runtime/vm/timer.h - sdk.git - Git at Google

 // Copyright (c) 2011, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef RUNTIME_VM_TIMER_H_
 #define RUNTIME_VM_TIMER_H_

 #include "platform/atomic.h"
 #include "platform/utils.h"
 #include "vm/allocation.h"
 #include "vm/flags.h"
 #include "vm/os.h"

 namespace dart {

 struct MeasureMonotonic {
   static inline int64_t Now() { return OS::GetCurrentMonotonicMicros(); }
 };

 struct MeasureCpu {
   static inline int64_t Now() { return OS::GetCurrentThreadCPUMicros(); }
 };

 // Timer class allows timing of specific operations in the VM.
 template <typename Measure>
 class TimerImpl : public ValueObject {
  public:
   TimerImpl() { Reset(); }
   ~TimerImpl() {}

   // Start timer.
   void Start() {
     start_ = Measure::Now();
     running_ = true;
   }

   // Stop timer.
   void Stop() {
     ASSERT(start_ != 0);
     ASSERT(running());
     stop_ = Measure::Now();
     int64_t elapsed = ElapsedMicros();
     max_contiguous_ = Utils::Maximum(max_contiguous_.load(), elapsed);
     // Make increment atomic in case it occurs in parallel with aggregation.
     total_.fetch_add(elapsed);
     running_ = false;
   }

   // Get total cumulative elapsed time in micros.
   int64_t TotalElapsedTime() const {
     int64_t result = total_;
     if (running_) {
       int64_t now = Measure::Now();
       result += (now - start_);
     }
     return result;
   }

   int64_t MaxContiguous() const {
     int64_t result = max_contiguous_;
     if (running_) {
       int64_t now = Measure::Now();
       result = Utils::Maximum(result, now - start_);
     }
     return result;
   }

   void Reset() {
     start_ = 0;
     stop_ = 0;
     total_ = 0;
     max_contiguous_ = 0;
     running_ = false;
   }

   bool IsReset() const {
     return (start_ == 0) && (stop_ == 0) && (total_ == 0) &&
            (max_contiguous_ == 0) && !running_;
   }

   void AddTotal(const TimerImpl& other) { total_.fetch_add(other.total_); }

   // Accessors.
   bool running() const { return running_; }

  private:
   friend class Timer;

   explicit TimerImpl(int64_t elapsed)
       : total_(elapsed), max_contiguous_(elapsed) {}

   int64_t ElapsedMicros() const {
     ASSERT(start_ != 0);
     ASSERT(stop_ != 0);
     return stop_ - start_;
   }

   RelaxedAtomic<int64_t> start_;
   RelaxedAtomic<int64_t> stop_;
   RelaxedAtomic<int64_t> total_;
   RelaxedAtomic<int64_t> max_contiguous_;

   bool running_ = false;

   DISALLOW_COPY_AND_ASSIGN(TimerImpl);
 };

 class Timer : public ValueObject {
  public:
   Timer(int64_t elapsed, int64_t elapsed_cpu)
       : monotonic_(elapsed), cpu_(elapsed) {}
   Timer() { Reset(); }
   ~Timer() {}

   // Start timer.
   void Start() {
     cpu_.Start();
     monotonic_.Start();
   }

   // Stop timer.
   void Stop() {
     cpu_.Stop();
     monotonic_.Stop();
   }

   // Get total cumulative elapsed time in micros.
   int64_t TotalElapsedTime() const { return monotonic_.TotalElapsedTime(); }
   int64_t TotalElapsedTimeCpu() const { return cpu_.TotalElapsedTime(); }

   int64_t MaxContiguous() const { return monotonic_.MaxContiguous(); }

   void Reset() {
     monotonic_.Reset();
     cpu_.Reset();
   }

   bool IsReset() const { return monotonic_.IsReset(); }

   void AddTotal(const Timer& other) {
     monotonic_.AddTotal(other.monotonic_);
     cpu_.AddTotal(other.cpu_);
   }

   const char* FormatElapsedHumanReadable(Zone* zone) const {
     return FormatElapsedHumanReadable(zone, TotalElapsedTime(),
                                       TotalElapsedTimeCpu());
   }

   static const char* FormatTime(Zone* zone, int64_t total) {
     if (total > kMicrosecondsPerSecond) {
       return OS::SCreate(zone, "%6.2f s", MicrosecondsToSeconds(total));
     } else if (total > kMicrosecondsPerMillisecond) {
       return OS::SCreate(zone, "%6.2f ms", MicrosecondsToMilliseconds(total));
     } else {
       return OS::SCreate(zone, "%6" Pd64 " \u00B5s", total);
     }
   }

   static constexpr double kCpuTimeReportingThreshold = 0.05;

