package node import ( "bytes" "crypto/ecdsa" "encoding/binary" "encoding/gob" "encoding/hex" "fmt" "math/big" "os" "strconv" "strings" "sync" "time" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/ethdb" "github.com/ethereum/go-ethereum/log" "github.com/ethereum/go-ethereum/params" "github.com/ethereum/go-ethereum/rlp" "github.com/harmony-one/harmony/api/client" clientService "github.com/harmony-one/harmony/api/client/service" proto_node "github.com/harmony-one/harmony/api/proto/node" "github.com/harmony-one/harmony/api/services/explorer" "github.com/harmony-one/harmony/api/services/syncing" "github.com/harmony-one/harmony/api/services/syncing/downloader" downloader_pb "github.com/harmony-one/harmony/api/services/syncing/downloader/proto" bft "github.com/harmony-one/harmony/consensus" "github.com/harmony-one/harmony/core" "github.com/harmony-one/harmony/core/types" "github.com/harmony-one/harmony/core/vm" "github.com/harmony-one/harmony/crypto/pki" "github.com/harmony-one/harmony/internal/utils" "github.com/harmony-one/harmony/node/worker" "github.com/harmony-one/harmony/p2p" ) // State is a state of a node. type State byte // All constants except the NodeLeader below are for validators only. const ( NodeInit State = iota // Node just started, before contacting BeaconChain NodeWaitToJoin // Node contacted BeaconChain, wait to join Shard NodeNotInSync // Node out of sync, might be just joined Shard or offline for a period of time NodeOffline // Node is offline NodeReadyForConsensus // Node is ready for doing consensus NodeDoingConsensus // Node is already doing consensus NodeLeader // Node is the leader of some shard. ) func (state State) String() string { switch state { case NodeInit: return "NodeInit" case NodeWaitToJoin: return "NodeWaitToJoin" case NodeNotInSync: return "NodeNotInSync" case NodeOffline: return "NodeOffline" case NodeReadyForConsensus: return "NodeReadyForConsensus" case NodeDoingConsensus: return "NodeDoingConsensus" case NodeLeader: return "NodeLeader" } return "Unknown" } // Constants related to doing syncing. const ( lastMileThreshold = 4 inSyncThreshold = 2 ) const ( waitBeforeJoinShard = time.Second * 3 timeOutToJoinShard = time.Minute * 10 // ClientServicePortDiff is the positive port diff for client service ClientServicePortDiff = 5555 maxBroadcastNodes = 10 // broadcast at most maxBroadcastNodes peers that need in sync broadcastTimeout int64 = 3 * 60 * 1000000000 // 3 mins ) // use to push new block to outofsync node type syncConfig struct { timestamp int64 client *downloader.Client } // NetworkNode ... type NetworkNode struct { SelfPeer p2p.Peer IDCPeer p2p.Peer } // Node represents a protocol-participating node in the network type Node struct { Consensus *bft.Consensus // Consensus object containing all Consensus related data (e.g. committee members, signatures, commits) BlockChannel chan *types.Block // The channel to receive new blocks from Node pendingTransactions types.Transactions // All the transactions received but not yet processed for Consensus transactionInConsensus []*types.Transaction // The transactions selected into the new block and under Consensus process pendingTxMutex sync.Mutex blockchain *core.BlockChain // The blockchain for the shard where this node belongs db *ethdb.LDBDatabase // LevelDB to store blockchain. ClientPeer *p2p.Peer // The peer for the harmony tx generator client, used for leaders to return proof-of-accept Client *client.Client // The presence of a client object means this node will also act as a client SelfPeer p2p.Peer // TODO(minhdoan): it could be duplicated with Self below whose is Alok work. IDCPeer p2p.Peer Neighbors sync.Map // All the neighbor nodes, key is the sha256 of Peer IP/Port, value is the p2p.Peer State State // State of the Node stateMutex sync.Mutex // mutex for change node state TxPool *core.TxPool Worker *worker.Worker // Client server (for wallet requests) clientServer *clientService.Server // Syncing component. downloaderServer *downloader.Server stateSync *syncing.StateSync peerRegistrationRecord map[uint32]*syncConfig // record registration time (unixtime) of peers begin in syncing // The p2p host used to send/receive p2p messages host p2p.Host // Channel to stop