使用C#实现RTP数据包传输 参照RFC3550

闲暇时折腾IP网络视频监控系统,需要支持视频帧数据包在网络内的传输。
未采用H.264或MPEG4等编码压缩方式,直接使用Bitmap图片。
由于对帧的准确到达要求不好,所以采用UDP传输。如果发生网络丢包现象则直接将帧丢弃。
为了记录数据包的传输顺序和帧的时间戳,所以研究了下RFC3550协议,采用RTP包封装视频帧。
并未全面深究,所以未使用SSRC和CSRC,因为不确切了解其用意。不过目前的实现情况已经足够了。

复制代码 代码如下:

///
   /// RTP(RFC3550)协议数据包
   ///

   ///
   /// The RTP header has the following format:
   ///  0                   1                   2                   3
   ///  0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 6 7 8 9 0 1
   /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   /// |V=2|P|X| CC    |M| PT          | sequence number               |
   /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   /// | timestamp                                                     |
   /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   /// | synchronization source (SSRC) identifier                      |
   /// +=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+=+
   /// | contributing source (CSRC) identifiers                        |
   /// | ....                                                          |
   /// +-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+-+
   ///

   public class RtpPacket
   {
     ///
     /// version (V): 2 bits
     /// RTP版本标识,当前规范定义值为2.
     /// This field identifies the version of RTP. The version defined by this specification is two (2).
     /// (The value 1 is used by the first draft version of RTP and the value 0 is used by the protocol
     /// initially implemented in the \vat" audio tool.)
     ///

     public int Version { get { return 2; } }

     ///
     /// padding (P):1 bit
     /// 如果设定padding,在报文的末端就会包含一个或者多个padding 字节,这不属于payload。
     /// 最后一个字节的padding 有一个计数器,标识需要忽略多少个padding 字节(包括自己)。
     /// 一些加密算法可能需要固定块长度的padding,或者是为了在更低层数据单元中携带一些RTP 报文。
     /// If the padding bit is set, the packet contains one or more additional padding octets at the
     /// end which are not part of the payload. The last octet of the padding contains a count of
     /// how many padding octets should be ignored, including itself. Padding may be needed by
     /// some encryption algorithms with fixed block sizes or for carrying several RTP packets in a
     /// lower-layer protocol data unit.
     ///

     public int Padding { get { return 0; } }

     ///
     /// extension (X):1 bit
     /// 如果设定了extension 位,定长头字段后面会有一个头扩展。
     /// If the extension bit is set, the fixed header must be followed by exactly one header extensio.
     ///

     public int Extension { get { return 0; } }

     ///
     /// CSRC count (CC):4 bits
     /// CSRC count 标识了定长头字段中包含的CSRC identifier 的数量。
     /// The CSRC count contains the number of CSRC identifiers that follow the fixed header.
     ///

     public int CC { get { return 0; } }

     ///
     /// marker (M):1 bit
     /// marker 是由一个profile 定义的。用来允许标识在像报文流中界定帧界等的事件。
     /// 一个profile 可能定义了附加的标识位或者通过修改payload type 域中的位数量来指定没有标识位.
     /// The interpretation of the marker is defined by a profile. It is intended to allow significant
     /// events such as frame boundaries to be marked in the packet stream. A profile may define
     /// additional marker bits or specify that there is no marker bit by changing the number of bits
     /// in the payload type field.
     ///

     public int Marker { get { return 0; } }

     ///
     /// payload type (PT):7 bits
     /// 这个字段定一个RTPpayload 的格式和在应用中定义解释。
     /// profile 可能指定一个从payload type 码字到payload format 的默认静态映射。
     /// 也可以通过non-RTP 方法来定义附加的payload type 码字(见第3 章)。
     /// 在 RFC 3551[1]中定义了一系列的默认音视频映射。
     /// 一个RTP 源有可能在会话中改变payload type,但是这个域在复用独立的媒体时是不同的。(见5.2 节)。
     /// 接收者必须忽略它不识别的payload type。
     /// This field identifies the format of the RTP payload and determines its interpretation by the
     /// application. A profile may specify a default static mapping of payload type codes to payload
     /// formats. Additional payload type codes may be defined dynamically through non-RTP means
     /// (see Section 3). A set of default mappings for audio and video is specified in the companion
     /// RFC 3551 [1]. An RTP source may change the payload type during a session, but this field
     /// should not be used for multiplexing separate media streams (see Section 5.2).
     /// A receiver must ignore packets with payload types that it does not understand.
     ///

     public RtpPayloadType PayloadType { get; private set; }

     ///
     /// sequence number:16 bits
     /// 每发送一个RTP 数据报文序列号值加一,接收者也可用来检测丢失的包或者重建报文序列。
     /// 初始的值是随机的,这样就使得known-plaintext 攻击更加困难, 即使源并没有加密(见9。1),
     /// 因为要通过的translator 会做这些事情。关于选择随机数方面的技术见[17]。
     /// The sequence number increments by one for each RTP data packet sent, and may be used
     /// by the receiver to detect packet loss and to restore packet sequence. The initial value of the
     /// sequence number should be random (unpredictable) to make known-plaintext attacks on
     /// encryption more dificult, even if the source itself does not encrypt according to the method
     /// in Section 9.1, because the packets may flow through a translator that does. Techniques for
     /// choosing unpredictable numbers are discussed in [17].
     ///

