I'm programming a standard math notation -> DC POSIX-compliant format converter. It takes the input string, parses it into an intermediary data type and then turns it into the output string by
This is the Data type used. I have no problems with the Data type -> Output String conversion, it works flawlessly:
data Expression = Expression :+ Expression | Expression :- Expression | Expression :* Expression | Expression :/ Expression | Expression :^ Expression | Cons String infixr 0 :+ infixr 0 :- infixr 1 :* infixr 1 :/ infixr 2 :^ instance Show Expression where show (x :+ y) = unwords [show x, show y, "+"] show (x :- y) = unwords [show x, show y, "-"] show (x :* y) = unwords [show x, show y, "*"] show (x :/ y) = unwords [show x, show y, "/"] show (x :^ y) = unwords [show x, show y, "^"] show (Cons y) = y
The Parsec parser part, however, refuses to comply with the defined operator precedency rules. Clearly because of the way
chainl1 is used in the
subexpression parser definition:
expression :: Parser Expression expression = do spaces x <- subexpression spaces >> eof >> return x subexpression :: Parser Expression subexpression = ( (bracketed subexpression) <|> constant ) `chainl1` ( try addition <|> try substraction <|> try multiplication <|> try division <|> try exponentiation ) addition = operator '+' (:+) substraction = operator '-' (:-) multiplication = operator '*' (:*) division = operator '/' (:/) exponentiation = operator '^' (:^) operator :: Char -> (a -> a -> a) -> Parser (a -> a -> a) operator c op = do spaces >> char c >> spaces return op bracketed :: Parser a -> Parser a bracketed parser = do char '(' x <- parser char ')' return x constant :: Parser Expression constant = do parity <- optionMaybe $ oneOf "-+" constant <- many1 (digit <|> char '.') return (if parity == Just '-' then (Cons $ '_':constant) else Cons constant)
Is there a way of making the parser take into account the operator precedence rules without having to rewrite the entirety of my code?