According to Scott Meyers, in his Effective STL book - item 46. He claimed that std::sort is about 670% faster than std::qsort due to the fact of inline. I tested myself, and I saw that qsort is faster :( ! Could anyone help me to explain this strange behavior?

#include <iostream>
#include <vector>
#include <algorithm>

#include <cstdlib>
#include <ctime>
#include <cstdio>

const size_t LARGE_SIZE = 100000;

struct rnd {
    int operator()() {
        return rand() % LARGE_SIZE;

int comp( const void* a, const void* b ) {
    return ( *( int* )a - *( int* )b );

int main() {
    int ary[LARGE_SIZE];
    int ary_copy[LARGE_SIZE];
    // generate random data
    std::generate( ary, ary + LARGE_SIZE, rnd() );
    std::copy( ary, ary + LARGE_SIZE, ary_copy );
    // get time
    std::time_t start = std::clock();
    // perform quick sort C using function pointer
    std::qsort( ary, LARGE_SIZE, sizeof( int ), comp );
    std::cout << "C quick-sort time elapsed: " << static_cast<double>( clock() - start ) / CLOCKS_PER_SEC << "\n";
    // get time again
    start = std::clock();
    // perform quick sort C++ using function object
    std::sort( ary_copy, ary_copy + LARGE_SIZE );
    std::cout << "C++ quick-sort time elapsed: " << static_cast<double>( clock() - start ) / CLOCKS_PER_SEC << "\n";

This is my result:

C quick-sort time elapsed: 0.061
C++ quick-sort time elapsed: 0.086
Press any key to continue . . .


Effective STL 3rd Edition ( 2001 )
Chapter 7 Programming with STL
Item 46: Consider function objects instead of functions as algorithm parameters.

  • 17
    Did you let your compiler optimize? Debug/unoptimized builds won't take full advantage of things like inlining. Jan 16, 2011 at 21:23
  • 5
    Understanding how quick sort works, would give you a better idea of how to test it, in short: 1. use a larger array, eg: 10^6 in size, then populate the array in descending order 999999... 4,3,2,1 - this will cause the sort to become O(n^2), doing this will effectively demonstrate why inlining comparators makes such a big difference in this particular algorithm.
    – Matthieu N.
    Jan 16, 2011 at 21:24
  • 11
    @Zenikoder- Almost no implementations of qsort or sort will use a quicksort implementation that breaks on reverse-sorted inputs. The most common STL sort implementation uses introsort, which introspects on the quicksort routine to ensure it never degrades to worse than O(n lg n), and I'm fairly confident that the C qsort routine uses something similar (or at least a heuristic like median-of-three) to prevent this. Jan 16, 2011 at 21:26
  • 3
    @Noah: According to a 06 article on artima SM: "I’ll begin with what many of you will find an unredeemably damning confession: I have not written production software in over 20 years, and I have never written production software in C++." He calls himself an archeologist/anthropologist of the C++ language.
    – Matthieu N.
    Jan 16, 2011 at 21:30
  • 3
    @Chan: The Bentley and McIlroy paper can be found here: cs.ubc.ca/local/reading/proceedings/spe91-95/spe/vol23/issue11/…
    – Matthieu N.
    Jan 16, 2011 at 21:54

8 Answers 8


std::clock() is not a viable timing clock. You should use a platform-specific higher resolution timer, like the Windows High Performance Timer. More than that, the way that you call clock() is that first, text is output to the console, which is included in the time. This definitely invalidates the test. In addition, make sure that you compiled with all optimizations.

Finally, I copied and pasted your code, and got 0.016 for qsort and 0.008 for std::sort.

  • 2
    @DeadMG: Thanks! I changed to release mode, and I got the similar result. I really love Scott Meyers, and I trust his word ;)
    – Chan
    Jan 16, 2011 at 21:27
  • Text seems to be is output on both cases so it can not exactly make the outcome invalid.
    – Öö Tiib
    Jan 16, 2011 at 21:29
  • 2
    @Oo Tiib: Text being output doesn't mean that it doesn't output in the same time. What if the buffer is somewhat bigger than the first but less than the second? Now it has to flush before the second call- but it didn't in the first call. Oh dear. I'm not very happy though because I fixed all the above problems and qsort is now a lot faster. :(
    – Puppy
    Jan 16, 2011 at 21:33
  • @DeadMG: How is qsort a lot faster? Could you explain this?
    – Chan
    Jan 16, 2011 at 21:41
  • 1
    @DeadMG: std::qsort requires "The return value of this function should represent whether elem1 is considered less than, equal to, or greater than elem2 by returning, respectively, a negative value, zero or a positive value." operator< does not meet that requirement (specifically it returns only 0 or 1). Check to make sure that std::sort and std::qsort produce the same results in your testing :) (Just changing - to < results in qsort returning the wrong answer for me) Jan 17, 2011 at 0:04

I am surprised that no one mentions caches.

