I think you're overthinking it slightly. A bifunctor is just like a two-parameter functor. Gibbons and Oliveira's idea is just one application of bifunctors, just like the standard zoo of recursion schemes is just one application of functors.

```
class Bifunctor f where
bimap :: (a -> c) -> (b -> d) -> f a b -> f c d
```

`Bifunctor`

s have a kind of `* -> * -> *`

and both parameters can be covariantly mapped over. Compare this to regular `Functor`

s, which have only one parameter (`f :: * -> *`

) which can be covariantly mapped over.

For example, think about `Either`

's usual `Functor`

instance. It only allows you to `fmap`

over the second type parameter - `Right`

values get mapped, `Left`

values stay as they are.

```
instance Functor (Either a) where
fmap f (Left x) = Left x
fmap f (Right y) = Right (f y)
```

However, its `Bifunctor`

instance allows you to map both halves of the sum.

```
instance Bifunctor Either where
bimap f g (Left x) = Left (f x)
bimap f g (Right y) = Right (g y)
```

Likewise for tuples: `(,)`

's `Functor`

instance allows you to map only the second component, but `Bifunctor`

allows you to map both parts.

```
instance Functor ((,) a) where
fmap f (x, y) = (x, f y)
instance Bifunctor (,) where
bimap f g (x, y) = (f x, g y)
```

Note that `Maybe`

, which you mentioned, doesn't fit into the framework of bifunctors because it has only one parameter.

On the question of `Fix`

, the fixed point of a bifunctor allows you to characterise recursive types which have a functorial type parameter, such as most container-like structures. Let's use lists as an example.

```
newtype Fix f = Fix { unFix :: f (Fix f) }
data ListF a r = Nil_ | Cons_ a r deriving Functor
type List a = Fix (ListF a)
```

Using the standard functorial `Fix`

, as I have above, there's no generic derivation of an instance of `Functor`

for `List`

, because `Fix`

doesn't know anything about `List`

's `a`

parameter. That is, I can't write anything like `instance Something f => Functor (Fix f)`

because `Fix`

has the wrong kind. I have to hand-crank a `map`

for lists, perhaps using `cata`

:

```
map :: (a -> b) -> List a -> List b
map f = cata phi
where phi Nil_ = Fix Nil_
phi Cons_ x r = Fix $ Cons_ (f x) r
```

The bifunctorial version of `Fix`

does permit an instance of `Functor`

. `Fix`

uses one of the bifunctor's parameters to plug in the recursive occurrence of `Fix f a`

and the other one to stand in for the resultant datatype's functorial parameter.

```
newtype Fix f a = Fix { unFix :: f a (Fix f a) }
instance Bifunctor f => Functor (Fix f) where
fmap f = Fix . bimap f (fmap f) . unFix
```

So we can write:

```
deriveBifunctor ''ListF
type List = Fix ListF
```

and get the `Functor`

instance for free:

```
map :: (a -> b) -> List a -> List b
map = fmap
```

Of course, if you want to work generically with recursive structures with more than one parameter then you need to generalise to tri-functors, quad-functors, etc... This is clearly not sustainable, and plenty of work (in more advanced programming languages) has been put into designing more flexible systems for characterising types.