vendor/go.etcd.io/etcd/raft/rawnode.go - voltha-go - Gitiles

 // Copyright 2015 The etcd Authors
 //
 // 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"

 	pb "go.etcd.io/etcd/raft/raftpb"
 	"go.etcd.io/etcd/raft/tracker"
 )

 // ErrStepLocalMsg is returned when try to step a local raft message
 var ErrStepLocalMsg = errors.New("raft: cannot step raft local message")

 // ErrStepPeerNotFound is returned when try to step a response message
 // but there is no peer found in raft.prs for that node.
 var ErrStepPeerNotFound = errors.New("raft: cannot step as peer not found")

 // RawNode is a thread-unsafe Node.
 // The methods of this struct correspond to the methods of Node and are described
 // more fully there.
 type RawNode struct {
 	raft       *raft
 	prevSoftSt *SoftState
 	prevHardSt pb.HardState
 }

 // NewRawNode instantiates a RawNode from the given configuration.
 //
 // See Bootstrap() for bootstrapping an initial state; this replaces the former
 // 'peers' argument to this method (with identical behavior). However, It is
 // recommended that instead of calling Bootstrap, applications bootstrap their
 // state manually by setting up a Storage that has a first index > 1 and which
 // stores the desired ConfState as its InitialState.
 func NewRawNode(config *Config) (*RawNode, error) {
 	r := newRaft(config)
 	rn := &RawNode{
 		raft: r,
 	}
 	rn.prevSoftSt = r.softState()
 	rn.prevHardSt = r.hardState()
 	return rn, nil
 }

 // Tick advances the internal logical clock by a single tick.
 func (rn *RawNode) Tick() {
 	rn.raft.tick()
 }

 // TickQuiesced advances the internal logical clock by a single tick without
 // performing any other state machine processing. It allows the caller to avoid
 // periodic heartbeats and elections when all of the peers in a Raft group are
 // known to be at the same state. Expected usage is to periodically invoke Tick
 // or TickQuiesced depending on whether the group is "active" or "quiesced".
 //
 // WARNING: Be very careful about using this method as it subverts the Raft
 // state machine. You should probably be using Tick instead.
 func (rn *RawNode) TickQuiesced() {
 	rn.raft.electionElapsed++
 }

 // Campaign causes this RawNode to transition to candidate state.
 func (rn *RawNode) Campaign() error {
 	return rn.raft.Step(pb.Message{
 		Type: pb.MsgHup,
 	})
 }

 // Propose proposes data be appended to the raft log.
 func (rn *RawNode) Propose(data []byte) error {
 	return rn.raft.Step(pb.Message{
 		Type: pb.MsgProp,
 		From: rn.raft.id,
 		Entries: []pb.Entry{
 			{Data: data},
 		}})
 }

 // ProposeConfChange proposes a config change. See (Node).ProposeConfChange for
 // details.
 func (rn *RawNode) ProposeConfChange(cc pb.ConfChangeI) error {
 	m, err := confChangeToMsg(cc)
 	if err != nil {
 		return err
 	}
 	return rn.raft.Step(m)
 }

 // ApplyConfChange applies a config change to the local node.
 func (rn *RawNode) ApplyConfChange(cc pb.ConfChangeI) *pb.ConfState {
 	cs := rn.raft.applyConfChange(cc.AsV2())
 	return &cs
 }

 // Step advances the state machine using the given message.
 func (rn *RawNode) Step(m pb.Message) error {
 	// ignore unexpected local messages receiving over network
 	if IsLocalMsg(m.Type) {
 		return ErrStepLocalMsg
 	}
 	if pr := rn.raft.prs.Progress[m.From]; pr != nil || !IsResponseMsg(m.Type) {
 		return rn.raft.Step(m)
 	}
 	return ErrStepPeerNotFound
 }

 // Ready returns the outstanding work that the application needs to handle. This
 // includes appending and applying entries or a snapshot, updating the HardState,
 // and sending messages. The returned Ready() *must* be handled and subsequently
 // passed back via Advance().
 func (rn *RawNode) Ready() Ready {
 	rd := rn.readyWithoutAccept()
 	rn.acceptReady(rd)
 	return rd
 }

