nebula/lighthouse.go

654 lines
17 KiB
Go

package nebula
import (
"context"
"encoding/binary"
"errors"
"fmt"
"net"
"sync"
"time"
"github.com/golang/protobuf/proto"
"github.com/rcrowley/go-metrics"
"github.com/sirupsen/logrus"
"github.com/slackhq/nebula/header"
"github.com/slackhq/nebula/iputil"
"github.com/slackhq/nebula/udp"
)
//TODO: if a lighthouse doesn't have an answer, clients AGGRESSIVELY REQUERY.. why? handshake manager and/or getOrHandshake?
//TODO: nodes are roaming lighthouses, this is bad. How are they learning?
var ErrHostNotKnown = errors.New("host not known")
type LightHouse struct {
//TODO: We need a timer wheel to kick out vpnIps that haven't reported in a long time
sync.RWMutex //Because we concurrently read and write to our maps
amLighthouse bool
myVpnIp iputil.VpnIp
myVpnZeros iputil.VpnIp
punchConn *udp.Conn
// Local cache of answers from light houses
// map of vpn Ip to answers
addrMap map[iputil.VpnIp]*RemoteList
// filters remote addresses allowed for each host
// - When we are a lighthouse, this filters what addresses we store and
// respond with.
// - When we are not a lighthouse, this filters which addresses we accept
// from lighthouses.
remoteAllowList *RemoteAllowList
// filters local addresses that we advertise to lighthouses
localAllowList *LocalAllowList
// used to trigger the HandshakeManager when we receive HostQueryReply
handshakeTrigger chan<- iputil.VpnIp
// staticList exists to avoid having a bool in each addrMap entry
// since static should be rare
staticList map[iputil.VpnIp]struct{}
lighthouses map[iputil.VpnIp]struct{}
interval int
nebulaPort uint32 // 32 bits because protobuf does not have a uint16
punchBack bool
punchDelay time.Duration
metrics *MessageMetrics
metricHolepunchTx metrics.Counter
l *logrus.Logger
}
func NewLightHouse(l *logrus.Logger, amLighthouse bool, myVpnIpNet *net.IPNet, ips []iputil.VpnIp, interval int, nebulaPort uint32, pc *udp.Conn, punchBack bool, punchDelay time.Duration, metricsEnabled bool) *LightHouse {
ones, _ := myVpnIpNet.Mask.Size()
h := LightHouse{
amLighthouse: amLighthouse,
myVpnIp: iputil.Ip2VpnIp(myVpnIpNet.IP),
myVpnZeros: iputil.VpnIp(32 - ones),
addrMap: make(map[iputil.VpnIp]*RemoteList),
nebulaPort: nebulaPort,
lighthouses: make(map[iputil.VpnIp]struct{}),
staticList: make(map[iputil.VpnIp]struct{}),
interval: interval,
punchConn: pc,
punchBack: punchBack,
punchDelay: punchDelay,
l: l,
}
if metricsEnabled {
h.metrics = newLighthouseMetrics()
h.metricHolepunchTx = metrics.GetOrRegisterCounter("messages.tx.holepunch", nil)
} else {
h.metricHolepunchTx = metrics.NilCounter{}
}
for _, ip := range ips {
h.lighthouses[ip] = struct{}{}
}
return &h
}
func (lh *LightHouse) SetRemoteAllowList(allowList *RemoteAllowList) {
lh.Lock()
defer lh.Unlock()
lh.remoteAllowList = allowList
