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raft.go
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raft.go
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// Copyright 2015 CoreOS, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package raft
import (
"errors"
"fmt"
"math"
"math/rand"
"sort"
"strings"
pb "github.com/coreos/etcd/raft/raftpb"
)
// None is a placeholder node ID used when there is no leader.
const None uint64 = 0
const noLimit = math.MaxUint64
var errNoLeader = errors.New("no leader")
// Possible values for StateType.
const (
StateFollower StateType = iota
StateCandidate
StateLeader
)
// StateType represents the role of a node in a cluster.
type StateType uint64
var stmap = [...]string{
"StateFollower",
"StateCandidate",
"StateLeader",
}
func (st StateType) String() string {
return stmap[uint64(st)]
}
// Config contains the parameters to start a raft.
type Config struct {
// ID is the identity of the local raft. ID cannot be 0.
ID uint64
// peers contains the IDs of all nodes (including self) in
// the raft cluster. It should only be set when starting a new
// raft cluster.
// Restarting raft from previous configuration will panic if
// peers is set.
// peer is private and only used for testing right now.
peers []uint64
// ElectionTick is the election timeout. If a follower does not
// receive any message from the leader of current term during
// ElectionTick, it will become candidate and start an election.
// ElectionTick must be greater than HeartbeatTick. We suggest
// to use ElectionTick = 10 * HeartbeatTick to avoid unnecessary
// leader switching.
ElectionTick int
// HeartbeatTick is the heartbeat interval. A leader sends heartbeat
// message to maintain the leadership every heartbeat interval.
HeartbeatTick int
// Storage is the storage for raft. raft generates entires and
// states to be stored in storage. raft reads the persisted entires
// and states out of Storage when it needs. raft reads out the previous
// state and configuration out of storage when restarting.
Storage Storage
// Applied is the last applied index. It should only be set when restarting
// raft. raft will not return entries to the application smaller or equal to Applied.
// If Applied is unset when restarting, raft might return previous applied entries.
// This is a very application dependent configuration.
Applied uint64
// MaxSizePerMsg limits the max size of each append message. Smaller value lowers
// the raft recovery cost(initial probing and message lost during normal operation).
// On the other side, it might affect the throughput during normal replication.
// Note: math.MaxUint64 for unlimited, 0 for at most one entry per message.
MaxSizePerMsg uint64
// MaxInflightMsgs limits the max number of in-flight append messages during optimistic
// replication phase. The application transportation layer usually has its own sending
// buffer over TCP/UDP. Setting MaxInflightMsgs to avoid overflowing that sending buffer.
// TODO (xiangli): feedback to application to limit the proposal rate?
MaxInflightMsgs int
// logger is the logger used for raft log. For multinode which
// can host multiple raft group, each raft group can have its
// own logger
Logger Logger
}
func (c *Config) validate() error {
if c.ID == None {
return errors.New("cannot use none as id")
}
if c.HeartbeatTick <= 0 {
return errors.New("heartbeat tick must be greater than 0")
}
if c.ElectionTick <= c.HeartbeatTick {
return errors.New("election tick must be greater than heartbeat tick")
}
if c.Storage == nil {
return errors.New("storage cannot be nil")
}
if c.MaxInflightMsgs <= 0 {
return errors.New("max inflight messages must be greater than 0")
}
if c.Logger == nil {
c.Logger = raftLogger
}
return nil
}
type raft struct {
pb.HardState
id uint64
// the log
raftLog *raftLog
maxInflight int
maxMsgSize uint64
prs map[uint64]*Progress
state StateType
votes map[uint64]bool
msgs []pb.Message
// the leader id
lead uint64
// New configuration is ignored if there exists unapplied configuration.
pendingConf bool
elapsed int // number of ticks since the last msg
heartbeatTimeout int
electionTimeout int
rand *rand.Rand
tick func()
step stepFunc
logger Logger
}
func newRaft(c *Config) *raft {
if err := c.validate(); err != nil {
panic(err.Error())
}
raftlog := newLog(c.Storage, c.Logger)
hs, cs, err := c.Storage.InitialState()
if err != nil {
panic(err) // TODO(bdarnell)
}
peers := c.peers
if len(cs.Nodes) > 0 {
if len(peers) > 0 {
// TODO(bdarnell): the peers argument is always nil except in
// tests; the argument should be removed and these tests should be
// updated to specify their nodes through a snapshot.
