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tailscale/wgengine/netstack/netstack.go

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// Copyright (c) Tailscale Inc & AUTHORS
// SPDX-License-Identifier: BSD-3-Clause
// Package netstack wires up gVisor's netstack into Tailscale.
package netstack
import (
"bytes"
"context"
"errors"
"expvar"
"fmt"
"io"
"log"
"math"
"net"
"net/netip"
"runtime"
"strconv"
"sync"
"sync/atomic"
"time"
"gvisor.dev/gvisor/pkg/buffer"
"gvisor.dev/gvisor/pkg/refs"
"gvisor.dev/gvisor/pkg/tcpip"
"gvisor.dev/gvisor/pkg/tcpip/adapters/gonet"
"gvisor.dev/gvisor/pkg/tcpip/header"
"gvisor.dev/gvisor/pkg/tcpip/link/channel"
"gvisor.dev/gvisor/pkg/tcpip/network/ipv4"
"gvisor.dev/gvisor/pkg/tcpip/network/ipv6"
"gvisor.dev/gvisor/pkg/tcpip/stack"
"gvisor.dev/gvisor/pkg/tcpip/transport/icmp"
"gvisor.dev/gvisor/pkg/tcpip/transport/tcp"
"gvisor.dev/gvisor/pkg/tcpip/transport/udp"
"gvisor.dev/gvisor/pkg/waiter"
"tailscale.com/drive"
"tailscale.com/envknob"
"tailscale.com/ipn/ipnlocal"
"tailscale.com/metrics"
"tailscale.com/net/dns"
"tailscale.com/net/ipset"
"tailscale.com/net/netaddr"
"tailscale.com/net/packet"
"tailscale.com/net/tsaddr"
"tailscale.com/net/tsdial"
"tailscale.com/net/tstun"
"tailscale.com/proxymap"
"tailscale.com/syncs"
"tailscale.com/tailcfg"
"tailscale.com/types/ipproto"
"tailscale.com/types/logger"
"tailscale.com/types/netmap"
"tailscale.com/types/nettype"
"tailscale.com/util/clientmetric"
"tailscale.com/version"
"tailscale.com/wgengine"
"tailscale.com/wgengine/filter"
"tailscale.com/wgengine/magicsock"
)
const debugPackets = false
// If non-zero, these override the values returned from the corresponding
// functions, below.
var (
maxInFlightConnectionAttemptsForTest int
maxInFlightConnectionAttemptsPerClientForTest int
)
// maxInFlightConnectionAttempts returns the global number of in-flight
// connection attempts that we allow for a single netstack Impl. Any new
// forwarded TCP connections that are opened after the limit has been hit are
// rejected until the number of in-flight connections drops below the limit
// again.
//
// Each in-flight connection attempt is a new goroutine and an open TCP
// connection, so we want to ensure that we don't allow an unbounded number of
// connections.
func maxInFlightConnectionAttempts() int {
if n := maxInFlightConnectionAttemptsForTest; n > 0 {
return n
}
if version.IsMobile() {
return 1024 // previous global value
}
switch version.OS() {
case "linux":
// On the assumption that most subnet routers deployed in
// production are running on Linux, we return a higher value.
//
// TODO(andrew-d): tune this based on the amount of system
// memory instead of a fixed limit.
return 8192
default:
// On all other platforms, return a reasonably high value that
// most users won't hit.
return 2048
}
}
// maxInFlightConnectionAttemptsPerClient is the same as
// maxInFlightConnectionAttempts, but applies on a per-client basis
// (i.e. keyed by the remote Tailscale IP).
func maxInFlightConnectionAttemptsPerClient() int {
if n := maxInFlightConnectionAttemptsPerClientForTest; n > 0 {
return n
}
// For now, allow each individual client at most 2/3rds of the global
// limit. On all platforms except mobile, this won't be a visible
// change for users since this limit was added at the same time as we
// bumped the global limit, above.
return maxInFlightConnectionAttempts() * 2 / 3
}
var debugNetstack = envknob.RegisterBool("TS_DEBUG_NETSTACK")
var (
serviceIP = tsaddr.TailscaleServiceIP()
serviceIPv6 = tsaddr.TailscaleServiceIPv6()
)
func init() {
mode := envknob.String("TS_DEBUG_NETSTACK_LEAK_MODE")
if mode == "" {
return
}
var lm refs.LeakMode
if err := lm.Set(mode); err != nil {
panic(err)
}
refs.SetLeakMode(lm)
}
// Impl contains the state for the netstack implementation,
// and implements wgengine.FakeImpl to act as a userspace network
// stack when Tailscale is running in fake mode.
type Impl struct {
// GetTCPHandlerForFlow conditionally handles an incoming TCP flow for the
// provided (src/port, dst/port) 4-tuple.
//
// A nil value is equivalent to a func returning (nil, false).
//
// If func returns intercept=false, the default forwarding behavior (if
// ProcessLocalIPs and/or ProcesssSubnetIPs) takes place.
//
// When intercept=true, the behavior depends on whether the returned handler
// is non-nil: if nil, the connection is rejected. If non-nil, handler takes
// over the TCP conn.
GetTCPHandlerForFlow func(src, dst netip.AddrPort) (handler func(net.Conn), intercept bool)
// GetUDPHandlerForFlow conditionally handles an incoming UDP flow for the
// provided (src/port, dst/port) 4-tuple.
//
// A nil value is equivalent to a func returning (nil, false).
//
// If func returns intercept=false, the default forwarding behavior (if
// ProcessLocalIPs and/or ProcesssSubnetIPs) takes place.
//
// When intercept=true, the behavior depends on whether the returned handler
// is non-nil: if nil, the connection is rejected. If non-nil, handler takes
// over the UDP flow.
GetUDPHandlerForFlow func(src, dst netip.AddrPort) (handler func(nettype.ConnPacketConn), intercept bool)
// ProcessLocalIPs is whether netstack should handle incoming
// traffic directed at the Node.Addresses (local IPs).
// It can only be set before calling Start.
ProcessLocalIPs bool
// ProcessSubnets is whether netstack should handle incoming
// traffic destined to non-local IPs (i.e. whether it should
// be a subnet router).
// It can only be set before calling Start.
ProcessSubnets bool
ipstack *stack.Stack
linkEP *channel.Endpoint
tundev *tstun.Wrapper
e wgengine.Engine
pm *proxymap.Mapper
mc *magicsock.Conn
logf logger.Logf
dialer *tsdial.Dialer
ctx context.Context // alive until Close
ctxCancel context.CancelFunc // called on Close
lb *ipnlocal.LocalBackend // or nil
dns *dns.Manager
driveForLocal drive.FileSystemForLocal // or nil
peerapiPort4Atomic atomic.Uint32 // uint16 port number for IPv4 peerapi
peerapiPort6Atomic atomic.Uint32 // uint16 port number for IPv6 peerapi
// atomicIsLocalIPFunc holds a func that reports whether an IP
// is a local (non-subnet) Tailscale IP address of this
// machine. It's always a non-nil func. It's changed on netmap
// updates.
atomicIsLocalIPFunc syncs.AtomicValue[func(netip.Addr) bool]
// forwardDialFunc, if non-nil, is the net.Dialer.DialContext-style
// function that is used to make outgoing connections when forwarding a
// TCP connection to another host (e.g. in subnet router mode).
//
// This is currently only used in tests.
forwardDialFunc func(context.Context, string, string) (net.Conn, error)
// forwardInFlightPerClientDropped is a metric that tracks how many
// in-flight TCP forward requests were dropped due to the per-client
// limit.
forwardInFlightPerClientDropped expvar.Int
mu sync.Mutex
// connsOpenBySubnetIP keeps track of number of connections open
// for each subnet IP temporarily registered on netstack for active
// TCP connections, so they can be unregistered when connections are
// closed.
connsOpenBySubnetIP map[netip.Addr]int
// connsInFlightByClient keeps track of the number of in-flight
// connections by the client ("Tailscale") IP. This is used to apply a
// per-client limit on in-flight connections that's smaller than the
// global limit, preventing a misbehaving client from starving the
// global limit.
connsInFlightByClient map[netip.Addr]int
// packetsInFlight tracks whether we're already handling a packet by
// the given endpoint ID; clients can send repeated SYN packets while
// trying to establish a connection (and while we're dialing the
// upstream address). If we don't deduplicate based on the endpoint,
// each SYN retransmit results in us incrementing
// connsInFlightByClient, and not decrementing them because the
// underlying TCP forwarder returns 'true' to indicate that the packet
// is handled but never actually launches our acceptTCP function.
