mirror of
https://github.com/moby/moby.git
synced 2022-11-09 12:21:53 -05:00
06c797f517
Signed-off-by: Cory Snider <csnider@mirantis.com>
1837 lines
64 KiB
Go
1837 lines
64 KiB
Go
// Copyright 2015 The etcd Authors
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package raft
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import (
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"bytes"
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"errors"
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"fmt"
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"math"
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"math/rand"
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"sort"
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"strings"
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"sync"
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"time"
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"go.etcd.io/etcd/raft/v3/confchange"
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"go.etcd.io/etcd/raft/v3/quorum"
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pb "go.etcd.io/etcd/raft/v3/raftpb"
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"go.etcd.io/etcd/raft/v3/tracker"
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)
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// None is a placeholder node ID used when there is no leader.
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const None uint64 = 0
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const noLimit = math.MaxUint64
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// Possible values for StateType.
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const (
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StateFollower StateType = iota
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StateCandidate
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StateLeader
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StatePreCandidate
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numStates
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)
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type ReadOnlyOption int
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const (
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// ReadOnlySafe guarantees the linearizability of the read only request by
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// communicating with the quorum. It is the default and suggested option.
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ReadOnlySafe ReadOnlyOption = iota
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// ReadOnlyLeaseBased ensures linearizability of the read only request by
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// relying on the leader lease. It can be affected by clock drift.
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// If the clock drift is unbounded, leader might keep the lease longer than it
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// should (clock can move backward/pause without any bound). ReadIndex is not safe
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// in that case.
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ReadOnlyLeaseBased
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)
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// Possible values for CampaignType
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const (
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// campaignPreElection represents the first phase of a normal election when
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// Config.PreVote is true.
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campaignPreElection CampaignType = "CampaignPreElection"
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// campaignElection represents a normal (time-based) election (the second phase
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// of the election when Config.PreVote is true).
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campaignElection CampaignType = "CampaignElection"
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// campaignTransfer represents the type of leader transfer
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campaignTransfer CampaignType = "CampaignTransfer"
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)
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// ErrProposalDropped is returned when the proposal is ignored by some cases,
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// so that the proposer can be notified and fail fast.
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var ErrProposalDropped = errors.New("raft proposal dropped")
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// lockedRand is a small wrapper around rand.Rand to provide
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// synchronization among multiple raft groups. Only the methods needed
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// by the code are exposed (e.g. Intn).
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type lockedRand struct {
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mu sync.Mutex
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rand *rand.Rand
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}
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func (r *lockedRand) Intn(n int) int {
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r.mu.Lock()
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v := r.rand.Intn(n)
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r.mu.Unlock()
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return v
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}
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var globalRand = &lockedRand{
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rand: rand.New(rand.NewSource(time.Now().UnixNano())),
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}
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// CampaignType represents the type of campaigning
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// the reason we use the type of string instead of uint64
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// is because it's simpler to compare and fill in raft entries
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type CampaignType string
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// StateType represents the role of a node in a cluster.
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type StateType uint64
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var stmap = [...]string{
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"StateFollower",
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"StateCandidate",
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"StateLeader",
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"StatePreCandidate",
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}
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func (st StateType) String() string {
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return stmap[uint64(st)]
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}
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// Config contains the parameters to start a raft.
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type Config struct {
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// ID is the identity of the local raft. ID cannot be 0.
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ID uint64
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// ElectionTick is the number of Node.Tick invocations that must pass between
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// elections. That is, if a follower does not receive any message from the
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// leader of current term before ElectionTick has elapsed, it will become
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// candidate and start an election. ElectionTick must be greater than
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// HeartbeatTick. We suggest ElectionTick = 10 * HeartbeatTick to avoid
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// unnecessary leader switching.
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ElectionTick int
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// HeartbeatTick is the number of Node.Tick invocations that must pass between
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// heartbeats. That is, a leader sends heartbeat messages to maintain its
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// leadership every HeartbeatTick ticks.
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HeartbeatTick int
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// Storage is the storage for raft. raft generates entries and states to be
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// stored in storage. raft reads the persisted entries and states out of
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// Storage when it needs. raft reads out the previous state and configuration
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// out of storage when restarting.
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Storage Storage
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// Applied is the last applied index. It should only be set when restarting
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// raft. raft will not return entries to the application smaller or equal to
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// Applied. If Applied is unset when restarting, raft might return previous
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// applied entries. This is a very application dependent configuration.
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Applied uint64
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// MaxSizePerMsg limits the max byte size of each append message. Smaller
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// value lowers the raft recovery cost(initial probing and message lost
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// during normal operation). On the other side, it might affect the
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// throughput during normal replication. Note: math.MaxUint64 for unlimited,
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// 0 for at most one entry per message.
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MaxSizePerMsg uint64
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// MaxCommittedSizePerReady limits the size of the committed entries which
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// can be applied.
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MaxCommittedSizePerReady uint64
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// MaxUncommittedEntriesSize limits the aggregate byte size of the
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// uncommitted entries that may be appended to a leader's log. Once this
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// limit is exceeded, proposals will begin to return ErrProposalDropped
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// errors. Note: 0 for no limit.
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MaxUncommittedEntriesSize uint64
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// MaxInflightMsgs limits the max number of in-flight append messages during
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// optimistic replication phase. The application transportation layer usually
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// has its own sending buffer over TCP/UDP. Setting MaxInflightMsgs to avoid
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// overflowing that sending buffer. TODO (xiangli): feedback to application to
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// limit the proposal rate?
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MaxInflightMsgs int
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// CheckQuorum specifies if the leader should check quorum activity. Leader
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// steps down when quorum is not active for an electionTimeout.
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CheckQuorum bool
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// PreVote enables the Pre-Vote algorithm described in raft thesis section
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// 9.6. This prevents disruption when a node that has been partitioned away
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// rejoins the cluster.
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PreVote bool
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// ReadOnlyOption specifies how the read only request is processed.
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//
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// ReadOnlySafe guarantees the linearizability of the read only request by
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// communicating with the quorum. It is the default and suggested option.
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//
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// ReadOnlyLeaseBased ensures linearizability of the read only request by
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// relying on the leader lease. It can be affected by clock drift.
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// If the clock drift is unbounded, leader might keep the lease longer than it
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// should (clock can move backward/pause without any bound). ReadIndex is not safe
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// in that case.
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// CheckQuorum MUST be enabled if ReadOnlyOption is ReadOnlyLeaseBased.
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ReadOnlyOption ReadOnlyOption
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// Logger is the logger used for raft log. For multinode which can host
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// multiple raft group, each raft group can have its own logger
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Logger Logger
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// DisableProposalForwarding set to true means that followers will drop
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// proposals, rather than forwarding them to the leader. One use case for
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// this feature would be in a situation where the Raft leader is used to
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// compute the data of a proposal, for example, adding a timestamp from a
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// hybrid logical clock to data in a monotonically increasing way. Forwarding
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// should be disabled to prevent a follower with an inaccurate hybrid
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// logical clock from assigning the timestamp and then forwarding the data
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// to the leader.
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DisableProposalForwarding bool
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}
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func (c *Config) validate() error {
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if c.ID == None {
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return errors.New("cannot use none as id")
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}
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if c.HeartbeatTick <= 0 {
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return errors.New("heartbeat tick must be greater than 0")
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}
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if c.ElectionTick <= c.HeartbeatTick {
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return errors.New("election tick must be greater than heartbeat tick")
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}
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if c.Storage == nil {
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return errors.New("storage cannot be nil")
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}
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if c.MaxUncommittedEntriesSize == 0 {
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c.MaxUncommittedEntriesSize = noLimit
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}
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// default MaxCommittedSizePerReady to MaxSizePerMsg because they were
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// previously the same parameter.
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if c.MaxCommittedSizePerReady == 0 {
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c.MaxCommittedSizePerReady = c.MaxSizePerMsg
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}
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if c.MaxInflightMsgs <= 0 {
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return errors.New("max inflight messages must be greater than 0")
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}
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if c.Logger == nil {
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c.Logger = getLogger()
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}
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if c.ReadOnlyOption == ReadOnlyLeaseBased && !c.CheckQuorum {
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return errors.New("CheckQuorum must be enabled when ReadOnlyOption is ReadOnlyLeaseBased")
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}
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return nil
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}
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type raft struct {
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id uint64
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Term uint64
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Vote uint64
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readStates []ReadState
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// the log
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raftLog *raftLog
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maxMsgSize uint64
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maxUncommittedSize uint64
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// TODO(tbg): rename to trk.
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prs tracker.ProgressTracker
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state StateType
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// isLearner is true if the local raft node is a learner.
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isLearner bool
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msgs []pb.Message
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// the leader id
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lead uint64
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// leadTransferee is id of the leader transfer target when its value is not zero.
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// Follow the procedure defined in raft thesis 3.10.
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leadTransferee uint64
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// Only one conf change may be pending (in the log, but not yet
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// applied) at a time. This is enforced via pendingConfIndex, which
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// is set to a value >= the log index of the latest pending
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// configuration change (if any). Config changes are only allowed to
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// be proposed if the leader's applied index is greater than this
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// value.
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pendingConfIndex uint64
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// an estimate of the size of the uncommitted tail of the Raft log. Used to
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// prevent unbounded log growth. Only maintained by the leader. Reset on
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// term changes.
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uncommittedSize uint64
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readOnly *readOnly
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// number of ticks since it reached last electionTimeout when it is leader
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// or candidate.
