refactor frame handling

2026-01-15 01:11:16 +01:00
parent 0d035e5bce
commit dbd04cb972
1 changed files with 203 additions and 96 deletions
@@ -2,6 +2,7 @@ package tutk
 import (
 	"encoding/binary"
 	"encoding/hex"
 	"fmt"
 	"github.com/AlexxIT/go2rtc/pkg/aac"
@@ -23,29 +24,48 @@ const (
 	ChannelPVideo uint8 = 0x07
 )
 // Resolution constants
 const (
-	ResolutionUnknown = 0
+	ResTierLow  uint8 = 1 // 360P/SD
-	ResolutionSD      = 1
+	ResTierHigh uint8 = 4 // HD/2K
-	Resolution360P    = 2
+)
-	Resolution2K      = 4
+
 const (
 	Bitrate360P uint8 = 30
 	BitrateHD   uint8 = 100
 	Bitrate2K   uint8 = 200
 )
 const FrameInfoSize = 40
 // FrameInfo - Wyze extended FRAMEINFO (40 bytes at end of packet)
 // Video: 40 bytes, Audio: 16 bytes (uses same struct, fields 16+ are zero)
 //
 // Offset  Size  Field
 // 0-1     2     CodecID     - 0x4E=H264, 0x7B=H265, 0x90=AAC_WYZE
 // 2       1     Flags       - Video: 1=Keyframe, 0=P-frame | Audio: sample rate/bits/channels
 // 3       1     CamIndex    - Camera index
 // 4       1     OnlineNum   - Online number
 // 5       1     FPS         - Framerate (e.g. 20)
 // 6       1     ResTier     - Video: 1=Low(360P), 4=High(HD/2K) | Audio: 0
 // 7       1     Bitrate     - Video: 30=360P, 100=HD, 200=2K | Audio: 1
 // 8-11    4     Timestamp   - Timestamp (increases ~50000/frame for 20fps video)
 // 12-15   4     SessionID   - Session marker (constant per stream)
 // 16-19   4     PayloadSize - Frame payload size in bytes
 // 20-23   4     FrameNo     - Global frame number
 // 24-35   12    DeviceID    - MAC address (ASCII) - video only
 // 36-39   4     Padding     - Always 0 - video only
 type FrameInfo struct {
-	CodecID     uint16
+	CodecID     uint16 // 0-1
-	Flags       uint8
+	Flags       uint8  // 2
-	CamIndex    uint8
+	CamIndex    uint8  // 3
-	OnlineNum   uint8
+	OnlineNum   uint8  // 4
-	Framerate   uint8
+	FPS         uint8  // 5: Framerate
-	FrameSize   uint8
+	ResTier     uint8  // 6: Resolution tier (1=Low, 4=High)
-	Bitrate     uint8
+	Bitrate     uint8  // 7: Bitrate index (30=360P, 100=HD, 200=2K)
-	TimestampUS uint32
+	Timestamp   uint32 // 8-11: Timestamp
-	Timestamp   uint32
+	SessionID   uint32 // 12-15: Session marker (constant)
-	PayloadSize uint32
+	PayloadSize uint32 // 16-19: Payload size
-	FrameNo     uint32
+	FrameNo     uint32 // 20-23: Frame number
 }
 func (fi *FrameInfo) IsKeyframe() bool {
@@ -53,12 +73,12 @@ func (fi *FrameInfo) IsKeyframe() bool {
 }
 func (fi *FrameInfo) Resolution() string {
-	switch fi.FrameSize {
+	switch fi.Bitrate {
-	case ResolutionSD:
+	case Bitrate360P:
 		return "SD"
 	case Resolution360P:
 		return "360P"
-	case Resolution2K:
+	case BitrateHD:
 		return "HD"
 	case Bitrate2K:
 		return "2K"
 	default:
 		return "unknown"
@@ -98,11 +118,11 @@ func ParseFrameInfo(data []byte) *FrameInfo {
 		Flags:       fi[2],
 		CamIndex:    fi[3],
 		OnlineNum:   fi[4],
