The core protocol of WoopChain
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woop/consensus/consensus_v2.go

749 lines
25 KiB

package consensus
import (
"time"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/rlp"
protobuf "github.com/golang/protobuf/proto"
"github.com/harmony-one/bls/ffi/go/bls"
"github.com/harmony-one/harmony/api/proto"
msg_pb "github.com/harmony-one/harmony/api/proto/message"
"github.com/harmony-one/harmony/api/service/explorer"
"github.com/harmony-one/harmony/core/types"
bls_cosi "github.com/harmony-one/harmony/crypto/bls"
nodeconfig "github.com/harmony-one/harmony/internal/configs/node"
"github.com/harmony-one/harmony/internal/ctxerror"
"github.com/harmony-one/harmony/internal/utils"
"github.com/harmony-one/harmony/p2p"
"github.com/harmony-one/harmony/p2p/host"
)
// handleMessageUpdate will update the consensus state according to received message
func (consensus *Consensus) handleMessageUpdate(payload []byte) {
if len(payload) == 0 {
return
}
msg := &msg_pb.Message{}
err := protobuf.Unmarshal(payload, msg)
if err != nil {
utils.GetLogInstance().Error("Failed to unmarshal message payload.", "err", err, "consensus", consensus)
return
}
// stop receiving normal message when is in viewchanging
if consensus.mode.Mode() == ViewChanging && msg.Type != msg_pb.MessageType_VIEWCHANGE && msg.Type != msg_pb.MessageType_NEWVIEW {
return
}
switch msg.Type {
case msg_pb.MessageType_ANNOUNCE:
consensus.onAnnounce(msg)
case msg_pb.MessageType_PREPARE:
consensus.onPrepare(msg)
case msg_pb.MessageType_PREPARED:
consensus.onPrepared(msg)
case msg_pb.MessageType_COMMIT:
consensus.onCommit(msg)
case msg_pb.MessageType_COMMITTED:
consensus.onCommitted(msg)
case msg_pb.MessageType_VIEWCHANGE:
consensus.onViewChange(msg)
case msg_pb.MessageType_NEWVIEW:
consensus.onNewView(msg)
}
}
// TODO: move to consensus_leader.go later
func (consensus *Consensus) tryAnnounce(block *types.Block) {
// here we assume the leader should always be update to date
if block.NumberU64() != consensus.blockNum {
utils.GetLogInstance().Debug("tryAnnounce blockNum not match", "blockNum", block.NumberU64(), "myBlockNum", consensus.blockNum)
return
}
if !consensus.PubKey.IsEqual(consensus.LeaderPubKey) {
utils.GetLogInstance().Debug("tryAnnounce key not match", "myKey", consensus.PubKey, "leaderKey", consensus.LeaderPubKey)
return
}
blockHash := block.Hash()
copy(consensus.blockHash[:], blockHash[:])
// prepare message and broadcast to validators
encodedBlock, err := rlp.EncodeToBytes(block)
if err != nil {
utils.GetLogInstance().Debug("tryAnnounce Failed encoding block")
return
}
consensus.block = encodedBlock
msgToSend := consensus.constructAnnounceMessage()
consensus.switchPhase(Prepare)
// save announce message to pbftLog
msgPayload, _ := proto.GetConsensusMessagePayload(msgToSend)
msg := &msg_pb.Message{}
_ = protobuf.Unmarshal(msgPayload, msg)
pbftMsg, err := ParsePbftMessage(msg)
if err != nil {
utils.GetLogInstance().Warn("tryAnnounce unable to parse pbft message", "error", err)
return
}
consensus.pbftLog.AddMessage(pbftMsg)
consensus.pbftLog.AddBlock(block)
// Leader sign the block hash itself
consensus.prepareSigs[consensus.SelfAddress] = consensus.priKey.SignHash(consensus.blockHash[:])
// Construct broadcast p2p message
utils.GetLogInstance().Warn("tryAnnounce", "sent announce message", len(msgToSend), "groupID", p2p.NewGroupIDByShardID(p2p.ShardID(consensus.ShardID)))
