quox/tests/Tests/Reduce.idr

133 lines
4.2 KiB
Idris

module Tests.Reduce
import Quox.Syntax as Lib
import Quox.Equal
import TypingImpls
import AstExtra
import TAP
import Control.Eff
%hide Prelude.App
%hide Pretty.App
parameters {0 isRedex : RedexTest tm} {auto _ : CanWhnf tm isRedex} {d, n : Nat}
{auto _ : (Eq (tm d n), Show (tm d n))}
{default empty defs : Definitions}
private
testWhnf : String -> WhnfContext d n -> tm d n -> tm d n -> Test
testWhnf label ctx from to = test "\{label} (whnf)" $ do
result <- mapFst toInfo $ runWhnf $ whnf0 defs ctx from
unless (result == to) $ Left [("exp", show to), ("got", show result)]
private
testNoStep : String -> WhnfContext d n -> tm d n -> Test
testNoStep label ctx e = testWhnf label ctx e e
private
ctx : Context (\n => (BindName, Term 0 n)) n -> WhnfContext 0 n
ctx xs = let (ns, ts) = unzip xs in MkWhnfContext [<] ns ts
export
tests : Test
tests = "whnf" :- [
"head constructors" :- [
testNoStep "★₀" empty $ ^TYPE 0,
testNoStep "1.A → B" empty $
^Arr One (^FT "A" 0) (^FT "B" 0),
testNoStep "(x: A) ⊸ B x" empty $
^PiY One "x" (^FT "A" 0) (E $ ^App (^F "B" 0) (^BVT 0)),
testNoStep "λ x ⇒ x" empty $
^LamY "x" (^BVT 0),
testNoStep "f a" empty $
E $ ^App (^F "f" 0) (^FT "a" 0)
],
"neutrals" :- [
testNoStep "x" (ctx [< ("A", ^Nat)]) $ ^BV 0,
testNoStep "a" empty $ ^F "a" 0,
testNoStep "f a" empty $ ^App (^F "f" 0) (^FT "a" 0),
testNoStep "★₀ ∷ ★₁" empty $ ^Ann (^TYPE 0) (^TYPE 1)
],
"redexes" :- [
testWhnf "a ∷ A" empty
(^Ann (^FT "a" 0) (^FT "A" 0))
(^F "a" 0),
testWhnf "★₁ ∷ ★₃" empty
(E $ ^Ann (^TYPE 1) (^TYPE 3))
(^TYPE 1),
testWhnf "(λ x ⇒ x ∷ 1.A → A) a" empty
(^App (^Ann (^LamY "x" (^BVT 0)) (^Arr One (^FT "A" 0) (^FT "A" 0)))
(^FT "a" 0))
(^F "a" 0)
],
"definitions" :- [
testWhnf "a (transparent)" empty
{defs = fromList [("a", ^mkDef gzero (^TYPE 1) (^TYPE 0))]}
(^F "a" 0) (^Ann (^TYPE 0) (^TYPE 1)),
testNoStep "a (opaque)" empty
{defs = fromList [("a", ^mkPostulate gzero (^TYPE 1))]}
(^F "a" 0)
],
"elim closure" :- [
testWhnf "x{}" (ctx [< ("x", ^Nat)])
(CloE (Sub (^BV 0) id))
(^BV 0),
testWhnf "x{a/x}" empty
(CloE (Sub (^BV 0) (^F "a" 0 ::: id)))
(^F "a" 0),
testWhnf "x{a/y}" (ctx [< ("x", ^Nat)])
(CloE (Sub (^BV 0) (^BV 0 ::: ^F "a" 0 ::: id)))
(^BV 0),
testWhnf "x{(y{a/y})/x}" empty
(CloE (Sub (^BV 0) ((CloE (Sub (^BV 0) (^F "a" 0 ::: id))) ::: id)))
(^F "a" 0),
testWhnf "(x y){f/x,a/y}" empty
(CloE (Sub (^App (^BV 0) (^BVT 1)) (^F "f" 0 ::: ^F "a" 0 ::: id)))
(^App (^F "f" 0) (^FT "a" 0)),
testWhnf "(y ∷ x){A/x}" (ctx [< ("x", ^Nat)])
(CloE (Sub (^Ann (^BVT 1) (^BVT 0)) (^F "A" 0 ::: id)))
(^BV 0),
testWhnf "(y ∷ x){A/x,a/y}" empty
(CloE (Sub (^Ann (^BVT 1) (^BVT 0)) (^F "A" 0 ::: ^F "a" 0 ::: id)))
(^F "a" 0)
],
"term closure" :- [
testWhnf "(λ y ⇒ x){a/x}" empty
(CloT (Sub (^LamN (^BVT 0)) (^F "a" 0 ::: id)))
(^LamN (^FT "a" 0)),
testWhnf "(λy. y){a/x}" empty
(CloT (Sub (^LamY "y" (^BVT 0)) (^F "a" 0 ::: id)))
(^LamY "y" (^BVT 0))
],
"looking inside `E`" :- [
testWhnf "(λx. x ∷ A ⊸ A) a" empty
(E $ ^App (^Ann (^LamY "x" (^BVT 0)) (^Arr One (^FT "A" 0) (^FT "A" 0)))
(^FT "a" 0))
(^FT "a" 0)
],
"nested redex" :- [
testNoStep "λ y ⇒ ((λ x ⇒ x) ∷ 1.A → A) y" empty $
^LamY "y" (E $
^App (^Ann (^LamY "x" (^BVT 0)) (^Arr One (^FT "A" 0) (^FT "A" 0)))
(^BVT 0)),
testNoStep "f (((λ x ⇒ x) ∷ 1.A → A) a)" empty $
^App (^F "f" 0)
(E $ ^App (^Ann (^LamY "x" (^BVT 0)) (^Arr One (^FT "A" 0) (^FT "A" 0)))
(^FT "a" 0)),
testNoStep "λx. (y x){x/x,a/y}" (ctx [< ("y", ^Nat)]) $
^LamY "x" (CloT $ Sub (E $ ^App (^BV 1) (^BVT 0))
(^BV 0 ::: ^F "a" 0 ::: id)),
testNoStep "f (y x){x/x,a/y}" (ctx [< ("y", ^Nat)]) $
^App (^F "f" 0)
(CloT (Sub (E $ ^App (^BV 1) (^BVT 0))
(^BV 0 ::: ^F "a" 0 ::: id)))
]
]