system_wrappers/source/clock.cc - src - Git at Google

 /*
  *  Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "system_wrappers/include/clock.h"

 #include "system_wrappers/include/field_trial.h"

 #if defined(WEBRTC_WIN)

 // Windows needs to be included before mmsystem.h
 #include "rtc_base/win32.h"

 #include <mmsystem.h>


 #elif defined(WEBRTC_POSIX)

 #include <sys/time.h>
 #include <time.h>

 #endif  // defined(WEBRTC_POSIX)

 #include "rtc_base/synchronization/mutex.h"
 #include "rtc_base/time_utils.h"

 namespace webrtc {
 namespace {

 int64_t NtpOffsetUsCalledOnce() {
   constexpr int64_t kNtpJan1970Sec = 2208988800;
   int64_t clock_time = rtc::TimeMicros();
   int64_t utc_time = rtc::TimeUTCMicros();
   return utc_time - clock_time + kNtpJan1970Sec * rtc::kNumMicrosecsPerSec;
 }

 NtpTime TimeMicrosToNtp(int64_t time_us) {
   static int64_t ntp_offset_us = NtpOffsetUsCalledOnce();

   int64_t time_ntp_us = time_us + ntp_offset_us;
   RTC_DCHECK_GE(time_ntp_us, 0);  // Time before year 1900 is unsupported.

   // Convert seconds to uint32 through uint64 for a well-defined cast.
   // A wrap around, which will happen in 2036, is expected for NTP time.
   uint32_t ntp_seconds =
       static_cast<uint64_t>(time_ntp_us / rtc::kNumMicrosecsPerSec);

   // Scale fractions of the second to NTP resolution.
   constexpr int64_t kNtpFractionsInSecond = 1LL << 32;
   int64_t us_fractions = time_ntp_us % rtc::kNumMicrosecsPerSec;
   uint32_t ntp_fractions =
       us_fractions * kNtpFractionsInSecond / rtc::kNumMicrosecsPerSec;

   return NtpTime(ntp_seconds, ntp_fractions);
 }

 void GetSecondsAndFraction(const timeval& time,
                            uint32_t* seconds,
                            double* fraction) {
   *seconds = time.tv_sec + kNtpJan1970;
   *fraction = time.tv_usec / 1e6;

   while (*fraction >= 1) {
     --*fraction;
     ++*seconds;
   }
   while (*fraction < 0) {
     ++*fraction;
     --*seconds;
   }
 }

 }  // namespace

 class RealTimeClock : public Clock {
  public:
   RealTimeClock()
       : use_system_independent_ntp_time_(!field_trial::IsEnabled(
             "WebRTC-SystemIndependentNtpTimeKillSwitch")) {}

   Timestamp CurrentTime() override {
     return Timestamp::Micros(rtc::TimeMicros());
   }

   NtpTime CurrentNtpTime() override {
     return use_system_independent_ntp_time_ ? TimeMicrosToNtp(rtc::TimeMicros())
                                             : SystemDependentNtpTime();
   }

  protected:
   virtual timeval CurrentTimeVal() = 0;

  private:
   NtpTime SystemDependentNtpTime() {
     uint32_t seconds;
     double fraction;
     GetSecondsAndFraction(CurrentTimeVal(), &seconds, &fraction);

     return NtpTime(seconds, static_cast<uint32_t>(
                                 fraction * kMagicNtpFractionalUnit + 0.5));
   }

   bool use_system_independent_ntp_time_;
 };

 #if defined(WINUWP)
 class WinUwpRealTimeClock final : public RealTimeClock {
  public:
   WinUwpRealTimeClock() = default;
   ~WinUwpRealTimeClock() override {}

  protected:
   timeval CurrentTimeVal() override {
     // The rtc::WinUwpSystemTimeNanos() method is already time offset from a
     // base epoch value and might as be synchronized against an NTP time server
     // as an added bonus.
     auto nanos = rtc::WinUwpSystemTimeNanos();

     struct timeval tv;

     tv.tv_sec = rtc::dchecked_cast<long>(nanos / 1000000000);
     tv.tv_usec = rtc::dchecked_cast<long>(nanos / 1000);

     return tv;
   }
 };

