---------------------------------------------------------------------- -- | -- Module : SourceToGF -- Maintainer : AR -- Stability : (stable) -- Portability : (portable) -- -- > CVS $Date: 2005/10/04 11:05:07 $ -- > CVS $Author: aarne $ -- > CVS $Revision: 1.28 $ -- -- based on the skeleton Haskell module generated by the BNF converter ----------------------------------------------------------------------------- module GF.Devel.Compile.SourceToGF ( transGrammar, transModDef, transExp, ---- transOldGrammar, ---- transInclude, newReservedWords ) where import qualified GF.Devel.Grammar.Grammar as G import GF.Devel.Grammar.Construct import qualified GF.Devel.Grammar.Macros as M ----import qualified GF.Compile.Update as U --import qualified GF.Infra.Option as GO --import qualified GF.Compile.ModDeps as GD import GF.Infra.Ident import GF.Devel.Compile.AbsGF import GF.Devel.Compile.PrintGF (printTree) ----import GF.Source.PrintGF ----import GF.Compile.RemoveLiT --- for bw compat import GF.Data.Operations --import GF.Infra.Option import Control.Monad import Data.Char import qualified Data.Map as Map import Data.List (genericReplicate) import Debug.Trace (trace) ---- -- based on the skeleton Haskell module generated by the BNF converter type Result = Err String failure :: Show a => a -> Err b failure x = Bad $ "Undefined case: " ++ show x getIdentPos :: PIdent -> Err (Ident,Int) getIdentPos x = case x of PIdent ((line,_),c) -> return (IC c,line) transIdent :: PIdent -> Err Ident transIdent = liftM fst . getIdentPos transName :: Name -> Err Ident transName n = case n of PIdentName i -> transIdent i ListName i -> transIdent (mkListId i) transGrammar :: Grammar -> Err G.GF transGrammar x = case x of Gr moddefs -> do moddefs' <- mapM transModDef moddefs let mos = Map.fromList moddefs' return $ emptyGF {G.gfmodules = mos} transModDef :: ModDef -> Err (Ident, G.Module) transModDef x = case x of MModule compl mtyp body -> do let isCompl = transComplMod compl (trDef, mtyp', id') <- case mtyp of MAbstract id -> do id' <- transIdent id return (transAbsDef, G.MTAbstract, id') MGrammar id -> mkModRes id G.MTGrammar body MResource id -> mkModRes id G.MTGrammar body MConcrete id open -> do id' <- transIdent id open' <- transIdent open return (transCncDef, G.MTConcrete open', id') MInterface id -> mkModRes id G.MTInterface body MInstance id open -> do open' <- transIdent open mkModRes id (G.MTInstance open') body mkBody (isCompl, trDef, mtyp', id') body where mkBody xx@(isc, trDef, mtyp', id') bod = case bod of MNoBody incls -> do mkBody xx $ MBody (Ext incls) NoOpens [] MBody extends opens defs -> do extends' <- transExtend extends opens' <- transOpens opens defs0 <- mapM trDef $ getTopDefs defs let defs' = Map.fromListWith unifyJudgements [(i,d) | Left ds <- defs0, (i,d) <- ds] let flags' = Map.fromList [f | Right fs <- defs0, f <- fs] return (id', G.Module mtyp' isc [] [] extends' opens' flags' defs') MWith m insts -> mkBody xx $ MWithEBody [] m insts NoOpens [] MWithBody m insts opens defs -> mkBody xx $ MWithEBody [] m insts opens defs MWithE extends m insts -> mkBody xx $ MWithEBody extends m insts NoOpens [] MWithEBody extends m insts opens defs -> do extends' <- mapM transIncludedExt extends m' <- transIncludedExt m insts' <- mapM transOpen insts opens' <- transOpens opens defs0 <- mapM trDef $ getTopDefs defs let defs' = Map.fromListWith unifyJudgements [(i,d) | Left ds <- defs0, (i,d) <- ds] let flags' = Map.fromList [f | Right fs <- defs0, f <- fs] return (id', G.Module mtyp' isc [] [(m',insts')] extends' opens' flags' defs') _ -> fail "deprecated module form" mkModRes id mtyp body = do id' <- transIdent id return (transResDef, mtyp, id') getTopDefs :: [TopDef] -> [TopDef] getTopDefs x = x transComplMod :: ComplMod -> Bool transComplMod x = case x of CMCompl -> True CMIncompl -> False transExtend :: Extend -> Err [(Ident,G.MInclude)] transExtend x = case x of Ext ids -> mapM transIncludedExt ids NoExt -> return [] transOpens :: Opens -> Err [(Ident,Ident)] transOpens x = case x of NoOpens -> return [] OpenIn opens -> mapM transOpen opens transOpen :: Open -> Err (Ident,Ident) transOpen x = case x of OName id -> transIdent id >>= \y -> return (y,y) OQual id m -> liftM2 (,) (transIdent id) (transIdent m) transIncludedExt :: Included -> Err (Ident, G.MInclude) transIncludedExt x = case x of IAll i -> liftM2 (,) (transIdent i) (return G.MIAll) ISome i ids -> liftM2 (,) (transIdent i) (liftM G.MIOnly $ mapM transIdent ids) IMinus i ids -> liftM2 (,) (transIdent i) (liftM G.MIExcept $ mapM transIdent ids) transAbsDef :: TopDef -> Err (Either [(Ident,G.Judgement)] [(Ident,String)]) transAbsDef x = case x of DefCat catdefs -> liftM (Left . concat) $ mapM transCatDef catdefs DefFun fundefs -> do fundefs' <- mapM transFunDef fundefs returnl [(fun, absFun typ) | (funs,typ) <- fundefs', fun <- funs] {- ---- DefFunData fundefs -> do fundefs' <- mapM transFunDef fundefs returnl $ [(cat, G.AbsCat nope (yes [M.cn fun])) | (funs,typ) <- fundefs', fun <- funs, Ok (_,cat) <- [M.valCat typ] ] ++ [(fun, G.AbsFun (yes typ) (yes G.EData)) | (funs,typ) <- fundefs', fun <- funs] DefDef defs -> do defs' <- liftM concat $ mapM getDefsGen defs returnl [(c, G.AbsFun nope pe) | (c,(_,pe)) <- defs'] DefData ds -> do ds' <- mapM transDataDef ds returnl $ [(c, G.AbsCat nope (yes ps)) | (c,ps) <- ds'] ++ [(f, G.AbsFun nope (yes G.EData)) | (_,fs) <- ds', tf <- fs, f <- funs tf] -} DefFlag defs -> liftM (Right . concat) $ mapM transFlagDef defs _ -> return $ Left [] ---- ---- _ -> Bad $ "illegal definition in abstract module:" ++++ printTree x where -- to get data constructors as terms funs t = case t of G.Con f -> [f] G.Q _ f -> [f] G.QC _ f -> [f] _ -> [] returnl :: a -> Err (Either a b) returnl = return . Left transFlagDef :: Def -> Err [(Ident,String)] transFlagDef x = case x of DDef f x -> do fs <- mapM transName f x' <- transExp x v <- case x' of G.K s -> return s G.Vr (IC s) -> return s G.EInt i -> return $ show i _ -> fail $ "illegal flag value" +++ printTree x return $ [(f',v) | f' <- fs] -- | Cat definitions can also return some fun defs -- if it is a list category definition transCatDef :: CatDef -> Err [(Ident, G.Judgement)] transCatDef x = case x of SimpleCatDef id ddecls -> liftM (:[]) $ cat id ddecls