}
func (lh *LightHouse) SetLocalAllowList(allowList *LocalAllowList) {
lh.Lock()
defer lh.Unlock()
lh.localAllowList = allowList
}
func (lh *LightHouse) ValidateLHStaticEntries() error {
for lhIP, _ := range lh.lighthouses {
if _, ok := lh.staticList[lhIP]; !ok {
return fmt.Errorf("Lighthouse %s does not have a static_host_map entry", lhIP)
}
}
return nil
}
func (lh *LightHouse) Query(ip iputil.VpnIp, f udp.EncWriter) *RemoteList {
if !lh.IsLighthouseIP(ip) {
lh.QueryServer(ip, f)
}
lh.RLock()
if v, ok := lh.addrMap[ip]; ok {
lh.RUnlock()
return v
}
lh.RUnlock()
return nil
}
// This is asynchronous so no reply should be expected
func (lh *LightHouse) QueryServer(ip iputil.VpnIp, f udp.EncWriter) {
if lh.amLighthouse {
return
}
if lh.IsLighthouseIP(ip) {
return
}
// Send a query to the lighthouses and hope for the best next time
query, err := proto.Marshal(NewLhQueryByInt(ip))
if err != nil {
lh.l.WithError(err).WithField("vpnIp", ip).Error("Failed to marshal lighthouse query payload")
return
}
lh.metricTx(NebulaMeta_HostQuery, int64(len(lh.lighthouses)))
nb := make([]byte, 12, 12)
out := make([]byte, mtu)
for n := range lh.lighthouses {
f.SendMessageToVpnIp(header.LightHouse, 0, n, query, nb, out)
}
}
func (lh *LightHouse) QueryCache(ip iputil.VpnIp) *RemoteList {
lh.RLock()
if v, ok := lh.addrMap[ip]; ok {
lh.RUnlock()
return v
}
lh.RUnlock()
lh.Lock()
defer lh.Unlock()
// Add an entry if we don't already have one
return lh.unlockedGetRemoteList(ip)
}
// queryAndPrepMessage is a lock helper on RemoteList, assisting the caller to build a lighthouse message containing
// details from the remote list. It looks for a hit in the addrMap and a hit in the RemoteList under the owner vpnIp
// If one is found then f() is called with proper locking, f() must return result of n.MarshalTo()
func (lh *LightHouse) queryAndPrepMessage(vpnIp iputil.VpnIp, f func(*cache) (int, error)) (bool, int, error) {
lh.RLock()
// Do we have an entry in the main cache?
if v, ok := lh.addrMap[vpnIp]; ok {
// Swap lh lock for remote list lock
v.RLock()
defer v.RUnlock()
lh.RUnlock()
// vpnIp should also be the owner here since we are a lighthouse.
c := v.cache[vpnIp]
// Make sure we have
if c != nil {
n, err := f(c)
return true, n, err
}
return false, 0, nil
}
lh.RUnlock()
return false, 0, nil
}
func (lh *LightHouse) DeleteVpnIp(vpnIp iputil.VpnIp) {
// First we check the static mapping
// and do nothing if it is there
if _, ok := lh.staticList[vpnIp]; ok {
return
}
lh.Lock()
//l.Debugln(lh.addrMap)
delete(lh.addrMap, vpnIp)
if lh.l.Level >= logrus.DebugLevel {
lh.l.Debugf("deleting %s from lighthouse.", vpnIp)
}
lh.Unlock()
}
// AddStaticRemote adds a static host entry for vpnIp as ourselves as the owner
// We are the owner because we don't want a lighthouse server to advertise for static hosts it was configured with
