# Better way to find all the prime factors of huge integers in C?

I have written a code in C that basically makes a list of all the prime factors of a huge number, which is stored using the `gmp` library. Here it is :

``````int is_div(mpz_t number, mpz_t i) {
return mpz_divisible_p(number,i)!=0;
}

mpz_t * prime_divs(mpz_t number){
mpz_t * prime_dividers = NULL;
mpz_t i, i_squared,TWO, comp;
mpz_inits(i, i_squared, TWO, comp, NULL);
mpz_set_ui(i,2);
mpz_mul(i_squared, i ,TWO);
while(mpz_cmp(i_squared,number)<=0){
if(is_div(number,i)){
mpz_fdiv_q(comp, number, i);
if(is_prime(i)) append(&prime_dividers,i);
if(is_prime(comp)) append(&prime_dividers,comp);
}
mpz_mul(i_squared, i ,i);
}
mpz_clears(i, i_squared, TWO, comp, NULL);
return prime_dividers;
}
``````

Note that the function `int is_prime(mpz_t n)` is not defined here because it is quite long. Just know that it is an implementation of a deterministic variant (up to 3,317,044,064,679,887,385,961,981) of Miller-Rabin's primality test. Same goes for the function `void append(mpz_t** arr, mpz_t i)`, it is just a function that appends it to a list.

So my `prime_divs` function searches for all integers `i`in the range `[2,sqrt(number)]` which divide `number`. If it is the case, it then calculates it's complementary divisor (i.e. `number/i`) and determines if any of them are primes. Would these integers be prime, then they would be appended to a list using `append`.

Is there any way to make`prime_divs` faster?

• The sieve of Erathosthenes is much slower than deterministic Miller-Rabin for huge numbers. Apr 20, 2020 at 1:53
• But testing every number in the range `[2, sqrt(number)]` probably negates whatever efficiency you're gaining by using M-R. You should at least restrict the loop to only odd numbers, since the only even prime is `2`. Apr 20, 2020 at 1:58
• The GMP source tarball includes a program `factorize.c`, in the demos directory, that implements Pollard's rho algorithm. This isn't the fastest known algorithm for factoring large integers, but it's a lot easier to understand than the newer ones.
– zwol
Apr 20, 2020 at 2:04
• You can instantly double the speed by adding 2 to i each time through the loop (after first checking 2 and 3). That way you only test odd divisors. You could use a more complex pattern to weed out even more factors (e.g., only test divisors that are 1 or 5 mod 6, once you're past 3). The larger the pattern, the further out you have to go before you can apply it. Apr 20, 2020 at 2:05
• @Michael Your objection makes no sense. For 348, it goes like this: You first find the factor 2, which occurs twice. So you divide by 4 to get 87. You then continue looking, and you find 3, which occurs once. So you divide by 3 to get 29. You then continue looking up to sqrt(29), but find no other factors. That means that 29 must be prime, so you're done: 348 = 2*2*3*29. It is very, very simple. Did you miss 29 as a factor? No, of course not. It's the prime that was left over after checking all possible factors. Apr 20, 2020 at 15:01