{- |

Module : $Header$

Copyright : (c) Christian Maeder and Uni Bremen 2003-2005

License : similar to LGPL, see HetCATS/LICENSE.txt or LIZENZ.txt

Maintainer : maeder@tzi.de

Stability : experimental

Portability : portable

Mixfix analysis of terms and patterns, type annotations are also analysed

-}

module HasCASL.MixAna where

import Common.GlobalAnnotations

import Common.Result

import Common.Id

import Common.Earley

import Common.Prec

import Common.ConvertLiteral

import Common.Lib.State

import qualified Common.Lib.Rel as Rel

import qualified Common.Lib.Set as Set

import HasCASL.As

import HasCASL.AsUtils

import HasCASL.PrintAs

import HasCASL.Unify

import HasCASL.VarDecl

import HasCASL.Le

import Data.Maybe

import Control.Exception(assert)

addType :: Term -> Term -> Term

addType (MixTypeTerm q ty ps) t = TypedTerm t q ty ps

addType _ _ = error "addType"

iterateCharts :: GlobalAnnos -> [Term] -> Chart Term

-> State Env (Chart Term)

iterateCharts ga terms chart =

do e <- get

let self = iterateCharts ga

oneStep = nextChart addType toMixTerm ga chart

vs = localVars e

tm = typeMap e

case terms of

[] -> return chart

t:tt -> do

let recurse trm = self tt $

oneStep (trm, exprTok {tokPos = getRange trm})

case t of

MixfixTerm ts -> self (ts ++ tt) chart

MixTypeTerm q typ ps -> do

mTyp <- anaStarType typ

case mTyp of

Nothing -> recurse t

Just nTyp -> self tt $ oneStep

(MixTypeTerm q (monoType nTyp) ps,

typeTok {tokPos = ps})

BracketTerm b ts ps -> self

(expandPos TermToken (getBrackets b) ts ps ++ tt) chart

QualVar (VarDecl v typ ok ps) -> do

mTyp <- anaStarType typ

case mTyp of

Nothing -> recurse t

Just nType -> recurse $ QualVar $

VarDecl v (monoType nType) ok ps

QualOp b (InstOpId v ts qs) sc ps -> do

mSc <- anaTypeScheme sc

newTs <- anaInstTypes ts

case mSc of

Nothing -> recurse t

Just nSc -> do

case findOpId e v nSc of

Nothing -> addDiags [mkDiag Error

"operation not found" v]

_ -> return ()

recurse $ QualOp b (InstOpId v newTs qs) nSc ps

QuantifiedTerm quant decls hd ps -> do

newDs <- mapM (anaddGenVarDecl False) decls

mt <- resolve ga hd

putLocalVars vs

putTypeMap tm

let newT = case mt of Just trm -> trm

_ -> hd

recurse $ QuantifiedTerm quant (catMaybes newDs) newT ps

LambdaTerm decls part hd ps -> do

mDecls <- mapM (resolvePattern ga) decls

let anaDecls = catMaybes mDecls

bs = concatMap extractVars anaDecls

checkUniqueVars bs

mapM_ (addLocalVar False) bs

mt <- resolve ga hd

putLocalVars vs

recurse $ LambdaTerm anaDecls part (maybe hd id mt) ps

CaseTerm hd eqs ps -> do

mt <- resolve ga hd

newEs <- resolveCaseEqs ga eqs

recurse $ CaseTerm (maybe hd id mt) newEs ps

LetTerm b eqs hd ps -> do

newEs <- resolveLetEqs ga eqs

mt <- resolve ga hd

putLocalVars vs

recurse $ LetTerm b newEs (maybe hd id mt) ps

TermToken tok -> do

let (ds1, trm) = convertMixfixToken

(literal_annos ga)

ResolvedMixTerm TermToken tok

addDiags ds1

self tt $ oneStep $

case trm of

TermToken _ -> (trm, tok)

_ -> (trm, exprTok

{tokPos = tokPos tok})

AsPattern vd p ps -> do

mp <- resolvePattern ga p

let newP = case mp of Just pat -> pat

Nothing -> p

recurse $ AsPattern vd newP ps

TypedTerm trm k ty ps -> do

-- assume that type is analysed

mt <- resolve ga trm

recurse $ TypedTerm (maybe trm id mt) k ty ps

_ -> error ("iterCharts: " ++ show t)

