tailscale/net/portmapper/portmapper.go
Will Norris 947c14793a all: update tools that manage copyright headers
Update all code generation tools, and those that check for license
headers to use the new standard header.

Also update copyright statement in LICENSE file.

Fixes #6865

Signed-off-by: Will Norris <will@tailscale.com>
2023-01-27 15:36:29 -08:00

983 lines
31 KiB
Go

// Copyright (c) Tailscale Inc & AUTHORS
// SPDX-License-Identifier: BSD-3-Clause
// Package portmapper is a UDP port mapping client. It currently allows for mapping over
// NAT-PMP, UPnP, and PCP.
package portmapper
import (
"context"
"encoding/binary"
"errors"
"fmt"
"io"
"net"
"net/http"
"net/netip"
"sync"
"time"
"go4.org/mem"
"tailscale.com/net/interfaces"
"tailscale.com/net/netaddr"
"tailscale.com/net/neterror"
"tailscale.com/net/netns"
"tailscale.com/types/logger"
"tailscale.com/types/nettype"
"tailscale.com/util/clientmetric"
)
// Debug knobs for "tailscaled debug --portmap".
var (
VerboseLogs bool
// Disable* disables a specific service from mapping.
DisableUPnP bool
DisablePMP bool
DisablePCP bool
)
// References:
//
// NAT-PMP: https://tools.ietf.org/html/rfc6886
// portMapServiceTimeout is the time we wait for port mapping
// services (UPnP, NAT-PMP, PCP) to respond before we give up and
// decide that they're not there. Since these services are on the
// same LAN as this machine and a single L3 hop away, we don't
// give them much time to respond.
const portMapServiceTimeout = 250 * time.Millisecond
// trustServiceStillAvailableDuration is how often we re-verify a port
// mapping service is available.
const trustServiceStillAvailableDuration = 10 * time.Minute
// Client is a port mapping client.
type Client struct {
logf logger.Logf
ipAndGateway func() (gw, ip netip.Addr, ok bool)
onChange func() // or nil
testPxPPort uint16 // if non-zero, pxpPort to use for tests
testUPnPPort uint16 // if non-zero, uPnPPort to use for tests
mu sync.Mutex // guards following, and all fields thereof
// runningCreate is whether we're currently working on creating
// a port mapping (whether GetCachedMappingOrStartCreatingOne kicked
// off a createMapping goroutine).
runningCreate bool
lastMyIP netip.Addr
lastGW netip.Addr
closed bool
lastProbe time.Time
pmpPubIP netip.Addr // non-zero if known
pmpPubIPTime time.Time // time pmpPubIP last verified
pmpLastEpoch uint32
pcpSawTime time.Time // time we last saw PCP was available
uPnPSawTime time.Time // time we last saw UPnP was available
uPnPMeta uPnPDiscoResponse // Location header from UPnP UDP discovery response
uPnPHTTPClient *http.Client // netns-configured HTTP client for UPnP; nil until needed
localPort uint16
mapping mapping // non-nil if we have a mapping
}
// mapping represents a created port-mapping over some protocol. It specifies a lease duration,
// how to release the mapping, and whether the map is still valid.
//
// After a mapping is created, it should be immutable, and thus reads should be safe across
// concurrent goroutines.
type mapping interface {
// Release will attempt to unmap the established port mapping. It will block until completion,
// but can be called asynchronously. Release should be idempotent, and thus even if called
// multiple times should not cause additional side-effects.
Release(context.Context)
// GoodUntil will return the lease time that the mapping is valid for.
GoodUntil() time.Time
// RenewAfter returns the earliest time that the mapping should be renewed.
RenewAfter() time.Time
// External indicates what port the mapping can be reached from on the outside.
External() netip.AddrPort
}
// HaveMapping reports whether we have a current valid mapping.
func (c *Client) HaveMapping() bool {
c.mu.Lock()
defer c.mu.Unlock()
return c.mapping != nil && c.mapping.GoodUntil().After(time.Now())
}
// pmpMapping is an already-created PMP mapping.
