assimp/include/assimp/matrix4x4.inl

678 lines
24 KiB
C++

/*
---------------------------------------------------------------------------
Open Asset Import Library (assimp)
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*/
/** @file matrix4x4.inl
* @brief Inline implementation of the 4x4 matrix operators
*/
#pragma once
#ifndef AI_MATRIX4X4_INL_INC
#define AI_MATRIX4X4_INL_INC
#ifdef __cplusplus
#include "matrix4x4.h"
#include "matrix3x3.h"
#include "quaternion.h"
#include "MathFunctions.h"
#include <algorithm>
#include <limits>
#include <cmath>
// ----------------------------------------------------------------------------------------
template <typename TReal>
aiMatrix4x4t<TReal>::aiMatrix4x4t() AI_NO_EXCEPT :
a1(1.0f), a2(), a3(), a4(),
b1(), b2(1.0f), b3(), b4(),
c1(), c2(), c3(1.0f), c4(),
d1(), d2(), d3(), d4(1.0f) {
// empty
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
aiMatrix4x4t<TReal>::aiMatrix4x4t (TReal _a1, TReal _a2, TReal _a3, TReal _a4,
TReal _b1, TReal _b2, TReal _b3, TReal _b4,
TReal _c1, TReal _c2, TReal _c3, TReal _c4,
TReal _d1, TReal _d2, TReal _d3, TReal _d4) :
a1(_a1), a2(_a2), a3(_a3), a4(_a4),
b1(_b1), b2(_b2), b3(_b3), b4(_b4),
c1(_c1), c2(_c2), c3(_c3), c4(_c4),
d1(_d1), d2(_d2), d3(_d3), d4(_d4) {
// empty
}
// ------------------------------------------------------------------------------------------------
template <typename TReal>
template <typename TOther>
aiMatrix4x4t<TReal>::operator aiMatrix4x4t<TOther> () const {
return aiMatrix4x4t<TOther>(static_cast<TOther>(a1),static_cast<TOther>(a2),static_cast<TOther>(a3),static_cast<TOther>(a4),
static_cast<TOther>(b1),static_cast<TOther>(b2),static_cast<TOther>(b3),static_cast<TOther>(b4),
static_cast<TOther>(c1),static_cast<TOther>(c2),static_cast<TOther>(c3),static_cast<TOther>(c4),
static_cast<TOther>(d1),static_cast<TOther>(d2),static_cast<TOther>(d3),static_cast<TOther>(d4));
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>::aiMatrix4x4t (const aiMatrix3x3t<TReal>& m) {
a1 = m.a1; a2 = m.a2; a3 = m.a3; a4 = static_cast<TReal>(0.0);
b1 = m.b1; b2 = m.b2; b3 = m.b3; b4 = static_cast<TReal>(0.0);
c1 = m.c1; c2 = m.c2; c3 = m.c3; c4 = static_cast<TReal>(0.0);
d1 = static_cast<TReal>(0.0); d2 = static_cast<TReal>(0.0); d3 = static_cast<TReal>(0.0); d4 = static_cast<TReal>(1.0);
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>::aiMatrix4x4t (const aiVector3t<TReal>& scaling, const aiQuaterniont<TReal>& rotation, const aiVector3t<TReal>& position) {
// build a 3x3 rotation matrix
aiMatrix3x3t<TReal> m = rotation.GetMatrix();
a1 = m.a1 * scaling.x;
a2 = m.a2 * scaling.x;
a3 = m.a3 * scaling.x;
a4 = position.x;
b1 = m.b1 * scaling.y;
b2 = m.b2 * scaling.y;
b3 = m.b3 * scaling.y;
b4 = position.y;
c1 = m.c1 * scaling.z;
c2 = m.c2 * scaling.z;
c3 = m.c3 * scaling.z;
c4= position.z;
d1 = static_cast<TReal>(0.0);
d2 = static_cast<TReal>(0.0);
d3 = static_cast<TReal>(0.0);
d4 = static_cast<TReal>(1.0);
