Multi-port refactor #1

Merged
josh merged 8 commits from multi-port-refactor into main 2024-05-04 17:06:20 +10:00
14 changed files with 961 additions and 869 deletions

View file

@ -101,7 +101,7 @@ func Unmarshal(data []byte) (*Packet, error) {
t := Tuple{
Network: ddp.Network(binary.BigEndian.Uint16(data[:2])),
Node: ddp.Node(data[2]),
Socket: data[3],
Socket: ddp.Socket(data[3]),
Enumerator: data[4],
}
data = data[5:]
@ -128,7 +128,7 @@ func Unmarshal(data []byte) (*Packet, error) {
type Tuple struct {
Network ddp.Network
Node ddp.Node
Socket uint8
Socket ddp.Socket
Enumerator uint8
Object string // length-prefixed
Type string // length-prefixed
@ -147,7 +147,7 @@ func (t *Tuple) writeTo(b *bytes.Buffer) error {
}
write16(b, t.Network)
b.WriteByte(byte(t.Node))
b.WriteByte(t.Socket)
b.WriteByte(byte(t.Socket))
b.WriteByte(t.Enumerator)
b.WriteByte(byte(len(t.Object)))
b.WriteString(t.Object)

279
main.go
View file

@ -23,7 +23,6 @@ import (
"errors"
"flag"
"fmt"
"io"
"log"
"math/rand/v2"
"net"
@ -44,7 +43,6 @@ import (
"github.com/google/gopacket/pcap"
"github.com/sfiera/multitalk/pkg/ddp"
"github.com/sfiera/multitalk/pkg/ethernet"
"github.com/sfiera/multitalk/pkg/ethertalk"
)
const routingTableTemplate = `
@ -63,7 +61,17 @@ const routingTableTemplate = `
<td>{{if $route.Extended}}{{else}}{{end}}</td>
<td>{{$route.Distance}}</td>
<td>{{$route.LastSeenAgo}}</td>
<td>{{if $route.AURPPeer}}{{$route.AURPPeer.RemoteAddr}}{{else if $route.EtherTalkPeer}}{{$route.EtherTalkPeer.PeerAddr.Network}}.{{$route.EtherTalkPeer.PeerAddr.Node}}{{else}}-{{end}}</td>
<td>
{{- with $route.AURPPeer -}}
{{.RemoteAddr}}
{{- end -}}
{{- with $route.EtherTalkPeer -}}
{{.Port.Device}} {{.PeerAddr.Network}}.{{.PeerAddr.Node}}
{{- end -}}
{{- with $route.EtherTalkDirect -}}
{{.Device}} {{.NetStart}}-{{.NetEnd}}
{{- end -}}
</td>
</tr>
{{end}}
</tbody>
@ -75,7 +83,7 @@ const zoneTableTemplate = `
<thead><tr>
<th>Network</th>
<th>Name</th>
<th>Local</th>
<th>Local Port</th>
<th>Last seen</th>
</tr></thead>
<tbody>
@ -83,7 +91,7 @@ const zoneTableTemplate = `
<tr>
<td>{{$zone.Network}}</td>
<td>{{$zone.Name}}</td>
<td>{{if $zone.Local}}{{else}}{{end}}</td>
<td>{{with $zone.LocalPort}}{{.Device}}{{else}}-{{end}}</td>
<td>{{$zone.LastSeenAgo}}</td>
</tr>
{{end}}
@ -159,10 +167,10 @@ func main() {
ln, err := net.ListenUDP("udp4", &net.UDPAddr{Port: int(cfg.ListenPort)})
if err != nil {
log.Fatalf("Couldn't listen on udp4:387: %v", err)
log.Fatalf("AURP: Couldn't listen on udp4:387: %v", err)
}
defer ln.Close()
log.Printf("Listening on %v", ln.LocalAddr())
log.Printf("AURP: Listening on %v", ln.LocalAddr())
log.Println("Press ^C or send SIGINT to stop the router gracefully")
cctx, cancel := context.WithCancel(context.Background())
@ -203,7 +211,7 @@ func main() {
defer pcapHandle.Close()
// -------------------------------- Tables --------------------------------
routes := router.NewRoutingTable()
routes := router.NewRouteTable()
status.AddItem(ctx, "Routing table", routingTableTemplate, func(context.Context) (any, error) {
rs := routes.Dump()
slices.SortFunc(rs, func(ra, rb router.Route) int {
@ -213,7 +221,6 @@ func main() {
})
zones := router.NewZoneTable()
zones.Upsert(cfg.EtherTalk.NetStart, cfg.EtherTalk.ZoneName, true)
status.AddItem(ctx, "Zone table", zoneTableTemplate, func(context.Context) (any, error) {
zs := zones.Dump()
slices.SortFunc(zs, func(za, zb router.Zone) int {
@ -331,174 +338,46 @@ func main() {
// --------------------------------- AARP ---------------------------------
aarpMachine := router.NewAARPMachine(cfg, pcapHandle, myHWAddr)
aarpCh := make(chan *ethertalk.Packet, 1024)
go aarpMachine.Run(ctx, aarpCh)
// --------------------------------- RTMP ---------------------------------
rtmpMachine := &router.RTMPMachine{
AARP: aarpMachine,
Config: cfg,
PcapHandle: pcapHandle,
RoutingTable: routes,
}
rtmpCh := make(chan *ddp.ExtPacket, 1024)
go rtmpMachine.Run(ctx, rtmpCh)
go aarpMachine.Run(ctx)
// -------------------------------- Router --------------------------------
rooter := &router.Router{
Config: cfg,
PcapHandle: pcapHandle,
MyHWAddr: myHWAddr,
// MyDDPAddr: ...,
AARPMachine: aarpMachine,
RouteTable: routes,
ZoneTable: zones,
RouteTable: routes,
ZoneTable: zones,
}
etherTalkPort := &router.EtherTalkPort{
Device: cfg.EtherTalk.Device,
EthernetAddr: myHWAddr,
NetStart: cfg.EtherTalk.NetStart,
NetEnd: cfg.EtherTalk.NetEnd,
DefaultZoneName: cfg.EtherTalk.ZoneName,
AvailableZones: []string{cfg.EtherTalk.ZoneName},
PcapHandle: pcapHandle,
AARPMachine: aarpMachine,
Router: rooter,
}
rooter.Ports = append(rooter.Ports, etherTalkPort)
routes.InsertEtherTalkDirect(etherTalkPort)
for _, az := range etherTalkPort.AvailableZones {
zones.Upsert(etherTalkPort.NetStart, az, etherTalkPort)
}
// --------------------------------- RTMP ---------------------------------
go etherTalkPort.RunRTMP(ctx)
// ---------------------- Raw AppleTalk/AARP inbound ----------------------
wg.Add(1)
go func() {
defer wg.Done()
ctx, setStatus, done := status.AddSimpleItem(ctx, "EtherTalk inbound")
defer done()
ctx, setStatus, _ := status.AddSimpleItem(ctx, "EtherTalk inbound")
defer setStatus("EtherTalk Serve goroutine exited!")
setStatus(fmt.Sprintf("Listening on %s", cfg.EtherTalk.Device))
for {
if ctx.Err() != nil {
return
}
rawPkt, _, err := pcapHandle.ReadPacketData()
if errors.Is(err, pcap.NextErrorTimeoutExpired) {
continue
}
if errors.Is(err, io.EOF) || errors.Is(err, pcap.NextErrorNoMorePackets) {
return
}
if err != nil {
log.Printf("Couldn't read AppleTalk / AARP packet data: %v", err)
return
}
ethFrame := new(ethertalk.Packet)
if err := ethertalk.Unmarshal(rawPkt, ethFrame); err != nil {
log.Printf("Couldn't unmarshal EtherTalk frame: %v", err)
continue
}
// Ignore if sent by me
if ethFrame.Src == myHWAddr {
continue
}
switch ethFrame.SNAPProto {
case ethertalk.AARPProto:
// log.Print("Got an AARP frame")
aarpCh <- ethFrame
case ethertalk.AppleTalkProto:
// log.Print("Got an AppleTalk frame")
ddpkt := new(ddp.ExtPacket)
if err := ddp.ExtUnmarshal(ethFrame.Payload, ddpkt); err != nil {
log.Printf("Couldn't unmarshal DDP packet: %v", err)
continue
}
log.Printf("DDP: src (%d.%d s %d) dst (%d.%d s %d) proto %d data len %d",
ddpkt.SrcNet, ddpkt.SrcNode, ddpkt.SrcSocket,
ddpkt.DstNet, ddpkt.DstNode, ddpkt.DstSocket,
ddpkt.Proto, len(ddpkt.Data))
// Glean address info for AMT, but only if SrcNet is our net
// (If it's not our net, then it was routed from elsewhere, and
// we'd be filling the AMT with entries for a router.)
if ddpkt.SrcNet >= cfg.EtherTalk.NetStart && ddpkt.SrcNet <= cfg.EtherTalk.NetEnd {
srcAddr := ddp.Addr{Network: ddpkt.SrcNet, Node: ddpkt.SrcNode}
aarpMachine.Learn(srcAddr, ethFrame.Src)
// log.Printf("DDP: Gleaned that %d.%d -> %v", srcAddr.Network, srcAddr.Node, ethFrame.Src)
}
// Packet for us? First, who am I?
myAddr, ok := aarpMachine.Address()
if !ok {
continue
}
rooter.MyDDPAddr = myAddr.Proto
// Our network?
// "The network number 0 is reserved to mean unknown; by default
// it specifies the local network to which the node is
// connected. Packets whose destination network number is 0 are
// addressed to a node on the local network."
// TODO: more generic routing
if ddpkt.DstNet != 0 && !(ddpkt.DstNet >= cfg.EtherTalk.NetStart && ddpkt.DstNet <= cfg.EtherTalk.NetEnd) {
// Is it for a network in the routing table?
route := routes.LookupRoute(ddpkt.DstNet)
if route == nil {
log.Printf("DDP: no route for network %d", ddpkt.DstNet)
continue
}
switch {
case route.AURPPeer != nil:
// Encap ethPacket.Payload into an AURP packet
log.Printf("DDP: forwarding to AURP peer %v", route.AURPPeer.RemoteAddr)
if _, err := route.AURPPeer.Send(route.AURPPeer.Transport.NewAppleTalkPacket(ethFrame.Payload)); err != nil {
log.Printf("DDP: Couldn't forward packet to AURP peer: %v", err)
}
case route.EtherTalkPeer != nil:
// Route payload to another router over EtherTalk
// TODO: this is unlikely because we currenly only support 1 EtherTalk port
log.Printf("DDP: forwarding to EtherTalk peer %v", route.EtherTalkPeer.PeerAddr)
// Note: resolving AARP can block
if err := route.EtherTalkPeer.Forward(ctx, ddpkt); err != nil {
log.Printf("DDP: Couldn't forward packet to EtherTalk peer: %v", err)
}
default:
log.Print("DDP: no forwarding mechanism for route; dropping packet")
}
continue
}
// To me?
// "Node ID 0 indicates any router on the network"- I'm a router
// "node ID $FF indicates either a network-wide or zone-specific
// broadcast"- that's relevant
if ddpkt.DstNode != 0 && ddpkt.DstNode != 0xff && ddpkt.DstNode != myAddr.Proto.Node {
continue
}
switch ddpkt.DstSocket {
case 1: // The RTMP socket
rtmpCh <- ddpkt
case 2: // The NIS (name information socket / NBP socket)
if err := rooter.HandleNBP(ethFrame.Src, ddpkt); err != nil {
log.Printf("NBP: Couldn't handle: %v", err)
}
case 4: // The AEP socket
if err := rooter.HandleAEP(ethFrame.Src, ddpkt); err != nil {
log.Printf("AEP: Couldn't handle: %v", err)
}
case 6: // The ZIS (zone information socket / ZIP socket)
if err := rooter.HandleZIP(ctx, ethFrame.Src, ddpkt); err != nil {
log.Printf("ZIP: couldn't handle: %v", err)
}
default:
log.Printf("DDP: No handler for socket %d", ddpkt.DstSocket)
}
default:
log.Printf("Read unknown packet %s -> %s with payload %x", ethFrame.Src, ethFrame.Dst, ethFrame.Payload)
}
}
etherTalkPort.Serve(ctx)
}()
// ----------------------------- AURP inbound -----------------------------
@ -593,79 +472,37 @@ func main() {
log.Printf("AURP: Couldn't unmarshal encapsulated DDP packet: %v", err)
continue
}
log.Printf("DDP/AURP: Got %d.%d.%d -> %d.%d.%d proto %d data len %d",
ddpkt.SrcNet, ddpkt.SrcNode, ddpkt.SrcSocket,
ddpkt.DstNet, ddpkt.DstNode, ddpkt.DstSocket,
ddpkt.Proto, len(ddpkt.Data))
// log.Printf("DDP/AURP: Got %d.%d.%d -> %d.%d.%d proto %d data len %d",
// ddpkt.SrcNet, ddpkt.SrcNode, ddpkt.SrcSocket,
// ddpkt.DstNet, ddpkt.DstNode, ddpkt.DstSocket,
// ddpkt.Proto, len(ddpkt.Data))
// Route the packet
// Check and adjust the Hop Count
// Note the ddp package doesn't make this simple
hopCount := (ddpkt.Size & 0x3C00) >> 10
if hopCount >= 15 {
log.Printf("DDP/AURP: hop count exceeded (%d >= 15)", hopCount)
continue
}
hopCount++
ddpkt.Size &^= 0x3C00
ddpkt.Size |= hopCount << 10
if ddpkt.DstNet < cfg.EtherTalk.NetStart || ddpkt.DstNet > cfg.EtherTalk.NetEnd {
// Is it a network in the routing table?
route := routes.LookupRoute(ddpkt.DstNet)
if route == nil {
log.Printf("DDP/AURP: no route for packet (dstnet %d); dropping packet", ddpkt.DstNet)
// Is it addressed to me?
var localPort *router.EtherTalkPort
for _, port := range rooter.Ports {
if ddpkt.DstNet >= port.NetStart && ddpkt.DstNet <= port.NetEnd {
localPort = port
break
}
switch {
case route.AURPPeer != nil:
// Routing between AURP peers... bit weird but OK
log.Printf("DDP/AURP: forwarding to AURP peer %v", route.AURPPeer.RemoteAddr)
outPkt, err := ddp.ExtMarshal(*ddpkt)
if err != nil {
log.Printf("DDP/AURP: Couldn't re-marshal packet: %v", err)
break
}
if _, err := route.AURPPeer.Send(route.AURPPeer.Transport.NewAppleTalkPacket(outPkt)); err != nil {
log.Printf("DDP/AURP: Couldn't forward packet to AURP peer: %v", err)
}
case route.EtherTalkPeer != nil:
// AURP peer -> EtherTalk peer
// Note: resolving AARP can block
log.Printf("DDP/AURP: forwarding to EtherTalk peer %v", route.EtherTalkPeer.PeerAddr)
if err := route.EtherTalkPeer.Forward(ctx, ddpkt); err != nil {
log.Printf("DDP/AURP: Couldn't forward packet to EtherTalk peer: %v", err)
}
default:
log.Print("DDP/AURP: no forwarding mechanism for route; dropping packet")
}
continue
}
// Is it addressed to me? Is it NBP?
if ddpkt.DstNode == 0 { // Node 0 = any router for the network = me
if ddpkt.DstNode == 0 && localPort != nil { // Node 0 = any router for the network = me
// Is it NBP? FwdReq needs translating.
if ddpkt.DstSocket != 2 {
// Something else?? TODO
log.Printf("DDP/AURP: I don't have anything 'listening' on socket %d", ddpkt.DstSocket)
continue
}
// It's NBP
if err := rooter.HandleNBPInAURP(pr, ddpkt); err != nil {
// It's NBP, specifically it should be a FwdReq
if err := rooter.HandleNBPFromAURP(ctx, ddpkt); err != nil {
log.Printf("NBP/DDP/AURP: %v", err)
}
continue
}
// Note: resolving AARP can block
if err := rooter.SendEtherTalkDDP(ctx, ddpkt); err != nil {
log.Printf("DDP/AURP: couldn't send Ethertalk out: %v", err)
// Route the packet!
if err := rooter.Forward(ctx, ddpkt); err != nil {
log.Printf("DDP/AURP: Couldn't route packet: %v", err)
}
continue
default:
log.Printf("AURP: Got unknown packet type %v", dh.PacketType)

