Elim.compare0 infers the type

instead of calling computeElimType over and over. now there's just one
at the start
This commit is contained in:
rhiannon morris 2023-08-27 19:05:25 +02:00
parent 3e3bf1b67f
commit 72609bc12f

View file

@ -173,7 +173,7 @@ parameters (defs : Definitions)
(E e, Lam b {}) => eta s.loc e b
(Lam b {}, E e) => eta s.loc e b
(E e, E f) => Elim.compare0 ctx e f
(E e, E f) => ignore $ Elim.compare0 ctx e f
(Lam {}, t) => wrongType t.loc ctx ty t
(E _, t) => wrongType t.loc ctx ty t
@ -197,7 +197,7 @@ parameters (defs : Definitions)
compare0 ctx fst sFst tFst
compare0 ctx (sub1 snd (Ann sFst fst fst.loc)) sSnd tSnd
(E e, E f) => Elim.compare0 ctx e f
(E e, E f) => ignore $ Elim.compare0 ctx e f
(Pair {}, E _) => clashT s.loc ctx ty s t
(E _, Pair {}) => clashT s.loc ctx ty s t
@ -214,7 +214,7 @@ parameters (defs : Definitions)
-- t ∈ ts is in the typechecker, not here, ofc
(Tag t1 {}, Tag t2 {}) =>
unless (t1 == t2) $ clashT s.loc ctx ty s t
(E e, E f) => Elim.compare0 ctx e f
(E e, E f) => ignore $ Elim.compare0 ctx e f
(Tag {}, E _) => clashT s.loc ctx ty s t
(E _, Tag {}) => clashT s.loc ctx ty s t
@ -241,7 +241,7 @@ parameters (defs : Definitions)
-- Γ ⊢ succ s = succ t :
(Succ s' {}, Succ t' {}) => compare0 ctx nat s' t'
(E e, E f) => Elim.compare0 ctx e f
(E e, E f) => ignore $ Elim.compare0 ctx e f
(Zero {}, Succ {}) => clashT s.loc ctx nat s t
(Zero {}, E _) => clashT s.loc ctx nat s t
@ -262,7 +262,7 @@ parameters (defs : Definitions)
-- Γ ⊢ [s] = [t] : [π.A]
(Box s' {}, Box t' {}) => compare0 ctx ty' s' t'
(E e, E f) => Elim.compare0 ctx e f
(E e, E f) => ignore $ Elim.compare0 ctx e f
(Box {}, t) => wrongType t.loc ctx ty t
(E _, t) => wrongType t.loc ctx ty t
@ -273,7 +273,7 @@ parameters (defs : Definitions)
-- e.g. an abstract value in an abstract type, bound variables, …
let E e = s | _ => wrongType s.loc ctx ty s
E f = t | _ => wrongType t.loc ctx ty t
Elim.compare0 ctx e f
ignore $ Elim.compare0 ctx e f
||| compares two types, using the current variance `mode` for universes.
||| fails if they are not types, even if they would happen to be equal.
@ -353,39 +353,48 @@ parameters (defs : Definitions)
compareType' ctx (E e) (E f) = do
-- no fanciness needed here cos anything other than a neutral
-- has been inlined by whnf
Elim.compare0 ctx e f
ignore $ Elim.compare0 ctx e f
namespace Elim
-- [fixme] the following code ends up repeating a lot of work in the
-- computeElimType calls. the results should be shared better
||| compare two eliminations according to the given variance `mode`.
|||
||| ⚠ **assumes that they have both been typechecked, and have
||| equal types.** ⚠
export covering %inline
compare0 : EqContext n -> (e, f : Elim 0 n) -> Eff EqualInner ()
compare0 : EqContext n -> (e, f : Elim 0 n) -> Eff EqualInner (Term 0 n)
compare0 ctx e f =
wrapErr (WhileComparingE ctx !mode e f) $ do
let Val n = ctx.termLen
Element e' ne <- whnf defs ctx e.loc e
Element f' nf <- whnf defs ctx f.loc f
unless !(isSubSing defs ctx =<< computeElimTypeE defs ctx e') $
compare0' ctx e' f' ne nf
-- [todo] share the work of this computeElimTypeE and the return value
-- of compare0' somehow?????
