To clarify upon what others have mentioned, consider the following type for non-empty lists:

```
data NonEmptyList a = One a | Many a (NonEmptyList a)
map :: (a -> b) -> NonEmptyList a -> NonEmptyList b
map f (One x) = One (f x)
map f (Many x xs) = Many (f x) (map f xs)
(++) :: NonEmptyList a -> NonEmptyList a -> NonEmptyList a
One x ++ ys = Many x ys
Many x xs ++ ys = Many x (xs ++ ys)
tails :: NonEmptyList a -> NonEmptyList (NonEmptyList a)
tails l@(One _) = One l
tails l@(Many _ xs) = Many l (tails xs)
```

You *can* write a valid comonad instance as follows:

```
instance Functor NonEmptyList where
fmap = map
instance Comonad NonEmptyList where
coreturn (One x) = x
coreturn (Many x xs) = x
cojoin = tails
-- this should be a default implementation
x =>> f = fmap f (cojoin x)
```

Let's prove the laws listed by hammar. I'll take the liberty of eta-expanding each one as a given first step.

Law 1.

```
(coreturn . cojoin) xs = id xs
-- definition of `.`, `cojoin`, and `id`
(coreturn (tails xs) = xs
-- case on xs
-- assume xs is (One x)
(coreturn (tails (One x))) = One x
-- definition of tails
(coreturn (One (One x))) = One x
-- definition of coreturn
One x = One x
-- assume xs is (Many y ys)
(coreturn (tails (Many y ys))) = Many y ys
-- definition of tails
(coreturn (Many (Many y ys) (tails ys)) = Many y ys
-- definition of coreturn
Many y ys = Many y ys
-- assume xs is _|_
(coreturn (tails _|_)) = _|_
-- tails pattern matches on its argument
(coreturn _|_) = _|_
-- coreturn pattern matches on its argument
_|_ = _|_
```

Law 2.

```
(fmap coreturn . cojoin) xs = id xs
-- definition of `.`, `cojoin`, `fmap`, and `id`
map coreturn (tails xs) = xs
-- case on xs
-- assume xs is (One x)
map coreturn (tails (One x)) = One x
-- defn of tails
map coreturn (One (One x)) = One x
-- defn of map
One (coreturn (One x)) = One x
-- defn of coreturn
One x = One x
-- assume xs is (Many y ys)
map coreturn (tails (Many y ys)) = Many y ys
-- defn of tails
map coreturn (Many (Many y ys) (tails ys)) = Many y ys
-- defn of map
Many (coreturn (Many y ys)) (map coreturn (tails ys)) = Many y ys
-- defn of coreturn
Many y (map coreturn (tail ys)) = Many y ys
-- eliminate matching portions
map coreturn (tail ys) = ys
-- wave hands.
-- If the list is not self-referential,
-- then this can be alleviated by an inductive hypothesis.
-- If not, then you can probably prove it anyways.
-- assume xs = _|_
map coreturn (tails _|_) = _|_
-- tails matches on its argument
map coreturn _|_ = _|_
-- map matches on its second argument
_|_ = _|_
```

Law 3.

```
(cojoin . cojoin) xs = (fmap cojoin . cojoin) xs
-- defn of `.`, `fmap`, and `cojoin`
tails (tails xs) = map tails (tails xs)
-- case on xs
-- assume xs = One x
tails (tails (One x)) = map tails (tails (One x))
-- defn of tails, both sides
tails (One (One x)) = map tails (One (One x))
-- defn of map
tails (One (One x)) = One (tails (One x))
-- defn of tails, both sides
One (One (One x)) = One (One (One x))
-- assume xs = Many y ys
(this gets ugly. left as exercise to reader)
-- assume xs = _|_
tails (tails _|_) = map tails (tails _|_)
-- tails matches on its argument
tails _|_ = map tails _|_
-- tails matches on its argument, map matches on its second argument
_|_ = _|_
```

`coreturn`

. What happens if the list is empty? – C. A. McCann Sep 21 '12 at 19:47`Monad`

instance for`(,) a`

without any other constraints for similar reasons--where would`return`

find something of an arbitrary type? Anyway, try non-empty lists and/or infinite streams instead. – C. A. McCann Sep 21 '12 at 20:00`cojoin`

has always been defined analogously to`tails`

. – dave4420 Sep 21 '12 at 20:20`tails`

, but notquite`tails`

.`tails`

adds one element to the list, you need to basically do everything that tails does except add the final empty list, which if you think about it should make sense, as a.) the empty list wouldn't be a legal comonadic value, and b.) comonadic actions shouldn't change the number of elements. =) – Edward KMETT Sep 22 '12 at 0:27