idris-0.9.3: src/Core/Unify.hs
{-# LANGUAGE PatternGuards #-}
module Core.Unify(unify, Fails) where
import Core.TT
import Core.Evaluate
import Control.Monad
import Control.Monad.State
import Debug.Trace
-- Unification is applied inside the theorem prover. We're looking for holes
-- which can be filled in, by matching one term's normal form against another.
-- Returns a list of hole names paired with the term which solves them, and
-- a list of things which need to be injective.
-- terms which need to be injective, with the things we're trying to unify
-- at the time
type Injs = [(TT Name, TT Name, TT Name)]
type Fails = [(TT Name, TT Name, Env, Err)]
data UInfo = UI Int Injs Fails
unify :: Context -> Env -> TT Name -> TT Name -> TC ([(Name, TT Name)],
Injs, Fails)
unify ctxt env topx topy
= -- case runStateT (un' False [] topx topy) (UI 0 [] []) of
-- OK (v, UI _ inj []) -> return (filter notTrivial v, inj, [])
-- _ ->
let topxn = normalise ctxt env topx
topyn = normalise ctxt env topy in
case runStateT (un' False [] topxn topyn)
(UI 0 [] []) of
OK (v, UI _ inj fails) -> return (filter notTrivial v, inj, reverse fails)
-- OK (_, UI s _ ((_,_,f):fs)) -> tfail $ CantUnify topx topy f s
Error e -> tfail e
where
notTrivial (x, P _ x' _) = x /= x'
notTrivial _ = True
injective (P (DCon _ _) _ _) = True
injective (P (TCon _ _) _ _) = True
injective (App f a) = injective f
injective _ = False
notP (P _ _ _) = False
notP _ = True
sc i = do UI s x f <- get
put (UI (s+i) x f)
uplus u1 u2 = do UI s i f <- get
r <- u1
UI s _ f' <- get
if (length f == length f')
then return r
else do put (UI s i f); u2
un' :: Bool -> [(Name, Name)] -> TT Name -> TT Name ->
StateT UInfo
TC [(Name, TT Name)]
un' fn bnames (P Bound x _) (P Bound y _)
| (x,y) `elem` bnames = do sc 1; return []
un' fn bnames (P Bound x _) tm
| holeIn env x = do UI s i f <- get
when (notP tm && fn) $ put (UI s ((tm, topx, topy) : i) f)
sc 1
return [(x, tm)]
un' fn bnames tm (P Bound y _)
| holeIn env y = do UI s i f <- get
when (notP tm && fn) $ put (UI s ((tm, topx, topy) : i) f)
sc 1
return [(y, tm)]
un' fn bnames (V i) (P Bound x _)
| fst (bnames!!i) == x || snd (bnames!!i) == x = do sc 1; return []
un' fn bnames (P Bound x _) (V i)
| fst (bnames!!i) == x || snd (bnames!!i) == x = do sc 1; return []
un' fn bnames (App fx ax) (App fy ay)
= do uplus -- do the second one if the first adds any errors
(do hf <- un' True bnames fx fy
let ax' = hnormalise hf ctxt env (substNames hf ax)
let ay' = hnormalise hf ctxt env (substNames hf ay)
ha <- un' False bnames ax' ay'
sc 1
combine bnames hf ha)
(do ha <- un' False bnames ax ay
let fx' = hnormalise ha ctxt env (substNames ha fx)
let fy' = hnormalise ha ctxt env (substNames ha fy)
hf <- un' False bnames fx' fy'
sc 1
combine bnames hf ha)
where hnormalise [] _ _ t = t
hnormalise ns ctxt env t = normalise ctxt env t
un' fn bnames x (Bind n (Lam t) (App y (P Bound n' _)))
| n == n' = un' False bnames x y
un' fn bnames (Bind n (Lam t) (App x (P Bound n' _))) y
| n == n' = un' False bnames x y
un' fn bnames (Bind x bx sx) (Bind y by sy)
= do h1 <- uB bnames bx by
h2 <- un' False ((x,y):bnames) sx sy
combine bnames h1 h2
un' fn bnames x y
| OK True <- convEq' ctxt x y = do sc 1; return []
| otherwise = do UI s i f <- get
let err = CantUnify topx topy (CantUnify x y (Msg "") [] s) (errEnv env) s
put (UI s i ((x, y, env, err) : f))
return [] -- lift $ tfail err
uB bnames (Let tx vx) (Let ty vy)
= do h1 <- un' False bnames tx ty
h2 <- un' False bnames ty vy
sc 1
combine bnames h1 h2
uB bnames (Guess tx vx) (Guess ty vy)
= do h1 <- un' False bnames tx ty
h2 <- un' False bnames ty vy
sc 1
combine bnames h1 h2
uB bnames (Lam tx) (Lam ty) = do sc 1; un' False bnames tx ty
uB bnames (Pi tx) (Pi ty) = do sc 1; un' False bnames tx ty
uB bnames (Hole tx) (Hole ty) = un' False bnames tx ty
uB bnames (PVar tx) (PVar ty) = un' False bnames tx ty
uB bnames x y = do UI s i f <- get
let err = CantUnify topx topy
(CantUnify (binderTy x) (binderTy y) (Msg "") [] s)
(errEnv env) s
put (UI s i ((binderTy x, binderTy y, env, err) : f))
return [] -- lift $ tfail err
combine bnames as [] = return as
combine bnames as ((n, t) : bs)
= case lookup n as of
Nothing -> combine bnames (as ++ [(n,t)]) bs
Just t' -> do un' False bnames t t'
sc 1
combine bnames as bs
errEnv = map (\(x, b) -> (x, binderTy b))
holeIn :: Env -> Name -> Bool
holeIn env n = case lookup n env of
Just (Hole _) -> True
_ -> False