Esempio n. 1
0
func TestCloneProto(t *testing.T) {
	testCases := []struct {
		pb          proto.Message
		shouldPanic bool
	}{
		{&roachpb.StoreIdent{}, false},
		{&roachpb.StoreIdent{ClusterID: uuid.MakeV4()}, true},
		{&roachpb.TxnMeta{}, false},
		{&roachpb.TxnMeta{ID: uuid.NewV4()}, true},
		{&roachpb.Transaction{}, false},
		{&config.ZoneConfig{RangeMinBytes: 123, RangeMaxBytes: 456}, false},
	}
	for _, tc := range testCases {
		var clone proto.Message
		var panicObj interface{}
		func() {
			defer func() {
				panicObj = recover()
			}()
			clone = protoutil.Clone(tc.pb)
		}()

		if tc.shouldPanic {
			if panicObj == nil {
				t.Errorf("%T: expected panic but didn't get one", tc.pb)
			}
		} else {
			if panicObj != nil {
				if panicStr := fmt.Sprint(panicObj); !strings.Contains(panicStr, "attempt to clone") {
					t.Errorf("%T: got unexpected panic %s", tc.pb, panicStr)
				}
			}
		}

		if panicObj == nil {
			realClone := proto.Clone(tc.pb)
			if !reflect.DeepEqual(clone, realClone) {
				t.Errorf("%T: clone did not equal original. expected:\n%+v\ngot:\n%+v", tc.pb, realClone, clone)
			}
		}
	}
}
Esempio n. 2
0
// 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) (uuid.UUID, error) {
	clusterID := uuid.MakeV4()
	stopper := stop.NewStopper()
	defer stopper.Stop()

	ctx := storage.StoreContext{}
	ctx.ScanInterval = 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)
	ctx.DB = client.NewDB(sender)
	ctx.Transport = storage.NewLocalRPCTransport(stopper)
	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{}, util.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{}, util.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{}, util.Errorf("expected to initialize store id allocator to %d, got %d: %s",
				sIdent.StoreID, storeID, err)
		}
	}
	return clusterID, nil
}
Esempio n. 3
0
func TestFlowRegistry(t *testing.T) {
	reg := makeFlowRegistry()

	id1 := FlowID{uuid.MakeV4()}
	f1 := &Flow{}

	id2 := FlowID{uuid.MakeV4()}
	f2 := &Flow{}

	id3 := FlowID{uuid.MakeV4()}
	f3 := &Flow{}

	// A basic duration; needs to be significantly larger than possible delays
	// in scheduling goroutines.
	jiffy := 10 * time.Millisecond

	// -- Lookup, register, lookup, unregister, lookup. --

	if f := reg.LookupFlow(id1, 0); f != nil {
		t.Error("looked up unregistered flow")
	}

	reg.RegisterFlow(id1, f1)

	if f := reg.LookupFlow(id1, 0); f != f1 {
		t.Error("couldn't lookup previously registered flow")
	}

	reg.UnregisterFlow(id1)

	if f := reg.LookupFlow(id1, 0); f != nil {
		t.Error("looked up unregistered flow")
	}

	// -- Lookup with timeout, register in the meantime. --

	go func() {
		time.Sleep(jiffy)
		reg.RegisterFlow(id1, f1)
	}()

	if f := reg.LookupFlow(id1, 10*jiffy); f != f1 {
		t.Error("couldn't lookup registered flow (with wait)")
	}

	if f := reg.LookupFlow(id1, 0); f != f1 {
		t.Error("couldn't lookup registered flow")
	}

	// -- Multiple lookups before register. --

	var wg sync.WaitGroup
	wg.Add(2)

	go func() {
		if f := reg.LookupFlow(id2, 10*jiffy); f != f2 {
			t.Error("couldn't lookup registered flow (with wait)")
		}
		wg.Done()
	}()

	go func() {
		if f := reg.LookupFlow(id2, 10*jiffy); f != f2 {
			t.Error("couldn't lookup registered flow (with wait)")
		}
		wg.Done()
	}()

	time.Sleep(jiffy)
	reg.RegisterFlow(id2, f2)
	wg.Wait()

