Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm sorry if I'm doing a bad thing with this, but I have a question which is a spin-off of this question here:

Why volatile in java 5+ doesn't synchronize cached copies of variables with main memory?

Basically, I wanted to see what happends when the volatile is eliminated from the a variable. Here's the code from the original question, with my modification applied:

public class Test {
    //volatile static private int a;
    static private int a;
    static private int b;
public static void main(String [] args) throws Exception {
    for (int i = 0; i < 100; i++) {
        new Thread() {

            public void run() {
                int tt = b; // makes the jvm cache the value of b

                while (a==0) {

                //some threads never get here (past the a==0 loop)

                if (b == 0) {


    b = 1;
    a = 1;

And what happens on my laptop (Win 7 64, JVM build 1.7.0_04-b22) is that without the volatile, the code seems to run forever (left in running for 20 minutes). Adding some more console output told me that while most of the 100 threads do finally see the change in a from 0 to 1, there's always a few left (less than 10) that keep doing the a==0 loop.

My question is: will those threads finally see that change as well? If yes, is it normal to take 10s of thousands of times more time to do it as compared to the majority of similar threads? How come?

share|improve this question
consider putting the code here as well in case the other question gets deleted, and just for the purposes of having self contained question. –  Matti Lyra Aug 19 '13 at 11:02
Please post the code, people may not like browsing other pages –  sanbhat Aug 19 '13 at 11:04
@MattiLyra: as per your request, I've added the code snippet. –  Shivan Dragon Aug 19 '13 at 17:55
Thank you for the answers and comments, they're all very helpful. I see most people say in them that it's normal and somewhat expected to have the threads hang forever if volatile is not used (and I get now why this is so). However I was thrown off initially by some examples I've found which basically said that for such a case, the bad thing that can happen is that the "happens before" is not respected, i.e. some threads would see the change to a but not to b, not that some changes would never ever propagate. –  Shivan Dragon Aug 19 '13 at 18:07

2 Answers 2

up vote 3 down vote accepted

Each thread has its own local memory. Making changes, even to the same variable, from one thread, may not (and you should assume: will not) propagate to other threads.

To enforce memory synchronization between threads you have to use synchronized block and obtain the variable value within that block.

The simplest way to achieve that is to use Atomic-class variable, like AtomicInteger. It ensures atomic and data race-free access to their values.

Using volatile is an option, but it prevents any compiler optimization of that variable. Besides, it only applies to atomic operations, you may encounter various race conditions with it, which can be avoided using a synchronized block.

The most precise and detailed information on how Java Memory model actually works can be found in the Java Language Specification and JSR-133 Java Memory Model and Thread Specification. Various interpretations (including mine) of these documents may be wrong, so remember to look at reliable sources when in doubt.

share|improve this answer
Not data races, which is an official JMM term. Race conditions of other kinds, yes. –  Marko Topolnik Aug 19 '13 at 11:20
AtomicInteger is all about lock-free programming. Grep its source code for synchronized, you won't find it. –  Marko Topolnik Aug 19 '13 at 11:21
@MarkoTopolnik ack, Atomics use volatiles; as for data races: I will trust you on this and will read Formalising Java’s Data Race Free Guarantee later. –  Dariusz Aug 19 '13 at 11:24
Atomics also use the Unsafe class to do low-level compare-and-swap operations, which often map to single CPU instructions. Therein lies their true magic. –  Marko Topolnik Aug 19 '13 at 11:36
@ShivanDragon I have added important links to my answer. Regardless of whether in your case what I wrote is true or not, these links I added are the best sources of information. Good luck! –  Dariusz Aug 20 '13 at 7:51

This is not at all about the speed of the propagation of the variable; the machine code may be such that the memory write isn't even attempted. The value could reside in a register.

Anyway, my suggestion would be not to explore the behavior of broken Java code: it will always be different, anyway. Instead, learn how to write correctly synchronized programs. Study the Java Memory Model in detail and understand its guarantees. The guarantees of the JMM are quite distantly removed from the actual JVM implementation code which upholds those guarantees, and the JMM was specifically written to give the JVM the freedom to apply all kinds of optimizations.

As a specifically poignant example, the behavior of your broken code can change in the midst of its execution, as the interpreted, or C1 code is being replaced just-in-time with C2 code. There is just nothing to learn from running the program you refer to.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.