webrtc/modules/video_coding/session_info.h - src - Git at Google

 /*
  *  Copyright (c) 2011 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 WEBRTC_MODULES_VIDEO_CODING_SESSION_INFO_H_
 #define WEBRTC_MODULES_VIDEO_CODING_SESSION_INFO_H_

 #include <list>

 #include "webrtc/modules/include/module_common_types.h"
 #include "webrtc/modules/video_coding/include/video_coding.h"
 #include "webrtc/modules/video_coding/packet.h"
 #include "webrtc/typedefs.h"

 namespace webrtc {
 // Used to pass data from jitter buffer to session info.
 // This data is then used in determining whether a frame is decodable.
 struct FrameData {
   int64_t rtt_ms;
   float rolling_average_packets_per_frame;
 };

 class VCMSessionInfo {
  public:
   VCMSessionInfo();

   void UpdateDataPointers(const uint8_t* old_base_ptr,
                           const uint8_t* new_base_ptr);
   // NACK - Building the NACK lists.
   // Build hard NACK list: Zero out all entries in list up to and including
   // _lowSeqNum.
   int BuildHardNackList(int* seq_num_list,
                         int seq_num_list_length,
                         int nack_seq_nums_index);

   // Build soft NACK list:  Zero out only a subset of the packets, discard
   // empty packets.
   int BuildSoftNackList(int* seq_num_list,
                         int seq_num_list_length,
                         int nack_seq_nums_index,
                         int rtt_ms);
   void Reset();
   int InsertPacket(const VCMPacket& packet,
                    uint8_t* frame_buffer,
                    VCMDecodeErrorMode enable_decodable_state,
                    const FrameData& frame_data);
   bool complete() const;
   bool decodable() const;

   // Builds fragmentation headers for VP8, each fragment being a decodable
   // VP8 partition. Returns the total number of bytes which are decodable. Is
   // used instead of MakeDecodable for VP8.
   size_t BuildVP8FragmentationHeader(uint8_t* frame_buffer,
                                      size_t frame_buffer_length,
                                      RTPFragmentationHeader* fragmentation);

   // Makes the frame decodable. I.e., only contain decodable NALUs. All
   // non-decodable NALUs will be deleted and packets will be moved to in
   // memory to remove any empty space.
   // Returns the number of bytes deleted from the session.
   size_t MakeDecodable();

   // Sets decodable_ to false.
   // Used by the dual decoder. After the mode is changed to kNoErrors from
   // kWithErrors or kSelective errors, any states that have been marked
   // decodable and are not complete are marked as non-decodable.
   void SetNotDecodableIfIncomplete();

   size_t SessionLength() const;
   int NumPackets() const;
   bool HaveFirstPacket() const;
   bool HaveLastPacket() const;
   bool session_nack() const;
   webrtc::FrameType FrameType() const { return frame_type_; }
   int LowSequenceNumber() const;

   // Returns highest sequence number, media or empty.
   int HighSequenceNumber() const;
   int PictureId() const;
   int TemporalId() const;
   bool LayerSync() const;
   int Tl0PicId() const;
   bool NonReference() const;

   void SetGofInfo(const GofInfoVP9& gof_info, size_t idx);

   // The number of packets discarded because the decoder can't make use of
   // them.
   int packets_not_decodable() const;

  private:
   enum { kMaxVP8Partitions = 9 };

   typedef std::list<VCMPacket> PacketList;
   typedef PacketList::iterator PacketIterator;
   typedef PacketList::const_iterator PacketIteratorConst;
   typedef PacketList::reverse_iterator ReversePacketIterator;

   void InformOfEmptyPacket(uint16_t seq_num);

   // Finds the packet of the beginning of the next VP8 partition. If
   // none is found the returned iterator points to |packets_.end()|.
   // |it| is expected to point to the last packet of the previous partition,
   // or to the first packet of the frame. |packets_skipped| is incremented
   // for each packet found which doesn't have the beginning bit set.
   PacketIterator FindNextPartitionBeginning(PacketIterator it) const;