In your code, you start by touching ary and *ary_copy* so they are resident in the cache at the time of qsort. During qsort, *ary_copy* might get evicted. At the time of std::sort, the elements would have to be fetched from memory or a larger (read slower) cache level. This will of course depend on your cache sizes.

Try to reverse the test, i.e., start by running std::sort.

As some people have pointed out; making the array larger will make the test more fair. The reason is that a large array is less likely to fit in cache.

  • 6
    I am surprised no one mentioned any strategies to measure the actual effectiveness of the code. You can write a tiny program that sorts a few hundred elements, get everything loaded into your L1 cache, and rip through that in record time, but that is in no way going to reflect your actual program running on a system with a few hundred other active processes, doing context switches because you're compute-bound and the scheduler hates you, while sorting a dataset the size of New Jersey. Make your benchmark look much like the real application.
    – Wexxor
    Jul 12, 2013 at 22:37

The two sorting algorithms, without optimizations enabled, should have comparable performance. The reason that the C++ sort tends to appreciably beat qsort is that the compiler can inline the comparisons being made, since the compiler has type information about what function is being used to perform the comparison. Did you run these tests with optimization enabled? If not, try turning it on and running this test again.

  • Thanks! I'm using Visual Studio, and I really don't know how to turn optimization on.
    – Chan
    Jan 16, 2011 at 21:24
  • 3
    @Chan: Switch to using the "Release" build. Also make sure you don't run the program from whithin visual studio for your benchmarks -- things like debuggers will change the time characteristics of your program. Jan 16, 2011 at 21:24
  • @Billy ONeal: I switched to Release, and I got the expected result. Happy ^_^ !
    – Chan
    Jan 16, 2011 at 21:28

Another reason that qsort may perform much better than expected is that newer compilers can inline and optimize through the function pointer.

If the C header defines an inline implementation of qsort instead of implementing it inside of a library and the compiler supports indirect function inlining, then qsort can be just as fast as std::sort.


On my machine adding some meat (making the array 10 million elements and moving it in the data section) and compiling with

g++ -Wall -O2 -osortspeed sortspeed.cpp

I get as result

C quick-sort time elapsed: 3.48
C++ quick-sort time elapsed: 1.26

Be also careful about modern "green" CPUs that may be configured to run at a variable speed depending on the load of the system. When benchmarking, this kind of behavior can drive you crazy (on my machine I've a small script that fixes CPU clock that I use when making speed tests).

  • 6
    "Green" CPUs don't matter if you're using performance counters (as you should be doing for meaningful benchmark results) Jan 16, 2011 at 21:50
  • Performance counters are great, but clock is not that bad if you're not trying to measure small stuff. Also clock() is per-process, perf counters are global.
    – 6502
    Jan 16, 2011 at 21:59
  • 2
    @6502: You have that reversed. Perf counters are per process, clock is global. Jan 16, 2011 at 23:49
  • @Billy ONeal: I thought you meant RDTSC and that's very nice but global. And no, clock() is a per-process counter. See cs.utah.edu/dept/old/texinfo/glibc-manual-0.02/library_19.html
    – 6502
    Jan 17, 2011 at 0:29
  • 1
    @6502: glibc != standard c. Usually I believe these things are implemented in terms of rdtsc, but the OS keeps track of what the timestamps are when it performs a context switch, and restores these values when the context is given back to the process being measured. Jan 17, 2011 at 0:35

Writing accurate benchmarks is difficult, so let's get Nonius to do it for us! Let's test qsort, std::sort with no inlining, and std::sort with inlining (the default) on a vector of a million random integers.

