package org.opendaylight.controller.cluster.datastore;
-import akka.actor.ActorPath;
import akka.actor.ActorSelection;
+import akka.dispatch.Mapper;
import akka.dispatch.OnComplete;
-
import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.FinalizablePhantomReference;
import com.google.common.base.FinalizableReferenceQueue;
import com.google.common.base.Preconditions;
import com.google.common.collect.Lists;
import com.google.common.util.concurrent.CheckedFuture;
+import com.google.common.util.concurrent.FutureCallback;
import com.google.common.util.concurrent.Futures;
import com.google.common.util.concurrent.SettableFuture;
-
+import java.util.HashMap;
+import java.util.List;
+import java.util.Map;
+import java.util.concurrent.ConcurrentHashMap;
+import java.util.concurrent.TimeUnit;
+import java.util.concurrent.atomic.AtomicBoolean;
+import java.util.concurrent.atomic.AtomicLong;
+import javax.annotation.concurrent.GuardedBy;
+import org.opendaylight.controller.cluster.datastore.exceptions.NoShardLeaderException;
import org.opendaylight.controller.cluster.datastore.identifiers.TransactionIdentifier;
import org.opendaylight.controller.cluster.datastore.messages.CloseTransaction;
import org.opendaylight.controller.cluster.datastore.messages.CreateTransaction;
import org.opendaylight.controller.cluster.datastore.messages.ReadDataReply;
import org.opendaylight.controller.cluster.datastore.messages.ReadyTransaction;
import org.opendaylight.controller.cluster.datastore.messages.ReadyTransactionReply;
+import org.opendaylight.controller.cluster.datastore.messages.SerializableMessage;
import org.opendaylight.controller.cluster.datastore.messages.WriteData;
import org.opendaylight.controller.cluster.datastore.shardstrategy.ShardStrategyFactory;
import org.opendaylight.controller.cluster.datastore.utils.ActorContext;
import org.opendaylight.yangtools.yang.model.api.SchemaContext;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
-
-import scala.Function1;
import scala.concurrent.Future;
-import scala.runtime.AbstractFunction1;
-
-import java.util.HashMap;
-import java.util.List;
-import java.util.Map;
-import java.util.concurrent.ConcurrentHashMap;
-import java.util.concurrent.atomic.AtomicBoolean;
-import java.util.concurrent.atomic.AtomicLong;
+import scala.concurrent.Promise;
+import scala.concurrent.duration.FiniteDuration;
/**
* TransactionProxy acts as a proxy for one or more transactions that were created on a remote shard
* </p>
*/
public class TransactionProxy implements DOMStoreReadWriteTransaction {
- public enum TransactionType {
+
+ public static enum TransactionType {
READ_ONLY,
WRITE_ONLY,
READ_WRITE
}
- static Function1<Throwable, Throwable> SAME_FAILURE_TRANSFORMER = new AbstractFunction1<
- Throwable, Throwable>() {
+ static final Mapper<Throwable, Throwable> SAME_FAILURE_TRANSFORMER =
+ new Mapper<Throwable, Throwable>() {
@Override
public Throwable apply(Throwable failure) {
return failure;
private static final AtomicLong counter = new AtomicLong();
- private static final Logger
- LOG = LoggerFactory.getLogger(TransactionProxy.class);
+ private static final Logger LOG = LoggerFactory.getLogger(TransactionProxy.class);
+ /**
+ * Time interval in between transaction create retries.
+ */
+ private static final FiniteDuration CREATE_TX_TRY_INTERVAL =
+ FiniteDuration.create(1, TimeUnit.SECONDS);
/**
* Used to enqueue the PhantomReferences for read-only TransactionProxy instances. The
if(remoteTransactionActorsMB.get()) {
for(ActorSelection actor : remoteTransactionActors) {
LOG.trace("Sending CloseTransaction to {}", actor);
- actorContext.sendRemoteOperationAsync(actor,
+ actorContext.sendOperationAsync(actor,
new CloseTransaction().toSerializable());
}
}
private List<ActorSelection> remoteTransactionActors;
private AtomicBoolean remoteTransactionActorsMB;
- private final Map<String, TransactionContext> remoteTransactionPaths = new HashMap<>();
+ /**
+ * Stores the create transaction results per shard.