//
// All fields are immutable once created.
type pmpMapping struct {
c *Client
gw netip.AddrPort
external netip.AddrPort
internal netip.AddrPort
renewAfter time.Time // the time at which we want to renew the mapping
goodUntil time.Time // the mapping's total lifetime
epoch uint32
}
// externalValid reports whether m.external is valid, with both its IP and Port populated.
func (m *pmpMapping) externalValid() bool {
return m.external.Addr().IsValid() && m.external.Port() != 0
}
func (p *pmpMapping) GoodUntil() time.Time { return p.goodUntil }
func (p *pmpMapping) RenewAfter() time.Time { return p.renewAfter }
func (p *pmpMapping) External() netip.AddrPort { return p.external }
// Release does a best effort fire-and-forget release of the PMP mapping m.
func (m *pmpMapping) Release(ctx context.Context) {
uc, err := m.c.listenPacket(ctx, "udp4", ":0")
if err != nil {
return
}
defer uc.Close()
pkt := buildPMPRequestMappingPacket(m.internal.Port(), m.external.Port(), pmpMapLifetimeDelete)
uc.WriteToUDPAddrPort(pkt, m.gw)
}
// NewClient returns a new portmapping client.
//
// The optional onChange argument specifies a func to run in a new
// goroutine whenever the port mapping status has changed. If nil,
// it doesn't make a callback.
func NewClient(logf logger.Logf, onChange func()) *Client {
return &Client{
logf: logf,
ipAndGateway: interfaces.LikelyHomeRouterIP,
onChange: onChange,
}
}
// SetGatewayLookupFunc set the func that returns the machine's default gateway IP, and
// the primary IP address for that gateway. It must be called before the client is used.
// If not called, interfaces.LikelyHomeRouterIP is used.
func (c *Client) SetGatewayLookupFunc(f func() (gw, myIP netip.Addr, ok bool)) {
c.ipAndGateway = f
}
// NoteNetworkDown should be called when the network has transitioned to a down state.
// It's too late to release port mappings at this point (the user might've just turned off
// their wifi), but we can make sure we invalidate mappings for later when the network
// comes back.
func (c *Client) NoteNetworkDown() {
c.mu.Lock()
defer c.mu.Unlock()
c.invalidateMappingsLocked(false)
}
func (c *Client) Close() error {
c.mu.Lock()
defer c.mu.Unlock()
if c.closed {
return nil
}
c.closed = true
c.invalidateMappingsLocked(true)
// TODO: close some future ever-listening UDP socket(s),
// waiting for multicast announcements from router.
return nil
}
// SetLocalPort updates the local port number to which we want to port
// map UDP traffic.
func (c *Client) SetLocalPort(localPort uint16) {
c.mu.Lock()
defer c.mu.Unlock()
if c.localPort == localPort {
return
}
c.localPort = localPort
c.invalidateMappingsLocked(true)
}
func (c *Client) gatewayAndSelfIP() (gw, myIP netip.Addr, ok bool) {
gw, myIP, ok = c.ipAndGateway()
if !ok {
gw = netip.Addr{}
myIP = netip.Addr{}
}
c.mu.Lock()
defer c.mu.Unlock()
if gw != c.lastGW || myIP != c.lastMyIP || !ok {
c.lastMyIP = myIP
c.lastGW = gw
c.invalidateMappingsLocked(true)
}
return
}
// pxpPort returns the NAT-PMP and PCP port number.
// It returns 5351, except for in tests where it varies by run.
func (c *Client) pxpPort() uint16 {
if c.testPxPPort != 0 {
return c.testPxPPort
}
return pmpDefaultPort
}
// upnpPort returns the UPnP discovery port number.
// It returns 1900, except for in tests where it varies by run.
func (c *Client) upnpPort() uint16 {
if c.testUPnPPort != 0 {
return c.testUPnPPort
}
return upnpDefaultPort
}
func (c *Client) listenPacket(ctx context.Context, network, addr string) (nettype.PacketConn, error) {
// When running under testing conditions, we bind the IGD server
// to localhost, and may be running in an environment where our
// netns code would decide that binding the portmapper client
// socket to the default route interface is the correct way to
// ensure connectivity. This can result in us trying to send
// packets for 127.0.0.1 out the machine's LAN interface, which
// obviously gets dropped on the floor.
