# C# loss of precision when dividing doubles

I know this has been discussed time and time again, but I can't seem to get even the most simple example of a one-step division of doubles to result in the expected, unrounded outcome in C# - so I'm wondering if perhaps there's i.e. some compiler flag or something else strange I'm not thinking of. Consider this example:

``````double v1 = 0.7;
double v2 = 0.025;
double result = v1 / v2;
``````

When I break after the last line and examine it in the VS debugger, the value of "result" is 27.999999999999996. I'm aware that I can resolve it by changing to "decimal," but that's not possible in the case of the surrounding program. Is it not strange that two low-precision doubles like this can't divide to the correct value of 28? Is the only solution really to Math.Round the result?

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See any of the items in the "Related" sidebar, like this one: stackoverflow.com/q/4252917/121309 – Hans Kesting May 4 '12 at 7:21
– Habib May 4 '12 at 7:24

Is it not strange that two low-precision doubles like this can't divide to the correct value of 28?

No, not really. Neither 0.7 nor 0.025 can be exactly represented in the `double` type. The exact values involved are:

``````0.6999999999999999555910790149937383830547332763671875
0.025000000000000001387778780781445675529539585113525390625
``````

Now are you surprised that the division doesn't give exactly 28? Garbage in, garbage out...

As you say, the right result to represent decimal numbers exactly is to use `decimal`. If the rest of your program is using the wrong type, that just means you need to work out which is higher: the cost of getting the wrong answer, or the cost of changing the whole program.

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OK where did you get the exact values from? I tried but couldn't work it out! – yamen May 4 '12 at 7:26
how did you know the "exact" values ? – CyprUS May 4 '12 at 7:26
@yamen @CyprUS: I have a little class called `DoubleConverter` which looks at the bit pattern to construct the decimal representation. See csharpindepth.com/Articles/General/FloatingPoint.aspx – Jon Skeet May 4 '12 at 7:29
@JonSkeet can you approximate how much of your SO reputation has been garnered specifically answering variations of this one question? Answer in double precision only please. – yamen May 4 '12 at 7:30
+1 for the article link – Habib May 4 '12 at 7:30

It has nothing to do with how 'simple' or 'small' the `double` numbers are. Strictly speaking, neither `0.7` or `0.025` may be stored as exactly those numbers in computer memory, so performing calculations on them may provide interesting results if you're after heavy precision.

So yes, use `decimal` or round.

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To explain this by analogy:

Imagine that you are working in base 3. In base 3, 0.1 is (in decimal) 1/3, or 0.333333333'.

So you can EXACTLY represent 1/3 (decimal) in base 3, but you get rounding errors when trying to express it in decimal.

Well, you can get exactly the same thing with some decimal numbers: They can be exactly expressed in decimal, but they CAN'T be exactly expressed in binary; hence, you get rounding errors with them.

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Excellent explanation - thanks :) – Metal450 May 4 '12 at 9:15

Precision is always a problem, in case you are dealing with `float` or `double`.

Its a known issue in Computer Science and every programming language is affected by it. To minimize these sort of errors, which are mostly related to rounding, a complete field of Numerical Analysis is dedicated to it.

For instance, let take the following code.

What would you expect?

You will expect the answer to be `1`, but this is not the case, you will get `0.9999907`.

``````        float v = .001f;
float sum = 0;
for (int i = 0; i < 1000; i++ )
{
sum += v;
}
``````
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Short answer to your first question: No, it's not strange. Floating-point numbers are discrete approximations of the real numbers, which means that rounding errors will propagate and scale when you do arithmetic operations.

Theres' a whole field of mathematics called numerical analyis that basically deal with how to minimize the errors when working with such approximations.

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It's the usual floating point imprecision. Not every number can be represented as a double, and those minor representation inaccuracies add up. It's also a reason why you should not compare doubles to exact numbers. I just tested it, and `result.ToString()` showed `28` (maybe some kind of rounding happens in `double.ToString()`?). `result == 28` returned `false` though. And `(int)result` returned `27`. So you'll just need to expect imprecisions like that.

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Yeah, I did try ToString() as well - but clearly it must be doing some internal rounding, as you also discovered... – Metal450 May 4 '12 at 7:42