{-# LANGUAGE PatternGuards #-}
module GF.Compile.TypeCheck.RConcrete( checkLType, inferLType, computeLType, ppType ) where
import GF.Infra.CheckM
import GF.Data.Operations
import GF.Grammar
import GF.Grammar.Lookup
import GF.Grammar.Predef
import GF.Grammar.PatternMatch
import GF.Grammar.Lockfield (isLockLabel, lockRecType, unlockRecord)
import GF.Compile.TypeCheck.Primitives
import Data.List
import Control.Monad
import GF.Text.Pretty
computeLType :: SourceGrammar -> Context -> Type -> Check Type
computeLType gr g0 t = comp (reverse [(b,x, Vr x) | (b,x,_) <- g0] ++ g0) t
where
comp g ty = case ty of
_ | Just _ <- isTypeInts ty -> return ty ---- shouldn't be needed
| isPredefConstant ty -> return ty ---- shouldn't be needed
Q (m,ident) -> checkIn ("module" <+> m) $ do
ty' <- lookupResDef gr (m,ident)
if ty' == ty then return ty else comp g ty' --- is this necessary to test?
AdHocOverload ts -> do
over <- getOverload gr g (Just typeType) t
case over of
Just (tr,_) -> return tr
_ -> checkError ("unresolved overloading of constants" <+> ppTerm Qualified 0 t)
Vr ident -> checkLookup ident g -- never needed to compute!
App f a -> do
f' <- comp g f
a' <- comp g a
case f' of
Abs b x t -> comp ((b,x,a'):g) t
_ -> return $ App f' a'
Prod bt x a b -> do
a' <- comp g a
b' <- comp ((bt,x,Vr x) : g) b
return $ Prod bt x a' b'
Abs bt x b -> do
b' <- comp ((bt,x,Vr x):g) b
return $ Abs bt x b'
Let (x,(_,a)) b -> comp ((Explicit,x,a):g) b
ExtR r s -> do
r' <- comp g r
s' <- comp g s
case (r',s') of
(RecType rs, RecType ss) -> plusRecType r' s' >>= comp g
_ -> return $ ExtR r' s'
RecType fs -> do
let fs' = sortRec fs
liftM RecType $ mapPairsM (comp g) fs'
ELincat c t -> do
t' <- comp g t
lockRecType c t' ---- locking to be removed AR 20/6/2009
_ | ty == typeTok -> return typeStr
_ | isPredefConstant ty -> return ty
_ -> composOp (comp g) ty
-- the underlying algorithms
inferLType :: SourceGrammar -> Context -> Term -> Check (Term, Type)
inferLType gr g trm = case trm of
Q (m,ident) | isPredef m -> termWith trm $ case typPredefined ident of
Just ty -> return ty
Nothing -> checkError ("unknown in Predef:" <+> ident)
Q ident -> checks [
termWith trm $ lookupResType gr ident >>= computeLType gr g
,
lookupResDef gr ident >>= inferLType gr g
,
checkError ("cannot infer type of constant" <+> ppTerm Unqualified 0 trm)
]
QC (m,ident) | isPredef m -> termWith trm $ case typPredefined ident of
Just ty -> return ty
Nothing -> checkError ("unknown in Predef:" <+> ident)
QC ident -> checks [
termWith trm $ lookupResType gr ident >>= computeLType gr g
,
lookupResDef gr ident >>= inferLType gr g
,
checkError ("cannot infer type of canonical constant" <+> ppTerm Unqualified 0 trm)
]
Vr ident -> termWith trm $ checkLookup ident g
Typed e t -> do
t' <- computeLType gr g t
checkLType gr g e t'
AdHocOverload ts -> do
over <- getOverload gr g Nothing trm
case over of
Just trty -> return trty
_ -> checkError ("unresolved overloading of constants" <+> ppTerm Qualified 0 trm)
App f a -> do
over <- getOverload gr g Nothing trm
case over of
Just trty -> return trty
_ -> do
(f',fty) <- inferLType gr g f
fty' <- computeLType gr g fty
case fty' of
Prod bt z arg val -> do
a' <- justCheck g a arg
ty <- if isWildIdent z
then return val
else substituteLType [(bt,z,a')] val
return (App f' a',ty)
_ -> checkError ("A function type is expected for" <+> ppTerm Unqualified 0 f <+> "instead of type" <+> ppType fty)
S f x -> do
(f', fty) <- inferLType gr g f
case fty of
Table arg val -> do
x'<- justCheck g x arg
return (S f' x', val)
_ -> checkError ("table lintype expected for the table in" $$ nest 2 (ppTerm Unqualified 0 trm))
P t i -> do
(t',ty) <- inferLType gr g t --- ??