 #elif defined(WEBRTC_WIN)
 // TODO(pbos): Consider modifying the implementation to synchronize itself
 // against system time (update ref_point_) periodically to
 // prevent clock drift.
 class WindowsRealTimeClock : public RealTimeClock {
  public:
   WindowsRealTimeClock()
       : last_time_ms_(0),
         num_timer_wraps_(0),
         ref_point_(GetSystemReferencePoint()) {}

   ~WindowsRealTimeClock() override {}

  protected:
   struct ReferencePoint {
     FILETIME file_time;
     LARGE_INTEGER counter_ms;
   };

   timeval CurrentTimeVal() override {
     const uint64_t FILETIME_1970 = 0x019db1ded53e8000;

     FILETIME StartTime;
     uint64_t Time;
     struct timeval tv;

     // We can't use query performance counter since they can change depending on
     // speed stepping.
     GetTime(&StartTime);

     Time = (((uint64_t)StartTime.dwHighDateTime) << 32) +
            (uint64_t)StartTime.dwLowDateTime;

     // Convert the hecto-nano second time to tv format.
     Time -= FILETIME_1970;

     tv.tv_sec = (uint32_t)(Time / (uint64_t)10000000);
     tv.tv_usec = (uint32_t)((Time % (uint64_t)10000000) / 10);
     return tv;
   }

   void GetTime(FILETIME* current_time) {
     DWORD t;
     LARGE_INTEGER elapsed_ms;
     {
       MutexLock lock(&mutex_);
       // time MUST be fetched inside the critical section to avoid non-monotonic
       // last_time_ms_ values that'll register as incorrect wraparounds due to
       // concurrent calls to GetTime.
       t = timeGetTime();
       if (t < last_time_ms_)
         num_timer_wraps_++;
       last_time_ms_ = t;
       elapsed_ms.HighPart = num_timer_wraps_;
     }
     elapsed_ms.LowPart = t;
     elapsed_ms.QuadPart = elapsed_ms.QuadPart - ref_point_.counter_ms.QuadPart;

     // Translate to 100-nanoseconds intervals (FILETIME resolution)
     // and add to reference FILETIME to get current FILETIME.
     ULARGE_INTEGER filetime_ref_as_ul;
     filetime_ref_as_ul.HighPart = ref_point_.file_time.dwHighDateTime;
     filetime_ref_as_ul.LowPart = ref_point_.file_time.dwLowDateTime;
     filetime_ref_as_ul.QuadPart +=
         static_cast<ULONGLONG>((elapsed_ms.QuadPart) * 1000 * 10);

     // Copy to result
     current_time->dwHighDateTime = filetime_ref_as_ul.HighPart;
     current_time->dwLowDateTime = filetime_ref_as_ul.LowPart;
   }

   static ReferencePoint GetSystemReferencePoint() {
     ReferencePoint ref = {};
     FILETIME ft0 = {};
     FILETIME ft1 = {};
     // Spin waiting for a change in system time. As soon as this change happens,
     // get the matching call for timeGetTime() as soon as possible. This is
     // assumed to be the most accurate offset that we can get between
     // timeGetTime() and system time.

     // Set timer accuracy to 1 ms.
     timeBeginPeriod(1);
     GetSystemTimeAsFileTime(&ft0);
     do {
       GetSystemTimeAsFileTime(&ft1);

       ref.counter_ms.QuadPart = timeGetTime();
       Sleep(0);
     } while ((ft0.dwHighDateTime == ft1.dwHighDateTime) &&
              (ft0.dwLowDateTime == ft1.dwLowDateTime));
     ref.file_time = ft1;
     timeEndPeriod(1);
     return ref;
   }

   Mutex mutex_;
   DWORD last_time_ms_;
   LONG num_timer_wraps_;
   const ReferencePoint ref_point_;
 };

 #elif defined(WEBRTC_POSIX)
 class UnixRealTimeClock : public RealTimeClock {
  public:
   UnixRealTimeClock() {}

   ~UnixRealTimeClock() override {}

  protected:
   timeval CurrentTimeVal() override {
     struct timeval tv;
     struct timezone tz;
     tz.tz_minuteswest = 0;
     tz.tz_dsttime = 0;
     gettimeofday(&tv, &tz);
     return tv;
   }
 };
 #endif  // defined(WEBRTC_POSIX)

