/* NAME senders.go DESCRIPTION See Readme.md AUTHORS Saxon A. Nelson-Milton Alan Noble LICENSE revid 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 revid import ( "errors" "fmt" "io" "net" "os" "sync" "time" "github.com/Comcast/gots/packet" "bitbucket.org/ausocean/av/container/mts" "bitbucket.org/ausocean/av/protocol/rtmp" "bitbucket.org/ausocean/av/protocol/rtp" "bitbucket.org/ausocean/iot/pi/netsender" "bitbucket.org/ausocean/utils/logger" "bitbucket.org/ausocean/utils/ring" ) // Log is used by the multiSender. type Log func(level int8, message string, params ...interface{}) // Sender ring buffer read timeouts. const ( rtmpRBReadTimeout = 1 * time.Second mtsRBReadTimeout = 1 * time.Second maxBuffLen = 50000000 ) var ( adjustedRTMPRBElementSize int adjustedMTSRBElementSize int ) // httpSender provides an implemntation of io.Writer to perform sends to a http // destination. type httpSender struct { client *netsender.Sender log func(lvl int8, msg string, args ...interface{}) report func(sent int) } // newHttpSender returns a pointer to a new httpSender. func newHTTPSender(ns *netsender.Sender, log func(lvl int8, msg string, args ...interface{}), report func(sent int)) *httpSender { return &httpSender{ client: ns, log: log, report: report, } } // Write implements io.Writer. func (s *httpSender) Write(d []byte) (int, error) { s.log(logger.Debug, "HTTP sending") err := httpSend(d, s.client, s.log) if err == nil { s.log(logger.Debug, "good send", "len", len(d)) s.report(len(d)) } else { s.log(logger.Debug, "bad send", "error", err) } return len(d), err } func (s *httpSender) Close() error { return nil } func httpSend(d []byte, client *netsender.Sender, log func(lvl int8, msg string, args ...interface{})) error { // Only send if "V0" is configured as an input. send := false ip := client.Param("ip") log(logger.Debug, "making pins, and sending recv request", "ip", ip) pins := netsender.MakePins(ip, "V") for i, pin := range pins { if pin.Name == "V0" { send = true pins[i].Value = len(d) pins[i].Data = d pins[i].MimeType = "video/mp2t" break } } if !send { return nil } var err error var reply string reply, _, err = client.Send(netsender.RequestRecv, pins) if err != nil { return err } log(logger.Debug, "good request", "reply", reply) return extractMeta(reply, log) } // extractMeta looks at a reply at extracts any time or location data - then used // to update time and location information in the mpegts encoder. func extractMeta(r string, log func(lvl int8, msg string, args ...interface{})) error { dec, err := netsender.NewJSONDecoder(r) if err != nil { return nil } // Extract time from reply t, err := dec.Int("ts") if err != nil { log(logger.Warning, "No timestamp in reply") } else { log(logger.Debug, fmt.Sprintf("got timestamp: %v", t)) mts.RealTime.Set(time.Unix(int64(t), 0)) } // Extract location from reply g, err := dec.String("ll") if err != nil { log(logger.Debug, "No location in reply") } else { log(logger.Debug, fmt.Sprintf("got location: %v", g)) mts.Meta.Add("loc", g) } return nil } // fileSender implements loadSender for a local file destination. type fileSender struct { file *os.File data []byte } func newFileSender(path string) (*fileSender, error) { f, err := os.Create(path) if err != nil { return nil, err } return &fileSender{file: f}, nil } // Write implements io.Writer. func (s *fileSender) Write(d []byte) (int, error) { return s.file.Write(d) } func (s *fileSender) Close() error { return s.file.Close() } // mtsSender implements io.WriteCloser and provides sending capability specifically // for use with MPEGTS packetization. It handles the construction of appropriately // lengthed clips based on clip duration and PSI. It also accounts for // discontinuities by setting the discontinuity indicator for the first packet of a clip. type mtsSender struct { dst io.WriteCloser buf []byte ring *ring.Buffer next []byte pkt packet.Packet repairer *mts.DiscontinuityRepairer curPid int clipDur time.Duration prev time.Time done chan struct{} log func(lvl int8, msg string, args ...interface{}) wg sync.WaitGroup } // newMtsSender returns a new mtsSender. func newMTSSender(dst io.WriteCloser, log func(lvl int8, msg string, args ...interface{}), rb *ring.Buffer, clipDur time.Duration) *mtsSender { s := &mtsSender{ dst: dst, repairer: mts.NewDiscontinuityRepairer(), log: log, ring: rb, done: make(chan struct{}), clipDur: clipDur, } s.wg.Add(1) go s.output() return s } // output starts an mtsSender's data handling routine. func (s *mtsSender) output() { var chunk *ring.Chunk for { select { case <-s.done: s.log(logger.Info, "terminating sender output routine") defer s.wg.Done() return default: // If chunk is nil then we're ready to get another from the ringBuffer. if chunk == nil { var err error chunk, err = s.ring.Next(mtsRBReadTimeout) switch err { case nil, io.EOF: continue case ring.ErrTimeout: s.log(logger.Debug, "mtsSender: ring buffer read timeout") continue default: s.log(logger.Error, "unexpected error", "error", err.Error()) continue } } err := s.repairer.Repair(chunk.Bytes()) if err != nil { chunk.Close() chunk = nil continue } s.log(logger.Debug, "mtsSender: writing") _, err = s.dst.Write(chunk.Bytes()) if err != nil { s.log(logger.Debug, "failed write, repairing MTS", "error", err) s.repairer.Failed() continue } else { s.log(logger.Debug, "good write") } chunk.Close() chunk = nil } } } // Write implements io.Writer. func (s *mtsSender) Write(d []byte) (int, error) { if len(d) < mts.PacketSize { return 0, errors.New("do not have full MTS packet") } if s.next != nil { s.buf = append(s.buf, s.next...) } bytes := make([]byte, len(d)) copy(bytes, d) s.next = bytes p, _ := mts.PID(bytes) s.curPid = int(p) if time.Now().Sub(s.prev) >= s.clipDur && s.curPid == mts.PatPid && len(s.buf) > 0 { s.prev = time.Now() n, err := s.ring.Write(s.buf) if err == nil { s.ring.Flush() } if err != nil { s.log(logger.Warning, "ringBuffer write error", "error", err.Error(), "n", n, "size", len(s.buf)) if err == ring.ErrTooLong { adjustedMTSRBElementSize = len(d) * 2 numElements := maxBuffLen / adjustedMTSRBElementSize s.ring = ring.NewBuffer(maxBuffLen/adjustedMTSRBElementSize, adjustedMTSRBElementSize, 5*time.Second) s.log(logger.Info, "adjusted MTS ring buffer element size", "new size", adjustedMTSRBElementSize, "num elements", numElements, "size(MB)", numElements*adjustedMTSRBElementSize) } } s.buf = s.buf[:0] } return len(d), nil } // Close implements io.Closer. func (s *mtsSender) Close() error { s.log(logger.Debug, "closing sender output routine") close(s.done) s.wg.Wait() s.log(logger.Info, "sender output routine closed") return nil } // rtmpSender implements loadSender for a native RTMP destination. type rtmpSender struct { conn *rtmp.Conn url string timeout uint retries int log func(lvl int8, msg string, args ...interface{}) ring *ring.Buffer done chan struct{} wg sync.WaitGroup report func(sent int) } func newRtmpSender(url string, timeout uint, retries int, rb *ring.Buffer, log func(lvl int8, msg string, args ...interface{}), report func(sent int)) (*rtmpSender, error) { var conn *rtmp.Conn var err error for n := 0; n < retries; n++ { conn, err = rtmp.Dial(url, timeout, log) if err == nil { break } log(logger.Error, "dial error", "error", err) if n < retries-1 { log(logger.Info, "retrying