# c# floating point for loop, unexpected results

Can anyone explain to me why this program:

``````for(float i = -1; i < 1; i += .1F)
Console.WriteLine(i);
``````

Outputs this:

-1

-0.9

-0.8

-0.6999999

-0.5999999

-0.4999999

-0.3999999

-0.2999999

-0.1999999

-0.99999993

7.450581E-08

0.1000001

0.2000001

0.3000001

0.4000001

0.5000001

0.6000001

0.7000001

0.8000001

0.9000002

Where is the rounding error coming from??

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Sure, you should simply read docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html. – Yuriy Faktorovich Jul 6 '12 at 15:18
possible duplicate of Why is floating point arithmetic in C# imprecise? – Juhana Jul 7 '12 at 14:56

I'm sure this question must have been asked in some form before but I can't find it anywhere quickly. :)

The answer comes down to the way that floating point numbers are represented. You can go into the technical detail via wikipedia but it is simply put that a decimal number doesn't necessarily have an exact floating point representation...

The way floating point numbers (base 2 floating point anyway like doubles and floats) work [0]is by adding up powers of 1/2 to get to what you want. So 0.5 is just 1/2. 0.75 is 1/2+1/4 and so on.

the problem comes that you can never represent 0.1 in this binary system without an unending stream of increasingly smaller powers of 2 so the best a computer can do is store a number that is very close to but not quite 0.1.

Usually you don't notice these differences but they are there and sometimes you can make them manifest themselves. There are a lot of ways to deal with these issues and which one you use is very much dependant on what you are actually doing with it.

[0] in the slightly handwavey close enough kind of way

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Floating point numbers are not correct, they are always approximated because they must be rounded!!
They are precise in binary representation.
Every CPU or pc could lead to different results.

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That's not true. As I've been corrected, FP are precise, but they are precise in binary. It's the conversion to decimal that is approximated, because it must often be rounded. – Chris Shain Jul 6 '12 at 15:18
A finite binary fraction can always be represented as a finite decimal number. The reason being that (1/2)^n is never a recurring number therefore a sum of them is not recurring. So you can get a precise decimal representation, it just depends how wide your numbers are. Its only the conversion from decimal to binary that cannot alwasy be done in a precise way (though it is worth noting that not all decimals lose precision in becoming binary floating point numbers). – Chris Jul 6 '12 at 15:29

The big issue is that `0.1` cannot be represented in binary, just like `1 / 3` or `1 / 7` cannot be represented in decimal. So since the computer has to cut off at some point, it will accumulate a rounding error.

Try doing `0.1 + 0.7 == 0.8` in pretty much any programming language, you'll get false as a result.

In C# to get around this, use the `decimal` type to get better precision.

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This will explain everything about floating-point: http://docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html

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The rounding error comes from the fact that Float is not a precise data type (when converted to decimal), it is an approxomation, note in the C# Reference Float is specified as having 7 digits of decimal precision.

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That's not true, and it doesn't answer the question. – Yuriy Faktorovich Jul 6 '12 at 15:20
The question is answered reasonably well - the answer is, the rounding error comes from the lack of decimal precision in the Float. Microsoft C# Reference is very clear that the precision is only 7 digits - the values the OP list are 7 digits long... – EtherDragon Jul 6 '12 at 15:23
converting a float to a decimal is not the problem. Its the converting the decimal to float that is the problem. The size (and precision) of a float means that it can always be represented as a decimal accurately. – Chris Jul 6 '12 at 15:33

It is fundamental to the any floating point variable. The reasons are complex but there is plenty of information if you google it.