modules/rtp_rtcp/source/forward_error_correction.h - src - 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.
  */

 #ifndef MODULES_RTP_RTCP_SOURCE_FORWARD_ERROR_CORRECTION_H_
 #define MODULES_RTP_RTCP_SOURCE_FORWARD_ERROR_CORRECTION_H_

 #include <stddef.h>
 #include <stdint.h>

 #include <list>
 #include <memory>
 #include <vector>

 #include "api/scoped_refptr.h"
 #include "modules/include/module_fec_types.h"
 #include "modules/rtp_rtcp/include/rtp_rtcp_defines.h"
 #include "modules/rtp_rtcp/source/forward_error_correction_internal.h"
 #include "rtc_base/copy_on_write_buffer.h"

 namespace webrtc {

 class FecHeaderReader;
 class FecHeaderWriter;

 // Performs codec-independent forward error correction (FEC), based on RFC 5109.
 // Option exists to enable unequal protection (UEP) across packets.
 // This is not to be confused with protection within packets
 // (referred to as uneven level protection (ULP) in RFC 5109).
 // TODO(brandtr): Split this class into a separate encoder
 // and a separate decoder.
 class ForwardErrorCorrection {
  public:
   // TODO(holmer): As a next step all these struct-like packet classes should be
   // refactored into proper classes, and their members should be made private.
   // This will require parts of the functionality in forward_error_correction.cc
   // and receiver_fec.cc to be refactored into the packet classes.
   class Packet {
    public:
     Packet();
     virtual ~Packet();

     // Add a reference.
     virtual int32_t AddRef();

     // Release a reference. Will delete the object if the reference count
     // reaches zero.
     virtual int32_t Release();

     rtc::CopyOnWriteBuffer data;  // Packet data.

    private:
     int32_t ref_count_;  // Counts the number of references to a packet.
   };

   // TODO(holmer): Refactor into a proper class.
   class SortablePacket {
    public:
     // Functor which returns true if the sequence number of `first`
     // is < the sequence number of `second`. Should only ever be called for
     // packets belonging to the same SSRC.
     struct LessThan {
       template <typename S, typename T>
       bool operator()(const S& first, const T& second);
     };

     uint32_t ssrc;
     uint16_t seq_num;
   };

   // Used for the input to DecodeFec().
   //
   // TODO(nisse): Delete class, instead passing `is_fec` and `pkt` as separate
   // arguments.
   class ReceivedPacket : public SortablePacket {
    public:
     ReceivedPacket();
     ~ReceivedPacket();

     bool is_fec;  // Set to true if this is an FEC packet and false
                   // otherwise.
     bool is_recovered;
     rtc::scoped_refptr<Packet> pkt;  // Pointer to the packet storage.
   };

   // The recovered list parameter of DecodeFec() references structs of
   // this type.
   // TODO(holmer): Refactor into a proper class.
   class RecoveredPacket : public SortablePacket {
    public:
     RecoveredPacket();
     ~RecoveredPacket();

     bool was_recovered;  // Will be true if this packet was recovered by
                          // the FEC. Otherwise it was a media packet passed in
                          // through the received packet list.
     bool returned;  // True when the packet already has been returned to the
                     // caller through the callback.
     rtc::scoped_refptr<Packet> pkt;  // Pointer to the packet storage.
   };

   // Used to link media packets to their protecting FEC packets.
   //
   // TODO(holmer): Refactor into a proper class.
   class ProtectedPacket : public SortablePacket {
    public:
     ProtectedPacket();
     ~ProtectedPacket();

     rtc::scoped_refptr<ForwardErrorCorrection::Packet> pkt;
   };

   using ProtectedPacketList = std::list<std::unique_ptr<ProtectedPacket>>;

   // Used for internal storage of received FEC packets in a list.
   //
   // TODO(holmer): Refactor into a proper class.
   class ReceivedFecPacket : public SortablePacket {
    public:
     ReceivedFecPacket();
     ~ReceivedFecPacket();

