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state.go
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state.go
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package memberlist
import (
"bytes"
"fmt"
"math"
"math/rand"
"net"
"sync/atomic"
"time"
metrics "github.com/armon/go-metrics"
)
type nodeStateType int
const (
stateAlive nodeStateType = iota
stateSuspect
stateDead
)
// Node represents a node in the cluster.
type Node struct {
Name string
Addr net.IP
Port uint16
Meta []byte // Metadata from the delegate for this node.
PMin uint8 // Minimum protocol version this understands
PMax uint8 // Maximum protocol version this understands
PCur uint8 // Current version node is speaking
DMin uint8 // Min protocol version for the delegate to understand
DMax uint8 // Max protocol version for the delegate to understand
DCur uint8 // Current version delegate is speaking
}
// Address returns the host:port form of a node's address, suitable for use
// with a transport.
func (n *Node) Address() string {
return joinHostPort(n.Addr.String(), n.Port)
}
// String returns the node name
func (n *Node) String() string {
return n.Name
}
// NodeState is used to manage our state view of another node
type nodeState struct {
Node
Incarnation uint32 // Last known incarnation number
State nodeStateType // Current state
StateChange time.Time // Time last state change happened
}
// Address returns the host:port form of a node's address, suitable for use
// with a transport.
func (n *nodeState) Address() string {
return n.Node.Address()
}
// ackHandler is used to register handlers for incoming acks and nacks.
type ackHandler struct {
ackFn func([]byte, time.Time)
nackFn func()
timer *time.Timer
}
// NoPingResponseError is used to indicate a 'ping' packet was
// successfully issued but no response was received
type NoPingResponseError struct {
node string
}
func (f NoPingResponseError) Error() string {
return fmt.Sprintf("No response from node %s", f.node)
}
// Schedule is used to ensure the Tick is performed periodically. This
// function is safe to call multiple times. If the memberlist is already
// scheduled, then it won't do anything.
func (m *Memberlist) schedule() {
m.tickerLock.Lock()
defer m.tickerLock.Unlock()
// If we already have tickers, then don't do anything, since we're
// scheduled
if len(m.tickers) > 0 {
return
}
// Create the stop tick channel, a blocking channel. We close this
// when we should stop the tickers.
stopCh := make(chan struct{})
// Create a new probeTicker
if m.config.ProbeInterval > 0 {
t := time.NewTicker(m.config.ProbeInterval)
go m.triggerFunc(m.config.ProbeInterval, t.C, stopCh, m.probe)
m.tickers = append(m.tickers, t)
}
// Create a push pull ticker if needed
if m.config.PushPullInterval > 0 {
go m.pushPullTrigger(stopCh)
}
// Create a gossip ticker if needed
if m.config.GossipInterval > 0 && m.config.GossipNodes > 0 {
t := time.NewTicker(m.config.GossipInterval)
go m.triggerFunc(m.config.GossipInterval, t.C, stopCh, m.gossip)
m.tickers = append(m.tickers, t)
}
// If we made any tickers, then record the stopTick channel for
// later.
if len(m.tickers) > 0 {
m.stopTick = stopCh
}
}
// triggerFunc is used to trigger a function call each time a
// message is received until a stop tick arrives.
func (m *Memberlist) triggerFunc(stagger time.Duration, C <-chan time.Time, stop <-chan struct{}, f func()) {
// Use a random stagger to avoid syncronizing
randStagger := time.Duration(uint64(rand.Int63()) % uint64(stagger))
select {
case <-time.After(randStagger):
case <-stop:
return
}
for {
select {
case <-C:
f()
case <-stop:
return
}
}
}
// pushPullTrigger is used to periodically trigger a push/pull until
// a stop tick arrives. We don't use triggerFunc since the push/pull
// timer is dynamically scaled based on cluster size to avoid network
// saturation
func (m *Memberlist) pushPullTrigger(stop <-chan struct{}) {
interval := m.config.PushPullInterval
// Use a random stagger to avoid syncronizing
randStagger := time.Duration(uint64(rand.Int63()) % uint64(interval))
select {
case <-time.After(randStagger):
case <-stop:
return
}
// Tick using a dynamic timer
for {
tickTime := pushPullScale(interval, m.estNumNodes())
select {
case <-time.After(tickTime):
m.pushPull()
case <-stop:
return
}
}
}
// Deschedule is used to stop the background maintenance. This is safe
// to call multiple times.
