Why is an object sometimes null, when it gets initialized in a thread and accessed from main?

Question

When I create a new object in a thread which is an attribute of an object I´am giving to the thread it stays null in the main-function (but just without the System.out). I wrote a simple example of my Problem, which has the same result:

public class T1 {
    public T2 t2;
}
public class T2 {
    public String s;
    /**
     * @param args
     */
    public static void main(String[] args) {
        T1 t1 = new T1();

        T3 thread = new T3(t1);
        thread.start();

        while(t1.t2 == null){
    //      System.out.println("null");
        }
        System.exit(0);
    }
}

public class T3 extends Thread{
    public T1 t1;

    public T3(T1 t1){
        this.t1 = t1;
    }

    @Override
    public void run(){
        try {
            Thread.sleep(1000);
        } catch (InterruptedException e) {
            e.printStackTrace();
        }
        t1.t2 = new T2();
        while(true){
            System.out.println(t1.t2);
        }
    }
}

So without System.out.println("null") it results in an infinite loop, but when I add this System.out it behaves like I suspect. I even get the same result or problem if I use static variables.

Is there some sort of optimization or something else I don´t understand? Or why is t1.t2 always == null without System.out.println("null")? I thought the T1-object and his attributes (in this case the object t2) will be created on the heap, which is shared between all threads and just the t1-reference-variable is stored on the stack. So hopefully someone can explain me, why it stays null without the System.out... The problem just occurs if the thread is executed after the while-loop, thats why there is a sleep(1000).

Answer 1

So without System.out.println("null") it results in an infinite loop, but when I add this System.out it behaves like I suspect. I even get the same result or problem if I use static variables.

If a thread is updating a value that another thread is reading, there must be some sort of memory synchronization. When you add the System.out.println(...) this uses the underlying PrintStream which is a synchronized class. So the call to println(...) is what synchronizes the memory between the threads.

Here's some good information around memory synchronization from Oracle.

You should add volatile to the T2 t2; field to have the updates to t2 be visible between threads.

The real problem here is that with a modern multi-CPU (and core) hardware, each CPU has its own high speed memory caches. Modern OS and JVM software makes use of these physical (and virtual) CPUs to schedule threads to run in parallel simultaneously. These caches are a critical part of threading performance. If every read and every write had to go to central storage, your application would run 2+ times order of magnitude slower. The memory synchronization flushes the cache so that local writes getting written to central storage, and local cached reads are marked dirty so they have to be re-read from central storage when necessary.