package node import ( "bytes" "context" "errors" "fmt" "net" "net/http" _ "net/http/pprof" "strings" "time" "github.com/prometheus/client_golang/prometheus" "github.com/prometheus/client_golang/prometheus/promhttp" amino "github.com/tendermint/go-amino" abci "github.com/tendermint/tendermint/abci/types" bc "github.com/tendermint/tendermint/blockchain" cfg "github.com/tendermint/tendermint/config" cs "github.com/tendermint/tendermint/consensus" "github.com/tendermint/tendermint/crypto/ed25519" "github.com/tendermint/tendermint/evidence" cmn "github.com/tendermint/tendermint/libs/common" dbm "github.com/tendermint/tendermint/libs/db" "github.com/tendermint/tendermint/libs/log" mempl "github.com/tendermint/tendermint/mempool" "github.com/tendermint/tendermint/p2p" "github.com/tendermint/tendermint/p2p/pex" "github.com/tendermint/tendermint/privval" "github.com/tendermint/tendermint/proxy" rpccore "github.com/tendermint/tendermint/rpc/core" ctypes "github.com/tendermint/tendermint/rpc/core/types" grpccore "github.com/tendermint/tendermint/rpc/grpc" rpc "github.com/tendermint/tendermint/rpc/lib" rpcserver "github.com/tendermint/tendermint/rpc/lib/server" sm "github.com/tendermint/tendermint/state" "github.com/tendermint/tendermint/state/txindex" "github.com/tendermint/tendermint/state/txindex/kv" "github.com/tendermint/tendermint/state/txindex/null" "github.com/tendermint/tendermint/types" tmtime "github.com/tendermint/tendermint/types/time" "github.com/tendermint/tendermint/version" ) //------------------------------------------------------------------------------ // DBContext specifies config information for loading a new DB. type DBContext struct { ID string Config *cfg.Config } // DBProvider takes a DBContext and returns an instantiated DB. type DBProvider func(*DBContext) (dbm.DB, error) // DefaultDBProvider returns a database using the DBBackend and DBDir // specified in the ctx.Config. func DefaultDBProvider(ctx *DBContext) (dbm.DB, error) { dbType := dbm.DBBackendType(ctx.Config.DBBackend) return dbm.NewDB(ctx.ID, dbType, ctx.Config.DBDir()), nil } // GenesisDocProvider returns a GenesisDoc. // It allows the GenesisDoc to be pulled from sources other than the // filesystem, for instance from a distributed key-value store cluster. type GenesisDocProvider func() (*types.GenesisDoc, error) // DefaultGenesisDocProviderFunc returns a GenesisDocProvider that loads // the GenesisDoc from the config.GenesisFile() on the filesystem. func DefaultGenesisDocProviderFunc(config *cfg.Config) GenesisDocProvider { return func() (*types.GenesisDoc, error) { return types.GenesisDocFromFile(config.GenesisFile()) } } // NodeProvider takes a config and a logger and returns a ready to go Node. type NodeProvider func(*cfg.Config, log.Logger) (*Node, error) // DefaultNewNode returns a Tendermint node with default settings for the // PrivValidator, ClientCreator, GenesisDoc, and DBProvider. // It implements NodeProvider. func DefaultNewNode(config *cfg.Config, logger log.Logger) (*Node, error) { // Generate node PrivKey nodeKey, err := p2p.LoadOrGenNodeKey(config.NodeKeyFile()) if err != nil { return nil, err } return NewNode(config, privval.LoadOrGenFilePV(config.PrivValidatorFile()), nodeKey, proxy.DefaultClientCreator(config.ProxyApp, config.ABCI, config.DBDir()), DefaultGenesisDocProviderFunc(config), DefaultDBProvider, DefaultMetricsProvider(config.Instrumentation), logger, ) } // MetricsProvider returns a consensus, p2p