nebula/handshake_manager.go

package nebula

import (
	"crypto/rand"
	"encoding/binary"
	"fmt"
	"net"
	"time"

	"github.com/sirupsen/logrus"
)

const (
	// Total time to try a handshake = sequence of HandshakeTryInterval * HandshakeRetries
	// With 100ms interval and 20 retries is 23.5 seconds
	HandshakeTryInterval = time.Millisecond * 100
	HandshakeRetries     = 20
	// HandshakeWaitRotation is the number of handshake attempts to do before starting to use other ips addresses
	HandshakeWaitRotation = 5
)

type HandshakeManager struct {
	pendingHostMap *HostMap
	mainHostMap    *HostMap
	lightHouse     *LightHouse
	outside        *udpConn

	OutboundHandshakeTimer *SystemTimerWheel
	InboundHandshakeTimer  *SystemTimerWheel
}

func NewHandshakeManager(tunCidr *net.IPNet, preferredRanges []*net.IPNet, mainHostMap *HostMap, lightHouse *LightHouse, outside *udpConn) *HandshakeManager {
	return &HandshakeManager{
		pendingHostMap: NewHostMap("pending", tunCidr, preferredRanges),
		mainHostMap:    mainHostMap,
		lightHouse:     lightHouse,
		outside:        outside,

		OutboundHandshakeTimer: NewSystemTimerWheel(HandshakeTryInterval, HandshakeTryInterval*HandshakeRetries),
		InboundHandshakeTimer:  NewSystemTimerWheel(HandshakeTryInterval, HandshakeTryInterval*HandshakeRetries),
	}
}

func (c *HandshakeManager) Run(f EncWriter) {
	clockSource := time.Tick(HandshakeTryInterval)
	for now := range clockSource {
		c.NextOutboundHandshakeTimerTick(now, f)
		c.NextInboundHandshakeTimerTick(now)
	}
}

func (c *HandshakeManager) NextOutboundHandshakeTimerTick(now time.Time, f EncWriter) {
	c.OutboundHandshakeTimer.advance(now)
	for {
		ep := c.OutboundHandshakeTimer.Purge()
		if ep == nil {
			break
		}
		vpnIP := ep.(uint32)

		index, err := c.pendingHostMap.GetIndexByVpnIP(vpnIP)
		if err != nil {
			continue
		}

		hostinfo, err := c.pendingHostMap.QueryVpnIP(vpnIP)
		if err != nil {
			continue
		}

		// If we haven't finished the handshake and we haven't hit max retries, query
		// lighthouse and then send the handshake packet again.
		if hostinfo.HandshakeCounter < HandshakeRetries && !hostinfo.HandshakeComplete {
			if hostinfo.remote == nil {
				// We continue to query the lighthouse because hosts may
				// come online during handshake retries. If the query
				// succeeds (no error), add the lighthouse info to hostinfo
				ips, err := c.lightHouse.Query(vpnIP, f)
				if err == nil {
					for _, ip := range ips {
						hostinfo.AddRemote(ip)
					}
					hostinfo.ForcePromoteBest(c.mainHostMap.preferredRanges)
				}
			}

			hostinfo.HandshakeCounter++

			// We want to use the "best" calculated ip for the first 5 attempts, after that we just blindly rotate through
			// all the others until we can stand up a connection.
			if hostinfo.HandshakeCounter > HandshakeWaitRotation {
				hostinfo.rotateRemote()
			}

			// Ensure the handshake is ready to avoid a race in timer tick and stage 0 handshake generation
			if hostinfo.HandshakeReady && hostinfo.remote != nil {
				err := c.outside.WriteTo(hostinfo.HandshakePacket[0], hostinfo.remote)
				if err != nil {
					l.WithField("vpnIp", IntIp(vpnIP)).WithField("udpAddr", hostinfo.remote).
						WithField("initiatorIndex", hostinfo.localIndexId).
						WithField("remoteIndex", hostinfo.remoteIndexId).
						WithField("handshake", m{"stage": 1, "style": "ix_psk0"}).
						WithError(err).Error("Failed to send handshake message")
				} else {
					//TODO: this log line is assuming a lot of stuff around the cached stage 0 handshake packet, we should
					// keep the real packet struct around for logging purposes
					l.WithField("vpnIp", IntIp(vpnIP)).WithField("udpAddr", hostinfo.remote).
						WithField("initiatorIndex", hostinfo.localIndexId).
						WithField("remoteIndex", hostinfo.remoteIndexId).
						WithField("handshake", m{"stage": 1, "style": "ix_psk0"}).
						Info("Handshake message sent")
				}
			}

