Multi-port refactor #1
4 changed files with 151 additions and 189 deletions
27
main.go
27
main.go
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@ -61,7 +61,17 @@ const routingTableTemplate = `
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<td>{{if $route.Extended}}✅{{else}}❌{{end}}</td>
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<td>{{if $route.Extended}}✅{{else}}❌{{end}}</td>
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<td>{{$route.Distance}}</td>
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<td>{{$route.Distance}}</td>
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<td>{{$route.LastSeenAgo}}</td>
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<td>{{$route.LastSeenAgo}}</td>
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<td>{{if $route.AURPPeer}}{{$route.AURPPeer.RemoteAddr}}{{else if $route.EtherTalkPeer}}{{$route.EtherTalkPeer.PeerAddr.Network}}.{{$route.EtherTalkPeer.PeerAddr.Node}}{{else}}-{{end}}</td>
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<td>
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{{- with $route.AURPPeer -}}
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{{.RemoteAddr}}
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{{- end -}}
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{{- with $route.EtherTalkPeer -}}
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{{.Port.Device}} {{.PeerAddr.Network}}.{{.PeerAddr.Node}}
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{{- end -}}
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{{- with $route.EtherTalkDirect -}}
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{{.Device}} {{.NetStart}}-{{.NetEnd}}
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{{- end -}}
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</td>
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</tr>
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</tr>
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{{end}}
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{{end}}
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</tbody>
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</tbody>
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@ -330,16 +340,6 @@ func main() {
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aarpMachine := router.NewAARPMachine(cfg, pcapHandle, myHWAddr)
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aarpMachine := router.NewAARPMachine(cfg, pcapHandle, myHWAddr)
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go aarpMachine.Run(ctx)
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go aarpMachine.Run(ctx)
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// --------------------------------- RTMP ---------------------------------
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rtmpMachine := &router.RTMPMachine{
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AARPMachine: aarpMachine,
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Config: cfg,
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PcapHandle: pcapHandle,
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RoutingTable: routes,
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IncomingCh: make(chan *ddp.ExtPacket, 1024),
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}
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go rtmpMachine.Run(ctx)
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// -------------------------------- Router --------------------------------
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// -------------------------------- Router --------------------------------
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rooter := &router.Router{
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rooter := &router.Router{
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Config: cfg,
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Config: cfg,
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@ -348,6 +348,7 @@ func main() {
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}
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}
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etherTalkPort := &router.EtherTalkPort{
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etherTalkPort := &router.EtherTalkPort{
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Device: cfg.EtherTalk.Device,
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EthernetAddr: myHWAddr,
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EthernetAddr: myHWAddr,
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NetStart: cfg.EtherTalk.NetStart,
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NetStart: cfg.EtherTalk.NetStart,
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NetEnd: cfg.EtherTalk.NetEnd,
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NetEnd: cfg.EtherTalk.NetEnd,
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@ -355,7 +356,6 @@ func main() {
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AvailableZones: []string{cfg.EtherTalk.ZoneName},
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AvailableZones: []string{cfg.EtherTalk.ZoneName},
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PcapHandle: pcapHandle,
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PcapHandle: pcapHandle,
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AARPMachine: aarpMachine,
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AARPMachine: aarpMachine,
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RTMPMachine: rtmpMachine,
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Router: rooter,
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Router: rooter,
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}
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}
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rooter.Ports = append(rooter.Ports, etherTalkPort)
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rooter.Ports = append(rooter.Ports, etherTalkPort)
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@ -364,6 +364,9 @@ func main() {
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zones.Upsert(etherTalkPort.NetStart, az, etherTalkPort)
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zones.Upsert(etherTalkPort.NetStart, az, etherTalkPort)
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}
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}
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// --------------------------------- RTMP ---------------------------------
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go etherTalkPort.RunRTMP(ctx)
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// ---------------------- Raw AppleTalk/AARP inbound ----------------------
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// ---------------------- Raw AppleTalk/AARP inbound ----------------------
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wg.Add(1)
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wg.Add(1)
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go func() {
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go func() {
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@ -19,29 +19,25 @@ package router
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import (
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import (
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"context"
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"context"
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"github.com/google/gopacket/pcap"
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"github.com/sfiera/multitalk/pkg/ddp"
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"github.com/sfiera/multitalk/pkg/ddp"
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"github.com/sfiera/multitalk/pkg/ethernet"
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"github.com/sfiera/multitalk/pkg/ethertalk"
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"github.com/sfiera/multitalk/pkg/ethertalk"
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)
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)
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// EtherTalkPeer holds data needed to exchange routes and zones with another
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// EtherTalkPeer holds data needed to forward packets to another router on the
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// router on the EtherTalk network.