and mempool Metrics. type MetricsProvider func() (*cs.Metrics, *p2p.Metrics, *mempl.Metrics) // DefaultMetricsProvider returns Metrics build using Prometheus client library // if Prometheus is enabled. Otherwise, it returns no-op Metrics. func DefaultMetricsProvider(config *cfg.InstrumentationConfig) MetricsProvider { return func() (*cs.Metrics, *p2p.Metrics, *mempl.Metrics) { if config.Prometheus { return cs.PrometheusMetrics(), p2p.PrometheusMetrics(), mempl.PrometheusMetrics() } return cs.NopMetrics(), p2p.NopMetrics(), mempl.NopMetrics() } } //------------------------------------------------------------------------------ // Node is the highest level interface to a full Tendermint node. // It includes all configuration information and running services. type Node struct { cmn.BaseService // config config *cfg.Config genesisDoc *types.GenesisDoc // initial validator set privValidator types.PrivValidator // local node's validator key // network transport *p2p.MultiplexTransport sw *p2p.Switch // p2p connections addrBook pex.AddrBook // known peers nodeInfo p2p.NodeInfo nodeKey *p2p.NodeKey // our node privkey isListening bool // services eventBus *types.EventBus // pub/sub for services stateDB dbm.DB blockStore *bc.BlockStore // store the blockchain to disk bcReactor *bc.BlockchainReactor // for fast-syncing mempoolReactor *mempl.MempoolReactor // for gossipping transactions consensusState *cs.ConsensusState // latest consensus state consensusReactor *cs.ConsensusReactor // for participating in the consensus evidencePool *evidence.EvidencePool // tracking evidence proxyApp proxy.AppConns // connection to the application rpcListeners []net.Listener // rpc servers txIndexer txindex.TxIndexer indexerService *txindex.IndexerService prometheusSrv *http.Server } // NewNode returns a new, ready to go, Tendermint Node. func NewNode(config *cfg.Config, privValidator types.PrivValidator, nodeKey *p2p.NodeKey, clientCreator proxy.ClientCreator, genesisDocProvider GenesisDocProvider, dbProvider DBProvider, metricsProvider MetricsProvider, logger log.Logger) (*Node, error) { // Get BlockStore blockStoreDB, err := dbProvider(&DBContext{"blockstore", config}) if err != nil { return nil, err } blockStore := bc.NewBlockStore(blockStoreDB) // Get State stateDB, err := dbProvider(&DBContext{"state", config}) if err != nil { return nil, err } // Get genesis doc // TODO: move to state package? genDoc, err := loadGenesisDoc(stateDB) if err != nil { genDoc, err = genesisDocProvider() if err != nil { return nil, err } // save genesis doc to prevent a certain class of user errors (e.g. when it // was changed, accidentally or not). Also good for audit trail. saveGenesisDoc(stateDB, genDoc) } state, err := sm.LoadStateFromDBOrGenesisDoc(stateDB, genDoc) if err != nil { return nil, err } // Create the proxyApp and establish connections to the ABCI app (consensus, mempool, query). proxyApp := proxy.NewAppConns(clientCreator) proxyApp.SetLogger(logger.With("module", "proxy")) if err := proxyApp.Start(); err != nil { return nil, fmt.Errorf("Error starting proxy app connections: %v", err) } // Create the handshaker, which calls RequestInfo and replays any blocks // as necessary to sync tendermint with the app. consensusLogger := logger.With("module", "consensus") handshaker := cs.NewHandshaker(stateDB, state, blockStore, genDoc) handshaker.SetLogger(consensusLogger) if err := handshaker.Handshake(proxyApp); err != nil { return