# Project Euler #25 - Can the performance be improved further?

The 12th term, F12, is the first term to contain three digits.

What is the index of the first term in the Fibonacci sequence to contain 1000 digits?

``````a = 1
b = 1
i = 2
while(1):
c = a + b
i += 1
length = len(str(c))
if length == 1000:
print(i)
break
a = b
b = c

``````

I got the answer(works fast enough). Just looking if there's a better way for this question

• you can use dis to check your versions – Drako Apr 11 '19 at 8:06
• If your code works and you want tips on how to improve it, try out the Code Review SE forum. – lucasgcb Apr 11 '19 at 8:15
• Of course perfomance can be improved. You can solve the problem much-much faster because there is exact formula to compute n-th fibonacci number - math.hmc.edu/funfacts/ffiles/10002.4-5.shtml. I guess even O(1) algorithm is possible. – Poolka Apr 11 '19 at 8:26

If you've answered the question, you'll find plenty of explanations on answers in the problem thread. The solution you posted is pretty much okay. You may get a slight speedup by simply checking that your `c>=10^999` at every step instead of first converting it to a string.

The better method is to use the fact that when the Fibonacci numbers become large enough, the Fibonacci numbers converge to `round(phi**n/(5**.5))` where `phi=1.6180...` is the golden ratio and `round(x)` rounds `x` to the nearest integer. Let's consider the general case of finding the first Fibonacci number with more than `m` digits. We are then looking for `n` such that `round(phi**n/(5**.5)) >= 10**(m-1)`

We can easily solve that by just taking the log of both sides and observe that `log(phi)*n - log(5)/2 >= m-1` and then solve for `n`.

If you're wondering "well how do I know that it has converged by the `n`th number?" Well, you can check for yourself, or you can look online.

Also, I think questions like these either belong on the Code Review SE or the Computer Science SE. Even Math Overflow might be a good place for Project Euler questions, since many are rooted in number theory.

Your solution is completely fine for #25 on project euler. However, if you really want to optimize for speed here you can try to calculate fibonacci using the identities I have written about in this blog post: https://sloperium.github.io/calculating-the-last-digits-of-large-fibonacci-numbers.html

``````from functools import lru_cache

@lru_cache(maxsize=None)
def fib4(n):
if n <= 1:
return n

if n % 2:
m = (n + 1) // 2
return fib4(m) ** 2 + fib4(m - 1) ** 2
else:
m = n // 2
return (2 * fib4(m - 1) + fib4(m)) * fib4(m)

def binarySearch( length):
first = 0
last = 10**5
found = False

midpoint = (first + last) // 2
length_string = len(str(fib4(midpoint)))
if length_string == length:
return midpoint -1
else:
if length < length_string:
last = midpoint - 1
else:
first = midpoint + 1

print(binarySearch(1000))
``````

This code tests about 12 times faster than your solution. (it does require an initial guess about max size though)