scala.concurrent.Future.never

object never extends Future[Nothing]

A Future which is never completed.

Value Members From scala.concurrent.Future

final def withFilter(p: (Nothing) ⇒ Boolean)(implicit executor: ExecutionContext): Future[Nothing]

Used by for-comprehensions.

  • Definition Classes
    • Future

(defined at scala.concurrent.Future)

Value Members From scala.concurrent.Future.never

def andThen[U](pf: PartialFunction[Try[Nothing], U])(implicit executor: ExecutionContext): Future[Nothing]

Applies the side-effecting function to the result of this future, and returns a new future with the result of this future.

This method allows one to enforce that the callbacks are executed in a specified order.

Note that if one of the chained andThen callbacks throws an exception, that exception is not propagated to the subsequent andThen callbacks. Instead, the subsequent andThen callbacks are given the original value of this future.

The following example prints out 5 :

val f = Future { 5 }
f andThen {
  case r => sys.error("runtime exception")
} andThen {
  case Failure(t) => println(t)
  case Success(v) => println(v)
}
  • U
    • only used to accept any return type of the given PartialFunction
  • pf
    • a PartialFunction which will be conditionally applied to the outcome of this Future
  • returns
    • a Future which will be completed with the exact same outcome as this Future but after the PartialFunction has been executed.
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def collect[S](pf: PartialFunction[Nothing, S])(implicit executor: ExecutionContext): Future[S]

Creates a new future by mapping the value of the current future, if the given partial function is defined at that value.

If the current future contains a value for which the partial function is defined, the new future will also hold that value. Otherwise, the resulting future will fail with a NoSuchElementException .

If the current future fails, then the resulting future also fails.

Example:

val f = Future { -5 }
val g = f collect {
  case x if x < 0 => -x
}
val h = f collect {
  case x if x > 0 => x * 2
}
g foreach println // Eventually prints 5
Await.result(h, Duration.Zero) // throw a NoSuchElementException
  • S
    • the type of the returned Future @param pf the PartialFunction to apply to the successful result of this Future
  • returns
    • a Future holding the result of application of the PartialFunction or a NoSuchElementException
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def failed: Future[Throwable]

The returned Future will be successfully completed with the Throwable of the original Future if the original Future fails.

If the original Future is successful, the returned Future is failed with a NoSuchElementException .

  • returns
    • a failed projection of this Future .
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def fallbackTo[U](that: Future[U]): Future[U]

Creates a new future which holds the result of this future if it was completed successfully, or, if not, the result of the that future if that is completed successfully. If both futures are failed, the resulting future holds the throwable object of the first future.

Using this method will not cause concurrent programs to become nondeterministic.

Example:

val f = Future { sys.error("failed") }
val g = Future { 5 }
val h = f fallbackTo g
h foreach println // Eventually prints 5
  • U
    • the type of the other Future and the resulting Future
  • that
    • the Future whose result we want to use if this Future fails.
  • returns
    • a Future with the successful result of this or that Future or the failure of this Future if both fail
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def filter(p: (Nothing) ⇒ Boolean)(implicit executor: ExecutionContext): Future[Nothing]

Creates a new future by filtering the value of the current future with a predicate.

If the current future contains a value which satisfies the predicate, the new future will also hold that value. Otherwise, the resulting future will fail with a NoSuchElementException .

If the current future fails, then the resulting future also fails.

Example:

val f = Future { 5 }
val g = f filter { _ % 2 == 1 }
val h = f filter { _ % 2 == 0 }
g foreach println // Eventually prints 5
Await.result(h, Duration.Zero) // throw a NoSuchElementException
  • p
    • the predicate to apply to the successful result of this Future
  • returns
    • a Future which will hold the successful result of this Future if it matches the predicate or a NoSuchElementException
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def flatMap[S](f: (Nothing) ⇒ Future[S])(implicit executor: ExecutionContext): Future[S]

Creates a new future by applying a function to the successful result of this future, and returns the result of the function as the new future. If this future is completed with an exception then the new future will also contain this exception.

Example:

val f = Future { 5 }
val g = Future { 3 }
val h = for {
  x: Int <- f // returns Future(5)
  y: Int <- g // returns Future(3)
} yield x + y

is translated to:

f flatMap { (x: Int) => g map { (y: Int) => x + y } }
  • S
    • the type of the returned Future
  • f
    • the function which will be applied to the successful result of this Future
  • returns
    • a Future which will be completed with the result of the application of the function
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def flatten[S](implicit ev: <:<[Nothing, Future[S]]): Future[S]

Creates a new future with one level of nesting flattened, this method is equivalent to flatMap(identity) .

  • S
    • the type of the returned Future
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def foreach[U](f: (Nothing) ⇒ U)(implicit executor: ExecutionContext): Unit

Asynchronously processes the value in the future once the value becomes available.

WARNING: Will not be called if this future is never completed or if it is completed with a failure.

Since this method executes asynchronously and does not produce a return value, any non-fatal exceptions thrown will be reported to the ExecutionContext .

  • U
    • only used to accept any return type of the given callback function
  • f
    • the function which will be executed if this Future completes with a result, the return value of f will be discarded.
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def mapTo[S](implicit tag: ClassTag[S]): Future[S]

Creates a new Future[S] which is completed with this Future ‘s result if that conforms to S ‘s erased type or a ClassCastException otherwise.

  • S
    • the type of the returned Future
  • tag
    • the ClassTag which will be used to cast the result of this Future
  • returns
    • a Future holding the casted result of this Future or a ClassCastException otherwise
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def map[S](f: (Nothing) ⇒ S)(implicit executor: ExecutionContext): Future[S]

Creates a new future by applying a function to the successful result of this future. If this future is completed with an exception then the new future will also contain this exception.

Example:

val f = Future { 5 }
val g = Future { 3 }
val h = for {
  x: Int <- f // returns Future(5)
  y: Int <- g // returns Future(3)
} yield x + y

is translated to:

f flatMap { (x: Int) => g map { (y: Int) => x + y } }
  • S
    • the type of the returned Future
  • f
    • the function which will be applied to the successful result of this Future
  • returns
    • a Future which will be completed with the result of the application of the function
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def onComplete[U](f: (Try[Nothing]) ⇒ U)(implicit executor: ExecutionContext): Unit

When this future is completed, either through an exception, or a value, apply the provided function.