// And we don't want a lighthouse query reply to interfere with our learned cache if we are a client
func (lh *LightHouse) AddStaticRemote(vpnIp iputil.VpnIp, toAddr *udp.Addr) {
lh.Lock()
am := lh.unlockedGetRemoteList(vpnIp)
am.Lock()
defer am.Unlock()
lh.Unlock()
if ipv4 := toAddr.IP.To4(); ipv4 != nil {
to := NewIp4AndPort(ipv4, uint32(toAddr.Port))
if !lh.unlockedShouldAddV4(vpnIp, to) {
return
}
am.unlockedPrependV4(lh.myVpnIp, to)
} else {
to := NewIp6AndPort(toAddr.IP, uint32(toAddr.Port))
if !lh.unlockedShouldAddV6(vpnIp, to) {
return
}
am.unlockedPrependV6(lh.myVpnIp, to)
}
// Mark it as static
lh.staticList[vpnIp] = struct{}{}
}
// unlockedGetRemoteList assumes you have the lh lock
func (lh *LightHouse) unlockedGetRemoteList(vpnIp iputil.VpnIp) *RemoteList {
am, ok := lh.addrMap[vpnIp]
if !ok {
am = NewRemoteList()
lh.addrMap[vpnIp] = am
}
return am
}
// unlockedShouldAddV4 checks if to is allowed by our allow list
func (lh *LightHouse) unlockedShouldAddV4(vpnIp iputil.VpnIp, to *Ip4AndPort) bool {
allow := lh.remoteAllowList.AllowIpV4(vpnIp, iputil.VpnIp(to.Ip))
if lh.l.Level >= logrus.TraceLevel {
lh.l.WithField("remoteIp", vpnIp).WithField("allow", allow).Trace("remoteAllowList.Allow")
}
if !allow || ipMaskContains(lh.myVpnIp, lh.myVpnZeros, iputil.VpnIp(to.Ip)) {
return false
}
return true
}
// unlockedShouldAddV6 checks if to is allowed by our allow list
func (lh *LightHouse) unlockedShouldAddV6(vpnIp iputil.VpnIp, to *Ip6AndPort) bool {
allow := lh.remoteAllowList.AllowIpV6(vpnIp, to.Hi, to.Lo)
if lh.l.Level >= logrus.TraceLevel {
lh.l.WithField("remoteIp", lhIp6ToIp(to)).WithField("allow", allow).Trace("remoteAllowList.Allow")
}
// We don't check our vpn network here because nebula does not support ipv6 on the inside
if !allow {
return false
}
return true
}
func lhIp6ToIp(v *Ip6AndPort) net.IP {
ip := make(net.IP, 16)
binary.BigEndian.PutUint64(ip[:8], v.Hi)
binary.BigEndian.PutUint64(ip[8:], v.Lo)
return ip
}
func (lh *LightHouse) IsLighthouseIP(vpnIp iputil.VpnIp) bool {
if _, ok := lh.lighthouses[vpnIp]; ok {
return true
}
return false
}
func NewLhQueryByInt(VpnIp iputil.VpnIp) *NebulaMeta {
return &NebulaMeta{
Type: NebulaMeta_HostQuery,
Details: &NebulaMetaDetails{
VpnIp: uint32(VpnIp),
},
}
}
func NewIp4AndPort(ip net.IP, port uint32) *Ip4AndPort {
ipp := Ip4AndPort{Port: port}
ipp.Ip = uint32(iputil.Ip2VpnIp(ip))
return &ipp
}
func NewIp6AndPort(ip net.IP, port uint32) *Ip6AndPort {
return &Ip6AndPort{
Hi: binary.BigEndian.Uint64(ip[:8]),
Lo: binary.BigEndian.Uint64(ip[8:]),
Port: port,
}
}
func NewUDPAddrFromLH4(ipp *Ip4AndPort) *udp.Addr {
ip := ipp.Ip
return udp.NewAddr(
net.IPv4(byte(ip&0xff000000>>24), byte(ip&0x00ff0000>>16), byte(ip&0x0000ff00>>8), byte(ip&0x000000ff)),
