modules/rtp_rtcp/source/ulpfec_generator.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - Git at Google

 /*
  *  Copyright (c) 2012 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 "modules/rtp_rtcp/source/ulpfec_generator.h"

 #include <string.h>
 #include <cstdint>
 #include <memory>
 #include <utility>

 #include "modules/rtp_rtcp/include/rtp_rtcp_defines.h"
 #include "modules/rtp_rtcp/source/byte_io.h"
 #include "modules/rtp_rtcp/source/forward_error_correction.h"
 #include "modules/rtp_rtcp/source/forward_error_correction_internal.h"
 #include "modules/rtp_rtcp/source/rtp_utility.h"
 #include "rtc_base/checks.h"

 namespace webrtc {

 namespace {

 constexpr size_t kRedForFecHeaderLength = 1;

 // This controls the maximum amount of excess overhead (actual - target)
 // allowed in order to trigger EncodeFec(), before |params_.max_fec_frames|
 // is reached. Overhead here is defined as relative to number of media packets.
 constexpr int kMaxExcessOverhead = 50;  // Q8.

 // This is the minimum number of media packets required (above some protection
 // level) in order to trigger EncodeFec(), before |params_.max_fec_frames| is
 // reached.
 constexpr size_t kMinMediaPackets = 4;

 // Threshold on the received FEC protection level, above which we enforce at
 // least |kMinMediaPackets| packets for the FEC code. Below this
 // threshold |kMinMediaPackets| is set to default value of 1.
 //
 // The range is between 0 and 255, where 255 corresponds to 100% overhead
 // (relative to the number of protected media packets).
 constexpr uint8_t kHighProtectionThreshold = 80;

 // This threshold is used to adapt the |kMinMediaPackets| threshold, based
 // on the average number of packets per frame seen so far. When there are few
 // packets per frame (as given by this threshold), at least
 // |kMinMediaPackets| + 1 packets are sent to the FEC code.
 constexpr float kMinMediaPacketsAdaptationThreshold = 2.0f;

 // At construction time, we don't know the SSRC that is used for the generated
 // FEC packets, but we still need to give it to the ForwardErrorCorrection ctor
 // to be used in the decoding.
 // TODO(brandtr): Get rid of this awkwardness by splitting
 // ForwardErrorCorrection in two objects -- one encoder and one decoder.
 constexpr uint32_t kUnknownSsrc = 0;

 }  // namespace

 RedPacket::RedPacket(size_t length)
     : data_(new uint8_t[length]), length_(length), header_length_(0) {}

 RedPacket::~RedPacket() = default;

 void RedPacket::CreateHeader(const uint8_t* rtp_header,
                              size_t header_length,
                              int red_payload_type,
                              int payload_type) {
   RTC_DCHECK_LE(header_length + kRedForFecHeaderLength, length_);
   memcpy(data_.get(), rtp_header, header_length);
   // Replace payload type.
   data_[1] &= 0x80;
   data_[1] += red_payload_type;
   // Add RED header
   // f-bit always 0
   data_[header_length] = static_cast<uint8_t>(payload_type);
   header_length_ = header_length + kRedForFecHeaderLength;
 }

 void RedPacket::SetSeqNum(int seq_num) {
   RTC_DCHECK_GE(seq_num, 0);
   RTC_DCHECK_LT(seq_num, 1 << 16);

   ByteWriter<uint16_t>::WriteBigEndian(&data_[2], seq_num);
 }

 void RedPacket::AssignPayload(const uint8_t* payload, size_t length) {
   RTC_DCHECK_LE(header_length_ + length, length_);
   memcpy(data_.get() + header_length_, payload, length);
 }

 void RedPacket::ClearMarkerBit() {
   data_[1] &= 0x7F;
 }

 uint8_t* RedPacket::data() const {
   return data_.get();
 }

 size_t RedPacket::length() const {
   return length_;
 }

 UlpfecGenerator::UlpfecGenerator()
     : UlpfecGenerator(ForwardErrorCorrection::CreateUlpfec(kUnknownSsrc)) {}

