package consensus import ( "bytes" "encoding/binary" "encoding/hex" "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/block" "github.com/harmony-one/harmony/consensus/quorum" "github.com/harmony-one/harmony/core/types" vrf_bls "github.com/harmony-one/harmony/crypto/vrf/bls" "github.com/harmony-one/harmony/internal/chain" 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/host" "github.com/harmony-one/harmony/shard" "github.com/harmony-one/vdf/src/vdf_go" ) // 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 { consensus.getLogger().Error().Err(err).Msg("Failed to unmarshal message payload.") return } // when node is in ViewChanging mode, it still accepts normal messages into FBFTLog // in order to avoid possible trap forever but drop PREPARE and COMMIT // which are message types specifically for a node acting as leader switch { case (consensus.current.Mode() == ViewChanging) && (msg.Type == msg_pb.MessageType_PREPARE || msg.Type == msg_pb.MessageType_COMMIT): return case consensus.current.Mode() == Listening: return } if msg.Type == msg_pb.MessageType_VIEWCHANGE || msg.Type == msg_pb.MessageType_NEWVIEW { if msg.GetViewchange() != nil && msg.GetViewchange().ShardId != consensus.ShardID { utils.Logger().Warn(). Uint32("myShardId", consensus.ShardID). Uint32("receivedShardId", msg.GetViewchange().ShardId). Msg("Received view change message from different shard") return } } else { if msg.GetConsensus() != nil && msg.GetConsensus().ShardId != consensus.ShardID { utils.Logger().Warn(). Uint32("myShardId", consensus.ShardID). Uint32("receivedShardId", msg.GetConsensus().ShardId). Msg("Received consensus message from different shard") return } } notMemberButStillCatchup := !consensus.Decider.AmIMemberOfCommitee() && msg.Type == msg_pb.MessageType_COMMITTED if notMemberButStillCatchup { consensus.onCommitted(msg) 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) announce(block *types.Block) { blockHash := block.Hash() copy(consensus.blockHash[:], blockHash[:]) // prepare message and broadcast to validators encodedBlock, err := rlp.EncodeToBytes(block) if err != nil { utils.Logger().Debug().Msg("[Announce] Failed encoding block") return } encodedBlockHeader, err := rlp.EncodeToBytes(block.Header()) if err != nil { utils.Logger().Debug().Msg("[Announce] Failed encoding block header") return } consensus.block = encodedBlock consensus.blockHeader = encodedBlockHeader msgToSend := consensus.constructAnnounceMessage() // save announce message to FBFTLog msgPayload, _ := proto.GetConsensusMessagePayload(msgToSend) // TODO(chao): don't unmarshall the message here and direclty pass the original object. msg := &msg_pb.Message{} _ = protobuf.Unmarshal(msgPayload, msg) FPBTMsg, err := ParseFBFTMessage(msg) if err != nil { utils.Logger().Warn().Err(err).Msg("[Announce] Unable to parse FPBT message") return } // TODO(chao): review FPBT log data structure consensus.FBFTLog.AddMessage(FPBTMsg) utils.Logger().Debug(). Str("MsgBlockHash", FPBTMsg.BlockHash.Hex()). Uint64("MsgViewID", FPBTMsg.ViewID). Uint64("MsgBlockNum", FPBTMsg.BlockNum). Msg("[Announce] Added Announce message in FPBT") consensus.FBFTLog.AddBlock(block) // Leader sign the block hash itself consensus.Decider.AddSignature( quorum.Prepare, consensus.PubKey, consensus.priKey.SignHash(consensus.blockHash[:]), ) if err := consensus.prepareBitmap.SetKey(consensus.PubKey, true); err != nil { utils.Logger().Warn().Err(err).Msg("[Announce] Leader prepareBitmap SetKey failed") return } // Construct broadcast p2p message if err := consensus.msgSender.SendWithRetry( consensus.blockNum, msg_pb.MessageType_ANNOUNCE, []nodeconfig.GroupID{ nodeconfig.NewGroupIDByShardID(nodeconfig.ShardID(consensus.ShardID)), }, host.ConstructP2pMessage(byte(17), msgToSend)); err != nil { utils.Logger().Warn(). Str("groupID", string(nodeconfig.NewGroupIDByShardID( nodeconfig.ShardID(consensus.ShardID), ))). Msg("[Announce] Cannot send announce message") } else { utils.Logger().Info(). Str("blockHash", block.Hash().Hex()). Uint64("blockNum", block.NumberU64()). Msg("[Announce] Sent Announce Message!!") } utils.Logger().Debug(). Str("From", consensus.phase.String()). Str("To", FBFTPrepare.String()). Msg("[Announce] Switching phase") consensus.switchPhase(FBFTPrepare, true) } func (consensus *Consensus) onAnnounce(msg *msg_pb.Message) { utils.Logger().Debug().Msg("[OnAnnounce] Receive announce message") if consensus.IsLeader() && consensus.current.Mode() == Normal { return } senderKey, err := consensus.verifySenderKey(msg) if err != nil { utils.Logger().Error().Err(err).Msg("[OnAnnounce] VerifySenderKey failed") return } if !senderKey.IsEqual(consensus.LeaderPubKey) && consensus.current.Mode() == Normal && !consensus.ignoreViewIDCheck { utils.Logger().Warn(). Str("senderKey", senderKey.SerializeToHexStr()). Str("leaderKey", consensus.LeaderPubKey.SerializeToHexStr()). Msg("[OnAnnounce] SenderKey does not match leader PubKey") return } if err = verifyMessageSig(senderKey, msg); err != nil { utils.Logger().Error().Err(err).Msg("[OnAnnounce] Failed to verify leader signature") return } recvMsg, err := ParseFBFTMessage(msg) if err != nil { utils.Logger().Error(). Err(err). Uint64("MsgBlockNum", recvMsg.BlockNum). Msg("[OnAnnounce] Unparseable leader message") return } // verify validity of block header object // TODO: think about just sending the block hash instead of the header. encodedHeader := recvMsg.Payload header := new(block.Header) err = rlp.DecodeBytes(encodedHeader, header) if err != nil { utils.Logger().Warn(). Err(err). Uint64("MsgBlockNum", recvMsg.BlockNum). Msg("[OnAnnounce] Unparseable block header data") return } if recvMsg.BlockNum < consensus.blockNum || recvMsg.BlockNum != header.Number().Uint64() { utils.Logger().Debug(). