Taking a cue from your remark about factorials, we can note that natural numbers can be treated as a recursive data structure:

```
data Nat = Zero | Succ Nat
```

In terms of the *recursion-schemes* machinery, the corresponding base functor would be:

```
data NatF a = ZeroF | SuccF a
deriving (Functor)
```

`NatF`

, however, is isomorphic to `Maybe`

. That being so, *recursion-schemes* conveniently makes `Maybe`

the base functor of the `Natural`

type from *base*. For instance, here is the type of `ana`

specialised to `Natural`

:

```
ana @Natural :: (a -> Maybe a) -> a -> Natural
```

We can use it to write the identity unfold for `Natural`

:

```
{-# LANGUAGE LambdaCase #-}
import Numeric.Natural
import Data.Functor.Foldable
idNatAna :: Natural -> Natural
idNatAna = ana $ \case
0 -> Nothing
x -> Just (x - 1)
```

The coalgebra we just gave to `ana`

is `project`

for `Natural`

, `project`

being the function that unwraps one layer of the recursive structure. In terms of the *recursion-schemes* vocabulary, `ana project`

is the identity unfold, and `cata embed`

is the identity fold. (In particular, `project`

for lists is `uncons`

from `Data.List`

, except that it is encoded with `ListF`

instead of `Maybe`

.)

By the way, the factorial function can be expressed as a paramorphism on naturals (as pointed out in the note at the end of this question). We can also implement that in terms of *recursion-schemes*:

```
fact :: Natural -> Natural
fact = para $ \case
Nothing -> 1
Just (predec, prod) -> prod * (predec + 1)
```

`para`

makes available, at each recursive step, the rest of the structure to be folded (if we were folding a list, that would be its tail). In this case, I have called the value thus provided `predec`

because at the `n`

-th recursive step from bottom to top `predec`

is `n - 1`

.

Note that user11228628's hylomorphism is probably a more efficient implementation, if you happen to care about that. (I haven't benchmarked them, though.)

`foldr (:) []`

is`unfoldr uncons`

. But what kind of`Int -> Int`

function are you looking for? There's no structure there to construct, destruct, or otherwise recurse over.`hylo`

morphism; are you asking for how exactly to do that? That question seems unrelated to whether unfoldl/r can be used to define the identity function, since factorial isn't the identity function.3more comments