forked from GitHub/gf-core
some work on evaluation with abstract expressions in PGF
This commit is contained in:
krasimir
@@ -600,7 +600,7 @@ allCommands cod env@(pgf, mos) = Map.fromList [
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exec = \opts arg -> do
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case arg of
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[Fun id []] -> case Map.lookup id (funs (abstract pgf)) of
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Just (ty,eqs) -> return $ fromString $
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Just (ty,_,eqs) -> return $ fromString $
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render (text "fun" <+> text (prCId id) <+> colon <+> ppType 0 ty $$
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if null eqs
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then empty
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@@ -42,7 +42,7 @@ computeAbsTerm :: Grammar -> Exp -> Err Exp
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computeAbsTerm gr = computeAbsTermIn (lookupAbsDef gr) []
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-- | a hack to make compute work on source grammar as well
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type LookDef = Ident -> Ident -> Err (Maybe [Equation])
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type LookDef = Ident -> Ident -> Err (Maybe Int,Maybe [Equation])
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computeAbsTermIn :: LookDef -> [Ident] -> Exp -> Err Exp
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computeAbsTermIn lookd xs e = errIn ("computing" +++ prt e) $ compt xs e where
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@@ -73,7 +73,7 @@ computeAbsTermIn lookd xs e = errIn ("computing" +++ prt e) $ compt xs e where
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look t = case t of
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(Q m f) -> case lookd m f of
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Ok md -> md
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Ok (_,md) -> md
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_ -> Nothing
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_ -> Nothing
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@@ -123,7 +123,7 @@ checkAbsInfo st m mo (c,info) = do
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case info of
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AbsCat (Just cont) _ -> mkCheck "category" $
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checkContext st cont ---- also cstrs
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AbsFun (Just typ0) md -> do
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AbsFun (Just typ0) ma md -> do
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typ <- compAbsTyp [] typ0 -- to calculate let definitions
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mkCheck "type of function" $
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checkTyp st typ
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@@ -131,7 +131,7 @@ checkAbsInfo st m mo (c,info) = do
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Just eqs -> mkCheck "definition of function" $
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checkDef st (m,c) typ eqs
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Nothing -> return (c,info)
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return $ (c,AbsFun (Just typ) md)
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return $ (c,AbsFun (Just typ) ma md)
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_ -> return (c,info)
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where
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mkCheck cat ss = case ss of
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@@ -181,28 +181,28 @@ checkCompleteGrammar gr abs cnc = do
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CncCat _ _ _ -> True
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_ -> False
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checkOne js i@(c,info) = case info of
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AbsFun (Just ty) _ -> do let mb_def = do
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(cxt,(_,i),_) <- typeForm ty
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info <- lookupIdent i js
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info <- case info of
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(AnyInd _ m) -> do (m,info) <- lookupOrigInfo gr m i
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return info
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_ -> return info
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case info of
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CncCat (Just (RecType [])) _ _ -> return (foldr (\_ -> Abs identW) (R []) cxt)
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_ -> Bad "no def lin"
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case lookupIdent c js of
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Ok (CncFun _ (Just _) _ ) -> return js
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Ok (CncFun cty Nothing pn) ->
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case mb_def of
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Ok def -> return $ updateTree (c,CncFun cty (Just def) pn) js