View file

@ -73,6 +73,8 @@ type AARPMachine struct {
cfg *Config
pcapHandle *pcap.Handle
incomingCh chan *ethertalk.Packet
// The Run goroutine is responsible for all writes to myAddr.Proto and
// probes, so this mutex is not used to enforce a single writer, only
// consistent reads
@ -90,6 +92,7 @@ func NewAARPMachine(cfg *Config, pcapHandle *pcap.Handle, myHWAddr ethernet.Addr
addressMappingTable: new(addressMappingTable),
cfg: cfg,
pcapHandle: pcapHandle,
incomingCh: make(chan *ethertalk.Packet, 1024), // arbitrary capacity
myAddr: aarp.AddrPair{
Hardware: myHWAddr,
},
@ -97,6 +100,14 @@ func NewAARPMachine(cfg *Config, pcapHandle *pcap.Handle, myHWAddr ethernet.Addr
}
}
// Handle handles a packet.
func (a *AARPMachine) Handle(ctx context.Context, pkt *ethertalk.Packet) {
select {
case <-ctx.Done():
case a.incomingCh <- pkt:
}
}
// Address returns the address of this node, and reports if the address is valid
// (i.e. not tentative).
func (a *AARPMachine) Address() (aarp.AddrPair, bool) {
@ -123,7 +134,7 @@ func (a *AARPMachine) status(ctx context.Context) (any, error) {
}
// Run executes the machine.
func (a *AARPMachine) Run(ctx context.Context, incomingCh <-chan *ethertalk.Packet) error {
func (a *AARPMachine) Run(ctx context.Context) error {
ctx, done := status.AddItem(ctx, "AARP", aarpStatusTemplate, a.status)
defer done()
@ -165,9 +176,9 @@ func (a *AARPMachine) Run(ctx context.Context, incomingCh <-chan *ethertalk.Pack
log.Printf("Couldn't broadcast a Probe: %v", err)
}
case ethFrame, ok := <-incomingCh:
case ethFrame, ok := <-a.incomingCh:
if !ok {
incomingCh = nil
a.incomingCh = nil
}
var aapkt aarp.Packet

View file

@ -17,14 +17,14 @@
package router
import (
"context"
"fmt"
"gitea.drjosh.dev/josh/jrouter/atalk/aep"
"github.com/sfiera/multitalk/pkg/ddp"
"github.com/sfiera/multitalk/pkg/ethernet"
)
func (rtr *Router) HandleAEP(src ethernet.Addr, ddpkt *ddp.ExtPacket) error {
func (rtr *Router) HandleAEP(ctx context.Context, ddpkt *ddp.ExtPacket) error {
if ddpkt.Proto != ddp.ProtoAEP {
return fmt.Errorf("invalid DDP type %d on socket 4", ddpkt.Proto)
}
@ -47,7 +47,7 @@ func (rtr *Router) HandleAEP(src ethernet.Addr, ddpkt *ddp.ExtPacket) error {
ddpkt.DstSocket, ddpkt.SrcSocket = ddpkt.SrcSocket, ddpkt.DstSocket
ddpkt.Data[0] = byte(aep.EchoReply)
return rtr.sendEtherTalkDDP(src, ddpkt)
return rtr.Output(ctx, ddpkt)
default:
return fmt.Errorf("invalid AEP function %d", ep.Function)

