// Copyright (c) Tailscale Inc & AUTHORS // SPDX-License-Identifier: BSD-3-Clause // Package interfaces contains helpers for looking up system network interfaces. package interfaces import ( "bytes" "fmt" "net" "net/http" "net/netip" "runtime" "slices" "sort" "strings" "tailscale.com/hostinfo" "tailscale.com/net/netaddr" "tailscale.com/net/tsaddr" "tailscale.com/net/tshttpproxy" ) // LoginEndpointForProxyDetermination is the URL used for testing // which HTTP proxy the system should use. var LoginEndpointForProxyDetermination = "https://controlplane.tailscale.com/" func isUp(nif *net.Interface) bool { return nif.Flags&net.FlagUp != 0 } func isLoopback(nif *net.Interface) bool { return nif.Flags&net.FlagLoopback != 0 } func isProblematicInterface(nif *net.Interface) bool { name := nif.Name // Don't try to send disco/etc packets over zerotier; they effectively // DoS each other by doing traffic amplification, both of them // preferring/trying to use each other for transport. See: // https://github.com/tailscale/tailscale/issues/1208 if strings.HasPrefix(name, "zt") || (runtime.GOOS == "windows" && strings.Contains(name, "ZeroTier")) { return true } return false } // LocalAddresses returns the machine's IP addresses, separated by // whether they're loopback addresses. If there are no regular addresses // it will return any IPv4 linklocal or IPv6 unique local addresses because we // know of environments where these are used with NAT to provide connectivity. func LocalAddresses() (regular, loopback []netip.Addr, err error) { // TODO(crawshaw): don't serve interface addresses that we are routing ifaces, err := netInterfaces() if err != nil { return nil, nil, err } var regular4, regular6, linklocal4, ula6 []netip.Addr for _, iface := range ifaces { stdIf := iface.Interface if !isUp(stdIf) || isProblematicInterface(stdIf) { // Skip down interfaces and ones that are // problematic that we don't want to try to // send Tailscale traffic over. continue } ifcIsLoopback := isLoopback(stdIf) addrs, err := iface.Addrs() if err != nil { return nil, nil, err } for _, a := range addrs { switch v := a.(type) { case *net.IPNet: ip, ok := netip.AddrFromSlice(v.IP) if !ok { continue } ip = ip.Unmap() // TODO(apenwarr): don't special case cgNAT. // In the general wireguard case, it might // very well be something we can route to // directly, because both nodes are // behind the same CGNAT router. if tsaddr.IsTailscaleIP(ip) { continue } if ip.IsLoopback() || ifcIsLoopback { loopback = append(loopback, ip) } else if ip.IsLinkLocalUnicast() { if ip.Is4() { linklocal4 = append(linklocal4, ip) } // We know of no cases where the IPv6 fe80:: addresses // are used to provide WAN connectivity. It is also very // common for users to have no IPv6 WAN connectivity, // but their OS supports IPv6 so they have an fe80:: // address. We don't want to report all of those // IPv6 LL to Control. } else if ip.Is6() && ip.IsPrivate() { // Google Cloud Run uses NAT with IPv6 Unique // Local Addresses to provide IPv6 connectivity. ula6 = append(ula6, ip) } else { if ip.Is4() { regular4 = append(regular4, ip) } else { regular6 = append(regular6, ip) } } } } } if len(regular4) == 0 && len(regular6) == 0 { // if we have no usable IP addresses then be willing to accept // addresses we otherwise wouldn't, like: // + 169.254.x.x (AWS Lambda and Azure App Services use NAT with these) // + IPv6 ULA (Google Cloud Run uses these with address translation) regular4 = linklocal4 regular6 = ula6 } regular = append(regular4, regular6...) sortIPs(regular) sortIPs(loopback) return regular, loopback, nil } func sortIPs(s []netip.Addr) { sort.Slice(s, func(i, j int) bool { return s[i].Less(s[j]) }) } // Interface is a wrapper around Go's net.Interface with some extra methods. type Interface struct { *net.Interface AltAddrs []net.Addr // if non-nil, returned