// Copyright (c) 2019 Tailscale Inc & 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 ( "bufio" "context" crand "crypto/rand" "encoding/binary" "errors" "fmt" "hash/fnv" "math/rand" "net" "os" "reflect" "sort" "strconv" "strings" "sync" "sync/atomic" "syscall" "time" "github.com/golang/groupcache/lru" "github.com/tailscale/wireguard-go/conn" "github.com/tailscale/wireguard-go/device" "github.com/tailscale/wireguard-go/wgcfg" "go4.org/mem" "golang.org/x/crypto/nacl/box" "golang.org/x/time/rate" "inet.af/netaddr" "tailscale.com/control/controlclient" "tailscale.com/derp" "tailscale.com/derp/derphttp" "tailscale.com/disco" "tailscale.com/ipn/ipnstate" "tailscale.com/net/dnscache" "tailscale.com/net/interfaces" "tailscale.com/net/netcheck" "tailscale.com/net/netns" "tailscale.com/net/stun" "tailscale.com/syncs" "tailscale.com/tailcfg" "tailscale.com/types/key" "tailscale.com/types/logger" "tailscale.com/types/opt" "tailscale.com/types/structs" "tailscale.com/version" ) // A Conn routes UDP packets and actively manages a list of its endpoints. // It implements wireguard/conn.Bind. type Conn struct { pconnPort uint16 // the preferred port from opts.Port; 0 means auto pconn4 *RebindingUDPConn pconn6 *RebindingUDPConn // non-nil if IPv6 available epFunc func(endpoints []string) logf logger.Logf sendLogLimit *rate.Limiter netChecker *netcheck.Client idleFunc func() time.Duration // nil means unknown // bufferedIPv4From and bufferedIPv4Packet are owned by // ReceiveIPv4, and used when both a DERP and IPv4 packet arrive // at the same time. It stores the IPv4 packet for use in the next call. bufferedIPv4From netaddr.IPPort // if non-zero, then bufferedIPv4Packet is valid bufferedIPv4Packet []byte // the received packet (reused, owned by ReceiveIPv4) connCtx context.Context // closed on Conn.Close connCtxCancel func() // closes connCtx // 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 // ============================================================ mu sync.Mutex // guards all following fields started bool // Start was called closed bool // Close was called endpointsUpdateWaiter *sync.Cond endpointsUpdateActive bool wantEndpointsUpdate string // true if non-empty; string is reason lastEndpoints []string peerSet map[key.Public]struct{} discoPrivate key.Private discoPublic tailcfg.DiscoKey // public of discoPrivate discoShort string // ShortString of discoPublic (to save logging work later) nodeOfDisco map[tailcfg.DiscoKey]*tailcfg.Node discoOfNode map[tailcfg.NodeKey]tailcfg.DiscoKey discoOfAddr map[netaddr.IPPort]tailcfg.DiscoKey // validated non-DERP paths only endpointOfDisco map[tailcfg.DiscoKey]*discoEndpoint sharedDiscoKey map[tailcfg.DiscoKey]*[32]byte // nacl/box precomputed key // addrsByUDP 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 addrsByUDP map contains: // 10.0.0.1:1 -> [10.0.0.1:1, 10.0.0.2:2] // 10.0.0.2:2 -> [10.0.0.1:1, 10.0.0.2:2] // 10.0.0.3:3 -> [10.0.0.3:3] addrsByUDP map[netaddr.IPPort]*AddrSet // addrsByKey maps from public keys (as seen by incoming DERP // packets) to its AddrSet (the same values as in addrsByUDP). addrsByKey map[key.Public]*AddrSet netInfoFunc func(*tailcfg.NetInfo) // nil until set netInfoLast *tailcfg.NetInfo derpMap *tailcfg.DERPMap // nil (or zero regions/nodes) means DERP is disabled netMap *controlclient.NetworkMap privateKey key.Private myDerp int // nearest DERP region ID; 0 means none/unknown derpStarted chan struct{} // closed on first connection to DERP; for tests activeDerp map[int]activeDerp // DERP regionID -> connection to a node in that region prevDerp map[int]*syncs.WaitGroupChan // derpRoute contains optional alternate routes to use as an // optimization instead of contacting a peer via their home // DERP connection. If they sent us a message on a different // DERP connection (which should really only be on our DERP // home connection, or what was once our home), then we // remember that route here to optimistically use instead of // creating a new DERP connection back to their home. derpRoute map[key.Public]derpRoute // peerLastDerp tracks which DERP node we last used to speak with a // peer. It's only used to quiet logging, so we only log on change. peerLastDerp map[key.Public]int // noV4 and noV6 are whether IPv4 and IPv6 are known to be // missing. They're only used to suppress log spam. The name // is named negatively because in early start-up, we don't yet // necessarily have a netcheck.Report and don't want to skip // logging. noV4, noV6 syncs.AtomicBool } // derpRoute is a route entry for a public key, saying that a certain // peer should be available at DERP node derpID, as long as the // current connection for that derpID is dc. (but dc should not be // used to write directly; it's owned by the read/write loops) type derpRoute struct { derpID int dc *derphttp.Client // don't use directly; see comment above } // removeDerpPeerRoute removes a DERP route entry previously added by addDerpPeerRoute. func (c *Conn) removeDerpPeerRoute(peer key.Public, derpID int, dc *derphttp.Client) { c.mu.Lock() defer c.mu.Unlock() r2 := derpRoute{derpID, dc} if r, ok := c.derpRoute[peer]; ok && r == r2 { delete(c.derpRoute, peer) } } // addDerpPeerRoute adds a DERP route entry, noting that peer was seen // on DERP node derpID, at least on the connection identified by dc. // See issue 150 for details. func (c *Conn) addDerpPeerRoute(peer key.Public, derpID int, dc *derphttp.Client) { c.mu.Lock() defer c.mu.Unlock() if c.derpRoute == nil { c.derpRoute = make(map[key.Public]derpRoute) } r := derpRoute{derpID, dc} c.derpRoute[peer] = r } // DerpMagicIP is a fake WireGuard endpoint IP address that means // to use DERP. When used, the port number of the WireGuard endpoint // is the DERP server number to use. // // Mnemonic: 3.3.40 are numbers above the keys D, E, R, P. const DerpMagicIP = "127.3.3.40" var derpMagicIP = net.ParseIP(DerpMagicIP).To4() var derpMagicIPAddr = netaddr.IPv4(127, 3, 3, 40) // activeDerp contains fields for an active DERP connection. type activeDerp struct { c *derphttp.Client cancel context.CancelFunc writeCh chan<- derpWriteRequest // lastWrite is the time of the last request for its write // channel (currently even if there was no write). // It is always non-nil and initialized to a non-zero Time[ lastWrite *time.Time createTime time.Time } // DefaultPort is the default port to listen on. // The current default (zero) means to auto-select a random free port. const DefaultPort = 0 var DisableSTUNForTesting bool // Options contains options for Listen. type Options struct { // Logf optionally provides a log function to use. // Must not be nil. Logf logger.Logf // Port is the port to listen on. // Zero means to pick one automatically. Port uint16 // EndpointsFunc optionally provides a func to be called when // endpoints change. The called func does not own the slice. EndpointsFunc func(endpoint []string) // IdleFunc optionally provides a func to return how long // it's been since a TUN packet was sent or received. IdleFunc func() time.Duration } func (o *Options) logf() logger.Logf { if o.Logf == nil { panic("must provide magicsock.Options.logf") } return o.Logf } func (o *Options) endpointsFunc() func([]string) { if o == nil || o.EndpointsFunc == nil { return func([]string) {} } return o.EndpointsFunc } // newConn is the error-free, network-listening-side-effect-free based // of NewConn. Mostly for tests. func newConn() *Conn { c := &Conn{ sendLogLimit: rate.NewLimiter(rate.Every(1*time.Minute), 1), addrsByUDP: make(map[netaddr.IPPort]*AddrSet), addrsByKey: make(map[key.Public]*AddrSet), derpRecvCh: make(chan derpReadResult), udpRecvCh: make(chan udpReadResult), derpStarted: make(chan struct{}), peerLastDerp: make(map[key.Public]int), endpointOfDisco: make(map[tailcfg.DiscoKey]*discoEndpoint), sharedDiscoKey: make(map[tailcfg.DiscoKey]*[32]byte), discoOfAddr: make(map[netaddr.IPPort]tailcfg.DiscoKey), } c.endpointsUpdateWaiter = sync.NewCond(&c.mu) return c } // NewConn creates a magic Conn listening on opts.Port. // As the set of possible endpoints for a Conn changes, the // callback opts.EndpointsFunc is called. // // It doesn't start doing anything until Start is called. func NewConn(opts Options) (*Conn, error) { c := newConn() c.pconnPort = opts.Port c.logf = opts.logf() c.epFunc = opts.endpointsFunc() c.idleFunc = opts.IdleFunc if err := c.initialBind(); err != nil { return nil, err } c.connCtx, c.connCtxCancel = context.WithCancel(context.Background()) c.netChecker = &netcheck.Client{ Logf: logger.WithPrefix(c.logf, "netcheck: "), GetSTUNConn4: func() netcheck.STUNConn { return c.pconn4 }, } if c.pconn6 != nil { c.netChecker.GetSTUNConn6 = func() netcheck.STUNConn { return c.pconn6 } } c.ignoreSTUNPackets() return c, nil } func (c *Conn) Start() { c.mu.Lock() if c.started { panic("duplicate Start call") } c.started = true c.mu.Unlock() c.ReSTUN("initial") // We assume that LinkChange notifications are plumbed through well // on our mobile clients, so don't do the timer thing to save radio/battery/CPU/etc. if !version.IsMobile() { go