 Clock* Clock::GetRealTimeClock() {
 #if defined(WINUWP)
   static Clock* const clock = new WinUwpRealTimeClock();
 #elif defined(WEBRTC_WIN)
   static Clock* const clock = new WindowsRealTimeClock();
 #elif defined(WEBRTC_POSIX)
   static Clock* const clock = new UnixRealTimeClock();
 #else
   static Clock* const clock = nullptr;
 #endif
   return clock;
 }

 SimulatedClock::SimulatedClock(int64_t initial_time_us)
     : time_us_(initial_time_us) {}

 SimulatedClock::SimulatedClock(Timestamp initial_time)
     : SimulatedClock(initial_time.us()) {}

 SimulatedClock::~SimulatedClock() {}

 Timestamp SimulatedClock::CurrentTime() {
   return Timestamp::Micros(time_us_.load(std::memory_order_relaxed));
 }

 NtpTime SimulatedClock::CurrentNtpTime() {
   int64_t now_ms = TimeInMilliseconds();
   uint32_t seconds = (now_ms / 1000) + kNtpJan1970;
   uint32_t fractions =
       static_cast<uint32_t>((now_ms % 1000) * kMagicNtpFractionalUnit / 1000);
   return NtpTime(seconds, fractions);
 }

 void SimulatedClock::AdvanceTimeMilliseconds(int64_t milliseconds) {
   AdvanceTime(TimeDelta::Millis(milliseconds));
 }

 void SimulatedClock::AdvanceTimeMicroseconds(int64_t microseconds) {
   AdvanceTime(TimeDelta::Micros(microseconds));
 }

 // TODO(bugs.webrtc.org(12102): It's desirable to let a single thread own
 // advancement of the clock. We could then replace this read-modify-write
 // operation with just a thread checker. But currently, that breaks a couple of
 // tests, in particular, RepeatingTaskTest.ClockIntegration and
 // CallStatsTest.LastProcessedRtt.
 void SimulatedClock::AdvanceTime(TimeDelta delta) {
   time_us_.fetch_add(delta.us(), std::memory_order_relaxed);
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2013 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "system_wrappers/include/clock.h"

	#include "system_wrappers/include/field_trial.h"

	#if defined(WEBRTC_WIN)

	// Windows needs to be included before mmsystem.h
	#include "rtc_base/win32.h"

	#include <mmsystem.h>


	#elif defined(WEBRTC_POSIX)

	#include <sys/time.h>
	#include <time.h>

	#endif // defined(WEBRTC_POSIX)

	#include "rtc_base/synchronization/mutex.h"
	#include "rtc_base/time_utils.h"

	namespace webrtc {
	namespace {

	int64_t NtpOffsetUsCalledOnce() {
	constexpr int64_t kNtpJan1970Sec = 2208988800;
	int64_t clock_time = rtc::TimeMicros();
	int64_t utc_time = rtc::TimeUTCMicros();
	return utc_time - clock_time + kNtpJan1970Sec * rtc::kNumMicrosecsPerSec;
	}

	NtpTime TimeMicrosToNtp(int64_t time_us) {
	static int64_t ntp_offset_us = NtpOffsetUsCalledOnce();

	int64_t time_ntp_us = time_us + ntp_offset_us;
	RTC_DCHECK_GE(time_ntp_us, 0); // Time before year 1900 is unsupported.

	// Convert seconds to uint32 through uint64 for a well-defined cast.
	// A wrap around, which will happen in 2036, is expected for NTP time.
	uint32_t ntp_seconds =
	static_cast<uint64_t>(time_ntp_us / rtc::kNumMicrosecsPerSec);

	// Scale fractions of the second to NTP resolution.
	constexpr int64_t kNtpFractionsInSecond = 1LL << 32;
	int64_t us_fractions = time_ntp_us % rtc::kNumMicrosecsPerSec;
	uint32_t ntp_fractions =
	us_fractions * kNtpFractionsInSecond / rtc::kNumMicrosecsPerSec;

	return NtpTime(ntp_seconds, ntp_fractions);
	}

	void GetSecondsAndFraction(const timeval& time,
	uint32_t* seconds,
	double* fraction) {
	*seconds = time.tv_sec + kNtpJan1970;
	*fraction = time.tv_usec / 1e6;

	while (*fraction >= 1) {
	--*fraction;
	++*seconds;
	}
	while (*fraction < 0) {
	++*fraction;
	--*seconds;
	}
	}

