This is one of those neat cases where I think it's simpler to grasp the more general case first, and then think about the specific case. So let's think about functors. We know that functors provide a way to map functions over a structure --

```
class Functor f where
fmap :: (a -> b) -> f a -> f b
```

But what if we have two layers of the functor? For example, a list of lists? In that case we can use two layers of `fmap`

```
>>> let xs = [[1,2,3], [4,5,6]]
>>> fmap (fmap (+10)) xs
[[11,12,13],[14,15,16]]
```

But the pattern `f (g x)`

is exactly the same as `(f . g) x`

so we could write

```
>>> (fmap . fmap) (+10) xs
[[11,12,13],[14,15,16]]
```

What is the type of `fmap . fmap`

?

```
>>> :t fmap.fmap
:: (Functor g, Functor f) => (a -> b) -> f (g a) -> f (g b)
```

We see that it maps over two layers of functor, as we wanted. But now remember that `(->) r`

is a functor (the type of functions from `r`

, which you might prefer to read as `(r ->)`

) and its functor instance is

```
instance Functor ((->) r) where
fmap f g = f . g
```

For a function, `fmap`

is just function composition! When we compose two `fmap`

s we map over two levels of the function functor. We initially have something of type `(->) s ((->) r a)`

, which is equivalent to `s -> r -> a`

, and we end up with something of type `s -> r -> b`

, so the type of `(.).(.)`

must be

```
(.).(.) :: (a -> b) -> (s -> r -> a) -> (s -> r -> b)
```

which takes its first function, and uses it to transform the output of the second (two-argument) function. So for example, the function `((.).(.)) show (+)`

is a function of two arguments, that first adds its arguments together and then transforms the result to a `String`

using `show`

:

```
>>> ((.).(.)) show (+) 11 22
"33"
```

There is then a natural generalization to thinking about longer chains of `fmap`

, for example

```
fmap.fmap.fmap ::
(Functor f, Functor g, Functor h) => (a -> b) -> f (g (h a)) -> f (g (h b))
```

which maps over three layers of functor, which is equivalent to composing with a function of three arguments:

```
(.).(.).(.) :: (a -> b) -> (r -> s -> t -> a) -> (r -> s -> t -> b)
```

for example

```
>>> import Data.Map
>>> ((.).(.).(.)) show insert 1 True empty
"fromList [(1,True)]"
```

which inserts the value `True`

into an empty map with key `1`

, and then converts the output to a string with `show`

.

These functions can be generally useful, so you sometimes see them defined as

```
(.:) :: (a -> b) -> (r -> s -> a) -> (r -> s -> b)
(.:) = (.).(.)
```

so that you can write

```
>>> let f = show .: (+)
>>> f 10 20
"30"
```

Of course, a simpler, pointful definition of `(.:)`

can be given

```
(.:) :: (a -> b) -> (r -> s -> a) -> (r -> s -> b)
(f .: g) x y = f (g x y)
```

which may help to demystify `(.).(.)`

somewhat.

`(.)`

actually takes one argument and returns a function that takes one argument. – Wes Jul 11 '13 at 8:02`(.) f g a = f (g a)`

– Ingo Jul 11 '13 at 10:40`(.) (+1) (*2) 3`

works :) – Wes Jul 11 '13 at 13:48`(return.return)`

, with`return = (.)`

to get the general idea of this sort of thing. – AndrewC Jul 15 '13 at 20:12