View file

@ -17,16 +17,17 @@
package router
import (
"context"
"fmt"
"log"
"slices"
"gitea.drjosh.dev/josh/jrouter/atalk"
"gitea.drjosh.dev/josh/jrouter/atalk/nbp"
"github.com/sfiera/multitalk/pkg/ddp"
"github.com/sfiera/multitalk/pkg/ethernet"
)
func (rtr *Router) HandleNBP(srcHWAddr ethernet.Addr, ddpkt *ddp.ExtPacket) error {
func (port *EtherTalkPort) HandleNBP(ctx context.Context, ddpkt *ddp.ExtPacket) error {
if ddpkt.Proto != ddp.ProtoNBP {
return fmt.Errorf("invalid DDP type %d on socket 2", ddpkt.Proto)
}
@ -41,130 +42,180 @@ func (rtr *Router) HandleNBP(srcHWAddr ethernet.Addr, ddpkt *ddp.ExtPacket) erro
switch nbpkt.Function {
case nbp.FunctionLkUp:
// when in AppleTalk, do as Apple Internet Router does...
outDDP, err := rtr.helloWorldThisIsMe(ddpkt, nbpkt.NBPID, &nbpkt.Tuples[0])
outDDP, err := port.helloWorldThisIsMe(nbpkt.NBPID, &nbpkt.Tuples[0])
if err != nil || outDDP == nil {
return err
}
log.Print("NBP: Replying to LkUp with LkUp-Reply for myself")
return rtr.sendEtherTalkDDP(srcHWAddr, outDDP)
// Note: AARP can block
return port.Send(ctx, outDDP)
case nbp.FunctionFwdReq:
return port.Router.handleNBPFwdReq(ctx, ddpkt, nbpkt)
case nbp.FunctionBrRq:
// There must be 1!
tuple := &nbpkt.Tuples[0]
return port.handleNBPBrRq(ctx, ddpkt, nbpkt)
zones := rtr.ZoneTable.LookupName(tuple.Zone)
default:
return fmt.Errorf("TODO: handle function %v", nbpkt.Function)
}
}
for _, z := range zones {
if z.Local {
// If it's for the local zone, translate it to a LkUp and broadcast it back
// out the EtherTalk port.
// "Note: On an internet, nodes on extended networks performing lookups in
// their own zone must replace a zone name of asterisk (*) with their actual
// zone name before sending the packet to A-ROUTER. All nodes performing
// lookups in their own zone will receive LkUp packets from themselves
// (actually sent by a router). The node's NBP process should expect to
// receive these packets and must reply to them."
nbpkt.Function = nbp.FunctionLkUp
nbpRaw, err := nbpkt.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal LkUp: %v", err)
}
func (port *EtherTalkPort) handleNBPBrRq(ctx context.Context, ddpkt *ddp.ExtPacket, nbpkt *nbp.Packet) error {
// A BrRq was addressed to us. The sender (on a local network) is aware that
// the network is extended and routed, and instead of broadcasting a LkUp
// itself, is asking us to do it.
outDDP := ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: atalk.DDPExtHeaderSize + uint16(len(nbpRaw)),
Cksum: 0,
SrcNet: ddpkt.SrcNet,
SrcNode: ddpkt.SrcNode,
SrcSocket: ddpkt.SrcSocket,
DstNet: 0x0000, // Local network broadcast
DstNode: 0xFF, // Broadcast node address within the dest network
DstSocket: 2,
Proto: ddp.ProtoNBP,
},
Data: nbpRaw,
}
// There must be 1!
tuple := &nbpkt.Tuples[0]
log.Printf("NBP: zone multicasting LkUp for tuple %v", tuple)
if err := rtr.ZoneMulticastEtherTalkDDP(tuple.Zone, &outDDP); err != nil {
return err
}
// This logic would be required on a non-extended network:
// if tuple.Zone == "" || tuple.Zone == "*" {
// tuple.Zone = port.DefaultZoneName
// }
// But also...if we match the query, reply as though it was a LkUp
outDDP2, err := rtr.helloWorldThisIsMe(ddpkt, nbpkt.NBPID, tuple)
if err != nil {
return err
}
if outDDP2 == nil {
continue
}
log.Print("NBP: Replying to BrRq with LkUp-Reply for myself")
if err := rtr.sendEtherTalkDDP(srcHWAddr, outDDP2); err != nil {
return err
}
zones := port.Router.ZoneTable.LookupName(tuple.Zone)
continue
}
route := rtr.RouteTable.LookupRoute(z.Network)
if route == nil {
return fmt.Errorf("no route for network %d", z.Network)
}
peer := route.AURPPeer
if peer == nil {
return fmt.Errorf("nil peer for route for network %d", z.Network)
}
// Translate it into a FwdReq and route it to the
// routers with the appropriate zone(s).
nbpkt.Function = nbp.FunctionFwdReq
for _, z := range zones {
if outPort := z.LocalPort; outPort != nil {
// If it's for a local zone, translate it to a LkUp and broadcast
// out the corresponding EtherTalk port.
// "Note: On an internet, nodes on extended networks performing lookups in
// their own zone must replace a zone name of asterisk (*) with their actual
// zone name before sending the packet to A-ROUTER. All nodes performing
// lookups in their own zone will receive LkUp packets from themselves
// (actually sent by a router). The node's NBP process should expect to
// receive these packets and must reply to them."
nbpkt.Function = nbp.FunctionLkUp
nbpRaw, err := nbpkt.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal FwdReq: %v", err)
return fmt.Errorf("couldn't marshal LkUp: %v", err)
}
outDDP := ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: atalk.DDPExtHeaderSize + uint16(len(nbpRaw)),
Cksum: 0,
SrcNet: ddpkt.SrcNet,
SrcNode: ddpkt.SrcNode,
SrcSocket: ddpkt.SrcSocket,
DstNet: z.Network,
DstNode: 0x00, // Any router for the dest network
SrcNet: port.MyAddr.Network,
SrcNode: port.MyAddr.Node,
SrcSocket: 2,
DstNet: 0x0000, // Local network broadcast
DstNode: 0xFF, // Broadcast node address within the dest network
DstSocket: 2,
Proto: ddp.ProtoNBP,
},
Data: nbpRaw,
}
outDDPRaw, err := ddp.ExtMarshal(outDDP)
if err != nil {
log.Printf("NBP: zone multicasting LkUp for tuple %v", tuple)
if err := outPort.ZoneMulticast(tuple.Zone, &outDDP); err != nil {
return err
}
log.Printf("NBP: Sending FwdReq to %v for tuple %v", peer.RemoteAddr, tuple)
if _, err := peer.Send(peer.Transport.NewAppleTalkPacket(outDDPRaw)); err != nil {
return fmt.Errorf("sending FwdReq on to peer: %w", err)
// But also...if we match the query, reply as though it was a LkUp
// This uses the *input* port information.
outDDP2, err := port.helloWorldThisIsMe(nbpkt.NBPID, tuple)
if err != nil {
return err
}
if outDDP2 == nil {
continue
}
log.Print("NBP: Replying to BrRq directly with LkUp-Reply for myself")
// Can reply to this BrRq on the same port we got it, because it
// wasn't routed
if err := port.Send(ctx, outDDP2); err != nil {
return err
}
continue
}
default:
return fmt.Errorf("TODO: handle function %v", nbpkt.Function)
}
// The zone table row is *not* for a local network.
// Translate it into a FwdReq and route that to the routers that do have
// that zone as a local network.
nbpkt.Function = nbp.FunctionFwdReq
nbpRaw, err := nbpkt.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal FwdReq: %v", err)
}
outDDP := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: atalk.DDPExtHeaderSize + uint16(len(nbpRaw)),
Cksum: 0,
SrcNet: ddpkt.SrcNet,
SrcNode: ddpkt.SrcNode,
SrcSocket: ddpkt.SrcSocket,
DstNet: z.Network,
DstNode: 0x00, // Any router for the dest network
DstSocket: 2,
Proto: ddp.ProtoNBP,
},
Data: nbpRaw,
}
if err := port.Router.Output(ctx, outDDP); err != nil {
return err
}
}
return nil
}
func (rtr *Router) helloWorldThisIsMe(ddpkt *ddp.ExtPacket, nbpID uint8, tuple *nbp.Tuple) (*ddp.ExtPacket, error) {
func (rtr *Router) handleNBPFwdReq(ctx context.Context, ddpkt *ddp.ExtPacket, nbpkt *nbp.Packet) error {
// A FwdReq was addressed to us. That means a remote router thinks the
// zone is available on one or more of our local networks.
// There must be 1!
tuple := &nbpkt.Tuples[0]
for _, outPort := range rtr.Ports {
if !slices.Contains(outPort.AvailableZones, tuple.Zone) {
continue
}
log.Printf("NBP: Converting FwdReq to LkUp (%v)", tuple)
// Convert it to a LkUp and broadcast on the corresponding port
nbpkt.Function = nbp.FunctionLkUp
nbpRaw, err := nbpkt.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal LkUp: %v", err)
}
// Inside AppleTalk SE, pp 8-20:
// "If the destination network is extended, however, the router must also
// change the destination network number to $0000, so that the packet is
// received by all nodes on the network (within the correct zone multicast
// address)."
ddpkt.DstNet = 0x0000
ddpkt.DstNode = 0xFF // Broadcast node address within the dest network
ddpkt.Data = nbpRaw
if err := outPort.ZoneMulticast(tuple.Zone, ddpkt); err != nil {
return err
}
// But also... if it matches us, reply directly with a LkUp-Reply of our own
outDDP, err := outPort.helloWorldThisIsMe(nbpkt.NBPID, tuple)
if err != nil || outDDP == nil {
return err
}
if err := rtr.Output(ctx, outDDP); err != nil {
return err
}
}
return nil
}
// Returns an NBP LkUp-Reply for the router itself, with the address from this port.
func (port *EtherTalkPort) helloWorldThisIsMe(nbpID uint8, tuple *nbp.Tuple) (*ddp.ExtPacket, error) {
if tuple.Object != "jrouter" && tuple.Object != "=" {
return nil, nil
}
if tuple.Type != "AppleRouter" && tuple.Type != "=" {
return nil, nil
}
if tuple.Zone != rtr.Config.EtherTalk.ZoneName && tuple.Zone != "*" && tuple.Zone != "" {
if tuple.Zone != port.DefaultZoneName && tuple.Zone != "*" && tuple.Zone != "" {
return nil, nil
}
respPkt := &nbp.Packet{
@ -172,13 +223,13 @@ func (rtr *Router) helloWorldThisIsMe(ddpkt *ddp.ExtPacket, nbpID uint8, tuple *
NBPID: nbpID,
Tuples: []nbp.Tuple{
{
Network: rtr.MyDDPAddr.Network,
Node: rtr.MyDDPAddr.Node,
Network: port.MyAddr.Network,
Node: port.MyAddr.Node,
Socket: 253,
Enumerator: 0,
Object: "jrouter",
Type: "AppleRouter",
Zone: rtr.Config.EtherTalk.ZoneName,
Zone: port.DefaultZoneName,
},
},
}
@ -186,15 +237,25 @@ func (rtr *Router) helloWorldThisIsMe(ddpkt *ddp.ExtPacket, nbpID uint8, tuple *
if err != nil {
return nil, fmt.Errorf("couldn't marshal LkUp-Reply: %v", err)
}
// Inside AppleTalk SE, pp 7-16:
// "In BrRq, FwdReq, and LkUp packets, which carry only a single tuple, the
// address field contains the internet address of the requester, allowing
// the responder to address the LkUp-Reply datagram."
// Inside AppleTalk SE, pp 8-20:
// "Note: NBP is defined so that the router's NBP process does not
// participate in the NBP response process; the response is sent directly to
// the original requester through DDP. It is important that the original
// requester's field be obtained from the address field of the NBP tuple."
return &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(respRaw)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: ddpkt.SrcNet,
DstNode: ddpkt.SrcNode,
DstSocket: ddpkt.SrcSocket,
SrcNet: rtr.MyDDPAddr.Network,
SrcNode: rtr.MyDDPAddr.Node,
DstNet: tuple.Network,
DstNode: tuple.Node,
DstSocket: tuple.Socket,
SrcNet: port.MyAddr.Network,
SrcNode: port.MyAddr.Node,
SrcSocket: 2,
Proto: ddp.ProtoNBP,
},