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::operator *= (const aiMatrix4x4t<TReal>& m) {
*this = aiMatrix4x4t<TReal>(
m.a1 * a1 + m.b1 * a2 + m.c1 * a3 + m.d1 * a4,
m.a2 * a1 + m.b2 * a2 + m.c2 * a3 + m.d2 * a4,
m.a3 * a1 + m.b3 * a2 + m.c3 * a3 + m.d3 * a4,
m.a4 * a1 + m.b4 * a2 + m.c4 * a3 + m.d4 * a4,
m.a1 * b1 + m.b1 * b2 + m.c1 * b3 + m.d1 * b4,
m.a2 * b1 + m.b2 * b2 + m.c2 * b3 + m.d2 * b4,
m.a3 * b1 + m.b3 * b2 + m.c3 * b3 + m.d3 * b4,
m.a4 * b1 + m.b4 * b2 + m.c4 * b3 + m.d4 * b4,
m.a1 * c1 + m.b1 * c2 + m.c1 * c3 + m.d1 * c4,
m.a2 * c1 + m.b2 * c2 + m.c2 * c3 + m.d2 * c4,
m.a3 * c1 + m.b3 * c2 + m.c3 * c3 + m.d3 * c4,
m.a4 * c1 + m.b4 * c2 + m.c4 * c3 + m.d4 * c4,
m.a1 * d1 + m.b1 * d2 + m.c1 * d3 + m.d1 * d4,
m.a2 * d1 + m.b2 * d2 + m.c2 * d3 + m.d2 * d4,
m.a3 * d1 + m.b3 * d2 + m.c3 * d3 + m.d3 * d4,
m.a4 * d1 + m.b4 * d2 + m.c4 * d3 + m.d4 * d4);
return *this;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE aiMatrix4x4t<TReal> aiMatrix4x4t<TReal>::operator* (const TReal& aFloat) const {
aiMatrix4x4t<TReal> temp(
a1 * aFloat,
a2 * aFloat,
a3 * aFloat,
a4 * aFloat,
b1 * aFloat,
b2 * aFloat,
b3 * aFloat,
b4 * aFloat,
c1 * aFloat,
c2 * aFloat,
c3 * aFloat,
c4 * aFloat,
d1 * aFloat,
d2 * aFloat,
d3 * aFloat,
d4 * aFloat);
return temp;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal> aiMatrix4x4t<TReal>::operator+ (const aiMatrix4x4t<TReal>& m) const {
aiMatrix4x4t<TReal> temp(
m.a1 + a1,
m.a2 + a2,
m.a3 + a3,
m.a4 + a4,
m.b1 + b1,
m.b2 + b2,
m.b3 + b3,
m.b4 + b4,
m.c1 + c1,
m.c2 + c2,
m.c3 + c3,
m.c4 + c4,
m.d1 + d1,
m.d2 + d2,
m.d3 + d3,
m.d4 + d4);
return temp;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal> aiMatrix4x4t<TReal>::operator* (const aiMatrix4x4t<TReal>& m) const {
aiMatrix4x4t<TReal> temp( *this);
temp *= m;
return temp;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::Transpose() {
// (TReal&) don't remove, GCC complains cause of packed fields
std::swap( (TReal&)b1, (TReal&)a2);
std::swap( (TReal&)c1, (TReal&)a3);
std::swap( (TReal&)c2, (TReal&)b3);
std::swap( (TReal&)d1, (TReal&)a4);
std::swap( (TReal&)d2, (TReal&)b4);
std::swap( (TReal&)d3, (TReal&)c4);
return *this;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
TReal aiMatrix4x4t<TReal>::Determinant() const {
return a1*b2*c3*d4 - a1*b2*c4*d3 + a1*b3*c4*d2 - a1*b3*c2*d4
+ a1*b4*c2*d3 - a1*b4*c3*d2 - a2*b3*c4*d1 + a2*b3*c1*d4
- a2*b4*c1*d3 + a2*b4*c3*d1 - a2*b1*c3*d4 + a2*b1*c4*d3
+ a3*b4*c1*d2 - a3*b4*c2*d1 + a3*b1*c2*d4 - a3*b1*c4*d2
+ a3*b2*c4*d1 - a3*b2*c1*d4 - a4*b1*c2*d3 + a4*b1*c3*d2
- a4*b2*c3*d1 + a4*b2*c1*d3 - a4*b3*c1*d2 + a4*b3*c2*d1;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::Inverse() {
// Compute the reciprocal determinant
const TReal det = Determinant();
if(det == static_cast<TReal>(0.0))
{
// Matrix not invertible. Setting all elements to nan is not really
// correct in a mathematical sense but it is easy to debug for the
// programmer.
