I got different execution result from the follow code if the Simple class field a was modified by final keyword.

If the a is a final field , this program will normally exit; If it's a plain field, this program will keep running all the time.

This situation only occurs in C2 compiler .

I thought this situation is related to visibility of the flag field in multi-threads environment.However, I try to observed the assembly code by hsdis ,and found the difference between with and without final keyword.

I found nothing difference.

Actually, I know the storing "final" field would not emit any assembly instructions on x86 platform. But why this situation came out? Are there some particular operations I don't know ?

Thanks for reading.

class MultiProcessorTask {

    private boolean flag= true;

    public void runMethod() {
        while (flag) {
            new Simple(1);

    public void stopMethod() {
        System.out.println("change 'flag' field ...");
        flag= false;

class ThreadA extends Thread {

    private MultiProcessorTask task;

    ThreadA(MultiProcessorTask task) {this.task = task;}

    public void run() {

class Simple {
    private int a;  // modify "a" as "final"

    Simple(int a) {this.a = a;}

public class TestRun {
    public static void main(String[] args) {
        MultiProcessorTask task = new MultiProcessorTask();
        ThreadA a = new ThreadA(task);
        System.out.println("it's over");

The disassembly code output:

  • The runMethod in the final case:

the final case

  • The runMethod in the non-final case:

the non-final case

  • 1
    I've just tried to run your code and in both cases the result is the same.
    – Amongalen
    Aug 9, 2019 at 9:53
  • 1
    Maybe it got something to do with Java Memory Model. It might emit the memory barrier that lets both thread see same value of the flag. Thing is, right now task thread aren't guaranteed to observe any particular value of flag. You should mark the flag volatile. Aug 9, 2019 at 9:54
  • 1
    Can you post the x86 disassembly you get with -XX:+PrintOptoAssembly? I don't have a debug version of the JVM Aug 10, 2019 at 8:04
  • 1
    @LeonWong Section 17.5 of the JLS explains what is happening: An object is considered to be completely initialized when its constructor finishes. A thread that can only see a reference to an object after that object has been completely initialized is guaranteed to see the correctly initialized values for that object's final fields.. If you look a the disassembly for the runMethod you'll see that in the non final case the thread enters a loop where only polls are done (I assume you know how the JVM safepoints works) and cannot exit it. ... Aug 10, 2019 at 10:46
  • 1
    ... This is because, without the final field, there is nothing that force the update of the JVM state between each iteration of the loop.The final version instead, don't loop (though I'm not sure why the execution its an hlt). Aug 10, 2019 at 10:46

1 Answer 1


You've disassembled the wrong compilation. I mean, there is a standalone compiled runMethod on both screenshots, however, it is never executed in reality. Instead, execution jumps from the interpreter to the OSR stub. You need to look for a compilation marked with % sign (which denotes on-stack replacement).

Compiled method (c2)     646  662 %           MultiProcessorTask::runMethod @ 0 (20 bytes)

Here is difference in the compiled code between non-final and final cases. I left only the relevant part:


  0x000000000309ae31: test   %eax,-0x5aae37(%rip)   ; safepoint poll
  0x000000000309ae37: jmp    0x000000000309ae31     ; loop


  0x0000000002c3a3a0: test   %eax,-0x265a3a6(%rip)  ; safepoint poll
  0x0000000002c3a3a6: movzbl 0xc(%rbx),%r11d        ; load 'flag' field
  0x0000000002c3a3ab: test   %r11d,%r11d
  0x0000000002c3a3ae: jne    0x0000000002c3a3a0     ; loop if flag == true

Indeed, the first case is compiled to an inifite loop, while the second one retains the field check.

You see, in both cases there is no Simple instance allocation at all, and no field assignment either. So, it's not a matter of instructions used to compile the final field assignment, but rather a compiler level barrier which prevents from caching the flag field out of the loop.

But since the allocation is eliminated altogether, the barrier implied by final field assignment can go away, too. Here we see just a missed optimization opportunity. And in fact, this missed optimization was fixed in newer JVM versions. If you run the same example on JDK 11, there will be an infinite loop in both cases, regardless of the final modifier.

  • 1
    As said in this comment, the fix is already in Java 9. As a side note, even without eliminating the object allocation, the optimization barrier is not necessary, at least not in that restrictive form.
    – Holger
    Aug 12, 2019 at 7:19

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