Class/Object

org.apache.spark.streaming.api.java

JavaPairDStream

Related Docs: object JavaPairDStream | package java

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class JavaPairDStream[K, V] extends AbstractJavaDStreamLike[(K, V), JavaPairDStream[K, V], JavaPairRDD[K, V]]

A Java-friendly interface to a DStream of key-value pairs, which provides extra methods like reduceByKey and join.

Source
JavaPairDStream.scala
Linear Supertypes
AbstractJavaDStreamLike[(K, V), JavaPairDStream[K, V], JavaPairRDD[K, V]], JavaDStreamLike[(K, V), JavaPairDStream[K, V], JavaPairRDD[K, V]], Serializable, Serializable, AnyRef, Any
Known Subclasses
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  1. JavaPairDStream
  2. AbstractJavaDStreamLike
  3. JavaDStreamLike
  4. Serializable
  5. Serializable
  6. AnyRef
  7. Any
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Visibility
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Instance Constructors

  1. new JavaPairDStream(dstream: DStream[(K, V)])(implicit kManifest: ClassTag[K], vManifest: ClassTag[V])

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Value Members

  1. final def !=(arg0: Any): Boolean

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    Definition Classes
    AnyRef → Any
  2. final def ##(): Int

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    AnyRef → Any
  3. final def ==(arg0: Any): Boolean

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    Definition Classes
    AnyRef → Any
  4. final def asInstanceOf[T0]: T0

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    Definition Classes
    Any
  5. def cache(): JavaPairDStream[K, V]

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    Persist RDDs of this DStream with the default storage level (MEMORY_ONLY_SER)

  6. def checkpoint(interval: Duration): DStream[(K, V)]

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    Enable periodic checkpointing of RDDs of this DStream.

    Enable periodic checkpointing of RDDs of this DStream.

    interval

    Time interval after which generated RDD will be checkpointed

    Definition Classes
    JavaDStreamLike
  7. val classTag: ClassTag[(K, V)]

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    Definition Classes
    JavaPairDStreamJavaDStreamLike
  8. def clone(): AnyRef

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    Attributes
    protected[java.lang]
    Definition Classes
    AnyRef
    Annotations
    @throws( ... )
  9. def cogroup[W](other: JavaPairDStream[K, W], partitioner: Partitioner): JavaPairDStream[K, (Iterable[V], Iterable[W])]

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    Return a new DStream by applying 'cogroup' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'cogroup' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with numPartitions partitions.

  10. def cogroup[W](other: JavaPairDStream[K, W], numPartitions: Int): JavaPairDStream[K, (Iterable[V], Iterable[W])]

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    Return a new DStream by applying 'cogroup' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'cogroup' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with numPartitions partitions.

  11. def cogroup[W](other: JavaPairDStream[K, W]): JavaPairDStream[K, (Iterable[V], Iterable[W])]

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    Return a new DStream by applying 'cogroup' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'cogroup' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

  12. def combineByKey[C](createCombiner: Function[V, C], mergeValue: Function2[C, V, C], mergeCombiners: Function2[C, C, C], partitioner: Partitioner, mapSideCombine: Boolean): JavaPairDStream[K, C]

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    Combine elements of each key in DStream's RDDs using custom function.

    Combine elements of each key in DStream's RDDs using custom function. This is similar to the combineByKey for RDDs. Please refer to combineByKey in org.apache.spark.rdd.PairRDDFunctions for more information.

  13. def combineByKey[C](createCombiner: Function[V, C], mergeValue: Function2[C, V, C], mergeCombiners: Function2[C, C, C], partitioner: Partitioner): JavaPairDStream[K, C]

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    Combine elements of each key in DStream's RDDs using custom function.

    Combine elements of each key in DStream's RDDs using custom function. This is similar to the combineByKey for RDDs. Please refer to combineByKey in org.apache.spark.rdd.PairRDDFunctions for more information.

  14. def compute(validTime: Time): JavaPairRDD[K, V]

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    Method that generates an RDD for the given Duration

  15. def context(): StreamingContext

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    Return the org.apache.spark.streaming.StreamingContext associated with this DStream

    Return the org.apache.spark.streaming.StreamingContext associated with this DStream

    Definition Classes
    JavaDStreamLike
  16. def count(): JavaDStream[Long]

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    Return a new DStream in which each RDD has a single element generated by counting each RDD of this DStream.

    Return a new DStream in which each RDD has a single element generated by counting each RDD of this DStream.

    Definition Classes
    JavaDStreamLike
  17. def countByValue(numPartitions: Int): JavaPairDStream[(K, V), Long]

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    Return a new DStream in which each RDD contains the counts of each distinct value in each RDD of this DStream.