const TReal nan = std::numeric_limits<TReal>::quiet_NaN();
*this = aiMatrix4x4t<TReal>(
nan,nan,nan,nan,
nan,nan,nan,nan,
nan,nan,nan,nan,
nan,nan,nan,nan);
return *this;
}
const TReal invdet = static_cast<TReal>(1.0) / det;
aiMatrix4x4t<TReal> res;
res.a1 = invdet * (b2 * (c3 * d4 - c4 * d3) + b3 * (c4 * d2 - c2 * d4) + b4 * (c2 * d3 - c3 * d2));
res.a2 = -invdet * (a2 * (c3 * d4 - c4 * d3) + a3 * (c4 * d2 - c2 * d4) + a4 * (c2 * d3 - c3 * d2));
res.a3 = invdet * (a2 * (b3 * d4 - b4 * d3) + a3 * (b4 * d2 - b2 * d4) + a4 * (b2 * d3 - b3 * d2));
res.a4 = -invdet * (a2 * (b3 * c4 - b4 * c3) + a3 * (b4 * c2 - b2 * c4) + a4 * (b2 * c3 - b3 * c2));
res.b1 = -invdet * (b1 * (c3 * d4 - c4 * d3) + b3 * (c4 * d1 - c1 * d4) + b4 * (c1 * d3 - c3 * d1));
res.b2 = invdet * (a1 * (c3 * d4 - c4 * d3) + a3 * (c4 * d1 - c1 * d4) + a4 * (c1 * d3 - c3 * d1));
res.b3 = -invdet * (a1 * (b3 * d4 - b4 * d3) + a3 * (b4 * d1 - b1 * d4) + a4 * (b1 * d3 - b3 * d1));
res.b4 = invdet * (a1 * (b3 * c4 - b4 * c3) + a3 * (b4 * c1 - b1 * c4) + a4 * (b1 * c3 - b3 * c1));
res.c1 = invdet * (b1 * (c2 * d4 - c4 * d2) + b2 * (c4 * d1 - c1 * d4) + b4 * (c1 * d2 - c2 * d1));
res.c2 = -invdet * (a1 * (c2 * d4 - c4 * d2) + a2 * (c4 * d1 - c1 * d4) + a4 * (c1 * d2 - c2 * d1));
res.c3 = invdet * (a1 * (b2 * d4 - b4 * d2) + a2 * (b4 * d1 - b1 * d4) + a4 * (b1 * d2 - b2 * d1));
res.c4 = -invdet * (a1 * (b2 * c4 - b4 * c2) + a2 * (b4 * c1 - b1 * c4) + a4 * (b1 * c2 - b2 * c1));
res.d1 = -invdet * (b1 * (c2 * d3 - c3 * d2) + b2 * (c3 * d1 - c1 * d3) + b3 * (c1 * d2 - c2 * d1));
res.d2 = invdet * (a1 * (c2 * d3 - c3 * d2) + a2 * (c3 * d1 - c1 * d3) + a3 * (c1 * d2 - c2 * d1));
res.d3 = -invdet * (a1 * (b2 * d3 - b3 * d2) + a2 * (b3 * d1 - b1 * d3) + a3 * (b1 * d2 - b2 * d1));
res.d4 = invdet * (a1 * (b2 * c3 - b3 * c2) + a2 * (b3 * c1 - b1 * c3) + a3 * (b1 * c2 - b2 * c1));
*this = res;
return *this;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
TReal* aiMatrix4x4t<TReal>::operator[](unsigned int p_iIndex) {
if (p_iIndex > 3) {
return nullptr;
}
switch ( p_iIndex ) {
case 0:
return &a1;
case 1:
return &b1;
case 2:
return &c1;
case 3:
return &d1;
default:
break;
}
return &a1;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
const TReal* aiMatrix4x4t<TReal>::operator[](unsigned int p_iIndex) const {
if (p_iIndex > 3) {
return nullptr;
}
switch ( p_iIndex ) {
case 0:
return &a1;
case 1:
return &b1;
case 2:
return &c1;
case 3:
return &d1;
default:
break;
}
return &a1;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
bool aiMatrix4x4t<TReal>::operator== (const aiMatrix4x4t<TReal>& m) const {
return (a1 == m.a1 && a2 == m.a2 && a3 == m.a3 && a4 == m.a4 &&
b1 == m.b1 && b2 == m.b2 && b3 == m.b3 && b4 == m.b4 &&
c1 == m.c1 && c2 == m.c2 && c3 == m.c3 && c4 == m.c4 &&
