# Prime factor of 300 000 000 000?

I need to find out the prime factors of over 300 billion. I have a function that is adding to the list of them...very slowly! It has been running for about an hour now and i think its got a fair distance to go still. Am i doing it completly wrong or is this expected?

Edit: Im trying to find the largest prime factor of the number 600851475143.

Edit: Result:

{
List<Int64> ListOfPrimeFactors = new List<Int64>();
Int64 Number = 600851475143;
Int64 DividingNumber = 2;

while (DividingNumber < Number / DividingNumber)
{
if (Number % DividingNumber == 0)
{
Number = Number/DividingNumber;
}
else
DividingNumber++;
}
listBox1.DataSource = ListOfPrimeFactors;
}
}
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Please clarify with proper language what is the precise problem you are trying to solve. What you explain could have at least five or six possible meanings. Also, do you have any sort of upper bound? 10^40000000000 is "over 300 billion" and might indeed take hours... :) –  Daniel Daranas Jan 13 '09 at 17:12
Do you really mean that you're trying to find the prime numbers over 300 000 000 000? (as a prime factor is something else entirely) –  Rowland Shaw Jan 13 '09 at 17:14
Are you trying to solve project Euler's problem 3 ? –  Perpetualcoder Jan 13 '09 at 17:14
is this a homework assignment? –  Anthony Potts Jan 13 '09 at 17:17
(1) Read and fully understand en.wikipedia.org/wiki/Prime_number (2) Read and fully understand en.wikipedia.org/wiki/Prime_factor (3) Read and fully understand en.wikipedia.org/wiki/Integer_factorization (4) Start thinking about algorithms (5) Choose one and code it –  Daniel Daranas Jan 14 '09 at 9:37

Are you remembering to divide the number that you're factorizing by each factor as you find them?

Say, for example, you find that 2 is a factor. You can add that to your list of factors, but then you divide the number that you're trying to factorise by that value.

Now you're only searching for the factors of 150 billion. Each time around you should start from the factor you just found. So if 2 was a factor, test 2 again. If the next factor you find is 3, there's no point testing from 2 again.

And so on...

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No... erm explain please =] –  xoxo Jan 13 '09 at 17:05
Ohh ok i get it! Thanks alot! –  xoxo Jan 13 '09 at 17:14
Look into researching recursion. –  EBGreen Jan 13 '09 at 17:15
Recursion for prime factoring? –  Eclipse Jan 13 '09 at 17:16
The process is recursive, but I wouldn't implement it as a recursive function or you'll get... a stackoverflow ;) Use iteration. –  Dave Swersky Jan 13 '09 at 17:40

Finding prime factors is difficult using brute force, which sounds like the technique you are using.

Here are a few tips to speed it up somewhat:

• Start low, not high
• Don't bother testing each potential factor to see whether it is prime--just test LIKELY prime numbers (odd numbers that end in 1,3,7 or 9)
• Don't bother testing even numbers (all divisible by 2), or odds that end in 5 (all divisible by 5). Of course, don't actually skip 2 and 5!!
• When you find a prime factor, make sure to divide it out--don't continue to use your massive original number. See my example below.
• If you find a factor, make sure to test it AGAIN to see if it is in there multiple times. Your number could be 2x2x3x7x7x7x31 or something like that.
• Stop when you reach >= sqrt(remaining large number)

Edit: A simple example: You are finding the factors of 275.

1. Test 275 for divisibility by 2. Does 275/2 = int(275/2)? No. Failed.
2. Test 275 for divisibility by 3. Failed.
3. Skip 4!
4. Test 275 for divisibility by 5. YES! 275/5 = 55. So your NEW test number is now 55.
5. Test 55 for divisibility by 5. YES! 55/5 = 11. So your NEW test number is now 11.
6. BUT 5 > sqrt (11), so 11 is prime, and you can stop!

So 275 = 5 * 5 * 11

Make more sense?

