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 ${\displaystyle \gamma }$ such that ${\displaystyle \alpha ^{\gamma }=\beta }$, where ${\displaystyle \beta }$ belongs to a cyclic group ${\displaystyle G}$ generated by ${\displaystyle \alpha }$. The algorithm computes integers ${\displaystyle a}$, ${\displaystyle b}$, ${\displaystyle A}$, and ${\displaystyle B}$ such that ${\displaystyle \alpha ^{a}\beta ^{b}=\alpha ^{A}\beta ^{B}}$. If the underlying group is cyclic of order ${\displaystyle n}$, by substituting ${\displaystyle \beta }$ as ${\displaystyle {\alpha }^{\gamma }}$ and noting that two powers are equal if and only if the exponents are equivalent modulo the order of the base, in this case modulo ${\displaystyle n}$, we get that ${\displaystyle \gamma }$ is one of the solutions of the equation ${\displaystyle (B-b)\gamma =(a-A){\pmod {n}}}$. Solutions to this equation are easily obtained using the extended Euclidean algorithm.

To find the needed ${\displaystyle a}$, ${\displaystyle b}$, ${\displaystyle A}$, and ${\displaystyle B}$ the algorithm uses Floyd's cycle-finding algorithm to find a cycle in the sequence ${\displaystyle x_{i}=\alpha ^{a_{i}}\beta ^{b_{i}}}$, where the function ${\displaystyle f:x_{i}\mapsto x_{i+1}}$ is assumed to be random-looking and thus is likely to enter into a loop of approximate length ${\displaystyle {\sqrt {\frac {\pi n}{8}}}}$ after ${\displaystyle {\sqrt {\frac {\pi n}{8}}}}$ steps. One way to define such a function is to use the following rules: Partition ${\displaystyle G}$ into three disjoint subsets ${\displaystyle S_{0}}$, ${\displaystyle S_{1}}$, and ${\displaystyle S_{2}}$ of approximately equal size using a hash function. If ${\displaystyle x_{i}}$ is in ${\displaystyle S_{0}}$ then double both ${\displaystyle a}$ and ${\displaystyle b}$; if ${\displaystyle x_{i}\in S_{1}}$ then increment ${\displaystyle a}$, if ${\displaystyle x_{i}\in S_{2}}$ then increment ${\displaystyle b}$.

Algorithm[edit]

Let ${\displaystyle G}$ be a cyclic group of order ${\displaystyle n}$, and given ${\displaystyle \alpha ,\beta \in G}$, and a partition ${\displaystyle G=S_{0}\cup S_{1}\cup S_{2}}$, let ${\displaystyle f:G\to G}$ be the map

${\displaystyle f(x)={\begin{cases}\beta x&x\in S_{0}\\x^{2}&x\in S_{1}\\\alpha x&x\in S_{2}\end{cases}}}$

and define maps ${\displaystyle g:G\times \mathbb {Z} \to \mathbb {Z} }$ and ${\displaystyle h:G\times \mathbb {Z} \to \mathbb {Z} }$ by

${\displaystyle {\begin{aligned}g(x,k)&={\begin{cases}k&x\in S_{0}\\2k{\pmod {n}}&x\in S_{1}\\k+1{\pmod {n}}&x\in S_{2}\end{cases}}\\h(x,k)&={\begin{cases}k+1{\pmod {n}}&x\in S_{0}\\2k{\pmod {n}}&x\in S_{1}\\k&x\in S_{2}\end{cases}}\end{aligned}}}$

input: a: a generator of G
       b: an element of G
output: An integer x such that ax = b, or failure

Initialise i ← 0, a0 ← 0, b0 ← 0, x0 ← 1 ∈ G

loop
    i ← i + 1

    xi ← f(xi−1),
    ai ← g(xi−1, ai−1),
    bi ← h(xi−1, bi−1)

    x2i−1 ← f(x2i−2),
    a2i−1 ← g(x2i−2, a2i−2),
    b2i−1 ← h(x2i−2, b2i−2)
    x2i ← f(x2i−1),
    a2i ← g(x2i−1, a2i−1),
    b2i ← h(x2i−1, b2i−1)
while xi ≠ x2i

r ← bi − b2i
if r = 0 return failure
return r−1(a2i − ai) mod n

Example[edit]

Consider, for example, the group generated by 2 modulo ${\displaystyle N=1019}$ (the order of the group is ${\displaystyle n=1018}$, 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 ${\displaystyle 2^{681}5^{378}=1010=2^{301}5^{416}{\pmod {1019}}}$ and so ${\displaystyle (416-378)\gamma =681-301{\pmod {1018}}}$, for which ${\displaystyle \gamma _{1}=10}$ is a solution as expected. As ${\displaystyle n=1018}$ is not prime, there is another solution ${\displaystyle \gamma _{2}=519}$, for which ${\displaystyle 2^{519}=1014=-5{\pmod {1019}}}$ holds.

Complexity[edit]

The running time is approximately ${\displaystyle {\mathcal {O}}({\sqrt {n}})}$. If used together with the Pohlig–Hellman algorithm, the running time of the combined algorithm is ${\displaystyle {\mathcal {O}}({\sqrt {p}})}$, where ${\displaystyle p}$ is the largest prime factor of ${\displaystyle n}$.

References[edit]

• Pollard, J. M. (1978). "Monte Carlo methods for index computation (mod p)". Mathematics of Computation. 32 (143): 918–924. doi:10.2307/2006496. JSTOR 2006496.
• Menezes, Alfred J.; van Oorschot, Paul C.; Vanstone, Scott A. (2001). "Chapter 3" (PDF). Handbook of Applied Cryptography.