// Copyright (c) 2020 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 wgengine import ( "bufio" "context" crand "crypto/rand" "errors" "fmt" "io" "net" "net/netip" "reflect" "runtime" "strings" "sync" "time" "golang.org/x/exp/maps" "golang.zx2c4.com/wireguard/device" "golang.zx2c4.com/wireguard/tun" "tailscale.com/control/controlclient" "tailscale.com/envknob" "tailscale.com/health" "tailscale.com/ipn/ipnstate" "tailscale.com/net/dns" "tailscale.com/net/dns/resolver" "tailscale.com/net/flowtrack" "tailscale.com/net/interfaces" "tailscale.com/net/packet" "tailscale.com/net/tsaddr" "tailscale.com/net/tsdial" "tailscale.com/net/tshttpproxy" "tailscale.com/net/tstun" "tailscale.com/syncs" "tailscale.com/tailcfg" "tailscale.com/tstime/mono" "tailscale.com/types/dnstype" "tailscale.com/types/ipproto" "tailscale.com/types/key" "tailscale.com/types/logger" "tailscale.com/types/netmap" "tailscale.com/util/clientmetric" "tailscale.com/util/deephash" "tailscale.com/util/mak" "tailscale.com/wgengine/filter" "tailscale.com/wgengine/magicsock" "tailscale.com/wgengine/monitor" "tailscale.com/wgengine/netlog" "tailscale.com/wgengine/router" "tailscale.com/wgengine/wgcfg" "tailscale.com/wgengine/wgint" "tailscale.com/wgengine/wglog" ) const magicDNSPort = 53 var ( magicDNSIP = tsaddr.TailscaleServiceIP() magicDNSIPv6 = tsaddr.TailscaleServiceIPv6() ) // Lazy wireguard-go configuration parameters. const ( // lazyPeerIdleThreshold is the idle duration after // which we remove a peer from the wireguard configuration. // (This includes peers that have never been idle, which // effectively have infinite idleness) lazyPeerIdleThreshold = 5 * time.Minute // packetSendTimeUpdateFrequency controls how often we record // the time that we wrote a packet to an IP address. packetSendTimeUpdateFrequency = 10 * time.Second // packetSendRecheckWireguardThreshold controls how long we can go // between packet sends to an IP before checking to see // whether this IP address needs to be added back to the // WireGuard peer oconfig. packetSendRecheckWireguardThreshold = 1 * time.Minute ) // statusPollInterval is how often we ask wireguard-go for its engine // status (as long as there's activity). See docs on its use below. const statusPollInterval = 1 * time.Minute // networkLoggerUploadTimeout is the maximum timeout to wait when // shutting down the network logger as it uploads the last network log messages. const networkLoggerUploadTimeout = 5 * time.Second type userspaceEngine struct { logf logger.Logf wgLogger *wglog.Logger //a wireguard-go logging wrapper reqCh chan struct{} waitCh chan struct{} // chan is closed when first Close call completes; contrast with closing bool timeNow func() mono.Time tundev *tstun.Wrapper wgdev *device.Device router router.Router confListenPort uint16 // original conf.ListenPort dns *dns.Manager magicConn *magicsock.Conn linkMon *monitor.Mon linkMonOwned bool // whether we created linkMon (and thus need to close it) linkMonUnregister func() // unsubscribes from changes; used regardless of linkMonOwned birdClient BIRDClient // or nil testMaybeReconfigHook func() // for tests; if non-nil, fires if maybeReconfigWireguardLocked called // isLocalAddr reports the whether an IP is assigned to the local // tunnel interface. It's used to reflect local packets // incorrectly sent to us. isLocalAddr syncs.AtomicValue[func(netip.Addr) bool] // isDNSIPOverTailscale reports the whether a DNS resolver's IP // is being routed over Tailscale. isDNSIPOverTailscale syncs.AtomicValue[func(netip.Addr) bool] wgLock sync.Mutex // serializes all wgdev operations; see lock order comment below lastCfgFull wgcfg.Config lastNMinPeers int lastRouterSig deephash.Sum // of router.Config lastEngineSigFull deephash.Sum // of full wireguard config lastEngineSigTrim deephash.Sum // of trimmed wireguard config lastDNSConfig *dns.Config lastIsSubnetRouter bool // was the node a primary subnet router in the last run. recvActivityAt map[key.NodePublic]mono.Time trimmedNodes map[key.NodePublic]bool // set of node keys of peers currently excluded from wireguard config sentActivityAt map[netip.Addr]*mono.Time // value is accessed atomically destIPActivityFuncs map[netip.Addr]func() statusBufioReader *bufio.Reader // reusable for UAPI lastStatusPollTime mono.Time // last time we polled the engine status mu sync.Mutex // guards following; see lock order comment below netMap *netmap.NetworkMap // or nil closing bool // Close was called (even if we're still closing) statusCallback StatusCallback peerSequence []key.NodePublic endpoints []tailcfg.Endpoint pendOpen map[flowtrack.Tuple]*pendingOpenFlow // see pendopen.go networkMapCallbacks map[*someHandle]NetworkMapCallback tsIPByIPPort map[netip.AddrPort]netip.Addr // allows registration of IP:ports as belonging to a certain Tailscale IP for whois lookups // pongCallback is the map of response handlers waiting for disco or TSMP // pong callbacks. The map key is a random slice of bytes. pongCallback map[[8]byte]func(packet.TSMPPongReply) // icmpEchoResponseCallback is the map of reponse handlers waiting for ICMP // echo responses. The map key is a random uint32 that is the little endian // value of the ICMP identifer and sequence number concatenated. icmpEchoResponseCallback map[uint32]func() // networkLogger logs statistics about network connections. networkLogger netlog.Logger // Lock ordering: magicsock.Conn.mu, wgLock, then mu. } // InternalsGetter is implemented by Engines that can export their internals. type InternalsGetter interface { GetInternals() (_ *tstun.Wrapper, _ *magicsock.Conn, _ *dns.Manager, ok bool) } func (e *userspaceEngine) GetInternals() (_ *tstun.Wrapper, _ *magicsock.Conn, _ *dns.Manager, ok bool) { return