panic("cannot specify both newRaft(peers) and ConfState.Nodes)")
}
peers = cs.Nodes
}
r := &raft{
id: c.ID,
lead: None,
raftLog: raftlog,
// 4MB for now and hard code it
// TODO(xiang): add a config arguement into newRaft after we add
// the max inflight message field.
maxMsgSize: c.MaxSizePerMsg,
maxInflight: c.MaxInflightMsgs,
prs: make(map[uint64]*Progress),
electionTimeout: c.ElectionTick,
heartbeatTimeout: c.HeartbeatTick,
logger: c.Logger,
}
r.rand = rand.New(rand.NewSource(int64(c.ID)))
for _, p := range peers {
r.prs[p] = &Progress{Next: 1, ins: newInflights(r.maxInflight)}
}
if !isHardStateEqual(hs, emptyState) {
r.loadState(hs)
}
if c.Applied > 0 {
raftlog.appliedTo(c.Applied)
}
r.becomeFollower(r.Term, None)
nodesStrs := make([]string, 0)
for _, n := range r.nodes() {
nodesStrs = append(nodesStrs, fmt.Sprintf("%x", n))
}
r.logger.Infof("newRaft %x [peers: [%s], term: %d, commit: %d, applied: %d, lastindex: %d, lastterm: %d]",
r.id, strings.Join(nodesStrs, ","), r.Term, r.raftLog.committed, r.raftLog.applied, r.raftLog.lastIndex(), r.raftLog.lastTerm())
return r
}
func (r *raft) hasLeader() bool { return r.lead != None }
func (r *raft) softState() *SoftState { return &SoftState{Lead: r.lead, RaftState: r.state} }
func (r *raft) q() int { return len(r.prs)/2 + 1 }
func (r *raft) nodes() []uint64 {
nodes := make([]uint64, 0, len(r.prs))
for k := range r.prs {
nodes = append(nodes, k)
}
sort.Sort(uint64Slice(nodes))
return nodes
}
// send persists state to stable storage and then sends to its mailbox.
func (r *raft) send(m pb.Message) {
m.From = r.id
// do not attach term to MsgProp
// proposals are a way to forward to the leader and
// should be treated as local message.
if m.Type != pb.MsgProp {
m.Term = r.Term
}
r.msgs = append(r.msgs, m)
}
// sendAppend sends RRPC, with entries to the given peer.
func (r *raft) sendAppend(to uint64) {
pr := r.prs[to]
if pr.isPaused() {
return
}
m := pb.Message{}
m.To = to
term, errt := r.raftLog.term(pr.Next - 1)
ents, erre := r.raftLog.entries(pr.Next, r.maxMsgSize)
if errt != nil || erre != nil { // send snapshot if we failed to get term or entries
m.Type = pb.MsgSnap
snapshot, err := r.raftLog.snapshot()
if err != nil {
panic(err) // TODO(bdarnell)
}
if IsEmptySnap(snapshot) {
panic("need non-empty snapshot")
}
m.Snapshot = snapshot
sindex, sterm := snapshot.Metadata.Index, snapshot.Metadata.Term
r.logger.Infof("%x [firstindex: %d, commit: %d] sent snapshot[index: %d, term: %d] to %x [%s]",
r.id, r.raftLog.firstIndex(), r.Commit, sindex, sterm, to, pr)
pr.becomeSnapshot(sindex)
r.logger.Infof("%x paused sending replication messages to %x [%s]", r.id, to, pr)
} else {
m.Type = pb.MsgApp
m.Index = pr.Next - 1
m.LogTerm = term
m.Entries = ents
m.Commit = r.raftLog.committed
if n := len(m.Entries); n != 0 {
switch pr.State {
// optimistically increase the next when in ProgressStateReplicate
case ProgressStateReplicate:
last := m.Entries[n-1].Index
pr.optimisticUpdate(last)
pr.ins.add(last)
case ProgressStateProbe:
pr.pause()
default:
r.logger.Panicf("%x is sending append in unhandled state %s", r.id, pr.State)
}
}
}
r.send(m)
}
// sendHeartbeat sends an empty MsgApp
func (r *raft) sendHeartbeat(to uint64) {
// Attach the commit as min(to.matched, r.committed).