nil, fmt.Errorf("Error during handshake: %v", err) } // reload the state (it may have been updated by the handshake) state = sm.LoadState(stateDB) // If an address is provided, listen on the socket for a // connection from an external signing process. if config.PrivValidatorListenAddr != "" { var ( // TODO: persist this key so external signer // can actually authenticate us privKey = ed25519.GenPrivKey() pvsc = privval.NewSocketPV( logger.With("module", "privval"), config.PrivValidatorListenAddr, privKey, ) ) if err := pvsc.Start(); err != nil { return nil, fmt.Errorf("Error starting private validator client: %v", err) } privValidator = pvsc } // Decide whether to fast-sync or not // We don't fast-sync when the only validator is us. fastSync := config.FastSync if state.Validators.Size() == 1 { addr, _ := state.Validators.GetByIndex(0) if bytes.Equal(privValidator.GetAddress(), addr) { fastSync = false } } // Log whether this node is a validator or an observer if state.Validators.HasAddress(privValidator.GetAddress()) { consensusLogger.Info("This node is a validator", "addr", privValidator.GetAddress(), "pubKey", privValidator.GetPubKey()) } else { consensusLogger.Info("This node is not a validator", "addr", privValidator.GetAddress(), "pubKey", privValidator.GetPubKey()) } csMetrics, p2pMetrics, memplMetrics := metricsProvider() // Make MempoolReactor mempool := mempl.NewMempool( config.Mempool, proxyApp.Mempool(), state.LastBlockHeight, mempl.WithMetrics(memplMetrics), mempl.WithPreCheck( mempl.PreCheckAminoMaxBytes( types.MaxDataBytesUnknownEvidence( state.ConsensusParams.BlockSize.MaxBytes, state.Validators.Size(), ), ), ), mempl.WithPostCheck( mempl.PostCheckMaxGas(state.ConsensusParams.BlockSize.MaxGas), ), ) mempoolLogger := logger.With("module", "mempool") mempool.SetLogger(mempoolLogger) mempool.InitWAL() // no need to have the mempool wal during tests mempoolReactor := mempl.NewMempoolReactor(config.Mempool, mempool) mempoolReactor.SetLogger(mempoolLogger) if config.Consensus.WaitForTxs() { mempool.EnableTxsAvailable() } // Make Evidence Reactor evidenceDB, err := dbProvider(&DBContext{"evidence", config}) if err != nil { return nil, err } evidenceLogger := logger.With("module", "evidence") evidenceStore := evidence.NewEvidenceStore(evidenceDB) evidencePool := evidence.NewEvidencePool(stateDB, evidenceStore) evidencePool.SetLogger(evidenceLogger) evidenceReactor := evidence.NewEvidenceReactor(evidencePool) evidenceReactor.SetLogger(evidenceLogger) blockExecLogger := logger.With("module", "state") // make block executor for consensus and blockchain reactors to execute blocks blockExec := sm.NewBlockExecutor(stateDB, blockExecLogger, proxyApp.Consensus(), mempool, evidencePool) // Make BlockchainReactor bcReactor := bc.NewBlockchainReactor(state.Copy(), blockExec, blockStore, fastSync) bcReactor.SetLogger(logger.With("module", "blockchain")) // Make ConsensusReactor consensusState := cs.NewConsensusState( config.Consensus, state.Copy(), blockExec, blockStore, mempool, evidencePool, cs.WithMetrics(csMetrics), ) consensusState.SetLogger(consensusLogger) if privValidator != nil { consensusState.SetPrivValidator(privValidator) } consensusReactor := cs.NewConsensusReactor(consensusState, fastSync) consensusReactor.SetLogger(consensusLogger) eventBus := types.NewEventBus() eventBus.SetLogger(logger.With("module", "events")) // services which will be publishing and/or subscribing for messages (events) // consensusReactor will set it on consensusState and blockExecutor consensusReactor.SetEventBus(eventBus) // Transaction indexing var txIndexer txindex.TxIndexer switch config.TxIndex.Indexer { case "kv": store, err := dbProvider(&DBContext{"tx_index", config}) if err != nil { return nil, err } if config.TxIndex.IndexTags != "" { txIndexer = kv.NewTxIndex(store, kv.IndexTags(splitAndTrimEmpty(config.TxIndex.IndexTags, ",", " "))) } else if config.TxIndex.IndexAllTags { txIndexer = kv.NewTxIndex(store, kv.IndexAllTags()) } else { txIndexer = kv.NewTxIndex(store) } default: txIndexer = &null.TxIndex{} } indexerService := txindex.NewIndexerService(txIndexer, eventBus) indexerService.SetLogger(logger.With("module", "txindex")) var ( p2pLogger = logger.With("module", "p2p") nodeInfo = makeNodeInfo(config, nodeKey.ID(), txIndexer, genDoc.ChainID) ) // Setup Transport. var ( transport = p2p.NewMultiplexTransport(nodeInfo, *nodeKey) connFilters = []p2p.ConnFilterFunc{} peerFilters = []p2p.PeerFilterFunc{} ) if !config.P2P.AllowDuplicateIP { connFilters = append(connFilters, p2p.ConnDuplicateIPFilter()) } // Filter peers by addr or pubkey with an ABCI query. // If the query return code is OK, add peer. // XXX: Query format subject to change if config.FilterPeers { connFilters = append( connFilters, // ABCI query for address filtering. func(_ p2p.ConnSet, c net.Conn, _ []net.IP) error { res, err := proxyApp.Query().QuerySync(abci.RequestQuery{ Path: fmt.Sprintf("/p2p/filter/addr/%s", c.RemoteAddr().String()), }) if err != nil { return err } if res.IsErr() { return fmt.Errorf("Error querying abci app: %v", res) } return nil }, ) peerFilters = append( peerFilters, // ABCI query for ID filtering. func(_ p2p.IPeerSet, p p2p.Peer) error { res, err := proxyApp.Query().QuerySync(abci.RequestQuery{ Path: fmt.Sprintf("/p2p/filter/id/%s", p.ID()), }) if err != nil { return err } if res.IsErr() { return fmt.Errorf("Error querying abci app: %v", res) } return nil }, ) } p2p.MultiplexTransportConnFilters(connFilters...)(transport) // Setup Switch. sw := p2p.NewSwitch( config.P2P, transport, p2p.WithMetrics(p2pMetrics), p2p.SwitchPeerFilters(peerFilters...), ) sw.SetLogger(p2pLogger) sw.AddReactor("MEMPOOL", mempoolReactor) sw.AddReactor("BLOCKCHAIN", bcReactor) sw.AddReactor("CONSENSUS", consensusReactor) sw.AddReactor("EVIDENCE", evidenceReactor) sw.SetNodeInfo(nodeInfo) sw.SetNodeKey(nodeKey) p2pLogger.Info("P2P Node ID", "ID", nodeKey.ID(), "file", config.NodeKeyFile()) // Optionally, start the pex reactor // // TODO: // // We need to set Seeds and PersistentPeers on the switch, // since it needs to be able to use these (and their DNS names) // even if the PEX is off. We can include the DNS name in the NetAddress, // but it would still be nice to have a clear list of the current "PersistentPeers" // somewhere that we can return with net_info. // // If PEX is on, it should handle dialing the seeds. Otherwise the switch does it. // Note we currently use the addrBook regardless at least for AddOurAddress addrBook := pex.NewAddrBook(config.P2P.AddrBookFile(), config.P2P.AddrBookStrict) // Add ourselves to addrbook to prevent dialing ourselves addrBook.AddOurAddress(nodeInfo.NetAddress()) addrBook.SetLogger(p2pLogger.With("book", config.P2P.AddrBookFile())) if config.P2P.PexReactor { // TODO persistent peers ? so we can have their DNS addrs saved pexReactor := pex.NewPEXReactor(addrBook, &pex.PEXReactorConfig{ Seeds: splitAndTrimEmpty(config.P2P.Seeds, ",", " "), SeedMode: config.P2P.SeedMode, }) pexReactor.SetLogger(p2pLogger) sw.AddReactor("PEX", pexReactor) } sw.SetAddrBook(addrBook) // run the profile server profileHost := config.ProfListenAddress if profileHost != "" { go func() { logger.Error("Profile server", "err", http.ListenAndServe(profileHost, nil)) }() } node := &Node{ config: config, genesisDoc: genDoc, privValidator: privValidator, transport: transport, sw: sw, addrBook: addrBook, nodeInfo: nodeInfo, nodeKey: nodeKey, stateDB: stateDB, blockStore: blockStore, bcReactor: bcReactor, mempoolReactor: mempoolReactor, consensusState: consensusState, consensusReactor: consensusReactor, evidencePool: evidencePool, proxyApp: proxyApp, txIndexer: txIndexer, indexerService: indexerService, eventBus: eventBus, } node.BaseService = *cmn.NewBaseService(logger, "Node", node) return node, nil } // OnStart starts the Node. It implements cmn.Service. func (n *Node) OnStart() error { now := tmtime.Now() genTime := n.genesisDoc.GenesisTime if genTime.After(now) { n.Logger.Info("Genesis time is in the future. Sleeping until then...", "genTime", genTime) time.Sleep(genTime.Sub(now)) } err := n.eventBus.Start() if err != nil { return err } // Add private IDs to addrbook to block those peers being added n.addrBook.AddPrivateIDs(splitAndTrimEmpty(n.config.P2P.PrivatePeerIDs, ",", " ")) // Start the RPC server before the P2P server // so we can eg. receive txs for the first block if n.config.RPC.ListenAddress != "" { listeners, err := n.startRPC() if err != nil { return err } n.rpcListeners = listeners } if n.config.Instrumentation.Prometheus && n.config.Instrumentation.PrometheusListenAddr != "" { n.prometheusSrv = n.startPrometheusServer(n.config.Instrumentation.PrometheusListenAddr) } // Start the transport. addr, err := p2p.NewNetAddressStringWithOptionalID(n.config.P2P.ListenAddress) if err != nil { return err } if err := n.transport.Listen(*addr); err != nil { return err } n.isListening = true // Start the switch (the P2P server). err = n.sw.Start() if err != nil { return err } // Always connect to persistent peers if n.config.P2P.PersistentPeers != "" { err = n.sw.DialPeersAsync(n.addrBook, splitAndTrimEmpty(n.config.P2P.PersistentPeers, ",", " "), true) if err != nil { return err } } // start tx indexer return n.indexerService.Start() } // OnStop stops the Node. It implements cmn.Service. func (n *Node) OnStop() { n.BaseService.OnStop() n.Logger.Info("Stopping Node") // first stop the non-reactor services n.eventBus.Stop() n.indexerService.Stop() // now stop the reactors // TODO: gracefully disconnect from peers. n.sw.Stop() if err := n.transport.Close(); err != nil { n.Logger.Error("Error closing transport", "err", err) } n.isListening = false // finally stop the listeners / external services for _, l := range n.rpcListeners { n.Logger.Info("Closing rpc listener", "listener", l) if err := l.Close(); err != nil { n.Logger.Error("Error closing listener", "listener", l, "err", err) } } if pvsc, ok := n.privValidator.