# Can you help me optimize this code for finding factors of a number? I'm brushing up on my math programming

I've never really bothered with math programming, but today I've decided to give it a shot.

Here's my code and it's working as intended:

``````using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Windows;
using System.Windows.Controls;
using System.Windows.Data;
using System.Windows.Documents;
using System.Windows.Input;
using System.Windows.Media;
using System.Windows.Media.Imaging;
using System.Windows.Shapes;

namespace PrimeFactorization
{
/// <summary>
/// Interaction logic for MainWindow.xaml
/// </summary>
public partial class MainWindow : Window
{
public MainWindow()
{
InitializeComponent();
}

private void btnSubmit_Click(object sender, RoutedEventArgs e)
{
List<int> primeFactors = FindPrimeFactors(Convert.ToInt32(txtNumber.Text));
primeFactors.Sort();
for (int i = 0; i < primeFactors.Count; i++)
{
}
}

private List<int> FindPrimeFactors(int number)
{
List<int> factors = new List<int>();

for (int i = 2; i < number; i++)
{

if (number % i == 0)
{
int holder = number / i;
//If the number is in the list, don't add it again.
if (!factors.Contains(i))
{
}
//If the number is in the list, don't add it again.
if (!factors.Contains(holder))
{
}
}
}

return factors;
}
}
}
``````

The only problem I can see with my code is that it will iterate through to the bitter end, even though there will definitely not be any factors.

For example, imagine I wrote in 35. My loop will go up to 35 and check 24,25,26,27...etc. Not very good.

What do you recommend?

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First of all you just need to iterate until sqrt(number)+1 –  tur1ng Mar 13 '10 at 15:30
How so? Is that a mathematical truth? Remember I'm a really new to math programming and hell, even math rules like this one. –  delete Mar 13 '10 at 15:32
That is a partial answer to a more complex solution, but if just changes his upper bound to sqrt(n) then he will get incorrect results. –  danben Mar 13 '10 at 15:33
tur1ng: Not true. For example, when n=104, sqrt(n)+1 = 11.2, but 13 is a prime factor. –  Ken Mar 13 '10 at 15:54
@Ken: true, because the OTHER factor of 104 / 13 is 8, and that certainly is below sqrt(104)+1. That's why that rule works. –  james Mar 13 '10 at 16:06
show 1 more comment

One thing you can do is avoid checking even numbers after 2, since they will never be prime.

So, check 2 and then declare your loop as such:

``````for (int i = 3; i < number; i+=2)
``````

Re: stopping at `sqrt(n)` - this is an effective technique for determining whether a given number is prime, since any `n` that divides `x` where `x > sqrt(n)` also divides `n/x` which is necessarily less than `sqrt(n)`. But a number may have prime factors larger than its own square root (for example, 1002 = 2 * 3 * 167).

That said, you could implement some kind of recursive solution where, for all prime factors `p` of `n` such that `p < sqrt(n)`, you also calculate the prime factors of `n / p`. My gut feeling is that this will decrease the running time of your algorithm in general, but might increase it for small values of `n`.

Edit: if you're interested in getting into more sophisticated techniques, the Wikipedia page on Integer Factorization links to all kinds of algorithms.

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I'm not sure if he's just looking for prime factors. He seems to want all factors of a number. –  ntownsend Mar 13 '10 at 15:38
My plan was to first find all factors, then just prime. This is a great answer. :) –  delete Mar 13 '10 at 15:40
Really? Everything in the code suggests otherwise. See: `namespace PrimeFactorization`; `List<int> primeFactors`, etc. –  danben Mar 13 '10 at 15:40
@Sergio Tapia: Ah ok, that explains it. –  danben Mar 13 '10 at 15:40
My mistake. I only skimmed over the code and missed that. –  ntownsend Mar 13 '10 at 15:43

One classic algorithm for finding prime factors is the Sieve of Eratosthenes (see this)

-

You can go only up to and including `sqrt(number)`. Consider `x` from `2` to `sqrt(N)`. if `N % x == 0`, then `N % (N / x) == 0` as well. Take `10` for example:

`sqrt(10) = 3 (integer part).`

`10 % 2 == 0 => 2 is a divisor of 10. 10 % (10 / 2) == 10 % 5 == 0 => 5 is also a divisor.`

`10 % 3 != 0.`

This is it, the divisors of 10 are 2 and 5. You have to be careful when dealing with perfect squares and that is it.

You also don't need your checks to see if a number is in the list or not if you do it like this. Just make sure you don't add the same number twice in case of perfect squares (if x == N / x, only add x).

This is about as efficient as it gets without considering a lot more complicated algorithms.

Edit: To get PRIME factors only, when you find an `x` such that `N % x == 0`, divide `N` by `x` while this is possible. For example, consider 20:

`sqrt(20)` = 4.

`20 % 2 == 0` => 2 is a prime factor. Divide it by 2 until the remainder of the division by 2 is no longer 0: `20 / 2 = 10, 10 / 2 = 5`.