 // readyWithoutAccept returns a Ready. This is a read-only operation, i.e. there
 // is no obligation that the Ready must be handled.
 func (rn *RawNode) readyWithoutAccept() Ready {
 	return newReady(rn.raft, rn.prevSoftSt, rn.prevHardSt)
 }

 // acceptReady is called when the consumer of the RawNode has decided to go
 // ahead and handle a Ready. Nothing must alter the state of the RawNode between
 // this call and the prior call to Ready().
 func (rn *RawNode) acceptReady(rd Ready) {
 	if rd.SoftState != nil {
 		rn.prevSoftSt = rd.SoftState
 	}
 	if len(rd.ReadStates) != 0 {
 		rn.raft.readStates = nil
 	}
 	rn.raft.msgs = nil
 }

 // HasReady called when RawNode user need to check if any Ready pending.
 // Checking logic in this method should be consistent with Ready.containsUpdates().
 func (rn *RawNode) HasReady() bool {
 	r := rn.raft
 	if !r.softState().equal(rn.prevSoftSt) {
 		return true
 	}
 	if hardSt := r.hardState(); !IsEmptyHardState(hardSt) && !isHardStateEqual(hardSt, rn.prevHardSt) {
 		return true
 	}
 	if r.raftLog.unstable.snapshot != nil && !IsEmptySnap(*r.raftLog.unstable.snapshot) {
 		return true
 	}
 	if len(r.msgs) > 0 || len(r.raftLog.unstableEntries()) > 0 || r.raftLog.hasNextEnts() {
 		return true
 	}
 	if len(r.readStates) != 0 {
 		return true
 	}
 	return false
 }

 // Advance notifies the RawNode that the application has applied and saved progress in the
 // last Ready results.
 func (rn *RawNode) Advance(rd Ready) {
 	if !IsEmptyHardState(rd.HardState) {
 		rn.prevHardSt = rd.HardState
 	}
 	rn.raft.advance(rd)
 }

 // Status returns the current status of the given group. This allocates, see
 // BasicStatus and WithProgress for allocation-friendlier choices.
 func (rn *RawNode) Status() Status {
 	status := getStatus(rn.raft)
 	return status
 }

 // BasicStatus returns a BasicStatus. Notably this does not contain the
 // Progress map; see WithProgress for an allocation-free way to inspect it.
 func (rn *RawNode) BasicStatus() BasicStatus {
 	return getBasicStatus(rn.raft)
 }

 // ProgressType indicates the type of replica a Progress corresponds to.
 type ProgressType byte

 const (
 	// ProgressTypePeer accompanies a Progress for a regular peer replica.
 	ProgressTypePeer ProgressType = iota
 	// ProgressTypeLearner accompanies a Progress for a learner replica.
 	ProgressTypeLearner
 )

 // WithProgress is a helper to introspect the Progress for this node and its
 // peers.
 func (rn *RawNode) WithProgress(visitor func(id uint64, typ ProgressType, pr tracker.Progress)) {
 	rn.raft.prs.Visit(func(id uint64, pr *tracker.Progress) {
 		typ := ProgressTypePeer
 		if pr.IsLearner {
 			typ = ProgressTypeLearner
 		}
 		p := *pr
 		p.Inflights = nil
 		visitor(id, typ, p)
 	})
 }

 // ReportUnreachable reports the given node is not reachable for the last send.
 func (rn *RawNode) ReportUnreachable(id uint64) {
 	_ = rn.raft.Step(pb.Message{Type: pb.MsgUnreachable, From: id})
 }

 // ReportSnapshot reports the status of the sent snapshot.
 func (rn *RawNode) ReportSnapshot(id uint64, status SnapshotStatus) {
 	rej := status == SnapshotFailure

 	_ = rn.raft.Step(pb.Message{Type: pb.MsgSnapStatus, From: id, Reject: rej})
 }

 // TransferLeader tries to transfer leadership to the given transferee.
 func (rn *RawNode) TransferLeader(transferee uint64) {
 	_ = rn.raft.Step(pb.Message{Type: pb.MsgTransferLeader, From: transferee})
 }