c.periodicReSTUN() } go c.periodicDerpCleanup() } func (c *Conn) donec() <-chan struct{} { return c.connCtx.Done() } // ignoreSTUNPackets sets a STUN packet processing func that does nothing. func (c *Conn) ignoreSTUNPackets() { c.stunReceiveFunc.Store(func([]byte, netaddr.IPPort) {}) } // c.mu must NOT be held. func (c *Conn) updateEndpoints(why string) { defer func() { c.mu.Lock() defer c.mu.Unlock() why := c.wantEndpointsUpdate c.wantEndpointsUpdate = "" if why != "" && !c.closed { go c.updateEndpoints(why) } else { c.endpointsUpdateActive = false c.endpointsUpdateWaiter.Broadcast() } }() c.logf("magicsock: starting endpoint update (%s)", why) endpoints, reasons, err := c.determineEndpoints(c.connCtx) if err != nil { c.logf("magicsock: endpoint update (%s) failed: %v", why, err) // TODO(crawshaw): are there any conditions under which // we should trigger a retry based on the error here? return } if c.setEndpoints(endpoints) { c.logEndpointChange(endpoints, reasons) c.epFunc(endpoints) } } // setEndpoints records the new endpoints, reporting whether they're changed. // It takes ownership of the slice. func (c *Conn) setEndpoints(endpoints []string) (changed bool) { c.mu.Lock() defer c.mu.Unlock() if stringsEqual(endpoints, c.lastEndpoints) { return false } c.lastEndpoints = endpoints return true } func (c *Conn) updateNetInfo(ctx context.Context) (*netcheck.Report, error) { c.mu.Lock() dm := c.derpMap c.mu.Unlock() if DisableSTUNForTesting || dm == nil { return new(netcheck.Report), nil } ctx, cancel := context.WithTimeout(ctx, 2*time.Second) defer cancel() c.stunReceiveFunc.Store(c.netChecker.ReceiveSTUNPacket) defer c.ignoreSTUNPackets() report, err := c.netChecker.GetReport(ctx, dm) if err != nil { return nil, err } c.noV4.Set(!report.IPv4) c.noV6.Set(!report.IPv6) ni := &tailcfg.NetInfo{ DERPLatency: map[string]float64{}, MappingVariesByDestIP: report.MappingVariesByDestIP, HairPinning: report.HairPinning, } for rid, d := range report.RegionV4Latency { ni.DERPLatency[fmt.Sprintf("%d-v4", rid)] = d.Seconds() } for rid, d := range report.RegionV6Latency { ni.DERPLatency[fmt.Sprintf("%d-v6", rid)] = d.Seconds() } ni.WorkingIPv6.Set(report.IPv6) ni.WorkingUDP.Set(report.UDP) ni.PreferredDERP = report.PreferredDERP if ni.PreferredDERP == 0 { // Perhaps UDP is blocked. Pick a deterministic but arbitrary // one. ni.PreferredDERP = c.pickDERPFallback() } if !c.setNearestDERP(ni.PreferredDERP) { ni.PreferredDERP = 0 } // TODO: set link type c.callNetInfoCallback(ni) return report, nil } var processStartUnixNano = time.Now().UnixNano() // pickDERPFallback returns a non-zero but deterministic DERP node to // connect to. This is only used if netcheck couldn't find the // nearest one (for instance, if UDP is blocked and thus STUN latency // checks aren't working). // // c.mu must NOT be held. func (c *Conn) pickDERPFallback() int { c.mu.Lock() defer c.mu.Unlock() if !c.wantDerpLocked() { return 0 } ids := c.derpMap.RegionIDs() if len(ids) == 0 { // No DERP regions in non-nil map. return 0 } // See where our peers are. var ( peersOnDerp = map[int]int{} best int bestCount int ) for _, as := range c.addrsByKey { if id := as.derpID(); id != 0 { peersOnDerp[id]++ if v := peersOnDerp[id]; v > bestCount { bestCount = v best = id } } } // If we already had selected something in the past and it has // any peers, stay on it. If there are no peers, though, also // stay where we are. if c.myDerp != 0 && (best == 0 || peersOnDerp[c.myDerp] != 0) { return c.myDerp } // Otherwise pick wherever the most peers are. if best != 0 { return best } // Otherwise just pick something randomly. h := fnv.New64() h.Write([]byte(fmt.Sprintf("%p/%d", c, processStartUnixNano))) // arbitrary return ids[rand.New(rand.NewSource(int64(h.Sum64()))).Intn(len(ids))] } // callNetInfoCallback calls the NetInfo callback (if previously // registered with SetNetInfoCallback) if ni has substantially changed // since the last state. // // callNetInfoCallback takes ownership of ni. // // c.mu must NOT be held. func (c *Conn) callNetInfoCallback(ni *tailcfg.NetInfo) { c.mu.Lock() defer c.mu.Unlock() if ni.BasicallyEqual(c.netInfoLast) { return } c.netInfoLast = ni if c.netInfoFunc != nil { c.logf("magicsock: netInfo update: %+v", ni) go c.netInfoFunc(ni) } } func (c *Conn) SetNetInfoCallback(fn func(*tailcfg.NetInfo)) { if fn == nil { panic("nil NetInfoCallback") } c.mu.Lock() last := c.netInfoLast c.netInfoFunc = fn c.mu.Unlock() if last != nil { fn(last) } } // SetDiscoPrivateKey sets the discovery key. func (c *Conn) SetDiscoPrivateKey(k key.Private) { c.mu.Lock() defer c.mu.Unlock() if !c.discoPrivate.IsZero() && c.discoPrivate != k { // TODO: support changing a key at runtime; need to // clear a bunch of maps at least panic("unsupported") } c.discoPrivate = k c.discoPublic = tailcfg.DiscoKey(k.Public()) c.discoShort = c.discoPublic.ShortString() c.logf("magicsock: set disco key = %v", c.discoShort) } // c.mu must NOT be held. func (c *Conn) setNearestDERP(derpNum int) (wantDERP bool) { c.mu.Lock() defer c.mu.Unlock() if !c.wantDerpLocked() { c.myDerp = 0 return false } if derpNum == c.myDerp { // No change. return true } c.myDerp = derpNum if c.privateKey.IsZero() { // No private key yet, so DERP connections won't come up anyway. // Return early rather than ultimately log a couple lines of noise. return true } // On change, notify all currently connected DERP servers and // start connecting to our home DERP if we are not already. dr := c.derpMap.Regions[derpNum] if dr == nil { c.logf("[unexpected] magicsock: derpMap.Regions[%v] is nil", derpNum) } else { c.logf("magicsock: home is now derp-%v (%v)", derpNum, c.derpMap.Regions[derpNum].RegionCode) } for i, ad := range c.activeDerp { go ad.c.NotePreferred(i == c.myDerp) } c.goDerpConnect(derpNum) return true } // goDerpConnect starts a goroutine to start connecting to the given // DERP node. // // c.mu may be held, but does not need to be. func (c *Conn) goDerpConnect(node int) { if node == 0 { return } go c.derpWriteChanOfAddr(netaddr.IPPort{IP: derpMagicIPAddr, Port: uint16(node)}, key.Public{}) } var debugOmitLocalAddresses, _ = strconv.ParseBool(os.Getenv("TS_DEBUG_OMIT_LOCAL_ADDRS")) // determineEndpoints returns the machine's endpoint addresses. It // does a STUN lookup (via netcheck) to determine its public address. // // c.mu must NOT be held. func (c *Conn) determineEndpoints(ctx context.Context) (ipPorts []string, reasons map[string]string, err error) { nr, err := c.updateNetInfo(ctx) if err != nil { c.logf("magicsock.Conn.determineEndpoints: updateNetInfo: %v", err) return nil, nil, err } already := make(map[string]string) // endpoint -> how it was found var eps []string // unique endpoints addAddr := func(s, reason string) { if debugOmitLocalAddresses && (reason == "localAddresses" || reason == "socket") { return } if _, ok := already[s]; !ok { already[s] = reason eps = append(eps, s) } } if nr.GlobalV4 != "" { addAddr(nr.GlobalV4, "stun") } if nr.GlobalV6 != "" { addAddr(nr.GlobalV6, "stun") } c.ignoreSTUNPackets() if localAddr := c.pconn4.LocalAddr(); localAddr.IP.IsUnspecified() { ips, loopback, err := interfaces.LocalAddresses() if err != nil { return nil, nil, err } reason := "localAddresses" if len(ips) == 0 && len(eps) == 0 { // Only include loopback addresses if we have no // interfaces at all to use as endpoints and don't // have a public IPv4 or IPv6 address. This allows // for localhost testing when you're on a plane and // offline, for example. ips = loopback reason = "loopback" } for _, ipStr := range ips { addAddr(net.JoinHostPort(ipStr, fmt.Sprint(localAddr.Port)), reason) } } 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, already, 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 (c *Conn) LocalPort() uint16 { laddr := c.pconn4.