If the future has already been completed, this will either be applied immediately or be scheduled asynchronously.

Since this method executes asynchronously and does not produce a return value, any non-fatal exceptions thrown will be reported to the ExecutionContext .

Multiple callbacks may be registered; there is no guarantee that they will be executed in a particular order.

The provided callback always runs in the provided implicit ExecutionContext , though there is no guarantee that the execute() method on the ExecutionContext will be called once per callback or that execute() will be called in the current thread. That is, the implementation may run multiple callbacks in a batch within a single execute() and it may run execute() either immediately or asynchronously.

  • U
    • only used to accept any return type of the given callback function
  • f
    • the function to be executed when this Future completes
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def onFailure[U](pf: PartialFunction[Throwable, U])(implicit executor: ExecutionContext): Unit

When this future is completed with a failure (i.e., with a throwable), apply the provided callback to the throwable.

The future may contain a throwable object and this means that the future failed. Futures obtained through combinators have the same exception as the future they were obtained from. The following throwable objects are not contained in the future:

  • Error - errors are not contained within futures
  • InterruptedException - not contained within futures
  • all scala.util.control.ControlThrowable except NonLocalReturnControl - not contained within futures

Instead, the future is completed with a ExecutionException with one of the exceptions above as the cause. If a future is failed with a scala.runtime.NonLocalReturnControl , it is completed with a value from that throwable instead.

If the future has already been completed with a failure, this will either be applied immediately or be scheduled asynchronously.

Will not be called in case that the future is completed with a value.

Since this method executes asynchronously and does not produce a return value, any non-fatal exceptions thrown will be reported to the ExecutionContext .

Multiple callbacks may be registered; there is no guarantee that they will be executed in a particular order.

The provided callback always runs in the provided implicit ExecutionContext , though there is no guarantee that the execute() method on the ExecutionContext will be called once per callback or that execute() will be called in the current thread. That is, the implementation may run multiple callbacks in a batch within a single execute() and it may run execute() either immediately or asynchronously.

  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def onSuccess[U](pf: PartialFunction[Nothing, U])(implicit executor: ExecutionContext): Unit

When this future is completed successfully (i.e., with a value), apply the provided partial function to the value if the partial function is defined at that value.

If the future has already been completed with a value, this will either be applied immediately or be scheduled asynchronously.

Since this method executes asynchronously and does not produce a return value, any non-fatal exceptions thrown will be reported to the ExecutionContext .

Multiple callbacks may be registered; there is no guarantee that they will be executed in a particular order.

The provided callback always runs in the provided implicit ExecutionContext , though there is no guarantee that the execute() method on the ExecutionContext will be called once per callback or that execute() will be called in the current thread. That is, the implementation may run multiple callbacks in a batch within a single execute() and it may run execute() either immediately or asynchronously.

  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def ready(atMost: Duration)(implicit permit: CanAwait): never.this.type

Await the “completed” state of this Awaitable .

  • This method should not be called directly; use Await.ready instead.*

  • atMost
    • maximum wait time, which may be negative (no waiting is done), Duration.Inf for unbounded waiting, or a finite positive duration
  • returns
    • this Awaitable
  • Definition Classes
    • never → Awaitable
  • Annotations
    • @ throws (clazz = classOf[TimeoutException]) @ throws (clazz = classOf[InterruptedException])
  • Exceptions thrown
    • IllegalArgumentException if atMost is Duration.Undefined InterruptedException if the current thread is interrupted while waiting TimeoutException if after waiting for the specified time this Awaitable is still not ready

(defined at scala.concurrent.Future.never)

def recoverWith[U](pf: PartialFunction[Throwable, Future[U]])(implicit executor: ExecutionContext): Future[U]

Creates a new future that will handle any matching throwable that this future might contain by assigning it a value of another future.

If there is no match, or if this future contains a valid result then the new future will contain the same result.

Example:

val f = Future { Int.MaxValue }
Future (6 / 0) recoverWith { case e: ArithmeticException => f } // result: Int.MaxValue
  • U
    • the type of the returned Future
  • pf
    • the PartialFunction to apply if this Future fails
  • returns
    • a Future with the successful value of this Future or the outcome of the Future returned by the PartialFunction
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def recover[U](pf: PartialFunction[Throwable, U])(implicit executor: ExecutionContext): Future[U]

Creates a new future that will handle any matching throwable that this future might contain. If there is no match, or if this future contains a valid result then the new future will contain the same.

Example:

Future (6 / 0) recover { case e: ArithmeticException => 0 } // result: 0
Future (6 / 0) recover { case e: NotFoundException   => 0 } // result: exception
Future (6 / 2) recover { case e: ArithmeticException => 0 } // result: 3
  • U
    • the type of the returned Future
  • pf
    • the PartialFunction to apply if this Future fails
  • returns
    • a Future with the successful value of this Future or the result of the PartialFunction
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def result(atMost: Duration)(implicit permit: CanAwait): Nothing

Await and return the result (of type T ) of this Awaitable .

  • This method should not be called directly; use Await.result instead.*

  • atMost
    • maximum wait time, which may be negative (no waiting is done), Duration.Inf for unbounded waiting, or a finite positive duration
  • returns
    • the result value if the Awaitable is completed within the specific maximum wait time
  • Definition Classes
    • never → Awaitable
  • Annotations
    • @ throws (clazz = classOf[Exception])
  • Exceptions thrown
    • IllegalArgumentException if atMost is Duration.Undefined InterruptedException if the current thread is interrupted while waiting TimeoutException if after waiting for the specified time this Awaitable is still not ready

(defined at scala.concurrent.Future.never)

def transformWith[S](f: (Try[Nothing]) ⇒ Future[S])(implicit executor: ExecutionContext): Future[S]

Creates a new Future by applying the specified function, which produces a Future, to the result of this Future. If there is any non-fatal exception thrown when ‘f’ is applied then that exception will be propagated to the resulting future.

  • S
    • the type of the returned Future
  • f
    • function that transforms the result of this future
  • returns
    • a Future that will be completed with the transformed value
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def transform[S](s: (Nothing) ⇒ S, f: (Throwable) ⇒ Throwable)(implicit executor: ExecutionContext): Future[S]

Creates a new future by applying the ‘s’ function to the successful result of this future, or the ‘f’ function to the failed result. If there is any non-fatal exception thrown when ‘s’ or ‘f’ is applied, that exception will be propagated to the resulting future.

