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

- generates a random number
`x`

of bitlength `Nbits`

- tries to factor out all prime factors < 100, keeping a list of prime factors that divide x.
- tests to see if the remaining factor is prime using Java's
`isProbablePrime`

method
- If the remaining factor product is prime with sufficient probability, we have succeeded in factoring x. (
**STOP**)
- Otherwise the remaining factor product is definitely composite (see the isProbablePrime docs).
- While we still have time, we run the Pollard rho algorithm until we find a divisor d.
- If we run out of time, we have failed. (
**STOP**)
- 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))
{
factors.add(divisor);
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)
{
return x.multiply(x).add(BigInteger.ONE).mod(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))
factors.add(x);
return done;
}
}
```