ParseTerm.hs revision 98890889ffb2e8f6f722b00e265a211f13b5a861
{- |
Module : $Header$
Description : parser for HasCASL kinds, types, terms, patterns and equations
Copyright : (c) Christian Maeder and Uni Bremen 2002-2005
License : GPLv2 or higher, see LICENSE.txt
Maintainer : Christian.Maeder@dfki.de
Stability : provisional
Portability : portable
parser for HasCASL kinds, types, terms, patterns and equations
-}
module HasCASL.ParseTerm where
import Common.AnnoState
import Common.Id
import Common.Keywords
import Common.Lexer
import Common.Parsec
import Common.Token
import HasCASL.As
import HasCASL.AsUtils
import HasCASL.HToken
import Text.ParserCombinators.Parsec
import Data.List ((\\))
import qualified Data.Set as Set
-- * key sign tokens
-- | a colon not followed by a question mark
colT :: AParser st Token
colT = asKey colonS
-- * parser for bracketed lists
-- | a generic bracket parser
bracketParser :: AParser st a -> AParser st Token -> AParser st Token
-> AParser st Token -> ([a] -> Range -> b) -> AParser st b
bracketParser parser op cl sep k = do
o <- op
(ts, ps) <- option ([], []) $ separatedBy parser sep
c <- cl
return $ k ts $ toRange o ps c
-- | parser for square brackets
mkBrackets :: AParser st a -> ([a] -> Range -> b) -> AParser st b
mkBrackets p = bracketParser p oBracketT cBracketT anComma
-- | parser for braces
mkBraces :: AParser st a -> ([a] -> Range -> b) -> AParser st b
mkBraces p = bracketParser p oBraceT cBraceT anComma
-- * kinds
-- | parse a simple class name or the type universe as kind
parseClassId :: AParser st Kind
parseClassId = fmap ClassKind classId
-- | do 'parseClassId' or a kind in parenthessis
parseSimpleKind :: AParser st Kind
parseSimpleKind = parseClassId <|> (oParenT >> kind << cParenT)
-- | do 'parseSimpleKind' and check for an optional 'Variance'
parseExtKind :: AParser st (Variance, Kind)
parseExtKind = pair variance parseSimpleKind
-- | parse a (right associative) function kind for a given argument kind
arrowKind :: (Variance, Kind) -> AParser st Kind
arrowKind (v, k) = do
a <- asKey funS
k2 <- kind
return $ FunKind v k k2 $ tokPos a
-- | parse a function kind but reject an extended kind
kind :: AParser st Kind
kind = do
k1@(v, k) <- parseExtKind
arrowKind k1 <|> case v of
NonVar -> return k
_ -> unexpected "variance of kind"
-- | parse a function kind but accept an extended kind
extKind :: AParser st (Variance, Kind)
extKind = do
k1 <- parseExtKind
do k <- arrowKind k1
return (NonVar, k)
<|> return k1
-- * type variables
variance :: AParser st Variance
variance = let l = [CoVar, ContraVar] in
choice (map ( \ v -> asKey (show v) >> return v) l) <|> return NonVar
-- a (simple) type variable with a 'Variance'
extVar :: AParser st Id -> AParser st (Id, Variance)
extVar vp = pair vp variance
-- several 'extVar' with a 'Kind'
typeVars :: AParser st [TypeArg]
typeVars = do
(ts, ps) <- extVar typeVar `separatedBy` anComma
typeKind False ts ps
allIsNonVar :: [(Id, Variance)] -> Bool
allIsNonVar = all ( \ (_, v) -> case v of
NonVar -> True
_ -> False)
-- 'parseType' a 'Downset' starting with 'lessT' (True means require kind)
typeKind :: Bool -> [(Id, Variance)] -> [Token]
-> AParser st [TypeArg]
typeKind b vs ps = do
c <- colT
if allIsNonVar vs then do
(v, k) <- extKind
return $ makeTypeArgs vs ps v (VarKind k) $ tokPos c
else do
k <- kind
return $ makeTypeArgs vs ps NonVar (VarKind k) $ tokPos c
<|> do
l <- lessT
t <- parseType
return $ makeTypeArgs vs ps NonVar (Downset t) $ tokPos l
<|> if b then unexpected "missing kind" else
return (makeTypeArgs vs ps NonVar MissingKind nullRange)
