otherwise the pre of [hash_map_t_find_s] is not satisfied.
- length hm.hash_map_slots = capacity /\
+ // otherwise the pre of [hashMap_t_find_s] is not satisfied.
+ length hm.slots = capacity /\
// The hash map has 0 values
- hash_map_t_len_s hm = 0 /\
+ hashMap_t_len_s hm = 0 /\
// It contains no bindings
- (forall k. hash_map_t_find_s hm k == None) /\
+ (forall k. hashMap_t_find_s hm k == None) /\
// We need this low-level property for the invariant
- (forall(i:nat{i < length hm.hash_map_slots}). index hm.hash_map_slots i == ListNil)))
+ (forall(i:nat{i < length hm.slots}). index hm.slots i == List_Nil)))
#push-options "--z3rlimit 50 --fuel 1"
-let hash_map_new_with_capacity_fwd_lem (t : Type0) (capacity : usize)
+let hashMap_new_with_capacity_lem (t : Type0) (capacity : usize)
(max_load_dividend : usize) (max_load_divisor : usize) =
- let v = vec_new (list_t t) in
+ let v = alloc_vec_Vec_new (list_t t) in
assert(length v = 0);
- hash_map_allocate_slots_fwd_lem t v capacity;
- begin match hash_map_allocate_slots_fwd t v capacity with
+ hashMap_allocate_slots_lem t v capacity;
+ begin match hashMap_allocate_slots t v capacity with
| Fail _ -> assert(False)
| Return v0 ->
begin match usize_mul capacity max_load_dividend with
@@ -582,9 +582,9 @@ let hash_map_new_with_capacity_fwd_lem (t : Type0) (capacity : usize)
begin match usize_div i max_load_divisor with
| Fail _ -> assert(False)
| Return i0 ->
- let hm = Mkhash_map_t 0 (max_load_dividend, max_load_divisor) i0 v0 in
+ let hm = MkhashMap_t 0 (max_load_dividend, max_load_divisor) i0 v0 in
slots_t_all_nil_inv_lem v0;
- slots_t_al_v_all_nil_is_empty_lem hm.hash_map_slots
+ slots_t_al_v_all_nil_is_empty_lem hm.slots
end
end
end
@@ -593,65 +593,65 @@ let hash_map_new_with_capacity_fwd_lem (t : Type0) (capacity : usize)
(*** new *)
/// [new] doesn't fail and returns an empty hash map
-val hash_map_new_fwd_lem_aux (t : Type0) :
+val hashMap_new_lem_aux (t : Type0) :
Lemma
(ensures (
- match hash_map_new_fwd t with
+ match hashMap_new t with
| Fail _ -> False
| Return hm ->
// The hash map invariant is satisfied
- hash_map_t_inv hm /\
+ hashMap_t_inv hm /\
// The hash map has 0 values
- hash_map_t_len_s hm = 0 /\
+ hashMap_t_len_s hm = 0 /\
// It contains no bindings
- (forall k. hash_map_t_find_s hm k == None)))
+ (forall k. hashMap_t_find_s hm k == None)))
#push-options "--fuel 1"
-let hash_map_new_fwd_lem_aux t =
- hash_map_new_with_capacity_fwd_lem t 32 4 5;
- match hash_map_new_with_capacity_fwd t 32 4 5 with
+let hashMap_new_lem_aux t =
+ hashMap_new_with_capacity_lem t 32 4 5;
+ match hashMap_new_with_capacity t 32 4 5 with
| Fail _ -> ()
| Return hm -> ()
#pop-options
/// The lemma we reveal in the .fsti
-let hash_map_new_fwd_lem t = hash_map_new_fwd_lem_aux t
+let hashMap_new_lem t = hashMap_new_lem_aux t
(*** clear *)
/// [clear]: the loop doesn't fail and simply clears the slots starting at index i
#push-options "--fuel 1"
-let rec hash_map_clear_loop_fwd_back_lem
- (t : Type0) (slots : vec (list_t t)) (i : usize) :
+let rec hashMap_clear_loop_lem
+ (t : Type0) (slots : alloc_vec_Vec (list_t t)) (i : usize) :
Lemma
(ensures (
- match hash_map_clear_loop_fwd_back t slots i with
+ match hashMap_clear_loop t slots i with
| Fail _ -> False
| Return slots' ->
// The length is preserved
length slots' == length slots /\
// The slots before i are left unchanged
(forall (j:nat{j < i /\ j < length slots}). index slots' j == index slots j) /\
- // The slots after i are set to ListNil
- (forall (j:nat{i <= j /\ j < length slots}). index slots' j == ListNil)))
- (decreases (hash_map_clear_loop_decreases t slots i))
+ // The slots after i are set to List_Nil
+ (forall (j:nat{i <= j /\ j < length slots}). index slots' j == List_Nil)))
+ (decreases (hashMap_clear_loop_decreases t slots i))
=
- let i0 = vec_len (list_t t) slots in
+ let i0 = alloc_vec_Vec_len (list_t t) slots in
let b = i < i0 in
if b
then
- begin match vec_index_mut_back (list_t t) slots i ListNil with
+ begin match alloc_vec_Vec_update_usize slots i List_Nil with
| Fail _ -> ()
| Return v ->
begin match usize_add i 1 with
| Fail _ -> ()
| Return i1 ->
- hash_map_clear_loop_fwd_back_lem t v i1;
- begin match hash_map_clear_loop_fwd_back t v i1 with
+ hashMap_clear_loop_lem t v i1;
+ begin match hashMap_clear_loop t v i1 with
| Fail _ -> ()
| Return slots1 ->
assert(length slots1 == length slots);
- assert(forall (j:nat{i+1 <= j /\ j < length slots}). index slots1 j == ListNil);
- assert(index slots1 i == ListNil)
+ assert(forall (j:nat{i+1 <= j /\ j < length slots}). index slots1 j == List_Nil);
+ assert(index slots1 i == List_Nil)
end
end
end
@@ -659,80 +659,80 @@ let rec hash_map_clear_loop_fwd_back_lem
#pop-options
/// [clear] doesn't fail and turns the hash map into an empty map
-val hash_map_clear_fwd_back_lem_aux
- (#t : Type0) (self : hash_map_t t) :
+val hashMap_clear_lem_aux
+ (#t : Type0) (self : hashMap_t t) :
Lemma
- (requires (hash_map_t_base_inv self))
+ (requires (hashMap_t_base_inv self))
(ensures (
- match hash_map_clear_fwd_back t self with
+ match hashMap_clear t self with
| Fail _ -> False
| Return hm ->
// The hash map invariant is satisfied
- hash_map_t_base_inv hm /\
+ hashMap_t_base_inv hm /\
// We preserved the parameters
- hash_map_t_same_params hm self /\
+ hashMap_t_same_params hm self /\
// The hash map has 0 values
- hash_map_t_len_s hm = 0 /\
+ hashMap_t_len_s hm = 0 /\
// It contains no bindings
- (forall k. hash_map_t_find_s hm k == None)))
+ (forall k. hashMap_t_find_s hm k == None)))
// Being lazy: fuel 1 helps a lot...
#push-options "--fuel 1"
-let hash_map_clear_fwd_back_lem_aux #t self =
- let p = self.hash_map_max_load_factor in
- let i = self.hash_map_max_load in
- let v = self.hash_map_slots in
- hash_map_clear_loop_fwd_back_lem t v 0;
- begin match hash_map_clear_loop_fwd_back t v 0 with
+let hashMap_clear_lem_aux #t self =
+ let p = self.max_load_factor in
+ let i = self.max_load in
+ let v = self.slots in
+ hashMap_clear_loop_lem t v 0;
+ begin match hashMap_clear_loop t v 0 with
| Fail _ -> ()
| Return slots1 ->
slots_t_al_v_all_nil_is_empty_lem slots1;
- let hm1 = Mkhash_map_t 0 p i slots1 in
- assert(hash_map_t_base_inv hm1);
- assert(hash_map_t_inv hm1)
+ let hm1 = MkhashMap_t 0 p i slots1 in
+ assert(hashMap_t_base_inv hm1);
+ assert(hashMap_t_inv hm1)
end
#pop-options
-let hash_map_clear_fwd_back_lem #t self = hash_map_clear_fwd_back_lem_aux #t self
+let hashMap_clear_lem #t self = hashMap_clear_lem_aux #t self
(*** len *)
/// [len]: we link it to a non-failing function.
/// Rk.: we might want to make an analysis to not use an error monad to translate
/// functions which statically can't fail.
-let hash_map_len_fwd_lem #t self = ()
+let hashMap_len_lem #t self = ()
(*** insert_in_list *)
(**** insert_in_list'fwd *)
-/// [insert_in_list_fwd]: returns true iff the key is not in the list (functional version)
-val hash_map_insert_in_list_fwd_lem
+/// [insert_in_list]: returns true iff the key is not in the list (functional version)
+val hashMap_insert_in_list_lem
(t : Type0) (key : usize) (value : t) (ls : list_t t) :
Lemma
(ensures (
- match hash_map_insert_in_list_fwd t key value ls with
+ match hashMap_insert_in_list t key value ls with
| Fail _ -> False
| Return b ->
b <==> (slot_t_find_s key ls == None)))
- (decreases (hash_map_insert_in_list_loop_decreases t key value ls))
+ (decreases (hashMap_insert_in_list_loop_decreases t key value ls))
#push-options "--fuel 1"
-let rec hash_map_insert_in_list_fwd_lem t key value ls =
+let rec hashMap_insert_in_list_lem t key value ls =
begin match ls with
- | ListCons ckey cvalue ls0 ->
+ | List_Cons ckey cvalue ls0 ->
let b = ckey = key in
if b
then ()
else
begin
- hash_map_insert_in_list_fwd_lem t key value ls0;
- match hash_map_insert_in_list_fwd t key value ls0 with
+ hashMap_insert_in_list_lem t key value ls0;
+ match hashMap_insert_in_list t key value ls0 with
| Fail _ -> ()
| Return b0 -> ()
end
- | ListNil ->
+ | List_Nil ->
assert(list_t_v ls == []);
assert_norm(find (same_key #t key) [] == None)
end
@@ -748,7 +748,7 @@ let rec hash_map_insert_in_list_fwd_lem t key value ls =
/// We write a helper which "captures" what [insert_in_list] does.
/// We then reason about this helper to prove the high-level properties we want
/// (functional properties, preservation of invariants, etc.).
-let hash_map_insert_in_list_s
+let hashMap_insert_in_list_s
(#t : Type0) (key : usize) (value : t) (ls : list (binding t)) :
list (binding t) =
// Check if there is already a binding for the key
@@ -761,86 +761,86 @@ let hash_map_insert_in_list_s
find_update (same_key key) ls (key,value)
/// [insert_in_list]: if the key is not in the map, appends a new bindings (functional version)
-val hash_map_insert_in_list_back_lem_append_s
+val hashMap_insert_in_list_back_lem_append_s
(t : Type0) (key : usize) (value : t) (ls : list_t t) :
Lemma
(requires (
slot_t_find_s key ls == None))
(ensures (
- match hash_map_insert_in_list_back t key value ls with
+ match hashMap_insert_in_list_back t key value ls with
| Fail _ -> False
| Return ls' ->
list_t_v ls' == list_t_v ls @ [(key,value)]))
- (decreases (hash_map_insert_in_list_loop_decreases t key value ls))
+ (decreases (hashMap_insert_in_list_loop_decreases t key value ls))
#push-options "--fuel 1"
-let rec hash_map_insert_in_list_back_lem_append_s t key value ls =
+let rec hashMap_insert_in_list_back_lem_append_s t key value ls =
begin match ls with
- | ListCons ckey cvalue ls0 ->
+ | List_Cons ckey cvalue ls0 ->
let b = ckey = key in
if b
then ()
else
begin
- hash_map_insert_in_list_back_lem_append_s t key value ls0;
- match hash_map_insert_in_list_back t key value ls0 with
+ hashMap_insert_in_list_back_lem_append_s t key value ls0;
+ match hashMap_insert_in_list_back t key value ls0 with
| Fail _ -> ()
| Return l -> ()
end
- | ListNil -> ()
+ | List_Nil -> ()
end
#pop-options
/// [insert_in_list]: if the key is in the map, we update the binding (functional version)
-val hash_map_insert_in_list_back_lem_update_s
+val hashMap_insert_in_list_back_lem_update_s
(t : Type0) (key : usize) (value : t) (ls : list_t t) :
Lemma
(requires (
Some? (find (same_key key) (list_t_v ls))))
(ensures (
- match hash_map_insert_in_list_back t key value ls with
+ match hashMap_insert_in_list_back t key value ls with
| Fail _ -> False
| Return ls' ->
list_t_v ls' == find_update (same_key key) (list_t_v ls) (key,value)))
- (decreases (hash_map_insert_in_list_loop_decreases t key value ls))
+ (decreases (hashMap_insert_in_list_loop_decreases t key value ls))
#push-options "--fuel 1"
-let rec hash_map_insert_in_list_back_lem_update_s t key value ls =
+let rec hashMap_insert_in_list_back_lem_update_s t key value ls =
begin match ls with
- | ListCons ckey cvalue ls0 ->
+ | List_Cons ckey cvalue ls0 ->
let b = ckey = key in
if b
then ()
else
begin
- hash_map_insert_in_list_back_lem_update_s t key value ls0;
- match hash_map_insert_in_list_back t key value ls0 with
+ hashMap_insert_in_list_back_lem_update_s t key value ls0;
+ match hashMap_insert_in_list_back t key value ls0 with
| Fail _ -> ()
| Return l -> ()
end
- | ListNil -> ()
+ | List_Nil -> ()
end
#pop-options
/// Put everything together
-val hash_map_insert_in_list_back_lem_s
+val hashMap_insert_in_list_back_lem_s
(t : Type0) (key : usize) (value : t) (ls : list_t t) :
Lemma
(ensures (
- match hash_map_insert_in_list_back t key value ls with
+ match hashMap_insert_in_list_back t key value ls with
| Fail _ -> False
| Return ls' ->
- list_t_v ls' == hash_map_insert_in_list_s key value (list_t_v ls)))
+ list_t_v ls' == hashMap_insert_in_list_s key value (list_t_v ls)))
-let hash_map_insert_in_list_back_lem_s t key value ls =
+let hashMap_insert_in_list_back_lem_s t key value ls =
match find (same_key key) (list_t_v ls) with
- | None -> hash_map_insert_in_list_back_lem_append_s t key value ls
- | Some _ -> hash_map_insert_in_list_back_lem_update_s t key value ls
+ | None -> hashMap_insert_in_list_back_lem_append_s t key value ls
+ | Some _ -> hashMap_insert_in_list_back_lem_update_s t key value ls
(**** Invariants of insert_in_list_s *)
/// Auxiliary lemmas
-/// We work on [hash_map_insert_in_list_s], the "high-level" version of [insert_in_list'back].
+/// We work on [hashMap_insert_in_list_s], the "high-level" version of [insert_in_list'back].
///
/// Note that in F* we can't have recursive proofs inside of other proofs, contrary
/// to Coq, which makes it a bit cumbersome to prove auxiliary results like the
@@ -893,14 +893,14 @@ let rec slot_s_inv_not_find_append_end_inv_lem t len key value ls =
#pop-options
/// [insert_in_list]: if the key is not in the map, appends a new bindings
-val hash_map_insert_in_list_s_lem_append
+val hashMap_insert_in_list_s_lem_append
(t : Type0) (len : usize{len > 0}) (key : usize) (value : t) (ls : list (binding t)) :
Lemma
(requires (
slot_s_inv len (hash_mod_key key len) ls /\
slot_s_find key ls == None))
(ensures (
- let ls' = hash_map_insert_in_list_s key value ls in
+ let ls' = hashMap_insert_in_list_s key value ls in
ls' == ls @ [(key,value)] /\
// The invariant is preserved
slot_s_inv len (hash_mod_key key len) ls' /\
@@ -909,20 +909,20 @@ val hash_map_insert_in_list_s_lem_append
// The other bindings are preserved
(forall k'. k' <> key ==> slot_s_find k' ls' == slot_s_find k' ls)))
-let hash_map_insert_in_list_s_lem_append t len key value ls =
+let hashMap_insert_in_list_s_lem_append t len key value ls =
slot_s_inv_not_find_append_end_inv_lem t len key value ls
/// [insert_in_list]: if the key is not in the map, appends a new bindings (quantifiers)
/// Rk.: we don't use this lemma.
/// TODO: remove?
-val hash_map_insert_in_list_back_lem_append
+val hashMap_insert_in_list_back_lem_append
(t : Type0) (len : usize{len > 0}) (key : usize) (value : t) (ls : list_t t) :
Lemma
(requires (
slot_t_inv len (hash_mod_key key len) ls /\
slot_t_find_s key ls == None))
(ensures (
- match hash_map_insert_in_list_back t key value ls with
+ match hashMap_insert_in_list_back t key value ls with
| Fail _ -> False
| Return ls' ->
list_t_v ls' == list_t_v ls @ [(key,value)] /\
@@ -933,9 +933,9 @@ val hash_map_insert_in_list_back_lem_append
// The other bindings are preserved
(forall k'. k' <> key ==> slot_t_find_s k' ls' == slot_t_find_s k' ls)))
-let hash_map_insert_in_list_back_lem_append t len key value ls =
- hash_map_insert_in_list_back_lem_s t key value ls;
- hash_map_insert_in_list_s_lem_append t len key value (list_t_v ls)
+let hashMap_insert_in_list_back_lem_append t len key value ls =
+ hashMap_insert_in_list_back_lem_s t key value ls;
+ hashMap_insert_in_list_s_lem_append t len key value (list_t_v ls)
(** Auxiliary lemmas: update case *)
@@ -1013,14 +1013,14 @@ let rec slot_s_inv_find_append_end_inv_lem t len key value ls =
#pop-options
/// [insert_in_list]: if the key is in the map, update the bindings
-val hash_map_insert_in_list_s_lem_update
+val hashMap_insert_in_list_s_lem_update
(t : Type0) (len : usize{len > 0}) (key : usize) (value : t) (ls : list (binding t)) :
Lemma
(requires (
slot_s_inv len (hash_mod_key key len) ls /\
Some? (slot_s_find key ls)))
(ensures (
- let ls' = hash_map_insert_in_list_s key value ls in
+ let ls' = hashMap_insert_in_list_s key value ls in
ls' == find_update (same_key key) ls (key,value) /\
// The invariant is preserved
slot_s_inv len (hash_mod_key key len) ls' /\
@@ -1029,20 +1029,20 @@ val hash_map_insert_in_list_s_lem_update
// The other bindings are preserved
(forall k'. k' <> key ==> slot_s_find k' ls' == slot_s_find k' ls)))
-let hash_map_insert_in_list_s_lem_update t len key value ls =
+let hashMap_insert_in_list_s_lem_update t len key value ls =
slot_s_inv_find_append_end_inv_lem t len key value ls
/// [insert_in_list]: if the key is in the map, update the bindings
/// TODO: not used: remove?
-val hash_map_insert_in_list_back_lem_update
+val hashMap_insert_in_list_back_lem_update
(t : Type0) (len : usize{len > 0}) (key : usize) (value : t) (ls : list_t t) :
Lemma
(requires (
slot_t_inv len (hash_mod_key key len) ls /\
Some? (slot_t_find_s key ls)))
(ensures (
- match hash_map_insert_in_list_back t key value ls with
+ match hashMap_insert_in_list_back t key value ls with
| Fail _ -> False
| Return ls' ->
let als = list_t_v ls in
@@ -1054,20 +1054,20 @@ val hash_map_insert_in_list_back_lem_update
// The other bindings are preserved
(forall k'. k' <> key ==> slot_t_find_s k' ls' == slot_t_find_s k' ls)))
-let hash_map_insert_in_list_back_lem_update t len key value ls =
- hash_map_insert_in_list_back_lem_s t key value ls;
- hash_map_insert_in_list_s_lem_update t len key value (list_t_v ls)
+let hashMap_insert_in_list_back_lem_update t len key value ls =
+ hashMap_insert_in_list_back_lem_s t key value ls;
+ hashMap_insert_in_list_s_lem_update t len key value (list_t_v ls)
(** Final lemmas about [insert_in_list] *)
/// High-level version
-val hash_map_insert_in_list_s_lem
+val hashMap_insert_in_list_s_lem
(t : Type0) (len : usize{len > 0}) (key : usize) (value : t) (ls : list (binding t)) :
Lemma
(requires (
slot_s_inv len (hash_mod_key key len) ls))
(ensures (
- let ls' = hash_map_insert_in_list_s key value ls in
+ let ls' = hashMap_insert_in_list_s key value ls in
// The invariant is preserved
slot_s_inv len (hash_mod_key key len) ls' /\
// [key] maps to [value]
@@ -1079,22 +1079,22 @@ val hash_map_insert_in_list_s_lem
| None -> length ls' = length ls + 1
| Some _ -> length ls' = length ls)))
-let hash_map_insert_in_list_s_lem t len key value ls =
+let hashMap_insert_in_list_s_lem t len key value ls =
match slot_s_find key ls with
| None ->
assert_norm(length [(key,value)] = 1);
- hash_map_insert_in_list_s_lem_append t len key value ls
+ hashMap_insert_in_list_s_lem_append t len key value ls
| Some _ ->
- hash_map_insert_in_list_s_lem_update t len key value ls
+ hashMap_insert_in_list_s_lem_update t len key value ls
/// [insert_in_list]
/// TODO: not used: remove?
-val hash_map_insert_in_list_back_lem
+val hashMap_insert_in_list_back_lem
(t : Type0) (len : usize{len > 0}) (key : usize) (value : t) (ls : list_t t) :
Lemma
(requires (slot_t_inv len (hash_mod_key key len) ls))
(ensures (
- match hash_map_insert_in_list_back t key value ls with
+ match hashMap_insert_in_list_back t key value ls with
| Fail _ -> False
| Return ls' ->
// The invariant is preserved
@@ -1111,127 +1111,127 @@ val hash_map_insert_in_list_back_lem
| Some _ ->
list_t_v ls' == find_update (same_key key) (list_t_v ls) (key,value) /\
list_t_len ls' = list_t_len ls)))
- (decreases (hash_map_insert_in_list_loop_decreases t key value ls))
+ (decreases (hashMap_insert_in_list_loop_decreases t key value ls))
-let hash_map_insert_in_list_back_lem t len key value ls =
- hash_map_insert_in_list_back_lem_s t key value ls;
- hash_map_insert_in_list_s_lem t len key value (list_t_v ls)
+let hashMap_insert_in_list_back_lem t len key value ls =
+ hashMap_insert_in_list_back_lem_s t key value ls;
+ hashMap_insert_in_list_s_lem t len key value (list_t_v ls)
(*** insert_no_resize *)
(**** Refinement proof *)
/// Same strategy as for [insert_in_list]: we introduce a high-level version of
/// the function, and reason about it.
-/// We work on [hash_map_s] (we use a higher-level view of the hash-map, but
+/// We work on [hashMap_s] (we use a higher-level view of the hash-map, but
/// not too high).
/// A high-level version of insert, which doesn't check if the table is saturated
-let hash_map_insert_no_fail_s
- (#t : Type0) (hm : hash_map_s_nes t)
+let hashMap_insert_no_fail_s
+ (#t : Type0) (hm : hashMap_s_nes t)
(key : usize) (value : t) :
- hash_map_s t =
+ hashMap_s t =
let len = length hm in
let i = hash_mod_key key len in
let slot = index hm i in
- let slot' = hash_map_insert_in_list_s key value slot in
+ let slot' = hashMap_insert_in_list_s key value slot in
let hm' = list_update hm i slot' in
hm'
-// TODO: at some point I used hash_map_s_nes and it broke proofs...x
-let hash_map_insert_no_resize_s
- (#t : Type0) (hm : hash_map_s_nes t)
+// TODO: at some point I used hashMap_s_nes and it broke proofs...x
+let hashMap_insert_no_resize_s
+ (#t : Type0) (hm : hashMap_s_nes t)
(key : usize) (value : t) :
- result (hash_map_s t) =
+ result (hashMap_s t) =
// Check if the table is saturated (too many entries, and we need to insert one)
let num_entries = length (flatten hm) in
- if None? (hash_map_s_find hm key) && num_entries = usize_max then Fail Failure
- else Return (hash_map_insert_no_fail_s hm key value)
+ if None? (hashMap_s_find hm key) && num_entries = usize_max then Fail Failure
+ else Return (hashMap_insert_no_fail_s hm key value)
-/// Prove that [hash_map_insert_no_resize_s] is refined by
-/// [hash_map_insert_no_resize'fwd_back]
-val hash_map_insert_no_resize_fwd_back_lem_s
- (t : Type0) (self : hash_map_t t) (key : usize) (value : t) :
+/// Prove that [hashMap_insert_no_resize_s] is refined by
+/// [hashMap_insert_no_resize'fwd_back]
+val hashMap_insert_no_resize_lem_s
+ (t : Type0) (self : hashMap_t t) (key : usize) (value : t) :
Lemma
(requires (
- hash_map_t_base_inv self /\
- hash_map_s_len (hash_map_t_v self) = hash_map_t_len_s self))
+ hashMap_t_base_inv self /\
+ hashMap_s_len (hashMap_t_v self) = hashMap_t_len_s self))
(ensures (
begin
- match hash_map_insert_no_resize_fwd_back t self key value,
- hash_map_insert_no_resize_s (hash_map_t_v self) key value
+ match hashMap_insert_no_resize t self key value,
+ hashMap_insert_no_resize_s (hashMap_t_v self) key value
with
| Fail _, Fail _ -> True
| Return hm, Return hm_v ->
- hash_map_t_base_inv hm /\
- hash_map_t_same_params hm self /\
- hash_map_t_v hm == hm_v /\
- hash_map_s_len hm_v == hash_map_t_len_s hm
+ hashMap_t_base_inv hm /\
+ hashMap_t_same_params hm self /\
+ hashMap_t_v hm == hm_v /\
+ hashMap_s_len hm_v == hashMap_t_len_s hm
| _ -> False
end))
-let hash_map_insert_no_resize_fwd_back_lem_s t self key value =
- begin match hash_key_fwd key with
+let hashMap_insert_no_resize_lem_s t self key value =
+ begin match hash_key key with
| Fail _ -> ()
| Return i ->
- let i0 = self.hash_map_num_entries in
- let p = self.hash_map_max_load_factor in
- let i1 = self.hash_map_max_load in
- let v = self.hash_map_slots in
- let i2 = vec_len (list_t t) v in
+ let i0 = self.num_entries in
+ let p = self.max_load_factor in
+ let i1 = self.max_load in
+ let v = self.slots in
+ let i2 = alloc_vec_Vec_len (list_t t) v in
let len = length v in
begin match usize_rem i i2 with
| Fail _ -> ()
| Return hash_mod ->
- begin match vec_index_mut_fwd (list_t t) v hash_mod with
+ begin match alloc_vec_Vec_index_usize v hash_mod with
| Fail _ -> ()
| Return l ->
begin
- // Checking that: list_t_v (index ...) == index (hash_map_t_v ...) ...
- assert(list_t_v l == index (hash_map_t_v self) hash_mod);
- hash_map_insert_in_list_fwd_lem t key value l;
- match hash_map_insert_in_list_fwd t key value l with
+ // Checking that: list_t_v (index ...) == index (hashMap_t_v ...) ...
+ assert(list_t_v l == index (hashMap_t_v self) hash_mod);
+ hashMap_insert_in_list_lem t key value l;
+ match hashMap_insert_in_list t key value l with
| Fail _ -> ()
| Return b ->
assert(b = None? (slot_s_find key (list_t_v l)));
- hash_map_insert_in_list_back_lem t len key value l;
+ hashMap_insert_in_list_back_lem t len key value l;
if b
then
begin match usize_add i0 1 with
| Fail _ -> ()
| Return i3 ->
begin
- match hash_map_insert_in_list_back t key value l with
+ match hashMap_insert_in_list_back t key value l with
| Fail _ -> ()
| Return l0 ->
- begin match vec_index_mut_back (list_t t) v hash_mod l0 with
+ begin match alloc_vec_Vec_update_usize v hash_mod l0 with
| Fail _ -> ()
| Return v0 ->
- let self_v = hash_map_t_v self in
- let hm = Mkhash_map_t i3 p i1 v0 in
- let hm_v = hash_map_t_v hm in
+ let self_v = hashMap_t_v self in
+ let hm = MkhashMap_t i3 p i1 v0 in
+ let hm_v = hashMap_t_v hm in
assert(hm_v == list_update self_v hash_mod (list_t_v l0));
assert_norm(length [(key,value)] = 1);
assert(length (list_t_v l0) = length (list_t_v l) + 1);
length_flatten_update self_v hash_mod (list_t_v l0);
- assert(hash_map_s_len hm_v = hash_map_t_len_s hm)
+ assert(hashMap_s_len hm_v = hashMap_t_len_s hm)
end
end
end
else
begin
- match hash_map_insert_in_list_back t key value l with
+ match hashMap_insert_in_list_back t key value l with
| Fail _ -> ()
| Return l0 ->
- begin match vec_index_mut_back (list_t t) v hash_mod l0 with
+ begin match alloc_vec_Vec_update_usize v hash_mod l0 with
| Fail _ -> ()
| Return v0 ->
- let self_v = hash_map_t_v self in
- let hm = Mkhash_map_t i0 p i1 v0 in
- let hm_v = hash_map_t_v hm in
+ let self_v = hashMap_t_v self in
+ let hm = MkhashMap_t i0 p i1 v0 in
+ let hm_v = hashMap_t_v hm in
assert(hm_v == list_update self_v hash_mod (list_t_v l0));
assert(length (list_t_v l0) = length (list_t_v l));
length_flatten_update self_v hash_mod (list_t_v l0);
- assert(hash_map_s_len hm_v = hash_map_t_len_s hm)
+ assert(hashMap_s_len hm_v = hashMap_t_len_s hm)
end
end
end
@@ -1241,108 +1241,108 @@ let hash_map_insert_no_resize_fwd_back_lem_s t self key value =
(**** insert_{no_fail,no_resize}: invariants *)
-let hash_map_s_updated_binding
- (#t : Type0) (hm : hash_map_s_nes t)
- (key : usize) (opt_value : option t) (hm' : hash_map_s_nes t) : Type0 =
+let hashMap_s_updated_binding
+ (#t : Type0) (hm : hashMap_s_nes t)
+ (key : usize) (opt_value : option t) (hm' : hashMap_s_nes t) : Type0 =
// [key] maps to [value]
- hash_map_s_find hm' key == opt_value /\
+ hashMap_s_find hm' key == opt_value /\
// The other bindings are preserved
- (forall k'. k' <> key ==> hash_map_s_find hm' k' == hash_map_s_find hm k')
+ (forall k'. k' <> key ==> hashMap_s_find hm' k' == hashMap_s_find hm k')
-let insert_post (#t : Type0) (hm : hash_map_s_nes t)
- (key : usize) (value : t) (hm' : hash_map_s_nes t) : Type0 =
+let insert_post (#t : Type0) (hm : hashMap_s_nes t)
+ (key : usize) (value : t) (hm' : hashMap_s_nes t) : Type0 =
// The invariant is preserved
- hash_map_s_inv hm' /\
+ hashMap_s_inv hm' /\
// [key] maps to [value] and the other bindings are preserved
- hash_map_s_updated_binding hm key (Some value) hm' /\
+ hashMap_s_updated_binding hm key (Some value) hm' /\
// The length is incremented, iff we inserted a new key
- (match hash_map_s_find hm key with
- | None -> hash_map_s_len hm' = hash_map_s_len hm + 1
- | Some _ -> hash_map_s_len hm' = hash_map_s_len hm)
+ (match hashMap_s_find hm key with
+ | None -> hashMap_s_len hm' = hashMap_s_len hm + 1
+ | Some _ -> hashMap_s_len hm' = hashMap_s_len hm)
-val hash_map_insert_no_fail_s_lem
- (#t : Type0) (hm : hash_map_s_nes t)
+val hashMap_insert_no_fail_s_lem
+ (#t : Type0) (hm : hashMap_s_nes t)
(key : usize) (value : t) :
Lemma
- (requires (hash_map_s_inv hm))
+ (requires (hashMap_s_inv hm))
(ensures (
- let hm' = hash_map_insert_no_fail_s hm key value in
+ let hm' = hashMap_insert_no_fail_s hm key value in
insert_post hm key value hm'))
-let hash_map_insert_no_fail_s_lem #t hm key value =
+let hashMap_insert_no_fail_s_lem #t hm key value =
let len = length hm in
let i = hash_mod_key key len in
let slot = index hm i in
- hash_map_insert_in_list_s_lem t len key value slot;
- let slot' = hash_map_insert_in_list_s key value slot in
+ hashMap_insert_in_list_s_lem t len key value slot;
+ let slot' = hashMap_insert_in_list_s key value slot in
length_flatten_update hm i slot'
-val hash_map_insert_no_resize_s_lem
- (#t : Type0) (hm : hash_map_s_nes t)
+val hashMap_insert_no_resize_s_lem
+ (#t : Type0) (hm : hashMap_s_nes t)
(key : usize) (value : t) :
Lemma
- (requires (hash_map_s_inv hm))
+ (requires (hashMap_s_inv hm))
(ensures (
- match hash_map_insert_no_resize_s hm key value with
+ match hashMap_insert_no_resize_s hm key value with
| Fail _ ->
// Can fail only if we need to create a new binding in
// an already saturated map
- hash_map_s_len hm = usize_max /\
- None? (hash_map_s_find hm key)
+ hashMap_s_len hm = usize_max /\
+ None? (hashMap_s_find hm key)
| Return hm' ->
insert_post hm key value hm'))
-let hash_map_insert_no_resize_s_lem #t hm key value =
+let hashMap_insert_no_resize_s_lem #t hm key value =
let num_entries = length (flatten hm) in
- if None? (hash_map_s_find hm key) && num_entries = usize_max then ()
- else hash_map_insert_no_fail_s_lem hm key value
+ if None? (hashMap_s_find hm key) && num_entries = usize_max then ()
+ else hashMap_insert_no_fail_s_lem hm key value
(**** find after insert *)
/// Lemmas about what happens if we call [find] after an insertion
-val hash_map_insert_no_resize_s_get_same_lem
- (#t : Type0) (hm : hash_map_s t)
+val hashMap_insert_no_resize_s_get_same_lem
+ (#t : Type0) (hm : hashMap_s t)
(key : usize) (value : t) :
- Lemma (requires (hash_map_s_inv hm))
+ Lemma (requires (hashMap_s_inv hm))
(ensures (
- match hash_map_insert_no_resize_s hm key value with
+ match hashMap_insert_no_resize_s hm key value with
| Fail _ -> True
| Return hm' ->
- hash_map_s_find hm' key == Some value))
+ hashMap_s_find hm' key == Some value))
-let hash_map_insert_no_resize_s_get_same_lem #t hm key value =
+let hashMap_insert_no_resize_s_get_same_lem #t hm key value =
let num_entries = length (flatten hm) in
- if None? (hash_map_s_find hm key) && num_entries = usize_max then ()
+ if None? (hashMap_s_find hm key) && num_entries = usize_max then ()
else
begin
- let hm' = Return?.v (hash_map_insert_no_resize_s hm key value) in
+ let hm' = Return?.v (hashMap_insert_no_resize_s hm key value) in
let len = length hm in
let i = hash_mod_key key len in
let slot = index hm i in
- hash_map_insert_in_list_s_lem t len key value slot
+ hashMap_insert_in_list_s_lem t len key value slot
end
-val hash_map_insert_no_resize_s_get_diff_lem
- (#t : Type0) (hm : hash_map_s t)
+val hashMap_insert_no_resize_s_get_diff_lem
+ (#t : Type0) (hm : hashMap_s t)
(key : usize) (value : t) (key' : usize{key' <> key}) :
- Lemma (requires (hash_map_s_inv hm))
+ Lemma (requires (hashMap_s_inv hm))
(ensures (
- match hash_map_insert_no_resize_s hm key value with
+ match hashMap_insert_no_resize_s hm key value with
| Fail _ -> True
| Return hm' ->
- hash_map_s_find hm' key' == hash_map_s_find hm key'))
+ hashMap_s_find hm' key' == hashMap_s_find hm key'))
-let hash_map_insert_no_resize_s_get_diff_lem #t hm key value key' =
+let hashMap_insert_no_resize_s_get_diff_lem #t hm key value key' =
let num_entries = length (flatten hm) in
- if None? (hash_map_s_find hm key) && num_entries = usize_max then ()
+ if None? (hashMap_s_find hm key) && num_entries = usize_max then ()
else
begin
- let hm' = Return?.v (hash_map_insert_no_resize_s hm key value) in
+ let hm' = Return?.v (hashMap_insert_no_resize_s hm key value) in
let len = length hm in
let i = hash_mod_key key len in
let slot = index hm i in
- hash_map_insert_in_list_s_lem t len key value slot;
+ hashMap_insert_in_list_s_lem t len key value slot;
let i' = hash_mod_key key' len in
if i <> i' then ()
else
@@ -1354,116 +1354,116 @@ let hash_map_insert_no_resize_s_get_diff_lem #t hm key value key' =
(*** move_elements_from_list *)
-/// Having a great time here: if we use `result (hash_map_s_res t)` as the
-/// return type for [hash_map_move_elements_from_list_s] instead of having this
-/// awkward match, the proof of [hash_map_move_elements_fwd_back_lem_refin] fails.
+/// Having a great time here: if we use `result (hashMap_s_res t)` as the
+/// return type for [hashMap_move_elements_from_list_s] instead of having this
+/// awkward match, the proof of [hashMap_move_elements_lem_refin] fails.
/// I guess it comes from F*'s poor subtyping.
-/// Followingly, I'm not taking any chance and using [result_hash_map_s]
+/// Followingly, I'm not taking any chance and using [result_hashMap_s]
/// everywhere.
-type result_hash_map_s_nes (t : Type0) : Type0 =
- res:result (hash_map_s t) {
+type result_hashMap_s_nes (t : Type0) : Type0 =
+ res:result (hashMap_s t) {
match res with
| Fail _ -> True
| Return hm -> is_pos_usize (length hm)
}
-let rec hash_map_move_elements_from_list_s
- (#t : Type0) (hm : hash_map_s_nes t)
+let rec hashMap_move_elements_from_list_s
+ (#t : Type0) (hm : hashMap_s_nes t)
(ls : slot_s t) :
- // Do *NOT* use `result (hash_map_s t)`
- Tot (result_hash_map_s_nes t)
+ // Do *NOT* use `result (hashMap_s t)`
+ Tot (result_hashMap_s_nes t)
(decreases ls) =
match ls with
| [] -> Return hm
| (key, value) :: ls' ->
- match hash_map_insert_no_resize_s hm key value with
+ match hashMap_insert_no_resize_s hm key value with
| Fail e -> Fail e
| Return hm' ->
- hash_map_move_elements_from_list_s hm' ls'
+ hashMap_move_elements_from_list_s hm' ls'
/// Refinement lemma
-val hash_map_move_elements_from_list_fwd_back_lem
- (t : Type0) (ntable : hash_map_t_nes t) (ls : list_t t) :
- Lemma (requires (hash_map_t_base_inv ntable))
+val hashMap_move_elements_from_list_lem
+ (t : Type0) (ntable : hashMap_t_nes t) (ls : list_t t) :
+ Lemma (requires (hashMap_t_base_inv ntable))
(ensures (
- match hash_map_move_elements_from_list_fwd_back t ntable ls,
- hash_map_move_elements_from_list_s (hash_map_t_v ntable) (slot_t_v ls)
+ match hashMap_move_elements_from_list t ntable ls,
+ hashMap_move_elements_from_list_s (hashMap_t_v ntable) (slot_t_v ls)
with
| Fail _, Fail _ -> True
| Return hm', Return hm_v ->
- hash_map_t_base_inv hm' /\
- hash_map_t_v hm' == hm_v /\
- hash_map_t_same_params hm' ntable
+ hashMap_t_base_inv hm' /\
+ hashMap_t_v hm' == hm_v /\
+ hashMap_t_same_params hm' ntable
| _ -> False))
- (decreases (hash_map_move_elements_from_list_loop_decreases t ntable ls))
+ (decreases (hashMap_move_elements_from_list_loop_decreases t ntable ls))
#push-options "--fuel 1"
-let rec hash_map_move_elements_from_list_fwd_back_lem t ntable ls =
+let rec hashMap_move_elements_from_list_lem t ntable ls =
begin match ls with
- | ListCons k v tl ->
+ | List_Cons k v tl ->
assert(list_t_v ls == (k, v) :: list_t_v tl);
let ls_v = list_t_v ls in
let (_,_) :: tl_v = ls_v in
- hash_map_insert_no_resize_fwd_back_lem_s t ntable k v;
- begin match hash_map_insert_no_resize_fwd_back t ntable k v with
+ hashMap_insert_no_resize_lem_s t ntable k v;
+ begin match hashMap_insert_no_resize t ntable k v with
| Fail _ -> ()
| Return h ->
- let h_v = Return?.v (hash_map_insert_no_resize_s (hash_map_t_v ntable) k v) in
- assert(hash_map_t_v h == h_v);
- hash_map_move_elements_from_list_fwd_back_lem t h tl;
- begin match hash_map_move_elements_from_list_fwd_back t h tl with
+ let h_v = Return?.v (hashMap_insert_no_resize_s (hashMap_t_v ntable) k v) in
+ assert(hashMap_t_v h == h_v);
+ hashMap_move_elements_from_list_lem t h tl;
+ begin match hashMap_move_elements_from_list t h tl with
| Fail _ -> ()
| Return h0 -> ()
end
end
- | ListNil -> ()
+ | List_Nil -> ()
end
#pop-options
(*** move_elements *)
(**** move_elements: refinement 0 *)
-/// The proof for [hash_map_move_elements_fwd_back_lem_refin] broke so many times
+/// The proof for [hashMap_move_elements_lem_refin] broke so many times
/// (while it is supposed to be super simple!) that we decided to add one refinement
/// level, to really do things step by step...
/// Doing this refinement layer made me notice that maybe the problem came from
-/// the fact that at some point we have to prove `list_t_v ListNil == []`: I
+/// the fact that at some point we have to prove `list_t_v List_Nil == []`: I
/// added the corresponding assert to help Z3 and everything became stable.
/// I finally didn't use this "simple" refinement lemma, but I still keep it here
-/// because it allows for easy comparisons with [hash_map_move_elements_s].
+/// because it allows for easy comparisons with [hashMap_move_elements_s].
-/// [hash_map_move_elements_fwd] refines this function, which is actually almost
+/// [hashMap_move_elements] refines this function, which is actually almost
/// the same (just a little bit shorter and cleaner, and has a pre).
///
/// The way I wrote the high-level model is the following:
-/// - I copy-pasted the definition of [hash_map_move_elements_fwd], wrote the
-/// signature which links this new definition to [hash_map_move_elements_fwd] and
+/// - I copy-pasted the definition of [hashMap_move_elements], wrote the
+/// signature which links this new definition to [hashMap_move_elements] and
/// checked that the proof passed
/// - I gradually simplified it, while making sure the proof still passes
#push-options "--fuel 1"
-let rec hash_map_move_elements_s_simpl
- (t : Type0) (ntable : hash_map_t t)
- (slots : vec (list_t t))
+let rec hashMap_move_elements_s_simpl
+ (t : Type0) (ntable : hashMap_t t)
+ (slots : alloc_vec_Vec (list_t t))
(i : usize{i <= length slots /\ length slots <= usize_max}) :
- Pure (result ((hash_map_t t) & (vec (list_t t))))
+ Pure (result ((hashMap_t t) & (alloc_vec_Vec (list_t t))))
(requires (True))
(ensures (fun res ->
- match res, hash_map_move_elements_fwd_back t ntable slots i with
+ match res, hashMap_move_elements t ntable slots i with
| Fail _, Fail _ -> True
| Return (ntable1, slots1), Return (ntable2, slots2) ->
ntable1 == ntable2 /\
slots1 == slots2
| _ -> False))
- (decreases (hash_map_move_elements_loop_decreases t ntable slots i))
+ (decreases (hashMap_move_elements_loop_decreases t ntable slots i))
=
if i < length slots
then
let slot = index slots i in
- begin match hash_map_move_elements_from_list_fwd_back t ntable slot with
+ begin match hashMap_move_elements_from_list t ntable slot with
| Fail e -> Fail e
| Return hm' ->
- let slots' = list_update slots i ListNil in
- hash_map_move_elements_s_simpl t hm' slots' (i+1)
+ let slots' = list_update slots i List_Nil in
+ hashMap_move_elements_s_simpl t hm' slots' (i+1)
end
else Return (ntable, slots)
#pop-options
@@ -1476,71 +1476,71 @@ let rec hash_map_move_elements_s_simpl
// Note that we ignore the returned slots (we thus don't return a pair:
// only the new hash map in which we moved the elements from the slots):
// this returned value is not used.
-let rec hash_map_move_elements_s
- (#t : Type0) (hm : hash_map_s_nes t)
+let rec hashMap_move_elements_s
+ (#t : Type0) (hm : hashMap_s_nes t)
(slots : slots_s t) (i : usize{i <= length slots /\ length slots <= usize_max}) :
- Tot (result_hash_map_s_nes t)
+ Tot (result_hashMap_s_nes t)
(decreases (length slots - i)) =
let len = length slots in
if i < len then
begin
let slot = index slots i in
- match hash_map_move_elements_from_list_s hm slot with
+ match hashMap_move_elements_from_list_s hm slot with
| Fail e -> Fail e
| Return hm' ->
let slots' = list_update slots i [] in
- hash_map_move_elements_s hm' slots' (i+1)
+ hashMap_move_elements_s hm' slots' (i+1)
end
else Return hm
-val hash_map_move_elements_fwd_back_lem_refin
- (t : Type0) (ntable : hash_map_t t)
- (slots : vec (list_t t)) (i : usize{i <= length slots}) :
+val hashMap_move_elements_lem_refin
+ (t : Type0) (ntable : hashMap_t t)
+ (slots : alloc_vec_Vec (list_t t)) (i : usize{i <= length slots}) :
Lemma
(requires (
- hash_map_t_base_inv ntable))
+ hashMap_t_base_inv ntable))
(ensures (
- match hash_map_move_elements_fwd_back t ntable slots i,
- hash_map_move_elements_s (hash_map_t_v ntable) (slots_t_v slots) i
+ match hashMap_move_elements t ntable slots i,
+ hashMap_move_elements_s (hashMap_t_v ntable) (slots_t_v slots) i
with
| Fail _, Fail _ -> True // We will prove later that this is not possible
| Return (ntable', _), Return ntable'_v ->
- hash_map_t_base_inv ntable' /\
- hash_map_t_v ntable' == ntable'_v /\
- hash_map_t_same_params ntable' ntable
+ hashMap_t_base_inv ntable' /\
+ hashMap_t_v ntable' == ntable'_v /\
+ hashMap_t_same_params ntable' ntable
| _ -> False))
(decreases (length slots - i))
#restart-solver
#push-options "--fuel 1"
-let rec hash_map_move_elements_fwd_back_lem_refin t ntable slots i =
- assert(hash_map_t_base_inv ntable);
- let i0 = vec_len (list_t t) slots in
+let rec hashMap_move_elements_lem_refin t ntable slots i =
+ assert(hashMap_t_base_inv ntable);
+ let i0 = alloc_vec_Vec_len (list_t t) slots in
let b = i < i0 in
if b
then
- begin match vec_index_mut_fwd (list_t t) slots i with
+ begin match alloc_vec_Vec_index_usize slots i with
| Fail _ -> ()
| Return l ->
- let l0 = mem_replace_fwd (list_t t) l ListNil in
+ let l0 = core_mem_replace (list_t t) l List_Nil in
assert(l0 == l);
- hash_map_move_elements_from_list_fwd_back_lem t ntable l0;
- begin match hash_map_move_elements_from_list_fwd_back t ntable l0 with
+ hashMap_move_elements_from_list_lem t ntable l0;
+ begin match hashMap_move_elements_from_list t ntable l0 with
| Fail _ -> ()
| Return h ->
- let l1 = mem_replace_back (list_t t) l ListNil in
- assert(l1 == ListNil);
- assert(slot_t_v #t ListNil == []); // THIS IS IMPORTANT
- begin match vec_index_mut_back (list_t t) slots i l1 with
+ let l1 = core_mem_replace_back (list_t t) l List_Nil in
+ assert(l1 == List_Nil);
+ assert(slot_t_v #t List_Nil == []); // THIS IS IMPORTANT
+ begin match alloc_vec_Vec_update_usize slots i l1 with
| Fail _ -> ()
| Return v ->
begin match usize_add i 1 with
| Fail _ -> ()
| Return i1 ->
- hash_map_move_elements_fwd_back_lem_refin t h v i1;
- begin match hash_map_move_elements_fwd_back t h v i1 with
+ hashMap_move_elements_lem_refin t h v i1;
+ begin match hashMap_move_elements t h v i1 with
| Fail _ ->
- assert(Fail? (hash_map_move_elements_fwd_back t ntable slots i));
+ assert(Fail? (hashMap_move_elements t ntable slots i));
()
| Return (ntable', v0) -> ()
end
@@ -1560,19 +1560,19 @@ let rec hash_map_move_elements_fwd_back_lem_refin t ntable slots i =
/// [ntable] is the hash map to which we move the elements
/// [slots] is the current hash map, from which we remove the elements, and seen
/// as a "flat" associative list (and not a list of lists)
-/// This is actually exactly [hash_map_move_elements_from_list_s]...
-let rec hash_map_move_elements_s_flat
- (#t : Type0) (ntable : hash_map_s_nes t)
+/// This is actually exactly [hashMap_move_elements_from_list_s]...
+let rec hashMap_move_elements_s_flat
+ (#t : Type0) (ntable : hashMap_s_nes t)
(slots : assoc_list t) :
- Tot (result_hash_map_s_nes t)
+ Tot (result_hashMap_s_nes t)
(decreases slots) =
match slots with
| [] -> Return ntable
| (k,v) :: slots' ->
- match hash_map_insert_no_resize_s ntable k v with
+ match hashMap_insert_no_resize_s ntable k v with
| Fail e -> Fail e
| Return ntable' ->
- hash_map_move_elements_s_flat ntable' slots'
+ hashMap_move_elements_s_flat ntable' slots'
/// The refinment lemmas
/// First, auxiliary helpers.
@@ -1656,42 +1656,42 @@ let rec flatten_nil_prefix_as_flatten_i #a l i =
/// The proof is trivial, the functions are the same.
/// Just keeping two definitions to allow changes...
-val hash_map_move_elements_from_list_s_as_flat_lem
- (#t : Type0) (hm : hash_map_s_nes t)
+val hashMap_move_elements_from_list_s_as_flat_lem
+ (#t : Type0) (hm : hashMap_s_nes t)
(ls : slot_s t) :
Lemma
(ensures (
- hash_map_move_elements_from_list_s hm ls ==
- hash_map_move_elements_s_flat hm ls))
+ hashMap_move_elements_from_list_s hm ls ==
+ hashMap_move_elements_s_flat hm ls))
(decreases ls)
#push-options "--fuel 1"
-let rec hash_map_move_elements_from_list_s_as_flat_lem #t hm ls =
+let rec hashMap_move_elements_from_list_s_as_flat_lem #t hm ls =
match ls with
| [] -> ()
| (key, value) :: ls' ->
- match hash_map_insert_no_resize_s hm key value with
+ match hashMap_insert_no_resize_s hm key value with
| Fail _ -> ()
| Return hm' ->
- hash_map_move_elements_from_list_s_as_flat_lem hm' ls'
+ hashMap_move_elements_from_list_s_as_flat_lem hm' ls'
#pop-options
-/// Composition of two calls to [hash_map_move_elements_s_flat]
-let hash_map_move_elements_s_flat_comp
- (#t : Type0) (hm : hash_map_s_nes t) (slot0 slot1 : slot_s t) :
- Tot (result_hash_map_s_nes t) =
- match hash_map_move_elements_s_flat hm slot0 with
+/// Composition of two calls to [hashMap_move_elements_s_flat]
+let hashMap_move_elements_s_flat_comp
+ (#t : Type0) (hm : hashMap_s_nes t) (slot0 slot1 : slot_s t) :
+ Tot (result_hashMap_s_nes t) =
+ match hashMap_move_elements_s_flat hm slot0 with
| Fail e -> Fail e
- | Return hm1 -> hash_map_move_elements_s_flat hm1 slot1
+ | Return hm1 -> hashMap_move_elements_s_flat hm1 slot1
/// High-level desc:
/// move_elements (move_elements hm slot0) slo1 == move_elements hm (slot0 @ slot1)
-val hash_map_move_elements_s_flat_append_lem
- (#t : Type0) (hm : hash_map_s_nes t) (slot0 slot1 : slot_s t) :
+val hashMap_move_elements_s_flat_append_lem
+ (#t : Type0) (hm : hashMap_s_nes t) (slot0 slot1 : slot_s t) :
Lemma
(ensures (
- match hash_map_move_elements_s_flat_comp hm slot0 slot1,
- hash_map_move_elements_s_flat hm (slot0 @ slot1)
+ match hashMap_move_elements_s_flat_comp hm slot0 slot1,
+ hashMap_move_elements_s_flat hm (slot0 @ slot1)
with
| Fail _, Fail _ -> True
| Return hm1, Return hm2 -> hm1 == hm2
@@ -1699,14 +1699,14 @@ val hash_map_move_elements_s_flat_append_lem
(decreases (slot0))
#push-options "--fuel 1"
-let rec hash_map_move_elements_s_flat_append_lem #t hm slot0 slot1 =
+let rec hashMap_move_elements_s_flat_append_lem #t hm slot0 slot1 =
match slot0 with
| [] -> ()
| (k,v) :: slot0' ->
- match hash_map_insert_no_resize_s hm k v with
+ match hashMap_insert_no_resize_s hm k v with
| Fail _ -> ()
| Return hm' ->
- hash_map_move_elements_s_flat_append_lem hm' slot0' slot1
+ hashMap_move_elements_s_flat_append_lem hm' slot0' slot1
#pop-options
val flatten_i_same_suffix (#a : Type) (l0 l1 : list (list a)) (i : nat) :
@@ -1726,16 +1726,16 @@ let rec flatten_i_same_suffix #a l0 l1 i =
#pop-options
/// Refinement lemma:
-/// [hash_map_move_elements_s] refines [hash_map_move_elements_s_flat]
+/// [hashMap_move_elements_s] refines [hashMap_move_elements_s_flat]
/// (actually the functions are equal on all inputs).
-val hash_map_move_elements_s_lem_refin_flat
- (#t : Type0) (hm : hash_map_s_nes t)
+val hashMap_move_elements_s_lem_refin_flat
+ (#t : Type0) (hm : hashMap_s_nes t)
(slots : slots_s t)
(i : nat{i <= length slots /\ length slots <= usize_max}) :
Lemma
(ensures (
- match hash_map_move_elements_s hm slots i,
- hash_map_move_elements_s_flat hm (flatten_i slots i)
+ match hashMap_move_elements_s hm slots i,
+ hashMap_move_elements_s_flat hm (flatten_i slots i)
with
| Fail _, Fail _ -> True
| Return hm, Return hm' -> hm == hm'
@@ -1743,22 +1743,22 @@ val hash_map_move_elements_s_lem_refin_flat
(decreases (length slots - i))
#push-options "--fuel 1"
-let rec hash_map_move_elements_s_lem_refin_flat #t hm slots i =
+let rec hashMap_move_elements_s_lem_refin_flat #t hm slots i =
let len = length slots in
if i < len then
begin
let slot = index slots i in
- hash_map_move_elements_from_list_s_as_flat_lem hm slot;
- match hash_map_move_elements_from_list_s hm slot with
+ hashMap_move_elements_from_list_s_as_flat_lem hm slot;
+ match hashMap_move_elements_from_list_s hm slot with
| Fail _ ->
assert(flatten_i slots i == slot @ flatten_i slots (i+1));
- hash_map_move_elements_s_flat_append_lem hm slot (flatten_i slots (i+1));
- assert(Fail? (hash_map_move_elements_s_flat hm (flatten_i slots i)))
+ hashMap_move_elements_s_flat_append_lem hm slot (flatten_i slots (i+1));
+ assert(Fail? (hashMap_move_elements_s_flat hm (flatten_i slots i)))
| Return hm' ->
let slots' = list_update slots i [] in
flatten_i_same_suffix slots slots' (i+1);
- hash_map_move_elements_s_lem_refin_flat hm' slots' (i+1);
- hash_map_move_elements_s_flat_append_lem hm slot (flatten_i slots' (i+1));
+ hashMap_move_elements_s_lem_refin_flat hm' slots' (i+1);
+ hashMap_move_elements_s_flat_append_lem hm slot (flatten_i slots' (i+1));
()
end
else ()
@@ -1769,21 +1769,21 @@ let assoc_list_inv (#t : Type0) (al : assoc_list t) : Type0 =
pairwise_rel binding_neq al
let disjoint_hm_al_on_key
- (#t : Type0) (hm : hash_map_s_nes t) (al : assoc_list t) (k : key) : Type0 =
- match hash_map_s_find hm k, assoc_list_find k al with
+ (#t : Type0) (hm : hashMap_s_nes t) (al : assoc_list t) (k : key) : Type0 =
+ match hashMap_s_find hm k, assoc_list_find k al with
| Some _, None
| None, Some _
| None, None -> True
| Some _, Some _ -> False
/// Playing a dangerous game here: using forall quantifiers
-let disjoint_hm_al (#t : Type0) (hm : hash_map_s_nes t) (al : assoc_list t) : Type0 =
+let disjoint_hm_al (#t : Type0) (hm : hashMap_s_nes t) (al : assoc_list t) : Type0 =
forall (k:key). disjoint_hm_al_on_key hm al k
let find_in_union_hm_al
- (#t : Type0) (hm : hash_map_s_nes t) (al : assoc_list t) (k : key) :
+ (#t : Type0) (hm : hashMap_s_nes t) (al : assoc_list t) (k : key) :
option t =
- match hash_map_s_find hm k with
+ match hashMap_s_find hm k with
| Some b -> Some b
| None -> assoc_list_find k al
@@ -1799,58 +1799,58 @@ let rec for_all_binding_neq_find_lem #t k v al =
| b :: al' -> for_all_binding_neq_find_lem k v al'
#pop-options
-val hash_map_move_elements_s_flat_lem
- (#t : Type0) (hm : hash_map_s_nes t) (al : assoc_list t) :
+val hashMap_move_elements_s_flat_lem
+ (#t : Type0) (hm : hashMap_s_nes t) (al : assoc_list t) :
Lemma
(requires (
// Invariants
- hash_map_s_inv hm /\
+ hashMap_s_inv hm /\
assoc_list_inv al /\
// The two are disjoint
disjoint_hm_al hm al /\
// We can add all the elements to the hashmap
- hash_map_s_len hm + length al <= usize_max))
+ hashMap_s_len hm + length al <= usize_max))
(ensures (
- match hash_map_move_elements_s_flat hm al with
+ match hashMap_move_elements_s_flat hm al with
| Fail _ -> False // We can't fail
| Return hm' ->
// The invariant is preserved
- hash_map_s_inv hm' /\
+ hashMap_s_inv hm' /\
// The new hash map is the union of the two maps
- (forall (k:key). hash_map_s_find hm' k == find_in_union_hm_al hm al k) /\
- hash_map_s_len hm' = hash_map_s_len hm + length al))
+ (forall (k:key). hashMap_s_find hm' k == find_in_union_hm_al hm al k) /\
+ hashMap_s_len hm' = hashMap_s_len hm + length al))
(decreases al)
#restart-solver
#push-options "--z3rlimit 200 --fuel 1"
-let rec hash_map_move_elements_s_flat_lem #t hm al =
+let rec hashMap_move_elements_s_flat_lem #t hm al =
match al with
| [] -> ()
| (k,v) :: al' ->
- hash_map_insert_no_resize_s_lem hm k v;
- match hash_map_insert_no_resize_s hm k v with
+ hashMap_insert_no_resize_s_lem hm k v;
+ match hashMap_insert_no_resize_s hm k v with
| Fail _ -> ()
| Return hm' ->
- assert(hash_map_s_inv hm');
+ assert(hashMap_s_inv hm');
assert(assoc_list_inv al');
let disjoint_lem (k' : key) :
Lemma (disjoint_hm_al_on_key hm' al' k')
[SMTPat (disjoint_hm_al_on_key hm' al' k')] =
if k' = k then
begin
- assert(hash_map_s_find hm' k' == Some v);
+ assert(hashMap_s_find hm' k' == Some v);
for_all_binding_neq_find_lem k v al';
assert(assoc_list_find k' al' == None)
end
else
begin
- assert(hash_map_s_find hm' k' == hash_map_s_find hm k');
+ assert(hashMap_s_find hm' k' == hashMap_s_find hm k');
assert(assoc_list_find k' al' == assoc_list_find k' al)
end
in
assert(disjoint_hm_al hm' al');
- assert(hash_map_s_len hm' + length al' <= usize_max);
- hash_map_move_elements_s_flat_lem hm' al'
+ assert(hashMap_s_len hm' + length al' <= usize_max);
+ hashMap_move_elements_s_flat_lem hm' al'
#pop-options
/// We need to prove that the invariants on the "low-level" representations of
@@ -1866,18 +1866,18 @@ let slots_t_inv_implies_slots_s_inv #t slots =
// Problem is: I can never really predict for sure with F*...
()
-val hash_map_t_base_inv_implies_hash_map_s_inv
- (#t : Type0) (hm : hash_map_t t) :
- Lemma (requires (hash_map_t_base_inv hm))
- (ensures (hash_map_s_inv (hash_map_t_v hm)))
+val hashMap_t_base_inv_implies_hashMap_s_inv
+ (#t : Type0) (hm : hashMap_t t) :
+ Lemma (requires (hashMap_t_base_inv hm))
+ (ensures (hashMap_s_inv (hashMap_t_v hm)))
-let hash_map_t_base_inv_implies_hash_map_s_inv #t hm = () // same as previous
+let hashMap_t_base_inv_implies_hashMap_s_inv #t hm = () // same as previous
/// Introducing a "partial" version of the hash map invariant, which operates on
/// a suffix of the hash map.
-let partial_hash_map_s_inv
+let partial_hashMap_s_inv
(#t : Type0) (len : usize{len > 0}) (offset : usize)
- (hm : hash_map_s t{offset + length hm <= usize_max}) : Type0 =
+ (hm : hashMap_s t{offset + length hm <= usize_max}) : Type0 =
forall(i:nat{i < length hm}). {:pattern index hm i} slot_s_inv len (offset + i) (index hm i)
/// Auxiliary lemma.
@@ -1887,13 +1887,13 @@ val binding_in_previous_slot_implies_neq
(#t : Type0) (len : usize{len > 0})
(i : usize) (b : binding t)
(offset : usize{i < offset})
- (slots : hash_map_s t{offset + length slots <= usize_max}) :
+ (slots : hashMap_s t{offset + length slots <= usize_max}) :
Lemma
(requires (
// The binding comes from a slot not in [slots]
hash_mod_key (fst b) len = i /\
// The slots are the well-formed suffix of a hash map
- partial_hash_map_s_inv len offset slots))
+ partial_hashMap_s_inv len offset slots))
(ensures (
for_all (binding_neq b) (flatten slots)))
(decreases slots)
@@ -1924,17 +1924,17 @@ let rec binding_in_previous_slot_implies_neq #t len i b offset slots =
for_all_append (binding_neq b) s (flatten slots')
#pop-options
-val partial_hash_map_s_inv_implies_assoc_list_lem
+val partial_hashMap_s_inv_implies_assoc_list_lem
(#t : Type0) (len : usize{len > 0}) (offset : usize)
- (hm : hash_map_s t{offset + length hm <= usize_max}) :
+ (hm : hashMap_s t{offset + length hm <= usize_max}) :
Lemma
(requires (
- partial_hash_map_s_inv len offset hm))
+ partial_hashMap_s_inv len offset hm))
(ensures (assoc_list_inv (flatten hm)))
(decreases (length hm + length (flatten hm)))
#push-options "--fuel 1"
-let rec partial_hash_map_s_inv_implies_assoc_list_lem #t len offset hm =
+let rec partial_hashMap_s_inv_implies_assoc_list_lem #t len offset hm =
match hm with
| [] -> ()
| slot :: hm' ->
@@ -1943,8 +1943,8 @@ let rec partial_hash_map_s_inv_implies_assoc_list_lem #t len offset hm =
match slot with
| [] ->
assert(flatten hm == flatten hm');
- assert(partial_hash_map_s_inv len (offset+1) hm'); // Triggers instantiations
- partial_hash_map_s_inv_implies_assoc_list_lem len (offset+1) hm'
+ assert(partial_hashMap_s_inv len (offset+1) hm'); // Triggers instantiations
+ partial_hashMap_s_inv_implies_assoc_list_lem len (offset+1) hm'
| x :: slot' ->
assert(flatten (slot' :: hm') == slot' @ flatten hm');
let hm'' = slot' :: hm' in
@@ -1953,45 +1953,45 @@ let rec partial_hash_map_s_inv_implies_assoc_list_lem #t len offset hm =
assert(index hm 0 == slot); // Triggers instantiations
assert(slot_s_inv len offset slot);
assert(slot_s_inv len offset slot');
- assert(partial_hash_map_s_inv len offset hm'');
- partial_hash_map_s_inv_implies_assoc_list_lem len offset (slot' :: hm');
+ assert(partial_hashMap_s_inv len offset hm'');
+ partial_hashMap_s_inv_implies_assoc_list_lem len offset (slot' :: hm');
// Proving that the key in `x` is different from all the other keys in
// the flattened map
assert(for_all (binding_neq x) slot');
for_all_append (binding_neq x) slot' (flatten hm');
- assert(partial_hash_map_s_inv len (offset+1) hm');
+ assert(partial_hashMap_s_inv len (offset+1) hm');
binding_in_previous_slot_implies_neq #t len offset x (offset+1) hm';
assert(for_all (binding_neq x) (flatten hm'));
assert(for_all (binding_neq x) (flatten (slot' :: hm')))
#pop-options
-val hash_map_s_inv_implies_assoc_list_lem
- (#t : Type0) (hm : hash_map_s t) :
- Lemma (requires (hash_map_s_inv hm))
+val hashMap_s_inv_implies_assoc_list_lem
+ (#t : Type0) (hm : hashMap_s t) :
+ Lemma (requires (hashMap_s_inv hm))
(ensures (assoc_list_inv (flatten hm)))
-let hash_map_s_inv_implies_assoc_list_lem #t hm =
- partial_hash_map_s_inv_implies_assoc_list_lem (length hm) 0 hm
+let hashMap_s_inv_implies_assoc_list_lem #t hm =
+ partial_hashMap_s_inv_implies_assoc_list_lem (length hm) 0 hm
-val hash_map_t_base_inv_implies_assoc_list_lem
- (#t : Type0) (hm : hash_map_t t):
- Lemma (requires (hash_map_t_base_inv hm))
- (ensures (assoc_list_inv (hash_map_t_al_v hm)))
+val hashMap_t_base_inv_implies_assoc_list_lem
+ (#t : Type0) (hm : hashMap_t t):
+ Lemma (requires (hashMap_t_base_inv hm))
+ (ensures (assoc_list_inv (hashMap_t_al_v hm)))
-let hash_map_t_base_inv_implies_assoc_list_lem #t hm =
- hash_map_s_inv_implies_assoc_list_lem (hash_map_t_v hm)
+let hashMap_t_base_inv_implies_assoc_list_lem #t hm =
+ hashMap_s_inv_implies_assoc_list_lem (hashMap_t_v hm)
/// For some reason, we can't write the below [forall] directly in the [ensures]
/// clause of the next lemma: it makes Z3 fails even with a huge rlimit.
/// I have no idea what's going on.
