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What would be the most optimal algorithm (performance-wise) to calculate the number of divisors of a given number?

It'll be great if you could provide pseudocode or a link to some example.

EDIT: All the answers have been very helpful, thank you. I'm implementing the Sieve of Atkin and then I'm going to use something similar to what Jonathan Leffler indicated. The link posted by Justin Bozonier has further information on what I wanted.

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Given your reqs coming up with the number of factors is vague. I'm guessing you are looking for the number of non-unique prime divisors because if you didn't want that I code just write a program to always return 1 if the number to factor is one and 2 if it's anything else. 0 might need a change... –  Justin Bozonier Sep 21 '08 at 6:09
    
@sker: Is there a range of Values for which you need the divisors. There are many ways of calculating the factors, and each method is better suited to a particular range. –  Ande Oct 30 '08 at 10:53
1  
Here is a related interesting problem projecteuler.net/problem=12 –  daniloquio Jan 6 '12 at 20:10

22 Answers 22

up vote 51 down vote accepted

Dmitriy is right that you'll want the Sieve of Atkin to generate the prime list but I don't believe that takes care of the whole issue. Now that you have a list of primes you'll need to see how many of those primes act as a divisor (and how often).

Here's some python for the algo Look here and search for "Subject: math - need divisors algorithm". Just count the number of items in the list instead of returning them however.

Here's a Dr. Math that explains what exactly it is you need to do mathematically.

Essentially it boils down to if your number n is:
n = a^x * b^y * c^z
(where a, b, and c are n's prime divisors and x, y, and z are the number of times that divisor is repeated) then the total count for all of the divisors is:
(x + 1) * (y + 1) * (z + 1).

Edit: BTW, to find a,b,c,etc you'll want to do what amounts to a greedy algo if I'm understanding this correctly. Start with your largest prime divisor and multiply it by itself until a further multiplication would exceed the number n. Then move to the next lowest factor and times the previous prime ^ number of times it was multiplied by the current prime and keep multiplying by the prime until the next will exceed n... etc. Keep track of the number of times you multiply the divisors together and apply those numbers into the formula above.

Not 100% sure about my algo description but if that isn't it it's something similar .

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If you're factoring a large number, you don't even want to have to look at the prime list. You want to eliminate whole ranges of possibilities as quickly as possible! See my answer for more. –  user11318 Sep 21 '08 at 9:33
    
I realize this was 2 years ago, but your python algo link is broken, happen to know where it exists now? –  jb. Apr 1 '11 at 6:19
    
@jb Interwebz fail. I don't have it no. Sorry. :( –  Justin Bozonier Apr 1 '11 at 15:39
    
Look here and search for "Subject: math - need divisors algorithm" –  opyate Jul 16 '11 at 9:24

There are a lot more techniques to factoring than the sieve of Atkin. For example suppose we want to factor 5893. Well its sqrt is 76.76... Now we'll try to write 5893 as a product of squares. Well (77*77 - 5893) = 36 which is 6 squared, so 5893 = 77*77 - 6*6 = (77 + 6)(77-6) = 83*71. If that hadn't worked we'd have looked at whether 78*78 - 5893 was a perfect square. And so on. With this technique you can quickly test for factors near the square root of n much faster than by testing individual primes. If you combine this technique for ruling out large primes with a sieve, you will have a much better factoring method than with the sieve alone.

And this is just one of a large number of techniques that have been developed. This is a fairly simple one. It would take you a long time to learn, say, enough number theory to understand the factoring techniques based on elliptic curves. (I know they exist. I don't understand them.)

Therefore unless you are dealing with small integers, I wouldn't try to solve that problem myself. Instead I'd try to find a way to use something like the PARI library that already has a highly efficient solution implemented. With that I can factor a random 40 digit number like 124321342332143213122323434312213424231341 in about .05 seconds. (Its factorization, in case you wondered, is 29*439*1321*157907*284749*33843676813*4857795469949. I am quite confident that it didn't figure this out using the sieve of Atkin...)