func (m *Memberlist) deschedule() {
m.tickerLock.Lock()
defer m.tickerLock.Unlock()
// If we have no tickers, then we aren't scheduled.
if len(m.tickers) == 0 {
return
}
// Close the stop channel so all the ticker listeners stop.
close(m.stopTick)
// Explicitly stop all the tickers themselves so they don't take
// up any more resources, and get rid of the list.
for _, t := range m.tickers {
t.Stop()
}
m.tickers = nil
}
// Tick is used to perform a single round of failure detection and gossip
func (m *Memberlist) probe() {
// Track the number of indexes we've considered probing
numCheck := 0
START:
m.nodeLock.RLock()
// Make sure we don't wrap around infinitely
if numCheck >= len(m.nodes) {
m.nodeLock.RUnlock()
return
}
// Handle the wrap around case
if m.probeIndex >= len(m.nodes) {
m.nodeLock.RUnlock()
m.resetNodes()
m.probeIndex = 0
numCheck++
goto START
}
// Determine if we should probe this node
skip := false
var node nodeState
node = *m.nodes[m.probeIndex]
if node.Name == m.config.Name {
skip = true
} else if node.State == stateDead {
skip = true
}
// Potentially skip
m.nodeLock.RUnlock()
m.probeIndex++
if skip {
numCheck++
goto START
}
// Probe the specific node
m.probeNode(&node)
}
// probeNodeByAddr just safely calls probeNode given only the address of the node (for tests)
func (m *Memberlist) probeNodeByAddr(addr string) {
m.nodeLock.RLock()
n := m.nodeMap[addr]
m.nodeLock.RUnlock()
m.probeNode(n)
}
// probeNode handles a single round of failure checking on a node.
func (m *Memberlist) probeNode(node *nodeState) {
defer metrics.MeasureSince([]string{"memberlist", "probeNode"}, time.Now())
// We use our health awareness to scale the overall probe interval, so we
// slow down if we detect problems. The ticker that calls us can handle
// us running over the base interval, and will skip missed ticks.
probeInterval := m.awareness.ScaleTimeout(m.config.ProbeInterval)
if probeInterval > m.config.ProbeInterval {
metrics.IncrCounter([]string{"memberlist", "degraded", "probe"}, 1)
}
// Prepare a ping message and setup an ack handler.
ping := ping{SeqNo: m.nextSeqNo(), Node: node.Name}
ackCh := make(chan ackMessage, m.config.IndirectChecks+1)
nackCh := make(chan struct{}, m.config.IndirectChecks+1)
m.setProbeChannels(ping.SeqNo, ackCh, nackCh, probeInterval)
// Mark the sent time here, which should be after any pre-processing but
// before system calls to do the actual send. This probably over-reports
// a bit, but it's the best we can do. We had originally put this right
// after the I/O, but that would sometimes give negative RTT measurements
// which was not desirable.
sent := time.Now()
// Send a ping to the node. If this node looks like it's suspect or dead,
// also tack on a suspect message so that it has a chance to refute as
// soon as possible.
