implement glueing and composition for glue

3 years ago · ebeb58c0bc
--- a/examples/axiom_j.itt
+++ b/examples/axiom_j.itt
@ -0,0 +1,23 @@
 let
  sym : (A : Type) (x y : A) -> Path (\x -> A) x y -> Path (\x -> A) y x
    = λ A x y p i -> p (~ i)
 in let
  funext : (A : Type) (B : A -> Type) (f g : (x : A) -> B x) -> ((x : A) -> Path (\i -> B x) (f x) (g x)) -> Path (\i -> (x : A) -> B x) f g
    = λ A B f g h i x -> h x i
 in let
  i0IsI1 : Path (\x -> I) i0 i1
    = λ i -> i
 in let
  singContr : (A : Type) (a b : A) (p : Path (\j -> A) a b) -> Path (\i -> (x : A) * (Path (\j -> A) a x)) (a, \i -> a) (b, p)
    = λ A a b p i -> (p i, λ j -> p (i && j))
 in let
  transport : (A : I -> Type) (a : A i0) -> A i1
    = \A a -> comp A i0 (\i -> []) a
 in let
  Jay : (A : Type) (x : A)
        (P : (y : A) -> Path (\i -> A) x y -> Type)
        (d : P x (\i -> x))
        (y : A) (p : Path (\i -> A) x y)
     -> P y p
    = \A x P d y p -> transport (\i -> P (p i) (\j -> p (i && j))) d
 in Jay
--- a/examples/univalence.itt
+++ b/examples/univalence.itt
@ -0,0 +1,74 @@
 let Id : (A : Type) -> A -> A -> Type = \A x y -> Path (\i -> A) x y in
 let the : (A : Type) -> A -> A = \A x -> x in
 let
  fill : (i : I) (A : I -> Type)
         (phi : I) (u : (i : I) -> Partial phi (A i))
      -> Sub (A i0) phi (u i0) -> A i
    = \i A phi u a0 ->
      comp (\j -> A (i && j)) (phi || ~i) (\j -> [ phi -> u (i && j), ~i -> a0 ]) a0
 in let
  trans : (A : Type) (a b c : A)
       -> Path (\i -> A) a b
       -> Path (\i -> A) b c
       -> Path (\i -> A) a c
    = \A a b c p q i ->
      comp (\j -> A) (i || ~i)
           (\j -> [ ~i -> a, i -> q j ])
           (p i)
 in
 let isContr : Type -> Type
      = \A -> (x : A) * (y : A) -> Path (\i -> A) x y in
 let fiber : (T A : Type) -> (T -> A) -> A -> Type
      = \T A f y -> (x : T) * Path (\i -> A) y (f x) in
 let isEquiv : (T A : Type) -> (T -> A) -> Type
      = \T A f -> (y : A) -> isContr (fiber T A f y) in
 let idFun : (B : Type) -> B -> B = \A x -> x in
 let idEquiv : (B : Type) -> isEquiv B B (idFun B)
    = \B y -> ((y, \i -> y), \u -> \i -> (u.2 i, \j -> u.2 (i && j))) in
 let equiv : (A B : Type) -> Type
      = \A B -> (f : A -> B) * isEquiv A B f in
 let
  univalence : (A B : Type) -> equiv A B -> Path (\i -> Type) A B
    = \A B fun i -> Glue B (i || ~i) [~i -> A, i -> B] [~i -> fun, i -> (idFun B, idEquiv B)]
 in
 let idToEquiv : (A B : Type) -> Path (\i -> Type) A B -> equiv A B
      = \A B p -> comp (\i -> equiv A (p i)) i0 (\i -> []) (idFun A,
      idEquiv A)
 in
 let transp : (A B : Type) (p : Path (\i -> Type) A B) -> A -> B = \A B p -> comp (\i -> p i) i0 (\j -> []) in
 let
  univalenceBeta : (A B : Type) (f : equiv A B)
    -> Id (A -> B) (transp A B (univalence A B f)) f.1
    = \A B f i a ->
      let b : B = transp B B (\i -> B) (f.1 a) in
      let rem1 : Id B b (f.1 a) = \i -> fill ~i (\i -> B) i0 (\j -> []) (f.1 a) in
      let rem2 : Id B (transp B B (\i -> B) b) b = \i -> fill ~i (\i -> B) i0 (\j -> []) b in
      let goal : Id B (transp B B (\i -> B) b) (f.1 a) = 
            trans B (transp B B (\i -> B) b) b (f.1 a) rem2 rem1
      in goal i
 in
 let not : Bool -> Bool = if (\x -> Bool) ff tt in
 let notInv : (b : Bool) -> Id Bool b (not (not b)) = if (\x -> Id Bool x (not (not x))) (\i -> tt) (\i -> ff) in
 let trueNotFalse : (A : Type) -> Id Bool tt ff -> A =
  \A p -> comp (\i -> if (\b -> Type) (A -> A) A (p i)) i0 (\j -> []) (\x -> x) in
 let notEquiv : isEquiv Bool Bool not =
  let contract1 : (a : Bool) (b : Path (\i -> Bool) tt (not a)) -> Path (\i -> fiber Bool Bool not tt) (ff, \i -> tt) (a, b)
      = \a -> if (\a -> (b : Path (\i -> Bool) tt (not a)) -> Path (\i -> fiber Bool Bool not tt) (ff, \i -> tt) (a, b))
                (\b -> trueNotFalse (Path (\i -> fiber Bool Bool not tt) (ff, \i -> tt) (tt, b)) b)
                (\b i -> (ff, \j -> b (i && j)))
                a in
  let contract2 : (a : Bool) (b : Path (\i -> Bool) ff (not a)) -> Path (\i -> fiber Bool Bool not ff) (tt, \i -> ff) (a, b) =
        \a -> if (\a -> (b : Path (\i -> Bool) ff (not a)) -> Path (\i -> fiber Bool Bool not ff) (tt, \i -> ff) (a, b))
                (\b i -> (tt, \j -> b (i && j)))
                (\b -> trueNotFalse (Path (\i -> fiber Bool Bool not ff) (tt, \i -> ff) (ff, b)) (\j -> b ~j))
                a in
    \b -> if (\b -> isContr (fiber Bool Bool not b))
