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package org.apache.flinkx.api

import org.apache.flink.annotation.{Internal, Public, PublicEvolving}
import org.apache.flink.api.common.ExecutionConfig
import org.apache.flink.api.common.eventtime.{TimestampAssigner, WatermarkGenerator, WatermarkStrategy}
import org.apache.flink.api.common.functions.{FilterFunction, FlatMapFunction, MapFunction, Partitioner}
import org.apache.flink.api.common.io.OutputFormat
import org.apache.flink.api.common.operators.{ResourceSpec, SlotSharingGroup}
import org.apache.flink.api.common.serialization.SerializationSchema
import org.apache.flink.api.common.state.MapStateDescriptor
import org.apache.flink.api.common.typeinfo.TypeInformation
import org.apache.flink.api.connector.sink2.Sink
import org.apache.flink.api.java.functions.KeySelector
import org.apache.flink.api.java.typeutils.ResultTypeQueryable
import org.apache.flink.streaming.api.datastream.{
  BroadcastStream,
  DataStreamSink,
  SingleOutputStreamOperator,
  AllWindowedStream => JavaAllWindowedStream,
  DataStream => JavaStream,
  KeyedStream => JavaKeyedStream
}
import org.apache.flink.streaming.api.functions.sink.SinkFunction
import org.apache.flink.streaming.api.functions.timestamps.AscendingTimestampExtractor
import org.apache.flink.streaming.api.functions.ProcessFunction
import org.apache.flink.streaming.api.operators.OneInputStreamOperator
import org.apache.flink.streaming.api.windowing.assigners._
import org.apache.flink.streaming.api.windowing.windows.{GlobalWindow, TimeWindow, Window}
import org.apache.flink.util.Collector
import org.apache.flink.api.java.tuple.{Tuple => JavaTuple}
import scala.jdk.CollectionConverters._
import ScalaStreamOps._

@Public
class DataStream[T](stream: JavaStream[T]) {

  /** Returns the [[StreamExecutionEnvironment]] associated with the current [[DataStream]].
    *
    * @return
    *   associated execution environment
    * @deprecated
    *   Use [[executionEnvironment]] instead
    */
  @deprecated
  @PublicEvolving
  def getExecutionEnvironment: StreamExecutionEnvironment =
    new StreamExecutionEnvironment(stream.getExecutionEnvironment)

  /** Returns the TypeInformation for the elements of this DataStream.
    *
    * @deprecated
    *   Use [[dataType]] instead.
    */
  @deprecated
  @PublicEvolving
  def getType(): TypeInformation[T] = stream.getType()

  /** Returns the parallelism of this operation.
    *
    * @deprecated
    *   Use [[parallelism]] instead.
    */
  @deprecated
  @PublicEvolving
  def getParallelism = stream.getParallelism

  /** Returns the execution config.
    *
    * @deprecated
    *   Use [[executionConfig]] instead.
    */
  @deprecated
  @PublicEvolving
  def getExecutionConfig = stream.getExecutionConfig

  /** Returns the ID of the DataStream.
    */
  @Internal
  private[flinkx] def getId = stream.getId()

  // --------------------------------------------------------------------------
  //  Scalaesk accessors
  // --------------------------------------------------------------------------

  /** Gets the underlying java DataStream object.
    */
  def javaStream: JavaStream[T] = stream

  /** Returns the TypeInformation for the elements of this DataStream.
    */
  def dataType: TypeInformation[T] = stream.getType()

  /** Returns the execution config.
    */
  def executionConfig: ExecutionConfig = stream.getExecutionConfig()

  /** Returns the [[StreamExecutionEnvironment]] associated with this data stream
    */
  def executionEnvironment: StreamExecutionEnvironment =
    new StreamExecutionEnvironment(stream.getExecutionEnvironment())

  /** Returns the parallelism of this operation.
    */
  def parallelism: Int = stream.getParallelism()

