package node import ( "bytes" "context" "errors" "math" "math/big" "os" "os/exec" "strconv" "sync" "sync/atomic" "syscall" "time" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/rlp" pb "github.com/golang/protobuf/proto" "github.com/harmony-one/bls/ffi/go/bls" libp2p_peer "github.com/libp2p/go-libp2p-peer" "github.com/harmony-one/harmony/api/proto" proto_discovery "github.com/harmony-one/harmony/api/proto/discovery" "github.com/harmony-one/harmony/api/proto/message" proto_node "github.com/harmony-one/harmony/api/proto/node" "github.com/harmony-one/harmony/contracts/structs" "github.com/harmony-one/harmony/core" "github.com/harmony-one/harmony/core/types" 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" ) const ( consensusTimeout = 30 * time.Second ) // ReceiveGlobalMessage use libp2p pubsub mechanism to receive global broadcast messages func (node *Node) ReceiveGlobalMessage() { ctx := context.Background() for { if node.globalGroupReceiver == nil { time.Sleep(100 * time.Millisecond) continue } msg, sender, err := node.globalGroupReceiver.Receive(ctx) if sender != node.host.GetID() { //utils.Logger().Info("[PUBSUB]", "received global msg", len(msg), "sender", sender) if err == nil { // skip the first 5 bytes, 1 byte is p2p type, 4 bytes are message size go node.messageHandler(msg[5:], sender) } } } } // ReceiveGroupMessage use libp2p pubsub mechanism to receive broadcast messages func (node *Node) ReceiveGroupMessage() { ctx := context.Background() for { if node.shardGroupReceiver == nil { time.Sleep(100 * time.Millisecond) continue } msg, sender, err := node.shardGroupReceiver.Receive(ctx) if sender != node.host.GetID() { //utils.Logger().Info("[PUBSUB]", "received group msg", len(msg), "sender", sender) if err == nil { // skip the first 5 bytes, 1 byte is p2p type, 4 bytes are message size go node.messageHandler(msg[5:], sender) } } } } // ReceiveClientGroupMessage use libp2p pubsub mechanism to receive broadcast messages for client func (node *Node) ReceiveClientGroupMessage() { ctx := context.Background() for { if node.clientReceiver == nil { // check less frequent on client messages time.Sleep(100 * time.Millisecond) continue } msg, sender, err := node.clientReceiver.Receive(ctx) if sender != node.host.GetID() { // utils.Logger().Info("[CLIENT]", "received group msg", len(msg), "sender", sender, "error", err) if err == nil { // skip the first 5 bytes, 1 byte is p2p type, 4 bytes are message size go node.messageHandler(msg[5:], sender) } } } } // messageHandler parses the message and dispatch the actions func (node *Node) messageHandler(content []byte, sender libp2p_peer.ID) { msgCategory, err := proto.GetMessageCategory(content) if err != nil { utils.Logger().Error(). Err(err). Msg("messageHandler get message category failed") return } msgType, err := proto.GetMessageType(content) if err != nil { utils.Logger().Error(). Err(err). Msg("messageHandler get message type failed") return } msgPayload, err := proto.GetMessagePayload(content) if err != nil { utils.Logger().Error(). Err(err). Msg("messageHandler get message payload failed") return } switch msgCategory { case proto.Consensus: msgPayload, _ := proto.GetConsensusMessagePayload(content) if node.NodeConfig.Role() == nodeconfig.ExplorerNode { node.ExplorerMessageHandler(msgPayload) } else { node.ConsensusMessageHandler(msgPayload) } case proto.DRand: msgPayload, _ := proto.GetDRandMessagePayload(content) if node.DRand != nil { if node.DRand.IsLeader { node.DRand.ProcessMessageLeader(msgPayload) } else { node.DRand.ProcessMessageValidator(msgPayload) } } case proto.Staking: utils.Logger().Debug().Msg("NET: Received staking message") msgPayload, _ := proto.GetStakingMessagePayload(content) // Only beacon leader processes staking txn if node.Consensus != nil && node.Consensus.ShardID == 0 && node.Consensus.IsLeader() { node.processStakingMessage(msgPayload) } case