ty <- computeElimTypeE defs ctx e'
if !(isSubSing defs ctx ty)
then pure ty
else compare0' ctx e' f' ne nf
private covering
compare0' : EqContext n ->
(e, f : Elim 0 n) ->
(0 ne : NotRedex defs e) -> (0 nf : NotRedex defs f) ->
Eff EqualInner ()
Eff EqualInner (Term 0 n)
compare0' ctx e@(F x u _) f@(F y v _) _ _ =
unless (x == y && u == v) $ clashE e.loc ctx e f
compare0' ctx e@(F x u loc) f@(F y v _) _ _ =
if x == y && u == v
then do let Val n = ctx.termLen
let Just def = lookup x defs
| Nothing => throw $ NotInScope loc x
pure def.type
else clashE e.loc ctx e f
compare0' ctx e@(F {}) f _ _ = clashE e.loc ctx e f
compare0' ctx e@(B i _) f@(B j _) _ _ =
unless (i == j) $ clashE e.loc ctx e f
if i == j
then pure $ ctx.tctx !! i
else clashE e.loc ctx e f
compare0' ctx e@(B {}) f _ _ = clashE e.loc ctx e f
-- Ψ | Γ ⊢ e = f ⇒ π.(x : A) → B
@ -394,10 +403,10 @@ parameters (defs : Definitions)
-- Ψ | Γ ⊢ e s = f t ⇒ B[s∷A/x]
compare0' ctx (App e s eloc) (App f t floc) ne nf =
local_ Equal $ do
compare0 ctx e f
(_, arg, _) <- expectPi defs ctx eloc =<<
computeElimTypeE defs ctx e @{noOr1 ne}
ety <- compare0 ctx e f
(_, arg, res) <- expectPi defs ctx eloc ety
Term.compare0 ctx arg s t
pure $ sub1 res (Ann s arg s.loc)
compare0' ctx e@(App {}) f _ _ = clashE e.loc ctx e f
-- Ψ | Γ ⊢ e = f ⇒ (x : A) × B
@ -409,8 +418,7 @@ parameters (defs : Definitions)
compare0' ctx (CasePair epi e eret ebody eloc)
(CasePair fpi f fret fbody {}) ne nf =
local_ Equal $ do
compare0 ctx e f
ety <- computeElimTypeE defs ctx e @{noOr1 ne}
ety <- compare0 ctx e f
compareType (extendTy Zero eret.name ety ctx) eret.term fret.term
(fst, snd) <- expectSig defs ctx eloc ety
let [< x, y] = ebody.names
@ -418,6 +426,7 @@ parameters (defs : Definitions)
(substCasePairRet ebody.names ety eret)
ebody.term fbody.term
expectEqualQ e.loc epi fpi
pure $ sub1 eret e
compare0' ctx e@(CasePair {}) f _ _ = clashE e.loc ctx e f
-- Ψ | Γ ⊢ e = f ⇒ {𝐚s}
@ -429,14 +438,14 @@ parameters (defs : Definitions)
compare0' ctx (CaseEnum epi e eret earms eloc)
(CaseEnum fpi f fret farms floc) ne nf =
local_ Equal $ do
compare0 ctx e f
ety <- computeElimTypeE defs ctx e @{noOr1 ne}
ety <- compare0 ctx e f
compareType (extendTy Zero eret.name ety ctx) eret.term fret.term
for_ !(expectEnum defs ctx eloc ety) $ \t => do
l <- lookupArm eloc t earms
r <- lookupArm floc t farms
compare0 ctx (sub1 eret $ Ann (Tag t l.loc) ety l.loc) l r
expectEqualQ eloc epi fpi
pure $ sub1 eret e
where
lookupArm : Loc -> TagVal -> CaseEnumArms d n ->
Eff EqualInner (Term d n)
@ -456,8 +465,7 @@ parameters (defs : Definitions)
compare0' ctx (CaseNat epi epi' e eret ezer esuc eloc)
(CaseNat fpi fpi' f fret fzer fsuc floc) ne nf =
local_ Equal $ do
compare0 ctx e f
ety <- computeElimTypeE defs ctx e @{noOr1 ne}
ety <- compare0 ctx e f
compareType (extendTy Zero eret.name ety ctx) eret.term fret.term
compare0 ctx
(sub1 eret (Ann (Zero ezer.loc) (Nat ezer.loc) ezer.loc))
