Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

On Windows, you have a problem you typically never encounter on Unix. That is how to get a thread to sleep for less than one millisecond. On Unix you typically have a number of choices (sleep, usleep and nanosleep) to fit your needs. On Windows, however, there is only Sleep with millisecond granularity. You can, however, use the select system call to create a microsecond sleep. On Unix, this is pretty straightforward:

int usleep(long usec)
{
    struct timeval tv;
    tv.tv_sec = usec/1000000L;
    tv.tv_usec = usec%1000000L;
    return select(0, 0, 0, 0, &tv);
}

On Windows, however, the use of select forces you to include the Winsock library which has to be initialized like this in your application:

WORD wVersionRequested = MAKEWORD(1,0);
WSADATA wsaData;
WSAStartup(wVersionRequested, &wsaData);

And then the select won't allow you to be called without any socket so you have to do a little more to create a microsleep method:

int usleep(long usec)
{
    struct timeval tv;
    fd_set dummy;
    SOCKET s = socket(PF_INET, SOCK_STREAM, IPPROTO_TCP);
    FD_ZERO(&dummy);
    FD_SET(s, &dummy);
    tv.tv_sec = usec/1000000L;
    tv.tv_usec = usec%1000000L;
    return select(0, 0, 0, &dummy, &tv);
}

All these created usleep methods return zero when successful and non-zero for errors.

share|improve this question
33  
and your question was? –  tialaramex Sep 17 '08 at 16:54
    
This does not work on Windows. The minimum "sleep" time with select is still approx 1 ms (Vista, RT thread, timeBeginPeriod(1), MMCSS "Pro Audio" RT Critical). –  Robert Jul 20 '11 at 16:54
6  
This is due to the fact that most machines Windows runs on have hardware limits in the 1-10ms range. PC Computer Hardware is cheap. You need to have dedicated hardware to keep accurate time. WiFi Cards for example: sub millisecond beacon timing must remain in hardware (even under Linux) due to the unreliability of a PC timekeeping. –  unixman83 Sep 21 '11 at 21:14
3  
Linux can run on complex and embedded devices, which can provide for better granularity than most Windows PCs. The kernel itself, being open source, is also very customizable. Its scheduler can be made a near-real-time OS. Hence the need for nanosleep(). –  unixman83 Sep 21 '11 at 21:18
    
@tialaramex, I know this is an old question, but I just can't help but laugh at your comment. :) –  Thayananthan Nov 7 '12 at 14:53

15 Answers 15

This indicates a mis-understanding of sleep functions. The parameter you pass is a minimum time for sleeping. There's no guarantee that the thread will wake up after exactly the time specified. In fact, threads don't 'wake up' at all, but are rather chosen for execution by the scheduler. The scheduler might choose to wait much longer than the requested sleep duration to activate a thread, especially if another thread is still active at that moment.

share|improve this answer
2  
Yes, Sleep() just means a hint. According to MSDN the Sleep() time can actually be less than what you request. It's just a guide to the OS to improve performance, not really a good timing mechanism, at any granularity. –  unixman83 Sep 21 '11 at 21:08
1  
However, the guarantee can be obtained by careful implementation. Proper setting of thread/process priorities and processor affinities are dicussed here. –  Arno Sep 26 '12 at 16:17
3  
There's serious misinformation here: "The parameter you pass is a minimum time for sleeping." Not true for windows: msdn.microsoft.com/en-gb/library/windows/desktop/… If dwMilliseconds is less than the resolution of the system clock, the thread may sleep for less than the specified length of time. If dwMilliseconds is greater than one tick but less than two, the wait can be anywhere between one and two ticks, and so on. –  Roddy Nov 7 '12 at 19:33
    
Outstanding answer to a not existing question. Despite of the fact, that every answer to no question is correct, this one is really good. –  Kenyakorn Ketsombut Sep 11 '13 at 7:27

As Joel says, you can't meaningfully 'sleep' (i.e. relinquish your scheduled CPU) for such short periods. If you want to delay for some short time, then you need to spin, repeatedly checking a suitably high-resolution timer (e.g. the 'performance timer') and hoping that something of high priority doesn't pre-empt you anyway.

If you really care about accurate delays of such short times, you should not be using Windows.

share|improve this answer
10  
+1 for '... you should not be using Windows.' –  Thomas Matthews Jul 27 '12 at 19:54
    
-1 for not considering the user of the application may have different preferences then the developers. –  Austin Mullins Jun 12 at 14:34
    
@AustinMullins Can you elaborate on that point a bit? Were you looking for some statement about the evils of busy-spinning? –  Will Dean Jun 18 at 11:48
    
No, I was referring to the "you should not be using Windows" remark. The developer should make programs for the user, who probably wants the program to work in Windows. –  Austin Mullins Jun 18 at 11:59
2  
Oh, I see. Well, if either the developer or his users foresee a hard real-time requirement as described in the question, then Windows is not the OS that either of them should be trying to use. That's neither a pejorative comment on Windows nor a licence for developer hubris, just an opinion on technical suitability, which (as a Windows developer :-) I'm happy to stand by. –  Will Dean Jun 18 at 14:28

Yes, you need to understand your OS' time quantums. On Windows, you won't even be getting 1ms resolution times unless you change the time quantum to 1ms. (Using for example timeBeginPeriod()/timeEndPeriod()) That still won't really guarantee anything. Even a little load or a single crappy device driver will throw everything off.

