package node import ( "bytes" "context" "math/rand" "time" "github.com/ethereum/go-ethereum/rlp" "github.com/harmony-one/harmony/api/proto" proto_node "github.com/harmony-one/harmony/api/proto/node" "github.com/harmony-one/harmony/block" "github.com/harmony-one/harmony/consensus" "github.com/harmony-one/harmony/core/types" nodeconfig "github.com/harmony-one/harmony/internal/configs/node" "github.com/harmony-one/harmony/internal/utils" "github.com/harmony-one/harmony/p2p" "github.com/harmony-one/harmony/shard" "github.com/harmony-one/harmony/staking/availability" "github.com/harmony-one/harmony/staking/slash" staking "github.com/harmony-one/harmony/staking/types" "github.com/harmony-one/harmony/webhooks" "github.com/pkg/errors" ) const p2pMsgPrefixSize = 5 const p2pNodeMsgPrefixSize = proto.MessageTypeBytes + proto.MessageCategoryBytes // some messages have uninteresting fields in header, slash, receipt and crosslink are // such messages. This function assumes that input bytes are a slice which already // past those not relevant header bytes. func (node *Node) processSkippedMsgTypeByteValue( cat proto_node.BlockMessageType, content []byte, ) { switch cat { case proto_node.SlashCandidate: node.processSlashCandidateMessage(content) case proto_node.Receipt: node.ProcessReceiptMessage(content) case proto_node.CrossLink: node.ProcessCrossLinkMessage(content) default: utils.Logger().Error(). Int("message-iota-value", int(cat)). Msg("Invariant usage of processSkippedMsgTypeByteValue violated") } } var ( errInvalidPayloadSize = errors.New("invalid payload size") errWrongBlockMsgSize = errors.New("invalid block message size") ) // HandleNodeMessage parses the message and dispatch the actions. func (node *Node) HandleNodeMessage( ctx context.Context, msgPayload []byte, actionType proto_node.MessageType, ) error { switch actionType { case proto_node.Transaction: node.transactionMessageHandler(msgPayload) case proto_node.Staking: node.stakingMessageHandler(msgPayload) case proto_node.Block: switch blockMsgType := proto_node.BlockMessageType(msgPayload[0]); blockMsgType { case proto_node.Sync: blocks := []*types.Block{} if err := rlp.DecodeBytes(msgPayload[1:], &blocks); err != nil { utils.Logger().Error(). Err(err). Msg("block sync") } else { // for non-beaconchain node, subscribe to beacon block broadcast if node.Blockchain().ShardID() != shard.BeaconChainShardID { for _, block := range blocks { if block.ShardID() == 0 { utils.Logger().Info(). Msgf("Beacon block being handled by block channel: %d", block.NumberU64()) go func(blk *types.Block) { node.BeaconBlockChannel <- blk }(block) } } } } case proto_node.SlashCandidate, proto_node.Receipt, proto_node.CrossLink: // skip first byte which is blockMsgType node.processSkippedMsgTypeByteValue(blockMsgType, msgPayload[1:]) } default: utils.Logger().Error(). Str("Unknown actionType", string(actionType)) } return nil } func (node *Node) transactionMessageHandler(msgPayload []byte) { txMessageType := proto_node.TransactionMessageType(msgPayload[0]) switch txMessageType { case proto_node.Send: txs := types.Transactions{} err := rlp.Decode(bytes.NewReader(msgPayload[1:]), &txs) // skip the Send messge type if err != nil { utils.Logger().Error(). Err(err). Msg("Failed to deserialize transaction list") return } node.addPendingTransactions(txs) } } func (node *Node) stakingMessageHandler(msgPayload []byte) { txMessageType := proto_node.TransactionMessageType(msgPayload[0]) switch txMessageType { case proto_node.Send: txs := staking.StakingTransactions{} err := rlp.Decode(bytes.NewReader(msgPayload[1:]), &txs) // skip the Send messge type if err != nil { utils.Logger().Error(). Err(err). Msg("Failed to deserialize staking transaction list") return } node.addPendingStakingTransactions(txs) } } // BroadcastNewBlock is called by consensus leader to sync new blocks with other clients/nodes. // NOTE: For now, just send to the client (basically not broadcasting) // TODO (lc): broadcast the new blocks to new nodes doing state sync func (node *Node) BroadcastNewBlock(newBlock *types.Block) { groups := []nodeconfig.GroupID{node.NodeConfig.GetClientGroupID()} utils.Logger().Info(). Msgf( "broadcasting new block %d, group %s", newBlock.NumberU64(), groups[0], ) msg := p2p.ConstructMessage( proto_node.ConstructBlocksSyncMessage([]*types.Block{newBlock}), ) if err := node.host.SendMessageToGroups(groups, msg); err != nil { utils.Logger().Warn().Err(err).Msg("cannot broadcast new block") } } // BroadcastSlash .. func (node *Node) BroadcastSlash(witness *slash.Record) { if err := node.host.SendMessageToGroups( []nodeconfig.GroupID{nodeconfig.NewGroupIDByShardID(shard.BeaconChainShardID)}, p2p.ConstructMessage( proto_node.ConstructSlashMessage(slash.Records{*witness})), ); err != nil { utils.Logger().Err(err). RawJSON("record", []byte(witness.String())). Msg("could not send slash record to beaconchain") } utils.Logger().Info().Msg("broadcast the double sign record") } // BroadcastCrossLink is called by consensus leader to // send the new header as cross link to beacon chain. func (node *Node) BroadcastCrossLink() { curBlock := node.Blockchain().CurrentBlock() if curBlock == nil { return } if node.NodeConfig.ShardID == shard.BeaconChainShardID || !node.Blockchain().Config().IsCrossLink(curBlock.Epoch()) { // no need to broadcast crosslink if it's beacon chain or it's not crosslink epoch return } // no point to broadcast the crosslink if we aren't even in the right epoch yet if !node.Blockchain().Config().IsCrossLink( node.Blockchain().CurrentHeader().Epoch(), ) { return } utils.Logger().Info().Msgf( "Construct and Broadcasting new crosslink to beacon chain groupID %s", nodeconfig.NewGroupIDByShardID(shard.BeaconChainShardID), ) headers := []*block.Header{} lastLink, err := node.Beaconchain().ReadShardLastCrossLink(curBlock.ShardID()) var latestBlockNum uint64 // TODO chao: record the missing crosslink in local database instead of using latest crosslink // if cannot find latest crosslink, broadcast latest 3 block headers if err != nil { utils.Logger().Debug().Err(err).Msg("[BroadcastCrossLink] ReadShardLastCrossLink Failed") header := node.Blockchain().GetHeaderByNumber(curBlock.NumberU64() - 2) if header != nil && node.Blockchain().Config().IsCrossLink(header.Epoch()) { headers = append(headers, header) } header = node.Blockchain().GetHeaderByNumber(curBlock.NumberU64() - 1) if header != nil && node.Blockchain().Config().IsCrossLink(header.Epoch()) { headers = append(headers, header) } headers = append(headers, curBlock.Header()) } else { latestBlockNum = lastLink.BlockNum() batchSize := crossLinkBatchSize diff := curBlock.Number().Uint64() - latestBlockNum // Increase batch size by 1 for every 5 blocks behind batchSize += int(diff) / 5 // Cap at a sane size to avoid overload network if batchSize > crossLinkBatchSize*2 { batchSize = crossLinkBatchSize * 2 } for blockNum := latestBlockNum + 1; blockNum <= curBlock.NumberU64(); blockNum++ { header := node.Blockchain().GetHeaderByNumber(blockNum) if header != nil && node.Blockchain().Config().IsCrossLink(header.Epoch()) { headers = append(headers, header) if len(headers) == batchSize { break } } } } utils.Logger().Info().Msgf("[BroadcastCrossLink] Broadcasting Block Headers, latestBlockNum %d, currentBlockNum %d, Number of Headers %d", latestBlockNum, curBlock.NumberU64(), len(headers)) for _, header := range headers { utils.Logger().Debug().Msgf( "[BroadcastCrossLink] Broadcasting %d", header.Number().Uint64(), ) } node.host.SendMessageToGroups( []nodeconfig.GroupID{nodeconfig.NewGroupIDByShardID(shard.BeaconChainShardID)}, p2p.ConstructMessage( proto_node.ConstructCrossLinkMessage(node.Consensus.Blockchain, headers)), ) } // VerifyNewBlock is called by consensus participants to verify the block (account model) they are // running consensus on func (node *Node) VerifyNewBlock(newBlock *types.Block) error { if newBlock == nil || newBlock.Header() == nil { return errors.New("nil header or block asked to verify") } if newBlock.NumberU64() <= node.Blockchain().CurrentBlock().NumberU64() { return errors.Errorf("block with the same block number is already committed: %d", newBlock.NumberU64()) } if err := node.Blockchain().Validator().ValidateHeader(newBlock, true); err != nil { utils.Logger().Error(). Str("blockHash", newBlock.Hash().Hex()). Err(err). Msg("[VerifyNewBlock] Cannot validate header for the new block") return err } if newBlock.ShardID() != node.Blockchain().ShardID() { utils.Logger().Error(). Uint32("my shard ID", node.Blockchain().ShardID()). Uint32("new block's shard ID", newBlock.ShardID()). Msg("[VerifyNewBlock] Wrong shard ID of the new block") return errors.New("[VerifyNewBlock] Wrong shard ID of the new block") } if err := node.Blockchain().Engine().VerifyShardState( node.Blockchain(), node.Beaconchain(), newBlock.Header(), ); err != nil { utils.Logger().Error(). Str("blockHash", newBlock.Hash().Hex()). Err(err). Msg("[VerifyNewBlock] Cannot verify shard state for the new block") return errors.New( "[VerifyNewBlock] Cannot verify shard state for the new block", ) } if err := node.Blockchain().ValidateNewBlock(newBlock); err != nil { if hooks := node.NodeConfig.WebHooks.Hooks; hooks != nil { if p := hooks.ProtocolIssues; p != nil { url := p.OnCannotCommit go func() { webhooks.DoPost(url, map[string]interface{}{ "bad-header": newBlock.Header(), "reason": err.Error(), }) }() } } utils.Logger().Error(). Str("blockHash", newBlock.Hash().Hex()). Int("numTx", len(newBlock.Transactions())). Int("numStakingTx", len(newBlock.StakingTransactions())). Err(err). Msg("[VerifyNewBlock] Cannot Verify New Block!!!") return errors.Errorf( "[VerifyNewBlock] Cannot Verify New Block!!! block-hash %s txn-count %d", newBlock.Hash().Hex(), len(newBlock.Transactions()), ) } // Verify cross links // TODO: move into ValidateNewBlock if node.NodeConfig.ShardID == shard.BeaconChainShardID { err := node.VerifyBlockCrossLinks(newBlock) if err != nil { utils.Logger().Debug().Err(err).Msg("ops2 VerifyBlockCrossLinks Failed") return err } } // TODO: move into ValidateNewBlock if err := node.verifyIncomingReceipts(newBlock); err != nil { utils.Logger().Error(). Str("blockHash", newBlock.Hash().Hex()). Int("numIncomingReceipts", len(newBlock.IncomingReceipts())). Err(err). Msg("[VerifyNewBlock] Cannot ValidateNewBlock") return errors.Wrapf( err, "[VerifyNewBlock] Cannot ValidateNewBlock", ) } return nil } // PostConsensusProcessing is called by consensus participants, after consensus is done, to: // 1. add the new block to blockchain // 2. [leader] send new block to the client // 3. [leader] send cross shard tx receipts to destination shard func (node *Node) PostConsensusProcessing(newBlock *types.Block) error { if node.Consensus.IsLeader() { if node.NodeConfig.ShardID == shard.BeaconChainShardID { node.BroadcastNewBlock(newBlock) } node.BroadcastCXReceipts(newBlock) } else { if node.Consensus.Mode() != consensus.Listening { utils.Logger().Info(). Uint64("blockNum", newBlock.NumberU64()). Uint64("epochNum", newBlock.Epoch().Uint64()). Uint64("ViewId", newBlock.Header().ViewID().Uint64()). Str("blockHash", newBlock.Hash().String()). Int("numTxns", len(newBlock.Transactions())). Int("numStakingTxns", len(newBlock.StakingTransactions())). Uint32("numSignatures", node.Consensus.NumSignaturesIncludedInBlock(newBlock)). Msg("BINGO !!! Reached Consensus") numSig := float64(node.Consensus.NumSignaturesIncludedInBlock(newBlock)) node.Consensus.UpdateValidatorMetrics(numSig, float64(newBlock.NumberU64())) // 1% of the validator also need to do broadcasting rand.Seed(time.Now().UTC().UnixNano()) rnd := rand.Intn(100) if rnd < 1 { // Beacon validators also broadcast new blocks to make sure beacon sync is strong. if node.NodeConfig.ShardID == shard.BeaconChainShardID { node.BroadcastNewBlock(newBlock) } node.BroadcastCXReceipts(newBlock) } } } // Broadcast client requested missing cross shard receipts if there is any node.BroadcastMissingCXReceipts() if h := node.NodeConfig.WebHooks.Hooks; h != nil { if h.Availability != nil { for _, addr := range node.GetAddresses(newBlock.Epoch()) { wrapper, err := node.Beaconchain().ReadValidatorInformation(addr) if err != nil { utils.Logger().Err(err).Str("addr", addr.Hex()).Msg("failed reaching validator info") return nil } snapshot, err := node.Beaconchain().ReadValidatorSnapshot(addr) if err != nil { utils.Logger().Err(err).Str("addr", addr.Hex()).Msg("failed reaching validator snapshot") return nil } computed := availability.ComputeCurrentSigning( snapshot.Validator, wrapper, ) lastBlockOfEpoch := shard.Schedule.EpochLastBlock(node.Beaconchain().CurrentBlock().Header().Epoch().Uint64()) computed.BlocksLeftInEpoch = lastBlockOfEpoch - node.Beaconchain().CurrentBlock().Header().Number().Uint64() if err != nil && computed.IsBelowThreshold { url := h.Availability.OnDroppedBelowThreshold go func() { webhooks.DoPost(url, computed) }() } } } } return nil } // BootstrapConsensus is the a goroutine to check number of peers and start the consensus func (node *Node) BootstrapConsensus() error { ctx, cancel := context.WithTimeout(context.Background(), time.Minute) defer cancel() min := node.Consensus.MinPeers enoughMinPeers := make(chan struct{}) const checkEvery = 3 * time.Second go func() { for { <-time.After(checkEvery) numPeersNow := node.host.GetPeerCount() if numPeersNow >= min { utils.Logger().Info().Msg("[bootstrap] StartConsensus") enoughMinPeers <- struct{}{} return } utils.Logger().Info(). Int("numPeersNow", numPeersNow). Int("targetNumPeers", min). Dur("next-peer-count-check-in-seconds", checkEvery). Msg("do not have enough min peers yet in bootstrap of consensus") } }() select { case <-ctx.Done(): return ctx.Err() case <-enoughMinPeers: go func() { node.startConsensus <- struct{}{} }() return nil } }