示例#1
0
// NewContext creates an rpc Context with the supplied values.
func NewContext(baseCtx *base.Context, clock *hlc.Clock, stopper *stop.Stopper) *Context {
	ctx := &Context{
		Context: baseCtx,
	}
	if clock != nil {
		ctx.localClock = clock
	} else {
		ctx.localClock = hlc.NewClock(hlc.UnixNano)
	}
	ctx.Stopper = stopper
	ctx.RemoteClocks = newRemoteClockMonitor(clock, 10*defaultHeartbeatInterval)
	ctx.HeartbeatInterval = defaultHeartbeatInterval
	ctx.HeartbeatTimeout = 2 * defaultHeartbeatInterval

	stopper.RunWorker(func() {
		<-stopper.ShouldQuiesce()

		ctx.conns.Lock()
		for key, meta := range ctx.conns.cache {
			ctx.removeConn(key, meta.conn)
		}
		ctx.conns.Unlock()
	})

	return ctx
}
示例#2
0
// ListenAndServeGRPC creates a listener and serves the specified grpc Server
// on it, closing the listener when signalled by the stopper.
func ListenAndServeGRPC(stopper *stop.Stopper, server *grpc.Server,
	addr net.Addr) (net.Listener, error) {
	ln, err := net.Listen(addr.Network(), addr.String())
	if err != nil {
		return ln, err
	}

	stopper.RunWorker(func() {
		<-stopper.ShouldQuiesce()
		server.Stop()
	})

	stopper.RunWorker(func() {
		FatalIfUnexpected(server.Serve(ln))
	})
	return ln, nil
}
示例#3
0
// NewContext creates an rpc Context with the supplied values.
func NewContext(baseCtx *base.Context, hlcClock *hlc.Clock, stopper *stop.Stopper) *Context {
	ctx := &Context{
		Context: baseCtx,
	}
	if hlcClock != nil {
		ctx.localClock = hlcClock
	} else {
		ctx.localClock = hlc.NewClock(hlc.UnixNano)
	}
	ctx.breakerClock = breakerClock{
		clock: ctx.localClock,
	}
	var cancel context.CancelFunc
	ctx.masterCtx, cancel = context.WithCancel(context.Background())
	ctx.Stopper = stopper
	ctx.RemoteClocks = newRemoteClockMonitor(ctx.localClock, 10*defaultHeartbeatInterval)
	ctx.HeartbeatInterval = defaultHeartbeatInterval
	ctx.HeartbeatTimeout = 2 * defaultHeartbeatInterval
	ctx.conns.cache = make(map[string]*connMeta)

	stopper.RunWorker(func() {
		<-stopper.ShouldQuiesce()

		cancel()
		ctx.conns.Lock()
		for key, meta := range ctx.conns.cache {
			meta.Do(func() {
				// Make sure initialization is not in progress when we're removing the
				// conn. We need to set the error in case we win the race against the
				// real initialization code.
				if meta.err == nil {
					meta.err = &roachpb.NodeUnavailableError{}
				}
			})
			ctx.removeConnLocked(key, meta)
		}
		ctx.conns.Unlock()
	})

	return ctx
}
// InitSenderForLocalTestCluster initializes a TxnCoordSender that can be used
// with LocalTestCluster.
func InitSenderForLocalTestCluster(
	nodeDesc *roachpb.NodeDescriptor,
	tracer opentracing.Tracer,
	clock *hlc.Clock,
	latency time.Duration,
	stores client.Sender,
	stopper *stop.Stopper,
	gossip *gossip.Gossip,
) client.Sender {
	retryOpts := base.DefaultRetryOptions()
	retryOpts.Closer = stopper.ShouldQuiesce()
	senderTransportFactory := SenderTransportFactory(tracer, stores)
	distSender := NewDistSender(&DistSenderConfig{
		Clock: clock,
		RangeDescriptorCacheSize: defaultRangeDescriptorCacheSize,
		RangeLookupMaxRanges:     defaultRangeLookupMaxRanges,
		LeaseHolderCacheSize:     defaultLeaseHolderCacheSize,
		RPCRetryOptions:          &retryOpts,
		nodeDescriptor:           nodeDesc,
		TransportFactory: func(
			opts SendOptions,
			rpcContext *rpc.Context,
			replicas ReplicaSlice,
			args roachpb.BatchRequest,
		) (Transport, error) {
			transport, err := senderTransportFactory(opts, rpcContext, replicas, args)
			if err != nil {
				return nil, err
			}
			return &localTestClusterTransport{transport, latency}, nil
		},
		RangeDescriptorDB: stores.(RangeDescriptorDB), // for descriptor lookup
	}, gossip)

	ctx := tracing.WithTracer(context.Background(), tracer)
	return NewTxnCoordSender(ctx, distSender, clock, false, /* !linearizable */
		stopper, MakeTxnMetrics())
}