Examples with KvToByteBufferKeySelector org.apache.beam.runners.flink.translation.wrappers.streaming.KvToByteBufferKeySelector used on opensource projects

Example 1 with KvToByteBufferKeySelector

use of org.apache.beam.runners.flink.translation.wrappers.streaming.KvToByteBufferKeySelector in project beam by apache.

the class FlinkStreamingPortablePipelineTranslator method translateExecutableStage.

private <InputT, OutputT> void translateExecutableStage(String id, RunnerApi.Pipeline pipeline, StreamingTranslationContext context) {
    // TODO: Fail on splittable DoFns.
    // TODO: Special-case single outputs to avoid multiplexing PCollections.
    RunnerApi.Components components = pipeline.getComponents();
    RunnerApi.PTransform transform = components.getTransformsOrThrow(id);
    Map<String, String> outputs = transform.getOutputsMap();
    final RunnerApi.ExecutableStagePayload stagePayload;
    try {
        stagePayload = RunnerApi.ExecutableStagePayload.parseFrom(transform.getSpec().getPayload());
    } catch (IOException e) {
        throw new RuntimeException(e);
    }
    String inputPCollectionId = stagePayload.getInput();
    final TransformedSideInputs transformedSideInputs;
    if (stagePayload.getSideInputsCount() > 0) {
        transformedSideInputs = transformSideInputs(stagePayload, components, context);
    } else {
        transformedSideInputs = new TransformedSideInputs(Collections.emptyMap(), null);
    }
    Map<TupleTag<?>, OutputTag<WindowedValue<?>>> tagsToOutputTags = Maps.newLinkedHashMap();
    Map<TupleTag<?>, Coder<WindowedValue<?>>> tagsToCoders = Maps.newLinkedHashMap();
    // TODO: does it matter which output we designate as "main"
    final TupleTag<OutputT> mainOutputTag = outputs.isEmpty() ? null : new TupleTag(outputs.keySet().iterator().next());
    // associate output tags with ids, output manager uses these Integer ids to serialize state
    BiMap<String, Integer> outputIndexMap = createOutputMap(outputs.keySet());
    Map<String, Coder<WindowedValue<?>>> outputCoders = Maps.newHashMap();
    Map<TupleTag<?>, Integer> tagsToIds = Maps.newHashMap();
    Map<String, TupleTag<?>> collectionIdToTupleTag = Maps.newHashMap();
    // order output names for deterministic mapping
    for (String localOutputName : new TreeMap<>(outputIndexMap).keySet()) {
        String collectionId = outputs.get(localOutputName);
        Coder<WindowedValue<?>> windowCoder = (Coder) instantiateCoder(collectionId, components);
        outputCoders.put(localOutputName, windowCoder);
        TupleTag<?> tupleTag = new TupleTag<>(localOutputName);
        CoderTypeInformation<WindowedValue<?>> typeInformation = new CoderTypeInformation(windowCoder, context.getPipelineOptions());
        tagsToOutputTags.put(tupleTag, new OutputTag<>(localOutputName, typeInformation));
        tagsToCoders.put(tupleTag, windowCoder);
        tagsToIds.put(tupleTag, outputIndexMap.get(localOutputName));
        collectionIdToTupleTag.put(collectionId, tupleTag);
    }
    final SingleOutputStreamOperator<WindowedValue<OutputT>> outputStream;
    DataStream<WindowedValue<InputT>> inputDataStream = context.getDataStreamOrThrow(inputPCollectionId);
    CoderTypeInformation<WindowedValue<OutputT>> outputTypeInformation = !outputs.isEmpty() ? new CoderTypeInformation(outputCoders.get(mainOutputTag.getId()), context.getPipelineOptions()) : null;
    ArrayList<TupleTag<?>> additionalOutputTags = Lists.newArrayList();
    for (TupleTag<?> tupleTag : tagsToCoders.keySet()) {
        if (!mainOutputTag.getId().equals(tupleTag.getId())) {
            additionalOutputTags.add(tupleTag);
        }
    }
    final Coder<WindowedValue<InputT>> windowedInputCoder = instantiateCoder(inputPCollectionId, components);
    final boolean stateful = stagePayload.getUserStatesCount() > 0 || stagePayload.getTimersCount() > 0;
    final boolean hasSdfProcessFn = stagePayload.getComponents().getTransformsMap().values().stream().anyMatch(pTransform -> pTransform.getSpec().getUrn().equals(PTransformTranslation.SPLITTABLE_PROCESS_SIZED_ELEMENTS_AND_RESTRICTIONS_URN));
    Coder keyCoder = null;
    KeySelector<WindowedValue<InputT>, ?> keySelector = null;
    if (stateful || hasSdfProcessFn) {