 UlpfecGenerator::UlpfecGenerator(std::unique_ptr<ForwardErrorCorrection> fec)
     : fec_(std::move(fec)),
       last_media_packet_rtp_header_length_(0),
       num_protected_frames_(0),
       min_num_media_packets_(1) {
   memset(&params_, 0, sizeof(params_));
   memset(&new_params_, 0, sizeof(new_params_));
 }

 UlpfecGenerator::~UlpfecGenerator() = default;

 void UlpfecGenerator::SetFecParameters(const FecProtectionParams& params) {
   RTC_DCHECK_GE(params.fec_rate, 0);
   RTC_DCHECK_LE(params.fec_rate, 255);
   // Store the new params and apply them for the next set of FEC packets being
   // produced.
   new_params_ = params;
   if (params.fec_rate > kHighProtectionThreshold) {
     min_num_media_packets_ = kMinMediaPackets;
   } else {
     min_num_media_packets_ = 1;
   }
 }

 int UlpfecGenerator::AddRtpPacketAndGenerateFec(const uint8_t* data_buffer,
                                                 size_t payload_length,
                                                 size_t rtp_header_length) {
   RTC_DCHECK(generated_fec_packets_.empty());
   if (media_packets_.empty()) {
     params_ = new_params_;
   }
   bool complete_frame = false;
   const bool marker_bit = (data_buffer[1] & kRtpMarkerBitMask) ? true : false;
   if (media_packets_.size() < kUlpfecMaxMediaPackets) {
     // Our packet masks can only protect up to |kUlpfecMaxMediaPackets| packets.
     std::unique_ptr<ForwardErrorCorrection::Packet> packet(
         new ForwardErrorCorrection::Packet());
     packet->length = payload_length + rtp_header_length;
     memcpy(packet->data, data_buffer, packet->length);
     media_packets_.push_back(std::move(packet));
     // Keep track of the RTP header length, so we can copy the RTP header
     // from |packet| to newly generated ULPFEC+RED packets.
     RTC_DCHECK_GE(rtp_header_length, kRtpHeaderSize);
     last_media_packet_rtp_header_length_ = rtp_header_length;
   }
   if (marker_bit) {
     ++num_protected_frames_;
     complete_frame = true;
   }
   // Produce FEC over at most |params_.max_fec_frames| frames, or as soon as:
   // (1) the excess overhead (actual overhead - requested/target overhead) is
   // less than |kMaxExcessOverhead|, and
   // (2) at least |min_num_media_packets_| media packets is reached.
   if (complete_frame &&
       (num_protected_frames_ == params_.max_fec_frames ||
        (ExcessOverheadBelowMax() && MinimumMediaPacketsReached()))) {
     // We are not using Unequal Protection feature of the parity erasure code.
     constexpr int kNumImportantPackets = 0;
     constexpr bool kUseUnequalProtection = false;
     int ret = fec_->EncodeFec(media_packets_, params_.fec_rate,
                               kNumImportantPackets, kUseUnequalProtection,
                               params_.fec_mask_type, &generated_fec_packets_);
     if (generated_fec_packets_.empty()) {
       ResetState();
     }
     return ret;
   }
   return 0;
 }

 bool UlpfecGenerator::ExcessOverheadBelowMax() const {
   return ((Overhead() - params_.fec_rate) < kMaxExcessOverhead);
 }

 bool UlpfecGenerator::MinimumMediaPacketsReached() const {
   float average_num_packets_per_frame =
       static_cast<float>(media_packets_.size()) / num_protected_frames_;
   int num_media_packets = static_cast<int>(media_packets_.size());
   if (average_num_packets_per_frame < kMinMediaPacketsAdaptationThreshold) {
     return num_media_packets >= min_num_media_packets_;
   } else {
     // For larger rates (more packets/frame), increase the threshold.
     // TODO(brandtr): Investigate what impact this adaptation has.
     return num_media_packets >= min_num_media_packets_ + 1;
   }
 }

 bool UlpfecGenerator::FecAvailable() const {
   return !generated_fec_packets_.empty();
 }

 size_t UlpfecGenerator::NumAvailableFecPackets() const {
   return generated_fec_packets_.size();
 }

 size_t UlpfecGenerator::MaxPacketOverhead() const {
   return fec_->MaxPacketOverhead();
 }