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Bad _ -> do checkWarn $ "no linearization of" +++ prt c
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return js
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_ -> do
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case mb_def of
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Ok def -> return $ updateTree (c,CncFun Nothing (Just def) Nothing) js
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Bad _ -> do checkWarn $ "no linearization of" +++ prt c
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return js
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AbsFun (Just ty) _ _ -> do let mb_def = do
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(cxt,(_,i),_) <- typeForm ty
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info <- lookupIdent i js
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info <- case info of
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(AnyInd _ m) -> do (m,info) <- lookupOrigInfo gr m i
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return info
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_ -> return info
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case info of
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CncCat (Just (RecType [])) _ _ -> return (foldr (\_ -> Abs identW) (R []) cxt)
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_ -> Bad "no def lin"
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case lookupIdent c js of
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Ok (CncFun _ (Just _) _ ) -> return js
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Ok (CncFun cty Nothing pn) ->
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case mb_def of
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Ok def -> return $ updateTree (c,CncFun cty (Just def) pn) js
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Bad _ -> do checkWarn $ "no linearization of" +++ prt c
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return js
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_ -> do
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case mb_def of
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Ok def -> return $ updateTree (c,CncFun Nothing (Just def) Nothing) js
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Bad _ -> do checkWarn $ "no linearization of" +++ prt c
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return js
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AbsCat (Just _) _ -> case lookupIdent c js of
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Ok (AnyInd _ _) -> return js
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Ok (CncCat (Just _) _ _) -> return js
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@@ -1115,7 +1115,7 @@ allDependencies ism b =
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ResParam (Just (ps,_)) -> [Just t | (_,cont) <- ps, (_,t) <- cont]
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CncCat pty _ _ -> [pty]
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CncFun _ pt _ -> [pt] ---- (Maybe (Ident,(Context,Type))
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AbsFun pty ptr -> [pty] --- ptr is def, which can be mutual
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AbsFun pty _ ptr -> [pty] --- ptr is def, which can be mutual
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AbsCat (Just co) _ -> [Just ty | (_,ty) <- co]
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_ -> []
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@@ -201,7 +201,7 @@ hSkeleton gr =
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fns = groupBy valtypg (sortBy valtyps (map jty (Map.assocs (funs (abstract gr)))))
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valtyps (_, (_,x)) (_, (_,y)) = compare x y
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valtypg (_, (_,x)) (_, (_,y)) = x == y
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jty (f,(ty,_)) = (f,catSkeleton ty)
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jty (f,(ty,_,_)) = (f,catSkeleton ty)
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updateSkeleton :: OIdent -> HSkeleton -> (OIdent, [OIdent]) -> HSkeleton
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updateSkeleton cat skel rule =
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@@ -34,8 +34,8 @@ pgf2js pgf =
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abstract2js :: String -> Abstr -> JS.Expr
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abstract2js start ds = new "GFAbstract" [JS.EStr start, JS.EObj $ map absdef2js (Map.assocs (funs ds))]
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absdef2js :: (CId,(Type,[Equation])) -> JS.Property
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absdef2js (f,(typ,_)) =
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absdef2js :: (CId,(Type,Int,[Equation])) -> JS.Property
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absdef2js (f,(typ,_,_)) =
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let (args,cat) = M.catSkeleton typ in
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JS.Prop (JS.IdentPropName (JS.Ident (prCId f))) (new "Type" [JS.EArray [JS.EStr (prCId x) | x <- args], JS.EStr (prCId cat)])
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@@ -71,16 +71,16 @@ plCat (cat, hypos) = plFact "cat" (plTypeWithHypos typ)