ty' <- computeLType gr g ty
let tr2 = P t' i
termWith tr2 $ case ty' of
RecType ts -> case lookup i ts of
Nothing -> checkError ("unknown label" <+> i <+> "in" $$ nest 2 (ppTerm Unqualified 0 ty'))
Just x -> return x
_ -> checkError ("record type expected for:" <+> ppTerm Unqualified 0 t $$
" instead of the inferred:" <+> ppTerm Unqualified 0 ty')
R r -> do
let (ls,fs) = unzip r
fsts <- mapM inferM fs
let ts = [ty | (Just ty,_) <- fsts]
checkCond ("cannot infer type of record" $$ nest 2 (ppTerm Unqualified 0 trm)) (length ts == length fsts)
return $ (R (zip ls fsts), RecType (zip ls ts))
T (TTyped arg) pts -> do
(_,val) <- checks $ map (inferCase (Just arg)) pts
checkLType gr g trm (Table arg val)
T (TComp arg) pts -> do
(_,val) <- checks $ map (inferCase (Just arg)) pts
checkLType gr g trm (Table arg val)
T ti pts -> do -- tries to guess: good in oper type inference
let pts' = [pt | pt@(p,_) <- pts, isConstPatt p]
case pts' of
[] -> checkError ("cannot infer table type of" <+> ppTerm Unqualified 0 trm)
---- PInt k : _ -> return $ Ints $ max [i | PInt i <- pts']
_ -> do
(arg,val) <- checks $ map (inferCase Nothing) pts'
checkLType gr g trm (Table arg val)
V arg pts -> do
(_,val) <- checks $ map (inferLType gr g) pts
-- return (trm, Table arg val) -- old, caused issue 68
checkLType gr g trm (Table arg val)
K s -> do
if elem ' ' s
then do
let ss = foldr C Empty (map K (words s))
----- removed irritating warning AR 24/5/2008
----- checkWarn ("token \"" ++ s ++
----- "\" converted to token list" ++ prt ss)
return (ss, typeStr)
else return (trm, typeStr)
EInt i -> return (trm, typeInt)
EFloat i -> return (trm, typeFloat)
Empty -> return (trm, typeStr)
C s1 s2 ->
check2 (flip (justCheck g) typeStr) C s1 s2 typeStr
Glue s1 s2 ->
check2 (flip (justCheck g) typeStr) Glue s1 s2 typeStr ---- typeTok
---- hack from Rename.identRenameTerm, to live with files with naming conflicts 18/6/2007
Strs (Cn c : ts) | c == cConflict -> do
checkWarn ("unresolved constant, could be any of" <+> hcat (map (ppTerm Unqualified 0) ts))
inferLType gr g (head ts)
Strs ts -> do
ts' <- mapM (\t -> justCheck g t typeStr) ts
return (Strs ts', typeStrs)
Alts t aa -> do
t' <- justCheck g t typeStr
aa' <- flip mapM aa (\ (c,v) -> do
c' <- justCheck g c typeStr
v' <- checks $ map (justCheck g v) [typeStrs, EPattType typeStr]
return (c',v'))
return (Alts t' aa', typeStr)
RecType r -> do
let (ls,ts) = unzip r
ts' <- mapM (flip (justCheck g) typeType) ts
return (RecType (zip ls ts'), typeType)
ExtR r s -> do
(r',rT) <- inferLType gr g r
rT' <- computeLType gr g rT
(s',sT) <- inferLType gr g s
sT' <- computeLType gr g sT
let trm' = ExtR r' s'
case (rT', sT') of
(RecType rs, RecType ss) -> do
let rt = RecType ([field | field@(l,_) <- rs, notElem l (map fst ss)] ++ ss) -- select types of later fields
checkLType gr g trm' rt ---- return (trm', rt)
_ | rT' == typeType && sT' == typeType -> do
return (trm', typeType)
_ -> checkError ("records or record types expected in" <+> ppTerm Unqualified 0 trm)
Sort _ ->
termWith trm $ return typeType
Prod bt x a b -> do
a' <- justCheck g a typeType
b' <- justCheck ((bt,x,a'):g) b typeType
return (Prod bt x a' b', typeType)
Table p t -> do
p' <- justCheck g p typeType --- check p partype!