 // ReadIndex requests a read state. The read state will be set in ready.
 // Read State has a read index. Once the application advances further than the read
 // index, any linearizable read requests issued before the read request can be
 // processed safely. The read state will have the same rctx attached.
 func (rn *RawNode) ReadIndex(rctx []byte) {
 	_ = rn.raft.Step(pb.Message{Type: pb.MsgReadIndex, Entries: []pb.Entry{{Data: rctx}}})
 }
	// Copyright 2015 The etcd Authors
	//
	// 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"

	pb "go.etcd.io/etcd/raft/raftpb"
	"go.etcd.io/etcd/raft/tracker"
	)

	// ErrStepLocalMsg is returned when try to step a local raft message
	var ErrStepLocalMsg = errors.New("raft: cannot step raft local message")

	// ErrStepPeerNotFound is returned when try to step a response message
	// but there is no peer found in raft.prs for that node.
	var ErrStepPeerNotFound = errors.New("raft: cannot step as peer not found")

	// RawNode is a thread-unsafe Node.
	// The methods of this struct correspond to the methods of Node and are described
	// more fully there.
	type RawNode struct {
	raft *raft
	prevSoftSt *SoftState
	prevHardSt pb.HardState
	}

	// NewRawNode instantiates a RawNode from the given configuration.
	//
	// See Bootstrap() for bootstrapping an initial state; this replaces the former
	// 'peers' argument to this method (with identical behavior). However, It is
	// recommended that instead of calling Bootstrap, applications bootstrap their
	// state manually by setting up a Storage that has a first index > 1 and which
	// stores the desired ConfState as its InitialState.
	func NewRawNode(config Config) (RawNode, error) {
	r := newRaft(config)
	rn := &RawNode{
	raft: r,
	}
	rn.prevSoftSt = r.softState()
	rn.prevHardSt = r.hardState()
	return rn, nil
	}

	// Tick advances the internal logical clock by a single tick.
	func (rn *RawNode) Tick() {
	rn.raft.tick()
	}

	// TickQuiesced advances the internal logical clock by a single tick without
	// performing any other state machine processing. It allows the caller to avoid
	// periodic heartbeats and elections when all of the peers in a Raft group are
	// known to be at the same state. Expected usage is to periodically invoke Tick
	// or TickQuiesced depending on whether the group is "active" or "quiesced".
	//
	// WARNING: Be very careful about using this method as it subverts the Raft
	// state machine. You should probably be using Tick instead.
	func (rn *RawNode) TickQuiesced() {
	rn.raft.electionElapsed++
	}

	// Campaign causes this RawNode to transition to candidate state.
	func (rn *RawNode) Campaign() error {
	return rn.raft.Step(pb.Message{
	Type: pb.MsgHup,
	})
	}

	// Propose proposes data be appended to the raft log.
	func (rn *RawNode) Propose(data []byte) error {
	return rn.raft.Step(pb.Message{
	Type: pb.MsgProp,
	From: rn.raft.id,
	Entries: []pb.Entry{
	{Data: data},
	}})
	}

	// ProposeConfChange proposes a config change. See (Node).ProposeConfChange for
	// details.
	func (rn *RawNode) ProposeConfChange(cc pb.ConfChangeI) error {
	m, err := confChangeToMsg(cc)
	if err != nil {
	return err
	}
	return rn.raft.Step(m)
	}

	// ApplyConfChange applies a config change to the local node.
	func (rn RawNode) ApplyConfChange(cc pb.ConfChangeI) pb.ConfState {
	cs := rn.raft.applyConfChange(cc.AsV2())
	return &cs
	}

	// Step advances the state machine using the given message.
	func (rn *RawNode) Step(m pb.Message) error {
	// ignore unexpected local messages receiving over network
	if IsLocalMsg(m.Type) {
	return ErrStepLocalMsg
	}
	if pr := rn.raft.prs.Progress[m.From]; pr != nil \|\| !IsResponseMsg(m.Type) {
	return rn.raft.Step(m)
	}
	return ErrStepPeerNotFound
	}

	// Ready returns the outstanding work that the application needs to handle. This
	// includes appending and applying entries or a snapshot, updating the HardState,
	// and sending messages. The returned Ready() must be handled and subsequently
	// passed back via Advance().
	func (rn *RawNode) Ready() Ready {
	rd := rn.readyWithoutAccept()
	rn.acceptReady(rd)
	return rd
	}

	// readyWithoutAccept returns a Ready. This is a read-only operation, i.e. there
	// is no obligation that the Ready must be handled.
	func (rn *RawNode) readyWithoutAccept() Ready {
	return newReady(rn.raft, rn.prevSoftSt, rn.prevHardSt)
	}

