video/video_quality_observer.cc - src - Git at Google

 /*
  *  Copyright (c) 2018 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 "video/video_quality_observer.h"

 #include <algorithm>
 #include <cstdint>
 #include <string>

 #include "rtc_base/logging.h"
 #include "rtc_base/strings/string_builder.h"
 #include "system_wrappers/include/metrics.h"

 namespace webrtc {

 namespace {
 const int kMinFrameSamplesToDetectFreeze = 5;
 const int kMinCallDurationMs = 3000;
 const int kMinRequiredSamples = 1;
 const int kMinIncreaseForFreezeMs = 150;
 const int kPixelsInHighResolution = 960 * 540;  // CPU-adapted HD still counts.
 const int kPixelsInMediumResolution = 640 * 360;
 const int kBlockyQpThresholdVp8 = 70;
 const int kBlockyQpThresholdVp9 = 60;  // TODO(ilnik): tune this value.
 // TODO(ilnik): Add H264/HEVC thresholds.
 }  // namespace

 VideoQualityObserver::VideoQualityObserver(VideoContentType content_type)
     : last_frame_decoded_ms_(-1),
       last_frame_rendered_ms_(-1),
       num_frames_decoded_(0),
       num_frames_rendered_(0),
       first_frame_decoded_ms_(-1),
       last_frame_pixels_(0),
       last_frame_qp_(0),
       last_unfreeze_time_(0),
       time_in_resolution_ms_(3, 0),
       current_resolution_(Resolution::Low),
       num_resolution_downgrades_(0),
       time_in_blocky_video_ms_(0),
       content_type_(content_type),
       is_paused_(false) {}

 VideoQualityObserver::~VideoQualityObserver() {
   UpdateHistograms();
 }

 void VideoQualityObserver::UpdateHistograms() {
   // Don't report anything on an empty video stream.
   if (num_frames_decoded_ == 0) {
     return;
   }

   char log_stream_buf[2 * 1024];
   rtc::SimpleStringBuilder log_stream(log_stream_buf);

   if (last_frame_decoded_ms_ > last_unfreeze_time_) {
     smooth_playback_durations_.Add(last_frame_decoded_ms_ -
                                    last_unfreeze_time_);
   }

   std::string uma_prefix = videocontenttypehelpers::IsScreenshare(content_type_)
                                ? "WebRTC.Video.Screenshare"
                                : "WebRTC.Video";

   auto mean_time_between_freezes =
       smooth_playback_durations_.Avg(kMinRequiredSamples);
   if (mean_time_between_freezes) {
     RTC_HISTOGRAM_COUNTS_SPARSE_100000(uma_prefix + ".MeanTimeBetweenFreezesMs",
                                        *mean_time_between_freezes);
     log_stream << uma_prefix << ".MeanTimeBetweenFreezesMs "
                << *mean_time_between_freezes << "\n";
   }
   auto avg_freeze_length = freezes_durations_.Avg(kMinRequiredSamples);
   if (avg_freeze_length) {
     RTC_HISTOGRAM_COUNTS_SPARSE_100000(uma_prefix + ".MeanFreezeDurationMs",
                                        *avg_freeze_length);
     log_stream << uma_prefix << ".MeanFreezeDurationMs " << *avg_freeze_length
                << "\n";
   }

   int64_t call_duration_ms = last_frame_decoded_ms_ - first_frame_decoded_ms_;

   if (call_duration_ms >= kMinCallDurationMs) {
     int time_spent_in_hd_percentage = static_cast<int>(
         time_in_resolution_ms_[Resolution::High] * 100 / call_duration_ms);
     RTC_HISTOGRAM_COUNTS_SPARSE_100(uma_prefix + ".TimeInHdPercentage",
                                     time_spent_in_hd_percentage);
     log_stream << uma_prefix << ".TimeInHdPercentage "
                << time_spent_in_hd_percentage << "\n";

     int time_with_blocky_video_percentage =
         static_cast<int>(time_in_blocky_video_ms_ * 100 / call_duration_ms);
     RTC_HISTOGRAM_COUNTS_SPARSE_100(uma_prefix + ".TimeInBlockyVideoPercentage",
                                     time_with_blocky_video_percentage);
     log_stream << uma_prefix << ".TimeInBlockyVideoPercentage "
                << time_with_blocky_video_percentage << "\n";

     int num_resolution_downgrades_per_minute =
         num_resolution_downgrades_ * 60000 / call_duration_ms;
     RTC_HISTOGRAM_COUNTS_SPARSE_100(
         uma_prefix + ".NumberResolutionDownswitchesPerMinute",
         num_resolution_downgrades_per_minute);
     log_stream << uma_prefix << ".NumberResolutionDownswitchesPerMinute "
                << num_resolution_downgrades_per_minute << "\n";