d1 == m.d1 && d2 == m.d2 && d3 == m.d3 && d4 == m.d4);
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
bool aiMatrix4x4t<TReal>::operator!= (const aiMatrix4x4t<TReal>& m) const {
return !(*this == m);
}
// ---------------------------------------------------------------------------
template<typename TReal>
AI_FORCE_INLINE
bool aiMatrix4x4t<TReal>::Equal(const aiMatrix4x4t<TReal>& m, TReal epsilon) const {
return
std::abs(a1 - m.a1) <= epsilon &&
std::abs(a2 - m.a2) <= epsilon &&
std::abs(a3 - m.a3) <= epsilon &&
std::abs(a4 - m.a4) <= epsilon &&
std::abs(b1 - m.b1) <= epsilon &&
std::abs(b2 - m.b2) <= epsilon &&
std::abs(b3 - m.b3) <= epsilon &&
std::abs(b4 - m.b4) <= epsilon &&
std::abs(c1 - m.c1) <= epsilon &&
std::abs(c2 - m.c2) <= epsilon &&
std::abs(c3 - m.c3) <= epsilon &&
std::abs(c4 - m.c4) <= epsilon &&
std::abs(d1 - m.d1) <= epsilon &&
std::abs(d2 - m.d2) <= epsilon &&
std::abs(d3 - m.d3) <= epsilon &&
std::abs(d4 - m.d4) <= epsilon;
}
// ----------------------------------------------------------------------------------------
#define ASSIMP_MATRIX4_4_DECOMPOSE_PART \
const aiMatrix4x4t<TReal>& _this = *this;/* Create alias for conveniance. */ \
\
/* extract translation */ \
pPosition.x = _this[0][3]; \
pPosition.y = _this[1][3]; \
pPosition.z = _this[2][3]; \
\
/* extract the columns of the matrix. */ \
aiVector3t<TReal> vCols[3] = { \
aiVector3t<TReal>(_this[0][0],_this[1][0],_this[2][0]), \
aiVector3t<TReal>(_this[0][1],_this[1][1],_this[2][1]), \
aiVector3t<TReal>(_this[0][2],_this[1][2],_this[2][2]) \
}; \
\
/* extract the scaling factors */ \
pScaling.x = vCols[0].Length(); \
pScaling.y = vCols[1].Length(); \
pScaling.z = vCols[2].Length(); \
\
/* and the sign of the scaling */ \
if (Determinant() < 0) pScaling = -pScaling; \
\
/* and remove all scaling from the matrix */ \
if(pScaling.x) vCols[0] /= pScaling.x; \
if(pScaling.y) vCols[1] /= pScaling.y; \
if(pScaling.z) vCols[2] /= pScaling.z; \
\
do {} while(false)
template <typename TReal>
AI_FORCE_INLINE
void aiMatrix4x4t<TReal>::Decompose (aiVector3t<TReal>& pScaling, aiQuaterniont<TReal>& pRotation,
aiVector3t<TReal>& pPosition) const {
ASSIMP_MATRIX4_4_DECOMPOSE_PART;
// build a 3x3 rotation matrix
aiMatrix3x3t<TReal> m(vCols[0].x,vCols[1].x,vCols[2].x,
vCols[0].y,vCols[1].y,vCols[2].y,
vCols[0].z,vCols[1].z,vCols[2].z);
// and generate the rotation quaternion from it
pRotation = aiQuaterniont<TReal>(m);
}
template <typename TReal>
AI_FORCE_INLINE
void aiMatrix4x4t<TReal>::Decompose(aiVector3t<TReal>& pScaling, aiVector3t<TReal>& pRotation, aiVector3t<TReal>& pPosition) const {
ASSIMP_MATRIX4_4_DECOMPOSE_PART;
/*
assuming a right-handed coordinate system
and post-multiplication of column vectors,
the rotation matrix for an euler XYZ rotation is M = Rz * Ry * Rx.