-- | add the 'Kind' to all 'extVar' and yield a 'TypeArg'
makeTypeArgs :: [(Id, Variance)] -> [Token]
-> Variance -> VarKind -> Range -> [TypeArg]
makeTypeArgs ts ps vv vk qs =
zipWith (mergeVariance Comma vv vk) (init ts)
(map tokPos ps)
++ [mergeVariance Other vv vk (last ts) qs]
where
mergeVariance c v k (t, NonVar) q = TypeArg t v k rStar 0 c q
mergeVariance c _ k (t, v) q = TypeArg t v k rStar 0 c q
-- | a single 'TypeArg' (parsed by 'typeVars')
singleTypeArg :: AParser st TypeArg
singleTypeArg = do
as <- typeVars
case as of
[a] -> return a
_ -> unexpected "list of type arguments"
-- | a 'singleTypeArg' put in parentheses
parenTypeArg :: AParser st (TypeArg, [Token])
parenTypeArg = do
o <- oParenT
a <- singleTypeArg
p <- cParenT
return (a, [o, p])
-- | a 'singleTypeArg' possibly put in parentheses
typeArg :: AParser st (TypeArg, [Token])
typeArg = do
a <- singleTypeArg
return (a, [])
<|> parenTypeArg
-- | a 'singleTypeArg' put in parentheses as 'TypePattern'
typePatternArg :: AParser st TypePattern
typePatternArg = do
(a, ps) <- parenTypeArg
return $ TypePatternArg a $ catRange ps
-- * parse special identifier tokens
type TokenMode = [String]
-- | parse a 'Token' of an 'Id' (to be declared)
-- but exclude the signs in 'TokenMode'
aToken :: TokenMode -> AParser st Token
aToken b = pToken $ scanQuotedChar <|> scanDigit <|> scanHCWords <|> placeS
<|> reserved b scanHCSigns
-- | just 'aToken' only excluding basic HasCASL keywords
idToken :: AParser st Token
idToken = aToken [] <|> pToken scanDotWords
-- * type patterns
-- 'TypePatternToken's within 'BracketTypePattern's
-- may recusively be 'idToken's.
-- Parenthesis are only legal for a 'typePatternArg'.
primTypePatternOrId :: AParser st TypePattern
primTypePatternOrId = fmap TypePatternToken idToken
<|> mkBraces typePatternOrId (BracketTypePattern Braces)
<|> mkBrackets typePatternOrId (BracketTypePattern Squares)
<|> typePatternArg
-- several 'primTypePatternOrId's possibly yielding a 'MixfixTypePattern'
mixTypePattern :: AParser st TypePattern -> AParser st TypePattern
mixTypePattern p = do
ts <- many1 p
return $ case ts of
[hd] -> hd
_ -> MixfixTypePattern ts
-- several 'primTypePatternOrId's possibly yielding a 'MixfixTypePattern'
typePatternOrId :: AParser st TypePattern
typePatternOrId = mixTypePattern primTypePatternOrId
-- | those (top-level) 'Token's (less than 'idToken')
-- that may appear in 'TypePattern's as 'TypePatternToken'.
typePatternToken :: AParser st TypePattern
typePatternToken = fmap TypePatternToken $ pToken $ scanHCWords <|> placeS
<|> reserved hascasl_reserved_tops scanHCSigns
-- | a 'typePatternToken' or something in braces (a 'typePattern'),
-- in square brackets (a 'typePatternOrId' covering compound lists)
-- or parenthesis ('typePatternArg')
primTypePattern :: AParser st TypePattern
primTypePattern = typePatternToken
<|> mkBrackets typePatternOrId (BracketTypePattern Squares)
<|> mkBraces typePattern (BracketTypePattern Braces)
<|> typePatternArg
-- several 'primTypePatter's possibly yielding a 'MixfixTypePattern'
typePattern :: AParser st TypePattern
typePattern = mixTypePattern primTypePattern
-- * types
-- a parsed type may also be interpreted as a kind (by the mixfix analysis)
-- | type tokens with some symbols removed
typeToken :: AParser st Type
typeToken = fmap TypeToken $ pToken $ scanHCWords <|> placeS <|>
reserved (hascasl_reserved_tops ++ hascasl_type_ops)
scanHCSigns
-- | 'TypeToken's within 'BracketType's may recusively be
-- 'idToken's. Parenthesis may group a mixfix type
-- or may be interpreted as a kind later on in a GEN-VAR-DECL.