View file

@ -17,14 +17,14 @@
package router
import (
"context"
"fmt"
"log"
"gitea.drjosh.dev/josh/jrouter/atalk/nbp"
"github.com/sfiera/multitalk/pkg/ddp"
)
func (rtr *Router) HandleNBPInAURP(peer *AURPPeer, ddpkt *ddp.ExtPacket) error {
func (rtr *Router) HandleNBPFromAURP(ctx context.Context, ddpkt *ddp.ExtPacket) error {
if ddpkt.Proto != ddp.ProtoNBP {
return fmt.Errorf("invalid DDP type %d on socket 2", ddpkt.Proto)
}
@ -36,49 +36,5 @@ func (rtr *Router) HandleNBPInAURP(peer *AURPPeer, ddpkt *ddp.ExtPacket) error {
// It's something else??
return fmt.Errorf("can't handle %v", nbpkt.Function)
}
if len(nbpkt.Tuples) < 1 {
return fmt.Errorf("no tuples in NBP packet")
}
tuple := &nbpkt.Tuples[0]
if tuple.Zone != rtr.Config.EtherTalk.ZoneName {
return fmt.Errorf("FwdReq querying zone %q, which is not our zone", tuple.Zone)
}
// TODO: Route the FwdReq to another router if it's not our zone
log.Printf("NBP/DDP/AURP: Converting FwdReq to LkUp (%v)", tuple)
// Convert it to a LkUp and broadcast on EtherTalk
nbpkt.Function = nbp.FunctionLkUp
nbpRaw, err := nbpkt.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal LkUp: %v", err)
}
// "If the destination network is extended, however, the router must also
// change the destination network number to $0000, so that the packet is
// received by all nodes on the network (within the correct zone multicast
// address)."
ddpkt.DstNet = 0x0000
ddpkt.DstNode = 0xFF // Broadcast node address within the dest network
ddpkt.Data = nbpRaw
if err := rtr.ZoneMulticastEtherTalkDDP(tuple.Zone, ddpkt); err != nil {
return err
}
// But also... if it matches us, reply directly with a LkUp-Reply of our own
outDDP, err := rtr.helloWorldThisIsMe(ddpkt, nbpkt.NBPID, tuple)
if err != nil || outDDP == nil {
return err
}
log.Print("NBP/DDP/AURP: Replying to BrRq with LkUp-Reply for myself")
outDDPRaw, err := ddp.ExtMarshal(*outDDP)
if err != nil {
return err
}
_, err = peer.Send(peer.Transport.NewAppleTalkPacket(outDDPRaw))
return err
return rtr.handleNBPFwdReq(ctx, ddpkt, nbpkt)
}

View file

@ -115,7 +115,7 @@ type AURPPeer struct {
ReceiveCh chan aurp.Packet
// Routing table (the peer will add/remove/update routes)
RoutingTable *RoutingTable
RoutingTable *RouteTable
// Zone table (the peer will add/remove/update zones)
ZoneTable *ZoneTable
@ -125,6 +125,15 @@ type AURPPeer struct {
sstate SenderState
}
func (p *AURPPeer) Forward(ddpkt *ddp.ExtPacket) error {
outPkt, err := ddp.ExtMarshal(*ddpkt)
if err != nil {
return err
}
_, err = p.Send(p.Transport.NewAppleTalkPacket(outPkt))
return err
}
func (p *AURPPeer) ReceiverState() ReceiverState {
p.mu.RLock()
defer p.mu.RUnlock()
@ -596,7 +605,7 @@ func (p *AURPPeer) Handle(ctx context.Context) error {
case *aurp.ZIRspPacket:
log.Printf("AURP Peer: Learned about these zones: %v", pkt.Zones)
for _, zt := range pkt.Zones {
p.ZoneTable.Upsert(ddp.Network(zt.Network), zt.Name, false)
p.ZoneTable.Upsert(ddp.Network(zt.Network), zt.Name, nil)
}
case *aurp.GDZLReqPacket:

View file

@ -19,29 +19,25 @@ package router
import (
"context"
"github.com/google/gopacket/pcap"
"github.com/sfiera/multitalk/pkg/ddp"
"github.com/sfiera/multitalk/pkg/ethernet"
"github.com/sfiera/multitalk/pkg/ethertalk"
)
// EtherTalkPeer holds data needed to exchange routes and zones with another
// router on the EtherTalk network.
// EtherTalkPeer holds data needed to forward packets to another router on the
// EtherTalk network.
type EtherTalkPeer struct {
PcapHandle *pcap.Handle
MyHWAddr ethernet.Addr
AARP *AARPMachine
PeerAddr ddp.Addr
Port *EtherTalkPort
PeerAddr ddp.Addr
}
// Forward forwards a DDP packet to the next router.
func (p *EtherTalkPeer) Forward(ctx context.Context, pkt *ddp.ExtPacket) error {
// TODO: AARP resolution can block
de, err := p.AARP.Resolve(ctx, p.PeerAddr)
de, err := p.Port.AARPMachine.Resolve(ctx, p.PeerAddr)
if err != nil {
return err
}
outFrame, err := ethertalk.AppleTalk(p.MyHWAddr, *pkt)
outFrame, err := ethertalk.AppleTalk(p.Port.EthernetAddr, *pkt)
if err != nil {
return err
}
@ -50,5 +46,5 @@ func (p *EtherTalkPeer) Forward(ctx context.Context, pkt *ddp.ExtPacket) error {
if err != nil {
return err
}
return p.PcapHandle.WritePacketData(outFrameRaw)
return p.Port.PcapHandle.WritePacketData(outFrameRaw)
}