//
// This mimics the 'inFlight' map in the TCP forwarder; it's
// unfortunate that we have to track this all twice, but thankfully the
// map only holds pending (in-flight) packets, and it's reasonably cheap.
packetsInFlight map[stack.TransportEndpointID]struct{}
}
const nicID = 1
// maxUDPPacketSize is the maximum size of a UDP packet we copy in
// startPacketCopy when relaying UDP packets. The user can configure
// the tailscale MTU to anything up to this size so we can potentially
// have a UDP packet as big as the MTU.
const maxUDPPacketSize = tstun.MaxPacketSize
// Create creates and populates a new Impl.
func Create(logf logger.Logf, tundev *tstun.Wrapper, e wgengine.Engine, mc *magicsock.Conn, dialer *tsdial.Dialer, dns *dns.Manager, pm *proxymap.Mapper, driveForLocal drive.FileSystemForLocal) (*Impl, error) {
if mc == nil {
return nil, errors.New("nil magicsock.Conn")
}
if tundev == nil {
return nil, errors.New("nil tundev")
}
if logf == nil {
return nil, errors.New("nil logger")
}
if e == nil {
return nil, errors.New("nil Engine")
}
if pm == nil {
return nil, errors.New("nil proxymap.Mapper")
}
if dialer == nil {
return nil, errors.New("nil Dialer")
}
ipstack := stack.New(stack.Options{
NetworkProtocols: []stack.NetworkProtocolFactory{ipv4.NewProtocol, ipv6.NewProtocol},
TransportProtocols: []stack.TransportProtocolFactory{tcp.NewProtocol, udp.NewProtocol, icmp.NewProtocol4, icmp.NewProtocol6},
})
sackEnabledOpt := tcpip.TCPSACKEnabled(true) // TCP SACK is disabled by default
tcpipErr := ipstack.SetTransportProtocolOption(tcp.ProtocolNumber, &sackEnabledOpt)
if tcpipErr != nil {
return nil, fmt.Errorf("could not enable TCP SACK: %v", tcpipErr)
}
if runtime.GOOS == "windows" {
// See https://github.com/tailscale/tailscale/issues/9707
// Windows w/RACK performs poorly. ACKs do not appear to be handled in a
// timely manner, leading to spurious retransmissions and a reduced
// congestion window.
tcpRecoveryOpt := tcpip.TCPRecovery(0)
tcpipErr = ipstack.SetTransportProtocolOption(tcp.ProtocolNumber, &tcpRecoveryOpt)
if tcpipErr != nil {
return nil, fmt.Errorf("could not disable TCP RACK: %v", tcpipErr)
}
}
linkEP := channel.New(512, uint32(tstun.DefaultTUNMTU()), "")
if tcpipProblem := ipstack.CreateNIC(nicID, linkEP); tcpipProblem != nil {
return nil, fmt.Errorf("could not create netstack NIC: %v", tcpipProblem)
}
// By default the netstack NIC will only accept packets for the IPs
// registered to it. Since in some cases we dynamically register IPs
// based on the packets that arrive, the NIC needs to accept all
// incoming packets. The NIC won't receive anything it isn't meant to
// since WireGuard will only send us packets that are meant for us.
ipstack.SetPromiscuousMode(nicID, true)
// Add IPv4 and IPv6 default routes, so all incoming packets from the Tailscale side
// are handled by the one fake NIC we use.
ipv4Subnet, err := tcpip.NewSubnet(tcpip.AddrFromSlice(make([]byte, 4)), tcpip.MaskFromBytes(make([]byte, 4)))
if err != nil {
return nil, fmt.Errorf("could not create IPv4 subnet: %v", err)
}
ipv6Subnet, err := tcpip.NewSubnet(tcpip.AddrFromSlice(make([]byte, 16)), tcpip.MaskFromBytes(make([]byte, 16)))
if err != nil {
return nil, fmt.Errorf("could not create IPv6 subnet: %v", err)
}
ipstack.SetRouteTable([]tcpip.Route{
{
Destination: ipv4Subnet,
NIC: nicID,
},
{
Destination: ipv6Subnet,
NIC: nicID,
},
})
ns := &Impl{
logf: logf,
ipstack: ipstack,
linkEP: linkEP,
tundev: tundev,
e: e,
pm: pm,
mc: mc,
dialer: dialer,
connsOpenBySubnetIP: make(map[netip.Addr]int),
connsInFlightByClient: make(map[netip.Addr]int),
packetsInFlight: make(map[stack.TransportEndpointID]struct{}),
dns: dns,
driveForLocal: driveForLocal,
}
ns.ctx, ns.ctxCancel = context.WithCancel(context.Background())
ns.atomicIsLocalIPFunc.Store(ipset.FalseContainsIPFunc())
ns.tundev.PostFilterPacketInboundFromWireGuard = ns.injectInbound
ns.tundev.PreFilterPacketOutboundToWireGuardNetstackIntercept = ns.handleLocalPackets
stacksForMetrics.Store(ns, struct{}{})
return ns, nil
}
func (ns *Impl) Close() error {
stacksForMetrics.Delete(ns)
ns.ctxCancel()
ns.ipstack.Close()
ns.ipstack.Wait()
return nil
}
// A single process might have several netstacks running at the same time.
// Exported clientmetric counters will have a sum of counters of all of them.
var stacksForMetrics syncs.Map[*Impl, struct{}]
func init() {
// Please take care to avoid exporting clientmetrics with the same metric
// names as the ones used by Impl.ExpVar. Both get exposed via the same HTTP
// endpoint, and name collisions will result in Prometheus scraping errors.
clientmetric.NewCounterFunc("netstack_tcp_forward_dropped_attempts", func() int64 {
var total uint64
stacksForMetrics.Range(func(ns *Impl, _ struct{}) bool {
delta := ns.ipstack.Stats().TCP.ForwardMaxInFlightDrop.Value()
if total+delta > math.MaxInt64 {
total = math.MaxInt64
return false
}
total += delta
return true
})
return int64(total)
})
}
type protocolHandlerFunc func(stack.TransportEndpointID, *stack.PacketBuffer) bool
// wrapUDPProtocolHandler wraps the protocol handler we pass to netstack for UDP.
func (ns *Impl) wrapUDPProtocolHandler(h protocolHandlerFunc) protocolHandlerFunc {
return func(tei stack.TransportEndpointID, pb *stack.PacketBuffer) bool {
addr := tei.LocalAddress
ip, ok := netip.AddrFromSlice(addr.AsSlice())
if !ok {
ns.logf("netstack: could not parse local address for incoming connection")
return false
}
// Dynamically reconfigure ns's subnet addresses as needed for
// outbound traffic.
ip = ip.Unmap()
if !ns.isLocalIP(ip) {
ns.addSubnetAddress(ip)
}
return h(tei, pb)
}
}
var (
metricPerClientForwardLimit = clientmetric.NewCounter("netstack_tcp_forward_dropped_attempts_per_client")
)
// wrapTCPProtocolHandler wraps the protocol handler we pass to netstack for TCP.
func (ns *Impl) wrapTCPProtocolHandler(h protocolHandlerFunc) protocolHandlerFunc {
// 'handled' is whether the packet should be accepted by netstack; if
// true, then the TCP connection is accepted by the transport layer and
// passes through our acceptTCP handler/etc. If false, then the packet
// is dropped and the TCP connection is rejected (typically with an
// ICMP Port Unreachable or ICMP Protocol Unreachable message).
return func(tei stack.TransportEndpointID, pb *stack.PacketBuffer) (handled bool) {
localIP, ok := netip.AddrFromSlice(tei.LocalAddress.AsSlice())
if !ok {
ns.logf("netstack: could not parse local address for incoming connection")
return false
}
localIP = localIP.Unmap()
remoteIP, ok := netip.AddrFromSlice(tei.RemoteAddress.AsSlice())
if !ok {
ns.logf("netstack: could not parse remote address for incoming connection")
return false
}
// If we have too many in-flight connections for this client, abort
// early and don't open a new one.
