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gf-core/src/compiler/GF/Compile/CheckGrammar.hs
hallgren f27d509075 Introducing GF.Text.Pretty for more concise pretty printers and GF.Infra.Location for modularity 
GF.Text.Pretty provides the class Pretty and overloaded versions of the pretty
printing combinators in Text.PrettyPrint, allowing pretty printable values to
be used directly instead of first having to convert them to Doc with functions
like text, int, char and ppIdent. Some modules have been converted to use
GF.Text.Pretty, but not all. Precedences could be added to simplify the pretty
printers for terms and patterns.

GF.Infra.Location contains the types Location and L, factored out from
GF.Grammar.Grammar, and the class HasSourcePath. This allowed the import
of GF.Grammar.Grammar to be removed from GF.Infra.CheckM, making it more
like a pure library module.
2014-07-27 22:06:23 +00:00

327 lines
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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 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 -> SourceGrammar -> SourceModule -> SourceModule -> Check SourceModule
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 = when (verbAtLeast opts Normal) $
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 = do
checkInModule cwd mo NoLoc empty $
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 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 gr ty typeType >>= return . CN.normalForm (CN.resourceValues 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 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 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 :: SourceGrammar -> Ident -> 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
]
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