talk/base/cpumonitor.cc - vendor/opensource/libjingle - Git at Google

 /*
  * libjingle
  * Copyright 2010 Google Inc.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are met:
  *
  *  1. Redistributions of source code must retain the above copyright notice,
  *     this list of conditions and the following disclaimer.
  *  2. Redistributions in binary form must reproduce the above copyright notice,
  *     this list of conditions and the following disclaimer in the documentation
  *     and/or other materials provided with the distribution.
  *  3. The name of the author may not be used to endorse or promote products
  *     derived from this software without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
  * EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
  * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
  * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
  * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
  * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "talk/base/cpumonitor.h"

 #include <string>

 #include "talk/base/common.h"
 #include "talk/base/logging.h"
 #include "talk/base/scoped_ptr.h"
 #include "talk/base/systeminfo.h"
 #include "talk/base/thread.h"
 #include "talk/base/timeutils.h"

 #ifdef WIN32
 #include "talk/base/win32.h"
 #include <winternl.h>
 #endif

 #ifdef POSIX
 #include <sys/time.h>
 #endif

 #if defined(IOS) || defined(OSX)
 #include <mach/mach_host.h>
 #include <mach/mach_init.h>
 #include <mach/host_info.h>
 #include <mach/task.h>
 #endif  // defined(IOS) || defined(OSX)

 #if defined(LINUX) || defined(ANDROID)
 #include <sys/resource.h>
 #include <errno.h>
 #include <stdio.h>
 #include "talk/base/fileutils.h"
 #include "talk/base/pathutils.h"
 #endif // defined(LINUX) || defined(ANDROID)

 #if defined(IOS) || defined(OSX)
 static uint64 TimeValueTToInt64(const time_value_t &time_value) {
   return talk_base::kNumMicrosecsPerSec * time_value.seconds +
       time_value.microseconds;
 }
 #endif  // defined(IOS) || defined(OSX)

 // How CpuSampler works
 // When threads switch, the time they spent is accumulated to system counters.
 // The time can be treated as user, kernel or idle.
 // user time is applications.
 // kernel time is the OS, including the thread switching code itself.
 //   typically kernel time indicates IO.
 // idle time is a process that wastes time when nothing is ready to run.
 //
 // User time is broken down by process (application).  One of the applications
 // is the current process.  When you add up all application times, this is
 // system time.  If only your application is running, system time should be the
 // same as process time.
 //
 // All cores contribute to these accumulators.  A dual core process is able to
 // process twice as many cycles as a single core.  The actual code efficiency
 // may be worse, due to contention, but the available cycles is exactly twice
 // as many, and the cpu load will reflect the efficiency.  Hyperthreads behave
 // the same way.  The load will reflect 200%, but the actual amount of work
 // completed will be much less than a true dual core.
 //
 // Total available performance is the sum of all accumulators.
 // If you tracked this for 1 second, it would essentially give you the clock
 // rate - number of cycles per second.
 // Speed step / Turbo Boost is not considered, so infact more processing time
 // may be available.

 namespace talk_base {

 // Note Tests on Windows show 600 ms is minimum stable interval for Windows 7.
 static const int32 kDefaultInterval = 950;  // Slightly under 1 second.

 CpuSampler::CpuSampler()
     : min_load_interval_(kDefaultInterval)
 #ifdef WIN32
       , get_system_times_(NULL),
       nt_query_system_information_(NULL),
       force_fallback_(false)
 #endif
     {
 }

