package consensus import ( "bytes" "context" "fmt" "reflect" "sync" "time" "github.com/pkg/errors" wire "github.com/tendermint/go-wire" cmn "github.com/tendermint/tmlibs/common" "github.com/tendermint/tmlibs/log" cstypes "github.com/tendermint/tendermint/consensus/types" "github.com/tendermint/tendermint/p2p" sm "github.com/tendermint/tendermint/state" "github.com/tendermint/tendermint/types" ) const ( StateChannel = byte(0x20) DataChannel = byte(0x21) VoteChannel = byte(0x22) VoteSetBitsChannel = byte(0x23) maxConsensusMessageSize = 1048576 // 1MB; NOTE/TODO: keep in sync with types.PartSet sizes. ) //----------------------------------------------------------------------------- // ConsensusReactor defines a reactor for the consensus service. type ConsensusReactor struct { p2p.BaseReactor // BaseService + p2p.Switch conS *ConsensusState mtx sync.RWMutex fastSync bool eventBus *types.EventBus } // NewConsensusReactor returns a new ConsensusReactor with the given consensusState. func NewConsensusReactor(consensusState *ConsensusState, fastSync bool) *ConsensusReactor { conR := &ConsensusReactor{ conS: consensusState, fastSync: fastSync, } conR.BaseReactor = *p2p.NewBaseReactor("ConsensusReactor", conR) return conR } // OnStart implements BaseService. func (conR *ConsensusReactor) OnStart() error { conR.Logger.Info("ConsensusReactor ", "fastSync", conR.FastSync()) conR.BaseReactor.OnStart() err := conR.startBroadcastRoutine() if err != nil { return err } if !conR.FastSync() { _, err := conR.conS.Start() if err != nil { return err } } return nil } // OnStop implements BaseService func (conR *ConsensusReactor) OnStop() { conR.BaseReactor.OnStop() conR.conS.Stop() } // SwitchToConsensus switches from fast_sync mode to consensus mode. // It resets the state, turns off fast_sync, and starts the consensus state-machine func (conR *ConsensusReactor) SwitchToConsensus(state *sm.State, blocksSynced int) { conR.Logger.Info("SwitchToConsensus") conR.conS.reconstructLastCommit(state) // NOTE: The line below causes broadcastNewRoundStepRoutine() to // broadcast a NewRoundStepMessage. conR.conS.updateToState(state) conR.mtx.Lock() conR.fastSync = false conR.mtx.Unlock() if blocksSynced > 0 { // dont bother with the WAL if we fast synced conR.conS.doWALCatchup = false } conR.conS.Start() } // GetChannels implements Reactor func (conR *ConsensusReactor) GetChannels() []*p2p.ChannelDescriptor { // TODO optimize return []*p2p.ChannelDescriptor{ &p2p.ChannelDescriptor{ ID: StateChannel, Priority: 5, SendQueueCapacity: 100, }, &p2p.ChannelDescriptor{ ID: DataChannel, // maybe split between gossiping current block and catchup stuff Priority: 10, // once we gossip the whole block there's nothing left to send until next height or round SendQueueCapacity: 100, RecvBufferCapacity: 50 * 4096, }, &p2p.ChannelDescriptor{ ID: VoteChannel, Priority: 5, SendQueueCapacity: 100, RecvBufferCapacity: 100 * 100, }, &p2p.ChannelDescriptor{ ID: VoteSetBitsChannel, Priority: 1, SendQueueCapacity: 2, RecvBufferCapacity: 1024, }, } } // AddPeer implements Reactor func (conR *ConsensusReactor) AddPeer(peer p2p.Peer) { if !conR.IsRunning() { return } // Create peerState for peer peerState := NewPeerState(peer).SetLogger(conR.Logger) peer.Set(types.PeerStateKey, peerState) // Begin routines for this peer. go conR.gossipDataRoutine(peer, peerState) go conR.gossipVotesRoutine(peer, peerState) go conR.queryMaj23Routine(peer, peerState) // Send our state to peer. // If we're fast_syncing, broadcast a RoundStepMessage later upon SwitchToConsensus(). if !conR.FastSync() { conR.sendNewRoundStepMessages(peer) } } // RemovePeer implements Reactor func (conR *ConsensusReactor) RemovePeer(peer p2p.Peer, reason interface{}) { if !conR.IsRunning() { return } // TODO //peer.Get(PeerStateKey).(*PeerState).Disconnect() } // Receive implements Reactor // NOTE: We process these messages even when we're fast_syncing. // Messages affect either a peer state or the consensus state. // Peer state updates can happen in parallel, but processing of // proposals, block parts, and votes are ordered by the receiveRoutine // NOTE: blocks on consensus state for proposals, block parts, and votes func (conR *ConsensusReactor) Receive(chID byte, src p2p.Peer, msgBytes []byte) { if !conR.IsRunning() { conR.Logger.Debug("Receive", "src", src, "chId", chID, "bytes", msgBytes) return } _, msg, err := DecodeMessage(msgBytes) if err != nil { conR.Logger.Error("Error decoding message", "src", src, "chId", chID, "msg", msg, "err", err, "bytes", msgBytes) // TODO punish peer? return } conR.Logger.Debug("Receive", "src", src, "chId", chID, "msg", msg) // Get peer states ps := src.Get(types.PeerStateKey).(*PeerState) switch chID { case StateChannel: switch msg := msg.