Floating point number

Revision as of 15:09, 10 March 2011 by Smitschu (talk | contribs)

In Python and almost all other programming languages floating point numbers are the primitive datatype used to represent rational numbers and real numbers. Most of the standard numerical operators and relational operators work on floating point numbers, but see below for a caveat.

Implementation Details

In the computer floating point numbers are stored as a series of significant digits, and an exponent (similar to scientific notation). However, unlike how humans write numbers, computers store numbers in binary. This is usually transparent to the programmer, but leads to several subtleties.

Unlike integers in Python, floating point numbers are always stored in a fixed amount of space (typically 64 bits for Python), which limits their precision to typically about 16 decimal digits. Because the computer has a limited space to store a number it must often round off to a value very close but not exactly equal to the original. Some rational numbers that can be represented as terminating decimals in base 10 (like 0.8) are repeating in base 2 (0.8 in base 2 would be 0.11001100...), and so can't be represented exactly. The range of floating point numbers is also limited, though this usually isn't a problem because it's very large, around $10^{300}$.

Because of this limited precision, floating point calculations may give results slightly different from what you might expect. In particular, it's bad practice to directly test floating point numbers for equality, because they may have been rounded differently. The usual solution to this problem is to test if the numbers in question are within a certain margin of error (which might change depending on the application) of each other, as seen below.

if fpNum1 == fpNum2:             # this is bad
if abs(fpNum1-fpNum2) < epsilon: # this is better