webrtc/modules/video_coding/protection_bitrate_calculator.cc - src - Git at Google

 /*
  *  Copyright (c) 2016 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 "webrtc/modules/video_coding/protection_bitrate_calculator.h"

 namespace webrtc {

 using rtc::CritScope;

 struct ProtectionBitrateCalculator::EncodedFrameSample {
   EncodedFrameSample(size_t size_bytes,
                      uint32_t timestamp,
                      int64_t time_complete_ms)
       : size_bytes(size_bytes),
         timestamp(timestamp),
         time_complete_ms(time_complete_ms) {}
   size_t size_bytes;
   uint32_t timestamp;
   int64_t time_complete_ms;
 };

 ProtectionBitrateCalculator::ProtectionBitrateCalculator(
     Clock* clock,
     VCMProtectionCallback* protection_callback)
     : clock_(clock),
       protection_callback_(protection_callback),
       loss_prot_logic_(new media_optimization::VCMLossProtectionLogic(
           clock_->TimeInMilliseconds())),
       max_payload_size_(1460) {}

 ProtectionBitrateCalculator::~ProtectionBitrateCalculator(void) {
   loss_prot_logic_->Release();
 }

 void ProtectionBitrateCalculator::SetEncodingData(size_t width,
                                                   size_t height,
                                                   size_t num_temporal_layers,
                                                   size_t max_payload_size) {
   CritScope lock(&crit_sect_);
   loss_prot_logic_->UpdateFrameSize(width, height);
   loss_prot_logic_->UpdateNumLayers(num_temporal_layers);
   max_payload_size_ = max_payload_size;
 }

 uint32_t ProtectionBitrateCalculator::SetTargetRates(
     uint32_t estimated_bitrate_bps,
     int actual_framerate_fps,
     uint8_t fraction_lost,
     int64_t round_trip_time_ms) {
   float target_bitrate_kbps =
       static_cast<float>(estimated_bitrate_bps) / 1000.0f;
   // Sanity check.
   if (actual_framerate_fps < 1.0) {
     actual_framerate_fps = 1.0;
   }

   FecProtectionParams delta_fec_params;
   FecProtectionParams key_fec_params;
   {
     CritScope lock(&crit_sect_);

     loss_prot_logic_->UpdateBitRate(target_bitrate_kbps);
     loss_prot_logic_->UpdateRtt(round_trip_time_ms);

     // Update frame rate for the loss protection logic class: frame rate should
     // be the actual/sent rate.
     loss_prot_logic_->UpdateFrameRate(actual_framerate_fps);

     // Returns the filtered packet loss, used for the protection setting.
     // The filtered loss may be the received loss (no filter), or some
     // filtered value (average or max window filter).
     // Use max window filter for now.
     media_optimization::FilterPacketLossMode filter_mode =
         media_optimization::kMaxFilter;
     uint8_t packet_loss_enc = loss_prot_logic_->FilteredLoss(
         clock_->TimeInMilliseconds(), filter_mode, fraction_lost);

     // For now use the filtered loss for computing the robustness settings.
     loss_prot_logic_->UpdateFilteredLossPr(packet_loss_enc);

     if (loss_prot_logic_->SelectedType() == media_optimization::kNone) {
       return estimated_bitrate_bps;
     }

     // Update method will compute the robustness settings for the given
     // protection method and the overhead cost
     // the protection method is set by the user via SetVideoProtection.
     loss_prot_logic_->UpdateMethod();

     // Get the bit cost of protection method, based on the amount of
     // overhead data actually transmitted (including headers) the last
     // second.

     // Get the FEC code rate for Key frames (set to 0 when NA).
     key_fec_params.fec_rate =
         loss_prot_logic_->SelectedMethod()->RequiredProtectionFactorK();

     // Get the FEC code rate for Delta frames (set to 0 when NA).
     delta_fec_params.fec_rate =
         loss_prot_logic_->SelectedMethod()->RequiredProtectionFactorD();

     // The RTP module currently requires the same |max_fec_frames| for both
     // key and delta frames.
     delta_fec_params.max_fec_frames =
         loss_prot_logic_->SelectedMethod()->MaxFramesFec();
     key_fec_params.max_fec_frames =
         loss_prot_logic_->SelectedMethod()->MaxFramesFec();
   }

   // Set the FEC packet mask type. |kFecMaskBursty| is more effective for
   // consecutive losses and little/no packet re-ordering. As we currently
   // do not have feedback data on the degree of correlated losses and packet
   // re-ordering, we keep default setting to |kFecMaskRandom| for now.
   delta_fec_params.fec_mask_type = kFecMaskRandom;
   key_fec_params.fec_mask_type = kFecMaskRandom;

   // Update protection callback with protection settings.
   uint32_t sent_video_rate_bps = 0;
   uint32_t sent_nack_rate_bps = 0;
   uint32_t sent_fec_rate_bps = 0;
   // Rate cost of the protection methods.
   float protection_overhead_rate = 0.0f;

