package consensus import ( "bytes" "context" "fmt" "io" "io/ioutil" "os" "path/filepath" "runtime" "testing" "time" "github.com/stretchr/testify/assert" "github.com/stretchr/testify/require" "sort" "github.com/tendermint/tendermint/abci/example/kvstore" abci "github.com/tendermint/tendermint/abci/types" cfg "github.com/tendermint/tendermint/config" "github.com/tendermint/tendermint/crypto" cmn "github.com/tendermint/tendermint/libs/common" "github.com/tendermint/tendermint/libs/log" mempl "github.com/tendermint/tendermint/mempool" "github.com/tendermint/tendermint/mock" "github.com/tendermint/tendermint/privval" "github.com/tendermint/tendermint/proxy" sm "github.com/tendermint/tendermint/state" "github.com/tendermint/tendermint/types" "github.com/tendermint/tendermint/version" dbm "github.com/tendermint/tm-db" ) func TestMain(m *testing.M) { config = ResetConfig("consensus_reactor_test") consensusReplayConfig = ResetConfig("consensus_replay_test") configStateTest := ResetConfig("consensus_state_test") configMempoolTest := ResetConfig("consensus_mempool_test") configByzantineTest := ResetConfig("consensus_byzantine_test") code := m.Run() os.RemoveAll(config.RootDir) os.RemoveAll(consensusReplayConfig.RootDir) os.RemoveAll(configStateTest.RootDir) os.RemoveAll(configMempoolTest.RootDir) os.RemoveAll(configByzantineTest.RootDir) os.Exit(code) } // These tests ensure we can always recover from failure at any part of the consensus process. // There are two general failure scenarios: failure during consensus, and failure while applying the block. // Only the latter interacts with the app and store, // but the former has to deal with restrictions on re-use of priv_validator keys. // The `WAL Tests` are for failures during the consensus; // the `Handshake Tests` are for failures in applying the block. // With the help of the WAL, we can recover from it all! //------------------------------------------------------------------------------------------ // WAL Tests // TODO: It would be better to verify explicitly which states we can recover from without the wal // and which ones we need the wal for - then we'd also be able to only flush the // wal writer when we need to, instead of with every message. func startNewStateAndWaitForBlock(t *testing.T, consensusReplayConfig *cfg.Config, lastBlockHeight int64, blockDB dbm.DB, stateDB dbm.DB) { logger := log.TestingLogger() state, _ := sm.LoadStateFromDBOrGenesisFile(stateDB, consensusReplayConfig.GenesisFile()) privValidator := loadPrivValidator(consensusReplayConfig) cs := newStateWithConfigAndBlockStore( consensusReplayConfig, state, privValidator, kvstore.NewApplication(), blockDB, ) cs.SetLogger(logger) bytes, _ := ioutil.ReadFile(cs.config.WalFile()) t.Logf("====== WAL: \n\r%X\n", bytes) err := cs.Start() require.NoError(t, err) defer cs.Stop() // This is just a signal that we haven't halted; its not something contained // in the WAL itself. Assuming the consensus state is running, replay of any // WAL, including the empty one, should eventually be followed by a new // block, or else something is wrong. newBlockSub, err := cs.eventBus.Subscribe(context.Background(), testSubscriber, types.EventQueryNewBlock) require.NoError(t, err) select { case <-newBlockSub.Out(): case <-newBlockSub.Cancelled(): t.Fatal("newBlockSub was cancelled") case <-time.After(120 * time.Second): t.Fatal("Timed out waiting for new block (see trace above)") } } func sendTxs(ctx context.Context, cs *State) { for i := 0; i < 256; i++ { select { case <-ctx.Done(): return default: tx := []byte{byte(i)} assertMempool(cs.txNotifier).CheckTx(tx, nil, mempl.TxInfo{}) i++ } } } // TestWALCrash uses crashing WAL to test we can recover from any WAL failure. func TestWALCrash(t *testing.T) { testCases := []struct { name string initFn func(dbm.DB, *State, context.Context) heightToStop int64 }{ {"empty block", func(stateDB dbm.DB, cs *State, ctx context.Context) {}, 1}, {"many non-empty blocks", func(stateDB dbm.DB, cs *State, ctx context.Context) { go sendTxs(ctx, cs) }, 3}, } for i, tc := range testCases { tc := tc consensusReplayConfig := ResetConfig(fmt.Sprintf("%s_%d", t.Name(), i)) t.Run(tc.name, func(t *testing.T) { crashWALandCheckLiveness(t, consensusReplayConfig, tc.initFn, tc.heightToStop) }) } } func crashWALandCheckLiveness(t *testing.T, consensusReplayConfig *cfg.Config, initFn func(dbm.DB, *State, context.Context), heightToStop int64) { walPanicked := make(chan error) crashingWal := &crashingWAL{panicCh: walPanicked, heightToStop: heightToStop} i := 1 LOOP: for { t.Logf("====== LOOP %d\n", i) // create consensus state from a clean slate logger := log.NewNopLogger() blockDB := dbm.NewMemDB() stateDB := blockDB state, _ := sm.MakeGenesisStateFromFile(consensusReplayConfig.GenesisFile()) privValidator := loadPrivValidator(consensusReplayConfig) cs := newStateWithConfigAndBlockStore( consensusReplayConfig, state, privValidator, kvstore.NewApplication(), blockDB, ) cs.SetLogger(logger) // start sending transactions ctx, cancel := context.WithCancel(context.Background()) initFn(stateDB, cs, ctx) // clean up WAL file from the previous iteration walFile := cs.config.WalFile() os.Remove(walFile) // set crashing WAL csWal, err := cs.OpenWAL(walFile) require.NoError(t, err) crashingWal.next = csWal // reset the message counter crashingWal.msgIndex = 1 cs.wal = crashingWal // start consensus state err = cs.Start() require.NoError(t, err) i++ select { case err := <-walPanicked: t.Logf("WAL panicked: %v", err) // make sure we can make blocks after a crash startNewStateAndWaitForBlock(t, consensusReplayConfig, cs.Height, blockDB, stateDB) // stop consensus state and transactions sender (initFn) cs.Stop() cancel() // if we reached the required height, exit if _, ok := err.(ReachedHeightToStopError); ok { break LOOP } case <-time.After(10 * time.Second): t.Fatal("WAL did not panic for 10 seconds (check the log)") } } } // crashingWAL is a WAL which crashes or rather simulates a crash during Save // (before and after). It remembers a message for which we last panicked // (lastPanickedForMsgIndex), so we don't panic for it in subsequent iterations. type crashingWAL struct { next WAL panicCh chan error heightToStop int64 msgIndex int // current message index lastPanickedForMsgIndex int // last message for which we panicked } var _ WAL = &crashingWAL{} // WALWriteError indicates a WAL crash. type WALWriteError struct { msg string } func (e WALWriteError) Error() string { return e.msg } // ReachedHeightToStopError indicates we've reached the required consensus // height and may exit. type ReachedHeightToStopError struct { height int64 } func (e ReachedHeightToStopError) Error() string { return fmt.Sprintf("reached height to stop %d", e.height) } // Write simulate WAL's crashing by sending an error to the panicCh and then // exiting the cs.receiveRoutine. func (w *crashingWAL) Write(m WALMessage) error { if endMsg, ok := m.(EndHeightMessage); ok { if endMsg.Height == w.heightToStop { w.panicCh <- ReachedHeightToStopError{endMsg.Height} runtime.Goexit() return nil } return w.next.Write(m) } if w.msgIndex > w.lastPanickedForMsgIndex { w.lastPanickedForMsgIndex = w.msgIndex _, file, line, _ := runtime.Caller(1) w.panicCh <- WALWriteError{fmt.Sprintf("failed to write %T to WAL (fileline: %s:%d)", m, file, line)} runtime.Goexit() return nil } w.msgIndex++ return w.next.Write(m) } func (w *crashingWAL) WriteSync(m WALMessage) error { return w.Write(m) } func (w *crashingWAL) FlushAndSync() error { return w.next.FlushAndSync() } func (w *crashingWAL) SearchForEndHeight( height int64, options *WALSearchOptions) (rd io.ReadCloser, found bool, err error) { return w.next.SearchForEndHeight(height, options) } func (w *crashingWAL) Start() error { return w.next.Start() } func (w *crashingWAL) Stop() error { return w.next.Stop() } func (w *crashingWAL) Wait() { w.next.Wait() } //------------------------------------------------------------------------------------------ type testSim struct { GenesisState sm.State Config *cfg.Config Chain []*types.Block Commits []*types.Commit CleanupFunc cleanupFunc } const ( numBlocks = 6 ) var ( mempool = mock.Mempool{} evpool = sm.MockEvidencePool{} sim testSim ) //--------------------------------------- // Test handshake/replay // 0 - all synced up // 1 - saved block but app and state are behind // 2 - save