//
// So, under those testing conditions, do _not_ use netns to
// create listening sockets. Such sockets are vulnerable to
// routing loops, but it's tests that don't set up routing loops,
// so we don't care.
if c.testPxPPort != 0 || c.testUPnPPort != 0 {
var lc net.ListenConfig
pc, err := lc.ListenPacket(ctx, network, addr)
if err != nil {
return nil, err
}
return pc.(*net.UDPConn), nil
}
pc, err := netns.Listener(c.logf).ListenPacket(ctx, network, addr)
if err != nil {
return nil, err
}
return pc.(*net.UDPConn), nil
}
func (c *Client) invalidateMappingsLocked(releaseOld bool) {
if c.mapping != nil {
if releaseOld {
c.mapping.Release(context.Background())
}
c.mapping = nil
}
c.pmpPubIP = netip.Addr{}
c.pmpPubIPTime = time.Time{}
c.pcpSawTime = time.Time{}
c.uPnPSawTime = time.Time{}
c.uPnPMeta = uPnPDiscoResponse{}
}
func (c *Client) sawPMPRecently() bool {
c.mu.Lock()
defer c.mu.Unlock()
return c.sawPMPRecentlyLocked()
}
func (c *Client) sawPMPRecentlyLocked() bool {
return c.pmpPubIP.IsValid() && c.pmpPubIPTime.After(time.Now().Add(-trustServiceStillAvailableDuration))
}
func (c *Client) sawPCPRecently() bool {
c.mu.Lock()
defer c.mu.Unlock()
return c.sawPCPRecentlyLocked()
}
func (c *Client) sawPCPRecentlyLocked() bool {
return c.pcpSawTime.After(time.Now().Add(-trustServiceStillAvailableDuration))
}
func (c *Client) sawUPnPRecently() bool {
c.mu.Lock()
defer c.mu.Unlock()
return c.uPnPSawTime.After(time.Now().Add(-trustServiceStillAvailableDuration))
}
// closeCloserOnContextDone starts a new goroutine to call c.Close
// if/when ctx becomes done.
// To stop the goroutine, call the returned stop func.
func closeCloserOnContextDone(ctx context.Context, c io.Closer) (stop func()) {
// Close uc on ctx being done.
ctxDone := ctx.Done()
if ctxDone == nil {
return func() {}
}
stopWaitDone := make(chan struct{})
go func() {
select {
case <-stopWaitDone:
case <-ctxDone:
c.Close()
}
}()
return func() { close(stopWaitDone) }
}
// NoMappingError is returned when no NAT mapping could be done.
type NoMappingError struct {
err error
}
func (nme NoMappingError) Unwrap() error { return nme.err }
func (nme NoMappingError) Error() string { return fmt.Sprintf("no NAT mapping available: %v", nme.err) }
// IsNoMappingError reports whether err is of type NoMappingError.
func IsNoMappingError(err error) bool {
_, ok := err.(NoMappingError)
return ok
}
var (
ErrNoPortMappingServices = errors.New("no port mapping services were found")
ErrGatewayRange = errors.New("skipping portmap; gateway range likely lacks support")
ErrGatewayIPv6 = errors.New("skipping portmap; no IPv6 support for portmapping")
)
// GetCachedMappingOrStartCreatingOne quickly returns with our current cached portmapping, if any.
// If there's not one, it starts up a background goroutine to create one.
// If the background goroutine ends up creating one, the onChange hook registered with the
// NewClient constructor (if any) will fire.
func (c *Client) GetCachedMappingOrStartCreatingOne() (external netip.AddrPort, ok bool) {
c.mu.Lock()
defer c.mu.Unlock()
// Do we have an existing mapping that's valid?
now := time.Now()
if m := c.mapping; m != nil {
if now.Before(m.GoodUntil()) {
if now.After(m.RenewAfter()) {
c.maybeStartMappingLocked()
}
return m.External(), true
}
}
c.maybeStartMappingLocked()
return netip.AddrPort{}, false
}
// maybeStartMappingLocked starts a createMapping goroutine up, if one isn't already running.
//
// c.mu must be held.
func (c *Client) maybeStartMappingLocked() {
if !c.runningCreate {
c.runningCreate = true
go c.createMapping()
}
}
func (c *Client) createMapping() {
ctx, cancel := context.WithTimeout(context.Background(), 5*time.Second)
defer cancel()
defer func() {
c.mu.Lock()
defer c.mu.Unlock()
c.runningCreate = false
}()
if _, err := c.createOrGetMapping(ctx); err == nil && c.onChange != nil {
go c.onChange()
} else if err != nil && !IsNoMappingError(err) {
c.logf("createOrGetMapping: %v", err)
}
}
// wildcardIP is used when the previous external IP is not known for PCP port mapping.
var wildcardIP = netip.MustParseAddr("0.0.0.0")
// createOrGetMapping either creates a new mapping or returns a cached
// valid one.