 CpuSampler::~CpuSampler() {
 }

 // Set minimum interval in ms between computing new load values. Default 950.
 void CpuSampler::set_load_interval(int min_load_interval) {
   min_load_interval_ = min_load_interval;
 }

 bool CpuSampler::Init() {
   sysinfo_.reset(new SystemInfo);
   cpus_ = sysinfo_->GetMaxCpus();
   if (cpus_ == 0) {
     return false;
   }
 #ifdef WIN32
   // Note that GetSystemTimes is available in Windows XP SP1 or later.
   // http://msdn.microsoft.com/en-us/library/ms724400.aspx
   // NtQuerySystemInformation is used as a fallback.
   if (!force_fallback_) {
     get_system_times_ = GetProcAddress(GetModuleHandle(L"kernel32.dll"),
         "GetSystemTimes");
   }
   nt_query_system_information_ = GetProcAddress(GetModuleHandle(L"ntdll.dll"),
       "NtQuerySystemInformation");
   if ((get_system_times_ == NULL) && (nt_query_system_information_ == NULL)) {
     return false;
   }
 #endif
 #if defined(LINUX) || defined(ANDROID)
   Pathname sname("/proc/stat");
   sfile_.reset(Filesystem::OpenFile(sname, "rb"));
   if (sfile_.get() == NULL) {
     LOG_ERR(LS_ERROR) << "open proc/stat failed:";
     return false;
   }
   if (!sfile_->DisableBuffering()) {
     LOG_ERR(LS_ERROR) << "could not disable buffering for proc/stat";
     return false;
   }
 #endif // defined(LINUX) || defined(ANDROID)
   GetProcessLoad();  // Initialize values.
   GetSystemLoad();
   // Help next user call return valid data by recomputing load.
   process_.prev_load_time_ = 0u;
   system_.prev_load_time_ = 0u;
   return true;
 }

 float CpuSampler::UpdateCpuLoad(uint64 current_total_times,
                                 uint64 current_cpu_times,
                                 uint64 *prev_total_times,
                                 uint64 *prev_cpu_times) {
   float result = 0.f;
   if (current_total_times < *prev_total_times ||
       current_cpu_times < *prev_cpu_times) {
     LOG(LS_ERROR) << "Inconsistent time values are passed. ignored";
   } else {
     const uint64 cpu_diff = current_cpu_times - *prev_cpu_times;
     const uint64 total_diff = current_total_times - *prev_total_times;
     result = (total_diff == 0ULL ? 0.f :
               static_cast<float>(1.0f * cpu_diff / total_diff));
     if (result > static_cast<float>(cpus_)) {
       result = static_cast<float>(cpus_);
     }
     *prev_total_times = current_total_times;
     *prev_cpu_times = current_cpu_times;
   }
   return result;
 }

 float CpuSampler::GetSystemLoad() {
   uint32 timenow = Time();
   int elapsed = static_cast<int>(TimeDiff(timenow, system_.prev_load_time_));
   if (min_load_interval_ != 0 && system_.prev_load_time_ != 0u &&
       elapsed < min_load_interval_) {
     return system_.prev_load_;
   }
 #ifdef WIN32
   uint64 total_times, cpu_times;

   typedef BOOL (_stdcall *GST_PROC)(LPFILETIME, LPFILETIME, LPFILETIME);
   typedef NTSTATUS (WINAPI *QSI_PROC)(SYSTEM_INFORMATION_CLASS,
       PVOID, ULONG, PULONG);

   GST_PROC get_system_times = reinterpret_cast<GST_PROC>(get_system_times_);
   QSI_PROC nt_query_system_information = reinterpret_cast<QSI_PROC>(
       nt_query_system_information_);

   if (get_system_times) {
     FILETIME idle_time, kernel_time, user_time;
     if (!get_system_times(&idle_time, &kernel_time, &user_time)) {
       LOG(LS_ERROR) << "::GetSystemTimes() failed: " << ::GetLastError();
       return 0.f;
     }
     // kernel_time includes Kernel idle time, so no need to
     // include cpu_time as total_times
     total_times = ToUInt64(kernel_time) + ToUInt64(user_time);
     cpu_times = total_times - ToUInt64(idle_time);