    Return a new DStream in which each RDD contains the counts of each distinct value in each RDD of this DStream. Hash partitioning is used to generate the RDDs with numPartitions partitions.

    numPartitions

    number of partitions of each RDD in the new DStream.

    Definition Classes
    JavaDStreamLike
  18. def countByValue(): JavaPairDStream[(K, V), Long]

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    Return a new DStream in which each RDD contains the counts of each distinct value in each RDD of this DStream.

    Return a new DStream in which each RDD contains the counts of each distinct value in each RDD of this DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

    Definition Classes
    JavaDStreamLike
  19. def countByValueAndWindow(windowDuration: Duration, slideDuration: Duration, numPartitions: Int): JavaPairDStream[(K, V), Long]

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    Return a new DStream in which each RDD contains the count of distinct elements in RDDs in a sliding window over this DStream.

    Return a new DStream in which each RDD contains the count of distinct elements in RDDs in a sliding window over this DStream. Hash partitioning is used to generate the RDDs with numPartitions partitions.

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    numPartitions

    number of partitions of each RDD in the new DStream.

    Definition Classes
    JavaDStreamLike
  20. def countByValueAndWindow(windowDuration: Duration, slideDuration: Duration): JavaPairDStream[(K, V), Long]

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    Return a new DStream in which each RDD contains the count of distinct elements in RDDs in a sliding window over this DStream.

    Return a new DStream in which each RDD contains the count of distinct elements in RDDs in a sliding window over this DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    Definition Classes
    JavaDStreamLike
  21. def countByWindow(windowDuration: Duration, slideDuration: Duration): JavaDStream[Long]

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    Return a new DStream in which each RDD has a single element generated by counting the number of elements in a window over this DStream.

    Return a new DStream in which each RDD has a single element generated by counting the number of elements in a window over this DStream. windowDuration and slideDuration are as defined in the window() operation. This is equivalent to window(windowDuration, slideDuration).count()

    Definition Classes
    JavaDStreamLike
  22. val dstream: DStream[(K, V)]

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    Definition Classes
    JavaPairDStreamJavaDStreamLike
  23. final def eq(arg0: AnyRef): Boolean

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    Definition Classes
    AnyRef
  24. def equals(arg0: Any): Boolean

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  25. def filter(f: Function[(K, V), Boolean]): JavaPairDStream[K, V]

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    Return a new DStream containing only the elements that satisfy a predicate.

  26. def finalize(): Unit

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    Attributes
    protected[java.lang]
    Definition Classes
    AnyRef
    Annotations
    @throws( classOf[java.lang.Throwable] )
  27. def flatMap[U](f: FlatMapFunction[(K, V), U]): JavaDStream[U]

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    Return a new DStream by applying a function to all elements of this DStream, and then flattening the results

    Return a new DStream by applying a function to all elements of this DStream, and then flattening the results

    Definition Classes
    JavaDStreamLike
  28. def flatMapToPair[K2, V2](f: PairFlatMapFunction[(K, V), K2, V2]): JavaPairDStream[K2, V2]

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    Return a new DStream by applying a function to all elements of this DStream, and then flattening the results

    Return a new DStream by applying a function to all elements of this DStream, and then flattening the results

    Definition Classes
    JavaDStreamLike
  29. def flatMapValues[U](f: Function[V, Iterable[U]]): JavaPairDStream[K, U]

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    Return a new DStream by applying a flatmap function to the value of each key-value pairs in 'this' DStream without changing the key.

  30. def foreachRDD(foreachFunc: VoidFunction2[JavaPairRDD[K, V], Time]): Unit

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    Apply a function to each RDD in this DStream.

    Apply a function to each RDD in this DStream. This is an output operator, so 'this' DStream will be registered as an output stream and therefore materialized.

    Definition Classes
    JavaDStreamLike
  31. def foreachRDD(foreachFunc: VoidFunction[JavaPairRDD[K, V]]): Unit

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    Apply a function to each RDD in this DStream.

    Apply a function to each RDD in this DStream. This is an output operator, so 'this' DStream will be registered as an output stream and therefore materialized.

    Definition Classes
    JavaDStreamLike
  32. def fullOuterJoin[W](other: JavaPairDStream[K, W], partitioner: Partitioner): JavaPairDStream[K, (Optional[V], Optional[W])]

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    Return a new DStream by applying 'full outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'full outer join' between RDDs of this DStream and other DStream. The supplied org.apache.spark.Partitioner is used to control the partitioning of each RDD.

  33. def fullOuterJoin[W](other: JavaPairDStream[K, W], numPartitions: Int): JavaPairDStream[K, (Optional[V], Optional[W])]

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    Return a new DStream by applying 'full outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'full outer join' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with numPartitions partitions.