	} // namespace

	class RealTimeClock : public Clock {
	public:
	RealTimeClock()
	: use_system_independent_ntp_time_(!field_trial::IsEnabled(
	"WebRTC-SystemIndependentNtpTimeKillSwitch")) {}

	Timestamp CurrentTime() override {
	return Timestamp::Micros(rtc::TimeMicros());
	}

	NtpTime CurrentNtpTime() override {
	return use_system_independent_ntp_time_ ? TimeMicrosToNtp(rtc::TimeMicros())
	: SystemDependentNtpTime();
	}

	protected:
	virtual timeval CurrentTimeVal() = 0;

	private:
	NtpTime SystemDependentNtpTime() {
	uint32_t seconds;
	double fraction;
	GetSecondsAndFraction(CurrentTimeVal(), &seconds, &fraction);

	return NtpTime(seconds, static_cast<uint32_t>(
	fraction * kMagicNtpFractionalUnit + 0.5));
	}

	bool use_system_independent_ntp_time_;
	};

	#if defined(WINUWP)
	class WinUwpRealTimeClock final : public RealTimeClock {
	public:
	WinUwpRealTimeClock() = default;
	~WinUwpRealTimeClock() override {}

	protected:
	timeval CurrentTimeVal() override {
	// The rtc::WinUwpSystemTimeNanos() method is already time offset from a
	// base epoch value and might as be synchronized against an NTP time server
	// as an added bonus.
	auto nanos = rtc::WinUwpSystemTimeNanos();

	struct timeval tv;

	tv.tv_sec = rtc::dchecked_cast<long>(nanos / 1000000000);
	tv.tv_usec = rtc::dchecked_cast<long>(nanos / 1000);

	return tv;
	}
	};

	#elif defined(WEBRTC_WIN)
	// TODO(pbos): Consider modifying the implementation to synchronize itself
	// against system time (update ref_point_) periodically to
	// prevent clock drift.
	class WindowsRealTimeClock : public RealTimeClock {
	public:
	WindowsRealTimeClock()
	: last_time_ms_(0),
	num_timer_wraps_(0),
	ref_point_(GetSystemReferencePoint()) {}

	~WindowsRealTimeClock() override {}

	protected:
	struct ReferencePoint {
	FILETIME file_time;
	LARGE_INTEGER counter_ms;
	};

	timeval CurrentTimeVal() override {
	const uint64_t FILETIME_1970 = 0x019db1ded53e8000;

	FILETIME StartTime;
	uint64_t Time;
	struct timeval tv;

	// We can't use query performance counter since they can change depending on
	// speed stepping.
	GetTime(&StartTime);

	Time = (((uint64_t)StartTime.dwHighDateTime) << 32) +
	(uint64_t)StartTime.dwLowDateTime;

	// Convert the hecto-nano second time to tv format.
	Time -= FILETIME_1970;

	tv.tv_sec = (uint32_t)(Time / (uint64_t)10000000);
	tv.tv_usec = (uint32_t)((Time % (uint64_t)10000000) / 10);
	return tv;
	}

	void GetTime(FILETIME* current_time) {
	DWORD t;
	LARGE_INTEGER elapsed_ms;
	{
	MutexLock lock(&mutex_);
	// time MUST be fetched inside the critical section to avoid non-monotonic
	// last_time_ms_ values that'll register as incorrect wraparounds due to
	// concurrent calls to GetTime.
	t = timeGetTime();
	if (t < last_time_ms_)
	num_timer_wraps_++;
	last_time_ms_ = t;
	elapsed_ms.HighPart = num_timer_wraps_;
	}
	elapsed_ms.LowPart = t;
	elapsed_ms.QuadPart = elapsed_ms.QuadPart - ref_point_.counter_ms.QuadPart;