  /** Sets the parallelism of this operation. This must be at least 1.
    */
  def setParallelism(parallelism: Int): DataStream[T] = {
    stream match {
      case ds: SingleOutputStreamOperator[T] => ds.setParallelism(parallelism)
      case _ =>
        throw new UnsupportedOperationException("Operator " + stream + " cannot set the parallelism.")
    }
    this
  }

  def setMaxParallelism(maxParallelism: Int): DataStream[T] = {
    stream match {
      case ds: SingleOutputStreamOperator[T] => ds.setMaxParallelism(maxParallelism)
      case _ =>
        throw new UnsupportedOperationException(
          "Operator " + stream + " cannot set the maximum" +
            "paralllelism"
        )
    }

    this
  }

  /** Returns the minimum resources of this operation.
    */
  @PublicEvolving
  def minResources: ResourceSpec = stream.getMinResources()

  /** Returns the preferred resources of this operation.
    */
  @PublicEvolving
  def preferredResources: ResourceSpec = stream.getPreferredResources()

  /** Gets the name of the current data stream. This name is used by the visualization and logging during runtime.
    *
    * @return
    *   Name of the stream.
    * @deprecated
    *   Use [[name]] instead
    */
  @deprecated
  @PublicEvolving
  def getName: String = name

  /** Gets the name of the current data stream. This name is used by the visualization and logging during runtime.
    *
    * @return
    *   Name of the stream.
    */
  def name: String = stream match {
    case stream: SingleOutputStreamOperator[T] => stream.getName
    case _ => throw new UnsupportedOperationException("Only supported for operators.")
  }

  // --------------------------------------------------------------------------

  /** Sets the name of the current data stream. This name is used by the visualization and logging during runtime.
    *
    * @return
    *   The named operator
    */
  def name(name: String): DataStream[T] = stream match {
    case stream: SingleOutputStreamOperator[T] => asScalaStream(stream.name(name))
    case _ =>
      throw new UnsupportedOperationException("Only supported for operators.")
      this
  }

  /** Sets an ID for this operator.
    *
    * The specified ID is used to assign the same operator ID across job submissions (for example when starting a job
    * from a savepoint).
    *
    * Important: this ID needs to be unique per transformation and job. Otherwise, job submission will
    * fail.
    *
    * @param uid
    *   The unique user-specified ID of this transformation.
    * @return
    *   The operator with the specified ID.
    */
  @PublicEvolving
  def uid(uid: String): DataStream[T] = javaStream match {
    case stream: SingleOutputStreamOperator[T] => asScalaStream(stream.uid(uid))
    case _ =>
      throw new UnsupportedOperationException("Only supported for operators.")
      this
  }

  @PublicEvolving
  def getSideOutput[X: TypeInformation](tag: OutputTag[X]): DataStream[X] = javaStream match {
    case stream: SingleOutputStreamOperator[_] =>
      asScalaStream(stream.getSideOutput(tag: OutputTag[X]))
  }

  /** Sets an user provided hash for this operator. This will be used AS IS the create the JobVertexID. 

The user * provided hash is an alternative to the generated hashes, that is considered when identifying an operator through * the default hash mechanics fails (e.g. because of changes between Flink versions).

*

Important: this should be used as a workaround or for trouble shooting. The provided hash * needs to be unique per transformation and job. Otherwise, job submission will fail. Furthermore, you cannot assign * user-specified hash to intermediate nodes in an operator chain and trying so will let your job fail. * * @param hash * the user provided hash for this operator. * @return * The operator with the user provided hash. */ @PublicEvolving def setUidHash(hash: String): DataStream[T] = javaStream match { case stream: SingleOutputStreamOperator[T] => asScalaStream(stream.setUidHash(hash)) case _ => throw new UnsupportedOperationException("Only supported for operators.") this } /** Turns off chaining for this operator so thread co-location will not be used as an optimization.

