aboutsummaryrefslogtreecommitdiff
path: root/new-luxc/test
diff options
context:
space:
mode:
Diffstat (limited to '')
-rw-r--r--new-luxc/test/test/luxc/lang/analysis/common.lux22
-rw-r--r--new-luxc/test/test/luxc/lang/analysis/structure.lux331
2 files changed, 0 insertions, 353 deletions
diff --git a/new-luxc/test/test/luxc/lang/analysis/common.lux b/new-luxc/test/test/luxc/lang/analysis/common.lux
index 35212e55d..7e343cc88 100644
--- a/new-luxc/test/test/luxc/lang/analysis/common.lux
+++ b/new-luxc/test/test/luxc/lang/analysis/common.lux
@@ -11,28 +11,6 @@
[eval]))
(test/luxc common))
-(def: gen-unit
- (r.Random Code)
- (r/wrap (' [])))
-
-(def: #export gen-primitive
- (r.Random [Type Code])
- (with-expansions
- [<generators> (do-template [<type> <code-wrapper> <value-gen>]
- [(r.seq (r/wrap <type>) (r/map <code-wrapper> <value-gen>))]
-
- [Top code.tuple (r.list +0 gen-unit)]
- [Bool code.bool r.bool]
- [Nat code.nat r.nat]
- [Int code.int r.int]
- [Deg code.deg r.deg]
- [Frac code.frac r.frac]
- [Text code.text (r.text +5)]
- )]
- ($_ r.either
- <generators>
- )))
-
(def: #export analyse
&.Analyser
(expressionA.analyser eval.eval))
diff --git a/new-luxc/test/test/luxc/lang/analysis/structure.lux b/new-luxc/test/test/luxc/lang/analysis/structure.lux
deleted file mode 100644
index 0a94e37da..000000000
--- a/new-luxc/test/test/luxc/lang/analysis/structure.lux
+++ /dev/null
@@ -1,331 +0,0 @@
-(.module:
- lux
- (lux [io]
- (control [monad #+ do]
- pipe)
- (data [bool "bool/" Eq<Bool>]
- ["e" error]
- [product]
- [maybe]
- [text]
- text/format
- (coll [list "list/" Functor<List>]
- (set ["set" unordered])))
- ["r" math/random "r/" Monad<Random>]
- [macro]
- (macro [code])
- (lang [type "type/" Eq<Type>]
- (type ["tc" check]))
- test)
- (luxc ["&" lang]
- (lang ["@." module]
- ["la" analysis]
- (analysis [".A" expression]
- ["@" structure]
- ["@." common])))
- (// common)
- (test/luxc common))
-
-(context: "Sums"
- (<| (times +100)
- (do @
- [size (|> r.nat (:: @ map (|>> (n/% +10) (n/max +2))))
- choice (|> r.nat (:: @ map (n/% size)))
- primitives (r.list size gen-primitive)
- +choice (|> r.nat (:: @ map (n/% (n/inc size))))
- [_ +valueC] gen-primitive
- #let [variantT (type.variant (list/map product.left primitives))
- [valueT valueC] (maybe.assume (list.nth choice primitives))
- +size (n/inc size)
- +primitives (list.concat (list (list.take choice primitives)
- (list [(#.Bound +1) +valueC])
- (list.drop choice primitives)))
- [+valueT +valueC] (maybe.assume (list.nth +choice +primitives))
- +variantT (type.variant (list/map product.left +primitives))]]
- ($_ seq
- (test "Can analyse sum."
- (|> (&.with-scope
- (&.with-type variantT
- (@.analyse-sum analyse choice valueC)))
- (macro.run (io.run init-jvm))
- (case> (^multi (#e.Success [_ sumA])
- [(la.unfold-variant sumA)
- (#.Some [tag last? valueA])])
- (and (n/= tag choice)
- (bool/= last? (n/= (n/dec size) choice)))
-
- _
- false)))
- (test "Can analyse sum through bound type-vars."
- (|> (&.with-scope
- (do macro.Monad<Meta>
- [[_ varT] (&.with-type-env tc.var)
- _ (&.with-type-env
- (tc.check varT variantT))]
- (&.with-type varT
- (@.analyse-sum analyse choice valueC))))
- (macro.run (io.run init-jvm))
- (case> (^multi (#e.Success [_ sumA])
- [(la.unfold-variant sumA)
- (#.Some [tag last? valueA])])
- (and (n/= tag choice)
- (bool/= last? (n/= (n/dec size) choice)))
-
- _
- false)))
- (test "Cannot analyse sum through unbound type-vars."
- (|> (&.with-scope
- (do macro.Monad<Meta>
- [[_ varT] (&.with-type-env tc.var)]
- (&.with-type varT
- (@.analyse-sum analyse choice valueC))))
- (macro.run (io.run init-jvm))
- (case> (#e.Success _)
- false
-
- _
- true)))
- (test "Can analyse sum through existential quantification."