by Addrs Desc string // extra description (used on Windows) } func (i Interface) IsLoopback() bool { return isLoopback(i.Interface) } func (i Interface) IsUp() bool { return isUp(i.Interface) } func (i Interface) Addrs() ([]net.Addr, error) { if i.AltAddrs != nil { return i.AltAddrs, nil } return i.Interface.Addrs() } // ForeachInterfaceAddress is a wrapper for GetList, then // List.ForeachInterfaceAddress. func ForeachInterfaceAddress(fn func(Interface, netip.Prefix)) error { ifaces, err := GetList() if err != nil { return err } return ifaces.ForeachInterfaceAddress(fn) } // ForeachInterfaceAddress calls fn for each interface in ifaces, with // all its addresses. The IPPrefix's IP is the IP address assigned to // the interface, and Bits are the subnet mask. func (ifaces List) ForeachInterfaceAddress(fn func(Interface, netip.Prefix)) error { for _, iface := range ifaces { addrs, err := iface.Addrs() if err != nil { return err } for _, a := range addrs { switch v := a.(type) { case *net.IPNet: if pfx, ok := netaddr.FromStdIPNet(v); ok { fn(iface, pfx) } } } } return nil } // ForeachInterface is a wrapper for GetList, then // List.ForeachInterface. func ForeachInterface(fn func(Interface, []netip.Prefix)) error { ifaces, err := GetList() if err != nil { return err } return ifaces.ForeachInterface(fn) } // ForeachInterface calls fn for each interface in ifaces, with // all its addresses. The IPPrefix's IP is the IP address assigned to // the interface, and Bits are the subnet mask. func (ifaces List) ForeachInterface(fn func(Interface, []netip.Prefix)) error { for _, iface := range ifaces { addrs, err := iface.Addrs() if err != nil { return err } var pfxs []netip.Prefix for _, a := range addrs { switch v := a.(type) { case *net.IPNet: if pfx, ok := netaddr.FromStdIPNet(v); ok { pfxs = append(pfxs, pfx) } } } sort.Slice(pfxs, func(i, j int) bool { return pfxs[i].Addr().Less(pfxs[j].Addr()) }) fn(iface, pfxs) } return nil } // State is intended to store the state of the machine's network interfaces, // routing table, and other network configuration. // For now it's pretty basic. type State struct { // InterfaceIPs maps from an interface name to the IP addresses // configured on that interface. Each address is represented as an // IPPrefix, where the IP is the interface IP address and Bits is // the subnet mask. InterfaceIPs map[string][]netip.Prefix Interface map[string]Interface // HaveV6 is whether this machine has an IPv6 Global or Unique Local Address // which might provide connectivity on a non-Tailscale interface that's up. HaveV6 bool // HaveV4 is whether the machine has some non-localhost, // non-link-local IPv4 address on a non-Tailscale interface that's up. HaveV4 bool // IsExpensive is whether the current network interface is // considered "expensive", which currently means LTE/etc // instead of Wifi. This field is not populated by GetState. IsExpensive bool // DefaultRouteInterface is the interface name for the // machine's default route. // // It is not yet populated on all OSes. // // When non-empty, its value is the map key into Interface and // InterfaceIPs. DefaultRouteInterface string // HTTPProxy is the HTTP proxy to use, if any. HTTPProxy string // PAC is the URL to the Proxy Autoconfig URL, if applicable. PAC string } func (s *State) String() string { var sb strings.Builder fmt.Fprintf(&sb, "interfaces.State{defaultRoute=%v ", s.DefaultRouteInterface) if s.DefaultRouteInterface != "" { if iface, ok := s.Interface[s.DefaultRouteInterface]; ok && iface.Desc != "" { fmt.Fprintf(&sb, "(%s) ", iface.Desc) } } sb.WriteString("ifs={") var ifs []string for k := range s.Interface { if s.keepInterfaceInStringSummary(k) { ifs = append(ifs, k) } } sort.Slice(ifs, func(i, j int) bool { upi, upj := s.Interface[ifs[i]].IsUp(), s.Interface[ifs[j]].IsUp() if upi != upj { // Up sorts before