Let's look at the example of `(compare? '(1 x 2 x 3 x 4))`

.

You want to ensure that `(compare? '(2 x 3 x 4))`

is true, and that the `1 x`

before that also matches.

That then means that you want to ensure that `(compare? '(3 x 4))`

is true (which it is, by definition), and that the `2 x`

before that also matches.

Notice how we are working with smaller and smaller lists each time. We can do that because lists have structural induction. Because of structural induction, you don't actually have to know the length of the list. The algorithm just works on smaller and smaller sublists until it hits a base case.

Sample skeletal solution (fill in the `<???>`

with suitable code):

```
(define (compare? lst)
(if (or (null? lst) (null? (cdr lst)))
#t
(let ((item (cadr lst))
(next (compare? (cddr lst))))
(case next
((#f) <???>)
((#t) <???>)
(else (and <???> <???>))))))
```

(Technically the `#f`

clause is not necessary, but, it may make it clearer to you what the solution approach should be.)

This solution will only work correctly if the matched slots in the list are not `#t`

or `#f`

. Since you're using symbols in your example, it will work correctly.