# My floating point number has extra digits when I print it

I define a floating point number as `float transparency = 0.85f;` And in the next line, I pass it to a function -- `fcn_name(transparency)` -- but it turns out that the variable `transparency` has value `0.850000002`, and when I print it with the default setting, it is `0.850000002`. For the value `0.65f`, it is `0.649999998`.

How can I avoid this issue? I know floating point is just an approximation, but if I define a float with just a few decimals, how can I make sure it is not changed?

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use `double` instead? –  William Morris Oct 23 '12 at 21:34
You can't. You get the closest representable floating point number to the constant you put in your source. You can mitigate the effect by using `double`s instead of `float`s. –  Daniel Fischer Oct 23 '12 at 21:35
Using a type with higher precision (if you need it!). You may even consider to do not use [0..1] range but [0..100] range so you will have a better approximation for numbers you're managing. You may divide by 100 at the end of all your calculations. –  Adriano Oct 23 '12 at 21:35
–  Adam Rosenfield Oct 23 '12 at 21:46
These values cannot be represented precisely in binary floating-point format regardless of how large your floating-point type is. Switching to `double` will reduce the error, but the error will still be there. You can concoct a 64-kilobyte floating-point type, and the error will still be there, simply because the representation of `0.65` in floating-point binary has infinite length. –  AndreyT Oct 23 '12 at 22:17

Floating-point values represented in binary format do not have any specific decimal precision. Just because you read in some spec that the number can represent some fixed amount of decimal digits, it doesn't really mean much. It is just a rough conversion of the physical (and meaningful) binary precision to its much less meaningful decimal approximation.

One property of binary floating-point format is that it can only represent precisely (within the limits of its mantissa width) the numbers that can be expressed as finite sums of powers of 2 (including negative powers of 2). Numbers like `0.5`, `0.25`, `0.75` (decimal) will be represented precisely in binary floating-point format, since these numbers are either powers of 2 (`2^-1`, `2^-2`) or sums thereof.

Meanwhile, such number as decimal `0.1` cannot be expressed by a finite sum of powers of 2. The representation of decimal `0.1` in floating-point binary has infinite length. This immediately means that `0.1` cannot be ever represented precisely in finite binary floating-point format. Note that `0.1` has only one decimal digit. However, this number is still not representable. This illustrates the fact that expressing floating-point precision in terms of decimal digits is not very useful.

Values like `0.85` and `0.65` from your example are also non-representable, which is why you see these values distorted after conversion to a finite binary floating-point format. Actually, you have to get used to the fact that most fractional decimal numbers you will encounter in everyday life will not be representable precisely in binary floating-point types, regardless of how large these floating-point types are.

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The only way I can think of solving this problem is to pass characteristic and mantissa to the function separately and let IT work on setting the values appropriately.

Also if you want more precision,

http://www.drdobbs.com/cpp/fixed-point-arithmetic-types-for-c/184401992 is the article I know. Though this works for C++ only. (Searching for an equivalent C implementation).

I tried this on VS2010,

``````#include <stdio.h>
void printfloat(float f)
{
printf("%f",f);
}

int main(int argc, char *argv[])
{
float f = 0.24f;
printfloat(f);
return 0;
}

OUTPUT: 0.240000
``````
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This is not a floating point versus fixed point issue. It is a radix issue. For example, if you had a binary fixed-point format with 8 integer bits and 8 fraction bits, it would not be able to represent .85 exactly. –  Eric Postpischil Oct 24 '12 at 13:05
@EricPostpischil which is why I asked him to send the characteristic and mantissa separately. for example: characteristic here would be 0 and mantissa would be 75 and let the program handle this if he wants accuracy. –  Aniket Oct 24 '12 at 13:07
Asking him to pass the characteristic and mantissa separately does not correct the problem that the first sentence in the answer is false. I suggest you edit the answer to remove the false statement “Alas, that’s the problem with floating point numbers, as opposed to fixed point numbers.” (Additionally, I do not see reason to use the code style for the phrases “floating point” and “fixed point”. They are not code. For emphasis, you can use bold or italic.) –  Eric Postpischil Oct 24 '12 at 13:09