   } else {
     if (nt_query_system_information) {
       ULONG returned_length = 0;
       scoped_array<SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION> processor_info(
           new SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION[cpus_]);
       nt_query_system_information(
           ::SystemProcessorPerformanceInformation,
           reinterpret_cast<void*>(processor_info.get()),
           cpus_ * sizeof(SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION),
           &returned_length);

       if (returned_length !=
           (cpus_ * sizeof(SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION))) {
         LOG(LS_ERROR) << "NtQuerySystemInformation has unexpected size";
         return 0.f;
       }

       uint64 current_idle = 0;
       uint64 current_kernel = 0;
       uint64 current_user = 0;
       for (int ix = 0; ix < cpus_; ++ix) {
         current_idle += processor_info[ix].IdleTime.QuadPart;
         current_kernel += processor_info[ix].UserTime.QuadPart;
         current_user += processor_info[ix].KernelTime.QuadPart;
       }
       total_times = current_kernel + current_user;
       cpu_times = total_times - current_idle;
     } else {
       return 0.f;
     }
   }
 #endif  // WIN32

 #if defined(IOS) || defined(OSX)
   host_cpu_load_info_data_t cpu_info;
   mach_msg_type_number_t info_count = HOST_CPU_LOAD_INFO_COUNT;
   if (KERN_SUCCESS != host_statistics(mach_host_self(), HOST_CPU_LOAD_INFO,
                                       reinterpret_cast<host_info_t>(&cpu_info),
                                       &info_count)) {
     LOG(LS_ERROR) << "::host_statistics() failed";
     return 0.f;
   }

   const uint64 cpu_times = cpu_info.cpu_ticks[CPU_STATE_NICE] +
       cpu_info.cpu_ticks[CPU_STATE_SYSTEM] +
       cpu_info.cpu_ticks[CPU_STATE_USER];
   const uint64 total_times = cpu_times + cpu_info.cpu_ticks[CPU_STATE_IDLE];
 #endif  // defined(IOS) || defined(OSX)

 #if defined(LINUX) || defined(ANDROID)
   if (sfile_.get() == NULL) {
     LOG(LS_ERROR) << "Invalid handle for proc/stat";
     return 0.f;
   }
   std::string statbuf;
   sfile_->SetPosition(0);
   if (!sfile_->ReadLine(&statbuf)) {
     LOG_ERR(LS_ERROR) << "Could not read proc/stat file";
     return 0.f;
   }

   unsigned long long user;
   unsigned long long nice;
   unsigned long long system;
   unsigned long long idle;
   if (sscanf(statbuf.c_str(), "cpu %Lu %Lu %Lu %Lu",
              &user, &nice,
              &system, &idle) != 4) {
     LOG_ERR(LS_ERROR) << "Could not parse cpu info";
     return 0.f;
   }
   const uint64 cpu_times = nice + system + user;
   const uint64 total_times = cpu_times + idle;
 #endif  // defined(LINUX) || defined(ANDROID)
   system_.prev_load_time_ = timenow;
   system_.prev_load_ = UpdateCpuLoad(total_times,
                                      cpu_times * cpus_,
                                      &system_.prev_total_times_,
                                      &system_.prev_cpu_times_);
   return system_.prev_load_;
 }

 float CpuSampler::GetProcessLoad() {
   uint32 timenow = Time();
   int elapsed = static_cast<int>(TimeDiff(timenow, process_.prev_load_time_));
   if (min_load_interval_ != 0 && process_.prev_load_time_ != 0u &&
       elapsed < min_load_interval_) {
     return process_.prev_load_;
   }
 #ifdef WIN32
   FILETIME current_file_time;
   ::GetSystemTimeAsFileTime(&current_file_time);

   FILETIME create_time, exit_time, kernel_time, user_time;
   if (!::GetProcessTimes(::GetCurrentProcess(),
                          &create_time, &exit_time, &kernel_time, &user_time)) {
     LOG(LS_ERROR) << "::GetProcessTimes() failed: " << ::GetLastError();
     return 0.f;
   }

   const uint64 total_times =
       ToUInt64(current_file_time) - ToUInt64(create_time);
   const uint64 cpu_times =
       (ToUInt64(kernel_time) + ToUInt64(user_time));
 #endif  // WIN32