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("hdrBlockNum", header.Number().Uint64()). Uint64("consensuBlockNum", consensus.blockNum). Msg("[OnAnnounce] BlockNum does not match") return } if consensus.current.Mode() == Normal { if err = chain.Engine.VerifyHeader(consensus.ChainReader, header, true); err != nil { utils.Logger().Warn(). Err(err). Str("inChain", consensus.ChainReader.CurrentHeader().Number().String()). Str("MsgBlockNum", header.Number().String()). Msg("[OnAnnounce] Block content is not verified successfully") return } //VRF/VDF is only generated in the beach chain if consensus.NeedsRandomNumberGeneration(header.Epoch()) { //validate the VRF with proof if a non zero VRF is found in header if len(header.Vrf()) > 0 { if !consensus.ValidateVrfAndProof(header) { return } } //validate the VDF with proof if a non zero VDF is found in header if len(header.Vdf()) > 0 { if !consensus.ValidateVdfAndProof(header) { return } } } } logMsgs := consensus.FBFTLog.GetMessagesByTypeSeqView( msg_pb.MessageType_ANNOUNCE, recvMsg.BlockNum, recvMsg.ViewID, ) if len(logMsgs) > 0 { if logMsgs[0].BlockHash != recvMsg.BlockHash && logMsgs[0].SenderPubkey.IsEqual(recvMsg.SenderPubkey) { utils.Logger().Debug(). Str("leaderKey", consensus.LeaderPubKey.SerializeToHexStr()). Msg("[OnAnnounce] Leader is malicious") consensus.startViewChange(consensus.viewID + 1) } utils.Logger().Debug(). Str("leaderKey", consensus.LeaderPubKey.SerializeToHexStr()). Msg("[OnAnnounce] Announce message received again") //return } utils.Logger().Debug(). Uint64("MsgViewID", recvMsg.ViewID). Uint64("MsgBlockNum", recvMsg.BlockNum). Msg("[OnAnnounce] Announce message Added") consensus.FBFTLog.AddMessage(recvMsg) consensus.mutex.Lock() defer consensus.mutex.Unlock() consensus.blockHash = recvMsg.BlockHash // we have already added message and block, skip check viewID and send prepare message if is in ViewChanging mode if consensus.current.Mode() == ViewChanging { utils.Logger().Debug().Msg("[OnAnnounce] Still in ViewChanging Mode, Exiting !!") return } if consensus.checkViewID(recvMsg) != nil { if consensus.current.Mode() == Normal { utils.Logger().Debug(). Uint64("MsgViewID", recvMsg.ViewID). Uint64("MsgBlockNum", recvMsg.BlockNum). Msg("[OnAnnounce] ViewID check failed") } return } consensus.prepare() return } // tryPrepare will try to send prepare message func (consensus *Consensus) prepare() { // Construct and send prepare message msgToSend := consensus.constructPrepareMessage() // TODO: this will not return immediatey, may block if err := consensus.msgSender.SendWithoutRetry([]nodeconfig.GroupID{nodeconfig.NewGroupIDByShardID(nodeconfig.ShardID(consensus.ShardID))}, host.ConstructP2pMessage(byte(17), msgToSend)); err != nil { utils.Logger().Warn().Err(err).Msg("[OnAnnounce] Cannot send prepare message") } else { utils.Logger().Info(). Str("blockHash", hex.EncodeToString(consensus.blockHash[:])). Msg("[OnAnnounce] Sent Prepare Message!!") } utils.Logger().Debug(). Str("From", consensus.phase.String()). Str("To", FBFTPrepare.String()). Msg("[Announce] Switching Phase") consensus.switchPhase(FBFTPrepare, true) } // TODO: move to consensus_leader.go later func (consensus *Consensus) onPrepare(msg *msg_pb.Message) { if !consensus.IsLeader() { return } senderKey, err := consensus.verifySenderKey(msg) if err != nil { utils.Logger().Error().Err(err).Msg("[OnPrepare] VerifySenderKey failed") return } if err = verifyMessageSig(senderKey, msg); err != nil { utils.Logger().Error().Err(err).Msg("[OnPrepare] Failed to verify sender's signature") return } recvMsg, err := ParseFBFTMessage(msg) if err != nil { utils.Logger().Error().Err(err).Msg("[OnPrepare] Unparseable validator message") return } if recvMsg.ViewID != consensus.viewID || recvMsg.BlockNum != consensus.blockNum { utils.Logger().Debug(). Uint64("MsgViewID", recvMsg.ViewID). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("blockNum", consensus.blockNum). Msg("[OnPrepare] Message ViewId or BlockNum not match") return } if !consensus.FBFTLog.HasMatchingViewAnnounce( consensus.blockNum, consensus.viewID, recvMsg.BlockHash, ) { utils.Logger().Debug(). Uint64("MsgViewID", recvMsg.ViewID). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("blockNum", consensus.blockNum). Msg("[OnPrepare] No Matching Announce message") //return } validatorPubKey := recvMsg.SenderPubkey prepareSig := recvMsg.Payload prepareBitmap := consensus.prepareBitmap consensus.mutex.Lock() defer consensus.mutex.Unlock() logger := utils.Logger().With(). Str("validatorPubKey", validatorPubKey.SerializeToHexStr()).Logger() // proceed only when the message is not received before signed := consensus.Decider.ReadSignature(quorum.Prepare, validatorPubKey) if signed != nil { logger.Debug(). Msg("[OnPrepare] Already Received prepare message from the validator") return } if consensus.Decider.IsQuorumAchieved(quorum.Prepare) { // already have enough signatures logger.Debug().Msg("[OnPrepare] Received Additional Prepare Message") return } // Check BLS signature for the multi-sig var sign