193
router/port.go Normal file
View file

@ -0,0 +1,193 @@
/*
Copyright 2024 Josh Deprez
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
package router
import (
"context"
"errors"
"io"
"log"
"gitea.drjosh.dev/josh/jrouter/atalk"
"github.com/google/gopacket/pcap"
"github.com/sfiera/multitalk/pkg/ddp"
"github.com/sfiera/multitalk/pkg/ethernet"
"github.com/sfiera/multitalk/pkg/ethertalk"
)
// EtherTalkPort is all the data and helpers needed for EtherTalk on one port.
type EtherTalkPort struct {
Device string
EthernetAddr ethernet.Addr
NetStart ddp.Network
NetEnd ddp.Network
MyAddr ddp.Addr
DefaultZoneName string
AvailableZones []string
PcapHandle *pcap.Handle
AARPMachine *AARPMachine
Router *Router
}
func (port *EtherTalkPort) Serve(ctx context.Context) {
for {
if ctx.Err() != nil {
return
}
rawPkt, _, err := port.PcapHandle.ReadPacketData()
if errors.Is(err, pcap.NextErrorTimeoutExpired) {
continue
}
if errors.Is(err, io.EOF) || errors.Is(err, pcap.NextErrorNoMorePackets) {
return
}
if err != nil {
log.Printf("Couldn't read AppleTalk / AARP packet data: %v", err)
return
}
ethFrame := new(ethertalk.Packet)
if err := ethertalk.Unmarshal(rawPkt, ethFrame); err != nil {
log.Printf("Couldn't unmarshal EtherTalk frame: %v", err)
continue
}
// Ignore if sent by me
if ethFrame.Src == port.EthernetAddr {
continue
}
switch ethFrame.SNAPProto {
case ethertalk.AARPProto:
// log.Print("Got an AARP frame")
port.AARPMachine.Handle(ctx, ethFrame)
case ethertalk.AppleTalkProto:
// log.Print("Got an AppleTalk frame")
ddpkt := new(ddp.ExtPacket)
if err := ddp.ExtUnmarshal(ethFrame.Payload, ddpkt); err != nil {
log.Printf("Couldn't unmarshal DDP packet: %v", err)
continue
}
// log.Printf("DDP: src (%d.%d s %d) dst (%d.%d s %d) proto %d data len %d",
// ddpkt.SrcNet, ddpkt.SrcNode, ddpkt.SrcSocket,
// ddpkt.DstNet, ddpkt.DstNode, ddpkt.DstSocket,
// ddpkt.Proto, len(ddpkt.Data))
// Glean address info for AMT, but only if SrcNet is our net
// (If it's not our net, then it was routed from elsewhere, and
// we'd be filling the AMT with entries for a router.)
if ddpkt.SrcNet >= port.NetStart && ddpkt.SrcNet <= port.NetEnd {
srcAddr := ddp.Addr{Network: ddpkt.SrcNet, Node: ddpkt.SrcNode}
port.AARPMachine.Learn(srcAddr, ethFrame.Src)
// log.Printf("DDP: Gleaned that %d.%d -> %v", srcAddr.Network, srcAddr.Node, ethFrame.Src)
}
// Packet for us? First, who am I?
myAddr, ok := port.AARPMachine.Address()
if !ok {
continue
}
port.MyAddr = myAddr.Proto
// Our network?
// "The network number 0 is reserved to mean unknown; by default
// it specifies the local network to which the node is
// connected. Packets whose destination network number is 0 are
// addressed to a node on the local network."
// TODO: more generic routing
if ddpkt.DstNet != 0 && !(ddpkt.DstNet >= port.NetStart && ddpkt.DstNet <= port.NetEnd) {
// Is it for a network in the routing table?
if err := port.Router.Forward(ctx, ddpkt); err != nil {
log.Printf("DDP: Couldn't forward packet: %v", err)
}
continue
}
// To me?
// "Node ID 0 indicates any router on the network"- I'm a router
// "node ID $FF indicates either a network-wide or zone-specific
// broadcast"- that's relevant
if ddpkt.DstNode != 0 && ddpkt.DstNode != 0xff && ddpkt.DstNode != myAddr.Proto.Node {
continue
}
switch ddpkt.DstSocket {
case 1: // The RTMP socket
if err := port.HandleRTMP(ctx, ddpkt); err != nil {
log.Printf("RTMP: Couldn't handle: %v", err)
}
case 2: // The NIS (name information socket / NBP socket)
if err := port.HandleNBP(ctx, ddpkt); err != nil {
log.Printf("NBP: Couldn't handle: %v", err)
}
case 4: // The AEP socket
if err := port.Router.HandleAEP(ctx, ddpkt); err != nil {
log.Printf("AEP: Couldn't handle: %v", err)
}
case 6: // The ZIS (zone information socket / ZIP socket)
if err := port.HandleZIP(ctx, ddpkt); err != nil {
log.Printf("ZIP: couldn't handle: %v", err)
}
default:
log.Printf("DDP: No handler for socket %d", ddpkt.DstSocket)
}
default:
log.Printf("Read unknown packet %s -> %s with payload %x", ethFrame.Src, ethFrame.Dst, ethFrame.Payload)
}
}
}
func (port *EtherTalkPort) Send(ctx context.Context, pkt *ddp.ExtPacket) error {
dstEth := ethertalk.AppleTalkBroadcast
if pkt.DstNode != 0xFF {
de, err := port.AARPMachine.Resolve(ctx, ddp.Addr{Network: pkt.DstNet, Node: pkt.DstNode})
if err != nil {
return err
}
dstEth = de
}
return port.send(dstEth, pkt)
}
func (port *EtherTalkPort) Broadcast(pkt *ddp.ExtPacket) error {
return port.send(ethertalk.AppleTalkBroadcast, pkt)
}
func (port *EtherTalkPort) ZoneMulticast(zone string, pkt *ddp.ExtPacket) error {
return port.send(atalk.MulticastAddr(zone), pkt)
}
func (port *EtherTalkPort) send(dstEth ethernet.Addr, pkt *ddp.ExtPacket) error {
outFrame, err := ethertalk.AppleTalk(port.EthernetAddr, *pkt)
if err != nil {
return err
}
outFrame.Dst = dstEth
outFrameRaw, err := ethertalk.Marshal(*outFrame)
if err != nil {
return err
}
return port.PcapHandle.WritePacketData(outFrameRaw)
}

View file

@ -35,8 +35,9 @@ type Route struct {
LastSeen time.Time
// Exactly one of the following should be set
AURPPeer *AURPPeer
EtherTalkPeer *EtherTalkPeer
AURPPeer *AURPPeer // Next hop is this peer router (over AURP)
EtherTalkPeer *EtherTalkPeer // Next hop is this peer router (over EtherTalk)
EtherTalkDirect *EtherTalkPort // Directly connected to this network (via EtherTalk)
}
func (r Route) LastSeenAgo() string {
@ -46,18 +47,33 @@ func (r Route) LastSeenAgo() string {
return fmt.Sprintf("%v ago", time.Since(r.LastSeen).Truncate(time.Millisecond))
}
type RoutingTable struct {
type RouteTable struct {
mu sync.Mutex
routes map[*Route]struct{}
}
func NewRoutingTable() *RoutingTable {
return &RoutingTable{
func NewRouteTable() *RouteTable {
return &RouteTable{
routes: make(map[*Route]struct{}),
}
}
func (rt *RoutingTable) Dump() []Route {
func (rt *RouteTable) InsertEtherTalkDirect(port *EtherTalkPort) {
r := &Route{
Extended: true,
NetStart: port.NetStart,
NetEnd: port.NetEnd,
Distance: 0, // we're connected directly
LastSeen: time.Now(),
EtherTalkDirect: port,
}
rt.mu.Lock()
defer rt.mu.Unlock()
rt.routes[r] = struct{}{}
}
func (rt *RouteTable) Dump() []Route {
rt.mu.Lock()
defer rt.mu.Unlock()
@ -68,7 +84,7 @@ func (rt *RoutingTable) Dump() []Route {
return table
}
func (rt *RoutingTable) LookupRoute(network ddp.Network) *Route {
func (rt *RouteTable) LookupRoute(network ddp.Network) *Route {
rt.mu.Lock()
defer rt.mu.Unlock()
@ -92,7 +108,7 @@ func (rt *RoutingTable) LookupRoute(network ddp.Network) *Route {
return bestRoute
}
func (rt *RoutingTable) DeleteAURPPeer(peer *AURPPeer) {
func (rt *RouteTable) DeleteAURPPeer(peer *AURPPeer) {
rt.mu.Lock()
defer rt.mu.Unlock()
@ -103,7 +119,7 @@ func (rt *RoutingTable) DeleteAURPPeer(peer *AURPPeer) {
}
}
func (rt *RoutingTable) DeleteAURPPeerNetwork(peer *AURPPeer, network ddp.Network) {
func (rt *RouteTable) DeleteAURPPeerNetwork(peer *AURPPeer, network ddp.Network) {
rt.mu.Lock()
defer rt.mu.Unlock()
@ -114,7 +130,7 @@ func (rt *RoutingTable) DeleteAURPPeerNetwork(peer *AURPPeer, network ddp.Networ
}
}
func (rt *RoutingTable) UpdateAURPRouteDistance(peer *AURPPeer, network ddp.Network, distance uint8) {
func (rt *RouteTable) UpdateAURPRouteDistance(peer *AURPPeer, network ddp.Network, distance uint8) {
rt.mu.Lock()
defer rt.mu.Unlock()
@ -126,7 +142,7 @@ func (rt *RoutingTable) UpdateAURPRouteDistance(peer *AURPPeer, network ddp.Netw
}
}
func (rt *RoutingTable) UpsertEthRoute(peer *EtherTalkPeer, extended bool, netStart, netEnd ddp.Network, metric uint8) error {
func (rt *RouteTable) UpsertEtherTalkRoute(peer *EtherTalkPeer, extended bool, netStart, netEnd ddp.Network, metric uint8) error {
if netStart > netEnd {
return fmt.Errorf("invalid network range [%d, %d]", netStart, netEnd)
}
@ -169,7 +185,7 @@ func (rt *RoutingTable) UpsertEthRoute(peer *EtherTalkPeer, extended bool, netSt
return nil
}
func (rt *RoutingTable) InsertAURPRoute(peer *AURPPeer, extended bool, netStart, netEnd ddp.Network, metric uint8) error {
func (rt *RouteTable) InsertAURPRoute(peer *AURPPeer, extended bool, netStart, netEnd ddp.Network, metric uint8) error {
if netStart > netEnd {
return fmt.Errorf("invalid network range [%d, %d]", netStart, netEnd)
}
@ -192,7 +208,7 @@ func (rt *RoutingTable) InsertAURPRoute(peer *AURPPeer, extended bool, netStart,
return nil
}
func (rt *RoutingTable) ValidRoutes() []*Route {
func (rt *RouteTable) ValidRoutes() []*Route {
rt.mu.Lock()
defer rt.mu.Unlock()
valid := make([]*Route, 0, len(rt.routes))