  34. def fullOuterJoin[W](other: JavaPairDStream[K, W]): JavaPairDStream[K, (Optional[V], Optional[W])]

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    Return a new DStream by applying 'full outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'full outer join' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

  35. final def getClass(): Class[_]

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    Definition Classes
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  36. def glom(): JavaDStream[List[(K, V)]]

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    Return a new DStream in which each RDD is generated by applying glom() to each RDD of this DStream.

    Return a new DStream in which each RDD is generated by applying glom() to each RDD of this DStream. Applying glom() to an RDD coalesces all elements within each partition into an array.

    Definition Classes
    JavaDStreamLike
  37. def groupByKey(partitioner: Partitioner): JavaPairDStream[K, Iterable[V]]

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    Return a new DStream by applying groupByKey on each RDD of this DStream.

    Return a new DStream by applying groupByKey on each RDD of this DStream. Therefore, the values for each key in this DStream's RDDs are grouped into a single sequence to generate the RDDs of the new DStream. org.apache.spark.Partitioner is used to control the partitioning of each RDD.

  38. def groupByKey(numPartitions: Int): JavaPairDStream[K, Iterable[V]]

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    Return a new DStream by applying groupByKey to each RDD.

    Return a new DStream by applying groupByKey to each RDD. Hash partitioning is used to generate the RDDs with numPartitions partitions.

  39. def groupByKey(): JavaPairDStream[K, Iterable[V]]

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    Return a new DStream by applying groupByKey to each RDD.

    Return a new DStream by applying groupByKey to each RDD. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

  40. def groupByKeyAndWindow(windowDuration: Duration, slideDuration: Duration, partitioner: Partitioner): JavaPairDStream[K, Iterable[V]]

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    Return a new DStream by applying groupByKey over a sliding window on this DStream.

    Return a new DStream by applying groupByKey over a sliding window on this DStream. Similar to DStream.groupByKey(), but applies it over a sliding window.

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    partitioner

    Partitioner for controlling the partitioning of each RDD in the new DStream.

  41. def groupByKeyAndWindow(windowDuration: Duration, slideDuration: Duration, numPartitions: Int): JavaPairDStream[K, Iterable[V]]

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    Return a new DStream by applying groupByKey over a sliding window on this DStream.

    Return a new DStream by applying groupByKey over a sliding window on this DStream. Similar to DStream.groupByKey(), but applies it over a sliding window. Hash partitioning is used to generate the RDDs with numPartitions partitions.

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    numPartitions

    Number of partitions of each RDD in the new DStream.

  42. def groupByKeyAndWindow(windowDuration: Duration, slideDuration: Duration): JavaPairDStream[K, Iterable[V]]

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    Return a new DStream by applying groupByKey over a sliding window.

    Return a new DStream by applying groupByKey over a sliding window. Similar to DStream.groupByKey(), but applies it over a sliding window. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

  43. def groupByKeyAndWindow(windowDuration: Duration): JavaPairDStream[K, Iterable[V]]

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    Return a new DStream by applying groupByKey over a sliding window.

    Return a new DStream by applying groupByKey over a sliding window. This is similar to DStream.groupByKey() but applies it over a sliding window. The new DStream generates RDDs with the same interval as this DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

  44. def hashCode(): Int

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  45. final def isInstanceOf[T0]: Boolean

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    Any
  46. def join[W](other: JavaPairDStream[K, W], partitioner: Partitioner): JavaPairDStream[K, (V, W)]

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    Return a new DStream by applying 'join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'join' between RDDs of this DStream and other DStream. The supplied org.apache.spark.Partitioner is used to control the partitioning of each RDD.

  47. def join[W](other: JavaPairDStream[K, W], numPartitions: Int): JavaPairDStream[K, (V, W)]

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    Return a new DStream by applying 'join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'join' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with numPartitions partitions.

  48. def join[W](other: JavaPairDStream[K, W]): JavaPairDStream[K, (V, W)]

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    Return a new DStream by applying 'join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'join' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

  49. implicit val kManifest: ClassTag[K]

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  50. def leftOuterJoin[W](other: JavaPairDStream[K, W], partitioner: Partitioner): JavaPairDStream[K, (V, Optional[W])]

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    Return a new DStream by applying 'left outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'left outer join' between RDDs of this DStream and other DStream. The supplied org.apache.spark.Partitioner is used to control the partitioning of each RDD.

  51. def leftOuterJoin[W](other: JavaPairDStream[K, W], numPartitions: Int): JavaPairDStream[K, (V, Optional[W])]

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    Return a new DStream by applying 'left outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'left outer join' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with numPartitions partitions.

