/**
  * Create superstep classes by initiazling from current state in configuration
  *
  * @param conf Configuration
  * @return Superstep classes
  */
 public static SuperstepClasses createAndExtractTypes(ImmutableClassesGiraphConfiguration conf) {
   return new SuperstepClasses(
       conf,
       conf.getComputationClass(),
       conf.getOutgoingMessageClasses(),
       conf.getOutgoingMessageClasses().createCopyForNewSuperstep());
 }
  /**
   * Verify that types of current Computation and MessageCombiner are valid. If types don't match an
   * {@link IllegalStateException} will be thrown.
   *
   * @param checkMatchingMesssageTypes Check that the incoming/outgoing message types match
   */
  public void verifyTypesMatch(boolean checkMatchingMesssageTypes) {
    // In some cases, for example when using Jython, the Computation class may
    // not be set. This is because it is created by a ComputationFactory
    // dynamically and not known ahead of time. In this case there is nothing to
    // verify here so we bail.
    if (COMPUTATION_LANGUAGE.get(conf) == Language.JYTHON) {
      return;
    }

    Class<?>[] computationTypes =
        ReflectionUtils.getTypeArguments(TypesHolder.class, computationClass);
    ReflectionUtils.verifyTypes(
        conf.getVertexIdClass(), computationTypes[0], "Vertex id", computationClass);
    ReflectionUtils.verifyTypes(
        conf.getVertexValueClass(), computationTypes[1], "Vertex value", computationClass);
    ReflectionUtils.verifyTypes(
        conf.getEdgeValueClass(), computationTypes[2], "Edge value", computationClass);

    if (checkMatchingMesssageTypes) {
      ReflectionUtils.verifyTypes(
          incomingMessageClasses.getMessageClass(),
          computationTypes[3],
          "Incoming message type",
          computationClass);
    }

    ReflectionUtils.verifyTypes(
        outgoingMessageClasses.getMessageClass(),
        computationTypes[4],
        "Outgoing message type",
        computationClass);

    outgoingMessageClasses.verifyConsistent(conf);
  }
Beispiel #3
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 /**
  * Constructor.
  *
  * @param service Service worker
  * @param configuration Configuration
  * @param progressable Progressable
  */
 public AbstractEdgeStore(
     CentralizedServiceWorker<I, V, E> service,
     ImmutableClassesGiraphConfiguration<I, V, E> configuration,
     Progressable progressable) {
   this.service = service;
   this.configuration = configuration;
   this.progressable = progressable;
   transientEdges =
       new MapMaker()
           .concurrencyLevel(configuration.getNettyServerExecutionConcurrency())
           .makeMap();
   reuseEdgeObjects = configuration.reuseEdgeObjects();
   useInputOutEdges = configuration.useInputOutEdges();
 }
Beispiel #4
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 /**
  * Convert the input edges to the {@link OutEdges} data structure used for computation (if
  * different).
  *
  * @param inputEdges Input edges
  * @return Compute edges
  */
 private OutEdges<I, E> convertInputToComputeEdges(OutEdges<I, E> inputEdges) {
   if (!useInputOutEdges) {
     return inputEdges;
   } else {
     return configuration.createAndInitializeOutEdges(inputEdges);
   }
 }
Beispiel #5
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  @Override
  public void moveEdgesToVertices() {
    final boolean createSourceVertex = configuration.getCreateSourceVertex();
    if (transientEdges.isEmpty()) {
      if (LOG.isInfoEnabled()) {
        LOG.info("moveEdgesToVertices: No edges to move");
      }
      return;
    }

    if (LOG.isInfoEnabled()) {
      LOG.info("moveEdgesToVertices: Moving incoming edges to vertices.");
    }

    final BlockingQueue<Integer> partitionIdQueue = new ArrayBlockingQueue<>(transientEdges.size());
    partitionIdQueue.addAll(transientEdges.keySet());
    int numThreads = configuration.getNumInputSplitsThreads();

    CallableFactory<Void> callableFactory =
        new CallableFactory<Void>() {
          @Override
          public Callable<Void> newCallable(int callableId) {
            return new Callable<Void>() {
              @Override
              public Void call() throws Exception {
                Integer partitionId;
                I representativeVertexId = configuration.createVertexId();
                while ((partitionId = partitionIdQueue.poll()) != null) {
                  Partition<I, V, E> partition =
                      service.getPartitionStore().getOrCreatePartition(partitionId);
                  Map<K, OutEdges<I, E>> partitionEdges = transientEdges.remove(partitionId);
                  Iterator<Et> iterator = getPartitionEdgesIterator(partitionEdges);
                  // process all vertices in given partition
                  while (iterator.hasNext()) {
                    Et entry = iterator.next();
                    I vertexId = getVertexId(entry, representativeVertexId);
                    OutEdges<I, E> outEdges =
                        convertInputToComputeEdges(removePartitionEdges(entry, partitionEdges));
                    Vertex<I, V, E> vertex = partition.getVertex(vertexId);
                    // If the source vertex doesn't exist, create it. Otherwise,
                    // just set the edges.
                    if (vertex == null) {
                      if (createSourceVertex) {
                        // createVertex only if it is allowed by configuration
                        vertex = configuration.createVertex();
                        vertex.initialize(
                            createVertexId(entry), configuration.createVertexValue(), outEdges);
                        partition.putVertex(vertex);
                      }
                    } else {
                      // A vertex may exist with or without edges initially
                      // and optimize the case of no initial edges
                      if (vertex.getNumEdges() == 0) {
                        vertex.setEdges(outEdges);
                      } else {
                        for (Edge<I, E> edge : outEdges) {
                          vertex.addEdge(edge);
                        }
                      }
                      // Some Partition implementations (e.g. ByteArrayPartition)
                      // require us to put back the vertex after modifying it.
                      partition.saveVertex(vertex);
                    }
                  }
                  // Some PartitionStore implementations
                  // (e.g. DiskBackedPartitionStore) require us to put back the
                  // partition after modifying it.
                  service.getPartitionStore().putPartition(partition);
                }
                return null;
              }
            };
          }
        };
    ProgressableUtils.getResultsWithNCallables(
        callableFactory, numThreads, "move-edges-%d", progressable);

    // remove all entries
    transientEdges.clear();

    if (LOG.isInfoEnabled()) {
      LOG.info("moveEdgesToVertices: Finished moving incoming edges to " + "vertices.");
    }
  }
 /**
  * Factory method to create a new wrapper over the existing out-edges.
  *
  * @param edges Current out-edges
  * @param conf Configuration
  * @param <I> Vertex id
  * @param <E> Edge value
  * @return The wrapped edges
  */
 public static <I extends WritableComparable, E extends Writable> MutableEdgesWrapper<I, E> wrap(
     OutEdges<I, E> edges, ImmutableClassesGiraphConfiguration<I, ?, E, ?> conf) {
   MutableEdgesWrapper<I, E> wrapper =
       new MutableEdgesWrapper<I, E>(edges, conf.createAndInitializeOutEdges(edges.size()));
   return wrapper;
 }