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("TS_DEBUG_LOG_PACKET_DESTS")) var logDisco, _ = strconv.ParseBool(os.Getenv("TS_DEBUG_DISCO")) const sprayPeriod = 3 * time.Second // appendDests appends to dsts the destinations that b should be // written to in order to reach as. Some of the returned IPPorts may // be fake addrs representing DERP servers. // // It also returns as's current roamAddr, if any. func (as *AddrSet) appendDests(dsts []netaddr.IPPort, b []byte) (_ []netaddr.IPPort, roamAddr netaddr.IPPort) { spray := shouldSprayPacket(b) // true for handshakes now := as.timeNow() as.mu.Lock() defer as.mu.Unlock() // Some internal invariant checks. if len(as.addrs) != len(as.ipPorts) { panic(fmt.Sprintf("lena %d != leni %d", len(as.addrs), len(as.ipPorts))) } if n1, n2 := as.roamAddr != nil, as.roamAddrStd != nil; n1 != n2 { panic(fmt.Sprintf("roamnil %v != roamstdnil %v", n1, n2)) } // 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 sprayFreq = 250 * time.Millisecond if spray { as.lastSpray = now as.stopSpray = now.Add(sprayPeriod) // Reset our favorite route on new handshakes so we // can downgrade to a worse path if our better path // goes away. (https://github.com/tailscale/tailscale/issues/92) as.curAddr = -1 } 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). switch { case spray: // This packet is being sprayed to all addresses. for i := range as.ipPorts { dsts = append(dsts, as.ipPorts[i]) } if as.roamAddr != nil { dsts = append(dsts, *as.roamAddr) } case as.roamAddr != nil: // We have a roaming address, prefer it over other addrs. // TODO(danderson): this is not correct, there's no reason // roamAddr should be special like this. dsts = append(dsts, *as.roamAddr) case as.curAddr != -1: if as.curAddr >= len(as.addrs) { as.Logf("[unexpected] magicsock bug: as.curAddr >= len(as.addrs): %d >= %d", as.curAddr, len(as.addrs)) break } // No roaming addr, but we've seen packets from a known peer // addr, so keep using that one. dsts = append(dsts, as.ipPorts[as.curAddr]) default: // We know nothing about how to reach this peer, and we're not // spraying. Use the first address in the array, which will // usually be a DERP address that guarantees connectivity. if len(as.ipPorts) > 0 { dsts = append(dsts, as.ipPorts[0]) } } if logPacketDests { as.Logf("spray=%v; roam=%v; dests=%v", spray, as.roamAddr, dsts) } if as.roamAddr != nil { roamAddr = *as.roamAddr } 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 *discoEndpoint: return v.send(b) case *singleEndpoint: addr := (*net.UDPAddr)(v) if addr.IP.Equal(derpMagicIP) { c.logf("magicsock: [unexpected] DERP BUG: attempting to send packet to DERP address %v", addr) return nil } _, err := c.sendUDPStd(addr, b) return err case *AddrSet: as = v } var addrBuf [8]netaddr.IPPort dsts, roamAddr := as.appendDests(addrBuf[:0], b) if len(dsts) == 0 { return errNoDestinations } var success bool var ret error for _, addr := range dsts { sent, err := c.sendAddr(addr, as.publicKey, b) if sent { success = true } else if ret == nil { ret = err } if err != nil && addr != roamAddr && c.sendLogLimit.Allow() { if c.connCtx.Err() == nil { // don't log if we're closed c.logf("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") // sendUDP sends UDP packet b to ipp. // See sendAddr's docs on the return value meanings. func (c *Conn) sendUDP(ipp netaddr.IPPort, b []byte) (sent bool, err error) { ua := ipp.UDPAddr() defer netaddr.PutUDPAddr(ua) return c.sendUDPStd(ua, b) } // sendUDP sends UDP packet b to addr. // See sendAddr's docs on the return value meanings. func (c *Conn) sendUDPStd(addr *net.UDPAddr, b []byte) (sent bool, err error) { switch { case addr.IP.To4() != nil: _, err = c.pconn4.WriteTo(b, addr) if err != nil && c.noV4.Get() { return false, nil } case len(addr.IP) == net.IPv6len: if c.pconn6 == nil { // ignore IPv6 dest if we don't have an IPv6 address. return false, nil } _, err = c.pconn6.WriteTo(b, addr) if err != nil && c.noV6.Get() { return false, nil } default: panic("bogus sendUDPStd addr type") } return err == nil, err } // 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. // // The returned err is whether there was an error writing when it // should've worked. // The returned sent is whether a packet went out at all. // An example of when they might be different: sending to an // IPv6 address when the local machine doesn't have IPv6 support // returns (false, nil); it's not an error, but nothing was sent. func (c *Conn) sendAddr(addr netaddr.IPPort, pubKey key.Public, b []byte) (sent bool, err error) { if addr.IP != derpMagicIPAddr { return c.sendUDP(addr, b) } ch := c.derpWriteChanOfAddr(addr, pubKey) if ch == nil { return false, nil } // TODO(bradfitz): this makes garbage for now; we could use a // buffer pool later. Previously we passed ownership of this // to derpWriteRequest and waited for derphttp.Client.Send to // complete, but that's too slow while holding wireguard-go // internal locks. pkt := make([]byte, len(b)) copy(pkt, b) select { case <-c.donec(): return false, errConnClosed case ch <- derpWriteRequest{addr, pubKey, pkt}: return true, nil default: // Too many writes queued. Drop packet. return false, errDropDerpPacket } } // 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 = 32 // debugUseDerpRoute temporarily (2020-03-22) controls whether DERP // reverse routing is enabled (Issue 150). It will become always true // later. var debugUseDerpRoute, _ = strconv.ParseBool(os.Getenv("TS_DEBUG_ENABLE_DERP_ROUTE")) // derpWriteChanOfAddr returns a DERP client for fake UDP addresses that // represent DERP servers, creating them as necessary. For real UDP // addresses, it returns nil. // // If peer is non-zero, it can be used to find an active reverse // path, without using addr. func (c *Conn) derpWriteChanOfAddr(addr netaddr.IPPort, peer key.Public) chan<- derpWriteRequest { if addr.IP != derpMagicIPAddr { return nil } regionID := int(addr.Port) c.mu.Lock() defer c.mu.Unlock() if !c.wantDerpLocked() || c.closed { return nil } if c.privateKey.IsZero() { c.logf("magicsock: DERP lookup of %v with no private key; ignoring", addr) return nil } // See if we have a connection open to that DERP node ID // first. If so, might as well use it. (It's a little // arbitrary whether we use this one vs. the reverse route // below when we have both.) ad, ok := c.activeDerp[regionID] if ok { *ad.lastWrite = time.Now() c.setPeerLastDerpLocked(peer, regionID, regionID) return ad.writeCh } // If we don't have an open connection to the peer's home DERP // node, see if we have an open connection to a DERP node // where we'd heard from that peer already. For instance, // perhaps peer's home is Frankfurt, but they dialed our home DERP // node in SF to reach us, so we can reply to them using our // SF connection rather than dialing Frankfurt. (Issue 150) if !peer.IsZero() && debugUseDerpRoute { if r, ok := c.derpRoute[peer]; ok { if ad, ok := c.activeDerp[r.derpID]; ok && ad.c == r.dc { c.setPeerLastDerpLocked(peer, r.derpID, regionID) *ad.lastWrite = time.Now() return ad.writeCh } } } why := "home-keep-alive" if !peer.IsZero() { why = peerShort(peer) } c.logf("magicsock: adding connection to derp-%v for %v", regionID, why) firstDerp := false if c.activeDerp == nil { firstDerp = true c.activeDerp = make(map[int]activeDerp) c.prevDerp = make(map[int]*syncs.WaitGroupChan) } if c.derpMap == nil || c.derpMap.Regions[regionID] == nil { return nil } // Note that derphttp.NewClient does not dial the server // so it is safe to do under the mu lock. dc := derphttp.NewRegionClient(c.privateKey, c.logf, func() *tailcfg.DERPRegion { c.mu.Lock() defer c.mu.Unlock() if c.derpMap == nil { return nil } return c.derpMap.Regions[regionID] }) dc.NotePreferred(c.myDerp == regionID) dc.DNSCache = dnscache.Get() ctx, cancel := context.WithCancel(c.connCtx) ch := make(chan derpWriteRequest, bufferedDerpWritesBeforeDrop) ad.c = dc ad.writeCh = ch ad.cancel = cancel ad.lastWrite = new(time.Time) *ad.lastWrite = time.Now() ad.createTime = time.Now() c.activeDerp[regionID] = ad c.logActiveDerpLocked() c.setPeerLastDerpLocked(peer, regionID, regionID) // Build a startGate for the derp reader+writer // goroutines, so they don't start running until any // previous generation is closed. startGate := syncs.ClosedChan() if prev := c.prevDerp[regionID]; prev != nil { startGate = prev.DoneChan() } // And register a WaitGroup(Chan) for this generation. wg := syncs.NewWaitGroupChan() wg.Add(2) c.prevDerp[regionID] = wg if firstDerp { startGate = c.derpStarted go func() { dc.Connect(ctx) close(c.derpStarted) }() } go c.runDerpReader(ctx, addr, dc, wg, startGate) go c.runDerpWriter(ctx, dc, ch, wg, startGate) return ad.writeCh } // setPeerLastDerpLocked notes that peer is now being written to via // the provided DERP regionID, and that the peer advertises a DERP // home region ID of homeID. // // If there's any change, it logs. // // c.mu must be held. func (c *Conn) setPeerLastDerpLocked(peer key.Public, regionID, homeID int) { if peer.IsZero() { return } old := c.peerLastDerp[peer] if old == regionID { return } c.peerLastDerp[peer] = regionID var newDesc string switch { case regionID == homeID && regionID == c.myDerp: newDesc = "shared home" case regionID == homeID: newDesc = "their home" case regionID == c.myDerp: newDesc = "our home" case regionID != homeID: newDesc = "alt" } if old == 0 { c.logf("magicsock: derp route for %s set to derp-%d (%s)", peerShort(peer), regionID, newDesc) } else { c.logf("magicsock: derp route for %s changed from derp-%d => derp-%d (%s)", peerShort(peer), old, regionID, newDesc) } } // derpReadResult is the type sent by runDerpClient to ReceiveIPv4 // when a DERP packet is available. // // Notably, it doesn't include the derp.ReceivedPacket because we // don't want to give the receiver access to the aliased []byte. To // get at the packet contents they need to call copyBuf to copy it // out, which also releases the buffer. type derpReadResult struct { regionID int n int // length of data received src key.Public // may be zero until server deployment if v2+ // 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 can only be called once. 