View file

@ -18,53 +18,56 @@ package router
import (
"context"
"fmt"
"gitea.drjosh.dev/josh/jrouter/atalk"
"github.com/google/gopacket/pcap"
"github.com/sfiera/multitalk/pkg/ddp"
"github.com/sfiera/multitalk/pkg/ethernet"
"github.com/sfiera/multitalk/pkg/ethertalk"
)
type Router struct {
Config *Config
PcapHandle *pcap.Handle
MyHWAddr ethernet.Addr
MyDDPAddr ddp.Addr
AARPMachine *AARPMachine
RouteTable *RoutingTable
ZoneTable *ZoneTable
Config *Config
RouteTable *RouteTable
ZoneTable *ZoneTable
Ports []*EtherTalkPort
}
func (rtr *Router) SendEtherTalkDDP(ctx context.Context, pkt *ddp.ExtPacket) error {
dstEth := ethertalk.AppleTalkBroadcast
if pkt.DstNode != 0xFF {
de, err := rtr.AARPMachine.Resolve(ctx, ddp.Addr{Network: pkt.DstNet, Node: pkt.DstNode})
if err != nil {
return err
}
dstEth = de
// Forward increments the hop count, then outputs the packet in the direction
// of the destination.
func (rtr *Router) Forward(ctx context.Context, ddpkt *ddp.ExtPacket) error {
// Check and adjust the Hop Count
// Note the ddp package doesn't make this simple
hopCount := (ddpkt.Size & 0x3C00) >> 10
if hopCount >= 15 {
return fmt.Errorf("hop count exceeded (%d >= 15)", hopCount)
}
return rtr.sendEtherTalkDDP(dstEth, pkt)
hopCount++
ddpkt.Size &^= 0x3C00
ddpkt.Size |= hopCount << 10
return rtr.Output(ctx, ddpkt)
}
func (rtr *Router) BroadcastEtherTalkDDP(pkt *ddp.ExtPacket) error {
return rtr.sendEtherTalkDDP(ethertalk.AppleTalkBroadcast, pkt)
}
// Output outputs the packet in the direction of the destination.
// (It does not check or adjust the hop count.)
func (rtr *Router) Output(ctx context.Context, ddpkt *ddp.ExtPacket) error {
switch route := rtr.RouteTable.LookupRoute(ddpkt.DstNet); {
case route == nil:
return fmt.Errorf("no route for packet (dstnet %d); dropping packet", ddpkt.DstNet)
func (rtr *Router) ZoneMulticastEtherTalkDDP(zone string, pkt *ddp.ExtPacket) error {
return rtr.sendEtherTalkDDP(atalk.MulticastAddr(zone), pkt)
}
case route.AURPPeer != nil:
// log.Printf("Forwarding packet to AURP peer %v", route.AURPPeer.RemoteAddr)
return route.AURPPeer.Forward(ddpkt)
func (rtr *Router) sendEtherTalkDDP(dstEth ethernet.Addr, pkt *ddp.ExtPacket) error {
outFrame, err := ethertalk.AppleTalk(rtr.MyHWAddr, *pkt)
if err != nil {
return err
case route.EtherTalkPeer != nil:
// log.Printf("Forwarding to EtherTalk peer %v", route.EtherTalkPeer.PeerAddr)
// Note: resolving AARP can block
return route.EtherTalkPeer.Forward(ctx, ddpkt)
case route.EtherTalkDirect != nil:
// log.Printf("Outputting to EtherTalk directly")
// Note: resolving AARP can block
return route.EtherTalkDirect.Send(ctx, ddpkt)
default:
return fmt.Errorf("no forwarding mechanism for route! %+v", route)
}
outFrame.Dst = dstEth
outFrameRaw, err := ethertalk.Marshal(*outFrame)
if err != nil {
return err
}
return rtr.PcapHandle.WritePacketData(outFrameRaw)
}

View file

@ -26,44 +26,131 @@ import (
"gitea.drjosh.dev/josh/jrouter/atalk/rtmp"
"gitea.drjosh.dev/josh/jrouter/status"
"github.com/google/gopacket/pcap"
"github.com/sfiera/multitalk/pkg/aarp"
"github.com/sfiera/multitalk/pkg/ddp"
"github.com/sfiera/multitalk/pkg/ethernet"
"github.com/sfiera/multitalk/pkg/ethertalk"
)
// RTMPMachine implements RTMP on an AppleTalk network attached to the router.
type RTMPMachine struct {
AARP *AARPMachine
Config *Config
PcapHandle *pcap.Handle
RoutingTable *RoutingTable
func (port *EtherTalkPort) HandleRTMP(ctx context.Context, pkt *ddp.ExtPacket) error {
switch pkt.Proto {
case ddp.ProtoRTMPReq:
// I can answer RTMP requests!
req, err := rtmp.UnmarshalRequestPacket(pkt.Data)
if err != nil {
return fmt.Errorf("unmarshal Request packet: %w", err)
}
switch req.Function {
case rtmp.FunctionRequest:
// Respond with RTMP Response
respPkt := &rtmp.ResponsePacket{
SenderAddr: port.MyAddr,
Extended: true,
RangeStart: port.NetStart,
RangeEnd: port.NetEnd,
}
respPktRaw, err := respPkt.Marshal()
if err != nil {
return fmt.Errorf("marshal RTMP Response packet: %w", err)
}
ddpPkt := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(respPktRaw)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: pkt.SrcNet,
DstNode: pkt.SrcNode,
DstSocket: 1, // the RTMP socket
SrcNet: port.MyAddr.Network,
SrcNode: port.MyAddr.Node,
SrcSocket: 1, // the RTMP socket
Proto: ddp.ProtoRTMPResp,
},
Data: respPktRaw,
}
if err := port.Router.Output(ctx, ddpPkt); err != nil {
return fmt.Errorf("send Response: %w", err)
}
case rtmp.FunctionRDRSplitHorizon, rtmp.FunctionRDRComplete:
// Like the Data broadcast, but solicited by a request (RDR).
splitHorizon := req.Function == rtmp.FunctionRDRSplitHorizon
for _, dataPkt := range port.rtmpDataPackets(splitHorizon) {
dataPktRaw, err := dataPkt.Marshal()
if err != nil {
return fmt.Errorf("marshal RTMP Data packet: %w", err)
}
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: port.MyAddr.Network,
SrcNode: port.MyAddr.Node,
SrcSocket: 1, // the RTMP socket
Proto: ddp.ProtoRTMPResp,
},
Data: dataPktRaw,
}
if err := port.Router.Output(ctx, ddpPkt); err != nil {
return fmt.Errorf("send Data: %w", err)
}
}
case rtmp.FunctionLoopProbe:
log.Print("RTMP: TODO: handle Loop Probes")
return nil
}
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{
Port: port,
PeerAddr: dataPkt.RouterAddr,
}
for _, rt := range dataPkt.NetworkTuples {
if err := port.Router.RouteTable.UpsertEtherTalkRoute(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)
}
return nil
}
// Run executes the machine.
func (m *RTMPMachine) Run(ctx context.Context, incomingCh <-chan *ddp.ExtPacket) error {
ctx, setStatus, done := status.AddSimpleItem(ctx, "RTMP")
defer done()
// RunRTMP makes periodic RTMP Data broadcasts on this port.
func (port *EtherTalkPort) RunRTMP(ctx context.Context) (err error) {
ctx, setStatus, _ := status.AddSimpleItem(ctx, "RTMP")
defer func() {
setStatus(fmt.Sprintf("Run loop stopped! Return: %v", err))
}()
setStatus("Awaiting DDP address assignment")
// Await local address assignment before doing anything
<-m.AARP.Assigned()
myAddr, ok := m.AARP.Address()
if !ok {
return fmt.Errorf("AARP machine closed Assigned channel but Address is not valid")
}
<-port.AARPMachine.Assigned()
setStatus("Initial RTMP Data broadcast")
// Initial broadcast
if err := m.broadcastData(myAddr); err != nil {
if err := port.broadcastRTMPData(); err != nil {
log.Printf("RTMP: Couldn't broadcast Data: %v", err)
}
setStatus("Packet loop")
setStatus("Starting broadcast loop")
bcastTicker := time.NewTicker(10 * time.Second)
defer bcastTicker.Stop()
@ -74,140 +161,18 @@ func (m *RTMPMachine) Run(ctx context.Context, incomingCh <-chan *ddp.ExtPacket)
return ctx.Err()
case <-bcastTicker.C:
if err := m.broadcastData(myAddr); err != nil {
log.Printf("RTMP: Couldn't broadcast Data: %v", err)
setStatus("Broadcasting RTMP Data")
if err := port.broadcastRTMPData(); err != nil {
st := fmt.Sprintf("Couldn't broadcast Data: %v", err)
setStatus(st)
log.Print(st)
}
case pkt := <-incomingCh:
switch pkt.Proto {
case ddp.ProtoRTMPReq:
// I can answer RTMP requests!
req, err := rtmp.UnmarshalRequestPacket(pkt.Data)
if err != nil {
log.Printf("RTMP: Couldn't unmarshal Request packet: %v", err)
}
// should be in the cache...
theirHWAddr, err := m.AARP.Resolve(ctx, ddp.Addr{Network: pkt.SrcNet, Node: pkt.SrcNode})
if err != nil {
log.Printf("RTMP: Couldn't resolve %d.%d to a hardware address: %v", pkt.SrcNet, pkt.SrcNode, err)
continue
}
switch req.Function {
case rtmp.FunctionRequest:
// Respond with RTMP Response
respPkt := &rtmp.ResponsePacket{
SenderAddr: myAddr.Proto,
Extended: true,
RangeStart: m.Config.EtherTalk.NetStart,
RangeEnd: m.Config.EtherTalk.NetEnd,
}
respPktRaw, err := respPkt.Marshal()
if err != nil {
log.Printf("RTMP: Couldn't marshal RTMP Response packet: %v", err)
continue
}
ddpPkt := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(respPktRaw)) + 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: respPktRaw,
}
if err := m.send(myAddr.Hardware, theirHWAddr, ddpPkt); err != nil {
log.Printf("RTMP: Couldn't send Data broadcast: %v", err)
}
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.AARP.myAddr.Hardware,
AARP: m.AARP,
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 {
ethFrame, err := ethertalk.AppleTalk(src, *ddpPkt)
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) {
func (port *EtherTalkPort) broadcastRTMPData() error {
for _, dataPkt := range port.rtmpDataPackets(true) {
dataPktRaw, err := dataPkt.Marshal()
if err != nil {
return fmt.Errorf("marshal Data packet: %v", err)
@ -217,29 +182,40 @@ func (m *RTMPMachine) broadcastData(myAddr aarp.AddrPair) error {
ExtHeader: ddp.ExtHeader{
Size: uint16(len(dataPktRaw)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: 0, // this network
DstNode: 0xff, // broadcast packet
DstSocket: 1, // the RTMP socket
SrcNet: myAddr.Proto.Network,
SrcNode: myAddr.Proto.Node,
DstNet: 0x0000, // this network
DstNode: 0xff, // broadcast packet
DstSocket: 1, // the RTMP socket
SrcNet: port.MyAddr.Network,
SrcNode: port.MyAddr.Node,
SrcSocket: 1, // the RTMP socket
Proto: ddp.ProtoRTMPResp,
},
Data: dataPktRaw,
}
if err := m.send(myAddr.Hardware, ethertalk.AppleTalkBroadcast, ddpPkt); err != nil {
if err := port.Broadcast(ddpPkt); err != nil {
return err
}
}
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.
routes := m.RoutingTable.ValidRoutes()
routes := port.Router.RouteTable.ValidRoutes()
tuples := make([]rtmp.NetworkTuple, 0, len(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 != nil && 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{
Extended: rt.Extended,
RangeStart: rt.NetStart,
@ -253,8 +229,8 @@ func (m *RTMPMachine) dataPackets(myAddr ddp.Addr) []*rtmp.DataPacket {
// TODO: support non-extended local networks (LocalTalk)
first := rtmp.NetworkTuple{
Extended: true,
RangeStart: m.Config.EtherTalk.NetStart,
RangeEnd: m.Config.EtherTalk.NetEnd,
RangeStart: port.NetStart,
RangeEnd: port.NetEnd,
Distance: 0,
}
@ -274,7 +250,7 @@ func (m *RTMPMachine) dataPackets(myAddr ddp.Addr) []*rtmp.DataPacket {
rem = rem[len(chunk)-1:]
packets = append(packets, &rtmp.DataPacket{
RouterAddr: myAddr,
RouterAddr: port.MyAddr,
Extended: true,
NetworkTuples: chunk,
})

