聊聊flink的SpoutWrapper

/**
 * A {@link SpoutWrapper} wraps an {@link IRichSpout} in order to execute it within a Flink Streaming program. It
 * takes the spout's output tuples and transforms them into Flink tuples of type {@code OUT} (see
 * {@link SpoutCollector} for supported types).<br>
 * <br>
 * Per default, {@link SpoutWrapper} calls the wrapped spout's {@link IRichSpout#nextTuple() nextTuple()} method in
 * an infinite loop.<br>
 * Alternatively, {@link SpoutWrapper} can call {@link IRichSpout#nextTuple() nextTuple()} for a finite number of
 * times and terminate automatically afterwards (for finite input streams). The number of {@code nextTuple()} calls can
 * be specified as a certain number of invocations or can be undefined. In the undefined case, {@link SpoutWrapper}
 * terminates if no record was emitted to the output collector for the first time during a call to
 * {@link IRichSpout#nextTuple() nextTuple()}.<br>
 * If the given spout implements {@link FiniteSpout} interface and {@link #numberOfInvocations} is not provided or
 * is {@code null}, {@link SpoutWrapper} calls {@link IRichSpout#nextTuple() nextTuple()} method until
 * {@link FiniteSpout#reachedEnd()} returns true.
 */
public final class SpoutWrapper<OUT> extends RichParallelSourceFunction<OUT> implements StoppableFunction {
    //......
​
    /** The number of {@link IRichSpout#nextTuple()} calls. */
    private Integer numberOfInvocations; // do not use int -> null indicates an infinite loop
​
    /**
     * Instantiates a new {@link SpoutWrapper} that calls the {@link IRichSpout#nextTuple() nextTuple()} method of
     * the given {@link IRichSpout spout} a finite number of times. The output type will be one of {@link Tuple0} to
     * {@link Tuple25} depending on the spout's declared number of attributes.
     *
     * @param spout
     *            The {@link IRichSpout spout} to be used.
     * @param numberOfInvocations
     *            The number of calls to {@link IRichSpout#nextTuple()}. If value is negative, {@link SpoutWrapper}
     *            terminates if no tuple was emitted for the first time. If value is {@code null}, finite invocation is
     *            disabled.
     * @throws IllegalArgumentException
     *             If the number of declared output attributes is not with range [0;25].
     */
    public SpoutWrapper(final IRichSpout spout, final Integer numberOfInvocations)
            throws IllegalArgumentException {
        this(spout, (Collection<String>) null, numberOfInvocations);
    }
​
    /**
     * Instantiates a new {@link SpoutWrapper} that calls the {@link IRichSpout#nextTuple() nextTuple()} method of
     * the given {@link IRichSpout spout} in an infinite loop. The output type will be one of {@link Tuple0} to
     * {@link Tuple25} depending on the spout's declared number of attributes.
     *
     * @param spout
     *            The {@link IRichSpout spout} to be used.
     * @throws IllegalArgumentException
     *             If the number of declared output attributes is not with range [0;25].
     */
    public SpoutWrapper(final IRichSpout spout) throws IllegalArgumentException {
        this(spout, (Collection<String>) null, null);
    }
​
    @Override
    public final void run(final SourceContext<OUT> ctx) throws Exception {
        final GlobalJobParameters config = super.getRuntimeContext().getExecutionConfig()
                .getGlobalJobParameters();
        StormConfig stormConfig = new StormConfig();
​
        if (config != null) {
            if (config instanceof StormConfig) {
                stormConfig = (StormConfig) config;
            } else {
                stormConfig.putAll(config.toMap());
            }
        }
​
        final TopologyContext stormTopologyContext = WrapperSetupHelper.createTopologyContext(
                (StreamingRuntimeContext) super.getRuntimeContext(), this.spout, this.name,
                this.stormTopology, stormConfig);
​
        SpoutCollector<OUT> collector = new SpoutCollector<OUT>(this.numberOfAttributes,
                stormTopologyContext.getThisTaskId(), ctx);
​
        this.spout.open(stormConfig, stormTopologyContext, new SpoutOutputCollector(collector));
        this.spout.activate();
​
        if (numberOfInvocations == null) {
            if (this.spout instanceof FiniteSpout) {
                final FiniteSpout finiteSpout = (FiniteSpout) this.spout;
​
                while (this.isRunning && !finiteSpout.reachedEnd()) {
                    finiteSpout.nextTuple();
                }
            } else {
                while (this.isRunning) {
                    this.spout.nextTuple();
                }
            }
        } else {
            int counter = this.numberOfInvocations;
            if (counter >= 0) {
                while ((--counter >= 0) && this.isRunning) {
                    this.spout.nextTuple();
                }
            } else {
                do {
                    collector.tupleEmitted = false;
                    this.spout.nextTuple();
                } while (collector.tupleEmitted && this.isRunning);
            }
        }
    }
​
    /**
     * {@inheritDoc}
     *
     * <p>Sets the {@link #isRunning} flag to {@code false}.
     */
    @Override
    public void cancel() {
        this.isRunning = false;
    }
​
    /**
     * {@inheritDoc}
     *
     * <p>Sets the {@link #isRunning} flag to {@code false}.
     */
    @Override
    public void stop() {
        this.isRunning = false;
    }
​
    @Override
    public void close() throws Exception {
        this.spout.close();
    }
}

