It seems like CRITICAL_SECTION performance became worse on Windows 8 and higher. (see graphs below)

The test is pretty simple: some concurrent threads do 3 million locks each to access a variable exclusively. You can find the C++ program at the bottom of the question. I run the test on Windows Vista, Windows 7, Windows 8, Windows 10 (x64, VMWare, Intel Core i7-2600 3.40GHz).

The results are on the image below. The X-axis is the number of concurrent threads. The Y-axis is the elapsed time in seconds (lower is better).

Test results

What we can see:

  • SRWLock performance is approximately the same for all platforms
  • CriticalSection performance became worse relatively SRWL on Windows 8 and higher

The question is: Can anybody please explain why did CRITICAL_SECTION performance become worse on Win8 and higher?

Some notes:

  • The results on real machines are pretty the same - CS is much worse than both std::mutex, std::recursive_mutex and SRWL on Win8 and higher. However I have no chance to run the test on different OSes with the same CPU.
  • std::mutex implementation for Windows Vista is based on CRITICAL_SECTION, but for Win7 and higher std::mutex is based on SWRL. It is correct for both MSVS17 and 15 (To make sure search for primitives.h file at MSVC++ installation and look for stl_critical_section_vista and stl_critical_section_win7 classes) This explains the difference between std::mutex performance on Win Vista and others.
  • As it is said in comments, the std::mutex is a wrapper, so the possible explanation for some overhead relatively SRWL may be overhead introduced by the wrapper code.

#include <chrono>
#include <iostream>
#include <mutex>
#include <string>
#include <thread>
#include <vector>

#include <Windows.h>

const size_t T = 10;
const size_t N = 3000000;
volatile uint64_t var = 0;

const std::string sep = ";";

namespace WinApi
    class CriticalSection
        CriticalSection() { InitializeCriticalSection(&cs); }
        ~CriticalSection() { DeleteCriticalSection(&cs); }
        void lock() { EnterCriticalSection(&cs); }
        void unlock() { LeaveCriticalSection(&cs); }

    class SRWLock
        SRWLOCK srw;
        SRWLock() { InitializeSRWLock(&srw); }
        void lock() { AcquireSRWLockExclusive(&srw); }
        void unlock() { ReleaseSRWLockExclusive(&srw); }

template <class M>
void doLock(void *param)
    M &m = *static_cast<M*>(param);
    for (size_t n = 0; n < N; ++n)
        var += std::rand();

template <class M>
void runTest(size_t threadCount)
    M m;
    std::vector<std::thread> thrs(threadCount);

    const auto start = std::chrono::system_clock::now();

    for (auto &t : thrs) t = std::thread(doLock<M>, &m);
    for (auto &t : thrs) t.join();

    const auto end = std::chrono::system_clock::now();

    const std::chrono::duration<double> diff = end - start;
    std::cout << diff.count() << sep;

template <class ...Args>
void runTests(size_t threadMax)
        int dummy[] = { (std::cout << typeid(Args).name() << sep, 0)... };
    std::cout << std::endl;

    for (size_t n = 1; n <= threadMax; ++n)
            int dummy[] = { (runTest<Args>(n), 0)... };
        std::cout << std::endl;

int main()
    runTests<std::mutex, WinApi::CriticalSection, WinApi::SRWLock>(T);
    return 0;

The test project was built as Windows Console Application on Microsoft Visual Studio 17 (15.8.2) with the folowing settings:

  • Use of MFC: Use MFC in a Static Library
  • Windows SDK Version: 10.0.17134.0
  • Platform Toolset: Visual Studio 2017 (v141)
  • Optimization: O2, Oi, Oy-, GL
  • There are some differences in semantics between SRWLock and Critical Section, have a read of: stackoverflow.com/questions/3498798/… – Richard Critten Sep 4 '18 at 16:52
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    I had a quick look at std::mutex implementation in my environment (Win7, VS2015) -- there is one layer of indirection on top of whatever OS primitive chosen by std::mutex (see _Mtx_storage + _Mtx_init_in_situ/etc functions used to operate the primitive). This may explain some of observed performance reduction. – C.M. Sep 4 '18 at 17:22
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    @Rom098 It is shared state between threads with semantics undefined by the C++ standard. In code attempting to profile multi-threaded performance. – Yakk - Adam Nevraumont Sep 4 '18 at 17:37
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    @Yakk-AdamNevraumont In general the standard says that rand is not thread safe. Do you mean the rand() call under the locked mutex is not thread-safe enough? Anyway I did experiments with “var += 1” and others, and the results are the same. – Rom098 Sep 4 '18 at 18:36
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    Regarding the discussion surrounding srand/rand, visual c++ uses a thread-local random seed so having two threads executing rand() at the same time will not interfere with each other. But also note this means that each thread needs to call srand to initialize the RNG. – SoronelHaetir Sep 4 '18 at 18:44

See Windows Critical Section - how to disable spinning completely Starting from Windows 8, Microsoft changed implementation (without even a word in documentation) of default behavior of Critical Section (if you use InitializeCriticalSection(&cs), you will get spinning with undocumented dynamic spin adjustment algorithm enabled). See my comment here: https://randomascii.wordpress.com/2012/06/05/in-praise-of-idleness/#comment-57420

For your test, try using InitializeCriticalSectionAndSpinCount(&cs,1) instead of InitializeCriticalSection(&cs). This should make it behave somewhat similar to Windows 7, though there are plenty of other changes in that area.

  • What are other changes in that area you refer to? I know there were a lot of changes throughout history, like adding keyed events, or changing from fair algorithm to unfair, but I don't know any other changes between Windows 7 and Windows 10, except this automatic spin. – Alex Guteniev Mar 2 '19 at 7:23
  • Actually it's somewhere between std::mutex and CriticalSection in case I use InitializeCriticalSectionAndSpinCount(&cs,1), but it's still much closer to CriticalSection. So your explanation doesn't look like the root cause. – Rom098 Mar 6 '19 at 10:09
  • @Rom098 any luck solving the mystery? Maybe mark this as the answer. It sheds pretty much light on the case, even if not explaining that in 100%. – quetzalcoatl Jun 26 '20 at 20:11
  • @quetzalcoatl As I mentioned before, this answer doesn't seem like the root cause. The most possible reason is there was some problem in Windows updates. As far as I know (but I'm not sure) the problem can't be reproduced now with all the latest updates installed. – Rom098 Jul 3 '20 at 13:28

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