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/*
* Copyright (C) 2009-2020 Lightbend Inc.
*/
package akka.japi
import java.util.Collections.{ emptyList, singletonList }
import scala.collection.immutable
import scala.language.implicitConversions
import scala.reflect.ClassTag
import scala.runtime.AbstractPartialFunction
import scala.util.control.NoStackTrace
import com.github.ghik.silencer.silent
import akka.util.Collections.EmptyImmutableSeq
/**
* A Function interface. Used to create first-class-functions is Java.
*
* This class is kept for compatibility, but for future API's please prefer [[akka.japi.function.Function]].
*/
trait Function[T, R] {
@throws(classOf[Exception])
def apply(param: T): R
}
/**
* A Function interface. Used to create 2-arg first-class-functions is Java.
*
* This class is kept for compatibility, but for future API's please prefer [[akka.japi.function.Function2]].
*/
trait Function2[T1, T2, R] {
@throws(classOf[Exception])
def apply(arg1: T1, arg2: T2): R
}
/**
* A Procedure is like a Function, but it doesn't produce a return value.
*
* This class is kept for compatibility, but for future API's please prefer [[akka.japi.function.Procedure]].
*/
trait Procedure[T] {
@throws(classOf[Exception])
def apply(param: T): Unit
}
/**
* An executable piece of code that takes no parameters and doesn't return any value.
*
* This class is kept for compatibility, but for future API's please prefer [[akka.japi.function.Effect]].
*/
trait Effect {
@throws(classOf[Exception])
def apply(): Unit
}
/**
* Java API: Defines a criteria and determines whether the parameter meets this criteria.
*
* This class is kept for compatibility, but for future API's please prefer [[java.util.function.Predicate]].
*/
trait Predicate[T] {
def test(param: T): Boolean
}
/**
* Java API
* Represents a pair (tuple) of two elements.
*
* Additional tuple types for 3 to 22 values are defined in the `akka.japi.tuple` package, e.g. [[akka.japi.tuple.Tuple3]].
*/
@SerialVersionUID(1L)
case class Pair[A, B](first: A, second: B) {
def toScala: (A, B) = (first, second)
}
object Pair {
def create[A, B](first: A, second: B): Pair[A, B] = new Pair(first, second)
}
/**
* A constructor/factory, takes no parameters but creates a new value of type T every call.
*
* This class is kept for compatibility, but for future API's please prefer [[akka.japi.function.Creator]].
*/
@silent("@SerialVersionUID has no effect")
@SerialVersionUID(1L)
trait Creator[T] extends Serializable {
/**
* This method must return a different instance upon every call.
*/
@throws(classOf[Exception])
def create(): T
}
object JavaPartialFunction {
sealed abstract class NoMatchException extends RuntimeException with NoStackTrace
case object NoMatch extends NoMatchException
final def noMatch(): RuntimeException = NoMatch
}
/**
* Helper for implementing a *pure* partial function: it will possibly be
* invoked multiple times for a single “application”, because its only abstract
* method is used for both isDefinedAt() and apply(); the former is mapped to
* `isCheck == true` and the latter to `isCheck == false` for those cases where
* this is important to know.
*
* Failure to match is signaled by throwing `noMatch()`, i.e. not returning
* normally (the exception used in this case is pre-allocated, hence not
* that expensive).
*
* {{{
* new JavaPartialFunction() {
* public String apply(Object in, boolean isCheck) {
* if (in instanceof TheThing) {
* if (isCheck) return null; // to spare the expensive or side-effecting code
* return doSomethingWithTheThing((TheThing) in);
* } else {
* throw noMatch();
* }
* }
* }
* }}}
*
* The typical use of partial functions from Akka looks like the following:
*
* {{{
* if (pf.isDefinedAt(x)) {
* pf.apply(x);
* }
* }}}
*
* i.e. it will first call `JavaPartialFunction.apply(x, true)` and if that
* does not throw `noMatch()` it will continue with calling
* `JavaPartialFunction.apply(x, false)`.
*/
abstract class JavaPartialFunction[A, B] extends AbstractPartialFunction[A, B] {
import JavaPartialFunction._
@throws(classOf[Exception])
def apply(x: A, isCheck: Boolean): B
final def isDefinedAt(x: A): Boolean =
try {
apply(x, true); true
} catch { case NoMatch => false }
final override def apply(x: A): B =
try apply(x, false)
catch { case NoMatch => throw new MatchError(x) }
final override def applyOrElse[A1 <: A, B1 >: B](x: A1, default: A1 => B1): B1 =
try apply(x, false)
catch { case NoMatch => default(x) }
}
/**
* This class represents optional values. Instances of Option
* are either instances of case class Some or it is case
* object None.