-let hash_map_is_assoc_list
- (#t : Type0) (ntable : hash_map_t t{length ntable.hash_map_slots > 0})
+let hashMap_is_assoc_list
+ (#t : Type0) (ntable : hashMap_t t{length ntable.slots > 0})
(al : assoc_list t) : Type0 =
- (forall (k:key). hash_map_t_find_s ntable k == assoc_list_find k al)
+ (forall (k:key). hashMap_t_find_s ntable k == assoc_list_find k al)
-let partial_hash_map_s_find
+let partial_hashMap_s_find
(#t : Type0) (len : usize{len > 0}) (offset : usize)
- (hm : hash_map_s_nes t{offset + length hm = len})
+ (hm : hashMap_s_nes t{offset + length hm = len})
(k : key{hash_mod_key k len >= offset}) : option t =
let i = hash_mod_key k len in
let slot = index hm (i - offset) in
@@ -2021,13 +2021,13 @@ val key_in_previous_slot_implies_not_found
(#t : Type0) (len : usize{len > 0})
(k : key)
(offset : usize)
- (slots : hash_map_s t{offset + length slots = len}) :
+ (slots : hashMap_s t{offset + length slots = len}) :
Lemma
(requires (
// The binding comes from a slot not in [slots]
hash_mod_key k len < offset /\
// The slots are the well-formed suffix of a hash map
- partial_hash_map_s_inv len offset slots))
+ partial_hashMap_s_inv len offset slots))
(ensures (
assoc_list_find k (flatten slots) == None))
(decreases slots)
@@ -2045,19 +2045,19 @@ let rec key_in_previous_slot_implies_not_found #t len k offset slots =
key_in_previous_slot_implies_not_found len k (offset+1) slots'
#pop-options
-val partial_hash_map_s_is_assoc_list_lem
+val partial_hashMap_s_is_assoc_list_lem
(#t : Type0) (len : usize{len > 0}) (offset : usize)
- (hm : hash_map_s_nes t{offset + length hm = len})
+ (hm : hashMap_s_nes t{offset + length hm = len})
(k : key{hash_mod_key k len >= offset}) :
Lemma
(requires (
- partial_hash_map_s_inv len offset hm))
+ partial_hashMap_s_inv len offset hm))
(ensures (
- partial_hash_map_s_find len offset hm k == assoc_list_find k (flatten hm)))
+ partial_hashMap_s_find len offset hm k == assoc_list_find k (flatten hm)))
(decreases hm)
#push-options "--fuel 1"
-let rec partial_hash_map_s_is_assoc_list_lem #t len offset hm k =
+let rec partial_hashMap_s_is_assoc_list_lem #t len offset hm k =
match hm with
| [] -> ()
| slot :: hm' ->
@@ -2066,7 +2066,7 @@ let rec partial_hash_map_s_is_assoc_list_lem #t len offset hm k =
if i = 0 then
begin
// We must look in the current slot
- assert(partial_hash_map_s_find len offset hm k == slot_s_find k slot);
+ assert(partial_hashMap_s_find len offset hm k == slot_s_find k slot);
find_append (same_key k) slot (flatten hm');
assert(forall (i:nat{i < length hm'}). index hm' i == index hm (i+1)); // Triggers instantiations
key_in_previous_slot_implies_not_found #t len k (offset+1) hm';
@@ -2085,64 +2085,64 @@ let rec partial_hash_map_s_is_assoc_list_lem #t len offset hm k =
else
begin
// We must ignore the current slot
- assert(partial_hash_map_s_find len offset hm k ==
- partial_hash_map_s_find len (offset+1) hm' k);
+ assert(partial_hashMap_s_find len offset hm k ==
+ partial_hashMap_s_find len (offset+1) hm' k);
find_append (same_key k) slot (flatten hm');
assert(index hm 0 == slot); // Triggers instantiations
not_same_hash_key_not_found_in_slot #t len k offset slot;
assert(forall (i:nat{i < length hm'}). index hm' i == index hm (i+1)); // Triggers instantiations
- partial_hash_map_s_is_assoc_list_lem #t len (offset+1) hm' k
+ partial_hashMap_s_is_assoc_list_lem #t len (offset+1) hm' k
end
#pop-options
-val hash_map_is_assoc_list_lem (#t : Type0) (hm : hash_map_t t) :
- Lemma (requires (hash_map_t_base_inv hm))
- (ensures (hash_map_is_assoc_list hm (hash_map_t_al_v hm)))
+val hashMap_is_assoc_list_lem (#t : Type0) (hm : hashMap_t t) :
+ Lemma (requires (hashMap_t_base_inv hm))
+ (ensures (hashMap_is_assoc_list hm (hashMap_t_al_v hm)))
-let hash_map_is_assoc_list_lem #t hm =
+let hashMap_is_assoc_list_lem #t hm =
let aux (k:key) :
- Lemma (hash_map_t_find_s hm k == assoc_list_find k (hash_map_t_al_v hm))
- [SMTPat (hash_map_t_find_s hm k)] =
- let hm_v = hash_map_t_v hm in
+ Lemma (hashMap_t_find_s hm k == assoc_list_find k (hashMap_t_al_v hm))
+ [SMTPat (hashMap_t_find_s hm k)] =
+ let hm_v = hashMap_t_v hm in
let len = length hm_v in
- partial_hash_map_s_is_assoc_list_lem #t len 0 hm_v k
+ partial_hashMap_s_is_assoc_list_lem #t len 0 hm_v k
in
()
/// The final lemma about [move_elements]: calling it on an empty hash table moves
/// all the elements to this empty table.
-val hash_map_move_elements_fwd_back_lem
- (t : Type0) (ntable : hash_map_t t) (slots : vec (list_t t)) :
+val hashMap_move_elements_lem
+ (t : Type0) (ntable : hashMap_t t) (slots : alloc_vec_Vec (list_t t)) :
Lemma
(requires (
let al = flatten (slots_t_v slots) in
- hash_map_t_base_inv ntable /\
+ hashMap_t_base_inv ntable /\
length al <= usize_max /\
assoc_list_inv al /\
// The table is empty
- hash_map_t_len_s ntable = 0 /\
- (forall (k:key). hash_map_t_find_s ntable k == None)))
+ hashMap_t_len_s ntable = 0 /\
+ (forall (k:key). hashMap_t_find_s ntable k == None)))
(ensures (
let al = flatten (slots_t_v slots) in
- match hash_map_move_elements_fwd_back t ntable slots 0,
- hash_map_move_elements_s_flat (hash_map_t_v ntable) al
+ match hashMap_move_elements t ntable slots 0,
+ hashMap_move_elements_s_flat (hashMap_t_v ntable) al
with
| Return (ntable', _), Return ntable'_v ->
// The invariant is preserved
- hash_map_t_base_inv ntable' /\
+ hashMap_t_base_inv ntable' /\
// We preserved the parameters
- hash_map_t_same_params ntable' ntable /\
+ hashMap_t_same_params ntable' ntable /\
// The table has the same number of slots
- length ntable'.hash_map_slots = length ntable.hash_map_slots /\
+ length ntable'.slots = length ntable.slots /\
// The count is good
- hash_map_t_len_s ntable' = length al /\
+ hashMap_t_len_s ntable' = length al /\
// The table can be linked to its model (we need this only to reveal
// "pretty" functional lemmas to the user in the fsti - so that we
// can write lemmas with SMT patterns - this is very F* specific)
- hash_map_t_v ntable' == ntable'_v /\
+ hashMap_t_v ntable' == ntable'_v /\
// The new table contains exactly all the bindings from the slots
- // Rk.: see the comment for [hash_map_is_assoc_list]
- hash_map_is_assoc_list ntable' al
+ // Rk.: see the comment for [hashMap_is_assoc_list]
+ hashMap_is_assoc_list ntable' al
| _ -> False // We can only succeed
))
@@ -2154,41 +2154,41 @@ val hash_map_move_elements_fwd_back_lem
// lack of ifuel (this kind of proofs is annoying, really).
#restart-solver
#push-options "--z3rlimit 100"
-let hash_map_move_elements_fwd_back_lem t ntable slots =
- let ntable_v = hash_map_t_v ntable in
+let hashMap_move_elements_lem t ntable slots =
+ let ntable_v = hashMap_t_v ntable in
let slots_v = slots_t_v slots in
let al = flatten slots_v in
- hash_map_move_elements_fwd_back_lem_refin t ntable slots 0;
+ hashMap_move_elements_lem_refin t ntable slots 0;
begin
- match hash_map_move_elements_fwd_back t ntable slots 0,
- hash_map_move_elements_s ntable_v slots_v 0
+ match hashMap_move_elements t ntable slots 0,
+ hashMap_move_elements_s ntable_v slots_v 0
with
| Fail _, Fail _ -> ()
| Return (ntable', _), Return ntable'_v ->
- assert(hash_map_t_base_inv ntable');
- assert(hash_map_t_v ntable' == ntable'_v)
+ assert(hashMap_t_base_inv ntable');
+ assert(hashMap_t_v ntable' == ntable'_v)
| _ -> assert(False)
end;
- hash_map_move_elements_s_lem_refin_flat ntable_v slots_v 0;
+ hashMap_move_elements_s_lem_refin_flat ntable_v slots_v 0;
begin
- match hash_map_move_elements_s ntable_v slots_v 0,
- hash_map_move_elements_s_flat ntable_v (flatten_i slots_v 0)
+ match hashMap_move_elements_s ntable_v slots_v 0,
+ hashMap_move_elements_s_flat ntable_v (flatten_i slots_v 0)
with
| Fail _, Fail _ -> ()
| Return hm, Return hm' -> assert(hm == hm')
| _ -> assert(False)
end;
flatten_0_is_flatten slots_v; // flatten_i slots_v 0 == flatten slots_v
- hash_map_move_elements_s_flat_lem ntable_v al;
- match hash_map_move_elements_fwd_back t ntable slots 0,
- hash_map_move_elements_s_flat ntable_v al
+ hashMap_move_elements_s_flat_lem ntable_v al;
+ match hashMap_move_elements t ntable slots 0,
+ hashMap_move_elements_s_flat ntable_v al
with
| Return (ntable', _), Return ntable'_v ->
- assert(hash_map_t_base_inv ntable');
- assert(length ntable'.hash_map_slots = length ntable.hash_map_slots);
- assert(hash_map_t_len_s ntable' = length al);
- assert(hash_map_t_v ntable' == ntable'_v);
- assert(hash_map_is_assoc_list ntable' al)
+ assert(hashMap_t_base_inv ntable');
+ assert(length ntable'.slots = length ntable.slots);
+ assert(hashMap_t_len_s ntable' = length al);
+ assert(hashMap_t_v ntable' == ntable'_v);
+ assert(hashMap_is_assoc_list ntable' al)
| _ -> assert(False)
#pop-options
@@ -2197,47 +2197,47 @@ let hash_map_move_elements_fwd_back_lem t ntable slots =
/// High-level model 1.
/// This is one is slightly "crude": we just simplify a bit the function.
-let hash_map_try_resize_s_simpl
+let hashMap_try_resize_s_simpl
(#t : Type0)
- (hm : hash_map_t t) :
- Pure (result (hash_map_t t))
+ (hm : hashMap_t t) :
+ Pure (result (hashMap_t t))
(requires (
- let (divid, divis) = hm.hash_map_max_load_factor in
+ let (divid, divis) = hm.max_load_factor in
divid > 0 /\ divis > 0))
(ensures (fun _ -> True)) =
- let capacity = length hm.hash_map_slots in
- let (divid, divis) = hm.hash_map_max_load_factor in
+ let capacity = length hm.slots in
+ let (divid, divis) = hm.max_load_factor in
if capacity <= (usize_max / 2) / divid then
let ncapacity : usize = capacity * 2 in
- begin match hash_map_new_with_capacity_fwd t ncapacity divid divis with
+ begin match hashMap_new_with_capacity t ncapacity divid divis with
| Fail e -> Fail e
| Return ntable ->
- match hash_map_move_elements_fwd_back t ntable hm.hash_map_slots 0 with
+ match hashMap_move_elements t ntable hm.slots 0 with
| Fail e -> Fail e
| Return (ntable', _) ->
let hm =
- { hm with hash_map_slots = ntable'.hash_map_slots;
- hash_map_max_load = ntable'.hash_map_max_load }
+ { hm with slots = ntable'.slots;
+ max_load = ntable'.max_load }
in
Return hm
end
else Return hm
-val hash_map_try_resize_fwd_back_lem_refin
- (t : Type0) (self : hash_map_t t) :
+val hashMap_try_resize_lem_refin
+ (t : Type0) (self : hashMap_t t) :
Lemma
(requires (
- let (divid, divis) = self.hash_map_max_load_factor in
+ let (divid, divis) = self.max_load_factor in
divid > 0 /\ divis > 0))
(ensures (
- match hash_map_try_resize_fwd_back t self,
- hash_map_try_resize_s_simpl self
+ match hashMap_try_resize t self,
+ hashMap_try_resize_s_simpl self
with
| Fail _, Fail _ -> True
| Return hm1, Return hm2 -> hm1 == hm2
| _ -> False))
-let hash_map_try_resize_fwd_back_lem_refin t self = ()
+let hashMap_try_resize_lem_refin t self = ()
/// Isolating arithmetic proofs
@@ -2342,78 +2342,78 @@ let new_max_load_lem len capacity divid divis =
assert(nmax_load >= max_load + 1)
#pop-options
-val hash_map_try_resize_s_simpl_lem (#t : Type0) (hm : hash_map_t t) :
+val hashMap_try_resize_s_simpl_lem (#t : Type0) (hm : hashMap_t t) :
Lemma
(requires (
// The base invariant is satisfied
- hash_map_t_base_inv hm /\
+ hashMap_t_base_inv hm /\
// However, the "full" invariant is broken, as we call [try_resize]
// only if the current number of entries is > the max load.
//
// There are two situations:
// - either we just reached the max load
// - or we were already saturated and can't resize
- (let (dividend, divisor) = hm.hash_map_max_load_factor in
- hm.hash_map_num_entries == hm.hash_map_max_load + 1 \/
- length hm.hash_map_slots * 2 * dividend > usize_max)
+ (let (dividend, divisor) = hm.max_load_factor in
+ hm.num_entries == hm.max_load + 1 \/
+ length hm.slots * 2 * dividend > usize_max)
))
(ensures (
- match hash_map_try_resize_s_simpl hm with
+ match hashMap_try_resize_s_simpl hm with
| Fail _ -> False
| Return hm' ->
// The full invariant is now satisfied (the full invariant is "base
// invariant" + the map is not overloaded (or can't be resized because
// already too big)
- hash_map_t_inv hm' /\
+ hashMap_t_inv hm' /\
// It contains the same bindings as the initial map
- (forall (k:key). hash_map_t_find_s hm' k == hash_map_t_find_s hm k)))
+ (forall (k:key). hashMap_t_find_s hm' k == hashMap_t_find_s hm k)))
#restart-solver
#push-options "--z3rlimit 400"
-let hash_map_try_resize_s_simpl_lem #t hm =
- let capacity = length hm.hash_map_slots in
- let (divid, divis) = hm.hash_map_max_load_factor in
+let hashMap_try_resize_s_simpl_lem #t hm =
+ let capacity = length hm.slots in
+ let (divid, divis) = hm.max_load_factor in
if capacity <= (usize_max / 2) / divid then
begin
let ncapacity : usize = capacity * 2 in
assert(ncapacity * divid <= usize_max);
- assert(hash_map_t_len_s hm = hm.hash_map_max_load + 1);
- new_max_load_lem (hash_map_t_len_s hm) capacity divid divis;
- hash_map_new_with_capacity_fwd_lem t ncapacity divid divis;
- match hash_map_new_with_capacity_fwd t ncapacity divid divis with
+ assert(hashMap_t_len_s hm = hm.max_load + 1);
+ new_max_load_lem (hashMap_t_len_s hm) capacity divid divis;
+ hashMap_new_with_capacity_lem t ncapacity divid divis;
+ match hashMap_new_with_capacity t ncapacity divid divis with
| Fail _ -> ()
| Return ntable ->
- let slots = hm.hash_map_slots in
+ let slots = hm.slots in
let al = flatten (slots_t_v slots) in
- // Proving that: length al = hm.hash_map_num_entries
+ // Proving that: length al = hm.num_entries
assert(al == flatten (map slot_t_v slots));
assert(al == flatten (map list_t_v slots));
- assert(hash_map_t_al_v hm == flatten (hash_map_t_v hm));
- assert(hash_map_t_al_v hm == flatten (map list_t_v hm.hash_map_slots));
- assert(al == hash_map_t_al_v hm);
- assert(hash_map_t_base_inv ntable);
- assert(length al = hm.hash_map_num_entries);
+ assert(hashMap_t_al_v hm == flatten (hashMap_t_v hm));
+ assert(hashMap_t_al_v hm == flatten (map list_t_v hm.slots));
+ assert(al == hashMap_t_al_v hm);
+ assert(hashMap_t_base_inv ntable);
+ assert(length al = hm.num_entries);
assert(length al <= usize_max);
- hash_map_t_base_inv_implies_assoc_list_lem hm;
+ hashMap_t_base_inv_implies_assoc_list_lem hm;
assert(assoc_list_inv al);
- assert(hash_map_t_len_s ntable = 0);
- assert(forall (k:key). hash_map_t_find_s ntable k == None);
- hash_map_move_elements_fwd_back_lem t ntable hm.hash_map_slots;
- match hash_map_move_elements_fwd_back t ntable hm.hash_map_slots 0 with
+ assert(hashMap_t_len_s ntable = 0);
+ assert(forall (k:key). hashMap_t_find_s ntable k == None);
+ hashMap_move_elements_lem t ntable hm.slots;
+ match hashMap_move_elements t ntable hm.slots 0 with
| Fail _ -> ()
| Return (ntable', _) ->
- hash_map_is_assoc_list_lem hm;
- assert(hash_map_is_assoc_list hm (hash_map_t_al_v hm));
+ hashMap_is_assoc_list_lem hm;
+ assert(hashMap_is_assoc_list hm (hashMap_t_al_v hm));
let hm' =
- { hm with hash_map_slots = ntable'.hash_map_slots;
- hash_map_max_load = ntable'.hash_map_max_load }
+ { hm with slots = ntable'.slots;
+ max_load = ntable'.max_load }
in
- assert(hash_map_t_base_inv ntable');
- assert(hash_map_t_base_inv hm');
- assert(hash_map_t_len_s hm' = hash_map_t_len_s hm);
- new_max_load_lem (hash_map_t_len_s hm') capacity divid divis;
- assert(hash_map_t_len_s hm' <= hm'.hash_map_max_load); // Requires a lemma
- assert(hash_map_t_inv hm')
+ assert(hashMap_t_base_inv ntable');
+ assert(hashMap_t_base_inv hm');
+ assert(hashMap_t_len_s hm' = hashMap_t_len_s hm);
+ new_max_load_lem (hashMap_t_len_s hm') capacity divid divis;
+ assert(hashMap_t_len_s hm' <= hm'.max_load); // Requires a lemma
+ assert(hashMap_t_inv hm')
end
else
begin
@@ -2422,203 +2422,203 @@ let hash_map_try_resize_s_simpl_lem #t hm =
end
#pop-options
-let hash_map_t_same_bindings (#t : Type0) (hm hm' : hash_map_t_nes t) : Type0 =
- forall (k:key). hash_map_t_find_s hm k == hash_map_t_find_s hm' k
+let hashMap_t_same_bindings (#t : Type0) (hm hm' : hashMap_t_nes t) : Type0 =
+ forall (k:key). hashMap_t_find_s hm k == hashMap_t_find_s hm' k
/// The final lemma about [try_resize]
-val hash_map_try_resize_fwd_back_lem (#t : Type0) (hm : hash_map_t t) :
+val hashMap_try_resize_lem (#t : Type0) (hm : hashMap_t t) :
Lemma
(requires (
- hash_map_t_base_inv hm /\
+ hashMap_t_base_inv hm /\
// However, the "full" invariant is broken, as we call [try_resize]
// only if the current number of entries is > the max load.
//
// There are two situations:
// - either we just reached the max load
// - or we were already saturated and can't resize
- (let (dividend, divisor) = hm.hash_map_max_load_factor in
- hm.hash_map_num_entries == hm.hash_map_max_load + 1 \/
- length hm.hash_map_slots * 2 * dividend > usize_max)))
+ (let (dividend, divisor) = hm.max_load_factor in
+ hm.num_entries == hm.max_load + 1 \/
+ length hm.slots * 2 * dividend > usize_max)))
(ensures (
- match hash_map_try_resize_fwd_back t hm with
+ match hashMap_try_resize t hm with
| Fail _ -> False
| Return hm' ->
// The full invariant is now satisfied (the full invariant is "base
// invariant" + the map is not overloaded (or can't be resized because
// already too big)
- hash_map_t_inv hm' /\
+ hashMap_t_inv hm' /\
// The length is the same
- hash_map_t_len_s hm' = hash_map_t_len_s hm /\
+ hashMap_t_len_s hm' = hashMap_t_len_s hm /\
// It contains the same bindings as the initial map
- hash_map_t_same_bindings hm' hm))
+ hashMap_t_same_bindings hm' hm))
-let hash_map_try_resize_fwd_back_lem #t hm =
- hash_map_try_resize_fwd_back_lem_refin t hm;
- hash_map_try_resize_s_simpl_lem hm
+let hashMap_try_resize_lem #t hm =
+ hashMap_try_resize_lem_refin t hm;
+ hashMap_try_resize_s_simpl_lem hm
(*** insert *)
/// The high-level model (very close to the original function: we don't need something
/// very high level, just to clean it a bit)
-let hash_map_insert_s
- (#t : Type0) (self : hash_map_t t) (key : usize) (value : t) :
- result (hash_map_t t) =
- match hash_map_insert_no_resize_fwd_back t self key value with
+let hashMap_insert_s
+ (#t : Type0) (self : hashMap_t t) (key : usize) (value : t) :
+ result (hashMap_t t) =
+ match hashMap_insert_no_resize t self key value with
| Fail e -> Fail e
| Return hm' ->
- if hash_map_t_len_s hm' > hm'.hash_map_max_load then
- hash_map_try_resize_fwd_back t hm'
+ if hashMap_t_len_s hm' > hm'.max_load then
+ hashMap_try_resize t hm'
else Return hm'
-val hash_map_insert_fwd_back_lem_refin
- (t : Type0) (self : hash_map_t t) (key : usize) (value : t) :
+val hashMap_insert_lem_refin
+ (t : Type0) (self : hashMap_t t) (key : usize) (value : t) :
Lemma (requires True)
(ensures (
- match hash_map_insert_fwd_back t self key value,
- hash_map_insert_s self key value
+ match hashMap_insert t self key value,
+ hashMap_insert_s self key value
with
| Fail _, Fail _ -> True
| Return hm1, Return hm2 -> hm1 == hm2
| _ -> False))
-let hash_map_insert_fwd_back_lem_refin t self key value = ()
+let hashMap_insert_lem_refin t self key value = ()
/// Helper
-let hash_map_insert_fwd_back_bindings_lem
- (t : Type0) (self : hash_map_t_nes t) (key : usize) (value : t)
- (hm' hm'' : hash_map_t_nes t) :
+let hashMap_insert_bindings_lem
+ (t : Type0) (self : hashMap_t_nes t) (key : usize) (value : t)
+ (hm' hm'' : hashMap_t_nes t) :
Lemma
(requires (
- hash_map_s_updated_binding (hash_map_t_v self) key
- (Some value) (hash_map_t_v hm') /\
- hash_map_t_same_bindings hm' hm''))
+ hashMap_s_updated_binding (hashMap_t_v self) key
+ (Some value) (hashMap_t_v hm') /\
+ hashMap_t_same_bindings hm' hm''))
(ensures (
- hash_map_s_updated_binding (hash_map_t_v self) key
- (Some value) (hash_map_t_v hm'')))
+ hashMap_s_updated_binding (hashMap_t_v self) key
+ (Some value) (hashMap_t_v hm'')))
= ()
-val hash_map_insert_fwd_back_lem_aux
- (#t : Type0) (self : hash_map_t t) (key : usize) (value : t) :
- Lemma (requires (hash_map_t_inv self))
+val hashMap_insert_lem_aux
+ (#t : Type0) (self : hashMap_t t) (key : usize) (value : t) :
+ Lemma (requires (hashMap_t_inv self))
(ensures (
- match hash_map_insert_fwd_back t self key value with
+ match hashMap_insert t self key value with
| Fail _ ->
// We can fail only if:
// - the key is not in the map and we need to add it
// - we are already saturated
- hash_map_t_len_s self = usize_max /\
- None? (hash_map_t_find_s self key)
+ hashMap_t_len_s self = usize_max /\
+ None? (hashMap_t_find_s self key)
| Return hm' ->
// The invariant is preserved
- hash_map_t_inv hm' /\
+ hashMap_t_inv hm' /\
// [key] maps to [value] and the other bindings are preserved
- hash_map_s_updated_binding (hash_map_t_v self) key (Some value) (hash_map_t_v hm') /\
+ hashMap_s_updated_binding (hashMap_t_v self) key (Some value) (hashMap_t_v hm') /\
// The length is incremented, iff we inserted a new key
- (match hash_map_t_find_s self key with
- | None -> hash_map_t_len_s hm' = hash_map_t_len_s self + 1
- | Some _ -> hash_map_t_len_s hm' = hash_map_t_len_s self)))
+ (match hashMap_t_find_s self key with
+ | None -> hashMap_t_len_s hm' = hashMap_t_len_s self + 1
+ | Some _ -> hashMap_t_len_s hm' = hashMap_t_len_s self)))
#restart-solver
#push-options "--z3rlimit 200"
-let hash_map_insert_fwd_back_lem_aux #t self key value =
- hash_map_insert_no_resize_fwd_back_lem_s t self key value;
- hash_map_insert_no_resize_s_lem (hash_map_t_v self) key value;
- match hash_map_insert_no_resize_fwd_back t self key value with
+let hashMap_insert_lem_aux #t self key value =
+ hashMap_insert_no_resize_lem_s t self key value;
+ hashMap_insert_no_resize_s_lem (hashMap_t_v self) key value;
+ match hashMap_insert_no_resize t self key value with
| Fail _ -> ()
| Return hm' ->
- // Expanding the post of [hash_map_insert_no_resize_fwd_back_lem_s]
- let self_v = hash_map_t_v self in
- let hm'_v = Return?.v (hash_map_insert_no_resize_s self_v key value) in
- assert(hash_map_t_base_inv hm');
- assert(hash_map_t_same_params hm' self);
- assert(hash_map_t_v hm' == hm'_v);
- assert(hash_map_s_len hm'_v == hash_map_t_len_s hm');
- // Expanding the post of [hash_map_insert_no_resize_s_lem]
+ // Expanding the post of [hashMap_insert_no_resize_lem_s]
+ let self_v = hashMap_t_v self in
+ let hm'_v = Return?.v (hashMap_insert_no_resize_s self_v key value) in
+ assert(hashMap_t_base_inv hm');
+ assert(hashMap_t_same_params hm' self);
+ assert(hashMap_t_v hm' == hm'_v);
+ assert(hashMap_s_len hm'_v == hashMap_t_len_s hm');
+ // Expanding the post of [hashMap_insert_no_resize_s_lem]
assert(insert_post self_v key value hm'_v);
// Expanding [insert_post]
- assert(hash_map_s_inv hm'_v);
+ assert(hashMap_s_inv hm'_v);
assert(
- match hash_map_s_find self_v key with
- | None -> hash_map_s_len hm'_v = hash_map_s_len self_v + 1
- | Some _ -> hash_map_s_len hm'_v = hash_map_s_len self_v);
- if hash_map_t_len_s hm' > hm'.hash_map_max_load then
+ match hashMap_s_find self_v key with
+ | None -> hashMap_s_len hm'_v = hashMap_s_len self_v + 1
+ | Some _ -> hashMap_s_len hm'_v = hashMap_s_len self_v);
+ if hashMap_t_len_s hm' > hm'.max_load then
begin
- hash_map_try_resize_fwd_back_lem hm';
- // Expanding the post of [hash_map_try_resize_fwd_back_lem]
- let hm'' = Return?.v (hash_map_try_resize_fwd_back t hm') in
- assert(hash_map_t_inv hm'');
- let hm''_v = hash_map_t_v hm'' in
- assert(forall k. hash_map_t_find_s hm'' k == hash_map_t_find_s hm' k);
- assert(hash_map_t_len_s hm'' = hash_map_t_len_s hm'); // TODO
+ hashMap_try_resize_lem hm';
+ // Expanding the post of [hashMap_try_resize_lem]
+ let hm'' = Return?.v (hashMap_try_resize t hm') in
+ assert(hashMap_t_inv hm'');
+ let hm''_v = hashMap_t_v hm'' in
+ assert(forall k. hashMap_t_find_s hm'' k == hashMap_t_find_s hm' k);
+ assert(hashMap_t_len_s hm'' = hashMap_t_len_s hm'); // TODO
// Proving the post
- assert(hash_map_t_inv hm'');
- hash_map_insert_fwd_back_bindings_lem t self key value hm' hm'';
+ assert(hashMap_t_inv hm'');
+ hashMap_insert_bindings_lem t self key value hm' hm'';
assert(
- match hash_map_t_find_s self key with
- | None -> hash_map_t_len_s hm'' = hash_map_t_len_s self + 1
- | Some _ -> hash_map_t_len_s hm'' = hash_map_t_len_s self)
+ match hashMap_t_find_s self key with
+ | None -> hashMap_t_len_s hm'' = hashMap_t_len_s self + 1
+ | Some _ -> hashMap_t_len_s hm'' = hashMap_t_len_s self)
end
else ()
#pop-options
-let hash_map_insert_fwd_back_lem #t self key value =
- hash_map_insert_fwd_back_lem_aux #t self key value
+let hashMap_insert_lem #t self key value =
+ hashMap_insert_lem_aux #t self key value
(*** contains_key *)
(**** contains_key_in_list *)
-val hash_map_contains_key_in_list_fwd_lem
+val hashMap_contains_key_in_list_lem
(#t : Type0) (key : usize) (ls : list_t t) :
Lemma
(ensures (
- match hash_map_contains_key_in_list_fwd t key ls with
+ match hashMap_contains_key_in_list t key ls with
| Fail _ -> False
| Return b ->
b = Some? (slot_t_find_s key ls)))
#push-options "--fuel 1"
-let rec hash_map_contains_key_in_list_fwd_lem #t key ls =
+let rec hashMap_contains_key_in_list_lem #t key ls =
match ls with
- | ListCons ckey x ls0 ->
+ | List_Cons ckey x ls0 ->
let b = ckey = key in
if b
then ()
else
begin
- hash_map_contains_key_in_list_fwd_lem key ls0;
- match hash_map_contains_key_in_list_fwd t key ls0 with
+ hashMap_contains_key_in_list_lem key ls0;
+ match hashMap_contains_key_in_list t key ls0 with
| Fail _ -> ()
| Return b0 -> ()
end
- | ListNil -> ()
+ | List_Nil -> ()
#pop-options
(**** contains_key *)
-val hash_map_contains_key_fwd_lem_aux
- (#t : Type0) (self : hash_map_t_nes t) (key : usize) :
+val hashMap_contains_key_lem_aux
+ (#t : Type0) (self : hashMap_t_nes t) (key : usize) :
Lemma
(ensures (
- match hash_map_contains_key_fwd t self key with
+ match hashMap_contains_key t self key with
| Fail _ -> False
- | Return b -> b = Some? (hash_map_t_find_s self key)))
+ | Return b -> b = Some? (hashMap_t_find_s self key)))
-let hash_map_contains_key_fwd_lem_aux #t self key =
- begin match hash_key_fwd key with
+let hashMap_contains_key_lem_aux #t self key =
+ begin match hash_key key with
| Fail _ -> ()
| Return i ->
- let v = self.hash_map_slots in
- let i0 = vec_len (list_t t) v in
+ let v = self.slots in
+ let i0 = alloc_vec_Vec_len (list_t t) v in
begin match usize_rem i i0 with
| Fail _ -> ()
| Return hash_mod ->
- begin match vec_index_fwd (list_t t) v hash_mod with
+ begin match alloc_vec_Vec_index_usize v hash_mod with
| Fail _ -> ()
| Return l ->
- hash_map_contains_key_in_list_fwd_lem key l;
- begin match hash_map_contains_key_in_list_fwd t key l with
+ hashMap_contains_key_in_list_lem key l;
+ begin match hashMap_contains_key_in_list t key l with
| Fail _ -> ()
| Return b -> ()
end
@@ -2627,66 +2627,66 @@ let hash_map_contains_key_fwd_lem_aux #t self key =
end
/// The lemma in the .fsti
-let hash_map_contains_key_fwd_lem #t self key =
- hash_map_contains_key_fwd_lem_aux #t self key
+let hashMap_contains_key_lem #t self key =
+ hashMap_contains_key_lem_aux #t self key
(*** get *)
(**** get_in_list *)
-val hash_map_get_in_list_fwd_lem
+val hashMap_get_in_list_lem
(#t : Type0) (key : usize) (ls : list_t t) :
Lemma
(ensures (
- match hash_map_get_in_list_fwd t key ls, slot_t_find_s key ls with
+ match hashMap_get_in_list t key ls, slot_t_find_s key ls with
| Fail _, None -> True
| Return x, Some x' -> x == x'
| _ -> False))
#push-options "--fuel 1"
-let rec hash_map_get_in_list_fwd_lem #t key ls =
+let rec hashMap_get_in_list_lem #t key ls =
begin match ls with
- | ListCons ckey cvalue ls0 ->
+ | List_Cons ckey cvalue ls0 ->
let b = ckey = key in
if b
then ()
else
begin
- hash_map_get_in_list_fwd_lem key ls0;
- match hash_map_get_in_list_fwd t key ls0 with
+ hashMap_get_in_list_lem key ls0;
+ match hashMap_get_in_list t key ls0 with
| Fail _ -> ()
| Return x -> ()
end
- | ListNil -> ()
+ | List_Nil -> ()
end
#pop-options
(**** get *)
-val hash_map_get_fwd_lem_aux
- (#t : Type0) (self : hash_map_t_nes t) (key : usize) :
+val hashMap_get_lem_aux
+ (#t : Type0) (self : hashMap_t_nes t) (key : usize) :
Lemma
(ensures (
- match hash_map_get_fwd t self key, hash_map_t_find_s self key with
+ match hashMap_get t self key, hashMap_t_find_s self key with
| Fail _, None -> True
| Return x, Some x' -> x == x'
| _ -> False))
-let hash_map_get_fwd_lem_aux #t self key =
- begin match hash_key_fwd key with
+let hashMap_get_lem_aux #t self key =
+ begin match hash_key key with
| Fail _ -> ()
| Return i ->
- let v = self.hash_map_slots in
- let i0 = vec_len (list_t t) v in
+ let v = self.slots in
+ let i0 = alloc_vec_Vec_len (list_t t) v in
begin match usize_rem i i0 with
| Fail _ -> ()
| Return hash_mod ->
- begin match vec_index_fwd (list_t t) v hash_mod with
+ begin match alloc_vec_Vec_index_usize v hash_mod with
| Fail _ -> ()
| Return l ->
begin
- hash_map_get_in_list_fwd_lem key l;
- match hash_map_get_in_list_fwd t key l with
+ hashMap_get_in_list_lem key l;
+ match hashMap_get_in_list t key l with
| Fail _ -> ()
| Return x -> ()
end
@@ -2695,66 +2695,66 @@ let hash_map_get_fwd_lem_aux #t self key =
end
/// .fsti
-let hash_map_get_fwd_lem #t self key = hash_map_get_fwd_lem_aux #t self key
+let hashMap_get_lem #t self key = hashMap_get_lem_aux #t self key
(*** get_mut'fwd *)
(**** get_mut_in_list'fwd *)
-val hash_map_get_mut_in_list_loop_fwd_lem
+val hashMap_get_mut_in_list_loop_lem
(#t : Type0) (ls : list_t t) (key : usize) :
Lemma
(ensures (
- match hash_map_get_mut_in_list_loop_fwd t ls key, slot_t_find_s key ls with
+ match hashMap_get_mut_in_list_loop t ls key, slot_t_find_s key ls with
| Fail _, None -> True
| Return x, Some x' -> x == x'
| _ -> False))
#push-options "--fuel 1"
-let rec hash_map_get_mut_in_list_loop_fwd_lem #t ls key =
+let rec hashMap_get_mut_in_list_loop_lem #t ls key =
begin match ls with
- | ListCons ckey cvalue ls0 ->
+ | List_Cons ckey cvalue ls0 ->
let b = ckey = key in
if b
then ()
else
begin
- hash_map_get_mut_in_list_loop_fwd_lem ls0 key;
- match hash_map_get_mut_in_list_loop_fwd t ls0 key with
+ hashMap_get_mut_in_list_loop_lem ls0 key;
+ match hashMap_get_mut_in_list_loop t ls0 key with
| Fail _ -> ()
| Return x -> ()
end
- | ListNil -> ()
+ | List_Nil -> ()
end
#pop-options
(**** get_mut'fwd *)
-val hash_map_get_mut_fwd_lem_aux
- (#t : Type0) (self : hash_map_t_nes t) (key : usize) :
+val hashMap_get_mut_lem_aux
+ (#t : Type0) (self : hashMap_t_nes t) (key : usize) :
Lemma
(ensures (
- match hash_map_get_mut_fwd t self key, hash_map_t_find_s self key with
+ match hashMap_get_mut t self key, hashMap_t_find_s self key with
| Fail _, None -> True
| Return x, Some x' -> x == x'
| _ -> False))
-let hash_map_get_mut_fwd_lem_aux #t self key =
- begin match hash_key_fwd key with
+let hashMap_get_mut_lem_aux #t self key =
+ begin match hash_key key with
| Fail _ -> ()
| Return i ->
- let v = self.hash_map_slots in
- let i0 = vec_len (list_t t) v in
+ let v = self.slots in
+ let i0 = alloc_vec_Vec_len (list_t t) v in
begin match usize_rem i i0 with
| Fail _ -> ()
| Return hash_mod ->
- begin match vec_index_fwd (list_t t) v hash_mod with
+ begin match alloc_vec_Vec_index_usize v hash_mod with
| Fail _ -> ()
| Return l ->
begin
- hash_map_get_mut_in_list_loop_fwd_lem l key;
- match hash_map_get_mut_in_list_loop_fwd t l key with
+ hashMap_get_mut_in_list_loop_lem l key;
+ match hashMap_get_mut_in_list_loop t l key with
| Fail _ -> ()
| Return x -> ()
end
@@ -2762,78 +2762,78 @@ let hash_map_get_mut_fwd_lem_aux #t self key =
end
end
-let hash_map_get_mut_fwd_lem #t self key =
- hash_map_get_mut_fwd_lem_aux #t self key
+let hashMap_get_mut_lem #t self key =
+ hashMap_get_mut_lem_aux #t self key
(*** get_mut'back *)
(**** get_mut_in_list'back *)
-val hash_map_get_mut_in_list_loop_back_lem
+val hashMap_get_mut_in_list_loop_back_lem
(#t : Type0) (ls : list_t t) (key : usize) (ret : t) :
Lemma
(requires (Some? (slot_t_find_s key ls)))
(ensures (
- match hash_map_get_mut_in_list_loop_back t ls key ret with
+ match hashMap_get_mut_in_list_loop_back t ls key ret with
| Fail _ -> False
| Return ls' -> list_t_v ls' == find_update (same_key key) (list_t_v ls) (key,ret)
| _ -> False))
#push-options "--fuel 1"
-let rec hash_map_get_mut_in_list_loop_back_lem #t ls key ret =
+let rec hashMap_get_mut_in_list_loop_back_lem #t ls key ret =
begin match ls with
- | ListCons ckey cvalue ls0 ->
+ | List_Cons ckey cvalue ls0 ->
let b = ckey = key in
if b
- then let ls1 = ListCons ckey ret ls0 in ()
+ then let ls1 = List_Cons ckey ret ls0 in ()
else
begin
- hash_map_get_mut_in_list_loop_back_lem ls0 key ret;
- match hash_map_get_mut_in_list_loop_back t ls0 key ret with
+ hashMap_get_mut_in_list_loop_back_lem ls0 key ret;
+ match hashMap_get_mut_in_list_loop_back t ls0 key ret with
| Fail _ -> ()
- | Return l -> let ls1 = ListCons ckey cvalue l in ()
+ | Return l -> let ls1 = List_Cons ckey cvalue l in ()
end
- | ListNil -> ()
+ | List_Nil -> ()
end
#pop-options
(**** get_mut'back *)
/// Refinement lemma
-val hash_map_get_mut_back_lem_refin
- (#t : Type0) (self : hash_map_t t{length self.hash_map_slots > 0})
+val hashMap_get_mut_back_lem_refin
+ (#t : Type0) (self : hashMap_t t{length self.slots > 0})
(key : usize) (ret : t) :
Lemma
- (requires (Some? (hash_map_t_find_s self key)))
+ (requires (Some? (hashMap_t_find_s self key)))
(ensures (
- match hash_map_get_mut_back t self key ret with
+ match hashMap_get_mut_back t self key ret with
| Fail _ -> False
| Return hm' ->
- hash_map_t_v hm' == hash_map_insert_no_fail_s (hash_map_t_v self) key ret))
+ hashMap_t_v hm' == hashMap_insert_no_fail_s (hashMap_t_v self) key ret))
-let hash_map_get_mut_back_lem_refin #t self key ret =
- begin match hash_key_fwd key with
+let hashMap_get_mut_back_lem_refin #t self key ret =
+ begin match hash_key key with
| Fail _ -> ()
| Return i ->
- let i0 = self.hash_map_num_entries in
- let p = self.hash_map_max_load_factor in
- let i1 = self.hash_map_max_load in
- let v = self.hash_map_slots in
- let i2 = vec_len (list_t t) v in
+ let i0 = self.num_entries in
+ let p = self.max_load_factor in
+ let i1 = self.max_load in
+ let v = self.slots in
+ let i2 = alloc_vec_Vec_len (list_t t) v in
begin match usize_rem i i2 with
| Fail _ -> ()
| Return hash_mod ->
- begin match vec_index_mut_fwd (list_t t) v hash_mod with
+ begin match alloc_vec_Vec_index_usize v hash_mod with
| Fail _ -> ()
| Return l ->
begin
- hash_map_get_mut_in_list_loop_back_lem l key ret;
- match hash_map_get_mut_in_list_loop_back t l key ret with
+ hashMap_get_mut_in_list_loop_back_lem l key ret;
+ match hashMap_get_mut_in_list_loop_back t l key ret with
| Fail _ -> ()
| Return l0 ->
- begin match vec_index_mut_back (list_t t) v hash_mod l0 with
+ begin match alloc_vec_Vec_update_usize v hash_mod l0 with
| Fail _ -> ()
- | Return v0 -> let self0 = Mkhash_map_t i0 p i1 v0 in ()
+ | Return v0 -> let self0 = MkhashMap_t i0 p i1 v0 in ()
end
end
end
@@ -2841,102 +2841,102 @@ let hash_map_get_mut_back_lem_refin #t self key ret =
end
/// Final lemma
-val hash_map_get_mut_back_lem_aux
- (#t : Type0) (hm : hash_map_t t)
+val hashMap_get_mut_back_lem_aux
+ (#t : Type0) (hm : hashMap_t t)
(key : usize) (ret : t) :
Lemma
(requires (
- hash_map_t_inv hm /\
- Some? (hash_map_t_find_s hm key)))
+ hashMap_t_inv hm /\
+ Some? (hashMap_t_find_s hm key)))
(ensures (
- match hash_map_get_mut_back t hm key ret with
+ match hashMap_get_mut_back t hm key ret with
| Fail _ -> False
| Return hm' ->
// Functional spec
- hash_map_t_v hm' == hash_map_insert_no_fail_s (hash_map_t_v hm) key ret /\
+ hashMap_t_v hm' == hashMap_insert_no_fail_s (hashMap_t_v hm) key ret /\
// The invariant is preserved
- hash_map_t_inv hm' /\
+ hashMap_t_inv hm' /\
// The length is preserved
- hash_map_t_len_s hm' = hash_map_t_len_s hm /\
+ hashMap_t_len_s hm' = hashMap_t_len_s hm /\
// [key] maps to [value]
- hash_map_t_find_s hm' key == Some ret /\
+ hashMap_t_find_s hm' key == Some ret /\
// The other bindings are preserved
- (forall k'. k' <> key ==> hash_map_t_find_s hm' k' == hash_map_t_find_s hm k')))
+ (forall k'. k' <> key ==> hashMap_t_find_s hm' k' == hashMap_t_find_s hm k')))
-let hash_map_get_mut_back_lem_aux #t hm key ret =
- let hm_v = hash_map_t_v hm in
- hash_map_get_mut_back_lem_refin hm key ret;
- match hash_map_get_mut_back t hm key ret with
+let hashMap_get_mut_back_lem_aux #t hm key ret =
+ let hm_v = hashMap_t_v hm in
+ hashMap_get_mut_back_lem_refin hm key ret;
+ match hashMap_get_mut_back t hm key ret with
| Fail _ -> assert(False)
| Return hm' ->
- hash_map_insert_no_fail_s_lem hm_v key ret
+ hashMap_insert_no_fail_s_lem hm_v key ret
/// .fsti
-let hash_map_get_mut_back_lem #t hm key ret = hash_map_get_mut_back_lem_aux hm key ret
+let hashMap_get_mut_back_lem #t hm key ret = hashMap_get_mut_back_lem_aux hm key ret
(*** remove'fwd *)
-val hash_map_remove_from_list_fwd_lem
+val hashMap_remove_from_list_lem
(#t : Type0) (key : usize) (ls : list_t t) :
Lemma
(ensures (
- match hash_map_remove_from_list_fwd t key ls with
+ match hashMap_remove_from_list t key ls with
| Fail _ -> False
| Return opt_x ->
opt_x == slot_t_find_s key ls /\
(Some? opt_x ==> length (slot_t_v ls) > 0)))
#push-options "--fuel 1"
-let rec hash_map_remove_from_list_fwd_lem #t key ls =
+let rec hashMap_remove_from_list_lem #t key ls =
begin match ls with
- | ListCons ckey x tl ->
+ | List_Cons ckey x tl ->
let b = ckey = key in
if b
then
- let mv_ls = mem_replace_fwd (list_t t) (ListCons ckey x tl) ListNil in
+ let mv_ls = core_mem_replace (list_t t) (List_Cons ckey x tl) List_Nil in
begin match mv_ls with
- | ListCons i cvalue tl0 -> ()
- | ListNil -> ()
+ | List_Cons i cvalue tl0 -> ()
+ | List_Nil -> ()
end
else
begin
- hash_map_remove_from_list_fwd_lem key tl;
- match hash_map_remove_from_list_fwd t key tl with
+ hashMap_remove_from_list_lem key tl;
+ match hashMap_remove_from_list t key tl with
| Fail _ -> ()
| Return opt -> ()
end
- | ListNil -> ()
+ | List_Nil -> ()
end
#pop-options
-val hash_map_remove_fwd_lem_aux
- (#t : Type0) (self : hash_map_t t) (key : usize) :
+val hashMap_remove_lem_aux
+ (#t : Type0) (self : hashMap_t t) (key : usize) :
Lemma
(requires (
// We need the invariant to prove that upon decrementing the entries counter,
// the counter doesn't become negative
- hash_map_t_inv self))
+ hashMap_t_inv self))
(ensures (
- match hash_map_remove_fwd t self key with
+ match hashMap_remove t self key with
| Fail _ -> False
- | Return opt_x -> opt_x == hash_map_t_find_s self key))
+ | Return opt_x -> opt_x == hashMap_t_find_s self key))
-let hash_map_remove_fwd_lem_aux #t self key =
- begin match hash_key_fwd key with
+let hashMap_remove_lem_aux #t self key =
+ begin match hash_key key with
| Fail _ -> ()
| Return i ->
- let i0 = self.hash_map_num_entries in
- let v = self.hash_map_slots in
- let i1 = vec_len (list_t t) v in
+ let i0 = self.num_entries in
+ let v = self.slots in
+ let i1 = alloc_vec_Vec_len (list_t t) v in
begin match usize_rem i i1 with
| Fail _ -> ()
| Return hash_mod ->
- begin match vec_index_mut_fwd (list_t t) v hash_mod with
+ begin match alloc_vec_Vec_index_usize v hash_mod with
| Fail _ -> ()
| Return l ->
begin
- hash_map_remove_from_list_fwd_lem key l;
- match hash_map_remove_from_list_fwd t key l with
+ hashMap_remove_from_list_lem key l;
+ match hashMap_remove_from_list t key l with
| Fail _ -> ()
| Return x ->
begin match x with
@@ -2945,7 +2945,7 @@ let hash_map_remove_fwd_lem_aux #t self key =
begin
assert(l == index v hash_mod);
assert(length (list_t_v #t l) > 0);
- length_flatten_index (hash_map_t_v self) hash_mod;
+ length_flatten_index (hashMap_t_v self) hash_mod;
match usize_sub i0 1 with
| Fail _ -> ()
| Return _ -> ()
@@ -2957,27 +2957,27 @@ let hash_map_remove_fwd_lem_aux #t self key =
end
/// .fsti
-let hash_map_remove_fwd_lem #t self key = hash_map_remove_fwd_lem_aux #t self key
+let hashMap_remove_lem #t self key = hashMap_remove_lem_aux #t self key
(*** remove'back *)
(**** Refinement proofs *)
/// High-level model for [remove_from_list'back]
-let hash_map_remove_from_list_s
+let hashMap_remove_from_list_s
(#t : Type0) (key : usize) (ls : slot_s t) :
slot_s t =
filter_one (not_same_key key) ls
/// Refinement lemma
-val hash_map_remove_from_list_back_lem_refin
+val hashMap_remove_from_list_back_lem_refin
(#t : Type0) (key : usize) (ls : list_t t) :
Lemma
(ensures (
- match hash_map_remove_from_list_back t key ls with
+ match hashMap_remove_from_list_back t key ls with
| Fail _ -> False
| Return ls' ->
- list_t_v ls' == hash_map_remove_from_list_s key (list_t_v ls) /\
+ list_t_v ls' == hashMap_remove_from_list_s key (list_t_v ls) /\
// The length is decremented, iff the key was in the slot
(let len = length (list_t_v ls) in
let len' = length (list_t_v ls') in
@@ -2986,89 +2986,89 @@ val hash_map_remove_from_list_back_lem_refin
| Some _ -> len = len' + 1)))
#push-options "--fuel 1"
-let rec hash_map_remove_from_list_back_lem_refin #t key ls =
+let rec hashMap_remove_from_list_back_lem_refin #t key ls =
begin match ls with
- | ListCons ckey x tl ->
+ | List_Cons ckey x tl ->
let b = ckey = key in
if b
then
- let mv_ls = mem_replace_fwd (list_t t) (ListCons ckey x tl) ListNil in
+ let mv_ls = core_mem_replace (list_t t) (List_Cons ckey x tl) List_Nil in
begin match mv_ls with
- | ListCons i cvalue tl0 -> ()
- | ListNil -> ()
+ | List_Cons i cvalue tl0 -> ()
+ | List_Nil -> ()
end
else
begin
- hash_map_remove_from_list_back_lem_refin key tl;
- match hash_map_remove_from_list_back t key tl with
+ hashMap_remove_from_list_back_lem_refin key tl;
+ match hashMap_remove_from_list_back t key tl with
| Fail _ -> ()
- | Return l -> let ls0 = ListCons ckey x l in ()
+ | Return l -> let ls0 = List_Cons ckey x l in ()
end
- | ListNil -> ()
+ | List_Nil -> ()
end
#pop-options
/// High-level model for [remove_from_list'back]
-let hash_map_remove_s
- (#t : Type0) (self : hash_map_s_nes t) (key : usize) :
- hash_map_s t =
+let hashMap_remove_s
+ (#t : Type0) (self : hashMap_s_nes t) (key : usize) :
+ hashMap_s t =
let len = length self in
let hash = hash_mod_key key len in
let slot = index self hash in
- let slot' = hash_map_remove_from_list_s key slot in
+ let slot' = hashMap_remove_from_list_s key slot in
list_update self hash slot'
/// Refinement lemma
-val hash_map_remove_back_lem_refin
- (#t : Type0) (self : hash_map_t_nes t) (key : usize) :
+val hashMap_remove_back_lem_refin
+ (#t : Type0) (self : hashMap_t_nes t) (key : usize) :
Lemma
(requires (
// We need the invariant to prove that upon decrementing the entries counter,
// the counter doesn't become negative
- hash_map_t_inv self))
+ hashMap_t_inv self))
(ensures (
- match hash_map_remove_back t self key with
+ match hashMap_remove_back t self key with
| Fail _ -> False
| Return hm' ->
- hash_map_t_same_params hm' self /\
- hash_map_t_v hm' == hash_map_remove_s (hash_map_t_v self) key /\
+ hashMap_t_same_params hm' self /\
+ hashMap_t_v hm' == hashMap_remove_s (hashMap_t_v self) key /\
// The length is decremented iff the key was in the map
- (let len = hash_map_t_len_s self in
- let len' = hash_map_t_len_s hm' in
- match hash_map_t_find_s self key with
+ (let len = hashMap_t_len_s self in
+ let len' = hashMap_t_len_s hm' in
+ match hashMap_t_find_s self key with
| None -> len = len'
| Some _ -> len = len' + 1)))
-let hash_map_remove_back_lem_refin #t self key =
- begin match hash_key_fwd key with
+let hashMap_remove_back_lem_refin #t self key =
+ begin match hash_key key with
| Fail _ -> ()
| Return i ->
- let i0 = self.hash_map_num_entries in
- let p = self.hash_map_max_load_factor in
- let i1 = self.hash_map_max_load in
- let v = self.hash_map_slots in
- let i2 = vec_len (list_t t) v in
+ let i0 = self.num_entries in
+ let p = self.max_load_factor in
+ let i1 = self.max_load in
+ let v = self.slots in
+ let i2 = alloc_vec_Vec_len (list_t t) v in
begin match usize_rem i i2 with
| Fail _ -> ()
| Return hash_mod ->
- begin match vec_index_mut_fwd (list_t t) v hash_mod with
+ begin match alloc_vec_Vec_index_usize v hash_mod with
| Fail _ -> ()
| Return l ->
begin
- hash_map_remove_from_list_fwd_lem key l;
- match hash_map_remove_from_list_fwd t key l with
+ hashMap_remove_from_list_lem key l;
+ match hashMap_remove_from_list t key l with
| Fail _ -> ()
| Return x ->
begin match x with
| None ->
begin
- hash_map_remove_from_list_back_lem_refin key l;
- match hash_map_remove_from_list_back t key l with
+ hashMap_remove_from_list_back_lem_refin key l;
+ match hashMap_remove_from_list_back t key l with
| Fail _ -> ()
| Return l0 ->
begin
length_flatten_update (slots_t_v v) hash_mod (list_t_v l0);
- match vec_index_mut_back (list_t t) v hash_mod l0 with
+ match alloc_vec_Vec_update_usize v hash_mod l0 with
| Fail _ -> ()
| Return v0 -> ()
end
@@ -3077,18 +3077,18 @@ let hash_map_remove_back_lem_refin #t self key =
begin
assert(l == index v hash_mod);
assert(length (list_t_v #t l) > 0);
- length_flatten_index (hash_map_t_v self) hash_mod;
+ length_flatten_index (hashMap_t_v self) hash_mod;
match usize_sub i0 1 with
| Fail _ -> ()
| Return i3 ->
begin
- hash_map_remove_from_list_back_lem_refin key l;
- match hash_map_remove_from_list_back t key l with
+ hashMap_remove_from_list_back_lem_refin key l;
+ match hashMap_remove_from_list_back t key l with
| Fail _ -> ()
| Return l0 ->
begin
length_flatten_update (slots_t_v v) hash_mod (list_t_v l0);
- match vec_index_mut_back (list_t t) v hash_mod l0 with
+ match alloc_vec_Vec_update_usize v hash_mod l0 with
| Fail _ -> ()
| Return v0 -> ()
end
@@ -3102,12 +3102,12 @@ let hash_map_remove_back_lem_refin #t self key =
(**** Invariants, high-level properties *)
-val hash_map_remove_from_list_s_lem
+val hashMap_remove_from_list_s_lem
(#t : Type0) (k : usize) (slot : slot_s t) (len : usize{len > 0}) (i : usize) :
Lemma
(requires (slot_s_inv len i slot))
(ensures (
- let slot' = hash_map_remove_from_list_s k slot in
+ let slot' = hashMap_remove_from_list_s k slot in
slot_s_inv len i slot' /\
slot_s_find k slot' == None /\
(forall (k':key{k' <> k}). slot_s_find k' slot' == slot_s_find k' slot) /\
@@ -3117,14 +3117,14 @@ val hash_map_remove_from_list_s_lem
))
#push-options "--fuel 1"
-let rec hash_map_remove_from_list_s_lem #t key slot len i =
+let rec hashMap_remove_from_list_s_lem #t key slot len i =
match slot with
| [] -> ()
| (k',v) :: slot' ->
if k' <> key then
begin
- hash_map_remove_from_list_s_lem key slot' len i;
- let slot'' = hash_map_remove_from_list_s key slot' in
+ hashMap_remove_from_list_s_lem key slot' len i;
+ let slot'' = hashMap_remove_from_list_s key slot' in
assert(for_all (same_hash_mod_key len i) ((k',v)::slot''));
assert(for_all (binding_neq (k',v)) slot'); // Triggers instanciation
assert(for_all (binding_neq (k',v)) slot'')
@@ -3136,51 +3136,51 @@ let rec hash_map_remove_from_list_s_lem #t key slot len i =
end
#pop-options
-val hash_map_remove_s_lem
- (#t : Type0) (self : hash_map_s_nes t) (key : usize) :
+val hashMap_remove_s_lem
+ (#t : Type0) (self : hashMap_s_nes t) (key : usize) :
Lemma
- (requires (hash_map_s_inv self))
+ (requires (hashMap_s_inv self))
(ensures (
- let hm' = hash_map_remove_s self key in
+ let hm' = hashMap_remove_s self key in
// The invariant is preserved
- hash_map_s_inv hm' /\
+ hashMap_s_inv hm' /\
// We updated the binding
- hash_map_s_updated_binding self key None hm'))
+ hashMap_s_updated_binding self key None hm'))
-let hash_map_remove_s_lem #t self key =
+let hashMap_remove_s_lem #t self key =
let len = length self in
let hash = hash_mod_key key len in
let slot = index self hash in
- hash_map_remove_from_list_s_lem key slot len hash;
- let slot' = hash_map_remove_from_list_s key slot in
+ hashMap_remove_from_list_s_lem key slot len hash;
+ let slot' = hashMap_remove_from_list_s key slot in
let hm' = list_update self hash slot' in
- assert(hash_map_s_inv self)
+ assert(hashMap_s_inv self)
/// Final lemma about [remove'back]
-val hash_map_remove_back_lem_aux
- (#t : Type0) (self : hash_map_t t) (key : usize) :
+val hashMap_remove_back_lem_aux
+ (#t : Type0) (self : hashMap_t t) (key : usize) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_remove_back t self key with
+ match hashMap_remove_back t self key with
| Fail _ -> False
| Return hm' ->
- hash_map_t_inv self /\
- hash_map_t_same_params hm' self /\
+ hashMap_t_inv self /\
+ hashMap_t_same_params hm' self /\
// We updated the binding
- hash_map_s_updated_binding (hash_map_t_v self) key None (hash_map_t_v hm') /\
- hash_map_t_v hm' == hash_map_remove_s (hash_map_t_v self) key /\
+ hashMap_s_updated_binding (hashMap_t_v self) key None (hashMap_t_v hm') /\
+ hashMap_t_v hm' == hashMap_remove_s (hashMap_t_v self) key /\
// The length is decremented iff the key was in the map
- (let len = hash_map_t_len_s self in
- let len' = hash_map_t_len_s hm' in
- match hash_map_t_find_s self key with
+ (let len = hashMap_t_len_s self in
+ let len' = hashMap_t_len_s hm' in
+ match hashMap_t_find_s self key with
| None -> len = len'
| Some _ -> len = len' + 1)))
-let hash_map_remove_back_lem_aux #t self key =
- hash_map_remove_back_lem_refin self key;
- hash_map_remove_s_lem (hash_map_t_v self) key
+let hashMap_remove_back_lem_aux #t self key =
+ hashMap_remove_back_lem_refin self key;
+ hashMap_remove_s_lem (hashMap_t_v self) key
/// .fsti
-let hash_map_remove_back_lem #t self key =
- hash_map_remove_back_lem_aux #t self key
+let hashMap_remove_back_lem #t self key =
+ hashMap_remove_back_lem_aux #t self key
diff --git a/tests/fstar/hashmap/Hashmap.Properties.fsti b/tests/fstar/hashmap/Hashmap.Properties.fsti
index 0a4f0134..26c0ec06 100644
--- a/tests/fstar/hashmap/Hashmap.Properties.fsti
+++ b/tests/fstar/hashmap/Hashmap.Properties.fsti
@@ -18,11 +18,11 @@ type key : eqtype = usize
type hash : eqtype = usize
-val hash_map_t_inv (#t : Type0) (hm : hash_map_t t) : Type0
+val hashMap_t_inv (#t : Type0) (hm : hashMap_t t) : Type0
-val len_s (#t : Type0) (hm : hash_map_t t) : nat
+val len_s (#t : Type0) (hm : hashMap_t t) : nat
-val find_s (#t : Type0) (hm : hash_map_t t) (k : key) : option t
+val find_s (#t : Type0) (hm : hashMap_t t) (k : key) : option t
(*** Overloading *)
@@ -32,16 +32,16 @@ val find_s (#t : Type0) (hm : hash_map_t t) (k : key) : option t
/// limiting the hash collisions.
/// This is expressed by the following property, which is maintained in the hash
/// map invariant.
-val hash_map_not_overloaded_lem (#t : Type0) (hm : hash_map_t t) :
+val hashMap_not_overloaded_lem (#t : Type0) (hm : hashMap_t t) :
Lemma
- (requires (hash_map_t_inv hm))
+ (requires (hashMap_t_inv hm))
(ensures (
// The capacity is the number of slots
- let capacity = length hm.hash_map_slots in
+ let capacity = length hm.slots in
// The max load factor defines a threshold on the number of entries:
// if there are more entries than a given fraction of the number of slots,
// we resize the slots vector to limit the hash collisions
- let (dividend, divisor) = hm.hash_map_max_load_factor in
+ let (dividend, divisor) = hm.max_load_factor in
// technicality: this postcondition won't typecheck if we don't reveal
// that divisor > 0 (because of the division)
divisor > 0 /\
@@ -63,14 +63,14 @@ val hash_map_not_overloaded_lem (#t : Type0) (hm : hash_map_t t) :
(**** [new'fwd] *)
/// [new] doesn't fail and returns an empty hash map
-val hash_map_new_fwd_lem (t : Type0) :
+val hashMap_new_lem (t : Type0) :
Lemma
(ensures (
- match hash_map_new_fwd t with
+ match hashMap_new t with
| Fail _ -> False
| Return hm ->
// The hash map invariant is satisfied
- hash_map_t_inv hm /\
+ hashMap_t_inv hm /\
// The hash map has a length of 0
len_s hm = 0 /\
// It contains no bindings
@@ -79,16 +79,16 @@ val hash_map_new_fwd_lem (t : Type0) :
(**** [clear] *)
/// [clear] doesn't fail and turns the hash map into an empty map
-val hash_map_clear_fwd_back_lem
- (#t : Type0) (self : hash_map_t t) :
+val hashMap_clear_lem
+ (#t : Type0) (self : hashMap_t t) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_clear_fwd_back t self with
+ match hashMap_clear t self with
| Fail _ -> False
| Return hm ->
// The hash map invariant is satisfied
- hash_map_t_inv hm /\
+ hashMap_t_inv hm /\
// The hash map has a length of 0
len_s hm = 0 /\
// It contains no bindings
@@ -97,11 +97,11 @@ val hash_map_clear_fwd_back_lem
(**** [len] *)
/// [len] can't fail and returns the length (the number of elements) of the hash map
-val hash_map_len_fwd_lem (#t : Type0) (self : hash_map_t t) :
+val hashMap_len_lem (#t : Type0) (self : hashMap_t t) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_len_fwd t self with
+ match hashMap_len t self with
| Fail _ -> False
| Return l -> l = len_s self))
@@ -114,12 +114,12 @@ val hash_map_len_fwd_lem (#t : Type0) (self : hash_map_t t) :
/// entirely encompassed by the effect of the backward function alone).
///
/// [insert'fwd_back] simply inserts a binding.
-val hash_map_insert_fwd_back_lem
- (#t : Type0) (self : hash_map_t t) (key : usize) (value : t) :
+val hashMap_insert_lem
+ (#t : Type0) (self : hashMap_t t) (key : usize) (value : t) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_insert_fwd_back t self key value with
+ match hashMap_insert t self key value with
| Fail _ ->
// We can fail only if:
// - the key is not in the map and we thus need to add it
@@ -128,7 +128,7 @@ val hash_map_insert_fwd_back_lem
len_s self = usize_max
| Return hm' ->
// The invariant is preserved
- hash_map_t_inv hm' /\
+ hashMap_t_inv hm' /\
// [key] maps to [value]
find_s hm' key == Some value /\
// The other bindings are preserved
@@ -145,24 +145,24 @@ val hash_map_insert_fwd_back_lem
/// [contains_key'fwd] can't fail and returns `true` if and only if there is
/// a binding for key [key]
-val hash_map_contains_key_fwd_lem
- (#t : Type0) (self : hash_map_t t) (key : usize) :
+val hashMap_contains_key_lem
+ (#t : Type0) (self : hashMap_t t) (key : usize) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_contains_key_fwd t self key with
+ match hashMap_contains_key t self key with
| Fail _ -> False
| Return b -> b = Some? (find_s self key)))
(**** [get'fwd] *)
/// [get] returns (a shared borrow to) the binding for key [key]
-val hash_map_get_fwd_lem
- (#t : Type0) (self : hash_map_t t) (key : usize) :
+val hashMap_get_lem
+ (#t : Type0) (self : hashMap_t t) (key : usize) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_get_fwd t self key, find_s self key with
+ match hashMap_get t self key, find_s self key with
| Fail _, None -> True
| Return x, Some x' -> x == x'
| _ -> False))
@@ -175,12 +175,12 @@ val hash_map_get_fwd_lem
/// in Rust, which gives the possibility of modifying this element in place. Then,
/// upon ending the borrow, the effect of the modification is modelled in the
/// translation through a call to the backward function.
-val hash_map_get_mut_fwd_lem
- (#t : Type0) (self : hash_map_t t) (key : usize) :
+val hashMap_get_mut_lem
+ (#t : Type0) (self : hashMap_t t) (key : usize) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_get_mut_fwd t self key, find_s self key with
+ match hashMap_get_mut t self key, find_s self key with
| Fail _, None -> True
| Return x, Some x' -> x == x'
| _ -> False))
@@ -192,11 +192,11 @@ val hash_map_get_mut_fwd_lem
/// A call to [get_mut'back] must follow a call to [get_mut'fwd], which gives
/// us that there must be a binding for key [key] in the map (otherwise we
/// can't prove the absence of failure).
-val hash_map_get_mut_back_lem
- (#t : Type0) (hm : hash_map_t t) (key : usize) (ret : t) :
+val hashMap_get_mut_back_lem
+ (#t : Type0) (hm : hashMap_t t) (key : usize) (ret : t) :
Lemma
(requires (
- hash_map_t_inv hm /\
+ hashMap_t_inv hm /\
// A call to the backward function must follow a call to the forward
// function, whose success gives us that there is a binding for the key.
// In the case of *forward* functions, "success" has to be understood as
@@ -207,14 +207,14 @@ val hash_map_get_mut_back_lem
// "failure" is to be understood as the semantics getting stuck.
// This is of course true unless we filtered the call to the forward function
// because its effect is encompassed by the backward function, as with
- // [hash_map_clear_fwd_back]).
+ // [hashMap_clear]).
Some? (find_s hm key)))
(ensures (
- match hash_map_get_mut_back t hm key ret with
+ match hashMap_get_mut_back t hm key ret with
| Fail _ -> False // Can't fail
| Return hm' ->
// The invariant is preserved
- hash_map_t_inv hm' /\
+ hashMap_t_inv hm' /\
// The length is preserved
len_s hm' = len_s hm /\
// [key] maps to the update value, [ret]
@@ -228,12 +228,12 @@ val hash_map_get_mut_back_lem
/// (the rust function *moves* it out of the map). Note that the effect of the update
/// on the map is modelles through the call to [remove'back] ([remove] takes a
/// mutable borrow to the hash map as parameter).
-val hash_map_remove_fwd_lem
- (#t : Type0) (self : hash_map_t t) (key : usize) :
+val hashMap_remove_lem
+ (#t : Type0) (self : hashMap_t t) (key : usize) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_remove_fwd t self key with
+ match hashMap_remove t self key with
| Fail _ -> False
| Return opt_x -> opt_x == find_s self key))
@@ -243,16 +243,16 @@ val hash_map_remove_fwd_lem
/// The hash map given as parameter to [remove] is given through a mutable borrow:
/// hence the backward function which gives back the updated map, without the
/// binding.
