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Is it possible to express the chainl1 combinator from Parsec not using the Monad instance defined by parsec?

chainl1 p op =
  do x <- p
     rest x
  where
    rest x = do f <- op
                y <- p
                rest (f x y)
          <|> return x
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2 Answers 2

up vote 4 down vote accepted

Yes, it is:

chainl1 p op = foldl (flip ($)) <$> p <*> many (flip <$> op <*> p)

The idea is that you have to parse p (op p)* and evaluate it as (...(((p) op p) op p)...).

It might help to expand the definition a bit:

chainl1 p op = foldl (\x f -> f x) <$> p <*> many ((\f y -> flip f y) <$> op <*> p)

As the pairs of op and p are parsed, the results are applied immediately, but because p is the right operand of op, it needs a flip.

So, the result type of many (flip <$> op <*> p) is f [a -> a]. This list of functions is then applied from left to right on an initial value of p by foldl.

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Would you care to explain a little bit more? Why the foldl and flip? –  adamse Oct 11 '11 at 6:48

Ugly but equivalent Applicative definition:

chainl1 p op =
    p <**>
    rest
  where
    rest = flip <$> op <*>
           p <**>
           pure (.) <*> rest
        <|> pure id

Instead of passing of left-side argument x explicitly to the right-hand side op, this Applicative form 'chains' op's partially applied to their right-side argument (hence flip <$> op <*> p) via lifted combinator (.) and then applies the leftmost p via (<**>) to the resulting rest :: Alternative f => f (a -> a).

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When I try this with chainl1 (read <$> many digit) ((+) <$ char '+' <|> (*) <$ char '*') on "1+2*3+4" I get 17 instead of 13. –  Sjoerd Visscher Oct 11 '11 at 15:40
    
It needs flip (.) instead of (.), then it works ok. –  Sjoerd Visscher Oct 11 '11 at 15:46

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