I know that floating point math can be ugly at best but I am wondering if somebody can explain the following quirk. In most of the programing languages I tested the addition of 0.4 to 0.2 gave a slight error, where as 0.4 + 0.1 + 0.1 gave non.

What is the reason for the inequality of both calculation and what measures can one undertake in the respective programing languages to obtain correct results.

In python2/3

.4 + .2
.4 + .1 + .1

The same happens in Julia 0.3

julia> .4 + .2

julia> .4 + .1 + .1

and Scala:

scala> 0.4 + 0.2
res0: Double = 0.6000000000000001

scala> 0.4 + 0.1 + 0.1
res1: Double = 0.6

and Haskell:

Prelude> 0.4 + 0.2
Prelude> 0.4 + 0.1 + 0.1

but R v3 gets it right:

> .4 + .2
[1] 0.6
> .4 + .1 + .1
[1] 0.6
  • 14
    Some languages hide the truth by rounding for display purposes.
    – DavidO
    Commented Feb 19, 2014 at 6:37
  • 18
    Actually, R is just hiding it from you: run format(.4 + .1 + .1, digits=17), format(.4 + .2, digits=17).
    – tonytonov
    Commented Feb 19, 2014 at 6:38
  • 3
    These results are as correct as possible in IEEE notation. Commented Feb 19, 2014 at 6:38
  • 3
    At best floating-point math is far from ugly; it has proven beautiful enough to land a man on the moon, to model the human heart in action, and to peer into the furthest depths of the universe. Any ugliness is in the eye of the (myopic, astigmatic) beholder. Commented Feb 19, 2014 at 14:29
  • 2
    @Mark Floating point is wonderful; it just doesn't have exact equality defined. Languages which give that to the programmer are committing small lies. Turns out that many real-world situations don't have exact equality either. Commented Feb 19, 2014 at 15:05

3 Answers 3


All these languages are using the system-provided floating-point format, which represents values in binary rather than in decimal. Values like 0.2 and 0.4 can't be represented exactly in that format, so instead the closest representable value is stored, resulting in a small error. For example, the numeric literal 0.2 results in a floating-point number whose exact value is 0.200000000000000011102230246251565404236316680908203125. Similarly, any given arithmetic operation on floating-point numbers may result in a value that's not exactly representable, so the true mathematical result is replaced with the closest representable value. These are the fundamental reasons for the errors you're seeing.

However, this doesn't explain the differences between languages: in all of your examples, the exact same computations are being made and the exact same results are being arrived at. The difference then lies in the way that the various languages choose to display the results.

Strictly speaking, none of the answers you show is correct. Making the (fairly safe) assumption of IEEE 754 binary 64 arithmetic with a round-to-nearest rounding mode, the exact value of the first sum is:


while the exact value of the second sum is:


However, neither of those outputs is particularly user-friendly, and clearly all of the languages you tested made the sensible decision to abbreviate the output when printing. However, they don't all adopt the same strategy for formatting the output, which is why you're seeing differences.

There are many possible strategies for formatting, but three particularly common ones are:

  1. Compute and display 17 correctly-rounded significant digits, possibly stripping trailing zeros where they appear. The output of 17 digits guarantees that distinct binary64 floats will have distinct representations, so that a floating-point value can be unambiguously recovered from its representation; 17 is the smallest integer with this property. This is the strategy that Python 2.6 uses, for example.

  2. Compute and display the shortest decimal string that rounds back to the given binary64 value under the usual round-ties-to-even rounding mode. This is rather more complicated to implement than strategy 1, but preserves the property that distinct floats have distinct representations, and tends to make for pleasanter output. This appears to be the strategy that all of the languages you tested (besides R) are using.

  3. Compute and display 15 (or fewer) correctly-rounded significant digits. This has the effect of hiding the errors involved in the decimal-to-binary conversions, giving the illusion of exact decimal arithmetic. It has the drawback that distinct floats can have the same representation. This appears to be what R is doing. (Thanks to @hadley for pointing out in the comments that there's an R setting which controls the number of digits used for display; the default is to use 7 significant digits.)

  • @hadley: Thanks. I was trying to find that information in the documentation; do you have a doc link handy? Commented Feb 19, 2014 at 14:17
  • In R, ?options, under 'digits'. Online at stat.ethz.ch/R-manual/R-patched/library/base/html/options.html
    – Gray
    Commented Feb 19, 2014 at 15:25
  • 3
    Excellent explanation. Printing binary floating-point values in the least number of decimal digits required to reproduce the same value on input is a surprisingly difficult problem. An efficient algorithm that doesn't need arbitrary precision arithmetic was only published in 2010 by Florian Loitsch. Julia uses the excellent double-conversion library which Florian developed for the V8 JavaScript engine. Commented Feb 20, 2014 at 4:28
  • @StefanKarpinski It still needs arbitrary precision for some cases (from the referenced paper: "... roughly 99.5% are processed correctly and are thus guaranteed to be optimal (with respect to shortness and rounding). The remaining 0.5% are rejected and need to be printed by another printing algorithm (like Dragon4).").
    – Rick Regan
    Commented Feb 20, 2014 at 17:09
  • Yes, that's true. Or you can give up very slightly on perfectly optimal printing and do without it. Commented Feb 20, 2014 at 20:18

You should be aware that 0.6 cannot be exactly represented in IEEE floating point, and neither can 0.4, 0.2, and 0.1. This is because the ratio 1/5 is an infinitely repeating fraction in binary, just like ratios such as 1/3 and 1/7 are in decimal. Since none of your initial constants is exact, it is not surprising that your results are not exact, either. (Note: if you want to get a better handle on this lack of exactness, try subtracting the value you expect from your computed results...)

There are a number of other potential gotchas in the same vein. For instance, floating point arithmetic is only approximately associative: adding the same set of numbers together in different orders will usually give you slightly different results (and occasionally can give you very different results). So, in cases where precision is important, you should be careful about how you accumulate floating point values.

The usual advice for this situation is to read "What Every Computer Scientist Should Know About Floating Point Arithmetic", by David Goldberg. The gist: floating point is not exact, and naive assumptions about its behavior may not be supported.


The reason is because it's being rounded up at the end according to the IEEE Standard for Floating-Point Arithmetic :


According to the standard: addition, multiplication, and division should be completely correct all the way up to the last bit. This is because a computer has a finite amount of space to represent these values and cannot infinitely trail the precision.

  • 2
    "cannot infinitely trail the zeros" - well, that's easy enough. An infinite number of 0s takes 0 space to store with an efficient encoding, since it contains 0 information. The problem is storing an infinite trail of mixed 0s and 1s. Commented Feb 19, 2014 at 6:59
  • 2
    Seriously, the phrase “cannot infinitely trail the zeros” does not make any sense. All numbers in IEEE 754 format have infinite trailing zeroes in decimal and in binary, so it is clearly possible to represent numbers with this property. Commented Feb 19, 2014 at 8:53
  • @PascalCuoq There you go, I fixed the wording for you
    – Nowayz
    Commented Jan 8, 2015 at 4:01

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