I see you posted your own solution, so I guess it's ok to show my complete answer. Here's another possible implementation, as a mutually-recursive pair of procedures. I like the fact that this solution doesn't require using `length`

or `list?`

(which might entail unnecessary traversals over the list), and uses only elementary functions (no `foldr`

, `reverse`

, `map`

or any other higher-order procedures are needed.)

```
(define (decompose lst)
(if (or (null? lst) ; if the list is empty
(null? (cdr lst)) ; or has only one element
(null? (cddr lst))) ; or has only two elements
lst ; then just return the list
(process (car lst) ; else process car of list (operator)
(cdr lst)))) ; together with cdr of list (operands)
(define (process op lst)
(cond ((null? (cdr lst)) ; if there's only one element left
(if (not (pair? (car lst))) ; if the element is not a list
(car lst) ; then return that element
(decompose (car lst)))) ; else decompose that element
((not (pair? (car lst))) ; if current element is not a list
(list op ; build a list with operator,
(car lst) ; current element,
(process op (cdr lst)))) ; process rest of list
(else ; else current element is a list
(list op ; build a list with operator,
(decompose (car lst)) ; decompose current element,
(process op (cdr lst)))))) ; process rest of list
```

It works for your examples, and then some:

```
(decompose '(* 1 2 3 4))
=> '(* 1 (* 2 (* 3 4)))
(decompose '(+ 1 2 3 (* 5 6 7)))
=> '(+ 1 (+ 2 (+ 3 (* 5 (* 6 7)))))
(decompose '(+ 1 (* 4 5 6) 2 3))
=> '(+ 1 (+ (* 4 (* 5 6)) (+ 2 3)))
(decompose '(+ 1 2 3 (* 5 6 7) 8))
=> '(+ 1 (+ 2 (+ 3 (+ (* 5 (* 6 7)) 8))))
(decompose '(+ 1 2 3 (* 5 6 7) (* 8 9 10) (* 11 12 (- 1))))
=> '(+ 1 (+ 2 (+ 3 (+ (* 5 (* 6 7)) (+ (* 8 (* 9 10)) (* 11 (* 12 (- 1))))))))
```