	// -- Multiple lookups, with the first one failing. --

	var wg1 sync.WaitGroup
	var wg2 sync.WaitGroup

	wg1.Add(1)
	wg2.Add(1)
	go func() {
		if f := reg.LookupFlow(id3, jiffy); f != nil {
			t.Error("expected lookup to fail")
		}
		wg1.Done()
	}()

	go func() {
		if f := reg.LookupFlow(id3, 10*jiffy); f != f3 {
			t.Error("couldn't lookup registered flow (with wait)")
		}
		wg2.Done()
	}()

	wg1.Wait()
	reg.RegisterFlow(id3, f3)
	wg2.Wait()
}
Esempio n. 4
0
func TestClusterFlow(t *testing.T) {
	defer leaktest.AfterTest(t)()
	const numRows = 100

	args := base.TestClusterArgs{ReplicationMode: base.ReplicationManual}
	tc := serverutils.StartTestCluster(t, 3, args)
	defer tc.Stopper().Stop()

	sumDigitsFn := func(row int) parser.Datum {
		sum := 0
		for row > 0 {
			sum += row % 10
			row /= 10
		}
		return parser.NewDInt(parser.DInt(sum))
	}

	sqlutils.CreateTable(t, tc.ServerConn(0), "t",
		"num INT PRIMARY KEY, digitsum INT, numstr STRING, INDEX s (digitsum)",
		numRows,
		sqlutils.ToRowFn(sqlutils.RowIdxFn, sumDigitsFn, sqlutils.RowEnglishFn))

	kvDB := tc.Server(0).KVClient().(*client.DB)
	desc := sqlbase.GetTableDescriptor(kvDB, "test", "t")
	makeIndexSpan := func(start, end int) TableReaderSpan {
		var span roachpb.Span
		prefix := roachpb.Key(sqlbase.MakeIndexKeyPrefix(desc, desc.Indexes[0].ID))
		span.Key = append(prefix, encoding.EncodeVarintAscending(nil, int64(start))...)
		span.EndKey = append(span.EndKey, prefix...)
		span.EndKey = append(span.EndKey, encoding.EncodeVarintAscending(nil, int64(end))...)
		return TableReaderSpan{Span: span}
	}

	// Set up table readers on three hosts feeding data into a join reader on
	// the third host. This is a basic test for the distributed flow
	// infrastructure, including local and remote streams.
	//
	// Note that the ranges won't necessarily be local to the table readers, but
	// that doesn't matter for the purposes of this test.

	tr1 := TableReaderSpec{
		Table:         *desc,
		IndexIdx:      1,
		OutputColumns: []uint32{0, 1},
		Spans:         []TableReaderSpan{makeIndexSpan(0, 8)},
	}

	tr2 := TableReaderSpec{
		Table:         *desc,
		IndexIdx:      1,
		OutputColumns: []uint32{0, 1},
		Spans:         []TableReaderSpan{makeIndexSpan(8, 12)},
	}

	tr3 := TableReaderSpec{
		Table:         *desc,
		IndexIdx:      1,
		OutputColumns: []uint32{0, 1},
		Spans:         []TableReaderSpan{makeIndexSpan(12, 100)},
	}

	jr := JoinReaderSpec{
		Table:         *desc,
		OutputColumns: []uint32{2},
	}

	txn := client.NewTxn(context.Background(), *kvDB)
	fid := FlowID{uuid.MakeV4()}

	req1 := &SetupFlowRequest{Txn: txn.Proto}
	req1.Flow = FlowSpec{
		FlowID: fid,
		Processors: []ProcessorSpec{{
			Core: ProcessorCoreUnion{TableReader: &tr1},
			Output: []OutputRouterSpec{{
				Type: OutputRouterSpec_MIRROR,
				Streams: []StreamEndpointSpec{
					{Mailbox: &MailboxSpec{StreamID: 0, TargetAddr: tc.Server(2).ServingAddr()}},
				},
			}},
		}},
	}

