I'm working on problem 401 in project euler, I coded up my solution in python but it's going to take a few days to run, obviously I'll need to speed it up or use a different approach. I came across a solution in Haskell that looks almost identical to my python solution but completes almost instantaneously.
Can someone explain how it is so fast? (I AM NOT ASKING FOR HELP OR SOLUTIONS TO PROBLEM 401)
divisors n = filter (\x -> n `mod` x == 0) [1..(n`div`2)] ++ [n] sigma2 n = sum $ map (\x -> x * x) (divisors n) sigma2big n = sum $ map (sigma2)[1..n] let s2b = sigma2big 10^15 putStrLn ("SIGMA2(10^15) mod 10^9 is " ++ (show (mod s2b 10^9)))
From my understanding it is just using trial division to generate a list of divisors, squaring and summing them, and then summing the results from 1 to n.
EDIT: forgot my python code
from time import clock def timer(function): def wrapper(*args, **kwargs): start = clock() print(function(*args, **kwargs)) runtime = clock() - start print("Runtime: %f seconds." % runtime) return wrapper @timer def find_answer(): return big_sigma2(10**15) % 10**9 def get_divisors(n): divs = set() for i in range(1, int(sqrt(n)) + 1): if n % i == 0: divs.add(i) divs.add(n // i) return divs def sigma2(n): return sum(map(lambda x: x**2, get_divisors(n))) def big_sigma2(n): total = 0 for i in range(1, n + 1): total += sigma2(i) return total if __name__ == "__main__": find_answer()