			// Readd to the timer wheel so we continue trying wait HandshakeTryInterval * counter longer for next try
			//l.Infoln("Interval: ", HandshakeTryInterval*time.Duration(hostinfo.HandshakeCounter))
			c.OutboundHandshakeTimer.Add(vpnIP, HandshakeTryInterval*time.Duration(hostinfo.HandshakeCounter))
		} else {
			c.pendingHostMap.DeleteVpnIP(vpnIP)
			c.pendingHostMap.DeleteIndex(index)
		}
	}
}

func (c *HandshakeManager) NextInboundHandshakeTimerTick(now time.Time) {
	c.InboundHandshakeTimer.advance(now)
	for {
		ep := c.InboundHandshakeTimer.Purge()
		if ep == nil {
			break
		}
		index := ep.(uint32)

		vpnIP, err := c.pendingHostMap.GetVpnIPByIndex(index)
		if err != nil {
			continue
		}
		c.pendingHostMap.DeleteIndex(index)
		c.pendingHostMap.DeleteVpnIP(vpnIP)
	}
}

func (c *HandshakeManager) AddVpnIP(vpnIP uint32) *HostInfo {
	hostinfo := c.pendingHostMap.AddVpnIP(vpnIP)
	// We lock here and use an array to insert items to prevent locking the
	// main receive thread for very long by waiting to add items to the pending map
	c.OutboundHandshakeTimer.Add(vpnIP, HandshakeTryInterval)
	return hostinfo
}

func (c *HandshakeManager) DeleteVpnIP(vpnIP uint32) {
	//l.Debugln("Deleting pending vpn ip :", IntIp(vpnIP))
	c.pendingHostMap.DeleteVpnIP(vpnIP)
}

func (c *HandshakeManager) AddIndex(index uint32, ci *ConnectionState) (*HostInfo, error) {
	hostinfo, err := c.pendingHostMap.AddIndex(index, ci)
	if err != nil {
		return nil, fmt.Errorf("Issue adding index: %d", index)
	}
	//c.mainHostMap.AddIndexHostInfo(index, hostinfo)
	c.InboundHandshakeTimer.Add(index, time.Second*10)
	return hostinfo, nil
}

func (c *HandshakeManager) AddIndexHostInfo(index uint32, h *HostInfo) {
	c.pendingHostMap.AddIndexHostInfo(index, h)
}

func (c *HandshakeManager) DeleteIndex(index uint32) {
	//l.Debugln("Deleting pending index :", index)
	c.pendingHostMap.DeleteIndex(index)
}

func (c *HandshakeManager) QueryIndex(index uint32) (*HostInfo, error) {
	return c.pendingHostMap.QueryIndex(index)
}

func (c *HandshakeManager) EmitStats() {
	c.pendingHostMap.EmitStats("pending")
	c.mainHostMap.EmitStats("main")
}

// Utility functions below

func generateIndex() (uint32, error) {
	b := make([]byte, 4)
	_, err := rand.Read(b)
	if err != nil {
		l.Errorln(err)
		return 0, err
	}

	index := binary.BigEndian.Uint32(b)
	if l.Level >= logrus.DebugLevel {
		l.WithField("index", index).
			Debug("Generated index")
	}
	return index, nil
}
Public Release 2019-11-19 18:00:20 +01:00			`package nebula`

			`import (`
			`"crypto/rand"`
			`"encoding/binary"`
			`"fmt"`
			`"net"`
			`"time"`