- (|> (&.with-scope
- (&.with-type (type.ex-q +1 +variantT)
- (@.analyse-sum analyse +choice +valueC)))
- (macro.run (io.run init-jvm))
- (case> (#e.Success _)
- true
-
- (#e.Error error)
- false)))
- (test "Can analyse sum through universal quantification."
- (|> (&.with-scope
- (&.with-type (type.univ-q +1 +variantT)
- (@.analyse-sum analyse +choice +valueC)))
- (macro.run (io.run init-jvm))
- (case> (#e.Success _)
- (not (n/= choice +choice))
-
- (#e.Error error)
- (n/= choice +choice))))
- ))))
-
-(context: "Products"
- (<| (times +100)
- (do @
- [size (|> r.nat (:: @ map (|>> (n/% +10) (n/max +2))))
- primitives (r.list size gen-primitive)
- choice (|> r.nat (:: @ map (n/% size)))
- [_ +valueC] gen-primitive
- #let [[singletonT singletonC] (|> primitives (list.nth choice) maybe.assume)
- +primitives (list.concat (list (list.take choice primitives)
- (list [(#.Bound +1) +valueC])
- (list.drop choice primitives)))
- +tupleT (type.tuple (list/map product.left +primitives))]]
- ($_ seq
- (test "Can analyse product."
- (|> (&.with-type (type.tuple (list/map product.left primitives))
- (@.analyse-product analyse (list/map product.right primitives)))
- (macro.run (io.run init-jvm))
- (case> (#e.Success tupleA)
- (n/= size (list.size (la.unfold-tuple tupleA)))
-
- _
- false)))
- (test "Can infer product."
- (|> (@common.with-unknown-type
- (@.analyse-product analyse (list/map product.right primitives)))
- (macro.run (io.run init-jvm))
- (case> (#e.Success [_type tupleA])
- (and (type/= (type.tuple (list/map product.left primitives))
- _type)
- (n/= size (list.size (la.unfold-tuple tupleA))))
-
- _
- false)))
- (test "Can analyse pseudo-product (singleton tuple)"
- (|> (&.with-type singletonT
- (analyse (` [(~ singletonC)])))
- (macro.run (io.run init-jvm))
- (case> (#e.Success singletonA)
- true
-
- (#e.Error error)
- false)))
- (test "Can analyse product through bound type-vars."
- (|> (&.with-scope
- (do macro.Monad<Meta>
- [[_ varT] (&.with-type-env tc.var)
- _ (&.with-type-env
- (tc.check varT (type.tuple (list/map product.left primitives))))]
- (&.with-type varT
- (@.analyse-product analyse (list/map product.right primitives)))))
- (macro.run (io.run init-jvm))
- (case> (#e.Success [_ tupleA])
- (n/= size (list.size (la.unfold-tuple tupleA)))
-
- _
- false)))
- (test "Can analyse product through existential quantification."
- (|> (&.with-scope
- (&.with-type (type.ex-q +1 +tupleT)
- (@.analyse-product analyse (list/map product.right +primitives))))
- (macro.run (io.run init-jvm))
- (case> (#e.Success _)
- true
-
- (#e.Error error)
- false)))
- (test "Cannot analyse product through universal quantification."
- (|> (&.with-scope
- (&.with-type (type.univ-q +1 +tupleT)
- (@.analyse-product analyse (list/map product.right +primitives))))
- (macro.run (io.run init-jvm))
- (case> (#e.Success _)
- false
-
- (#e.Error error)
- true)))
- ))))
-
-(def: (check-variant variantT choice size analysis)
- (-> Type Nat Nat (Meta [Module Scope la.Analysis]) Bool)
- (|> analysis
- (&.with-type variantT)
- (macro.run (io.run init-jvm))
- (case> (^multi (#e.Success [_ _ sumA])
- [(la.unfold-variant sumA)
- (#.Some [tag last? valueA])])
- (and (n/= tag choice)
- (bool/= last? (n/= (n/dec size) choice)))
-
- _
- false)))
-
-(def: (check-record-inference tupleT size analysis)
- (-> Type Nat (Meta [Module Scope Type la.Analysis]) Bool)
- (|> analysis
- (macro.run (io.run init-jvm))
- (case> (^multi (#e.Success [_ _ productT productA])
- [(la.unfold-tuple productA)
- membersA])
- (and (type/= tupleT productT)
- (n/= size (list.size membersA)))
-
- _
- false)))
-
-(context: "Tagged Sums"
- (<| (times +100)
- (do @
- [size (|> r.nat (:: @ map (|>> (n/% +10) (n/max +2))))
- tags (|> (r.set text.Hash<Text> size (r.text +5)) (:: @ map set.to-list))
- choice (|> r.nat (:: @ map (n/% size)))
- other-choice (|> r.nat (:: @ map (n/% size)) (r.filter (|>> (n/= choice) not)))
- primitives (r.list size gen-primitive)
- module-name (r.text +5)
- type-name (r.text +5)
- #let [varT (#.Bound +1)
- primitivesT (list/map product.left primitives)
- [choiceT choiceC] (maybe.assume (list.nth choice primitives))
- [other-choiceT other-choiceC] (maybe.assume (list.nth other-choice primitives))
- variantT (type.variant primitivesT)
- namedT (#.Named [module-name type-name] variantT)
- polyT (|> (type.variant (list.concat (list (list.take choice primitivesT)
- (list varT)
- (list.drop (n/inc choice) primitivesT))))
- (type.univ-q +1))
- named-polyT (#.Named [module-name type-name] polyT)
- choice-tag (maybe.assume (list.nth choice tags))
- other-choice-tag (maybe.assume (list.nth other-choice tags))]]
- ($_ seq
- (test "Can infer tagged sum."
