At the type level you have another programming language, *almost*-Haskell. In particular, you can view types as having constructors and being able to be partially applied.

To view this a bit more rigorously, we introduce "types of types" called "kinds". For instance, the type constructor `Int`

has kind

```
Int ::: *
```

where I write `(:::)`

to read "has kind", though this isn't valid Haskell syntax. Now we also have "partially applied type constructors" like

```
Maybe ::: * -> *
```

which has a function type just like you'd expect at the value level.

There's one really important concept to the notion of kinds—values may instantiate types only if they are kind `*`

. Or, for example, there exist no values of type `Maybe`

```
x :: Maybe
x = -- .... what!
```

In fact, it's not possible to even express a type of kind other than `*`

anywhere where we'd expect that type to be describing a value.

This leads to a certain kind of restriction in the power of "type level functions" in Haskell in that we can't just universally pass around "unapplied type constructors" since they don't always make much sense. Instead, the whole system is designed such that only sensible types can ever be constructed.

But one place where these "higher kinded types" are allowed to be expressed is in typeclass definitions.

If we enable `KindSignatures`

then we can write the kinds of our types directly. One place this shows up is in class definitions. Here's `Show`

```
class Show (a :: *) where
show :: a -> String
...
```

This is totally natural as the occurrences of the type `a`

in the signatures of the methods of `Show`

are of values.

But of course, as you've noted here, `Functor`

is different. If we write out its kind signature we see why

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

This is a really novel kind of polymorphism, higher-kinded polymorphism, so it takes a minute to get your head all the way around it. What's important to note however is that `f`

only appears in the methods of `Functor`

*being applied* to some other types `a`

and `b`

. In particular, a class like this would be rejected

```
class Nope (f :: * -> *) where
nope :: f -> String
```

because we told the system that `f`

has kind `(* -> *)`

but we used it as though it could instantiate values, as though it were kind `*`

.

Normally, we don't have to use `KindSignatures`

because Haskell can infer the signatures directly. For instance, we could (and in fact do) write

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

and Haskell infers that the kind of `f`

must be `(* -> *)`

because it appears applied to `a`

and `b`

. Likewise, we can fail "kind checking" in the same was as we fail type checking if we write something inconsistent. For instance

```
class NopeNope f where
fmap :: f -> f a -> a
```

implies that `f`

has kind `*`

*and* `(* -> *)`

which is inconsistent.

`f = Promise a`

" -- which is exactly what your`Functor`

instance is (`Functor (Promise x)`

). – Xeo May 27 '14 at 21:31`Promise a`

?`Promise a`

is a type constructor that takes one argument, so it doesn't have a type (it constructs types). – David Young May 27 '14 at 21:47