**Method 1**

Since k is small, you can use the tournament method to find the kth largest. This method is described in Knuth's Art of Programming, Volume 3, Page 212.

First create a tournament on n-k+2 elements. Something like a knockout tennis tournament. First you split into pairs and compare the members of the pairs (as if those two played a match and one lost). Then the winners, you split in to pairs again and so on, till you have a winner. You can view it as a tree, with the winner at the top.

This takes n-k+1 compares exactly.

Now the winner of these n-k+2 cannot be your kth largest element. Consider its path P up the tournament.

Of the remaining k-2 now pick one, and follow that up the path P which will give you a new largest. Basically you sort of redo the tournament with the previous winner being replaced by one of the k-2 elements. Let P be the path of the new winner. Now pick another from the k-3 and follow the new path up and so on.

At the end after you exhaust the k-2, replace the largest with -infinity and the largest of the tournament will be the kth largest. The elements you have thrown away are the top k-1 elements.

This takes at most `n - k + (k-1) [log (n-k+2)]`

comparisons to find the top k. It uses O(n) memory though.

In terms of number of compares this should likely beat any selection algorithms.

**Method 2**

As an alternative, you can maintain a min-heap of k elements.

First insert k elements. Then for each element of array, if it is less than the min element of the heap, throw it away. Otherwise, delete-min of the heap and insert the element from the array.

At the end, the heap will contain the top k elements. This will take `O(n log k)`

compares.

Of course, if n is small, just sorting the array should be good enough. The code will be simpler too.