func TestTxnAbandonCount(t *testing.T) {
	defer leaktest.AfterTest(t)()
	manual, sender, cleanupFn := setupMetricsTest(t)
	defer cleanupFn()
	value := []byte("value")
	db := client.NewDB(sender)

	// Test abandoned transaction by making the client timeout ridiculously short. We also set
	// the sender to heartbeat very frequently, because the heartbeat detects and tears down
	// abandoned transactions.
	sender.heartbeatInterval = 2 * time.Millisecond
	sender.clientTimeout = 1 * time.Millisecond
	if err := db.Txn(func(txn *client.Txn) error {
		key := []byte("key-abandon")

		if err := txn.SetIsolation(enginepb.SNAPSHOT); err != nil {
			return err
		}

		if err := txn.Put(key, value); err != nil {
			return err
		}

		manual.Increment(int64(sender.clientTimeout + sender.heartbeatInterval*2))

		checkTxnMetrics(t, sender, "abandon txn", 0, 0, 1, 0, 0)

		return nil
	}); !testutils.IsError(err, "writing transaction timed out") {
		t.Fatalf("unexpected error: %s", err)
	}
}
func TestTxnAbortCount(t *testing.T) {
	defer leaktest.AfterTest(t)()
	_, sender, cleanupFn := setupMetricsTest(t)
	defer cleanupFn()

	value := []byte("value")
	db := client.NewDB(sender)

	intentionalErrText := "intentional error to cause abort"
	// Test aborted transaction.
	if err := db.Txn(func(txn *client.Txn) error {
		key := []byte("key-abort")

		if err := txn.SetIsolation(enginepb.SNAPSHOT); err != nil {
			return err
		}

		if err := txn.Put(key, value); err != nil {
			t.Fatal(err)
		}

		return errors.New(intentionalErrText)
	}); !testutils.IsError(err, intentionalErrText) {
		t.Fatalf("unexpected error: %s", err)
	}
	teardownHeartbeats(sender)
	checkTxnMetrics(t, sender, "abort txn", 0, 0, 0, 1, 0)
}
// Test a normal transaction. This and the other metrics tests below use real KV operations,
// because it took far too much mucking with TxnCoordSender internals to mock out the sender
// function as other tests do.
func TestTxnCommit(t *testing.T) {
	defer leaktest.AfterTest(t)()
	_, sender, cleanupFn := setupMetricsTest(t)
	defer cleanupFn()
	value := []byte("value")
	db := client.NewDB(sender)

	// Test normal commit.
	if err := db.Txn(func(txn *client.Txn) error {
		key := []byte("key-commit")

		if err := txn.SetIsolation(enginepb.SNAPSHOT); err != nil {
			return err
		}

		if err := txn.Put(key, value); err != nil {
			return err
		}

		if err := txn.CommitOrCleanup(); err != nil {
			return err
		}

		return nil
	}); err != nil {
		t.Fatal(err)
	}
	teardownHeartbeats(sender)
	checkTxnMetrics(t, sender, "commit txn", 1, 0 /* not 1PC */, 0, 0, 0)
}
Esempio n. 4
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func (c *cluster) makeClient(nodeIdx int) *client.DB {
	sender, err := client.NewSender(c.rpcCtx, c.rpcAddr(nodeIdx))
	if err != nil {
		log.Fatalf(context.Background(), "failed to initialize KV client: %s", err)
	}
	return client.NewDB(sender)
}
Esempio n. 5
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func newKVNative(b *testing.B) kvInterface {
	enableTracing := tracing.Disable()
	s, _, _ := serverutils.StartServer(b, base.TestServerArgs{})

	// TestServer.DB() returns the TxnCoordSender wrapped client. But that isn't
	// a fair comparison with SQL as we want these client requests to be sent
	// over the network.
	sender, err := client.NewSender(
		rpc.NewContext(&base.Context{
			User:       security.NodeUser,
			SSLCA:      filepath.Join(security.EmbeddedCertsDir, security.EmbeddedCACert),
			SSLCert:    filepath.Join(security.EmbeddedCertsDir, "node.crt"),
			SSLCertKey: filepath.Join(security.EmbeddedCertsDir, "node.key"),
		}, nil, s.Stopper()),
		s.ServingAddr())
	if err != nil {
		b.Fatal(err)
	}

	return &kvNative{
		db: client.NewDB(sender),
		doneFn: func() {
			s.Stopper().Stop()
			enableTracing()
		},
	}
}
Esempio n. 6
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// NewClient implements the Cluster interface.
func (f *Farmer) NewClient(t *testing.T, i int) (*client.DB, *stop.Stopper) {
	stopper := stop.NewStopper()
	rpcContext := rpc.NewContext(&base.Context{
		Insecure: true,
		User:     security.NodeUser,
	}, nil, stopper)
	sender, err := client.NewSender(rpcContext, f.Addr(i, base.DefaultPort))
	if err != nil {
		t.Fatal(err)
	}
	return client.NewDB(sender), stopper
}
Esempio n. 7
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// TestInconsistentReads tests that the methods that generate inconsistent reads
// generate outgoing requests with an INCONSISTENT read consistency.
func TestInconsistentReads(t *testing.T) {
	defer leaktest.AfterTest(t)()

