The answer had already been given here, but not an (illustrative) derivation. So even after all these years, perhaps it's worth adding it.

It is actually quite simple. First,

foldr f z xs
= foldr f z [x1,x2,x3,...,xn] = f x1 **(foldr f z [x2,x3,...,xn])**
= ... = f x1 **(f x2 (f x3 (... (f xn z) ...)))**

hence by eta-expansion,

foldr f z xs ys
= foldr f z [x1,x2,x3,...,xn] ys = f x1 (foldr f z [x2,x3,...,xn]) ys
= ... = f x1 **(f x2 (f x3 (... (f xn z) ...)))** ys

As is apparent here, *if *`f`

is non-forcing in its 2nd argument, it gets to work *first* on `x1`

and `ys`

, `f x1`

`r1`

`ys`

where `r1 =`

`(f x2 (f x3 (... (f xn z) ...)))`

`= foldr f z [x2,x3,...,xn]`

.

So, using

f x1 **r1** [] = []
f x1 **r1** (y1:ys1) = (x1,y1) : **r1** ys1

we arrange for passage of information *left-to-right* along the list, by *calling* `r1`

with the *rest* of the input list `ys1`

, `foldr f z [x2,x3,...,xn]`

`ys1 = f x2`

`r2`

`ys1`

, as the next step. And that's that.

When `ys`

is shorter than `xs`

(or the same length), the `[]`

case for `f`

fires and the processing stops. But if `ys`

is longer than `xs`

then `f`

's `[]`

case won't fire and we'll get to the final `f xn`

`z`

`(yn:ysn)`

application,

f xn **z** (yn:ysn) = (xn,yn) : **z** ysn

Since we've reached the end of `xs`

, the `zip`

processing must stop:

**z** _ = []

And this means the definition `z = const []`

should be used:

```
zip xs ys = foldr f (const []) xs ys
where
f x r [] = []
f x r (y:ys) = (x,y) : r ys
```

From the standpoint of `f`

, `r`

plays the role of a *success continuation*, which `f`

calls when the processing is to continue, after having emitted the pair `(x,y)`

.

So `r`

is *"what to do with the next *`x`

", and `z = const []`

, the `nil`

-case in `foldr`

, is *"what to do when there are no more *`x`

s". Or `f`

can stop by itself, returning `[]`

when `ys`

is exhausted.

Notice how `ys`

is used as a kind of accumulating value, which is passed from left to right along the list `xs`

, from one invocation of `f`

to the next ("accumulating" step being, here, stripping a head element from it).

Naturally this corresponds to the left fold, where an accumulating step is "applying the function", with `z = id`

returning the final accumulated value when "there are no more `x`

s":

```
foldl f a xs =~ foldr (\x r a-> r (f a x)) id xs a
```

Similarly, for finite lists,

```
foldr f a xs =~ foldl (\r x a-> r (f x a)) id xs a
```

And since the combining function gets to decide whether to continue or not, it is now possible to have left fold that can stop early:

```
foldlWhile t f a xs = foldr cons id xs a
where
cons x r a = if t x then r (f a x) else a
```

or a skipping left fold, `foldlWhen t ...`

, with

```
cons x r a = if t x then r (f a x) else r a
```

etc.