(type) { case *NewRoundStepMessage: ps.ApplyNewRoundStepMessage(msg) case *CommitStepMessage: ps.ApplyCommitStepMessage(msg) case *HasVoteMessage: ps.ApplyHasVoteMessage(msg) case *VoteSetMaj23Message: cs := conR.conS cs.mtx.Lock() height, votes := cs.Height, cs.Votes cs.mtx.Unlock() if height != msg.Height { return } // Peer claims to have a maj23 for some BlockID at H,R,S, votes.SetPeerMaj23(msg.Round, msg.Type, ps.Peer.Key(), msg.BlockID) // Respond with a VoteSetBitsMessage showing which votes we have. // (and consequently shows which we don't have) var ourVotes *cmn.BitArray switch msg.Type { case types.VoteTypePrevote: ourVotes = votes.Prevotes(msg.Round).BitArrayByBlockID(msg.BlockID) case types.VoteTypePrecommit: ourVotes = votes.Precommits(msg.Round).BitArrayByBlockID(msg.BlockID) default: conR.Logger.Error("Bad VoteSetBitsMessage field Type") return } src.TrySend(VoteSetBitsChannel, struct{ ConsensusMessage }{&VoteSetBitsMessage{ Height: msg.Height, Round: msg.Round, Type: msg.Type, BlockID: msg.BlockID, Votes: ourVotes, }}) case *ProposalHeartbeatMessage: hb := msg.Heartbeat conR.Logger.Debug("Received proposal heartbeat message", "height", hb.Height, "round", hb.Round, "sequence", hb.Sequence, "valIdx", hb.ValidatorIndex, "valAddr", hb.ValidatorAddress) default: conR.Logger.Error(cmn.Fmt("Unknown message type %v", reflect.TypeOf(msg))) } case DataChannel: if conR.FastSync() { conR.Logger.Info("Ignoring message received during fastSync", "msg", msg) return } switch msg := msg.(type) { case *ProposalMessage: ps.SetHasProposal(msg.Proposal) conR.conS.peerMsgQueue <- msgInfo{msg, src.Key()} case *ProposalPOLMessage: ps.ApplyProposalPOLMessage(msg) case *BlockPartMessage: ps.SetHasProposalBlockPart(msg.Height, msg.Round, msg.Part.Index) conR.conS.peerMsgQueue <- msgInfo{msg, src.Key()} default: conR.Logger.Error(cmn.Fmt("Unknown message type %v", reflect.TypeOf(msg))) } case VoteChannel: if conR.FastSync() { conR.Logger.Info("Ignoring message received during fastSync", "msg", msg) return } switch msg := msg.(type) { case *VoteMessage: cs := conR.conS cs.mtx.Lock() height, valSize, lastCommitSize := cs.Height, cs.Validators.Size(), cs.LastCommit.Size() cs.mtx.Unlock() ps.EnsureVoteBitArrays(height, valSize) ps.EnsureVoteBitArrays(height-1, lastCommitSize) ps.SetHasVote(msg.Vote) cs.peerMsgQueue <- msgInfo{msg, src.Key()} default: // don't punish (leave room for soft upgrades) conR.Logger.Error(cmn.Fmt("Unknown message type %v", reflect.TypeOf(msg))) } case VoteSetBitsChannel: if conR.FastSync() { conR.Logger.Info("Ignoring message received during fastSync", "msg", msg) return } switch msg := msg.(type) { case *VoteSetBitsMessage: cs := conR.conS cs.mtx.Lock() height, votes := cs.Height, cs.Votes cs.mtx.Unlock() if height == msg.Height { var ourVotes *cmn.BitArray switch msg.Type { case types.VoteTypePrevote: ourVotes = votes.Prevotes(msg.Round).BitArrayByBlockID(msg.BlockID) case types.VoteTypePrecommit: ourVotes = votes.Precommits(msg.Round).BitArrayByBlockID(msg.BlockID) default: conR.Logger.Error("Bad VoteSetBitsMessage field Type") return } ps.ApplyVoteSetBitsMessage(msg, ourVotes) } else { ps.ApplyVoteSetBitsMessage(msg, nil) } default: // don't punish (leave room for soft upgrades) conR.Logger.Error(cmn.Fmt("Unknown message type %v", reflect.TypeOf(msg))) } default: conR.Logger.Error(cmn.Fmt("Unknown chId %X", chID)) } if err != nil { conR.Logger.Error("Error in Receive()", "err", err) } } // SetEventBus sets event bus. func (conR *ConsensusReactor) SetEventBus(b *types.EventBus) { conR.eventBus = b conR.conS.SetEventBus(b) } // FastSync returns whether the consensus reactor is in fast-sync mode. func (conR *ConsensusReactor) FastSync() bool { conR.mtx.RLock() defer conR.mtx.RUnlock() return conR.fastSync } //-------------------------------------- // startBroadcastRoutine subscribes for new round steps, votes and proposal // heartbeats using the event bus and starts a go routine to broadcasts events // to peers upon receiving them. func (conR *ConsensusReactor) startBroadcastRoutine() error { const subscriber = "consensus-reactor" ctx := context.Background() // new round steps stepsCh := make(chan interface{}) err := conR.eventBus.Subscribe(ctx, subscriber, types.EventQueryNewRoundStep, stepsCh) if err != nil { return errors.Wrapf(err, "failed to subscribe %s to %s", subscriber, types.EventQueryNewRoundStep) } // votes votesCh := make(chan interface{}) err = conR.eventBus.Subscribe(ctx, subscriber, types.EventQueryVote, votesCh) if err != nil { return errors.Wrapf(err, "failed to subscribe %s to %s", subscriber, types.EventQueryVote) } // proposal heartbeats heartbeatsCh := make(chan interface{}) err = conR.eventBus.Subscribe(ctx, subscriber, types.EventQueryProposalHeartbeat, heartbeatsCh) if err != nil { return errors.Wrapf(err, "failed to subscribe %s to %s", subscriber, types.EventQueryProposalHeartbeat) } go func() { for { select { case data, ok := <-stepsCh: if ok { // a receive from a closed channel returns the zero value immediately edrs := data.