     // List of media packets that this FEC packet protects.
     ProtectedPacketList protected_packets;
     // RTP header fields.
     uint32_t ssrc;
     // FEC header fields.
     size_t fec_header_size;
     uint32_t protected_ssrc;
     uint16_t seq_num_base;
     size_t packet_mask_offset;  // Relative start of FEC header.
     size_t packet_mask_size;
     size_t protection_length;
     // Raw data.
     rtc::scoped_refptr<ForwardErrorCorrection::Packet> pkt;
   };

   using PacketList = std::list<std::unique_ptr<Packet>>;
   using RecoveredPacketList = std::list<std::unique_ptr<RecoveredPacket>>;
   using ReceivedFecPacketList = std::list<std::unique_ptr<ReceivedFecPacket>>;

   ~ForwardErrorCorrection();

   // Creates a ForwardErrorCorrection tailored for a specific FEC scheme.
   static std::unique_ptr<ForwardErrorCorrection> CreateUlpfec(uint32_t ssrc);
   static std::unique_ptr<ForwardErrorCorrection> CreateFlexfec(
       uint32_t ssrc,
       uint32_t protected_media_ssrc);

   // Generates a list of FEC packets from supplied media packets.
   //
   // Input:  media_packets          List of media packets to protect, of type
   //                                Packet. All packets must belong to the
   //                                same frame and the list must not be empty.
   // Input:  protection_factor      FEC protection overhead in the [0, 255]
   //                                domain. To obtain 100% overhead, or an
   //                                equal number of FEC packets as
   //                                media packets, use 255.
   // Input:  num_important_packets  The number of "important" packets in the
   //                                frame. These packets may receive greater
   //                                protection than the remaining packets.
   //                                The important packets must be located at the
   //                                start of the media packet list. For codecs
   //                                with data partitioning, the important
   //                                packets may correspond to first partition
   //                                packets.
   // Input:  use_unequal_protection Parameter to enable/disable unequal
   //                                protection (UEP) across packets. Enabling
   //                                UEP will allocate more protection to the
   //                                num_important_packets from the start of the
   //                                media_packets.
   // Input:  fec_mask_type          The type of packet mask used in the FEC.
   //                                Random or bursty type may be selected. The
   //                                bursty type is only defined up to 12 media
   //                                packets. If the number of media packets is
   //                                above 12, the packet masks from the random
   //                                table will be selected.
   // Output: fec_packets            List of pointers to generated FEC packets,
   //                                of type Packet. Must be empty on entry.
   //                                The memory available through the list will
   //                                be valid until the next call to
   //                                EncodeFec().
   //
   // Returns 0 on success, -1 on failure.
   //
   int EncodeFec(const PacketList& media_packets,
                 uint8_t protection_factor,
                 int num_important_packets,
                 bool use_unequal_protection,
                 FecMaskType fec_mask_type,
                 std::list<Packet*>* fec_packets);

   // Decodes a list of received media and FEC packets. It will parse the
   // `received_packets`, storing FEC packets internally, and move
   // media packets to `recovered_packets`. The recovered list will be
   // sorted by ascending sequence number and have duplicates removed.
   // The function should be called as new packets arrive, and
   // `recovered_packets` will be progressively assembled with each call.
   // When the function returns, `received_packets` will be empty.
   //
   // The caller will allocate packets submitted through `received_packets`.
   // The function will handle allocation of recovered packets.
   //
   // Input:  received_packets   List of new received packets, of type
   //                            ReceivedPacket, belonging to a single
   //                            frame. At output the list will be empty,
   //                            with packets either stored internally,
   //                            or accessible through the recovered list.
   // Output: recovered_packets  List of recovered media packets, of type
   //                            RecoveredPacket, belonging to a single
   //                            frame. The memory available through the
   //                            list will be valid until the next call to
   //                            DecodeFec().
   //
   void DecodeFec(const ReceivedPacket& received_packet,
                  RecoveredPacketList* recovered_packets);

   // Get the number of generated FEC packets, given the number of media packets
   // and the protection factor.
   static int NumFecPackets(int num_media_packets, int protection_factor);

