zolfa
/
tendermint

package mempool
import (	"context"	"os"	"runtime"	"strings"	"sync"	"testing"	"time"
	"github.com/fortytw2/leaktest"	"github.com/stretchr/testify/require"	"github.com/tendermint/tendermint/abci/example/kvstore"	abci "github.com/tendermint/tendermint/abci/types"	"github.com/tendermint/tendermint/config"	tmsync "github.com/tendermint/tendermint/internal/libs/sync"	"github.com/tendermint/tendermint/internal/p2p"	"github.com/tendermint/tendermint/internal/p2p/p2ptest"	"github.com/tendermint/tendermint/libs/log"	tmrand "github.com/tendermint/tendermint/libs/rand"	protomem "github.com/tendermint/tendermint/proto/tendermint/mempool"	"github.com/tendermint/tendermint/types")
type reactorTestSuite struct {	network *p2ptest.Network	logger  log.Logger
	reactors        map[types.NodeID]*Reactor	mempoolChannels map[types.NodeID]*p2p.Channel	mempools        map[types.NodeID]*TxMempool	kvstores        map[types.NodeID]*kvstore.Application
	peerChans   map[types.NodeID]chan p2p.PeerUpdate	peerUpdates map[types.NodeID]*p2p.PeerUpdates
	nodes []types.NodeID}
func setupReactors(ctx context.Context, t *testing.T, numNodes int, chBuf uint) *reactorTestSuite {	t.Helper()
	cfg, err := config.ResetTestRoot(strings.ReplaceAll(t.Name(), "/", "|"))	require.NoError(t, err)	t.Cleanup(func() { os.RemoveAll(cfg.RootDir) })
	rts := &reactorTestSuite{		logger:          log.NewNopLogger().With("testCase", t.Name()),		network:         p2ptest.MakeNetwork(ctx, t, p2ptest.NetworkOptions{NumNodes: numNodes}),		reactors:        make(map[types.NodeID]*Reactor, numNodes),		mempoolChannels: make(map[types.NodeID]*p2p.Channel, numNodes),		mempools:        make(map[types.NodeID]*TxMempool, numNodes),		kvstores:        make(map[types.NodeID]*kvstore.Application, numNodes),		peerChans:       make(map[types.NodeID]chan p2p.PeerUpdate, numNodes),		peerUpdates:     make(map[types.NodeID]*p2p.PeerUpdates, numNodes),	}
	chDesc := getChannelDescriptor(cfg.Mempool)	rts.mempoolChannels = rts.network.MakeChannelsNoCleanup(ctx, t, chDesc)
	for nodeID := range rts.network.Nodes {		rts.kvstores[nodeID] = kvstore.NewApplication()
		mempool := setup(ctx, t, 0)		rts.mempools[nodeID] = mempool
		rts.peerChans[nodeID] = make(chan p2p.PeerUpdate, chBuf)		rts.peerUpdates[nodeID] = p2p.NewPeerUpdates(rts.peerChans[nodeID], 1)		rts.network.Nodes[nodeID].PeerManager.Register(ctx, rts.peerUpdates[nodeID])
		chCreator := func(ctx context.Context, chDesc *p2p.ChannelDescriptor) (*p2p.Channel, error) {			return rts.mempoolChannels[nodeID], nil		}
		rts.reactors[nodeID], err = NewReactor(			ctx,			rts.logger.With("nodeID", nodeID),			cfg.Mempool,			rts.network.Nodes[nodeID].PeerManager,			mempool,			chCreator,			rts.peerUpdates[nodeID],		)
		require.NoError(t, err)		rts.nodes = append(rts.nodes, nodeID)
		require.NoError(t, rts.reactors[nodeID].Start(ctx))		require.True(t, rts.reactors[nodeID].IsRunning())	}
	require.Len(t, rts.reactors, numNodes)
	t.Cleanup(func() {		for nodeID := range rts.reactors {			if rts.reactors[nodeID].IsRunning() {				require.NoError(t, rts.reactors[nodeID].Stop())				rts.reactors[nodeID].Wait()				require.False(t, rts.reactors[nodeID].IsRunning())			}
		}	})
	t.Cleanup(leaktest.Check(t))
	return rts}
func (rts *reactorTestSuite) start(ctx context.Context, t *testing.T) {	t.Helper()	rts.network.Start(ctx, t)
	require.Len(t,		rts.network.RandomNode().PeerManager.Peers(),		len(rts.nodes)-1,		"network does not have expected number of nodes")}
func (rts *reactorTestSuite) waitForTxns(t *testing.T, txs []types.Tx, ids ...types.NodeID) {	t.Helper()
	// ensure that the transactions get fully broadcast to the
	// rest of the network
	wg := &sync.WaitGroup{}	for name, pool := range rts.mempools {		if !p2ptest.NodeInSlice(name, ids) {			continue		}		if len(txs) == pool.Size() {			continue		}
