So basically you want to generate the cartesian product `s1 x s2 x ... x sN`

.

This is a classic application of backtracking / recursion. Here's how a pseudocode would look like:

```
function CartesianProduct(current, k)
if (k == N + 1)
current is one possibility, so call f(current[1], current[2], ..., current[N])
and return
for each element e in Sk
call CartesianProduct(current + {e}, k + 1)
Initial call is CartesianProduct({}, 1)
```

You should write it on paper and see how it works. For example, consider the sets:

```
s1 = {1, 2}
s2 = {3, 4}
s3 = {5, 6}
```

The first call will be `CartesianProduct({}, 1)`

, which will then start iterating over the elements in the first set. The first recursive call with thus be `CartesianProduct({1}, 2)`

. This will go on in the same manner, eventually reaching `CartesianProduct({1, 3, 5}, 4)`

, for which the termination condition will be true (`current.Length == N + 1`

). Then it will backtrack and call `CartesianProduct({1, 3, 6}, 4)`

and so on, until all possibilities are generated. Run it on paper all the way to see exactly how it works.
A

**Extra credit**: can you figure out how to get rid of the `k`

parameter?