# Comparing double values for equality in Java.

I would like some advice from people who have more experience working with primitive `double` equality in Java. Using `d1 == d2` for two doubles `d1` and `d2` is not sufficient due to possible rounding errors.

My questions are:

1. Is Java's `Double.compare(d1,d2) == 0` handling rounding errors to some degree? As explained in the 1.7 documentation it returns value `0` if `d1` is numerically equal to `d2`. Is anyone certain what exactly they mean by numerically equal?

2. Using relative error calculation against some delta value, is there a generic (not application specific) value of delta you would recommend? Please see example below.

Below is a generic function for checking equality considering relative error. What value of `delta` would you recommend to capture the majority of rounding errors from simple operations +,-,/,* operations?

``````public static boolean isEqual(double d1, double d2) {
return d1 == d2 || isRelativelyEqual(d1,d2);
}

private static boolean isRelativelyEqual(double d1, double d2) {
return delta > Math.abs(d1- d2) / Math.max(Math.abs(d1), Math.abs(d2));
}
``````

You could experiment with delta values in the order of 10-15 but you will notice that some calculations give a larger rounding error. Furthermore, the more operations you make the larger will be the accumulated rounding error.

One particularly bad case is if you subtract two almost equal numbers, for example 1.0000000001 - 1.0 and compare the result to 0.0000000001

So there is little hope to find a generic method that would be applicable in all situations. You always have to calculate the accuracy you can expect in a certain application and then consider results equal if they are closer than this accuracy.

For example the output of

``````public class Main {

public static double delta(double d1, double d2) {
return Math.abs(d1- d2) / Math.max(Math.abs(d1), Math.abs(d2));
}

public static void main(String[] args) {
System.out.println(delta(0.1*0.1, 0.01));
System.out.println(delta(1.0000000001 - 1.0, 0.0000000001));
}

}
``````

is

``````1.7347234759768068E-16
8.274036411668976E-8
``````

Interval arithmetic can be used to keep track of the accumulated rounding errors. However in practise the error intervals come out too pessimistic, because sometimes rounding errors also cancel each other.

• What if the expected value is 0.0? Oct 4, 2017 at 11:34
• @simon.watts Nothing special, as I said above: "there is little hope to find a generic method that would be applicable in all situations". Oct 4, 2017 at 11:49

You could try something like this (not tested):

``````public static int sortaClose(double d1, double d2, int bits) {
long bitMask = 0xFFFFFFFFFFFFFFFFL << bits;
long thisBits = Double.doubleToLongBits(d1) & bitMask;
long anotherBits = Double.doubleToLongBits(d2) & bitMask;

if (thisBits < anotherBits) return -1;
if (thisBits > anotherBits) return 1;
return 0;
}
``````

"bits" would typically be from 1 to 4 or so, depending on how precise you wanted the cutoff.

A refinement would be to add 1 to the position of the first bit to be zeroed before masking (for "rounding"), but then you have to worry about ripple all the way up past the most significant bit.

• Thanks, this is the approach I was looking for. However, this doesn't quite work "across 0" -- positive +ε and negative -ε aren't seen as being anywhere close. Here's an alternate version that passes the tests I've made (but I wouldn't be shocked if it has some glitch somewhere, too): `return d1==d2 /* hotpath; also handles infinities and NaNs. */ || (Math.abs(d1-d2) < Math.max( Math.ulp(d1), Math.ulp(d2) ) * (0b1L << bits));` Sep 18, 2019 at 10:07

``````double epsilon = 0.0000001;