-		Framerate:   fi[5],
+		FPS:         fi[5],
-		FrameSize:   fi[6],
+		ResTier:     fi[6],
 		Bitrate:     fi[7],
-		TimestampUS: binary.LittleEndian.Uint32(fi[8:]),
+		Timestamp:   binary.LittleEndian.Uint32(fi[8:]),
-		Timestamp:   binary.LittleEndian.Uint32(fi[12:]),
+		SessionID:   binary.LittleEndian.Uint32(fi[12:]),
 		PayloadSize: binary.LittleEndian.Uint32(fi[16:]),
 		FrameNo:     binary.LittleEndian.Uint32(fi[20:]),
 	}
@@ -166,7 +186,7 @@ func ParsePacketHeader(data []byte) *PacketHeader {
 		hdr.PayloadSize = binary.LittleEndian.Uint16(data[16:])
 		hdr.FrameNo = binary.LittleEndian.Uint32(data[24:])
-		if IsEndFrame(frameType) && pktIdxOrMarker == 0x0028 {
+		if pktIdxOrMarker == 0x0028 && (IsEndFrame(frameType) || hdr.PktTotal == 1) {
 			hdr.HasFrameInfo = true
 			if hdr.PktTotal > 0 {
 				hdr.PktIdx = hdr.PktTotal - 1
@@ -180,7 +200,7 @@ func ParsePacketHeader(data []byte) *PacketHeader {
 		hdr.PayloadSize = binary.LittleEndian.Uint16(data[24:])
 		hdr.FrameNo = binary.LittleEndian.Uint32(data[32:])
-		if IsEndFrame(frameType) && pktIdxOrMarker == 0x0028 {
+		if pktIdxOrMarker == 0x0028 && (IsEndFrame(frameType) || hdr.PktTotal == 1) {
 			hdr.HasFrameInfo = true
 			if hdr.PktTotal > 0 {
 				hdr.PktIdx = hdr.PktTotal - 1
@@ -207,11 +227,24 @@ func IsContinuationFrame(frameType uint8) bool {
 	return frameType == FrameTypeCont || frameType == FrameTypeContAlt
 }
-type FrameAssembler struct {
+type channelState struct {
-	FrameNo   uint32
+	frameNo    uint32     // current frame being assembled
-	PktTotal  uint16
+	pktTotal   uint16     // expected total packets
-	Packets   map[uint16][]byte
+	waitSeq    uint16     // next expected packet index (0, 1, 2, ...)
-	FrameInfo *FrameInfo
+	waitData   []byte     // accumulated payload data
 	frameInfo  *FrameInfo // frame info (from end packet)
 	hasStarted bool       // received first packet of frame
 	lastPktIdx uint16     // last received packet index (for OOO detection)
 }
 func (cs *channelState) reset() {
 	cs.frameNo = 0
 	cs.pktTotal = 0
 	cs.waitSeq = 0
 	cs.waitData = cs.waitData[:0]
 	cs.frameInfo = nil
 	cs.hasStarted = false
 	cs.lastPktIdx = 0
 }
 func ParseAudioParams(payload []byte, fi *FrameInfo) (sampleRate uint32, channels uint8) {
@@ -229,18 +262,22 @@ func ParseAudioParams(payload []byte, fi *FrameInfo) (sampleRate uint32, channel
 	return 16000, 1
 }
 const tsWrapPeriod uint32 = 1000000
 type FrameHandler struct {
-	assemblers map[byte]*FrameAssembler
+	channels  map[byte]*channelState
-	baseTS     uint64
+	lastRawTS uint32
-	output     chan *Packet
+	accumUS   uint64
-	verbose    bool
+	firstTS   bool
 	output    chan *Packet
 	verbose   bool
 }
 func NewFrameHandler(verbose bool) *FrameHandler {
 	return &FrameHandler{
-		assemblers: make(map[byte]*FrameAssembler),
+		channels: make(map[byte]*channelState),
-		output:     make(chan *Packet, 128),
+		output:   make(chan *Packet, 128),