            ((ff, \i -> tt), \fiber -> contract1 fiber.1 fiber.2)
            ((tt, \i -> ff), \fiber -> contract2 fiber.1 fiber.2)
            b
 in the (Id Bool (not ff) tt) (\i -> transp Bool Bool (univalence Bool Bool (not, notEquiv)) ff)
--- a/src/Elab.hs
+++ b/src/Elab.hs
@ -42,14 +42,9 @@ check env (P.Span s e exp) wants =
    `catch` \er -> throwIO $ InSpan s e (UnifyError er)
 check env exp (VSub a fm@(toFormula -> Just phi) el) = do
  putStrLn $
    "checking cubical subtype of " ++ show a ++ " with φ = " ++ show phi
  tm <- check env exp a
  putStrLn $ "the expression is " ++ show tm
  for (addFormula phi env) \env -> do
    let tm' = eval env tm
    putStrLn $ "have " ++ show tm'
    unifyTC env tm' el
  pure (InclSub (quote a) (quote fm) (quote el) tm)
@ -95,7 +90,6 @@ check env (P.Partial fs) ty = do
    pure (fn, tn)
 check env exp (VPartial fm@(toFormula -> Just phi) a) = do
  print $ (phi, a)
  case addFormula phi env of
    [] -> pure $ System (FMap mempty)
    (x:xs) -> do
@ -115,7 +109,6 @@ check env (P.Lam s b) expected = do
      let t = Lam s I bd
          t' = eval env t
      print $ (Map.lookup "phi" (names env), t', t' @@ VI0)
      checkBoundary env [s] t'
        [ ([VI0], x)
        , ([VI1], y)
@ -230,7 +223,7 @@ infer env (P.IOr x y) = do
  y <- check env y VI
  pure (IOr x y, VI)
 infer env P.Path = do
 infer env P.Path =
  pure
    ( Lam "A" (quote index_t) $
        Lam "x" (App (Var "A") I0) $
@ -240,7 +233,7 @@ infer env P.Path = do
        VPi "x" (a @@ VI0) \_ ->
          VPi "y" (a @@ VI1) (const VType))
 infer env P.PartialT = do
 infer env P.PartialT =
  pure
    ( Lam "r" I $
        Lam "A" Type $
@ -248,8 +241,19 @@ infer env P.PartialT = do
    , VPi "I" VI \i ->
        VPi "A" VType (const VTypeω))
 infer env P.PartialP =
  pure
    ( Lam "r" I $
        Lam "A" (Partial (Var "r") Typeω) $
          PartialP (Var "r") (Var "A")
    , VPi "phi" VI \i ->
        VPi "A" (VPartial i VTypeω) (const VTypeω))
 infer env P.Comp = do
  let u_t a r = VPi "i" VI \i -> VPartial r (a @@ i)
  let
    u_t a r = VPi "i" VI \i -> VPartial r (a @@ i)
    index_t :: Value
    index_t = VPi "_" VI (const VType)
  pure
    ( Lam "A" (quote index_t) $
@ -264,7 +268,7 @@ infer env P.Comp = do
              a @@ VI1
    )
 infer env P.SubT = do
 infer env P.SubT =
  pure
    ( Lam "A" Type $
        Lam "phi" I $
@ -275,6 +279,69 @@ infer env P.SubT = do
          VPi "_" (VPartial phi a) (const VType)
    )
 infer env P.GlueTy =
  pure
    ( Lam "A" Type $
        Lam "phi" I $
          Lam "T" (Partial (Var "phi") Type) $
            Lam "e" (PartialP (Var "phi") (quote (equiv (VVar "T") (VVar "A")))) $
              GlueTy (Var "A") (Var "phi") (Var "T") (Var "e")
    , VPi "A" VType \a ->
        VPi "phi" VI \phi ->
          VPi "T" (VPartial phi VType) \t ->
            VPi "e" (VPartialP phi (equiv t a)) \_ ->
              VType
    )
 infer env P.Glue =
  pure
    ( Lam "A" Type $
        Lam "phi" I $
          Lam "T" (Partial (Var "phi") Type) $
            Lam "e" (PartialP (Var "phi") (quote (equiv (VVar "T") (VVar "A")))) $
              Lam "t" (PartialP (Var "phi") (Var "T")) $ 
                Lam "a" (Var "A") $
                  Glue (Var "A") (Var "phi") (Var "T") (Var "e") (Var "t") (Var "a")
    , VPi "A" VType \a ->
        VPi "phi" VI \phi ->
          VPi "T" (VPartial phi VType) \t ->
            VPi "e" (VPartialP phi (equiv t a)) \_ ->
              VPi "_" (VPartialP phi t) \_ ->
                VPi "_" a \_ -> VType
    )
 infer env P.Unglue =
  pure
    ( Lam "A" Type $
        Lam "phi" I $
          Lam "T" (Partial (Var "phi") Type) $
            Lam "e" (PartialP (Var "phi") (quote (equiv (VVar "T") (VVar "A")))) $
              Lam "g" (GlueTy (Var "A") (Var "phi") (Var "T") (Var "e")) $
                Unglue (Var "A") (Var "phi") (Var "T") (Var "e") (Var "g")
    , VPi "A" VType \a ->
        VPi "phi" VI \phi ->
          VPi "T" (VPartial phi VType) \t ->
            VPi "e" (VPartialP phi (equiv t a)) \e ->
              VPi "_" (VGlue a phi t e) \_ -> a
    )
 infer env P.Bool = pure (Bool, VType)
 infer env P.Tt   = pure (Tt, VBool)
 infer env P.Ff   = pure (Ff, VBool)
 infer env P.If =
  pure
    (Lam "P" (Pi "_" Bool Type) $
      Lam "x" (App (Var "P") Tt) $
        Lam "y" (App (Var "P") Ff) $
          Lam "b" Bool $
            If (Var "P") (Var "x") (Var "y") (Var "b")
    , VPi "P" (VPi "_" VBool (const VType)) \p ->
