Pohlig–Hellman algorithm for computing discrete logarithms

I'm working on coding the Pohlig-Hellman Algorithm but I am having problem understand the steps in the algorithm based on the definition of the algorithm.

Going by the Wiki of the algorithm:

I know the first part 1) is to calculate the prime factor of p-1 - which is fine.

However, I am not sure what I need to do in steps 2) where you calculate the co-efficents:

``````Let x2 = c0 + c1(2).
125(180/2) = 12590 1 mod (181) so c0 = 0.
125(180/4) = 12545 1 mod (181) so c1 = 0.
Thus, x2 = 0 + 0 = 0.
``````

and 3) put the coefficents together and solve in the chinese remainder theorem.

Can someone help with explaining this in plain english (i) - or pseudocode. I want to code the solution myself obviously but I cannot make any more progress unless i understand the algorithm.

Note: I have done a lot of searching for this and I read S. Pohlig and M. Hellman (1978). "An Improved Algorithm for Computing Logarithms over GF(p) and its Cryptographic Significance but its still not really making sense to me.

Update: how come q(125) stays constant in this example.

Where as in this example is appears like he is calculating a new q each time.

To be more specific I don't understand how the following is computed: Now divide 7531 by a^c0 to get `7531(a^-2) = 6735 mod p`.

Let's start with the main idea behind Pohlig-Hellman. Assume that we are given y, g and p and that we want to find x, such that

y == gx (mod p).

(I'm using == to denote an equivalence relation). To simplify things, I'm also assuming that the order of g is p-1, i.e. the smallest positive k with 1==gk (mod p) is k=p-1.

An inefficient method to find x, would be to simply try all values in the range 1 .. p-1. Somewhat better is the "Baby-step giant-step" method that requires O(p0.5) arithmetic operations. Both methods are quite slow for large p. Pohlig-Hellman is a significant improvement when p-1 has many factors. I.e. assume that

p-1 = n r

Then what Pohlig and Hellman propose is to solve the equation

yn == (gn)z (mod p).

If we take logarithms to the basis g on both sides, this is the same as

n logg(y) == logg(yn) == nz (mod p-1).

n can be divided out, giving

logg(y) == z (mod r).

Hence x == z (mod r).

This is an improvement, since we only have to search a range 0 .. r-1 for a solution of z. And again "Baby-step giant-step" can be used to improve the search for z. Obviously, doing this once is not a complete solution yet. I.e. one has to repeat the algorithm above for every prime factor r of p-1 and then to use the Chinese remainder theorem to find x from the partial solutions. This works nicely if p-1 is square free.

If p-1 is divisible by a prime power then a similiar idea can be used. For example let's assume that p-1 = m qk. In the first step, we compute z such that x == z (mod q) as shown above. Next we want to extend this to a solution x == z' (mod q2). E.g. if p-1 = m q2 then this means that we have to find z' such that

ym == (gm)z' (mod p).

Since we already know that z' == z (mod q), z' must be in the set {z, z+q, z+2q, ..., z+(q-1)q }. Again we could either do an exhaustive search for z' or improve the search with "baby-step giant-step". This step is repeated for every exponent of q, this is from knowing x mod qi we iteratively derive x mod qi+1.

• Does that mean there's a quicker way when calculating the coeficients for 350377^4 that we don't have to go from 0..350377 calculating all the cofficients – Robben_Ford_Fan_boy Apr 5 '10 at 0:57
• Yup, you can always use Baby-step giant-step. I've added a link to the wikipedia article that explains this algorithm. With this algorithm the largest loop that you need should have about sqrt(350377) iterations. – Accipitridae Apr 5 '10 at 20:33

I'm coding it up myself right now (JAVA). I'm using Pollard-Rho to find the small prime factors of p-1. Then using Pohlig-Hellman to solve a DSA private key. y = g^x. I am having the same problem..

UPDATE: "To be more specific I don't understand how the following is computed: Now divide 7531 by a^c0 to get 7531(a^-2) = 6735 mod p."

if you find the modInverse of a^c0 it will make sense

Regards