e.tundev, e.magicConn, e.dns, true } // ResolvingEngine is implemented by Engines that have DNS resolvers. type ResolvingEngine interface { GetResolver() (_ *resolver.Resolver, ok bool) } var ( _ ResolvingEngine = (*userspaceEngine)(nil) _ ResolvingEngine = (*watchdogEngine)(nil) ) func (e *userspaceEngine) GetResolver() (r *resolver.Resolver, ok bool) { return e.dns.Resolver(), true } // BIRDClient handles communication with the BIRD Internet Routing Daemon. type BIRDClient interface { EnableProtocol(proto string) error DisableProtocol(proto string) error Close() error } // Config is the engine configuration. type Config struct { // Tun is the device used by the Engine to exchange packets with // the OS. // If nil, a fake Device that does nothing is used. Tun tun.Device // IsTAP is whether Tun is actually a TAP (Layer 2) device that'll // require ethernet headers. IsTAP bool // Router interfaces the Engine to the OS network stack. // If nil, a fake Router that does nothing is used. Router router.Router // DNS interfaces the Engine to the OS DNS resolver configuration. // If nil, a fake OSConfigurator that does nothing is used. DNS dns.OSConfigurator // LinkMonitor optionally provides an existing link monitor to re-use. // If nil, a new link monitor is created. LinkMonitor *monitor.Mon // Dialer is the dialer to use for outbound connections. // If nil, a new Dialer is created Dialer *tsdial.Dialer // ListenPort is the port on which the engine will listen. // If zero, a port is automatically selected. ListenPort uint16 // RespondToPing determines whether this engine should internally // reply to ICMP pings, without involving the OS. // Used in "fake" mode for development. RespondToPing bool // BIRDClient, if non-nil, will be used to configure BIRD whenever // this node is a primary subnet router. BIRDClient BIRDClient } func NewFakeUserspaceEngine(logf logger.Logf, listenPort uint16) (Engine, error) { logf("Starting userspace WireGuard engine (with fake TUN device)") return NewUserspaceEngine(logf, Config{ ListenPort: listenPort, RespondToPing: true, }) } // NetstackRouterType is a gross cross-package init-time registration // from netstack to here, informing this package of netstack's router // type. var NetstackRouterType reflect.Type // IsNetstackRouter reports whether e is either fully netstack based // (without TUN) or is at least using netstack for routing. func IsNetstackRouter(e Engine) bool { switch e := e.(type) { case *userspaceEngine: if reflect.TypeOf(e.router) == NetstackRouterType { return true } case *watchdogEngine: return IsNetstackRouter(e.wrap) } return IsNetstack(e) } // IsNetstack reports whether e is a netstack-based TUN-free engine. func IsNetstack(e Engine) bool { ig, ok := e.(InternalsGetter) if !ok { return false } tw, _, _, ok := ig.GetInternals() if !ok { return false } name, err := tw.Name() return err == nil && name == "FakeTUN" } // NewUserspaceEngine creates the named tun device and returns a // Tailscale Engine running on it. func NewUserspaceEngine(logf logger.Logf, conf Config) (_ Engine, reterr error) { var closePool closeOnErrorPool defer closePool.closeAllIfError(&reterr) if conf.Tun == nil { logf("[v1] using fake (no-op) tun device") conf.Tun = tstun.NewFake() } if conf.Router == nil { logf("[v1] using fake (no-op) OS network configurator") conf.Router = router.NewFake(logf) } if conf.DNS == nil { logf("[v1] using fake (no-op) DNS configurator") d, err := dns.NewNoopManager() if err != nil { return nil, err } conf.DNS = d } if conf.Dialer == nil { conf.Dialer = &tsdial.Dialer{Logf: logf} } var tsTUNDev *tstun.Wrapper if conf.IsTAP { tsTUNDev = tstun.WrapTAP(logf, conf.Tun) } else { tsTUNDev = tstun.Wrap(logf, conf.Tun) } closePool.add(tsTUNDev) e := &userspaceEngine{ timeNow: mono.Now, logf: logf, reqCh: make(chan struct{}, 1), waitCh: make(chan struct{}), tundev: tsTUNDev, router: conf.Router, confListenPort: conf.ListenPort, birdClient: conf.BIRDClient, } if e.birdClient != nil { // Disable the protocol at start time. if err := e.birdClient.DisableProtocol("tailscale"); err != nil { return nil, err } } e.isLocalAddr.Store(tsaddr.NewContainsIPFunc(nil)) e.isDNSIPOverTailscale.Store(tsaddr.NewContainsIPFunc(nil)) if conf.LinkMonitor != nil { e.linkMon = conf.LinkMonitor } else { mon, err := monitor.New(logf) if err != nil { return nil, err } closePool.add(mon) e.linkMon = mon e.linkMonOwned = true } tunName, _ := conf.Tun.Name() conf.Dialer.SetTUNName(tunName) conf.Dialer.SetLinkMonitor(e.linkMon) e.dns = dns.NewManager(logf, conf.DNS, e.linkMon, conf.Dialer, fwdDNSLinkSelector{e, tunName}) logf("link state: %+v", e.linkMon.InterfaceState()) unregisterMonWatch := e.linkMon.RegisterChangeCallback(func(changed bool, st *interfaces.State) { tshttpproxy.InvalidateCache() e.linkChange(changed, st) }) closePool.addFunc(unregisterMonWatch) e.linkMonUnregister = unregisterMonWatch endpointsFn := func(endpoints []tailcfg.Endpoint) { e.mu.Lock() e.endpoints = append(e.endpoints[:0], endpoints...) e.mu.Unlock() e.RequestStatus() } magicsockOpts := magicsock.Options{ Logf: logf, Port: conf.ListenPort, EndpointsFunc: endpointsFn, DERPActiveFunc: e.RequestStatus, IdleFunc: e.tundev.IdleDuration, NoteRecvActivity: e.noteRecvActivity, LinkMonitor: e.linkMon, } var err error e.magicConn, err = magicsock.NewConn(magicsockOpts) if err != nil { return nil, fmt.Errorf("wgengine: %v", err) } closePool.add(e.magicConn) e.magicConn.SetNetworkUp(e.linkMon.InterfaceState().AnyInterfaceUp()) tsTUNDev.SetDiscoKey(e.magicConn.DiscoPublicKey()) if conf.RespondToPing { e.tundev.PostFilterIn = echoRespondToAll } e.tundev.PreFilterFromTunToEngine = e.handleLocalPackets if envknob.BoolDefaultTrue("TS_DEBUG_CONNECT_FAILURES") { if e.tundev.PreFilterIn != nil { return