This question is strongly related to How to propose specialized floating point rounding questions and answers

Having the first Q&A in the proposed series be of high quality from its first non-meta appearance is essential for success of the project. I am presenting a draft here to get feedback and suggestions for improvement. Although I present examples in a couple of languages for concreteness and clarity, it is intended to be as general and language-neutral as possible. The tags will be [language-agnostic],[floating-point],[double], and [floating-accuracy].

The meta question is whether this is a good first Q&A for the project, with enough detail but not too much. Also, how should I protect this from routine treatment as a duplicate? Probably a link to the meta-discussion, but should it be in the body of the question or as a comment?

**Question**

*Title:* A floating point variable in my program does not have exactly the initial value I specified.

*Body:*

Some, but not all, floating point variables are slightly bigger or smaller than the value I specified.

Java example:

`import java.math.BigDecimal; public strictfp class Test { public static void main(String[] args) { double x = 0.1; double y = 0.25; double z = 0.3; System.out.println(new BigDecimal(x)); System.out.println(new BigDecimal(y)); System.out.println(new BigDecimal(z)); } }`

prints

`0.1000000000000000055511151231257827021181583404541015625 0.25 0.299999999999999988897769753748434595763683319091796875`

Python example:

`x=0.1 y=0.25 z=0.3 print ("%30.30f" % x) print ("%30.30f" % y) print ("%30.30f" % z)`

prints

`0.100000000000000005551115123126 0.250000000000000000000000000000 0.299999999999999988897769753748`

In each case,

`x`

is bigger than I specified,`y`

is just right, and`z`

is smaller than specified. Why does this happen?

**Answer**

This answer covers only this specific question. See Is floating point math broken? for much more information, background, and useful links.

The effect described in the question is a natural consequence of using binary floating point. The numbers that can be represented in a binary floating point format are a format-dependent subset of the terminating binary fractions, those numbers that can be written as

significand*2^{exponent}, wheresignificandandexponentare both integers.0.25 can be written as 1*2

^{-2}. 1 and -2 are both small enough magnitude that 0.25 can be represented exactly in any practical binary floating point system.Neither 0.1 nor 0.3 can be written as a terminating binary fraction, for the same reason as 1/3 cannot be written as a terminating decimal fraction. Only deep familiarity with decimal arithmetic makes it seem stranger that 1/10 cannot be written as terminating binary fraction.

Languages that use binary floating point deal with numbers such as 0.1 and 0.3 by substituting the closest number that the floating point format can represent. That may be larger or smaller than the specified value.