I believe that the C++ standard for std::sort does not guarantee O(n) performance on a list that's already sorted. But still, I'm wondering whether to your knowledge any implementations of the STL (GCC, MSVC, etc) make the std::is_sorted check before executing the sort algorithm?

Asked another way, what performance can one expect (without guarantees, of course) from running std::sort on a sorted container?

Side note: I posted some benchmarks for GCC 4.5 with C++0x enabled on my blog. Here's the results:

Comparison of std::sort and std::is_sorted

  • 6
    would like to see on a log-log scale
    – Inverse
    Jul 10, 2011 at 19:12

7 Answers 7


Implementations are free to use any efficient sorting algorithm they want so this is highly implementation dependant

However I have seen a performance comparison of libstdc++ as used on linux and against libc++ the new C++ library developed by Apple/LLVM. Both these libraries are very efficient on sorted or reverse sorted data (much faster than on a random list) with the new library being considerable faster then the old and recognizing many more patterns.

To be certain you should consider doing your own benchmarks.

  • 18
    A few months ago I asked Howard Hinnant how he implemented the std::sort in libc++. His implementation does check for sorted and reverse-sorted inputs, not only at the "full" level, but also at each level of the recursion, so that partially sorted inputs also benefit from the speed-up. He believed it was important enough to sacrifice some performance in the "chaotic" case. Jul 4, 2011 at 6:36
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    The STL available with msvc 2010 (Dinkumware, I think) also does something similar to what Matthieu mentions. It's not the same as calling is_sorted on the inputs, but rather builds a check for partially sorted sub-ranges into the quicksort partition, hence useful for partially sorted sequences. Jul 4, 2011 at 6:51
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    Clarification. libc++ doesn't not actually do an is_sorted check at each level (which would burn up too much cpu). But it is close to that. I believe libc++ does 2N comparisons (and no swaps) on a sorted sequence (is_sorted only does N comparisons on a sorted sequence). libc++ counts swaps during each partition phase. If there are no swaps done, then libc++ switches to a "partial" insertion sort for each partition. This insertion sort will abort if more than a few elements need to be inserted. Recall that insertion sort does only N comparisons (and no moves) for a sorted sequence. Jul 4, 2011 at 14:23
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    -1: Actually, implementations must provide an std::sort with Complexity: Approximately N log N (where N == last - first) comparisons on the average. ( Sorting [lib.sort]), so the set of allowed sorting functions is limited. Jul 20, 2011 at 6:48
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    @Eelke: Of course they are free to vary, but within a non -infinite set of algorithms, and I am afraid that invalidates the your phrase "Implementations are free to use any sorting algorithm they want so this is highly implementation dependant". Jul 20, 2011 at 8:50

No. Also, it's not logical to have is_sorted() called for any STL implementation. Since, is_sorted() is available already as a stand-alone. And many users may not want to waste execution cycles unnecessarily to call that function when they already know that their container is not sorted.

STL also should be following the C++ philosophy: "pay per use".

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    What do you mean by "pay per use"? Jul 4, 2011 at 4:46
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    @Lex Fridman: it means that something costs only if you use it. std::sort wouldn't call std::is_sorted because then std::sort would incur the costs of std::is_sorted in addition to its own. That is, if you want to prevent possibly NlogN for std::sorting a sorted list, it is up to you to pay the price of calling std::is_sorted. Besides, if you have lists that are nearly-sorted, you should be using a bubble sort or something else that has good sorting characteristics for nearly sorted lists. Jul 4, 2011 at 4:48
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    @Lex, in Bjarne Stroustrup's words, "Pay only for what you use." I don't recall in which interview he said this. But this phrase is easily available on net.
    – iammilind
    Jul 4, 2011 at 4:49
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    @Martin: An already sorted list is O(n) for several sorts, most of which perform MUCH better than bubble sort. For example, insertion sort. (Quicksort can be written this way but I don't think most common implementations are....) Jul 4, 2011 at 6:05
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    @Billy: and that is why the original comment also mentions other sorts <quote>using a bubble sort or something else that has good sorting characteristics</quote>. It is the way you phrased your exclamation it seemed like you doubted bubble sort had good characteristics for nearly sorted lists. Jul 4, 2011 at 14:26

Wow! Did you have optimizations all the way cranked up?