 #ifdef POSIX
   // Common to both OSX and Linux.
   struct timeval tv;
   gettimeofday(&tv, NULL);
   const uint64 total_times = tv.tv_sec * kNumMicrosecsPerSec + tv.tv_usec;
 #endif

 #if defined(IOS) || defined(OSX)
   // Get live thread usage.
   task_thread_times_info task_times_info;
   mach_msg_type_number_t info_count = TASK_THREAD_TIMES_INFO_COUNT;

   if (KERN_SUCCESS != task_info(mach_task_self(), TASK_THREAD_TIMES_INFO,
                                 reinterpret_cast<task_info_t>(&task_times_info),
                                 &info_count)) {
     LOG(LS_ERROR) << "::task_info(TASK_THREAD_TIMES_INFO) failed";
     return 0.f;
   }

   // Get terminated thread usage.
   task_basic_info task_term_info;
   info_count = TASK_BASIC_INFO_COUNT;
   if (KERN_SUCCESS != task_info(mach_task_self(), TASK_BASIC_INFO,
                                 reinterpret_cast<task_info_t>(&task_term_info),
                                 &info_count)) {
     LOG(LS_ERROR) << "::task_info(TASK_BASIC_INFO) failed";
     return 0.f;
   }

   const uint64 cpu_times = (TimeValueTToInt64(task_times_info.user_time) +
       TimeValueTToInt64(task_times_info.system_time) +
       TimeValueTToInt64(task_term_info.user_time) +
       TimeValueTToInt64(task_term_info.system_time));
 #endif  // defined(IOS) || defined(OSX)

 #if defined(LINUX) || defined(ANDROID)
   rusage usage;
   if (getrusage(RUSAGE_SELF, &usage) < 0) {
     LOG_ERR(LS_ERROR) << "getrusage failed";
     return 0.f;
   }

   const uint64 cpu_times =
       (usage.ru_utime.tv_sec + usage.ru_stime.tv_sec) * kNumMicrosecsPerSec +
       usage.ru_utime.tv_usec + usage.ru_stime.tv_usec;
 #endif  // defined(LINUX) || defined(ANDROID)
   process_.prev_load_time_ = timenow;
   process_.prev_load_ = UpdateCpuLoad(total_times,
                                      cpu_times,
                                      &process_.prev_total_times_,
                                      &process_.prev_cpu_times_);
   return process_.prev_load_;
 }

 int CpuSampler::GetMaxCpus() const {
   return cpus_;
 }

 int CpuSampler::GetCurrentCpus() {
   return sysinfo_->GetCurCpus();
 }

 ///////////////////////////////////////////////////////////////////
 // Implementation of class CpuMonitor.
 CpuMonitor::CpuMonitor(Thread* thread)
     : monitor_thread_(thread ? thread : Thread::Current()) {
   monitor_thread_->SignalQueueDestroyed.connect(
       this, &CpuMonitor::OnMessageQueueDestroyed);
 }

 CpuMonitor::~CpuMonitor() {
   Stop();
 }

 bool CpuMonitor::Start(int period_ms) {
   if (!sampler_.Init()) return false;

   period_ms_ = period_ms;
   if (monitor_thread_) {
     monitor_thread_->PostDelayed(period_ms_, this);
   }
   return true;
 }

 void CpuMonitor::Stop() {
   if (monitor_thread_) {
     monitor_thread_->Clear(this);
   }
 }

 void CpuMonitor::OnMessage(Message* msg) {
   int max_cpus = sampler_.GetMaxCpus();
   int current_cpus = sampler_.GetCurrentCpus();
   float process_load = sampler_.GetProcessLoad();
   float system_load = sampler_.GetSystemLoad();
   SignalUpdate(current_cpus, max_cpus, process_load, system_load);

   if (monitor_thread_) {
     monitor_thread_->PostDelayed(period_ms_, this);
   }
 }