  • S
    • the type of the returned Future
  • s
    • function that transforms a successful result of the receiver into a successful result of the returned future
  • f
    • function that transforms a failure of the receiver into a failure of the returned future
  • returns
    • a Future that will be completed with the transformed value
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def transform[S](f: (Try[Nothing]) ⇒ Try[S])(implicit executor: ExecutionContext): Future[S]

Creates a new Future by applying the specified function to the result of this Future. If there is any non-fatal exception thrown when ‘f’ is applied then that exception will be propagated to the resulting future.

  • S
    • the type of the returned Future
  • f
    • function that transforms the result of this future
  • returns
    • a Future that will be completed with the transformed value
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def value: Option[Try[Nothing]]

The current value of this Future .

Note: using this method yields nondeterministic dataflow programs.

If the future is not completed the returned value will be None . If the future is completed the value will be Some(Success(t)) if it contains a valid result, or Some(Failure(error)) if it contains an exception.

  • returns
    • None if the Future wasn’t completed, Some if it was.
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def zipWith[U, R](that: Future[U])(f: (Nothing, U) ⇒ R)(implicit executor: ExecutionContext): Future[R]

Zips the values of this and that future using a function f , and creates a new future holding the result.

If this future fails, the resulting future is failed with the throwable stored in this . Otherwise, if that future fails, the resulting future is failed with the throwable stored in that . If the application of f throws a throwable, the resulting future is failed with that throwable if it is non-fatal.

  • U
    • the type of the other Future
  • R
    • the type of the resulting Future
  • that
    • the other Future
  • f
    • the function to apply to the results of this and that
  • returns
    • a Future with the result of the application of f to the results of this and that
  • Definition Classes
    • never → Future

(defined at scala.concurrent.Future.never)

def zip[U](that: Future[U]): Future[(Nothing, U)]

Zips the values of this and that future, and creates a new future holding the tuple of their results.

If this future fails, the resulting future is failed with the throwable stored in this . Otherwise, if that future fails, the resulting future is failed with the throwable stored in that .

  • U
    • the type of the other Future
  • that
    • the other Future
  • returns
    • a Future with the results of both futures or the failure of the first of them that failed
  • Definition Classes
    • never → Future (defined at scala.concurrent.Future.never)

Full Source:

/*                     __                                               *\
**     ________ ___   / /  ___     Scala API                            **
**    / __/ __// _ | / /  / _ |    (c) 2003-2013, LAMP/EPFL             **
**  __\ \/ /__/ __ |/ /__/ __ |    http://scala-lang.org/               **
** /____/\___/_/ |_/____/_/ | |                                         **
**                          |/                                          **
\*                                                                      */

package scala.concurrent

import scala.language.higherKinds

import java.util.concurrent.{CountDownLatch, TimeUnit}
import java.util.concurrent.atomic.AtomicInteger

import scala.util.control.NonFatal
import scala.util.{Try, Success, Failure}
import scala.concurrent.duration._
import scala.collection.generic.CanBuildFrom
import scala.reflect.ClassTag


/** The trait that represents futures.
 *
 *  Asynchronous computations that yield futures are created with the `Future.apply` call:
 *
 *  {{{
 *  val s = "Hello"
 *  val f: Future[String] = Future {
 *    s + " future!"
 *  }
 *  f onSuccess {
 *    case msg => println(msg)
 *  }
 *  }}}
 *
 *  @author  Philipp Haller, Heather Miller, Aleksandar Prokopec, Viktor Klang
 *
 *  @see [[http://docs.scala-lang.org/overviews/core/futures.html Futures and Promises]]
 *
 *  @define multipleCallbacks
 *  Multiple callbacks may be registered; there is no guarantee that they will be
 *  executed in a particular order.
 *
 *  @define caughtThrowables
 *  The future may contain a throwable object and this means that the future failed.
 *  Futures obtained through combinators have the same exception as the future they were obtained from.
 *  The following throwable objects are not contained in the future:
 *  - `Error` - errors are not contained within futures
 *  - `InterruptedException` - not contained within futures
 *  - all `scala.util.control.ControlThrowable` except `NonLocalReturnControl` - not contained within futures
 *
 *  Instead, the future is completed with a ExecutionException with one of the exceptions above
 *  as the cause.
 *  If a future is failed with a `scala.runtime.NonLocalReturnControl`,
 *  it is completed with a value from that throwable instead.
 *
 *  @define swallowsExceptions
 *  Since this method executes asynchronously and does not produce a return value,
 *  any non-fatal exceptions thrown will be reported to the `ExecutionContext`.
 *
 *  @define nonDeterministic
 *  Note: using this method yields nondeterministic dataflow programs.
 *
 *  @define forComprehensionExamples
 *  Example:
 *
 *  {{{
 *  val f = Future { 5 }
 *  val g = Future { 3 }
 *  val h = for {
 *    x: Int <- f // returns Future(5)
 *    y: Int <- g // returns Future(3)
 *  } yield x + y
 *  }}}
 *
 *  is translated to:
 *
 *  {{{
 *  f flatMap { (x: Int) => g map { (y: Int) => x + y } }
 *  }}}
 *
 * @define callbackInContext
 * The provided callback always runs in the provided implicit
 *`ExecutionContext`, though there is no guarantee that the
 * `execute()` method on the `ExecutionContext` will be called once
 * per callback or that `execute()` will be called in the current
 * thread. That is, the implementation may run multiple callbacks
 * in a batch within a single `execute()` and it may run
 * `execute()` either immediately or asynchronously.
 */
trait Future[+T] extends Awaitable[T] {
  import Future.{ InternalCallbackExecutor => internalExecutor }

  /* Callbacks */

  /** When this future is completed successfully (i.e., with a value),
   *  apply the provided partial function to the value if the partial function
   *  is defined at that value.
   *
   *  If the future has already been completed with a value,
   *  this will either be applied immediately or be scheduled asynchronously.
   *
   *  $swallowsExceptions
   *  $multipleCallbacks
   *  $callbackInContext
   */
  @deprecated("use `foreach` or `onComplete` instead (keep in mind that they take total rather than partial functions)", "2.12")
  def onSuccess[U](pf: PartialFunction[T, U])(implicit executor: ExecutionContext): Unit = onComplete {
    case Success(v) =>
      pf.applyOrElse[T, Any](v, Predef.conforms[T]) // Exploiting the cached function to avoid MatchError
    case _ =>
  }