-val hash_map_remove_back_lem
- (#t : Type0) (self : hash_map_t t) (key : usize) :
+val hashMap_remove_back_lem
+ (#t : Type0) (self : hashMap_t t) (key : usize) :
Lemma
- (requires (hash_map_t_inv self))
+ (requires (hashMap_t_inv self))
(ensures (
- match hash_map_remove_back t self key with
+ match hashMap_remove_back t self key with
| Fail _ -> False
| Return hm' ->
// The invariant is preserved
- hash_map_t_inv self /\
+ hashMap_t_inv self /\
// The binding for [key] is not there anymore
find_s hm' key == None /\
// The other bindings are preserved
diff --git a/tests/fstar/hashmap/Hashmap.Types.fst b/tests/fstar/hashmap/Hashmap.Types.fst
index 91ee26c6..753730fe 100644
--- a/tests/fstar/hashmap/Hashmap.Types.fst
+++ b/tests/fstar/hashmap/Hashmap.Types.fst
@@ -7,15 +7,15 @@ open Primitives
(** [hashmap::List] *)
type list_t (t : Type0) =
-| ListCons : usize -> t -> list_t t -> list_t t
-| ListNil : list_t t
+| List_Cons : usize -> t -> list_t t -> list_t t
+| List_Nil : list_t t
(** [hashmap::HashMap] *)
-type hash_map_t (t : Type0) =
+type hashMap_t (t : Type0) =
{
- hash_map_num_entries : usize;
- hash_map_max_load_factor : (usize & usize);
- hash_map_max_load : usize;
- hash_map_slots : vec (list_t t);
+ num_entries : usize;
+ max_load_factor : (usize & usize);
+ max_load : usize;
+ slots : alloc_vec_Vec (list_t t);
}
diff --git a/tests/fstar/hashmap/Primitives.fst b/tests/fstar/hashmap/Primitives.fst
index 9db82069..3297803c 100644
--- a/tests/fstar/hashmap/Primitives.fst
+++ b/tests/fstar/hashmap/Primitives.fst
@@ -55,8 +55,12 @@ type string = string
let is_zero (n: nat) : bool = n = 0
let decrease (n: nat{n > 0}) : nat = n - 1
-let mem_replace_fwd (a : Type0) (x : a) (y : a) : a = x
-let mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+let core_mem_replace (a : Type0) (x : a) (y : a) : a = x
+let core_mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+
+// We don't really use raw pointers for now
+type mut_raw_ptr (t : Type0) = { v : t }
+type const_raw_ptr (t : Type0) = { v : t }
(*** Scalars *)
/// Rem.: most of the following code was partially generated
@@ -100,6 +104,11 @@ type scalar_ty =
| U64
| U128
+let is_unsigned = function
+ | Isize | I8 | I16 | I32 | I64 | I128 -> false
+ | Usize | U8 | U16 | U32 | U64 | U128 -> true
+
+
let scalar_min (ty : scalar_ty) : int =
match ty with
| Isize -> isize_min
@@ -162,6 +171,15 @@ let scalar_sub (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scala
let scalar_mul (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
mk_scalar ty (x * y)
+let scalar_lxor (#ty : scalar_ty { is_unsigned ty && ty <> Usize })
+ (x : scalar ty) (y : scalar ty) : scalar ty =
+ match ty with
+ | U8 -> FStar.UInt.logxor #8 x y
+ | U16 -> FStar.UInt.logxor #16 x y
+ | U32 -> FStar.UInt.logxor #32 x y
+ | U64 -> FStar.UInt.logxor #64 x y
+ | U128 -> FStar.UInt.logxor #128 x y
+
(** Cast an integer from a [src_ty] to a [tgt_ty] *)
// TODO: check the semantics of casts in Rust
let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) =
@@ -169,17 +187,44 @@ let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) :
/// The scalar types
type isize : eqtype = scalar Isize
-type i8 : eqtype = scalar I8
-type i16 : eqtype = scalar I16
-type i32 : eqtype = scalar I32
-type i64 : eqtype = scalar I64
-type i128 : eqtype = scalar I128
+type i8 : eqtype = scalar I8
+type i16 : eqtype = scalar I16
+type i32 : eqtype = scalar I32
+type i64 : eqtype = scalar I64
+type i128 : eqtype = scalar I128
type usize : eqtype = scalar Usize
-type u8 : eqtype = scalar U8
-type u16 : eqtype = scalar U16
-type u32 : eqtype = scalar U32
-type u64 : eqtype = scalar U64
-type u128 : eqtype = scalar U128
+type u8 : eqtype = scalar U8
+type u16 : eqtype = scalar U16
+type u32 : eqtype = scalar U32
+type u64 : eqtype = scalar U64
+type u128 : eqtype = scalar U128
+
+
+let core_isize_min : isize = isize_min
+let core_isize_max : isize = isize_max
+let core_i8_min : i8 = i8_min
+let core_i8_max : i8 = i8_max
+let core_i16_min : i16 = i16_min
+let core_i16_max : i16 = i16_max
+let core_i32_min : i32 = i32_min
+let core_i32_max : i32 = i32_max
+let core_i64_min : i64 = i64_min
+let core_i64_max : i64 = i64_max
+let core_i128_min : i128 = i128_min
+let core_i128_max : i128 = i128_max
+
+let core_usize_min : usize = usize_min
+let core_usize_max : usize = usize_max
+let core_u8_min : u8 = u8_min
+let core_u8_max : u8 = u8_max
+let core_u16_min : u16 = u16_min
+let core_u16_max : u16 = u16_max
+let core_u32_min : u32 = u32_min
+let core_u32_max : u32 = u32_max
+let core_u64_min : u64 = u64_min
+let core_u64_max : u64 = u64_max
+let core_u128_min : u128 = u128_min
+let core_u128_max : u128 = u128_max
/// Negation
let isize_neg = scalar_neg #Isize
@@ -231,7 +276,7 @@ let u32_add = scalar_add #U32
let u64_add = scalar_add #U64
let u128_add = scalar_add #U128
-/// Substraction
+/// Subtraction
let isize_sub = scalar_sub #Isize
let i8_sub = scalar_sub #I8
let i16_sub = scalar_sub #I16
@@ -259,12 +304,65 @@ let u32_mul = scalar_mul #U32
let u64_mul = scalar_mul #U64
let u128_mul = scalar_mul #U128
-(*** Range *)
-type range (a : Type0) = {
+/// Logical operators, defined for unsigned types only, so far
+let u8_xor = scalar_lxor #U8
+let u16_xor = scalar_lxor #U16
+let u32_xor = scalar_lxor #U32
+let u64_xor = scalar_lxor #U64
+let u128_xor = scalar_lxor #U128
+
+(*** core::ops *)
+
+// Trait declaration: [core::ops::index::Index]
+noeq type core_ops_index_Index (self idx : Type0) = {
+ output : Type0;
+ index : self → idx → result output
+}
+
+// Trait declaration: [core::ops::index::IndexMut]
+noeq type core_ops_index_IndexMut (self idx : Type0) = {
+ indexInst : core_ops_index_Index self idx;
+ index_mut : self → idx → result indexInst.output;
+ index_mut_back : self → idx → indexInst.output → result self;
+}
+
+// Trait declaration [core::ops::deref::Deref]
+noeq type core_ops_deref_Deref (self : Type0) = {
+ target : Type0;
+ deref : self → result target;
+}
+
+// Trait declaration [core::ops::deref::DerefMut]
+noeq type core_ops_deref_DerefMut (self : Type0) = {
+ derefInst : core_ops_deref_Deref self;
+ deref_mut : self → result derefInst.target;
+ deref_mut_back : self → derefInst.target → result self;
+}
+
+type core_ops_range_Range (a : Type0) = {
start : a;
end_ : a;
}
+(*** [alloc] *)
+
+let alloc_boxed_Box_deref (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut_back (t : Type) (_ : t) (x : t) : result t = Return x
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefInst (self : Type0) : core_ops_deref_Deref self = {
+ target = self;
+ deref = alloc_boxed_Box_deref self;
+}
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefMutInst (self : Type0) : core_ops_deref_DerefMut self = {
+ derefInst = alloc_boxed_Box_coreOpsDerefInst self;
+ deref_mut = alloc_boxed_Box_deref_mut self;
+ deref_mut_back = alloc_boxed_Box_deref_mut_back self;
+}
+
(*** Array *)
type array (a : Type0) (n : usize) = s:list a{length s = n}
@@ -278,15 +376,11 @@ let mk_array (a : Type0) (n : usize)
normalize_term_spec (FStar.List.Tot.length l);
l
-let array_index_shared (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let array_index_mut_fwd (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
+let array_index_usize (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let array_index_mut_back (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
+let array_update_usize (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
if i < length x then Return (list_update x i nx)
else Fail Failure
@@ -295,55 +389,54 @@ type slice (a : Type0) = s:list a{length s <= usize_max}
let slice_len (a : Type0) (s : slice a) : usize = length s
-let slice_index_shared (a : Type0) (x : slice a) (i : usize) : result a =
+let slice_index_usize (a : Type0) (x : slice a) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let slice_index_mut_fwd (a : Type0) (x : slice a) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let slice_index_mut_back (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
+let slice_update_usize (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
if i < length x then Return (list_update x i nx)
else Fail Failure
(*** Subslices *)
-let array_to_slice_shared (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_fwd (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_back (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
+let array_to_slice (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
+let array_from_slice (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
if length s = n then Return s
else Fail Failure
// TODO: finish the definitions below (there lacks [List.drop] and [List.take] in the standard library *)
-let array_subslice_shared (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
- admit()
-
-let array_subslice_mut_fwd (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
+let array_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let array_subslice_mut_back (a : Type0) (n : usize) (x : array a n) (r : range usize) (ns : slice a) : result (array a n) =
+let array_update_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) (ns : slice a) : result (array a n) =
admit()
-let slice_subslice_shared (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let array_repeat (a : Type0) (n : usize) (x : a) : array a n =
admit()
-let slice_subslice_mut_fwd (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let slice_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let slice_subslice_mut_back (a : Type0) (x : slice a) (r : range usize) (ns : slice a) : result (slice a) =
+let slice_update_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) (ns : slice a) : result (slice a) =
admit()
(*** Vector *)
-type vec (a : Type0) = v:list a{length v <= usize_max}
+type alloc_vec_Vec (a : Type0) = v:list a{length v <= usize_max}
-let vec_new (a : Type0) : vec a = assert_norm(length #a [] == 0); []
-let vec_len (a : Type0) (v : vec a) : usize = length v
+let alloc_vec_Vec_new (a : Type0) : alloc_vec_Vec a = assert_norm(length #a [] == 0); []
+let alloc_vec_Vec_len (a : Type0) (v : alloc_vec_Vec a) : usize = length v
+
+// Helper
+let alloc_vec_Vec_index_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) : result a =
+ if i < length v then Return (index v i) else Fail Failure
+// Helper
+let alloc_vec_Vec_update_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
// The **forward** function shouldn't be used
-let vec_push_fwd (a : Type0) (v : vec a) (x : a) : unit = ()
-let vec_push_back (a : Type0) (v : vec a) (x : a) :
- Pure (result (vec a))
+let alloc_vec_Vec_push_fwd (a : Type0) (v : alloc_vec_Vec a) (x : a) : unit = ()
+let alloc_vec_Vec_push (a : Type0) (v : alloc_vec_Vec a) (x : a) :
+ Pure (result (alloc_vec_Vec a))
(requires True)
(ensures (fun res ->
match res with
@@ -358,18 +451,279 @@ let vec_push_back (a : Type0) (v : vec a) (x : a) :
else Fail Failure
// The **forward** function shouldn't be used
-let vec_insert_fwd (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
+let alloc_vec_Vec_insert_fwd (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result unit =
if i < length v then Return () else Fail Failure
-let vec_insert_back (a : Type0) (v : vec a) (i : usize) (x : a) : result (vec a) =
+let alloc_vec_Vec_insert (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
if i < length v then Return (list_update v i x) else Fail Failure
-// The **backward** function shouldn't be used
-let vec_index_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_back (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
- if i < length v then Return () else Fail Failure
+// Trait declaration: [core::slice::index::private_slice_index::Sealed]
+type core_slice_index_private_slice_index_Sealed (self : Type0) = unit
+
+// Trait declaration: [core::slice::index::SliceIndex]
+noeq type core_slice_index_SliceIndex (self t : Type0) = {
+ sealedInst : core_slice_index_private_slice_index_Sealed self;
+ output : Type0;
+ get : self → t → result (option output);
+ get_mut : self → t → result (option output);
+ get_mut_back : self → t → option output → result t;
+ get_unchecked : self → const_raw_ptr t → result (const_raw_ptr output);
+ get_unchecked_mut : self → mut_raw_ptr t → result (mut_raw_ptr output);
+ index : self → t → result output;
+ index_mut : self → t → result output;
+ index_mut_back : self → t → output → result t;
+}
-let vec_index_mut_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_mut_back (a : Type0) (v : vec a) (i : usize) (nx : a) : result (vec a) =
- if i < length v then Return (list_update v i nx) else Fail Failure
+// [core::slice::index::[T]::index]: forward function
+let core_slice_index_Slice_index
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (s : slice t) (i : idx) : result inst.output =
+ let* x = inst.get i s in
+ match x with
+ | None -> Fail Failure
+ | Some x -> Return x
+
+// [core::slice::index::Range:::get]: forward function
+let core_slice_index_Range_get (t : Type0) (i : core_ops_range_Range usize) (s : slice t) :
+ result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: forward function
+let core_slice_index_Range_get_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: backward function 0
+let core_slice_index_Range_get_mut_back
+ (t : Type0) :
+ core_ops_range_Range usize → slice t → option (slice t) → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_unchecked]: forward function
+let core_slice_index_Range_get_unchecked
+ (t : Type0) :
+ core_ops_range_Range usize → const_raw_ptr (slice t) → result (const_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::get_unchecked_mut]: forward function
+let core_slice_index_Range_get_unchecked_mut
+ (t : Type0) :
+ core_ops_range_Range usize → mut_raw_ptr (slice t) → result (mut_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::index]: forward function
+let core_slice_index_Range_index
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: forward function
+let core_slice_index_Range_index_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: backward function 0
+let core_slice_index_Range_index_mut_back
+ (t : Type0) : core_ops_range_Range usize → slice t → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::[T]::index_mut]: forward function
+let core_slice_index_Slice_index_mut
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → result inst.output =
+ admit () //
+
+// [core::slice::index::[T]::index_mut]: backward function 0
+let core_slice_index_Slice_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → inst.output → result (slice t) =
+ admit () // TODO
+
+// [core::array::[T; N]::index]: forward function
+let core_array_Array_index
+ (t idx : Type0) (n : usize) (inst : core_ops_index_Index (slice t) idx)
+ (a : array t n) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: forward function
+let core_array_Array_index_mut
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) : result inst.indexInst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: backward function 0
+let core_array_Array_index_mut_back
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) (x : inst.indexInst.output) : result (array t n) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (slice t) idx = {
+ output = inst.output;
+ index = core_slice_index_Slice_index t idx inst;
+}
+
+// Trait implementation: [core::slice::index::private_slice_index::Range]
+let core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) = ()
+
+// Trait implementation: [core::slice::index::Range]
+let core_slice_index_Range_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ output = slice t;
+ get = core_slice_index_Range_get t;
+ get_mut = core_slice_index_Range_get_mut t;
+ get_mut_back = core_slice_index_Range_get_mut_back t;
+ get_unchecked = core_slice_index_Range_get_unchecked t;
+ get_unchecked_mut = core_slice_index_Range_get_unchecked_mut t;
+ index = core_slice_index_Range_index t;
+ index_mut = core_slice_index_Range_index_mut t;
+ index_mut_back = core_slice_index_Range_index_mut_back t;
+}
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (slice t) idx = {
+ indexInst = core_slice_index_Slice_coreopsindexIndexInst t idx inst;
+ index_mut = core_slice_index_Slice_index_mut t idx inst;
+ index_mut_back = core_slice_index_Slice_index_mut_back t idx inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_Index (slice t) idx) :
+ core_ops_index_Index (array t n) idx = {
+ output = inst.output;
+ index = core_array_Array_index t idx n inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexMutInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_IndexMut (slice t) idx) :
+ core_ops_index_IndexMut (array t n) idx = {
+ indexInst = core_array_Array_coreopsindexIndexInst t idx n inst.indexInst;
+ index_mut = core_array_Array_index_mut t idx n inst;
+ index_mut_back = core_array_Array_index_mut_back t idx n inst;
+}
+
+// [core::slice::index::usize::get]: forward function
+let core_slice_index_usize_get
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: forward function
+let core_slice_index_usize_get_mut
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: backward function 0
+let core_slice_index_usize_get_mut_back
+ (t : Type0) : usize → slice t → option t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked]: forward function
+let core_slice_index_usize_get_unchecked
+ (t : Type0) : usize → const_raw_ptr (slice t) → result (const_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked_mut]: forward function
+let core_slice_index_usize_get_unchecked_mut
+ (t : Type0) : usize → mut_raw_ptr (slice t) → result (mut_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::index]: forward function
+let core_slice_index_usize_index (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: forward function
+let core_slice_index_usize_index_mut (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: backward function 0
+let core_slice_index_usize_index_mut_back
+ (t : Type0) : usize → slice t → t → result (slice t) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::private_slice_index::usize]
+let core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize = ()
+
+// Trait implementation: [core::slice::index::usize]
+let core_slice_index_usize_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex usize (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ output = t;
+ get = core_slice_index_usize_get t;
+ get_mut = core_slice_index_usize_get_mut t;
+ get_mut_back = core_slice_index_usize_get_mut_back t;
+ get_unchecked = core_slice_index_usize_get_unchecked t;
+ get_unchecked_mut = core_slice_index_usize_get_unchecked_mut t;
+ index = core_slice_index_usize_index t;
+ index_mut = core_slice_index_usize_index_mut t;
+ index_mut_back = core_slice_index_usize_index_mut_back t;
+}
+
+// [alloc::vec::Vec::index]: forward function
+let alloc_vec_Vec_index (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: forward function
+let alloc_vec_Vec_index_mut (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: backward function 0
+let alloc_vec_Vec_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) (x : inst.output) : result (alloc_vec_Vec t) =
+ admit () // TODO
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (alloc_vec_Vec t) idx = {
+ output = inst.output;
+ index = alloc_vec_Vec_index t idx inst;
+}
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (alloc_vec_Vec t) idx = {
+ indexInst = alloc_vec_Vec_coreopsindexIndexInst t idx inst;
+ index_mut = alloc_vec_Vec_index_mut t idx inst;
+ index_mut_back = alloc_vec_Vec_index_mut_back t idx inst;
+}
+
+(*** Theorems *)
+
+let alloc_vec_Vec_index_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_back_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) :
+ Lemma (
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x ==
+ alloc_vec_Vec_update_usize v i x)
+ [SMTPat (alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x)]
+ =
+ admit()
diff --git a/tests/fstar/hashmap_on_disk/HashmapMain.Clauses.Template.fst b/tests/fstar/hashmap_on_disk/HashmapMain.Clauses.Template.fst
index 615c670d..61885ac7 100644
--- a/tests/fstar/hashmap_on_disk/HashmapMain.Clauses.Template.fst
+++ b/tests/fstar/hashmap_on_disk/HashmapMain.Clauses.Template.fst
@@ -8,56 +8,56 @@ open HashmapMain.Types
(** [hashmap_main::hashmap::HashMap::{0}::allocate_slots]: decreases clause *)
unfold
-let hashmap_hash_map_allocate_slots_loop_decreases (t : Type0)
- (slots : vec (hashmap_list_t t)) (n : usize) : nat =
+let hashmap_HashMap_allocate_slots_loop_decreases (t : Type0)
+ (slots : alloc_vec_Vec (hashmap_List_t t)) (n : usize) : nat =
admit ()
(** [hashmap_main::hashmap::HashMap::{0}::clear]: decreases clause *)
unfold
-let hashmap_hash_map_clear_loop_decreases (t : Type0)
- (slots : vec (hashmap_list_t t)) (i : usize) : nat =
+let hashmap_HashMap_clear_loop_decreases (t : Type0)
+ (slots : alloc_vec_Vec (hashmap_List_t t)) (i : usize) : nat =
admit ()
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: decreases clause *)
unfold
-let hashmap_hash_map_insert_in_list_loop_decreases (t : Type0) (key : usize)
- (value : t) (ls : hashmap_list_t t) : nat =
+let hashmap_HashMap_insert_in_list_loop_decreases (t : Type0) (key : usize)
+ (value : t) (ls : hashmap_List_t t) : nat =
admit ()
(** [hashmap_main::hashmap::HashMap::{0}::move_elements_from_list]: decreases clause *)
unfold
-let hashmap_hash_map_move_elements_from_list_loop_decreases (t : Type0)
- (ntable : hashmap_hash_map_t t) (ls : hashmap_list_t t) : nat =
+let hashmap_HashMap_move_elements_from_list_loop_decreases (t : Type0)
+ (ntable : hashmap_HashMap_t t) (ls : hashmap_List_t t) : nat =
admit ()
(** [hashmap_main::hashmap::HashMap::{0}::move_elements]: decreases clause *)
unfold
-let hashmap_hash_map_move_elements_loop_decreases (t : Type0)
- (ntable : hashmap_hash_map_t t) (slots : vec (hashmap_list_t t)) (i : usize)
- : nat =
+let hashmap_HashMap_move_elements_loop_decreases (t : Type0)
+ (ntable : hashmap_HashMap_t t) (slots : alloc_vec_Vec (hashmap_List_t t))
+ (i : usize) : nat =
admit ()
(** [hashmap_main::hashmap::HashMap::{0}::contains_key_in_list]: decreases clause *)
unfold
-let hashmap_hash_map_contains_key_in_list_loop_decreases (t : Type0)
- (key : usize) (ls : hashmap_list_t t) : nat =
+let hashmap_HashMap_contains_key_in_list_loop_decreases (t : Type0)
+ (key : usize) (ls : hashmap_List_t t) : nat =
admit ()
(** [hashmap_main::hashmap::HashMap::{0}::get_in_list]: decreases clause *)
unfold
-let hashmap_hash_map_get_in_list_loop_decreases (t : Type0) (key : usize)
- (ls : hashmap_list_t t) : nat =
+let hashmap_HashMap_get_in_list_loop_decreases (t : Type0) (key : usize)
+ (ls : hashmap_List_t t) : nat =
admit ()
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: decreases clause *)
unfold
-let hashmap_hash_map_get_mut_in_list_loop_decreases (t : Type0)
- (ls : hashmap_list_t t) (key : usize) : nat =
+let hashmap_HashMap_get_mut_in_list_loop_decreases (t : Type0)
+ (ls : hashmap_List_t t) (key : usize) : nat =
admit ()
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: decreases clause *)
unfold
-let hashmap_hash_map_remove_from_list_loop_decreases (t : Type0) (key : usize)
- (ls : hashmap_list_t t) : nat =
+let hashmap_HashMap_remove_from_list_loop_decreases (t : Type0) (key : usize)
+ (ls : hashmap_List_t t) : nat =
admit ()
diff --git a/tests/fstar/hashmap_on_disk/HashmapMain.Clauses.fst b/tests/fstar/hashmap_on_disk/HashmapMain.Clauses.fst
index 699ff3b2..be5a4ab1 100644
--- a/tests/fstar/hashmap_on_disk/HashmapMain.Clauses.fst
+++ b/tests/fstar/hashmap_on_disk/HashmapMain.Clauses.fst
@@ -8,54 +8,54 @@ open HashmapMain.Types
(** [hashmap::HashMap::allocate_slots]: decreases clause *)
unfold
-let hashmap_hash_map_allocate_slots_loop_decreases (t : Type0) (slots : vec (hashmap_list_t t))
+let hashmap_HashMap_allocate_slots_loop_decreases (t : Type0) (slots : alloc_vec_Vec (hashmap_List_t t))
(n : usize) : nat = n
(** [hashmap::HashMap::clear]: decreases clause *)
unfold
-let hashmap_hash_map_clear_loop_decreases (t : Type0) (slots : vec (hashmap_list_t t))
+let hashmap_HashMap_clear_loop_decreases (t : Type0) (slots : alloc_vec_Vec (hashmap_List_t t))
(i : usize) : nat =
if i < length slots then length slots - i else 0
(** [hashmap::HashMap::insert_in_list]: decreases clause *)
unfold
-let hashmap_hash_map_insert_in_list_loop_decreases (t : Type0) (key : usize) (value : t)
- (ls : hashmap_list_t t) : hashmap_list_t t =
+let hashmap_HashMap_insert_in_list_loop_decreases (t : Type0) (key : usize) (value : t)
+ (ls : hashmap_List_t t) : hashmap_List_t t =
ls
(** [hashmap::HashMap::move_elements_from_list]: decreases clause *)
unfold
-let hashmap_hash_map_move_elements_from_list_loop_decreases (t : Type0)
- (ntable : hashmap_hash_map_t t) (ls : hashmap_list_t t) : hashmap_list_t t =
+let hashmap_HashMap_move_elements_from_list_loop_decreases (t : Type0)
+ (ntable : hashmap_HashMap_t t) (ls : hashmap_List_t t) : hashmap_List_t t =
ls
(** [hashmap::HashMap::move_elements]: decreases clause *)
unfold
-let hashmap_hash_map_move_elements_loop_decreases (t : Type0) (ntable : hashmap_hash_map_t t)
- (slots : vec (hashmap_list_t t)) (i : usize) : nat =
+let hashmap_HashMap_move_elements_loop_decreases (t : Type0) (ntable : hashmap_HashMap_t t)
+ (slots : alloc_vec_Vec (hashmap_List_t t)) (i : usize) : nat =
if i < length slots then length slots - i else 0
(** [hashmap::HashMap::contains_key_in_list]: decreases clause *)
unfold
-let hashmap_hash_map_contains_key_in_list_loop_decreases (t : Type0) (key : usize)
- (ls : hashmap_list_t t) : hashmap_list_t t =
+let hashmap_HashMap_contains_key_in_list_loop_decreases (t : Type0) (key : usize)
+ (ls : hashmap_List_t t) : hashmap_List_t t =
ls
(** [hashmap::HashMap::get_in_list]: decreases clause *)
unfold
-let hashmap_hash_map_get_in_list_loop_decreases (t : Type0) (key : usize) (ls : hashmap_list_t t) :
- hashmap_list_t t =
+let hashmap_HashMap_get_in_list_loop_decreases (t : Type0) (key : usize) (ls : hashmap_List_t t) :
+ hashmap_List_t t =
ls
(** [hashmap::HashMap::get_mut_in_list]: decreases clause *)
unfold
-let hashmap_hash_map_get_mut_in_list_loop_decreases (t : Type0)
- (ls : hashmap_list_t t) (key : usize) : hashmap_list_t t =
+let hashmap_HashMap_get_mut_in_list_loop_decreases (t : Type0)
+ (ls : hashmap_List_t t) (key : usize) : hashmap_List_t t =
ls
(** [hashmap::HashMap::remove_from_list]: decreases clause *)
unfold
-let hashmap_hash_map_remove_from_list_loop_decreases (t : Type0) (key : usize)
- (ls : hashmap_list_t t) : hashmap_list_t t =
+let hashmap_HashMap_remove_from_list_loop_decreases (t : Type0) (key : usize)
+ (ls : hashmap_List_t t) : hashmap_List_t t =
ls
diff --git a/tests/fstar/hashmap_on_disk/HashmapMain.Funs.fst b/tests/fstar/hashmap_on_disk/HashmapMain.Funs.fst
index 1c94209c..5f227596 100644
--- a/tests/fstar/hashmap_on_disk/HashmapMain.Funs.fst
+++ b/tests/fstar/hashmap_on_disk/HashmapMain.Funs.fst
@@ -9,529 +9,528 @@ include HashmapMain.Clauses
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [hashmap_main::hashmap::hash_key]: forward function *)
-let hashmap_hash_key_fwd (k : usize) : result usize =
+let hashmap_hash_key (k : usize) : result usize =
Return k
(** [hashmap_main::hashmap::HashMap::{0}::allocate_slots]: loop 0: forward function *)
-let rec hashmap_hash_map_allocate_slots_loop_fwd
- (t : Type0) (slots : vec (hashmap_list_t t)) (n : usize) :
- Tot (result (vec (hashmap_list_t t)))
- (decreases (hashmap_hash_map_allocate_slots_loop_decreases t slots n))
+let rec hashmap_HashMap_allocate_slots_loop
+ (t : Type0) (slots : alloc_vec_Vec (hashmap_List_t t)) (n : usize) :
+ Tot (result (alloc_vec_Vec (hashmap_List_t t)))
+ (decreases (hashmap_HashMap_allocate_slots_loop_decreases t slots n))
=
if n > 0
then
- let* slots0 = vec_push_back (hashmap_list_t t) slots HashmapListNil in
+ let* slots0 = alloc_vec_Vec_push (hashmap_List_t t) slots Hashmap_List_Nil
+ in
let* n0 = usize_sub n 1 in
- hashmap_hash_map_allocate_slots_loop_fwd t slots0 n0
+ hashmap_HashMap_allocate_slots_loop t slots0 n0
else Return slots
(** [hashmap_main::hashmap::HashMap::{0}::allocate_slots]: forward function *)
-let hashmap_hash_map_allocate_slots_fwd
- (t : Type0) (slots : vec (hashmap_list_t t)) (n : usize) :
- result (vec (hashmap_list_t t))
+let hashmap_HashMap_allocate_slots
+ (t : Type0) (slots : alloc_vec_Vec (hashmap_List_t t)) (n : usize) :
+ result (alloc_vec_Vec (hashmap_List_t t))
=
- hashmap_hash_map_allocate_slots_loop_fwd t slots n
+ hashmap_HashMap_allocate_slots_loop t slots n
(** [hashmap_main::hashmap::HashMap::{0}::new_with_capacity]: forward function *)
-let hashmap_hash_map_new_with_capacity_fwd
+let hashmap_HashMap_new_with_capacity
(t : Type0) (capacity : usize) (max_load_dividend : usize)
(max_load_divisor : usize) :
- result (hashmap_hash_map_t t)
+ result (hashmap_HashMap_t t)
=
- let v = vec_new (hashmap_list_t t) in
- let* slots = hashmap_hash_map_allocate_slots_fwd t v capacity in
+ let v = alloc_vec_Vec_new (hashmap_List_t t) in
+ let* slots = hashmap_HashMap_allocate_slots t v capacity in
let* i = usize_mul capacity max_load_dividend in
let* i0 = usize_div i max_load_divisor in
Return
{
- hashmap_hash_map_num_entries = 0;
- hashmap_hash_map_max_load_factor = (max_load_dividend, max_load_divisor);
- hashmap_hash_map_max_load = i0;
- hashmap_hash_map_slots = slots
+ num_entries = 0;
+ max_load_factor = (max_load_dividend, max_load_divisor);
+ max_load = i0;
+ slots = slots
}
(** [hashmap_main::hashmap::HashMap::{0}::new]: forward function *)
-let hashmap_hash_map_new_fwd (t : Type0) : result (hashmap_hash_map_t t) =
- hashmap_hash_map_new_with_capacity_fwd t 32 4 5
+let hashmap_HashMap_new (t : Type0) : result (hashmap_HashMap_t t) =
+ hashmap_HashMap_new_with_capacity t 32 4 5
(** [hashmap_main::hashmap::HashMap::{0}::clear]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec hashmap_hash_map_clear_loop_fwd_back
- (t : Type0) (slots : vec (hashmap_list_t t)) (i : usize) :
- Tot (result (vec (hashmap_list_t t)))
- (decreases (hashmap_hash_map_clear_loop_decreases t slots i))
+let rec hashmap_HashMap_clear_loop
+ (t : Type0) (slots : alloc_vec_Vec (hashmap_List_t t)) (i : usize) :
+ Tot (result (alloc_vec_Vec (hashmap_List_t t)))
+ (decreases (hashmap_HashMap_clear_loop_decreases t slots i))
=
- let i0 = vec_len (hashmap_list_t t) slots in
+ let i0 = alloc_vec_Vec_len (hashmap_List_t t) slots in
if i < i0
then
let* i1 = usize_add i 1 in
- let* slots0 = vec_index_mut_back (hashmap_list_t t) slots i HashmapListNil
- in
- hashmap_hash_map_clear_loop_fwd_back t slots0 i1
+ let* slots0 =
+ alloc_vec_Vec_index_mut_back (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ t)) slots i Hashmap_List_Nil in
+ hashmap_HashMap_clear_loop t slots0 i1
else Return slots
(** [hashmap_main::hashmap::HashMap::{0}::clear]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hashmap_hash_map_clear_fwd_back
- (t : Type0) (self : hashmap_hash_map_t t) : result (hashmap_hash_map_t t) =
- let* v = hashmap_hash_map_clear_loop_fwd_back t self.hashmap_hash_map_slots 0
- in
- Return
- { self with hashmap_hash_map_num_entries = 0; hashmap_hash_map_slots = v }
+let hashmap_HashMap_clear
+ (t : Type0) (self : hashmap_HashMap_t t) : result (hashmap_HashMap_t t) =
+ let* v = hashmap_HashMap_clear_loop t self.slots 0 in
+ Return { self with num_entries = 0; slots = v }
(** [hashmap_main::hashmap::HashMap::{0}::len]: forward function *)
-let hashmap_hash_map_len_fwd
- (t : Type0) (self : hashmap_hash_map_t t) : result usize =
- Return self.hashmap_hash_map_num_entries
+let hashmap_HashMap_len
+ (t : Type0) (self : hashmap_HashMap_t t) : result usize =
+ Return self.num_entries
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: loop 0: forward function *)
-let rec hashmap_hash_map_insert_in_list_loop_fwd
- (t : Type0) (key : usize) (value : t) (ls : hashmap_list_t t) :
+let rec hashmap_HashMap_insert_in_list_loop
+ (t : Type0) (key : usize) (value : t) (ls : hashmap_List_t t) :
Tot (result bool)
- (decreases (hashmap_hash_map_insert_in_list_loop_decreases t key value ls))
+ (decreases (hashmap_HashMap_insert_in_list_loop_decreases t key value ls))
=
begin match ls with
- | HashmapListCons ckey cvalue tl ->
+ | Hashmap_List_Cons ckey cvalue tl ->
if ckey = key
then Return false
- else hashmap_hash_map_insert_in_list_loop_fwd t key value tl
- | HashmapListNil -> Return true
+ else hashmap_HashMap_insert_in_list_loop t key value tl
+ | Hashmap_List_Nil -> Return true
end
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: forward function *)
-let hashmap_hash_map_insert_in_list_fwd
- (t : Type0) (key : usize) (value : t) (ls : hashmap_list_t t) : result bool =
- hashmap_hash_map_insert_in_list_loop_fwd t key value ls
+let hashmap_HashMap_insert_in_list
+ (t : Type0) (key : usize) (value : t) (ls : hashmap_List_t t) : result bool =
+ hashmap_HashMap_insert_in_list_loop t key value ls
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: loop 0: backward function 0 *)
-let rec hashmap_hash_map_insert_in_list_loop_back
- (t : Type0) (key : usize) (value : t) (ls : hashmap_list_t t) :
- Tot (result (hashmap_list_t t))
- (decreases (hashmap_hash_map_insert_in_list_loop_decreases t key value ls))
+let rec hashmap_HashMap_insert_in_list_loop_back
+ (t : Type0) (key : usize) (value : t) (ls : hashmap_List_t t) :
+ Tot (result (hashmap_List_t t))
+ (decreases (hashmap_HashMap_insert_in_list_loop_decreases t key value ls))
=
begin match ls with
- | HashmapListCons ckey cvalue tl ->
+ | Hashmap_List_Cons ckey cvalue tl ->
if ckey = key
- then Return (HashmapListCons ckey value tl)
+ then Return (Hashmap_List_Cons ckey value tl)
else
- let* tl0 = hashmap_hash_map_insert_in_list_loop_back t key value tl in
- Return (HashmapListCons ckey cvalue tl0)
- | HashmapListNil ->
- let l = HashmapListNil in Return (HashmapListCons key value l)
+ let* tl0 = hashmap_HashMap_insert_in_list_loop_back t key value tl in
+ Return (Hashmap_List_Cons ckey cvalue tl0)
+ | Hashmap_List_Nil ->
+ let l = Hashmap_List_Nil in Return (Hashmap_List_Cons key value l)
end
(** [hashmap_main::hashmap::HashMap::{0}::insert_in_list]: backward function 0 *)
-let hashmap_hash_map_insert_in_list_back
- (t : Type0) (key : usize) (value : t) (ls : hashmap_list_t t) :
- result (hashmap_list_t t)
+let hashmap_HashMap_insert_in_list_back
+ (t : Type0) (key : usize) (value : t) (ls : hashmap_List_t t) :
+ result (hashmap_List_t t)
=
- hashmap_hash_map_insert_in_list_loop_back t key value ls
+ hashmap_HashMap_insert_in_list_loop_back t key value ls
(** [hashmap_main::hashmap::HashMap::{0}::insert_no_resize]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hashmap_hash_map_insert_no_resize_fwd_back
- (t : Type0) (self : hashmap_hash_map_t t) (key : usize) (value : t) :
- result (hashmap_hash_map_t t)
+let hashmap_HashMap_insert_no_resize
+ (t : Type0) (self : hashmap_HashMap_t t) (key : usize) (value : t) :
+ result (hashmap_HashMap_t t)
=
- let* hash = hashmap_hash_key_fwd key in
- let i = vec_len (hashmap_list_t t) self.hashmap_hash_map_slots in
+ let* hash = hashmap_hash_key key in
+ let i = alloc_vec_Vec_len (hashmap_List_t t) self.slots in
let* hash_mod = usize_rem hash i in
let* l =
- vec_index_mut_fwd (hashmap_list_t t) self.hashmap_hash_map_slots hash_mod
- in
- let* inserted = hashmap_hash_map_insert_in_list_fwd t key value l in
+ alloc_vec_Vec_index_mut (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t t))
+ self.slots hash_mod in
+ let* inserted = hashmap_HashMap_insert_in_list t key value l in
if inserted
then
- let* i0 = usize_add self.hashmap_hash_map_num_entries 1 in
- let* l0 = hashmap_hash_map_insert_in_list_back t key value l in
+ let* i0 = usize_add self.num_entries 1 in
+ let* l0 = hashmap_HashMap_insert_in_list_back t key value l in
let* v =
- vec_index_mut_back (hashmap_list_t t) self.hashmap_hash_map_slots
- hash_mod l0 in
- Return
- { self with hashmap_hash_map_num_entries = i0; hashmap_hash_map_slots = v
- }
+ alloc_vec_Vec_index_mut_back (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ t)) self.slots hash_mod l0 in
+ Return { self with num_entries = i0; slots = v }
else
- let* l0 = hashmap_hash_map_insert_in_list_back t key value l in
+ let* l0 = hashmap_HashMap_insert_in_list_back t key value l in
let* v =
- vec_index_mut_back (hashmap_list_t t) self.hashmap_hash_map_slots
- hash_mod l0 in
- Return { self with hashmap_hash_map_slots = v }
-
-(** [core::num::u32::{8}::MAX] *)
-let core_num_u32_max_body : result u32 = Return 4294967295
-let core_num_u32_max_c : u32 = eval_global core_num_u32_max_body
+ alloc_vec_Vec_index_mut_back (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ t)) self.slots hash_mod l0 in
+ Return { self with slots = v }
(** [hashmap_main::hashmap::HashMap::{0}::move_elements_from_list]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec hashmap_hash_map_move_elements_from_list_loop_fwd_back
- (t : Type0) (ntable : hashmap_hash_map_t t) (ls : hashmap_list_t t) :
- Tot (result (hashmap_hash_map_t t))
+let rec hashmap_HashMap_move_elements_from_list_loop
+ (t : Type0) (ntable : hashmap_HashMap_t t) (ls : hashmap_List_t t) :
+ Tot (result (hashmap_HashMap_t t))
(decreases (
- hashmap_hash_map_move_elements_from_list_loop_decreases t ntable ls))
+ hashmap_HashMap_move_elements_from_list_loop_decreases t ntable ls))
=
begin match ls with
- | HashmapListCons k v tl ->
- let* ntable0 = hashmap_hash_map_insert_no_resize_fwd_back t ntable k v in
- hashmap_hash_map_move_elements_from_list_loop_fwd_back t ntable0 tl
- | HashmapListNil -> Return ntable
+ | Hashmap_List_Cons k v tl ->
+ let* ntable0 = hashmap_HashMap_insert_no_resize t ntable k v in
+ hashmap_HashMap_move_elements_from_list_loop t ntable0 tl
+ | Hashmap_List_Nil -> Return ntable
end
(** [hashmap_main::hashmap::HashMap::{0}::move_elements_from_list]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hashmap_hash_map_move_elements_from_list_fwd_back
- (t : Type0) (ntable : hashmap_hash_map_t t) (ls : hashmap_list_t t) :
- result (hashmap_hash_map_t t)
+let hashmap_HashMap_move_elements_from_list
+ (t : Type0) (ntable : hashmap_HashMap_t t) (ls : hashmap_List_t t) :
+ result (hashmap_HashMap_t t)
=
- hashmap_hash_map_move_elements_from_list_loop_fwd_back t ntable ls
+ hashmap_HashMap_move_elements_from_list_loop t ntable ls
(** [hashmap_main::hashmap::HashMap::{0}::move_elements]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec hashmap_hash_map_move_elements_loop_fwd_back
- (t : Type0) (ntable : hashmap_hash_map_t t) (slots : vec (hashmap_list_t t))
- (i : usize) :
- Tot (result ((hashmap_hash_map_t t) & (vec (hashmap_list_t t))))
- (decreases (hashmap_hash_map_move_elements_loop_decreases t ntable slots i))
+let rec hashmap_HashMap_move_elements_loop
+ (t : Type0) (ntable : hashmap_HashMap_t t)
+ (slots : alloc_vec_Vec (hashmap_List_t t)) (i : usize) :
+ Tot (result ((hashmap_HashMap_t t) & (alloc_vec_Vec (hashmap_List_t t))))
+ (decreases (hashmap_HashMap_move_elements_loop_decreases t ntable slots i))
=
- let i0 = vec_len (hashmap_list_t t) slots in
+ let i0 = alloc_vec_Vec_len (hashmap_List_t t) slots in
if i < i0
then
- let* l = vec_index_mut_fwd (hashmap_list_t t) slots i in
- let ls = mem_replace_fwd (hashmap_list_t t) l HashmapListNil in
- let* ntable0 =
- hashmap_hash_map_move_elements_from_list_fwd_back t ntable ls in
+ let* l =
+ alloc_vec_Vec_index_mut (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ t)) slots i in
+ let ls = core_mem_replace (hashmap_List_t t) l Hashmap_List_Nil in
+ let* ntable0 = hashmap_HashMap_move_elements_from_list t ntable ls in
let* i1 = usize_add i 1 in
- let l0 = mem_replace_back (hashmap_list_t t) l HashmapListNil in
- let* slots0 = vec_index_mut_back (hashmap_list_t t) slots i l0 in
- hashmap_hash_map_move_elements_loop_fwd_back t ntable0 slots0 i1
+ let l0 = core_mem_replace_back (hashmap_List_t t) l Hashmap_List_Nil in
+ let* slots0 =
+ alloc_vec_Vec_index_mut_back (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ t)) slots i l0 in
+ hashmap_HashMap_move_elements_loop t ntable0 slots0 i1
else Return (ntable, slots)
(** [hashmap_main::hashmap::HashMap::{0}::move_elements]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hashmap_hash_map_move_elements_fwd_back
- (t : Type0) (ntable : hashmap_hash_map_t t) (slots : vec (hashmap_list_t t))
- (i : usize) :
- result ((hashmap_hash_map_t t) & (vec (hashmap_list_t t)))
+let hashmap_HashMap_move_elements
+ (t : Type0) (ntable : hashmap_HashMap_t t)
+ (slots : alloc_vec_Vec (hashmap_List_t t)) (i : usize) :
+ result ((hashmap_HashMap_t t) & (alloc_vec_Vec (hashmap_List_t t)))
=
- hashmap_hash_map_move_elements_loop_fwd_back t ntable slots i
+ hashmap_HashMap_move_elements_loop t ntable slots i
(** [hashmap_main::hashmap::HashMap::{0}::try_resize]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hashmap_hash_map_try_resize_fwd_back
- (t : Type0) (self : hashmap_hash_map_t t) : result (hashmap_hash_map_t t) =
- let* max_usize = scalar_cast U32 Usize core_num_u32_max_c in
- let capacity = vec_len (hashmap_list_t t) self.hashmap_hash_map_slots in
+let hashmap_HashMap_try_resize
+ (t : Type0) (self : hashmap_HashMap_t t) : result (hashmap_HashMap_t t) =
+ let* max_usize = scalar_cast U32 Usize core_u32_max in
+ let capacity = alloc_vec_Vec_len (hashmap_List_t t) self.slots in
let* n1 = usize_div max_usize 2 in
- let (i, i0) = self.hashmap_hash_map_max_load_factor in
+ let (i, i0) = self.max_load_factor in
let* i1 = usize_div n1 i in
if capacity <= i1
then
let* i2 = usize_mul capacity 2 in
- let* ntable = hashmap_hash_map_new_with_capacity_fwd t i2 i i0 in
- let* (ntable0, _) =
- hashmap_hash_map_move_elements_fwd_back t ntable
- self.hashmap_hash_map_slots 0 in
+ let* ntable = hashmap_HashMap_new_with_capacity t i2 i i0 in
+ let* (ntable0, _) = hashmap_HashMap_move_elements t ntable self.slots 0 in
Return
- {
- ntable0
- with
- hashmap_hash_map_num_entries = self.hashmap_hash_map_num_entries;
- hashmap_hash_map_max_load_factor = (i, i0)
+ { ntable0 with num_entries = self.num_entries; max_load_factor = (i, i0)
}
- else Return { self with hashmap_hash_map_max_load_factor = (i, i0) }
+ else Return { self with max_load_factor = (i, i0) }
(** [hashmap_main::hashmap::HashMap::{0}::insert]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let hashmap_hash_map_insert_fwd_back
- (t : Type0) (self : hashmap_hash_map_t t) (key : usize) (value : t) :
- result (hashmap_hash_map_t t)
+let hashmap_HashMap_insert
+ (t : Type0) (self : hashmap_HashMap_t t) (key : usize) (value : t) :
+ result (hashmap_HashMap_t t)
=
- let* self0 = hashmap_hash_map_insert_no_resize_fwd_back t self key value in
- let* i = hashmap_hash_map_len_fwd t self0 in
- if i > self0.hashmap_hash_map_max_load
- then hashmap_hash_map_try_resize_fwd_back t self0
+ let* self0 = hashmap_HashMap_insert_no_resize t self key value in
+ let* i = hashmap_HashMap_len t self0 in
+ if i > self0.max_load
+ then hashmap_HashMap_try_resize t self0
else Return self0
(** [hashmap_main::hashmap::HashMap::{0}::contains_key_in_list]: loop 0: forward function *)
-let rec hashmap_hash_map_contains_key_in_list_loop_fwd
- (t : Type0) (key : usize) (ls : hashmap_list_t t) :
+let rec hashmap_HashMap_contains_key_in_list_loop
+ (t : Type0) (key : usize) (ls : hashmap_List_t t) :
Tot (result bool)
- (decreases (hashmap_hash_map_contains_key_in_list_loop_decreases t key ls))
+ (decreases (hashmap_HashMap_contains_key_in_list_loop_decreases t key ls))
=
begin match ls with
- | HashmapListCons ckey x tl ->
+ | Hashmap_List_Cons ckey x tl ->
if ckey = key
then Return true
- else hashmap_hash_map_contains_key_in_list_loop_fwd t key tl
- | HashmapListNil -> Return false
+ else hashmap_HashMap_contains_key_in_list_loop t key tl
+ | Hashmap_List_Nil -> Return false
end
(** [hashmap_main::hashmap::HashMap::{0}::contains_key_in_list]: forward function *)
-let hashmap_hash_map_contains_key_in_list_fwd
- (t : Type0) (key : usize) (ls : hashmap_list_t t) : result bool =
- hashmap_hash_map_contains_key_in_list_loop_fwd t key ls
+let hashmap_HashMap_contains_key_in_list
+ (t : Type0) (key : usize) (ls : hashmap_List_t t) : result bool =
+ hashmap_HashMap_contains_key_in_list_loop t key ls
(** [hashmap_main::hashmap::HashMap::{0}::contains_key]: forward function *)
-let hashmap_hash_map_contains_key_fwd
- (t : Type0) (self : hashmap_hash_map_t t) (key : usize) : result bool =
- let* hash = hashmap_hash_key_fwd key in
- let i = vec_len (hashmap_list_t t) self.hashmap_hash_map_slots in
+let hashmap_HashMap_contains_key
+ (t : Type0) (self : hashmap_HashMap_t t) (key : usize) : result bool =
+ let* hash = hashmap_hash_key key in
+ let i = alloc_vec_Vec_len (hashmap_List_t t) self.slots in
let* hash_mod = usize_rem hash i in
let* l =
- vec_index_fwd (hashmap_list_t t) self.hashmap_hash_map_slots hash_mod in
- hashmap_hash_map_contains_key_in_list_fwd t key l
+ alloc_vec_Vec_index (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t t))
+ self.slots hash_mod in
+ hashmap_HashMap_contains_key_in_list t key l
(** [hashmap_main::hashmap::HashMap::{0}::get_in_list]: loop 0: forward function *)
-let rec hashmap_hash_map_get_in_list_loop_fwd
- (t : Type0) (key : usize) (ls : hashmap_list_t t) :
+let rec hashmap_HashMap_get_in_list_loop
+ (t : Type0) (key : usize) (ls : hashmap_List_t t) :
Tot (result t)
- (decreases (hashmap_hash_map_get_in_list_loop_decreases t key ls))
+ (decreases (hashmap_HashMap_get_in_list_loop_decreases t key ls))
=
begin match ls with
- | HashmapListCons ckey cvalue tl ->
+ | Hashmap_List_Cons ckey cvalue tl ->
if ckey = key
then Return cvalue
- else hashmap_hash_map_get_in_list_loop_fwd t key tl
- | HashmapListNil -> Fail Failure
+ else hashmap_HashMap_get_in_list_loop t key tl
+ | Hashmap_List_Nil -> Fail Failure
end
(** [hashmap_main::hashmap::HashMap::{0}::get_in_list]: forward function *)
-let hashmap_hash_map_get_in_list_fwd
- (t : Type0) (key : usize) (ls : hashmap_list_t t) : result t =
- hashmap_hash_map_get_in_list_loop_fwd t key ls
+let hashmap_HashMap_get_in_list
+ (t : Type0) (key : usize) (ls : hashmap_List_t t) : result t =
+ hashmap_HashMap_get_in_list_loop t key ls
(** [hashmap_main::hashmap::HashMap::{0}::get]: forward function *)
-let hashmap_hash_map_get_fwd
- (t : Type0) (self : hashmap_hash_map_t t) (key : usize) : result t =
- let* hash = hashmap_hash_key_fwd key in
- let i = vec_len (hashmap_list_t t) self.hashmap_hash_map_slots in
+let hashmap_HashMap_get
+ (t : Type0) (self : hashmap_HashMap_t t) (key : usize) : result t =
+ let* hash = hashmap_hash_key key in
+ let i = alloc_vec_Vec_len (hashmap_List_t t) self.slots in
let* hash_mod = usize_rem hash i in
let* l =
- vec_index_fwd (hashmap_list_t t) self.hashmap_hash_map_slots hash_mod in
- hashmap_hash_map_get_in_list_fwd t key l
+ alloc_vec_Vec_index (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t t))
+ self.slots hash_mod in
+ hashmap_HashMap_get_in_list t key l
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: loop 0: forward function *)
-let rec hashmap_hash_map_get_mut_in_list_loop_fwd
- (t : Type0) (ls : hashmap_list_t t) (key : usize) :
+let rec hashmap_HashMap_get_mut_in_list_loop
+ (t : Type0) (ls : hashmap_List_t t) (key : usize) :
Tot (result t)
- (decreases (hashmap_hash_map_get_mut_in_list_loop_decreases t ls key))
+ (decreases (hashmap_HashMap_get_mut_in_list_loop_decreases t ls key))
=
begin match ls with
- | HashmapListCons ckey cvalue tl ->
+ | Hashmap_List_Cons ckey cvalue tl ->
if ckey = key
then Return cvalue
- else hashmap_hash_map_get_mut_in_list_loop_fwd t tl key
- | HashmapListNil -> Fail Failure
+ else hashmap_HashMap_get_mut_in_list_loop t tl key
+ | Hashmap_List_Nil -> Fail Failure
end
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: forward function *)
-let hashmap_hash_map_get_mut_in_list_fwd
- (t : Type0) (ls : hashmap_list_t t) (key : usize) : result t =
- hashmap_hash_map_get_mut_in_list_loop_fwd t ls key
+let hashmap_HashMap_get_mut_in_list
+ (t : Type0) (ls : hashmap_List_t t) (key : usize) : result t =
+ hashmap_HashMap_get_mut_in_list_loop t ls key
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: loop 0: backward function 0 *)
-let rec hashmap_hash_map_get_mut_in_list_loop_back
- (t : Type0) (ls : hashmap_list_t t) (key : usize) (ret : t) :
- Tot (result (hashmap_list_t t))
- (decreases (hashmap_hash_map_get_mut_in_list_loop_decreases t ls key))
+let rec hashmap_HashMap_get_mut_in_list_loop_back
+ (t : Type0) (ls : hashmap_List_t t) (key : usize) (ret : t) :
+ Tot (result (hashmap_List_t t))
+ (decreases (hashmap_HashMap_get_mut_in_list_loop_decreases t ls key))
=
begin match ls with
- | HashmapListCons ckey cvalue tl ->
+ | Hashmap_List_Cons ckey cvalue tl ->
if ckey = key
- then Return (HashmapListCons ckey ret tl)
+ then Return (Hashmap_List_Cons ckey ret tl)
else
- let* tl0 = hashmap_hash_map_get_mut_in_list_loop_back t tl key ret in
- Return (HashmapListCons ckey cvalue tl0)
- | HashmapListNil -> Fail Failure
+ let* tl0 = hashmap_HashMap_get_mut_in_list_loop_back t tl key ret in
+ Return (Hashmap_List_Cons ckey cvalue tl0)
+ | Hashmap_List_Nil -> Fail Failure
end
(** [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: backward function 0 *)
-let hashmap_hash_map_get_mut_in_list_back
- (t : Type0) (ls : hashmap_list_t t) (key : usize) (ret : t) :
- result (hashmap_list_t t)
+let hashmap_HashMap_get_mut_in_list_back
+ (t : Type0) (ls : hashmap_List_t t) (key : usize) (ret : t) :
+ result (hashmap_List_t t)
=
- hashmap_hash_map_get_mut_in_list_loop_back t ls key ret
+ hashmap_HashMap_get_mut_in_list_loop_back t ls key ret
(** [hashmap_main::hashmap::HashMap::{0}::get_mut]: forward function *)
-let hashmap_hash_map_get_mut_fwd
- (t : Type0) (self : hashmap_hash_map_t t) (key : usize) : result t =
- let* hash = hashmap_hash_key_fwd key in
- let i = vec_len (hashmap_list_t t) self.hashmap_hash_map_slots in
+let hashmap_HashMap_get_mut
+ (t : Type0) (self : hashmap_HashMap_t t) (key : usize) : result t =
+ let* hash = hashmap_hash_key key in
+ let i = alloc_vec_Vec_len (hashmap_List_t t) self.slots in
let* hash_mod = usize_rem hash i in
let* l =
- vec_index_mut_fwd (hashmap_list_t t) self.hashmap_hash_map_slots hash_mod
- in
- hashmap_hash_map_get_mut_in_list_fwd t l key
+ alloc_vec_Vec_index_mut (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t t))
+ self.slots hash_mod in
+ hashmap_HashMap_get_mut_in_list t l key
(** [hashmap_main::hashmap::HashMap::{0}::get_mut]: backward function 0 *)
-let hashmap_hash_map_get_mut_back
- (t : Type0) (self : hashmap_hash_map_t t) (key : usize) (ret : t) :
- result (hashmap_hash_map_t t)
+let hashmap_HashMap_get_mut_back
+ (t : Type0) (self : hashmap_HashMap_t t) (key : usize) (ret : t) :
+ result (hashmap_HashMap_t t)
=
- let* hash = hashmap_hash_key_fwd key in
- let i = vec_len (hashmap_list_t t) self.hashmap_hash_map_slots in
+ let* hash = hashmap_hash_key key in
+ let i = alloc_vec_Vec_len (hashmap_List_t t) self.slots in
let* hash_mod = usize_rem hash i in
let* l =
- vec_index_mut_fwd (hashmap_list_t t) self.hashmap_hash_map_slots hash_mod
- in
- let* l0 = hashmap_hash_map_get_mut_in_list_back t l key ret in
+ alloc_vec_Vec_index_mut (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t t))
+ self.slots hash_mod in
+ let* l0 = hashmap_HashMap_get_mut_in_list_back t l key ret in
let* v =
- vec_index_mut_back (hashmap_list_t t) self.hashmap_hash_map_slots hash_mod
- l0 in
- Return { self with hashmap_hash_map_slots = v }
+ alloc_vec_Vec_index_mut_back (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t t))
+ self.slots hash_mod l0 in
+ Return { self with slots = v }
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: loop 0: forward function *)
-let rec hashmap_hash_map_remove_from_list_loop_fwd
- (t : Type0) (key : usize) (ls : hashmap_list_t t) :
+let rec hashmap_HashMap_remove_from_list_loop
+ (t : Type0) (key : usize) (ls : hashmap_List_t t) :
Tot (result (option t))
- (decreases (hashmap_hash_map_remove_from_list_loop_decreases t key ls))
+ (decreases (hashmap_HashMap_remove_from_list_loop_decreases t key ls))
=
begin match ls with
- | HashmapListCons ckey x tl ->
+ | Hashmap_List_Cons ckey x tl ->
if ckey = key
then
let mv_ls =
- mem_replace_fwd (hashmap_list_t t) (HashmapListCons ckey x tl)
- HashmapListNil in
+ core_mem_replace (hashmap_List_t t) (Hashmap_List_Cons ckey x tl)
+ Hashmap_List_Nil in
begin match mv_ls with
- | HashmapListCons i cvalue tl0 -> Return (Some cvalue)
- | HashmapListNil -> Fail Failure
+ | Hashmap_List_Cons i cvalue tl0 -> Return (Some cvalue)
+ | Hashmap_List_Nil -> Fail Failure
end
- else hashmap_hash_map_remove_from_list_loop_fwd t key tl
- | HashmapListNil -> Return None
+ else hashmap_HashMap_remove_from_list_loop t key tl
+ | Hashmap_List_Nil -> Return None
end
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: forward function *)
-let hashmap_hash_map_remove_from_list_fwd
- (t : Type0) (key : usize) (ls : hashmap_list_t t) : result (option t) =
- hashmap_hash_map_remove_from_list_loop_fwd t key ls
+let hashmap_HashMap_remove_from_list
+ (t : Type0) (key : usize) (ls : hashmap_List_t t) : result (option t) =
+ hashmap_HashMap_remove_from_list_loop t key ls
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: loop 0: backward function 1 *)
-let rec hashmap_hash_map_remove_from_list_loop_back
- (t : Type0) (key : usize) (ls : hashmap_list_t t) :
- Tot (result (hashmap_list_t t))
- (decreases (hashmap_hash_map_remove_from_list_loop_decreases t key ls))
+let rec hashmap_HashMap_remove_from_list_loop_back
+ (t : Type0) (key : usize) (ls : hashmap_List_t t) :
+ Tot (result (hashmap_List_t t))
+ (decreases (hashmap_HashMap_remove_from_list_loop_decreases t key ls))
=
begin match ls with
- | HashmapListCons ckey x tl ->
+ | Hashmap_List_Cons ckey x tl ->
if ckey = key
then
let mv_ls =
- mem_replace_fwd (hashmap_list_t t) (HashmapListCons ckey x tl)
- HashmapListNil in
+ core_mem_replace (hashmap_List_t t) (Hashmap_List_Cons ckey x tl)
+ Hashmap_List_Nil in
begin match mv_ls with
- | HashmapListCons i cvalue tl0 -> Return tl0
- | HashmapListNil -> Fail Failure
+ | Hashmap_List_Cons i cvalue tl0 -> Return tl0
+ | Hashmap_List_Nil -> Fail Failure
end
else
- let* tl0 = hashmap_hash_map_remove_from_list_loop_back t key tl in
- Return (HashmapListCons ckey x tl0)
- | HashmapListNil -> Return HashmapListNil
+ let* tl0 = hashmap_HashMap_remove_from_list_loop_back t key tl in
+ Return (Hashmap_List_Cons ckey x tl0)
+ | Hashmap_List_Nil -> Return Hashmap_List_Nil
end
(** [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: backward function 1 *)
-let hashmap_hash_map_remove_from_list_back
- (t : Type0) (key : usize) (ls : hashmap_list_t t) :
- result (hashmap_list_t t)
+let hashmap_HashMap_remove_from_list_back
+ (t : Type0) (key : usize) (ls : hashmap_List_t t) :
+ result (hashmap_List_t t)
=
- hashmap_hash_map_remove_from_list_loop_back t key ls
+ hashmap_HashMap_remove_from_list_loop_back t key ls
(** [hashmap_main::hashmap::HashMap::{0}::remove]: forward function *)
-let hashmap_hash_map_remove_fwd
- (t : Type0) (self : hashmap_hash_map_t t) (key : usize) : result (option t) =
- let* hash = hashmap_hash_key_fwd key in
- let i = vec_len (hashmap_list_t t) self.hashmap_hash_map_slots in
+let hashmap_HashMap_remove
+ (t : Type0) (self : hashmap_HashMap_t t) (key : usize) : result (option t) =
+ let* hash = hashmap_hash_key key in
+ let i = alloc_vec_Vec_len (hashmap_List_t t) self.slots in
let* hash_mod = usize_rem hash i in
let* l =
- vec_index_mut_fwd (hashmap_list_t t) self.hashmap_hash_map_slots hash_mod
- in
- let* x = hashmap_hash_map_remove_from_list_fwd t key l in
+ alloc_vec_Vec_index_mut (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t t))
+ self.slots hash_mod in
+ let* x = hashmap_HashMap_remove_from_list t key l in
begin match x with
| None -> Return None
- | Some x0 ->
- let* _ = usize_sub self.hashmap_hash_map_num_entries 1 in Return (Some x0)
+ | Some x0 -> let* _ = usize_sub self.num_entries 1 in Return (Some x0)
end
(** [hashmap_main::hashmap::HashMap::{0}::remove]: backward function 0 *)
-let hashmap_hash_map_remove_back
- (t : Type0) (self : hashmap_hash_map_t t) (key : usize) :
- result (hashmap_hash_map_t t)
+let hashmap_HashMap_remove_back
+ (t : Type0) (self : hashmap_HashMap_t t) (key : usize) :
+ result (hashmap_HashMap_t t)
=
- let* hash = hashmap_hash_key_fwd key in
- let i = vec_len (hashmap_list_t t) self.hashmap_hash_map_slots in
+ let* hash = hashmap_hash_key key in
+ let i = alloc_vec_Vec_len (hashmap_List_t t) self.slots in
let* hash_mod = usize_rem hash i in
let* l =
- vec_index_mut_fwd (hashmap_list_t t) self.hashmap_hash_map_slots hash_mod
- in
- let* x = hashmap_hash_map_remove_from_list_fwd t key l in
+ alloc_vec_Vec_index_mut (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t t))
+ self.slots hash_mod in
+ let* x = hashmap_HashMap_remove_from_list t key l in
begin match x with
| None ->
- let* l0 = hashmap_hash_map_remove_from_list_back t key l in
+ let* l0 = hashmap_HashMap_remove_from_list_back t key l in
let* v =
- vec_index_mut_back (hashmap_list_t t) self.hashmap_hash_map_slots
- hash_mod l0 in
- Return { self with hashmap_hash_map_slots = v }
+ alloc_vec_Vec_index_mut_back (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ t)) self.slots hash_mod l0 in
+ Return { self with slots = v }
| Some x0 ->
- let* i0 = usize_sub self.hashmap_hash_map_num_entries 1 in
- let* l0 = hashmap_hash_map_remove_from_list_back t key l in
+ let* i0 = usize_sub self.num_entries 1 in
+ let* l0 = hashmap_HashMap_remove_from_list_back t key l in
let* v =
- vec_index_mut_back (hashmap_list_t t) self.hashmap_hash_map_slots
- hash_mod l0 in
- Return
- { self with hashmap_hash_map_num_entries = i0; hashmap_hash_map_slots = v
- }
+ alloc_vec_Vec_index_mut_back (hashmap_List_t t) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (hashmap_List_t
+ t)) self.slots hash_mod l0 in
+ Return { self with num_entries = i0; slots = v }
end
(** [hashmap_main::hashmap::test1]: forward function *)
-let hashmap_test1_fwd : result unit =
- let* hm = hashmap_hash_map_new_fwd u64 in
- let* hm0 = hashmap_hash_map_insert_fwd_back u64 hm 0 42 in
- let* hm1 = hashmap_hash_map_insert_fwd_back u64 hm0 128 18 in
- let* hm2 = hashmap_hash_map_insert_fwd_back u64 hm1 1024 138 in
- let* hm3 = hashmap_hash_map_insert_fwd_back u64 hm2 1056 256 in
- let* i = hashmap_hash_map_get_fwd u64 hm3 128 in
+let hashmap_test1 : result unit =
+ let* hm = hashmap_HashMap_new u64 in
+ let* hm0 = hashmap_HashMap_insert u64 hm 0 42 in
+ let* hm1 = hashmap_HashMap_insert u64 hm0 128 18 in
+ let* hm2 = hashmap_HashMap_insert u64 hm1 1024 138 in
+ let* hm3 = hashmap_HashMap_insert u64 hm2 1056 256 in
+ let* i = hashmap_HashMap_get u64 hm3 128 in
if not (i = 18)
then Fail Failure
else
- let* hm4 = hashmap_hash_map_get_mut_back u64 hm3 1024 56 in
- let* i0 = hashmap_hash_map_get_fwd u64 hm4 1024 in
+ let* hm4 = hashmap_HashMap_get_mut_back u64 hm3 1024 56 in
+ let* i0 = hashmap_HashMap_get u64 hm4 1024 in
if not (i0 = 56)
then Fail Failure
else
- let* x = hashmap_hash_map_remove_fwd u64 hm4 1024 in
+ let* x = hashmap_HashMap_remove u64 hm4 1024 in
begin match x with
| None -> Fail Failure
| Some x0 ->
if not (x0 = 56)
then Fail Failure
else
- let* hm5 = hashmap_hash_map_remove_back u64 hm4 1024 in
- let* i1 = hashmap_hash_map_get_fwd u64 hm5 0 in
+ let* hm5 = hashmap_HashMap_remove_back u64 hm4 1024 in
+ let* i1 = hashmap_HashMap_get u64 hm5 0 in
if not (i1 = 42)
then Fail Failure
else
- let* i2 = hashmap_hash_map_get_fwd u64 hm5 128 in
+ let* i2 = hashmap_HashMap_get u64 hm5 128 in
if not (i2 = 18)
then Fail Failure
else
- let* i3 = hashmap_hash_map_get_fwd u64 hm5 1056 in
+ let* i3 = hashmap_HashMap_get u64 hm5 1056 in
if not (i3 = 256) then Fail Failure else Return ()
end
-(** Unit test for [hashmap_main::hashmap::test1] *)
-let _ = assert_norm (hashmap_test1_fwd = Return ())
-
(** [hashmap_main::insert_on_disk]: forward function *)
-let insert_on_disk_fwd
+let insert_on_disk
(key : usize) (value : u64) (st : state) : result (state & unit) =
- let* (st0, hm) = hashmap_utils_deserialize_fwd st in
- let* hm0 = hashmap_hash_map_insert_fwd_back u64 hm key value in
- let* (st1, _) = hashmap_utils_serialize_fwd hm0 st0 in
+ let* (st0, hm) = hashmap_utils_deserialize st in
+ let* hm0 = hashmap_HashMap_insert u64 hm key value in
+ let* (st1, _) = hashmap_utils_serialize hm0 st0 in
Return (st1, ())
(** [hashmap_main::main]: forward function *)
-let main_fwd : result unit =
+let main : result unit =
Return ()
-(** Unit test for [hashmap_main::main] *)
-let _ = assert_norm (main_fwd = Return ())
-
diff --git a/tests/fstar/hashmap_on_disk/HashmapMain.Opaque.fsti b/tests/fstar/hashmap_on_disk/HashmapMain.Opaque.fsti
index 78a6c3ba..d6cecf36 100644
--- a/tests/fstar/hashmap_on_disk/HashmapMain.Opaque.fsti
+++ b/tests/fstar/hashmap_on_disk/HashmapMain.Opaque.fsti
@@ -7,10 +7,10 @@ include HashmapMain.Types
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [hashmap_main::hashmap_utils::deserialize]: forward function *)
-val hashmap_utils_deserialize_fwd
- : state -> result (state & (hashmap_hash_map_t u64))
+val hashmap_utils_deserialize
+ : state -> result (state & (hashmap_HashMap_t u64))
(** [hashmap_main::hashmap_utils::serialize]: forward function *)
-val hashmap_utils_serialize_fwd
- : hashmap_hash_map_t u64 -> state -> result (state & unit)
+val hashmap_utils_serialize
+ : hashmap_HashMap_t u64 -> state -> result (state & unit)
diff --git a/tests/fstar/hashmap_on_disk/HashmapMain.Properties.fst b/tests/fstar/hashmap_on_disk/HashmapMain.Properties.fst
index 106fe05a..358df29e 100644
--- a/tests/fstar/hashmap_on_disk/HashmapMain.Properties.fst
+++ b/tests/fstar/hashmap_on_disk/HashmapMain.Properties.fst
@@ -13,36 +13,36 @@ open HashmapMain.Funs
/// [state_v] gives us the hash map currently stored on disk
assume
-val state_v : state -> hashmap_hash_map_t u64
+val state_v : state -> hashmap_HashMap_t u64
/// [serialize] updates the hash map stored on disk
assume
-val serialize_lem (hm : hashmap_hash_map_t u64) (st : state) : Lemma (
- match hashmap_utils_serialize_fwd hm st with
+val serialize_lem (hm : hashmap_HashMap_t u64) (st : state) : Lemma (
+ match hashmap_utils_serialize hm st with
| Fail _ -> True
| Return (st', ()) -> state_v st' == hm)
- [SMTPat (hashmap_utils_serialize_fwd hm st)]
+ [SMTPat (hashmap_utils_serialize hm st)]
/// [deserialize] gives us the hash map stored on disk, without updating it
assume
val deserialize_lem (st : state) : Lemma (
- match hashmap_utils_deserialize_fwd st with
+ match hashmap_utils_deserialize st with
| Fail _ -> True
| Return (st', hm) -> hm == state_v st /\ st' == st)
- [SMTPat (hashmap_utils_deserialize_fwd st)]
+ [SMTPat (hashmap_utils_deserialize st)]
(*** Lemmas *)
/// The obvious lemma about [insert_on_disk]: the updated hash map stored on disk
/// is exactly the hash map produced from inserting the binding ([key], [value])
/// in the hash map previously stored on disk.