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What do you mean 'divide it out'? And im not sure how the square root affects it? –  xoxo Jan 13 '09 at 17:13
If you haven't found a factor by the sqrt of a number, you're not going to find any no matter how far you go. This makes a HUGE difference when checking larger numbers. –  Eclipse Jan 13 '09 at 17:15
Why do you say "at least all odd numbers ending in 1,3,7 or 9"? –  PEZ Jan 13 '09 at 18:54
You do have to balance that waste with the effort needed to skip every 5th number. You'd probably get more benefit by skipping every 3rd odd number after 3. Note that from the computers point of view, there's nothing special about numbers that end in 5 in decimal. –  Eclipse Jan 13 '09 at 20:04
@Grace, to your latter question, yes, I think so. There are two issues here: "programming" and "solving a real world problem". In your case the real world problem is "prime number" and the very first thing you should do is study the theory about them. Then think about algorithms. –  Daniel Daranas Jan 14 '09 at 9:29

Factoring big numbers is a hard problem. So hard, in fact, that we rely on it to keep RSA secure. But take a look at the wikipedia page for some pointers to algorithms that can help. But for a number that small, it really shouldn't be taking that long, unless you are re-doing work over and over again that you don't have to somewhere.

For the brute-force solution, remember that you can do some mini-optimizations:

• Check 2 specially, then only check odd numbers.
• You only ever need to check up to the square-root of the number (if you find no factors by then, then the number is prime).
• Once you find a factor, don't use the original number to find the next factor, divide it by the found factor, and search the new smaller number.
• When you find a factor, divide it through as many times as you can. After that, you never need to check that number, or any smaller numbers again.
• If you do all the above, each new factor you find will be prime, since any smaller factors have already been removed.
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The number in the question is neither large nor hard to factor. –  Sam Meldrum Jan 13 '09 at 17:12
When we say factoring big numbers is hard, we mean numbers above approximately 2^512. RSA and similar probably use primes up around 2^2048. The number in the OP is only about 2^39... much, much smaller –  abelenky Jan 14 '09 at 0:47

Here is an XSLT solution!

This XSLT transformation takes 0.109 sec.

<xsl:stylesheet version="2.0"
xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
xmlns:xs="http://www.w3.org/2001/XMLSchema"
xmlns:saxon="http://saxon.sf.net/"
xmlns:f="http://fxsl.sf.net/"
exclude-result-prefixes="xs saxon f"
>
<xsl:import href="../f/func-Primes.xsl"/>

<xsl:output method="text"/>

<xsl:template name="initial" match="/*">
<xsl:sequence select="f:maxPrimeFactor(600851475143)"/>
</xsl:template>

<xsl:function name="f:maxPrimeFactor" as="xs:integer">
<xsl:param name="pNum" as="xs:integer"/>

<xsl:sequence select=
"if(f:isPrime(\$pNum))
then \$pNum
else
for \$vEnd in xs:integer(floor(f:sqrt(\$pNum, 0.1E0))),
\$vDiv1 in (2 to \$vEnd)[\$pNum mod . = 0][1],
\$vDiv2 in \$pNum idiv \$vDiv1
return
max((f:maxPrimeFactor(\$vDiv1),f:maxPrimeFactor(\$vDiv2)))
"/>
</xsl:function>
</xsl:stylesheet>

This transformation produces the correct result (the maximum prime factor of 600851475143) in just 0.109 sec.:

6857

The transformation uses the f:sqrt() and f:isPrime() defined in FXSL 2.0 -- a library for functional programming in XSLT. FXSL is itself written entirely in XSLT.

f:isPrime() uses Fermat's little theorem so that it is efficient to determine primeality.