proto.Node: actionType := proto_node.MessageType(msgType) switch actionType { case proto_node.Transaction: utils.Logger().Debug().Msg("NET: received message: Node/Transaction") node.transactionMessageHandler(msgPayload) case proto_node.Block: utils.Logger().Debug().Msg("NET: received message: Node/Block") blockMsgType := proto_node.BlockMessageType(msgPayload[0]) switch blockMsgType { case proto_node.Sync: utils.Logger().Debug().Msg("NET: received message: Node/Sync") var blocks []*types.Block err := rlp.DecodeBytes(msgPayload[1:], &blocks) if err != nil { utils.Logger().Error(). Err(err). Msg("block sync") } else { // for non-beaconchain node, subscribe to beacon block broadcast role := node.NodeConfig.Role() if role == nodeconfig.Validator { for _, block := range blocks { if block.ShardID() == 0 { utils.Logger().Info(). Uint64("block", blocks[0].NumberU64()). Msgf("Block being handled by block channel %d %d", block.NumberU64(), block.ShardID()) node.BeaconBlockChannel <- block } } } if node.Client != nil && node.Client.UpdateBlocks != nil && blocks != nil { utils.Logger().Info().Msg("Block being handled by client") node.Client.UpdateBlocks(blocks) } } case proto_node.Header: // only beacon chain will accept the header from other shards utils.Logger().Debug().Msg("NET: received message: Node/Header") if node.NodeConfig.ShardID != 0 { return } node.ProcessHeaderMessage(msgPayload[1:]) // skip first byte which is blockMsgType case proto_node.Receipt: utils.Logger().Debug().Msg("NET: received message: Node/Receipt") node.ProcessReceiptMessage(msgPayload[1:]) // skip first byte which is blockMsgType } case proto_node.PING: node.pingMessageHandler(msgPayload, sender) case proto_node.ShardState: if err := node.epochShardStateMessageHandler(msgPayload); err != nil { ctxerror.Log15(utils.GetLogger().Warn, err) } } default: utils.Logger().Error(). Str("Unknown MsgCateogry", string(msgCategory)) } } func (node *Node) processStakingMessage(msgPayload []byte) { msg := &message.Message{} err := pb.Unmarshal(msgPayload, msg) if err == nil { stakingRequest := msg.GetStaking() txs := types.Transactions{} if err = rlp.DecodeBytes(stakingRequest.Transaction, &txs); err == nil { utils.Logger().Info().Msg("Successfully added staking transaction to pending list.") node.addPendingTransactions(txs) } else { utils.Logger().Error(). Err(err). Msg("Failed to unmarshal staking transaction list") } } else { utils.Logger().Error(). Err(err). Msg("Failed to unmarshal staking msg payload") } } 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") } node.addPendingTransactions(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 := []p2p.GroupID{node.NodeConfig.GetClientGroupID()} utils.Logger().Info().Msgf("broadcasting new block %d, group %s", newBlock.NumberU64(), groups[0]) msg := host.ConstructP2pMessage(byte(0), 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") } } // BroadcastCrossLinkHeader is called by consensus leader to send the new header as cross link to beacon chain. func (node *Node) BroadcastCrossLinkHeader(newBlock *types.Block) { utils.Logger().Info().Msgf("Broadcasting new header to beacon chain groupID %s", node.NodeConfig.GetBeaconGroupID()) lastThreeHeaders := []*types.Header{} block := node.Blockchain().GetBlockByNumber(newBlock.NumberU64() - 2) if block != nil { lastThreeHeaders = append(lastThreeHeaders, block.Header()) } block = node.Blockchain().GetBlockByNumber(newBlock.NumberU64() - 1) if block != nil { lastThreeHeaders = append(lastThreeHeaders, block.Header()) } lastThreeHeaders = append(lastThreeHeaders, newBlock.Header()) node.host.SendMessageToGroups([]p2p.GroupID{node.NodeConfig.GetBeaconGroupID()}, host.ConstructP2pMessage(byte(0), proto_node.ConstructCrossLinkHeadersMessage(lastThreeHeaders))) } // BroadcastCXReceipts broadcasts cross shard