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|
----------------------------------------------------------------------
-- |
-- Module : CheckGrammar
-- Maintainer : AR
-- Stability : (stable)
-- Portability : (portable)
--
-- > CVS $Date: 2005/11/11 23:24:33 $
-- > CVS $Author: aarne $
-- > CVS $Revision: 1.31 $
--
-- AR 4\/12\/1999 -- 1\/4\/2000 -- 8\/9\/2001 -- 15\/5\/2002 -- 27\/11\/2002 -- 18\/6\/2003
--
-- type checking also does the following modifications:
--
-- - types of operations and local constants are inferred and put in place
--
-- - both these types and linearization types are computed
--
-- - tables are type-annotated
-----------------------------------------------------------------------------
module GF.Compile.CheckGrammar(checkModule) where
import Prelude hiding ((<>)) -- GHC 8.4.1 clash with Text.PrettyPrint
import GF.Infra.Ident
import GF.Infra.Option
import GF.Compile.TypeCheck.Abstract
import GF.Compile.TypeCheck.RConcrete
import qualified GF.Compile.TypeCheck.ConcreteNew as CN
import qualified GF.Compile.Compute.ConcreteNew as CN
import GF.Grammar
import GF.Grammar.Lexer
import GF.Grammar.Lookup
--import GF.Grammar.Predef
--import GF.Grammar.PatternMatch
import GF.Data.Operations
import GF.Infra.CheckM
import Data.List
import qualified Data.Set as Set
import Control.Monad
import GF.Text.Pretty
-- | checking is performed in the dependency order of modules
checkModule :: Options -> FilePath -> SourceGrammar -> SourceModule -> Check SourceModule
checkModule opts cwd sgr mo@(m,mi) = do
checkRestrictedInheritance cwd sgr mo
mo <- case mtype mi of
MTConcrete a -> do let gr = prependModule sgr mo
abs <- lookupModule gr a
checkCompleteGrammar opts cwd gr (a,abs) mo
_ -> return mo
infoss <- checkInModule cwd mi NoLoc empty $ topoSortJments2 mo
foldM updateCheckInfos mo infoss
where
updateCheckInfos mo = fmap (foldl update mo) . parallelCheck . map check
where check (i,info) = fmap ((,) i) (checkInfo opts cwd sgr mo i info)
update mo@(m,mi) (i,info) = (m,mi{jments=updateTree (i,info) (jments mi)})
-- check if restricted inheritance modules are still coherent
-- i.e. that the defs of remaining names don't depend on omitted names
checkRestrictedInheritance :: FilePath -> SourceGrammar -> SourceModule -> Check ()
checkRestrictedInheritance cwd sgr (name,mo) = checkInModule cwd mo NoLoc empty $ do
let irs = [ii | ii@(_,mi) <- mextend mo, mi /= MIAll] -- names with restr. inh.
let mrs = [((i,m),mi) | (i,m) <- mos, Just mi <- [lookup i irs]]
-- the restr. modules themself, with restr. infos
mapM_ checkRem mrs
where
mos = modules sgr
checkRem ((i,m),mi) = do
let (incl,excl) = partition (isInherited mi) (map fst (tree2list (jments m)))
let incld c = Set.member c (Set.fromList incl)
let illegal c = Set.member c (Set.fromList excl)
let illegals = [(f,is) |
(f,cs) <- allDeps, incld f, let is = filter illegal cs, not (null is)]
case illegals of
[] -> return ()
cs -> checkWarn ("In inherited module" <+> i <> ", dependence of excluded constants:" $$
nest 2 (vcat [f <+> "on" <+> fsep is | (f,is) <- cs]))
allDeps = concatMap (allDependencies (const True) . jments . snd) mos
checkCompleteGrammar :: Options -> FilePath -> Grammar -> Module -> Module -> Check Module
checkCompleteGrammar opts cwd gr (am,abs) (cm,cnc) = checkInModule cwd cnc NoLoc empty $ do
let jsa = jments abs
let jsc = jments cnc
-- check that all concrete constants are in abstract; build types for all lin
jsc <- foldM checkCnc emptyBinTree (tree2list jsc)
-- check that all abstract constants are in concrete; build default lin and lincats
jsc <- foldM checkAbs jsc (tree2list jsa)
return (cm,cnc{jments=jsc})
where
checkAbs js i@(c,info) =
case info of
AbsFun (Just (L loc ty)) _ _ _
-> do let mb_def = do
let (cxt,(_,i),_) = typeForm ty
info <- lookupIdent i js
info <- case info of
(AnyInd _ m) -> do (m,info) <- lookupOrigInfo gr (m,i)
return info
_ -> return info
case info of
CncCat (Just (L loc (RecType []))) _ _ _ _ -> return (foldr (\_ -> Abs Explicit identW) (R []) cxt)
_ -> Bad "no def lin"
case lookupIdent c js of
Ok (AnyInd _ _) -> return js