t' <- justCheck g t typeType
return $ (Table p' t', typeType)
FV vs -> do
(_,ty) <- checks $ map (inferLType gr g) vs
--- checkIfComplexVariantType trm ty
checkLType gr g trm ty
EPattType ty -> do
ty' <- justCheck g ty typeType
return (EPattType ty',typeType)
EPatt p -> do
ty <- inferPatt p
return (trm, EPattType ty)
ELin c trm -> do
(trm',ty) <- inferLType gr g trm
ty' <- lockRecType c ty ---- lookup c; remove lock AR 20/6/2009
return $ (ELin c trm', ty')
_ -> checkError ("cannot infer lintype of" <+> ppTerm Unqualified 0 trm)
where
isPredef m = elem m [cPredef,cPredefAbs]
justCheck g ty te = checkLType gr g ty te >>= return . fst
-- for record fields, which may be typed
inferM (mty, t) = do
(t', ty') <- case mty of
Just ty -> checkLType gr g t ty
_ -> inferLType gr g t
return (Just ty',t')
inferCase mty (patt,term) = do
arg <- maybe (inferPatt patt) return mty
cont <- pattContext gr g arg patt
(_,val) <- inferLType gr (reverse cont ++ g) term
return (arg,val)
isConstPatt p = case p of
PC _ ps -> True --- all isConstPatt ps
PP _ ps -> True --- all isConstPatt ps
PR ps -> all (isConstPatt . snd) ps
PT _ p -> isConstPatt p
PString _ -> True
PInt _ -> True
PFloat _ -> True
PChar -> True
PChars _ -> True
PSeq p q -> isConstPatt p && isConstPatt q
PAlt p q -> isConstPatt p && isConstPatt q
PRep p -> isConstPatt p
PNeg p -> isConstPatt p
PAs _ p -> isConstPatt p
_ -> False
inferPatt p = case p of
PP (q,c) ps | q /= cPredef -> liftM valTypeCnc (lookupResType gr (q,c))
PAs _ p -> inferPatt p
PNeg p -> inferPatt p
PAlt p q -> checks [inferPatt p, inferPatt q]
PSeq _ _ -> return $ typeStr
PRep _ -> return $ typeStr
PChar -> return $ typeStr
PChars _ -> return $ typeStr
_ -> inferLType gr g (patt2term p) >>= return . snd
-- type inference: Nothing, type checking: Just t
-- the latter permits matching with value type
getOverload :: SourceGrammar -> Context -> Maybe Type -> Term -> Check (Maybe (Term,Type))
getOverload gr g mt ot = case appForm ot of
(f@(Q c), ts) -> case lookupOverload gr c of
Ok typs -> do
ttys <- mapM (inferLType gr g) ts
v <- matchOverload f typs ttys
return $ Just v
_ -> return Nothing
(AdHocOverload cs@(f:_), ts) -> do --- the function name f is only used in error messages
let typs = concatMap collectOverloads cs
ttys <- mapM (inferLType gr g) ts
v <- matchOverload f typs ttys
return $ Just v
_ -> return Nothing
where
collectOverloads tr@(Q c) = case lookupOverload gr c of
Ok typs -> typs
_ -> case lookupResType gr c of
Ok ty -> let (args,val) = typeFormCnc ty in [(map (\(b,x,t) -> t) args,(val,tr))]
_ -> []
collectOverloads _ = [] --- constructors QC
matchOverload f typs ttys = do
let (tts,tys) = unzip ttys
let vfs = lookupOverloadInstance tys typs
let matches = [vf | vf@((_,v,_),_) <- vfs, matchVal mt v]
let showTypes ty = hsep (map ppType ty)
let (stys,styps) = (showTypes tys, [showTypes ty | (ty,_) <- typs])
-- to avoid strange error msg e.g. in case of unmatch record extension, show whole types if needed AR 28/1/2013
