#include "CStreamer.h" #include //#define STREAM_DEBUG CStreamer::CStreamer(SOCKET aClient, u_short width, u_short height) : m_Client(aClient) { printf("Creating TSP streamer\n"); m_RtpServerPort = 0; m_RtcpServerPort = 0; m_RtpClientPort = 0; m_RtcpClientPort = 0; m_SequenceNumber = 0; m_Timestamp = 0; m_SendIdx = 0; m_TCPTransport = false; m_RtpSocket = NULLSOCKET; m_RtcpSocket = NULLSOCKET; m_width = width; m_height = height; m_prevMsec = 0; }; CStreamer::~CStreamer() { udpsocketclose(m_RtpSocket); udpsocketclose(m_RtcpSocket); }; int CStreamer::SendRtpPacket(unsigned const char * jpeg, int jpegLen, int fragmentOffset, BufPtr quant0tbl, BufPtr quant1tbl) { #define KRtpHeaderSize 12 // size of the RTP header #define KJpegHeaderSize 8 // size of the special JPEG payload header #define MAX_FRAGMENT_SIZE 1100 // FIXME, pick more carefully int fragmentLen = MAX_FRAGMENT_SIZE; if(fragmentLen + fragmentOffset > jpegLen) // Shrink last fragment if needed fragmentLen = jpegLen - fragmentOffset; bool isLastFragment = (fragmentOffset + fragmentLen) == jpegLen; // Do we have custom quant tables? If so include them per RFC bool includeQuantTbl = quant0tbl && quant1tbl && fragmentOffset == 0; uint8_t q = includeQuantTbl ? 128 : 0x5e; //static char RtpBuf[2048]; // Note: we assume single threaded, this large buf we keep off of the tiny stack int RtpPacketSize = fragmentLen + KRtpHeaderSize + KJpegHeaderSize + (includeQuantTbl ? (4 + 64 * 2) : 0); memset(RtpBuf,0x00,sizeof(RtpBuf)); // Prepare the first 4 byte of the packet. This is the Rtp over Rtsp header in case of TCP based transport RtpBuf[0] = '$'; // magic number RtpBuf[1] = 0; // number of multiplexed subchannel on RTPS connection - here the RTP channel RtpBuf[2] = (RtpPacketSize & 0x0000FF00) >> 8; RtpBuf[3] = (RtpPacketSize & 0x000000FF); // Prepare the 12 byte RTP header RtpBuf[4] = 0x80; // RTP version RtpBuf[5] = 0x1a | (isLastFragment ? 0x80 : 0x00); // JPEG payload (26) and marker bit RtpBuf[7] = m_SequenceNumber & 0x0FF; // each packet is counted with a sequence counter RtpBuf[6] = m_SequenceNumber >> 8; RtpBuf[8] = (m_Timestamp & 0xFF000000) >> 24; // each image gets a timestamp RtpBuf[9] = (m_Timestamp & 0x00FF0000) >> 16; RtpBuf[10] = (m_Timestamp & 0x0000FF00) >> 8; RtpBuf[11] = (m_Timestamp & 0x000000FF); RtpBuf[12] = 0x13; // 4 byte SSRC (sychronization source identifier) RtpBuf[13] = 0xf9; // we just an arbitrary number here to keep it simple RtpBuf[14] = 0x7e; RtpBuf[15] = 0x67; // Prepare the 8 byte payload JPEG header RtpBuf[16] = 0x00; // type specific RtpBuf[17] = (fragmentOffset & 0x00FF0000) >> 16; // 3 byte fragmentation offset for fragmented images RtpBuf[18] = (fragmentOffset & 0x0000FF00) >> 8; RtpBuf[19] = (fragmentOffset & 0x000000FF); /* These sampling factors indicate that the chrominance components of type 0 video is downsampled horizontally by 2 (often called 4:2:2) while the chrominance components of type 1 video are downsampled both horizontally and vertically by 2 (often called 4:2:0). */ RtpBuf[20] = 0x00; // type (fixme might be wrong for camera data) https://tools.ietf.org/html/rfc2435 RtpBuf[21] = q; // quality scale factor was 0x5e RtpBuf[22] = m_width / 8; // width / 8 RtpBuf[23] = m_height / 8; // height / 8 int headerLen = 24; // Inlcuding jpeg header but not qant table header if(includeQuantTbl) { // we need a quant header - but only in first packet of the frame //printf("inserting quanttbl\n"); RtpBuf[24] = 0; // MBZ RtpBuf[25] = 0; // 8 