# Why does fold left expect (a -> b -> a) instead of (b -> a -> a)?

I wonder why the function expected by fold left has type signature `a -> b -> a` instead of `b -> a -> a`. Is there a design decision behind this?

In Haskell, for example, I have to write `foldl (\xs x -> x:xs) [] xs` to reverse a list instead of the shorter `foldl (:) [] xs` (which would be possible with `b -> a -> a`). On the other hand, there are use cases which require the standard `a -> b -> a`. In Scala, this could be appending: `xs.foldLeft(List.empty[Int]) ((xs, x) => xs:+x)` which can be written as `xs.foldLeft(List.empty[Int]) (_:+_)`.

Do proportionately more use cases occur requiring the given type signature instead of the alternative one, or are there other decisions which led to the design that fold left has in Haskell and Scala (and probably lots of other languages)?

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In other words, you have to reverse the argument order of `(:)` in order to reverse a list. Makes sense to me. –  C. A. McCann Sep 5 '12 at 20:01
Note that `mapAccumL` and `mapAccumR` (from `Data.List` / `Data.Traversable`) have the same signature, though they also work in opposite directions. –  leftaroundabout Sep 6 '12 at 10:04

Conceptually speaking, a right fold, say `foldr f z [1..4]` replaces a list of the following form

``````  :
/ \
1   :
/ \
2   :
/ \
3   :
/ \
4  []
``````

with the value of an expression of the following form

``````  f
/ \
1   f
/ \
2   f
/ \
3   f
/ \
4   z
``````

If we were to represent this expression on a single line, all parentheses would associate to the right, hence the name right fold: `(1 `f` (2 `f` (3 `f` (4 `f` z))))`. A left fold is dual in some sense to a right fold. In particular, we would like for the shape of the corresponding diagram for a left fold to be a mirror image of that for a left fold, as in the following:

``````        f
/ \
f   4
/ \
f   3
/ \
f   2
/ \
z   1
``````

If we were to write out this diagram on a single line, we would get an expression where all parentheses associate to the left, which jibes well with the name of a left fold:

``````((((z `f` 1) `f` 2) `f` 3) `f` 4)
``````

But notice that in this mirror diagram, the recursive result of the fold is fed to `f` as the first argument, while each element of the list is fed as the second argument, ie the arguments are fed to `f` in reverse order compared to right folds.

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The type signature is `foldl :: (a -> b -> a) -> a -> [b] -> a`; it's natural for the combining function to have the initial value on the left, because that's the way it combines with the elements of the list. Similarly, you'll notice `foldr` has it the other way round. The complication in your definition of reverse is because you're using a lambda expression where `flip` would have been nicer: `foldl (flip (:)) [] xs`, which also has the pleasant similarity between the concepts of flip and reverse.

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Because you write `(a /: bs)` for `foldLeft` in short form; this is an operator which pushes `a` through all the `bs`, so it is natural to write the function the same way (i.e. `(A,B) => A`). Note that `foldRight` does it in the other order.

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Nice, but that will only explain it for Scala not in Haskell which doesn't has `/:`. –  sschaef Sep 5 '12 at 20:13

Say you have this:

``````List(4, 2, 1).foldLeft(8)(_ / _)
``````

That's the same as:

``````((8 / 4) / 2) / 1
``````

See how the first parameter is always te accumulator? Having the parameters in this order makes placeholder syntax (the underscore) a direct translation to the expanded expression.

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