The situation is as follows (I changed to more standard-ish Haskell notation):

```
class Functor f => MonoidallyCopointed f where
copointAppend :: (∀r.f(r)->r) -> (∀r.f(r)->r) -> (∀r.f(r)->r)
copointEmpty :: ∀r.f(r)->r
```

such that for all instance F of `MonoidallyCopointed`

and for all

```
x,y,z::∀r.F(r)->r
```

The following holds:

```
x `copointAppend` copointEmpty == copointEmpty `copointAppend` x == x
x `copointAppend` (y `copointAppend` z) == (x `copointAppend` y) `copointAppend` z
```

Then is it true that F has a natural `Comonad`

instance defined from `copointAppend`

and `copointEmpty`

?

N.B. The converse holds (with `copointEmpty = extract`

and `copointAppend f g = f . g . duplicate`

.)

EDIT

As Bartosz pointed out in the comment, this is mostly the definition of comonads using the co-Kleisli adjunction. So the question is really about the constructivity of this notion. Accordingly, the following question is probably more interesting in terms of real-world applications:

Does there exist a constructive isomorphism between the set of possible `Comonad`

instances of f and the set of possible `MonoidallyCopointed`

instances of f?

This can be useful in practice because a direct definition of `Comonad`

instance can involve a bit of
technical, hard-to-read code that cannot be verified by the type checker. For example,

```
data W a = W (Maybe a) (Int -> a) (Either (String -> a) (a,a,a,a))
```

has a Comonad instance but the direct definition (with the proof that it's indeed a Comonad!) may not be so easy.
On the other hand, providing a `MonoidallyCopointed`

instance may be a little easier (but I'm not perfectly
sure of this point).

`e`

seems to be a natural fit for the unit. Do you have an idea how you might define, uh, comultiplcation?`f(r) -> f(f(r))`

– luqui Dec 28 '16 at 8:57`<*>`

? – leftaroundabout Dec 28 '16 at 13:46`⊗`

would be a problem. Nevertheless something ASCII like, whatever,`>*<`

might be preferrable for compatibility. – leftaroundabout Dec 29 '16 at 15:17