ui/gl/sync_control_vsync_provider.cc - mojo - Git at Google

 // Copyright 2013 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "ui/gl/sync_control_vsync_provider.h"

 #include <math.h>

 #include "base/logging.h"
 #include "base/time/time.h"

 #if defined(OS_LINUX)
 // These constants define a reasonable range for a calculated refresh interval.
 // Calculating refreshes out of this range will be considered a fatal error.
 const int64 kMinVsyncIntervalUs = base::Time::kMicrosecondsPerSecond / 400;
 const int64 kMaxVsyncIntervalUs = base::Time::kMicrosecondsPerSecond / 10;

 // How much noise we'll tolerate between successive computed intervals before
 // we think the latest computed interval is invalid (noisey due to
 // monitor configuration change, moving a window between monitors, etc.).
 const double kRelativeIntervalDifferenceThreshold = 0.05;
 #endif

 namespace gfx {

 SyncControlVSyncProvider::SyncControlVSyncProvider()
     : VSyncProvider(), last_media_stream_counter_(0), invalid_msc_(false) {
   // On platforms where we can't get an accurate reading on the refresh
   // rate we fall back to the assumption that we're displaying 60 frames
   // per second.
   last_good_interval_ = base::TimeDelta::FromSeconds(1) / 60;
 }

 SyncControlVSyncProvider::~SyncControlVSyncProvider() {}

 void SyncControlVSyncProvider::GetVSyncParameters(
     const UpdateVSyncCallback& callback) {
 #if defined(OS_LINUX)
   base::TimeTicks timebase;

   // The actual clock used for the system time returned by glXGetSyncValuesOML
   // is unspecified. In practice, the clock used is likely to be either
   // CLOCK_REALTIME or CLOCK_MONOTONIC, so we compare the returned time to the
   // current time according to both clocks, and assume that the returned time
   // was produced by the clock whose current time is closest to it, subject
   // to the restriction that the returned time must not be in the future
   // (since it is the time of a vblank that has already occurred).
   int64 system_time;
   int64 media_stream_counter;
   int64 swap_buffer_counter;
   if (!GetSyncValues(&system_time, &media_stream_counter, &swap_buffer_counter))
     return;

   // Both Intel and Mali drivers will return TRUE for GetSyncValues
   // but a value of 0 for MSC if they cannot access the CRTC data structure
   // associated with the surface. crbug.com/231945
   bool prev_invalid_msc = invalid_msc_;
   invalid_msc_ = (media_stream_counter == 0);
   if (invalid_msc_) {
     LOG_IF(ERROR, !prev_invalid_msc) << "glXGetSyncValuesOML "
         "should not return TRUE with a media stream counter of 0.";
     return;
   }

   struct timespec real_time;
   struct timespec monotonic_time;
   clock_gettime(CLOCK_REALTIME, &real_time);
   clock_gettime(CLOCK_MONOTONIC, &monotonic_time);

   int64 real_time_in_microseconds =
       real_time.tv_sec * base::Time::kMicrosecondsPerSecond +
       real_time.tv_nsec / base::Time::kNanosecondsPerMicrosecond;
   int64 monotonic_time_in_microseconds =
       monotonic_time.tv_sec * base::Time::kMicrosecondsPerSecond +
       monotonic_time.tv_nsec / base::Time::kNanosecondsPerMicrosecond;

   // We need the time according to CLOCK_MONOTONIC, so if we've been given
   // a time from CLOCK_REALTIME, we need to convert.
   bool time_conversion_needed =
       llabs(system_time - real_time_in_microseconds) <
       llabs(system_time - monotonic_time_in_microseconds);

   if (time_conversion_needed)
     system_time += monotonic_time_in_microseconds - real_time_in_microseconds;

   // Return if |system_time| is more than 1 frames in the future.
   int64 interval_in_microseconds = last_good_interval_.InMicroseconds();
   if (system_time > monotonic_time_in_microseconds + interval_in_microseconds)
     return;

   // If |system_time| is slightly in the future, adjust it to the previous
   // frame and use the last frame counter to prevent issues in the callback.
   if (system_time > monotonic_time_in_microseconds) {
     system_time -= interval_in_microseconds;
     media_stream_counter--;
   }
   if (monotonic_time_in_microseconds - system_time >
       base::Time::kMicrosecondsPerSecond)
     return;

   timebase = base::TimeTicks::FromInternalValue(system_time);

