# How does addition/subtraction of float numbers work in Python?

I don't understand what is going on in the following lines of code:

``````>>> 123456789012345678. -123456789012345677.
0.0
``````

Shouldn't the result be 1.0?

Thanks. Cheers :)

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Duplicate of so many "float math is broken" questions. Perhaps SO should add a special hint to pop up when floats are mentioned in a new question (+ perhaps a few other heuristics to eliminate the worst false positives)... – delnan Nov 5 '11 at 21:50
Float math works the way float math works, not the way we expect float math to work. – ObscureRobot Nov 5 '11 at 21:51
Maybe downvoters should take into account a) the OP is a newcomer in his first SO question. b) the answer is not evident for a noob and in fact an answer got 5 upvotes c) neither is to relate the problem with other headers in SO – joaquin Nov 5 '11 at 21:59
@delnan: Technically, it's not a duplicate. Most newbie "float math is broken" questions are about the non-decimal base. This one is about the limited precision. – dan04 Nov 8 '11 at 17:47

Floats only store 53 bits of information, so you are being affected by round-off.

``````>>> 123456789012345678 - 123456789012345677
1
``````

Or use the Decimal module:

``````>>> from decimal import Decimal
>>> Decimal('123456789012345678.0') - Decimal('123456789012345677.0')
Decimal('1.0')
``````
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There is no exact representation of 123456789012345678 as a float:

``````>>> 123456789012345678.
1.2345678901234568e+17
^ oops
``````
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Floating point numbers are stored as 53 bits1 of mantissa plus 11 bits of exponent, plus a sign bit.

Your numbers require more than 53 bits to represent, so the nearest actual representable floating point value is used.

Floating point numbers usually model real-world measurements or simulations of real-world systems. Few if any physical constants or measurements are known to anything even close to 52 bits of precision, so this normally works out OK.

1. The 53rd bit is a hidden bit but it isn't enough to help you:
\$ dc
2 52^p
4503599627370496
2 53^p
9007199254740992
123456789012345678 <<<< your number is bigger, actually, it requires about 56 bits:
2o 2 53^1-p
11111111111111111111111111111111111111111111111111111
123456789012345678p
110110110100110110100101110100110001100001111001101001110

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Effectively, it is a 53 bit mantissa but the leading 1 isn't stored. – Raymond Hettinger Nov 5 '11 at 21:56

Float arithmetics has common issue of rounding problem.

What Every Computer Scientist Should Know About Floating-Point Arithmetic

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