        VPi "_" (p @@ VTrue) \_ ->
          VPi "_" (p @@ VFalse) \_ ->
            VPi "x" VBool \x -> p @@ x)
 infer env (P.INot x) = (, VI) . INot <$> check env x VI
 infer env P.Lam{}    = error "can't infer type for lambda"
--- a/src/Eval.hs
+++ b/src/Eval.hs
@ -12,8 +12,6 @@ import Data.Typeable
 import Data.IORef
 import Data.Maybe
 import Debug.Trace
 import GHC.Stack
 import qualified Presyntax as P
@ -24,6 +22,7 @@ import Syntax
 import System.IO.Unsafe (unsafePerformIO)
 import Systems
 import Debug.Trace (traceShowId)
 iand :: Value -> Value -> Value
 iand = \case
@ -52,26 +51,37 @@ inot (VINot x) = x
 inot x = VINot x
 (@@) :: Value -> Value -> Value
 VNe hd xs @@ vl = VNe hd (PApp vl:xs)
 VLam _ _ k        @@ vl = k vl
 VEqGlued a b      @@ vl = VEqGlued (a @@ vl) (b @@ vl)
 VOfSub a phi u0 x @@ vl = x @@ vl
 VSystem fs        @@ vl = mapVSystem (VSystem fs) (@@ vl)
 f @@ _  = error $ "can't apply argument to " ++ show f
 VNe hd xs                   @@ vl = VNe hd (PApp vl:xs)
 VLam _ _ k                  @@ vl = k vl
 VEqGlued a b                @@ vl = VEqGlued (a @@ vl) (b @@ vl)
 VOfSub (VPi _ _ k) phi u0 x @@ vl = VOfSub (k vl) phi (u0 @@ vl) (x @@ vl)
 VSystem fs                  @@ vl = mapVSystem (VSystem fs) (@@ vl)
 VIf (VLam s d k) c t b      @@ vl = VIf (VLam s d (ap . force . k)) (c @@ vl) (t @@ vl) b where
  ap (VPi _ _ r) = r vl
  ap _ = error "type error when pushing application into if"
 f @@ _  = error $ "\ncan't apply argument to " ++ show f
 proj1 :: Value -> Value
 proj1 (VPair x _) = x
 proj1 (VEqGlued x y) = VEqGlued (proj1 x) (proj1 y)
 proj1 (VNe s xs) = VNe s (PProj1:xs)
 proj1 (VOfSub (VSigma _ d _) phi u0 x) = VOfSub d phi (proj1 u0) (proj1 x)
 proj1 v@VSystem{} = mapVSystem v proj1
 proj1 (VIf (VLam s d k) c t b) = VIf (VLam s d (proj1t . k)) (proj1 c) (proj1 t) b where
  proj1t (VSigma _ d _) = d
  proj1t _ = error "type error when pushing proj1 into if"
 proj1 x = error $ "can't proj1 " ++ show x
 proj2 :: Value -> Value
 proj2 (VPair _ y) = y
 proj2 (VEqGlued x y) = VEqGlued (proj1 x) (proj1 y)
 proj2 (VEqGlued x y) = VEqGlued (proj2 x) (proj2 y)
 proj2 (VNe s xs) = VNe s (PProj2:xs)
 proj2 (VOfSub (VSigma _ d r) phi u0 x) =
  VOfSub (r (proj1 x)) phi (proj2 u0) (proj2 x)
 proj2 v@VSystem{} = mapVSystem v proj2
 proj2 (VIf (VLam s d k) c t b) = VIf (VLam s d (proj2t . k)) (proj2 c) (proj2 t) b where
  proj2t (VSigma _ d r) = r (VIf (VLam s VBool (const d)) (proj1 c) (proj1 t) b)
  proj2t _ = error "type error when pushing proj1 into if"
 proj2 x = error $ "can't proj2 " ++ show x
 pathp :: Env -> Value -> Value -> Value -> Value -> Value -> Value
@ -81,12 +91,17 @@ pathp env p x y f@(VLine _a _x _y e) i =
    Just P.Top -> VEqGlued (e i) y
    _          -> e i
 pathp env p x y (VEqGlued e e') i = VEqGlued (pathp env p x y e i) (pathp env p x y e' i)
 pathp env p x y (VNe hd sp) i =
  case reduceCube env i of
    Just P.Bot -> VEqGlued (VNe hd (PPathP p x y i:sp)) x
    Just P.Top -> VEqGlued (VNe hd (PPathP p x y i:sp)) y
    _ | quote x == quote y -> VEqGlued (VNe hd (PPathP p x y i:sp)) x
    _ -> VNe hd (PPathP p x y i:sp)
 pathp env p x y (VOfSub _ _ _ v) i = pathp env p x y v i
 pathp env p x y v@VSystem{} i = mapVSystem v (\f -> pathp env p x y f i)
 pathp env p x y f i = error $ "Invalid pathP " ++ show f ++ " @@ " ++ show i 
 comp :: Env -> Value -> Formula -> Value -> Value -> Value
 comp env a@(VLam ivar VI fam) phi u a0 = glue $ go (fam (VVar "woopsie")) phi u a0 where
@ -94,7 +109,7 @@ comp env a@(VLam ivar VI fam) phi u a0 = glue $ go (fam (VVar "woopsie")) phi u
  stuck = VComp a (toValue phi) u a0
  glue :: Value -> Value
  glue = VOfSub (fam VI1) (toValue' env phi) (u @@ VI1)
  glue = VOfSub (fam VI1) (toValue phi) (u @@ VI1)
  go :: HasCallStack => Value -> Formula -> Value -> Value -> Value
  go VPi{} phi u a0 =
@ -148,6 +163,35 @@ comp env a@(VLam ivar VI fam) phi u a0 = glue $ go (fam (VVar "woopsie")) phi u
                                           ])
              (pathp env (ai0 @@ VI0) u0 v0 p0 j)
  go VGlue{} psi b b0 =
    let
      base i    = let VGlue base _ _ _   = force $ fam i in base
      phi i     =
        case force (fam i) of
          VGlue _ phi _ _    -> fromJust (reduceCube env phi)
          x -> error (show x)
      types i   = let VGlue _ _ types _  = force $ fam i in types
      equivs i  = let VGlue _ _ _ equivs = force $ fam i in equivs
