You can store above 2billions of ints in a long. What's the problem?
Well, if you need even more ints. Do a simple class holding multiple longs (and long[] will do), and add on top of the 1st. Each 2billions of adds, get a fresh new long.

In the end (avg) sum the longs in a BigInteger and divide. The code has close to no overhead, one extra counter and one extra check (that's branch predicted).

[hopefully I didn't make some stupid off by 1 ;) ]

```
package t1;
import java.math.BigInteger;
import java.util.Arrays;
public class Avg {
long sum;
long[] totals = new long[0];
int counter;
public void add(int v){
if (counter++==Integer.MAX_VALUE){
counter = 0;
int len =totals.length;
totals = Arrays.copyOf(totals, len+1);
totals[len]=sum;
sum = 0;
}
sum+=v;
}
public int avg(){
long count = this.counter;
count+=totals.length*(long)Integer.MAX_VALUE;
BigInteger sum = BigInteger.valueOf(this.sum);
for (long subSum : totals)
sum=sum.add(BigInteger.valueOf(subSum));
return sum.divide(BigInteger.valueOf(count)).intValue();//tweak if you need be
}
}
```

`currentAverage * currentCount`

, and ignoring floating point inaccuracy the result of that multiplication is exactly the same value that everyone else is storing in a`long`

or`BigInteger`

running total. You just do a lot of unnecessary division along the way. – Steve Jessop Jan 25 '11 at 17:11algorithm, just the datatype. Assuming that`double`

is the correct datatype to use for the sum, your answer does extra work (perhaps introducing extra inaccuracy), that's completely unrelated to avoiding overflow. Using a running average doesn't help avoid overflow in any way. – Steve Jessop Jan 25 '11 at 17:15