System F-omega allows universal quantification, abstraction and application at *higher kinds*, so not only over types (at kind `*`

), but also at kinds `k1 -> k2`

, where `k1`

and `k2`

are themselves kinds generated from `*`

and `->`

. Hence, the type level itself becomes a simply typed lambda-calculus.

Haskell delivers slightly less than F-omega, in that the type system allows quantification and application at higher kinds, but not abstraction. Quantification at higher kinds is how we have types like

```
fmap :: forall f, s, t. Functor f => (s -> t) -> f s -> f t
```

with `f :: * -> *`

. Correspondingly, variables like `f`

can be instantiated with higher-kinded type expressions, such as `Either String`

. The lack of abstraction makes it possible to solve unification problems in type expressions by the standard first-order techniques which underpin the Hindley-Milner type system.

However, *type families* are not really another means to introduce higher-kinded types, nor a replacement for the missing type-level lambda. Crucially, they must be *fully applied*. So your example,

```
type family Foo a
type instance Foo Int = Int
type instance Foo Float = ...
....
```

should not be considered as introducing some

```
Foo :: * -> * -- this is not what's happening
```

because `Foo`

on its own is not a meaningful type expression. We have only the weaker rule that `Foo t :: *`

whenever `t :: *`

.

Type families do, however, act as a distinct type-level computation mechanism beyond F-omega, in that they introduce *equations* between type expressions. The extension of System F with equations is what gives us the "System Fc" which GHC uses today. Equations `s ~ t`

between type expressions of kind `*`

induce coercions transporting values from `s`

to `t`

. Computation is done by deducing equations from the rules you give when you define type families.

Moreover, you *can* give type families a higher-kinded return type, as in

```
type family Hoo a
type instance Hoo Int = Maybe
type instance Hoo Float = IO
...
```

so that `Hoo t :: * -> *`

whenever `t :: *`

, but still we cannot let `Hoo`

stand alone.

The trick we sometimes use to get around this restriction is `newtype`

wrapping:

```
newtype Noo i = TheNoo {theNoo :: Foo i}
```

which does indeed give us

```
Noo :: * -> *
```

but means that we have to apply the projection to make computation happen, so `Noo Int`

and `Int`

are provably distinct types, but

```
theNoo :: Noo Int -> Int
```

So it's a bit clunky, but we can kind of compensate for the fact that type families do not directly correspond to type operators in the F-omega sense.