  52. def leftOuterJoin[W](other: JavaPairDStream[K, W]): JavaPairDStream[K, (V, Optional[W])]

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    Return a new DStream by applying 'left outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'left outer join' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

  53. def map[R](f: Function[(K, V), R]): JavaDStream[R]

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    Return a new DStream by applying a function to all elements of this DStream.

    Return a new DStream by applying a function to all elements of this DStream.

    Definition Classes
    JavaDStreamLike
  54. def mapPartitions[U](f: FlatMapFunction[Iterator[(K, V)], U]): JavaDStream[U]

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    Return a new DStream in which each RDD is generated by applying mapPartitions() to each RDDs of this DStream.

    Return a new DStream in which each RDD is generated by applying mapPartitions() to each RDDs of this DStream. Applying mapPartitions() to an RDD applies a function to each partition of the RDD.

    Definition Classes
    JavaDStreamLike
  55. def mapPartitionsToPair[K2, V2](f: PairFlatMapFunction[Iterator[(K, V)], K2, V2]): JavaPairDStream[K2, V2]

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    Return a new DStream in which each RDD is generated by applying mapPartitions() to each RDDs of this DStream.

    Return a new DStream in which each RDD is generated by applying mapPartitions() to each RDDs of this DStream. Applying mapPartitions() to an RDD applies a function to each partition of the RDD.

    Definition Classes
    JavaDStreamLike
  56. def mapToPair[K2, V2](f: PairFunction[(K, V), K2, V2]): JavaPairDStream[K2, V2]

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    Return a new DStream by applying a function to all elements of this DStream.

    Return a new DStream by applying a function to all elements of this DStream.

    Definition Classes
    JavaDStreamLike
  57. def mapValues[U](f: Function[V, U]): JavaPairDStream[K, U]

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    Return a new DStream by applying a map function to the value of each key-value pairs in 'this' DStream without changing the key.

  58. def mapWithState[StateType, MappedType](spec: StateSpec[K, V, StateType, MappedType]): JavaMapWithStateDStream[K, V, StateType, MappedType]

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    :: Experimental :: Return a JavaMapWithStateDStream by applying a function to every key-value element of this stream, while maintaining some state data for each unique key.

    :: Experimental :: Return a JavaMapWithStateDStream by applying a function to every key-value element of this stream, while maintaining some state data for each unique key. The mapping function and other specification (e.g. partitioners, timeouts, initial state data, etc.) of this transformation can be specified using StateSpec class. The state data is accessible in as a parameter of type State in the mapping function.

    Example of using mapWithState:

    // A mapping function that maintains an integer state and return a string
    Function3<String, Optional<Integer>, State<Integer>, String> mappingFunction =
        new Function3<String, Optional<Integer>, State<Integer>, String>() {
            @Override
            public Optional<String> call(Optional<Integer> value, State<Integer> state) {
                // Use state.exists(), state.get(), state.update() and state.remove()
                // to manage state, and return the necessary string
            }
        };
    
     JavaMapWithStateDStream<String, Integer, Integer, String> mapWithStateDStream =
         keyValueDStream.mapWithState(StateSpec.function(mappingFunc));
    StateType

    Class type of the state data

    MappedType

    Class type of the mapped data

    spec

    Specification of this transformation

    Annotations
    @Experimental()
  59. final def ne(arg0: AnyRef): Boolean

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  60. final def notify(): Unit

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  61. final def notifyAll(): Unit

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  62. def persist(storageLevel: StorageLevel): JavaPairDStream[K, V]

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    Persist the RDDs of this DStream with the given storage level

  63. def persist(): JavaPairDStream[K, V]

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    Persist RDDs of this DStream with the default storage level (MEMORY_ONLY_SER)

  64. def print(num: Int): Unit

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    Print the first num elements of each RDD generated in this DStream.

    Print the first num elements of each RDD generated in this DStream. This is an output operator, so this DStream will be registered as an output stream and there materialized.

    Definition Classes
    JavaDStreamLike
  65. def print(): Unit

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    Print the first ten elements of each RDD generated in this DStream.

    Print the first ten elements of each RDD generated in this DStream. This is an output operator, so this DStream will be registered as an output stream and there materialized.

    Definition Classes
    JavaDStreamLike
  66. def reduce(f: Function2[(K, V), (K, V), (K, V)]): JavaDStream[(K, V)]

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    Return a new DStream in which each RDD has a single element generated by reducing each RDD of this DStream.

    Return a new DStream in which each RDD has a single element generated by reducing each RDD of this DStream.

    Definition Classes
    JavaDStreamLike
  67. def reduceByKey(func: Function2[V, V, V], partitioner: Partitioner): JavaPairDStream[K, V]

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    Return a new DStream by applying reduceByKey to each RDD.

