Value Members

1.  final def !=(arg0: Any): Boolean

   Definition Classes

   AnyRef → Any

2.  final def ##: Int

   Definition Classes

   AnyRef → Any

3.  final def ==(arg0: Any): Boolean

   Definition Classes

   AnyRef → Any

4.  def andThenPresent[D](present2: (Moments) => D): MonoidAggregator[Double, Moments, D]

   Like calling andThen on the present function

   Like calling andThen on the present function

   Definition Classes

   MonoidAggregator → Aggregator

5.  def append(l: Moments, r: Double): Moments

   Definition Classes

   Aggregator

6.  def appendAll(items: TraversableOnce[Double]): Moments

   Definition Classes

   MonoidAggregator

7.  def appendAll(old: Moments, items: TraversableOnce[Double]): Moments

   Definition Classes

   Aggregator

8.  def apply(inputs: TraversableOnce[Double]): Moments

   This may error if inputs are empty (for Monoid Aggregators it never will, instead you see present(Monoid.zero[B])

   This may error if inputs are empty (for Monoid Aggregators it never will, instead you see present(Monoid.zero[B])

   Definition Classes

   Aggregator

9.  def applyCumulatively[In <: TraversableOnce[Double], Out](inputs: In)(implicit bf: CanBuildFrom[In, Moments, Out]): Out

   This returns the cumulative sum of its inputs, in the same order.

   This returns the cumulative sum of its inputs, in the same order. If the inputs are empty, the result will be empty too.

   Definition Classes

   Aggregator

10.  def applyOption(inputs: TraversableOnce[Double]): Option[Moments]

    This returns None if the inputs are empty

    This returns None if the inputs are empty

    Definition Classes

    Aggregator

11.  final def asInstanceOf[T0]: T0

    Definition Classes

    Any

12.  def clone(): AnyRef

    Attributes

    protected[lang]

    Definition Classes

    AnyRef

    Annotations

    @throws(classOf[java.lang.CloneNotSupportedException]) @native()

13.  def collectBefore[A2](fn: PartialFunction[A2, Double]): MonoidAggregator[A2, Moments, Moments]

    Only transform values where the function is defined, else discard

    Only transform values where the function is defined, else discard

    Definition Classes

    MonoidAggregator

14.  def composePrepare[A2](prepare2: (A2) => Double): MonoidAggregator[A2, Moments, Moments]

    Like calling compose on the prepare function

    Like calling compose on the prepare function

    Definition Classes

    MonoidAggregator → Aggregator

15.  def cumulativeIterator(inputs: Iterator[Double]): Iterator[Moments]

    This returns the cumulative sum of its inputs, in the same order.

    This returns the cumulative sum of its inputs, in the same order. If the inputs are empty, the result will be empty too.

    Definition Classes

    Aggregator

16.  def either[A2, B2, C2](that: MonoidAggregator[A2, B2, C2]): MonoidAggregator[Either[Double, A2], (Moments, B2), (Moments, C2)]

    Build a MonoidAggregator that either takes left or right input and outputs the pair from both

    Build a MonoidAggregator that either takes left or right input and outputs the pair from both

    Definition Classes

    MonoidAggregator

17.  final def eq(arg0: AnyRef): Boolean

    Definition Classes

    AnyRef

18.  def equals(arg0: AnyRef): Boolean

    Definition Classes

    AnyRef → Any

19.  def filterBefore[A1 <: Double](pred: (A1) => Boolean): MonoidAggregator[A1, Moments, Moments]

    Only aggregate items that match a predicate

    Only aggregate items that match a predicate

    Definition Classes

    MonoidAggregator

20.  def finalize(): Unit

    Attributes

    protected[lang]

    Definition Classes

    AnyRef

    Annotations

    @throws(classOf[java.lang.Throwable])

21.  final def getClass(): Class[_ <: AnyRef]

    Definition Classes

    AnyRef → Any

    Annotations

    @native()

22.  def hashCode(): Int

    Definition Classes

    AnyRef → Any

    Annotations

    @native()

23.  final def isInstanceOf[T0]: Boolean

    Definition Classes

    Any

24.  def join[A2 <: Double, B2, C2](that: Aggregator[A2, B2, C2]): Aggregator[A2, (Moments, B2), (Moments, C2)]

