// Copyright 2019 Tailscale & AUTHORS. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package magicsock implements a socket that can change its communication path while // in use, actively searching for the best way to communicate. package magicsock import ( "context" "encoding/binary" "errors" "fmt" "log" "net" "os" "strconv" "strings" "sync" "sync/atomic" "syscall" "time" "github.com/tailscale/wireguard-go/conn" "github.com/tailscale/wireguard-go/device" "github.com/tailscale/wireguard-go/wgcfg" "tailscale.com/derp" "tailscale.com/derp/derphttp" "tailscale.com/stun" "tailscale.com/stunner" "tailscale.com/types/key" ) // A Conn routes UDP packets and actively manages a list of its endpoints. // It implements wireguard/device.Bind. type Conn struct { pconn *RebindingUDPConn pconnPort uint16 privateKey key.Private stunServers []string startEpUpdate chan struct{} // send to trigger endpoint update epFunc func(endpoints []string) logf func(format string, args ...interface{}) donec chan struct{} // closed on Conn.Close epUpdateCtx context.Context // endpoint updater context epUpdateCancel func() // the func to cancel epUpdateCtx // indexedAddrs is a map of every remote ip:port to a priority // list of endpoint addresses for a peer. // The priority list is provided by wgengine configuration. // // Given a wgcfg describing: // machineA: 10.0.0.1:1, 10.0.0.2:2 // machineB: 10.0.0.3:3 // the indexedAddrs map contains: // 10.0.0.1:1 -> [10.0.0.1:1, 10.0.0.2:2], index:0 // 10.0.0.2:2 -> [10.0.0.1:1, 10.0.0.2:2], index:1 // 10.0.0.3:3 -> [10.0.0.3:3], index:0 indexedAddrsMu sync.Mutex indexedAddrs map[udpAddr]indexedAddrSet // stunReceiveFunc holds the current STUN packet processing func. // Its Loaded value is always non-nil. stunReceiveFunc atomic.Value // of func(p []byte, fromAddr *net.UDPAddr) udpRecvCh chan udpReadResult derpRecvCh chan derpReadResult derpMu sync.Mutex derpConn map[int]*derphttp.Client // magic derp port (see derpmap.go) to its client derpWriteCh map[int]chan<- derpWriteRequest } // udpAddr is the key in the indexedAddrs map. // It maps an ip:port onto an indexedAddr. type udpAddr struct { ip wgcfg.IP port uint16 } // indexedAddrSet is an AddrSet (a priority list of ip:ports for a peer and the // current favored ip:port for communicating with the peer) and an index // number saying which element of the priority list is this map entry. type indexedAddrSet struct { addr *AddrSet index int // index of map key in addr.Addrs } // DefaultPort is the default port to listen on. // The current default (zero) means to auto-select a random free port. const DefaultPort = 0 var DefaultSTUN = []string{ "stun.l.google.com:19302", "stun3.l.google.com:19302", } // Options contains options for Listen. type Options struct { // Port is the port to listen on. // Zero means to pick one automatically. Port uint16 STUN []string // EndpointsFunc optionally provides a func to be called when // endpoints change. The called func does not own the slice. EndpointsFunc func(endpoint []string) } func (o *Options) endpointsFunc() func([]string) { if o == nil || o.EndpointsFunc == nil { return func([]string) {} } return o.EndpointsFunc } // Listen creates a magic Conn listening on opts.Port. // As the set of possible endpoints for a Conn changes, the // callback opts.EndpointsFunc is called. func Listen(opts Options) (*Conn, error) { var packetConn net.PacketConn var err error if opts.Port == 0 { // Our choice of port. Start with DefaultPort. // If unavailable, pick any port. want := fmt.Sprintf(":%d", DefaultPort) log.Printf("magicsock: bind: trying %v\n", want) packetConn, err = net.ListenPacket("udp4", want) if err != nil { want = ":0" log.Printf("magicsock: bind: falling back to %v (%v)\n", want, err) packetConn, err = net.ListenPacket("udp4", want) } } else { packetConn, err = net.ListenPacket("udp4", fmt.Sprintf(":%d", opts.Port)) } if err != nil { return nil, fmt.Errorf("magicsock.Listen: %v", err) } epUpdateCtx, epUpdateCancel := context.WithCancel(context.Background()) c := &Conn{ pconn: new(RebindingUDPConn), pconnPort: opts.Port, donec: make(chan struct{}), stunServers: append([]string{}, opts.STUN...), startEpUpdate: make(chan struct{}, 1), epUpdateCtx: epUpdateCtx, epUpdateCancel: epUpdateCancel, epFunc: opts.endpointsFunc(), logf: log.Printf, indexedAddrs: make(map[udpAddr]indexedAddrSet), derpRecvCh: make(chan derpReadResult), udpRecvCh: make(chan udpReadResult), } c.ignoreSTUNPackets() c.pconn.Reset(packetConn.(*net.UDPConn)) c.reSTUN() go c.epUpdate(epUpdateCtx) return c, nil } // ignoreSTUNPackets sets a STUN packet processing func that does nothing. func (c *Conn) ignoreSTUNPackets() { c.stunReceiveFunc.Store(func([]byte, *net.UDPAddr) {}) } // epUpdate runs in its own goroutine until ctx is shut down. // Whenever c.startEpUpdate receives a value, it starts an // STUN endpoint lookup. func (c *Conn) epUpdate(ctx context.Context) { var lastEndpoints []string var lastCancel func() var lastDone chan struct{} for { select { case <-ctx.Done(): if lastCancel != nil { lastCancel() } return case <-c.startEpUpdate: } if lastCancel != nil { lastCancel() <-lastDone } var epCtx context.Context epCtx, lastCancel = context.WithCancel(ctx) lastDone = make(chan struct{}) go func() { defer close(lastDone) endpoints, err := c.determineEndpoints(epCtx) if err != nil { c.logf("magicsock.Conn: endpoint update failed: %v", err) // TODO(crawshaw): are there any conditions under which // we should trigger a retry based on the error here? return } if stringsEqual(endpoints, lastEndpoints) { return } lastEndpoints = endpoints c.epFunc(endpoints) }() } } // determineEndpoints returns the machine's endpoint addresses. It // does a STUN lookup to determine its public address. func (c *Conn) determineEndpoints(ctx context.Context) ([]string, error) { var ( alreadyMu sync.Mutex already = make(map[string]bool) // endpoint -> true ) var eps []string // unique endpoints addAddr := func(s, reason string) { log.Printf("magicsock: found local %s (%s)\n", s, reason) alreadyMu.Lock() defer alreadyMu.Unlock() if !already[s] { already[s] = true eps = append(eps, s) } } s := &stunner.Stunner{ Send: c.pconn.WriteTo, Endpoint: func(server, endpoint string, d time.Duration) { addAddr(endpoint, "stun") }, Servers: c.stunServers, Logf: c.logf, } c.stunReceiveFunc.Store(s.Receive) if err := s.Run(ctx); err != nil { return nil, err } c.ignoreSTUNPackets() if localAddr := c.pconn.LocalAddr(); localAddr.IP.IsUnspecified() { localPort := fmt.Sprintf("%d", localAddr.Port) loopbacks, err := localAddresses(localPort, func(s string) { addAddr(s, "localAddresses") }) if err != nil { return nil, err } if len(eps) == 0 { // Only include loopback addresses if we have no // interfaces at all to use as endpoints. This allows // for localhost testing when you're on a plane and // offline, for