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Way neat! Too bad the problem 3 forum is closed so you can't post this there. I don't think I've seen an XSLT solution there. –  PEZ Jan 15 '09 at 13:56
@PEZ: What is the problem 3 forum? –  Dimitre Novatchev Jan 15 '09 at 13:59
Problem 3 at Project Euler (projecteuler.net/index.php?section=problems&id=3). When you register at that site you get an answer box there and if you submit the correct one (which you obviously will) you'll get access to a forum where people have discussed the problem and their solutions. –  PEZ Jan 15 '09 at 15:00
Though the problem was presented long ago so the forum is "full" and they have closed it for new entries. –  PEZ Jan 15 '09 at 15:01
@PEZ: Thank you for mentioninh ProjectEuler. I already solved 28 problems and the only programming language I used has been XSLT. –  Dimitre Novatchev Jan 23 '09 at 3:47

One last thing nobody has mentioned, perhaps because it seems obvious. Every time you find a factor and divide it out, keep trying the factor until it fails.

64 only has one prime factor, 2. You will find that out pretty trivially if you keep dividing out the 2 until you can't anymore.

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\$ time factor 300000000000 > /dev/null

real        0m0.027s
user        0m0.000s
sys         0m0.001s

You're doing something wrong if it's taking an hour. You might even have an infinite loop somewhere - make sure you're not using 32-bit ints.

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The key to understanding why the square root is important, consider that each factor of n below the square root of n has a corresponding factor above it. To see this, consider that if x is factor of n, then x/n = m which means that x/m = n, hence m is also a factor.

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I wouldn't expect it to take very long at all - that's not a particularly large number.

Could you give us an example number which is causing your code difficulties?

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600851475143. i cut it in half (thats what i thought i remembered from school) to make it 300425737571. I get rid of the numbers divisible by 2, 3, 5 and 7. Then i get rid of any numbers that cannot be divided into the number and find any primes left... –  xoxo Jan 13 '09 at 17:12
"600851475143. i cut it in half (thats what i thought i remembered from school) to make it 300425737571." Sorry???? If you don't know the basic semantics of the problem, you shouldn't even try. –  Daniel Daranas Jan 13 '09 at 17:17
No Daniel, thanks but i think ill give this one a go! –  xoxo Jan 13 '09 at 17:18
600851475143 and 300425737571 each have four distinct prime factors. They share none in common. @Daniel Daranas is suggesting that you understand why "cutting [an odd number] in half" doesn't work. For example, you may try the same with 27, which "cuts" to 13 but shares no factors with 13. –  A. Rex Jan 14 '09 at 9:00
@A. Rex thank you for your clarification. Yes, what I was saying is basically that you can "try" any approaches, but it helps if they are mathematically correct. Dividing the number by 7.65 and then taking its logarithm certainly won't help. –  Daniel Daranas Jan 14 '09 at 9:22

Here's one site where you can get answers: Factoris - Online factorization service. It can do really big numbers, but it also can factorize algebraic expressions.

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The fastest algorithms are sieve algorithms, and are based on arcane areas of discrete mathematics (over my head at least), complicated to implement and test.

The simplest algorithm for factoring is probably (as others have said) the Sieve of Eratosthenes. Things to remember about using this to factor a number N:

• general idea: you're checking an increasing sequence of possible integer factors x to see if they evenly divide your candidate number N (in C/Java/Javascript check whether N % x == 0) in which case N is not prime.
• you just need to go up to sqrt(N), but don't actually calculate sqrt(N): loop as long as your test factor x passes the test x*x<N
• if you have the memory to save a bunch of previous primes, use only those as the test factors (and don't save them if prime P fails the test P*P > N_max since you'll never use them again
• Even if you don't save the previous primes, for possible factors x just check 2 and all the odd numbers. Yes, it will take longer, but not that much longer for reasonable sized numbers. The prime-counting function and its approximations can tell you what fraction of numbers are prime; this fraction decreases very slowly. Even for 264 = approx 1.8x1019, roughly one out of every 43 numbers is prime (= one out of every 21.5 odd numbers is prime). For factors of numbers less than 264, those factors x are less than 232 where about one out of every 20 numbers is prime = one out of every 10 odd numbers is prime. So you'll have to test 10 times as many numbers, but the loop should be a bit faster and you don't have to mess around with storing all those primes.