//
// If no mapping is available, the error will be of type
// NoMappingError; see IsNoMappingError.
func (c *Client) createOrGetMapping(ctx context.Context) (external netip.AddrPort, err error) {
if DisableUPnP && DisablePCP && DisablePMP {
return netip.AddrPort{}, NoMappingError{ErrNoPortMappingServices}
}
gw, myIP, ok := c.gatewayAndSelfIP()
if !ok {
return netip.AddrPort{}, NoMappingError{ErrGatewayRange}
}
if gw.Is6() {
return netip.AddrPort{}, NoMappingError{ErrGatewayIPv6}
}
c.mu.Lock()
localPort := c.localPort
internalAddr := netip.AddrPortFrom(myIP, localPort)
// prevPort is the port we had most previously, if any. We try
// to ask for the same port. 0 means to give us any port.
var prevPort uint16
// Do we have an existing mapping that's valid?
now := time.Now()
if m := c.mapping; m != nil {
if now.Before(m.RenewAfter()) {
defer c.mu.Unlock()
return m.External(), nil
}
// The mapping might still be valid, so just try to renew it.
prevPort = m.External().Port()
}
if DisablePCP && DisablePMP {
c.mu.Unlock()
if external, ok := c.getUPnPPortMapping(ctx, gw, internalAddr, prevPort); ok {
return external, nil
}
return netip.AddrPort{}, NoMappingError{ErrNoPortMappingServices}
}
// If we just did a Probe (e.g. via netchecker) but didn't
// find a PMP service, bail out early rather than probing
// again. Cuts down latency for most clients.
haveRecentPMP := c.sawPMPRecentlyLocked()
haveRecentPCP := c.sawPCPRecentlyLocked()
// Since PMP mapping may require multiple calls, and it's not clear from the outset
// whether we're doing a PCP or PMP call, initialize the PMP mapping here,
// and only return it once completed.
//
// PCP returns all the information necessary for a mapping in a single packet, so we can
// construct it upon receiving that packet.
m := &pmpMapping{
c: c,
gw: netip.AddrPortFrom(gw, c.pxpPort()),
internal: internalAddr,
}
if haveRecentPMP {
m.external = netip.AddrPortFrom(c.pmpPubIP, m.external.Port())
}
if c.lastProbe.After(now.Add(-5*time.Second)) && !haveRecentPMP && !haveRecentPCP {
c.mu.Unlock()
// fallback to UPnP portmapping
if external, ok := c.getUPnPPortMapping(ctx, gw, internalAddr, prevPort); ok {
return external, nil
}
return netip.AddrPort{}, NoMappingError{ErrNoPortMappingServices}
}
c.mu.Unlock()
uc, err := c.listenPacket(ctx, "udp4", ":0")
if err != nil {
return netip.AddrPort{}, err
}
defer uc.Close()
uc.SetReadDeadline(time.Now().Add(portMapServiceTimeout))
defer closeCloserOnContextDone(ctx, uc)()
pxpAddr := netip.AddrPortFrom(gw, c.pxpPort())
preferPCP := !DisablePCP && (DisablePMP || (!haveRecentPMP && haveRecentPCP))
// Create a mapping, defaulting to PMP unless only PCP was seen recently.
if preferPCP {
// TODO replace wildcardIP here with previous external if known.
// Only do PCP mapping in the case when PMP did not appear to be available recently.
pkt := buildPCPRequestMappingPacket(myIP, localPort, prevPort, pcpMapLifetimeSec, wildcardIP)
if _, err := uc.WriteToUDPAddrPort(pkt, pxpAddr); err != nil {
if neterror.TreatAsLostUDP(err) {
err = NoMappingError{ErrNoPortMappingServices}
}
return netip.AddrPort{}, err
}
} else {
// Ask for our external address if needed.
