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)
```

`decimal`

. But I could be wrong... – senderle Feb 24 '11 at 20:51calculatein 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