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// number of ticks since it reached last electionTimeout or received a
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// valid message from current leader when it is a follower.
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electionElapsed int
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// number of ticks since it reached last heartbeatTimeout.
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// only leader keeps heartbeatElapsed.
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heartbeatElapsed int
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checkQuorum bool
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preVote bool
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heartbeatTimeout int
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electionTimeout int
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// randomizedElectionTimeout is a random number between
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// [electiontimeout, 2 * electiontimeout - 1]. It gets reset
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// when raft changes its state to follower or candidate.
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randomizedElectionTimeout int
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disableProposalForwarding bool
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tick func()
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step stepFunc
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logger Logger
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// pendingReadIndexMessages is used to store messages of type MsgReadIndex
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// that can't be answered as new leader didn't committed any log in
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// current term. Those will be handled as fast as first log is committed in
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// current term.
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pendingReadIndexMessages []pb.Message
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}
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func newRaft(c *Config) *raft {
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if err := c.validate(); err != nil {
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panic(err.Error())
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}
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raftlog := newLogWithSize(c.Storage, c.Logger, c.MaxCommittedSizePerReady)
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hs, cs, err := c.Storage.InitialState()
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if err != nil {
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panic(err) // TODO(bdarnell)
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}
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r := &raft{
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id: c.ID,
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lead: None,
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isLearner: false,
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raftLog: raftlog,
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maxMsgSize: c.MaxSizePerMsg,
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maxUncommittedSize: c.MaxUncommittedEntriesSize,
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prs: tracker.MakeProgressTracker(c.MaxInflightMsgs),
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electionTimeout: c.ElectionTick,
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heartbeatTimeout: c.HeartbeatTick,
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logger: c.Logger,
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checkQuorum: c.CheckQuorum,
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preVote: c.PreVote,
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readOnly: newReadOnly(c.ReadOnlyOption),
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disableProposalForwarding: c.DisableProposalForwarding,
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}
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cfg, prs, err := confchange.Restore(confchange.Changer{
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Tracker: r.prs,
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LastIndex: raftlog.lastIndex(),
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}, cs)
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if err != nil {
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panic(err)
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}
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assertConfStatesEquivalent(r.logger, cs, r.switchToConfig(cfg, prs))
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if !IsEmptyHardState(hs) {
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r.loadState(hs)
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}
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if c.Applied > 0 {
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raftlog.appliedTo(c.Applied)
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}
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r.becomeFollower(r.Term, None)
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var nodesStrs []string
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for _, n := range r.prs.VoterNodes() {
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nodesStrs = append(nodesStrs, fmt.Sprintf("%x", n))
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}
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r.logger.Infof("newRaft %x [peers: [%s], term: %d, commit: %d, applied: %d, lastindex: %d, lastterm: %d]",
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r.id, strings.Join(nodesStrs, ","), r.Term, r.raftLog.committed, r.raftLog.applied, r.raftLog.lastIndex(), r.raftLog.lastTerm())
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return r
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}
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func (r *raft) hasLeader() bool { return r.lead != None }
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func (r *raft) softState() *SoftState { return &SoftState{Lead: r.lead, RaftState: r.state} }
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func (r *raft) hardState() pb.HardState {
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return pb.HardState{
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Term: r.Term,
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Vote: r.Vote,
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Commit: r.raftLog.committed,
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}
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}
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// send schedules persisting state to a stable storage and AFTER that
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// sending the message (as part of next Ready message processing).
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func (r *raft) send(m pb.Message) {
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if m.From == None {
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m.From = r.id
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}
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if m.Type == pb.MsgVote || m.Type == pb.MsgVoteResp || m.Type == pb.MsgPreVote || m.Type == pb.MsgPreVoteResp {
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if m.Term == 0 {
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// All {pre-,}campaign messages need to have the term set when
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// sending.
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// - MsgVote: m.Term is the term the node is campaigning for,
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// non-zero as we increment the term when campaigning.
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// - MsgVoteResp: m.Term is the new r.Term if the MsgVote was
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// granted, non-zero for the same reason MsgVote is
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// - MsgPreVote: m.Term is the term the node will campaign,
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// non-zero as we use m.Term to indicate the next term we'll be
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// campaigning for
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// - MsgPreVoteResp: m.Term is the term received in the original
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// MsgPreVote if the pre-vote was granted, non-zero for the
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// same reasons MsgPreVote is
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panic(fmt.Sprintf("term should be set when sending %s", m.Type))
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}
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} else {
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if m.Term != 0 {
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panic(fmt.Sprintf("term should not be set when sending %s (was %d)", m.Type, m.Term))
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}
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// do not attach term to MsgProp, MsgReadIndex
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// proposals are a way to forward to the leader and
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// should be treated as local message.
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// MsgReadIndex is also forwarded to leader.
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if m.Type != pb.MsgProp && m.Type != pb.MsgReadIndex {
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m.Term = r.Term
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}
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}
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r.msgs = append(r.msgs, m)
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}
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// sendAppend sends an append RPC with new entries (if any) and the
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// current commit index to the given peer.
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func (r *raft) sendAppend(to uint64) {
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r.maybeSendAppend(to, true)
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}
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// maybeSendAppend sends an append RPC with new entries to the given peer,
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// if necessary. Returns true if a message was sent. The sendIfEmpty
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// argument controls whether messages with no entries will be sent
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// ("empty" messages are useful to convey updated Commit indexes, but
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// are undesirable when we're sending multiple messages in a batch).
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func (r *raft) maybeSendAppend(to uint64, sendIfEmpty bool) bool {
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pr := r.prs.Progress[to]
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if pr.IsPaused() {
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return false
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}
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m := pb.Message{}
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m.To = to
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term, errt := r.raftLog.term(pr.Next - 1)
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ents, erre := r.raftLog.entries(pr.Next, r.maxMsgSize)
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if len(ents) == 0 && !sendIfEmpty {
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return false
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}
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if errt != nil || erre != nil { // send snapshot if we failed to get term or entries
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if !pr.RecentActive {
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r.logger.Debugf("ignore sending snapshot to %x since it is not recently active", to)
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return false
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}
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m.Type = pb.MsgSnap
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snapshot, err := r.raftLog.snapshot()
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if err != nil {
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if err == ErrSnapshotTemporarilyUnavailable {
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r.logger.Debugf("%x failed to send snapshot to %x because snapshot is temporarily unavailable", r.id, to)
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return false
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}
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panic(err) // TODO(bdarnell)
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}
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if IsEmptySnap(snapshot) {
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panic("need non-empty snapshot")
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}
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m.Snapshot = snapshot
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sindex, sterm := snapshot.Metadata.Index, snapshot.Metadata.Term
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r.logger.Debugf("%x [firstindex: %d, commit: %d] sent snapshot[index: %d, term: %d] to %x [%s]",
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r.id, r.raftLog.firstIndex(), r.raftLog.committed, sindex, sterm, to, pr)
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pr.BecomeSnapshot(sindex)
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r.logger.Debugf("%x paused sending replication messages to %x [%s]", r.id, to, pr)
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} else {
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m.Type = pb.MsgApp
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m.Index = pr.Next - 1
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m.LogTerm = term
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m.Entries = ents
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m.Commit = r.raftLog.committed
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if n := len(m.Entries); n != 0 {
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switch pr.State {
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// optimistically increase the next when in StateReplicate
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case tracker.StateReplicate:
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last := m.Entries[n-1].Index
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pr.OptimisticUpdate(last)
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pr.Inflights.Add(last)
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case tracker.StateProbe:
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pr.ProbeSent = true
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default:
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r.logger.Panicf("%x is sending append in unhandled state %s", r.id, pr.State)
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}
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}
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}
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r.send(m)
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return true
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}
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|
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// sendHeartbeat sends a heartbeat RPC to the given peer.
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|
func (r *raft) sendHeartbeat(to uint64, ctx []byte) {
|
|
// Attach the commit as min(to.matched, r.committed).
|
|
// When the leader sends out heartbeat message,
|
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// the receiver(follower) might not be matched with the leader
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// or it might not have all the committed entries.