   // Returns an iterator pointing to the last packet of the partition pointed to
   // by |it|.
   PacketIterator FindPartitionEnd(PacketIterator it) const;
   static bool InSequence(const PacketIterator& it,
                          const PacketIterator& prev_it);
   size_t InsertBuffer(uint8_t* frame_buffer, PacketIterator packetIterator);
   size_t Insert(const uint8_t* buffer,
                 size_t length,
                 bool insert_start_code,
                 uint8_t* frame_buffer);
   void ShiftSubsequentPackets(PacketIterator it, int steps_to_shift);
   PacketIterator FindNaluEnd(PacketIterator packet_iter) const;
   // Deletes the data of all packets between |start| and |end|, inclusively.
   // Note that this function doesn't delete the actual packets.
   size_t DeletePacketData(PacketIterator start, PacketIterator end);
   void UpdateCompleteSession();

   // When enabled, determine if session is decodable, i.e. incomplete but
   // would be sent to the decoder.
   // Note: definition assumes random loss.
   // A frame is defined to be decodable when:
   //  Round trip time is higher than threshold
   //  It is not a key frame
   //  It has the first packet: In VP8 the first packet contains all or part of
   //    the first partition, which consists of the most relevant information for
   //    decoding.
   //  Either more than the upper threshold of the average number of packets per
   //        frame is present
   //      or less than the lower threshold of the average number of packets per
   //        frame is present: suggests a small frame. Such a frame is unlikely
   //        to contain many motion vectors, so having the first packet will
   //        likely suffice. Once we have more than the lower threshold of the
   //        frame, we know that the frame is medium or large-sized.
   void UpdateDecodableSession(const FrameData& frame_data);

   // If this session has been NACKed by the jitter buffer.
   bool session_nack_;
   bool complete_;
   bool decodable_;
   webrtc::FrameType frame_type_;
   // Packets in this frame.
   PacketList packets_;
   int empty_seq_num_low_;
   int empty_seq_num_high_;

   // The following two variables correspond to the first and last media packets
   // in a session defined by the first packet flag and the marker bit.
   // They are not necessarily equal to the front and back packets, as packets
   // may enter out of order.
   // TODO(mikhal): Refactor the list to use a map.
   int first_packet_seq_num_;
   int last_packet_seq_num_;
 };

 }  // namespace webrtc

 #endif  // WEBRTC_MODULES_VIDEO_CODING_SESSION_INFO_H_
	/*
	* Copyright (c) 2011 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 WEBRTC_MODULES_VIDEO_CODING_SESSION_INFO_H_
	#define WEBRTC_MODULES_VIDEO_CODING_SESSION_INFO_H_

	#include <list>

	#include "webrtc/modules/include/module_common_types.h"
	#include "webrtc/modules/video_coding/include/video_coding.h"
	#include "webrtc/modules/video_coding/packet.h"
	#include "webrtc/typedefs.h"

	namespace webrtc {
	// Used to pass data from jitter buffer to session info.
	// This data is then used in determining whether a frame is decodable.
	struct FrameData {
	int64_t rtt_ms;
	float rolling_average_packets_per_frame;
	};

	class VCMSessionInfo {
	public:
	VCMSessionInfo();

	void UpdateDataPointers(const uint8_t* old_base_ptr,
	const uint8_t* new_base_ptr);
	// NACK - Building the NACK lists.
	// Build hard NACK list: Zero out all entries in list up to and including
	// _lowSeqNum.
	int BuildHardNackList(int* seq_num_list,
	int seq_num_list_length,
	int nack_seq_nums_index);

	// Build soft NACK list: Zero out only a subset of the packets, discard
	// empty packets.
	int BuildSoftNackList(int* seq_num_list,
	int seq_num_list_length,
	int nack_seq_nums_index,
	int rtt_ms);
	void Reset();
	int InsertPacket(const VCMPacket& packet,
	uint8_t* frame_buffer,
	VCMDecodeErrorMode enable_decodable_state,
	const FrameData& frame_data);
	bool complete() const;
	bool decodable() const;

	// Builds fragmentation headers for VP8, each fragment being a decodable
	// VP8 partition. Returns the total number of bytes which are decodable. Is
	// used instead of MakeDecodable for VP8.
	size_t BuildVP8FragmentationHeader(uint8_t* frame_buffer,
	size_t frame_buffer_length,
	RTPFragmentationHeader* fragmentation);