 std::vector<std::unique_ptr<RedPacket>> UlpfecGenerator::GetUlpfecPacketsAsRed(
     int red_payload_type,
     int ulpfec_payload_type,
     uint16_t first_seq_num) {
   std::vector<std::unique_ptr<RedPacket>> red_packets;
   red_packets.reserve(generated_fec_packets_.size());
   RTC_DCHECK(!media_packets_.empty());
   ForwardErrorCorrection::Packet* last_media_packet =
       media_packets_.back().get();
   uint16_t seq_num = first_seq_num;
   for (const auto* fec_packet : generated_fec_packets_) {
     // Wrap FEC packet (including FEC headers) in a RED packet. Since the
     // FEC packets in |generated_fec_packets_| don't have RTP headers, we
     // reuse the header from the last media packet.
     RTC_DCHECK_GT(last_media_packet_rtp_header_length_, 0);
     std::unique_ptr<RedPacket> red_packet(
         new RedPacket(last_media_packet_rtp_header_length_ +
                       kRedForFecHeaderLength + fec_packet->length));
     red_packet->CreateHeader(last_media_packet->data,
                              last_media_packet_rtp_header_length_,
                              red_payload_type, ulpfec_payload_type);
     red_packet->SetSeqNum(seq_num++);
     red_packet->ClearMarkerBit();
     red_packet->AssignPayload(fec_packet->data, fec_packet->length);
     red_packets.push_back(std::move(red_packet));
   }

   ResetState();

   return red_packets;
 }

 int UlpfecGenerator::Overhead() const {
   RTC_DCHECK(!media_packets_.empty());
   int num_fec_packets =
       fec_->NumFecPackets(media_packets_.size(), params_.fec_rate);
   // Return the overhead in Q8.
   return (num_fec_packets << 8) / media_packets_.size();
 }

 void UlpfecGenerator::ResetState() {
   media_packets_.clear();
   last_media_packet_rtp_header_length_ = 0;
   generated_fec_packets_.clear();
   num_protected_frames_ = 0;
 }

 }  // namespace webrtc
	/*
	* Copyright (c) 2012 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 "modules/rtp_rtcp/source/ulpfec_generator.h"

	#include <string.h>
	#include <cstdint>
	#include <memory>
	#include <utility>

	#include "modules/rtp_rtcp/include/rtp_rtcp_defines.h"
	#include "modules/rtp_rtcp/source/byte_io.h"
	#include "modules/rtp_rtcp/source/forward_error_correction.h"
	#include "modules/rtp_rtcp/source/forward_error_correction_internal.h"
	#include "modules/rtp_rtcp/source/rtp_utility.h"
	#include "rtc_base/checks.h"

	namespace webrtc {

	namespace {

	constexpr size_t kRedForFecHeaderLength = 1;

	// This controls the maximum amount of excess overhead (actual - target)
	// allowed in order to trigger EncodeFec(), before \|params_.max_fec_frames\|
	// is reached. Overhead here is defined as relative to number of media packets.
	constexpr int kMaxExcessOverhead = 50; // Q8.

	// This is the minimum number of media packets required (above some protection
	// level) in order to trigger EncodeFec(), before \|params_.max_fec_frames\| is
	// reached.
	constexpr size_t kMinMediaPackets = 4;

	// Threshold on the received FEC protection level, above which we enforce at
	// least \|kMinMediaPackets\| packets for the FEC code. Below this
	// threshold \|kMinMediaPackets\| is set to default value of 1.
	//
	// The range is between 0 and 255, where 255 corresponds to 100% overhead
	// (relative to the number of protected media packets).
	constexpr uint8_t kHighProtectionThreshold = 80;

	// This threshold is used to adapt the \|kMinMediaPackets\| threshold, based
	// on the average number of packets per frame seen so far. When there are few
	// packets per frame (as given by this threshold), at least
	// \|kMinMediaPackets\| + 1 packets are sent to the FEC code.
	constexpr float kMinMediaPacketsAdaptationThreshold = 2.0f;

