org.skfiy.util.v8

类 RecursiveAction

java.lang.Object

org.skfiy.util.v8.ForkJoinTask<Void>

org.skfiy.util.v8.RecursiveAction

所有已实现的接口:

Serializable, Future<Void>

public abstract class RecursiveAction
extends ForkJoinTask<Void>

A recursive resultless ForkJoinTask. This class establishes conventions to parameterize resultless actions as Void ForkJoinTasks. Because null is the only valid value of type Void, methods such as join always return null upon completion.

Sample Usages. Here is a simple but complete ForkJoin sort that sorts a given long[] array:

 static class SortTask extends RecursiveAction {
   final long[] array; final int lo, hi;
   SortTask(long[] array, int lo, int hi) {
     this.array = array; this.lo = lo; this.hi = hi;
   }
   SortTask(long[] array) { this(array, 0, array.length); }
   protected void compute() {
     if (hi - lo < THRESHOLD)
       sortSequentially(lo, hi);
     else {
       int mid = (lo + hi) >>> 1;
       invokeAll(new SortTask(array, lo, mid),
                 new SortTask(array, mid, hi));
       merge(lo, mid, hi);
     }
   }
   // implementation details follow:
   static final int THRESHOLD = 1000;
   void sortSequentially(int lo, int hi) {
     Arrays.sort(array, lo, hi);
   }
   void merge(int lo, int mid, int hi) {
     long[] buf = Arrays.copyOfRange(array, lo, mid);
     for (int i = 0, j = lo, k = mid; i < buf.length; j++)
       array[j] = (k == hi || buf[i] < array[k]) ?
         buf[i++] : array[k++];
   }
 }

You could then sort anArray by creating new SortTask(anArray) and invoking it in a ForkJoinPool. As a more concrete simple example, the following task increments each element of an array:

 class IncrementTask extends RecursiveAction {
   final long[] array; final int lo, hi;
   IncrementTask(long[] array, int lo, int hi) {
     this.array = array; this.lo = lo; this.hi = hi;
   }
   protected void compute() {
     if (hi - lo < THRESHOLD) {
       for (int i = lo; i < hi; ++i)
         array[i]++;
     }
     else {
       int mid = (lo + hi) >>> 1;
       invokeAll(new IncrementTask(array, lo, mid),
                 new IncrementTask(array, mid, hi));
     }
 }
 }

The following example illustrates some refinements and idioms that may lead to better performance: RecursiveActions need not be fully recursive, so long as they maintain the basic divide-and-conquer approach. Here is a class that sums the squares of each element of a double array, by subdividing out only the right-hand-sides of repeated divisions by two, and keeping track of them with a chain of next references. It uses a dynamic threshold based on method getSurplusQueuedTaskCount, but counterbalances potential excess partitioning by directly performing leaf actions on unstolen tasks rather than further subdividing.

 double sumOfSquares(ForkJoinPool pool, double[] array) {
   int n = array.length;
   Applyer a = new Applyer(array, 0, n, null);
   pool.invoke(a);
   return a.result;
 }

 class Applyer extends RecursiveAction {
   final double[] array;
   final int lo, hi;
   double result;
   Applyer next; // keeps track of right-hand-side tasks
   Applyer(double[] array, int lo, int hi, Applyer next) {
     this.array = array; this.lo = lo; this.hi = hi;
     this.next = next;
   }

   double atLeaf(int l, int h) {
     double sum = 0;
     for (int i = l; i < h; ++i) // perform leftmost base step
       sum += array[i] * array[i];
     return sum;
   }

   protected void compute() {
     int l = lo;
     int h = hi;
     Applyer right = null;
     while (h - l > 1 && getSurplusQueuedTaskCount() <= 3) {
       int mid = (l + h) >>> 1;
       right = new Applyer(array, mid, h, right);
       right.fork();
       h = mid;
     }
     double sum = atLeaf(l, h);
     while (right != null) {
       if (right.tryUnfork()) // directly calculate if not stolen
         sum += right.atLeaf(right.lo, right.hi);
       else {
         right.join();
         sum += right.result;
       }
       right = right.next;
     }
     result = sum;
   }
 }

从以下版本开始:

1.7

作者:

Doug Lea

另请参阅:

序列化表格

构造器概要

构造器

构造器和说明
RecursiveAction()

方法概要

方法

限定符和类型	方法和说明
protected abstract void	compute() The main computation performed by this task.
protected boolean	exec() Implements execution conventions for RecursiveActions.
Void	getRawResult() Always returns null.
protected void	setRawResult(Void mustBeNull) Requires null completion value.

从类继承的方法 org.skfiy.util.v8.ForkJoinTask

adapt, adapt, adapt, cancel, compareAndSetForkJoinTaskTag, complete, completeExceptionally, fork, get, get, getException, getForkJoinTaskTag, getPool, getQueuedTaskCount, getSurplusQueuedTaskCount, helpQuiesce, inForkJoinPool, invoke, invokeAll, invokeAll, invokeAll, isCancelled, isCompletedAbnormally, isCompletedNormally, isDone, join, peekNextLocalTask, pollNextLocalTask, pollTask, quietlyComplete, quietlyInvoke, quietlyJoin, reinitialize, setForkJoinTaskTag, tryUnfork

从类继承的方法 java.lang.Object

clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait

构造器详细资料

RecursiveAction

public RecursiveAction()

方法详细资料

compute

protected abstract void compute()

The main computation performed by this task.

getRawResult

public final Void getRawResult()

Always returns null.

指定者:

getRawResult 在类中 ForkJoinTask<Void>

返回:

null always

setRawResult

protected final void setRawResult(Void mustBeNull)

Requires null completion value.

指定者:

setRawResult 在类中 ForkJoinTask<Void>

参数:

mustBeNull - the value

exec

protected final boolean exec()

Implements execution conventions for RecursiveActions.

指定者:

exec 在类中 ForkJoinTask<Void>

返回:

true if this task is known to have completed normally