	// Mock out DistSender's sender function to check the read consistency for
	// outgoing BatchRequests and return an empty reply.
	var senderFn client.SenderFunc
	senderFn = func(_ context.Context, ba roachpb.BatchRequest) (*roachpb.BatchResponse, *roachpb.Error) {
		if ba.ReadConsistency != roachpb.INCONSISTENT {
			return nil, roachpb.NewErrorf("BatchRequest has unexpected ReadConsistency %s",
				ba.ReadConsistency)
		}
		return ba.CreateReply(), nil
	}
	db := client.NewDB(senderFn)

	prepInconsistent := func() *client.Batch {
		var b client.Batch
		b.Header.ReadConsistency = roachpb.INCONSISTENT
		return &b
	}

	// Perform inconsistent reads through the mocked sender function.
	{
		key := roachpb.Key([]byte("key"))
		b := prepInconsistent()
		b.Get(key)
		if err := db.Run(b); err != nil {
			t.Fatal(err)
		}
	}

	{
		b := prepInconsistent()
		key1 := roachpb.Key([]byte("key1"))
		key2 := roachpb.Key([]byte("key2"))
		const dontCareMaxRows = 1000
		b.Scan(key1, key2, dontCareMaxRows)
		if err := db.Run(b); err != nil {
			t.Fatal(err)
		}
	}

	{
		key := roachpb.Key([]byte("key"))
		b := db.NewBatch()
		b.Header.ReadConsistency = roachpb.INCONSISTENT
		b.Get(key)
		if err := db.Run(b); err != nil {
			t.Fatal(err)
		}
	}
}
Esempio n. 8
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// createTestNode creates an rpc server using the specified address,
// gossip instance, KV database and a node using the specified slice
// of engines. The server, clock and node are returned. If gossipBS is
// not nil, the gossip bootstrap address is set to gossipBS.
func createTestNode(addr net.Addr, engines []engine.Engine, gossipBS net.Addr, t *testing.T) (
	*grpc.Server, net.Addr, *hlc.Clock, *Node, *stop.Stopper) {
	ctx := storage.StoreContext{}

	stopper := stop.NewStopper()
	ctx.Clock = hlc.NewClock(hlc.UnixNano)
	nodeRPCContext := rpc.NewContext(nodeTestBaseContext, ctx.Clock, stopper)
	ctx.ScanInterval = 10 * time.Hour
	ctx.ConsistencyCheckInterval = 10 * time.Hour
	grpcServer := rpc.NewServer(nodeRPCContext)
	serverCtx := makeTestContext()
	g := gossip.New(
		context.Background(),
		nodeRPCContext,
		grpcServer,
		serverCtx.GossipBootstrapResolvers,
		stopper,
		metric.NewRegistry())
	ln, err := netutil.ListenAndServeGRPC(stopper, grpcServer, addr)
	if err != nil {
		t.Fatal(err)
	}
	if gossipBS != nil {
		// Handle possibility of a :0 port specification.
		if gossipBS.Network() == addr.Network() && gossipBS.String() == addr.String() {
			gossipBS = ln.Addr()
		}
		r, err := resolver.NewResolverFromAddress(gossipBS)
		if err != nil {
			t.Fatalf("bad gossip address %s: %s", gossipBS, err)
		}
		g.SetResolvers([]resolver.Resolver{r})
		g.Start(ln.Addr())
	}
	ctx.Gossip = g
	retryOpts := base.DefaultRetryOptions()
	retryOpts.Closer = stopper.ShouldQuiesce()
	distSender := kv.NewDistSender(&kv.DistSenderConfig{
		Clock:           ctx.Clock,
		RPCContext:      nodeRPCContext,
		RPCRetryOptions: &retryOpts,
	}, g)
	ctx.Ctx = tracing.WithTracer(context.Background(), tracing.NewTracer())
	sender := kv.NewTxnCoordSender(ctx.Ctx, distSender, ctx.Clock, false, stopper,
		kv.MakeTxnMetrics())
	ctx.DB = client.NewDB(sender)
	ctx.Transport = storage.NewDummyRaftTransport()
	node := NewNode(ctx, status.NewMetricsRecorder(ctx.Clock), metric.NewRegistry(), stopper,
		kv.MakeTxnMetrics(), sql.MakeEventLogger(nil))
	roachpb.RegisterInternalServer(grpcServer, node)
	return grpcServer, ln.Addr(), ctx.Clock, node, stopper
}
Esempio n. 9
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func createTestClientForUser(t *testing.T, stopper *stop.Stopper, addr, user string) *client.DB {
	var ctx base.Context
	ctx.InitDefaults()
	ctx.User = user
	ctx.SSLCA = filepath.Join(security.EmbeddedCertsDir, security.EmbeddedCACert)
	ctx.SSLCert = filepath.Join(security.EmbeddedCertsDir, fmt.Sprintf("%s.crt", user))
	ctx.SSLCertKey = filepath.Join(security.EmbeddedCertsDir, fmt.Sprintf("%s.key", user))
	sender, err := client.NewSender(rpc.NewContext(&ctx, nil, stopper), addr)
	if err != nil {
		t.Fatal(err)
	}
	return client.NewDB(sender)
}
Esempio n. 10
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// NewClient implements the Cluster interface.
func (l *LocalCluster) NewClient(t *testing.T, i int) (*roachClient.DB, *stop.Stopper) {
	stopper := stop.NewStopper()
	rpcContext := rpc.NewContext(&base.Context{
		User:       security.NodeUser,
		SSLCA:      filepath.Join(l.CertsDir, security.EmbeddedCACert),
		SSLCert:    filepath.Join(l.CertsDir, security.EmbeddedNodeCert),
		SSLCertKey: filepath.Join(l.CertsDir, security.EmbeddedNodeKey),
	}, nil, stopper)
	sender, err := roachClient.NewSender(rpcContext, l.Nodes[i].Addr(DefaultTCP).String())
	if err != nil {
		t.Fatal(err)
	}
	return roachClient.NewDB(sender), stopper
}
Esempio n. 11
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func makeDBClient() (*client.DB, *stop.Stopper) {
	stopper := stop.NewStopper()
	context := &base.Context{
		User:       security.NodeUser,
		SSLCA:      baseCtx.SSLCA,
		SSLCert:    baseCtx.SSLCert,
		SSLCertKey: baseCtx.SSLCertKey,
		Insecure:   baseCtx.Insecure,
	}
	sender, err := client.NewSender(rpc.NewContext(context, nil, stopper), baseCtx.Addr)
	if err != nil {
		stopper.Stop()
		panicf("failed to initialize KV client: %s", err)
	}
	return client.NewDB(sender), stopper
}
Esempio n. 12
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// TestTxnOnePhaseCommit verifies that 1PC metric tracking works.
func TestTxnOnePhaseCommit(t *testing.T) {
	defer leaktest.AfterTest(t)()
	_, sender, cleanupFn := setupMetricsTest(t)
	defer cleanupFn()
	value := []byte("value")
	db := client.NewDB(sender)