 }  // namespace talk_base
	/*
	* libjingle
	* Copyright 2010 Google Inc.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are met:
	*
	* 1. Redistributions of source code must retain the above copyright notice,
	* this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright notice,
	* this list of conditions and the following disclaimer in the documentation
	* and/or other materials provided with the distribution.
	* 3. The name of the author may not be used to endorse or promote products
	* derived from this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
	* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
	* EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
	* OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
	* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
	* OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
	* ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "talk/base/cpumonitor.h"

	#include <string>

	#include "talk/base/common.h"
	#include "talk/base/logging.h"
	#include "talk/base/scoped_ptr.h"
	#include "talk/base/systeminfo.h"
	#include "talk/base/thread.h"
	#include "talk/base/timeutils.h"

	#ifdef WIN32
	#include "talk/base/win32.h"
	#include <winternl.h>
	#endif

	#ifdef POSIX
	#include <sys/time.h>
	#endif

	#if defined(IOS) \|\| defined(OSX)
	#include <mach/mach_host.h>
	#include <mach/mach_init.h>
	#include <mach/host_info.h>
	#include <mach/task.h>
	#endif // defined(IOS) \|\| defined(OSX)

	#if defined(LINUX) \|\| defined(ANDROID)
	#include <sys/resource.h>
	#include <errno.h>
	#include <stdio.h>
	#include "talk/base/fileutils.h"
	#include "talk/base/pathutils.h"
	#endif // defined(LINUX) \|\| defined(ANDROID)

	#if defined(IOS) \|\| defined(OSX)
	static uint64 TimeValueTToInt64(const time_value_t &time_value) {
	return talk_base::kNumMicrosecsPerSec * time_value.seconds +
	time_value.microseconds;
	}
	#endif // defined(IOS) \|\| defined(OSX)

	// How CpuSampler works
	// When threads switch, the time they spent is accumulated to system counters.
	// The time can be treated as user, kernel or idle.
	// user time is applications.
	// kernel time is the OS, including the thread switching code itself.
	// typically kernel time indicates IO.
	// idle time is a process that wastes time when nothing is ready to run.
	//
	// User time is broken down by process (application). One of the applications
	// is the current process. When you add up all application times, this is
	// system time. If only your application is running, system time should be the
	// same as process time.
	//
	// All cores contribute to these accumulators. A dual core process is able to
	// process twice as many cycles as a single core. The actual code efficiency
	// may be worse, due to contention, but the available cycles is exactly twice
	// as many, and the cpu load will reflect the efficiency. Hyperthreads behave
	// the same way. The load will reflect 200%, but the actual amount of work
	// completed will be much less than a true dual core.
	//
	// Total available performance is the sum of all accumulators.
	// If you tracked this for 1 second, it would essentially give you the clock
	// rate - number of cycles per second.
	// Speed step / Turbo Boost is not considered, so infact more processing time
	// may be available.

	namespace talk_base {

	// Note Tests on Windows show 600 ms is minimum stable interval for Windows 7.
	static const int32 kDefaultInterval = 950; // Slightly under 1 second.

	CpuSampler::CpuSampler()
	: min_load_interval_(kDefaultInterval)
	#ifdef WIN32
	, get_system_times_(NULL),
	nt_query_system_information_(NULL),
	force_fallback_(false)
	#endif
	{
	}

	CpuSampler::~CpuSampler() {
	}

	// Set minimum interval in ms between computing new load values. Default 950.
	void CpuSampler::set_load_interval(int min_load_interval) {
	min_load_interval_ = min_load_interval;
	}

