# Integer counter - What to do when Max-Value?

How do you solve the max value problem when using an integer counter, that looks like

``````counter = counter + 1;
``````

When this reaches the max value, how do you know this happened? Do you add another counter for this counting how often this happened?

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hi David, I do, but some are still open, the user want to edit it later, or it's closed. So there are'n as many to check as answered. :) –  Andreas Hornig Jan 7 '10 at 0:12
@Andreas: don't worry about the editing part - if a user wants to edit their answer, they can still do this after you've accepted it. –  Andrzej Doyle Jan 7 '10 at 1:51

For a fast saturated `int` increment (one that stops when it gets to `MAX_VALUE`), I guess you could write:

``````counters = (counter+1) + ((counter+1)>>31);
``````

Or

``````counters = (counter+1) - ((counter+1)>>>31);
``````

Or in the interests of fun, for `AtomicInteger`, I think:

``````private final AtomicInteger counter = new AtomicInteger(0);

public void increment() {
int count;
do {
count = counter.get();
if (count == Integer.MAX_VALUE) {
return;
}
} while (!counter.compareAndSet(count, count+1));
}
``````
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You can tell whether you have hit the max value by comparing against Integer.MAX_VALUE.

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Sometime "simple is the best" :) –  akuhn Jan 7 '10 at 0:32

Choose a numeric type that has a range that is comfortably large enough for your requirements. So if `int` isn't big enough use `long` or `BigInteger`.

You'll know when your `int` has surpassed `Integer.MAX_VALUE` because it will overflow and become negative.

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You have to know something about how large the 'counter' variable is likely to grow.

• Integer.MAX_VALUE is 2147483647
• Long.MAX_VALUE is 9223372036854775807L (considerably larger)

If neither of those 2 is large enough, BigInteger has no maximum (except what your machine can handle).

In practice most things you want to count easily fit within an int.

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Dan's answer is correct. However, if you're definitely incrementing by 1 each time and you need to use an int for some reason (can't imagine why) then you would indeed need a second counter, say b, that get's incremented every time a++ == max_value (or a++ % max_value == 0). You can do the same for b and so on. Essentially you're just working in base max_value arithmetic instead of base 10.

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Nice idea - though it's going to be fun trying to actually combine all of those counters together at the end: `int total = c * Integer.MAX_VALUE * Integer.MAX_VALUE + b * Integer.MAX_VALUE + a`... ;-) –  Andrzej Doyle Jan 7 '10 at 1:52

Well, what you do depends on what you need it for.

If you're doing it as a sort of ID generator for request messages being sent over a network, then, depending on your needs, you might not care about the overflow, because the oldest IDs will have expired by then. If it's important that the value has never been seen before, then you use a larger datatype - with a 64-bit long, you have more than 9 quintillion values, so that should be plenty (although in many cases, the 2.1 billion of an int should be enough too!)

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Just to put things into perspective: If you exhausted all ~4.3 billion values for an unsigned 32-bit integer in one second, it would take you approximately 68 years to exhaust a long, assuming constant speed - that's about 2 IDs per 3 people on Earth every second, which is insanely unrealistic. –  Michael Madsen Jan 7 '10 at 0:42
By the time the long rolls over, you will not need to care about it, because either the ID will have expired and can be reused, or you have the far bigger problem of being able to store many exabytes - if not zettabytes or even yottabytes - of data (someone's using the ID for something, so there must be some data associated with it). –  Michael Madsen Jan 7 '10 at 0:43

Having one int as a counter and another int to count the overflows gives you the same range as a long (less, actually as ints are signed, which is one wasted bit for the overflow counter).

You may want to use BigIntegers if you expect the counter to overflow.

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Java does not detect nor does it cause anything to occur with integer overflow, either negative or positive, with int or long types.

The primitive types int and long, along with their corresponding class types, Int and Long, overflow in either positive or negative direction in accordance with two's complement arithmetic. The first value after the maximum positive value is the maximum negative value. For ints, it is Integer.MIN_VALUE. For longs, it is Long.MIN_VALUE. The reverse happens with negative overflow. The first value after the maximum negative value is the maximum positive value. For ints, it is Integer.MAX_VALUE. For longs, it is Long.MAX_VALUE.

With a counter that increments by +1, a very simple way to detect overflow is to check to see if it has reached Integer.MAX_VALUE for an int or Long.MAX_VALUE for a long and take some graceful action such as starting over from 0. The alternative is to halt processing or accomodate the behavior of two's complement arithmetic which is rolls over to the maximum negative value and proceeds from there. If overflow is really an issue because you are using really large integers, then use an instance of the BigInteger class. It is almost as efficient as an int and likely a lot more efficient than handling the two's complement roll-over in your own code.

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You can start `counter` from `Integer.MAX_VALUE` and go down. You can stop at `Zero` or go upto `-Integer.MAX_VALUE`.

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This doesn't solve the problem of detecting or coping with overflow, though. Counting from MAX_VALUE down to zero will be exhausted after the same number of ticks as counting from zero up to MAX_VALUE anyway. Plus the counter value would be much harder to work with (I can guarantee someone will forget that the "real" value is `MAX_VALUE - counter` in any non-trivial situation). –  Andrzej Doyle Jan 7 '10 at 1:55