  /** When this future is completed with a failure (i.e., with a throwable),
   *  apply the provided callback to the throwable.
   *
   *  $caughtThrowables
   *
   *  If the future has already been completed with a failure,
   *  this will either be applied immediately or be scheduled asynchronously.
   *
   *  Will not be called in case that the future is completed with a value.
   *
   *  $swallowsExceptions
   *  $multipleCallbacks
   *  $callbackInContext
   */
  @deprecated("use `onComplete` or `failed.foreach` instead (keep in mind that they take total rather than partial functions)", "2.12")
  def onFailure[U](@deprecatedName('callback) pf: PartialFunction[Throwable, U])(implicit executor: ExecutionContext): Unit = onComplete {
    case Failure(t) =>
      pf.applyOrElse[Throwable, Any](t, Predef.conforms[Throwable]) // Exploiting the cached function to avoid MatchError
    case _ =>
  }

  /** When this future is completed, either through an exception, or a value,
   *  apply the provided function.
   *
   *  If the future has already been completed,
   *  this will either be applied immediately or be scheduled asynchronously.
   *
   *  $swallowsExceptions
   *  $multipleCallbacks
   *  $callbackInContext
   *
   * @tparam U    only used to accept any return type of the given callback function
   * @param f     the function to be executed when this `Future` completes
   */
  def onComplete[U](@deprecatedName('func) f: Try[T] => U)(implicit executor: ExecutionContext): Unit


  /* Miscellaneous */

  /** Returns whether the future has already been completed with
   *  a value or an exception.
   *
   *  $nonDeterministic
   *
   *  @return    `true` if the future is already completed, `false` otherwise
   */
  def isCompleted: Boolean

  /** The current value of this `Future`.
   *
   *  $nonDeterministic
   *
   *  If the future is not completed the returned value will be `None`.
   *  If the future is completed the value will be `Some(Success(t))`
   *  if it contains a valid result, or `Some(Failure(error))` if it contains
   *  an exception.
   *
   * @return    `None` if the `Future` wasn't completed, `Some` if it was.
   */
  def value: Option[Try[T]]


  /* Projections */

  /** The returned `Future` will be successfully completed with the `Throwable` of the original `Future`
   *  if the original `Future` fails.
   *
   *  If the original `Future` is successful, the returned `Future` is failed with a `NoSuchElementException`.
   *
   * @return a failed projection of this `Future`.
   */
  def failed: Future[Throwable] =
    transform({
      case Failure(t) => Success(t)
      case Success(v) => Failure(new NoSuchElementException("Future.failed not completed with a throwable."))
    })(internalExecutor)


  /* Monadic operations */

  /** Asynchronously processes the value in the future once the value becomes available.
   *
   *  WARNING: Will not be called if this future is never completed or if it is completed with a failure.
   *
   *  $swallowsExceptions
   *
   * @tparam U     only used to accept any return type of the given callback function
   * @param f      the function which will be executed if this `Future` completes with a result,
   *               the return value of `f` will be discarded.
   */
  def foreach[U](f: T => U)(implicit executor: ExecutionContext): Unit = onComplete { _ foreach f }

  /** Creates a new future by applying the 's' function to the successful result of
   *  this future, or the 'f' function to the failed result. If there is any non-fatal
   *  exception thrown when 's' or 'f' is applied, that exception will be propagated
   *  to the resulting future.
   *
   *  @tparam S  the type of the returned `Future`
   *  @param  s  function that transforms a successful result of the receiver into a successful result of the returned future
   *  @param  f  function that transforms a failure of the receiver into a failure of the returned future
   *  @return    a `Future` that will be completed with the transformed value
   */
  def transform[S](s: T => S, f: Throwable => Throwable)(implicit executor: ExecutionContext): Future[S] =
    transform {
      case Success(r) => Try(s(r))
      case Failure(t) => Try(throw f(t)) // will throw fatal errors!
    }

  /** Creates a new Future by applying the specified function to the result
   * of this Future. If there is any non-fatal exception thrown when 'f'
   * is applied then that exception will be propagated to the resulting future.
   *
   *  @tparam S  the type of the returned `Future`
   *  @param  f  function that transforms the result of this future
   *  @return    a `Future` that will be completed with the transformed value
   */
  def transform[S](f: Try[T] => Try[S])(implicit executor: ExecutionContext): Future[S]

  /** Creates a new Future by applying the specified function, which produces a Future, to the result
   * of this Future. If there is any non-fatal exception thrown when 'f'
   * is applied then that exception will be propagated to the resulting future.
   *
   *  @tparam S  the type of the returned `Future`
   *  @param  f  function that transforms the result of this future
   *  @return    a `Future` that will be completed with the transformed value
   */
  def transformWith[S](f: Try[T] => Future[S])(implicit executor: ExecutionContext): Future[S]


  /** Creates a new future by applying a function to the successful result of
   *  this future. If this future is completed with an exception then the new
   *  future will also contain this exception.
   *
   *  $forComprehensionExamples
   *
   *  @tparam S  the type of the returned `Future`
   *  @param f   the function which will be applied to the successful result of this `Future`
   *  @return    a `Future` which will be completed with the result of the application of the function
   */
  def map[S](f: T => S)(implicit executor: ExecutionContext): Future[S] = transform(_.map(f))

  /** Creates a new future by applying a function to the successful result of
   *  this future, and returns the result of the function as the new future.
   *  If this future is completed with an exception then the new future will
   *  also contain this exception.
   *
   *  $forComprehensionExamples
   *
   *  @tparam S  the type of the returned `Future`
   *  @param f   the function which will be applied to the successful result of this `Future`
   *  @return    a `Future` which will be completed with the result of the application of the function
   */
  def flatMap[S](f: T => Future[S])(implicit executor: ExecutionContext): Future[S] = transformWith {
    case Success(s) => f(s)
    case Failure(_) => this.asInstanceOf[Future[S]]
  }

  /** Creates a new future with one level of nesting flattened, this method is equivalent
   *  to `flatMap(identity)`.
   *
   *  @tparam S  the type of the returned `Future`
   */
  def flatten[S](implicit ev: T <:< Future[S]): Future[S] = flatMap(ev)(internalExecutor)

