Because a `Functor`

is a very general kind of object; not all `Functor`

s support folds. For example, there is an instance^{1}

```
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.

`fold`

on`IO`

, which is a`Functor`

, but not`Foldable`

? – Zeta Jul 30 '15 at 13:33`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`fmap`

in my post was a typo. I mean`map`

. – akonsu Jul 30 '15 at 14:01