5

(Apology by the title, I can't do better)

My question is to find some generalized struct or "standard" function to perform the next thing:

xmap :: (a -> b) -> f a -> g b

then, we can map not only elements, by also the entire struct.

Some (not real) example

xmap id myBinaryTree :: [a]

at the moment, I must to do a explicit structure conversor (typical fromList, toList) then

toList . fmap id   -- if source struct has map
fmap id . fromList -- if destination struct has map

(to perform toStruct, fromStruct I use fold).

Exists some way to generalize to/from structs? (should be) Exists that function (xmap)?

Thank you!! :)

  • 4
    Is the foldMap is something like what are you looking for? – m0nhawk Jul 24 '13 at 13:52
  • @m0nhawk, looks fine (+1), be monoid is a reasonable restriction, maybe exists some more general? (if not, it would be the solution :) – josejuan Jul 24 '13 at 13:57
  • That's depend on what the a, b, f and g is. I don't think there is something more general. But, you can check Hoogle for more. – m0nhawk Jul 24 '13 at 14:14
  • 1
    Looks like a Profunctor. – phipsgabler Jul 24 '13 at 14:25
  • @joseJuan foldMap is as general as it gets. Just have your target data structure implement Monoid, and most of them already do (like lists). – Gabriel Gonzalez Jul 24 '13 at 18:42
4

I'd like to add to tel's answer (I got my idea only after reading it) that in many cases you can make general natural transformation that will work similarly to foldMap. If we can use foldMap, we know that f is Foldable. Then we need some way how to constructs elements of g a and combine them together. We can use Alternative for that, it has all we need (pure, empty and <|>), although we could also construct some less general type class for this purpose (we don't need <*> anywhere).

{-# LANGUAGE TypeOperators, RankNTypes #-}
import Prelude hiding (foldr)
import Control.Applicative
import Data.Foldable

type f :~> g = forall a. f a -> g a

nt :: (Functor f, Foldable f, Alternative g) => f :~> g
nt = foldr ((<|>) . pure) empty

Then using tel's xmap

xmap :: (a -> b) -> (f :~> g) -> (f a -> g b)
xmap f n = map f . n

we can do things like

> xmap (+1) nt (Just 1) :: [Int]
[2]
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  • Haha—I added a comment on my answer simultaneously with this. Your answer provides much more depth, though. +1 – J. Abrahamson Jul 24 '13 at 19:59
  • Really, all responses are great, I think Petr's answer is the best candidate to be accepted, is practical and closed to theory (although I'd like accept all :D) – josejuan Jul 25 '13 at 6:31
  • @josejuan I'd rather like if you accepted tel's answer - my only builds on his and I wouldn't get the idea without having seen his. – Petr Pudlák Jul 25 '13 at 6:51
  • I was thinking on "first readers", I suggest to you refer @tel response into your answer (to me their "natural..." explanation was illuminating). – josejuan Jul 25 '13 at 7:07
  • Feel free to incorporate any important details from mine to yours. I think it's best to have a maximally comprehensive answer and mine does end shy of the "folding" aspect since there are so many non-folding natural transformations. – J. Abrahamson Jul 25 '13 at 18:49
5

As f and g are functors, a natural transformation is what you're looking for (see also You Could Have Defined Natural Transformations). So a transformation like

f :~> g = forall a. f a -> g a 

is needed to create xmap which is then just

xmap :: (a -> b) -> (f :~> g) -> (f a -> g b)
xmap f n = map f . n

You still need to define types of (f :~> g), but there' not a general way of doing that.

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  • #tel your response close to my search (clarify me a lot... I think :) "natural..."), I'm doubting between your theorical response and @m0nhawk practicals, I can't accept both! :D, thanks a lot to all! :) – josejuan Jul 24 '13 at 19:14
  • Glad this was useful. I'll add quickly that foldMap can be viewed as a natural transformation as well. Define newtype Id a = Id a to be "the most boring functor" and foldMap :: Monoid m => f m -> m is a natural translation (f :~> Id). It implies more than that though since it promises to fold all your values together, while there are plenty of (f :~> Id)s that do nothing interesting. – J. Abrahamson Jul 24 '13 at 19:58
  • Sorry, foldMap :: Monoid m => (a -> m) -> f a -> m isn't quite what you'd need. You need fold :: Monoid m => f m -> m which is like fold :: Monoid m => (f :~> Id) m. – J. Abrahamson Jul 24 '13 at 20:06
  • 1
    Oh, and funny story about "natural". They're called that because they were invented before anything else in category theory. The idea arises as a kind of "natural" thing in algebraic topology that Eilenberg and MacLane wanted to generalize. To do so they invented Functors which needed a place to live, so they focused on and developed Categories. – J. Abrahamson Jul 24 '13 at 20:38
  • Also worth a look: haskell.org/haskellwiki/Category_theory/Natural_transformation – AndrewC Jul 24 '13 at 20:41

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