Haskell's `Data.Bifunctor` is basically:

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

I could find a `Biapply` as well. My question is, why isn't there a complete bi-hierarchy (bierarchy?) like:

``````class Bifunctor f => Biapplicative f where
bipure :: a -> b -> f a b
biap :: f (a -> b) (c -> d) -> f a c -> f b d

class Biapplicative m => Bimonad m where
bibind :: m a b -> (a -> b -> m c d) -> m c d

bireturn :: a -> b -> m a b
bireturn = bipure

bilift :: Biapplicative f => (a -> b) -> (c -> d) -> f a c -> f b d
bilift f g = biap \$ bipure f g

bilift2 :: Biapplicative f => (a -> b -> c) -> (x -> y -> z) -> f a x -> f b y -> f c z
bilift2 f g = biap . biap (bipure f g)
``````

Pair is an instance of these:

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

instance Biapplicative (,) where
bipure x y = (x,y)
biap (f,g) (x,y) = (f x, g y)

bibind (x,y) f = f x y
``````

And types like...

``````data Maybe2 a b = Fst a | Snd b | None
--or
data Or a b = Both a b | This a | That b | Nope
``````

...would IMO have instances as well.

Are there not enough matching types? Or is something concerning my code deeply flawed?

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How would you define `bipure` for `Maybe2 a b`? Neither `Fst` nor `Snd` is canonical, leaving `None`, which is hardly useful. I reckon most nontrivial candidate types for these classes have similar problems, but it's just a guess. At least `Or` looks reasonable. Good question. –  leftaroundabout Nov 25 '12 at 23:00
Also, how would you define `bijoin`? –  hammar Nov 26 '12 at 0:03
From practical point of view, I'd say the reason why these type classes are not used is that they have very little interesting instances. Consider how many instances `Bifunctor` has. Then `Biapplicative` or `Bimonad` would have even less (possible 0). Other than that, it's certainly an interesting question. Have you tried to construct some complete instances of those suggested type classes? –  Petr Pudlák Nov 26 '12 at 12:21

A monad in category theory is an endofunctor, i.e. a functor where the domain and codomain is the same category. But a `Bifunctor` is a functor from the product category `Hask x Hask` to `Hask`. But we could try to find out what a monad in the `Hask x Hask` category looks like. It is a category where objects are pairs of types, i.e. `(a, b)`, and arrows are pairs of functions, i.e. an arrow from `(a, b)` to `(c, d)` has type `(a -> c, b -> d)`. An endofunctor in this category maps pairs of types to pairs of types, i.e. `(a, b)` to `(l a b, r a b)`, and pairs of arrows to pairs of arrows, i.e.

``````(a -> c, b -> d) -> (l a b -> l c d, r a b -> r c d)
``````

If you split this map function in 2, you'll see that an endofunctor in `Hask x Hask` is the same as two `Bifunctor`s, `l` and `r`.

Now for the monad: `return` and `join` are arrows, so in this case both are 2 functions. `return` is an arrow from `(a, b)` to `(l a b, r a b)`, and `join` is an arrow from `(l (l a b) (r a b), r (l a b) (r a b))` to `(l a b, r a b)`. This is what it looks like:

``````class (Bifunctor l, Bifunctor r) => Bimonad l r where
bireturn :: (a -> l a b, b -> r a b)
bijoin :: (l (l a b) (r a b) -> l a b, r (l a b) (r a b) -> r a b)
``````

Or separated out:

``````class (Bifunctor l, Bifunctor r) => Bimonad l r where
bireturnl :: a -> l a b
bireturnr :: b -> r a b
bijoinl :: l (l a b) (r a b) -> l a b
bijoinr :: r (l a b) (r a b) -> r a b
``````

And similar to `m >>= f = join (fmap f m)` we can define:

``````  bibindl :: l a b -> (a -> l c d) -> (b -> r c d) -> l c d
bibindl lab l r = bijoinl (bimap l r lab)
bibindr :: r a b -> (a -> l c d) -> (b -> r c d) -> r c d
bibindr rab l r = bijoinr (bimap l r rab)
``````
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PS. Your `Biapplicative` class is correct I think. Biapplicative functors seem to match monoidal functors from `Hask x Hask` to `Hask`. –  Sjoerd Visscher Nov 27 '12 at 12:05