# Readable FoldRight via FoldLeft in Scala

In Functional Programming in Scala, the author asks to express FoldRight via FoldLeft. And then the author offers the following implementation:

``````  def foldRightViaFoldLeftAuthor[A, B](l: List[A], z: B)(f: (A, B) => B): B = {
foldLeft(l, (b: B) => b)((g, a) => b => g(f(a, b)))(z)
}
``````

There have been a couple of questions like this asking to explain the author's solution. And probably a lot of people are still struggling to understand it.

While I was thinking about the task I came up with a different implementation that seems much more readable and easier to grasp at least for me

``````  def foldRightViaFoldLeftMy[A, B](l: List[A], z: B)(f: (A, B) => B): B = {
foldLeft(l, z)(((g: (A, B) => B) => (b: B, a: A) => g(a, b)) (f))
}
``````

So I basically prepare a function that converts `f(a,b)` to `f(b,a)` and now I'm able to call `foldLeft` that is tail-recursive.

So my questions are:

1. Is there any reason to implement it in the way the author did?
2. Are there any drawbacks in my implementation in comparison to the author's?

## 1 Answer

You've written an implementation that has the same signature as `foldRight`, but it doesn't have the right semantics when the combination operation isn't commutative. To take one example, a right fold with the empty list as zero and cons as the combination operation should be identity:

``````scala> val input = List(1, 2, 3)
input: List[Int] = List(1, 2, 3)

scala> val f: (Int, List[Int]) => List[Int] = _ :: _
f: (Int, List[Int]) => List[Int] = \$\$Lambda\$1912/991363637@5e9bf744

scala> foldRightViaFoldLeftAuthor(input, List.empty[Int])(f)
res0: List[Int] = List(1, 2, 3)
``````

But your implementation reverses the list:

``````scala> foldRightViaFoldLeftMy(input, List.empty[Int])(f)
res1: List[Int] = List(3, 2, 1)
``````

This is because you're still folding from left to right, even though you've switched the order of the combination function's arguments. I find the diagrams on the Wikipedia page about `fold` useful for visualizing the difference. In your implementation the applications happen like this:

``````scala> f(3, f(2, f(1, Nil)))
res2: List[Int] = List(3, 2, 1)
``````

While in the book's implementation you have something like this:

``````((b3: List[Int]) =>
((b2: List[Int]) =>
((b1: List[Int]) => identity(f(1, b1)))(f(2, b2)))(f(3, b3)
)
)(Nil)
``````

Which boils down to:

``````scala> f(1, f(2, f(3, Nil)))
res3: List[Int] = List(1, 2, 3)
``````

So the answer to both of your questions is "yes", there is an important difference between your implementation and the book's.