I would suggest you use OpenCV for this. I also think, this question would be more suited to StackOverflow.
The textbook on this subject would be "Multiple-View Geometry" by Hartley and Zisserman. http://www.robots.ox.ac.uk/~vgg/hzbook/ (There is a sample chapter on the Fundamental Matrix on that website.)
Basically, first find the Fundamental Matrix, then by knowing the intrinsic parameters of the camera, find a solution to the position.
This is how I would do it in OpenCV. I have done this before, so it ought to work.
1. Run Feature Detection and Detector Extractor on both images.
2. Match Features.
3. Use F = cv::findFundamentalMatrix with Ransac.
4. E = K.t() * F * K. // K needs to be found beforehand.
5. Do SingularValueDecomposition of E such that E = U * S * V.t()
6. R = U * W.inv() * V.t() // W = [[0, -1, 0], [1, 0, 0], [0, 0, 1]]
7. Tx = V * Z * V.t() // Z = [[0, -1, 0], [1, 0, 0], [0, 0, 0]]
8. get t from Tx (matrix version of cross product)
9. Find the correct solution. R.t() and -t are possiblities.
10. Get overall scale by knowing the length of the size of the Rubrik's cube.
I am certain that a more straightforward approach can also work. The benefit of this approach is that no human input is needed (unsupervised). This is not true for the optional step 10 (determining scale).
A different solution would exploit the knowledge of the geometry of the Rubrik's cube. For example, six (5.5) points are needed to estimate the position of the camera, if the point's 3D position is known.
Unfortunatly, I am not aware of any software that does this for you automatically.
So here is the alternative algorithm:
Write down the coordinates of the corners of the cube as (X_i, Y_i, Z_i), and possibly also points with other knowable positions.
Mark the corresponding points u_i = (x_i, y_i).
For every correspondence create two lines in a matrix A.
(X_i, Y_i, Z_i, 1, 0, 0, 0, 0, -x_i*X_i, -x_i*Y_i, -x_i*Z_i -x_i)
(0, 0, 0, 0, X_i, Y_i, Z_i, 1, -y_i*X_i, -y_i*Y_i, -y_i*Z_i -y_i)
Then find p such that Ap = 0. I.e. p is the right kernel of A, or the least-squared solution to Ap=0.
De-flatten p, to create a 3x4 matrix. P.