-		verbose:    verbose,
+		verbose:  verbose,
 	}
 }
@@ -252,6 +289,27 @@ func (h *FrameHandler) Close() {
 	close(h.output)
 }
 func (h *FrameHandler) updateTimestamp(rawTS uint32) uint64 {
 	if !h.firstTS {
 		h.firstTS = true
 		h.lastRawTS = rawTS
 		return 0
 	}
 	var delta uint32
 	if rawTS >= h.lastRawTS {
 		delta = rawTS - h.lastRawTS
 	} else {
 		// Wrapped: delta = (wrap - last) + new
 		delta = (tsWrapPeriod - h.lastRawTS) + rawTS
 	}
 	h.accumUS += uint64(delta)
 	h.lastRawTS = rawTS
 	return h.accumUS
 }
 func (h *FrameHandler) Handle(data []byte) {
 	hdr := ParsePacketHeader(data)
 	if hdr == nil {
@@ -263,6 +321,16 @@ func (h *FrameHandler) Handle(data []byte) {
 		return
 	}
 	if h.verbose {
 		fiStr := ""
 		if hdr.HasFrameInfo {
 			fiStr = " +FI"
 		}
 		fmt.Printf("[RX] ch=0x%02x type=0x%02x #%d pkt=%d/%d data=%dB%s\n",
 			hdr.Channel, hdr.FrameType,
 			hdr.FrameNo, hdr.PktIdx, hdr.PktTotal, len(payload), fiStr)
 	}
 	switch hdr.Channel {
 	case ChannelAudio:
 		h.handleAudio(payload, fi)
@@ -335,71 +403,73 @@ func (h *FrameHandler) extractPayload(data []byte, channel byte) ([]byte, *Frame
 }
 func (h *FrameHandler) handleVideo(channel byte, hdr *PacketHeader, payload []byte, fi *FrameInfo) {
-	asm := h.assemblers[channel]
+	cs := h.channels[channel]
-
+	if cs == nil {
-	// Frame transition: new frame number = previous frame complete
+		cs = &channelState{}
-	if asm != nil && hdr.FrameNo != asm.FrameNo {
+		h.channels[channel] = cs
 		gotAll := uint16(len(asm.Packets)) == asm.PktTotal
 		if gotAll && asm.FrameInfo != nil {
 			h.assembleAndQueue(channel, asm)
 		}
 		asm = nil
 	}
-	// Create new assembler if needed
+	// New frame number - reset and start fresh
-	if asm == nil {
+	if hdr.FrameNo != cs.frameNo {
-		asm = &FrameAssembler{
+		// Check if previous frame was incomplete
-			FrameNo:  hdr.FrameNo,
+		if cs.hasStarted && cs.waitSeq < cs.pktTotal {
-			PktTotal: hdr.PktTotal,
+			fmt.Printf("[DROP] ch=0x%02x #%d INCOMPLETE: got %d/%d pkts\n",
-			Packets:  make(map[uint16][]byte, hdr.PktTotal),
+				channel, cs.frameNo, cs.waitSeq, cs.pktTotal)
 		}
-		h.assemblers[channel] = asm
+		cs.reset()
 		cs.frameNo = hdr.FrameNo
 		cs.pktTotal = hdr.PktTotal
 	}
-	// Store packet (copy payload - buffer is reused by worker)
+	// Sequential check: if packet index doesn't match expected, reset (data loss)
-	payloadCopy := make([]byte, len(payload))
+	if hdr.PktIdx != cs.waitSeq {
-	copy(payloadCopy, payload)
+		fmt.Printf("[OOO] ch=0x%02x #%d frameType=0x%02x pktTotal=%d expected pkt %d, got %d - reset\n",
-	asm.Packets[hdr.PktIdx] = payloadCopy
+			channel, hdr.FrameNo, hdr.FrameType, hdr.PktTotal, cs.waitSeq, hdr.PktIdx)
 		cs.reset()
 		return
 	}
 	// First packet - mark as started
 	if cs.waitSeq == 0 {
 		cs.hasStarted = true
 	}
 	// Append payload (simple sequential accumulation)
 	cs.waitData = append(cs.waitData, payload...)
