Coming up with `(.) . (.)`

is actually pretty straightforward, it's the intuition behind what it does that is quite tricky to understand.

`(.)`

gets you very far when rewriting expression into the "pipe" style computations (think of `|`

in shell). However, it becomes awkward to use once you try to compose a function that takes multiple arguments with a function that only takes one. As an example, let's have a definition of `concatMap`

:

```
concatMap :: (a -> [b]) -> [a] -> [b]
concatMap f xs = concat (map f xs)
```

Getting rid of `xs`

is just a standard operation:

```
concatMap f = concat . map f
```

However, there's no "nice" way of getting rid of `f`

. This is caused by the fact, that `map`

takes two arguments and we'd like to apply `concat`

on its final result.

You can of course apply some pointfree tricks and get away with just `(.)`

:

```
concatMap f = (.) concat (map f)
concatMap f = (.) concat . map $ f
concatMap = (.) concat . map
concatMap = (concat .) . map
```

But alas, readability of this code is mostly gone. Instead, we introduce a new combinator, that does exactly what we need: apply the second function to the *final result* of first one.

```
-- .: is fairly standard name for this combinator
(.:) :: (c -> d) -> (a -> b -> c) -> a -> b -> d
(f .: g) x y = f (g x y)
concatMap = concat .: map
```

Fine, that's it for motivation. Let's get to the pointfree business.

```
(.:) = \f g x y -> f (g x y)
= \f g x y -> f ((g x) y)
= \f g x y -> f . g x $ y
= \f g x -> f . g x
```

Now, here comes the interesting part. This is yet another of the pointfree tricks that usually helps when you get stuck: we rewrite `.`

into its prefix form and try to continue from there.

```
= \f g x -> (.) f (g x)
= \f g x -> (.) f . g $ x
= \f g -> (.) f . g
= \f g -> (.) ((.) f) g
= \f -> (.) ((.) f)
= \f -> (.) . (.) $ f
= (.) . (.)
```

As for intuition, there's this very nice article that you should read. I'll paraphrase the part about `(.)`

:

Let's think again about what our combinator should do: it should apply `f`

to the *result* of *result* of `g`

(I've been using *final result* in the part before on purpose, it's really what you get when you fully apply - modulo unifying type variables with another function type - the `g`

function, *result* here is just application `g x`

for some `x`

).

What it means for us to apply `f`

to the *result* of `g`

? Well, once we apply `g`

to some value, we'll take the result and apply `f`

to it. Sounds familiar: that's what `(.)`

does.

```
result :: (b -> c) -> ((a -> b) -> (a -> c))
result = (.)
```

Now, it turns out that composition (our *of* word) of those combinators is just a function composition, that is:

```
(.:) = result . result -- the result of result
```

`fmap . fmap`

, well, just specialize both`fmap`

s to the`(->) e`

functor and you're done. ;-) – Daniel Wagner Feb 23 '13 at 2:08