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/* __ *\
** ________ ___ / / ___ Scala API **
** / __/ __// _ | / / / _ | (c) 2003-2013, LAMP/EPFL **
** __\ \/ /__/ __ |/ /__/ __ | http://scala-lang.org/ **
** /____/\___/_/ |_/____/_/ | | **
** |/ **
\* */
package scala
package collection.parallel
import java.util.concurrent.ThreadPoolExecutor
import scala.concurrent.forkjoin._
import scala.concurrent.ExecutionContext
import scala.util.control.Breaks._
import scala.annotation.unchecked.uncheckedVariance
trait Task[R, +Tp] {
type Result = R
def repr = this.asInstanceOf[Tp]
/** Body of the task - non-divisible unit of work done by this task.
* Optionally is provided with the result from the previous completed task
* or `None` if there was no previous task (or the previous task is uncompleted or unknown).
*/
def leaf(result: Option[R])
/** A result that can be accessed once the task is completed. */
var result: R
/** Decides whether or not this task should be split further. */
def shouldSplitFurther: Boolean
/** Splits this task into a list of smaller tasks. */
private[parallel] def split: Seq[Task[R, Tp]]
/** Read of results of `that` task and merge them into results of this one. */
private[parallel] def merge(that: Tp @uncheckedVariance) {}
// exception handling mechanism
@volatile var throwable: Throwable = null
def forwardThrowable() = if (throwable != null) throw throwable
// tries to do the leaf computation, storing the possible exception
private[parallel] def tryLeaf(lastres: Option[R]) {
try {
tryBreakable {
leaf(lastres)
result = result // ensure that effects of `leaf` are visible to readers of `result`
} catchBreak {
signalAbort()
}
} catch {
case thr: Throwable =>
result = result // ensure that effects of `leaf` are visible
throwable = thr
signalAbort()
}
}
private[parallel] def tryMerge(t: Tp @uncheckedVariance) {
val that = t.asInstanceOf[Task[R, Tp]]
if (this.throwable == null && that.throwable == null) merge(t)
mergeThrowables(that)
}
private[parallel] def mergeThrowables(that: Task[_, _]) {
// TODO: As soon as we target Java >= 7, use Throwable#addSuppressed
// to pass additional Throwables to the caller, e. g.
// if (this.throwable != null && that.throwable != null)
// this.throwable.addSuppressed(that.throwable)
// For now, we just use whatever Throwable comes across “first”.
if (this.throwable == null && that.throwable != null)
this.throwable = that.throwable
}
// override in concrete task implementations to signal abort to other tasks
private[parallel] def signalAbort() {}
}
/** A trait that declares task execution capabilities used
* by parallel collections.
*/
trait Tasks {
private[parallel] val debugMessages = scala.collection.mutable.ArrayBuffer[String]()
private[parallel] def debuglog(s: String) = synchronized {
debugMessages += s
}
trait WrappedTask[R, +Tp] {
/** the body of this task - what it executes, how it gets split and how results are merged. */
val body: Task[R, Tp]
def split: Seq[WrappedTask[R, Tp]]
/** Code that gets called after the task gets started - it may spawn other tasks instead of calling `leaf`. */
def compute()
/** Start task. */
def start()
/** Wait for task to finish. */
def sync()
/** Try to cancel the task.
* @return `true` if cancellation is successful.
*/
def tryCancel(): Boolean
/** If the task has been cancelled successfully, those syncing on it may
* automatically be notified, depending on the implementation. If they
* aren't, this release method should be called after processing the
* cancelled task.
*
* This method may be overridden.
*/
def release() {}
}
/* task control */
/** The type of the environment is more specific in the implementations. */
val environment: AnyRef
/** Executes a task and returns a future. Forwards an exception if some task threw it. */
def execute[R, Tp](fjtask: Task[R, Tp]): () => R
/** Executes a result task, waits for it to finish, then returns its result. Forwards an exception if some task threw it. */
def executeAndWaitResult[R, Tp](task: Task[R, Tp]): R
/** Retrieves the parallelism level of the task execution environment. */
def parallelismLevel: Int
}
/** This trait implements scheduling by employing
* an adaptive work stealing technique.