	bool CpuSampler::Init() {
	sysinfo_.reset(new SystemInfo);
	cpus_ = sysinfo_->GetMaxCpus();
	if (cpus_ == 0) {
	return false;
	}
	#ifdef WIN32
	// Note that GetSystemTimes is available in Windows XP SP1 or later.
	// http://msdn.microsoft.com/en-us/library/ms724400.aspx
	// NtQuerySystemInformation is used as a fallback.
	if (!force_fallback_) {
	get_system_times_ = GetProcAddress(GetModuleHandle(L"kernel32.dll"),
	"GetSystemTimes");
	}
	nt_query_system_information_ = GetProcAddress(GetModuleHandle(L"ntdll.dll"),
	"NtQuerySystemInformation");
	if ((get_system_times_ == NULL) && (nt_query_system_information_ == NULL)) {
	return false;
	}
	#endif
	#if defined(LINUX) \|\| defined(ANDROID)
	Pathname sname("/proc/stat");
	sfile_.reset(Filesystem::OpenFile(sname, "rb"));
	if (sfile_.get() == NULL) {
	LOG_ERR(LS_ERROR) << "open proc/stat failed:";
	return false;
	}
	if (!sfile_->DisableBuffering()) {
	LOG_ERR(LS_ERROR) << "could not disable buffering for proc/stat";
	return false;
	}
	#endif // defined(LINUX) \|\| defined(ANDROID)
	GetProcessLoad(); // Initialize values.
	GetSystemLoad();
	// Help next user call return valid data by recomputing load.
	process_.prev_load_time_ = 0u;
	system_.prev_load_time_ = 0u;
	return true;
	}

	float CpuSampler::UpdateCpuLoad(uint64 current_total_times,
	uint64 current_cpu_times,
	uint64 *prev_total_times,
	uint64 *prev_cpu_times) {
	float result = 0.f;
	if (current_total_times < *prev_total_times \|\|
	current_cpu_times < *prev_cpu_times) {
	LOG(LS_ERROR) << "Inconsistent time values are passed. ignored";
	} else {
	const uint64 cpu_diff = current_cpu_times - *prev_cpu_times;
	const uint64 total_diff = current_total_times - *prev_total_times;
	result = (total_diff == 0ULL ? 0.f :
	static_cast<float>(1.0f * cpu_diff / total_diff));
	if (result > static_cast<float>(cpus_)) {
	result = static_cast<float>(cpus_);
	}
	*prev_total_times = current_total_times;
	*prev_cpu_times = current_cpu_times;
	}
	return result;
	}

	float CpuSampler::GetSystemLoad() {
	uint32 timenow = Time();
	int elapsed = static_cast<int>(TimeDiff(timenow, system_.prev_load_time_));
	if (min_load_interval_ != 0 && system_.prev_load_time_ != 0u &&
	elapsed < min_load_interval_) {
	return system_.prev_load_;
	}
	#ifdef WIN32
	uint64 total_times, cpu_times;

	typedef BOOL (_stdcall *GST_PROC)(LPFILETIME, LPFILETIME, LPFILETIME);
	typedef NTSTATUS (WINAPI *QSI_PROC)(SYSTEM_INFORMATION_CLASS,
	PVOID, ULONG, PULONG);

	GST_PROC get_system_times = reinterpret_cast<GST_PROC>(get_system_times_);
	QSI_PROC nt_query_system_information = reinterpret_cast<QSI_PROC>(
	nt_query_system_information_);

	if (get_system_times) {
	FILETIME idle_time, kernel_time, user_time;
	if (!get_system_times(&idle_time, &kernel_time, &user_time)) {
	LOG(LS_ERROR) << "::GetSystemTimes() failed: " << ::GetLastError();
	return 0.f;
	}
	// kernel_time includes Kernel idle time, so no need to
	// include cpu_time as total_times
	total_times = ToUInt64(kernel_time) + ToUInt64(user_time);
	cpu_times = total_times - ToUInt64(idle_time);

