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I've been reading about non-blocking approaches for some time. Here is a piece of code for so called lock-free counter.

public class CasCounter {
private SimulatedCAS value;

public int getValue() {
    return value.get();

public int increment() {
    int v;
    do {
        v = value.get();
    while (v != value.compareAndSwap(v, v + 1));
    return v + 1;


I was just wondering about this loop:

do {
    v = value.get();
while (v != value.compareAndSwap(v, v + 1));

People say:

So it tries again, and again, until all other threads trying to change the value have done so. This is lock free as no lock is used, but not blocking free as it may have to try again (which is rare) more than once (very rare).

My question is:

How can they be so sure about that? As for me I can't see any reason why this loop can't be infinite, unless JVM has some special mechanisms to solve this.

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And what would be the advantages of this approach (if it would work)? –  Alex Calugarescu Jan 28 '12 at 9:00
Does compareAndSwap return the old value or the new one? –  Tudor Jan 28 '12 at 9:21
@Tudor, I am not sure. In fact I've never tried this myself. However, I read that in different languages could be different implementations: ones return boolean, others - the value should check yourself. –  Max Jan 28 '12 at 9:42
@Alex Calugarescu: v+1 does not need to be atomic because v is a local variable. The code posted is correct. And I don't see how a reading about producer-consumer will help in this case. –  Tudor Jan 28 '12 at 16:25
But the code is correct and safe. I don't see where you are objecting. –  Tudor Jan 28 '12 at 16:54

2 Answers 2

up vote 2 down vote accepted

The loop can be infinite (since it can generate starvation for your thread), but the likelihood for that happening is very small. In order for you to get starvation you need some other thread succeeding in changing the value that you want to update between your read and your store and for that to happen repeatedly.

It would be possible to write code to trigger starvation but for real programs it would be unlikely to happen.

The compare and swap is usually used when you don't think you will have write conflicts very often. Say there is a 50% chance of "miss" when you update, then there is a 25% chance that you will miss in two loops and less than 0.1% chance that no update would succeed in 10 loops. For real world examples, a 50% miss rate is very high (basically not doing anything than updating), and as the miss rate is reduces, to say 1% then the risk of not succeeding in two tries is only 0.01% and in 3 tries 0.0001%.

The usage is similar to the following problem

Set a variable a to 0 and have two threads updating it with a = a+1 a million times each concurrently. At the end a could have any answer between 1000000 (every other update was lost due to overwrite) and 2000000 (no update was overwritten).

The closer to 2000000 you get the more likely the CAS usage is to work since that mean that quite often the CAS would see the expected value and be able to set with the new value.

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good one. I was thinking that it's all about real statistics and likelihood itself. And I guess the key point here in your words: The compare and swap is usually used when you don't think you will have write conflicts very often. And I took the situation when 2 threads did this operation all the time. –  Max Jan 29 '12 at 11:31

Edit: I think I have a satisfactory answer now. The bit that confused me was the 'v != compareAndSwap'. In the actual code, CAS returns true if the value is equal to the compared expression. Thus, even if the first thread is interrupted between get and CAS, the second thread will succeed the swap and exit the method, so the first thread will be able to do the CAS.

Of course, it is possible that if two threads call this method an infinite number of times, one of them will not get the chance to run the CAS at all, especially if it has a lower priority, but this is one of the risks of unfair locking (the probability is very low however). As I've said, a queue mechanism would be able to solve this problem.

Sorry for the initial wrong assumptions.

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saying should implement an arrival queue you mean a developer should care about this or it's already implemented in behind the stage? –  Max Jan 28 '12 at 10:05
It's not implemented. Repeatedly checking a non-blocking operation is by definition unfair. You can implement it yourself, but I hardly see the benefit, since the code you posted would not be used in practice. –  Tudor Jan 28 '12 at 10:13
Can't find anything specific in AtomicInteger class implementation though. –  Max Jan 28 '12 at 10:13
Atomic operations such as these are usually implemented by using an atomicity bit in the messages going from the CPU to the memory module where the value is located. Several messages can be sent in a sequence with the atomicity bit set and in the meantime the memory module will not accept transactions from other threads. –  Tudor Jan 28 '12 at 10:16
hm why the code I posted wouldn't be used in practice? It's pretty mush the same as implementation of decrementAndGet() method of AtomicInteger for instance. My initial question still in the place.:) –  Max Jan 28 '12 at 10:26

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