(types.TMEventData).Unwrap().(types.EventDataRoundState) conR.broadcastNewRoundStep(edrs.RoundState.(*cstypes.RoundState)) } case data, ok := <-votesCh: if ok { edv := data.(types.TMEventData).Unwrap().(types.EventDataVote) conR.broadcastHasVoteMessage(edv.Vote) } case data, ok := <-heartbeatsCh: if ok { edph := data.(types.TMEventData).Unwrap().(types.EventDataProposalHeartbeat) conR.broadcastProposalHeartbeatMessage(edph) } case <-conR.Quit: conR.eventBus.UnsubscribeAll(ctx, subscriber) return } } }() return nil } func (conR *ConsensusReactor) broadcastProposalHeartbeatMessage(heartbeat types.EventDataProposalHeartbeat) { hb := heartbeat.Heartbeat conR.Logger.Debug("Broadcasting proposal heartbeat message", "height", hb.Height, "round", hb.Round, "sequence", hb.Sequence) msg := &ProposalHeartbeatMessage{hb} conR.Switch.Broadcast(StateChannel, struct{ ConsensusMessage }{msg}) } func (conR *ConsensusReactor) broadcastNewRoundStep(rs *cstypes.RoundState) { nrsMsg, csMsg := makeRoundStepMessages(rs) if nrsMsg != nil { conR.Switch.Broadcast(StateChannel, struct{ ConsensusMessage }{nrsMsg}) } if csMsg != nil { conR.Switch.Broadcast(StateChannel, struct{ ConsensusMessage }{csMsg}) } } // Broadcasts HasVoteMessage to peers that care. func (conR *ConsensusReactor) broadcastHasVoteMessage(vote *types.Vote) { msg := &HasVoteMessage{ Height: vote.Height, Round: vote.Round, Type: vote.Type, Index: vote.ValidatorIndex, } conR.Switch.Broadcast(StateChannel, struct{ ConsensusMessage }{msg}) /* // TODO: Make this broadcast more selective. for _, peer := range conR.Switch.Peers().List() { ps := peer.Get(PeerStateKey).(*PeerState) prs := ps.GetRoundState() if prs.Height == vote.Height { // TODO: Also filter on round? peer.TrySend(StateChannel, struct{ ConsensusMessage }{msg}) } else { // Height doesn't match // TODO: check a field, maybe CatchupCommitRound? // TODO: But that requires changing the struct field comment. } } */ } func makeRoundStepMessages(rs *cstypes.RoundState) (nrsMsg *NewRoundStepMessage, csMsg *CommitStepMessage) { nrsMsg = &NewRoundStepMessage{ Height: rs.Height, Round: rs.Round, Step: rs.Step, SecondsSinceStartTime: int(time.Since(rs.StartTime).Seconds()), LastCommitRound: rs.LastCommit.Round(), } if rs.Step == cstypes.RoundStepCommit { csMsg = &CommitStepMessage{ Height: rs.Height, BlockPartsHeader: rs.ProposalBlockParts.Header(), BlockParts: rs.ProposalBlockParts.BitArray(), } } return } func (conR *ConsensusReactor) sendNewRoundStepMessages(peer p2p.Peer) { rs := conR.conS.GetRoundState() nrsMsg, csMsg := makeRoundStepMessages(rs) if nrsMsg != nil { peer.Send(StateChannel, struct{ ConsensusMessage }{nrsMsg}) } if csMsg != nil { peer.Send(StateChannel, struct{ ConsensusMessage }{csMsg}) } } func (conR *ConsensusReactor) gossipDataRoutine(peer p2p.Peer, ps *PeerState) { logger := conR.Logger.With("peer", peer) OUTER_LOOP: for { // Manage disconnects from self or peer. if !peer.IsRunning() || !conR.IsRunning() { logger.Info("Stopping gossipDataRoutine for peer") return } rs := conR.conS.GetRoundState() prs := ps.GetRoundState() // Send proposal Block parts? if rs.ProposalBlockParts.HasHeader(prs.ProposalBlockPartsHeader) { if index, ok := rs.ProposalBlockParts.BitArray().Sub(prs.ProposalBlockParts.Copy()).PickRandom(); ok { part := rs.ProposalBlockParts.GetPart(index) msg := &BlockPartMessage{ Height: rs.Height, // This tells peer that this part applies to us. Round: rs.Round, // This tells peer that this part applies to us. Part: part, } logger.Debug("Sending block part", "height", prs.Height, "round", prs.Round) if peer.Send(DataChannel, struct{ ConsensusMessage }{msg}) { ps.SetHasProposalBlockPart(prs.Height, prs.Round, index) } continue OUTER_LOOP } } // If the peer is on a previous height, help catch up. if (0 < prs.Height) && (prs.Height < rs.Height) { heightLogger := logger.With("height", prs.Height) conR.gossipDataForCatchup(heightLogger, rs, prs, ps, peer) continue OUTER_LOOP } // If height and round don't match, sleep. if (rs.Height != prs.Height) || (rs.Round != prs.Round) { //logger.Info("Peer Height|Round mismatch, sleeping", "peerHeight", prs.Height, "peerRound", prs.Round, "peer", peer) time.Sleep(conR.conS.config.PeerGossipSleep()) continue OUTER_LOOP } // By here, height and round match. // Proposal block parts were already matched and sent if any were wanted. // (These can match on hash so the round doesn't matter) // Now consider sending other things, like the Proposal itself. // Send Proposal && ProposalPOL BitArray? if rs.Proposal != nil && !prs.Proposal { // Proposal: share the proposal metadata with peer. { msg := &ProposalMessage{Proposal: rs.Proposal} logger.Debug("Sending