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|
// The leader MUST NOT forward the follower's commit to
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// an unmatched index.
|
|
commit := min(r.prs.Progress[to].Match, r.raftLog.committed)
|
|
m := pb.Message{
|
|
To: to,
|
|
Type: pb.MsgHeartbeat,
|
|
Commit: commit,
|
|
Context: ctx,
|
|
}
|
|
|
|
r.send(m)
|
|
}
|
|
|
|
// bcastAppend sends RPC, with entries to all peers that are not up-to-date
|
|
// according to the progress recorded in r.prs.
|
|
func (r *raft) bcastAppend() {
|
|
r.prs.Visit(func(id uint64, _ *tracker.Progress) {
|
|
if id == r.id {
|
|
return
|
|
}
|
|
r.sendAppend(id)
|
|
})
|
|
}
|
|
|
|
// bcastHeartbeat sends RPC, without entries to all the peers.
|
|
func (r *raft) bcastHeartbeat() {
|
|
lastCtx := r.readOnly.lastPendingRequestCtx()
|
|
if len(lastCtx) == 0 {
|
|
r.bcastHeartbeatWithCtx(nil)
|
|
} else {
|
|
r.bcastHeartbeatWithCtx([]byte(lastCtx))
|
|
}
|
|
}
|
|
|
|
func (r *raft) bcastHeartbeatWithCtx(ctx []byte) {
|
|
r.prs.Visit(func(id uint64, _ *tracker.Progress) {
|
|
if id == r.id {
|
|
return
|
|
}
|
|
r.sendHeartbeat(id, ctx)
|
|
})
|
|
}
|
|
|
|
func (r *raft) advance(rd Ready) {
|
|
r.reduceUncommittedSize(rd.CommittedEntries)
|
|
|
|
// If entries were applied (or a snapshot), update our cursor for
|
|
// the next Ready. Note that if the current HardState contains a
|
|
// new Commit index, this does not mean that we're also applying
|
|
// all of the new entries due to commit pagination by size.
|
|
if newApplied := rd.appliedCursor(); newApplied > 0 {
|
|
oldApplied := r.raftLog.applied
|
|
r.raftLog.appliedTo(newApplied)
|
|
|
|
if r.prs.Config.AutoLeave && oldApplied <= r.pendingConfIndex && newApplied >= r.pendingConfIndex && r.state == StateLeader {
|
|
// If the current (and most recent, at least for this leader's term)
|
|
// configuration should be auto-left, initiate that now. We use a
|
|
// nil Data which unmarshals into an empty ConfChangeV2 and has the
|
|
// benefit that appendEntry can never refuse it based on its size
|
|
// (which registers as zero).
|
|
ent := pb.Entry{
|
|
Type: pb.EntryConfChangeV2,
|
|
Data: nil,
|
|
}
|
|
// There's no way in which this proposal should be able to be rejected.
|
|
if !r.appendEntry(ent) {
|
|
panic("refused un-refusable auto-leaving ConfChangeV2")
|
|
}
|
|
r.pendingConfIndex = r.raftLog.lastIndex()
|
|
r.logger.Infof("initiating automatic transition out of joint configuration %s", r.prs.Config)
|
|
}
|
|
}
|
|
|
|
if len(rd.Entries) > 0 {
|
|
e := rd.Entries[len(rd.Entries)-1]
|
|
r.raftLog.stableTo(e.Index, e.Term)
|
|
}
|
|
if !IsEmptySnap(rd.Snapshot) {
|
|
r.raftLog.stableSnapTo(rd.Snapshot.Metadata.Index)
|
|
}
|
|
}
|
|
|
|
// maybeCommit attempts to advance the commit index. Returns true if
|
|
// the commit index changed (in which case the caller should call
|
|
// r.bcastAppend).
|
|
func (r *raft) maybeCommit() bool {
|
|
mci := r.prs.Committed()
|
|
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.electionElapsed = 0
|
|
r.heartbeatElapsed = 0
|
|
r.resetRandomizedElectionTimeout()
|
|
|
|
r.abortLeaderTransfer()
|
|
|
|
r.prs.ResetVotes()
|
|
r.prs.Visit(func(id uint64, pr *tracker.Progress) {
|
|
*pr = tracker.Progress{
|
|
Match: 0,
|
|
Next: r.raftLog.lastIndex() + 1,
|
|
Inflights: tracker.NewInflights(r.prs.MaxInflight),
|
|
IsLearner: pr.IsLearner,
|
|
}
|
|
if id == r.id {
|
|
pr.Match = r.raftLog.lastIndex()
|
|
}
|
|
})
|
|
|
|
r.pendingConfIndex = 0
|
|
r.uncommittedSize = 0
|
|
r.readOnly = newReadOnly(r.readOnly.option)
|
|
}
|
|
|
|
func (r *raft) appendEntry(es ...pb.Entry) (accepted bool) {
|
|
li := r.raftLog.lastIndex()
|
|
for i := range es {
|
|
es[i].Term = r.Term
|
|
es[i].Index = li + 1 + uint64(i)
|
|
}
|
|
// Track the size of this uncommitted proposal.
|
|
if !r.increaseUncommittedSize(es) {
|
|
r.logger.Debugf(
|
|
"%x appending new entries to log would exceed uncommitted entry size limit; dropping proposal",
|
|
r.id,
|
|
)
|
|
// Drop the proposal.
|
|
return false
|
|
}
|
|
// use latest "last" index after truncate/append
|
|
li = r.raftLog.append(es...)
|
|
r.prs.Progress[r.id].MaybeUpdate(li)
|
|
// Regardless of maybeCommit's return, our caller will call bcastAppend.
|
|
r.maybeCommit()
|
|
return true
|
|
}
|
|
|
|
// tickElection is run by followers and candidates after r.electionTimeout.
|
|
func (r *raft) tickElection() {
|
|
r.electionElapsed++
|
|
|
|
if r.promotable() && r.pastElectionTimeout() {
|
|
r.electionElapsed = 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.heartbeatElapsed++
|
|
r.electionElapsed++
|
|
|
|
if r.electionElapsed >= r.electionTimeout {
|
|
r.electionElapsed = 0
|
|
if r.checkQuorum {
|
|
r.Step(pb.Message{From: r.id, Type: pb.MsgCheckQuorum})
|
|
}
|
|
// If current leader cannot transfer leadership in electionTimeout, it becomes leader again.
|
|
if r.state == StateLeader && r.leadTransferee != None {
|
|
r.abortLeaderTransfer()
|
|
}
|
|
}
|
|
|
|
if r.state != StateLeader {
|
|
return
|
|
}
|
|
|
|
if r.heartbeatElapsed >= r.heartbeatTimeout {
|
|
r.heartbeatElapsed = 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) becomePreCandidate() {
|
|
// TODO(xiangli) remove the panic when the raft implementation is stable
|
|
if r.state == StateLeader {
|
|
panic("invalid transition [leader -> pre-candidate]")
|
|
}
|
|
// Becoming a pre-candidate changes our step functions and state,
|
|
// but doesn't change anything else. In particular it does not increase
|
|
// r.Term or change r.Vote.
|
|
r.step = stepCandidate
|
|
r.prs.ResetVotes()
|
|
r.tick = r.tickElection
|
|
r.lead = None
|
|
r.state = StatePreCandidate
|
|
r.logger.Infof("%x became pre-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
|
|
// Followers enter replicate mode when they've been successfully probed
|
|
// (perhaps after having received a snapshot as a result). The leader is
|
|
// trivially in this state. Note that r.reset() has initialized this
|
|
// progress with the last index already.
|
|
r.prs.Progress[r.id].BecomeReplicate()
|
|
|
|
// Conservatively set the pendingConfIndex to the last index in the
|
|
// log. There may or may not be a pending config change, but it's
|
|
// safe to delay any future proposals until we commit all our
|
|
// pending log entries, and scanning the entire tail of the log
|
|
// could be expensive.
|
|
r.pendingConfIndex = r.raftLog.lastIndex()
|
|
|
|
emptyEnt := pb.Entry{Data: nil}
|
|
if !r.appendEntry(emptyEnt) {
|
|
// This won't happen because we just called reset() above.
|
|
r.logger.Panic("empty entry was dropped")
|
|
}
|
|
// As a special case, don't count the initial empty entry towards the
|
|
// uncommitted log quota. This is because we want to preserve the
|
|
// behavior of allowing one entry larger than quota if the current
|
|
// usage is zero.
|
|
r.reduceUncommittedSize([]pb.Entry{emptyEnt})
|
|
r.logger.Infof("%x became leader at term %d", r.id, r.Term)
|
|
}
|
|
|
|
func (r *raft) hup(t CampaignType) {
|
|
if r.state == StateLeader {
|
|
r.logger.Debugf("%x ignoring MsgHup because already leader", r.id)
|
|
return
|
|
}
|
|
|
|
if !r.promotable() {
|
|
r.logger.Warningf("%x is unpromotable and can not campaign", r.id)
|
|
return
|
|
}
|
|
ents, err := r.raftLog.slice(r.raftLog.applied+1, r.raftLog.committed+1, noLimit)
|
|
if err != nil {
|
|
r.logger.Panicf("unexpected error getting unapplied entries (%v)", err)
|
|
}
|
|
if n := numOfPendingConf(ents); n != 0 && r.raftLog.committed > r.raftLog.applied {
|
|
r.logger.Warningf("%x cannot campaign at term %d since there are still %d pending configuration changes to apply", r.id, r.Term, n)
|
|
return
|
|
}
|
|
|
|
r.logger.Infof("%x is starting a new election at term %d", r.id, r.Term)
|
|
r.campaign(t)
|
|
}
|
|
|
|
// campaign transitions the raft instance to candidate state. This must only be
|
|
// called after verifying that this is a legitimate transition.
|
|
func (r *raft) campaign(t CampaignType) {
|
|
if !r.promotable() {
|
|
// This path should not be hit (callers are supposed to check), but
|
|
// better safe than sorry.
|
|
r.logger.Warningf("%x is unpromotable; campaign() should have been called", r.id)
|
|
}
|
|
var term uint64
|
|
var voteMsg pb.MessageType
|
|
if t == campaignPreElection {
|
|
r.becomePreCandidate()
|
|
voteMsg = pb.MsgPreVote
|
|
// PreVote RPCs are sent for the next term before we've incremented r.Term.
|
|
term = r.Term + 1
|
|
} else {
|
|
r.becomeCandidate()
|
|
voteMsg = pb.MsgVote
|
|
term = r.Term
|
|
}
|
|
if _, _, res := r.poll(r.id, voteRespMsgType(voteMsg), true); res == quorum.VoteWon {
|
|
// We won the election after voting for ourselves (which must mean that
|
|
// this is a single-node cluster). Advance to the next state.