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args = reverse [EVar x | (_,x) <- subst]
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typ = wildcardUnusedVars $ DTyp hypos' cat args
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plFun :: (CId, (Type, [Equation])) -> String
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plFun (fun, (typ, _)) = plFact "fun" (plp fun : plTypeWithHypos typ')
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plFun :: (CId, (Type, Int, [Equation])) -> String
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plFun (fun, (typ,_,_)) = plFact "fun" (plp fun : plTypeWithHypos typ')
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where typ' = wildcardUnusedVars $ snd $ alphaConvert emptyEnv typ
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plTypeWithHypos :: Type -> [String]
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plTypeWithHypos (DTyp hypos cat args) = [plTerm (plp cat) (map plp args), plp hypos]
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plFundef :: (CId, (Type, [Equation])) -> [String]
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plFundef (fun, (_, [])) = []
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plFundef (fun, (_, eqs)) = [plFact "def" [plp fun, plp fundef']]
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plFundef :: (CId, (Type,Int,[Equation])) -> [String]
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plFundef (fun, (_,_,[])) = []
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plFundef (fun, (_,_,eqs)) = [plFact "def" [plp fun, plp fundef']]
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where fundef' = snd $ alphaConvert emptyEnv eqs
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@@ -43,30 +43,30 @@ convertConcrete abs cnc = fixHoasFuns $ convert abs_defs' conc' cats'
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cats = lincats cnc
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(abs_defs',conc',cats') = expandHOAS abs_defs conc cats
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expandHOAS :: [(CId,(Type,[Equation]))] -> TermMap -> TermMap -> ([(CId,(Type,[Equation]))],TermMap,TermMap)
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expandHOAS :: [(CId,(Type,Int,[Equation]))] -> TermMap -> TermMap -> ([(CId,(Type,Int,[Equation]))],TermMap,TermMap)
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expandHOAS funs lins lincats = (funs' ++ hoFuns ++ varFuns,
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Map.unions [lins, hoLins, varLins],
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Map.unions [lincats, hoLincats, varLincat])
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where
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-- replace higher-order fun argument types with new categories
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funs' = [(f,(fixType ty,e)) | (f,(ty,e)) <- funs]
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funs' = [(f,(fixType ty,a,e)) | (f,(ty,a,e)) <- funs]
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where
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fixType :: Type -> Type
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fixType ty = let (ats,rt) = typeSkeleton ty in cftype (map catName ats) rt
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hoTypes :: [(Int,CId)]
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hoTypes = sortNub [(n,c) | (_,(ty,_)) <- funs, (n,c) <- fst (typeSkeleton ty), n > 0]
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hoTypes = sortNub [(n,c) | (_,(ty,_,_)) <- funs, (n,c) <- fst (typeSkeleton ty), n > 0]
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hoCats = sortNub (map snd hoTypes)
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-- for each Cat with N bindings, we add a new category _NCat
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-- each new category contains a single function __NCat : Cat -> _Var -> ... -> _Var -> _NCat
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hoFuns = [(funName ty,(cftype (c : replicate n varCat) (catName ty),[])) | ty@(n,c) <- hoTypes]
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hoFuns = [(funName ty,(cftype (c : replicate n varCat) (catName ty),0,[])) | ty@(n,c) <- hoTypes]
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-- lincats for the new categories
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hoLincats = Map.fromList [(catName ty, modifyRec (++ replicate n (S [])) (lincatOf c)) | ty@(n,c) <- hoTypes]
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-- linearizations of the new functions, lin __NCat v_0 ... v_n-1 x = { s1 = x.s1; ...; sk = x.sk; $0 = v_0.s ...
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hoLins = Map.fromList [ (funName ty, mkLin c n) | ty@(n,c) <- hoTypes]
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where mkLin c n = modifyRec (\fs -> [P (V 0) (C j) | j <- [0..length fs-1]] ++ [P (V i) (C 0) | i <- [1..n]]) (lincatOf c)
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-- for each Cat, we a add a fun _Var_Cat : _Var -> Cat
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varFuns = [(varFunName cat, (cftype [varCat] cat,[])) | cat <- hoCats]
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varFuns = [(varFunName cat, (cftype [varCat] cat,0,[])) | cat <- hoCats]