ListCatDef id ddecls -> listCat id ddecls 0 ListSizeCatDef id ddecls size -> listCat id ddecls size where cat id ddecls = do i <- transIdent id cont <- liftM concat $ mapM transDDecl ddecls return (i, absCat cont) listCat id ddecls size = do let li = mkListId id li' <- transIdent $ li baseId <- transIdent $ mkBaseId id consId <- transIdent $ mkConsId id catd0@(c,ju) <- cat li ddecls id' <- transIdent id let cont0 = [] ---- cat context catd = (c,ju) ----(Yes cont0) (Yes [M.cn baseId,M.cn consId])) cont = [(mkId x i,ty) | (i,(x,ty)) <- zip [0..] cont0] xs = map (G.Vr . fst) cont cd = M.mkDecl (M.mkApp (G.Vr id') xs) lc = M.mkApp (G.Vr li') xs niltyp = mkProd (cont ++ genericReplicate size cd) lc nilfund = (baseId, absFun niltyp) ---- (yes niltyp) (yes G.EData)) constyp = mkProd (cont ++ [cd, M.mkDecl lc]) lc consfund = (consId, absFun constyp) ---- (yes constyp) (yes G.EData)) return [catd,nilfund,consfund] mkId x i = if isWildIdent x then (mkIdent "x" i) else x transFunDef :: FunDef -> Err ([Ident], G.Type) transFunDef x = case x of FDecl ids typ -> liftM2 (,) (mapM transName ids) (transExp typ) {- ---- transDataDef :: DataDef -> Err (Ident,[G.Term]) transDataDef x = case x of DataDef id ds -> liftM2 (,) (transIdent id) (mapM transData ds) where transData d = case d of DataId id -> liftM G.Con $ transIdent id DataQId id0 id -> liftM2 G.QC (transIdent id0) (transIdent id) -} transResDef :: TopDef -> Err (Either [(Ident,G.Judgement)] [(Ident,String)]) transResDef x = case x of DefPar pardefs -> do pardefs' <- mapM transParDef pardefs returnl $ concatMap mkParamDefs pardefs' DefOper defs -> do defs' <- liftM concat $ mapM getDefs defs returnl $ concatMap mkOverload [(f, resOper pt pe) | (f,(pt,pe)) <- defs'] DefLintype defs -> do defs' <- liftM concat $ mapM getDefs defs returnl [(f, resOper pt pe) | (f,(pt,pe)) <- defs'] DefFlag defs -> liftM (Right . concat) $ mapM transFlagDef defs _ -> return $ Left [] ---- ---- _ -> Bad $ "illegal definition form in resource" +++ printTree x where mkParamDefs (p,pars) = if null pars then [(p,addJType M.meta0 (emptyJudgement G.JParam))] -- in an interface else (p,resParam p pars) : paramConstructors p pars mkOverload (c,j) = case (G.jtype j, G.jdef j) of (_,G.App keyw (G.R fs@(_:_:_))) | isOverloading keyw c fs -> [(c,resOverload [(ty,fu) | (_,(Just ty,fu)) <- fs])] -- to enable separare type signature --- not type-checked (G.App keyw (G.RecType fs@(_:_:_)),_) | isOverloading keyw c fs -> [] _ -> [(c,j)] isOverloading (G.Vr keyw) c fs = prIdent keyw == "overload" && -- overload is a "soft keyword" True ---- all (== GP.prt c) (map (GP.prt . fst) fs) transParDef :: ParDef -> Err (Ident, [(Ident,G.Context)]) transParDef x = case x of ParDefDir id params -> liftM2 (,) (transIdent id) (mapM transParConstr params) ParDefAbs id -> liftM2 (,) (transIdent id) (return []) transCncDef :: TopDef -> Err (Either [(Ident,G.Judgement)] [(Ident,String)]) transCncDef x = case x of DefLincat defs -> do defs' <- liftM concat $ mapM transPrintDef defs returnl [(f, cncCat t) | (f,t) <- defs'] ---- DefLindef defs -> do ---- defs' <- liftM concat $ mapM getDefs defs ---- returnl [(f, G.CncCat pt pe nope) | (f,(pt,pe)) <- defs'] DefLin defs -> do defs' <- liftM concat $ mapM getDefs defs returnl [(f, cncFun pe) | (f,(_,pe)) <- defs'] {- ---- DefPrintCat defs -> do defs' <- liftM concat $ mapM transPrintDef defs returnl [(f, G.CncCat nope nope (yes e)) | (f,e) <- defs'] DefPrintFun defs -> do defs' <- liftM concat $ mapM transPrintDef defs returnl [(f, G.CncFun Nothing nope (yes e)) | (f,e) <- defs'] DefPrintOld defs -> do --- a guess, for backward compatibility defs' <- liftM concat $ mapM transPrintDef defs returnl [(f, G.CncFun Nothing nope (yes e)) | (f,e) <- defs'] DefFlag defs -> liftM Right $ mapM transFlagDef defs DefPattern defs -> do defs' <- liftM concat $ mapM getDefs defs let defs2 = [(f, termInPattern t) | (f,(_,Yes t)) <- defs'] returnl [(f, G.CncFun Nothing (yes t) nope) | (f,t) <- defs2] -} _ -> return $ Left [] ---- ---- _ -> errIn ("illegal definition in concrete syntax:") $ transResDef x transPrintDef :: Def -> Err [(Ident,G.Term)] transPrintDef x = case x of DDef ids exp -> do (ids,e) <- liftM2 (,) (mapM transName ids) (transExp exp) return $ [(i,e) | i <- ids] getDefsGen :: Def -> Err [(Ident, (G.Type, G.Term))] getDefsGen d = case d of DDecl ids t -> do ids' <- mapM transName ids t' <- transExp t return [(i,(t', nope)) | i <- ids'] DDef ids e -> do ids' <- mapM transName ids e' <- transExp e return [(i,(nope, yes e')) | i <- ids'] DFull ids t e -> do ids' <- mapM transName ids t' <- transExp t e' <- transExp e return [(i,(yes t', yes e')) | i <- ids'] DPatt id patts e -> do id' <- transName id ps' <- mapM transPatt patts e' <- transExp e return [(id',(nope, yes (G.Eqs [(ps',e')])))] where yes = id nope = G.Meta 0 -- | sometimes you need this special case, e.g. in linearization rules getDefs :: Def -> Err [(Ident, (G.Type, G.Term))] getDefs d = case d of DPatt id patts e -> do id' <- transName id xs <- mapM tryMakeVar patts e' <- transExp e return [(id',(nope, (M.mkAbs xs e')))] _ -> getDefsGen d where nope = G.Meta 0 -- | accepts a pattern that is either a variable or a wild card tryMakeVar :: Patt -> Err Ident tryMakeVar p = do p' <- transPatt p case p' of G.PV i -> return i G.PW -> return identW _ -> Bad $ "not a legal pattern in lambda binding" +++ show p' transExp :: Exp -> Err G.Term transExp x = case x of EPIdent id -> liftM G.Vr $ transIdent id EConstr id -> liftM G.Con $ transIdent id ECons id -> liftM G.Con $ transIdent id EQConstr m c -> liftM2 G.QC (transIdent m) (transIdent c) EQCons m c -> liftM2 G.Q (transIdent m) (transIdent c) EString str -> return $ G.K str ESort sort -> liftM G.Sort $ transSort sort EInt n -> return $ G.EInt n EFloat n -> return $ G.EFloat n EMeta -> return $ G.Meta 0 EEmpty -> return G.Empty -- [ C x_1 ... x_n ] becomes (ListC x_1 ... x_n) EList i es -> transExp $ foldl EApp (EPIdent (mkListId i)) (exps2list es) EStrings [] -> return G.Empty EStrings str -> return $ foldr1 G.C $ map G.K $ words str ERecord defs -> erecord2term defs ETupTyp _ _ -> do let tups t = case t of ETupTyp x y -> tups x ++ [y] -- right-associative parsing _ -> [t] es <- mapM transExp $ tups x return $ G.RecType $ M.tuple2recordType