    Return a new DStream by applying reduceByKey to each RDD. The values for each key are merged using the supplied reduce function. org.apache.spark.Partitioner is used to control the partitioning of each RDD.

  68. def reduceByKey(func: Function2[V, V, V], numPartitions: Int): JavaPairDStream[K, V]

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    Return a new DStream by applying reduceByKey to each RDD.

    Return a new DStream by applying reduceByKey to each RDD. The values for each key are merged using the supplied reduce function. Hash partitioning is used to generate the RDDs with numPartitions partitions.

  69. def reduceByKey(func: Function2[V, V, V]): JavaPairDStream[K, V]

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    Return a new DStream by applying reduceByKey to each RDD.

    Return a new DStream by applying reduceByKey to each RDD. The values for each key are merged using the associative and commutative reduce function. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

  70. def reduceByKeyAndWindow(reduceFunc: Function2[V, V, V], invReduceFunc: Function2[V, V, V], windowDuration: Duration, slideDuration: Duration, partitioner: Partitioner, filterFunc: Function[(K, V), Boolean]): JavaPairDStream[K, V]

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    Return a new DStream by applying incremental reduceByKey over a sliding window.

    Return a new DStream by applying incremental reduceByKey over a sliding window. The reduced value of over a new window is calculated using the old window's reduce value :

    1. reduce the new values that entered the window (e.g., adding new counts) 2. "inverse reduce" the old values that left the window (e.g., subtracting old counts) This is more efficient that reduceByKeyAndWindow without "inverse reduce" function. However, it is applicable to only "invertible reduce functions".
    reduceFunc

    associative and commutative reduce function

    invReduceFunc

    inverse function

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    partitioner

    Partitioner for controlling the partitioning of each RDD in the new DStream.

    filterFunc

    function to filter expired key-value pairs; only pairs that satisfy the function are retained set this to null if you do not want to filter

  71. def reduceByKeyAndWindow(reduceFunc: Function2[V, V, V], invReduceFunc: Function2[V, V, V], windowDuration: Duration, slideDuration: Duration, numPartitions: Int, filterFunc: Function[(K, V), Boolean]): JavaPairDStream[K, V]

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    Return a new DStream by applying incremental reduceByKey over a sliding window.

    Return a new DStream by applying incremental reduceByKey over a sliding window. The reduced value of over a new window is calculated using the old window's reduce value :

    1. reduce the new values that entered the window (e.g., adding new counts) 2. "inverse reduce" the old values that left the window (e.g., subtracting old counts) This is more efficient that reduceByKeyAndWindow without "inverse reduce" function. However, it is applicable to only "invertible reduce functions". Hash partitioning is used to generate the RDDs with numPartitions partitions.
    reduceFunc

    associative and commutative reduce function

    invReduceFunc

    inverse function

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    numPartitions

    number of partitions of each RDD in the new DStream.

    filterFunc

    function to filter expired key-value pairs; only pairs that satisfy the function are retained set this to null if you do not want to filter

  72. def reduceByKeyAndWindow(reduceFunc: Function2[V, V, V], invReduceFunc: Function2[V, V, V], windowDuration: Duration, slideDuration: Duration): JavaPairDStream[K, V]

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    Return a new DStream by reducing over a using incremental computation.

    Return a new DStream by reducing over a using incremental computation. The reduced value of over a new window is calculated using the old window's reduce value :

    1. reduce the new values that entered the window (e.g., adding new counts) 2. "inverse reduce" the old values that left the window (e.g., subtracting old counts) This is more efficient that reduceByKeyAndWindow without "inverse reduce" function. However, it is applicable to only "invertible reduce functions". Hash partitioning is used to generate the RDDs with Spark's default number of partitions.
    reduceFunc

    associative and commutative reduce function

    invReduceFunc

    inverse function; such that for all y, invertible x: invReduceFunc(reduceFunc(x, y), x) = y

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

  73. def reduceByKeyAndWindow(reduceFunc: Function2[V, V, V], windowDuration: Duration, slideDuration: Duration, partitioner: Partitioner): JavaPairDStream[K, V]

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    Return a new DStream by applying reduceByKey over a sliding window.

    Return a new DStream by applying reduceByKey over a sliding window. Similar to DStream.reduceByKey(), but applies it over a sliding window.

    reduceFunc

    associative rand commutative educe function

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    partitioner

    Partitioner for controlling the partitioning of each RDD in the new DStream.

  74. def reduceByKeyAndWindow(reduceFunc: Function2[V, V, V], windowDuration: Duration, slideDuration: Duration, numPartitions: Int): JavaPairDStream[K, V]

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    Return a new DStream by applying reduceByKey over a sliding window.

