{- |

Module : $Header$

Copyright : (c) Christian Maeder and Uni Bremen 2003

Licence : similar to LGPL, see HetCATS/LICENCE.txt or LIZENZ.txt

Maintainer : maeder@tzi.de

Stability : experimental

Portability : portable

type inference

-}

module HasCASL.TypeCheck where

import HasCASL.Unify

import HasCASL.AsUtils

import HasCASL.Merge

import HasCASL.VarDecl

import HasCASL.As

import HasCASL.Le

import HasCASL.MixAna

import HasCASL.MapTerm

import HasCASL.Constrain

import qualified Common.Lib.Map as Map

import qualified Common.Lib.Set as Set

import Common.Id

import Common.Result

import Common.GlobalAnnotations

import Common.Lib.State

import Data.Maybe

substTerm :: Subst -> Term -> Term

substTerm s = mapTerm (id, subst s)

resolveTerm :: GlobalAnnos -> Maybe Type -> Term -> State Env (Maybe Term)

resolveTerm ga mt trm = do

mtrm <- resolve ga trm

case mtrm of

Nothing -> return Nothing

Just t -> typeCheck mt t

checkPattern :: GlobalAnnos -> Pattern -> State Env (Maybe Pattern)

checkPattern ga pat = do

mPat <- resolvePattern ga pat

case mPat of

Nothing -> return Nothing

Just p -> do

np <- anaPattern p

typeCheck Nothing np

instantiate :: TypeScheme -> State Env (Type, [Type], Constraints)

instantiate sc = do

(typ, inst) <- toEnvState $ freshInstList sc

return (typ, inst, Set.fromList $ map ( \ ty@(TypeName _ k _)

-> Kinding ty k) inst)

instOpInfo :: OpInfo -> State Env (Type, [Type], Constraints, OpInfo)

instOpInfo oi = do

(ty, inst, cs) <- instantiate $ opType oi

return (ty, inst, cs, oi)

lookupError :: Type -> [OpInfo] -> String

lookupError ty ois =

" with type: " ++ showPrettyWithPos ty "\n"

++ " known types:\n " ++

showSepList ("\n "++) (showPrettyWithPos . opType) ois ""

checkList :: [Maybe Type] -> [Term]

-> State Env [(Subst, Constraints, [Type], [Term])]

checkList [] [] = return [(eps, noC, [], [])]

checkList (ty : rty) (trm : rt) = do

fts <- infer ty trm

combs <- mapM ( \ (sf, cs, tyf, tf) -> do

rts <- checkList (map (fmap (subst sf)) rty) rt

return $ map ( \ (sr, cr, tys, tts) ->

(compSubst sf sr,

substC sr cs `joinC` cr,

subst sr tyf : tys,

tf : tts)) rts) fts

return $ concat combs

checkList _ _ = error "checkList"

typeCheck :: Maybe Type -> Term -> State Env (Maybe Term)

typeCheck mt trm =

do alts <- infer mt trm

tm <- gets typeMap

let p = getMyPos trm

if null alts then

do addDiags [mkDiag Error "no typing for" trm]

return Nothing

else if null $ tail alts then do

let (s, cs, _, t) = head alts

(ds, rcs) = simplify tm cs

es = map ( \ d -> d {diagKind = Hint, diagPos = p}) ds

addDiags(es ++ map ( \ c ->

mkDiag Error "unresolved constraint" c)

(Set.toList rcs))

return $ Just $ substTerm s t

else let falts = filter ( \ (_, cs, _, _) ->

Set.isEmpty $ snd $ simplify tm cs) alts in

if null falts then do

addDiags [mkDiag Error "no constraint resolution for" trm]

return Nothing

else if null $ tail falts then

let (s, _, _, t) = head falts in

return $ Just $ substTerm s t

else

do addDiags [Diag Error

("ambiguous typings \n " ++

showSepList ("\n "++)

showPrettyWithPos

(take 5 $ map ( \ (s,_,_,t) ->

substTerm s t) falts) "")

p]

return Nothing

freshTypeVar :: Pos -> State Env Type

freshTypeVar p =

do (var, c) <- toEnvState $ freshVar p

return $ TypeName var star c

freshVars :: [Term] -> State Env [Type]

freshVars l = mapM (freshTypeVar . posOfTerm) l

inferAppl :: [Pos] -> Maybe Type -> Term -> Term

-> State Env [(Subst, Constraints, Type, Term)]

inferAppl ps mt t1 t2 = do

tm <- gets typeMap

aty <- freshTypeVar $ posOfTerm t2

rty <- case mt of

Nothing -> freshTypeVar $ posOfTerm t1

Just ty -> return ty

ops <- infer (Just $ FunType aty PFunArr rty []) t1

combs <- mapM ( \ (sf, cs, _, tf) -> do

let sfty = subst sf aty

args <- infer Nothing t2

return $ concatMap ( \ (sa, cr, tya, ta) ->

let m1 = mgu tm tya sfty

m2 = mgu tm tya $ FunType logicalType

PFunArr sfty ps

mkAT b s =

let rs = compSubst sa $ compSubst sf s in

(rs,

substC rs cs `joinC`

substC rs cr,

subst rs rty,

ApplTerm

(substTerm rs

(if b then ApplTerm tf

(TupleTerm [] ps) ps else tf))