es ETuple tuplecomps -> do es <- mapM transExp [e | TComp e <- tuplecomps] return $ G.R $ M.tuple2record es EProj exp id -> liftM2 G.P (transExp exp) (trLabel id) EApp exp0 exp -> liftM2 G.App (transExp exp0) (transExp exp) ETable cases -> liftM (G.T G.TRaw) (transCases cases) ETTable exp cases -> liftM2 (\t c -> G.T (G.TTyped t) c) (transExp exp) (transCases cases) EVTable exp cases -> liftM2 (\t c -> G.V t c) (transExp exp) (mapM transExp cases) ECase exp cases -> do exp' <- transExp exp cases' <- transCases cases let annot = case exp' of G.Typed _ t -> G.TTyped t _ -> G.TRaw return $ G.S (G.T annot cases') exp' ECTable binds exp -> liftM2 M.mkCTable (mapM transBind binds) (transExp exp) EVariants exps -> liftM G.FV $ mapM transExp exps EPre exp alts -> liftM2 (curry G.Alts) (transExp exp) (mapM transAltern alts) EStrs exps -> liftM G.FV $ mapM transExp exps ESelect exp0 exp -> liftM2 G.S (transExp exp0) (transExp exp) EExtend exp0 exp -> liftM2 G.ExtR (transExp exp0) (transExp exp) EAbstr binds exp -> liftM2 M.mkAbs (mapM transBind binds) (transExp exp) ETyped exp0 exp -> liftM2 G.Typed (transExp exp0) (transExp exp) EExample exp str -> liftM2 G.Example (transExp exp) (return str) EProd decl exp -> liftM2 mkProd (transDecl decl) (transExp exp) ETType exp0 exp -> liftM2 G.Table (transExp exp0) (transExp exp) EConcat exp0 exp -> liftM2 G.C (transExp exp0) (transExp exp) EGlue exp0 exp -> liftM2 G.Glue (transExp exp0) (transExp exp) ELet defs exp -> do exp' <- transExp exp defs0 <- mapM locdef2fields defs defs' <- mapM tryLoc $ concat defs0 return $ M.mkLet defs' exp' where tryLoc (c,(mty,Just e)) = return (c,(mty,e)) tryLoc (c,_) = Bad $ "local definition of" +++ prIdent c +++ "without value" ELetb defs exp -> transExp $ ELet defs exp EWhere exp defs -> transExp $ ELet defs exp EPattType typ -> liftM G.EPattType (transExp typ) EPatt patt -> liftM G.EPatt (transPatt patt) ELString (LString str) -> return $ G.K str ---- ELin id -> liftM G.LiT $ transIdent id EEqs eqs -> liftM G.Eqs $ mapM transEquation eqs EData -> return G.EData _ -> Bad $ "translation not yet defined for" +++ printTree x ---- exps2list :: Exps -> [Exp] exps2list NilExp = [] exps2list (ConsExp e es) = e : exps2list es --- this is complicated: should we change Exp or G.Term ? erecord2term :: [LocDef] -> Err G.Term erecord2term ds = do ds' <- mapM locdef2fields ds mkR $ concat ds' where mkR fs = do fs' <- transF fs return $ case fs' of Left ts -> G.RecType ts Right ds -> G.R ds transF [] = return $ Left [] --- empty record always interpreted as record type transF fs@(f:_) = case f of (lab,(Just ty,Nothing)) -> mapM tryRT fs >>= return . Left _ -> mapM tryR fs >>= return . Right tryRT f = case f of (lab,(Just ty,Nothing)) -> return (M.ident2label lab,ty) _ -> Bad $ "illegal record type field" +++ show (fst f) --- manifest fields ?! tryR f = case f of (lab,(mty, Just t)) -> return (M.ident2label lab,(mty,t)) _ -> Bad $ "illegal record field" +++ show (fst f) locdef2fields :: LocDef -> Err [(Ident, (Maybe G.Type, Maybe G.Type))] locdef2fields d = case d of LDDecl ids t -> do labs <- mapM transIdent ids t' <- transExp t return [(lab,(Just t',Nothing)) | lab <- labs] LDDef ids e -> do labs <- mapM transIdent ids e' <- transExp e return [(lab,(Nothing, Just e')) | lab <- labs] LDFull ids t e -> do labs <- mapM transIdent ids t' <- transExp t e' <- transExp e return [(lab,(Just t', Just e')) | lab <- labs] trLabel :: Label -> Err G.Label trLabel x = case x of -- this case is for bward compatibiity and should be removed LPIdent (PIdent (_,'v':ds)) | all isDigit ds -> return $ G.LVar $ readIntArg ds LPIdent (PIdent (_, s)) -> return $ G.LIdent s LVar x -> return $ G.LVar $ fromInteger x transSort :: Sort -> Err String transSort x = case x of _ -> return $ printTree x transPatt :: Patt -> Err G.Patt transPatt x = case x of PChar -> return G.PChar PChars s -> return $ G.PChars s PMacro c -> liftM G.PMacro $ transIdent c PM m c -> liftM2 G.PM (transIdent m) (transIdent c) PW -> return wildPatt PV (PIdent (_,"_")) -> return wildPatt PV id -> liftM G.PV $ transIdent id PC id patts -> liftM2 G.PC (transIdent id) (mapM transPatt patts) PCon id -> liftM2 G.PC (transIdent id) (return []) PInt n -> return $ G.PInt n PFloat n -> return $ G.PFloat n PStr str -> return $ G.PString str PR pattasss -> do let (lss,ps) = unzip [(ls,p) | PA ls p <- pattasss] ls = map LPIdent $ concat lss liftM G.PR $ liftM2 zip (mapM trLabel ls) (mapM transPatt ps) PTup pcs -> liftM (G.PR . M.tuple2recordPatt) (mapM transPatt [e | PTComp e <- pcs]) PQ id0 id -> liftM3 G.PP (transIdent id0) (transIdent id) (return []) PQC id0 id patts -> liftM3 G.PP (transIdent id0) (transIdent id) (mapM transPatt patts) PDisj p1 p2 -> liftM2 G.PAlt (transPatt p1) (transPatt p2) PSeq p1 p2 -> liftM2 G.PSeq (transPatt p1) (transPatt p2) PRep p -> liftM G.PRep (transPatt p) PNeg p -> liftM G.PNeg (transPatt p) PAs x p -> liftM2 G.PAs (transIdent x) (transPatt p) transBind :: Bind -> Err Ident transBind x = case x of BPIdent (PIdent (_,"_")) -> return identW BPIdent id -> transIdent id BWild -> return identW transDecl :: Decl -> Err [G.Decl] transDecl x = case x of DDec binds exp -> do xs <- mapM transBind binds exp' <- transExp exp return [(x,exp') | x <- xs] DExp exp -> liftM (return . M.mkDecl) $ transExp exp transCases :: [Case] -> Err [G.Case] transCases = mapM transCase transCase :: Case -> Err G.Case transCase (Case p exp) = do patt <- transPatt p exp' <- transExp exp return (patt,exp') transEquation :: Equation -> Err G.Equation transEquation x = case x of Equ apatts exp -> liftM2 (,) (mapM transPatt apatts) (transExp exp) transAltern :: Altern -> Err (G.Term, G.Term) transAltern x = case x of Alt exp0 exp -> liftM2 (,) (transExp exp0) (transExp exp) transParConstr :: ParConstr -> Err (Ident,G.Context) transParConstr x = case x of ParConstr id ddecls -> do id' <- transIdent id ddecls' <- mapM transDDecl ddecls return (id',concat ddecls') transDDecl :: DDecl -> Err [G.Decl] transDDecl x = case x of DDDec binds exp -> transDecl $ DDec binds exp DDExp exp -> transDecl $ DExp exp {- ---- -- | to deal with the old format, sort judgements in three modules, forming -- their names from a given string, e.g. file name or overriding user-given string transOldGrammar :: Options -> FilePath -> OldGrammar -> Err G.SourceGrammar transOldGrammar opts name0 x = case x of OldGr includes topdefs -> do --- includes must be collected separately let moddefs = sortTopDefs topdefs g1 <- transGrammar $ Gr moddefs removeLiT g1 --- needed for bw compatibility with an obsolete feature where sortTopDefs ds = [mkAbs a,mkRes ops r,mkCnc ops c] ++ map mkPack ps where ops = map fst ps (a,r,c,ps) = foldr srt ([],[],[],[]) ds srt d (a,r,c,ps) = case d of DefCat catdefs -> (d:a,r,c,ps) DefFun fundefs -> (d:a,r,c,ps) DefFunData fundefs -> (d:a,r,c,ps) DefDef defs -> (d:a,r,c,ps) DefData pardefs -> (d:a,r,c,ps) DefPar pardefs -> (a,d:r,c,ps) DefOper defs -> (a,d:r,c,ps) DefLintype defs -> (a,d:r,c,ps) DefLincat defs -> (a,r,d:c,ps) DefLindef defs -> (a,r,d:c,ps) DefLin defs -> (a,r,d:c,ps) DefPattern defs -> (a,r,d:c,ps) DefFlag defs -> (a,r,d:c,ps) --- a guess DefPrintCat printdefs -> (a,r,d:c,ps) DefPrintFun printdefs -> (a,r,d:c,ps) DefPrintOld printdefs -> (a,r,d:c,ps) DefPackage m ds -> (a,r,c,(m,ds):ps) _ -> (a,r,c,ps) mkAbs a = MModule q (MTAbstract absName) (MBody ne (OpenIn []) (topDefs a)) mkRes ps r = MModule q (MTResource resName) (MBody ne (OpenIn ops) (topDefs r)) where ops = map OName ps mkCnc ps r = MModule q (MTConcrete cncName absName) (MBody ne (OpenIn (map OName (resName:ps))) (topDefs r)) mkPack (m, ds) = MModule q (MTResource m) (MBody ne (OpenIn []) (topDefs ds)) topDefs t = t ne = NoExt q = CMCompl name = maybe name0 (++ ".gf") $ getOptVal opts useName absName = identC $ maybe topic id $ getOptVal opts useAbsName resName = identC $ maybe ("Res" ++ lang) id $ getOptVal opts useResName cncName = identC $ maybe lang id $ getOptVal opts useCncName (beg,rest) = span (/='.') name (topic,lang) = case rest of -- to avoid overwriting old files ".gf" -> ("Abs" ++ beg,"Cnc" ++ beg) ".cf" -> ("Abs" ++ beg,"Cnc" ++ beg) ".ebnf" -> ("Abs" ++ beg,"Cnc" ++ beg) [] -> ("Abs" ++ beg,"Cnc" ++ beg) _:s -> (beg, takeWhile (/='.') s) transInclude :: Include -> Err [FilePath] transInclude x = case x of NoIncl -> return [] Incl filenames -> return $ map trans filenames where trans f = case f of FString s -> s FIdent (IC s) -> modif s FSlash filename -> '/' : trans filename FDot filename -> '.' : trans filename FMinus filename -> '-' : trans filename FAddId (IC s) filename -> modif s ++ trans filename modif s = let s' = init s ++ [toLower (last s)] in if elem s' newReservedWords then s' else s --- unsafe hack ; cf. GetGrammar.oldLexer -} newReservedWords :: [String] newReservedWords = words $ "abstract concrete interface incomplete " ++ "instance out open resource reuse transfer union with where" termInPattern :: G.Term -> G.Term termInPattern t = M.mkAbs xx $ G.R [(s, (Nothing, toP body))] where toP t = case t of G.Vr x -> G.P t s _ -> M.composSafeOp toP t s = G.LIdent "s" (xx,body) = abss [] t abss xs t = case t of G.Abs x b -> abss (x:xs) b _ -> (reverse xs,t) mkListId,mkConsId,mkBaseId :: PIdent -> PIdent mkListId = prefixId "List" mkConsId = prefixId "Cons" mkBaseId = prefixId "Base" prefixId :: String -> PIdent -> PIdent prefixId pref (PIdent (p,id)) = PIdent (p, pref ++ id)