I think that to even store your result (which will be an ordered list of N items) will be O(N) in memory, no?

Anyhow, to answer your later question about picking a permutation at random, here's a technique that will be better than just producing all N! possibilities in a list, say, and then picking an index randomly. If we can just pick the index randomly and generate the associated permutation from it, we're much better off.

We can imagine the dictionary order on your words/permutations, and associate a unique number to these based on the word's/permutation's order of appearance in the dictionary. E.g., words on three characters would be

```
perm. index
012 <----> 0
021 <----> 1
102 <----> 2
120 <----> 3
201 <----> 4
210 <----> 5
```

You'll see later why it was easiest to use the numbers we did, but others could be accommodated with a bit more work.

To choose one at random, you could pick its associated index randomly from the range 0 ... N!-1 with a uniform probability (the simplest implementation of this is clearly out of the question for even moderately large N, I know, but I think there are decent workarounds) and then determine its associated permutation. Notice that the list begins with all the permutations of the last N-1 elements, keeping the first digit fixed equal to 0. After those possibilities are exhausted, we generate all those that start with 1. After these next (N-1)! permutations are exhausted, we generate those that start with a 2. Etc. Thus we can determine the leading digit is Floor[R / (N-1)!], where R was the index in the sense shown above. See now why we zero indexed, too?

To generate the remaining N-1 digits in the permutation, let's say that we determined Floor[R/(N-1)!] = a0. Start with the list {0, ..., N-1} - {a0} (set subtraction). We want the Qth permutation of this list, for Q = R mod (N-1)!. Except for accounting for the fact that there's a missing digit, this is just the same as the problem we've just solved. Recurse.

`Random rnd = ...; List<Integer> l = ...; while (l.size() < N) { int r = 1+rnd.nextInt(N); if(!l.contains(r)) l.add(r) } return l;`

– Bruno Reis Nov 8 '11 at 4:36