Perhaps the canonical example is given by the vectors.

```
data Nat = Z | S Nat deriving (Show, Eq, Ord)
data Vec :: Nat -> * -> * where
V0 :: Vec Z x
(:>) :: x -> Vec n x -> Vec (S n) x
```

We can make them applicative with a little effort, first defining singletons, then wrapping them in a class.

```
data Natty :: Nat -> * where
Zy :: Natty Z
Sy :: Natty n -> Natty (S n)
class NATTY (n :: Nat) where
natty :: Natty n
instance NATTY Z where
natty = Zy
instance NATTY n => NATTY (S n) where
natty = Sy natty
```

Now we may develop the `Applicative`

structure

```
instance NATTY n => Applicative (Vec n) where
pure = vcopies natty
(<*>) = vapp
vcopies :: forall n x. Natty n -> x -> Vec n x
vcopies Zy x = V0
vcopies (Sy n) x = x :> vcopies n x
vapp :: forall n s t. Vec n (s -> t) -> Vec n s -> Vec n t
vapp V0 V0 = V0
vapp (f :> fs) (s :> ss) = f s :> vapp fs ss
```

I omit the `Functor`

instance (which should be extracted via `fmapDefault`

from the `Traversable`

instance).

Now, there is a `Monad`

instance corresponding to this `Applicative`

, but what is it? *Diagonal thinking! That's what's required!* A vector can be seen as the tabulation of a function from a finite domain, hence the `Applicative`

is just a tabulation of the K- and S-combinators, and the `Monad`

has a `Reader`

-like behaviour.

```
vtail :: forall n x. Vec (S n) x -> Vec n x
vtail (x :> xs) = xs
vjoin :: forall n x. Natty n -> Vec n (Vec n x) -> Vec n x
vjoin Zy _ = V0
vjoin (Sy n) ((x :> _) :> xxss) = x :> vjoin n (fmap vtail xxss)
instance NATTY n => Monad (Vec n) where
return = vcopies natty
xs >>= f = vjoin natty (fmap f xs)
```

You might save a bit by defining `>>=`

more directly, but any way you cut it, the monadic behaviour creates useless thunks for off-diagonal computations. Laziness might save us from slowing down by an armageddon factor, but the zipping behaviour of the `<*>`

is bound to be at least a little cheaper than taking the diagonal of a matrix.