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// EtherTalk network.
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type EtherTalkPeer struct {
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type EtherTalkPeer struct {
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PcapHandle *pcap.Handle
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Port *EtherTalkPort
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MyHWAddr ethernet.Addr
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AARP *AARPMachine
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PeerAddr ddp.Addr
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PeerAddr ddp.Addr
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}
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}
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// Forward forwards a DDP packet to the next router.
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// Forward forwards a DDP packet to the next router.
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func (p *EtherTalkPeer) Forward(ctx context.Context, pkt *ddp.ExtPacket) error {
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func (p *EtherTalkPeer) Forward(ctx context.Context, pkt *ddp.ExtPacket) error {
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// TODO: AARP resolution can block
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// TODO: AARP resolution can block
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de, err := p.AARP.Resolve(ctx, p.PeerAddr)
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de, err := p.Port.AARPMachine.Resolve(ctx, p.PeerAddr)
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if err != nil {
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if err != nil {
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return err
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return err
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}
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}
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outFrame, err := ethertalk.AppleTalk(p.MyHWAddr, *pkt)
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outFrame, err := ethertalk.AppleTalk(p.Port.EthernetAddr, *pkt)
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if err != nil {
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if err != nil {
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return err
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return err
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}
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}
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@ -50,5 +46,5 @@ func (p *EtherTalkPeer) Forward(ctx context.Context, pkt *ddp.ExtPacket) error {
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if err != nil {
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if err != nil {
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return err
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return err
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}
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}
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return p.PcapHandle.WritePacketData(outFrameRaw)
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return p.Port.PcapHandle.WritePacketData(outFrameRaw)
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}
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}
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@ -31,6 +31,7 @@ import (
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// EtherTalkPort is all the data and helpers needed for EtherTalk on one port.
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// EtherTalkPort is all the data and helpers needed for EtherTalk on one port.
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type EtherTalkPort struct {
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type EtherTalkPort struct {
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Device string
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EthernetAddr ethernet.Addr
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EthernetAddr ethernet.Addr
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NetStart ddp.Network
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NetStart ddp.Network
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NetEnd ddp.Network
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NetEnd ddp.Network
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@ -39,7 +40,6 @@ type EtherTalkPort struct {
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AvailableZones []string
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AvailableZones []string
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PcapHandle *pcap.Handle
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PcapHandle *pcap.Handle
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AARPMachine *AARPMachine
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AARPMachine *AARPMachine
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RTMPMachine *RTMPMachine
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Router *Router
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Router *Router
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}
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}
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@ -129,7 +129,9 @@ func (port *EtherTalkPort) Serve(ctx context.Context) {
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switch ddpkt.DstSocket {
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switch ddpkt.DstSocket {
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case 1: // The RTMP socket
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case 1: // The RTMP socket
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port.RTMPMachine.Handle(ctx, ddpkt)
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if err := port.HandleRTMP(ctx, ddpkt); err != nil {
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log.Printf("RTMP: Couldn't handle: %v", err)
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}
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case 2: // The NIS (name information socket / NBP socket)
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case 2: // The NIS (name information socket / NBP socket)
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if err := port.HandleNBP(ctx, ddpkt); err != nil {
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if err := port.HandleNBP(ctx, ddpkt); err != nil {
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285
router/rtmp.go
285
router/rtmp.go
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@ -26,33 +26,113 @@ import (
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"gitea.drjosh.dev/josh/jrouter/atalk/rtmp"
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"gitea.drjosh.dev/josh/jrouter/atalk/rtmp"
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"gitea.drjosh.dev/josh/jrouter/status"
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"gitea.drjosh.dev/josh/jrouter/status"
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"github.com/google/gopacket/pcap"
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"github.com/sfiera/multitalk/pkg/aarp"
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"github.com/sfiera/multitalk/pkg/ddp"
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"github.com/sfiera/multitalk/pkg/ddp"
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"github.com/sfiera/multitalk/pkg/ethernet"
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"github.com/sfiera/multitalk/pkg/ethertalk"
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)
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)
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// RTMPMachine implements RTMP on an AppleTalk network attached to the router.