primTypeOrId :: AParser st Type
primTypeOrId = fmap TypeToken idToken
<|> mkBrackets typeOrId (BracketType Squares)
<|> mkBraces typeOrId (BracketType Braces)
<|> bracketParser typeOrId oParenT cParenT anComma (BracketType Parens)
mkMixfixType :: AParser st Type -> AParser st Type
mkMixfixType p = do
ts <- many1 p
return $ case ts of
[hd] -> hd
_ -> MixfixType ts
mkKindedMixType :: AParser st Type -> AParser st Type
mkKindedMixType p = do
t <- mkMixfixType p
kindAnno t <|> return t
-- | several 'primTypeOrId's possibly yielding a 'MixfixType'
-- and possibly followed by a 'kindAnno'.
typeOrId :: AParser st Type
typeOrId = mkKindedMixType primTypeOrId
-- | a 'Kind' annotation starting with 'colT'.
kindAnno :: Type -> AParser st Type
kindAnno t = do
c <- colT
k <- kind
return $ KindedType t (Set.singleton k) $ tokPos c
-- | a typeToken' or a 'BracketType'. Square brackets may contain 'typeOrId'.
primType :: AParser st Type
primType = typeToken
<|> mkBrackets typeOrId (BracketType Squares)
<|> mkBraces parseType (BracketType Braces)
<|> bracketParser parseType oParenT cParenT anComma (BracketType Parens)
-- | a 'primType' possibly preceded by 'quMarkT'
lazyType :: AParser st Type
lazyType = fmap mkLazyType (quMarkT >> mkMixfixType primType) <|> primType
-- | several 'lazyType's (as 'MixfixType') possibly followed by 'kindAnno'
mixType :: AParser st Type
mixType = mkKindedMixType lazyType
-- | 'mixType' possibly interspersed with 'crossT'
prodType :: AParser st Type
prodType = do
(ts, ps) <- mixType `separatedBy` crossT
return $ mkProductTypeWithRange ts $ catRange ps
-- | a (right associativ) function type
parseType :: AParser st Type
parseType = do
t1 <- prodType
do a <- arrowT <?> funS
t2 <- parseType
return $ mkTypeAppl
(TypeName a (toRaw $ funKindWithRange $ posOfId a) 0) [t1, t2]
<|> return t1
-- | parse one of the four possible 'Arrow's
arrowT :: AParser st Id
arrowT = let l = [FunArr, PFunArr, ContFunArr, PContFunArr] in
choice $ map ( \ a -> do
t <- asKey $ show a
return $ mkId [placeTok, t, placeTok]) l
-- | parse a 'TypeScheme' using 'forallT', 'typeVars', 'dotT' and 'parseType'
typeScheme :: PolyId -> AParser st TypeScheme
typeScheme (PolyId _ tys ps) = if null tys then do
f <- forallT
(ts, cs) <- typeVars `separatedBy` anSemi
d <- dotT
t <- parseType
return $ TypeScheme (concat ts) t $ toRange f cs d
<|> fmap simpleTypeScheme parseType
else do
t <- parseType
return $ TypeScheme tys t ps
-- * varDecls and genVarDecls
-- | comma separated 'var' with 'varDeclType'
varDecls :: AParser st [VarDecl]
varDecls = do
(vs, ps) <- var `separatedBy` anComma
varDeclType vs ps
-- | a type ('parseType') following a colon
varDeclType :: [Id] -> [Token] -> AParser st [VarDecl]
varDeclType vs ps = do
c <- colonST
t <- parseType
return $ makeVarDecls vs ps t $ tokPos c
-- | attach the 'Type' to every 'Var'
makeVarDecls :: [Id] -> [Token] -> Type -> Range -> [VarDecl]
makeVarDecls vs ps t q = zipWith ( \ v -> VarDecl v t Comma . tokPos)
(init vs) ps ++ [VarDecl (last vs) t Other q]
-- | either like 'varDecls' or declared type variables.