     int num_freezes_per_minute =
         freezes_durations_.NumSamples() * 60000 / call_duration_ms;
     RTC_HISTOGRAM_COUNTS_SPARSE_100(uma_prefix + ".NumberFreezesPerMinute",
                                     num_freezes_per_minute);
     log_stream << uma_prefix << ".NumberFreezesPerMinute "
                << num_freezes_per_minute << "\n";
   }
   RTC_LOG(LS_INFO) << log_stream.str();
 }

 void VideoQualityObserver::OnRenderedFrame(int64_t now_ms) {
   if (num_frames_rendered_ == 0) {
     last_unfreeze_time_ = now_ms;
   }

   ++num_frames_rendered_;

   if (!is_paused_ && num_frames_rendered_ > 1) {
     // Process inter-frame delay.
     int64_t interframe_delay_ms = now_ms - last_frame_rendered_ms_;
     render_interframe_delays_.Add(interframe_delay_ms);
     absl::optional<int> avg_interframe_delay =
         render_interframe_delays_.Avg(kMinFrameSamplesToDetectFreeze);
     // Check if it was a freeze.
     if (avg_interframe_delay &&
         interframe_delay_ms >=
             std::max(3 * *avg_interframe_delay,
                      *avg_interframe_delay + kMinIncreaseForFreezeMs)) {
       freezes_durations_.Add(interframe_delay_ms);
       smooth_playback_durations_.Add(last_frame_rendered_ms_ -
                                      last_unfreeze_time_);
       last_unfreeze_time_ = now_ms;
     }
   }

   if (is_paused_) {
     // If the stream was paused since the previous frame, do not count the
     // pause toward smooth playback. Explicitly count the part before it and
     // start the new smooth playback interval from this frame.
     is_paused_ = false;
     if (last_frame_rendered_ms_ > last_unfreeze_time_) {
       smooth_playback_durations_.Add(last_frame_rendered_ms_ -
                                      last_unfreeze_time_);
     }
     last_unfreeze_time_ = now_ms;
   }

   last_frame_rendered_ms_ = now_ms;
 }

 void VideoQualityObserver::OnDecodedFrame(absl::optional<uint8_t> qp,
                                           int width,
                                           int height,
                                           int64_t now_ms,
                                           VideoCodecType codec) {
   if (num_frames_decoded_ == 0) {
     first_frame_decoded_ms_ = now_ms;
   }

   ++num_frames_decoded_;

   if (!is_paused_ && num_frames_decoded_ > 1) {
     // Process inter-frame delay.
     int64_t interframe_delay_ms = now_ms - last_frame_decoded_ms_;
     decode_interframe_delays_.Add(interframe_delay_ms);
     absl::optional<int> avg_interframe_delay =
         decode_interframe_delays_.Avg(kMinFrameSamplesToDetectFreeze);
     // Count spatial metrics if there were no freeze.
     if (!avg_interframe_delay ||
         interframe_delay_ms <
             std::max(3 * *avg_interframe_delay,
                      *avg_interframe_delay + kMinIncreaseForFreezeMs)) {
       time_in_resolution_ms_[current_resolution_] += interframe_delay_ms;
       absl::optional<int> qp_blocky_threshold;
       // TODO(ilnik): add other codec types when we have QP for them.
       switch (codec) {
         case kVideoCodecVP8:
           qp_blocky_threshold = kBlockyQpThresholdVp8;
           break;
         case kVideoCodecVP9:
           qp_blocky_threshold = kBlockyQpThresholdVp9;
           break;
         default:
           qp_blocky_threshold = absl::nullopt;
       }
       if (qp_blocky_threshold && qp.value_or(0) > *qp_blocky_threshold) {
         time_in_blocky_video_ms_ += interframe_delay_ms;
       }
     }
   }

   int64_t pixels = width * height;
   if (pixels >= kPixelsInHighResolution) {
     current_resolution_ = Resolution::High;
   } else if (pixels >= kPixelsInMediumResolution) {
     current_resolution_ = Resolution::Medium;
   } else {
     current_resolution_ = Resolution::Low;
   }

   if (pixels < last_frame_pixels_) {
     ++num_resolution_downgrades_;
   }

   last_frame_decoded_ms_ = now_ms;
   last_frame_qp_ = qp.value_or(0);
   last_frame_pixels_ = pixels;
 }

 void VideoQualityObserver::OnStreamInactive() {
   is_paused_ = true;
 }
 }  // namespace webrtc
	/*
	* Copyright (c) 2018 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 "video/video_quality_observer.h"