     public int SequenceNumber { get; private set; }

     ///
     /// timestamp:32 bits
     /// timestamp 反映的是RTP 数据报文中的第一个字段的采样时刻的时间瞬时值。
     /// 采样时间值必须是从恒定的和线性的时间中得到以便于同步和jitter 计算(见第6.4.1 节)。
     /// 必须保证同步和测量保温jitter 到来所需要的时间精度(一帧一个tick 一般情况下是不够的)。
     /// 时钟频率是与payload 所携带的数据格式有关的,在profile 中静态的定义或是在定义格式的payload format 中,
     /// 或通过non-RTP 方法所定义的payload format 中动态的定义。如果RTP 报文周期的生成,就采用虚拟的(nominal)
     /// 采样时钟而不是从系统时钟读数。例如,在固定比特率的音频中,timestamp 时钟会在每个采样周期时加一。
     /// 如果音频应用中从输入设备中读入160 个采样周期的块,the timestamp 就会每一块增加160,
     /// 而不管块是否传输了或是丢弃了。
     /// 对于序列号来说,timestamp 初始值是随机的。只要它们是同时(逻辑上)同时生成的,
     /// 这些连续的的 RTP 报文就会有相同的timestamp,
     /// 例如,同属一个视频帧。正像在MPEG 中内插视频帧一样,
     /// 连续的但不是按顺序发送的RTP 报文可能含有相同的timestamp。
     /// The timestamp reflects the sampling instant of the first octet in the RTP data packet. The
     /// sampling instant must be derived from a clock that increments monotonically and linearly
     /// in time to allow synchronization and jitter calculations (see Section 6.4.1). The resolution
     /// of the clock must be suficient for the desired synchronization accuracy and for measuring
     /// packet arrival jitter (one tick per video frame is typically not suficient). The clock frequency
     /// is dependent on the format of data carried as payload and is specified statically in the profile
     /// or payload format specification that defines the format, or may be specified dynamically for
     /// payload formats defined through non-RTP means. If RTP packets are generated periodically,
     /// the nominal sampling instant as determined from the sampling clock is to be used, not a
     /// reading of the system clock. As an example, for fixed-rate audio the timestamp clock would
     /// likely increment by one for each sampling period. If an audio application reads blocks covering
     /// 160 sampling periods from the input device, the timestamp would be increased by 160 for
     /// each such block, regardless of whether the block is transmitted in a packet or dropped as silent.
     ///

     public long Timestamp { get; private set; }

     ///
     /// SSRC:32 bits
     /// SSRC 域识别同步源。为了防止在一个会话中有相同的同步源有相同的SSRC identifier,
     /// 这个identifier 必须随机选取。
     /// 生成随机 identifier 的算法见目录A.6 。虽然选择相同的identifier 概率很小,
     /// 但是所有的RTP implementation 必须检测和解决冲突。
     /// 第8 章描述了冲突的概率和解决机制和RTP 级的检测机制,根据唯一的 SSRCidentifier 前向循环。
     /// 如果有源改变了它的源传输地址,
     /// 就必须为它选择一个新的SSRCidentifier 来避免被识别为循环过的源(见第8.2 节)。
     /// The SSRC field identifies the synchronization source. This identifier should be chosen
     /// randomly, with the intent that no two synchronization sources within the same RTP session
     /// will have the same SSRC identifier. An example algorithm for generating a random identifier
     /// is presented in Appendix A.6. Although the probability of multiple sources choosing the same
     /// identifier is low, all RTP implementations must be prepared to detect and resolve collisions.
     /// Section 8 describes the probability of collision along with a mechanism for resolving collisions
     /// and detecting RTP-level forwarding loops based on the uniqueness of the SSRC identifier. If
     /// a source changes its source transport address, it must also choose a new SSRC identifier to
     /// avoid being interpreted as a looped source (see Section 8.2).
     ///

     public int SSRC { get { return 0; } }

     ///
     /// 每一个RTP包中都有前12个字节定长的头字段
     /// The first twelve octets are present in every RTP packet
     ///

     public const int HeaderSize = 12;
     ///
     /// RTP消息头
     ///

     private byte[] _header;
     ///
     /// RTP消息头
     ///

     public byte[] Header { get { return _header; } }

     ///
     /// RTP有效载荷长度
     ///

     private int _payloadSize;
     ///
     /// RTP有效载荷长度
     ///

     public int PayloadSize { get { return _payloadSize; } }

     ///
     /// RTP有效载荷
     ///

     private byte[] _payload;
     ///
     /// RTP有效载荷
     ///

     public byte[] Payload { get { return _payload; } }

     ///
     /// RTP消息总长度,包括Header和Payload
     ///

     public int Length { get { return HeaderSize + PayloadSize; } }

     ///
     /// RTP(RFC3550)协议数据包
     ///

     /// 数据报文有效载荷类型
     /// 数据报文序列号值
     /// 数据报文采样时刻
     /// 数据
     /// 数据长度
     public RtpPacket(
       RtpPayloadType playloadType,
       int sequenceNumber,
       long timestamp,
       byte[] data,
       int dataSize)
     {
       // fill changing header fields
       SequenceNumber = sequenceNumber;
       Timestamp = timestamp;
       PayloadType = playloadType;