example. for _, s := range loopbacks { addAddr(s, "loopback") } } } else { // Our local endpoint is bound to a particular address. // Do not offer addresses on other local interfaces. addAddr(localAddr.String(), "socket") } // Note: the endpoints are intentionally returned in priority order, // from "farthest but most reliable" to "closest but least // reliable." Addresses returned from STUN should be globally // addressable, but might go farther on the network than necessary. // Local interface addresses might have lower latency, but not be // globally addressable. // // The STUN address(es) are always first so that legacy wireguard // can use eps[0] as its only known endpoint address (although that's // obviously non-ideal). return eps, nil } func stringsEqual(x, y []string) bool { if len(x) != len(y) { return false } for i := range x { if x[i] != y[i] { return false } } return true } func localAddresses(localPort string, addAddr func(s string)) ([]string, error) { var loopback []string // TODO(crawshaw): don't serve interface addresses that we are routing ifaces, err := net.Interfaces() if err != nil { return nil, err } for _, i := range ifaces { if (i.Flags & net.FlagUp) == 0 { // Down interfaces don't count continue } ifcIsLoopback := (i.Flags & net.FlagLoopback) != 0 addrs, err := i.Addrs() if err != nil { return nil, err } for _, a := range addrs { switch v := a.(type) { case *net.IPNet: // TODO(crawshaw): IPv6 support. // Easy to do here, but we need good endpoint ordering logic. ip := v.IP.To4() if ip == nil { continue } // TODO(apenwarr): don't special case cgNAT. // In the general wireguard case, it might // very well be something we can route to // directly, because both nodes are // behind the same CGNAT router. if cgNAT.Contains(ip) { continue } if linkLocalIPv4.Contains(ip) { continue } ep := net.JoinHostPort(ip.String(), localPort) if ip.IsLoopback() || ifcIsLoopback { loopback = append(loopback, ep) continue } addAddr(ep) } } } return loopback, nil } var cgNAT = func() *net.IPNet { _, ipNet, err := net.ParseCIDR("100.64.0.0/10") if err != nil { panic(err) } return ipNet }() var linkLocalIPv4 = func() *net.IPNet { _, ipNet, err := net.ParseCIDR("169.254.0.0/16") if err != nil { panic(err) } return ipNet }() func (c *Conn) LocalPort() uint16 { laddr := c.pconn.LocalAddr() return uint16(laddr.Port) } func shouldSprayPacket(b []byte) bool { if len(b) < 4 { return false } msgType := binary.LittleEndian.Uint32(b[:4]) switch msgType { case device.MessageInitiationType, device.MessageResponseType, device.MessageCookieReplyType: // TODO: necessary? return true } return false } var logPacketDests, _ = strconv.ParseBool(os.Getenv("DEBUG_LOG_PACKET_DESTS")) // appendDests appends to dsts the destinations that b should be // written to in order to reach as. Some of the returned UDPAddrs may // be fake addrs representing DERP servers. // // It also returns as's current roamAddr, if any. func appendDests(dsts []*net.UDPAddr, as *AddrSet, b []byte) (_ []*net.UDPAddr, roamAddr *net.UDPAddr) { spray := shouldSprayPacket(b) // true for handshakes now := time.Now() as.mu.Lock() defer as.mu.Unlock() // Spray logic. // // After exchanging a handshake with a peer, we send some outbound // packets to every endpoint of that peer. These packets are spaced out // over several seconds to make sure that our peer has an opportunity to // send its own spray packet to us before we are