// Copyright (c) Tailscale Inc & AUTHORS // SPDX-License-Identifier: BSD-3-Clause package router import ( "errors" "fmt" "net" "net/netip" "os" "os/exec" "strconv" "strings" "sync/atomic" "syscall" "time" "github.com/tailscale/netlink" "github.com/tailscale/wireguard-go/tun" "go4.org/netipx" "golang.org/x/sys/unix" "golang.org/x/time/rate" "tailscale.com/envknob" "tailscale.com/net/netmon" "tailscale.com/types/logger" "tailscale.com/types/preftype" "tailscale.com/util/linuxfw" "tailscale.com/util/multierr" "tailscale.com/version/distro" ) const ( netfilterOff = preftype.NetfilterOff netfilterNoDivert = preftype.NetfilterNoDivert netfilterOn = preftype.NetfilterOn ) // netfilterRunner abstracts helpers to run netfilter commands. It is // implemented by linuxfw.IPTablesRunner and linuxfw.NfTablesRunner. type netfilterRunner interface { AddLoopbackRule(addr netip.Addr) error DelLoopbackRule(addr netip.Addr) error AddHooks() error DelHooks(logf logger.Logf) error AddChains() error DelChains() error AddBase(tunname string) error DelBase() error AddSNATRule() error DelSNATRule() error HasIPV6() bool HasIPV6NAT() bool } // tableDetector abstracts helpers to detect the firewall mode. // It is implemented for testing purposes. type tableDetector interface { iptDetect() (int, error) nftDetect() (int, error) } type linuxFWDetector struct{} // iptDetect returns the number of iptables rules in the current namespace. func (l *linuxFWDetector) iptDetect() (int, error) { return linuxfw.DetectIptables() } // nftDetect returns the number of nftables rules in the current namespace. func (l *linuxFWDetector) nftDetect() (int, error) { return linuxfw.DetectNetfilter() } // chooseFireWallMode returns the firewall mode to use based on the // environment and the system's capabilities. func chooseFireWallMode(logf logger.Logf, det tableDetector) linuxfw.FirewallMode { if distro.Get() == distro.Gokrazy { // Reduce startup logging on gokrazy. There's no way to do iptables on // gokrazy anyway. return linuxfw.FirewallModeNfTables } iptAva, nftAva := true, true iptRuleCount, err := det.iptDetect() if err != nil { logf("router: detect iptables rule: %v", err) iptAva = false } nftRuleCount, err := det.nftDetect() if err != nil { logf("router: detect nftables rule: %v", err) nftAva = false } logf("router: nftables rule count: %d, iptables rule count: %d", nftRuleCount, iptRuleCount) switch { case envknob.String("TS_DEBUG_FIREWALL_MODE") == "nftables": // TODO(KevinLiang10): Updates to a flag logf("router: envknob TS_DEBUG_FIREWALL_MODE=nftables set") return linuxfw.FirewallModeNfTables case envknob.String("TS_DEBUG_FIREWALL_MODE") == "iptables": logf("router: envknob TS_DEBUG_FIREWALL_MODE=iptables set") return linuxfw.FirewallModeIPTables case nftRuleCount > 0 && iptRuleCount == 0: logf("router: nftables is currently in use") return linuxfw.FirewallModeNfTables case iptRuleCount > 0 && nftRuleCount == 0: logf("router: iptables is currently in use") return linuxfw.FirewallModeIPTables case nftAva: // if both iptables and nftables are available but // neither/both are currently used, use nftables. logf("router: nftables is available") return linuxfw.FirewallModeNfTables case iptAva: logf("router: iptables is available") return linuxfw.FirewallModeIPTables default: // if neither iptables nor nftables are available, use iptablesRunner as a dummy // runner which exists but won't do anything. Creating iptablesRunner errors only // if the iptables command is missing or doesn’t support "--version", as long as it // can determine a version then it’ll carry on. return linuxfw.FirewallModeIPTables } } // newNetfilterRunner creates a netfilterRunner using either nftables or iptables. // As nftables is still experimental, iptables will be used unless TS_DEBUG_USE_NETLINK_NFTABLES is set. func newNetfilterRunner(logf logger.Logf) (netfilterRunner, error) { tableDetector := &linuxFWDetector{} mode := chooseFireWallMode(logf, tableDetector) var nfr netfilterRunner var err error switch mode { case linuxfw.FirewallModeIPTables: logf("router: using iptables") nfr, err = linuxfw.NewIPTablesRunner(logf) if err != nil { return nil, err } case linuxfw.FirewallModeNfTables: logf("router: using nftables") nfr, err = linuxfw.NewNfTablesRunner(logf) if err != nil { return nil, err } default: return nil, fmt.Errorf("unknown firewall mode: %v", mode) } return nfr, nil } type linuxRouter struct { closed atomic.Bool logf func(fmt string, args ...any) tunname string netMon *netmon.Monitor unregNetMon func() addrs map[netip.Prefix]bool routes map[netip.Prefix]bool localRoutes map[netip.Prefix]bool snatSubnetRoutes bool netfilterMode preftype.NetfilterMode // ruleRestorePending is whether a timer has been started to // restore deleted ip