   // Formats the given monotonic and CPU times as a human readable string.
   //
   // CPU time is included into the formated string only if
   // it is |kCpuTimeReportingThreshold| percent different from the monotonic
   // time.
   static const char* FormatElapsedHumanReadable(Zone* zone,
                                                 int64_t total_elapsed,
                                                 int64_t total_elapsed_cpu) {
     if ((total_elapsed == 0) ||
         static_cast<double>(Utils::Abs(total_elapsed - total_elapsed_cpu) /
                             total_elapsed) < kCpuTimeReportingThreshold) {
       return FormatTime(zone, total_elapsed);
     } else {
       return OS::SCreate(zone, "%s (cpu %s)", FormatTime(zone, total_elapsed),
                          FormatTime(zone, total_elapsed_cpu));
     }
   }

  private:
   TimerImpl<MeasureMonotonic> monotonic_;
   TimerImpl<MeasureCpu> cpu_;

   DISALLOW_COPY_AND_ASSIGN(Timer);
 };

 class TimerScope : public StackResource {
  public:
   TimerScope(ThreadState* thread, Timer* timer)
       : StackResource(thread), timer_(timer) {
     if (timer_ != nullptr) timer_->Start();
   }
   ~TimerScope() {
     if (timer_ != nullptr) timer_->Stop();
   }

  private:
   Timer* const timer_;
 };

 class PrintTimeScope : public ValueObject {
  public:
   explicit PrintTimeScope(const char* name) : name_(name) { timer_.Start(); }
   ~PrintTimeScope();

  private:
   Timer timer_;
   const char* name_;
 };

 }  // namespace dart

 #endif  // RUNTIME_VM_TIMER_H_
	// Copyright (c) 2011, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef RUNTIME_VM_TIMER_H_
	#define RUNTIME_VM_TIMER_H_

	#include "platform/atomic.h"
	#include "platform/utils.h"
	#include "vm/allocation.h"
	#include "vm/flags.h"
	#include "vm/os.h"

	namespace dart {

	struct MeasureMonotonic {
	static inline int64_t Now() { return OS::GetCurrentMonotonicMicros(); }
	};

	struct MeasureCpu {
	static inline int64_t Now() { return OS::GetCurrentThreadCPUMicros(); }
	};

	// Timer class allows timing of specific operations in the VM.
	template <typename Measure>
	class TimerImpl : public ValueObject {
	public:
	TimerImpl() { Reset(); }
	~TimerImpl() {}

	// Start timer.
	void Start() {
	start_ = Measure::Now();
	running_ = true;
	}

	// Stop timer.
	void Stop() {
	ASSERT(start_ != 0);
	ASSERT(running());
	stop_ = Measure::Now();
	int64_t elapsed = ElapsedMicros();
	max_contiguous_ = Utils::Maximum(max_contiguous_.load(), elapsed);
	// Make increment atomic in case it occurs in parallel with aggregation.
	total_.fetch_add(elapsed);
	running_ = false;
	}

	// Get total cumulative elapsed time in micros.
	int64_t TotalElapsedTime() const {
	int64_t result = total_;
	if (running_) {
	int64_t now = Measure::Now();
	result += (now - start_);
	}
	return result;
	}

	int64_t MaxContiguous() const {
	int64_t result = max_contiguous_;
	if (running_) {
	int64_t now = Measure::Now();
	result = Utils::Maximum(result, now - start_);
	}
	return result;
	}

	void Reset() {
	start_ = 0;
	stop_ = 0;
	total_ = 0;
	max_contiguous_ = 0;
	running_ = false;
	}

	bool IsReset() const {
	return (start_ == 0) && (stop_ == 0) && (total_ == 0) &&
	(max_contiguous_ == 0) && !running_;
	}

	void AddTotal(const TimerImpl& other) { total_.fetch_add(other.total_); }

	// Accessors.
	bool running() const { return running_; }

	private:
	friend class Timer;

	explicit TimerImpl(int64_t elapsed)
	: total_(elapsed), max_contiguous_(elapsed) {}

	int64_t ElapsedMicros() const {
	ASSERT(start_ != 0);
	ASSERT(stop_ != 0);
	return stop_ - start_;
	}