-- A 'GenVarDecl' may later become a 'GenTypeVarDecl'.
genVarDecls:: AParser st [GenVarDecl]
genVarDecls = fmap (map ( \ g -> case g of
GenTypeVarDecl (TypeArg i v MissingKind _ n s ps) ->
GenTypeVarDecl (TypeArg i v (VarKind universe)
rStar n s ps)
_ -> g)) $ do
(vs, ps) <- extVar var `separatedBy` anComma
let other = fmap (map GenTypeVarDecl) (typeKind True vs ps)
if allIsNonVar vs then fmap (map GenVarDecl)
(varDeclType (map fst vs) ps) <|> other
else other
-- * patterns
{- | different legal 'TermToken's possibly excluding 'funS' or
'equalS' for case or let patterns resp. -}
tokenPattern :: TokenMode -> AParser st Term
tokenPattern b = fmap TermToken (aToken b <|> pToken (string "_"))
-- a single underscore serves as wildcard pattern
-- | 'tokenPattern' or 'BracketTerm'
primPattern :: TokenMode -> AParser st Term
primPattern b = tokenPattern b
<|> mkBrackets pattern (BracketTerm Squares)
<|> mkBraces pattern (BracketTerm Braces)
<|> bracketParser (pattern <|> varTerm <|> qualOpName)
oParenT cParenT anComma (BracketTerm Parens)
mkMixfixTerm :: [Term] -> Term
mkMixfixTerm ts = case ts of
[hd] -> hd
_ -> MixfixTerm ts
-- | several 'typedPattern'
mixPattern :: TokenMode -> AParser st Term
mixPattern = fmap mkMixfixTerm . many1 . asPattern
-- | a possibly typed ('parseType') pattern
typedPattern :: TokenMode -> AParser st Term
typedPattern b = do
t <- primPattern b
do c <- colT
ty <- parseType
return $ MixfixTerm [t, MixTypeTerm OfType ty $ tokPos c]
<|> return t
-- | top-level pattern (possibly 'AsPattern')
asPattern :: TokenMode -> AParser st Term
asPattern b = do
v <- typedPattern b
case v of
TermToken tt -> if isPlace tt then return v else do
c <- asKey asP
t <- typedPattern b
return $ AsPattern (VarDecl (mkId [tt]) (MixfixType [])
Other $ tokPos c) t $ tokPos c
<|> return v
_ -> return v
-- | an unrestricted 'asPattern'
pattern :: AParser st Term
pattern = mixPattern []
myChoice :: [(AParser st Token, a)] -> AParser st (a, Token)
myChoice = choice . map ( \ (p, a) -> do
t <- p
return (a, t))
-- | a 'Total' or 'Partial' lambda dot
lamDot :: AParser st (Partiality, Token)
lamDot = myChoice [ (choice $ map (asKey . (++ exMark)) [dotS, cDot], Total)
, (dotT, Partial)]
-- | patterns between 'lamS' and 'lamDot'
lamPattern :: AParser st [Term]
lamPattern =
(lookAhead lamDot >> return []) <|> typedPattern [] <:> lamPattern
-- * terms
{- | 'Token's that may occur in 'Term's including literals
'scanFloat', 'scanString' but excluding 'ifS', 'whenS' and 'elseS'
to allow a quantifier after 'whenS'. In case-terms also 'barS' will
be excluded on the top-level. -}
tToken :: TokenMode -> AParser st Token
tToken b = pToken (scanFloat
<|> scanString
<|> scanQuotedChar <|> scanDotWords
<|> reserved [ifS, whenS, elseS] scanHCWords
<|> reserved b scanHCSigns
