I believe you can do better than 13, just on the principle of O(n log n) growth.

The basic approach is that you design a decision tree that determines which permutation you're dealing with, but not sensitive to actual values. But assuming that an exhaustive search of possible decision trees is needed to find an optimal one, you need to be aware that as the number of items increases, the number of decision trees to consider increases *very* quickly. At a guess exponentially, though I haven't checked that guess - it may even be worse than that.

You may be able to do better than 13 by just hard-coding the tests that a common sort algorithm - but not an O(n^2) algorithm such as bubble-sort or even (I suspect) quicksort.

Basically, I think the idea is more trouble than its worth. Five is probably the practical limit for a hard-coded optimal sort. Anything larger - just use a standard sort algorithm. Though I'll bet someone will answer with an implementation anyway.

`6! = 720, 2 ** 10 = 1024`

) – Niet the Dark Absol Nov 28 '10 at 9:27