#ifndef CTRANSFORM_HPP #define CTRANSFORM_HPP #include "Global.hpp" #include "CMatrix3f.hpp" #include "CMatrix4f.hpp" #include "CVector3f.hpp" #include "CQuaternion.hpp" namespace Zeus { class ZE_ALIGN(16) CTransform { public: ZE_DECLARE_ALIGNED_ALLOCATOR(); CTransform() : m_basis(false) {} CTransform(const CMatrix3f& basis, const CVector3f& offset=CVector3f::skZero) : m_basis(basis), m_origin(offset) {} #if ZE_ATHENA_TYPES CTransform(const atVec4f* mtx) : m_basis(mtx[0], mtx[1], mtx[2]), m_origin(mtx[0].vec[3], mtx[1].vec[3], mtx[2].vec[3]) {} #endif inline CTransform operator*(const CTransform& rhs) const {return CTransform(m_basis * rhs.m_basis, m_origin + (m_basis * rhs.m_origin));} inline CTransform inverse() const { CMatrix3f inv = m_basis.inverted(); return CTransform(inv, inv * -m_origin); } inline void translate(const CVector3f& position) { m_basis = CMatrix3f::skIdentityMatrix3f; m_origin = position; } inline void translate(float x, float y, float z) { translate({x, y, z}); } inline void rotate(const CVector3f& euler) { *this = *this * CMatrix3f(CQuaternion(euler)); } inline void scaleBy(float factor) { CTransform xfrm(CMatrix3f(CVector3f(factor, factor, factor))); *this = *this * xfrm; } inline void scale(const CVector3f& factor) { m_basis = CMatrix3f(true); m_basis[0][0] = factor.x; m_basis[1][1] = factor.y; m_basis[2][2] = factor.z; m_origin.zeroOut(); } inline void scale(float x, float y, float z) { scale({x, y, z}); } inline void scale(float factor) { scale({factor, factor, factor}); } inline void multiplyIgnoreTranslation(const CTransform& xfrm) { m_basis = m_basis*xfrm.m_basis; } inline CTransform getRotation() { CTransform ret = *this; ret.m_origin.zeroOut(); return ret; } void setRotation(const CMatrix3f& mat) { m_basis = mat; } void setRotation(const CTransform& xfrm) { setRotation(xfrm.m_basis); } /** * @brief buildMatrix3f Returns the stored matrix * buildMatrix3f is here for compliance with Retro's Math API * @return The Matrix (Neo, you are the one) */ inline CMatrix3f buildMatrix3f() { return m_basis; } inline CVector3f operator*(const CVector3f& other) const {return m_origin + m_basis * other;} inline void toMatrix4f(CMatrix4f& mat) const { #if __SSE__ mat.vec[0].mVec128 = m_basis[0].mVec128; mat.m[0][3] = 0.0f; mat.vec[1].mVec128 = m_basis[1].mVec128; mat.m[1][3] = 0.0f; mat.vec[2].mVec128 = m_basis[2].mVec128; mat.m[2][3] = 0.0f; mat.vec[3].mVec128 = m_origin.mVec128; mat.m[3][3] = 1.0f; #else mat.m[0][0] = m_basis[0][0]; mat.m[0][1] = m_basis[0][1]; mat.m[0][2] = m_basis[0][2]; mat.m[0][3] = 0.0f; mat.m[1][0] = m_basis[1][0]; mat.m[1][1] = m_basis[1][1]; mat.m[1][2] = m_basis[1][2]; mat.m[1][3] = 0.0f; mat.m[2][0] = m_basis[2][0]; mat.m[2][1] = m_basis[2][1]; mat.m[2][2] = m_basis[2][2]; mat.m[2][3] = 0.0f; mat.m[3][0] = m_origin[0]; mat.m[3][1] = m_origin[1]; mat.m[3][2] = m_origin[2]; mat.m[3][3] = 1.0f; #endif } static inline CTransform fromColumns(const CVector3f& m0, const CVector3f& m1, const CVector3f& m2, const CVector3f& m3) { CTransform ret; ret.m_basis[0][0] = m0[0]; ret.m_basis[0][1] = m1[0]; ret.m_basis[0][2] = m2[0]; ret.m_origin[0] = m3[0]; ret.m_basis[1][0] = m0[1]; ret.m_basis[1][1] = m1[1]; ret.m_basis[1][2] = m2[1]; ret.m_origin[1] = m3[1]; ret.m_basis[2][0] = m0[2]; ret.m_basis[2][1] = m1[2]; ret.m_basis[2][2] = m2[2]; ret.m_origin[2] = m3[2]; return ret; } CMatrix3f m_basis; CVector3f m_origin; }; static inline CTransform CTransformFromScaleVector(const CVector3f& scale) { return CTransform(CMatrix3f(scale)); } CTransform CTransformFromEditorEuler(const CVector3f& eulerVec); CTransform CTransformFromEditorEulers(const CVector3f& eulerVec, const CVector3f& origin); CTransform CTransformFromAxisAngle(const CVector3f& axis, float angle); } #endif // CTRANSFORM_HPP