+ */
+ private final Map<String, TransactionFutureCallback> txFutureCallbackMap = new HashMap<>();
private final TransactionType transactionType;
private final ActorContext actorContext;
private final TransactionIdentifier identifier;
+ private final String transactionChainId;
private final SchemaContext schemaContext;
private boolean inReadyState;
public TransactionProxy(ActorContext actorContext, TransactionType transactionType) {
+ this(actorContext, transactionType, "");
+ }
+
+ public TransactionProxy(ActorContext actorContext, TransactionType transactionType,
+ String transactionChainId) {
this.actorContext = Preconditions.checkNotNull(actorContext,
- "actorContext should not be null");
+ "actorContext should not be null");
this.transactionType = Preconditions.checkNotNull(transactionType,
- "transactionType should not be null");
+ "transactionType should not be null");
this.schemaContext = Preconditions.checkNotNull(actorContext.getSchemaContext(),
- "schemaContext should not be null");
+ "schemaContext should not be null");
+ this.transactionChainId = transactionChainId;
String memberName = actorContext.getCurrentMemberName();
if(memberName == null){
}
this.identifier = TransactionIdentifier.builder().memberName(memberName).counter(
- counter.getAndIncrement()).build();
+ counter.getAndIncrement()).build();
if(transactionType == TransactionType.READ_ONLY) {
// Read-only Tx's aren't explicitly closed by the client so we create a PhantomReference
remoteTransactionActorsMB = new AtomicBoolean();
TransactionProxyCleanupPhantomReference cleanup =
- new TransactionProxyCleanupPhantomReference(this);
+ new TransactionProxyCleanupPhantomReference(this);
phantomReferenceCache.put(cleanup, cleanup);
}
- LOG.debug("Created txn {} of type {}", identifier, transactionType);
+ LOG.debug("Created txn {} of type {} on chain {}", identifier, transactionType, transactionChainId);
}
@VisibleForTesting
List<Future<Object>> getRecordedOperationFutures() {
List<Future<Object>> recordedOperationFutures = Lists.newArrayList();
- for(TransactionContext transactionContext : remoteTransactionPaths.values()) {
- recordedOperationFutures.addAll(transactionContext.getRecordedOperationFutures());
+ for(TransactionFutureCallback txFutureCallback : txFutureCallbackMap.values()) {
+ TransactionContext transactionContext = txFutureCallback.getTransactionContext();
+ if(transactionContext != null) {
+ recordedOperationFutures.addAll(transactionContext.getRecordedOperationFutures());
+ }
}
return recordedOperationFutures;
}
+ @VisibleForTesting
+ boolean hasTransactionContext() {
+ for(TransactionFutureCallback txFutureCallback : txFutureCallbackMap.values()) {
+ TransactionContext transactionContext = txFutureCallback.getTransactionContext();
+ if(transactionContext != null) {
+ return true;
+ }
+ }
+
+ return false;
+ }
+
@Override
- public CheckedFuture<Optional<NormalizedNode<?, ?>>, ReadFailedException> read(
- final YangInstanceIdentifier path) {
+ public CheckedFuture<Optional<NormalizedNode<?, ?>>, ReadFailedException> read(final YangInstanceIdentifier path) {
Preconditions.checkState(transactionType != TransactionType.WRITE_ONLY,
"Read operation on write-only transaction is not allowed");
LOG.debug("Tx {} read {}", identifier, path);
- createTransactionIfMissing(actorContext, path);
-
- return transactionContext(path).readData(path);
+ TransactionFutureCallback txFutureCallback = getOrCreateTxFutureCallback(path);
+ return txFutureCallback.enqueueReadOperation(new ReadOperation<Optional<NormalizedNode<?, ?>>>() {
+ @Override
+ public CheckedFuture<Optional<NormalizedNode<?, ?>>, ReadFailedException> invoke(
+ TransactionContext transactionContext) {
+ return transactionContext.readData(path);
+ }
+ });
}
@Override
- public CheckedFuture<Boolean, ReadFailedException> exists(YangInstanceIdentifier path) {
+ public CheckedFuture<Boolean, ReadFailedException> exists(final YangInstanceIdentifier path) {
Preconditions.checkState(transactionType != TransactionType.WRITE_ONLY,
"Exists operation on write-only transaction is not allowed");
LOG.debug("Tx {} exists {}", identifier, path);
- createTransactionIfMissing(actorContext, path);
-
- return transactionContext(path).dataExists(path);
+ TransactionFutureCallback txFutureCallback = getOrCreateTxFutureCallback(path);
+ return txFutureCallback.enqueueReadOperation(new ReadOperation<Boolean>() {
+ @Override
+ public CheckedFuture<Boolean, ReadFailedException> invoke(TransactionContext transactionContext) {
+ return transactionContext.dataExists(path);
+ }
+ });
}
+
private void checkModificationState() {
Preconditions.checkState(transactionType != TransactionType.READ_ONLY,
"Modification operation on read-only transaction is not allowed");
}
@Override
- public void write(YangInstanceIdentifier path, NormalizedNode<?, ?> data) {
+ public void write(final YangInstanceIdentifier path, final NormalizedNode<?, ?> data) {
checkModificationState();
LOG.debug("Tx {} write {}", identifier, path);
- createTransactionIfMissing(actorContext, path);
-
- transactionContext(path).writeData(path, data);
+ TransactionFutureCallback txFutureCallback = getOrCreateTxFutureCallback(path);
+ txFutureCallback.enqueueModifyOperation(new TransactionOperation() {
+ @Override
+ public void invoke(TransactionContext transactionContext) {
+ transactionContext.writeData(path, data);
+ }
+ });
}
@Override
