The 5.0 just shows that the *precise* result as Java understands it is closer to 5.0 than it is to any other double. That doesn't mean the precise result of the operation is *exactly* 5.

Now when you ask for the modulus, you're able to down to a much finer level of detail, because the result isn't pinned to having the "5" part.

That's not a great explanation, but imagine you had a *decimal* floating point type with 4 digits of precision. What's the result of 1000 / 99.99 and 1000 % 99.99?

Well, the real result starts with 10.001001 - so you have to round that to 10.00. However, the remainder is 0.10, which you can express. So again, it *looks* like the division gives you a whole number, but it doesn't *quite*.

With that in mind, bear in mind that your literal of 5.6 is *actually* 5.5999999999999996447286321199499070644378662109375. Now clearly 28.0 (which *can) be represented exactly divided by that number isn't exactly 5.

EDIT: Now if you perform the result with *decimal* floating point arithmetic using `BigDecimal`

, the value really *is* exactly 5.6, and there are no problems:

```
import java.math.BigDecimal;
public class Test {
public static void main(String[] args) {
BigDecimal x = new BigDecimal("28.0");
BigDecimal y = new BigDecimal("5.6");
BigDecimal div = x.divide(y);
BigDecimal rem = x.remainder(y);
System.out.println(div); // Prints 5
System.out.println(rem); // Prints 0.0
}
}
```