You *can* do it with `DataKinds`

. This may be overcomplicated, though:

```
{-# LANGUAGE DataKinds, KindSignatures, GADTs #-}
-- requires 7.4.1, I think
data Nat = S Nat | Z
infixr 0 :.
data R (n :: Nat) where
Nil :: R Z -- like []
(:.) :: Bool -> R n -> R (S n) -- and (:)
data T (n :: Nat) = T [R n]
-- OK
test1 = T [(True :. True :. Nil), (True :. False :. Nil)]
-- will fail
test2 = T [(True :. True :. Nil), (False :. Nil)]
```

I'd rather recommend @MathematicalOrchids alternative approach using smart constructors.

EDIT: What `DataKinds`

do.

The `DataKinds`

extension lets the compiler automatically create a new kind other than `*`

for each data type one writes, and new types living in this kind from the constructors.

So `Nat`

, besides being a simple ADT, also gives rise to a kind `Nat`

, and type constructors `Z :: Nat`

and `S :: Nat -> Nat`

. This `S`

is comparable to `Maybe :: * -> *`

-- it just doesn't use the kind of all types, but your new kind `Nat`

, inhabited only by the representations of the natural numbers.

The point is, that now you also can define type constructors of *mixed* kinds. The classic example for this is `Vec`

:

```
data Vec (n :: Nat) (a :: *) where {-...-}
```

which has kind `Vec :: Nat -> * -> *`

. Similarly, `T`

has kind `T :: Nat -> *`

. This let's you use it with a type-encoded constant lenght, and leads to a type error if one two rows of different lenght are put together.

Although this looks extremely powerful, it is in fact restricted. To get the everything out of such representations, dependently typed languages should like Agda should be used.