# Where's the functor in the natural transformation?

I've had this question on the very back of my mind ever since I saw the definition of natural transformations in the Edward Kmett's old category-extras package:

``````-- | A natural transformation between functors f and g.
type f :~> g = forall a. f a -> g a
``````

But now reading Stephen Diehl's blog post on adjunctions, I find this:

A natural transformation in our context will be a polymorphic function associated with two Haskell functor instances f and g with type signature (Functor f, Functor g) => forall a. f a -> g a. Which could be written with the following type synonym.

``````type Nat f g = forall a. f a -> g a
``````

Which was a slap in the face of my "I'll continue ignoring this" attitude. So for the question: Why is okay to suddenly drop the functor constraints?

-
When you use `Nat`, you will be supplying types. The type synonym itself makes no use of the fact that they are Functors. Only when you use it does that make a difference, if that makes sense. –  David Young Feb 18 at 0:27
Hmmmm. The `forall` itself reduces the number of non-natural transform functions you can define, even if the Functors in question aren't initially evident/knocking about. –  AndrewC Feb 18 at 0:39
Read the excellent You could have defined natural transformations for a better explanation of the relationship between polymorphism and natural transformations. –  AndrewC Feb 18 at 0:54
I don't quite understand your first comment, even after reading the linked article. Sure, `f` and `g` have to be polymorphic - but that isn't the same as being a functor. What am I missing? And: thanks for the link; a quick read through it didn't settle my doubts, but it does seem very interesting. –  user2141650 Feb 18 at 14:34
@user2141650 Actually, `f` and `g` don't need to be polymorphic (if you're talking about a specific natural transformation). For example, we might talk about the natural transformation `safeHead :: Nat [] Maybe`. `a` must be polymorphic and universally quantified though, for it to be natural. –  David Young Feb 18 at 22:37

Doesn't that only apply to `data` types, not type synonyms? What about the lens type synonyms, for example? –  David Young Feb 18 at 0:54
Actually, now that I think about it, the lens types are a bit different because the Functor type variables are universally quantified. I still suspect that the deprecation you're referring to only applies to `data` types though (maybe `newtype` as well). –  David Young Feb 18 at 1:53
This works just fine for me if I enable `RankNTypes` and `TypeOperators`: `type f :-> g = forall x . (Functor f) => f x -> g x` –  Gabriel Gonzalez Feb 18 at 3:07
@Tarmil I think you have a point (as does David Young in his comments to the question, if I understand him correctly). E.g `test3 natt fn pt = natt \$ fmap fn pt`, where `test3 :: (f :-> g) -> (a -> b) -> f a -> g b`, and (`:->`) is as Gabriel defined it above, doesn't typecheck because it still requires the `Functor f` constraint. So the situation with type synonyms with constraints is in fact similar to that with DatatypeContexts, except that it looks like they haven't been deprecated for some reason, and doesn't even require an extension! –  user2141650 Feb 19 at 0:48