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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)

instance Bimonad (,) where
  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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1  
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
2  
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

1 Answer 1

up vote 11 down vote accepted

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 Bifunctors, 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

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