   // Gets the maximum size of the FEC headers in bytes, which must be
   // accounted for as packet overhead.
   size_t MaxPacketOverhead() const;

   // Reset internal states from last frame and clear `recovered_packets`.
   // Frees all memory allocated by this class.
   void ResetState(RecoveredPacketList* recovered_packets);

   // TODO(brandtr): Remove these functions when the Packet classes
   // have been refactored.
   static uint16_t ParseSequenceNumber(const uint8_t* packet);
   static uint32_t ParseSsrc(const uint8_t* packet);

  protected:
   ForwardErrorCorrection(std::unique_ptr<FecHeaderReader> fec_header_reader,
                          std::unique_ptr<FecHeaderWriter> fec_header_writer,
                          uint32_t ssrc,
                          uint32_t protected_media_ssrc);

  private:
   // Analyzes `media_packets` for holes in the sequence and inserts zero columns
   // into the `packet_mask` where those holes are found. Zero columns means that
   // those packets will have no protection.
   // Returns the number of bits used for one row of the new packet mask.
   // Requires that `packet_mask` has at least 6 * `num_fec_packets` bytes
   // allocated.
   int InsertZerosInPacketMasks(const PacketList& media_packets,
                                size_t num_fec_packets);

   // Writes FEC payloads and some recovery fields in the FEC headers.
   void GenerateFecPayloads(const PacketList& media_packets,
                            size_t num_fec_packets);

   // Writes the FEC header fields that are not written by GenerateFecPayloads.
   // This includes writing the packet masks.
   void FinalizeFecHeaders(size_t num_fec_packets,
                           uint32_t media_ssrc,
                           uint16_t seq_num_base);

   // Inserts the `received_packet` into the internal received FEC packet list
   // or into `recovered_packets`.
   void InsertPacket(const ReceivedPacket& received_packet,
                     RecoveredPacketList* recovered_packets);

   // Inserts the `received_packet` into `recovered_packets`. Deletes duplicates.
   void InsertMediaPacket(RecoveredPacketList* recovered_packets,
                          const ReceivedPacket& received_packet);

   // Assigns pointers to the recovered packet from all FEC packets which cover
   // it.
   // Note: This reduces the complexity when we want to try to recover a packet
   // since we don't have to find the intersection between recovered packets and
   // packets covered by the FEC packet.
   void UpdateCoveringFecPackets(const RecoveredPacket& packet);

   // Insert `received_packet` into internal FEC list. Deletes duplicates.
   void InsertFecPacket(const RecoveredPacketList& recovered_packets,
                        const ReceivedPacket& received_packet);

   // Assigns pointers to already recovered packets covered by `fec_packet`.
   static void AssignRecoveredPackets(
       const RecoveredPacketList& recovered_packets,
       ReceivedFecPacket* fec_packet);

   // Attempt to recover missing packets, using the internally stored
   // received FEC packets.
   void AttemptRecovery(RecoveredPacketList* recovered_packets);

   // Initializes headers and payload before the XOR operation
   // that recovers a packet.
   static bool StartPacketRecovery(const ReceivedFecPacket& fec_packet,
                                   RecoveredPacket* recovered_packet);

   // Performs XOR between the first 8 bytes of `src` and `dst` and stores
   // the result in `dst`. The 3rd and 4th bytes are used for storing
   // the length recovery field.
   static void XorHeaders(const Packet& src, Packet* dst);

   // Performs XOR between the payloads of `src` and `dst` and stores the result
   // in `dst`. The parameter `dst_offset` determines at  what byte the
   // XOR operation starts in `dst`. In total, `payload_length` bytes are XORed.
   static void XorPayloads(const Packet& src,
                           size_t payload_length,
                           size_t dst_offset,
                           Packet* dst);

   // Finalizes recovery of packet by setting RTP header fields.
   // This is not specific to the FEC scheme used.
   static bool FinishPacketRecovery(const ReceivedFecPacket& fec_packet,
                                    RecoveredPacket* recovered_packet);

