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So I have algorithms (easily searchable on the net) for prime factorization and divisor acquisition but I don't know how to scale it to finding those divisors within a range. For example all divisors of 100 between 23 and 49 (arbitrary). But also something efficient so I can scale this to big numbers in larger ranges. At first I was thinking of using an array that's the size of the range and then use all the primes <= the upper bound to sieve all the elements in that array to return an eventual list of divisors, but for large ranges this would be too memory intensive.

Is there a simple way to just directly generate the divisors?

closed as not a real question by Mitch Wheat, casperOne Mar 11 '13 at 11:59

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Let n[i] be the i-th factor of your number x, i < m. For any integer j greater than 1 and less than 2^m, then the product of all n[j[r]] where j[r] is the r-th bit of j is a divisor of x.

Consider 105. Its factors are [3, 5, 7]. So 3 factor, 2^3 is 8:

 0  000                = 1
 1  001              7 = 7
 2  010          5     = 5
 3  011          5 * 7 = 35
 4  100      3         = 3
 5  101      3   *   7 = 21
 6  110      3 * 5     = 15
 7  111      3 * 5 * 7 = 105

See? All possible divisors of 105 (0 and 7 are a little questionable).

  • Would you be able to explain this using an example? – KaliMa Mar 11 '13 at 0:13
  • Look at it now. – Malvolio Mar 11 '13 at 0:20
  • Note also that you do explicitly need duplicate factors. If you're getting the unique prime divisors (3,5) for 45, instead of (3,3,5) it wouldn't give you 9 as a possible divisor. – James Mar 11 '13 at 0:23
  • I am trying to find only the divisors within a range, though -- I already have methods for finding all divisors in general – KaliMa Mar 11 '13 at 0:24
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    The generation of duplicates for numbers which have some prime multiple times in their factorization is not very elegant. Also 3*7=21. This probably would be done better using recursion and a loop for the multiplicities of the primes. – G. Bach Mar 11 '13 at 0:27
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As Malvolio was (indirectly) going about, I personal wouldn't find a use for prime factorization if you want to find factors in a range, I would start at int t = (int)(sqrt(n)) and then decremnt until
1. t is a factor
2. Complete util t or t/n range has been REACHED(a flag) and then (both) has left the range

Or if your range is relatively small, check versus those values themselves.

  • Well, unless the number is really big (like, say, 2^32 * 3^32). Then I doubt you will want to use this approach. – nneonneo Mar 11 '13 at 0:57
  • Yeah, far easier to generate all 1089 numbers of the form 2^m * 3^n where n and m are less than or equal to 32. In Python: [ 2**n * 3**m for m in range(33) for n in range(33) ] – Malvolio Mar 14 '13 at 21:03
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If you know the factors of n, you can calculate the divisors of n --- those numbers, including 1 and n, that evenly divide n --- by taking the products of the powerset of the factors of n:

function divisors(n)
    divs := [1]
    for fact in factors(n)
        temp := []
        for div in divs
            if fact * div not in divs
                append fact * div to temp
        divs := divs + temp
    return divs

Once you have the complete list of divisors, you can select only those that are in the required range.

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