All of the algorithms presented have a similar *average case* bounds, of `O(n lg n)`

, which is the "best" a comparison sort can do.

Since they share the same average bounds, the expected performance of these algorithms over random data should be similar - which is what the findings show. However, the devil is in the details. Here is a very quick summary; follow the links for further details.

Quicksort is generally *not stable* (but there are stable variations). While quicksort has an *average* bounds of `O(n lg n)`

, Quicksort has a *worst case* bounds of `O(n * n)`

but there are ways to mitigate this. Quicksort, like heapsort, is done *in-place*.

Merge-sort is a *stable* sort. Mergesort has a *worst case* bounds of `O(n lg n)`

which means it has predictable performance. Base merge-sort requires `O(n)`

extra space so it's generally *not* an in-place sort (although there is an in-place variant, and the memory for a linked list implementation is constant).

Heapsort is *not stable*; it also has the worst case bounds of `O(n lg n)`

, but has the benefit of a constant size bounds and being *in-place*. It has worse cache and parallelism aspects than merge-sort.

Exactly which one is "best" depends upon the use-case, data, and exact implementation/variant.

I believe that merge-sort (or a variant of such) is currently the "default" sort implementation in many libraries/languages - and quicksort, if present, is provided as a secondary sort algorithm, usually specifically over mutable arrays.

Merge-sort: a *stable sort* with consistent performance and acceptable memory bounds.

Quicksort/heapsort: trivially work *in-place* and [effectively] don't require additional memory.

onebenchmark ofoneimplementation. Also, "we" don't "always" use Quicksort; for example the standard sorting algorithm in Python is Timsort, a highly modified mergesort. – delnan Jan 27 at 20:20worsecase for mergesort vs quicksort?). Also, check out comb-sort. – user2864740 Jan 27 at 20:47