# Bottleneck in math parser Haskell

I got this code below from the wiki books page here. It parses math expressions, and it works very well for the code I'm working on. Although there is one problem, when I start to add layers of brackets to my expression the program slows down dramatically, crashing my computer at some point. It has something to do with the number of operators I have it check for, the more operators I have the less brackets I can parse. Is there anyway to get around or fix this bottleneck?

Any help is much appreciated.

``````import Text.ParserCombinators.ReadP

-- slower
operators = [("Equality",'='),("Sum",'+'), ("Product",'*'), ("Division",'/'), ("Power",'^')]
-- faster
-- ~ operators = [("Sum",'+'), ("Product",'*'), ("Power",'^')]

skipWhitespace = do
many (choice (map char [' ','\n']))
return ()

brackets p = do
skipWhitespace
char '('
r <- p
skipWhitespace
char ')'
return r

data Tree op = Apply (Tree op) (Tree op) | Branch op (Tree op) (Tree op) | Leaf String deriving Show

leaf = chainl1 (brackets tree
+++ do
skipWhitespace
s <- many1 (choice (map char "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789.-[]" ))
return (Leaf s))
(return Apply)
tree = foldr (\(op,name) p ->
let this = p +++ do
a <- p +++ brackets tree
skipWhitespace
char name
b <- this
return (Branch op a b)
in this)
(leaf +++ brackets tree)
operators

readA str = fst \$ last \$ readP_to_S tree str

main = do loop

loop = do
-- ~ try this
-- ~ (a+b+(c*d))
str <- getLine
print \$ last \$ readP_to_S tree str
loop
``````
-
ReadP parses all alternatives in parallel, so I'd guess that your grammar includes a lot of potential alternative parses. Try turning skipWhiteSpace into a no-op: maybe its trying to parse all the alternative interpretations of which skipWhiteSpace should consume any given space, or even any given lack of space. Or you could switch to Parsec which only backtracks when you tell it to. – Paul Johnson Dec 6 '13 at 20:13

## 1 Answer

This is a classic problem in backtracking (or parallel parsing, they are basically the same thing).... Backtracking grows (at worst) exponentially with the size of the input, so the time to parse something can suddenly explode. In practice backtracking works OK in language parsing for most input, but explodes with recursive infix operator notation. You can see why by considering how many possibile ways this could be parsed (using made up & and % operators):

``````a & b % c & d
``````

could be parsed as

``````a & (b % (c & d))
a & ((b % c) & d)
(a & (b % c)) & d
((a & b) % c) & d
``````

This grows like 2^(n-1). The solution to this is to add some operator precidence information earlier in the parse, and throw away all but the sensible cases.... You will need an extra stack to hold pending operators, but you can always go through infix operator expressions in O(1).

LR parsers like yacc do this for you.... With a parser combinator you need to do it by hand. In parsec, there is a Expr package with a buildExpressionParser function that builds this for you.

-
Awesome, this is good answer! Should I close the question? I'm a bit new here. – Freakasuar Dec 6 '13 at 20:59
Remember the Seinfeld where Elaine asks the luggage guy at the airport how much to tip and he says something like \$10 per bag? With that in mind, let me just answer your question by saying- Give me the accepted answer, then upvote me, then you are done here :) (seriously though, if you like an answer you can always choose it as the accepted answer and that kind of closes up things, although others are still free to answer). – jamshidh Dec 6 '13 at 21:01
If you don't mind, do you know of any good examples of buildExpressionParser?, or I can just Google it. – Freakasuar Dec 6 '13 at 21:03
I could write something, but it probably wouldn't be as good as what you will google.... When I used this months ago, it was really easy to get examples. (here is something haskell.org/haskellwiki/Parsing_expressions_and_statements) – jamshidh Dec 6 '13 at 21:06
Thanks again, good example btw – Freakasuar Dec 6 '13 at 21:11