`5 % 3 != 0`

`5 % 4 != 0`

The number you are left with at the end of the algorithm is `5 > 1`, so add 5 as well. The prime factors of 20 are therefore 2 and 5.

So basically your algorithm in pseudocode is this:

``````listPrimes(number)
N = number;
for ( i = 2; i <= (int)sqrt(number); ++i )
if ( N % i == 0 )
while ( N % i == 0 )
N /= i;

if ( N > 1 )
``````

You can also use what @danben has suggested in his post, using increments of 2 and starting from 3 and treating 2 separately. The most efficient however is to generate primes using the sieve of Eratosthenes and using those generated primes in combination with this algorithm. Most efficient while staying in the world of basic math anyway.

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That works nicely for a small input like 10 where pretty much everything smaller than it is prime, but for 1000 your algorithm would add 500 as a prime factor. –  danben Mar 13 '10 at 15:38
Oh, sorry, I missed the prime factors part. This can still work though, I'll edit in a few seconds. –  IVlad Mar 13 '10 at 15:39
I think you might be approaching what I have already written up so please read that first, but if you have something new then by all means post it. –  danben Mar 13 '10 at 15:42

First order of business is to use a proper prime-generating algorithm. Most common is the Sieve of Eratosthenes, which I'll post because it's easier, but there's also the Sieve of Atkin which is far more optimized.

I'd use something like this for the sieve, which I've posted before:

``````public class Primes
{
public static IEnumerable<int> To(int maxValue)
{
if (maxValue < 2)
return Enumerable.Empty<int>();

bool[] primes = new bool[maxValue + 1];
for (int i = 2; i <= maxValue; i++)
primes[i] = true;

for (int i = 2; i < Math.Sqrt(maxValue + 1) + 1; i++)
{
if (primes[i])
{
for (int j = i * i; j <= maxValue; j += i)
primes[j] = false;
}
}

return Enumerable.Range(2, maxValue - 1).Where(i => primes[i]);
}
}
``````

The last step is just to find out which primes are factors, which is easy:

``````public static IEnumerable<int> GetPrimeFactors(int num)
{
return Primes.To(num).Where(i => num % i == 0);
}
``````

That's it! This will generate prime factors up to 20 million in less than 1 second, so it's probably good enough for whatever you're doing. Otherwise you can use a better sieve, as I mentioned at the top, or a lazy skip-set algorithm.

One last thing: If you're trying to factor huge numbers then you need to switch to something very different, such as the General Number Field Sieve. This is (as far as I know) currently the fastest factorization algorithm for very large numbers, as part of ongoing research to see if RSA encryption can be cracked.

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You can optimize your sieve further by starting `j` from `i * i` not `2 * i` and ignoring multiples of 2. And isn't this checking all the primes up to `num`? –  IVlad Mar 13 '10 at 16:05
@IVlad: Good point about starting from `i*i` (although in practice the improvement is very marginal, about 1% of the running time). The "multiples of 2" optimization is silly because the sieve already eliminates those on the first step. Why not also ignore multiples of 3, and 5, and 7? These don't actually decrease the order of the algorithm, and not attempting to make such optimizations was very intentional. –  Aaronaught Mar 13 '10 at 16:09
@Aaronaught: no, it isn't silly. Your `i` variable gets incremented by `1` at each step. You can start it from `3` and increment it by `2` at each step, resulting in half the number of incrementations of `i`. A prime number different than `2` is never even, but an odd number might be, so ignoring multiples of `2` is the easiest. You can also use half the memory by ignoring indexes of even numbers in your `primes` array. so `primes[i] = true` if `2*i-1` is prime. The order of the algorithm remains unchanged, but these optimizations can matter a lot in practice. Also: `i * i <= sqrt(maxValue)`. –  IVlad Mar 13 '10 at 16:13
I will definitely look into your solution because if I'm not mistaken you're using Lambdas correct? That's something I've always wanted to look into. Thank you! –  delete Mar 13 '10 at 16:35
@IVlad: The "optimizations" you're talking about are exactly what the sieve does! Incrementing the counter isn't the bottleneck here, crossing out multiples is, and if the index is already known to be composite then it will just get skipped. "Optimizing" for the case of 2 accomplishes precisely nothing. Profile it and see. It's not only silly, it's harmful, it needlessly complicates the algorithm for no tangible benefit. I actually have a profiler right in front of me and can tell you that it barely has any impact on the running time. Please don't make unsupported claims like this. –  Aaronaught Mar 13 '10 at 17:14
If you want to find all factors (not just prime), once you find a smallest factor, `k`, you can update your loop's upper bound to only go up to (and including) `n/k`. This is because the largest factor `l` must satisfy `p = k * l`.
An even better approach may be to use the factors that you've found so far to calculate the factors greater than `sqrt(n)`. So, in the above, you could calculate `l` directly from `k` and `n`.
`n/k` will have a lower bound of `sqrt(n)`, so it is more efficient to always stop at `sqrt(n)` (as noted in other answers). –  danben Mar 13 '10 at 15:46