# 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?

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.