<|> placeS <?> "id/literal")
-- | 'tToken' as 'Term' plus 'exEqual' and 'equalS'
termToken :: TokenMode -> AParser st Term
termToken b = fmap TermToken (asKey exEqual <|> asKey equalS <|> tToken b)
-- | 'termToken' plus 'BracketTerm's
primTerm :: TokenMode -> AParser st Term
primTerm b = termToken b
<|> mkBraces term (BracketTerm Braces)
<|> mkBrackets term (BracketTerm Squares)
<|> bracketParser termInParens oParenT cParenT anComma (BracketTerm Parens)
-- | how the keyword 'inS' should be treated
data InMode = NoIn -- ^ next 'inS' belongs to 'letS'
| WithIn -- ^ 'inS' is the element test
-- | all 'Term's that start with a unique keyword
baseTerm :: (InMode, TokenMode) -> AParser st Term
baseTerm b = ifTerm b
<|> whenTerm b
<|> exTerm b
<|> lambdaTerm b
<|> caseTerm b
<|> letTerm b
-- | 'whenS' possibly followed by an 'elseS'
whenTerm :: (InMode, TokenMode) -> AParser st Term
whenTerm b = do
i <- asKey whenS
c <- mixTerm b
let l1 = [TermToken i, c]
do t <- asKey elseS
e <- mixTerm b
return $ MixfixTerm $ l1 ++ [TermToken t, e]
<|> return (MixfixTerm l1)
-- | 'ifS' possibly followed by 'thenS' and 'elseS'
-- yielding a 'MixfixTerm'
ifTerm :: (InMode, TokenMode) -> AParser st Term
ifTerm b = do
i <- asKey ifS
c <- mixTerm b
let l1 = [TermToken i, c]
do t <- asKey thenS
e <- mixTerm b
let l2 = l1 ++ [TermToken t, e]
do s <- asKey elseS
f <- mixTerm b
return $ MixfixTerm $ l2 ++ [TermToken s, f]
<|> return (MixfixTerm l2)
<|> return (MixfixTerm l1)
-- | unrestricted terms including qualified names
termInParens :: AParser st Term
termInParens = term <|> varTerm <|> qualOpName <|> qualPredName
-- | a qualified 'var'
varTerm :: AParser st Term
varTerm = do
v <- asKey varS
i <- var
c <- colonST
t <- parseType
return $ QualVar $ VarDecl i t Other $ toRange v [] c
-- | 'opS' or 'functS'
opBrand :: AParser st (Token, OpBrand)
opBrand = pair (asKey opS) (return Op)
<|> pair (asKey functS) (return Fun)
parsePolyId :: AParser st PolyId
parsePolyId = do
l <- try ite <|> start hcKeys
if isPlace (last l)
then return $ PolyId (Id l [] nullRange) [] nullRange else do
(cs, ps) <- option ([], nullRange) (try $ comps hcKeys)
(tys, qs) <- option ([], nullRange) $
bracketParser typeVars oBracketT cBracketT semiT (,)
u <- many placeT
return $ PolyId (Id (l ++ u) cs ps) (concat tys) qs
-- | a qualified operation (with 'opBrand')
qualOpName :: AParser st Term
qualOpName = do
(v, b) <- opBrand
i <- parsePolyId
c <- colonST
t <- typeScheme i
return $ QualOp b i t [] Infer $ toRange v [] c
-- | a qualified predicate
qualPredName :: AParser st Term
qualPredName = do
v <- asKey predS
i <- parsePolyId
c <- colT
t <- typeScheme i
let p = toRange v [] c
return $ QualOp Pred i (predTypeScheme p t) [] Infer p
-- | a qualifier expecting a further 'Type'.
