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I have been reading the book of Windows via C/C++. In chapter 8,page 215,the author compared the performance of synchronization mechanism. And I found the poor performance of mutex.When 4 threads run simultaneously, it spent more than twenty three seconds for the mutex synchronization.

Why is the Win32 mutex so time-consuming? And when can we use a mutex?

PS: I posted the test code in GitHub: https://gist.github.com/985198

Thanks for your replies.

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4  
Spends more than twenty three seconds over how long? That value means nothing without context –  Rob May 22 '11 at 5:27
    
If you write a benchmark that creates several threads that all try to acquire the same mutex, you will find that the performance goes down the tubes. Such a benchmark is usually not reflective of real-world programs. –  Dietrich Epp May 22 '11 at 5:29
    
@Dietrich Epp : I wonder what make the performance of mutex goes down the tubes.And In real-world programs,how should we use the mutex? –  thinkhy May 22 '11 at 6:24
    
@thinkthy: The performance goes down the tubes because you have several processors trying to simultaneously access the same mutex. This happens whether you use critical sections, mutexes, or atomic variables — the performance of all of them goes down. This doesn't matter as much in most real world programs because real world programs spend most of their time doing work instead of acquiring mutexes. As for how to use the mutex — use it when it is necessary. –  Dietrich Epp May 22 '11 at 6:31
    
Note that this is twenty three seconds for four million mutex synchronizations, not four. (According to the posted code) –  Billy ONeal May 22 '11 at 6:53

3 Answers 3

up vote 8 down vote accepted

A mutex in Win32 is a kernel object, meaning that every use of it (Wait, Release) requires a system call that switches into kernel mode and back to user mode. Plus if your thread actually has to wait for the mutex, it loses its quantum while another thread that can run gets scheduled on the CPU. On WinXP and earlier (and maybe some later versions of Windows), mutexes were "fair", meaning that if your thread was last to wait for a mutex, it would be the last to receive it, further increasing the potential for contention.

The reasons to use a mutex are that you can easily share them between processes, you can be notified when the thread owning it is killed, and you can wait on them along with other objects using WaitForMultipleObjects.

Note that your use of them in this benchmark is not the ideal way to use them because the overhead of just acquiring a mutex is way more than the amount of work you're doing.

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Because mutexes are kernel objects, all operations on them require a context switch. Such operations are relatively expensive. The rule of thumb is that when you need share resources between threads in the same process, use CRITICAL_SECTION objects. When you need to share resources between threads in different processes, then use Win32 mutexes.

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@Dietruch: In NT land "Kernel Object" has specific semantics -- namely that it's managed by the NT Object Manager -- not that "the kernel touches it". Jorgen's answer is correct. –  Billy ONeal May 22 '11 at 5:30
    
@Dietrich Epp: A futex in Linux is CRITICAL_SECTION in Windows. –  hackworks May 22 '11 at 5:33
    
This operation of context switch does takes time, but it is unimaginable that synchronization time for just four threads took over 23 seconds (My CPU is Core 2 Duo T7100). –  thinkhy May 22 '11 at 5:35
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@hackworks, no, a futex in Linux is a keyed event in windows (used in Vista's SRW locks). A CRITICAL_SECTION is an atomic compare-exchange fastpath coupled with a Mutex-based (or Event-based, etc) slow path. –  bdonlan May 22 '11 at 6:03
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@Billy: I wrote a program that does nothing but Wait on a mutex and Release it in a tight loop. It was able to do 700k wait/release cycles per second, or 1.4M calls/sec. While running it, I monitored the number of context switches/sec for the main thread, and it averaged about 130/sec, which is about what you'd expect for a system with a 10ms thread quantum. –  Gabe May 22 '11 at 16:46

CRITICAL_SECTION is a spinlock which spins in userspace to acquire a lock. If it fails to get the lock at the end of spinning (limited by spin count), it gets into an wake-able wait (WaitForSingleObject()). Hence, for short sections of code you want to protect (critical section name comes from it) CRITICAL_SECTION is the way to go. If you plan to do IO and other time consuming tasks, CRITICAL_SECTION versus mutex/semaphore does not give you any savings.

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It does not create a mutex or semaphore. It simply yields. (e.g. by calling sleep(0). –  Billy ONeal May 22 '11 at 5:31
    
@Billy ONeal: The following link msdn.microsoft.com/en-us/library/ms683476(v=vs.85).aspx says it calls a WaitForSingleObject(). Not sure if is specific to heap or CRITICAL_SECTION from the link though. –  hackworks May 22 '11 at 5:38
    
@Hackworks: WaitForSingleObject does not create a mutex or semaphore. It simply yields. –  Billy ONeal May 22 '11 at 5:39
    
@Billy ONeal: I get it, thanks. It executes a wait on some other kernel object since WaitForSingleObject() requires one. Wonder what that kernel object is though? –  hackworks May 22 '11 at 5:42
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@Billy: It's actually an event that it creates. See msdn.microsoft.com/en-us/library/ff542796(v=VS.85).aspx for a flag that lets you have the events created when CRITICAL_SECTION objects are created rather than once the spin count runs out. –  Gabe May 22 '11 at 6:23

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