Java ComponentCommon.get_parallelism_hint Exemples

Exemple #1

Fichier : DefaultTopologyAssignContext.java Projet : zcoway/learn_jstorm

  private int computeWorkerNum() {
    Integer settingNum = JStormUtils.parseInt(stormConf.get(Config.TOPOLOGY_WORKERS));

    int hintSum = 0;

    Map<String, Object> components = ThriftTopologyUtils.getComponents(sysTopology);
    for (Entry<String, Object> entry : components.entrySet()) {
      String componentName = entry.getKey();
      Object component = entry.getValue();

      ComponentCommon common = null;
      if (component instanceof Bolt) {
        common = ((Bolt) component).get_common();
      }
      if (component instanceof SpoutSpec) {
        common = ((SpoutSpec) component).get_common();
      }
      if (component instanceof StateSpoutSpec) {
        common = ((StateSpoutSpec) component).get_common();
      }

      int hint = common.get_parallelism_hint();
      hintSum += hint;
    }

    if (settingNum == null) {
      return hintSum;
    } else {
      return Math.min(settingNum, hintSum);
    }
  }

Exemple #2

Fichier : FlinkTopology.java Projet : wangyangjun/flink

  /** Creates a Flink program that uses the specified spouts and bolts. */
  private void translateTopology() {

    unprocessdInputsPerBolt.clear();
    outputStreams.clear();
    declarers.clear();
    availableInputs.clear();

    // Storm defaults to parallelism 1
    env.setParallelism(1);

    /* Translation of topology */

    for (final Entry<String, IRichSpout> spout : spouts.entrySet()) {
      final String spoutId = spout.getKey();
      final IRichSpout userSpout = spout.getValue();

      final FlinkOutputFieldsDeclarer declarer = new FlinkOutputFieldsDeclarer();
      userSpout.declareOutputFields(declarer);
      final HashMap<String, Fields> sourceStreams = declarer.outputStreams;
      this.outputStreams.put(spoutId, sourceStreams);
      declarers.put(spoutId, declarer);

      final HashMap<String, DataStream<Tuple>> outputStreams =
          new HashMap<String, DataStream<Tuple>>();
      final DataStreamSource<?> source;

      if (sourceStreams.size() == 1) {
        final SpoutWrapper<Tuple> spoutWrapperSingleOutput =
            new SpoutWrapper<Tuple>(userSpout, spoutId, null, null);
        spoutWrapperSingleOutput.setStormTopology(stormTopology);

        final String outputStreamId = (String) sourceStreams.keySet().toArray()[0];

        DataStreamSource<Tuple> src =
            env.addSource(
                spoutWrapperSingleOutput, spoutId, declarer.getOutputType(outputStreamId));

        outputStreams.put(outputStreamId, src);
        source = src;
      } else {
        final SpoutWrapper<SplitStreamType<Tuple>> spoutWrapperMultipleOutputs =
            new SpoutWrapper<SplitStreamType<Tuple>>(userSpout, spoutId, null, null);
        spoutWrapperMultipleOutputs.setStormTopology(stormTopology);

        @SuppressWarnings({"unchecked", "rawtypes"})
        DataStreamSource<SplitStreamType<Tuple>> multiSource =
            env.addSource(
                spoutWrapperMultipleOutputs,
                spoutId,
                (TypeInformation) TypeExtractor.getForClass(SplitStreamType.class));

        SplitStream<SplitStreamType<Tuple>> splitSource =
            multiSource.split(new StormStreamSelector<Tuple>());
        for (String streamId : sourceStreams.keySet()) {
          SingleOutputStreamOperator<Tuple, ?> outStream =
              splitSource.select(streamId).map(new SplitStreamMapper<Tuple>());
          outStream.getTransformation().setOutputType(declarer.getOutputType(streamId));
          outputStreams.put(streamId, outStream);
        }
        source = multiSource;
      }
      availableInputs.put(spoutId, outputStreams);

      final ComponentCommon common = stormTopology.get_spouts().get(spoutId).get_common();
      if (common.is_set_parallelism_hint()) {
        int dop = common.get_parallelism_hint();
        source.setParallelism(dop);
      } else {
        common.set_parallelism_hint(1);
      }
    }

    /**
     * 1. Connect all spout streams with bolts streams 2. Then proceed with the bolts stream already
     * connected
     *
     * <p>Because we do not know the order in which an iterator steps over a set, we might process a
     * consumer before its producer ->thus, we might need to repeat multiple times
     */
    boolean makeProgress = true;
    while (bolts.size() > 0) {
      if (!makeProgress) {
        StringBuilder strBld = new StringBuilder();
        strBld.append("Unable to build Topology. Could not connect the following bolts:");
        for (String boltId : bolts.keySet()) {
          strBld.append("\n  ");
          strBld.append(boltId);
          strBld.append(": missing input streams [");
          for (Entry<GlobalStreamId, Grouping> streams : unprocessdInputsPerBolt.get(boltId)) {
            strBld.append("'");
            strBld.append(streams.getKey().get_streamId());
            strBld.append("' from '");
            strBld.append(streams.getKey().get_componentId());
            strBld.append("'; ");
          }
          strBld.append("]");
        }

        throw new RuntimeException(strBld.toString());
      }
      makeProgress = false;

      final Iterator<Entry<String, IRichBolt>> boltsIterator = bolts.entrySet().iterator();
      while (boltsIterator.hasNext()) {

        final Entry<String, IRichBolt> bolt = boltsIterator.next();
        final String boltId = bolt.getKey();
        final IRichBolt userBolt = copyObject(bolt.getValue());

        final ComponentCommon common = stormTopology.get_bolts().get(boltId).get_common();

        Set<Entry<GlobalStreamId, Grouping>> unprocessedBoltInputs =
            unprocessdInputsPerBolt.get(boltId);
        if (unprocessedBoltInputs == null) {
          unprocessedBoltInputs = new HashSet<>();
          unprocessedBoltInputs.addAll(common.get_inputs().entrySet());
          unprocessdInputsPerBolt.put(boltId, unprocessedBoltInputs);
        }

        // check if all inputs are available
        final int numberOfInputs = unprocessedBoltInputs.size();
        int inputsAvailable = 0;
        for (Entry<GlobalStreamId, Grouping> entry : unprocessedBoltInputs) {
          final String producerId = entry.getKey().get_componentId();
          final String streamId = entry.getKey().get_streamId();
          final HashMap<String, DataStream<Tuple>> streams = availableInputs.get(producerId);
          if (streams != null && streams.get(streamId) != null) {
            inputsAvailable++;
          }
        }

        if (inputsAvailable != numberOfInputs) {
          // traverse other bolts first until inputs are available
          continue;
        } else {
          makeProgress = true;
          boltsIterator.remove();
        }

        final Map<GlobalStreamId, DataStream<Tuple>> inputStreams = new HashMap<>(numberOfInputs);

        for (Entry<GlobalStreamId, Grouping> input : unprocessedBoltInputs) {
          final GlobalStreamId streamId = input.getKey();
          final Grouping grouping = input.getValue();

          final String producerId = streamId.get_componentId();

          final Map<String, DataStream<Tuple>> producer = availableInputs.get(producerId);

          inputStreams.put(streamId, processInput(boltId, userBolt, streamId, grouping, producer));
        }

        final SingleOutputStreamOperator<?, ?> outputStream =
            createOutput(boltId, userBolt, inputStreams);

        if (common.is_set_parallelism_hint()) {
          int dop = common.get_parallelism_hint();
          outputStream.setParallelism(dop);
        } else {
          common.set_parallelism_hint(1);
        }
      }
    }
  }