/* NAME encoder.go DESCRIPTION See Readme.md AUTHOR Dan Kortschak Saxon Nelson-Milton LICENSE encoder.go is Copyright (C) 2017-2018 the Australian Ocean Lab (AusOcean) It is free software: you can redistribute it and/or modify them under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. It is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with revid in gpl.txt. If not, see http://www.gnu.org/licenses. */ package mts import ( "encoding/binary" "hash/crc32" "io" "math/bits" "time" "bitbucket.org/ausocean/av/stream/mts/pes" ) const ( psiPacketSize = 184 psiSendCount = 100 ) // TODO: really need to finish the at and pmt stuff - this is too hacky var ( patTable = []byte{ 0x00, // pointer // ---- section included in data sent to CRC32 during check // table header 0x00, // table id 0xb0, // section syntax indicator:1|private bit:1|reserved:2|section length:2|more bytes...:2 0x0d, // more bytes... // syntax section 0x00, 0x01, // table id extension 0xc1, // reserved bits:3|version:5|use now:1 0x00, // section number 0x00, // last section number // table data 0x00, 0x01, // Program number 0xf0, 0x00, // reserved:3|program map PID:13 // 0x2a, 0xb1, 0x04, 0xb2, // CRC // ---- } pmtTable = []byte{ 0x00, // pointer // ---- section included in data sent to CRC32 during check // table header 0x02, // table id 0xb0, // section syntax indicator:1|private bit:1|reserved:2|section length:2|more bytes...:2 0x12, // more bytes... // syntax section 0x00, 0x01, // table id extension 0xc1, // reserved bits:3|version:5|use now:1 0x00, // section number 0x00, // last section number // table data 0xe1, 0x00, // reserved:3|PCR PID:13 0xf0, 0x00, // reserved:4|unused:2|program info length:10 // No program descriptors since program info length is 0. // elementary stream info data 0x1b, // stream type 0xe1, 0x00, // reserved:3|elementary PID:13 0xf0, 0x00, // reserved:4|unused:2|ES info length:10 // No elementary stream descriptors since ES info length is 0. // 0x15, 0xbd, 0x4d, 0x56, // CRC // ---- } ) func init() { // Generate IEEE polynomial table // for the big-endian algorithm. crcTable := crc32_MakeTable(bits.Reverse32(crc32.IEEE)) patTable = completePSI(patTable, crcTable) pmtTable = completePSI(pmtTable, crcTable) } func completePSI(psi []byte, tab *crc32.Table) []byte { var buf [4]byte crc := crc32_Update(0xffffffff, tab, psi[1:]) binary.BigEndian.PutUint32(buf[:], crc) dst := make([]byte, len(psi), psiPacketSize) copy(dst, psi) dst = append(dst, buf[:]...) for len(dst) < cap(dst) { dst = append(dst, 0xff) } return dst } func crc32_MakeTable(poly uint32) *crc32.Table { var t crc32.Table for i := range t { crc := uint32(i) << 24 for j := 0; j < 8; j++ { if crc&0x80000000 != 0 { crc = (crc << 1) ^ poly } else { crc <<= 1 } } t[i] = crc } return &t } func crc32_Update(crc uint32, tab *crc32.Table, p []byte) uint32 { for _, v := range p { crc = tab[byte(crc>>24)^v] ^ (crc << 8) } return crc } const ( sdtPid = 17 patPid = 0 pmtPid = 4096 videoPid = 256 streamID = 0xe0 // First video stream ID. ) // Time related constants. const ( // ptsOffset is the offset added to the clock to determine // the current presentation timestamp, ptsOffset = 700 * time.Millisecond // pcrFreq is the base Program Clock Reference frequency. pcrFreq = 90000 // Hz ) // Encoder encapsulates properties of an mpegts generator. type Encoder struct { dst io.Writer clock time.Duration frameInterval time.Duration ptsOffset time.Duration psiCount uint continuity map[int]byte } // NewEncoder returns an Encoder with the specified frame rate. func NewEncoder(dst io.Writer, fps float64) *Encoder { return &Encoder{ dst: dst, frameInterval: time.Duration(float64(time.Second) / fps), ptsOffset: ptsOffset, continuity: map[int]byte{ patPid: 0, pmtPid: 0, videoPid: 0, }, } } const ( hasPayload = 0x1 hasAdaptationField = 0x2 ) const ( hasDTS = 0x1 hasPTS = 0x2 ) // generate handles the incoming data and generates equivalent mpegts packets - // sending them to the output channel func (e *Encoder) Encode(nalu []byte) error { if e.psiCount <= 0 { err := e.writePSI() if err != nil { return err } } e.psiCount -= 1 // Prepare PES data. pesPkt := pes.Packet{ StreamID: streamID, PDI: hasPTS, PTS: e.pts(), Data: nalu, HeaderLength: 5, } buf := pesPkt.Bytes() pusi := true for len(buf) != 0 { pkt := Packet{ PUSI: pusi, PID: videoPid, RAI: pusi, CC: e.ccFor(videoPid), AFC: hasAdaptationField | hasPayload, PCRF: pusi, } n := pkt.FillPayload(buf) buf = buf[n:] if pusi { // If the packet has a Payload Unit Start Indicator // flag set then we need to write a PCR. pkt.PCR = e.pcr() pusi = false } _, err := e.dst.Write(pkt.Bytes()) if err != nil { return err } } e.tick() return nil } func (e *Encoder) writePSI() error { // Write PAT patPkt := Packet{ PUSI: true, PID: patPid, CC: e.ccFor(patPid), AFC: hasPayload, Payload: patTable, } _, err := e.dst.Write(patPkt.Bytes()) if err != nil { return err } // Write PMT. pmtPkt := Packet{ PUSI: true, PID: pmtPid, CC: e.ccFor(pmtPid), AFC: hasPayload, Payload: pmtTable, } _, err = e.dst.Write(pmtPkt.Bytes()) if err != nil { return err } e.psiCount = psiSendCount return nil } // tick advances the clock one frame interval. func (e *Encoder) tick() { e.clock += e.frameInterval } // pts retuns the current presentation timestamp. func (e *Encoder) pts() uint64 { return uint64((e.clock + e.ptsOffset).Seconds() * pcrFreq) } // pcr returns the current program clock reference. func (e *Encoder) pcr() uint64 { return uint64(e.clock.Seconds() * pcrFreq) } // ccFor returns the next continuity counter for pid. func (e *Encoder) ccFor(pid int) byte { cc := e.continuity[pid] const continuityCounterMask = 0xf e.continuity[pid] = (cc + 1) & continuityCounterMask return cc }