-val insert_on_disk_fwd_lem (key : usize) (value : u64) (st : state) : Lemma (
- match insert_on_disk_fwd key value st with
+val insert_on_disk_lem (key : usize) (value : u64) (st : state) : Lemma (
+ match insert_on_disk key value st with
| Fail _ -> True
| Return (st', ()) ->
let hm = state_v st in
- match hashmap_hash_map_insert_fwd_back u64 hm key value with
+ match hashmap_HashMap_insert u64 hm key value with
| Fail _ -> False
| Return hm' -> hm' == state_v st')
-let insert_on_disk_fwd_lem key value st = ()
+let insert_on_disk_lem key value st = ()
diff --git a/tests/fstar/hashmap_on_disk/HashmapMain.Types.fsti b/tests/fstar/hashmap_on_disk/HashmapMain.Types.fsti
index e289174b..24b78c2a 100644
--- a/tests/fstar/hashmap_on_disk/HashmapMain.Types.fsti
+++ b/tests/fstar/hashmap_on_disk/HashmapMain.Types.fsti
@@ -6,17 +6,17 @@ open Primitives
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [hashmap_main::hashmap::List] *)
-type hashmap_list_t (t : Type0) =
-| HashmapListCons : usize -> t -> hashmap_list_t t -> hashmap_list_t t
-| HashmapListNil : hashmap_list_t t
+type hashmap_List_t (t : Type0) =
+| Hashmap_List_Cons : usize -> t -> hashmap_List_t t -> hashmap_List_t t
+| Hashmap_List_Nil : hashmap_List_t t
(** [hashmap_main::hashmap::HashMap] *)
-type hashmap_hash_map_t (t : Type0) =
+type hashmap_HashMap_t (t : Type0) =
{
- hashmap_hash_map_num_entries : usize;
- hashmap_hash_map_max_load_factor : (usize & usize);
- hashmap_hash_map_max_load : usize;
- hashmap_hash_map_slots : vec (hashmap_list_t t);
+ num_entries : usize;
+ max_load_factor : (usize & usize);
+ max_load : usize;
+ slots : alloc_vec_Vec (hashmap_List_t t);
}
(** The state type used in the state-error monad *)
diff --git a/tests/fstar/hashmap_on_disk/Primitives.fst b/tests/fstar/hashmap_on_disk/Primitives.fst
index 9db82069..3297803c 100644
--- a/tests/fstar/hashmap_on_disk/Primitives.fst
+++ b/tests/fstar/hashmap_on_disk/Primitives.fst
@@ -55,8 +55,12 @@ type string = string
let is_zero (n: nat) : bool = n = 0
let decrease (n: nat{n > 0}) : nat = n - 1
-let mem_replace_fwd (a : Type0) (x : a) (y : a) : a = x
-let mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+let core_mem_replace (a : Type0) (x : a) (y : a) : a = x
+let core_mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+
+// We don't really use raw pointers for now
+type mut_raw_ptr (t : Type0) = { v : t }
+type const_raw_ptr (t : Type0) = { v : t }
(*** Scalars *)
/// Rem.: most of the following code was partially generated
@@ -100,6 +104,11 @@ type scalar_ty =
| U64
| U128
+let is_unsigned = function
+ | Isize | I8 | I16 | I32 | I64 | I128 -> false
+ | Usize | U8 | U16 | U32 | U64 | U128 -> true
+
+
let scalar_min (ty : scalar_ty) : int =
match ty with
| Isize -> isize_min
@@ -162,6 +171,15 @@ let scalar_sub (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scala
let scalar_mul (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
mk_scalar ty (x * y)
+let scalar_lxor (#ty : scalar_ty { is_unsigned ty && ty <> Usize })
+ (x : scalar ty) (y : scalar ty) : scalar ty =
+ match ty with
+ | U8 -> FStar.UInt.logxor #8 x y
+ | U16 -> FStar.UInt.logxor #16 x y
+ | U32 -> FStar.UInt.logxor #32 x y
+ | U64 -> FStar.UInt.logxor #64 x y
+ | U128 -> FStar.UInt.logxor #128 x y
+
(** Cast an integer from a [src_ty] to a [tgt_ty] *)
// TODO: check the semantics of casts in Rust
let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) =
@@ -169,17 +187,44 @@ let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) :
/// The scalar types
type isize : eqtype = scalar Isize
-type i8 : eqtype = scalar I8
-type i16 : eqtype = scalar I16
-type i32 : eqtype = scalar I32
-type i64 : eqtype = scalar I64
-type i128 : eqtype = scalar I128
+type i8 : eqtype = scalar I8
+type i16 : eqtype = scalar I16
+type i32 : eqtype = scalar I32
+type i64 : eqtype = scalar I64
+type i128 : eqtype = scalar I128
type usize : eqtype = scalar Usize
-type u8 : eqtype = scalar U8
-type u16 : eqtype = scalar U16
-type u32 : eqtype = scalar U32
-type u64 : eqtype = scalar U64
-type u128 : eqtype = scalar U128
+type u8 : eqtype = scalar U8
+type u16 : eqtype = scalar U16
+type u32 : eqtype = scalar U32
+type u64 : eqtype = scalar U64
+type u128 : eqtype = scalar U128
+
+
+let core_isize_min : isize = isize_min
+let core_isize_max : isize = isize_max
+let core_i8_min : i8 = i8_min
+let core_i8_max : i8 = i8_max
+let core_i16_min : i16 = i16_min
+let core_i16_max : i16 = i16_max
+let core_i32_min : i32 = i32_min
+let core_i32_max : i32 = i32_max
+let core_i64_min : i64 = i64_min
+let core_i64_max : i64 = i64_max
+let core_i128_min : i128 = i128_min
+let core_i128_max : i128 = i128_max
+
+let core_usize_min : usize = usize_min
+let core_usize_max : usize = usize_max
+let core_u8_min : u8 = u8_min
+let core_u8_max : u8 = u8_max
+let core_u16_min : u16 = u16_min
+let core_u16_max : u16 = u16_max
+let core_u32_min : u32 = u32_min
+let core_u32_max : u32 = u32_max
+let core_u64_min : u64 = u64_min
+let core_u64_max : u64 = u64_max
+let core_u128_min : u128 = u128_min
+let core_u128_max : u128 = u128_max
/// Negation
let isize_neg = scalar_neg #Isize
@@ -231,7 +276,7 @@ let u32_add = scalar_add #U32
let u64_add = scalar_add #U64
let u128_add = scalar_add #U128
-/// Substraction
+/// Subtraction
let isize_sub = scalar_sub #Isize
let i8_sub = scalar_sub #I8
let i16_sub = scalar_sub #I16
@@ -259,12 +304,65 @@ let u32_mul = scalar_mul #U32
let u64_mul = scalar_mul #U64
let u128_mul = scalar_mul #U128
-(*** Range *)
-type range (a : Type0) = {
+/// Logical operators, defined for unsigned types only, so far
+let u8_xor = scalar_lxor #U8
+let u16_xor = scalar_lxor #U16
+let u32_xor = scalar_lxor #U32
+let u64_xor = scalar_lxor #U64
+let u128_xor = scalar_lxor #U128
+
+(*** core::ops *)
+
+// Trait declaration: [core::ops::index::Index]
+noeq type core_ops_index_Index (self idx : Type0) = {
+ output : Type0;
+ index : self → idx → result output
+}
+
+// Trait declaration: [core::ops::index::IndexMut]
+noeq type core_ops_index_IndexMut (self idx : Type0) = {
+ indexInst : core_ops_index_Index self idx;
+ index_mut : self → idx → result indexInst.output;
+ index_mut_back : self → idx → indexInst.output → result self;
+}
+
+// Trait declaration [core::ops::deref::Deref]
+noeq type core_ops_deref_Deref (self : Type0) = {
+ target : Type0;
+ deref : self → result target;
+}
+
+// Trait declaration [core::ops::deref::DerefMut]
+noeq type core_ops_deref_DerefMut (self : Type0) = {
+ derefInst : core_ops_deref_Deref self;
+ deref_mut : self → result derefInst.target;
+ deref_mut_back : self → derefInst.target → result self;
+}
+
+type core_ops_range_Range (a : Type0) = {
start : a;
end_ : a;
}
+(*** [alloc] *)
+
+let alloc_boxed_Box_deref (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut_back (t : Type) (_ : t) (x : t) : result t = Return x
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefInst (self : Type0) : core_ops_deref_Deref self = {
+ target = self;
+ deref = alloc_boxed_Box_deref self;
+}
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefMutInst (self : Type0) : core_ops_deref_DerefMut self = {
+ derefInst = alloc_boxed_Box_coreOpsDerefInst self;
+ deref_mut = alloc_boxed_Box_deref_mut self;
+ deref_mut_back = alloc_boxed_Box_deref_mut_back self;
+}
+
(*** Array *)
type array (a : Type0) (n : usize) = s:list a{length s = n}
@@ -278,15 +376,11 @@ let mk_array (a : Type0) (n : usize)
normalize_term_spec (FStar.List.Tot.length l);
l
-let array_index_shared (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let array_index_mut_fwd (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
+let array_index_usize (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let array_index_mut_back (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
+let array_update_usize (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
if i < length x then Return (list_update x i nx)
else Fail Failure
@@ -295,55 +389,54 @@ type slice (a : Type0) = s:list a{length s <= usize_max}
let slice_len (a : Type0) (s : slice a) : usize = length s
-let slice_index_shared (a : Type0) (x : slice a) (i : usize) : result a =
+let slice_index_usize (a : Type0) (x : slice a) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let slice_index_mut_fwd (a : Type0) (x : slice a) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let slice_index_mut_back (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
+let slice_update_usize (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
if i < length x then Return (list_update x i nx)
else Fail Failure
(*** Subslices *)
-let array_to_slice_shared (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_fwd (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_back (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
+let array_to_slice (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
+let array_from_slice (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
if length s = n then Return s
else Fail Failure
// TODO: finish the definitions below (there lacks [List.drop] and [List.take] in the standard library *)
-let array_subslice_shared (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
- admit()
-
-let array_subslice_mut_fwd (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
+let array_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let array_subslice_mut_back (a : Type0) (n : usize) (x : array a n) (r : range usize) (ns : slice a) : result (array a n) =
+let array_update_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) (ns : slice a) : result (array a n) =
admit()
-let slice_subslice_shared (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let array_repeat (a : Type0) (n : usize) (x : a) : array a n =
admit()
-let slice_subslice_mut_fwd (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let slice_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let slice_subslice_mut_back (a : Type0) (x : slice a) (r : range usize) (ns : slice a) : result (slice a) =
+let slice_update_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) (ns : slice a) : result (slice a) =
admit()
(*** Vector *)
-type vec (a : Type0) = v:list a{length v <= usize_max}
+type alloc_vec_Vec (a : Type0) = v:list a{length v <= usize_max}
-let vec_new (a : Type0) : vec a = assert_norm(length #a [] == 0); []
-let vec_len (a : Type0) (v : vec a) : usize = length v
+let alloc_vec_Vec_new (a : Type0) : alloc_vec_Vec a = assert_norm(length #a [] == 0); []
+let alloc_vec_Vec_len (a : Type0) (v : alloc_vec_Vec a) : usize = length v
+
+// Helper
+let alloc_vec_Vec_index_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) : result a =
+ if i < length v then Return (index v i) else Fail Failure
+// Helper
+let alloc_vec_Vec_update_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
// The **forward** function shouldn't be used
-let vec_push_fwd (a : Type0) (v : vec a) (x : a) : unit = ()
-let vec_push_back (a : Type0) (v : vec a) (x : a) :
- Pure (result (vec a))
+let alloc_vec_Vec_push_fwd (a : Type0) (v : alloc_vec_Vec a) (x : a) : unit = ()
+let alloc_vec_Vec_push (a : Type0) (v : alloc_vec_Vec a) (x : a) :
+ Pure (result (alloc_vec_Vec a))
(requires True)
(ensures (fun res ->
match res with
@@ -358,18 +451,279 @@ let vec_push_back (a : Type0) (v : vec a) (x : a) :
else Fail Failure
// The **forward** function shouldn't be used
-let vec_insert_fwd (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
+let alloc_vec_Vec_insert_fwd (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result unit =
if i < length v then Return () else Fail Failure
-let vec_insert_back (a : Type0) (v : vec a) (i : usize) (x : a) : result (vec a) =
+let alloc_vec_Vec_insert (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
if i < length v then Return (list_update v i x) else Fail Failure
-// The **backward** function shouldn't be used
-let vec_index_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_back (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
- if i < length v then Return () else Fail Failure
+// Trait declaration: [core::slice::index::private_slice_index::Sealed]
+type core_slice_index_private_slice_index_Sealed (self : Type0) = unit
+
+// Trait declaration: [core::slice::index::SliceIndex]
+noeq type core_slice_index_SliceIndex (self t : Type0) = {
+ sealedInst : core_slice_index_private_slice_index_Sealed self;
+ output : Type0;
+ get : self → t → result (option output);
+ get_mut : self → t → result (option output);
+ get_mut_back : self → t → option output → result t;
+ get_unchecked : self → const_raw_ptr t → result (const_raw_ptr output);
+ get_unchecked_mut : self → mut_raw_ptr t → result (mut_raw_ptr output);
+ index : self → t → result output;
+ index_mut : self → t → result output;
+ index_mut_back : self → t → output → result t;
+}
-let vec_index_mut_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_mut_back (a : Type0) (v : vec a) (i : usize) (nx : a) : result (vec a) =
- if i < length v then Return (list_update v i nx) else Fail Failure
+// [core::slice::index::[T]::index]: forward function
+let core_slice_index_Slice_index
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (s : slice t) (i : idx) : result inst.output =
+ let* x = inst.get i s in
+ match x with
+ | None -> Fail Failure
+ | Some x -> Return x
+
+// [core::slice::index::Range:::get]: forward function
+let core_slice_index_Range_get (t : Type0) (i : core_ops_range_Range usize) (s : slice t) :
+ result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: forward function
+let core_slice_index_Range_get_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: backward function 0
+let core_slice_index_Range_get_mut_back
+ (t : Type0) :
+ core_ops_range_Range usize → slice t → option (slice t) → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_unchecked]: forward function
+let core_slice_index_Range_get_unchecked
+ (t : Type0) :
+ core_ops_range_Range usize → const_raw_ptr (slice t) → result (const_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::get_unchecked_mut]: forward function
+let core_slice_index_Range_get_unchecked_mut
+ (t : Type0) :
+ core_ops_range_Range usize → mut_raw_ptr (slice t) → result (mut_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::index]: forward function
+let core_slice_index_Range_index
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: forward function
+let core_slice_index_Range_index_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: backward function 0
+let core_slice_index_Range_index_mut_back
+ (t : Type0) : core_ops_range_Range usize → slice t → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::[T]::index_mut]: forward function
+let core_slice_index_Slice_index_mut
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → result inst.output =
+ admit () //
+
+// [core::slice::index::[T]::index_mut]: backward function 0
+let core_slice_index_Slice_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → inst.output → result (slice t) =
+ admit () // TODO
+
+// [core::array::[T; N]::index]: forward function
+let core_array_Array_index
+ (t idx : Type0) (n : usize) (inst : core_ops_index_Index (slice t) idx)
+ (a : array t n) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: forward function
+let core_array_Array_index_mut
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) : result inst.indexInst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: backward function 0
+let core_array_Array_index_mut_back
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) (x : inst.indexInst.output) : result (array t n) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (slice t) idx = {
+ output = inst.output;
+ index = core_slice_index_Slice_index t idx inst;
+}
+
+// Trait implementation: [core::slice::index::private_slice_index::Range]
+let core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) = ()
+
+// Trait implementation: [core::slice::index::Range]
+let core_slice_index_Range_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ output = slice t;
+ get = core_slice_index_Range_get t;
+ get_mut = core_slice_index_Range_get_mut t;
+ get_mut_back = core_slice_index_Range_get_mut_back t;
+ get_unchecked = core_slice_index_Range_get_unchecked t;
+ get_unchecked_mut = core_slice_index_Range_get_unchecked_mut t;
+ index = core_slice_index_Range_index t;
+ index_mut = core_slice_index_Range_index_mut t;
+ index_mut_back = core_slice_index_Range_index_mut_back t;
+}
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (slice t) idx = {
+ indexInst = core_slice_index_Slice_coreopsindexIndexInst t idx inst;
+ index_mut = core_slice_index_Slice_index_mut t idx inst;
+ index_mut_back = core_slice_index_Slice_index_mut_back t idx inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_Index (slice t) idx) :
+ core_ops_index_Index (array t n) idx = {
+ output = inst.output;
+ index = core_array_Array_index t idx n inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexMutInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_IndexMut (slice t) idx) :
+ core_ops_index_IndexMut (array t n) idx = {
+ indexInst = core_array_Array_coreopsindexIndexInst t idx n inst.indexInst;
+ index_mut = core_array_Array_index_mut t idx n inst;
+ index_mut_back = core_array_Array_index_mut_back t idx n inst;
+}
+
+// [core::slice::index::usize::get]: forward function
+let core_slice_index_usize_get
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: forward function
+let core_slice_index_usize_get_mut
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: backward function 0
+let core_slice_index_usize_get_mut_back
+ (t : Type0) : usize → slice t → option t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked]: forward function
+let core_slice_index_usize_get_unchecked
+ (t : Type0) : usize → const_raw_ptr (slice t) → result (const_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked_mut]: forward function
+let core_slice_index_usize_get_unchecked_mut
+ (t : Type0) : usize → mut_raw_ptr (slice t) → result (mut_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::index]: forward function
+let core_slice_index_usize_index (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: forward function
+let core_slice_index_usize_index_mut (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: backward function 0
+let core_slice_index_usize_index_mut_back
+ (t : Type0) : usize → slice t → t → result (slice t) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::private_slice_index::usize]
+let core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize = ()
+
+// Trait implementation: [core::slice::index::usize]
+let core_slice_index_usize_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex usize (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ output = t;
+ get = core_slice_index_usize_get t;
+ get_mut = core_slice_index_usize_get_mut t;
+ get_mut_back = core_slice_index_usize_get_mut_back t;
+ get_unchecked = core_slice_index_usize_get_unchecked t;
+ get_unchecked_mut = core_slice_index_usize_get_unchecked_mut t;
+ index = core_slice_index_usize_index t;
+ index_mut = core_slice_index_usize_index_mut t;
+ index_mut_back = core_slice_index_usize_index_mut_back t;
+}
+
+// [alloc::vec::Vec::index]: forward function
+let alloc_vec_Vec_index (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: forward function
+let alloc_vec_Vec_index_mut (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: backward function 0
+let alloc_vec_Vec_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) (x : inst.output) : result (alloc_vec_Vec t) =
+ admit () // TODO
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (alloc_vec_Vec t) idx = {
+ output = inst.output;
+ index = alloc_vec_Vec_index t idx inst;
+}
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (alloc_vec_Vec t) idx = {
+ indexInst = alloc_vec_Vec_coreopsindexIndexInst t idx inst;
+ index_mut = alloc_vec_Vec_index_mut t idx inst;
+ index_mut_back = alloc_vec_Vec_index_mut_back t idx inst;
+}
+
+(*** Theorems *)
+
+let alloc_vec_Vec_index_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_back_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) :
+ Lemma (
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x ==
+ alloc_vec_Vec_update_usize v i x)
+ [SMTPat (alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x)]
+ =
+ admit()
diff --git a/tests/fstar/misc/Constants.fst b/tests/fstar/misc/Constants.fst
index d2b0415e..c21d6a5f 100644
--- a/tests/fstar/misc/Constants.fst
+++ b/tests/fstar/misc/Constants.fst
@@ -9,12 +9,8 @@ open Primitives
let x0_body : result u32 = Return 0
let x0_c : u32 = eval_global x0_body
-(** [core::num::u32::{8}::MAX] *)
-let core_num_u32_max_body : result u32 = Return 4294967295
-let core_num_u32_max_c : u32 = eval_global core_num_u32_max_body
-
(** [constants::X1] *)
-let x1_body : result u32 = Return core_num_u32_max_c
+let x1_body : result u32 = Return core_u32_max
let x1_c : u32 = eval_global x1_body
(** [constants::X2] *)
@@ -22,30 +18,30 @@ let x2_body : result u32 = Return 3
let x2_c : u32 = eval_global x2_body
(** [constants::incr]: forward function *)
-let incr_fwd (n : u32) : result u32 =
+let incr (n : u32) : result u32 =
u32_add n 1
(** [constants::X3] *)
-let x3_body : result u32 = incr_fwd 32
+let x3_body : result u32 = incr 32
let x3_c : u32 = eval_global x3_body
(** [constants::mk_pair0]: forward function *)
-let mk_pair0_fwd (x : u32) (y : u32) : result (u32 & u32) =
+let mk_pair0 (x : u32) (y : u32) : result (u32 & u32) =
Return (x, y)
(** [constants::Pair] *)
-type pair_t (t1 t2 : Type0) = { pair_x : t1; pair_y : t2; }
+type pair_t (t1 t2 : Type0) = { x : t1; y : t2; }
(** [constants::mk_pair1]: forward function *)
-let mk_pair1_fwd (x : u32) (y : u32) : result (pair_t u32 u32) =
- Return { pair_x = x; pair_y = y }
+let mk_pair1 (x : u32) (y : u32) : result (pair_t u32 u32) =
+ Return { x = x; y = y }
(** [constants::P0] *)
-let p0_body : result (u32 & u32) = mk_pair0_fwd 0 1
+let p0_body : result (u32 & u32) = mk_pair0 0 1
let p0_c : (u32 & u32) = eval_global p0_body
(** [constants::P1] *)
-let p1_body : result (pair_t u32 u32) = mk_pair1_fwd 0 1
+let p1_body : result (pair_t u32 u32) = mk_pair1 0 1
let p1_c : pair_t u32 u32 = eval_global p1_body
(** [constants::P2] *)
@@ -53,26 +49,26 @@ let p2_body : result (u32 & u32) = Return (0, 1)
let p2_c : (u32 & u32) = eval_global p2_body
(** [constants::P3] *)
-let p3_body : result (pair_t u32 u32) = Return { pair_x = 0; pair_y = 1 }
+let p3_body : result (pair_t u32 u32) = Return { x = 0; y = 1 }
let p3_c : pair_t u32 u32 = eval_global p3_body
(** [constants::Wrap] *)
-type wrap_t (t : Type0) = { wrap_val : t; }
+type wrap_t (t : Type0) = { value : t; }
(** [constants::Wrap::{0}::new]: forward function *)
-let wrap_new_fwd (t : Type0) (val0 : t) : result (wrap_t t) =
- Return { wrap_val = val0 }
+let wrap_new (t : Type0) (value : t) : result (wrap_t t) =
+ Return { value = value }
(** [constants::Y] *)
-let y_body : result (wrap_t i32) = wrap_new_fwd i32 2
+let y_body : result (wrap_t i32) = wrap_new i32 2
let y_c : wrap_t i32 = eval_global y_body
(** [constants::unwrap_y]: forward function *)
-let unwrap_y_fwd : result i32 =
- Return y_c.wrap_val
+let unwrap_y : result i32 =
+ Return y_c.value
(** [constants::YVAL] *)
-let yval_body : result i32 = unwrap_y_fwd
+let yval_body : result i32 = unwrap_y
let yval_c : i32 = eval_global yval_body
(** [constants::get_z1::Z1] *)
@@ -80,11 +76,11 @@ let get_z1_z1_body : result i32 = Return 3
let get_z1_z1_c : i32 = eval_global get_z1_z1_body
(** [constants::get_z1]: forward function *)
-let get_z1_fwd : result i32 =
+let get_z1 : result i32 =
Return get_z1_z1_c
(** [constants::add]: forward function *)
-let add_fwd (a : i32) (b : i32) : result i32 =
+let add (a : i32) (b : i32) : result i32 =
i32_add a b
(** [constants::Q1] *)
@@ -96,19 +92,19 @@ let q2_body : result i32 = Return q1_c
let q2_c : i32 = eval_global q2_body
(** [constants::Q3] *)
-let q3_body : result i32 = add_fwd q2_c 3
+let q3_body : result i32 = add q2_c 3
let q3_c : i32 = eval_global q3_body
(** [constants::get_z2]: forward function *)
-let get_z2_fwd : result i32 =
- let* i = get_z1_fwd in let* i0 = add_fwd i q3_c in add_fwd q1_c i0
+let get_z2 : result i32 =
+ let* i = get_z1 in let* i0 = add i q3_c in add q1_c i0
(** [constants::S1] *)
let s1_body : result u32 = Return 6
let s1_c : u32 = eval_global s1_body
(** [constants::S2] *)
-let s2_body : result u32 = incr_fwd s1_c
+let s2_body : result u32 = incr s1_c
let s2_c : u32 = eval_global s2_body
(** [constants::S3] *)
@@ -116,6 +112,6 @@ let s3_body : result (pair_t u32 u32) = Return p3_c
let s3_c : pair_t u32 u32 = eval_global s3_body
(** [constants::S4] *)
-let s4_body : result (pair_t u32 u32) = mk_pair1_fwd 7 8
+let s4_body : result (pair_t u32 u32) = mk_pair1 7 8
let s4_c : pair_t u32 u32 = eval_global s4_body
diff --git a/tests/fstar/misc/External.Funs.fst b/tests/fstar/misc/External.Funs.fst
index f118a2cf..e26014ac 100644
--- a/tests/fstar/misc/External.Funs.fst
+++ b/tests/fstar/misc/External.Funs.fst
@@ -8,8 +8,8 @@ include External.Opaque
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [external::swap]: forward function *)
-let swap_fwd (t : Type0) (x : t) (y : t) (st : state) : result (state & unit) =
- let* (st0, _) = core_mem_swap_fwd t x y st in
+let swap (t : Type0) (x : t) (y : t) (st : state) : result (state & unit) =
+ let* (st0, _) = core_mem_swap t x y st in
let* (st1, _) = core_mem_swap_back0 t x y st st0 in
let* (st2, _) = core_mem_swap_back1 t x y st st1 in
Return (st2, ())
@@ -19,28 +19,29 @@ let swap_back
(t : Type0) (x : t) (y : t) (st : state) (st0 : state) :
result (state & (t & t))
=
- let* (st1, _) = core_mem_swap_fwd t x y st in
+ let* (st1, _) = core_mem_swap t x y st in
let* (st2, x0) = core_mem_swap_back0 t x y st st1 in
let* (_, y0) = core_mem_swap_back1 t x y st st2 in
Return (st0, (x0, y0))
(** [external::test_new_non_zero_u32]: forward function *)
-let test_new_non_zero_u32_fwd
- (x : u32) (st : state) : result (state & core_num_nonzero_non_zero_u32_t) =
- let* (st0, opt) = core_num_nonzero_non_zero_u32_new_fwd x st in
- core_option_option_unwrap_fwd core_num_nonzero_non_zero_u32_t opt st0
+let test_new_non_zero_u32
+ (x : u32) (st : state) : result (state & core_num_nonzero_NonZeroU32_t) =
+ let* (st0, o) = core_num_nonzero_NonZeroU32_new x st in
+ core_option_Option_unwrap core_num_nonzero_NonZeroU32_t o st0
(** [external::test_vec]: forward function *)
-let test_vec_fwd : result unit =
- let v = vec_new u32 in let* _ = vec_push_back u32 v 0 in Return ()
+let test_vec : result unit =
+ let v = alloc_vec_Vec_new u32 in
+ let* _ = alloc_vec_Vec_push u32 v 0 in
+ Return ()
(** Unit test for [external::test_vec] *)
-let _ = assert_norm (test_vec_fwd = Return ())
+let _ = assert_norm (test_vec = Return ())
(** [external::custom_swap]: forward function *)
-let custom_swap_fwd
- (t : Type0) (x : t) (y : t) (st : state) : result (state & t) =
- let* (st0, _) = core_mem_swap_fwd t x y st in
+let custom_swap (t : Type0) (x : t) (y : t) (st : state) : result (state & t) =
+ let* (st0, _) = core_mem_swap t x y st in
let* (st1, x0) = core_mem_swap_back0 t x y st st0 in
let* (st2, _) = core_mem_swap_back1 t x y st st1 in
Return (st2, x0)
@@ -50,15 +51,14 @@ let custom_swap_back
(t : Type0) (x : t) (y : t) (st : state) (ret : t) (st0 : state) :
result (state & (t & t))
=
- let* (st1, _) = core_mem_swap_fwd t x y st in
+ let* (st1, _) = core_mem_swap t x y st in
let* (st2, _) = core_mem_swap_back0 t x y st st1 in
let* (_, y0) = core_mem_swap_back1 t x y st st2 in
Return (st0, (ret, y0))
(** [external::test_custom_swap]: forward function *)
-let test_custom_swap_fwd
- (x : u32) (y : u32) (st : state) : result (state & unit) =
- let* (st0, _) = custom_swap_fwd u32 x y st in Return (st0, ())
+let test_custom_swap (x : u32) (y : u32) (st : state) : result (state & unit) =
+ let* (st0, _) = custom_swap u32 x y st in Return (st0, ())
(** [external::test_custom_swap]: backward function 0 *)
let test_custom_swap_back
@@ -68,8 +68,8 @@ let test_custom_swap_back
custom_swap_back u32 x y st 1 st0
(** [external::test_swap_non_zero]: forward function *)
-let test_swap_non_zero_fwd (x : u32) (st : state) : result (state & u32) =
- let* (st0, _) = swap_fwd u32 x 0 st in
+let test_swap_non_zero (x : u32) (st : state) : result (state & u32) =
+ let* (st0, _) = swap u32 x 0 st in
let* (st1, (x0, _)) = swap_back u32 x 0 st st0 in
if x0 = 0 then Fail Failure else Return (st1, x0)
diff --git a/tests/fstar/misc/External.Opaque.fsti b/tests/fstar/misc/External.Opaque.fsti
index 2e19f767..85cf285c 100644
--- a/tests/fstar/misc/External.Opaque.fsti
+++ b/tests/fstar/misc/External.Opaque.fsti
@@ -7,7 +7,7 @@ include External.Types
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [core::mem::swap]: forward function *)
-val core_mem_swap_fwd (t : Type0) : t -> t -> state -> result (state & unit)
+val core_mem_swap (t : Type0) : t -> t -> state -> result (state & unit)
(** [core::mem::swap]: backward function 0 *)
val core_mem_swap_back0
@@ -18,10 +18,10 @@ val core_mem_swap_back1
(t : Type0) : t -> t -> state -> state -> result (state & t)
(** [core::num::nonzero::NonZeroU32::{14}::new]: forward function *)
-val core_num_nonzero_non_zero_u32_new_fwd
- : u32 -> state -> result (state & (option core_num_nonzero_non_zero_u32_t))
+val core_num_nonzero_NonZeroU32_new
+ : u32 -> state -> result (state & (option core_num_nonzero_NonZeroU32_t))
(** [core::option::Option::{0}::unwrap]: forward function *)
-val core_option_option_unwrap_fwd
+val core_option_Option_unwrap
(t : Type0) : option t -> state -> result (state & t)
diff --git a/tests/fstar/misc/External.Types.fsti b/tests/fstar/misc/External.Types.fsti
index 4a13a744..78b5228d 100644
--- a/tests/fstar/misc/External.Types.fsti
+++ b/tests/fstar/misc/External.Types.fsti
@@ -6,7 +6,7 @@ open Primitives
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [core::num::nonzero::NonZeroU32] *)
-val core_num_nonzero_non_zero_u32_t : Type0
+val core_num_nonzero_NonZeroU32_t : Type0
(** The state type used in the state-error monad *)
val state : Type0
diff --git a/tests/fstar/misc/Loops.Clauses.Template.fst b/tests/fstar/misc/Loops.Clauses.Template.fst
index 053b7663..9920bdc1 100644
--- a/tests/fstar/misc/Loops.Clauses.Template.fst
+++ b/tests/fstar/misc/Loops.Clauses.Template.fst
@@ -22,7 +22,8 @@ let sum_with_shared_borrows_loop_decreases (max : u32) (i : u32) (s : u32) :
admit ()
(** [loops::clear]: decreases clause *)
-unfold let clear_loop_decreases (v : vec u32) (i : usize) : nat = admit ()
+unfold
+let clear_loop_decreases (v : alloc_vec_Vec u32) (i : usize) : nat = admit ()
(** [loops::list_mem]: decreases clause *)
unfold let list_mem_loop_decreases (x : u32) (ls : list_t u32) : nat = admit ()
diff --git a/tests/fstar/misc/Loops.Clauses.fst b/tests/fstar/misc/Loops.Clauses.fst
index 82f34de1..75194437 100644
--- a/tests/fstar/misc/Loops.Clauses.fst
+++ b/tests/fstar/misc/Loops.Clauses.fst
@@ -20,7 +20,7 @@ let sum_with_shared_borrows_loop_decreases (max : u32) (i : u32) (s : u32) : nat
if max >= i then max - i else 0
(** [loops::clear]: decreases clause *)
-unfold let clear_loop_decreases (v : vec u32) (i : usize) : nat =
+unfold let clear_loop_decreases (v : alloc_vec_Vec u32) (i : usize) : nat =
if i <= List.Tot.length v then List.Tot.length v - i else 0
(** [loops::list_mem]: decreases clause *)
diff --git a/tests/fstar/misc/Loops.Funs.fst b/tests/fstar/misc/Loops.Funs.fst
index 9a80f415..0f755351 100644
--- a/tests/fstar/misc/Loops.Funs.fst
+++ b/tests/fstar/misc/Loops.Funs.fst
@@ -8,20 +8,20 @@ include Loops.Clauses
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [loops::sum]: loop 0: forward function *)
-let rec sum_loop_fwd
+let rec sum_loop
(max : u32) (i : u32) (s : u32) :
Tot (result u32) (decreases (sum_loop_decreases max i s))
=
if i < max
- then let* s0 = u32_add s i in let* i0 = u32_add i 1 in sum_loop_fwd max i0 s0
+ then let* s0 = u32_add s i in let* i0 = u32_add i 1 in sum_loop max i0 s0
else u32_mul s 2
(** [loops::sum]: forward function *)
-let sum_fwd (max : u32) : result u32 =
- sum_loop_fwd max 0 0
+let sum (max : u32) : result u32 =
+ sum_loop max 0 0
(** [loops::sum_with_mut_borrows]: loop 0: forward function *)
-let rec sum_with_mut_borrows_loop_fwd
+let rec sum_with_mut_borrows_loop
(max : u32) (mi : u32) (ms : u32) :
Tot (result u32) (decreases (sum_with_mut_borrows_loop_decreases max mi ms))
=
@@ -29,15 +29,15 @@ let rec sum_with_mut_borrows_loop_fwd
then
let* ms0 = u32_add ms mi in
let* mi0 = u32_add mi 1 in
- sum_with_mut_borrows_loop_fwd max mi0 ms0
+ sum_with_mut_borrows_loop max mi0 ms0
else u32_mul ms 2
(** [loops::sum_with_mut_borrows]: forward function *)
-let sum_with_mut_borrows_fwd (max : u32) : result u32 =
- sum_with_mut_borrows_loop_fwd max 0 0
+let sum_with_mut_borrows (max : u32) : result u32 =
+ sum_with_mut_borrows_loop max 0 0
(** [loops::sum_with_shared_borrows]: loop 0: forward function *)
-let rec sum_with_shared_borrows_loop_fwd
+let rec sum_with_shared_borrows_loop
(max : u32) (i : u32) (s : u32) :
Tot (result u32) (decreases (sum_with_shared_borrows_loop_decreases max i s))
=
@@ -45,62 +45,64 @@ let rec sum_with_shared_borrows_loop_fwd
then
let* i0 = u32_add i 1 in
let* s0 = u32_add s i0 in
- sum_with_shared_borrows_loop_fwd max i0 s0
+ sum_with_shared_borrows_loop max i0 s0
else u32_mul s 2
(** [loops::sum_with_shared_borrows]: forward function *)
-let sum_with_shared_borrows_fwd (max : u32) : result u32 =
- sum_with_shared_borrows_loop_fwd max 0 0
+let sum_with_shared_borrows (max : u32) : result u32 =
+ sum_with_shared_borrows_loop max 0 0
(** [loops::clear]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let rec clear_loop_fwd_back
- (v : vec u32) (i : usize) :
- Tot (result (vec u32)) (decreases (clear_loop_decreases v i))
+let rec clear_loop
+ (v : alloc_vec_Vec u32) (i : usize) :
+ Tot (result (alloc_vec_Vec u32)) (decreases (clear_loop_decreases v i))
=
- let i0 = vec_len u32 v in
+ let i0 = alloc_vec_Vec_len u32 v in
if i < i0
then
let* i1 = usize_add i 1 in
- let* v0 = vec_index_mut_back u32 v i 0 in
- clear_loop_fwd_back v0 i1
+ let* v0 =
+ alloc_vec_Vec_index_mut_back u32 usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst u32) v i 0 in
+ clear_loop v0 i1
else Return v
(** [loops::clear]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let clear_fwd_back (v : vec u32) : result (vec u32) =
- clear_loop_fwd_back v 0
+let clear (v : alloc_vec_Vec u32) : result (alloc_vec_Vec u32) =
+ clear_loop v 0
(** [loops::list_mem]: loop 0: forward function *)
-let rec list_mem_loop_fwd
+let rec list_mem_loop
(x : u32) (ls : list_t u32) :
Tot (result bool) (decreases (list_mem_loop_decreases x ls))
=
begin match ls with
- | ListCons y tl -> if y = x then Return true else list_mem_loop_fwd x tl
- | ListNil -> Return false
+ | List_Cons y tl -> if y = x then Return true else list_mem_loop x tl
+ | List_Nil -> Return false
end
(** [loops::list_mem]: forward function *)
-let list_mem_fwd (x : u32) (ls : list_t u32) : result bool =
- list_mem_loop_fwd x ls
+let list_mem (x : u32) (ls : list_t u32) : result bool =
+ list_mem_loop x ls
(** [loops::list_nth_mut_loop]: loop 0: forward function *)
-let rec list_nth_mut_loop_loop_fwd
+let rec list_nth_mut_loop_loop
(t : Type0) (ls : list_t t) (i : u32) :
Tot (result t) (decreases (list_nth_mut_loop_loop_decreases t ls i))
=
begin match ls with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
then Return x
- else let* i0 = u32_sub i 1 in list_nth_mut_loop_loop_fwd t tl i0
- | ListNil -> Fail Failure
+ else let* i0 = u32_sub i 1 in list_nth_mut_loop_loop t tl i0
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop]: forward function *)
-let list_nth_mut_loop_fwd (t : Type0) (ls : list_t t) (i : u32) : result t =
- list_nth_mut_loop_loop_fwd t ls i
+let list_nth_mut_loop (t : Type0) (ls : list_t t) (i : u32) : result t =
+ list_nth_mut_loop_loop t ls i
(** [loops::list_nth_mut_loop]: loop 0: backward function 0 *)
let rec list_nth_mut_loop_loop_back
@@ -108,14 +110,14 @@ let rec list_nth_mut_loop_loop_back
Tot (result (list_t t)) (decreases (list_nth_mut_loop_loop_decreases t ls i))
=
begin match ls with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
- then Return (ListCons ret tl)
+ then Return (List_Cons ret tl)
else
let* i0 = u32_sub i 1 in
let* tl0 = list_nth_mut_loop_loop_back t tl i0 ret in
- Return (ListCons x tl0)
- | ListNil -> Fail Failure
+ Return (List_Cons x tl0)
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop]: backward function 0 *)
@@ -124,36 +126,40 @@ let list_nth_mut_loop_back
list_nth_mut_loop_loop_back t ls i ret
(** [loops::list_nth_shared_loop]: loop 0: forward function *)
-let rec list_nth_shared_loop_loop_fwd
+let rec list_nth_shared_loop_loop
(t : Type0) (ls : list_t t) (i : u32) :
Tot (result t) (decreases (list_nth_shared_loop_loop_decreases t ls i))
=
begin match ls with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
then Return x
- else let* i0 = u32_sub i 1 in list_nth_shared_loop_loop_fwd t tl i0
- | ListNil -> Fail Failure
+ else let* i0 = u32_sub i 1 in list_nth_shared_loop_loop t tl i0
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_shared_loop]: forward function *)
-let list_nth_shared_loop_fwd (t : Type0) (ls : list_t t) (i : u32) : result t =
- list_nth_shared_loop_loop_fwd t ls i
+let list_nth_shared_loop (t : Type0) (ls : list_t t) (i : u32) : result t =
+ list_nth_shared_loop_loop t ls i
(** [loops::get_elem_mut]: loop 0: forward function *)
-let rec get_elem_mut_loop_fwd
+let rec get_elem_mut_loop
(x : usize) (ls : list_t usize) :
Tot (result usize) (decreases (get_elem_mut_loop_decreases x ls))
=
begin match ls with
- | ListCons y tl -> if y = x then Return y else get_elem_mut_loop_fwd x tl
- | ListNil -> Fail Failure
+ | List_Cons y tl -> if y = x then Return y else get_elem_mut_loop x tl
+ | List_Nil -> Fail Failure
end
(** [loops::get_elem_mut]: forward function *)
-let get_elem_mut_fwd (slots : vec (list_t usize)) (x : usize) : result usize =
- let* l = vec_index_mut_fwd (list_t usize) slots 0 in
- get_elem_mut_loop_fwd x l
+let get_elem_mut
+ (slots : alloc_vec_Vec (list_t usize)) (x : usize) : result usize =
+ let* l =
+ alloc_vec_Vec_index_mut (list_t usize) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t usize))
+ slots 0 in
+ get_elem_mut_loop x l
(** [loops::get_elem_mut]: loop 0: backward function 0 *)
let rec get_elem_mut_loop_back
@@ -161,39 +167,48 @@ let rec get_elem_mut_loop_back
Tot (result (list_t usize)) (decreases (get_elem_mut_loop_decreases x ls))
=
begin match ls with
- | ListCons y tl ->
+ | List_Cons y tl ->
if y = x
- then Return (ListCons ret tl)
- else let* tl0 = get_elem_mut_loop_back x tl ret in Return (ListCons y tl0)
- | ListNil -> Fail Failure
+ then Return (List_Cons ret tl)
+ else let* tl0 = get_elem_mut_loop_back x tl ret in Return (List_Cons y tl0)
+ | List_Nil -> Fail Failure
end
(** [loops::get_elem_mut]: backward function 0 *)
let get_elem_mut_back
- (slots : vec (list_t usize)) (x : usize) (ret : usize) :
- result (vec (list_t usize))
+ (slots : alloc_vec_Vec (list_t usize)) (x : usize) (ret : usize) :
+ result (alloc_vec_Vec (list_t usize))
=
- let* l = vec_index_mut_fwd (list_t usize) slots 0 in
+ let* l =
+ alloc_vec_Vec_index_mut (list_t usize) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t usize))
+ slots 0 in
let* l0 = get_elem_mut_loop_back x l ret in
- vec_index_mut_back (list_t usize) slots 0 l0
+ alloc_vec_Vec_index_mut_back (list_t usize) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t usize)) slots
+ 0 l0
(** [loops::get_elem_shared]: loop 0: forward function *)
-let rec get_elem_shared_loop_fwd
+let rec get_elem_shared_loop
(x : usize) (ls : list_t usize) :
Tot (result usize) (decreases (get_elem_shared_loop_decreases x ls))
=
begin match ls with
- | ListCons y tl -> if y = x then Return y else get_elem_shared_loop_fwd x tl
- | ListNil -> Fail Failure
+ | List_Cons y tl -> if y = x then Return y else get_elem_shared_loop x tl
+ | List_Nil -> Fail Failure
end
(** [loops::get_elem_shared]: forward function *)
-let get_elem_shared_fwd
- (slots : vec (list_t usize)) (x : usize) : result usize =
- let* l = vec_index_fwd (list_t usize) slots 0 in get_elem_shared_loop_fwd x l
+let get_elem_shared
+ (slots : alloc_vec_Vec (list_t usize)) (x : usize) : result usize =
+ let* l =
+ alloc_vec_Vec_index (list_t usize) usize
+ (core_slice_index_usize_coresliceindexSliceIndexInst (list_t usize))
+ slots 0 in
+ get_elem_shared_loop x l
(** [loops::id_mut]: forward function *)
-let id_mut_fwd (t : Type0) (ls : list_t t) : result (list_t t) =
+let id_mut (t : Type0) (ls : list_t t) : result (list_t t) =
Return ls
(** [loops::id_mut]: backward function 0 *)
@@ -202,26 +217,26 @@ let id_mut_back
Return ret
(** [loops::id_shared]: forward function *)
-let id_shared_fwd (t : Type0) (ls : list_t t) : result (list_t t) =
+let id_shared (t : Type0) (ls : list_t t) : result (list_t t) =
Return ls
(** [loops::list_nth_mut_loop_with_id]: loop 0: forward function *)
-let rec list_nth_mut_loop_with_id_loop_fwd
+let rec list_nth_mut_loop_with_id_loop
(t : Type0) (i : u32) (ls : list_t t) :
Tot (result t) (decreases (list_nth_mut_loop_with_id_loop_decreases t i ls))
=
begin match ls with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
then Return x
- else let* i0 = u32_sub i 1 in list_nth_mut_loop_with_id_loop_fwd t i0 tl
- | ListNil -> Fail Failure
+ else let* i0 = u32_sub i 1 in list_nth_mut_loop_with_id_loop t i0 tl
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop_with_id]: forward function *)
-let list_nth_mut_loop_with_id_fwd
+let list_nth_mut_loop_with_id
(t : Type0) (ls : list_t t) (i : u32) : result t =
- let* ls0 = id_mut_fwd t ls in list_nth_mut_loop_with_id_loop_fwd t i ls0
+ let* ls0 = id_mut t ls in list_nth_mut_loop_with_id_loop t i ls0
(** [loops::list_nth_mut_loop_with_id]: loop 0: backward function 0 *)
let rec list_nth_mut_loop_with_id_loop_back
@@ -230,66 +245,64 @@ let rec list_nth_mut_loop_with_id_loop_back
(decreases (list_nth_mut_loop_with_id_loop_decreases t i ls))
=
begin match ls with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
- then Return (ListCons ret tl)
+ then Return (List_Cons ret tl)
else
let* i0 = u32_sub i 1 in
let* tl0 = list_nth_mut_loop_with_id_loop_back t i0 tl ret in
- Return (ListCons x tl0)
- | ListNil -> Fail Failure
+ Return (List_Cons x tl0)
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop_with_id]: backward function 0 *)
let list_nth_mut_loop_with_id_back
(t : Type0) (ls : list_t t) (i : u32) (ret : t) : result (list_t t) =
- let* ls0 = id_mut_fwd t ls in
+ let* ls0 = id_mut t ls in
let* l = list_nth_mut_loop_with_id_loop_back t i ls0 ret in
id_mut_back t ls l
(** [loops::list_nth_shared_loop_with_id]: loop 0: forward function *)
-let rec list_nth_shared_loop_with_id_loop_fwd
+let rec list_nth_shared_loop_with_id_loop
(t : Type0) (i : u32) (ls : list_t t) :
Tot (result t)
(decreases (list_nth_shared_loop_with_id_loop_decreases t i ls))
=
begin match ls with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
then Return x
- else let* i0 = u32_sub i 1 in list_nth_shared_loop_with_id_loop_fwd t i0 tl
- | ListNil -> Fail Failure
+ else let* i0 = u32_sub i 1 in list_nth_shared_loop_with_id_loop t i0 tl
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_shared_loop_with_id]: forward function *)
-let list_nth_shared_loop_with_id_fwd
+let list_nth_shared_loop_with_id
(t : Type0) (ls : list_t t) (i : u32) : result t =
- let* ls0 = id_shared_fwd t ls in
- list_nth_shared_loop_with_id_loop_fwd t i ls0
+ let* ls0 = id_shared t ls in list_nth_shared_loop_with_id_loop t i ls0
(** [loops::list_nth_mut_loop_pair]: loop 0: forward function *)
-let rec list_nth_mut_loop_pair_loop_fwd
+let rec list_nth_mut_loop_pair_loop
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) :
Tot (result (t & t))
(decreases (list_nth_mut_loop_pair_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
then Return (x0, x1)
- else
- let* i0 = u32_sub i 1 in list_nth_mut_loop_pair_loop_fwd t tl0 tl1 i0
- | ListNil -> Fail Failure
+ else let* i0 = u32_sub i 1 in list_nth_mut_loop_pair_loop t tl0 tl1 i0
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop_pair]: forward function *)
-let list_nth_mut_loop_pair_fwd
+let list_nth_mut_loop_pair
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) : result (t & t) =
- list_nth_mut_loop_pair_loop_fwd t ls0 ls1 i
+ list_nth_mut_loop_pair_loop t ls0 ls1 i
(** [loops::list_nth_mut_loop_pair]: loop 0: backward function 0 *)
let rec list_nth_mut_loop_pair_loop_back'a
@@ -298,18 +311,18 @@ let rec list_nth_mut_loop_pair_loop_back'a
(decreases (list_nth_mut_loop_pair_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
- then Return (ListCons ret tl0)
+ then Return (List_Cons ret tl0)
else
let* i0 = u32_sub i 1 in
let* tl00 = list_nth_mut_loop_pair_loop_back'a t tl0 tl1 i0 ret in
- Return (ListCons x0 tl00)
- | ListNil -> Fail Failure
+ Return (List_Cons x0 tl00)
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop_pair]: backward function 0 *)
@@ -326,18 +339,18 @@ let rec list_nth_mut_loop_pair_loop_back'b
(decreases (list_nth_mut_loop_pair_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
- then Return (ListCons ret tl1)
+ then Return (List_Cons ret tl1)
else
let* i0 = u32_sub i 1 in
let* tl10 = list_nth_mut_loop_pair_loop_back'b t tl0 tl1 i0 ret in
- Return (ListCons x1 tl10)
- | ListNil -> Fail Failure
+ Return (List_Cons x1 tl10)
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop_pair]: backward function 1 *)
@@ -348,54 +361,51 @@ let list_nth_mut_loop_pair_back'b
list_nth_mut_loop_pair_loop_back'b t ls0 ls1 i ret
(** [loops::list_nth_shared_loop_pair]: loop 0: forward function *)
-let rec list_nth_shared_loop_pair_loop_fwd
+let rec list_nth_shared_loop_pair_loop
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) :
Tot (result (t & t))
(decreases (list_nth_shared_loop_pair_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
then Return (x0, x1)
- else
- let* i0 = u32_sub i 1 in
- list_nth_shared_loop_pair_loop_fwd t tl0 tl1 i0
- | ListNil -> Fail Failure
+ else let* i0 = u32_sub i 1 in list_nth_shared_loop_pair_loop t tl0 tl1 i0
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_shared_loop_pair]: forward function *)
-let list_nth_shared_loop_pair_fwd
+let list_nth_shared_loop_pair
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) : result (t & t) =
- list_nth_shared_loop_pair_loop_fwd t ls0 ls1 i
+ list_nth_shared_loop_pair_loop t ls0 ls1 i
(** [loops::list_nth_mut_loop_pair_merge]: loop 0: forward function *)
-let rec list_nth_mut_loop_pair_merge_loop_fwd
+let rec list_nth_mut_loop_pair_merge_loop
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) :
Tot (result (t & t))
(decreases (list_nth_mut_loop_pair_merge_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
then Return (x0, x1)
else
- let* i0 = u32_sub i 1 in
- list_nth_mut_loop_pair_merge_loop_fwd t tl0 tl1 i0
- | ListNil -> Fail Failure
+ let* i0 = u32_sub i 1 in list_nth_mut_loop_pair_merge_loop t tl0 tl1 i0
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop_pair_merge]: forward function *)
-let list_nth_mut_loop_pair_merge_fwd
+let list_nth_mut_loop_pair_merge
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) : result (t & t) =
- list_nth_mut_loop_pair_merge_loop_fwd t ls0 ls1 i
+ list_nth_mut_loop_pair_merge_loop t ls0 ls1 i
(** [loops::list_nth_mut_loop_pair_merge]: loop 0: backward function 0 *)
let rec list_nth_mut_loop_pair_merge_loop_back
@@ -404,19 +414,19 @@ let rec list_nth_mut_loop_pair_merge_loop_back
(decreases (list_nth_mut_loop_pair_merge_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
- then let (x, x2) = ret in Return (ListCons x tl0, ListCons x2 tl1)
+ then let (x, x2) = ret in Return (List_Cons x tl0, List_Cons x2 tl1)
else
let* i0 = u32_sub i 1 in
let* (tl00, tl10) =
list_nth_mut_loop_pair_merge_loop_back t tl0 tl1 i0 ret in
- Return (ListCons x0 tl00, ListCons x1 tl10)
- | ListNil -> Fail Failure
+ Return (List_Cons x0 tl00, List_Cons x1 tl10)
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_loop_pair_merge]: backward function 0 *)
@@ -427,54 +437,54 @@ let list_nth_mut_loop_pair_merge_back
list_nth_mut_loop_pair_merge_loop_back t ls0 ls1 i ret
(** [loops::list_nth_shared_loop_pair_merge]: loop 0: forward function *)
-let rec list_nth_shared_loop_pair_merge_loop_fwd
+let rec list_nth_shared_loop_pair_merge_loop
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) :
Tot (result (t & t))
(decreases (list_nth_shared_loop_pair_merge_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
then Return (x0, x1)
else
let* i0 = u32_sub i 1 in
- list_nth_shared_loop_pair_merge_loop_fwd t tl0 tl1 i0
- | ListNil -> Fail Failure
+ list_nth_shared_loop_pair_merge_loop t tl0 tl1 i0
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_shared_loop_pair_merge]: forward function *)
-let list_nth_shared_loop_pair_merge_fwd
+let list_nth_shared_loop_pair_merge
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) : result (t & t) =
- list_nth_shared_loop_pair_merge_loop_fwd t ls0 ls1 i
+ list_nth_shared_loop_pair_merge_loop t ls0 ls1 i
(** [loops::list_nth_mut_shared_loop_pair]: loop 0: forward function *)
-let rec list_nth_mut_shared_loop_pair_loop_fwd
+let rec list_nth_mut_shared_loop_pair_loop
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) :
Tot (result (t & t))
(decreases (list_nth_mut_shared_loop_pair_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
then Return (x0, x1)
else
let* i0 = u32_sub i 1 in
- list_nth_mut_shared_loop_pair_loop_fwd t tl0 tl1 i0
- | ListNil -> Fail Failure
+ list_nth_mut_shared_loop_pair_loop t tl0 tl1 i0
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_shared_loop_pair]: forward function *)
-let list_nth_mut_shared_loop_pair_fwd
+let list_nth_mut_shared_loop_pair
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) : result (t & t) =
- list_nth_mut_shared_loop_pair_loop_fwd t ls0 ls1 i
+ list_nth_mut_shared_loop_pair_loop t ls0 ls1 i
(** [loops::list_nth_mut_shared_loop_pair]: loop 0: backward function 0 *)
let rec list_nth_mut_shared_loop_pair_loop_back
@@ -483,18 +493,18 @@ let rec list_nth_mut_shared_loop_pair_loop_back
(decreases (list_nth_mut_shared_loop_pair_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
- then Return (ListCons ret tl0)
+ then Return (List_Cons ret tl0)
else
let* i0 = u32_sub i 1 in
let* tl00 = list_nth_mut_shared_loop_pair_loop_back t tl0 tl1 i0 ret in
- Return (ListCons x0 tl00)
- | ListNil -> Fail Failure
+ Return (List_Cons x0 tl00)
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_shared_loop_pair]: backward function 0 *)
@@ -505,29 +515,29 @@ let list_nth_mut_shared_loop_pair_back
list_nth_mut_shared_loop_pair_loop_back t ls0 ls1 i ret
(** [loops::list_nth_mut_shared_loop_pair_merge]: loop 0: forward function *)
-let rec list_nth_mut_shared_loop_pair_merge_loop_fwd
+let rec list_nth_mut_shared_loop_pair_merge_loop
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) :
Tot (result (t & t))
(decreases (list_nth_mut_shared_loop_pair_merge_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
then Return (x0, x1)
else
let* i0 = u32_sub i 1 in
- list_nth_mut_shared_loop_pair_merge_loop_fwd t tl0 tl1 i0
- | ListNil -> Fail Failure
+ list_nth_mut_shared_loop_pair_merge_loop t tl0 tl1 i0
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_shared_loop_pair_merge]: forward function *)
-let list_nth_mut_shared_loop_pair_merge_fwd
+let list_nth_mut_shared_loop_pair_merge
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) : result (t & t) =
- list_nth_mut_shared_loop_pair_merge_loop_fwd t ls0 ls1 i
+ list_nth_mut_shared_loop_pair_merge_loop t ls0 ls1 i
(** [loops::list_nth_mut_shared_loop_pair_merge]: loop 0: backward function 0 *)
let rec list_nth_mut_shared_loop_pair_merge_loop_back
@@ -536,19 +546,19 @@ let rec list_nth_mut_shared_loop_pair_merge_loop_back
(decreases (list_nth_mut_shared_loop_pair_merge_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
- then Return (ListCons ret tl0)
+ then Return (List_Cons ret tl0)
else
let* i0 = u32_sub i 1 in
let* tl00 =
list_nth_mut_shared_loop_pair_merge_loop_back t tl0 tl1 i0 ret in
- Return (ListCons x0 tl00)
- | ListNil -> Fail Failure
+ Return (List_Cons x0 tl00)
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_mut_shared_loop_pair_merge]: backward function 0 *)
@@ -559,29 +569,29 @@ let list_nth_mut_shared_loop_pair_merge_back
list_nth_mut_shared_loop_pair_merge_loop_back t ls0 ls1 i ret
(** [loops::list_nth_shared_mut_loop_pair]: loop 0: forward function *)
-let rec list_nth_shared_mut_loop_pair_loop_fwd
+let rec list_nth_shared_mut_loop_pair_loop
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) :
Tot (result (t & t))
(decreases (list_nth_shared_mut_loop_pair_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
then Return (x0, x1)
else
let* i0 = u32_sub i 1 in
- list_nth_shared_mut_loop_pair_loop_fwd t tl0 tl1 i0
- | ListNil -> Fail Failure
+ list_nth_shared_mut_loop_pair_loop t tl0 tl1 i0
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_shared_mut_loop_pair]: forward function *)
-let list_nth_shared_mut_loop_pair_fwd
+let list_nth_shared_mut_loop_pair
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) : result (t & t) =
- list_nth_shared_mut_loop_pair_loop_fwd t ls0 ls1 i
+ list_nth_shared_mut_loop_pair_loop t ls0 ls1 i
(** [loops::list_nth_shared_mut_loop_pair]: loop 0: backward function 1 *)
let rec list_nth_shared_mut_loop_pair_loop_back
@@ -590,18 +600,18 @@ let rec list_nth_shared_mut_loop_pair_loop_back
(decreases (list_nth_shared_mut_loop_pair_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
- then Return (ListCons ret tl1)
+ then Return (List_Cons ret tl1)
else
let* i0 = u32_sub i 1 in
let* tl10 = list_nth_shared_mut_loop_pair_loop_back t tl0 tl1 i0 ret in
- Return (ListCons x1 tl10)
- | ListNil -> Fail Failure
+ Return (List_Cons x1 tl10)
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_shared_mut_loop_pair]: backward function 1 *)
@@ -612,29 +622,29 @@ let list_nth_shared_mut_loop_pair_back
list_nth_shared_mut_loop_pair_loop_back t ls0 ls1 i ret
(** [loops::list_nth_shared_mut_loop_pair_merge]: loop 0: forward function *)
-let rec list_nth_shared_mut_loop_pair_merge_loop_fwd
+let rec list_nth_shared_mut_loop_pair_merge_loop
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) :
Tot (result (t & t))
(decreases (list_nth_shared_mut_loop_pair_merge_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
then Return (x0, x1)
else
let* i0 = u32_sub i 1 in
- list_nth_shared_mut_loop_pair_merge_loop_fwd t tl0 tl1 i0
- | ListNil -> Fail Failure
+ list_nth_shared_mut_loop_pair_merge_loop t tl0 tl1 i0
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_shared_mut_loop_pair_merge]: forward function *)
-let list_nth_shared_mut_loop_pair_merge_fwd
+let list_nth_shared_mut_loop_pair_merge
(t : Type0) (ls0 : list_t t) (ls1 : list_t t) (i : u32) : result (t & t) =
- list_nth_shared_mut_loop_pair_merge_loop_fwd t ls0 ls1 i
+ list_nth_shared_mut_loop_pair_merge_loop t ls0 ls1 i
(** [loops::list_nth_shared_mut_loop_pair_merge]: loop 0: backward function 0 *)
let rec list_nth_shared_mut_loop_pair_merge_loop_back
@@ -643,19 +653,19 @@ let rec list_nth_shared_mut_loop_pair_merge_loop_back
(decreases (list_nth_shared_mut_loop_pair_merge_loop_decreases t ls0 ls1 i))
=
begin match ls0 with
- | ListCons x0 tl0 ->
+ | List_Cons x0 tl0 ->
begin match ls1 with
- | ListCons x1 tl1 ->
+ | List_Cons x1 tl1 ->
if i = 0
- then Return (ListCons ret tl1)
+ then Return (List_Cons ret tl1)
else
let* i0 = u32_sub i 1 in
let* tl10 =
list_nth_shared_mut_loop_pair_merge_loop_back t tl0 tl1 i0 ret in
- Return (ListCons x1 tl10)
- | ListNil -> Fail Failure
+ Return (List_Cons x1 tl10)
+ | List_Nil -> Fail Failure
end
- | ListNil -> Fail Failure
+ | List_Nil -> Fail Failure
end
(** [loops::list_nth_shared_mut_loop_pair_merge]: backward function 0 *)
diff --git a/tests/fstar/misc/Loops.Types.fst b/tests/fstar/misc/Loops.Types.fst