deadline := sent.Add(probeInterval)
addr := node.Address()
if node.State == stateAlive {
if err := m.encodeAndSendMsg(addr, pingMsg, &ping); err != nil {
m.logger.Printf("[ERR] memberlist: Failed to send ping: %s", err)
return
}
} else {
var msgs [][]byte
if buf, err := encode(pingMsg, &ping); err != nil {
m.logger.Printf("[ERR] memberlist: Failed to encode ping message: %s", err)
return
} else {
msgs = append(msgs, buf.Bytes())
}
s := suspect{Incarnation: node.Incarnation, Node: node.Name, From: m.config.Name}
if buf, err := encode(suspectMsg, &s); err != nil {
m.logger.Printf("[ERR] memberlist: Failed to encode suspect message: %s", err)
return
} else {
msgs = append(msgs, buf.Bytes())
}
compound := makeCompoundMessage(msgs)
if err := m.rawSendMsgPacket(addr, &node.Node, compound.Bytes()); err != nil {
m.logger.Printf("[ERR] memberlist: Failed to send compound ping and suspect message to %s: %s", addr, err)
return
}
}
// Arrange for our self-awareness to get updated. At this point we've
// sent the ping, so any return statement means the probe succeeded
// which will improve our health until we get to the failure scenarios
// at the end of this function, which will alter this delta variable
// accordingly.
awarenessDelta := -1
defer func() {
m.awareness.ApplyDelta(awarenessDelta)
}()
// Wait for response or round-trip-time.
select {
case v := <-ackCh:
if v.Complete == true {
if m.config.Ping != nil {
rtt := v.Timestamp.Sub(sent)
m.config.Ping.NotifyPingComplete(&node.Node, rtt, v.Payload)
}
return
}
// As an edge case, if we get a timeout, we need to re-enqueue it
// here to break out of the select below.
if v.Complete == false {
ackCh <- v
}
case <-time.After(m.config.ProbeTimeout):
// Note that we don't scale this timeout based on awareness and
// the health score. That's because we don't really expect waiting
// longer to help get UDP through. Since health does extend the
// probe interval it will give the TCP fallback more time, which
// is more active in dealing with lost packets, and it gives more
// time to wait for indirect acks/nacks.
m.logger.Printf("[DEBUG] memberlist: Failed ping: %v (timeout reached)", node.Name)
}
// Get some random live nodes.
m.nodeLock.RLock()
kNodes := kRandomNodes(m.config.IndirectChecks, m.nodes, func(n *nodeState) bool {
return n.Name == m.config.Name ||
n.Name == node.Name ||
n.State != stateAlive
})
m.nodeLock.RUnlock()
// Attempt an indirect ping.
expectedNacks := 0
ind := indirectPingReq{SeqNo: ping.SeqNo, Target: node.Addr, Port: node.Port, Node: node.Name}
for _, peer := range kNodes {
// We only expect nack to be sent from peers who understand
// version 4 of the protocol.
if ind.Nack = peer.PMax >= 4; ind.Nack {
expectedNacks++
}
if err := m.encodeAndSendMsg(peer.Address(), indirectPingMsg, &ind); err != nil {
m.logger.Printf("[ERR] memberlist: Failed to send indirect ping: %s", err)
}
}
// Also make an attempt to contact the node directly over TCP. This
// helps prevent confused clients who get isolated from UDP traffic
// but can still speak TCP (which also means they can possibly report
// misinformation to other nodes via anti-entropy), avoiding flapping in
// the cluster.
//
// This is a little unusual because we will attempt a TCP ping to any
// member who understands version 3 of the protocol, regardless of
// which protocol version we are speaking. That's why we've included a
// config option to turn this off if desired.
fallbackCh := make(chan bool, 1)
if (!m.config.DisableTcpPings) && (node.PMax >= 3) {
go func() {
defer close(fallbackCh)
didContact, err := m.sendPingAndWaitForAck(node.Address(), ping, deadline)
if err != nil {
m.logger.Printf("[ERR] memberlist: Failed fallback ping: %s", err)
} else {
fallbackCh <- didContact
}
}()
} else {
close(fallbackCh)
}
// Wait for the acks or timeout. Note that we don't check the fallback
// channel here because we want to issue a warning below if that's the
// *only* way we hear back from the peer, so we have to let this time
// out first to allow the normal UDP-based acks to come in.
select {
case v := <-ackCh:
if v.Complete == true {
return
}
}
// Finally, poll the fallback channel. The timeouts are set such that
// the channel will have something or be closed without having to wait
// any additional time here.
for didContact := range fallbackCh {
if didContact {
m.logger.Printf("[WARN] memberlist: Was able to connect to %s but other probes failed, network may be misconfigured", node.Name)
return
}
}
// Update our self-awareness based on the results of this failed probe.
