When you make an instance of Functor, you should *prove* the side condition that

```
fmap id = id
```

and

```
fmap (f . g) = fmap f . fmap g
```

(Technically the latter comes for free given the types involved and the former law, but it is still a good exercise.)

You can't do this just by saying

```
fmap id = id
```

but instead you use this as a reasoning tool -- once you have proven it.

That said, the code that you have written doesn't make sense for a number of reasons.

```
(f . g) x = f (g x)
```

Since this is indented, I'm somewhat unclear if this is intended to be a definition for (.), but that is already included in the Prelude, so you need not define it again.

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

This definition is also provided for you in the Prelude.

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

But then you define the class again, but here it has mangled the signature of fmap, which would have to be

```
fmap :: (a -> b) -> g a -> g b
```

But as you have another definition of Functor right above (and the Prelude has still another, you couldn't get that to compile)

Finally, your

```
instance Functor F where
fmap id = id
fmap (f . g) = fmap f . fmap g
```

makes up a name `F`

for a type that you want to make into an instance of `Functor`

, and then tries to give the laws as an implementation, which isn't how it works.

Let us take an example of how it should work.

Consider a very simple functor:

```
data Pair a = Pair a a
instance Functor Pair where
fmap f (Pair a b) = Pair (f a) (f b)
```

now, to prove `fmap id = id`

, let us consider what `fmap id`

and `id`

do pointwise:

```
fmap id (Pair a b) = -- by definition
Pair (id a) (id b) = -- by beta reduction
Pair a (id b) = -- by beta reduction
Pair a b
id (Pair a b) = -- by definition
Pair a b
```

So, `fmap id = id`

in this particular case.

Then you can check (though technically given the above, you don't have to) that `fmap f . fmap g = fmap (f . g)`

```
(fmap f . fmap g) (Pair a b) = -- definition of (.)
fmap f (fmap g (Pair a b)) = -- definition of fmap
fmap f (Pair (g a) (g b)) = -- definition of fmap
Pair (f (g a)) (f (g b))
fmap (f . g) (Pair a b) = -- definition of fmap
Pair ((f . g) a) ((f . g) b) = -- definition of (.)
Pair (f (g a)) ((f . g) b) = -- definition of (.)
Pair (f (g a)) (f (g b))
```

so `fmap f . fmap g = fmap (f . g)`

Now, you can make function composition into a functor.

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

by partially applying the function arrow constructor.

Note that `a -> b`

and `(->) a b`

mean the same thing, so when we say

```
instance Functor ((->) e) where
```

the signature of fmap specializes to

```
fmap {- for (->) e -} :: (a -> b) -> (->) e a -> (->) e b
```

which once you have flipped the arrows around looks like

```
fmap {- for (->) e -} :: (a -> b) -> (e -> a) -> e -> b
```

but this is just the signature for function composition!

So

```
instance Functor ((->)e) where
fmap f g x = f (g x)
```

is a perfectly reasonable definition, or even

```
instance Functor ((->)e) where
fmap = (.)
```

and it actually shows up in Control.Monad.Instances.

So all you need to use it is

```
import Control.Monad.Instances
```

and you don't need to write any code to support this at all and you can use `fmap`

as function composition as a special case, so for instance

```
fmap (+1) (*2) 3 =
((+1) . (*2)) 3 =
((+1) ((*2) 3)) =
((+1) (3 * 2)) =
3 * 2 + 1 =
7
```