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I recently decided that I needed to change from using milliseconds to microseconds for my Timer class, and after some research I've decided that QueryPerformanceCounter is probably my safest bet. (The warning on Boost::Posix that it may not works on Win32 API put me off a bit). However, I'm not really sure how to implement it.

What I'm doing is calling whatever GetTicks() esque function I'm using and assigning it to Timer's startingTicks variable. Then to find the amount of time passed I just subtract the function's return value from the startingTicks, and when I reset the timer I just call the function again and assign startingTicks to it. Unfortunately, from the code I've seen it isn't as simple as just calling QueryPerformanceCounter(), and I'm not sure what I'm supposed to pass as its argument.

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I've taken Ramonster's code snippets and made them into a library here: for followers. – rogerdpack Aug 18 '11 at 1:13
We've recently updated the documentation for QueryPerformanceCounter, and added additional information proper usage, and answers to FAQ. You can find the updated documentation here… – Ed Briggs Feb 20 '14 at 16:12
up vote 108 down vote accepted
#include <windows.h>

double PCFreq = 0.0;
__int64 CounterStart = 0;

void StartCounter()
	cout << "QueryPerformanceFrequency failed!\n";

    PCFreq = double(li.QuadPart)/1000.0;

    CounterStart = li.QuadPart;
double GetCounter()
    return double(li.QuadPart-CounterStart)/PCFreq;

int main()
    cout << GetCounter() <<"\n";
    return 0;

This program should output a number close to 1000 (windows sleep isn't that accurate, but it should be like 999).

The StartCounter() function records the number of ticks the performance counter has in the CounterStart variable. The GetCounter() function returns the number of milliseconds since StartCounter() was last called as a double, so if GetCounter() returns 0.001 then it has been about 1 microsecond since StartCounter() was called.

If you want to have the timer use seconds instead then change

PCFreq = double(li.QuadPart)/1000.0;


PCFreq = double(li.QuadPart);

or if you want microseconds then use

PCFreq = double(li.QuadPart)/1000000.0;

But really it's about convenience since it returns a double.

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Exactly, what is LARGE_INTEGER? – Anonymous Nov 15 '09 at 23:26
it's a windows type, basically a portable 64 bit integer. It's definition depends on whether the target system supports 64 bit integers or not. If the system doesn't support 64 bit ints then it's defined as 2 32 bit ints, a HighPart and a LowPart. If the system does support 64 bit ints then it's a union between the 2 32 bit ints and a 64 bit int called the QuadPart. – Ramónster Nov 15 '09 at 23:28
This answer's badly flawed. QueryPerformanceCounter reads a core specific cycle counter register, and if the thread of execution has been rescheduled on another core, two measurements from QueryPerformanceCounter incorporate not only elapsed time, but often a fixed, large and hard to pinpoint delta between the two cores registers. So - this only works reliably as presented if your process is bound to a specific core. – Tony D Mar 1 '12 at 8:36
@TonyD: MSDN documentation says: On a multiprocessor computer, it should not matter which processor is called. However, you can get different results on different processors due to bugs in the basic input/output system (BIOS) or the hardware abstraction layer (HAL). This code isn't badly flawed, but some BIOS or HAL. – Lucas May 22 '13 at 10:32
@TonyD: I just looked into this a little bit more. I added the following call into the StartCounter function: old_mask = SetThreadAffinityMask(GetCurrentThread,1); and then set it back at the end SetThreadAffinityMask ( GetCurrentThread , old_mask ) ;. I hope that will do the trick. This should prevent my thread from getting rescheduled to anything but the 1st CPU core. (Which is obviously only a solution for a testing environment) – Lucas May 22 '13 at 11:04

I use these defines:

/** Use to init the clock */
#define TIMER_INIT \
    LARGE_INTEGER frequency; \
    LARGE_INTEGER t1,t2; \
    double elapsedTime; \

/** Use to start the performance timer */
#define TIMER_START QueryPerformanceCounter(&t1);

/** Use to stop the performance timer and output the result to the standard stream. Less verbose than \c TIMER_STOP_VERBOSE */
#define TIMER_STOP \
    QueryPerformanceCounter(&t2); \
    elapsedTime=(float)(t2.QuadPart-t1.QuadPart)/frequency.QuadPart; \
    std::wcout<<elapsedTime<<L" sec"<<endl;

Usage (brackets to prevent redefines):




Output from usage example:

1.00003 sec
1.23407 sec
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Assuming you're on Windows (if so you should tag your question as such!), on this MSDN page you can find the source for a simple, useful HRTimer C++ class that wraps the needed system calls to do something very close to what you require (it would be easy to add a GetTicks() method to it, in particular, to do exactly what you require).

On non-Windows platforms, there's no QueryPerformanceCounter function, so the solution won't be directly portable. However, if you do wrap it in a class such as the above-mentioned HRTimer, it will be easier to change the class's implementation to use what the current platform is indeed able to offer (maybe via Boost or whatever!).

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I would extend this question with a NDIS driver example on getting time. As one knows, KeQuerySystemTime (mimicked under NdisGetCurrentSystemTime) has a low resolution above milliseconds, and there are some processes like network packets or other IRPs which may need a better timestamp;

The example is just as simple:

LONG_INTEGER data, frequency;
data = KeQueryPerformanceCounter((LARGE_INTEGER *)&frequency)
diff = data.QuadPart / (Frequency.QuadPart/$divisor)

where divisor is 10^3, or 10^6 depending on required resolution.

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