utils/google-benchmark/src/thread_timer.h - libcxx - Git at Google

 #ifndef BENCHMARK_THREAD_TIMER_H
 #define BENCHMARK_THREAD_TIMER_H

 #include "check.h"
 #include "timers.h"

 namespace benchmark {
 namespace internal {

 class ThreadTimer {
  public:
   ThreadTimer() = default;

   // Called by each thread
   void StartTimer() {
     running_ = true;
     start_real_time_ = ChronoClockNow();
     start_cpu_time_ = ThreadCPUUsage();
   }

   // Called by each thread
   void StopTimer() {
     CHECK(running_);
     running_ = false;
     real_time_used_ += ChronoClockNow() - start_real_time_;
     // Floating point error can result in the subtraction producing a negative
     // time. Guard against that.
     cpu_time_used_ += std::max<double>(ThreadCPUUsage() - start_cpu_time_, 0);
   }

   // Called by each thread
   void SetIterationTime(double seconds) { manual_time_used_ += seconds; }

   bool running() const { return running_; }

   // REQUIRES: timer is not running
   double real_time_used() {
     CHECK(!running_);
     return real_time_used_;
   }

   // REQUIRES: timer is not running
   double cpu_time_used() {
     CHECK(!running_);
     return cpu_time_used_;
   }

   // REQUIRES: timer is not running
   double manual_time_used() {
     CHECK(!running_);
     return manual_time_used_;
   }

  private:
   bool running_ = false;        // Is the timer running
   double start_real_time_ = 0;  // If running_
   double start_cpu_time_ = 0;   // If running_

   // Accumulated time so far (does not contain current slice if running_)
   double real_time_used_ = 0;
   double cpu_time_used_ = 0;
   // Manually set iteration time. User sets this with SetIterationTime(seconds).
   double manual_time_used_ = 0;
 };

 }  // namespace internal
 }  // namespace benchmark

 #endif  // BENCHMARK_THREAD_TIMER_H
	#ifndef BENCHMARK_THREAD_TIMER_H
	#define BENCHMARK_THREAD_TIMER_H

	#include "check.h"
	#include "timers.h"

	namespace benchmark {
	namespace internal {

	class ThreadTimer {
	public:
	ThreadTimer() = default;

	// Called by each thread
	void StartTimer() {
	running_ = true;
	start_real_time_ = ChronoClockNow();
	start_cpu_time_ = ThreadCPUUsage();
	}

	// Called by each thread
	void StopTimer() {
	CHECK(running_);
	running_ = false;
	real_time_used_ += ChronoClockNow() - start_real_time_;
	// Floating point error can result in the subtraction producing a negative
	// time. Guard against that.
	cpu_time_used_ += std::max<double>(ThreadCPUUsage() - start_cpu_time_, 0);
	}

	// Called by each thread
	void SetIterationTime(double seconds) { manual_time_used_ += seconds; }

	bool running() const { return running_; }

	// REQUIRES: timer is not running
	double real_time_used() {
	CHECK(!running_);
	return real_time_used_;
	}

	// REQUIRES: timer is not running
	double cpu_time_used() {
	CHECK(!running_);
	return cpu_time_used_;
	}

	// REQUIRES: timer is not running
	double manual_time_used() {
	CHECK(!running_);
	return manual_time_used_;
	}

	private:
	bool running_ = false; // Is the timer running
	double start_real_time_ = 0; // If running_
	double start_cpu_time_ = 0; // If running_

	// Accumulated time so far (does not contain current slice if running_)
	double real_time_used_ = 0;
	double cpu_time_used_ = 0;
	// Manually set iteration time. User sets this with SetIterationTime(seconds).
	double manual_time_used_ = 0;
	};

	} // namespace internal
	} // namespace benchmark

	#endif // BENCHMARK_THREAD_TIMER_H