// When the leader sends out heartbeat message,
// the receiver(follower) might not be matched with the leader
// or it might not have all the committed entries.
// The leader MUST NOT forward the follower's commit to
// an unmatched index.
commit := min(r.prs[to].Match, r.raftLog.committed)
m := pb.Message{
To: to,
Type: pb.MsgHeartbeat,
Commit: commit,
}
r.send(m)
}
// bcastAppend sends RRPC, with entries to all peers that are not up-to-date
// according to the progress recorded in r.prs.
func (r *raft) bcastAppend() {
for i := range r.prs {
if i == r.id {
continue
}
r.sendAppend(i)
}
}
// bcastHeartbeat sends RRPC, without entries to all the peers.
func (r *raft) bcastHeartbeat() {
for i := range r.prs {
if i == r.id {
continue
}
r.sendHeartbeat(i)
r.prs[i].resume()
}
}
func (r *raft) maybeCommit() bool {
// TODO(bmizerany): optimize.. Currently naive
mis := make(uint64Slice, 0, len(r.prs))
for i := range r.prs {
mis = append(mis, r.prs[i].Match)
}
sort.Sort(sort.Reverse(mis))
mci := mis[r.q()-1]
return r.raftLog.maybeCommit(mci, r.Term)
}
func (r *raft) reset(term uint64) {
if r.Term != term {
r.Term = term
r.Vote = None
}
r.lead = None
r.elapsed = 0
r.votes = make(map[uint64]bool)
for i := range r.prs {
r.prs[i] = &Progress{Next: r.raftLog.lastIndex() + 1, ins: newInflights(r.maxInflight)}
if i == r.id {
r.prs[i].Match = r.raftLog.lastIndex()
}
}
r.pendingConf = false
}
func (r *raft) appendEntry(es ...pb.Entry) {
li := r.raftLog.lastIndex()
for i := range es {
es[i].Term = r.Term
es[i].Index = li + 1 + uint64(i)
}
r.raftLog.append(es...)
r.prs[r.id].maybeUpdate(r.raftLog.lastIndex())
r.maybeCommit()
}
// tickElection is run by followers and candidates after r.electionTimeout.
func (r *raft) tickElection() {
if !r.promotable() {
r.elapsed = 0
return
}
r.elapsed++
if r.isElectionTimeout() {
r.elapsed = 0
r.Step(pb.Message{From: r.id, Type: pb.MsgHup})
}
}
// tickHeartbeat is run by leaders to send a MsgBeat after r.heartbeatTimeout.
func (r *raft) tickHeartbeat() {
r.elapsed++
if r.elapsed >= r.heartbeatTimeout {
r.elapsed = 0
r.Step(pb.Message{From: r.id, Type: pb.MsgBeat})
}
}
func (r *raft) becomeFollower(term uint64, lead uint64) {
r.step = stepFollower
r.reset(term)
r.tick = r.tickElection
r.lead = lead
r.state = StateFollower
r.logger.Infof("%x became follower at term %d", r.id, r.Term)
}
func (r *raft) becomeCandidate() {
// TODO(xiangli) remove the panic when the raft implementation is stable
if r.state == StateLeader {
panic("invalid transition [leader -> candidate]")
}
r.step = stepCandidate
r.reset(r.Term + 1)
r.tick = r.tickElection
r.Vote = r.id
r.state = StateCandidate
r.logger.Infof("%x became candidate at term %d", r.id, r.Term)
}
func (r *raft) becomeLeader() {
// TODO(xiangli) remove the panic when the raft implementation is stable
if r.state == StateFollower {
panic("invalid transition [follower -> leader]")
}
r.step = stepLeader
r.reset(r.Term)
r.tick = r.tickHeartbeat
r.lead = r.id
r.state = StateLeader
ents, err := r.raftLog.entries(r.raftLog.committed+1, noLimit)
if err != nil {
r.logger.Panicf("unexpected error getting uncommitted entries (%v)", err)
}
for _, e := range ents {
if e.Type != pb.EntryConfChange {
continue
}
if r.pendingConf {
panic("unexpected double uncommitted config entry")
}
r.pendingConf = true
}
r.appendEntry(pb.Entry{Data: nil})
r.logger.Infof("%x became leader at term %d", r.id, r.Term)
}
func (r *raft) campaign() {
r.becomeCandidate()
if r.q() == r.poll(r.id, true) {
r.becomeLeader()
return
}
for i := range r.prs {
if i == r.id {
continue
}
r.logger.Infof("%x [logterm: %d, index: %d] sent vote request to %x at term %d",