View file

@ -20,266 +20,300 @@ import (
"context"
"fmt"
"log"
"slices"
"gitea.drjosh.dev/josh/jrouter/atalk"
"gitea.drjosh.dev/josh/jrouter/atalk/atp"
"gitea.drjosh.dev/josh/jrouter/atalk/zip"
"github.com/sfiera/multitalk/pkg/ddp"
"github.com/sfiera/multitalk/pkg/ethernet"
"github.com/sfiera/multitalk/pkg/ethertalk"
)
func (rtr *Router) HandleZIP(ctx context.Context, srcHWAddr ethernet.Addr, ddpkt *ddp.ExtPacket) error {
func (port *EtherTalkPort) HandleZIP(ctx context.Context, ddpkt *ddp.ExtPacket) error {
switch ddpkt.Proto {
case ddp.ProtoATP:
atpkt, err := atp.UnmarshalPacket(ddpkt.Data)
if err != nil {
return err
}
switch atpkt := atpkt.(type) {
case *atp.TReq:
gzl, err := zip.UnmarshalTReq(atpkt)
if err != nil {
return err
}
if gzl.StartIndex == 0 {
return fmt.Errorf("ZIP ATP: received request with StartIndex = 0 (invalid)")
}
resp := &zip.GetZonesReplyPacket{
TID: gzl.TID,
LastFlag: true,
}
switch gzl.Function {
case zip.FunctionGetZoneList:
resp.Zones = rtr.ZoneTable.AllNames()
case zip.FunctionGetLocalZones:
resp.Zones = rtr.ZoneTable.LocalNames()
case zip.FunctionGetMyZone:
resp.Zones = []string{rtr.Config.EtherTalk.ZoneName}
}
// Inside AppleTalk SE, pp 8-8
if int(gzl.StartIndex) > len(resp.Zones) {
// "Note: A 0-byte response will be returned by a router if the
// index specified in the request is greater than the index of
// the last zone in the list (and the user bytes field will
// indicate no more zones)."
resp.Zones = nil
} else {
// Trim the zones list
// "zone names in the router are assumed to be numbered starting
// with 1"
resp.Zones = resp.Zones[gzl.StartIndex-1:]
size := 0
for i, z := range resp.Zones {
size += 1 + len(z) // length prefix plus string
if size > atp.MaxDataSize {
resp.LastFlag = false
resp.Zones = resp.Zones[:i]
break
}
}
}
respATP, err := resp.MarshalTResp()
if err != nil {
return err
}
ddpBody, err := respATP.Marshal()
if err != nil {
return err
}
respDDP := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(ddpBody)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: ddpkt.SrcNet,
DstNode: ddpkt.SrcNode,
DstSocket: ddpkt.SrcSocket,
SrcNet: rtr.MyDDPAddr.Network,
SrcNode: rtr.MyDDPAddr.Node,
SrcSocket: 6,
Proto: ddp.ProtoATP,
},
Data: ddpBody,
}
return rtr.sendEtherTalkDDP(srcHWAddr, respDDP)
case *atp.TResp:
return fmt.Errorf("TODO: support handling ZIP ATP replies?")
default:
return fmt.Errorf("unsupported ATP packet type %T for ZIP", atpkt)
}
return port.handleZIPATP(ctx, ddpkt)
case ddp.ProtoZIP:
zipkt, err := zip.UnmarshalPacket(ddpkt.Data)
if err != nil {
return err
}
switch zipkt := zipkt.(type) {
case *zip.QueryPacket:
log.Printf("ZIP: Got Query for networks %v", zipkt.Networks)
networks := rtr.ZoneTable.Query(zipkt.Networks)
sendReply := func(resp *zip.ReplyPacket) error {
respRaw, err := resp.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal %T: %w", resp, err)
}
outDDP := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(respRaw)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: ddpkt.SrcNet,
DstNode: ddpkt.SrcNode,
DstSocket: ddpkt.SrcSocket,
SrcNet: rtr.MyDDPAddr.Network,
SrcNode: rtr.MyDDPAddr.Node,
SrcSocket: 6,
Proto: ddp.ProtoZIP,
},
Data: respRaw,
}
return rtr.sendEtherTalkDDP(srcHWAddr, outDDP)
}
// Inside AppleTalk SE, pp 8-11:
//
// "Replies (but not Extended Replies) can contain any number of
// zones lists, as long as the zones list for each network is
// entirely contained in the Reply packet."
//
// and
//
// "The zones list for a given network must be contiguous in the
// packet, with each zone name in that list preceded by the first
// network number in the range of the requested network."
size := 2
for _, zl := range networks {
for _, z := range zl {
size += 3 + len(z) // Network number, length byte, string
}
}
if size <= atalk.DDPMaxDataSize {
// Send one non-extended reply packet with all the data
log.Printf("ZIP: Replying with non-extended Reply: %v", networks)
return sendReply(&zip.ReplyPacket{
Extended: false,
// "Replies contain the number of zones lists indicated in
// the Reply header."
NetworkCount: uint8(len(networks)),
Networks: networks,
})
}
// Send Extended Reply packets, 1 or more for each network
//
// "Extended Replies can contain only one zones list."
for nn, zl := range networks {
rem := zl // rem: remaining zone names to send for this network
for len(rem) > 0 {
size := 2
var chunk []string // chunk: zone names to send now
for _, z := range rem {
size += 3 + len(z)
if size > atalk.DDPMaxDataSize {
break
}
chunk = append(chunk, z)
}
rem = rem[len(chunk):]
nets := map[ddp.Network][]string{
nn: chunk,
}
log.Printf("ZIP: Replying with Extended Reply: %v", nets)
err := sendReply(&zip.ReplyPacket{
Extended: true,
// "The network count in the header indicates, not the
// number of zones names in the packet, but the number
// of zone names in the entire zones list for the
// requested network, which may span more than one
// packet."
NetworkCount: uint8(len(zl)),
Networks: nets,
})
if err != nil {
return err
}
}
}
return nil
case *zip.GetNetInfoPacket:
log.Printf("ZIP: Got GetNetInfo for zone %q", zipkt.ZoneName)
// Only running a network with one zone for now.
resp := &zip.GetNetInfoReplyPacket{
ZoneInvalid: zipkt.ZoneName != rtr.Config.EtherTalk.ZoneName,
UseBroadcast: false,
OnlyOneZone: true,
NetStart: rtr.Config.EtherTalk.NetStart,
NetEnd: rtr.Config.EtherTalk.NetEnd,
ZoneName: zipkt.ZoneName, // has to match request
MulticastAddr: atalk.MulticastAddr(rtr.Config.EtherTalk.ZoneName),
DefaultZoneName: rtr.Config.EtherTalk.ZoneName,
}
log.Printf("ZIP: Replying with GetNetInfo-Reply: %+v", resp)
respRaw, err := resp.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal %T: %w", resp, err)
}
// "In cases where a node's provisional address is
// invalid, routers will not be able to respond to
// the node in a directed manner. An address is
// invalid if the network number is neither in the
// startup range nor in the network number range
// assigned to the node's network. In these cases,
// if the request was sent via a broadcast, the
// routers should respond with a broadcast."
outDDP := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(respRaw)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: ddpkt.SrcNet,
DstNode: ddpkt.SrcNode,
DstSocket: ddpkt.SrcSocket,
SrcNet: rtr.MyDDPAddr.Network,
SrcNode: rtr.MyDDPAddr.Node,
SrcSocket: 6,
Proto: ddp.ProtoZIP,
},
Data: respRaw,
}
if ddpkt.DstNet == 0x0000 {
outDDP.DstNet = 0x0000
}
if ddpkt.DstNode == 0xFF {
outDDP.DstNode = 0xFF
}
// If it's a broadcast packet, broadcast it. Otherwise don't
dstEth := ethertalk.AppleTalkBroadcast
if outDDP.DstNode != 0xFF {
dstEth = srcHWAddr
}
return rtr.sendEtherTalkDDP(dstEth, outDDP)
default:
return fmt.Errorf("TODO: handle type %T", zipkt)
}
return port.handleZIPZIP(ctx, ddpkt)
default:
return fmt.Errorf("invalid DDP type %d on socket 6", ddpkt.Proto)
}
}
func (port *EtherTalkPort) handleZIPZIP(ctx context.Context, ddpkt *ddp.ExtPacket) error {
zipkt, err := zip.UnmarshalPacket(ddpkt.Data)
if err != nil {
return err
}
switch zipkt := zipkt.(type) {
case *zip.QueryPacket:
return port.handleZIPQuery(ctx, ddpkt, zipkt)
case *zip.GetNetInfoPacket:
return port.handleZIPGetNetInfo(ctx, ddpkt, zipkt)
default:
return fmt.Errorf("TODO: handle type %T", zipkt)
}
}
func (port *EtherTalkPort) handleZIPQuery(ctx context.Context, ddpkt *ddp.ExtPacket, zipkt *zip.QueryPacket) error {
log.Printf("ZIP: Got Query for networks %v", zipkt.Networks)
networks := port.Router.ZoneTable.Query(zipkt.Networks)
sendReply := func(resp *zip.ReplyPacket) error {
respRaw, err := resp.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal %T: %w", resp, err)
}
outDDP := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(respRaw)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: ddpkt.SrcNet,
DstNode: ddpkt.SrcNode,
DstSocket: ddpkt.SrcSocket,
SrcNet: port.MyAddr.Network,
SrcNode: port.MyAddr.Node,
SrcSocket: 6,
Proto: ddp.ProtoZIP,
},
Data: respRaw,
}
// Note: AARP can block
return port.Send(ctx, outDDP)
}
// Inside AppleTalk SE, pp 8-11:
//
// "Replies (but not Extended Replies) can contain any number of
// zones lists, as long as the zones list for each network is
// entirely contained in the Reply packet."
//
// and
//
// "The zones list for a given network must be contiguous in the
// packet, with each zone name in that list preceded by the first
// network number in the range of the requested network."
size := 2
for _, zl := range networks {
for _, z := range zl {
size += 3 + len(z) // Network number, length byte, string
}
}
if size <= atalk.DDPMaxDataSize {
// Send one non-extended reply packet with all the data
log.Printf("ZIP: Replying with non-extended Reply: %v", networks)
return sendReply(&zip.ReplyPacket{
Extended: false,
// "Replies contain the number of zones lists indicated in
// the Reply header."
NetworkCount: uint8(len(networks)),
Networks: networks,
})
}
// Send Extended Reply packets, 1 or more for each network
//
// "Extended Replies can contain only one zones list."
for nn, zl := range networks {
rem := zl // rem: remaining zone names to send for this network
for len(rem) > 0 {
size := 2
var chunk []string // chunk: zone names to send now
for _, z := range rem {
size += 3 + len(z)
if size > atalk.DDPMaxDataSize {
break
}
chunk = append(chunk, z)
}
rem = rem[len(chunk):]
nets := map[ddp.Network][]string{
nn: chunk,
}
log.Printf("ZIP: Replying with Extended Reply: %v", nets)
err := sendReply(&zip.ReplyPacket{
Extended: true,
// "The network count in the header indicates, not the
// number of zones names in the packet, but the number
// of zone names in the entire zones list for the
// requested network, which may span more than one
// packet."
NetworkCount: uint8(len(zl)),
Networks: nets,
})
if err != nil {
return err
}
}
}
return nil
}
func (port *EtherTalkPort) handleZIPGetNetInfo(ctx context.Context, ddpkt *ddp.ExtPacket, zipkt *zip.GetNetInfoPacket) error {
log.Printf("ZIP: Got GetNetInfo for zone %q", zipkt.ZoneName)
// The request is zoneValid if the zone name is available on this network.
zoneValid := slices.Contains(port.AvailableZones, zipkt.ZoneName)
// The multicast address we return depends on the validity of the zone
// name.
var mcastAddr ethernet.Addr
if zoneValid {
mcastAddr = atalk.MulticastAddr(zipkt.ZoneName)
} else {
mcastAddr = atalk.MulticastAddr(port.DefaultZoneName)
}
resp := &zip.GetNetInfoReplyPacket{
ZoneInvalid: !zoneValid,
UseBroadcast: false,
OnlyOneZone: len(port.AvailableZones) == 1,
NetStart: port.NetStart,
NetEnd: port.NetEnd,
ZoneName: zipkt.ZoneName, // has to match request
MulticastAddr: mcastAddr,
}
// The default zone name is only returned if the requested zone name is
// invalid.
if !zoneValid {
resp.DefaultZoneName = port.DefaultZoneName
}
log.Printf("ZIP: Replying with GetNetInfo-Reply: %+v", resp)
respRaw, err := resp.Marshal()
if err != nil {
return fmt.Errorf("couldn't marshal %T: %w", resp, err)
}
// "In cases where a node's provisional address is
// invalid, routers will not be able to respond to
// the node in a directed manner. An address is
// invalid if the network number is neither in the
// startup range nor in the network number range
// assigned to the node's network. In these cases,
// if the request was sent via a broadcast, the
// routers should respond with a broadcast."
outDDP := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(respRaw)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: ddpkt.SrcNet,
DstNode: ddpkt.SrcNode,
DstSocket: ddpkt.SrcSocket,
SrcNet: port.MyAddr.Network,
SrcNode: port.MyAddr.Node,
SrcSocket: 6,
Proto: ddp.ProtoZIP,
},
Data: respRaw,
}
// If it arrived as a broadcast, send the reply as a broadcast.
if ddpkt.DstNet == 0x0000 {
outDDP.DstNet = 0x0000
}
if ddpkt.DstNode == 0xFF {
outDDP.DstNode = 0xFF
}
// Note: AARP can block
return port.Send(ctx, outDDP)
}
func (port *EtherTalkPort) handleZIPATP(ctx context.Context, ddpkt *ddp.ExtPacket) error {
atpkt, err := atp.UnmarshalPacket(ddpkt.Data)
if err != nil {
return err
}
switch atpkt := atpkt.(type) {
case *atp.TReq:
return port.handleZIPTReq(ctx, ddpkt, atpkt)
case *atp.TResp:
return fmt.Errorf("TODO: support handling ZIP ATP replies?")
default:
return fmt.Errorf("unsupported ATP packet type %T for ZIP", atpkt)
}
}
func (port *EtherTalkPort) handleZIPTReq(ctx context.Context, ddpkt *ddp.ExtPacket, atpkt *atp.TReq) error {
gzl, err := zip.UnmarshalTReq(atpkt)
if err != nil {
return err
}
if gzl.StartIndex == 0 {
return fmt.Errorf("ZIP ATP: received request with StartIndex = 0 (invalid)")
}
resp := &zip.GetZonesReplyPacket{
TID: gzl.TID,
LastFlag: true,
}
switch gzl.Function {
case zip.FunctionGetZoneList:
resp.Zones = port.Router.ZoneTable.AllNames()
case zip.FunctionGetLocalZones:
resp.Zones = port.AvailableZones
case zip.FunctionGetMyZone:
// Note: This shouldn't happen on extended networks (e.g. EtherTalk)
resp.Zones = []string{port.DefaultZoneName}
}
// Inside AppleTalk SE, pp 8-8
if int(gzl.StartIndex) > len(resp.Zones) {
// "Note: A 0-byte response will be returned by a router if the
// index specified in the request is greater than the index of
// the last zone in the list (and the user bytes field will
// indicate no more zones)."
resp.Zones = nil
} else {
// Trim the zones list
// "zone names in the router are assumed to be numbered starting
// with 1"
// and note we checked for 0 above
resp.Zones = resp.Zones[gzl.StartIndex-1:]
size := 0
for i, z := range resp.Zones {
size += 1 + len(z) // length prefix plus string
if size > atp.MaxDataSize {
resp.LastFlag = false
resp.Zones = resp.Zones[:i]
break
}
}
}
respATP, err := resp.MarshalTResp()
if err != nil {
return err
}
ddpBody, err := respATP.Marshal()
if err != nil {
return err
}
respDDP := &ddp.ExtPacket{
ExtHeader: ddp.ExtHeader{
Size: uint16(len(ddpBody)) + atalk.DDPExtHeaderSize,
Cksum: 0,
DstNet: ddpkt.SrcNet,
DstNode: ddpkt.SrcNode,
DstSocket: ddpkt.SrcSocket,
SrcNet: port.MyAddr.Network,
SrcNode: port.MyAddr.Node,
SrcSocket: 6,
Proto: ddp.ProtoATP,
},
Data: ddpBody,
}
// Note: AARP can block
return port.Send(ctx, respDDP)
}

