If you really mean that output order is irrelevant, then you want `std::nth_element`

, rather than `std::partial_sort`

, since it is generally somewhat faster. Note that `std::nth_element`

puts the n^{th} element in the right position, so you can do the following, which is 100% standard algorithm invocations (warning: not tested very well; fencepost error possibilities abound):

```
template<typename RandomIterator, typename Compare>
void best_n(RandomIterator first,
RandomIterator nth,
RandomIterator limit,
Compare cmp) {
using ref = typename std::iterator_traits<RandomIterator>::reference;
std::nth_element(first, nth, limit, cmp);
auto p = std::partition(first, nth, [&](ref a){return cmp(a, *nth);});
auto q = std::partition(nth + 1, limit, [&](ref a){return !cmp(*nth, a);});
std::random_shuffle(p, q); // See note
}
```

The function takes three iterators, like `nth_element`

, where `nth`

is an iterator to the n^{th} element, which means that it is `begin() + (n - 1))`

.

**Edit**: Note that this is different from most STL algorithms, in that it is effectively an *inclusive* range. In particular, it is UB if `nth == limit`

, since it is required that `*nth`

be valid. Furthermore, there is no way to request the `best 0`

elements, just as there is no way to ask for the 0^{th} element with `std::nth_element`

. You might prefer it with a different interface; do feel free to do so.

Or you might call it like this, after requiring that `0 < k <= n`

:

```
best_n(container.begin(), container.begin()+(k-1), container.end(), cmp);
```

It first uses `nth_element`

to put the "best" `k`

elements in positions `0..k-1`

, guaranteeing that the k^{th} element (or one of them, anyway) is at position `k-1`

. It then repartitions the elements preceding position `k-1`

so that the equal elements are at the end, and the elements following position `k-1`

so that the equal elements are at the beginning. Finally, it shuffles the equal elements.

`nth_element`

is `O(n)`

; the two `partition`

operations sum up to `O(n)`

; and `random_shuffle`

is `O(r)`

where `r`

is the number of equal elements shuffled. I think that all sums up to `O(n)`

so it's optimally scalable, but it may or may not be the fastest solution.

Note: You should use `std::shuffle`

instead of `std::random_shuffle`

, passing a uniform random number generator through to `best_n`

. But I was too lazy to write all the boilerplate to do that and test it. Sorry.

reproductiblebehavior, which meansstable sorting. Indeed the STL provides`std::sort`

,`std::stable_sort`

,`std::partial_sort`

and`std::nth_element`

, but nothing like what you are looking for (directly). – Matthieu M. Nov 10 '12 at 16:25