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-- linearizations of the _Var_Cat functions
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varLins = Map.fromList [(varFunName cat, R [P (V 0) (C 0)]) | cat <- hoCats]
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-- lincat for the _Var category
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@@ -98,12 +98,12 @@ fixHoasFuns pinfo = pinfo{functions=mkArray [FFun (fixName n) prof lins | FFun n
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| BS.pack "_Var_" `BS.isPrefixOf` n = wildCId
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fixName n = n
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convert :: [(CId,(Type,[Equation]))] -> TermMap -> TermMap -> ParserInfo
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convert :: [(CId,(Type,Int,[Equation]))] -> TermMap -> TermMap -> ParserInfo
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convert abs_defs cnc_defs cat_defs = getParserInfo (loop grammarEnv)
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where
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srules = [
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(XRule id args res (map findLinType args) (findLinType res) term) |
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(id, (ty,_)) <- abs_defs, let (args,res) = catSkeleton ty,
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(id, (ty,_,_)) <- abs_defs, let (args,res) = catSkeleton ty,
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term <- maybeToList (Map.lookup id cnc_defs)]
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findLinType id = fromMaybe (error $ "No lincat for " ++ show id) (Map.lookup id cat_defs)
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@@ -38,14 +38,14 @@ convertConcrete abs cnc = convert abs_defs conc cats
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conc = Map.union (opers cnc) (lins cnc) -- "union big+small most efficient"
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cats = lincats cnc
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convert :: [(CId,(Type,[Equation]))] -> TermMap -> TermMap -> ParserInfo
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convert :: [(CId,(Type,Int,[Equation]))] -> TermMap -> TermMap -> ParserInfo
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convert abs_defs cnc_defs cat_defs =
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let env = expandHOAS abs_defs cnc_defs cat_defs (emptyGrammarEnv cnc_defs cat_defs)
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in getParserInfo (List.foldl' (convertRule cnc_defs) env pfrules)
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where
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pfrules = [
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(PFRule id args (0,res) (map findLinType args) (findLinType (0,res)) term) |
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(id, (ty,_)) <- abs_defs, let (args,res) = typeSkeleton ty,
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(id, (ty,_,_)) <- abs_defs, let (args,res) = typeSkeleton ty,
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term <- maybeToList (Map.lookup id cnc_defs)]
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findLinType (_,id) = fromMaybe (error $ "No lincat for " ++ show id) (Map.lookup id cat_defs)
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@@ -320,11 +320,11 @@ expandHOAS abs_defs cnc_defs lincats env =
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foldl add_varFun (foldl (\env ncat -> add_hoFun (add_hoCat env ncat) ncat) env hoTypes) hoCats
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where
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hoTypes :: [(Int,CId)]
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hoTypes = sortNub [(n,c) | (_,(ty,_)) <- abs_defs
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hoTypes = sortNub [(n,c) | (_,(ty,_,_)) <- abs_defs
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, (n,c) <- fst (typeSkeleton ty), n > 0]
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hoCats :: [CId]
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hoCats = sortNub [c | (_,(ty,_)) <- abs_defs
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hoCats = sortNub [c | (_,(ty,_,_)) <- abs_defs
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, Hyp _ ty <- case ty of {DTyp hyps val _ -> hyps}
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, c <- fst (catSkeleton ty)]
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@@ -71,16 +71,19 @@ canon2gfcc opts pars cgr@(M.MGrammar ((a,abm):cms)) =
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mkDef (Just eqs) = [C.Equ (map mkPatt ps) (mkExp e) | (ps,e) <- eqs]
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mkDef Nothing = []
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mkArrity (Just a) = a
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mkArrity Nothing = 0
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-- concretes
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lfuns = [(f', (mkType ty, mkDef pty)) |
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(f,AbsFun (Just ty) pty) <- tree2list (M.jments abm), let f' = i2i f]
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lfuns = [(f', (mkType ty, mkArrity ma, mkDef pty)) |
