the type of fmap in Functor is:

```
fmap :: Functor f => (a -> b) -> f a -> f b
```

it looks like ,first apply function (a -> b) to the parameter of f a
to create a result of type b, then apply f to it, and result is f b

That is the type of `fmap`

, but your interpretation of what that type means is wrong.

You seem to assume that `f a`

has one parameter, and that that parameter has type `a`

.

Consider `xs :: [a]`

:

- Perhaps
`xs = []`

.
- Perhaps
`xs = [x1]`

.
- Perhaps
`xs = [x1, x2]`

.
- ...

The *type* `f a`

is a functor `f`

with a single type parameter `a`

. But *values* of type `f a`

do not necessarily take the form `F x`

, as you can see from the first and third cases above.

Now consider `fmap f xs`

:

- Perhaps
`fmap f xs = []`

.
- Perhaps
`fmap f xs = [f x1]`

.
- Perhaps
`fmap f xs = [f x1, f x2]`

.
- ...

We don't necessarily apply `f`

at all (first case)! Or we might apply it more than once (third case).

What we do is replace the things of type `a`

, with things of type `b`

. But we leave the larger structure intact --- no new elements added, no elements removed, their order is left unchanged.

Now let's think about the functor `(c ->)`

. (Remember, a functor takes one type parameter only, so the input to `(->)`

is fixed.)

Does a `c -> a`

even contain an `a`

? It might not contain any `a`

s at all, but it can somehow magic one out of thin air when we give it a `c`

. But the result from `fmap`

has type `c -> b`

: we only have to provide a `b`

out of that when we're presented with a `c`

.

So we can say `fmap f x = \y -> f (x y)`

.

In this case, we're applying `f`

on demand --- every time the function we return gets applied, `f`

gets applied as well.