*/
sealed abstract class Option[A] extends java.lang.Iterable[A] {
def get: A
/**
* Returns a if this is some(a) or defaultValue if
* this is none.
*/
def getOrElse[B >: A](defaultValue: B): B
def isEmpty: Boolean
def isDefined: Boolean = !isEmpty
def asScala: scala.Option[A]
def iterator: java.util.Iterator[A] = if (isEmpty) emptyList[A].iterator else singletonList(get).iterator
}
object Option {
/**
* Option factory that creates Some
*/
def some[A](v: A): Option[A] = Some(v)
/**
* Option factory that creates None
*/
def none[A] = None.asInstanceOf[Option[A]]
/**
* Option factory that creates None if
* v is null, Some(v) otherwise.
*/
def option[A](v: A): Option[A] = if (v == null) none else some(v)
/**
* Converts a Scala Option to a Java Option
*/
def fromScalaOption[T](scalaOption: scala.Option[T]): Option[T] = scalaOption match {
case scala.Some(r) => some(r)
case scala.None => none
}
/**
* Class Some[A] represents existing values of type
* A.
*/
final case class Some[A](v: A) extends Option[A] {
def get: A = v
def getOrElse[B >: A](defaultValue: B): B = v
def isEmpty: Boolean = false
def asScala: scala.Some[A] = scala.Some(v)
}
/**
* This case object represents non-existent values.
*/
private case object None extends Option[Nothing] {
def get: Nothing = throw new NoSuchElementException("None.get")
def getOrElse[B](defaultValue: B): B = defaultValue
def isEmpty: Boolean = true
def asScala: scala.None.type = scala.None
}
implicit def java2ScalaOption[A](o: Option[A]): scala.Option[A] = o.asScala
implicit def scala2JavaOption[A](o: scala.Option[A]): Option[A] = if (o.isDefined) some(o.get) else none
}
/**
* This class hold common utilities for Java
*/
object Util {
/**
* Returns a ClassTag describing the provided Class.
*/
def classTag[T](clazz: Class[T]): ClassTag[T] = ClassTag(clazz)
/**
* Returns an immutable.Seq representing the provided array of Classes,
* an overloading of the generic immutableSeq in Util, to accommodate for erasure.
*/
def immutableSeq(arr: Array[Class[_]]): immutable.Seq[Class[_]] = immutableSeq[Class[_]](arr)
/**
* Turns an array into an immutable Scala sequence (by copying it).
*/
def immutableSeq[T](arr: Array[T]): immutable.Seq[T] =
if ((arr ne null) && arr.length > 0) arr.toIndexedSeq else Nil
/**
* Turns an [[java.lang.Iterable]] into an immutable Scala sequence (by copying it).
*/
def immutableSeq[T](iterable: java.lang.Iterable[T]): immutable.Seq[T] =
iterable match {
case imm: immutable.Seq[_] => imm.asInstanceOf[immutable.Seq[T]]
case other =>
val i = other.iterator()
if (i.hasNext) {
val builder = new immutable.VectorBuilder[T]
while ({ builder += i.next(); i.hasNext }) ()
builder.result()
} else EmptyImmutableSeq
}
def immutableSingletonSeq[T](value: T): immutable.Seq[T] = value :: Nil
def javaArrayList[T](seq: Seq[T]): java.util.List[T] = {
val size = seq.size
val l = new java.util.ArrayList[T](size)
seq.foreach(l.add) // TODO could be optimised based on type of Seq
l
}
/**
* Turns an [[java.lang.Iterable]] into an immutable Scala IndexedSeq (by copying it).
*/
def immutableIndexedSeq[T](iterable: java.lang.Iterable[T]): immutable.IndexedSeq[T] =
immutableSeq(iterable).toVector
// TODO in case we decide to pull in scala-java8-compat methods below could be removed - https://github.com/akka/akka/issues/16247
def option[T](jOption: java.util.Optional[T]): scala.Option[T] =
scala.Option(jOption.orElse(null.asInstanceOf[T]))
}