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(f,AbsFun (Just ty) ma pty) <- tree2list (M.jments abm), let f' = i2i f]
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funs = Map.fromAscList lfuns
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lcats = [(i2i c, mkContext cont) |
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(c,AbsCat (Just cont) _) <- tree2list (M.jments abm)]
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cats = Map.fromAscList lcats
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catfuns = Map.fromList
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[(cat,[f | (f, (C.DTyp _ c _,_)) <- lfuns, c==cat]) | (cat,_) <- lcats]
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[(cat,[f | (f, (C.DTyp _ c _,_,_)) <- lfuns, c==cat]) | (cat,_) <- lcats]
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cncs = Map.fromList [mkConcr lang (i2i lang) mo | (lang,mo) <- cms]
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mkConcr lang0 lang mo =
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@@ -31,8 +31,8 @@ prCat :: CId -> [Hypo] -> Doc
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prCat c h | isLiteralCat c = empty
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| otherwise = text "cat" <+> text (prCId c)
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prFun :: CId -> (Type,[Equation]) -> Doc
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prFun f (t,_) = text "fun" <+> text (prCId f) <+> text ":" <+> prType t
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prFun :: CId -> (Type,Int,[Equation]) -> Doc
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prFun f (t,_,_) = text "fun" <+> text (prCId f) <+> text ":" <+> prType t
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prType :: Type -> Doc
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prType t = parens (hsep (punctuate (text ",") (map (text . prCId) cs))) <+> text "->" <+> text (prCId c)
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@@ -116,7 +116,7 @@ renameIdentPatt env p = do
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info2status :: Maybe Ident -> (Ident,Info) -> StatusInfo
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info2status mq (c,i) = case i of
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AbsFun _ Nothing -> maybe Con QC mq
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AbsFun _ _ Nothing -> maybe Con QC mq
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ResValue _ -> maybe Con QC mq
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ResParam _ -> maybe Con QC mq
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AnyInd True m -> maybe Con (const (QC m)) mq
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@@ -156,7 +156,7 @@ renameInfo mo status (i,info) = errIn
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liftM ((,) i) $ case info of
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AbsCat pco pfs -> liftM2 AbsCat (renPerh (renameContext status) pco)
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(renPerh (mapM rent) pfs)
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AbsFun pty ptr -> liftM2 AbsFun (ren pty) (renPerh (mapM (renameEquation status [])) ptr)
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AbsFun pty pa ptr -> liftM3 AbsFun (ren pty) (return pa) (renPerh (mapM (renameEquation status [])) ptr)
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ResOper pty ptr -> liftM2 ResOper (ren pty) (ren ptr)
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ResOverload os tysts ->
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liftM (ResOverload os) (mapM (pairM rent) tysts)
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@@ -236,7 +236,6 @@ checkBranch th tenv b@(ps,t) ty = errIn ("branch" +++ show b) $
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ps2ts k = foldr p2t ([],0,[],k)
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p2t p (ps,i,g,k) = case p of
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PW -> (Meta (MetaSymb i) : ps, i+1,g,k)
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PV IW -> (Meta (MetaSymb i) : ps, i+1,g,k)
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PV x -> (Vr x : ps, i, upd x k g,k+1)
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PString s -> (K s : ps, i, g, k)
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PInt n -> (EInt n : ps, i, g, k)
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@@ -163,7 +163,7 @@ extendMod gr isCompl (name,cond) base old new = foldM try new $ Map.toList old
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(b,n') = case info of
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ResValue _ -> (True,n)
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ResParam _ -> (True,n)
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AbsFun _ Nothing -> (True,n)
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AbsFun _ _ Nothing -> (True,n)
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AnyInd b k -> (b,k)
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_ -> (False,n) ---- canonical in Abs
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@@ -171,8 +171,8 @@ unifyAnyInfo :: Ident -> Info -> Info -> Err Info
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unifyAnyInfo m i j = case (i,j) of
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(AbsCat mc1 mf1, AbsCat mc2 mf2) ->