Chaining can * be turned off for the whole job by [[StreamExecutionEnvironment.disableOperatorChaining()]] however it is not * advised for performance considerations. */ @PublicEvolving def disableChaining(): DataStream[T] = { stream match { case ds: SingleOutputStreamOperator[T] => ds.disableChaining() case _ => throw new UnsupportedOperationException("Only supported for operators.") } this } /** Starts a new task chain beginning at this operator. This operator will not be chained (thread co-located for * increased performance) to any previous tasks even if possible. */ @PublicEvolving def startNewChain(): DataStream[T] = { stream match { case ds: SingleOutputStreamOperator[T] => ds.startNewChain() case _ => throw new UnsupportedOperationException("Only supported for operators.") } this } /** Sets the slot sharing group of this operation. Parallel instances of operations that are in the same slot sharing * group will be co-located in the same TaskManager slot, if possible. * * Operations inherit the slot sharing group of input operations if all input operations are in the same slot sharing * group and no slot sharing group was explicitly specified. * * Initially an operation is in the default slot sharing group. An operation can be put into the default group * explicitly by setting the slot sharing group to `"default"`. * * @param slotSharingGroup * The slot sharing group name. */ @PublicEvolving def slotSharingGroup(slotSharingGroup: String): DataStream[T] = { stream match { case ds: SingleOutputStreamOperator[T] => ds.slotSharingGroup(slotSharingGroup) case _ => throw new UnsupportedOperationException("Only supported for operators.") } this } /** Sets the slot sharing group of this operation. Parallel instances of operations that are in the same slot sharing * group will be co-located in the same TaskManager slot, if possible. * * Operations inherit the slot sharing group of input operations if all input operations are in the same slot sharing * group and no slot sharing group was explicitly specified. * * Initially an operation is in the default slot sharing group. An operation can be put into the default group * explicitly by setting the slot sharing group to `"default"`. * * @param slotSharingGroup * Which contains name and its resource spec. */ @PublicEvolving def slotSharingGroup(slotSharingGroup: SlotSharingGroup): DataStream[T] = { stream match { case ds: SingleOutputStreamOperator[T] => ds.slotSharingGroup(slotSharingGroup) case _ => throw new UnsupportedOperationException("Only supported for operators.") } this } /** Sets the maximum time frequency (ms) for the flushing of the output buffer. By default the output buffers flush * only when they are full. * * @param timeoutMillis * The maximum time between two output flushes. * @return * The operator with buffer timeout set. */ def setBufferTimeout(timeoutMillis: Long): DataStream[T] = { stream match { case ds: SingleOutputStreamOperator[T] => ds.setBufferTimeout(timeoutMillis) case _ => throw new UnsupportedOperationException("Only supported for operators.") } this } // -------------------------------------------------------------------------- // Stream Transformations // -------------------------------------------------------------------------- /** Creates a new DataStream by merging DataStream outputs of the same type with each other. The DataStreams merged * using this operator will be transformed simultaneously. */ def union(dataStreams: DataStream[T]*): DataStream[T] = asScalaStream(stream.union(dataStreams.map(_.javaStream): _*)) /** Creates a new ConnectedStreams by connecting DataStream outputs of different type with each other. The DataStreams * connected using this operators can be used with CoFunctions. */ def connect[T2](dataStream: DataStream[T2]): ConnectedStreams[T, T2] = asScalaStream(stream.connect(dataStream.javaStream)) /** Creates a new [[BroadcastConnectedStream]] by connecting the current [[DataStream]] or [[KeyedStream]] with a * [[BroadcastStream]]. * * The latter can be created using the [[broadcast(MapStateDescriptor[])]] method. * * The resulting stream can be further processed using the ``broadcastConnectedStream.process(myFunction)`` method, * where ``myFunction`` can be either a [[org.apache.flink.streaming.api.functions.co.KeyedBroadcastProcessFunction]] * or a [[org.apache.flink.streaming.api.functions.co.BroadcastProcessFunction]] depending on the current stream * being a [[KeyedStream]] or not. * * @param broadcastStream * The broadcast stream with the broadcast state to be connected with this stream. * @return * The [[BroadcastConnectedStream]]. */ @PublicEvolving def connect[R](broadcastStream: BroadcastStream[R]): BroadcastConnectedStream[T, R] = asScalaStream(stream.connect(broadcastStream)) /** Groups the elements of a DataStream by the given key positions (for tuple/array types) to be used with grouped * operators like grouped reduce or grouped aggregations. */ @deprecated("use [[DataStream.keyBy(KeySelector)]] instead") def keyBy(fields: Int*): KeyedStream[T, JavaTuple] = asScalaStream(stream.keyBy(fields: _*)) /** Groups the elements of a DataStream by the given field expressions to be used with grouped operators like grouped * reduce or grouped aggregations. */ @deprecated("use [[DataStream.keyBy(KeySelector)]] instead") def keyBy(firstField: String, otherFields: String*): KeyedStream[T, JavaTuple] = asScalaStream(stream.keyBy(firstField +: otherFields.toArray: _*)) /** Groups the elements of a DataStream by the given K key to be used with grouped operators like grouped reduce or * grouped aggregations. */ def keyBy[K: TypeInformation](fun: T => K): KeyedStream[T, K] = { val cleanFun = clean(fun) val keyType: TypeInformation[K] = implicitly[TypeInformation[K]] val keyExtractor = new KeySelector[T, K] with ResultTypeQueryable[K] { def getKey(in: T) = cleanFun(in) override def getProducedType: TypeInformation[K] = keyType } asScalaStream(new JavaKeyedStream(stream, keyExtractor, keyType)) } /** Groups the elements of a DataStream by the given K key to be used with grouped operators like grouped reduce or * grouped aggregations. */ def keyBy[K: TypeInformation](fun: KeySelector[T, K]): KeyedStream[T, K] = { val cleanFun = clean(fun) val keyType: TypeInformation[K] = implicitly[TypeInformation[K]] asScalaStream(new JavaKeyedStream(stream, cleanFun, keyType)) } /** Partitions a tuple DataStream on the specified key fields using a custom partitioner. This method takes the key * position to partition on, and a partitioner that accepts the key type. * * Note: This method works only on single field keys. */ @deprecated("Use [[DataStream.partitionCustom(Partitioner, Function1)]] instead") def partitionCustom[K: TypeInformation](partitioner: Partitioner[K], field: Int): DataStream[T] = asScalaStream(stream.partitionCustom(partitioner, field)) /** Partitions a POJO DataStream on the specified key fields using a custom partitioner. This method takes the key * expression to partition on, and a partitioner that accepts the key type. * * Note: This method works only on single field keys. */ @deprecated("Use [[DataStream.partitionCustom(Partitioner, Function1)]] instead") def partitionCustom[K: TypeInformation](partitioner: Partitioner[K], field: String): DataStream[T] = asScalaStream(stream.partitionCustom(partitioner, field)) /** Partitions a DataStream on the key returned by the selector, using a custom partitioner. This method takes the key * selector to get the key to partition on, and a partitioner that accepts the key type. * * Note: This method works only on single field keys, i.e. the selector cannot return tuples of fields. */ def partitionCustom[K: TypeInformation](partitioner: Partitioner[K], fun: T => K): DataStream[T] = { val keyType = implicitly[TypeInformation[K]] val cleanFun = clean(fun) val keyExtractor = new KeySelector[T, K] with ResultTypeQueryable[K] { def getKey(in: T) = cleanFun(in) override def getProducedType(): TypeInformation[K] = keyType } asScalaStream(stream.partitionCustom(partitioner, keyExtractor)) } /** Sets the partitioning of the DataStream so that the output tuples are broad casted to every parallel instance of * the next component. */ def broadcast: DataStream[T] = asScalaStream(stream.broadcast()) /** Sets the partitioning of the [[DataStream]] so that the output elements are broadcasted to every parallel instance * of the next operation. In addition, it implicitly creates as many * [[org.apache.flink.api.common.state.BroadcastState broadcast states]] as the specified descriptors which can be * used to store the element of the stream. * * @param broadcastStateDescriptors * the descriptors of the broadcast states to create. * @return * A [[BroadcastStream]] which can be used in the [[DataStream.connect(BroadcastStream)]] to create a * [[BroadcastConnectedStream]] for further processing of the elements. */ @PublicEvolving def broadcast(broadcastStateDescriptors: MapStateDescriptor[_, _]*): BroadcastStream[T] = { if (broadcastStateDescriptors == null) { throw new NullPointerException("State Descriptors must not be null.") } javaStream.broadcast(broadcastStateDescriptors: _*) } /** Sets the partitioning of the DataStream so that the output values all go to the first instance of the next * processing operator. Use this setting with care since it might cause a serious performance bottleneck in the * application. */ @PublicEvolving def global: DataStream[T] = asScalaStream(stream.global()) /** Sets the partitioning of the DataStream so that the output tuples are shuffled to the next component. */ @PublicEvolving def shuffle: DataStream[T] = asScalaStream(stream.shuffle()) /** Sets the partitioning of the DataStream so that the output tuples are forwarded to the local subtask of the next * component (whenever possible). */ def forward: DataStream[T] = asScalaStream(stream.forward()) /** Sets