diff options
29 files changed, 3043 insertions, 500 deletions
@@ -46,6 +46,17 @@ tests/fstar/hashmap/obj/ tests/fstar/hashmap_on_disk/obj/ tests/fstar/misc/obj/ +# Coq +*.vo +*.vok +*.vos +*.glob +*.aux +*.lia.cache +*.d +*Makefile.coq +*CoqMakefile.conf + # Misc /fstar-tests *~ @@ -34,7 +34,7 @@ AENEAS_EXE ?= bin/aeneas.exe # - unfold all the monadic let bindings to matches (required by F*) # - insert calls to the normalizer in the translated code to test the # generated unit functions -OPTIONS += -unfold-monads -test-trans-units +OPTIONS += # # The rules use (and update) the following variables @@ -43,6 +43,8 @@ OPTIONS += -unfold-monads -test-trans-units CHARON_TEST_DIR = # The options with which to call Charon CHARON_OPTIONS = +# The backend sub-directory in which to generate the files +BACKEND_SUBDIR := # The directory in which to extract the result of the translation SUBDIR := @@ -86,8 +88,8 @@ clean: tests: trans-no_nested_borrows trans-paper \ trans-hashmap trans-hashmap_main \ trans-external trans-constants \ - trans-polonius-polonius_list trans-polonius-betree_main \ - test-trans-polonius-betree_main + transp-polonius_list transp-betree_main \ + test-transp-betree_main # Verify the F* files generated by the translation .PHONY: verify @@ -106,70 +108,102 @@ CHARON_CMD = cd $(CHARON_TEST_DIR) && NOT_ALL_TESTS=1 $(MAKE) test-$* endif # The command to run Aeneas on the proper llbc file -AENEAS_CMD = $(AENEAS_EXE) $(CHARON_TEST_DIR)/llbc/$(FILE).llbc -dest tests/fstar/$(SUBDIR) $(OPTIONS) +AENEAS_CMD = $(AENEAS_EXE) $(CHARON_TEST_DIR)/llbc/$(FILE).llbc -dest tests/$(BACKEND_SUBDIR)/$(SUBDIR) $(OPTIONS) # Add specific options to some tests trans-no_nested_borrows trans-paper: \ - OPTIONS += -test-units -test-trans-units -no-split-files -no-state -no-decreases-clauses + OPTIONS += -test-units -test-trans-units -no-split-files -no-state trans-no_nested_borrows trans-paper: SUBDIR:=misc +tfstar-no_nested_borrows tfstar-paper: -trans-hashmap: OPTIONS += -template-clauses -no-state +trans-hashmap: OPTIONS += -no-state trans-hashmap: SUBDIR:=hashmap +tfstar-hashmap: OPTIONS += -decreases-clauses -template-clauses -trans-hashmap_main: OPTIONS += -template-clauses +trans-hashmap_main: OPTIONS += trans-hashmap_main: SUBDIR:=hashmap_on_disk +tfstar-hashmap_main: OPTIONS += -decreases-clauses -template-clauses -trans-polonius-polonius_list: OPTIONS += -test-units -test-trans-units -no-split-files -no-state -no-decreases-clauses -trans-polonius-polonius_list: SUBDIR:=misc +transp-polonius_list: OPTIONS += -test-units -test-trans-units -no-split-files -no-state +transp-polonius_list: SUBDIR:=misc +tfstarp-polonius_list: OPTIONS += -trans-constants: OPTIONS += -test-units -test-trans-units -no-split-files -no-state -no-decreases-clauses +trans-constants: OPTIONS += -test-units -test-trans-units -no-split-files -no-state trans-constants: SUBDIR:=misc +tfstar-constants: OPTIONS += trans-external: OPTIONS += trans-external: SUBDIR:=misc +tfstar-external: OPTIONS += -BETREE_OPTIONS = -template-clauses -trans-polonius-betree_main: OPTIONS += $(BETREE_OPTIONS) -backward-no-state-update -trans-polonius-betree_main: SUBDIR:=betree +BETREE_FSTAR_OPTIONS = -decreases-clauses -template-clauses +transp-betree_main: OPTIONS += -backward-no-state-update +transp-betree_main: SUBDIR:=betree +tfstarp-betree_main: OPTIONS += $(BETREE_FSTAR_OPTIONS) # Additional test on the betree: translate it without `-backward-no-state-update`. # This generates very ugly code, but is good to test the translation. -test-trans-polonius-betree_main: trans-polonius-betree_main -test-trans-polonius-betree_main: OPTIONS += $(BETREE_OPTIONS) -test-trans-polonius-betree_main: SUBDIR:=betree_back_stateful -test-trans-polonius-betree_main: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR) -test-trans-polonius-betree_main: FILE = betree_main -test-trans-polonius-betree_main: +.PHONY: test-transp-betree_main +test-transp-betree_main: transp-betree_main +test-transp-betree_main: OPTIONS += -backend fstar -unfold-monads -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: $(AENEAS_CMD) # Generic rules to extract the LLBC from a rust file # We use the rules in Charon's Makefile to generate the .llbc files: the options # vary with the test files. -.PHONY: gen-llbc-polonius-% -gen-llbc-polonius-%: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR) -gen-llbc-polonius-%: - $(CHARON_CMD) - .PHONY: gen-llbc-% gen-llbc-%: CHARON_TEST_DIR = $(CHARON_TESTS_REGULAR_DIR) gen-llbc-%: $(CHARON_CMD) -# Generic rule to test the translation of an LLBC file. +# "p" stands for "Polonius" +.PHONY: gen-llbcp-% +gen-llbcp-%: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR) +gen-llbcp-%: + $(CHARON_CMD) + +# Generic rules to test the translation of an LLBC file. # Note that the files requiring the Polonius borrow-checker are generated # in the tests-polonius subdirectory. .PHONY: trans-% -trans-%: -trans-polonius-%: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR) trans-%: CHARON_TEST_DIR = $(CHARON_TESTS_REGULAR_DIR) +trans-%: FILE = $* +trans-%: gen-llbc-% tfstar-% tcoq-% + echo "# Test $* done" + +# "p" stands for "Polonius" +.PHONY: transp-% +transp-%: CHARON_TEST_DIR = $(CHARON_TESTS_POLONIUS_DIR) +transp-%: FILE = $* +transp-%: gen-llbcp-% tfstarp-% + echo "# Test $* done" + +.PHONY: tfstar-% +tfstar-%: OPTIONS += -backend fstar -unfold-monads -test-trans-units +tfstar-%: BACKEND_SUBDIR := fstar +tfstar-%: + $(AENEAS_CMD) -trans-polonius-%: FILE = $* -trans-polonius-%: gen-llbc-polonius-% +# "p" stands for "Polonius" +.PHONY: tfstarp-% +tfstarp-%: OPTIONS += -backend fstar -unfold-monads -test-trans-units +tfstarp-%: BACKEND_SUBDIR := fstar +tfstarp-%: $(AENEAS_CMD) -trans-%: FILE = $* -trans-%: gen-llbc-% +# TODO: -test-trans-units +# It doesn't work on vec_push_fwd, I don't understand why. +.PHONY: tcoq-% +tcoq-%: OPTIONS += -backend coq -decompose-monads +tcoq-%: BACKEND_SUBDIR := coq +tcoq-%: $(AENEAS_CMD) # Nix diff --git a/backends/coq/Primitives.v b/backends/coq/Primitives.v new file mode 100644 index 00000000..c27b8aed --- /dev/null +++ b/backends/coq/Primitives.v @@ -0,0 +1,478 @@ +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 result A := + | Return : A -> result A + | Fail_ : result A. + +Arguments Return {_} a. +Arguments Fail_ {_}. + +Definition bind {A B} (m: result A) (f: A -> result B) : result B := + match m with + | Fail_ => Fail_ + | Return x => f x + end. + +Definition return_ {A: Type} (x: A) : result A := Return x . +Definition fail_ {A: Type} : result A := Fail_ . + +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_. + +(** 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_ => fun p' => + False_rect _ (eq_ind Fail_ + (fun e : result A => + match e with + | Return _ => False + | Fail_ => 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_)%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 . + +(*** 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_ + 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_ 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 *) +Print Z.leb . + +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. + +(*** Vectors *) + +Definition 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 vec_length {T: Type} (v: vec T) : Z := Z.of_nat (length (vec_to_list v)). + +Lemma le_0_usize_max : 0 <= usize_max. +Proof. + pose (H := usize_max_bound). + unfold u32_max in H. + lia. +Qed. + +Definition vec_new (T: Type) : vec T := (exist _ [] le_0_usize_max). + +Lemma vec_len_in_usize {T} (v: vec T) : usize_min <= vec_length v <= usize_max. +Proof. + unfold 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). + +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 vec_bind {A B} (v: vec A) (f: list A -> result (list B)) : result (vec B) := + l <- f (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_ + end. + +(* The **forward** function shouldn't be used *) +Definition vec_push_fwd (T: Type) (v: 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])). + +(* 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_. + +Definition vec_insert_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_). + +(* 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_ + 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_. + +(* 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_ + 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_). + +End Primitives. diff --git a/compiler/Config.ml b/compiler/Config.ml index c9723bd4..95442761 100644 --- a/compiler/Config.ml +++ b/compiler/Config.ml @@ -1,5 +1,33 @@ (** Define the global configuration options *) +(** {1 Backend choice} *) + +(** The choice of backend *) +type backend = FStar | Coq + +let backend_names = [ "fstar"; "coq" ] + +(** Utility to compute the backend from an input parameter *) +let backend_of_string (b : string) : backend option = + match b with "fstar" -> Some FStar | "coq" -> Some Coq | _ -> None + +let opt_backend : backend option ref = ref None + +let set_backend (b : string) : unit = + match backend_of_string b with + | Some b -> opt_backend := Some b + | None -> + (* We shouldn't get there: the string should have been checked as + belonging to the proper set *) + raise (Failure "Unexpected") + +(** The backend to which to extract. + + We initialize it with a default value, but it always gets overwritten: + we check that the user provides a backend argument. + *) +let backend = ref FStar + (** {1 Interpreter} *) (** Check that invariants are maintained whenever we execute a statement *) @@ -44,6 +72,39 @@ let allow_bottom_below_borrow = true *) let return_unit_end_abs_with_no_loans = true +(** Forbids using field projectors for structures. + + If we don't use field projectors, whenever we symbolically expand a structure + value (note that accessing a structure field in the symbolic execution triggers + its expansion), then instead of generating code like this: + {[ + let x1 = s.f1 in + let x2 = s.f2 in + ... + ]} + + we generate code like this: + {[ + let Mkstruct x1 x2 ... = s in + ... + ]} + + We use this for instance for Coq, because in Coq we can't define groups + of mutually recursive records and inductives. In such cases, we extract + the structures as inductives, which means that field projectors are not + always available. + + TODO: we could define a notation to take care of this. + TODO: today dont_use_field_projectors is not useful actually. + *) +let dont_use_field_projectors = ref false + +(** Deconstructing ADTs which have only one variant with let-bindings is not always + supported: this parameter controls whether we use let-bindings in such situations or not. + *) + +let always_deconstruct_adts_with_matches = ref false + (** {1 Translation} *) (** Controls whether we need to use a state to model the external world @@ -103,7 +164,7 @@ let test_trans_unit_functions = ref false The body of such clauses must be defined by the user. *) -let extract_decreases_clauses = ref true +let extract_decreases_clauses = ref false (** In order to help the user, we can generate "template" decrease clauses (i.e., definitions with proper signatures but dummy bodies) in a @@ -113,10 +174,10 @@ let extract_template_decreases_clauses = ref false (** {1 Micro passes} *) -(** Some provers like F* don't support the decomposition of return values +(** Some provers like F* and Coq don't support the decomposition of return values in monadic let-bindings: {[ - // NOT supported in F* + (* NOT supported in F*/Coq *) let (x, y) <-- f (); ... ]} diff --git a/compiler/Driver.ml b/compiler/Driver.ml index 3059ec2f..5089cb8e 100644 --- a/compiler/Driver.ml +++ b/compiler/Driver.ml @@ -33,6 +33,9 @@ let () = let spec = [ + ( "-backend", + Arg.Symbol (backend_names, set_backend), + " Specify the backend to which to extract" ); ("-dest", Arg.Set_string dest_dir, " Specify the output directory"); ( "-decompose-monads", Arg.Set decompose_monadic_let_bindings, @@ -61,9 +64,9 @@ let () = Arg.Set test_trans_unit_functions, " Test the translated unit functions with the target theorem\n\ \ prover's normalizer" ); - ( "-no-decreases-clauses", - Arg.Clear extract_decreases_clauses, - " Do not add decrease clauses to the recursive definitions" ); + ( "-decreases-clauses", + Arg.Set extract_decreases_clauses, + " Use decreases clauses for the recursive definitions" ); ( "-no-state", Arg.Clear use_state, " Do not use state-error monads, simply use error monads" ); @@ -73,8 +76,8 @@ let () = ( "-template-clauses", Arg.Set extract_template_decreases_clauses, " Generate templates for the required decreases clauses, in a\n\ - \ dedicated file. Incompatible with \ - -no-decreases-clauses" ); + \ dedicated file. Reauires -decreases-clauses" + ); ( "-no-split-files", Arg.Clear split_files, " Don't split the definitions between different files for types,\n\ @@ -98,6 +101,29 @@ let () = print_string usage; exit 1 in + + (* Check that the user specified a backend *) + let _ = + match !opt_backend with + | Some b -> backend := b + | None -> + print_string "Backend not specified (use the `-backend` argument)\n"; + fail () + in + + (* In the case of Coq, we forbid using field projectors (see the comments for + [dont_use_field_projectors]). + Also, we always decompose ADT values with matches (decomposing with + let-bindings is not supported). + *) + let _ = + match !backend with + | FStar -> () + | Coq -> + dont_use_field_projectors := true; + always_deconstruct_adts_with_matches := true + in + (* Retrieve and check the