Unify.hs revision 97018cf5fa25b494adffd7e9b4e87320dae6bf47
{- |
Module : $Header$
Copyright : (c) Christian Maeder and Uni Bremen 2003
License : similar to LGPL, see HetCATS/LICENSE.txt or LIZENZ.txt
Maintainer : maeder@tzi.de
Stability : experimental
Portability : portable
substitution and unification of types
-}
module HasCASL.Unify where
import HasCASL.As
import HasCASL.AsUtils
import HasCASL.Le
import qualified Common.Lib.Map as Map
import qualified Common.Lib.Set as Set
import Common.PrettyPrint
import Common.Id
import Common.Lib.State
import Common.Result
import Data.List as List
import Data.Maybe
-- | bound vars
genVarsOf :: Type -> [TypeArg]
genVarsOf = map snd . leaves (<0)
-- | vars or other ids
leaves :: (Int -> Bool) -> Type -> [(Int, TypeArg)]
leaves b t =
case t of
TypeName j k i -> if b(i)
then [(i, TypeArg j k Other [])]
else []
TypeAppl t1 t2 -> leaves b t1 `List.union` leaves b t2
ExpandedType _ t2 -> leaves b t2
KindedType tk _ _ -> leaves b tk
LazyType tl _ -> leaves b tl
ProductType l _ -> foldl List.union [] $ map (leaves b) l
FunType t1 _ t2 _ -> leaves b t1 `List.union` leaves b t2
_ -> error ("leaves: " ++ show t)
-- | composition (reversed: first substitution first!)
compSubst :: Subst -> Subst -> Subst
-- | unifiability of type schemes including instantiation with fresh variables
-- (and looking up type aliases)
isUnifiable :: TypeMap -> Int -> TypeScheme -> TypeScheme -> Bool
isUnifiable tm c = asSchemes c (unify tm)
-- | test if second scheme is a substitution instance
instScheme :: TypeMap -> Int -> TypeScheme -> TypeScheme -> Bool
instScheme tm c = asSchemes c (subsume tm)
-- | lift 'State' Int to 'State' Env
toEnvState :: State Int a -> State Env a
toEnvState p =
do s <- get
let (r, c) = runState p $ counter s
put s { counter = c }
return r
toSchemes :: (Type -> Type -> a) -> TypeScheme -> TypeScheme -> State Int a
toSchemes f sc1 sc2 =
do (t1, _) <- freshInstList sc1
(t2, _) <- freshInstList sc2
return $ f t1 t2
asSchemes :: Int -> (Type -> Type -> a) -> TypeScheme -> TypeScheme -> a
asSchemes c f sc1 sc2 = fst $ runState (toSchemes f sc1 sc2) c
-- -------------------------------------------------------------------------
freshInstList :: TypeScheme -> State Int (Type, [Type])
freshInstList (TypeScheme tArgs t _) =
do let ls = leaves (< 0) t -- generic vars
vs = map snd ls
ts <- mkSubst vs
return (subst (Map.fromList $ zip (map fst ls) ts) t,
map (mapArg $ zip vs ts) tArgs)
mapArg :: [(TypeArg, a)] -> TypeArg -> a
mapArg ts (TypeArg i k _ _) =
maybe (error "mapArg") snd $
find (\ (TypeArg j l _ _, _) -> i == j && k == l) ts
freshVar :: [Pos] -> State Int (Id, Int)
freshVar p =
do c <- get
put (c + 1)
return (simpleIdToId $ Token ("_var_" ++ show c) p, c)
mkSingleSubst :: TypeArg -> State Int Type
mkSingleSubst tv@(TypeArg _ k _ _) =
do (ty, c) <- freshVar $ posOfTypeArg tv
return (TypeName ty k c)
mkSubst :: [TypeArg] -> State Int [Type]
mkSubst = mapM mkSingleSubst
type Subst = Map.Map Int Type
eps :: Subst
eps = Map.empty
class Unifiable a where
subst :: Subst -> a -> a
match :: TypeMap -> (TypeId -> TypeId -> Bool)
-> (Bool, a) -> (Bool, a) -> Result Subst
-- | most general unifier via 'match'
-- where both sides may contribute substitutions
mgu :: Unifiable a => TypeMap -> a -> a -> Result Subst
mgu tm a b = match tm (==) (True, a) (True, b)
shapeMatch :: Unifiable a => TypeMap -> a -> a -> Result Subst
shapeMatch tm a b = match tm (const $ const True) (True, a) (True, b)
unify :: Unifiable a => TypeMap -> a -> a -> Bool
unify tm a b = isJust $ maybeResult $ mgu tm a b
subsume :: Unifiable a => TypeMap -> a -> a -> Bool
subsume tm a b =
isJust $ maybeResult $ match tm (==) (False, a) (True, b)
equalSubs :: Unifiable a => TypeMap -> a -> a -> Bool
equalSubs tm a b = subsume tm a b && subsume tm b a
-- | get the type variable
getTypeVar :: TypeArg -> Id
getTypeVar(TypeArg v _ _ _) = v
idsOf :: (Int -> Bool) -> Type -> Set.Set TypeId
idsOf b = Set.fromList . map (getTypeVar . snd) . leaves b
instance Unifiable Type where
subst m = rename (\ i k n ->
case Map.lookup n m of
Just s -> s
_ -> TypeName i k n)
match tm rel t1 (b2, ExpandedType _ t2) = match tm rel t1 (b2, t2)