SetThreadPriority() helps, but is quite dangerous. Bad device drivers can still ruin you.

You need an ultra-controlled computing environment to make this ugly stuff work at all.

share|improve this answer

Use the high resolution timers available in winmm.lib. See this for an example.

share|improve this answer

What are you waiting for that requires such precision? In general if you need to specify that level of precision (e.g. because of a dependency on some external hardware) you are on the wrong platform and should look at a real time OS.

Otherwise you should be considering if there is an event you can synchronize on, or in the worse case just busy wait the CPU and use the high performance counter API to measure the elapsed time.

share|improve this answer

As several people have pointed out, sleep and other related functions are by default dependent on the "system tick". This is the minimum unit of time between OS tasks; the scheduler, for instance, will not run faster than this. Even with a realtime OS, the system tick is not usually less than 1 ms. While it is tunable, this has implications for the entire system, not just your sleep functionality, because your scheduler will be running more frequently, and potentially increasing the overhead of your OS (amount of time for the scheduler to run, vs. amount of time a task can run).

The solution to this is to use an external, high-speed clock device. Most Unix systems will allow you to specify to your timers and such a different clock to use, as opposed to the default system clock.

share|improve this answer

If you want so much granularity you are in the wrong place (in user space). Remember that if you are in user space your time is not always précis. The scheduler can start your thread (or app), and schedule it, so you are depending by the OS scheduler . If you are looking for something precisely you have to go: 1) In kernel space (like drivers) 2) Choose an RTOS. Anyway if you are looking for some granularity (but remember the problem with user space ) look to QueryPerformanceCounter Function and QueryPerformanceFrequency function in MSDN.

share|improve this answer

Generally a sleep will last at least until the next system interrupt occurs. However, this depends on settings of the multimedia timer resources. It may be set to something close to 1 ms, some hardware even allows to run at interrupt periods of 0.9765625 (ActualResolution provided by NtQueryTimerResolution will show 0.9766 but that's actually wrong. They just can't put the correct number into the ActualResolution format. It's 0.9765625ms at 1024 interrupts per second).

There is one exception wich allows us to escape from the fact that it may be impossible to sleep for less than the interrupt period: It is the famous Sleep(0). This is a very powerful tool and it is not used as often as it should! It relinquishes the reminder of the thread's time slice. This way the thread will stop until the scheduler forces the thread to get cpu service again. Sleep(0) is an asynchronous service, the call will force the scheduler to react independent of an interrupt.

A second way is the use of a waitable object. A wait function like WaitForSingleObject() can wait for an event. In order to have a thread sleeping for any time, also times in the microsecond regime, the thread needs to setup some service thread which will generate an event at the desired delay. The "sleeping" thread will setup this thread and then pause at the wait function until the service thread will set the event signaled.

This way any thread can "sleep" or wait for any time. The service thread can be of big complexity and it may offer system wide services like timed events at microsecond resolution. However, microsecond resolution may force the service thread to spin on a high resolution time service for at most one interrupt period (~1ms). If care is taken, this can run very well, particulary on multi-processor or multi-core systems. A one ms spin does not hurt considerably on multi-core system, when the affinity mask for the calling thread and the service thread are carefully handled.

Code, description, and testing can be visited at the Windows Timestamp Project

share|improve this answer

Actually using this usleep function will cause a big memory/resource leak. (depending how often called)

use this corrected version (sorry can't edit?)

bool usleep(unsigned long usec)
{
    struct timeval tv;
    fd_set dummy;
    SOCKET s = socket(PF_INET, SOCK_STREAM, IPPROTO_TCP);
    FD_ZERO(&dummy);
    FD_SET(s, &dummy);
    tv.tv_sec = usec / 1000000ul;
    tv.tv_usec = usec % 1000000ul;
    bool success = (0 == select(0, 0, 0, &dummy, &tv));
    closesocket(s);
    return success;
}
share|improve this answer
    
You do not need to create a socket just to be able to call select() –  Jon Watte Sep 9 '12 at 0:35
    
I fixed the code sample. Be aware that you have to call WSAStartup/WSACleanup before/after using this function when coding under Windows. –  Max Truxa Aug 7 '13 at 7:26

Just use Sleep(0). 0 is clearly less than a millisecond. Now, that sounds funny, but i'm serious. Sleep(0) tells Windows that you don't have anything to do right now, but that you do want to be reconsidered as soon as the scheduler runs again. And since obviously the thread can't be scheduled to run before the scheduler itself runs, this is the shortest delay possible.

