The variables in a formula can be encoded as bits in an integral value. The brute force method then boils down to range over all possible values that the integral "container" may take.

In other words, you have an array of integers, which represents all your formula's variables, and you increment the integers with carry, and at each step check the solution it represents against your formula. You stop when the solution is a match.

Here's a dead simple implementation for such a variable container:

```
class OverflowException extends RuntimeException {}
public class Variables {
int[] data;
int size;
public Variables(int size_){
size = size_;
data = new int[1 + size/32];
}
public boolean get(int i){
return (data[i/32] & (1 << i%32)) != 0;
}
public void set(int i, boolean v){
if (v)
data[i/32] |= (1 << i%32);
else
data[i/32] &= ~(1 << i%32);
}
public void increment(){
int i;
for (i=0; i < size/32; i++){
data[i]++;
if (data[i] != 0) return;
}
if (size%32 != 0){
data[i]++;
if ((data[i] & ~((1 << (size%32)) - 1)) != 0)
throw new OverflowException();
}
}
}
```

*(Caveat emptor: code untested).*

The variable array can also be more simply represented as a `boolean`

container, but you might lose a bit in performance, because of the increment step (although that could be perhaps mitigated by using gray code instead of plain binary encoding for the increment operation, but the complexity of this implementation seems to indicate the contrary, and if you go for a complex solution, it might as well be a good sat2 solver instead).