package evidence_test import ( "encoding/hex" "math/rand" "sync" "testing" "time" "github.com/fortytw2/leaktest" "github.com/stretchr/testify/assert" "github.com/stretchr/testify/mock" "github.com/stretchr/testify/require" dbm "github.com/tendermint/tm-db" "github.com/tendermint/tendermint/crypto" "github.com/tendermint/tendermint/crypto/tmhash" "github.com/tendermint/tendermint/internal/evidence" "github.com/tendermint/tendermint/internal/evidence/mocks" "github.com/tendermint/tendermint/internal/p2p" "github.com/tendermint/tendermint/internal/p2p/p2ptest" sm "github.com/tendermint/tendermint/internal/state" "github.com/tendermint/tendermint/libs/log" tmproto "github.com/tendermint/tendermint/proto/tendermint/types" "github.com/tendermint/tendermint/types" ) var ( numEvidence = 10 rng = rand.New(rand.NewSource(time.Now().UnixNano())) ) type reactorTestSuite struct { network *p2ptest.Network logger log.Logger reactors map[types.NodeID]*evidence.Reactor pools map[types.NodeID]*evidence.Pool evidenceChannels map[types.NodeID]*p2p.Channel peerUpdates map[types.NodeID]*p2p.PeerUpdates peerChans map[types.NodeID]chan p2p.PeerUpdate nodes []*p2ptest.Node numStateStores int } func setup(t *testing.T, stateStores []sm.Store, chBuf uint) *reactorTestSuite { t.Helper() pID := make([]byte, 16) _, err := rng.Read(pID) require.NoError(t, err) numStateStores := len(stateStores) rts := &reactorTestSuite{ numStateStores: numStateStores, logger: log.TestingLogger().With("testCase", t.Name()), network: p2ptest.MakeNetwork(t, p2ptest.NetworkOptions{NumNodes: numStateStores}), reactors: make(map[types.NodeID]*evidence.Reactor, numStateStores), pools: make(map[types.NodeID]*evidence.Pool, numStateStores), peerUpdates: make(map[types.NodeID]*p2p.PeerUpdates, numStateStores), peerChans: make(map[types.NodeID]chan p2p.PeerUpdate, numStateStores), } chDesc := p2p.ChannelDescriptor{ID: byte(evidence.EvidenceChannel)} rts.evidenceChannels = rts.network.MakeChannelsNoCleanup(t, chDesc, new(tmproto.EvidenceList), int(chBuf)) require.Len(t, rts.network.RandomNode().PeerManager.Peers(), 0) idx := 0 evidenceTime := time.Date(2019, 1, 1, 0, 0, 0, 0, time.UTC) for nodeID := range rts.network.Nodes { logger := rts.logger.With("validator", idx) evidenceDB := dbm.NewMemDB() blockStore := &mocks.BlockStore{} state, _ := stateStores[idx].Load() blockStore.On("LoadBlockMeta", mock.AnythingOfType("int64")).Return(func(h int64) *types.BlockMeta { if h <= state.LastBlockHeight { return &types.BlockMeta{Header: types.Header{Time: evidenceTime}} } return nil }) rts.pools[nodeID], err = evidence.NewPool(logger, evidenceDB, stateStores[idx], blockStore) require.NoError(t, err) rts.peerChans[nodeID] = make(chan p2p.PeerUpdate) rts.peerUpdates[nodeID] = p2p.NewPeerUpdates(rts.peerChans[nodeID], 1) rts.network.Nodes[nodeID].PeerManager.Register(rts.peerUpdates[nodeID]) rts.nodes = append(rts.nodes, rts.network.Nodes[nodeID]) rts.reactors[nodeID] = evidence.NewReactor(logger, rts.evidenceChannels[nodeID], rts.peerUpdates[nodeID], rts.pools[nodeID]) require.NoError(t, rts.reactors[nodeID].Start()) require.True(t, rts.reactors[nodeID].IsRunning()) idx++ } t.Cleanup(func() { for _, r := range rts.reactors { if r.IsRunning() { require.NoError(t, r.Stop()) require.False(t, r.IsRunning()) } } leaktest.Check(t) }) return rts } func (rts *reactorTestSuite) start(t *testing.T) { rts.network.Start(t) require.Len(t, rts.network.RandomNode().PeerManager.Peers(), rts.numStateStores-1, "network does not have expected number of nodes") } func (rts *reactorTestSuite) waitForEvidence(t *testing.T, evList types.EvidenceList, ids ...types.NodeID) { t.Helper() fn := func(pool *evidence.Pool) { var ( localEvList []types.Evidence size int64 loops int ) // wait till we have at least the amount of evidence // that we expect. if there's more local evidence then // it doesn't make sense to wait longer and a // different assertion should catch the resulting error for