# Java floats and doubles, how to avoid that 0.0 + 0.1 + … + 0.1 == 0.9000001?

I have a very annoying problem with long sums of floats or doubles in Java. Basically the idea is that if I execute:

``````for ( float value = 0.0f; value < 1.0f; value += 0.1f )
System.out.println( value );
``````

What I get is:

``````0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.70000005
0.8000001
0.9000001
``````

I understand that there is an accumulation of the floating precision error, however, how to get rid of this? I tried using doubles to half the error, but the result is still the same.

Any ideas?

Thank you
Tunnuz

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There is a no exact representation of 0.1 as a `float` or `double`. Because of this representation error the results are slightly different from what you expected.

A couple of approaches you can use:

• When using the `double` type, only display as many digits as you need. When checking for equality allow for a small tolerance either way.
• Alternatively use a type that allows you to store the numbers you are trying to represent exactly, for example `BigDecimal` can represent 0.1 exactly.

Example code for `BigDecimal`:

``````BigDecimal step = new BigDecimal("0.1");
for (BigDecimal value = BigDecimal.ZERO;
value.compareTo(BigDecimal.ONE) < 0;
System.out.println(value);
}
``````

See it online: ideone

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You can avoid this specific problem using classes like `BigDecimal`. `float` and `double`, being IEEE 754 floating-point, are not designed to be perfectly accurate, they're designed to be fast. But note Jon's point below: `BigDecimal` can't represent "one third" accurately, any more than `double` can represent "one tenth" accurately. But for (say) financial calculations, `BigDecimal` and classes like it tend to be the way to go, because they can represent numbers in the way that we humans tend to think about them.

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It's not a matter of "precise" and "imprecise" - it's a matter of what can be represented in each type. BigDecimal is no more capable of representing "a third" exactly than double is capable of representing "a tenth" exactly. –  Jon Skeet Mar 10 '11 at 8:39
@Jon: Actually, as you commented I was editing, I'd said "precise" where I meant "accurate" (because everyone does, but I try to avoid doing it). Fascinating point about "a third", though. Very good point indeed. –  T.J. Crowder Mar 10 '11 at 8:41
I'd say that "accurate" isn't necessarily a good word either. There are two issues here - one is base representation, and the other is a fixed or varying size (where BigDecimal can expand as it sees fit depending on the MathContext, whereas something like System.Decimal in .NET is always 128 bits). But it's definitely a complicated thing to describe concisely :) "Accurate" may or may not be appropriate for BigDecimal based on the MathContext used - I believe that with an "unlimited", operations will throw an exception if the result can't be represented exactly. –  Jon Skeet Mar 10 '11 at 8:44
@Jon: Yeah, as you said in an earlier version of that comment, it's complicated to say concisely. :-) Thanks again for the one-third thing. I had genuinely never considered infinite decimal series in this context (which is fairly shocking). –  T.J. Crowder Mar 10 '11 at 8:46
I've updated my comment, because it's even more complicated than I'd remembered, due to BigDecimal's MathContext :) –  Jon Skeet Mar 10 '11 at 8:47

Don't use float/double in an iterator as this maximises your rounding error. If you just use the following

``````for (int i = 0; i < 10; i++)
System.out.println(i / 10.0);
``````

it prints

``````0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
``````

I know BigDecimal is a popular choice, but I prefer double not because its much faster but its usually much shorter/cleaner to understand.

If you count the number of symbols as a measure of code complexity

• using double => 11 symbols
• use BigDecimal (from @Mark Byers example) => 21 symbols

BTW: don't use float unless there is a really good reason to not use double.

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It's not just an accumulated error (and has absolutely nothing to do with Java). `1.0f`, once translated to actual code, does not have the value 0.1 - you already get a rounding error.

What can I do to avoid this problem?

That depends on what kind of calculations you’re doing.

• If you really need your results to add up exactly, especially when you work with money: use a special decimal datatype.
• If you just don’t want to see all those extra decimal places: simply format your result rounded to a fixed number of decimal places when displaying it.
• If you have no decimal datatype available, an alternative is to work with integers, e.g. do money calculations entirely in cents. But this is more work and has some drawbacks.

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You should use a decimal datatype, not floats:

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Another solution is to forgo `==` and check if the two values are close enough. (I know this is not what you asked in the body but I'm answering the question title.)

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For the sake of completeness I recommend this one:

Shewchuck, "Robust Adaptive Floating-Point Geometric Predicates", if you want more examples of how to perform exact arithmetic with floating point - or at least controlled accuracy which is the original intention of author, http://www.cs.berkeley.edu/~jrs/papers/robustr.pdf

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If you want to keep on using `float` and avoid accumulating errors by repeatedly adding `0.1f`, try something like this:

``````for (int count = 0; count < 10; count++) {
float value = 0.1f * count;
System.out.println(value);
}
``````

Note however, as others have already explained, that `float` is not an infinitely precise data type.

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You just need to be aware of the precision required in your calculation and the precision your chosen data type is capable of and present your answers accordingly.

For example, if you are dealing with numbers with 3 significant figures, use of `float` (which provides a precision of 7 significant figures) is appropriate. However, you can't quote your final answer to a precision of 7 significant figures if your starting values only have a precision of 2 significant figures.

``````5.01 + 4.02 = 9.03 (to 3 significant figures)
``````

In your example you are performing multiple additions, and with each addition there is a consequent impact on the final precision.

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