	RelaxedAtomic<int64_t> start_;
	RelaxedAtomic<int64_t> stop_;
	RelaxedAtomic<int64_t> total_;
	RelaxedAtomic<int64_t> max_contiguous_;

	bool running_ = false;

	DISALLOW_COPY_AND_ASSIGN(TimerImpl);
	};

	class Timer : public ValueObject {
	public:
	Timer(int64_t elapsed, int64_t elapsed_cpu)
	: monotonic_(elapsed), cpu_(elapsed) {}
	Timer() { Reset(); }
	~Timer() {}

	// Start timer.
	void Start() {
	cpu_.Start();
	monotonic_.Start();
	}

	// Stop timer.
	void Stop() {
	cpu_.Stop();
	monotonic_.Stop();
	}

	// Get total cumulative elapsed time in micros.
	int64_t TotalElapsedTime() const { return monotonic_.TotalElapsedTime(); }
	int64_t TotalElapsedTimeCpu() const { return cpu_.TotalElapsedTime(); }

	int64_t MaxContiguous() const { return monotonic_.MaxContiguous(); }

	void Reset() {
	monotonic_.Reset();
	cpu_.Reset();
	}

	bool IsReset() const { return monotonic_.IsReset(); }

	void AddTotal(const Timer& other) {
	monotonic_.AddTotal(other.monotonic_);
	cpu_.AddTotal(other.cpu_);
	}

	const char* FormatElapsedHumanReadable(Zone* zone) const {
	return FormatElapsedHumanReadable(zone, TotalElapsedTime(),
	TotalElapsedTimeCpu());
	}

	static const char* FormatTime(Zone* zone, int64_t total) {
	if (total > kMicrosecondsPerSecond) {
	return OS::SCreate(zone, "%6.2f s", MicrosecondsToSeconds(total));
	} else if (total > kMicrosecondsPerMillisecond) {
	return OS::SCreate(zone, "%6.2f ms", MicrosecondsToMilliseconds(total));
	} else {
	return OS::SCreate(zone, "%6" Pd64 " \u00B5s", total);
	}
	}

	static constexpr double kCpuTimeReportingThreshold = 0.05;

	// Formats the given monotonic and CPU times as a human readable string.
	//
	// CPU time is included into the formated string only if
	// it is \|kCpuTimeReportingThreshold\| percent different from the monotonic
	// time.
	static const char* FormatElapsedHumanReadable(Zone* zone,
	int64_t total_elapsed,
	int64_t total_elapsed_cpu) {
	if ((total_elapsed == 0) \|\|
	static_cast<double>(Utils::Abs(total_elapsed - total_elapsed_cpu) /
	total_elapsed) < kCpuTimeReportingThreshold) {
	return FormatTime(zone, total_elapsed);
	} else {
	return OS::SCreate(zone, "%s (cpu %s)", FormatTime(zone, total_elapsed),
	FormatTime(zone, total_elapsed_cpu));
	}
	}

	private:
	TimerImpl<MeasureMonotonic> monotonic_;
	TimerImpl<MeasureCpu> cpu_;

	DISALLOW_COPY_AND_ASSIGN(Timer);
	};

	class TimerScope : public StackResource {
	public:
	TimerScope(ThreadState* thread, Timer* timer)
	: StackResource(thread), timer_(timer) {
	if (timer_ != nullptr) timer_->Start();
	}
	~TimerScope() {
	if (timer_ != nullptr) timer_->Stop();
	}

	private:
	Timer* const timer_;
	};

	class PrintTimeScope : public ValueObject {
	public:
	explicit PrintTimeScope(const char* name) : name_(name) { timer_.Start(); }
	~PrintTimeScope();

	private:
	Timer timer_;
	const char* name_;
	};

	} // namespace dart

	#endif // RUNTIME_VM_TIMER_H_