# Is it possible to define foldr using map?

After I defined `map` using `foldr` a question came to my mind:

If it is possible to define `map` using `foldr`, what about the opposite?

From my point of view it is not possible, but I can't find a proper explanation. Thanks for the help!

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`map` outputs a list of the same length it gets. `foldr` can output a list of any length, or something that is not a list at all. –  n.m. May 24 '14 at 22:25
Somewhat relevant: web.jaguarpaw.co.uk/~tom/blog/posts/… –  Tom Ellis May 24 '14 at 22:52
You have to be a little more specific. Note that it's possible to define `foldr` without using anything but pattern matching, so you certainly can define it using pattern matching and `map`. –  Piotr Miś May 24 '14 at 22:55

``````foldr :: (a -> b -> b) -> b -> [a] -> b
map :: (a -> b) -> [a] -> [b]
``````

We can simulate `map` using `fold` because `fold` is a universal operator (here's a more mathematical yet quite friendly paper on this property).

I'm sure that there's some creative way of using `map` to simulate `foldr`. That can certainly be a fun exercise. But I don't think there's a straight-forward, not "crazy pointfree" solution, and in order to explain it let's forget about `foldr` for a moment and concentrate on a much simpler accumulation function:

``````sum :: [Int] -> Int
``````

`sum == foldr (+) 0`, which means `foldr` implements `sum`. If we can implement `foldr` with `map` we can definitely implement `sum` with `map`. Can we do it?

I think `sum`'s signature is a crashing blow - `sum` returns an `Int`, and `map` always returns a list of something. So maybe `map` can do the heavy-lifting, but we'll still need another function of type `[a] -> a` in order to get the final result. In our case, we'll need a function of type `[Int] -> Int`. Which is quite unfortunate, because that's exactly what we were trying to avoid in the first place.

So I guess the answer is: you can implement `foldr` using `map` - but it'll probably require using `foldr` :)

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In short, no :) –  John L May 25 '14 at 2:53
While reading this I couldn't stop thinking "Curry-Howard strikes again" ;-) –  chi May 25 '14 at 19:40

The simplest way to look at it is to see that `map` preserves the spine of the list. If you look at the more general fmap (which is map, but not just for lists but for `Functor`s in general), it's even a law that

``````fmap id = id
``````

There are many ways to "cheat," but in the most direct interpretation of your question, folds are simply more general than maps. There is a nice trick that's used in Edward Kmett's Lens library quite a lot. Consider the `Const` monad, which is defined as follows:

``````newtype Const a b = Const { runConst :: a }

instance Functor (Const a) where fmap _ (Const a) = Const a
instance (Monoid a) => Monad (Const a) where
return _ = Const mempty
Const a >>= Const b = Const (a <> b)
``````

Now you can formulate a fold in terms of the monadic map operation `mapM`, as long as the result type is monoidal:

``````fold :: Monoid m => [m] -> m
fold = runConst . mapM Const
``````
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Of course, this is still just a fold. It's just had the combiner and zero elements distributed through the monoid. –  J. Abrahamson May 25 '14 at 2:28

If you make some sort of cheating helper function:

``````f [x] a = x a
f (x:xs) a = f xs (x a)

foldr g i xs = f (map g \$ reverse xs) i
``````
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