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// RTMPMachine implements RTMP on an AppleTalk network attached to the router.
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type RTMPMachine struct {
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func (port *EtherTalkPort) HandleRTMP(ctx context.Context, pkt *ddp.ExtPacket) error {
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AARPMachine *AARPMachine
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switch pkt.Proto {
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Config *Config
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case ddp.ProtoRTMPReq:
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PcapHandle *pcap.Handle
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// I can answer RTMP requests!
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RoutingTable *RouteTable
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req, err := rtmp.UnmarshalRequestPacket(pkt.Data)
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if err != nil {
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IncomingCh chan *ddp.ExtPacket
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return fmt.Errorf("unmarshal Request packet: %w", err)
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}
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}
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func (m *RTMPMachine) Handle(ctx context.Context, pkt *ddp.ExtPacket) {
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switch req.Function {
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select {
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case rtmp.FunctionRequest:
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case <-ctx.Done():
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// Respond with RTMP Response
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case m.IncomingCh <- pkt:
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respPkt := &rtmp.ResponsePacket{
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SenderAddr: port.MyAddr,
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Extended: true,
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RangeStart: port.NetStart,
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RangeEnd: port.NetEnd,
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}
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respPktRaw, err := respPkt.Marshal()
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if err != nil {
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return fmt.Errorf("marshal RTMP Response packet: %w", err)
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}
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ddpPkt := &ddp.ExtPacket{
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ExtHeader: ddp.ExtHeader{
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Size: uint16(len(respPktRaw)) + atalk.DDPExtHeaderSize,
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Cksum: 0,
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DstNet: pkt.SrcNet,
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DstNode: pkt.SrcNode,
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DstSocket: 1, // the RTMP socket
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SrcNet: port.MyAddr.Network,
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SrcNode: port.MyAddr.Node,
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SrcSocket: 1, // the RTMP socket
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Proto: ddp.ProtoRTMPResp,
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},
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Data: respPktRaw,
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}
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if err := port.Router.Forward(ctx, ddpPkt); err != nil {
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return fmt.Errorf("send Response: %w", err)
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}
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case rtmp.FunctionRDRSplitHorizon, rtmp.FunctionRDRComplete:
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// Like the Data broadcast, but solicited by a request (RDR).
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splitHorizon := req.Function == rtmp.FunctionRDRSplitHorizon
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for _, dataPkt := range port.rtmpDataPackets(splitHorizon) {
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dataPktRaw, err := dataPkt.Marshal()
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if err != nil {
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return fmt.Errorf("marshal RTMP Data packet: %w", err)
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}
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ddpPkt := &ddp.ExtPacket{
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ExtHeader: ddp.ExtHeader{
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Size: uint16(len(dataPktRaw)) + atalk.DDPExtHeaderSize,
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Cksum: 0,
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DstNet: pkt.SrcNet,
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DstNode: pkt.SrcNode,
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DstSocket: 1, // the RTMP socket
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SrcNet: port.MyAddr.Network,
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SrcNode: port.MyAddr.Node,
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SrcSocket: 1, // the RTMP socket
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Proto: ddp.ProtoRTMPResp,
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},
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Data: dataPktRaw,
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}
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if err := port.Router.Forward(ctx, ddpPkt); err != nil {
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return fmt.Errorf("send Data: %w", err)
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}
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}
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}
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}
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// Run executes the machine.
