This seems to be an implementation:
http://www.cs.miami.edu/~burt/learning/Csc598.0/PohligHellman.java

EDIT: Adding code from above link here:

```
package polighelex;
/**
* Title: Example of Polig Hellman method of Discret Logs
* Description:
* Copyright: Copyright (c) 2001
* Company:
* @author Burton Rosenberg
* @version 1.0
*/
public class PohligHellman {
public PohligHellman() {
}
public static void main(String[] args) {
PohligHellman ph = new PohligHellman();
ph.entryPoint(12) ;
}
public void entryPoint(int mystery_index)
{
int gen = 3 ;
int modu = 17 ;
int order = 16 ;
// prove 3 generates Z/17Z
System.out.println("Demonstrate that 3 generates Z/17Z.") ;
this.cycle(gen,modu) ;
System.out.println() ;
// calculate and check gen_inv
int gen_inv = pwr ( gen, order-1, modu ) ;
System.out.println( gen + " * " + gen_inv + " = " + (gen*gen_inv)%17);
System.out.println();
setMagicPower( 2, order ) ;
int mp = getMagicPower();
int possible_coeff_1 = pwr( gen, mp, modu ) ;
System.out.println("We should either get 1 or " + possible_coeff_1 +
" during PH index extractions" ) ;
// create mystery number
int mystery = pwr( gen, mystery_index, modu ) ;
System.out.println("Mystery: " + mystery );
int coeff_index = 0 ;
int coeff_power = 1 ;
while ( isNextMagicPower() )
{
// kill all but leading term of current_factor-adic expansion
// of index of mystery
System.out.println("magic power: " + getMagicPower());
int this_reduction = pwr( mystery, nextMagicPower(), modu ) ;
System.out.println(coeff_index + ", reduction: " + this_reduction );
if ( this_reduction==possible_coeff_1 )
{
// coeff is 1
System.out.println(coeff_index + ", coeffic: " + 1 ) ;
mystery = mystery * pwr(gen_inv,coeff_power,modu) % modu ;
System.out.println("New mystery: "+ mystery );
}
else
{
// coeff is 0
System.out.println(coeff_index + ", coeffic: " + 0 ) ;
}
coeff_index++ ;
coeff_power *= 2 ;
}
}
int pMagicPower ;
int pCurrentFactor ;
public void setMagicPower( int current_factor, int group_order )
{
// ASSERT : current_factor | group_order
pMagicPower = group_order ;
pCurrentFactor = current_factor ;
}
public boolean isNextMagicPower()
{
if ( pMagicPower % pCurrentFactor == 0 ) return true ;
else return false;
}
public int getMagicPower()
{
return pMagicPower / pCurrentFactor ;
}
public int nextMagicPower( )
{
return pMagicPower = pMagicPower/pCurrentFactor ;
}
public int pwr(int base, int expon, int modu)
{
// recursive base^expon % modu
base %= modu ;
if (expon==0) return 1 ;
if (expon==1) return base ;
if ((expon%2)==0 )
{
int t = pwr( base, expon/2, modu ) ;
return t*t % modu;
}
else
{
int t = pwr( base, expon-1, modu ) ;
return base*t % modu ;
}
}
public int cycle(int gen, int modu)
{
// Assume gen^i =1 % modul for some i>0
int g = gen ;
int i = 1 ;
while ( g!=1 )
{
System.out.println(i + ": " + g) ;
g = (g*gen)%modu ;
i++ ;
}
System.out.println(i + ": " + g) ;
return i ;
}
}
```