Ok (CncFun ty (Just def) mn mf) ->
return $ updateTree (c,CncFun ty (Just def) mn mf) js
Ok (CncFun ty Nothing mn mf) ->
case mb_def of
Ok def -> return $ updateTree (c,CncFun ty (Just (L NoLoc def)) mn mf) js
Bad _ -> do noLinOf c
return js
_ -> do
case mb_def of
Ok def -> do (cont,val) <- linTypeOfType gr cm ty
let linty = (snd (valCat ty),cont,val)
return $ updateTree (c,CncFun (Just linty) (Just (L NoLoc def)) Nothing Nothing) js
Bad _ -> do noLinOf c
return js
where noLinOf c = checkWarn ("no linearization of" <+> c)
AbsCat (Just _) -> case lookupIdent c js of
Ok (AnyInd _ _) -> return js
Ok (CncCat (Just _) _ _ _ _) -> return js
Ok (CncCat Nothing md mr mp mpmcfg) -> do
checkWarn ("no linearization type for" <+> c <> ", inserting default {s : Str}")
return $ updateTree (c,CncCat (Just (L NoLoc defLinType)) md mr mp mpmcfg) js
_ -> do
checkWarn ("no linearization type for" <+> c <> ", inserting default {s : Str}")
return $ updateTree (c,CncCat (Just (L NoLoc defLinType)) Nothing Nothing Nothing Nothing) js
_ -> return js
checkCnc js i@(c,info) =
case info of
CncFun _ d mn mf -> case lookupOrigInfo gr (am,c) of
Ok (_,AbsFun (Just (L _ ty)) _ _ _) ->
do (cont,val) <- linTypeOfType gr cm ty
let linty = (snd (valCat ty),cont,val)
return $ updateTree (c,CncFun (Just linty) d mn mf) js
_ -> do checkWarn ("function" <+> c <+> "is not in abstract")
return js
CncCat _ _ _ _ _ -> case lookupOrigInfo gr (am,c) of
Ok _ -> return $ updateTree i js
_ -> do checkWarn ("category" <+> c <+> "is not in abstract")
return js
_ -> return $ updateTree i js
-- | General Principle: only Just-values are checked.
-- A May-value has always been checked in its origin module.
checkInfo :: Options -> FilePath -> SourceGrammar -> SourceModule -> Ident -> Info -> Check Info
checkInfo opts cwd sgr (m,mo) c info = checkInModule cwd mo NoLoc empty $ do
checkReservedId c
case info of
AbsCat (Just (L loc cont)) ->
mkCheck loc "the category" $
checkContext gr cont
AbsFun (Just (L loc typ0)) ma md moper -> do
typ <- compAbsTyp [] typ0 -- to calculate let definitions
mkCheck loc "the type of function" $
checkTyp gr typ
case md of
Just eqs -> mapM_ (\(L loc eq) -> mkCheck loc "the definition of function" $
checkDef gr (m,c) typ eq) eqs
Nothing -> return ()
return (AbsFun (Just (L loc typ)) ma md moper)
CncCat mty mdef mref mpr mpmcfg -> do
mty <- case mty of
Just (L loc typ) -> chIn loc "linearization type of" $
(if False --flag optNewComp opts
then do (typ,_) <- CN.checkLType (CN.resourceValues opts gr) typ typeType
typ <- computeLType gr [] typ
return (Just (L loc typ))
else do (typ,_) <- checkLType gr [] typ typeType
typ <- computeLType gr [] typ
return (Just (L loc typ)))
Nothing -> return Nothing
mdef <- case (mty,mdef) of
(Just (L _ typ),Just (L loc def)) ->
chIn loc "default linearization of" $ do
(def,_) <- checkLType gr [] def (mkFunType [typeStr] typ)
return (Just (L loc def))
_ -> return Nothing
mref <- case (mty,mref) of
(Just (L _ typ),Just (L loc ref)) ->
chIn loc "reference linearization of" $ do
(ref,_) <- checkLType gr [] ref (mkFunType [typ] typeStr)
return (Just (L loc ref))
_ -> return Nothing
mpr <- case mpr of
(Just (L loc t)) ->
chIn loc "print name of" $ do
(t,_) <- checkLType gr [] t typeStr
return (Just (L loc t))
_ -> return Nothing
return (CncCat mty mdef mref mpr mpmcfg)
CncFun mty mt mpr mpmcfg -> do
mt <- case (mty,mt) of
(Just (cat,cont,val),Just (L loc trm)) ->
chIn loc "linearization of" $ do
(trm,_) <- checkLType gr [] trm (mkFunType (map (\(_,_,ty) -> ty) cont) val) -- erases arg vars
return (Just (L loc trm))
_ -> return mt
mpr <- case mpr of
(Just (L loc t)) ->
chIn loc "print name of" $ do
(t,_) <- checkLType gr [] t typeStr
return (Just (L loc t))
_ -> return Nothing
return (CncFun mty mt mpr mpmcfg)
ResOper pty pde -> do
(pty', pde') <- case (pty,pde) of
(Just (L loct ty), Just (L locd de)) -> do
ty' <- chIn loct "operation" $
(if False --flag optNewComp opts
then CN.checkLType (CN.resourceValues opts gr) ty typeType >>= return . CN.normalForm (CN.resourceValues opts gr) (L loct c) . fst -- !!