bls.Sign err = sign.Deserialize(prepareSig) if err != nil { utils.Logger().Error().Err(err). Msg("[OnPrepare] Failed to deserialize bls signature") return } if !sign.VerifyHash(recvMsg.SenderPubkey, consensus.blockHash[:]) { utils.Logger().Error().Msg("[OnPrepare] Received invalid BLS signature") return } logger = logger.With(). Int64("NumReceivedSoFar", consensus.Decider.SignersCount(quorum.Prepare)). Int64("PublicKeys", consensus.Decider.ParticipantsCount()).Logger() logger.Info().Msg("[OnPrepare] Received New Prepare Signature") consensus.Decider.AddSignature(quorum.Prepare, validatorPubKey, &sign) // Set the bitmap indicating that this validator signed. if err := prepareBitmap.SetKey(recvMsg.SenderPubkey, true); err != nil { utils.Logger().Warn().Err(err).Msg("[OnPrepare] prepareBitmap.SetKey failed") return } if consensus.Decider.IsQuorumAchieved(quorum.Prepare) { logger.Debug().Msg("[OnPrepare] Received Enough Prepare Signatures") // Construct and broadcast prepared message msgToSend, aggSig := consensus.constructPreparedMessage() consensus.aggregatedPrepareSig = aggSig //leader adds prepared message to log // TODO(chao): don't unmarshall the payload again msgPayload, _ := proto.GetConsensusMessagePayload(msgToSend) msg := &msg_pb.Message{} _ = protobuf.Unmarshal(msgPayload, msg) FBFTMsg, err := ParseFBFTMessage(msg) if err != nil { utils.Logger().Warn().Err(err).Msg("[OnPrepare] Unable to parse pbft message") return } consensus.FBFTLog.AddMessage(FBFTMsg) // Leader add commit phase signature blockNumHash := make([]byte, 8) binary.LittleEndian.PutUint64(blockNumHash, consensus.blockNum) commitPayload := append(blockNumHash, consensus.blockHash[:]...) consensus.Decider.AddSignature( quorum.Commit, consensus.PubKey, consensus.priKey.SignHash(commitPayload), ) if err := consensus.commitBitmap.SetKey(consensus.PubKey, true); err != nil { utils.Logger().Debug().Msg("[OnPrepare] Leader commit bitmap set failed") return } if err := consensus.msgSender.SendWithRetry( consensus.blockNum, msg_pb.MessageType_PREPARED, []nodeconfig.GroupID{ nodeconfig.NewGroupIDByShardID(nodeconfig.ShardID(consensus.ShardID)), }, host.ConstructP2pMessage(byte(17), msgToSend), ); err != nil { utils.Logger().Warn().Msg("[OnPrepare] Cannot send prepared message") } else { utils.Logger().Debug(). Hex("blockHash", consensus.blockHash[:]). Uint64("blockNum", consensus.blockNum). Msg("[OnPrepare] Sent Prepared Message!!") } consensus.msgSender.StopRetry(msg_pb.MessageType_ANNOUNCE) // Stop retry committed msg of last consensus consensus.msgSender.StopRetry(msg_pb.MessageType_COMMITTED) utils.Logger().Debug(). Str("From", consensus.phase.String()). Str("To", FBFTCommit.String()). Msg("[OnPrepare] Switching phase") consensus.switchPhase(FBFTCommit, true) } return } func (consensus *Consensus) onPrepared(msg *msg_pb.Message) { utils.Logger().Debug().Msg("[OnPrepared] Received Prepared message") if consensus.IsLeader() && consensus.current.Mode() == Normal { return } senderKey, err := consensus.verifySenderKey(msg) if err != nil { utils.Logger().Debug().Err(err).Msg("[OnPrepared] VerifySenderKey failed") return } if !senderKey.IsEqual(consensus.LeaderPubKey) && consensus.current.Mode() == Normal && !consensus.ignoreViewIDCheck { utils.Logger().Warn().Msg("[OnPrepared] SenderKey not match leader PubKey") return } if err := verifyMessageSig(senderKey, msg); err != nil { utils.Logger().Debug().Err(err).Msg("[OnPrepared] Failed to verify sender's signature") return } recvMsg, err := ParseFBFTMessage(msg) if err != nil { utils.Logger().Debug().Err(err).Msg("[OnPrepared] Unparseable validator message") return } utils.Logger().Info(). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("MsgViewID", recvMsg.ViewID). Msg("[OnPrepared] Received prepared message") if recvMsg.BlockNum < consensus.blockNum { utils.Logger().Debug().Uint64("MsgBlockNum", recvMsg.BlockNum).Msg("Old Block Received, ignoring!!") return } // check validity of prepared signature blockHash := recvMsg.BlockHash aggSig, mask, err := consensus.ReadSignatureBitmapPayload(recvMsg.Payload, 0) if err != nil { utils.Logger().Error().Err(err).Msg("ReadSignatureBitmapPayload failed!!") return } if !consensus.Decider.IsQuorumAchievedByMask(mask) { utils.Logger().Warn(). Msgf("[OnPrepared] Quorum Not achieved") return } if !aggSig.VerifyHash(mask.AggregatePublic, blockHash[:]) { myBlockHash := common.Hash{} myBlockHash.SetBytes(consensus.blockHash[:]) utils.Logger().Warn(). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("MsgViewID", recvMsg.ViewID). Msg("[OnPrepared] failed to verify multi signature for prepare phase") return } // check validity of block block := recvMsg.Block var blockObj types.Block err = rlp.DecodeBytes(block, &blockObj) if err != nil { utils.Logger().Warn(). Err(err). Uint64("MsgBlockNum", recvMsg.BlockNum). Msg("[OnPrepared] Unparseable block header data") return } if blockObj.NumberU64() != recvMsg.BlockNum || recvMsg.BlockNum < consensus.blockNum { utils.Logger().Warn(). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("blockNum", blockObj.NumberU64()). Msg("[OnPrepared] BlockNum not match") return } if blockObj.Header().Hash() != recvMsg.BlockHash { utils.Logger().Warn(). Uint64("MsgBlockNum", recvMsg.BlockNum). Hex("MsgBlockHash", recvMsg.BlockHash[:]). Str("blockObjHash", blockObj.Header().Hash().Hex()). Msg("[OnPrepared] BlockHash not match") return } if consensus.current.Mode() == Normal { err := chain.Engine.VerifyHeader(consensus.ChainReader, blockObj.Header(), true) if err != nil { utils.Logger().Error(). Err(err). Str("inChain", consensus.ChainReader.CurrentHeader().Number().String()). Str("MsgBlockNum", blockObj.Header().Number().String()). Msg("[OnPrepared] Block header is not verified successfully") return } if consensus.BlockVerifier == nil { // do nothing } else if err := consensus.BlockVerifier(&blockObj); err != nil { utils.Logger().Error().Err(err).Msg("[OnPrepared] Block verification failed") return } } consensus.FBFTLog.AddBlock(&blockObj) recvMsg.Block = []byte{} // save memory space consensus.FBFTLog.AddMessage(recvMsg) utils.Logger().Debug(). Uint64("MsgViewID", recvMsg.ViewID). Uint64("MsgBlockNum", recvMsg.BlockNum). Hex("blockHash", recvMsg.BlockHash[:]). Msg("[OnPrepared] Prepared message and block added") consensus.mutex.Lock() defer consensus.mutex.Unlock() consensus.tryCatchup() if consensus.current.Mode() == ViewChanging { utils.Logger().Debug().Msg("[OnPrepared] Still in ViewChanging mode, Exiting!!") return } if consensus.checkViewID(recvMsg) != nil { if consensus.current.Mode() == Normal { utils.Logger().Debug(). Uint64("MsgViewID", recvMsg.ViewID). Uint64("MsgBlockNum", recvMsg.BlockNum). Msg("[OnPrepared] ViewID check failed") } return } if recvMsg.BlockNum > consensus.blockNum { utils.Logger().Debug(). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("blockNum", consensus.blockNum). Msg("[OnPrepared] Future Block Received, ignoring!!") return } // add block field blockPayload := make([]byte, len(block)) copy(blockPayload[:], block[:]) consensus.block = blockPayload // add preparedSig field consensus.aggregatedPrepareSig = aggSig consensus.prepareBitmap = mask // Optimistically add blockhash field of prepare message emptyHash := [32]byte{} if bytes.Compare(consensus.blockHash[:], emptyHash[:]) == 0 { copy(consensus.blockHash[:], blockHash[:]) } // Construct and send the commit message // TODO: should only sign on block hash blockNumBytes := make([]byte, 8) binary.LittleEndian.PutUint64(blockNumBytes, consensus.blockNum) commitPayload := append(blockNumBytes, consensus.blockHash[:]...) msgToSend := consensus.constructCommitMessage(commitPayload) // TODO: genesis account node delay for 1 second, this is a temp fix for allows FN nodes to earning reward if consensus.delayCommit > 0 { time.Sleep(consensus.delayCommit) } if err := consensus.msgSender.SendWithoutRetry([]nodeconfig.GroupID{nodeconfig.NewGroupIDByShardID(nodeconfig.ShardID(consensus.ShardID))}, host.ConstructP2pMessage(byte(17), msgToSend)); err != nil { utils.Logger().Warn().Msg("[OnPrepared] Cannot send commit message!!") } else { utils.Logger().Info(). Uint64("blockNum", consensus.blockNum). Hex("blockHash", consensus.blockHash[:]). Msg("[OnPrepared] Sent Commit Message!!") } utils.Logger().Debug(). Str("From", consensus.phase.String()). Str("To", FBFTCommit.String()). Msg("[OnPrepared] Switching phase") consensus.switchPhase(FBFTCommit, true) return } // TODO: move it to consensus_leader.go later func (consensus *Consensus) onCommit(msg *msg_pb.Message) { if !consensus.IsLeader() { return } senderKey, err := consensus.verifySenderKey(msg) if err != nil { utils.Logger().Debug().Err(err).Msg("[OnCommit] VerifySenderKey Failed") return } if err = verifyMessageSig(senderKey, msg); err != nil { utils.Logger().Debug().Err(err).Msg("[OnCommit] Failed to verify sender's signature") return } recvMsg, err := ParseFBFTMessage(msg) if err != nil { utils.Logger().Debug().Err(err).Msg("[OnCommit] Parse pbft message failed") return } if recvMsg.ViewID != consensus.viewID || recvMsg.BlockNum != consensus.blockNum { utils.Logger().Debug(). Uint64("MsgViewID", recvMsg.ViewID). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("blockNum", consensus.blockNum). Str("ValidatorPubKey", recvMsg.SenderPubkey.SerializeToHexStr()). Msg("[OnCommit] BlockNum/viewID not match") return } if !consensus.FBFTLog.HasMatchingAnnounce(consensus.blockNum, recvMsg.BlockHash) { utils.Logger().Debug(). Hex("MsgBlockHash", recvMsg.BlockHash[:]). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("blockNum", consensus.blockNum). Msg("[OnCommit] Cannot find matching blockhash") return } if !consensus.FBFTLog.HasMatchingPrepared(consensus.blockNum, recvMsg.BlockHash) { utils.Logger().Debug(). Hex("blockHash", recvMsg.BlockHash[:]). Uint64("blockNum", consensus.blockNum). Msg("[OnCommit] Cannot find matching prepared message") return } validatorPubKey := recvMsg.SenderPubkey commitSig := recvMsg.Payload consensus.mutex.Lock() defer consensus.mutex.Unlock() logger := utils.Logger().With(). Str("validatorPubKey", validatorPubKey.SerializeToHexStr()).Logger() if !consensus.IsValidatorInCommittee(recvMsg.SenderPubkey) { logger.Error().Msg("[OnCommit] Invalid validator") return } commitBitmap := consensus.commitBitmap // proceed only when the message is not received before signed := consensus.Decider.ReadSignature(quorum.Commit, validatorPubKey) if signed != nil { logger.Debug(). Msg("[OnCommit] Already received commit message from the validator") return } // has to be called before verifying signature quorumWasMet := consensus.Decider.IsQuorumAchieved(quorum.Commit) // Verify the signature on commitPayload is correct var sign bls.Sign err = sign.Deserialize(commitSig) if err != nil { logger.Debug().Msg("[OnCommit] Failed