   // Recover a missing packet.
   static bool RecoverPacket(const ReceivedFecPacket& fec_packet,
                             RecoveredPacket* recovered_packet);

   // Get the number of missing media packets which are covered by `fec_packet`.
   // An FEC packet can recover at most one packet, and if zero packets are
   // missing the FEC packet can be discarded. This function returns 2 when two
   // or more packets are missing.
   static int NumCoveredPacketsMissing(const ReceivedFecPacket& fec_packet);

   // Discards old packets in `recovered_packets`, which are no longer relevant
   // for recovering lost packets.
   void DiscardOldRecoveredPackets(RecoveredPacketList* recovered_packets);

   // Checks if the FEC packet is old enough and no longer relevant for
   // recovering lost media packets.
   bool IsOldFecPacket(const ReceivedFecPacket& fec_packet,
                       const RecoveredPacketList* recovered_packets);

   // These SSRCs are only used by the decoder.
   const uint32_t ssrc_;
   const uint32_t protected_media_ssrc_;

   std::unique_ptr<FecHeaderReader> fec_header_reader_;
   std::unique_ptr<FecHeaderWriter> fec_header_writer_;

   std::vector<Packet> generated_fec_packets_;
   ReceivedFecPacketList received_fec_packets_;

   // Arrays used to avoid dynamically allocating memory when generating
   // the packet masks.
   // (There are never more than `kUlpfecMaxMediaPackets` FEC packets generated.)
   uint8_t packet_masks_[kUlpfecMaxMediaPackets * kUlpfecMaxPacketMaskSize];
   uint8_t tmp_packet_masks_[kUlpfecMaxMediaPackets * kUlpfecMaxPacketMaskSize];
   size_t packet_mask_size_;
 };

 // Classes derived from FecHeader{Reader,Writer} encapsulate the
 // specifics of reading and writing FEC header for, e.g., ULPFEC
 // and FlexFEC.
 class FecHeaderReader {
  public:
   virtual ~FecHeaderReader();

   // The maximum number of media packets that can be covered by one FEC packet.
   size_t MaxMediaPackets() const;

   // The maximum number of FEC packets that is supported, per call
   // to ForwardErrorCorrection::EncodeFec().
   size_t MaxFecPackets() const;

   // Parses FEC header and stores information in ReceivedFecPacket members.
   virtual bool ReadFecHeader(
       ForwardErrorCorrection::ReceivedFecPacket* fec_packet) const = 0;

  protected:
   FecHeaderReader(size_t max_media_packets, size_t max_fec_packets);

   const size_t max_media_packets_;
   const size_t max_fec_packets_;
 };

 class FecHeaderWriter {
  public:
   virtual ~FecHeaderWriter();

   // The maximum number of media packets that can be covered by one FEC packet.
   size_t MaxMediaPackets() const;

   // The maximum number of FEC packets that is supported, per call
   // to ForwardErrorCorrection::EncodeFec().
   size_t MaxFecPackets() const;

   // The maximum overhead (in bytes) per packet, due to FEC headers.
   size_t MaxPacketOverhead() const;

   // Calculates the minimum packet mask size needed (in bytes),
   // given the discrete options of the ULPFEC masks and the bits
   // set in the current packet mask.
   virtual size_t MinPacketMaskSize(const uint8_t* packet_mask,
                                    size_t packet_mask_size) const = 0;

   // The header size (in bytes), given the packet mask size.
   virtual size_t FecHeaderSize(size_t packet_mask_size) const = 0;

   // Writes FEC header.
   virtual void FinalizeFecHeader(
       uint32_t media_ssrc,
       uint16_t seq_num_base,
       const uint8_t* packet_mask,
       size_t packet_mask_size,
       ForwardErrorCorrection::Packet* fec_packet) const = 0;

  protected:
   FecHeaderWriter(size_t max_media_packets,
                   size_t max_fec_packets,
                   size_t max_packet_overhead);

   const size_t max_media_packets_;
   const size_t max_fec_packets_;
   const size_t max_packet_overhead_;
 };