//
// NOTE: the counter is decremented in
// decrementInFlightTCPForward, called from the acceptTCP
// function, below.
ns.mu.Lock()
if _, ok := ns.packetsInFlight[tei]; ok {
// We're already handling this packet; just bail early
// (this is also what would happen in the TCP
// forwarder).
ns.mu.Unlock()
return true
}
// Check the per-client limit.
inFlight := ns.connsInFlightByClient[remoteIP]
tooManyInFlight := inFlight >= maxInFlightConnectionAttemptsPerClient()
if !tooManyInFlight {
ns.connsInFlightByClient[remoteIP]++
}
// We're handling this packet now; see the comment on the
// packetsInFlight field for more details.
ns.packetsInFlight[tei] = struct{}{}
ns.mu.Unlock()
if debugNetstack() {
ns.logf("[v2] netstack: in-flight connections for client %v: %d", remoteIP, inFlight)
}
if tooManyInFlight {
ns.logf("netstack: ignoring a new TCP connection from %v to %v because the client already has %d in-flight connections", localIP, remoteIP, inFlight)
metricPerClientForwardLimit.Add(1)
ns.forwardInFlightPerClientDropped.Add(1)
return false // unhandled
}
// On return, if this packet isn't handled by the inner handler
// we're wrapping (`h`), we need to decrement the per-client
// in-flight count and remove the ID from our tracking map.
// This can happen if the underlying forwarder's limit has been
// reached, at which point it will return false to indicate
// that it's not handling the packet, and it will not run
// acceptTCP. If we don't decrement here, then we would
// eventually increment the per-client counter up to the limit
// and never decrement because we'd never hit the codepath in
// acceptTCP, below, or just drop all packets from the same
// endpoint due to the packetsInFlight check.
defer func() {
if !handled {
ns.mu.Lock()
delete(ns.packetsInFlight, tei)
ns.connsInFlightByClient[remoteIP]--
new := ns.connsInFlightByClient[remoteIP]
ns.mu.Unlock()
ns.logf("netstack: decrementing connsInFlightByClient[%v] because the packet was not handled; new value is %d", remoteIP, new)
}
}()
// Dynamically reconfigure ns's subnet addresses as needed for
// outbound traffic.
if !ns.isLocalIP(localIP) {
ns.addSubnetAddress(localIP)
}
return h(tei, pb)
}
}
func (ns *Impl) decrementInFlightTCPForward(tei stack.TransportEndpointID, remoteAddr netip.Addr) {
ns.mu.Lock()
defer ns.mu.Unlock()
// Remove this packet so future SYNs from this address will be handled.
delete(ns.packetsInFlight, tei)
was := ns.connsInFlightByClient[remoteAddr]
newVal := was - 1
if newVal == 0 {
delete(ns.connsInFlightByClient, remoteAddr) // free up space in the map
} else {
ns.connsInFlightByClient[remoteAddr] = newVal
}
}
// Start sets up all the handlers so netstack can start working. Implements
// wgengine.FakeImpl.
func (ns *Impl) Start(lb *ipnlocal.LocalBackend) error {
if lb == nil {
panic("nil LocalBackend")
}
ns.lb = lb
// size = 0 means use default buffer size
const tcpReceiveBufferSize = 0
tcpFwd := tcp.NewForwarder(ns.ipstack, tcpReceiveBufferSize, maxInFlightConnectionAttempts(), ns.acceptTCP)
udpFwd := udp.NewForwarder(ns.ipstack, ns.acceptUDP)
ns.ipstack.SetTransportProtocolHandler(tcp.ProtocolNumber, ns.wrapTCPProtocolHandler(tcpFwd.HandlePacket))
ns.ipstack.SetTransportProtocolHandler(udp.ProtocolNumber, ns.wrapUDPProtocolHandler(udpFwd.HandlePacket))
go ns.inject()
return nil
}
func (ns *Impl) addSubnetAddress(ip netip.Addr) {
ns.mu.Lock()
ns.connsOpenBySubnetIP[ip]++
needAdd := ns.connsOpenBySubnetIP[ip] == 1
ns.mu.Unlock()
// Only register address into netstack for first concurrent connection.
if needAdd {
pa := tcpip.ProtocolAddress{
AddressWithPrefix: tcpip.AddrFromSlice(ip.AsSlice()).WithPrefix(),
}
if ip.Is4() {
pa.Protocol = ipv4.ProtocolNumber
} else if ip.Is6() {
pa.Protocol = ipv6.ProtocolNumber
}
ns.ipstack.AddProtocolAddress(nicID, pa, stack.AddressProperties{
PEB: stack.CanBePrimaryEndpoint, // zero value default
ConfigType: stack.AddressConfigStatic, // zero value default
})
}
}
func (ns *Impl) removeSubnetAddress(ip netip.Addr) {
ns.mu.Lock()
defer ns.mu.Unlock()
ns.connsOpenBySubnetIP[ip]--
// Only unregister address from netstack after last concurrent connection.
if ns.connsOpenBySubnetIP[ip] == 0 {
ns.ipstack.RemoveAddress(nicID, tcpip.AddrFromSlice(ip.AsSlice()))
delete(ns.connsOpenBySubnetIP, ip)
}
}
func ipPrefixToAddressWithPrefix(ipp netip.Prefix) tcpip.AddressWithPrefix {
return tcpip.AddressWithPrefix{
Address: tcpip.AddrFromSlice(ipp.Addr().AsSlice()),
PrefixLen: int(ipp.Bits()),
}
}
var v4broadcast = netaddr.IPv4(255, 255, 255, 255)
// UpdateNetstackIPs updates the set of local IPs that netstack should handle
// from nm.
//
// TODO(bradfitz): don't pass the whole netmap here; just pass the two
// address slice views.
func (ns *Impl) UpdateNetstackIPs(nm *netmap.NetworkMap) {
var selfNode tailcfg.NodeView
if nm != nil {
ns.atomicIsLocalIPFunc.Store(ipset.NewContainsIPFunc(nm.GetAddresses()))
selfNode = nm.SelfNode
} else {
ns.atomicIsLocalIPFunc.Store(ipset.FalseContainsIPFunc())
}
oldPfx := make(map[netip.Prefix]bool)
for _, protocolAddr := range ns.ipstack.AllAddresses()[nicID] {
ap := protocolAddr.AddressWithPrefix
ip := netaddrIPFromNetstackIP(ap.Address)
if ip == v4broadcast && ap.PrefixLen == 32 {
// Don't add 255.255.255.255/32 to oldIPs so we don't
// delete it later. We didn't install it, so it's not
// ours to delete.
continue
}
p := netip.PrefixFrom(ip, ap.PrefixLen)
oldPfx[p] = true
}
newPfx := make(map[netip.Prefix]bool)
if selfNode.Valid() {
for i := range selfNode.Addresses().Len() {
p := selfNode.Addresses().At(i)
newPfx[p] = true
}
if ns.ProcessSubnets {
for i := range selfNode.AllowedIPs().Len() {
p := selfNode.AllowedIPs().At(i)
newPfx[p] = true
}
}
}
pfxToAdd := make(map[netip.Prefix]bool)
for p := range newPfx {
if !oldPfx[p] {
pfxToAdd[p] = true
}
}
pfxToRemove := make(map[netip.Prefix]bool)
for p := range oldPfx {
if !newPfx[p] {
pfxToRemove[p] = true
}
}
ns.mu.Lock()
for ip := range ns.connsOpenBySubnetIP {
// TODO(maisem): this looks like a bug, remove or document. It seems as
// though we might end up either leaking the address on the netstack
// NIC, or where we do accounting for connsOpenBySubnetIP from 1 to 0,
// we might end up removing the address from the netstack NIC that was
// still being advertised.
delete(pfxToRemove, netip.PrefixFrom(ip, ip.BitLen()))
}
ns.mu.Unlock()
for p := range pfxToRemove {
err := ns.ipstack.RemoveAddress(nicID, tcpip.AddrFromSlice(p.Addr().AsSlice()))
if err != nil {
ns.logf("netstack: could not deregister IP %s: %v", p, err)
} else {
ns.logf("[v2] netstack: deregistered IP %s", p)
}
}
for p := range pfxToAdd {
if !p.IsValid() {
ns.logf("netstack: [unexpected] skipping invalid IP (%v/%v)", p.Addr(), p.Bits())
continue
}
tcpAddr := tcpip.ProtocolAddress{
AddressWithPrefix: ipPrefixToAddressWithPrefix(p),
}
if p.Addr().Is6() {
tcpAddr.Protocol = ipv6.ProtocolNumber
} else {
tcpAddr.Protocol = ipv4.ProtocolNumber
}
var tcpErr tcpip.Error // not error
tcpErr = ns.ipstack.AddProtocolAddress(nicID, tcpAddr, stack.AddressProperties{
PEB: stack.CanBePrimaryEndpoint, // zero value default
ConfigType: stack.AddressConfigStatic, // zero value default
})
if tcpErr != nil {
ns.logf("netstack: could not register IP %s: %v", p, tcpErr)
} else {
ns.logf("[v2] netstack: registered IP %s", p)
}
}
}
// handleLocalPackets is hooked into the tun datapath for packets leaving
// the host and arriving at tailscaled. This method returns filter.DropSilently
// to intercept a packet for handling, for instance traffic to quad-100.
func (ns *Impl) handleLocalPackets(p *packet.Parsed, t *tstun.Wrapper) filter.Response {
if ns.ctx.Err() != nil {
return filter.DropSilently
}
// Determine if we care about this local packet.
dst := p.Dst.Addr()
switch {
case dst == serviceIP || dst == serviceIPv6:
// We want to intercept some traffic to the "service IP" (e.g.