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(ctx context.Context, derpFakeAddr netaddr.IPPort, dc *derphttp.Client, wg *syncs.WaitGroupChan, startGate <-chan struct{}) { defer wg.Decr() defer dc.Close() select { case <-startGate: case <-ctx.Done(): return } didCopy := make(chan struct{}, 1) regionID := int(derpFakeAddr.Port) res := derpReadResult{regionID: regionID} var pkt derp.ReceivedPacket res.copyBuf = func(dst []byte) int { n := copy(dst, pkt.Data) didCopy <- struct{}{} return n } // peerPresent is the set of senders we know are present on this // connection, based on messages we've received from the server. peerPresent := map[key.Public]bool{} for { msg, err := dc.Recv() if err == derphttp.ErrClientClosed { return } if err != nil { // Forget that all these peers have routes. for peer := range peerPresent { delete(peerPresent, peer) c.removeDerpPeerRoute(peer, regionID, dc) } select { case <-ctx.Done(): return default: } c.ReSTUN("derp-close") c.logf("magicsock: [%p] derp.Recv(derp-%d): %v", dc, regionID, err) time.Sleep(250 * time.Millisecond) continue } switch m := msg.(type) { case derp.ReceivedPacket: pkt = m res.n = len(m.Data) res.src = m.Source if logDerpVerbose { c.logf("magicsock: got derp-%v packet: %q", regionID, m.Data) } // If this is a new sender we hadn't seen before, remember it and // register a route for this peer. if _, ok := peerPresent[m.Source]; !ok { peerPresent[m.Source] = true c.addDerpPeerRoute(m.Source, regionID, dc) } default: // Ignore. // TODO: handle endpoint notification messages. continue } select { case <-ctx.Done(): return case c.derpRecvCh <- res: <-didCopy } } } type derpWriteRequest struct { addr netaddr.IPPort pubKey key.Public b []byte // copied; ownership passed to receiver } // runDerpWriter runs in a goroutine for the life of a DERP // connection, handling received packets. func (c *Conn) runDerpWriter(ctx context.Context, dc *derphttp.Client, ch <-chan derpWriteRequest, wg *syncs.WaitGroupChan, startGate <-chan struct{}) { defer wg.Decr() select { case <-startGate: case <-ctx.Done(): return } for { select { case <-ctx.Done(): return case wr := <-ch: err := dc.Send(wr.pubKey, wr.b) if err != nil { c.logf("magicsock: derp.Send(%v): %v", wr.addr, err) } } } } // findEndpoint maps from a UDP address to a WireGuard endpoint, for // ReceiveIPv4/ReceiveIPv6. // The provided addr and ipp must match. // // TODO(bradfitz): add a fast path that returns nil here for normal // wireguard-go transport packets; IIRC wireguard-go only uses this // Endpoint for the relatively rare non-data packets. func (c *Conn) findEndpoint(ipp netaddr.IPPort, addr *net.UDPAddr) conn.Endpoint { c.mu.Lock() defer c.mu.Unlock() // See if they have a discoEndpoint, for a set of peers // both supporting active discovery. if dk, ok := c.discoOfAddr[ipp]; ok { if ep, ok := c.endpointOfDisco[dk]; ok { return ep } } // Pre-disco: look up their AddrSet. if as, ok := c.addrsByUDP[ipp]; ok { return as } // Pre-disco: 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 (*singleEndpoint)(addr) } type udpReadResult struct { _ structs.Incomparable n int err error addr *net.UDPAddr ipp netaddr.IPPort } // aLongTimeAgo is a non-zero time, far in the past, used for // immediate cancellation of network operations. var aLongTimeAgo = time.Unix(233431200, 0) // awaitUDP4 reads a single IPv4 UDP packet (or an error) and sends it // to c.udpRecvCh, skipping over (but handling) any STUN replies. func (c *Conn) awaitUDP4(b []byte) { for { n, pAddr, err := c.pconn4.ReadFrom(b) if err != nil { select { case c.udpRecvCh <- udpReadResult{err: err}: case <-c.donec(): } return } addr := pAddr.(*net.UDPAddr) ipp, ok := c.pconn4.ippCache.IPPort(addr) if !ok { continue } if stun.Is(b[:n]) { c.stunReceiveFunc.Load().(func([]byte, netaddr.IPPort))(b[:n], ipp) continue } if c.handleDiscoMessage(b[:n], ipp) { continue } select { case c.udpRecvCh <- udpReadResult{n: n, addr: addr, ipp: ipp}: case <-c.donec(): } return } } // wgRecvAddr returns the net.UDPAddr we tell wireguard-go the address // from which we received a packet for an endpoint. // // ipp is required. addr can be optionally provided. func wgRecvAddr(e conn.Endpoint, ipp netaddr.IPPort, addr *net.UDPAddr) *net.UDPAddr { if ipp == (netaddr.IPPort{}) { panic("zero ipp") } if de, ok := e.(*discoEndpoint); ok { return de.fakeWGAddrStd } if addr != nil { return addr } return ipp.UDPAddr() } func (c *Conn) ReceiveIPv4(b []byte) (n int, ep conn.Endpoint, addr *net.UDPAddr, err error) { Top: // First, process any buffered packet from earlier. if from := c.bufferedIPv4From; from != (netaddr.IPPort{}) { c.bufferedIPv4From = netaddr.IPPort{} addr = from.UDPAddr() ep := c.findEndpoint(from, addr) return copy(b, c.bufferedIPv4Packet), ep, wgRecvAddr(ep, from, addr), nil } go c.awaitUDP4(b) // Once the above goroutine has started, it owns b until it writes // to udpRecvCh. The code below must not access b until it's // completed a successful receive on udpRecvCh. var addrSet *AddrSet var discoEp *discoEndpoint var ipp netaddr.IPPort select { case dm := <-c.derpRecvCh: // Cancel the pconn read goroutine c.pconn4.SetReadDeadline(aLongTimeAgo) // Wait for the UDP-reading goroutine to be done, since it's currently // the owner of the b []byte buffer: select { case um := <-c.udpRecvCh: if um.err != nil { // The normal case. The SetReadDeadline interrupted // the read and we get an error which we now ignore. } else { // The pconn.ReadFrom succeeded and was about to send, // but DERP sent first. So now we have both ready. // Save the UDP packet away for use by the next // ReceiveIPv4 call. c.bufferedIPv4From = um.ipp c.bufferedIPv4Packet = append(c.bufferedIPv4Packet[:0], b[:um.n]...) } c.pconn4.SetReadDeadline(time.Time{}) case <-c.donec(): return 0, nil, nil, errors.New("Conn closed") } var regionID int n, regionID = dm.n, dm.regionID 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) c.logf("magicsock: %v", err) return 0, nil, nil, err } ipp = netaddr.IPPort{IP: derpMagicIPAddr, Port: uint16(regionID)} if c.handleDiscoMessage(b[:n], ipp) { goto Top } c.mu.Lock() if dk, ok := c.discoOfNode[tailcfg.NodeKey(dm.src)]; ok { discoEp = c.endpointOfDisco[dk] } if discoEp == nil { addrSet = c.addrsByKey[dm.src] } c.mu.Unlock() if addrSet == nil && discoEp == nil { key := wgcfg.Key(dm.src) c.logf("magicsock: DERP packet from unknown key: %s", key.ShortString()) } case um := <-c.udpRecvCh: if um.err != nil { return 0, nil, nil, err } n, addr, ipp = um.n, um.addr, um.ipp case <-c.donec(): // Socket has been shut down. All the producers of packets // respond to the context cancellation and go away, so we have // to also unblock and return an error, to inform wireguard-go // that this socket has gone away. // // Specifically, wireguard-go depends on its bind.Conn having // the standard socket behavior, which is that a Close() // unblocks any concurrent Read()s. wireguard-go itself calls // Clos() on magicsock, and expects ReceiveIPv4 to unblock // with an error so it can clean up. return 0, nil, nil, errors.New("socket closed") } if addrSet != nil { ep = addrSet } else if discoEp != nil { ep = discoEp } else { ep = c.findEndpoint(ipp, addr) } return n, ep, wgRecvAddr(ep, ipp, addr), nil } func (c *Conn) ReceiveIPv6(b []byte) (int, conn.Endpoint, *net.UDPAddr, error) { if c.pconn6 == nil { return 0, nil, nil, syscall.EAFNOSUPPORT } for { n, pAddr, err := c.pconn6.ReadFrom(b) if err != nil { return 0, nil, nil, err } addr := pAddr.(*net.UDPAddr) ipp, ok := c.pconn6.ippCache.IPPort(addr) if !ok { continue } if stun.Is(b[:n]) { c.stunReceiveFunc.Load().(func([]byte, netaddr.IPPort))(b[:n], ipp) continue } if c.handleDiscoMessage(b[:n], ipp) { continue } ep := c.findEndpoint(ipp, addr) return n, ep, wgRecvAddr(ep, ipp, addr), nil } } func (c *Conn) sendDiscoMessage(dst netaddr.IPPort, dstKey key.Public, dstDisco tailcfg.DiscoKey, m disco.Message) (sent bool, err error) { c.mu.Lock() var nonce [disco.NonceLen]byte if _, err := crand.Read(nonce[:]); err != nil { panic(err) // worth dying for } pkt := make([]byte, 0, 512) // TODO: size it correctly? pool? if it matters. pkt = append(pkt, disco.Magic...) pkt = append(pkt, c.discoPublic[:]...) pkt = append(pkt, nonce[:]...) sharedKey := c.sharedDiscoKeyLocked(dstDisco) c.mu.Unlock() pkt = box.SealAfterPrecomputation(pkt, m.AppendMarshal(nil), &nonce, sharedKey) sent, err = c.sendAddr(dst, dstKey, pkt) if sent { c.logf("magicsock: disco: %v->%v (%v, %v): %v", c.discoShort, dstDisco.ShortString(), dstKey.ShortString(), derpStr(dst.String()), disco.MessageSummary(m)) } else if err == nil { // Can't send. (e.g. no IPv6 locally) } else { c.logf("magicsock: disco: failed to send %T to %v: %v", m, dst, err) } return sent, err } // handleDiscoMessage reports whether msg was a Tailscale inter-node discovery message // that was handled. // // A discovery message has the form: // // * magic [6]byte // * senderDiscoPubKey [32]byte // * nonce [24]byte // * naclbox of payload (see tailscale.com/disco package for inner payload format) // // For messages received over DERP, the addr will be derpMagicIP (with // port being the region) func (c *Conn) handleDiscoMessage(msg []byte, src netaddr.IPPort) bool { const headerLen = len(disco.Magic) + len(tailcfg.DiscoKey{}) + disco.NonceLen