			`"github.com/sirupsen/logrus"`
			`)`

			`const (`
			`// Total time to try a handshake = sequence of HandshakeTryInterval * HandshakeRetries`
			`// With 100ms interval and 20 retries is 23.5 seconds`
			`HandshakeTryInterval = time.Millisecond * 100`
			`HandshakeRetries = 20`
			`// HandshakeWaitRotation is the number of handshake attempts to do before starting to use other ips addresses`
			`HandshakeWaitRotation = 5`
			`)`

			`type HandshakeManager struct {`
			`pendingHostMap *HostMap`
			`mainHostMap *HostMap`
			`lightHouse *LightHouse`
			`outside *udpConn`

			`OutboundHandshakeTimer *SystemTimerWheel`
			`InboundHandshakeTimer *SystemTimerWheel`
			`}`

			`func NewHandshakeManager(tunCidr net.IPNet, preferredRanges []net.IPNet, mainHostMap HostMap, lightHouse LightHouse, outside udpConn) HandshakeManager {`
			`return &HandshakeManager{`
			`pendingHostMap: NewHostMap("pending", tunCidr, preferredRanges),`
			`mainHostMap: mainHostMap,`
			`lightHouse: lightHouse,`
			`outside: outside,`

			`OutboundHandshakeTimer: NewSystemTimerWheel(HandshakeTryInterval, HandshakeTryInterval*HandshakeRetries),`
			`InboundHandshakeTimer: NewSystemTimerWheel(HandshakeTryInterval, HandshakeTryInterval*HandshakeRetries),`
			`}`
			`}`

			`func (c *HandshakeManager) Run(f EncWriter) {`
			`clockSource := time.Tick(HandshakeTryInterval)`
			`for now := range clockSource {`
			`c.NextOutboundHandshakeTimerTick(now, f)`
			`c.NextInboundHandshakeTimerTick(now)`
			`}`
			`}`

			`func (c *HandshakeManager) NextOutboundHandshakeTimerTick(now time.Time, f EncWriter) {`
			`c.OutboundHandshakeTimer.advance(now)`
			`for {`
			`ep := c.OutboundHandshakeTimer.Purge()`
			`if ep == nil {`
			`break`
			`}`
			`vpnIP := ep.(uint32)`

			`index, err := c.pendingHostMap.GetIndexByVpnIP(vpnIP)`
			`if err != nil {`
			`continue`
			`}`

			`hostinfo, err := c.pendingHostMap.QueryVpnIP(vpnIP)`
			`if err != nil {`
			`continue`
			`}`

			`// If we haven't finished the handshake and we haven't hit max retries, query`
			`// lighthouse and then send the handshake packet again.`
			`if hostinfo.HandshakeCounter < HandshakeRetries && !hostinfo.HandshakeComplete {`
			`if hostinfo.remote == nil {`
			`// We continue to query the lighthouse because hosts may`
			`// come online during handshake retries. If the query`
			`// succeeds (no error), add the lighthouse info to hostinfo`
			`ips, err := c.lightHouse.Query(vpnIP, f)`
			`if err == nil {`
			`for _, ip := range ips {`
			`hostinfo.AddRemote(ip)`
			`}`
			`hostinfo.ForcePromoteBest(c.mainHostMap.preferredRanges)`
			`}`
			`}`

			`hostinfo.HandshakeCounter++`

			`// We want to use the "best" calculated ip for the first 5 attempts, after that we just blindly rotate through`
			`// all the others until we can stand up a connection.`
			`if hostinfo.HandshakeCounter > HandshakeWaitRotation {`
			`hostinfo.rotateRemote()`
			`}`

			`// Ensure the handshake is ready to avoid a race in timer tick and stage 0 handshake generation`
			`if hostinfo.HandshakeReady && hostinfo.remote != nil {`
			`err := c.outside.WriteTo(hostinfo.HandshakePacket[0], hostinfo.remote)`
			`if err != nil {`
			`l.WithField("vpnIp", IntIp(vpnIP)).WithField("udpAddr", hostinfo.remote).`
			`WithField("initiatorIndex", hostinfo.localIndexId).`
			`WithField("remoteIndex", hostinfo.remoteIndexId).`
			`WithField("handshake", m{"stage": 1, "style": "ix_psk0"}).`
			`WithError(err).Error("Failed to send handshake message")`
			`} else {`
			`//TODO: this log line is assuming a lot of stuff around the cached stage 0 handshake packet, we should`
			`// keep the real packet struct around for logging purposes`
			`l.WithField("vpnIp", IntIp(vpnIP)).WithField("udpAddr", hostinfo.remote).`
			`WithField("initiatorIndex", hostinfo.localIndexId).`
			`WithField("remoteIndex", hostinfo.remoteIndexId).`
			`WithField("handshake", m{"stage": 1, "style": "ix_psk0"}).`
			`Info("Handshake message sent")`
			`}`
			`}`

