Ana.hs revision dcf7a9c571e15547fd5302de8064663a486c26fa
{- |
Module : $Header$
Description : static analysis of VSE parts
Copyright : (c) C. Maeder, DFKI Bremen 2008
License : similar to LGPL, see HetCATS/LICENSE.txt or LIZENZ.txt
Maintainer : Christian.Maeder@dfki.de
Stability : provisional
Portability : portable
analysis of VSE logic extension of CASL
-}
module VSE.Ana where
import Data.Maybe
import qualified Data.Map as Map
import qualified Data.Set as Set
import qualified Common.Lib.Rel as Rel
import Common.AS_Annotation
import Common.GlobalAnnotations
import Common.ExtSign
import Common.Id
import Common.Result
import Common.Lib.State
import CASL.AS_Basic_CASL
import CASL.Fold
import CASL.Sign
import CASL.MixfixParser
import CASL.MapSentence as MapSen
import CASL.Morphism
import CASL.Overload
import CASL.Quantification
import CASL.StaticAna
import CASL.ShowMixfix as Paren
import CASL.SimplifySen
import CASL.ToSExpr
import VSE.As
lookupProc :: Id -> Sign f Procs -> Maybe Profile
lookupProc i sig = Map.lookup i $ procsMap $ extendedInfo sig
basicAna
:: (BASIC_SPEC () Procdecls Dlformula,
Sign Dlformula Procs, GlobalAnnos)
-> Result (BASIC_SPEC () Procdecls Dlformula,
ExtSign (Sign Dlformula Procs) Symbol,
[Named Sentence])
basicAna =
basicAnalysis minExpForm (const return) anaProcdecls anaMix
anaMix :: Mix () Procdecls Dlformula Procs
anaMix = emptyMix
{ putParen = parenDlFormula
, mixResolve = resolveDlformula }
-- | put parens around ambiguous mixfix formulas (for error messages)
parenDlFormula :: Dlformula -> Dlformula
parenDlFormula (Ranged f r) = case f of
Dlformula b p s ->
let n = mapFormula parenDlFormula s
in Ranged (Dlformula b (parenProg p) n) r
Defprocs ps -> Ranged (Defprocs $ map parenDefproc ps) r
mapProg :: (TERM () -> TERM ()) -> (FORMULA () -> FORMULA ())
-> FoldRec Program
mapProg mt mf = mapRec
{ foldAssign = \ (Ranged _ r) v t -> Ranged (Assign v $ mt t) r
, foldCall = \ (Ranged _ r) f -> Ranged (Call $ mf f) r
, foldReturn = \ (Ranged _ r) t -> Ranged (Return $ mt t) r
, foldIf = \ (Ranged _ r) c p1 p2 -> Ranged (If (mf c) p1 p2) r
, foldWhile = \ (Ranged _ r) c p -> Ranged (While (mf c) p) r }
parenProg :: Program -> Program
parenProg = foldProg $ mapProg (Paren.mapTerm id) $ mapFormula id
parenDefproc :: Defproc -> Defproc
parenDefproc (Defproc k i vs p r) = Defproc k i vs (parenProg p) r
-- | resolve mixfix applications of terms and formulas
resolveDlformula :: MixResolve Dlformula
resolveDlformula ga rules (Ranged f r) = case f of
Dlformula b p s -> do
np <- resolveProg ga rules p
n <- resolveMixFrm id resolveDlformula ga rules s
return $ Ranged (Dlformula b np n) r
Defprocs ps -> do
nps <- mapM (resolveDefproc ga rules) ps
return $ Ranged (Defprocs nps) r
resolveT :: MixResolve (TERM ())
resolveT = resolveMixTrm id (mixResolve emptyMix)
resolveF :: MixResolve (FORMULA ())
resolveF = resolveMixFrm id (mixResolve emptyMix)
resolveProg :: MixResolve Program
resolveProg ga rules p@(Ranged prg r) = case prg of
Abort -> return p
Skip -> return p
Assign v t -> do
nt <- resolveT ga rules t
return $ Ranged (Assign v nt) r
Call f -> do
nf <- resolveF ga rules f
return $ Ranged (Call nf) r