	// Makes the frame decodable. I.e., only contain decodable NALUs. All
	// non-decodable NALUs will be deleted and packets will be moved to in
	// memory to remove any empty space.
	// Returns the number of bytes deleted from the session.
	size_t MakeDecodable();

	// Sets decodable_ to false.
	// Used by the dual decoder. After the mode is changed to kNoErrors from
	// kWithErrors or kSelective errors, any states that have been marked
	// decodable and are not complete are marked as non-decodable.
	void SetNotDecodableIfIncomplete();

	size_t SessionLength() const;
	int NumPackets() const;
	bool HaveFirstPacket() const;
	bool HaveLastPacket() const;
	bool session_nack() const;
	webrtc::FrameType FrameType() const { return frame_type_; }
	int LowSequenceNumber() const;

	// Returns highest sequence number, media or empty.
	int HighSequenceNumber() const;
	int PictureId() const;
	int TemporalId() const;
	bool LayerSync() const;
	int Tl0PicId() const;
	bool NonReference() const;

	void SetGofInfo(const GofInfoVP9& gof_info, size_t idx);

	// The number of packets discarded because the decoder can't make use of
	// them.
	int packets_not_decodable() const;

	private:
	enum { kMaxVP8Partitions = 9 };

	typedef std::list<VCMPacket> PacketList;
	typedef PacketList::iterator PacketIterator;
	typedef PacketList::const_iterator PacketIteratorConst;
	typedef PacketList::reverse_iterator ReversePacketIterator;

	void InformOfEmptyPacket(uint16_t seq_num);

	// Finds the packet of the beginning of the next VP8 partition. If
	// none is found the returned iterator points to \|packets_.end()\|.
	// \|it\| is expected to point to the last packet of the previous partition,
	// or to the first packet of the frame. \|packets_skipped\| is incremented
	// for each packet found which doesn't have the beginning bit set.
	PacketIterator FindNextPartitionBeginning(PacketIterator it) const;

	// Returns an iterator pointing to the last packet of the partition pointed to
	// by \|it\|.
	PacketIterator FindPartitionEnd(PacketIterator it) const;
	static bool InSequence(const PacketIterator& it,
	const PacketIterator& prev_it);
	size_t InsertBuffer(uint8_t* frame_buffer, PacketIterator packetIterator);
	size_t Insert(const uint8_t* buffer,
	size_t length,
	bool insert_start_code,
	uint8_t* frame_buffer);
	void ShiftSubsequentPackets(PacketIterator it, int steps_to_shift);
	PacketIterator FindNaluEnd(PacketIterator packet_iter) const;
	// Deletes the data of all packets between \|start\| and \|end\|, inclusively.
	// Note that this function doesn't delete the actual packets.
	size_t DeletePacketData(PacketIterator start, PacketIterator end);
	void UpdateCompleteSession();

	// When enabled, determine if session is decodable, i.e. incomplete but
	// would be sent to the decoder.
	// Note: definition assumes random loss.
	// A frame is defined to be decodable when:
	// Round trip time is higher than threshold
	// It is not a key frame
	// It has the first packet: In VP8 the first packet contains all or part of
	// the first partition, which consists of the most relevant information for
	// decoding.
	// Either more than the upper threshold of the average number of packets per
	// frame is present
	// or less than the lower threshold of the average number of packets per
	// frame is present: suggests a small frame. Such a frame is unlikely
	// to contain many motion vectors, so having the first packet will
	// likely suffice. Once we have more than the lower threshold of the
	// frame, we know that the frame is medium or large-sized.
	void UpdateDecodableSession(const FrameData& frame_data);

	// If this session has been NACKed by the jitter buffer.
	bool session_nack_;
	bool complete_;
	bool decodable_;
	webrtc::FrameType frame_type_;
	// Packets in this frame.
	PacketList packets_;
	int empty_seq_num_low_;
	int empty_seq_num_high_;

	// The following two variables correspond to the first and last media packets
	// in a session defined by the first packet flag and the marker bit.
	// They are not necessarily equal to the front and back packets, as packets
	// may enter out of order.
	// TODO(mikhal): Refactor the list to use a map.
	int first_packet_seq_num_;
	int last_packet_seq_num_;
	};

	} // namespace webrtc

	#endif // WEBRTC_MODULES_VIDEO_CODING_SESSION_INFO_H_