Consider the simple code that measures execution time and the number of swaps performed:

#include <iostream>

#include <vector>
#include <random>
#include <chrono>
#include <algorithm>

struct A {
    A(int i = 0) : i(i) {}
    int i;
    static int nSwaps;

    friend void swap(A& l, A& r)
        std::swap(l.i, r.i);

    bool operator<(const A& r) const
        return i < r.i;

int A::nSwaps = 0;

using std::chrono::high_resolution_clock;
using std::chrono::duration_cast;
using std::chrono::milliseconds;

int main()
    std::vector<A> v(10000000);

    std::minstd_rand gen(std::random_device{}());
    std::generate(v.begin(), v.end(), [&gen]() {return gen();});

    auto s = high_resolution_clock::now();
    std::sort(v.begin(), v.end());
    std::cout << duration_cast<milliseconds>(high_resolution_clock::now() - s).count() 
        << "ms with " << A::nSwaps << " swaps\n";

    A::nSwaps = 0;
    s = high_resolution_clock::now();
    std::shuffle(v.begin(), v.end(), gen);
    std::cout << duration_cast<milliseconds>(high_resolution_clock::now() - s).count() 
        << "ms with " << A::nSwaps << " swaps\n";

The output of the program depends on the compiler and the machine, but they are quite similar in their nature. On my laptop with VS2015, I get 1044ms with ~100 million swaps for sort and 824ms with 10 million swaps for shuffle.

libstdc++ and libc++ do twice as few swaps for sort (~50M) and the results are as follows. Rextester gives me similar results: gcc sort 854ms, shuffle 565ms, clang sort 874ms, shuffle 648ms. The results shown by ideone and coliru are even more drastic: ideone sort 1181ms, shuffle 1292ms and coliru sort 1157ms, shuffle 1461ms.

So what's the culprit here? Why with 5 to 10 times more swaps sort is almost as fast or even faster than a simple shuffle? I'm not even taking into account comparisons and more complex logic in std::sort including choosing insertion, heap or quick sort algorithms, etc. I doubt it's the random engine - I've even chosen the simplest one std::minstd_rand which basically does an integer multiplication and a modulo. Is it the cache misses that make shuffle relatively slow?

PS: the behaviour is the same for simple std::vector<int>

  • 1
    it's probably worth measuring how much of that time is taken up by the ~10 million random number generations. Sep 15, 2015 at 13:12
  • @SanderDeDycker Good point. Ideone reports only 71ms though.
    – Rostislav
    Sep 15, 2015 at 13:16
  • These are rather different jobs. I am not sure any comparison would be valid. std::shuffle is going to depend heavily on the random number generation algorithm. I would think swapping is very cheap and so is comparing two valies a < b. Generating random numbers, though, has to involve many more processing steps than a < b.
    – Galik
    Sep 15, 2015 at 13:24
  • on my laptop, gcc gives these results : unoptimized [4109ms with 46947242 swaps, 1318ms with 9999999 swaps, 375ms with 9999999 rng], with -O2 [794ms with 46992015 swaps, 461ms with 9999999 swaps, 194ms with 9999999 rng]. Both of these look very reasonable to me (ignoring the time taken for rng, the difference is a factor 3-4, which is very close to the factor 4-5 difference in number of swaps) - ie. I can't replicate your results here. Sep 15, 2015 at 13:24
  • Did you compile with the Release configuration? I compiled with VS2013, release, the result is: 1005ms with 94135436 swaps 733ms with 9999999 swaps. I did run several times, the result it the same: shuffle is faster
    – Matt
    Sep 15, 2015 at 13:31

2 Answers 2


std::random_shuffle usually works as follows:

//random(k) generates uniform random from 0 to k-1 inclusive
for (int i = 1; i < n; i++)
  swap(arr[i], arr[random(i + 1)]);

So we can see two sources of inefficiency here:

  1. Random number generators are often quite slow.
  2. Each swap uses a totally random element from the vector. When the data size is large, the whole vector does not fit into CPU cache, so each such access has to wait until the data is read from RAM.

Speaking of point 2, sorting algorithms like quicksort are much more cache-friendly: most of their memory accesses hit cache.

  • Thanks! It seems to make sense. Note though that I consciously chose shuffle with very simple generator and not random_shuffle to avoid this influence. But thinking further to the implementation of sort, even the first partition will likely hit cache most of the time as there are two iterators moving linearly forward. Every swap in shuffle is very likely a cache miss. Thus the performance penalty. Thanks again, I'll accept your answer.
    – Rostislav
    Sep 15, 2015 at 14:02
  • @Rostislav: You might want to measure performance for lesser sizes of vector. Perhaps you will be able to see more.
    – stgatilov
    Sep 15, 2015 at 14:18

First, std::sort is not required to use an unqualified swap. It's not a customization point, and you cannot rely on your own user-defined swap being found through ADL. But even it would, sort can also use std::rotate, which can do swap but also memmove. This would not be counted by your implementation.

Second, the Standard Library only specifies asymptotic complexity, which is O(N) for std::shuffle and O(N log N) for std::sort. So you should measure for different values of N (e.g. powers of 2 from 65K to 65M amounts of elements) and measure the scaling behavior. For small N, the constant of proportionality of sort could be much smaller than the one for shuffle since it has to call a potentially expensive random generator.

Update: it indeed appears that constant factors and/or cache-effects are the culprit (as pointed out by @stgatilov). See this DEMO where I run std::sort on the data after std::shuffle has been called. Runtime for sort is about half of that of shuffle, with 5x more swaps.

  • Thanks for the answer! Yes, I understand that there's no guarantee for swap to be used. However this is not my concern - it's picked up by current implementations of standard library which let's me count swaps - that's enough for testing. And yes, the algorithmic complexity will probably have its effect for different sizes, but again it wouldn't answer my practical question - why the observed behaviour is like it is for this particular case. Note that the results are similar for 100M elements on my machine as well.
    – Rostislav
    Sep 15, 2015 at 13:55
  • @Rostislav if you look at libc++, it indeed uses unqualified swap in many places, but it also uses while-loops with std::move for contiguously moving data. So it's not purely swap-based and you would have to debug it to measure how much of the permutations are being swapped and how many are being moved. Sep 15, 2015 at 13:59
  • indeed. However, the thing is, unless shuffle doesn't use swap in some cases, the ratio of at least 5 is still there, so sort may do even more work than shuffle that I don't capture with my simple metric. Yet it is relatively fast. That was puzzling to me but it seems cache friendliness is the key.
    – Rostislav
    Sep 15, 2015 at 14:10
  • 2
    std::sort is allowed to call the client's swap via ADL, move construction and move assignment. A poor but legal implementation can call std::swap (without using ADL) only because std::swap is only allowed to call a move construction and move assignment. std::shuffle is only allowed to call swap via ADL (which may resolve to std::swap if there is no custom swap). In all cases, swap is a "customization point." Sep 15, 2015 at 14:31
  • 1
    Well that's the problem with using terms that don't have an official definition in the standard. :-) I consider swap a customization point because it can be a custom replacement for a std algorithm. But the standard doesn't use this term. It uses terms like: "shuffle requires Swappable. And then Swappable is rigorously defined to mean: calls your custom swap if you have one, else calls std::swap. Some algorithms like sort say (I'm paraphrasing): Requires Swappable, MoveConstructible and MoveAssignable. It is allowed to use any/all of these and nothing else. Sep 15, 2015 at 15:08

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