        // Stateful/SDF stages are only allowed of KV input.
        Coder valueCoder = ((WindowedValue.FullWindowedValueCoder) windowedInputCoder).getValueCoder();
        if (!(valueCoder instanceof KvCoder)) {
            throw new IllegalStateException(String.format(Locale.ENGLISH, "The element coder for stateful DoFn '%s' must be KvCoder but is: %s", inputPCollectionId, valueCoder.getClass().getSimpleName()));
        }
        if (stateful) {
            keyCoder = ((KvCoder) valueCoder).getKeyCoder();
            keySelector = new KvToByteBufferKeySelector(keyCoder, new SerializablePipelineOptions(context.getPipelineOptions()));
        } else {
            // as the key.
            if (!(((KvCoder) valueCoder).getKeyCoder() instanceof KvCoder)) {
                throw new IllegalStateException(String.format(Locale.ENGLISH, "The element coder for splittable DoFn '%s' must be KVCoder(KvCoder, DoubleCoder) but is: %s", inputPCollectionId, valueCoder.getClass().getSimpleName()));
            }
            keyCoder = ((KvCoder) ((KvCoder) valueCoder).getKeyCoder()).getKeyCoder();
            keySelector = new SdfByteBufferKeySelector(keyCoder, new SerializablePipelineOptions(context.getPipelineOptions()));
        }
        inputDataStream = inputDataStream.keyBy(keySelector);
    }
    DoFnOperator.MultiOutputOutputManagerFactory<OutputT> outputManagerFactory = new DoFnOperator.MultiOutputOutputManagerFactory<>(mainOutputTag, tagsToOutputTags, tagsToCoders, tagsToIds, new SerializablePipelineOptions(context.getPipelineOptions()));
    DoFnOperator<InputT, OutputT> doFnOperator = new ExecutableStageDoFnOperator<>(transform.getUniqueName(), windowedInputCoder, Collections.emptyMap(), mainOutputTag, additionalOutputTags, outputManagerFactory, transformedSideInputs.unionTagToView, new ArrayList<>(transformedSideInputs.unionTagToView.values()), getSideInputIdToPCollectionViewMap(stagePayload, components), context.getPipelineOptions(), stagePayload, context.getJobInfo(), FlinkExecutableStageContextFactory.getInstance(), collectionIdToTupleTag, getWindowingStrategy(inputPCollectionId, components), keyCoder, keySelector);
    final String operatorName = generateNameFromStagePayload(stagePayload);
    if (transformedSideInputs.unionTagToView.isEmpty()) {
        outputStream = inputDataStream.transform(operatorName, outputTypeInformation, doFnOperator);
    } else {
        DataStream<RawUnionValue> sideInputStream = transformedSideInputs.unionedSideInputs.broadcast();
        if (stateful || hasSdfProcessFn) {
            // We have to manually construct the two-input transform because we're not
            // allowed to have only one input keyed, normally. Since Flink 1.5.0 it's
            // possible to use the Broadcast State Pattern which provides a more elegant
            // way to process keyed main input with broadcast state, but it's not feasible
            // here because it breaks the DoFnOperator abstraction.
            TwoInputTransformation<WindowedValue<KV<?, InputT>>, RawUnionValue, WindowedValue<OutputT>> rawFlinkTransform = new TwoInputTransformation(inputDataStream.getTransformation(), sideInputStream.getTransformation(), transform.getUniqueName(), doFnOperator, outputTypeInformation, inputDataStream.getParallelism());
            rawFlinkTransform.setStateKeyType(((KeyedStream) inputDataStream).getKeyType());
            rawFlinkTransform.setStateKeySelectors(((KeyedStream) inputDataStream).getKeySelector(), null);
            outputStream = new SingleOutputStreamOperator(inputDataStream.getExecutionEnvironment(), // we have to cheat around the ctor being protected
            rawFlinkTransform) {
            };
        } else {
            outputStream = inputDataStream.connect(sideInputStream).transform(operatorName, outputTypeInformation, doFnOperator);
        }
    }
    // Assign a unique but consistent id to re-map operator state
    outputStream.uid(transform.getUniqueName());
    if (mainOutputTag != null) {
        context.addDataStream(outputs.get(mainOutputTag.getId()), outputStream);
    }
    for (TupleTag<?> tupleTag : additionalOutputTags) {
        context.addDataStream(outputs.get(tupleTag.getId()), outputStream.getSideOutput(tagsToOutputTags.get(tupleTag)));
    }
}