package yggdrasil // This communicates with peers via UDP // It's not as well tested or debugged as the TCP transport // It's intended to use UDP, so debugging/optimzing this is a high priority // TODO? use golang.org/x/net/ipv6.PacketConn's ReadBatch and WriteBatch? // To send all chunks of a message / recv all available chunks in one syscall // That might be faster on supported platforms, but it needs investigation // Chunks are currently murged, but outgoing messages aren't chunked // This is just to support chunking in the future, if it's needed and debugged // Basically, right now we might send UDP packets that are too large // TODO remove old/unused code and better document live code import "net" import "time" import "sync" import "fmt" type udpInterface struct { core *Core sock *net.UDPConn // Or more general PacketConn? mutex sync.RWMutex // each conn has an owner goroutine conns map[connAddr]*connInfo } type connAddr struct { ip [16]byte port int zone string } func (c *connAddr) fromUDPAddr(u *net.UDPAddr) { copy(c.ip[:], u.IP.To16()) c.port = u.Port c.zone = u.Zone } func (c *connAddr) toUDPAddr() *net.UDPAddr { var u net.UDPAddr u.IP = make([]byte, 16) copy(u.IP, c.ip[:]) u.Port = c.port u.Zone = c.zone return &u } type connInfo struct { name string addr connAddr peer *peer linkIn chan []byte keysIn chan *udpKeys timeout int // count of how many heartbeats have been missed in func([]byte) out chan []byte countIn uint8 countOut uint8 } type udpKeys struct { box boxPubKey sig sigPubKey } func (iface *udpInterface) init(core *Core, addr string) { iface.core = core udpAddr, err := net.ResolveUDPAddr("udp", addr) if err != nil { panic(err) } iface.sock, err = net.ListenUDP("udp", udpAddr) if err != nil { panic(err) } iface.conns = make(map[connAddr]*connInfo) go iface.reader() } func (iface *udpInterface) sendKeys(addr connAddr) { udpAddr := addr.toUDPAddr() msg := []byte{} msg = udp_encode(msg, 0, 0, 0, nil) msg = append(msg, iface.core.boxPub[:]...) msg = append(msg, iface.core.sigPub[:]...) iface.sock.WriteToUDP(msg, udpAddr) } func udp_isKeys(msg []byte) bool { keyLen := 3 + boxPubKeyLen + sigPubKeyLen return len(msg) == keyLen && msg[0] == 0x00 } func (iface *udpInterface) startConn(info *connInfo) { ticker := time.NewTicker(6 * time.Second) defer ticker.Stop() defer func() { // Cleanup // FIXME this still leaks a peer struct iface.mutex.Lock() delete(iface.conns, info.addr) iface.mutex.Unlock() iface.core.peers.mutex.Lock() oldPorts := iface.core.peers.getPorts() newPorts := make(map[switchPort]*peer) for k, v := range oldPorts { newPorts[k] = v } delete(newPorts, info.peer.port) iface.core.peers.putPorts(newPorts) iface.core.peers.mutex.Unlock() close(info.linkIn) close(info.keysIn) close(info.out) iface.core.log.Println("Removing peer:", info.name) }() for { select { case ks := <-info.keysIn: { // FIXME? need signatures/sequence-numbers or something // Spoofers could lock out a peer with fake/bad keys if ks.box == info.peer.box && ks.sig == info.peer.sig { info.timeout = 0 } } case <-ticker.C: { if info.timeout > 10 { return } info.timeout++ iface.sendKeys(info.addr) } } } } func (iface *udpInterface) handleKeys(msg []byte, addr connAddr) { //defer util_putBytes(msg) var ks udpKeys _, _, _, bs := udp_decode(msg) switch { case !wire_chop_slice(ks.box[:], &bs): return case !wire_chop_slice(ks.sig[:], &bs): return } if ks.box == iface.core.boxPub { return } if ks.sig == iface.core.sigPub { return } iface.mutex.RLock() conn, isIn := iface.conns[addr] iface.mutex.RUnlock() if !isIn { udpAddr := addr.toUDPAddr() themNodeID := getNodeID(&ks.box) themAddr := address_addrForNodeID(themNodeID) themAddrString := net.IP(themAddr[:]).String() themString := fmt.Sprintf("%s@%s", themAddrString, udpAddr.String()) conn = &connInfo{ name: themString, addr: connAddr(addr), peer: iface.core.peers.newPeer(&ks.box, &ks.sig), linkIn: make(chan []byte, 