package node import ( "fmt" "net" "sync" "time" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/rlp" "github.com/pkg/errors" "github.com/harmony-one/harmony/api/service/syncing" "github.com/harmony-one/harmony/api/service/syncing/downloader" downloader_pb "github.com/harmony-one/harmony/api/service/syncing/downloader/proto" "github.com/harmony-one/harmony/consensus" "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/utils" "github.com/harmony-one/harmony/node/worker" "github.com/harmony-one/harmony/p2p" ) // Constants related to doing syncing. const ( lastMileThreshold = 4 inSyncThreshold = 1 // unit in number of block SyncFrequency = 10 // unit in second MinConnectedPeers = 10 // minimum number of peers connected to in node syncing ) // getNeighborPeers is a helper function to return list of peers // based on different neightbor map func getNeighborPeers(neighbor *sync.Map) []p2p.Peer { tmp := []p2p.Peer{} neighbor.Range(func(k, v interface{}) bool { p := v.(p2p.Peer) t := p.Port p.Port = syncing.GetSyncingPort(t) tmp = append(tmp, p) return true }) return tmp } // DoSyncWithoutConsensus gets sync-ed to blockchain without joining consensus func (node *Node) DoSyncWithoutConsensus() { go node.DoSyncing(node.Blockchain(), node.Worker, false) //Don't join consensus } // IsSameHeight tells whether node is at same bc height as a peer func (node *Node) IsSameHeight() (uint64, bool) { if node.stateSync == nil { node.stateSync = syncing.CreateStateSync(node.SelfPeer.IP, node.SelfPeer.Port, node.GetSyncID()) } return node.stateSync.IsSameBlockchainHeight(node.Blockchain()) } // SyncingPeerProvider is an interface for getting the peers in the given shard. type SyncingPeerProvider interface { SyncingPeers(shardID uint32) (peers []p2p.Peer, err error) } // LegacySyncingPeerProvider uses neighbor lists stored in a Node to serve // syncing peer list query. type LegacySyncingPeerProvider struct { node *Node shardID func() uint32 } // NewLegacySyncingPeerProvider creates and returns a new node-based syncing // peer provider. func NewLegacySyncingPeerProvider(node *Node) *LegacySyncingPeerProvider { var shardID func() uint32 if node.shardChains != nil { shardID = node.Blockchain().ShardID } return &LegacySyncingPeerProvider{node: node, shardID: shardID} } // SyncingPeers returns peers stored in neighbor maps in the node structure. func (p *LegacySyncingPeerProvider) SyncingPeers(shardID uint32) (peers []p2p.Peer, err error) { switch shardID { case p.shardID(): peers = getNeighborPeers(&p.node.Neighbors) case 0: peers = getNeighborPeers(&p.node.BeaconNeighbors) default: return nil, errors.Errorf("unsupported shard ID %v", shardID) } return peers, nil } // DNSSyncingPeerProvider uses the given DNS zone to resolve syncing peers. type DNSSyncingPeerProvider struct { zone, port string lookupHost func(name string) (addrs []string, err error) } // NewDNSSyncingPeerProvider returns a provider that uses given DNS name and // port number to resolve syncing peers. func NewDNSSyncingPeerProvider(zone, port string) *DNSSyncingPeerProvider { return &DNSSyncingPeerProvider{ zone: zone, port: port, lookupHost: net.LookupHost, } } // SyncingPeers resolves DNS name into peers and returns them. func (p *DNSSyncingPeerProvider) SyncingPeers(shardID uint32) (peers []p2p.Peer, err error) { dns := fmt.Sprintf("s%d.%s", shardID, p.zone) addrs, err := p.lookupHost(dns) if err != nil { return nil, errors.Wrapf(err, "[SYNC] cannot find peers using DNS name %#v", dns) } for _, addr := range addrs { peers = append(peers, p2p.Peer{IP: addr, Port: p.port}) } return peers, nil } // LocalSyncingPeerProvider uses localnet deployment convention to synthesize // syncing peers. type LocalSyncingPeerProvider struct { basePort, selfPort uint16 numShards, shardSize uint32 } // NewLocalSyncingPeerProvider returns a provider that synthesizes syncing // peers given the network configuration func NewLocalSyncingPeerProvider( basePort, selfPort uint16, numShards, shardSize uint32, ) *LocalSyncingPeerProvider { return &LocalSyncingPeerProvider{ basePort: basePort, selfPort: selfPort, numShards: numShards, shardSize: shardSize, } } // SyncingPeers returns local syncing peers using the sharding configuration. func (p *LocalSyncingPeerProvider) SyncingPeers(shardID uint32) (peers []p2p.Peer, err error) { if shardID >= p.numShards { return nil, errors.Errorf( "shard ID %d out of range 0..