proposal", "height", prs.Height, "round", prs.Round) if peer.Send(DataChannel, struct{ ConsensusMessage }{msg}) { ps.SetHasProposal(rs.Proposal) } } // ProposalPOL: lets peer know which POL votes we have so far. // Peer must receive ProposalMessage first. // rs.Proposal was validated, so rs.Proposal.POLRound <= rs.Round, // so we definitely have rs.Votes.Prevotes(rs.Proposal.POLRound). if 0 <= rs.Proposal.POLRound { msg := &ProposalPOLMessage{ Height: rs.Height, ProposalPOLRound: rs.Proposal.POLRound, ProposalPOL: rs.Votes.Prevotes(rs.Proposal.POLRound).BitArray(), } logger.Debug("Sending POL", "height", prs.Height, "round", prs.Round) peer.Send(DataChannel, struct{ ConsensusMessage }{msg}) } continue OUTER_LOOP } // Nothing to do. Sleep. time.Sleep(conR.conS.config.PeerGossipSleep()) continue OUTER_LOOP } } func (conR *ConsensusReactor) gossipDataForCatchup(logger log.Logger, rs *cstypes.RoundState, prs *cstypes.PeerRoundState, ps *PeerState, peer p2p.Peer) { if index, ok := prs.ProposalBlockParts.Not().PickRandom(); ok { // Ensure that the peer's PartSetHeader is correct blockMeta := conR.conS.blockStore.LoadBlockMeta(prs.Height) if blockMeta == nil { logger.Error("Failed to load block meta", "ourHeight", rs.Height, "blockstoreHeight", conR.conS.blockStore.Height()) time.Sleep(conR.conS.config.PeerGossipSleep()) return } else if !blockMeta.BlockID.PartsHeader.Equals(prs.ProposalBlockPartsHeader) { logger.Info("Peer ProposalBlockPartsHeader mismatch, sleeping", "blockPartsHeader", blockMeta.BlockID.PartsHeader, "peerBlockPartsHeader", prs.ProposalBlockPartsHeader) time.Sleep(conR.conS.config.PeerGossipSleep()) return } // Load the part part := conR.conS.blockStore.LoadBlockPart(prs.Height, index) if part == nil { logger.Error("Could not load part", "index", index, "blockPartsHeader", blockMeta.BlockID.PartsHeader, "peerBlockPartsHeader", prs.ProposalBlockPartsHeader) time.Sleep(conR.conS.config.PeerGossipSleep()) return } // Send the part msg := &BlockPartMessage{ Height: prs.Height, // Not our height, so it doesn't matter. Round: prs.Round, // Not our height, so it doesn't matter. Part: part, } logger.Debug("Sending block part for catchup", "round", prs.Round) if peer.Send(DataChannel, struct{ ConsensusMessage }{msg}) { ps.SetHasProposalBlockPart(prs.Height, prs.Round, index) } return } else { //logger.Info("No parts to send in catch-up, sleeping") time.Sleep(conR.conS.config.PeerGossipSleep()) return } } func (conR *ConsensusReactor) gossipVotesRoutine(peer p2p.Peer, ps *PeerState) { logger := conR.Logger.With("peer", peer) // Simple hack to throttle logs upon sleep. var sleeping = 0 OUTER_LOOP: for { // Manage disconnects from self or peer. if !peer.IsRunning() || !conR.IsRunning() { logger.Info("Stopping gossipVotesRoutine for peer") return } rs := conR.conS.GetRoundState() prs := ps.GetRoundState() switch sleeping { case 1: // First sleep sleeping = 2 case 2: // No more sleep sleeping = 0 } //logger.Debug("gossipVotesRoutine", "rsHeight", rs.Height, "rsRound", rs.Round, // "prsHeight", prs.Height, "prsRound", prs.Round, "prsStep", prs.Step) // If height matches, then send LastCommit, Prevotes, Precommits. if rs.Height == prs.Height { heightLogger := logger.With("height", prs.Height) if conR.gossipVotesForHeight(heightLogger, rs, prs, ps) { continue OUTER_LOOP } } // Special catchup logic. // If peer is lagging by height 1, send LastCommit. if prs.Height != 0 && rs.Height == prs.Height+1 { if ps.PickSendVote(rs.LastCommit) { logger.Debug("Picked rs.LastCommit to send", "height", prs.Height) continue OUTER_LOOP } } // Catchup logic // If peer is lagging by more than 1, send Commit. if prs.Height != 0 && rs.Height >= prs.Height+2 { // Load the block commit for prs.Height, // which contains precommit signatures for prs.Height. commit := conR.conS.blockStore.LoadBlockCommit(prs.Height) logger.Info("Loaded BlockCommit for catch-up", "height", prs.Height, "commit", commit) if ps.PickSendVote(commit) { logger.Debug("Picked Catchup commit to send", "height", prs.Height) continue OUTER_LOOP } } if sleeping == 0 { // We sent nothing. Sleep... sleeping = 1 logger.Debug("No votes to send, sleeping", "rs.Height", rs.Height, "prs.Height", prs.Height, "localPV", rs.Votes.Prevotes(rs.Round).BitArray(), "peerPV", prs.Prevotes, "localPC", rs.Votes.Precommits(rs.Round).BitArray(), "peerPC", prs.Precommits) } else if sleeping == 2 { // Continued sleep... sleeping = 1 } time.Sleep(conR.conS.config.PeerGossipSleep()) continue OUTER_LOOP } } func (conR *ConsensusReactor) gossipVotesForHeight(logger log.Logger, rs *cstypes.RoundState, prs *cstypes.PeerRoundState, ps *PeerState) bool { // If there are lastCommits to send... if prs.Step == cstypes.RoundStepNewHeight { if ps.PickSendVote(rs.LastCommit) { logger.Debug("Picked rs.LastCommit to send") return true } } // If there are prevotes to