I'm trying out a bunch of different algorithms for finding near-optimal solutions to the Traveling Salesman Problem, and one of the methods is the brute force approach - checking *every* possible path between n cities, and simply returning the best one. This is an O(n!) algorithm, so naturally it takes a very long time to execute for a large number of cities.

I want to improve the efficiency of my brute force implementation, and one of the things I've noticed is that you don't have to check *every* single permutation of the cities. For example, if you have cities 1, 2, 3, and 4, the path (1-2-3-4) is the same length as path (2-3-4-1). The same goes for the paths (3-4-1-2) and (4-1-2-3). By exploiting this fact, we should be able to reduce the complexity of the brute force algorithm from O(n!) to O((n-1)!), or even O((n-1)!/2) if we realize that all paths can be reversed without affecting their lengths.

Basically, I'm looking for an algorithm that is capable of generating circular permutations from a set of distinct integers. It would also be great if the algorithm treated "mirrored" permutations as equivalent (e.g. 1-2-3 and 3-2-1 are the same, so only one of them is needed). Does anyone know of a way to accomplish this? A Java implementation would be wonderful, but I'll take anything!