|
|
if t == campaignPreElection {
|
|
r.campaign(campaignElection)
|
|
} else {
|
|
r.becomeLeader()
|
|
}
|
|
return
|
|
}
|
|
var ids []uint64
|
|
{
|
|
idMap := r.prs.Voters.IDs()
|
|
ids = make([]uint64, 0, len(idMap))
|
|
for id := range idMap {
|
|
ids = append(ids, id)
|
|
}
|
|
sort.Slice(ids, func(i, j int) bool { return ids[i] < ids[j] })
|
|
}
|
|
for _, id := range ids {
|
|
if id == r.id {
|
|
continue
|
|
}
|
|
r.logger.Infof("%x [logterm: %d, index: %d] sent %s request to %x at term %d",
|
|
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), voteMsg, id, r.Term)
|
|
|
|
var ctx []byte
|
|
if t == campaignTransfer {
|
|
ctx = []byte(t)
|
|
}
|
|
r.send(pb.Message{Term: term, To: id, Type: voteMsg, Index: r.raftLog.lastIndex(), LogTerm: r.raftLog.lastTerm(), Context: ctx})
|
|
}
|
|
}
|
|
|
|
func (r *raft) poll(id uint64, t pb.MessageType, v bool) (granted int, rejected int, result quorum.VoteResult) {
|
|
if v {
|
|
r.logger.Infof("%x received %s from %x at term %d", r.id, t, id, r.Term)
|
|
} else {
|
|
r.logger.Infof("%x received %s rejection from %x at term %d", r.id, t, id, r.Term)
|
|
}
|
|
r.prs.RecordVote(id, v)
|
|
return r.prs.TallyVotes()
|
|
}
|
|
|
|
func (r *raft) Step(m pb.Message) error {
|
|
// Handle the message term, which may result in our stepping down to a follower.
|
|
switch {
|
|
case m.Term == 0:
|
|
// local message
|
|
case m.Term > r.Term:
|
|
if m.Type == pb.MsgVote || m.Type == pb.MsgPreVote {
|
|
force := bytes.Equal(m.Context, []byte(campaignTransfer))
|
|
inLease := r.checkQuorum && r.lead != None && r.electionElapsed < r.electionTimeout
|
|
if !force && inLease {
|
|
// If a server receives a RequestVote request within the minimum election timeout
|
|
// of hearing from a current leader, it does not update its term or grant its vote
|
|
r.logger.Infof("%x [logterm: %d, index: %d, vote: %x] ignored %s from %x [logterm: %d, index: %d] at term %d: lease is not expired (remaining ticks: %d)",
|
|
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), r.Vote, m.Type, m.From, m.LogTerm, m.Index, r.Term, r.electionTimeout-r.electionElapsed)
|
|
return nil
|
|
}
|
|
}
|
|
switch {
|
|
case m.Type == pb.MsgPreVote:
|
|
// Never change our term in response to a PreVote
|
|
case m.Type == pb.MsgPreVoteResp && !m.Reject:
|
|
// We send pre-vote requests with a term in our future. If the
|
|
// pre-vote is granted, we will increment our term when we get a
|
|
// quorum. If it is not, the term comes from the node that
|
|
// rejected our vote so we should become a follower at the new
|
|
// term.
|
|
default:
|
|
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)
|
|
if m.Type == pb.MsgApp || m.Type == pb.MsgHeartbeat || m.Type == pb.MsgSnap {
|
|
r.becomeFollower(m.Term, m.From)
|
|
} else {
|
|
r.becomeFollower(m.Term, None)
|
|
}
|
|
}
|
|
|
|
case m.Term < r.Term:
|
|
if (r.checkQuorum || r.preVote) && (m.Type == pb.MsgHeartbeat || m.Type == pb.MsgApp) {
|
|
// We have received messages from a leader at a lower term. It is possible
|
|
// that these messages were simply delayed in the network, but this could
|
|
// also mean that this node has advanced its term number during a network
|
|
// partition, and it is now unable to either win an election or to rejoin
|
|
// the majority on the old term. If checkQuorum is false, this will be
|
|
// handled by incrementing term numbers in response to MsgVote with a
|
|
// higher term, but if checkQuorum is true we may not advance the term on
|
|
// MsgVote and must generate other messages to advance the term. The net
|
|
// result of these two features is to minimize the disruption caused by
|
|
// nodes that have been removed from the cluster's configuration: a
|
|
// removed node will send MsgVotes (or MsgPreVotes) which will be ignored,
|
|
// but it will not receive MsgApp or MsgHeartbeat, so it will not create
|
|
// disruptive term increases, by notifying leader of this node's activeness.
|
|
// The above comments also true for Pre-Vote
|
|
//
|
|
// When follower gets isolated, it soon starts an election ending
|
|
// up with a higher term than leader, although it won't receive enough
|
|
// votes to win the election. When it regains connectivity, this response
|
|
// with "pb.MsgAppResp" of higher term would force leader to step down.
|
|
// However, this disruption is inevitable to free this stuck node with
|
|
// fresh election. This can be prevented with Pre-Vote phase.
|
|
r.send(pb.Message{To: m.From, Type: pb.MsgAppResp})
|
|
} else if m.Type == pb.MsgPreVote {
|
|
// Before Pre-Vote enable, there may have candidate with higher term,
|
|
// but less log. After update to Pre-Vote, the cluster may deadlock if
|
|
// we drop messages with a lower term.
|
|
r.logger.Infof("%x [logterm: %d, index: %d, vote: %x] rejected %s from %x [logterm: %d, index: %d] at term %d",
|
|
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), r.Vote, m.Type, m.From, m.LogTerm, m.Index, r.Term)
|
|
r.send(pb.Message{To: m.From, Term: r.Term, Type: pb.MsgPreVoteResp, Reject: true})
|
|
} else {
|
|
// ignore other cases
|
|
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
|
|
}
|
|
|
|
switch m.Type {
|
|
case pb.MsgHup:
|
|
if r.preVote {
|
|
r.hup(campaignPreElection)
|
|
} else {
|
|
r.hup(campaignElection)
|
|
}
|
|
|
|
case pb.MsgVote, pb.MsgPreVote:
|
|
// We can vote if this is a repeat of a vote we've already cast...
|
|
canVote := r.Vote == m.From ||
|
|
// ...we haven't voted and we don't think there's a leader yet in this term...
|
|
(r.Vote == None && r.lead == None) ||
|
|
// ...or this is a PreVote for a future term...
|
|
(m.Type == pb.MsgPreVote && m.Term > r.Term)
|
|
// ...and we believe the candidate is up to date.
|
|
if canVote && r.raftLog.isUpToDate(m.Index, m.LogTerm) {
|
|
// Note: it turns out that that learners must be allowed to cast votes.
|
|
// This seems counter- intuitive but is necessary in the situation in which
|
|
// a learner has been promoted (i.e. is now a voter) but has not learned
|
|
// about this yet.
|
|
// For example, consider a group in which id=1 is a learner and id=2 and
|
|
// id=3 are voters. A configuration change promoting 1 can be committed on
|
|
// the quorum `{2,3}` without the config change being appended to the
|
|
// learner's log. If the leader (say 2) fails, there are de facto two
|
|
// voters remaining. Only 3 can win an election (due to its log containing
|
|
// all committed entries), but to do so it will need 1 to vote. But 1
|
|
// considers itself a learner and will continue to do so until 3 has
|
|
// stepped up as leader, replicates the conf change to 1, and 1 applies it.
|
|
// Ultimately, by receiving a request to vote, the learner realizes that
|
|
// the candidate believes it to be a voter, and that it should act
|
|
// accordingly. The candidate's config may be stale, too; but in that case
|
|
// it won't win the election, at least in the absence of the bug discussed
|
|
// in:
|
|
// https://github.com/etcd-io/etcd/issues/7625#issuecomment-488798263.
|
|
r.logger.Infof("%x [logterm: %d, index: %d, vote: %x] cast %s for %x [logterm: %d, index: %d] at term %d",
|
|
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), r.Vote, m.Type, m.From, m.LogTerm, m.Index, r.Term)
|
|
// When responding to Msg{Pre,}Vote messages we include the term
|
|
// from the message, not the local term. To see why, consider the
|
|
// case where a single node was previously partitioned away and
|
|
// it's local term is now out of date. If we include the local term
|
|
// (recall that for pre-votes we don't update the local term), the
|
|
// (pre-)campaigning node on the other end will proceed to ignore
|
|
// the message (it ignores all out of date messages).
|
|
// The term in the original message and current local term are the
|
|
// same in the case of regular votes, but different for pre-votes.
|
|
r.send(pb.Message{To: m.From, Term: m.Term, Type: voteRespMsgType(m.Type)})
|
|
if m.Type == pb.MsgVote {
|
|
// Only record real votes.
|
|
r.electionElapsed = 0
|
|
r.Vote = m.From
|
|
}
|
|
} else {
|
|
r.logger.Infof("%x [logterm: %d, index: %d, vote: %x] rejected %s from %x [logterm: %d, index: %d] at term %d",
|
|
r.id, r.raftLog.lastTerm(), r.raftLog.lastIndex(), r.Vote, m.Type, m.From, m.LogTerm, m.Index, r.Term)
|
|
r.send(pb.Message{To: m.From, Term: r.Term, Type: voteRespMsgType(m.Type), Reject: true})
|
|
}
|
|
|
|
default:
|
|
err := r.step(r, m)
|
|
if err != nil {
|
|
return err
|
|
}
|
|
}
|
|
return nil
|
|
}
|
|
|
|
type stepFunc func(r *raft, m pb.Message) error
|
|
|
|
func stepLeader(r *raft, m pb.Message) error {
|
|
// These message types do not require any progress for m.From.
