luni/src/main/java/java/util/concurrent/RecursiveAction.java - platform/libcore - Git at Google

 /*
  * Written by Doug Lea with assistance from members of JCP JSR-166
  * Expert Group and released to the public domain, as explained at
  * http://creativecommons.org/publicdomain/zero/1.0/
  */

 package java.util.concurrent;

 /**
  * A recursive resultless {@link ForkJoinTask}.  This class
  * establishes conventions to parameterize resultless actions as
  * {@code Void} {@code ForkJoinTask}s. Because {@code null} is the
  * only valid value of type {@code Void}, methods such as {@code join}
  * always return {@code null} upon completion.
  *
  * <p><b>Sample Usages.</b> Here is a simple but complete ForkJoin
  * sort that sorts a given {@code long[]} array:
  *
  * <pre> {@code
  * 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++];
  *   }
  * }}</pre>
  *
  * You could then sort {@code anArray} by creating {@code new
  * SortTask(anArray)} and invoking it in a ForkJoinPool.  As a more
  * concrete simple example, the following task increments each element
  * of an array:
  * <pre> {@code
  * 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));
  *     }
  *   }
  * }}</pre>
  *
  * <p>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 {@code next} references. It uses a dynamic
  * threshold based on method {@code getSurplusQueuedTaskCount}, but
  * counterbalances potential excess partitioning by directly
  * performing leaf actions on unstolen tasks rather than further
  * subdividing.
  *
  * <pre> {@code
  * 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;
  *   }
  * }}</pre>
  *
  * @since 1.7
  * @author Doug Lea
  */
 public abstract class RecursiveAction extends ForkJoinTask<Void> {
     private static final long serialVersionUID = 5232453952276485070L;

     /**
      * The main computation performed by this task.
      */
     protected abstract void compute();

     /**
      * Always returns {@code null}.
      *
      * @return {@code null} always
      */
     public final Void getRawResult() { return null; }

     /**
      * Requires null completion value.
      */
     protected final void setRawResult(Void mustBeNull) { }

     /**
      * Implements execution conventions for RecursiveActions.
      */
     protected final boolean exec() {
         compute();
         return true;
     }

 }
	/*
	* Written by Doug Lea with assistance from members of JCP JSR-166
	* Expert Group and released to the public domain, as explained at
	* http://creativecommons.org/publicdomain/zero/1.0/
	*/

	package java.util.concurrent;

	/**
	* A recursive resultless {@link ForkJoinTask}. This class
	* establishes conventions to parameterize resultless actions as
	* {@code Void} {@code ForkJoinTask}s. Because {@code null} is the
	* only valid value of type {@code Void}, methods such as {@code join}
	* always return {@code null} upon completion.
	*
	* <p><b>Sample Usages.</b> Here is a simple but complete ForkJoin
	* sort that sorts a given {@code long[]} array:
	*
	* <pre> {@code
	* 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++];
	* }
	* }}</pre>
	*
	* You could then sort {@code anArray} by creating {@code new
	* SortTask(anArray)} and invoking it in a ForkJoinPool. As a more
	* concrete simple example, the following task increments each element
	* of an array:
	* <pre> {@code
	* 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));
	* }
	* }
	* }}</pre>
	*
	* <p>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 {@code next} references. It uses a dynamic
	* threshold based on method {@code getSurplusQueuedTaskCount}, but
	* counterbalances potential excess partitioning by directly
	* performing leaf actions on unstolen tasks rather than further
	* subdividing.
	*
	* <pre> {@code
	* 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;
	* }
	* }}</pre>
	*
	* @since 1.7
	* @author Doug Lea
	*/
	public abstract class RecursiveAction extends ForkJoinTask<Void> {
	private static final long serialVersionUID = 5232453952276485070L;

	/**
	* The main computation performed by this task.
	*/
	protected abstract void compute();

	/**
	* Always returns {@code null}.
	*
	* @return {@code null} always
	*/
	public final Void getRawResult() { return null; }

	/**
	* Requires null completion value.
	*/
	protected final void setRawResult(Void mustBeNull) { }

	/**
	* Implements execution conventions for RecursiveActions.
	*/
	protected final boolean exec() {
	compute();
	return true;
	}

	}