	// At construction time, we don't know the SSRC that is used for the generated
	// FEC packets, but we still need to give it to the ForwardErrorCorrection ctor
	// to be used in the decoding.
	// TODO(brandtr): Get rid of this awkwardness by splitting
	// ForwardErrorCorrection in two objects -- one encoder and one decoder.
	constexpr uint32_t kUnknownSsrc = 0;

	} // namespace

	RedPacket::RedPacket(size_t length)
	: data_(new uint8_t[length]), length_(length), header_length_(0) {}

	RedPacket::~RedPacket() = default;

	void RedPacket::CreateHeader(const uint8_t* rtp_header,
	size_t header_length,
	int red_payload_type,
	int payload_type) {
	RTC_DCHECK_LE(header_length + kRedForFecHeaderLength, length_);
	memcpy(data_.get(), rtp_header, header_length);
	// Replace payload type.
	data_[1] &= 0x80;
	data_[1] += red_payload_type;
	// Add RED header
	// f-bit always 0
	data_[header_length] = static_cast<uint8_t>(payload_type);
	header_length_ = header_length + kRedForFecHeaderLength;
	}

	void RedPacket::SetSeqNum(int seq_num) {
	RTC_DCHECK_GE(seq_num, 0);
	RTC_DCHECK_LT(seq_num, 1 << 16);

	ByteWriter<uint16_t>::WriteBigEndian(&data_[2], seq_num);
	}

	void RedPacket::AssignPayload(const uint8_t* payload, size_t length) {
	RTC_DCHECK_LE(header_length_ + length, length_);
	memcpy(data_.get() + header_length_, payload, length);
	}

	void RedPacket::ClearMarkerBit() {
	data_[1] &= 0x7F;
	}

	uint8_t* RedPacket::data() const {
	return data_.get();
	}

	size_t RedPacket::length() const {
	return length_;
	}

	UlpfecGenerator::UlpfecGenerator()
	: UlpfecGenerator(ForwardErrorCorrection::CreateUlpfec(kUnknownSsrc)) {}

	UlpfecGenerator::UlpfecGenerator(std::unique_ptr<ForwardErrorCorrection> fec)
	: fec_(std::move(fec)),
	last_media_packet_rtp_header_length_(0),
	num_protected_frames_(0),
	min_num_media_packets_(1) {
	memset(&params_, 0, sizeof(params_));
	memset(&new_params_, 0, sizeof(new_params_));
	}

	UlpfecGenerator::~UlpfecGenerator() = default;

	void UlpfecGenerator::SetFecParameters(const FecProtectionParams& params) {
	RTC_DCHECK_GE(params.fec_rate, 0);
	RTC_DCHECK_LE(params.fec_rate, 255);
	// Store the new params and apply them for the next set of FEC packets being
	// produced.
	new_params_ = params;
	if (params.fec_rate > kHighProtectionThreshold) {
	min_num_media_packets_ = kMinMediaPackets;
	} else {
	min_num_media_packets_ = 1;
	}
	}

	int UlpfecGenerator::AddRtpPacketAndGenerateFec(const uint8_t* data_buffer,
	size_t payload_length,
	size_t rtp_header_length) {
	RTC_DCHECK(generated_fec_packets_.empty());
	if (media_packets_.empty()) {
	params_ = new_params_;
	}
	bool complete_frame = false;
	const bool marker_bit = (data_buffer[1] & kRtpMarkerBitMask) ? true : false;
	if (media_packets_.size() < kUlpfecMaxMediaPackets) {
	// Our packet masks can only protect up to \|kUlpfecMaxMediaPackets\| packets.
	std::unique_ptr<ForwardErrorCorrection::Packet> packet(
	new ForwardErrorCorrection::Packet());
	packet->length = payload_length + rtp_header_length;
	memcpy(packet->data, data_buffer, packet->length);
	media_packets_.push_back(std::move(packet));
	// Keep track of the RTP header length, so we can copy the RTP header
	// from \|packet\| to newly generated ULPFEC+RED packets.
	RTC_DCHECK_GE(rtp_header_length, kRtpHeaderSize);
	last_media_packet_rtp_header_length_ = rtp_header_length;
	}
	if (marker_bit) {
	++num_protected_frames_;
	complete_frame = true;
	}
	// Produce FEC over at most \|params_.max_fec_frames\| frames, or as soon as:
	// (1) the excess overhead (actual overhead - requested/target overhead) is
	// less than \|kMaxExcessOverhead\|, and
	// (2) at least \|min_num_media_packets_\| media packets is reached.
	if (complete_frame &&
	(num_protected_frames_ == params_.max_fec_frames \|\|
	(ExcessOverheadBelowMax() && MinimumMediaPacketsReached()))) {
	// We are not using Unequal Protection feature of the parity erasure code.
	constexpr int kNumImportantPackets = 0;
	constexpr bool kUseUnequalProtection = false;
	int ret = fec_->EncodeFec(media_packets_, params_.fec_rate,
	kNumImportantPackets, kUseUnequalProtection,
	params_.fec_mask_type, &generated_fec_packets_);
	if (generated_fec_packets_.empty()) {
	ResetState();
	}
	return ret;
	}
	return 0;
	}

