With Java, some generic simplistic implementation would require at least two classes :

**Some delegate** to pass to the recursive algorithm, so you can receive updates wherever the execution is at. Something like :

```
public interface IDelegate {
public void found(List<CombinationFinder.FoundElement> nstack);
}
```

**The ***for* implementation, something like :

```
public class CombinationFinder {
private CombinationFinder next;
private int multiplier;
public CombinationFinder(int multiplier) {
this(multiplier, null);
}
public CombinationFinder(int multiplier, CombinationFinder next) {
this.multiplier = multiplier;
this.next = next;
}
public void setNext(CombinationFinder next) {
this.next = next;
}
public CombinationFinder getNext() {
return next;
}
public void search(int max, IDelegate d) {
Stack<FoundElement> stack = new Stack<FoundElement>();
this.search(0, max, stack, d);
}
private void search(int start, int max, Stack<FoundElement> s, IDelegate d) {
for (int i=0, val; (val = start + (i*multiplier)) <= max; i++) {
s.push(i);
if (null != next) {
next.search(val, max, s, d);
} else if (val == max) {
d.found(s);
}
s.pop();
}
}
static public class FoundElement {
private int value;
private int multiplier;
public FoundElement(int value, int multiplier) {
this.value = value;
this.multiplier = multiplier;
}
public int getValue() {
return value;
}
public int getMultiplier() {
return multiplier;
}
public String toString() {
return value+"*"+multiplier;
}
}
}
```

And finally, to setup and run (test) :

```
CombinationFinder a1 = new CombinationFinder(20);
CombinationFinder a2 = new CombinationFinder(5);
CombinationFinder a3 = new CombinationFinder(10);
a1.setNext(a2);
a2.setNext(a3);
a1.search(100, new IDelegate() {
int count = 1;
@Override
public void found(List<CombinationFinder.FoundElement> nstack) {
System.out.print("#" + (count++) + " Found : ");
for (int i=0; i<nstack.size(); i++) {
if (i>0) System.out.print(" + ");
System.out.print(nstack.get(i));
}
System.out.println();
}
}
});
```

Will output 36 solutions.

With this concept, you can have as many inner loops as you want, and even customize each one if you want through inheritance. You can even reuse objects (ie: `a1.setNext(a1);`

) with no problem at all.

** **UPDATE** **

Simply because I like monty's solution, I couldn't resist into testing it, and here's the result, tweaked a little.

*DISCLAIMER* all credits goes to monty for the algorithm

```
public class PolynomialSolver {
private SolverResult delegate;
private int min = 0;
private int max = Integer.MAX_VALUE;
public PolynomialSolver(SolverResult delegate) {
this.delegate = delegate;
}
public SolverResult getDelegate() {
return delegate;
}
public int getMax() {
return max;
}
public int getMin() {
return min;
}
public void setRange(int min, int max) {
this.min = min;
this.max = max;
}
public void solve(int[] constants, int total) {
solveImpl(constants, new int[constants.length], total, 0, 0);
}
private void solveImpl(int[] c, int[] v, int t, int n, int r) {
if (n == c.length) { //your end condition for the recursion
if (r == t) {
delegate.solution(c, v, t);
}
} else if (r <= t){ //keep going
for (int i=min, j; (i<=max) && ((j=r+c[n]*i)<=t); i++) {
v[n] = i;
solveImpl(c, v, t, n+1, j);
}
}
}
static public interface SolverResult {
public void solution(int[] constants, int[] variables, int total);
}
static public void main(String...args) {
PolynomialSolver solver = new PolynomialSolver(new SolverResult() {
int count = 1;
@Override
public void solution(int[] constants, int[] variables, int total) {
System.out.print("#"+(count++)+" Found : ");
for (int i=0, len=constants.length; i<len; i++) {
if (i>0) System.out.print(" + ");
System.out.print(constants[i]+"*"+variables[i]);
}
System.out.println(" = " + total);
}
});
// test some constants = total
solver.setRange(-10, 20);
solver.solve(new int[] {20, 5, 10}, 100); // will output 162 solutions
}
}
```

a1 + ja2 from sum, and just check, if this is divisible by a3, but this will not help you much with 6000 variables. :) – user unknown Jun 5 '11 at 3:29