-- * equation stuff

resolveCaseEq :: GlobalAnnos -> ProgEq -> State Env (Maybe ProgEq)

resolveCaseEq ga (ProgEq p t ps) =

do mp <- resolvePattern ga p

case mp of

Nothing -> return Nothing

Just newP -> do

let bs = extractVars newP

checkUniqueVars bs

vs <- gets localVars

mapM_ (addLocalVar False) bs

mtt <- resolve ga t

putLocalVars vs

return $ case mtt of

Nothing -> Nothing

Just newT -> Just $ ProgEq newP newT ps

resolveCaseEqs :: GlobalAnnos -> [ProgEq] -> State Env [ProgEq]

resolveCaseEqs _ [] = return []

resolveCaseEqs ga (eq : rt) =

do mEq <- resolveCaseEq ga eq

eqs <- resolveCaseEqs ga rt

return $ case mEq of

Nothing -> eqs

Just newEq -> newEq : eqs

resolveLetEqs :: GlobalAnnos -> [ProgEq] -> State Env [ProgEq]

resolveLetEqs _ [] = return []

resolveLetEqs ga (ProgEq pat trm ps : rt) =

do mPat <- resolvePattern ga pat

case mPat of

Nothing -> do resolve ga trm

resolveLetEqs ga rt

Just newPat -> do

let bs = extractVars newPat

checkUniqueVars bs

mapM_ (addLocalVar False) bs

mTrm <- resolve ga trm

case mTrm of

Nothing -> resolveLetEqs ga rt

Just newTrm -> do

eqs <- resolveLetEqs ga rt

return (ProgEq newPat newTrm ps : eqs)

mkPatAppl :: Term -> Term -> Range -> Term

mkPatAppl op arg qs =

case op of

QualVar (VarDecl i (MixfixType []) _ _) ->

ResolvedMixTerm i [arg] qs

_ -> ApplTerm op arg qs

toMixTerm :: Id -> [Term] -> Range -> Term

toMixTerm i ar qs =

if i == applId then assert (length ar == 2) $

let [op, arg] = ar in mkPatAppl op arg qs

else if i == tupleId || i == unitId then

mkTupleTerm ar qs

else ResolvedMixTerm i ar qs

getKnowns :: Id -> Set.Set Token

getKnowns (Id ts cs _) = Set.union (Set.fromList ts) $

Set.unions (map getKnowns cs)

resolvePattern :: GlobalAnnos -> Pattern -> State Env (Maybe Pattern)

resolvePattern = resolver True

resolve :: GlobalAnnos -> Term -> State Env (Maybe Term)

resolve = resolver False

resolver :: Bool -> GlobalAnnos -> Term -> State Env (Maybe Term)

resolver isPat ga trm =

do ass <- gets assumps

vs <- gets localVars

ps <- gets preIds

let (addRule, ruleS, sIds) = makeRules ga ps

$ Set.union (Rel.keysSet ass) $ Rel.keysSet vs

chart <- iterateCharts ga [trm] $ initChart addRule ruleS

let Result ds mr = getResolved

(shows . printTerm emptyGlobalAnnos . parenTerm) (getRange trm)

toMixTerm chart

addDiags ds

if isPat then case mr of

Nothing -> return mr

Just pat -> fmap Just $ anaPattern sIds pat

else return mr

uTok :: Token

uTok = mkSimpleId "_"

builtinIds :: [Id]

builtinIds = [unitId, parenId, tupleId, exprId, typeId, applId]

makeRules :: GlobalAnnos -> (PrecMap, Set.Set Id) -> Set.Set Id

-> (Token -> [Rule], Rules, Set.Set Id)

makeRules ga ps@(p, _) aIds =

let (sIds, ids) = Set.partition isSimpleId aIds

ks = Set.fold (Set.union . getKnowns) Set.empty ids

rIds = Set.union ids $ Set.intersection sIds $ Set.map simpleIdToId ks

m2 = maxWeight p + 2

in ( \ tok -> if isSimpleToken tok

&& not (Set.member tok ks)

|| tok == uTok then

[(simpleIdToId tok, m2, [tok])] else []