// sort.cpp
#include <nonius.h++>
#include <random>
#include <algorithm>

// qsort
int comp(const void* a, const void* b) {
    const int arg1 = *static_cast<const int*>(a);
    const int arg2 = *static_cast<const int*>(b);

    // we can't simply return a - b, because that might under/overflow
    return (arg1 > arg2) - (arg1 < arg2);

// std::sort with no inlining
struct compare_noinline {
    __attribute__((noinline)) bool operator()(const int a, const int b) {
        return a < b;

// std::sort with inlining
struct compare {
    // the compiler will automatically inline this
    bool operator()(const int a, const int b) {
        return a < b;

std::vector<int> gen_random_vector(const size_t size) {

    std::random_device seed;
    std::default_random_engine engine{seed()};
    std::uniform_int_distribution<int> dist{std::numeric_limits<int>::min(), std::numeric_limits<int>::max()};

    std::vector<int> vec;
    for (size_t i = 0; i < size; i += 1) {
        const int rand_int = dist(engine);

    return vec;

// generate a vector of a million random integers
constexpr size_t size = 1'000'000;
static const std::vector<int> rand_vec = gen_random_vector(size);

NONIUS_BENCHMARK("qsort", [](nonius::chronometer meter) {

    // Nonius does multiple runs of the benchmark, and each one needs a new
    // copy of the original vector, otherwise we'd just be sorting the same
    // one over and over
    const size_t runs = static_cast<size_t>(meter.runs());
    std::vector<std::vector<int>> vectors{runs};
    std::fill(vectors.begin(), vectors.end(), rand_vec);

    meter.measure([&](const size_t run) {

        std::vector<int>& current_vec = vectors[run];

        std::qsort(current_vec.data(), current_vec.size(), sizeof(int), comp);

        return current_vec;

NONIUS_BENCHMARK("std::sort noinline", [](nonius::chronometer meter) {

    const size_t runs = static_cast<size_t>(meter.runs());
    std::vector<std::vector<int>> vectors{runs};
    std::fill(vectors.begin(), vectors.end(), rand_vec);

    meter.measure([&](const size_t run) {

        std::vector<int>& current_vec = vectors[run];

        std::sort(current_vec.begin(), current_vec.end(), compare_noinline{});

        return current_vec;


NONIUS_BENCHMARK("std::sort inline", [](nonius::chronometer meter) {

    const size_t runs = static_cast<size_t>(meter.runs());
    std::vector<std::vector<int>> vectors{runs};
    std::fill(vectors.begin(), vectors.end(), rand_vec);

    meter.measure([&](const size_t run) {

        std::vector<int>& current_vec = vectors[run];

        std::sort(current_vec.begin(), current_vec.end(), compare{});

        return current_vec;


Compiling with Apple Clang 7.3.0,

$ clang++ -std=c++14 -stdlib=libc++ -O3 -march=native sort.cpp -o sort
$ ./sort

and running it on my 1.7 GHz i5 Macbook Air, we get

qsort                211 ms +/- 6 ms
std::sort noinline   127 ms +/- 5 ms
std::sort inline      87 ms +/- 4 ms

So std::sort with no inlining is about 1.7x faster than qsort (perhaps due to different sorting algorithms), and inlining bumps that up to about 2.4x faster. Certainly an impressive speedup, but much less than 670%.

  • 1
    Can this be a case when CPU caches values so consectutive access to them is much faster, so if you, for example, will run std::sort test before qsort it will show that qsort is faster? Feb 6, 2021 at 14:39

Why there's no one mentions that extra memory fetch in the C standard library's compare function?

In the C standard library, void* is used to hold all types of member data, which means that when the member data is actually accessed, the void* pointer must be performed once additional dereference.

struct list {
        void *p_data; // deference this pointer when access real data
        struct list *prev;
        struct list *next;

However, in STL, with the help of template's code generation capabilities, member data saved with void* in the C standard library can be directly placed inside the type, avoiding additional dereferences during access.

template <typename T>
class list {
        T data; // access data directly
        list *prev;
        list *next;

So, in theory, std::sort is faster than qsort.


I am not sure with 670% faster. It must have been a specific dataset tailored to show the speed of std::sort. In general, std::sort is indeed faster than qsort because of a couple of these things:

  1. qsort operates on void*, which first requires a dereference, and second requires the size of the data type to perform the swaps. Therefore, the swap operation of qsort is done every byte. Look at qsort implementation and notice its SWAP macro is a loop. Here's the video by Jon Bentley explaining the timing differences (starts at 45m): https://www.youtube.com/watch?v=aMnn0Jq0J-E&t=2700s

  2. The inline may make it speed up a bit, but that's micro-optimization, not the major contributor.

  3. std::sort is actually a hybrid algorithm called Introsort. C qsort is a pure quicksort implementation. Given a dataset that's terrible for quicksort, std::sort changes to heapsort instead. So if you create a bad input for qsort, it will be unbearably slow.

  4. The profiling code above is insufficient. Input size should be increased. 100K is hardly enough. Increase it to 1M or 10M, then repeat the sorting multiple times then take the average or median. If necessary, compile them into a separate binary and run them separately.

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