       // build the header bistream
       _header = new byte[HeaderSize];

       // fill the header array of byte with RTP header fields
       _header[0] = (byte)((Version << 6) | (Padding << 5) | (Extension << 4) | CC);
       _header[1] = (byte)((Marker << 7) | (int)PayloadType);
       _header[2] = (byte)(SequenceNumber >> 8);
       _header[3] = (byte)(SequenceNumber);
       for (int i = 0; i < 4; i++)
       {
         _header[7 - i] = (byte)(Timestamp >> (8 * i));
       }
       for (int i = 0; i < 4; i++)
       {
         _header[11 - i] = (byte)(SSRC >> (8 * i));
       }

       // fill the payload bitstream
       _payload = new byte[dataSize];
       _payloadSize = dataSize;

       // fill payload array of byte from data (given in parameter of the constructor)
       Array.Copy(data, 0, _payload, 0, dataSize);
     }

     ///
     /// RTP(RFC3550)协议数据包
     ///

     /// 数据报文有效载荷类型
     /// 数据报文序列号值
     /// 数据报文采样时刻
     /// 图片
     public RtpPacket(
       RtpPayloadType playloadType,
       int sequenceNumber,
       long timestamp,
       Image frame)
     {
       // fill changing header fields
       SequenceNumber = sequenceNumber;
       Timestamp = timestamp;
       PayloadType = playloadType;

       // build the header bistream
       _header = new byte[HeaderSize];

       // fill the header array of byte with RTP header fields
       _header[0] = (byte)((Version << 6) | (Padding << 5) | (Extension << 4) | CC);
       _header[1] = (byte)((Marker << 7) | (int)PayloadType);
       _header[2] = (byte)(SequenceNumber >> 8);
       _header[3] = (byte)(SequenceNumber);
       for (int i = 0; i < 4; i++)
       {
         _header[7 - i] = (byte)(Timestamp >> (8 * i));
       }
       for (int i = 0; i < 4; i++)
       {
         _header[11 - i] = (byte)(SSRC >> (8 * i));
       }

       // fill the payload bitstream
       using (MemoryStream ms = new MemoryStream())
       {
         frame.Save(ms, ImageFormat.Jpeg);
         _payload = ms.ToArray();
         _payloadSize = _payload.Length;
       }
     }

     ///
     /// RTP(RFC3550)协议数据包
     ///

     /// 数据包
     /// 数据包长度
     public RtpPacket(byte[] packet, int packetSize)
     {
       //check if total packet size is lower than the header size
       if (packetSize >= HeaderSize)
       {
         //get the header bitsream
         _header = new byte[HeaderSize];
         for (int i = 0; i < HeaderSize; i++)
         {
           _header[i] = packet[i];
         }

         //get the payload bitstream
         _payloadSize = packetSize - HeaderSize;
         _payload = new byte[_payloadSize];
         for (int i = HeaderSize; i < packetSize; i++)
         {
           _payload[i - HeaderSize] = packet[i];
         }

         //interpret the changing fields of the header
         PayloadType = (RtpPayloadType)(_header[1] & 127);
         SequenceNumber = UnsignedInt(_header[3]) + 256 * UnsignedInt(_header[2]);
         Timestamp = UnsignedInt(_header[7])
           + 256 * UnsignedInt(_header[6])
           + 65536 * UnsignedInt(_header[5])
           + 16777216 * UnsignedInt(_header[4]);
       }
     }

     ///
     /// 将消息转换成byte数组
     ///

     /// 消息byte数组
     public byte[] ToArray()
     {
       byte[] packet = new byte[Length];

       Array.Copy(_header, 0, packet, 0, HeaderSize);
       Array.Copy(_payload, 0, packet, HeaderSize, PayloadSize);

       return packet;
     }

     ///
     /// 将消息体转换成图片
     ///

     /// 图片
     public Bitmap ToBitmap()
     {
       return new Bitmap(new MemoryStream(_payload));
     }

     ///
     /// 将消息体转换成图片
     ///

     /// 图片
     public Image ToImage()
     {
       return Image.FromStream(new MemoryStream(_payload));
     }

     ///
     /// 将图片转换成消息
     ///

     /// 数据报文有效载荷类型
     /// 数据报文序列号值
     /// 数据报文采样时刻
     /// 图片帧
     ///
     /// RTP消息
     ///

     public static RtpPacket FromImage(
       RtpPayloadType playloadType,
       int sequenceNumber,
       long timestamp,
       Image frame)
     {
       return new RtpPacket(playloadType, sequenceNumber, timestamp, frame);
     }

     ///
     /// return the unsigned value of 8-bit integer nb
     ///

     ///
     ///
     private static int UnsignedInt(int nb)
     {
       if (nb >= 0)
         return (nb);
       else
         return (256 + nb);
     }
   }

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