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), i, r.Term)
r.send(pb.Message{To: i, Type: pb.MsgVote, Index: r.raftLog.lastIndex(), LogTerm: r.raftLog.lastTerm()})
}
}
func (r *raft) poll(id uint64, v bool) (granted int) {
if v {
r.logger.Infof("%x received vote from %x at term %d", r.id, id, r.Term)
} else {
r.logger.Infof("%x received vote rejection from %x at term %d", r.id, id, r.Term)
}
if _, ok := r.votes[id]; !ok {
r.votes[id] = v
}
for _, vv := range r.votes {
if vv {
granted++
}
}
return granted
}
func (r *raft) Step(m pb.Message) error {
if m.Type == pb.MsgHup {
r.logger.Infof("%x is starting a new election at term %d", r.id, r.Term)
r.campaign()
r.Commit = r.raftLog.committed
return nil
}
switch {
case m.Term == 0:
// local message
case m.Term > r.Term:
lead := m.From
if m.Type == pb.MsgVote {
lead = None
}
r.logger.Infof("%x [term: %d] received a %s message with higher term from %x [term: %d]",
r.id, r.Term, m.Type, m.From, m.Term)
r.becomeFollower(m.Term, lead)
case m.Term < r.Term:
// ignore
r.logger.Infof("%x [term: %d] ignored a %s message with lower term from %x [term: %d]",
r.id, r.Term, m.Type, m.From, m.Term)
return nil
}
r.step(r, m)
r.Commit = r.raftLog.committed
return nil
}
type stepFunc func(r *raft, m pb.Message)
func stepLeader(r *raft, m pb.Message) {
pr := r.prs[m.From]
switch m.Type {
case pb.MsgBeat:
r.bcastHeartbeat()
case pb.MsgProp:
if len(m.Entries) == 0 {
r.logger.Panicf("%x stepped empty MsgProp", r.id)
}
for i, e := range m.Entries {
if e.Type == pb.EntryConfChange {
if r.pendingConf {
m.Entries[i] = pb.Entry{Type: pb.EntryNormal}
}
r.pendingConf = true
}
}
r.appendEntry(m.Entries...)
r.bcastAppend()
case pb.MsgAppResp:
if m.Reject {
r.logger.Debugf("%x received msgApp rejection(lastindex: %d) from %x for index %d",
r.id, m.RejectHint, m.From, m.Index)
if pr.maybeDecrTo(m.Index, m.RejectHint) {
r.logger.Debugf("%x decreased progress of %x to [%s]", r.id, m.From, pr)
if pr.State == ProgressStateReplicate {
pr.becomeProbe()
}
r.sendAppend(m.From)
}
} else {
oldPaused := pr.isPaused()
if pr.maybeUpdate(m.Index) {
switch {
case pr.State == ProgressStateProbe:
pr.becomeReplicate()
case pr.State == ProgressStateSnapshot && pr.maybeSnapshotAbort():
r.logger.Infof("%x snapshot aborted, resumed sending replication messages to %x [%s]", r.id, m.From, pr)
pr.becomeProbe()
case pr.State == ProgressStateReplicate:
pr.ins.freeTo(m.Index)
}
if r.maybeCommit() {
r.bcastAppend()
} else if oldPaused {
// update() reset the wait state on this node. If we had delayed sending
// an update before, send it now.
r.sendAppend(m.From)
}
}
}
case pb.MsgHeartbeatResp:
// free one slot for the full inflights window to allow progress.
if pr.State == ProgressStateReplicate && pr.ins.full() {
pr.ins.freeFirstOne()
}
if pr.Match < r.raftLog.lastIndex() {
r.sendAppend(m.From)
}
case pb.MsgVote:
r.logger.Infof("%x [logterm: %d, index: %d, vote: %x] rejected vote from %x [logterm: %d, index: %d] at term %d",
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), r.Vote, m.From, m.LogTerm, m.Index, r.Term)
r.send(pb.Message{To: m.From, Type: pb.MsgVoteResp, Reject: true})
case pb.MsgSnapStatus:
if pr.State != ProgressStateSnapshot {
return
}
if !m.Reject {
pr.becomeProbe()
r.logger.Infof("%x snapshot succeeded, resumed sending replication messages to %x [%s]", r.id, m.From, pr)
} else {
pr.snapshotFailure()
pr.becomeProbe()
r.logger.Infof("%x snapshot failed, resumed sending replication messages to %x [%s]", r.id, m.From, pr)
}
// If snapshot finish, wait for the msgAppResp from the remote node before sending
// out the next msgApp.
