For the first stage, you need to pair up every LHS component with every RHS component; a cartesian product of the two sets. This requires a two-level map followed by a concatenation of the second-level lists of pairs into a single top level list (think `(apply #'append ...`

).

The second stage can be done with a reduce that builds up an association list, keyed on the exponent.

EDIT: Let me solve a different problem for you, and let you figure out how to translate it into the solution for your problem:

Compute `(a + b + ... + k) * (l + m + ... + z)`

by first expanding into pairs and then summing the products:

```
(defun mul-sums (aa bb)
(reduce #'+
(apply #'append
(map 'list
#'(lambda (a)
(map 'list
#'(lambda (b)
(* a b))
bb))
aa))))
; Compute (1 + 2 + 3) * (3 + 4).
> (mul-sums '(1 2 3) '(3 4))
42
```

f) (b+g)) ((aj)(b+k))((cf)(d+g))((cj)(d+k))) and then you combine: (3 2) with (-35 2) and (-5 1) with (14 1) and then you transform and calculate 21x3+32x2+9x+2 – iulia May 15 '10 at 8:13`3 - 35 != 32`

. – Marcelo Cantos May 15 '10 at 9:17