if !m.external.Addr().IsValid() {
if _, err := uc.WriteToUDPAddrPort(pmpReqExternalAddrPacket, pxpAddr); err != nil {
if neterror.TreatAsLostUDP(err) {
err = NoMappingError{ErrNoPortMappingServices}
}
return netip.AddrPort{}, err
}
}
pkt := buildPMPRequestMappingPacket(localPort, prevPort, pmpMapLifetimeSec)
if _, err := uc.WriteToUDPAddrPort(pkt, pxpAddr); err != nil {
if neterror.TreatAsLostUDP(err) {
err = NoMappingError{ErrNoPortMappingServices}
}
return netip.AddrPort{}, err
}
}
res := make([]byte, 1500)
for {
n, srci, err := uc.ReadFrom(res)
if err != nil {
if ctx.Err() == context.Canceled {
return netip.AddrPort{}, err
}
// fallback to UPnP portmapping
if mapping, ok := c.getUPnPPortMapping(ctx, gw, internalAddr, prevPort); ok {
return mapping, nil
}
return netip.AddrPort{}, NoMappingError{ErrNoPortMappingServices}
}
srcu := srci.(*net.UDPAddr)
src := netaddr.Unmap(srcu.AddrPort())
if !src.IsValid() {
continue
}
if src == pxpAddr {
version := res[0]
switch version {
case pmpVersion:
pres, ok := parsePMPResponse(res[:n])
if !ok {
c.logf("unexpected PMP response: % 02x", res[:n])
continue
}
if pres.ResultCode != 0 {
return netip.AddrPort{}, NoMappingError{fmt.Errorf("PMP response Op=0x%x,Res=0x%x", pres.OpCode, pres.ResultCode)}
}
if pres.OpCode == pmpOpReply|pmpOpMapPublicAddr {
m.external = netip.AddrPortFrom(pres.PublicAddr, m.external.Port())
}
if pres.OpCode == pmpOpReply|pmpOpMapUDP {
m.external = netip.AddrPortFrom(m.external.Addr(), pres.ExternalPort)
d := time.Duration(pres.MappingValidSeconds) * time.Second
now := time.Now()
m.goodUntil = now.Add(d)
m.renewAfter = now.Add(d / 2) // renew in half the time
m.epoch = pres.SecondsSinceEpoch
}
case pcpVersion:
pcpMapping, err := parsePCPMapResponse(res[:n])
if err != nil {
c.logf("failed to get PCP mapping: %v", err)
// PCP should only have a single packet response
return netip.AddrPort{}, NoMappingError{ErrNoPortMappingServices}
}
pcpMapping.c = c
pcpMapping.internal = m.internal
pcpMapping.gw = netip.AddrPortFrom(gw, c.pxpPort())
c.mu.Lock()
defer c.mu.Unlock()
c.mapping = pcpMapping
return pcpMapping.external, nil
default:
c.logf("unknown PMP/PCP version number: %d %v", version, res[:n])
return netip.AddrPort{}, NoMappingError{ErrNoPortMappingServices}
}
}
if m.externalValid() {
c.mu.Lock()
defer c.mu.Unlock()
c.mapping = m
return m.external, nil
}
}
}
//go:generate go run tailscale.com/cmd/addlicense -file pmpresultcode_string.go go run golang.org/x/tools/cmd/stringer -type=pmpResultCode -trimprefix=pmpCode
type pmpResultCode uint16
// NAT-PMP constants.
const (
pmpDefaultPort = 5351
pmpMapLifetimeSec = 7200 // RFC recommended 2 hour map duration
pmpMapLifetimeDelete = 0 // 0 second lifetime deletes
pmpVersion = 0
pmpOpMapPublicAddr = 0
pmpOpMapUDP = 1
pmpOpReply = 0x80 // OR'd into request's op code on response
pmpCodeOK pmpResultCode = 0
pmpCodeUnsupportedVersion pmpResultCode = 1
pmpCodeNotAuthorized pmpResultCode = 2 // "e.g., box supports mapping, but user has turned feature off"
pmpCodeNetworkFailure pmpResultCode = 3 // "e.g., NAT box itself has not obtained a DHCP lease"
pmpCodeOutOfResources pmpResultCode = 4
pmpCodeUnsupportedOpcode pmpResultCode = 5
)
func buildPMPRequestMappingPacket(localPort, prevPort uint16, lifetimeSec uint32) (pkt []byte) {
pkt = make([]byte, 12)
pkt[1] = pmpOpMapUDP
binary.BigEndian.PutUint16(pkt[4:], localPort)
binary.BigEndian.PutUint16(pkt[6:], prevPort)
binary.BigEndian.PutUint32(pkt[8:], lifetimeSec)
return pkt
}
type pmpResponse struct {
OpCode uint8
ResultCode pmpResultCode
SecondsSinceEpoch uint32
// For Map ops:
MappingValidSeconds uint32
InternalPort uint16
ExternalPort uint16
// For public addr ops:
PublicAddr netip.Addr
}
func parsePMPResponse(pkt []byte) (res pmpResponse, ok bool) {
if len(pkt) < 12 {
return
}
ver := pkt[0]
if ver != 0 {
return
}
res.OpCode = pkt[1]
res.ResultCode = pmpResultCode(binary.BigEndian.Uint16(pkt[2:]))
res.SecondsSinceEpoch = binary.BigEndian.Uint32(pkt[4:])
if res.OpCode == pmpOpReply|pmpOpMapUDP {
if len(pkt) != 16 {
return res, false
}
res.InternalPort = binary.BigEndian.Uint16(pkt[8:])
res.ExternalPort = binary.BigEndian.Uint16(pkt[10:])
res.MappingValidSeconds = binary.BigEndian.Uint32(pkt[12:])
}
if res.OpCode == pmpOpReply|pmpOpMapPublicAddr {
if len(pkt) != 12 {
return res, false
}
res.PublicAddr = netaddr.IPv4(pkt[8], pkt[9], pkt[10], pkt[11])
}
return res, true
}
type ProbeResult struct {
PCP bool
PMP bool
UPnP bool
}
// Probe returns a summary of which port mapping services are
// available on the network.