Return t -> do
nt <- resolveT ga rules t
return $ Ranged (Return nt) r
Block vs q -> do
np <- resolveProg ga rules q
return $ Ranged (Block vs np) r
Seq p1 p2 -> do
p3 <- resolveProg ga rules p1
p4 <- resolveProg ga rules p2
return $ Ranged (Seq p3 p4) r
If f p1 p2 -> do
c <- resolveF ga rules f
p3 <- resolveProg ga rules p1
p4 <- resolveProg ga rules p2
return $ Ranged (If c p3 p4) r
While f q -> do
c <- resolveF ga rules f
np <- resolveProg ga rules q
return $ Ranged (While c np) r
resolveDefproc :: MixResolve Defproc
resolveDefproc ga rules (Defproc k i vs p r) = do
np <- resolveProg ga rules p
return $ Defproc k i vs np r
-- | resolve overloading and type check terms and formulas
minExpForm :: Min Dlformula Procs
minExpForm sign (Ranged f r) = let sig = castSign sign in case f of
Dlformula b p s -> do
np <- minExpProg Set.empty Nothing sig p
n <- minExpFORMULA minExpForm sig s
return $ Ranged (Dlformula b np n) r
Defprocs ps -> do
nps <- mapM (minProcdecl sig) ps
return $ Ranged (Defprocs nps) r
oneExpT :: Sign () Procs -> TERM () -> Result (TERM ())
oneExpT = oneExpTerm (const return)
minExpF :: Sign () Procs -> FORMULA () -> Result (FORMULA ())
minExpF = minExpFORMULA (const return)
minExpProg :: Set.Set VAR -> Maybe SORT -> Sign () Procs
-> Program -> Result Program
minExpProg invars res sig p@(Ranged prg r) = let
tRec = sRec False sig $ error "minExpProg"
checkCond = foldFormula tRec
checkTerm = foldTerm tRec
in case prg of
Abort -> return p
Skip -> return p
Assign v t -> case Map.lookup v $ varMap sig of
Nothing -> Result [mkDiag Error "undeclared program variable" v] Nothing
Just s -> do
nt <- oneExpT sig $ Sorted_term t s r
checkTerm nt
if Set.member v invars then
Result [mkDiag Warning "assignment to input variable" v] $ Just ()
else return ()
return $ Ranged (Assign v nt) r
Call f -> case f of
Predication ps ts _ -> do
let i = case ps of
Pred_name j -> j
Qual_pred_name j _ _ -> j
case lookupProc i sig of
Nothing -> Result [mkDiag Error "unknown procedure" i] Nothing
Just (Profile l re) -> let
nl = case re of
Nothing -> l
Just s -> l ++ [Procparam Out s]
in if length nl /= length ts then
Result [mkDiag Error "non-matching number of parameters for" i]
Nothing
else do
if length l < length nl then
Result [mkDiag Warning "function used as procedure" i] $ Just ()
else return ()
nf <- minExpF sig f
checkCond nf
return $ Ranged (Call nf) r
_ -> Result [mkDiag Error "no procedure call" f] Nothing
Return t -> case res of
Nothing -> Result [mkDiag Error "unexpected return statement" t] Nothing
Just s -> do
nt <- oneExpT sig $ Sorted_term t s r
checkTerm nt
return $ Ranged (Return nt) r
Block vs q -> do
let (_, sign') = runState (mapM_ addVars vs) sig { envDiags = [] }
Result (envDiags sign') $ Just ()
np <- minExpProg invars res sign' q
return $ Ranged (Block vs np) r
Seq p1 p2 -> do
p3 <- minExpProg invars res sig p1
p4 <- minExpProg invars res sig p2
return $ Ranged (Seq p3 p4) r
If f p1 p2 -> do
c <- minExpF sig f
checkCond c
p3 <- minExpProg invars res sig p1
p4 <- minExpProg invars res sig p2
return $ Ranged (If c p3 p4) r
While f q -> do
c <- minExpF sig f
checkCond c
