video/quality_convergence_monitor.cc - src - Git at Google

 /*
  *  Copyright (c) 2024 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/quality_convergence_monitor.h"

 #include <numeric>

 #include "rtc_base/checks.h"
 #include "rtc_base/experiments/struct_parameters_parser.h"

 namespace webrtc {
 namespace {
 constexpr size_t kDefaultRecentWindowLength = 6;
 constexpr size_t kDefaultPastWindowLength = 6;
 constexpr float kDefaultAlpha = 0.06;

 struct DynamicDetectionConfig {
   bool enabled = false;
   // alpha is a percentage of the codec-specific max QP value that is used to
   // determine the dynamic QP threshold:
   //   dynamic_qp_threshold = static_qp_threshold + alpha * max_QP
   double alpha = kDefaultAlpha;
   int recent_length = kDefaultRecentWindowLength;
   int past_length = kDefaultPastWindowLength;
   std::unique_ptr<StructParametersParser> Parser();
 };

 std::unique_ptr<StructParametersParser> DynamicDetectionConfig::Parser() {
   // The empty comments ensures that each pair is on a separate line.
   return StructParametersParser::Create("enabled", &enabled,              //
                                         "alpha", &alpha,                  //
                                         "recent_length", &recent_length,  //
                                         "past_length", &past_length);
 }

 QualityConvergenceMonitor::Parameters GetParameters(
     int static_qp_threshold,
     VideoCodecType codec,
     const FieldTrialsView& trials) {
   QualityConvergenceMonitor::Parameters params;
   params.static_qp_threshold = static_qp_threshold;

   DynamicDetectionConfig dynamic_config;
   // Apply codec specific settings.
   int max_qp = 0;
   switch (codec) {
     case kVideoCodecVP8:
       dynamic_config.Parser()->Parse(trials.Lookup("WebRTC-QCM-Dynamic-VP8"));
       max_qp = 127;
       break;
     case kVideoCodecVP9:
       // Change to enabled by default for VP9.
       dynamic_config.enabled = true;
       dynamic_config.Parser()->Parse(trials.Lookup("WebRTC-QCM-Dynamic-VP9"));
       max_qp = 255;
       break;
     case kVideoCodecAV1:
       // Change to enabled by default for AV1.
       dynamic_config.enabled = true;
       dynamic_config.Parser()->Parse(trials.Lookup("WebRTC-QCM-Dynamic-AV1"));
       max_qp = 255;
       break;
     case kVideoCodecGeneric:
     case kVideoCodecH264:
     case kVideoCodecH265:
       break;
   }

   if (dynamic_config.enabled) {
     params.dynamic_detection_enabled = dynamic_config.enabled;
     params.dynamic_qp_threshold =
         params.static_qp_threshold + max_qp * dynamic_config.alpha;
     params.recent_window_length = dynamic_config.recent_length;
     params.past_window_length = dynamic_config.past_length;
   }
   return params;
 }
 }  // namespace

 QualityConvergenceMonitor::QualityConvergenceMonitor(const Parameters& params)
     : params_(params) {
   RTC_CHECK(
       !params_.dynamic_detection_enabled ||
       (params_.past_window_length > 0 && params_.recent_window_length > 0));
 }

 // Adds the sample to the algorithms detection window and runs the following
 // convergence detection algorithm to determine if the time series of QP
 // values indicates that the encoded video has reached "target quality".
 //
 // Definitions
 //
 // - Let x[n] be the pixel data of a video frame.
 // - Let e[n] be the encoded representation of x[n].
 // - Let qp[n] be the corresponding QP value of the encoded video frame e[n].
 // - x[n] is a refresh frame if x[n] = x[n-1].
 // - qp_window is a list (or queue) of stored QP values, with size
 //   L <= past_window_length + recent_window_length.
 // - qp_window can be partioned into:
 //     qp_past = qp_window[ 0:end-recent_window_length ] and
 //     qp_recent = qp_window[ -recent_window_length:end ].
 // - Let dynamic_qp_threshold be a maximum QP value for which convergence
 //   is accepted.
 //
 // Algorithm
 //
 // For each encoded video frame e[n], take the corresponding qp[n] and do the
 // following:
 // 0. Check Static Threshold: if qp[n] < static_qp_threshold, return true.
 // 1. Check for Refresh Frame: If x[n] is not a refresh frame:
 //     - Clear Q.
 //     - Return false.
 // 2. Check Previous Convergence: If x[n] is a refresh frame AND true was
 //    returned for x[n-1], return true.
 // 3. Update QP History: Append qp[n] to qp_window. If qp_window's length
 //    exceeds past_window_length + recent_window_length, remove the first
 //    element.
 // 4. Check for Sufficient Data: If L <= recent_window_length, return false.
 // 5. Calculate Average QP: Calculate avg(qp_past) and avg(ap_recent).
 // 6. Determine Convergence: If avg(qp_past) <= dynamic_qp_threshold AND
 //    avg(qp_past) <= avg(qp_recent), return true. Otherwise, return false.
 //
 void QualityConvergenceMonitor::AddSample(int qp, bool is_refresh_frame) {
   // Invalid QP.
   if (qp < 0) {
     qp_window_.clear();
     at_target_quality_ = false;
     return;
   }