len(localEvList) < len(evList) { // each evidence should not be more than 500 bytes localEvList, size = pool.PendingEvidence(int64(len(evList) * 500)) if loops == 100 { t.Log("current wait status:", "|", "local", len(localEvList), "|", "waitlist", len(evList), "|", "size", size) } loops++ } // put the reaped evidence in a map so we can quickly check we got everything evMap := make(map[string]types.Evidence) for _, e := range localEvList { evMap[string(e.Hash())] = e } for i, expectedEv := range evList { gotEv := evMap[string(expectedEv.Hash())] require.Equalf( t, expectedEv, gotEv, "evidence for pool %d in pool does not match; got: %v, expected: %v", i, gotEv, expectedEv, ) } } if len(ids) == 1 { // special case waiting once, just to avoid the extra // goroutine, in the case that this hits a timeout, // the stack will be clearer. fn(rts.pools[ids[0]]) return } wg := sync.WaitGroup{} for id := range rts.pools { if len(ids) > 0 && !p2ptest.NodeInSlice(id, ids) { // if an ID list is specified, then we only // want to wait for those pools that are // specified in the list, otherwise, wait for // all pools. continue } wg.Add(1) go func(id types.NodeID) { defer wg.Done(); fn(rts.pools[id]) }(id) } wg.Wait() } func (rts *reactorTestSuite) assertEvidenceChannelsEmpty(t *testing.T) { t.Helper() for id, r := range rts.reactors { require.NoError(t, r.Stop(), "stopping reactor #%s", id) r.Wait() require.False(t, r.IsRunning(), "reactor #%d did not stop", id) } for id, ech := range rts.evidenceChannels { require.Empty(t, ech.Out, "checking channel #%q", id) } } func createEvidenceList( t *testing.T, pool *evidence.Pool, val types.PrivValidator, numEvidence int, ) types.EvidenceList { t.Helper() evList := make([]types.Evidence, numEvidence) for i := 0; i < numEvidence; i++ { ev := types.NewMockDuplicateVoteEvidenceWithValidator( int64(i+1), time.Date(2019, 1, 1, 0, 0, 0, 0, time.UTC), val, evidenceChainID, ) require.NoError(t, pool.AddEvidence(ev), "adding evidence it#%d of %d to pool with height %d", i, numEvidence, pool.State().LastBlockHeight) evList[i] = ev } return evList } func TestReactorMultiDisconnect(t *testing.T) { val := types.NewMockPV() height := int64(numEvidence) + 10 stateDB1 := initializeValidatorState(t, val, height) stateDB2 := initializeValidatorState(t, val, height) rts := setup(t, []sm.Store{stateDB1, stateDB2}, 20) primary := rts.nodes[0] secondary := rts.nodes[1] _ = createEvidenceList(t, rts.pools[primary.NodeID], val, numEvidence) require.Equal(t, primary.PeerManager.Status(secondary.NodeID), p2p.PeerStatusDown) rts.start(t) require.Equal(t, primary.PeerManager.Status(secondary.NodeID), p2p.PeerStatusUp) // Ensure "disconnecting" the secondary peer from the primary more than once // is handled gracefully. primary.PeerManager.Disconnected(secondary.NodeID) require.Equal(t, primary.PeerManager.Status(secondary.NodeID), p2p.PeerStatusDown) _, err := primary.PeerManager.TryEvictNext() require.NoError(t, err) primary.PeerManager.Disconnected(secondary.NodeID) require.Equal(t, primary.PeerManager.Status(secondary.NodeID), p2p.PeerStatusDown) require.Equal(t, secondary.PeerManager.Status(primary.NodeID), p2p.PeerStatusUp) } // TestReactorBroadcastEvidence creates an environment of multiple peers that // are all at the same height. One peer, designated as a primary, gossips all // evidence to the remaining peers. func TestReactorBroadcastEvidence(t *testing.T) { numPeers := 7 // create a stateDB for all test suites (nodes) stateDBs := make([]sm.Store, numPeers) val := types.NewMockPV() // We need all validators saved for heights at least as high as we have // evidence for. height := int64(numEvidence) + 10 for i := 0; i < numPeers; i++ { stateDBs[i] = initializeValidatorState(t, val, height) } rts := setup(t, stateDBs, 0) rts.start(t) // Create a series of fixtures where each suite contains a reactor and // evidence pool. In addition, we mark a primary suite and the rest are // secondaries where each