There are lots of clever approaches (like the priority queue solutions), but one of the simplest things you can do can also be fast and efficient.

If you want the top `k`

of `n`

, consider:

```
allocate an array of k ints
while more input
perform insertion sort of next value into the array
```

This may sound absurdly simplistic. You might expect this to be `O(n^2)`

, but it's actually only `O(k*n)`

, and if `k`

is much smaller than `n`

(as is postulated in the problem statement), it approaches `O(n)`

.

You might argue that the constant factor is too high because doing an average of `k/2`

comparisons and moves per input is a lot. But most values will be trivially rejected on the first comparison against the `k`

th largest value seen so far. If you have a billion inputs, only a small fraction are likely to be larger than the 100th so far.

(You *could* construe a worst-case input where each value is larger than its predecessor, thus requiring `k`

comparisons and moves for every input. But that is essentially a sorted input, and the problem statement said the input is unsorted.)

Even the binary-search improvement (to find the insertion point) only cuts the comparisons to `ceil(log_2(k))`

, and unless you special case an extra comparison against the `k`

th-so-far, you're much less likely to get the trivial rejection of the vast majority of inputs. And it does nothing to reduce the number of moves you need. Given caching schemes and branch prediction, doing 7 non-consecutive comparisons and then 50 consecutive moves doesn't seem likely to be significantly faster than doing 50 consecutive comparisons and moves. It's why many system sorts abandon Quicksort in favor of insertion sort for small sizes.

Also consider that this requires almost no extra memory and that the algorithm is extremely cache friendly (which may or may not be true for a heap or priority queue), and it's trivial to write without errors.

The process of reading the file is probably the major bottleneck, so the real performance gains are likely to be by doing a simple solution for the selection, you can focus your efforts on finding a good buffering strategy for minimizing the i/o.

If `k`

can be arbitrarily large, approaching `n`

, then it makes sense to consider a priority queue or other, smarter, data structure. Another option would be to split the input into multiple chunks, sort each of them in parallel, and then merge.