 }  // namespace webrtc

 #endif  // MODULES_RTP_RTCP_SOURCE_FORWARD_ERROR_CORRECTION_H_
	/*
	* 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.
	*/

	#ifndef MODULES_RTP_RTCP_SOURCE_FORWARD_ERROR_CORRECTION_H_
	#define MODULES_RTP_RTCP_SOURCE_FORWARD_ERROR_CORRECTION_H_

	#include <stddef.h>
	#include <stdint.h>

	#include <list>
	#include <memory>
	#include <vector>

	#include "api/scoped_refptr.h"
	#include "modules/include/module_fec_types.h"
	#include "modules/rtp_rtcp/include/rtp_rtcp_defines.h"
	#include "modules/rtp_rtcp/source/forward_error_correction_internal.h"
	#include "rtc_base/copy_on_write_buffer.h"

	namespace webrtc {

	class FecHeaderReader;
	class FecHeaderWriter;

	// Performs codec-independent forward error correction (FEC), based on RFC 5109.
	// Option exists to enable unequal protection (UEP) across packets.
	// This is not to be confused with protection within packets
	// (referred to as uneven level protection (ULP) in RFC 5109).
	// TODO(brandtr): Split this class into a separate encoder
	// and a separate decoder.
	class ForwardErrorCorrection {
	public:
	// TODO(holmer): As a next step all these struct-like packet classes should be
	// refactored into proper classes, and their members should be made private.
	// This will require parts of the functionality in forward_error_correction.cc
	// and receiver_fec.cc to be refactored into the packet classes.
	class Packet {
	public:
	Packet();
	virtual ~Packet();

	// Add a reference.
	virtual int32_t AddRef();

	// Release a reference. Will delete the object if the reference count
	// reaches zero.
	virtual int32_t Release();

	rtc::CopyOnWriteBuffer data; // Packet data.

	private:
	int32_t ref_count_; // Counts the number of references to a packet.
	};

	// TODO(holmer): Refactor into a proper class.
	class SortablePacket {
	public:
	// Functor which returns true if the sequence number of `first`
	// is < the sequence number of `second`. Should only ever be called for
	// packets belonging to the same SSRC.
	struct LessThan {
	template <typename S, typename T>
	bool operator()(const S& first, const T& second);
	};

	uint32_t ssrc;
	uint16_t seq_num;
	};

	// Used for the input to DecodeFec().
	//
	// TODO(nisse): Delete class, instead passing `is_fec` and `pkt` as separate
	// arguments.
	class ReceivedPacket : public SortablePacket {
	public:
	ReceivedPacket();
	~ReceivedPacket();

	bool is_fec; // Set to true if this is an FEC packet and false
	// otherwise.
	bool is_recovered;
	rtc::scoped_refptr<Packet> pkt; // Pointer to the packet storage.
	};

	// The recovered list parameter of DecodeFec() references structs of
	// this type.
	// TODO(holmer): Refactor into a proper class.
	class RecoveredPacket : public SortablePacket {
	public:
	RecoveredPacket();
	~RecoveredPacket();

	bool was_recovered; // Will be true if this packet was recovered by
	// the FEC. Otherwise it was a media packet passed in
	// through the received packet list.
	bool returned; // True when the packet already has been returned to the
	// caller through the callback.
	rtc::scoped_refptr<Packet> pkt; // Pointer to the packet storage.
	};

	// Used to link media packets to their protecting FEC packets.
	//
	// TODO(holmer): Refactor into a proper class.
	class ProtectedPacket : public SortablePacket {
	public:
	ProtectedPacket();
	~ProtectedPacket();

	rtc::scoped_refptr<ForwardErrorCorrection::Packet> pkt;
	};

	using ProtectedPacketList = std::list<std::unique_ptr<ProtectedPacket>>;

	// Used for internal storage of received FEC packets in a list.
	//
	// TODO(holmer): Refactor into a proper class.
	class ReceivedFecPacket : public SortablePacket {
	public:
	ReceivedFecPacket();
	~ReceivedFecPacket();