@ -468,6 +476,7 @@ parameters (defs : Definitions)
(substCaseSuccRet esuc.names eret) esuc.term fsuc.term
expectEqualQ e.loc epi fpi
expectEqualQ e.loc epi' fpi'
pure $ sub1 eret e
compare0' ctx e@(CaseNat {}) f _ _ = clashE e.loc ctx e f
-- Ψ | Γ ⊢ e = f ⇒ [ρ. A]
@ -479,14 +488,14 @@ parameters (defs : Definitions)
compare0' ctx (CaseBox epi e eret ebody eloc)
(CaseBox fpi f fret fbody floc) ne nf =
local_ Equal $ do
compare0 ctx e f
ety <- computeElimTypeE defs ctx e @{noOr1 ne}
ety <- compare0 ctx e f
compareType (extendTy Zero eret.name ety ctx) eret.term fret.term
(q, ty) <- expectBOX defs ctx eloc ety
compare0 (extendTy (epi * q) ebody.name ty ctx)
(substCaseBoxRet ebody.name ety eret)
ebody.term fbody.term
expectEqualQ eloc epi fpi
pure $ sub1 eret e
compare0' ctx e@(CaseBox {}) f _ _ = clashE e.loc ctx e f
-- all dim apps replaced with ends by whnf
@ -501,6 +510,7 @@ parameters (defs : Definitions)
compare0' ctx (Ann s a _) (Ann t b _) _ _ = do
ty <- bigger a b
Term.compare0 ctx ty s t
pure ty
-- Ψ | Γ ⊢ Ap₁/𝑖 <: Bp₂/𝑖
-- Ψ | Γ ⊢ Aq₁/𝑖 <: Bq₂/𝑖
@ -514,8 +524,9 @@ parameters (defs : Definitions)
ty1q = dsub1 ty1 q1; ty2q = dsub1 ty2 q2
compareType ctx ty1p ty2p
compareType ctx ty1q ty2q
ty_p <- bigger ty1p ty2p
(ty_p, ty_q) <- bigger (ty1p, ty1q) (ty2p, ty2q)
Term.compare0 ctx ty_p val1 val2
pure ty_q
compare0' ctx e@(Coe {}) f _ _ = clashE e.loc ctx e f
-- (no neutral compositions in a closed dctx)
@ -527,14 +538,14 @@ parameters (defs : Definitions)
compare0' ctx (TypeCase ty1 ret1 arms1 def1 eloc)
(TypeCase ty2 ret2 arms2 def2 floc) ne _ =
local_ Equal $ do
compare0 ctx ty1 ty2
u <- expectTYPE defs ctx eloc =<<
computeElimTypeE defs ctx ty1 @{noOr1 ne}
ety <- compare0 ctx ty1 ty2
u <- expectTYPE defs ctx eloc ety
compareType ctx ret1 ret2
compareType ctx def1 def2
for_ allKinds $ \k =>
compareArm ctx k ret1 u
(lookupPrecise k arms1) (lookupPrecise k arms2) def1
pure ret1
compare0' ctx e@(TypeCase {}) f _ _ = clashE e.loc ctx e f
-- Ψ | Γ ⊢ s <: f ⇐ A
@ -542,9 +553,12 @@ parameters (defs : Definitions)
-- Ψ | Γ ⊢ (s ∷ A) <: f ⇒ A
--
-- and vice versa
compare0' ctx (Ann s a _) f _ _ = Term.compare0 ctx a s (E f)
compare0' ctx e (Ann t b _) _ _ = Term.compare0 ctx b (E e) t
compare0' ctx e@(Ann {}) f _ _ = clashE e.loc ctx e f
compare0' ctx (Ann s a _) f _ _ =
Term.compare0 ctx a s (E f) $> a
compare0' ctx e (Ann t b _) _ _ =
Term.compare0 ctx b (E e) t $> b
compare0' ctx e@(Ann {}) f _ _ =
clashE e.loc ctx e f
||| compare two type-case branches, which came from the arms of the given
||| kind. `ret` is the return type of the case expression, and `u` is the
@ -644,7 +658,7 @@ parameters (loc : Loc) (ctx : TyContext d n)
export covering
compare : (e, f : Elim d n) -> Eff Equal ()
compare e f = runCompare $ \defs, ectx, th =>
compare0 defs ectx (e // th) (f // th)
ignore $ compare0 defs ectx (e // th) (f // th)
namespace Term
export covering %inline