let (stysError,stypsError) = if elem (render stys) (map render styps)
then (hsep (map (ppTerm Unqualified 0) tys), [hsep (map (ppTerm Unqualified 0) ty) | (ty,_) <- typs])
else (stys,styps)
case ([vf | (vf,True) <- matches],[vf | (vf,False) <- matches]) of
([(_,val,fun)],_) -> return (mkApp fun tts, val)
([],[(pre,val,fun)]) -> do
checkWarn $ "ignoring lock fields in resolving" <+> ppTerm Unqualified 0 ot $$
"for" $$
nest 2 (showTypes tys) $$
"using" $$
nest 2 (showTypes pre)
return (mkApp fun tts, val)
([],[]) -> do
checkError $ "no overload instance of" <+> ppTerm Unqualified 0 f $$
"for" $$
nest 2 stysError $$
"among" $$
nest 2 (vcat stypsError) $$
maybe empty (\x -> "with value type" <+> ppType x) mt
(vfs1,vfs2) -> case (noProds vfs1,noProds vfs2) of
([(val,fun)],_) -> do
return (mkApp fun tts, val)
([],[(val,fun)]) -> do
checkWarn ("ignoring lock fields in resolving" <+> ppTerm Unqualified 0 ot)
return (mkApp fun tts, val)
----- unsafely exclude irritating warning AR 24/5/2008
----- checkWarn $ "overloading of" +++ prt f +++
----- "resolved by excluding partial applications:" ++++
----- unlines [prtType env ty | (ty,_) <- vfs', not (noProd ty)]
--- now forgiving ambiguity with a warning AR 1/2/2014
-- This gives ad hoc overloading the same behaviour as the choice of the first match in renaming did before.
-- But it also gives a chance to ambiguous overloadings that were banned before.
(nps1,nps2) -> do
checkWarn $ "ambiguous overloading of" <+> ppTerm Unqualified 0 f <+>
---- "with argument types" <+> hsep (map (ppTerm Qualified 0) tys) $$
"resolved by selecting the first of the alternatives" $$
nest 2 (vcat [ppTerm Qualified 0 fun | (_,ty,fun) <- vfs1 ++ if null vfs1 then vfs2 else []])
case [(mkApp fun tts,val) | (val,fun) <- nps1 ++ nps2] of
[] -> checkError $ "no alternatives left when resolving" <+> ppTerm Unqualified 0 f
h:_ -> return h
matchVal mt v = elem mt [Nothing,Just v,Just (unlocked v)]
unlocked v = case v of
RecType fs -> RecType $ filter (not . isLockLabel . fst) fs
_ -> v
---- TODO: accept subtypes
---- TODO: use a trie
lookupOverloadInstance tys typs =
[((pre,mkFunType rest val, t),isExact) |
let lt = length tys,
(ty,(val,t)) <- typs, length ty >= lt,
let (pre,rest) = splitAt lt ty,
let isExact = pre == tys,
isExact || map unlocked pre == map unlocked tys
]
noProds vfs = [(v,f) | (_,v,f) <- vfs, noProd v]
noProd ty = case ty of
Prod _ _ _ _ -> False
_ -> True
checkLType :: SourceGrammar -> Context -> Term -> Type -> Check (Term, Type)
checkLType gr g trm typ0 = do
typ <- computeLType gr g typ0
case trm of
Abs bt x c -> do
case typ of
Prod bt' z a b -> do
(c',b') <- if isWildIdent z
then checkLType gr ((bt,x,a):g) c b
else do b' <- checkIn (pp "abs") $ substituteLType [(bt',z,Vr x)] b
checkLType gr ((bt,x,a):g) c b'
return $ (Abs bt x c', Prod bt' z a b')
_ -> checkError $ "function type expected instead of" <+> ppType typ
App f a -> do