/**
 * A {@link SpoutCollector} is used by {@link SpoutWrapper} to provided an Storm
 * compatible output collector to the wrapped spout. It transforms the emitted Storm tuples into
 * Flink tuples and emits them via the provide {@link SourceContext} object.
 */
class SpoutCollector<OUT> extends AbstractStormCollector<OUT> implements ISpoutOutputCollector {
​
    /** The Flink source context object. */
    private final SourceContext<OUT> flinkContext;
​
    /**
     * Instantiates a new {@link SpoutCollector} that emits Flink tuples to the given Flink source context. If the
     * number of attributes is specified as zero, any output type is supported. If the number of attributes is between 0
     * to 25, the output type is {@link Tuple0} to {@link Tuple25}, respectively.
     *
     * @param numberOfAttributes
     *            The number of attributes of the emitted tuples.
     * @param taskId
     *            The ID of the producer task (negative value for unknown).
     * @param flinkContext
     *            The Flink source context to be used.
     * @throws UnsupportedOperationException
     *             if the specified number of attributes is greater than 25
     */
    SpoutCollector(final HashMap<String, Integer> numberOfAttributes, final int taskId,
            final SourceContext<OUT> flinkContext) throws UnsupportedOperationException {
        super(numberOfAttributes, taskId);
        assert (flinkContext != null);
        this.flinkContext = flinkContext;
    }
​
    @Override
    protected List<Integer> doEmit(final OUT flinkTuple) {
        this.flinkContext.collect(flinkTuple);
        // TODO
        return null;
    }
​
    @Override
    public void reportError(final Throwable error) {
        // not sure, if Flink can support this
    }
​
    @Override
    public List<Integer> emit(final String streamId, final List<Object> tuple, final Object messageId) {
        return this.tansformAndEmit(streamId, tuple);
    }
​
    @Override
    public void emitDirect(final int taskId, final String streamId, final List<Object> tuple, final Object messageId) {
        throw new UnsupportedOperationException("Direct emit is not supported by Flink");
    }
​
    public long getPendingCount() {
        return 0;
    }
​
}

    /**
     * Transforms a Storm tuple into a Flink tuple of type {@code OUT} and emits this tuple via {@link #doEmit(Object)}
     * to the specified output stream.
     *
     * @param The
     *            The output stream id.
     * @param tuple
     *            The Storm tuple to be emitted.
     * @return the return value of {@link #doEmit(Object)}
     */
    @SuppressWarnings("unchecked")
    protected final List<Integer> tansformAndEmit(final String streamId, final List<Object> tuple) {
        List<Integer> taskIds;
​
        int numAtt = this.numberOfAttributes.get(streamId);
        int taskIdIdx = numAtt;
        if (this.taskId >= 0 && numAtt < 0) {
            numAtt = 1;
            taskIdIdx = 0;
        }
        if (numAtt >= 0) {
            assert (tuple.size() == numAtt);
            Tuple out = this.outputTuple.get(streamId);
            for (int i = 0; i < numAtt; ++i) {
                out.setField(tuple.get(i), i);
            }
            if (this.taskId >= 0) {
                out.setField(this.taskId, taskIdIdx);
            }
            if (this.split) {
                this.splitTuple.streamId = streamId;
                this.splitTuple.value = out;
​
                taskIds = doEmit((OUT) this.splitTuple);
            } else {
                taskIds = doEmit((OUT) out);
            }
​
        } else {
            assert (tuple.size() == 1);
            if (this.split) {
                this.splitTuple.streamId = streamId;
                this.splitTuple.value = tuple.get(0);
​
                taskIds = doEmit((OUT) this.splitTuple);
            } else {
                taskIds = doEmit((OUT) tuple.get(0));
            }
        }
        this.tupleEmitted = true;
​
        return taskIds;
    }

