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I've started to wrap my head around it, and rather like using it for simple situations in which I can essentially pipe the values from one output to one input. A simple example of a pointfree composition I'm comfortable with would be:

let joinLines = foldr (++) "" . intersperse "\n"

While playing with GHCI today, I wanted to see if I could compose not and (==) to replicate (/=), but I wasn't really able to reason it out. (==) take two inputs, and not takes one. I thought that this might work:

let ne = not . (==)

With the assumption that the single Bool output of (==) would go to not, but it won't compile, citing the following error:

    Couldn't match expected type `Bool' with actual type `a0 -> Bool'
    Expected type: a0 -> Bool
      Actual type: a0 -> a0 -> Bool
    In the second argument of `(.)', namely `(==)'
    In the expression: not . (==)

I wish I could say it meant much to me, but all I'm getting is that maybe the second argument that's passed to (==) is mucking things up for not? Can anybody help me understand a little better the logic behind this composition?

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For the point-free lovers: the combinator you're looking for is (.).(.) :: (b -> c) -> (a -> a1 -> b) -> a -> a1 -> c, or fmap . fmap. – phg Sep 13 '12 at 19:43

2 Answers 2

up vote 13 down vote accepted

If you start to remove one argument at the time, you get

ne x y = not (x == y)
       = (not . (x ==)) y
ne x   = not . (x ==)
       = not . ((==) x)
       = ((not .) . (==)) x
ne     = (not .) . (==)

basically, for every argument you need one (.), properly associated.

The type of (==) is Eq a => a -> a -> Bool. So if you write whatever . (==), and pass a value x to that, you get whatever ((==) x), but (==) x is a function a -> Bool (where a is the type of x, and an instance of Eq). So the whatever must accept arguments of function type.

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Logically that makes sense to me, and it compiles, but results in a runtime error on (for example) ne 1 1: "No instance for (Num ()) arising from the literal 1' Possible fix: add an instance declaration for (Num ()) In the second argument of ne', namely 1' In the expression: ne 1 1 In an equation for it': it = ne 1 1" – KChaloux Sep 13 '12 at 15:23
That's the monomorphism restriction. Give the binding a type signature, or disable the MR (:set -XNoMonomorphismRestriction). For ghci, the latter is easier, for files, I recommend the former. – Daniel Fischer Sep 13 '12 at 15:28
Alright, totally new to me. Thanks. I'm sure this will help prepare me for stuff down the road. EDIT: Just tried the latter in ghci, and it does indeed work. I'll mark you as the answer when it lets me :p – KChaloux Sep 13 '12 at 15:29
To elaborate, let ne = (not .) . (==) is binding ne with a simple pattern binding [no function arguments] and without type signature. By the MR, entities bound by such bindings must have monomorphic types. Thus the type variable in the inferred type ne :: Eq a => a -> a -> Bool must be specialised to a concrete type. ghci's extended defaulting rules specialise it to (). In a file, that constraint is not defaultable [unless you enable ExtendedDefaultRules] and leads to a compilation error. – Daniel Fischer Sep 13 '12 at 15:32

Another useful operator is (.:), which is a combinator for an initial function taking two arguments:

f . g  $ x
f .: g $ x y
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+1 For being informative. And apparently creating an account just to do so :p – KChaloux Sep 13 '12 at 20:01
Is this defined somewhere standard? I usually call it oo (as in ML) and define it as: oo = (.) . (.), but I'm not aware if it's in Base somewhere. – singpolyma Sep 14 '12 at 0:56

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