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How does one convert a base-10 floating point number in Python to a base-N floating point number?

Specifically in my case, I would like to convert numbers to base 3 (obtain the representation of floating point numbers in base 3), for calculations with the Cantor set.

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The floats you have built into Python use base 2... –  delnan Feb 24 '11 at 20:45
    
I doubt there's any way to do actual calculations in base 3 in Python without rolling your own crazy base 3 version of decimal. But I could be wrong... –  senderle Feb 24 '11 at 20:51
    
Well, internal representation is surely in binary, but does that change anything with regards to converting to any other base? –  Herman Schaaf Feb 24 '11 at 20:52
    
@Herman, sorry I guess I'm confused. Do you want to calculate in base 3, as your question seems to suggest, or do you just want to represent the results of normal binary floating point calculations in base 3? –  senderle Feb 24 '11 at 21:01
3  
Handling the integer part is easy. Handling the fractional part can result in a staggering amount of inaccuracy if done incorrectly. –  Ignacio Vazquez-Abrams Feb 24 '11 at 21:12
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1 Answer

up vote 6 down vote accepted

After a bit of fiddling, here's what I came up with. I present it to you humbly, keeping in mind Ignacio's warning. Please let me know if you find any flaws. Among other things, I have no reason to believe that the precision argument provides anything more than a vague assurance that the first precision digits are pretty close to correct.

def base3int(x):
    x = int(x)
    exponents = range(int(math.log(x, 3)), -1, -1)
    for e in exponents:
        d = int(x // (3 ** e))
        x -= d * (3 ** e)
        yield d

def base3fraction(x, precision=1000):
    x = x - int(x)
    exponents = range(-1, (-precision - 1) * 2, -1)
    for e in exponents:
        d = int(x // (3 ** e))
        x -= d * (3 ** e)
        yield d
        if x == 0: break

These are iterators returning ints. Let me know if you need string conversion; but I imagine you can handle that.

EDIT: Actually looking at this some more, it seems like a if x == 0: break line after the yield in base3fraction gives you pretty much arbitrary precision. I went ahead and added that. Still, I'm leaving in the precision argument; it makes sense to be able to limit that quantity.

Also, if you want to convert back to decimal fractions, this is what I used to test the above.

sum(d * (3 ** (-i - 1)) for i, d in enumerate(base3fraction(x)))

Update

For some reason I've felt inspired by this problem. Here's a much more generalized solution. This returns two generators that generate sequences of integers representing the integral and fractional part of a given number in an arbitrary base. Note that this only returns two generators to distinguish between the parts of the number; the algorithm for generating digits is the same in both cases.

def convert_base(x, base=3, precision=None):
    length_of_int = int(math.log(x, base))
    iexps = range(length_of_int, -1, -1)
    if precision == None: fexps = itertools.count(-1, -1)
    else: fexps = range(-1, -int(precision + 1), -1)

    def cbgen(x, base, exponents):
        for e in exponents:
            d = int(x // (base ** e))
            x -= d * (base ** e)
            yield d
            if x == 0 and e < 0: break

    return cbgen(int(x), base, iexps), cbgen(x - int(x), base, fexps)
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Nice, that seems to work reasonably well. (Sometimes off by a few digits later on from what the built-in javascript function toString(3) tells me it should be.) –  Herman Schaaf Feb 24 '11 at 22:28
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