send... if prs.Step <= cstypes.RoundStepPrevote && prs.Round != -1 && prs.Round <= rs.Round { if ps.PickSendVote(rs.Votes.Prevotes(prs.Round)) { logger.Debug("Picked rs.Prevotes(prs.Round) to send", "round", prs.Round) return true } } // If there are precommits to send... if prs.Step <= cstypes.RoundStepPrecommit && prs.Round != -1 && prs.Round <= rs.Round { if ps.PickSendVote(rs.Votes.Precommits(prs.Round)) { logger.Debug("Picked rs.Precommits(prs.Round) to send", "round", prs.Round) return true } } // If there are POLPrevotes to send... if prs.ProposalPOLRound != -1 { if polPrevotes := rs.Votes.Prevotes(prs.ProposalPOLRound); polPrevotes != nil { if ps.PickSendVote(polPrevotes) { logger.Debug("Picked rs.Prevotes(prs.ProposalPOLRound) to send", "round", prs.ProposalPOLRound) return true } } } return false } // NOTE: `queryMaj23Routine` has a simple crude design since it only comes // into play for liveness when there's a signature DDoS attack happening. func (conR *ConsensusReactor) queryMaj23Routine(peer p2p.Peer, ps *PeerState) { logger := conR.Logger.With("peer", peer) OUTER_LOOP: for { // Manage disconnects from self or peer. if !peer.IsRunning() || !conR.IsRunning() { logger.Info("Stopping queryMaj23Routine for peer") return } // Maybe send Height/Round/Prevotes { rs := conR.conS.GetRoundState() prs := ps.GetRoundState() if rs.Height == prs.Height { if maj23, ok := rs.Votes.Prevotes(prs.Round).TwoThirdsMajority(); ok { peer.TrySend(StateChannel, struct{ ConsensusMessage }{&VoteSetMaj23Message{ Height: prs.Height, Round: prs.Round, Type: types.VoteTypePrevote, BlockID: maj23, }}) time.Sleep(conR.conS.config.PeerQueryMaj23Sleep()) } } } // Maybe send Height/Round/Precommits { rs := conR.conS.GetRoundState() prs := ps.GetRoundState() if rs.Height == prs.Height { if maj23, ok := rs.Votes.Precommits(prs.Round).TwoThirdsMajority(); ok { peer.TrySend(StateChannel, struct{ ConsensusMessage }{&VoteSetMaj23Message{ Height: prs.Height, Round: prs.Round, Type: types.VoteTypePrecommit, BlockID: maj23, }}) time.Sleep(conR.conS.config.PeerQueryMaj23Sleep()) } } } // Maybe send Height/Round/ProposalPOL { rs := conR.conS.GetRoundState() prs := ps.GetRoundState() if rs.Height == prs.Height && prs.ProposalPOLRound >= 0 { if maj23, ok := rs.Votes.Prevotes(prs.ProposalPOLRound).TwoThirdsMajority(); ok { peer.TrySend(StateChannel, struct{ ConsensusMessage }{&VoteSetMaj23Message{ Height: prs.Height, Round: prs.ProposalPOLRound, Type: types.VoteTypePrevote, BlockID: maj23, }}) time.Sleep(conR.conS.config.PeerQueryMaj23Sleep()) } } } // Little point sending LastCommitRound/LastCommit, // These are fleeting and non-blocking. // Maybe send Height/CatchupCommitRound/CatchupCommit. { prs := ps.GetRoundState() if prs.CatchupCommitRound != -1 && 0 < prs.Height && prs.Height <= conR.conS.blockStore.Height() { commit := conR.conS.LoadCommit(prs.Height) peer.TrySend(StateChannel, struct{ ConsensusMessage }{&VoteSetMaj23Message{ Height: prs.Height, Round: commit.Round(), Type: types.VoteTypePrecommit, BlockID: commit.BlockID, }}) time.Sleep(conR.conS.config.PeerQueryMaj23Sleep()) } } time.Sleep(conR.conS.config.PeerQueryMaj23Sleep()) continue OUTER_LOOP } } // String returns a string representation of the ConsensusReactor. // NOTE: For now, it is just a hard-coded string to avoid accessing unprotected shared variables. // TODO: improve! func (conR *ConsensusReactor) String() string { // better not to access shared variables return "ConsensusReactor" // conR.StringIndented("") } // StringIndented returns an indented string representation of the ConsensusReactor func (conR *ConsensusReactor) StringIndented(indent string) string { s := "ConsensusReactor{\n" s += indent + " " + conR.conS.StringIndented(indent+" ") + "\n" for _, peer := range conR.Switch.Peers().List() { ps := peer.Get(types.PeerStateKey).(*PeerState) s += indent + " " + ps.StringIndented(indent+" ") + "\n" } s += indent + "}" return s } //----------------------------------------------------------------------------- var ( ErrPeerStateHeightRegression = errors.New("Error peer state height regression") ErrPeerStateInvalidStartTime = errors.New("Error peer state invalid startTime") ) // PeerState contains the known state of a peer, including its connection // and threadsafe access to its PeerRoundState. type PeerState struct { Peer p2p.Peer logger log.Logger mtx sync.Mutex cstypes.PeerRoundState } // NewPeerState returns a new PeerState for the given Peer func NewPeerState(peer p2p.Peer) *PeerState { return &PeerState{ Peer: peer, logger: log.NewNopLogger(), PeerRoundState: cstypes.PeerRoundState{ Round: -1, ProposalPOLRound: -1, LastCommitRound: -1, CatchupCommitRound: -1, }, } } func (ps *PeerState) SetLogger(logger log.Logger) *PeerState { ps.logger = logger return ps } // GetRoundState returns an atomic snapshot of the