index 2e032fe7..c622c548 100644
--- a/tests/fstar/misc/Loops.Types.fst
+++ b/tests/fstar/misc/Loops.Types.fst
@@ -7,6 +7,6 @@ open Primitives
(** [loops::List] *)
type list_t (t : Type0) =
-| ListCons : t -> list_t t -> list_t t
-| ListNil : list_t t
+| List_Cons : t -> list_t t -> list_t t
+| List_Nil : list_t t
diff --git a/tests/fstar/misc/NoNestedBorrows.fst b/tests/fstar/misc/NoNestedBorrows.fst
index 2cdd6e21..e97927aa 100644
--- a/tests/fstar/misc/NoNestedBorrows.fst
+++ b/tests/fstar/misc/NoNestedBorrows.fst
@@ -6,95 +6,107 @@ open Primitives
#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
(** [no_nested_borrows::Pair] *)
-type pair_t (t1 t2 : Type0) = { pair_x : t1; pair_y : t2; }
+type pair_t (t1 t2 : Type0) = { x : t1; y : t2; }
(** [no_nested_borrows::List] *)
type list_t (t : Type0) =
-| ListCons : t -> list_t t -> list_t t
-| ListNil : list_t t
+| List_Cons : t -> list_t t -> list_t t
+| List_Nil : list_t t
(** [no_nested_borrows::One] *)
-type one_t (t1 : Type0) = | OneOne : t1 -> one_t t1
+type one_t (t1 : Type0) = | One_One : t1 -> one_t t1
(** [no_nested_borrows::EmptyEnum] *)
-type empty_enum_t = | EmptyEnumEmpty : empty_enum_t
+type emptyEnum_t = | EmptyEnum_Empty : emptyEnum_t
(** [no_nested_borrows::Enum] *)
-type enum_t = | EnumVariant1 : enum_t | EnumVariant2 : enum_t
+type enum_t = | Enum_Variant1 : enum_t | Enum_Variant2 : enum_t
(** [no_nested_borrows::EmptyStruct] *)
-type empty_struct_t = unit
+type emptyStruct_t = unit
(** [no_nested_borrows::Sum] *)
type sum_t (t1 t2 : Type0) =
-| SumLeft : t1 -> sum_t t1 t2
-| SumRight : t2 -> sum_t t1 t2
+| Sum_Left : t1 -> sum_t t1 t2
+| Sum_Right : t2 -> sum_t t1 t2
(** [no_nested_borrows::neg_test]: forward function *)
-let neg_test_fwd (x : i32) : result i32 =
+let neg_test (x : i32) : result i32 =
i32_neg x
(** [no_nested_borrows::add_test]: forward function *)
-let add_test_fwd (x : u32) (y : u32) : result u32 =
+let add_test (x : u32) (y : u32) : result u32 =
u32_add x y
(** [no_nested_borrows::subs_test]: forward function *)
-let subs_test_fwd (x : u32) (y : u32) : result u32 =
+let subs_test (x : u32) (y : u32) : result u32 =
u32_sub x y
(** [no_nested_borrows::div_test]: forward function *)
-let div_test_fwd (x : u32) (y : u32) : result u32 =
+let div_test (x : u32) (y : u32) : result u32 =
u32_div x y
(** [no_nested_borrows::div_test1]: forward function *)
-let div_test1_fwd (x : u32) : result u32 =
+let div_test1 (x : u32) : result u32 =
u32_div x 2
(** [no_nested_borrows::rem_test]: forward function *)
-let rem_test_fwd (x : u32) (y : u32) : result u32 =
+let rem_test (x : u32) (y : u32) : result u32 =
u32_rem x y
+(** [no_nested_borrows::mul_test]: forward function *)
+let mul_test (x : u32) (y : u32) : result u32 =
+ u32_mul x y
+
+(** [no_nested_borrows::CONST0] *)
+let const0_body : result usize = usize_add 1 1
+let const0_c : usize = eval_global const0_body
+
+(** [no_nested_borrows::CONST1] *)
+let const1_body : result usize = usize_mul 2 2
+let const1_c : usize = eval_global const1_body
+
(** [no_nested_borrows::cast_test]: forward function *)
-let cast_test_fwd (x : u32) : result i32 =
+let cast_test (x : u32) : result i32 =
scalar_cast U32 I32 x
(** [no_nested_borrows::test2]: forward function *)
-let test2_fwd : result unit =
+let test2 : result unit =
let* _ = u32_add 23 44 in Return ()
(** Unit test for [no_nested_borrows::test2] *)
-let _ = assert_norm (test2_fwd = Return ())
+let _ = assert_norm (test2 = Return ())
(** [no_nested_borrows::get_max]: forward function *)
-let get_max_fwd (x : u32) (y : u32) : result u32 =
+let get_max (x : u32) (y : u32) : result u32 =
if x >= y then Return x else Return y
(** [no_nested_borrows::test3]: forward function *)
-let test3_fwd : result unit =
- let* x = get_max_fwd 4 3 in
- let* y = get_max_fwd 10 11 in
+let test3 : result unit =
+ let* x = get_max 4 3 in
+ let* y = get_max 10 11 in
let* z = u32_add x y in
if not (z = 15) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::test3] *)
-let _ = assert_norm (test3_fwd = Return ())
+let _ = assert_norm (test3 = Return ())
(** [no_nested_borrows::test_neg1]: forward function *)
-let test_neg1_fwd : result unit =
+let test_neg1 : result unit =
let* y = i32_neg 3 in if not (y = -3) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::test_neg1] *)
-let _ = assert_norm (test_neg1_fwd = Return ())
+let _ = assert_norm (test_neg1 = Return ())
(** [no_nested_borrows::refs_test1]: forward function *)
-let refs_test1_fwd : result unit =
+let refs_test1 : result unit =
if not (1 = 1) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::refs_test1] *)
-let _ = assert_norm (refs_test1_fwd = Return ())
+let _ = assert_norm (refs_test1 = Return ())
(** [no_nested_borrows::refs_test2]: forward function *)
-let refs_test2_fwd : result unit =
+let refs_test2 : result unit =
if not (2 = 2)
then Fail Failure
else
@@ -106,76 +118,76 @@ let refs_test2_fwd : result unit =
else if not (2 = 2) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::refs_test2] *)
-let _ = assert_norm (refs_test2_fwd = Return ())
+let _ = assert_norm (refs_test2 = Return ())
(** [no_nested_borrows::test_list1]: forward function *)
-let test_list1_fwd : result unit =
+let test_list1 : result unit =
Return ()
(** Unit test for [no_nested_borrows::test_list1] *)
-let _ = assert_norm (test_list1_fwd = Return ())
+let _ = assert_norm (test_list1 = Return ())
(** [no_nested_borrows::test_box1]: forward function *)
-let test_box1_fwd : result unit =
+let test_box1 : result unit =
let b = 1 in let x = b in if not (x = 1) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::test_box1] *)
-let _ = assert_norm (test_box1_fwd = Return ())
+let _ = assert_norm (test_box1 = Return ())
(** [no_nested_borrows::copy_int]: forward function *)
-let copy_int_fwd (x : i32) : result i32 =
+let copy_int (x : i32) : result i32 =
Return x
(** [no_nested_borrows::test_unreachable]: forward function *)
-let test_unreachable_fwd (b : bool) : result unit =
+let test_unreachable (b : bool) : result unit =
if b then Fail Failure else Return ()
(** [no_nested_borrows::test_panic]: forward function *)
-let test_panic_fwd (b : bool) : result unit =
+let test_panic (b : bool) : result unit =
if b then Fail Failure else Return ()
(** [no_nested_borrows::test_copy_int]: forward function *)
-let test_copy_int_fwd : result unit =
- let* y = copy_int_fwd 0 in if not (0 = y) then Fail Failure else Return ()
+let test_copy_int : result unit =
+ let* y = copy_int 0 in if not (0 = y) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::test_copy_int] *)
-let _ = assert_norm (test_copy_int_fwd = Return ())
+let _ = assert_norm (test_copy_int = Return ())
(** [no_nested_borrows::is_cons]: forward function *)
-let is_cons_fwd (t : Type0) (l : list_t t) : result bool =
+let is_cons (t : Type0) (l : list_t t) : result bool =
begin match l with
- | ListCons x l0 -> Return true
- | ListNil -> Return false
+ | List_Cons x l0 -> Return true
+ | List_Nil -> Return false
end
(** [no_nested_borrows::test_is_cons]: forward function *)
-let test_is_cons_fwd : result unit =
- let l = ListNil in
- let* b = is_cons_fwd i32 (ListCons 0 l) in
+let test_is_cons : result unit =
+ let l = List_Nil in
+ let* b = is_cons i32 (List_Cons 0 l) in
if not b then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::test_is_cons] *)
-let _ = assert_norm (test_is_cons_fwd = Return ())
+let _ = assert_norm (test_is_cons = Return ())
(** [no_nested_borrows::split_list]: forward function *)
-let split_list_fwd (t : Type0) (l : list_t t) : result (t & (list_t t)) =
+let split_list (t : Type0) (l : list_t t) : result (t & (list_t t)) =
begin match l with
- | ListCons hd tl -> Return (hd, tl)
- | ListNil -> Fail Failure
+ | List_Cons hd tl -> Return (hd, tl)
+ | List_Nil -> Fail Failure
end
(** [no_nested_borrows::test_split_list]: forward function *)
-let test_split_list_fwd : result unit =
- let l = ListNil in
- let* p = split_list_fwd i32 (ListCons 0 l) in
+let test_split_list : result unit =
+ let l = List_Nil in
+ let* p = split_list i32 (List_Cons 0 l) in
let (hd, _) = p in
if not (hd = 0) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::test_split_list] *)
-let _ = assert_norm (test_split_list_fwd = Return ())
+let _ = assert_norm (test_split_list = Return ())
(** [no_nested_borrows::choose]: forward function *)
-let choose_fwd (t : Type0) (b : bool) (x : t) (y : t) : result t =
+let choose (t : Type0) (b : bool) (x : t) (y : t) : result t =
if b then Return x else Return y
(** [no_nested_borrows::choose]: backward function 0 *)
@@ -184,8 +196,8 @@ let choose_back
if b then Return (ret, y) else Return (x, ret)
(** [no_nested_borrows::choose_test]: forward function *)
-let choose_test_fwd : result unit =
- let* z = choose_fwd i32 true 0 0 in
+let choose_test : result unit =
+ let* z = choose i32 true 0 0 in
let* z0 = i32_add z 1 in
if not (z0 = 1)
then Fail Failure
@@ -196,115 +208,112 @@ let choose_test_fwd : result unit =
else if not (y = 0) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::choose_test] *)
-let _ = assert_norm (choose_test_fwd = Return ())
+let _ = assert_norm (choose_test = Return ())
(** [no_nested_borrows::test_char]: forward function *)
-let test_char_fwd : result char =
+let test_char : result char =
Return 'a'
(** [no_nested_borrows::Tree] *)
type tree_t (t : Type0) =
-| TreeLeaf : t -> tree_t t
-| TreeNode : t -> node_elem_t t -> tree_t t -> tree_t t
+| Tree_Leaf : t -> tree_t t
+| Tree_Node : t -> nodeElem_t t -> tree_t t -> tree_t t
(** [no_nested_borrows::NodeElem] *)
-and node_elem_t (t : Type0) =
-| NodeElemCons : tree_t t -> node_elem_t t -> node_elem_t t
-| NodeElemNil : node_elem_t t
+and nodeElem_t (t : Type0) =
+| NodeElem_Cons : tree_t t -> nodeElem_t t -> nodeElem_t t
+| NodeElem_Nil : nodeElem_t t
(** [no_nested_borrows::list_length]: forward function *)
-let rec list_length_fwd (t : Type0) (l : list_t t) : result u32 =
+let rec list_length (t : Type0) (l : list_t t) : result u32 =
begin match l with
- | ListCons x l1 -> let* i = list_length_fwd t l1 in u32_add 1 i
- | ListNil -> Return 0
+ | List_Cons x l1 -> let* i = list_length t l1 in u32_add 1 i
+ | List_Nil -> Return 0
end
(** [no_nested_borrows::list_nth_shared]: forward function *)
-let rec list_nth_shared_fwd (t : Type0) (l : list_t t) (i : u32) : result t =
+let rec list_nth_shared (t : Type0) (l : list_t t) (i : u32) : result t =
begin match l with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
then Return x
- else let* i0 = u32_sub i 1 in list_nth_shared_fwd t tl i0
- | ListNil -> Fail Failure
+ else let* i0 = u32_sub i 1 in list_nth_shared t tl i0
+ | List_Nil -> Fail Failure
end
(** [no_nested_borrows::list_nth_mut]: forward function *)
-let rec list_nth_mut_fwd (t : Type0) (l : list_t t) (i : u32) : result t =
+let rec list_nth_mut (t : Type0) (l : list_t t) (i : u32) : result t =
begin match l with
- | ListCons x tl ->
- if i = 0
- then Return x
- else let* i0 = u32_sub i 1 in list_nth_mut_fwd t tl i0
- | ListNil -> Fail Failure
+ | List_Cons x tl ->
+ if i = 0 then Return x else let* i0 = u32_sub i 1 in list_nth_mut t tl i0
+ | List_Nil -> Fail Failure
end
(** [no_nested_borrows::list_nth_mut]: backward function 0 *)
let rec list_nth_mut_back
(t : Type0) (l : list_t t) (i : u32) (ret : t) : result (list_t t) =
begin match l with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
- then Return (ListCons ret tl)
+ then Return (List_Cons ret tl)
else
let* i0 = u32_sub i 1 in
let* tl0 = list_nth_mut_back t tl i0 ret in
- Return (ListCons x tl0)
- | ListNil -> Fail Failure
+ Return (List_Cons x tl0)
+ | List_Nil -> Fail Failure
end
(** [no_nested_borrows::list_rev_aux]: forward function *)
-let rec list_rev_aux_fwd
+let rec list_rev_aux
(t : Type0) (li : list_t t) (lo : list_t t) : result (list_t t) =
begin match li with
- | ListCons hd tl -> list_rev_aux_fwd t tl (ListCons hd lo)
- | ListNil -> Return lo
+ | List_Cons hd tl -> list_rev_aux t tl (List_Cons hd lo)
+ | List_Nil -> Return lo
end
(** [no_nested_borrows::list_rev]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let list_rev_fwd_back (t : Type0) (l : list_t t) : result (list_t t) =
- let li = mem_replace_fwd (list_t t) l ListNil in
- list_rev_aux_fwd t li ListNil
+let list_rev (t : Type0) (l : list_t t) : result (list_t t) =
+ let li = core_mem_replace (list_t t) l List_Nil in list_rev_aux t li List_Nil
(** [no_nested_borrows::test_list_functions]: forward function *)
-let test_list_functions_fwd : result unit =
- let l = ListNil in
- let l0 = ListCons 2 l in
- let l1 = ListCons 1 l0 in
- let* i = list_length_fwd i32 (ListCons 0 l1) in
+let test_list_functions : result unit =
+ let l = List_Nil in
+ let l0 = List_Cons 2 l in
+ let l1 = List_Cons 1 l0 in
+ let* i = list_length i32 (List_Cons 0 l1) in
if not (i = 3)
then Fail Failure
else
- let* i0 = list_nth_shared_fwd i32 (ListCons 0 l1) 0 in
+ let* i0 = list_nth_shared i32 (List_Cons 0 l1) 0 in
if not (i0 = 0)
then Fail Failure
else
- let* i1 = list_nth_shared_fwd i32 (ListCons 0 l1) 1 in
+ let* i1 = list_nth_shared i32 (List_Cons 0 l1) 1 in
if not (i1 = 1)
then Fail Failure
else
- let* i2 = list_nth_shared_fwd i32 (ListCons 0 l1) 2 in
+ let* i2 = list_nth_shared i32 (List_Cons 0 l1) 2 in
if not (i2 = 2)
then Fail Failure
else
- let* ls = list_nth_mut_back i32 (ListCons 0 l1) 1 3 in
- let* i3 = list_nth_shared_fwd i32 ls 0 in
+ let* ls = list_nth_mut_back i32 (List_Cons 0 l1) 1 3 in
+ let* i3 = list_nth_shared i32 ls 0 in
if not (i3 = 0)
then Fail Failure
else
- let* i4 = list_nth_shared_fwd i32 ls 1 in
+ let* i4 = list_nth_shared i32 ls 1 in
if not (i4 = 3)
then Fail Failure
else
- let* i5 = list_nth_shared_fwd i32 ls 2 in
+ let* i5 = list_nth_shared i32 ls 2 in
if not (i5 = 2) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::test_list_functions] *)
-let _ = assert_norm (test_list_functions_fwd = Return ())
+let _ = assert_norm (test_list_functions = Return ())
(** [no_nested_borrows::id_mut_pair1]: forward function *)
-let id_mut_pair1_fwd (t1 t2 : Type0) (x : t1) (y : t2) : result (t1 & t2) =
+let id_mut_pair1 (t1 t2 : Type0) (x : t1) (y : t2) : result (t1 & t2) =
Return (x, y)
(** [no_nested_borrows::id_mut_pair1]: backward function 0 *)
@@ -313,7 +322,7 @@ let id_mut_pair1_back
let (x0, x1) = ret in Return (x0, x1)
(** [no_nested_borrows::id_mut_pair2]: forward function *)
-let id_mut_pair2_fwd (t1 t2 : Type0) (p : (t1 & t2)) : result (t1 & t2) =
+let id_mut_pair2 (t1 t2 : Type0) (p : (t1 & t2)) : result (t1 & t2) =
let (x, x0) = p in Return (x, x0)
(** [no_nested_borrows::id_mut_pair2]: backward function 0 *)
@@ -322,7 +331,7 @@ let id_mut_pair2_back
let (x, x0) = ret in Return (x, x0)
(** [no_nested_borrows::id_mut_pair3]: forward function *)
-let id_mut_pair3_fwd (t1 t2 : Type0) (x : t1) (y : t2) : result (t1 & t2) =
+let id_mut_pair3 (t1 t2 : Type0) (x : t1) (y : t2) : result (t1 & t2) =
Return (x, y)
(** [no_nested_borrows::id_mut_pair3]: backward function 0 *)
@@ -336,7 +345,7 @@ let id_mut_pair3_back'b
Return ret
(** [no_nested_borrows::id_mut_pair4]: forward function *)
-let id_mut_pair4_fwd (t1 t2 : Type0) (p : (t1 & t2)) : result (t1 & t2) =
+let id_mut_pair4 (t1 t2 : Type0) (p : (t1 & t2)) : result (t1 & t2) =
let (x, x0) = p in Return (x, x0)
(** [no_nested_borrows::id_mut_pair4]: backward function 0 *)
@@ -350,81 +359,76 @@ let id_mut_pair4_back'b
Return ret
(** [no_nested_borrows::StructWithTuple] *)
-type struct_with_tuple_t (t1 t2 : Type0) = { struct_with_tuple_p : (t1 & t2); }
+type structWithTuple_t (t1 t2 : Type0) = { p : (t1 & t2); }
(** [no_nested_borrows::new_tuple1]: forward function *)
-let new_tuple1_fwd : result (struct_with_tuple_t u32 u32) =
- Return { struct_with_tuple_p = (1, 2) }
+let new_tuple1 : result (structWithTuple_t u32 u32) =
+ Return { p = (1, 2) }
(** [no_nested_borrows::new_tuple2]: forward function *)
-let new_tuple2_fwd : result (struct_with_tuple_t i16 i16) =
- Return { struct_with_tuple_p = (1, 2) }
+let new_tuple2 : result (structWithTuple_t i16 i16) =
+ Return { p = (1, 2) }
(** [no_nested_borrows::new_tuple3]: forward function *)
-let new_tuple3_fwd : result (struct_with_tuple_t u64 i64) =
- Return { struct_with_tuple_p = (1, 2) }
+let new_tuple3 : result (structWithTuple_t u64 i64) =
+ Return { p = (1, 2) }
(** [no_nested_borrows::StructWithPair] *)
-type struct_with_pair_t (t1 t2 : Type0) =
-{
- struct_with_pair_p : pair_t t1 t2;
-}
+type structWithPair_t (t1 t2 : Type0) = { p : pair_t t1 t2; }
(** [no_nested_borrows::new_pair1]: forward function *)
-let new_pair1_fwd : result (struct_with_pair_t u32 u32) =
- Return { struct_with_pair_p = { pair_x = 1; pair_y = 2 } }
+let new_pair1 : result (structWithPair_t u32 u32) =
+ Return { p = { x = 1; y = 2 } }
(** [no_nested_borrows::test_constants]: forward function *)
-let test_constants_fwd : result unit =
- let* swt = new_tuple1_fwd in
- let (i, _) = swt.struct_with_tuple_p in
+let test_constants : result unit =
+ let* swt = new_tuple1 in
+ let (i, _) = swt.p in
if not (i = 1)
then Fail Failure
else
- let* swt0 = new_tuple2_fwd in
- let (i0, _) = swt0.struct_with_tuple_p in
+ let* swt0 = new_tuple2 in
+ let (i0, _) = swt0.p in
if not (i0 = 1)
then Fail Failure
else
- let* swt1 = new_tuple3_fwd in
- let (i1, _) = swt1.struct_with_tuple_p in
+ let* swt1 = new_tuple3 in
+ let (i1, _) = swt1.p in
if not (i1 = 1)
then Fail Failure
else
- let* swp = new_pair1_fwd in
- if not (swp.struct_with_pair_p.pair_x = 1)
- then Fail Failure
- else Return ()
+ let* swp = new_pair1 in
+ if not (swp.p.x = 1) then Fail Failure else Return ()
(** Unit test for [no_nested_borrows::test_constants] *)
-let _ = assert_norm (test_constants_fwd = Return ())
+let _ = assert_norm (test_constants = Return ())
(** [no_nested_borrows::test_weird_borrows1]: forward function *)
-let test_weird_borrows1_fwd : result unit =
+let test_weird_borrows1 : result unit =
Return ()
(** Unit test for [no_nested_borrows::test_weird_borrows1] *)
-let _ = assert_norm (test_weird_borrows1_fwd = Return ())
+let _ = assert_norm (test_weird_borrows1 = Return ())
(** [no_nested_borrows::test_mem_replace]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let test_mem_replace_fwd_back (px : u32) : result u32 =
- let y = mem_replace_fwd u32 px 1 in
+let test_mem_replace (px : u32) : result u32 =
+ let y = core_mem_replace u32 px 1 in
if not (y = 0) then Fail Failure else Return 2
(** [no_nested_borrows::test_shared_borrow_bool1]: forward function *)
-let test_shared_borrow_bool1_fwd (b : bool) : result u32 =
+let test_shared_borrow_bool1 (b : bool) : result u32 =
if b then Return 0 else Return 1
(** [no_nested_borrows::test_shared_borrow_bool2]: forward function *)
-let test_shared_borrow_bool2_fwd : result u32 =
+let test_shared_borrow_bool2 : result u32 =
Return 0
(** [no_nested_borrows::test_shared_borrow_enum1]: forward function *)
-let test_shared_borrow_enum1_fwd (l : list_t u32) : result u32 =
- begin match l with | ListCons i l0 -> Return 1 | ListNil -> Return 0 end
+let test_shared_borrow_enum1 (l : list_t u32) : result u32 =
+ begin match l with | List_Cons i l0 -> Return 1 | List_Nil -> Return 0 end
(** [no_nested_borrows::test_shared_borrow_enum2]: forward function *)
-let test_shared_borrow_enum2_fwd : result u32 =
+let test_shared_borrow_enum2 : result u32 =
Return 0
diff --git a/tests/fstar/misc/Paper.fst b/tests/fstar/misc/Paper.fst
index e2d692c2..bfb710dc 100644
--- a/tests/fstar/misc/Paper.fst
+++ b/tests/fstar/misc/Paper.fst
@@ -7,19 +7,18 @@ open Primitives
(** [paper::ref_incr]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
-let ref_incr_fwd_back (x : i32) : result i32 =
+let ref_incr (x : i32) : result i32 =
i32_add x 1
(** [paper::test_incr]: forward function *)
-let test_incr_fwd : result unit =
- let* x = ref_incr_fwd_back 0 in
- if not (x = 1) then Fail Failure else Return ()
+let test_incr : result unit =
+ let* x = ref_incr 0 in if not (x = 1) then Fail Failure else Return ()
(** Unit test for [paper::test_incr] *)
-let _ = assert_norm (test_incr_fwd = Return ())
+let _ = assert_norm (test_incr = Return ())
(** [paper::choose]: forward function *)
-let choose_fwd (t : Type0) (b : bool) (x : t) (y : t) : result t =
+let choose (t : Type0) (b : bool) (x : t) (y : t) : result t =
if b then Return x else Return y
(** [paper::choose]: backward function 0 *)
@@ -28,8 +27,8 @@ let choose_back
if b then Return (ret, y) else Return (x, ret)
(** [paper::test_choose]: forward function *)
-let test_choose_fwd : result unit =
- let* z = choose_fwd i32 true 0 0 in
+let test_choose : result unit =
+ let* z = choose i32 true 0 0 in
let* z0 = i32_add z 1 in
if not (z0 = 1)
then Fail Failure
@@ -40,62 +39,60 @@ let test_choose_fwd : result unit =
else if not (y = 0) then Fail Failure else Return ()
(** Unit test for [paper::test_choose] *)
-let _ = assert_norm (test_choose_fwd = Return ())
+let _ = assert_norm (test_choose = Return ())
(** [paper::List] *)
type list_t (t : Type0) =
-| ListCons : t -> list_t t -> list_t t
-| ListNil : list_t t
+| List_Cons : t -> list_t t -> list_t t
+| List_Nil : list_t t
(** [paper::list_nth_mut]: forward function *)
-let rec list_nth_mut_fwd (t : Type0) (l : list_t t) (i : u32) : result t =
+let rec list_nth_mut (t : Type0) (l : list_t t) (i : u32) : result t =
begin match l with
- | ListCons x tl ->
- if i = 0
- then Return x
- else let* i0 = u32_sub i 1 in list_nth_mut_fwd t tl i0
- | ListNil -> Fail Failure
+ | List_Cons x tl ->
+ if i = 0 then Return x else let* i0 = u32_sub i 1 in list_nth_mut t tl i0
+ | List_Nil -> Fail Failure
end
(** [paper::list_nth_mut]: backward function 0 *)
let rec list_nth_mut_back
(t : Type0) (l : list_t t) (i : u32) (ret : t) : result (list_t t) =
begin match l with
- | ListCons x tl ->
+ | List_Cons x tl ->
if i = 0
- then Return (ListCons ret tl)
+ then Return (List_Cons ret tl)
else
let* i0 = u32_sub i 1 in
let* tl0 = list_nth_mut_back t tl i0 ret in
- Return (ListCons x tl0)
- | ListNil -> Fail Failure
+ Return (List_Cons x tl0)
+ | List_Nil -> Fail Failure
end
(** [paper::sum]: forward function *)
-let rec sum_fwd (l : list_t i32) : result i32 =
+let rec sum (l : list_t i32) : result i32 =
begin match l with
- | ListCons x tl -> let* i = sum_fwd tl in i32_add x i
- | ListNil -> Return 0
+ | List_Cons x tl -> let* i = sum tl in i32_add x i
+ | List_Nil -> Return 0
end
(** [paper::test_nth]: forward function *)
-let test_nth_fwd : result unit =
- let l = ListNil in
- let l0 = ListCons 3 l in
- let l1 = ListCons 2 l0 in
- let* x = list_nth_mut_fwd i32 (ListCons 1 l1) 2 in
+let test_nth : result unit =
+ let l = List_Nil in
+ let l0 = List_Cons 3 l in
+ let l1 = List_Cons 2 l0 in
+ let* x = list_nth_mut i32 (List_Cons 1 l1) 2 in
let* x0 = i32_add x 1 in
- let* l2 = list_nth_mut_back i32 (ListCons 1 l1) 2 x0 in
- let* i = sum_fwd l2 in
+ let* l2 = list_nth_mut_back i32 (List_Cons 1 l1) 2 x0 in
+ let* i = sum l2 in
if not (i = 7) then Fail Failure else Return ()
(** Unit test for [paper::test_nth] *)
-let _ = assert_norm (test_nth_fwd = Return ())
+let _ = assert_norm (test_nth = Return ())
(** [paper::call_choose]: forward function *)
-let call_choose_fwd (p : (u32 & u32)) : result u32 =
+let call_choose (p : (u32 & u32)) : result u32 =
let (px, py) = p in
- let* pz = choose_fwd u32 true px py in
+ let* pz = choose u32 true px py in
let* pz0 = u32_add pz 1 in
let* (px0, _) = choose_back u32 true px py pz0 in
Return px0
diff --git a/tests/fstar/misc/PoloniusList.fst b/tests/fstar/misc/PoloniusList.fst
index 79c86606..428c4210 100644
--- a/tests/fstar/misc/PoloniusList.fst
+++ b/tests/fstar/misc/PoloniusList.fst
@@ -7,25 +7,25 @@ open Primitives
(** [polonius_list::List] *)
type list_t (t : Type0) =
-| ListCons : t -> list_t t -> list_t t
-| ListNil : list_t t
+| List_Cons : t -> list_t t -> list_t t
+| List_Nil : list_t t
(** [polonius_list::get_list_at_x]: forward function *)
-let rec get_list_at_x_fwd (ls : list_t u32) (x : u32) : result (list_t u32) =
+let rec get_list_at_x (ls : list_t u32) (x : u32) : result (list_t u32) =
begin match ls with
- | ListCons hd tl ->
- if hd = x then Return (ListCons hd tl) else get_list_at_x_fwd tl x
- | ListNil -> Return ListNil
+ | List_Cons hd tl ->
+ if hd = x then Return (List_Cons hd tl) else get_list_at_x tl x
+ | List_Nil -> Return List_Nil
end
(** [polonius_list::get_list_at_x]: backward function 0 *)
let rec get_list_at_x_back
(ls : list_t u32) (x : u32) (ret : list_t u32) : result (list_t u32) =
begin match ls with
- | ListCons hd tl ->
+ | List_Cons hd tl ->
if hd = x
then Return ret
- else let* tl0 = get_list_at_x_back tl x ret in Return (ListCons hd tl0)
- | ListNil -> Return ret
+ else let* tl0 = get_list_at_x_back tl x ret in Return (List_Cons hd tl0)
+ | List_Nil -> Return ret
end
diff --git a/tests/fstar/misc/Primitives.fst b/tests/fstar/misc/Primitives.fst
index 9db82069..3297803c 100644
--- a/tests/fstar/misc/Primitives.fst
+++ b/tests/fstar/misc/Primitives.fst
@@ -55,8 +55,12 @@ type string = string
let is_zero (n: nat) : bool = n = 0
let decrease (n: nat{n > 0}) : nat = n - 1
-let mem_replace_fwd (a : Type0) (x : a) (y : a) : a = x
-let mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+let core_mem_replace (a : Type0) (x : a) (y : a) : a = x
+let core_mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+
+// We don't really use raw pointers for now
+type mut_raw_ptr (t : Type0) = { v : t }
+type const_raw_ptr (t : Type0) = { v : t }
(*** Scalars *)
/// Rem.: most of the following code was partially generated
@@ -100,6 +104,11 @@ type scalar_ty =
| U64
| U128
+let is_unsigned = function
+ | Isize | I8 | I16 | I32 | I64 | I128 -> false
+ | Usize | U8 | U16 | U32 | U64 | U128 -> true
+
+
let scalar_min (ty : scalar_ty) : int =
match ty with
| Isize -> isize_min
@@ -162,6 +171,15 @@ let scalar_sub (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scala
let scalar_mul (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
mk_scalar ty (x * y)
+let scalar_lxor (#ty : scalar_ty { is_unsigned ty && ty <> Usize })
+ (x : scalar ty) (y : scalar ty) : scalar ty =
+ match ty with
+ | U8 -> FStar.UInt.logxor #8 x y
+ | U16 -> FStar.UInt.logxor #16 x y
+ | U32 -> FStar.UInt.logxor #32 x y
+ | U64 -> FStar.UInt.logxor #64 x y
+ | U128 -> FStar.UInt.logxor #128 x y
+
(** Cast an integer from a [src_ty] to a [tgt_ty] *)
// TODO: check the semantics of casts in Rust
let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) =
@@ -169,17 +187,44 @@ let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) :
/// The scalar types
type isize : eqtype = scalar Isize
-type i8 : eqtype = scalar I8
-type i16 : eqtype = scalar I16
-type i32 : eqtype = scalar I32
-type i64 : eqtype = scalar I64
-type i128 : eqtype = scalar I128
+type i8 : eqtype = scalar I8
+type i16 : eqtype = scalar I16
+type i32 : eqtype = scalar I32
+type i64 : eqtype = scalar I64
+type i128 : eqtype = scalar I128
type usize : eqtype = scalar Usize
-type u8 : eqtype = scalar U8
-type u16 : eqtype = scalar U16
-type u32 : eqtype = scalar U32
-type u64 : eqtype = scalar U64
-type u128 : eqtype = scalar U128
+type u8 : eqtype = scalar U8
+type u16 : eqtype = scalar U16
+type u32 : eqtype = scalar U32
+type u64 : eqtype = scalar U64
+type u128 : eqtype = scalar U128
+
+
+let core_isize_min : isize = isize_min
+let core_isize_max : isize = isize_max
+let core_i8_min : i8 = i8_min
+let core_i8_max : i8 = i8_max
+let core_i16_min : i16 = i16_min
+let core_i16_max : i16 = i16_max
+let core_i32_min : i32 = i32_min
+let core_i32_max : i32 = i32_max
+let core_i64_min : i64 = i64_min
+let core_i64_max : i64 = i64_max
+let core_i128_min : i128 = i128_min
+let core_i128_max : i128 = i128_max
+
+let core_usize_min : usize = usize_min
+let core_usize_max : usize = usize_max
+let core_u8_min : u8 = u8_min
+let core_u8_max : u8 = u8_max
+let core_u16_min : u16 = u16_min
+let core_u16_max : u16 = u16_max
+let core_u32_min : u32 = u32_min
+let core_u32_max : u32 = u32_max
+let core_u64_min : u64 = u64_min
+let core_u64_max : u64 = u64_max
+let core_u128_min : u128 = u128_min
+let core_u128_max : u128 = u128_max
/// Negation
let isize_neg = scalar_neg #Isize
@@ -231,7 +276,7 @@ let u32_add = scalar_add #U32
let u64_add = scalar_add #U64
let u128_add = scalar_add #U128
-/// Substraction
+/// Subtraction
let isize_sub = scalar_sub #Isize
let i8_sub = scalar_sub #I8
let i16_sub = scalar_sub #I16
@@ -259,12 +304,65 @@ let u32_mul = scalar_mul #U32
let u64_mul = scalar_mul #U64
let u128_mul = scalar_mul #U128
-(*** Range *)
-type range (a : Type0) = {
+/// Logical operators, defined for unsigned types only, so far
+let u8_xor = scalar_lxor #U8
+let u16_xor = scalar_lxor #U16
+let u32_xor = scalar_lxor #U32
+let u64_xor = scalar_lxor #U64
+let u128_xor = scalar_lxor #U128
+
+(*** core::ops *)
+
+// Trait declaration: [core::ops::index::Index]
+noeq type core_ops_index_Index (self idx : Type0) = {
+ output : Type0;
+ index : self → idx → result output
+}
+
+// Trait declaration: [core::ops::index::IndexMut]
+noeq type core_ops_index_IndexMut (self idx : Type0) = {
+ indexInst : core_ops_index_Index self idx;
+ index_mut : self → idx → result indexInst.output;
+ index_mut_back : self → idx → indexInst.output → result self;
+}
+
+// Trait declaration [core::ops::deref::Deref]
+noeq type core_ops_deref_Deref (self : Type0) = {
+ target : Type0;
+ deref : self → result target;
+}
+
+// Trait declaration [core::ops::deref::DerefMut]
+noeq type core_ops_deref_DerefMut (self : Type0) = {
+ derefInst : core_ops_deref_Deref self;
+ deref_mut : self → result derefInst.target;
+ deref_mut_back : self → derefInst.target → result self;
+}
+
+type core_ops_range_Range (a : Type0) = {
start : a;
end_ : a;
}
+(*** [alloc] *)
+
+let alloc_boxed_Box_deref (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut_back (t : Type) (_ : t) (x : t) : result t = Return x
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefInst (self : Type0) : core_ops_deref_Deref self = {
+ target = self;
+ deref = alloc_boxed_Box_deref self;
+}
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefMutInst (self : Type0) : core_ops_deref_DerefMut self = {
+ derefInst = alloc_boxed_Box_coreOpsDerefInst self;
+ deref_mut = alloc_boxed_Box_deref_mut self;
+ deref_mut_back = alloc_boxed_Box_deref_mut_back self;
+}
+
(*** Array *)
type array (a : Type0) (n : usize) = s:list a{length s = n}
@@ -278,15 +376,11 @@ let mk_array (a : Type0) (n : usize)
normalize_term_spec (FStar.List.Tot.length l);
l
-let array_index_shared (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let array_index_mut_fwd (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
+let array_index_usize (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let array_index_mut_back (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
+let array_update_usize (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
if i < length x then Return (list_update x i nx)
else Fail Failure
@@ -295,55 +389,54 @@ type slice (a : Type0) = s:list a{length s <= usize_max}
let slice_len (a : Type0) (s : slice a) : usize = length s
-let slice_index_shared (a : Type0) (x : slice a) (i : usize) : result a =
+let slice_index_usize (a : Type0) (x : slice a) (i : usize) : result a =
if i < length x then Return (index x i)
else Fail Failure
-let slice_index_mut_fwd (a : Type0) (x : slice a) (i : usize) : result a =
- if i < length x then Return (index x i)
- else Fail Failure
-
-let slice_index_mut_back (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
+let slice_update_usize (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
if i < length x then Return (list_update x i nx)
else Fail Failure
(*** Subslices *)
-let array_to_slice_shared (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_fwd (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
-let array_to_slice_mut_back (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
+let array_to_slice (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
+let array_from_slice (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
if length s = n then Return s
else Fail Failure
// TODO: finish the definitions below (there lacks [List.drop] and [List.take] in the standard library *)
-let array_subslice_shared (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
- admit()
-
-let array_subslice_mut_fwd (a : Type0) (n : usize) (x : array a n) (r : range usize) : result (slice a) =
+let array_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let array_subslice_mut_back (a : Type0) (n : usize) (x : array a n) (r : range usize) (ns : slice a) : result (array a n) =
+let array_update_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) (ns : slice a) : result (array a n) =
admit()
-let slice_subslice_shared (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let array_repeat (a : Type0) (n : usize) (x : a) : array a n =
admit()
-let slice_subslice_mut_fwd (a : Type0) (x : slice a) (r : range usize) : result (slice a) =
+let slice_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) : result (slice a) =
admit()
-let slice_subslice_mut_back (a : Type0) (x : slice a) (r : range usize) (ns : slice a) : result (slice a) =
+let slice_update_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) (ns : slice a) : result (slice a) =
admit()
(*** Vector *)
-type vec (a : Type0) = v:list a{length v <= usize_max}
+type alloc_vec_Vec (a : Type0) = v:list a{length v <= usize_max}
-let vec_new (a : Type0) : vec a = assert_norm(length #a [] == 0); []
-let vec_len (a : Type0) (v : vec a) : usize = length v
+let alloc_vec_Vec_new (a : Type0) : alloc_vec_Vec a = assert_norm(length #a [] == 0); []
+let alloc_vec_Vec_len (a : Type0) (v : alloc_vec_Vec a) : usize = length v
+
+// Helper
+let alloc_vec_Vec_index_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) : result a =
+ if i < length v then Return (index v i) else Fail Failure
+// Helper
+let alloc_vec_Vec_update_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
// The **forward** function shouldn't be used
-let vec_push_fwd (a : Type0) (v : vec a) (x : a) : unit = ()
-let vec_push_back (a : Type0) (v : vec a) (x : a) :
- Pure (result (vec a))
+let alloc_vec_Vec_push_fwd (a : Type0) (v : alloc_vec_Vec a) (x : a) : unit = ()
+let alloc_vec_Vec_push (a : Type0) (v : alloc_vec_Vec a) (x : a) :
+ Pure (result (alloc_vec_Vec a))
(requires True)
(ensures (fun res ->
match res with
@@ -358,18 +451,279 @@ let vec_push_back (a : Type0) (v : vec a) (x : a) :
else Fail Failure
// The **forward** function shouldn't be used
-let vec_insert_fwd (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
+let alloc_vec_Vec_insert_fwd (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result unit =
if i < length v then Return () else Fail Failure
-let vec_insert_back (a : Type0) (v : vec a) (i : usize) (x : a) : result (vec a) =
+let alloc_vec_Vec_insert (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
if i < length v then Return (list_update v i x) else Fail Failure
-// The **backward** function shouldn't be used
-let vec_index_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_back (a : Type0) (v : vec a) (i : usize) (x : a) : result unit =
- if i < length v then Return () else Fail Failure
+// Trait declaration: [core::slice::index::private_slice_index::Sealed]
+type core_slice_index_private_slice_index_Sealed (self : Type0) = unit
+
+// Trait declaration: [core::slice::index::SliceIndex]
+noeq type core_slice_index_SliceIndex (self t : Type0) = {
+ sealedInst : core_slice_index_private_slice_index_Sealed self;
+ output : Type0;
+ get : self → t → result (option output);
+ get_mut : self → t → result (option output);
+ get_mut_back : self → t → option output → result t;
+ get_unchecked : self → const_raw_ptr t → result (const_raw_ptr output);
+ get_unchecked_mut : self → mut_raw_ptr t → result (mut_raw_ptr output);
+ index : self → t → result output;
+ index_mut : self → t → result output;
+ index_mut_back : self → t → output → result t;
+}
-let vec_index_mut_fwd (a : Type0) (v : vec a) (i : usize) : result a =
- if i < length v then Return (index v i) else Fail Failure
-let vec_index_mut_back (a : Type0) (v : vec a) (i : usize) (nx : a) : result (vec a) =
- if i < length v then Return (list_update v i nx) else Fail Failure
+// [core::slice::index::[T]::index]: forward function
+let core_slice_index_Slice_index
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (s : slice t) (i : idx) : result inst.output =
+ let* x = inst.get i s in
+ match x with
+ | None -> Fail Failure
+ | Some x -> Return x
+
+// [core::slice::index::Range:::get]: forward function
+let core_slice_index_Range_get (t : Type0) (i : core_ops_range_Range usize) (s : slice t) :
+ result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: forward function
+let core_slice_index_Range_get_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: backward function 0
+let core_slice_index_Range_get_mut_back
+ (t : Type0) :
+ core_ops_range_Range usize → slice t → option (slice t) → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_unchecked]: forward function
+let core_slice_index_Range_get_unchecked
+ (t : Type0) :
+ core_ops_range_Range usize → const_raw_ptr (slice t) → result (const_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::get_unchecked_mut]: forward function
+let core_slice_index_Range_get_unchecked_mut
+ (t : Type0) :
+ core_ops_range_Range usize → mut_raw_ptr (slice t) → result (mut_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::index]: forward function
+let core_slice_index_Range_index
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: forward function
+let core_slice_index_Range_index_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: backward function 0
+let core_slice_index_Range_index_mut_back
+ (t : Type0) : core_ops_range_Range usize → slice t → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::[T]::index_mut]: forward function
+let core_slice_index_Slice_index_mut
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → result inst.output =
+ admit () //
+
+// [core::slice::index::[T]::index_mut]: backward function 0
+let core_slice_index_Slice_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → inst.output → result (slice t) =
+ admit () // TODO
+
+// [core::array::[T; N]::index]: forward function
+let core_array_Array_index
+ (t idx : Type0) (n : usize) (inst : core_ops_index_Index (slice t) idx)
+ (a : array t n) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: forward function
+let core_array_Array_index_mut
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) : result inst.indexInst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: backward function 0
+let core_array_Array_index_mut_back
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) (x : inst.indexInst.output) : result (array t n) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (slice t) idx = {
+ output = inst.output;
+ index = core_slice_index_Slice_index t idx inst;
+}
+
+// Trait implementation: [core::slice::index::private_slice_index::Range]
+let core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) = ()
+
+// Trait implementation: [core::slice::index::Range]
+let core_slice_index_Range_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ output = slice t;
+ get = core_slice_index_Range_get t;
+ get_mut = core_slice_index_Range_get_mut t;
+ get_mut_back = core_slice_index_Range_get_mut_back t;
+ get_unchecked = core_slice_index_Range_get_unchecked t;
+ get_unchecked_mut = core_slice_index_Range_get_unchecked_mut t;
+ index = core_slice_index_Range_index t;
+ index_mut = core_slice_index_Range_index_mut t;
+ index_mut_back = core_slice_index_Range_index_mut_back t;
+}
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (slice t) idx = {
+ indexInst = core_slice_index_Slice_coreopsindexIndexInst t idx inst;
+ index_mut = core_slice_index_Slice_index_mut t idx inst;
+ index_mut_back = core_slice_index_Slice_index_mut_back t idx inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_Index (slice t) idx) :
+ core_ops_index_Index (array t n) idx = {
+ output = inst.output;
+ index = core_array_Array_index t idx n inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexMutInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_IndexMut (slice t) idx) :
+ core_ops_index_IndexMut (array t n) idx = {
+ indexInst = core_array_Array_coreopsindexIndexInst t idx n inst.indexInst;
+ index_mut = core_array_Array_index_mut t idx n inst;
+ index_mut_back = core_array_Array_index_mut_back t idx n inst;
+}
+
+// [core::slice::index::usize::get]: forward function
+let core_slice_index_usize_get
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: forward function
+let core_slice_index_usize_get_mut
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: backward function 0
+let core_slice_index_usize_get_mut_back
+ (t : Type0) : usize → slice t → option t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked]: forward function
+let core_slice_index_usize_get_unchecked
+ (t : Type0) : usize → const_raw_ptr (slice t) → result (const_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked_mut]: forward function
+let core_slice_index_usize_get_unchecked_mut
+ (t : Type0) : usize → mut_raw_ptr (slice t) → result (mut_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::index]: forward function
+let core_slice_index_usize_index (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: forward function
+let core_slice_index_usize_index_mut (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: backward function 0
+let core_slice_index_usize_index_mut_back
+ (t : Type0) : usize → slice t → t → result (slice t) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::private_slice_index::usize]
+let core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize = ()
+
+// Trait implementation: [core::slice::index::usize]
+let core_slice_index_usize_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex usize (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ output = t;
+ get = core_slice_index_usize_get t;
+ get_mut = core_slice_index_usize_get_mut t;
+ get_mut_back = core_slice_index_usize_get_mut_back t;
+ get_unchecked = core_slice_index_usize_get_unchecked t;
+ get_unchecked_mut = core_slice_index_usize_get_unchecked_mut t;
+ index = core_slice_index_usize_index t;
+ index_mut = core_slice_index_usize_index_mut t;
+ index_mut_back = core_slice_index_usize_index_mut_back t;
+}
+
+// [alloc::vec::Vec::index]: forward function
+let alloc_vec_Vec_index (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: forward function
+let alloc_vec_Vec_index_mut (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: backward function 0
+let alloc_vec_Vec_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) (x : inst.output) : result (alloc_vec_Vec t) =
+ admit () // TODO
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (alloc_vec_Vec t) idx = {
+ output = inst.output;
+ index = alloc_vec_Vec_index t idx inst;
+}
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (alloc_vec_Vec t) idx = {
+ indexInst = alloc_vec_Vec_coreopsindexIndexInst t idx inst;
+ index_mut = alloc_vec_Vec_index_mut t idx inst;
+ index_mut_back = alloc_vec_Vec_index_mut_back t idx inst;
+}
+
+(*** Theorems *)
+
+let alloc_vec_Vec_index_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_back_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) :
+ Lemma (
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x ==
+ alloc_vec_Vec_update_usize v i x)
+ [SMTPat (alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x)]
+ =
+ admit()
diff --git a/tests/fstar/traits/Makefile b/tests/fstar/traits/Makefile
new file mode 100644
index 00000000..fa7d1f36
--- /dev/null
+++ b/tests/fstar/traits/Makefile
@@ -0,0 +1,49 @@
+# This file was automatically generated - modify ../Makefile.template instead
+INCLUDE_DIRS = .
+
+FSTAR_INCLUDES = $(addprefix --include ,$(INCLUDE_DIRS))
+
+FSTAR_HINTS ?= --use_hints --use_hint_hashes --record_hints
+
+FSTAR_OPTIONS = $(FSTAR_HINTS) \
+ --cache_checked_modules $(FSTAR_INCLUDES) --cmi \
+ --warn_error '+241@247+285-274' \
+
+FSTAR_EXE ?= fstar.exe
+FSTAR_NO_FLAGS = $(FSTAR_EXE) --already_cached 'Prims FStar LowStar Steel' --odir obj --cache_dir obj
+
+FSTAR = $(FSTAR_NO_FLAGS) $(FSTAR_OPTIONS)
+
+# The F* roots are used to compute the dependency graph, and generate the .depend file
+FSTAR_ROOTS ?= $(wildcard *.fst *.fsti)
+
+# Build all the files
+all: $(addprefix obj/,$(addsuffix .checked,$(FSTAR_ROOTS)))
+
+# This is the right way to ensure the .depend file always gets re-built.
+ifeq (,$(filter %-in,$(MAKECMDGOALS)))
+ifndef NODEPEND
+ifndef MAKE_RESTARTS
+.depend: .FORCE
+ $(FSTAR_NO_FLAGS) --dep full $(notdir $(FSTAR_ROOTS)) > $@
+
+.PHONY: .FORCE
+.FORCE:
+endif
+endif
+
+include .depend
+endif
+
+# For the interactive mode
+%.fst-in %.fsti-in:
+ @echo $(FSTAR_OPTIONS)
+
+# Generete the .checked files in batch mode
+%.checked:
+ $(FSTAR) $(FSTAR_OPTIONS) $< && \
+ touch -c $@
+
+.PHONY: clean
+clean:
+ rm -f obj/*
diff --git a/tests/fstar/traits/Primitives.fst b/tests/fstar/traits/Primitives.fst
new file mode 100644
index 00000000..3297803c
--- /dev/null
+++ b/tests/fstar/traits/Primitives.fst
@@ -0,0 +1,729 @@
+/// This file lists primitive and assumed functions and types
+module Primitives
+open FStar.Mul
+open FStar.List.Tot
+
+#set-options "--z3rlimit 15 --fuel 0 --ifuel 1"
+
+(*** Utilities *)
+val list_update (#a : Type0) (ls : list a) (i : nat{i < length ls}) (x : a) :
+ ls':list a{
+ length ls' = length ls /\
+ index ls' i == x
+ }
+#push-options "--fuel 1"
+let rec list_update #a ls i x =
+ match ls with
+ | x' :: ls -> if i = 0 then x :: ls else x' :: list_update ls (i-1) x
+#pop-options
+
+(*** Result *)
+type error : Type0 =
+| Failure
+| OutOfFuel
+
+type result (a : Type0) : Type0 =
+| Return : v:a -> result a
+| Fail : e:error -> result a
+
+// Monadic return operator
+unfold let return (#a : Type0) (x : a) : result a = Return x
+
+// Monadic bind operator.
+// Allows to use the notation:
+// ```
+// let* x = y in
+// ...
+// ```
+unfold let (let*) (#a #b : Type0) (m: result a)
+ (f: (x:a) -> Pure (result b) (requires (m == Return x)) (ensures fun _ -> True)) :
+ result b =
+ match m with
+ | Return x -> f x
+ | Fail e -> Fail e
+
+// Monadic assert(...)
+let massert (b:bool) : result unit = if b then Return () else Fail Failure
+
+// Normalize and unwrap a successful result (used for globals).
+let eval_global (#a : Type0) (x : result a{Return? (normalize_term x)}) : a = Return?.v x
+
+(*** Misc *)
+type char = FStar.Char.char
+type string = string
+
+let is_zero (n: nat) : bool = n = 0
+let decrease (n: nat{n > 0}) : nat = n - 1
+
+let core_mem_replace (a : Type0) (x : a) (y : a) : a = x
+let core_mem_replace_back (a : Type0) (x : a) (y : a) : a = y
+
+// We don't really use raw pointers for now
+type mut_raw_ptr (t : Type0) = { v : t }
+type const_raw_ptr (t : Type0) = { v : t }
+
+(*** Scalars *)
+/// Rem.: most of the following code was partially generated
+
+let isize_min : int = -9223372036854775808 // TODO: should be opaque
+let isize_max : int = 9223372036854775807 // TODO: should be opaque
+let i8_min : int = -128
+let i8_max : int = 127
+let i16_min : int = -32768
+let i16_max : int = 32767
+let i32_min : int = -2147483648
+let i32_max : int = 2147483647
+let i64_min : int = -9223372036854775808
+let i64_max : int = 9223372036854775807
+let i128_min : int = -170141183460469231731687303715884105728
+let i128_max : int = 170141183460469231731687303715884105727
+let usize_min : int = 0
+let usize_max : int = 4294967295 // TODO: should be opaque
+let u8_min : int = 0
+let u8_max : int = 255
+let u16_min : int = 0
+let u16_max : int = 65535
+let u32_min : int = 0
+let u32_max : int = 4294967295
+let u64_min : int = 0
+let u64_max : int = 18446744073709551615
+let u128_min : int = 0
+let u128_max : int = 340282366920938463463374607431768211455
+
+type scalar_ty =
+| Isize
+| I8
+| I16
+| I32
+| I64
+| I128
+| Usize
+| U8
+| U16
+| U32
+| U64
+| U128
+
+let is_unsigned = function
+ | Isize | I8 | I16 | I32 | I64 | I128 -> false
+ | Usize | U8 | U16 | U32 | U64 | U128 -> true
+
+
+let scalar_min (ty : scalar_ty) : int =
+ match ty with
+ | Isize -> isize_min
+ | I8 -> i8_min
+ | I16 -> i16_min
+ | I32 -> i32_min
+ | I64 -> i64_min
+ | I128 -> i128_min
+ | Usize -> usize_min
+ | U8 -> u8_min
+ | U16 -> u16_min
+ | U32 -> u32_min
+ | U64 -> u64_min
+ | U128 -> u128_min
+
+let scalar_max (ty : scalar_ty) : int =
+ match ty with
+ | Isize -> isize_max
+ | I8 -> i8_max
+ | I16 -> i16_max
+ | I32 -> i32_max
+ | I64 -> i64_max
+ | I128 -> i128_max
+ | Usize -> usize_max
+ | U8 -> u8_max
+ | U16 -> u16_max
+ | U32 -> u32_max
+ | U64 -> u64_max
+ | U128 -> u128_max
+
+type scalar (ty : scalar_ty) : eqtype = x:int{scalar_min ty <= x && x <= scalar_max ty}
+
+let mk_scalar (ty : scalar_ty) (x : int) : result (scalar ty) =
+ if scalar_min ty <= x && scalar_max ty >= x then Return x else Fail Failure
+
+let scalar_neg (#ty : scalar_ty) (x : scalar ty) : result (scalar ty) = mk_scalar ty (-x)
+
+let scalar_div (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
+ if y <> 0 then mk_scalar ty (x / y) else Fail Failure
+
+/// The remainder operation
+let int_rem (x : int) (y : int{y <> 0}) : int =
+ if x >= 0 then (x % y) else -(x % y)
+
+(* Checking consistency with Rust *)
+let _ = assert_norm(int_rem 1 2 = 1)
+let _ = assert_norm(int_rem (-1) 2 = -1)
+let _ = assert_norm(int_rem 1 (-2) = 1)
+let _ = assert_norm(int_rem (-1) (-2) = -1)
+
+let scalar_rem (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
+ if y <> 0 then mk_scalar ty (int_rem x y) else Fail Failure
+
+let scalar_add (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
+ mk_scalar ty (x + y)
+
+let scalar_sub (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
+ mk_scalar ty (x - y)
+
+let scalar_mul (#ty : scalar_ty) (x : scalar ty) (y : scalar ty) : result (scalar ty) =
+ mk_scalar ty (x * y)
+
+let scalar_lxor (#ty : scalar_ty { is_unsigned ty && ty <> Usize })
+ (x : scalar ty) (y : scalar ty) : scalar ty =
+ match ty with
+ | U8 -> FStar.UInt.logxor #8 x y
+ | U16 -> FStar.UInt.logxor #16 x y
+ | U32 -> FStar.UInt.logxor #32 x y
+ | U64 -> FStar.UInt.logxor #64 x y
+ | U128 -> FStar.UInt.logxor #128 x y
+
+(** Cast an integer from a [src_ty] to a [tgt_ty] *)
+// TODO: check the semantics of casts in Rust
+let scalar_cast (src_ty : scalar_ty) (tgt_ty : scalar_ty) (x : scalar src_ty) : result (scalar tgt_ty) =
+ mk_scalar tgt_ty x
+
+/// The scalar types
+type isize : eqtype = scalar Isize
+type i8 : eqtype = scalar I8
+type i16 : eqtype = scalar I16
+type i32 : eqtype = scalar I32
+type i64 : eqtype = scalar I64
+type i128 : eqtype = scalar I128
+type usize : eqtype = scalar Usize
+type u8 : eqtype = scalar U8
+type u16 : eqtype = scalar U16
+type u32 : eqtype = scalar U32
+type u64 : eqtype = scalar U64
+type u128 : eqtype = scalar U128
+
+
+let core_isize_min : isize = isize_min
+let core_isize_max : isize = isize_max
+let core_i8_min : i8 = i8_min
+let core_i8_max : i8 = i8_max
+let core_i16_min : i16 = i16_min
+let core_i16_max : i16 = i16_max
+let core_i32_min : i32 = i32_min
+let core_i32_max : i32 = i32_max
+let core_i64_min : i64 = i64_min
+let core_i64_max : i64 = i64_max
+let core_i128_min : i128 = i128_min
+let core_i128_max : i128 = i128_max
+
+let core_usize_min : usize = usize_min
+let core_usize_max : usize = usize_max
+let core_u8_min : u8 = u8_min
+let core_u8_max : u8 = u8_max
+let core_u16_min : u16 = u16_min
+let core_u16_max : u16 = u16_max
+let core_u32_min : u32 = u32_min
+let core_u32_max : u32 = u32_max
+let core_u64_min : u64 = u64_min
+let core_u64_max : u64 = u64_max
+let core_u128_min : u128 = u128_min
+let core_u128_max : u128 = u128_max
+
+/// Negation
+let isize_neg = scalar_neg #Isize
+let i8_neg = scalar_neg #I8
+let i16_neg = scalar_neg #I16
+let i32_neg = scalar_neg #I32
+let i64_neg = scalar_neg #I64
+let i128_neg = scalar_neg #I128
+
+/// Division
+let isize_div = scalar_div #Isize
+let i8_div = scalar_div #I8
+let i16_div = scalar_div #I16
+let i32_div = scalar_div #I32
+let i64_div = scalar_div #I64
+let i128_div = scalar_div #I128
+let usize_div = scalar_div #Usize
+let u8_div = scalar_div #U8
+let u16_div = scalar_div #U16
+let u32_div = scalar_div #U32
+let u64_div = scalar_div #U64
+let u128_div = scalar_div #U128
+
+/// Remainder
+let isize_rem = scalar_rem #Isize
+let i8_rem = scalar_rem #I8
+let i16_rem = scalar_rem #I16
+let i32_rem = scalar_rem #I32
+let i64_rem = scalar_rem #I64
+let i128_rem = scalar_rem #I128
+let usize_rem = scalar_rem #Usize
+let u8_rem = scalar_rem #U8
+let u16_rem = scalar_rem #U16
+let u32_rem = scalar_rem #U32
+let u64_rem = scalar_rem #U64
+let u128_rem = scalar_rem #U128
+
+/// Addition
+let isize_add = scalar_add #Isize
+let i8_add = scalar_add #I8
+let i16_add = scalar_add #I16
+let i32_add = scalar_add #I32
+let i64_add = scalar_add #I64
+let i128_add = scalar_add #I128
+let usize_add = scalar_add #Usize
+let u8_add = scalar_add #U8
+let u16_add = scalar_add #U16
+let u32_add = scalar_add #U32
+let u64_add = scalar_add #U64
+let u128_add = scalar_add #U128
+
+/// Subtraction
+let isize_sub = scalar_sub #Isize
+let i8_sub = scalar_sub #I8
+let i16_sub = scalar_sub #I16
+let i32_sub = scalar_sub #I32
+let i64_sub = scalar_sub #I64
+let i128_sub = scalar_sub #I128
+let usize_sub = scalar_sub #Usize
+let u8_sub = scalar_sub #U8
+let u16_sub = scalar_sub #U16
+let u32_sub = scalar_sub #U32
+let u64_sub = scalar_sub #U64
+let u128_sub = scalar_sub #U128
+
+/// Multiplication
+let isize_mul = scalar_mul #Isize
+let i8_mul = scalar_mul #I8
+let i16_mul = scalar_mul #I16
+let i32_mul = scalar_mul #I32
+let i64_mul = scalar_mul #I64
+let i128_mul = scalar_mul #I128
+let usize_mul = scalar_mul #Usize
+let u8_mul = scalar_mul #U8
+let u16_mul = scalar_mul #U16
+let u32_mul = scalar_mul #U32
+let u64_mul = scalar_mul #U64
+let u128_mul = scalar_mul #U128
+
+/// Logical operators, defined for unsigned types only, so far
+let u8_xor = scalar_lxor #U8
+let u16_xor = scalar_lxor #U16
+let u32_xor = scalar_lxor #U32
+let u64_xor = scalar_lxor #U64
+let u128_xor = scalar_lxor #U128
+
+(*** core::ops *)
+
+// Trait declaration: [core::ops::index::Index]
+noeq type core_ops_index_Index (self idx : Type0) = {
+ output : Type0;
+ index : self → idx → result output
+}
+
+// Trait declaration: [core::ops::index::IndexMut]
+noeq type core_ops_index_IndexMut (self idx : Type0) = {
+ indexInst : core_ops_index_Index self idx;
+ index_mut : self → idx → result indexInst.output;
+ index_mut_back : self → idx → indexInst.output → result self;
+}
+
+// Trait declaration [core::ops::deref::Deref]
+noeq type core_ops_deref_Deref (self : Type0) = {
+ target : Type0;
+ deref : self → result target;
+}
+
+// Trait declaration [core::ops::deref::DerefMut]
+noeq type core_ops_deref_DerefMut (self : Type0) = {
+ derefInst : core_ops_deref_Deref self;
+ deref_mut : self → result derefInst.target;
+ deref_mut_back : self → derefInst.target → result self;
+}
+
+type core_ops_range_Range (a : Type0) = {
+ start : a;
+ end_ : a;
+}
+
+(*** [alloc] *)
+
+let alloc_boxed_Box_deref (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut (t : Type0) (x : t) : result t = Return x
+let alloc_boxed_Box_deref_mut_back (t : Type) (_ : t) (x : t) : result t = Return x
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefInst (self : Type0) : core_ops_deref_Deref self = {
+ target = self;
+ deref = alloc_boxed_Box_deref self;
+}
+
+// Trait instance
+let alloc_boxed_Box_coreOpsDerefMutInst (self : Type0) : core_ops_deref_DerefMut self = {
+ derefInst = alloc_boxed_Box_coreOpsDerefInst self;
+ deref_mut = alloc_boxed_Box_deref_mut self;
+ deref_mut_back = alloc_boxed_Box_deref_mut_back self;
+}
+
+(*** Array *)
+type array (a : Type0) (n : usize) = s:list a{length s = n}
+
+// We tried putting the normalize_term condition as a refinement on the list
+// but it didn't work. It works with the requires clause.