uint16(ipp.Port),
)
}
func NewUDPAddrFromLH6(ipp *Ip6AndPort) *udp.Addr {
return udp.NewAddr(lhIp6ToIp(ipp), uint16(ipp.Port))
}
func (lh *LightHouse) LhUpdateWorker(ctx context.Context, f udp.EncWriter) {
if lh.amLighthouse || lh.interval == 0 {
return
}
clockSource := time.NewTicker(time.Second * time.Duration(lh.interval))
defer clockSource.Stop()
for {
lh.SendUpdate(f)
select {
case <-ctx.Done():
return
case <-clockSource.C:
continue
}
}
}
func (lh *LightHouse) SendUpdate(f udp.EncWriter) {
var v4 []*Ip4AndPort
var v6 []*Ip6AndPort
for _, e := range *localIps(lh.l, lh.localAllowList) {
if ip4 := e.To4(); ip4 != nil && ipMaskContains(lh.myVpnIp, lh.myVpnZeros, iputil.Ip2VpnIp(ip4)) {
continue
}
// Only add IPs that aren't my VPN/tun IP
if ip := e.To4(); ip != nil {
v4 = append(v4, NewIp4AndPort(e, lh.nebulaPort))
} else {
v6 = append(v6, NewIp6AndPort(e, lh.nebulaPort))
}
}
m := &NebulaMeta{
Type: NebulaMeta_HostUpdateNotification,
Details: &NebulaMetaDetails{
VpnIp: uint32(lh.myVpnIp),
Ip4AndPorts: v4,
Ip6AndPorts: v6,
},
}
lh.metricTx(NebulaMeta_HostUpdateNotification, int64(len(lh.lighthouses)))
nb := make([]byte, 12, 12)
out := make([]byte, mtu)
mm, err := proto.Marshal(m)
if err != nil {
lh.l.WithError(err).Error("Error while marshaling for lighthouse update")
return
}
for vpnIp := range lh.lighthouses {
f.SendMessageToVpnIp(header.LightHouse, 0, vpnIp, mm, nb, out)
}
}
type LightHouseHandler struct {
lh *LightHouse
nb []byte
out []byte
pb []byte
meta *NebulaMeta
l *logrus.Logger
}
func (lh *LightHouse) NewRequestHandler() *LightHouseHandler {
lhh := &LightHouseHandler{
lh: lh,
nb: make([]byte, 12, 12),
out: make([]byte, mtu),
l: lh.l,
pb: make([]byte, mtu),
meta: &NebulaMeta{
Details: &NebulaMetaDetails{},
},
}
return lhh
}
func (lh *LightHouse) metricRx(t NebulaMeta_MessageType, i int64) {
lh.metrics.Rx(header.MessageType(t), 0, i)
}
func (lh *LightHouse) metricTx(t NebulaMeta_MessageType, i int64) {
lh.metrics.Tx(header.MessageType(t), 0, i)
}
// This method is similar to Reset(), but it re-uses the pointer structs
// so that we don't have to re-allocate them
func (lhh *LightHouseHandler) resetMeta() *NebulaMeta {
details := lhh.meta.Details
lhh.meta.Reset()
// Keep the array memory around
details.Ip4AndPorts = details.Ip4AndPorts[:0]
details.Ip6AndPorts = details.Ip6AndPorts[:0]
lhh.meta.Details = details
return lhh.meta
}
func (lhh *LightHouseHandler) HandleRequest(rAddr *udp.Addr, vpnIp iputil.VpnIp, p []byte, w udp.EncWriter) {
n := lhh.resetMeta()
err := n.Unmarshal(p)
if err != nil {
lhh.l.WithError(err).WithField("vpnIp", vpnIp).WithField("udpAddr", rAddr).
Error("Failed to unmarshal lighthouse packet")
//TODO: send recv_error?
return
}
if n.Details == nil {
lhh.l.WithField("vpnIp", vpnIp).WithField("udpAddr", rAddr).