  /** Creates a new future by filtering the value of the current future with a predicate.
   *
   *  If the current future contains a value which satisfies the predicate, the new future will also hold that value.
   *  Otherwise, the resulting future will fail with a `NoSuchElementException`.
   *
   *  If the current future fails, then the resulting future also fails.
   *
   *  Example:
   *  {{{
   *  val f = Future { 5 }
   *  val g = f filter { _ % 2 == 1 }
   *  val h = f filter { _ % 2 == 0 }
   *  g foreach println // Eventually prints 5
   *  Await.result(h, Duration.Zero) // throw a NoSuchElementException
   *  }}}
   *
   *  @param p   the predicate to apply to the successful result of this `Future`
   *  @return    a `Future` which will hold the successful result of this `Future` if it matches the predicate or a `NoSuchElementException`
   */
  def filter(@deprecatedName('pred) p: T => Boolean)(implicit executor: ExecutionContext): Future[T] =
    map { r => if (p(r)) r else throw new NoSuchElementException("Future.filter predicate is not satisfied") }

  /** Used by for-comprehensions.
   */
  final def withFilter(p: T => Boolean)(implicit executor: ExecutionContext): Future[T] = filter(p)(executor)

  /** Creates a new future by mapping the value of the current future, if the given partial function is defined at that value.
   *
   *  If the current future contains a value for which the partial function is defined, the new future will also hold that value.
   *  Otherwise, the resulting future will fail with a `NoSuchElementException`.
   *
   *  If the current future fails, then the resulting future also fails.
   *
   *  Example:
   *  {{{
   *  val f = Future { -5 }
   *  val g = f collect {
   *    case x if x < 0 => -x
   *  }
   *  val h = f collect {
   *    case x if x > 0 => x * 2
   *  }
   *  g foreach println // Eventually prints 5
   *  Await.result(h, Duration.Zero) // throw a NoSuchElementException
   *  }}}
   *
   *  @tparam S    the type of the returned `Future`
   *  @param pf    the `PartialFunction` to apply to the successful result of this `Future`
   *  @return      a `Future` holding the result of application of the `PartialFunction` or a `NoSuchElementException`
   */
  def collect[S](pf: PartialFunction[T, S])(implicit executor: ExecutionContext): Future[S] =
    map {
      r => pf.applyOrElse(r, (t: T) => throw new NoSuchElementException("Future.collect partial function is not defined at: " + t))
    }

  /** Creates a new future that will handle any matching throwable that this
   *  future might contain. If there is no match, or if this future contains
   *  a valid result then the new future will contain the same.
   *
   *  Example:
   *
   *  {{{
   *  Future (6 / 0) recover { case e: ArithmeticException => 0 } // result: 0
   *  Future (6 / 0) recover { case e: NotFoundException   => 0 } // result: exception
   *  Future (6 / 2) recover { case e: ArithmeticException => 0 } // result: 3
   *  }}}
   *
   *  @tparam U    the type of the returned `Future`
   *  @param pf    the `PartialFunction` to apply if this `Future` fails
   *  @return      a `Future` with the successful value of this `Future` or the result of the `PartialFunction`
   */
  def recover[U >: T](pf: PartialFunction[Throwable, U])(implicit executor: ExecutionContext): Future[U] =
    transform { _ recover pf }

  /** Creates a new future that will handle any matching throwable that this
   *  future might contain by assigning it a value of another future.
   *
   *  If there is no match, or if this future contains
   *  a valid result then the new future will contain the same result.
   *
   *  Example:
   *
   *  {{{
   *  val f = Future { Int.MaxValue }
   *  Future (6 / 0) recoverWith { case e: ArithmeticException => f } // result: Int.MaxValue
   *  }}}
   *
   *  @tparam U    the type of the returned `Future`
   *  @param pf    the `PartialFunction` to apply if this `Future` fails
   *  @return      a `Future` with the successful value of this `Future` or the outcome of the `Future` returned by the `PartialFunction`
   */
  def recoverWith[U >: T](pf: PartialFunction[Throwable, Future[U]])(implicit executor: ExecutionContext): Future[U] =
    transformWith {
      case Failure(t) => pf.applyOrElse(t, (_: Throwable) => this)
      case Success(_) => this
    }

  /** Zips the values of `this` and `that` future, and creates
   *  a new future holding the tuple of their results.
   *
   *  If `this` future fails, the resulting future is failed
   *  with the throwable stored in `this`.
   *  Otherwise, if `that` future fails, the resulting future is failed
   *  with the throwable stored in `that`.
   *
   *  @tparam U      the type of the other `Future`
   *  @param that    the other `Future`
   *  @return        a `Future` with the results of both futures or the failure of the first of them that failed
   */
  def zip[U](that: Future[U]): Future[(T, U)] = {
    implicit val ec = internalExecutor
    flatMap { r1 => that.map(r2 => (r1, r2)) }
  }

  /** Zips the values of `this` and `that` future using a function `f`,
   *  and creates a new future holding the result.
   *
   *  If `this` future fails, the resulting future is failed
   *  with the throwable stored in `this`.
   *  Otherwise, if `that` future fails, the resulting future is failed
   *  with the throwable stored in `that`.
   *  If the application of `f` throws a throwable, the resulting future
   *  is failed with that throwable if it is non-fatal.
   *
   *  @tparam U      the type of the other `Future`
   *  @tparam R      the type of the resulting `Future`
   *  @param that    the other `Future`
   *  @param f       the function to apply to the results of `this` and `that`
   *  @return        a `Future` with the result of the application of `f` to the results of `this` and `that`
   */
  def zipWith[U, R](that: Future[U])(f: (T, U) => R)(implicit executor: ExecutionContext): Future[R] =
    flatMap(r1 => that.map(r2 => f(r1, r2)))(internalExecutor)