receipts to correspoding // destination shards func (node *Node) BroadcastCXReceipts(newBlock *types.Block) { epoch := newBlock.Header().Epoch shardingConfig := core.ShardingSchedule.InstanceForEpoch(epoch) shardNum := int(shardingConfig.NumShards()) myShardID := node.Consensus.ShardID utils.Logger().Info().Int("shardNum", shardNum).Uint32("myShardID", myShardID).Uint64("blockNum", newBlock.NumberU64()).Msg("[BroadcastCXReceipts]") for i := 0; i < shardNum; i++ { if i == int(myShardID) { continue } cxReceipts, err := node.Blockchain().ReadCXReceipts(uint32(i), newBlock.NumberU64(), newBlock.Hash(), false) if err != nil || len(cxReceipts) == 0 { //utils.Logger().Warn().Err(err).Uint32("ToShardID", uint32(i)).Int("numCXReceipts", len(cxReceipts)).Msg("[BroadcastCXReceipts] No ReadCXReceipts found") continue } merkleProof, err := node.Blockchain().CXMerkleProof(uint32(i), newBlock) if err != nil { utils.Logger().Warn().Uint32("ToShardID", uint32(i)).Msg("[BroadcastCXReceipts] Unable to get merkleProof") continue } utils.Logger().Info().Uint32("ToShardID", uint32(i)).Msg("[BroadcastCXReceipts] ReadCXReceipts and MerkleProof Found") groupID := p2p.ShardID(i) go node.host.SendMessageToGroups([]p2p.GroupID{p2p.NewGroupIDByShardID(groupID)}, host.ConstructP2pMessage(byte(0), proto_node.ConstructCXReceiptsProof(cxReceipts, merkleProof))) } } // 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 { // TODO ek – where do we verify parent-child invariants, // e.g. "child.Number == child.IsGenesis() ? 0 : parent.Number+1"? if newBlock.NumberU64() > 1 { err := core.VerifyBlockLastCommitSigs(node.Blockchain(), newBlock) if err != nil { return err } } if newBlock.ShardID() != node.Blockchain().ShardID() { return ctxerror.New("wrong shard ID", "my shard ID", node.Blockchain().ShardID(), "new block's shard ID", newBlock.ShardID()) } err := node.Blockchain().ValidateNewBlock(newBlock) if err != nil { return ctxerror.New("cannot ValidateNewBlock", "blockHash", newBlock.Hash(), "numTx", len(newBlock.Transactions()), ).WithCause(err) } // Verify cross links if node.NodeConfig.ShardID == 0 { err := node.VerifyBlockCrossLinks(newBlock) if err != nil { return err } } err = node.verifyIncomingReceipts(newBlock) if err != nil { return ctxerror.New("[VerifyNewBlock] Cannot ValidateNewBlock", "blockHash", newBlock.Hash(), "numIncomingReceipts", len(newBlock.IncomingReceipts())).WithCause(err) } // TODO: verify the vrf randomness // _ = newBlock.Header().Vrf // TODO: uncomment 4 lines after we finish staking mechanism //err = node.validateNewShardState(newBlock, &node.CurrentStakes) // if err != nil { // return ctxerror.New("failed to verify sharding state").WithCause(err) // } return nil } // VerifyBlockCrossLinks verifies the cross links of the block func (node *Node) VerifyBlockCrossLinks(block *types.Block) error { if len(block.Header().CrossLinks) == 0 { return nil } crossLinks := &types.CrossLinks{} err := rlp.DecodeBytes(block.Header().CrossLinks, crossLinks) if err != nil { return ctxerror.New("[CrossLinkVerification] failed to decode cross links", "blockHash", block.Hash(), "crossLinks", len(block.Header().CrossLinks), ).WithCause(err) } if !crossLinks.IsSorted() { return ctxerror.New("[CrossLinkVerification] cross links are not sorted", "blockHash", block.Hash(), "crossLinks", len(block.Header().CrossLinks), ) } firstCrossLinkBlock := core.ShardingSchedule.FirstCrossLinkBlock() for i, crossLink := range *crossLinks { lastLink := &types.CrossLink{} if i == 0 { if crossLink.BlockNum().Uint64() > firstCrossLinkBlock { lastLink, err = node.Blockchain().ReadShardLastCrossLink(crossLink.ShardID()) if err != nil { return ctxerror.New("[CrossLinkVerification] no last cross link found 1", "blockHash", block.Hash(), "crossLink", lastLink, ).WithCause(err) } } } else { if (*crossLinks)[i-1].Header().ShardID != crossLink.Header().ShardID { if crossLink.BlockNum().Uint64() > firstCrossLinkBlock { lastLink, err = node.Blockchain().ReadShardLastCrossLink(crossLink.ShardID()) if err != nil { return ctxerror.New("[CrossLinkVerification] no last cross link found 2", "blockHash", block.Hash(), "crossLink", lastLink, ).WithCause(err) } } } else { lastLink = &(*crossLinks)[i-1] } } if crossLink.BlockNum().Uint64() > firstCrossLinkBlock { // TODO: verify genesis block err = node.VerifyCrosslinkHeader(lastLink.Header(), crossLink.Header()) if err != nil { return ctxerror.New("cannot ValidateNewBlock", "blockHash", block.Hash(), "numTx", len(block.Transactions()), ).WithCause(err) } } } return nil } // BigMaxUint64 is maximum possible uint64 value, that is, (1**64)-1. var BigMaxUint64 = new(big.Int).SetBytes([]byte{ 255, 255, 255, 255, 255, 255, 255, 255, }) // validateNewShardState validate whether the new shard state root matches func (node *Node) validateNewShardState(block *types.Block, stakeInfo *map[common.Address]*structs.StakeInfo) error { // Common case first – blocks without resharding proposal header := block.Header() if header.ShardStateHash == (common.Hash{}) { // No new shard state was proposed if block.ShardID() == 0 { if core.IsEpochLastBlock(block) { // TODO ek - invoke view change return errors.New("beacon leader did not propose resharding") } } else { if node.nextShardState.master != nil && !time.Now().Before(node.nextShardState.proposeTime) { // TODO ek – invoke view change return errors.New("regular leader did not propose resharding") } } // We aren't expecting to reshard, so proceed to sign return nil } shardState := &types.ShardState{} err := rlp.DecodeBytes(header.ShardState, shardState) if err != nil { return err } proposed := *shardState if block.ShardID() == 0 { // Beacon validators independently recalculate the master state and // compare it against the proposed copy. nextEpoch := new(big.Int).Add(block.Header().Epoch, common.Big1) // TODO ek – this may be called from regular shards, // for vetting beacon chain blocks received during block syncing. // DRand may or or may not get in the way. Test this out. expected, err := core.CalculateNewShardState( node.Blockchain(), nextEpoch, stakeInfo) if err != nil { return ctxerror.New("cannot calculate expected shard state"). WithCause(err) } if types.CompareShardState(expected, proposed) != 0 { // TODO ek – log state proposal differences // TODO ek – this error should trigger view change err := errors.New("shard state proposal is different from expected") // TODO ek/chao – calculated shard state is different even with the // same input, i.e. it is nondeterministic. // Don't treat this as a blocker until we fix the nondeterminism. //return err ctxerror.Log15(utils.GetLogger().Warn, err) } } else { // Regular validators fetch the local-shard copy on the beacon chain // and compare it against the proposed copy. // // We trust the master proposal in our copy of beacon chain. // The sanity check for the master proposal is done earlier, // when the beacon block containing the master proposal is received // and before it is admitted into the local beacon chain. // // TODO ek – fetch masterProposal from beaconchain instead masterProposal := node.nextShardState.master.ShardState expected := masterProposal.FindCommitteeByID(block.ShardID()) switch len(proposed) { case 0: // Proposal to discontinue shard if expected != nil { // TODO ek – invoke view change return errors.New( "leader proposed to disband against beacon decision") } case 1: // Proposal to continue shard proposed := proposed[0] // Sanity check: Shard ID should match if proposed.ShardID != block.ShardID() { // TODO ek – invoke view change return ctxerror.New("proposal has incorrect shard ID", "proposedShard", proposed.ShardID, "blockShard", block.ShardID()) } // Did beaconchain say we are no more? if