consensus.host.SendMessageToGroups([]p2p.GroupID{p2p.NewGroupIDByShardID(p2p.ShardID(consensus.ShardID))}, host.ConstructP2pMessage(byte(17), msgToSend))
}
func (consensus *Consensus) onAnnounce(msg *msg_pb.Message) {
if consensus.PubKey.IsEqual(consensus.LeaderPubKey) {
return
}
senderKey, err := consensus.verifySenderKey(msg)
if err != nil {
utils.GetLogInstance().Debug("onAnnounce verifySenderKey failed", "error", err)
return
}
if !senderKey.IsEqual(consensus.LeaderPubKey) {
utils.GetLogInstance().Warn("onAnnounce senderKey not match leader PubKey", "senderKey", senderKey.GetHexString(), "leaderKey", consensus.LeaderPubKey.GetHexString())
return
}
if err = verifyMessageSig(senderKey, msg); err != nil {
utils.GetLogInstance().Debug("onAnnounce Failed to verify leader signature", "error", err)
return
}
recvMsg, err := ParsePbftMessage(msg)
if err != nil {
utils.GetLogInstance().Debug("onAnnounce Unparseable leader message", "error", err)
return
}
block := recvMsg.Payload
// check block header is valid
var blockObj types.Block
err = rlp.DecodeBytes(block, &blockObj)
if err != nil {
utils.GetLogInstance().Warn("onAnnounce Unparseable block header data", "error", err)
return
}
// check block data transactions
if err := consensus.VerifyHeader(consensus.ChainReader, blockObj.Header(), false); err != nil {
utils.GetLogInstance().Warn("onAnnounce block content is not verified successfully", "error", err)
return
}
if consensus.BlockVerifier == nil {
// do nothing
} else if err := consensus.BlockVerifier(&blockObj); err != nil {
// TODO ek – maybe we could do this in commit phase
err := ctxerror.New("block verification failed",
"blockHash", blockObj.Hash(),
).WithCause(err)
ctxerror.Log15(utils.GetLogInstance().Warn, err)
return
}
logMsgs := consensus.pbftLog.GetMessagesByTypeSeqView(msg_pb.MessageType_ANNOUNCE, recvMsg.BlockNum, recvMsg.ViewID)
if len(logMsgs) > 0 {
if logMsgs[0].BlockHash != blockObj.Header().Hash() {
utils.GetLogInstance().Debug("onAnnounce leader is malicious", "leaderKey", utils.GetBlsAddress(consensus.LeaderPubKey))
consensus.startViewChange(consensus.viewID + 1)
}
return
}
blockPayload := make([]byte, len(block))
copy(blockPayload[:], block[:])
consensus.block = blockPayload
consensus.blockHash = recvMsg.BlockHash
consensus.pbftLog.AddMessage(recvMsg)
consensus.pbftLog.AddBlock(&blockObj)
consensus.tryPrepare(blockObj.Header().Hash())
consensus.consensusTimeout["bootstrap"].Stop()
consensus.consensusTimeout["announce"].Stop()
if !consensus.consensusTimeout["prepare"].IsActive() {
consensus.consensusTimeout["prepare"].Start()
}
return
}
// tryPrepare will try to send prepare message
func (consensus *Consensus) tryPrepare(blockHash common.Hash) {
var hash common.Hash
copy(hash[:], blockHash[:])
block := consensus.pbftLog.GetBlockByHash(hash)
if block == nil {
return
}
if consensus.phase != Announce || consensus.blockNum != block.NumberU64() || !consensus.pbftLog.HasMatchingAnnounce(consensus.blockNum, consensus.viewID, hash) {
return
}
consensus.switchPhase(Prepare)
if !consensus.PubKey.IsEqual(consensus.LeaderPubKey) { //TODO(chao): check whether this is necessary when calling tryPrepare
// Construct and send prepare message
msgToSend := consensus.constructPrepareMessage()
utils.GetLogInstance().Info("tryPrepare", "sent prepare message", len(msgToSend))