rules. ruleRestorePending atomic.Bool ipRuleFixLimiter *rate.Limiter // Various feature checks for the network stack. ipRuleAvailable bool // whether kernel was built with IP_MULTIPLE_TABLES fwmaskWorks bool // whether we can use 'ip rule...fwmark /' // ipPolicyPrefBase is the base priority at which ip rules are installed. ipPolicyPrefBase int nfr netfilterRunner cmd commandRunner } func newUserspaceRouter(logf logger.Logf, tunDev tun.Device, netMon *netmon.Monitor) (Router, error) { tunname, err := tunDev.Name() if err != nil { return nil, err } nfr, err := newNetfilterRunner(logf) if err != nil { return nil, err } cmd := osCommandRunner{ ambientCapNetAdmin: useAmbientCaps(), } return newUserspaceRouterAdvanced(logf, tunname, netMon, nfr, cmd) } func newUserspaceRouterAdvanced(logf logger.Logf, tunname string, netMon *netmon.Monitor, nfr netfilterRunner, cmd commandRunner) (Router, error) { r := &linuxRouter{ logf: logf, tunname: tunname, netfilterMode: netfilterOff, netMon: netMon, nfr: nfr, cmd: cmd, ipRuleFixLimiter: rate.NewLimiter(rate.Every(5*time.Second), 10), ipPolicyPrefBase: 5200, } if r.useIPCommand() { r.ipRuleAvailable = (cmd.run("ip", "rule") == nil) } else { if rules, err := netlink.RuleList(netlink.FAMILY_V4); err != nil { r.logf("error querying IP rules (does kernel have IP_MULTIPLE_TABLES?): %v", err) r.logf("warning: running without policy routing") } else { r.logf("[v1] policy routing available; found %d rules", len(rules)) r.ipRuleAvailable = true } } // To be a good denizen of the 4-byte 'fwmark' bitspace on every packet, we try to // only use the third byte. However, support for masking to part of the fwmark bitspace // was only added to busybox in 1.33.0. As such, we want to detect older versions and // not issue such a stanza. var err error if r.fwmaskWorks, err = ipCmdSupportsFwmask(); err != nil { r.logf("failed to determine ip command fwmask support: %v", err) } if r.fwmaskWorks { r.logf("[v1] ip command supports fwmark masks") } else { r.logf("[v1] ip command does NOT support fwmark masks") } // A common installation of OpenWRT involves use of the 'mwan3' package. // This package installs ip-tables rules like: // -A mwan3_fallback_policy -m mark --mark 0x0/0x3f00 -j MARK --set-xmark 0x100/0x3f00 // // which coupled with an ip rule: // 2001: from all fwmark 0x100/0x3f00 lookup 1 // // has the effect of gobbling tailscale packets, because tailscale by default installs // its policy routing rules at priority 52xx. // // As such, if we are running on openWRT, detect a mwan3 config, AND detect a rule // with a preference 2001 (corresponding to the first interface wman3 manages), we // shift the priority of our policies to 13xx. This effectively puts us between mwan3's // permit-by-src-ip rules and mwan3 lookup of its own routing table which would drop // the packet. isMWAN3, err := checkOpenWRTUsingMWAN3() if err != nil { r.logf("error checking mwan3 installation: %v", err) } else if isMWAN3 { r.ipPolicyPrefBase = 1300 r.logf("mwan3 on openWRT detected, switching policy base priority to 1300") } r.fixupWSLMTU() return r, nil } // ipCmdSupportsFwmask returns true if the system 'ip' binary supports using a // fwmark stanza with a mask specified. To our knowledge, everything except busybox // pre-1.33 supports this. func ipCmdSupportsFwmask() (bool, error) { ipPath, err := exec.LookPath("ip") if err != nil { return false, fmt.Errorf("lookpath: %v", err) } stat, err := os.Lstat(ipPath) if err != nil { return false, fmt.Errorf("lstat: %v", err) } if stat.Mode()&os.ModeSymlink == 0 { // Not a symlink, so can't be busybox. Must be regular ip utility. return true, nil } linkDest, err := os.Readlink(ipPath) if err != nil { return false, err } if !strings.Contains(strings.ToLower(linkDest), "busybox") { // Not busybox, presumably supports fwmark masks. return true, nil } // If we got this far, the ip utility is a busybox version with an // unknown version. // We run `ip --version` and look for the busybox banner (which // is a stable 'BusyBox vX.Y.Z ()' string) to determine // the version. out, err := exec.Command("ip", "--version").CombinedOutput() if err != nil { return false, err } major, minor, _, err := busyboxParseVersion(string(out)) if err != nil { return false, nil } // Support for masks added in 1.33.0. switch { case major > 1: return true, nil case major == 1 && minor >= 33: return true, nil default: return false, nil } } func busyboxParseVersion(output string) (major, minor, patch int, err error) { bannerStart := strings.Index(output, "BusyBox v") if bannerStart < 0 { return 0, 0, 0, errors.New("missing BusyBox banner") } bannerEnd := bannerStart + len("BusyBox v") end := strings.Index(output[bannerEnd:], " ") if end < 0 { return 0, 0, 0, errors.New("missing end