	#include <algorithm>
	#include <cstdint>
	#include <string>

	#include "rtc_base/logging.h"
	#include "rtc_base/strings/string_builder.h"
	#include "system_wrappers/include/metrics.h"

	namespace webrtc {

	namespace {
	const int kMinFrameSamplesToDetectFreeze = 5;
	const int kMinCallDurationMs = 3000;
	const int kMinRequiredSamples = 1;
	const int kMinIncreaseForFreezeMs = 150;
	const int kPixelsInHighResolution = 960 * 540; // CPU-adapted HD still counts.
	const int kPixelsInMediumResolution = 640 * 360;
	const int kBlockyQpThresholdVp8 = 70;
	const int kBlockyQpThresholdVp9 = 60; // TODO(ilnik): tune this value.
	// TODO(ilnik): Add H264/HEVC thresholds.
	} // namespace

	VideoQualityObserver::VideoQualityObserver(VideoContentType content_type)
	: last_frame_decoded_ms_(-1),
	last_frame_rendered_ms_(-1),
	num_frames_decoded_(0),
	num_frames_rendered_(0),
	first_frame_decoded_ms_(-1),
	last_frame_pixels_(0),
	last_frame_qp_(0),
	last_unfreeze_time_(0),
	time_in_resolution_ms_(3, 0),
	current_resolution_(Resolution::Low),
	num_resolution_downgrades_(0),
	time_in_blocky_video_ms_(0),
	content_type_(content_type),
	is_paused_(false) {}

	VideoQualityObserver::~VideoQualityObserver() {
	UpdateHistograms();
	}

	void VideoQualityObserver::UpdateHistograms() {
	// Don't report anything on an empty video stream.
	if (num_frames_decoded_ == 0) {
	return;
	}

	char log_stream_buf[2 * 1024];
	rtc::SimpleStringBuilder log_stream(log_stream_buf);

	if (last_frame_decoded_ms_ > last_unfreeze_time_) {
	smooth_playback_durations_.Add(last_frame_decoded_ms_ -
	last_unfreeze_time_);
	}

	std::string uma_prefix = videocontenttypehelpers::IsScreenshare(content_type_)
	? "WebRTC.Video.Screenshare"
	: "WebRTC.Video";

	auto mean_time_between_freezes =
	smooth_playback_durations_.Avg(kMinRequiredSamples);
	if (mean_time_between_freezes) {
	RTC_HISTOGRAM_COUNTS_SPARSE_100000(uma_prefix + ".MeanTimeBetweenFreezesMs",
	*mean_time_between_freezes);
	log_stream << uma_prefix << ".MeanTimeBetweenFreezesMs "
	<< *mean_time_between_freezes << "\n";
	}
	auto avg_freeze_length = freezes_durations_.Avg(kMinRequiredSamples);
	if (avg_freeze_length) {
	RTC_HISTOGRAM_COUNTS_SPARSE_100000(uma_prefix + ".MeanFreezeDurationMs",
	*avg_freeze_length);
	log_stream << uma_prefix << ".MeanFreezeDurationMs " << *avg_freeze_length
	<< "\n";
	}

	int64_t call_duration_ms = last_frame_decoded_ms_ - first_frame_decoded_ms_;

	if (call_duration_ms >= kMinCallDurationMs) {
	int time_spent_in_hd_percentage = static_cast<int>(
	time_in_resolution_ms_[Resolution::High] * 100 / call_duration_ms);
	RTC_HISTOGRAM_COUNTS_SPARSE_100(uma_prefix + ".TimeInHdPercentage",
	time_spent_in_hd_percentage);
	log_stream << uma_prefix << ".TimeInHdPercentage "
	<< time_spent_in_hd_percentage << "\n";

	int time_with_blocky_video_percentage =
	static_cast<int>(time_in_blocky_video_ms_ * 100 / call_duration_ms);
	RTC_HISTOGRAM_COUNTS_SPARSE_100(uma_prefix + ".TimeInBlockyVideoPercentage",
	time_with_blocky_video_percentage);
	log_stream << uma_prefix << ".TimeInBlockyVideoPercentage "
	<< time_with_blocky_video_percentage << "\n";

	int num_resolution_downgrades_per_minute =
	num_resolution_downgrades_ * 60000 / call_duration_ms;
	RTC_HISTOGRAM_COUNTS_SPARSE_100(
	uma_prefix + ".NumberResolutionDownswitchesPerMinute",
	num_resolution_downgrades_per_minute);
	log_stream << uma_prefix << ".NumberResolutionDownswitchesPerMinute "
	<< num_resolution_downgrades_per_minute << "\n";

