# Is it safe to check floating point values for equality to 0?

I know you can't rely on equality between double or decimal type values normally, but I'm wondering if 0 is a special case.

While I can understand imprecisions between 0.00000000000001 and 0.00000000000002, 0 itself seems pretty hard to mess up since it's just nothing. If you're imprecise on nothing, it's not nothing anymore.

``````double x = 0.0;
return (x == 0.0) ? true : false;
``````

Will that always return true?

• The ternary operator is redundant in that code :) – Joel Coehoorn Jan 27 '09 at 21:48
• LOL you're right. Go me – Gene Roberts Jan 27 '09 at 22:13
• I would not do it because you don,t know how x got set to zero. If you still want to do it you probably want to round or floor x to get rid of the 1e-12 or such that might be tagged on the end. – Rex Logan Jan 27 '09 at 23:16

It is safe to expect that the comparison will return `true` if and only if the double variable has a value of exactly `0.0` (which in your original code snippet is, of course, the case). This is consistent with the semantics of the `==` operator. `a == b` means "`a` is equal to `b`".

It is not safe (because it is not correct) to expect that the result of some calculation will be zero in double (or more generally, floating point) arithmetics whenever the result of the same calculation in pure Mathematics is zero. This is because when calculations come into the ground, floating point precision error appears - a concept which does not exist in Real number arithmetics in Mathematics.

If you need to do a lot of "equality" comparisons it might be a good idea to write a little helper function or extension method in .NET 3.5 for comparing:

``````public static bool AlmostEquals(this double double1, double double2, double precision)
{
return (Math.Abs(double1 - double2) <= precision);
}
``````

This could be used the following way:

``````double d1 = 10.0 * .1;
bool equals = d1.AlmostEquals(0.0, 0.0000001);
``````
• You might be having a subtractive cancellation error by comparing double1 and double2, in case these numbers have values very close to each other. I would remove the Math.Abs and check each branch individually d1 >= d2 - e and d1 <= d2 + e – Theodore Zographos Jun 14 '12 at 23:15
• "Because Epsilon defines the minimum expression of a positive value whose range is near zero, the margin of difference between two similar values must be greater than Epsilon. Typically, it is many times greater than Epsilon. Because of this, we recommend that you do not use Epsilon when comparing Double values for equality." - msdn.microsoft.com/en-gb/library/ya2zha7s(v=vs.110).aspx – Rafael Costa Mar 14 '18 at 15:12

``````bool b = ( 10.0 * .1 - 1.0 == 0.0 );
``````

Remember that .1 is a repeating decimal in binary and can't be represented exactly. Then compare that to this code:

``````double d1 = 10.0 * .1; // make sure the compiler hasn't optimized the .1 issue away
bool b = ( d1 - 1.0 == 0.0 );
``````

I'll leave you to run a test to see the actual results: you're more likely to remember it that way.

• Actually, this returns true for some reason (in LINQPad, at least). – Alexey Romanov Jun 25 '09 at 13:19
• What's the ".1 issue" you talk about? – Teejay Mar 5 at 10:04

From the MSDN entry for Double.Equals:

Precision in Comparisons

The Equals method should be used with caution, because two apparently equivalent values can be unequal due to the differing precision of the two values. The following example reports that the Double value .3333 and the Double returned by dividing 1 by 3 are unequal.

...

Rather than comparing for equality, one recommended technique involves defining an acceptable margin of difference between two values (such as .01% of one of the values). If the absolute value of the difference between the two values is less than or equal to that margin, the difference is likely to be due to differences in precision and, therefore, the values are likely to be equal. The following example uses this technique to compare .33333 and 1/3, the two Double values that the previous code example found to be unequal.

Also, see Double.Epsilon.