bit precision RtpBuf[26] = 0; // MSB of lentgh int numQantBytes = 64; // Two 64 byte tables RtpBuf[27] = 2 * numQantBytes; // LSB of length headerLen += 4; memcpy(RtpBuf + headerLen, quant0tbl, numQantBytes); headerLen += numQantBytes; memcpy(RtpBuf + headerLen, quant1tbl, numQantBytes); headerLen += numQantBytes; } // printf("Sending timestamp %d, seq %d, fragoff %d, fraglen %d, jpegLen %d\n", m_Timestamp, m_SequenceNumber, fragmentOffset, fragmentLen, jpegLen); // append the JPEG scan data to the RTP buffer memcpy(RtpBuf + headerLen,jpeg + fragmentOffset, fragmentLen); fragmentOffset += fragmentLen; m_SequenceNumber++; // prepare the packet counter for the next packet IPADDRESS otherip; IPPORT otherport; socketpeeraddr(m_Client, &otherip, &otherport); // RTP marker bit must be set on last fragment if (m_TCPTransport) // RTP over RTSP - we send the buffer + 4 byte additional header socketsend(m_Client,RtpBuf,RtpPacketSize + 4); else // UDP - we send just the buffer by skipping the 4 byte RTP over RTSP header udpsocketsend(m_RtpSocket,&RtpBuf[4],RtpPacketSize, otherip, m_RtpClientPort); return isLastFragment ? 0 : fragmentOffset; }; void CStreamer::InitTransport(u_short aRtpPort, u_short aRtcpPort, bool TCP) { m_RtpClientPort = aRtpPort; m_RtcpClientPort = aRtcpPort; m_TCPTransport = TCP; if (!m_TCPTransport) { // allocate port pairs for RTP/RTCP ports in UDP transport mode for (u_short P = 6970; P < 0xFFFE; P += 2) { m_RtpSocket = udpsocketcreate(P); if (m_RtpSocket) { // Rtp socket was bound successfully. Lets try to bind the consecutive Rtsp socket m_RtcpSocket = udpsocketcreate(P + 1); if (m_RtcpSocket) { m_RtpServerPort = P; m_RtcpServerPort = P+1; break; } else { udpsocketclose(m_RtpSocket); udpsocketclose(m_RtcpSocket); }; } }; }; }; u_short CStreamer::GetRtpServerPort() { return m_RtpServerPort; }; u_short CStreamer::GetRtcpServerPort() { return m_RtcpServerPort; }; void CStreamer::streamFrame(unsigned const char *data, uint32_t dataLen, uint32_t curMsec) { if(m_prevMsec == 0) // first frame init our timestamp m_prevMsec = curMsec; // compute deltat (being careful to handle clock rollover with a little lie) uint32_t deltams = (curMsec >= m_prevMsec) ? curMsec - m_prevMsec : 100; m_prevMsec = curMsec; // locate quant tables if possible BufPtr qtable0, qtable1; if (!decodeJPEGfile(&data, &dataLen, &qtable0, &qtable1)) { #ifdef STREAM_DEBUG printf("can't decode jpeg data\n"); #endif return; } int offset = 0; do { offset = SendRtpPacket(data, dataLen, offset, qtable0, qtable1); } while(offset != 0); // Increment ONLY after a full frame uint32_t units = 90000; // Hz per RFC 2435 m_Timestamp += (units * deltams / 1000); // fixed timestamp increment for a frame rate of 25fps m_SendIdx++; if (m_SendIdx > 1) m_SendIdx = 0; #ifdef STREAM_DEBUG printf("frame sent\n"); #endif }; #include // search for a particular JPEG marker, moves *start to just after that marker // This function fixes up the provided start ptr to point to the // actual JPEG stream data and returns the number of bytes skipped // APP0 e0 // DQT db // DQT db // DHT c4 // DHT c4 // DHT c4 // DHT c4 // SOF0 c0 baseline (not progressive) 3 color 0x01 Y, 0x21 2h1v, 0x00 tbl0 // - 0x02 Cb, 0x11 1h1v, 0x01 tbl1 - 0x03 Cr, 0x11 1h1v, 0x01 tbl1 // therefore 4:2:2, with two separate quant tables (0 and 1) // SOS da // EOI d9 (no need to strip data after this RFC says client will discard) bool findJPEGheader(BufPtr *start, uint32_t *len, uint8_t marker) { // per