	int num_freezes_per_minute =
	freezes_durations_.NumSamples() * 60000 / call_duration_ms;
	RTC_HISTOGRAM_COUNTS_SPARSE_100(uma_prefix + ".NumberFreezesPerMinute",
	num_freezes_per_minute);
	log_stream << uma_prefix << ".NumberFreezesPerMinute "
	<< num_freezes_per_minute << "\n";
	}
	RTC_LOG(LS_INFO) << log_stream.str();
	}

	void VideoQualityObserver::OnRenderedFrame(int64_t now_ms) {
	if (num_frames_rendered_ == 0) {
	last_unfreeze_time_ = now_ms;
	}

	++num_frames_rendered_;

	if (!is_paused_ && num_frames_rendered_ > 1) {
	// Process inter-frame delay.
	int64_t interframe_delay_ms = now_ms - last_frame_rendered_ms_;
	render_interframe_delays_.Add(interframe_delay_ms);
	absl::optional<int> avg_interframe_delay =
	render_interframe_delays_.Avg(kMinFrameSamplesToDetectFreeze);
	// Check if it was a freeze.
	if (avg_interframe_delay &&
	interframe_delay_ms >=
	std::max(3 * *avg_interframe_delay,
	*avg_interframe_delay + kMinIncreaseForFreezeMs)) {
	freezes_durations_.Add(interframe_delay_ms);
	smooth_playback_durations_.Add(last_frame_rendered_ms_ -
	last_unfreeze_time_);
	last_unfreeze_time_ = now_ms;
	}
	}

	if (is_paused_) {
	// If the stream was paused since the previous frame, do not count the
	// pause toward smooth playback. Explicitly count the part before it and
	// start the new smooth playback interval from this frame.
	is_paused_ = false;
	if (last_frame_rendered_ms_ > last_unfreeze_time_) {
	smooth_playback_durations_.Add(last_frame_rendered_ms_ -
	last_unfreeze_time_);
	}
	last_unfreeze_time_ = now_ms;
	}

	last_frame_rendered_ms_ = now_ms;
	}

	void VideoQualityObserver::OnDecodedFrame(absl::optional<uint8_t> qp,
	int width,
	int height,
	int64_t now_ms,
	VideoCodecType codec) {
	if (num_frames_decoded_ == 0) {
	first_frame_decoded_ms_ = now_ms;
	}

	++num_frames_decoded_;

	if (!is_paused_ && num_frames_decoded_ > 1) {
	// Process inter-frame delay.
	int64_t interframe_delay_ms = now_ms - last_frame_decoded_ms_;
	decode_interframe_delays_.Add(interframe_delay_ms);
	absl::optional<int> avg_interframe_delay =
	decode_interframe_delays_.Avg(kMinFrameSamplesToDetectFreeze);
	// Count spatial metrics if there were no freeze.
	if (!avg_interframe_delay \|\|
	interframe_delay_ms <
	std::max(3 * *avg_interframe_delay,
	*avg_interframe_delay + kMinIncreaseForFreezeMs)) {
	time_in_resolution_ms_[current_resolution_] += interframe_delay_ms;
	absl::optional<int> qp_blocky_threshold;
	// TODO(ilnik): add other codec types when we have QP for them.
	switch (codec) {
	case kVideoCodecVP8:
	qp_blocky_threshold = kBlockyQpThresholdVp8;
	break;
	case kVideoCodecVP9:
	qp_blocky_threshold = kBlockyQpThresholdVp9;
	break;
	default:
	qp_blocky_threshold = absl::nullopt;
	}
	if (qp_blocky_threshold && qp.value_or(0) > *qp_blocky_threshold) {
	time_in_blocky_video_ms_ += interframe_delay_ms;
	}
	}
	}

	int64_t pixels = width * height;
	if (pixels >= kPixelsInHighResolution) {
	current_resolution_ = Resolution::High;
	} else if (pixels >= kPixelsInMediumResolution) {
	current_resolution_ = Resolution::Medium;
	} else {
	current_resolution_ = Resolution::Low;
	}

	if (pixels < last_frame_pixels_) {
	++num_resolution_downgrades_;
	}

	last_frame_decoded_ms_ = now_ms;
	last_frame_qp_ = qp.value_or(0);
	last_frame_pixels_ = pixels;
	}

	void VideoQualityObserver::OnStreamInactive() {
	is_paused_ = true;
	}
	} // namespace webrtc