 	cs.waitSeq++
 	// Store frame info if present
 	if fi != nil {
-		asm.FrameInfo = fi
+		cs.frameInfo = fi
 	}
 	// Check if frame is complete
-	if uint16(len(asm.Packets)) == asm.PktTotal && asm.FrameInfo != nil {
+	if cs.waitSeq == cs.pktTotal && cs.frameInfo != nil {
-		h.assembleAndQueue(channel, asm)
+		h.emitVideo(channel, cs)
-		delete(h.assemblers, channel)
+		cs.reset()
 	}
 }
-func (h *FrameHandler) assembleAndQueue(channel byte, asm *FrameAssembler) {
+func (h *FrameHandler) emitVideo(channel byte, cs *channelState) {
-	fi := asm.FrameInfo
+	fi := cs.frameInfo
 	// Assemble packets in correct order
 	var payload []byte
 	for i := uint16(0); i < asm.PktTotal; i++ {
 		if pkt, ok := asm.Packets[i]; ok {
 			payload = append(payload, pkt...)
 		}
 	}
 	// Size validation
-	if fi.PayloadSize > 0 && len(payload) != int(fi.PayloadSize) {
+	if fi.PayloadSize > 0 && uint32(len(cs.waitData)) != fi.PayloadSize {
 		fmt.Printf("[SIZE] ch=0x%02x #%d mismatch: expected %d, got %d\n",
 			channel, cs.frameNo, fi.PayloadSize, len(cs.waitData))
 		return
 	}
-	if len(payload) == 0 {
+	if len(cs.waitData) == 0 {
 		return
 	}
-	// Calculate RTP timestamp (90kHz for video) using relative timestamps
+	accumUS := h.updateTimestamp(fi.Timestamp)
-	absoluteTS := uint64(fi.Timestamp)*1000000 + uint64(fi.TimestampUS)
+	rtpTS := uint32(accumUS * 90000 / 1000000)
-	if h.baseTS == 0 {
+
-		h.baseTS = absoluteTS
+	// Copy payload (buffer will be reused)
-	}
+	payload := make([]byte, len(cs.waitData))
-	relativeUS := absoluteTS - h.baseTS
+	copy(payload, cs.waitData)
 	const clockRate uint64 = 90000
 	rtpTS := uint32(relativeUS * clockRate / 1000000)
 	pkt := &Packet{
 		Channel:    channel,
@@ -413,10 +483,18 @@ func (h *FrameHandler) assembleAndQueue(channel byte, asm *FrameAssembler) {
 	if h.verbose {
 		frameType := "P"
 		if fi.IsKeyframe() {
-			frameType = "I"
+			frameType = "KEY"
 		}
-		fmt.Printf("[VIDEO] #%d %s %s size=%d rtp=%d\n",
+		fmt.Printf("[OK] ch=0x%02x #%d %s %s size=%d\n",
-			fi.FrameNo, CodecName(fi.CodecID), frameType, len(payload), rtpTS)
+			channel, fi.FrameNo, CodecName(fi.CodecID), frameType, len(payload))
 		fmt.Printf("  [0-1]codec=0x%x(%s) [2]flags=0x%x [3]=%d [4]=%d\n",
 			fi.CodecID, CodecName(fi.CodecID), fi.Flags, fi.CamIndex, fi.OnlineNum)
 		fmt.Printf("  [5]=%d [6]=%d [7]=%d [8-11]ts=%d\n",
 			fi.FPS, fi.ResTier, fi.Bitrate, fi.Timestamp)