	if err := db.Txn(func(txn *client.Txn) error {
		key := []byte("key-commit")
		b := txn.NewBatch()
		b.Put(key, value)
		return txn.CommitInBatch(b)
	}); err != nil {
		t.Fatal(err)
	}
	teardownHeartbeats(sender)
	checkTxnMetrics(t, sender, "commit 1PC txn", 1, 1 /* 1PC */, 0, 0, 0)
}
Esempio n. 13
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func TestTxnDurations(t *testing.T) {
	defer leaktest.AfterTest(t)()
	manual, sender, cleanupFn := setupMetricsTest(t)
	defer cleanupFn()

	db := client.NewDB(sender)
	const puts = 10

	const incr int64 = 1000
	for i := 0; i < puts; i++ {
		key := roachpb.Key(fmt.Sprintf("key-txn-durations-%d", i))
		if err := db.Txn(func(txn *client.Txn) error {
			if err := txn.SetIsolation(enginepb.SNAPSHOT); err != nil {
				return err
			}
			if err := txn.Put(key, []byte("val")); err != nil {
				return err
			}
			manual.Increment(incr)
			return nil
		}); err != nil {
			t.Fatal(err)
		}
	}

	teardownHeartbeats(sender)
	checkTxnMetrics(t, sender, "txn durations", puts, 0, 0, 0, 0)

	hist := sender.metrics.Durations[metric.Scale1M].Current()

	// The clock is a bit odd in these tests, so I can't test the mean without introducing
	// spurious errors or being overly lax.
	// TODO(cdo): look into cause of variance.
	if a, e := hist.TotalCount(), int64(puts); a != e {
		t.Fatalf("durations %d != expected %d", a, e)
	}

	if min := hist.Min(); min < incr {
		t.Fatalf("min %d < %d", min, incr)
	}
}
Esempio n. 14
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func TestTxnRestartCount(t *testing.T) {
	defer leaktest.AfterTest(t)()
	_, sender, cleanupFn := setupMetricsTest(t)
	defer cleanupFn()

	key := []byte("key-restart")
	value := []byte("value")
	db := client.NewDB(sender)

	// Start a transaction and do a GET. This forces a timestamp to be chosen for the transaction.
	txn := client.NewTxn(context.Background(), *db)
	if _, err := txn.Get(key); err != nil {
		t.Fatal(err)
	}

	// Outside of the transaction, read the same key as was read within the transaction. This
	// means that future attempts to write will increase the timestamp.
	if _, err := db.Get(key); err != nil {
		t.Fatal(err)
	}

	// This put will lay down an intent, txn timestamp will increase beyond original.
	if err := txn.Put(key, value); err != nil {
		t.Fatal(err)
	}
	if !txn.Proto.OrigTimestamp.Less(txn.Proto.Timestamp) {
		t.Errorf("expected timestamp to increase: %s", txn.Proto)
	}

