Did you try just generating such numbers and checking them? I would expect that to be acceptably fast. The prime density decreases only as the logarithm of the number, so I'd except you to try a few hundred numbers until you hit a prime. `ln(2^512) = 354`

so about one number in 350 will be prime.

Roughly speaking, the prime number theorem states that if a random number nearby some large number N is selected, the chance of it being prime is about 1 / ln(N), where ln(N) denotes the natural logarithm of N. For example, near N = 10,000, about one in nine numbers is prime, whereas near N = 1,000,000,000, only one in every 21 numbers is prime. In other words, the average gap between prime numbers near N is roughly ln(N)

from http://en.wikipedia.org/wiki/Prime_number_theorem

You just need to take care that a number exists for your final digits. But I think that's as easy as checking that the last digit isn't divisible by 2 or 5(i.e. it is 1, 3, 7 or 9).

According to this performance data you can do about 2000 ModPow operations on 512 bit data per second, and since a simple prime-test is checking `2^(p-1) mod p=1`

which is one ModPow operation, you should be able to generate several primes with your properties per second.

So you could do(pseudocode):

```
BigInteger FindPrimeCandidate(int lastDigits)
{
BigInteger i=Random512BitInt;
int remainder = i % 100000;
int increment = lastDigits-remainder;
i+=increment;
BigInteger test=BigInteger.ModPow(2, i-1, i);
if(test==1)
return i;
else
return null;
}
```

And do more extensive prime checks on the result of that function.

needthis for? – Thorbjørn Ravn Andersen Dec 4 '10 at 19:55