//
// If a probe has run recently and there haven't been any network changes since,
// the returned result might be server from the Client's cache, without
// sending any network traffic.
func (c *Client) Probe(ctx context.Context) (res ProbeResult, err error) {
gw, myIP, ok := c.gatewayAndSelfIP()
if !ok {
return res, ErrGatewayRange
}
defer func() {
if err == nil {
c.mu.Lock()
defer c.mu.Unlock()
c.lastProbe = time.Now()
}
}()
uc, err := c.listenPacket(context.Background(), "udp4", ":0")
if err != nil {
c.logf("ProbePCP: %v", err)
return res, err
}
defer uc.Close()
ctx, cancel := context.WithTimeout(ctx, 250*time.Millisecond)
defer cancel()
defer closeCloserOnContextDone(ctx, uc)()
pxpAddr := netip.AddrPortFrom(gw, c.pxpPort())
upnpAddr := netip.AddrPortFrom(gw, c.upnpPort())
upnpMulticastAddr := netip.AddrPortFrom(netaddr.IPv4(239, 255, 255, 250), c.upnpPort())
// Don't send probes to services that we recently learned (for
// the same gw/myIP) are available. See
// https://github.com/tailscale/tailscale/issues/1001
if c.sawPMPRecently() {
res.PMP = true
} else if !DisablePMP {
metricPMPSent.Add(1)
uc.WriteToUDPAddrPort(pmpReqExternalAddrPacket, pxpAddr)
}
if c.sawPCPRecently() {
res.PCP = true
} else if !DisablePCP {
metricPCPSent.Add(1)
uc.WriteToUDPAddrPort(pcpAnnounceRequest(myIP), pxpAddr)
}
if c.sawUPnPRecently() {
res.UPnP = true
} else if !DisableUPnP {
// Strictly speaking, you discover UPnP services by sending an
// SSDP query (which uPnPPacket is) to udp/1900 on the SSDP
// multicast address, and then get a flood of responses back
// from everything on your network.
//
// Empirically, many home routers also respond to SSDP queries
// directed at udp/1900 on their LAN unicast IP
// (e.g. 192.168.1.1). This is handy because it means we can
// probe the router directly and likely get a reply. However,
// the specs do not _require_ UPnP devices to respond to
// unicast SSDP queries, so some conformant UPnP
// implementations only respond to multicast queries.
//
// In theory, we could send just the multicast query and get
// all compliant devices to respond. However, we instead send
// to both a unicast and a multicast addresses, for a couple
// of reasons:
//
// First, some LANs and OSes have broken multicast in one way
// or another, so it's possible for the multicast query to be
// lost while the unicast query gets through. But we still
// have to send the multicast query to also get a response
// from strict-UPnP devices on multicast-working networks.
//
// Second, SSDP's packet dynamics are a bit weird: you send
// the SSDP query from your unicast IP to the SSDP multicast
// IP, but responses are from the UPnP devices's _unicast_ IP
// to your unicast IP. This can confuse some less-intelligent
// stateful host firewalls, who might block the responses. To
// work around this, we send the unicast query first, to teach
// the firewall to expect a unicast response from the router,
// and then send our multicast query. That way, even if the
// device doesn't respond to the unicast query, we've set the
// stage for the host firewall to accept the response to the
// multicast query.
//
// See https://github.com/tailscale/tailscale/issues/3197 for
// an example of a device that strictly implements UPnP, and
// only responds to multicast queries.