*/
trait AdaptiveWorkStealingTasks extends Tasks {
trait WrappedTask[R, Tp] extends super.WrappedTask[R, Tp] {
@volatile var next: WrappedTask[R, Tp] = null
@volatile var shouldWaitFor = true
def split: Seq[WrappedTask[R, Tp]]
def compute() = if (body.shouldSplitFurther) {
internal()
release()
} else {
body.tryLeaf(None)
release()
}
def internal() = {
var last = spawnSubtasks()
last.body.tryLeaf(None)
last.release()
body.result = last.body.result
body.throwable = last.body.throwable
while (last.next != null) {
// val lastresult = Option(last.body.result)
last = last.next
if (last.tryCancel()) {
// println("Done with " + beforelast.body + ", next direct is " + last.body)
last.body.tryLeaf(Some(body.result))
last.release()
} else {
// println("Done with " + beforelast.body + ", next sync is " + last.body)
last.sync()
}
// println("Merging " + body + " with " + last.body)
body.tryMerge(last.body.repr)
}
}
def spawnSubtasks() = {
var last: WrappedTask[R, Tp] = null
var head: WrappedTask[R, Tp] = this
do {
val subtasks = head.split
head = subtasks.head
for (t <- subtasks.tail.reverse) {
t.next = last
last = t
t.start()
}
} while (head.body.shouldSplitFurther)
head.next = last
head
}
def printChain() = {
var curr = this
var chain = "chain: "
while (curr != null) {
chain += curr + " ---> "
curr = curr.next
}
println(chain)
}
}
// specialize ctor
protected def newWrappedTask[R, Tp](b: Task[R, Tp]): WrappedTask[R, Tp]
}
/** An implementation of tasks objects based on the Java thread pooling API. */
@deprecated("Use `ForkJoinTasks` instead.", "2.11.0")
trait ThreadPoolTasks extends Tasks {
import java.util.concurrent._
trait WrappedTask[R, +Tp] extends Runnable with super.WrappedTask[R, Tp] {
// initially, this is null
// once the task is started, this future is set and used for `sync`
// utb: var future: Future[_] = null
@volatile var owned = false
@volatile var completed = false
def start() = synchronized {
// debuglog("Starting " + body)
// utb: future = executor.submit(this)
executor.synchronized {
incrTasks()
executor.submit(this)
}
}
def sync() = synchronized {
// debuglog("Syncing on " + body)
// utb: future.get()
executor.synchronized {
val coresize = executor.getCorePoolSize
if (coresize < totaltasks) {
executor.setCorePoolSize(coresize + 1)
//assert(executor.getCorePoolSize == (coresize + 1))
}
}
while (!completed) this.wait
}
def tryCancel() = synchronized {
// utb: future.cancel(false)
if (!owned) {
// debuglog("Cancelling " + body)
owned = true
true
} else false
}
def run() = {
// utb: compute
var isOkToRun = false
synchronized {
if (!owned) {
owned = true
isOkToRun = true
}
}
if (isOkToRun) {
// debuglog("Running body of " + body)
compute()
} else {
// just skip
// debuglog("skipping body of " + body)
}
}
override def release() = synchronized {
//println("releasing: " + this + ", body: " + this.body)
completed = true
executor.synchronized {
decrTasks()
}
this.notifyAll
}
}
protected def newWrappedTask[R, Tp](b: Task[R, Tp]): WrappedTask[R, Tp]
val environment: ThreadPoolExecutor
def executor = environment.asInstanceOf[ThreadPoolExecutor]
def queue = executor.getQueue.asInstanceOf[LinkedBlockingQueue[Runnable]]
@volatile var totaltasks = 0
private def incrTasks() = synchronized {
totaltasks += 1
}