Error("Invalid lighthouse update")
//TODO: send recv_error?
return
}
lhh.lh.metricRx(n.Type, 1)
switch n.Type {
case NebulaMeta_HostQuery:
lhh.handleHostQuery(n, vpnIp, rAddr, w)
case NebulaMeta_HostQueryReply:
lhh.handleHostQueryReply(n, vpnIp)
case NebulaMeta_HostUpdateNotification:
lhh.handleHostUpdateNotification(n, vpnIp)
case NebulaMeta_HostMovedNotification:
case NebulaMeta_HostPunchNotification:
lhh.handleHostPunchNotification(n, vpnIp, w)
}
}
func (lhh *LightHouseHandler) handleHostQuery(n *NebulaMeta, vpnIp iputil.VpnIp, addr *udp.Addr, w udp.EncWriter) {
// Exit if we don't answer queries
if !lhh.lh.amLighthouse {
if lhh.l.Level >= logrus.DebugLevel {
lhh.l.Debugln("I don't answer queries, but received from: ", addr)
}
return
}
//TODO: we can DRY this further
reqVpnIp := n.Details.VpnIp
//TODO: Maybe instead of marshalling into n we marshal into a new `r` to not nuke our current request data
found, ln, err := lhh.lh.queryAndPrepMessage(iputil.VpnIp(n.Details.VpnIp), func(c *cache) (int, error) {
n = lhh.resetMeta()
n.Type = NebulaMeta_HostQueryReply
n.Details.VpnIp = reqVpnIp
lhh.coalesceAnswers(c, n)
return n.MarshalTo(lhh.pb)
})
if !found {
return
}
if err != nil {
lhh.l.WithError(err).WithField("vpnIp", vpnIp).Error("Failed to marshal lighthouse host query reply")
return
}
lhh.lh.metricTx(NebulaMeta_HostQueryReply, 1)
w.SendMessageToVpnIp(header.LightHouse, 0, vpnIp, lhh.pb[:ln], lhh.nb, lhh.out[:0])
// This signals the other side to punch some zero byte udp packets
found, ln, err = lhh.lh.queryAndPrepMessage(vpnIp, func(c *cache) (int, error) {
n = lhh.resetMeta()
n.Type = NebulaMeta_HostPunchNotification
n.Details.VpnIp = uint32(vpnIp)
lhh.coalesceAnswers(c, n)
return n.MarshalTo(lhh.pb)
})
if !found {
return
}
if err != nil {
lhh.l.WithError(err).WithField("vpnIp", vpnIp).Error("Failed to marshal lighthouse host was queried for")
return
}
lhh.lh.metricTx(NebulaMeta_HostPunchNotification, 1)
w.SendMessageToVpnIp(header.LightHouse, 0, iputil.VpnIp(reqVpnIp), lhh.pb[:ln], lhh.nb, lhh.out[:0])
}
func (lhh *LightHouseHandler) coalesceAnswers(c *cache, n *NebulaMeta) {
if c.v4 != nil {
if c.v4.learned != nil {
n.Details.Ip4AndPorts = append(n.Details.Ip4AndPorts, c.v4.learned)
}
if c.v4.reported != nil && len(c.v4.reported) > 0 {
n.Details.Ip4AndPorts = append(n.Details.Ip4AndPorts, c.v4.reported...)
}
}
if c.v6 != nil {
if c.v6.learned != nil {
n.Details.Ip6AndPorts = append(n.Details.Ip6AndPorts, c.v6.learned)
}
if c.v6.reported != nil && len(c.v6.reported) > 0 {
n.Details.Ip6AndPorts = append(n.Details.Ip6AndPorts, c.v6.reported...)