   // TODO(Marco): Pass FEC protection values per layer.
   protection_callback_->ProtectionRequest(
       &delta_fec_params, &key_fec_params, &sent_video_rate_bps,
       &sent_nack_rate_bps, &sent_fec_rate_bps);

   uint32_t sent_total_rate_bps =
       sent_video_rate_bps + sent_nack_rate_bps + sent_fec_rate_bps;
   // Estimate the overhead costs of the next second as staying the same
   // wrt the source bitrate.
   if (sent_total_rate_bps > 0) {
     protection_overhead_rate =
         static_cast<float>(sent_nack_rate_bps + sent_fec_rate_bps) /
         sent_total_rate_bps;
   }
   // Cap the overhead estimate to 50%.
   if (protection_overhead_rate > 0.5)
     protection_overhead_rate = 0.5;

   // Source coding rate: total rate - protection overhead.
   return estimated_bitrate_bps * (1.0 - protection_overhead_rate);
 }

 void ProtectionBitrateCalculator::SetProtectionMethod(bool enable_fec,
                                                       bool enable_nack) {
   media_optimization::VCMProtectionMethodEnum method(media_optimization::kNone);
   if (enable_fec && enable_nack) {
     method = media_optimization::kNackFec;
   } else if (enable_nack) {
     method = media_optimization::kNack;
   } else if (enable_fec) {
     method = media_optimization::kFec;
   }
   CritScope lock(&crit_sect_);
   loss_prot_logic_->SetMethod(method);
 }

 void ProtectionBitrateCalculator::UpdateWithEncodedData(
     const EncodedImage& encoded_image) {
   const size_t encoded_length = encoded_image._length;
   CritScope lock(&crit_sect_);
   if (encoded_length > 0) {
     const bool delta_frame = encoded_image._frameType != kVideoFrameKey;

     if (max_payload_size_ > 0 && encoded_length > 0) {
       const float min_packets_per_frame =
           encoded_length / static_cast<float>(max_payload_size_);
       if (delta_frame) {
         loss_prot_logic_->UpdatePacketsPerFrame(min_packets_per_frame,
                                                 clock_->TimeInMilliseconds());
       } else {
         loss_prot_logic_->UpdatePacketsPerFrameKey(
             min_packets_per_frame, clock_->TimeInMilliseconds());
       }
     }
     if (!delta_frame && encoded_length > 0) {
       loss_prot_logic_->UpdateKeyFrameSize(static_cast<float>(encoded_length));
     }
   }
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2016 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 "webrtc/modules/video_coding/protection_bitrate_calculator.h"

	namespace webrtc {

	using rtc::CritScope;

	struct ProtectionBitrateCalculator::EncodedFrameSample {
	EncodedFrameSample(size_t size_bytes,
	uint32_t timestamp,
	int64_t time_complete_ms)
	: size_bytes(size_bytes),
	timestamp(timestamp),
	time_complete_ms(time_complete_ms) {}
	size_t size_bytes;
	uint32_t timestamp;
	int64_t time_complete_ms;
	};

	ProtectionBitrateCalculator::ProtectionBitrateCalculator(
	Clock* clock,
	VCMProtectionCallback* protection_callback)
	: clock_(clock),
	protection_callback_(protection_callback),
	loss_prot_logic_(new media_optimization::VCMLossProtectionLogic(
	clock_->TimeInMilliseconds())),
	max_payload_size_(1460) {}

	ProtectionBitrateCalculator::~ProtectionBitrateCalculator(void) {
	loss_prot_logic_->Release();
	}

	void ProtectionBitrateCalculator::SetEncodingData(size_t width,
	size_t height,
	size_t num_temporal_layers,
	size_t max_payload_size) {
	CritScope lock(&crit_sect_);
	loss_prot_logic_->UpdateFrameSize(width, height);
	loss_prot_logic_->UpdateNumLayers(num_temporal_layers);
	max_payload_size_ = max_payload_size;
	}

	uint32_t ProtectionBitrateCalculator::SetTargetRates(
	uint32_t estimated_bitrate_bps,
	int actual_framerate_fps,
	uint8_t fraction_lost,
	int64_t round_trip_time_ms) {
	float target_bitrate_kbps =
	static_cast<float>(estimated_bitrate_bps) / 1000.0f;
	// Sanity check.
	if (actual_framerate_fps < 1.0) {
	actual_framerate_fps = 1.0;
	}

	FecProtectionParams delta_fec_params;
	FecProtectionParams key_fec_params;
	{
	CritScope lock(&crit_sect_);

	loss_prot_logic_->UpdateBitRate(target_bitrate_kbps);
	loss_prot_logic_->UpdateRtt(round_trip_time_ms);

	// Update frame rate for the loss protection logic class: frame rate should
	// be the actual/sent rate.
	loss_prot_logic_->UpdateFrameRate(actual_framerate_fps);