|
|
switch m.Type {
|
|
case pb.MsgBeat:
|
|
r.bcastHeartbeat()
|
|
return nil
|
|
case pb.MsgCheckQuorum:
|
|
// The leader should always see itself as active. As a precaution, handle
|
|
// the case in which the leader isn't in the configuration any more (for
|
|
// example if it just removed itself).
|
|
//
|
|
// TODO(tbg): I added a TODO in removeNode, it doesn't seem that the
|
|
// leader steps down when removing itself. I might be missing something.
|
|
if pr := r.prs.Progress[r.id]; pr != nil {
|
|
pr.RecentActive = true
|
|
}
|
|
if !r.prs.QuorumActive() {
|
|
r.logger.Warningf("%x stepped down to follower since quorum is not active", r.id)
|
|
r.becomeFollower(r.Term, None)
|
|
}
|
|
// Mark everyone (but ourselves) as inactive in preparation for the next
|
|
// CheckQuorum.
|
|
r.prs.Visit(func(id uint64, pr *tracker.Progress) {
|
|
if id != r.id {
|
|
pr.RecentActive = false
|
|
}
|
|
})
|
|
return nil
|
|
case pb.MsgProp:
|
|
if len(m.Entries) == 0 {
|
|
r.logger.Panicf("%x stepped empty MsgProp", r.id)
|
|
}
|
|
if r.prs.Progress[r.id] == nil {
|
|
// If we are not currently a member of the range (i.e. this node
|
|
// was removed from the configuration while serving as leader),
|
|
// drop any new proposals.
|
|
return ErrProposalDropped
|
|
}
|
|
if r.leadTransferee != None {
|
|
r.logger.Debugf("%x [term %d] transfer leadership to %x is in progress; dropping proposal", r.id, r.Term, r.leadTransferee)
|
|
return ErrProposalDropped
|
|
}
|
|
|
|
for i := range m.Entries {
|
|
e := &m.Entries[i]
|
|
var cc pb.ConfChangeI
|
|
if e.Type == pb.EntryConfChange {
|
|
var ccc pb.ConfChange
|
|
if err := ccc.Unmarshal(e.Data); err != nil {
|
|
panic(err)
|
|
}
|
|
cc = ccc
|
|
} else if e.Type == pb.EntryConfChangeV2 {
|
|
var ccc pb.ConfChangeV2
|
|
if err := ccc.Unmarshal(e.Data); err != nil {
|
|
panic(err)
|
|
}
|
|
cc = ccc
|
|
}
|
|
if cc != nil {
|
|
alreadyPending := r.pendingConfIndex > r.raftLog.applied
|
|
alreadyJoint := len(r.prs.Config.Voters[1]) > 0
|
|
wantsLeaveJoint := len(cc.AsV2().Changes) == 0
|
|
|
|
var refused string
|
|
if alreadyPending {
|
|
refused = fmt.Sprintf("possible unapplied conf change at index %d (applied to %d)", r.pendingConfIndex, r.raftLog.applied)
|
|
} else if alreadyJoint && !wantsLeaveJoint {
|
|
refused = "must transition out of joint config first"
|
|
} else if !alreadyJoint && wantsLeaveJoint {
|
|
refused = "not in joint state; refusing empty conf change"
|
|
}
|
|
|
|
if refused != "" {
|
|
r.logger.Infof("%x ignoring conf change %v at config %s: %s", r.id, cc, r.prs.Config, refused)
|
|
m.Entries[i] = pb.Entry{Type: pb.EntryNormal}
|
|
} else {
|
|
r.pendingConfIndex = r.raftLog.lastIndex() + uint64(i) + 1
|
|
}
|
|
}
|
|
}
|
|
|
|
if !r.appendEntry(m.Entries...) {
|
|
return ErrProposalDropped
|
|
}
|
|
r.bcastAppend()
|
|
return nil
|
|
case pb.MsgReadIndex:
|
|
// only one voting member (the leader) in the cluster
|
|
if r.prs.IsSingleton() {
|
|
if resp := r.responseToReadIndexReq(m, r.raftLog.committed); resp.To != None {
|
|
r.send(resp)
|
|
}
|
|
return nil
|
|
}
|
|
|
|
// Postpone read only request when this leader has not committed
|
|
// any log entry at its term.
|
|
if !r.committedEntryInCurrentTerm() {
|
|
r.pendingReadIndexMessages = append(r.pendingReadIndexMessages, m)
|
|
return nil
|
|
}
|
|
|
|
sendMsgReadIndexResponse(r, m)
|
|
|
|
return nil
|
|
}
|
|
|
|
// All other message types require a progress for m.From (pr).
|
|
pr := r.prs.Progress[m.From]
|
|
if pr == nil {
|
|
r.logger.Debugf("%x no progress available for %x", r.id, m.From)
|
|
return nil
|
|
}
|
|
switch m.Type {
|
|
case pb.MsgAppResp:
|
|
pr.RecentActive = true
|
|
|
|
if m.Reject {
|
|
// RejectHint is the suggested next base entry for appending (i.e.
|
|
// we try to append entry RejectHint+1 next), and LogTerm is the
|
|
// term that the follower has at index RejectHint. Older versions
|
|
// of this library did not populate LogTerm for rejections and it
|
|
// is zero for followers with an empty log.
|
|
//
|
|
// Under normal circumstances, the leader's log is longer than the
|
|
// follower's and the follower's log is a prefix of the leader's
|
|
// (i.e. there is no divergent uncommitted suffix of the log on the
|
|
// follower). In that case, the first probe reveals where the
|
|
// follower's log ends (RejectHint=follower's last index) and the
|
|
// subsequent probe succeeds.
|
|
//
|
|
// However, when networks are partitioned or systems overloaded,
|
|
// large divergent log tails can occur. The naive attempt, probing
|
|
// entry by entry in decreasing order, will be the product of the
|
|
// length of the diverging tails and the network round-trip latency,
|
|
// which can easily result in hours of time spent probing and can
|
|
// even cause outright outages. The probes are thus optimized as
|
|
// described below.
|
|
r.logger.Debugf("%x received MsgAppResp(rejected, hint: (index %d, term %d)) from %x for index %d",
|
|
r.id, m.RejectHint, m.LogTerm, m.From, m.Index)
|
|
nextProbeIdx := m.RejectHint
|
|
if m.LogTerm > 0 {
|
|
// If the follower has an uncommitted log tail, we would end up
|
|
// probing one by one until we hit the common prefix.
|
|
//
|
|
// For example, if the leader has:
|
|
//
|
|
// idx 1 2 3 4 5 6 7 8 9
|
|
// -----------------
|
|
// term (L) 1 3 3 3 5 5 5 5 5
|
|
// term (F) 1 1 1 1 2 2
|
|
//
|
|
// Then, after sending an append anchored at (idx=9,term=5) we
|
|
// would receive a RejectHint of 6 and LogTerm of 2. Without the
|
|
// code below, we would try an append at index 6, which would
|
|
// fail again.
|
|
//
|
|
// However, looking only at what the leader knows about its own
|
|
// log and the rejection hint, it is clear that a probe at index
|
|
// 6, 5, 4, 3, and 2 must fail as well:
|
|
//
|
|
// For all of these indexes, the leader's log term is larger than
|
|
// the rejection's log term. If a probe at one of these indexes
|
|
// succeeded, its log term at that index would match the leader's,
|
|
// i.e. 3 or 5 in this example. But the follower already told the
|
|
// leader that it is still at term 2 at index 9, and since the
|
|
// log term only ever goes up (within a log), this is a contradiction.
|
|
//
|
|
// At index 1, however, the leader can draw no such conclusion,
|
|
// as its term 1 is not larger than the term 2 from the
|
|
// follower's rejection. We thus probe at 1, which will succeed
|
|
// in this example. In general, with this approach we probe at
|
|
// most once per term found in the leader's log.
|
|
//
|
|
// There is a similar mechanism on the follower (implemented in
|
|
// handleAppendEntries via a call to findConflictByTerm) that is
|
|
// useful if the follower has a large divergent uncommitted log
|
|
// tail[1], as in this example:
|
|
//
|
|
// idx 1 2 3 4 5 6 7 8 9
|
|
// -----------------
|
|
// term (L) 1 3 3 3 3 3 3 3 7
|
|
// term (F) 1 3 3 4 4 5 5 5 6
|
|
//
|
|
// Naively, the leader would probe at idx=9, receive a rejection
|
|
// revealing the log term of 6 at the follower. Since the leader's
|
|
// term at the previous index is already smaller than 6, the leader-
|
|
// side optimization discussed above is ineffective. The leader thus
|
|
// probes at index 8 and, naively, receives a rejection for the same
|
|
// index and log term 5. Again, the leader optimization does not improve
|
|
// over linear probing as term 5 is above the leader's term 3 for that
|
|
// and many preceding indexes; the leader would have to probe linearly
|
|
// until it would finally hit index 3, where the probe would succeed.