      a i = mapVSystem (b @@ i) (unglue (base i) (phi i) (types i) (equivs i))
      a0  = unglue (base VI0) (phi VI0) (types VI0) (equivs VI0) b0 
      del = faceForall phi
      a1' = comp env (VLam "i" VI base)  psi (VLam "i" VI a)      a0
      t1' = comp env (VLam "i" VI types) psi (VLam "i" VI (b @@)) b0
      omega   = pres env types base (flip mapVSystem proj1 . equivs) psi b b0
      t1alpha = opEquiv env (base VI1) (types VI1) (equivs VI1) (orFormula [del, psi]) ts ps a1'
      (t1, alpha) = (proj1 t1alpha, proj2 t1alpha)
      ts = VSystem (FMap (Map.fromList [(del, t1'), (psi, b @@ VI1)]))
      ps = VSystem (FMap (Map.fromList [(del, omega), (psi, VLine (VLam "j" VI \_ -> base VI1) a1' a1' (\j -> a1'))]))
      a1 = comp env (VLam "j" VI (const (base VI1))) (orFormula [phi VI1, psi]) (VLam "j" VI \j -> a1_sys j) a1'
      a1_sys j = VSystem (FMap (Map.fromList [(phi VI1, pathp env (base VI1) a1' (mapVSystem (equivs VI1) proj1) alpha j), (psi, a VI1)]))
      b1 = introGlue (base VI1) (phi VI1) (types VI1) (equivs VI1) t1 a1
    in b1
  go VBool{} _ _ a0 = a0
  go a P.Top u a0 = u @@ VI1
  go a phi u a0 = stuck
@ -158,6 +202,50 @@ comp env va phi u a0 =
  where
    phi' = toValue phi
 opEquiv :: Env -> Value -> Value -> Value -> Formula -> Value -> Value -> Value -> Value
 opEquiv env aT tT f phi t p a = VOfSub ty (toValue phi) (VPair t p) v where
  fun = proj1 f
  ty  = VSigma "x" tT \x -> VPath (VLam "i" VI (const aT)) a (fun @@ x)
  sys = Map.singleton phi (VPair t p)
  v   = contr env ty (proj2 f @@ a) phi (VSystem (FMap sys))
 force :: Value -> Value
 force (VEqGlued x _) = force x
 force (VOfSub _ _ _ x) = force x
 force x = x
 faceForall :: (Value -> Formula) -> Formula
 faceForall k = go (k (VVar "$elim")) where
  go (P.Is0 "$elim") = P.Bot
  go (P.Is1 "$elim") = P.Bot
  go (P.Or a b)      = orFormula [go a, go b]
  go (P.And a b)     = andFormula [go a, go b]
  go x = x
 pres :: Env -> (Value -> Value) -> (Value -> Value) -> (Value -> Value) -> Formula -> Value -> Value -> Value
 pres env tT tA f phi t t0 = VOfSub (VPath (tA VI1) c1 c2) (toValue phi) base (VLine (tA VI1) c1 c2 cont) where
  c1   = comp env (VLam "i" VI tA) phi (VLam "i" VI \j -> mapVSystem t (f j @@)) (f VI0 @@ t0)
  c2   = f VI1 @@ comp env (VLam "i" VI tA) phi t t0
  base = VLine (tA VI1) (f VI1 @@ (t @@ VI1)) (f VI1 @@ (t @@ VI1)) (\i -> f VI1 @@ (t @@ VI1))
  cont j =
    let v i = fill env i tT phi t t0
        form = orFormula [phi, fromJust (reduceCube env j)]
        a0 = f VI0 @@ t0
     in comp env (VLam "I" VI tA) form
          (VLam "I" VI (\j -> VSystem (FMap (Map.fromList [(form, f j @@ v j)]))))
          a0
 contr :: Env -> Value -> Value -> Formula -> Value -> Value
 contr env a aC phi u =
  comp env (VLam "i" VI (const a)) phi
    (VLam "i" VI (pathp env a u (proj1 aC) (proj2 aC @@ u)))
    (proj1 aC)
 -- t : Partial phi T
 -- T : Type
 -- a : A
 -- f : Equiv T A
 mkVSystem :: Map.Map Formula Value -> Value
 mkVSystem mp
  | Just e <- Map.lookup P.Top mp = e
@ -189,6 +277,19 @@ evalSystem env face = mk . Map.fromList . mapMaybe (uncurry go) . Map.toList $ f
    [(_, x)] -> x
    _ -> mkVSystem x
 glue :: Value -> Formula -> Value -> Value -> Value
 -- glue baseT P.Top types _equivs = types
 glue baseT phi types equivs    = VGlue baseT (toValue phi) types equivs
 introGlue :: Value -> Formula -> Value -> Value -> Value -> Value -> Value
 introGlue baseT P.Top types equivs t a = t
 introGlue baseT phi types equivs t a = VGlueIntro baseT (toValue phi) types equivs t a
 unglue :: Value -> Formula -> Value -> Value -> Value -> Value
 unglue baseT P.Top types equivs b = mapVSystem equivs ((@@ b) . proj1)
 unglue baseT phi types equivs val =
  VOfSub baseT (toValue phi) (mapVSystem equivs ((@@ val) . proj1)) (VGlueElim baseT (toValue phi) types equivs val)
 eval :: Env -> Term -> Value
 eval env = \case
  Var v ->
@ -228,6 +329,7 @@ eval env = \case
  Path p x y      -> VPath (eval env p) (eval env x) (eval env y)
  Partial r a     -> VPartial (eval env r) (eval env a)
  PartialP r a    -> VPartialP (eval env r) (eval env a)
  PathI p x y s e -> VLine (eval env p) (eval env x) (eval env y) (\ a -> eval env{ names = Map.insert s (VI, a) (names env) } e)
  PathP p x y f i -> pathp env (eval env p) (eval env x) (eval env y) (eval env f) (eval env i)
@ -246,6 +348,50 @@ eval env = \case
  System fs       -> evalSystem env (getSystem fs)
  GlueTy a phi types equivs ->