else checkLType gr [] ty typeType >>= computeLType gr [] . fst)
(de',_) <- chIn locd "operation" $
(if False -- flag optNewComp opts
then CN.checkLType (CN.resourceValues opts gr) de ty'
else checkLType gr [] de ty')
return (Just (L loct ty'), Just (L locd de'))
(Nothing , Just (L locd de)) -> do
(de',ty') <- chIn locd "operation" $
(if False -- flag optNewComp opts
then CN.inferLType (CN.resourceValues opts gr) de
else inferLType gr [] de)
return (Just (L locd ty'), Just (L locd de'))
(Just (L loct ty), Nothing) -> do
chIn loct "operation" $
checkError (pp "No definition given to the operation")
return (ResOper pty' pde')
ResOverload os tysts -> chIn NoLoc "overloading" $ do
tysts' <- mapM (uncurry $ flip (\(L loc1 t) (L loc2 ty) -> checkLType gr [] t ty >>= \(t,ty) -> return (L loc1 t, L loc2 ty))) tysts -- return explicit ones
tysts0 <- lookupOverload gr (m,c) -- check against inherited ones too
tysts1 <- mapM (uncurry $ flip (checkLType gr []))
[(mkFunType args val,tr) | (args,(val,tr)) <- tysts0]
--- this can only be a partial guarantee, since matching
--- with value type is only possible if expected type is given
checkUniq $
sort [let (xs,t) = typeFormCnc x in t : map (\(b,x,t) -> t) xs | (_,x) <- tysts1]
return (ResOverload os [(y,x) | (x,y) <- tysts'])
ResParam (Just (L loc pcs)) _ -> do
ts <- chIn loc "parameter type" $
liftM concat $ mapM mkPar pcs
return (ResParam (Just (L loc pcs)) (Just ts))
_ -> return info
where
gr = prependModule sgr (m,mo)
chIn loc cat = checkInModule cwd mo loc ("Happened in" <+> cat <+> c)
mkPar (f,co) = do
vs <- liftM combinations $ mapM (\(_,_,ty) -> allParamValues gr ty) co
return $ map (mkApp (QC (m,f))) vs
checkUniq xss = case xss of
x:y:xs
| x == y -> checkError $ "ambiguous for type" <+>
ppType (mkFunType (tail x) (head x))
| otherwise -> checkUniq $ y:xs
_ -> return ()
mkCheck loc cat ss = case ss of
[] -> return info
_ -> chIn loc cat $ checkError (vcat ss)
compAbsTyp g t = case t of
Vr x -> maybe (checkError ("no value given to variable" <+> x)) return $ lookup x g
Let (x,(_,a)) b -> do
a' <- compAbsTyp g a
compAbsTyp ((x, a'):g) b
Prod b x a t -> do
a' <- compAbsTyp g a
t' <- compAbsTyp ((x,Vr x):g) t
return $ Prod b x a' t'
Abs _ _ _ -> return t
_ -> composOp (compAbsTyp g) t
-- | for grammars obtained otherwise than by parsing ---- update!!
checkReservedId :: Ident -> Check ()
checkReservedId x =
when (isReservedWord x) $
checkWarn ("reserved word used as identifier:" <+> x)
-- auxiliaries
-- | linearization types and defaults
linTypeOfType :: Grammar -> ModuleName -> Type -> Check (Context,Type)
linTypeOfType cnc m typ = do
let (cont,cat) = typeSkeleton typ
val <- lookLin cat
args <- mapM mkLinArg (zip [0..] cont)
return (args, val)
where
mkLinArg (i,(n,mc@(m,cat))) = do
val <- lookLin mc
let vars = mkRecType varLabel $ replicate n typeStr
symb = argIdent n cat i
rec <- if n==0 then return val else
errIn (render ("extending" $$
nest 2 vars $$
"with" $$
nest 2 val)) $
plusRecType vars val
return (Explicit,symb,rec)
lookLin (_,c) = checks [ --- rather: update with defLinType ?
lookupLincat cnc m c >>= computeLType cnc []
,return defLinType
]
|