	// Commit (should cause restart metric to increase).
	err := txn.CommitOrCleanup()
	assertTransactionRetryError(t, err)

	teardownHeartbeats(sender)
	checkTxnMetrics(t, sender, "restart txn", 0, 0, 0, 1, 1)
}
Esempio n. 15
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// TestTxnCoordSenderTxnUpdatedOnError verifies that errors adjust the
// response transaction's timestamp and priority as appropriate.
func TestTxnCoordSenderTxnUpdatedOnError(t *testing.T) {
	defer leaktest.AfterTest(t)()
	origTS := makeTS(123, 0)
	plus10 := origTS.Add(10, 10)
	plus20 := plus10.Add(10, 0)
	testCases := []struct {
		pErr             *roachpb.Error
		expEpoch         uint32
		expPri           int32
		expTS, expOrigTS hlc.Timestamp
		nodeSeen         bool
	}{
		{
			// No error, so nothing interesting either.
			pErr:      nil,
			expEpoch:  0,
			expPri:    1,
			expTS:     origTS,
			expOrigTS: origTS,
		},
		{
			// On uncertainty error, new epoch begins and node is seen.
			// Timestamp moves ahead of the existing write.
			pErr: func() *roachpb.Error {
				pErr := roachpb.NewErrorWithTxn(
					roachpb.NewReadWithinUncertaintyIntervalError(hlc.ZeroTimestamp, hlc.ZeroTimestamp),
					&roachpb.Transaction{})
				const nodeID = 1
				pErr.GetTxn().UpdateObservedTimestamp(nodeID, plus10)
				pErr.OriginNode = nodeID
				return pErr
			}(),
			expEpoch:  1,
			expPri:    1,
			expTS:     plus10,
			expOrigTS: plus10,
			nodeSeen:  true,
		},
		{
			// On abort, nothing changes but we get a new priority to use for
			// the next attempt.
			pErr: roachpb.NewErrorWithTxn(&roachpb.TransactionAbortedError{},
				&roachpb.Transaction{
					TxnMeta: enginepb.TxnMeta{Timestamp: plus20, Priority: 10},
				}),
			expPri: 10,
		},
		{
			// On failed push, new epoch begins just past the pushed timestamp.
			// Additionally, priority ratchets up to just below the pusher's.
			pErr: roachpb.NewErrorWithTxn(&roachpb.TransactionPushError{
				PusheeTxn: roachpb.Transaction{
					TxnMeta: enginepb.TxnMeta{Timestamp: plus10, Priority: int32(10)},
				},
			},
				&roachpb.Transaction{}),
			expEpoch:  1,
			expPri:    9,
			expTS:     plus10,
			expOrigTS: plus10,
		},
		{
			// On retry, restart with new epoch, timestamp and priority.
			pErr: roachpb.NewErrorWithTxn(&roachpb.TransactionRetryError{},
				&roachpb.Transaction{
					TxnMeta: enginepb.TxnMeta{Timestamp: plus10, Priority: int32(10)},
				},
			),
			expEpoch:  1,
			expPri:    10,
			expTS:     plus10,
			expOrigTS: plus10,
		},
	}

	for i, test := range testCases {
		stopper := stop.NewStopper()

		manual := hlc.NewManualClock(origTS.WallTime)
		clock := hlc.NewClock(manual.UnixNano)
		clock.SetMaxOffset(20)

		ts := NewTxnCoordSender(senderFn(func(_ context.Context, ba roachpb.BatchRequest) (*roachpb.BatchResponse, *roachpb.Error) {
			var reply *roachpb.BatchResponse
			if test.pErr == nil {
				reply = ba.CreateReply()
			}
			return reply, test.pErr
		}), clock, false, tracing.NewTracer(), stopper, NewTxnMetrics(metric.NewRegistry()))
		db := client.NewDB(ts)
		txn := client.NewTxn(context.Background(), *db)
		txn.InternalSetPriority(1)
		txn.Proto.Name = "test txn"
		key := roachpb.Key("test-key")
		_, err := txn.Get(key)
		teardownHeartbeats(ts)
		stopper.Stop()

		if test.pErr != nil && err == nil {
			t.Fatalf("expected an error")
		}
		if txn.Proto.Epoch != test.expEpoch {
			t.Errorf("%d: expected epoch = %d; got %d",
				i, test.expEpoch, txn.Proto.Epoch)
		}
		if txn.Proto.Priority != test.expPri {
			t.Errorf("%d: expected priority = %d; got %d",
				i, test.expPri, txn.Proto.Priority)
		}
		if !txn.Proto.Timestamp.Equal(test.expTS) {
			t.Errorf("%d: expected timestamp to be %s; got %s",
				i, test.expTS, txn.Proto.Timestamp)
		}
		if !txn.Proto.OrigTimestamp.Equal(test.expOrigTS) {
			t.Errorf("%d: expected orig timestamp to be %s; got %s",
				i, test.expOrigTS, txn.Proto.OrigTimestamp)
		}
		if ns := txn.Proto.ObservedTimestamps; (len(ns) != 0) != test.nodeSeen {
			t.Errorf("%d: expected nodeSeen=%t, but list of hosts is %v",
				i, test.nodeSeen, ns)
		}
	}
}
Esempio n. 16
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// bootstrapCluster bootstraps a multiple stores using the provided
// engines and cluster ID. The first bootstrapped store contains a
// single range spanning all keys. Initial range lookup metadata is
// populated for the range. Returns the cluster ID.
func bootstrapCluster(engines []engine.Engine, txnMetrics *kv.TxnMetrics) (uuid.UUID, error) {
	clusterID := uuid.MakeV4()
	stopper := stop.NewStopper()
	defer stopper.Stop()

	ctx := storage.StoreContext{}
	ctx.ScanInterval = 10 * time.Minute
	ctx.ConsistencyCheckInterval = 10 * time.Minute
	ctx.Clock = hlc.NewClock(hlc.UnixNano)
	ctx.Tracer = tracing.NewTracer()
	// Create a KV DB with a local sender.
	stores := storage.NewStores(ctx.Clock)
	sender := kv.NewTxnCoordSender(stores, ctx.Clock, false, ctx.Tracer, stopper, txnMetrics)
	ctx.DB = client.NewDB(sender)
	ctx.Transport = storage.NewDummyRaftTransport()
	for i, eng := range engines {
		sIdent := roachpb.StoreIdent{
			ClusterID: clusterID,
			NodeID:    1,
			StoreID:   roachpb.StoreID(i + 1),
		}