to deserialize bls signature") return } blockNumHash := make([]byte, 8) binary.LittleEndian.PutUint64(blockNumHash, recvMsg.BlockNum) commitPayload := append(blockNumHash, recvMsg.BlockHash[:]...) logger = logger.With().Uint64("MsgViewID", recvMsg.ViewID).Uint64("MsgBlockNum", recvMsg.BlockNum).Logger() if !sign.VerifyHash(recvMsg.SenderPubkey, commitPayload) { logger.Error().Msg("[OnCommit] Cannot verify commit message") return } logger = logger.With(). Int64("numReceivedSoFar", consensus.Decider.SignersCount(quorum.Commit)). Logger() logger.Info().Msg("[OnCommit] Received new commit message") consensus.Decider.AddSignature(quorum.Commit, validatorPubKey, &sign) // Set the bitmap indicating that this validator signed. if err := commitBitmap.SetKey(recvMsg.SenderPubkey, true); err != nil { utils.Logger().Warn().Err(err).Msg("[OnCommit] commitBitmap.SetKey failed") return } quorumIsMet := consensus.Decider.IsQuorumAchieved(quorum.Commit) if !quorumWasMet && quorumIsMet { logger.Info().Msg("[OnCommit] 2/3 Enough commits received") go func(viewID uint64) { time.Sleep(2 * time.Second) logger.Debug().Msg("[OnCommit] Commit Grace Period Ended") consensus.commitFinishChan <- viewID }(consensus.viewID) consensus.msgSender.StopRetry(msg_pb.MessageType_PREPARED) } if consensus.Decider.IsRewardThresholdAchieved() { go func(viewID uint64) { consensus.commitFinishChan <- viewID logger.Info().Msg("[OnCommit] 90% Enough commits received") }(consensus.viewID) } } func (consensus *Consensus) finalizeCommits() { utils.Logger().Info(). Int64("NumCommits", consensus.Decider.SignersCount(quorum.Commit)). Msg("[Finalizing] Finalizing Block") beforeCatchupNum := consensus.blockNum // Construct committed message msgToSend, aggSig := consensus.constructCommittedMessage() consensus.aggregatedCommitSig = aggSig // this may not needed // leader adds committed message to log msgPayload, _ := proto.GetConsensusMessagePayload(msgToSend) msg := &msg_pb.Message{} _ = protobuf.Unmarshal(msgPayload, msg) pbftMsg, err := ParseFBFTMessage(msg) if err != nil { utils.Logger().Warn().Err(err).Msg("[FinalizeCommits] Unable to parse pbft message") return } consensus.FBFTLog.AddMessage(pbftMsg) // find correct block content curBlockHash := consensus.blockHash block := consensus.FBFTLog.GetBlockByHash(curBlockHash) if block == nil { utils.Logger().Warn(). Str("blockHash", hex.EncodeToString(curBlockHash[:])). Msg("[FinalizeCommits] Cannot find block by hash") return } consensus.tryCatchup() if consensus.blockNum-beforeCatchupNum != 1 { utils.Logger().Warn(). Uint64("beforeCatchupBlockNum", beforeCatchupNum). Msg("[FinalizeCommits] Leader cannot provide the correct block for committed message") return } consensus.ChainReader.WriteLastCommits(pbftMsg.Payload) // if leader success finalize the block, send committed message to validators if err := consensus.msgSender.SendWithRetry( block.NumberU64(), msg_pb.MessageType_COMMITTED, []nodeconfig.GroupID{ nodeconfig.NewGroupIDByShardID(nodeconfig.ShardID(consensus.ShardID)), }, host.ConstructP2pMessage(byte(17), msgToSend)); err != nil { utils.Logger().Warn().Err(err).Msg("[Finalizing] Cannot send committed message") } else { utils.Logger().Info(). Hex("blockHash", curBlockHash[:]). Uint64("blockNum", consensus.blockNum). Msg("[Finalizing] Sent Committed Message") } consensus.reportMetrics(*block) // Dump new block into level db // In current code, we add signatures in block in tryCatchup, the block dump to explorer does not contains signatures // but since explorer doesn't need signatures, it should be fine // in future, we will move signatures to next block //explorer.GetStorageInstance(consensus.leader.IP, consensus.leader.Port, true).Dump(block, beforeCatchupNum) if consensus.consensusTimeout[timeoutBootstrap].IsActive() { consensus.consensusTimeout[timeoutBootstrap].Stop() utils.Logger().Debug().Msg("[Finalizing] Start consensus timer; stop bootstrap timer only once") } else { utils.Logger().Debug().Msg("[Finalizing] Start consensus timer") } consensus.consensusTimeout[timeoutConsensus].Start() utils.Logger().Info(). Uint64("blockNum", block.NumberU64()). Uint64("epochNum", block.Epoch().Uint64()). Uint64("ViewId", block.Header().ViewID().Uint64()). Str("blockHash", block.Hash().String()). Int("index", consensus.Decider.IndexOf(consensus.PubKey)). Int("numTxns", len(block.Transactions())). Int("numStakingTxns", len(block.StakingTransactions())). Msg("HOORAY!!!!!!! CONSENSUS REACHED!!!!!!!") // Send signal to Node so the new block can be added and new round of consensus can be triggered consensus.ReadySignal <- struct{}{} } func (consensus *Consensus) onCommitted(msg *msg_pb.Message) { utils.Logger().Debug().Msg("[OnCommitted] Receive committed message") if consensus.IsLeader() && consensus.current.Mode() == Normal { return } senderKey, err := consensus.verifySenderKey(msg) if err != nil { utils.Logger().Warn().Err(err).Msg("[OnCommitted] verifySenderKey failed") return } if !senderKey.IsEqual(consensus.LeaderPubKey) && consensus.current.Mode() == Normal && !consensus.ignoreViewIDCheck { utils.Logger().Warn().Msg("[OnCommitted] senderKey not match leader PubKey") return } if err = verifyMessageSig(senderKey, msg); err != nil { utils.Logger().Warn().Err(err).Msg("[OnCommitted] Failed to verify sender's signature") return } recvMsg, err := ParseFBFTMessage(msg) if err != nil { utils.Logger().Warn().Msg("[OnCommitted] unable