	// Returns the filtered packet loss, used for the protection setting.
	// The filtered loss may be the received loss (no filter), or some
	// filtered value (average or max window filter).
	// Use max window filter for now.
	media_optimization::FilterPacketLossMode filter_mode =
	media_optimization::kMaxFilter;
	uint8_t packet_loss_enc = loss_prot_logic_->FilteredLoss(
	clock_->TimeInMilliseconds(), filter_mode, fraction_lost);

	// For now use the filtered loss for computing the robustness settings.
	loss_prot_logic_->UpdateFilteredLossPr(packet_loss_enc);

	if (loss_prot_logic_->SelectedType() == media_optimization::kNone) {
	return estimated_bitrate_bps;
	}

	// Update method will compute the robustness settings for the given
	// protection method and the overhead cost
	// the protection method is set by the user via SetVideoProtection.
	loss_prot_logic_->UpdateMethod();

	// Get the bit cost of protection method, based on the amount of
	// overhead data actually transmitted (including headers) the last
	// second.

	// Get the FEC code rate for Key frames (set to 0 when NA).
	key_fec_params.fec_rate =
	loss_prot_logic_->SelectedMethod()->RequiredProtectionFactorK();

	// Get the FEC code rate for Delta frames (set to 0 when NA).
	delta_fec_params.fec_rate =
	loss_prot_logic_->SelectedMethod()->RequiredProtectionFactorD();

	// The RTP module currently requires the same \|max_fec_frames\| for both
	// key and delta frames.
	delta_fec_params.max_fec_frames =
	loss_prot_logic_->SelectedMethod()->MaxFramesFec();
	key_fec_params.max_fec_frames =
	loss_prot_logic_->SelectedMethod()->MaxFramesFec();
	}

	// Set the FEC packet mask type. \|kFecMaskBursty\| is more effective for
	// consecutive losses and little/no packet re-ordering. As we currently
	// do not have feedback data on the degree of correlated losses and packet
	// re-ordering, we keep default setting to \|kFecMaskRandom\| for now.
	delta_fec_params.fec_mask_type = kFecMaskRandom;
	key_fec_params.fec_mask_type = kFecMaskRandom;

	// Update protection callback with protection settings.
	uint32_t sent_video_rate_bps = 0;
	uint32_t sent_nack_rate_bps = 0;
	uint32_t sent_fec_rate_bps = 0;
	// Rate cost of the protection methods.
	float protection_overhead_rate = 0.0f;

	// TODO(Marco): Pass FEC protection values per layer.
	protection_callback_->ProtectionRequest(
	&delta_fec_params, &key_fec_params, &sent_video_rate_bps,
	&sent_nack_rate_bps, &sent_fec_rate_bps);

	uint32_t sent_total_rate_bps =
	sent_video_rate_bps + sent_nack_rate_bps + sent_fec_rate_bps;
	// Estimate the overhead costs of the next second as staying the same
	// wrt the source bitrate.
	if (sent_total_rate_bps > 0) {
	protection_overhead_rate =
	static_cast<float>(sent_nack_rate_bps + sent_fec_rate_bps) /
	sent_total_rate_bps;
	}
	// Cap the overhead estimate to 50%.
	if (protection_overhead_rate > 0.5)
	protection_overhead_rate = 0.5;

	// Source coding rate: total rate - protection overhead.
	return estimated_bitrate_bps * (1.0 - protection_overhead_rate);
	}

	void ProtectionBitrateCalculator::SetProtectionMethod(bool enable_fec,
	bool enable_nack) {
	media_optimization::VCMProtectionMethodEnum method(media_optimization::kNone);
	if (enable_fec && enable_nack) {
	method = media_optimization::kNackFec;
	} else if (enable_nack) {
	method = media_optimization::kNack;
	} else if (enable_fec) {
	method = media_optimization::kFec;
	}
	CritScope lock(&crit_sect_);
	loss_prot_logic_->SetMethod(method);
	}

	void ProtectionBitrateCalculator::UpdateWithEncodedData(
	const EncodedImage& encoded_image) {
	const size_t encoded_length = encoded_image._length;
	CritScope lock(&crit_sect_);
	if (encoded_length > 0) {
	const bool delta_frame = encoded_image._frameType != kVideoFrameKey;

	if (max_payload_size_ > 0 && encoded_length > 0) {
	const float min_packets_per_frame =
	encoded_length / static_cast<float>(max_payload_size_);
	if (delta_frame) {
	loss_prot_logic_->UpdatePacketsPerFrame(min_packets_per_frame,
	clock_->TimeInMilliseconds());
	} else {
	loss_prot_logic_->UpdatePacketsPerFrameKey(
	min_packets_per_frame, clock_->TimeInMilliseconds());
	}
	}
	if (!delta_frame && encoded_length > 0) {
	loss_prot_logic_->UpdateKeyFrameSize(static_cast<float>(encoded_length));
	}
	}
	}

	} // namespace webrtc