ta ps)

mkATM b = maybe [] ((:[]) . mkAT b) . maybeResult

l1 = mkATM False m1

l2 = mkATM True m2

(as, acs, ty, atrm) = mkAT False eps

in if null l1 then

if null l2 then

[(as, Subtyping (subst sf tya) sfty

`Set.insert` acs, ty, atrm)]

else l2

else l1

) args) ops

let res = concat combs

origAppl = ApplTerm t1 t2 ps

if null res then

addDiags [case mt of

Nothing -> mkDiag Error

"wrongly typed application" origAppl

Just ty -> mkDiag Hint

("wrong result type "

++ showPrettyWithPos ty "\n for application")

origAppl]

else return ()

return res

infer :: Maybe Type -> Term -> State Env [(Subst, Constraints, Type, Term)]

infer mt trm = do

tm <- gets typeMap

let mUnify = mgu tm mt . Just

uniDiags = addDiags . map (improveDiag trm)

as <- gets assumps

case trm of

QualVar (VarDecl v t ok ps) -> do

let Result ds ms = mUnify t

uniDiags ds

case ms of

Nothing -> return []

Just s -> let ty = subst s t in

return [(s, noC, ty, QualVar $ VarDecl v ty ok ps)]

QualOp b (InstOpId i ts qs) sc ps -> do

(ty, inst, cs) <- instantiate sc

let Result ds ms = mgu tm (mt, if null ts then inst else ts)

(Just ty, inst)

uniDiags ds

case ms of

Nothing -> return []

Just s -> return [(s, substC s cs, subst s ty, QualOp b

(InstOpId i (map (subst s) inst) qs)

sc ps)]

ResolvedMixTerm i ts ps ->

if null ts then do

let ois = opInfos $ Map.findWithDefault (OpInfos []) i as

insts <- mapM instOpInfo ois

ls <- case mt of

Nothing -> return $ map ( \ (ty, is, cs, oi)

-> (eps, ty, is, cs, oi)) insts

Just inTy -> do

let rs = concatMap ( \ (ty, is, cs, oi) ->

let Result _ ms = mgu tm inTy ty in

case ms of Nothing -> []

Just s -> [(s, subst s ty

, map (subst s) is

, substC s cs

, oi)]) insts

if null rs then

addDiags [Diag Hint

("no type match for: " ++ showId i "\n"

++ lookupError inTy ois)

(posOfId i) ]

else return ()

return rs

return $ map ( \ (s, ty, is, cs, oi) ->

case opDefn oi of

VarDefn -> (s, cs, ty, QualVar $

VarDecl i ty Other ps)

x -> let br = case x of

NoOpDefn b -> b

Definition b _ -> b

_ -> Op in

(s, cs, ty,

QualOp br (InstOpId i is [])

(opType oi) ps)) ls

else infer mt $ ApplTerm (ResolvedMixTerm i [] ps)

(mkTupleTerm ts ps) ps

ApplTerm t1 t2 ps -> inferAppl ps

mt t1 t2

TupleTerm ts ps ->

case mt of

Nothing -> do

ls <- checkList (map (const Nothing) ts) ts

return $ map ( \ (su, cs, tys, trms) ->

(su, cs, mkProductType tys ps,

mkTupleTerm trms ps)) ls

Just ty -> do

vs <- freshVars ts

let pt = mkProductType vs []

Result ds ms = mgu tm ty pt

uniDiags ds

case ms of

Nothing -> return []

Just s -> do

ls <- checkList (map (Just . subst s) vs) ts

return $ map ( \ (su, cs, tys, trms) ->

(compSubst s su, substC s cs,

mkProductType tys ps,

mkTupleTerm trms ps)) ls

TypedTerm t qual ty ps -> do

case qual of

OfType -> do

let Result ds ms = mUnify ty

uniDiags ds

case ms of

Nothing -> return []

Just s -> do

rs <- infer (Just $ subst s ty) t

return $ map ( \ (s2, cs, typ, tr) ->

(compSubst s s2, substC s cs, typ,

TypedTerm tr qual ty ps)) rs

InType -> do

let Result ds ms = mUnify logicalType

uniDiags ds

case ms of

Nothing -> return []

Just s -> do

rs <- infer Nothing t -- Nothing

return $ map ( \ (s2, cs, _, tr) ->

(compSubst s s2, substC s cs, logicalType,

TypedTerm tr qual ty ps)) rs

AsType -> do

let Result ds ms = mUnify ty

uniDiags ds

case ms of

Nothing -> return []

Just s -> do

rs <- infer Nothing t -- Nothing

return $ map ( \ (s2, cs, _, tr) ->

(compSubst s s2, substC s cs, ty,

TypedTerm tr qual ty ps)) rs

QuantifiedTerm quant decls t ps -> do

mapM_ addGenVarDecl decls

let Result ds ms = mUnify logicalType

uniDiags ds

case ms of

Nothing -> return []