   // Only need the previous calculated interval for our filtering.
   while (last_computed_intervals_.size() > 1)
     last_computed_intervals_.pop();

   int32 numerator, denominator;
   if (GetMscRate(&numerator, &denominator)) {
     last_computed_intervals_.push(base::TimeDelta::FromSeconds(denominator) /
                                   numerator);
   } else if (!last_timebase_.is_null()) {
     base::TimeDelta timebase_diff = timebase - last_timebase_;
     int64 counter_diff = media_stream_counter - last_media_stream_counter_;
     if (counter_diff > 0 && timebase > last_timebase_)
       last_computed_intervals_.push(timebase_diff / counter_diff);
   }

   if (last_computed_intervals_.size() == 2) {
     const base::TimeDelta& old_interval = last_computed_intervals_.front();
     const base::TimeDelta& new_interval = last_computed_intervals_.back();

     double relative_change =
         fabs(old_interval.InMillisecondsF() - new_interval.InMillisecondsF()) /
         new_interval.InMillisecondsF();
     if (relative_change < kRelativeIntervalDifferenceThreshold) {
       if (new_interval.InMicroseconds() < kMinVsyncIntervalUs ||
           new_interval.InMicroseconds() > kMaxVsyncIntervalUs) {
         LOG(ERROR)
             << "Calculated bogus refresh interval="
             << new_interval.InMicroseconds()
             << " us., last_timebase_=" << last_timebase_.ToInternalValue()
             << " us., timebase=" << timebase.ToInternalValue()
             << " us., last_media_stream_counter_=" << last_media_stream_counter_
             << ", media_stream_counter=" << media_stream_counter;
       } else {
         last_good_interval_ = new_interval;
       }
     }
   }

   last_timebase_ = timebase;
   last_media_stream_counter_ = media_stream_counter;
   callback.Run(timebase, last_good_interval_);
 #endif  // defined(OS_LINUX)
 }

 }  // namespace gfx
	// Copyright 2013 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "ui/gl/sync_control_vsync_provider.h"

	#include <math.h>

	#include "base/logging.h"
	#include "base/time/time.h"

	#if defined(OS_LINUX)
	// These constants define a reasonable range for a calculated refresh interval.
	// Calculating refreshes out of this range will be considered a fatal error.
	const int64 kMinVsyncIntervalUs = base::Time::kMicrosecondsPerSecond / 400;
	const int64 kMaxVsyncIntervalUs = base::Time::kMicrosecondsPerSecond / 10;

	// How much noise we'll tolerate between successive computed intervals before
	// we think the latest computed interval is invalid (noisey due to
	// monitor configuration change, moving a window between monitors, etc.).
	const double kRelativeIntervalDifferenceThreshold = 0.05;
	#endif

	namespace gfx {

	SyncControlVSyncProvider::SyncControlVSyncProvider()
	: VSyncProvider(), last_media_stream_counter_(0), invalid_msc_(false) {
	// On platforms where we can't get an accurate reading on the refresh
	// rate we fall back to the assumption that we're displaying 60 frames
	// per second.
	last_good_interval_ = base::TimeDelta::FromSeconds(1) / 60;
	}

	SyncControlVSyncProvider::~SyncControlVSyncProvider() {}

	void SyncControlVSyncProvider::GetVSyncParameters(
	const UpdateVSyncCallback& callback) {
	#if defined(OS_LINUX)
	base::TimeTicks timebase;

	// The actual clock used for the system time returned by glXGetSyncValuesOML
	// is unspecified. In practice, the clock used is likely to be either
	// CLOCK_REALTIME or CLOCK_MONOTONIC, so we compare the returned time to the
	// current time according to both clocks, and assume that the returned time
	// was produced by the clock whose current time is closest to it, subject
	// to the restriction that the returned time must not be in the future
	// (since it is the time of a vblank that has already occurred).
	int64 system_time;
	int64 media_stream_counter;
	int64 swap_buffer_counter;
	if (!GetSyncValues(&system_time, &media_stream_counter, &swap_buffer_counter))
	return;