sending ping message StopPing chan struct{} // Signal channel for lost validators OfflinePeers chan p2p.Peer // Action Channel actionChannel chan *Action serviceStore *ServiceStore // For test only TestBankKeys []*ecdsa.PrivateKey ContractKeys []*ecdsa.PrivateKey ContractAddresses []common.Address } // Blockchain returns the blockchain from node func (node *Node) Blockchain() *core.BlockChain { return node.blockchain } // Add new transactions to the pending transaction list func (node *Node) addPendingTransactions(newTxs types.Transactions) { node.pendingTxMutex.Lock() node.pendingTransactions = append(node.pendingTransactions, newTxs...) node.pendingTxMutex.Unlock() utils.GetLogInstance().Debug("Got more transactions", "num", len(newTxs), "totalPending", len(node.pendingTransactions)) } // Take out a subset of valid transactions from the pending transaction list // Note the pending transaction list will then contain the rest of the txs func (node *Node) getTransactionsForNewBlock(maxNumTxs int) types.Transactions { node.pendingTxMutex.Lock() selected, unselected, invalid := node.Worker.SelectTransactionsForNewBlock(node.pendingTransactions, maxNumTxs) _ = invalid // invalid txs are discard utils.GetLogInstance().Debug("Invalid transactions discarded", "number", len(invalid)) node.pendingTransactions = unselected utils.GetLogInstance().Debug("Remaining pending transactions", "number", len(node.pendingTransactions)) node.pendingTxMutex.Unlock() return selected } // StartServer starts a server and process the requests by a handler. func (node *Node) StartServer() { node.host.BindHandlerAndServe(node.StreamHandler) } // Count the total number of transactions in the blockchain // Currently used for stats reporting purpose func (node *Node) countNumTransactionsInBlockchain() int { count := 0 for block := node.blockchain.CurrentBlock(); block != nil; block = node.blockchain.GetBlockByHash(block.Header().ParentHash) { count += len(block.Transactions()) } return count } // SerializeNode serializes the node // https://stackoverflow.com/questions/12854125/how-do-i-dump-the-struct-into-the-byte-array-without-reflection/12854659#12854659 func (node *Node) SerializeNode(nnode *NetworkNode) []byte { //Needs to escape the serialization of unexported fields var result bytes.Buffer encoder := gob.NewEncoder(&result) err := encoder.Encode(nnode) if err != nil { fmt.Println("Could not serialize node") fmt.Println("ERROR", err) //utils.GetLogInstance().Error("Could not serialize node") } return result.Bytes() } // DeserializeNode deserializes the node func DeserializeNode(d []byte) *NetworkNode { var wn NetworkNode r := bytes.NewBuffer(d) decoder := gob.NewDecoder(r) err := decoder.Decode(&wn) if err != nil { log.Error("Could not de-serialize node 1") } return &wn } // New creates a new node. func New(host p2p.Host, consensus *bft.Consensus, db ethdb.Database) *Node { node := Node{} if host != nil { node.host = host node.SelfPeer = host.GetSelfPeer() } if host != nil && consensus != nil { // Consensus and associated channel to communicate blocks node.Consensus = consensus // Initialize genesis block and blockchain genesisAlloc := node.CreateGenesisAllocWithTestingAddresses(100) contractKey, _ := ecdsa.GenerateKey(crypto.S256(), strings.NewReader("Test contract key string stream that is fixed so that generated test key are deterministic every time")) contractAddress := crypto.PubkeyToAddress(contractKey.PublicKey) contractFunds := big.NewInt(9000000) contractFunds = contractFunds.Mul(contractFunds, big.NewInt(params.Ether)) genesisAlloc[contractAddress] = core.GenesisAccount{Balance: contractFunds} node.ContractKeys = append(node.ContractKeys, contractKey) database := db if database == nil { database = ethdb.NewMemDatabase() } chainConfig := params.TestChainConfig chainConfig.ChainID = big.NewInt(int64(node.Consensus.ShardID)) // Use ChainID as piggybacked ShardID gspec := core.Genesis{ Config: chainConfig, Alloc: genesisAlloc, ShardID: uint32(node.Consensus.ShardID), } _ = gspec.MustCommit(database) chain, _ := core.NewBlockChain(database, nil, gspec.Config, node.Consensus, vm.Config{}, nil) node.blockchain = chain node.BlockChannel = make(chan *types.Block) node.TxPool = core.NewTxPool(core.DefaultTxPoolConfig, params.TestChainConfig, chain) node.Worker = worker.New(params.TestChainConfig, chain, node.Consensus, pki.GetAddressFromPublicKey(node.SelfPeer.PubKey), node.Consensus.ShardID) node.AddSmartContractsToPendingTransactions() node.Consensus.ConsensusBlock = make(chan *types.Block) node.Consensus.VerifiedNewBlock = make(chan *types.Block) } if consensus != nil && consensus.IsLeader { node.State = NodeLeader } else { node.State = NodeInit } // Setup initial state of syncing. node.StopPing = make(chan struct{}) node.peerRegistrationRecord = make(map[uint32]*syncConfig) node.OfflinePeers = make(chan p2p.Peer) go node.RemovePeersHandler() return &node } // IsOutOfSync checks whether the node is out of sync by comparing latest block with consensus block func (node *Node) IsOutOfSync(consensusBlock *types.Block) bool { myHeight := node.blockchain.CurrentBlock().NumberU64() newHeight := consensusBlock.NumberU64() utils.GetLogInstance().Debug("[SYNC]", "myHeight", myHeight, "newHeight", newHeight) if newHeight-myHeight <= inSyncThreshold { return false } // cache latest blocks for last mile catch up if newHeight-myHeight <= lastMileThreshold && node.stateSync != nil { node.stateSync.AddLastMileBlock(consensusBlock) } return true } // DoSyncing wait for check status and starts syncing if out of sync func (node *Node) DoSyncing() { for { select { // in current implementation logic, timeout means in sync case <-time.After(5 * time.Second): node.stateMutex.Lock() node.State = NodeReadyForConsensus node.stateMutex.Unlock() continue case consensusBlock := <-node.Consensus.ConsensusBlock: if !node.IsOutOfSync(consensusBlock) { if node.State == NodeNotInSync { utils.GetLogInstance().Info("[SYNC] Node is now IN SYNC!") node.stateSync.CloseConnections() node.stateSync = nil } node.stateMutex.Lock() node.State = NodeReadyForConsensus node.stateMutex.Unlock() continue } else { utils.GetLogInstance().Debug("[SYNC] node is out of sync") node.stateMutex.Lock() node.State = NodeNotInSync node.stateMutex.Unlock() } if node.stateSync == nil { node.stateSync = syncing.CreateStateSync(node.SelfPeer.IP, node.SelfPeer.Port) node.stateSync.CreateSyncConfig(node.GetSyncingPeers()) node.stateSync.MakeConnectionToPeers() } startHash := node.blockchain.CurrentBlock().Hash() node.stateSync.StartStateSync(startHash[:], node.blockchain, node.Worker) } } } // AddPeers adds neighbors nodes func (node *Node) AddPeers(peers []*p2p.Peer) int { count := 0 for _, p := range peers { key := fmt.Sprintf("%v", p.PubKey) _, ok := node.Neighbors.Load(key) if !ok { node.Neighbors.Store(key, *p) count++ node.host.AddPeer(p) continue } if node.SelfPeer.ValidatorID == -1 && p.IP == node.SelfPeer.IP && p.Port == node.SelfPeer.Port { node.SelfPeer.ValidatorID = p.ValidatorID } } if count > 0 { node.Consensus.AddPeers(peers) } return count } // GetSyncingPort returns the syncing port. func GetSyncingPort(nodePort string) string { if port, err := strconv.Atoi(nodePort); err == nil { return fmt.Sprintf("%d", port-syncing.SyncingPortDifference) } os.Exit(1) return "" } // GetSyncingPeers returns list of peers. func (node *Node) GetSyncingPeers() []p2p.Peer { res := []p2p.Peer{} node.Neighbors.Range(func(k, v interface{}) bool { res = append(res, v.(p2p.Peer)) return true }) removeID := -1 for i := range res { if res[i].Port == node.SelfPeer.Port { removeID = i } res[i].Port = GetSyncingPort(res[i].Port) } if removeID != -1 { res = append(res[:removeID], res[removeID+1:]...) } utils.GetLogInstance().Debug("GetSyncingPeers: ", "res", res, "self", node.SelfPeer) return res } //AddSmartContractsToPendingTransactions adds the faucet contract the genesis block. func (node *Node) AddSmartContractsToPendingTransactions() { // Add a contract deployment transactionv priKey := node.ContractKeys[0] contractData := "0x6080604052678ac7230489e8000060015560028054600160a060020a031916331790556101aa806100316000396000f3fe608060405260043610610045577c0100000000000000000000000000000000000000000000000000000000600035046327c78c42811461004a5780634ddd108a1461008c575b600080fd5b34801561005657600080fd5b5061008a6004803603602081101561006d57600080fd5b503573ffffffffffffffffffffffffffffffffffffffff166100b3565b005b34801561009857600080fd5b506100a1610179565b60408051918252519081900360200190f35b60025473ffffffffffffffffffffffffffffffffffffffff1633146100d757600080fd5b600154303110156100e757600080fd5b73ffffffffffffffffffffffffffffffffffffffff811660009081526020819052604090205460ff161561011a57600080fd5b73ffffffffffffffffffffffffffffffffffffffff8116600081815260208190526040808220805460ff1916600190811790915554905181156108fc0292818181858888f19350505050158015610175573d6000803e3d6000fd5b5050565b30319056fea165627a7a723058203e799228fee2fa7c5d15e71c04267a0cc2687c5eff3b48b98f21f355e1064ab30029" dataEnc := common.FromHex(contractData) // Unsigned transaction to avoid the case of transaction address. contractFunds := big.NewInt(8000000) contractFunds = contractFunds.Mul(contractFunds, big.NewInt(params.Ether)) mycontracttx, _ := types.SignTx(types.NewContractCreation(uint64(0), node.Consensus.ShardID, contractFunds, params.TxGasContractCreation*10, nil, dataEnc), types.HomesteadSigner{}, priKey) node.ContractAddresses = append(node.ContractAddresses, crypto.CreateAddress(crypto.PubkeyToAddress(priKey.PublicKey), uint64(0))) node.addPendingTransactions(types.Transactions{mycontracttx}) } //CallFaucetContract invokes the faucet contract to give the walletAddress initial money func (node *Node) CallFaucetContract(walletAddress common.Address) common.Hash { state, err := node.blockchain.State() if err != nil { log.Error("Failed to get chain state", "Error", err) } nonce := state.GetNonce(crypto.PubkeyToAddress(node.ContractKeys[0].PublicKey)) callingFunction := "0x27c78c42000000000000000000000000" contractData := callingFunction + hex.EncodeToString(walletAddress.Bytes()) dataEnc := common.FromHex(contractData) tx, _ := types.SignTx(types.NewTransaction(nonce, node.ContractAddresses[0], node.Consensus.ShardID, big.NewInt(0), params.TxGasContractCreation*10, nil, dataEnc), types.HomesteadSigner{}, node.ContractKeys[0]) node.addPendingTransactions(types.Transactions{tx}) return tx.Hash() } // JoinShard helps a new node to join a shard. func (node *Node) JoinShard(leader p2p.Peer) { // try to join the shard, send ping message every 1 second, with a 10 minutes time-out tick := time.NewTicker(1 * time.Second) timeout := time.NewTicker(10 * time.Minute) defer tick.Stop() defer timeout.Stop() for { select { case <-tick.C: ping := proto_node.NewPingMessage(node.SelfPeer) if node.Client != nil { // assume this is the client node ping.Node.Role = proto_node.ClientRole } buffer := ping.ConstructPingMessage() // Talk to leader. node.SendMessage(leader, buffer) case <-timeout.C: utils.GetLogInstance().Info("JoinShard timeout") return case <-node.StopPing: utils.GetLogInstance().Info("Stopping JoinShard") return } } } // SupportClient initializes and starts the client service func (node *Node) SupportClient() { node.InitClientServer() node.StartClientServer() } // SupportExplorer initializes and starts the client service func (node *Node) SupportExplorer() { es := explorer.Service{ IP: node.SelfPeer.IP, Port: node.SelfPeer.Port, } es.Init(true) es.Run() } // InitClientServer initializes client server. func (node *Node) InitClientServer() { node.clientServer = clientService.NewServer(node.blockchain.State, node.CallFaucetContract) } // StartClientServer starts client server. func (node *Node) StartClientServer() { port, _ := strconv.Atoi(node.SelfPeer.Port) utils.GetLogInstance().Info("support_client: StartClientServer on port:", "port", port+ClientServicePortDiff) node.clientServer.Start(node.SelfPeer.IP, strconv.Itoa(port+ClientServicePortDiff)) } // SupportSyncing keeps sleeping until it's doing consensus or it's a leader. func (node *Node) SupportSyncing() { node.InitSyncingServer() node.StartSyncingServer() go node.DoSyncing() go node.SendNewBlockToUnsync() } // InitSyncingServer starts downloader server. func (node *Node) InitSyncingServer() { node.downloaderServer = downloader.NewServer(node) } // StartSyncingServer starts syncing server. func (node *Node) StartSyncingServer() { port := GetSyncingPort(node.SelfPeer.Port) utils.GetLogInstance().Info("support_sycning: StartSyncingServer on port:", "port", port) node.downloaderServer.Start(node.SelfPeer.IP, GetSyncingPort(node.SelfPeer.Port)) } // CalculateResponse