//
// Then we send a discovery packet looking for
// urn:schemas-upnp-org:device:InternetGatewayDevice:1 specifically, not
// just ssdp:all, because there appear to be devices which only send
// their first descriptor (like urn:schemas-wifialliance-org:device:WFADevice:1)
// in response to ssdp:all. https://github.com/tailscale/tailscale/issues/3557
metricUPnPSent.Add(1)
uc.WriteToUDPAddrPort(uPnPPacket, upnpAddr)
uc.WriteToUDPAddrPort(uPnPPacket, upnpMulticastAddr)
uc.WriteToUDPAddrPort(uPnPIGDPacket, upnpMulticastAddr)
}
buf := make([]byte, 1500)
pcpHeard := false // true when we get any PCP response
for {
if pcpHeard && res.PMP && res.UPnP {
// Nothing more to discover.
return res, nil
}
n, addr, err := uc.ReadFrom(buf)
if err != nil {
if ctx.Err() == context.DeadlineExceeded {
err = nil
}
return res, err
}
ip, ok := netip.AddrFromSlice(addr.(*net.UDPAddr).IP)
if !ok {
continue
}
ip = ip.Unmap()
port := uint16(addr.(*net.UDPAddr).Port)
switch port {
case c.upnpPort():
metricUPnPResponse.Add(1)
if mem.Contains(mem.B(buf[:n]), mem.S(":InternetGatewayDevice:")) {
if ip != gw {
// https://github.com/tailscale/tailscale/issues/5502
c.logf("UPnP discovery response from %v, but gateway IP is %v", ip, gw)
}
meta, err := parseUPnPDiscoResponse(buf[:n])
if err != nil {
metricUPnPParseErr.Add(1)
c.logf("unrecognized UPnP discovery response; ignoring: %v", err)
continue
}
metricUPnPOK.Add(1)
c.logf("[v1] UPnP reply %+v, %q", meta, buf[:n])
res.UPnP = true
c.mu.Lock()
c.uPnPSawTime = time.Now()
if c.uPnPMeta != meta {
c.logf("UPnP meta changed: %+v", meta)
c.uPnPMeta = meta
metricUPnPUpdatedMeta.Add(1)
}
c.mu.Unlock()
}
case c.pxpPort(): // same value for PMP and PCP
metricPXPResponse.Add(1)
if pres, ok := parsePCPResponse(buf[:n]); ok {
if pres.OpCode == pcpOpReply|pcpOpAnnounce {
pcpHeard = true
c.mu.Lock()
c.pcpSawTime = time.Now()
c.mu.Unlock()
switch pres.ResultCode {
case pcpCodeOK:
c.logf("[v1] Got PCP response: epoch: %v", pres.Epoch)
res.PCP = true
metricPCPOK.Add(1)
continue
case pcpCodeNotAuthorized:
// A PCP service is running, but refuses to
// provide port mapping services.
res.PCP = false
metricPCPNotAuthorized.Add(1)
continue
case pcpCodeAddressMismatch:
// A PCP service is running, but it is behind a NAT, so it can't help us.
res.PCP = false
metricPCPAddressMismatch.Add(1)
continue
default:
// Fall through to unexpected log line.
}
}
metricPCPUnhandledResponseCode.Add(1)
c.logf("unexpected PCP probe response: %+v", pres)
}
if pres, ok := parsePMPResponse(buf[:n]); ok {
if pres.OpCode != pmpOpReply|pmpOpMapPublicAddr {
c.logf("unexpected PMP probe response opcode: %+v", pres)
metricPMPUnhandledOpcode.Add(1)
continue
}
switch pres.ResultCode {
case pmpCodeOK:
metricPMPOK.Add(1)
c.logf("[v1] Got PMP response; IP: %v, epoch: %v", pres.PublicAddr, pres.SecondsSinceEpoch)
res.PMP = true
c.mu.Lock()
c.pmpPubIP = pres.PublicAddr
c.pmpPubIPTime = time.Now()
c.pmpLastEpoch = pres.SecondsSinceEpoch
c.mu.Unlock()
continue
case pmpCodeNotAuthorized:
metricPMPNotAuthorized.Add(1)
c.logf("PMP probe failed due result code: %+v", pres)
continue
case pmpCodeNetworkFailure:
metricPMPNetworkFailure.Add(1)
c.logf("PMP probe failed due result code: %+v", pres)
continue
case pmpCodeOutOfResources:
metricPMPOutOfResources.Add(1)
c.logf("PMP probe failed due result code: %+v", pres)
continue
}
metricPMPUnhandledResponseCode.Add(1)
c.logf("unexpected PMP probe response: %+v", pres)
}
}
}
}
var pmpReqExternalAddrPacket = []byte{pmpVersion, pmpOpMapPublicAddr} // 0, 0
const (
upnpDefaultPort = 1900 // for UDP discovery only; TCP port discovered later
)
// uPnPPacket is the UPnP UDP discovery packet's request body.