- public void merge(YangInstanceIdentifier path, NormalizedNode<?, ?> data) {
+ public void merge(final YangInstanceIdentifier path, final NormalizedNode<?, ?> data) {
checkModificationState();
LOG.debug("Tx {} merge {}", identifier, path);
- createTransactionIfMissing(actorContext, path);
-
- transactionContext(path).mergeData(path, data);
+ TransactionFutureCallback txFutureCallback = getOrCreateTxFutureCallback(path);
+ txFutureCallback.enqueueModifyOperation(new TransactionOperation() {
+ @Override
+ public void invoke(TransactionContext transactionContext) {
+ transactionContext.mergeData(path, data);
+ }
+ });
}
@Override
- public void delete(YangInstanceIdentifier path) {
+ public void delete(final YangInstanceIdentifier path) {
checkModificationState();
LOG.debug("Tx {} delete {}", identifier, path);
- createTransactionIfMissing(actorContext, path);
-
- transactionContext(path).deleteData(path);
+ TransactionFutureCallback txFutureCallback = getOrCreateTxFutureCallback(path);
+ txFutureCallback.enqueueModifyOperation(new TransactionOperation() {
+ @Override
+ public void invoke(TransactionContext transactionContext) {
+ transactionContext.deleteData(path);
+ }
+ });
}
@Override
inReadyState = true;
- LOG.debug("Tx {} Trying to get {} transactions ready for commit", identifier,
- remoteTransactionPaths.size());
+ LOG.debug("Tx {} Readying {} transactions for commit", identifier,
+ txFutureCallbackMap.size());
- List<Future<ActorPath>> cohortPathFutures = Lists.newArrayList();
+ List<Future<ActorSelection>> cohortFutures = Lists.newArrayList();
- for(TransactionContext transactionContext : remoteTransactionPaths.values()) {
+ for(TransactionFutureCallback txFutureCallback : txFutureCallbackMap.values()) {
- LOG.debug("Tx {} Readying transaction for shard {}", identifier,
- transactionContext.getShardName());
+ LOG.debug("Tx {} Readying transaction for shard {} chain {}", identifier,
+ txFutureCallback.getShardName(), transactionChainId);
- cohortPathFutures.add(transactionContext.readyTransaction());
+ Future<ActorSelection> future = txFutureCallback.enqueueFutureOperation(new FutureOperation<ActorSelection>() {
+ @Override
+ public Future<ActorSelection> invoke(TransactionContext transactionContext) {
+ return transactionContext.readyTransaction();
+ }
+ });
+
+ cohortFutures.add(future);
}
- return new ThreePhaseCommitCohortProxy(actorContext, cohortPathFutures,
+ onTransactionReady(cohortFutures);
+
+ return new ThreePhaseCommitCohortProxy(actorContext, cohortFutures,
identifier.toString());
}
+ /**
+ * Method for derived classes to be notified when the transaction has been readied.
+ *
+ * @param cohortFutures the cohort Futures for each shard transaction.
+ */
+ protected void onTransactionReady(List<Future<ActorSelection>> cohortFutures) {
+ }
+
+ /**
+ * Method called to send a CreateTransaction message to a shard.
+ *
+ * @param shard the shard actor to send to
+ * @param serializedCreateMessage the serialized message to send
+ * @return the response Future
+ */
+ protected Future<Object> sendCreateTransaction(ActorSelection shard,
+ Object serializedCreateMessage) {
+ return actorContext.executeOperationAsync(shard, serializedCreateMessage);
+ }
+
@Override
public Object getIdentifier() {
return this.identifier;
@Override
public void close() {
- for(TransactionContext transactionContext : remoteTransactionPaths.values()) {
- transactionContext.closeTransaction();
+ for (TransactionFutureCallback txFutureCallback : txFutureCallbackMap.values()) {
+ txFutureCallback.enqueueModifyOperation(new TransactionOperation() {
+ @Override
+ public void invoke(TransactionContext transactionContext) {
+ transactionContext.closeTransaction();
+ }
+ });
}
- remoteTransactionPaths.clear();
+ txFutureCallbackMap.clear();
if(transactionType == TransactionType.READ_ONLY) {
remoteTransactionActors.clear();
}
}
- private TransactionContext transactionContext(YangInstanceIdentifier path){
+ private String shardNameFromIdentifier(YangInstanceIdentifier path){
+ return ShardStrategyFactory.getStrategy(path).findShard(path);
+ }
+
+ private TransactionFutureCallback getOrCreateTxFutureCallback(YangInstanceIdentifier path) {
String shardName = shardNameFromIdentifier(path);
- return remoteTransactionPaths.get(shardName);
+ TransactionFutureCallback txFutureCallback = txFutureCallbackMap.get(shardName);
+ if(txFutureCallback == null) {
+ Future<ActorSelection> findPrimaryFuture = actorContext.findPrimaryShardAsync(shardName);
+
+ final TransactionFutureCallback newTxFutureCallback =
+ new TransactionFutureCallback(shardName);
+
+ txFutureCallback = newTxFutureCallback;
+ txFutureCallbackMap.put(shardName, txFutureCallback);
+
+ findPrimaryFuture.onComplete(new OnComplete<ActorSelection>() {
+ @Override
+ public void onComplete(Throwable failure, ActorSelection primaryShard) {
+ if(failure != null) {
+ newTxFutureCallback.onComplete(failure, null);
+ } else {
+ newTxFutureCallback.setPrimaryShard(primaryShard);
+ }
+ }
+ }, actorContext.getActorSystem().dispatcher());
+ }
+
+ return txFutureCallback;
}
- private String shardNameFromIdentifier(YangInstanceIdentifier path){
- return ShardStrategyFactory.getStrategy(path).findShard(path);
+ public String getTransactionChainId() {
+ return transactionChainId;
+ }
+
+ protected ActorContext getActorContext() {
+ return actorContext;
+ }
+
+ /**
+ * Interfaces for transaction operations to be invoked later.