implements DownloadInterface on Node object. func (node *Node) CalculateResponse(request *downloader_pb.DownloaderRequest) (*downloader_pb.DownloaderResponse, error) { response := &downloader_pb.DownloaderResponse{} switch request.Type { case downloader_pb.DownloaderRequest_HEADER: utils.GetLogInstance().Debug("[SYNC] CalculateResponse DownloaderRequest_HEADER", "request.BlockHash", request.BlockHash) var startHeaderHash []byte if request.BlockHash == nil { tmp := node.blockchain.Genesis().Hash() startHeaderHash = tmp[:] } else { startHeaderHash = request.BlockHash } for block := node.blockchain.CurrentBlock(); block != nil; block = node.blockchain.GetBlockByHash(block.Header().ParentHash) { blockHash := block.Hash() if bytes.Compare(blockHash[:], startHeaderHash) == 0 { break } 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) encodedBlock, err := rlp.EncodeToBytes(block) if err == nil { response.Payload = append(response.Payload, encodedBlock) } } case downloader_pb.DownloaderRequest_NEWBLOCK: if node.State != NodeNotInSync { utils.GetLogInstance().Debug("[SYNC] new block received, but state is", "state", node.State.String()) response.Type = downloader_pb.DownloaderResponse_INSYNC return response, nil } var blockObj types.Block err := rlp.DecodeBytes(request.BlockHash, &blockObj) if err != nil { utils.GetLogInstance().Warn("[SYNC] unable to decode received new block") return response, err } node.stateSync.AddNewBlock(request.PeerHash, &blockObj) case downloader_pb.DownloaderRequest_REGISTER: peerID := binary.BigEndian.Uint32(request.PeerHash) if _, ok := node.peerRegistrationRecord[peerID]; ok { response.Type = downloader_pb.DownloaderResponse_FAIL return response, nil } else if len(node.peerRegistrationRecord) >= maxBroadcastNodes { response.Type = downloader_pb.DownloaderResponse_FAIL return response, nil } else { peer, ok := node.Consensus.GetPeerFromID(peerID) if !ok { utils.GetLogInstance().Warn("[SYNC] unable to get peer from peerID", "peerID", peerID) } client := downloader.ClientSetup(peer.IP, GetSyncingPort(peer.Port)) if client == nil { utils.GetLogInstance().Warn("[SYNC] unable to setup client") return response, nil } utils.GetLogInstance().Debug("[SYNC] client setup correctly", "client", client) config := &syncConfig{timestamp: time.Now().UnixNano(), client: client} node.stateMutex.Lock() node.peerRegistrationRecord[peerID] = config node.stateMutex.Unlock() utils.GetLogInstance().Debug("[SYNC] register peerID success", "peerID", peerID) response.Type = downloader_pb.DownloaderResponse_SUCCESS } case downloader_pb.DownloaderRequest_REGISTERTIMEOUT: if node.State == NodeNotInSync { count := node.stateSync.RegisterNodeInfo() utils.GetLogInstance().Debug("[SYNC] extra node registered", "number", count) } } return response, nil } // 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.GetLogInstance().Warn("[SYNC] unable to encode block to hashes") continue } // really need to have a unique id independent of ip/port selfPeerID := utils.GetUniqueIDFromIPPort(node.SelfPeer.IP, node.SelfPeer.Port) utils.GetLogInstance().Debug("[SYNC] peerRegistration Record", "peerID", selfPeerID, "number", len(node.peerRegistrationRecord)) for peerID, config := range node.peerRegistrationRecord { elapseTime := time.Now().UnixNano() - config.timestamp if elapseTime > broadcastTimeout { utils.GetLogInstance().Warn("[SYNC] SendNewBlockToUnsync to peer timeout", "peerID", peerID) // send last time and delete config.client.PushNewBlock(selfPeerID, blockHash, true) node.stateMutex.Lock() node.peerRegistrationRecord[peerID].client.Close() delete(node.peerRegistrationRecord, peerID) node.stateMutex.Unlock() continue } response := config.client.PushNewBlock(selfPeerID, blockHash, false) if response.Type == downloader_pb.DownloaderResponse_INSYNC { node.stateMutex.Lock() node.peerRegistrationRecord[peerID].client.Close() delete(node.peerRegistrationRecord, peerID) node.stateMutex.Unlock() } } } } // RemovePeersHandler is a goroutine to wait on the OfflinePeers channel // and remove the peers from validator list func (node *Node) RemovePeersHandler() { for { select { case p := <-node.OfflinePeers: node.Consensus.OfflinePeerList = append(node.Consensus.OfflinePeerList, p) } } }