block and committed but state is behind var modes = []uint{0, 1, 2} // This is actually not a test, it's for storing validator change tx data for testHandshakeReplay func TestSimulateValidatorsChange(t *testing.T) { nPeers := 7 nVals := 4 css, genDoc, config, cleanup := randConsensusNetWithPeers( nVals, nPeers, "replay_test", newMockTickerFunc(true), newPersistentKVStoreWithPath) sim.Config = config sim.GenesisState, _ = sm.MakeGenesisState(genDoc) sim.CleanupFunc = cleanup partSize := types.BlockPartSizeBytes newRoundCh := subscribe(css[0].eventBus, types.EventQueryNewRound) proposalCh := subscribe(css[0].eventBus, types.EventQueryCompleteProposal) vss := make([]*validatorStub, nPeers) for i := 0; i < nPeers; i++ { vss[i] = NewValidatorStub(css[i].privValidator, i) } height, round := css[0].Height, css[0].Round // start the machine startTestRound(css[0], height, round) incrementHeight(vss...) ensureNewRound(newRoundCh, height, 0) ensureNewProposal(proposalCh, height, round) rs := css[0].GetRoundState() signAddVotes(css[0], types.PrecommitType, rs.ProposalBlock.Hash(), rs.ProposalBlockParts.Header(), vss[1:nVals]...) ensureNewRound(newRoundCh, height+1, 0) //height 2 height++ incrementHeight(vss...) newValidatorPubKey1 := css[nVals].privValidator.GetPubKey() valPubKey1ABCI := types.TM2PB.PubKey(newValidatorPubKey1) newValidatorTx1 := kvstore.MakeValSetChangeTx(valPubKey1ABCI, testMinPower) err := assertMempool(css[0].txNotifier).CheckTx(newValidatorTx1, nil, mempl.TxInfo{}) assert.Nil(t, err) propBlock, _ := css[0].createProposalBlock() //changeProposer(t, cs1, vs2) propBlockParts := propBlock.MakePartSet(partSize) blockID := types.BlockID{Hash: propBlock.Hash(), PartsHeader: propBlockParts.Header()} proposal := types.NewProposal(vss[1].Height, round, -1, blockID) if err := vss[1].SignProposal(config.ChainID(), proposal); err != nil { t.Fatal("failed to sign bad proposal", err) } // set the proposal block if err := css[0].SetProposalAndBlock(proposal, propBlock, propBlockParts, "some peer"); err != nil { t.Fatal(err) } ensureNewProposal(proposalCh, height, round) rs = css[0].GetRoundState() signAddVotes(css[0], types.PrecommitType, rs.ProposalBlock.Hash(), rs.ProposalBlockParts.Header(), vss[1:nVals]...) ensureNewRound(newRoundCh, height+1, 0) //height 3 height++ incrementHeight(vss...) updateValidatorPubKey1 := css[nVals].privValidator.GetPubKey() updatePubKey1ABCI := types.TM2PB.PubKey(updateValidatorPubKey1) updateValidatorTx1 := kvstore.MakeValSetChangeTx(updatePubKey1ABCI, 25) err = assertMempool(css[0].txNotifier).CheckTx(updateValidatorTx1, nil, mempl.TxInfo{}) assert.Nil(t, err) propBlock, _ = css[0].createProposalBlock() //changeProposer(t, cs1, vs2) propBlockParts = propBlock.MakePartSet(partSize) blockID = types.BlockID{Hash: propBlock.Hash(), PartsHeader: propBlockParts.Header()} proposal = types.NewProposal(vss[2].Height, round, -1, blockID) if err := vss[2].SignProposal(config.ChainID(), proposal); err != nil { t.Fatal("failed to sign bad proposal", err) } // set the proposal block if err := css[0].SetProposalAndBlock(proposal, propBlock, propBlockParts, "some peer"); err != nil { t.Fatal(err) } ensureNewProposal(proposalCh, height, round) rs = css[0].GetRoundState() signAddVotes(css[0], types.PrecommitType, rs.ProposalBlock.Hash(), rs.ProposalBlockParts.Header(), vss[1:nVals]...) ensureNewRound(newRoundCh, height+1, 0) //height 4 height++ incrementHeight(vss...) newValidatorPubKey2 := css[nVals+1].privValidator.GetPubKey() newVal2ABCI := types.TM2PB.PubKey(newValidatorPubKey2) newValidatorTx2 := kvstore.MakeValSetChangeTx(newVal2ABCI, testMinPower) err = assertMempool(css[0].txNotifier).CheckTx(newValidatorTx2, nil, mempl.TxInfo{}) assert.Nil(t, err) newValidatorPubKey3 := css[nVals+2].privValidator.GetPubKey() newVal3ABCI := types.TM2PB.PubKey(newValidatorPubKey3) newValidatorTx3 := kvstore.MakeValSetChangeTx(newVal3ABCI, testMinPower) err = assertMempool(css[0].txNotifier).CheckTx(newValidatorTx3, nil, mempl.TxInfo{}) assert.Nil(t, err) propBlock, _ = css[0].createProposalBlock() //changeProposer(t, cs1, vs2) propBlockParts = propBlock.MakePartSet(partSize) blockID = types.BlockID{Hash: propBlock.Hash(), PartsHeader: propBlockParts.Header()} newVss := make([]*validatorStub, nVals+1) copy(newVss, vss[:nVals+1]) sort.Sort(ValidatorStubsByAddress(newVss)) selfIndex := 0 for i, vs := range newVss { if vs.GetPubKey().Equals(css[0].privValidator.GetPubKey()) { selfIndex = i break } } proposal = types.NewProposal(vss[3].Height, round, -1, blockID) if err := vss[3].SignProposal(config.ChainID(), proposal); err != nil { t.Fatal("failed to sign bad proposal", err) } // set the proposal block if err := css[0].SetProposalAndBlock(proposal, propBlock, propBlockParts, "some peer"); err != nil { t.Fatal(err) } ensureNewProposal(proposalCh, height, round) removeValidatorTx2 := kvstore.MakeValSetChangeTx(newVal2ABCI, 0) err = assertMempool(css[0].txNotifier).CheckTx(removeValidatorTx2, nil, mempl.TxInfo{}) assert.Nil(t, err) rs = css[0].GetRoundState() for i := 0; i < nVals+1; i++ { if i == selfIndex { continue } signAddVotes(css[0], types.PrecommitType, rs.ProposalBlock.Hash(), rs.ProposalBlockParts.Header(), newVss[i]) } ensureNewRound(newRoundCh, height+1, 0) //height 5 height++ incrementHeight(vss...) ensureNewProposal(proposalCh, height, round) rs = css[0].GetRoundState() for i := 0; i < nVals+1; i++ { if i == selfIndex { continue } signAddVotes(css[0], types.PrecommitType, rs.ProposalBlock.Hash(), rs.ProposalBlockParts.Header(), newVss[i]) } ensureNewRound(newRoundCh, height+1, 0) //height 6 height++ incrementHeight(vss...) removeValidatorTx3 := kvstore.MakeValSetChangeTx(newVal3ABCI, 0) err = assertMempool(css[0].txNotifier).CheckTx(removeValidatorTx3, nil, mempl.TxInfo{}) assert.Nil(t, err) propBlock, _ = css[0].createProposalBlock() //changeProposer(t, cs1, vs2) propBlockParts = propBlock.MakePartSet(partSize) blockID = types.BlockID{Hash: propBlock.Hash(), PartsHeader: propBlockParts.Header()} newVss = make([]*validatorStub, nVals+3) copy(newVss, vss[:nVals+3]) sort.Sort(ValidatorStubsByAddress(newVss)) for i, vs := range newVss { if vs.GetPubKey().Equals(css[0].privValidator.GetPubKey()) { selfIndex = i break } } proposal = types.NewProposal(vss[1].Height, round, -1, blockID) if err := vss[1].SignProposal(config.ChainID(), proposal); err != nil { t.Fatal("failed to sign bad proposal", err) } // set the proposal block if err := css[0].SetProposalAndBlock(proposal, propBlock, propBlockParts, "some peer"); err != nil { t.Fatal(err) } ensureNewProposal(proposalCh, height, round) rs = css[0].GetRoundState() for i := 0; i < nVals+3; i++ { if i == selfIndex { continue } signAddVotes(css[0], types.PrecommitType, rs.ProposalBlock.Hash(), rs.ProposalBlockParts.Header(), newVss[i]) } ensureNewRound(newRoundCh, height+1, 0) sim.Chain = make([]*types.Block, 0) sim.Commits = make([]*types.Commit, 0) for i := 1; i <= numBlocks; i++ { sim.Chain = append(sim.Chain, css[0].blockStore.LoadBlock(int64(i))) sim.Commits = append(sim.Commits, css[0].blockStore.LoadBlockCommit(int64(i))) } } // Sync from scratch func TestHandshakeReplayAll(t *testing.T) { for _, m := range modes { testHandshakeReplay(t, config, 0, m, false) } for _, m := range modes { testHandshakeReplay(t, config, 0, m, true) } } // Sync many, not from scratch func TestHandshakeReplaySome(t *testing.T) { for _, m := range modes { testHandshakeReplay(t, config, 1, m, false) } for _, m := range modes { testHandshakeReplay(t, config, 1, m, true) } } // Sync from lagging by one func TestHandshakeReplayOne(t *testing.T) { for _, m := range modes { testHandshakeReplay(t, config, numBlocks-1, m, false) } for _, m := range modes { testHandshakeReplay(t, config, numBlocks-1, m, true) } } // Sync from caught up func TestHandshakeReplayNone(t *testing.T) { for _, m := range modes { testHandshakeReplay(t, config, numBlocks, m, false) } for _, m := range modes { testHandshakeReplay(t, config, numBlocks, m, true) } } // Test mockProxyApp should not panic when app return ABCIResponses with some empty ResponseDeliverTx func TestMockProxyApp(t *testing.T) { sim.CleanupFunc() //clean the test env created in TestSimulateValidatorsChange logger := log.TestingLogger() var validTxs, invalidTxs = 0, 0 txIndex := 0 assert.NotPanics(t, func() { abciResWithEmptyDeliverTx := new(sm.ABCIResponses) abciResWithEmptyDeliverTx.DeliverTxs = make([]*abci.ResponseDeliverTx, 0) abciResWithEmptyDeliverTx.DeliverTxs = append(abciResWithEmptyDeliverTx.DeliverTxs, &abci.ResponseDeliverTx{}) // called when saveABCIResponses: bytes := cdc.MustMarshalBinaryBare(abciResWithEmptyDeliverTx) loadedAbciRes := new(sm.ABCIResponses) // this also happens sm.LoadABCIResponses err := cdc.UnmarshalBinaryBare(bytes, loadedAbciRes) require.NoError(t, err) mock := newMockProxyApp([]byte("mock_hash"), loadedAbciRes) abciRes := new(sm.ABCIResponses) abciRes.DeliverTxs = make([]*abci.ResponseDeliverTx, len(loadedAbciRes.DeliverTxs)) // Execute transactions and get hash. proxyCb := func(req *abci.Request, res *abci.Response) { if r, ok := res.Value.(*abci.Response_DeliverTx); ok { // TODO: make use of res.Log // TODO: make use of this info // Blocks may include invalid txs. txRes := r.DeliverTx if txRes.Code == abci.CodeTypeOK { validTxs++ } else { logger.Debug("Invalid tx", "code", txRes.Code, "log", txRes.Log) invalidTxs++ } abciRes.DeliverTxs[txIndex] = txRes txIndex++ } } mock.SetResponseCallback(proxyCb) someTx := []byte("tx") mock.DeliverTxAsync(abci.RequestDeliverTx{Tx: someTx}) }) assert.True(t, validTxs == 1) assert.True(t, invalidTxs == 0) } func tempWALWithData(data []byte) string { walFile, err := ioutil.TempFile("", "wal") if err != nil { panic(fmt.Sprintf("failed to create temp WAL file: %v", err)) } _, err = walFile.Write(data) if err != nil { panic(fmt.Sprintf("failed to write to temp WAL file: %v", err)) } if err := walFile.Close(); err != nil { panic(fmt.Sprintf("failed to close temp WAL file: %v", err)) } return walFile.Name() } // Make some blocks. Start a fresh app and apply nBlocks blocks. // Then restart the app and sync it up with the remaining blocks func testHandshakeReplay(t *testing.T, config *cfg.Config, nBlocks int, mode uint, testValidatorsChange bool) { var chain []*types.Block var commits []*types.Commit var store *mockBlockStore var stateDB dbm.DB var genisisState sm.State if testValidatorsChange { testConfig := ResetConfig(fmt.Sprintf("%s_%v_m", t.Name(), mode)) defer os.RemoveAll(testConfig.RootDir) stateDB = dbm.NewMemDB() genisisState = sim.GenesisState config = sim.Config chain = sim.Chain commits = sim.Commits store = newMockBlockStore(config, genisisState.ConsensusParams) } else { //test single node testConfig := ResetConfig(fmt.Sprintf("%s_%v_s", t.Name(), mode)) defer os.RemoveAll(testConfig.RootDir) walBody, err := WALWithNBlocks(t, numBlocks) require.NoError(t, err) walFile := tempWALWithData(walBody) config.Consensus.SetWalFile(walFile) privVal := privval.LoadFilePV(config.PrivValidatorKeyFile(), config.PrivValidatorStateFile()) wal, err := NewWAL(walFile) require.NoError(t, err) wal.SetLogger(log.TestingLogger()) err = wal.Start() require.NoError(t, err) defer wal.Stop() chain, commits, err = makeBlockchainFromWAL(wal) require.NoError(t, err) stateDB, genisisState, store = stateAndStore(config, privVal.GetPubKey(), kvstore.ProtocolVersion) } store.chain = chain store.commits = commits state := genisisState.Copy() // run the chain through state.ApplyBlock to build up the tendermint state state = buildTMStateFromChain(config, stateDB, state, chain, nBlocks, mode) latestAppHash := state.AppHash // make a new client creator kvstoreApp := kvstore.NewPersistentKVStoreApplication( filepath.Join(config.DBDir(), fmt.Sprintf("replay_test_%d_%d_a", nBlocks, mode))) clientCreator2 := proxy.NewLocalClientCreator(kvstoreApp) if nBlocks > 0 { // run nBlocks against a new client to build up the app state. // use a throwaway tendermint state proxyApp := proxy.NewAppConns(clientCreator2) stateDB1 := dbm.NewMemDB() sm.SaveState(stateDB1, genisisState) buildAppStateFromChain(proxyApp, stateDB1, genisisState, chain, nBlocks, mode) } // now start the app using the handshake - it should sync genDoc, _ := sm.MakeGenesisDocFromFile(config.GenesisFile()) handshaker := NewHandshaker(stateDB, state, store, genDoc) proxyApp := proxy.NewAppConns(clientCreator2) if err := proxyApp.Start(); err != nil { t.Fatalf("Error starting proxy app connections: %v", err) } defer proxyApp.Stop() if err := handshaker.Handshake(proxyApp); err != nil { t.Fatalf("Error on abci handshake: %v", err) } // get the latest app hash from the app res, err := proxyApp.Query().InfoSync(abci.RequestInfo{Version: ""}) if err != nil { t.Fatal(err) } // the app hash should be synced up if !bytes.Equal(latestAppHash, res.LastBlockAppHash) { t.Fatalf( "Expected app hashes to match after handshake/replay. got %X, expected %X", res.LastBlockAppHash, latestAppHash) } expectedBlocksToSync := numBlocks - nBlocks if nBlocks == numBlocks && mode > 0 { expectedBlocksToSync++ } else if nBlocks > 0 && mode == 1 { expectedBlocksToSync++ } if handshaker.NBlocks() != expectedBlocksToSync { t.Fatalf("Expected handshake to sync %d blocks, got %d", expectedBlocksToSync, handshaker.NBlocks()) } } func applyBlock(stateDB dbm.DB, st sm.State, blk *types.Block, proxyApp proxy.AppConns) sm.State { testPartSize := types.BlockPartSizeBytes blockExec := sm.NewBlockExecutor(stateDB, log.TestingLogger(), proxyApp.Consensus(), mempool, evpool) blkID := types.BlockID{Hash: blk.Hash(), PartsHeader: blk.MakePartSet(testPartSize).Header()} newState, err := blockExec.ApplyBlock(st, blkID, blk) if err != nil { panic(err) } return newState } func buildAppStateFromChain(proxyApp proxy.AppConns, stateDB dbm.DB, state sm.State, chain []*types.Block, nBlocks int, mode uint) { // start a new app without handshake, play nBlocks blocks if err := proxyApp.Start(); err != nil { panic(err) } defer proxyApp.Stop() state.Version.Consensus.App = kvstore.ProtocolVersion //simulate handshake, receive app version validators := types.TM2PB.ValidatorUpdates(state.Validators) if _, err := proxyApp.Consensus().InitChainSync(abci.RequestInitChain{ Validators: validators, }); err != nil { panic(err) } sm.SaveState(stateDB, state) //save height 1's validatorsInfo switch mode { case 0: for i := 0; i < nBlocks; i++ { block := chain[i] state = applyBlock(stateDB, state, block, proxyApp) } case 1, 2: for i := 0; i < nBlocks-1; i++ { block := chain[i] state = applyBlock(stateDB, state, block, proxyApp) } if mode == 2 { // update the kvstore height and apphash // as if we ran commit but not state = applyBlock(stateDB, state, chain[nBlocks-1], proxyApp) } } } func buildTMStateFromChain( config *cfg.Config, stateDB dbm.DB, state sm.State, chain []*types.Block, nBlocks int, mode uint) sm.State { // run the whole chain against this client to build up the tendermint state clientCreator := proxy.NewLocalClientCreator( kvstore.NewPersistentKVStoreApplication( filepath.Join(config.DBDir(), fmt.Sprintf("replay_test_%d_%d_t", nBlocks, mode)))) proxyApp := proxy.NewAppConns(clientCreator) if err := proxyApp.Start(); err != nil { panic(err) } defer proxyApp.Stop() state.Version.Consensus.App = kvstore.ProtocolVersion //simulate handshake, receive app version validators := types.TM2PB.ValidatorUpdates(state.Validators) if _, err := proxyApp.Consensus().InitChainSync(abci.RequestInitChain{ Validators: validators, }); err != nil { panic(err) } sm.SaveState(stateDB, state) //save height 1's validatorsInfo switch mode { case 0: // sync right up for _, block := range chain { state = applyBlock(stateDB, state, block, proxyApp) } case 1, 2: // sync up to the penultimate as if we stored the block. // whether we commit or not depends on the appHash for _, block := range chain[:len(chain)-1] { state = applyBlock(stateDB, state, block, proxyApp) } // apply the final block to a state copy so we can // get the right next appHash but keep the state back applyBlock(stateDB, state, chain[len(chain)-1], proxyApp) } return state } func TestHandshakePanicsIfAppReturnsWrongAppHash(t *testing.T) { // 1. Initialize tendermint and commit 3 blocks with the following app hashes: // - 0x01 // - 0x02 // - 0x03 config := ResetConfig("handshake_test_") defer os.RemoveAll(config.RootDir) privVal := privval.LoadFilePV(config.PrivValidatorKeyFile(), config.PrivValidatorStateFile()) const appVersion = 0x0 stateDB, state, store := stateAndStore(config, privVal.GetPubKey(), appVersion) genDoc, _ := sm.MakeGenesisDocFromFile(config.GenesisFile()) state.LastValidators = state.Validators.Copy() // mode = 0 for committing all the blocks blocks := makeBlocks(3, &state, privVal) store.chain = blocks // 2. Tendermint must panic if app returns wrong hash for the first block // - RANDOM HASH // - 0x02 // - 0x03 { app := &badApp{numBlocks: 3, allHashesAreWrong: true} clientCreator := proxy.NewLocalClientCreator(app) proxyApp := proxy.NewAppConns(clientCreator) err := proxyApp.Start() require.NoError(t, err) defer proxyApp.Stop() assert.Panics(t, func() { h := NewHandshaker(stateDB, state, store, genDoc) h.Handshake(proxyApp) }) } // 3. Tendermint must panic if app returns wrong hash for the last block // - 0x01 // - 0x02 // - RANDOM HASH { app := &badApp{numBlocks: 3, onlyLastHashIsWrong: true} clientCreator := proxy.NewLocalClientCreator(app) proxyApp := proxy.NewAppConns(clientCreator) err := proxyApp.Start() require.NoError(t, err) defer proxyApp.Stop() assert.Panics(t, func() { h := NewHandshaker(stateDB, state, store, genDoc) h.Handshake(proxyApp) }) } } func makeBlocks(n int, state *sm.State, privVal types.PrivValidator) []*types.Block { blocks := make([]*types.Block, 0) var ( prevBlock *types.Block prevBlockMeta *types.BlockMeta ) appHeight := byte(0x01) for i := 0; i < n; i++ { height := int64(i + 1) block, parts := makeBlock(*state, prevBlock, prevBlockMeta, privVal, height) blocks = append(blocks, block) prevBlock = block prevBlockMeta = types.NewBlockMeta(block, parts) // update state state.AppHash = []byte{appHeight} appHeight++ state.LastBlockHeight = height } return blocks } func makeBlock(state sm.State, lastBlock *types.Block, lastBlockMeta *types.BlockMeta, privVal types.PrivValidator, height int64) (*types.Block, *types.PartSet) { lastCommit := types.NewCommit(height-1, 0, types.BlockID{}, nil) if height > 1 { vote, _ := types.MakeVote( lastBlock.Header.Height, lastBlockMeta.BlockID, state.Validators, privVal, lastBlock.Header.ChainID) lastCommit = types.NewCommit(vote.Height, vote.Round, lastBlockMeta.BlockID, []types.CommitSig{vote.CommitSig()}) } return state.MakeBlock(height, []types.Tx{}, lastCommit, nil, state.Validators.GetProposer().Address) } type badApp struct { abci.BaseApplication numBlocks byte height byte allHashesAreWrong bool onlyLastHashIsWrong bool } func (app *badApp) Commit() abci.ResponseCommit { app.height++ if app.onlyLastHashIsWrong { if app.height == app.numBlocks { return abci.ResponseCommit{Data: cmn.RandBytes(8)} } return abci.ResponseCommit{Data: []byte{app.height}} } else if app.allHashesAreWrong { return abci.ResponseCommit{Data: cmn.RandBytes(8)} } panic("either allHashesAreWrong or onlyLastHashIsWrong must be set") } //-------------------------- // utils for making blocks func makeBlockchainFromWAL(wal WAL) ([]*types.Block, []*types.Commit, error) { var height int64 // Search for height marker gr, found, err := wal.SearchForEndHeight(height, &WALSearchOptions{}) if err != nil { return nil, nil, err } if !found { return nil, nil, fmt.Errorf("wal does not contain height %d", height) } defer gr.Close() // nolint: errcheck // log.Notice("Build a blockchain by reading from the WAL") var ( blocks []*types.Block commits []*types.Commit thisBlockParts *types.PartSet thisBlockCommit *types.Commit ) dec := NewWALDecoder(gr) for { msg, err := dec.Decode() if err == io.EOF { break } else if err != nil { return nil, nil, err } piece := readPieceFromWAL(msg) if piece == nil { continue } switch p := piece.(type) { case EndHeightMessage: // if its not the first one, we have a full block if thisBlockParts != nil { var block = new(types.Block) _, err = cdc.UnmarshalBinaryLengthPrefixedReader(thisBlockParts.GetReader(), block, 0) if err != nil { panic(err) } if block.Height != height+1 { panic(fmt.Sprintf("read bad block from wal. got height %d, expected %d", block.Height, height+1)) } commitHeight := thisBlockCommit.Height if commitHeight != height+1 { panic(fmt.Sprintf("commit doesnt match. got height %d, expected %d", commitHeight, height+1)) } blocks = append(blocks, block) commits = append(commits, thisBlockCommit) height++ } case *types.PartSetHeader: thisBlockParts = types.NewPartSetFromHeader(*p) case *types.Part: _, err := thisBlockParts.AddPart(p) if err != nil { return nil, nil, err } case *types.Vote: if p.Type == types.PrecommitType { thisBlockCommit = types.NewCommit(p.Height, p.Round, p.BlockID, []types.CommitSig{p.CommitSig()}) } } } // grab the last block too var block = new(types.Block) _, err = cdc.UnmarshalBinaryLengthPrefixedReader(thisBlockParts.GetReader(), block, 0) if err != nil { panic(err) } if block.Height != height+1 { panic(fmt.Sprintf("read bad block from wal. got height %d, expected %d", block.Height, height+1)) } commitHeight := thisBlockCommit.Height if commitHeight != height+1 { panic(fmt.Sprintf("commit doesnt match. got height %d, expected %d", commitHeight, height+1)) } blocks = append(blocks, block) commits = append(commits, thisBlockCommit) return blocks, commits, nil } func readPieceFromWAL(msg *TimedWALMessage) interface{} { // for logging switch m := msg.Msg.(type) { case msgInfo: switch msg := m.Msg.(type) { case *ProposalMessage: return &msg.Proposal.BlockID.PartsHeader case *BlockPartMessage: return msg.Part case *VoteMessage: return msg.Vote } case EndHeightMessage: return m } return nil } // fresh state and mock store func stateAndStore( config *cfg.Config, pubKey crypto.PubKey, appVersion version.Protocol) (dbm.DB, sm.State, *mockBlockStore) { stateDB := dbm.NewMemDB() state, _ := sm.MakeGenesisStateFromFile(config.GenesisFile()) state.Version.Consensus.App = appVersion store := newMockBlockStore(config, state.ConsensusParams) sm.SaveState(stateDB, state) return stateDB, state, store } //---------------------------------- // mock block store type mockBlockStore struct { config *cfg.Config params types.ConsensusParams chain []*types.Block commits []*types.Commit } // TODO: NewBlockStore(db.NewMemDB) ... func newMockBlockStore(config *cfg.Config, params types.ConsensusParams) *mockBlockStore { return &mockBlockStore{config, params, nil, nil} } func (bs *mockBlockStore) Height() int64 { return int64(len(bs.chain)) } func (bs *mockBlockStore) LoadBlock(height int64) *types.Block { return bs.chain[height-1] } func (bs *mockBlockStore) LoadBlockMeta(height int64) *types.BlockMeta { block := bs.chain[height-1] return &types.BlockMeta{ BlockID: types.BlockID{Hash: block.Hash(), PartsHeader: block.MakePartSet(types.BlockPartSizeBytes).Header()}, Header: block.Header, } } func (bs *mockBlockStore) LoadBlockPart(height int64, index int) *types.Part { return nil } func (bs *mockBlockStore) SaveBlock(block *types.Block, blockParts *types.PartSet, seenCommit *types.Commit) { } func (bs *mockBlockStore) LoadBlockCommit(height int64) *types.Commit { return bs.commits[height-1] } func (bs *mockBlockStore) LoadSeenCommit(height int64) *types.Commit { return bs.commits[height-1] } //--------------------------------------- // Test handshake/init chain func TestHandshakeUpdatesValidators(t *testing.T) { val, _ := types.RandValidator(true, 10) vals := types.NewValidatorSet([]*types.Validator{val}) app := &initChainApp{vals: types.TM2PB.ValidatorUpdates(vals)} clientCreator := proxy.NewLocalClientCreator(app) config := ResetConfig("handshake_test_") defer os.RemoveAll(config.RootDir) privVal := privval.LoadFilePV(config.PrivValidatorKeyFile(), config.PrivValidatorStateFile()) stateDB, state, store := stateAndStore(config, privVal.GetPubKey(), 0x0) oldValAddr := state.Validators.Validators[0].Address // now start the app using the handshake - it should sync genDoc, _ := sm.MakeGenesisDocFromFile(config.GenesisFile()) handshaker := NewHandshaker(stateDB, state, store, genDoc) proxyApp := proxy.NewAppConns(clientCreator) if err := proxyApp.Start(); err != nil { t.Fatalf("Error starting proxy app connections: %v", err) } defer proxyApp.Stop() if err := handshaker.Handshake(proxyApp); err != nil { t.Fatalf("Error on abci handshake: %v", err) } // reload the state, check the validator set was updated state = sm.LoadState(stateDB) newValAddr := state.Validators.Validators[0].Address expectValAddr := val.Address assert.NotEqual(t, oldValAddr, newValAddr) assert.Equal(t, newValAddr, expectValAddr) } // returns the vals on InitChain type initChainApp struct { abci.BaseApplication vals []abci.ValidatorUpdate } func (ica *initChainApp) InitChain(req abci.RequestInitChain) abci.ResponseInitChain { return abci.ResponseInitChain{ Validators: ica.vals, } }