----------------------------------------------------------------
-- the Henk Parser
-- Copyright 2000, Jan-Willem Roorda and Daan Leijen
----------------------------------------------------------------
module HenkParser where
import Text.ParserCombinators.Parsec
import qualified Text.ParserCombinators.Parsec.Token as P
import Text.ParserCombinators.Parsec.Language
import HenkAS
----------------------------------------------------------------
-- the Henk Parser
--
-- anonymous variables are any identifiers starting with "_"
--
-- unknown types (those that need to be inferred) can explicitly
-- be given using "?"
--
-- instead of grammar: "var : aexpr" as in the henk paper,
-- we use "var : expr" instead. This means that variable
-- sequences as in \, |~|, \/ and /\ expressions need to
-- be comma seperated. Pattern variables are also comma
-- seperated. The case arrow (->) now needs to be (=>) in
-- order to distinguish the end of the pattern from function
-- arrows.
----------------------------------------------------------------
program
= do{ whiteSpace
; ts <- semiSep tdecl
; vs <- semiSep vdecl
; eof
; return $ Program ts vs
}
----------------------------------------------------------------
-- Type declarations
----------------------------------------------------------------
tdecl
= do{ reserved "data"
; t <- bindVar
; symbol "="
; ts <- braces (semiSep1 tvar)
; return $ Data t ts
}
----------------------------------------------------------------
-- Value declarations
----------------------------------------------------------------
vdecl :: Parser ValueDecl
vdecl
= do{ reserved "let"
; b <- bind
; return $ Let b
}
<|>
do{ reserved "letrec"
; bs <- braces (semiSep1 bind)
; return $ LetRec bs
}
bind
= do{ t <- tvar
; symbol "="
; e <- expr
; return $ Bind t e
}
----------------------------------------------------------------
-- Expressions
----------------------------------------------------------------
expr :: Parser Expr
expr
= choice
[ letExpr
, forallExpr -- forall before lambda! \/ vs. \
, lambdaExpr
, piExpr
, caseExpr
, functionExpr
, bigLamdaExpr
]
<?> "expression"
letExpr
= do{ vd <- vdecl
; reserved "in"
; e <- expr
; return (In vd e)
}
lambdaExpr
= do{ symbol "\\"
; ts <- commaSep1 bindVar
; symbol "."
; e <- expr
; return $ (foldr Lam e ts)
}
piExpr
= do{ symbol "|~|"
; ts <- commaSep1 bindVar
; symbol "."
; e <- expr
; return (foldr Pi e ts)
}
----------------------------------------------------------------
-- Case expressions
----------------------------------------------------------------
caseExpr
= do{ reserved "case"
; e <- expr
; reserved "of"
; as <- braces (semiSep1 alt)
; es <- option [] (do{ reserved "at"
; braces (semiSep expr)
})
; return (Case e as es)
}
alt
= do{ pat <- pattern
; symbol "=>"
; e <- expr
; return (pat e)
}
pattern
= do{ p <- atomPattern
; vs <- commaSep boundVar
; return (\e -> Alt p (foldr Lam e vs))
}
atomPattern
= do{ v <- boundVar
; return (PatVar v)
}
<|> do{ l <- literal
; return (PatLit l)
}
<?> "pattern"
----------------------------------------------------------------
-- Syntactic sugar: ->, \/, /\
----------------------------------------------------------------
functionExpr
= chainr1 appExpr arrow
where
arrow = do{ symbol "->"
; return ((\x y ->
Pi (TVar anonymous x) y))
}
<?> ""
bigLamdaExpr
= do{ symbol "/\\"
; ts <- commaSep1 bindVar
; symbol "."
; e <- expr
; return (foldr Lam e ts)
}
forallExpr
= do{ try (symbol "\\/") -- use "try" to try "\" (lambda) too.
; ts <- commaSep1 bindVar
; symbol "."
; e <- expr
; return (foldr Pi e ts)
}
----------------------------------------------------------------
-- Simple expressions
----------------------------------------------------------------
appExpr
= do{ es <- many1 atomExpr
; return (foldl1 App es)
}
atomExpr
= parens expr
<|> do{ v <- boundVar; return (Var v) }
<|> do{ l <- literal; return (Lit l)}
<|> do{ symbol "*"; return Star }
<|> do{ symbol "[]"; return Box }
<|> do{ symbol "?"; return Unknown }
<?> "simple expression"
----------------------------------------------------------------
-- Variables & Literals
----------------------------------------------------------------
variable
= identifier
anonymousVar
= lexeme $
do{ c <- char '_'
; cs <- many (identLetter henkDef)
; return (c:cs)
}
bindVar
= do{ i <- variable <|> anonymousVar
; do{ e <- varType
; return (TVar i e)
}
<|> return (TVar i Star)
}
<?> "variable"
boundVar
= do{ i <- variable
; do{ e <- varType
; return (TVar i e)
}
<|> return (TVar i Unknown)
}
<?> "variable"
tvar
= do{ v <- variable
; t <- varType
; return (TVar v t)
}
<?> "typed variable"
varType
= do{ symbol ":"
; expr
}
<?> "variable type"
literal
= do{ i <- natural
; return (LitInt i)
}
<?> "literal"
----------------------------------------------------------------
-- Tokens
----------------------------------------------------------------
henk = P.makeTokenParser henkDef
lexeme = P.lexeme henk
parens = P.parens henk
braces = P.braces henk
semiSep = P.semiSep henk
semiSep1 = P.semiSep1 henk
commaSep = P.commaSep henk
commaSep1 = P.commaSep1 henk
whiteSpace = P.whiteSpace henk
symbol = P.symbol henk
identifier = P.identifier henk
reserved = P.reserved henk
natural = P.natural henk
henkDef
= haskellStyle
{ identStart = letter
, identLetter = alphaNum <|> oneOf "_'"
, opStart = opLetter henkDef
, opLetter = oneOf ":=\\->/|~.*[]"
, reservedOpNames = ["::","=","\\","->","=>","/\\","\\/"
,"|~|",".",":","*","[]"]
, reservedNames = [ "case", "data", "letrec", "type"
, "import", "in", "let", "of", "at"
]
}
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