filename *) let filename = match !filenames with diff --git a/compiler/ExtractToBackend.ml b/compiler/Extract.ml index fc04ce90..f9c4d10a 100644 --- a/compiler/ExtractToBackend.ml +++ b/compiler/Extract.ml @@ -1,41 +1,19 @@ -(** Extract to F* *) +(** The generic extraction *) +(* Turn the whole module into a functor: it is very annoying to carry the + the formatter everywhere... +*) open Utils open Pure open PureUtils open TranslateCore -open PureToExtract +open ExtractBase open StringUtils +open Config module F = Format -(** A qualifier for a type definition. - - Controls whether we should use [type ...] or [and ...] (for mutually - recursive datatypes). - *) -type type_decl_qualif = - | Type (** [type t = ...] *) - | And (** [type t0 = ... and t1 = ...] *) - | AssumeType (** [assume type t] *) - | TypeVal (** In an fsti: [val t : Type0] *) - -(** A qualifier for function definitions. - - Controls whether we should use [let ...], [let rec ...] or [and ...], - or only generate a declaration with [val] or [assume val] - *) -type fun_decl_qualif = Let | LetRec | And | Val | AssumeVal - -let fun_decl_qualif_keyword (qualif : fun_decl_qualif) : string = - match qualif with - | Let -> "let" - | LetRec -> "let rec" - | And -> "and" - | Val -> "val" - | AssumeVal -> "assume val" - (** Small helper to compute the name of an int type *) -let fstar_int_name (int_ty : integer_type) = +let int_name (int_ty : integer_type) = match int_ty with | Isize -> "isize" | I8 -> "i8" @@ -51,17 +29,17 @@ let fstar_int_name (int_ty : integer_type) = | U128 -> "u128" (** Small helper to compute the name of a unary operation *) -let fstar_unop_name (unop : unop) : string = +let unop_name (unop : unop) : string = match unop with - | Not -> "not" - | Neg int_ty -> fstar_int_name int_ty ^ "_neg" + | Not -> ( match !backend with FStar -> "not" | Coq -> "negb") + | Neg int_ty -> int_name int_ty ^ "_neg" | Cast _ -> 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 fstar_named_binop_name (binop : E.binop) (int_ty : integer_type) : string = +let named_binop_name (binop : E.binop) (int_ty : integer_type) : string = let binop = match binop with | Div -> "div" @@ -71,64 +49,105 @@ let fstar_named_binop_name (binop : E.binop) (int_ty : integer_type) : string = | Mul -> "mul" | _ -> raise (Failure "Unreachable") in - fstar_int_name int_ty ^ "_" ^ binop + int_name int_ty ^ "_" ^ binop -(** A list of keywords/identifiers used in F* and with which we want to check - collision. *) -let fstar_keywords = +(** A list of keywords/identifiers used by the backend and with which we + want to check collision. *) +let keywords () = let named_unops = - fstar_unop_name Not - :: List.map (fun it -> fstar_unop_name (Neg it)) T.all_signed_int_types + 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 (List.map - (fun bn -> - List.map (fun it -> fstar_named_binop_name bn it) T.all_int_types) + (fun bn -> List.map (fun it -> named_binop_name bn it) T.all_int_types) named_binops) in let misc = - [ - "let"; - "rec"; - "in"; - "fn"; - "val"; - "int"; - "nat"; - "list"; - "FStar"; - "FStar.Mul"; - "type"; - "match"; - "with"; - "assert"; - "assert_norm"; - "assume"; - "Type0"; - "Type"; - "unit"; - "not"; - "scalar_cast"; - ] + match !backend with + | FStar -> + [ + "let"; + "rec"; + "in"; + "fun"; + "fn"; + "val"; + "int"; + "nat"; + "list"; + "FStar"; + "FStar.Mul"; + "type"; + "match"; + "with"; + "assert"; + "assert_norm"; + "assume"; + "Type0"; + "Type"; + "unit"; + "not"; + "scalar_cast"; + ] + | Coq -> + [ + "Record"; + "Inductive"; + "Fixpoint"; + "Definition"; + "Arguments"; + "Notation"; + "Check"; + "Search"; + "SearchPattern"; + "Axiom"; + "Type"; + "Set"; + "let"; + "rec"; + "in"; + "unit"; + "fun"; + "type"; + "int"; + "nat"; + "match"; + "with"; + "assert"; + "not"; + (* [tt] is unit *) + "tt"; + "char_of_byte"; + ] in List.concat [ named_unops; named_binops; misc ] -let fstar_assumed_adts : (assumed_ty * string) list = +let assumed_adts : (assumed_ty * string) list = [ (State, "state"); (Result, "result"); (Option, "option"); (Vec, "vec") ] -let fstar_assumed_structs : (assumed_ty * string) list = [] - -let fstar_assumed_variants : (assumed_ty * VariantId.id * string) list = - [ - (Result, result_return_id, "Return"); - (Result, result_fail_id, "Fail"); - (Option, option_some_id, "Some"); - (Option, option_none_id, "None"); - ] - -let fstar_assumed_llbc_functions : +let assumed_structs : (assumed_ty * string) list = [] + +let assumed_variants () : (assumed_ty * VariantId.id * string) list = + match !backend with + | FStar -> + [ + (Result, result_return_id, "Return"); + (Result, result_fail_id, "Fail"); + (Option, option_some_id, "Some"); + (Option, option_none_id, "None"); + ] + | Coq -> + [ + (Result, result_return_id, "Return"); + (Result, result_fail_id, "Fail_"); + (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 [ @@ -146,25 +165,27 @@ let fstar_assumed_llbc_functions : (VecIndexMut, rg0, "vec_index_mut_back"); ] -let fstar_assumed_pure_functions : (pure_assumed_fun_id * string) list = - [ (Return, "return"); (Fail, "fail"); (Assert, "massert") ] +let assumed_pure_functions : (pure_assumed_fun_id * string) list = + match !backend with + | FStar -> [ (Return, "return"); (Fail, "fail"); (Assert, "massert") ] + | Coq -> [ (Return, "return_"); (Fail, "fail_"); (Assert, "massert") ] -let fstar_names_map_init : names_map_init = +let names_map_init () : names_map_init = { - keywords = fstar_keywords; - assumed_adts = fstar_assumed_adts; - assumed_structs = fstar_assumed_structs; - assumed_variants = fstar_assumed_variants; - assumed_llbc_functions = fstar_assumed_llbc_functions; - assumed_pure_functions = fstar_assumed_pure_functions; + keywords = keywords (); + assumed_adts; + assumed_structs; + assumed_variants = assumed_variants (); + assumed_llbc_functions; + assumed_pure_functions; } -let fstar_extract_unop (extract_expr : bool -> texpression -> unit) +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 = fstar_unop_name unop in + 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 (); @@ -186,7 +207,7 @@ let fstar_extract_unop (extract_expr : bool -> texpression -> unit) extract_expr true arg; if inside then F.pp_print_string fmt ")" -let fstar_extract_binop (extract_expr : bool -> texpression -> unit) +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 "("; @@ -203,13 +224,14 @@ let fstar_extract_binop (extract_expr : bool -> texpression -> unit) | Gt -> ">" | _ -> raise (Failure "Unreachable") in + let binop = match !backend with FStar -> 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 | Div | Rem | Add | Sub | Mul -> - let binop = fstar_named_binop_name binop int_ty in + let binop = named_binop_name binop int_ty in F.pp_print_string fmt binop; F.pp_print_space fmt (); extract_expr false arg0; @@ -218,6 +240,52 @@ let fstar_extract_binop (extract_expr : bool -> texpression -> unit) | 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 = + match !backend with + | FStar -> ( + match kind with + | SingleNonRec -> "type" + | SingleRec -> "type" + | MutRecFirst -> "type" + | MutRecInner -> "and" + | MutRecLast -> "and" + | Assumed -> "assume type" + | Declared -> "val") + | Coq -> ( + match (kind, type_kind) with + | SingleNonRec, Some Enum -> "Inductive" + | SingleNonRec, Some Struct -> "Record" + | (SingleRec | MutRecFirst), 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 + *) + "with" + | (Assumed | Declared), None -> "Axiom" + | _ -> raise (Failure "Unexpected")) + +let fun_decl_kind_to_qualif (kind : decl_kind) = + match !backend with + | FStar -> ( + match kind with + | SingleNonRec -> "let" + | SingleRec -> "let rec" + | MutRecFirst -> "let rec" + | MutRecInner -> "and" + | MutRecLast -> "and" + | Assumed -> "assume val" + | Declared -> "val") + | Coq -> ( + match kind with + | SingleNonRec -> "Definition" + | SingleRec -> "Fixpoint" + | MutRecFirst -> "Fixpoint" + | MutRecInner -> "with" + | MutRecLast -> "with" + | Assumed -> "Axiom" + | Declared -> "Axiom") + (** [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 @@ -256,7 +324,7 @@ let fstar_extract_binop (extract_expr : bool -> texpression -> unit) *) let mk_formatter (ctx : trans_ctx) (crate_name : string) (variant_concatenate_type_name : bool) : formatter = - let int_name = fstar_int_name in + let int_name = int_name in (* Prepare a name. * The first id elem is always the crate: if it is the local crate, @@ -291,7 +359,8 @@ let mk_formatter (ctx : trans_ctx) (crate_name : string) let type_name_to_snake_case name = let name = get_type_name name in let name = List.map to_snake_case name in - String.concat "_" name + let name = String.concat "_" name in + match !backend with FStar -> name | Coq -> capitalize_first_letter name in let type_name name = type_name_to_snake_case name ^ "_t" in let field_name (def_name : name) (field_id : FieldId.id) @@ -309,7 +378,8 @@ let mk_formatter (ctx : trans_ctx) (crate_name : string) in let struct_constructor (basename : name) : string = let tname = type_name basename in - "Mk" ^ tname + let prefix = match !backend with FStar -> "Mk" | Coq -> "mk" in + prefix ^ tname in let get_fun_name = get_name in let fun_name_to_snake_case (fname : fun_name) : string = @@ -381,7 +451,11 @@ let mk_formatter (ctx : trans_ctx) (crate_name : string) assert (List.length cl > 0); let cl = List.map (fun s -> s.[0]) cl in StringUtils.string_of_chars cl) - | TypeVar _ -> "x" (* lacking imagination here... *) + | TypeVar _ -> ( + (* TODO: use "t" also for F* *) + match !backend with + | FStar -> "x" (* lacking inspiration here... *) + | Coq -> "t" (* lacking inspiration here... *)) | Bool -> "b" | Char -> "c" | Integer _ -> "i" @@ -390,22 +464,51 @@ let mk_formatter (ctx : trans_ctx) (crate_name : string) | Array _ | Slice _ -> raise Unimplemented) in let type_var_basename (_varset : StringSet.t) (basename : string) : string = - (* This is *not* a no-op: type variables in Rust often start with - * a capital letter *) - to_snake_case basename + (* 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 + | Coq -> basename in let append_index (basename : string) (i : int) : string = basename ^ string_of_int i in - let extract_primitive_value (fmt : F.formatter) (_inside : bool) + let extract_primitive_value (fmt : F.formatter) (inside : bool) (cv : primitive_value) : unit = match cv with - | Scalar sv -> F.pp_print_string fmt (Z.to_string sv.PV.value) + | Scalar sv -> ( + match !backend with + | FStar -> F.pp_print_string fmt (Z.to_string sv.PV.value) + | Coq -> + if inside then F.pp_print_string fmt "("; + (* 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 ^ ")"); + F.pp_print_space fmt (); + F.pp_print_string fmt ("%" ^ int_name sv.PV.int_ty); + if inside then F.pp_print_string fmt ")") | Bool b -> let b = if b then "true" else "false" in F.pp_print_string fmt b - | Char c -> F.pp_print_string fmt ("'" ^ String.make 1 c ^ "'") + | Char c -> ( + match !backend with + | FStar -> 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 ")") | String s -> (* We need to replace all the line breaks *) let s = @@ -420,6 +523,8 @@ let mk_formatter (ctx : trans_ctx) (crate_name : string) char_name = "char"; int_name; str_name = "string"; + type_decl_kind_to_qualif; + fun_decl_kind_to_qualif; field_name; variant_name; struct_constructor; @@ -431,10 +536,22 @@ let mk_formatter (ctx : trans_ctx) (crate_name : string) type_var_basename; append_index; extract_primitive_value; - extract_unop = fstar_extract_unop; - extract_binop = fstar_extract_binop; + 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) + +(** In Coq, a group of definitions must be ended with a "." *) +let print_decl_end_delimiter (fmt : F.formatter) (kind : decl_kind) = + if !backend = Coq && decl_is_last_from_group kind then ( + F.pp_print_space fmt (); + F.pp_print_string fmt ".") + (** [inside] constrols whether we should add parentheses or not around type applications (if [true] we add parentheses). *) @@ -444,7 +561,7 @@ let rec extract_ty (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) | Adt (type_id, tys) -> ( match type_id with | Tuple -> - (* This is a bit annoying, but in F* [()] is not the unit type: + (* This is a bit annoying, but in F*/Coq [()] is not the unit type: * we have to write [unit]... *) if tys = [] then F.pp_print_string fmt "unit" else ( @@ -452,7 +569,8 @@ let rec extract_ty (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) Collections.List.iter_link (fun () -> F.pp_print_space fmt (); - F.pp_print_string fmt "&"; + let product = match !backend with FStar -> "&" | Coq -> "*" in + F.pp_print_string fmt product; F.pp_print_space fmt ()) (extract_ty ctx fmt true) tys; F.pp_print_string fmt ")") @@ -516,68 +634,73 @@ let extract_type_decl_register_names (ctx : extraction_ctx) (def : type_decl) : (* Return *) ctx -let extract_type_decl_struct_body (ctx : extraction_ctx) (fmt : F.formatter) - (def : type_decl) (fields : field list) : unit = - (* We want to generate a definition which looks like this: - {[ - 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* ). - *) - (* Note that we already printed: [type t =] *) - if fields = [] then ( - F.pp_print_space fmt (); - F.pp_print_string fmt "unit") - else ( - F.pp_print_space fmt (); - F.pp_print_string fmt "{"; - F.pp_print_break fmt 1 ctx.indent_incr; - (* The body itself *) - F.pp_open_hvbox 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 - 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 false f.field_ty; - F.pp_print_string fmt ";"; - F.pp_close_box fmt () +(** Print the variants *) +let extract_type_decl_variant (ctx : extraction_ctx) (fmt : F.formatter) + (type_name : string) (type_params : string list) (cons_name : string) + (fields : field list) : unit = + F.pp_print_space fmt (); + F.pp_open_hvbox fmt ctx.indent_incr; + (* variant box *) + (* [| Cons :] + * Note that we really don't want any break above so we print everything + * at once. *) + F.pp_print_string fmt ("| " ^ cons_name ^ " :"); + F.pp_print_space fmt (); + let print_field (fid : FieldId.id) (f : field) (ctx : extraction_ctx) : + extraction_ctx = + (* Open the field box *) + F.pp_open_box fmt ctx.indent_incr; + (* Print the field names + * [ 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 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 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 *) + (* Print the field type *) + extract_ty ctx fmt false f.field_ty; + (* Print the arrow [->]*) + F.pp_print_space fmt (); + F.pp_print_string fmt "->"; + (* Close the field box *) F.pp_close_box fmt (); F.pp_print_space fmt (); - F.pp_print_string 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 + (* Print the final type *) + F.pp_open_hovbox fmt 0; + F.pp_print_string fmt type_name; + List.iter + (fun type_param -> + F.pp_print_space fmt (); + F.pp_print_string fmt type_param) + type_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) (def : type_decl) (def_name : string) (type_params : string list) (variants : variant list) : unit = - (* We want to generate a definition which looks like this: + (* 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 ]} @@ -609,70 +732,104 @@ let extract_type_decl_enum_body (ctx : extraction_ctx) (fmt : F.formatter) Note that we already printed: [type s =] *) + let print_variant variant_id v = + let cons_name = ctx_get_variant (AdtId def.def_id) variant_id ctx in + let fields = v.fields in + extract_type_decl_variant ctx fmt def_name type_params cons_name fields + in (* Print the variants *) - let print_variant (variant_id : VariantId.id) (variant : variant) : unit = - let variant_name = ctx_get_variant (AdtId def.def_id) variant_id ctx in - F.pp_print_space fmt (); - F.pp_open_hvbox fmt ctx.indent_incr; - (* variant box *) - (* [| Cons :] - * Note that we really don't want any break above so we print everything - * at once. *) - F.pp_print_string fmt ("| " ^ variant_name ^ " :"); + 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) + (kind : decl_kind) (def : type_decl) (type_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). + *) + (* Note that we already printed: [type t =] *) + let is_rec = decl_is_from_rec_group kind in + (* If Coq: print the constructor name *) + if !backend = Coq && not is_rec then ( F.pp_print_space fmt (); - let print_field (fid : FieldId.id) (f : field) (ctx : extraction_ctx) : - extraction_ctx = - (* Open the field box *) - F.pp_open_box fmt ctx.indent_incr; - (* Print the field names - * [ 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 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 - in - (* Print the field type *) - extract_ty ctx fmt false f.field_ty; - (* Print the arrow [->]*) + F.pp_print_string fmt (ctx_get_struct (AdtId def.def_id) ctx)); + let _ = + if !backend = FStar && fields = [] then ( F.pp_print_space fmt (); - F.pp_print_string fmt "->"; - (* Close the field box *) - F.pp_close_box fmt (); + F.pp_print_string fmt "unit") + else if (not is_rec) || !backend = FStar then ( F.pp_print_space fmt (); - (* Return *) - ctx - in - (* Print the fields *) - let fields = FieldId.mapi (fun fid f -> (fid, f)) variant.fields in - let _ = - List.fold_left (fun ctx (fid, f) -> print_field fid f ctx) ctx fields - in - (* Print the final type *) - F.pp_open_hovbox fmt 0; - F.pp_print_string fmt def_name; - List.iter - (fun type_param -> + F.pp_print_string fmt "{"; + F.pp_print_break fmt 1 ctx.indent_incr; + (* The body itself *) + F.pp_open_hvbox 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 + 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 type_param) - type_params; - F.pp_close_box fmt (); - (* Close the variant box *) - F.pp_close_box fmt () + F.pp_print_string fmt ":"; + F.pp_print_space fmt (); + extract_ty ctx fmt false f.field_ty; + F.pp_print_string fmt ";"; + 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 *) + F.pp_close_box fmt (); + F.pp_print_space fmt (); + F.pp_print_string fmt "}") + else ( + (* We extract for Coq, 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); + let cons_name = 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 def_name type_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 + () (** Extract a type declaration. @@ -680,7 +837,27 @@ let extract_type_decl_enum_body (ctx : extraction_ctx) (fmt : F.formatter) registered. *) let extract_type_decl (ctx : extraction_ctx) (fmt : F.formatter) - (qualif : type_decl_qualif) (def : type_decl) : unit = + (kind : decl_kind) (def : type_decl) : unit = + let extract_body = + match kind with + | SingleNonRec | SingleRec | MutRecFirst | MutRecInner | MutRecLast -> true + | Assumed | Declared -> false + in + 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), ... -> ... -> ...]. + + The boolean [is_opaque_coq] is used to detect this case. + *) + let is_opaque_coq = !backend = Coq && type_kind = None in + let use_forall = is_opaque_coq && def.type_params <> [] in (* Retrieve the definition name *) let def_name = ctx_get_local_type def.def_id ctx in (* Add the type params - note that we need those bindings only for the @@ -697,16 +874,16 @@ let extract_type_decl (ctx : extraction_ctx) (fmt : F.formatter) (* Open a box for "type TYPE_NAME (TYPE_PARAMS) =" *) F.pp_open_hovbox fmt ctx.indent_incr; (* > "type TYPE_NAME" *) - let extract_body, qualif = - match qualif with - | Type -> (true, "type") - | And -> (true, "and") - | AssumeType -> (false, "assume type") - | TypeVal -> (false, "val") - in + let qualif = ctx.fmt.type_decl_kind_to_qualif kind type_kind in F.pp_print_string fmt (qualif ^ " " ^ def_name); (* Print the type parameters *) + let type_keyword = match !backend with FStar -> "Type0" | Coq -> "Type" in if def.type_params <> [] 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"); F.pp_print_space fmt (); F.pp_print_string fmt "("; List.iter @@ -717,34 +894,117 @@ let extract_type_decl (ctx : extraction_ctx) (fmt : F.formatter) def.type_params; F.pp_print_string fmt ":"; F.pp_print_space fmt (); - F.pp_print_string fmt "Type0)"); + F.pp_print_string fmt (type_keyword ^ ")")); (* Print the "=" if we extract the body*) if extract_body then ( F.pp_print_space fmt (); - F.pp_print_string fmt "=") + let eq = match !backend with FStar -> "=" | Coq -> ":=" in + F.pp_print_string fmt eq) else ( (* Otherwise print ": Type0" *) + 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 ":"; - F.pp_print_space fmt (); - F.pp_print_string fmt "Type0"); + 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 def fields + | Struct fields -> + extract_type_decl_struct_body ctx_body fmt kind def type_params fields | Enum variants -> extract_type_decl_enum_body ctx_body fmt def def_name type_params variants | Opaque -> raise (Failure "Unreachable")); + (* If Coq: end the definition with a "." *) + print_decl_end_delimiter fmt kind; (* 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 +(** Extract extra information for a type (e.g., [Arguments] information 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 -> () + | Coq -> ( + (* 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 = ctx_add_type_params decl.type_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_type_vars () = + List.iter + (fun (var : string) -> + F.pp_print_string fmt ("{" ^ var ^ "}"); + F.pp_print_space fmt ()) + type_params + in + let print_fields () = + List.iter + (fun _ -> + F.pp_print_string fmt "_"; + F.pp_print_space 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; + F.pp_print_space fmt (); + print_type_vars (); + print_fields (); + F.pp_print_space fmt (); + 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 cons_name = ctx_get_struct 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) + (** Extract the state type declaration. *) let extract_state_type (fmt : F.formatter) (ctx : extraction_ctx) - (qualif : type_decl_qualif) : unit = + (kind : decl_kind) : unit = (* Add a break before *) F.pp_print_break fmt 0 0; (* Print a comment *) @@ -755,27 +1015,48 @@ let extract_state_type (fmt : F.formatter) (ctx : extraction_ctx) F.pp_open_hvbox fmt 0; (* Retrieve the name *) let state_name = ctx_get_assumed_type State ctx in - (* The qualif should be [AssumeType] or [TypeVal] *) - (match qualif with - | Type | And -> raise (Failure "Unexpected") - | AssumeType -> - 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" - | TypeVal -> - 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"); + (* 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" + | Coq -> + 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.") + | 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" + | Coq -> + 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.")); (* Close the box for the definition *) F.pp_close_box fmt (); (* Add breaks to insert new lines between definitions *) @@ -813,7 +1094,8 @@ let extract_global_decl_register_names (ctx : extraction_ctx) Note that patterns can introduce new variables: we thus return an extraction context updated with new bindings. - TODO: we don't need something very generic anymore + TODO: we don't need something very generic anymore (some definitions used + to be polymorphic). *) let extract_adt_g_value (extract_value : extraction_ctx -> bool -> 'v -> extraction_ctx) @@ -823,17 +1105,23 @@ let extract_adt_g_value match ty with | Adt (Tuple, _) -> (* Tuple *) - F.pp_print_string fmt "("; - let ctx = - Collections.List.fold_left_link - (fun () -> - F.pp_print_string fmt ","; - F.pp_print_space fmt ()) - (fun ctx v -> extract_value ctx false v) - ctx field_values - in - F.pp_print_string fmt ")"; - ctx + (* 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 ( + F.pp_print_string fmt "tt"; + ctx) + else ( + F.pp_print_string fmt "("; + let ctx = + Collections.List.fold_left_link + (fun () -> + F.pp_print_string fmt ","; + F.pp_print_space fmt ()) + (fun ctx v -> extract_value ctx false v) + ctx field_values + in + F.pp_print_string fmt ")"; + ctx) | Adt (adt_id, _) -> (* "Regular" ADT *) (* We print something of the form: [Cons field0 ... fieldn]. @@ -1014,15 +1302,19 @@ and extract_adt_cons (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) | Tuple -> (* Tuple *) (* For now, we only support fully applied tuple constructors *) + (* This is very annoying: in Coq, we can't write [()] for the value of + type [unit], we have to write [tt]. *) assert (List.length type_args = List.length args); - F.pp_print_string fmt "("; - Collections.List.iter_link - (fun () -> - F.pp_print_string fmt ","; - F.pp_print_space fmt ()) - (fun v -> extract_texpression ctx fmt false v) - args; - F.pp_print_string fmt ")" + if !backend = Coq && args = [] then F.pp_print_string fmt "tt" + else ( + F.pp_print_string fmt "("; + Collections.List.iter_link + (fun () -> + F.pp_print_string fmt ","; + F.pp_print_space fmt ()) + (fun v -> extract_texpression ctx fmt false v) + args; + F.pp_print_string fmt ")") | _ -> (* "Regular" ADT *) (* We print something of the form: [Cons field0 ... fieldn]. @@ -1062,7 +1354,10 @@ and extract_field_projector (ctx : extraction_ctx) (fmt : F.formatter) (* We allow to break where the "." appears *) F.pp_print_break fmt 0 0; F.pp_print_string fmt "."; - F.pp_print_string fmt field_name; + (* If in Coq, the field projection has to be parenthesized *) + (match !backend with + | FStar -> F.pp_print_string fmt field_name + | Coq -> F.pp_print_string fmt ("(" ^ field_name ^ ")")); (* Close the box *) F.pp_close_box fmt () | arg :: args -> @@ -1114,7 +1409,8 @@ and extract_Let (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) * a variable *) let ctx = extract_typed_pattern ctx fmt true lv in F.pp_print_space fmt (); - F.pp_print_string fmt "<--"; + let arrow = match !backend with FStar -> "<--" | Coq -> "<-" in + F.pp_print_string fmt arrow; F.pp_print_space fmt (); extract_texpression ctx fmt false re; F.pp_print_string fmt ";"; @@ -1124,7 +1420,8 @@ and extract_Let (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) F.pp_print_space fmt (); let ctx = extract_typed_pattern ctx fmt true lv in F.pp_print_space fmt (); - F.pp_print_string fmt "="; + let eq = match !backend with FStar -> "=" | Coq -> ":=" in + F.pp_print_string fmt eq; F.pp_print_space fmt (); extract_texpression ctx fmt false re; F.pp_print_space fmt (); @@ -1170,15 +1467,18 @@ and extract_Switch (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) F.pp_open_hovbox fmt ctx.indent_incr; (* Print the [begin] if necessary *) let parenth = PureUtils.let_group_requires_parentheses e_branch in + let left_delim, right_delim = + match !backend with FStar -> ("begin", "end") | Coq -> ("(", ")") + in if parenth then ( - F.pp_print_string fmt "begin"; + F.pp_print_string fmt left_delim; F.pp_print_space fmt ()); (* Print the branch expression *) extract_texpression ctx fmt false e_branch; (* Close the [begin ... end ] *) if parenth then ( F.pp_print_space fmt (); - F.pp_print_string fmt "end"); + F.pp_print_string fmt right_delim); (* Close the box for the branch *) F.pp_close_box fmt (); (* Close the box for the then/else+branch *) @@ -1191,7 +1491,10 @@ and extract_Switch (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) (* Open a box for the [match ... with] *) F.pp_open_hovbox fmt ctx.indent_incr; (* Print the [match ... with] *) - F.pp_print_string fmt "begin match"; + let match_begin = + match !backend with FStar -> "begin match" | Coq -> "match" + in + F.pp_print_string fmt match_begin; F.pp_print_space fmt (); let scrut_inside = PureUtils.let_group_requires_parentheses scrut in extract_texpression ctx fmt scrut_inside scrut; @@ -1210,7 +1513,8 @@ and extract_Switch (ctx : extraction_ctx) (fmt : F.formatter) (inside : bool) F.pp_print_space fmt (); let ctx = extract_typed_pattern ctx fmt false br.pat in F.pp_print_space fmt (); - F.pp_print_string fmt "->"; + let arrow = match !backend with FStar -> "->" | Coq -> "=>" in + F.pp_print_string fmt arrow; F.pp_print_space fmt (); (* Open a box for the branch *) F.pp_open_hovbox fmt ctx.indent_incr; @@ -1258,7 +1562,8 @@ let extract_fun_parameters (ctx : extraction_ctx) (fmt : F.formatter) def.signature.type_params; F.pp_print_string fmt ":"; F.pp_print_space fmt (); - F.pp_print_string fmt "Type0)"; + let type_keyword = match !backend with FStar -> "Type0" | Coq -> "Type" in + F.pp_print_string fmt (type_keyword ^ ")"); (* Close the box for the type parameters *) F.pp_close_box fmt (); F.pp_print_space fmt ()); @@ -1305,8 +1610,10 @@ let extract_fun_input_parameters_types (ctx : extraction_ctx) (** Extract a decrease clause function template body. + Only for F*. + In order to help the user, we can generate a template for the functions - required by the decreases clauses. We simply generate definitions of + required by the decreases clauses for. We simply generate definitions of the following form in a separate file: {[ let f_decrease (t : Type0) (x : t) : nat = admit() @@ -1319,6 +1626,7 @@ let extract_fun_input_parameters_types (ctx : extraction_ctx) *) let extract_template_decreases_clause (ctx : extraction_ctx) (fmt : F.formatter) (def : fun_decl) : unit = + assert (!backend = FStar); (* Retrieve the function name *) let def_name = ctx_get_decreases_clause def.def_id ctx in (* Add a break before *) @@ -1371,14 +1679,10 @@ let extract_template_decreases_clause (ctx : extraction_ctx) (fmt : F.formatter) it is useful for the decrease clause. *) let extract_fun_decl (ctx : extraction_ctx) (fmt : F.formatter) - (qualif : fun_decl_qualif) (has_decreases_clause : bool) (def : fun_decl) : - unit = + (kind : decl_kind) (has_decreases_clause : bool) (def : fun_decl) : unit = assert (not def.is_global_decl_body); (* Retrieve the function name *) let def_name = ctx_get_local_function def.def_id def.back_id ctx in - (* (* Add the type parameters - note that we need those bindings only for the - * body translation (they are not top-level) *) - let ctx, _ = ctx_add_type_params def.signature.type_params 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 *) @@ -1392,9 +1696,21 @@ let extract_fun_decl (ctx : extraction_ctx) (fmt : F.formatter) F.pp_open_hovbox fmt ctx.indent_incr; (* > "let FUN_NAME" *) let is_opaque = Option.is_none def.body in - let qualif = fun_decl_qualif_keyword qualif in + (* If in Coq and the declaration is opaque, it must have the shape: + [Axiom Ident : forall (T0 ... Tn : Type), ... -> ... -> ...]. + + The boolean [is_opaque_coq] is used to detect this case. + *) + let is_opaque_coq = !backend = Coq && is_opaque in + let use_forall = is_opaque_coq && def.signature.type_params <> [] in + (* *) + let qualif = ctx.fmt.fun_decl_kind_to_qualif kind in F.pp_print_string fmt (qualif ^ " " ^ def_name); F.pp_print_space fmt (); + if use_forall then ( + F.pp_print_string fmt ":"; + F.pp_print_space fmt (); + F.pp_print_string fmt "forall"); (* Open a box for "(PARAMS) : EFFECT =" *) F.pp_open_hvbox fmt 0; (* Open a box for "(PARAMS)" *) @@ -1408,7 +1724,7 @@ let extract_fun_decl (ctx : extraction_ctx) (fmt : F.formatter) * the bindings we introduced above. * TODO: figure out a cleaner way *) let _ = - F.pp_print_string fmt ":"; + if use_forall then F.pp_print_string fmt "," else F.pp_print_string fmt ":"; F.pp_print_space fmt (); (* Open a box for the EFFECT *) F.pp_open_hvbox fmt 0; @@ -1421,6 +1737,7 @@ let extract_fun_decl (ctx : extraction_ctx) (fmt : F.formatter) if is_opaque then extract_fun_input_parameters_types ctx fmt def; (* [Tot] *) if has_decreases_clause then ( + assert (!backend = FStar); F.pp_print_string fmt "Tot"; F.pp_print_space fmt ()); extract_ty ctx fmt has_decreases_clause def.signature.output; @@ -1429,6 +1746,7 @@ let extract_fun_decl (ctx : extraction_ctx) (fmt : F.formatter) (* Print the decrease clause - rk.: a function with a decreases clause * is necessarily a transparent function *) if has_decreases_clause then ( + assert (!backend = FStar); F.pp_print_space fmt (); (* Open a box for the decrease clause *) F.pp_open_hovbox fmt 0; @@ -1476,7 +1794,8 @@ let extract_fun_decl (ctx : extraction_ctx) (fmt : F.formatter) (* Print the "=" *) if not is_opaque then ( F.pp_print_space fmt (); - F.pp_print_string fmt "="); + let eq = match !backend with FStar -> "=" | Coq -> ":=" in + F.pp_print_string fmt eq); (* Close the box for "(PARAMS) : EFFECT =" *) F.pp_close_box fmt (); (* Close the box for "let FUN_NAME (PARAMS) : EFFECT =" *) @@ -1487,16 +1806,22 @@ let extract_fun_decl (ctx : extraction_ctx) (fmt : F.formatter) F.pp_open_hvbox fmt 0; (* Extract the body *) let _ = extract_texpression ctx_body fmt false (Option.get def.body).body in + (* Coq: add a "." *) + print_decl_end_delimiter fmt kind; (* Close the box for the body *) F.pp_close_box fmt ()); + (* Coq: add a "." *) + if is_opaque_coq then print_decl_end_delimiter fmt kind; (* 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 -(** Extract a global declaration body of the shape "QUALIF NAME : TYPE = BODY" with a custom body extractor *) +(** Extract a global declaration body of the shape "QUALIF NAME : TYPE = BODY" + with a custom body extractor + *) let extract_global_decl_body (ctx : extraction_ctx) (fmt : F.formatter) - (qualif : fun_decl_qualif) (name : string) (ty : ty) + (kind : decl_kind) (name : string) (ty : ty) (extract_body : (F.formatter -> unit) Option.t) : unit = let is_opaque = Option.is_none extract_body in @@ -1506,7 +1831,9 @@ let extract_global_decl_body (ctx : extraction_ctx) (fmt : F.formatter) (* Open "QUALIF NAME : TYPE =" box (depth=1) *) F.pp_open_hovbox fmt ctx.indent_incr; (* Print "QUALIF NAME " *) - F.pp_print_string fmt (fun_decl_qualif_keyword qualif ^ " " ^ name); + F.pp_print_string fmt (ctx.fmt.fun_decl_kind_to_qualif kind); + F.pp_print_space fmt (); + F.pp_print_string fmt name; F.pp_print_space fmt (); (* Open ": TYPE =" box (depth=2) *) @@ -1525,7 +1852,8 @@ let extract_global_decl_body (ctx : extraction_ctx) (fmt : F.formatter) if not is_opaque then ( (* Print " =" *) F.pp_print_space fmt (); - F.pp_print_string fmt "="); + let eq = match !backend with FStar -> "=" | Coq -> ":=" in + F.pp_print_string fmt eq); (* Close ": TYPE =" box (depth=2) *) F.pp_close_box fmt (); (* Close "QUALIF NAME : TYPE =" box (depth=1) *) @@ -1539,16 +1867,22 @@ let extract_global_decl_body (ctx : extraction_ctx) (fmt : F.formatter) (Option.get extract_body) fmt; (* Close "BODY" box (depth=1) *) F.pp_close_box fmt ()); + + (* Coq: add a "." *) + print_decl_end_delimiter fmt Declared; + (* Close the definition box (depth=0) *) F.pp_close_box fmt () (** Extract a global declaration. - We generate the body which computes the global value separately from the value declaration itself. + + We generate the body which computes the global value separately from the + value declaration itself. For example in Rust, [static X: u32 = 3;] - will be translated to: + will be translated to the following F*: [let x_body : result u32 = Return 3] [let x_c : u32 = eval_global x_body] *) @@ -1578,22 +1912,37 @@ let extract_global_decl (ctx : extraction_ctx) (fmt : F.formatter) in match body.body with | None -> - let qualif = if interface then Val else AssumeVal in - extract_global_decl_body ctx fmt qualif decl_name decl_ty None + let kind = if interface then Declared else Assumed in + extract_global_decl_body ctx fmt kind decl_name decl_ty None | Some body -> - extract_global_decl_body ctx fmt Let body_name body_ty + extract_global_decl_body ctx fmt SingleNonRec body_name body_ty (Some (fun fmt -> extract_texpression ctx fmt false body.body)); F.pp_print_break fmt 0 0; - extract_global_decl_body ctx fmt Let decl_name decl_ty - (Some (fun fmt -> F.pp_print_string fmt ("eval_global " ^ body_name))); + extract_global_decl_body ctx fmt SingleNonRec decl_name decl_ty + (Some + (fun fmt -> + let body = + match !backend with + | FStar -> "eval_global " ^ body_name + | Coq -> body_name ^ "%global" + in + F.pp_print_string fmt body)); + (* Add a break to insert lines between declarations *) F.pp_print_break fmt 0 0 (** Extract a unit test, if the function is a unit function (takes no parameters, returns unit). - A unit test simply checks that the function normalizes to [Return ()]: + A unit test simply checks that the function normalizes to [Return ()]. + + F*: {[ - let _ = assert_norm (FUNCTION () = Return ()) + let _ = assert_norm (FUNCTION = Return ()) + ]} + + Coq: + {[ + Check (FUNCTION)%return). ]} *) let extract_unit_test_if_unit_fun (ctx : extraction_ctx) (fmt : F.formatter) @@ -1616,21 +1965,34 @@ let extract_unit_test_if_unit_fun (ctx : extraction_ctx) (fmt : F.formatter) (* Open a box for the test *) F.pp_open_hovbox fmt ctx.indent_incr; (* Print the test *) - F.pp_print_string fmt "let _ ="; - F.pp_print_space fmt (); - F.pp_print_string fmt "assert_norm"; - F.pp_print_space fmt (); - F.pp_print_string fmt "("; - let fun_name = ctx_get_local_function def.def_id def.back_id ctx in - F.pp_print_string fmt fun_name; - if sg.inputs <> [] then ( - F.pp_print_space fmt (); - F.pp_print_string fmt "()"); - F.pp_print_space fmt (); - F.pp_print_string fmt "="; - F.pp_print_space fmt (); - let success = ctx_get_variant (Assumed Result) result_return_id ctx in - F.pp_print_string fmt (success ^ " ())"); + (match !backend with + | FStar -> + F.pp_print_string fmt "let _ ="; + F.pp_print_space fmt (); + F.pp_print_string fmt "assert_norm"; + F.pp_print_space fmt (); + F.pp_print_string fmt "("; + let fun_name = ctx_get_local_function def.def_id def.back_id ctx in + F.pp_print_string fmt fun_name; + if sg.inputs <> [] then ( + F.pp_print_space fmt (); + F.pp_print_string fmt "()"); + F.pp_print_space fmt (); + F.pp_print_string fmt "="; + F.pp_print_space fmt (); + let success = ctx_get_variant (Assumed Result) result_return_id ctx in + F.pp_print_string fmt (success ^ " ())") + | Coq -> + F.pp_print_string fmt "Check"; + F.pp_print_space fmt (); + F.pp_print_string fmt "("; + let fun_name = ctx_get_local_function def.def_id def.back_id ctx in + F.pp_print_string fmt fun_name; + if sg.inputs <> [] then ( + F.pp_print_space fmt (); + F.pp_print_string fmt "()"); + F.pp_print_space fmt (); + F.pp_print_string fmt ")%return."); (* Close the box for the test *) F.pp_close_box fmt (); (* Add a break after *) diff --git a/compiler/PureToExtract.ml b/compiler/ExtractBase.ml index 25ad6713..33939e6a 100644 --- a/compiler/PureToExtract.ml +++ b/compiler/ExtractBase.ml @@ -1,8 +1,4 @@ -(** This module is used to extract the pure ASTs to various theorem provers. - It defines utilities and helpers to make the work as easy as possible: - we try to factorize as much as possible the different extractions to the - backends we target. - *) +(** Define base utilities for the extraction *) open Pure open TranslateCore @@ -33,8 +29,79 @@ type type_name = Names.type_name type global_name = Names.global_name type fun_name = Names.fun_name +(** Characterizes a declaration. + + Is in particular useful to derive the proper keywords to introduce the + declarations/definitions. + *) +type decl_kind = + | SingleNonRec + (** A single, non-recursive definition. + + F*: [let x = ...] + Coq: [Definition x := ...] + *) + | SingleRec + (** A single, recursive definition. + + F*: [let rec x = ...] + Coq: [Fixpoint x := ...] + *) + | MutRecFirst + (** The first definition of a group of mutually-recursive definitions. + + F*: [type x0 = ... and x1 = ...] + Coq: [Fixpoing x0 := ... with x1 := ...] + *) + | MutRecInner + (** An inner definition in a group of mutually-recursive definitions. *) + | MutRecLast + (** The last definition in a group of mutually-recursive definitions. + + We need this because in some theorem provers like Coq, we need to + delimit group of mutually recursive definitions (in particular, we + need to insert an end delimiter). + *) + | Assumed + (** An assumed definition. + + F*: [assume val x] + Coq: [Axiom x : Type.] + *) + | Declared + (** Declare a type in an interface or a module signature. + + Rem.: for now, in Coq, we don't declare module signatures: we + thus assume the corresponding declarations. + + F*: [val x : Type0] + Coq: [Axiom x : Type.] + *) + +(** Return [true] if the declaration is the last from its group of declarations. + + We need this because in some provers (e.g., Coq), we need to delimit the + end of a (group of) definition(s) (in Coq: with a "."). + *) +let decl_is_last_from_group (kind : decl_kind) : bool = + match kind with + | SingleNonRec | SingleRec | MutRecLast | Assumed | Declared -> true + | MutRecFirst | MutRecInner -> false + +let decl_is_from_rec_group (kind : decl_kind) : bool = + match kind with + | SingleNonRec | Assumed | Declared -> false + | SingleRec | MutRecFirst | MutRecInner | MutRecLast -> true + +let decl_is_from_mut_rec_group (kind : decl_kind) : bool = + match kind with + | SingleNonRec | SingleRec | Assumed | Declared -> false + | MutRecFirst | MutRecInner | MutRecLast -> true + (* TODO: this should a module we give to a functor! *) +type type_decl_kind = Enum | Struct + (** A formatter's role is twofold: 1. Come up with name suggestions. For instance, provided some information about a function (its basename, @@ -51,6 +118,16 @@ type formatter = { char_name : string; int_name : integer_type -> string; str_name : string; + type_decl_kind_to_qualif : decl_kind -> type_decl_kind option -> string; + (** Compute the qualified for a type definition/declaration. + + For instance: "type", "and", etc. + *) + fun_decl_kind_to_qualif : decl_kind -> string; + (** Compute the qualified for a function definition/declaration. + + For instance: "let", "let rec", "and", etc. + *) field_name : name -> FieldId.id -> string option -> string; (** Inputs: - type name diff --git a/compiler/ExtractToCoq.ml b/compiler/ExtractToCoq.ml new file mode 100644 index 00000000..3681adc3 --- /dev/null +++ b/compiler/ExtractToCoq.ml @@ -0,0 +1,8 @@ +(** Utilities for the extraction to Coq *) + +open Utils +open Pure +open TranslateCore +open ExtractBase +open StringUtils +module F = Format diff --git a/compiler/ExtractToFStar.ml b/compiler/ExtractToFStar.ml new file mode 100644 index 00000000..21a6fc8f --- /dev/null +++ b/compiler/ExtractToFStar.ml @@ -0,0 +1,8 @@ +(** Utilities for the extraction to F* *) + +open Utils +open Pure +open TranslateCore +open ExtractBase +open StringUtils +module F = Format diff --git a/compiler/Logging.ml b/compiler/Logging.ml index 5f22506b..1d57fa5b 100644 --- a/compiler/Logging.ml +++ b/compiler/Logging.ml @@ -18,8 +18,8 @@ let symbolic_to_pure_log = L.get_logger "MainLogger.SymbolicToPure" (** Logger for PureMicroPasses *) let pure_micro_passes_log = L.get_logger "MainLogger.PureMicroPasses" -(** Logger for PureToExtract *) -let pure_to_extract_log = L.get_logger "MainLogger.PureToExtract" +(** Logger for ExtractBase *) +let pure_to_extract_log = L.get_logger "MainLogger.ExtractBase" (** Logger for Interpreter *) let interpreter_log = L.get_logger "MainLogger.Interpreter" diff --git a/compiler/PureMicroPasses.ml b/compiler/PureMicroPasses.ml index 30fc4989..7b261516 100644 --- a/compiler/PureMicroPasses.ml +++ b/compiler/PureMicroPasses.ml @@ -1250,6 +1250,7 @@ let apply_passes_to_def (ctx : trans_ctx) (def : fun_decl) : fun_decl option = (lazy ("filter_useless:\n\n" ^ fun_decl_to_string ctx def ^ "\n")); (* Simplify the aggregated ADTs. + Ex.: {[ type struct = { f0 : nat; f1 : nat } diff --git a/compiler/PureUtils.ml b/compiler/PureUtils.ml index ff55f322..5a024d9e 100644 --- a/compiler/PureUtils.ml +++ b/compiler/PureUtils.ml @@ -398,9 +398,9 @@ let mk_simpl_tuple_texpression (vl : texpression list) : texpression = let cons = { e = Qualif qualif; ty } in mk_apps cons vl -let mk_adt_pattern (adt_ty : ty) (variant_id : VariantId.id) +let mk_adt_pattern (adt_ty : ty) (variant_id : VariantId.id option) (vl : typed_pattern list) : typed_pattern = - let value = PatAdt { variant_id = Some variant_id; field_values = vl } in + let value = PatAdt { variant_id; field_values = vl } in { value; ty = adt_ty } let ty_as_integer (t : ty) : T.integer_type = diff --git a/compiler/SymbolicAst.ml b/compiler/SymbolicAst.ml index 235e33e4..9d95db7f 100644 --- a/compiler/SymbolicAst.ml +++ b/compiler/SymbolicAst.ml @@ -26,6 +26,7 @@ type mplace = { projection : E.projection; (** We store the projection because we can, but it is actually not that useful *) } +[@@deriving show] type call_id = | Fun of A.fun_id * V.FunCallId.id @@ -43,6 +44,7 @@ type call = { dest : V.symbolic_value; dest_place : mplace option; (** Meta information *) } +[@@deriving show] (** Meta information, not necessary for synthesis but useful to guide it to generate a pretty output. @@ -51,6 +53,7 @@ type call = { type meta = | Assignment of mplace * V.typed_value * mplace option (** We generated an assignment (destination, assigned value, src) *) +[@@deriving show] (** **Rk.:** here, {!expression} is not at all equivalent to the expressions used in LLBC: they are a first step towards lambda-calculus expressions. @@ -108,3 +111,4 @@ and expansion = T.integer_type * (V.scalar_value * expression) list * expression (** An integer expansion (i.e, a switch over an integer). The last expression is for the "otherwise" branch. *) +[@@deriving show] diff --git a/compiler/SymbolicToPure.ml b/compiler/SymbolicToPure.ml index a327c785..62be5efd 100644 --- a/compiler/SymbolicToPure.ml +++ b/compiler/SymbolicToPure.ml @@ -1578,8 +1578,17 @@ and translate_expansion (p : S.mplace option) (sv : V.symbolic_value) (* We don't do the same thing if there is a branching or not *) match branches with | [] -> raise (Failure "Unreachable") - | [ (variant_id, svl, branch) ] -> ( - (* There is exactly one branch: no branching *) + | [ (variant_id, svl, branch) ] + when not + (TypesUtils.ty_is_custom_adt sv.V.sv_ty + && !Config.always_deconstruct_adts_with_matches) -> ( + (* There is exactly one branch: no branching. + + We can decompose the ADT value with a let-binding, unless + the backend doesn't support this (see {!Config.always_deconstruct_adts_with_matches}): + we *ignore* this branch (and go to the next one) if the ADT is a custom + adt, and [always_deconstruct_adts_with_matches] is true. + *) 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 @@ -1588,9 +1597,16 @@ and translate_expansion (p : S.mplace option) (sv : V.symbolic_value) (* Detect if this is an enumeration or not *) let tdef = bs_ctx_lookup_llbc_type_decl adt_id ctx in let is_enum = type_decl_is_enum tdef in - if is_enum then - (* This is an enumeration: introduce an [ExpandEnum] let-binding *) - let variant_id = Option.get variant_id in + (* We deconstruct the ADT with a let-binding in two situations: + - if the ADT is an enumeration (which must have exactly one branch) + - if we forbid using field projectors. + + We forbid using field projectors in some situations, for example + if the backend is Coq. See '!Config.dont_use_field_projectors}. + *) + let use_let = is_enum || !Config.dont_use_field_projectors in + if use_let then + (* Introduce a let binding which expands the ADT *) let lvars = List.map (fun v -> mk_typed_pattern_from_var v None) vars in @@ -1665,8 +1681,6 @@ and translate_expansion (p : S.mplace option) (sv : V.symbolic_value) let translate_branch (variant_id : T.VariantId.id option) (svl : V.symbolic_value list) (branch : S.expression) : match_branch = - (* There *must* be a variant id - otherwise there can't be several branches *) - let variant_id = Option.get variant_id in let ctx, vars = fresh_vars_for_symbolic_values svl ctx in let vars = List.map (fun x -> mk_typed_pattern_from_var x None) vars diff --git a/compiler/Translate.ml b/compiler/Translate.ml index 79d1c913..b2a28710 100644 --- a/compiler/Translate.ml +++ b/compiler/Translate.ml @@ -293,7 +293,7 @@ let translate_module_to_pure (crate : A.crate) : (** Extraction context *) type gen_ctx = { crate : A.crate; - extract_ctx : PureToExtract.extraction_ctx; + 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 : A.FunDeclId.Set.t; @@ -342,30 +342,41 @@ let module_has_opaque_decls (ctx : gen_ctx) : bool * bool = *) let extract_definitions (fmt : Format.formatter) (config : gen_config) (ctx : gen_ctx) : unit = - (* Export the definition groups to the file, in the proper order *) - let export_type (qualif : ExtractToBackend.type_decl_qualif) - (id : Pure.TypeDeclId.id) : unit = - (* Retrive the declaration *) + (* Export the definition groups to the file, in the proper order. + - [extract_decl]: extract the type declaration (if not filtered) + - [extract_extra_info]: extra the extra type information (e.g., + the [Arguments] information in Coq). + *) + let export_type (kind : ExtractBase.decl_kind) (id : Pure.TypeDeclId.id) + (extract_decl : bool) (extract_extra_info : bool) : unit = + (* Retrieve the declaration *) let def = Pure.TypeDeclId.Map.find id ctx.trans_types in - (* Update the qualifier, if the type is opaque *) - let is_opaque, qualif = + (* Update the kind, if the type is opaque *) + let is_opaque, kind = match def.kind with - | Enum _ | Struct _ -> (false, qualif) + | Enum _ | Struct _ -> (false, kind) | Opaque -> - let qualif = - if config.interface then ExtractToBackend.TypeVal - else ExtractToBackend.AssumeType + let kind = + if config.interface then ExtractBase.Declared + else ExtractBase.Assumed in - (true, qualif) + (true, kind) in (* Extract, if the config instructs to do so (depending on whether the type * is opaque or not) *) if (is_opaque && config.extract_opaque) || ((not is_opaque) && config.extract_transparent) - then ExtractToBackend.extract_type_decl ctx.extract_ctx fmt qualif def + then ( + if extract_decl then + Extract.extract_type_decl ctx.extract_ctx fmt kind def; + if extract_extra_info then + Extract.extract_type_decl_extra_info ctx.extract_ctx fmt kind def) in + let export_type_decl kind id = export_type kind id true false in + let export_type_extra_info kind id = export_type kind id false true in + (* Utility to check a function has a decrease clause *) let has_decreases_clause (def : Pure.fun_decl) : bool = A.FunDeclId.Set.mem def.def_id ctx.functions_with_decreases_clause @@ -393,8 +404,7 @@ let extract_definitions (fmt : Format.formatter) (config : gen_config) (fun (_, (fwd, _)) -> let has_decr_clause = has_decreases_clause fwd in if has_decr_clause then - ExtractToBackend.extract_template_decreases_clause ctx.extract_ctx fmt - fwd) + Extract.extract_template_decreases_clause ctx.extract_ctx fmt fwd) pure_ls; (* Extract the function definitions *) (if config.extract_fun_decls then @@ -408,17 +418,25 @@ let extract_definitions (fmt : Format.formatter) (config : gen_config) else true else false in + let fls_length = List.length fls in List.iteri (fun i (fwd_def, def) -> let is_opaque = Option.is_none fwd_def.Pure.body in - let qualif = + let kind = if is_opaque then - if config.interface then ExtractToBackend.Val - else ExtractToBackend.AssumeVal - else if not is_rec then ExtractToBackend.Let + if config.interface then ExtractBase.Declared + else ExtractBase.Assumed + else if not is_rec then ExtractBase.SingleNonRec else if is_mut_rec then - if i = 0 then ExtractToBackend.LetRec else ExtractToBackend.And - else ExtractToBackend.LetRec + (* If the functions are mutually recursive, we need to distinguish: + * - the first of the group + * - the last of the group + * - the inner functions + *) + if i = 0 then ExtractBase.MutRecFirst + else if i = fls_length - 1 then ExtractBase.MutRecLast + else ExtractBase.MutRecInner + else ExtractBase.SingleRec in let has_decr_clause = has_decreases_clause def && config.extract_decreases_clauses @@ -428,15 +446,14 @@ let extract_definitions (fmt : Format.formatter) (config : gen_config) ((not is_opaque) && config.extract_transparent) || (is_opaque && config.extract_opaque) then - ExtractToBackend.extract_fun_decl ctx.extract_ctx fmt qualif - has_decr_clause def) + Extract.extract_fun_decl ctx.extract_ctx fmt kind has_decr_clause def) fls); (* Insert unit tests if necessary *) if config.test_trans_unit_functions then List.iter (fun (keep_fwd, (fwd, _)) -> if keep_fwd then - ExtractToBackend.extract_unit_test_if_unit_fun ctx.extract_ctx fmt fwd) + Extract.extract_unit_test_if_unit_fun ctx.extract_ctx fmt fwd) pure_ls in @@ -454,32 +471,49 @@ let extract_definitions (fmt : Format.formatter) (config : gen_config) ((not is_opaque) && config.extract_transparent) || (is_opaque && config.extract_opaque) then - ExtractToBackend.extract_global_decl ctx.extract_ctx fmt global body + Extract.extract_global_decl ctx.extract_ctx fmt global body config.interface in let export_state_type () : unit = - let qualif = - if config.interface then ExtractToBackend.TypeVal - else ExtractToBackend.AssumeType + let kind = + if config.interface then ExtractBase.Declared else ExtractBase.Assumed in - ExtractToBackend.extract_state_type fmt ctx.extract_ctx qualif + Extract.extract_state_type fmt ctx.extract_ctx kind in let export_decl (decl : A.declaration_group) : unit = match decl with | Type (NonRec id) -> - if config.extract_types then export_type ExtractToBackend.Type id + if config.extract_types then ( + let kind = ExtractBase.SingleNonRec in + (* Export the type declaration *) + export_type_decl kind id; + (* Export the extra information (ex.: [Arguments] instructions in Coq) *) + export_type_extra_info kind id) | Type (Rec ids) -> (* Rk.: we shouldn't have (mutually) recursive opaque types *) - if config.extract_types then + let num_decls = List.length ids in + let is_mut_rec = num_decls > 1 in + if config.extract_types then ( + let kind_from_index i = + if not is_mut_rec then ExtractBase.SingleRec + else if i = 0 then ExtractBase.MutRecFirst + else if i = num_decls - 1 then ExtractBase.MutRecLast + else ExtractBase.MutRecInner + in + (* Extract the type declarations *) + List.iteri + (fun i id -> + let kind = kind_from_index i in + export_type_decl kind id) + ids; + (* Export the extra information (ex.: [Arguments] instructions in Coq) *) List.iteri (fun i id -> - let qualif = - if i = 0 then ExtractToBackend.Type else ExtractToBackend.And - in - export_type qualif id) - ids + let kind = kind_from_index i in + export_type_extra_info kind id) + ids) | Fun (NonRec id) -> (* Lookup *) let pure_fun = A.FunDeclId.Map.find id ctx.trans_funs in @@ -527,15 +561,33 @@ let extract_file (config : gen_config) (ctx : gen_ctx) (filename : string) (* Create the header *) Printf.fprintf out "(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *)\n"; Printf.fprintf out "(** [%s]%s *)\n" rust_module_name custom_msg; - Printf.fprintf out "module %s\n" module_name; - Printf.fprintf out "open Primitives\n"; - (* Add the custom imports *) - List.iter (fun m -> Printf.fprintf out "open %s\n" m) custom_imports; - (* Add the custom includes *) - List.iter (fun m -> Printf.fprintf out "include %s\n" m) custom_includes; - (* Z3 options - note that we use fuel 1 because it its useful for the decrease clauses *) - Printf.fprintf out "\n#set-options \"--z3rlimit 50 --fuel 1 --ifuel 1\"\n"; - + (match !Config.backend with + | FStar -> + Printf.fprintf out "module %s\n" module_name; + Printf.fprintf out "open Primitives\n"; + (* Add the custom imports *) + List.iter (fun m -> Printf.fprintf out "open %s\n" m) custom_imports; + (* Add the custom includes *) + List.iter (fun m -> Printf.fprintf out "include %s\n" m) custom_includes; + (* Z3 options - note that we use fuel 1 because it its useful for the decrease clauses *) + Printf.fprintf out "\n#set-options \"--z3rlimit 50 --fuel 1 --ifuel 1\"\n" + | Coq -> + Printf.fprintf out "Require Import Primitives.