+let mk_array (a : Type0) (n : usize)
+ (l : list a) :
+ Pure (array a n)
+ (requires (normalize_term(FStar.List.Tot.length l) = n))
+ (ensures (fun _ -> True)) =
+ normalize_term_spec (FStar.List.Tot.length l);
+ l
+
+let array_index_usize (a : Type0) (n : usize) (x : array a n) (i : usize) : result a =
+ if i < length x then Return (index x i)
+ else Fail Failure
+
+let array_update_usize (a : Type0) (n : usize) (x : array a n) (i : usize) (nx : a) : result (array a n) =
+ if i < length x then Return (list_update x i nx)
+ else Fail Failure
+
+(*** Slice *)
+type slice (a : Type0) = s:list a{length s <= usize_max}
+
+let slice_len (a : Type0) (s : slice a) : usize = length s
+
+let slice_index_usize (a : Type0) (x : slice a) (i : usize) : result a =
+ if i < length x then Return (index x i)
+ else Fail Failure
+
+let slice_update_usize (a : Type0) (x : slice a) (i : usize) (nx : a) : result (slice a) =
+ if i < length x then Return (list_update x i nx)
+ else Fail Failure
+
+(*** Subslices *)
+
+let array_to_slice (a : Type0) (n : usize) (x : array a n) : result (slice a) = Return x
+let array_from_slice (a : Type0) (n : usize) (x : array a n) (s : slice a) : result (array a n) =
+ if length s = n then Return s
+ else Fail Failure
+
+// TODO: finish the definitions below (there lacks [List.drop] and [List.take] in the standard library *)
+let array_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) : result (slice a) =
+ admit()
+
+let array_update_subslice (a : Type0) (n : usize) (x : array a n) (r : core_ops_range_Range usize) (ns : slice a) : result (array a n) =
+ admit()
+
+let array_repeat (a : Type0) (n : usize) (x : a) : array a n =
+ admit()
+
+let slice_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) : result (slice a) =
+ admit()
+
+let slice_update_subslice (a : Type0) (x : slice a) (r : core_ops_range_Range usize) (ns : slice a) : result (slice a) =
+ admit()
+
+(*** Vector *)
+type alloc_vec_Vec (a : Type0) = v:list a{length v <= usize_max}
+
+let alloc_vec_Vec_new (a : Type0) : alloc_vec_Vec a = assert_norm(length #a [] == 0); []
+let alloc_vec_Vec_len (a : Type0) (v : alloc_vec_Vec a) : usize = length v
+
+// Helper
+let alloc_vec_Vec_index_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) : result a =
+ if i < length v then Return (index v i) else Fail Failure
+// Helper
+let alloc_vec_Vec_update_usize (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
+
+// The **forward** function shouldn't be used
+let alloc_vec_Vec_push_fwd (a : Type0) (v : alloc_vec_Vec a) (x : a) : unit = ()
+let alloc_vec_Vec_push (a : Type0) (v : alloc_vec_Vec a) (x : a) :
+ Pure (result (alloc_vec_Vec a))
+ (requires True)
+ (ensures (fun res ->
+ match res with
+ | Fail e -> e == Failure
+ | Return v' -> length v' = length v + 1)) =
+ if length v < usize_max then begin
+ (**) assert_norm(length [x] == 1);
+ (**) append_length v [x];
+ (**) assert(length (append v [x]) = length v + 1);
+ Return (append v [x])
+ end
+ else Fail Failure
+
+// The **forward** function shouldn't be used
+let alloc_vec_Vec_insert_fwd (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result unit =
+ if i < length v then Return () else Fail Failure
+let alloc_vec_Vec_insert (a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) : result (alloc_vec_Vec a) =
+ if i < length v then Return (list_update v i x) else Fail Failure
+
+// Trait declaration: [core::slice::index::private_slice_index::Sealed]
+type core_slice_index_private_slice_index_Sealed (self : Type0) = unit
+
+// Trait declaration: [core::slice::index::SliceIndex]
+noeq type core_slice_index_SliceIndex (self t : Type0) = {
+ sealedInst : core_slice_index_private_slice_index_Sealed self;
+ output : Type0;
+ get : self → t → result (option output);
+ get_mut : self → t → result (option output);
+ get_mut_back : self → t → option output → result t;
+ get_unchecked : self → const_raw_ptr t → result (const_raw_ptr output);
+ get_unchecked_mut : self → mut_raw_ptr t → result (mut_raw_ptr output);
+ index : self → t → result output;
+ index_mut : self → t → result output;
+ index_mut_back : self → t → output → result t;
+}
+
+// [core::slice::index::[T]::index]: forward function
+let core_slice_index_Slice_index
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (s : slice t) (i : idx) : result inst.output =
+ let* x = inst.get i s in
+ match x with
+ | None -> Fail Failure
+ | Some x -> Return x
+
+// [core::slice::index::Range:::get]: forward function
+let core_slice_index_Range_get (t : Type0) (i : core_ops_range_Range usize) (s : slice t) :
+ result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: forward function
+let core_slice_index_Range_get_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (option (slice t)) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_mut]: backward function 0
+let core_slice_index_Range_get_mut_back
+ (t : Type0) :
+ core_ops_range_Range usize → slice t → option (slice t) → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::get_unchecked]: forward function
+let core_slice_index_Range_get_unchecked
+ (t : Type0) :
+ core_ops_range_Range usize → const_raw_ptr (slice t) → result (const_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::get_unchecked_mut]: forward function
+let core_slice_index_Range_get_unchecked_mut
+ (t : Type0) :
+ core_ops_range_Range usize → mut_raw_ptr (slice t) → result (mut_raw_ptr (slice t)) =
+ // Don't know what the model should be - for now we always fail to make
+ // sure code which uses it fails
+ fun _ _ -> Fail Failure
+
+// [core::slice::index::Range::index]: forward function
+let core_slice_index_Range_index
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: forward function
+let core_slice_index_Range_index_mut
+ (t : Type0) : core_ops_range_Range usize → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::Range::index_mut]: backward function 0
+let core_slice_index_Range_index_mut_back
+ (t : Type0) : core_ops_range_Range usize → slice t → slice t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::[T]::index_mut]: forward function
+let core_slice_index_Slice_index_mut
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → result inst.output =
+ admit () //
+
+// [core::slice::index::[T]::index_mut]: backward function 0
+let core_slice_index_Slice_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t)) :
+ slice t → idx → inst.output → result (slice t) =
+ admit () // TODO
+
+// [core::array::[T; N]::index]: forward function
+let core_array_Array_index
+ (t idx : Type0) (n : usize) (inst : core_ops_index_Index (slice t) idx)
+ (a : array t n) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: forward function
+let core_array_Array_index_mut
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) : result inst.indexInst.output =
+ admit () // TODO
+
+// [core::array::[T; N]::index_mut]: backward function 0
+let core_array_Array_index_mut_back
+ (t idx : Type0) (n : usize) (inst : core_ops_index_IndexMut (slice t) idx)
+ (a : array t n) (i : idx) (x : inst.indexInst.output) : result (array t n) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (slice t) idx = {
+ output = inst.output;
+ index = core_slice_index_Slice_index t idx inst;
+}
+
+// Trait implementation: [core::slice::index::private_slice_index::Range]
+let core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed (core_ops_range_Range usize) = ()
+
+// Trait implementation: [core::slice::index::Range]
+let core_slice_index_Range_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex (core_ops_range_Range usize) (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_Range_coresliceindexprivate_slice_indexSealedInst;
+ output = slice t;
+ get = core_slice_index_Range_get t;
+ get_mut = core_slice_index_Range_get_mut t;
+ get_mut_back = core_slice_index_Range_get_mut_back t;
+ get_unchecked = core_slice_index_Range_get_unchecked t;
+ get_unchecked_mut = core_slice_index_Range_get_unchecked_mut t;
+ index = core_slice_index_Range_index t;
+ index_mut = core_slice_index_Range_index_mut t;
+ index_mut_back = core_slice_index_Range_index_mut_back t;
+}
+
+// Trait implementation: [core::slice::index::[T]]
+let core_slice_index_Slice_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (slice t) idx = {
+ indexInst = core_slice_index_Slice_coreopsindexIndexInst t idx inst;
+ index_mut = core_slice_index_Slice_index_mut t idx inst;
+ index_mut_back = core_slice_index_Slice_index_mut_back t idx inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_Index (slice t) idx) :
+ core_ops_index_Index (array t n) idx = {
+ output = inst.output;
+ index = core_array_Array_index t idx n inst;
+}
+
+// Trait implementation: [core::array::[T; N]]
+let core_array_Array_coreopsindexIndexMutInst (t idx : Type0) (n : usize)
+ (inst : core_ops_index_IndexMut (slice t) idx) :
+ core_ops_index_IndexMut (array t n) idx = {
+ indexInst = core_array_Array_coreopsindexIndexInst t idx n inst.indexInst;
+ index_mut = core_array_Array_index_mut t idx n inst;
+ index_mut_back = core_array_Array_index_mut_back t idx n inst;
+}
+
+// [core::slice::index::usize::get]: forward function
+let core_slice_index_usize_get
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: forward function
+let core_slice_index_usize_get_mut
+ (t : Type0) : usize → slice t → result (option t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_mut]: backward function 0
+let core_slice_index_usize_get_mut_back
+ (t : Type0) : usize → slice t → option t → result (slice t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked]: forward function
+let core_slice_index_usize_get_unchecked
+ (t : Type0) : usize → const_raw_ptr (slice t) → result (const_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::get_unchecked_mut]: forward function
+let core_slice_index_usize_get_unchecked_mut
+ (t : Type0) : usize → mut_raw_ptr (slice t) → result (mut_raw_ptr t) =
+ admit () // TODO
+
+// [core::slice::index::usize::index]: forward function
+let core_slice_index_usize_index (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: forward function
+let core_slice_index_usize_index_mut (t : Type0) : usize → slice t → result t =
+ admit () // TODO
+
+// [core::slice::index::usize::index_mut]: backward function 0
+let core_slice_index_usize_index_mut_back
+ (t : Type0) : usize → slice t → t → result (slice t) =
+ admit () // TODO
+
+// Trait implementation: [core::slice::index::private_slice_index::usize]
+let core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst
+ : core_slice_index_private_slice_index_Sealed usize = ()
+
+// Trait implementation: [core::slice::index::usize]
+let core_slice_index_usize_coresliceindexSliceIndexInst (t : Type0) :
+ core_slice_index_SliceIndex usize (slice t) = {
+ sealedInst = core_slice_index_private_slice_index_usize_coresliceindexprivate_slice_indexSealedInst;
+ output = t;
+ get = core_slice_index_usize_get t;
+ get_mut = core_slice_index_usize_get_mut t;
+ get_mut_back = core_slice_index_usize_get_mut_back t;
+ get_unchecked = core_slice_index_usize_get_unchecked t;
+ get_unchecked_mut = core_slice_index_usize_get_unchecked_mut t;
+ index = core_slice_index_usize_index t;
+ index_mut = core_slice_index_usize_index_mut t;
+ index_mut_back = core_slice_index_usize_index_mut_back t;
+}
+
+// [alloc::vec::Vec::index]: forward function
+let alloc_vec_Vec_index (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: forward function
+let alloc_vec_Vec_index_mut (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) : result inst.output =
+ admit () // TODO
+
+// [alloc::vec::Vec::index_mut]: backward function 0
+let alloc_vec_Vec_index_mut_back
+ (t idx : Type0) (inst : core_slice_index_SliceIndex idx (slice t))
+ (self : alloc_vec_Vec t) (i : idx) (x : inst.output) : result (alloc_vec_Vec t) =
+ admit () // TODO
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_Index (alloc_vec_Vec t) idx = {
+ output = inst.output;
+ index = alloc_vec_Vec_index t idx inst;
+}
+
+// Trait implementation: [alloc::vec::Vec]
+let alloc_vec_Vec_coreopsindexIndexMutInst (t idx : Type0)
+ (inst : core_slice_index_SliceIndex idx (slice t)) :
+ core_ops_index_IndexMut (alloc_vec_Vec t) idx = {
+ indexInst = alloc_vec_Vec_coreopsindexIndexInst t idx inst;
+ index_mut = alloc_vec_Vec_index_mut t idx inst;
+ index_mut_back = alloc_vec_Vec_index_mut_back t idx inst;
+}
+
+(*** Theorems *)
+
+let alloc_vec_Vec_index_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) :
+ Lemma (
+ alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i ==
+ alloc_vec_Vec_index_usize v i)
+ [SMTPat (alloc_vec_Vec_index_mut a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i)]
+ =
+ admit()
+
+let alloc_vec_Vec_index_mut_back_eq (#a : Type0) (v : alloc_vec_Vec a) (i : usize) (x : a) :
+ Lemma (
+ alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x ==
+ alloc_vec_Vec_update_usize v i x)
+ [SMTPat (alloc_vec_Vec_index_mut_back a usize (core_slice_index_usize_coresliceindexSliceIndexInst a) v i x)]
+ =
+ admit()
diff --git a/tests/fstar/traits/Traits.fst b/tests/fstar/traits/Traits.fst
new file mode 100644
index 00000000..318efa2b
--- /dev/null
+++ b/tests/fstar/traits/Traits.fst
@@ -0,0 +1,371 @@
+(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *)
+(** [traits] *)
+module Traits
+open Primitives
+
+#set-options "--z3rlimit 50 --fuel 1 --ifuel 1"
+
+(** Trait declaration: [traits::BoolTrait] *)
+noeq type boolTrait_t (self : Type0) = { get_bool : self -> result bool; }
+
+(** [traits::Bool::{0}::get_bool]: forward function *)
+let bool_get_bool (self : bool) : result bool =
+ Return self
+
+(** Trait implementation: [traits::Bool::{0}] *)
+let bool_BoolTraitInst : boolTrait_t bool = { get_bool = bool_get_bool; }
+
+(** [traits::BoolTrait::ret_true]: forward function *)
+let boolTrait_ret_true
+ (#self : Type0) (self_clause : boolTrait_t self) (self0 : self) :
+ result bool
+ =
+ Return true
+
+(** [traits::test_bool_trait_bool]: forward function *)
+let test_bool_trait_bool (x : bool) : result bool =
+ let* b = bool_get_bool x in
+ if b then boolTrait_ret_true bool_BoolTraitInst x else Return false
+
+(** [traits::Option::{1}::get_bool]: forward function *)
+let option_get_bool (t : Type0) (self : option t) : result bool =
+ begin match self with | None -> Return false | Some x -> Return true end
+
+(** Trait implementation: [traits::Option::{1}] *)
+let option_BoolTraitInst (t : Type0) : boolTrait_t (option t) = {
+ get_bool = option_get_bool t;
+}
+
+(** [traits::test_bool_trait_option]: forward function *)
+let test_bool_trait_option (t : Type0) (x : option t) : result bool =
+ let* b = option_get_bool t x in
+ if b then boolTrait_ret_true (option_BoolTraitInst t) x else Return false
+
+(** [traits::test_bool_trait]: forward function *)
+let test_bool_trait (t : Type0) (inst : boolTrait_t t) (x : t) : result bool =
+ inst.get_bool x
+
+(** Trait declaration: [traits::ToU64] *)
+noeq type toU64_t (self : Type0) = { to_u64 : self -> result u64; }
+
+(** [traits::u64::{2}::to_u64]: forward function *)
+let u64_to_u64 (self : u64) : result u64 =
+ Return self
+
+(** Trait implementation: [traits::u64::{2}] *)
+let u64_ToU64Inst : toU64_t u64 = { to_u64 = u64_to_u64; }
+
+(** [traits::Tuple2::{3}::to_u64]: forward function *)
+let tuple2_to_u64
+ (a : Type0) (inst : toU64_t a) (self : (a & a)) : result u64 =
+ let (x, x0) = self in
+ let* i = inst.to_u64 x in
+ let* i0 = inst.to_u64 x0 in
+ u64_add i i0
+
+(** Trait implementation: [traits::Tuple2::{3}] *)
+let tuple2_ToU64Inst (a : Type0) (inst : toU64_t a) : toU64_t (a & a) = {
+ to_u64 = tuple2_to_u64 a inst;
+}
+
+(** [traits::f]: forward function *)
+let f (t : Type0) (inst : toU64_t t) (x : (t & t)) : result u64 =
+ tuple2_to_u64 t inst x
+
+(** [traits::g]: forward function *)
+let g (t : Type0) (inst : toU64_t (t & t)) (x : (t & t)) : result u64 =
+ inst.to_u64 x
+
+(** [traits::h0]: forward function *)
+let h0 (x : u64) : result u64 =
+ u64_to_u64 x
+
+(** [traits::Wrapper] *)
+type wrapper_t (t : Type0) = { x : t; }
+
+(** [traits::Wrapper::{4}::to_u64]: forward function *)
+let wrapper_to_u64
+ (t : Type0) (inst : toU64_t t) (self : wrapper_t t) : result u64 =
+ inst.to_u64 self.x
+
+(** Trait implementation: [traits::Wrapper::{4}] *)
+let wrapper_ToU64Inst (t : Type0) (inst : toU64_t t) : toU64_t (wrapper_t t)
+ = {
+ to_u64 = wrapper_to_u64 t inst;
+}
+
+(** [traits::h1]: forward function *)
+let h1 (x : wrapper_t u64) : result u64 =
+ wrapper_to_u64 u64 u64_ToU64Inst x
+
+(** [traits::h2]: forward function *)
+let h2 (t : Type0) (inst : toU64_t t) (x : wrapper_t t) : result u64 =
+ wrapper_to_u64 t inst x
+
+(** Trait declaration: [traits::ToType] *)
+noeq type toType_t (self t : Type0) = { to_type : self -> result t; }
+
+(** [traits::u64::{5}::to_type]: forward function *)
+let u64_to_type (self : u64) : result bool =
+ Return (self > 0)
+
+(** Trait implementation: [traits::u64::{5}] *)
+let u64_ToTypeInst : toType_t u64 bool = { to_type = u64_to_type; }
+
+(** Trait declaration: [traits::OfType] *)
+noeq type ofType_t (self : Type0) = {
+ of_type : (t : Type0) -> (inst : toType_t t self) -> t -> result self;
+}
+
+(** [traits::h3]: forward function *)
+let h3
+ (t1 t2 : Type0) (inst : ofType_t t1) (inst0 : toType_t t2 t1) (y : t2) :
+ result t1
+ =
+ inst.of_type t2 inst0 y
+
+(** Trait declaration: [traits::OfTypeBis] *)
+noeq type ofTypeBis_t (self t : Type0) = {
+ parent_clause_0 : toType_t t self;
+ of_type : t -> result self;
+}
+
+(** [traits::h4]: forward function *)
+let h4
+ (t1 t2 : Type0) (inst : ofTypeBis_t t1 t2) (inst0 : toType_t t2 t1)
+ (y : t2) :
+ result t1
+ =
+ inst.of_type y
+
+(** [traits::TestType] *)
+type testType_t (t : Type0) = { _0 : t; }
+
+(** [traits::TestType::{6}::test::TestType1] *)
+type testType_test_TestType1_t = { _0 : u64; }
+
+(** Trait declaration: [traits::TestType::{6}::test::TestTrait] *)
+noeq type testType_test_TestTrait_t (self : Type0) = {
+ test : self -> result bool;
+}
+
+(** [traits::TestType::{6}::test::TestType1::{0}::test]: forward function *)
+let testType_test_TestType1_test
+ (self : testType_test_TestType1_t) : result bool =
+ Return (self._0 > 1)
+
+(** Trait implementation: [traits::TestType::{6}::test::TestType1::{0}] *)
+let testType_test_TestType1_TestType_test_TestTraitInst :
+ testType_test_TestTrait_t testType_test_TestType1_t = {
+ test = testType_test_TestType1_test;
+}
+
+(** [traits::TestType::{6}::test]: forward function *)
+let testType_test
+ (t : Type0) (inst : toU64_t t) (self : testType_t t) (x : t) : result bool =
+ let* x0 = inst.to_u64 x in
+ if x0 > 0 then testType_test_TestType1_test { _0 = 0 } else Return false
+
+(** [traits::BoolWrapper] *)
+type boolWrapper_t = { _0 : bool; }
+
+(** [traits::BoolWrapper::{7}::to_type]: forward function *)
+let boolWrapper_to_type
+ (t : Type0) (inst : toType_t bool t) (self : boolWrapper_t) : result t =
+ inst.to_type self._0
+
+(** Trait implementation: [traits::BoolWrapper::{7}] *)
+let boolWrapper_ToTypeInst (t : Type0) (inst : toType_t bool t) : toType_t
+ boolWrapper_t t = {
+ to_type = boolWrapper_to_type t inst;
+}
+
+(** [traits::WithConstTy::LEN2] *)
+let with_const_ty_len2_body : result usize = Return 32
+let with_const_ty_len2_c : usize = eval_global with_const_ty_len2_body
+
+(** Trait declaration: [traits::WithConstTy] *)
+noeq type withConstTy_t (self : Type0) (len : usize) = {
+ cLEN1 : usize;
+ cLEN2 : usize;
+ tV : Type0;
+ tW : Type0;
+ tW_clause_0 : toU64_t tW;
+ f : tW -> array u8 len -> result tW;
+}
+
+(** [traits::Bool::{8}::LEN1] *)
+let bool_len1_body : result usize = Return 12
+let bool_len1_c : usize = eval_global bool_len1_body
+
+(** [traits::Bool::{8}::f]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) *)
+let bool_f (i : u64) (a : array u8 32) : result u64 =
+ Return i
+
+(** Trait implementation: [traits::Bool::{8}] *)
+let bool_WithConstTyInst : withConstTy_t bool 32 = {
+ cLEN1 = bool_len1_c;
+ cLEN2 = with_const_ty_len2_c;
+ tV = u8;
+ tW = u64;
+ tW_clause_0 = u64_ToU64Inst;
+ f = bool_f;
+}
+
+(** [traits::use_with_const_ty1]: forward function *)
+let use_with_const_ty1
+ (h : Type0) (len : usize) (inst : withConstTy_t h len) : result usize =
+ let i = inst.cLEN1 in Return i
+
+(** [traits::use_with_const_ty2]: forward function *)
+let use_with_const_ty2
+ (h : Type0) (len : usize) (inst : withConstTy_t h len) (w : inst.tW) :
+ result unit
+ =
+ Return ()
+
+(** [traits::use_with_const_ty3]: forward function *)
+let use_with_const_ty3
+ (h : Type0) (len : usize) (inst : withConstTy_t h len) (x : inst.tW) :
+ result u64
+ =
+ inst.tW_clause_0.to_u64 x
+
+(** [traits::test_where1]: forward function *)
+let test_where1 (t : Type0) (_x : t) : result unit =
+ Return ()
+
+(** [traits::test_where2]: forward function *)
+let test_where2
+ (t : Type0) (inst : withConstTy_t t 32) (_x : u32) : result unit =
+ Return ()
+
+(** [alloc::string::String] *)
+assume type alloc_string_String_t : Type0
+
+(** Trait declaration: [traits::ParentTrait0] *)
+noeq type parentTrait0_t (self : Type0) = {
+ tW : Type0;
+ get_name : self -> result alloc_string_String_t;
+ get_w : self -> result tW;
+}
+
+(** Trait declaration: [traits::ParentTrait1] *)
+type parentTrait1_t (self : Type0) = unit
+
+(** Trait declaration: [traits::ChildTrait] *)
+noeq type childTrait_t (self : Type0) = {
+ parent_clause_0 : parentTrait0_t self;
+ parent_clause_1 : parentTrait1_t self;
+}
+
+(** [traits::test_child_trait1]: forward function *)
+let test_child_trait1
+ (t : Type0) (inst : childTrait_t t) (x : t) : result alloc_string_String_t =
+ inst.parent_clause_0.get_name x
+
+(** [traits::test_child_trait2]: forward function *)
+let test_child_trait2
+ (t : Type0) (inst : childTrait_t t) (x : t) :
+ result inst.parent_clause_0.tW
+ =
+ inst.parent_clause_0.get_w x
+
+(** [traits::order1]: forward function *)
+let order1
+ (t u : Type0) (inst : parentTrait0_t t) (inst0 : parentTrait0_t u) :
+ result unit
+ =
+ Return ()
+
+(** Trait declaration: [traits::ChildTrait1] *)
+noeq type childTrait1_t (self : Type0) = {
+ parent_clause_0 : parentTrait1_t self;
+}
+
+(** Trait implementation: [traits::usize::{9}] *)
+let usize_ParentTrait1Inst : parentTrait1_t usize = ()
+
+(** Trait implementation: [traits::usize::{10}] *)
+let usize_ChildTrait1Inst : childTrait1_t usize = {
+ parent_clause_0 = usize_ParentTrait1Inst;
+}
+
+(** Trait declaration: [traits::Iterator] *)
+noeq type iterator_t (self : Type0) = { tItem : Type0; }
+
+(** Trait declaration: [traits::IntoIterator] *)
+noeq type intoIterator_t (self : Type0) = {
+ tItem : Type0;
+ tIntoIter : Type0;
+ tIntoIter_clause_0 : iterator_t tIntoIter;
+ into_iter : self -> result tIntoIter;
+}
+
+(** Trait declaration: [traits::FromResidual] *)
+type fromResidual_t (self t : Type0) = unit
+
+(** Trait declaration: [traits::Try] *)
+noeq type try_t (self : Type0) = {
+ tResidual : Type0;
+ parent_clause_0 : fromResidual_t self tResidual;
+}
+
+(** Trait declaration: [traits::WithTarget] *)
+noeq type withTarget_t (self : Type0) = { tTarget : Type0; }
+
+(** Trait declaration: [traits::ParentTrait2] *)
+noeq type parentTrait2_t (self : Type0) = {
+ tU : Type0;
+ tU_clause_0 : withTarget_t tU;
+}
+
+(** Trait declaration: [traits::ChildTrait2] *)
+noeq type childTrait2_t (self : Type0) = {
+ parent_clause_0 : parentTrait2_t self;
+ convert : parent_clause_0.tU -> result parent_clause_0.tU_clause_0.tTarget;
+}
+
+(** Trait implementation: [traits::u32::{11}] *)
+let u32_WithTargetInst : withTarget_t u32 = { tTarget = u32; }
+
+(** Trait implementation: [traits::u32::{12}] *)
+let u32_ParentTrait2Inst : parentTrait2_t u32 = {
+ tU = u32;
+ tU_clause_0 = u32_WithTargetInst;
+}
+
+(** [traits::u32::{13}::convert]: forward function *)
+let u32_convert (x : u32) : result u32 =
+ Return x
+
+(** Trait implementation: [traits::u32::{13}] *)
+let u32_ChildTrait2Inst : childTrait2_t u32 = {
+ parent_clause_0 = u32_ParentTrait2Inst;
+ convert = u32_convert;
+}
+
+(** [traits::incr_u32]: forward function *)
+let incr_u32 (x : u32) : result u32 =
+ u32_add x 1
+
+(** Trait declaration: [traits::CFnOnce] *)
+noeq type cFnOnce_t (self args : Type0) = {
+ tOutput : Type0;
+ call_once : self -> args -> result tOutput;
+}
+
+(** Trait declaration: [traits::CFnMut] *)
+noeq type cFnMut_t (self args : Type0) = {
+ parent_clause_0 : cFnOnce_t self args;
+ call_mut : self -> args -> result parent_clause_0.tOutput;
+ call_mut_back : self -> args -> parent_clause_0.tOutput -> result self;
+}
+
+(** Trait declaration: [traits::CFn] *)
+noeq type cFn_t (self args : Type0) = {
+ parent_clause_0 : cFnMut_t self args;
+ call_mut : self -> args -> result parent_clause_0.parent_clause_0.tOutput;
+}
+
diff --git a/tests/hol4/betree/betreeMain_FunsScript.sml b/tests/hol4/betree/betreeMain_FunsScript.sml
index 5e604f8c..bd16c16c 100644
--- a/tests/hol4/betree/betreeMain_FunsScript.sml
+++ b/tests/hol4/betree/betreeMain_FunsScript.sml
@@ -88,14 +88,6 @@ val betree_node_id_counter_fresh_id_back_def = Define ‘
od
-(** [core::num::u64::{9}::MAX] *)
-Definition core_num_u64_max_body_def:
- core_num_u64_max_body : u64 result = Return (int_to_u64 18446744073709551615)
-End
-Definition core_num_u64_max_c_def:
- core_num_u64_max_c : u64 = get_return_value core_num_u64_max_body
-End
-
val betree_upsert_update_fwd_def = Define ‘
(** [betree_main::betree::upsert_update]: forward function *)
betree_upsert_update_fwd
@@ -109,8 +101,8 @@ val betree_upsert_update_fwd_def = Define ‘
(case st of
| BetreeUpsertFunStateAdd v =>
do
- margin <- u64_sub core_num_u64_max_c prev0;
- if u64_ge margin v then u64_add prev0 v else Return core_num_u64_max_c
+ margin <- u64_sub core_u64_max prev0;
+ if u64_ge margin v then u64_add prev0 v else Return core_u64_max
od
| BetreeUpsertFunStateSub v =>
if u64_ge prev0 v then u64_sub prev0 v else Return (int_to_u64 0)))
diff --git a/tests/hol4/betree/betreeMain_FunsTheory.sig b/tests/hol4/betree/betreeMain_FunsTheory.sig
index 6c249f70..c922ca9f 100644
--- a/tests/hol4/betree/betreeMain_FunsTheory.sig
+++ b/tests/hol4/betree/betreeMain_FunsTheory.sig
@@ -58,8 +58,6 @@ sig
val betree_store_internal_node_fwd_def : thm
val betree_store_leaf_node_fwd_def : thm
val betree_upsert_update_fwd_def : thm
- val core_num_u64_max_body_def : thm
- val core_num_u64_max_c_def : thm
val main_fwd_def : thm
val betreeMain_Funs_grammars : type_grammar.grammar * term_grammar.grammar
@@ -1215,22 +1213,14 @@ sig
case st of
BetreeUpsertFunStateAdd v =>
do
- margin <- u64_sub core_num_u64_max_c prev0;
+ margin <- u64_sub core_u64_max prev0;
if u64_ge margin v then u64_add prev0 v
- else Return core_num_u64_max_c
+ else Return core_u64_max
od
| BetreeUpsertFunStateSub v' =>
if u64_ge prev0 v' then u64_sub prev0 v'
else Return (int_to_u64 0)
- [core_num_u64_max_body_def] Definition
-
- ⊢ core_num_u64_max_body = Return (int_to_u64 18446744073709551615)
-
- [core_num_u64_max_c_def] Definition
-
- ⊢ core_num_u64_max_c = get_return_value core_num_u64_max_body
-
[main_fwd_def] Definition
⊢ main_fwd = Return ()
diff --git a/tests/hol4/hashmap/hashmap_FunsScript.sml b/tests/hol4/hashmap/hashmap_FunsScript.sml
index e3c3d2a5..682c5760 100644
--- a/tests/hol4/hashmap/hashmap_FunsScript.sml
+++ b/tests/hol4/hashmap/hashmap_FunsScript.sml
@@ -170,14 +170,6 @@ val hash_map_insert_no_resize_fwd_back_def = Define ‘
od
-(** [core::num::u32::{8}::MAX] *)
-Definition core_num_u32_max_body_def:
- core_num_u32_max_body : u32 result = Return (int_to_u32 4294967295)
-End
-Definition core_num_u32_max_c_def:
- core_num_u32_max_c : u32 = get_return_value core_num_u32_max_body
-End
-
val [hash_map_move_elements_from_list_loop_fwd_back_def] = DefineDiv ‘
(** [hashmap::HashMap::{0}::move_elements_from_list]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
@@ -241,7 +233,7 @@ val hash_map_try_resize_fwd_back_def = Define ‘
(there is a single backward function, and the forward function returns ()) *)
hash_map_try_resize_fwd_back (self : 't hash_map_t) : 't hash_map_t result =
do
- max_usize <- mk_usize (u32_to_int core_num_u32_max_c);
+ max_usize <- mk_usize (u32_to_int core_u32_max);
let capacity = vec_len self.hash_map_slots in
do
n1 <- usize_div max_usize (int_to_usize 2);
diff --git a/tests/hol4/hashmap/hashmap_FunsTheory.sig b/tests/hol4/hashmap/hashmap_FunsTheory.sig
index 50482547..bb3e192b 100644
--- a/tests/hol4/hashmap/hashmap_FunsTheory.sig
+++ b/tests/hol4/hashmap/hashmap_FunsTheory.sig
@@ -3,8 +3,6 @@ sig
type thm = Thm.thm
(* Definitions *)
- val core_num_u32_max_body_def : thm
- val core_num_u32_max_c_def : thm
val hash_key_fwd_def : thm
val hash_map_allocate_slots_fwd_def : thm
val hash_map_allocate_slots_loop_fwd_def : thm
@@ -48,14 +46,6 @@ sig
(*
[hashmap_Types] Parent theory of "hashmap_Funs"
- [core_num_u32_max_body_def] Definition
-
- ⊢ core_num_u32_max_body = Return (int_to_u32 4294967295)
-
- [core_num_u32_max_c_def] Definition
-
- ⊢ core_num_u32_max_c = get_return_value core_num_u32_max_body
-
[hash_key_fwd_def] Definition
⊢ ∀k. hash_key_fwd k = Return k
@@ -472,7 +462,7 @@ sig
⊢ ∀self.
hash_map_try_resize_fwd_back self =
do
- max_usize <- mk_usize (u32_to_int core_num_u32_max_c);
+ max_usize <- mk_usize (u32_to_int core_u32_max);
capacity <<- vec_len self.hash_map_slots;
n1 <- usize_div max_usize (int_to_usize 2);
(i,i0) <<- self.hash_map_max_load_factor;
diff --git a/tests/hol4/hashmap/hashmap_PropertiesScript.sml b/tests/hol4/hashmap/hashmap_PropertiesScript.sml
index 7259f2f5..8bc12fa5 100644
--- a/tests/hol4/hashmap/hashmap_PropertiesScript.sml
+++ b/tests/hol4/hashmap/hashmap_PropertiesScript.sml
@@ -1296,7 +1296,7 @@ Proof
rw [hash_map_try_resize_fwd_back_def] >>
(* “_ <-- mk_usize (u32_to_int core_num_u32_max_c)” *)
assume_tac usize_u32_bounds >>
- fs [core_num_u32_max_c_def, core_num_u32_max_body_def, get_return_value_def, u32_max_def] >>
+ fs [core_u32_max_def, u32_max_def] >>
massage >> fs [mk_usize_def, u32_max_def] >>
(* / 2 *)
progress >>
diff --git a/tests/hol4/hashmap_on_disk/hashmapMain_FunsScript.sml b/tests/hol4/hashmap_on_disk/hashmapMain_FunsScript.sml
index b21c4f58..c1e30aa6 100644
--- a/tests/hol4/hashmap_on_disk/hashmapMain_FunsScript.sml
+++ b/tests/hol4/hashmap_on_disk/hashmapMain_FunsScript.sml
@@ -193,14 +193,6 @@ val hashmap_hash_map_insert_no_resize_fwd_back_def = Define ‘
od
-(** [core::num::u32::{8}::MAX] *)
-Definition core_num_u32_max_body_def:
- core_num_u32_max_body : u32 result = Return (int_to_u32 4294967295)
-End
-Definition core_num_u32_max_c_def:
- core_num_u32_max_c : u32 = get_return_value core_num_u32_max_body
-End
-
val [hashmap_hash_map_move_elements_from_list_loop_fwd_back_def] = DefineDiv ‘
(** [hashmap_main::hashmap::HashMap::{0}::move_elements_from_list]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) *)
@@ -271,7 +263,7 @@ val hashmap_hash_map_try_resize_fwd_back_def = Define ‘
hashmap_hash_map_try_resize_fwd_back
(self : 't hashmap_hash_map_t) : 't hashmap_hash_map_t result =
do
- max_usize <- mk_usize (u32_to_int core_num_u32_max_c);
+ max_usize <- mk_usize (u32_to_int core_u32_max);
let capacity = vec_len self.hashmap_hash_map_slots in
do
n1 <- usize_div max_usize (int_to_usize 2);
diff --git a/tests/hol4/hashmap_on_disk/hashmapMain_FunsTheory.sig b/tests/hol4/hashmap_on_disk/hashmapMain_FunsTheory.sig
index 1d24cb26..d4e43d9a 100644
--- a/tests/hol4/hashmap_on_disk/hashmapMain_FunsTheory.sig
+++ b/tests/hol4/hashmap_on_disk/hashmapMain_FunsTheory.sig
@@ -3,8 +3,6 @@ sig
type thm = Thm.thm
(* Definitions *)
- val core_num_u32_max_body_def : thm
- val core_num_u32_max_c_def : thm
val hashmap_hash_key_fwd_def : thm
val hashmap_hash_map_allocate_slots_fwd_def : thm
val hashmap_hash_map_allocate_slots_loop_fwd_def : thm
@@ -50,14 +48,6 @@ sig
(*
[hashmapMain_Opaque] Parent theory of "hashmapMain_Funs"
- [core_num_u32_max_body_def] Definition
-
- ⊢ core_num_u32_max_body = Return (int_to_u32 4294967295)
-
- [core_num_u32_max_c_def] Definition
-
- ⊢ core_num_u32_max_c = get_return_value core_num_u32_max_body
-
[hashmap_hash_key_fwd_def] Definition
⊢ ∀k. hashmap_hash_key_fwd k = Return k
@@ -506,7 +496,7 @@ sig
⊢ ∀self.
hashmap_hash_map_try_resize_fwd_back self =
do
- max_usize <- mk_usize (u32_to_int core_num_u32_max_c);
+ max_usize <- mk_usize (u32_to_int core_u32_max);
capacity <<- vec_len self.hashmap_hash_map_slots;
n1 <- usize_div max_usize (int_to_usize 2);
(i,i0) <<- self.hashmap_hash_map_max_load_factor;
diff --git a/tests/hol4/misc-constants/constantsScript.sml b/tests/hol4/misc-constants/constantsScript.sml
index d589d348..40a319c6 100644
--- a/tests/hol4/misc-constants/constantsScript.sml
+++ b/tests/hol4/misc-constants/constantsScript.sml
@@ -13,17 +13,9 @@ Definition x0_c_def:
x0_c : u32 = get_return_value x0_body
End
-(** [core::num::u32::{8}::MAX] *)
-Definition core_num_u32_max_body_def:
- core_num_u32_max_body : u32 result = Return (int_to_u32 4294967295)
-End
-Definition core_num_u32_max_c_def:
- core_num_u32_max_c : u32 = get_return_value core_num_u32_max_body
-End
-
(** [constants::X1] *)
Definition x1_body_def:
- x1_body : u32 result = Return core_num_u32_max_c
+ x1_body : u32 result = Return core_u32_max
End
Definition x1_c_def:
x1_c : u32 = get_return_value x1_body
diff --git a/tests/hol4/misc-constants/constantsTheory.sig b/tests/hol4/misc-constants/constantsTheory.sig
index 149d7e22..287ad5f5 100644
--- a/tests/hol4/misc-constants/constantsTheory.sig
+++ b/tests/hol4/misc-constants/constantsTheory.sig
@@ -4,8 +4,6 @@ sig
(* Definitions *)
val add_fwd_def : thm
- val core_num_u32_max_body_def : thm
- val core_num_u32_max_c_def : thm
val get_z1_fwd_def : thm
val get_z1_z1_body_def : thm
val get_z1_z1_c_def : thm
@@ -110,14 +108,6 @@ sig
⊢ ∀a b. add_fwd a b = i32_add a b
- [core_num_u32_max_body_def] Definition
-
- ⊢ core_num_u32_max_body = Return (int_to_u32 4294967295)
-
- [core_num_u32_max_c_def] Definition
-
- ⊢ core_num_u32_max_c = get_return_value core_num_u32_max_body
-
[get_z1_fwd_def] Definition
⊢ get_z1_fwd = Return get_z1_z1_c
@@ -321,7 +311,7 @@ sig
[x1_body_def] Definition
- ⊢ x1_body = Return core_num_u32_max_c
+ ⊢ x1_body = Return core_u32_max
[x1_c_def] Definition
diff --git a/tests/lean/Array.lean b/tests/lean/Array.lean
index 277b63d9..20f02e97 100644
--- a/tests/lean/Array.lean
+++ b/tests/lean/Array.lean
@@ -1 +1,435 @@
-import Array.Funs
+-- THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS
+-- [array]
+import Base
+open Primitives
+
+namespace array
+
+/- [array::AB] -/
+inductive AB :=
+| A : AB
+| B : AB
+
+/- [array::incr]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) -/
+def incr (x : U32) : Result U32 :=
+ x + 1#u32
+
+/- [array::array_to_shared_slice_]: forward function -/
+def array_to_shared_slice_
+ (T : Type) (s : Array T 32#usize) : Result (Slice T) :=
+ Array.to_slice T 32#usize s
+
+/- [array::array_to_mut_slice_]: forward function -/
+def array_to_mut_slice_ (T : Type) (s : Array T 32#usize) : Result (Slice T) :=
+ Array.to_slice T 32#usize s
+
+/- [array::array_to_mut_slice_]: backward function 0 -/
+def array_to_mut_slice__back
+ (T : Type) (s : Array T 32#usize) (ret0 : Slice T) :
+ Result (Array T 32#usize)
+ :=
+ Array.from_slice T 32#usize s ret0
+
+/- [array::array_len]: forward function -/
+def array_len (T : Type) (s : Array T 32#usize) : Result Usize :=
+ do
+ let s0 ← Array.to_slice T 32#usize s
+ let i := Slice.len T s0
+ Result.ret i
+
+/- [array::shared_array_len]: forward function -/
+def shared_array_len (T : Type) (s : Array T 32#usize) : Result Usize :=
+ do
+ let s0 ← Array.to_slice T 32#usize s
+ let i := Slice.len T s0
+ Result.ret i
+
+/- [array::shared_slice_len]: forward function -/
+def shared_slice_len (T : Type) (s : Slice T) : Result Usize :=
+ let i := Slice.len T s
+ Result.ret i
+
+/- [array::index_array_shared]: forward function -/
+def index_array_shared
+ (T : Type) (s : Array T 32#usize) (i : Usize) : Result T :=
+ Array.index_usize T 32#usize s i
+
+/- [array::index_array_u32]: forward function -/
+def index_array_u32 (s : Array U32 32#usize) (i : Usize) : Result U32 :=
+ Array.index_usize U32 32#usize s i
+
+/- [array::index_array_copy]: forward function -/
+def index_array_copy (x : Array U32 32#usize) : Result U32 :=
+ Array.index_usize U32 32#usize x 0#usize
+
+/- [array::index_mut_array]: forward function -/
+def index_mut_array (T : Type) (s : Array T 32#usize) (i : Usize) : Result T :=
+ Array.index_usize T 32#usize s i
+
+/- [array::index_mut_array]: backward function 0 -/
+def index_mut_array_back
+ (T : Type) (s : Array T 32#usize) (i : Usize) (ret0 : T) :
+ Result (Array T 32#usize)
+ :=
+ Array.update_usize T 32#usize s i ret0
+
+/- [array::index_slice]: forward function -/
+def index_slice (T : Type) (s : Slice T) (i : Usize) : Result T :=
+ Slice.index_usize T s i
+
+/- [array::index_mut_slice]: forward function -/
+def index_mut_slice (T : Type) (s : Slice T) (i : Usize) : Result T :=
+ Slice.index_usize T s i
+
+/- [array::index_mut_slice]: backward function 0 -/
+def index_mut_slice_back
+ (T : Type) (s : Slice T) (i : Usize) (ret0 : T) : Result (Slice T) :=
+ Slice.update_usize T s i ret0
+
+/- [array::slice_subslice_shared_]: forward function -/
+def slice_subslice_shared_
+ (x : Slice U32) (y : Usize) (z : Usize) : Result (Slice U32) :=
+ core.slice.index.Slice.index U32 (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32) x
+ { start := y, end_ := z }
+
+/- [array::slice_subslice_mut_]: forward function -/
+def slice_subslice_mut_
+ (x : Slice U32) (y : Usize) (z : Usize) : Result (Slice U32) :=
+ core.slice.index.Slice.index_mut U32 (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32) x
+ { start := y, end_ := z }
+
+/- [array::slice_subslice_mut_]: backward function 0 -/
+def slice_subslice_mut__back
+ (x : Slice U32) (y : Usize) (z : Usize) (ret0 : Slice U32) :
+ Result (Slice U32)
+ :=
+ core.slice.index.Slice.index_mut_back U32 (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32) x
+ { start := y, end_ := z } ret0
+
+/- [array::array_to_slice_shared_]: forward function -/
+def array_to_slice_shared_ (x : Array U32 32#usize) : Result (Slice U32) :=
+ Array.to_slice U32 32#usize x
+
+/- [array::array_to_slice_mut_]: forward function -/
+def array_to_slice_mut_ (x : Array U32 32#usize) : Result (Slice U32) :=
+ Array.to_slice U32 32#usize x
+
+/- [array::array_to_slice_mut_]: backward function 0 -/
+def array_to_slice_mut__back
+ (x : Array U32 32#usize) (ret0 : Slice U32) : Result (Array U32 32#usize) :=
+ Array.from_slice U32 32#usize x ret0
+
+/- [array::array_subslice_shared_]: forward function -/
+def array_subslice_shared_
+ (x : Array U32 32#usize) (y : Usize) (z : Usize) : Result (Slice U32) :=
+ core.array.Array.index U32 (core.ops.range.Range Usize) 32#usize
+ (core.slice.index.Slice.coreopsindexIndexInst U32 (core.ops.range.Range
+ Usize) (core.slice.index.Range.coresliceindexSliceIndexInst U32)) x
+ { start := y, end_ := z }
+
+/- [array::array_subslice_mut_]: forward function -/
+def array_subslice_mut_
+ (x : Array U32 32#usize) (y : Usize) (z : Usize) : Result (Slice U32) :=
+ core.array.Array.index_mut U32 (core.ops.range.Range Usize) 32#usize
+ (core.slice.index.Slice.coreopsindexIndexMutInst U32 (core.ops.range.Range
+ Usize) (core.slice.index.Range.coresliceindexSliceIndexInst U32)) x
+ { start := y, end_ := z }
+
+/- [array::array_subslice_mut_]: backward function 0 -/
+def array_subslice_mut__back
+ (x : Array U32 32#usize) (y : Usize) (z : Usize) (ret0 : Slice U32) :
+ Result (Array U32 32#usize)
+ :=
+ core.array.Array.index_mut_back U32 (core.ops.range.Range Usize) 32#usize
+ (core.slice.index.Slice.coreopsindexIndexMutInst U32 (core.ops.range.Range
+ Usize) (core.slice.index.Range.coresliceindexSliceIndexInst U32)) x
+ { start := y, end_ := z } ret0
+
+/- [array::index_slice_0]: forward function -/
+def index_slice_0 (T : Type) (s : Slice T) : Result T :=
+ Slice.index_usize T s 0#usize
+
+/- [array::index_array_0]: forward function -/
+def index_array_0 (T : Type) (s : Array T 32#usize) : Result T :=
+ Array.index_usize T 32#usize s 0#usize
+
+/- [array::index_index_array]: forward function -/
+def index_index_array
+ (s : Array (Array U32 32#usize) 32#usize) (i : Usize) (j : Usize) :
+ Result U32
+ :=
+ do
+ let a ← Array.index_usize (Array U32 32#usize) 32#usize s i
+ Array.index_usize U32 32#usize a j
+
+/- [array::update_update_array]: forward function -/
+def update_update_array
+ (s : Array (Array U32 32#usize) 32#usize) (i : Usize) (j : Usize) :
+ Result Unit
+ :=
+ do
+ let a ← Array.index_usize (Array U32 32#usize) 32#usize s i
+ let a0 ← Array.update_usize U32 32#usize a j 0#u32
+ let _ ← Array.update_usize (Array U32 32#usize) 32#usize s i a0
+ Result.ret ()
+
+/- [array::array_local_deep_copy]: forward function -/
+def array_local_deep_copy (x : Array U32 32#usize) : Result Unit :=
+ Result.ret ()
+
+/- [array::take_array]: forward function -/
+def take_array (a : Array U32 2#usize) : Result Unit :=
+ Result.ret ()
+
+/- [array::take_array_borrow]: forward function -/
+def take_array_borrow (a : Array U32 2#usize) : Result Unit :=
+ Result.ret ()
+
+/- [array::take_slice]: forward function -/
+def take_slice (s : Slice U32) : Result Unit :=
+ Result.ret ()
+
+/- [array::take_mut_slice]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) -/
+def take_mut_slice (s : Slice U32) : Result (Slice U32) :=
+ Result.ret s
+
+/- [array::take_all]: forward function -/
+def take_all : Result Unit :=
+ do
+ let _ ← take_array (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let _ ← take_array_borrow (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let s ←
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let _ ← take_slice s
+ let s0 ←
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let s1 ← take_mut_slice s0
+ let _ ←
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ]) s1
+ Result.ret ()
+
+/- [array::index_array]: forward function -/
+def index_array (x : Array U32 2#usize) : Result U32 :=
+ Array.index_usize U32 2#usize x 0#usize
+
+/- [array::index_array_borrow]: forward function -/
+def index_array_borrow (x : Array U32 2#usize) : Result U32 :=
+ Array.index_usize U32 2#usize x 0#usize
+
+/- [array::index_slice_u32_0]: forward function -/
+def index_slice_u32_0 (x : Slice U32) : Result U32 :=
+ Slice.index_usize U32 x 0#usize
+
+/- [array::index_mut_slice_u32_0]: forward function -/
+def index_mut_slice_u32_0 (x : Slice U32) : Result U32 :=
+ Slice.index_usize U32 x 0#usize
+
+/- [array::index_mut_slice_u32_0]: backward function 0 -/
+def index_mut_slice_u32_0_back (x : Slice U32) : Result (Slice U32) :=
+ do
+ let _ ← Slice.index_usize U32 x 0#usize
+ Result.ret x
+
+/- [array::index_all]: forward function -/
+def index_all : Result U32 :=
+ do
+ let i ← index_array (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let i0 ← index_array (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let i1 ← i + i0
+ let i2 ← index_array_borrow (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let i3 ← i1 + i2
+ let s ←
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let i4 ← index_slice_u32_0 s
+ let i5 ← i3 + i4
+ let s0 ←
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let i6 ← index_mut_slice_u32_0 s0
+ let i7 ← i5 + i6
+ let s1 ← index_mut_slice_u32_0_back s0
+ let _ ←
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ]) s1
+ Result.ret i7
+
+/- [array::update_array]: forward function -/
+def update_array (x : Array U32 2#usize) : Result Unit :=
+ do
+ let _ ← Array.update_usize U32 2#usize x 0#usize 1#u32
+ Result.ret ()
+
+/- [array::update_array_mut_borrow]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) -/
+def update_array_mut_borrow
+ (x : Array U32 2#usize) : Result (Array U32 2#usize) :=
+ Array.update_usize U32 2#usize x 0#usize 1#u32
+
+/- [array::update_mut_slice]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) -/
+def update_mut_slice (x : Slice U32) : Result (Slice U32) :=
+ Slice.update_usize U32 x 0#usize 1#u32
+
+/- [array::update_all]: forward function -/
+def update_all : Result Unit :=
+ do
+ let _ ← update_array (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let x ← update_array_mut_borrow (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let s ← Array.to_slice U32 2#usize x
+ let s0 ← update_mut_slice s
+ let _ ← Array.from_slice U32 2#usize x s0
+ Result.ret ()
+
+/- [array::range_all]: forward function -/
+def range_all : Result Unit :=
+ do
+ let s ←
+ core.array.Array.index_mut U32 (core.ops.range.Range Usize) 4#usize
+ (core.slice.index.Slice.coreopsindexIndexMutInst U32
+ (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32))
+ (Array.make U32 4#usize [ 0#u32, 0#u32, 0#u32, 0#u32 ])
+ { start := 1#usize, end_ := 3#usize }
+ let s0 ← update_mut_slice s
+ let _ ←
+ core.array.Array.index_mut_back U32 (core.ops.range.Range Usize) 4#usize
+ (core.slice.index.Slice.coreopsindexIndexMutInst U32
+ (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32))
+ (Array.make U32 4#usize [ 0#u32, 0#u32, 0#u32, 0#u32 ])
+ { start := 1#usize, end_ := 3#usize } s0
+ Result.ret ()
+
+/- [array::deref_array_borrow]: forward function -/
+def deref_array_borrow (x : Array U32 2#usize) : Result U32 :=
+ Array.index_usize U32 2#usize x 0#usize
+
+/- [array::deref_array_mut_borrow]: forward function -/
+def deref_array_mut_borrow (x : Array U32 2#usize) : Result U32 :=
+ Array.index_usize U32 2#usize x 0#usize
+
+/- [array::deref_array_mut_borrow]: backward function 0 -/
+def deref_array_mut_borrow_back
+ (x : Array U32 2#usize) : Result (Array U32 2#usize) :=
+ do
+ let _ ← Array.index_usize U32 2#usize x 0#usize
+ Result.ret x
+
+/- [array::take_array_t]: forward function -/
+def take_array_t (a : Array AB 2#usize) : Result Unit :=
+ Result.ret ()
+
+/- [array::non_copyable_array]: forward function -/
+def non_copyable_array : Result Unit :=
+ do
+ let _ ← take_array_t (Array.make AB 2#usize [ AB.A, AB.B ])
+ Result.ret ()
+
+/- [array::sum]: loop 0: forward function -/
+divergent def sum_loop (s : Slice U32) (sum0 : U32) (i : Usize) : Result U32 :=
+ let i0 := Slice.len U32 s
+ if i < i0
+ then
+ do
+ let i1 ← Slice.index_usize U32 s i
+ let sum1 ← sum0 + i1
+ let i2 ← i + 1#usize
+ sum_loop s sum1 i2
+ else Result.ret sum0
+
+/- [array::sum]: forward function -/
+def sum (s : Slice U32) : Result U32 :=
+ sum_loop s 0#u32 0#usize
+
+/- [array::sum2]: loop 0: forward function -/
+divergent def sum2_loop
+ (s : Slice U32) (s2 : Slice U32) (sum0 : U32) (i : Usize) : Result U32 :=
+ let i0 := Slice.len U32 s
+ if i < i0
+ then
+ do
+ let i1 ← Slice.index_usize U32 s i
+ let i2 ← Slice.index_usize U32 s2 i
+ let i3 ← i1 + i2
+ let sum1 ← sum0 + i3
+ let i4 ← i + 1#usize
+ sum2_loop s s2 sum1 i4
+ else Result.ret sum0
+
+/- [array::sum2]: forward function -/
+def sum2 (s : Slice U32) (s2 : Slice U32) : Result U32 :=
+ let i := Slice.len U32 s
+ let i0 := Slice.len U32 s2
+ if not (i = i0)
+ then Result.fail Error.panic
+ else sum2_loop s s2 0#u32 0#usize
+
+/- [array::f0]: forward function -/
+def f0 : Result Unit :=
+ do
+ let s ←
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ])
+ let s0 ← Slice.update_usize U32 s 0#usize 1#u32
+ let _ ←
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ]) s0
+ Result.ret ()
+
+/- [array::f1]: forward function -/
+def f1 : Result Unit :=
+ do
+ let _ ←
+ Array.update_usize U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ])
+ 0#usize 1#u32
+ Result.ret ()
+
+/- [array::f2]: forward function -/
+def f2 (i : U32) : Result Unit :=
+ Result.ret ()
+
+/- [array::f4]: forward function -/
+def f4 (x : Array U32 32#usize) (y : Usize) (z : Usize) : Result (Slice U32) :=
+ core.array.Array.index U32 (core.ops.range.Range Usize) 32#usize
+ (core.slice.index.Slice.coreopsindexIndexInst U32 (core.ops.range.Range
+ Usize) (core.slice.index.Range.coresliceindexSliceIndexInst U32)) x
+ { start := y, end_ := z }
+
+/- [array::f3]: forward function -/
+def f3 : Result U32 :=
+ do
+ let i ←
+ Array.index_usize U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ])
+ 0#usize
+ let _ ← f2 i
+ let b := Array.repeat U32 32#usize 0#u32
+ let s ←
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ])
+ let s0 ← f4 b 16#usize 18#usize
+ sum2 s s0
+
+/- [array::SZ] -/
+def sz_body : Result Usize := Result.ret 32#usize
+def sz_c : Usize := eval_global sz_body (by simp)
+
+/- [array::f5]: forward function -/
+def f5 (x : Array U32 32#usize) : Result U32 :=
+ Array.index_usize U32 32#usize x 0#usize
+
+/- [array::ite]: forward function -/
+def ite : Result Unit :=
+ do
+ let s ←
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let s0 ←
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let s1 ← index_mut_slice_u32_0_back s0
+ let _ ←
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ]) s1
+ let s2 ← index_mut_slice_u32_0_back s
+ let _ ←
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ]) s2
+ Result.ret ()
+
+end array
diff --git a/tests/lean/Array/Funs.lean b/tests/lean/Array/Funs.lean
index ad737dca..32ae6248 100644
--- a/tests/lean/Array/Funs.lean
+++ b/tests/lean/Array/Funs.lean
@@ -6,189 +6,183 @@ open Primitives
namespace array
+/- [array::incr]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) -/
+def incr (x : U32) : Result U32 :=
+ x + 1#u32
+
/- [array::array_to_shared_slice_]: forward function -/
def array_to_shared_slice_
- (T0 : Type) (s : Array T0 (Usize.ofInt 32)) : Result (Slice T0) :=
- Array.to_slice_shared T0 (Usize.ofInt 32) s
+ (T : Type) (s : Array T 32#usize) : Result (Slice T) :=
+ Array.to_slice T 32#usize s
/- [array::array_to_mut_slice_]: forward function -/
-def array_to_mut_slice_
- (T0 : Type) (s : Array T0 (Usize.ofInt 32)) : Result (Slice T0) :=
- Array.to_slice_mut T0 (Usize.ofInt 32) s
+def array_to_mut_slice_ (T : Type) (s : Array T 32#usize) : Result (Slice T) :=
+ Array.to_slice T 32#usize s
/- [array::array_to_mut_slice_]: backward function 0 -/
def array_to_mut_slice__back
- (T0 : Type) (s : Array T0 (Usize.ofInt 32)) (ret0 : Slice T0) :
- Result (Array T0 (Usize.ofInt 32))
+ (T : Type) (s : Array T 32#usize) (ret0 : Slice T) :
+ Result (Array T 32#usize)
:=
- Array.to_slice_mut_back T0 (Usize.ofInt 32) s ret0
+ Array.from_slice T 32#usize s ret0
/- [array::array_len]: forward function -/
-def array_len (T0 : Type) (s : Array T0 (Usize.ofInt 32)) : Result Usize :=
+def array_len (T : Type) (s : Array T 32#usize) : Result Usize :=
do
- let s0 ← Array.to_slice_shared T0 (Usize.ofInt 32) s
- let i := Slice.len T0 s0
+ let s0 ← Array.to_slice T 32#usize s
+ let i := Slice.len T s0
Result.ret i
/- [array::shared_array_len]: forward function -/
-def shared_array_len
- (T0 : Type) (s : Array T0 (Usize.ofInt 32)) : Result Usize :=
+def shared_array_len (T : Type) (s : Array T 32#usize) : Result Usize :=
do
- let s0 ← Array.to_slice_shared T0 (Usize.ofInt 32) s
- let i := Slice.len T0 s0
+ let s0 ← Array.to_slice T 32#usize s
+ let i := Slice.len T s0
Result.ret i
/- [array::shared_slice_len]: forward function -/
-def shared_slice_len (T0 : Type) (s : Slice T0) : Result Usize :=
- let i := Slice.len T0 s
+def shared_slice_len (T : Type) (s : Slice T) : Result Usize :=
+ let i := Slice.len T s
Result.ret i
/- [array::index_array_shared]: forward function -/
def index_array_shared
- (T0 : Type) (s : Array T0 (Usize.ofInt 32)) (i : Usize) : Result T0 :=
- Array.index_shared T0 (Usize.ofInt 32) s i
+ (T : Type) (s : Array T 32#usize) (i : Usize) : Result T :=
+ Array.index_usize T 32#usize s i
/- [array::index_array_u32]: forward function -/
-def index_array_u32
- (s : Array U32 (Usize.ofInt 32)) (i : Usize) : Result U32 :=
- Array.index_shared U32 (Usize.ofInt 32) s i
-
-/- [array::index_array_generic]: forward function -/
-def index_array_generic
- (N : Usize) (s : Array U32 N) (i : Usize) : Result U32 :=
- Array.index_shared U32 N s i
-
-/- [array::index_array_generic_call]: forward function -/
-def index_array_generic_call
- (N : Usize) (s : Array U32 N) (i : Usize) : Result U32 :=
- index_array_generic N s i
+def index_array_u32 (s : Array U32 32#usize) (i : Usize) : Result U32 :=
+ Array.index_usize U32 32#usize s i
/- [array::index_array_copy]: forward function -/
-def index_array_copy (x : Array U32 (Usize.ofInt 32)) : Result U32 :=
- Array.index_shared U32 (Usize.ofInt 32) x (Usize.ofInt 0)
+def index_array_copy (x : Array U32 32#usize) : Result U32 :=
+ Array.index_usize U32 32#usize x 0#usize
/- [array::index_mut_array]: forward function -/
-def index_mut_array
- (T0 : Type) (s : Array T0 (Usize.ofInt 32)) (i : Usize) : Result T0 :=
- Array.index_mut T0 (Usize.ofInt 32) s i
+def index_mut_array (T : Type) (s : Array T 32#usize) (i : Usize) : Result T :=
+ Array.index_usize T 32#usize s i
/- [array::index_mut_array]: backward function 0 -/
def index_mut_array_back
- (T0 : Type) (s : Array T0 (Usize.ofInt 32)) (i : Usize) (ret0 : T0) :
- Result (Array T0 (Usize.ofInt 32))
+ (T : Type) (s : Array T 32#usize) (i : Usize) (ret0 : T) :
+ Result (Array T 32#usize)
:=
- Array.index_mut_back T0 (Usize.ofInt 32) s i ret0
+ Array.update_usize T 32#usize s i ret0
/- [array::index_slice]: forward function -/
-def index_slice (T0 : Type) (s : Slice T0) (i : Usize) : Result T0 :=
- Slice.index_shared T0 s i
+def index_slice (T : Type) (s : Slice T) (i : Usize) : Result T :=
+ Slice.index_usize T s i
/- [array::index_mut_slice]: forward function -/
-def index_mut_slice (T0 : Type) (s : Slice T0) (i : Usize) : Result T0 :=
- Slice.index_mut T0 s i
+def index_mut_slice (T : Type) (s : Slice T) (i : Usize) : Result T :=
+ Slice.index_usize T s i
/- [array::index_mut_slice]: backward function 0 -/
def index_mut_slice_back
- (T0 : Type) (s : Slice T0) (i : Usize) (ret0 : T0) : Result (Slice T0) :=
- Slice.index_mut_back T0 s i ret0
+ (T : Type) (s : Slice T) (i : Usize) (ret0 : T) : Result (Slice T) :=
+ Slice.update_usize T s i ret0
/- [array::slice_subslice_shared_]: forward function -/
def slice_subslice_shared_
(x : Slice U32) (y : Usize) (z : Usize) : Result (Slice U32) :=
- Slice.subslice_shared U32 x (Range.mk y z)
+ core.slice.index.Slice.index U32 (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32) x
+ { start := y, end_ := z }
/- [array::slice_subslice_mut_]: forward function -/
def slice_subslice_mut_
(x : Slice U32) (y : Usize) (z : Usize) : Result (Slice U32) :=
- Slice.subslice_mut U32 x (Range.mk y z)
+ core.slice.index.Slice.index_mut U32 (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32) x
+ { start := y, end_ := z }
/- [array::slice_subslice_mut_]: backward function 0 -/
def slice_subslice_mut__back
(x : Slice U32) (y : Usize) (z : Usize) (ret0 : Slice U32) :
Result (Slice U32)
:=
- Slice.subslice_mut_back U32 x (Range.mk y z) ret0
+ core.slice.index.Slice.index_mut_back U32 (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32) x
+ { start := y, end_ := z } ret0
/- [array::array_to_slice_shared_]: forward function -/
-def array_to_slice_shared_
- (x : Array U32 (Usize.ofInt 32)) : Result (Slice U32) :=
- Array.to_slice_shared U32 (Usize.ofInt 32) x
+def array_to_slice_shared_ (x : Array U32 32#usize) : Result (Slice U32) :=
+ Array.to_slice U32 32#usize x
/- [array::array_to_slice_mut_]: forward function -/
-def array_to_slice_mut_
- (x : Array U32 (Usize.ofInt 32)) : Result (Slice U32) :=
- Array.to_slice_mut U32 (Usize.ofInt 32) x
+def array_to_slice_mut_ (x : Array U32 32#usize) : Result (Slice U32) :=
+ Array.to_slice U32 32#usize x
/- [array::array_to_slice_mut_]: backward function 0 -/
def array_to_slice_mut__back
- (x : Array U32 (Usize.ofInt 32)) (ret0 : Slice U32) :
- Result (Array U32 (Usize.ofInt 32))
- :=
- Array.to_slice_mut_back U32 (Usize.ofInt 32) x ret0
+ (x : Array U32 32#usize) (ret0 : Slice U32) : Result (Array U32 32#usize) :=
+ Array.from_slice U32 32#usize x ret0
/- [array::array_subslice_shared_]: forward function -/
def array_subslice_shared_
- (x : Array U32 (Usize.ofInt 32)) (y : Usize) (z : Usize) :
- Result (Slice U32)
- :=
- Array.subslice_shared U32 (Usize.ofInt 32) x (Range.mk y z)
+ (x : Array U32 32#usize) (y : Usize) (z : Usize) : Result (Slice U32) :=
+ core.array.Array.index U32 (core.ops.range.Range Usize) 32#usize
+ (core.slice.index.Slice.coreopsindexIndexInst U32 (core.ops.range.Range
+ Usize) (core.slice.index.Range.coresliceindexSliceIndexInst U32)) x
+ { start := y, end_ := z }
/- [array::array_subslice_mut_]: forward function -/
def array_subslice_mut_
- (x : Array U32 (Usize.ofInt 32)) (y : Usize) (z : Usize) :
- Result (Slice U32)
- :=
- Array.subslice_mut U32 (Usize.ofInt 32) x (Range.mk y z)
+ (x : Array U32 32#usize) (y : Usize) (z : Usize) : Result (Slice U32) :=
+ core.array.Array.index_mut U32 (core.ops.range.Range Usize) 32#usize
+ (core.slice.index.Slice.coreopsindexIndexMutInst U32 (core.ops.range.Range
+ Usize) (core.slice.index.Range.coresliceindexSliceIndexInst U32)) x
+ { start := y, end_ := z }
/- [array::array_subslice_mut_]: backward function 0 -/
def array_subslice_mut__back
- (x : Array U32 (Usize.ofInt 32)) (y : Usize) (z : Usize) (ret0 : Slice U32) :
- Result (Array U32 (Usize.ofInt 32))
+ (x : Array U32 32#usize) (y : Usize) (z : Usize) (ret0 : Slice U32) :
+ Result (Array U32 32#usize)
:=
- Array.subslice_mut_back U32 (Usize.ofInt 32) x (Range.mk y z) ret0
+ core.array.Array.index_mut_back U32 (core.ops.range.Range Usize) 32#usize
+ (core.slice.index.Slice.coreopsindexIndexMutInst U32 (core.ops.range.Range
+ Usize) (core.slice.index.Range.coresliceindexSliceIndexInst U32)) x
+ { start := y, end_ := z } ret0
/- [array::index_slice_0]: forward function -/
-def index_slice_0 (T0 : Type) (s : Slice T0) : Result T0 :=
- Slice.index_shared T0 s (Usize.ofInt 0)
+def index_slice_0 (T : Type) (s : Slice T) : Result T :=
+ Slice.index_usize T s 0#usize
/- [array::index_array_0]: forward function -/
-def index_array_0 (T0 : Type) (s : Array T0 (Usize.ofInt 32)) : Result T0 :=
- Array.index_shared T0 (Usize.ofInt 32) s (Usize.ofInt 0)
+def index_array_0 (T : Type) (s : Array T 32#usize) : Result T :=
+ Array.index_usize T 32#usize s 0#usize
/- [array::index_index_array]: forward function -/
def index_index_array
- (s : Array (Array U32 (Usize.ofInt 32)) (Usize.ofInt 32)) (i : Usize)
- (j : Usize) :
+ (s : Array (Array U32 32#usize) 32#usize) (i : Usize) (j : Usize) :
Result U32
:=
do
- let a ←
- Array.index_shared (Array U32 (Usize.ofInt 32)) (Usize.ofInt 32) s i
- Array.index_shared U32 (Usize.ofInt 32) a j
+ let a ← Array.index_usize (Array U32 32#usize) 32#usize s i
+ Array.index_usize U32 32#usize a j
/- [array::update_update_array]: forward function -/
def update_update_array
- (s : Array (Array U32 (Usize.ofInt 32)) (Usize.ofInt 32)) (i : Usize)
- (j : Usize) :
+ (s : Array (Array U32 32#usize) 32#usize) (i : Usize) (j : Usize) :
Result Unit
:=
do
- let a ← Array.index_mut (Array U32 (Usize.ofInt 32)) (Usize.ofInt 32) s i
- let a0 ← Array.index_mut_back U32 (Usize.ofInt 32) a j (U32.ofInt 0)
- let _ ←
- Array.index_mut_back (Array U32 (Usize.ofInt 32)) (Usize.ofInt 32) s i a0
+ let a ← Array.index_usize (Array U32 32#usize) 32#usize s i
+ let a0 ← Array.update_usize U32 32#usize a j 0#u32
+ let _ ← Array.update_usize (Array U32 32#usize) 32#usize s i a0
Result.ret ()
/- [array::array_local_deep_copy]: forward function -/
-def array_local_deep_copy (x : Array U32 (Usize.ofInt 32)) : Result Unit :=
+def array_local_deep_copy (x : Array U32 32#usize) : Result Unit :=
Result.ret ()
/- [array::take_array]: forward function -/
-def take_array (a : Array U32 (Usize.ofInt 2)) : Result Unit :=
+def take_array (a : Array U32 2#usize) : Result Unit :=
Result.ret ()
/- [array::take_array_borrow]: forward function -/
-def take_array_borrow (a : Array U32 (Usize.ofInt 2)) : Result Unit :=
+def take_array_borrow (a : Array U32 2#usize) : Result Unit :=
Result.ret ()
/- [array::take_slice]: forward function -/
@@ -203,148 +197,131 @@ def take_mut_slice (s : Slice U32) : Result (Slice U32) :=
/- [array::take_all]: forward function -/
