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My question is an extension to this one: Java: volatile guarantees and out-of-order execution

To make it more concrete, let's say we have a simple class which can be in two states after it is initialized:

class A {
    private /*volatile?*/ boolean state;
    private volatile boolean initialized = false;

    boolean getState(){
        if (!initialized){
            throw new IllegalStateException();
        return state;

    void setState(boolean newState){
        state = newState;
        initialized = true;

The field initialized is declared volatile, so it introduces happen-before 'barrier' which ensures that reordering can't take place. Since the state field is written only before initialized field is written and read only after the initialized field is read, I can remove the volatile keyword from declaration of the state and still never see a stale value. Questions are:

  1. Is this reasoning correct?
  2. Is it guaranteed that the write to initialized field won't be optimized away (since it changes only the first time) and the 'barrier' won't be lost?
  3. Suppose, instead of the flag, a CountDownLatch was used as an initializer like this:

    class A {
        private /*volatile?*/ boolean state;
        private final CountDownLatch initialized = new CountDownLatch(1);
        boolean getState() throws InterruptedException {
            return state;
        void setState(boolean newState){
            state = newState;

    Would it still be alright?

share|improve this question
in the second case it will be visible the first time, however new updates after the first are not guaranteed to be visible. – ratchet freak Nov 9 '11 at 11:29
up vote 5 down vote accepted

Your code is (mostly) correct and it is a common idiom.

// reproducing your code
class A

    state=false;              //A
    initialized=false;        //B

    boolean state;
    volatile boolean initialized = false;        //0

    void setState(boolean newState)
        state = newState;                        //1
        initialized = true;                      //2

    boolean getState()
        if (!initialized)                        //3
            throw ...;
        return state;                            //4

Line #A #B are pseudo code for writing default values to variables (aka zeroing the fields). We need to include them in a strict analysis. Note that #B is different from #0; both are executed. Line #B is not considered a volatile write.

All volatile accesses(read/write) on all variables are in a total order. We want to establish that #2 is before #3 in this order, if #4 is reached.

There are 3 writes to initialized: #B, #0 and #2. Only #2 assigns true. Therefore if #2 is after #3, #3 cannot read true (this is probably due to the no out-of-thin-air guarantee which I don't fully understand), then #4 can't be reached.

Therefore if #4 is reached, #2 must be before #3 (in the total order of volatile accesses).

Therefore #2 happens-before #3 (a volatile write happens-before a subsequent volatile read).

By programming order, #1 happens-before #2, #3 happens-before #4.

By transitivity, therefore #1 happens-before #4.

Line#A, the default write, happens-before everything (except other default writes)

Therefore all accesses to variable state are in a happens-before chain: #A -> #1 -> #4. There is no data race. The program is correctly synchronized. Read #4 must observe write #1

There is a little problem though. Line #0 is apparently redundant, since #B already assigned false. In practice, a volatile write is not negligible on performance, therefore we should avoid #0.

Even worse, the presence of #0 can cause undesired behavior: #0 can occur after #2! Therefore it may happen that setState() is called, yet subsequent getState() keep throwing errors.

This is possible if the object is not safely published. Suppose thread T1 creates the object and publishes it; thread T2 gets the object and calls setState() on it. If the publication is not safe, T2 can observe the reference to the object, before T1 has finished initializing the object.

You can ignore this problem if you require that all A objects are safely published. That is a reasonable requirement. It can be implicitly expected.

But if we don't have line #0, this won't be a problem at all. Default write #B must happens-before #2, therefore as long as setState() is called, all subsequent getState() will observe initialized==true.

In the count down latch example, initialized is final; that is crucial in guaranteeing safe publication: all threads will observe a properly initialized latch.

share|improve this answer
I have a question. If the first thread calls setState(true) and after that the second thread calls getState() there is a big chance it will return false, because state is not volatile. The second thread may not observe the change at all. Am I right here? – Petar Minchev Nov 9 '11 at 17:30
@PetarMinchev that's addressed by #1 happens-before #2 happens-before #3 happens-before #4. Consequently, #1 happens-before #4. Volatility is only necessary for the #2 happens-before #3 part—the rest is established by normal execution order. – alf Nov 9 '11 at 17:33
You are mistaken. A formal analysis yields that read#4 must observe write#1. In an informal explanation, a volatile read will first clear the cache. So if the 2nd thread cached state, the cache is cleared upon reading volatile initialized; the subsequent read of state will effectively fetch from main memory, and sees the last assigned value. – irreputable Nov 9 '11 at 17:36
@irreputable - Does a volatile read of one variable clear the cache of all other non-volatile variables? – Petar Minchev Nov 9 '11 at 17:37
@Petar That is implied by the latest memory model. The old memory model (before Java5) indeed has no such guarantee(see In the new model, volatile write/read are like lock release/acquire for visibility. see – irreputable Nov 9 '11 at 17:55

1. Is this reasoning correct?

No, state will be cached in thread, so you can not get the latest value.

2. Is it guaranteed that the write to initialized field won't be optimized away (since it changes only the first time) and the 'barrier' won't be lost?


3. Suppose, instead of the flag, a CountDownLatch was used as an initializer like this...

just like @ratchet freak mentioned, CountDownLatch is one time latch, while volatile is kinda of reusable latch, so the answer for your third question should be: If you are going to set the state multiple times you should use volatile.

share|improve this answer
except that there is no acquire happening when the latch is empty. (correct me if I'm wrong) the docs say the await and countdown methods are no-ops when count() ==0 – ratchet freak Nov 9 '11 at 11:50
setState(...) first modifies a non-volatile variable, and then it performs a volatile write to initialized. After another thread performs a volatile read of initialized, it is guaranteed (as per chapter 17 of the JVM spec) that all modifications prior to the volatile write are visible to the thread after the volatile read, without need for further synchronization (or volatiles). – Bruno Reis Nov 9 '11 at 11:59
To make it clear: the second time setState is called, it will first change the state variable. If at this time, before the write to the volatile, another thread calls getState(), he will see the initialized variable as true, then read the state variable, where he might still see the old value of the state. – JB Nizet Nov 9 '11 at 12:00
JB Nizet, the second time setState is called, it will execute a new volatile write (writing the same value, but it is still a volatile write). Any voltile read after this one will guarantee that a read of state will reflect the current value in main memory. If a read of state by one thread occurs between the write to state and the volatile write by another thread, it has 2 possibilities: it will read the old value (which is exactly the same as if the call to getState() happened timely before the call to setState(...) by the second thread), or it will read the new value. – Bruno Reis Nov 9 '11 at 12:14
@Bruno Reis: I agree that in this case, it won't probably make a difference. The problem is that it's very fragile. If the state becomes two variables instead of one, or a long or double instead of a boolean, you could have serious problems. – JB Nizet Nov 9 '11 at 12:53

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