luni/src/main/java/java/util/concurrent/RecursiveTask.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 result-bearing {@link ForkJoinTask}.
  *
  * <p>For a classic example, here is a task computing Fibonacci numbers:
  *
  *  <pre> {@code
  * class Fibonacci extends RecursiveTask<Integer> {
  *   final int n;
  *   Fibonacci(int n) { this.n = n; }
  *   Integer compute() {
  *     if (n <= 1)
  *       return n;
  *     Fibonacci f1 = new Fibonacci(n - 1);
  *     f1.fork();
  *     Fibonacci f2 = new Fibonacci(n - 2);
  *     return f2.compute() + f1.join();
  *   }
  * }}</pre>
  *
  * However, besides being a dumb way to compute Fibonacci functions
  * (there is a simple fast linear algorithm that you'd use in
  * practice), this is likely to perform poorly because the smallest
  * subtasks are too small to be worthwhile splitting up. Instead, as
  * is the case for nearly all fork/join applications, you'd pick some
  * minimum granularity size (for example 10 here) for which you always
  * sequentially solve rather than subdividing.
  *
  * @since 1.7
  * @author Doug Lea
  */
 public abstract class RecursiveTask<V> extends ForkJoinTask<V> {
     private static final long serialVersionUID = 5232453952276485270L;

     /**
      * The result of the computation.
      */
     V result;

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

     public final V getRawResult() {
         return result;
     }

     protected final void setRawResult(V value) {
         result = value;
     }

     /**
      * Implements execution conventions for RecursiveTask.
      */
     protected final boolean exec() {
         result = 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 result-bearing {@link ForkJoinTask}.
	*
	* <p>For a classic example, here is a task computing Fibonacci numbers:
	*
	* <pre> {@code
	* class Fibonacci extends RecursiveTask<Integer> {
	* final int n;
	* Fibonacci(int n) { this.n = n; }
	* Integer compute() {
	* if (n <= 1)
	* return n;
	* Fibonacci f1 = new Fibonacci(n - 1);
	* f1.fork();
	* Fibonacci f2 = new Fibonacci(n - 2);
	* return f2.compute() + f1.join();
	* }
	* }}</pre>
	*
	* However, besides being a dumb way to compute Fibonacci functions
	* (there is a simple fast linear algorithm that you'd use in
	* practice), this is likely to perform poorly because the smallest
	* subtasks are too small to be worthwhile splitting up. Instead, as
	* is the case for nearly all fork/join applications, you'd pick some
	* minimum granularity size (for example 10 here) for which you always
	* sequentially solve rather than subdividing.
	*
	* @since 1.7
	* @author Doug Lea
	*/
	public abstract class RecursiveTask<V> extends ForkJoinTask<V> {
	private static final long serialVersionUID = 5232453952276485270L;

	/**
	* The result of the computation.
	*/
	V result;

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

	public final V getRawResult() {
	return result;
	}

	protected final void setRawResult(V value) {
	result = value;
	}

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

	}