the partitioning of the DataStream so that the output tuples are distributed evenly to the next component. */ def rebalance: DataStream[T] = asScalaStream(stream.rebalance()) /** Sets the partitioning of the [[DataStream]] so that the output tuples are distributed evenly to a subset of * instances of the downstream operation. * * The subset of downstream operations to which the upstream operation sends elements depends on the degree of * parallelism of both the upstream and downstream operation. For example, if the upstream operation has parallelism * 2 and the downstream operation has parallelism 4, then one upstream operation would distribute elements to two * downstream operations while the other upstream operation would distribute to the other two downstream operations. * If, on the other hand, the downstream operation has parallelism 2 while the upstream operation has parallelism 4 * then two upstream operations will distribute to one downstream operation while the other two upstream operations * will distribute to the other downstream operations. * * In cases where the different parallelisms are not multiples of each other one or several downstream operations * will have a differing number of inputs from upstream operations. */ @PublicEvolving def rescale: DataStream[T] = asScalaStream(stream.rescale()) /** Initiates an iterative part of the program that creates a loop by feeding back data streams. To create a streaming * iteration the user needs to define a transformation that creates two DataStreams. The first one is the output that * will be fed back to the start of the iteration and the second is the output stream of the iterative part. * * stepfunction: initialStream => (feedback, output) * * A common pattern is to use output splitting to create feedback and output DataStream. Please see the side outputs * of [[ProcessFunction]] method of the DataStream * * By default a DataStream with iteration will never terminate, but the user can use the maxWaitTime parameter to set * a max waiting time for the iteration head. If no data received in the set time the stream terminates. * * Parallelism of the feedback stream must match the parallelism of the original stream. Please refer to the * [[setParallelism]] method for parallelism modification */ @PublicEvolving def iterate[R]( stepFunction: DataStream[T] => (DataStream[T], DataStream[R]), maxWaitTimeMillis: Long = 0 ): DataStream[R] = { val iterativeStream = stream.iterate(maxWaitTimeMillis) val (feedback, output) = stepFunction(new DataStream[T](iterativeStream)) iterativeStream.closeWith(feedback.javaStream) output } /** Initiates an iterative part of the program that creates a loop by feeding back data streams. To create a streaming * iteration the user needs to define a transformation that creates two DataStreams. The first one is the output that * will be fed back to the start of the iteration and the second is the output stream of the iterative part. * * The input stream of the iterate operator and the feedback stream will be treated as a ConnectedStreams where the * input is connected with the feedback stream. * * This allows the user to distinguish standard input from feedback inputs. * * stepfunction: initialStream => (feedback, output) * * The user must set the max waiting time for the iteration head. If no data received in the set time the stream * terminates. If this parameter is set to 0 then the iteration sources will indefinitely, so the job must be killed * to stop. */ @PublicEvolving def iterate[R, F: TypeInformation]( stepFunction: ConnectedStreams[T, F] => (DataStream[F], DataStream[R]), maxWaitTimeMillis: Long ): DataStream[R] = { val feedbackType: TypeInformation[F] = implicitly[TypeInformation[F]] val connectedIterativeStream = stream.iterate(maxWaitTimeMillis).withFeedbackType(feedbackType) val (feedback, output) = stepFunction(asScalaStream(connectedIterativeStream)) connectedIterativeStream.closeWith(feedback.javaStream) output } /** Creates a new DataStream by applying the given function to every element of this DataStream. */ def map[R: TypeInformation](fun: T => R): DataStream[R] = { if (fun == null) { throw new NullPointerException("Map function must not be null.") } val cleanFun = clean(fun) val mapper = new MapFunction[T, R] { def map(in: T): R = cleanFun(in) } map(mapper) } /** Creates a new DataStream by applying the given function to every element of this DataStream. */ def map[R: TypeInformation](mapper: MapFunction[T, R]): DataStream[R] = { if (mapper == null) { throw new NullPointerException("Map function must not be null.") } val outType: TypeInformation[R] = implicitly[TypeInformation[R]] asScalaStream(stream.map(mapper, outType).asInstanceOf[JavaStream[R]]) } /** Creates a new DataStream by applying the given function to every element and flattening the results. */ def flatMap[R: TypeInformation](flatMapper: FlatMapFunction[T, R]): DataStream[R] = { if (flatMapper == null) { throw new NullPointerException("FlatMap function must not be null.") } val outType: TypeInformation[R] = implicitly[TypeInformation[R]] asScalaStream(stream.flatMap(flatMapper, outType).asInstanceOf[JavaStream[R]]) } /** Creates a new DataStream by applying the given function to every element and flattening the results. */ def flatMap[R: TypeInformation](fun: (T, Collector[R]) => Unit): DataStream[R] = { if (fun == null) { throw new NullPointerException("FlatMap function must not be null.") } val cleanFun = clean(fun) val flatMapper = new FlatMapFunction[T, R] { def flatMap(in: T, out: Collector[R]) = { cleanFun(in, out) } } flatMap(flatMapper) } /** Creates a new DataStream by applying the given function to every element and flattening the results. */ def flatMap[R: TypeInformation](fun: T => TraversableOnce[R]): DataStream[R] = { if (fun == null) { throw new NullPointerException("FlatMap function must not be null.") } val cleanFun = clean(fun) val flatMapper = new FlatMapFunction[T, R] { def flatMap(in: T, out: Collector[R]) = { cleanFun(in).foreach(out.collect _) } } flatMap(flatMapper) } /** Applies the given [[ProcessFunction]] on the input stream, thereby creating a transformed output stream. * * The function will be called for every element in the stream and can produce zero or more output. * * @param processFunction * The [[ProcessFunction]] that is called for each element in the stream. */ @PublicEvolving def process[R: TypeInformation](processFunction: ProcessFunction[T, R]): DataStream[R] = { if (processFunction == null) { throw new NullPointerException("ProcessFunction must not be null.") } asScalaStream(javaStream.process(processFunction, implicitly[TypeInformation[R]])) } /** Creates a new DataStream that contains only the elements satisfying the given filter predicate. */ def filter(filter: FilterFunction[T]): DataStream[T] = { if (filter == null) { throw new NullPointerException("Filter function must not be null.") } asScalaStream(stream.filter(filter)) } /** Creates a new DataStream that contains only the elements satisfying the given filter predicate. */ def filter(fun: T => Boolean): DataStream[T] = { if (fun == null) { throw new NullPointerException("Filter function must not be null.") } val cleanFun = clean(fun) val filterFun = new FilterFunction[T] { def filter(in: T) = cleanFun(in) } filter(filterFun) } /** Windows this [[DataStream]] into sliding count windows. * * Note: This operation can be inherently non-parallel since all elements have to pass through the same operator * instance. (Only for special cases, such as aligned time windows is it possible to perform this operation in * parallel). * * @param size * The size of the windows in number of elements. * @param slide * The slide interval in number of elements. */ def countWindowAll(size: Long, slide: Long): AllWindowedStream[T, GlobalWindow] = { new AllWindowedStream(stream.countWindowAll(size, slide)) } /** Windows this [[DataStream]] into tumbling count windows. * * Note: This operation can be inherently non-parallel since all elements have to pass through the same operator * instance. (Only for special cases, such as aligned time windows is it possible to perform this operation in * parallel). * * @param size * The size of the windows in number of elements. */ def countWindowAll(size: Long): AllWindowedStream[T, GlobalWindow] = { new AllWindowedStream(stream.countWindowAll(size)) } /** Windows this data stream to a [[AllWindowedStream]], which evaluates windows over a key grouped stream. Elements * are put into windows by a [[WindowAssigner]]. The grouping of elements is done both by key and by window. * * A [[org.apache.flink.streaming.api.windowing.triggers.Trigger]] can be defined to specify when windows are * evaluated. However, `WindowAssigner` have a default `Trigger` that is used if a `Trigger` is not specified. * * Note: This operation can be inherently non-parallel since all elements have to pass through the same operator * instance. (Only for special cases, such as aligned time windows is it possible to perform this operation in * parallel). * * @param assigner * The `WindowAssigner` that assigns elements to windows. * @return * The trigger windows data stream. */ @PublicEvolving def windowAll[W <: Window](assigner: WindowAssigner[_ >: T, W]): AllWindowedStream[T, W] = { new AllWindowedStream[T, W](new JavaAllWindowedStream[T, W](stream, assigner)) } /** Assigns timestamps to the elements in the data stream and generates watermarks to signal event time progress. The * given [[WatermarkStrategy is used to create a [[TimestampAssigner]] and * [[org.apache.flink.api.common.eventtime.WatermarkGenerator]]. * * For each event in the data stream, the [[TimestampAssigner#extractTimestamp(Object, long)]] method is called to * assign an event timestamp. * * For each event in the data stream, the [[WatermarkGenerator#onEvent(Object, long, WatermarkOutput)]] will