EDIT: I actually think Hynek Vychodil's answer is superior to mine, but I'm leaving this here just in case someone is looking for an alternate method.

I think the other methods are all valid, but not optimal. Using Binet's formula should give you the right answer in principle, but rounding to the closest integer will give some problems for large values of n. The other solutions will unnecessarily recalculate the values upto n every time you call the function, and so the function is not optimized for repeated calling.

In my opinion the best thing to do is to define a global array and then to add new values to the array IF needed. In Python:

```
import numpy
fibo=numpy.array([1,1])
last_index=fibo.size
def fib(n):
global fibo,last_index
if (n>0):
if(n>last_index):
for i in range(last_index+1,n+1):
fibo=numpy.concatenate((fibo,numpy.array([fibo[i-2]+fibo[i-3]])))
last_index=fibo.size
return fibo[n-1]
else:
print "fib called for index less than 1"
quit()
```

Naturally, if you need to call fib for n>80 (approximately) then you will need to implement arbitrary precision integers, which is easy to do in python.

`f(n - 1) = f(n - 2) + f(n - 3)`

so`f(n) = 2 * f(n - 2) + f(n - 3)`

. You can cache`f(n - 2)`

. Of course, doing it iteratively is much better, especially if your language of choice has`yield`

. – Ryan O'Hara♦ Jun 7 '12 at 0:33