+ */
+ private static interface TransactionOperation {
+ void invoke(TransactionContext transactionContext);
+ }
+
+ /**
+ * This interface returns a Guava Future
+ */
+ private static interface ReadOperation<T> {
+ CheckedFuture<T, ReadFailedException> invoke(TransactionContext transactionContext);
}
- private void createTransactionIfMissing(ActorContext actorContext, YangInstanceIdentifier path) {
- String shardName = ShardStrategyFactory.getStrategy(path).findShard(path);
+ /**
+ * This interface returns a Scala Future
+ */
+ private static interface FutureOperation<T> {
+ Future<T> invoke(TransactionContext transactionContext);
+ }
+
+ /**
+ * Implements a Future OnComplete callback for a CreateTransaction message. This class handles
+ * retries, up to a limit, if the shard doesn't have a leader yet. This is done by scheduling a
+ * retry task after a short delay.
+ * <p>
+ * The end result from a completed CreateTransaction message is a TransactionContext that is
+ * used to perform transaction operations. Transaction operations that occur before the
+ * CreateTransaction completes are cache and executed once the CreateTransaction completes,
+ * successfully or not.
+ */
+ private class TransactionFutureCallback extends OnComplete<Object> {
+
+ /**
+ * The list of transaction operations to execute once the CreateTransaction completes.
+ */
+ @GuardedBy("txOperationsOnComplete")
+ private final List<TransactionOperation> txOperationsOnComplete = Lists.newArrayList();
+
+ /**
+ * The TransactionContext resulting from the CreateTransaction reply.
+ */
+ private volatile TransactionContext transactionContext;
- TransactionContext transactionContext =
- remoteTransactionPaths.get(shardName);
+ /**
+ * The target primary shard.
+ */
+ private volatile ActorSelection primaryShard;
- if(transactionContext != null){
- // A transaction already exists with that shard
- return;
+ private volatile int createTxTries = (int) (actorContext.getDatastoreContext().
+ getShardLeaderElectionTimeout().duration().toMillis() /
+ CREATE_TX_TRY_INTERVAL.toMillis());
+
+ private final String shardName;
+
+ TransactionFutureCallback(String shardName) {
+ this.shardName = shardName;
}
- try {
- Object response = actorContext.executeShardOperation(shardName,
- new CreateTransaction(identifier.toString(),this.transactionType.ordinal() ).toSerializable(),
- ActorContext.ASK_DURATION);
- if (response.getClass().equals(CreateTransactionReply.SERIALIZABLE_CLASS)) {
- CreateTransactionReply reply =
- CreateTransactionReply.fromSerializable(response);
+ String getShardName() {
+ return shardName;
+ }
- String transactionPath = reply.getTransactionPath();
+ TransactionContext getTransactionContext() {
+ return transactionContext;
+ }
- LOG.debug("Tx {} Received transaction path = {}", identifier, transactionPath);
- ActorSelection transactionActor = actorContext.actorSelection(transactionPath);
+ /**
+ * Sets the target primary shard and initiates a CreateTransaction try.
+ */
+ void setPrimaryShard(ActorSelection primaryShard) {
+ LOG.debug("Tx {} Primary shard found - trying create transaction", identifier);
- if(transactionType == TransactionType.READ_ONLY) {
- // Add the actor to the remoteTransactionActors list for access by the
- // cleanup PhantonReference.
- remoteTransactionActors.add(transactionActor);
+ this.primaryShard = primaryShard;
+ tryCreateTransaction();
+ }
- // Write to the memory barrier volatile to publish the above update to the
- // remoteTransactionActors list for thread visibility.
- remoteTransactionActorsMB.set(true);
+ /**
+ * Adds a TransactionOperation to be executed after the CreateTransaction completes.