	} else {
	if (nt_query_system_information) {
	ULONG returned_length = 0;
	scoped_array<SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION> processor_info(
	new SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION[cpus_]);
	nt_query_system_information(
	::SystemProcessorPerformanceInformation,
	reinterpret_cast<void*>(processor_info.get()),
	cpus_ * sizeof(SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION),
	&returned_length);

	if (returned_length !=
	(cpus_ * sizeof(SYSTEM_PROCESSOR_PERFORMANCE_INFORMATION))) {
	LOG(LS_ERROR) << "NtQuerySystemInformation has unexpected size";
	return 0.f;
	}

	uint64 current_idle = 0;
	uint64 current_kernel = 0;
	uint64 current_user = 0;
	for (int ix = 0; ix < cpus_; ++ix) {
	current_idle += processor_info[ix].IdleTime.QuadPart;
	current_kernel += processor_info[ix].UserTime.QuadPart;
	current_user += processor_info[ix].KernelTime.QuadPart;
	}
	total_times = current_kernel + current_user;
	cpu_times = total_times - current_idle;
	} else {
	return 0.f;
	}
	}
	#endif // WIN32

	#if defined(IOS) \|\| defined(OSX)
	host_cpu_load_info_data_t cpu_info;
	mach_msg_type_number_t info_count = HOST_CPU_LOAD_INFO_COUNT;
	if (KERN_SUCCESS != host_statistics(mach_host_self(), HOST_CPU_LOAD_INFO,
	reinterpret_cast<host_info_t>(&cpu_info),
	&info_count)) {
	LOG(LS_ERROR) << "::host_statistics() failed";
	return 0.f;
	}

	const uint64 cpu_times = cpu_info.cpu_ticks[CPU_STATE_NICE] +
	cpu_info.cpu_ticks[CPU_STATE_SYSTEM] +
	cpu_info.cpu_ticks[CPU_STATE_USER];
	const uint64 total_times = cpu_times + cpu_info.cpu_ticks[CPU_STATE_IDLE];
	#endif // defined(IOS) \|\| defined(OSX)

	#if defined(LINUX) \|\| defined(ANDROID)
	if (sfile_.get() == NULL) {
	LOG(LS_ERROR) << "Invalid handle for proc/stat";
	return 0.f;
	}
	std::string statbuf;
	sfile_->SetPosition(0);
	if (!sfile_->ReadLine(&statbuf)) {
	LOG_ERR(LS_ERROR) << "Could not read proc/stat file";
	return 0.f;
	}

	unsigned long long user;
	unsigned long long nice;
	unsigned long long system;
	unsigned long long idle;
	if (sscanf(statbuf.c_str(), "cpu %Lu %Lu %Lu %Lu",
	&user, &nice,
	&system, &idle) != 4) {
	LOG_ERR(LS_ERROR) << "Could not parse cpu info";
	return 0.f;
	}
	const uint64 cpu_times = nice + system + user;
	const uint64 total_times = cpu_times + idle;
	#endif // defined(LINUX) \|\| defined(ANDROID)
	system_.prev_load_time_ = timenow;
	system_.prev_load_ = UpdateCpuLoad(total_times,
	cpu_times * cpus_,
	&system_.prev_total_times_,
	&system_.prev_cpu_times_);
	return system_.prev_load_;
	}

	float CpuSampler::GetProcessLoad() {
	uint32 timenow = Time();
	int elapsed = static_cast<int>(TimeDiff(timenow, process_.prev_load_time_));
	if (min_load_interval_ != 0 && process_.prev_load_time_ != 0u &&
	elapsed < min_load_interval_) {
	return process_.prev_load_;
	}
	#ifdef WIN32
	FILETIME current_file_time;
	::GetSystemTimeAsFileTime(&current_file_time);

	FILETIME create_time, exit_time, kernel_time, user_time;
	if (!::GetProcessTimes(::GetCurrentProcess(),
	&create_time, &exit_time, &kernel_time, &user_time)) {
	LOG(LS_ERROR) << "::GetProcessTimes() failed: " << ::GetLastError();
	return 0.f;
	}

	const uint64 total_times =
	ToUInt64(current_file_time) - ToUInt64(create_time);
	const uint64 cpu_times =
	(ToUInt64(kernel_time) + ToUInt64(user_time));
	#endif // WIN32

