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module Parser(parseProgram) where
import Control.Monad
import Data.Char
import Data.Functor.Identity
import Data.Maybe
import qualified Data.Map.Strict as Map
import Text.Parsec
import qualified Text.Parsec.Expr as E
import AST
type Parser = Parsec String ()
(<<) :: (Monad m) => m a -> m b -> m a
(<<) = (<*)
parseProgram :: String -> String -> Either ParseError Program
parseProgram source fname = parse pProgram fname source
-- parse' :: Parser a -> String -> Either ParseError a
-- parse' p s = parse p "" s
pProgram :: Parser Program
pProgram = pWhiteComment >> (Program <$> many1 pDeclaration)
pDeclaration :: Parser Declaration
pDeclaration = pDecTypedef <|> pDecExtern <|> do
t <- pTypeVoid <|> pType
n <- pName
if t == TypeVoid
then pDecFunction' t n
else pDecFunction' t n <|> pDecVariable' t n
pDecTypedef :: Parser Declaration
pDecTypedef = do
symbol "type"
n <- pName
symbol "="
t <- pType
symbol ";"
return $ DecTypedef t n
pDecExtern :: Parser Declaration
pDecExtern = do
symbol "extern"
t <- pType
n <- pName
symbol ";"
return $ DecExtern t n
pDecFunction' :: Type -> Name -> Parser Declaration
pDecFunction' t n = do
symbol "("
a <- sepBy ((,) <$> pType <*> pName) (symbol ",")
symbol ")"
b <- pBlock
return $ DecFunction t n a b
pDecVariable' :: Type -> Name -> Parser Declaration
pDecVariable' t n = do
e <- (Just <$> (symbol "=" >> pExpression)) <|> return Nothing
symbol ";"
return $ DecVariable t n e
pBlock :: Parser Block
pBlock = do
symbol "{"
s <- many pStatement
symbol "}"
return $ Block s
exprTable :: (E.OperatorTable String () Identity) Expression
exprTable =
[[prefix "-" Negate,
prefix "!" Not,
prefix "~" Invert,
prefix "*" Dereference,
prefix "&" Address],
[binary "*" Times E.AssocLeft,
binary "/" Divide E.AssocLeft,
binary "%" Modulo E.AssocLeft],
[binary "+" Plus E.AssocLeft,
binary "-" Minus E.AssocLeft],
[binary ">=" GEqual E.AssocNone,
binary "<=" LEqual E.AssocNone,
binary ">" Greater E.AssocNone,
binary "<" Less E.AssocNone],
[binary "==" Equal E.AssocNone,
binary "!=" Unequal E.AssocNone],
[binary "&&" BoolAnd E.AssocLeft,
binary "||" BoolOr E.AssocLeft]]
where
binary name op assoc = E.Infix (exBinOp_ op <$ symbol name) assoc
prefix name op = E.Prefix (exUnOp_ op <$ symbol name)
pExpression :: Parser Expression
pExpression = E.buildExpressionParser exprTable (pExCast <|> pExLit)
pExCast :: Parser Expression
pExCast = do
symbol "cast"
symbol "("
t <- pType
symbol ")"
e <- pParenExpr
return $ ExCast t e
pExLit :: Parser Expression
pExLit = (exLit_ <$> pLiteral) <|> pParenExpr
pParenExpr :: Parser Expression
pParenExpr = do
symbol "("
e <- pExpression
symbol ")"
return e
pLiteral :: Parser Literal
pLiteral = (LitFloat <$> pFloat) <|> pLitInt <|> (LitInt <$> pCharStr)
<|> (LitString <$> pString) <|> try pLitCall <|> (LitVar <$> pName)
pLitInt :: Parser Literal
pLitInt = do
i <- pInteger
liftM (maybe (LitInt i) (const $ LitUInt i)) $ optionMaybe (symbol "U")
pLitCall :: Parser Literal
pLitCall = do
n <- pName
symbol "("
a <- sepBy pExpression (symbol ",")
symbol ")"
return $ LitCall n a
pStatement :: Parser Statement
pStatement = pStEmpty <|> pStIf <|> pStWhile <|> pStReturn <|> pStBlock
<|> try pStAssignment <|> try pStVarDeclaration <|> pStExpr
pStEmpty :: Parser Statement
pStEmpty = symbol ";" >> return StEmpty
pStBlock :: Parser Statement
pStBlock = StBlock <$> pBlock
pStVarDeclaration :: Parser Statement
pStVarDeclaration = do
t <- pType
n <- pName
e <- optionMaybe (symbol "=" >> pExpression)
symbol ";"
return $ StVarDeclaration t n e
pStExpr :: Parser Statement
pStExpr = (StExpr <$> pExpression) << symbol ";"
pStAssignment :: Parser Statement
pStAssignment = do
n <- pName
symbol "="
e <- pExpression
symbol ";"
