I would like to know how std::sort and std::stable_sort differ with respect to functionality, memory and hardware? The documentation mentions that "Sorts the elements in the range [first,last) into ascending order, like sort, but stable_sort preserves the relative order of the elements with equivalent values.", but that didn't make sense to me. What is the "relative order" and "equivalent values"?
4 Answers
Yes, it's as you said, and this is not a concept unique to C++.
Stable sorts preserve the physical order of semantically equivalent values.
The order of equal elements is not guaranteed to be preserved.
Complexity:O(N·log(N))
, whereN
=std::distance(first, last)
comparisons
The order of equal elements is guaranteed to be preserved.
Complexity:O(N·log^2(N))
, whereN
=std::distance(first, last)
applications ofcmp
. If additional memory is available, then the complexity isO(N·log(N))
.
The implication is that std::stable_sort
cannot be performed quite as efficiently in terms of execution time, unless "additional memory is available" in which case it is not being performed as efficiently in terms of memory consumption.

3Empirically, for an array of size 65536, I find that stable_sort is faster than sort. I conclude that "cannot be performed quite as efficiently" is not the full story. Commented Jul 23, 2018 at 15:10

@JoachimW As is the case with any algorithm, we are talking only about growth rates, and it is perfectly to be expected that one algorithm may be faster than the other with small inputs, but that the performance of the former degrades quicker than the latter as the number of inputs grows. As such, I'd be interested to find out what results you get when you exchange 65536 for [many] other numbers. (I will concede that my wording glossed over this possibility.) Commented Jul 23, 2018 at 15:47

Outcome may also depend in subtle ways on any partial order present in the input data, right? Commented Jul 24, 2018 at 7:30

3@JoachimW stable_sort will likely be faster for some input sets, particularly ones with lots of equivalent elements, simply because it goes straight for the "definitely O(n log n)" approach rather than struggling through a few levels of introsort first. I would not expect it to be faster than stable_sort for a shuffled array of 2^16 unique integers, though.– SneftelCommented Feb 21, 2020 at 17:17
I think that an example with sorting a struct, rather than a list of integers, is helpful to clarify what the difference is between both.
Imagine a list of neighbours in a building, that you construct ordered by the floor where they live.
struct Neighbour
{
int floor;
string name;
Neighbour(int f, string n) : floor(f), name(n) {}
};
std::vector<Neighbour> vec = {Neighbour(1,Bob), Neighbour(2,Anna), ... };
 1 Bob
 2 Anna
 3 Peter
 4 Bob
 5 Laura
If you now want to sort your list alphabetically, and you use
std::sort(vec.begin(), vec.end(), [](Neighbour a, Neighbour b){ return a.name < b.name; }
the result might be:
 2 Anna
 1 Bob
 4 Bob
 5 Laura
 3 Peter
or:
 2 Anna
 4 Bob
 1 Bob
 5 Laura
 3 Peter
With stable_sort
, it is ensured that you always will get the first result. With the duplicates in the same order they were in the initial list.
As mentioned, the standard only notes that std::stable_sort preserves the original order for equal elements, while std::sort doesn't.
In the case of HP / Microsoft STL, std::sort is usually quick sort, unless the nesting gets too deep, in which case it switched to heap sort. Quick sort time complexity is typically O(n log(n)), but it's worst case is O(n^2), which is avoided with the switch to heap sort, since heap sort is always O(n log(n)) (but slower than quick sort so it's only used to avoid O(n^2)).
In the case of HP / Microsoft STL, std::stable_sort is a hybrid bottom up merge sort, using insertion sort to create sorted groups of 32 elements, then doing bottom up merge sort with the groups. The array (or vector) is split into two, a temporary array (or vector) 1/2 the size of the array to be sorted is allocated, and used to do a merge sort for both halfs of the array. Then one of the half arrays is moved to the temp array to do a final merge pass. Merge sort is also O(n log n), taking a bit longer for sorting arrays of objects, but merge sort is often faster if sorting an array of pointers to objects where a comparison function is included in the call. This because merge sort involves more moves but fewer compares than quick sort.
For sorting an array of integers, a radix sort is faster. If sorting by byte, then it takes 4 passes to sort an array of 32 bit integers, and 8 passes to sort an array of 64 bit integers.
As you correctly realized, std::stable_sort()
retains the relative order of objects considered equivalent. std::sort()
doesn't have this requirement. As a result, std::stable_sort()
is likely to be more resourcehungry: it will probably be slower and will probably use more temporary memory as it has to obey more constraints. I'm not aware of any algorithm which does inplace stable sorting as efficient as sorting.

1I think an example would've helped best. I understood it as if I have
[s1, s2, s3]
as[3, 2, 2]
and do astable_sort
on the array to obtain [2, 2, 3], thenstable_sort
ensures that the array order remains as[s2, s3, s1]
instead of there being a chance ofs2
ands3
's positions getting mixed up. Correct?– NavCommented Feb 21, 2020 at 15:42 
std::sort
usually uses introsort, andstd::stable_sort
merge sort