consensus.host.SendMessageToGroups([]p2p.GroupID{p2p.NewGroupIDByShardID(p2p.ShardID(consensus.ShardID))}, host.ConstructP2pMessage(byte(17), msgToSend))
}
}
// TODO: move to consensus_leader.go later
func (consensus *Consensus) onPrepare(msg *msg_pb.Message) {
if !consensus.PubKey.IsEqual(consensus.LeaderPubKey) {
return
}
senderKey, err := consensus.verifySenderKey(msg)
if err != nil {
utils.GetLogInstance().Debug("onPrepare verifySenderKey failed", "error", err)
return
}
if err = verifyMessageSig(senderKey, msg); err != nil {
utils.GetLogInstance().Debug("onPrepare Failed to verify sender's signature", "error", err)
return
}
recvMsg, err := ParsePbftMessage(msg)
if err != nil {
utils.GetLogInstance().Debug("[Consensus] onPrepare Unparseable validator message", "error", err)
return
}
if recvMsg.ViewID != consensus.viewID || recvMsg.BlockNum != consensus.blockNum || consensus.phase != Prepare {
utils.GetLogInstance().Debug("onPrepare message not match", "myPhase", consensus.phase, "myViewID", consensus.viewID,
"msgViewID", recvMsg.ViewID, "myBlockNum", consensus.blockNum, "msgBlockNum", recvMsg.BlockNum)
return
}
if !consensus.pbftLog.HasMatchingAnnounce(consensus.blockNum, consensus.viewID, recvMsg.BlockHash) {
utils.GetLogInstance().Debug("onPrepare no matching announce message", "blockNum", consensus.blockNum, "viewID", consensus.viewID, "blockHash", recvMsg.BlockHash)
return
}
validatorPubKey := recvMsg.SenderPubkey
addrBytes := validatorPubKey.GetAddress()
validatorAddress := common.BytesToAddress(addrBytes[:])
prepareSig := recvMsg.Payload
prepareSigs := consensus.prepareSigs
prepareBitmap := consensus.prepareBitmap
consensus.mutex.Lock()
defer consensus.mutex.Unlock()
if len(prepareSigs) >= ((len(consensus.PublicKeys)*2)/3 + 1) {
// already have enough signatures
return
}
// proceed only when the message is not received before
_, ok := prepareSigs[validatorAddress]
if ok {
utils.GetLogInstance().Debug("Already received prepare message from the validator", "validatorAddress", validatorAddress)
return
}
// Check BLS signature for the multi-sig
var sign bls.Sign
err = sign.Deserialize(prepareSig)
if err != nil {
utils.GetLogInstance().Error("Failed to deserialize bls signature", "validatorAddress", validatorAddress)
return
}
if !sign.VerifyHash(validatorPubKey, consensus.blockHash[:]) {
utils.GetLogInstance().Error("Received invalid BLS signature", "validatorAddress", validatorAddress)
return
}
utils.GetLogInstance().Debug("Received new prepare signature", "numReceivedSoFar", len(prepareSigs), "validatorAddress", validatorAddress, "PublicKeys", len(consensus.PublicKeys))
prepareSigs[validatorAddress] = &sign
prepareBitmap.SetKey(validatorPubKey, true) // Set the bitmap indicating that this validator signed.
if len(prepareSigs) >= ((len(consensus.PublicKeys)*2)/3 + 1) {
consensus.switchPhase(Commit)
// Construct and broadcast prepared message
msgToSend, aggSig := consensus.constructPreparedMessage()
consensus.aggregatedPrepareSig = aggSig
utils.GetLogInstance().Warn("onPrepare", "sent prepared message", len(msgToSend))
consensus.host.SendMessageToGroups([]p2p.GroupID{p2p.NewGroupIDByShardID(p2p.ShardID(consensus.ShardID))}, host.ConstructP2pMessage(byte(17), msgToSend))
// Leader sign the multi-sig and bitmap (for commit phase)
multiSigAndBitmap := append(aggSig.Serialize(), prepareBitmap.Bitmap...)
