# Finding the total divisors of a number up to 10^12 as fast as possible?

I need to calculate the total number of divisors of a number N (without caring about what the values of the divisors are) and do so within 40-80 operations for all such numbers N. How can I do it? This is not a homework question. I tried out Pollard's Rho algorithm but even that turned out too slow for my purposes. Here is my code in python. How can I improve its performance, if possible?

``````def is_prime(n):
if n < 2:
return False
ps = [2,3,5,7,11,13,17,19,23,29,31,37,41,
43,47,53,59,61,67,71,73,79,83,89,97]
def is_spsp(n, a):
d, s = n-1, 0
while d%2 == 0:
d /= 2; s += 1
t = pow(int(a),int(d),int(n))
if t == 1:
return True
while s > 0:
if t == n-1:
return True
t = (t*t) % n
s -= 1
return False
if n in ps: return True
for p in ps:
if not is_spsp(n,p):
return False
return True

def gcd(a,b):
while b: a, b = b, a%b
return abs(a)

def rho_factors(n, limit=100):
def gcd(a,b):
while b: a, b = b, a%b
return abs(a)
def rho_factor(n, c, limit):
f = lambda x:    (x*x+c) % n
t, h, d = 2, 2, 1
while d == 1:
if limit == 0:
raise OverflowError('limit exceeded')
t = f(t); h = f(f(h)); d = gcd(t-h, n)
if d == n:
return rho_factor(n, c+1, limit)
if is_prime(d):
return d
return rho_factor(d, c+1, limit)
if -1 <= n <= 1: return [n]
if n < -1: return [-1] + rho_factors(-n, limit)
fs = []
while n % 2 == 0:
n = n // 2; fs = fs + [2]
if n == 1: return fs
while not is_prime(n):
f = rho_factor(n, 1, limit)
n = int(n / f)
fs = fs + [f]
return sorted(fs + [n])

def divs(n):
if(n==1):
return 1
ndiv=1
f=rho_factors(n)
l=len(f)
#print(f)
c=1
for x in range(1,l):
#print(f[x])
if(f[x]==f[x-1]):
c=c+1
else:
ndiv=ndiv*(c+1)
c=1
# print ("C",c,"ndiv",ndiv)
ndiv=ndiv*(c+1)
return ndiv
``````
• Please clean up your code formatting. – Steven Rumbalski Sep 6 '12 at 17:43
• A good start would be to code it in C :P – Haile Sep 6 '12 at 17:56
• If this is a problem with some real-world code, can you explain why you need to do this? If this is an online programming challenge, can you provide a link to the problem description? If this is an interview question, does your interviewer know you're looking for help online? :-) – Kevin Sep 6 '12 at 17:56
• I'm pretty sure finding the number of divisors of any number N is very very hard to do efficiently. It's strictly harder than testing if any number N is prime or not, and that's the kind of problem that institutes offer million dollar prizes for solving. – Kevin Sep 6 '12 at 18:04
• The usual method is to first remove small prime factors by trial division, and then switch to a method like Pollard's rho or elliptic curve factorisation, and hope for the best. For numbers in the given range, the rho algorithm finds the larger prime factors reasonably quickly, so if that's too slow after it's been optimised, you must be missing a trick. Could you please link to the problem statement? – Daniel Fischer Sep 6 '12 at 19:05

I remember solving this problem before on SPOJ, but I don't remember the exact method I used (it'd be great if you provide the problem ID). Did you try the naive method here? It has a complexity of `O(sqrt n)`, which is about `O(10 ^ 6)` in the worst case. The modulo operator might be a bit slow, but it's worth giving it a try. Here's how it should look when done in C++:

``````int cntdiv = 0;
for(int i = 2; i * i <= x; i ++) {
if(x % i == 0) {
cntdiv += 1 + (i * i != x);
}
}
``````

First, do you mean find the total number of divisors, the number of primes in its factorization, or the number of distinct prime divisors? For instance, 12 = 2 * 2 * 3 has 6 divisors (1,2,3,4,6,12), 3 primes in its factorization (2,2,3), and 2 distinct prime divisors (2,3). Do you want 6, 3, or 2 as your result? I'm going to assume you want the second of these for the rest of this, but I don't think anything materially changes if you were interested in one of the others...

Second, you're going to have to fully factor your number. There is no known shortcut that can find the number of prime factors without finding the factors themselves. (With the notable exception that you can test whether the number of factors is ==1 or >=2 quickly.)

10^12 is not that big. You only need to test divisors up to the square root of the number, which is at most 10^6. Say a divide takes 20 cycles on a modern CPU at 2GHz, that's only 10 milliseconds to test a million divisors.

``````#include <stdio.h>
#include <stdlib.h>
int main(int argc, char *argv[]) {
long long n = atoll(argv[1]);
for (int i = 2; i < 1000000; i++) {
while (n % i == 0) { printf("%d\n", i); n /= i; }
}
if (n > 1) printf("%lld\n", n);
}
``````

Takes 23 milliseconds on my machine. Wonder where that other 13 milliseconds went?

Python is about 10x slower, as this code still takes only 0.23 seconds on my machine:

``````import sys
n = int(sys.argv[1])
for i in xrange(2, 1000000):
while n%i==0: print i; n/=i
if n>1: print n
``````

How fast do you want it?

• :I only want total number of divisors of a number(both prime and composite) – thedarkknight Sep 7 '12 at 19:37
• Then once you have the prime factorization, use stackoverflow.com/questions/110344/… to calculate the total number of divisors. – Keith Randall Sep 7 '12 at 20:29
• @keith Randall.....ok for example take n to be 99, then (99)^(1/2) gives 9 or 10(if u consider smallest integer function then calculate prime no.s upto 10 then what abt prime no. 11 which is also the factor of 99??? – Sumit Kumar Saha Sep 17 '13 at 17:31
• @SumitKumarSaha: If a number is not prime, it will have a factor less than or equal to the square root of the number. It is not guaranteed that all factors are <= the square root, but you don't need that. 99=11*3*3, so you'll find both factors of 3 by checking divisibility by 2..9. Compute 99/3/3=11 as the final prime factor (if it is not 1). – Keith Randall Sep 18 '13 at 15:27

I remember there is a solution based on sum of digits in a number and other features
As an example, 3411 is divisible by 9, because 3+4+1+1 = 9, sum of digits is divisible by 9, than a number is also divisible by 9. with other numbers rules are similar.

• That's just a math trick, and it only works for 9's. – Robert Harvey Sep 6 '12 at 23:37
• @RobertHarvey actually there are variants in different bases (such as 16 which is more convenient) and for different divisors. They don't work nearly as well as just taking the mod with that number and testing whether it's zero, though. – harold Sep 7 '12 at 9:19
• Such tricks work with 2,3,4,5,6,9 for sure – oleg.foreigner Sep 7 '12 at 20:04
• OK, come up with 78498 rules for me... (78498 = number of primes < 1000000) – Keith Randall Sep 7 '12 at 20:34