So by this point you've certainly heard of *currying* or *partial application*: if you have `f :: a -> b -> c`

and `x :: a`

, then `f x :: b -> c`

. I.e., If `f`

is a two-argument function and `x`

has the type of `f`

's first argument, then `f x`

is a function that takes the second argument and "completes" the application.

Well, in Haskell the same thing applies to type constructors like `State`

. Types and type constructors have a *kind*, which is analogous to how values have types. A non-parametric type like `Integer`

has kind `*`

; a one-parameter type like `Maybe`

has kind `* -> *`

; `State`

has kind `* -> * -> *`

.

And then, `State state`

is a partial application of the `State`

type constructor, and has kind `* -> *`

. `Monad`

is a class that applies to the kind `* -> *`

. So, applied to our examples:

`instance Monad (Integer) where ...`

is forbidden because `Integer`

has kind `*`

.
`instance Monad (Maybe) where ...`

is allowed because `Maybe`

has kind `* -> *`

.
`instance Monad (State) where ...`

is forbidden because `State`

has kind `* -> * -> *`

.
`instance Monad (State st) where ...`

is allowed because `State st`

has kind `* -> *`

.

How do we know that `Monad`

applies to types of kind `* -> *`

? We can infer it from the class declaration:

```
class Monad m where
return :: a -> m a
(>>=) :: m a -> (a -> m b) -> m b
-- ...
```

Look at how `m`

is used in this class declaration: as part of `m a`

and `m b`

, i.e., as taking one argument. Because of this, Haskell infers that `m`

is a type variable of kind `* -> *`

.

Compare to this:

```
class Num a where
(+) :: a -> a -> a
(-) :: a -> a -> a
-- ...
```

Here the type variable `a`

is not applied to other type variables—thus it must be of kind `*`

.

So strictly speaking, `State`

is not a monad; it's a two-place type constructor that, when partially applied to just one type, gives you a monad. So `State state`

is a monad, as is `State Integer`

, `State [a]`

, etc. People do often speak loosely and talk of `State`

and similar things as monads, though, but you should understand it's a *parametrized* monad—it's a monad that has an internal type parameter and thus many variants that differ in the type of that parameter.