consensus.commitSigs[consensus.SelfAddress] = consensus.priKey.SignHash(multiSigAndBitmap)
}
return
}
func (consensus *Consensus) onPrepared(msg *msg_pb.Message) {
if consensus.PubKey.IsEqual(consensus.LeaderPubKey) {
return
}
senderKey, err := consensus.verifySenderKey(msg)
if err != nil {
utils.GetLogInstance().Debug("onPrepared verifySenderKey failed", "error", err)
return
}
if !senderKey.IsEqual(consensus.LeaderPubKey) {
utils.GetLogInstance().Warn("onPrepared senderKey not match leader PubKey")
return
}
if err := verifyMessageSig(senderKey, msg); err != nil {
utils.GetLogInstance().Debug("onPrepared Failed to verify sender's signature", "error", err)
return
}
utils.GetLogInstance().Info("onPrepared received prepared message", "ValidatorAddress", consensus.SelfAddress)
recvMsg, err := ParsePbftMessage(msg)
if err != nil {
utils.GetLogInstance().Debug("onPrepared Unparseable validator message", "error", err)
return
}
if recvMsg.BlockNum < consensus.blockNum {
return
}
blockHash := recvMsg.BlockHash
pubKey := recvMsg.SenderPubkey
if !pubKey.IsEqual(consensus.LeaderPubKey) {
utils.GetLogInstance().Debug("onPrepared leader pubkey not match", "suppose", consensus.LeaderPubKey, "got", pubKey)
return
}
addrBytes := pubKey.GetAddress()
leaderAddress := common.BytesToAddress(addrBytes[:]).Hex()
messagePayload := recvMsg.Payload
//#### Read payload data
offset := 0
// 48 byte of multi-sig
multiSig := messagePayload[offset : offset+48]
offset += 48
// bitmap
bitmap := messagePayload[offset:]
//#### END Read payload data
consensus.mutex.Lock()
defer consensus.mutex.Unlock()
// Verify the multi-sig for prepare phase
deserializedMultiSig := bls.Sign{}
err = deserializedMultiSig.Deserialize(multiSig)
if err != nil {
utils.GetLogInstance().Warn("onPrepared failed to deserialize the multi signature for prepare phase", "Error", err, "leader Address", leaderAddress)
return
}
mask, err := bls_cosi.NewMask(consensus.PublicKeys, nil)
mask.SetMask(bitmap)
// TODO: add 2f+1 signature checking
if !deserializedMultiSig.VerifyHash(mask.AggregatePublic, blockHash[:]) || err != nil {
myBlockHash := common.Hash{}
myBlockHash.SetBytes(consensus.blockHash[:])
utils.GetLogInstance().Warn("onPrepared failed to verify multi signature for prepare phase", "error", err, "blockHash", blockHash, "myBlockHash", myBlockHash)
return
}
consensus.pbftLog.AddMessage(recvMsg)
if recvMsg.BlockNum > consensus.blockNum || consensus.phase != Prepare || recvMsg.ViewID != consensus.viewID {
return
}
consensus.aggregatedPrepareSig = &deserializedMultiSig
consensus.prepareBitmap = mask
// Construct and send the commit message
multiSigAndBitmap := append(multiSig, bitmap...)
msgToSend := consensus.constructCommitMessage(multiSigAndBitmap)
utils.GetLogInstance().Warn("[Consensus]", "sent commit message", len(msgToSend))
consensus.host.SendMessageToGroups([]p2p.GroupID{p2p.NewGroupIDByShardID(p2p.ShardID(consensus.ShardID))}, host.ConstructP2pMessage(byte(17), msgToSend))
consensus.switchPhase(Commit)
consensus.consensusTimeout["prepare"].Stop()
if !consensus.consensusTimeout["commit"].IsActive() {
consensus.consensusTimeout["commit"].Start()
}
return
}
// TODO: move it to consensus_leader.go later
func (consensus *Consensus) onCommit(msg *msg_pb.Message) {
if !consensus.PubKey.IsEqual(consensus.LeaderPubKey) {
return
}
senderKey, err := consensus.verifySenderKey(msg)
if err != nil {
utils.GetLogInstance().Debug("onCommit verifySenderKey failed", "error", err)
return
