Can a Haskell type constructor have non-type parameters?

Let's unpack what you mean by *type parameter*. The word *type* has (at least) two potential meanings: do you mean *type* in the narrow sense of *things of kind *`*`

, or in the broader sense of *things at the type level*? We can't (yet) use values in types, but modern GHC features a very rich kind language, allowing us to use a wide range of things other than concrete types as type parameters.

## Higher-Kinded Types

Type constructors in Haskell have always admitted non-`*`

parameters. For example, the encoding of the fixed point of a functor works in plain old Haskell 98:

```
newtype Fix f = Fix { unFix :: f (Fix f) }
ghci> :k Fix
Fix :: (* -> *) -> *
```

`Fix`

is parameterised by a functor of kind `* -> *`

, not a type of kind `*`

.

## Beyond `*`

and `->`

The `DataKinds`

extension enriches GHC's kind system with user-declared kinds, so kinds may be built of pieces other than `*`

and `->`

. It works by *promoting* all `data`

declarations to the kind level. That is to say, a `data`

declaration like

```
data Nat = Z | S Nat -- natural numbers
```

introduces a *kind* `Nat`

and *type* constructors `Z :: Nat`

and `S :: Nat -> Nat`

, as well as the usual type and value constructors. This allows you to write datatypes parameterised by type-level data, such as the customary *vector* type, which is a linked list indexed by its length.

```
data Vec n a where
Nil :: Vec Z a
(:>) :: a -> Vec n a -> Vec (S n) a
ghci> :k Vec
Vec :: Nat -> * -> *
```

There's a related extension called `ConstraintKinds`

, which frees constraints like `Ord a`

from the yoke of the "fat arrow" `=>`

, allowing them to roam across the landscape of the type system as nature intended. Kmett has used this power to build a category of constraints, with the newtype `(:-) :: Constraint -> Constraint -> *`

denoting "entailment": a value of type `c :- d`

is a proof that if `c`

holds then `d`

also holds. For example, we can prove that `Ord a`

implies `Eq [a]`

for all `a`

:

```
ordToEqList :: Ord a :- Eq [a]
ordToEqList = Sub Dict
```

## Life after `forall`

However, Haskell currently maintains a strict separation between the type level and the value level. Things at the type level are always erased before the program runs, (almost) always inferrable, invisible in expressions, and (dependently) quantified by `forall`

. If your application requires something more flexible, such as dependent quantification over runtime data, then you have to manually simulate it using a *singleton* encoding.

For example, the specification of `split`

says it chops a vector at a certain length according to its (runtime!) argument. The *type* of the output vector depends on the *value* of `split`

's argument. We'd like to write this...

```
split :: (n :: Nat) -> Vec (n :+: m) a -> (Vec n a, Vec m a)
```

... where I'm using the type function `(:+:) :: Nat -> Nat -> Nat`

, which stands for addition of type-level naturals, to ensure that the input vector is at least as long as `n`

...

```
type family n :+: m where
Z :+: m = m
S n :+: m = S (n :+: m)
```

... but Haskell won't allow that declaration of `split`

! There aren't any values of type `Z`

or `S n`

; only types of kind `*`

contain values. We can't access `n`

at runtime directly, but we can use a GADT which we can pattern-match on to *learn* what the type-level `n`

is:

```
data Natty n where
Zy :: Natty Z
Sy :: Natty n -> Natty (S n)
ghci> :k Natty
Natty :: Nat -> *
```

`Natty`

is called a *singleton*, because for a given (well-defined) `n`

there is only one (well-defined) value of type `Natty n`

. We can use `Natty n`

as a run-time stand-in for `n`

.

```
split :: Natty n -> Vec (n :+: m) a -> (Vec n a, Vec m a)
split Zy xs = (Nil, xs)
split (Sy n) (x :> xs) =
let (ys, zs) = split n xs
in (x :> ys, zs)
```

Anyway, the point is that values - runtime data - can't appear in types. It's pretty tedious to duplicate the definition of `Nat`

in singleton form (and things get worse if you want the compiler to infer such values); dependently-typed languages like Agda, Idris, or a future Haskell escape the tyranny of strictly separating types from values and give us a range of expressive quantifiers. You're able to use an honest-to-goodness `Nat`

as `split`

's runtime argument and mention its value dependently in the return type.

@pigworker has written extensively about the unsuitability of Haskell's strict separation between types and values for modern dependently-typed programming. See, for example, the *Hasochism* paper, or his talk on the unexamined assumptions that have been drummed into us by four decades of Hindley-Milner-style programming.

## Dependent Kinds

Finally, for what it's worth, with `TypeInType`

modern GHC unifies types and kinds, allowing us to talk about kind variables using the same tools that we use to talk about type variables. In a previous post about session types I made use of `TypeInType`

to define a kind for tagged type-level sequences of types:

```
infixr 5 :!, :?
data Session = Type :! Session -- Type is a synonym for *
| Type :? Session
| E
```

`Char -> ...`

but there are no types which inhabit the kind`Char`

, because`data Char = C# Char#`

and primitive types are not promotable.