# Bad result from Java modulo operator?

I suspect this has been asked before, but can't seem to find a question that matches...

I'm using Scala, but I'm pretty sure this is just a Java problem... input values are doubles

``````println(28.0 / 5.6)
println(28.0 % 5.6)
``````

The result of these lines is

``````5.0
1.7763568394002505E-15
``````

Which means that Java is performing the division correctly, but for some reason getting the modulo wrong, since the modulo should be 0 for any division problem that resolves to a whole number...

Is there a workaround for this?

Thanks!

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You're doing float-math here. The divide doesn't give you "5" but gives you "something like 5.0". Theres not infinite precision. The modulo gives you the remainder, which is also subject to the same precission problem, and gives you something close-ish to 0. Within the precision you have, this rather close to the answer. ONly sollution is: don't do float-math is you aim for exact answers? –  Nanne Aug 16 '11 at 19:11
FWIW: C# yields the same results with doubles, so it's clearly not just a Java issue. –  StriplingWarrior Aug 16 '11 at 19:16
@StriplingWarrior: It's not an "issue" with Java or C# at all. It's an issue with the OP's interpretation of the results :) –  Jon Skeet Aug 16 '11 at 19:17
@Jon Skeet: Thanks for clarifying. That's the point I was trying to make, but I didn't state it quite right. It's not "just a Java problem" as the OP states, but rather an indication of what happens when we try to force a binary calculator to give us binary results. –  StriplingWarrior Aug 16 '11 at 19:32
@ Jon Skeet -- okay, you just go and live in your own world where 56 * 5 is something other than 280 then -- the rest of us are living in this world where decimal math systems are supposed to be consistent –  Sam Dealey Aug 16 '11 at 19:42

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
}
}
``````
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More precisely, it's closer to 5.0 than any other double that can be represented in the default floating point precision of println. –  Russell Borogove Aug 16 '11 at 19:12
@Nayuki: No, 5.0 is "as close to the theoretical result of the operation as any other double is". I didn't say that the 5.0 wasn't exactly 5 - I said the precise result wasn't 5. See the bottom part of my edited answer and you'll see what I mean... –  Jon Skeet Aug 16 '11 at 19:16
(Edited for clarity anyway.) –  Jon Skeet Aug 16 '11 at 19:16
@Nayuki Minase: In the calculation itself, there is a slight floating-point imprecision, but when you represent the calculated value as a Double with a whole number value, it loses the precision necessary to preserve this imprecision (weird, huh?). A double doesn't have enough bits to represent 5.000000000000001, so it will become 5.0 exactly. However, when the result of the calculation no longer includes the "5", that causes the 0.000000000000001 to appear. The `double` is capable of representing this now because it doesn't have to represent all the digits between the 5 and the 1. –  StriplingWarrior Aug 16 '11 at 19:22

The result isn't actually 0, but it's pretty close( 0.00000000000000177635... ). The problem is that some decimal numbers can't be represented exactly in binary, so that's where the issue is coming in; I'd suspect that the same result would be printed out in C/C++.

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C/C++ gets around the issue by prohibiting `float` or `double` from being arguments to the modulus operator :) –  QuantumMechanic Aug 16 '11 at 19:14
Ah, did not realize that. I've never actually had a reason to do it. –  rm5248 Aug 16 '11 at 19:16
While C/C++ do not have a modulo operator applicable to floating-point types, they do have an equivalent function, remainder() for double, remainderf() for float. For the case at hand the output from the double version matches what Sam Dealey is seeing with Java: x= 2.8000000000000000e+001 (403c000000000000), y= 5.5999999999999996e+000 (4016666666666666), res= 1.7763568394002505e-015 (3ce0000000000000). As pointed out by other posters, the issue is that 5.6 is not exactly representable in a double. The result of remainder() itself is always exact. –  njuffa Aug 17 '11 at 2:26

### Arithmetic

First of all, the decimal number 5.6 cannot be represented exactly in binary floating-point. It is rounded to the exact binary fraction 3152519739159347/249.

The fact that 28.0 / 5.6 = 5.0 is because 5.0 is the closest `double` number to the true result, where the true result is 5.0000000000000003172065784643....

As for 28.0 % 5.6, the true result is exactly 1/249, which is approximately 1.776 × 10−15, so the calculation is correctly rounded.

### Workarounds

Why do you need a workaround? For most applications, keeping the very slightly wrong result is fine. Are you concerned about displaying "pretty" results?

If you need absolutely precise arithmetic, then you will need to use some implementation of BigFraction.

The topic of floating-point caveats has been covered in a variety of articles:

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I'm creating a ruler for an art application and using the modulo to determine an index in an array to find the height of the mark on the ruler -- if it doesn't find a height with a modulo value of zero it returns -1 and produces an ArrayIndexOutOfBounds error, so yeah, it's not a question of "pretty", it's functional –  Sam Dealey Aug 16 '11 at 19:46
Can you rewrite your math code so that you only do integer arithmetic? For example instead of 28 % 5.6, how about shifting everything left by one place and calculating 280 % 56? –  Nayuki Minase Aug 16 '11 at 20:09

This is my solution for check if double value is divisible by another using modulo operator:

``````public class DoubleOperation
{
public static final double EPSILON = 0.000001d;

public static boolean equals(double val1, double val2)
{
return (Math.abs(val1 - val2) < EPSILON);
}

public static boolean divisible(double dividend, double divisor)
{
double divisionRemainder = dividend % divisor;
return (equals(divisionRemainder, 0.0d) || equals(divisionRemainder, divisor));
}
}
``````
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