nil, errors.New("unexpected PreFilterIn already set") } e.tundev.PreFilterIn = e.trackOpenPreFilterIn if e.tundev.PostFilterOut != nil { return nil, errors.New("unexpected PostFilterOut already set") } e.tundev.PostFilterOut = e.trackOpenPostFilterOut } e.wgLogger = wglog.NewLogger(logf) e.tundev.OnTSMPPongReceived = func(pong packet.TSMPPongReply) { e.mu.Lock() defer e.mu.Unlock() cb := e.pongCallback[pong.Data] e.logf("wgengine: got TSMP pong %02x, peerAPIPort=%v; cb=%v", pong.Data, pong.PeerAPIPort, cb != nil) if cb != nil { go cb(pong) } } e.tundev.OnICMPEchoResponseReceived = func(p *packet.Parsed) bool { idSeq := p.EchoIDSeq() e.mu.Lock() defer e.mu.Unlock() cb := e.icmpEchoResponseCallback[idSeq] if cb == nil { // We didn't swallow it, so let it flow to the host. return false } e.logf("wgengine: got diagnostic ICMP response %02x", idSeq) go cb() return true } // wgdev takes ownership of tundev, will close it when closed. e.logf("Creating WireGuard device...") e.wgdev = wgcfg.NewDevice(e.tundev, e.magicConn.Bind(), e.wgLogger.DeviceLogger) closePool.addFunc(e.wgdev.Close) closePool.addFunc(func() { if err := e.magicConn.Close(); err != nil { e.logf("error closing magicconn: %v", err) } }) go func() { up := false for event := range e.tundev.EventsUpDown() { if event&tun.EventUp != 0 && !up { e.logf("external route: up") e.RequestStatus() up = true } if event&tun.EventDown != 0 && up { e.logf("external route: down") e.RequestStatus() up = false } } }() e.logf("Bringing WireGuard device up...") if err := e.wgdev.Up(); err != nil { return nil, fmt.Errorf("wgdev.Up: %w", err) } e.logf("Bringing router up...") if err := e.router.Up(); err != nil { return nil, fmt.Errorf("router.Up: %w", err) } // It's a little pointless to apply no-op settings here (they // should already be empty?), but it at least exercises the // router implementation early on. e.logf("Clearing router settings...") if err := e.router.Set(nil); err != nil { return nil, fmt.Errorf("router.Set(nil): %w", err) } e.logf("Starting link monitor...") e.linkMon.Start() go e.pollResolver() e.logf("Engine created.") return e, nil } // echoRespondToAll is an inbound post-filter responding to all echo requests. func echoRespondToAll(p *packet.Parsed, t *tstun.Wrapper) filter.Response { if p.IsEchoRequest() { header := p.ICMP4Header() header.ToResponse() outp := packet.Generate(&header, p.Payload()) t.InjectOutbound(outp) // We already responded to it, but it's not an error. // Proceed with regular delivery. (Since this code is only // used in fake mode, regular delivery just means throwing // it away. If this ever gets run in non-fake mode, you'll // get double responses to pings, which is an indicator you // shouldn't be doing that I guess.) return filter.Accept } return filter.Accept } // handleLocalPackets inspects packets coming from the local network // stack, and intercepts any packets that should be handled by // tailscaled directly. Other packets are allowed to proceed into the // main ACL filter. func (e *userspaceEngine) handleLocalPackets(p *packet.Parsed, t *tstun.Wrapper) filter.Response { // Handle traffic to the service IP. // TODO(tom): Netstack handles this when it is installed. Rip all // this out once netstack is used on all platforms. switch p.Dst.Addr() { case magicDNSIP, magicDNSIPv6: err := e.dns.EnqueuePacket(append([]byte(nil), p.Payload()...), p.IPProto, p.Src, p.Dst) if err != nil { e.logf("dns: enqueue: %v", err) } metricMagicDNSPacketIn.Add(1) return filter.Drop } if runtime.GOOS == "darwin" || runtime.GOOS == "ios" { isLocalAddr, ok := e.isLocalAddr.LoadOk() if !ok { e.logf("[unexpected] e.isLocalAddr was nil, can't check for loopback packet") } else if isLocalAddr(p.Dst.Addr()) { // macOS NetworkExtension directs packets destined to the // tunnel's local IP address into the tunnel, instead of // looping back within the kernel network stack. We have to // notice that an outbound packet is actually destined for // ourselves, and loop it back into macOS. t.InjectInboundCopy(p.Buffer()) metricReflectToOS.Add(1) return filter.Drop } } return filter.Accept } // pollResolver reads packets from the DNS resolver and injects them inbound. // // TODO(tom): Remove this fallback path (via NextPacket()) once all // platforms use netstack. func (e *userspaceEngine) pollResolver() { for { bs, err := e.dns.NextPacket() if errors.Is(err, net.ErrClosed) { return } if err != nil { e.logf("dns: error: %v", err) continue } // The leading empty space required by the semantics of // InjectInboundDirect is allocated in NextPacket(). e.tundev.InjectInboundDirect(bs, tstun.PacketStartOffset) } } var debugTrimWireguard = envknob.RegisterOptBool("TS_DEBUG_TRIM_WIREGUARD") // forceFullWireguardConfig reports whether we should give wireguard our full // network map, even for inactive peers. // // TODO(bradfitz): remove this at some point. We had a TODO to do it before 1.0 // but it's still there as of 1.30. Really we should not do this wireguard lazy // peer config at all and just fix wireguard-go to not have so much extra memory // usage per peer. That would simplify a lot of Tailscale code. OTOH, we have 50 // MB of memory on iOS now instead of 15 MB, so the other option is to just give // up on lazy wireguard config and blow the memory and hope for the best on iOS. // That's sad too. Or we get rid of these knobs (lazy wireguard config has been // stable!) but I'm worried that a future regression would be easier to debug // with these knobs in place. func forceFullWireguardConfig(numPeers int) bool { // Did the user explicitly enable trimming via the environment variable knob? if b, ok := debugTrimWireguard().Get(); ok { return !b } if opt := controlclient.TrimWGConfig(); opt != "" { return !opt.EqualBool(true) } return false } // isTrimmablePeer reports whether p is a peer that we can trim out of the // network map. // // For implementation simplicity, we can only trim peers that have // only non-subnet AllowedIPs (an IPv4 /32 or IPv6 /128), which is the // common case for most peers. Subnet router nodes will just always be // created in the wireguard-go config. func isTrimmablePeer(p *wgcfg.Peer, numPeers int) bool { if forceFullWireguardConfig(numPeers) { return false } // AllowedIPs must all be single IPs, not subnets. for _, aip := range p.AllowedIPs { if !aip.IsSingleIP() { return false } } return true } // noteRecvActivity is called by magicsock when a packet has been // received for the peer with node key nk. Magicsock calls this no // more than every 10 seconds for a given peer. func (e *userspaceEngine) noteRecvActivity(nk key.NodePublic) { e.wgLock.Lock() defer e.wgLock.Unlock() if _, ok := e.recvActivityAt[nk]; !ok { // Not a trimmable peer we care about tracking. (See isTrimmablePeer) if e.trimmedNodes[nk] { e.logf("wgengine: [unexpected] noteReceiveActivity called on idle node %v that's not in recvActivityAt", nk.ShortString()) } return } now := e.timeNow() e.recvActivityAt[nk] = now // As long as there's activity, periodically poll the engine to get // stats for the far away side effect of // ipn/ipnlocal.LocalBackend.parseWgStatusLocked to log activity, for // use in various admin dashboards. // This particularly matters on platforms without a connected GUI, as // the GUIs generally poll this enough to cause that logging. But // tailscaled alone did not, hence this. if e.lastStatusPollTime.IsZero() || now.Sub(e.lastStatusPollTime) >= statusPollInterval { e.lastStatusPollTime = now go e.RequestStatus() } // If the last activity time jumped a bunch (say, at least // half the idle timeout) then see if we need to reprogram // WireGuard. This could probably be just // lazyPeerIdleThreshold without the divide by 2, but // maybeReconfigWireguardLocked is cheap enough to call every // couple minutes (just not on every packet). if e.trimmedNodes[nk] { e.logf("wgengine: idle peer %v now active, reconfiguring WireGuard", nk.ShortString()) e.maybeReconfigWireguardLocked(nil) } } // isActiveSinceLocked reports whether the peer identified by (nk, ip) // has had a packet sent to or received from it since t. // // e.wgLock must be held. func (e *userspaceEngine) isActiveSinceLocked(nk key.NodePublic, ip netip.Addr, t mono.Time) bool { if e.recvActivityAt[nk].After(t) { return true } timePtr, ok := e.sentActivityAt[ip] if !ok { return false } return timePtr.LoadAtomic().After(t) } // discoChanged are the set of peers whose disco keys have changed, implying they've restarted. // If a peer is in this set and was previously in the live wireguard config, // it needs to be first removed and then re-added to flush out its wireguard session key. // If discoChanged is nil or empty, this extra removal step isn't done. // // e.wgLock must be held. func (e *userspaceEngine) maybeReconfigWireguardLocked(discoChanged map[key.NodePublic]bool) error { if hook := e.testMaybeReconfigHook; hook != nil { hook() return nil } full := e.lastCfgFull e.wgLogger.SetPeers(full.Peers) // Compute a minimal config to pass to wireguard-go // based on the full config. Prune off all the peers // and only add the active ones back. min := full min.Peers = make([]wgcfg.Peer, 0, e.lastNMinPeers) // We'll only keep a peer around if it's been active in // the past 5 minutes. That's more than WireGuard's key // rotation time anyway so it's no harm if we remove it // later if it's been inactive. activeCutoff := e.timeNow().Add(-lazyPeerIdleThreshold) // Not all peers can be trimmed from the network map (see // isTrimmablePeer). For those that are trimmable, keep track of // their NodeKey and Tailscale IPs. These are the ones we'll need // to install tracking hooks for to watch their send/receive // activity. trackNodes := make([]key.NodePublic, 0, len(full.Peers)) trackIPs := make([]netip.Addr, 0, len(full.Peers)) // Don't re-alloc the map; the Go compiler optimizes map clears as of // Go 1.11, so we can re-use the existing + allocated map. if e.trimmedNodes != nil { maps.Clear(e.trimmedNodes) } else { e.trimmedNodes = make(map[key.NodePublic]bool) } needRemoveStep := false for i := range full.Peers { p := &full.Peers[i] nk := p.PublicKey if !isTrimmablePeer(p, len(full.Peers)) { min.Peers = append(min.Peers, *p) if discoChanged[nk] { needRemoveStep = true } continue } trackNodes = append(trackNodes, nk) recentlyActive := false for _, cidr := range p.AllowedIPs { trackIPs = append(trackIPs, cidr.Addr()) recentlyActive = recentlyActive || e.isActiveSinceLocked(nk, cidr.Addr(), activeCutoff) } if recentlyActive { min.Peers = append(min.Peers, *p) if discoChanged[nk] { needRemoveStep = true } } else { e.trimmedNodes[nk] = true } } e.lastNMinPeers = len(min.Peers) if changed := deephash.Update(&e.lastEngineSigTrim, &struct { WGConfig *wgcfg.Config TrimmedNodes map[key.NodePublic]bool TrackNodes []key.NodePublic TrackIPs []netip.Addr }{&min, e.trimmedNodes, trackNodes, trackIPs}); !changed { return nil } e.updateActivityMapsLocked(trackNodes, trackIPs) if needRemoveStep { minner := min minner.Peers = nil numRemove := 0 for _, p := range min.Peers { if discoChanged[p.PublicKey] { numRemove++ continue } minner.Peers = append(minner.Peers, p) } if numRemove > 0 { e.logf("wgengine: Reconfig: removing session keys for %d peers", numRemove) if err := wgcfg.ReconfigDevice(e.wgdev, &minner, e.logf); err != nil { e.logf("wgdev.Reconfig: %v", err) return err } } } e.logf("wgengine: Reconfig: configuring userspace WireGuard config (with %d/%d peers)", len(min.Peers), len(full.Peers)) if err := wgcfg.ReconfigDevice(e.wgdev, &min, e.logf); err != nil { e.logf("wgdev.Reconfig: %v", err) return err } return nil } // updateActivityMapsLocked updates the data structures used for tracking the activity // of wireguard peers that we might add/remove dynamically from the real config // as given to wireguard-go. // // e.wgLock must be held. func (e *userspaceEngine) updateActivityMapsLocked(trackNodes []key.NodePublic, trackIPs []netip.Addr) { // Generate the new map of which nodekeys we want to track // receive times for. mr := map[key.NodePublic]mono.Time{} // TODO: only recreate this if set of keys changed for _, nk := range trackNodes { // Preserve old times in the new map, but also // populate map entries for new trackNodes values with // time.Time{} zero values. (Only entries in this map // are tracked, so the Time zero values allow it to be // tracked later) mr[nk] = e.recvActivityAt[nk] } e.recvActivityAt = mr oldTime := e.sentActivityAt e.sentActivityAt = make(map[netip.Addr]*mono.Time, len(oldTime)) oldFunc := e.destIPActivityFuncs e.destIPActivityFuncs = make(map[netip.Addr]func(), len(oldFunc)) updateFn := func(timePtr *mono.Time) func() { return func() { now := e.timeNow() old := timePtr.LoadAtomic() // How long's it been since we last sent a packet? elapsed := now.Sub(old) if old == 0 { // For our first packet, old is 0, which has indeterminate meaning. // Set elapsed to a big number (four score and seven years). elapsed = 762642 * time.Hour } if elapsed >= packetSendTimeUpdateFrequency { timePtr.StoreAtomic(now) } // On a big jump, assume we might no longer be in the wireguard // config and go check. if elapsed >= packetSendRecheckWireguardThreshold { e.wgLock.Lock() defer e.wgLock.Unlock() e.maybeReconfigWireguardLocked(nil) } } } for _, ip := range trackIPs { timePtr := oldTime[ip] if timePtr == nil { timePtr = new(mono.Time) } e.sentActivityAt[ip] = timePtr fn := oldFunc[ip] if fn == nil { fn = updateFn(timePtr) } e.destIPActivityFuncs[ip] = fn } e.tundev.SetDestIPActivityFuncs(e.destIPActivityFuncs) } // hasOverlap checks if there is a IPPrefix which is common amongst the two // provided slices. func hasOverlap(aips, rips []netip.Prefix) bool { for _, aip := range aips { for _, rip := range rips { if aip == rip { return true } } } return false } func (e *userspaceEngine) Reconfig(cfg *wgcfg.Config, routerCfg *router.Config, dnsCfg *dns.Config, debug *tailcfg.Debug) error { if routerCfg == nil { panic("routerCfg must not be nil") } if dnsCfg == nil { panic("dnsCfg must not be nil") } e.isLocalAddr.Store(tsaddr.NewContainsIPFunc(routerCfg.LocalAddrs)) e.wgLock.Lock() defer e.wgLock.Unlock() e.lastDNSConfig = dnsCfg peerSet := make(map[key.NodePublic]struct{}, len(cfg.Peers)) e.mu.Lock() e.peerSequence = e.peerSequence[:0] for _, p := range cfg.Peers { e.peerSequence = append(e.peerSequence, p.PublicKey) peerSet[p.PublicKey] = struct{}{} } nm := e.netMap e.mu.Unlock() listenPort := e.confListenPort if debug != nil && debug.RandomizeClientPort { listenPort = 0 } isSubnetRouter := false if e.birdClient != nil && nm != nil && nm.SelfNode != nil { isSubnetRouter = hasOverlap(nm.SelfNode.PrimaryRoutes, nm.Hostinfo.RoutableIPs) e.logf("[v1] Reconfig: hasOverlap(%v, %v) = %v; isSubnetRouter=%v lastIsSubnetRouter=%v", nm.SelfNode.PrimaryRoutes, nm.Hostinfo.RoutableIPs, isSubnetRouter, isSubnetRouter, e.lastIsSubnetRouter) } isSubnetRouterChanged := isSubnetRouter != e.lastIsSubnetRouter engineChanged := deephash.Update(&e.lastEngineSigFull, cfg) routerChanged := deephash.Update(&e.lastRouterSig, &struct { RouterConfig *router.Config DNSConfig *dns.Config }{routerCfg, dnsCfg}) if !engineChanged && !routerChanged && listenPort == e.magicConn.LocalPort() && !isSubnetRouterChanged { return ErrNoChanges } newLogIDs := cfg.NetworkLogging oldLogIDs := e.lastCfgFull.NetworkLogging netLogIDsNowValid := !newLogIDs.NodeID.IsZero() && !newLogIDs.DomainID.IsZero() netLogIDsWasValid := !oldLogIDs.NodeID.IsZero() && !oldLogIDs.DomainID.IsZero() netLogIDsChanged := netLogIDsNowValid && netLogIDsWasValid && newLogIDs != oldLogIDs netLogRunning := netLogIDsNowValid && !routerCfg.Equal(&router.Config{}) if envknob.NoLogsNoSupport() { netLogRunning = false } // TODO(bradfitz,danderson): maybe delete this isDNSIPOverTailscale // field and delete the resolver.ForwardLinkSelector hook and // instead have ipnlocal populate a map of DNS IP => linkName and // put that in the *dns.Config instead, and plumb it down to the // dns.Manager. Maybe also with isLocalAddr above. e.isDNSIPOverTailscale.Store(tsaddr.NewContainsIPFunc(dnsIPsOverTailscale(dnsCfg, routerCfg))) // See if any peers have changed disco keys, which means they've restarted. // If so, we need to update the wireguard-go/device.Device in two phases: // once without the node which has restarted, to clear its wireguard session key, // and a second time with it. discoChanged := make(map[key.NodePublic]bool) { prevEP := make(map[key.NodePublic]key.DiscoPublic) for i := range e.lastCfgFull.Peers { if p := &e.lastCfgFull.Peers[i]; !p.DiscoKey.IsZero() { prevEP[p.PublicKey] = p.DiscoKey } } for i := range cfg.Peers { p := &cfg.Peers[i] if p.DiscoKey.IsZero() { continue } pub := p.PublicKey if old, ok := prevEP[pub]; ok && old != p.DiscoKey { discoChanged[pub] = true e.logf("wgengine: Reconfig: %s changed from %q to %q", pub.ShortString(), old, p.DiscoKey) } } } e.lastCfgFull = *cfg.Clone() // Tell magicsock about the new (or initial) private key // (which is needed by DERP) before wgdev gets it, as wgdev // will start trying to handshake, which we want to be able to // go over DERP. if err := e.magicConn.SetPrivateKey(cfg.PrivateKey); err != nil { e.logf("wgengine: Reconfig: SetPrivateKey: %v", err) } e.magicConn.UpdatePeers(peerSet) e.magicConn.SetPreferredPort(listenPort) if err := e.maybeReconfigWireguardLocked(discoChanged); err != nil { return err } // Shutdown the network logger because the IDs changed. // Let it be started back up by subsequent logic. if netLogIDsChanged && e.networkLogger.Running() { e.logf("wgengine: Reconfig: shutting down network logger") ctx, cancel := context.WithTimeout(context.Background(), networkLoggerUploadTimeout) defer cancel() if err := e.networkLogger.Shutdown(ctx); err != nil { e.logf("wgengine: Reconfig: error shutting down network logger: %v", err) } } // Startup the network logger. // Do this before configuring the router so that we capture initial packets. if netLogRunning && !e.networkLogger.Running() { nid := cfg.NetworkLogging.NodeID tid := cfg.NetworkLogging.DomainID e.logf("wgengine: Reconfig: starting up network logger (node:%s tailnet:%s)", nid.Public(), tid.Public()) if err := e.networkLogger.Startup(cfg.NodeID, nid, tid, e.tundev, e.magicConn); err != nil { e.logf("wgengine: Reconfig: error starting up network logger: %v", err) } e.networkLogger.ReconfigRoutes(routerCfg) } if routerChanged { e.logf("wgengine: Reconfig: configuring router") e.networkLogger.ReconfigRoutes(routerCfg) err := e.router.Set(routerCfg) health.SetRouterHealth(err) if err != nil { return err } // Keep DNS configuration after router configuration, as some // DNS managers refuse to apply settings if the device has no // assigned address. e.logf("wgengine: Reconfig: configuring DNS") err = e.dns.Set(*dnsCfg) health.SetDNSHealth(err) if err != nil { return err } } // Shutdown the network logger. // Do this after configuring the router so that we capture final packets. // This attempts to flush out any log messages and may block. if !netLogRunning && e.networkLogger.Running() { e.logf("wgengine: Reconfig: shutting down network logger") ctx, cancel := context.WithTimeout(context.Background(), networkLoggerUploadTimeout) defer cancel() if err := e.networkLogger.Shutdown(ctx); err != nil { e.logf("wgengine: Reconfig: error shutting down network logger: %v", err) } } if isSubnetRouterChanged && e.birdClient != nil { e.logf("wgengine: Reconfig: configuring BIRD") var err error if isSubnetRouter { err = e.birdClient.EnableProtocol("tailscale") } else { err = e.birdClient.DisableProtocol("tailscale") } if err != nil { // Log but don't fail here. e.logf("wgengine: error configuring BIRD: %v", err) } else { e.lastIsSubnetRouter = isSubnetRouter } } e.logf("[v1] wgengine: Reconfig done") return nil } func (e *userspaceEngine) GetFilter() *filter.Filter { return e.tundev.GetFilter() } func (e *userspaceEngine) SetFilter(filt *filter.Filter) { e.tundev.SetFilter(filt) } func (e *userspaceEngine) SetStatusCallback(cb StatusCallback) { e.mu.Lock() defer e.mu.Unlock() e.statusCallback = cb } func (e *userspaceEngine) getStatusCallback() StatusCallback { e.mu.Lock() defer e.mu.Unlock() return e.statusCallback } var singleNewline = []byte{'\n'} var ErrEngineClosing = errors.New("engine closing; no status") func (e *userspaceEngine) getPeerStatusLite(pk key.NodePublic) (status ipnstate.PeerStatusLite, ok bool) { e.wgLock.Lock() if e.wgdev == nil { e.wgLock.Unlock() return status, false } peer := e.wgdev.LookupPeer(pk.Raw32()) e.wgLock.Unlock() if peer == nil { return status, false } status.NodeKey = pk status.RxBytes = int64(wgint.PeerRxBytes(peer)) status.TxBytes = int64(wgint.PeerTxBytes(peer)) status.LastHandshake = time.Unix(0, wgint.PeerLastHandshakeNano(peer)) return status, true } func (e *userspaceEngine) getStatus() (*Status, error) { // Grab derpConns before acquiring wgLock to not violate lock ordering; // the DERPs method acquires magicsock.Conn.mu. // (See comment in userspaceEngine's declaration.) derpConns := e.magicConn.DERPs() e.mu.Lock() closing := e.closing peerKeys := make([]key.NodePublic, len(e.peerSequence)) copy(peerKeys, e.peerSequence) localAddrs := append([]tailcfg.Endpoint(nil), e.endpoints...) e.mu.Unlock() if closing { return nil, ErrEngineClosing } peers := make([]ipnstate.PeerStatusLite, 0, len(peerKeys)) for _, key := range peerKeys { if status, found := e.getPeerStatusLite(key); found { peers = append(peers, status) } } return &Status{ AsOf: time.Now(), LocalAddrs: localAddrs, Peers: peers, DERPs: derpConns, }, nil } func (e *userspaceEngine) RequestStatus() { // This is slightly tricky. e.getStatus() can theoretically get // blocked inside wireguard for a while, and RequestStatus() is // sometimes called from a goroutine, so we don't want a lot of // them hanging around. On the other hand, requesting multiple // status updates simultaneously is pointless anyway; they will // all say the same thing. // Enqueue at most one request. If one is in progress already, this // adds one more to the queue. If one has been requested but not // started, it is a no-op. select { case e.reqCh <- struct{}{}: default: } // Dequeue at most one request. Another thread may have already // dequeued the request we enqueued above, which is fine, since the // information is guaranteed to be at least as recent as the current // call to RequestStatus(). select { case <-e.reqCh: s, err := e.getStatus() if s == nil && err == nil { e.logf("[unexpected] RequestStatus: both s and err are nil") return } if cb := e.getStatusCallback(); cb != nil { cb(s, err) } default: } } func (e *userspaceEngine) Close() { e.mu.Lock() if e.closing { e.mu.Unlock() return } e.closing = true e.mu.Unlock() r := bufio.NewReader(strings.NewReader("")) e.wgdev.IpcSetOperation(r) e.magicConn.Close() e.linkMonUnregister() if e.linkMonOwned { e.linkMon.Close() } e.dns.Down() e.router.Close() e.wgdev.Close() e.tundev.Close() if e.birdClient != nil { e.birdClient.DisableProtocol("tailscale") e.birdClient.Close() } close(e.waitCh) ctx, cancel := context.WithTimeout(context.Background(), networkLoggerUploadTimeout) defer cancel() if err := e.networkLogger.Shutdown(ctx); err != nil { e.logf("wgengine: Close: error shutting down network logger: %v", err) } } func (e *userspaceEngine) Wait() { <-e.waitCh } func (e *userspaceEngine) GetLinkMonitor() *monitor.Mon { return e.linkMon } // LinkChange signals a network change event. It's currently // (2021-03-03) only called on Android. On other platforms, linkMon // generates link change events for us. func (e *userspaceEngine) LinkChange(_ bool) { e.linkMon.InjectEvent() } func (e *userspaceEngine) linkChange(changed bool, cur *interfaces.State) { up := cur.AnyInterfaceUp() if !up { e.logf("LinkChange: all links down; pausing: %v", cur) } else if changed { e.logf("LinkChange: major, rebinding. New state: %v", cur) } else { e.logf("[v1] LinkChange: minor") } health.SetAnyInterfaceUp(up) e.magicConn.SetNetworkUp(up) if !up || changed { if err := e.dns.FlushCaches(); err != nil { e.logf("wgengine: dns flush failed after major link change: %v", err) } } // Hacky workaround for Linux DNS issue 2458: on // suspend/resume or whenever NetworkManager is started, it // nukes all systemd-resolved configs. So reapply our DNS // config on major link change. if changed { switch runtime.GOOS { case "linux", "android", "ios", "darwin": e.wgLock.Lock() dnsCfg := e.lastDNSConfig e.wgLock.Unlock() if dnsCfg != nil { if err := e.dns.Set(*dnsCfg); err != nil { e.logf("wgengine: error setting DNS config after major link change: %v", err) } else { e.logf("wgengine: set DNS config again after major link change") } } } } why := "link-change-minor" if changed { why = "link-change-major" metricNumMajorChanges.Add(1) e.magicConn.Rebind() } else { metricNumMinorChanges.Add(1) } e.magicConn.ReSTUN(why) } func (e *userspaceEngine) AddNetworkMapCallback(cb NetworkMapCallback) func() { e.mu.Lock() defer e.mu.Unlock() if e.networkMapCallbacks == nil { e.networkMapCallbacks = make(map[*someHandle]NetworkMapCallback) } h := new(someHandle) e.networkMapCallbacks[h] = cb return func() { e.mu.Lock() defer e.mu.Unlock() delete(e.networkMapCallbacks, h) } } func (e *userspaceEngine) SetNetInfoCallback(cb NetInfoCallback) { e.magicConn.SetNetInfoCallback(cb) } func (e *userspaceEngine) SetDERPMap(dm *tailcfg.DERPMap) { e.magicConn.SetDERPMap(dm) } func (e *userspaceEngine) SetNetworkMap(nm *netmap.NetworkMap) { e.magicConn.SetNetworkMap(nm) e.mu.Lock() e.netMap = nm callbacks := make([]NetworkMapCallback, 0, 4) for _, fn := range e.networkMapCallbacks { callbacks = append(callbacks, fn) } e.mu.Unlock() for _, fn := range callbacks { fn(nm) } } func (e *userspaceEngine) DiscoPublicKey() key.DiscoPublic { return e.magicConn.DiscoPublicKey() } func (e *userspaceEngine) UpdateStatus(sb *ipnstate.StatusBuilder) { st, err := e.getStatus() if err != nil { e.logf("wgengine: getStatus: %v", err) return } for _, ps := range st.Peers { sb.AddPeer(ps.NodeKey, &ipnstate.PeerStatus{ RxBytes: int64(ps.RxBytes), TxBytes: int64(ps.TxBytes), LastHandshake: ps.LastHandshake, InEngine: true, }) } e.magicConn.UpdateStatus(sb) } func (e *userspaceEngine) Ping(ip netip.Addr, pingType tailcfg.PingType, cb func(*ipnstate.PingResult)) { res := &ipnstate.PingResult{IP: ip.String()} pip, ok := e.PeerForIP(ip) if !ok { e.logf("ping(%v): no matching peer", ip) res.Err = "no matching peer" cb(res) return } if pip.IsSelf { res.Err = fmt.Sprintf("%v is local Tailscale IP", ip) res.IsLocalIP = true cb(res) return } peer := pip.Node e.logf("ping(%v): sending %v ping to %v %v ...", ip, pingType, peer.Key.ShortString(), peer.ComputedName) switch pingType { case "disco": e.magicConn.Ping(peer, res, cb) case "TSMP": e.sendTSMPPing(ip, peer, res, cb) case "ICMP": e.sendICMPEchoRequest(ip, peer, res, cb) } } func (e *userspaceEngine) mySelfIPMatchingFamily(dst netip.Addr) (src netip.Addr, err error) { e.mu.Lock() defer e.mu.Unlock() if e.netMap == nil { return netip.Addr{}, errors.New("no netmap") } for _, a := range e.netMap.Addresses { if a.IsSingleIP() && a.Addr().BitLen() == dst.BitLen() { return a.Addr(), nil } } if len(e.netMap.Addresses) == 0 { return netip.Addr{}, errors.New("no self address in netmap") } return netip.Addr{}, errors.New("no self address in netmap matching address family") } func (e *userspaceEngine) sendICMPEchoRequest(destIP netip.Addr, peer *tailcfg.Node, res *ipnstate.PingResult, cb func(*ipnstate.PingResult)) { srcIP, err := e.mySelfIPMatchingFamily(destIP) if err != nil { res.Err = err.Error() cb(res) return } var icmph packet.Header if srcIP.Is4() { icmph = packet.ICMP4Header{ IP4Header: packet.IP4Header{ IPProto: ipproto.ICMPv4, Src: srcIP, Dst: destIP, }, Type: packet.ICMP4EchoRequest, Code: packet.ICMP4NoCode, } } else { icmph = packet.ICMP6Header{ IP6Header: packet.IP6Header{ IPProto: ipproto.ICMPv6, Src: srcIP, Dst: destIP, }, Type: packet.ICMP6EchoRequest, Code: packet.ICMP6NoCode, } } idSeq, payload := packet.ICMPEchoPayload(nil) expireTimer := time.AfterFunc(10*time.Second, func() { e.setICMPEchoResponseCallback(idSeq, nil) }) t0 := time.Now() e.setICMPEchoResponseCallback(idSeq, func() { expireTimer.Stop() d := time.Since(t0) res.LatencySeconds = d.Seconds() res.NodeIP = destIP.String() res.NodeName = peer.ComputedName cb(res) }) icmpPing := packet.Generate(icmph, payload) e.tundev.InjectOutbound(icmpPing) } func (e *userspaceEngine) sendTSMPPing(ip netip.Addr, peer *tailcfg.Node, res *ipnstate.PingResult, cb func(*ipnstate.PingResult)) { srcIP, err := e.mySelfIPMatchingFamily(ip) if err != nil { res.Err = err.Error() cb(res) return } var iph packet.Header if srcIP.Is4() { iph = packet.IP4Header{ IPProto: ipproto.TSMP, Src: srcIP, Dst: ip, } } else { iph = packet.IP6Header{ IPProto: ipproto.TSMP, Src: srcIP, Dst: ip, } } var data [8]byte crand.Read(data[:]) expireTimer := time.AfterFunc(10*time.Second, func() { e.setTSMPPongCallback(data, nil) }) t0 := time.Now() e.setTSMPPongCallback(data, func(pong packet.TSMPPongReply) { expireTimer.Stop() d := time.Since(t0) res.LatencySeconds = d.Seconds() res.NodeIP = ip.String() res.NodeName = peer.ComputedName res.PeerAPIPort = pong.PeerAPIPort cb(res) }) var tsmpPayload [9]byte tsmpPayload[0] = byte(packet.TSMPTypePing) copy(tsmpPayload[1:], data[:]) tsmpPing := packet.Generate(iph, tsmpPayload[:]) e.tundev.InjectOutbound(tsmpPing) } func (e *userspaceEngine) setTSMPPongCallback(data [8]byte, cb func(packet.TSMPPongReply)) { e.mu.Lock() defer e.mu.Unlock() if e.pongCallback == nil { e.pongCallback = map[[8]byte]func(packet.TSMPPongReply){} } if cb == nil { delete(e.pongCallback, data) } else { e.pongCallback[data] = cb } } func (e *userspaceEngine) setICMPEchoResponseCallback(idSeq uint32, cb func()) { e.mu.Lock() defer e.mu.Unlock() if cb == nil { delete(e.icmpEchoResponseCallback, idSeq) } else { mak.Set(&e.icmpEchoResponseCallback, idSeq, cb) } } func (e *userspaceEngine) RegisterIPPortIdentity(ipport netip.AddrPort, tsIP netip.Addr) { e.mu.Lock() defer e.mu.Unlock() if e.tsIPByIPPort == nil { e.tsIPByIPPort = make(map[netip.AddrPort]netip.Addr) } e.tsIPByIPPort[ipport] = tsIP } func (e *userspaceEngine) UnregisterIPPortIdentity(ipport netip.AddrPort) { e.mu.Lock() defer e.mu.Unlock() if e.tsIPByIPPort == nil { return } delete(e.tsIPByIPPort, ipport) } var whoIsSleeps = [...]time.Duration{ 0, 10 * time.Millisecond, 20 * time.Millisecond, 50 * time.Millisecond, 100 * time.Millisecond, } func (e *userspaceEngine) WhoIsIPPort(ipport netip.AddrPort) (tsIP netip.Addr, ok bool) { // We currently have a registration race, // https://github.com/tailscale/tailscale/issues/1616, // so loop a few times for now waiting for the registration // to appear. // TODO(bradfitz,namansood): remove this once #1616 is fixed. for _, d := range whoIsSleeps { time.Sleep(d) e.mu.Lock() tsIP, ok = e.tsIPByIPPort[ipport] e.mu.Unlock() if ok { return tsIP, true } } return tsIP, false } // PeerForIP returns the Node in the wireguard config // that's responsible for handling the given IP address. // // If none is found in the wireguard config but one is found in // the netmap, it's described in an error. // // peerForIP acquires both e.mu and e.wgLock, but neither at the same // time. func (e *userspaceEngine) PeerForIP(ip netip.Addr) (ret PeerForIP, ok bool) { e.mu.Lock() nm := e.netMap e.mu.Unlock() if nm == nil { return ret, false } // Check for exact matches before looking for subnet matches. // TODO(bradfitz): add maps for these. on NetworkMap? for _, p := range nm.Peers { for _, a := range p.Addresses { if a.Addr() == ip && a.IsSingleIP() && tsaddr.IsTailscaleIP(ip) { return PeerForIP{Node: p, Route: a}, true } } } for _, a := range nm.Addresses { if a.Addr() == ip && a.IsSingleIP() && tsaddr.IsTailscaleIP(ip) { return PeerForIP{Node: nm.SelfNode, IsSelf: true, Route: a}, true } } e.wgLock.Lock() defer e.wgLock.Unlock() // TODO(bradfitz): this is O(n peers). Add ART to netaddr? var best netip.Prefix var bestKey key.NodePublic for _, p := range e.lastCfgFull.Peers { for _, cidr := range p.AllowedIPs { if !cidr.Contains(ip) { continue } if !best.IsValid() || cidr.Bits() > best.Bits() { best = cidr bestKey = p.PublicKey } } } // And another pass. Probably better than allocating a map per peerForIP // call. But TODO(bradfitz): add a lookup map to netmap.NetworkMap. if !bestKey.IsZero() { for _, p := range nm.Peers { if p.Key == bestKey { return PeerForIP{Node: p, Route: best}, true } } } return ret, false } type closeOnErrorPool []func() func (p *closeOnErrorPool) add(c io.Closer) { *p = append(*p, func() { c.Close() }) } func (p *closeOnErrorPool) addFunc(fn func()) { *p = append(*p, fn) } func (p closeOnErrorPool) closeAllIfError(errp *error) { if *errp != nil { for _, closeFn := range p { closeFn() } } } // ipInPrefixes reports whether ip is in any of pp. func ipInPrefixes(ip netip.Addr, pp []netip.Prefix) bool { for _, p := range pp { if p.Contains(ip) { return true } } return false } // dnsIPsOverTailscale returns the IPPrefixes of DNS resolver IPs that are // routed over Tailscale. The returned value does not contain duplicates is // not necessarily sorted. func dnsIPsOverTailscale(dnsCfg *dns.Config, routerCfg *router.Config) (ret []netip.Prefix) { m := map[netip.Addr]bool{} add := func(resolvers []*dnstype.Resolver) { for _, r := range resolvers { ip, err := netip.ParseAddr(r.Addr) if err != nil { if ipp, err := netip.ParseAddrPort(r.Addr); err == nil { ip = ipp.Addr() } else { continue } } if ipInPrefixes(ip, routerCfg.Routes) && !ipInPrefixes(ip, routerCfg.LocalRoutes) { m[ip] = true } } } add(dnsCfg.DefaultResolvers) for _, resolvers := range dnsCfg.Routes { add(resolvers) } ret = make([]netip.Prefix, 0, len(m)) for ip := range m { ret = append(ret, netip.PrefixFrom(ip, ip.BitLen())) } return ret } // fwdDNSLinkSelector is userspaceEngine's resolver.ForwardLinkSelector, to pick // which network interface to send DNS queries out of. type fwdDNSLinkSelector struct { ue *userspaceEngine tunName string } func (ls fwdDNSLinkSelector) PickLink(ip netip.Addr) (linkName string) { if ls.ue.isDNSIPOverTailscale.Load()(ip) { return ls.tunName } return "" } var ( metricMagicDNSPacketIn = clientmetric.NewCounter("magicdns_packet_in") // for 100.100.100.100 metricReflectToOS = clientmetric.NewCounter("packet_reflect_to_os") metricNumMajorChanges = clientmetric.NewCounter("wgengine_major_changes") metricNumMinorChanges = clientmetric.NewCounter("wgengine_minor_changes") )