View file

@ -29,10 +29,10 @@ import (
//const maxZoneAge = 10 * time.Minute // TODO: confirm
type Zone struct {
Network ddp.Network
Name string
Local bool
LastSeen time.Time
Network ddp.Network
Name string
LocalPort *EtherTalkPort // nil if remote (local to another router)
LastSeen time.Time
}
func (z Zone) LastSeenAgo() string {
@ -68,21 +68,21 @@ func (zt *ZoneTable) Dump() []Zone {
return zs
}
func (zt *ZoneTable) Upsert(network ddp.Network, name string, local bool) {
func (zt *ZoneTable) Upsert(network ddp.Network, name string, localPort *EtherTalkPort) {
zt.mu.Lock()
defer zt.mu.Unlock()
key := zoneKey{network, name}
z := zt.zones[key]
if z != nil {
z.Local = local
z.LocalPort = localPort
z.LastSeen = time.Now()
return
}
zt.zones[key] = &Zone{
Network: network,
Name: name,
Local: local,
LastSeen: time.Now(),
Network: network,
Name: name,
LocalPort: localPort,
LastSeen: time.Now(),
}
}
@ -116,29 +116,29 @@ func (zt *ZoneTable) LookupName(name string) []*Zone {
return zs
}
func (zt *ZoneTable) LocalNames() []string {
zt.mu.Lock()
seen := make(map[string]struct{})
zs := make([]string, 0, len(zt.zones))
for _, z := range zt.zones {
// if time.Since(z.LastSeen) > maxZoneAge {
// continue
// }
if !z.Local {
continue
}
if _, s := seen[z.Name]; s {
continue
}
seen[z.Name] = struct{}{}
zs = append(zs, z.Name)
// func (zt *ZoneTable) LocalNames() []string {
// zt.mu.Lock()
// seen := make(map[string]struct{})
// zs := make([]string, 0, len(zt.zones))
// for _, z := range zt.zones {
// // if time.Since(z.LastSeen) > maxZoneAge {
// // continue
// // }
// if z.Local != nil {
// continue
// }
// if _, s := seen[z.Name]; s {
// continue
// }
// seen[z.Name] = struct{}{}
// zs = append(zs, z.Name)
}
zt.mu.Unlock()
// }
// zt.mu.Unlock()
sort.Strings(zs)
return zs
}
// sort.Strings(zs)
// return zs
// }
func (zt *ZoneTable) AllNames() []string {
zt.mu.Lock()