For the non-native Haskellers here, I've written a Scheme version of this algorithm to make it clearer what's actually happening:

```
> (define (zip lista listb)
((foldr (lambda (el func)
(lambda (a)
(if (empty? a)
empty
(cons (cons el (first a)) (func (rest a))))))
(lambda (a) empty)
lista) listb))
> (zip '(1 2 3 4) '(5 6 7 8))
(list (cons 1 5) (cons 2 6) (cons 3 7) (cons 4 8))
```

The `foldr`

results in a function which, when applied to a list, will return the zip of the list folded over with the list given to the function. The Haskell hides the inner `lambda`

because of lazy evaluation.

To break it down further:

Take zip on input: '(1 2 3)
The foldr func gets called with

```
el->3, func->(lambda (a) empty)
```

This expands to:

```
(lambda (a) (cons (cons el (first a)) (func (rest a))))
(lambda (a) (cons (cons 3 (first a)) ((lambda (a) empty) (rest a))))
```

If we were to return this now, we'd have a function which takes a list of one element
and returns the pair (3 element):

```
> (define f (lambda (a) (cons (cons 3 (first a)) ((lambda (a) empty) (rest a)))))
> (f (list 9))
(list (cons 3 9))
```

Continuing, foldr now calls func with

```
el->3, func->f ;using f for shorthand
(lambda (a) (cons (cons el (first a)) (func (rest a))))
(lambda (a) (cons (cons 2 (first a)) (f (rest a))))
```

This is a func which takes a list with two elements, now, and zips them with `(list 2 3)`

:

```
> (define g (lambda (a) (cons (cons 2 (first a)) (f (rest a)))))
> (g (list 9 1))
(list (cons 2 9) (cons 3 1))
```

What's happening?

```
(lambda (a) (cons (cons 2 (first a)) (f (rest a))))
```

`a`

, in this case, is `(list 9 1)`

```
(cons (cons 2 (first (list 9 1))) (f (rest (list 9 1))))
(cons (cons 2 9) (f (list 1)))
```

And, as you recall, `f`

zips its argument with `3`

.

And this continues etc...