var uPnPPacket = []byte("M-SEARCH * HTTP/1.1\r\n" +
"HOST: 239.255.255.250:1900\r\n" +
"ST: ssdp:all\r\n" +
"MAN: \"ssdp:discover\"\r\n" +
"MX: 2\r\n\r\n")
// Send a discovery frame for InternetGatewayDevice, since some devices respond
// to ssdp:all with only their first descriptor (which is often not IGD).
// https://github.com/tailscale/tailscale/issues/3557
var uPnPIGDPacket = []byte("M-SEARCH * HTTP/1.1\r\n" +
"HOST: 239.255.255.250:1900\r\n" +
"ST: urn:schemas-upnp-org:device:InternetGatewayDevice:1\r\n" +
"MAN: \"ssdp:discover\"\r\n" +
"MX: 2\r\n\r\n")
// PCP/PMP metrics
var (
// metricPXPResponse counts the number of times we received a PMP/PCP response.
metricPXPResponse = clientmetric.NewCounter("portmap_pxp_response")
// metricPCPSent counts the number of times we sent a PCP request.
metricPCPSent = clientmetric.NewCounter("portmap_pcp_sent")
// metricPCPOK counts the number of times
// we received a successful PCP response.
metricPCPOK = clientmetric.NewCounter("portmap_pcp_ok")
// metricPCPAddressMismatch counts the number of times
// we received a PCP address mismatch result code.
metricPCPAddressMismatch = clientmetric.NewCounter("portmap_pcp_address_mismatch")
// metricPCPNotAuthorized counts the number of times
// we received a PCP not authorized result code.
metricPCPNotAuthorized = clientmetric.NewCounter("portmap_pcp_not_authorized")
// metricPCPUnhandledResponseCode counts the number of times
// we received an (as yet) unhandled PCP result code.
metricPCPUnhandledResponseCode = clientmetric.NewCounter("portmap_pcp_unhandled_response_code")
// metricPMPSent counts the number of times we sent a PMP request.
metricPMPSent = clientmetric.NewCounter("portmap_pmp_sent")
// metricPMPOK counts the number of times
// we received a succesful PMP response.
metricPMPOK = clientmetric.NewCounter("portmap_pmp_ok")
// metricPMPUnhandledOpcode counts the number of times
// we received an unhandled PMP opcode.
metricPMPUnhandledOpcode = clientmetric.NewCounter("portmap_pmp_unhandled_opcode")
// metricPMPUnhandledResponseCode counts the number of times
// we received an unhandled PMP result code.
metricPMPUnhandledResponseCode = clientmetric.NewCounter("portmap_pmp_unhandled_response_code")
// metricPMPOutOfResources counts the number of times
// we received a PCP out of resources result code.
metricPMPOutOfResources = clientmetric.NewCounter("portmap_pmp_out_of_resources")
// metricPMPNetworkFailure counts the number of times
// we received a PCP network failure result code.
metricPMPNetworkFailure = clientmetric.NewCounter("portmap_pmp_network_failure")
// metricPMPNotAuthorized counts the number of times
// we received a PCP not authorized result code.
metricPMPNotAuthorized = clientmetric.NewCounter("portmap_pmp_not_authorized")
)
// UPnP metrics
var (
// metricUPnPSent counts the number of times we sent a UPnP request.
metricUPnPSent = clientmetric.NewCounter("portmap_upnp_sent")
// metricUPnPResponse counts the number of times we received a UPnP response.
metricUPnPResponse = clientmetric.NewCounter("portmap_upnp_response")
// metricUPnPParseErr counts the number of times we failed to parse a UPnP response.
metricUPnPParseErr = clientmetric.NewCounter("portmap_upnp_parse_err")
// metricUPnPOK counts the number of times we received a usable UPnP response.
metricUPnPOK = clientmetric.NewCounter("portmap_upnp_ok")
// metricUPnPUpdatedMeta counts the number of times
// we received a UPnP response with a new meta.
metricUPnPUpdatedMeta = clientmetric.NewCounter("portmap_upnp_updated_meta")
)