private def decrTasks() = synchronized {
totaltasks -= 1
}
def execute[R, Tp](task: Task[R, Tp]): () => R = {
val t = newWrappedTask(task)
// debuglog("-----------> Executing without wait: " + task)
t.start()
() => {
t.sync()
t.body.forwardThrowable()
t.body.result
}
}
def executeAndWaitResult[R, Tp](task: Task[R, Tp]): R = {
val t = newWrappedTask(task)
// debuglog("-----------> Executing with wait: " + task)
t.start()
t.sync()
t.body.forwardThrowable()
t.body.result
}
def parallelismLevel = ThreadPoolTasks.numCores
}
@deprecated("Use `ForkJoinTasks` instead.", "2.11.0")
object ThreadPoolTasks {
import java.util.concurrent._
val numCores = Runtime.getRuntime.availableProcessors
val tcount = new atomic.AtomicLong(0L)
val defaultThreadPool = new ThreadPoolExecutor(
numCores,
Int.MaxValue,
60L, TimeUnit.MILLISECONDS,
new LinkedBlockingQueue[Runnable],
new ThreadFactory {
def newThread(r: Runnable) = {
val t = new Thread(r)
t.setName("pc-thread-" + tcount.incrementAndGet)
t.setDaemon(true)
t
}
},
new ThreadPoolExecutor.CallerRunsPolicy
)
}
object FutureThreadPoolTasks {
import java.util.concurrent._
val numCores = Runtime.getRuntime.availableProcessors
val tcount = new atomic.AtomicLong(0L)
val defaultThreadPool = Executors.newCachedThreadPool()
}
/**
* A trait describing objects that provide a fork/join pool.
*/
trait HavingForkJoinPool {
def forkJoinPool: ForkJoinPool
}
/** An implementation trait for parallel tasks based on the fork/join framework.
*
* @define fjdispatch
* If the current thread is a fork/join worker thread, the task's `fork` method will
* be invoked. Otherwise, the task will be executed on the fork/join pool.
*/
trait ForkJoinTasks extends Tasks with HavingForkJoinPool {
trait WrappedTask[R, +Tp] extends RecursiveAction with super.WrappedTask[R, Tp] {
def start() = fork
def sync() = join
def tryCancel = tryUnfork
}
// specialize ctor
protected def newWrappedTask[R, Tp](b: Task[R, Tp]): WrappedTask[R, Tp]
/** The fork/join pool of this collection.
*/
def forkJoinPool: ForkJoinPool = environment.asInstanceOf[ForkJoinPool]
val environment: ForkJoinPool
/** Executes a task and does not wait for it to finish - instead returns a future.
*
* $fjdispatch
*/
def execute[R, Tp](task: Task[R, Tp]): () => R = {
val fjtask = newWrappedTask(task)
if (Thread.currentThread.isInstanceOf[ForkJoinWorkerThread]) {
fjtask.fork
} else {
forkJoinPool.execute(fjtask)
}
() => {
fjtask.sync()
fjtask.body.forwardThrowable()
fjtask.body.result
}
}
/** Executes a task on a fork/join pool and waits for it to finish.
* Returns its result when it does.
*
* $fjdispatch
*
* @return the result of the task
*/
def executeAndWaitResult[R, Tp](task: Task[R, Tp]): R = {
val fjtask = newWrappedTask(task)
if (Thread.currentThread.isInstanceOf[ForkJoinWorkerThread]) {
fjtask.fork
} else {
forkJoinPool.execute(fjtask)
}
fjtask.sync()
// if (fjtask.body.throwable != null) println("throwing: " + fjtask.body.throwable + " at " + fjtask.body)
fjtask.body.forwardThrowable()
fjtask.body.result
}
def parallelismLevel = forkJoinPool.getParallelism
}
object ForkJoinTasks {
lazy val defaultForkJoinPool: ForkJoinPool = new ForkJoinPool()
}
/* Some boilerplate due to no deep mixin composition. Not sure if it can be done differently without them.
