# Factor a large number efficiently with gmp

I need to get all the prime factors of large numbers that can easily get to 1k bits. The numbers are practically random so it shouldn't be hard. How do I do it efficiently? I use C++ with GMP library.

EDIT: I guess you all misunderstood me.
What I mean by prime a number is to get all prime factors of the number.
Sorry for my english, in my language prime and factor are the same :)

clarification (from OP's other post):

What I need is a way to efficiently factor(find prime factors of a number) large numbers(may get to 2048 bits) using C++ and GMP(Gnu Multiple Precession lib) or less preferably any other way. The numbers are practically random so there is little chance it will be hard to factor, and even if the number is hard to factor, I can re-roll the number(can't choose though).

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What do you mean by prime in this context? Are you trying to generate large prime numbers? Or do you mean prepare the numbers ahead of time for some particular use? –  DGH Nov 29 '10 at 6:43
You push the little squishy button on the side of the number to bump it up a few notches, so it's prime and the engine starts running smoothly. –  Potatoswatter Nov 29 '10 at 7:01
I agree, the english on this is bad enough that I can guess what the OP meant, but it certainly isn't clear. –  Omnifarious Nov 29 '10 at 7:07
The probability of the hard case of composite numbers with two prime factors is not negligible IMHO (my quick estimation gives on the order of 1 in 100000 random numbers with 1024 bits). –  starblue Nov 30 '10 at 20:58
@starblue: Interesting! could you explain your math in more detail? –  Jason S Dec 5 '10 at 16:58

A good start would be some pre-filtering with small primes, say about all primes lower than 100 000 or so. Simply try to divide by every single one of them (create a table which you then load at runtime or have it as static data in your code). It might seem slow and stupid, but if the number is totally random, this will give you some factors very fast with a huge probability. Then look at the remaining number and decide what to do next. If it is quite small (what "small" means is up to you) you could try a primality test (there is something in GMP i think) and if it gives it is a prime, you can in most of the cases trust it. Otherwise you have to factor it further.

If your numbers are really huge and you care about performance, then you definitely need to implement something more sophisticated than just a stupid division. Look at Quadratic Sieve (try wikipedia). It is quite simple but very powerful. If you are up to the chalenge, try MPQS, a variant of the quadratic sieve algorithm. This forum is a good source of information. There are even existing implementations of a tool you need - see for example this.

Note though that numbers with 1k bits are huge by all means. Factoring such a number (even with MPQS or others) might take years if you are lucky and forever if not. I think that MPQS performs well with numbers of about 100-400 bits (if they are composed of two primes almost equally large, which is the hardest case of course).

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for numbers with more than about 100 digits the Quadratic Sieve starts to get beaten by the General Number Field Sieve (GNFS). –  Chris Card Nov 29 '10 at 15:52
@Chris Card - A 100 digits in which base? Please specify. –  Omnifarious Nov 29 '10 at 15:56
In decimal base of course. Chris is right for such large numbers, QS (or to be clearer, MPQS, since QS is way slower with such numbers) starts to get slower than GNFS. –  PeterK Nov 29 '10 at 15:58
The current record factorisation is RSA768 (crypto-world.com/FactorRecords.html) which took a massive amount of work. It's possible to factor numbers with about 150 digits using GNFS on a standard modern PC, but 1k bits is out of reach at the moment to even the top researchers. –  Chris Card Nov 29 '10 at 15:58
Yes, and any attempts on factoring huge numbers are most of the time done on distributed computer systems where each node contributes to the result with a small part. Even then it takes months or even years to finish the task. –  PeterK Nov 29 '10 at 16:02

Below is a sample algorithm in Java (it's not C++ with GMP, but converting should be pretty straightforward) that:

1. generates a random number `x` of bitlength `Nbits`
2. tries to factor out all prime factors < 100, keeping a list of prime factors that divide x.
3. tests to see if the remaining factor is prime using Java's `isProbablePrime` method
4. If the remaining factor product is prime with sufficient probability, we have succeeded in factoring x. (STOP)
5. Otherwise the remaining factor product is definitely composite (see the isProbablePrime docs).
6. While we still have time, we run the Pollard rho algorithm until we find a divisor d.
7. If we run out of time, we have failed. (STOP)
8. We have found a divisor d. So we factor out d, add the prime factors of d to the list of prime factors of x, and go to step 4.

All the parameters of this algorithm are near the beginning of the program listing. I looked for 1024-bit random numbers, with a timeout of 250 milliseconds, and I keep running the program until I get a number x with at least 4 prime factors (sometimes the program finds a number with 1, 2, or 3 prime factors first). With this parameter set, it usually takes about 15-20 seconds on my 2.66Ghz iMac.

Pollard's rho algorithm isn't really that efficient, but it's simple, compared to the quadratic sieve (QS) or the general number field sieve (GNFS) -- I just wanted to see how the simple algorithm worked.

Why this works: (despite the claim of many of you that this is a hard problem)

The plain fact of it is, that prime numbers aren't that rare. For 1024-bit numbers, the Prime Number Theorem says that about 1 in every 1024 ln 2 (= about 710) numbers is prime.

So if I generate a random number x that is prime, and I accept probabilistic prime detection, I've successfully factored x.

If it's not prime, but I quickly factor out a few small factors, and the remaining factor is (probabilistically) prime, then I've successfully factored x.

Otherwise I just give up and generate a new random number. (which the OP says is acceptible)

Most of the numbers successfully factored will have 1 large prime factor and a few small prime factors.