    Return a new DStream by applying reduceByKey over a sliding window. This is similar to DStream.reduceByKey() but applies it over a sliding window. Hash partitioning is used to generate the RDDs with numPartitions partitions.

    reduceFunc

    associative and commutative reduce function

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    numPartitions

    Number of partitions of each RDD in the new DStream.

  75. def reduceByKeyAndWindow(reduceFunc: Function2[V, V, V], windowDuration: Duration, slideDuration: Duration): JavaPairDStream[K, V]

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    Return a new DStream by applying reduceByKey over a sliding window.

    Return a new DStream by applying reduceByKey over a sliding window. This is similar to DStream.reduceByKey() but applies it over a sliding window. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

    reduceFunc

    associative and commutative reduce function

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

  76. def reduceByKeyAndWindow(reduceFunc: Function2[V, V, V], windowDuration: Duration): JavaPairDStream[K, V]

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    Create a new DStream by applying reduceByKey over a sliding window on this DStream.

    Create a new DStream by applying reduceByKey over a sliding window on this DStream. Similar to DStream.reduceByKey(), but applies it over a sliding window. The new DStream generates RDDs with the same interval as this DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

    reduceFunc

    associative and commutative reduce function

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

  77. def reduceByWindow(reduceFunc: Function2[(K, V), (K, V), (K, V)], invReduceFunc: Function2[(K, V), (K, V), (K, V)], windowDuration: Duration, slideDuration: Duration): JavaDStream[(K, V)]

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    Return a new DStream in which each RDD has a single element generated by reducing all elements in a sliding window over this DStream.

    Return a new DStream in which each RDD has a single element generated by reducing all elements in a sliding window over this DStream. However, the reduction is done incrementally using the old window's reduced value :

    1. reduce the new values that entered the window (e.g., adding new counts) 2. "inverse reduce" the old values that left the window (e.g., subtracting old counts) This is more efficient than reduceByWindow without "inverse reduce" function. However, it is applicable to only "invertible reduce functions".
    reduceFunc

    associative and commutative reduce function

    invReduceFunc

    inverse reduce function; such that for all y, invertible x: invReduceFunc(reduceFunc(x, y), x) = y

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    Definition Classes
    JavaDStreamLike
  78. def reduceByWindow(reduceFunc: Function2[(K, V), (K, V), (K, V)], windowDuration: Duration, slideDuration: Duration): JavaDStream[(K, V)]

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    Return a new DStream in which each RDD has a single element generated by reducing all elements in a sliding window over this DStream.

    Return a new DStream in which each RDD has a single element generated by reducing all elements in a sliding window over this DStream.

    reduceFunc

    associative and commutative reduce function

    windowDuration

    width of the window; must be a multiple of this DStream's batching interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's batching interval

    Definition Classes
    JavaDStreamLike
  79. def repartition(numPartitions: Int): JavaPairDStream[K, V]

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    Return a new DStream with an increased or decreased level of parallelism.

    Return a new DStream with an increased or decreased level of parallelism. Each RDD in the returned DStream has exactly numPartitions partitions.

  80. def rightOuterJoin[W](other: JavaPairDStream[K, W], partitioner: Partitioner): JavaPairDStream[K, (Optional[V], W)]

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    Return a new DStream by applying 'right outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'right outer join' between RDDs of this DStream and other DStream. The supplied org.apache.spark.Partitioner is used to control the partitioning of each RDD.

  81. def rightOuterJoin[W](other: JavaPairDStream[K, W], numPartitions: Int): JavaPairDStream[K, (Optional[V], W)]

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    Return a new DStream by applying 'right outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'right outer join' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with numPartitions partitions.

  82. def rightOuterJoin[W](other: JavaPairDStream[K, W]): JavaPairDStream[K, (Optional[V], W)]

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    Return a new DStream by applying 'right outer join' between RDDs of this DStream and other DStream.

    Return a new DStream by applying 'right outer join' between RDDs of this DStream and other DStream. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

  83. def saveAsHadoopFiles[F <: OutputFormat[_, _]](prefix: String, suffix: String, keyClass: Class[_], valueClass: Class[_], outputFormatClass: Class[F], conf: JobConf): Unit

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    Save each RDD in this DStream as a Hadoop file.

    Save each RDD in this DStream as a Hadoop file. The file name at each batch interval is generated based on prefix and suffix: "prefix-TIME_IN_MS.suffix".

  84. def saveAsHadoopFiles[F <: OutputFormat[_, _]](prefix: String, suffix: String, keyClass: Class[_], valueClass: Class[_], outputFormatClass: Class[F]): Unit

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    Save each RDD in this DStream as a Hadoop file.

    Save each RDD in this DStream as a Hadoop file. The file name at each batch interval is generated based on prefix and suffix: "prefix-TIME_IN_MS.suffix".