-- 'inS' is rejected for 'NoIn'
typeQual :: InMode -> AParser st (TypeQual, Token)
typeQual m = myChoice $ (colT, OfType) : (asT, AsType) : case m of
NoIn -> []
WithIn -> [(asKey inS, InType)]
-- | a qualifier plus a subsequent type as mixfix term component
qualAndType :: InMode -> AParser st Term
qualAndType i = do
(q, p) <- typeQual i
ty <- parseType
return $ MixTypeTerm q ty $ tokPos p
-- | a possibly type qualified ('typeQual') 'primTerm' or a 'baseTerm'
typedTerm :: (InMode, TokenMode) -> AParser st Term
typedTerm (i, b) = do
t <- primTerm b
tys <- many $ qualAndType i
return $ if null tys then t else MixfixTerm $ t : tys
<|> baseTerm (i, b)
-- | several 'typedTerm's yielding a 'MixfixTerm'
mixTerm :: (InMode, TokenMode) -> AParser st Term
mixTerm = fmap mkMixfixTerm . many1 . typedTerm
-- | keywords that start a new item
hasCaslStartKeywords :: [String]
hasCaslStartKeywords =
dotS : cDot : (hascasl_reserved_words \\ [existsS, letS, caseS])
-- | a 'mixTerm' followed by 'whereS' and equations separated by 'optSemi'
whereTerm :: (InMode, TokenMode) -> AParser st Term
whereTerm b = do
t <- mixTerm b
do p <- asKey whereS
(es, ps, _ans) <- itemAux hasCaslStartKeywords $
patternTermPair [equalS] b equalS
-- ignore collected annotations
return $ LetTerm Where es t $ catRange $ p : ps
<|> return t
-- | a 'whereTerm' called with ('WithIn', [])
term :: AParser st Term
term = whereTerm (WithIn, [])
-- | a 'Universal', 'Unique' or 'Existential' 'QuantifiedTerm'
exQuant :: AParser st (Token, Quantifier)
exQuant = choice $ map (\ (v, s) -> pair (asKey s) $ return v)
[ (Universal, forallS)
, (Unique, existsS ++ exMark)
, (Existential, existsS) ]
-- | a (possibly unique) existential 'QuantifiedTerm'
exTerm :: (InMode, TokenMode) -> AParser st Term
exTerm b = do
(p, q) <- exQuant
(vs, ps) <- varDecls `separatedBy` anSemi
d <- dotT
f <- mixTerm b
return $ QuantifiedTerm q (map GenVarDecl $ concat vs) f $ toRange p ps d
lamDecls :: AParser st [Term]
lamDecls = try ((do
(vs, _) <- separatedBy varDecls anSemi
lookAhead lamDot
return $ case concat vs of
[(VarDecl (Id [t] [] _) ty _ ps)] ->
-- this may be a constant constructor
[MixfixTerm [TermToken t, MixTypeTerm OfType ty ps]]
vss -> map QualVar vss) <?> "VAR-DECL") <|> lamPattern
-- | a 'LambdaTerm'
lambdaTerm :: (InMode, TokenMode) -> AParser st Term
lambdaTerm b = do
l <- asKey lamS
pl <- lamDecls
(k, d) <- lamDot
t <- mixTerm b
return $ LambdaTerm (if null pl then [BracketTerm Parens [] nullRange]
else pl) k t $ toRange l [] d
-- | a 'CaseTerm' with 'funS' excluded in 'patternTermPair'
caseTerm :: (InMode, TokenMode) -> AParser st Term
caseTerm (i, _) = do
c <- asKey caseS
t <- term
o <- asKey ofS
(ts, ps) <- patternTermPair [funS] (i, [barS]) funS `separatedBy` barT
return $ CaseTerm t ts $ catRange $ c : o : ps
-- | a 'LetTerm' with 'equalS' excluded in 'patternTermPair'
-- (called with 'NoIn')
letTerm :: (InMode, TokenMode) -> AParser st Term
letTerm b = do
l <- asKey letS
(es, ps) <- patternTermPair [equalS] (NoIn, []) equalS `separatedBy` anSemi
i <- asKey inS
t <- mixTerm b
return $ LetTerm Let es t $ toRange l ps i
-- | a customizable pattern equation
patternTermPair :: TokenMode -> (InMode, TokenMode) -> String
-> AParser st ProgEq
patternTermPair b1 b2 sep = do
p <- mixPattern b1
s <- asKey sep
t <- mixTerm b2
return $ ProgEq p t $ tokPos s