There are also some older and simpler sieve algorithms that a little bit more complex but still fairly understandable. See Dixon's, Shanks' and Fermat's factoring algorithms. I read an article about one of these once, can't remember which one, but they're all fairly straightforward and use algebraic properties of the differences of squares.

If you're just testing whether a number N is prime, and you don't actually care about the factors themselves, use a probabilistic primality test. Miller-Rabin is the most standard one, I think.

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When I do x*x<N instead of x<sqrt(N) it takes longer for the number in question (in Python). Maybe sqrt(N) brings the comparison down to integer types that compare faster? –  PEZ Jan 13 '09 at 21:21
if N is fixed maybe the interpreter is "smart" enough to evaluate it only once... –  Jason S Jan 13 '09 at 22:03
In another thread in factorization I ran a test on the Sieve--it absolutely STUNK, even when put up against a crude algorithm that didn't consider all the tricks listed here. (Not that I'm sure all the tricks are good--the cost may be higher than what they save!) –  Loren Pechtel Jan 14 '09 at 1:12
Jason, the thing is that I don't compute sqrt(N) very often, only when I find a factor. It's the comparison that takes place often. Maybe it's much (my tests indicate that it's much) more efficient to compare p<sqrt_N than p_times_p<N. –  PEZ Jan 14 '09 at 8:55

I spent some time on this since it just sucked me in. I won't paste the code here just yet. Instead see this factors.py gist if you're curious.

Mind you, I didn't know anything about factoring (still don't) before reading this question. It's just a Python implementation of BradC's answer above.

On my MacBook it takes 0.002 secs to factor the number mentioned in the question (600851475143).

There must obviously be much, much faster ways of doing this. My program takes 19 secs to compute the factors of 6008514751431331. But the Factoris service just spits out the answer in no-time.

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@PEZ: What is the problem 3 forum? –  Dimitre Novatchev Jan 15 '09 at 14:11
It's a forum on the Project Euler site (projecteuler.net) that you get access to once you've submitted the correct answer to the problem we're discussing here. Check it out. But I warn you; It's highly addictive! –  PEZ Jan 15 '09 at 15:21
@PEZ: Many thanks for mentioning ProjectEuler. I already solved 28 problems and the only programming language I used has been XSLT. –  Dimitre Novatchev Jan 23 '09 at 3:57
That's amazing. Can't you put your solutions up on gist.github.com or some such. I'd like to see some more XSLT solutions to problems I've solved. And the last problem was launched last sat so if you solve that one you can probably post on the project forum. They're launching a new problem tomorrow. –  PEZ Jan 23 '09 at 9:05

The specific number is 300425737571? It trivially factors into 131 * 151 * 673 * 22567. I don't see what all the fuss is...

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Here's some Haskell goodness for you guys :)

primeFactors n = factor n primes
where factor n (p:ps) | p*p > n = [n]
| n `mod` p /= 0 = factor n ps
| otherwise = p : factor (n `div` p) (p:ps)
primes = 2 : filter ((==1) . length . primeFactors) [3,5..]

Took it about .5 seconds to find them, so I'd call that a success.

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He specifically asked for hints, not code. –  EvilTeach Jan 13 '09 at 19:04
Evilteach is too picky: the please no code was edited later –  blabla999 Jan 13 '09 at 20:25
He? I am a she! and no i did ask for no code in the original question but its not the language i am using so its no bother! –  xoxo Jan 14 '09 at 8:37
If you don't sieve, it's less code and faster: primeFactors n = factor n (2:[3,5..]) –  A. Rex Jan 14 '09 at 9:28
the backticks around mod and div didn't show up. Anybody else who's trying to use this code, put `backticks` around mod and div. @A. Rex: faster always? or just in the given case? Would the sieve help more as the input number gets bigger? –  LarsH Aug 18 '10 at 9:08

It shouldn't take that long, even with a relatively naive brute force. For that specific number, I can factor it in my head in about one second.