+ */
+ void addTxOperationOnComplete(TransactionOperation operation) {
+ synchronized(txOperationsOnComplete) {
+ if(transactionContext == null) {
+ LOG.debug("Tx {} Adding operation on complete {}", identifier);
+
+ txOperationsOnComplete.add(operation);
+ } else {
+ operation.invoke(transactionContext);
}
+ }
+ }
+
+
+ <T> Future<T> enqueueFutureOperation(final FutureOperation<T> op) {
+
+ Future<T> future;
+
+ if (transactionContext != null) {
+ future = op.invoke(transactionContext);
+ } else {
+ // The shard Tx hasn't been created yet so add the Tx operation to the Tx Future
+ // callback to be executed after the Tx is created.
+ final Promise<T> promise = akka.dispatch.Futures.promise();
+ addTxOperationOnComplete(new TransactionOperation() {
+ @Override
+ public void invoke(TransactionContext transactionContext) {
+ promise.completeWith(op.invoke(transactionContext));
+ }
+ });
+
+ future = promise.future();
+ }
+
+ return future;
+ }
+
+ <T> CheckedFuture<T, ReadFailedException> enqueueReadOperation(final ReadOperation<T> op) {
+
+ CheckedFuture<T, ReadFailedException> future;
- transactionContext = new TransactionContextImpl(shardName, transactionPath,
- transactionActor, identifier, actorContext, schemaContext);
+ if (transactionContext != null) {
+ future = op.invoke(transactionContext);
+ } else {
+ // The shard Tx hasn't been created yet so add the Tx operation to the Tx Future
+ // callback to be executed after the Tx is created.
+ final SettableFuture<T> proxyFuture = SettableFuture.create();
+ addTxOperationOnComplete(new TransactionOperation() {
+ @Override
+ public void invoke(TransactionContext transactionContext) {
+ Futures.addCallback(op.invoke(transactionContext), new FutureCallback<T>() {
+ @Override
+ public void onSuccess(T data) {
+ proxyFuture.set(data);
+ }
+
+ @Override
+ public void onFailure(Throwable t) {
+ proxyFuture.setException(t);
+ }
+ });
+ }
+ });
+
+ future = MappingCheckedFuture.create(proxyFuture, ReadFailedException.MAPPER);
+ }
+
+ return future;
+ }
+
+ void enqueueModifyOperation(final TransactionOperation op) {
- remoteTransactionPaths.put(shardName, transactionContext);
+ if (transactionContext != null) {
+ op.invoke(transactionContext);
} else {
- throw new IllegalArgumentException(String.format(
- "Invalid reply type {} for CreateTransaction", response.getClass()));
+ // The shard Tx hasn't been created yet so add the Tx operation to the Tx Future
+ // callback to be executed after the Tx is created.
+ addTxOperationOnComplete(op);
+ }
+ }
+
+
+
+
+
+ /**
+ * Performs a CreateTransaction try async.
+ */
+ private void tryCreateTransaction() {
+ Future<Object> createTxFuture = sendCreateTransaction(primaryShard,
+ new CreateTransaction(identifier.toString(),
+ TransactionProxy.this.transactionType.ordinal(),
+ getTransactionChainId()).toSerializable());
+
+ createTxFuture.onComplete(this, actorContext.getActorSystem().dispatcher());
+ }
+
+ @Override
+ public void onComplete(Throwable failure, Object response) {
+ if(failure instanceof NoShardLeaderException) {
+ // There's no leader for the shard yet - schedule and try again, unless we're out
+ // of retries. Note: createTxTries is volatile as it may be written by different
+ // threads however not concurrently, therefore decrementing it non-atomically here
+ // is ok.
+ if(--createTxTries > 0) {
+ LOG.debug("Tx {} Shard {} has no leader yet - scheduling create Tx retry",
+ identifier, shardName);
+
+ actorContext.getActorSystem().scheduler().scheduleOnce(CREATE_TX_TRY_INTERVAL,
+ new Runnable() {
+ @Override
+ public void run() {
+ tryCreateTransaction();
+ }
+ }, actorContext.getActorSystem().dispatcher());
+ return;
+ }
+ }
+
+ // Create the TransactionContext from the response or failure and execute delayed
+ // TransactionOperations. This entire section is done atomically (ie synchronized) with
+ // respect to #addTxOperationOnComplete to handle timing issues and ensure no
+ // TransactionOperation is missed and that they are processed in the order they occurred.
+ synchronized(txOperationsOnComplete) {
+ // Store the new TransactionContext locally until we've completed invoking the
+ // TransactionOperations. This avoids thread timing issues which could cause
+ // out-of-order TransactionOperations. Eg, on a modification operation, if the
+ // TransactionContext is non-null, then we directly call the TransactionContext.
+ // However, at the same time, the code may be executing the cached
+ // TransactionOperations. So to avoid thus timing, we don't publish the
+ // TransactionContext until after we've executed all cached TransactionOperations.