  /** Creates a new future which holds the result of this future if it was completed successfully, or, if not,
   *  the result of the `that` future if `that` is completed successfully.
   *  If both futures are failed, the resulting future holds the throwable object of the first future.
   *
   *  Using this method will not cause concurrent programs to become nondeterministic.
   *
   *  Example:
   *  {{{
   *  val f = Future { sys.error("failed") }
   *  val g = Future { 5 }
   *  val h = f fallbackTo g
   *  h foreach println // Eventually prints 5
   *  }}}
   *
   *  @tparam U     the type of the other `Future` and the resulting `Future`
   *  @param that   the `Future` whose result we want to use if this `Future` fails.
   *  @return       a `Future` with the successful result of this or that `Future` or the failure of this `Future` if both fail
   */
  def fallbackTo[U >: T](that: Future[U]): Future[U] =
    if (this eq that) this
    else {
      implicit val ec = internalExecutor
      recoverWith { case _ => that } recoverWith { case _ => this }
    }

  /** Creates a new `Future[S]` which is completed with this `Future`'s result if
   *  that conforms to `S`'s erased type or a `ClassCastException` otherwise.
   *
   *  @tparam S     the type of the returned `Future`
   *  @param tag    the `ClassTag` which will be used to cast the result of this `Future`
   *  @return       a `Future` holding the casted result of this `Future` or a `ClassCastException` otherwise
   */
  def mapTo[S](implicit tag: ClassTag[S]): Future[S] = {
    implicit val ec = internalExecutor
    val boxedClass = {
      val c = tag.runtimeClass
      if (c.isPrimitive) Future.toBoxed(c) else c
    }
    require(boxedClass ne null)
    map(s => boxedClass.cast(s).asInstanceOf[S])
  }

  /** Applies the side-effecting function to the result of this future, and returns
   *  a new future with the result of this future.
   *
   *  This method allows one to enforce that the callbacks are executed in a
   *  specified order.
   *
   *  Note that if one of the chained `andThen` callbacks throws
   *  an exception, that exception is not propagated to the subsequent `andThen`
   *  callbacks. Instead, the subsequent `andThen` callbacks are given the original
   *  value of this future.
   *
   *  The following example prints out `5`:
   *
   *  {{{
   *  val f = Future { 5 }
   *  f andThen {
   *    case r => sys.error("runtime exception")
   *  } andThen {
   *    case Failure(t) => println(t)
   *    case Success(v) => println(v)
   *  }
   *  }}}
   *
   *  @tparam U     only used to accept any return type of the given `PartialFunction`
   *  @param pf     a `PartialFunction` which will be conditionally applied to the outcome of this `Future`
   *  @return       a `Future` which will be completed with the exact same outcome as this `Future` but after the `PartialFunction` has been executed.
   */
  def andThen[U](pf: PartialFunction[Try[T], U])(implicit executor: ExecutionContext): Future[T] =
    transform {
      result =>
        try pf.applyOrElse[Try[T], Any](result, Predef.conforms[Try[T]])
        catch { case NonFatal(t) => executor reportFailure t }

        result
    }
}



/** Future companion object.
 *
 *  @define nonDeterministic
 *  Note: using this method yields nondeterministic dataflow programs.
 */
object Future {

  private[concurrent] val toBoxed = Map[Class[_], Class[_]](
    classOf[Boolean] -> classOf[java.lang.Boolean],
    classOf[Byte]    -> classOf[java.lang.Byte],
    classOf[Char]    -> classOf[java.lang.Character],
    classOf[Short]   -> classOf[java.lang.Short],
    classOf[Int]     -> classOf[java.lang.Integer],
    classOf[Long]    -> classOf[java.lang.Long],
    classOf[Float]   -> classOf[java.lang.Float],
    classOf[Double]  -> classOf[java.lang.Double],
    classOf[Unit]    -> classOf[scala.runtime.BoxedUnit]
  )

  /** A Future which is never completed.
   */
  final object never extends Future[Nothing] {

    @throws(classOf[TimeoutException])
    @throws(classOf[InterruptedException])
    override def ready(atMost: Duration)(implicit permit: CanAwait): this.type = {
      atMost match {
        case e if e eq Duration.Undefined => throw new IllegalArgumentException("cannot wait for Undefined period")
        case Duration.Inf        => new CountDownLatch(1).await()
        case Duration.MinusInf   => // Drop out
        case f: FiniteDuration   =>
          if (f > Duration.Zero) new CountDownLatch(1).await(f.toNanos, TimeUnit.NANOSECONDS)
      }
      throw new TimeoutException(s"Future timed out after [$atMost]")
    }

    @throws(classOf[Exception])
    override def result(atMost: Duration)(implicit permit: CanAwait): Nothing = {
      ready(atMost)
      throw new TimeoutException(s"Future timed out after [$atMost]")
    }

    override def onSuccess[U](pf: PartialFunction[Nothing, U])(implicit executor: ExecutionContext): Unit = ()
    override def onFailure[U](pf: PartialFunction[Throwable, U])(implicit executor: ExecutionContext): Unit = ()
    override def onComplete[U](f: Try[Nothing] => U)(implicit executor: ExecutionContext): Unit = ()
    override def isCompleted: Boolean = false
    override def value: Option[Try[Nothing]] = None
    override def failed: Future[Throwable] = this
    override def foreach[U](f: Nothing => U)(implicit executor: ExecutionContext): Unit = ()
    override def transform[S](s: Nothing => S, f: Throwable => Throwable)(implicit executor: ExecutionContext): Future[S] = this
    override def transform[S](f: Try[Nothing] => Try[S])(implicit executor: ExecutionContext): Future[S] = this
    override def transformWith[S](f: Try[Nothing] => Future[S])(implicit executor: ExecutionContext): Future[S] = this
    override def map[S](f: Nothing => S)(implicit executor: ExecutionContext): Future[S] = this
    override def flatMap[S](f: Nothing => Future[S])(implicit executor: ExecutionContext): Future[S] = this
    override def flatten[S](implicit ev: Nothing <:< Future[S]): Future[S] = this
    override def filter(p: Nothing => Boolean)(implicit executor: ExecutionContext): Future[Nothing] = this
    override def collect[S](pf: PartialFunction[Nothing, S])(implicit executor: ExecutionContext): Future[S] = this
    override def recover[U >: Nothing](pf: PartialFunction[Throwable, U])(implicit executor: ExecutionContext): Future[U] = this
    override def recoverWith[U >: Nothing](pf: PartialFunction[Throwable, Future[U]])(implicit executor: ExecutionContext): Future[U] = this
    override def zip[U](that: Future[U]): Future[(Nothing, U)] = this
    override def zipWith[U, R](that: Future[U])(f: (Nothing, U) => R)(implicit executor: ExecutionContext): Future[R] = this
    override def fallbackTo[U >: Nothing](that: Future[U]): Future[U] = this
    override def mapTo[S](implicit tag: ClassTag[S]): Future[S] = this
    override def andThen[U](pf: PartialFunction[Try[Nothing], U])(implicit executor: ExecutionContext): Future[Nothing] = this

    override def toString: String = "Future(<never>)"
  }

  /** A Future which is always completed with the Unit value.
   */
  val unit: Future[Unit] = successful(())