	// List of media packets that this FEC packet protects.
	ProtectedPacketList protected_packets;
	// RTP header fields.
	uint32_t ssrc;
	// FEC header fields.
	size_t fec_header_size;
	uint32_t protected_ssrc;
	uint16_t seq_num_base;
	size_t packet_mask_offset; // Relative start of FEC header.
	size_t packet_mask_size;
	size_t protection_length;
	// Raw data.
	rtc::scoped_refptr<ForwardErrorCorrection::Packet> pkt;
	};

	using PacketList = std::list<std::unique_ptr<Packet>>;
	using RecoveredPacketList = std::list<std::unique_ptr<RecoveredPacket>>;
	using ReceivedFecPacketList = std::list<std::unique_ptr<ReceivedFecPacket>>;

	~ForwardErrorCorrection();

	// Creates a ForwardErrorCorrection tailored for a specific FEC scheme.
	static std::unique_ptr<ForwardErrorCorrection> CreateUlpfec(uint32_t ssrc);
	static std::unique_ptr<ForwardErrorCorrection> CreateFlexfec(
	uint32_t ssrc,
	uint32_t protected_media_ssrc);

	// Generates a list of FEC packets from supplied media packets.
	//
	// Input: media_packets List of media packets to protect, of type
	// Packet. All packets must belong to the
	// same frame and the list must not be empty.
	// Input: protection_factor FEC protection overhead in the [0, 255]
	// domain. To obtain 100% overhead, or an
	// equal number of FEC packets as
	// media packets, use 255.
	// Input: num_important_packets The number of "important" packets in the
	// frame. These packets may receive greater
	// protection than the remaining packets.
	// The important packets must be located at the
	// start of the media packet list. For codecs
	// with data partitioning, the important
	// packets may correspond to first partition
	// packets.
	// Input: use_unequal_protection Parameter to enable/disable unequal
	// protection (UEP) across packets. Enabling
	// UEP will allocate more protection to the
	// num_important_packets from the start of the
	// media_packets.
	// Input: fec_mask_type The type of packet mask used in the FEC.
	// Random or bursty type may be selected. The
	// bursty type is only defined up to 12 media
	// packets. If the number of media packets is
	// above 12, the packet masks from the random
	// table will be selected.
	// Output: fec_packets List of pointers to generated FEC packets,
	// of type Packet. Must be empty on entry.
	// The memory available through the list will
	// be valid until the next call to
	// EncodeFec().
	//
	// Returns 0 on success, -1 on failure.
	//
	int EncodeFec(const PacketList& media_packets,
	uint8_t protection_factor,
	int num_important_packets,
	bool use_unequal_protection,
	FecMaskType fec_mask_type,
	std::list<Packet> fec_packets);

	// Decodes a list of received media and FEC packets. It will parse the
	// `received_packets`, storing FEC packets internally, and move
	// media packets to `recovered_packets`. The recovered list will be
	// sorted by ascending sequence number and have duplicates removed.
	// The function should be called as new packets arrive, and
	// `recovered_packets` will be progressively assembled with each call.
	// When the function returns, `received_packets` will be empty.
	//
	// The caller will allocate packets submitted through `received_packets`.
	// The function will handle allocation of recovered packets.
	//
	// Input: received_packets List of new received packets, of type
	// ReceivedPacket, belonging to a single
	// frame. At output the list will be empty,
	// with packets either stored internally,
	// or accessible through the recovered list.
	// Output: recovered_packets List of recovered media packets, of type
	// RecoveredPacket, belonging to a single
	// frame. The memory available through the
	// list will be valid until the next call to
	// DecodeFec().
	//
	void DecodeFec(const ReceivedPacket& received_packet,
	RecoveredPacketList* recovered_packets);

	// Get the number of generated FEC packets, given the number of media packets
	// and the protection factor.
	static int NumFecPackets(int num_media_packets, int protection_factor);