if len(msg) < headerLen || string(msg[:len(disco.Magic)]) != disco.Magic { return false } var sender tailcfg.DiscoKey copy(sender[:], msg[len(disco.Magic):]) c.mu.Lock() defer c.mu.Unlock() if logDisco { c.logf("magicsock: disco: got disco-looking frame from %v", sender.ShortString()) } if c.discoPrivate.IsZero() { if logDisco { c.logf("magicsock: disco: ignoring disco-looking frame, no local key") } return false } de, ok := c.endpointOfDisco[sender] if !ok { if logDisco { c.logf("magicsock: disco: ignoring disco-looking frame, don't know about %v", sender.ShortString()) } // Returning false keeps passing it down, to WireGuard. // WireGuard will almost surely reject it, but give it a chance. return false } // First, do we even know (and thus care) about this sender? If not, // don't bother decrypting it. var nonce [disco.NonceLen]byte copy(nonce[:], msg[len(disco.Magic)+len(key.Public{}):]) sealedBox := msg[headerLen:] payload, ok := box.OpenAfterPrecomputation(nil, sealedBox, &nonce, c.sharedDiscoKeyLocked(sender)) if !ok { // This might be have been intended for a previous // disco key. When we restart we get a new disco key // and old packets might've still been in flight (or // scheduled). This is particularly the case for LANs // or non-NATed endpoints. // Don't log in normal case. Pass on to wireguard, in case // it's actually a a wireguard packet (super unlikely, // but). if logDisco { c.logf("magicsock: disco: failed to open naclbox from %v (wrong rcpt?)", sender) } // TODO(bradfitz): add some counter for this that logs rarely return false } dm, err := disco.Parse(payload) if logDisco { c.logf("magicsock: disco: disco.Parse = %T, %v", dm, err) } if err != nil { // Couldn't parse it, but it was inside a correctly // signed box, so just ignore it, assuming it's from a // newer version of Tailscale that we don't // understand. Not even worth logging about, lest it // be too spammy for old clients. // TODO(bradfitz): add some counter for this that logs rarely return true } switch dm := dm.(type) { case *disco.Ping: c.handlePingLocked(dm, de, src) case *disco.Pong: de.handlePongConnLocked(dm, src) case disco.CallMeMaybe: if src.IP != derpMagicIPAddr { // CallMeMaybe messages should only come via DERP. c.logf("[unexpected] CallMeMaybe packets should only come via DERP") return true } go de.handleCallMeMaybe() } return true } func (c *Conn) handlePingLocked(dm *disco.Ping, de *discoEndpoint, src netaddr.IPPort) { c.logf("magicsock: disco: %v<-%v (%v, %v) ping tx=%x", c.discoShort, de.discoKey.ShortString(), de.publicKey.ShortString(), src, dm.TxID) // Remember this this route if not present. c.setAddrToDiscoLocked(src, de.discoKey, nil) go de.sendDiscoMessage(src, &disco.Pong{ TxID: dm.TxID, Src: src, }) } // setAddrToDiscoLocked records that newk is at src. // // c.mu must be held. // // If the caller already has a discoEndpoint mutex held as well, it // can be passed in as alreadyLocked so it won't be re-acquired during // any lazy cleanup of the mapping. func (c *Conn) setAddrToDiscoLocked(src netaddr.IPPort, newk tailcfg.DiscoKey, alreadyLocked *discoEndpoint) { oldk, ok := c.discoOfAddr[src] if ok && oldk == newk { return } if ok { c.logf("magicsock: disco: changing mapping of %v from %x=>%x", src, oldk.ShortString(), newk.ShortString()) } else { c.logf("magicsock: disco: adding mapping of %v to %v", src, newk.ShortString()) } c.discoOfAddr[src] = newk if !ok { c.cleanDiscoOfAddrLocked(alreadyLocked) } } // cleanDiscoOfAddrLocked lazily checks a few entries in c.discoOfAddr // and deletes them if they're stale. It has no pointers in it so we // don't go through the effort of keeping it aggressively // pruned. Instead, we lazily clean it whenever it grows. // // c.mu must be held. // // If the caller already has a discoEndpoint mutex held as well, it // can be passed in as alreadyLocked so it won't be re-acquired. func (c *Conn) cleanDiscoOfAddrLocked(alreadyLocked *discoEndpoint) { // If it's small enough, don't worry about it. if len(c.discoOfAddr) < 16 { return } const checkEntries = 5 // per one unit of growth // Take advantage of Go's random map iteration to check & clean // a few entries. n := 0 for ipp, dk := range c.discoOfAddr { n++ if n > checkEntries { return } de, ok := c.endpointOfDisco[dk] if !ok { // This discokey isn't even known anymore. Clean. delete(c.discoOfAddr, ipp) continue } if de != alreadyLocked { de.mu.Lock() } if _, ok := de.endpointState[ipp]; !ok { // The discoEndpoint no longer knows about that endpoint. // It must've changed. Clean. delete(c.discoOfAddr, ipp) } if de != alreadyLocked { de.mu.Unlock() } } } func (c *Conn) sharedDiscoKeyLocked(k tailcfg.DiscoKey) *[32]byte { if v, ok := c.sharedDiscoKey[k]; ok { return v } shared := new([32]byte) box.Precompute(shared, key.Public(k).B32(), c.discoPrivate.B32()) c.sharedDiscoKey[k] = shared return shared } // SetPrivateKey sets the connection's private key. // // This is only used to be able prove our identity when connecting to // DERP servers. // // If the private key changes, any DERP connections are torn down & // recreated when needed. func (c *Conn) SetPrivateKey(privateKey wgcfg.PrivateKey) error { c.mu.Lock() defer c.mu.Unlock() oldKey, newKey := c.privateKey, key.Private(privateKey) if newKey == oldKey { return nil } c.privateKey = newKey if oldKey.IsZero() { c.logf("magicsock: SetPrivateKey called (init)") go c.ReSTUN("set-private-key") } else { c.logf("magicsock: SetPrivateKey called (changed") } c.closeAllDerpLocked("new-private-key") // Key changed. Close existing DERP connections and reconnect to home. if c.myDerp != 0 { c.logf("magicsock: private key changed, reconnecting to home derp-%d", c.myDerp) c.goDerpConnect(c.myDerp) } return nil } // UpdatePeers is called when the set of WireGuard peers changes. It // then removes any state for old peers. // // The caller passes ownership of newPeers map to UpdatePeers. func (c *Conn) UpdatePeers(newPeers map[key.Public]struct{}) { c.mu.Lock() defer c.mu.Unlock() oldPeers := c.peerSet c.peerSet = newPeers // Clean up any key.Public-keyed maps for peers that no longer // exist. for peer := range oldPeers { if _, ok := newPeers[peer]; !ok { delete(c.addrsByKey, peer) delete(c.derpRoute, peer) delete(c.peerLastDerp, peer) } } if len(oldPeers) == 0 && len(newPeers) > 0 { go c.ReSTUN("non-zero-peers") } } // SetDERPMap controls which (if any) DERP servers are used. // A nil value means to disable DERP; it's disabled by default. func (c *Conn) SetDERPMap(dm *tailcfg.DERPMap) { c.mu.Lock() defer c.mu.Unlock() if reflect.DeepEqual(dm, c.derpMap) { return } c.derpMap = dm if dm == nil { c.closeAllDerpLocked("derp-disabled") return } go c.ReSTUN("derp-map-update") } // SetNetworkMap is called when the control client gets a new network // map from the control server. // // It should not use the DERPMap field of NetworkMap; that's // conditionally sent to SetDERPMap instead. func (c *Conn) SetNetworkMap(nm *controlclient.NetworkMap) { c.mu.Lock() defer c.mu.Unlock() if reflect.DeepEqual(nm, c.netMap) { return } numDisco := 0 for _, n := range nm.Peers { if n.DiscoKey.IsZero() { continue } numDisco++ if ep, ok := c.endpointOfDisco[n.DiscoKey]; ok { ep.updateFromNode(n) } } c.logf("magicsock: got updated network map; %d peers (%d with discokey)", len(nm.Peers), numDisco) c.netMap = nm // Build and/or update node<->disco maps, only reallocating if // the set of discokeys changed. for pass := 1; pass <= 2; pass++ { if c.nodeOfDisco == nil || pass == 2 { c.nodeOfDisco = map[tailcfg.DiscoKey]*tailcfg.Node{} c.discoOfNode = map[tailcfg.NodeKey]tailcfg.DiscoKey{} } for _, n := range nm.Peers { if !n.DiscoKey.IsZero() { c.nodeOfDisco[n.DiscoKey] = n if old, ok := c.discoOfNode[n.Key]; ok && old != n.DiscoKey { c.logf("magicsock: node %s changed discovery key from %x to %x", n.Key.ShortString(), old[:8], n.DiscoKey[:8]) // TODO: reset AddrSet states, reset wireguard session key, etc. } c.discoOfNode[n.Key] = n.DiscoKey } } if len(c.nodeOfDisco) == numDisco && len(c.discoOfNode) == numDisco { break } } // Clean c.endpointOfDisco for discovery keys that are no longer present. for dk, de := range c.endpointOfDisco { if _, ok := c.nodeOfDisco[dk]; !ok { de.cleanup() delete(c.endpointOfDisco, dk) delete(c.sharedDiscoKey, dk) } } } func (c *Conn) wantDerpLocked() bool { return c.derpMap != nil } // c.mu must be held. func (c *Conn) closeAllDerpLocked(why string) { if len(c.activeDerp) == 0 { return // without the useless log statement } for i := range c.activeDerp { c.closeDerpLocked(i, why) } c.logActiveDerpLocked() } // c.mu must be held. // It is the responsibility of the caller to call logActiveDerpLocked after any set of closes. func (c *Conn) closeDerpLocked(node int, why string) { if ad, ok := c.activeDerp[node]; ok { c.logf("magicsock: closing connection to derp-%v (%v), age %v", node, why, time.Since(ad.createTime).Round(time.Second)) go ad.c.Close() ad.cancel() delete(c.activeDerp, node) } } // c.mu must be held. func (c *Conn) logActiveDerpLocked() { now := time.Now() c.logf("magicsock: %v active