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How can I get the Windows system time with millisecond resolution?

If the above is not possible, then how can I get the operating system start time? I would like to use this value together with timeGetTime() in order to compute a system time with millisecond resolution.

Thank you in advance.

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7 Answers 7

up vote 2 down vote accepted

GetTickCount will not get it done for you.

Look into QueryPerformanceFrequency / QueryPerformanceCounter. The only gotcha here is CPU scaling though, so do your research.

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QPC is not what I want. I want the system time with millisecond precision, not a timer. –  axilmar Sep 20 '10 at 12:09
    
Power saving (even just idle power saving) and Turbo Boost play merry hell with QPF. It used to be very effective, but with modern CPUs it's no good anymore. –  Ben Voigt Sep 20 '10 at 13:12
    
"The only gotcha here is CPU scaling" - not true. These functions don't cope with systems where the Hardware Abstraction Layer hasn't synchronised the TSC values across cores/cpus: that can be a several-second delta. It bites when one sample is taken on one core, then compared to a sample taken on another core. There are workarounds for multi-core use, but none I've seen packaged up in a publicly available library. You can bind your thread to a single core, but sometimes that's more destructive than the timing is useful. –  Tony D Feb 12 '13 at 1:47

Try this article from MSDN Magazine. It's actually quite complicated.

Implement a Continuously Updating, High-Resolution Time Provider for Windows

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I do not want a timer, I want the system time with millisecond precision. –  axilmar Sep 20 '10 at 12:12
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Did you read the article? That what it is about! This guy did exactly what you are asking and shows how it is done including code. –  Kevin Gale Sep 21 '10 at 17:17
    
You would think I would deserve at least one vote up for being the only one to provide a solution even if it is probably more complicated than people wanted to hear. :-) –  Kevin Gale Sep 21 '10 at 17:26
    
I up voted... I can't get the code on that site to work though. It locks my PC hard most of the time. Sometimes it works and when it does, it's dead accurate on a very busy CPU. Still rummanging through the code to see why it won't work. My set up is Win7 Pro 64bit with Visual Studio 2005 and C++ Builder XE. I ported the code to C++ Builder if anyone is interested. Might make for a good open source project ;) –  Eric Jan 24 '11 at 20:29
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The link died for me. web.archive.org/web/20121018065403/http://msdn.microsoft.com/… –  JDong Jan 31 at 5:48

This is an elaboration of the above comments to explain the some of the whys.

First, the GetSystemTime* calls are the only Win32 APIs providing the system's time. This time has a fairly coarse granularity, as most applications do not need the overhead required to maintain a higher resolution. Time is (likely) stored internally as a 64-bit count of milliseconds. Calling timeGetTime gets the low order 32 bits. Calling GetSystemTime, etc requests Windows to return this millisecond time, after converting into days, etc and including the system start time.

There are two time sources in a machine: the CPU's clock and an on-board clock (e.g., real-time clock (RTC), Programmable Interval Timers (PIT), and High Precision Event Timer (HPET)). The first has a resolution of around ~0.5ns (2GHz) and the second is generally programmable down to a period of 1ms (though newer chips (HPET) have higher resolution). Windows uses these periodic ticks to perform certain operations, including updating the system time.

Applications can change this period via timerBeginPeriod; however, this affects the entire system. The OS will check / update regular events at the requested frequency. Under low CPU loads / frequencies, there are idle periods for power savings. At high frequencies, there isn't time to put the processor into low power states. See Timer Resolution for further details. Finally, each tick has some overhead and increasing the frequency consumes more CPU cycles.

For higher resolution time, the system time is not maintained to this accuracy, no more than Big Ben has a second hand. Using QueryPerformanceCounter(QPC) or the CPU's ticks (rdtsc) can provide the resolution between the system time ticks. Such an approach was used in the MSDN magazine article Kevin cited. Though these approaches may have drift (e.g., due to frequency scaling), etc and therefore need to be synced to the system time.

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I like your answer. If its so hard for windows to run with 1ms period then how can Linux do it? –  yan bellavance Jul 27 '11 at 19:23
    
I don't know how well either OS performs with a 1ms period, but both can do it. In any software design, trade offs must be made. Should the code be designed for a 1ms period or 16ms (specifically 15.625ms)? Even then, some design points will execute better. –  Brian Aug 12 '11 at 2:05

GetSystemTimeAsFileTime gives the best precision of any Win32 function for absolute time. QPF/QPC as Joel Clark suggested will give better relative time.

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Isn't there anything better than GetSystemTimeAsFileTime? the get-system-time functions have a precision of 10 to 15 milliseconds. –  axilmar Sep 20 '10 at 12:11
    
That's the accuracy, not precision. And a call to timeBeginPeriod(1); will set the accuracy to 1ms. –  Ben Voigt Sep 20 '10 at 13:10
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Ok, it's the accuracy then (I always mix those two since in my language there is only one word that represents both). Is there a way to get the system time in Windows with 1 millisecond accuracy? I am using timeBeginPeriod(1), but the time is still returned with 10-15 milliseconds accuracy. –  axilmar Sep 21 '10 at 9:39

QueryPerformanceCounter() is built for fine-grained timer resolution.

It is the highest resolution timer that the system has to offer that you can use in your application code to identify performance bottlenecks

Here is a simple implementation for C# devs:

    [DllImport("kernel32.dll")]
    extern static short QueryPerformanceCounter(ref long x);
    [DllImport("kernel32.dll")]
    extern static short QueryPerformanceFrequency(ref long x);
    private long m_endTime;
    private long m_startTime;
    private long m_frequency;

    public Form1()
    {
        InitializeComponent();
    }
    public void Begin()
    {
        QueryPerformanceCounter(ref m_startTime);
    }
    public void End()
    {
        QueryPerformanceCounter(ref m_endTime);
    }

    private void button1_Click(object sender, EventArgs e)
    {
        QueryPerformanceFrequency(ref m_frequency);
        Begin();
        for (long i = 0; i < 1000; i++) ;
        End();
        MessageBox.Show((m_endTime - m_startTime).ToString());
    }

If you are a C/C++ dev, then take a look here: http://support.microsoft.com/kb/815668

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From the support article "•The API call may fail under some circumstances. Check the return value, and then adjust your application code to make sure that you receive valid results." - yeah well. Those functions have many well documented problems, including problems as CPU speeds vary due to power saving modes, and unsynchronised TSC registers across cores. –  Tony D Feb 12 '13 at 1:53

Well, this one is very old, yet there is another useful function in Windows C library _ftime, which returns a structure with local time as time_t, milliseconds, timezone, and daylight saving time flag.

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I've written up some information about how to implement this quickly and easily, in a manner suitable for most purposes, in my answer to the "Microsecond resolution timestamps on Windows" question.

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