/**
 * The Task represents one execution of a parallel subtask on a TaskManager.
 * A Task wraps a Flink operator (which may be a user function) and
 * runs it, providing all services necessary for example to consume input data,
 * produce its results (intermediate result partitions) and communicate
 * with the JobManager.
 *
 * <p>The Flink operators (implemented as subclasses of
 * {@link AbstractInvokable} have only data readers, -writers, and certain event callbacks.
 * The task connects those to the network stack and actor messages, and tracks the state
 * of the execution and handles exceptions.
 *
 * <p>Tasks have no knowledge about how they relate to other tasks, or whether they
 * are the first attempt to execute the task, or a repeated attempt. All of that
 * is only known to the JobManager. All the task knows are its own runnable code,
 * the task's configuration, and the IDs of the intermediate results to consume and
 * produce (if any).
 *
 * <p>Each Task is run by one dedicated thread.
 */
public class Task implements Runnable, TaskActions, CheckpointListener {
    //......
​
    /**
     * The core work method that bootstraps the task and executes its code.
     */
    @Override
    public void run() {
            //......
            // now load and instantiate the task's invokable code
            invokable = loadAndInstantiateInvokable(userCodeClassLoader, nameOfInvokableClass, env);
​
            // ----------------------------------------------------------------
            //  actual task core work
            // ----------------------------------------------------------------
​
            // we must make strictly sure that the invokable is accessible to the cancel() call
            // by the time we switched to running.
            this.invokable = invokable;
​
            // switch to the RUNNING state, if that fails, we have been canceled/failed in the meantime
            if (!transitionState(ExecutionState.DEPLOYING, ExecutionState.RUNNING)) {
                throw new CancelTaskException();
            }
​
            // notify everyone that we switched to running
            notifyObservers(ExecutionState.RUNNING, null);
            taskManagerActions.updateTaskExecutionState(new TaskExecutionState(jobId, executionId, ExecutionState.RUNNING));
​
            // make sure the user code classloader is accessible thread-locally
            executingThread.setContextClassLoader(userCodeClassLoader);
​
            // run the invokable
            invokable.invoke();
​
            //......
    }
}

/**
 * Base class for all streaming tasks. A task is the unit of local processing that is deployed
 * and executed by the TaskManagers. Each task runs one or more {@link StreamOperator}s which form
 * the Task's operator chain. Operators that are chained together execute synchronously in the
 * same thread and hence on the same stream partition. A common case for these chains
 * are successive map/flatmap/filter tasks.
 *
 * <p>The task chain contains one "head" operator and multiple chained operators.
 * The StreamTask is specialized for the type of the head operator: one-input and two-input tasks,
 * as well as for sources, iteration heads and iteration tails.
 *
 * <p>The Task class deals with the setup of the streams read by the head operator, and the streams
 * produced by the operators at the ends of the operator chain. Note that the chain may fork and
 * thus have multiple ends.
 *
 * <p>The life cycle of the task is set up as follows:
 * <pre>{@code
 *  -- setInitialState -> provides state of all operators in the chain
 *
 *  -- invoke()
 *        |
 *        +----> Create basic utils (config, etc) and load the chain of operators
 *        +----> operators.setup()
 *        +----> task specific init()
 *        +----> initialize-operator-states()
 *        +----> open-operators()
 *        +----> run()
 *        +----> close-operators()
 *        +----> dispose-operators()
 *        +----> common cleanup
 *        +----> task specific cleanup()
 * }</pre>
 *
 * <p>The {@code StreamTask} has a lock object called {@code lock}. All calls to methods on a
 * {@code StreamOperator} must be synchronized on this lock object to ensure that no methods
 * are called concurrently.
 *
 * @param <OUT>
 * @param <OP>
 */
@Internal
public abstract class StreamTask<OUT, OP extends StreamOperator<OUT>>
        extends AbstractInvokable
        implements AsyncExceptionHandler {
​
        //......
​
    @Override
    public final void invoke() throws Exception {
​
        boolean disposed = false;
        try {
            //......
​
            // let the task do its work
            isRunning = true;
            run();
​
            // if this left the run() method cleanly despite the fact that this was canceled,
            // make sure the "clean shutdown" is not attempted
            if (canceled) {
                throw new CancelTaskException();
            }
​
            LOG.debug("Finished task {}", getName());
​
            //......
        }
        finally {
            // clean up everything we initialized
            isRunning = false;
​
            //......
        }
    }
}