 		fmt.Printf("  [12-15]=0x%x [16-19]payload=%d [20-23]frameNo=%d\n",
 			fi.SessionID, fi.PayloadSize, fi.FrameNo)
 		fmt.Printf("  rtp_ts=%d accum_us=%d\n", rtpTS, accumUS)
 		fmt.Printf("  hex: %s\n", dumpHex(fi))
 	}
 	h.queue(pkt)
@@ -438,14 +516,8 @@ func (h *FrameHandler) handleAudio(payload []byte, fi *FrameInfo) {
 		channels = fi.Channels()
 	}
-	// Calculate RTP timestamp using relative timestamps (shared baseTS for A/V sync)
+	accumUS := h.updateTimestamp(fi.Timestamp)
-	absoluteTS := uint64(fi.Timestamp)*1000000 + uint64(fi.TimestampUS)
+	rtpTS := uint32(accumUS * uint64(sampleRate) / 1000000)
 	if h.baseTS == 0 {
 		h.baseTS = absoluteTS
 	}
 	relativeUS := absoluteTS - h.baseTS
 	clockRate := uint64(sampleRate)
 	rtpTS := uint32(relativeUS * clockRate / 1000000)
 	pkt := &Packet{
 		Channel:    ChannelAudio,
@@ -458,8 +530,17 @@ func (h *FrameHandler) handleAudio(payload []byte, fi *FrameInfo) {
 	}
 	if h.verbose {
-		fmt.Printf("[AUDIO] #%d %s size=%d rate=%d ch=%d rtp=%d\n",
+		bits := 8
-			fi.FrameNo, AudioCodecName(fi.CodecID), len(payload), sampleRate, channels, rtpTS)
+		if fi.Flags&0x02 != 0 {
 			bits = 16
 		}
 		fmt.Printf("[OK] Audio #%d %s size=%d\n",
 			fi.FrameNo, AudioCodecName(fi.CodecID), len(payload))
 		fmt.Printf("  [0-1]codec=0x%x(%s) [2]flags=0x%x(%dHz/%dbit/%dch)\n",
 			fi.CodecID, AudioCodecName(fi.CodecID), fi.Flags, sampleRate, bits, channels)
 		fmt.Printf("  [8-11]ts=%d [12-15]=0x%x rtp_ts=%d\n",
 			fi.Timestamp, fi.SessionID, rtpTS)
 		fmt.Printf("  hex: %s\n", dumpHex(fi))
 	}
 	h.queue(pkt)
@@ -477,3 +558,29 @@ func (h *FrameHandler) queue(pkt *Packet) {
 		h.output <- pkt
 	}
 }
 func dumpHex(fi *FrameInfo) string {
 	b := make([]byte, FrameInfoSize)
 	binary.LittleEndian.PutUint16(b[0:], fi.CodecID)
 	b[2] = fi.Flags
 	b[3] = fi.CamIndex
 	b[4] = fi.OnlineNum
 	b[5] = fi.FPS
 	b[6] = fi.ResTier
 	b[7] = fi.Bitrate
 	binary.LittleEndian.PutUint32(b[8:], fi.Timestamp)
 	binary.LittleEndian.PutUint32(b[12:], fi.SessionID)
 	binary.LittleEndian.PutUint32(b[16:], fi.PayloadSize)
 	binary.LittleEndian.PutUint32(b[20:], fi.FrameNo)
 	// Bytes 24-39 are DeviceID and Padding (not stored in struct)
 	hexStr := hex.EncodeToString(b)
 	formatted := ""
 	for i := 0; i < len(hexStr); i += 2 {
 		if i > 0 {
 			formatted += " "
 		}
 		formatted += hexStr[i : i+2]
 	}
 	return formatted
 }