	// Both Intel and Mali drivers will return TRUE for GetSyncValues
	// but a value of 0 for MSC if they cannot access the CRTC data structure
	// associated with the surface. crbug.com/231945
	bool prev_invalid_msc = invalid_msc_;
	invalid_msc_ = (media_stream_counter == 0);
	if (invalid_msc_) {
	LOG_IF(ERROR, !prev_invalid_msc) << "glXGetSyncValuesOML "
	"should not return TRUE with a media stream counter of 0.";
	return;
	}

	struct timespec real_time;
	struct timespec monotonic_time;
	clock_gettime(CLOCK_REALTIME, &real_time);
	clock_gettime(CLOCK_MONOTONIC, &monotonic_time);

	int64 real_time_in_microseconds =
	real_time.tv_sec * base::Time::kMicrosecondsPerSecond +
	real_time.tv_nsec / base::Time::kNanosecondsPerMicrosecond;
	int64 monotonic_time_in_microseconds =
	monotonic_time.tv_sec * base::Time::kMicrosecondsPerSecond +
	monotonic_time.tv_nsec / base::Time::kNanosecondsPerMicrosecond;

	// We need the time according to CLOCK_MONOTONIC, so if we've been given
	// a time from CLOCK_REALTIME, we need to convert.
	bool time_conversion_needed =
	llabs(system_time - real_time_in_microseconds) <
	llabs(system_time - monotonic_time_in_microseconds);

	if (time_conversion_needed)
	system_time += monotonic_time_in_microseconds - real_time_in_microseconds;

	// Return if \|system_time\| is more than 1 frames in the future.
	int64 interval_in_microseconds = last_good_interval_.InMicroseconds();
	if (system_time > monotonic_time_in_microseconds + interval_in_microseconds)
	return;

	// If \|system_time\| is slightly in the future, adjust it to the previous
	// frame and use the last frame counter to prevent issues in the callback.
	if (system_time > monotonic_time_in_microseconds) {
	system_time -= interval_in_microseconds;
	media_stream_counter--;
	}
	if (monotonic_time_in_microseconds - system_time >
	base::Time::kMicrosecondsPerSecond)
	return;

	timebase = base::TimeTicks::FromInternalValue(system_time);

	// Only need the previous calculated interval for our filtering.
	while (last_computed_intervals_.size() > 1)
	last_computed_intervals_.pop();

	int32 numerator, denominator;
	if (GetMscRate(&numerator, &denominator)) {
	last_computed_intervals_.push(base::TimeDelta::FromSeconds(denominator) /
	numerator);
	} else if (!last_timebase_.is_null()) {
	base::TimeDelta timebase_diff = timebase - last_timebase_;
	int64 counter_diff = media_stream_counter - last_media_stream_counter_;
	if (counter_diff > 0 && timebase > last_timebase_)
	last_computed_intervals_.push(timebase_diff / counter_diff);
	}

	if (last_computed_intervals_.size() == 2) {
	const base::TimeDelta& old_interval = last_computed_intervals_.front();
	const base::TimeDelta& new_interval = last_computed_intervals_.back();

	double relative_change =
	fabs(old_interval.InMillisecondsF() - new_interval.InMillisecondsF()) /
	new_interval.InMillisecondsF();
	if (relative_change < kRelativeIntervalDifferenceThreshold) {
	if (new_interval.InMicroseconds() < kMinVsyncIntervalUs \|\|
	new_interval.InMicroseconds() > kMaxVsyncIntervalUs) {
	LOG(ERROR)
	<< "Calculated bogus refresh interval="
	<< new_interval.InMicroseconds()
	<< " us., last_timebase_=" << last_timebase_.ToInternalValue()
	<< " us., timebase=" << timebase.ToInternalValue()
	<< " us., last_media_stream_counter_=" << last_media_stream_counter_
	<< ", media_stream_counter=" << media_stream_counter;
	} else {
	last_good_interval_ = new_interval;
	}
	}
	}

	last_timebase_ = timebase;
	last_media_stream_counter_ = media_stream_counter;
	callback.Run(timebase, last_good_interval_);
	#endif // defined(OS_LINUX)
	}

	} // namespace gfx