https://en.wikipedia.org/wiki/JPEG_File_Interchange_Format unsigned const char *bytes = *start; // kinda skanky, will break if unlucky and the headers inxlucde 0xffda // might fall off array if jpeg is invalid // FIXME - return false instead while(bytes - *start < *len) { uint8_t framing = *bytes++; // better be 0xff if(framing != 0xff) { printf("malformed jpeg, framing=%x\n", framing); return false; } uint8_t typecode = *bytes++; if(typecode == marker) { unsigned skipped = bytes - *start; //printf("found marker 0x%x, skipped %d\n", marker, skipped); *start = bytes; // shrink len for the bytes we just skipped *len -= skipped; return true; } else { // not the section we were looking for, skip the entire section switch(typecode) { case 0xd8: // start of image { break; // no data to skip } case 0xe0: // app0 case 0xdb: // dqt case 0xc4: // dht case 0xc0: // sof0 case 0xda: // sos { // standard format section with 2 bytes for len. skip that many bytes uint32_t len = bytes[0] * 256 + bytes[1]; //printf("skipping section 0x%x, %d bytes\n", typecode, len); bytes += len; break; } default: printf("unexpected jpeg typecode 0x%x\n", typecode); break; } } } printf("failed to find jpeg marker 0x%x", marker); return false; } // the scan data uses byte stuffing to guarantee anything that starts with 0xff // followed by something not zero, is a new section. Look for that marker and return the ptr // pointing there void skipScanBytes(BufPtr *start) { BufPtr bytes = *start; while(true) { // FIXME, check against length while(*bytes++ != 0xff); if(*bytes++ != 0) { *start = bytes - 2; // back up to the 0xff marker we just found return; } } } void nextJpegBlock(BufPtr *bytes) { uint32_t len = (*bytes)[0] * 256 + (*bytes)[1]; //printf("going to next jpeg block %d bytes\n", len); *bytes += len; } // When JPEG is stored as a file it is wrapped in a container // This function fixes up the provided start ptr to point to the // actual JPEG stream data and returns the number of bytes skipped bool decodeJPEGfile(BufPtr *start, uint32_t *len, BufPtr *qtable0, BufPtr *qtable1) { // per https://en.wikipedia.org/wiki/JPEG_File_Interchange_Format unsigned const char *bytes = *start; if(!findJPEGheader(&bytes, len, 0xd8)) // better at least look like a jpeg file return false; // FAILED! // Look for quant tables if they are present *qtable0 = NULL; *qtable1 = NULL; BufPtr quantstart = *start; uint32_t quantlen = *len; if(!findJPEGheader(&quantstart, &quantlen, 0xdb)) { printf("error can't find quant table 0\n"); } else { // printf("found quant table %x\n", quantstart[2]); *qtable0 = quantstart + 3; // 3 bytes of header skipped nextJpegBlock(&quantstart); if(!findJPEGheader(&quantstart, &quantlen, 0xdb)) { printf("error can't find quant table 1\n"); } else { // printf("found quant table %x\n", quantstart[2]); } *qtable1 = quantstart + 3; nextJpegBlock(&quantstart); } if(!findJPEGheader(start, len, 0xda)) return false; // FAILED! // Skip the header bytes of the SOS marker FIXME why doesn't this work? uint32_t soslen = (*start)[0] * 256 + (*start)[1]; *start += soslen; *len -= soslen; // start scanning the data portion of the scan to find the end marker BufPtr endmarkerptr = *start; uint32_t endlen = *len; skipScanBytes(&endmarkerptr); if(!findJPEGheader(&endmarkerptr, &endlen, 0xd9)) return false; // FAILED! // endlen must now be the # of bytes between the start of our scan and // the end marker, tell the caller to ignore bytes afterwards *len = endmarkerptr - *start; return true; }