*/
trait AdaptiveWorkStealingForkJoinTasks extends ForkJoinTasks with AdaptiveWorkStealingTasks {
class WrappedTask[R, Tp](val body: Task[R, Tp])
extends super[ForkJoinTasks].WrappedTask[R, Tp] with super[AdaptiveWorkStealingTasks].WrappedTask[R, Tp] {
def split = body.split.map(b => newWrappedTask(b))
}
def newWrappedTask[R, Tp](b: Task[R, Tp]) = new WrappedTask[R, Tp](b)
}
@deprecated("Use `AdaptiveWorkStealingForkJoinTasks` instead.", "2.11.0")
trait AdaptiveWorkStealingThreadPoolTasks extends ThreadPoolTasks with AdaptiveWorkStealingTasks {
class WrappedTask[R, Tp](val body: Task[R, Tp])
extends super[ThreadPoolTasks].WrappedTask[R, Tp] with super[AdaptiveWorkStealingTasks].WrappedTask[R, Tp] {
def split = body.split.map(b => newWrappedTask(b))
}
def newWrappedTask[R, Tp](b: Task[R, Tp]) = new WrappedTask[R, Tp](b)
}
/** An implementation of the `Tasks` that uses Scala `Future`s to compute
* the work encapsulated in each task.
*/
private[parallel] final class FutureTasks(executor: ExecutionContext) extends Tasks {
import scala.concurrent._
import scala.util._
private val maxdepth = (math.log(parallelismLevel) / math.log(2) + 1).toInt
val environment: ExecutionContext = executor
/** Divides this task into a lot of small tasks and executes them asynchronously
* using futures.
* Folds the futures and merges them asynchronously.
*/
private def exec[R, Tp](topLevelTask: Task[R, Tp]): Future[R] = {
implicit val ec = environment
/** Constructs a tree of futures where tasks can be reasonably split.
*/
def compute(task: Task[R, Tp], depth: Int): Future[Task[R, Tp]] = {
if (task.shouldSplitFurther && depth < maxdepth) {
val subtasks = task.split
val subfutures = for (subtask <- subtasks.iterator) yield compute(subtask, depth + 1)
subfutures.reduceLeft { (firstFuture, nextFuture) =>
for {
firstTask <- firstFuture
nextTask <- nextFuture
} yield {
firstTask tryMerge nextTask.repr
firstTask
}
} andThen {
case Success(firstTask) =>
task.throwable = firstTask.throwable
task.result = firstTask.result
case Failure(exception) =>
task.throwable = exception
}
} else Future {
task.tryLeaf(None)
task
}
}
compute(topLevelTask, 0) map { t =>
t.forwardThrowable()
t.result
}
}
def execute[R, Tp](task: Task[R, Tp]): () => R = {
val future = exec(task)
val callback = () => {
Await.result(future, scala.concurrent.duration.Duration.Inf)
}
callback
}
def executeAndWaitResult[R, Tp](task: Task[R, Tp]): R = {
execute(task)()
}
def parallelismLevel = Runtime.getRuntime.availableProcessors
}
/** This tasks implementation uses execution contexts to spawn a parallel computation.
*
* As an optimization, it internally checks whether the execution context is the
* standard implementation based on fork/join pools, and if it is, creates a
* `ForkJoinTaskSupport` that shares the same pool to forward its request to it.
*
* Otherwise, it uses an execution context exclusive `Tasks` implementation to
* divide the tasks into smaller chunks and execute operations on it.
*/
trait ExecutionContextTasks extends Tasks {
def executionContext = environment
val environment: ExecutionContext
/** A driver serves as a target for this proxy `Tasks` object.
*
* If the execution context has the standard implementation and uses fork/join pools,
* the driver is `ForkJoinTaskSupport` with the same pool, as an optimization.
* Otherwise, the driver will be a Scala `Future`-based implementation.
*/
private val driver: Tasks = executionContext match {
case eci: scala.concurrent.impl.ExecutionContextImpl => eci.executor match {
case fjp: ForkJoinPool => new ForkJoinTaskSupport(fjp)
case _ => new FutureTasks(environment)
}
case _ => new FutureTasks(environment)
}
def execute[R, Tp](task: Task[R, Tp]): () => R = driver execute task
def executeAndWaitResult[R, Tp](task: Task[R, Tp]): R = driver executeAndWaitResult task
def parallelismLevel = driver.parallelismLevel
}
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