Let's look at each line separately.

```
class Functor f where
```

This declares a single-parameter type class called `Functor`

; the type which satisfies it will be called `f`

.

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

Like any function definition, all the free type variables are implicitly `forall`

ed—they can be replaced with anything. However, thanks to the first line, `f`

is in scope. Thus, `fmap`

has the type signature `fmap :: forall a b. Functor f => (a -> b) -> f a -> f b`

. In other words, every functor needs to have a definition of `fmap`

which can work for *any* `a`

and `b`

, and `f`

must have **kind** (the type of a type) `* -> *`

; that is, it must be a type which takes another type, such as `[]`

or `Maybe`

or `IO`

.

What you said, then, is incorrect; the `a`

isn't special, and if we had another function in `Functor`

, it wouldn't see the same `a`

or `b`

. However, the compiler *does* use the `f a`

bit to figure out what the kind of `f`

must be. Additionally, your `Foo`

class is perfectly legal; I could specify an instance as follows

```
instance Foo (a -> b) where
foo f _ = f
```

This satisfies `foo :: a -> b -> a`

for *any* `b`

; note that the `b`

in `Foo (a -> b)`

is different. Admittedly, it's not a very interesting instance, but it's perfectly legal.