1), keysIn: make(chan *udpKeys, 1), out: make(chan []byte, 32), } /* conn.in = func (msg []byte) { conn.peer.handlePacket(msg, conn.linkIn) } conn.peer.out = func (msg []byte) { start := time.Now() iface.sock.WriteToUDP(msg, udpAddr) timed := time.Since(start) conn.peer.updateBandwidth(len(msg), timed) util_putBytes(msg) } // Old version, always one syscall per packet //*/ /* conn.peer.out = func (msg []byte) { defer func() { recover() }() select { case conn.out<-msg: default: util_putBytes(msg) } } go func () { for msg := range conn.out { start := time.Now() iface.sock.WriteToUDP(msg, udpAddr) timed := time.Since(start) conn.peer.updateBandwidth(len(msg), timed) util_putBytes(msg) } }() //*/ //* var inChunks uint8 var inBuf []byte conn.in = func(bs []byte) { //defer util_putBytes(bs) chunks, chunk, count, payload := udp_decode(bs) //iface.core.log.Println("DEBUG:", addr, chunks, chunk, count, len(payload)) //iface.core.log.Println("DEBUG: payload:", payload) if count != conn.countIn { inChunks = 0 inBuf = inBuf[:0] conn.countIn = count } if chunk <= chunks && chunk == inChunks+1 { //iface.core.log.Println("GOING:", addr, chunks, chunk, count, len(payload)) inChunks += 1 inBuf = append(inBuf, payload...) if chunks != chunk { return } msg := append(util_getBytes(), inBuf...) conn.peer.handlePacket(msg, conn.linkIn) //iface.core.log.Println("DONE:", addr, chunks, chunk, count, len(payload)) } } conn.peer.out = func(msg []byte) { defer func() { recover() }() select { case conn.out <- msg: default: util_putBytes(msg) } } go func() { var out []byte var chunks [][]byte for msg := range conn.out { chunks = chunks[:0] bs := msg for len(bs) > udp_chunkSize { chunks, bs = append(chunks, bs[:udp_chunkSize]), bs[udp_chunkSize:] } chunks = append(chunks, bs) //iface.core.log.Println("DEBUG: out chunks:", len(chunks), len(msg)) if len(chunks) > 255 { continue } start := time.Now() for idx, bs := range chunks { nChunks, nChunk, count := uint8(len(chunks)), uint8(idx)+1, conn.countOut out = udp_encode(out[:0], nChunks, nChunk, count, bs) //iface.core.log.Println("DEBUG out:", nChunks, nChunk, count, len(bs)) iface.sock.WriteToUDP(out, udpAddr) } timed := time.Since(start) conn.countOut += 1 conn.peer.updateBandwidth(len(msg), timed) util_putBytes(msg) } }() //*/ iface.mutex.Lock() iface.conns[addr] = conn iface.mutex.Unlock() iface.core.log.Println("Adding peer:", conn.name) go iface.startConn(conn) go conn.peer.linkLoop(conn.linkIn) iface.sendKeys(conn.addr) } func() { defer func() { recover() }() select { case conn.keysIn <- &ks: default: } }() } func (iface *udpInterface) handlePacket(msg []byte, addr connAddr) { iface.mutex.RLock() if conn, isIn := iface.conns[addr]; isIn { conn.in(msg) } iface.mutex.RUnlock() } func (iface *udpInterface) reader() { bs := make([]byte, 2048) // This needs to be large enough for everything... for { //iface.core.log.Println("Starting read") n, udpAddr, err := iface.sock.ReadFromUDP(bs) //iface.core.log.Println("Read", n, udpAddr.String(), err) if err != nil { panic(err) break } if n > 1500 { panic(n) } //msg := append(util_getBytes(), bs[:n]...) msg := bs[:n] var addr connAddr addr.fromUDPAddr(udpAddr) if udp_isKeys(msg) { var them address copy(them[:], udpAddr.IP.To16()) if them.isValid() { continue } if udpAddr.IP.IsLinkLocalUnicast() && !iface.core.ifceExpr.MatchString(udpAddr.Zone) { continue } iface.handleKeys(msg, addr) } else { iface.handlePacket(msg, addr) } } } //////////////////////////////////////////////////////////////////////////////// const udp_chunkSize = 508 // Apparently the maximum guaranteed safe IPv4 size func udp_decode(bs []byte) (chunks, chunk, count uint8, payload []byte) { if len(bs) >= 3 { chunks, chunk, count, payload = bs[0], bs[1], bs[2], bs[3:] } return } func udp_encode(out []byte, chunks, chunk, count uint8, payload []byte) []byte { return append(append(out, chunks, chunk, count), payload...) }