|
|
//
|
|
// Instead, we apply a similar optimization on the follower. When the
|
|
// follower receives the probe at index 8 (log term 3), it concludes
|
|
// that all of the leader's log preceding that index has log terms of
|
|
// 3 or below. The largest index in the follower's log with a log term
|
|
// of 3 or below is index 3. The follower will thus return a rejection
|
|
// for index=3, log term=3 instead. The leader's next probe will then
|
|
// succeed at that index.
|
|
//
|
|
// [1]: more precisely, if the log terms in the large uncommitted
|
|
// tail on the follower are larger than the leader's. At first,
|
|
// it may seem unintuitive that a follower could even have such
|
|
// a large tail, but it can happen:
|
|
//
|
|
// 1. Leader appends (but does not commit) entries 2 and 3, crashes.
|
|
// idx 1 2 3 4 5 6 7 8 9
|
|
// -----------------
|
|
// term (L) 1 2 2 [crashes]
|
|
// term (F) 1
|
|
// term (F) 1
|
|
//
|
|
// 2. a follower becomes leader and appends entries at term 3.
|
|
// -----------------
|
|
// term (x) 1 2 2 [down]
|
|
// term (F) 1 3 3 3 3
|
|
// term (F) 1
|
|
//
|
|
// 3. term 3 leader goes down, term 2 leader returns as term 4
|
|
// leader. It commits the log & entries at term 4.
|
|
//
|
|
// -----------------
|
|
// term (L) 1 2 2 2
|
|
// term (x) 1 3 3 3 3 [down]
|
|
// term (F) 1
|
|
// -----------------
|
|
// term (L) 1 2 2 2 4 4 4
|
|
// term (F) 1 3 3 3 3 [gets probed]
|
|
// term (F) 1 2 2 2 4 4 4
|
|
//
|
|
// 4. the leader will now probe the returning follower at index
|
|
// 7, the rejection points it at the end of the follower's log
|
|
// which is at a higher log term than the actually committed
|
|
// log.
|
|
nextProbeIdx = r.raftLog.findConflictByTerm(m.RejectHint, m.LogTerm)
|
|
}
|
|
if pr.MaybeDecrTo(m.Index, nextProbeIdx) {
|
|
r.logger.Debugf("%x decreased progress of %x to [%s]", r.id, m.From, pr)
|
|
if pr.State == tracker.StateReplicate {
|
|
pr.BecomeProbe()
|
|
}
|
|
r.sendAppend(m.From)
|
|
}
|
|
} else {
|
|
oldPaused := pr.IsPaused()
|
|
if pr.MaybeUpdate(m.Index) {
|
|
switch {
|
|
case pr.State == tracker.StateProbe:
|
|
pr.BecomeReplicate()
|
|
case pr.State == tracker.StateSnapshot && pr.Match >= pr.PendingSnapshot:
|
|
// TODO(tbg): we should also enter this branch if a snapshot is
|
|
// received that is below pr.PendingSnapshot but which makes it
|
|
// possible to use the log again.
|
|
r.logger.Debugf("%x recovered from needing snapshot, resumed sending replication messages to %x [%s]", r.id, m.From, pr)
|
|
// Transition back to replicating state via probing state
|
|
// (which takes the snapshot into account). If we didn't
|
|
// move to replicating state, that would only happen with
|
|
// the next round of appends (but there may not be a next
|
|
// round for a while, exposing an inconsistent RaftStatus).
|
|
pr.BecomeProbe()
|
|
pr.BecomeReplicate()
|
|
case pr.State == tracker.StateReplicate:
|
|
pr.Inflights.FreeLE(m.Index)
|
|
}
|
|
|
|
if r.maybeCommit() {
|
|
// committed index has progressed for the term, so it is safe
|
|
// to respond to pending read index requests
|
|
releasePendingReadIndexMessages(r)
|
|
r.bcastAppend()
|
|
} else if oldPaused {
|
|
// If we were paused before, this node may be missing the
|
|
// latest commit index, so send it.
|
|
r.sendAppend(m.From)
|
|
}
|
|
// We've updated flow control information above, which may
|
|
// allow us to send multiple (size-limited) in-flight messages
|
|
// at once (such as when transitioning from probe to
|
|
// replicate, or when freeTo() covers multiple messages). If
|
|
// we have more entries to send, send as many messages as we
|
|
// can (without sending empty messages for the commit index)
|
|
for r.maybeSendAppend(m.From, false) {
|
|
}
|
|
// Transfer leadership is in progress.
|
|
if m.From == r.leadTransferee && pr.Match == r.raftLog.lastIndex() {
|
|
r.logger.Infof("%x sent MsgTimeoutNow to %x after received MsgAppResp", r.id, m.From)
|
|
r.sendTimeoutNow(m.From)
|
|
}
|
|
}
|
|
}
|
|
case pb.MsgHeartbeatResp:
|
|
pr.RecentActive = true
|
|
pr.ProbeSent = false
|
|
|
|
// free one slot for the full inflights window to allow progress.
|
|
if pr.State == tracker.StateReplicate && pr.Inflights.Full() {
|
|
pr.Inflights.FreeFirstOne()
|
|
}
|
|
if pr.Match < r.raftLog.lastIndex() {
|
|
r.sendAppend(m.From)
|
|
}
|
|
|
|
if r.readOnly.option != ReadOnlySafe || len(m.Context) == 0 {
|
|
return nil
|
|
}
|
|
|
|
if r.prs.Voters.VoteResult(r.readOnly.recvAck(m.From, m.Context)) != quorum.VoteWon {
|
|
return nil
|
|
}
|
|
|
|
rss := r.readOnly.advance(m)
|
|
for _, rs := range rss {
|
|
if resp := r.responseToReadIndexReq(rs.req, rs.index); resp.To != None {
|
|
r.send(resp)
|
|
}
|
|
}
|
|
case pb.MsgSnapStatus:
|
|
if pr.State != tracker.StateSnapshot {
|
|
return nil
|
|
}
|
|
// TODO(tbg): this code is very similar to the snapshot handling in
|
|
// MsgAppResp above. In fact, the code there is more correct than the
|
|
// code here and should likely be updated to match (or even better, the
|
|
// logic pulled into a newly created Progress state machine handler).
|
|
if !m.Reject {
|
|
pr.BecomeProbe()
|
|
r.logger.Debugf("%x snapshot succeeded, resumed sending replication messages to %x [%s]", r.id, m.From, pr)
|
|
} else {
|
|
// NB: the order here matters or we'll be probing erroneously from
|
|
// the snapshot index, but the snapshot never applied.
|
|
pr.PendingSnapshot = 0
|
|
pr.BecomeProbe()
|
|
r.logger.Debugf("%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.ProbeSent = true
|
|
case pb.MsgUnreachable:
|
|
// During optimistic replication, if the remote becomes unreachable,
|
|
// there is huge probability that a MsgApp is lost.
|
|
if pr.State == tracker.StateReplicate {
|
|
pr.BecomeProbe()
|
|
}
|
|
r.logger.Debugf("%x failed to send message to %x because it is unreachable [%s]", r.id, m.From, pr)
|
|
case pb.MsgTransferLeader:
|
|
if pr.IsLearner {
|
|
r.logger.Debugf("%x is learner. Ignored transferring leadership", r.id)
|
|
return nil
|
|
}
|
|
leadTransferee := m.From
|
|
lastLeadTransferee := r.leadTransferee
|
|
if lastLeadTransferee != None {
|
|
if lastLeadTransferee == leadTransferee {
|
|
r.logger.Infof("%x [term %d] transfer leadership to %x is in progress, ignores request to same node %x",
|
|
r.id, r.Term, leadTransferee, leadTransferee)
|
|
return nil
|
|
}
|
|
r.abortLeaderTransfer()
|
|
r.logger.Infof("%x [term %d] abort previous transferring leadership to %x", r.id, r.Term, lastLeadTransferee)
|
|
}
|
|
if leadTransferee == r.id {
|
|
r.logger.Debugf("%x is already leader. Ignored transferring leadership to self", r.id)
|
|
return nil
|
|
}
|
|
// Transfer leadership to third party.
|
|
r.logger.Infof("%x [term %d] starts to transfer leadership to %x", r.id, r.Term, leadTransferee)
|
|
// Transfer leadership should be finished in one electionTimeout, so reset r.electionElapsed.
|
|
r.electionElapsed = 0
|
|
r.leadTransferee = leadTransferee
|
|
if pr.Match == r.raftLog.lastIndex() {
|
|
r.sendTimeoutNow(leadTransferee)
|
|
r.logger.Infof("%x sends MsgTimeoutNow to %x immediately as %x already has up-to-date log", r.id, leadTransferee, leadTransferee)
|
|
} else {
|
|
r.sendAppend(leadTransferee)
|
|
}
|
|
}
|
|
return nil
|
|
}
|
|
|
|
// stepCandidate is shared by StateCandidate and StatePreCandidate; the difference is
|
|
// whether they respond to MsgVoteResp or MsgPreVoteResp.
|
|
func stepCandidate(r *raft, m pb.Message) error {
|
|
// Only handle vote responses corresponding to our candidacy (while in
|
|
// StateCandidate, we may get stale MsgPreVoteResp messages in this term from
|
|
// our pre-candidate state).