// 100.100.100.100 for IPv4). However, of traffic to the
// service IP, we only care about UDP 53, and TCP on port 53,
// 80, and 8080.
switch p.IPProto {
case ipproto.TCP:
if port := p.Dst.Port(); port != 53 && port != 80 && port != 8080 {
return filter.Accept
}
case ipproto.UDP:
if port := p.Dst.Port(); port != 53 {
return filter.Accept
}
}
case viaRange.Contains(dst):
// We need to handle 4via6 packets leaving the host if the via
// route is for this host; otherwise the packet will be dropped
// because nothing will translate it.
var shouldHandle bool
if p.IPVersion == 6 && !ns.isLocalIP(dst) {
shouldHandle = ns.lb != nil && ns.lb.ShouldHandleViaIP(dst)
}
if !shouldHandle {
// Unhandled means that we let the regular processing
// occur without doing anything ourselves.
return filter.Accept
}
if debugNetstack() {
ns.logf("netstack: handling local 4via6 packet: version=%d proto=%v dst=%v src=%v",
p.IPVersion, p.IPProto, p.Dst, p.Src)
}
// If this is a ping message, handle it and don't pass to
// netstack.
pingIP, handlePing := ns.shouldHandlePing(p)
if handlePing {
ns.logf("netstack: handling local 4via6 ping: dst=%v pingIP=%v", dst, pingIP)
var pong []byte // the reply to the ping, if our relayed ping works
if dst.Is4() {
h := p.ICMP4Header()
h.ToResponse()
pong = packet.Generate(&h, p.Payload())
} else if dst.Is6() {
h := p.ICMP6Header()
h.ToResponse()
pong = packet.Generate(&h, p.Payload())
}
go ns.userPing(pingIP, pong, userPingDirectionInbound)
return filter.DropSilently
}
// Fall through to writing inbound so netstack handles the
// 4via6 via connection.
default:
// Not traffic to the service IP or a 4via6 IP, so we don't
// care about the packet; resume processing.
return filter.Accept
}
var pn tcpip.NetworkProtocolNumber
switch p.IPVersion {
case 4:
pn = header.IPv4ProtocolNumber
case 6:
pn = header.IPv6ProtocolNumber
}
if debugPackets {
ns.logf("[v2] service packet in (from %v): % x", p.Src, p.Buffer())
}
packetBuf := stack.NewPacketBuffer(stack.PacketBufferOptions{
Payload: buffer.MakeWithData(bytes.Clone(p.Buffer())),
})
ns.linkEP.InjectInbound(pn, packetBuf)
packetBuf.DecRef()
return filter.DropSilently
}
func (ns *Impl) DialContextTCP(ctx context.Context, ipp netip.AddrPort) (*gonet.TCPConn, error) {
remoteAddress := tcpip.FullAddress{
NIC: nicID,
Addr: tcpip.AddrFromSlice(ipp.Addr().AsSlice()),
Port: ipp.Port(),
}
var ipType tcpip.NetworkProtocolNumber
if ipp.Addr().Is4() {
ipType = ipv4.ProtocolNumber
} else {
ipType = ipv6.ProtocolNumber
}
return gonet.DialContextTCP(ctx, ns.ipstack, remoteAddress, ipType)
}
func (ns *Impl) DialContextUDP(ctx context.Context, ipp netip.AddrPort) (*gonet.UDPConn, error) {
remoteAddress := &tcpip.FullAddress{
NIC: nicID,
Addr: tcpip.AddrFromSlice(ipp.Addr().AsSlice()),
Port: ipp.Port(),
}
var ipType tcpip.NetworkProtocolNumber
if ipp.Addr().Is4() {
ipType = ipv4.ProtocolNumber
} else {
ipType = ipv6.ProtocolNumber
}
return gonet.DialUDP(ns.ipstack, nil, remoteAddress, ipType)
}
// The inject goroutine reads in packets that netstack generated, and delivers
// them to the correct path.
func (ns *Impl) inject() {
for {
pkt := ns.linkEP.ReadContext(ns.ctx)
if pkt.IsNil() {
if ns.ctx.Err() != nil {
// Return without logging.
return
}
ns.logf("[v2] ReadContext-for-write = ok=false")
continue
}
if debugPackets {
ns.logf("[v2] packet Write out: % x", stack.PayloadSince(pkt.NetworkHeader()).AsSlice())
}
// In the normal case, netstack synthesizes the bytes for
// traffic which should transit back into WG and go to peers.
// However, some uses of netstack (presently, magic DNS)
// send traffic destined for the local device, hence must
// be injected 'inbound'.
sendToHost := ns.shouldSendToHost(pkt)
// pkt has a non-zero refcount, so injection methods takes
// ownership of one count and will decrement on completion.
if sendToHost {
if err := ns.tundev.InjectInboundPacketBuffer(pkt); err != nil {
log.Printf("netstack inject inbound: %v", err)
return
}
} else {
if err := ns.tundev.InjectOutboundPacketBuffer(pkt); err != nil {
log.Printf("netstack inject outbound: %v", err)
return
}
}
}
}
// shouldSendToHost determines if the provided packet should be sent to the
// host (i.e the current machine running Tailscale), in which case it will
// return true. It will return false if the packet should be sent outbound, for
// transit via WireGuard to another Tailscale node.
func (ns *Impl) shouldSendToHost(pkt *stack.PacketBuffer) bool {
// Determine if the packet is from a service IP (100.100.100.100 or the
// IPv6 variant), in which case it needs to go back into the machine's
// network (inbound) instead of out.
hdr := pkt.Network()
switch v := hdr.(type) {
case header.IPv4:
srcIP := netip.AddrFrom4(v.SourceAddress().As4())
if serviceIP == srcIP {
return true
}
case header.IPv6:
srcIP := netip.AddrFrom16(v.SourceAddress().As16())
if srcIP == serviceIPv6 {
return true
}
if viaRange.Contains(srcIP) {
// Only send to the host if this 4via6 route is
// something this node handles.
if ns.lb != nil && ns.lb.ShouldHandleViaIP(srcIP) {
dstIP := netip.AddrFrom16(v.DestinationAddress().As16())
// Also, only forward to the host if the packet
// is destined for a local IP; otherwise, we'd
// send traffic that's intended for another
// peer from the local 4via6 address to the
// host instead of outbound to WireGuard. See:
// https://github.com/tailscale/tailscale/issues/12448
if ns.isLocalIP(dstIP) {
return true
}
if debugNetstack() {
ns.logf("netstack: sending 4via6 packet to host: src=%v dst=%v", srcIP, dstIP)
}
}
}
default:
// unknown; don't forward to host
if debugNetstack() {
ns.logf("netstack: unexpected packet in shouldSendToHost: %T", v)
}
}
return false
}
// isLocalIP reports whether ip is a Tailscale IP assigned to this
// node directly (but not a subnet-routed IP).
func (ns *Impl) isLocalIP(ip netip.Addr) bool {
return ns.atomicIsLocalIPFunc.Load()(ip)
}
func (ns *Impl) peerAPIPortAtomic(ip netip.Addr) *atomic.Uint32 {
if ip.Is4() {
return &ns.peerapiPort4Atomic
} else {
return &ns.peerapiPort6Atomic
}
}
var viaRange = tsaddr.TailscaleViaRange()
// shouldProcessInbound reports whether an inbound packet (a packet from a
// WireGuard peer) should be handled by netstack.
func (ns *Impl) shouldProcessInbound(p *packet.Parsed, t *tstun.Wrapper) bool {
// Handle incoming peerapi connections in netstack.