be * called. * * Periodically (defined by the [[ExecutionConfig#getAutoWatermarkInterval()]]), the * [[WatermarkGenerator#onPeriodicEmit(WatermarkOutput)]] method will be called. * * Common watermark generation patterns can be found as static methods in the * [[org.apache.flink.api.common.eventtime.WatermarkStrategy]] class. */ def assignTimestampsAndWatermarks(watermarkStrategy: WatermarkStrategy[T]): DataStream[T] = { val cleanedStrategy = clean(watermarkStrategy) asScalaStream(stream.assignTimestampsAndWatermarks(cleanedStrategy)) } /** Assigns timestamps to the elements in the data stream and periodically creates watermarks to signal event time * progress. * * This method is a shortcut for data streams where the element timestamp are known to be monotonously ascending * within each parallel stream. In that case, the system can generate watermarks automatically and perfectly by * tracking the ascending timestamps. * * For cases where the timestamps are not monotonously increasing, use the more general methods * [[assignTimestampsAndWatermarks(AssignerWithPeriodicWatermarks)]] and * [[assignTimestampsAndWatermarks(AssignerWithPunctuatedWatermarks)]]. */ @PublicEvolving def assignAscendingTimestamps(extractor: T => Long): DataStream[T] = { val cleanExtractor = clean(extractor) val extractorFunction = new AscendingTimestampExtractor[T] { def extractAscendingTimestamp(element: T): Long = { cleanExtractor(element) } } asScalaStream(stream.assignTimestampsAndWatermarks(extractorFunction)) } /** Creates a co-group operation. See [[CoGroupedStreams]] for an example of how the keys and window can be specified. */ def coGroup[T2](otherStream: DataStream[T2]): CoGroupedStreams[T, T2] = { new CoGroupedStreams(this, otherStream) } /** Creates a join operation. See [[JoinedStreams]] for an example of how the keys and window can be specified. */ def join[T2](otherStream: DataStream[T2]): JoinedStreams[T, T2] = { new JoinedStreams(this, otherStream) } /** Writes a DataStream to the standard output stream (stdout). For each element of the DataStream the result of * .toString is written. */ @PublicEvolving def print(): DataStreamSink[T] = stream.print() /** Writes a DataStream to the standard error stream (stderr). * * For each element of the DataStream the result of [[AnyRef.toString()]] is written. * * @return * The closed DataStream. */ @PublicEvolving def printToErr() = stream.printToErr() /** Writes a DataStream to the standard output stream (stdout). For each element of the DataStream the result of * [[AnyRef.toString()]] is written. * * @param sinkIdentifier * The string to prefix the output with. * @return * The closed DataStream. */ @PublicEvolving def print(sinkIdentifier: String): DataStreamSink[T] = stream.print(sinkIdentifier) /** Writes a DataStream to the standard error stream (stderr). * * For each element of the DataStream the result of [[AnyRef.toString()]] is written. * * @param sinkIdentifier * The string to prefix the output with. * @return * The closed DataStream. */ @PublicEvolving def printToErr(sinkIdentifier: String) = stream.printToErr(sinkIdentifier) /** Writes a DataStream using the given [[OutputFormat]]. */ @PublicEvolving def writeUsingOutputFormat(format: OutputFormat[T]): DataStreamSink[T] = { stream.writeUsingOutputFormat(format) } /** Writes the DataStream to a socket as a byte array. The format of the output is specified by a * [[SerializationSchema]]. */ @PublicEvolving def writeToSocket(hostname: String, port: Integer, schema: SerializationSchema[T]): DataStreamSink[T] = { stream.writeToSocket(hostname, port, schema) } /** Adds the given sink to this DataStream. Only streams with sinks added will be executed once the * StreamExecutionEnvironment.execute(...) method is called. */ def addSink(sinkFunction: SinkFunction[T]): DataStreamSink[T] = stream.addSink(sinkFunction) /** Adds the given sink to this DataStream. Only streams with sinks added will be executed once the * StreamExecutionEnvironment.execute(...) method is called. */ def addSink(fun: T => Unit): DataStreamSink[T] = { if (fun == null) { throw new NullPointerException("Sink function must not be null.") } val cleanFun = clean(fun) val sinkFunction = new SinkFunction[T] { override def invoke(in: T) = cleanFun(in) } this.addSink(sinkFunction) } /** Adds the given sink to this DataStream. Only streams with sinks added will be executed once the * StreamExecutionEnvironment.execute(...) method is called. */ def sinkTo(sink: org.apache.flink.api.connector.sink.Sink[T, _, _, _]): DataStreamSink[T] = stream.sinkTo(sink) /** Adds the given sink to this DataStream. Only streams with sinks added will be executed once the * StreamExecutionEnvironment.execute(...) method is called. */ def sinkTo(sink: Sink[T]): DataStreamSink[T] = stream.sinkTo(sink) /** Triggers the distributed execution of the streaming dataflow and returns an iterator over the elements of the * given DataStream. * *

