# How to avoid floating point errors?

I was trying to write a function to approximate square roots (I know there's the math module...I want to do it myself), and I was getting screwed over by the floating point arithmetic. How can you avoid that?

def sqrt(num):
root = 0.0
while root * root < num:
root += 0.01
return root

Using this has these results:

>>> sqrt(4)
2.0000000000000013
>>> sqrt(9)
3.00999999999998

I realize I could just use round(), but I want to be able to make this really accurate. I want to be able to calculate out to 6 or 7 digits. That wouldn't be possible if I'm rounding. I want to understand how to properly handle floating point calculations in Python.

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Perhaps try the decimal module, which is designed for precision? – Michael0x2a Oct 20 '13 at 4:05

This really has nothing to do with Python - you'd see the same behavior in any language using your hardware's binary floating-point arithmetic. First read the docs.

>>> from decimal import Decimal
>>> Decimal(.01)
Decimal('0.01000000000000000020816681711721685132943093776702880859375')

That string shows the exact decimal value of the binary floating ("double precision" in C) approximation to the exact decimal value 0.01. The thing you're really adding is a little bigger than 1/100.

Controlling floating-point numeric errors is the field called "numerical analysis", and is a very large and complex topic. So long as you're startled by the fact that floats are just approximations to decimal values, use the decimal module. That will take away a world of "shallow" problems for you. For example, given this small modification to your function:

from decimal import Decimal as D

def sqrt(num):
root = D(0)
while root * root < num:
root += D("0.01")
return root

then:

>>> sqrt(4)
Decimal('2.00')
>>> sqrt(9)
Decimal('3.00')

It's not really more accurate, but may be less surprising in simple examples because now it's adding exactly one one-hundredth.

An alternative is to stick to floats and add something that is exactly representable as a binary float: values of the form I/2**J. For example, instead of adding 0.01, add 0.125 (1/8) or 0.0625 (1/16).

Then look up "Newton's method" for computing square roots ;-)

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For the record I had read the docs and I did already know about the whole floating point accuracy thing with storing binary representations. I had forgotten Newton's method. You're picking up all my questions around here! My lucky day when you discovered SO. I wonder how the Decimal module works. Is there any way to find out besides reading the source? – Aerovistae Oct 20 '13 at 4:37
Well, decimal was originally written in Python and worked on lists of decimal digits (0, 1, 2, ..., 9). Very much emulating how we do arithmetic on paper! "Floating point" just requires adding a (decimal) exponent to the representation, and then being very careful ;-) The current decimal module is coded in C, and is much more obscure :-( – Tim Peters Oct 20 '13 at 4:41
as you said, I tried to solve 4 - 3.2 using decimal module. a = Decimal(4) b = Decimal(3.2) but a - b result is Decimal('0.7999999999999998223643160600') – Srinesh Jan 5 at 11:46