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pollard_rho.rs
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pollard_rho.rs
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use super::miller_rabin;
struct LinearCongruenceGenerator {
// modulus as 2 ^ 32
multiplier: u32,
increment: u32,
state: u32,
}
impl LinearCongruenceGenerator {
fn new(multiplier: u32, increment: u32, state: u32) -> Self {
Self {
multiplier,
increment,
state,
}
}
fn next(&mut self) -> u32 {
self.state = (self.multiplier as u64 * self.state as u64 + self.increment as u64) as u32;
self.state
}
fn get_64bits(&mut self) -> u64 {
((self.next() as u64) << 32) | (self.next() as u64)
}
}
fn gcd(mut a: u64, mut b: u64) -> u64 {
while a != 0 {
let tmp = b % a;
b = a;
a = tmp;
}
b
}
#[inline]
fn advance(x: u128, c: u64, number: u64) -> u128 {
((x * x) + c as u128) % number as u128
}
fn pollard_rho_customizable(
number: u64,
x0: u64,
c: u64,
iterations_before_check: u32,
iterations_cutoff: u32,
) -> u64 {
/*
Here we are using Brent's method for finding cycle.
It is generally faster because we will not use `advance` function as often
as Floyd's method.
We also wait to do a few iterations before calculating the GCD, because
it is an expensive function. We will correct for overshooting later.
This function may return either 1, `number` or a proper divisor of `number`
*/
let mut x = x0 as u128; // tortoise
let mut x_start = 0_u128; // to save the starting tortoise if we overshoot
let mut y = 0_u128; // hare
let mut remainder = 1_u128;
let mut current_gcd = 1_u64;
let mut max_iterations = 1_u32;
while current_gcd == 1 {
y = x;
for _ in 1..max_iterations {
x = advance(x, c, number);
}
let mut big_iteration = 0_u32;
while big_iteration < max_iterations && current_gcd == 1 {
x_start = x;
let mut small_iteration = 0_u32;
while small_iteration < iterations_before_check
&& small_iteration < (max_iterations - big_iteration)
{
small_iteration += 1;
x = advance(x, c, number);
let diff = x.abs_diff(y);
remainder = (remainder * diff) % number as u128;
}
current_gcd = gcd(remainder as u64, number);
big_iteration += iterations_before_check;
}
max_iterations *= 2;
if max_iterations > iterations_cutoff {
break;
}
}
if current_gcd == number {
while current_gcd == 1 {
x_start = advance(x_start, c, number);
current_gcd = gcd(x_start.abs_diff(y) as u64, number);
}
}
current_gcd
}
/*
Note: using this function with `check_is_prime` = false
and a prime number will result in an infinite loop.
RNG's internal state is represented as `seed`. It is
advisable (but not mandatory) to reuse the saved seed value
In subsequent calls to this function.
*/
pub fn pollard_rho_get_one_factor(number: u64, seed: &mut u32, check_is_prime: bool) -> u64 {
// LCG parameters from wikipedia
let mut rng = LinearCongruenceGenerator::new(1103515245, 12345, *seed);
if number <= 1 {
return number;
}
if check_is_prime {
let mut bases = vec![2u64, 3, 5, 7];
if number > 3_215_031_000 {
bases.append(&mut vec![11, 13, 17, 19, 23, 29, 31, 37]);
}
if miller_rabin(number, &bases) == 0 {
return number;
}
}
let mut factor = 1u64;
while factor == 1 || factor == number {
let x = rng.get_64bits();
let c = rng.get_64bits();
factor = pollard_rho_customizable(
number,
(x % (number - 3)) + 2,
(c % (number - 2)) + 1,
32,
1 << 18, // This shouldn't take much longer than number ^ 0.25
);
// These numbers were selected based on local testing.
// For specific applications there maybe better choices.