  /** Creates an already completed Future with the specified exception.
   *
   *  @tparam T        the type of the value in the future
   *  @param exception the non-null instance of `Throwable`
   *  @return          the newly created `Future` instance
   */
  def failed[T](exception: Throwable): Future[T] = Promise.failed(exception).future

  /** Creates an already completed Future with the specified result.
   *
   *  @tparam T       the type of the value in the future
   *  @param result   the given successful value
   *  @return         the newly created `Future` instance
   */
  def successful[T](result: T): Future[T] = Promise.successful(result).future

  /** Creates an already completed Future with the specified result or exception.
   *
   *  @tparam T       the type of the value in the `Future`
   *  @param result   the result of the returned `Future` instance
   *  @return         the newly created `Future` instance
   */
  def fromTry[T](result: Try[T]): Future[T] = Promise.fromTry(result).future

  /** Starts an asynchronous computation and returns a `Future` instance with the result of that computation.
  *
  *  The result becomes available once the asynchronous computation is completed.
  *
  *  @tparam T        the type of the result
  *  @param body      the asynchronous computation
  *  @param executor  the execution context on which the future is run
  *  @return          the `Future` holding the result of the computation
  */
  def apply[T](body: =>T)(implicit @deprecatedName('execctx) executor: ExecutionContext): Future[T] =
    unit.map(_ => body)

  /** Simple version of `Future.traverse`. Asynchronously and non-blockingly transforms a `TraversableOnce[Future[A]]`
   *  into a `Future[TraversableOnce[A]]`. Useful for reducing many `Future`s into a single `Future`.
   *
   * @tparam A        the type of the value inside the Futures
   * @tparam M        the type of the `TraversableOnce` of Futures
   * @param in        the `TraversableOnce` of Futures which will be sequenced
   * @return          the `Future` of the `TraversableOnce` of results
   */
  def sequence[A, M[X] <: TraversableOnce[X]](in: M[Future[A]])(implicit cbf: CanBuildFrom[M[Future[A]], A, M[A]], executor: ExecutionContext): Future[M[A]] = {
    in.foldLeft(successful(cbf(in))) {
      (fr, fa) => for (r <- fr; a <- fa) yield (r += a)
    }.map(_.result())(InternalCallbackExecutor)
  }

  /** Asynchronously and non-blockingly returns a new `Future` to the result of the first future
   *  in the list that is completed. This means no matter if it is completed as a success or as a failure.
   *
   * @tparam T        the type of the value in the future
   * @param futures   the `TraversableOnce` of Futures in which to find the first completed
   * @return          the `Future` holding the result of the future that is first to be completed
   */
  def firstCompletedOf[T](futures: TraversableOnce[Future[T]])(implicit executor: ExecutionContext): Future[T] = {
    val p = Promise[T]()
    val completeFirst: Try[T] => Unit = p tryComplete _
    futures foreach { _ onComplete completeFirst }
    p.future
  }

  /** Asynchronously and non-blockingly returns a `Future` that will hold the optional result
   *  of the first `Future` with a result that matches the predicate.
   *
   * @tparam T        the type of the value in the future
   * @param futures   the `TraversableOnce` of Futures to search
   * @param p         the predicate which indicates if it's a match
   * @return          the `Future` holding the optional result of the search
   */
  @deprecated("Use the overloaded version of this method that takes a scala.collection.immutable.Iterable instead", "2.12")
  def find[T](@deprecatedName('futurestravonce) futures: TraversableOnce[Future[T]])(@deprecatedName('predicate) p: T => Boolean)(implicit executor: ExecutionContext): Future[Option[T]] = {
    val futuresBuffer = futures.toBuffer
    if (futuresBuffer.isEmpty) successful[Option[T]](None)
    else {
      val result = Promise[Option[T]]()
      val ref = new AtomicInteger(futuresBuffer.size)
      val search: Try[T] => Unit = v => try {
        v match {
          case Success(r) if p(r) => result tryComplete Success(Some(r))
          case _ =>
        }
      } finally {
        if (ref.decrementAndGet == 0) {
          result tryComplete Success(None)
        }
      }

      futuresBuffer.foreach(_ onComplete search)

      result.future
    }
  }


  /** Asynchronously and non-blockingly returns a `Future` that will hold the optional result
   *  of the first `Future` with a result that matches the predicate, failed `Future`s will be ignored.
   *
   * @tparam T        the type of the value in the future
   * @param futures   the `scala.collection.immutable.Iterable` of Futures to search
   * @param p         the predicate which indicates if it's a match
   * @return          the `Future` holding the optional result of the search
   */
  def find[T](futures: scala.collection.immutable.Iterable[Future[T]])(p: T => Boolean)(implicit executor: ExecutionContext): Future[Option[T]] = {
    def searchNext(i: Iterator[Future[T]]): Future[Option[T]] =
      if (!i.hasNext) successful[Option[T]](None)
      else {
        i.next().transformWith {
          case Success(r) if p(r) => successful(Some(r))
          case other => searchNext(i)
        }
      }
    searchNext(futures.iterator)
  }

  /** A non-blocking, asynchronous left fold over the specified futures,
   *  with the start value of the given zero.
   *  The fold is performed asynchronously in left-to-right order as the futures become completed.
   *  The result will be the first failure of any of the futures, or any failure in the actual fold,
   *  or the result of the fold.
   *
   *  Example:
   *  {{{
   *    val futureSum = Future.foldLeft(futures)(0)(_ + _)
   *  }}}
   *
   * @tparam T       the type of the value of the input Futures
   * @tparam R       the type of the value of the returned `Future`
   * @param futures  the `scala.collection.immutable.Iterable` of Futures to be folded
   * @param zero     the start value of the fold
   * @param op       the fold operation to be applied to the zero and futures
   * @return         the `Future` holding the result of the fold
   */
  def foldLeft[T, R](futures: scala.collection.immutable.Iterable[Future[T]])(zero: R)(op: (R, T) => R)(implicit executor: ExecutionContext): Future[R] =
    foldNext(futures.iterator, zero, op)

  private[this] def foldNext[T, R](i: Iterator[Future[T]], prevValue: R, op: (R, T) => R)(implicit executor: ExecutionContext): Future[R] =
    if (!i.hasNext) successful(prevValue)
    else i.next().flatMap { value => foldNext(i, op(prevValue, value), op) }