done spraying. // // Multiple packets are necessary because we have to both establish the // NAT mappings between two peers *and use* the mappings to switch away // from DERP to a higher-priority UDP endpoint. const sprayPeriod = 3 * time.Second const sprayFreq = 250 * time.Millisecond if spray { as.lastSpray = now as.stopSpray = now.Add(sprayPeriod) } else if now.Before(as.stopSpray) { // We are in the spray window. If it has been sprayFreq since we // last sprayed a packet, spray this packet. if now.Sub(as.lastSpray) >= sprayFreq { spray = true as.lastSpray = now } } // Pick our destination address(es). roamAddr = as.roamAddr if roamAddr != nil { dsts = append(dsts, roamAddr) if !spray { return dsts, roamAddr } } for i := len(as.addrs) - 1; i >= 0; i-- { addr := &as.addrs[i] if spray || as.curAddr == -1 || as.curAddr == i { dsts = append(dsts, addr) } if !spray && len(dsts) != 0 { break } } if logPacketDests { log.Printf("spray=%v; roam=%v; dests=%v", spray, roamAddr, dsts) } return dsts, roamAddr } var errNoDestinations = errors.New("magicsock: no destinations") func (c *Conn) Send(b []byte, ep conn.Endpoint) error { var as *AddrSet switch v := ep.(type) { default: panic(fmt.Sprintf("unexpected Endpoint type %T", v)) case *singleEndpoint: _, err := c.pconn.WriteTo(b, (*net.UDPAddr)(v)) return err case *AddrSet: as = v } var addrBuf [8]*net.UDPAddr dsts, roamAddr := appendDests(addrBuf[:0], as, b) if len(dsts) == 0 { return errNoDestinations } var success bool var ret error for _, addr := range dsts { err := c.sendAddr(addr, as.publicKey, b) if err == nil { success = true } else if ret == nil { ret = err } if err != nil && addr != roamAddr { log.Printf("magicsock: Conn.Send(%v): %v", addr, err) } } if success { return nil } return ret } var errConnClosed = errors.New("Conn closed") var errDropDerpPacket = errors.New("too many DERP packets queued; dropping") // sendAddr sends packet b to addr, which is either a real UDP address // or a fake UDP address representing a DERP server (see derpmap.go). // The provided public key identifies the recipient. func (c *Conn) sendAddr(addr *net.UDPAddr, pubKey key.Public, b []byte) error { if ch := c.derpWriteChanOfAddr(addr); ch != nil { errc := make(chan error, 1) select { case <-c.donec: return errConnClosed case ch <- derpWriteRequest{addr, pubKey, b, errc}: select { case <-c.donec: return errConnClosed case err := <-errc: return err // usually nil } default: // Too many writes queued. Drop packet. return errDropDerpPacket } } _, err := c.pconn.WriteTo(b, addr) return err } // bufferedDerpWritesBeforeDrop is how many packets writes can be // queued up the DERP client to write on the wire before we start // dropping. // // TODO: this is currently arbitrary. Figure out something better? const bufferedDerpWritesBeforeDrop = 4 // derpWriteChanOfAddr returns a DERP client for fake UDP addresses that // represent DERP servers, creating them as necessary. For real UDP // addresses, it returns nil. func (c *Conn) derpWriteChanOfAddr(addr *net.UDPAddr) chan<- derpWriteRequest { if !addr.IP.Equal(derpMagicIP) { return nil } c.derpMu.Lock() defer c.derpMu.Unlock() ch, ok := c.derpWriteCh[addr.Port] if !ok { if c.derpWriteCh == nil { c.derpWriteCh = make(map[int]chan<- derpWriteRequest) c.derpConn = make(map[int]*derphttp.Client) } host := derpHost(addr.Port) dc, err := derphttp.NewClient(c.privateKey, "https://"+host+"/derp", log.Printf) if