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I'm running into an issue with python automatically rounding very small numbers (smaller than 1e-8) when subtracting an array from an single float. Take this example:

 import numpy as np
 float(1) - np.array([1e-10, 1e-5])

Any thoughts on how to force python not to round? This is forcing me to divide by zero in some cases, and becoming a problem. The same problem arises when subtracting from an numpy array.

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I'm having the same issue raising small numbers to the power of 1, and having them rounded to 0. – mike Jul 29 '11 at 0:37
Odd that you got a downvote... It's a good question, i.m.o. – Joe Kington Jul 29 '11 at 1:15
up vote 6 down vote accepted

Mostly, it's just the repr of numpy arrays that's fooling you.

Consider your example above:

import numpy as np  
x = float(1) - np.array([1e-10, 1e-5]) 
print x
print x[0]
print x[0] == 1.0

This yields:

[ 1.      0.99999 ]

So the first element isn't actually zero, it's just the pretty-printing of numpy arrays that's showing it that way.

This can be controlled by numpy.set_printoptions.

Of course, numpy is fundementally using limited precision floats. The whole point of numpy is to be a memory-efficient container for arrays of similar data, so there's no equivalent of the decimal class in numpy.

However, 64-bit floats have a decent range of precision. You won't hit too many problems with 1e-10 and 1e-5. If you need, there's also a numpy.float128 dtype, but operations will be much slower than using native floats.

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I didn't think of that, but you are absolutely right.. never trust just a mere representation of something! +1 – redShadow Jul 29 '11 at 1:37

I guess all that depends on the handling of very small float numbers, by Python and by the underlying C libraries, that at a certain point tend to loose precision.

If you need that level of precision, imho you should rely on something different, such as fractionary numbers etc.

I don't know whether there already is something to handle that, but if you could manage to represent that numbers in a different way (such as 1/10000000000 and 1/100000) and then calculate the floating point result only at the end of all calculations, you should avoid all these problems.

(Of course, you need some class that automagically handles fractionary calculations to avoid having to reimplement formulas, etc.)

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