The numbers that are hard to factor are the ones that have no small prime factors and at least 2 large prime factors (these include cryptographic keys that are the product of two large numbers; the OP has said nothing about cryptography), and I can just skip them when I run out of time.

``````package com.example;

import java.math.BigInteger;
import java.util.ArrayList;
import java.util.List;
import java.util.Random;

public class FindLargeRandomComposite {
final static private int[] smallPrimes = {2, 3, 5, 7, 11, 13, 17, 19, 23, 29,
31, 37, 41, 43, 47, 53, 59, 61, 67, 71,
73, 79, 83, 89, 97};

final static private int maxTime = 250;
final static private int Nbits = 1024;
final static private int minFactors = 4;
final static private int NCERTAINTY = 4096;

private interface Predicate { public boolean isTrue(); }

static public void main(String[] args)
{
Random r = new Random();
boolean found = false;
BigInteger x=null;
List<BigInteger> factors=null;
long startTime = System.currentTimeMillis();
while (!found)
{
x = new BigInteger(Nbits, r);
factors = new ArrayList<BigInteger>();
Predicate keepRunning = new Predicate() {
final private long stopTime = System.currentTimeMillis() + maxTime;
public boolean isTrue() {
return System.currentTimeMillis() < stopTime;
}
};
found = factor(x, factors, keepRunning);
System.out.println((found?(factors.size()+" factors "):"not factored ")+x+"= product: "+factors);
if (factors.size() < minFactors)
found = false;
}
long stopTime = System.currentTimeMillis();
System.out.println("Product verification: "+(x.equals(product(factors))?"passed":"failed"));
System.out.println("elapsed time: "+(stopTime-startTime)+" msec");
}

private static BigInteger product(List<BigInteger> factors) {
BigInteger result = BigInteger.ONE;
for (BigInteger f : factors)
result = result.multiply(f);
return result;
}

private static BigInteger findFactor(BigInteger x, List<BigInteger> factors,
BigInteger divisor)
{
BigInteger[] qr = x.divideAndRemainder(divisor);
if (qr[1].equals(BigInteger.ZERO))
{
return qr[0];
}
else
return x;
}

private static BigInteger findRepeatedFactor(BigInteger x,
List<BigInteger> factors, BigInteger p) {
BigInteger xprev = null;
while (xprev != x)
{
xprev = x;
x = findFactor(x, factors, p);
}
return x;
}

private static BigInteger f(BigInteger x, BigInteger n)
{
}

private static BigInteger gcd(BigInteger a, BigInteger b) {
while (!b.equals(BigInteger.ZERO))
{
BigInteger nextb = a.mod(b);
a = b;
b = nextb;
}
return a;
}
private static BigInteger tryPollardRho(BigInteger n,
List<BigInteger> factors, Predicate keepRunning) {
BigInteger x = new BigInteger("2");
BigInteger y = x;
BigInteger d = BigInteger.ONE;
while (d.equals(BigInteger.ONE) && keepRunning.isTrue())
{
x = f(x,n);
y = f(f(y,n),n);
d = gcd(x.subtract(y).abs(), n);
}
if (d.equals(n))
return x;
BigInteger[] qr = n.divideAndRemainder(d);
if (!qr[1].equals(BigInteger.ZERO))
throw new IllegalStateException("Huh?");
// d is a factor of x. But it may not be prime, so run it through the factoring algorithm.
factor(d, factors, keepRunning);
return qr[0];
}

private static boolean factor(BigInteger x0, List<BigInteger> factors,
Predicate keepRunning) {

BigInteger x = x0;
for (int p0 : smallPrimes)
{
BigInteger p = new BigInteger(Integer.toString(p0));
x = findRepeatedFactor(x, factors, p);
}
boolean done = false;
while (!done && keepRunning.isTrue())
{
done = x.equals(BigInteger.ONE) || x.isProbablePrime(NCERTAINTY);
if (!done)
{
x = tryPollardRho(x, factors, keepRunning);
}
}
if (!x.equals(BigInteger.ONE))
return done;
}
}
``````
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What about `mpz_nextprime`? I construct a random string of `n` bits (where `n` is > 1K or whatever you want) and make sure the first bit is a `1`. Then create an `mpz_t` from the string. I then use `mpz_nextprime` to get the next probable prime from the generated number.

This might not be ideal because the next probable prime it finds could be much greater than your 1K bits but it always worked just fine for me. I used it to create ElGamal keys.

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I would feel nervous about doing this. It would seem to me that it would make primes with certain properties more probable than they would be if you chose a new random number to test each time. If these primes are being generated for cryptographic purposes (and I can't see any other good reason to generate large primes) you do not want any structure to your primes that might aid an attacker. –  Omnifarious Nov 29 '10 at 7:21
Yes, the chance of a prime being chosen this way is basically linear in the difference with the prevous prime. I.e. 17 is twice as probable as 19, because 17-13=4 and 19-17=2. –  MSalters Nov 29 '10 at 8:30
Actually, given 1000 random bits, the probability that using `mpz_nextprime` yields a 1001 bit number is really really small. The largest 1000 bit prime is (2^1000 - 1245), hence one would obtain a 1001 bit prime only if he/she starts the incremental search starting from (2^1000 - 1244). If the starting number is randomly chosen, the probability of this happening is about 10^-298, which is an astronomically small probability. Just to be sure one may check the obtained prime size - odds are that that "if" check will never be true in your lifetime. –  Giuseppe Cardone Nov 29 '10 at 9:50
... in fact, it's far more likely that the `if` test returns true due to a miscalculation (soft error, likelihood is about 1E-15 ~ 1E-20). HW just isn't perfect. –  MSalters Nov 29 '10 at 12:04