dstIP := p.Dst.Addr()
isLocal := ns.isLocalIP(dstIP)
// Handle TCP connection to the Tailscale IP(s) in some cases:
if ns.lb != nil && p.IPProto == ipproto.TCP && isLocal {
var peerAPIPort uint16
if p.TCPFlags&packet.TCPSynAck == packet.TCPSyn {
if port, ok := ns.lb.GetPeerAPIPort(dstIP); ok {
peerAPIPort = port
ns.peerAPIPortAtomic(dstIP).Store(uint32(port))
}
} else {
peerAPIPort = uint16(ns.peerAPIPortAtomic(dstIP).Load())
}
dport := p.Dst.Port()
if dport == peerAPIPort {
return true
}
// Also handle SSH connections, webserver, etc, if enabled:
if ns.lb.ShouldInterceptTCPPort(dport) {
return true
}
}
if p.IPVersion == 6 && !isLocal && viaRange.Contains(dstIP) {
return ns.lb != nil && ns.lb.ShouldHandleViaIP(dstIP)
}
if ns.ProcessLocalIPs && isLocal {
return true
}
if ns.ProcessSubnets && !isLocal {
return true
}
return false
}
var userPingSem = syncs.NewSemaphore(20) // 20 child ping processes at once
type userPingDirection int
const (
// userPingDirectionOutbound is used when the pong packet is to be sent
// "outbound"i.e. from this node to a peer via WireGuard.
userPingDirectionOutbound userPingDirection = iota
// userPingDirectionInbound is used when the pong packet is to be sent
// "inbound"i.e. from Tailscale to another process on this host.
userPingDirectionInbound
)
// userPing tried to ping dstIP and if it succeeds, injects pingResPkt
// into the tundev.
//
// It's used in userspace/netstack mode when we don't have kernel
// support or raw socket access. As such, this does the dumbest thing
// that can work: runs the ping command. It's not super efficient, so
// it bounds the number of pings going on at once. The idea is that
// people only use ping occasionally to see if their internet's working
// so this doesn't need to be great.
// On Apple platforms, this function doesn't run the ping command. Instead,
// it sends a non-privileged ping.
//
// The 'direction' parameter is used to determine where the response "pong"
// packet should be written, if the ping succeeds. See the documentation on the
// constants for more details.
//
// TODO(bradfitz): when we're running on Windows as the system user, use
// raw socket APIs instead of ping child processes.
func (ns *Impl) userPing(dstIP netip.Addr, pingResPkt []byte, direction userPingDirection) {
if !userPingSem.TryAcquire() {
return
}
defer userPingSem.Release()
t0 := time.Now()
err := ns.sendOutboundUserPing(dstIP, 3*time.Second)
d := time.Since(t0)
if err != nil {
if d < time.Second/2 {
// If it failed quicker than the 3 second
// timeout we gave above (500 ms is a
// reasonable threshold), then assume the ping
// failed for problems finding/running
// ping. We don't want to log if the host is
// just down.
ns.logf("exec ping of %v failed in %v: %v", dstIP, d, err)
}
return
}
if debugNetstack() {
ns.logf("exec pinged %v in %v", dstIP, time.Since(t0))
}
if direction == userPingDirectionOutbound {
if err := ns.tundev.InjectOutbound(pingResPkt); err != nil {
ns.logf("InjectOutbound ping response: %v", err)
}
} else if direction == userPingDirectionInbound {
if err := ns.tundev.InjectInboundCopy(pingResPkt); err != nil {
ns.logf("InjectInboundCopy ping response: %v", err)
}
}
}
// injectInbound is installed as a packet hook on the 'inbound' (from a
// WireGuard peer) path. Returning filter.Accept releases the packet to
// continue normally (typically being delivered to the host networking stack),
// whereas returning filter.DropSilently is done when netstack intercepts the
// packet and no further processing towards to host should be done.
func (ns *Impl) injectInbound(p *packet.Parsed, t *tstun.Wrapper) filter.Response {
if ns.ctx.Err() != nil {
return filter.DropSilently
}
if !ns.shouldProcessInbound(p, t) {
// Let the host network stack (if any) deal with it.
return filter.Accept
}
destIP := p.Dst.Addr()
// If this is an echo request and we're a subnet router, handle pings
// ourselves instead of forwarding the packet on.
pingIP, handlePing := ns.shouldHandlePing(p)
if handlePing {
var pong []byte // the reply to the ping, if our relayed ping works
if destIP.Is4() {
h := p.ICMP4Header()
h.ToResponse()
pong = packet.Generate(&h, p.Payload())
} else if destIP.Is6() {
h := p.ICMP6Header()
h.ToResponse()
pong = packet.Generate(&h, p.Payload())
}
go ns.userPing(pingIP, pong, userPingDirectionOutbound)
return filter.DropSilently
}
var pn tcpip.NetworkProtocolNumber
switch p.IPVersion {
case 4:
pn = header.IPv4ProtocolNumber
case 6:
pn = header.IPv6ProtocolNumber
}
if debugPackets {
ns.logf("[v2] packet in (from %v): % x", p.Src, p.Buffer())
}
packetBuf := stack.NewPacketBuffer(stack.PacketBufferOptions{
Payload: buffer.MakeWithData(bytes.Clone(p.Buffer())),
})
ns.linkEP.InjectInbound(pn, packetBuf)
packetBuf.DecRef()
// We've now delivered this to netstack, so we're done.
// Instead of returning a filter.Accept here (which would also
// potentially deliver it to the host OS), and instead of
// filter.Drop (which would log about rejected traffic),
// instead return filter.DropSilently which just quietly stops
// processing it in the tstun TUN wrapper.
return filter.DropSilently
}
// shouldHandlePing returns whether or not netstack should handle an incoming
// ICMP echo request packet, and the IP address that should be pinged from this
// process. The IP address can be different from the destination in the packet
// if the destination is a 4via6 address.
func (ns *Impl) shouldHandlePing(p *packet.Parsed) (_ netip.Addr, ok bool) {
if !p.IsEchoRequest() {
return netip.Addr{}, false
}
destIP := p.Dst.Addr()
// We need to handle pings for all 4via6 addresses, even if this
// netstack instance normally isn't responsible for processing subnets.
//
// For example, on Linux, subnet router traffic could be handled via
// tun+iptables rules for most packets, but we still need to handle
// ICMP echo requests over 4via6 since the host networking stack
// doesn't know what to do with a 4via6 address.
//
// shouldProcessInbound returns 'true' to say that we should process
// all IPv6 packets with a destination address in the 'via' range, so
// check before we check the "ProcessSubnets" boolean below.
if viaRange.Contains(destIP) {
// The input echo request was to a 4via6 address, which we cannot
// simply ping as-is from this process. Translate the destination to an
// IPv4 address, so that our relayed ping (in userPing) is pinging the
// underlying destination IP.
//
// ICMPv4 and ICMPv6 are different protocols with different on-the-wire
// representations, so normally you can't send an ICMPv6 message over
// IPv4 and expect to get a useful result. However, in this specific
// case things are safe because the 'userPing' function doesn't make
// use of the input packet.
return tsaddr.UnmapVia(destIP), true
}
// If we get here, we don't do anything unless this netstack instance
// is responsible for processing subnet traffic.
if !ns.ProcessSubnets {
return netip.Addr{}, false
}
// For non-4via6 addresses, we don't handle pings if they're destined
// for a Tailscale IP.
if tsaddr.IsTailscaleIP(destIP) {
return netip.Addr{}, false
}
// This netstack instance is processing subnet traffic, so handle the
// ping ourselves.
return destIP, true
}
func netaddrIPFromNetstackIP(s tcpip.Address) netip.Addr {
switch s.Len() {
case 4:
s := s.As4()
return netaddr.IPv4(s[0], s[1], s[2], s[3])
case 16:
s := s.As16()
return netip.AddrFrom16(s).Unmap()
}
return netip.Addr{}
}
func (ns *Impl) acceptTCP(r *tcp.ForwarderRequest) {
reqDetails := r.ID()
if debugNetstack() {
ns.logf("[v2] TCP ForwarderRequest: %s", stringifyTEI(reqDetails))
}
clientRemoteIP := netaddrIPFromNetstackIP(reqDetails.RemoteAddress)
if !clientRemoteIP.IsValid() {
ns.logf("invalid RemoteAddress in TCP ForwarderRequest: %s", stringifyTEI(reqDetails))
r.Complete(true) // sends a RST
return
}
// After we've returned from this function or have otherwise reached a
// non-pending state, decrement the per-client in-flight count and
// remove this endpoint from our packet tracking map so future TCP
// connections aren't dropped.