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You're technique is very clever, but it doesn't tell me how many factors does the number have, does it? –  sker Sep 21 '08 at 18:09
15  
Once you have the prime factorization, figuring out how many factors there are is straightforward. Suppose the prime factors are p1, p2, ..., pk and they are repeated m1, m2, ..., mk times. Then there are (1+m1)(1+m2)...(1+mk) factors. –  user11318 Sep 21 '08 at 20:59
    
An interesting sieve is the quadratic sieve. This uses number theory - quadratic congruences, and some linear algebra. I learned enough to use it in a 2nd year number theory course at university. –  Tanner Nov 24 '12 at 4:28

I disagree that the sieve of Atkin is the way to go, because it could easily take longer to check every number in [1,n] for primality than it would to reduce the number by divisions.

Here's some code that, although slightly hackier, is generally much faster:

import operator
# A slightly efficient superset of primes.
def PrimesPlus():
  yield 2
  yield 3
  i = 5
  while True:
    yield i
    if i % 6 == 1:
      i += 2
    i += 2
# Returns a dict d with n = product p ^ d[p]
def GetPrimeDecomp(n):
  d = {}
  primes = PrimesPlus()
  for p in primes:
    while n % p == 0:
      n /= p
      d[p] = d.setdefault(p, 0) + 1
    if n == 1:
      return d
def NumberOfDivisors(n):
  d = GetPrimeDecomp(n)
  powers_plus = map(lambda x: x+1, d.values())
  return reduce(operator.mul, powers_plus, 1)

ps That's working python code to solve this problem.

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@Yasky

Your divisors function has a bug in that it does not work correctly for perfect squares.

Try:

int divisors(int x) {
    int limit = x;
    int numberOfDivisors = 0;

    for (int i(1); i < limit; ++i) {
        if (x % i == 0) {
            limit = x / i;
            if (limit != i) {
                numberOfDivisors++;
            }
            numberOfDivisors++;
        }
    }

    return numberOfDivisors;
}
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+1 You are right. I'll edit his answer. –  opyate Jul 16 '11 at 10:19
5  
Won't (x % i) cause a divide by zero when i = 0? should i = 1..limit ? –  rhu Jun 27 '12 at 21:03
    
Thanks for the feedback –  Yasky May 27 at 9:02
    
This is incredibly cleaver and simple, well done! –  Derek Aug 19 at 11:01

This interesting question is much harder than it looks, and it has not been answered. The question can be factored into 2 very different questions.

1 given N, find the list L of N's prime factors

2 given L, calculate number of unique combinations

All answers I see so far refer to #1 and fail to mention it is not tractable for enormous numbers. For moderately sized N, even 64-bit numbers, it is easy; for enormous N, the factoring problem can take "forever". Public key encryption depends on this.

Question #2 needs more discussion. If L contains only unique numbers, it is a simple calculation using the combination formula for choosing k objects from n items. Actually, you need to sum the results from applying the formula while varying k from 1 to sizeof(L). However, L will usually contain multiple occurrences of multiple primes. For example, L = {2,2,2,3,3,5} is the factorization of N = 360. Now this problem is quite difficult!

Restating #2, given collection C containing k items, such that item a has a' duplicates, and item b has b' duplicates, etc. how many unique combinations of 1 to k-1 items are there? For example, {2}, {2,2}, {2,2,2}, {2,3}, {2,2,3,3} must each occur once and only once if L = {2,2,2,3,3,5}. Each such unique sub-collection is a unique divisor of N by multiplying the items in the sub-collection.

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Here is a link to some pseudo code for a problem very similar to 2. answers.google.com/answers/threadview/id/392914.html –  mR_fr0g May 9 '11 at 20:25
1  
Question #2 has a well known solution. For a factorization of { p_i, k_i } where p_i is a prime factor of a number with k_i multiplicity, the total number of divisors of that number is (k_1+1)*(k_2+1)*...*(k_n+1). I guess you know this by now but I write this down for the benefit if a random reader here. –  Will Ness Sep 6 '12 at 16:20

An answer to your question depends greatly on the size of the integer. Methods for small numbers, e.g. less then 100 bit, and for numbers ~1000 bit (such as used in cryptography) are completely different.