np <- minExpProg invars res sig q
return $ Ranged (While c np) r
minProcdecl :: Sign () Procs -> Defproc -> Result Defproc
minProcdecl sig (Defproc k i vs p r) = case lookupProc i sig of
Nothing -> Result [mkDiag Error "unknown procedure" i] Nothing
Just (Profile l re) -> if length vs /= length l then
Result [mkDiag Error "unknown procedure" i] Nothing
else do
let invars = Set.fromList $ map fst $
filter (\ (_, Procparam j _) -> j == In) $ zip vs l
np <- minExpProg invars re sig { varMap = Map.fromList $ zipWith
(\ v (Procparam _ s) -> (v, s)) vs l } p
return $ Defproc k i vs np r
-- | analyse and add procedure declarations
anaProcdecls :: Ana Procdecls () Procdecls Dlformula Procs
anaProcdecls _ ds@(Procdecls ps _) = do
mapM_ (anaProcdecl . item) ps
return ds
anaProcdecl :: Sigentry -> State (Sign Dlformula Procs) ()
anaProcdecl (Procedure i p@(Profile ps _) q) = do
updateExtInfo (\ (Procs m) ->
let n = Procs $ Map.insert i p m in case Map.lookup i m of
Just o -> if p == o then
hint n ("repeated procedure " ++ showId i "") q
else warning n ("redeclared procedure " ++ showId i "") q
Nothing -> return n)
case profileToOpType p of
Just t -> do
if all (\ (Procparam j _) -> j == In) ps then return () else
addDiags [mkDiag Warning "function must have IN params only" i]
addOp (emptyAnno ()) t i
e <- get
put e { predMap = Rel.setInsert i (funProfileToPredType p)
$ predMap e }
_ -> addPred (emptyAnno ()) (profileToPredType p) i
paramsToArgs :: [Procparam] -> [SORT]
paramsToArgs = map (\ (Procparam _ s) -> s)
profileToPredType :: Profile -> PredType
profileToPredType (Profile a _) = PredType $ paramsToArgs a
funProfileToPredType :: Profile -> PredType
funProfileToPredType (Profile a r) = case r of
Nothing -> error "funProfileToPredType"
Just s -> PredType $ paramsToArgs a ++ [s]
profileToOpType :: Profile -> Maybe OpType
profileToOpType (Profile a r) = case r of
Nothing -> Nothing
Just s -> Just $ OpType Partial (paramsToArgs a) s
castSign :: Sign f e -> Sign a e
castSign s = s { sentences = [] }
castMor :: Morphism f e b -> Morphism a e b
castMor m = m
{ msource = castSign $ msource m
, mtarget = castSign $ mtarget m }
-- | apply a morphism
mapMorProg :: Morphism f Procs () -> Program -> Program
mapMorProg mor = let m = castMor mor in
foldProg (mapProg (MapSen.mapTerm (const id) m)
$ mapSen (const id) m)
{ foldBlock = \ (Ranged _ r) vs p ->
Ranged (Block (map (mapVars m) vs) p) r
, foldCall = \ (Ranged _ r) f ->
Ranged (Call $ MapSen.mapSen (const id) m f) r }
mapProcId :: Morphism f Procs () -> Id -> Id
mapProcId m i = case lookupProc i $ msource m of
Just p -> mapProcIdProfile m i p
Nothing -> error $ "VSE.mapProcId unknown " ++ show i
mapProcIdProfile :: Morphism f Procs () -> Id -> Profile -> Id
mapProcIdProfile m i p = case profileToOpType p of
Just t -> fst $ mapOpSym (sort_map m) (fun_map m) (i, t)
Nothing -> fst $ mapPredSym (sort_map m) (pred_map m)
(i, profileToPredType p)
mapMorDefproc :: Morphism f Procs () -> Defproc -> Defproc
mapMorDefproc m (Defproc k i vs p r) =
Defproc k (mapProcId m i) vs (mapMorProg m p) r
mapDlformula :: MapSen Dlformula Procs ()
mapDlformula m (Ranged f r) = case f of