expected == nil { // TODO ek – invoke view change return errors.New( "leader proposed to continue against beacon decision") } // Did beaconchain say the same proposal? if types.CompareCommittee(expected, &proposed) != 0 { // TODO ek – log differences // TODO ek – invoke view change return errors.New("proposal differs from one in beacon chain") } default: // TODO ek – invoke view change return ctxerror.New( "regular resharding proposal has incorrect number of shards", "numShards", len(proposed)) } } 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) { if err := node.AddNewBlock(newBlock); err != nil { utils.Logger().Error(). Err(err). Msg("Error when adding new block") return } else if core.IsEpochLastBlock(newBlock) { node.Consensus.UpdateConsensusInformation() } // Update last consensus time for metrics node.lastConsensusTime = time.Now().Unix() if node.Consensus.PubKey.IsEqual(node.Consensus.LeaderPubKey) { if node.NodeConfig.ShardID == 0 { node.BroadcastNewBlock(newBlock) } else { node.BroadcastCrossLinkHeader(newBlock) } node.BroadcastCXReceipts(newBlock) } else { utils.Logger().Info(). Uint64("ViewID", node.Consensus.GetViewID()). Msg("BINGO !!! Reached Consensus") } node.Blockchain().CleanCXReceiptsCheckpointsByBlock(newBlock) if node.NodeConfig.GetNetworkType() != nodeconfig.Mainnet { // Update contract deployer's nonce so default contract like faucet can issue transaction with current nonce nonce := node.GetNonceOfAddress(crypto.PubkeyToAddress(node.ContractDeployerKey.PublicKey)) atomic.StoreUint64(&node.ContractDeployerCurrentNonce, nonce) for _, tx := range newBlock.Transactions() { msg, err := tx.AsMessage(types.HomesteadSigner{}) if err != nil { utils.Logger().Error().Msg("Error when parsing tx into message") } if _, ok := node.AddressNonce.Load(msg.From()); ok { nonce := node.GetNonceOfAddress(msg.From()) node.AddressNonce.Store(msg.From(), nonce) } } // TODO: Enable the following after v0 if node.Consensus.ShardID == 0 { // TODO: enable drand only for beacon chain // ConfirmedBlockChannel which is listened by drand leader who will initiate DRG if its a epoch block (first block of a epoch) //if node.DRand != nil { // go func() { // node.ConfirmedBlockChannel <- newBlock // }() //} // TODO: enable staking // TODO: update staking information once per epoch. //node.UpdateStakingList(node.QueryStakeInfo()) //node.printStakingList() } // TODO: enable shard state update //newBlockHeader := newBlock.Header() //if newBlockHeader.ShardStateHash != (common.Hash{}) { // if node.Consensus.ShardID == 0 { // // TODO ek – this is a temp hack until beacon chain sync is fixed // // End-of-epoch block on beacon chain; block's EpochState is the // // master resharding table. Broadcast it to the network. // if err := node.broadcastEpochShardState(newBlock); err != nil { // e := ctxerror.New("cannot broadcast shard state").WithCause(err) // ctxerror.Log15(utils.Logger().Error, e) // } // } // shardState, err := newBlockHeader.GetShardState() // if err != nil { // e := ctxerror.New("cannot get shard state from header").WithCause(err) // ctxerror.Log15(utils.Logger().Error, e) // } else { // node.transitionIntoNextEpoch(shardState) // } //} } } func (node *Node) broadcastEpochShardState(newBlock *types.Block) error { shardState, err := newBlock.Header().GetShardState() if err != nil { return err } epochShardStateMessage := proto_node.ConstructEpochShardStateMessage( types.EpochShardState{ Epoch: newBlock.Header().Epoch.Uint64() + 1, ShardState: shardState, }, ) return node.host.SendMessageToGroups( []p2p.GroupID{node.NodeConfig.GetClientGroupID()}, host.ConstructP2pMessage(byte(0), epochShardStateMessage)) } // AddNewBlock is usedd to add new block into the blockchain. func (node *Node) AddNewBlock(newBlock *types.Block) error { _, err := node.Blockchain().InsertChain([]*types.Block{newBlock}) if err != nil { utils.Logger().Error(). Err(err). Uint64("blockNum", newBlock.NumberU64()). Bytes("parentHash", newBlock.Header().ParentHash.Bytes()[:]). Bytes("hash", newBlock.Header().Hash().Bytes()[:]). Msg("Error Adding new block to blockchain") } else { utils.Logger().Info(). Uint64("blockNum", newBlock.NumberU64()). Str("hash", newBlock.Header().Hash().Hex()). Msg("Added New Block to Blockchain!!!") } return err } type genesisNode struct { ShardID uint32 MemberIndex int NodeID types.NodeID } var ( genesisCatalogOnce sync.Once genesisNodeByStakingAddress = make(map[common.Address]*genesisNode) genesisNodeByConsensusKey = make(map[types.BlsPublicKey]*genesisNode) ) func initGenesisCatalog() { genesisShardState := core.GetInitShardState() for _, committee := range genesisShardState { for i, nodeID := range committee.NodeList { genesisNode := &genesisNode{ ShardID: committee.ShardID, MemberIndex: i, NodeID: nodeID, } genesisNodeByStakingAddress[nodeID.EcdsaAddress] = genesisNode genesisNodeByConsensusKey[nodeID.BlsPublicKey] = genesisNode } } } func getGenesisNodeByStakingAddress(address common.Address) *genesisNode { genesisCatalogOnce.Do(initGenesisCatalog) return genesisNodeByStakingAddress[address] } func getGenesisNodeByConsensusKey(key types.BlsPublicKey) *genesisNode { genesisCatalogOnce.Do(initGenesisCatalog) return genesisNodeByConsensusKey[key] } func (node *Node) pingMessageHandler(msgPayload []byte, sender libp2p_peer.ID) int { ping, err := proto_discovery.GetPingMessage(msgPayload) if err != nil { utils.Logger().Error(). Err(err). Msg("Can't get Ping Message") return -1 } peer := new(p2p.Peer) peer.IP = ping.Node.IP peer.Port = ping.Node.Port peer.PeerID = ping.Node.PeerID peer.ConsensusPubKey = nil if ping.Node.PubKey != nil { peer.ConsensusPubKey = &bls.PublicKey{} if err := peer.ConsensusPubKey.Deserialize(ping.Node.PubKey[:]); err != nil { utils.Logger().Error(). Err(err). Msg("UnmarshalBinary Failed") return -1 } } utils.Logger().Debug(). Str("Version", ping.NodeVer). Str("BlsKey", peer.ConsensusPubKey.SerializeToHexStr()). Str("IP", peer.IP). Str("Port", peer.Port). Interface("PeerID", peer.PeerID). Msg("[PING] PeerInfo") senderStr := string(sender) if senderStr != "" { _, ok := node.duplicatedPing.LoadOrStore(senderStr, true) if ok { // duplicated ping message return return 0 } } // add to incoming peer list //node.host.AddIncomingPeer(*peer) node.host.ConnectHostPeer(*peer) if ping.Node.Role == proto_node.ClientRole { utils.Logger().Info(). Str("Client", peer.String()). Msg("Add Client Peer to Node") node.ClientPeer = peer } else { node.AddPeers([]*p2p.Peer{peer}) utils.Logger().Info(). Str("Peer", peer.String()). Int("# Peers", len(node.Consensus.PublicKeys)). Msg("Add Peer to Node") } return 1 } // bootstrapConsensus is the a goroutine to check number of peers and start the consensus func (node *Node) bootstrapConsensus() { tick := time.NewTicker(5 * time.Second) for { select { case <-tick.C: numPeersNow := node.numPeers // no peers, wait for another tick if numPeersNow == 0 { utils.Logger().Info(). Int("numPeersNow", numPeersNow). Msg("No peers, continue") continue } if numPeersNow >= node.Consensus.MinPeers { utils.Logger().Info().Msg("[bootstrap] StartConsensus") node.startConsensus <- struct{}{} return } } } } func (node *Node) epochShardStateMessageHandler(msgPayload []byte) error { epochShardState, err := proto_node.DeserializeEpochShardStateFromMessage(msgPayload) if err != nil { return ctxerror.New("Can't get shard state message").WithCause(err) } if node.Consensus == nil { return nil } receivedEpoch := big.NewInt(int64(epochShardState.Epoch)) utils.Logger().Info(). Int64("epoch", receivedEpoch.Int64()). Msg("received new shard state") node.nextShardState.master = epochShardState if node.Consensus.IsLeader() { // Wait a bit to allow the master table to reach other