/**
 * Stoppable task for executing stoppable streaming sources.
 *
 * @param <OUT> Type of the produced elements
 * @param <SRC> Stoppable source function
 */
public class StoppableSourceStreamTask<OUT, SRC extends SourceFunction<OUT> & StoppableFunction>
    extends SourceStreamTask<OUT, SRC, StoppableStreamSource<OUT, SRC>> implements StoppableTask {
​
    private volatile boolean stopped;
​
    public StoppableSourceStreamTask(Environment environment) {
        super(environment);
    }
​
    @Override
    protected void run() throws Exception {
        if (!stopped) {
            super.run();
        }
    }
​
    @Override
    public void stop() {
        stopped = true;
        if (this.headOperator != null) {
            this.headOperator.stop();
        }
    }
}

/**
 * {@link StreamTask} for executing a {@link StreamSource}.
 *
 * <p>One important aspect of this is that the checkpointing and the emission of elements must never
 * occur at the same time. The execution must be serial. This is achieved by having the contract
 * with the StreamFunction that it must only modify its state or emit elements in
 * a synchronized block that locks on the lock Object. Also, the modification of the state
 * and the emission of elements must happen in the same block of code that is protected by the
 * synchronized block.
 *
 * @param <OUT> Type of the output elements of this source.
 * @param <SRC> Type of the source function for the stream source operator
 * @param <OP> Type of the stream source operator
 */
@Internal
public class SourceStreamTask<OUT, SRC extends SourceFunction<OUT>, OP extends StreamSource<OUT, SRC>>
    extends StreamTask<OUT, OP> {
​
    //......
​
    @Override
    protected void run() throws Exception {
        headOperator.run(getCheckpointLock(), getStreamStatusMaintainer());
    }
}

/**
 * {@link StreamOperator} for streaming sources.
 *
 * @param <OUT> Type of the output elements
 * @param <SRC> Type of the source function of this stream source operator
 */
@Internal
public class StreamSource<OUT, SRC extends SourceFunction<OUT>>
        extends AbstractUdfStreamOperator<OUT, SRC> implements StreamOperator<OUT> {
​
    //......    
​
    public void run(final Object lockingObject, final StreamStatusMaintainer streamStatusMaintainer) throws Exception {
        run(lockingObject, streamStatusMaintainer, output);
    }
​
    public void run(final Object lockingObject,
            final StreamStatusMaintainer streamStatusMaintainer,
            final Output<StreamRecord<OUT>> collector) throws Exception {
​
        final TimeCharacteristic timeCharacteristic = getOperatorConfig().getTimeCharacteristic();
​
        final Configuration configuration = this.getContainingTask().getEnvironment().getTaskManagerInfo().getConfiguration();
        final long latencyTrackingInterval = getExecutionConfig().isLatencyTrackingConfigured()
            ? getExecutionConfig().getLatencyTrackingInterval()
            : configuration.getLong(MetricOptions.LATENCY_INTERVAL);
​
        LatencyMarksEmitter<OUT> latencyEmitter = null;
        if (latencyTrackingInterval > 0) {
            latencyEmitter = new LatencyMarksEmitter<>(
                getProcessingTimeService(),
                collector,
                latencyTrackingInterval,
                this.getOperatorID(),
                getRuntimeContext().getIndexOfThisSubtask());
        }
​
        final long watermarkInterval = getRuntimeContext().getExecutionConfig().getAutoWatermarkInterval();
​
        this.ctx = StreamSourceContexts.getSourceContext(
            timeCharacteristic,
            getProcessingTimeService(),
            lockingObject,
            streamStatusMaintainer,
            collector,
            watermarkInterval,
            -1);
​
        try {
            userFunction.run(ctx);
​
            // if we get here, then the user function either exited after being done (finite source)
            // or the function was canceled or stopped. For the finite source case, we should emit
            // a final watermark that indicates that we reached the end of event-time
            if (!isCanceledOrStopped()) {
                ctx.emitWatermark(Watermark.MAX_WATERMARK);
            }
        } finally {
            // make sure that the context is closed in any case
            ctx.close();
            if (latencyEmitter != null) {
                latencyEmitter.close();
            }
        }
    }