Dlformula b p s ->
let n = mapSen mapDlformula m s
in Ranged (Dlformula b (mapMorProg m p) n) r
Defprocs ps -> Ranged (Defprocs $ map (mapMorDefproc m) ps) r
-- | simplify fully qualified terms and formulas for pretty printing sentences
simpProg :: Sign () e -> Program -> Program
simpProg sig =
foldProg (mapProg (simplifyTerm dummyMin (const id) sig)
$ simplifySen dummyMin (const id) sig)
{ foldBlock = \ (Ranged (Block vs p) r) _ _ ->
Ranged (Block vs $ simpProg
(execState (mapM_ addVars vs) sig) p) r }
simpDefproc :: Sign () Procs -> Defproc -> Defproc
simpDefproc sign (Defproc k i vs p r) =
let sig = case lookupProc i sign of
Nothing -> sign
Just (Profile l _) -> if length vs /= length l then sign
else sign { varMap = Map.fromList $ zipWith
(\ v (Procparam _ s) -> (v, s)) vs l }
in Defproc k i vs (simpProg sig p) r
simpDlformula :: Sign Dlformula Procs -> Dlformula -> Dlformula
simpDlformula sign (Ranged f r) = let sig = castSign sign in case f of
Dlformula b p s -> let
q = simpProg sig p
n = simplifySen minExpForm simpDlformula sign s
in Ranged (Dlformula b q n) r
Defprocs ps -> Ranged (Defprocs $ map (simpDefproc sig) ps) r
-- | free variables to be universally bound on the top level
freeProgVars :: Sign () e -> Program -> VarSet
freeProgVars sig = foldProg FoldRec
{ foldAbort = const Set.empty
, foldSkip = const Set.empty
, foldAssign = \ _ v t -> (case Map.lookup v $ varMap sig of
Just s -> Set.insert (v, s)
Nothing -> Set.insert (v, sortOfTerm t)) $ freeTermVars sig t
, foldCall = \ _ f -> freeVars sig f
, foldReturn = \ _ t -> freeTermVars sig t
, foldBlock = \ (Ranged (Block vs p) _) _ _ ->
Set.difference (freeProgVars (execState (mapM_ addVars vs) sig) p)
$ Set.fromList $ flatVAR_DECLs vs
, foldSeq = \ _ p1 p2 -> Set.union p1 p2
, foldIf = \ _ c p1 p2 -> Set.union (freeVars sig c)
$ Set.union p1 p2
, foldWhile = \ _ c p -> Set.union (freeVars sig c) p }
freeDlVars :: Sign Dlformula e -> Dlformula -> VarSet
freeDlVars sig (Ranged f _) = case f of
Dlformula _ p s -> Set.union (freeProgVars (castSign sig) p) $
freeVars sig s
Defprocs _ -> Set.empty
instance GetRange (Ranged a) where
getRange (Ranged _ r) = r
instance FreeVars Dlformula where
freeVarsOfExt = freeDlVars
-- | adjust procs map in morphism target signature
correctTarget :: Morphism f Procs () -> Morphism f Procs ()
correctTarget m = let tar = mtarget m in m
{ mtarget = correctSign tar
{ extendedInfo = Procs $ Map.fromList
$ map (\ (i, p) -> (mapProcIdProfile m i p, mapProfile (sort_map m) p))
$ Map.toList $ procsMap $ extendedInfo tar }
, msource = correctSign $ msource m }
correctSign :: Sign f Procs -> Sign f Procs
correctSign sig = sig
{ extendedInfo = Procs $ Map.filterWithKey (\ i p -> case profileToOpType p of
Just t -> case Map.lookup i $ opMap sig of
Just s -> Set.member t s || Set.member t { opKind = Total } s
Nothing -> False
Nothing -> case Map.lookup i $ predMap sig of
Just s -> Set.member (profileToPredType p) s
Nothing -> False) $ procsMap $ extendedInfo sig }
mapProfile :: Sort_map -> Profile -> Profile
mapProfile m (Profile l r) = Profile
(map (\ (Procparam k s) -> Procparam k $ mapSort m s) l)
$ fmap (mapSort m) r