# “Transposition” of functors?

Recently I had to write the following function:

``````mToL :: Maybe [a] -> [Maybe a]
mToL Nothing = []
mToL (Just xs) = map Just xs
``````

This begged the question whether it is possible to generalize the above to:

``````transposeF :: (Functor f, Functor g) => f (g a) -> g (f a)
``````

I guess it only works if there is a way to "collapse" `f (g a)` into `f a`, or is there any other way?

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It's worth noting that this isn't necessarily a symmetric operation—moving `f (g a) -> g (f a)` might be possible without having `g (f a) -> f (g a)`. –  J. Abrahamson Apr 23 at 15:59
The class you want is probably Distributive. –  shachaf Apr 23 at 18:08

Actually, there is a type class that would support this. It's not included in the standard type class but "representable functors" have this capability.

A representative functor is a functor `F` with two things

1. a type `A`
2. An isomorphism between `F` and `(->) A`

We could represent this as

`````` type family ReprObj (f :: * -> *):: *

class Functor f => Repr f where
toHom   :: f a -> (ReprObj f -> a)
fromHom :: (ReprObj f -> a) -> f a
``````

where `toHom . fromHom = fromHom . toHom = id`. An example of a representable functor,

`````` newtype Pair a = Pair (a, a) deriving Functor
type instance ReprObj Pair = Bool

instance Repr Pair where
toHom (Pair (a, b)) True  = a
toHom (Pair (a, b)) False = b
fromHom f = Pair (f True, f False)
``````

Now using this we can derive

``````swap :: (Functor f, Functor g, Repr f, Repr g) => f (g a) -> g (f a)
swap g = fromHom \$ \obj -> fmap (\$ obj) hom
where hom = fmap toHom g
``````

In fact, we can also get a free applicative and monad instance out of representable functors. I detailed how you could do this in a blog post.

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The `Traversable` typeclass provides the `sequence` and `sequenceA` operations, which provide the most general solutions to your problem, but they require different constraints:

``````sequence :: (Traversable t, Monad m) => t (m a) -> m (t a)

sequenceA :: (Traversable t, Applicative f) => t (f a) -> f (t a)
``````
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This is not possible in general, no. Set `f` to `Const b` and `g` to `Identity`.

``````newtype Const b a = Const { getConst :: b }
newtype Identity a = Identity { runIdentity :: a }
``````

These are both obviously functors with their normal instances. `transposeF` can't work because `Const b` doesn't supply any `a`s with which to wrap with Identity. So you can't write the transposition function.

On the other hand, this is nice for a whole lot of Functor pairings. The categorical notion is that of the adjoint functor and once you see them, you'll start seeing them everywhere. They're a very powerful notion in their own right.

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It's not possible to do so using functors simply because there's no generic way to unwrap a functor value:

``````Prelude> :info Functor
class Functor f where
fmap :: (a -> b) -> f a -> f b
(GHC.Base.<\$) :: a -> f b -> f a
-- Defined in `GHC.Base'
instance Functor Maybe -- Defined in `Data.Maybe'
instance Functor (Either a) -- Defined in `Data.Either'
instance Functor [] -- Defined in `GHC.Base'
instance Functor IO -- Defined in `GHC.Base'
instance Functor ((->) r) -- Defined in `GHC.Base'
instance Functor ((,) a) -- Defined in `GHC.Base'
``````

Instead you could create your own typeclass to provide a generic `transpose` function as follows:

``````import Control.Applicative

class Applicative f => Transposable t where
unwrap :: t a -> a
transpose :: s (t a) -> t (s a)
transpose = fmap pure . unwrap
``````

The reason we make `Applicative` a superclass of `Transposable` is so that we can use its `pure` method. All instances of `Applicative` are also instances of `Functor`.

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