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module GSA.Parser where
import Data.Char
import Data.IntMap.Strict (IntMap)
import qualified Data.IntMap.Strict as IMap
import Data.Map.Strict (Map)
import qualified Data.Map.Strict as Map
import Data.Text (Text)
import qualified Data.Text as T
import Data.Void (Void)
import GSA.Types
import Text.Megaparsec
import Text.Megaparsec.Char
import qualified Text.Megaparsec.Char.Lexer as L
type Parser = Parsec Void Text
sc :: Parser ()
sc =
L.space
space1
(L.skipLineComment "//")
(L.skipBlockComment "/*" "*/")
lexeme :: Parser a -> Parser a
lexeme = L.lexeme sc
symbol :: Text -> Parser Text
symbol = L.symbol sc
parens :: Parser a -> Parser a
parens = between (symbol "(") (symbol ")")
braces :: Parser a -> Parser a
braces = between (symbol "{") (symbol "}")
brackets :: Parser a -> Parser a
brackets = between (symbol "[") (symbol "]")
integer :: Parser Integer
integer = lexeme L.decimal
float :: Parser Double
float = lexeme L.float
signedInteger :: Parser Integer
signedInteger = L.signed sc integer
signedFloat :: Parser Double
signedFloat = L.signed sc float
charLiteral :: Parser Char
charLiteral = between (char '\'') (char '\'') L.charLiteral
stringLiteral :: Parser String
stringLiteral = char '\"' *> manyTill L.charLiteral (char '\"')
typParser :: Parser Typ
typParser = undefined
retTypParser :: Parser RetTyp
retTypParser = undefined
chunkParser :: Parser Chunk
chunkParser = undefined
signatureParser :: Parser Signature
signatureParser = undefined
nodeParser :: Parser Node
nodeParser = undefined
regParser :: Parser Reg
regParser = do
char 'x'
Reg . fromInteger <$> integer
identParser :: Parser Ident
identParser = undefined
ptrofsParser :: Parser Ptrofs
ptrofsParser = undefined
comparisonParser :: Parser Comparison
comparisonParser =
choice
[ string "==" >> return Ceq,
string "!=" >> return Cne,
string "<" >> return Clt,
string "<=" >> return Cle,
string ">" >> return Cgt,
string ">=" >> return Cge
]
compParser :: (Comparison -> Condition) -> Text -> Parser (Condition, [Reg])
compParser f t = do
r1 <- regParser
comp <- comparisonParser >> symbol t
r2 <- regParser
return $ (f comp, [r1, r2])
conditionParser :: Parser (Condition, [Reg])
conditionParser =
choice [ compParser Ccomp "s",
compParser Ccompu "u",
compParser Ccompl "ls",
compParser Ccomplu "lu"
]
addressingParser :: Parser Addressing
addressingParser = undefined
omoveParser :: Parser (Operation, [Reg])
omoveParser = do
r <- regParser
return (Omove, [r])
ointconstParser :: Parser (Operation, [Reg])
ointconstParser = do
i <- fromInteger <$> integer
return (Ointconst i, [])
onegParser :: Parser (Operation, [Reg])
onegParser = do
r <- parens (symbol "-" >> regParser)
return (Oneg, [r])
obinopParser :: Operation -> Text -> Parser (Operation, [Reg])
obinopParser op t = do
r1 <- regParser
r2 <- symbol t >> regParser
return (op, [r1, r2])
obinopimmParser :: (Int -> Operation) -> Text -> Parser (Operation, [Reg])
obinopimmParser op t = do
r1 <- regParser
i <- symbol t >> fromInteger <$> integer
return (op i, [r1])
operationParser :: Parser (Operation, [Reg])
operationParser =
choice
[ omoveParser,
ointconstParser,
onegParser,
obinopParser Osub "-",
obinopParser Omul "*",
obinopimmParser Omulimm "*",
obinopParser Odiv "/s",
obinopParser Odivu "/u",
obinopParser Omod "%s",
obinopParser Omodu "%u",
obinopParser Oand "&",
obinopimmParser Oandimm "&",
obinopParser Oor "|",
obinopimmParser Oorimm "|"
]
predicateParser :: Parser Predicate
predicateParser = undefined
mergeinstructionParser :: Parser Instruction
mergeinstructionParser = undefined
inopParser :: Int -> Parser Instruction
inopParser i = symbol "nop" >> return (Inop . Node $ i -1)
gotoParser' :: Parser Node
gotoParser' = symbol "goto" >> integer >>= (return . Node . fromInteger)
gotoParser :: Parser Instruction
gotoParser = Inop <$> gotoParser'
icondParser :: Parser Instruction
icondParser = do
(cond, args) <- symbol "if" >> parens conditionParser
n1 <- gotoParser'
n2 <- symbol "else" >> gotoParser'
return $ Icond cond args n1 n2
iopParser :: Int -> Parser Instruction
iopParser i = do
r <- regParser
symbol "="
(op, args) <- operationParser
goto <- optional gotoParser'
case goto of
Just goto' -> return $ Iop op args r goto'
Nothing -> return $ Iop op args r (Node $ i -1)
instructionParser :: Parser (Int, Instruction)
instructionParser = do
i <- fromInteger <$> integer
symbol ":"
instr <- choice [gotoParser, inopParser i, icondParser, iopParser i]
return (i, instr)
codeParser :: Parser Code
codeParser =
Code . IMap.fromList <$> many instructionParser
functionParser :: Parser (Text, Function)
functionParser = do
name <- lexeme (takeWhile1P (Just "Function name") isAlphaNum)
args <- parens $ regParser `sepBy` symbol ","
code <- braces codeParser
return (name, Function signatureMain args 0 code (Node 0) [])
gsaParser :: Parser Program
gsaParser = Program . Map.fromList <$> many functionParser
parse :: String -> Text -> Either String Program
parse file t =
case runParser gsaParser file t of
Left a -> Left (show a)
Right a -> Right a
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