*Full disclaimer:* this is not really a homework, but I tagged it as such because it is mostly a self-learning exercise rather than actually "for work".

Let's say I want to write a simple thread safe modular counter in Java. That is, if the modulo `M`

is 3, then the counter should cycle through `0, 1, 2, 0, 1, 2, …`

ad infinitum.

Here's one attempt:

```
import java.util.concurrent.atomic.AtomicInteger;
public class AtomicModularCounter {
private final AtomicInteger tick = new AtomicInteger();
private final int M;
public AtomicModularCounter(int M) {
this.M = M;
}
public int next() {
return modulo(tick.getAndIncrement(), M);
}
private final static int modulo(int v, int M) {
return ((v % M) + M) % M;
}
}
```

My analysis (which may be faulty) of this code is that since it uses `AtomicInteger`

, it's quite thread safe even without any explicit `synchronized`

method/block.

Unfortunately the "algorithm" itself doesn't quite "work", because when `tick`

wraps around `Integer.MAX_VALUE`

, `next()`

may return the wrong value depending on the modulo `M`

. That is:

```
System.out.println(Integer.MAX_VALUE + 1 == Integer.MIN_VALUE); // true
System.out.println(modulo(Integer.MAX_VALUE, 3)); // 1
System.out.println(modulo(Integer.MIN_VALUE, 3)); // 1
```

That is, two calls to `next()`

will return `1, 1`

when the modulo is 3 and `tick`

wraps around.

There may also be an issue with `next()`

getting out-of-order values, e.g.:

*Thread1*calls`next()`

*Thread2*calls`next()`

*Thread2*completes`tick.getAndIncrement()`

, returns*x**Thread1*completes`tick.getAndIncrement()`

, returns*y = x+1 (mod M)*

Here, barring the forementioned wrapping problem, *x* and *y* are indeed the two correct values to return for these two `next()`

calls, but depending on how the counter behavior is specified, it can be argued that they're out of order. That is, we now have *(Thread1, y)* and *(Thread2, x)*, but maybe it should really be specified that *(Thread1, x)* and *(Thread2, y)* is the "proper" behavior.

So by some definition of the words, `AtomicModularCounter`

is *thread-safe*, but not actually *atomic*.

So the questions are:

- Is my analysis correct? If not, then please point out any errors.
- Is my last statement above using the correct terminology? If not, what is the correct statement?
- If the problems mentioned above are real, then how would you fix it?
- Can you fix it without using
`synchronized`

, by harnessing the atomicity of`AtomicInteger`

? - How would you write it such that
`tick`

itself is range-controlled by the modulo and never even gets a chance to wraps over`Integer.MAX_VALUE`

?- We can assume
`M`

is at least an order smaller than`Integer.MAX_VALUE`

if necessary

- We can assume

### Appendix

Here's a `List`

analogy of the out-of-order "problem".

*Thread1*calls`add(first)`

*Thread2*calls`add(second)`

Now, if we have the list updated succesfully with two elements added, but `second`

comes before `first`

, which is at the end, is that "thread safe"?

If that is "thread safe", then what is it not? That is, if we specify that in the above scenario, `first`

should always come before `second`

, what is that concurrency property called? (I called it "atomicity" but I'm not sure if this is the correct terminology).

For what it's worth, what is the `Collections.synchronizedList`

behavior with regards to this out-of-order aspect?