Note that you can pass in a microsecond number to your usleep, but so does void usleep(__int64 t) { Sleep(t/1000); } - no guarantees to actually sleeping that period.

share|improve this answer
3  
I think that if you actually try this, you'll find that Sleep(0) usually sleeps for 10-15ms depending on your hardware and system load. –  Dave Moore Sep 19 '08 at 0:02
8  
From MSDN: A value of zero causes the thread to relinquish the remainder of its time slice to any other thread of equal priority that is ready to run. If there are no other threads of equal priority ready to run, the function returns immediately, and the thread continues execution. –  Ferruccio Sep 24 '08 at 10:20

I have the same problem and nothing seems to be faster than a ms, even the Sleep(0). My problem is the communication between a client and a server application where I use the _InterlockedExchange function to test and set a bit and then I Sleep(0).

I really need to perform thousands of operations per second this way and it doesn't work as fast as I planned.

Since I have a thin client dealing with the user, which in turn invokes an agent which then talks to a thread, I will move soon to merge the thread with the agent so that no event interface will be required.

Just to give you guys an idea how slow this Sleep is, I ran a test for 10 seconds performing an empty loop (getting something like 18,000,000 loops) whereas with the event in place I only got 180,000 loops. That is, 100 times slower!

share|improve this answer

Like everybody mentioned there is indeed no guarantees about the sleep time. but nobody wants to admit that sometimes, on an idle system, usleep command can be very precise. Especially with a tickless kernel. Vista has it, linux has it since 2.6.16. tickless kernels exists to help improve laptops batterly life: c.f. intel's powertop utility. In that condition, I happend to have measured linux usleep command that respected the requested sleep time very closely, down to half a dozen of micro seconds. So, maybe OP wants something that will roughly work most of the time on an idling system, and be able to ask for micro second scheduling ! I actually would want that on windows too.

also Sleep(0) sounds like boost::thread::yield(), which terminology is clearer.

I wonder if boost timed locks have a better precision. because then you could just lock on a mutex that nobody ever releases, and when the timeout is reached, continue on... timeouts are set with boost::system_time + boost::milliseconds & cie. (xtime is deprecated)

share|improve this answer

It looks like most answers say it's impossible. I don't think there's a function for it, but if you're in a loop or something, and you don't need precision, you can make the effect of it by doing something like this:

int count = 0;
while (condition) {
    if (count == 5) { // Kind of like sleeping for 0.2 milliseconds
        Sleep(1);
        count = 0;
    }
    // Do whatever.
    count++;
}
share|improve this answer
2  
This answer makes no sense. Your code does not do anything. –  Scott Chamberlain Jul 28 '12 at 21:48
    
Insert you're code at the comment "Do whatever." It will sleep for a millisecond every five in the loop, creating the effect of a 0.2 millisecond Sleep. You might insert std::cout << "Hi! "; or whatever you like at the comment. –  Cosine Jul 28 '12 at 21:56
    
You never do anything to change count away from 0 (at least now I can guess what you are doing now that you added count = 0 inside the if). Also sleep(1) does not give you a 1ms sleep, anything below 15ms will likely round up to 15. Go run the code yourself with a high precision timer and see what happens. –  Scott Chamberlain Jul 28 '12 at 22:01
4  
Sorry for OT, but this just made my day, after tens of superelaborate answers that talk about countless kernels, sockets, boost timers, thread schedulers and just about every intricate possibility there is to wait in Windows, here is just some random code, hey why not, maybe this works :))) The best part is "kind of like sleeping for 0.2 milliseconds", what teh hell is that?? :))) –  Cray Dec 23 '12 at 23:26
up vote 1 down vote accepted

On Windows, however, the use of select forces you to include the Winsock library which has to be initialized like this in your application:

WORD wVersionRequested = MAKEWORD(1,0);
WSADATA wsaData;
WSAStartup(wVersionRequested, &wsaData);

And then the select won't allow you to be called without any socket so you have to do a little more to create a microsleep method:

int usleep(long usec)
{
    struct timeval tv;
    fd_set dummy;
    SOCKET s = socket(PF_INET, SOCK_STREAM, IPPROTO_TCP);
    FD_ZERO(&dummy);
    FD_SET(s, &dummy);
    tv.tv_sec = usec/1000000L;
    tv.tv_usec = usec%1000000L;
    return select(0, 0, 0, &dummy, &tv);
}

All these created usleep methods return zero when successful and non-zero for errors.

share|improve this answer

Try boost::xtime and a timed_wait()

has nanosecond accuracy.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.