// If snapshot failure, wait for a heartbeat interval before next try
pr.pause()
case pb.MsgUnreachable:
// During optimistic replication, if the remote becomes unreachable,
// there is huge probability that a MsgApp is lost.
if pr.State == ProgressStateReplicate {
pr.becomeProbe()
}
r.logger.Debugf("%x failed to send message to %x because it is unreachable [%s]", r.id, m.From, pr)
}
}
func stepCandidate(r *raft, m pb.Message) {
switch m.Type {
case pb.MsgProp:
r.logger.Infof("%x no leader at term %d; dropping proposal", r.id, r.Term)
return
case pb.MsgApp:
r.becomeFollower(r.Term, m.From)
r.handleAppendEntries(m)
case pb.MsgHeartbeat:
r.becomeFollower(r.Term, m.From)
r.handleHeartbeat(m)
case pb.MsgSnap:
r.becomeFollower(m.Term, m.From)
r.handleSnapshot(m)
case pb.MsgVote:
r.logger.Infof("%x [logterm: %d, index: %d, vote: %x] rejected vote from %x [logterm: %d, index: %d] at term %x",
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), r.Vote, m.From, m.LogTerm, m.Index, r.Term)
r.send(pb.Message{To: m.From, Type: pb.MsgVoteResp, Reject: true})
case pb.MsgVoteResp:
gr := r.poll(m.From, !m.Reject)
r.logger.Infof("%x [q:%d] has received %d votes and %d vote rejections", r.id, r.q(), gr, len(r.votes)-gr)
switch r.q() {
case gr:
r.becomeLeader()
r.bcastAppend()
case len(r.votes) - gr:
r.becomeFollower(r.Term, None)
}
}
}
func stepFollower(r *raft, m pb.Message) {
switch m.Type {
case pb.MsgProp:
if r.lead == None {
r.logger.Infof("%x no leader at term %d; dropping proposal", r.id, r.Term)
return
}
m.To = r.lead
r.send(m)
case pb.MsgApp:
r.elapsed = 0
r.lead = m.From
r.handleAppendEntries(m)
case pb.MsgHeartbeat:
r.elapsed = 0
r.lead = m.From
r.handleHeartbeat(m)
case pb.MsgSnap:
r.elapsed = 0
r.handleSnapshot(m)
case pb.MsgVote:
if (r.Vote == None || r.Vote == m.From) && r.raftLog.isUpToDate(m.Index, m.LogTerm) {
r.elapsed = 0
r.logger.Infof("%x [logterm: %d, index: %d, vote: %x] voted for %x [logterm: %d, index: %d] at term %d",
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), r.Vote, m.From, m.LogTerm, m.Index, r.Term)
r.Vote = m.From
r.send(pb.Message{To: m.From, Type: pb.MsgVoteResp})
} else {
r.logger.Infof("%x [logterm: %d, index: %d, vote: %x] rejected vote from %x [logterm: %d, index: %d] at term %d",
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), r.Vote, m.From, m.LogTerm, m.Index, r.Term)
r.send(pb.Message{To: m.From, Type: pb.MsgVoteResp, Reject: true})
}
}
}
func (r *raft) handleAppendEntries(m pb.Message) {
if m.Index < r.Commit {
r.send(pb.Message{To: m.From, Type: pb.MsgAppResp, Index: r.Commit})
return
}
if mlastIndex, ok := r.raftLog.maybeAppend(m.Index, m.LogTerm, m.Commit, m.Entries...); ok {
r.send(pb.Message{To: m.From, Type: pb.MsgAppResp, Index: mlastIndex})
} else {
r.logger.Debugf("%x [logterm: %d, index: %d] rejected msgApp [logterm: %d, index: %d] from %x",
r.id, r.raftLog.zeroTermOnErrCompacted(r.raftLog.term(m.Index)), m.Index, m.LogTerm, m.Index, m.From)
r.send(pb.Message{To: m.From, Type: pb.MsgAppResp, Index: m.Index, Reject: true, RejectHint: r.raftLog.lastIndex()})
}
}
func (r *raft) handleHeartbeat(m pb.Message) {
r.raftLog.commitTo(m.Commit)
r.send(pb.Message{To: m.From, Type: pb.MsgHeartbeatResp})
}
func (r *raft) handleSnapshot(m pb.Message) {
sindex, sterm := m.Snapshot.Metadata.Index, m.Snapshot.Metadata.Term
if r.restore(m.Snapshot) {
r.logger.Infof("%x [commit: %d] restored snapshot [index: %d, term: %d]",
r.id, r.Commit, sindex, sterm)
r.send(pb.Message{To: m.From, Type: pb.MsgAppResp, Index: r.raftLog.lastIndex()})
} else {
r.logger.Infof("%x [commit: %d] ignored snapshot [index: %d, term: %d]",
r.id, r.Commit, sindex, sterm)
r.send(pb.Message{To: m.From, Type: pb.MsgAppResp, Index: r.raftLog.committed})
}
}
// restore recovers the state machine from a snapshot. It restores the log and the
// configuration of state machine.