err != nil { log.Printf("derphttp.NewClient: port %d, host %q invalid? err: %v", addr.Port, host, err) return nil } bidiCh := make(chan derpWriteRequest, bufferedDerpWritesBeforeDrop) ch = bidiCh c.derpConn[addr.Port] = dc c.derpWriteCh[addr.Port] = ch go c.runDerpReader(addr, dc) go c.runDerpWriter(addr, dc, bidiCh) } return ch } // derpReadResult is the type sent by runDerpClient to ReceiveIPv4 // when a DERP packet is available. type derpReadResult struct { derpAddr *net.UDPAddr n int // length of data received // copyBuf is called to copy the data to dst. It returns how // much data was copied, which will be n if dst is large // enough. copyBuf func(dst []byte) int } var logDerpVerbose, _ = strconv.ParseBool(os.Getenv("DEBUG_DERP_VERBOSE")) // runDerpReader runs in a goroutine for the life of a DERP // connection, handling received packets. func (c *Conn) runDerpReader(derpFakeAddr *net.UDPAddr, dc *derphttp.Client) { didCopy := make(chan struct{}, 1) var buf [derp.MaxPacketSize]byte var bufValid int // bytes in buf that are valid copyFn := func(dst []byte) int { n := copy(dst, buf[:bufValid]) didCopy <- struct{}{} return n } for { msg, err := dc.Recv(buf[:]) if err != nil { if err == derphttp.ErrClientClosed { return } select { case <-c.donec: return default: } log.Printf("derp.Recv: %v", err) time.Sleep(250 * time.Millisecond) continue } switch m := msg.(type) { case derp.ReceivedPacket: bufValid = len(m) default: // Ignore. // TODO: handle endpoint notification messages. continue } if logDerpVerbose { log.Printf("got derp %v packet: %q", derpFakeAddr, buf[:bufValid]) } select { case <-c.donec: return case c.derpRecvCh <- derpReadResult{derpFakeAddr, bufValid, copyFn}: <-didCopy } } } type derpWriteRequest struct { addr *net.UDPAddr pubKey key.Public b []byte errc chan<- error } // runDerpWriter runs in a goroutine for the life of a DERP // connection, handling received packets. func (c *Conn) runDerpWriter(derpFakeAddr *net.UDPAddr, dc *derphttp.Client, ch <-chan derpWriteRequest) { for { select { case <-c.donec: return case wr := <-ch: err := dc.Send(wr.pubKey, wr.b) if err != nil { log.Printf("magicsock: derp.Send(%v): %v", wr.addr, err) } select { case wr.errc <- err: case <-c.donec: return } } } } func (c *Conn) findIndexedAddrSet(addr *net.UDPAddr) (addrSet *AddrSet, index int) { var epAddr udpAddr copy(epAddr.ip.Addr[:], addr.IP.To16()) epAddr.port = uint16(addr.Port) c.indexedAddrsMu.Lock() defer c.indexedAddrsMu.Unlock() indAddr := c.indexedAddrs[epAddr] if indAddr.addr == nil { return nil, 0 } return indAddr.addr, indAddr.index } type udpReadResult struct { n int err error addr *net.UDPAddr } // aLongTimeAgo is a non-zero time, far in the past, used for // immediate cancellation of network operations. var aLongTimeAgo = time.Unix(233431200, 0) func (c *Conn) ReceiveIPv4(b []byte) (n int, ep conn.Endpoint, addr *net.UDPAddr, err error) { go func() { // Read a packet, and process any STUN packets before returning. for { var pAddr net.Addr n, pAddr, err = c.pconn.ReadFrom(b) if err != nil { select { case c.udpRecvCh <- udpReadResult{err: err}: case <-c.donec: } return } if stun.Is(b[:n]) { c.stunReceiveFunc.Load().(func([]byte, *net.UDPAddr))(b, addr) continue } addr := pAddr.