The answer was given (some years back, too), but not an (illustrative) derivation. So even after all this years, perhaps it'll be beneficial to add 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** (y:ys1) = (x,y) : **r1** ys1

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

with the *rest* of 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`

the `[]`

case for `f`

fires up and the processing stops. But if `ys`

is longer then `xs`

the `[]`

case won't fire up and we'll arrive at 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 x1 r1 [] = []
f x1 r1 (y:ys1) = (x,y) : r1 ys1
```

which is what the others got, up to arguments renaming.

As a bonus, similar considerations give us

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