There is no general rule that ensures that adding `n`

copies of `1.0/n`

will result in exactly `1.0`

. This can be explored by changing `n`

in the following program:

```
import java.math.BigDecimal;
public class Test {
public static void main(String[] args) {
int n = 3;
double[] counts = new double[n+1];
for(int i=1; i<counts.length; i++){
counts[i] = counts[i-1]+1.0/n;
}
for(double count : counts){
System.out.println(new BigDecimal(count));
}
}
}
```

For `n=3`

it prints:

```
0
0.333333333333333314829616256247390992939472198486328125
0.66666666666666662965923251249478198587894439697265625
1
```

The first addition adds to zero. The second addition is a simple doubling, so it is also exact. The third and final addition involves rounding, but rounds to `1.0`

. The exact result of that addition is:

```
0.999999999999999944488848768742172978818416595458984375
```

It is closer to 1.0 than it is to the next value down:

```
0.99999999999999988897769753748434595763683319091796875
```

so round-to-nearest rounds to 1.0.

However, changing `n`

to `7`

results in:

```
0
0.142857142857142849212692681248881854116916656494140625
0.28571428571428569842538536249776370823383331298828125
0.428571428571428547638078043746645562350749969482421875
0.5714285714285713968507707249955274164676666259765625
0.7142857142857141905523121749865822494029998779296875
0.8571428571428569842538536249776370823383331298828125
0.9999999999999997779553950749686919152736663818359375
```

Running the original program modified to add `1.0/7`

would have resulted in an infinite loop. `count`

would have increased until it was so big that adding `1.0/7`

would round to the old value, and then stuck at that value.