Pollard's rho algorithm for logarithms
Pollard's rho algorithm for logarithms is an algorithm introduced by John Pollard in 1978 to solve the discrete logarithm problem, analogous to Pollard's rho algorithm to solve the integer factorization problem.
The goal is to compute such that , where belongs to a cyclic group generated by . The algorithm computes integers , , , and such that . If the underlying group is cyclic of order , we can calculate as a solution of the equation .
To find the needed , , , and the algorithm uses Floyd's cycle-finding algorithm to find a cycle in the sequence , where the function is assumed to be random-looking and thus is likely to enter into a loop after approximately steps. One way to define such a function is to use the following rules: Divide into three disjoint subsets of approximately equal size: , , and . If is in then double both and ; if then increment , if then increment .
Algorithm
Let G be a cyclic group of order p, and given , and a partition , let be a map
and define maps and by
Inputs a: a generator of G, b: an element of G Output An integer x such that ax = b, or failure Initialise a0 ← 0, b0 ← 0, x0 ← 1 ∈ G, i ← 1 loop xi ← f(xi-1), ai ← g(xi-1, ai-1), bi ← h(xi-1, bi-1) x2i ← f(f(x2i-2)), a2i ← g(f(x2i-2), g(x2i-2, a2i-2)), b2i ← h(f(x2i-2), h(x2i-2, b2i-2)) if xi = x2i then r ← bi - b2i if r = 0 return failure x ← r−1(a2i - ai) mod p return x else # xi ≠ x2i i ← i+1, break loop end if end loop
Example
Consider, for example, the group generated by 2 modulo (the order of the group is , 2 generates the group of units modulo 1019). The algorithm is implemented by the following C++ program:
#include <stdio.h>
const int n = 1018, N = n + 1; /* N = 1019 -- prime */
const int alpha = 2; /* generator */
const int beta = 5; /* 2^{10} = 1024 = 5 (N) */
void new_xab( int& x, int& a, int& b ) {
switch( x%3 ) {
case 0: x = x*x % N; a = a*2 % n; b = b*2 % n; break;
case 1: x = x*alpha % N; a = (a+1) % n; break;
case 2: x = x*beta % N; b = (b+1) % n; break;
}
}
int main(void) {
int x=1, a=0, b=0;
int X=x, A=a, B=b;
for(int i = 1; i < n; ++i ) {
new_xab( x, a, b );
new_xab( X, A, B );
new_xab( X, A, B );
printf( "%3d %4d %3d %3d %4d %3d %3d\n", i, x, a, b, X, A, B );
if( x == X ) break;
}
return 0;
}
The results are as follows (edited):
i x a b X A B ------------------------------ 1 2 1 0 10 1 1 2 10 1 1 100 2 2 3 20 2 1 1000 3 3 4 100 2 2 425 8 6 5 200 3 2 436 16 14 6 1000 3 3 284 17 15 7 981 4 3 986 17 17 8 425 8 6 194 17 19 .............................. 48 224 680 376 86 299 412 49 101 680 377 860 300 413 50 505 680 378 101 300 415 51 1010 681 378 1010 301 416
That is and so , for which is a solution as expected. As is not prime, there is another solution , for which holds.
Complexity
The running time is approximately . If used together with the Pohlig-Hellman algorithm, the running time of the combined algorithm is , where is the largest prime factor of .
References
- Pollard, J. M. (1978). "Monte Carlo methods for index computation (mod p)". Mathematics of Computation. 32 (143): 918–924. doi:10.2307/2006496.
- Menezes, Alfred J.; van Oorschot, Paul C.; Vanstone, Scott A. (2001). "Chapter 3" (PDF). Handbook of Applied Cryptography.