   // 0. Check static threshold.
   if (qp <= params_.static_qp_threshold) {
     at_target_quality_ = true;
     return;
   }

   // 1. Check for refresh frame and if dynamic detection is disabled.
   if (!is_refresh_frame || !params_.dynamic_detection_enabled) {
     qp_window_.clear();
     at_target_quality_ = false;
     return;
   }

   // 2. Check previous convergence.
   RTC_CHECK(is_refresh_frame);
   if (at_target_quality_) {
     // No need to update state.
     return;
   }

   // 3. Update QP history.
   qp_window_.push_back(qp);
   if (qp_window_.size() >
       params_.recent_window_length + params_.past_window_length) {
     qp_window_.pop_front();
   }

   // 4. Check for sufficient data.
   if (qp_window_.size() <= params_.recent_window_length) {
     // No need to update state.
     RTC_CHECK(at_target_quality_ == false);
     return;
   }

   // 5. Calculate average QP.
   float qp_past_average =
       std::accumulate(qp_window_.begin(),
                       qp_window_.end() - params_.recent_window_length, 0.0) /
       (qp_window_.size() - params_.recent_window_length);
   float qp_recent_average =
       std::accumulate(qp_window_.end() - params_.recent_window_length,
                       qp_window_.end(), 0.0) /
       params_.recent_window_length;
   // 6. Determine convergence.
   if (qp_past_average <= params_.dynamic_qp_threshold &&
       qp_past_average <= qp_recent_average) {
     at_target_quality_ = true;
   }
 }

 bool QualityConvergenceMonitor::AtTargetQuality() const {
   return at_target_quality_;
 }

 // Static
 std::unique_ptr<QualityConvergenceMonitor> QualityConvergenceMonitor::Create(
     int static_qp_threshold,
     VideoCodecType codec,
     const FieldTrialsView& trials) {
   Parameters params = GetParameters(static_qp_threshold, codec, trials);
   return std::unique_ptr<QualityConvergenceMonitor>(
       new QualityConvergenceMonitor(params));
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2024 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/quality_convergence_monitor.h"

	#include <numeric>

	#include "rtc_base/checks.h"
	#include "rtc_base/experiments/struct_parameters_parser.h"

	namespace webrtc {
	namespace {
	constexpr size_t kDefaultRecentWindowLength = 6;
	constexpr size_t kDefaultPastWindowLength = 6;
	constexpr float kDefaultAlpha = 0.06;

	struct DynamicDetectionConfig {
	bool enabled = false;
	// alpha is a percentage of the codec-specific max QP value that is used to
	// determine the dynamic QP threshold:
	// dynamic_qp_threshold = static_qp_threshold + alpha * max_QP
	double alpha = kDefaultAlpha;
	int recent_length = kDefaultRecentWindowLength;
	int past_length = kDefaultPastWindowLength;
	std::unique_ptr<StructParametersParser> Parser();
	};

	std::unique_ptr<StructParametersParser> DynamicDetectionConfig::Parser() {
	// The empty comments ensures that each pair is on a separate line.
	return StructParametersParser::Create("enabled", &enabled, //
	"alpha", &alpha, //
	"recent_length", &recent_length, //
	"past_length", &past_length);
	}

	QualityConvergenceMonitor::Parameters GetParameters(
	int static_qp_threshold,
	VideoCodecType codec,
	const FieldTrialsView& trials) {
	QualityConvergenceMonitor::Parameters params;
	params.static_qp_threshold = static_qp_threshold;

	DynamicDetectionConfig dynamic_config;
	// Apply codec specific settings.
	int max_qp = 0;
	switch (codec) {
	case kVideoCodecVP8:
	dynamic_config.Parser()->Parse(trials.Lookup("WebRTC-QCM-Dynamic-VP8"));
	max_qp = 127;
	break;
	case kVideoCodecVP9:
	// Change to enabled by default for VP9.
	dynamic_config.enabled = true;
	dynamic_config.Parser()->Parse(trials.Lookup("WebRTC-QCM-Dynamic-VP9"));
	max_qp = 255;
	break;
	case kVideoCodecAV1:
	// Change to enabled by default for AV1.
	dynamic_config.enabled = true;
	dynamic_config.Parser()->Parse(trials.Lookup("WebRTC-QCM-Dynamic-AV1"));
	max_qp = 255;
	break;
	case kVideoCodecGeneric:
	case kVideoCodecH264:
	case kVideoCodecH265:
	break;
	}

	if (dynamic_config.enabled) {
	params.dynamic_detection_enabled = dynamic_config.enabled;
	params.dynamic_qp_threshold =
	params.static_qp_threshold + max_qp * dynamic_config.alpha;
	params.recent_window_length = dynamic_config.recent_length;
	params.past_window_length = dynamic_config.past_length;
	}
	return params;
	}
	} // namespace

