bench/BenchSysTimer_windows.cpp - skia - Git at Google


 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */
 #include "BenchSysTimer_windows.h"

 //Time
 #define WIN32_LEAN_AND_MEAN 1
 #include <windows.h>

 static ULONGLONG winCpuTime() {
     FILETIME createTime;
     FILETIME exitTime;
     FILETIME usrTime;
     FILETIME sysTime;
     if (0 == GetProcessTimes(GetCurrentProcess()
                            , &createTime, &exitTime
                            , &sysTime, &usrTime))
     {
         return 0;
     }
     ULARGE_INTEGER start_cpu_sys;
     ULARGE_INTEGER start_cpu_usr;
     start_cpu_sys.LowPart  = sysTime.dwLowDateTime;
     start_cpu_sys.HighPart = sysTime.dwHighDateTime;
     start_cpu_usr.LowPart  = usrTime.dwLowDateTime;
     start_cpu_usr.HighPart = usrTime.dwHighDateTime;
     return start_cpu_sys.QuadPart + start_cpu_usr.QuadPart;
 }

 void BenchSysTimer::startWall() {
     if (0 == ::QueryPerformanceCounter(&this->fStartWall)) {
         this->fStartWall.QuadPart = 0;
     }
 }
 void BenchSysTimer::startCpu() {
     this->fStartCpu = winCpuTime();
 }

 double BenchSysTimer::endCpu() {
     ULONGLONG end_cpu = winCpuTime();
     return static_cast<double>((end_cpu - this->fStartCpu)) / 10000.0L;
 }
 double BenchSysTimer::endWall() {
     LARGE_INTEGER end_wall;
     if (0 == ::QueryPerformanceCounter(&end_wall)) {
         end_wall.QuadPart = 0;
     }

     LARGE_INTEGER ticks_elapsed;
     ticks_elapsed.QuadPart = end_wall.QuadPart - this->fStartWall.QuadPart;

     LARGE_INTEGER frequency;
     if (0 == ::QueryPerformanceFrequency(&frequency)) {
         return 0.0L;
     } else {
         return static_cast<double>(ticks_elapsed.QuadPart)
              / static_cast<double>(frequency.QuadPart)
              * 1000.0L;
     }
 }

	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/
	#include "BenchSysTimer_windows.h"

	//Time
	#define WIN32_LEAN_AND_MEAN 1
	#include <windows.h>

	static ULONGLONG winCpuTime() {
	FILETIME createTime;
	FILETIME exitTime;
	FILETIME usrTime;
	FILETIME sysTime;
	if (0 == GetProcessTimes(GetCurrentProcess()
	, &createTime, &exitTime
	, &sysTime, &usrTime))
	{
	return 0;
	}
	ULARGE_INTEGER start_cpu_sys;
	ULARGE_INTEGER start_cpu_usr;
	start_cpu_sys.LowPart = sysTime.dwLowDateTime;
	start_cpu_sys.HighPart = sysTime.dwHighDateTime;
	start_cpu_usr.LowPart = usrTime.dwLowDateTime;
	start_cpu_usr.HighPart = usrTime.dwHighDateTime;
	return start_cpu_sys.QuadPart + start_cpu_usr.QuadPart;
	}

	void BenchSysTimer::startWall() {
	if (0 == ::QueryPerformanceCounter(&this->fStartWall)) {
	this->fStartWall.QuadPart = 0;
	}
	}
	void BenchSysTimer::startCpu() {
	this->fStartCpu = winCpuTime();
	}

	double BenchSysTimer::endCpu() {
	ULONGLONG end_cpu = winCpuTime();
	return static_cast<double>((end_cpu - this->fStartCpu)) / 10000.0L;
	}
	double BenchSysTimer::endWall() {
	LARGE_INTEGER end_wall;
	if (0 == ::QueryPerformanceCounter(&end_wall)) {
	end_wall.QuadPart = 0;
	}

	LARGE_INTEGER ticks_elapsed;
	ticks_elapsed.QuadPart = end_wall.QuadPart - this->fStartWall.QuadPart;

	LARGE_INTEGER frequency;
	if (0 == ::QueryPerformanceFrequency(&frequency)) {
	return 0.0L;
	} else {
	return static_cast<double>(ticks_elapsed.QuadPart)
	/ static_cast<double>(frequency.QuadPart)
	* 1000.0L;
	}
	}