+ TransactionContext localTransactionContext;
+ if(failure != null) {
+ LOG.debug("Tx {} Creating NoOpTransaction because of error: {}", identifier,
+ failure.getMessage());
+
+ localTransactionContext = new NoOpTransactionContext(failure, identifier);
+ } else if (response.getClass().equals(CreateTransactionReply.SERIALIZABLE_CLASS)) {
+ localTransactionContext = createValidTransactionContext(
+ CreateTransactionReply.fromSerializable(response));
+ } else {
+ IllegalArgumentException exception = new IllegalArgumentException(String.format(
+ "Invalid reply type %s for CreateTransaction", response.getClass()));
+
+ localTransactionContext = new NoOpTransactionContext(exception, identifier);
+ }
+
+ for(TransactionOperation oper: txOperationsOnComplete) {
+ oper.invoke(localTransactionContext);
+ }
+
+ txOperationsOnComplete.clear();
+
+ // We're done invoking the TransactionOperations so we can now publish the
+ // TransactionContext.
+ transactionContext = localTransactionContext;
+ }
+ }
+
+ private TransactionContext createValidTransactionContext(CreateTransactionReply reply) {
+ String transactionPath = reply.getTransactionPath();
+
+ LOG.debug("Tx {} Received transaction actor path {}", identifier, transactionPath);
+
+ ActorSelection transactionActor = actorContext.actorSelection(transactionPath);
+
+ if (transactionType == TransactionType.READ_ONLY) {
+ // Add the actor to the remoteTransactionActors list for access by the
+ // cleanup PhantonReference.
+ remoteTransactionActors.add(transactionActor);
+
+ // Write to the memory barrier volatile to publish the above update to the
+ // remoteTransactionActors list for thread visibility.
+ remoteTransactionActorsMB.set(true);
}
- } catch(Exception e){
- LOG.debug("Tx {} Creating NoOpTransaction because of : {}", identifier, e.getMessage());
- remoteTransactionPaths.put(shardName, new NoOpTransactionContext(shardName, e, identifier));
+
+ // TxActor is always created where the leader of the shard is.
+ // Check if TxActor is created in the same node
+ boolean isTxActorLocal = actorContext.isPathLocal(transactionPath);
+
+ return new TransactionContextImpl(transactionPath, transactionActor, identifier,
+ actorContext, schemaContext, isTxActorLocal, reply.getVersion());
}
}
private interface TransactionContext {
- String getShardName();
-
void closeTransaction();
- Future<ActorPath> readyTransaction();
+ Future<ActorSelection> readyTransaction();
void writeData(YangInstanceIdentifier path, NormalizedNode<?, ?> data);
private static abstract class AbstractTransactionContext implements TransactionContext {
protected final TransactionIdentifier identifier;
- protected final String shardName;
protected final List<Future<Object>> recordedOperationFutures = Lists.newArrayList();
- AbstractTransactionContext(String shardName, TransactionIdentifier identifier) {
- this.shardName = shardName;
+ AbstractTransactionContext(TransactionIdentifier identifier) {
this.identifier = identifier;
}
- @Override
- public String getShardName() {
- return shardName;
- }
-
@Override
public List<Future<Object>> getRecordedOperationFutures() {
return recordedOperationFutures;
private final ActorContext actorContext;
private final SchemaContext schemaContext;
- private final String actorPath;
+ private final String transactionPath;
private final ActorSelection actor;
-
- private TransactionContextImpl(String shardName, String actorPath,
- ActorSelection actor, TransactionIdentifier identifier, ActorContext actorContext,
- SchemaContext schemaContext) {
- super(shardName, identifier);
- this.actorPath = actorPath;
+ private final boolean isTxActorLocal;
+ private final int remoteTransactionVersion;
+
+ private TransactionContextImpl(String transactionPath, ActorSelection actor, TransactionIdentifier identifier,
+ ActorContext actorContext, SchemaContext schemaContext,
+ boolean isTxActorLocal, int remoteTransactionVersion) {
+ super(identifier);
+ this.transactionPath = transactionPath;
this.actor = actor;
this.actorContext = actorContext;
this.schemaContext = schemaContext;
+ this.isTxActorLocal = isTxActorLocal;
+ this.remoteTransactionVersion = remoteTransactionVersion;
}
private ActorSelection getActor() {
return actor;
}
- private String getResolvedCohortPath(String cohortPath) {
- return actorContext.resolvePath(actorPath, cohortPath);
+ private Future<Object> executeOperationAsync(SerializableMessage msg) {
+ return actorContext.executeOperationAsync(getActor(), isTxActorLocal ? msg : msg.toSerializable());
}
@Override
public void closeTransaction() {
LOG.debug("Tx {} closeTransaction called", identifier);
- actorContext.sendRemoteOperationAsync(getActor(), new CloseTransaction().toSerializable());
+
+ actorContext.sendOperationAsync(getActor(), new CloseTransaction().toSerializable());
}
@Override
- public Future<ActorPath> readyTransaction() {
+ public Future<ActorSelection> readyTransaction() {
LOG.debug("Tx {} readyTransaction called with {} previous recorded operations pending",
identifier, recordedOperationFutures.size());
// Send the ReadyTransaction message to the Tx actor.
