In Effective Java: item 66, Joshua Bloch gave an example about life failure:

// Broken! - How long would you expect this program to run
class StopThread {
    private static boolean stopRequested = false;

    public static void main(String[] args) 
            throws InterruptedException {

        Thread backgroundThread = new Thread(new Runnable() {
            public void run() {
                int i = 0;
                while (!stopRequested) {

        stopRequested = true;

As Joshua Bloch said, this program would not terminate. But, if I change i++ into System.out.println(i++), it terminates successfully!

I can't figure out how it happens!

  • Independent of the answers, you also need to consider that the book is 10 years and 3 major versions old. Things change, sometimes. – Sean Patrick Floyd Feb 22 '16 at 16:52
  • @SeanPatrickFloyd Sometimes they don't, though: the behaviour reported in the item still happens. – Andy Turner Feb 22 '16 at 16:54
  • @AndyTurner I know. Which is why I provided this as comment, not as answer – Sean Patrick Floyd Feb 22 '16 at 16:55
  • @SeanPatrickFloyd What you said is a red herring. What held true for Java 10 years ago is still largely true today. In this particular case, the concurrency behavior is still totally legal and according to spec. – Nayuki Feb 22 '16 at 17:16
  • I never said otherwise. I am a huge advocate of Effective Java myself. – Sean Patrick Floyd Feb 22 '16 at 17:23

The problem is related to the memory value of the variable stopRequest.

This variable is not defined as volatile.

If you have a two processors the inner thread check the value of stopRequest taken from its registry.

The main thread alter the value of stopRequest in the registry of the other processor.

So the main thread modify a value of stopRequest but the thread see only a copy of it that never changes.

Modified after take a look at the source code of PrintStream (thanks to the commend of ΔλЛ): Using a System.out.print command will use an explicit synchronized block to print the value passed to it this will grant that the value of stopRequest is taken from the main memory and not from the registry of the processor.

Adding a volatile keyword will inform the JVM to take the value from the main memory instead from the registries of the processors and it solve the problem.

Also using the keyword synchronized will solve this problem because any variable used in the synchronized block is taken and update the main memory.

Memory model without volatile (Main thread use Processor 1 and explicit thread use Processor 2)

Processor 1         Processor 2     Main memory
-----------         -----------     -----------
  false                false           false
  true                 false           true       // After setting 
                                                  //stopRequest to true

Defining stopRequest as volatile where all threads read stopRequest from main memory.

    Processor 1         Processor 2     Main memory
-----------         -----------     -----------
       NA                   NA           false
       NA                   NA           true       // After setting 
                                                  //stopRequest to true
  • 1
    @flkes: it would be better to use interruption for this, and not make a flag that duplicates existing functionality. should mention that the println acquires a lock and it ends up forcing the variable's updated value to become visible. – Nathan Hughes Feb 22 '16 at 16:57
  • 3
    Yes.... but I think that the efforts of Joshua were to explain that also a subtle error can create very strange errors, but for sure also an AtomicBoolean will solve this problem. – Davide Lorenzo MARINO Feb 22 '16 at 16:57
  • @NathanHughes true; could just call Thread::interrupt. I was just thinking more generally about accessing a boolean from multiple threads. – flakes Feb 22 '16 at 17:02
  • 1
    I think it's important to note that just adding synchronized isn't guaranteed to solve the problem, unless both threads synchronize on the same exact object. Otherwise, the synchronization makes it a bit more likely that the write will be see, but not guaranteed. – yshavit Feb 22 '16 at 17:05
  • @ ΔλЛ You are true. It is not a new thread. Just the synchronized keyword that will cause the read from the main memory. Thanks – Davide Lorenzo MARINO Feb 22 '16 at 17:15

Since you are not telling the thread that stopRequested is a value that can be modified from outside that thread there are no guarantees that the while will evaluate to the most recent value of the variable.

This is why the volatile keyword is useful in this situation, because it will explicitly enforce that stopRequested value, when read, will be the most recent value set by any thread.

There are further considerations, actually from the point of view of the thread, stopRequested is a loop invariant, since it is never set by only read, so optimization choices should be considered too: if a value is thought not to be modified then there is no reason to evaluate it on each iteration.

  • It doesn't explain the effect of System.out.println() in this context though. – syntagma Feb 22 '16 at 16:58
  • The effect of System.out.println() is not certain IMHO, on some machine it could solve the problem on some others it couldn't so it's irrelevant to understand the reason since the problem is elsewhere. According to how threads are allocated on CPUs, who is taking care of buffered output and such things. It's a sort of undefined behavior. – Jack Feb 22 '16 at 17:01
  • @Jack my question is: why System.out.println() changes the state of program, even not using synchronized and volatile key words. – HuangDong.Li Feb 23 '16 at 13:43
  • @HuangDong.Li: that's an XY problem, it's irrelevant why something seems to fix a problem when the problem is elsewhere. It's like asking why checking for var != nullptr when var is unitialized in C++ works when compiled without optimization under a specific environment. Totally irrelevant. – Jack Feb 23 '16 at 14:34

tl;dr: It's most likely an "accidental" side effect of println being synchronized.

First, realize that it's not the case that the thread is guaranteed not to finish; it's that it's not guaranteed that it will finish. In other words, the race condition on stopRequested — caused by the fact that one thread is writing to it, and another thread is reading from it, and there's no synchronization between the two threads — means that the JVM may, but is not required to, let the reader see what the writer has done.

So, why does System.out.println change this? Because it's a synchronized method. This doesn't actually give you any guarantees about stopRequested as far as the JLS is concerned, but it does mean that the JVM has to do some things, like acquiring a(n unrelated) lock, and establishing (unrelated) happens-before edges, that make it more likely that the write to stopRequested will be seen across threads.


System.out.println() requests a resource to write on the console, which in itself a blocking method… meaning, it will block the backgroundThread() to print() on the console. This is similar to sending an interrupt to it.

Thus, backgroundThread() will become aware of the change in the value of the boolean and stop executing, thereby terminating the Daemon.

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