    let phi' = eval env phi in
    case reduceCube env phi' of
      Just formula -> glue (eval env a) formula (eval env types) (eval env equivs)
      Nothing -> VGlue (eval env a) phi' (eval env types) (eval env equivs)
  Glue a phi types equivs t a0 ->
    let phi' = eval env phi
        t' = eval env t
        a0' = eval env a0
        types' = eval env types
        equivs' = eval env equivs
        a' = eval env a
    in
    case reduceCube env phi' of
      Just formula -> introGlue a' formula types' equivs' t' a0'
      Nothing      -> VGlueIntro a' phi' types' equivs' t' a0'
  Unglue a phi types equivs val ->
    let phi' = eval env phi
        val' = eval env val
        types' = eval env types
        equivs' = eval env equivs
        a' = eval env a
    in
    case reduceCube env phi' of
      Just formula -> unglue a' formula types' equivs' val'
      Nothing      -> VGlueElim a' phi' types' equivs' val'
  If p x y t -> elimBool (eval env p) (eval env x) (eval env y) (eval env t)
  Tt -> VTrue
  Ff -> VFalse
  Bool -> VBool
 elimBool :: Value -> Value -> Value -> Value -> Value
 elimBool _ x _ (VEqGlued _ VTrue) = x
 elimBool _ x _ (VOfSub _ _ _ VTrue) = x
 elimBool _ x _ VTrue = x
 elimBool _ _ y (VEqGlued _ VFalse) = y
 elimBool _ _ y (VOfSub _ _ _ VFalse) = y
 elimBool _ _ y VFalse = y
 elimBool p x y t = VIf p x y t
 data UnifyError
  = Mismatch       Value Value
@ -320,10 +466,12 @@ unify env (VSigma x d r) (VSigma _ d' r') = do
  unify env (r (VVar x)) (r' (VVar x))
 unify env VType VType = pure ()
 unify env VI  VI      = pure ()
 unify env VBool VBool = pure ()
 unify env VI  VI = pure ()
 unify env (VPair a b) e = unify env a (proj1 e) *> unify env b (proj2 e)
 unify env e (VPair a b) = unify env a (proj1 e) *> unify env b (proj2 e)
 unify env (VPair a b) (VPair c d) = unify env a c *> unify env b d
 unify env (VPath a x y) (VPath a' x' y') = unify env a a' *> unify env x x' *> unify env y y'
 unify env (VComp a phi u a0) (VComp a' phi' u' a0') =
  traverse_ (uncurry (unify env))
@ -343,15 +491,23 @@ unify env (VSystem fs) vl
  | ((_, vl'):_) <-
      Map.toList (Map.filterWithKey (\f _ -> isTrue (toValue' env f)) (getSystem fs))
  = unify env vl' vl
  | Map.null (getSystem fs) = pure ()
 unify env vl (VSystem fs)
  | ((_, vl'):_) <-
    Map.toList (Map.filterWithKey (\f _ -> isTrue (toValue' env f)) (getSystem fs))
  = unify env vl' vl
  | Map.null (getSystem fs) = pure ()
 unify env VType VTypeω = pure ()
 unify env VTypeω VTypeω = pure ()
 unify env (VGlue _ VI1 b _) x = unify env b x
 unify env VTrue VTrue = pure ()
 unify env VFalse VFalse = pure ()
 unify env (VIf p a b c) (VIf p' a' b' c') = traverse_ (uncurry (unify env)) [(p, p'), (a, a'), (b, b'), (c, c')]
 unify env x y =
  case sameCube env x y of
    Just True -> pure ()
@ -422,6 +578,10 @@ isPartialType f p@(VPartial x y) =
  case toFormula x of
    Just x -> pure (x, y)
    Nothing -> throwIO $ NotPartialType f p
 isPartialType f p@(VPartialP x y) =
  case toFormula x of
    Just x -> pure (x, y)
    Nothing -> throwIO $ NotPartialType f p
 isPartialType f x = throwIO $ NotPartialType f x
 getVar :: IO Value
@ -451,7 +611,7 @@ fill env i a phi u a0 =
    a0
  where
    uiand j = u @@ (i `iand` j)
    ifc = fromJust (reduceCube env i)
    ifc = fromMaybe P.Bot $ (reduceCube env i)
 toValue :: Formula -> Value
 toValue P.Top = VI1
@ -475,8 +635,17 @@ toValue' env (P.Is0 x) =
 toValue' env (P.Is1 x) =
  case Map.lookup x (names env) of
    Just (VI, x) -> x
    _ -> error $ "type error in toValue'"
    vl -> error $ "type error in toValue': Is1 " ++ show x ++ ": " ++ show vl
 isTrue :: Value -> Bool
 isTrue VI1 = True
 isTrue _ = False
 equiv :: Value -> Value -> Value
 equiv t a = VSigma "f" (VPi "_" t (const a)) \f -> isEquiv t a f
 isEquiv :: Value -> Value -> Value -> Value
 isEquiv t a f = VPi "y" a \y -> isContr (VSigma "x" t \x -> VPath (VLam "_" VI (const a)) y (f @@ x))
 isContr :: Value -> Value
 isContr t = VSigma "x" t \x -> VPi "y" t \y -> VPath (VLam "_" VI (const t)) x y
--- a/src/Main.hs
+++ b/src/Main.hs
@ -20,6 +20,7 @@ import System.Console.Haskeline (runInputT, defaultSettings, getInputLine)
 import System.Exit
 import Systems (formulaOfFace, Face)
 import System.Environment
 showTypeError :: Maybe [String] -> Elab.TypeError -> String
 showTypeError lines (NotInScope l_c)       = "Variable not in scope: " ++ l_c