// If we don't have peers who will send nacks then we penalize for any
// failed probe as a simple health metric. If we do have peers to nack
// verify, then we can use that as a more sophisticated measure of self-
// health because we assume them to be working, and they can help us
// decide if the probed node was really dead or if it was something wrong
// with ourselves.
awarenessDelta = 0
if expectedNacks > 0 {
if nackCount := len(nackCh); nackCount < expectedNacks {
awarenessDelta += (expectedNacks - nackCount)
}
} else {
awarenessDelta += 1
}
// No acks received from target, suspect it as failed.
m.logger.Printf("[INFO] memberlist: Suspect %s has failed, no acks received", node.Name)
s := suspect{Incarnation: node.Incarnation, Node: node.Name, From: m.config.Name}
m.suspectNode(&s)
}
// Ping initiates a ping to the node with the specified name.
func (m *Memberlist) Ping(node string, addr net.Addr) (time.Duration, error) {
// Prepare a ping message and setup an ack handler.
ping := ping{SeqNo: m.nextSeqNo(), Node: node}
ackCh := make(chan ackMessage, m.config.IndirectChecks+1)
m.setProbeChannels(ping.SeqNo, ackCh, nil, m.config.ProbeInterval)
// Send a ping to the node.
if err := m.encodeAndSendMsg(addr.String(), pingMsg, &ping); err != nil {
return 0, err
}
// Mark the sent time here, which should be after any pre-processing and
// system calls to do the actual send. This probably under-reports a bit,
// but it's the best we can do.
sent := time.Now()
// Wait for response or timeout.
select {
case v := <-ackCh:
if v.Complete == true {
return v.Timestamp.Sub(sent), nil
}
case <-time.After(m.config.ProbeTimeout):
// Timeout, return an error below.
}
m.logger.Printf("[DEBUG] memberlist: Failed UDP ping: %v (timeout reached)", node)
return 0, NoPingResponseError{ping.Node}
}
// resetNodes is used when the tick wraps around. It will reap the
// dead nodes and shuffle the node list.
func (m *Memberlist) resetNodes() {
m.nodeLock.Lock()
defer m.nodeLock.Unlock()
// Move dead nodes, but respect gossip to the dead interval
deadIdx := moveDeadNodes(m.nodes, m.config.GossipToTheDeadTime)
// Deregister the dead nodes
for i := deadIdx; i < len(m.nodes); i++ {
delete(m.nodeMap, m.nodes[i].Name)
m.nodes[i] = nil
}
// Trim the nodes to exclude the dead nodes
m.nodes = m.nodes[0:deadIdx]
// Update numNodes after we've trimmed the dead nodes
atomic.StoreUint32(&m.numNodes, uint32(deadIdx))
// Shuffle live nodes
shuffleNodes(m.nodes)
}
// gossip is invoked every GossipInterval period to broadcast our gossip
// messages to a few random nodes.