}
*seed = rng.state;
factor
}
fn get_small_factors(mut number: u64, primes: &[usize]) -> (u64, Vec<u64>) {
let mut result: Vec<u64> = Vec::new();
for p in primes {
while (number % *p as u64) == 0 {
number /= *p as u64;
result.push(*p as u64);
}
}
(number, result)
}
fn factor_using_mpf(mut number: usize, mpf: &[usize]) -> Vec<u64> {
let mut result = Vec::new();
while number > 1 {
result.push(mpf[number] as u64);
number /= mpf[number];
}
result
}
/*
`primes` and `minimum_prime_factors` use usize because so does
LinearSieve implementation in this repository
*/
pub fn pollard_rho_factorize(
mut number: u64,
seed: &mut u32,
primes: &[usize],
minimum_prime_factors: &[usize],
) -> Vec<u64> {
if number <= 1 {
return vec![];
}
let mut result: Vec<u64> = Vec::new();
{
// Create a new scope to keep the outer scope clean
let (rem, mut res) = get_small_factors(number, primes);
number = rem;
result.append(&mut res);
}
if number == 1 {
return result;
}
let mut to_be_factored = vec![number];
while !to_be_factored.is_empty() {
let last = to_be_factored.pop().unwrap();
if last < minimum_prime_factors.len() as u64 {
result.append(&mut factor_using_mpf(last as usize, minimum_prime_factors));
continue;
}
let fact = pollard_rho_get_one_factor(last, seed, true);
if fact == last {
result.push(last);
continue;
}
to_be_factored.push(fact);
to_be_factored.push(last / fact);
}
result.sort_unstable();
result
}
#[cfg(test)]
mod test {
use super::super::LinearSieve;
use super::*;
fn check_is_proper_factor(number: u64, factor: u64) -> bool {
factor > 1 && factor < number && ((number % factor) == 0)
}
fn check_factorization(number: u64, factors: &[u64]) -> bool {
let bases = vec![2u64, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37];
let mut prod = 1_u64;
let mut prime_check = 0_u64;
for p in factors {
prod *= *p;
prime_check |= miller_rabin(*p, &bases);
}
prime_check == 0 && prod == number
}
#[test]
fn one_factor() {
// a few small cases
let mut sieve = LinearSieve::new();
sieve.prepare(1e5 as usize).unwrap();
let numbers = vec![1235, 239874233, 4353234, 456456, 120983];
let mut seed = 314159_u32; // first digits of pi; nothing up my sleeve
for num in numbers {
let factor = pollard_rho_get_one_factor(num, &mut seed, true);
assert!(check_is_proper_factor(num, factor));
let factor = pollard_rho_get_one_factor(num, &mut seed, false);
assert!(check_is_proper_factor(num, factor));
assert!(check_factorization(
num,
&pollard_rho_factorize(num, &mut seed, &sieve.primes, &sieve.minimum_prime_factor)
));
}
// check if it goes into infinite loop if `number` is prime
let numbers = vec![
2, 3, 5, 7, 11, 13, 101, 998244353, 1000000007, 1000000009, 1671398671, 1652465729,
1894404511, 1683402997, 1661963047, 1946039987, 2071566551, 1867816303, 1952199377,
1622379469, 1739317499, 1775433631, 1994828917, 1818930719, 1672996277,
];
for num in numbers {
assert_eq!(pollard_rho_get_one_factor(num, &mut seed, true), num);
assert!(check_factorization(
num,
&pollard_rho_factorize(num, &mut seed, &sieve.primes, &sieve.minimum_prime_factor)
));
}
}
#[test]
fn big_numbers() {
// Bigger cases:
// Each of these numbers is a product of two 31 bit primes
// This shouldn't take more than a 10ms per number on a modern PC
let mut seed = 314159_u32; // first digits of pi; nothing up my sleeve
let numbers: Vec<u64> = vec![
2761929023323646159,
3189046231347719467,
3234246546378360389,
3869305776707280953,
3167208188639390813,
3088042782711408869,
3628455596280801323,
2953787574901819241,
3909561575378030219,
4357328471891213977,
2824368080144930999,
3348680054093203003,
2704267100962222513,
2916169237307181179,
3669851121098875703,
];
for num in numbers {
assert!(check_factorization(
num,
&pollard_rho_factorize(num, &mut seed, &vec![], &vec![])
));
}
}
}