# How to make the Parsec chainl1 function follow operator precedence rules

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 `show`ing it.

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 substraction          <|>
try multiplication        <|>
try division              <|>
try exponentiation
)

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?

-

Well, you don't need to rewrite your entire code, but since your `subexpression` parser doesn't take precedence into account at all, you have to rewrite that - substantially.

One possibility is to build it from parsers for subexpressions with top-level operators with the same precedence,

``````atom :: Parser Expression
atom = bracketed subexpression <|> constant

-- highest precedence operator is exponentiation, usually that's
-- right-associative, hence I use chainr1 here
powers :: Parser Expression
powers = atom `chainr1` try exponentiation

-- a multiplicative expression is a product or quotient of powers,
-- left-associative
multis :: Parser Expression
multis = powers `chainl1` (try multiplication <|> try division)

-- a subexpression is a sum (or difference) of multiplicative expressions
subexpression :: Parser Expression
subexpression = multis `chainl1` (try addition <|> try substraction)
``````

Another option is to let the precedence and associativities be taken care of by the library and use `Text.Parsec.Expr`, namely `buildExpressionParser`:

``````table = [ [binary "^" (:^) AssocRight]
, [binary "*" (:*) AssocLeft, binary "/" (:/) AssocLeft]
, [binary "+" (:+) AssocLeft, binary "-" (:-) AssocLeft]
]

binary  name fun assoc = Infix (do{ string name; spaces; return fun }) assoc

subexpression = buildExpressionParser table atom
``````

(which requires that `bracketed parser` and `constant` consume the spaces after the used tokens).

-
Thank you. This parser encapsulation was exactly what I needed. So far I've only worked with Regular Expressions, so the context-sensitive capabilities of Parsec and the like still make my head spin a little. – Witiko May 3 '13 at 22:28
You'll have to relearn a bit then, but writing parsers is much easier than regular expressions for even mildly complicated things once you got your feet wet. – Daniel Fischer May 3 '13 at 22:30