func (m *Memberlist) gossip() {
defer metrics.MeasureSince([]string{"memberlist", "gossip"}, time.Now())
// Get some random live, suspect, or recently dead nodes
m.nodeLock.RLock()
kNodes := kRandomNodes(m.config.GossipNodes, m.nodes, func(n *nodeState) bool {
if n.Name == m.config.Name {
return true
}
switch n.State {
case stateAlive, stateSuspect:
return false
case stateDead:
return time.Since(n.StateChange) > m.config.GossipToTheDeadTime
default:
return true
}
})
m.nodeLock.RUnlock()
// Compute the bytes available
bytesAvail := m.config.UDPBufferSize - compoundHeaderOverhead
if m.config.EncryptionEnabled() {
bytesAvail -= encryptOverhead(m.encryptionVersion())
}
for _, node := range kNodes {
// Get any pending broadcasts
msgs := m.getBroadcasts(compoundOverhead, bytesAvail)
if len(msgs) == 0 {
return
}
addr := node.Address()
if len(msgs) == 1 {
// Send single message as is
if err := m.rawSendMsgPacket(addr, &node.Node, msgs[0]); err != nil {
m.logger.Printf("[ERR] memberlist: Failed to send gossip to %s: %s", addr, err)
}
} else {
// Otherwise create and send a compound message
compound := makeCompoundMessage(msgs)
if err := m.rawSendMsgPacket(addr, &node.Node, compound.Bytes()); err != nil {
m.logger.Printf("[ERR] memberlist: Failed to send gossip to %s: %s", addr, err)
}
}
}
}
// pushPull is invoked periodically to randomly perform a complete state
// exchange. Used to ensure a high level of convergence, but is also
// reasonably expensive as the entire state of this node is exchanged
// with the other node.
func (m *Memberlist) pushPull() {
// Get a random live node
m.nodeLock.RLock()
nodes := kRandomNodes(1, m.nodes, func(n *nodeState) bool {
return n.Name == m.config.Name ||
n.State != stateAlive
})
m.nodeLock.RUnlock()
// If no nodes, bail
if len(nodes) == 0 {
return
}
node := nodes[0]
// Attempt a push pull
if err := m.pushPullNode(node.Address(), false); err != nil {
m.logger.Printf("[ERR] memberlist: Push/Pull with %s failed: %s", node.Name, err)
}
}
// pushPullNode does a complete state exchange with a specific node.
func (m *Memberlist) pushPullNode(addr string, join bool) error {
defer metrics.MeasureSince([]string{"memberlist", "pushPullNode"}, time.Now())
// Attempt to send and receive with the node
remote, userState, err := m.sendAndReceiveState(addr, join)
if err != nil {
return err
}
if err := m.mergeRemoteState(join, remote, userState); err != nil {
return err
}
return nil
}
// verifyProtocol verifies that all the remote nodes can speak with our
// nodes and vice versa on both the core protocol as well as the
// delegate protocol level.
//
// The verification works by finding the maximum minimum and
// minimum maximum understood protocol and delegate versions. In other words,
// it finds the common denominator of protocol and delegate version ranges
// for the entire cluster.
//
// After this, it goes through the entire cluster (local and remote) and
// verifies that everyone's speaking protocol versions satisfy this range.
// If this passes, it means that every node can understand each other.
func (m *Memberlist) verifyProtocol(remote []pushNodeState) error {
m.nodeLock.RLock()
defer m.nodeLock.RUnlock()
// Maximum minimum understood and minimum maximum understood for both
// the protocol and delegate versions. We use this to verify everyone
// can be understood.
var maxpmin, minpmax uint8
var maxdmin, mindmax uint8
minpmax = math.MaxUint8
mindmax = math.MaxUint8
for _, rn := range remote {
// If the node isn't alive, then skip it
if rn.State != stateAlive {
continue
}
// Skip nodes that don't have versions set, it just means
// their version is zero.
if len(rn.Vsn) == 0 {
continue
}
if rn.Vsn[0] > maxpmin {
maxpmin = rn.Vsn[0]
}
if rn.Vsn[1] < minpmax {
minpmax = rn.Vsn[1]
}
if rn.Vsn[3] > maxdmin {
maxdmin = rn.Vsn[3]
}
if rn.Vsn[4] < mindmax {
mindmax = rn.Vsn[4]
}
}
for _, n := range m.nodes {
// Ignore non-alive nodes
if n.State != stateAlive {
continue
}
if n.PMin > maxpmin {
maxpmin = n.PMin
}
if n.PMax < minpmax {
minpmax = n.PMax
}
if n.DMin > maxdmin {
maxdmin = n.DMin
}
if n.DMax < mindmax {
mindmax = n.DMax
}
}
// Now that we definitively know the minimum and maximum understood
// version that satisfies the whole cluster, we verify that every
// node in the cluster satisifies this.
