Untested. Note that the `append-list`

procedure I defined actually returns a list ending in `sos2`

. That is appropriate (and the right thing to do) here, but is not in general.

```
(define cart-product
(lambda (sos1 sos2)
(if (null? sos1) '()
(append-list
(cart-prod-sexpr (car sos1) sos2)
(cart-product (cdr sos1) sos2)))))
(define cart-prod-sexpr
(lambda (s sos)
(if (null? sos) '()
(cons
(list s (car sos))
(cart-prod-sexpr s (cdr sos))))))
(define append-list
(lambda (sos1 sos2)
(if (null? sos1) sos2
(cons
(car sos1)
(append-list (cdr sos1) sos2)))))
```

Note that if the lists are of size n then this will take time O(n^{3}) to produce a list of size O(n^{2}). ~~Using regular ~~`append`

would take O(n^{4}) instead. *I just implemented the regular *`append`

without realizing it. If you want to take O(n^{2}) you have to be more clever. As in this untested code.

```
(define cart-product
(lambda (sos1 sos2)
(let cart-product-finish
(lambda (list1-current list2-current answer-current)
(if (null? list2-current)
(if (null? list1-current)
answer-current
(cart-product-finish (car list1-current) sos2 answer-current))
(cart-product-finish list1-current (car sos2)
(cons (cons (cdr list1-current) (cdr list2-current)) answer-current))))
(cart-product-finish list1 '() '())))
```

In case I have a bug, the idea is to recursively loop through all combinations of elements in the first and the second, with each one replacing `answer-current`

with a `cons`

with one more combination, followed by everything else we have found already. Thanks to tail-call optimization, this should be efficient.