		wg.Add(1)		go func(pool *TxMempool) {			defer wg.Done()			require.Eventually(t, func() bool { return len(txs) == pool.Size() },				time.Minute,				250*time.Millisecond,				"ntx=%d, size=%d", len(txs), pool.Size(),			)		}(pool)	}	wg.Wait()}
func TestReactorBroadcastDoesNotPanic(t *testing.T) {	ctx, cancel := context.WithCancel(context.Background())	defer cancel()
	const numNodes = 2	rts := setupReactors(ctx, t, numNodes, 0)
	observePanic := func(r interface{}) {		t.Fatal("panic detected in reactor")	}
	primary := rts.nodes[0]	secondary := rts.nodes[1]	primaryReactor := rts.reactors[primary]	primaryMempool := primaryReactor.mempool	secondaryReactor := rts.reactors[secondary]
	primaryReactor.observePanic = observePanic	secondaryReactor.observePanic = observePanic
	firstTx := &WrappedTx{}	primaryMempool.insertTx(firstTx)
	// run the router
	rts.start(ctx, t)
	closer := tmsync.NewCloser()	primaryReactor.peerWG.Add(1)	go primaryReactor.broadcastTxRoutine(ctx, secondary, closer)
	wg := &sync.WaitGroup{}	for i := 0; i < 50; i++ {		next := &WrappedTx{}		wg.Add(1)		go func() {			defer wg.Done()			primaryMempool.insertTx(next)		}()	}
	err := primaryReactor.Stop()	require.NoError(t, err)	primaryReactor.peerWG.Wait()	wg.Wait()}
func TestReactorBroadcastTxs(t *testing.T) {	numTxs := 1000	numNodes := 10	ctx, cancel := context.WithCancel(context.Background())	defer cancel()
	rts := setupReactors(ctx, t, numNodes, uint(numTxs))
	primary := rts.nodes[0]	secondaries := rts.nodes[1:]
	txs := checkTxs(ctx, t, rts.reactors[primary].mempool, numTxs, UnknownPeerID)
	require.Equal(t, numTxs, rts.reactors[primary].mempool.Size())
	rts.start(ctx, t)
	// Wait till all secondary suites (reactor) received all mempool txs from the
	// primary suite (node).
	rts.waitForTxns(t, convertTex(txs), secondaries...)}
// regression test for https://github.com/tendermint/tendermint/issues/5408
func TestReactorConcurrency(t *testing.T) {	numTxs := 10	numNodes := 2
	ctx, cancel := context.WithCancel(context.Background())	defer cancel()
	rts := setupReactors(ctx, t, numNodes, 0)
	primary := rts.nodes[0]	secondary := rts.nodes[1]
	rts.start(ctx, t)
	var wg sync.WaitGroup
	for i := 0; i < runtime.NumCPU()*2; i++ {		wg.Add(2)
		// 1. submit a bunch of txs
		// 2. update the whole mempool

		txs := checkTxs(ctx, t, rts.reactors[primary].mempool, numTxs, UnknownPeerID)		go func() {			defer wg.Done()
			mempool := rts.mempools[primary]
			mempool.Lock()			defer mempool.Unlock()
			deliverTxResponses := make([]*abci.ResponseDeliverTx, len(txs))			for i := range txs {				deliverTxResponses[i] = &abci.ResponseDeliverTx{Code: 0}			}
			require.NoError(t, mempool.Update(ctx, 1, convertTex(txs), deliverTxResponses, nil, nil))		}()
		// 1. submit a bunch of txs
		// 2. update none
		_ = checkTxs(ctx, t, rts.reactors[secondary].mempool, numTxs, UnknownPeerID)		go func() {			defer wg.Done()
			mempool := rts.mempools[secondary]
			mempool.Lock()			defer mempool.Unlock()
			err := mempool.Update(ctx, 1, []types.Tx{}, make([]*abci.ResponseDeliverTx, 0), nil, nil)			require.NoError(t, err)		}()	}
	wg.Wait()}
func TestReactorNoBroadcastToSender(t *testing.T) {	numTxs := 1000	numNodes := 2
	ctx, cancel := context.WithCancel(context.Background())	defer cancel()
	rts := setupReactors(ctx, t, numNodes, uint(numTxs))
	primary := rts.nodes[0]	secondary := rts.nodes[1]
	peerID := uint16(1)	_ = checkTxs(ctx, t, rts.mempools[primary], numTxs, peerID)
	rts.start(ctx, t)
	time.Sleep(100 * time.Millisecond)
	require.Eventually(t, func() bool {		return rts.mempools[secondary].Size() == 0	}, time.Minute, 100*time.Millisecond)}
func TestReactor_MaxTxBytes(t *testing.T) {	numNodes := 2	cfg := config.TestConfig()
	ctx, cancel := context.WithCancel(context.Background())	defer cancel()
	rts := setupReactors(ctx, t, numNodes, 0)
	primary := rts.nodes[0]	secondary := rts.nodes[1]
	// Broadcast a tx, which has the max size and ensure it's received by the
	// second reactor.