secondary is added as a peer via a PeerUpdate to the // primary. As a result, the primary will gossip all evidence to each secondary. primary := rts.network.RandomNode() secondaries := make([]*p2ptest.Node, 0, len(rts.network.NodeIDs())-1) secondaryIDs := make([]types.NodeID, 0, cap(secondaries)) for id := range rts.network.Nodes { if id == primary.NodeID { continue } secondaries = append(secondaries, rts.network.Nodes[id]) secondaryIDs = append(secondaryIDs, id) } evList := createEvidenceList(t, rts.pools[primary.NodeID], val, numEvidence) // Add each secondary suite (node) as a peer to the primary suite (node). This // will cause the primary to gossip all evidence to the secondaries. for _, suite := range secondaries { rts.peerChans[primary.NodeID] <- p2p.PeerUpdate{ Status: p2p.PeerStatusUp, NodeID: suite.NodeID, } } // Wait till all secondary suites (reactor) received all evidence from the // primary suite (node). rts.waitForEvidence(t, evList, secondaryIDs...) for _, pool := range rts.pools { require.Equal(t, numEvidence, int(pool.Size())) } rts.assertEvidenceChannelsEmpty(t) } // TestReactorSelectiveBroadcast tests a context where we have two reactors // connected to one another but are at different heights. Reactor 1 which is // ahead receives a list of evidence. func TestReactorBroadcastEvidence_Lagging(t *testing.T) { val := types.NewMockPV() height1 := int64(numEvidence) + 10 height2 := int64(numEvidence) / 2 // stateDB1 is ahead of stateDB2, where stateDB1 has all heights (1-20) and // stateDB2 only has heights 1-5. stateDB1 := initializeValidatorState(t, val, height1) stateDB2 := initializeValidatorState(t, val, height2) rts := setup(t, []sm.Store{stateDB1, stateDB2}, 100) rts.start(t) primary := rts.nodes[0] secondary := rts.nodes[1] // Send a list of valid evidence to the first reactor's, the one that is ahead, // evidence pool. evList := createEvidenceList(t, rts.pools[primary.NodeID], val, numEvidence) // Add each secondary suite (node) as a peer to the primary suite (node). This // will cause the primary to gossip all evidence to the secondaries. rts.peerChans[primary.NodeID] <- p2p.PeerUpdate{ Status: p2p.PeerStatusUp, NodeID: secondary.NodeID, } // only ones less than the peers height should make it through rts.waitForEvidence(t, evList[:height2], secondary.NodeID) require.Equal(t, numEvidence, int(rts.pools[primary.NodeID].Size())) require.Equal(t, int(height2), int(rts.pools[secondary.NodeID].Size())) rts.assertEvidenceChannelsEmpty(t) } func TestReactorBroadcastEvidence_Pending(t *testing.T) { val := types.NewMockPV() height := int64(10) stateDB1 := initializeValidatorState(t, val, height) stateDB2 := initializeValidatorState(t, val, height) rts := setup(t, []sm.Store{stateDB1, stateDB2}, 100) primary := rts.nodes[0] secondary := rts.nodes[1] evList := createEvidenceList(t, rts.pools[primary.NodeID], val, numEvidence) // Manually add half the evidence to the secondary which will mark them as // pending. for i := 0; i < numEvidence/2; i++ { require.NoError(t, rts.pools[secondary.NodeID].AddEvidence(evList[i])) } // the secondary should have half the evidence as pending require.Equal(t, numEvidence/2, int(rts.pools[secondary.NodeID].Size())) rts.start(t) // The secondary reactor should have received all the evidence ignoring the // already pending evidence. rts.waitForEvidence(t, evList, secondary.NodeID) // check to make sure that all of the evidence has // propogated require.Len(t, rts.pools, 2) assert.EqualValues(t, numEvidence, rts.pools[primary.NodeID].Size(), "primary node should have all the evidence") assert.EqualValues(t, numEvidence, rts.pools[secondary.NodeID].Size(), "secondary nodes should have caught up") } func TestReactorBroadcastEvidence_Committed(t *testing.T) { val := types.NewMockPV() height := int64(10) stateDB1 := initializeValidatorState(t, val, height) stateDB2 := initializeValidatorState(t, val, height) rts := setup(t, []sm.Store{stateDB1, stateDB2}, 0) primary := rts.nodes[0] secondary := rts.nodes[1] // add all evidence to the primary reactor evList := createEvidenceList(t, rts.pools[primary.NodeID], val, numEvidence) // Manually add half the evidence to the secondary which will mark them as // pending. for i := 0; i < numEvidence/2; i++ { require.NoError(t, rts.pools[secondary.NodeID].AddEvidence(evList[i])) } // the secondary should have half the evidence as pending require.Equal(t, numEvidence/2, int(rts.pools[secondary.NodeID].Size())) state, err := stateDB2.Load() require.NoError(t, err) // update the secondary's pool such that all pending evidence is committed state.LastBlockHeight++ rts.pools[secondary.NodeID].Update(state, evList[:numEvidence/2]) // the secondary should have half the evidence as committed require.Equal(t, 0, int(rts.pools[secondary.NodeID].Size())) // start the network and ensure it's configured rts.start(t) // The secondary reactor should have received all the evidence ignoring the // already committed evidence. rts.waitForEvidence(t, evList[numEvidence/2:], secondary.NodeID) require.Len(t, rts.pools, 2) assert.EqualValues(t, numEvidence, rts.pools[primary.NodeID].Size(), "primary node should have all the evidence") assert.EqualValues(t, numEvidence/2, rts.pools[secondary.NodeID].Size(), "secondary nodes should have caught up") } func TestReactorBroadcastEvidence_FullyConnected(t *testing.T) { numPeers := 7 // create a stateDB for all test suites (nodes) stateDBs := make([]sm.Store, numPeers) val := types.NewMockPV() // We need all validators saved for heights at least as high as we have // evidence for. height := int64(numEvidence) + 10 for i := 0; i < numPeers; i++ { stateDBs[i] = initializeValidatorState(t, val, height) } rts := setup(t, stateDBs, 0) rts.start(t) evList := createEvidenceList(t, rts.pools[rts.network.RandomNode().NodeID], val, numEvidence) // every suite (reactor) connects to every other suite (reactor) for outerID, outerChan := range rts.peerChans { for innerID := range rts.peerChans { if outerID != innerID { outerChan <- p2p.PeerUpdate{ Status: p2p.PeerStatusUp, NodeID: innerID, } } } } // wait till all suites (reactors) received all evidence from other suites (reactors) rts.waitForEvidence(t, evList) for _, pool := range rts.pools { require.Equal(t, numEvidence, int(pool.Size())) // commit state so we do not continue to repeat gossiping the same evidence state := pool.State() state.LastBlockHeight++ pool.Update(state, evList) } } // nolint:lll func TestEvidenceListSerialization(t *testing.T) { exampleVote := func(msgType byte) *types.Vote { var stamp, err = time.Parse(types.TimeFormat, "2017-12-25T03:00:01.234Z") require.NoError(t, err) return &types.Vote{ Type: tmproto.SignedMsgType(msgType), Height: 3, Round: 2, Timestamp: stamp, BlockID: types.BlockID{ Hash: tmhash.Sum([]byte("blockID_hash")), PartSetHeader: types.PartSetHeader{ Total: 1000000, Hash: tmhash.Sum([]byte("blockID_part_set_header_hash")), }, }, ValidatorAddress: crypto.AddressHash([]byte("validator_address")), ValidatorIndex: 56789, } } val := &types.Validator{ Address: crypto.AddressHash([]byte("validator_address")), VotingPower: 10, } valSet := types.NewValidatorSet([]*types.Validator{val}) dupl, err := types.NewDuplicateVoteEvidence( exampleVote(1), exampleVote(2), defaultEvidenceTime, valSet, ) require.NoError(t, err) testCases := map[string]struct { evidenceList []types.Evidence expBytes string }{ "DuplicateVoteEvidence": { []types.Evidence{dupl}, "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", }, } for name, tc := range testCases { tc := tc t.Run(name, func(t *testing.T) { protoEv := make([]tmproto.Evidence, len(tc.evidenceList)) for i := 0; i < len(tc.evidenceList); i++ { ev, err := types.EvidenceToProto(tc.evidenceList[i]) require.NoError(t, err) protoEv[i] = *ev } epl := tmproto.EvidenceList{ Evidence: protoEv, } bz, err := epl.Marshal() require.NoError(t, err) require.Equal(t, tc.expBytes, hex.EncodeToString(bz)) }) } }