First, your program never ends. You have a
while True loop without a
break, or any other way to exit the loop. The other code you posted has
while one == 0 instead of
while True, and it sets
one = 1 as soon as
len(l) > 500. That's a little awkward, but it works.
a = 1
if get_divisors_count(get_triangular(a)) > 500:
a += 1
This is still pretty slow, but not infinitely slow.
The next biggest difference is that you're counting up to n/2+1, while the other code is counting to sqrt(n), and counting each divisor twice. (Why does this work? Think about it: If
a is a divisor of
n/a is too, and exactly one of them must be less than
sqrt(n) unless they're both equal to it.)
You're also wasting a bit of time in a few areas where the other program doesn't, like calculating
sum(range(1, nth+1)) over and over, instead of keeping a running sum and doing
running_sum += a. On the other hand, you're already saving some time by just keeping a count of divisors instead of building a list of them and then taking its length.
But those are minor compared to the previous issues. At least your program now has the same algorithmic complexity,
O(N**1.5), instead of
O(N**2) (or infinite); on my machine, it runs in 15.3 seconds vs. 12.1.
If you really want to make it faster, there are two major options:
- Look at it mathematically and see if there's a better way to solve this than brute force. (Hint: Can see how prime factorization would help you here?)
- Figure out if there's information you can memoize (cache) that would help out. For example, if you want to count the factors of 96, and you already have the factors of 24, does that do you any good? What if you have only the factor count? Or only the prime factors?