	#ifdef POSIX
	// Common to both OSX and Linux.
	struct timeval tv;
	gettimeofday(&tv, NULL);
	const uint64 total_times = tv.tv_sec * kNumMicrosecsPerSec + tv.tv_usec;
	#endif

	#if defined(IOS) \|\| defined(OSX)
	// Get live thread usage.
	task_thread_times_info task_times_info;
	mach_msg_type_number_t info_count = TASK_THREAD_TIMES_INFO_COUNT;

	if (KERN_SUCCESS != task_info(mach_task_self(), TASK_THREAD_TIMES_INFO,
	reinterpret_cast<task_info_t>(&task_times_info),
	&info_count)) {
	LOG(LS_ERROR) << "::task_info(TASK_THREAD_TIMES_INFO) failed";
	return 0.f;
	}

	// Get terminated thread usage.
	task_basic_info task_term_info;
	info_count = TASK_BASIC_INFO_COUNT;
	if (KERN_SUCCESS != task_info(mach_task_self(), TASK_BASIC_INFO,
	reinterpret_cast<task_info_t>(&task_term_info),
	&info_count)) {
	LOG(LS_ERROR) << "::task_info(TASK_BASIC_INFO) failed";
	return 0.f;
	}

	const uint64 cpu_times = (TimeValueTToInt64(task_times_info.user_time) +
	TimeValueTToInt64(task_times_info.system_time) +
	TimeValueTToInt64(task_term_info.user_time) +
	TimeValueTToInt64(task_term_info.system_time));
	#endif // defined(IOS) \|\| defined(OSX)

	#if defined(LINUX) \|\| defined(ANDROID)
	rusage usage;
	if (getrusage(RUSAGE_SELF, &usage) < 0) {
	LOG_ERR(LS_ERROR) << "getrusage failed";
	return 0.f;
	}

	const uint64 cpu_times =
	(usage.ru_utime.tv_sec + usage.ru_stime.tv_sec) * kNumMicrosecsPerSec +
	usage.ru_utime.tv_usec + usage.ru_stime.tv_usec;
	#endif // defined(LINUX) \|\| defined(ANDROID)
	process_.prev_load_time_ = timenow;
	process_.prev_load_ = UpdateCpuLoad(total_times,
	cpu_times,
	&process_.prev_total_times_,
	&process_.prev_cpu_times_);
	return process_.prev_load_;
	}

	int CpuSampler::GetMaxCpus() const {
	return cpus_;
	}

	int CpuSampler::GetCurrentCpus() {
	return sysinfo_->GetCurCpus();
	}

	///////////////////////////////////////////////////////////////////
	// Implementation of class CpuMonitor.
	CpuMonitor::CpuMonitor(Thread* thread)
	: monitor_thread_(thread ? thread : Thread::Current()) {
	monitor_thread_->SignalQueueDestroyed.connect(
	this, &CpuMonitor::OnMessageQueueDestroyed);
	}

	CpuMonitor::~CpuMonitor() {
	Stop();
	}

	bool CpuMonitor::Start(int period_ms) {
	if (!sampler_.Init()) return false;

	period_ms_ = period_ms;
	if (monitor_thread_) {
	monitor_thread_->PostDelayed(period_ms_, this);
	}
	return true;
	}

	void CpuMonitor::Stop() {
	if (monitor_thread_) {
	monitor_thread_->Clear(this);
	}
	}

	void CpuMonitor::OnMessage(Message* msg) {
	int max_cpus = sampler_.GetMaxCpus();
	int current_cpus = sampler_.GetCurrentCpus();
	float process_load = sampler_.GetProcessLoad();
	float system_load = sampler_.GetSystemLoad();
	SignalUpdate(current_cpus, max_cpus, process_load, system_load);

	if (monitor_thread_) {
	monitor_thread_->PostDelayed(period_ms_, this);
	}
	}

	} // namespace talk_base