# (Scheme) Recursive function to compute all possible combinations of some lists?

What is an example of a recursive function to compute all possible combinations of lists? For example, `(combine (list 1 2 3) (list 1 2))` should return `'((1 1) (1 2) (2 1) (2 2) (3 1) (3 2))`.

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possible duplicate of Cartesian product in Scheme – Chris Jester-Young Apr 5 '11 at 3:10
BTW, the inner lists aren't quoted. You should expect to get `'((1 1) (1 2) (2 1) (2 2) (3 1) (3 2))`. – Chris Jester-Young Apr 5 '11 at 3:12
My solution for 2 lists in 3 lines: stackoverflow.com/questions/5058219/… – knivil Apr 5 '11 at 10:40

Here's my solution. Requires SRFIs 1 and 26 to be available.

``````(define (cartesian-product first . rest)
(define (iter l result)
(define (prepend-all x)
(map (cut cons <> x) l))
(concatenate (map prepend-all result)))
(map reverse (fold iter (map list first) rest)))
``````
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Here's my take; I first define a helper `concat/map`, which takes a list and a function. Like regular `map`, it applies that function to each element in the list. Unlike `map`, though, it uses `append` to combine the results rather than `cons`. This is useful because we want to get back a single level of lists as an answer:

``````(define concat/map
(lambda (ls f)
(cond
[(null? ls) '()]
[else (append (f (car ls)) (concat/map (cdr ls) f))])))
``````

Then, writing `combine` for two lists is straightforward. You take each element of the first list, then make every list combining it and an element `x` from the second list. Since this gives back a list of answers for each element in the first list, use `concat/map` to put it together as we want:

``````(define combine
(lambda (xs ys)
(concat/map xs (lambda (x)
(map (lambda (y) (list x y)) ys)))))
``````

The version of `combine` that operates on one or more lists, let's call it `combine*`, is a bit trickier. Instead of making all the lists combining `x` with the elements from the second list, we just recursively ask for the product of all the remaining `ys`, and then `cons` `x` onto each of those results. The recursion stops when there's only two lists to combine, and uses the original `combine` in that case.

``````(define combine*
(lambda (xs . ys*)
(cond
[(null? ys*) (map list xs)]
[(null? (cdr ys*)) (combine xs (car ys*))]
[else (concat/map xs (lambda (x)
(map (lambda (y) (cons x y))
(apply combine* ys*))))])))
``````

As a bonus, this pattern of using `concat/map` to do some work and combine the resulting answers is actually the list monad. It's simplified here, but the structure is in place.

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(a) In scheme "concat" is rarely used, "append" is much preferred; (b) your `concat/map` is also weird in that it gets the list before the function, whereas the order is almost always the other way (to accommodate more list arguments that are used for a function of more thn one input); (c) there's a subtle bug in your `combine*` -- it'll accept one argument but will break when given one; (d) finally, it would be much easier to write it using `case-lambda`. – Eli Barzilay Apr 8 '11 at 10:05
@Eli Barzilay my intent with `concat/map` was to sneak the definition of the list monad's `bind` into the solution. Good catch on the single list bug. – acfoltzer Apr 8 '11 at 13:04
This is another reason why Scheme et al. is a no go for me: one has to re-invent trivial stuff like list comprehension, which is available in languges that utilize more than round parentheses: [ (a,b) | a <- as, b <- bs ] – Ingo Apr 8 '11 at 13:16
Ingo: That's true for "Scheme", but false for most actual implementations. (That's re the re-inventing point, the parens comment is irrelevant flamebait.) – Eli Barzilay Apr 8 '11 at 18:41
Adam: You could do just the same with `append` in the name... – Eli Barzilay Apr 8 '11 at 18:41