derp conns%s", len(c.activeDerp), logger.ArgWriter(func(buf *bufio.Writer) { if len(c.activeDerp) == 0 { return } buf.WriteString(":") c.foreachActiveDerpSortedLocked(func(node int, ad activeDerp) { fmt.Fprintf(buf, " derp-%d=cr%v,wr%v", node, simpleDur(now.Sub(ad.createTime)), simpleDur(now.Sub(*ad.lastWrite))) }) })) } func (c *Conn) logEndpointChange(endpoints []string, reasons map[string]string) { c.logf("magicsock: endpoints changed: %s", logger.ArgWriter(func(buf *bufio.Writer) { for i, ep := range endpoints { if i > 0 { buf.WriteString(", ") } fmt.Fprintf(buf, "%s (%s)", ep, reasons[ep]) } })) } // c.mu must be held. func (c *Conn) foreachActiveDerpSortedLocked(fn func(regionID int, ad activeDerp)) { if len(c.activeDerp) < 2 { for id, ad := range c.activeDerp { fn(id, ad) } return } ids := make([]int, 0, len(c.activeDerp)) for id := range c.activeDerp { ids = append(ids, id) } sort.Ints(ids) for _, id := range ids { fn(id, c.activeDerp[id]) } } func (c *Conn) cleanStaleDerp() { c.mu.Lock() defer c.mu.Unlock() const inactivityTime = 60 * time.Second tooOld := time.Now().Add(-inactivityTime) dirty := false for i, ad := range c.activeDerp { if i == c.myDerp { continue } if ad.lastWrite.Before(tooOld) { c.closeDerpLocked(i, "idle") dirty = true } } if dirty { c.logActiveDerpLocked() } } // DERPs reports the number of active DERP connections. func (c *Conn) DERPs() int { c.mu.Lock() defer c.mu.Unlock() return len(c.activeDerp) } func (c *Conn) SetMark(value uint32) error { return nil } func (c *Conn) LastMark() uint32 { return 0 } // Close closes the connection. // // Only the first close does anything. Any later closes return nil. func (c *Conn) Close() error { c.mu.Lock() if c.closed { c.mu.Unlock() return nil } defer c.mu.Unlock() c.closed = true c.connCtxCancel() c.closeAllDerpLocked("conn-close") if c.pconn6 != nil { c.pconn6.Close() } err := c.pconn4.Close() // Wait on endpoints updating right at the end, once everything is // already closed. We want everything else in the Conn to be // consistently in the closed state before we release mu to wait // on the endpoint updater. for c.endpointsUpdateActive { c.endpointsUpdateWaiter.Wait() } return err } var debugReSTUNStopOnIdle, _ = strconv.ParseBool(os.Getenv("TS_DEBUG_RESTUN_STOP_ON_IDLE")) func maxIdleBeforeSTUNShutdown() time.Duration { if debugReSTUNStopOnIdle { return time.Minute } return 5 * time.Minute } func (c *Conn) shouldDoPeriodicReSTUN() bool { c.mu.Lock() defer c.mu.Unlock() if len(c.peerSet) == 0 { // No peers, so not worth doing. return false } // If it turns out this optimization was a mistake, we can // override it from the control server without waiting for a // new software rollout: if c.netMap != nil && c.netMap.Debug != nil && c.netMap.Debug.ForceBackgroundSTUN && !debugReSTUNStopOnIdle { return true } if f := c.idleFunc; f != nil { idleFor := f() if debugReSTUNStopOnIdle { c.logf("magicsock: periodicReSTUN: idle for %v", idleFor.Round(time.Second)) } if idleFor > maxIdleBeforeSTUNShutdown() { if debugReSTUNStopOnIdle || version.IsMobile() { // TODO: make this unconditional later return false } } } return true } func (c *Conn) periodicReSTUN() { prand := rand.New(rand.NewSource(time.Now().UnixNano())) dur := func() time.Duration { // Just under 30s, a common UDP NAT timeout (Linux at least) return time.Duration(20+prand.Intn(7)) * time.Second } timer := time.NewTimer(dur()) defer timer.Stop() var lastIdleState opt.Bool for { select { case <-c.donec(): return case <-timer.C: doReSTUN := c.shouldDoPeriodicReSTUN() if !lastIdleState.EqualBool(doReSTUN) { if doReSTUN { c.logf("magicsock: periodicReSTUN enabled") } else { c.logf("magicsock: periodicReSTUN disabled due to inactivity") } lastIdleState.Set(doReSTUN) } if doReSTUN { c.ReSTUN("periodic") } timer.Reset(dur()) } } } func (c *Conn) periodicDerpCleanup() { ticker := time.NewTicker(15 * time.Second) // arbitrary defer ticker.Stop() for { select { case <-c.donec(): return case <-ticker.C: c.cleanStaleDerp() } } } // ReSTUN triggers an address discovery. // The provided why string is for debug logging only. func (c *Conn) ReSTUN(why string) { c.mu.Lock() defer c.mu.Unlock() if !c.started { panic("call to ReSTUN before Start") } if c.closed { // raced with a shutdown. return } if c.endpointsUpdateActive { if c.wantEndpointsUpdate != why { c.logf("magicsock: ReSTUN: endpoint update active, need another later (%q)", why) c.wantEndpointsUpdate = why } } else { c.endpointsUpdateActive = true go c.updateEndpoints(why) } } func (c *Conn) initialBind() error { if err := c.bind1(&c.pconn4, "udp4"); err != nil { return err } if err := c.bind1(&c.pconn6, "udp6"); err != nil { c.logf("magicsock: ignoring IPv6 bind failure: %v", err) } return nil } func (c *Conn) bind1(ruc **RebindingUDPConn, which string) error { host := "" if v, _ := strconv.ParseBool(os.Getenv("IN_TS_TEST")); v { host = "127.0.0.1" } var pc net.PacketConn var err error listenCtx := context.Background() // unused without DNS name to resolve if c.pconnPort == 0 && DefaultPort != 0 { pc, err = netns.Listener().ListenPacket(listenCtx, which, fmt.Sprintf("%s:%d", host, DefaultPort)) if err != nil { c.logf("magicsock: bind: default port %s/%v unavailable; picking random", which, DefaultPort) } } if pc == nil { pc, err = netns.Listener().ListenPacket(listenCtx, which, fmt.Sprintf("%s:%d", host, c.pconnPort)) } if err != nil { c.logf("magicsock: bind(%s/%v): %v", which, c.pconnPort, err) return fmt.Errorf("magicsock: bind: %s/%d: %v", which, c.pconnPort, err) } if *ruc == nil { *ruc = new(RebindingUDPConn) } (*ruc).Reset(pc.(*net.UDPConn)) return nil } // Rebind closes and re-binds the UDP sockets. // It should be followed by a call to ReSTUN. func (c *Conn) Rebind() { host := "" if v, _ := strconv.ParseBool(os.Getenv("IN_TS_TEST")); v { host = "127.0.0.1" } listenCtx := context.Background() // unused without DNS name to resolve if c.pconnPort != 0 { c.pconn4.mu.Lock() if err := c.pconn4.pconn.Close(); err != nil { c.logf("magicsock: link change close failed: %v", err) } packetConn, err := netns.Listener().ListenPacket(listenCtx, "udp4", fmt.Sprintf("%s:%d", host, c.pconnPort)) if err == nil { c.logf("magicsock: link change rebound port: %d", c.pconnPort) c.pconn4.pconn = packetConn.(*net.UDPConn) c.pconn4.mu.Unlock() return } c.logf("magicsock: link change unable to bind fixed port %d: %v, falling back to random port", c.pconnPort, err) c.pconn4.mu.Unlock() } c.logf("magicsock: link change, binding new port") packetConn, err := netns.Listener().ListenPacket(listenCtx, "udp4", host+":0") if err != nil { c.logf("magicsock: link change failed to bind new port: %v", err) return } c.pconn4.Reset(packetConn.(*net.UDPConn)) c.mu.Lock() c.closeAllDerpLocked("rebind") c.mu.Unlock() c.goDerpConnect(c.myDerp) c.resetAddrSetStates() } // resetAddrSetStates resets the preferred address for all peers and // re-enables spraying. // This is called when connectivity changes enough that we no longer // trust the old routes. func (c *Conn) resetAddrSetStates() { c.mu.Lock() defer c.mu.Unlock() for _, as := range c.addrsByKey { as.curAddr = -1 as.stopSpray = as.timeNow().Add(sprayPeriod) } for _, de := range c.endpointOfDisco { de.noteConnectivityChange() } } // AddrSet is a set of UDP addresses that implements wireguard/conn.Endpoint. // // This is the legacy endpoint for peers that don't support discovery; // it predates discoEndpoint. type AddrSet struct { publicKey key.Public // peer public key used for DERP communication // addrs is an ordered priority list provided by wgengine, // sorted from expensive+slow+reliable at the begnining to // fast+cheap at the end. More concretely, it's typically: // // [DERP fakeip:node, Global IP:port, LAN ip:port] // // But there could be multiple or none of each. addrs []net.UDPAddr ipPorts []netaddr.IPPort // same as addrs, in different form // clock, if non-nil, is used in tests instead of time.Now. clock func() time.Time Logf logger.Logf // must not be nil 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 *netaddr.IPPort roamAddrStd *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 last time we sprayed a packet. lastSpray time.Time // loggedLogPriMask is a bit field of that tracks whether // we've already logged about receiving a packet from a low // priority ("low-pri") address when we already have curAddr // set to a better one. This is only to suppress some // redundant logs. loggedLogPriMask uint32 } // derpID returns this AddrSet's home DERP node, or 0 if none is found. func (as *AddrSet) derpID() int { for _, ua := range as.addrs { if ua.IP.Equal(derpMagicIP) { return ua.Port } } return 0 } func (as *AddrSet) timeNow() time.Time { if as.clock != nil { return as.clock() } return time.Now() } var noAddr, _ = netaddr.FromStdAddr(net.ParseIP("127.127.127.127"), 127, "") func (a *AddrSet) dst() netaddr.IPPort { 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.ipPorts[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 } // packIPPort packs an IPPort into the form wanted by WireGuard. func packIPPort(ua