}
}
}
func (lhh *LightHouseHandler) handleHostQueryReply(n *NebulaMeta, vpnIp iputil.VpnIp) {
if !lhh.lh.IsLighthouseIP(vpnIp) {
return
}
lhh.lh.Lock()
am := lhh.lh.unlockedGetRemoteList(iputil.VpnIp(n.Details.VpnIp))
am.Lock()
lhh.lh.Unlock()
certVpnIp := iputil.VpnIp(n.Details.VpnIp)
am.unlockedSetV4(vpnIp, certVpnIp, n.Details.Ip4AndPorts, lhh.lh.unlockedShouldAddV4)
am.unlockedSetV6(vpnIp, certVpnIp, n.Details.Ip6AndPorts, lhh.lh.unlockedShouldAddV6)
am.Unlock()
// Non-blocking attempt to trigger, skip if it would block
select {
case lhh.lh.handshakeTrigger <- iputil.VpnIp(n.Details.VpnIp):
default:
}
}
func (lhh *LightHouseHandler) handleHostUpdateNotification(n *NebulaMeta, vpnIp iputil.VpnIp) {
if !lhh.lh.amLighthouse {
if lhh.l.Level >= logrus.DebugLevel {
lhh.l.Debugln("I am not a lighthouse, do not take host updates: ", vpnIp)
}
return
}
//Simple check that the host sent this not someone else
if n.Details.VpnIp != uint32(vpnIp) {
if lhh.l.Level >= logrus.DebugLevel {
lhh.l.WithField("vpnIp", vpnIp).WithField("answer", iputil.VpnIp(n.Details.VpnIp)).Debugln("Host sent invalid update")
}
return
}
lhh.lh.Lock()
am := lhh.lh.unlockedGetRemoteList(vpnIp)
am.Lock()
lhh.lh.Unlock()
certVpnIp := iputil.VpnIp(n.Details.VpnIp)
am.unlockedSetV4(vpnIp, certVpnIp, n.Details.Ip4AndPorts, lhh.lh.unlockedShouldAddV4)
am.unlockedSetV6(vpnIp, certVpnIp, n.Details.Ip6AndPorts, lhh.lh.unlockedShouldAddV6)
am.Unlock()
}
func (lhh *LightHouseHandler) handleHostPunchNotification(n *NebulaMeta, vpnIp iputil.VpnIp, w udp.EncWriter) {
if !lhh.lh.IsLighthouseIP(vpnIp) {
return
}
empty := []byte{0}
punch := func(vpnPeer *udp.Addr) {
if vpnPeer == nil {
return
}
go func() {
time.Sleep(lhh.lh.punchDelay)
lhh.lh.metricHolepunchTx.Inc(1)
lhh.lh.punchConn.WriteTo(empty, vpnPeer)
}()
if lhh.l.Level >= logrus.DebugLevel {
//TODO: lacking the ip we are actually punching on, old: l.Debugf("Punching %s on %d for %s", IntIp(a.Ip), a.Port, IntIp(n.Details.VpnIp))
lhh.l.Debugf("Punching on %d for %s", vpnPeer.Port, iputil.VpnIp(n.Details.VpnIp))
}
}
for _, a := range n.Details.Ip4AndPorts {
punch(NewUDPAddrFromLH4(a))
}
for _, a := range n.Details.Ip6AndPorts {
punch(NewUDPAddrFromLH6(a))
}
// This sends a nebula test packet to the host trying to contact us. In the case
// of a double nat or other difficult scenario, this may help establish
// a tunnel.
if lhh.lh.punchBack {
queryVpnIp := iputil.VpnIp(n.Details.VpnIp)
go func() {
time.Sleep(time.Second * 5)
if lhh.l.Level >= logrus.DebugLevel {
lhh.l.Debugf("Sending a nebula test packet to vpn ip %s", queryVpnIp)
}
//NOTE: we have to allocate a new output buffer here since we are spawning a new goroutine
// for each punchBack packet. We should move this into a timerwheel or a single goroutine
// managed by a channel.
w.SendMessageToVpnIp(header.Test, header.TestRequest, queryVpnIp, []byte(""), make([]byte, 12, 12), make([]byte, mtu))
}()
}
}
// ipMaskContains checks if testIp is contained by ip after applying a cidr
// zeros is 32 - bits from net.IPMask.Size()
func ipMaskContains(ip iputil.VpnIp, zeros iputil.VpnIp, testIp iputil.VpnIp) bool {
return (testIp^ip)>>zeros == 0
}