The expression `fmap . fmap`

has two instances of `fmap`

which can, in principle, have different types. So let's say their types are

```
fmap :: (x -> y) -> (g x -> g y)
fmap :: (u -> v) -> (f u -> f v)
```

Our job is to unify types (which amounts to coming up with equality relations between these type variables) so that the right-hand side of the first `fmap`

is the same as the left-hand side of the second `fmap`

. Hopefully you can see that if you set `u = g x`

and `v = g y`

you will end up with

```
fmap :: ( x -> y) -> ( g x -> g y )
fmap :: (g x -> g y) -> (f (g x) -> f (g y))
```

Now the type of compose is

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

To make this work out, you can pick `a = x -> y`

and `b = g x -> g y`

and `c = f (g x) -> f (g y)`

so that the type can be written

```
(.) :: ((g x -> g y) -> (f (g x) -> f (g y))) -> ((x -> y) -> (g x -> g y)) -> ((x -> y) -> (f (g x) -> f (g y)))
```

which is pretty unwieldy, but it's just a specialization of the original type signature for `(.)`

. Now you can check that everything matches up such that `fmap . fmap`

typechecks.

An alternative is to approach it from the opposite direction. Let's say that you have some object that has two levels of functoriality, for example

```
>> let x = [Just "Alice", Nothing, Just "Bob"]
```

and you have some function that adds bangs to any string

```
bang :: String -> String
bang str = str ++ "!"
```

You'd like to add the bang to each of the strings in `x`

. You can go from `String -> String`

to `Maybe String -> Maybe String`

with one level of `fmap`

```
fmap bang :: Maybe String -> Maybe String
```

and you can go to `[Maybe String] -> [Maybe String]`

with another application of `fmap`

```
fmap (fmap bang) :: [Maybe String] -> [Maybe String]
```

Does that do what we want? Hell yeah!

```
>> fmap (fmap bang) x
[Just "Alice!", Nothing, Just "Bob!"]
```

Let's write a utility function, `fmap2`

, that takes any function `f`

and applies `fmap`

to it twice, so that we could just write `fmap2 bang x`

instead. That would look like this

```
fmap2 f x = fmap (fmap f) x
```

You can certainly drop the `x`

from both sides

```
fmap2 f = fmap (fmap f)
```

Now you realize that the pattern `g (h x)`

is the same as `(g . h) x`

so you can write

```
fmap2 f = (fmap . fmap) f
```

so you can now drop the `f`

from both sides

```
fmap2 = fmap . fmap
```

which is the function you were interested in. So you see that `fmap . fmap`

just takes a function, and applies `fmap`

to it twice, so that it can be lifted through two levels of functoriality.