def take_all : Result Unit :=
do
- let _ ←
- take_array
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
- let _ ←
- take_array_borrow
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ let _ ← take_array (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let _ ← take_array_borrow (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let s ←
- Array.to_slice_shared U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let _ ← take_slice s
let s0 ←
- Array.to_slice_mut U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let s1 ← take_mut_slice s0
let _ ←
- Array.to_slice_mut_back U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ]) s1
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ]) s1
Result.ret ()
/- [array::index_array]: forward function -/
-def index_array (x : Array U32 (Usize.ofInt 2)) : Result U32 :=
- Array.index_shared U32 (Usize.ofInt 2) x (Usize.ofInt 0)
+def index_array (x : Array U32 2#usize) : Result U32 :=
+ Array.index_usize U32 2#usize x 0#usize
/- [array::index_array_borrow]: forward function -/
-def index_array_borrow (x : Array U32 (Usize.ofInt 2)) : Result U32 :=
- Array.index_shared U32 (Usize.ofInt 2) x (Usize.ofInt 0)
+def index_array_borrow (x : Array U32 2#usize) : Result U32 :=
+ Array.index_usize U32 2#usize x 0#usize
/- [array::index_slice_u32_0]: forward function -/
def index_slice_u32_0 (x : Slice U32) : Result U32 :=
- Slice.index_shared U32 x (Usize.ofInt 0)
+ Slice.index_usize U32 x 0#usize
/- [array::index_mut_slice_u32_0]: forward function -/
def index_mut_slice_u32_0 (x : Slice U32) : Result U32 :=
- Slice.index_shared U32 x (Usize.ofInt 0)
+ Slice.index_usize U32 x 0#usize
/- [array::index_mut_slice_u32_0]: backward function 0 -/
def index_mut_slice_u32_0_back (x : Slice U32) : Result (Slice U32) :=
do
- let _ ← Slice.index_shared U32 x (Usize.ofInt 0)
+ let _ ← Slice.index_usize U32 x 0#usize
Result.ret x
/- [array::index_all]: forward function -/
def index_all : Result U32 :=
do
- let i ←
- index_array
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
- let i0 ←
- index_array
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ let i ← index_array (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let i0 ← index_array (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let i1 ← i + i0
- let i2 ←
- index_array_borrow
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ let i2 ← index_array_borrow (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let i3 ← i1 + i2
let s ←
- Array.to_slice_shared U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let i4 ← index_slice_u32_0 s
let i5 ← i3 + i4
let s0 ←
- Array.to_slice_mut U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let i6 ← index_mut_slice_u32_0 s0
let i7 ← i5 + i6
let s1 ← index_mut_slice_u32_0_back s0
let _ ←
- Array.to_slice_mut_back U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ]) s1
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ]) s1
Result.ret i7
/- [array::update_array]: forward function -/
-def update_array (x : Array U32 (Usize.ofInt 2)) : Result Unit :=
+def update_array (x : Array U32 2#usize) : Result Unit :=
do
- let _ ←
- Array.index_mut_back U32 (Usize.ofInt 2) x (Usize.ofInt 0) (U32.ofInt 1)
+ let _ ← Array.update_usize U32 2#usize x 0#usize 1#u32
Result.ret ()
/- [array::update_array_mut_borrow]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
def update_array_mut_borrow
- (x : Array U32 (Usize.ofInt 2)) : Result (Array U32 (Usize.ofInt 2)) :=
- Array.index_mut_back U32 (Usize.ofInt 2) x (Usize.ofInt 0) (U32.ofInt 1)
+ (x : Array U32 2#usize) : Result (Array U32 2#usize) :=
+ Array.update_usize U32 2#usize x 0#usize 1#u32
/- [array::update_mut_slice]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
def update_mut_slice (x : Slice U32) : Result (Slice U32) :=
- Slice.index_mut_back U32 x (Usize.ofInt 0) (U32.ofInt 1)
+ Slice.update_usize U32 x 0#usize 1#u32
/- [array::update_all]: forward function -/
def update_all : Result Unit :=
do
- let _ ←
- update_array
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
- let x ←
- update_array_mut_borrow
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
- let s ← Array.to_slice_mut U32 (Usize.ofInt 2) x
+ let _ ← update_array (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let x ← update_array_mut_borrow (Array.make U32 2#usize [ 0#u32, 0#u32 ])
+ let s ← Array.to_slice U32 2#usize x
let s0 ← update_mut_slice s
- let _ ← Array.to_slice_mut_back U32 (Usize.ofInt 2) x s0
+ let _ ← Array.from_slice U32 2#usize x s0
Result.ret ()
/- [array::range_all]: forward function -/
def range_all : Result Unit :=
do
let s ←
- Array.subslice_mut U32 (Usize.ofInt 4)
- (Array.make U32 (Usize.ofInt 4) [
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0)
- ]) (Range.mk (Usize.ofInt 1) (Usize.ofInt 3))
+ core.array.Array.index_mut U32 (core.ops.range.Range Usize) 4#usize
+ (core.slice.index.Slice.coreopsindexIndexMutInst U32
+ (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32))
+ (Array.make U32 4#usize [ 0#u32, 0#u32, 0#u32, 0#u32 ])
+ { start := 1#usize, end_ := 3#usize }
let s0 ← update_mut_slice s
let _ ←
- Array.subslice_mut_back U32 (Usize.ofInt 4)
- (Array.make U32 (Usize.ofInt 4) [
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0)
- ]) (Range.mk (Usize.ofInt 1) (Usize.ofInt 3)) s0
+ core.array.Array.index_mut_back U32 (core.ops.range.Range Usize) 4#usize
+ (core.slice.index.Slice.coreopsindexIndexMutInst U32
+ (core.ops.range.Range Usize)
+ (core.slice.index.Range.coresliceindexSliceIndexInst U32))
+ (Array.make U32 4#usize [ 0#u32, 0#u32, 0#u32, 0#u32 ])
+ { start := 1#usize, end_ := 3#usize } s0
Result.ret ()
/- [array::deref_array_borrow]: forward function -/
-def deref_array_borrow (x : Array U32 (Usize.ofInt 2)) : Result U32 :=
- Array.index_shared U32 (Usize.ofInt 2) x (Usize.ofInt 0)
+def deref_array_borrow (x : Array U32 2#usize) : Result U32 :=
+ Array.index_usize U32 2#usize x 0#usize
/- [array::deref_array_mut_borrow]: forward function -/
-def deref_array_mut_borrow (x : Array U32 (Usize.ofInt 2)) : Result U32 :=
- Array.index_shared U32 (Usize.ofInt 2) x (Usize.ofInt 0)
+def deref_array_mut_borrow (x : Array U32 2#usize) : Result U32 :=
+ Array.index_usize U32 2#usize x 0#usize
/- [array::deref_array_mut_borrow]: backward function 0 -/
def deref_array_mut_borrow_back
- (x : Array U32 (Usize.ofInt 2)) : Result (Array U32 (Usize.ofInt 2)) :=
+ (x : Array U32 2#usize) : Result (Array U32 2#usize) :=
do
- let _ ← Array.index_shared U32 (Usize.ofInt 2) x (Usize.ofInt 0)
+ let _ ← Array.index_usize U32 2#usize x 0#usize
Result.ret x
/- [array::take_array_t]: forward function -/
-def take_array_t (a : Array T (Usize.ofInt 2)) : Result Unit :=
+def take_array_t (a : Array AB 2#usize) : Result Unit :=
Result.ret ()
/- [array::non_copyable_array]: forward function -/
def non_copyable_array : Result Unit :=
do
- let _ ← take_array_t (Array.make T (Usize.ofInt 2) [ T.A, T.B ])
+ let _ ← take_array_t (Array.make AB 2#usize [ AB.A, AB.B ])
Result.ret ()
/- [array::sum]: loop 0: forward function -/
@@ -353,15 +330,15 @@ divergent def sum_loop (s : Slice U32) (sum0 : U32) (i : Usize) : Result U32 :=
if i < i0
then
do
- let i1 ← Slice.index_shared U32 s i
+ let i1 ← Slice.index_usize U32 s i
let sum1 ← sum0 + i1
- let i2 ← i + (Usize.ofInt 1)
+ let i2 ← i + 1#usize
sum_loop s sum1 i2
else Result.ret sum0
/- [array::sum]: forward function -/
def sum (s : Slice U32) : Result U32 :=
- sum_loop s (U32.ofInt 0) (Usize.ofInt 0)
+ sum_loop s 0#u32 0#usize
/- [array::sum2]: loop 0: forward function -/
divergent def sum2_loop
@@ -370,11 +347,11 @@ divergent def sum2_loop
if i < i0
then
do
- let i1 ← Slice.index_shared U32 s i
- let i2 ← Slice.index_shared U32 s2 i
+ let i1 ← Slice.index_usize U32 s i
+ let i2 ← Slice.index_usize U32 s2 i
let i3 ← i1 + i2
let sum1 ← sum0 + i3
- let i4 ← i + (Usize.ofInt 1)
+ let i4 ← i + 1#usize
sum2_loop s s2 sum1 i4
else Result.ret sum0
@@ -384,27 +361,24 @@ def sum2 (s : Slice U32) (s2 : Slice U32) : Result U32 :=
let i0 := Slice.len U32 s2
if not (i = i0)
then Result.fail Error.panic
- else sum2_loop s s2 (U32.ofInt 0) (Usize.ofInt 0)
+ else sum2_loop s s2 0#u32 0#usize
/- [array::f0]: forward function -/
def f0 : Result Unit :=
do
let s ←
- Array.to_slice_mut U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 1), (U32.ofInt 2) ])
- let s0 ← Slice.index_mut_back U32 s (Usize.ofInt 0) (U32.ofInt 1)
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ])
+ let s0 ← Slice.update_usize U32 s 0#usize 1#u32
let _ ←
- Array.to_slice_mut_back U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 1), (U32.ofInt 2) ]) s0
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ]) s0
Result.ret ()
/- [array::f1]: forward function -/
def f1 : Result Unit :=
do
let _ ←
- Array.index_mut_back U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 1), (U32.ofInt 2) ])
- (Usize.ofInt 0) (U32.ofInt 1)
+ Array.update_usize U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ])
+ 0#usize 1#u32
Result.ret ()
/- [array::f2]: forward function -/
@@ -412,54 +386,46 @@ def f2 (i : U32) : Result Unit :=
Result.ret ()
/- [array::f4]: forward function -/
-def f4
- (x : Array U32 (Usize.ofInt 32)) (y : Usize) (z : Usize) :
- Result (Slice U32)
- :=
- Array.subslice_shared U32 (Usize.ofInt 32) x (Range.mk y z)
+def f4 (x : Array U32 32#usize) (y : Usize) (z : Usize) : Result (Slice U32) :=
+ core.array.Array.index U32 (core.ops.range.Range Usize) 32#usize
+ (core.slice.index.Slice.coreopsindexIndexInst U32 (core.ops.range.Range
+ Usize) (core.slice.index.Range.coresliceindexSliceIndexInst U32)) x
+ { start := y, end_ := z }
/- [array::f3]: forward function -/
def f3 : Result U32 :=
do
let i ←
- Array.index_shared U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 1), (U32.ofInt 2) ])
- (Usize.ofInt 0)
+ Array.index_usize U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ])
+ 0#usize
let _ ← f2 i
+ let b := Array.repeat U32 32#usize 0#u32
let s ←
- Array.to_slice_shared U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 1), (U32.ofInt 2) ])
- let s0 ←
- f4
- (Array.make U32 (Usize.ofInt 32) [
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0),
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0),
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0),
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0),
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0),
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0),
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0),
- (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0), (U32.ofInt 0)
- ]) (Usize.ofInt 16) (Usize.ofInt 18)
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 1#u32, 2#u32 ])
+ let s0 ← f4 b 16#usize 18#usize
sum2 s s0
+/- [array::SZ] -/
+def sz_body : Result Usize := Result.ret 32#usize
+def sz_c : Usize := eval_global sz_body (by simp)
+
+/- [array::f5]: forward function -/
+def f5 (x : Array U32 32#usize) : Result U32 :=
+ Array.index_usize U32 32#usize x 0#usize
+
/- [array::ite]: forward function -/
def ite : Result Unit :=
do
let s ←
- Array.to_slice_mut U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let s0 ←
- Array.to_slice_mut U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ])
+ Array.to_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ])
let s1 ← index_mut_slice_u32_0_back s0
let _ ←
- Array.to_slice_mut_back U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ]) s1
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ]) s1
let s2 ← index_mut_slice_u32_0_back s
let _ ←
- Array.to_slice_mut_back U32 (Usize.ofInt 2)
- (Array.make U32 (Usize.ofInt 2) [ (U32.ofInt 0), (U32.ofInt 0) ]) s2
+ Array.from_slice U32 2#usize (Array.make U32 2#usize [ 0#u32, 0#u32 ]) s2
Result.ret ()
end array
diff --git a/tests/lean/Array/Types.lean b/tests/lean/Array/Types.lean
index 72241276..60fa81ab 100644
--- a/tests/lean/Array/Types.lean
+++ b/tests/lean/Array/Types.lean
@@ -5,9 +5,9 @@ open Primitives
namespace array
-/- [array::T] -/
-inductive T :=
-| A : T
-| B : T
+/- [array::AB] -/
+inductive AB :=
+| A : AB
+| B : AB
end array
diff --git a/tests/lean/BetreeMain/Funs.lean b/tests/lean/BetreeMain/Funs.lean
index 07ef08dc..0901d449 100644
--- a/tests/lean/BetreeMain/Funs.lean
+++ b/tests/lean/BetreeMain/Funs.lean
@@ -40,77 +40,71 @@ def betree.store_leaf_node
/- [betree_main::betree::fresh_node_id]: forward function -/
def betree.fresh_node_id (counter : U64) : Result U64 :=
do
- let _ ← counter + (U64.ofInt 1)
+ let _ ← counter + 1#u64
Result.ret counter
/- [betree_main::betree::fresh_node_id]: backward function 0 -/
def betree.fresh_node_id_back (counter : U64) : Result U64 :=
- counter + (U64.ofInt 1)
+ counter + 1#u64
/- [betree_main::betree::NodeIdCounter::{0}::new]: forward function -/
def betree.NodeIdCounter.new : Result betree.NodeIdCounter :=
- Result.ret { next_node_id := (U64.ofInt 0) }
+ Result.ret { next_node_id := 0#u64 }
/- [betree_main::betree::NodeIdCounter::{0}::fresh_id]: forward function -/
def betree.NodeIdCounter.fresh_id (self : betree.NodeIdCounter) : Result U64 :=
do
- let _ ← self.next_node_id + (U64.ofInt 1)
+ let _ ← self.next_node_id + 1#u64
Result.ret self.next_node_id
/- [betree_main::betree::NodeIdCounter::{0}::fresh_id]: backward function 0 -/
def betree.NodeIdCounter.fresh_id_back
(self : betree.NodeIdCounter) : Result betree.NodeIdCounter :=
do
- let i ← self.next_node_id + (U64.ofInt 1)
+ let i ← self.next_node_id + 1#u64
Result.ret { next_node_id := i }
-/- [core::num::u64::{9}::MAX] -/
-def core_num_u64_max_body : Result U64 :=
- Result.ret (U64.ofInt 18446744073709551615)
-def core_num_u64_max_c : U64 := eval_global core_num_u64_max_body (by simp)
-
/- [betree_main::betree::upsert_update]: forward function -/
def betree.upsert_update
(prev : Option U64) (st : betree.UpsertFunState) : Result U64 :=
match prev with
- | Option.none =>
+ | none =>
match st with
| betree.UpsertFunState.Add v => Result.ret v
- | betree.UpsertFunState.Sub i => Result.ret (U64.ofInt 0)
- | Option.some prev0 =>
+ | betree.UpsertFunState.Sub i => Result.ret 0#u64
+ | some prev0 =>
match st with
| betree.UpsertFunState.Add v =>
do
- let margin ← core_num_u64_max_c - prev0
+ let margin ← core_u64_max - prev0
if margin >= v
then prev0 + v
- else Result.ret core_num_u64_max_c
+ else Result.ret core_u64_max
| betree.UpsertFunState.Sub v =>
if prev0 >= v
then prev0 - v
- else Result.ret (U64.ofInt 0)
+ else Result.ret 0#u64
/- [betree_main::betree::List::{1}::len]: forward function -/
divergent def betree.List.len (T : Type) (self : betree.List T) : Result U64 :=
match self with
- | betree.List.Cons t tl =>
- do
- let i ← betree.List.len T tl
- (U64.ofInt 1) + i
- | betree.List.Nil => Result.ret (U64.ofInt 0)
+ | betree.List.Cons t tl => do
+ let i ← betree.List.len T tl
+ 1#u64 + i
+ | betree.List.Nil => Result.ret 0#u64
/- [betree_main::betree::List::{1}::split_at]: forward function -/
divergent def betree.List.split_at
(T : Type) (self : betree.List T) (n : U64) :
Result ((betree.List T) × (betree.List T))
:=
- if n = (U64.ofInt 0)
+ if n = 0#u64
then Result.ret (betree.List.Nil, self)
else
match self with
| betree.List.Cons hd tl =>
do
- let i ← n - (U64.ofInt 1)
+ let i ← n - 1#u64
let p ← betree.List.split_at T tl i
let (ls0, ls1) := p
let l := ls0
@@ -121,13 +115,13 @@ divergent def betree.List.split_at
(there is a single backward function, and the forward function returns ()) -/
def betree.List.push_front
(T : Type) (self : betree.List T) (x : T) : Result (betree.List T) :=
- let tl := mem.replace (betree.List T) self betree.List.Nil
+ let tl := core.mem.replace (betree.List T) self betree.List.Nil
let l := tl
Result.ret (betree.List.Cons x l)
/- [betree_main::betree::List::{1}::pop_front]: forward function -/
def betree.List.pop_front (T : Type) (self : betree.List T) : Result T :=
- let ls := mem.replace (betree.List T) self betree.List.Nil
+ let ls := core.mem.replace (betree.List T) self betree.List.Nil
match ls with
| betree.List.Cons x tl => Result.ret x
| betree.List.Nil => Result.fail Error.panic
@@ -135,7 +129,7 @@ def betree.List.pop_front (T : Type) (self : betree.List T) : Result T :=
/- [betree_main::betree::List::{1}::pop_front]: backward function 0 -/
def betree.List.pop_front_back
(T : Type) (self : betree.List T) : Result (betree.List T) :=
- let ls := mem.replace (betree.List T) self betree.List.Nil
+ let ls := core.mem.replace (betree.List T) self betree.List.Nil
match ls with
| betree.List.Cons x tl => Result.ret tl
| betree.List.Nil => Result.fail Error.panic
@@ -261,7 +255,7 @@ divergent def betree.Node.apply_upserts
let v ← betree.upsert_update prev s
let msgs0 ←
betree.List.pop_front_back (U64 × betree.Message) msgs
- betree.Node.apply_upserts msgs0 (Option.some v) key st
+ betree.Node.apply_upserts msgs0 (some v) key st
else
do
let (st0, v) ← core.option.Option.unwrap U64 prev st
@@ -291,7 +285,7 @@ divergent def betree.Node.apply_upserts_back
let v ← betree.upsert_update prev s
let msgs0 ←
betree.List.pop_front_back (U64 × betree.Message) msgs
- betree.Node.apply_upserts_back msgs0 (Option.some v) key st
+ betree.Node.apply_upserts_back msgs0 (some v) key st
else
do
let (_, v) ← core.option.Option.unwrap U64 prev st
@@ -305,12 +299,12 @@ divergent def betree.Node.lookup_in_bindings
| betree.List.Cons hd tl =>
let (i, i0) := hd
if i = key
- then Result.ret (Option.some i0)
+ then Result.ret (some i0)
else
if i > key
- then Result.ret Option.none
+ then Result.ret none
else betree.Node.lookup_in_bindings key tl
- | betree.List.Nil => Result.ret Option.none
+ | betree.List.Nil => Result.ret none
/- [betree_main::betree::Internal::{4}::lookup_in_children]: forward function -/
mutual divergent def betree.Internal.lookup_in_children
@@ -353,13 +347,13 @@ divergent def betree.Node.lookup
if k != key
then
do
- let (st1, opt) ←
+ let (st1, o) ←
betree.Internal.lookup_in_children (betree.Internal.mk i i0 n n0)
key st0
let _ ←
betree.Node.lookup_first_message_for_key_back key msgs
(betree.List.Cons (k, msg) l)
- Result.ret (st1, opt)
+ Result.ret (st1, o)
else
match msg with
| betree.Message.Insert v =>
@@ -367,13 +361,13 @@ divergent def betree.Node.lookup
let _ ←
betree.Node.lookup_first_message_for_key_back key msgs
(betree.List.Cons (k, betree.Message.Insert v) l)
- Result.ret (st0, Option.some v)
+ Result.ret (st0, some v)
| betree.Message.Delete =>
do
let _ ←
betree.Node.lookup_first_message_for_key_back key msgs
(betree.List.Cons (k, betree.Message.Delete) l)
- Result.ret (st0, Option.none)
+ Result.ret (st0, none)
| betree.Message.Upsert ufs =>
do
let (st1, v) ←
@@ -392,21 +386,21 @@ divergent def betree.Node.lookup
let msgs0 ←
betree.Node.lookup_first_message_for_key_back key msgs pending0
let (st3, _) ← betree.store_internal_node i1 msgs0 st2
- Result.ret (st3, Option.some v0)
+ Result.ret (st3, some v0)
| betree.List.Nil =>
do
- let (st1, opt) ←
+ let (st1, o) ←
betree.Internal.lookup_in_children (betree.Internal.mk i i0 n n0)
key st0
let _ ←
betree.Node.lookup_first_message_for_key_back key msgs
betree.List.Nil
- Result.ret (st1, opt)
+ Result.ret (st1, o)
| betree.Node.Leaf node =>
do
let (st0, bindings) ← betree.load_leaf_node node.id st
- let opt ← betree.Node.lookup_in_bindings key bindings
- Result.ret (st0, opt)
+ let o ← betree.Node.lookup_in_bindings key bindings
+ Result.ret (st0, o)
/- [betree_main::betree::Node::{5}::lookup]: backward function 0 -/
divergent def betree.Node.lookup_back
@@ -565,7 +559,7 @@ def betree.Node.apply_to_internal
match m with
| betree.Message.Insert prev =>
do
- let v ← betree.upsert_update (Option.some prev) s
+ let v ← betree.upsert_update (some prev) s
let msgs1 ←
betree.List.pop_front_back (U64 × betree.Message) msgs0
let msgs2 ←
@@ -574,7 +568,7 @@ def betree.Node.apply_to_internal
betree.Node.lookup_first_message_for_key_back key msgs msgs2
| betree.Message.Delete =>
do
- let v ← betree.upsert_update Option.none s
+ let v ← betree.upsert_update none s
let msgs1 ←
betree.List.pop_front_back (U64 × betree.Message) msgs0
let msgs2 ←
@@ -670,7 +664,7 @@ def betree.Node.apply_to_leaf
| betree.Message.Upsert s =>
do
let (_, i) := hd
- let v ← betree.upsert_update (Option.some i) s
+ let v ← betree.upsert_update (some i) s
let bindings1 ← betree.List.pop_front_back (U64 × U64) bindings0
let bindings2 ←
betree.List.push_front (U64 × U64) bindings1 (key, v)
@@ -686,7 +680,7 @@ def betree.Node.apply_to_leaf
betree.Node.lookup_mut_in_bindings_back key bindings bindings0
| betree.Message.Upsert s =>
do
- let v ← betree.upsert_update Option.none s
+ let v ← betree.upsert_update none s
let bindings1 ←
betree.List.push_front (U64 × U64) bindings0 (key, v)
betree.Node.lookup_mut_in_bindings_back key bindings bindings1
@@ -813,7 +807,7 @@ divergent def betree.Node.apply_messages
let (st0, content) ← betree.load_leaf_node node.id st
let content0 ← betree.Node.apply_messages_to_leaf content msgs
let len ← betree.List.len (U64 × U64) content0
- let i ← (U64.ofInt 2) * params.split_size
+ let i ← 2#u64 * params.split_size
if len >= i
then
do
@@ -863,7 +857,7 @@ divergent def betree.Node.apply_messages_back
let (st0, content) ← betree.load_leaf_node node.id st
let content0 ← betree.Node.apply_messages_to_leaf content msgs
let len ← betree.List.len (U64 × U64) content0
- let i ← (U64.ofInt 2) * params.split_size
+ let i ← 2#u64 * params.split_size
if len >= i
then
do
@@ -923,7 +917,7 @@ def betree.BeTree.new
params :=
{ min_flush_size := min_flush_size, split_size := split_size },
node_id_cnt := node_id_cnt0,
- root := (betree.Node.Leaf { id := id, size := (U64.ofInt 0) })
+ root := (betree.Node.Leaf { id := id, size := 0#u64 })
})
/- [betree_main::betree::BeTree::{6}::apply]: forward function -/
diff --git a/tests/lean/Constants.lean b/tests/lean/Constants.lean
index 51b415d6..bd3a07b7 100644
--- a/tests/lean/Constants.lean
+++ b/tests/lean/Constants.lean
@@ -6,27 +6,23 @@ open Primitives
namespace constants
/- [constants::X0] -/
-def x0_body : Result U32 := Result.ret (U32.ofInt 0)
+def x0_body : Result U32 := Result.ret 0#u32
def x0_c : U32 := eval_global x0_body (by simp)
-/- [core::num::u32::{8}::MAX] -/
-def core_num_u32_max_body : Result U32 := Result.ret (U32.ofInt 4294967295)
-def core_num_u32_max_c : U32 := eval_global core_num_u32_max_body (by simp)
-
/- [constants::X1] -/
-def x1_body : Result U32 := Result.ret core_num_u32_max_c
+def x1_body : Result U32 := Result.ret core_u32_max
def x1_c : U32 := eval_global x1_body (by simp)
/- [constants::X2] -/
-def x2_body : Result U32 := Result.ret (U32.ofInt 3)
+def x2_body : Result U32 := Result.ret 3#u32
def x2_c : U32 := eval_global x2_body (by simp)
/- [constants::incr]: forward function -/
def incr (n : U32) : Result U32 :=
- n + (U32.ofInt 1)
+ n + 1#u32
/- [constants::X3] -/
-def x3_body : Result U32 := incr (U32.ofInt 32)
+def x3_body : Result U32 := incr 32#u32
def x3_c : U32 := eval_global x3_body (by simp)
/- [constants::mk_pair0]: forward function -/
@@ -43,44 +39,43 @@ def mk_pair1 (x : U32) (y : U32) : Result (Pair U32 U32) :=
Result.ret { x := x, y := y }
/- [constants::P0] -/
-def p0_body : Result (U32 × U32) := mk_pair0 (U32.ofInt 0) (U32.ofInt 1)
+def p0_body : Result (U32 × U32) := mk_pair0 0#u32 1#u32
def p0_c : (U32 × U32) := eval_global p0_body (by simp)
/- [constants::P1] -/
-def p1_body : Result (Pair U32 U32) := mk_pair1 (U32.ofInt 0) (U32.ofInt 1)
+def p1_body : Result (Pair U32 U32) := mk_pair1 0#u32 1#u32
def p1_c : Pair U32 U32 := eval_global p1_body (by simp)
/- [constants::P2] -/
-def p2_body : Result (U32 × U32) := Result.ret ((U32.ofInt 0), (U32.ofInt 1))
+def p2_body : Result (U32 × U32) := Result.ret (0#u32, 1#u32)
def p2_c : (U32 × U32) := eval_global p2_body (by simp)
/- [constants::P3] -/
-def p3_body : Result (Pair U32 U32) :=
- Result.ret { x := (U32.ofInt 0), y := (U32.ofInt 1) }
+def p3_body : Result (Pair U32 U32) := Result.ret { x := 0#u32, y := 1#u32 }
def p3_c : Pair U32 U32 := eval_global p3_body (by simp)
/- [constants::Wrap] -/
structure Wrap (T : Type) where
- val : T
+ value : T
/- [constants::Wrap::{0}::new]: forward function -/
-def Wrap.new (T : Type) (val : T) : Result (Wrap T) :=
- Result.ret { val := val }
+def Wrap.new (T : Type) (value : T) : Result (Wrap T) :=
+ Result.ret { value := value }
/- [constants::Y] -/
-def y_body : Result (Wrap I32) := Wrap.new I32 (I32.ofInt 2)
+def y_body : Result (Wrap I32) := Wrap.new I32 2#i32
def y_c : Wrap I32 := eval_global y_body (by simp)
/- [constants::unwrap_y]: forward function -/
def unwrap_y : Result I32 :=
- Result.ret y_c.val
+ Result.ret y_c.value
/- [constants::YVAL] -/
def yval_body : Result I32 := unwrap_y
def yval_c : I32 := eval_global yval_body (by simp)
/- [constants::get_z1::Z1] -/
-def get_z1_z1_body : Result I32 := Result.ret (I32.ofInt 3)
+def get_z1_z1_body : Result I32 := Result.ret 3#i32
def get_z1_z1_c : I32 := eval_global get_z1_z1_body (by simp)
/- [constants::get_z1]: forward function -/
@@ -92,7 +87,7 @@ def add (a : I32) (b : I32) : Result I32 :=
a + b
/- [constants::Q1] -/
-def q1_body : Result I32 := Result.ret (I32.ofInt 5)
+def q1_body : Result I32 := Result.ret 5#i32
def q1_c : I32 := eval_global q1_body (by simp)
/- [constants::Q2] -/
@@ -100,7 +95,7 @@ def q2_body : Result I32 := Result.ret q1_c
def q2_c : I32 := eval_global q2_body (by simp)
/- [constants::Q3] -/
-def q3_body : Result I32 := add q2_c (I32.ofInt 3)
+def q3_body : Result I32 := add q2_c 3#i32
def q3_c : I32 := eval_global q3_body (by simp)
/- [constants::get_z2]: forward function -/
@@ -111,7 +106,7 @@ def get_z2 : Result I32 :=
add q1_c i0
/- [constants::S1] -/
-def s1_body : Result U32 := Result.ret (U32.ofInt 6)
+def s1_body : Result U32 := Result.ret 6#u32
def s1_c : U32 := eval_global s1_body (by simp)
/- [constants::S2] -/
@@ -123,7 +118,7 @@ def s3_body : Result (Pair U32 U32) := Result.ret p3_c
def s3_c : Pair U32 U32 := eval_global s3_body (by simp)
/- [constants::S4] -/
-def s4_body : Result (Pair U32 U32) := mk_pair1 (U32.ofInt 7) (U32.ofInt 8)
+def s4_body : Result (Pair U32 U32) := mk_pair1 7#u32 8#u32
def s4_c : Pair U32 U32 := eval_global s4_body (by simp)
end constants
diff --git a/tests/lean/External/Funs.lean b/tests/lean/External/Funs.lean
index 055d7860..55fb07be 100644
--- a/tests/lean/External/Funs.lean
+++ b/tests/lean/External/Funs.lean
@@ -30,14 +30,14 @@ def swap_back
def test_new_non_zero_u32
(x : U32) (st : State) : Result (State × core.num.nonzero.NonZeroU32) :=
do
- let (st0, opt) ← core.num.nonzero.NonZeroU32.new x st
- core.option.Option.unwrap core.num.nonzero.NonZeroU32 opt st0
+ let (st0, o) ← core.num.nonzero.NonZeroU32.new x st
+ core.option.Option.unwrap core.num.nonzero.NonZeroU32 o st0
/- [external::test_vec]: forward function -/
def test_vec : Result Unit :=
do
- let v := Vec.new U32
- let _ ← Vec.push U32 v (U32.ofInt 0)
+ let v := alloc.vec.Vec.new U32
+ let _ ← alloc.vec.Vec.push U32 v 0#u32
Result.ret ()
/- Unit test for [external::test_vec] -/
@@ -75,14 +75,14 @@ def test_custom_swap_back
(x : U32) (y : U32) (st : State) (st0 : State) :
Result (State × (U32 × U32))
:=
- custom_swap_back U32 x y st (U32.ofInt 1) st0
+ custom_swap_back U32 x y st 1#u32 st0
/- [external::test_swap_non_zero]: forward function -/
def test_swap_non_zero (x : U32) (st : State) : Result (State × U32) :=
do
- let (st0, _) ← swap U32 x (U32.ofInt 0) st
- let (st1, (x0, _)) ← swap_back U32 x (U32.ofInt 0) st st0
- if x0 = (U32.ofInt 0)
+ let (st0, _) ← swap U32 x 0#u32 st
+ let (st1, (x0, _)) ← swap_back U32 x 0#u32 st st0
+ if x0 = 0#u32
then Result.fail Error.panic
else Result.ret (st1, x0)
diff --git a/tests/lean/Hashmap/Funs.lean b/tests/lean/Hashmap/Funs.lean
index 30b30e0b..8464c432 100644
--- a/tests/lean/Hashmap/Funs.lean
+++ b/tests/lean/Hashmap/Funs.lean
@@ -12,18 +12,22 @@ def hash_key (k : Usize) : Result Usize :=
/- [hashmap::HashMap::{0}::allocate_slots]: loop 0: forward function -/
divergent def HashMap.allocate_slots_loop
- (T : Type) (slots : Vec (List T)) (n : Usize) : Result (Vec (List T)) :=
- if n > (Usize.ofInt 0)
+ (T : Type) (slots : alloc.vec.Vec (List T)) (n : Usize) :
+ Result (alloc.vec.Vec (List T))
+ :=
+ if n > 0#usize
then
do
- let slots0 ← Vec.push (List T) slots List.Nil
- let n0 ← n - (Usize.ofInt 1)
+ let slots0 ← alloc.vec.Vec.push (List T) slots List.Nil
+ let n0 ← n - 1#usize
HashMap.allocate_slots_loop T slots0 n0
else Result.ret slots
/- [hashmap::HashMap::{0}::allocate_slots]: forward function -/
def HashMap.allocate_slots
- (T : Type) (slots : Vec (List T)) (n : Usize) : Result (Vec (List T)) :=
+ (T : Type) (slots : alloc.vec.Vec (List T)) (n : Usize) :
+ Result (alloc.vec.Vec (List T))
+ :=
HashMap.allocate_slots_loop T slots n
/- [hashmap::HashMap::{0}::new_with_capacity]: forward function -/
@@ -33,13 +37,13 @@ def HashMap.new_with_capacity
Result (HashMap T)
:=
do
- let v := Vec.new (List T)
+ let v := alloc.vec.Vec.new (List T)
let slots ← HashMap.allocate_slots T v capacity
let i ← capacity * max_load_dividend
let i0 ← i / max_load_divisor
Result.ret
{
- num_entries := (Usize.ofInt 0),
+ num_entries := 0#usize,
max_load_factor := (max_load_dividend, max_load_divisor),
max_load := i0,
slots := slots
@@ -47,18 +51,23 @@ def HashMap.new_with_capacity
/- [hashmap::HashMap::{0}::new]: forward function -/
def HashMap.new (T : Type) : Result (HashMap T) :=
- HashMap.new_with_capacity T (Usize.ofInt 32) (Usize.ofInt 4) (Usize.ofInt 5)
+ HashMap.new_with_capacity T 32#usize 4#usize 5#usize
/- [hashmap::HashMap::{0}::clear]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
divergent def HashMap.clear_loop
- (T : Type) (slots : Vec (List T)) (i : Usize) : Result (Vec (List T)) :=
- let i0 := Vec.len (List T) slots
+ (T : Type) (slots : alloc.vec.Vec (List T)) (i : Usize) :
+ Result (alloc.vec.Vec (List T))
+ :=
+ let i0 := alloc.vec.Vec.len (List T) slots
if i < i0
then
do
- let i1 ← i + (Usize.ofInt 1)
- let slots0 ← Vec.index_mut_back (List T) slots i List.Nil
+ let i1 ← i + 1#usize
+ let slots0 ←
+ alloc.vec.Vec.index_mut_back (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T)) slots
+ i List.Nil
HashMap.clear_loop T slots0 i1
else Result.ret slots
@@ -66,8 +75,8 @@ divergent def HashMap.clear_loop
(there is a single backward function, and the forward function returns ()) -/
def HashMap.clear (T : Type) (self : HashMap T) : Result (HashMap T) :=
do
- let v ← HashMap.clear_loop T self.slots (Usize.ofInt 0)
- Result.ret { self with num_entries := (Usize.ofInt 0), slots := v }
+ let v ← HashMap.clear_loop T self.slots 0#usize
+ Result.ret { self with num_entries := 0#usize, slots := v }
/- [hashmap::HashMap::{0}::len]: forward function -/
def HashMap.len (T : Type) (self : HashMap T) : Result Usize :=
@@ -115,27 +124,32 @@ def HashMap.insert_no_resize
:=
do
let hash ← hash_key key
- let i := Vec.len (List T) self.slots
+ let i := alloc.vec.Vec.len (List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod
let inserted ← HashMap.insert_in_list T key value l
if inserted
then
do
- let i0 ← self.num_entries + (Usize.ofInt 1)
+ let i0 ← self.num_entries + 1#usize
let l0 ← HashMap.insert_in_list_back T key value l
- let v ← Vec.index_mut_back (List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod l0
Result.ret { self with num_entries := i0, slots := v }
else
do
let l0 ← HashMap.insert_in_list_back T key value l
- let v ← Vec.index_mut_back (List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod l0
Result.ret { self with slots := v }
-/- [core::num::u32::{8}::MAX] -/
-def core_num_u32_max_body : Result U32 := Result.ret (U32.ofInt 4294967295)
-def core_num_u32_max_c : U32 := eval_global core_num_u32_max_body (by simp)
-
/- [hashmap::HashMap::{0}::move_elements_from_list]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
divergent def HashMap.move_elements_from_list_loop
@@ -156,27 +170,35 @@ def HashMap.move_elements_from_list
/- [hashmap::HashMap::{0}::move_elements]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
divergent def HashMap.move_elements_loop
- (T : Type) (ntable : HashMap T) (slots : Vec (List T)) (i : Usize) :
- Result ((HashMap T) × (Vec (List T)))
+ (T : Type) (ntable : HashMap T) (slots : alloc.vec.Vec (List T)) (i : Usize)
+ :
+ Result ((HashMap T) × (alloc.vec.Vec (List T)))
:=
- let i0 := Vec.len (List T) slots
+ let i0 := alloc.vec.Vec.len (List T) slots
if i < i0
then
do
- let l ← Vec.index_mut (List T) slots i
- let ls := mem.replace (List T) l List.Nil
+ let l ←
+ alloc.vec.Vec.index_mut (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T)) slots
+ i
+ let ls := core.mem.replace (List T) l List.Nil
let ntable0 ← HashMap.move_elements_from_list T ntable ls
- let i1 ← i + (Usize.ofInt 1)
- let l0 := mem.replace_back (List T) l List.Nil
- let slots0 ← Vec.index_mut_back (List T) slots i l0
+ let i1 ← i + 1#usize
+ let l0 := core.mem.replace_back (List T) l List.Nil
+ let slots0 ←
+ alloc.vec.Vec.index_mut_back (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T)) slots
+ i l0
HashMap.move_elements_loop T ntable0 slots0 i1
else Result.ret (ntable, slots)
/- [hashmap::HashMap::{0}::move_elements]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
def HashMap.move_elements
- (T : Type) (ntable : HashMap T) (slots : Vec (List T)) (i : Usize) :
- Result ((HashMap T) × (Vec (List T)))
+ (T : Type) (ntable : HashMap T) (slots : alloc.vec.Vec (List T)) (i : Usize)
+ :
+ Result ((HashMap T) × (alloc.vec.Vec (List T)))
:=
HashMap.move_elements_loop T ntable slots i
@@ -184,18 +206,17 @@ def HashMap.move_elements
(there is a single backward function, and the forward function returns ()) -/
def HashMap.try_resize (T : Type) (self : HashMap T) : Result (HashMap T) :=
do
- let max_usize ← Scalar.cast .Usize core_num_u32_max_c
- let capacity := Vec.len (List T) self.slots
- let n1 ← max_usize / (Usize.ofInt 2)
+ let max_usize ← Scalar.cast .Usize core_u32_max
+ let capacity := alloc.vec.Vec.len (List T) self.slots
+ let n1 ← max_usize / 2#usize
let (i, i0) := self.max_load_factor
let i1 ← n1 / i
if capacity <= i1
then
do
- let i2 ← capacity * (Usize.ofInt 2)
+ let i2 ← capacity * 2#usize
let ntable ← HashMap.new_with_capacity T i2 i i0
- let (ntable0, _) ←
- HashMap.move_elements T ntable self.slots (Usize.ofInt 0)
+ let (ntable0, _) ← HashMap.move_elements T ntable self.slots 0#usize
Result.ret
{
ntable0
@@ -237,9 +258,12 @@ def HashMap.contains_key
(T : Type) (self : HashMap T) (key : Usize) : Result Bool :=
do
let hash ← hash_key key
- let i := Vec.len (List T) self.slots
+ let i := alloc.vec.Vec.len (List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_shared (List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod
HashMap.contains_key_in_list T key l
/- [hashmap::HashMap::{0}::get_in_list]: loop 0: forward function -/
@@ -260,9 +284,12 @@ def HashMap.get_in_list (T : Type) (key : Usize) (ls : List T) : Result T :=
def HashMap.get (T : Type) (self : HashMap T) (key : Usize) : Result T :=
do
let hash ← hash_key key
- let i := Vec.len (List T) self.slots
+ let i := alloc.vec.Vec.len (List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_shared (List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod
HashMap.get_in_list T key l
/- [hashmap::HashMap::{0}::get_mut_in_list]: loop 0: forward function -/
@@ -302,9 +329,12 @@ def HashMap.get_mut_in_list_back
def HashMap.get_mut (T : Type) (self : HashMap T) (key : Usize) : Result T :=
do
let hash ← hash_key key
- let i := Vec.len (List T) self.slots
+ let i := alloc.vec.Vec.len (List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod
HashMap.get_mut_in_list T l key
/- [hashmap::HashMap::{0}::get_mut]: backward function 0 -/
@@ -314,11 +344,17 @@ def HashMap.get_mut_back
:=
do
let hash ← hash_key key
- let i := Vec.len (List T) self.slots
+ let i := alloc.vec.Vec.len (List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod
let l0 ← HashMap.get_mut_in_list_back T l key ret0
- let v ← Vec.index_mut_back (List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod l0
Result.ret { self with slots := v }
/- [hashmap::HashMap::{0}::remove_from_list]: loop 0: forward function -/
@@ -328,12 +364,12 @@ divergent def HashMap.remove_from_list_loop
| List.Cons ckey t tl =>
if ckey = key
then
- let mv_ls := mem.replace (List T) (List.Cons ckey t tl) List.Nil
+ let mv_ls := core.mem.replace (List T) (List.Cons ckey t tl) List.Nil
match mv_ls with
- | List.Cons i cvalue tl0 => Result.ret (Option.some cvalue)
+ | List.Cons i cvalue tl0 => Result.ret (some cvalue)
| List.Nil => Result.fail Error.panic
else HashMap.remove_from_list_loop T key tl
- | List.Nil => Result.ret Option.none
+ | List.Nil => Result.ret none
/- [hashmap::HashMap::{0}::remove_from_list]: forward function -/
def HashMap.remove_from_list
@@ -347,7 +383,7 @@ divergent def HashMap.remove_from_list_loop_back
| List.Cons ckey t tl =>
if ckey = key
then
- let mv_ls := mem.replace (List T) (List.Cons ckey t tl) List.Nil
+ let mv_ls := core.mem.replace (List T) (List.Cons ckey t tl) List.Nil
match mv_ls with
| List.Cons i cvalue tl0 => Result.ret tl0
| List.Nil => Result.fail Error.panic
@@ -367,84 +403,91 @@ def HashMap.remove
(T : Type) (self : HashMap T) (key : Usize) : Result (Option T) :=
do
let hash ← hash_key key
- let i := Vec.len (List T) self.slots
+ let i := alloc.vec.Vec.len (List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod
let x ← HashMap.remove_from_list T key l
match x with
- | Option.none => Result.ret Option.none
- | Option.some x0 =>
- do
- let _ ← self.num_entries - (Usize.ofInt 1)
- Result.ret (Option.some x0)
+ | none => Result.ret none
+ | some x0 => do
+ let _ ← self.num_entries - 1#usize
+ Result.ret (some x0)
/- [hashmap::HashMap::{0}::remove]: backward function 0 -/
def HashMap.remove_back
(T : Type) (self : HashMap T) (key : Usize) : Result (HashMap T) :=
do
let hash ← hash_key key
- let i := Vec.len (List T) self.slots
+ let i := alloc.vec.Vec.len (List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod
let x ← HashMap.remove_from_list T key l
match x with
- | Option.none =>
+ | none =>
do
let l0 ← HashMap.remove_from_list_back T key l
- let v ← Vec.index_mut_back (List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod l0
Result.ret { self with slots := v }
- | Option.some x0 =>
+ | some x0 =>
do
- let i0 ← self.num_entries - (Usize.ofInt 1)
+ let i0 ← self.num_entries - 1#usize
let l0 ← HashMap.remove_from_list_back T key l
- let v ← Vec.index_mut_back (List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List T))
+ self.slots hash_mod l0
Result.ret { self with num_entries := i0, slots := v }
/- [hashmap::test1]: forward function -/
def test1 : Result Unit :=
do
let hm ← HashMap.new U64
- let hm0 ← HashMap.insert U64 hm (Usize.ofInt 0) (U64.ofInt 42)
- let hm1 ← HashMap.insert U64 hm0 (Usize.ofInt 128) (U64.ofInt 18)
- let hm2 ← HashMap.insert U64 hm1 (Usize.ofInt 1024) (U64.ofInt 138)
- let hm3 ← HashMap.insert U64 hm2 (Usize.ofInt 1056) (U64.ofInt 256)
- let i ← HashMap.get U64 hm3 (Usize.ofInt 128)
- if not (i = (U64.ofInt 18))
+ let hm0 ← HashMap.insert U64 hm 0#usize 42#u64
+ let hm1 ← HashMap.insert U64 hm0 128#usize 18#u64
+ let hm2 ← HashMap.insert U64 hm1 1024#usize 138#u64
+ let hm3 ← HashMap.insert U64 hm2 1056#usize 256#u64
+ let i ← HashMap.get U64 hm3 128#usize
+ if not (i = 18#u64)
then Result.fail Error.panic
else
do
- let hm4 ←
- HashMap.get_mut_back U64 hm3 (Usize.ofInt 1024) (U64.ofInt 56)
- let i0 ← HashMap.get U64 hm4 (Usize.ofInt 1024)
- if not (i0 = (U64.ofInt 56))
+ let hm4 ← HashMap.get_mut_back U64 hm3 1024#usize 56#u64
+ let i0 ← HashMap.get U64 hm4 1024#usize
+ if not (i0 = 56#u64)
then Result.fail Error.panic
else
do
- let x ← HashMap.remove U64 hm4 (Usize.ofInt 1024)
+ let x ← HashMap.remove U64 hm4 1024#usize
match x with
- | Option.none => Result.fail Error.panic
- | Option.some x0 =>
- if not (x0 = (U64.ofInt 56))
+ | none => Result.fail Error.panic
+ | some x0 =>
+ if not (x0 = 56#u64)
then Result.fail Error.panic
else
do
- let hm5 ← HashMap.remove_back U64 hm4 (Usize.ofInt 1024)
- let i1 ← HashMap.get U64 hm5 (Usize.ofInt 0)
- if not (i1 = (U64.ofInt 42))
+ let hm5 ← HashMap.remove_back U64 hm4 1024#usize
+ let i1 ← HashMap.get U64 hm5 0#usize
+ if not (i1 = 42#u64)
then Result.fail Error.panic
else
do
- let i2 ← HashMap.get U64 hm5 (Usize.ofInt 128)
- if not (i2 = (U64.ofInt 18))
+ let i2 ← HashMap.get U64 hm5 128#usize
+ if not (i2 = 18#u64)
then Result.fail Error.panic
else
do
- let i3 ← HashMap.get U64 hm5 (Usize.ofInt 1056)
- if not (i3 = (U64.ofInt 256))
+ let i3 ← HashMap.get U64 hm5 1056#usize
+ if not (i3 = 256#u64)
then Result.fail Error.panic
else Result.ret ()
-/- Unit test for [hashmap::test1] -/
-#assert (test1 == .ret ())
-
end hashmap
diff --git a/tests/lean/Hashmap/Properties.lean b/tests/lean/Hashmap/Properties.lean
index fe00ab14..e79c422d 100644
--- a/tests/lean/Hashmap/Properties.lean
+++ b/tests/lean/Hashmap/Properties.lean
@@ -157,7 +157,7 @@ instance : Inhabited (List α) where
def slots_s_inv (s : Core.List (List α)) : Prop :=
∀ (i : Int), 0 ≤ i → i < s.len → slot_t_inv s.len i (s.index i)
-def slots_t_inv (s : Vec (List α)) : Prop :=
+def slots_t_inv (s : alloc.vec.Vec (List α)) : Prop :=
slots_s_inv s.v
@[simp]
@@ -302,20 +302,19 @@ theorem insert_no_resize_spec {α : Type} (hm : HashMap α) (key : Usize) (value
| none => nhm.len_s = hm.len_s + 1
| some _ => nhm.len_s = hm.len_s) := by
rw [insert_no_resize]
- simp only [hash_key, bind_tc_ret] -- TODO: annoying
- have _ : (Vec.len (List α) hm.slots).val ≠ 0 := by checkpoint
+ -- Simplify. Note that this also simplifies some function calls, like array index
+ simp [hash_key, bind_tc_ret]
+ have _ : (alloc.vec.Vec.len (List α) hm.slots).val ≠ 0 := by
intro
simp_all [inv]
- progress keep _ as ⟨ hash_mod, hhm ⟩
- have _ : 0 ≤ hash_mod.val := by checkpoint scalar_tac
- have _ : hash_mod.val < Vec.length hm.slots := by
+ progress as ⟨ hash_mod, hhm ⟩
+ have _ : 0 ≤ hash_mod.val := by scalar_tac
+ have _ : hash_mod.val < alloc.vec.Vec.length hm.slots := by
have : 0 < hm.slots.val.len := by
simp [inv] at hinv
simp [hinv]
-- TODO: we want to automate that
simp [*, Int.emod_lt_of_pos]
- -- TODO: change the spec of Vec.index_mut to introduce a let-binding.
- -- or: make progress introduce the let-binding by itself (this is clearer)
progress as ⟨ l, h_leq ⟩
-- TODO: make progress use the names written in the goal
progress as ⟨ inserted ⟩
@@ -376,7 +375,7 @@ theorem insert_no_resize_spec {α : Type} (hm : HashMap α) (key : Usize) (value
-- TODO: we want to automate this
simp
apply Int.emod_nonneg k.val hvnz
- have _ : k_hash_mod < Vec.length hm.slots := by
+ have _ : k_hash_mod < alloc.vec.Vec.length hm.slots := by
-- TODO: we want to automate this
simp
have h := Int.emod_lt_of_pos k.val hvpos
diff --git a/tests/lean/Hashmap/Types.lean b/tests/lean/Hashmap/Types.lean
index 6455798d..e007bce0 100644
--- a/tests/lean/Hashmap/Types.lean
+++ b/tests/lean/Hashmap/Types.lean
@@ -15,6 +15,6 @@ structure HashMap (T : Type) where
num_entries : Usize
max_load_factor : (Usize × Usize)
max_load : Usize
- slots : Vec (List T)
+ slots : alloc.vec.Vec (List T)
end hashmap
diff --git a/tests/lean/HashmapMain/Funs.lean b/tests/lean/HashmapMain/Funs.lean
index aec957ec..74fa8653 100644
--- a/tests/lean/HashmapMain/Funs.lean
+++ b/tests/lean/HashmapMain/Funs.lean
@@ -13,21 +13,21 @@ def hashmap.hash_key (k : Usize) : Result Usize :=
/- [hashmap_main::hashmap::HashMap::{0}::allocate_slots]: loop 0: forward function -/
divergent def hashmap.HashMap.allocate_slots_loop
- (T : Type) (slots : Vec (hashmap.List T)) (n : Usize) :
- Result (Vec (hashmap.List T))
+ (T : Type) (slots : alloc.vec.Vec (hashmap.List T)) (n : Usize) :
+ Result (alloc.vec.Vec (hashmap.List T))
:=
- if n > (Usize.ofInt 0)
+ if n > 0#usize
then
do
- let slots0 ← Vec.push (hashmap.List T) slots hashmap.List.Nil
- let n0 ← n - (Usize.ofInt 1)
+ let slots0 ← alloc.vec.Vec.push (hashmap.List T) slots hashmap.List.Nil
+ let n0 ← n - 1#usize
hashmap.HashMap.allocate_slots_loop T slots0 n0
else Result.ret slots
/- [hashmap_main::hashmap::HashMap::{0}::allocate_slots]: forward function -/
def hashmap.HashMap.allocate_slots
- (T : Type) (slots : Vec (hashmap.List T)) (n : Usize) :
- Result (Vec (hashmap.List T))
+ (T : Type) (slots : alloc.vec.Vec (hashmap.List T)) (n : Usize) :
+ Result (alloc.vec.Vec (hashmap.List T))
:=
hashmap.HashMap.allocate_slots_loop T slots n
@@ -38,13 +38,13 @@ def hashmap.HashMap.new_with_capacity
Result (hashmap.HashMap T)
:=
do
- let v := Vec.new (hashmap.List T)
+ let v := alloc.vec.Vec.new (hashmap.List T)
let slots ← hashmap.HashMap.allocate_slots T v capacity
let i ← capacity * max_load_dividend
let i0 ← i / max_load_divisor
Result.ret
{
- num_entries := (Usize.ofInt 0),
+ num_entries := 0#usize,
max_load_factor := (max_load_dividend, max_load_divisor),
max_load := i0,
slots := slots
@@ -52,22 +52,23 @@ def hashmap.HashMap.new_with_capacity
/- [hashmap_main::hashmap::HashMap::{0}::new]: forward function -/
def hashmap.HashMap.new (T : Type) : Result (hashmap.HashMap T) :=
- hashmap.HashMap.new_with_capacity T (Usize.ofInt 32) (Usize.ofInt 4)
- (Usize.ofInt 5)
+ hashmap.HashMap.new_with_capacity T 32#usize 4#usize 5#usize
/- [hashmap_main::hashmap::HashMap::{0}::clear]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
divergent def hashmap.HashMap.clear_loop
- (T : Type) (slots : Vec (hashmap.List T)) (i : Usize) :
- Result (Vec (hashmap.List T))
+ (T : Type) (slots : alloc.vec.Vec (hashmap.List T)) (i : Usize) :
+ Result (alloc.vec.Vec (hashmap.List T))
:=
- let i0 := Vec.len (hashmap.List T) slots
+ let i0 := alloc.vec.Vec.len (hashmap.List T) slots
if i < i0
then
do
- let i1 ← i + (Usize.ofInt 1)
+ let i1 ← i + 1#usize
let slots0 ←
- Vec.index_mut_back (hashmap.List T) slots i hashmap.List.Nil
+ alloc.vec.Vec.index_mut_back (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List
+ T)) slots i hashmap.List.Nil
hashmap.HashMap.clear_loop T slots0 i1
else Result.ret slots
@@ -76,8 +77,8 @@ divergent def hashmap.HashMap.clear_loop
def hashmap.HashMap.clear
(T : Type) (self : hashmap.HashMap T) : Result (hashmap.HashMap T) :=
do
- let v ← hashmap.HashMap.clear_loop T self.slots (Usize.ofInt 0)
- Result.ret { self with num_entries := (Usize.ofInt 0), slots := v }
+ let v ← hashmap.HashMap.clear_loop T self.slots 0#usize
+ Result.ret { self with num_entries := 0#usize, slots := v }
/- [hashmap_main::hashmap::HashMap::{0}::len]: forward function -/
def hashmap.HashMap.len (T : Type) (self : hashmap.HashMap T) : Result Usize :=
@@ -130,27 +131,32 @@ def hashmap.HashMap.insert_no_resize
:=
do
let hash ← hashmap.hash_key key
- let i := Vec.len (hashmap.List T) self.slots
+ let i := alloc.vec.Vec.len (hashmap.List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (hashmap.List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List T))
+ self.slots hash_mod
let inserted ← hashmap.HashMap.insert_in_list T key value l
if inserted
then
do
- let i0 ← self.num_entries + (Usize.ofInt 1)
+ let i0 ← self.num_entries + 1#usize
let l0 ← hashmap.HashMap.insert_in_list_back T key value l
- let v ← Vec.index_mut_back (hashmap.List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List
+ T)) self.slots hash_mod l0
Result.ret { self with num_entries := i0, slots := v }
else
do
let l0 ← hashmap.HashMap.insert_in_list_back T key value l
- let v ← Vec.index_mut_back (hashmap.List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List
+ T)) self.slots hash_mod l0
Result.ret { self with slots := v }
-/- [core::num::u32::{8}::MAX] -/
-def core_num_u32_max_body : Result U32 := Result.ret (U32.ofInt 4294967295)
-def core_num_u32_max_c : U32 := eval_global core_num_u32_max_body (by simp)
-
/- [hashmap_main::hashmap::HashMap::{0}::move_elements_from_list]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
divergent def hashmap.HashMap.move_elements_from_list_loop
@@ -175,29 +181,35 @@ def hashmap.HashMap.move_elements_from_list
/- [hashmap_main::hashmap::HashMap::{0}::move_elements]: loop 0: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
divergent def hashmap.HashMap.move_elements_loop
- (T : Type) (ntable : hashmap.HashMap T) (slots : Vec (hashmap.List T))
- (i : Usize) :
- Result ((hashmap.HashMap T) × (Vec (hashmap.List T)))
+ (T : Type) (ntable : hashmap.HashMap T)
+ (slots : alloc.vec.Vec (hashmap.List T)) (i : Usize) :
+ Result ((hashmap.HashMap T) × (alloc.vec.Vec (hashmap.List T)))
:=
- let i0 := Vec.len (hashmap.List T) slots
+ let i0 := alloc.vec.Vec.len (hashmap.List T) slots
if i < i0
then
do
- let l ← Vec.index_mut (hashmap.List T) slots i
- let ls := mem.replace (hashmap.List T) l hashmap.List.Nil
+ let l ←
+ alloc.vec.Vec.index_mut (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List
+ T)) slots i
+ let ls := core.mem.replace (hashmap.List T) l hashmap.List.Nil
let ntable0 ← hashmap.HashMap.move_elements_from_list T ntable ls
- let i1 ← i + (Usize.ofInt 1)
- let l0 := mem.replace_back (hashmap.List T) l hashmap.List.Nil
- let slots0 ← Vec.index_mut_back (hashmap.List T) slots i l0
+ let i1 ← i + 1#usize
+ let l0 := core.mem.replace_back (hashmap.List T) l hashmap.List.Nil
+ let slots0 ←
+ alloc.vec.Vec.index_mut_back (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List
+ T)) slots i l0
hashmap.HashMap.move_elements_loop T ntable0 slots0 i1
else Result.ret (ntable, slots)
/- [hashmap_main::hashmap::HashMap::{0}::move_elements]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
def hashmap.HashMap.move_elements
- (T : Type) (ntable : hashmap.HashMap T) (slots : Vec (hashmap.List T))
- (i : Usize) :
- Result ((hashmap.HashMap T) × (Vec (hashmap.List T)))
+ (T : Type) (ntable : hashmap.HashMap T)
+ (slots : alloc.vec.Vec (hashmap.List T)) (i : Usize) :
+ Result ((hashmap.HashMap T) × (alloc.vec.Vec (hashmap.List T)))
:=
hashmap.HashMap.move_elements_loop T ntable slots i
@@ -206,18 +218,18 @@ def hashmap.HashMap.move_elements
def hashmap.HashMap.try_resize
(T : Type) (self : hashmap.HashMap T) : Result (hashmap.HashMap T) :=
do
- let max_usize ← Scalar.cast .Usize core_num_u32_max_c
- let capacity := Vec.len (hashmap.List T) self.slots
- let n1 ← max_usize / (Usize.ofInt 2)
+ let max_usize ← Scalar.cast .Usize core_u32_max
+ let capacity := alloc.vec.Vec.len (hashmap.List T) self.slots
+ let n1 ← max_usize / 2#usize
let (i, i0) := self.max_load_factor
let i1 ← n1 / i
if capacity <= i1
then
do
- let i2 ← capacity * (Usize.ofInt 2)
+ let i2 ← capacity * 2#usize
let ntable ← hashmap.HashMap.new_with_capacity T i2 i i0
let (ntable0, _) ←
- hashmap.HashMap.move_elements T ntable self.slots (Usize.ofInt 0)
+ hashmap.HashMap.move_elements T ntable self.slots 0#usize
Result.ret
{
ntable0
@@ -259,9 +271,12 @@ def hashmap.HashMap.contains_key
(T : Type) (self : hashmap.HashMap T) (key : Usize) : Result Bool :=
do
let hash ← hashmap.hash_key key
- let i := Vec.len (hashmap.List T) self.slots
+ let i := alloc.vec.Vec.len (hashmap.List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_shared (hashmap.List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List T))
+ self.slots hash_mod
hashmap.HashMap.contains_key_in_list T key l
/- [hashmap_main::hashmap::HashMap::{0}::get_in_list]: loop 0: forward function -/
@@ -284,9 +299,12 @@ def hashmap.HashMap.get
(T : Type) (self : hashmap.HashMap T) (key : Usize) : Result T :=
do
let hash ← hashmap.hash_key key
- let i := Vec.len (hashmap.List T) self.slots
+ let i := alloc.vec.Vec.len (hashmap.List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_shared (hashmap.List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List T))
+ self.slots hash_mod
hashmap.HashMap.get_in_list T key l
/- [hashmap_main::hashmap::HashMap::{0}::get_mut_in_list]: loop 0: forward function -/
@@ -331,9 +349,12 @@ def hashmap.HashMap.get_mut
(T : Type) (self : hashmap.HashMap T) (key : Usize) : Result T :=
do
let hash ← hashmap.hash_key key
- let i := Vec.len (hashmap.List T) self.slots
+ let i := alloc.vec.Vec.len (hashmap.List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (hashmap.List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List T))
+ self.slots hash_mod
hashmap.HashMap.get_mut_in_list T l key
/- [hashmap_main::hashmap::HashMap::{0}::get_mut]: backward function 0 -/
@@ -343,11 +364,17 @@ def hashmap.HashMap.get_mut_back
:=
do
let hash ← hashmap.hash_key key
- let i := Vec.len (hashmap.List T) self.slots
+ let i := alloc.vec.Vec.len (hashmap.List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (hashmap.List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List T))
+ self.slots hash_mod
let l0 ← hashmap.HashMap.get_mut_in_list_back T l key ret0
- let v ← Vec.index_mut_back (hashmap.List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List T))
+ self.slots hash_mod l0
Result.ret { self with slots := v }
/- [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: loop 0: forward function -/
@@ -358,13 +385,13 @@ divergent def hashmap.HashMap.remove_from_list_loop
if ckey = key
then
let mv_ls :=
- mem.replace (hashmap.List T) (hashmap.List.Cons ckey t tl)
+ core.mem.replace (hashmap.List T) (hashmap.List.Cons ckey t tl)
hashmap.List.Nil
match mv_ls with
- | hashmap.List.Cons i cvalue tl0 => Result.ret (Option.some cvalue)
+ | hashmap.List.Cons i cvalue tl0 => Result.ret (some cvalue)
| hashmap.List.Nil => Result.fail Error.panic
else hashmap.HashMap.remove_from_list_loop T key tl
- | hashmap.List.Nil => Result.ret Option.none
+ | hashmap.List.Nil => Result.ret none
/- [hashmap_main::hashmap::HashMap::{0}::remove_from_list]: forward function -/
def hashmap.HashMap.remove_from_list
@@ -379,7 +406,7 @@ divergent def hashmap.HashMap.remove_from_list_loop_back
if ckey = key
then
let mv_ls :=
- mem.replace (hashmap.List T) (hashmap.List.Cons ckey t tl)
+ core.mem.replace (hashmap.List T) (hashmap.List.Cons ckey t tl)
hashmap.List.Nil
match mv_ls with
| hashmap.List.Cons i cvalue tl0 => Result.ret tl0
@@ -400,16 +427,18 @@ def hashmap.HashMap.remove
(T : Type) (self : hashmap.HashMap T) (key : Usize) : Result (Option T) :=
do
let hash ← hashmap.hash_key key
- let i := Vec.len (hashmap.List T) self.slots
+ let i := alloc.vec.Vec.len (hashmap.List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (hashmap.List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List T))
+ self.slots hash_mod
let x ← hashmap.HashMap.remove_from_list T key l
match x with
- | Option.none => Result.ret Option.none
- | Option.some x0 =>
- do
- let _ ← self.num_entries - (Usize.ofInt 1)
- Result.ret (Option.some x0)
+ | none => Result.ret none
+ | some x0 => do
+ let _ ← self.num_entries - 1#usize
+ Result.ret (some x0)
/- [hashmap_main::hashmap::HashMap::{0}::remove]: backward function 0 -/
def hashmap.HashMap.remove_back
@@ -418,75 +447,75 @@ def hashmap.HashMap.remove_back
:=
do
let hash ← hashmap.hash_key key
- let i := Vec.len (hashmap.List T) self.slots
+ let i := alloc.vec.Vec.len (hashmap.List T) self.slots
let hash_mod ← hash % i
- let l ← Vec.index_mut (hashmap.List T) self.slots hash_mod
+ let l ←
+ alloc.vec.Vec.index_mut (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List T))
+ self.slots hash_mod
let x ← hashmap.HashMap.remove_from_list T key l
match x with
- | Option.none =>
+ | none =>
do
let l0 ← hashmap.HashMap.remove_from_list_back T key l
- let v ← Vec.index_mut_back (hashmap.List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List
+ T)) self.slots hash_mod l0
Result.ret { self with slots := v }
- | Option.some x0 =>
+ | some x0 =>
do
- let i0 ← self.num_entries - (Usize.ofInt 1)
+ let i0 ← self.num_entries - 1#usize
let l0 ← hashmap.HashMap.remove_from_list_back T key l
- let v ← Vec.index_mut_back (hashmap.List T) self.slots hash_mod l0
+ let v ←
+ alloc.vec.Vec.index_mut_back (hashmap.List T) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (hashmap.List
+ T)) self.slots hash_mod l0
Result.ret { self with num_entries := i0, slots := v }
/- [hashmap_main::hashmap::test1]: forward function -/
def hashmap.test1 : Result Unit :=
do
let hm ← hashmap.HashMap.new U64
- let hm0 ← hashmap.HashMap.insert U64 hm (Usize.ofInt 0) (U64.ofInt 42)
- let hm1 ← hashmap.HashMap.insert U64 hm0 (Usize.ofInt 128) (U64.ofInt 18)
- let hm2 ←
- hashmap.HashMap.insert U64 hm1 (Usize.ofInt 1024) (U64.ofInt 138)
- let hm3 ←
- hashmap.HashMap.insert U64 hm2 (Usize.ofInt 1056) (U64.ofInt 256)
- let i ← hashmap.HashMap.get U64 hm3 (Usize.ofInt 128)
- if not (i = (U64.ofInt 18))
+ let hm0 ← hashmap.HashMap.insert U64 hm 0#usize 42#u64
+ let hm1 ← hashmap.HashMap.insert U64 hm0 128#usize 18#u64
+ let hm2 ← hashmap.HashMap.insert U64 hm1 1024#usize 138#u64
+ let hm3 ← hashmap.HashMap.insert U64 hm2 1056#usize 256#u64
+ let i ← hashmap.HashMap.get U64 hm3 128#usize
+ if not (i = 18#u64)
then Result.fail Error.panic
else
do
- let hm4 ←
- hashmap.HashMap.get_mut_back U64 hm3 (Usize.ofInt 1024)
- (U64.ofInt 56)
- let i0 ← hashmap.HashMap.get U64 hm4 (Usize.ofInt 1024)
- if not (i0 = (U64.ofInt 56))
+ let hm4 ← hashmap.HashMap.get_mut_back U64 hm3 1024#usize 56#u64
+ let i0 ← hashmap.HashMap.get U64 hm4 1024#usize
+ if not (i0 = 56#u64)
then Result.fail Error.panic
else
do
- let x ← hashmap.HashMap.remove U64 hm4 (Usize.ofInt 1024)
+ let x ← hashmap.HashMap.remove U64 hm4 1024#usize
match x with
- | Option.none => Result.fail Error.panic
- | Option.some x0 =>
- if not (x0 = (U64.ofInt 56))
+ | none => Result.fail Error.panic
+ | some x0 =>
+ if not (x0 = 56#u64)
then Result.fail Error.panic
else
do
- let hm5 ←
- hashmap.HashMap.remove_back U64 hm4 (Usize.ofInt 1024)
- let i1 ← hashmap.HashMap.get U64 hm5 (Usize.ofInt 0)
- if not (i1 = (U64.ofInt 42))
+ let hm5 ← hashmap.HashMap.remove_back U64 hm4 1024#usize
+ let i1 ← hashmap.HashMap.get U64 hm5 0#usize
+ if not (i1 = 42#u64)
then Result.fail Error.panic
else
do
- let i2 ← hashmap.HashMap.get U64 hm5 (Usize.ofInt 128)
- if not (i2 = (U64.ofInt 18))
+ let i2 ← hashmap.HashMap.get U64 hm5 128#usize
+ if not (i2 = 18#u64)
then Result.fail Error.panic
else
do
- let i3 ←
- hashmap.HashMap.get U64 hm5 (Usize.ofInt 1056)
- if not (i3 = (U64.ofInt 256))
+ let i3 ← hashmap.HashMap.get U64 hm5 1056#usize
+ if not (i3 = 256#u64)
then Result.fail Error.panic
else Result.ret ()
-/- Unit test for [hashmap_main::hashmap::test1] -/
-#assert (hashmap.test1 == .ret ())
-
/- [hashmap_main::insert_on_disk]: forward function -/
def insert_on_disk
(key : Usize) (value : U64) (st : State) : Result (State × Unit) :=
@@ -500,7 +529,4 @@ def insert_on_disk
def main : Result Unit :=
Result.ret ()
-/- Unit test for [hashmap_main::main] -/
-#assert (main == .ret ())
-
end hashmap_main
diff --git a/tests/lean/HashmapMain/Types.lean b/tests/lean/HashmapMain/Types.lean
index 2b5cbd6c..065c109b 100644
--- a/tests/lean/HashmapMain/Types.lean
+++ b/tests/lean/HashmapMain/Types.lean
@@ -15,7 +15,7 @@ structure hashmap.HashMap (T : Type) where
num_entries : Usize
max_load_factor : (Usize × Usize)
max_load : Usize
- slots : Vec (hashmap.List T)
+ slots : alloc.vec.Vec (hashmap.List T)
/- The state type used in the state-error monad -/
axiom State : Type
diff --git a/tests/lean/Loops.lean b/tests/lean/Loops.lean
index 60c73776..c6360338 100644
--- a/tests/lean/Loops.lean
+++ b/tests/lean/Loops.lean
@@ -1 +1,629 @@
-import Loops.Funs
+-- THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS
+-- [loops]
+import Base
+open Primitives
+
+namespace loops
+
+/- [loops::sum]: loop 0: forward function -/
+divergent def sum_loop (max : U32) (i : U32) (s : U32) : Result U32 :=
+ if i < max
+ then do
+ let s0 ← s + i
+ let i0 ← i + 1#u32
+ sum_loop max i0 s0
+ else s * 2#u32
+
+/- [loops::sum]: forward function -/
+def sum (max : U32) : Result U32 :=
+ sum_loop max 0#u32 0#u32
+
+/- [loops::sum_with_mut_borrows]: loop 0: forward function -/
+divergent def sum_with_mut_borrows_loop
+ (max : U32) (mi : U32) (ms : U32) : Result U32 :=
+ if mi < max
+ then
+ do
+ let ms0 ← ms + mi
+ let mi0 ← mi + 1#u32
+ sum_with_mut_borrows_loop max mi0 ms0
+ else ms * 2#u32