down. return upi } return ifs[i] < ifs[j] }) for i, ifName := range ifs { if i > 0 { sb.WriteString(" ") } iface := s.Interface[ifName] if iface.Interface == nil { fmt.Fprintf(&sb, "%s:nil", ifName) continue } if !iface.IsUp() { fmt.Fprintf(&sb, "%s:down", ifName) continue } fmt.Fprintf(&sb, "%s:[", ifName) needSpace := false for _, pfx := range s.InterfaceIPs[ifName] { a := pfx.Addr() if a.IsMulticast() { continue } fam := "4" if a.Is6() { fam = "6" } if needSpace { sb.WriteString(" ") } needSpace = true switch { case a.IsLoopback(): fmt.Fprintf(&sb, "lo%s", fam) case a.IsLinkLocalUnicast(): fmt.Fprintf(&sb, "llu%s", fam) default: fmt.Fprintf(&sb, "%s", pfx) } } sb.WriteString("]") } sb.WriteString("}") if s.IsExpensive { sb.WriteString(" expensive") } if s.HTTPProxy != "" { fmt.Fprintf(&sb, " httpproxy=%s", s.HTTPProxy) } if s.PAC != "" { fmt.Fprintf(&sb, " pac=%s", s.PAC) } fmt.Fprintf(&sb, " v4=%v v6=%v}", s.HaveV4, s.HaveV6) return sb.String() } // Equal reports whether s and s2 are exactly equal. func (s *State) Equal(s2 *State) bool { if s == nil && s2 == nil { return true } if s == nil || s2 == nil { return false } if s.HaveV6 != s2.HaveV6 || s.HaveV4 != s2.HaveV4 || s.IsExpensive != s2.IsExpensive || s.DefaultRouteInterface != s2.DefaultRouteInterface || s.HTTPProxy != s2.HTTPProxy || s.PAC != s2.PAC { return false } for iname, i := range s.Interface { i2, ok := s2.Interface[iname] if !ok { return false } if !i.Equal(i2) { return false } } for iname, vv := range s.InterfaceIPs { if !slices.Equal(vv, s2.InterfaceIPs[iname]) { return false } } return true } // HasIP reports whether any interface has the provided IP address. func (s *State) HasIP(ip netip.Addr) bool { if s == nil { return false } want := netip.PrefixFrom(ip, ip.BitLen()) for _, pv := range s.InterfaceIPs { for _, p := range pv { if p == want { return true } } } return false } func (a Interface) Equal(b Interface) bool { if (a.Interface == nil) != (b.Interface == nil) { return false } if !(a.Desc == b.Desc && netAddrsEqual(a.AltAddrs, b.AltAddrs)) { return false } if a.Interface != nil && !(a.Index == b.Index && a.MTU == b.MTU && a.Name == b.Name && a.Flags == b.Flags && bytes.Equal([]byte(a.HardwareAddr), []byte(b.HardwareAddr))) { return false } return true } func (s *State) HasPAC() bool { return s != nil && s.PAC != "" } // AnyInterfaceUp reports whether any interface seems like it has Internet access. func (s *State) AnyInterfaceUp() bool { if runtime.GOOS == "js" || runtime.GOOS == "tamago" { return true } return s != nil && (s.HaveV4 || s.HaveV6) } func netAddrsEqual(a, b []net.Addr) bool { if len(a) != len(b) { return false } for i, av := range a { if av.Network() != b[i].Network() || av.String() != b[i].String() { return false } } return true } func hasTailscaleIP(pfxs []netip.Prefix) bool { for _, pfx := range pfxs { if tsaddr.IsTailscaleIP(pfx.Addr()) { return true } } return false } func isTailscaleInterface(name string, ips []netip.Prefix) bool { if runtime.GOOS == "darwin" && strings.HasPrefix(name, "utun") && hasTailscaleIP(ips) { // On macOS in the sandboxed app (at least as of // 2021-02-25), we often see two utun devices // (e.g. utun4 and utun7) with the same IPv4 and IPv6 // addresses. Just remove all utun devices with // Tailscale IPs until we know what's happening with // macOS NetworkExtensions and utun devices. return true } return name == "Tailscale" || // as it is on Windows strings.HasPrefix(name, "tailscale") // TODO: use --tun flag value, etc; see TODO in method doc } // getPAC, if non-nil, returns the current PAC file URL. var getPAC func() string // GetState returns the state of all the current machine's network interfaces. // // It does not set the returned State.IsExpensive. The caller can populate that. // // Deprecated: use netmon.Monitor.InterfaceState instead. func GetState() (*State, error) { s := &State{ InterfaceIPs: make(map[string][]netip.Prefix), Interface: make(map[string]Interface), } if err := ForeachInterface(func(ni Interface, pfxs []netip.Prefix) { ifUp := ni.IsUp() s.Interface[ni.Name] = ni s.InterfaceIPs[ni.Name] = append(s.InterfaceIPs[ni.Name], pfxs...) if !ifUp || isTailscaleInterface(ni.Name, pfxs) { return } for _, pfx := range pfxs { if pfx.Addr().IsLoopback() { continue } s.HaveV6 = s.HaveV6 || isUsableV6(pfx.Addr()) s.HaveV4 = s.HaveV4 || isUsableV4(pfx.Addr()) } }); err != nil { return nil, err } dr, _ := DefaultRoute() s.DefaultRouteInterface = dr.InterfaceName // Populate description (for Windows, primarily) if present. if desc := dr.InterfaceDesc; desc != "" { if iface, ok := s.Interface[dr.InterfaceName]; ok { iface.Desc = desc s.Interface[dr.InterfaceName] = iface } } if s.AnyInterfaceUp() { req, err := http.NewRequest("GET", LoginEndpointForProxyDetermination, nil) if err != nil { return nil, err } if u, err := tshttpproxy.ProxyFromEnvironment(req); err == nil && u != nil { s.HTTPProxy = u.String() } if getPAC != nil { s.PAC = getPAC() } } return s, nil } // HTTPOfListener returns the HTTP address to ln. // If the listener is listening on the unspecified address, it // it tries to find a reasonable interface address on the machine to use. func HTTPOfListener(ln net.Listener) string { ta, ok := ln.Addr().(*net.TCPAddr) if !ok || !ta.IP.IsUnspecified() { return fmt.Sprintf("http://%v/", ln.Addr()) } var goodIP string var privateIP string ForeachInterfaceAddress(func(i Interface, pfx netip.Prefix) { ip := pfx.Addr() if ip.IsPrivate() { if privateIP == "" { privateIP = ip.String() } return } goodIP = ip.String() }) if privateIP != "" { goodIP = privateIP } if goodIP != "" { return fmt.Sprintf("http://%v/", net.JoinHostPort(goodIP, fmt.Sprint(ta.Port))) } return fmt.Sprintf("http://localhost:%v/", fmt.Sprint(ta.Port)) } var likelyHomeRouterIP func() (netip.Addr, bool) // LikelyHomeRouterIP returns the likely IP of the residential router, // which will always be an IPv4 private address, if found. // In addition, it returns the IP address of the current machine on // the LAN using that gateway. // This is used as the destination for UPnP, NAT-PMP, PCP, etc queries. func LikelyHomeRouterIP() (gateway, myIP netip.Addr, ok bool) { if likelyHomeRouterIP != nil { gateway, ok = likelyHomeRouterIP() if !ok { return } } if !ok { return } ForeachInterfaceAddress(func(i Interface, pfx netip.Prefix) { if !i.IsUp() { // Skip interfaces that aren't up. return } else if myIP.IsValid() { // We already have a valid self IP; skip this one. return } ip := pfx.Addr() if !ip.IsValid() || !ip.Is4() { // Skip IPs that aren't valid or aren't IPv4, since we // always return an IPv4 address. return } if gateway.IsPrivate() && ip.IsPrivate() { myIP = ip ok = true return } }) return gateway, myIP, myIP.IsValid() } // isUsableV4 reports whether ip is a usable IPv4 address which could // conceivably be used to get Internet connectivity. Globally routable and // private IPv4 addresses are always Usable, and link local 169.254.x.x // addresses are in some environments. func isUsableV4(ip netip.Addr) bool { if !ip.Is4() || ip.IsLoopback() { return false } if ip.IsLinkLocalUnicast() { switch hostinfo.GetEnvType() { case hostinfo.AWSLambda: return true case hostinfo.AzureAppService: return true default: return false } } return true } // isUsableV6 reports whether ip is a usable IPv6 address which could // conceivably be used to get Internet connectivity. Globally routable // IPv6 addresses are always Usable, and Unique Local Addresses // (fc00::/7) are in some environments used with address translation. func isUsableV6(ip netip.Addr) bool { return v6Global1.Contains(ip) || (ip.Is6() && ip.IsPrivate() && !tsaddr.TailscaleULARange().Contains(ip)) } var ( v6Global1 = netip.MustParsePrefix("2000::/3") ) // keepInterfaceInStringSummary reports whether the named interface should be included // in the String method's summary string. func (s *State) keepInterfaceInStringSummary(ifName string) bool { iface, ok := s.Interface[ifName] if !ok || iface.Interface == nil { return false } if ifName == s.DefaultRouteInterface { return true } up := iface.IsUp() for _, p := range s.InterfaceIPs[ifName] { a := p.Addr() if a.IsLinkLocalUnicast() || a.IsLoopback() { continue } if up || a.IsGlobalUnicast() || a.IsPrivate() { return true } } return false } // isInterestingIP reports whether ip is an interesting IP that we // should log in interfaces.State logging. We don't need to show // loopback, link-local addresses, or non-Tailscale ULA addresses. func isInterestingIP(ip netip.Addr) bool { if ip.IsLoopback() || ip.IsLinkLocalUnicast() { return false } return true } var altNetInterfaces func() ([]Interface, error) // RegisterInterfaceGetter sets the function that's used to query // the system network interfaces. func RegisterInterfaceGetter(getInterfaces func() ([]Interface, error)) { altNetInterfaces = getInterfaces } // List is a list of interfaces on the machine. type List []Interface // GetList returns the list of interfaces on the machine. func GetList() (List, error) { return netInterfaces() } // netInterfaces is a wrapper around the standard library's net.Interfaces // that returns a []*Interface instead of a []net.Interface. // It exists because Android SDK 30 no longer permits Go's net.Interfaces // to work (Issue 2293); this wrapper lets us the Android app register // an alternate implementation. func netInterfaces() ([]Interface, error) { if altNetInterfaces != nil { return altNetInterfaces() } ifs, err := net.Interfaces() if err != nil { return nil, err } ret := make([]Interface, len(ifs)) for i := range ifs { ret[i].Interface = &ifs[i] } return ret, nil } // DefaultRouteDetails are the details about a default route returned // by DefaultRoute. type DefaultRouteDetails struct { // InterfaceName is the interface name. It must always be populated. // It's like "eth0" (Linux), "Ethernet 2" (Windows), "en0" (macOS). InterfaceName string // InterfaceDesc is populated on Windows at least. It's a // longer description, like "Red Hat VirtIO Ethernet Adapter". InterfaceDesc string // InterfaceIndex is like net.Interface.Index. // Zero means not populated. InterfaceIndex int // TODO(bradfitz): break this out into v4-vs-v6 once that need arises. } // DefaultRouteInterface is like DefaultRoute but only returns the // interface name. func DefaultRouteInterface() (string, error) { dr, err := DefaultRoute() if err != nil { return "", err } return dr.InterfaceName, nil } // DefaultRoute returns details of the network interface that owns // the default route, not including any tailscale interfaces. func DefaultRoute() (DefaultRouteDetails, error) { return defaultRoute() } // HasCGNATInterface reports whether there are any non-Tailscale interfaces that // use a CGNAT IP range. func HasCGNATInterface() (bool, error) { hasCGNATInterface := false cgnatRange := tsaddr.CGNATRange() err := ForeachInterface(func(i Interface, pfxs []netip.Prefix) { if hasCGNATInterface || !i.IsUp() || isTailscaleInterface(i.Name, pfxs) { return } for _, pfx := range pfxs { if cgnatRange.Overlaps(pfx) { hasCGNATInterface = true break } } }) if err != nil { return false, err } return hasCGNATInterface, nil } var interfaceDebugExtras func(ifIndex int) (string, error) // InterfaceDebugExtras returns extra debugging information about an interface // if any (an empty string will be returned if there are no additional details). // Formatting is platform-dependent and should not be parsed. func InterfaceDebugExtras(ifIndex int) (string, error) { if interfaceDebugExtras != nil { return interfaceDebugExtras(ifIndex) } return "", nil }