delimiter") } elements := strings.Split(output[bannerEnd:bannerEnd+end], ".") if len(elements) < 3 { return 0, 0, 0, fmt.Errorf("expected 3 version elements, got %d", len(elements)) } if major, err = strconv.Atoi(elements[0]); err != nil { return 0, 0, 0, fmt.Errorf("parsing major: %v", err) } if minor, err = strconv.Atoi(elements[1]); err != nil { return 0, 0, 0, fmt.Errorf("parsing minor: %v", err) } if patch, err = strconv.Atoi(elements[2]); err != nil { return 0, 0, 0, fmt.Errorf("parsing patch: %v", err) } return major, minor, patch, nil } func useAmbientCaps() bool { if distro.Get() != distro.Synology { return false } return distro.DSMVersion() >= 7 } var forceIPCommand = envknob.RegisterBool("TS_DEBUG_USE_IP_COMMAND") // useIPCommand reports whether r should use the "ip" command (or its // fake commandRunner for tests) instead of netlink. func (r *linuxRouter) useIPCommand() bool { if r.cmd == nil { panic("invalid init") } if forceIPCommand() { return true } // In the future we might need to fall back to using the "ip" // command if, say, netlink is blocked somewhere but the ip // command is allowed to use netlink. For now we only use the ip // command runner in tests. _, ok := r.cmd.(osCommandRunner) return !ok } // onIPRuleDeleted is the callback from the network monitor for when an IP // policy rule is deleted. See Issue 1591. // // If an ip rule is deleted (with pref number 52xx, as Tailscale sets), then // set a timer to restore our rules, in case they were deleted. The timer lets // us do one fixup in response to a batch of rule deletes. It also lets us // delay arbitrarily to prevent a high-speed fight over the rule between // competing processes. (Although empirically, systemd doesn't fight us // like that... yet.) // // Note that we don't care about the table number. We don't strictly even care // about the priority number. We could just do this in response to any netlink // change. Filtering by known priority ranges cuts back on some logspam. func (r *linuxRouter) onIPRuleDeleted(table uint8, priority uint32) { if int(priority) < r.ipPolicyPrefBase || int(priority) >= (r.ipPolicyPrefBase+100) { // Not our rule. return } if !r.ruleRestorePending.Swap(true) { // Another timer is already pending. return } rr := r.ipRuleFixLimiter.Reserve() if !rr.OK() { r.ruleRestorePending.Swap(false) return } time.AfterFunc(rr.Delay()+250*time.Millisecond, func() { if r.ruleRestorePending.Swap(false) && !r.closed.Load() { r.logf("somebody (likely systemd-networkd) deleted ip rules; restoring Tailscale's") r.justAddIPRules() } }) } func (r *linuxRouter) Up() error { if r.unregNetMon == nil && r.netMon != nil { r.unregNetMon = r.netMon.RegisterRuleDeleteCallback(r.onIPRuleDeleted) } if err := r.addIPRules(); err != nil { return fmt.Errorf("adding IP rules: %w", err) } if err := r.setNetfilterMode(netfilterOff); err != nil { return fmt.Errorf("setting netfilter mode: %w", err) } if err := r.upInterface(); err != nil { return fmt.Errorf("bringing interface up: %w", err) } return nil } func (r *linuxRouter) Close() error { r.closed.Store(true) if r.unregNetMon != nil { r.unregNetMon() } if err := r.downInterface(); err != nil { return err } if err := r.delIPRules(); err != nil { return err } if err := r.setNetfilterMode(netfilterOff); err != nil { return err } if err := r.delRoutes(); err != nil { return err } r.addrs = nil r.routes = nil r.localRoutes = nil return nil } // Set implements the Router interface. func (r *linuxRouter) Set(cfg *Config) error { var errs []error if cfg == nil { cfg = &shutdownConfig } if err := r.setNetfilterMode(cfg.NetfilterMode); err != nil { errs = append(errs, err) } newLocalRoutes, err := cidrDiff("localRoute", r.localRoutes, cfg.LocalRoutes, r.addThrowRoute, r.delThrowRoute, r.logf) if err != nil { errs = append(errs, err) } r.localRoutes = newLocalRoutes newRoutes, err := cidrDiff("route", r.routes, cfg.Routes, r.addRoute, r.delRoute, r.logf) if err != nil { errs = append(errs, err) } r.routes = newRoutes newAddrs, err := cidrDiff("addr", r.addrs, cfg.LocalAddrs, r.addAddress, r.delAddress, r.logf) if err != nil { errs = append(errs, err) } r.addrs = newAddrs switch { case cfg.SNATSubnetRoutes == r.snatSubnetRoutes: // state already correct, nothing to do. case cfg.SNATSubnetRoutes: if err := r.addSNATRule(); err != nil { errs = append(errs, err) } default: if err := r.delSNATRule(); err != nil { errs = append(errs, err) } } r.snatSubnetRoutes = cfg.SNATSubnetRoutes return multierr.New(errs...) } // setNetfilterMode switches the router to the given netfilter // mode. Netfilter state is created or deleted appropriately to // reflect the new mode, and r.snatSubnetRoutes is updated to reflect // the current state of subnet SNATing. func (r *linuxRouter) setNetfilterMode(mode