The most basic form of the kind language contains only `*`

(or `Type`

in more modern Haskell; I suspect we'll eventually move away from `*`

) and `->`

.

But there are more things you can build with that language than you can express by just "counting the number of `*`

s". It's not just the number of `*`

or `->`

that matter, but how they are nested. For example `* -> * -> *`

is the kind of things that take two type arguments to produce a type, but `(* -> *) -> *`

is the kind of things that take a single argumemt to produce a type where that argument itself must be a thing that takes a type argument to produce a type. `data ThreeStars a b = Cons a b`

makes a type constructor with kind `* -> * -> *`

, while `data AlsoThreeStars f = AlsoCons (f Integer)`

makes a type constructor with kind `(* -> *) -> *`

.

There are several language extensions that add more features to the kind language.

`PolyKinds`

adds kind *variables* that work exactly the same way type variables work. Now we can have kinds like `forall k. (* -> k) -> k`

.

`ConstraintKinds`

makes constraints (the stuff to the left of the `=>`

in type signatures, like `Eq a`

) become ordinary type-level entities in a new kind: `Constraint`

. Rather than the stuff left of the `=>`

being special purpose syntax fairly disconnected from the rest of the language, now what is acceptable there is anything with kind `Constraint`

. Classes like `Eq`

become type constructors with kind `* -> Constraint`

; you apply it to a type like `Eq Bool`

to produce a `Constraint`

. The advantage is now we can use all of the language features for manipulating type-level entities to manipulate constraints (including `PolyKinds`

!).

`DataKinds`

adds the ability to create new user-defined kinds containing new type-level things, in exactly the same way that in vanilla Haskell we can create new user-defined types containing new term-level things. (**Exactly** the same way; the way `DataKinds`

actually works is that it lets you use a `data`

declaration as normal and then you can use the resulting type constructor at either the type or the kind level)

There are also kinds used for unboxed/unlifted types, which must not be ever mixed with "normal" Haskell types because they have a different memory layout; they can't contain thunks to implement lazy evaluation, so the runtime has to know never to try to "enter" them as a code pointer, or look for additional header bits, etc. They need to be kept separate at the kind level so that ordinary type variables of kind `*`

can't be instantiated with these unlifted/unboxed types (which would allow you to pass these types that need special handling to generic code that doesn't know to provide the special handling). I'm vaguely aware of this stuff but have never actually had to use it, so I won't add any more so I don't get anything wrong. (Anyone who knows what they're talking about enough to write a brief summary paragraph here, please feel free to edit the answer)

There are probably some others I'm forgetting. But certainly the kind language is richer than the OP is imagining just with the basic Haskell features, and there is much more to it once you turn on a few (quite widely used) extensions.

`DataKinds`

, if you then define a`data Foo = Foo Nat`

for example, you can define a type`type Bar = Foo 42`

, and`Bar`

has kind`Foo`

.`*`

kind (also known as`Type`

) the kinds`* -> * -> *`

and`(* -> *) -> *`

wouldn't be the same.`Nat`

is for example a kind that allows to use natural numbers as kind.`MaybeT`

, have kind`(* -> *) -> * -> *`

.