over <- getOverload gr g (Just typ) trm
case over of
Just trty -> return trty
_ -> do
(trm',ty') <- inferLType gr g trm
termWith trm' $ checkEqLType gr g typ ty' trm'
AdHocOverload ts -> do
over <- getOverload gr g Nothing trm
case over of
Just trty -> return trty
_ -> checkError ("unresolved overloading of constants" <+> ppTerm Qualified 0 trm)
Q _ -> do
over <- getOverload gr g (Just typ) trm
case over of
Just trty -> return trty
_ -> do
(trm',ty') <- inferLType gr g trm
termWith trm' $ checkEqLType gr g typ ty' trm'
T _ [] ->
checkError ("found empty table in type" <+> ppTerm Unqualified 0 typ)
T _ cs -> case typ of
Table arg val -> do
case allParamValues gr arg of
Ok vs -> do
let ps0 = map fst cs
ps <- testOvershadow ps0 vs
if null ps
then return ()
else checkWarn ("patterns never reached:" $$
nest 2 (vcat (map (ppPatt Unqualified 0) ps)))
_ -> return () -- happens with variable types
cs' <- mapM (checkCase arg val) cs
return (T (TTyped arg) cs', typ)
_ -> checkError $ "table type expected for table instead of" $$ nest 2 (ppType typ)
V arg0 vs ->
case typ of
Table arg1 val ->
do arg' <- checkEqLType gr g arg0 arg1 trm
vs1 <- allParamValues gr arg1
if length vs1 == length vs
then return ()
else checkError $ "wrong number of values in table" <+> ppTerm Unqualified 0 trm
vs' <- map fst `fmap` sequence [checkLType gr g v val|v<-vs]
return (V arg' vs',typ)
R r -> case typ of --- why needed? because inference may be too difficult
RecType rr -> do
--let (ls,_) = unzip rr -- labels of expected type
fsts <- mapM (checkM r) rr -- check that they are found in the record
return $ (R fsts, typ) -- normalize record
_ -> checkError ("record type expected in type checking instead of" $$ nest 2 (ppTerm Unqualified 0 typ))
ExtR r s -> case typ of
_ | typ == typeType -> do
trm' <- computeLType gr g trm
case trm' of
RecType _ -> termWith trm' $ return typeType
ExtR (Vr _) (RecType _) -> termWith trm' $ return typeType
-- ext t = t ** ...
_ -> checkError ("invalid record type extension" <+> nest 2 (ppTerm Unqualified 0 trm))
RecType rr -> do
ll2 <- case s of
R ss -> return $ map fst ss
_ -> do
(s',typ2) <- inferLType gr g s
case typ2 of
RecType ss -> return $ map fst ss
_ -> checkError ("cannot get labels from" $$ nest 2 (ppTerm Unqualified 0 typ2))
let ll1 = [l | (l,_) <- rr, notElem l ll2]
(r',_) <- checkLType gr g r (RecType [field | field@(l,_) <- rr, elem l ll1])
(s',_) <- checkLType gr g s (RecType [field | field@(l,_) <- rr, elem l ll2])
let rec = R ([(l,(Nothing,P r' l)) | l <- ll1] ++ [(l,(Nothing,P s' l)) | l <- ll2])
return (rec, typ)
ExtR ty ex -> do
r' <- justCheck g r ty
s' <- justCheck g s ex
return $ (ExtR r' s', typ) --- is this all? it assumes the same division in trm and typ
_ -> checkError ("record extension not meaningful for" <+> ppTerm Unqualified 0 typ)
FV vs -> do
ttys <- mapM (flip (checkLType gr g) typ) vs
--- checkIfComplexVariantType trm typ
return (FV (map fst ttys), typ) --- typ' ?