• It's also possible for not-quite-equivalent values to compare as equal. One would expect that if `x.Equals(y)`, then `(1/x).Equals(1/y)`, but that's not the case if `x` is `0` and `y` is `1/Double.NegativeInfinity`. Those values declare as equal, even though their reciprocals do not. – supercat Sep 26 '12 at 20:44
• @supercat: They are equivalent. And they don't have reciprocals. You could run your test again with `x = 0` and `y = 0`, and you'd still find that `1/x != 1/y`. – Ben Voigt Aug 5 '16 at 14:48
• @BenVoigt: With `x` and `y` as type `double`? How do you compare the results to make them report unequal? Note that 1/0.0 is not NaN. – supercat Aug 5 '16 at 15:15
• @supercat: Ok, it's one of the things that IEEE-754 gets wrong. (First, that `1.0/0.0` fails to be NaN as it should be, as the limit is not unique. Secondly, that infinities compare equal to each other, without paying any attention to degrees of infinity) – Ben Voigt Aug 5 '16 at 15:35
• @BenVoigt: If the zero was a result of multiplying two very small numbers, then dividing 1.0 into that should yield a value which compares greater than any number of the small numbers had the same sign, and less than any number if one of the small numbers had opposite signs. IMHO, IEEE-754 would be better if it had an unsigned zero, but positive and negative infinitesimals. – supercat Aug 5 '16 at 16:21

The problem comes when you are comparing different types of floating point value implementation e.g. comparing float with double. But with same type, it shouldn't be a problem.

``````float f = 0.1F;
bool b1 = (f == 0.1); //returns false
bool b2 = (f == 0.1F); //returns true
``````

The problem is, programmer sometimes forgets that implicit type cast (double to float) is happening for the comparison and the it results into a bug.

If the number was directly assigned to the float or double then it is safe to test against zero or any whole number that can be represented in 53 bits for a double or 24 bits for a float.

Or to put it another way you can always assign and integer value to a double and then compare the double back to the same integer and be guaranteed it will be equal.

You can also start out by assigning a whole number and have simple comparisons continue to work by sticking to adding, subtracting or multiplying by whole numbers (assuming the result is less than 24 bits for a float abd 53 bits for a double). So you can treat floats and doubles as integers under certain controlled conditions.

• I agree with your statement in general (and upvoted it) but I believe it really depends if IEEE 754 floating point implementation is used or not. And I believe every "modern" computer uses IEEE 754, at least for storage of floats (there are weird rounding rules that differ). – Mark Lakata Mar 20 '17 at 18:18

No, it is not OK. So-called denormalized values (subnormal), when compared equal to 0.0, would compare as false (non-zero), but when used in an equation would be normalized (become 0.0). Thus, using this as a mechanism to avoid a divide-by-zero is not safe. Instead, add 1.0 and compare to 1.0. This will ensure that all subnormals are treated as zero.

• Subnormals are also known as denormals – Manuel Sep 30 '09 at 19:14
• Subnormals do not become equal to zero when used, though they may or may not produce the same result depending on the exact operation. – wnoise Mar 18 '11 at 11:14

Try this, and you will find that == is not reliable for double/float.
```double d = 0.1 + 0.2; bool b = d == 0.3;```

Here is the answer from Quora.

Actually, I think it is better to use the following codes to compare a double value against to 0.0:

``````double x = 0.0;
return (Math.Abs(x) < double.Epsilon) ? true : false;
``````

Same for float:

``````float x = 0.0f;
return (Math.Abs(x) < float.Epsilon) ? true : false;
``````
• No. From the docs from double.Epsilon: "If you create a custom algorithm that determines whether two floating-point numbers can be considered equal, you must use a value that is greater than the Epsilon constant to establish the acceptable absolute margin of difference for the two values to be considered equal. (Typically, that margin of difference is many times greater than Epsilon.)" – Alastair Maw Jun 6 '12 at 8:49
• @AlastairMaw this applies to checking two doubles of any size for equality. For checking equality to zero, double.Epsilon is fine. – jwg Jan 3 '13 at 13:30
• No, it's not. It's very likely that the value you have arrived at via some calculation is many times epsilon away from zero, but should still be considered as zero. You don't magically achieve a whole bunch of extra precision in your intermediate result from somewhere, just because it happens to be close to zero. – Alastair Maw Jan 3 '13 at 19:01
• For example: (1.0/5.0 + 1.0/5.0 - 1.0/10.0 - 1.0/10.0 - 1.0/10.0 - 1.0/10.0) < double.Epsilon == false (and considerably so in magnitude terms: 2.78E-17 vs 4.94E-324) – Alastair Maw Jan 3 '13 at 19:07
• so, what is the precision recommended, if double.Epsilon is not ok? Would 10 times of epsilon ok? 100 times? – liang May 14 '13 at 16:56