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The sieve of Atkin is an optimized version of the sieve of Eratosthenes which gives all prime numbers up to a given integer. You should be able to google this for more detail.

Once you have that list, it's a simple matter to divide your number by each prime to see if it's an exact divisor (i.e., remainder is zero).

The basic steps calculating the divisors for a number (n) are [this is pseudocode converted from real code so I hope I haven't introduced errors]:

for z in 1..n:
    prime[z] = false
prime[2] = true;
prime[3] = true;

for x in 1..sqrt(n):
    xx = x * x

    for y in 1..sqrt(n):
        yy = y * y

        z = 4*xx+yy
        if (z <= n) and ((z mod 12 == 1) or (z mod 12 == 5)):
            prime[z] = not prime[z]

        z = z-xx
        if (z <= n) and (z mod 12 == 7):
            prime[z] = not prime[z]

        z = z-yy-yy
        if (z <= n) and (x > y) and (z mod 12 == 11):
            prime[z] = not prime[z]

for z in 5..sqrt(n):
    if prime[z]:
        zz = z*z
        x = zz
        while x <= limit:
            prime[x] = false
            x = x + zz

for z in 2,3,5..n:
    if prime[z]:
        if n modulo z == 0 then print z
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JUST one line
I have thought very carefuly about your question and I have tried to write a highly efficient and performant piece of code To print all divisors of a given number on screen we need just one line of code! (use option -std=c99 while compiling via gcc)

for(int i=1,n=9;((!(n%i)) && printf("%d is a divisor of %d\n",i,n)) || i<=(n/2);i++);//n is your number

for finding numbers of divisors you can use the following very very fast function(work correctly for all integer number except 1 and 2)

int number_of_divisors(int n)
{
    int counter,i;
    for(counter=0,i=1;(!(n%i) && (counter++)) || i<=(n/2);i++);
    return counter;
}

or if you treat given number as a divisor(work correctly for all integer number except 1 and 2)

int number_of_divisors(int n)
{
    int counter,i;
    for(counter=0,i=1;(!(n%i) && (counter++)) || i<=(n/2);i++);
    return ++counter;
}

NOTE:two above functions works correctly for all positive integer number except number 1 and 2 so it is functional for all numbers that are greater than 2 but if you Need to cover 1 and 2 , you can use one of the following functions( a little slower)

int number_of_divisors(int n)
{
    int counter,i;
    for(counter=0,i=1;(!(n%i) && (counter++)) || i<=(n/2);i++);
    if (n==2 || n==1)
    {
    return counter;
    }
    return ++counter;
}

OR

int number_of_divisors(int n)
{
    int counter,i;
for(counter=0,i=1;(!(i==n) && !(n%i) && (counter++)) || i<=(n/2);i++);
    return ++counter;
}

small is beautiful :)

I have also explained the above codes in Persian at the link below http://cnevis.com/?p=196

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You might try this one. It's a bit hackish, but it's reasonably fast.

def factors(n):
    for x in xrange(2,n):
        if n%x == 0:
            return (x,) + factors(n/x)
    return (n,1)
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Once you have the prime factorization, there is a way to find the number of divisors. Add one to each of the exponents on each individual factor and then multiply the exponents together.