@ -63,7 +64,14 @@ makeRange line (_, sc) (_, ec) = line ++ "\n" ++ replicate (sc + 1) ' ' ++ repli
 main :: IO ()
 main = do
  code <- readFile "test.itt"
  t <- getArgs
  case t of
    [file] -> Main.check file
    _ -> repl
 check :: FilePath -> IO ()
 check file = do
  code <- readFile file
  let
    ste e = do
      putStrLn $ showTypeError (Just (lines code)) e
@ -72,7 +80,7 @@ main = do
    Left e -> print e
    Right x -> do
      (tm, _) <- infer (Env mempty) x `catch` ste `catch` (ste . UnifyError)
      print tm
      print (eval (Env mempty) tm)
 repl :: IO ()
 repl = runInputT defaultSettings (go (Env mempty)) where
@ -93,7 +101,7 @@ repl = runInputT defaultSettings (go (Env mempty)) where
        Right (Assume vs) ->
          let
            loop env ((v, t):vs) = do
              tm <- liftIO $ check env t VTypeω
              tm <- liftIO $ Elab.check env t VTypeω
              let ty = eval env tm
              loop env{ names = Map.insert v (ty, VVar v) (names env) } vs
            loop env [] = go env
@ -111,9 +119,9 @@ repl = runInputT defaultSettings (go (Env mempty)) where
          go env
        Right (Declare n t e) -> do
          (do
            t <- liftIO $ check env t VTypeω
            t <- liftIO $ Elab.check env t VTypeω
            let t' = eval env t
            b <- liftIO $ check env e t'
            b <- liftIO $ Elab.check env e t'
            let b' = eval env b
            go env{ names = Map.insert n (t', b') (names env) })
          `catch` \e -> (liftIO $ putStrLn (showTypeError (Just [i]) e)) *> go env
--- a/src/Presyntax.hs
+++ b/src/Presyntax.hs
@ -30,12 +30,24 @@ data Exp
  -- Formulas, partial elements, and the type of formulas
  | Partial [(Formula, Exp)]
  | PartialT
  | PartialP
  -- Compositions
  | Comp
  -- Cubical subtypes
  | SubT
  -- Glueing
  | GlueTy
  | Glue
  | Unglue
  -- Bools
  | Bool
  | Tt
  | Ff
  | If
  deriving (Eq, Show, Ord)
 data Formula
--- a/src/Presyntax/Lexer.hs
+++ b/src/Presyntax/Lexer.hs
@ -13,7 +13,8 @@ data TokenClass
  | Tok_type
  | Tok_typeω
  | Tok_path
  | Tok_phi
  | Tok_Partial
  | Tok_PartialP
  | Tok_sub
  | Tok_comp
  | Tok_tr
@ -22,6 +23,15 @@ data TokenClass
  | Tok_I0
  | Tok_I1
  | Tok_Glue
  | Tok_glue
  | Tok_unglue
  | Tok_bool
  | Tok_tt
  | Tok_ff
  | Tok_if
  | Tok_oparen
  | Tok_cparen
@ -179,10 +189,21 @@ lexString = go 0 0 0 where
  finishIdent c
    | T.pack "Type" == c    = Tok_type
    | T.pack "Typeω" == c || T.pack "Pretype" == c = Tok_typeω
    | T.pack "Path" == c    = Tok_path
    | T.pack "Partial" == c = Tok_phi
    | T.pack "Sub" == c     = Tok_sub
    | T.pack "comp" == c    = Tok_comp
    | T.pack "Path" == c     = Tok_path
    | T.pack "Partial" == c  = Tok_Partial
    | T.pack "PartialP" == c = Tok_PartialP
    | T.pack "Sub" == c      = Tok_sub
    | T.pack "comp" == c     = Tok_comp
    | T.pack "Glue" == c    = Tok_Glue
    | T.pack "glue" == c    = Tok_glue
    | T.pack "unglue" == c  = Tok_unglue
    | T.pack "Bool" == c    = Tok_bool
    | T.pack "tt" == c      = Tok_tt
    | T.pack "ff" == c      = Tok_ff
    | T.pack "if" == c      = Tok_if
    | T.pack "tr" == c      = Tok_tr
    | T.pack "I" == c       = Tok_I
    | T.pack "i0" == c      = Tok_I0
--- a/src/Presyntax/Parser.hs
+++ b/src/Presyntax/Parser.hs
@ -185,18 +185,36 @@ exprConj = attachPos $
 atom0 :: Parser Exp
 atom0 = attachPos $
       fmap (Var . T.unpack) var
   <|> fmap (const Type)     (expect Tok_type)
   <|> fmap (const Typeω)    (expect Tok_typeω)
   <|> fmap (const I)        (expect Tok_I)
   <|> fmap (const I0)       (expect Tok_I0)
   <|> fmap (const I1)       (expect Tok_I1)
   <|> fmap (const Path)     (expect Tok_path)
   <|> fmap (const SubT)     (expect Tok_sub)
   <|> fmap (const PartialT) (expect Tok_phi)
   <|> fmap (const Comp)     (expect Tok_comp)
   <|> fmap INot           (expect Tok_not *> atom)
   <|> keywords
   <|> fmap INot             (expect Tok_not *> atom)
   <|> parens pair
   <|> square (Partial <$> (system <|> pure []))
  where
    table = [ (Type,      Tok_type)
            , (Typeω,     Tok_typeω)
            , (I,         Tok_I)
            , (I0,        Tok_I0)
            , (I1,        Tok_I1)
            , (Path,      Tok_path)
            , (SubT,      Tok_sub)
            , (PartialT,  Tok_Partial)
            , (PartialP,  Tok_PartialP)
            , (Comp,      Tok_comp)
            , (SubT,      Tok_sub)
            , (Comp,      Tok_comp)