- final Future<Object> replyFuture = actorContext.executeRemoteOperationAsync(getActor(),
- new ReadyTransaction().toSerializable(), ActorContext.ASK_DURATION);
+ final Future<Object> replyFuture = executeOperationAsync(new ReadyTransaction());
// Combine all the previously recorded put/merge/delete operation reply Futures and the
// ReadyTransactionReply Future into one Future. If any one fails then the combined
// Transform the combined Future into a Future that returns the cohort actor path from
// the ReadyTransactionReply. That's the end result of the ready operation.
- return combinedFutures.transform(new AbstractFunction1<Iterable<Object>, ActorPath>() {
+ return combinedFutures.transform(new Mapper<Iterable<Object>, ActorSelection>() {
@Override
- public ActorPath apply(Iterable<Object> notUsed) {
-
+ public ActorSelection checkedApply(Iterable<Object> notUsed) {
LOG.debug("Tx {} readyTransaction: pending recorded operations succeeded",
identifier);
// Note the Future get call here won't block as it's complete.
Object serializedReadyReply = replyFuture.value().get().get();
- if(serializedReadyReply.getClass().equals(
- ReadyTransactionReply.SERIALIZABLE_CLASS)) {
- ReadyTransactionReply reply = ReadyTransactionReply.fromSerializable(
- actorContext.getActorSystem(), serializedReadyReply);
-
- String resolvedCohortPath = getResolvedCohortPath(
- reply.getCohortPath().toString());
+ if (serializedReadyReply instanceof ReadyTransactionReply) {
+ return actorContext.actorSelection(((ReadyTransactionReply)serializedReadyReply).getCohortPath());
+
+ } else if(serializedReadyReply.getClass().equals(ReadyTransactionReply.SERIALIZABLE_CLASS)) {
+ ReadyTransactionReply reply = ReadyTransactionReply.fromSerializable(serializedReadyReply);
+ String cohortPath = reply.getCohortPath();
+
+ // In Helium we used to return the local path of the actor which represented
+ // a remote ThreePhaseCommitCohort. The local path would then be converted to
+ // a remote path using this resolvePath method. To maintain compatibility with
+ // a Helium node we need to continue to do this conversion.
+ // At some point in the future when upgrades from Helium are not supported
+ // we could remove this code to resolvePath and just use the cohortPath as the
+ // resolved cohortPath
+ if(TransactionContextImpl.this.remoteTransactionVersion < CreateTransaction.HELIUM_1_VERSION) {
+ cohortPath = actorContext.resolvePath(transactionPath, cohortPath);
+ }
- LOG.debug("Tx {} readyTransaction: resolved cohort path {}",
- identifier, resolvedCohortPath);
+ return actorContext.actorSelection(cohortPath);
- return actorContext.actorFor(resolvedCohortPath);
} else {
// Throwing an exception here will fail the Future.
-
throw new IllegalArgumentException(String.format("Invalid reply type {}",
serializedReadyReply.getClass()));
}
@Override
public void deleteData(YangInstanceIdentifier path) {
LOG.debug("Tx {} deleteData called path = {}", identifier, path);
- recordedOperationFutures.add(actorContext.executeRemoteOperationAsync(getActor(),
- new DeleteData(path).toSerializable(), ActorContext.ASK_DURATION ));
+
+ recordedOperationFutures.add(executeOperationAsync(new DeleteData(path)));
}
@Override
public void mergeData(YangInstanceIdentifier path, NormalizedNode<?, ?> data) {
LOG.debug("Tx {} mergeData called path = {}", identifier, path);
- recordedOperationFutures.add(actorContext.executeRemoteOperationAsync(getActor(),
- new MergeData(path, data, schemaContext).toSerializable(),
- ActorContext.ASK_DURATION));
+
+ recordedOperationFutures.add(executeOperationAsync(new MergeData(path, data, schemaContext)));
}
@Override
public void writeData(YangInstanceIdentifier path, NormalizedNode<?, ?> data) {
LOG.debug("Tx {} writeData called path = {}", identifier, path);
- recordedOperationFutures.add(actorContext.executeRemoteOperationAsync(getActor(),
- new WriteData(path, data, schemaContext).toSerializable(),
- ActorContext.ASK_DURATION));
+
+ recordedOperationFutures.add(executeOperationAsync(new WriteData(path, data, schemaContext)));
}
@Override
Future<Iterable<Object>> combinedFutures = akka.dispatch.Futures.sequence(
Lists.newArrayList(recordedOperationFutures),
actorContext.getActorSystem().dispatcher());
+
OnComplete<Iterable<Object>> onComplete = new OnComplete<Iterable<Object>>() {
@Override
public void onComplete(Throwable failure, Iterable<Object> notUsed)
if(failure != null) {
LOG.debug("Tx {} readData: a recorded operation failed: {}",
identifier, failure);
-
returnFuture.setException(new ReadFailedException(