inFlightCompleted := false
tei := r.ID()
defer func() {
if !inFlightCompleted {
ns.decrementInFlightTCPForward(tei, clientRemoteIP)
}
}()
clientRemotePort := reqDetails.RemotePort
clientRemoteAddrPort := netip.AddrPortFrom(clientRemoteIP, clientRemotePort)
dialIP := netaddrIPFromNetstackIP(reqDetails.LocalAddress)
isTailscaleIP := tsaddr.IsTailscaleIP(dialIP)
dstAddrPort := netip.AddrPortFrom(dialIP, reqDetails.LocalPort)
if viaRange.Contains(dialIP) {
isTailscaleIP = false
dialIP = tsaddr.UnmapVia(dialIP)
}
defer func() {
if !isTailscaleIP {
// if this is a subnet IP, we added this in before the TCP handshake
// so netstack is happy TCP-handshaking as a subnet IP
ns.removeSubnetAddress(dialIP)
}
}()
var wq waiter.Queue
// We can't actually create the endpoint or complete the inbound
// request until we're sure that the connection can be handled by this
// endpoint. This function sets up the TCP connection and should be
// called immediately before a connection is handled.
getConnOrReset := func(opts ...tcpip.SettableSocketOption) *gonet.TCPConn {
ep, err := r.CreateEndpoint(&wq)
if err != nil {
ns.logf("CreateEndpoint error for %s: %v", stringifyTEI(reqDetails), err)
r.Complete(true) // sends a RST
return nil
}
r.Complete(false)
for _, opt := range opts {
ep.SetSockOpt(opt)
}
// SetKeepAlive so that idle connections to peers that have forgotten about
// the connection or gone completely offline eventually time out.
// Applications might be setting this on a forwarded connection, but from
// userspace we can not see those, so the best we can do is to always
// perform them with conservative timing.
// TODO(tailscale/tailscale#4522): Netstack defaults match the Linux
// defaults, and results in a little over two hours before the socket would
// be closed due to keepalive. A shorter default might be better, or seeking
// a default from the host IP stack. This also might be a useful
// user-tunable, as in userspace mode this can have broad implications such
// as lingering connections to fork style daemons. On the other side of the
// fence, the long duration timers are low impact values for battery powered
// peers.
ep.SocketOptions().SetKeepAlive(true)
// This function is called when we're ready to use the
// underlying connection, and thus it's no longer in a
// "in-flight" state; decrement our per-client limit right now,
// and tell the defer in acceptTCP that it doesn't need to do
// so upon return.
ns.decrementInFlightTCPForward(tei, clientRemoteIP)
inFlightCompleted = true
// The ForwarderRequest.CreateEndpoint above asynchronously
// starts the TCP handshake. Note that the gonet.TCPConn
// methods c.RemoteAddr() and c.LocalAddr() will return nil
// until the handshake actually completes. But we have the
// remote address in reqDetails instead, so we don't use
// gonet.TCPConn.RemoteAddr. The byte copies in both
// directions to/from the gonet.TCPConn in forwardTCP will
// block until the TCP handshake is complete.
return gonet.NewTCPConn(&wq, ep)
}
// Local Services (DNS and WebDAV)
hittingServiceIP := dialIP == serviceIP || dialIP == serviceIPv6
hittingDNS := hittingServiceIP && reqDetails.LocalPort == 53
if hittingDNS {
c := getConnOrReset()
if c == nil {
return
}
addrPort := netip.AddrPortFrom(clientRemoteIP, reqDetails.RemotePort)
go ns.dns.HandleTCPConn(c, addrPort)
return
}
if ns.lb != nil {
handler, opts := ns.lb.TCPHandlerForDst(clientRemoteAddrPort, dstAddrPort)
if handler != nil {
c := getConnOrReset(opts...) // will send a RST if it fails
if c == nil {
return
}
handler(c)
return
}
}
if ns.GetTCPHandlerForFlow != nil {
handler, ok := ns.GetTCPHandlerForFlow(clientRemoteAddrPort, dstAddrPort)
if ok {
if handler == nil {
r.Complete(true)
return
}
c := getConnOrReset() // will send a RST if it fails
if c == nil {
return
}
handler(c)
return
}
}
if isTailscaleIP {
dialIP = netaddr.IPv4(127, 0, 0, 1)
}
dialAddr := netip.AddrPortFrom(dialIP, uint16(reqDetails.LocalPort))
if !ns.forwardTCP(getConnOrReset, clientRemoteIP, &wq, dialAddr) {
r.Complete(true) // sends a RST
}
}
func (ns *Impl) forwardTCP(getClient func(...tcpip.SettableSocketOption) *gonet.TCPConn, clientRemoteIP netip.Addr, wq *waiter.Queue, dialAddr netip.AddrPort) (handled bool) {
dialAddrStr := dialAddr.String()
if debugNetstack() {
ns.logf("[v2] netstack: forwarding incoming connection to %s", dialAddrStr)
}
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
waitEntry, notifyCh := waiter.NewChannelEntry(waiter.EventHUp) // TODO(bradfitz): right EventMask?
wq.EventRegister(&waitEntry)
defer wq.EventUnregister(&waitEntry)
done := make(chan bool)
// netstack doesn't close the notification channel automatically if there was no
// hup signal, so we close done after we're done to not leak the goroutine below.
defer close(done)
go func() {
select {
case <-notifyCh:
if debugNetstack() {
ns.logf("[v2] netstack: forwardTCP notifyCh fired; canceling context for %s", dialAddrStr)
}
case <-done:
}
cancel()
}()
// Attempt to dial the outbound connection before we accept the inbound one.
var dialFunc func(context.Context, string, string) (net.Conn, error)
if ns.forwardDialFunc != nil {
dialFunc = ns.forwardDialFunc
} else {
var stdDialer net.Dialer
dialFunc = stdDialer.DialContext
}
server, err := dialFunc(ctx, "tcp", dialAddrStr)
if err != nil {
ns.logf("netstack: could not connect to local server at %s: %v", dialAddr.String(), err)
return
}
defer server.Close()
// If we get here, either the getClient call below will succeed and
// return something we can Close, or it will fail and will properly
// respond to the client with a RST. Either way, the caller no longer
// needs to clean up the client connection.
handled = true
// We dialed the connection; we can complete the client's TCP handshake.
client := getClient()
if client == nil {
return
}
defer client.Close()
backendLocalAddr := server.LocalAddr().(*net.TCPAddr)
backendLocalIPPort := netaddr.Unmap(backendLocalAddr.AddrPort())
ns.pm.RegisterIPPortIdentity("tcp", backendLocalIPPort, clientRemoteIP)
defer ns.pm.UnregisterIPPortIdentity("tcp", backendLocalIPPort)
connClosed := make(chan error, 2)
go func() {
_, err := io.Copy(server, client)
connClosed <- err
}()
go func() {
_, err := io.Copy(client, server)
connClosed <- err
}()
err = <-connClosed
if err != nil {
ns.logf("proxy connection closed with error: %v", err)
}
ns.logf("[v2] netstack: forwarder connection to %s closed", dialAddrStr)
return
}
// ListenPacket listens for incoming packets for the given network and address.
// Address must be of the form "ip:port" or "[ip]:port".
//
// As of 2024-05-18, only udp4 and udp6 are supported.
func (ns *Impl) ListenPacket(network, address string) (net.PacketConn, error) {
ap, err := netip.ParseAddrPort(address)
if err != nil {
return nil, fmt.Errorf("netstack: ParseAddrPort(%q): %v", address, err)
}
var networkProto tcpip.NetworkProtocolNumber
switch network {
case "udp":
return nil, fmt.Errorf("netstack: udp not supported; use udp4 or udp6")
case "udp4":
networkProto = ipv4.ProtocolNumber
if !ap.Addr().Is4() {
return nil, fmt.Errorf("netstack: udp4 requires an IPv4 address")
}
case "udp6":
networkProto = ipv6.ProtocolNumber
if !ap.Addr().Is6() {
return nil, fmt.Errorf("netstack: udp6 requires an IPv6 address")
}
default:
return nil, fmt.Errorf("netstack: unsupported network %q", network)
}
var wq waiter.Queue
ep, nserr := ns.ipstack.NewEndpoint(udp.ProtocolNumber, networkProto, &wq)
if nserr != nil {
return nil, fmt.Errorf("netstack: NewEndpoint: %v", nserr)
}
localAddress := tcpip.FullAddress{
NIC: nicID,
Addr: tcpip.AddrFromSlice(ap.Addr().AsSlice()),
Port: ap.Port(),
}
if err := ep.Bind(localAddress); err != nil {
ep.Close()
return nil, fmt.Errorf("netstack: Bind(%v): %v", localAddress, err)
}
return gonet.NewUDPConn(&wq, ep), nil
}
func (ns *Impl) acceptUDP(r *udp.ForwarderRequest) {
sess := r.ID()
if debugNetstack() {
ns.logf("[v2] UDP ForwarderRequest: %v", stringifyTEI(sess))
}
var wq waiter.Queue
ep, err := r.CreateEndpoint(&wq)
if err != nil {
ns.logf("acceptUDP: could not create endpoint: %v", err)
return
}
dstAddr, ok := ipPortOfNetstackAddr(sess.LocalAddress, sess.LocalPort)
if !ok {
ep.Close()
return
}
srcAddr, ok := ipPortOfNetstackAddr(sess.RemoteAddress, sess.RemotePort)
if !ok {
ep.Close()
return
}
// Handle magicDNS traffic (via UDP) here.
if dst := dstAddr.Addr(); dst == serviceIP || dst == serviceIPv6 {
if dstAddr.Port() != 53 {
ep.Close()
return // Only MagicDNS traffic runs on the service IPs for now.
