I just did this exercise, and would like to share how I arrived at an answer (basically the same as what's in the question, only the letters are different), in the hope that it may be useful to someone.

As background, let's start with what `foldLeft`

and `foldRight`

do. For example, the result of foldLeft on the list [1, 2, 3] with the operation `*`

and starting value `z`

is the value
```
((z * 1) * 2) * 3
```

We can think of foldLeft as consuming values of the list incrementally, left to right. In other words, we initially start with the value `z`

(which is what the result would be if the list were empty), then we reveal to `foldLeft`

that our list starts with 1 and the value becomes `z * 1`

, then `foldLeft`

sees our list next has `2`

and the value becomes `(z * 1) * 2`

, and finally, after acting on 3, it becomes the value `((z * 1) * 2) * 3`

.

```
1 2 3
Initially: z
After consuming 1: (z * 1)
After consuming 2: ((z * 1) * 2
After consuming 3: (((z * 1) * 2) * 3
```

This final value is the value we want to achieve, except (as the exercise asks us) using `foldRight`

instead. Now note that, just as `foldLeft`

consumes values of the list left to right, `foldRight`

consumes values of the list right to left. So on the list [1, 2, 3],

- This foldRight will act on 3 and [something], giving a [result]
- Then it will act on 2 and the [result], giving [result2]
- Finally it will act on 1 and [result2] giving the final expression
- We want our final expression to be
`(((z * 1) * 2) * 3`

In other words: using `foldRight`

, we first arrive at what the result would be if the list were empty, then the result if the list contained only [3], then the result if the list were [2, 3], and finally the result for the list being [1, 2, 3].

That is, these are the values we would like to arrive at, using `foldRight`

:

```
1 2 3
Initially: z
After consuming 3: z * 3
After consuming 2: (z * 2) * 3
After consuming 1: ((z * 1) * 2) * 3
```

So we need to go from `z`

to `(z * 3)`

to `(z * 2) * 3`

to `((z * 1) * 2) * 3`

.

As *values*, we cannot do this: there's no natural way to go from the value `(z * 3)`

to the value `(z * 2) * 3`

, for an arbitrary operation `*`

. (There is for multiplication as it's commutative and associative, but we're only using `*`

to stand for an arbitrary operation.)

But as *functions* we may be able to do this! We need to have a function with a "placeholder" or "hole": something that will take `z`

and put it in the proper place.

- E.g. after the first step (after acting on 3) we have the placeholder function
`z => (z * 3)`

. Or rather, as a function must take arbitrary values and we've been using `z`

for a specific value, let's write this as `t => (t * 3)`

. (This function applied on input `z`

gives the value `(z * 3)`

.)
- After the second step (after acting on 2 and the result) we have the placeholder function
`t => (t * 2) * 3`

maybe?

Can we go from the first placeholder function to the next? Let

```
f1(t) = t * 3
and f2(t) = (t * 2) * 3
```

What is `f2`

in terms of `f1`

?

```
f2(t) = f1(t * 2)
```

Yes we can! So the function we want takes `2`

and `f1`

and gives `f2`

. Let's call this `g`

. We have `g(2, f1) = f2`

where `f2(t) = f1(t * 2)`

or in other words

```
g(2, f1) =
t => f1(t * 2)
```

Let's see if this would work if we carried it forward: the next step would be `g(1, f2) = (t => f2(t * 1))`

and the RHS is same as `t => f1((t * 1) * 2))`

or `t => (((t * 1) * 2) * 3)`

.

Looks like it works! And finally we apply `z`

to this result.

What should the initial step be? We apply `g`

on `3`

and `f0`

to get `f1`

, where `f1(t) = t * 3`

as defined above but also `f1(t) = f0(t * 3)`

from the definition of `g`

. So looks like we need `f0`

to be the identity function.

Let's start afresh.

```
Our foldLeft(List(1, 2, 3), z)(*) is ((z * 1) * 2) * 3
Types here: List(1, 2, 3) is type List[A]
z is of type B
* is of type (B, A) -> B
Result is of type B
We want to express that in terms of foldRight
As above:
f0 = identity. f0(t) = t.
f1 = g(3, f0). So f1(t) = f0(t * 3) = t * 3
f2 = g(2, f1). So f2(t) = f1(t * 2) = (t * 2) * 3
f3 = g(1, f2). So f3(t) = f2(t * 1) = ((t * 1) * 2) * 3
```

And finally we apply f3 on z and get the expression we want. Everything works out. So

```
f3 = g(1, g(2, g(3, f0)))
```

which means f3 = `foldRight(xs, f0)(g)`

Let's define `g`

, this time instead of `x * y`

using an arbitrary function `s(x, y)`

:

Putting all this together

```
def foldLeft[A, B](xs: List[A], z: B)(s: (B, A) => B): B = {
val f0 = (b: B) => b
def g(a: A, f: B=>B): B=>B =
t => f(s(t, a))
foldRight(xs, f0)(g)(z)
}
```

At this level of working through the book, I actually prefer this form as it's more explicit and easier to understand. But to get closer to the form of the solution, we can inline the definitions of `f0`

and `g`

(we no longer need to declare the type of `g`

as it's input to `foldRight`

and the compiler infers it), giving:

```
def foldLeft[A, B](xs: List[A], z: B)(s: (B, A) => B): B =
foldRight(xs, (b: B) => b)((a, f) => t => f(s(t, a)))(z)
```

which is exactly what is in the question, just with different symbols. Similarly for foldRight in terms of foldLeft.

`myFoldl f z xs = foldr step id xs z where step x g a = g (f a x)`

– Hugo Sereno Ferreira Sep 21 '13 at 14:18