	// Gets the maximum size of the FEC headers in bytes, which must be
	// accounted for as packet overhead.
	size_t MaxPacketOverhead() const;

	// Reset internal states from last frame and clear `recovered_packets`.
	// Frees all memory allocated by this class.
	void ResetState(RecoveredPacketList* recovered_packets);

	// TODO(brandtr): Remove these functions when the Packet classes
	// have been refactored.
	static uint16_t ParseSequenceNumber(const uint8_t* packet);
	static uint32_t ParseSsrc(const uint8_t* packet);

	protected:
	ForwardErrorCorrection(std::unique_ptr<FecHeaderReader> fec_header_reader,
	std::unique_ptr<FecHeaderWriter> fec_header_writer,
	uint32_t ssrc,
	uint32_t protected_media_ssrc);

	private:
	// Analyzes `media_packets` for holes in the sequence and inserts zero columns
	// into the `packet_mask` where those holes are found. Zero columns means that
	// those packets will have no protection.
	// Returns the number of bits used for one row of the new packet mask.
	// Requires that `packet_mask` has at least 6 * `num_fec_packets` bytes
	// allocated.
	int InsertZerosInPacketMasks(const PacketList& media_packets,
	size_t num_fec_packets);

	// Writes FEC payloads and some recovery fields in the FEC headers.
	void GenerateFecPayloads(const PacketList& media_packets,
	size_t num_fec_packets);

	// Writes the FEC header fields that are not written by GenerateFecPayloads.
	// This includes writing the packet masks.
	void FinalizeFecHeaders(size_t num_fec_packets,
	uint32_t media_ssrc,
	uint16_t seq_num_base);

	// Inserts the `received_packet` into the internal received FEC packet list
	// or into `recovered_packets`.
	void InsertPacket(const ReceivedPacket& received_packet,
	RecoveredPacketList* recovered_packets);

	// Inserts the `received_packet` into `recovered_packets`. Deletes duplicates.
	void InsertMediaPacket(RecoveredPacketList* recovered_packets,
	const ReceivedPacket& received_packet);

	// Assigns pointers to the recovered packet from all FEC packets which cover
	// it.
	// Note: This reduces the complexity when we want to try to recover a packet
	// since we don't have to find the intersection between recovered packets and
	// packets covered by the FEC packet.
	void UpdateCoveringFecPackets(const RecoveredPacket& packet);

	// Insert `received_packet` into internal FEC list. Deletes duplicates.
	void InsertFecPacket(const RecoveredPacketList& recovered_packets,
	const ReceivedPacket& received_packet);

	// Assigns pointers to already recovered packets covered by `fec_packet`.
	static void AssignRecoveredPackets(
	const RecoveredPacketList& recovered_packets,
	ReceivedFecPacket* fec_packet);

	// Attempt to recover missing packets, using the internally stored
	// received FEC packets.
	void AttemptRecovery(RecoveredPacketList* recovered_packets);

	// Initializes headers and payload before the XOR operation
	// that recovers a packet.
	static bool StartPacketRecovery(const ReceivedFecPacket& fec_packet,
	RecoveredPacket* recovered_packet);

	// Performs XOR between the first 8 bytes of `src` and `dst` and stores
	// the result in `dst`. The 3rd and 4th bytes are used for storing
	// the length recovery field.
	static void XorHeaders(const Packet& src, Packet* dst);

	// Performs XOR between the payloads of `src` and `dst` and stores the result
	// in `dst`. The parameter `dst_offset` determines at what byte the
	// XOR operation starts in `dst`. In total, `payload_length` bytes are XORed.
	static void XorPayloads(const Packet& src,
	size_t payload_length,
	size_t dst_offset,
	Packet* dst);

	// Finalizes recovery of packet by setting RTP header fields.
	// This is not specific to the FEC scheme used.
	static bool FinishPacketRecovery(const ReceivedFecPacket& fec_packet,
	RecoveredPacket* recovered_packet);

	// Recover a missing packet.
	static bool RecoverPacket(const ReceivedFecPacket& fec_packet,
	RecoveredPacket* recovered_packet);