dial") } } s := &rtmpSender{ conn: conn, url: url, timeout: timeout, retries: retries, log: log, ring: rb, done: make(chan struct{}), report: report, } s.wg.Add(1) go s.output() return s, err } // output starts an mtsSender's data handling routine. func (s *rtmpSender) output() { var chunk *ring.Chunk for { select { case <-s.done: s.log(logger.Info, "terminating sender output routine") defer s.wg.Done() return default: // If chunk is nil then we're ready to get another from the ring buffer. if chunk == nil { var err error chunk, err = s.ring.Next(rtmpRBReadTimeout) switch err { case nil, io.EOF: continue case ring.ErrTimeout: s.log(logger.Debug, "rtmpSender: ring buffer read timeout") continue default: s.log(logger.Error, "unexpected error", "error", err.Error()) continue } } if s.conn == nil { s.log(logger.Warning, "no rtmp connection, re-dialing") err := s.restart() if err != nil { s.log(logger.Warning, "could not restart connection", "error", err) continue } } _, err := s.conn.Write(chunk.Bytes()) switch err { case nil, rtmp.ErrInvalidFlvTag: s.log(logger.Debug, "good write to conn") default: s.log(logger.Warning, "send error, re-dialing", "error", err) err = s.restart() if err != nil { s.log(logger.Warning, "could not restart connection", "error", err) } continue } chunk.Close() chunk = nil } } } // Write implements io.Writer. func (s *rtmpSender) Write(d []byte) (int, error) { s.log(logger.Debug, "writing to ring buffer") _, err := s.ring.Write(d) if err == nil { s.ring.Flush() s.log(logger.Debug, "good ring buffer write", "len", len(d)) } else { s.log(logger.Warning, "ring buffer write error", "error", err.Error()) if err == ring.ErrTooLong { adjustedRTMPRBElementSize = len(d) * 2 numElements := maxBuffLen / adjustedRTMPRBElementSize s.ring = ring.NewBuffer(numElements, adjustedRTMPRBElementSize, 5*time.Second) s.log(logger.Info, "adjusted RTMP ring buffer element size", "new size", adjustedRTMPRBElementSize, "num elements", numElements, "size(MB)", numElements*adjustedRTMPRBElementSize) } } s.report(len(d)) return len(d), nil } func (s *rtmpSender) restart() error { s.close() var err error for n := 0; n < s.retries; n++ { s.log(logger.Debug, "dialing", "dials", n) s.conn, err = rtmp.Dial(s.url, s.timeout, s.log) if err == nil { break } s.log(logger.Error, "dial error", "error", err) if n < s.retries-1 { s.log(logger.Info, "retry rtmp connection") } } return err } func (s *rtmpSender) Close() error { s.log(logger.Debug, "closing output routine") if s.done != nil { close(s.done) } s.wg.Wait() s.log(logger.Info, "output routine closed") return s.close() } func (s *rtmpSender) close() error { s.log(logger.Debug, "closing connection") if s.conn == nil { return nil } return s.conn.Close() } // TODO: Write restart func for rtpSender // rtpSender implements loadSender for a native udp destination with rtp packetization. type rtpSender struct { log func(lvl int8, msg string, args ...interface{}) encoder *rtp.Encoder data []byte report func(sent int) } func newRtpSender(addr string, log func(lvl int8, msg string, args ...interface{}), fps uint, report func(sent int)) (*rtpSender, error) { conn, err := net.Dial("udp", addr) if err != nil { return nil, err } s := &rtpSender{ log: log, encoder: rtp.NewEncoder(conn, int(fps)), report: report, } return s, nil } // Write implements io.Writer. func (s *rtpSender) Write(d []byte) (int, error) { s.data = make([]byte, len(d)) copy(s.data, d) _, err := s.encoder.Write(s.data) if err != nil { s.log(logger.Warning, "rtpSender: write error", err.Error()) } s.report(len(d)) return len(d), nil } func (s *rtpSender) Close() error { return nil }