Yes!

We can view `[a]`

as a free monad instance `Free ((,) a) ()`

.

Thus we can apply the scheme described by Edward Kmett in Free Monads for Less.

The type we'll get is

```
newtype F a = F { runF :: forall r. (() -> r) -> ((a, r) -> r) -> r }
```

or simply

```
newtype F a = F { runF :: forall r. r -> (a -> r -> r) -> r }
```

So `runF`

is nothing else than the `foldr`

function for our list!

This is called the Boehm-Berarducci encoding and it's isomorphic to the original data type (list) — so this is as small as you can possibly get.

Will Ness says:

So this type is still too "wide", it allows more than just prefixing - doesn't constrain the g function argument.

If I understood his argument correctly, he points out that you can apply the `foldr`

(or `runF`

) function to something different from `[]`

and `(:)`

.

But I never claimed that you can use `foldr`

-encoding only for concatenation. Indeed, as this name implies, you can use it to calculate *any* fold — and that's what Will Ness demonstrated.

It may become more clear if you forget for a moment that there's one true list type, `[a]`

. There may be lots of list types — e.g. I can define one by

```
data List a = Nil | Cons a (List a)
```

It's be different from, but isomorphic to `[a]`

.

The `foldr`

-encoding above is just yet another encoding of lists, like `List a`

or `[a]`

. It is also isomorphic to `[a]`

, as evidenced by functions `\l -> F (\a f -> foldr a f l)`

and `\x -> runF [] (:)`

and the fact that their compositions (in either order) is identity. But you are not obliged to convert to `[a]`

— you can convert to `List`

directly, using `\x -> runF x Nil Cons`

.

The important point is that `F a`

doesn't contain an element that is not the `foldr`

functions for some list — nor does it contain an element that is the `foldr`

functions for more than one list (obviously).

Thus, it doesn't contain too few or too many elements — it contains precisely as many elements as needed to exactly represent all lists.

This is not true of the difference list encoding — for example, the `reverse`

function is not an append operation for any list.