(*privval.SocketPV); ok { if err := pvsc.Stop(); err != nil { n.Logger.Error("Error stopping priv validator socket client", "err", err) } } if n.prometheusSrv != nil { if err := n.prometheusSrv.Shutdown(context.Background()); err != nil { // Error from closing listeners, or context timeout: n.Logger.Error("Prometheus HTTP server Shutdown", "err", err) } } } // RunForever waits for an interrupt signal and stops the node. func (n *Node) RunForever() { // Sleep forever and then... cmn.TrapSignal(func() { n.Stop() }) } // ConfigureRPC sets all variables in rpccore so they will serve // rpc calls from this node func (n *Node) ConfigureRPC() { rpccore.SetStateDB(n.stateDB) rpccore.SetBlockStore(n.blockStore) rpccore.SetConsensusState(n.consensusState) rpccore.SetMempool(n.mempoolReactor.Mempool) rpccore.SetEvidencePool(n.evidencePool) rpccore.SetP2PPeers(n.sw) rpccore.SetP2PTransport(n) rpccore.SetPubKey(n.privValidator.GetPubKey()) rpccore.SetGenesisDoc(n.genesisDoc) rpccore.SetAddrBook(n.addrBook) rpccore.SetProxyAppQuery(n.proxyApp.Query()) rpccore.SetTxIndexer(n.txIndexer) rpccore.SetConsensusReactor(n.consensusReactor) rpccore.SetEventBus(n.eventBus) rpccore.SetLogger(n.Logger.With("module", "rpc")) } func (n *Node) startRPC() ([]net.Listener, error) { n.ConfigureRPC() listenAddrs := splitAndTrimEmpty(n.config.RPC.ListenAddress, ",", " ") coreCodec := amino.NewCodec() ctypes.RegisterAmino(coreCodec) if n.config.RPC.Unsafe { rpccore.AddUnsafeRoutes() } // we may expose the rpc over both a unix and tcp socket listeners := make([]net.Listener, len(listenAddrs)) for i, listenAddr := range listenAddrs { mux := http.NewServeMux() rpcLogger := n.Logger.With("module", "rpc-server") wm := rpcserver.NewWebsocketManager(rpccore.Routes, coreCodec, rpcserver.EventSubscriber(n.eventBus)) wm.SetLogger(rpcLogger.With("protocol", "websocket")) mux.HandleFunc("/websocket", wm.WebsocketHandler) rpcserver.RegisterRPCFuncs(mux, rpccore.Routes, coreCodec, rpcLogger) listener, err := rpcserver.StartHTTPServer( listenAddr, mux, rpcLogger, rpcserver.Config{MaxOpenConnections: n.config.RPC.MaxOpenConnections}, ) if err != nil { return nil, err } listeners[i] = listener } // we expose a simplified api over grpc for convenience to app devs grpcListenAddr := n.config.RPC.GRPCListenAddress if grpcListenAddr != "" { listener, err := grpccore.StartGRPCServer( grpcListenAddr, grpccore.Config{ MaxOpenConnections: n.config.RPC.GRPCMaxOpenConnections, }, ) if err != nil { return nil, err } listeners = append(listeners, listener) } return listeners, nil } // startPrometheusServer starts a Prometheus HTTP server, listening for metrics // collectors on addr. func (n *Node) startPrometheusServer(addr string) *http.Server { srv := &http.Server{ Addr: addr, Handler: promhttp.InstrumentMetricHandler( prometheus.DefaultRegisterer, promhttp.HandlerFor( prometheus.DefaultGatherer, promhttp.HandlerOpts{MaxRequestsInFlight: n.config.Instrumentation.MaxOpenConnections}, ), ), } go func() { if err := srv.ListenAndServe(); err != http.ErrServerClosed { // Error starting or closing listener: n.Logger.Error("Prometheus HTTP server ListenAndServe", "err", err) } }() return srv } // Switch returns the Node's Switch. func (n *Node) Switch() *p2p.Switch { return n.sw } // BlockStore returns the Node's BlockStore. func (n *Node) BlockStore() *bc.BlockStore { return n.blockStore } // ConsensusState returns the Node's ConsensusState. func (n *Node) ConsensusState() *cs.ConsensusState { return n.consensusState } // ConsensusReactor returns the Node's ConsensusReactor. func (n *Node) ConsensusReactor() *cs.ConsensusReactor { return n.consensusReactor } // MempoolReactor returns the Node's MempoolReactor. func (n *Node) MempoolReactor() *mempl.MempoolReactor { return n.mempoolReactor } // EvidencePool returns the Node's EvidencePool. func (n *Node) EvidencePool() *evidence.EvidencePool { return n.evidencePool } // EventBus returns the Node's EventBus. func (n *Node) EventBus() *types.EventBus { return n.eventBus } // PrivValidator returns the Node's PrivValidator. // XXX: for convenience only! func (n *Node) PrivValidator() types.PrivValidator { return n.privValidator } // GenesisDoc returns the Node's GenesisDoc. func (n *Node) GenesisDoc() *types.GenesisDoc { return n.genesisDoc } // ProxyApp returns the Node's AppConns, representing its connections to the ABCI application. func (n *Node) ProxyApp() proxy.AppConns { return n.proxyApp } //------------------------------------------------------------------------------ func (n *Node) Listeners() []string { return []string{ fmt.Sprintf("Listener(@%v)", n.config.P2P.ExternalAddress), } } func (n *Node) IsListening() bool { return n.isListening } // NodeInfo returns the Node's Info from the Switch. func (n *Node) NodeInfo() p2p.NodeInfo { return n.nodeInfo } func makeNodeInfo( config *cfg.Config, nodeID p2p.ID, txIndexer txindex.TxIndexer, chainID string, ) p2p.NodeInfo { txIndexerStatus := "on" if _, ok := txIndexer.(*null.TxIndex); ok { txIndexerStatus = "off" } nodeInfo := p2p.NodeInfo{ ID: nodeID, Network: chainID, Version: version.Version, Channels: []byte{ bc.BlockchainChannel, cs.StateChannel, cs.DataChannel, cs.VoteChannel, cs.VoteSetBitsChannel, mempl.MempoolChannel, evidence.EvidenceChannel, }, Moniker: config.Moniker, Other: p2p.NodeInfoOther{ AminoVersion: amino.Version, P2PVersion: p2p.Version, ConsensusVersion: cs.Version, RPCVersion: fmt.Sprintf("%v/%v", rpc.Version, rpccore.Version), TxIndex: txIndexerStatus, RPCAddress: config.RPC.ListenAddress, }, } if config.P2P.PexReactor { nodeInfo.Channels = append(nodeInfo.Channels, pex.PexChannel) } lAddr := config.P2P.ExternalAddress if lAddr == "" { lAddr = config.P2P.ListenAddress } nodeInfo.ListenAddr = lAddr return nodeInfo } //------------------------------------------------------------------------------ var ( genesisDocKey = []byte("genesisDoc") ) // panics if failed to unmarshal bytes func loadGenesisDoc(db dbm.DB) (*types.GenesisDoc, error) { bytes := db.Get(genesisDocKey) if len(bytes) == 0 { return nil, errors.New("Genesis doc not found") } var genDoc *types.GenesisDoc err := cdc.UnmarshalJSON(bytes, &genDoc) if err != nil { cmn.PanicCrisis(fmt.Sprintf("Failed to load genesis doc due to unmarshaling error: %v (bytes: %X)", err, bytes)) } return genDoc, nil } // panics if failed to marshal the given genesis document func saveGenesisDoc(db dbm.DB, genDoc *types.GenesisDoc) { bytes, err := cdc.MarshalJSON(genDoc) if err != nil { cmn.PanicCrisis(fmt.Sprintf("Failed to save genesis doc due to marshaling error: %v", err)) } db.SetSync(genesisDocKey, bytes) } // splitAndTrimEmpty slices s into all subslices separated by sep and returns a // slice of the string s with all leading and trailing Unicode code points // contained in cutset removed. If sep is empty, SplitAndTrim splits after each // UTF-8 sequence. First part is equivalent to strings.SplitN with a count of // -1. also filter out empty strings, only return non-empty strings. func splitAndTrimEmpty(s, sep, cutset string) []string { if s == "" { return []string{} } spl := strings.Split(s, sep) nonEmptyStrings := make([]string, 0, len(spl)) for i := 0; i < len(spl); i++ { element := strings.Trim(spl[i], cutset) if element != "" { nonEmptyStrings = append(nonEmptyStrings, element) } } return nonEmptyStrings }