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Part of my code stores the equivalent of a 4x3 matrix, by storing an xyz position, an xyz scale, and a quaternion. Code snippet below:

class tTransform
{

    // data
    tVector4f    m_Position;
    tQuaternion  m_Rotation;
    tVector4f    m_Scale;

};

I want to multiply 2 of these objects together, (as though it were a matrix multiply), and am wondering if there is a faster/better way to do it than to convert each to a matrix, do the multiply that way, and then extract the resulting position, rotation and scale back out again?

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Thanks for the response :) I couldn't help thinking that doing matrix-to-quat, quat-to-matrix, plus getting the lengths of the XYZ axes of the resulting matrix for the new scales wasn't the best way. I guess I can skip the scale part with a couple of checks though. –  Hybrid Dec 21 '11 at 18:58
    
If you know a better solution by hand you can overload the multiply operator on matrix quaternion –  ted Dec 21 '11 at 18:58
    
I think the lack of answers suggest I'm attacking my problem in completely the wrong way to begin with.. back to the drawing board I think! :) –  Hybrid Dec 21 '11 at 19:07
1  
There is a way. –  Charles Beattie Dec 22 '11 at 16:42
    
@CharlesBeattie Interesting... I've reworked my implementation to not need a solution to this, but I'd still be curious to hear a solution? –  Hybrid Dec 23 '11 at 8:45

1 Answer 1

up vote 2 down vote accepted

Health warning as this is from memory and completely untested. You need to define or replace operators for tQuaternions and tVector4s.

class tTransform
{

    // data
    tVector4f    m_Position;
    tQuaternion  m_Rotation;
    tVector4f    m_Scale;

public:
    // World = Parent * Local (*this == parent)
    tTransform operator * (const tTransform& localSpace)
    {
        tTransform worldSpace;
        worldSpace.m_Position = m_Position + 
                                m_Rotation * (localSpace.m_Position * m_Scale);
        worldSpace.m_Rotation = m_Rotation * localSpace.m_Rotation;
        worldSpace.m_Scale = m_Scale * (m_Rotation * localSpace.m_Scale);
        return worldSpace;
    }

    // Local = World / Parent (*this = World)
    tTransform operator / (const tTransform& parentSpace)
    {
        tTransform localSpace;
        tQuaternion parentSpaceConjugate = parentSpace.m_Rotation.conjugate(); 
        localSpace.m_Position = (parentSpaceConjugate * 
                                (m_Position - parentSpace.m_Position)) /
                                parentSpace.m_Scale;

        localSpace.m_Rotation = parentSpaceConjugate * m_Rotation;

        localSpace.m_Scale = parentSpaceConjugate *
                             (m_Scale / parentSpace.m_Scale);
        return localSpace;
    }
};
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