(*net.UDPAddr) addr.IP = addr.IP.To4() select { case c.udpRecvCh <- udpReadResult{n: n, addr: addr}: case <-c.donec: } return } }() select { case dm := <-c.derpRecvCh: // Cancel the pconn read goroutine c.pconn.SetReadDeadline(aLongTimeAgo) select { case <-c.udpRecvCh: // It's likely an error, since we just canceled the read. // But there's a small window where the pconn.ReadFrom could've // succeeded but not yet sent, and we got into the derp recv path // first. In that case this udpReadResult is a real non-err packet // and we need to choose which to use. Currently, arbitrarily, we currently // select DERP and discard this result entirely. // The main point of this receive, though, is to make sure that the goroutine // is done with our b []byte buf. c.pconn.SetReadDeadline(time.Time{}) case <-c.donec: return 0, nil, nil, errors.New("Conn closed") } n, addr = dm.n, dm.derpAddr ncopy := dm.copyBuf(b) if ncopy != n { err = fmt.Errorf("received DERP packet of length %d that's too big for WireGuard ReceiveIPv4 buf size %d", n, ncopy) log.Printf("magicsock: %v", err) return 0, nil, nil, err } case um := <-c.udpRecvCh: if um.err != nil { return 0, nil, nil, err } n, addr = um.n, um.addr } addrSet, _ := c.findIndexedAddrSet(addr) if addrSet == nil { // The peer that sent this packet has roamed beyond the // knowledge provided by the control server. // If the packet is valid wireguard will call UpdateDst // on the original endpoint using this addr. return n, (*singleEndpoint)(addr), addr, nil } return n, addrSet, addr, nil } func (c *Conn) ReceiveIPv6(buff []byte) (int, conn.Endpoint, *net.UDPAddr, error) { // TODO(crawshaw): IPv6 support return 0, nil, nil, syscall.EAFNOSUPPORT } func (c *Conn) SetPrivateKey(privateKey wgcfg.PrivateKey) error { c.privateKey = key.Private(privateKey) return nil } func (c *Conn) SetMark(value uint32) error { return nil } func (c *Conn) LastMark() uint32 { return 0 } func (c *Conn) Close() error { select { case <-c.donec: return nil default: } close(c.donec) c.epUpdateCancel() for _, dc := range c.derpConn { dc.Close() } return c.pconn.Close() } func (c *Conn) reSTUN() { select { case c.startEpUpdate <- struct{}{}: case <-c.epUpdateCtx.Done(): } } func (c *Conn) LinkChange() { defer c.reSTUN() if c.pconnPort != 0 { c.pconn.mu.Lock() if err := c.pconn.pconn.Close(); err != nil { log.Printf("magicsock: link change close failed: %v", err) } packetConn, err := net.ListenPacket("udp4", fmt.Sprintf(":%d", c.pconnPort)) if err == nil { log.Printf("magicsock: link change rebound port: %d", c.pconnPort) c.pconn.pconn = packetConn.(*net.UDPConn) c.pconn.mu.Unlock() return } log.Printf("magicsock: link change unable to bind fixed port %d: %v, falling back to random port", c.pconnPort, err) c.pconn.mu.Unlock() } log.Printf("magicsock: link change, binding new port") packetConn, err := net.ListenPacket("udp4", ":0") if err != nil { log.Printf("magicsock: link change failed to bind new port: %v", err) return } c.pconn.Reset(packetConn.(*net.UDPConn)) } // AddrSet is a set of UDP addresses that implements wireguard/conn.Endpoint. type AddrSet struct { publicKey key.Public // peer public key used for DERP communication addrs []net.UDPAddr // ordered priority list (low to high) provided by wgengine mu sync.Mutex // guards following fields // roamAddr is non-nil if/when we receive a correctly signed // WireGuard packet from an unexpected address. If so, we // remember it and send responses there in the future, but // this should hopefully never be used (or at least used // rarely) in the case that all the components of Tailscale // are