PeerRoundState. // There's no point in mutating it since it won't change PeerState. func (ps *PeerState) GetRoundState() *cstypes.PeerRoundState { ps.mtx.Lock() defer ps.mtx.Unlock() prs := ps.PeerRoundState // copy return &prs } // GetHeight returns an atomic snapshot of the PeerRoundState's height // used by the mempool to ensure peers are caught up before broadcasting new txs func (ps *PeerState) GetHeight() int { ps.mtx.Lock() defer ps.mtx.Unlock() return ps.PeerRoundState.Height } // SetHasProposal sets the given proposal as known for the peer. func (ps *PeerState) SetHasProposal(proposal *types.Proposal) { ps.mtx.Lock() defer ps.mtx.Unlock() if ps.Height != proposal.Height || ps.Round != proposal.Round { return } if ps.Proposal { return } ps.Proposal = true ps.ProposalBlockPartsHeader = proposal.BlockPartsHeader ps.ProposalBlockParts = cmn.NewBitArray(proposal.BlockPartsHeader.Total) ps.ProposalPOLRound = proposal.POLRound ps.ProposalPOL = nil // Nil until ProposalPOLMessage received. } // SetHasProposalBlockPart sets the given block part index as known for the peer. func (ps *PeerState) SetHasProposalBlockPart(height int, round int, index int) { ps.mtx.Lock() defer ps.mtx.Unlock() if ps.Height != height || ps.Round != round { return } ps.ProposalBlockParts.SetIndex(index, true) } // PickSendVote picks a vote and sends it to the peer. // Returns true if vote was sent. func (ps *PeerState) PickSendVote(votes types.VoteSetReader) bool { if vote, ok := ps.PickVoteToSend(votes); ok { msg := &VoteMessage{vote} return ps.Peer.Send(VoteChannel, struct{ ConsensusMessage }{msg}) } return false } // PickVoteToSend picks a vote to send to the peer. // Returns true if a vote was picked. // NOTE: `votes` must be the correct Size() for the Height(). func (ps *PeerState) PickVoteToSend(votes types.VoteSetReader) (vote *types.Vote, ok bool) { ps.mtx.Lock() defer ps.mtx.Unlock() if votes.Size() == 0 { return nil, false } height, round, type_, size := votes.Height(), votes.Round(), votes.Type(), votes.Size() // Lazily set data using 'votes'. if votes.IsCommit() { ps.ensureCatchupCommitRound(height, round, size) } ps.ensureVoteBitArrays(height, size) psVotes := ps.getVoteBitArray(height, round, type_) if psVotes == nil { return nil, false // Not something worth sending } if index, ok := votes.BitArray().Sub(psVotes).PickRandom(); ok { ps.setHasVote(height, round, type_, index) return votes.GetByIndex(index), true } return nil, false } func (ps *PeerState) getVoteBitArray(height, round int, type_ byte) *cmn.BitArray { if !types.IsVoteTypeValid(type_) { return nil } if ps.Height == height { if ps.Round == round { switch type_ { case types.VoteTypePrevote: return ps.Prevotes case types.VoteTypePrecommit: return ps.Precommits } } if ps.CatchupCommitRound == round { switch type_ { case types.VoteTypePrevote: return nil case types.VoteTypePrecommit: return ps.CatchupCommit } } if ps.ProposalPOLRound == round { switch type_ { case types.VoteTypePrevote: return ps.ProposalPOL case types.VoteTypePrecommit: return nil } } return nil } if ps.Height == height+1 { if ps.LastCommitRound == round { switch type_ { case types.VoteTypePrevote: return nil case types.VoteTypePrecommit: return ps.LastCommit } } return nil } return nil } // 'round': A round for which we have a +2/3 commit. func (ps *PeerState) ensureCatchupCommitRound(height, round int, numValidators int) { if ps.Height != height { return } /* NOTE: This is wrong, 'round' could change. e.g. if orig round is not the same as block LastCommit round. if ps.CatchupCommitRound != -1 && ps.CatchupCommitRound != round { cmn.PanicSanity(cmn.Fmt("Conflicting CatchupCommitRound. Height: %v, Orig: %v, New: %v", height, ps.CatchupCommitRound, round)) } */ if ps.CatchupCommitRound == round { return // Nothing to do! } ps.CatchupCommitRound = round if round == ps.Round { ps.CatchupCommit = ps.Precommits } else { ps.CatchupCommit = cmn.NewBitArray(numValidators) } } // EnsureVoteVitArrays ensures the bit-arrays have been allocated for tracking // what votes this peer has received. // NOTE: It's important to make sure that numValidators actually matches // what the node sees as the number of validators for height. func (ps *PeerState) EnsureVoteBitArrays(height int, numValidators int) { ps.mtx.Lock() defer ps.mtx.Unlock() ps.ensureVoteBitArrays(height, numValidators) } func (ps *PeerState) ensureVoteBitArrays(height int, numValidators int) { if ps.Height == height { if ps.Prevotes == nil { ps.Prevotes = cmn.NewBitArray(numValidators) } if ps.Precommits == nil { ps.Precommits = cmn.NewBitArray(numValidators) } if ps.CatchupCommit == nil { ps.CatchupCommit = cmn.NewBitArray(numValidators) } if ps.ProposalPOL == nil { ps.ProposalPOL = cmn.NewBitArray(numValidators) } } else if ps.Height == height+1 { if ps.LastCommit == nil { ps.LastCommit = cmn.NewBitArray(numValidators) } } } // SetHasVote sets the given vote as known by the peer func (ps *PeerState) SetHasVote(vote *types.Vote) { ps.mtx.Lock() defer ps.mtx.Unlock() ps.setHasVote(vote.Height, vote.Round, vote.Type, vote.ValidatorIndex) } func (ps *PeerState) setHasVote(height int, round int, type_ byte, index int) { logger := ps.logger.With("peerRound", ps.Round, "height", height, "round", round) logger.Debug("setHasVote(LastCommit)", "lastCommit", ps.LastCommit, "index", index) // NOTE: some may be nil BitArrays -> no side effects. psVotes := ps.getVoteBitArray(height, round, type_) if psVotes != nil { psVotes.SetIndex(index, true) } } // ApplyNewRoundStepMessage updates the peer state for the new round. func (ps *PeerState) ApplyNewRoundStepMessage(msg *NewRoundStepMessage) { ps.mtx.Lock() defer ps.mtx.Unlock() // Ignore duplicates or decreases if CompareHRS(msg.Height, msg.Round, msg.Step, ps.Height, ps.Round, ps.Step) <= 0 { return } // Just remember these values. psHeight := ps.Height psRound := ps.Round //psStep := ps.Step psCatchupCommitRound := ps.CatchupCommitRound psCatchupCommit := ps.CatchupCommit startTime := time.Now().Add(-1 * time.Duration(msg.SecondsSinceStartTime) * time.Second) ps.Height = msg.Height ps.Round = msg.Round ps.Step = msg.Step ps.StartTime = startTime if psHeight != msg.Height || psRound != msg.Round { ps.Proposal = false ps.ProposalBlockPartsHeader = types.PartSetHeader{} ps.ProposalBlockParts = nil ps.ProposalPOLRound = -1 ps.ProposalPOL = nil // We'll update the BitArray capacity later. ps.Prevotes = nil ps.Precommits = nil } if psHeight == msg.Height && psRound != msg.Round && msg.Round == psCatchupCommitRound { // Peer caught up to CatchupCommitRound. // Preserve psCatchupCommit! // NOTE: We prefer to use prs.Precommits if // pr.Round matches pr.CatchupCommitRound. ps.Precommits = psCatchupCommit } if psHeight != msg.Height { // Shift Precommits to LastCommit. if psHeight+1 == msg.Height && psRound == msg.LastCommitRound { ps.LastCommitRound = msg.LastCommitRound ps.LastCommit = ps.Precommits } else { ps.LastCommitRound = msg.LastCommitRound ps.LastCommit = nil } // We'll update the BitArray capacity later. ps.CatchupCommitRound = -1 ps.CatchupCommit = nil } } // ApplyCommitStepMessage updates the peer state for the new commit. func (ps *PeerState) ApplyCommitStepMessage(msg *CommitStepMessage) { ps.mtx.Lock() defer ps.mtx.Unlock() if ps.Height != msg.Height { return } ps.ProposalBlockPartsHeader = msg.BlockPartsHeader ps.ProposalBlockParts = msg.BlockParts } // ApplyProposalPOLMessage updates the peer state for the new proposal POL. func (ps *PeerState) ApplyProposalPOLMessage(msg *ProposalPOLMessage) { ps.mtx.Lock() defer ps.mtx.Unlock() if ps.Height != msg.Height { return } if ps.ProposalPOLRound != msg.ProposalPOLRound { return } // TODO: Merge onto existing ps.ProposalPOL? // We might have sent some prevotes in the meantime. ps.ProposalPOL = msg.ProposalPOL } // ApplyHasVoteMessage updates the peer state for the new vote. func (ps *PeerState) ApplyHasVoteMessage(msg *HasVoteMessage) { ps.mtx.Lock() defer ps.mtx.Unlock() if ps.Height != msg.Height { return } ps.setHasVote(msg.Height, msg.Round, msg.Type, msg.Index) } // ApplyVoteSetBitsMessage updates the peer state for the bit-array of votes // it claims to have for the corresponding BlockID. // `ourVotes` is a BitArray of votes we have for msg.BlockID // NOTE: if ourVotes is nil (e.g. msg.Height < rs.Height), // we conservatively overwrite ps's votes w/ msg.Votes. func (ps *PeerState) ApplyVoteSetBitsMessage(msg *VoteSetBitsMessage, ourVotes *cmn.BitArray) { ps.mtx.Lock() defer ps.mtx.Unlock() votes := ps.getVoteBitArray(msg.Height, msg.Round, msg.Type) if votes != nil { if ourVotes == nil { votes.Update(msg.Votes) } else { otherVotes := votes.Sub(ourVotes) hasVotes := otherVotes.Or(msg.Votes) votes.Update(hasVotes) } } } // String returns a string representation of the PeerState func (ps *PeerState) String() string { return ps.StringIndented("") } // StringIndented returns a string representation of the PeerState func (ps *PeerState) StringIndented(indent string) string { return fmt.Sprintf(`PeerState{ %s Key %v %s PRS %v %s}`, indent, ps.Peer.Key(), indent, ps.PeerRoundState.StringIndented(indent+" "), indent) } //----------------------------------------------------------------------------- // Messages const ( msgTypeNewRoundStep = byte(0x01) msgTypeCommitStep = byte(0x02) msgTypeProposal = byte(0x11) msgTypeProposalPOL = byte(0x12) msgTypeBlockPart = byte(0x13) // both block & POL msgTypeVote = byte(0x14) msgTypeHasVote = byte(0x15) msgTypeVoteSetMaj23 = byte(0x16) msgTypeVoteSetBits = byte(0x17) msgTypeProposalHeartbeat = byte(0x20) ) // ConsensusMessage is a message that can be sent and received on the ConsensusReactor type ConsensusMessage