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liftM2 AbsCat (unifMaybe mc1 mc2) (unifConstrs mf1 mf2) -- adding constrs
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(AbsFun mt1 md1, AbsFun mt2 md2) ->
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liftM2 AbsFun (unifMaybe mt1 mt2) (unifAbsDefs md1 md2) -- adding defs
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(AbsFun mt1 ma1 md1, AbsFun mt2 ma2 md2) ->
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liftM3 AbsFun (unifMaybe mt1 mt2) (unifAbsArrity ma1 ma2) (unifAbsDefs md1 md2) -- adding defs
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(ResParam mt1, ResParam mt2) -> liftM ResParam $ unifMaybe mt1 mt2
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(ResValue mt1, ResValue mt2) ->
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@@ -203,6 +203,14 @@ unifMaybe (Just p1) (Just p2)
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| p1==p2 = return (Just p1)
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| otherwise = fail ""
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unifAbsArrity :: Maybe Int -> Maybe Int -> Err (Maybe Int)
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unifAbsArrity Nothing Nothing = return Nothing
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unifAbsArrity (Just a ) Nothing = return (Just a )
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unifAbsArrity Nothing (Just a ) = return (Just a )
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unifAbsArrity (Just a1) (Just a2)
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| a1==a2 = return (Just a1)
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| otherwise = fail ""
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unifAbsDefs :: Maybe [Equation] -> Maybe [Equation] -> Err (Maybe [Equation])
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unifAbsDefs Nothing Nothing = return Nothing
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unifAbsDefs (Just _ ) Nothing = fail ""
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@@ -90,7 +90,7 @@ instance Binary Options where
|
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instance Binary Info where
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put (AbsCat x y) = putWord8 0 >> put (x,y)
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put (AbsFun x y) = putWord8 1 >> put (x,y)
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put (AbsFun x y z) = putWord8 1 >> put (x,y,z)
|
||||
put (ResParam x) = putWord8 2 >> put x
|
||||
put (ResValue x) = putWord8 3 >> put x
|
||||
put (ResOper x y) = putWord8 4 >> put (x,y)
|
||||
@@ -101,7 +101,7 @@ instance Binary Info where
|
||||
get = do tag <- getWord8
|
||||
case tag of
|
||||
0 -> get >>= \(x,y) -> return (AbsCat x y)
|
||||
1 -> get >>= \(x,y) -> return (AbsFun x y)
|
||||
1 -> get >>= \(x,y,z) -> return (AbsFun x y z)
|
||||
2 -> get >>= \x -> return (ResParam x)
|
||||
3 -> get >>= \x -> return (ResValue x)
|
||||
4 -> get >>= \(x,y) -> return (ResOper x y)
|
||||
|
||||
@@ -41,7 +41,6 @@ module GF.Grammar.Grammar (SourceGrammar,
|
||||
Param,
|
||||
Altern,
|
||||
Substitution,
|
||||
wildPatt,
|
||||
varLabel, tupleLabel, linLabel, theLinLabel,
|
||||
ident2label, label2ident
|
||||
) where
|
||||
@@ -80,8 +79,8 @@ type PValues = [Term]
|
||||
-- and indirection to module (/INDIR/)
|
||||
data Info =
|
||||
-- judgements in abstract syntax
|
||||
AbsCat (Maybe Context) (Maybe [Term]) -- ^ (/ABS/) constructors; must be 'Id' or 'QId'
|
||||
| AbsFun (Maybe Type) (Maybe [Equation]) -- ^ (/ABS/)
|
||||
AbsCat (Maybe Context) (Maybe [Term]) -- ^ (/ABS/) the second parameter is list of constructors - must be 'Id' or 'QId'
|
||||
| AbsFun (Maybe Type) (Maybe Int) (Maybe [Equation]) -- ^ (/ABS/) type, arrity and definition of function
|
||||
|
||||
-- judgements in resource
|
||||
| ResParam (Maybe ([Param],Maybe PValues)) -- ^ (/RES/)
|
||||
@@ -229,6 +228,3 @@ ident2label c = LIdent (ident2bs c)
|
||||
label2ident :: Label -> Ident
|
||||
label2ident (LIdent s) = identC s
|
||||
label2ident (LVar i) = identC (BS.pack ('$':show i))
|
||||
|
||||
wildPatt :: Patt
|
||||
wildPatt = PV identW
|
||||
|
||||
@@ -121,7 +121,7 @@ lookupResType gr m c = do
|
||||
mu <- lookupModule gr a
|
||||
info <- lookupIdentInfo mu c
|
||||
case info of
|
||||
AbsFun (Just ty) _ -> return $ redirectTerm e ty
|
||||
AbsFun (Just ty) _ _ -> return $ redirectTerm e ty
|
||||
AbsCat _ _ -> return typeType
|
||||
AnyInd _ n -> lookFun e m c n
|
||||
_ -> prtBad "cannot find type of reused function" c
|
||||
@@ -227,14 +227,14 @@ qualifAnnotPar m t = case t of
|
||||
Con c -> QC m c
|
||||
_ -> composSafeOp (qualifAnnotPar m) t
|
||||
|
||||
lookupAbsDef :: SourceGrammar -> Ident -> Ident -> Err (Maybe [Equation])
|
||||
lookupAbsDef :: SourceGrammar -> Ident -> Ident -> Err (Maybe Int,Maybe [Equation])
|
||||
lookupAbsDef gr m c = errIn ("looking up absdef of" +++ prt c) $ do
|
||||
mo <- lookupModule gr m
|
||||
info <- lookupIdentInfo mo c
|
||||
case info of
|
||||
AbsFun _ (Just t) -> return (Just t)
|
||||
AnyInd _ n -> lookupAbsDef gr n c
|
||||
_ -> return Nothing
|
||||
AbsFun _ a d -> return (a,d)
|
||||
AnyInd _ n -> lookupAbsDef gr n c
|
||||
_ -> return (Nothing,Nothing)
|
||||
|
||||
lookupLincat :: SourceGrammar -> Ident -> Ident -> Err Type
|
||||
lookupLincat gr m c | isPredefCat c = return defLinType --- ad hoc; not needed?