preftype.NetfilterMode) error { if distro.Get() == distro.Synology { mode = netfilterOff } if r.netfilterMode == mode { return nil } // Depending on the netfilter mode we switch from and to, we may // have created the Tailscale netfilter chains. If so, we have to // go back through existing router state, and add the netfilter // rules for that state. // // This bool keeps track of whether the current state transition // is one that requires adding rules of existing state. reprocess := false switch mode { case netfilterOff: switch r.netfilterMode { case netfilterNoDivert: if err := r.nfr.DelBase(); err != nil { return err } if err := r.nfr.DelChains(); err != nil { r.logf("note: %v", err) // harmless, continue. // This can happen if someone left a ref to // this table somewhere else. } case netfilterOn: if err := r.nfr.DelHooks(r.logf); err != nil { return err } if err := r.nfr.DelBase(); err != nil { return err } if err := r.nfr.DelChains(); err != nil { r.logf("note: %v", err) // harmless, continue. // This can happen if someone left a ref to // this table somewhere else. } } r.snatSubnetRoutes = false case netfilterNoDivert: switch r.netfilterMode { case netfilterOff: reprocess = true if err := r.nfr.AddChains(); err != nil { return err } if err := r.nfr.AddBase(r.tunname); err != nil { return err } r.snatSubnetRoutes = false case netfilterOn: if err := r.nfr.DelHooks(r.logf); err != nil { return err } } case netfilterOn: // Because of bugs in old version of iptables-compat, // we can't add a "-j ts-forward" rule to FORWARD // while ts-forward contains an "-m mark" rule. But // we can add the row *before* populating ts-forward. // So we have to delBase, then add the hooks, // then re-addBase, just in case. switch r.netfilterMode { case netfilterOff: reprocess = true if err := r.nfr.AddChains(); err != nil { return err } if err := r.nfr.DelBase(); err != nil { return err } // AddHooks adds the ts loopback rule. if err := r.nfr.AddHooks(); err != nil { return err } // AddBase adds base ts rules if err := r.nfr.AddBase(r.tunname); err != nil { return err } r.snatSubnetRoutes = false case netfilterNoDivert: reprocess = true if err := r.nfr.DelBase(); err != nil { return err } if err := r.nfr.AddHooks(); err != nil { return err } if err := r.nfr.AddBase(r.tunname); err != nil { return err } r.snatSubnetRoutes = false } default: panic("unhandled netfilter mode") } r.netfilterMode = mode if !reprocess { return nil } for cidr := range r.addrs { if err := r.addLoopbackRule(cidr.Addr()); err != nil { return err } } return nil } func (r *linuxRouter) getV6Available() bool { return r.nfr.HasIPV6() } func (r *linuxRouter) getV6NATAvailable() bool { return r.nfr.HasIPV6NAT() } // addAddress adds an IP/mask to the tunnel interface. Fails if the // address is already assigned to the interface, or if the addition // fails. func (r *linuxRouter) addAddress(addr netip.Prefix) error { if !r.getV6Available() && addr.Addr().Is6() { return nil } if r.useIPCommand() { if err := r.cmd.run("ip", "addr", "add", addr.String(), "dev", r.tunname); err != nil { return fmt.Errorf("adding address %q to tunnel interface: %w", addr, err) } } else { link, err := r.link() if err != nil { return fmt.Errorf("adding address %v, %w", addr, err) } if err := netlink.AddrReplace(link, nlAddrOfPrefix(addr)); err != nil { return fmt.Errorf("adding address %v from tunnel interface: %w", addr, err) } } if err := r.addLoopbackRule(addr.Addr()); err != nil { return err } return nil } // delAddress removes an IP/mask from the tunnel interface. Fails if // the address is not assigned to the interface, or if the removal // fails. func (r *linuxRouter) delAddress(addr netip.Prefix) error { if !r.getV6Available() && addr.Addr().Is6() { return nil } if err := r.delLoopbackRule(addr.Addr()); err != nil { return err } if r.useIPCommand() { if err := r.cmd.run("ip", "addr", "del", addr.String(), "dev", r.tunname); err != nil { return fmt.Errorf("deleting address %q from tunnel interface: %w", addr, err) } } else { link, err := r.link() if err != nil { return fmt.Errorf("deleting address %v, %w", addr, err) } if err := netlink.AddrDel(link, nlAddrOfPrefix(addr)); err != nil { return fmt.Errorf("deleting address %v from tunnel interface: %w", addr, err) } } return nil } // addLoopbackRule adds a firewall rule to permit loopback traffic to // a local Tailscale IP. func (r *linuxRouter) addLoopbackRule(addr netip.Addr) error { if r.netfilterMode == netfilterOff { return nil } if err := r.nfr.AddLoopbackRule(addr); err != nil { return err } return nil } // delLoopbackRule removes the firewall rule permitting loopback // traffic to a Tailscale IP. func (r *linuxRouter) delLoopbackRule(addr netip.Addr) error { if r.netfilterMode == netfilterOff { return nil } if err := r.nfr.DelLoopbackRule(addr); err != nil { return err } return nil } // addRoute adds a route for cidr, pointing to the tunnel // interface. Fails if the route already exists, or if adding the // route fails. func (r *linuxRouter) addRoute(cidr netip.Prefix) error { if !r.getV6Available() && cidr.Addr().Is6() { return nil } if r.useIPCommand() { return r.addRouteDef([]string{normalizeCIDR(cidr), "dev", r.tunname}, cidr) } linkIndex, err := r.linkIndex() if err != nil { return err } return netlink.RouteReplace(&netlink.Route{ LinkIndex: linkIndex, Dst: netipx.PrefixIPNet(cidr.Masked()), Table: r.routeTable(), }) } // addThrowRoute adds a throw route for the provided cidr. // This has the effect that lookup in the routing table is terminated // pretending that no route was found. Fails if the route already exists, // or if adding the route fails. func (r *linuxRouter) addThrowRoute(cidr netip.Prefix) error { if !r.ipRuleAvailable { return nil } if !r.getV6Available() && cidr.Addr().Is6() { return nil } if r.useIPCommand() { return r.addRouteDef([]string{"throw", normalizeCIDR(cidr)}, cidr) } err := netlink.RouteReplace(&netlink.Route{ Dst: netipx.PrefixIPNet(cidr.Masked()), Table: tailscaleRouteTable.Num, Type: unix.RTN_THROW, }) if err != nil { r.logf("THROW ERROR adding %v: %#v", cidr, err) } return err } func (r *linuxRouter) addRouteDef(routeDef []string, cidr netip.Prefix) error { if !r.getV6Available() && cidr.Addr().Is6() { return nil } args := append([]string{"ip", "route", "add"}, routeDef...) if r.ipRuleAvailable { args = append(args, "table", tailscaleRouteTable.ipCmdArg()) } err := r.cmd.run(args...) if err == nil { return nil } // This is an ugly hack to detect failure to add a route that // already exists (as happens in when we're racing to add // kernel-maintained routes when enabling exit nodes w/o Local // LAN access, Issue 3060). Fortunately in the common case we // use netlink directly instead and don't exercise this code. if errCode(err) == 2 && strings.Contains(err.Error(), "RTNETLINK answers: File exists") { r.logf("ignoring route add of %v; already exists", cidr) return nil } return err } var ( errESRCH error = syscall.ESRCH errENOENT error = syscall.ENOENT errEEXIST error = syscall.EEXIST ) // delRoute removes the route for cidr pointing to the tunnel // interface. Fails if the route doesn't exist, or if removing the // route fails. func (r *linuxRouter) delRoute(cidr netip.Prefix) error { if !r.getV6Available() && cidr.Addr().Is6() { return nil } if r.useIPCommand() { return r.delRouteDef([]string{normalizeCIDR(cidr), "dev", r.tunname}, cidr) } linkIndex, err := r.linkIndex() if err != nil { return err } err = netlink.RouteDel(&netlink.Route{ LinkIndex: linkIndex, Dst: netipx.PrefixIPNet(cidr.Masked()), Table: r.routeTable(), }) if errors.Is(err, errESRCH) { // Didn't exist to begin with. return nil } return err } // delThrowRoute removes the throw route for the cidr. Fails if the route // doesn't exist, or if removing the route fails. func (r *linuxRouter) delThrowRoute(cidr netip.Prefix) error { if !r.ipRuleAvailable { return nil } if !r.getV6Available() && cidr.Addr().Is6() { return nil } if r.useIPCommand() { return r.delRouteDef([]string{"throw", normalizeCIDR(cidr)}, cidr) } err := netlink.RouteDel(&netlink.Route{ Dst: netipx.PrefixIPNet(cidr.Masked()), Table: r.routeTable(), Type: unix.RTN_THROW, }) if errors.Is(err, errESRCH) { // Didn't exist to begin with. return nil } return err } func (r *linuxRouter) delRouteDef(routeDef []string, cidr netip.Prefix) error { if !r.getV6Available() && cidr.Addr().Is6() { return nil } args := append([]string{"ip", "route", "del"}, routeDef...) if r.ipRuleAvailable { args = append(args, "table", tailscaleRouteTable.ipCmdArg()) } err := r.cmd.run(args...) if err != nil { ok, err := r.hasRoute(routeDef, cidr) if err != nil { r.logf("warning: error checking whether %v even exists after error deleting it: %v", err) } else { if !ok { r.logf("warning: tried to delete route %v but it was already gone; ignoring error", cidr) return nil } } } return err } func dashFam(ip netip.Addr) string { if ip.Is6() { return "-6" } return "-4" } func (r *linuxRouter) hasRoute(routeDef []string, cidr netip.Prefix) (bool, error) { args := append([]string{"ip", dashFam(cidr.Addr()), "route", "show"}, routeDef...) if r.ipRuleAvailable { args = append(args, "table", tailscaleRouteTable.ipCmdArg()) } out, err := r.cmd.output(args...) if err != nil { return false, err } return len(out) > 0, nil } func (r *linuxRouter) link() (netlink.Link, error) { link, err := netlink.LinkByName(r.tunname) if err != nil { return nil, fmt.Errorf("failed to look up link %q: %w", r.tunname, err) } return link, nil } func (r *linuxRouter) linkIndex() (int, error) { // TODO(bradfitz): cache this? It doesn't change often, and on start-up // hundreds of addRoute calls to add /32s can happen quickly. link, err := r.link() if err != nil { return 0, err } return link.Attrs().Index, nil } // routeTable returns the route table to use. func (r *linuxRouter) routeTable() int { if r.ipRuleAvailable { return tailscaleRouteTable.Num } return 0 } // upInterface brings up the tunnel interface. func (r *linuxRouter) upInterface() error { if r.useIPCommand() { return r.cmd.run("ip", "link", "set", "dev", r.tunname, "up") } link, err := r.link() if err != nil { return fmt.Errorf("bringing interface up, %w", err) } return netlink.LinkSetUp(link) } // downInterface sets the tunnel interface administratively down. func (r *linuxRouter) downInterface() error { if r.useIPCommand() { return r.cmd.run("ip", "link", "set", "dev", r.tunname, "down") } link, err := r.link() if err != nil { return fmt.Errorf("bringing interface down, %w", err) } return netlink.LinkSetDown(link) } // fixupWSLMTU sets the MTU on the eth0 interface to 1360 bytes if running under // WSL, eth0 is the default route, and has the MTU 1280 bytes. func (r *linuxRouter) fixupWSLMTU() { if !distro.IsWSL() { return } if r.useIPCommand() { r.logf("fixupWSLMTU: not implemented by ip command") return } link, err := netlink.LinkByName("eth0") if err != nil { r.logf("warning: fixupWSLMTU: could not open eth0: %v", err) return } routes, err := netlink.RouteGet(net.IPv4(8, 8, 8, 8)) if err != nil || len(routes) == 0 { if err == nil { err = fmt.Errorf("none found") } r.logf("fixupWSLMTU: could not get default route: %v", err) return } if routes[0].LinkIndex != link.Attrs().Index { r.logf("fixupWSLMTU: default route is not via eth0") return } if link.Attrs().MTU == 1280 { if err := netlink.LinkSetMTU(link, 1360); err != nil { r.logf("warning: fixupWSLMTU: could not raise eth0 MTU: %v", err) } } } // addrFamily is an address family: IPv4 or IPv6. type addrFamily byte const ( v4 = addrFamily(4) v6 = addrFamily(6) ) func (f addrFamily) dashArg() string { switch f { case 4: return "-4" case 6: return "-6" } panic("illegal") } func (f addrFamily) netlinkInt() int { switch f { case 4: return netlink.FAMILY_V4 case 6: return netlink.FAMILY_V6 } panic("illegal") } func (r *linuxRouter) addrFamilies() []addrFamily { if r.getV6Available() { return []addrFamily{v4, v6} } return []addrFamily{v4} } // addIPRules adds the policy routing rule that avoids tailscaled // routing loops. If the rule exists and appears to be a // tailscale-managed rule, it is gracefully replaced. func (r *linuxRouter) addIPRules() error { if !r.ipRuleAvailable { return nil } // Clear out old rules. After that, any error adding a rule is fatal, // because there should be no reason we add a duplicate. if err := r.delIPRules(); err != nil { return err } return r.justAddIPRules() } // RouteTable is a Linux routing table: both its name and number. // See /etc/iproute2/rt_tables. type RouteTable struct { Name string Num int } var routeTableByNumber = map[int]RouteTable{} // IpCmdArg returns the string form of the table to pass to the "ip" command. func (rt RouteTable) ipCmdArg() string { if rt.Num >= 253 { return rt.Name } return strconv.Itoa(rt.Num) } func newRouteTable(name string, num int) RouteTable { rt := RouteTable{name, num} routeTableByNumber[num] = rt return rt } // MustRouteTable returns the RouteTable with the given number key. // It panics if the number is unknown because this result is a part // of IP rule argument and we don't want to continue with an invalid // argument with table no exist. func mustRouteTable(num int) RouteTable { rt, ok := routeTableByNumber[num] if !ok { panic(fmt.Sprintf("unknown route table %v", num)) } return rt } var ( mainRouteTable = newRouteTable("main", 254) defaultRouteTable = newRouteTable("default", 253) // tailscaleRouteTable is the routing table number for Tailscale // network routes. See addIPRules for the detailed policy routing // logic that ends up doing lookups within that table. // // NOTE(danderson): We chose 52 because those are the digits above the // letters "TS" on a qwerty keyboard, and 52 is sufficiently unlikely // to be picked by other software. // // NOTE(danderson): You might wonder why we didn't pick some // high table number like 5252, to further avoid the potential // for collisions with other software. Unfortunately, // Busybox's `ip` implementation believes that table numbers // are 8-bit integers, so for maximum compatibility we had to // stay in the 0-255 range even though linux itself supports // larger numbers. (but nowadays we use netlink directly and // aren't affected by the busybox binary's limitations) tailscaleRouteTable = newRouteTable("tailscale", 52) ) // ipRules are the policy routing rules that Tailscale uses. // The priority is the value represented here added to r.ipPolicyPrefBase, // which is usually 5200. // // NOTE(apenwarr): We leave spaces between each pref number. // This is so the sysadmin can override by inserting rules in // between if they want. // // NOTE(apenwarr): This sequence seems complicated, right? // If we could simply have a rule that said "match packets that // *don't* have this fwmark", then we would only need to add one // link to table 52 and we'd be done. Unfortunately, older kernels // and 'ip rule' implementations (including busybox), don't support // checking for the lack of a fwmark, only the presence. The technique // below works even on very old kernels. var ipRules = []netlink.Rule{ // Packets from us, tagged with our fwmark, first try the kernel's // main routing table. { Priority: 10, Mark: linuxfw.TailscaleBypassMarkNum, Table: mainRouteTable.Num, }, // ...and then we try the 'default' table, for correctness, // even though it's been empty on every Linux system I've ever seen. { Priority: 30, Mark: linuxfw.TailscaleBypassMarkNum, Table: defaultRouteTable.Num, }, // If neither of those matched (no default route on this system?) // then packets from us should be aborted rather than falling through // to the tailscale routes, because that would create routing loops. { Priority: 50, Mark: linuxfw.TailscaleBypassMarkNum, Type: unix.RTN_UNREACHABLE, }, // If we get to this point, capture all packets and send them // through to the tailscale route table. For apps other than us // (ie. with no fwmark set), this is the first routing table, so // it takes precedence over all the others, ie. VPN routes always // beat non-VPN routes. { Priority: 70, Table: tailscaleRouteTable.Num, }, // If that didn't match, then non-fwmark packets fall through to the // usual rules (pref 32766 and 32767, ie. main and default). } // justAddIPRules adds policy routing rule without deleting any first. func (r *linuxRouter) justAddIPRules() error { if !r.ipRuleAvailable { return nil } if r.useIPCommand() { return r.addIPRulesWithIPCommand() } var errAcc error for _, family := range r.addrFamilies() { for _, ru := range ipRules { // Note: r is a value type here; safe to mutate it. ru.Family = family.netlinkInt() if ru.Mark != 0 { ru.Mask = linuxfw.TailscaleFwmarkMaskNum } ru.Goto = -1 ru.SuppressIfgroup = -1 ru.SuppressPrefixlen = -1 ru.Flow = -1 ru.Priority += r.ipPolicyPrefBase err := netlink.RuleAdd(&ru) if errors.Is(err, errEEXIST) { // Ignore dups. continue } if err != nil && errAcc == nil { errAcc = err } } } return errAcc } func (r *linuxRouter) addIPRulesWithIPCommand() error { rg := newRunGroup(nil, r.cmd) for _, family := range r.addrFamilies() { for _, rule := range ipRules { args := []string{ "ip", family.dashArg(), "rule", "add", "pref", strconv.Itoa(rule.Priority + r.ipPolicyPrefBase), } if rule.Mark != 0 { if r.fwmaskWorks { args = append(args, "fwmark", fmt.Sprintf("0x%x/%s", rule.Mark, linuxfw.TailscaleFwmarkMask)) } else { args = append(args, "fwmark", fmt.Sprintf("0x%x", rule.Mark)) } } if rule.Table != 0 { args = append(args, "table", mustRouteTable(rule.Table).ipCmdArg()) } if rule.Type == unix.RTN_UNREACHABLE { args = append(args, "type", "unreachable") } rg.Run(args...) } } return rg.ErrAcc } // delRoutes removes any local routes that we added that would not be // cleaned up on interface down. func (r *linuxRouter) delRoutes() error { for rt := range r.localRoutes { if err := r.delThrowRoute(rt); err != nil { r.logf("failed to delete throw route(%q): %v", rt, err) } } return nil } // delIPRules removes the policy routing rules that avoid // tailscaled routing loops, if it exists. func (r *linuxRouter) delIPRules() error { if !r.ipRuleAvailable { return nil } if r.useIPCommand() { return r.delIPRulesWithIPCommand() } var errAcc error for _, family := range r.addrFamilies() { for _, ru := range ipRules { // Note: r is a value type here; safe to mutate it. // When deleting rules, we want to be a bit specific (mention which // table we were routing to) but not *too* specific (fwmarks, etc). // That leaves us some flexibility to change these values in later // versions without having ongoing hacks for every possible // combination. ru.Family = family.netlinkInt() ru.Mark = -1 ru.Mask = -1 ru.Goto = -1 ru.SuppressIfgroup = -1 ru.SuppressPrefixlen = -1 ru.Priority += r.ipPolicyPrefBase err := netlink.RuleDel(&ru) if errors.Is(err, errENOENT) { // Didn't exist to begin with. continue } if err != nil && errAcc == nil { errAcc = err } } } return errAcc } func (r *linuxRouter) delIPRulesWithIPCommand() error { // Error codes: 'ip rule' returns error code 2 if the rule is a // duplicate (add) or