Here's the results of your code on my platform (note the values on the vertical axis).


I suggest you read this comparison of sorting algorithms, it is very well done and informative, it compares a number of sorting algorithms with each other and with GCC's implementation of std::sort. You will notice, in the charts on the given link, that the performance of std::sort for "almost sorted" and "almost reverse" are linear in the number of elements to sort, that is, O(n). So, no guarantee, but you can easily expect that an almost sorted list will be sorted in almost linear-time. But, of course, it does not do a is_sorted check, and even if it will sort a sorted array in linear-time, it won't be as fast as doing a is_sorted check and skipping the sorting altogether. It is your decision to determine if it is better to check before sorting or not.


The standard sanctions only std::sort implementations with complexity O(n log n):

Complexity: Approximately N log N (where N == last - first) comparisons on the average.

See section Sorting [lib.sort] (ISO/IEC 14882:2003(E)).

Thus, the set of allowed sorting functions is limited, and you are right that it does not guarantee linear complexity.

Ideal behavior for a sort is O(n), but this is not possible in the average case.

Of course the average case is not necessarily the exact case you have right now, so for corner cases, there's not much of a guarantee.

  • the problem is - depending on the algorithm, a sorted vector might present the worst case. O(n log n) on average does not say anything about the worst case - so it can be O(n^2) as it is for standard quicksort. Jul 20, 2011 at 7:48

And why would any implementation do that check? What would it gain? -- Nothing in average. A good design rule is not to clutter implementation with optimizations for corner cases which make no difference in average. This example is similar to check for self-assignment. A simple answer: don't do it.

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    Your "on average" case only works if your input is uniformly distributed over the possible inputs (i.e. all possible permutations). However, with many applications, this is not the case. Also, the same code that prevents ordinary quick-sort from falling down into square complexity usually helps with almost-sorted sequences, so you usually kill two birds with one stone.
    – ltjax
    Jul 20, 2011 at 9:24
  • Also, not checking for self-assignment is can often be an error in C++. So do do it! (unless you know it's not an error to omit).
    – ltjax
    Jul 20, 2011 at 9:25
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    @ltjax: not really, the optimization for corner cases is often another root of all evil in programming. Regarding self-assignment: avoid writing a copy assignment operator that relies on a check for self-assignment in order to work properly; often, that reveals a lack of error safety -- Herb Sutter Jul 20, 2011 at 15:36
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    I agree that optimization for corner cases is bad. But somewhat sorted input is not a corner case. Input to sorting functions is usually not very random at all.
    – ltjax
    Jul 21, 2011 at 9:50

There's no guarantee that it'll check this. Some implementations will do it , others probably won't.

However, if you suspect that your input might already be sorted (or nearly sorted), std::stable_sort might be a better option.

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    Do you have evidence to support the claim that stable sort might be better there?
    – ltjax
    Jul 20, 2011 at 9:27
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    std::sort is intended to be implemented as quicksort. And quicksort (in some implementations) exhibits worst-case (On^2)behavior on sorted input. stable_sort is intended to be implemented as heapsort or mergesort, which provide stricter worst-case guarantees
    – jalf
    Jul 20, 2011 at 10:26
  • @jalf: The worst case scenario for quicksort is for a naïve implementation of quicksort. Many implementations will use median of three to find a pivot, picking the median of the first, last and middle element in a sorted sequence, the median is the center, and the pivot will partition the input into two elements of roughly the same size (it might not be exact in the presence of duplicates for the middle element). Of course, there is one sorted worst case for median of three: all elements being the same. Also, std::sort often do introsort that will attempt quicksort or fallback to merge Mar 7, 2014 at 20:59
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    just measured it, std::stable_sort() is a bit worse than std::sort() on unsorted data, and actually much worse on sorted data. Sep 28, 2016 at 22:15

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