av/generator/MPEGTSGenerator.go

218 lines
5.9 KiB
Go

/*
NAME
MPEGTSGenerator.go
DESCRIPTION
See Readme.md
AUTHOR
Saxon Nelson-Milton <saxon@ausocean.org>
LICENSE
MPEGTSGenerator.go is Copyright (C) 2017 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 [GNU licenses](http://www.gnu.org/licenses).
*/
package generator
import (
"bitbucket.org/ausocean/av/mpegts"
"bitbucket.org/ausocean/av/pes"
/*
"../mpegts"
"../pes"
*/)
const mpegtsPacketSize = 184
// TODO: really need to finish the at and pmt stuff - this is too hacky
var (
patTableStart = []byte{0, 0, 176, 13, 0, 1, 193, 0, 0, 0, 1, 240, 0, 42, 177, 4, 178}
patTable []byte
pmtTableStart = []byte{0, 2, 176, 18, 0, 1, 193, 0, 0, 0xE1, 0x00, 0xF0, 0, 0x1B, 0xE1, 0, 0xF0, 0, 0x15, 0xBD, 0x4D, 0x56}
pmtTable []byte
)
// genPatAndPmt generates the rest of the pat and pmt tables i.e. fills them
// with 0xFFs - because it looks ugly to hardcode above. This is called through
// NewMpegtsgenerator
func genPatAndPmt() {
patTable = make([]byte, 0, mpegtsPacketSize)
patTable = append(patTable, patTableStart...)
for i := len(pmtTableStart); i < mpegtsPacketSize - len(pmtTableStart); i++ {
pmtTable[i] = 255
}
pmtTable = make([]byte, 0, mpegtsPacketSize)
pmtTable = append(pmtTable, pmtTableStart...)
for i := len(patTableStart); i < mpegtsPacketSize - len(patTableStart); i++ {
pmtTable[i] = 255
}
}
const (
SdtPid = 17
PatPid = 0
pmtPid = 4096
videoPid = 256
streamID = 0xE0
outputChanSize = 100
inputChanSize = 10000
pesPktChanSize = 1000
payloadByteChanSize = 100000
ptsOffset = .7
maxCC = 15
)
// tsGenerator encapsulates properties of an mpegts generator.
type tsGenerator struct {
outputChan chan []byte
nalInputChan chan []byte
currentTsPacket *mpegts.MpegTsPacket
payloadByteChan chan byte
currentCC byte
currentPtsTime float64
currentPcrTime float64
fps uint
pesPktChan chan []byte
ccMap map[int]int
isGenerating bool
}
// getInputChan returns a handle to the nalInputChan (inputChan) so that nal units
// can be passed to the generator and processed
func (g *tsGenerator) GetInputChan() chan []byte {
return g.nalInputChan
}
// GetOutputChan returns a handle to the generator output chan where the mpegts
// packets will show up once ready to go
func (g *tsGenerator) GetOutputChan() chan []byte {
return g.outputChan
}
// NewTsGenerator returns an instance of the tsGenerator struct
func NewTsGenerator(fps uint) (g *tsGenerator) {
g = new(tsGenerator)
g.outputChan = make(chan []byte, outputChanSize)
g.nalInputChan = make(chan []byte, inputChanSize)
g.currentCC = 0
g.fps = fps
g.currentPcrTime = 0.0
g.currentPtsTime = ptsOffset
g.pesPktChan = make(chan []byte, pesPktChanSize)
g.payloadByteChan = make(chan byte, payloadByteChanSize)
g.ccMap = make(map[int]int, 4)
g.ccMap[SdtPid] = 0
g.ccMap[PatPid] = 0
g.ccMap[pmtPid] = 0
g.ccMap[videoPid] = 0
genPatAndPmt()
g.isGenerating = false
return
}
// getPts retuns the next presentation timestamp for the tsGenerator t.
func (g *tsGenerator) genPts() (pts uint64) {
pts = uint64(g.currentPtsTime * float64(90000))
g.currentPtsTime += 1.0 / float64(g.fps)
return
}
// genPcr returns the next program clock reference for the tsGenerator g
func (g *tsGenerator) genPcr() (pcr uint64) {
pcr = uint64(g.currentPcrTime * float64(90000))
g.currentPcrTime += 1.0 / float64(g.fps)
return
}
// Start is called when we would like generation to begin, i.e. we would like
// the generator to start taking input data and creating mpegts packets
func (g *tsGenerator) Start() {
g.isGenerating = true
go g.generate()
}
func (g *tsGenerator) Stop() {
g.isGenerating = false
}
// getCC returns the next continuity counter for a particular pid
func (g *tsGenerator) getCC(pid int) int {
temp := g.ccMap[pid]
if g.ccMap[pid]++; g.ccMap[pid] > maxCC {
g.ccMap[pid] = 0
}
return temp
}
// generate handles the incoming data and generates equivalent mpegts packets -
// sending them to the output channel
func (g *tsGenerator) generate() {
for {
select {
case nalUnit := <-g.nalInputChan:
pesPkt := pes.PESPacket{
StreamID: streamID,
PDI: byte(2),
PTS: g.genPts(),
Data: nalUnit,
HeaderLength: 5,
}
g.pesPktChan <- pesPkt.ToByteSlice()
case pesPkt := <-g.pesPktChan:
for ii := range pesPkt {
g.payloadByteChan <- pesPkt[ii]
}
pusi := true
for len(g.payloadByteChan) > 0 {
pkt := mpegts.MpegTsPacket{
PUSI: pusi,
PID: videoPid,
RAI: pusi,
CC: byte(g.getCC(videoPid)),
AFC: byte(3),
PCRF: pusi,
}
pkt.FillPayload(g.payloadByteChan)
// TODO: create consts for AFC parameters
if pusi {
// Create pat table
patPkt := mpegts.MpegTsPacket{
PUSI: pusi,
PID: PatPid,
CC: byte(g.getCC(PatPid)),
AFC: 1,
Payload: patTable,
}
g.outputChan <- patPkt.ToByteSlice()
// Create pmt table
pmtPkt := mpegts.MpegTsPacket{
PUSI: pusi,
PID: pmtPid,
CC: byte(g.getCC(pmtPid)),
AFC: 1,
Payload: pmtTable,
}
g.outputChan <- pmtPkt.ToByteSlice()
// If pusi then we need to gen a pcr
pkt.PCR = g.genPcr()
pusi = false
}
g.outputChan <- pkt.ToByteSlice()
}
}
}
}