validators. node.nextShardState.proposeTime = time.Now().Add(5 * time.Second) } else { // Wait a bit to allow the master table to reach the leader, // and to allow the leader to propose next shard state based upon it. node.nextShardState.proposeTime = time.Now().Add(15 * time.Second) } // TODO ek – this should be done from replaying beaconchain once // beaconchain sync is fixed err = node.Beaconchain().WriteShardState( receivedEpoch, epochShardState.ShardState) if err != nil { return ctxerror.New("cannot store shard state", "epoch", receivedEpoch). WithCause(err) } return nil } /* func (node *Node) transitionIntoNextEpoch(shardState types.ShardState) { logger = logger.New( "blsPubKey", hex.EncodeToString(node.Consensus.PubKey.Serialize()), "curShard", node.Blockchain().ShardID(), "curLeader", node.Consensus.IsLeader()) for _, c := range shardState { utils.Logger().Debug(). Uint32("shardID", c.ShardID). Str("nodeList", c.NodeList). Msg("new shard information") } myShardID, isNextLeader := findRoleInShardState( node.Consensus.PubKey, shardState) logger = logger.New( "nextShard", myShardID, "nextLeader", isNextLeader) if myShardID == math.MaxUint32 { getLogger().Info("Somehow I got kicked out. Exiting") os.Exit(8) // 8 represents it's a loop and the program restart itself } myShardState := shardState[myShardID] // Update public keys var publicKeys []*bls.PublicKey for idx, nodeID := range myShardState.NodeList { key := &bls.PublicKey{} err := key.Deserialize(nodeID.BlsPublicKey[:]) if err != nil { getLogger().Error("Failed to deserialize BLS public key in shard state", "idx", idx, "error", err) } publicKeys = append(publicKeys, key) } node.Consensus.UpdatePublicKeys(publicKeys) // node.DRand.UpdatePublicKeys(publicKeys) if node.Blockchain().ShardID() == myShardID { getLogger().Info("staying in the same shard") } else { getLogger().Info("moving to another shard") if err := node.shardChains.Close(); err != nil { getLogger().Error("cannot close shard chains", "error", err) } restartProcess(getRestartArguments(myShardID)) } } */ func findRoleInShardState( key *bls.PublicKey, state types.ShardState, ) (shardID uint32, isLeader bool) { keyBytes := key.Serialize() for idx, shard := range state { for nodeIdx, nodeID := range shard.NodeList { if bytes.Compare(nodeID.BlsPublicKey[:], keyBytes) == 0 { return uint32(idx), nodeIdx == 0 } } } return math.MaxUint32, false } func restartProcess(args []string) { execFile, err := getBinaryPath() if err != nil { utils.Logger().Error(). Err(err). Str("file", execFile). Msg("Failed to get program path when restarting program") } utils.Logger().Info(). Strs("args", args). Strs("env", os.Environ()). Msg("Restarting program") err = syscall.Exec(execFile, args, os.Environ()) if err != nil { utils.Logger().Error(). Err(err). Msg("Failed to restart program after resharding") } panic("syscall.Exec() is not supposed to return") } func getRestartArguments(myShardID uint32) []string { args := os.Args hasShardID := false shardIDFlag := "-shard_id" // newNodeFlag := "-is_newnode" for i, arg := range args { if arg == shardIDFlag { if i+1 < len(args) { args[i+1] = strconv.Itoa(int(myShardID)) } else { args = append(args, strconv.Itoa(int(myShardID))) } hasShardID = true } // TODO: enable this //if arg == newNodeFlag { // args[i] = "" // remove new node flag //} } if !hasShardID { args = append(args, shardIDFlag) args = append(args, strconv.Itoa(int(myShardID))) } return args } // Gets the path of this currently running binary program. func getBinaryPath() (argv0 string, err error) { argv0, err = exec.LookPath(os.Args[0]) if nil != err { return } if _, err = os.Stat(argv0); nil != err { return } return } // ConsensusMessageHandler passes received message in node_handler to consensus func (node *Node) ConsensusMessageHandler(msgPayload []byte) { node.Consensus.MsgChan <- msgPayload }