}
if err = verifyMessageSig(senderKey, msg); err != nil {
utils.GetLogInstance().Debug("onCommit Failed to verify sender's signature", "error", err)
return
}
recvMsg, err := ParsePbftMessage(msg)
if err != nil {
utils.GetLogInstance().Debug("onCommit parse pbft message failed", "error", err)
return
}
if recvMsg.ViewID != consensus.viewID || recvMsg.BlockNum != consensus.blockNum || consensus.phase != Commit {
return
}
if !consensus.pbftLog.HasMatchingAnnounce(consensus.blockNum, consensus.viewID, recvMsg.BlockHash) {
return
}
validatorPubKey := recvMsg.SenderPubkey
addrBytes := validatorPubKey.GetAddress()
validatorAddress := common.BytesToAddress(addrBytes[:])
commitSig := recvMsg.Payload
consensus.mutex.Lock()
defer consensus.mutex.Unlock()
if !consensus.IsValidatorInCommittee(validatorAddress) {
utils.GetLogInstance().Error("Invalid validator", "validatorAddress", validatorAddress)
return
}
commitSigs := consensus.commitSigs
commitBitmap := consensus.commitBitmap
// proceed only when the message is not received before
_, ok := commitSigs[validatorAddress]
if ok {
utils.GetLogInstance().Debug("Already received commit message from the validator", "validatorAddress", validatorAddress)
return
}
if len((commitSigs)) >= ((len(consensus.PublicKeys)*2)/3 + 1) {
return
}
// Verify the signature on prepare multi-sig and bitmap is correct
var sign bls.Sign
err = sign.Deserialize(commitSig)
if err != nil {
utils.GetLogInstance().Debug("Failed to deserialize bls signature", "validatorAddress", validatorAddress)
return
}
aggSig := bls_cosi.AggregateSig(consensus.GetPrepareSigsArray())
if !sign.VerifyHash(validatorPubKey, append(aggSig.Serialize(), consensus.prepareBitmap.Bitmap...)) {
utils.GetLogInstance().Error("Received invalid BLS signature", "validatorAddress", validatorAddress)
return
}
utils.GetLogInstance().Debug("Received new commit message", "numReceivedSoFar", len(commitSigs), "validatorAddress", validatorAddress)
commitSigs[validatorAddress] = &sign
// Set the bitmap indicating that this validator signed.
commitBitmap.SetKey(validatorPubKey, true)
if len(commitSigs) >= ((len(consensus.PublicKeys)*2)/3 + 1) {
utils.GetLogInstance().Info("Enough commits received!", "num", len(commitSigs), "state", consensus.state)
consensus.switchPhase(Announce)
// Construct and broadcast committed message
msgToSend, aggSig := consensus.constructCommittedMessage()
consensus.aggregatedCommitSig = aggSig
utils.GetLogInstance().Warn("[Consensus]", "sent committed message", len(msgToSend))
consensus.host.SendMessageToGroups([]p2p.GroupID{p2p.NewGroupIDByShardID(p2p.ShardID(consensus.ShardID))}, host.ConstructP2pMessage(byte(17), msgToSend))
var blockObj types.Block
err := rlp.DecodeBytes(consensus.block, &blockObj)
if err != nil {
utils.GetLogInstance().Debug("failed to construct the new block after consensus")
}
// Sign the block
blockObj.SetPrepareSig(
consensus.aggregatedPrepareSig.Serialize(),
consensus.prepareBitmap.Bitmap)
blockObj.SetCommitSig(
consensus.aggregatedCommitSig.Serialize(),
consensus.commitBitmap.Bitmap)
select {
case consensus.VerifiedNewBlock <- &blockObj:
default:
utils.GetLogInstance().Info("[SYNC] Failed to send consensus verified block for state sync", "blockHash", blockObj.Hash())
}
consensus.reportMetrics(blockObj)
// Dump new block into level db.
explorer.GetStorageInstance(consensus.leader.IP, consensus.leader.Port, true).Dump(&blockObj, consensus.viewID)
// Reset state to Finished, and clear other data.