    This allows you to run two aggregators on the same data with a single pass

    This allows you to run two aggregators on the same data with a single pass

    Definition Classes

    Aggregator

25.  def lift: MonoidAggregator[Double, Option[Moments], Option[Moments]]

    Definition Classes

    Aggregator

26.  val monoid: MomentsGroup.type

    Definition Classes

    MomentsAggregator → MonoidAggregator

27.  final def ne(arg0: AnyRef): Boolean

    Definition Classes

    AnyRef

28.  final def notify(): Unit

    Definition Classes

    AnyRef

    Annotations

    @native()

29.  final def notifyAll(): Unit

    Definition Classes

    AnyRef

    Annotations

    @native()

30.  def prepare(input: Double): Moments

    Definition Classes

    MomentsAggregator → Aggregator

31.  def present(m: Moments): Moments

    Definition Classes

    MomentsAggregator → Aggregator

32.  final def reduce(items: TraversableOnce[Moments]): Moments

    This may error if items is empty.

    This may error if items is empty. To be safe you might use reduceOption if you don't know that items is non-empty

    Definition Classes

    MonoidAggregator → Aggregator

33.  def reduce(l: Moments, r: Moments): Moments

    combine two inner values

    combine two inner values

    Definition Classes

    Aggregator

34.  def reduceOption(items: TraversableOnce[Moments]): Option[Moments]

    This is the safe version of the above.

    This is the safe version of the above. If the input in empty, return None, else reduce the items

    Definition Classes

    Aggregator

35.  def semigroup: Monoid[Moments]

    Definition Classes

    MonoidAggregator → Aggregator

36.  def sumBefore: MonoidAggregator[TraversableOnce[Double], Moments, Moments]

    This maps the inputs to Bs, then sums them, effectively flattening the inputs to the MonoidAggregator

    This maps the inputs to Bs, then sums them, effectively flattening the inputs to the MonoidAggregator

    Definition Classes

    MonoidAggregator

37.  final def synchronized[T0](arg0: => T0): T0

    Definition Classes

    AnyRef

38.  def toFold: Fold[Double, Option[Moments]]

    An Aggregator can be converted to a Fold, but not vice-versa Note, a Fold is more constrained so only do this if you require joining a Fold with an Aggregator to produce a Fold

    An Aggregator can be converted to a Fold, but not vice-versa Note, a Fold is more constrained so only do this if you require joining a Fold with an Aggregator to produce a Fold

    Definition Classes

    Aggregator

39.  def toString(): String

    Definition Classes

    AnyRef → Any

40.  final def wait(): Unit

    Definition Classes

    AnyRef

    Annotations

    @throws(classOf[java.lang.InterruptedException])

41.  final def wait(arg0: Long, arg1: Int): Unit

    Definition Classes

    AnyRef

    Annotations

    @throws(classOf[java.lang.InterruptedException])

42.  final def wait(arg0: Long): Unit

    Definition Classes

    AnyRef

    Annotations

    @throws(classOf[java.lang.InterruptedException]) @native()

43.  def zip[A2, B2, C2](ag2: MonoidAggregator[A2, B2, C2]): MonoidAggregator[(Double, A2), (Moments, B2), (Moments, C2)]

    This allows you to join two aggregators into one that takes a tuple input, which in turn allows you to chain .composePrepare onto the result if you have an initial input that has to be prepared differently for each of the joined aggregators.

    This allows you to join two aggregators into one that takes a tuple input, which in turn allows you to chain .composePrepare onto the result if you have an initial input that has to be prepared differently for each of the joined aggregators.

    The law here is: ag1.zip(ag2).apply(as.zip(bs)) == (ag1(as), ag2(bs))

    Definition Classes

    MonoidAggregator

44.  def zip[A2, B2, C2](ag2: Aggregator[A2, B2, C2]): Aggregator[(Double, A2), (Moments, B2), (Moments, C2)]

    This allows you to join two aggregators into one that takes a tuple input, which in turn allows you to chain .composePrepare onto the result if you have an initial input that has to be prepared differently for each of the joined aggregators.

    This allows you to join two aggregators into one that takes a tuple input, which in turn allows you to chain .composePrepare onto the result if you have an initial input that has to be prepared differently for each of the joined aggregators.

    The law here is: ag1.zip(ag2).apply(as.zip(bs)) == (ag1(as), ag2(bs))

    Definition Classes

    Aggregator