**Is there an efficient algorithm for finding all sequences of k non-negative integers that sum to n, while avoiding rotations (completely, if possible)?** The order matters, but rotations are redundant for the problem I'm working on.

For example, with *k* = 3 and *n* = 3, I would want to get a list like the following:

(3, 0, 0), (2, 1, 0), (2, 0, 1), (1, 1, 1).

The tuple (0, 3, 0) should not be on the list, since it is a rotation of (3, 0, 0). However, (0, 3, 0) could be in the list *instead of* (3, 0, 0). Note that both (2, 1, 0) and (2, 0, 1) are on the list -- **I do not want to avoid all permutations of a tuple, just rotations.** Additionally, 0 is a valid entry -- I am

**not looking for partitions of**.

*n*My current procedure is to loop from over 1 <= *i* <= *n*, set the first entry equal to *i*, and then recursively solve the problem for *n'* = *n* - *i* and *k'* = *k* - 1. I get some speed-up by mandating that no entry is strictly greater than the first, but this approach still generate a lot of rotations -- for example, given *n* = 4 and *k* = 3, both (2,2,0) and (2,0,2) are in the output list.

Edit: Added clarifications in bold. I apologize for not making these issues as clear as I should have in the original post.

ARElooking for partitions of n, but with sizeup tok. And inserting zeros to fill up k spaces – belisarius Sep 17 '10 at 5:39nup to sizekis part of the problem, but not all of it. Strictly speaking, two partitions are the same if the order of the summands are permuted. I am not having difficulty computing partitions, or even all permutations of the summands -- the problem is finding all the permutations up to rotation. – Seth Sep 17 '10 at 6:08