netaddr.IPPort) []byte { ip := ua.IP.Unmap() a := ip.As16() ipb := a[:] if ip.Is4() { ipb = ipb[12:] } b := make([]byte, 0, len(ipb)+2) b = append(b, ipb...) b = append(b, byte(ua.Port)) b = append(b, byte(ua.Port>>8)) return b } func (a *AddrSet) DstToBytes() []byte { return packIPPort(a.dst()) } func (a *AddrSet) DstToString() string { dst := a.dst() return dst.String() } func (a *AddrSet) DstIP() net.IP { return a.dst().IP.IPAddr().IP // TODO: add netaddr accessor to cut an alloc here? } 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 { if new.IP.Equal(derpMagicIP) { // Never consider DERP addresses as a viable candidate for // either curAddr or roamAddr. It's only ever a last resort // choice, never a preferred choice. // This is a hot path for established connections. return nil } a.mu.Lock() defer a.mu.Unlock() if a.roamAddrStd != nil && equalUDPAddr(new, a.roamAddrStd) { // Packet from the current roaming address, no logging. // This is a hot path for established connections. return nil } if a.roamAddr == nil && 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 } newa, ok := netaddr.FromStdAddr(new.IP, new.Port, new.Zone) if !ok { 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 { a.Logf("magicsock: rx %s from roaming address %s, set as new priority", pk, new) } else { a.Logf("magicsock: rx %s from roaming address %s, replaces roaming address %s", pk, new, a.roamAddr) } a.roamAddr = &newa a.roamAddrStd = new case a.roamAddr != nil: a.Logf("magicsock: rx %s from known %s (%d), replaces roaming address %s", pk, new, index, a.roamAddr) a.roamAddr = nil a.roamAddrStd = nil a.curAddr = index a.loggedLogPriMask = 0 case a.curAddr == -1: a.Logf("magicsock: rx %s from %s (%d/%d), set as new priority", pk, new, index, len(a.addrs)) a.curAddr = index a.loggedLogPriMask = 0 case index < a.curAddr: if 1 <= index && index <= 32 && (a.loggedLogPriMask&1<<(index-1)) == 0 { a.Logf("magicsock: rx %s from low-pri %s (%d), keeping current %s (%d)", pk, new, index, old, a.curAddr) a.loggedLogPriMask |= 1 << (index - 1) } default: // index > a.curAddr a.Logf("magicsock: rx %s from %s (%d/%d), replaces old priority %s", pk, new, index, len(a.addrs), old) a.curAddr = index a.loggedLogPriMask = 0 } 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 { buf.WriteString("roam:") sbPrintAddr(buf, *a.roamAddrStd) } for i, addr := range a.addrs { if i > 0 || a.roamAddr != nil { buf.WriteString(", ") } sbPrintAddr(buf, addr) 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 } // CreateBind is called by WireGuard to create a UDP binding. func (c *Conn) CreateBind(uint16) (conn.Bind, uint16, error) { return c, c.LocalPort(), nil } // CreateEndpoint is called by WireGuard to connect to an endpoint. // // The key is the public key of the peer and addrs is either: // // 1) a comma-separated list of UDP ip:ports (the the peer doesn't have a discovery key) // 2) ".disco.tailscale:12345", a magic value that means the peer // is running code that supports active discovery, so CreateEndpoint returns // a discoEndpoint. // func (c *Conn) CreateEndpoint(pubKey [32]byte, addrs string) (conn.Endpoint, error) { pk := key.Public(pubKey) c.logf("magicsock: CreateEndpoint: key=%s: %s", pk.ShortString(), derpStr(addrs)) if strings.HasSuffix(addrs, controlclient.EndpointDiscoSuffix) { discoHex := strings.TrimSuffix(addrs, controlclient.EndpointDiscoSuffix) discoKey, err := key.NewPublicFromHexMem(mem.S(discoHex)) if err != nil { return nil, fmt.Errorf("magicsock: invalid discokey endpoint %q for %v: %w", addrs, pk.ShortString(), err) } c.mu.Lock() defer c.mu.Unlock() de := &discoEndpoint{ c: c, publicKey: pk, // peer public key (for WireGuard + DERP) discoKey: tailcfg.DiscoKey(discoKey), // for discovery mesages discoShort: tailcfg.DiscoKey(discoKey).ShortString(), wgEndpointHostPort: addrs, sentPing: map[stun.TxID]sentPing{}, endpointState: map[netaddr.IPPort]*endpointState{}, timers: map[*time.Timer]bool{}, } de.initFakeUDPAddr() de.updateFromNode(c.nodeOfDisco[de.discoKey]) c.endpointOfDisco[de.discoKey] = de return de, nil } a := &AddrSet{ Logf: c.logf, publicKey: pk, curAddr: -1, } if addrs != "" { for _, ep := range strings.Split(addrs, ",") { ipp, err := netaddr.ParseIPPort(ep) if err != nil { return nil, fmt.Errorf("bogus address %q", ep) } a.ipPorts = append(a.ipPorts, ipp) a.addrs = append(a.addrs, *ipp.UDPAddr()) } } c.mu.Lock() defer c.mu.Unlock() // If this endpoint is being updated, remember its old set of // endpoints so we can remove any (from c.addrsByUDP) that are // not in the new set. var oldIPP []netaddr.IPPort if preva, ok := c.addrsByKey[pk]; ok { oldIPP = preva.ipPorts } c.addrsByKey[pk] = a // Add entries to c.addrsByUDP. for _, ipp := range a.ipPorts { if ipp.IP == derpMagicIPAddr { continue } c.addrsByUDP[ipp] = a } // Remove previous c.addrsByUDP entries that are no longer in the new set. for _, ipp := range oldIPP { if ipp.IP != derpMagicIPAddr && c.addrsByUDP[ipp] != a { delete(c.addrsByUDP, ipp) } } return a, nil } // singleEndpoint is a wireguard-go/conn.Endpoint used for "roaming // addressed" in releases of Tailscale that predate discovery // messages. New peers use discoEndpoint. 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 { // ippCache is a cache from UDPAddr => netaddr.IPPort. It's not safe for concurrent use. // This is used by ReceiveIPv6 and awaitUDP4 (called from ReceiveIPv4). ippCache ippCache 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 } } // simpleDur rounds d such that it stringifies to something short. func simpleDur(d time.Duration) time.Duration { if d < time.Second { return d.Round(time.Millisecond) } if d < time.Minute { return d.Round(time.Second) } return d.Round(time.Minute) } func peerShort(k key.Public) string { k2 := wgcfg.Key(k) return k2.ShortString() } func sbPrintAddr(sb *strings.Builder, a net.UDPAddr) { is6 := a.IP.To4() == nil if is6 { sb.WriteByte('[') } fmt.Fprintf(sb, "%s", a.IP) if is6 { sb.WriteByte(']') } fmt.Fprintf(sb, ":%d", a.Port) } func (c *Conn) UpdateStatus(sb *ipnstate.StatusBuilder) { c.mu.Lock() defer c.mu.Unlock() for k, as := range c.addrsByKey { ps := &ipnstate.PeerStatus{ InMagicSock: true, } for i, ua := range as.addrs { uaStr := udpAddrDebugString(ua) ps.Addrs = append(ps.Addrs, uaStr) if as.curAddr == i { ps.CurAddr = uaStr } } if as.roamAddr != nil { ps.CurAddr = udpAddrDebugString(*as.roamAddrStd) } sb.AddPeer(k, ps) } c.foreachActiveDerpSortedLocked(func(node int, ad activeDerp) { // TODO(bradfitz): add to ipnstate.StatusBuilder //f("
  • derp-%v: cr%v,wr%v
  • ", node, simpleDur(now.Sub(ad.createTime)), simpleDur(now.Sub(*ad.lastWrite))) }) } func udpAddrDebugString(ua net.UDPAddr) string { if ua.IP.Equal(derpMagicIP) { return fmt.Sprintf("derp-%d", ua.Port) } return ua.String() } // discoEndpoint is a wireguard/conn.Endpoint for new-style peers that // advertise a DiscoKey and participate in active discovery. type discoEndpoint struct { // These fields are initialized once and never modified. c *Conn publicKey key.Public // peer public key (for WireGuard + DERP) discoKey tailcfg.DiscoKey // for discovery mesages discoShort string // ShortString of discoKey fakeWGAddr netaddr.IPPort // the UDP address we tell wireguard-go we're using fakeWGAddrStd *net.UDPAddr // the *net.UDPAddr form of fakeWGAddr wgEndpointHostPort string // string from CreateEndpoint: ".disco.tailscale:12345" // mu protects all following fields. mu sync.Mutex // Lock ordering: Conn.mu, then discoEndpoint.mu lastSend time.Time // last time there was outgoing packets sent to this peer (from wireguard-go) derpAddr netaddr.IPPort // fallback/bootstrap path, if non-zero (non-zero for well-behaved clients) bestAddr netaddr.IPPort // best non-DERP path; zero if none bestAddrLatency time.Duration bestAddrAt time.Time // time best address re-confirmed trustBestAddrUntil time.Time // time when bestAddr expires sentPing map[stun.TxID]sentPing endpointState map[netaddr.IPPort]*endpointState // timers are all outstanding timers. They're all stopped on // cleanup if the discovery endpoint is removed from the // network map. timers map[*time.Timer]bool } type endpointState struct { lastPing time.Time // TODO: lastPong time.Time index int // index in nodecfg.Node.Endpoints } type sentPing struct { to netaddr.IPPort at time.Time timer *time.Timer // timeout timer } // initFakeUDPAddr populates fakeWGAddr with a globally unique fake UDPAddr. // The current implementation just uses the pointer value of de jammed into an IPv6 // address, but it could also be, say, a counter. func (de *discoEndpoint) initFakeUDPAddr() { var addr [16]byte addr[0] = 0xfd addr[1] = 0x00 binary.BigEndian.PutUint64(addr[2:], uint64(reflect.ValueOf(de).Pointer())) de.fakeWGAddr = netaddr.IPPort{ IP: netaddr.IPFrom16(addr), Port: 12345, } de.fakeWGAddrStd = de.fakeWGAddr.UDPAddr() } func (de *discoEndpoint) Addrs() []wgcfg.Endpoint { // This has to be the same string that was passed to // CreateEndpoint, otherwise Reconfig will end up recreating // Endpoints and losing state over time. host, portStr, err := net.SplitHostPort(de.wgEndpointHostPort) if err != nil { panic(err) } port, err := strconv.ParseUint(portStr, 10, 16) if err != nil { panic(err) } return []wgcfg.Endpoint{{host, uint16(port)}} } func (de *discoEndpoint) ClearSrc() {} func (de *discoEndpoint) SrcToString() string { panic("unused") } // unused by wireguard-go func (de *discoEndpoint) SrcIP() net.IP { panic("unused") } // unused by wireguard-go func (de *discoEndpoint) DstToString() string { return de.wgEndpointHostPort } func (de *discoEndpoint) DstIP() net.IP { panic("unused") } func (de *discoEndpoint) DstToBytes() []byte { return packIPPort(de.fakeWGAddr) } func (de *discoEndpoint) UpdateDst(addr *net.UDPAddr) error { // This is called ~per packet (and requiring a mutex acquisition inside wireguard-go). // TODO(bradfitz): make that cheaper and/or remove it. We don't need it. return nil } func (de *discoEndpoint) send(b []byte) error { now := time.Now() de.mu.Lock() de.lastSend = now derpAddr := de.derpAddr haveDerp := !derpAddr.IsZero() bestAddr := de.bestAddr bestOld := now.After(de.trustBestAddrUntil) if bestAddr.IsZero() || bestOld { de.sendPingsLocked(now, true) } de.mu.Unlock() var didDerp bool if bestAddr.IsZero() { if !haveDerp { return errors.New("no DERP addr") } bestAddr = derpAddr } else if bestOld && haveDerp { // We have a bestAddr, but it hasn't been confirmed in a while, // so let's not entirely trust it and also send via DERP. didDerp, _ = de.c.sendAddr(derpAddr, de.publicKey, b) } _, err := de.c.sendAddr(bestAddr, de.publicKey, b) if didDerp { return nil } return err } // newTimerLocked creates a new AfterFunc(d, f) and returns it after // registering it with de.timers. // // The timer will unregister itself from de.timers after it fires and after f runs. func (de *discoEndpoint) newTimerLocked(d time.Duration, f func()) *time.Timer { var t *time.Timer t = time.AfterFunc(d, func() { f() de.mu.Lock() delete(de.timers, t) de.mu.Unlock() }) de.timers[t] = true return t } // forgetPing is called by a timer when a ping either fails to send or // has taken too long to get a pong reply. func (de *discoEndpoint) forgetPing(txid stun.TxID) { de.mu.Lock() defer de.mu.Unlock() if sp, ok := de.sentPing[txid]; ok { de.removeSentPingLocked(txid, sp) } } func (de *discoEndpoint) removeSentPingLocked(txid stun.TxID, sp sentPing) { // Stop the timer for the case where sendPing failed to write to UDP. // In the case of a timer already having fired, this is a no-op: sp.timer.Stop() delete(de.sentPing, txid) delete(de.timers, sp.timer) } // sendPing sends a ping with the provided txid to ep. // The caller should've already been recorded the ping in sentPing // and set up the timer. func (de *discoEndpoint) sendPing(ep netaddr.IPPort, txid stun.TxID) { sent, _ := de.sendDiscoMessage(ep, &disco.Ping{TxID: [12]byte(txid)}) if !sent { de.forgetPing(txid) } } func (de *discoEndpoint) sendPingsLocked(now time.Time, sendCallMeMaybe bool) { var sentAny bool for ep, st := range de.endpointState { ep := ep if !st.lastPing.IsZero() && now.Sub(st.lastPing) < 5*time.Second { continue } st.lastPing = now txid := stun.NewTxID() t := de.newTimerLocked(5*time.Second, func() { de.c.logf("magicsock: disco: timeout waiting for pong %x from %v (%v, %v)", txid, ep, de.publicKey.ShortString(), de.discoShort) de.forgetPing(txid) }) de.sentPing[txid] = sentPing{ to: ep, at: now, timer: t, } firstPing := !sentAny sentAny = true if firstPing && sendCallMeMaybe { de.c.logf("magicsock: disco: send, starting discovery for %v (%v)", de.publicKey.ShortString(), de.discoShort) } go de.sendPing(ep, txid) } derpAddr := de.derpAddr if sentAny && sendCallMeMaybe && !derpAddr.IsZero() { // In just a bit of a time (for goroutines above to schedule and run), // send a message to peer via DERP informing them that we've sent // so our firewall ports are probably open and now would be a good time // for them to connect. time.AfterFunc(5*time.Millisecond, func() { de.sendDiscoMessage(derpAddr, disco.CallMeMaybe{}) }) } } func (de *discoEndpoint) sendDiscoMessage(dst netaddr.IPPort, dm disco.Message) (sent bool, err error) { return de.c.sendDiscoMessage(dst, de.publicKey, de.discoKey, dm) } func (de *discoEndpoint) updateFromNode(n *tailcfg.Node) { if n == nil { // TODO: log, error, count? if this even happens. return } de.mu.Lock() defer de.mu.Unlock() if n.DERP == "" { de.derpAddr = netaddr.IPPort{} } else { de.derpAddr, _ = netaddr.ParseIPPort(n.DERP) } for _, st := range de.endpointState { st.index = -1 // assume deleted until updated in next loop } for i, epStr := range n.Endpoints { ipp, err := netaddr.ParseIPPort(epStr) if err != nil { de.c.logf("magicsock: bogus netmap endpoint %q", epStr) continue } if st, ok := de.endpointState[ipp]; ok { st.index = i } else { de.endpointState[ipp] = &endpointState{index: i} } } // Now delete anything that wasn't updated. for ipp, st := range de.endpointState { if st.index == -1 { delete(de.endpointState, ipp) if de.bestAddr == ipp { de.bestAddr = netaddr.IPPort{} } } } } // noteConnectivityChange is called when connectivity changes enough // that we should question our earlier assumptions about which paths // work. func (de *discoEndpoint) noteConnectivityChange() { de.mu.Lock() defer de.mu.Unlock() de.trustBestAddrUntil = time.Time{} } // handlePongConnLocked handles a Pong message (a reply to an earlier ping). // It should be called with the Conn.mu held. func (de *discoEndpoint) handlePongConnLocked(m *disco.Pong, src netaddr.IPPort) { de.mu.Lock() defer de.mu.Unlock() if src.IP == derpMagicIPAddr { // We might support pinging a node via DERP in the // future to see if it's still there, but we don't // yet. We shouldn't ever get here, but bail out early // in case we do in the future. (In which case, hi!, // you'll be modifying this code.) return } sp, ok := de.sentPing[m.TxID] if !ok { // This is not a pong for a ping we sent. Ignore. return } de.removeSentPingLocked(m.TxID, sp) de.c.setAddrToDiscoLocked(src, de.discoKey, de) now := time.Now() delay := now.Sub(sp.at) de.c.logf("magicsock: disco: %v<-%v (%v, %v) pong tx=%x latency=%v pong.src=%v%v", de.c.discoShort, de.discoShort, de.publicKey.ShortString(), src, m.TxID, delay.Round(time.Millisecond), m.Src, logger.ArgWriter(func(bw *bufio.Writer) { if sp.to != src { fmt.Fprintf(bw, " ping.to=%v", sp.to) } })) // Expire our best address if we haven't heard from it in awhile. tooOld := now.Add(-15 * time.Second) if !de.bestAddr.IsZero() && de.bestAddrAt.Before(tooOld) { de.bestAddr = netaddr.IPPort{} } // Promote this pong response to our current best address if it's lower latency. // TODO(bradfitz): decide how latency vs. preference order affects decision if de.bestAddr.IsZero() || delay < de.bestAddrLatency { if de.bestAddr != sp.to { de.c.logf("magicsock: disco: node %v %v now using %v", de.publicKey.ShortString(), de.discoShort, sp.to) de.bestAddr = sp.to } } if de.bestAddr == sp.to { de.bestAddrLatency = delay de.bestAddrAt = now de.trustBestAddrUntil = now.Add(5 * time.Second) } } // handleCallMeMaybe handles a CallMeMaybe discovery message via // DERP. The contract for use of this message is that the peer has // already sent to us via UDP, so their stateful firewall should be // open. Now we can Ping back and make it through. func (de *discoEndpoint) handleCallMeMaybe() { de.mu.Lock() defer de.mu.Unlock() // Zero out all the lastPing times to force sendPingsLocked to send new ones, // even if it's been less than 5 seconds ago. for _, st := range de.endpointState { st.lastPing = time.Time{} } de.sendPingsLocked(time.Now(), false) } // cleanup is called when a discovery endpoint is no longer present in the NetworkMap. // This is where we can do cleanup such as closing goroutines or canceling timers. func (de *discoEndpoint) cleanup() { de.mu.Lock() defer de.mu.Unlock() de.c.logf("magicsock: doing cleanup for discovery key %x", de.discoKey[:]) // TODO: real work later, when there's stuff to do for t := range de.timers { t.Stop() delete(de.timers, t) } } // ippCache is a cache of *net.UDPAddr => netaddr.IPPort mappings. // // It's not safe for concurrent use. type ippCache struct { c *lru.Cache } // IPPort is a caching wrapper around netaddr.FromStdAddr. // // It is not safe for concurrent use. func (ic *ippCache) IPPort(u *net.UDPAddr) (netaddr.IPPort, bool) { if u == nil || len(u.IP) > 16 { return netaddr.IPPort{}, false } if ic.c == nil { ic.c = lru.New(64) // arbitrary } key := ippCacheKey{ipLen: uint8(len(u.IP)), port: uint16(u.Port), zone: u.Zone} copy(key.ip[:], u.IP[:]) if v, ok := ic.c.Get(key); ok { return v.(netaddr.IPPort), true } ipp, ok := netaddr.FromStdAddr(u.IP, u.Port, u.Zone) if ok { ic.c.Add(key, ipp) } return ipp, ok } // ippCacheKey is the cache key type used by ippCache.IPPort. // It must be comparable, being used as a map key in the lru package. type ippCacheKey struct { ip [16]byte port uint16 ipLen uint8 // bytes in ip that are valid; rest are zero zone string } // derpStr replaces DERP IPs in s with "derp-". func derpStr(s string) string { return strings.ReplaceAll(s, "127.3.3.40:", "derp-") }