}
c := gonet.NewUDPConn(&wq, ep)
go ns.handleMagicDNSUDP(srcAddr, c)
return
}
if get := ns.GetUDPHandlerForFlow; get != nil {
h, intercept := get(srcAddr, dstAddr)
if intercept {
if h == nil {
ep.Close()
return
}
go h(gonet.NewUDPConn(&wq, ep))
return
}
}
c := gonet.NewUDPConn(&wq, ep)
go ns.forwardUDP(c, srcAddr, dstAddr)
}
// Buffer pool for forwarding UDP packets. Implementations are advised not to
// exceed 512 bytes per DNS request due to fragmenting but in reality can and do
// send much larger packets, so use the maximum possible UDP packet size.
var udpBufPool = &sync.Pool{
New: func() any {
b := make([]byte, maxUDPPacketSize)
return &b
},
}
func (ns *Impl) handleMagicDNSUDP(srcAddr netip.AddrPort, c *gonet.UDPConn) {
// Packets are being generated by the local host, so there should be
// very, very little latency. 150ms was chosen as something of an upper
// bound on resource usage, while hopefully still being long enough for
// a heavily loaded system.
const readDeadline = 150 * time.Millisecond
defer c.Close()
bufp := udpBufPool.Get().(*[]byte)
defer udpBufPool.Put(bufp)
q := *bufp
// libresolv from glibc is quite adamant that transmitting multiple DNS
// requests down the same UDP socket is valid. To support this, we read
// in a loop (with a tight deadline so we don't chew too many resources).
//
// See: https://github.com/bminor/glibc/blob/f7fbb99652eceb1b6b55e4be931649df5946497c/resolv/res_send.c#L995
for {
c.SetReadDeadline(time.Now().Add(readDeadline))
n, _, err := c.ReadFrom(q)
if err != nil {
if oe, ok := err.(*net.OpError); !(ok && oe.Timeout()) {
ns.logf("dns udp read: %v", err) // log non-timeout errors
}
return
}
resp, err := ns.dns.Query(context.Background(), q[:n], "udp", srcAddr)
if err != nil {
ns.logf("dns udp query: %v", err)
return
}
c.Write(resp)
}
}
// forwardUDP proxies between client (with addr clientAddr) and dstAddr.
//
// dstAddr may be either a local Tailscale IP, in which we case we proxy to
// 127.0.0.1, or any other IP (from an advertised subnet), in which case we
// proxy to it directly.
func (ns *Impl) forwardUDP(client *gonet.UDPConn, clientAddr, dstAddr netip.AddrPort) {
port, srcPort := dstAddr.Port(), clientAddr.Port()
if debugNetstack() {
ns.logf("[v2] netstack: forwarding incoming UDP connection on port %v", port)
}
var backendListenAddr *net.UDPAddr
var backendRemoteAddr *net.UDPAddr
isLocal := ns.isLocalIP(dstAddr.Addr())
if isLocal {
backendRemoteAddr = &net.UDPAddr{IP: net.ParseIP("127.0.0.1"), Port: int(port)}
backendListenAddr = &net.UDPAddr{IP: net.ParseIP("127.0.0.1"), Port: int(srcPort)}
} else {
if dstIP := dstAddr.Addr(); viaRange.Contains(dstIP) {
dstAddr = netip.AddrPortFrom(tsaddr.UnmapVia(dstIP), dstAddr.Port())
}
backendRemoteAddr = net.UDPAddrFromAddrPort(dstAddr)
if dstAddr.Addr().Is4() {
backendListenAddr = &net.UDPAddr{IP: net.ParseIP("0.0.0.0"), Port: int(srcPort)}
} else {
backendListenAddr = &net.UDPAddr{IP: net.ParseIP("::"), Port: int(srcPort)}
}
}
backendConn, err := net.ListenUDP("udp", backendListenAddr)
if err != nil {
ns.logf("netstack: could not bind local port %v: %v, trying again with random port", backendListenAddr.Port, err)
backendListenAddr.Port = 0
backendConn, err = net.ListenUDP("udp", backendListenAddr)
if err != nil {
ns.logf("netstack: could not create UDP socket, preventing forwarding to %v: %v", dstAddr, err)
return
}
}
backendLocalAddr := backendConn.LocalAddr().(*net.UDPAddr)
backendLocalIPPort := netip.AddrPortFrom(backendListenAddr.AddrPort().Addr().Unmap().WithZone(backendLocalAddr.Zone), backendLocalAddr.AddrPort().Port())
if !backendLocalIPPort.IsValid() {
ns.logf("could not get backend local IP:port from %v:%v", backendLocalAddr.IP, backendLocalAddr.Port)
}
if isLocal {
ns.pm.RegisterIPPortIdentity("udp", backendLocalIPPort, clientAddr.Addr())
}
ctx, cancel := context.WithCancel(context.Background())
idleTimeout := 2 * time.Minute
if port == 53 {
// Make DNS packet copies time out much sooner.
//
// TODO(bradfitz): make DNS queries over UDP forwarding even
// cheaper by adding an additional idleTimeout post-DNS-reply.
// For instance, after the DNS response goes back out, then only
// wait a few seconds (or zero, really)
idleTimeout = 30 * time.Second
}
timer := time.AfterFunc(idleTimeout, func() {
if isLocal {
ns.pm.UnregisterIPPortIdentity("udp", backendLocalIPPort)
}
ns.logf("netstack: UDP session between %s and %s timed out", backendListenAddr, backendRemoteAddr)
cancel()
client.Close()
backendConn.Close()
})
extend := func() {
timer.Reset(idleTimeout)
}
startPacketCopy(ctx, cancel, client, net.UDPAddrFromAddrPort(clientAddr), backendConn, ns.logf, extend)
startPacketCopy(ctx, cancel, backendConn, backendRemoteAddr, client, ns.logf, extend)
if isLocal {
// Wait for the copies to be done before decrementing the
// subnet address count to potentially remove the route.
<-ctx.Done()
ns.removeSubnetAddress(dstAddr.Addr())
}
}
func startPacketCopy(ctx context.Context, cancel context.CancelFunc, dst net.PacketConn, dstAddr net.Addr, src net.PacketConn, logf logger.Logf, extend func()) {
if debugNetstack() {
logf("[v2] netstack: startPacketCopy to %v (%T) from %T", dstAddr, dst, src)
}
go func() {
defer cancel() // tear down the other direction's copy
bufp := udpBufPool.Get().(*[]byte)
defer udpBufPool.Put(bufp)
pkt := *bufp
for {
select {
case <-ctx.Done():
return
default:
n, srcAddr, err := src.ReadFrom(pkt)
if err != nil {
if ctx.Err() == nil {
logf("read packet from %s failed: %v", srcAddr, err)
}
return
}
_, err = dst.WriteTo(pkt[:n], dstAddr)
if err != nil {
if ctx.Err() == nil {
logf("write packet to %s failed: %v", dstAddr, err)
}
return
}
if debugNetstack() {
logf("[v2] wrote UDP packet %s -> %s", srcAddr, dstAddr)
}
extend()
}
}
}()
}
func stringifyTEI(tei stack.TransportEndpointID) string {
localHostPort := net.JoinHostPort(tei.LocalAddress.String(), strconv.Itoa(int(tei.LocalPort)))
remoteHostPort := net.JoinHostPort(tei.RemoteAddress.String(), strconv.Itoa(int(tei.RemotePort)))
return fmt.Sprintf("%s -> %s", remoteHostPort, localHostPort)
}
func ipPortOfNetstackAddr(a tcpip.Address, port uint16) (ipp netip.AddrPort, ok bool) {
if addr, ok := netip.AddrFromSlice(a.AsSlice()); ok {
return netip.AddrPortFrom(addr, port), true
}
return netip.AddrPort{}, false
}
func readStatCounter(sc *tcpip.StatCounter) int64 {
vv := sc.Value()
if vv > math.MaxInt64 {
return int64(math.MaxInt64)
}
return int64(vv)
}
// ExpVar returns an expvar variable suitable for registering with expvar.Publish.