func (r *raft) restore(s pb.Snapshot) bool {
if s.Metadata.Index <= r.raftLog.committed {
return false
}
if r.raftLog.matchTerm(s.Metadata.Index, s.Metadata.Term) {
r.logger.Infof("%x [commit: %d, lastindex: %d, lastterm: %d] fast-forwarded commit to snapshot [index: %d, term: %d]",
r.id, r.Commit, r.raftLog.lastIndex(), r.raftLog.lastTerm(), s.Metadata.Index, s.Metadata.Term)
r.raftLog.commitTo(s.Metadata.Index)
return false
}
r.logger.Infof("%x [commit: %d, lastindex: %d, lastterm: %d] starts to restore snapshot [index: %d, term: %d]",
r.id, r.Commit, r.raftLog.lastIndex(), r.raftLog.lastTerm(), s.Metadata.Index, s.Metadata.Term)
r.raftLog.restore(s)
r.prs = make(map[uint64]*Progress)
for _, n := range s.Metadata.ConfState.Nodes {
match, next := uint64(0), uint64(r.raftLog.lastIndex())+1
if n == r.id {
match = next - 1
} else {
match = 0
}
r.setProgress(n, match, next)
r.logger.Infof("%x restored progress of %x [%s]", r.id, n, r.prs[n])
}
return true
}
// promotable indicates whether state machine can be promoted to leader,
// which is true when its own id is in progress list.
func (r *raft) promotable() bool {
_, ok := r.prs[r.id]
return ok
}
func (r *raft) addNode(id uint64) {
if _, ok := r.prs[id]; ok {
// Ignore any redundant addNode calls (which can happen because the
// initial bootstrapping entries are applied twice).
return
}
r.setProgress(id, 0, r.raftLog.lastIndex()+1)
r.pendingConf = false
}
func (r *raft) removeNode(id uint64) {
r.delProgress(id)
r.pendingConf = false
}
func (r *raft) resetPendingConf() { r.pendingConf = false }
func (r *raft) setProgress(id, match, next uint64) {
r.prs[id] = &Progress{Next: next, Match: match, ins: newInflights(r.maxInflight)}
}
func (r *raft) delProgress(id uint64) {
delete(r.prs, id)
}
func (r *raft) loadState(state pb.HardState) {
if state.Commit < r.raftLog.committed || state.Commit > r.raftLog.lastIndex() {
r.logger.Panicf("%x state.commit %d is out of range [%d, %d]", r.id, state.Commit, r.raftLog.committed, r.raftLog.lastIndex())
}
r.raftLog.committed = state.Commit
r.Term = state.Term
r.Vote = state.Vote
r.Commit = state.Commit
}
// isElectionTimeout returns true if r.elapsed is greater than the
// randomized election timeout in (electiontimeout, 2 * electiontimeout - 1).
// Otherwise, it returns false.
func (r *raft) isElectionTimeout() bool {
d := r.elapsed - r.electionTimeout
if d < 0 {
return false
}
return d > r.rand.Int()%r.electionTimeout
}