# Float random(?!) precision quirk [duplicate]

I have just started learning python and I have stumbled across a particularity

python version:

Python 2.7.2 (default, Jul 20 2011, 02:32:18) [GCC 4.2.1 (LLVM, Emscripten 1.5, Empythoned)] on linux2

Working with the interpreter assigning:

``````    pi = 3.141 // 3 places decimal precision
#typing pi  & pressing return puts 3.141
type(pi)
=> <type 'float'>
pi = 3.1415
type(pi)
=> <type 'float'>
#pi puts 3.1415000000000002
``````

Ok floating point precision is notorious for being unprecise; but why do only the 4 point precision get that "tail"?

Also:

`````` pi2 = 3.1415100000000002
pi == pi2 # pi was assigned 3.1415
=> True
print(pi2)
3.14151 # Where's my precision?
``````
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## marked as duplicate by ev-br, glglgl, Ian, karthikr, JoeJul 17 '13 at 13:10

Not every decimal fraction can be precisely represented by a binary encoded float. For this reason, using `==` with floats is generally not a good idea. A much simpler case: `0.1 + 0.2` evaluates to `0.30000000000000004`. This is not loss of precision, this is a byproduct of encoding a decimal fraction in binary IEEE-754 format. – android Jul 17 '13 at 9:52
@android why does it cut my precise assignment? – raam86 Jul 17 '13 at 9:53
If you want your precision, you can use `Decimal` module. – zhangyangyu Jul 17 '13 at 9:56
@raam86 en.wikipedia.org/wiki/Floating_point#Accuracy_problems. This might help. – android Jul 17 '13 at 9:56
@raam86 If you're still confused, read up on how to convert a fraction from decimal to binary and try doing this conversion by hand (on paper) for `0.1`. You'll see why. – android Jul 17 '13 at 9:58

Integers and floats are given a certain number of bits. For integers, each bit corresponds to a power of two. The first digit is 20, then 21, 22, and so on. So to store the integer `5` we have 20 + 22 = 1 + 4.

For floating point numbers, we store them in two parts. The exponent, and the decimal. If we have an decimal of .75 and a exponent of 2, we do .75 * 102 = 7.5. The decimal is stored as negative powers of 2. So we have 2-1, 2-2. 2-3. etc. These equate to `.5`, `.25`, `.125`, etc.

Some numbers are impossible to store, because they literally require infinite bits to represent, like 0.1, and others like 3.1415 require more bits than the CPU provides for floating-point numbers (24 is standard for 32bit floats, but algorithms vary).

The correct way to compare floats is to have a variance defined, and use something along these lines.

``````variance = .0001
floatsEqual = lambda f1, f2: f1 - variance <= f2 and f1 + variance >= f2

if (floatsEqual(3.1415, 3.1415 + 1 - 1)):
pass
``````

In Python, the decimal library is also useful.

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