  85. def saveAsHadoopFiles(prefix: String, suffix: String): Unit

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    Save each RDD in this DStream as a Hadoop file.

    Save each RDD in this DStream as a Hadoop file. The file name at each batch interval is generated based on prefix and suffix: "prefix-TIME_IN_MS.suffix".

  86. def saveAsNewAPIHadoopFiles[F <: OutputFormat[_, _]](prefix: String, suffix: String, keyClass: Class[_], valueClass: Class[_], outputFormatClass: Class[F], conf: Configuration = ...): Unit

    Permalink

    Save each RDD in this DStream as a Hadoop file.

    Save each RDD in this DStream as a Hadoop file. The file name at each batch interval is generated based on prefix and suffix: "prefix-TIME_IN_MS.suffix".

  87. def saveAsNewAPIHadoopFiles[F <: OutputFormat[_, _]](prefix: String, suffix: String, keyClass: Class[_], valueClass: Class[_], outputFormatClass: Class[F]): Unit

    Permalink

    Save each RDD in this DStream as a Hadoop file.

    Save each RDD in this DStream as a Hadoop file. The file name at each batch interval is generated based on prefix and suffix: "prefix-TIME_IN_MS.suffix".

  88. def saveAsNewAPIHadoopFiles(prefix: String, suffix: String): Unit

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    Save each RDD in this DStream as a Hadoop file.

    Save each RDD in this DStream as a Hadoop file. The file name at each batch interval is generated based on prefix and suffix: "prefix-TIME_IN_MS.suffix".

  89. implicit def scalaIntToJavaLong(in: DStream[Long]): JavaDStream[Long]

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    Definition Classes
    JavaDStreamLike
  90. def slice(fromTime: Time, toTime: Time): List[JavaPairRDD[K, V]]

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    Return all the RDDs between 'fromDuration' to 'toDuration' (both included)

    Return all the RDDs between 'fromDuration' to 'toDuration' (both included)

    Definition Classes
    JavaDStreamLike
  91. final def synchronized[T0](arg0: ⇒ T0): T0

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    Definition Classes
    AnyRef
  92. def toJavaDStream(): JavaDStream[(K, V)]

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    Convert to a JavaDStream

  93. def toString(): String

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    Definition Classes
    AnyRef → Any
  94. def transform[U](transformFunc: Function2[JavaPairRDD[K, V], Time, JavaRDD[U]]): JavaDStream[U]

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    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream.

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream.

    Definition Classes
    JavaDStreamLike
  95. def transform[U](transformFunc: Function[JavaPairRDD[K, V], JavaRDD[U]]): JavaDStream[U]

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    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream.

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream.

    Definition Classes
    JavaDStreamLike
  96. def transformToPair[K2, V2](transformFunc: Function2[JavaPairRDD[K, V], Time, JavaPairRDD[K2, V2]]): JavaPairDStream[K2, V2]

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    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream.

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream.

    Definition Classes
    JavaDStreamLike
  97. def transformToPair[K2, V2](transformFunc: Function[JavaPairRDD[K, V], JavaPairRDD[K2, V2]]): JavaPairDStream[K2, V2]

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    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream.

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream.

    Definition Classes
    JavaDStreamLike
  98. def transformWith[K2, V2, W](other: JavaPairDStream[K2, V2], transformFunc: Function3[JavaPairRDD[K, V], JavaPairRDD[K2, V2], Time, JavaRDD[W]]): JavaDStream[W]

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    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream and 'other' DStream.

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream and 'other' DStream.

    Definition Classes
    JavaDStreamLike
  99. def transformWith[U, W](other: JavaDStream[U], transformFunc: Function3[JavaPairRDD[K, V], JavaRDD[U], Time, JavaRDD[W]]): JavaDStream[W]

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    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream and 'other' DStream.

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream and 'other' DStream.

    Definition Classes
    JavaDStreamLike
  100. def transformWithToPair[K2, V2, K3, V3](other: JavaPairDStream[K2, V2], transformFunc: Function3[JavaPairRDD[K, V], JavaPairRDD[K2, V2], Time, JavaPairRDD[K3, V3]]): JavaPairDStream[K3, V3]

    Permalink

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream and 'other' DStream.

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream and 'other' DStream.

    Definition Classes
    JavaDStreamLike
  101. def transformWithToPair[U, K2, V2](other: JavaDStream[U], transformFunc: Function3[JavaPairRDD[K, V], JavaRDD[U], Time, JavaPairRDD[K2, V2]]): JavaPairDStream[K2, V2]

    Permalink

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream and 'other' DStream.

    Return a new DStream in which each RDD is generated by applying a function on each RDD of 'this' DStream and 'other' DStream.