            , (GlueTy,    Tok_Glue)
            , (Glue,      Tok_glue)
            , (Unglue,    Tok_unglue)
            , (Bool,      Tok_bool)
            , (Tt,        Tok_tt)
            , (Ff,        Tok_ff)
            , (If,        Tok_if)
            ]
    keyword (x, y) = fmap (const x) (expect y)
    keywords = foldr ((<|>) . keyword) empty table
 atom :: Parser Exp
 atom = attachPos $
@ -282,3 +300,4 @@ formula = conjunction where
     <|> (Is0 . T.unpack) <$> (expect Tok_not *> var)
     <|> Top <$ expect Tok_I1
     <|> Bot <$ expect Tok_I0
     <|> parens conjunction
--- a/src/Syntax.hs
+++ b/src/Syntax.hs
@ -42,9 +42,33 @@ data Term
  | System (System Term)
  | Partial Term Term
  | PartialP Term Term
  | Comp Term Term Term Term
  | Sub Term Term Term
  | InclSub Term Term Term Term
  | GlueTy
      Term -- Base type
      Term -- Extent
      Term -- Partial types
      Term -- Partial equivs
  | Glue
      Term -- Base
      Term -- Extent
      Term -- Partial types
      Term -- Partial equivs
      Term -- t
      Term -- a
  | Unglue
      Term -- Base
      Term -- Extent
      Term -- Partial types
      Term -- Partial equivs
      Term -- glued value
  | Bool
  | Tt | Ff
  | If Term Term Term Term
  deriving (Eq, Ord)
 instance Show Term where
@ -53,13 +77,17 @@ instance Show Term where
      Var s -> showString s
      System fs -> showListWith showPE (Map.toList (getSystem fs))
      -- ew
      App (App (App (Lam _ _ (Lam _ _ (Lam _ _ Path{}))) a) x) y -> showsPrec p (Path a x y)
      App (App (App (Lam _ _ (Lam _ _ (Lam _ _ Sub{}))) a) x) y -> showsPrec p (Sub a x y)
      App (App (Lam _ _ (Lam _ _ Partial{})) phi) r -> showsPrec p (Partial phi r)
      App (App (App (Lam _ _ (Lam _ _ (Lam _ _ Path{}))) a) x) y   -> showsPrec p (Path a x y)
      App (App (App (Lam _ _ (Lam _ _ (Lam _ _ Sub{}))) a) x) y    -> showsPrec p (Sub a x y)
      App (App (Lam _ _ (Lam _ _ Partial{})) phi) r                -> showsPrec p (Partial phi r)
      App (App (Lam _ _ (Lam _ _ PartialP{})) phi) r               -> showsPrec p (PartialP phi r)
      App (App (App (App (Lam _ _ (Lam _ _ (Lam _ _ (Lam _ _ Comp{})))) a) phi) u) a0 ->
        showsPrec p (Comp a phi u a0)
      App (App (App (App (Lam _ _ (Lam _ _ (Lam _ _ (Lam _ _ GlueTy{})))) a) phi) u) a0 ->
        showsPrec p (GlueTy a phi u a0)
      App f x -> showParen (p >= app_prec) $
        showsPrec fun_prec f
        . showChar ' '
@ -131,13 +159,27 @@ instance Show Term where
      INot s -> showChar '~' . showsPrec p s
      Path a x y -> showsPrec p (App (App (App (Var "Path") a) x) y)
      Sub a x y -> showsPrec p (App (App (App (Var "Sub") a) x) y)
      Partial r a -> showsPrec p (App (App (Var "Partial") r) a)
      Path a x y       -> showApps p (Var "Path") [a, x, y]
      Sub a x y        -> showApps p (Var "Sub") [a, x, y]
      InclSub _a _phi _u0 a0 -> showsPrec p a0
      Comp a I0 (Lam _ I (System (FMap (Map.null -> True)))) a0 -> showsPrec p (foldl App (Var "transp") [a, a0])
      Comp a phi u a0 -> showsPrec p (foldl App (Var "comp") [a, phi, u, a0])
      GlueTy a phi t e -> showApps p (Var "Glue") [a, phi, t, e]
      Glue base phi ty te t a ->
        showApps p (Var "glue") [phi, t, a]
      Unglue base phi ty te a ->
        showApps p (Var "unglue") [a]
      Partial r a -> showApps p (Var "Partial") [r, a]
      PartialP r a -> showApps p (Var "PartialP") [r, a]
      Comp a phi u a0 -> showApps p (Var "comp") [a, phi, u, a0]
      If _ Ff Tt d -> showApps p (Var "not") [d]
      If _ b c d -> showApps p (Var "if") [b, c, d]
      Bool -> showString "Bool"
      Tt -> showString "tt"
      Ff -> showString "ff"
      PathI a x y s b -> showParen (p >= fun_prec) $
        showString ("λ " ++ s ++ " -> ")
@ -163,6 +205,9 @@ instance Show Term where
      or_prec     = 3
      fun_prec    = 1
 showApps :: Int -> Term -> [Term] -> ShowS
 showApps p f xs = showsPrec p (foldl App f xs)
 showPE :: (Formula, Term) -> String -> String
 showPE (f, t) = shows f . showString " -> " . shows t
@ -188,8 +233,18 @@ data Value
  | VPath Value Value Value
  | VSub Value Value Value
  | VPartial Value Value
  | VPartialP Value Value
  | VComp Value Value Value Value
  | VGlue      Value Value Value Value
  | VGlueIntro Value Value Value Value Value Value
  | VGlueElim  Value Value Value Value Value 
  | VBool
  | VTrue
  | VFalse
  | VIf Value Value Value Value
 data Proj
  = PApp Value