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case rtmp.FunctionLoopProbe:
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func (m *RTMPMachine) Run(ctx context.Context) (err error) {
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log.Print("RTMP: TODO: handle Loop Probes")
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return nil
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}
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case ddp.ProtoRTMPResp:
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// It's a peer router on the AppleTalk network!
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log.Print("RTMP: Got Response or Data")
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dataPkt, err := rtmp.UnmarshalDataPacket(pkt.Data)
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if err != nil {
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log.Printf("RTMP: Couldn't unmarshal RTMP Data packet: %v", err)
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break
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}
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peer := &EtherTalkPeer{
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Port: port,
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PeerAddr: dataPkt.RouterAddr,
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}
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for _, rt := range dataPkt.NetworkTuples {
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if err := port.Router.RouteTable.UpsertEthRoute(peer, rt.Extended, rt.RangeStart, rt.RangeEnd, rt.Distance+1); err != nil {
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log.Printf("RTMP: Couldn't upsert EtherTalk route: %v", err)
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}
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}
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default:
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log.Printf("RTMP: invalid DDP type %d on socket 1", pkt.Proto)
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}
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return nil
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}
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// RunRTMP makes periodic RTMP Data broadcasts on this port.
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func (port *EtherTalkPort) RunRTMP(ctx context.Context) (err error) {
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ctx, setStatus, _ := status.AddSimpleItem(ctx, "RTMP")
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ctx, setStatus, _ := status.AddSimpleItem(ctx, "RTMP")
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defer func() {
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defer func() {
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setStatus(fmt.Sprintf("Run loop stopped! Return: %v", err))
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setStatus(fmt.Sprintf("Run loop stopped! Return: %v", err))
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@ -61,16 +141,12 @@ func (m *RTMPMachine) Run(ctx context.Context) (err error) {
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setStatus("Awaiting DDP address assignment")
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setStatus("Awaiting DDP address assignment")
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// Await local address assignment before doing anything
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// Await local address assignment before doing anything
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<-m.AARPMachine.Assigned()
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<-port.AARPMachine.Assigned()
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myAddr, ok := m.AARPMachine.Address()
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if !ok {
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return fmt.Errorf("AARP machine closed Assigned channel but Address is not valid")
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}
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setStatus("Initial RTMP Data broadcast")
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setStatus("Initial RTMP Data broadcast")
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// Initial broadcast
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// Initial broadcast
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if err := m.broadcastData(myAddr); err != nil {
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if err := port.broadcastRTMPData(); err != nil {
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log.Printf("RTMP: Couldn't broadcast Data: %v", err)
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log.Printf("RTMP: Couldn't broadcast Data: %v", err)
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}
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}
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@ -86,141 +162,15 @@ func (m *RTMPMachine) Run(ctx context.Context) (err error) {
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case <-bcastTicker.C:
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case <-bcastTicker.C:
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setStatus("Broadcasting RTMP Data")
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setStatus("Broadcasting RTMP Data")
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if err := m.broadcastData(myAddr); err != nil {
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if err := port.broadcastRTMPData(); err != nil {
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log.Printf("RTMP: Couldn't broadcast Data: %v", err)
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log.Printf("RTMP: Couldn't broadcast Data: %v", err)
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}
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}
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case pkt := <-m.IncomingCh:
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|
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setStatus("Handling incoming packet")
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switch pkt.Proto {
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|
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case ddp.ProtoRTMPReq:
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|
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// I can answer RTMP requests!
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|
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req, err := rtmp.UnmarshalRequestPacket(pkt.Data)
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|
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if err != nil {
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|
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log.Printf("RTMP: Couldn't unmarshal Request packet: %v", err)
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}
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|
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// should be in the cache...