match tm rel (b1, ExpandedType _ t1) t2 = match tm rel (b1, t1) t2
match tm rel t1 (b2, LazyType t2 _) = match tm rel t1 (b2, t2)
match tm rel (b1, LazyType t1 _) t2 = match tm rel (b1, t1) t2
match tm rel t1 (b2, KindedType t2 _ _) = match tm rel t1 (b2, t2)
match tm rel (b1, KindedType t1 _ _) t2 = match tm rel (b1, t1) t2
match _ rel (b1, t1@(TypeName i1 _k1 v1)) (b2, t2@(TypeName i2 _k2 v2)) =
if rel i1 i2 && v1 == v2
then return eps
else if v1 > 0 && b1 then return $
Map.singleton v1 t2
else if v2 > 0 && b2 then return $
Map.singleton v2 t1
else uniResult "typename" t1
"is not unifiable with typename" t2
match _tm _ (b1, TypeName i1 _ v1) (_, t2) =
if v1 > 0 && b1 then
if null $ leaves (==v1) t2 then
return $ Map.singleton v1 t2
else uniResult "var" i1 "occurs in" t2
else uniResult "typename" i1
"is not unifiable with type" t2
match tm rel t2 t1@(_, TypeName _ _ _) = match tm rel t1 t2
match tm rel (b1, TypeAppl t1 t2) (b2, TypeAppl t3 t4) =
match tm rel (b1, (t1, t2)) (b2, (t3, t4))
match tm rel (b1, ProductType p1 _) (b2, ProductType p2 _) =
match tm rel (b1, p1) (b2, p2)
match tm rel (b1, FunType t1 _ t2 _) (b2, FunType t3 _ t4 _) =
match tm rel (b1, (t1, t2)) (b2, (t3, t4))
match _ _ (_,t1) (_,t2) = uniResult "type" t1
"is not unifiable with type" t2
showPrettyWithPos :: (PrettyPrint a, PosItem a) => a -> ShowS
showPrettyWithPos a = let p = get_pos a in
showChar '\'' . showPretty a . showChar '\''
. noShow (null p) (showChar ' ' .
showParen True (showPos $ maximumBy comparePos p))
uniResult :: (PrettyPrint a, PosItem a, PrettyPrint b, PosItem b) =>
String -> a -> String -> b -> Result Subst
uniResult s1 a s2 b =
Result [Diag Hint ("in type\n" ++ " " ++ s1 ++ " " ++
showPrettyWithPos a "\n " ++ s2 ++ " " ++
showPrettyWithPos b "") []] Nothing
instance (Unifiable a, Unifiable b) => Unifiable (a, b) where
subst s (t1, t2) = (subst s t1, subst s t2)
match tm rel (b1, (t1, t2)) (b2, (t3, t4)) =
let r1@(Result _ m1) = match tm rel (b1, t1) (b2, t3) in
case m1 of
Nothing -> r1
Just s1 -> let r2@(Result _ m2) = match tm rel
(b1, if b1 then subst s1 t2 else t2)
(b2, if b2 then subst s1 t4 else t4)
in case m2 of
Nothing -> r2
Just s2 -> return $ compSubst s1 s2
instance (PrettyPrint a, PosItem a, Unifiable a) => Unifiable [a] where
subst s = map (subst s)
match _ _ (_, []) (_, []) = return eps
match tm rel (b1, a1:r1) (b2, a2:r2) =
match tm rel (b1, (a1, r1)) (b2, (a2, r2))
match tm rel (b1, []) l = match tm rel l (b1, [])
match _ _ (_, (a:_)) (_, []) = uniResult "type component" a
"is not unifiable with the empty list"
(mkSimpleId "[]")
instance (PrettyPrint a, PosItem a, Unifiable a) => Unifiable (Maybe a) where
subst s = fmap (subst s)
match _ _ (_, Nothing) _ = return eps
match _ _ _ (_, Nothing) = return eps
match tm rel (b1, Just a1) (b2, Just a2) = match tm rel (b1, a1) (b2, a2)
repl :: Map.Map TypeArg Type -> Type -> Type
repl m = rename ( \ i k n ->
case Map.lookup (TypeArg i k Other []) m of
Just s -> s
Nothing -> TypeName i k n)
expand :: TypeMap -> TypeScheme -> TypeScheme
expand = mapTypeOfScheme . expandAlias
expandAlias :: TypeMap -> Type -> Type
expandAlias tm t =
let (ps, as, ta, b) = expandAliases tm t in
if b && length ps == length as then
ExpandedType t $ repl (Map.fromList (zip ps $ reverse as)) ta
else ta
expandAliases :: TypeMap -> Type -> ([TypeArg], [Type], Type, Bool)
expandAliases tm t = case t of
TypeName i _ _ -> case Map.lookup i tm of
Just (TypeInfo _ _ _
(AliasTypeDefn (TypeScheme l ty _))) ->
(l, [], ty, True)
Just (TypeInfo _ _ _
(Supertype _ (TypeScheme l ty _) _)) ->
case ty of
TypeName _ _ _ -> wrap t
_ -> (l, [], ty, True)
_ -> wrap t
TypeAppl t1 t2 ->
let (ps, as, ta, b) = expandAliases tm t1
t3 = expandAlias tm t2
in if b then
(ps, t3:as, ta, b) -- reverse later on
else wrap $ TypeAppl t1 t3
FunType t1 a t2 ps ->
wrap $ FunType (expandAlias tm t1) a (expandAlias tm t2) ps
ProductType ts ps -> wrap $ ProductType (map (expandAlias tm) ts) ps
LazyType ty ps -> wrap $ LazyType (expandAlias tm ty) ps
ExpandedType t1 t2 -> wrap $ ExpandedType t1 $ expandAlias tm t2
KindedType ty k ps -> wrap $ KindedType (expandAlias tm ty) k ps
_ -> wrap t
where wrap ty = ([], [], ty, False)