- (|> (@module.with-module +0 module-name
- (do macro.Monad<Meta>
- [_ (@module.declare-tags tags false namedT)]
- (&.with-scope
- (@.analyse-tagged-sum analyse [module-name choice-tag] choiceC))))
- (check-variant variantT choice size)))
- (test "Tagged sums specialize when type-vars get bound."
- (|> (@module.with-module +0 module-name
- (do macro.Monad<Meta>
- [_ (@module.declare-tags tags false named-polyT)]
- (&.with-scope
- (@.analyse-tagged-sum analyse [module-name choice-tag] choiceC))))
- (check-variant variantT choice size)))
- (test "Tagged sum inference retains universal quantification when type-vars are not bound."
- (|> (@module.with-module +0 module-name
- (do macro.Monad<Meta>
- [_ (@module.declare-tags tags false named-polyT)]
- (&.with-scope
- (@.analyse-tagged-sum analyse [module-name other-choice-tag] other-choiceC))))
- (check-variant polyT other-choice size)))
- (test "Can specialize generic tagged sums."
- (|> (@module.with-module +0 module-name
- (do macro.Monad<Meta>
- [_ (@module.declare-tags tags false named-polyT)]
- (&.with-scope
- (&.with-type variantT
- (@.analyse-tagged-sum analyse [module-name other-choice-tag] other-choiceC)))))
- (macro.run (io.run init-jvm))
- (case> (^multi (#e.Success [_ _ sumA])
- [(la.unfold-variant sumA)
- (#.Some [tag last? valueA])])
- (and (n/= tag other-choice)
- (bool/= last? (n/= (n/dec size) other-choice)))
-
- _
- false)))
- ))))
-
-(context: "Records"
- (<| (times +100)
- (do @
- [size (|> r.nat (:: @ map (|>> (n/% +10) (n/max +2))))
- tags (|> (r.set text.Hash<Text> size (r.text +5)) (:: @ map set.to-list))
- primitives (r.list size gen-primitive)
- module-name (r.text +5)
- type-name (r.text +5)
- choice (|> r.nat (:: @ map (n/% size)))
- #let [varT (#.Bound +1)
- tagsC (list/map (|>> [module-name] code.tag) tags)
- primitivesT (list/map product.left primitives)
- primitivesC (list/map product.right primitives)
- tupleT (type.tuple primitivesT)
- namedT (#.Named [module-name type-name] tupleT)
- recordC (list.zip2 tagsC primitivesC)
- polyT (|> (type.tuple (list.concat (list (list.take choice primitivesT)
- (list varT)
- (list.drop (n/inc choice) primitivesT))))
- (type.univ-q +1))
- named-polyT (#.Named [module-name type-name] polyT)]]
- ($_ seq
- (test "Can infer record."
- (|> (@module.with-module +0 module-name
- (do macro.Monad<Meta>
- [_ (@module.declare-tags tags false namedT)]
- (&.with-scope
- (@common.with-unknown-type
- (@.analyse-record analyse recordC)))))
- (check-record-inference tupleT size)))
- (test "Records specialize when type-vars get bound."
- (|> (@module.with-module +0 module-name
- (do macro.Monad<Meta>
- [_ (@module.declare-tags tags false named-polyT)]
- (&.with-scope
- (@common.with-unknown-type
- (@.analyse-record analyse recordC)))))
- (check-record-inference tupleT size)))
- (test "Can specialize generic records."
- (|> (@module.with-module +0 module-name
- (do macro.Monad<Meta>
- [_ (@module.declare-tags tags false named-polyT)]
- (&.with-scope
- (&.with-type tupleT
- (@.analyse-record analyse recordC)))))
- (macro.run (io.run init-jvm))
- (case> (^multi (#e.Success [_ _ productA])
- [(la.unfold-tuple productA)
- membersA])
- (n/= size (list.size membersA))
-
- _
- false)))
- ))))