"The read could not be performed because a previous put, merge,"
+ "or delete operation failed", failure));
public void onComplete(Throwable failure, Object readResponse) throws Throwable {
if(failure != null) {
LOG.debug("Tx {} read operation failed: {}", identifier, failure);
-
returnFuture.setException(new ReadFailedException(
"Error reading data for path " + path, failure));
} else {
LOG.debug("Tx {} read operation succeeded", identifier, failure);
- if (readResponse.getClass().equals(ReadDataReply.SERIALIZABLE_CLASS)) {
- ReadDataReply reply = ReadDataReply.fromSerializable(schemaContext,
- path, readResponse);
- if (reply.getNormalizedNode() == null) {
- returnFuture.set(Optional.<NormalizedNode<?, ?>>absent());
- } else {
- returnFuture.set(Optional.<NormalizedNode<?, ?>>of(
- reply.getNormalizedNode()));
- }
+ if (readResponse instanceof ReadDataReply) {
+ ReadDataReply reply = (ReadDataReply) readResponse;
+ returnFuture.set(Optional.<NormalizedNode<?, ?>>fromNullable(reply.getNormalizedNode()));
+
+ } else if (readResponse.getClass().equals(ReadDataReply.SERIALIZABLE_CLASS)) {
+ ReadDataReply reply = ReadDataReply.fromSerializable(schemaContext, path, readResponse);
+ returnFuture.set(Optional.<NormalizedNode<?, ?>>fromNullable(reply.getNormalizedNode()));
+
} else {
returnFuture.setException(new ReadFailedException(
- "Invalid response reading data for path " + path));
+ "Invalid response reading data for path " + path));
}
}
}
};
- Future<Object> readFuture = actorContext.executeRemoteOperationAsync(getActor(),
- new ReadData(path).toSerializable(), ActorContext.ASK_DURATION);
+ Future<Object> readFuture = executeOperationAsync(new ReadData(path));
+
readFuture.onComplete(onComplete, actorContext.getActorSystem().dispatcher());
}
if(failure != null) {
LOG.debug("Tx {} dataExists: a recorded operation failed: {}",
identifier, failure);
-
returnFuture.setException(new ReadFailedException(
"The data exists could not be performed because a previous "
+ "put, merge, or delete operation failed", failure));
public void onComplete(Throwable failure, Object response) throws Throwable {
if(failure != null) {
LOG.debug("Tx {} dataExists operation failed: {}", identifier, failure);
-
returnFuture.setException(new ReadFailedException(
"Error checking data exists for path " + path, failure));
} else {
LOG.debug("Tx {} dataExists operation succeeded", identifier, failure);
- if (response.getClass().equals(DataExistsReply.SERIALIZABLE_CLASS)) {
- returnFuture.set(Boolean.valueOf(DataExistsReply.
- fromSerializable(response).exists()));
+ if (response instanceof DataExistsReply) {
+ returnFuture.set(Boolean.valueOf(((DataExistsReply) response).exists()));
+
+ } else if (response.getClass().equals(DataExistsReply.SERIALIZABLE_CLASS)) {
+ returnFuture.set(Boolean.valueOf(DataExistsReply.fromSerializable(response).exists()));
+
} else {
returnFuture.setException(new ReadFailedException(
"Invalid response checking exists for path " + path));
}
};
- Future<Object> future = actorContext.executeRemoteOperationAsync(getActor(),
- new DataExists(path).toSerializable(), ActorContext.ASK_DURATION);
+ Future<Object> future = executeOperationAsync(new DataExists(path));
+
future.onComplete(onComplete, actorContext.getActorSystem().dispatcher());
}
}
private final Logger LOG = LoggerFactory.getLogger(NoOpTransactionContext.class);
- private final Exception failure;
+ private final Throwable failure;
- public NoOpTransactionContext(String shardName, Exception failure,
- TransactionIdentifier identifier){
- super(shardName, identifier);
+ public NoOpTransactionContext(Throwable failure, TransactionIdentifier identifier){
+ super(identifier);
this.failure = failure;
}
}
@Override
- public Future<ActorPath> readyTransaction() {
+ public Future<ActorSelection> readyTransaction() {
LOG.debug("Tx {} readyTransaction called", identifier);
return akka.dispatch.Futures.failed(failure);
}
@Override
public CheckedFuture<Optional<NormalizedNode<?, ?>>, ReadFailedException> readData(
- YangInstanceIdentifier path) {
+ YangInstanceIdentifier path) {
LOG.debug("Tx {} readData called path = {}", identifier, path);
return Futures.immediateFailedCheckedFuture(new ReadFailedException(
"Error reading data for path " + path, failure));
@Override
public CheckedFuture<Boolean, ReadFailedException> dataExists(
- YangInstanceIdentifier path) {
+ YangInstanceIdentifier path) {
LOG.debug("Tx {} dataExists called path = {}", identifier, path);
return Futures.immediateFailedCheckedFuture(new ReadFailedException(
"Error checking exists for path " + path, failure));