for _, n := range remote {
var nPCur, nDCur uint8
if len(n.Vsn) > 0 {
nPCur = n.Vsn[2]
nDCur = n.Vsn[5]
}
if nPCur < maxpmin || nPCur > minpmax {
return fmt.Errorf(
"Node '%s' protocol version (%d) is incompatible: [%d, %d]",
n.Name, nPCur, maxpmin, minpmax)
}
if nDCur < maxdmin || nDCur > mindmax {
return fmt.Errorf(
"Node '%s' delegate protocol version (%d) is incompatible: [%d, %d]",
n.Name, nDCur, maxdmin, mindmax)
}
}
for _, n := range m.nodes {
nPCur := n.PCur
nDCur := n.DCur
if nPCur < maxpmin || nPCur > minpmax {
return fmt.Errorf(
"Node '%s' protocol version (%d) is incompatible: [%d, %d]",
n.Name, nPCur, maxpmin, minpmax)
}
if nDCur < maxdmin || nDCur > mindmax {
return fmt.Errorf(
"Node '%s' delegate protocol version (%d) is incompatible: [%d, %d]",
n.Name, nDCur, maxdmin, mindmax)
}
}
return nil
}
// nextSeqNo returns a usable sequence number in a thread safe way
func (m *Memberlist) nextSeqNo() uint32 {
return atomic.AddUint32(&m.sequenceNum, 1)
}
// nextIncarnation returns the next incarnation number in a thread safe way
func (m *Memberlist) nextIncarnation() uint32 {
return atomic.AddUint32(&m.incarnation, 1)
}
// skipIncarnation adds the positive offset to the incarnation number.
func (m *Memberlist) skipIncarnation(offset uint32) uint32 {
return atomic.AddUint32(&m.incarnation, offset)
}
// estNumNodes is used to get the current estimate of the number of nodes
func (m *Memberlist) estNumNodes() int {
return int(atomic.LoadUint32(&m.numNodes))
}
type ackMessage struct {
Complete bool
Payload []byte
Timestamp time.Time
}
// setProbeChannels is used to attach the ackCh to receive a message when an ack
// with a given sequence number is received. The `complete` field of the message
// will be false on timeout. Any nack messages will cause an empty struct to be
// passed to the nackCh, which can be nil if not needed.
func (m *Memberlist) setProbeChannels(seqNo uint32, ackCh chan ackMessage, nackCh chan struct{}, timeout time.Duration) {
// Create handler functions for acks and nacks
ackFn := func(payload []byte, timestamp time.Time) {
select {
case ackCh <- ackMessage{true, payload, timestamp}:
default:
}
}
nackFn := func() {
select {
case nackCh <- struct{}{}:
default:
}
}
// Add the handlers
ah := &ackHandler{ackFn, nackFn, nil}
m.ackLock.Lock()
m.ackHandlers[seqNo] = ah
m.ackLock.Unlock()
// Setup a reaping routing
ah.timer = time.AfterFunc(timeout, func() {
m.ackLock.Lock()
delete(m.ackHandlers, seqNo)
m.ackLock.Unlock()
select {
case ackCh <- ackMessage{false, nil, time.Now()}:
default:
}
})
}
// setAckHandler is used to attach a handler to be invoked when an ack with a
// given sequence number is received. If a timeout is reached, the handler is
// deleted. This is used for indirect pings so does not configure a function
// for nacks.
