### First method

Use this idea to generate equations:

a1, a2 and a3 are coordinates in the original system, x y are the coordinates you get from the end-result and z is a coordinate you don’t know. This generates 2 equations for every point of the cube. E.g for point 0 with coordinates (-1, -1, 1) these are:

Do this for the 4 front points of the cube and you get 8 equations. Now add the fact that this is a rotation matrix -> the determinant is 1 and you have 9 equations. Solve these with any of the usual algorithms for solving equation systems and you have the transformation matrix. Getting the axis and angle from that is easy via google: http://www.euclideanspace.com/maths/geometry/rotations/conversions/matrixToAngle/

### Second method

Naming your points 0, 1, 2, 3 a, b, c, d respectively, you can get the z coordinates of the vectors between them (e.g. `b-a`

) with this idea:

you will still have to sort out if `b3-a3`

is positive, though. One way to do that is to use the centermost point as b (calculate distance from the center for all points, use the one with the minimal distance). Then you know for sure that `b3-a3`

is positive (if z is positive towards you).

Now assume that `a`

is (0,0,0) in your transformed space and you can calculate all the point positions by adding the appropriate vectors to that.

To get the rotation you use the fact that you know where `b-a`

did point in your origin space (e.g. (1,0,0)). You get the rotation angle via dot product of `b-a`

and `(1,0,0)`

and the rotation axis via cross product between those vectors.