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Here is the output for the below program.

value is : 2.7755575615628914E-17 with zero : 1
isEqual with zero : true

My question is, what should be an epsilon value? Is there any robust way to obtain the value, instead of picking a number out from the sky.

package sandbox;

 * @author yccheok
public class Main {

     * @param args the command line arguments
    public static void main(String[] args) {
        double zero = 1.0/5.0 + 1.0/5.0 - 1.0/10.0 - 1.0/10.0 - 1.0/10.0 - 1.0/10.0;
        System.out.println("value is : " + zero);
        System.out.println(" with zero : " +, 0.0));
        System.out.println("isEqual with zero : " + isEqual(zero, 0.0));

    public static boolean isEqual(double d0, double d1) {
        final double epsilon = 0.0000001;
        return d0 == d1 ? true : Math.abs(d0 - d1) < epsilon;
share|improve this question
@Cheok, your question is not clear, what is you expecting from epsilon? – mhshams Sep 16 '10 at 15:48
up vote 6 down vote accepted

The answer to your second question is no. The magnitude of finite-machine precision error can be arbitrarily large:

public static void main(String[] args) {
    double z = 0.0;
    double x = 0.23;
    double y = 1.0 / x;
    int N = 50000;
    for (int i = 0; i < N; i++) {
        z += x * y - 1.0;
    System.out.println("z should be zero, is " + z);

This gives ~5.55E-12, but if you increase N you can get just about any level of error you desire.

There is a vast amount of past and current research on how to write numerically stable algorithms. It is a hard problem.

share|improve this answer
Is 0.23 a magic number? – Cheok Yan Cheng Sep 16 '10 at 16:20
No, just an example of a number where x * (1.0/x) is not quite equal to 1. – mob Sep 16 '10 at 16:59
Isn't we should call 0.23 as magic number? As I can use 0.24 as well, right? I thought if we can pick an arbitrary number, we usually call that as magic number. – Cheok Yan Cheng Sep 18 '10 at 6:10

I like (pseudo code, I don't do java)

bool fuzzyEquals(double a, double b)
    return abs(a - b) < eps * max(abs(a), abs(b));

with epsilon being a few times the machine epsilon. Take 10^-12 if you don't know what to use.

This is quite problem dependant however. If the computations giving a and b are prone to roundoff error, or involve many operations, or are themselves within some (known) accuracy, you want to take a bigger epsilon.

Ths point is to use relative precision, not absolute.

share|improve this answer
Can I return abs(a - b) < eps * abs(b); – Cheok Yan Cheng Sep 16 '10 at 16:31
@Yan: yes, of course. – Alexandre C. Sep 16 '10 at 16:34
I think we should compare across abs(a) and abs(b), and take the minimum value to multiply with eps. See essentiallyEqual :… – Cheok Yan Cheng Sep 18 '10 at 6:08
@Yan: It depends on what you want. – Alexandre C. Sep 18 '10 at 15:28

There is no one right value. You need to compute it relative to the magnitude of the numbers involved. What you're basically dealing with is a number of significant digits, not a specific magnitude. If, for example, your numbers are both in the range of 1e-100, and your calculations should maintain roughly 8 significant digits, then your epsilon should be around 1e-108. If you did the same calculations on numbers in the range of 1e+200, then your epsilon would be around 1e+192 (i.e., epsilon ~= magnitude - significant digits).

I'd also note that isEqual is a poor name -- you want something like isNearlyEQual. For one reason, people quite reasonably expect "equal" to be transitive. At the very least, you need to convey the idea that the result is no longer transitive -- i.e., with your definition of isEqual, isEqual(a, c) can be false, even though isEqual(a, b) and isEqual(b, c) are both true.

Edit: (responding to comments): I said "If [...] your calculations should maintain roughly 8 significant digits, then your epsilon should be...". Basically, it comes to looking at what calculations you're doing, and how much precision you're likely to lose in the process, to provide a reasonable guess at how big a difference has to be before it's significant. Without knowing the calculation you're doing, I can't guess that.

As far as the magnitude of epsilon goes: no, it does not make sense for it to always be less than or equal to 1. A floating point number can only maintain limited precision. In the case of an IEEE double precision floating point, the maximum precision that can be represented is about 20 decimal digits. That means if you start with 1e+200, the absolute smallest difference from that number that the machine can represent at all is about 1e+180 (and a double can represent numbers up to ~1e+308, at which point the smallest difference that can be represented is ~1e+288).

share|improve this answer
Why my number is 1e-100, then epsilon should be around 1e-108. Why 8 significant digits? – Cheok Yan Cheng Sep 16 '10 at 16:18
@Coffin, why epsilon is 1e+192 ? Isn't epsilon should at least lesser than 1, and greater than 0? – Cheok Yan Cheng Sep 16 '10 at 16:19

In isEqual, have something like:

epsilon = Math.max(Math.ulp(d0), Math.ulp(d1))

An ulp of a double value is the positive distance between this floating-point value and the double value next larger in magnitude. [1]


share|improve this answer

You should definitely read first.

It discusses various ways of comparing floating point numbers: absolute tolerance, relative tolerance, ulp distance. It makes a fairly good argument that ulp checking is the way to go. The case hinges around the argument that if you want to check if two floating point numbers are the same, you have to take into account the distance between representable floats. In other words, you should check if the two numbers are within e floats of each other.

The algorithms are given in C, but can be translated to java using java.lang.Double#doubleToLongBits and java.lang.Float#floatToIntBits to implement the casting from floating to integer types. Also, with java > 1.5 there are methods ulp(double) ulp(float) and for java > 1.6 nextUp(double) nextUp(float) nextAfter(double, double) nextAfter(float, float) that are useful for quantifying the difference between two floating point numbers.

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