func (ns *Impl) ExpVar() expvar.Var {
m := new(metrics.Set)
// Global metrics
stats := ns.ipstack.Stats()
m.Set("counter_dropped_packets", expvar.Func(func() any {
return readStatCounter(stats.DroppedPackets)
}))
// IP statistics
ipStats := ns.ipstack.Stats().IP
ipMetrics := []struct {
name string
field *tcpip.StatCounter
}{
{"packets_received", ipStats.PacketsReceived},
{"valid_packets_received", ipStats.ValidPacketsReceived},
{"disabled_packets_received", ipStats.DisabledPacketsReceived},
{"invalid_destination_addresses_received", ipStats.InvalidDestinationAddressesReceived},
{"invalid_source_addresses_received", ipStats.InvalidSourceAddressesReceived},
{"packets_delivered", ipStats.PacketsDelivered},
{"packets_sent", ipStats.PacketsSent},
{"outgoing_packet_errors", ipStats.OutgoingPacketErrors},
{"malformed_packets_received", ipStats.MalformedPacketsReceived},
{"malformed_fragments_received", ipStats.MalformedFragmentsReceived},
{"iptables_prerouting_dropped", ipStats.IPTablesPreroutingDropped},
{"iptables_input_dropped", ipStats.IPTablesInputDropped},
{"iptables_forward_dropped", ipStats.IPTablesForwardDropped},
{"iptables_output_dropped", ipStats.IPTablesOutputDropped},
{"iptables_postrouting_dropped", ipStats.IPTablesPostroutingDropped},
{"option_timestamp_received", ipStats.OptionTimestampReceived},
{"option_record_route_received", ipStats.OptionRecordRouteReceived},
{"option_router_alert_received", ipStats.OptionRouterAlertReceived},
{"option_unknown_received", ipStats.OptionUnknownReceived},
}
for _, metric := range ipMetrics {
metric := metric
m.Set("counter_ip_"+metric.name, expvar.Func(func() any {
return readStatCounter(metric.field)
}))
}
// IP forwarding statistics
fwdStats := ipStats.Forwarding
fwdMetrics := []struct {
name string
field *tcpip.StatCounter
}{
{"unrouteable", fwdStats.Unrouteable},
{"exhausted_ttl", fwdStats.ExhaustedTTL},
{"initializing_source", fwdStats.InitializingSource},
{"link_local_source", fwdStats.LinkLocalSource},
{"link_local_destination", fwdStats.LinkLocalDestination},
{"packet_too_big", fwdStats.PacketTooBig},
{"host_unreachable", fwdStats.HostUnreachable},
{"extension_header_problem", fwdStats.ExtensionHeaderProblem},
{"unexpected_multicast_input_interface", fwdStats.UnexpectedMulticastInputInterface},
{"unknown_output_endpoint", fwdStats.UnknownOutputEndpoint},
{"no_multicast_pending_queue_buffer_space", fwdStats.NoMulticastPendingQueueBufferSpace},
{"outgoing_device_no_buffer_space", fwdStats.OutgoingDeviceNoBufferSpace},
{"errors", fwdStats.Errors},
}
for _, metric := range fwdMetrics {
metric := metric
m.Set("counter_ip_forward_"+metric.name, expvar.Func(func() any {
return readStatCounter(metric.field)
}))
}
// TCP metrics
tcpStats := ns.ipstack.Stats().TCP
tcpMetrics := []struct {
name string
field *tcpip.StatCounter
}{
{"active_connection_openings", tcpStats.ActiveConnectionOpenings},
{"passive_connection_openings", tcpStats.PassiveConnectionOpenings},
{"established_resets", tcpStats.EstablishedResets},
{"established_closed", tcpStats.EstablishedClosed},
{"established_timeout", tcpStats.EstablishedTimedout},
{"listen_overflow_syn_drop", tcpStats.ListenOverflowSynDrop},
{"listen_overflow_ack_drop", tcpStats.ListenOverflowAckDrop},
{"listen_overflow_syn_cookie_sent", tcpStats.ListenOverflowSynCookieSent},
{"listen_overflow_syn_cookie_rcvd", tcpStats.ListenOverflowSynCookieRcvd},
{"listen_overflow_invalid_syn_cookie_rcvd", tcpStats.ListenOverflowInvalidSynCookieRcvd},
{"failed_connection_attempts", tcpStats.FailedConnectionAttempts},
{"valid_segments_received", tcpStats.ValidSegmentsReceived},
{"invalid_segments_received", tcpStats.InvalidSegmentsReceived},
{"segments_sent", tcpStats.SegmentsSent},
{"segment_send_errors", tcpStats.SegmentSendErrors},
{"resets_sent", tcpStats.ResetsSent},
{"resets_received", tcpStats.ResetsReceived},
{"retransmits", tcpStats.Retransmits},
{"fast_recovery", tcpStats.FastRecovery},
{"sack_recovery", tcpStats.SACKRecovery},
{"tlp_recovery", tcpStats.TLPRecovery},
{"slow_start_retransmits", tcpStats.SlowStartRetransmits},
{"fast_retransmit", tcpStats.FastRetransmit},
{"timeouts", tcpStats.Timeouts},
{"checksum_errors", tcpStats.ChecksumErrors},
{"failed_port_reservations", tcpStats.FailedPortReservations},
{"segments_acked_with_dsack", tcpStats.SegmentsAckedWithDSACK},
{"spurious_recovery", tcpStats.SpuriousRecovery},
{"spurious_rto_recovery", tcpStats.SpuriousRTORecovery},
{"forward_max_in_flight_drop", tcpStats.ForwardMaxInFlightDrop},
}
for _, metric := range tcpMetrics {
metric := metric
m.Set("counter_tcp_"+metric.name, expvar.Func(func() any {
return readStatCounter(metric.field)
}))
}
m.Set("gauge_tcp_current_established", expvar.Func(func() any {
return readStatCounter(tcpStats.CurrentEstablished)
}))
m.Set("gauge_tcp_current_connected", expvar.Func(func() any {
return readStatCounter(tcpStats.CurrentConnected)
}))
// UDP metrics
udpStats := ns.ipstack.Stats().UDP
udpMetrics := []struct {
name string
field *tcpip.StatCounter
}{
{"packets_received", udpStats.PacketsReceived},
{"unknown_port_errors", udpStats.UnknownPortErrors},
{"receive_buffer_errors", udpStats.ReceiveBufferErrors},
{"malformed_packets_received", udpStats.MalformedPacketsReceived},
{"packets_sent", udpStats.PacketsSent},
{"packet_send_errors", udpStats.PacketSendErrors},
{"checksum_errors", udpStats.ChecksumErrors},
}
for _, metric := range udpMetrics {
metric := metric
m.Set("counter_udp_"+metric.name, expvar.Func(func() any {
return readStatCounter(metric.field)
}))
}
// Export gauges that show the current TCP forwarding limits.
m.Set("gauge_tcp_forward_in_flight_limit", expvar.Func(func() any {
return maxInFlightConnectionAttempts()
}))
m.Set("gauge_tcp_forward_in_flight_per_client_limit", expvar.Func(func() any {
return maxInFlightConnectionAttemptsPerClient()
}))
// This metric tracks the number of in-flight TCP forwarding
// connections that are "in-flight"i.e. waiting to complete.
m.Set("gauge_tcp_forward_in_flight", expvar.Func(func() any {
ns.mu.Lock()
defer ns.mu.Unlock()
var sum int64
for _, n := range ns.connsInFlightByClient {
sum += int64(n)
}
return sum
}))
m.Set("counter_tcp_forward_max_in_flight_per_client_drop", &ns.forwardInFlightPerClientDropped)
// This metric tracks how many (if any) of the per-client limit on
// in-flight TCP forwarding requests have been reached.
m.Set("gauge_tcp_forward_in_flight_per_client_limit_reached", expvar.Func(func() any {
ns.mu.Lock()
defer ns.mu.Unlock()
limit := maxInFlightConnectionAttemptsPerClient()
var count int64
for _, n := range ns.connsInFlightByClient {
if n == limit {
count++
}
}
return count
}))
return m
}