func (m *Memberlist) setAckHandler(seqNo uint32, ackFn func([]byte, time.Time), timeout time.Duration) {
// Add the handler
ah := &ackHandler{ackFn, nil, nil}
m.ackLock.Lock()
m.ackHandlers[seqNo] = ah
m.ackLock.Unlock()
// Setup a reaping routing
ah.timer = time.AfterFunc(timeout, func() {
m.ackLock.Lock()
delete(m.ackHandlers, seqNo)
m.ackLock.Unlock()
})
}
// Invokes an ack handler if any is associated, and reaps the handler immediately
func (m *Memberlist) invokeAckHandler(ack ackResp, timestamp time.Time) {
m.ackLock.Lock()
ah, ok := m.ackHandlers[ack.SeqNo]
delete(m.ackHandlers, ack.SeqNo)
m.ackLock.Unlock()
if !ok {
return
}
ah.timer.Stop()
ah.ackFn(ack.Payload, timestamp)
}
// Invokes nack handler if any is associated.
func (m *Memberlist) invokeNackHandler(nack nackResp) {
m.ackLock.Lock()
ah, ok := m.ackHandlers[nack.SeqNo]
m.ackLock.Unlock()
if !ok || ah.nackFn == nil {
return
}
ah.nackFn()
}
// refute gossips an alive message in response to incoming information that we
// are suspect or dead. It will make sure the incarnation number beats the given
// accusedInc value, or you can supply 0 to just get the next incarnation number.
// This alters the node state that's passed in so this MUST be called while the
// nodeLock is held.
func (m *Memberlist) refute(me *nodeState, accusedInc uint32) {
// Make sure the incarnation number beats the accusation.
inc := m.nextIncarnation()
if accusedInc >= inc {
inc = m.skipIncarnation(accusedInc - inc + 1)
}
me.Incarnation = inc
// Decrease our health because we are being asked to refute a problem.
m.awareness.ApplyDelta(1)
// Format and broadcast an alive message.
a := alive{
Incarnation: inc,
Node: me.Name,
Addr: me.Addr,
Port: me.Port,
Meta: me.Meta,
Vsn: []uint8{
me.PMin, me.PMax, me.PCur,
me.DMin, me.DMax, me.DCur,
},
}
m.encodeAndBroadcast(me.Addr.String(), aliveMsg, a)
}
// aliveNode is invoked by the network layer when we get a message about a
// live node.
func (m *Memberlist) aliveNode(a *alive, notify chan struct{}, bootstrap bool) {
m.nodeLock.Lock()
defer m.nodeLock.Unlock()
state, ok := m.nodeMap[a.Node]
// It is possible that during a Leave(), there is already an aliveMsg
// in-queue to be processed but blocked by the locks above. If we let
// that aliveMsg process, it'll cause us to re-join the cluster. This
// ensures that we don't.
if m.hasLeft() && a.Node == m.config.Name {
return
}
if len(a.Vsn) >= 3 {
pMin := a.Vsn[0]
pMax := a.Vsn[1]
pCur := a.Vsn[2]
if pMin == 0 || pMax == 0 || pMin > pMax {
m.logger.Printf("[WARN] memberlist: Ignoring an alive message for '%s' (%v:%d) because protocol version(s) are wrong: %d <= %d <= %d should be >0", a.Node, net.IP(a.Addr), a.Port, pMin, pCur, pMax)
return
}
}
// Invoke the Alive delegate if any. This can be used to filter out
// alive messages based on custom logic. For example, using a cluster name.
// Using a merge delegate is not enough, as it is possible for passive
// cluster merging to still occur.
if m.config.Alive != nil {
if len(a.Vsn) < 6 {
m.logger.Printf("[WARN] memberlist: ignoring alive message for '%s' (%v:%d) because Vsn is not present",
a.Node, net.IP(a.Addr), a.Port)
return
}
node := &Node{
Name: a.Node,
Addr: a.Addr,
Port: a.Port,
Meta: a.Meta,
PMin: a.Vsn[0],
PMax: a.Vsn[1],
PCur: a.Vsn[2],
DMin: a.Vsn[3],
DMax: a.Vsn[4],
DCur: a.Vsn[5],
}
if err := m.config.Alive.NotifyAlive(node); err != nil {
m.logger.Printf("[WARN] memberlist: ignoring alive message for '%s': %s",
a.Node, err)
return
}
}
// Check if we've never seen this node before, and if not, then
// store this node in our node map.