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|
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theirHWAddr, err := m.AARPMachine.Resolve(ctx, ddp.Addr{Network: pkt.SrcNet, Node: pkt.SrcNode})
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if err != nil {
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log.Printf("RTMP: Couldn't resolve %d.%d to a hardware address: %v", pkt.SrcNet, pkt.SrcNode, err)
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|
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continue
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}
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|
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switch req.Function {
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|
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case rtmp.FunctionRequest:
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|
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// Respond with RTMP Response
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|
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respPkt := &rtmp.ResponsePacket{
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|
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SenderAddr: myAddr.Proto,
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Extended: true,
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RangeStart: m.Config.EtherTalk.NetStart,
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RangeEnd: m.Config.EtherTalk.NetEnd,
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|
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}
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respPktRaw, err := respPkt.Marshal()
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|
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if err != nil {
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|
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log.Printf("RTMP: Couldn't marshal RTMP Response packet: %v", err)
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|
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continue
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}
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|
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ddpPkt := &ddp.ExtPacket{
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|
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ExtHeader: ddp.ExtHeader{
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|
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Size: uint16(len(respPktRaw)) + atalk.DDPExtHeaderSize,
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|
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Cksum: 0,
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|
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DstNet: pkt.SrcNet,
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|
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DstNode: pkt.SrcNode,
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|
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DstSocket: 1, // the RTMP socket
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|
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SrcNet: myAddr.Proto.Network,
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|
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SrcNode: myAddr.Proto.Node,
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|
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SrcSocket: 1, // the RTMP socket
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|
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Proto: ddp.ProtoRTMPResp,
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|
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},
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|
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Data: respPktRaw,
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|
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}
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|
||||||
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|
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if err := m.send(myAddr.Hardware, theirHWAddr, ddpPkt); err != nil {
|
|
||||||
log.Printf("RTMP: Couldn't send Data broadcast: %v", err)
|
|
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}
|
|
||||||
|
|
||||||
case rtmp.FunctionRDRSplitHorizon, rtmp.FunctionRDRComplete:
|
|
||||||
// Like the Data broadcast, but solicited by a request (RDR).
|
|
||||||
// TODO: handle split-horizon processing
|
|
||||||
for _, dataPkt := range m.dataPackets(myAddr.Proto) {
|
|
||||||
dataPktRaw, err := dataPkt.Marshal()
|
|
||||||
if err != nil {
|
|
||||||
log.Printf("RTMP: Couldn't marshal Data packet: %v", err)
|
|
||||||
break
|
|
||||||
}
|
|
||||||
|
|
||||||
ddpPkt := &ddp.ExtPacket{
|
|
||||||
ExtHeader: ddp.ExtHeader{
|
|
||||||
Size: uint16(len(dataPktRaw)) + atalk.DDPExtHeaderSize,
|
|
||||||
Cksum: 0,
|
|
||||||
DstNet: pkt.SrcNet,
|
|
||||||
DstNode: pkt.SrcNode,
|
|
||||||
DstSocket: 1, // the RTMP socket
|
|
||||||
SrcNet: myAddr.Proto.Network,
|
|
||||||
SrcNode: myAddr.Proto.Node,
|
|
||||||
SrcSocket: 1, // the RTMP socket
|
|
||||||
Proto: ddp.ProtoRTMPResp,
|
|
||||||
},
|
|
||||||
Data: dataPktRaw,
|
|
||||||
}
|
|
||||||
|
|
||||||
if err := m.send(myAddr.Hardware, theirHWAddr, ddpPkt); err != nil {
|
|
||||||
log.Printf("RTMP: Couldn't send Data response: %v", err)
|
|
||||||
break
|
|
||||||
}
|
|
||||||
}
|
|
||||||
|
|
||||||
case rtmp.FunctionLoopProbe:
|
|
||||||
log.Print("RTMP: TODO: handle Loop Probes")
|
|
||||||
|
|
||||||
}
|
|
||||||
|
|
||||||
case ddp.ProtoRTMPResp:
|
|
||||||
// It's a peer router on the AppleTalk network!