		// The bootstrapping store will not connect to other nodes so its
		// StoreConfig doesn't really matter.
		s := storage.NewStore(ctx, eng, &roachpb.NodeDescriptor{NodeID: 1})

		// Verify the store isn't already part of a cluster.
		if s.Ident.ClusterID != *uuid.EmptyUUID {
			return uuid.UUID{}, errors.Errorf("storage engine already belongs to a cluster (%s)", s.Ident.ClusterID)
		}

		// Bootstrap store to persist the store ident.
		if err := s.Bootstrap(sIdent, stopper); err != nil {
			return uuid.UUID{}, err
		}
		// Create first range, writing directly to engine. Note this does
		// not create the range, just its data. Only do this if this is the
		// first store.
		if i == 0 {
			initialValues := GetBootstrapSchema().GetInitialValues()
			if err := s.BootstrapRange(initialValues); err != nil {
				return uuid.UUID{}, err
			}
		}
		if err := s.Start(stopper); err != nil {
			return uuid.UUID{}, err
		}

		stores.AddStore(s)

		// Initialize node and store ids.  Only initialize the node once.
		if i == 0 {
			if nodeID, err := allocateNodeID(ctx.DB); nodeID != sIdent.NodeID || err != nil {
				return uuid.UUID{}, errors.Errorf("expected to initialize node id allocator to %d, got %d: %s",
					sIdent.NodeID, nodeID, err)
			}
		}
		if storeID, err := allocateStoreIDs(sIdent.NodeID, 1, ctx.DB); storeID != sIdent.StoreID || err != nil {
			return uuid.UUID{}, errors.Errorf("expected to initialize store id allocator to %d, got %d: %s",
				sIdent.StoreID, storeID, err)
		}
	}
	return clusterID, nil
}
Esempio n. 17
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// NewServer creates a Server from a server.Context.
func NewServer(srvCtx Context, stopper *stop.Stopper) (*Server, error) {
	if _, err := net.ResolveTCPAddr("tcp", srvCtx.Addr); err != nil {
		return nil, errors.Errorf("unable to resolve RPC address %q: %v", srvCtx.Addr, err)
	}

	if srvCtx.Ctx == nil {
		srvCtx.Ctx = context.Background()
	}
	if srvCtx.Ctx.Done() != nil {
		panic("context with cancel or deadline")
	}
	if tracing.TracerFromCtx(srvCtx.Ctx) == nil {
		// TODO(radu): instead of modifying srvCtx.Ctx, we should have a separate
		// context.Context inside Server. We will need to rename server.Context
		// though.
		srvCtx.Ctx = tracing.WithTracer(srvCtx.Ctx, tracing.NewTracer())
	}

	if srvCtx.Insecure {
		log.Warning(srvCtx.Ctx, "running in insecure mode, this is strongly discouraged. See --insecure.")
	}
	// Try loading the TLS configs before anything else.
	if _, err := srvCtx.GetServerTLSConfig(); err != nil {
		return nil, err
	}
	if _, err := srvCtx.GetClientTLSConfig(); err != nil {
		return nil, err
	}

	s := &Server{
		mux:     http.NewServeMux(),
		clock:   hlc.NewClock(hlc.UnixNano),
		stopper: stopper,
	}
	// Add a dynamic log tag value for the node ID.
	//
	// We need to pass the server's Ctx as a base context for the various server
	// components, but we won't know the node ID until we Start(). At that point
	// it's too late to change the contexts in the components (various background
	// processes will have already started using the contexts).
	//
	// The dynamic value allows us to add the log tag to the context now and
	// update the value asynchronously. It's not significantly more expensive than
	// a regular tag since it's just doing an (atomic) load when a log/trace
	// message is constructed.
	s.nodeLogTagVal.Set(log.DynamicIntValueUnknown)
	srvCtx.Ctx = log.WithLogTag(srvCtx.Ctx, "n", &s.nodeLogTagVal)
	s.ctx = srvCtx

	s.clock.SetMaxOffset(srvCtx.MaxOffset)

	s.rpcContext = rpc.NewContext(srvCtx.Context, s.clock, s.stopper)
	s.rpcContext.HeartbeatCB = func() {
		if err := s.rpcContext.RemoteClocks.VerifyClockOffset(); err != nil {
			log.Fatal(s.Ctx(), err)
		}
	}
	s.grpc = rpc.NewServer(s.rpcContext)

	s.registry = metric.NewRegistry()
	s.gossip = gossip.New(
		s.Ctx(), s.rpcContext, s.grpc, s.ctx.GossipBootstrapResolvers, s.stopper, s.registry)
	s.storePool = storage.NewStorePool(
		s.gossip,
		s.clock,
		s.rpcContext,
		srvCtx.ReservationsEnabled,
		srvCtx.TimeUntilStoreDead,
		s.stopper,
	)