consensus.ResetState()
consensus.viewID++
consensus.blockNum++
consensus.OnConsensusDone(&blockObj)
utils.GetLogInstance().Debug("HOORAY!!!!!!! CONSENSUS REACHED!!!!!!!", "viewID", consensus.viewID, "numOfSignatures", len(commitSigs))
// Send signal to Node so the new block can be added and new round of consensus can be triggered
consensus.ReadySignal <- struct{}{}
}
return
}
func (consensus *Consensus) onCommitted(msg *msg_pb.Message) {
utils.GetLogInstance().Warn("Received Committed Message", "ValidatorAddress", consensus.SelfAddress)
if consensus.PubKey.IsEqual(consensus.LeaderPubKey) {
return
}
senderKey, err := consensus.verifySenderKey(msg)
if err != nil {
utils.GetLogInstance().Debug("onCommitted verifySenderKey failed", "error", err)
return
}
if !senderKey.IsEqual(consensus.LeaderPubKey) {
utils.GetLogInstance().Warn("onCommitted senderKey not match leader PubKey")
return
}
if err = verifyMessageSig(senderKey, msg); err != nil {
utils.GetLogInstance().Debug("onCommitted Failed to verify sender's signature", "error", err)
return
}
recvMsg, err := ParsePbftMessage(msg)
if err != nil {
utils.GetLogInstance().Warn("onCommitted unable to parse msg", "error", err)
return
}
if recvMsg.BlockNum < consensus.blockNum {
return
}
validatorPubKey := recvMsg.SenderPubkey
addrBytes := validatorPubKey.GetAddress()
leaderAddress := common.BytesToAddress(addrBytes[:]).Hex()
messagePayload := recvMsg.Payload
//#### Read payload data
offset := 0
// 48 byte of multi-sig
multiSig := messagePayload[offset : offset+48]
offset += 48
// bitmap
bitmap := messagePayload[offset:]
//#### END Read payload data
consensus.mutex.Lock()
defer consensus.mutex.Unlock()
// Verify the multi-sig for commit phase
deserializedMultiSig := bls.Sign{}
err = deserializedMultiSig.Deserialize(multiSig)
if err != nil {
utils.GetLogInstance().Warn("Failed to deserialize the multi signature for commit phase", "Error", err, "leader Address", leaderAddress)
return
}
mask, err := bls_cosi.NewMask(consensus.PublicKeys, nil)
mask.SetMask(bitmap)
prepareMultiSigAndBitmap := append(consensus.aggregatedPrepareSig.Serialize(), consensus.prepareBitmap.Bitmap...)
// TODO: add 2f+1 signature checking
if !deserializedMultiSig.VerifyHash(mask.AggregatePublic, prepareMultiSigAndBitmap) || err != nil {
utils.GetLogInstance().Warn("Failed to verify the multi signature for commit phase", "Error", err, "leader Address", leaderAddress)
return
}
consensus.pbftLog.AddMessage(recvMsg)
if recvMsg.BlockNum > consensus.blockNum || consensus.phase != Commit || recvMsg.ViewID != consensus.viewID {
return
}
consensus.aggregatedCommitSig = &deserializedMultiSig
consensus.commitBitmap = mask
consensus.tryCatchup()
consensus.consensusTimeout["commit"].Stop()
if !consensus.consensusTimeout["announce"].IsActive() {
consensus.consensusTimeout["announce"].Start()
}
return
}
// try to catch up if fall behind
func (consensus *Consensus) tryCatchup() {
utils.GetLogInstance().Info("tryCatchup: commit new blocks", "blockNum", consensus.blockNum)
if consensus.phase != Commit {
return
}
consensus.switchPhase(Announce)
for {
msgs := consensus.pbftLog.GetMessagesByTypeSeq(msg_pb.MessageType_COMMITTED, consensus.blockNum)
if len(msgs) == 0 {
break
}
if len(msgs) > 1 {
utils.GetLogInstance().Info("[PBFT] we should only get one committed message for a given blockNum", "blockNum", consensus.blockNum, "numMsgs", len(msgs))
}
block := consensus.pbftLog.GetBlockByHash(msgs[0].BlockHash)
if block == nil {
break
}
if block.ParentHash() != consensus.ChainReader.CurrentHeader().Hash() {
utils.GetLogInstance().Debug("[PBFT] parent block hash not match", "blockNum", consensus.blockNum)
break
}
preparedMsgs := consensus.pbftLog.GetMessagesByTypeSeqHash(msg_pb.MessageType_PREPARED, msgs[0].BlockNum, msgs[0].BlockHash)
if len(preparedMsgs) > 1 {