|
||||
@@ -252,9 +252,9 @@ lookupFunType gr m c = do
|
||||
mo <- lookupModule gr m
|
||||
info <- lookupIdentInfo mo c
|
||||
case info of
|
||||
AbsFun (Just t) _ -> return t
|
||||
AnyInd _ n -> lookupFunType gr n c
|
||||
_ -> prtBad "cannot find type of" c
|
||||
AbsFun (Just t) _ _ -> return t
|
||||
AnyInd _ n -> lookupFunType gr n c
|
||||
_ -> prtBad "cannot find type of" c
|
||||
|
||||
-- | this is needed at compile time
|
||||
lookupCatContext :: SourceGrammar -> Ident -> Ident -> Err Context
|
||||
@@ -281,7 +281,7 @@ opersForType gr orig val =
|
||||
let cat = err error snd (valCat orig) in --- ignore module
|
||||
[(f,ty) |
|
||||
Ok a <- [abstractOfConcrete gr i >>= lookupModule gr],
|
||||
(f, AbsFun (Just ty0) _) <- tree2list $ jments a,
|
||||
(f, AbsFun (Just ty0) _ _) <- tree2list $ jments a,
|
||||
let ty = redirectTerm i ty0,
|
||||
Ok valt <- [valCat ty],
|
||||
cat == snd valt ---
|
||||
|
||||
@@ -414,7 +414,8 @@ linAsStr s = mkRecord linLabel [K s] -- default linearization {s = s}
|
||||
|
||||
term2patt :: Term -> Err Patt
|
||||
term2patt trm = case termForm trm of
|
||||
Ok ([], Vr x, []) -> return (PV x)
|
||||
Ok ([], Vr x, []) | x == identW -> return PW
|
||||
| otherwise -> return (PV x)
|
||||
Ok ([], Val te ty x, []) -> do
|
||||
te' <- term2patt te
|
||||
return (PVal te' ty x)
|
||||
|
||||
@@ -240,19 +240,19 @@ CatDef
|
||||
|
||||
FunDef :: { [(Ident,SrcSpan,Info)] }
|
||||
FunDef
|
||||
: Posn ListIdent ':' Exp Posn { [(fun, ($1,$5), AbsFun (Just $4) (Just [])) | fun <- $2] }
|
||||
: Posn ListIdent ':' Exp Posn { [(fun, ($1,$5), AbsFun (Just $4) Nothing (Just [])) | fun <- $2] }
|
||||
|
||||
DefDef :: { [(Ident,SrcSpan,Info)] }
|
||||
DefDef
|
||||
: Posn ListName '=' Exp Posn { [(f, ($1,$5),AbsFun Nothing (Just [([],$4)])) | f <- $2] }
|
||||
| Posn Name ListPatt '=' Exp Posn { [($2,($1,$6),AbsFun Nothing (Just [($3,$5)]))] }
|
||||
: Posn ListName '=' Exp Posn { [(f, ($1,$5),AbsFun Nothing (Just 0) (Just [([],$4)])) | f <- $2] }
|
||||
| Posn Name ListPatt '=' Exp Posn { [($2,($1,$6),AbsFun Nothing (Just (length $3)) (Just [($3,$5)]))] }
|
||||
|
||||
DataDef :: { [(Ident,SrcSpan,Info)] }
|
||||
DataDef
|
||||
: Posn Ident '=' ListDataConstr Posn { ($2, ($1,$5), AbsCat Nothing (Just (map Cn $4))) :
|
||||
[(fun, ($1,$5), AbsFun Nothing Nothing) | fun <- $4] }
|
||||
[(fun, ($1,$5), AbsFun Nothing Nothing Nothing) | fun <- $4] }
|
||||
| Posn ListIdent ':' Exp Posn { [(cat, ($1,$5), AbsCat Nothing (Just (map Cn $2))) | Ok (_,cat) <- [valCat $4]] ++
|
||||
[(fun, ($1,$5), AbsFun (Just $4) Nothing) | fun <- $2] }
|
||||
[(fun, ($1,$5), AbsFun (Just $4) Nothing Nothing) | fun <- $2] }
|
||||
|
||||
ParamDef :: { [(Ident,SrcSpan,Info)] }
|
||||
ParamDef
|
||||
@@ -481,7 +481,7 @@ Patt2
|
||||
| '[' String ']' { PChars $2 }
|
||||
| '#' Ident { PMacro $2 }
|
||||
| '#' Ident '.' Ident { PM $2 $4 }
|
||||
| '_' { wildPatt }
|
||||
| '_' { PW }
|
||||
| Ident { PV $1 }
|
||||
| Ident '.' Ident { PP $1 $3 [] }
|
||||
| Integer { PInt $1 }
|
||||
@@ -609,8 +609,8 @@ listCatDef id pos cont size = [catd,nilfund,consfund]
|
||||
consId = mkConsId id
|
||||
|
||||
catd = (listId, pos, AbsCat (Just cont') (Just [Cn baseId,Cn consId]))
|
||||