	// A custom RetryOptions is created which uses stopper.ShouldQuiesce() as
	// the Closer. This prevents infinite retry loops from occurring during
	// graceful server shutdown
	//
	// Such a loop loop occurs with the DistSender attempts a connection to the
	// local server during shutdown, and receives an internal server error (HTTP
	// Code 5xx). This is the correct error for a server to return when it is
	// shutting down, and is normally retryable in a cluster environment.
	// However, on a single-node setup (such as a test), retries will never
	// succeed because the only server has been shut down; thus, thus the
	// DistSender needs to know that it should not retry in this situation.
	retryOpts := base.DefaultRetryOptions()
	retryOpts.Closer = s.stopper.ShouldQuiesce()
	distSenderCfg := kv.DistSenderConfig{
		Ctx:             s.Ctx(),
		Clock:           s.clock,
		RPCContext:      s.rpcContext,
		RPCRetryOptions: &retryOpts,
	}
	s.distSender = kv.NewDistSender(&distSenderCfg, s.gossip)

	txnMetrics := kv.MakeTxnMetrics()
	s.registry.AddMetricStruct(txnMetrics)
	s.txnCoordSender = kv.NewTxnCoordSender(s.Ctx(), s.distSender, s.clock, srvCtx.Linearizable,
		s.stopper, txnMetrics)
	s.db = client.NewDB(s.txnCoordSender)

	s.raftTransport = storage.NewRaftTransport(storage.GossipAddressResolver(s.gossip), s.grpc, s.rpcContext)

	s.kvDB = kv.NewDBServer(s.ctx.Context, s.txnCoordSender, s.stopper)
	roachpb.RegisterExternalServer(s.grpc, s.kvDB)

	// Set up Lease Manager
	var lmKnobs sql.LeaseManagerTestingKnobs
	if srvCtx.TestingKnobs.SQLLeaseManager != nil {
		lmKnobs = *srvCtx.TestingKnobs.SQLLeaseManager.(*sql.LeaseManagerTestingKnobs)
	}
	s.leaseMgr = sql.NewLeaseManager(0, *s.db, s.clock, lmKnobs, s.stopper)
	s.leaseMgr.RefreshLeases(s.stopper, s.db, s.gossip)

	// Set up the DistSQL server
	distSQLCfg := distsql.ServerConfig{
		Context:    s.Ctx(),
		DB:         s.db,
		RPCContext: s.rpcContext,
	}
	s.distSQLServer = distsql.NewServer(distSQLCfg)
	distsql.RegisterDistSQLServer(s.grpc, s.distSQLServer)

	// Set up Executor
	execCfg := sql.ExecutorConfig{
		Context:      s.Ctx(),
		DB:           s.db,
		Gossip:       s.gossip,
		LeaseManager: s.leaseMgr,
		Clock:        s.clock,
		DistSQLSrv:   s.distSQLServer,
	}
	if srvCtx.TestingKnobs.SQLExecutor != nil {
		execCfg.TestingKnobs = srvCtx.TestingKnobs.SQLExecutor.(*sql.ExecutorTestingKnobs)
	} else {
		execCfg.TestingKnobs = &sql.ExecutorTestingKnobs{}
	}

	s.sqlExecutor = sql.NewExecutor(execCfg, s.stopper)
	s.registry.AddMetricStruct(s.sqlExecutor)

	s.pgServer = pgwire.MakeServer(s.ctx.Context, s.sqlExecutor)
	s.registry.AddMetricStruct(s.pgServer.Metrics())

	// TODO(bdarnell): make StoreConfig configurable.
	nCtx := storage.StoreContext{
		Ctx:                            s.Ctx(),
		Clock:                          s.clock,
		DB:                             s.db,
		Gossip:                         s.gossip,
		Transport:                      s.raftTransport,
		RaftTickInterval:               s.ctx.RaftTickInterval,
		ScanInterval:                   s.ctx.ScanInterval,
		ScanMaxIdleTime:                s.ctx.ScanMaxIdleTime,
		ConsistencyCheckInterval:       s.ctx.ConsistencyCheckInterval,
		ConsistencyCheckPanicOnFailure: s.ctx.ConsistencyCheckPanicOnFailure,
		StorePool:                      s.storePool,
		SQLExecutor: sql.InternalExecutor{
			LeaseManager: s.leaseMgr,
		},
		LogRangeEvents: true,
		AllocatorOptions: storage.AllocatorOptions{
			AllowRebalance: true,
		},
	}
	if srvCtx.TestingKnobs.Store != nil {
		nCtx.TestingKnobs = *srvCtx.TestingKnobs.Store.(*storage.StoreTestingKnobs)
	}

	s.recorder = status.NewMetricsRecorder(s.clock)
	s.registry.AddMetricStruct(s.rpcContext.RemoteClocks.Metrics())

	s.runtime = status.MakeRuntimeStatSampler(s.clock)
	s.registry.AddMetricStruct(s.runtime)