For example: 36 Prime Factorization: 2^2*3^2 Divisors: 1, 2, 3, 4, 6, 9, 12, 18, 36 Number of Divisors: 9

Add one to each exponent 2^3*3^3 Multiply exponents: 3*3 = 9

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Divisors do something spectacular: they divide completely. If you want to check the number of divisors for a number, n, it clearly is redundant to span the whole spectrum, 1...n. I have not done any in-depth research for this but I solved Project Euler's problem 12 on Triangular Numbers. My solution for the greater then 500 divisors test ran for 309504 microseconds (~0.3s). I wrote this divisor function for the solution.

int divisors (int x) {
    int limit = x;
    int numberOfDivisors = 1;

    for (int i(0); i < limit; ++i) {
        if (x % i == 0) {
            limit = x / i;
            numberOfDivisors++;
        }
    }

    return numberOfDivisors * 2;
}

To every algorithm, there is a weak point. I thought this was weak against prime numbers. But since triangular numbers are not print, it served its purpose flawlessly. From my profiling, I think it did pretty well.

Happy Holidays.

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You'd have a divide by 0 on the first iteration here –  barfoon Aug 19 '11 at 16:31
    
unfortunately not. the ++i is different from i++ (which would result in a divide-by-zero error) –  Yasky Sep 23 '11 at 8:53
    
I wrote your function in PHP and ran it - here's what I got - i.minus.com/iKzuSXesAkpbp.png –  barfoon Sep 23 '11 at 14:48
    
for some weird reason, this worked flawlessly for me. oh well, my bad. start numberOfDivisors and the iterator at 1; this should get rid of the divide by zero error –  Yasky Oct 21 '11 at 10:57
    
Your algorithm doesn't work for perfect squares. For example, it returns 4 for the input x = 4, because it is counting 2 twice...1, 2, 2, 4. Answer should be 3: 1,2,4 –  Michael Jan 24 '12 at 18:48

Before you commit to a solution consider that the Sieve approach might not be a good answer in the typical case.

A while back there was a prime question and I did a time test--for 32-bit integers at least determining if it was prime was slower than brute force. There are two factors going on:

1) While a human takes a while to do a division they are very quick on the computer--similar to the cost of looking up the answer.

2) If you do not have a prime table you can make a loop that runs entirely in the L1 cache. This makes it faster.

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You want the Sieve of Atkin, described here: http://en.wikipedia.org/wiki/Sieve_of_Atkin

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1  
That's going to get you the primes below your given number - but there's not guarantee that those primes are going to be divisors? (unless I'm missing something) –  Andrew Edgecombe Sep 21 '08 at 6:05
    
It's a quick leap from here to finding all primes < sqrt(N) that evenly divide N. –  SquareCog Sep 21 '08 at 6:17
    
It may be a quick leap, but testing all primes < sqrt(N) is still a bad factoring technique no matter how efficiently you find them. There are a lot of ways to improve that. –  user11318 Sep 21 '08 at 8:49
    
Testing the primes is O(N), it's finding the primes that's the hard part. But with even with the unoptimised sieve of eratosthenes, you can still find all primes under a few million in under a second. That covers any 64b number, and I'm sure we're not talking about factoring crypto level stuff here –  Matthew Scharley Oct 6 '08 at 8:00

the prime number method is very clear here . P[] is a list of prime number less than or equal the sq = sqrt(n) ;

for (int i = 0 ; i < size && P[i]<=sq ; i++){
          nd = 1;
          while(n%P[i]==0){
               n/=P[i];
               nd++;
               }
          count*=nd;
          if (n==1)break;
          }
      if (n!=1)count*=2;//the confusing line :D :P .

     i will lift the understanding for the reader  .
     i now look forward to a method more optimized  .
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Here is a straight forward O(sqrt(n)) algorithm. I used this to solve project euler

def divisors(n):
    count=2 # accounts for 'n' and '1'
    i=2
    while(i**2 <= n):
        if(n%i==0):
            count+=2
        i+=1
    return count  
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Number theory textbooks call the divisor-counting function tau. The first interesting fact is that it's multiplicative, ie. τ(ab) = τ(a)τ(b) , when a and b have no common factor. (Proof: each pair of divisors of a and b gives a distinct divisor of ab).

Now note that for p a prime, τ(p**k) = k+1 (the powers of p). Thus you can easily compute τ(n) from its factorisation.