S tab arg -> checks [ do
(tab',ty) <- inferLType gr g tab
ty' <- computeLType gr g ty
case ty' of
Table p t -> do
(arg',val) <- checkLType gr g arg p
checkEqLType gr g typ t trm
return (S tab' arg', t)
_ -> checkError ("table type expected for applied table instead of" <+> ppType ty')
, do
(arg',ty) <- inferLType gr g arg
ty' <- computeLType gr g ty
(tab',_) <- checkLType gr g tab (Table ty' typ)
return (S tab' arg', typ)
]
Let (x,(mty,def)) body -> case mty of
Just ty -> do
(ty0,_) <- checkLType gr g ty typeType
(def',ty') <- checkLType gr g def ty0
body' <- justCheck ((Explicit,x,ty'):g) body typ
return (Let (x,(Just ty',def')) body', typ)
_ -> do
(def',ty) <- inferLType gr g def -- tries to infer type of local constant
checkLType gr g (Let (x,(Just ty,def')) body) typ
ELin c tr -> do
tr1 <- unlockRecord c tr
checkLType gr g tr1 typ
_ -> do
(trm',ty') <- inferLType gr g trm
termWith trm' $ checkEqLType gr g typ ty' trm'
where
justCheck g ty te = checkLType gr g ty te >>= return . fst
{-
recParts rr t = (RecType rr1,RecType rr2) where
(rr1,rr2) = partition (flip elem (map fst t) . fst) rr
-}
checkM rms (l,ty) = case lookup l rms of
Just (Just ty0,t) -> do
checkEqLType gr g ty ty0 t
(t',ty') <- checkLType gr g t ty
return (l,(Just ty',t'))
Just (_,t) -> do
(t',ty') <- checkLType gr g t ty
return (l,(Just ty',t'))
_ -> checkError $
if isLockLabel l
then let cat = drop 5 (showIdent (label2ident l))
in ppTerm Unqualified 0 (R rms) <+> "is not in the lincat of" <+> cat <>
"; try wrapping it with lin" <+> cat
else "cannot find value for label" <+> l <+> "in" <+> ppTerm Unqualified 0 (R rms)
checkCase arg val (p,t) = do
cont <- pattContext gr g arg p
t' <- justCheck (reverse cont ++ g) t val
return (p,t')
pattContext :: SourceGrammar -> Context -> Type -> Patt -> Check Context
pattContext env g typ p = case p of
PV x -> return [(Explicit,x,typ)]
PP (q,c) ps | q /= cPredef -> do ---- why this /=? AR 6/1/2006
t <- lookupResType env (q,c)
let (cont,v) = typeFormCnc t
checkCond ("wrong number of arguments for constructor in" <+> ppPatt Unqualified 0 p)
(length cont == length ps)
checkEqLType env g typ v (patt2term p)
mapM (\((_,_,ty),p) -> pattContext env g ty p) (zip cont ps) >>= return . concat
PR r -> do
typ' <- computeLType env g typ
case typ' of
RecType t -> do
let pts = [(ty,tr) | (l,tr) <- r, Just ty <- [lookup l t]]
----- checkWarn $ prt p ++++ show pts ----- debug
mapM (uncurry (pattContext env g)) pts >>= return . concat
_ -> checkError ("record type expected for pattern instead of" <+> ppTerm Unqualified 0 typ')
PT t p' -> do
checkEqLType env g typ t (patt2term p')
pattContext env g typ p'
PAs x p -> do
g' <- pattContext env g typ p
return ((Explicit,x,typ):g')
PAlt p' q -> do
g1 <- pattContext env g typ p'
g2 <- pattContext env g typ q
let pts = nub ([x | pt@(_,x,_) <- g1, notElem pt g2] ++ [x | pt@(_,x,_) <- g2, notElem pt g1])
checkCond
("incompatible bindings of" <+>
fsep pts <+>
"in pattern alterantives" <+> ppPatt Unqualified 0 p) (null pts)
return g1 -- must be g1 == g2
PSeq p q -> do
g1 <- pattContext env g typ p
g2 <- pattContext env g typ q
return $ g1 ++ g2
PRep p' -> noBind typeStr p'
PNeg p' -> noBind typ p'
_ -> return [] ---- check types!
where
noBind typ p' = do
co <- pattContext env g typ p'
if not (null co)
then checkWarn ("no variable bound inside pattern" <+> ppPatt Unqualified 0 p)
>> return []
else return []
checkEqLType :: SourceGrammar -> Context -> Type -> Type -> Term -> Check Type
checkEqLType gr g t u trm = do
(b,t',u',s) <- checkIfEqLType gr g t u trm
case b of
True -> return t'
False -> checkError $ s <+> "type of" <+> ppTerm Unqualified 0 trm $$
"expected:" <+> ppTerm Qualified 0 t $$ -- ppqType t u $$
"inferred:" <+> ppTerm Qualified 0 u -- ppqType u t
checkIfEqLType :: SourceGrammar -> Context -> Type -> Type -> Term -> Check (Bool,Type,Type,String)
checkIfEqLType gr g t u trm = do
t' <- computeLType gr g t
u' <- computeLType gr g u
case t' == u' || alpha [] t' u' of
True -> return (True,t',u',[])
-- forgive missing lock fields by only generating a warning.