|
|
||||||
log.Print("RTMP: Got Response or Data")
|
|
||||||
dataPkt, err := rtmp.UnmarshalDataPacket(pkt.Data)
|
|
||||||
if err != nil {
|
|
||||||
log.Printf("RTMP: Couldn't unmarshal RTMP Data packet: %v", err)
|
|
||||||
break
|
|
||||||
}
|
|
||||||
peer := &EtherTalkPeer{
|
|
||||||
PcapHandle: m.PcapHandle,
|
|
||||||
MyHWAddr: m.AARPMachine.myAddr.Hardware,
|
|
||||||
AARP: m.AARPMachine,
|
|
||||||
PeerAddr: dataPkt.RouterAddr,
|
|
||||||
}
|
|
||||||
|
|
||||||
for _, rt := range dataPkt.NetworkTuples {
|
|
||||||
if err := m.RoutingTable.UpsertEthRoute(peer, rt.Extended, rt.RangeStart, rt.RangeEnd, rt.Distance+1); err != nil {
|
|
||||||
log.Printf("RTMP: Couldn't upsert EtherTalk route: %v", err)
|
|
||||||
}
|
|
||||||
}
|
|
||||||
|
|
||||||
default:
|
|
||||||
log.Printf("RTMP: invalid DDP type %d on socket 1", pkt.Proto)
|
|
||||||
}
|
|
||||||
|
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
|
|
||||||
func (m *RTMPMachine) send(src, dst ethernet.Addr, ddpPkt *ddp.ExtPacket) error {
|
func (port *EtherTalkPort) broadcastRTMPData() error {
|
||||||
ethFrame, err := ethertalk.AppleTalk(src, *ddpPkt)
|
for _, dataPkt := range port.rtmpDataPackets(true) {
|
||||||
if err != nil {
|
|
||||||
return err
|
|
||||||
}
|
|
||||||
ethFrame.Dst = dst
|
|
||||||
|
|
||||||
ethFrameRaw, err := ethertalk.Marshal(*ethFrame)
|
|
||||||
if err != nil {
|
|
||||||
return err
|
|
||||||
}
|
|
||||||
return m.PcapHandle.WritePacketData(ethFrameRaw)
|
|
||||||
}
|
|
||||||
|
|
||||||
func (m *RTMPMachine) broadcastData(myAddr aarp.AddrPair) error {
|
|
||||||
for _, dataPkt := range m.dataPackets(myAddr.Proto) {
|
|
||||||
dataPktRaw, err := dataPkt.Marshal()
|
dataPktRaw, err := dataPkt.Marshal()
|
||||||
if err != nil {
|
if err != nil {
|
||||||
return fmt.Errorf("marshal Data packet: %v", err)
|
return fmt.Errorf("marshal Data packet: %v", err)
|
||||||
|
@ -230,29 +180,40 @@ func (m *RTMPMachine) broadcastData(myAddr aarp.AddrPair) error {
|
||||||
ExtHeader: ddp.ExtHeader{
|
ExtHeader: ddp.ExtHeader{
|
||||||
Size: uint16(len(dataPktRaw)) + atalk.DDPExtHeaderSize,
|
Size: uint16(len(dataPktRaw)) + atalk.DDPExtHeaderSize,
|
||||||
Cksum: 0,
|
Cksum: 0,
|
||||||
DstNet: 0, // this network
|
DstNet: 0x0000, // this network
|
||||||
DstNode: 0xff, // broadcast packet
|
DstNode: 0xff, // broadcast packet
|
||||||
DstSocket: 1, // the RTMP socket
|
DstSocket: 1, // the RTMP socket
|
||||||
SrcNet: myAddr.Proto.Network,
|
SrcNet: port.MyAddr.Network,
|
||||||
SrcNode: myAddr.Proto.Node,
|
SrcNode: port.MyAddr.Node,
|
||||||
SrcSocket: 1, // the RTMP socket
|
SrcSocket: 1, // the RTMP socket
|
||||||
Proto: ddp.ProtoRTMPResp,
|
Proto: ddp.ProtoRTMPResp,
|
||||||
},
|
},
|
||||||
Data: dataPktRaw,
|
Data: dataPktRaw,
|
||||||
}
|
}
|
||||||
|
|
||||||
if err := m.send(myAddr.Hardware, ethertalk.AppleTalkBroadcast, ddpPkt); err != nil {
|
if err := port.Broadcast(ddpPkt); err != nil {
|
||||||
return err
|
return err
|
||||||
}
|
}
|
||||||
}
|
}
|
||||||
return nil
|
return nil
|
||||||
}
|
}
|
||||||
|
|
||||||
func (m *RTMPMachine) dataPackets(myAddr ddp.Addr) []*rtmp.DataPacket {
|
func (port *EtherTalkPort) rtmpDataPackets(splitHorizon bool) []*rtmp.DataPacket {
|
||||||
// Build up a slice of routing tuples.