correctly learning/sharing the network map details. roamAddr *net.UDPAddr // curAddr is an index into addrs of the highest-priority // address a valid packet has been received from so far. // If no valid packet from addrs has been received, curAddr is -1. curAddr int // stopSpray is the time after which we stop spraying packets. stopSpray time.Time // lastSpray is the lsat time we sprayed a packet. lastSpray time.Time } var noAddr = &net.UDPAddr{ IP: net.ParseIP("127.127.127.127"), Port: 127, } func (a *AddrSet) dst() *net.UDPAddr { a.mu.Lock() defer a.mu.Unlock() if a.roamAddr != nil { return a.roamAddr } if len(a.addrs) == 0 { return noAddr } i := a.curAddr if i == -1 { i = 0 } return &a.addrs[i] } // packUDPAddr packs a UDPAddr in the form wanted by WireGuard. func packUDPAddr(ua *net.UDPAddr) []byte { ip := ua.IP.To4() if ip == nil { ip = ua.IP } b := make([]byte, 0, len(ip)+2) b = append(b, ip...) b = append(b, byte(ua.Port)) b = append(b, byte(ua.Port>>8)) return b } func (a *AddrSet) DstToBytes() []byte { return packUDPAddr(a.dst()) } func (a *AddrSet) DstToString() string { dst := a.dst() return dst.String() } func (a *AddrSet) DstIP() net.IP { return a.dst().IP } func (a *AddrSet) SrcIP() net.IP { return nil } func (a *AddrSet) SrcToString() string { return "" } func (a *AddrSet) ClearSrc() {} func (a *AddrSet) UpdateDst(new *net.UDPAddr) error { a.mu.Lock() defer a.mu.Unlock() if a.roamAddr != nil { if equalUDPAddr(a.roamAddr, new) { // Packet from the current roaming address, no logging. // This is a hot path for established connections. return nil } } else if a.curAddr >= 0 && equalUDPAddr(new, &a.addrs[a.curAddr]) { // Packet from current-priority address, no logging. // This is a hot path for established connections. return nil } index := -1 for i := range a.addrs { if equalUDPAddr(new, &a.addrs[i]) { index = i break } } publicKey := wgcfg.Key(a.publicKey) pk := publicKey.ShortString() old := "" if a.curAddr >= 0 { old = a.addrs[a.curAddr].String() } switch { case index == -1: if a.roamAddr == nil { log.Printf("magicsock: rx %s from roaming address %s, set as new priority", pk, new) } else { log.Printf("magicsock: rx %s from roaming address %s, replaces roaming address %s", pk, new, a.roamAddr) } a.roamAddr = new case a.roamAddr != nil: log.Printf("magicsock: rx %s from known %s (%d), replaces roaming address %s", pk, new, index, a.roamAddr) a.roamAddr = nil a.curAddr = index case a.curAddr == -1: log.Printf("magicsock: rx %s from %s (%d/%d), set as new priority", pk, new, index, len(a.addrs)) a.curAddr = index case index < a.curAddr: log.Printf("magicsock: rx %s from low-pri %s (%d), keeping current %s (%d)", pk, new, index, old, a.curAddr) default: // index > a.curAddr log.Printf("magicsock: rx %s from %s (%d/%d), replaces old priority %s", pk, new, index, len(a.addrs), old) a.curAddr = index } return nil } func equalUDPAddr(x, y *net.UDPAddr) bool { return x.Port == y.Port && x.IP.Equal(y.IP) } func (a *AddrSet) String() string { a.mu.Lock() defer a.mu.Unlock() buf := new(strings.Builder) buf.WriteByte('[') if a.roamAddr != nil { fmt.Fprintf(buf, "roam:%s:%d", a.roamAddr.IP, a.roamAddr.Port) } for i, addr := range a.addrs { if i > 0 || a.roamAddr != nil { buf.WriteString(", ") } fmt.Fprintf(buf, "%s:%d", addr.IP, addr.Port) if a.curAddr == i { buf.WriteByte('*') } } buf.WriteByte(']') return buf.String() } func (a *AddrSet) Addrs() []wgcfg.Endpoint { var