not found (del). It returns a different code // for syntax errors. This is also true of busybox. // // Some older versions of iproute2 also return error code 254 for // unknown rules during deletion. rg := newRunGroup([]int{2, 254}, r.cmd) for _, family := range r.addrFamilies() { // When deleting rules, we want to be a bit specific (mention which // table we were routing to) but not *too* specific (fwmarks, etc). // That leaves us some flexibility to change these values in later // versions without having ongoing hacks for every possible // combination. for _, rule := range ipRules { args := []string{ "ip", family.dashArg(), "rule", "del", "pref", strconv.Itoa(rule.Priority + r.ipPolicyPrefBase), } if rule.Table != 0 { args = append(args, "table", mustRouteTable(rule.Table).ipCmdArg()) } else { args = append(args, "type", "unreachable") } rg.Run(args...) } } return rg.ErrAcc } // addSNATRule adds a netfilter rule to SNAT traffic destined for // local subnets. func (r *linuxRouter) addSNATRule() error { if r.netfilterMode == netfilterOff { return nil } if err := r.nfr.AddSNATRule(); err != nil { return err } return nil } // delSNATRule removes the netfilter rule to SNAT traffic destined for // local subnets. Fails if the rule does not exist. func (r *linuxRouter) delSNATRule() error { if r.netfilterMode == netfilterOff { return nil } if err := r.nfr.DelSNATRule(); err != nil { return err } return nil } // cidrDiff calls add and del as needed to make the set of prefixes in // old and new match. Returns a map reflecting the actual new state // (which may be somewhere in between old and new if some commands // failed), and any error encountered while reconfiguring. func cidrDiff(kind string, old map[netip.Prefix]bool, new []netip.Prefix, add, del func(netip.Prefix) error, logf logger.Logf) (map[netip.Prefix]bool, error) { newMap := make(map[netip.Prefix]bool, len(new)) for _, cidr := range new { newMap[cidr] = true } // ret starts out as a copy of old, and updates as we // add/delete. That way we can always return it and have it be the // true state of what we've done so far. ret := make(map[netip.Prefix]bool, len(old)) for cidr := range old { ret[cidr] = true } // We want to add before we delete, so that if there is no overlap, we don't // end up in a state where we have no addresses on an interface as that // results in other kernel entities (like routes) pointing to that interface // to also be deleted. var addFail []error for cidr := range newMap { if old[cidr] { continue } if err := add(cidr); err != nil { logf("%s add failed: %v", kind, err) addFail = append(addFail, err) } else { ret[cidr] = true } } if len(addFail) == 1 { return ret, addFail[0] } if len(addFail) > 0 { return ret, fmt.Errorf("%d add %s failures; first was: %w", len(addFail), kind, addFail[0]) } var delFail []error for cidr := range old { if newMap[cidr] { continue } if err := del(cidr); err != nil { logf("%s del failed: %v", kind, err) delFail = append(delFail, err) } else { delete(ret, cidr) } } if len(delFail) == 1 { return ret, delFail[0] } if len(delFail) > 0 { return ret, fmt.Errorf("%d delete %s failures; first was: %w", len(delFail), kind, delFail[0]) } return ret, nil } // normalizeCIDR returns cidr as an ip/mask string, with the host bits // of the IP address zeroed out. func normalizeCIDR(cidr netip.Prefix) string { return cidr.Masked().String() } // cleanup removes all the rules and routes that were added by the linux router. // The function calls cleanup for both iptables and nftables since which ever // netfilter runner is used, the cleanup function for the other one doesn't do anything. func cleanup(logf logger.Logf, interfaceName string) { if interfaceName != "userspace-networking" { linuxfw.IPTablesCleanup(logf) linuxfw.NfTablesCleanUp(logf) } } // Checks if the running openWRT system is using mwan3, based on the heuristic // of the config file being present as well as a policy rule with a specific // priority (2000 + 1 - first interface mwan3 manages) and non-zero mark. func checkOpenWRTUsingMWAN3() (bool, error) { if distro.Get() != distro.OpenWrt { return false, nil } if _, err := os.Stat("/etc/config/mwan3"); err != nil { if os.IsNotExist(err) { return false, nil } return false, err } rules, err := netlink.RuleList(netlink.FAMILY_V4) if err != nil { return false, err } for _, r := range rules { // We want to match on a rule like this: // 2001: from all fwmark 0x100/0x3f00 lookup 1 // // We dont match on the mask because it can vary, or the // table because I'm not sure if it can vary. if r.Priority >= 2001 && r.Priority <= 2004 && r.Mark != 0 { return true, nil } } return false, nil } func nlAddrOfPrefix(p netip.Prefix) *netlink.Addr { return &netlink.Addr{ IPNet: netipx.PrefixIPNet(p), } }