Why does the type class Functor have only the memberfmap? I often find it useful to perform a fold over datatypes. Say, hierarchical ones, like a tree.

Note that a map is a special case of fold, that is, the latter is more fundamental. I guess I can take it the way it is, but maybe there is a reason?

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    How would you define fold on IO, which is a Functor, but not Foldable? – Zeta Jul 30 '15 at 13:33
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    How is fmap a special case of fold? I can't imagine how you would be able to implement either in terms of the other, which is what I think of when I think of "more fundamental". – Dietrich Epp Jul 30 '15 at 13:47
  • the fmap in my post was a typo. I mean map. – akonsu Jul 30 '15 at 14:01

Because a Functor is a very general kind of object; not all Functors support folds. For example, there is an instance1

instance Functor (a ->) where
     -- > fmap :: (b -> c) -> (a -> b) -> (a -> c)
     fmap f g = g . f

But, while (a ->) is a Functor for all a, for infinite a there isn't a reasonable fold definition. (Incidentally, a 'fold' in general is a catamorphism, which means it has a different type for each functor. The Foldable type class defines it for sequence-like types.).

Consider what the foldr definition for Integer -> Integer would look like; what would the outermost application be? What would the value of

foldr (\ _ n -> 1 + n) 0 (\ n -> n + 1)

be? There isn't a reasonable definition of fold without a lot more structure on the argument type.

1 (a ->) isn't legal Haskell for some reason. But I'm going to use it anyway as a more readable version of (->) a, since I think it's easier for a novice to understand.

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    I think I see where I was wrong: map is a special case of fold only for lists (maybe for something else) but not in general. Thanks. – akonsu Jul 30 '15 at 14:39
  • Yeah, fold is way more powerful on lists than on other types (especially something like arbitrary trees). Formally (ignoring laziness), the list functor is the free monoid functor, which is the left adjoint of the forgetful functor from monoids to sets; the general fold function is then one direction of the hom-set adjunction between the list functor and the forgetful functor. As such, every monoid homomorphism on lists (which includes map) is given by some instance of fold. – Jonathan Cast Nov 13 '17 at 16:29

The abstraction you are looking for is Foldable: This is a type class providing variuos forms of fold.

There is also Traversable for things where you can “fold while changing”, comparable to the mapAccumL function for lists.

It is actually not true that fmap is a special case of fold, as pointed out by @DietrichEpp, see as here are possible non-Functor instances of Foldable.

map is however a special case of mapAccumL (no surprise, given the name), and hence the definition of Traversable requires the thing to be also a Functor and a Foldable.

  • thanks. this is interesting. I am a beginner, I vaguely understand what you are saying. in general, though, it seems confusing that a Functor is not necessarily a Foldable. Given that map is defined in terms of fold... – akonsu Jul 30 '15 at 13:37
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    That's exactly the reason, though: if fold were defined in terms of map, then we could define fold for every Functor, since we could use the existing map to get fold for free. – Lynn Jul 30 '15 at 13:40
  • @DietrichEpp's hinting the right thing; there are possible non-Functor instances of Foldable. – Lynn Jul 30 '15 at 13:47
  • Sorry, confused fold with traverse; fixed the answer accordingly. – Joachim Breitner Jul 30 '15 at 13:52

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