, partitionRules $ listRules m2 ga ++

initRules ps builtinIds (Set.toList rIds)

, sIds)

initRules :: (PrecMap, Set.Set Id) -> [Id] -> [Id] -> [Rule]

initRules (p, ps) bs is =

map ( \ i -> mixRule (getIdPrec p ps i) i)

(bs ++ is) ++

map ( \ i -> (protect i, maxWeight p + 3, getPlainTokenList i))

(filter isMixfix is)

-- create fresh type vars for unknown ids tagged with type MixfixType [].

anaPattern :: Set.Set Id -> Pattern -> State Env Pattern

anaPattern s pat =

case pat of

QualVar vd -> do newVd <- checkVarDecl vd

return $ QualVar newVd

ResolvedMixTerm i pats ps | null pats &&

(isSimpleId i || i == simpleIdToId uTok) &&

not (Set.member i s) -> do

(tvar, c) <- toEnvState $ freshVar $ posOfId i

return $ QualVar $ VarDecl i (TypeName tvar rStar c) Other ps

| otherwise -> do

l <- mapM (anaPattern s) pats

return $ ResolvedMixTerm i l ps

ApplTerm p1 p2 ps -> do

p3 <- anaPattern s p1

p4 <- anaPattern s p2

return $ ApplTerm p3 p4 ps

TupleTerm pats ps -> do

l <- mapM (anaPattern s) pats

return $ TupleTerm l ps

TypedTerm p q ty ps -> do

case p of

QualVar (VarDecl v (MixfixType []) ok qs) ->

let newVd = VarDecl v ty ok (qs `appRange` ps) in

return $ QualVar newVd

_ -> do newP <- anaPattern s p

return $ TypedTerm newP q ty ps

AsPattern vd p2 ps -> do

newVd <- checkVarDecl vd

p4 <- anaPattern s p2

return $ AsPattern newVd p4 ps

_ -> return pat

where checkVarDecl vd@(VarDecl v t ok ps) = case t of

MixfixType [] -> do

(tvar, c) <- toEnvState $ freshVar $ posOfId v

return $ VarDecl v (TypeName tvar rStar c) ok ps

_ -> return vd

-- | put parenthesis around applications

parenTerm :: Term -> Term

parenTerm trm = case trm of

ResolvedMixTerm n ts ps ->

ResolvedMixTerm n (map parenTerm ts) ps

ApplTerm t1 t2' ps -> let t2 = parenTerm t2' in

ApplTerm (addParAppl t1) (case t2 of

ResolvedMixTerm _ [] _ -> t2

QualVar _ -> t2

QualOp _ _ _ _ -> t2

TermToken _ -> t1

BracketTerm _ _ _ -> t2

TupleTerm _ _ -> t2

_ -> addPar t2) ps

TupleTerm ts ps -> TupleTerm (map parenTerm ts) ps

TypedTerm t q typ ps ->

TypedTerm (addParAppl t) q typ ps

QuantifiedTerm q vs t ps -> QuantifiedTerm q vs (parenTerm t) ps

LambdaTerm ps q t qs ->

LambdaTerm (map parenTerm ps) q (parenTerm t) qs

CaseTerm t es ps -> CaseTerm (parenTerm t) (map parenProgEq es) ps

LetTerm br es t ps ->

LetTerm br (map parenProgEq es) (parenTerm t) ps

MixfixTerm ts -> MixfixTerm $ map addParAppl ts

BracketTerm k ts ps -> BracketTerm k (map parenTerm ts) ps

AsPattern v p ps -> AsPattern v (addParAppl p) ps

TermToken _ -> trm

MixTypeTerm _ _ _ -> trm

QualVar _ -> trm

QualOp _ _ _ _ -> trm

where addPar t = TupleTerm [t] nullRange

addParAppl t' = let t = parenTerm t' in case t of

ApplTerm _ _ _ -> t

ResolvedMixTerm _ _ _ -> t

QualVar _ -> t

QualOp _ _ _ _ -> t

TermToken _ -> t

BracketTerm _ _ _ -> t

TupleTerm _ _ -> t

_ -> addPar t

-- | put parenthesis around applications in equations

parenProgEq :: ProgEq -> ProgEq

parenProgEq (ProgEq p t q) = ProgEq (parenTerm p) (parenTerm t) q