what I am trying to do is to set up functions that can perform global and object space rotations, but am having problems understand how to go about object space rotations, as just multiplying a point by the rotation only works for global space, so my idea was to build the rotation in object space, then multiply it by the inverse of the objects matrix, supposedly taking away all the excess rotation between object and global space, so still maintaining the object space rotation, but in global values, I was wrong in this logic, as it did not work, here is my code, if you want to inspect it, all functions it calls have been tested to work:

```
// build object space rotation
sf::Vector3<float> XMatrix (MultiplyByMatrix(sf::Vector3<float> (cosz,sinz,0)));
sf::Vector3<float> YMatrix (MultiplyByMatrix(sf::Vector3<float> (-sinz,cosz,0)));
sf::Vector3<float> ZMatrix (MultiplyByMatrix(sf::Vector3<float> (0,0,1)));
// build cofactor matrix
sf::Vector3<float> InverseMatrix[3];
CoFactor(InverseMatrix);
// multiply by the transpose of the cofactor matrix(the adjoint), to bring the rotation to world space coordinates
sf::Vector3<float> RelativeXMatrix = MultiplyByTranspose(XMatrix, InverseMatrix[0], InverseMatrix[1], InverseMatrix[2]);
sf::Vector3<float> RelativeYMatrix = MultiplyByTranspose(YMatrix, InverseMatrix[0], InverseMatrix[1], InverseMatrix[2]);
sf::Vector3<float> RelativeZMatrix = MultiplyByTranspose(ZMatrix, InverseMatrix[0], InverseMatrix[1], InverseMatrix[2]);
// perform the rotation from world space
PointsPlusMatrix(RelativeXMatrix, RelativeYMatrix, RelativeZMatrix);
```