	QualityConvergenceMonitor::QualityConvergenceMonitor(const Parameters& params)
	: params_(params) {
	RTC_CHECK(
	!params_.dynamic_detection_enabled \|\|
	(params_.past_window_length > 0 && params_.recent_window_length > 0));
	}

	// Adds the sample to the algorithms detection window and runs the following
	// convergence detection algorithm to determine if the time series of QP
	// values indicates that the encoded video has reached "target quality".
	//
	// Definitions
	//
	// - Let x[n] be the pixel data of a video frame.
	// - Let e[n] be the encoded representation of x[n].
	// - Let qp[n] be the corresponding QP value of the encoded video frame e[n].
	// - x[n] is a refresh frame if x[n] = x[n-1].
	// - qp_window is a list (or queue) of stored QP values, with size
	// L <= past_window_length + recent_window_length.
	// - qp_window can be partioned into:
	// qp_past = qp_window[ 0:end-recent_window_length ] and
	// qp_recent = qp_window[ -recent_window_length:end ].
	// - Let dynamic_qp_threshold be a maximum QP value for which convergence
	// is accepted.
	//
	// Algorithm
	//
	// For each encoded video frame e[n], take the corresponding qp[n] and do the
	// following:
	// 0. Check Static Threshold: if qp[n] < static_qp_threshold, return true.
	// 1. Check for Refresh Frame: If x[n] is not a refresh frame:
	// - Clear Q.
	// - Return false.
	// 2. Check Previous Convergence: If x[n] is a refresh frame AND true was
	// returned for x[n-1], return true.
	// 3. Update QP History: Append qp[n] to qp_window. If qp_window's length
	// exceeds past_window_length + recent_window_length, remove the first
	// element.
	// 4. Check for Sufficient Data: If L <= recent_window_length, return false.
	// 5. Calculate Average QP: Calculate avg(qp_past) and avg(ap_recent).
	// 6. Determine Convergence: If avg(qp_past) <= dynamic_qp_threshold AND
	// avg(qp_past) <= avg(qp_recent), return true. Otherwise, return false.
	//
	void QualityConvergenceMonitor::AddSample(int qp, bool is_refresh_frame) {
	// Invalid QP.
	if (qp < 0) {
	qp_window_.clear();
	at_target_quality_ = false;
	return;
	}

	// 0. Check static threshold.
	if (qp <= params_.static_qp_threshold) {
	at_target_quality_ = true;
	return;
	}

	// 1. Check for refresh frame and if dynamic detection is disabled.
	if (!is_refresh_frame \|\| !params_.dynamic_detection_enabled) {
	qp_window_.clear();
	at_target_quality_ = false;
	return;
	}

	// 2. Check previous convergence.
	RTC_CHECK(is_refresh_frame);
	if (at_target_quality_) {
	// No need to update state.
	return;
	}

	// 3. Update QP history.
	qp_window_.push_back(qp);
	if (qp_window_.size() >
	params_.recent_window_length + params_.past_window_length) {
	qp_window_.pop_front();
	}

	// 4. Check for sufficient data.
	if (qp_window_.size() <= params_.recent_window_length) {
	// No need to update state.
	RTC_CHECK(at_target_quality_ == false);
	return;
	}

	// 5. Calculate average QP.
	float qp_past_average =
	std::accumulate(qp_window_.begin(),
	qp_window_.end() - params_.recent_window_length, 0.0) /
	(qp_window_.size() - params_.recent_window_length);
	float qp_recent_average =
	std::accumulate(qp_window_.end() - params_.recent_window_length,
	qp_window_.end(), 0.0) /
	params_.recent_window_length;
	// 6. Determine convergence.
	if (qp_past_average <= params_.dynamic_qp_threshold &&
	qp_past_average <= qp_recent_average) {
	at_target_quality_ = true;
	}
	}

	bool QualityConvergenceMonitor::AtTargetQuality() const {
	return at_target_quality_;
	}

	// Static
	std::unique_ptr<QualityConvergenceMonitor> QualityConvergenceMonitor::Create(
	int static_qp_threshold,
	VideoCodecType codec,
	const FieldTrialsView& trials) {
	Parameters params = GetParameters(static_qp_threshold, codec, trials);
	return std::unique_ptr<QualityConvergenceMonitor>(
	new QualityConvergenceMonitor(params));
	}

	} // namespace webrtc