%d", shardID, p.numShards-1) } firstPort := uint32(p.basePort) + shardID endPort := uint32(p.basePort) + p.numShards*p.shardSize for port := firstPort; port < endPort; port += p.numShards { if port == uint32(p.selfPort) { continue // do not sync from self } peers = append(peers, p2p.Peer{IP: "127.0.0.1", Port: fmt.Sprint(port)}) } return peers, nil } // DoBeaconSyncing update received beaconchain blocks and downloads missing beacon chain blocks func (node *Node) DoBeaconSyncing() { for { select { case beaconBlock := <-node.BeaconBlockChannel: if node.beaconSync == nil { utils.Logger().Info().Msg("initializing beacon sync") node.beaconSync = syncing.CreateStateSync(node.SelfPeer.IP, node.SelfPeer.Port, node.GetSyncID()) } if node.beaconSync.GetActivePeerNumber() == 0 { utils.Logger().Info().Msg("no peers; bootstrapping beacon sync config") peers, err := node.SyncingPeerProvider.SyncingPeers(0) if err != nil { utils.Logger().Warn(). Err(err). Msg("cannot retrieve beacon syncing peers") continue } if err := node.beaconSync.CreateSyncConfig(peers, true); err != nil { utils.Logger().Warn().Err(err).Msg("cannot create beacon sync config") continue } } node.beaconSync.AddLastMileBlock(beaconBlock) node.beaconSync.SyncLoop(node.Beaconchain(), node.BeaconWorker, false, true) } } } // DoSyncing keep the node in sync with other peers, willJoinConsensus means the node will try to join consensus after catch up func (node *Node) DoSyncing(bc *core.BlockChain, worker *worker.Worker, willJoinConsensus bool) { ticker := time.NewTicker(SyncFrequency * time.Second) SyncingLoop: for { select { case <-ticker.C: if node.stateSync == nil { node.stateSync = syncing.CreateStateSync(node.SelfPeer.IP, node.SelfPeer.Port, node.GetSyncID()) utils.Logger().Debug().Msg("[SYNC] initialized state sync") } if node.stateSync.GetActivePeerNumber() < MinConnectedPeers { shardID := bc.ShardID() peers, err := node.SyncingPeerProvider.SyncingPeers(shardID) if err != nil { utils.Logger().Warn(). Err(err). Uint32("shard_id", shardID). Msg("cannot retrieve syncing peers") continue SyncingLoop } if err := node.stateSync.CreateSyncConfig(peers, false); err != nil { utils.Logger().Warn(). Err(err). Interface("peers", peers). Msg("[SYNC] create peers error") continue SyncingLoop } utils.Logger().Debug().Int("len", node.stateSync.GetActivePeerNumber()).Msg("[SYNC] Get Active Peers") } if node.stateSync.IsOutOfSync(bc) { node.stateMutex.Lock() node.State = NodeNotInSync node.stateMutex.Unlock() if willJoinConsensus && node.Consensus.Mode() != consensus.Listening { node.Consensus.BlocksNotSynchronized() } node.stateSync.SyncLoop(bc, worker, willJoinConsensus, false) if willJoinConsensus && node.Consensus.Mode() != consensus.Listening { node.stateMutex.Lock() node.State = NodeReadyForConsensus node.stateMutex.Unlock() node.Consensus.BlocksSynchronized() } } node.stateMutex.Lock() node.State = NodeReadyForConsensus node.stateMutex.Unlock() if willJoinConsensus && node.Consensus.Mode() != consensus.Listening { node.Consensus.WaitForSyncing() } } } } // SupportBeaconSyncing sync with beacon chain for archival node in beacon chan or non-beacon node func (node *Node) SupportBeaconSyncing() { go node.DoBeaconSyncing() } // SupportSyncing keeps sleeping until it's doing consensus or it's a leader. func (node *Node) SupportSyncing() { node.InitSyncingServer() node.StartSyncingServer() // Check if the current node is explorer node. isExplorerNode := node.NodeConfig.Role() == nodeconfig.ExplorerNode // Send new block to unsync node if the current node is not explorer node. if !isExplorerNode { go node.SendNewBlockToUnsync() } go node.DoSyncing(node.Blockchain(), node.Worker, !isExplorerNode) } // InitSyncingServer starts downloader server. func (node *Node) InitSyncingServer() { if node.downloaderServer == nil { node.downloaderServer = downloader.NewServer(node) } } // StartSyncingServer starts syncing server. func (node *Node) StartSyncingServer() { utils.Logger().Info().Msg("[SYNC] support_syncing: StartSyncingServer") if node.downloaderServer.GrpcServer == nil { node.downloaderServer.Start(node.SelfPeer.IP, syncing.GetSyncingPort(node.SelfPeer.Port)) } } // SendNewBlockToUnsync send latest verified block to unsync, registered nodes func (node *Node) SendNewBlockToUnsync() { for { block := <-node.Consensus.VerifiedNewBlock blockHash, err := rlp.EncodeToBytes(block) if err != nil { utils.Logger().Warn().Msg("[SYNC] unable to encode block to hashes") continue } node.stateMutex.Lock() for peerID, config := range node.peerRegistrationRecord { elapseTime := time.Now().UnixNano() - config.timestamp if elapseTime > broadcastTimeout { utils.Logger().Warn().Str("peerID", peerID).Msg("[SYNC] SendNewBlockToUnsync to peer timeout") node.peerRegistrationRecord[peerID].client.Close() delete(node.peerRegistrationRecord, peerID) continue } response := config.client.PushNewBlock(node.GetSyncID(), blockHash, false) if response != nil && response.Type == downloader_pb.DownloaderResponse_INSYNC { node.peerRegistrationRecord[peerID].client.Close() delete(node.peerRegistrationRecord, peerID) } } node.stateMutex.Unlock() } } // CalculateResponse implements DownloadInterface on Node object. func (node *Node) CalculateResponse(request *downloader_pb.DownloaderRequest, incomingPeer string) (*downloader_pb.DownloaderResponse, error) { response := &downloader_pb.DownloaderResponse{} switch request.Type { case downloader_pb.DownloaderRequest_HEADER: if request.BlockHash == nil { return response, fmt.Errorf("[SYNC] GetBlockHashes Request BlockHash is NIL") } if request.Size == 0 || request.Size > syncing.BatchSize { return response, fmt.Errorf("[SYNC] GetBlockHashes Request contains invalid Size %v", request.Size) } size := uint64(request.Size) var startHashHeader common.Hash copy(startHashHeader[:], request.BlockHash[:]) startBlock := node.Blockchain().GetBlockByHash(startHashHeader) if startBlock == nil { return response, fmt.Errorf("[SYNC] GetBlockHashes Request cannot find startHash %s", startHashHeader.Hex()) } startHeight := startBlock.NumberU64() endHeight := node.Blockchain().CurrentBlock().NumberU64() if startHeight >= endHeight { utils.Logger(). Debug(). Uint64("myHeight", endHeight). Uint64("requestHeight", startHeight). Str("incomingIP", request.Ip). Str("incomingPort", request.Port). Str("incomingPeer", incomingPeer). Msg("[SYNC] GetBlockHashes Request: I am not higher than requested node") return response, nil } for blockNum := startHeight; blockNum <= startHeight+size; blockNum++ { block := node.Blockchain().GetBlockByNumber(blockNum) if block == nil { break } blockHash := block.Hash() response.Payload = append(response.Payload, blockHash[:]) } case downloader_pb.DownloaderRequest_BLOCK: for _, bytes := range request.Hashes { var hash common.Hash hash.SetBytes(bytes) block := node.Blockchain().GetBlockByHash(hash) if block == nil { continue } encodedBlock, err := rlp.EncodeToBytes(block) if err == nil { response.Payload = append(response.Payload, encodedBlock) } } case downloader_pb.DownloaderRequest_BLOCKHEIGHT: response.BlockHeight = node.Blockchain().CurrentBlock().NumberU64() // this is the out of sync node acts as grpc server side case downloader_pb.DownloaderRequest_NEWBLOCK: if node.State != NodeNotInSync { utils.Logger().Debug(). Str("state", node.State.String()). Msg("[SYNC] new block received, but state is") response.Type = downloader_pb.DownloaderResponse_INSYNC return response, nil } var blockObj types.Block err := rlp.DecodeBytes(request.BlockHash, &blockObj) if err != nil { utils.Logger().Warn().Msg("[SYNC] unable to decode received new block") return response, err } node.stateSync.AddNewBlock(request.PeerHash, &blockObj) case downloader_pb.DownloaderRequest_REGISTER: peerID := string(request.PeerHash[:]) ip := request.Ip port := request.Port node.stateMutex.Lock() defer node.stateMutex.Unlock() if _, ok := node.peerRegistrationRecord[peerID]; ok { response.Type = downloader_pb.DownloaderResponse_FAIL utils.Logger().Warn(). Interface("ip", ip). Interface("port", port). Msg("[SYNC] peerRegistration record already exists") return response, nil } else if len(node.peerRegistrationRecord) >= maxBroadcastNodes { response.Type = downloader_pb.DownloaderResponse_FAIL utils.GetLogInstance().Warn("[SYNC] maximum registration limit exceeds", "ip", ip, "port", port) return response, nil } else { response.Type = downloader_pb.DownloaderResponse_FAIL syncPort := syncing.GetSyncingPort(port) client := downloader.ClientSetup(ip, syncPort) if client == nil { utils.Logger().Warn(). Str("ip", ip). Str("port", port). Msg("[SYNC] unable to setup client for peerID") return response, nil } config := &syncConfig{timestamp: time.Now().UnixNano(), client: client} node.peerRegistrationRecord[peerID] = config utils.Logger().Debug(). Str("ip", ip). Str("port", port). Msg("[SYNC] register peerID success") response.Type = downloader_pb.DownloaderResponse_SUCCESS } case downloader_pb.DownloaderRequest_REGISTERTIMEOUT: if node.State == NodeNotInSync { count := node.stateSync.RegisterNodeInfo() utils.Logger().Debug(). Int("number", count). Msg("[SYNC] extra node registered") } } return response, nil }