If you are selecting `M`

elements out of `N`

, the strategy changes depending on whether `M`

is of the same order as `N`

or much less (i.e. less than about N/log N).

If they are similar in size, then you go through each item from `1`

to `N`

. You keep track of how many items you've got so far (let's call that `m`

items picked out of `n`

that you've gone through), and then you take the next number with probability `(M-m)/(N-n)`

and discard it otherwise. You then update `m`

and `n`

appropriately and continue. This is a `O(N)`

algorithm with low constant cost.

If, on the other hand, `M`

is significantly less than `N`

, then a resampling strategy is a good one. Here you will want to sort `M`

so you can find them quickly (and that will cost you `O(M log M)`

time--stick them into a tree, for example). Now you pick numbers uniformly from `1`

to `N`

and insert them into your list. If you find a collision, pick again. You will collide about `M/N`

of the time (actually, you're integrating from 1/N to M/N), which will require you to pick again (recursively), so you'll expect to take `M/(1-M/N)`

selections to complete the process. Thus, your cost for this algorithm is approximately `O(M*(N/(N-M))*log(M))`

.

These are both such simple methods that you can just implement both--assuming you have access to a sorted tree--and pick the one that is appropriate given the fraction of numbers that will be picked.

(Note that picking numbers is symmetric with not picking them, so if `M`

is almost equal to `N`

, then you can use the resampling strategy, but pick those numbers to *not* include; this can be a win, even if you have to push all almost-`N`

numbers around, if your random number generation is expensive.)