--- better: use a flag to forgive? (AR 31/1/2006)
_ -> case missingLock [] t' u' of
Ok lo -> do
checkWarn $ "missing lock field" <+> fsep lo
return (True,t',u',[])
Bad s -> return (False,t',u',s)
where
-- check that u is a subtype of t
--- quick hack version of TC.eqVal
alpha g t u = case (t,u) of
-- error (the empty type!) is subtype of any other type
(_,u) | u == typeError -> True
-- contravariance
(Prod _ x a b, Prod _ y c d) -> alpha g c a && alpha ((x,y):g) b d
-- record subtyping
(RecType rs, RecType ts) -> all (\ (l,a) ->
any (\ (k,b) -> l == k && alpha g a b) ts) rs
(ExtR r s, ExtR r' s') -> alpha g r r' && alpha g s s'
(ExtR r s, t) -> alpha g r t || alpha g s t
-- the following say that Ints n is a subset of Int and of Ints m >= n
-- But why does it also allow Int as a subtype of Ints m? /TH 2014-04-04
(t,u) | Just m <- isTypeInts t, Just n <- isTypeInts u -> m >= n
| Just _ <- isTypeInts t, u == typeInt -> True ---- check size!
| t == typeInt, Just _ <- isTypeInts u -> True ---- why this ???? AR 11/12/2005
---- this should be made in Rename
(Q (m,a), Q (n,b)) | a == b -> elem m (allExtendsPlus gr n)
|| elem n (allExtendsPlus gr m)
|| m == n --- for Predef
(QC (m,a), QC (n,b)) | a == b -> elem m (allExtendsPlus gr n)
|| elem n (allExtendsPlus gr m)
(QC (m,a), Q (n,b)) | a == b -> elem m (allExtendsPlus gr n)
|| elem n (allExtendsPlus gr m)
(Q (m,a), QC (n,b)) | a == b -> elem m (allExtendsPlus gr n)
|| elem n (allExtendsPlus gr m)
-- contravariance
(Table a b, Table c d) -> alpha g c a && alpha g b d
(Vr x, Vr y) -> x == y || elem (x,y) g || elem (y,x) g
_ -> t == u
--- the following should be one-way coercions only. AR 4/1/2001
|| elem t sTypes && elem u sTypes
|| (t == typeType && u == typePType)
|| (u == typeType && t == typePType)
missingLock g t u = case (t,u) of
(RecType rs, RecType ts) ->
let
ls = [l | (l,a) <- rs,
not (any (\ (k,b) -> alpha g a b && l == k) ts)]
(locks,others) = partition isLockLabel ls
in case others of
_:_ -> Bad $ render ("missing record fields:" <+> fsep (punctuate ',' (others)))
_ -> return locks
-- contravariance
(Prod _ x a b, Prod _ y c d) -> do
ls1 <- missingLock g c a
ls2 <- missingLock g b d
return $ ls1 ++ ls2
_ -> Bad ""
sTypes = [typeStr, typeTok, typeString]
-- auxiliaries
-- | light-weight substitution for dep. types
substituteLType :: Context -> Type -> Check Type
substituteLType g t = case t of
Vr x -> return $ maybe t id $ lookup x [(x,t) | (_,x,t) <- g]
_ -> composOp (substituteLType g) t
termWith :: Term -> Check Type -> Check (Term, Type)
termWith t ct = do
ty <- ct
return (t,ty)
-- | compositional check\/infer of binary operations
check2 :: (Term -> Check Term) -> (Term -> Term -> Term) ->
Term -> Term -> Type -> Check (Term,Type)
check2 chk con a b t = do
a' <- chk a
b' <- chk b
return (con a' b', t)
-- printing a type with a lock field lock_C as C
ppType :: Type -> Doc
ppType ty =
case ty of
RecType fs -> case filter isLockLabel $ map fst fs of
[lock] -> pp (drop 5 (showIdent (label2ident lock)))
_ -> ppTerm Unqualified 0 ty
Prod _ x a b -> ppType a <+> "->" <+> ppType b
_ -> ppTerm Unqualified 0 ty
{-
ppqType :: Type -> Type -> Doc
ppqType t u = case (ppType t, ppType u) of
(pt,pu) | render pt == render pu -> ppTerm Qualified 0 t
(pt,_) -> pt
-}
checkLookup :: Ident -> Context -> Check Type
checkLookup x g =
case [ty | (b,y,ty) <- g, x == y] of
[] -> checkError ("unknown variable" <+> x)
(ty:_) -> return ty