|
|
var myVoteRespType pb.MessageType
|
|
if r.state == StatePreCandidate {
|
|
myVoteRespType = pb.MsgPreVoteResp
|
|
} else {
|
|
myVoteRespType = pb.MsgVoteResp
|
|
}
|
|
switch m.Type {
|
|
case pb.MsgProp:
|
|
r.logger.Infof("%x no leader at term %d; dropping proposal", r.id, r.Term)
|
|
return ErrProposalDropped
|
|
case pb.MsgApp:
|
|
r.becomeFollower(m.Term, m.From) // always m.Term == r.Term
|
|
r.handleAppendEntries(m)
|
|
case pb.MsgHeartbeat:
|
|
r.becomeFollower(m.Term, m.From) // always m.Term == r.Term
|
|
r.handleHeartbeat(m)
|
|
case pb.MsgSnap:
|
|
r.becomeFollower(m.Term, m.From) // always m.Term == r.Term
|
|
r.handleSnapshot(m)
|
|
case myVoteRespType:
|
|
gr, rj, res := r.poll(m.From, m.Type, !m.Reject)
|
|
r.logger.Infof("%x has received %d %s votes and %d vote rejections", r.id, gr, m.Type, rj)
|
|
switch res {
|
|
case quorum.VoteWon:
|
|
if r.state == StatePreCandidate {
|
|
r.campaign(campaignElection)
|
|
} else {
|
|
r.becomeLeader()
|
|
r.bcastAppend()
|
|
}
|
|
case quorum.VoteLost:
|
|
// pb.MsgPreVoteResp contains future term of pre-candidate
|
|
// m.Term > r.Term; reuse r.Term
|
|
r.becomeFollower(r.Term, None)
|
|
}
|
|
case pb.MsgTimeoutNow:
|
|
r.logger.Debugf("%x [term %d state %v] ignored MsgTimeoutNow from %x", r.id, r.Term, r.state, m.From)
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func stepFollower(r *raft, m pb.Message) error {
|
|
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 ErrProposalDropped
|
|
} else if r.disableProposalForwarding {
|
|
r.logger.Infof("%x not forwarding to leader %x at term %d; dropping proposal", r.id, r.lead, r.Term)
|
|
return ErrProposalDropped
|
|
}
|
|
m.To = r.lead
|
|
r.send(m)
|
|
case pb.MsgApp:
|
|
r.electionElapsed = 0
|
|
r.lead = m.From
|
|
r.handleAppendEntries(m)
|
|
case pb.MsgHeartbeat:
|
|
r.electionElapsed = 0
|
|
r.lead = m.From
|
|
r.handleHeartbeat(m)
|
|
case pb.MsgSnap:
|
|
r.electionElapsed = 0
|
|
r.lead = m.From
|
|
r.handleSnapshot(m)
|
|
case pb.MsgTransferLeader:
|
|
if r.lead == None {
|
|
r.logger.Infof("%x no leader at term %d; dropping leader transfer msg", r.id, r.Term)
|
|
return nil
|
|
}
|
|
m.To = r.lead
|
|
r.send(m)
|
|
case pb.MsgTimeoutNow:
|
|
r.logger.Infof("%x [term %d] received MsgTimeoutNow from %x and starts an election to get leadership.", r.id, r.Term, m.From)
|
|
// Leadership transfers never use pre-vote even if r.preVote is true; we
|
|
// know we are not recovering from a partition so there is no need for the
|
|
// extra round trip.
|
|
r.hup(campaignTransfer)
|
|
case pb.MsgReadIndex:
|
|
if r.lead == None {
|
|
r.logger.Infof("%x no leader at term %d; dropping index reading msg", r.id, r.Term)
|
|
return nil
|
|
}
|
|
m.To = r.lead
|
|
r.send(m)
|
|
case pb.MsgReadIndexResp:
|
|
if len(m.Entries) != 1 {
|
|
r.logger.Errorf("%x invalid format of MsgReadIndexResp from %x, entries count: %d", r.id, m.From, len(m.Entries))
|
|
return nil
|
|
}
|
|
r.readStates = append(r.readStates, ReadState{Index: m.Index, RequestCtx: m.Entries[0].Data})
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func (r *raft) handleAppendEntries(m pb.Message) {
|
|
if m.Index < r.raftLog.committed {
|
|
r.send(pb.Message{To: m.From, Type: pb.MsgAppResp, Index: r.raftLog.committed})
|
|
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)
|
|
|
|
// Return a hint to the leader about the maximum index and term that the
|
|
// two logs could be divergent at. Do this by searching through the
|
|
// follower's log for the maximum (index, term) pair with a term <= the
|
|
// MsgApp's LogTerm and an index <= the MsgApp's Index. This can help
|
|
// skip all indexes in the follower's uncommitted tail with terms
|
|
// greater than the MsgApp's LogTerm.
|
|
//
|
|
// See the other caller for findConflictByTerm (in stepLeader) for a much
|
|
// more detailed explanation of this mechanism.
|
|
hintIndex := min(m.Index, r.raftLog.lastIndex())
|
|
hintIndex = r.raftLog.findConflictByTerm(hintIndex, m.LogTerm)
|
|
hintTerm, err := r.raftLog.term(hintIndex)
|
|
if err != nil {
|
|
panic(fmt.Sprintf("term(%d) must be valid, but got %v", hintIndex, err))
|
|
}
|
|
r.send(pb.Message{
|
|
To: m.From,
|
|
Type: pb.MsgAppResp,
|
|
Index: m.Index,
|
|
Reject: true,
|
|
RejectHint: hintIndex,
|
|
LogTerm: hintTerm,
|
|
})
|
|
}
|
|
}
|
|
|
|
func (r *raft) handleHeartbeat(m pb.Message) {
|
|
r.raftLog.commitTo(m.Commit)
|
|
r.send(pb.Message{To: m.From, Type: pb.MsgHeartbeatResp, Context: m.Context})
|
|
}
|
|
|
|
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.raftLog.committed, 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.raftLog.committed, 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. If this method returns false, the snapshot was
|
|
// ignored, either because it was obsolete or because of an error.
|
|
func (r *raft) restore(s pb.Snapshot) bool {
|
|
if s.Metadata.Index <= r.raftLog.committed {
|
|
return false
|
|
}
|
|
if r.state != StateFollower {
|
|
// This is defense-in-depth: if the leader somehow ended up applying a
|
|
// snapshot, it could move into a new term without moving into a
|
|
// follower state. This should never fire, but if it did, we'd have
|
|
// prevented damage by returning early, so log only a loud warning.
|
|
//
|
|
// At the time of writing, the instance is guaranteed to be in follower
|
|
// state when this method is called.
|
|
r.logger.Warningf("%x attempted to restore snapshot as leader; should never happen", r.id)
|
|
r.becomeFollower(r.Term+1, None)
|
|
return false
|
|
}
|
|
|
|
// More defense-in-depth: throw away snapshot if recipient is not in the
|
|
// config. This shouldn't ever happen (at the time of writing) but lots of
|
|
// code here and there assumes that r.id is in the progress tracker.
|
|
found := false
|
|
cs := s.Metadata.ConfState
|
|
|
|
for _, set := range [][]uint64{
|
|
cs.Voters,
|
|
cs.Learners,
|
|
cs.VotersOutgoing,
|
|
// `LearnersNext` doesn't need to be checked. According to the rules, if a peer in
|
|
// `LearnersNext`, it has to be in `VotersOutgoing`.
|
|
} {
|
|
for _, id := range set {
|
|
if id == r.id {
|
|
found = true
|
|
break
|
|
}
|
|
}
|
|
if found {
|
|
break
|
|
}
|
|
}
|
|
if !found {
|
|
r.logger.Warningf(
|
|
"%x attempted to restore snapshot but it is not in the ConfState %v; should never happen",
|
|
r.id, cs,
|
|
)
|
|
return false
|
|
}
|
|
|
|
// Now go ahead and actually restore.
|
|
|
|
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.raftLog.committed, r.raftLog.lastIndex(), r.raftLog.lastTerm(), s.Metadata.Index, s.Metadata.Term)
|
|
r.raftLog.commitTo(s.Metadata.Index)
|
|
return false
|
|
}
|
|
|
|
r.raftLog.restore(s)
|
|
|
|
// Reset the configuration and add the (potentially updated) peers in anew.
|
|
r.prs = tracker.MakeProgressTracker(r.prs.MaxInflight)
|
|
cfg, prs, err := confchange.Restore(confchange.Changer{
|
|
Tracker: r.prs,
|
|
LastIndex: r.raftLog.lastIndex(),
|
|
}, cs)
|
|
|
|
if err != nil {
|
|
// This should never happen. Either there's a bug in our config change
|
|
// handling or the client corrupted the conf change.
|
|
panic(fmt.Sprintf("unable to restore config %+v: %s", cs, err))
|
|
}
|
|
|
|
assertConfStatesEquivalent(r.logger, cs, r.switchToConfig(cfg, prs))
|
|
|
|
pr := r.prs.Progress[r.id]
|
|
pr.MaybeUpdate(pr.Next - 1) // TODO(tbg): this is untested and likely unneeded
|
|
|
|
r.logger.Infof("%x [commit: %d, lastindex: %d, lastterm: %d] restored snapshot [index: %d, term: %d]",
|
|
r.id, r.raftLog.committed, r.raftLog.lastIndex(), r.raftLog.lastTerm(), s.Metadata.Index, s.Metadata.Term)
|
|
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 {
|
|
pr := r.prs.Progress[r.id]
|
|
return pr != nil && !pr.IsLearner && !r.raftLog.hasPendingSnapshot()
|
|
}
|
|
|
|
func (r *raft) applyConfChange(cc pb.ConfChangeV2) pb.ConfState {
|
|
cfg, prs, err := func() (tracker.Config, tracker.ProgressMap, error) {
|
|
changer := confchange.Changer{
|
|
Tracker: r.prs,
|
|
LastIndex: r.raftLog.lastIndex(),
|
|
}
|
|
if cc.LeaveJoint() {
|
|
return changer.LeaveJoint()
|
|
} else if autoLeave, ok := cc.EnterJoint(); ok {
|
|
return changer.EnterJoint(autoLeave, cc.Changes...)