eps []wgcfg.Endpoint for _, addr := range a.addrs { eps = append(eps, wgcfg.Endpoint{ Host: addr.IP.String(), Port: uint16(addr.Port), }) } a.mu.Lock() defer a.mu.Unlock() if a.roamAddr != nil { eps = append(eps, wgcfg.Endpoint{ Host: a.roamAddr.IP.String(), Port: uint16(a.roamAddr.Port), }) } return eps } // CreateEndpoint is called by WireGuard to connect to an endpoint. // The key is the public key of the peer and addrs is a // comma-separated list of UDP ip:ports. func (c *Conn) CreateEndpoint(key [32]byte, addrs string) (conn.Endpoint, error) { pk := wgcfg.Key(key) log.Printf("magicsock: CreateEndpoint: key=%s: %s", pk.ShortString(), addrs) a := &AddrSet{ publicKey: key, curAddr: -1, } if addrs != "" { for _, ep := range strings.Split(addrs, ",") { addr, err := net.ResolveUDPAddr("udp", ep) if err != nil { return nil, err } if ip4 := addr.IP.To4(); ip4 != nil { addr.IP = ip4 } a.addrs = append(a.addrs, *addr) } } c.indexedAddrsMu.Lock() for i, addr := range a.addrs { var epAddr udpAddr copy(epAddr.ip.Addr[:], addr.IP.To16()) epAddr.port = uint16(addr.Port) c.indexedAddrs[epAddr] = indexedAddrSet{ addr: a, index: i, } } c.indexedAddrsMu.Unlock() return a, nil } type singleEndpoint net.UDPAddr func (e *singleEndpoint) ClearSrc() {} func (e *singleEndpoint) DstIP() net.IP { return (*net.UDPAddr)(e).IP } func (e *singleEndpoint) SrcIP() net.IP { return nil } func (e *singleEndpoint) SrcToString() string { return "" } func (e *singleEndpoint) DstToString() string { return (*net.UDPAddr)(e).String() } func (e *singleEndpoint) DstToBytes() []byte { return packUDPAddr((*net.UDPAddr)(e)) } func (e *singleEndpoint) UpdateDst(dst *net.UDPAddr) error { return fmt.Errorf("magicsock.singleEndpoint(%s).UpdateDst(%s): should never be called", (*net.UDPAddr)(e), dst) } func (e *singleEndpoint) Addrs() []wgcfg.Endpoint { return []wgcfg.Endpoint{{ Host: e.IP.String(), Port: uint16(e.Port), }} } // RebindingUDPConn is a UDP socket that can be re-bound. // Unix has no notion of re-binding a socket, so we swap it out for a new one. type RebindingUDPConn struct { mu sync.Mutex pconn *net.UDPConn } func (c *RebindingUDPConn) Reset(pconn *net.UDPConn) { c.mu.Lock() old := c.pconn c.pconn = pconn c.mu.Unlock() if old != nil { old.Close() } } func (c *RebindingUDPConn) ReadFrom(b []byte) (int, net.Addr, error) { for { c.mu.Lock() pconn := c.pconn c.mu.Unlock() n, addr, err := pconn.ReadFrom(b) if err != nil { c.mu.Lock() pconn2 := c.pconn c.mu.Unlock() if pconn != pconn2 { continue } } return n, addr, err } } func (c *RebindingUDPConn) LocalAddr() *net.UDPAddr { c.mu.Lock() defer c.mu.Unlock() return c.pconn.LocalAddr().(*net.UDPAddr) } func (c *RebindingUDPConn) Close() error { c.mu.Lock() defer c.mu.Unlock() return c.pconn.Close() } func (c *RebindingUDPConn) SetReadDeadline(t time.Time) { c.mu.Lock() defer c.mu.Unlock() c.pconn.SetReadDeadline(t) } func (c *RebindingUDPConn) WriteToUDP(b []byte, addr *net.UDPAddr) (int, error) { for { c.mu.Lock() pconn := c.pconn c.mu.Unlock() n, err := pconn.WriteToUDP(b, addr) if err != nil { c.mu.Lock() pconn2 := c.pconn c.mu.Unlock() if pconn != pconn2 { continue } } return n, err } } func (c *RebindingUDPConn) WriteTo(b []byte, addr net.Addr) (int, error) { for { c.mu.Lock() pconn := c.pconn c.mu.Unlock() n, err := pconn.WriteTo(b, addr) if err != nil { c.mu.Lock() pconn2 := c.pconn c.mu.Unlock() if pconn != pconn2 { continue } } return n, err } }