If you actually want to use that algorithm, and you want to work beyond the limits of the built-in `float`

, then yes, you need a different type.

If all you want is to get an approximate answer instead of an exception, that's easy; you can get infinite range out of the box. But if you also want to eliminate the rounding errors, you can't have infinite precision (that would take infinite time/space), so you have to know how to work out the precision needed for your range of inputs. (I'll leave that as an exercise for the reader.)

The standard library type `decimal.Decimal`

may be all you need. It provides arbitrary-precision fixed- or floating-point decimal arithmetic according to the IEEE-854 standard. There are many cases for which it's unusable because it doesn't provide enough mathematical functions, but you only need basic arithmetic and `sqrt`

, which are just fine. It can also be slow for huge numbers, but if you just want to calculate `fib`

on a few three-digit numbers it's more than sufficient.

When `Decimal`

is insufficient, there are a number of third-party modules, usually wrapping industry-standard C libraries like gmp/mpfr, such as bigfloat.

Here's how to get infinite range, but with rounding errors on roughly the same scale as the built-in float:

```
>>> s5 = decimal.Decimal(5).sqrt()
>>> def fib(n):
... return ((1+s5)**n - (1-s5)**n)/(2**n*s5)
>>> fib(800)
Decimal('6.928308186422471713629008226E+166')
>>> int(fib(800))
69283081864224717136290082260000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000L
>>> s5 = bigfloat.sqrt(5)
>>> def fib(n):
... return ((1+s5)**n - (1-s5)**n)/(2**n*s5)
>>> fib(800)
BigFloat.exact('6.9283081864226567e+166', precision=53)
>>> int(fib(800))
69283081864226566841137772774650010139572747244991592044952506898599601083170460360533811597710072779197410943266632999194601974766803264653830633103719677469311107072L
```

But notice that neither of these are actually the answer you'd get if you did the math perfectly; you've lost 24 digits to rounding errors. (The reason the values are different is that `bigfloat`

is rounding in base 2, `decimal`

in base 10.)

To fix that, you need more precision. All libraries provide some way to change the precision; `bigfloat`

has more convenient options than most, but none are too onerous:

```
>>> decimal.getcontext().prec = 300
>>> s5 = decimal.Decimal(5).sqrt()
>>> def fib(n):
... return ((1+s5)**n - (1-s5)**n)/(2**n*s5)
>>> fib(800)
69283081864224717136290077681328518273399124385204820718966040597691435587278383112277161967532530675374170857404743017623467220361778016172106855838975759985190398725.0000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000048
>>> def fibp(n, p):
... with bigfloat.precision(p):
... s5 = bigfloat.sqrt(5)
... return ((1+s5)**n - (1-s5)**n)/(2**n*s5)
>>> fibp(800, 125)
BigFloat.exact('6.92830818642247171362900776814484912138e+166', precision=125)
>>> int(fibp(800, 125))
69283081864224717136290077681448491213794574774712670552070914552025662674717073354503451578576268674564384721027806323979200718479461097490537109958812524476157132800L
```