Esempio n. 1
0
// heartbeatLoop periodically sends a HeartbeatTxn RPC to an extant
// transaction, stopping in the event the transaction is aborted or
// committed after attempting to resolve the intents. When the
// heartbeat stops, the transaction is unregistered from the
// coordinator,
func (tc *TxnCoordSender) heartbeatLoop(id string) {
	var tickChan <-chan time.Time
	{
		ticker := time.NewTicker(tc.heartbeatInterval)
		tickChan = ticker.C
		defer ticker.Stop()
	}
	defer func() {
		tc.Lock()
		tc.unregisterTxnLocked(id)
		tc.Unlock()
	}()

	var closer <-chan struct{}
	var trace *tracer.Trace
	{
		tc.Lock()
		txnMeta := tc.txns[id] // do not leak to outer scope
		closer = txnMeta.txnEnd
		trace = tc.tracer.NewTrace(tracer.Coord, &txnMeta.txn)
		defer trace.Finalize()
		tc.Unlock()
	}
	if closer == nil {
		// Avoid race in which a Txn is cleaned up before the heartbeat
		// goroutine gets a chance to start.
		return
	}
	ctx := tracer.ToCtx(context.Background(), trace)
	// Loop with ticker for periodic heartbeats.
	for {
		select {
		case <-tickChan:
			if !tc.heartbeat(id, trace, ctx) {
				return
			}
		case <-closer:
			// Transaction finished normally.
			return

		case <-tc.stopper.ShouldDrain():
			return
		}
	}
}
Esempio n. 2
0
// heartbeat periodically sends a HeartbeatTxn RPC to an extant
// transaction, stopping in the event the transaction is aborted or
// committed after attempting to resolve the intents. When the
// heartbeat stops, the transaction is unregistered from the
// coordinator,
func (tc *TxnCoordSender) heartbeat(id string) {
	var tickChan <-chan time.Time
	{
		ticker := time.NewTicker(tc.heartbeatInterval)
		tickChan = ticker.C
		defer ticker.Stop()
	}
	defer tc.unregisterTxn(id)

	var closer <-chan struct{}
	var trace *tracer.Trace
	{
		tc.Lock()
		txnMeta := tc.txns[id] // do not leak to outer scope
		closer = txnMeta.txnEnd
		trace = tc.tracer.NewTrace(&txnMeta.txn)
		tc.Unlock()
	}
	if closer == nil {
		// Avoid race in which a Txn is cleaned up before the heartbeat
		// goroutine gets a chance to start.
		return
	}
	ctx := tracer.ToCtx(context.Background(), trace)
	defer trace.Finalize()
	// Loop with ticker for periodic heartbeats.
	for {
		select {
		case <-tickChan:
			tc.Lock()
			proceed := true
			txnMeta := tc.txns[id]
			// Before we send a heartbeat, determine whether this transaction
			// should be considered abandoned. If so, exit heartbeat.
			if txnMeta.hasClientAbandonedCoord(tc.clock.PhysicalNow()) {
				// TODO(tschottdorf): should we be more proactive here?
				// The client might be continuing the transaction
				// through another coordinator, but in the most likely
				// case it's just gone and the open transaction record
				// could block concurrent operations.
				if log.V(1) {
					log.Infof("transaction %s abandoned; stopping heartbeat",
						txnMeta.txn)
				}
				proceed = false
			}
			// txnMeta.txn is possibly replaced concurrently,
			// so grab a copy before unlocking.
			txn := txnMeta.txn
			tc.Unlock()
			if !proceed {
				return
			}

			request := &proto.HeartbeatTxnRequest{
				RequestHeader: proto.RequestHeader{
					Key:  txn.Key,
					User: security.RootUser,
					Txn:  &txn,
				},
			}

			request.Header().Timestamp = tc.clock.Now()
			reply := &proto.HeartbeatTxnResponse{}
			call := proto.Call{
				Args:  request,
				Reply: reply,
			}

			epochEnds := trace.Epoch("heartbeat")
			tc.wrapped.Send(ctx, call)
			epochEnds()
			// If the transaction is not in pending state, then we can stop
			// the heartbeat. It's either aborted or committed, and we resolve
			// write intents accordingly.
			if reply.GoError() != nil {
				log.Warningf("heartbeat to %s failed: %s", txn, reply.GoError())
			} else if reply.Txn != nil && reply.Txn.Status != proto.PENDING {
				// Signal cleanup. Doesn't do much but stop this goroutine, but
				// let's be future-proof.
				tc.cleanupTxn(trace, *reply.Txn)
				return
			}
		case <-closer:
			// Transaction finished normally.
			return
		}
	}
}