However factorising large numbers can be slow (the security of RSA crytopraphy depends on the product of two large primes being hard to factorise). That suggests this optimised algorithm

  1. Test if the number is prime (fast)
  2. If so, return 2
  3. Otherwise, factorise the number (slow if multiple large prime factors)
  4. Compute τ(n) from the factorisation
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The following is a C program to find the number of divisors of a given number.

The complexity of the above algorithm is O(sqrt(n)).

This algorithm will work correctly for the number which are perfect square as well as the numbers which are not perfect square.

Note that the upperlimit of the loop is set to the square-root of number to have the algorithm most efficient.

Note that storing the upperlimit in a separate variable also saves the time, you should not call the sqrt function in the condition section of the for loop, this also saves your computational time.

#include<stdio.h>
#include<math.h>
int main()
{
    int i,n,limit,numberOfDivisors=1;
    printf("Enter the number : ");
    scanf("%d",&n);
    limit=(int)sqrt((double)n);
    for(i=2;i<=limit;i++)
        if(n%i==0)
        {
            if(i!=n/i)
                numberOfDivisors+=2;
            else
                numberOfDivisors++;
        }
    printf("%d\n",numberOfDivisors);
    return 0;
}

Instead of the above for loop you can also use the following loop which is even more efficient as this removes the need to find the square-root of the number.

for(i=2;i*i<=n;i++)
{
    ...
}
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Here is a function that I wrote. it's worst time complexity is O(sqrt(n)),best time on the other hand is O(log(n)). It gives you all the prime divisors along with the number of its occurence.

public static List<Integer> divisors(n) {   
    ArrayList<Integer> aList = new ArrayList();
    int top_count = (int) Math.round(Math.sqrt(n));
    int new_n = n;

    for (int i = 2; i <= top_count; i++) {
        if (new_n == (new_n / i) * i) {
            aList.add(i);
            new_n = new_n / i;
            top_count = (int) Math.round(Math.sqrt(new_n));
            i = 1;
        }
    }
    aList.add(new_n);
    return aList;
}
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This is an efficient solution:

#include <iostream>
int main() {
  int num = 20; 
  int numberOfDivisors = 1;

  for (int i = 2; i <= num; i++)
  {
    int exponent = 0;
    while (num % i == 0) {
        exponent++; 
        num /= i;
    }   
    numberOfDivisors *= (exponent+1);
  }

  std::cout << numberOfDivisors << std::endl;
  return 0;
}
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This is the most basic way of computing the number divissors:

class PrintDivisors
{
    public static void main(String args[])
    {

    System.out.println("Enter the number");

    // Create Scanner object for taking input
    Scanner s=new Scanner(System.in);

    // Read an int
    int n=s.nextInt();

        // Loop from 1 to 'n'
        for(int i=1;i<=n;i++)
        {

            // If remainder is 0 when 'n' is divided by 'i',
            if(n%i==0)
            {
            System.out.print(i+", ");
            }
        }

    // Print [not necessary]    
    System.out.print("are divisors of "+n);

    }
}
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Isn't this just a question of factoring the number - determining all the factors of the number? You can then decide whether you need all combinations of one or more factors.

So, one possible algorithm would be:

factor(N)
    divisor = first_prime
    list_of_factors = { 1 }
    while (N > 1)
        while (N % divisor == 0)
            add divisor to list_of_factors
            N /= divisor
        divisor = next_prime
    return list_of_factors

It is then up to you to combine the factors to determine the rest of the answer.

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I don't know the MOST efficient method, but I'd do the following:

  • Create a table of primes to find all primes less than or equal to the square root of the number (Personally, I'd use the Sieve of Atkin)
  • Count all primes less than or equal to the square root of the number and multiply that by two. If the square root of the number is an integer, then subtract one from the count variable.

Should work \o/

If you need, I can code something up tomorrow in C to demonstrate.

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1  
I'm confused. Counting all the primes less than the square root of a number will not give you it's divisors... not every prime less than the square root of a number will be a divisor for that number. –  Garrett Berg Aug 2 '11 at 18:09

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