	bool UlpfecGenerator::ExcessOverheadBelowMax() const {
	return ((Overhead() - params_.fec_rate) < kMaxExcessOverhead);
	}

	bool UlpfecGenerator::MinimumMediaPacketsReached() const {
	float average_num_packets_per_frame =
	static_cast<float>(media_packets_.size()) / num_protected_frames_;
	int num_media_packets = static_cast<int>(media_packets_.size());
	if (average_num_packets_per_frame < kMinMediaPacketsAdaptationThreshold) {
	return num_media_packets >= min_num_media_packets_;
	} else {
	// For larger rates (more packets/frame), increase the threshold.
	// TODO(brandtr): Investigate what impact this adaptation has.
	return num_media_packets >= min_num_media_packets_ + 1;
	}
	}

	bool UlpfecGenerator::FecAvailable() const {
	return !generated_fec_packets_.empty();
	}

	size_t UlpfecGenerator::NumAvailableFecPackets() const {
	return generated_fec_packets_.size();
	}

	size_t UlpfecGenerator::MaxPacketOverhead() const {
	return fec_->MaxPacketOverhead();
	}

	std::vector<std::unique_ptr<RedPacket>> UlpfecGenerator::GetUlpfecPacketsAsRed(
	int red_payload_type,
	int ulpfec_payload_type,
	uint16_t first_seq_num) {
	std::vector<std::unique_ptr<RedPacket>> red_packets;
	red_packets.reserve(generated_fec_packets_.size());
	RTC_DCHECK(!media_packets_.empty());
	ForwardErrorCorrection::Packet* last_media_packet =
	media_packets_.back().get();
	uint16_t seq_num = first_seq_num;
	for (const auto* fec_packet : generated_fec_packets_) {
	// Wrap FEC packet (including FEC headers) in a RED packet. Since the
	// FEC packets in \|generated_fec_packets_\| don't have RTP headers, we
	// reuse the header from the last media packet.
	RTC_DCHECK_GT(last_media_packet_rtp_header_length_, 0);
	std::unique_ptr<RedPacket> red_packet(
	new RedPacket(last_media_packet_rtp_header_length_ +
	kRedForFecHeaderLength + fec_packet->length));
	red_packet->CreateHeader(last_media_packet->data,
	last_media_packet_rtp_header_length_,
	red_payload_type, ulpfec_payload_type);
	red_packet->SetSeqNum(seq_num++);
	red_packet->ClearMarkerBit();
	red_packet->AssignPayload(fec_packet->data, fec_packet->length);
	red_packets.push_back(std::move(red_packet));
	}

	ResetState();

	return red_packets;
	}

	int UlpfecGenerator::Overhead() const {
	RTC_DCHECK(!media_packets_.empty());
	int num_fec_packets =
	fec_->NumFecPackets(media_packets_.size(), params_.fec_rate);
	// Return the overhead in Q8.
	return (num_fec_packets << 8) / media_packets_.size();
	}

	void UlpfecGenerator::ResetState() {
	media_packets_.clear();
	last_media_packet_rtp_header_length_ = 0;
	generated_fec_packets_.clear();
	num_protected_frames_ = 0;
	}

	} // namespace webrtc