You say you don't want solutions(?), but here's your "subtle" hint. The only prime factors of the number are the lowest three primes.

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No there are more then that! The specific number is 300425737571 so go for it... –  xoxo Jan 13 '09 at 17:09
I almost don't want to know the answer to this... but why do you need the factor of JUST this specific number? –  EdgarVerona Jan 13 '09 at 20:04
It's for projecteuler. –  recursive Jan 13 '09 at 21:29

You could use the sieve of Eratosthenes to find the primes and see if your number is divisible by those you find.

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Yes thats what im working from lol –  xoxo Jan 13 '09 at 17:19
a sieve is extremely slow compared to just testing every odd number. –  zaratustra Jan 13 '09 at 18:14

You only need to check it's remainder mod(n) where n is a prime <= sqrt(N) where N is the number you are trying to factor. It really shouldn't take over an hour, even on a really slow computer or a TI-85.

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Sighs no i think its just my lack of prime number knowledge! –  xoxo Jan 13 '09 at 17:20
Before I became a programmer I was a PhD student in Number Theory, and it looks like there are a number of other people who are in to that too. As mentioned in other posts prime numbers are what keeps everything secure. If you get the time and it interests you, check it out. –  Anthony Potts Jan 14 '09 at 17:04

Your algorithm must be FUBAR. This only takes about 0.1s on my 1.6 GHz netbook in Python. Python isn't known for its blazing speed. It does, however, have arbitrary precision integers...

import math
import operator

def factor(n):
"""Given the number n, to factor yield a it's prime factors.
factor(1) yields one result: 1. Negative n is not supported."""
M = math.sqrt(n)  # no factors larger than M
p = 2             # candidate factor to test
while p <= M:     # keep looking until pointless
d, m = divmod(n, p)
if m == 0:
yield p   # p is a prime factor
n = d     # divide n accordingly
M = math.sqrt(n)  # and adjust M
else:
p += 1    # p didn't pan out, try the next candidate
yield n  # whatever's left in n is a prime factor

def test_factor(n):
f = factor(n)
n2 = reduce(operator.mul, f)
assert n2 == n

def example():
n = 600851475143
f = list(factor(n))
assert reduce(operator.mul, f) == n
print n, "=", "*".join(str(p) for p in f)

example()

# output:
# 600851475143 = 71*839*1471*6857

(This code seems to work in defiance of the fact that I don't know enough about number theory to fill a thimble.)

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You lucked out with your choice: 71 shows up fairly quickly and that greatly reduces the time spent. Try factoring this one: 12073531234081300153 –  Jason S Jan 13 '09 at 18:46
Yes, naturally, even this fairly stupid algorithm would be better if it didn't waste its time trying values of p that are not prime. However, I should point out that 600851475143 is specifically mentioned in the question, so it wasn't luck, as such. ;-) –  bendin Jan 13 '09 at 20:44

Just to expand/improve slightly on the "only test odd numbers that don't end in 5" suggestions...

All primes greater than 3 are either one more or one less than a multiple of 6 (6x + 1 or 6x - 1 for integer values of x).

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Semi-prime numbers of that size are used for encryption, so I am curious as to what you exactly want to use them for.

That aside, there currently are not good ways to find the prime factorization of large numbers in a relatively small amount of time.

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300 billion is less than 40 bits. Encryption primes are closer to 2048 bits... –  flussence Jan 13 '09 at 17:13
True on the less than 40 bits part, my mistake. However, encryption primes iirc are usually 512 bits each (1024 bits total for the resulting key). You use two, multiply them, and get a semi-prime (a number with only two prime factors). –  Matthew Brubaker Jan 13 '09 at 17:25