	// acceptReady is called when the consumer of the RawNode has decided to go
	// ahead and handle a Ready. Nothing must alter the state of the RawNode between
	// this call and the prior call to Ready().
	func (rn *RawNode) acceptReady(rd Ready) {
	if rd.SoftState != nil {
	rn.prevSoftSt = rd.SoftState
	}
	if len(rd.ReadStates) != 0 {
	rn.raft.readStates = nil
	}
	rn.raft.msgs = nil
	}

	// HasReady called when RawNode user need to check if any Ready pending.
	// Checking logic in this method should be consistent with Ready.containsUpdates().
	func (rn *RawNode) HasReady() bool {
	r := rn.raft
	if !r.softState().equal(rn.prevSoftSt) {
	return true
	}
	if hardSt := r.hardState(); !IsEmptyHardState(hardSt) && !isHardStateEqual(hardSt, rn.prevHardSt) {
	return true
	}
	if r.raftLog.unstable.snapshot != nil && !IsEmptySnap(*r.raftLog.unstable.snapshot) {
	return true
	}
	if len(r.msgs) > 0 \|\| len(r.raftLog.unstableEntries()) > 0 \|\| r.raftLog.hasNextEnts() {
	return true
	}
	if len(r.readStates) != 0 {
	return true
	}
	return false
	}

	// Advance notifies the RawNode that the application has applied and saved progress in the
	// last Ready results.
	func (rn *RawNode) Advance(rd Ready) {
	if !IsEmptyHardState(rd.HardState) {
	rn.prevHardSt = rd.HardState
	}
	rn.raft.advance(rd)
	}

	// Status returns the current status of the given group. This allocates, see
	// BasicStatus and WithProgress for allocation-friendlier choices.
	func (rn *RawNode) Status() Status {
	status := getStatus(rn.raft)
	return status
	}

	// BasicStatus returns a BasicStatus. Notably this does not contain the
	// Progress map; see WithProgress for an allocation-free way to inspect it.
	func (rn *RawNode) BasicStatus() BasicStatus {
	return getBasicStatus(rn.raft)
	}

	// ProgressType indicates the type of replica a Progress corresponds to.
	type ProgressType byte

	const (
	// ProgressTypePeer accompanies a Progress for a regular peer replica.
	ProgressTypePeer ProgressType = iota
	// ProgressTypeLearner accompanies a Progress for a learner replica.
	ProgressTypeLearner
	)

	// WithProgress is a helper to introspect the Progress for this node and its
	// peers.
	func (rn *RawNode) WithProgress(visitor func(id uint64, typ ProgressType, pr tracker.Progress)) {
	rn.raft.prs.Visit(func(id uint64, pr *tracker.Progress) {
	typ := ProgressTypePeer
	if pr.IsLearner {
	typ = ProgressTypeLearner
	}
	p := *pr
	p.Inflights = nil
	visitor(id, typ, p)
	})
	}

	// ReportUnreachable reports the given node is not reachable for the last send.
	func (rn *RawNode) ReportUnreachable(id uint64) {
	_ = rn.raft.Step(pb.Message{Type: pb.MsgUnreachable, From: id})
	}

	// ReportSnapshot reports the status of the sent snapshot.
	func (rn *RawNode) ReportSnapshot(id uint64, status SnapshotStatus) {
	rej := status == SnapshotFailure

	_ = rn.raft.Step(pb.Message{Type: pb.MsgSnapStatus, From: id, Reject: rej})
	}

	// TransferLeader tries to transfer leadership to the given transferee.
	func (rn *RawNode) TransferLeader(transferee uint64) {
	_ = rn.raft.Step(pb.Message{Type: pb.MsgTransferLeader, From: transferee})
	}

	// ReadIndex requests a read state. The read state will be set in ready.
	// Read State has a read index. Once the application advances further than the read
	// index, any linearizable read requests issued before the read request can be
	// processed safely. The read state will have the same rctx attached.
	func (rn *RawNode) ReadIndex(rctx []byte) {
	_ = rn.raft.Step(pb.Message{Type: pb.MsgReadIndex, Entries: []pb.Entry{{Data: rctx}}})
	}