var updatesNode bool
if !ok {
state = &nodeState{
Node: Node{
Name: a.Node,
Addr: a.Addr,
Port: a.Port,
Meta: a.Meta,
},
State: stateDead,
}
if len(a.Vsn) > 5 {
state.PMin = a.Vsn[0]
state.PMax = a.Vsn[1]
state.PCur = a.Vsn[2]
state.DMin = a.Vsn[3]
state.DMax = a.Vsn[4]
state.DCur = a.Vsn[5]
}
// Add to map
m.nodeMap[a.Node] = state
// Get a random offset. This is important to ensure
// the failure detection bound is low on average. If all
// nodes did an append, failure detection bound would be
// very high.
n := len(m.nodes)
offset := randomOffset(n)
// Add at the end and swap with the node at the offset
m.nodes = append(m.nodes, state)
m.nodes[offset], m.nodes[n] = m.nodes[n], m.nodes[offset]
// Update numNodes after we've added a new node
atomic.AddUint32(&m.numNodes, 1)
} else {
// Check if this address is different than the existing node unless the old node is dead.
if !bytes.Equal([]byte(state.Addr), a.Addr) || state.Port != a.Port {
// If DeadNodeReclaimTime is configured, check if enough time has elapsed since the node died.
canReclaim := (m.config.DeadNodeReclaimTime > 0 &&
time.Since(state.StateChange) > m.config.DeadNodeReclaimTime)
// Allow the address to be updated if a dead node is being replaced.
if state.State == stateDead && canReclaim {
m.logger.Printf("[INFO] memberlist: Updating address for failed node %s from %v:%d to %v:%d",
state.Name, state.Addr, state.Port, net.IP(a.Addr), a.Port)
updatesNode = true
} else {
m.logger.Printf("[ERR] memberlist: Conflicting address for %s. Mine: %v:%d Theirs: %v:%d Old state: %v",
state.Name, state.Addr, state.Port, net.IP(a.Addr), a.Port, state.State)
// Inform the conflict delegate if provided
if m.config.Conflict != nil {
other := Node{
Name: a.Node,
Addr: a.Addr,
Port: a.Port,
Meta: a.Meta,
}
m.config.Conflict.NotifyConflict(&state.Node, &other)
}
return
}
}
}
// Bail if the incarnation number is older, and this is not about us
isLocalNode := state.Name == m.config.Name
if a.Incarnation <= state.Incarnation && !isLocalNode && !updatesNode {
return
}
// Bail if strictly less and this is about us
if a.Incarnation < state.Incarnation && isLocalNode {
return
}
// Clear out any suspicion timer that may be in effect.
delete(m.nodeTimers, a.Node)
// Store the old state and meta data
oldState := state.State
oldMeta := state.Meta
// If this is us we need to refute, otherwise re-broadcast
if !bootstrap && isLocalNode {
// Compute the version vector
versions := []uint8{
state.PMin, state.PMax, state.PCur,
state.DMin, state.DMax, state.DCur,
}
// If the Incarnation is the same, we need special handling, since it
// possible for the following situation to happen:
// 1) Start with configuration C, join cluster
// 2) Hard fail / Kill / Shutdown
// 3) Restart with configuration C', join cluster
//
// In this case, other nodes and the local node see the same incarnation,
// but the values may not be the same. For this reason, we always
// need to do an equality check for this Incarnation. In most cases,
// we just ignore, but we may need to refute.
//
if a.Incarnation == state.Incarnation &&
bytes.Equal(a.Meta, state.Meta) &&
bytes.Equal(a.Vsn, versions) {