I've got another answer. Lets replace the inner loop with an abstract func():
Firstly, forgetting the calls to func(), the complexity M to calculate all (i % j) is O(n^2).
Now, we can ask ourselves how many times the func() is called. It's called once for each divisor of i. That is it is called d(i) times for each i. This is a Divisor summatory function D(n). D(n) ~ n log n for large n.
So func() is called n log n times. At the same time the func() itself has complexity of O(n). So it gives the complexity P = O(n * n log n).
So total complexity is M + P = O(n^2) + O(n^2 log n) = O(n^2 log n)
Vow, thanks for downvote! I guess I need to prove it using python.
This code prints out n, how many times the inner loop is called for n, and outputs ratio of the latter and Divisor summatory function
n = 100000
i = 0
z = 0
gg = 2 * 0.5772156649 - 1
while i < n:
j = 1
while j <= i:
if i % j == 0:
#ignoring the most inner loop just calculate the number of times it is called
if i > 0 and i % 1000 == 0:
#Exact divisor summatory function, to make z/Di converge to 1.0 quicker
Di = (i * math.log(i) + i * gg)
#prints n Di z/Di
print str(i) + ": " + str(z) + ": " + str(z/Di)
24000: 245792: 1.00010672544
25000: 257036: 1.00003672445
26000: 268353: 1.00009554815
So the most inner loop is called n * log n times, and total complexity is n^2 * log n