utils.GetLogInstance().Info("[PBFT] we should only get one prepared message for a given blockNum", "blockNum", consensus.blockNum, "numMsgs", len(preparedMsgs))
}
if len(preparedMsgs) == 0 {
break
}
cnt := 0
for _, msg := range preparedMsgs {
if msg.BlockHash == msgs[0].BlockHash {
cnt++
consensus.blockHash = [32]byte{}
consensus.blockNum = consensus.blockNum + 1
consensus.viewID = consensus.viewID + 1
//#### Read payload data from committed msg
aggSig := make([]byte, 48)
bitmap := make([]byte, len(msgs[0].Payload)-48)
offset := 0
copy(aggSig[:], msgs[0].Payload[offset:offset+48])
offset += 48
copy(bitmap[:], msgs[0].Payload[offset:])
//#### END Read payload data from committed msg
//#### Read payload data from prepared msg
prepareSig := make([]byte, 48)
prepareBitmap := make([]byte, len(msg.Payload)-48)
offset = 0
copy(prepareSig[:], msg.Payload[offset:offset+48])
offset += 48
copy(prepareBitmap[:], msg.Payload[offset:])
//#### END Read payload data from committed msg
// Put the signatures into the block
block.SetPrepareSig(prepareSig, prepareBitmap)
block.SetCommitSig(aggSig, bitmap)
utils.GetLogInstance().Info("Adding block to chain", "numTx", len(block.Transactions()))
consensus.OnConsensusDone(block)
consensus.ResetState()
select {
case consensus.VerifiedNewBlock <- block:
default:
utils.GetLogInstance().Info("[SYNC] consensus verified block send to chan failed", "blockHash", block.Hash())
continue
}
break
}
}
if cnt == 0 { // didn't find match block for current blockNum, return
break
}
}
}
// Start waits for the next new block and run consensus
func (consensus *Consensus) Start(blockChannel chan *types.Block, stopChan chan struct{}, stoppedChan chan struct{}, startChannel chan struct{}) {
if nodeconfig.GetDefaultConfig().IsLeader() {
<-startChannel
}
go func() {
utils.GetLogInstance().Info("start consensus", "time", time.Now())
defer close(stoppedChan)
ticker := time.NewTicker(3 * time.Second)
consensus.consensusTimeout["bootstrap"].Start()
for {
select {
case <-ticker.C:
if !consensus.PubKey.IsEqual(consensus.LeaderPubKey) {
for k, v := range consensus.consensusTimeout {
if !v.CheckExpire() {
continue
}
if k != "viewchange" {
utils.GetLogInstance().Debug("ops", "phase", k, "mode", consensus.mode.Mode())
consensus.startViewChange(consensus.viewID + 1)
break
} else {
utils.GetLogInstance().Debug("ops", "phase", k, "mode", consensus.mode.Mode())
viewID := consensus.mode.ViewID()
consensus.startViewChange(viewID + 1)
break
}
}
}
case newBlock := <-blockChannel:
utils.GetLogInstance().Info("receive newBlock", "blockNum", newBlock.NumberU64())
if consensus.ShardID == 0 {
// TODO ek/rj - re-enable this after fixing DRand
//if core.IsEpochBlock(newBlock) { // Only beacon chain do randomness generation
// // Receive pRnd from DRG protocol
// utils.GetLogInstance().Debug("[DRG] Waiting for pRnd")
// pRndAndBitmap := <-consensus.PRndChannel
// utils.GetLogInstance().Debug("[DRG] Got pRnd", "pRnd", pRndAndBitmap)
// pRnd := [32]byte{}
// copy(pRnd[:], pRndAndBitmap[:32])
// bitmap := pRndAndBitmap[32:]
// vrfBitmap, _ := bls_cosi.NewMask(consensus.PublicKeys, consensus.leader.ConsensusPubKey)
// vrfBitmap.SetMask(bitmap)
//
// // TODO: check validity of pRnd
// newBlock.AddRandPreimage(pRnd)
//}
rnd, blockHash, err := consensus.GetNextRnd()
if err == nil {
// Verify the randomness
_ = blockHash
utils.GetLogInstance().Info("Adding randomness into new block", "rnd", rnd)
newBlock.AddRandSeed(rnd)
} else {
utils.GetLogInstance().Info("Failed to get randomness", "error", err)
}
}
startTime = time.Now()
utils.GetLogInstance().Debug("STARTING CONSENSUS", "numTxs", len(newBlock.Transactions()), "consensus", consensus, "startTime", startTime, "publicKeys", len(consensus.PublicKeys))
consensus.tryAnnounce(newBlock)
case msg := <-consensus.MsgChan:
consensus.handleMessageUpdate(msg)
case <-stopChan:
return
}
}
}()
}