# How should I compare these doubles to get the desired result?

I have a simple example application here where I am multiplying and adding `double` variables and then comparing them against an expected result. In both cases the result is equal to the expected result yet when I do the comparison it fails.

``````static void Main(string[] args)
{
double a = 98.1;
double b = 107.7;
double c = 92.5;
double d = 96.5;

double expectedResult = 88.5;
double result1 = (1*2*a) + (-1*1*b);
double result2 = (1*2*c) + (-1*1*d);

Console.WriteLine(String.Format("2x{0} - {1} = {2}\nEqual to 88.5? {3}\n", a, b, result1, expectedResult == result1));
Console.WriteLine(String.Format("2x{0} - {1} = {2}\nEqual to 88.5? {3}\n", c, d, result2, expectedResult == result2));

}
``````

And here is the output:

``````2x98.1 - 107.7 = 88.5
Equal to 88.5? False

2x92.5 - 96.5 = 88.5
Equal to 88.5? True
``````

I need to be able to capture that it is in fact `True` in BOTH cases. How would I do it?

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Floating point numbers often don't contain the exact value that mathematics tells us, because of how they store numbers.

To still have a reliable comparison, you need to allow some difference:

``````private const double DoubleEpsilon = 2.22044604925031E-16;

/// <summary>Determines whether <paramref name="value1"/> is very close to <paramref name="value2"/>.</summary>
/// <param name="value1">The value1.</param>
/// <param name="value2">The value2.</param>
/// <returns><c>true</c> if <paramref name="value1"/> is very close to value2; otherwise, <c>false</c>.</returns>
public static bool IsVeryCloseTo(this double value1, double value2)
{
if (value1 == value2)
return true;

var tolerance = (Math.Abs(value1) + Math.Abs(value2)) * DoubleEpsilon;
var difference = value1 - value2;

return -tolerance < difference && tolerance > difference;
}
``````

Please also make sure to read this blog post.

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+1 But can I ask you where did you take that formula from? Silverlight Control Toolkit? Or is there some real math behind the voodoo? Because... stackoverflow.com/questions/2411392/… –  xanatos Aug 6 '13 at 13:22
@xanatos: Good question. It is from one of my helper libraries I haven't changed in years. I am pretty sure I got it from the net somewhere. I am trying to track down the source. –  Daniel Hilgarth Aug 6 '13 at 13:31
@xanatos: About the constant `DoubleEpsilon`, see en.wikipedia.org/wiki/Machine_epsilon. Still not sure about the rest. –  Daniel Hilgarth Aug 6 '13 at 13:44
Your constant is `Math.Pow(2, -52)` rounded to 15 significant decimal figures. EDIT: To get the exact number, two to the minus 52nd, insert an extra digit `3` just before the `E` in your `const` declaration. –  Jeppe Stig Nielsen Aug 6 '13 at 13:45
@JeppeStigNielsen: This is a really interesting topic. Unfortunately, I was unable to find the original source and I can't find any other source that justifies the `+ 10`. Because of this, I adjusted the code in the answer. –  Daniel Hilgarth Aug 6 '13 at 15:34

If you need more precision (for money and such) then use `decimal`.

``````var a = 98.1M;
var b = 107.7M;
var c = 92.5M;
var d = 96.5M;

var expectedResult = 88.5M;
var result1 = (2 * a) + (-1 * b);
var result2 = (2 * c) + (-1 * d);

Console.WriteLine(String.Format("2x{0} - {1} = {2}\nEqual to 88.5? {3}\n", a, b, result1, expectedResult == result1));
Console.WriteLine(String.Format("2x{0} - {1} = {2}\nEqual to 88.5? {3}\n", c, d, result2, expectedResult == result2));
``````

Output:

``````2x98.1 - 107.7 = 88.5
Equal to 88.5? True

2x92.5 - 96.5 = 88.5
Equal to 88.5? True
``````
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`decimal` is NOT fixed point. It still is floating point. But the internal representation is not binary but decimal, that's why it works well with "normal" numbers like 0.1. Simple proof: `Assert.Equal(1/3m * 2, 2/3m); // will fail` –  Daniel Hilgarth Aug 6 '13 at 13:32
@DanielHilgarth I can agree that `decimal` is not fixed-point. But the proof is not valid, because for a fixed-point type that assert would fail as well. For example with three fixed decimals after the point, one value would be `0.666` while the other would be `0.667`. (I was assuming a fixed-point arithmetic where division rounded to nearest representable value, not just truncated.) –  Jeppe Stig Nielsen Aug 6 '13 at 14:17

It's a problem with how floating point numbers are represented in memory.

You should read this to get a better understanding of whats going on: What Every Computer Scientist Should Know About Floating-Point Arithmetic

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Simply change your rounding to level 2 , this will give TRUE

``````double result1 =Math.Round ( (1 * 2 * a) + (-1 * 1 * b),2);
``````
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using Math.Round() will round result1 to the correct decimal

``````result1 = Math.Round(result1, 1);
``````
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using the debugger,

``````result1=88.499999999999986;
expectedResult = 88.5
``````

So when using the double ,these are not equal.

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There is a whole school of thought that is against using `Double.Epsilon` and similar numbers...

I think they use this: (taken from http://stackoverflow.com/a/2411661/613130 but modified with the checks for `IsNaN` and `IsInfinity` suggested here by nobugz

``````public static bool AboutEqual(double x, double y)
{
if (double.IsNaN(x)) return double.IsNaN(y);
if (double.IsInfinity(x)) return double.IsInfinity(y) && Math.Sign(x) == Math.Sign(y);

double epsilon = Math.Max(Math.Abs(x), Math.Abs(y)) * 1E-15;
return Math.Abs(x - y) <= epsilon;
}
``````

The `1E-15` "magic number" is based on the fact that `double`s have a little more than 15 digits of precision.

I'll add that for your numbers it returns true :-)

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