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I have an array of size N. I want to shuffle its elements in 2 threads (or more). Each thread should work with it's own part of the array.

Lets say, the first thread shuffles elements from 0 to K, and the second thread shuffles elements from K to N (where 0 < K < N). So, it can look like this:

//try-catch stuff is ommited
static void shuffle(int[] array) {
   Thread t1 = new ShufflingThread(array, 0, array.length / 2);
   Thread t2 = new ShufflingThread(array, array.length / 2, array.length);
   t1.start();
   t2.start();
   t1.join();
   t2.join();
}

public static void main(String[] args) {
   int array = generateBigSortedArray();
   shuffle(array);
}

Are there any guaranties from JVM that I will see changes in the array from the main method after such shuffling?

How should I implement ShufflingThread (or, how should I run it, maybe within a synchronized block or whatever else) in order to get such guaranties?

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I suppose that any thread-level caching ends after join() returns, so in the end you must get consistent data in array without declaring it volatile. But I'm not entirely certain in the case of a shared array. Maybe making a copy of either half of the array and passing it to one of the threads is a good idea. –  9000 Jan 19 '11 at 14:05
    
Just for your interest, this task is perfectly suited for the Java 7 Fork/join API, gee.cs.oswego.edu/dl/jsr166/dist/jsr166ydocs –  Andrew Jan 19 '11 at 14:29
1  
The problem you will have is that elements in the first half will never appear in the second half and visa-versa. As such you are shuffling two independant arrays (which happens to appear in the same object) i.e. you are not shuffling the whole array. If you shuffled cards this way, you might get all the black cards before all the red cards, every time. –  Peter Lawrey Jan 19 '11 at 14:36
    
@Peter Lawrey: thanks, it's a useful point. –  Roman Jan 19 '11 at 19:14
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5 Answers 5

up vote 1 down vote accepted

Thread.start() and Thread.join() are enough to give you the happens-before relationships between the array initialisation, its hand-off to the threads and then the read back in the main method.

Actions that cause happens-before are documented here.

As mentioned elsewhere, ForkJoin is very well suited to this kind of divide-and-conquer algorithm and frees you from a lot of the book-keeping that you'd otherwise need to implement.

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The join() calls are sufficient to ensure memory coherency: when t1.join() returns, the main thread "sees" whatever operations thread t1 did on the array.

Also, Java guarantees that there is no word-tearing on arrays: distinct threads may use distinct elements of the same array without needing synchronization.

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I think this is a good exercise in thread control, where (1) a job can be broken up into several parts (2) the parts can run independently and asynchronously and (3) A master thread monitors the completion of all such jobs in their respective threads. All you need is for this master thread to wait() and be notify()-ed jobCount times, every time a thread completes execution. Here is a sample code that you can compile/run. Uncomment the println()'s to see more.

Notes: [1] JVM doesnt guarantee the order of execution of the threads [2] You need to synchronize when your master thread access the big array, to not have corrupted data....

public class ShufflingArray {

private int nPart = 4,      // Count of jobs distributed, resource dependent
        activeThreadCount,  // Currently active, monitored with notify
        iRay[];         // Array the threads will work on

    public ShufflingArray (int[] a) {
    iRay = a;
    printArray (a);
}

private void printArray (int[] ia) {
    for (int i = 0 ; i < ia.length ; i++)
        System.out.print (" " + ((ia[i] < 10) ? " " : "") + ia[i]);
    System.out.println();
    }

public void shuffle () {
    int startNext = 0, pLen = iRay.length / nPart;  // make a bunch of parts
    for (int i = 0 ; i < nPart ; i++, activeThreadCount++) {
        int start = (i == 0) ? 0 : startNext,
            stop = start + pLen;
        startNext = stop;
        if (i == (nPart-1))
            stop = iRay.length;
        new Thread (new ShuffleOnePart (start, stop, (i+1))).start();
    }
    waitOnShufflers (0);        // returns when activeThreadCount == 0
    printArray (iRay);
}

synchronized private void waitOnShufflers (int bump) {
    if (bump == 0) {
        while (activeThreadCount > 0) {
            // System.out.println ("Waiting on " + activeThreadCount + " threads");
            try {
                wait();
            } catch (InterruptedException intex) {
    }}} else {
        activeThreadCount += bump;
        notify();
}}

public class ShuffleOnePart implements Runnable {
    private int startIndex, stopIndex;      // Operate on global array iRay

    public ShuffleOnePart (int i, int j, int k) {
        startIndex = i;
        stopIndex = j;
        // System.out.println ("Shuffler part #" + k);
    }

    // Suppose shuffling means interchanging the first and last pairs
    public void run () {
        int tmp = iRay[startIndex+1];
        iRay[startIndex+1] = iRay[startIndex];  iRay[startIndex] = tmp;
        tmp = iRay[stopIndex-1];
        iRay[stopIndex-1] = iRay[stopIndex-2];  iRay[stopIndex-2] = tmp;
        try {   // Lets imagine it needs to do something else too
            Thread.sleep (157);
        } catch (InterruptedException iex) { }
        waitOnShufflers (-1);
}}

public static void main (String[] args) {
    int n = 25, ia[] = new int[n];
    for (int i = 0 ; i < n ; i++)
        ia[i] = i+1;
    new ShufflingArray(ia).shuffle();

}}

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using ExecutorService from java.util.Concurrent package along with Callable Task to return the part of the array's from each thread run, once both thread are completed is another way to do for consistent behaviour.

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Well, they can't BOTH be accessing the same array and if you use a lock, or a mutex or any other synchronizing mechanism, you kinda lose the power of the threads (since one will have to wait for another, either to finish the shuffling or finish a bit of the shuffling). Why don't you just divide the array in half, give each thread its bit of the array and then merge the two arrays?

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-1 they both can access the same array –  dogbane Jan 19 '11 at 13:59
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