			`// Readd to the timer wheel so we continue trying wait HandshakeTryInterval * counter longer for next try`
			`//l.Infoln("Interval: ", HandshakeTryInterval*time.Duration(hostinfo.HandshakeCounter))`
			`c.OutboundHandshakeTimer.Add(vpnIP, HandshakeTryInterval*time.Duration(hostinfo.HandshakeCounter))`
			`} else {`
			`c.pendingHostMap.DeleteVpnIP(vpnIP)`
			`c.pendingHostMap.DeleteIndex(index)`
			`}`
			`}`
			`}`

			`func (c *HandshakeManager) NextInboundHandshakeTimerTick(now time.Time) {`
			`c.InboundHandshakeTimer.advance(now)`
			`for {`
			`ep := c.InboundHandshakeTimer.Purge()`
			`if ep == nil {`
			`break`
			`}`
			`index := ep.(uint32)`

			`vpnIP, err := c.pendingHostMap.GetVpnIPByIndex(index)`
			`if err != nil {`
			`continue`
			`}`
			`c.pendingHostMap.DeleteIndex(index)`
			`c.pendingHostMap.DeleteVpnIP(vpnIP)`
			`}`
			`}`

			`func (c HandshakeManager) AddVpnIP(vpnIP uint32) HostInfo {`
			`hostinfo := c.pendingHostMap.AddVpnIP(vpnIP)`
			`// We lock here and use an array to insert items to prevent locking the`
			`// main receive thread for very long by waiting to add items to the pending map`
			`c.OutboundHandshakeTimer.Add(vpnIP, HandshakeTryInterval)`
			`return hostinfo`
			`}`

			`func (c *HandshakeManager) DeleteVpnIP(vpnIP uint32) {`
			`//l.Debugln("Deleting pending vpn ip :", IntIp(vpnIP))`
			`c.pendingHostMap.DeleteVpnIP(vpnIP)`
			`}`

			`func (c HandshakeManager) AddIndex(index uint32, ci ConnectionState) (*HostInfo, error) {`
			`hostinfo, err := c.pendingHostMap.AddIndex(index, ci)`
			`if err != nil {`
			`return nil, fmt.Errorf("Issue adding index: %d", index)`
			`}`
			`//c.mainHostMap.AddIndexHostInfo(index, hostinfo)`
			`c.InboundHandshakeTimer.Add(index, time.Second*10)`
			`return hostinfo, nil`
			`}`

			`func (c HandshakeManager) AddIndexHostInfo(index uint32, h HostInfo) {`
			`c.pendingHostMap.AddIndexHostInfo(index, h)`
			`}`

			`func (c *HandshakeManager) DeleteIndex(index uint32) {`
			`//l.Debugln("Deleting pending index :", index)`
			`c.pendingHostMap.DeleteIndex(index)`
			`}`

			`func (c HandshakeManager) QueryIndex(index uint32) (HostInfo, error) {`
			`return c.pendingHostMap.QueryIndex(index)`
			`}`

			`func (c *HandshakeManager) EmitStats() {`
			`c.pendingHostMap.EmitStats("pending")`
			`c.mainHostMap.EmitStats("main")`
			`}`

			`// Utility functions below`

			`func generateIndex() (uint32, error) {`
			`b := make([]byte, 4)`
			`_, err := rand.Read(b)`
			`if err != nil {`
			`l.Errorln(err)`
			`return 0, err`
			`}`

			`index := binary.BigEndian.Uint32(b)`
			`if l.Level >= logrus.DebugLevel {`
			`l.WithField("index", index).`
			`Debug("Generated index")`
			`}`
			`return index, nil`
			`}`