# Get all factors of a number (iterators showdown :)

You are given all the prime factors of a number, along with their multiplicities (highest powers).
The requirment is to produce all the factors of that number.

Let me give an example:

Prime factors:

• 2 (power: 3)
• 3 (power: 1)

(meaning the number is 2^3 * 3^1 = 24)

The expected result is:
1, 2, 3, 4, 6, 8, 12, 24

I'm thinking of doing this (in C#) with some chained custom iterators, one for each prime factor, that would count from 0 to the power of that prime number.

How would you implement this? Use your preferred language.

This is related to problem #23 from Project Euler

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I don't know how fond the Project Euler administrators are of SO exposing solutions to their problems. See stackoverflow.com/questions/1010739/… . –  anderstornvig Jul 7 '09 at 10:03
In this case I think it is ok, because the question asks for a standard algorithm, not for the solution of the problem. Also, the problem is still rather easy, and this is not the best approach. –  starblue Jul 7 '09 at 10:56
+1, this is not the Project Euler problem at all. This question is a very general one, and certainly a "real" programming question. (Referring to the two votes for closing it as "not a real question".) –  ShreevatsaR Jul 7 '09 at 19:12

Consider all possible combinations of powers. For each combination, raise the primes to their corresponding power, and multiply the result.

>>> from functools import reduce
>>> from itertools import product, starmap
>>> from operator import mul
>>>
>>> def factors(prime_factors):
...     primes, powers = zip(*prime_factors)
...     power_combos = product(*(range(p + 1) for p in powers))
...     prime_combos = (zip(primes, c) for c in power_combos)
...     return (reduce(mul, starmap(pow, c)) for c in prime_combos)
...
>>> sorted(factors([(2, 3), (3, 1)]))
[1, 2, 3, 4, 6, 8, 12, 24]


This code uses Python 3.0. Aside from the call to sorted, it makes use of iterators exclusively.

Side remark: too bad this question seems to be rather unpopular. I would like to see e.g. some functional solutions being posted. (I may attempt to write a Haskell solution later.)

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cartesianWith f xs = concatMap $\y -> map (f y) xs factorsOfPrimeFactorization = foldl (cartesianWith (*)) [1] . map (\(p, e) -> map (p^) [0..e])  > factorsOfPrimeFactorization [(2, 3), (3, 1)] [1,2,4,8,3,6,12,24]  To sort the result, import Data.List cartesianWith f xs = concatMap$ \y -> map (f y) xs
factorsOfPrimeFactorization =
sort . foldl (cartesianWith (*)) [1] . map (\(p, e) -> map (p^) [0..e])


Perl.

sub factors {
my %factorization = @_;
my @results = (1);
while (my ($p,$e) = each %factorization) {
@results = map {my $i =$_; map $i*$_, @results} map $p**$_, 0..$e; } sort {$a <=> $b} @results; } print join($,, factors(2, 3, 3, 1)), \$/;  # => 1 2 3 4 6 8 12 24


J.

   /:~~.,*/"1/{:@({.^i.@{:@>:)"1 ] 2 3 ,: 3 1
1 2 3 4 6 8 12 24


These all implement the same algorithm, which is to generate the list p0,p1,…,pe for each pair (p,e) in the factorization, and take the product of each set in the Cartesian product across all those lists.

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I should note that none of these languages really have a concept of "iterators"... (well, you can make tied arrays in Perl, but that's a pain). However, due to Haskell's laziness, normal lists are like iterators in other languages, but much easier to use. –  ephemient Jul 7 '09 at 19:26

If you do not care about the single divisors, but about the sum of all divisors of n you might want to have a look at the Divisor Function:

Thus the sum of the divisors of

is

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texify.com typeset for you. –  ephemient Jul 8 '09 at 16:31
This answer relates more to the actual PE problem than to my question; however, this is a great insight! +1 Like the texify.com tip as well - is this yours? –  Cristi Diaconescu Jul 12 '09 at 10:55

I first shoot without an IDE at hand so there might be some errors in there.

struct PrimePower
{
public PrimePower(Int32 prime, Int32 power) : this()
{
this.Prime = prime;
this.Power = power;
}

public Int32 Prime { get; private set; }
public Int32 Power { get; private set; }
}


And then just this recursive function.

public IEnumerable<Int32> GetFactors(IList<PrimePowers> primePowers, Int32 index)
{
if (index < primePowers.Length() - 1)
{
Int32 factor = 1;
for (Int32 p = 0; p <= primePowers[index].Power; p++)
{
yield return factor * GetFactors(primePowers, index + 1);
factor *= primePowers[index].Prime;
}
}
else if (index = primePowers.Length() - 1)
{
Int32 factor = 1;
for (Int32 p = 0; p <= primePowers[index].Power; p++)
{
yield return factor * GetFactors(primePowers, index + 1);
factor *= primePowers[index].Prime;
}
}
else
{
throw new ArgumentOutOfRangeException("index");
}
}


It could also be an extension method and IList<PrimerPower> could probably weakened to IEnumerable<PrimePower> with a few Skip() and Take() calls. I don't like passing the index around, too, but the alternative would be copying the prime power list for each call. In consequence I think a iterative solution would be preferable - going to add one if I have an IDE again.

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Very easy to do. In fact, I wrote an article on my blog about this very thing. Check out this code.

#Application lists all factors/divisors for a number.
targetNumber=input('What number do you want the factors for?\n> ')
factors=[]
for i in range(1,targetNumber):
if targetNumber%i==0:
factors.append(i)
elif targetNumber/i==1:
factors.append(targetNumber)
break
print factors