|
// Build up a slice of routing tuples.
|
||||||
routes := m.RoutingTable.ValidRoutes()
|
routes := port.Router.RouteTable.ValidRoutes()
|
||||||
tuples := make([]rtmp.NetworkTuple, 0, len(routes))
|
tuples := make([]rtmp.NetworkTuple, 0, len(routes))
|
||||||
for _, rt := range routes {
|
for _, rt := range routes {
|
||||||
|
if rt.EtherTalkDirect == port {
|
||||||
|
// If the route is actually a direct connection to this port,
|
||||||
|
// don't include it.
|
||||||
|
// (It's manually set as the first tuple anyway.)
|
||||||
|
continue
|
||||||
|
}
|
||||||
|
if splitHorizon && rt.EtherTalkPeer.Port == port {
|
||||||
|
// If the route is through a peer accessible on this port, don't
|
||||||
|
// include it.
|
||||||
|
continue
|
||||||
|
}
|
||||||
tuples = append(tuples, rtmp.NetworkTuple{
|
tuples = append(tuples, rtmp.NetworkTuple{
|
||||||
Extended: rt.Extended,
|
Extended: rt.Extended,
|
||||||
RangeStart: rt.NetStart,
|
RangeStart: rt.NetStart,
|
||||||
|
@ -266,8 +227,8 @@ func (m *RTMPMachine) dataPackets(myAddr ddp.Addr) []*rtmp.DataPacket {
|
||||||
// TODO: support non-extended local networks (LocalTalk)
|
// TODO: support non-extended local networks (LocalTalk)
|
||||||
first := rtmp.NetworkTuple{
|
first := rtmp.NetworkTuple{
|
||||||
Extended: true,
|
Extended: true,
|
||||||
RangeStart: m.Config.EtherTalk.NetStart,
|
RangeStart: port.NetStart,
|
||||||
RangeEnd: m.Config.EtherTalk.NetEnd,
|
RangeEnd: port.NetEnd,
|
||||||
Distance: 0,
|
Distance: 0,
|
||||||
}
|
}
|
||||||
|
|
||||||
|
@ -287,7 +248,7 @@ func (m *RTMPMachine) dataPackets(myAddr ddp.Addr) []*rtmp.DataPacket {
|
||||||
rem = rem[len(chunk)-1:]
|
rem = rem[len(chunk)-1:]
|
||||||
|
|
||||||
packets = append(packets, &rtmp.DataPacket{
|
packets = append(packets, &rtmp.DataPacket{
|
||||||
RouterAddr: myAddr,
|
RouterAddr: port.MyAddr,
|
||||||
Extended: true,
|
Extended: true,
|
||||||
NetworkTuples: chunk,
|
NetworkTuples: chunk,
|
||||||
})
|
})
|
||||||
|
|
Loading…
Reference in a new issue