	// Translate to 100-nanoseconds intervals (FILETIME resolution)
	// and add to reference FILETIME to get current FILETIME.
	ULARGE_INTEGER filetime_ref_as_ul;
	filetime_ref_as_ul.HighPart = ref_point_.file_time.dwHighDateTime;
	filetime_ref_as_ul.LowPart = ref_point_.file_time.dwLowDateTime;
	filetime_ref_as_ul.QuadPart +=
	static_cast<ULONGLONG>((elapsed_ms.QuadPart) * 1000 * 10);

	// Copy to result
	current_time->dwHighDateTime = filetime_ref_as_ul.HighPart;
	current_time->dwLowDateTime = filetime_ref_as_ul.LowPart;
	}

	static ReferencePoint GetSystemReferencePoint() {
	ReferencePoint ref = {};
	FILETIME ft0 = {};
	FILETIME ft1 = {};
	// Spin waiting for a change in system time. As soon as this change happens,
	// get the matching call for timeGetTime() as soon as possible. This is
	// assumed to be the most accurate offset that we can get between
	// timeGetTime() and system time.

	// Set timer accuracy to 1 ms.
	timeBeginPeriod(1);
	GetSystemTimeAsFileTime(&ft0);
	do {
	GetSystemTimeAsFileTime(&ft1);

	ref.counter_ms.QuadPart = timeGetTime();
	Sleep(0);
	} while ((ft0.dwHighDateTime == ft1.dwHighDateTime) &&
	(ft0.dwLowDateTime == ft1.dwLowDateTime));
	ref.file_time = ft1;
	timeEndPeriod(1);
	return ref;
	}

	Mutex mutex_;
	DWORD last_time_ms_;
	LONG num_timer_wraps_;
	const ReferencePoint ref_point_;
	};

	#elif defined(WEBRTC_POSIX)
	class UnixRealTimeClock : public RealTimeClock {
	public:
	UnixRealTimeClock() {}

	~UnixRealTimeClock() override {}

	protected:
	timeval CurrentTimeVal() override {
	struct timeval tv;
	struct timezone tz;
	tz.tz_minuteswest = 0;
	tz.tz_dsttime = 0;
	gettimeofday(&tv, &tz);
	return tv;
	}
	};
	#endif // defined(WEBRTC_POSIX)

	Clock* Clock::GetRealTimeClock() {
	#if defined(WINUWP)
	static Clock* const clock = new WinUwpRealTimeClock();
	#elif defined(WEBRTC_WIN)
	static Clock* const clock = new WindowsRealTimeClock();
	#elif defined(WEBRTC_POSIX)
	static Clock* const clock = new UnixRealTimeClock();
	#else
	static Clock* const clock = nullptr;
	#endif
	return clock;
	}

	SimulatedClock::SimulatedClock(int64_t initial_time_us)
	: time_us_(initial_time_us) {}

	SimulatedClock::SimulatedClock(Timestamp initial_time)
	: SimulatedClock(initial_time.us()) {}

	SimulatedClock::~SimulatedClock() {}

	Timestamp SimulatedClock::CurrentTime() {
	return Timestamp::Micros(time_us_.load(std::memory_order_relaxed));
	}

	NtpTime SimulatedClock::CurrentNtpTime() {
	int64_t now_ms = TimeInMilliseconds();
	uint32_t seconds = (now_ms / 1000) + kNtpJan1970;
	uint32_t fractions =
	static_cast<uint32_t>((now_ms % 1000) * kMagicNtpFractionalUnit / 1000);
	return NtpTime(seconds, fractions);
	}

	void SimulatedClock::AdvanceTimeMilliseconds(int64_t milliseconds) {
	AdvanceTime(TimeDelta::Millis(milliseconds));
	}

	void SimulatedClock::AdvanceTimeMicroseconds(int64_t microseconds) {
	AdvanceTime(TimeDelta::Micros(microseconds));
	}

	// TODO(bugs.webrtc.org(12102): It's desirable to let a single thread own
	// advancement of the clock. We could then replace this read-modify-write
	// operation with just a thread checker. But currently, that breaks a couple of
	// tests, in particular, RepeatingTaskTest.ClockIntegration and
	// CallStatsTest.LastProcessedRtt.
	void SimulatedClock::AdvanceTime(TimeDelta delta) {
	time_us_.fetch_add(delta.us(), std::memory_order_relaxed);
	}

	} // namespace webrtc