# What's the best way to compare Double and Int?

The following code in C# doesn't work:

``````int iValue = 0;
double dValue = 0.0;

bool isEqual = iValue.Equals(dValue);
``````

So, the question: what's the best way to compare Double and Int?

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See the this related question: <stackoverflow.com/questions/1530069/…; – Konamiman Oct 30 '09 at 14:51

You really can't compare floating point and integral values in a naive way; particularly, since there's the classic floating point representation challenges. What you can do is subtract one from the other and see if the difference between them is less than some precision you care about, like so:

``````int iValue = 0;
double dValue = 0.0;

var diff = Math.Abs(dvalue - iValue);
if( diff < 0.0000001 ) // need some min threshold to compare floating points
return true; // items equal
``````

You really have to define for yourself what `equality` means to you. For example, you may want a floating point value to round towards the nearest integer, so that 3.999999981 will be "equal" to 4. Or you may want to truncate the value, so it would effectively be 3. It all depends on what you're trying to achieve.

EDIT: Note that i chose 0.0000001 as an example threshold value ... you need to decide for yourself what precision is sufficient for comparison. Just realize you need to be within the normal representational bounds of `double` which I believe is defined as `Double.Espilon`.

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This is a nice solution to the problem I mentioned. For greater accuracy (only when its necessary), use only integers, as I suggested in my answer. – San Jacinto Oct 30 '09 at 14:30
Would you be better comparing with the system defined constant epsilon (see here msdn.microsoft.com/en-us/library/system.double.epsilon.aspx) instead of a hard-coded value like 0.0000001? NB I've never coded C# (just C++) but I assume the same principle applies – pxb Oct 30 '09 at 14:35
I mention that in the edit to my answer. Epsilon may or may not be a good choice depending on what precision the OP cares about in his code. – LBushkin Oct 30 '09 at 14:37
Double.Epsilon is only useful if you are subtracting values between 0 and 1 as it's the "smallest positive Double value greater than zero". Since `double` values aren't evenly spaced and their distance increases with their magnitude you won't ever get something around Double.Epsilon if you subtract two values. – Joey Oct 30 '09 at 14:37
@Johannes: That's a good point. For very large positive/negative values the code would need to be more "relaxed" in how it evaluates equality. – LBushkin Oct 30 '09 at 14:39

It's an exceedingly bad idea to compare integers and floating-point numbers for equality in any language. It works for very simple cases, but after you do any math at all, the likliehood of the program doing what you want it to decreases dramatically.

It has to do with the way floating-point numbers are stored on a binary, digital system.

If you are very sure you want to use this, create a class to make you own number with fractions. use one int to maintain the whole number, and another int to maintain the fraction.

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``````double val1 = 0;
double val2 = 0.0;
if((val1 - Double.Epsilon) < 0)
{
}

OR

if((val2 - Double.Epsilon) < 0)
{
}
``````

where Double.Epsilon is lowest possible value for Double.

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This really depends on what you consider "equal". If you want your comparison to return true if and only if the double precisely matches the integer value (i.e. has no fractional component), you should cast your int to a double to do the comparison:

``````bool isEqual = (double)iValue == dValue;
``````

If something like 1.1 would be considered equal to 1, you can either cast the double to an int (if you want to ignore the fractional component altogether) or round the double if you want say 1.9 to equal 2.

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Careful with rounding, though. Many people seem surprised when 2.5 rounds to 2. – Joey Oct 30 '09 at 14:31
@Joey It's pretty trivial to write your own rounding code to have the behavior you want if the three built-in ones do not meet your needs. – Casey Jan 12 '15 at 18:57

Nowadays, just about the only time one should be comparing values of types `double` and either `integer` or `long` for strict equality is when, for some reason, one is stuck storing or passing integral quantities as floating-point values and later needs to convert them back. Such conversion may in most cases be most easily accomplished by casting the integral type to `double`, and then comparing the result of that cast. Note that conversion from `long` to `double` may be imprecise if the number is outside the range ±252. Nonetheless, in the days before 64-bit `long` became available, `double` was a handy storage type for integer quantities which were too big for a 32-bit `int` but small enough to be handled by `double`.

Note that converting a `long` to `double` and then doing the comparison will yield an "equal" result if the nominal value of the `double` doesn't precisely match the `long` value, but represents the closest possible `double` to that value. This behavior makes sense if one recognizes that floating-point types don't actually represent a single precise value, but rather a range of values.

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