package consensus import ( "bufio" "bytes" "fmt" "io" "path/filepath" "testing" "time" db "github.com/tendermint/tm-db" "github.com/tendermint/tendermint/abci/example/kvstore" cfg "github.com/tendermint/tendermint/config" "github.com/tendermint/tendermint/libs/log" tmrand "github.com/tendermint/tendermint/libs/rand" "github.com/tendermint/tendermint/privval" "github.com/tendermint/tendermint/proxy" sm "github.com/tendermint/tendermint/state" "github.com/tendermint/tendermint/store" "github.com/tendermint/tendermint/types" ) // WALGenerateNBlocks generates a consensus WAL. It does this by spinning up a // stripped down version of node (proxy app, event bus, consensus state) with a // persistent kvstore application and special consensus wal instance // (byteBufferWAL) and waits until numBlocks are created. // If the node fails to produce given numBlocks, it returns an error. func WALGenerateNBlocks(t *testing.T, wr io.Writer, numBlocks int) (err error) { config := getConfig(t) app := kvstore.NewPersistentKVStoreApplication(filepath.Join(config.DBDir(), "wal_generator")) logger := log.TestingLogger().With("wal_generator", "wal_generator") logger.Info("generating WAL (last height msg excluded)", "numBlocks", numBlocks) ///////////////////////////////////////////////////////////////////////////// // COPY PASTE FROM node.go WITH A FEW MODIFICATIONS // NOTE: we can't import node package because of circular dependency. // NOTE: we don't do handshake so need to set state.Version.Consensus.App directly. privValidatorKeyFile := config.PrivValidatorKeyFile() privValidatorStateFile := config.PrivValidatorStateFile() privValidator := privval.LoadOrGenFilePV(privValidatorKeyFile, privValidatorStateFile) genDoc, err := types.GenesisDocFromFile(config.GenesisFile()) if err != nil { return fmt.Errorf("failed to read genesis file: %w", err) } blockStoreDB := db.NewMemDB() stateDB := blockStoreDB stateStore := sm.NewStore(stateDB) state, err := sm.MakeGenesisState(genDoc) if err != nil { return fmt.Errorf("failed to make genesis state: %w", err) } state.Version.Consensus.App = kvstore.ProtocolVersion if err = stateStore.Save(state); err != nil { t.Error(err) } blockStore := store.NewBlockStore(blockStoreDB) proxyApp := proxy.NewAppConns(proxy.NewLocalClientCreator(app)) proxyApp.SetLogger(logger.With("module", "proxy")) if err := proxyApp.Start(); err != nil { return fmt.Errorf("failed to start proxy app connections: %w", err) } t.Cleanup(func() { if err := proxyApp.Stop(); err != nil { t.Error(err) } }) eventBus := types.NewEventBus() eventBus.SetLogger(logger.With("module", "events")) if err := eventBus.Start(); err != nil { return fmt.Errorf("failed to start event bus: %w", err) } t.Cleanup(func() { if err := eventBus.Stop(); err != nil { t.Error(err) } }) mempool := emptyMempool{} evpool := sm.EmptyEvidencePool{} blockExec := sm.NewBlockExecutor(stateStore, log.TestingLogger(), proxyApp.Consensus(), mempool, evpool) consensusState := NewState(config.Consensus, state.Copy(), blockExec, blockStore, mempool, evpool) consensusState.SetLogger(logger) consensusState.SetEventBus(eventBus) if privValidator != nil { consensusState.SetPrivValidator(privValidator) } // END OF COPY PASTE ///////////////////////////////////////////////////////////////////////////// // set consensus wal to buffered WAL, which will write all incoming msgs to buffer numBlocksWritten := make(chan struct{}) wal := newByteBufferWAL(logger, NewWALEncoder(wr), int64(numBlocks), numBlocksWritten) // see wal.go#103 if err := wal.Write(EndHeightMessage{0}); err != nil { t.Error(err) } consensusState.wal = wal if err := consensusState.Start(); err != nil { return fmt.Errorf("failed to start consensus state: %w", err) } select { case <-numBlocksWritten: if err := consensusState.Stop(); err != nil { t.Error(err) } return nil case <-time.After(1 * time.Minute): if err := consensusState.Stop(); err != nil { t.Error(err) } return fmt.Errorf("waited too long for tendermint to produce %d blocks (grep logs for `wal_generator`)", numBlocks) } } //WALWithNBlocks returns a WAL content with numBlocks. func WALWithNBlocks(t *testing.T, numBlocks int) (data []byte, err error) { var b bytes.Buffer wr := bufio.NewWriter(&b) if err := WALGenerateNBlocks(t, wr, numBlocks); err != nil { return []byte{}, err } wr.Flush() return b.Bytes(), nil } func randPort() int { // returns between base and base + spread base, spread := 20000, 20000 return base + tmrand.Intn(spread) } func makeAddrs() (string, string, string) { start := randPort() return fmt.Sprintf("tcp://127.0.0.1:%d", start), fmt.Sprintf("tcp://127.0.0.1:%d", start+1), fmt.Sprintf("tcp://127.0.0.1:%d", start+2) } // getConfig returns a config for test cases func getConfig(t *testing.T) *cfg.Config { c := cfg.ResetTestRoot(t.Name()) // and we use random ports to run in parallel tm, rpc, grpc := makeAddrs() c.P2P.ListenAddress = tm c.RPC.ListenAddress = rpc c.RPC.GRPCListenAddress = grpc return c } // byteBufferWAL is a WAL which writes all msgs to a byte buffer. Writing stops // when the heightToStop is reached. Client will be notified via // signalWhenStopsTo channel. type byteBufferWAL struct { enc *WALEncoder stopped bool heightToStop int64 signalWhenStopsTo chan<- struct{} logger log.Logger } // needed for determinism var fixedTime, _ = time.Parse(time.RFC3339, "2017-01-02T15:04:05Z") func newByteBufferWAL(logger log.Logger, enc *WALEncoder, nBlocks int64, signalStop chan<- struct{}) *byteBufferWAL { return &byteBufferWAL{ enc: enc, heightToStop: nBlocks, signalWhenStopsTo: signalStop, logger: logger, } } // Save writes message to the internal buffer except when heightToStop is // reached, in which case it will signal the caller via signalWhenStopsTo and // skip writing. func (w *byteBufferWAL) Write(m WALMessage) error { if w.stopped { w.logger.Debug("WAL already stopped. Not writing message", "msg", m) return nil } if endMsg, ok := m.(EndHeightMessage); ok { w.logger.Debug("WAL write end height message", "height", endMsg.Height, "stopHeight", w.heightToStop) if endMsg.Height == w.heightToStop { w.logger.Debug("Stopping WAL at height", "height", endMsg.Height) w.signalWhenStopsTo <- struct{}{} w.stopped = true return nil } } w.logger.Debug("WAL Write Message", "msg", m) err := w.enc.Encode(&TimedWALMessage{fixedTime, m}) if err != nil { panic(fmt.Sprintf("failed to encode the msg %v", m)) } return nil } func (w *byteBufferWAL) WriteSync(m WALMessage) error { return w.Write(m) } func (w *byteBufferWAL) FlushAndSync() error { return nil } func (w *byteBufferWAL) SearchForEndHeight( height int64, options *WALSearchOptions) (rd io.ReadCloser, found bool, err error) { return nil, false, nil } func (w *byteBufferWAL) Start() error { return nil } func (w *byteBufferWAL) Stop() error { return nil } func (w *byteBufferWAL) Wait() {}