interface{} var _ = wire.RegisterInterface( struct{ ConsensusMessage }{}, wire.ConcreteType{&NewRoundStepMessage{}, msgTypeNewRoundStep}, wire.ConcreteType{&CommitStepMessage{}, msgTypeCommitStep}, wire.ConcreteType{&ProposalMessage{}, msgTypeProposal}, wire.ConcreteType{&ProposalPOLMessage{}, msgTypeProposalPOL}, wire.ConcreteType{&BlockPartMessage{}, msgTypeBlockPart}, wire.ConcreteType{&VoteMessage{}, msgTypeVote}, wire.ConcreteType{&HasVoteMessage{}, msgTypeHasVote}, wire.ConcreteType{&VoteSetMaj23Message{}, msgTypeVoteSetMaj23}, wire.ConcreteType{&VoteSetBitsMessage{}, msgTypeVoteSetBits}, wire.ConcreteType{&ProposalHeartbeatMessage{}, msgTypeProposalHeartbeat}, ) // DecodeMessage decodes the given bytes into a ConsensusMessage. // TODO: check for unnecessary extra bytes at the end. func DecodeMessage(bz []byte) (msgType byte, msg ConsensusMessage, err error) { msgType = bz[0] n := new(int) r := bytes.NewReader(bz) msgI := wire.ReadBinary(struct{ ConsensusMessage }{}, r, maxConsensusMessageSize, n, &err) msg = msgI.(struct{ ConsensusMessage }).ConsensusMessage return } //------------------------------------- // NewRoundStepMessage is sent for every step taken in the ConsensusState. // For every height/round/step transition type NewRoundStepMessage struct { Height int Round int Step cstypes.RoundStepType SecondsSinceStartTime int LastCommitRound int } // String returns a string representation. func (m *NewRoundStepMessage) String() string { return fmt.Sprintf("[NewRoundStep H:%v R:%v S:%v LCR:%v]", m.Height, m.Round, m.Step, m.LastCommitRound) } //------------------------------------- // CommitStepMessage is sent when a block is committed. type CommitStepMessage struct { Height int BlockPartsHeader types.PartSetHeader BlockParts *cmn.BitArray } // String returns a string representation. func (m *CommitStepMessage) String() string { return fmt.Sprintf("[CommitStep H:%v BP:%v BA:%v]", m.Height, m.BlockPartsHeader, m.BlockParts) } //------------------------------------- // ProposalMessage is sent when a new block is proposed. type ProposalMessage struct { Proposal *types.Proposal } // String returns a string representation. func (m *ProposalMessage) String() string { return fmt.Sprintf("[Proposal %v]", m.Proposal) } //------------------------------------- // ProposalPOLMessage is sent when a previous proposal is re-proposed. type ProposalPOLMessage struct { Height int ProposalPOLRound int ProposalPOL *cmn.BitArray } // String returns a string representation. func (m *ProposalPOLMessage) String() string { return fmt.Sprintf("[ProposalPOL H:%v POLR:%v POL:%v]", m.Height, m.ProposalPOLRound, m.ProposalPOL) } //------------------------------------- // BlockPartMessage is sent when gossipping a piece of the proposed block. type BlockPartMessage struct { Height int Round int Part *types.Part } // String returns a string representation. func (m *BlockPartMessage) String() string { return fmt.Sprintf("[BlockPart H:%v R:%v P:%v]", m.Height, m.Round, m.Part) } //------------------------------------- // VoteMessage is sent when voting for a proposal (or lack thereof). type VoteMessage struct { Vote *types.Vote } // String returns a string representation. func (m *VoteMessage) String() string { return fmt.Sprintf("[Vote %v]", m.Vote) } //------------------------------------- // HasVoteMessage is sent to indicate that a particular vote has been received. type HasVoteMessage struct { Height int Round int Type byte Index int } // String returns a string representation. func (m *HasVoteMessage) String() string { return fmt.Sprintf("[HasVote VI:%v V:{%v/%02d/%v} VI:%v]", m.Index, m.Height, m.Round, m.Type, m.Index) } //------------------------------------- // VoteSetMaj23Message is sent to indicate that a given BlockID has seen +2/3 votes. type VoteSetMaj23Message struct { Height int Round int Type byte BlockID types.BlockID } // String returns a string representation. func (m *VoteSetMaj23Message) String() string { return fmt.Sprintf("[VSM23 %v/%02d/%v %v]", m.Height, m.Round, m.Type, m.BlockID) } //------------------------------------- // VoteSetBitsMessage is sent to communicate the bit-array of votes seen for the BlockID. type VoteSetBitsMessage struct { Height int Round int Type byte BlockID types.BlockID Votes *cmn.BitArray } // String returns a string representation. func (m *VoteSetBitsMessage) String() string { return fmt.Sprintf("[VSB %v/%02d/%v %v %v]", m.Height, m.Round, m.Type, m.BlockID, m.Votes) } //------------------------------------- // ProposalHeartbeatMessage is sent to signal that a node is alive and waiting for transactions for a proposal. type ProposalHeartbeatMessage struct { Heartbeat *types.Heartbeat } // String returns a string representation. func (m *ProposalHeartbeatMessage) String() string { return fmt.Sprintf("[HEARTBEAT %v]", m.Heartbeat) }