	req2 := &SetupFlowRequest{Txn: txn.Proto}
	req2.Flow = FlowSpec{
		FlowID: fid,
		Processors: []ProcessorSpec{{
			Core: ProcessorCoreUnion{TableReader: &tr2},
			Output: []OutputRouterSpec{{
				Type: OutputRouterSpec_MIRROR,
				Streams: []StreamEndpointSpec{
					{Mailbox: &MailboxSpec{StreamID: 1, TargetAddr: tc.Server(2).ServingAddr()}},
				},
			}},
		}},
	}

	req3 := &SetupFlowRequest{Txn: txn.Proto}
	req3.Flow = FlowSpec{
		FlowID: fid,
		Processors: []ProcessorSpec{
			{
				Core: ProcessorCoreUnion{TableReader: &tr3},
				Output: []OutputRouterSpec{{
					Type: OutputRouterSpec_MIRROR,
					Streams: []StreamEndpointSpec{
						{LocalStreamID: LocalStreamID(0)},
					},
				}},
			},
			{
				Input: []InputSyncSpec{{
					Type:     InputSyncSpec_ORDERED,
					Ordering: Ordering{Columns: []Ordering_Column{{1, Ordering_Column_ASC}}},
					Streams: []StreamEndpointSpec{
						{Mailbox: &MailboxSpec{StreamID: 0}},
						{Mailbox: &MailboxSpec{StreamID: 1}},
						{LocalStreamID: LocalStreamID(0)},
					},
				}},
				Core: ProcessorCoreUnion{JoinReader: &jr},
				Output: []OutputRouterSpec{{
					Type:    OutputRouterSpec_MIRROR,
					Streams: []StreamEndpointSpec{{Mailbox: &MailboxSpec{SimpleResponse: true}}},
				}}},
		},
	}

	var clients []DistSQLClient
	for i := 0; i < 3; i++ {
		s := tc.Server(i)
		conn, err := s.RPCContext().GRPCDial(s.ServingAddr())
		if err != nil {
			t.Fatal(err)
		}
		clients = append(clients, NewDistSQLClient(conn))
	}

	ctx := context.Background()

	if log.V(1) {
		log.Infof(ctx, "Setting up flow on 0")
	}
	if resp, err := clients[0].SetupFlow(context.Background(), req1); err != nil {
		t.Fatal(err)
	} else if resp.Error != nil {
		t.Fatal(resp.Error)
	}

	if log.V(1) {
		log.Infof(ctx, "Setting up flow on 1")
	}
	if resp, err := clients[1].SetupFlow(context.Background(), req2); err != nil {
		t.Fatal(err)
	} else if resp.Error != nil {
		t.Fatal(resp.Error)
	}

	if log.V(1) {
		log.Infof(ctx, "Running flow on 2")
	}
	stream, err := clients[2].RunSimpleFlow(context.Background(), req3)
	if err != nil {
		t.Fatal(err)
	}

	var decoder StreamDecoder
	var rows sqlbase.EncDatumRows
	for {
		msg, err := stream.Recv()
		if err != nil {
			if err == io.EOF {
				break
			}
			t.Fatal(err)
		}
		err = decoder.AddMessage(msg)
		if err != nil {
			t.Fatal(err)
		}
		rows = testGetDecodedRows(t, &decoder, rows)
	}
	if done, trailerErr := decoder.IsDone(); !done {
		t.Fatal("stream not done")
	} else if trailerErr != nil {
		t.Fatal("error in the stream trailer:", trailerErr)
	}
	// The result should be all the numbers in string form, ordered by the
	// digit sum (and then by number).
	var results []string
	for sum := 1; sum <= 50; sum++ {
		for i := 1; i <= numRows; i++ {
			if int(*sumDigitsFn(i).(*parser.DInt)) == sum {
				results = append(results, fmt.Sprintf("['%s']", sqlutils.IntToEnglish(i)))
			}
		}
	}
	expected := strings.Join(results, " ")
	expected = "[" + expected + "]"
	if rowStr := rows.String(); rowStr != expected {
		t.Errorf("Result: %s\n Expected: %s\n", rowStr, expected)
	}
}