+
+/- [loops::sum_with_mut_borrows]: forward function -/
+def sum_with_mut_borrows (max : U32) : Result U32 :=
+ sum_with_mut_borrows_loop max 0#u32 0#u32
+
+/- [loops::sum_with_shared_borrows]: loop 0: forward function -/
+divergent def sum_with_shared_borrows_loop
+ (max : U32) (i : U32) (s : U32) : Result U32 :=
+ if i < max
+ then
+ do
+ let i0 ← i + 1#u32
+ let s0 ← s + i0
+ sum_with_shared_borrows_loop max i0 s0
+ else s * 2#u32
+
+/- [loops::sum_with_shared_borrows]: forward function -/
+def sum_with_shared_borrows (max : U32) : Result U32 :=
+ sum_with_shared_borrows_loop max 0#u32 0#u32
+
+/- [loops::clear]: loop 0: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) -/
+divergent def clear_loop
+ (v : alloc.vec.Vec U32) (i : Usize) : Result (alloc.vec.Vec U32) :=
+ let i0 := alloc.vec.Vec.len U32 v
+ if i < i0
+ then
+ do
+ let i1 ← i + 1#usize
+ let v0 ←
+ alloc.vec.Vec.index_mut_back U32 Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst U32) v i 0#u32
+ clear_loop v0 i1
+ else Result.ret v
+
+/- [loops::clear]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) -/
+def clear (v : alloc.vec.Vec U32) : Result (alloc.vec.Vec U32) :=
+ clear_loop v 0#usize
+
+/- [loops::List] -/
+inductive List (T : Type) :=
+| Cons : T → List T → List T
+| Nil : List T
+
+/- [loops::list_mem]: loop 0: forward function -/
+divergent def list_mem_loop (x : U32) (ls : List U32) : Result Bool :=
+ match ls with
+ | List.Cons y tl => if y = x
+ then Result.ret true
+ else list_mem_loop x tl
+ | List.Nil => Result.ret false
+
+/- [loops::list_mem]: forward function -/
+def list_mem (x : U32) (ls : List U32) : Result Bool :=
+ list_mem_loop x ls
+
+/- [loops::list_nth_mut_loop]: loop 0: forward function -/
+divergent def list_nth_mut_loop_loop
+ (T : Type) (ls : List T) (i : U32) : Result T :=
+ match ls with
+ | List.Cons x tl =>
+ if i = 0#u32
+ then Result.ret x
+ else do
+ let i0 ← i - 1#u32
+ list_nth_mut_loop_loop T tl i0
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop]: forward function -/
+def list_nth_mut_loop (T : Type) (ls : List T) (i : U32) : Result T :=
+ list_nth_mut_loop_loop T ls i
+
+/- [loops::list_nth_mut_loop]: loop 0: backward function 0 -/
+divergent def list_nth_mut_loop_loop_back
+ (T : Type) (ls : List T) (i : U32) (ret0 : T) : Result (List T) :=
+ match ls with
+ | List.Cons x tl =>
+ if i = 0#u32
+ then Result.ret (List.Cons ret0 tl)
+ else
+ do
+ let i0 ← i - 1#u32
+ let tl0 ← list_nth_mut_loop_loop_back T tl i0 ret0
+ Result.ret (List.Cons x tl0)
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop]: backward function 0 -/
+def list_nth_mut_loop_back
+ (T : Type) (ls : List T) (i : U32) (ret0 : T) : Result (List T) :=
+ list_nth_mut_loop_loop_back T ls i ret0
+
+/- [loops::list_nth_shared_loop]: loop 0: forward function -/
+divergent def list_nth_shared_loop_loop
+ (T : Type) (ls : List T) (i : U32) : Result T :=
+ match ls with
+ | List.Cons x tl =>
+ if i = 0#u32
+ then Result.ret x
+ else do
+ let i0 ← i - 1#u32
+ list_nth_shared_loop_loop T tl i0
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_shared_loop]: forward function -/
+def list_nth_shared_loop (T : Type) (ls : List T) (i : U32) : Result T :=
+ list_nth_shared_loop_loop T ls i
+
+/- [loops::get_elem_mut]: loop 0: forward function -/
+divergent def get_elem_mut_loop (x : Usize) (ls : List Usize) : Result Usize :=
+ match ls with
+ | List.Cons y tl => if y = x
+ then Result.ret y
+ else get_elem_mut_loop x tl
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::get_elem_mut]: forward function -/
+def get_elem_mut
+ (slots : alloc.vec.Vec (List Usize)) (x : Usize) : Result Usize :=
+ do
+ let l ←
+ alloc.vec.Vec.index_mut (List Usize) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List Usize))
+ slots 0#usize
+ get_elem_mut_loop x l
+
+/- [loops::get_elem_mut]: loop 0: backward function 0 -/
+divergent def get_elem_mut_loop_back
+ (x : Usize) (ls : List Usize) (ret0 : Usize) : Result (List Usize) :=
+ match ls with
+ | List.Cons y tl =>
+ if y = x
+ then Result.ret (List.Cons ret0 tl)
+ else
+ do
+ let tl0 ← get_elem_mut_loop_back x tl ret0
+ Result.ret (List.Cons y tl0)
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::get_elem_mut]: backward function 0 -/
+def get_elem_mut_back
+ (slots : alloc.vec.Vec (List Usize)) (x : Usize) (ret0 : Usize) :
+ Result (alloc.vec.Vec (List Usize))
+ :=
+ do
+ let l ←
+ alloc.vec.Vec.index_mut (List Usize) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List Usize))
+ slots 0#usize
+ let l0 ← get_elem_mut_loop_back x l ret0
+ alloc.vec.Vec.index_mut_back (List Usize) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List Usize)) slots
+ 0#usize l0
+
+/- [loops::get_elem_shared]: loop 0: forward function -/
+divergent def get_elem_shared_loop
+ (x : Usize) (ls : List Usize) : Result Usize :=
+ match ls with
+ | List.Cons y tl => if y = x
+ then Result.ret y
+ else get_elem_shared_loop x tl
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::get_elem_shared]: forward function -/
+def get_elem_shared
+ (slots : alloc.vec.Vec (List Usize)) (x : Usize) : Result Usize :=
+ do
+ let l ←
+ alloc.vec.Vec.index (List Usize) Usize
+ (core.slice.index.usize.coresliceindexSliceIndexInst (List Usize))
+ slots 0#usize
+ get_elem_shared_loop x l
+
+/- [loops::id_mut]: forward function -/
+def id_mut (T : Type) (ls : List T) : Result (List T) :=
+ Result.ret ls
+
+/- [loops::id_mut]: backward function 0 -/
+def id_mut_back (T : Type) (ls : List T) (ret0 : List T) : Result (List T) :=
+ Result.ret ret0
+
+/- [loops::id_shared]: forward function -/
+def id_shared (T : Type) (ls : List T) : Result (List T) :=
+ Result.ret ls
+
+/- [loops::list_nth_mut_loop_with_id]: loop 0: forward function -/
+divergent def list_nth_mut_loop_with_id_loop
+ (T : Type) (i : U32) (ls : List T) : Result T :=
+ match ls with
+ | List.Cons x tl =>
+ if i = 0#u32
+ then Result.ret x
+ else do
+ let i0 ← i - 1#u32
+ list_nth_mut_loop_with_id_loop T i0 tl
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop_with_id]: forward function -/
+def list_nth_mut_loop_with_id (T : Type) (ls : List T) (i : U32) : Result T :=
+ do
+ let ls0 ← id_mut T ls
+ list_nth_mut_loop_with_id_loop T i ls0
+
+/- [loops::list_nth_mut_loop_with_id]: loop 0: backward function 0 -/
+divergent def list_nth_mut_loop_with_id_loop_back
+ (T : Type) (i : U32) (ls : List T) (ret0 : T) : Result (List T) :=
+ match ls with
+ | List.Cons x tl =>
+ if i = 0#u32
+ then Result.ret (List.Cons ret0 tl)
+ else
+ do
+ let i0 ← i - 1#u32
+ let tl0 ← list_nth_mut_loop_with_id_loop_back T i0 tl ret0
+ Result.ret (List.Cons x tl0)
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop_with_id]: backward function 0 -/
+def list_nth_mut_loop_with_id_back
+ (T : Type) (ls : List T) (i : U32) (ret0 : T) : Result (List T) :=
+ do
+ let ls0 ← id_mut T ls
+ let l ← list_nth_mut_loop_with_id_loop_back T i ls0 ret0
+ id_mut_back T ls l
+
+/- [loops::list_nth_shared_loop_with_id]: loop 0: forward function -/
+divergent def list_nth_shared_loop_with_id_loop
+ (T : Type) (i : U32) (ls : List T) : Result T :=
+ match ls with
+ | List.Cons x tl =>
+ if i = 0#u32
+ then Result.ret x
+ else do
+ let i0 ← i - 1#u32
+ list_nth_shared_loop_with_id_loop T i0 tl
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_shared_loop_with_id]: forward function -/
+def list_nth_shared_loop_with_id
+ (T : Type) (ls : List T) (i : U32) : Result T :=
+ do
+ let ls0 ← id_shared T ls
+ list_nth_shared_loop_with_id_loop T i ls0
+
+/- [loops::list_nth_mut_loop_pair]: loop 0: forward function -/
+divergent def list_nth_mut_loop_pair_loop
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (x0, x1)
+ else do
+ let i0 ← i - 1#u32
+ list_nth_mut_loop_pair_loop T tl0 tl1 i0
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop_pair]: forward function -/
+def list_nth_mut_loop_pair
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ list_nth_mut_loop_pair_loop T ls0 ls1 i
+
+/- [loops::list_nth_mut_loop_pair]: loop 0: backward function 0 -/
+divergent def list_nth_mut_loop_pair_loop_back'a
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (List.Cons ret0 tl0)
+ else
+ do
+ let i0 ← i - 1#u32
+ let tl00 ← list_nth_mut_loop_pair_loop_back'a T tl0 tl1 i0 ret0
+ Result.ret (List.Cons x0 tl00)
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop_pair]: backward function 0 -/
+def list_nth_mut_loop_pair_back'a
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ list_nth_mut_loop_pair_loop_back'a T ls0 ls1 i ret0
+
+/- [loops::list_nth_mut_loop_pair]: loop 0: backward function 1 -/
+divergent def list_nth_mut_loop_pair_loop_back'b
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (List.Cons ret0 tl1)
+ else
+ do
+ let i0 ← i - 1#u32
+ let tl10 ← list_nth_mut_loop_pair_loop_back'b T tl0 tl1 i0 ret0
+ Result.ret (List.Cons x1 tl10)
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop_pair]: backward function 1 -/
+def list_nth_mut_loop_pair_back'b
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ list_nth_mut_loop_pair_loop_back'b T ls0 ls1 i ret0
+
+/- [loops::list_nth_shared_loop_pair]: loop 0: forward function -/
+divergent def list_nth_shared_loop_pair_loop
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (x0, x1)
+ else do
+ let i0 ← i - 1#u32
+ list_nth_shared_loop_pair_loop T tl0 tl1 i0
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_shared_loop_pair]: forward function -/
+def list_nth_shared_loop_pair
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ list_nth_shared_loop_pair_loop T ls0 ls1 i
+
+/- [loops::list_nth_mut_loop_pair_merge]: loop 0: forward function -/
+divergent def list_nth_mut_loop_pair_merge_loop
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (x0, x1)
+ else
+ do
+ let i0 ← i - 1#u32
+ list_nth_mut_loop_pair_merge_loop T tl0 tl1 i0
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop_pair_merge]: forward function -/
+def list_nth_mut_loop_pair_merge
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ list_nth_mut_loop_pair_merge_loop T ls0 ls1 i
+
+/- [loops::list_nth_mut_loop_pair_merge]: loop 0: backward function 0 -/
+divergent def list_nth_mut_loop_pair_merge_loop_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : (T × T)) :
+ Result ((List T) × (List T))
+ :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then let (t, t0) := ret0
+ Result.ret (List.Cons t tl0, List.Cons t0 tl1)
+ else
+ do
+ let i0 ← i - 1#u32
+ let (tl00, tl10) ←
+ list_nth_mut_loop_pair_merge_loop_back T tl0 tl1 i0 ret0
+ Result.ret (List.Cons x0 tl00, List.Cons x1 tl10)
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_loop_pair_merge]: backward function 0 -/
+def list_nth_mut_loop_pair_merge_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : (T × T)) :
+ Result ((List T) × (List T))
+ :=
+ list_nth_mut_loop_pair_merge_loop_back T ls0 ls1 i ret0
+
+/- [loops::list_nth_shared_loop_pair_merge]: loop 0: forward function -/
+divergent def list_nth_shared_loop_pair_merge_loop
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (x0, x1)
+ else
+ do
+ let i0 ← i - 1#u32
+ list_nth_shared_loop_pair_merge_loop T tl0 tl1 i0
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_shared_loop_pair_merge]: forward function -/
+def list_nth_shared_loop_pair_merge
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ list_nth_shared_loop_pair_merge_loop T ls0 ls1 i
+
+/- [loops::list_nth_mut_shared_loop_pair]: loop 0: forward function -/
+divergent def list_nth_mut_shared_loop_pair_loop
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (x0, x1)
+ else
+ do
+ let i0 ← i - 1#u32
+ list_nth_mut_shared_loop_pair_loop T tl0 tl1 i0
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_shared_loop_pair]: forward function -/
+def list_nth_mut_shared_loop_pair
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ list_nth_mut_shared_loop_pair_loop T ls0 ls1 i
+
+/- [loops::list_nth_mut_shared_loop_pair]: loop 0: backward function 0 -/
+divergent def list_nth_mut_shared_loop_pair_loop_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (List.Cons ret0 tl0)
+ else
+ do
+ let i0 ← i - 1#u32
+ let tl00 ←
+ list_nth_mut_shared_loop_pair_loop_back T tl0 tl1 i0 ret0
+ Result.ret (List.Cons x0 tl00)
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_shared_loop_pair]: backward function 0 -/
+def list_nth_mut_shared_loop_pair_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ list_nth_mut_shared_loop_pair_loop_back T ls0 ls1 i ret0
+
+/- [loops::list_nth_mut_shared_loop_pair_merge]: loop 0: forward function -/
+divergent def list_nth_mut_shared_loop_pair_merge_loop
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (x0, x1)
+ else
+ do
+ let i0 ← i - 1#u32
+ list_nth_mut_shared_loop_pair_merge_loop T tl0 tl1 i0
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_shared_loop_pair_merge]: forward function -/
+def list_nth_mut_shared_loop_pair_merge
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ list_nth_mut_shared_loop_pair_merge_loop T ls0 ls1 i
+
+/- [loops::list_nth_mut_shared_loop_pair_merge]: loop 0: backward function 0 -/
+divergent def list_nth_mut_shared_loop_pair_merge_loop_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (List.Cons ret0 tl0)
+ else
+ do
+ let i0 ← i - 1#u32
+ let tl00 ←
+ list_nth_mut_shared_loop_pair_merge_loop_back T tl0 tl1 i0 ret0
+ Result.ret (List.Cons x0 tl00)
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_mut_shared_loop_pair_merge]: backward function 0 -/
+def list_nth_mut_shared_loop_pair_merge_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ list_nth_mut_shared_loop_pair_merge_loop_back T ls0 ls1 i ret0
+
+/- [loops::list_nth_shared_mut_loop_pair]: loop 0: forward function -/
+divergent def list_nth_shared_mut_loop_pair_loop
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (x0, x1)
+ else
+ do
+ let i0 ← i - 1#u32
+ list_nth_shared_mut_loop_pair_loop T tl0 tl1 i0
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_shared_mut_loop_pair]: forward function -/
+def list_nth_shared_mut_loop_pair
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ list_nth_shared_mut_loop_pair_loop T ls0 ls1 i
+
+/- [loops::list_nth_shared_mut_loop_pair]: loop 0: backward function 1 -/
+divergent def list_nth_shared_mut_loop_pair_loop_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (List.Cons ret0 tl1)
+ else
+ do
+ let i0 ← i - 1#u32
+ let tl10 ←
+ list_nth_shared_mut_loop_pair_loop_back T tl0 tl1 i0 ret0
+ Result.ret (List.Cons x1 tl10)
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_shared_mut_loop_pair]: backward function 1 -/
+def list_nth_shared_mut_loop_pair_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ list_nth_shared_mut_loop_pair_loop_back T ls0 ls1 i ret0
+
+/- [loops::list_nth_shared_mut_loop_pair_merge]: loop 0: forward function -/
+divergent def list_nth_shared_mut_loop_pair_merge_loop
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (x0, x1)
+ else
+ do
+ let i0 ← i - 1#u32
+ list_nth_shared_mut_loop_pair_merge_loop T tl0 tl1 i0
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_shared_mut_loop_pair_merge]: forward function -/
+def list_nth_shared_mut_loop_pair_merge
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
+ list_nth_shared_mut_loop_pair_merge_loop T ls0 ls1 i
+
+/- [loops::list_nth_shared_mut_loop_pair_merge]: loop 0: backward function 0 -/
+divergent def list_nth_shared_mut_loop_pair_merge_loop_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ match ls0 with
+ | List.Cons x0 tl0 =>
+ match ls1 with
+ | List.Cons x1 tl1 =>
+ if i = 0#u32
+ then Result.ret (List.Cons ret0 tl1)
+ else
+ do
+ let i0 ← i - 1#u32
+ let tl10 ←
+ list_nth_shared_mut_loop_pair_merge_loop_back T tl0 tl1 i0 ret0
+ Result.ret (List.Cons x1 tl10)
+ | List.Nil => Result.fail Error.panic
+ | List.Nil => Result.fail Error.panic
+
+/- [loops::list_nth_shared_mut_loop_pair_merge]: backward function 0 -/
+def list_nth_shared_mut_loop_pair_merge_back
+ (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
+ Result (List T)
+ :=
+ list_nth_shared_mut_loop_pair_merge_loop_back T ls0 ls1 i ret0
+
+end loops
diff --git a/tests/lean/Loops/Funs.lean b/tests/lean/Loops/Funs.lean
deleted file mode 100644
index 5fbe200f..00000000
--- a/tests/lean/Loops/Funs.lean
+++ /dev/null
@@ -1,612 +0,0 @@
--- THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS
--- [loops]: function definitions
-import Base
-import Loops.Types
-open Primitives
-
-namespace loops
-
-/- [loops::sum]: loop 0: forward function -/
-divergent def sum_loop (max : U32) (i : U32) (s : U32) : Result U32 :=
- if i < max
- then do
- let s0 ← s + i
- let i0 ← i + (U32.ofInt 1)
- sum_loop max i0 s0
- else s * (U32.ofInt 2)
-
-/- [loops::sum]: forward function -/
-def sum (max : U32) : Result U32 :=
- sum_loop max (U32.ofInt 0) (U32.ofInt 0)
-
-/- [loops::sum_with_mut_borrows]: loop 0: forward function -/
-divergent def sum_with_mut_borrows_loop
- (max : U32) (mi : U32) (ms : U32) : Result U32 :=
- if mi < max
- then
- do
- let ms0 ← ms + mi
- let mi0 ← mi + (U32.ofInt 1)
- sum_with_mut_borrows_loop max mi0 ms0
- else ms * (U32.ofInt 2)
-
-/- [loops::sum_with_mut_borrows]: forward function -/
-def sum_with_mut_borrows (max : U32) : Result U32 :=
- sum_with_mut_borrows_loop max (U32.ofInt 0) (U32.ofInt 0)
-
-/- [loops::sum_with_shared_borrows]: loop 0: forward function -/
-divergent def sum_with_shared_borrows_loop
- (max : U32) (i : U32) (s : U32) : Result U32 :=
- if i < max
- then
- do
- let i0 ← i + (U32.ofInt 1)
- let s0 ← s + i0
- sum_with_shared_borrows_loop max i0 s0
- else s * (U32.ofInt 2)
-
-/- [loops::sum_with_shared_borrows]: forward function -/
-def sum_with_shared_borrows (max : U32) : Result U32 :=
- sum_with_shared_borrows_loop max (U32.ofInt 0) (U32.ofInt 0)
-
-/- [loops::clear]: loop 0: merged forward/backward function
- (there is a single backward function, and the forward function returns ()) -/
-divergent def clear_loop (v : Vec U32) (i : Usize) : Result (Vec U32) :=
- let i0 := Vec.len U32 v
- if i < i0
- then
- do
- let i1 ← i + (Usize.ofInt 1)
- let v0 ← Vec.index_mut_back U32 v i (U32.ofInt 0)
- clear_loop v0 i1
- else Result.ret v
-
-/- [loops::clear]: merged forward/backward function
- (there is a single backward function, and the forward function returns ()) -/
-def clear (v : Vec U32) : Result (Vec U32) :=
- clear_loop v (Usize.ofInt 0)
-
-/- [loops::list_mem]: loop 0: forward function -/
-divergent def list_mem_loop (x : U32) (ls : List U32) : Result Bool :=
- match ls with
- | List.Cons y tl => if y = x
- then Result.ret true
- else list_mem_loop x tl
- | List.Nil => Result.ret false
-
-/- [loops::list_mem]: forward function -/
-def list_mem (x : U32) (ls : List U32) : Result Bool :=
- list_mem_loop x ls
-
-/- [loops::list_nth_mut_loop]: loop 0: forward function -/
-divergent def list_nth_mut_loop_loop
- (T : Type) (ls : List T) (i : U32) : Result T :=
- match ls with
- | List.Cons x tl =>
- if i = (U32.ofInt 0)
- then Result.ret x
- else do
- let i0 ← i - (U32.ofInt 1)
- list_nth_mut_loop_loop T tl i0
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop]: forward function -/
-def list_nth_mut_loop (T : Type) (ls : List T) (i : U32) : Result T :=
- list_nth_mut_loop_loop T ls i
-
-/- [loops::list_nth_mut_loop]: loop 0: backward function 0 -/
-divergent def list_nth_mut_loop_loop_back
- (T : Type) (ls : List T) (i : U32) (ret0 : T) : Result (List T) :=
- match ls with
- | List.Cons x tl =>
- if i = (U32.ofInt 0)
- then Result.ret (List.Cons ret0 tl)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let tl0 ← list_nth_mut_loop_loop_back T tl i0 ret0
- Result.ret (List.Cons x tl0)
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop]: backward function 0 -/
-def list_nth_mut_loop_back
- (T : Type) (ls : List T) (i : U32) (ret0 : T) : Result (List T) :=
- list_nth_mut_loop_loop_back T ls i ret0
-
-/- [loops::list_nth_shared_loop]: loop 0: forward function -/
-divergent def list_nth_shared_loop_loop
- (T : Type) (ls : List T) (i : U32) : Result T :=
- match ls with
- | List.Cons x tl =>
- if i = (U32.ofInt 0)
- then Result.ret x
- else do
- let i0 ← i - (U32.ofInt 1)
- list_nth_shared_loop_loop T tl i0
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_shared_loop]: forward function -/
-def list_nth_shared_loop (T : Type) (ls : List T) (i : U32) : Result T :=
- list_nth_shared_loop_loop T ls i
-
-/- [loops::get_elem_mut]: loop 0: forward function -/
-divergent def get_elem_mut_loop (x : Usize) (ls : List Usize) : Result Usize :=
- match ls with
- | List.Cons y tl => if y = x
- then Result.ret y
- else get_elem_mut_loop x tl
- | List.Nil => Result.fail Error.panic
-
-/- [loops::get_elem_mut]: forward function -/
-def get_elem_mut (slots : Vec (List Usize)) (x : Usize) : Result Usize :=
- do
- let l ← Vec.index_mut (List Usize) slots (Usize.ofInt 0)
- get_elem_mut_loop x l
-
-/- [loops::get_elem_mut]: loop 0: backward function 0 -/
-divergent def get_elem_mut_loop_back
- (x : Usize) (ls : List Usize) (ret0 : Usize) : Result (List Usize) :=
- match ls with
- | List.Cons y tl =>
- if y = x
- then Result.ret (List.Cons ret0 tl)
- else
- do
- let tl0 ← get_elem_mut_loop_back x tl ret0
- Result.ret (List.Cons y tl0)
- | List.Nil => Result.fail Error.panic
-
-/- [loops::get_elem_mut]: backward function 0 -/
-def get_elem_mut_back
- (slots : Vec (List Usize)) (x : Usize) (ret0 : Usize) :
- Result (Vec (List Usize))
- :=
- do
- let l ← Vec.index_mut (List Usize) slots (Usize.ofInt 0)
- let l0 ← get_elem_mut_loop_back x l ret0
- Vec.index_mut_back (List Usize) slots (Usize.ofInt 0) l0
-
-/- [loops::get_elem_shared]: loop 0: forward function -/
-divergent def get_elem_shared_loop
- (x : Usize) (ls : List Usize) : Result Usize :=
- match ls with
- | List.Cons y tl => if y = x
- then Result.ret y
- else get_elem_shared_loop x tl
- | List.Nil => Result.fail Error.panic
-
-/- [loops::get_elem_shared]: forward function -/
-def get_elem_shared (slots : Vec (List Usize)) (x : Usize) : Result Usize :=
- do
- let l ← Vec.index_shared (List Usize) slots (Usize.ofInt 0)
- get_elem_shared_loop x l
-
-/- [loops::id_mut]: forward function -/
-def id_mut (T : Type) (ls : List T) : Result (List T) :=
- Result.ret ls
-
-/- [loops::id_mut]: backward function 0 -/
-def id_mut_back (T : Type) (ls : List T) (ret0 : List T) : Result (List T) :=
- Result.ret ret0
-
-/- [loops::id_shared]: forward function -/
-def id_shared (T : Type) (ls : List T) : Result (List T) :=
- Result.ret ls
-
-/- [loops::list_nth_mut_loop_with_id]: loop 0: forward function -/
-divergent def list_nth_mut_loop_with_id_loop
- (T : Type) (i : U32) (ls : List T) : Result T :=
- match ls with
- | List.Cons x tl =>
- if i = (U32.ofInt 0)
- then Result.ret x
- else do
- let i0 ← i - (U32.ofInt 1)
- list_nth_mut_loop_with_id_loop T i0 tl
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop_with_id]: forward function -/
-def list_nth_mut_loop_with_id (T : Type) (ls : List T) (i : U32) : Result T :=
- do
- let ls0 ← id_mut T ls
- list_nth_mut_loop_with_id_loop T i ls0
-
-/- [loops::list_nth_mut_loop_with_id]: loop 0: backward function 0 -/
-divergent def list_nth_mut_loop_with_id_loop_back
- (T : Type) (i : U32) (ls : List T) (ret0 : T) : Result (List T) :=
- match ls with
- | List.Cons x tl =>
- if i = (U32.ofInt 0)
- then Result.ret (List.Cons ret0 tl)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let tl0 ← list_nth_mut_loop_with_id_loop_back T i0 tl ret0
- Result.ret (List.Cons x tl0)
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop_with_id]: backward function 0 -/
-def list_nth_mut_loop_with_id_back
- (T : Type) (ls : List T) (i : U32) (ret0 : T) : Result (List T) :=
- do
- let ls0 ← id_mut T ls
- let l ← list_nth_mut_loop_with_id_loop_back T i ls0 ret0
- id_mut_back T ls l
-
-/- [loops::list_nth_shared_loop_with_id]: loop 0: forward function -/
-divergent def list_nth_shared_loop_with_id_loop
- (T : Type) (i : U32) (ls : List T) : Result T :=
- match ls with
- | List.Cons x tl =>
- if i = (U32.ofInt 0)
- then Result.ret x
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_shared_loop_with_id_loop T i0 tl
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_shared_loop_with_id]: forward function -/
-def list_nth_shared_loop_with_id
- (T : Type) (ls : List T) (i : U32) : Result T :=
- do
- let ls0 ← id_shared T ls
- list_nth_shared_loop_with_id_loop T i ls0
-
-/- [loops::list_nth_mut_loop_pair]: loop 0: forward function -/
-divergent def list_nth_mut_loop_pair_loop
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (x0, x1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_mut_loop_pair_loop T tl0 tl1 i0
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop_pair]: forward function -/
-def list_nth_mut_loop_pair
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- list_nth_mut_loop_pair_loop T ls0 ls1 i
-
-/- [loops::list_nth_mut_loop_pair]: loop 0: backward function 0 -/
-divergent def list_nth_mut_loop_pair_loop_back'a
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (List.Cons ret0 tl0)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let tl00 ← list_nth_mut_loop_pair_loop_back'a T tl0 tl1 i0 ret0
- Result.ret (List.Cons x0 tl00)
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop_pair]: backward function 0 -/
-def list_nth_mut_loop_pair_back'a
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- list_nth_mut_loop_pair_loop_back'a T ls0 ls1 i ret0
-
-/- [loops::list_nth_mut_loop_pair]: loop 0: backward function 1 -/
-divergent def list_nth_mut_loop_pair_loop_back'b
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (List.Cons ret0 tl1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let tl10 ← list_nth_mut_loop_pair_loop_back'b T tl0 tl1 i0 ret0
- Result.ret (List.Cons x1 tl10)
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop_pair]: backward function 1 -/
-def list_nth_mut_loop_pair_back'b
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- list_nth_mut_loop_pair_loop_back'b T ls0 ls1 i ret0
-
-/- [loops::list_nth_shared_loop_pair]: loop 0: forward function -/
-divergent def list_nth_shared_loop_pair_loop
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (x0, x1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_shared_loop_pair_loop T tl0 tl1 i0
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_shared_loop_pair]: forward function -/
-def list_nth_shared_loop_pair
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- list_nth_shared_loop_pair_loop T ls0 ls1 i
-
-/- [loops::list_nth_mut_loop_pair_merge]: loop 0: forward function -/
-divergent def list_nth_mut_loop_pair_merge_loop
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (x0, x1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_mut_loop_pair_merge_loop T tl0 tl1 i0
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop_pair_merge]: forward function -/
-def list_nth_mut_loop_pair_merge
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- list_nth_mut_loop_pair_merge_loop T ls0 ls1 i
-
-/- [loops::list_nth_mut_loop_pair_merge]: loop 0: backward function 0 -/
-divergent def list_nth_mut_loop_pair_merge_loop_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : (T × T)) :
- Result ((List T) × (List T))
- :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then let (t, t0) := ret0
- Result.ret (List.Cons t tl0, List.Cons t0 tl1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let (tl00, tl10) ←
- list_nth_mut_loop_pair_merge_loop_back T tl0 tl1 i0 ret0
- Result.ret (List.Cons x0 tl00, List.Cons x1 tl10)
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_loop_pair_merge]: backward function 0 -/
-def list_nth_mut_loop_pair_merge_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : (T × T)) :
- Result ((List T) × (List T))
- :=
- list_nth_mut_loop_pair_merge_loop_back T ls0 ls1 i ret0
-
-/- [loops::list_nth_shared_loop_pair_merge]: loop 0: forward function -/
-divergent def list_nth_shared_loop_pair_merge_loop
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (x0, x1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_shared_loop_pair_merge_loop T tl0 tl1 i0
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_shared_loop_pair_merge]: forward function -/
-def list_nth_shared_loop_pair_merge
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- list_nth_shared_loop_pair_merge_loop T ls0 ls1 i
-
-/- [loops::list_nth_mut_shared_loop_pair]: loop 0: forward function -/
-divergent def list_nth_mut_shared_loop_pair_loop
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (x0, x1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_mut_shared_loop_pair_loop T tl0 tl1 i0
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_shared_loop_pair]: forward function -/
-def list_nth_mut_shared_loop_pair
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- list_nth_mut_shared_loop_pair_loop T ls0 ls1 i
-
-/- [loops::list_nth_mut_shared_loop_pair]: loop 0: backward function 0 -/
-divergent def list_nth_mut_shared_loop_pair_loop_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (List.Cons ret0 tl0)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let tl00 ←
- list_nth_mut_shared_loop_pair_loop_back T tl0 tl1 i0 ret0
- Result.ret (List.Cons x0 tl00)
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_shared_loop_pair]: backward function 0 -/
-def list_nth_mut_shared_loop_pair_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- list_nth_mut_shared_loop_pair_loop_back T ls0 ls1 i ret0
-
-/- [loops::list_nth_mut_shared_loop_pair_merge]: loop 0: forward function -/
-divergent def list_nth_mut_shared_loop_pair_merge_loop
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (x0, x1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_mut_shared_loop_pair_merge_loop T tl0 tl1 i0
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_shared_loop_pair_merge]: forward function -/
-def list_nth_mut_shared_loop_pair_merge
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- list_nth_mut_shared_loop_pair_merge_loop T ls0 ls1 i
-
-/- [loops::list_nth_mut_shared_loop_pair_merge]: loop 0: backward function 0 -/
-divergent def list_nth_mut_shared_loop_pair_merge_loop_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (List.Cons ret0 tl0)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let tl00 ←
- list_nth_mut_shared_loop_pair_merge_loop_back T tl0 tl1 i0 ret0
- Result.ret (List.Cons x0 tl00)
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_mut_shared_loop_pair_merge]: backward function 0 -/
-def list_nth_mut_shared_loop_pair_merge_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- list_nth_mut_shared_loop_pair_merge_loop_back T ls0 ls1 i ret0
-
-/- [loops::list_nth_shared_mut_loop_pair]: loop 0: forward function -/
-divergent def list_nth_shared_mut_loop_pair_loop
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (x0, x1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_shared_mut_loop_pair_loop T tl0 tl1 i0
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_shared_mut_loop_pair]: forward function -/
-def list_nth_shared_mut_loop_pair
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- list_nth_shared_mut_loop_pair_loop T ls0 ls1 i
-
-/- [loops::list_nth_shared_mut_loop_pair]: loop 0: backward function 1 -/
-divergent def list_nth_shared_mut_loop_pair_loop_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (List.Cons ret0 tl1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let tl10 ←
- list_nth_shared_mut_loop_pair_loop_back T tl0 tl1 i0 ret0
- Result.ret (List.Cons x1 tl10)
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_shared_mut_loop_pair]: backward function 1 -/
-def list_nth_shared_mut_loop_pair_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- list_nth_shared_mut_loop_pair_loop_back T ls0 ls1 i ret0
-
-/- [loops::list_nth_shared_mut_loop_pair_merge]: loop 0: forward function -/
-divergent def list_nth_shared_mut_loop_pair_merge_loop
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (x0, x1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- list_nth_shared_mut_loop_pair_merge_loop T tl0 tl1 i0
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_shared_mut_loop_pair_merge]: forward function -/
-def list_nth_shared_mut_loop_pair_merge
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) : Result (T × T) :=
- list_nth_shared_mut_loop_pair_merge_loop T ls0 ls1 i
-
-/- [loops::list_nth_shared_mut_loop_pair_merge]: loop 0: backward function 0 -/
-divergent def list_nth_shared_mut_loop_pair_merge_loop_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- match ls0 with
- | List.Cons x0 tl0 =>
- match ls1 with
- | List.Cons x1 tl1 =>
- if i = (U32.ofInt 0)
- then Result.ret (List.Cons ret0 tl1)
- else
- do
- let i0 ← i - (U32.ofInt 1)
- let tl10 ←
- list_nth_shared_mut_loop_pair_merge_loop_back T tl0 tl1 i0 ret0
- Result.ret (List.Cons x1 tl10)
- | List.Nil => Result.fail Error.panic
- | List.Nil => Result.fail Error.panic
-
-/- [loops::list_nth_shared_mut_loop_pair_merge]: backward function 0 -/
-def list_nth_shared_mut_loop_pair_merge_back
- (T : Type) (ls0 : List T) (ls1 : List T) (i : U32) (ret0 : T) :
- Result (List T)
- :=
- list_nth_shared_mut_loop_pair_merge_loop_back T ls0 ls1 i ret0
-
-end loops
diff --git a/tests/lean/Loops/Types.lean b/tests/lean/Loops/Types.lean
deleted file mode 100644
index 018af901..00000000
--- a/tests/lean/Loops/Types.lean
+++ /dev/null
@@ -1,13 +0,0 @@
--- THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS
--- [loops]: type definitions
-import Base
-open Primitives
-
-namespace loops
-
-/- [loops::List] -/
-inductive List (T : Type) :=
-| Cons : T → List T → List T
-| Nil : List T
-
-end loops
diff --git a/tests/lean/NoNestedBorrows.lean b/tests/lean/NoNestedBorrows.lean
index 884e62c4..c4a6a265 100644
--- a/tests/lean/NoNestedBorrows.lean
+++ b/tests/lean/NoNestedBorrows.lean
@@ -54,12 +54,24 @@ def div_test (x : U32) (y : U32) : Result U32 :=
/- [no_nested_borrows::div_test1]: forward function -/
def div_test1 (x : U32) : Result U32 :=
- x / (U32.ofInt 2)
+ x / 2#u32
/- [no_nested_borrows::rem_test]: forward function -/
def rem_test (x : U32) (y : U32) : Result U32 :=
x % y
+/- [no_nested_borrows::mul_test]: forward function -/
+def mul_test (x : U32) (y : U32) : Result U32 :=
+ x * y
+
+/- [no_nested_borrows::CONST0] -/
+def const0_body : Result Usize := 1#usize + 1#usize
+def const0_c : Usize := eval_global const0_body (by simp)
+
+/- [no_nested_borrows::CONST1] -/
+def const1_body : Result Usize := 2#usize * 2#usize
+def const1_c : Usize := eval_global const1_body (by simp)
+
/- [no_nested_borrows::cast_test]: forward function -/
def cast_test (x : U32) : Result I32 :=
Scalar.cast .I32 x
@@ -67,7 +79,7 @@ def cast_test (x : U32) : Result I32 :=
/- [no_nested_borrows::test2]: forward function -/
def test2 : Result Unit :=
do
- let _ ← (U32.ofInt 23) + (U32.ofInt 44)
+ let _ ← 23#u32 + 44#u32
Result.ret ()
/- Unit test for [no_nested_borrows::test2] -/
@@ -82,10 +94,10 @@ def get_max (x : U32) (y : U32) : Result U32 :=
/- [no_nested_borrows::test3]: forward function -/
def test3 : Result Unit :=
do
- let x ← get_max (U32.ofInt 4) (U32.ofInt 3)
- let y ← get_max (U32.ofInt 10) (U32.ofInt 11)
+ let x ← get_max 4#u32 3#u32
+ let y ← get_max 10#u32 11#u32
let z ← x + y
- if not (z = (U32.ofInt 15))
+ if not (z = 15#u32)
then Result.fail Error.panic
else Result.ret ()
@@ -95,8 +107,8 @@ def test3 : Result Unit :=
/- [no_nested_borrows::test_neg1]: forward function -/
def test_neg1 : Result Unit :=
do
- let y ← - (I32.ofInt 3)
- if not (y = (I32.ofInt (-(3:Int))))
+ let y ← - 3#i32
+ if not (y = (-(3:Int))#i32)
then Result.fail Error.panic
else Result.ret ()
@@ -105,7 +117,7 @@ def test_neg1 : Result Unit :=
/- [no_nested_borrows::refs_test1]: forward function -/
def refs_test1 : Result Unit :=
- if not ((I32.ofInt 1) = (I32.ofInt 1))
+ if not (1#i32 = 1#i32)
then Result.fail Error.panic
else Result.ret ()
@@ -114,16 +126,16 @@ def refs_test1 : Result Unit :=
/- [no_nested_borrows::refs_test2]: forward function -/
def refs_test2 : Result Unit :=
- if not ((I32.ofInt 2) = (I32.ofInt 2))
+ if not (2#i32 = 2#i32)
then Result.fail Error.panic
else
- if not ((I32.ofInt 0) = (I32.ofInt 0))
+ if not (0#i32 = 0#i32)
then Result.fail Error.panic
else
- if not ((I32.ofInt 2) = (I32.ofInt 2))
+ if not (2#i32 = 2#i32)
then Result.fail Error.panic
else
- if not ((I32.ofInt 2) = (I32.ofInt 2))
+ if not (2#i32 = 2#i32)
then Result.fail Error.panic
else Result.ret ()
@@ -139,9 +151,9 @@ def test_list1 : Result Unit :=
/- [no_nested_borrows::test_box1]: forward function -/
def test_box1 : Result Unit :=
- let b := (I32.ofInt 1)
+ let b := 1#i32
let x := b
- if not (x = (I32.ofInt 1))
+ if not (x = 1#i32)
then Result.fail Error.panic
else Result.ret ()
@@ -167,8 +179,8 @@ def test_panic (b : Bool) : Result Unit :=
/- [no_nested_borrows::test_copy_int]: forward function -/
def test_copy_int : Result Unit :=
do
- let y ← copy_int (I32.ofInt 0)
- if not ((I32.ofInt 0) = y)
+ let y ← copy_int 0#i32
+ if not (0#i32 = y)
then Result.fail Error.panic
else Result.ret ()
@@ -185,7 +197,7 @@ def is_cons (T : Type) (l : List T) : Result Bool :=
def test_is_cons : Result Unit :=
do
let l := List.Nil
- let b ← is_cons I32 (List.Cons (I32.ofInt 0) l)
+ let b ← is_cons I32 (List.Cons 0#i32 l)
if not b
then Result.fail Error.panic
else Result.ret ()
@@ -203,9 +215,9 @@ def split_list (T : Type) (l : List T) : Result (T × (List T)) :=
def test_split_list : Result Unit :=
do
let l := List.Nil
- let p ← split_list I32 (List.Cons (I32.ofInt 0) l)
+ let p ← split_list I32 (List.Cons 0#i32 l)
let (hd, _) := p
- if not (hd = (I32.ofInt 0))
+ if not (hd = 0#i32)
then Result.fail Error.panic
else Result.ret ()
@@ -228,19 +240,18 @@ def choose_back
/- [no_nested_borrows::choose_test]: forward function -/
def choose_test : Result Unit :=
do
- let z ← choose I32 true (I32.ofInt 0) (I32.ofInt 0)
- let z0 ← z + (I32.ofInt 1)
- if not (z0 = (I32.ofInt 1))
+ let z ← choose I32 true 0#i32 0#i32
+ let z0 ← z + 1#i32
+ if not (z0 = 1#i32)
then Result.fail Error.panic
else
do
- let (x, y) ← choose_back I32 true (I32.ofInt 0) (I32.ofInt 0) z0
- if not (x = (I32.ofInt 1))
+ let (x, y) ← choose_back I32 true 0#i32 0#i32 z0
+ if not (x = 1#i32)
then Result.fail Error.panic
- else
- if not (y = (I32.ofInt 0))
- then Result.fail Error.panic
- else Result.ret ()
+ else if not (y = 0#i32)
+ then Result.fail Error.panic
+ else Result.ret ()
/- Unit test for [no_nested_borrows::choose_test] -/
#assert (choose_test == .ret ())
@@ -268,17 +279,17 @@ divergent def list_length (T : Type) (l : List T) : Result U32 :=
match l with
| List.Cons t l1 => do
let i ← list_length T l1
- (U32.ofInt 1) + i
- | List.Nil => Result.ret (U32.ofInt 0)
+ 1#u32 + i
+ | List.Nil => Result.ret 0#u32
/- [no_nested_borrows::list_nth_shared]: forward function -/
divergent def list_nth_shared (T : Type) (l : List T) (i : U32) : Result T :=
match l with
| List.Cons x tl =>
- if i = (U32.ofInt 0)
+ if i = 0#u32
then Result.ret x
else do
- let i0 ← i - (U32.ofInt 1)
+ let i0 ← i - 1#u32
list_nth_shared T tl i0
| List.Nil => Result.fail Error.panic
@@ -286,10 +297,10 @@ divergent def list_nth_shared (T : Type) (l : List T) (i : U32) : Result T :=
divergent def list_nth_mut (T : Type) (l : List T) (i : U32) : Result T :=
match l with
| List.Cons x tl =>
- if i = (U32.ofInt 0)
+ if i = 0#u32
then Result.ret x
else do
- let i0 ← i - (U32.ofInt 1)
+ let i0 ← i - 1#u32
list_nth_mut T tl i0
| List.Nil => Result.fail Error.panic
@@ -298,11 +309,11 @@ divergent def list_nth_mut_back
(T : Type) (l : List T) (i : U32) (ret0 : T) : Result (List T) :=
match l with
| List.Cons x tl =>
- if i = (U32.ofInt 0)
+ if i = 0#u32
then Result.ret (List.Cons ret0 tl)
else
do
- let i0 ← i - (U32.ofInt 1)
+ let i0 ← i - 1#u32
let tl0 ← list_nth_mut_back T tl i0 ret0
Result.ret (List.Cons x tl0)
| List.Nil => Result.fail Error.panic
@@ -317,54 +328,49 @@ divergent def list_rev_aux
/- [no_nested_borrows::list_rev]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
def list_rev (T : Type) (l : List T) : Result (List T) :=
- let li := mem.replace (List T) l List.Nil
+ let li := core.mem.replace (List T) l List.Nil
list_rev_aux T li List.Nil
/- [no_nested_borrows::test_list_functions]: forward function -/
def test_list_functions : Result Unit :=
do
let l := List.Nil
- let l0 := List.Cons (I32.ofInt 2) l
- let l1 := List.Cons (I32.ofInt 1) l0
- let i ← list_length I32 (List.Cons (I32.ofInt 0) l1)
- if not (i = (U32.ofInt 3))
+ let l0 := List.Cons 2#i32 l
+ let l1 := List.Cons 1#i32 l0
+ let i ← list_length I32 (List.Cons 0#i32 l1)
+ if not (i = 3#u32)
then Result.fail Error.panic
else
do
- let i0 ←
- list_nth_shared I32 (List.Cons (I32.ofInt 0) l1) (U32.ofInt 0)
- if not (i0 = (I32.ofInt 0))
+ let i0 ← list_nth_shared I32 (List.Cons 0#i32 l1) 0#u32
+ if not (i0 = 0#i32)
then Result.fail Error.panic
else
do
- let i1 ←
- list_nth_shared I32 (List.Cons (I32.ofInt 0) l1) (U32.ofInt 1)
- if not (i1 = (I32.ofInt 1))
+ let i1 ← list_nth_shared I32 (List.Cons 0#i32 l1) 1#u32
+ if not (i1 = 1#i32)
then Result.fail Error.panic
else
do
- let i2 ←
- list_nth_shared I32 (List.Cons (I32.ofInt 0) l1)
- (U32.ofInt 2)
- if not (i2 = (I32.ofInt 2))
+ let i2 ← list_nth_shared I32 (List.Cons 0#i32 l1) 2#u32
+ if not (i2 = 2#i32)
then Result.fail Error.panic
else
do
let ls ←
- list_nth_mut_back I32 (List.Cons (I32.ofInt 0) l1)
- (U32.ofInt 1) (I32.ofInt 3)
- let i3 ← list_nth_shared I32 ls (U32.ofInt 0)
- if not (i3 = (I32.ofInt 0))
+ list_nth_mut_back I32 (List.Cons 0#i32 l1) 1#u32 3#i32
+ let i3 ← list_nth_shared I32 ls 0#u32
+ if not (i3 = 0#i32)
then Result.fail Error.panic
else
do
- let i4 ← list_nth_shared I32 ls (U32.ofInt 1)
- if not (i4 = (I32.ofInt 3))
+ let i4 ← list_nth_shared I32 ls 1#u32
+ if not (i4 = 3#i32)
then Result.fail Error.panic
else
do
- let i5 ← list_nth_shared I32 ls (U32.ofInt 2)
- if not (i5 = (I32.ofInt 2))
+ let i5 ← list_nth_shared I32 ls 2#u32
+ if not (i5 = 2#i32)
then Result.fail Error.panic
else Result.ret ()
@@ -427,15 +433,15 @@ structure StructWithTuple (T1 T2 : Type) where
/- [no_nested_borrows::new_tuple1]: forward function -/
def new_tuple1 : Result (StructWithTuple U32 U32) :=
- Result.ret { p := ((U32.ofInt 1), (U32.ofInt 2)) }
+ Result.ret { p := (1#u32, 2#u32) }
/- [no_nested_borrows::new_tuple2]: forward function -/
def new_tuple2 : Result (StructWithTuple I16 I16) :=
- Result.ret { p := ((I16.ofInt 1), (I16.ofInt 2)) }
+ Result.ret { p := (1#i16, 2#i16) }
/- [no_nested_borrows::new_tuple3]: forward function -/
def new_tuple3 : Result (StructWithTuple U64 I64) :=
- Result.ret { p := ((U64.ofInt 1), (I64.ofInt 2)) }
+ Result.ret { p := (1#u64, 2#i64) }
/- [no_nested_borrows::StructWithPair] -/
structure StructWithPair (T1 T2 : Type) where
@@ -443,31 +449,31 @@ structure StructWithPair (T1 T2 : Type) where
/- [no_nested_borrows::new_pair1]: forward function -/
def new_pair1 : Result (StructWithPair U32 U32) :=
- Result.ret { p := { x := (U32.ofInt 1), y := (U32.ofInt 2) } }
+ Result.ret { p := { x := 1#u32, y := 2#u32 } }
/- [no_nested_borrows::test_constants]: forward function -/
def test_constants : Result Unit :=
do
let swt ← new_tuple1
let (i, _) := swt.p
- if not (i = (U32.ofInt 1))
+ if not (i = 1#u32)
then Result.fail Error.panic
else
do
let swt0 ← new_tuple2
let (i0, _) := swt0.p
- if not (i0 = (I16.ofInt 1))
+ if not (i0 = 1#i16)
then Result.fail Error.panic
else
do
let swt1 ← new_tuple3
let (i1, _) := swt1.p
- if not (i1 = (U64.ofInt 1))
+ if not (i1 = 1#u64)
then Result.fail Error.panic
else
do
let swp ← new_pair1
- if not (swp.p.x = (U32.ofInt 1))
+ if not (swp.p.x = 1#u32)
then Result.fail Error.panic
else Result.ret ()
@@ -484,29 +490,29 @@ def test_weird_borrows1 : Result Unit :=
/- [no_nested_borrows::test_mem_replace]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
def test_mem_replace (px : U32) : Result U32 :=
- let y := mem.replace U32 px (U32.ofInt 1)
- if not (y = (U32.ofInt 0))
+ let y := core.mem.replace U32 px 1#u32
+ if not (y = 0#u32)
then Result.fail Error.panic
- else Result.ret (U32.ofInt 2)
+ else Result.ret 2#u32
/- [no_nested_borrows::test_shared_borrow_bool1]: forward function -/
def test_shared_borrow_bool1 (b : Bool) : Result U32 :=
if b
- then Result.ret (U32.ofInt 0)
- else Result.ret (U32.ofInt 1)
+ then Result.ret 0#u32
+ else Result.ret 1#u32
/- [no_nested_borrows::test_shared_borrow_bool2]: forward function -/
def test_shared_borrow_bool2 : Result U32 :=
- Result.ret (U32.ofInt 0)
+ Result.ret 0#u32
/- [no_nested_borrows::test_shared_borrow_enum1]: forward function -/
def test_shared_borrow_enum1 (l : List U32) : Result U32 :=
match l with
- | List.Cons i l0 => Result.ret (U32.ofInt 1)
- | List.Nil => Result.ret (U32.ofInt 0)
+ | List.Cons i l0 => Result.ret 1#u32
+ | List.Nil => Result.ret 0#u32
/- [no_nested_borrows::test_shared_borrow_enum2]: forward function -/
def test_shared_borrow_enum2 : Result U32 :=
- Result.ret (U32.ofInt 0)
+ Result.ret 0#u32
end no_nested_borrows
diff --git a/tests/lean/Paper.lean b/tests/lean/Paper.lean
index c15c5e4b..ae4dd243 100644
--- a/tests/lean/Paper.lean
+++ b/tests/lean/Paper.lean
@@ -8,13 +8,13 @@ namespace paper
/- [paper::ref_incr]: merged forward/backward function
(there is a single backward function, and the forward function returns ()) -/
def ref_incr (x : I32) : Result I32 :=
- x + (I32.ofInt 1)
+ x + 1#i32
/- [paper::test_incr]: forward function -/
def test_incr : Result Unit :=
do
- let x ← ref_incr (I32.ofInt 0)
- if not (x = (I32.ofInt 1))
+ let x ← ref_incr 0#i32
+ if not (x = 1#i32)
then Result.fail Error.panic
else Result.ret ()
@@ -37,19 +37,18 @@ def choose_back
/- [paper::test_choose]: forward function -/
def test_choose : Result Unit :=
do
- let z ← choose I32 true (I32.ofInt 0) (I32.ofInt 0)
- let z0 ← z + (I32.ofInt 1)
- if not (z0 = (I32.ofInt 1))
+ let z ← choose I32 true 0#i32 0#i32
+ let z0 ← z + 1#i32
+ if not (z0 = 1#i32)
then Result.fail Error.panic
else
do
- let (x, y) ← choose_back I32 true (I32.ofInt 0) (I32.ofInt 0) z0
- if not (x = (I32.ofInt 1))
+ let (x, y) ← choose_back I32 true 0#i32 0#i32 z0
+ if not (x = 1#i32)
then Result.fail Error.panic
- else
- if not (y = (I32.ofInt 0))
- then Result.fail Error.panic
- else Result.ret ()
+ else if not (y = 0#i32)
+ then Result.fail Error.panic
+ else Result.ret ()
/- Unit test for [paper::test_choose] -/
#assert (test_choose == .ret ())
@@ -63,10 +62,10 @@ inductive List (T : Type) :=
divergent def list_nth_mut (T : Type) (l : List T) (i : U32) : Result T :=
match l with
| List.Cons x tl =>
- if i = (U32.ofInt 0)
+ if i = 0#u32
then Result.ret x
else do
- let i0 ← i - (U32.ofInt 1)
+ let i0 ← i - 1#u32
list_nth_mut T tl i0
| List.Nil => Result.fail Error.panic
@@ -75,11 +74,11 @@ divergent def list_nth_mut_back
(T : Type) (l : List T) (i : U32) (ret0 : T) : Result (List T) :=
match l with
| List.Cons x tl =>
- if i = (U32.ofInt 0)
+ if i = 0#u32
then Result.ret (List.Cons ret0 tl)
else
do
- let i0 ← i - (U32.ofInt 1)
+ let i0 ← i - 1#u32
let tl0 ← list_nth_mut_back T tl i0 ret0
Result.ret (List.Cons x tl0)
| List.Nil => Result.fail Error.panic
@@ -90,20 +89,19 @@ divergent def sum (l : List I32) : Result I32 :=
| List.Cons x tl => do
let i ← sum tl
x + i
- | List.Nil => Result.ret (I32.ofInt 0)
+ | List.Nil => Result.ret 0#i32
/- [paper::test_nth]: forward function -/
def test_nth : Result Unit :=
do
let l := List.Nil
- let l0 := List.Cons (I32.ofInt 3) l
- let l1 := List.Cons (I32.ofInt 2) l0
- let x ← list_nth_mut I32 (List.Cons (I32.ofInt 1) l1) (U32.ofInt 2)
- let x0 ← x + (I32.ofInt 1)
- let l2 ←
- list_nth_mut_back I32 (List.Cons (I32.ofInt 1) l1) (U32.ofInt 2) x0
+ let l0 := List.Cons 3#i32 l
+ let l1 := List.Cons 2#i32 l0
+ let x ← list_nth_mut I32 (List.Cons 1#i32 l1) 2#u32
+ let x0 ← x + 1#i32
+ let l2 ← list_nth_mut_back I32 (List.Cons 1#i32 l1) 2#u32 x0
let i ← sum l2
- if not (i = (I32.ofInt 7))
+ if not (i = 7#i32)
then Result.fail Error.panic
else Result.ret ()
@@ -115,7 +113,7 @@ def call_choose (p : (U32 × U32)) : Result U32 :=
do
let (px, py) := p
let pz ← choose U32 true px py
- let pz0 ← pz + (U32.ofInt 1)
+ let pz0 ← pz + 1#u32
let (px0, _) ← choose_back U32 true px py pz0
Result.ret px0
diff --git a/tests/lean/Traits.lean b/tests/lean/Traits.lean
new file mode 100644
index 00000000..12e7eafa
--- /dev/null
+++ b/tests/lean/Traits.lean
@@ -0,0 +1,383 @@
+-- THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS
+-- [traits]
+import Base
+open Primitives
+
+namespace traits
+
+/- Trait declaration: [traits::BoolTrait] -/
+structure BoolTrait (Self : Type) where
+ get_bool : Self → Result Bool
+
+/- [traits::Bool::{0}::get_bool]: forward function -/
+def Bool.get_bool (self : Bool) : Result Bool :=
+ Result.ret self
+
+/- Trait implementation: [traits::Bool::{0}] -/
+def Bool.BoolTraitInst : BoolTrait Bool := {
+ get_bool := Bool.get_bool
+}
+
+/- [traits::BoolTrait::ret_true]: forward function -/
+def BoolTrait.ret_true
+ {Self : Type} (self_clause : BoolTrait Self) (self : Self) : Result Bool :=
+ Result.ret true
+
+/- [traits::test_bool_trait_bool]: forward function -/
+def test_bool_trait_bool (x : Bool) : Result Bool :=
+ do
+ let b ← Bool.get_bool x
+ if b
+ then BoolTrait.ret_true Bool.BoolTraitInst x
+ else Result.ret false
+
+/- [traits::Option::{1}::get_bool]: forward function -/
+def Option.get_bool (T : Type) (self : Option T) : Result Bool :=
+ match self with
+ | none => Result.ret false
+ | some t => Result.ret true
+
+/- Trait implementation: [traits::Option::{1}] -/
+def Option.BoolTraitInst (T : Type) : BoolTrait (Option T) := {
+ get_bool := Option.get_bool T
+}
+
+/- [traits::test_bool_trait_option]: forward function -/
+def test_bool_trait_option (T : Type) (x : Option T) : Result Bool :=
+ do
+ let b ← Option.get_bool T x
+ if b
+ then BoolTrait.ret_true (Option.BoolTraitInst T) x
+ else Result.ret false
+
+/- [traits::test_bool_trait]: forward function -/
+def test_bool_trait (T : Type) (inst : BoolTrait T) (x : T) : Result Bool :=
+ inst.get_bool x
+
+/- Trait declaration: [traits::ToU64] -/
+structure ToU64 (Self : Type) where
+ to_u64 : Self → Result U64
+
+/- [traits::u64::{2}::to_u64]: forward function -/
+def u64.to_u64 (self : U64) : Result U64 :=
+ Result.ret self
+
+/- Trait implementation: [traits::u64::{2}] -/
+def u64.ToU64Inst : ToU64 U64 := {
+ to_u64 := u64.to_u64
+}
+
+/- [traits::Tuple2::{3}::to_u64]: forward function -/
+def Tuple2.to_u64 (A : Type) (inst : ToU64 A) (self : (A × A)) : Result U64 :=
+ do
+ let (t, t0) := self
+ let i ← inst.to_u64 t
+ let i0 ← inst.to_u64 t0
+ i + i0
+
+/- Trait implementation: [traits::Tuple2::{3}] -/
+def Tuple2.ToU64Inst (A : Type) (inst : ToU64 A) : ToU64 (A × A) := {
+ to_u64 := Tuple2.to_u64 A inst
+}
+
+/- [traits::f]: forward function -/
+def f (T : Type) (inst : ToU64 T) (x : (T × T)) : Result U64 :=
+ Tuple2.to_u64 T inst x
+
+/- [traits::g]: forward function -/
+def g (T : Type) (inst : ToU64 (T × T)) (x : (T × T)) : Result U64 :=
+ inst.to_u64 x
+
+/- [traits::h0]: forward function -/
+def h0 (x : U64) : Result U64 :=
+ u64.to_u64 x
+
+/- [traits::Wrapper] -/
+structure Wrapper (T : Type) where
+ x : T
+
+/- [traits::Wrapper::{4}::to_u64]: forward function -/
+def Wrapper.to_u64
+ (T : Type) (inst : ToU64 T) (self : Wrapper T) : Result U64 :=
+ inst.to_u64 self.x
+
+/- Trait implementation: [traits::Wrapper::{4}] -/
+def Wrapper.ToU64Inst (T : Type) (inst : ToU64 T) : ToU64 (Wrapper T) := {
+ to_u64 := Wrapper.to_u64 T inst
+}
+
+/- [traits::h1]: forward function -/
+def h1 (x : Wrapper U64) : Result U64 :=
+ Wrapper.to_u64 U64 u64.ToU64Inst x
+
+/- [traits::h2]: forward function -/
+def h2 (T : Type) (inst : ToU64 T) (x : Wrapper T) : Result U64 :=
+ Wrapper.to_u64 T inst x
+
+/- Trait declaration: [traits::ToType] -/
+structure ToType (Self T : Type) where
+ to_type : Self → Result T
+
+/- [traits::u64::{5}::to_type]: forward function -/
+def u64.to_type (self : U64) : Result Bool :=
+ Result.ret (self > 0#u64)
+
+/- Trait implementation: [traits::u64::{5}] -/
+def u64.ToTypeInst : ToType U64 Bool := {
+ to_type := u64.to_type
+}
+
+/- Trait declaration: [traits::OfType] -/
+structure OfType (Self : Type) where
+ of_type : forall (T : Type) (inst : ToType T Self), T → Result Self
+
+/- [traits::h3]: forward function -/
+def h3
+ (T1 T2 : Type) (inst : OfType T1) (inst0 : ToType T2 T1) (y : T2) :
+ Result T1
+ :=
+ inst.of_type T2 inst0 y
+
+/- Trait declaration: [traits::OfTypeBis] -/
+structure OfTypeBis (Self T : Type) where
+ parent_clause_0 : ToType T Self
+ of_type : T → Result Self
+
+/- [traits::h4]: forward function -/
+def h4
+ (T1 T2 : Type) (inst : OfTypeBis T1 T2) (inst0 : ToType T2 T1) (y : T2) :
+ Result T1
+ :=
+ inst.of_type y
+
+/- [traits::TestType] -/
+structure TestType (T : Type) where
+ _0 : T
+
+/- [traits::TestType::{6}::test::TestType1] -/
+structure TestType.test.TestType1 where
+ _0 : U64
+
+/- Trait declaration: [traits::TestType::{6}::test::TestTrait] -/
+structure TestType.test.TestTrait (Self : Type) where
+ test : Self → Result Bool
+
+/- [traits::TestType::{6}::test::TestType1::{0}::test]: forward function -/
+def TestType.test.TestType1.test
+ (self : TestType.test.TestType1) : Result Bool :=
+ Result.ret (self._0 > 1#u64)
+
+/- Trait implementation: [traits::TestType::{6}::test::TestType1::{0}] -/
+def TestType.test.TestType1.TestTypetestTestTraitInst : TestType.test.TestTrait
+ TestType.test.TestType1 := {
+ test := TestType.test.TestType1.test
+}
+
+/- [traits::TestType::{6}::test]: forward function -/
+def TestType.test
+ (T : Type) (inst : ToU64 T) (self : TestType T) (x : T) : Result Bool :=
+ do
+ let x0 ← inst.to_u64 x
+ if x0 > 0#u64
+ then TestType.test.TestType1.test { _0 := 0#u64 }
+ else Result.ret false
+
+/- [traits::BoolWrapper] -/
+structure BoolWrapper where
+ _0 : Bool
+
+/- [traits::BoolWrapper::{7}::to_type]: forward function -/
+def BoolWrapper.to_type
+ (T : Type) (inst : ToType Bool T) (self : BoolWrapper) : Result T :=
+ inst.to_type self._0
+
+/- Trait implementation: [traits::BoolWrapper::{7}] -/
+def BoolWrapper.ToTypeInst (T : Type) (inst : ToType Bool T) : ToType
+ BoolWrapper T := {
+ to_type := BoolWrapper.to_type T inst
+}
+
+/- [traits::WithConstTy::LEN2] -/
+def with_const_ty_len2_body : Result Usize := Result.ret 32#usize
+def with_const_ty_len2_c : Usize :=
+ eval_global with_const_ty_len2_body (by simp)
+
+/- Trait declaration: [traits::WithConstTy] -/
+structure WithConstTy (Self : Type) (LEN : Usize) where
+ LEN1 : Usize
+ LEN2 : Usize
+ V : Type
+ W : Type
+ W_clause_0 : ToU64 W
+ f : W → Array U8 LEN → Result W
+
+/- [traits::Bool::{8}::LEN1] -/
+def bool_len1_body : Result Usize := Result.ret 12#usize
+def bool_len1_c : Usize := eval_global bool_len1_body (by simp)
+
+/- [traits::Bool::{8}::f]: merged forward/backward function
+ (there is a single backward function, and the forward function returns ()) -/
+def Bool.f (i : U64) (a : Array U8 32#usize) : Result U64 :=
+ Result.ret i
+
+/- Trait implementation: [traits::Bool::{8}] -/
+def Bool.WithConstTyInst : WithConstTy Bool 32#usize := {
+ LEN1 := bool_len1_c
+ LEN2 := with_const_ty_len2_c
+ V := U8
+ W := U64
+ W_clause_0 := u64.ToU64Inst
+ f := Bool.f
+}
+
+/- [traits::use_with_const_ty1]: forward function -/
+def use_with_const_ty1
+ (H : Type) (LEN : Usize) (inst : WithConstTy H LEN) : Result Usize :=
+ let i := inst.LEN1
+ Result.ret i
+
+/- [traits::use_with_const_ty2]: forward function -/
+def use_with_const_ty2
+ (H : Type) (LEN : Usize) (inst : WithConstTy H LEN) (w : inst.W) :
+ Result Unit
+ :=
+ Result.ret ()
+
+/- [traits::use_with_const_ty3]: forward function -/
+def use_with_const_ty3
+ (H : Type) (LEN : Usize) (inst : WithConstTy H LEN) (x : inst.W) :
+ Result U64
+ :=
+ inst.W_clause_0.to_u64 x
+
+/- [traits::test_where1]: forward function -/
+def test_where1 (T : Type) (_x : T) : Result Unit :=
+ Result.ret ()
+
+/- [traits::test_where2]: forward function -/
+def test_where2
+ (T : Type) (inst : WithConstTy T 32#usize) (_x : U32) : Result Unit :=
+ Result.ret ()
+
+/- [alloc::string::String] -/
+axiom alloc.string.String : Type
+
+/- Trait declaration: [traits::ParentTrait0] -/
+structure ParentTrait0 (Self : Type) where
+ W : Type
+ get_name : Self → Result alloc.string.String
+ get_w : Self → Result W
+
+/- Trait declaration: [traits::ParentTrait1] -/
+structure ParentTrait1 (Self : Type) where
+
+/- Trait declaration: [traits::ChildTrait] -/
+structure ChildTrait (Self : Type) where
+ parent_clause_0 : ParentTrait0 Self
+ parent_clause_1 : ParentTrait1 Self
+
+/- [traits::test_child_trait1]: forward function -/
+def test_child_trait1
+ (T : Type) (inst : ChildTrait T) (x : T) : Result alloc.string.String :=
+ inst.parent_clause_0.get_name x
+
+/- [traits::test_child_trait2]: forward function -/
+def test_child_trait2
+ (T : Type) (inst : ChildTrait T) (x : T) : Result inst.parent_clause_0.W :=
+ inst.parent_clause_0.get_w x
+
+/- [traits::order1]: forward function -/
+def order1
+ (T U : Type) (inst : ParentTrait0 T) (inst0 : ParentTrait0 U) :
+ Result Unit
+ :=
+ Result.ret ()
+
+/- Trait declaration: [traits::ChildTrait1] -/
+structure ChildTrait1 (Self : Type) where
+ parent_clause_0 : ParentTrait1 Self
+
+/- Trait implementation: [traits::usize::{9}] -/
+def usize.ParentTrait1Inst : ParentTrait1 Usize := {
+}
+
+/- Trait implementation: [traits::usize::{10}] -/
+def usize.ChildTrait1Inst : ChildTrait1 Usize := {
+ parent_clause_0 := usize.ParentTrait1Inst
+}
+
+/- Trait declaration: [traits::Iterator] -/
+structure Iterator (Self : Type) where
+ Item : Type
+
+/- Trait declaration: [traits::IntoIterator] -/
+structure IntoIterator (Self : Type) where
+ Item : Type
+ IntoIter : Type
+ IntoIter_clause_0 : Iterator IntoIter
+ into_iter : Self → Result IntoIter
+
+/- Trait declaration: [traits::FromResidual] -/
+structure FromResidual (Self T : Type) where
+
+/- Trait declaration: [traits::Try] -/
+structure Try (Self : Type) where
+ Residual : Type
+ parent_clause_0 : FromResidual Self Residual
+
+/- Trait declaration: [traits::WithTarget] -/
+structure WithTarget (Self : Type) where
+ Target : Type
+
+/- Trait declaration: [traits::ParentTrait2] -/
+structure ParentTrait2 (Self : Type) where
+ U : Type
+ U_clause_0 : WithTarget U
+
+/- Trait declaration: [traits::ChildTrait2] -/
+structure ChildTrait2 (Self : Type) where
+ parent_clause_0 : ParentTrait2 Self
+ convert : parent_clause_0.U → Result parent_clause_0.U_clause_0.Target
+
+/- Trait implementation: [traits::u32::{11}] -/
+def u32.WithTargetInst : WithTarget U32 := {
+ Target := U32
+}
+
+/- Trait implementation: [traits::u32::{12}] -/
+def u32.ParentTrait2Inst : ParentTrait2 U32 := {
+ U := U32
+ U_clause_0 := u32.WithTargetInst
+}
+
+/- [traits::u32::{13}::convert]: forward function -/
+def u32.convert (x : U32) : Result U32 :=
+ Result.ret x
+
+/- Trait implementation: [traits::u32::{13}] -/
+def u32.ChildTrait2Inst : ChildTrait2 U32 := {
+ parent_clause_0 := u32.ParentTrait2Inst
+ convert := u32.convert
+}
+
+/- [traits::incr_u32]: forward function -/
+def incr_u32 (x : U32) : Result U32 :=
+ x + 1#u32
+
+/- Trait declaration: [traits::CFnOnce] -/
+structure CFnOnce (Self Args : Type) where
+ Output : Type
+ call_once : Self → Args → Result Output
+
+/- Trait declaration: [traits::CFnMut] -/
+structure CFnMut (Self Args : Type) where
+ parent_clause_0 : CFnOnce Self Args
+ call_mut : Self → Args → Result parent_clause_0.Output
+ call_mut_back : Self → Args → parent_clause_0.Output → Result Self
+
+/- Trait declaration: [traits::CFn] -/
+structure CFn (Self Args : Type) where
+ parent_clause_0 : CFnMut Self Args
+ call_mut : Self → Args → Result parent_clause_0.parent_clause_0.Output
+
+end traits
diff --git a/tests/lean/lakefile.lean b/tests/lean/lakefile.lean
index 8acf6973..fef94971 100644
--- a/tests/lean/lakefile.lean
+++ b/tests/lean/lakefile.lean
@@ -19,3 +19,4 @@ package «tests» {}
@[default_target] lean_lib paper
@[default_target] lean_lib poloniusList
@[default_target] lean_lib array
+@[default_target] lean_lib traits