return $ StAssignment n e
pStIf :: Parser Statement
pStIf = do
symbol "if"
symbol "("
c <- pExpression
symbol ")"
t <- pStatement
e <- (symbol "else" >> pStatement) <|> return StEmpty
return $ StIf c t e
pStWhile :: Parser Statement
pStWhile = do
symbol "while"
symbol "("
c <- pExpression
symbol ")"
b <- pStatement
return $ StWhile c b
pStReturn :: Parser Statement
pStReturn = do
symbol "return"
(symbol ";" >> return (StReturn Nothing)) <|> do
e <- pExpression
symbol ";"
return $ StReturn (Just e)
primitiveTypes :: Map.Map String Type
primitiveTypes = Map.fromList
[("i8", TypeInt 8), ("i16", TypeInt 16), ("i32", TypeInt 32), ("i64", TypeInt 64),
("u1", TypeUInt 1), ("u8", TypeUInt 8), ("u16", TypeUInt 16), ("u32", TypeUInt 32), ("u64", TypeUInt 64),
("float", TypeFloat), ("double", TypeDouble)]
findPrimType :: String -> Type
findPrimType s = fromJust $ Map.lookup s primitiveTypes
pType :: Parser Type
pType = pPrimType <|> pTypePtr <|> pTypeFunc <|> pTypeName
pPrimType :: Parser Type
pPrimType = findPrimType <$> choice (map typeParser $ Map.keys primitiveTypes)
where typeParser t = try $ do
void $ string t
void $ lookAhead $ satisfy (\c -> not (isAlphaNum c) && c /= '_')
pWhiteComment
return t
pTypeVoid :: Parser Type
pTypeVoid = symbol "void" >> return TypeVoid
pTypePtr :: Parser Type
pTypePtr = do
symbol "ptr"
symbol "("
t <- pType
symbol ")"
return $ TypePtr t
pTypeFunc :: Parser Type
pTypeFunc = do
symbol "func"
r <- pTypeVoid <|> pType
symbol "("
a <- sepBy pType (symbol ",")
symbol ")"
return $ TypeFunc r a
pTypeName :: Parser Type
pTypeName = TypeName <$> pName
pName :: Parser Name
pName = ((:) <$> pFirstChar <*> many pOtherChar) << pWhiteComment
where pFirstChar = satisfy (isAlpha .||. (=='_'))
pOtherChar = satisfy (isAlpha .||. isDigit .||. (=='_'))
pInteger :: Parser Integer
pInteger = (read <$> many1 digit) << pWhiteComment
pFloat :: Parser Double
pFloat = try $ do
pre <- many1 digit
post <- choice [pExponent,
(do
void $ char '.'
s <- many1 digit
ex <- option "" pExponent
return $ '.' : s ++ ex)]
pWhiteComment
return $ read $ pre ++ post
where
pExponent = do
c <- choice [char 'e', char 'E']
pm <- option "" $ choice [string "+", string "-"]
val <- many1 digit
return $ c : pm ++ val
pString :: Parser String
pString = do
void $ char '"'
s <- many (pEscape <|> satisfy (/='"'))
symbol "\""
return s
pCharStr :: Parser Integer
pCharStr = do
void $ char '\''
c <- pEscape <|> satisfy (/='\'')
symbol "'"
return $ fromIntegral (ord c)
pEscape :: Parser Char
pEscape = char '\\' >> (pEscapeQuote <|> pEscapeN <|> pEscapeR <|> pEscapeT <|> pEscapeHex)
where
pEscapeQuote, pEscapeN, pEscapeR, pEscapeT :: Parser Char
pEscapeQuote = ('"' <$ char '"') <|> ('\'' <$ char '\'')
pEscapeN = '\n' <$ char 'n'
pEscapeR = '\r' <$ char 'r'
pEscapeT = '\t' <$ char 't'
pEscapeHex :: Parser Char
pEscapeHex = do
void $ char 'x'
c1 <- pHexChar
c2 <- pHexChar
return $ chr $ 16 * c1 + c2
where
pHexChar :: Parser Int
pHexChar = (liftM (\c -> ord c - ord '0') digit)
<|> (liftM (\c -> ord c - ord 'a' + 10) (oneOf "abcdef"))
<|> (liftM (\c -> ord c - ord 'A' + 10) (oneOf "ABCDEF"))
symbol :: String -> Parser ()
symbol s = do
void $ try (string s)
when (isAlphaNum (last s)) $ notFollowedBy alphaNum
pWhiteComment
pWhiteComment :: Parser ()
pWhiteComment = sepBy pWhitespace pComment >> return ()
pWhitespace :: Parser ()
pWhitespace = many (oneOf " \t\n") >> return ()
pComment :: Parser ()
pComment = pLineComment <|> pBlockComment
pLineComment :: Parser ()
pLineComment = try (string "//") >> manyTill anyChar (char '\n') >> return ()
pBlockComment :: Parser ()
pBlockComment = try (string "/*") >> manyTill anyChar (try (string "*/")) >> return ()
infixr 2 .||.
(.||.) :: (a -> Bool) -> (a -> Bool) -> a -> Bool
f .||. g = \x -> f x || g x
|