to parse msg") return } if recvMsg.BlockNum < consensus.blockNum { utils.Logger().Info(). Uint64("MsgBlockNum", recvMsg.BlockNum). Uint64("blockNum", consensus.blockNum). Msg("[OnCommitted] Received Old Blocks!!") return } aggSig, mask, err := consensus.ReadSignatureBitmapPayload(recvMsg.Payload, 0) if err != nil { utils.Logger().Error().Err(err).Msg("[OnCommitted] readSignatureBitmapPayload failed") return } if !consensus.Decider.IsQuorumAchievedByMask(mask) { utils.Logger().Warn(). Msgf("[OnCommitted] Quorum Not achieved") return } blockNumBytes := make([]byte, 8) binary.LittleEndian.PutUint64(blockNumBytes, recvMsg.BlockNum) commitPayload := append(blockNumBytes, recvMsg.BlockHash[:]...) if !aggSig.VerifyHash(mask.AggregatePublic, commitPayload) { utils.Logger().Error(). Uint64("MsgBlockNum", recvMsg.BlockNum). Msg("[OnCommitted] Failed to verify the multi signature for commit phase") return } consensus.FBFTLog.AddMessage(recvMsg) consensus.ChainReader.WriteLastCommits(recvMsg.Payload) utils.Logger().Debug(). Uint64("MsgViewID", recvMsg.ViewID). Uint64("MsgBlockNum", recvMsg.BlockNum). Msg("[OnCommitted] Committed message added") consensus.mutex.Lock() defer consensus.mutex.Unlock() consensus.aggregatedCommitSig = aggSig consensus.commitBitmap = mask if recvMsg.BlockNum-consensus.blockNum > consensusBlockNumBuffer { utils.Logger().Debug().Uint64("MsgBlockNum", recvMsg.BlockNum).Msg("[OnCommitted] out of sync") go func() { select { case consensus.blockNumLowChan <- struct{}{}: consensus.current.SetMode(Syncing) for _, v := range consensus.consensusTimeout { v.Stop() } case <-time.After(1 * time.Second): } }() return } // if consensus.checkViewID(recvMsg) != nil { // utils.Logger().Debug("viewID check failed", "viewID", recvMsg.ViewID, "myViewID", consensus.viewID) // return // } consensus.tryCatchup() if consensus.current.Mode() == ViewChanging { utils.Logger().Debug().Msg("[OnCommitted] Still in ViewChanging mode, Exiting!!") return } if consensus.consensusTimeout[timeoutBootstrap].IsActive() { consensus.consensusTimeout[timeoutBootstrap].Stop() utils.Logger().Debug().Msg("[OnCommitted] Start consensus timer; stop bootstrap timer only once") } else { utils.Logger().Debug().Msg("[OnCommitted] Start consensus timer") } consensus.consensusTimeout[timeoutConsensus].Start() return } // LastCommitSig returns the byte array of aggregated commit signature and bitmap of last block func (consensus *Consensus) LastCommitSig() ([]byte, []byte, error) { if consensus.blockNum <= 1 { return nil, nil, nil } lastCommits, err := consensus.ChainReader.ReadLastCommits() if err != nil || len(lastCommits) < 96 { msgs := consensus.FBFTLog.GetMessagesByTypeSeq(msg_pb.MessageType_COMMITTED, consensus.blockNum-1) if len(msgs) != 1 { utils.Logger().Error(). Int("numCommittedMsg", len(msgs)). Msg("GetLastCommitSig failed with wrong number of committed message") return nil, nil, ctxerror.New("GetLastCommitSig failed with wrong number of committed message", "numCommittedMsg", len(msgs)) } lastCommits = msgs[0].Payload } //#### Read payload data from committed msg aggSig := make([]byte, 96) bitmap := make([]byte, len(lastCommits)-96) offset := 0 copy(aggSig[:], lastCommits[offset:offset+96]) offset += 96 copy(bitmap[:], lastCommits[offset:]) //#### END Read payload data from committed msg return aggSig, bitmap, nil } // try to catch up if fall behind func (consensus *Consensus) tryCatchup() { utils.Logger().Info().Msg("[TryCatchup] commit new blocks") // if consensus.phase != Commit && consensus.mode.Mode() == Normal { // return // } currentBlockNum := consensus.blockNum for { msgs := consensus.FBFTLog.GetMessagesByTypeSeq(msg_pb.MessageType_COMMITTED, consensus.blockNum) if len(msgs) == 0 { break } if len(msgs) > 1 { utils.Logger().Error(). Int("numMsgs", len(msgs)). Msg("[TryCatchup] DANGER!!! we should only get one committed message for a given blockNum") } utils.Logger().Info().Msg("[TryCatchup] committed message found") block := consensus.FBFTLog.GetBlockByHash(msgs[0].BlockHash) if block == nil { break } if consensus.BlockVerifier == nil { // do nothing } else if err := consensus.BlockVerifier(block); err != nil { utils.Logger().Info().Msg("[TryCatchup] block verification failed") return } if block.ParentHash() != consensus.ChainReader.CurrentHeader().Hash() { utils.Logger().Debug().Msg("[TryCatchup] parent block hash not match") break } utils.Logger().Info().Msg("[TryCatchup] block found to commit") preparedMsgs := consensus.FBFTLog.GetMessagesByTypeSeqHash(msg_pb.MessageType_PREPARED, msgs[0].BlockNum, msgs[0].BlockHash) msg := consensus.FBFTLog.FindMessageByMaxViewID(preparedMsgs) if msg == nil { break } utils.Logger().Info().Msg("[TryCatchup] prepared message found to commit") // TODO(Chao): Explain the reasoning for these code consensus.blockHash = [32]byte{} consensus.blockNum = consensus.blockNum + 1 consensus.viewID = msgs[0].ViewID + 1 consensus.LeaderPubKey = msgs[0].SenderPubkey utils.Logger().Info().Msg("[TryCatchup] Adding block to chain") consensus.OnConsensusDone(block, msgs[0].Payload) consensus.ResetState() select { case consensus.VerifiedNewBlock <- block: default: utils.Logger().Info(). Str("blockHash", block.Hash().String()). Msg("[TryCatchup] consensus verified block send to chan failed") continue } break } if currentBlockNum < consensus.blockNum { utils.Logger().Info(). Uint64("From", currentBlockNum). Uint64("To", consensus.blockNum). Msg("[TryCatchup] Caught up!") consensus.switchPhase(FBFTAnnounce, true) } // catup up and skip from view change trap if currentBlockNum < consensus.blockNum && consensus.current.Mode() == ViewChanging { consensus.current.SetMode(Normal) consensus.consensusTimeout[timeoutViewChange].Stop() } // clean up old log consensus.FBFTLog.DeleteBlocksLessThan(consensus.blockNum - 1) consensus.FBFTLog.DeleteMessagesLessThan(consensus.blockNum - 1) } // 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{}) { go func() { toStart := false isInitialLeader := consensus.IsLeader() if isInitialLeader { utils.Logger().Info().Time("time", time.Now()).Msg("[ConsensusMainLoop] Waiting for consensus start") // send a signal to indicate it's ready to run consensus // this signal is consumed by node object to create a new block and in turn trigger a new consensus on it go func() { <-startChannel toStart = true utils.Logger().Info().Time("time", time.Now()).Msg("[ConsensusMainLoop] Send ReadySignal") consensus.ReadySignal <- struct{}{} }() } utils.Logger().Info().Time("time", time.Now()).Msg("[ConsensusMainLoop] Consensus started") defer close(stoppedChan) ticker := time.NewTicker(3 * time.Second) defer ticker.Stop() consensus.consensusTimeout[timeoutBootstrap].Start() utils.Logger().Debug(). Uint64("viewID", consensus.viewID). Uint64("blockNum", consensus.blockNum). Msg("[ConsensusMainLoop] Start bootstrap timeout (only once)") vdfInProgress := false for { select { case <-ticker.C: if toStart == false && isInitialLeader { continue } for k, v := range consensus.consensusTimeout { if consensus.current.Mode() == Syncing || consensus.current.Mode() == Listening { v.Stop() } if !v.CheckExpire() { continue } if k != timeoutViewChange { utils.Logger().Debug().Msg("[ConsensusMainLoop] Ops Consensus Timeout!!!") consensus.startViewChange(consensus.viewID + 1) break } else { utils.Logger().Debug().Msg("[ConsensusMainLoop] Ops View Change Timeout!!!") viewID := consensus.current.ViewID() consensus.startViewChange(viewID + 1) break } } case <-consensus.syncReadyChan: consensus.SetBlockNum(consensus.ChainReader.CurrentHeader().Number().Uint64() + 1) consensus.SetViewID(consensus.ChainReader.CurrentHeader().ViewID().Uint64() + 1) mode := consensus.UpdateConsensusInformation() consensus.current.SetMode(mode) utils.Logger().Info().Str("Mode", mode.String()).Msg("Node is in sync") case <-consensus.syncNotReadyChan: consensus.SetBlockNum(consensus.ChainReader.CurrentHeader().Number().Uint64() + 1) consensus.current.SetMode(Syncing) utils.Logger().Info().Msg("Node is out of sync") case newBlock := <-blockChannel: // Debug code to trigger leader change. //if consensus.ShardID == 0 && newBlock.NumberU64() == 2 && strings.Contains(consensus.PubKey.SerializeToHexStr(), "65f55eb") { // continue //} utils.Logger().Info(). Uint64("MsgBlockNum", newBlock.NumberU64()). Msg("[ConsensusMainLoop] Received Proposed New Block!") //VRF/VDF is only generated in the beacon chain if consensus.NeedsRandomNumberGeneration(newBlock.Header().Epoch()) { // generate VRF if the current block has a new leader if !consensus.ChainReader.IsSameLeaderAsPreviousBlock(newBlock) { vrfBlockNumbers, err := consensus.ChainReader.ReadEpochVrfBlockNums(newBlock.Header().Epoch()) if err != nil { consensus.getLogger().Info(). Uint64("MsgBlockNum", newBlock.NumberU64()). Uint64("Epoch", newBlock.Header().Epoch().Uint64()). Msg("[ConsensusMainLoop] no VRF block number from local db") } //check if VRF is already generated for the current block vrfAlreadyGenerated := false for _, v := range vrfBlockNumbers { if v == newBlock.NumberU64() { consensus.getLogger().Info(). Uint64("MsgBlockNum", newBlock.NumberU64()). Uint64("Epoch", newBlock.Header().Epoch().Uint64()). Msg("[ConsensusMainLoop] VRF is already generated for this block") vrfAlreadyGenerated = true break } } if !vrfAlreadyGenerated { //generate a new VRF for the current block vrfBlockNumbers := consensus.GenerateVrfAndProof(newBlock, vrfBlockNumbers) //generate a new VDF for the current epoch if there are enough VRFs in the current epoch //note that >= instead of == is used, because it is possible the current leader //can commit this block, go offline without finishing VDF if (!vdfInProgress) && len(vrfBlockNumbers) >= consensus.VdfSeedSize() { //check local database to see if there's a VDF generated for this epoch //generate a VDF if no blocknum is available _, err := consensus.ChainReader.ReadEpochVdfBlockNum(newBlock.Header().Epoch()) if err != nil { consensus.GenerateVdfAndProof(newBlock, vrfBlockNumbers) vdfInProgress = true } } } } vdfOutput, seed, err := consensus.GetNextRnd() if err == nil { vdfInProgress = false // Verify the randomness vdfObject := vdf_go.New(shard.Schedule.VdfDifficulty(), seed) if !vdfObject.Verify(vdfOutput) { consensus.getLogger().Warn(). Uint64("MsgBlockNum", newBlock.NumberU64()). Uint64("Epoch", newBlock.Header().Epoch().Uint64()). Msg("[ConsensusMainLoop] failed to verify the VDF output") } else { //write the VDF only if VDF has not been generated _, err := consensus.ChainReader.ReadEpochVdfBlockNum(newBlock.Header().Epoch()) if err == nil { consensus.getLogger().Info(). Uint64("MsgBlockNum", newBlock.NumberU64()). Uint64("Epoch", newBlock.Header().Epoch().Uint64()). Msg("[ConsensusMainLoop] VDF has already been generated previously") } else { consensus.getLogger().Info(). Uint64("MsgBlockNum", newBlock.NumberU64()). Uint64("Epoch", newBlock.Header().Epoch().Uint64()). Msg("[ConsensusMainLoop] Generated a new VDF") newBlock.AddVdf(vdfOutput[:]) } } } else { //consensus.getLogger().Error().Err(err). Msg("[ConsensusMainLoop] Failed to get randomness") } } startTime = time.Now() consensus.msgSender.Reset(newBlock.NumberU64()) utils.Logger().Debug(). Int("numTxs", len(newBlock.Transactions())). Time("startTime", startTime). Int64("publicKeys", consensus.Decider.ParticipantsCount()). Msg("[ConsensusMainLoop] STARTING CONSENSUS") consensus.announce(newBlock) case msg := <-consensus.MsgChan: consensus.handleMessageUpdate(msg) case viewID := <-consensus.commitFinishChan: // Only Leader execute this condition func() { consensus.mutex.Lock() defer consensus.mutex.Unlock() if viewID == consensus.viewID { consensus.finalizeCommits() } }() case <-stopChan: return } } }() } // GenerateVrfAndProof generates new VRF/Proof from hash of previous block func (consensus *Consensus) GenerateVrfAndProof(newBlock *types.Block, vrfBlockNumbers []uint64) []uint64 { sk := vrf_bls.NewVRFSigner(consensus.priKey) blockHash := [32]byte{} previousHeader := consensus.ChainReader.GetHeaderByNumber(newBlock.NumberU64() - 1) previousHash := previousHeader.Hash() copy(blockHash[:], previousHash[:]) vrf, proof := sk.Evaluate(blockHash[:]) newBlock.AddVrf(append(vrf[:], proof...)) consensus.getLogger().Info(). Uint64("MsgBlockNum", newBlock.NumberU64()). Uint64("Epoch", newBlock.Header().Epoch().Uint64()). Int("Num of VRF", len(vrfBlockNumbers)). Msg("[ConsensusMainLoop] Leader generated a VRF") return vrfBlockNumbers } // ValidateVrfAndProof validates a VRF/Proof from hash of previous block func (consensus *Consensus) ValidateVrfAndProof(headerObj *block.Header) bool { vrfPk := vrf_bls.NewVRFVerifier(consensus.LeaderPubKey) var blockHash [32]byte previousHeader := consensus.ChainReader.GetHeaderByNumber( headerObj.Number().Uint64() - 1, ) previousHash := previousHeader.Hash() copy(blockHash[:], previousHash[:]) vrfProof := [96]byte{} copy(vrfProof[:], headerObj.Vrf()[32:]) hash, err := vrfPk.ProofToHash(blockHash[:], vrfProof[:]) if err != nil { consensus.getLogger().Warn(). Err(err). Str("MsgBlockNum", headerObj.Number().String()). Msg("[OnAnnounce] VRF verification error") return false } if !bytes.Equal(hash[:], headerObj.Vrf()[:32]) { consensus.getLogger().Warn(). Str("MsgBlockNum", headerObj.Number().String()). Msg("[OnAnnounce] VRF proof is not valid") return false } vrfBlockNumbers, _ := consensus.ChainReader.ReadEpochVrfBlockNums( headerObj.Epoch(), ) consensus.getLogger().Info(). Str("MsgBlockNum", headerObj.Number().String()). Int("Number of VRF", len(vrfBlockNumbers)). Msg("[OnAnnounce] validated a new VRF") return true } // GenerateVdfAndProof generates new VDF/Proof from VRFs in the current epoch func (consensus *Consensus) GenerateVdfAndProof(newBlock *types.Block, vrfBlockNumbers []uint64) { //derive VDF seed from VRFs generated in the current epoch seed := [32]byte{} for i := 0; i < consensus.VdfSeedSize(); i++ { previousVrf := consensus.ChainReader.GetVrfByNumber(vrfBlockNumbers[i]) for j := 0; j < len(seed); j++ { seed[j] = seed[j] ^ previousVrf[j] } } consensus.getLogger().Info(). Uint64("MsgBlockNum", newBlock.NumberU64()). Uint64("Epoch", newBlock.Header().Epoch().Uint64()). Int("Num of VRF", len(vrfBlockNumbers)). Msg("[ConsensusMainLoop] VDF computation started") // TODO ek – limit concurrency go func() { vdf := vdf_go.New(shard.Schedule.VdfDifficulty(), seed) outputChannel := vdf.GetOutputChannel() start := time.Now() vdf.Execute() duration := time.Now().Sub(start) consensus.getLogger().Info(). Dur("duration", duration). Msg("[ConsensusMainLoop] VDF computation finished") output := <-outputChannel // The first 516 bytes are the VDF+proof and the last 32 bytes are XORed VRF as seed rndBytes := [548]byte{} copy(rndBytes[:516], output[:]) copy(rndBytes[516:], seed[:]) consensus.RndChannel <- rndBytes }() } // ValidateVdfAndProof validates the VDF/proof in the current epoch func (consensus *Consensus) ValidateVdfAndProof(headerObj *block.Header) bool { vrfBlockNumbers, err := consensus.ChainReader.ReadEpochVrfBlockNums(headerObj.Epoch()) if err != nil { consensus.getLogger().Error().Err(err). Str("MsgBlockNum", headerObj.Number().String()). Msg("[OnAnnounce] failed to read VRF block numbers for VDF computation") } //extra check to make sure there's no index out of range error //it can happen if epoch is messed up, i.e. VDF ouput is generated in the next epoch if consensus.VdfSeedSize() > len(vrfBlockNumbers) { return false } seed := [32]byte{} for i := 0; i < consensus.VdfSeedSize(); i++ { previousVrf := consensus.ChainReader.GetVrfByNumber(vrfBlockNumbers[i]) for j := 0; j < len(seed); j++ { seed[j] = seed[j] ^ previousVrf[j] } } vdfObject := vdf_go.New(shard.Schedule.VdfDifficulty(), seed) vdfOutput := [516]byte{} copy(vdfOutput[:], headerObj.Vdf()) if vdfObject.Verify(vdfOutput) { consensus.getLogger().Info(). Str("MsgBlockNum", headerObj.Number().String()). Int("Num of VRF", consensus.VdfSeedSize()). Msg("[OnAnnounce] validated a new VDF") } else { consensus.getLogger().Warn(). Str("MsgBlockNum", headerObj.Number().String()). Uint64("Epoch", headerObj.Epoch().Uint64()). Int("Num of VRF", consensus.VdfSeedSize()). Msg("[OnAnnounce] VDF proof is not valid") return false } return true }