    Definition Classes
    JavaDStreamLike
  102. def union(that: JavaPairDStream[K, V]): JavaPairDStream[K, V]

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    Return a new DStream by unifying data of another DStream with this DStream.

    Return a new DStream by unifying data of another DStream with this DStream.

    that

    Another DStream having the same interval (i.e., slideDuration) as this DStream.

  103. def updateStateByKey[S](updateFunc: Function2[List[V], Optional[S], Optional[S]], partitioner: Partitioner, initialRDD: JavaPairRDD[K, S]): JavaPairDStream[K, S]

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    Return a new "state" DStream where the state for each key is updated by applying the given function on the previous state of the key and the new values of the key.

    Return a new "state" DStream where the state for each key is updated by applying the given function on the previous state of the key and the new values of the key. org.apache.spark.Partitioner is used to control the partitioning of each RDD.

    S

    State type

    updateFunc

    State update function. If this function returns None, then corresponding state key-value pair will be eliminated.

    partitioner

    Partitioner for controlling the partitioning of each RDD in the new DStream.

    initialRDD

    initial state value of each key.

  104. def updateStateByKey[S](updateFunc: Function2[List[V], Optional[S], Optional[S]], partitioner: Partitioner): JavaPairDStream[K, S]

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    Return a new "state" DStream where the state for each key is updated by applying the given function on the previous state of the key and the new values of the key.

    Return a new "state" DStream where the state for each key is updated by applying the given function on the previous state of the key and the new values of the key. org.apache.spark.Partitioner is used to control the partitioning of each RDD.

    S

    State type

    updateFunc

    State update function. If this function returns None, then corresponding state key-value pair will be eliminated.

    partitioner

    Partitioner for controlling the partitioning of each RDD in the new DStream.

  105. def updateStateByKey[S](updateFunc: Function2[List[V], Optional[S], Optional[S]], numPartitions: Int): JavaPairDStream[K, S]

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    Return a new "state" DStream where the state for each key is updated by applying the given function on the previous state of the key and the new values of each key.

    Return a new "state" DStream where the state for each key is updated by applying the given function on the previous state of the key and the new values of each key. Hash partitioning is used to generate the RDDs with numPartitions partitions.

    S

    State type

    updateFunc

    State update function. If this function returns None, then corresponding state key-value pair will be eliminated.

    numPartitions

    Number of partitions of each RDD in the new DStream.

  106. def updateStateByKey[S](updateFunc: Function2[List[V], Optional[S], Optional[S]]): JavaPairDStream[K, S]

    Permalink

    Return a new "state" DStream where the state for each key is updated by applying the given function on the previous state of the key and the new values of each key.

    Return a new "state" DStream where the state for each key is updated by applying the given function on the previous state of the key and the new values of each key. Hash partitioning is used to generate the RDDs with Spark's default number of partitions.

    S

    State type

    updateFunc

    State update function. If this function returns None, then corresponding state key-value pair will be eliminated.

  107. implicit val vManifest: ClassTag[V]

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  108. final def wait(): Unit

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    Definition Classes
    AnyRef
    Annotations
    @throws( ... )
  109. final def wait(arg0: Long, arg1: Int): Unit

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    Definition Classes
    AnyRef
    Annotations
    @throws( ... )
  110. final def wait(arg0: Long): Unit

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    Definition Classes
    AnyRef
    Annotations
    @throws( ... )
  111. def window(windowDuration: Duration, slideDuration: Duration): JavaPairDStream[K, V]

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    Return a new DStream which is computed based on windowed batches of this DStream.

    Return a new DStream which is computed based on windowed batches of this DStream.

    windowDuration

    duration (i.e., width) of the window; must be a multiple of this DStream's interval

    slideDuration

    sliding interval of the window (i.e., the interval after which the new DStream will generate RDDs); must be a multiple of this DStream's interval

  112. def window(windowDuration: Duration): JavaPairDStream[K, V]

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    Return a new DStream which is computed based on windowed batches of this DStream.

    Return a new DStream which is computed based on windowed batches of this DStream. The new DStream generates RDDs with the same interval as this DStream.

    windowDuration

    width of the window; must be a multiple of this DStream's interval.

  113. def wrapRDD(rdd: RDD[(K, V)]): JavaPairRDD[K, V]

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    Definition Classes
    JavaPairDStreamJavaDStreamLike

Inherited from AbstractJavaDStreamLike[(K, V), JavaPairDStream[K, V], JavaPairRDD[K, V]]

Inherited from JavaDStreamLike[(K, V), JavaPairDStream[K, V], JavaPairRDD[K, V]]

Inherited from Serializable

Inherited from Serializable

Inherited from AnyRef

Inherited from Any

Ungrouped