  /** A non-blocking, asynchronous fold over the specified futures, with the start value of the given zero.
   *  The fold is performed on the thread where the last future is completed,
   *  the result will be the first failure of any of the futures, or any failure in the actual fold,
   *  or the result of the fold.
   *
   *  Example:
   *  {{{
   *    val futureSum = Future.fold(futures)(0)(_ + _)
   *  }}}
   *
   * @tparam T       the type of the value of the input Futures
   * @tparam R       the type of the value of the returned `Future`
   * @param futures  the `TraversableOnce` of Futures to be folded
   * @param zero     the start value of the fold
   * @param op       the fold operation to be applied to the zero and futures
   * @return         the `Future` holding the result of the fold
   */
  @deprecated("Use Future.foldLeft instead", "2.12")
  def fold[T, R](futures: TraversableOnce[Future[T]])(zero: R)(@deprecatedName('foldFun) op: (R, T) => R)(implicit executor: ExecutionContext): Future[R] = {
    if (futures.isEmpty) successful(zero)
    else sequence(futures).map(_.foldLeft(zero)(op))
  }

  /** Initiates a non-blocking, asynchronous, fold over the supplied futures
   *  where the fold-zero is the result value of the `Future` that's completed first.
   *
   *  Example:
   *  {{{
   *    val futureSum = Future.reduce(futures)(_ + _)
   *  }}}
   * @tparam T       the type of the value of the input Futures
   * @tparam R       the type of the value of the returned `Future`
   * @param futures  the `TraversableOnce` of Futures to be reduced
   * @param op       the reduce operation which is applied to the results of the futures
   * @return         the `Future` holding the result of the reduce
   */
  @deprecated("Use Future.reduceLeft instead", "2.12")
  def reduce[T, R >: T](futures: TraversableOnce[Future[T]])(op: (R, T) => R)(implicit executor: ExecutionContext): Future[R] = {
    if (futures.isEmpty) failed(new NoSuchElementException("reduce attempted on empty collection"))
    else sequence(futures).map(_ reduceLeft op)
  }

  /** Initiates a non-blocking, asynchronous, left reduction over the supplied futures
   *  where the zero is the result value of the first `Future`.
   *
   *  Example:
   *  {{{
   *    val futureSum = Future.reduceLeft(futures)(_ + _)
   *  }}}
   * @tparam T       the type of the value of the input Futures
   * @tparam R       the type of the value of the returned `Future`
   * @param futures  the `scala.collection.immutable.Iterable` of Futures to be reduced
   * @param op       the reduce operation which is applied to the results of the futures
   * @return         the `Future` holding the result of the reduce
   */
  def reduceLeft[T, R >: T](futures: scala.collection.immutable.Iterable[Future[T]])(op: (R, T) => R)(implicit executor: ExecutionContext): Future[R] = {
    val i = futures.iterator
    if (!i.hasNext) failed(new NoSuchElementException("reduceLeft attempted on empty collection"))
    else i.next() flatMap { v => foldNext(i, v, op) }
  }

  /** Asynchronously and non-blockingly transforms a `TraversableOnce[A]` into a `Future[TraversableOnce[B]]`
   *  using the provided function `A => Future[B]`.
   *  This is useful for performing a parallel map. For example, to apply a function to all items of a list
   *  in parallel:
   *
   *  {{{
   *    val myFutureList = Future.traverse(myList)(x => Future(myFunc(x)))
   *  }}}
   * @tparam A        the type of the value inside the Futures in the `TraversableOnce`
   * @tparam B        the type of the value of the returned `Future`
   * @tparam M        the type of the `TraversableOnce` of Futures
   * @param in        the `TraversableOnce` of Futures which will be sequenced
   * @param fn        the function to apply to the `TraversableOnce` of Futures to produce the results
   * @return          the `Future` of the `TraversableOnce` of results
   */
  def traverse[A, B, M[X] <: TraversableOnce[X]](in: M[A])(fn: A => Future[B])(implicit cbf: CanBuildFrom[M[A], B, M[B]], executor: ExecutionContext): Future[M[B]] =
    in.foldLeft(successful(cbf(in))) { (fr, a) =>
      val fb = fn(a)
      for (r <- fr; b <- fb) yield (r += b)
    }.map(_.result())


  // This is used to run callbacks which are internal
  // to scala.concurrent; our own callbacks are only
  // ever used to eventually run another callback,
  // and that other callback will have its own
  // executor because all callbacks come with
  // an executor. Our own callbacks never block
  // and have no "expected" exceptions.
  // As a result, this executor can do nothing;
  // some other executor will always come after
  // it (and sometimes one will be before it),
  // and those will be performing the "real"
  // dispatch to code outside scala.concurrent.
  // Because this exists, ExecutionContext.defaultExecutionContext
  // isn't instantiated by Future internals, so
  // if some code for some reason wants to avoid
  // ever starting up the default context, it can do so
  // by just not ever using it itself. scala.concurrent
  // doesn't need to create defaultExecutionContext as
  // a side effect.
  private[concurrent] object InternalCallbackExecutor extends ExecutionContext with BatchingExecutor {
    override protected def unbatchedExecute(r: Runnable): Unit =
      r.run()
    override def reportFailure(t: Throwable): Unit =
      throw new IllegalStateException("problem in scala.concurrent internal callback", t)
  }
}

/** A marker indicating that a `java.lang.Runnable` provided to `scala.concurrent.ExecutionContext`
 * wraps a callback provided to `Future.onComplete`.
 * All callbacks provided to a `Future` end up going through `onComplete`, so this allows an
 * `ExecutionContext` to special-case callbacks that were executed by `Future` if desired.
 */
trait OnCompleteRunnable {
  self: Runnable =>
}