	// Get the number of missing media packets which are covered by `fec_packet`.
	// An FEC packet can recover at most one packet, and if zero packets are
	// missing the FEC packet can be discarded. This function returns 2 when two
	// or more packets are missing.
	static int NumCoveredPacketsMissing(const ReceivedFecPacket& fec_packet);

	// Discards old packets in `recovered_packets`, which are no longer relevant
	// for recovering lost packets.
	void DiscardOldRecoveredPackets(RecoveredPacketList* recovered_packets);

	// Checks if the FEC packet is old enough and no longer relevant for
	// recovering lost media packets.
	bool IsOldFecPacket(const ReceivedFecPacket& fec_packet,
	const RecoveredPacketList* recovered_packets);

	// These SSRCs are only used by the decoder.
	const uint32_t ssrc_;
	const uint32_t protected_media_ssrc_;

	std::unique_ptr<FecHeaderReader> fec_header_reader_;
	std::unique_ptr<FecHeaderWriter> fec_header_writer_;

	std::vector<Packet> generated_fec_packets_;
	ReceivedFecPacketList received_fec_packets_;

	// Arrays used to avoid dynamically allocating memory when generating
	// the packet masks.
	// (There are never more than `kUlpfecMaxMediaPackets` FEC packets generated.)
	uint8_t packet_masks_[kUlpfecMaxMediaPackets * kUlpfecMaxPacketMaskSize];
	uint8_t tmp_packet_masks_[kUlpfecMaxMediaPackets * kUlpfecMaxPacketMaskSize];
	size_t packet_mask_size_;
	};

	// Classes derived from FecHeader{Reader,Writer} encapsulate the
	// specifics of reading and writing FEC header for, e.g., ULPFEC
	// and FlexFEC.
	class FecHeaderReader {
	public:
	virtual ~FecHeaderReader();

	// The maximum number of media packets that can be covered by one FEC packet.
	size_t MaxMediaPackets() const;

	// The maximum number of FEC packets that is supported, per call
	// to ForwardErrorCorrection::EncodeFec().
	size_t MaxFecPackets() const;

	// Parses FEC header and stores information in ReceivedFecPacket members.
	virtual bool ReadFecHeader(
	ForwardErrorCorrection::ReceivedFecPacket* fec_packet) const = 0;

	protected:
	FecHeaderReader(size_t max_media_packets, size_t max_fec_packets);

	const size_t max_media_packets_;
	const size_t max_fec_packets_;
	};

	class FecHeaderWriter {
	public:
	virtual ~FecHeaderWriter();

	// The maximum number of media packets that can be covered by one FEC packet.
	size_t MaxMediaPackets() const;

	// The maximum number of FEC packets that is supported, per call
	// to ForwardErrorCorrection::EncodeFec().
	size_t MaxFecPackets() const;

	// The maximum overhead (in bytes) per packet, due to FEC headers.
	size_t MaxPacketOverhead() const;

	// Calculates the minimum packet mask size needed (in bytes),
	// given the discrete options of the ULPFEC masks and the bits
	// set in the current packet mask.
	virtual size_t MinPacketMaskSize(const uint8_t* packet_mask,
	size_t packet_mask_size) const = 0;

	// The header size (in bytes), given the packet mask size.
	virtual size_t FecHeaderSize(size_t packet_mask_size) const = 0;

	// Writes FEC header.
	virtual void FinalizeFecHeader(
	uint32_t media_ssrc,
	uint16_t seq_num_base,
	const uint8_t* packet_mask,
	size_t packet_mask_size,
	ForwardErrorCorrection::Packet* fec_packet) const = 0;

	protected:
	FecHeaderWriter(size_t max_media_packets,
	size_t max_fec_packets,
	size_t max_packet_overhead);

	const size_t max_media_packets_;
	const size_t max_fec_packets_;
	const size_t max_packet_overhead_;
	};

	} // namespace webrtc

	#endif // MODULES_RTP_RTCP_SOURCE_FORWARD_ERROR_CORRECTION_H_