	tx1 := tmrand.Bytes(cfg.Mempool.MaxTxBytes)	err := rts.reactors[primary].mempool.CheckTx(		ctx,		tx1,		nil,		TxInfo{			SenderID: UnknownPeerID,		},	)	require.NoError(t, err)
	rts.start(ctx, t)
	rts.reactors[primary].mempool.Flush()	rts.reactors[secondary].mempool.Flush()
	// broadcast a tx, which is beyond the max size and ensure it's not sent
	tx2 := tmrand.Bytes(cfg.Mempool.MaxTxBytes + 1)	err = rts.mempools[primary].CheckTx(ctx, tx2, nil, TxInfo{SenderID: UnknownPeerID})	require.Error(t, err)}
func TestDontExhaustMaxActiveIDs(t *testing.T) {	// we're creating a single node network, but not starting the
	// network.

	ctx, cancel := context.WithCancel(context.Background())	defer cancel()
	rts := setupReactors(ctx, t, 1, MaxActiveIDs+1)
	nodeID := rts.nodes[0]
	peerID, err := types.NewNodeID("0011223344556677889900112233445566778899")	require.NoError(t, err)
	// ensure the reactor does not panic (i.e. exhaust active IDs)
	for i := 0; i < MaxActiveIDs+1; i++ {		rts.peerChans[nodeID] <- p2p.PeerUpdate{			Status: p2p.PeerStatusUp,			NodeID: peerID,		}
		require.NoError(t, rts.mempoolChannels[nodeID].Send(ctx, p2p.Envelope{			To: peerID,			Message: &protomem.Txs{				Txs: [][]byte{},			},		}))	}}
func TestMempoolIDsPanicsIfNodeRequestsOvermaxActiveIDs(t *testing.T) {	if testing.Short() {		t.Skip("skipping test in short mode")	}
	// 0 is already reserved for UnknownPeerID
	ids := NewMempoolIDs()
	peerID, err := types.NewNodeID("0011223344556677889900112233445566778899")	require.NoError(t, err)
	for i := 0; i < MaxActiveIDs-1; i++ {		ids.ReserveForPeer(peerID)	}
	require.Panics(t, func() {		ids.ReserveForPeer(peerID)	})}
func TestBroadcastTxForPeerStopsWhenPeerStops(t *testing.T) {	if testing.Short() {		t.Skip("skipping test in short mode")	}
	ctx, cancel := context.WithCancel(context.Background())	defer cancel()
	rts := setupReactors(ctx, t, 2, 2)
	primary := rts.nodes[0]	secondary := rts.nodes[1]
	rts.start(ctx, t)
	// disconnect peer
	rts.peerChans[primary] <- p2p.PeerUpdate{		Status: p2p.PeerStatusDown,		NodeID: secondary,	}	time.Sleep(500 * time.Millisecond)
	txs := checkTxs(ctx, t, rts.reactors[primary].mempool, 4, UnknownPeerID)	require.Equal(t, 4, len(txs))	require.Equal(t, 4, rts.mempools[primary].Size())	require.Equal(t, 0, rts.mempools[secondary].Size())}