nilfund = (baseId, pos, AbsFun (Just niltyp) Nothing)
|
||||
consfund = (consId, pos, AbsFun (Just constyp) Nothing)
|
||||
nilfund = (baseId, pos, AbsFun (Just niltyp) Nothing Nothing)
|
||||
consfund = (consId, pos, AbsFun (Just constyp) Nothing Nothing)
|
||||
|
||||
cont' = [(mkId x i,ty) | (i,(x,ty)) <- zip [0..] cont]
|
||||
xs = map (Vr . fst) cont'
|
||||
@@ -667,7 +667,7 @@ type SrcSpan = (Posn,Posn)
|
||||
checkInfoType MTAbstract (id,pos,info) =
|
||||
case info of
|
||||
AbsCat _ _ -> return ()
|
||||
AbsFun _ _ -> return ()
|
||||
AbsFun _ _ _ -> return ()
|
||||
_ -> failLoc (fst pos) "illegal definition in abstract module"
|
||||
checkInfoType MTResource (id,pos,info) =
|
||||
case info of
|
||||
@@ -701,7 +701,7 @@ checkInfoType (MTInstance _) (id,pos,info) =
|
||||
checkInfoType (MTTransfer _ _) (id,pos,info) =
|
||||
case info of
|
||||
AbsCat _ _ -> return ()
|
||||
AbsFun _ _ -> return ()
|
||||
AbsFun _ _ _ -> return ()
|
||||
_ -> failLoc (fst pos) "illegal definition in transfer module"
|
||||
|
||||
|
||||
|
||||
@@ -79,7 +79,7 @@ ppJudgement q (id, AbsCat pcont pconstrs) =
|
||||
case pconstrs of
|
||||
Just costrs -> text "data" <+> ppIdent id <+> equals <+> fsep (intersperse (char '|') (map (ppTerm q 0) costrs)) <+> semi
|
||||
Nothing -> empty
|
||||
ppJudgement q (id, AbsFun ptype pexp) =
|
||||
ppJudgement q (id, AbsFun ptype _ pexp) =
|
||||
(case ptype of
|
||||
Just typ -> text "fun" <+> ppIdent id <+> colon <+> ppTerm q 0 typ <+> semi
|
||||
Nothing -> empty) $$
|
||||
|
||||
@@ -105,7 +105,7 @@ cf2cat (_,(cat, items)) = map identS $ cat : [c | Left c <- items]
|
||||
cf2rule :: CFRule -> ((Ident,Info),(Ident,Info))
|
||||
cf2rule (fun, (cat, items)) = (def,ldef) where
|
||||
f = identS fun
|
||||
def = (f, AbsFun (Just (mkProd (args', Cn (identS cat), []))) Nothing)
|
||||
def = (f, AbsFun (Just (mkProd (args', Cn (identS cat), []))) Nothing Nothing)
|
||||
args0 = zip (map (identS . ("x" ++) . show) [0..]) items
|
||||
args = [(v, Cn (identS c)) | (v, Left c) <- args0]
|
||||
args' = [(identS "_", Cn (identS c)) | (_, Left c) <- args0]
|
||||
|
||||
@@ -75,9 +75,9 @@ mkTopDefs ds = ds
|
||||
trAnyDef :: (Ident,Info) -> [P.TopDef]
|
||||
trAnyDef (i,info) = let i' = tri i in case info of
|
||||
AbsCat (Just co) pd -> [P.DefCat [P.SimpleCatDef i' (map trDecl co)]]
|
||||
AbsFun (Just ty) Nothing -> [P.DefFunData [P.FunDef [i'] (trt ty)]]
|
||||
AbsFun (Just ty) (Just eqs) -> [P.DefFun [P.FunDef [i'] (trt ty)]] ++
|
||||
[P.DefDef [P.DPatt (mkName i') (map trp patts) (trt res)] | (patts,res) <- eqs]
|
||||
AbsFun (Just ty) _ Nothing -> [P.DefFunData [P.FunDef [i'] (trt ty)]]
|
||||
AbsFun (Just ty) _ (Just eqs) -> [P.DefFun [P.FunDef [i'] (trt ty)]] ++
|
||||
[P.DefDef [P.DPatt (mkName i') (map trp patts) (trt res)] | (patts,res) <- eqs]
|
||||
|
||||
ResOper pty ptr -> [P.DefOper [trDef i' pty ptr]]
|
||||
ResParam pp -> [P.DefPar [case pp of
|
||||
|
||||
@@ -585,7 +585,7 @@ transPatts p = case p of
|
||||
|
||||
transPatt :: Patt -> Err G.Patt
|
||||
transPatt x = case x of
|
||||
PW -> return G.wildPatt
|
||||
PW -> return G.PW
|
||||
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 [])
|
||||
|
||||
Reference in New Issue
Block a user