  | PPathP Value Value Value Value
@ -227,6 +282,7 @@ quote = go mempty where
  go scope (VPath a x y) = Path (go scope a) (go scope x) (go scope y)
  go scope (VSub a x y) = Sub (go scope a) (go scope x) (go scope y)
  go scope (VPartial r a) = Partial (go scope r) (go scope a)
  go scope (VPartialP r a) = PartialP (go scope r) (go scope a)
  go scope (VComp a b c d) = Comp (go scope a) (go scope b) (go scope c) (go scope d)
  go scope (VEqGlued e _) = go scope e
@ -237,6 +293,17 @@ quote = go mempty where
  go scope (VSystem (FMap fs)) = System (FMap (fmap (go scope) fs))
  go scope (VOfSub _ _ _ x) = go scope x
  go scope (VGlue a phi tys eqvs) = GlueTy (go scope a) (go scope phi) (go scope tys) (go scope eqvs)
  go scope (VGlueIntro base phi tys eqvs t a) =
    Glue (go scope base) (go scope phi) (go scope tys) (go scope eqvs) (go scope t) (go scope a)
  go scope (VGlueElim base phi tys eqvs a) =
    Unglue (go scope base) (go scope phi) (go scope tys) (go scope eqvs) (go scope a)
  go scope VBool = Bool
  go scope VTrue = Tt
  go scope VFalse = Ff
  go scope (VIf a b c d) = If (go scope a) (go scope b) (go scope c) (go scope d)
  goSpine :: Set String -> Term -> Proj -> Term
  goSpine scope t (PApp x) = App t (go scope x)
  goSpine scope t (PPathP a x y i) = PathP (go scope a) (go scope x) (go scope y) t (go scope i)
--- a/src/Systems.hs
+++ b/src/Systems.hs
@ -94,4 +94,4 @@ emptySystem :: System a
 emptySystem = FMap mempty
 mapSystem :: System a -> (a -> b) -> System b
 mapSystem (FMap x) f = FMap (fmap f x)
 mapSystem (FMap x) f = FMap (Map.filterWithKey (\f _ -> f /= Bot) (fmap f x))
--- a/test.itt
+++ b/test.itt
@ -1,79 +0,0 @@
 {- {- let
  sym : (A : Type) (x y : A) -> Path (\x -> A) x y -> Path (\x -> A) y x
    = λ A x y p i -> p (~ i)
 in let
  funext : (A : Type) (B : A -> Type) (f g : (x : A) -> B x) -> ((x : A) -> Path (\i -> B x) (f x) (g x)) -> Path (\i -> (x : A) -> B x) f g
    = λ A B f g h i x -> h x i
 in let
  i0IsI1 : Path (\x -> I) i0 i1
    = λ i -> i
 in let
  singContr : (A : Type) (a b : A) (p : Path (\j -> A) a b) -> Path (\i -> (x : A) * (Path (\j -> A) a x)) (a, \i -> a) (b, p)
    = λ A a b p i -> (p i, λ j -> p (i && j))
 in let
  transport : (A : I -> Type) (a : A i0) -> A i1
    = \A a -> comp A i0 (\i -> []) a
 in let
  Jay : (A : Type) (x : A)
        (P : (y : A) -> Path (\i -> A) x y -> Type)
        (d : P x (\i -> x))
        (y : A) (p : Path (\i -> A) x y)
     -> P y p
    = \A x P d y p -> transport (\i -> P (p i) (\j -> p (i && j))) d
 in -}
 let
  fill : (i : I) (A : I -> Type)
         (phi : I) (u : (i : I) -> Partial phi (A i))
      -> Sub (A i0) phi (u i0) -> A i
    = \i A phi u a0 ->
      comp (\j -> A (i && j)) (phi || ~i) (\j -> [ phi -> u (i && j), ~i -> a0 ]) a0
 in let
  trans : (A : Type) (a b c : A)
       -> Path (\i -> A) a b
       -> Path (\i -> A) b c
       -> Path (\i -> A) a c
    = \A a b c p q i ->
      comp (\j -> A) (i || ~i)
           (\j -> [ ~i -> a, i -> q j ])
           (p i)
 in let
  elimI : (P : I -> Type)
          (a : P i0)
          (b : P i1)
       -> Path P a b
       -> (i : I) -> P i
    = \P a b p i -> p i
 in let
  contrI : (i : I) -> Path (\i -> I) i0 i
    = \i -> elimI (\x -> Path (\i -> I) i0 x) (\i -> i0) (\i -> i) (\i j -> i && j) i
 in let
  IisContr : (i : I) * ((j : I) -> Path (\i -> I) i j)
    = (i0, contrI)
 in let
  compPath : (A : I -> Type)
             (phi : I) (u : (i : I) -> Partial phi (A i))
          -> (a0 : Sub (A i0) phi (u i0)) -> Path A a0 (comp A phi u a0)
    = \A phi u a0 j -> fill j A phi u a0
 in compPath -}
 let
  fill : (i : I) (A : I -> Type)
         (phi : I) (u : (i : I) -> Partial phi (A i))
      -> Sub (A i0) phi (u i0) -> A i
    = \i A phi u a0 ->
      comp (\j -> A (i && j)) (phi || ~i) (\j -> [ phi -> u (i && j), ~i -> a0 ]) a0
 in 
 let
  pres : (A : I -> Type)
         (T : I -> Type)
         (f : (i : I) -> T i -> A i)
         (phi : I)
         (t : (i : I) -> Partial phi (T i))
         (t0 : Sub (T i0) phi (t i0))
      -> (let c1 : A i1 = comp A phi (\j -> [phi -> f j (t j)]) (f i0 t0) in
          let c2 : A i1 = f i1 (comp T phi (\j -> [phi -> t j]) t0) in
            Sub (Path (\i -> A i1) c1 c2) phi (\j -> f i1 (t i1)))
  = \A T f phi t t0 j ->
      let v : (i : I) -> T i = \i -> fill i T phi (\j -> [phi -> t j]) t0
       in comp A (phi || j) (\u -> [phi || j -> f u (v u)]) (f i0 t0)
 in pres