	s.node = NewNode(nCtx, s.recorder, s.registry, s.stopper, txnMetrics, sql.MakeEventLogger(s.leaseMgr))
	roachpb.RegisterInternalServer(s.grpc, s.node)
	storage.RegisterStoresServer(s.grpc, s.node.storesServer)

	s.tsDB = ts.NewDB(s.db)
	s.tsServer = ts.MakeServer(s.tsDB)

	s.admin = makeAdminServer(s)
	s.status = newStatusServer(s.db, s.gossip, s.recorder, s.ctx.Context, s.rpcContext, s.node.stores)
	for _, gw := range []grpcGatewayServer{&s.admin, s.status, &s.tsServer} {
		gw.RegisterService(s.grpc)
	}

	return s, nil
}
Esempio n. 18
0
// NewServer creates a Server from a server.Context.
func NewServer(ctx Context, stopper *stop.Stopper) (*Server, error) {
	if _, err := net.ResolveTCPAddr("tcp", ctx.Addr); err != nil {
		return nil, errors.Errorf("unable to resolve RPC address %q: %v", ctx.Addr, err)
	}

	if ctx.Insecure {
		log.Warning(context.TODO(), "running in insecure mode, this is strongly discouraged. See --insecure.")
	}
	// Try loading the TLS configs before anything else.
	if _, err := ctx.GetServerTLSConfig(); err != nil {
		return nil, err
	}
	if _, err := ctx.GetClientTLSConfig(); err != nil {
		return nil, err
	}

	s := &Server{
		Tracer:  tracing.NewTracer(),
		ctx:     ctx,
		mux:     http.NewServeMux(),
		clock:   hlc.NewClock(hlc.UnixNano),
		stopper: stopper,
	}
	s.clock.SetMaxOffset(ctx.MaxOffset)

	s.rpcContext = rpc.NewContext(ctx.Context, s.clock, s.stopper)
	s.rpcContext.HeartbeatCB = func() {
		if err := s.rpcContext.RemoteClocks.VerifyClockOffset(); err != nil {
			log.Fatal(context.TODO(), err)
		}
	}
	s.grpc = rpc.NewServer(s.rpcContext)

	s.registry = metric.NewRegistry()
	s.gossip = gossip.New(s.rpcContext, s.grpc, s.ctx.GossipBootstrapResolvers, s.stopper, s.registry)
	s.storePool = storage.NewStorePool(
		s.gossip,
		s.clock,
		s.rpcContext,
		ctx.ReservationsEnabled,
		ctx.TimeUntilStoreDead,
		s.stopper,
	)

	// A custom RetryOptions is created which uses stopper.ShouldQuiesce() as
	// the Closer. This prevents infinite retry loops from occurring during
	// graceful server shutdown
	//
	// Such a loop loop occurs with the DistSender attempts a connection to the
	// local server during shutdown, and receives an internal server error (HTTP
	// Code 5xx). This is the correct error for a server to return when it is
	// shutting down, and is normally retryable in a cluster environment.
	// However, on a single-node setup (such as a test), retries will never
	// succeed because the only server has been shut down; thus, thus the
	// DistSender needs to know that it should not retry in this situation.
	retryOpts := base.DefaultRetryOptions()
	retryOpts.Closer = s.stopper.ShouldQuiesce()
	s.distSender = kv.NewDistSender(&kv.DistSenderContext{
		Clock:           s.clock,
		RPCContext:      s.rpcContext,
		RPCRetryOptions: &retryOpts,
	}, s.gossip)
	txnMetrics := kv.NewTxnMetrics(s.registry)
	sender := kv.NewTxnCoordSender(s.distSender, s.clock, ctx.Linearizable, s.Tracer,
		s.stopper, txnMetrics)
	s.db = client.NewDB(sender)

	s.raftTransport = storage.NewRaftTransport(storage.GossipAddressResolver(s.gossip), s.grpc, s.rpcContext)

	s.kvDB = kv.NewDBServer(s.ctx.Context, sender, s.stopper)
	roachpb.RegisterExternalServer(s.grpc, s.kvDB)

	// Set up Lease Manager
	var lmKnobs sql.LeaseManagerTestingKnobs
	if ctx.TestingKnobs.SQLLeaseManager != nil {
		lmKnobs = *ctx.TestingKnobs.SQLLeaseManager.(*sql.LeaseManagerTestingKnobs)
	}
	s.leaseMgr = sql.NewLeaseManager(0, *s.db, s.clock, lmKnobs, s.stopper)
	s.leaseMgr.RefreshLeases(s.stopper, s.db, s.gossip)

	// Set up the DistSQL server
	distSQLCtx := distsql.ServerContext{
		Context:    context.Background(),
		DB:         s.db,
		RPCContext: s.rpcContext,
	}
	s.distSQLServer = distsql.NewServer(distSQLCtx)
	distsql.RegisterDistSQLServer(s.grpc, s.distSQLServer)

	// Set up Executor
	eCtx := sql.ExecutorContext{
		Context:      context.Background(),
		DB:           s.db,
		Gossip:       s.gossip,
		LeaseManager: s.leaseMgr,
		Clock:        s.clock,
		DistSQLSrv:   s.distSQLServer,
	}
	if ctx.TestingKnobs.SQLExecutor != nil {
		eCtx.TestingKnobs = ctx.TestingKnobs.SQLExecutor.(*sql.ExecutorTestingKnobs)
	} else {
		eCtx.TestingKnobs = &sql.ExecutorTestingKnobs{}
	}

	s.sqlExecutor = sql.NewExecutor(eCtx, s.stopper, s.registry)

	s.pgServer = pgwire.MakeServer(s.ctx.Context, s.sqlExecutor, s.registry)