Just _ -> do

rs <- infer (Just logicalType) t

putAssumps as

return $ map ( \ (s, cs, typ, tr) ->

(s, cs, typ, QuantifiedTerm quant decls tr ps)) rs

LambdaTerm pats part resTrm ps -> do

vs <- freshVars pats

rty <- freshTypeVar $ posOfTerm resTrm

let fty l = if null l then rty else

FunType (head l) PFunArr (fty $ tail l) []

myty = fty vs

Result ds ms = mUnify myty

uniDiags ds

case ms of

Nothing -> return []

Just s -> do

ls <- checkList (map (Just . subst s) vs) pats

rs <- mapM ( \ ( s2, cs, _, nps) -> do

mapM_ addVarDecl $ concatMap extractVars nps

let newS = compSubst s s2

es <- infer (Just $ subst newS rty) resTrm

putAssumps as

return $ map ( \ (s3, cr, _, rtm) ->

(compSubst newS s3,

substC s3 cs `joinC` cr,

subst s3 (subst newS myty),

LambdaTerm nps part rtm ps)) es) ls

return $ concat rs

CaseTerm ofTrm eqs ps -> do

ts <- infer Nothing ofTrm

rty <- case mt of

Nothing -> freshTypeVar $ posOfTerm trm

Just ty -> return ty

if null ts then addDiags [mkDiag Error

"unresolved of-term in case" ofTrm]

else return ()

rs <- mapM ( \ (s1, cs, oty, otrm) -> do

es <- inferCaseEqs oty (subst s1 rty) eqs

return $ map ( \ (s2, cr, _, ty, nes) ->

(compSubst s1 s2,

substC s2 cs `joinC` cr, ty,

CaseTerm otrm nes ps)) es) ts

return $ concat rs

LetTerm b eqs inTrm ps -> do

es <- inferLetEqs eqs

rs <- mapM ( \ (s1, cs, _, nes) -> do

mapM_ addVarDecl $ concatMap (\ (ProgEq p _ _) ->

extractVars p) nes

ts <- infer mt inTrm

return $ map ( \ (s2, cr, ty, nt) ->

(compSubst s1 s2,

substC s2 cs `joinC` cr,

ty,

LetTerm b nes nt ps)) ts) es

putAssumps as

return $ concat rs

AsPattern (VarDecl v _ ok qs) pat ps -> do

pats <- infer mt pat

return $ map ( \ (s1, cs, t1, p1) -> (s1, cs, t1,

AsPattern (VarDecl v t1 ok qs) p1 ps)) pats

_ -> do ty <- freshTypeVar $ posOfTerm trm

addDiags [mkDiag Error "unexpected term" trm]

return [(eps, noC, ty, trm)]

inferLetEqs :: [ProgEq] -> State Env [(Subst, Constraints, [Type], [ProgEq])]

inferLetEqs es = do

let pats = map (\ (ProgEq p _ _) -> p) es

trms = map (\ (ProgEq _ t _) -> t) es

qs = map (\ (ProgEq _ _ q) -> q) es

do as <- gets assumps

newPats <- checkList (map (const Nothing) pats) pats

combs <- mapM ( \ (sf, _, tys, pps) -> do

mapM_ addVarDecl $ concatMap extractVars pps

newTrms <- checkList (map Just tys) trms

return $ map ( \ (sr, _, tys2, tts ) ->

(compSubst sf sr, noC, tys2,

zipWith3 ( \ p t q -> ProgEq (substTerm sr p) t q)

pps tts qs)) newTrms) newPats

putAssumps as

return $ concat combs

inferCaseEq :: Type -> Type -> ProgEq

-> State Env [(Subst, Constraints, Type, Type, ProgEq)]

inferCaseEq pty tty (ProgEq pat trm ps) = do

as <- gets assumps

let newAs = filterAssumps ( \ o -> case opDefn o of

ConstructData _ -> True

VarDefn -> True

_ -> False) as

putAssumps newAs

pats <- infer (Just pty) pat

putAssumps as

if null pats then addDiags [mkDiag Error "unresolved case pattern" pat]

else return ()

es <- mapM ( \ (s, cs, ty, p) -> do

mapM_ addVarDecl $ extractVars p

ts <- infer (Just $ subst s tty) trm

putAssumps as

return $ map ( \ (st, cr, tyt, t) ->

(compSubst s st,

substC st cs `joinC` cr,

subst st ty, tyt,

ProgEq p t ps)) ts) pats

return $ concat es

inferCaseEqs :: Type -> Type -> [ProgEq]

-> State Env [(Subst, Constraints, Type, Type, [ProgEq])]

inferCaseEqs pty tTy [] = return [(eps, noC, pty, tTy, [])]

inferCaseEqs pty tty (eq:eqs) = do

fts <- inferCaseEq pty tty eq

rs <- mapM (\ (_, cs, pty1, tty1, ne) -> do

rts <- inferCaseEqs pty1 tty1 eqs

return $ map ( \ (s2, cr, pty2, tty2, nes) ->

(s2,

substC s2 cs `joinC` cr,

pty2, tty2, ne:nes)) rts) fts

return $ concat rs