|
|
}
|
|
return changer.Simple(cc.Changes...)
|
|
}()
|
|
|
|
if err != nil {
|
|
// TODO(tbg): return the error to the caller.
|
|
panic(err)
|
|
}
|
|
|
|
return r.switchToConfig(cfg, prs)
|
|
}
|
|
|
|
// switchToConfig reconfigures this node to use the provided configuration. It
|
|
// updates the in-memory state and, when necessary, carries out additional
|
|
// actions such as reacting to the removal of nodes or changed quorum
|
|
// requirements.
|
|
//
|
|
// The inputs usually result from restoring a ConfState or applying a ConfChange.
|
|
func (r *raft) switchToConfig(cfg tracker.Config, prs tracker.ProgressMap) pb.ConfState {
|
|
r.prs.Config = cfg
|
|
r.prs.Progress = prs
|
|
|
|
r.logger.Infof("%x switched to configuration %s", r.id, r.prs.Config)
|
|
cs := r.prs.ConfState()
|
|
pr, ok := r.prs.Progress[r.id]
|
|
|
|
// Update whether the node itself is a learner, resetting to false when the
|
|
// node is removed.
|
|
r.isLearner = ok && pr.IsLearner
|
|
|
|
if (!ok || r.isLearner) && r.state == StateLeader {
|
|
// This node is leader and was removed or demoted. We prevent demotions
|
|
// at the time writing but hypothetically we handle them the same way as
|
|
// removing the leader: stepping down into the next Term.
|
|
//
|
|
// TODO(tbg): step down (for sanity) and ask follower with largest Match
|
|
// to TimeoutNow (to avoid interruption). This might still drop some
|
|
// proposals but it's better than nothing.
|
|
//
|
|
// TODO(tbg): test this branch. It is untested at the time of writing.
|
|
return cs
|
|
}
|
|
|
|
// The remaining steps only make sense if this node is the leader and there
|
|
// are other nodes.
|
|
if r.state != StateLeader || len(cs.Voters) == 0 {
|
|
return cs
|
|
}
|
|
|
|
if r.maybeCommit() {
|
|
// If the configuration change means that more entries are committed now,
|
|
// broadcast/append to everyone in the updated config.
|
|
r.bcastAppend()
|
|
} else {
|
|
// Otherwise, still probe the newly added replicas; there's no reason to
|
|
// let them wait out a heartbeat interval (or the next incoming
|
|
// proposal).
|
|
r.prs.Visit(func(id uint64, pr *tracker.Progress) {
|
|
r.maybeSendAppend(id, false /* sendIfEmpty */)
|
|
})
|
|
}
|
|
// If the the leadTransferee was removed or demoted, abort the leadership transfer.
|
|
if _, tOK := r.prs.Config.Voters.IDs()[r.leadTransferee]; !tOK && r.leadTransferee != 0 {
|
|
r.abortLeaderTransfer()
|
|
}
|
|
|
|
return cs
|
|
}
|
|
|
|
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
|
|
}
|
|
|
|
// pastElectionTimeout returns true iff r.electionElapsed is greater
|
|
// than or equal to the randomized election timeout in
|
|
// [electiontimeout, 2 * electiontimeout - 1].
|
|
func (r *raft) pastElectionTimeout() bool {
|
|
return r.electionElapsed >= r.randomizedElectionTimeout
|
|
}
|
|
|
|
func (r *raft) resetRandomizedElectionTimeout() {
|
|
r.randomizedElectionTimeout = r.electionTimeout + globalRand.Intn(r.electionTimeout)
|
|
}
|
|
|
|
func (r *raft) sendTimeoutNow(to uint64) {
|
|
r.send(pb.Message{To: to, Type: pb.MsgTimeoutNow})
|
|
}
|
|
|
|
func (r *raft) abortLeaderTransfer() {
|
|
r.leadTransferee = None
|
|
}
|
|
|
|
// committedEntryInCurrentTerm return true if the peer has committed an entry in its term.
|
|
func (r *raft) committedEntryInCurrentTerm() bool {
|
|
return r.raftLog.zeroTermOnErrCompacted(r.raftLog.term(r.raftLog.committed)) == r.Term
|
|
}
|
|
|
|
// responseToReadIndexReq constructs a response for `req`. If `req` comes from the peer
|
|
// itself, a blank value will be returned.
|
|
func (r *raft) responseToReadIndexReq(req pb.Message, readIndex uint64) pb.Message {
|
|
if req.From == None || req.From == r.id {
|
|
r.readStates = append(r.readStates, ReadState{
|
|
Index: readIndex,
|
|
RequestCtx: req.Entries[0].Data,
|
|
})
|
|
return pb.Message{}
|
|
}
|
|
return pb.Message{
|
|
Type: pb.MsgReadIndexResp,
|
|
To: req.From,
|
|
Index: readIndex,
|
|
Entries: req.Entries,
|
|
}
|
|
}
|
|
|
|
// increaseUncommittedSize computes the size of the proposed entries and
|
|
// determines whether they would push leader over its maxUncommittedSize limit.
|
|
// If the new entries would exceed the limit, the method returns false. If not,
|
|
// the increase in uncommitted entry size is recorded and the method returns
|
|
// true.
|
|
//
|
|
// Empty payloads are never refused. This is used both for appending an empty
|
|
// entry at a new leader's term, as well as leaving a joint configuration.
|
|
func (r *raft) increaseUncommittedSize(ents []pb.Entry) bool {
|
|
var s uint64
|
|
for _, e := range ents {
|
|
s += uint64(PayloadSize(e))
|
|
}
|
|
|
|
if r.uncommittedSize > 0 && s > 0 && r.uncommittedSize+s > r.maxUncommittedSize {
|
|
// If the uncommitted tail of the Raft log is empty, allow any size
|
|
// proposal. Otherwise, limit the size of the uncommitted tail of the
|
|
// log and drop any proposal that would push the size over the limit.
|
|
// Note the added requirement s>0 which is used to make sure that
|
|
// appending single empty entries to the log always succeeds, used both
|
|
// for replicating a new leader's initial empty entry, and for
|
|
// auto-leaving joint configurations.
|
|
return false
|
|
}
|
|
r.uncommittedSize += s
|
|
return true
|
|
}
|
|
|
|
// reduceUncommittedSize accounts for the newly committed entries by decreasing
|
|
// the uncommitted entry size limit.
|
|
func (r *raft) reduceUncommittedSize(ents []pb.Entry) {
|
|
if r.uncommittedSize == 0 {
|
|
// Fast-path for followers, who do not track or enforce the limit.
|
|
return
|
|
}
|
|
|
|
var s uint64
|
|
for _, e := range ents {
|
|
s += uint64(PayloadSize(e))
|
|
}
|
|
if s > r.uncommittedSize {
|
|
// uncommittedSize may underestimate the size of the uncommitted Raft
|
|
// log tail but will never overestimate it. Saturate at 0 instead of
|
|
// allowing overflow.
|
|
r.uncommittedSize = 0
|
|
} else {
|
|
r.uncommittedSize -= s
|
|
}
|
|
}
|
|
|
|
func numOfPendingConf(ents []pb.Entry) int {
|
|
n := 0
|
|
for i := range ents {
|
|
if ents[i].Type == pb.EntryConfChange || ents[i].Type == pb.EntryConfChangeV2 {
|
|
n++
|
|
}
|
|
}
|
|
return n
|
|
}
|
|
|
|
func releasePendingReadIndexMessages(r *raft) {
|
|
if !r.committedEntryInCurrentTerm() {
|
|
r.logger.Error("pending MsgReadIndex should be released only after first commit in current term")
|
|
return
|
|
}
|
|
|
|
msgs := r.pendingReadIndexMessages
|
|
r.pendingReadIndexMessages = nil
|
|
|
|
for _, m := range msgs {
|
|
sendMsgReadIndexResponse(r, m)
|
|
}
|
|
}
|
|
|
|
func sendMsgReadIndexResponse(r *raft, m pb.Message) {
|
|
// thinking: use an internally defined context instead of the user given context.
|
|
// We can express this in terms of the term and index instead of a user-supplied value.
|
|
// This would allow multiple reads to piggyback on the same message.
|
|
switch r.readOnly.option {
|
|
// If more than the local vote is needed, go through a full broadcast.
|
|
case ReadOnlySafe:
|
|
r.readOnly.addRequest(r.raftLog.committed, m)
|
|
// The local node automatically acks the request.
|
|
r.readOnly.recvAck(r.id, m.Entries[0].Data)
|
|
r.bcastHeartbeatWithCtx(m.Entries[0].Data)
|
|
case ReadOnlyLeaseBased:
|
|
if resp := r.responseToReadIndexReq(m, r.raftLog.committed); resp.To != None {
|
|
r.send(resp)
|
|
}
|
|
}
|
|
}
|