	// TODO(bdarnell): make StoreConfig configurable.
	nCtx := storage.StoreContext{
		Clock:                          s.clock,
		DB:                             s.db,
		Gossip:                         s.gossip,
		Transport:                      s.raftTransport,
		RaftTickInterval:               s.ctx.RaftTickInterval,
		ScanInterval:                   s.ctx.ScanInterval,
		ScanMaxIdleTime:                s.ctx.ScanMaxIdleTime,
		ConsistencyCheckInterval:       s.ctx.ConsistencyCheckInterval,
		ConsistencyCheckPanicOnFailure: s.ctx.ConsistencyCheckPanicOnFailure,
		Tracer:    s.Tracer,
		StorePool: s.storePool,
		SQLExecutor: sql.InternalExecutor{
			LeaseManager: s.leaseMgr,
		},
		LogRangeEvents: true,
		AllocatorOptions: storage.AllocatorOptions{
			AllowRebalance: true,
		},
	}
	if ctx.TestingKnobs.Store != nil {
		nCtx.TestingKnobs = *ctx.TestingKnobs.Store.(*storage.StoreTestingKnobs)
	}

	s.recorder = status.NewMetricsRecorder(s.clock)
	s.rpcContext.RemoteClocks.RegisterMetrics(s.registry)
	s.runtime = status.MakeRuntimeStatSampler(s.clock, s.registry)

	s.node = NewNode(nCtx, s.recorder, s.registry, s.stopper, txnMetrics, sql.MakeEventLogger(s.leaseMgr))
	roachpb.RegisterInternalServer(s.grpc, s.node)
	roachpb.RegisterInternalStoresServer(s.grpc, s.node.InternalStoresServer)

	s.tsDB = ts.NewDB(s.db)
	s.tsServer = ts.MakeServer(s.tsDB)

	s.admin = makeAdminServer(s)
	s.status = newStatusServer(s.db, s.gossip, s.recorder, s.ctx.Context, s.rpcContext, s.node.stores)
	for _, gw := range []grpcGatewayServer{&s.admin, s.status, &s.tsServer} {
		gw.RegisterService(s.grpc)
	}

	return s, nil
}
Esempio n. 19
0
// TestTxnCoordSenderNoDuplicateIntents verifies that TxnCoordSender does not
// generate duplicate intents and that it merges intents for overlapping ranges.
func TestTxnCoordSenderNoDuplicateIntents(t *testing.T) {
	defer leaktest.AfterTest(t)()
	stopper := stop.NewStopper()
	manual := hlc.NewManualClock(0)
	clock := hlc.NewClock(manual.UnixNano)

	var expectedIntents []roachpb.Span

	senderFunc := func(_ context.Context, ba roachpb.BatchRequest) (
		*roachpb.BatchResponse, *roachpb.Error) {
		if rArgs, ok := ba.GetArg(roachpb.EndTransaction); ok {
			et := rArgs.(*roachpb.EndTransactionRequest)
			if !reflect.DeepEqual(et.IntentSpans, expectedIntents) {
				t.Errorf("Invalid intents: %+v; expected %+v", et.IntentSpans, expectedIntents)
			}
		}
		br := ba.CreateReply()
		txnClone := ba.Txn.Clone()
		br.Txn = &txnClone
		br.Txn.Writing = true
		return br, nil
	}
	ts := NewTxnCoordSender(senderFn(senderFunc), clock, false, tracing.NewTracer(), stopper,
		NewTxnMetrics(metric.NewRegistry()))

	defer stopper.Stop()
	defer teardownHeartbeats(ts)

	db := client.NewDB(ts)
	txn := client.NewTxn(context.Background(), *db)

	// Write to a, b, u-w before the final batch.

	pErr := txn.Put(roachpb.Key("a"), []byte("value"))
	if pErr != nil {
		t.Fatal(pErr)
	}
	pErr = txn.Put(roachpb.Key("b"), []byte("value"))
	if pErr != nil {
		t.Fatal(pErr)
	}
	pErr = txn.DelRange(roachpb.Key("u"), roachpb.Key("w"))
	if pErr != nil {
		t.Fatal(pErr)
	}

	// The final batch overwrites key a and overlaps part of the u-w range.
	b := txn.NewBatch()
	b.Put(roachpb.Key("b"), []byte("value"))
	b.Put(roachpb.Key("c"), []byte("value"))
	b.DelRange(roachpb.Key("v"), roachpb.Key("z"), false)

	// The expected intents are a, b, c, and u-z.
	expectedIntents = []roachpb.Span{
		{Key: roachpb.Key("a"), EndKey: nil},
		{Key: roachpb.Key("b"), EndKey: nil},
		{Key: roachpb.Key("c"), EndKey: nil},
		{Key: roachpb.Key("u"), EndKey: roachpb.Key("z")},
	}

	pErr = txn.CommitInBatch(b)
	if pErr != nil {
		t.Fatal(pErr)
	}
}