The DataStream application is executed in the regular distributed manner on the target environment, and the * events from the stream are polled back to this application process and thread through Flink's REST API. * *

IMPORTANT The returned iterator must be closed to free all cluster resources. */ def executeAndCollect(): CloseableIterator[T] = CloseableIterator.fromJava(stream.executeAndCollect()) /** Triggers the distributed execution of the streaming dataflow and returns an iterator over the elements of the * given DataStream. * *

The DataStream application is executed in the regular distributed manner on the target environment, and the * events from the stream are polled back to this application process and thread through Flink's REST API. * *

IMPORTANT The returned iterator must be closed to free all cluster resources. */ def executeAndCollect(jobExecutionName: String): CloseableIterator[T] = CloseableIterator.fromJava(stream.executeAndCollect(jobExecutionName)) /** Triggers the distributed execution of the streaming dataflow and returns an iterator over the elements of the * given DataStream. * *

The DataStream application is executed in the regular distributed manner on the target environment, and the * events from the stream are polled back to this application process and thread through Flink's REST API. */ def executeAndCollect(limit: Int): List[T] = stream.executeAndCollect(limit).asScala.toList /** Triggers the distributed execution of the streaming dataflow and returns an iterator over the elements of the * given DataStream. * *

The DataStream application is executed in the regular distributed manner on the target environment, and the * events from the stream are polled back to this application process and thread through Flink's REST API. */ def executeAndCollect(jobExecutionName: String, limit: Int): List[T] = stream.executeAndCollect(jobExecutionName, limit).asScala.toList /** Returns a "closure-cleaned" version of the given function. Cleans only if closure cleaning is not disabled in the * [[org.apache.flink.api.common.ExecutionConfig]]. */ private[flinkx] def clean[F <: AnyRef](f: F): F = { new StreamExecutionEnvironment(stream.getExecutionEnvironment).scalaClean(f) } /** Transforms the [[DataStream]] by using a custom [[OneInputStreamOperator]]. * * @param operatorName * name of the operator, for logging purposes * @param operator * the object containing the transformation logic * @tparam R * the type of elements emitted by the operator */ @PublicEvolving def transform[R: TypeInformation](operatorName: String, operator: OneInputStreamOperator[T, R]): DataStream[R] = { asScalaStream(stream.transform(operatorName, implicitly[TypeInformation[R]], operator)) } /** Sets the description of this data stream. * *

Description is used in json plan and web ui, but not in logging and metrics where only name is available. * Description is expected to provide detailed information about this operation, while name is expected to be more * simple, providing summary information only, so that we can have more user-friendly logging messages and metric * tags without losing useful messages for debugging. * * @return * The operator with new description */ @PublicEvolving def setDescription(description: String): DataStream[T] = stream match { case stream: SingleOutputStreamOperator[T] => asScalaStream(stream.setDescription(description)) case _ => throw new UnsupportedOperationException("Only supported for operators.") this } }





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