\n"; + Printf.fprintf out "Import Primitives.\n"; + Printf.fprintf out "Require Import Coq.ZArith.ZArith.\n"; + Printf.fprintf out "Local Open Scope Primitives_scope.\n"; + + (* Add the custom imports *) + List.iter + (fun m -> Printf.fprintf out "Require Import %s .\n" m) + custom_imports; + (* Add the custom includes *) + List.iter + (fun m -> + Printf.fprintf out "Require Export %s .\n" m; + Printf.fprintf out "Import %s .\n" m) + custom_includes; + Printf.fprintf out "Module %s .\n" module_name); (* From now onwards, we use the formatter *) (* Set the margin *) Format.pp_set_margin fmt 80; @@ -550,6 +602,11 @@ let extract_file (config : gen_config) (ctx : gen_ctx) (filename : string) Format.pp_close_box fmt (); Format.pp_print_newline fmt (); + (* Close the module *) + (match !Config.backend with + | FStar -> () + | Coq -> Printf.fprintf out "End %s .\n" module_name); + (* Some logging *) log#linfo (lazy ("Generated: " ^ filename)); @@ -568,17 +625,12 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : * We initialize the names map by registering the keywords used in the * language, as well as some primitive names ("u32", etc.) *) let variant_concatenate_type_name = true in - let fstar_fmt = - ExtractToBackend.mk_formatter trans_ctx crate.name + 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 variant_concatenate_type_name in - let names_map = - PureToExtract.initialize_names_map fstar_fmt - ExtractToBackend.fstar_names_map_init - in - let ctx = - { PureToExtract.trans_ctx; names_map; fmt = fstar_fmt; indent_incr = 2 } - in + let ctx = { ExtractBase.trans_ctx; names_map; fmt; indent_incr = 2 } in (* We need to compute which functions are recursive, in order to know * whether we should generate a decrease clause or not. *) @@ -596,7 +648,7 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : * sure there are no name clashes. *) let ctx = List.fold_left - (fun ctx def -> ExtractToBackend.extract_type_decl_register_names ctx def) + (fun ctx def -> Extract.extract_type_decl_register_names ctx def) ctx trans_types in @@ -612,14 +664,13 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : let is_global = (fst def).Pure.is_global_decl_body in if is_global then ctx else - ExtractToBackend.extract_fun_decl_register_names ctx keep_fwd - gen_decr_clause def) + Extract.extract_fun_decl_register_names ctx keep_fwd gen_decr_clause + def) ctx trans_funs in let ctx = - List.fold_left ExtractToBackend.extract_global_decl_register_names ctx - crate.globals + List.fold_left Extract.extract_global_decl_register_names ctx crate.globals in (* Open the output file *) @@ -658,12 +709,17 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : (* Create a directory with *default* permissions *) Core_unix.mkdir_p dest_dir); - (* Copy "Primitives.fst" *) + (* Copy the "Primitives" file *) let _ = (* Retrieve the executable's directory *) let exe_dir = Filename.dirname Sys.argv.(0) in - let src = open_in (exe_dir ^ "/backends/fstar/Primitives.fst") in - let tgt_filename = Filename.concat dest_dir "Primitives.fst" in + let primitives_src, primitives_destname = + match !Config.backend with + | Config.FStar -> ("/backends/fstar/Primitives.fst", "Primitives.fst") + | Config.Coq -> ("/backends/coq/Primitives.v", "Primitives.v") + in + let src = open_in (exe_dir ^ primitives_src) in + let tgt_filename = Filename.concat dest_dir primitives_destname in let tgt = open_out tgt_filename in (* Very annoying: I couldn't find a "cp" function in the OCaml libraries... *) try @@ -689,6 +745,10 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : } in + let module_delimiter = + match !Config.backend with FStar -> "." | Coq -> "__" + in + (* Extract one or several files, depending on the configuration *) if !Config.split_files then ( let base_gen_config = @@ -712,9 +772,16 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : (* Extract the types *) (* If there are opaque types, we extract in an interface *) - let types_filename_ext = if has_opaque_types then ".fsti" else ".fst" in - let types_filename = extract_filebasename ^ ".Types" ^ types_filename_ext in - let types_module = module_name ^ ".Types" in + let types_filename_ext = + match !Config.backend with + | FStar -> if has_opaque_types then ".fsti" else ".fst" + | Coq -> if has_opaque_types then ".v" else ".v" + in + let types_file_suffix = module_delimiter ^ "Types" in + let types_filename = + extract_filebasename ^ types_file_suffix ^ types_filename_ext + in + let types_module = module_name ^ types_file_suffix in let types_config = { base_gen_config with @@ -733,8 +800,12 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : && not (A.FunDeclId.Set.is_empty rec_functions) in (if needs_clauses_module && !Config.extract_template_decreases_clauses then - let clauses_filename = extract_filebasename ^ ".Clauses.Template.fst" in - let clauses_module = module_name ^ ".Clauses.Template" in + let ext = match !Config.backend with FStar -> ".fst" | Coq -> ".v" in + let clauses_file_suffix = + module_delimiter ^ "Clauses" ^ module_delimiter ^ "Template" + in + let clauses_filename = extract_filebasename ^ clauses_file_suffix ^ ext in + let clauses_module = module_name ^ clauses_file_suffix in let clauses_config = { base_gen_config with extract_template_decreases_clauses = true } in @@ -745,8 +816,10 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : (* Extract the opaque functions, if needed *) let opaque_funs_module = if has_opaque_funs then ( - let opaque_filename = extract_filebasename ^ ".Opaque.fsti" in - let opaque_module = module_name ^ ".Opaque" in + let ext = match !Config.backend with FStar -> ".fsti" | Coq -> ".v" in + let opaque_file_suffix = module_delimiter ^ "Opaque" in + let opaque_filename = extract_filebasename ^ opaque_file_suffix ^ ext in + let opaque_module = module_name ^ opaque_file_suffix in let opaque_config = { base_gen_config with @@ -763,8 +836,10 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : in (* Extract the functions *) - let fun_filename = extract_filebasename ^ ".Funs.fst" in - let fun_module = module_name ^ ".Funs" in + let ext = match !Config.backend with FStar -> ".fst" | Coq -> ".v" in + let fun_file_suffix = module_delimiter ^ "Funs" in + let fun_filename = extract_filebasename ^ fun_file_suffix ^ ext in + let fun_module = module_name ^ fun_file_suffix in let fun_config = { base_gen_config with @@ -773,7 +848,9 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : } in let clauses_module = - if needs_clauses_module then [ module_name ^ ".Clauses" ] else [] + if needs_clauses_module then + [ module_name ^ module_delimiter ^ "Clauses" ] + else [] in extract_file fun_config gen_ctx fun_filename crate.A.name fun_module ": function definitions" [] @@ -794,6 +871,7 @@ let translate_module (filename : string) (dest_dir : string) (crate : A.crate) : } in (* Add the extension for F* *) - let extract_filename = extract_filebasename ^ ".fst" in + let ext = match !Config.backend with FStar -> ".fst" | Coq -> ".v" in + let extract_filename = extract_filebasename ^ ext in extract_file gen_config gen_ctx extract_filename crate.A.name module_name "" [] [] diff --git a/compiler/Values.ml b/compiler/Values.ml index 44b22f9f..046f0482 100644 --- a/compiler/Values.ml +++ b/compiler/Values.ml @@ -817,3 +817,4 @@ type symbolic_expansion = | SeAdt of (VariantId.id option * symbolic_value list) | SeMutRef of BorrowId.id * symbolic_value | SeSharedRef of BorrowId.Set.t * symbolic_value +[@@deriving show] diff --git a/compiler/dune b/compiler/dune index 10aa9b10..b530340b 100644 --- a/compiler/dune +++ b/compiler/dune @@ -20,7 +20,10 @@ Cps Expressions ExpressionsUtils - ExtractToBackend + Extract + ExtractBase + ExtractToCoq + ExtractToFStar FunsAnalysis Identifiers InterpreterBorrowsCore @@ -44,7 +47,6 @@ PrintPure PureMicroPasses Pure - PureToExtract PureTypeCheck PureUtils Scalars diff --git a/tests/Makefile b/tests/Makefile new file mode 100644 index 00000000..dfb20cc4 --- /dev/null +++ b/tests/Makefile @@ -0,0 +1,3 @@ +all: + cd fstar && $(MAKE) all + cd coq && $(MAKE) all diff --git a/tests/coq/Makefile b/tests/coq/Makefile new file mode 100644 index 00000000..5fead9c9 --- /dev/null +++ b/tests/coq/Makefile @@ -0,0 +1,3 @@ +# TODO: make this more general +all: + cd misc && $(MAKE) all diff --git a/tests/coq/misc/Constants.v b/tests/coq/misc/Constants.v new file mode 100644 index 00000000..677aae8c --- /dev/null +++ b/tests/coq/misc/Constants.v @@ -0,0 +1,138 @@ +(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *) +(** [constants] *) +Require Import Primitives. +Import Primitives. +Require Import Coq.ZArith.ZArith. +Local Open Scope Primitives_scope. +Module Constants . + +(** [constants::X0] *) +Definition x0_body : result u32 := Return (0 %u32) . +Definition x0_c : u32 := x0_body%global . + +(** [core::num::u32::{9}::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_c : u32 := x1_body%global . + +(** [constants::X2] *) +Definition x2_body : result u32 := Return (3 %u32) . +Definition x2_c : u32 := x2_body%global . + +(** [constants::incr] *) +Definition incr_fwd (n : u32) : result u32 := i <- u32_add n 1 %u32; Return i . + +(** [constants::X3] *) +Definition x3_body : result u32 := i <- incr_fwd (32 %u32); Return i . +Definition x3_c : u32 := x3_body%global . + +(** [constants::mk_pair0] *) +Definition mk_pair0_fwd (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; } . + +Arguments mkPair_t {T1} {T2} _ _ . +Arguments Pair_x {T1} {T2} . +Arguments Pair_y {T1} {T2} . + +(** [constants::mk_pair1] *) +Definition mk_pair1_fwd (x : u32) (y : u32) : result (Pair_t u32 u32) := + Return (mkPair_t x y) . + +(** [constants::P0] *) +Definition p0_body : result (u32 * u32) := + p <- mk_pair0_fwd (0 %u32) (1 %u32); Return p + . +Definition p0_c : (u32 * u32) := p0_body%global . + +(** [constants::P1] *) +Definition p1_body : result (Pair_t u32 u32) := + p <- mk_pair1_fwd (0 %u32) (1 %u32); Return p + . +Definition p1_c : Pair_t u32 u32 := p1_body%global . + +(** [constants::P2] *) +Definition p2_body : result (u32 * u32) := Return (0 %u32, 1 %u32) . +Definition p2_c : (u32 * u32) := p2_body%global . + +(** [constants::P3] *) +Definition p3_body : result (Pair_t u32 u32) := + Return (mkPair_t (0 %u32) (1 %u32)) + . +Definition p3_c : Pair_t u32 u32 := p3_body%global . + +(** [constants::Wrap] *) +Record Wrap_t (T : Type) := mkWrap_t { Wrap_val : T; } . + +Arguments mkWrap_t {T} _ . +Arguments Wrap_val {T} . + +(** [constants::Wrap::{0}::new] *) +Definition wrap_new_fwd (T : Type) (val : T) : result (Wrap_t T) := + Return (mkWrap_t val) . + +(** [constants::Y] *) +Definition y_body : result (Wrap_t i32) := + w <- wrap_new_fwd i32 (2 %i32); Return w + . +Definition y_c : Wrap_t i32 := y_body%global . + +(** [constants::unwrap_y] *) +Definition unwrap_y_fwd : result i32 := + match y_c with | mkWrap_t i => Return i end . + +(** [constants::YVAL] *) +Definition yval_body : result i32 := i <- unwrap_y_fwd; Return i . +Definition yval_c : i32 := yval_body%global . + +(** [constants::get_z1::Z1] *) +Definition get_z1_z1_body : result i32 := Return (3 %i32) . +Definition get_z1_z1_c : i32 := get_z1_z1_body%global . + +(** [constants::get_z1] *) +Definition get_z1_fwd : result i32 := Return get_z1_z1_c . + +(** [constants::add] *) +Definition add_fwd (a : i32) (b : i32) : result i32 := + i <- i32_add a b; Return i . + +(** [constants::Q1] *) +Definition q1_body : result i32 := Return (5 %i32) . +Definition q1_c : i32 := q1_body%global . + +(** [constants::Q2] *) +Definition q2_body : result i32 := Return q1_c . +Definition q2_c : i32 := q2_body%global . + +(** [constants::Q3] *) +Definition q3_body : result i32 := i <- add_fwd q2_c (3 %i32); Return i . +Definition q3_c : i32 := q3_body%global . + +(** [constants::get_z2] *) +Definition get_z2_fwd : result i32 := + i <- get_z1_fwd; i0 <- add_fwd i q3_c; i1 <- add_fwd q1_c i0; Return i1 . + +(** [constants::S1] *) +Definition s1_body : result u32 := Return (6 %u32) . +Definition s1_c : u32 := s1_body%global . + +(** [constants::S2] *) +Definition s2_body : result u32 := i <- incr_fwd s1_c; Return i . +Definition s2_c : u32 := s2_body%global . + +(** [constants::S3] *) +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) := + p <- mk_pair1_fwd (7 %u32) (8 %u32); Return p + . +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 new file mode 100644 index 00000000..77b738b0 --- /dev/null +++ b/tests/coq/misc/External__Funs.v @@ -0,0 +1,100 @@ +(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *) +(** [external]: function definitions *) +Require Import Primitives. +Import Primitives. +Require Import Coq.ZArith.ZArith. +Local Open Scope Primitives_scope. +Require Export External__Types . +Import External__Types . +Require Export External__Opaque . +Import External__Opaque . +Module External__Funs . + +(** [external::swap] *) +Definition swap_fwd + (T : Type) (x : T) (y : T) (st : state) : result (state * unit) := + p <- core_mem_swap_fwd T x y st; + let (st0, _) := p in + p0 <- core_mem_swap_back0 T x y st st0; + let (st1, _) := p0 in + p1 <- core_mem_swap_back1 T x y st st1; + let (st2, _) := p1 in Return (st2, tt) + . + +(** [external::swap] *) +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; + let (st1, _) := p in + p0 <- core_mem_swap_back0 T x y st st1; + let (st2, x0) := p0 in + p1 <- core_mem_swap_back1 T x y st st2; + let (_, y0) := p1 in Return (st0, (x0, y0)) + . + +(** [external::test_new_non_zero_u32] *) +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 + p0 <- core_option_option_unwrap_fwd Core_num_nonzero_non_zero_u32_t opt st0; + let (st1, nzu) := p0 in Return (st1, nzu) + . + +(** [external::test_vec] *) +Definition test_vec_fwd : result unit := + let v := vec_new u32 in + v0 <- vec_push_back u32 v (0 %u32); let _ := v0 in Return tt + . + +(** [external::custom_swap] *) +Definition custom_swap_fwd + (T : Type) (x : T) (y : T) (st : state) : result (state * T) := + p <- core_mem_swap_fwd T x y st; + let (st0, _) := p in + p0 <- core_mem_swap_back0 T x y st st0; + let (st1, x0) := p0 in + p1 <- core_mem_swap_back1 T x y st st1; + let (st2, _) := p1 in Return (st2, x0) + . + +(** [external::custom_swap] *) +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; + let (st1, _) := p in + p0 <- core_mem_swap_back0 T x y st st1; + let (st2, _) := p0 in + p1 <- core_mem_swap_back1 T x y st st2; + let (_, y0) := p1 in Return (st0, (ret, y0)) + . + +(** [external::test_custom_swap] *) +Definition test_custom_swap_fwd + (x : u32) (y : u32) (st : state) : result (state * unit) := + p <- custom_swap_fwd u32 x y st; let (st0, _) := p in Return (st0, tt) . + +(** [external::test_custom_swap] *) +Definition test_custom_swap_back + (x : u32) (y : u32) (st : state) (st0 : state) : + result (state * (u32 * u32)) + := + p <- custom_swap_back u32 x y st (1 %u32) st0; + let (st1, tmp) := p in + let (x0, y0) := tmp in Return (st1, (x0, y0)) + . + +(** [external::test_swap_non_zero] *) +Definition test_swap_non_zero_fwd + (x : u32) (st : state) : result (state * u32) := + p <- swap_fwd u32 x (0 %u32) st; + let (st0, _) := p in + p0 <- swap_back u32 x (0 %u32) st st0; + let (st1, (x0, _)) := p0 in if x0 s= 0 %u32 then Fail_ else Return (st1, x0) + . + +End External__Funs . diff --git a/tests/coq/misc/External__Opaque.v b/tests/coq/misc/External__Opaque.v new file mode 100644 index 00000000..19111a37 --- /dev/null +++ b/tests/coq/misc/External__Opaque.v @@ -0,0 +1,36 @@ +(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *) +(** [external]: opaque function definitions *) +Require Import Primitives. +Import Primitives. +Require Import Coq.ZArith.ZArith. +Local Open Scope Primitives_scope. +Require Export External__Types . +Import External__Types . +Module External__Opaque . + +(** [core::mem::swap] *) +Axiom core_mem_swap_fwd : + forall(T : Type) , T -> T -> state -> result (state * unit) + . + +(** [core::mem::swap] *) +Axiom core_mem_swap_back0 : + forall(T : Type) , T -> T -> state -> state -> result (state * T) + . + +(** [core::mem::swap] *) +Axiom core_mem_swap_back1 : + forall(T : Type) , T -> T -> state -> state -> result (state * T) + . + +(** [core::num::nonzero::NonZeroU32::{14}::new] *) +Axiom core_num_nonzero_non_zero_u32_new_fwd + : u32 -> state -> result (state * (option Core_num_nonzero_non_zero_u32_t)) + . + +(** [core::option::Option::{0}::unwrap] *) +Axiom core_option_option_unwrap_fwd : + forall(T : Type) , option T -> state -> result (state * T) + . + +End External__Opaque . diff --git a/tests/coq/misc/External__Types.v b/tests/coq/misc/External__Types.v new file mode 100644 index 00000000..1513ec4a --- /dev/null +++ b/tests/coq/misc/External__Types.v @@ -0,0 +1,15 @@ +(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *) +(** [external]: type definitions *) +Require Import Primitives. +Import Primitives. +Require Import Coq.ZArith.ZArith. +Local Open Scope Primitives_scope. +Module External__Types . + +(** [core::num::nonzero::NonZeroU32] *) +Axiom Core_num_nonzero_non_zero_u32_t : Type . + +(** The state type used in the state-error monad *) +Axiom state : Type. + +End External__Types . diff --git a/tests/coq/misc/Makefile b/tests/coq/misc/Makefile new file mode 100644 index 00000000..ff1ccd39 --- /dev/null +++ b/tests/coq/misc/Makefile @@ -0,0 +1,22 @@ +# 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/misc/NoNestedBorrows.v b/tests/coq/misc/NoNestedBorrows.v new file mode 100644 index 00000000..6dc41204 --- /dev/null +++ b/tests/coq/misc/NoNestedBorrows.v @@ -0,0 +1,510 @@ +(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *) +(** [no_nested_borrows] *) +Require Import Primitives. +Import Primitives. +Require Import Coq.ZArith.ZArith. +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; } . + +Arguments mkPair_t {T1} {T2} _ _ . +Arguments Pair_x {T1} {T2} . +Arguments Pair_y {T1} {T2} . + +(** [no_nested_borrows::List] *) +Inductive List_t (T : Type) := +| ListCons : T -> List_t T -> List_t T +| ListNil : List_t T +. + +Arguments ListCons {T} _ _ . +Arguments ListNil {T} . + +(** [no_nested_borrows::One] *) +Inductive One_t (T1 : Type) := | OneOne : T1 -> One_t T1 . + +Arguments OneOne {T1} _ . + +(** [no_nested_borrows::EmptyEnum] *) +Inductive Empty_enum_t := | EmptyEnumEmpty : Empty_enum_t . + +Arguments EmptyEnumEmpty . + +(** [no_nested_borrows::Enum] *) +Inductive Enum_t := | EnumVariant1 : Enum_t | EnumVariant2 : Enum_t . + +Arguments EnumVariant1 . +Arguments EnumVariant2 . + +(** [no_nested_borrows::EmptyStruct] *) +Record Empty_struct_t := mkEmpty_struct_t { } . + +Arguments mkEmpty_struct_t . + +(** [no_nested_borrows::Sum] *) +Inductive Sum_t (T1 T2 : Type) := +| SumLeft : T1 -> Sum_t T1 T2 +| SumRight : T2 -> Sum_t T1 T2 +. + +Arguments SumLeft {T1} {T2} _ . +Arguments SumRight {T1} {T2} _ . + +(** [no_nested_borrows::neg_test] *) +Definition neg_test_fwd (x : i32) : result i32 := i <- i32_neg x; Return i . + +(** [no_nested_borrows::add_test] *) +Definition add_test_fwd (x : u32) (y : u32) : result u32 := + i <- u32_add x y; Return i . + +(** [no_nested_borrows::subs_test] *) +Definition subs_test_fwd (x : u32) (y : u32) : result u32 := + i <- u32_sub x y; Return i . + +(** [no_nested_borrows::div_test] *) +Definition div_test_fwd (x : u32) (y : u32) : result u32 := + i <- u32_div x y; Return i . + +(** [no_nested_borrows::div_test1] *) +Definition div_test1_fwd (x : u32) : result u32 := + i <- u32_div x 2 %u32; Return i . + +(** [no_nested_borrows::rem_test] *) +Definition rem_test_fwd (x : u32) (y : u32) : result u32 := + i <- u32_rem x y; Return i . + +(** [no_nested_borrows::cast_test] *) +Definition cast_test_fwd (x : u32) : result i32 := + i <- scalar_cast U32 I32 x; Return i . + +(** [no_nested_borrows::test2] *) +Definition test2_fwd : result unit := + i <- u32_add 23 %u32 44 %u32; let _ := i in Return tt . + +(** Unit test for [no_nested_borrows::test2] *) +Check (test2_fwd )%return. + +(** [no_nested_borrows::get_max] *) +Definition get_max_fwd (x : u32) (y : u32) : result u32 := + if x s>= y then Return x else Return y . + +(** [no_nested_borrows::test3] *) +Definition test3_fwd : result unit := + x <- get_max_fwd (4 %u32) (3 %u32); + y <- get_max_fwd (10 %u32) (11 %u32); + z <- u32_add x y; if negb (z s= 15 %u32) then Fail_ else Return tt + . + +(** Unit test for [no_nested_borrows::test3] *) +Check (test3_fwd )%return. + +(** [no_nested_borrows::test_neg1] *) +Definition test_neg1_fwd : result unit := + y <- i32_neg (3 %i32); if negb (y s= (-3) %i32) then Fail_ else Return tt . + +(** Unit test for [no_nested_borrows::test_neg1] *) +Check (test_neg1_fwd )%return. + +(** [no_nested_borrows::refs_test1] *) +Definition refs_test1_fwd : result unit := + if negb (1 %i32 s= 1 %i32) then Fail_ else Return tt . + +(** Unit test for [no_nested_borrows::refs_test1] *) +Check (refs_test1_fwd )%return. + +(** [no_nested_borrows::refs_test2] *) +Definition refs_test2_fwd : result unit := + if negb (2 %i32 s= 2 %i32) + then Fail_ + else + if negb (0 %i32 s= 0 %i32) + then Fail_ + else + if negb (2 %i32 s= 2 %i32) + then Fail_ + else if negb (2 %i32 s= 2 %i32) then Fail_ else Return tt + . + +(** Unit test for [no_nested_borrows::refs_test2] *) +Check (refs_test2_fwd )%return. + +(** [no_nested_borrows::test_list1] *) +Definition test_list1_fwd : result unit := Return tt . + +(** Unit test for [no_nested_borrows::test_list1] *) +Check (test_list1_fwd )%return. + +(** [no_nested_borrows::test_box1] *) +Definition test_box1_fwd : result unit := + let b := 1 %i32 in + let x := b in if negb (x s= 1 %i32) then Fail_ else Return tt + . + +(** Unit test for [no_nested_borrows::test_box1] *) +Check (test_box1_fwd )%return. + +(** [no_nested_borrows::copy_int] *) +Definition copy_int_fwd (x : i32) : result i32 := Return x . + +(** [no_nested_borrows::test_unreachable] *) +Definition test_unreachable_fwd (b : bool) : result unit := + if b then Fail_ else Return tt . + +(** [no_nested_borrows::test_panic] *) +Definition test_panic_fwd (b : bool) : result unit := + if b then Fail_ else Return tt . + +(** [no_nested_borrows::test_copy_int] *) +Definition test_copy_int_fwd : result unit := + y <- copy_int_fwd (0 %i32); if negb (0 %i32 s= y) then Fail_ else Return tt . + +(** Unit test for [no_nested_borrows::test_copy_int] *) +Check (test_copy_int_fwd )%return. + +(** [no_nested_borrows::is_cons] *) +Definition is_cons_fwd (T : Type) (l : List_t T) : result bool := + match l with | ListCons t l0 => Return true | ListNil => Return false end . + +(** [no_nested_borrows::test_is_cons] *) +Definition test_is_cons_fwd : result unit := + let l := ListNil in + b <- is_cons_fwd i32 (ListCons (0 %i32) l); + if negb b then Fail_ else Return tt + . + +(** Unit test for [no_nested_borrows::test_is_cons] *) +Check (test_is_cons_fwd )%return. + +(** [no_nested_borrows::split_list] *) +Definition split_list_fwd + (T : Type) (l : List_t T) : result (T * (List_t T)) := + match l with | ListCons hd tl => Return (hd, tl) | ListNil => Fail_ end . + +(** [no_nested_borrows::test_split_list] *) +Definition test_split_list_fwd : result unit := + let l := ListNil in + p <- split_list_fwd i32 (ListCons (0 %i32) l); + let (hd, _) := p in if negb (hd s= 0 %i32) then Fail_ else Return tt + . + +(** Unit test for [no_nested_borrows::test_split_list] *) +Check (test_split_list_fwd )%return. + +(** [no_nested_borrows::choose] *) +Definition choose_fwd (T : Type) (b : bool) (x : T) (y : T) : result T := + if b then Return x else Return y . + +(** [no_nested_borrows::choose] *) +Definition choose_back + (T : Type) (b : bool) (x : T) (y : T) (ret : T) : result (T * T) := + if b then Return (ret, y) else Return (x, ret) . + +(** [no_nested_borrows::choose_test] *) +Definition choose_test_fwd : result unit := + z <- choose_fwd i32 true (0 %i32) (0 %i32); + z0 <- i32_add z 1 %i32; + if negb (z0 s= 1 %i32) + then Fail_ + else + ( + p <- choose_back i32 true (0 %i32) (0 %i32) z0; + let (x, y) := p in + if negb (x s= 1 %i32) + then Fail_ + else if negb (y s= 0 %i32) then Fail_ else Return tt ) + . + +(** Unit test for [no_nested_borrows::choose_test] *) +Check (choose_test_fwd )%return. + +(** [no_nested_borrows::test_char] *) +Definition test_char_fwd : result char := + Return (char_of_byte Coq.Init.Byte.x61) . + +(** [no_nested_borrows::NodeElem] *) +Inductive Node_elem_t (T : Type) := +| NodeElemCons : Tree_t T -> Node_elem_t T -> Node_elem_t T +| NodeElemNil : Node_elem_t T + +(** [no_nested_borrows::Tree] *) +with Tree_t (T : Type) := +| TreeLeaf : T -> Tree_t T +| TreeNode : T -> Node_elem_t T -> Tree_t T -> Tree_t T +. + +Arguments NodeElemCons {T} _ _ . +Arguments NodeElemNil {T} . + +Arguments TreeLeaf {T} _ . +Arguments TreeNode {T} _ _ _ . + +(** [no_nested_borrows::list_length] *) +Fixpoint list_length_fwd (T : Type) (l : List_t T) : result u32 := + match l with + | ListCons t l1 => + i <- list_length_fwd T l1; i0 <- u32_add 1 %u32 i; Return i0 + | ListNil => Return (0 %u32) + end + . + +(** [no_nested_borrows::list_nth_shared] *) +Fixpoint list_nth_shared_fwd (T : Type) (l : List_t T) (i : u32) : result T := + match l with + | ListCons x tl => + if i s= 0 %u32 + then Return x + else ( i0 <- u32_sub i 1 %u32; t <- list_nth_shared_fwd T tl i0; Return t ) + | ListNil => Fail_ + end + . + +(** [no_nested_borrows::list_nth_mut] *) +Fixpoint list_nth_mut_fwd (T : Type) (l : List_t T) (i : u32) : result T := + match l with + | ListCons x tl => + if i s= 0 %u32 + then Return x + else ( i0 <- u32_sub i 1 %u32; t <- list_nth_mut_fwd T tl i0; Return t ) + | ListNil => Fail_ + end + . + +(** [no_nested_borrows::list_nth_mut] *) +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 => + if i s= 0 %u32 + then Return (ListCons ret tl) + else + ( + i0 <- u32_sub i 1 %u32; + tl0 <- list_nth_mut_back T tl i0 ret; Return (ListCons x tl0) ) + | ListNil => Fail_ + end + . + +(** [no_nested_borrows::list_rev_aux] *) +Fixpoint list_rev_aux_fwd + (T : Type) (li : List_t T) (lo : List_t T) : result (List_t T) := + match li with + | ListCons hd tl => l <- list_rev_aux_fwd T tl (ListCons hd lo); Return l + | ListNil => Return lo + end + . + +(** [no_nested_borrows::list_rev] *) +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 + l0 <- list_rev_aux_fwd T li ListNil; Return l0 + . + +(** [no_nested_borrows::test_list_functions] *) +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); + if negb (i s= 3 %u32) + then Fail_ + else + ( + i0 <- list_nth_shared_fwd i32 (ListCons (0 %i32) l1) (0 %u32); + if negb (i0 s= 0 %i32) + then Fail_ + else + ( + i1 <- list_nth_shared_fwd i32 (ListCons (0 %i32) l1) (1 %u32); + if negb (i1 s= 1 %i32) + then Fail_ + else + ( + i2 <- list_nth_shared_fwd i32 (ListCons (0 %i32) l1) (2 %u32); + if negb (i2 s= 2 %i32) + then Fail_ + else + ( + ls <- + list_nth_mut_back i32 (ListCons (0 %i32) l1) (1 %u32) (3 + %i32); + i3 <- list_nth_shared_fwd i32 ls (0 %u32); + if negb (i3 s= 0 %i32) + then Fail_ + else + ( + i4 <- list_nth_shared_fwd i32 ls (1 %u32); + if negb (i4 s= 3 %i32) + then Fail_ + else + ( + i5 <- list_nth_shared_fwd i32 ls (2 %u32); + if negb (i5 s= 2 %i32) then Fail_ else Return tt ) ) + ) ) ) ) + . + +(** Unit test for [no_nested_borrows::test_list_functions] *) +Check (test_list_functions_fwd )%return. + +(** [no_nested_borrows::id_mut_pair1] *) +Definition id_mut_pair1_fwd + (T1 T2 : Type) (x : T1) (y : T2) : result (T1 * T2) := + Return (x, y) . + +(** [no_nested_borrows::id_mut_pair1] *) +Definition id_mut_pair1_back + (T1 T2 : Type) (x : T1) (y : T2) (ret : (T1 * T2)) : result (T1 * T2) := + let (t, t0) := ret in Return (t, t0) . + +(** [no_nested_borrows::id_mut_pair2] *) +Definition id_mut_pair2_fwd + (T1 T2 : Type) (p : (T1 * T2)) : result (T1 * T2) := + let (t, t0) := p in Return (t, t0) . + +(** [no_nested_borrows::id_mut_pair2] *) +Definition id_mut_pair2_back + (T1 T2 : Type) (p : (T1 * T2)) (ret : (T1 * T2)) : result (T1 * T2) := + let (t, t0) := ret in Return (t, t0) . + +(** [no_nested_borrows::id_mut_pair3] *) +Definition id_mut_pair3_fwd + (T1 T2 : Type) (x : T1) (y : T2) : result (T1 * T2) := + Return (x, y) . + +(** [no_nested_borrows::id_mut_pair3] *) +Definition id_mut_pair3_back'a + (T1 T2 : Type) (x : T1) (y : T2) (ret : T1) : result T1 := + Return ret . + +(** [no_nested_borrows::id_mut_pair3] *) +Definition id_mut_pair3_back'b + (T1 T2 : Type) (x : T1) (y : T2) (ret : T2) : result T2 := + Return ret . + +(** [no_nested_borrows::id_mut_pair4] *) +Definition id_mut_pair4_fwd + (T1 T2 : Type) (p : (T1 * T2)) : result (T1 * T2) := + let (t, t0) := p in Return (t, t0) . + +(** [no_nested_borrows::id_mut_pair4] *) +Definition id_mut_pair4_back'a + (T1 T2 : Type) (p : (T1 * T2)) (ret : T1) : result T1 := + Return ret . + +(** [no_nested_borrows::id_mut_pair4] *) +Definition id_mut_pair4_back'b + (T1 T2 : Type) (p : (T1 * T2)) (ret : T2) : result T2 := + Return ret . + +(** [no_nested_borrows::StructWithTuple] *) +Record Struct_with_tuple_t (T1 T2 : Type) := +mkStruct_with_tuple_t +{ + Struct_with_tuple_p : (T1 * T2); +} +. + +Arguments mkStruct_with_tuple_t {T1} {T2} _ . +Arguments Struct_with_tuple_p {T1} {T2} . + +(** [no_nested_borrows::new_tuple1] *) +Definition new_tuple1_fwd : result (Struct_with_tuple_t u32 u32) := + Return (mkStruct_with_tuple_t (1 %u32, 2 %u32)) . + +(** [no_nested_borrows::new_tuple2] *) +Definition new_tuple2_fwd : result (Struct_with_tuple_t i16 i16) := + Return (mkStruct_with_tuple_t (1 %i16, 2 %i16)) . + +(** [no_nested_borrows::new_tuple3] *) +Definition new_tuple3_fwd : result (Struct_with_tuple_t u64 i64) := + Return (mkStruct_with_tuple_t (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; +} +. + +Arguments mkStruct_with_pair_t {T1} {T2} _ . +Arguments Struct_with_pair_p {T1} {T2} . + +(** [no_nested_borrows::new_pair1] *) +Definition new_pair1_fwd : result (Struct_with_pair_t u32 u32) := + Return (mkStruct_with_pair_t (mkPair_t (1 %u32) (2 %u32))) . + +(** [no_nested_borrows::test_constants] *) +Definition test_constants_fwd : result unit := + swt <- new_tuple1_fwd; + match swt with + | mkStruct_with_tuple_t p => + let (i, _) := p in + if negb (i s= 1 %u32) + then Fail_ + else + ( + swt0 <- new_tuple2_fwd; + match swt0 with + | mkStruct_with_tuple_t p0 => + let (i0, _) := p0 in + if negb (i0 s= 1 %i16) + then Fail_ + else + ( + swt1 <- new_tuple3_fwd; + match swt1 with + | mkStruct_with_tuple_t p1 => + let (i1, _) := p1 in + if negb (i1 s= 1 %u64) + then Fail_ + else + ( + swp <- new_pair1_fwd; + match swp with + | mkStruct_with_pair_t p2 => + match p2 with + | mkPair_t i2 i3 => + if negb (i2 s= 1 %u32) then Fail_ else Return tt + end + end ) + end ) + end ) + end + . + +(** Unit test for [no_nested_borrows::test_constants] *) +Check (test_constants_fwd )%return. + +(** [no_nested_borrows::test_weird_borrows1] *) +Definition test_weird_borrows1_fwd : result unit := Return tt . + +(** Unit test for [no_nested_borrows::test_weird_borrows1] *) +Check (test_weird_borrows1_fwd )%return. + +(** [no_nested_borrows::test_mem_replace] *) +Definition test_mem_replace_fwd_back (px : u32) : result u32 := + let y := mem_replace_fwd u32 px (1 %u32) in + if negb (y s= 0 %u32) then Fail_ else Return (2 %u32) + . + +(** [no_nested_borrows::test_shared_borrow_bool1] *) +Definition test_shared_borrow_bool1_fwd (b : bool) : result u32 := + if b then Return (0 %u32) else Return (1 %u32) . + +(** [no_nested_borrows::test_shared_borrow_bool2] *) +Definition test_shared_borrow_bool2_fwd : result u32 := Return (0 %u32) . + +(** [no_nested_borrows::test_shared_borrow_enum1] *) +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 + . + +(** [no_nested_borrows::test_shared_borrow_enum2] *) +Definition test_shared_borrow_enum2_fwd : result u32 := Return (0 %u32) . + +End NoNestedBorrows . diff --git a/tests/coq/misc/Paper.v b/tests/coq/misc/Paper.v new file mode 100644 index 00000000..5d9598eb --- /dev/null +++ b/tests/coq/misc/Paper.v @@ -0,0 +1,114 @@ +(** THIS FILE WAS AUTOMATICALLY GENERATED BY AENEAS *) +(** [paper] *) +Require Import Primitives. +Import Primitives. +Require Import Coq.ZArith.ZArith. +Local Open Scope Primitives_scope. +Module Paper . + +(** [paper::ref_incr] *) +Definition ref_incr_fwd_back (x : i32) : result i32 := + x0 <- i32_add x 1 %i32; Return x0 . + +(** [paper::test_incr] *) +Definition test_incr_fwd : result unit := + x <- ref_incr_fwd_back (0 %i32); + if negb (x s= 1 %i32) then Fail_ else Return tt + . + +(** Unit test for [paper::test_incr] *) +Check (test_incr_fwd )%return. + +(** [paper::choose] *) +Definition choose_fwd (T : Type) (b : bool) (x : T) (y : T) : result T := + if b then Return x else Return y . + +(** [paper::choose] *) +Definition choose_back + (T : Type) (b : bool) (x : T) (y : T) (ret : T) : result (T * T) := + if b then Return (ret, y) else Return (x, ret) . + +(** [paper::test_choose] *) +Definition test_choose_fwd : result unit := + z <- choose_fwd i32 true (0 %i32) (0 %i32); + z0 <- i32_add z 1 %i32; + if negb (z0 s= 1 %i32) + then Fail_ + else + ( + p <- choose_back i32 true (0 %i32) (0 %i32) z0; + let (x, y) := p in + if negb (x s= 1 %i32) + then Fail_ + else if negb (y s= 0 %i32) then Fail_ else Return tt ) + . + +(** Unit test for [paper::test_choose] *) +Check (test_choose_fwd )%return. + +(** [paper::List] *) +Inductive List_t (T : Type) := +| ListCons : T -> List_t T -> List_t T +| ListNil : List_t T +. + +Arguments ListCons {T} _ _ . +Arguments ListNil {T} . + +(** [paper::list_nth_mut] *) +Fixpoint list_nth_mut_fwd (T : Type) (l : List_t T) (i : u32) : result T := + match l with + | ListCons x tl => + if i s= 0 %u32 + then Return x + else ( i0 <- u32_sub i 1 %u32; t <- list_nth_mut_fwd T tl i0; Return t ) + | ListNil => Fail_ + end + . + +(** [paper::list_nth_mut] *) +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 => + if i s= 0 %u32 + then Return (ListCons ret tl) + else + ( + i0 <- u32_sub i 1 %u32; + tl0 <- list_nth_mut_back T tl i0 ret; Return (ListCons x tl0) ) + | ListNil => Fail_ + end + . + +(** [paper::sum] *) +Fixpoint sum_fwd (l : List_t i32) : result i32 := + match l with + | ListCons x tl => i <- sum_fwd tl; i0 <- i32_add x i; Return i0 + | ListNil => Return (0 %i32) + end + . + +(** [paper::test_nth] *) +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); + x0 <- i32_add x 1 %i32; + l2 <- list_nth_mut_back i32 (ListCons (1 %i32) l1) (2 %u32) x0; + i <- sum_fwd l2; if negb (i s= 7 %i32) then Fail_ else Return tt + . + +(** Unit test for [paper::test_nth] *) +Check (test_nth_fwd )%return. + +(** [paper::call_choose] *) +Definition call_choose_fwd (p : (u32 * u32)) : result u32 := + let (px, py) := p in + pz <- choose_fwd u32 true px py; + pz0 <- u32_add pz 1 %u32; + p0 <- choose_back u32 true px py pz0; let (px0, _) := p0 in Return px0 + . + +End Paper . diff --git a/tests/coq/misc/Primitives.v b/tests/coq/misc/Primitives.v new file mode 100644 index 00000000..c27b8aed --- /dev/null +++ b/tests/coq/misc/Primitives.v @@ -0,0 +1,478 @@ +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 result A := + | Return : A -> result A + | Fail_ : result A. + +Arguments Return {_} a. +Arguments Fail_ {_}. + +Definition bind {A B} (m: result A) (f: A -> result B) : result B := + match m with + | Fail_ => Fail_ + | Return x => f x + end. + +Definition return_ {A: Type} (x: A) : result A := Return x . +Definition fail_ {A: Type} : result A := Fail_ . + +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_. + +(** 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_ => fun p' => + False_rect _ (eq_ind Fail_ + (fun e : result A => + match e with + | Return _ => False + | Fail_ => 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_)%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 . + +(*** 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_ + 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_ 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 *) +Print Z.leb . + +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. + +(*** Vectors *) + +Definition 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 vec_length {T: Type} (v: vec T) : Z := Z.of_nat (length (vec_to_list v)). + +Lemma le_0_usize_max : 0 <= usize_max. +Proof. + pose (H := usize_max_bound). + unfold u32_max in H. + lia. +Qed. + +Definition vec_new (T: Type) : vec T := (exist _ [] le_0_usize_max). + +Lemma vec_len_in_usize {T} (v: vec T) : usize_min <= vec_length v <= usize_max. +Proof. + unfold 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). + +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 vec_bind {A B} (v: vec A) (f: list A -> result (list B)) : result (vec B) := + l <- f (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_ + end. + +(* The **forward** function shouldn't be used *) +Definition vec_push_fwd (T: Type) (v: 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])). + +(* 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_. + +Definition vec_insert_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_). + +(* 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_ + 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_. + +(* 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_ + 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_). + +End Primitives. diff --git a/tests/coq/misc/_CoqProject b/tests/coq/misc/_CoqProject new file mode 100644 index 00000000..7f4981fa --- /dev/null +++ b/tests/coq/misc/_CoqProject @@ -0,0 +1,12 @@ +-R . Lib +-arg -w +-arg all + +Primitives.v + +Constants.v +External__Funs.v +External__Opaque.v +External__Types.v +NoNestedBorrows.v +Paper.v
\ No newline at end of file diff --git a/tests/fstar/misc/NoNestedBorrows.fst b/tests/fstar/misc/NoNestedBorrows.fst index 8161e7cd..36dea95b 100644 --- a/tests/fstar/misc/NoNestedBorrows.fst +++ b/tests/fstar/misc/NoNestedBorrows.fst @@ -228,59 +228,6 @@ and tree_t (t : Type0) = | TreeLeaf : t -> tree_t t | TreeNode : t -> node_elem_t t -> tree_t t -> tree_t t -(** [no_nested_borrows::odd] *) -let rec odd_fwd (x : u32) : result bool = - if x = 0 - then Return false - else - begin match u32_sub x 1 with - | Fail -> Fail - | Return i -> - begin match even_fwd i with | Fail -> Fail | Return b -> Return b end - end - -(** [no_nested_borrows::even] *) -and even_fwd (x : u32) : result bool = - if x = 0 - then Return true - else - begin match u32_sub x 1 with - | Fail -> Fail - | Return i -> - begin match odd_fwd i with | Fail -> Fail | Return b -> Return b end - end - -(** [no_nested_borrows::test_even_odd] *) -let test_even_odd_fwd : result unit = - begin match even_fwd 0 with - | Fail -> Fail - | Return b -> - if not b - then Fail - else - begin match even_fwd 4 with - | Fail -> Fail - | Return b0 -> - if not b0 - then Fail - else - begin match odd_fwd 1 with - | Fail -> Fail - | Return b1 -> - if not b1 - then Fail - else - begin match odd_fwd 5 with - | Fail -> Fail - | Return b2 -> if not b2 then Fail else Return () - end - end - end - end - -(** Unit test for [no_nested_borrows::test_even_odd] *) -let _ = assert_norm (test_even_odd_fwd = Return ()) - (** [no_nested_borrows::list_length] *) let rec list_length_fwd (t : Type0) (l : list_t t) : result u32 = begin match l with |