Basically you're looking to solve the following system for x_{1} and x_{2}:

x_{1}∙**r**_{1} + x_{2}∙**r**_{2} = **b** - **a**

In MATLAB you can do this by following these instructions from the official documentation:

```
y = reshape(b - a, [], 1);
R = [r1(:), r2(:)];
x0 = R \ y; %// Basic solution
Z = null(R, 'r'); %// Null space of R
```

Any solution of the form: `x = x0 + Z * p`

(for any arbitrary vector `p`

) should satisfy: `y = R * x`

. Note that this might give you tiny errors because of floating point operations, so consider setting a tolerance threshold and rounding them:

```
idx = (x0 - round(x0) < 100 * eps);
x0(idx) = round(x0(idx));
```

Now let's find all possible positive integer combinations of the form `x0 + Z * p`

:

```
if isempty(Z) %// Only one solution exists
X = x0;
else
N = max([ceil(x0); Z(:)]); %// Set a search range
U = cell(size(Z, 2), 1);
[U{:}] = ndgrid(-N:N);
U = cellfun(@(x)x(:), U, 'UniformOutput', false);
P = [U{:}]; %// All possible values for p within search range
X = bsxfun(@plus, x0(:).', P * Z.');
X = unique(X(all(X >= 0, 2), :), 'rows');
end
%// Keep only the positive combinations
X = unique(X(all(X >= 0, 2), :), 'rows');
```

### Example

Let's set the initial conditions first:

```
a = eye(3);
b = 5 * eye(3);
r1 = eye(3);
r2 = 2 * eye(3);
```

After running the first part of the code, we should get:

```
x0 =
0
2
Z =
-2
1
```

The second part of the code should produce all possible positive integer combinations:

```
X =
0 2
2 1
4 0
```

which correspond to the sums: 0**r**_{1} + 2**r**_{2}, 2**r**_{1} + 1**r**_{2} and 4**r**_{1} + 0**r**_{2}, respectively.

`n`

vectors that are needed at most a factor`k`

and`k*n!`

is not really a big number (upto k=5 and n=10 for example or k =1000 and n=7) you could just make a few nested for loops and store the result in a huge matrix. – Dennis Jaheruddin May 7 '13 at 8:34