combining gives:
| CE BDE-AF ADE+BF 0 |
M = | CF BDF+AE ADF-BE 0 |
| -D CB AC 0 |
| 0 0 0 1 |
where
A = cos(angle_x), B = sin(angle_x);
C = cos(angle_y), D = sin(angle_y);
E = cos(angle_z), F = sin(angle_z);
*/
// Use a small epsilon to solve floating-point inaccuracies
const TReal epsilon = Assimp::Math::getEpsilon<TReal>();
pRotation.y = std::asin(-vCols[0].z);// D. Angle around oY.
TReal C = std::cos(pRotation.y);
if(std::fabs(C) > epsilon)
{
// Finding angle around oX.
TReal tan_x = vCols[2].z / C;// A
TReal tan_y = vCols[1].z / C;// B
pRotation.x = std::atan2(tan_y, tan_x);
// Finding angle around oZ.
tan_x = vCols[0].x / C;// E
tan_y = vCols[0].y / C;// F
pRotation.z = std::atan2(tan_y, tan_x);
}
else
{// oY is fixed.
pRotation.x = 0;// Set angle around oX to 0. => A == 1, B == 0, C == 0, D == 1.
// And finding angle around oZ.
TReal tan_x = vCols[1].y;// BDF+AE => E
TReal tan_y = -vCols[1].x;// BDE-AF => F
pRotation.z = std::atan2(tan_y, tan_x);
}
}
#undef ASSIMP_MATRIX4_4_DECOMPOSE_PART
template <typename TReal>
AI_FORCE_INLINE
void aiMatrix4x4t<TReal>::Decompose(aiVector3t<TReal>& pScaling, aiVector3t<TReal>& pRotationAxis, TReal& pRotationAngle,
aiVector3t<TReal>& pPosition) const {
aiQuaterniont<TReal> pRotation;
Decompose(pScaling, pRotation, pPosition);
pRotation.Normalize();
TReal angle_cos = pRotation.w;
TReal angle_sin = std::sqrt(1.0f - angle_cos * angle_cos);
pRotationAngle = std::acos(angle_cos) * 2;
// Use a small epsilon to solve floating-point inaccuracies
const TReal epsilon = 10e-3f;
if(std::fabs(angle_sin) < epsilon) angle_sin = 1;
pRotationAxis.x = pRotation.x / angle_sin;
pRotationAxis.y = pRotation.y / angle_sin;
pRotationAxis.z = pRotation.z / angle_sin;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
void aiMatrix4x4t<TReal>::DecomposeNoScaling (aiQuaterniont<TReal>& rotation,
aiVector3t<TReal>& position) const {
const aiMatrix4x4t<TReal>& _this = *this;
// extract translation
position.x = _this[0][3];
position.y = _this[1][3];
position.z = _this[2][3];
// extract rotation
rotation = aiQuaterniont<TReal>((aiMatrix3x3t<TReal>)_this);
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::FromEulerAnglesXYZ(const aiVector3t<TReal>& blubb) {
return FromEulerAnglesXYZ(blubb.x,blubb.y,blubb.z);
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::FromEulerAnglesXYZ(TReal x, TReal y, TReal z) {
aiMatrix4x4t<TReal>& _this = *this;
TReal cx = std::cos(x);
TReal sx = std::sin(x);
TReal cy = std::cos(y);
TReal sy = std::sin(y);
TReal cz = std::cos(z);
TReal sz = std::sin(z);
// mz*my*mx
_this.a1 = cz * cy;
_this.a2 = cz * sy * sx - sz * cx;
_this.a3 = sz * sx + cz * sy * cx;
_this.b1 = sz * cy;
_this.b2 = cz * cx + sz * sy * sx;
_this.b3 = sz * sy * cx - cz * sx;
_this.c1 = -sy;
_this.c2 = cy * sx;
_this.c3 = cy * cx;
return *this;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
bool aiMatrix4x4t<TReal>::IsIdentity() const {
// Use a small epsilon to solve floating-point inaccuracies
const static TReal epsilon = 10e-3f;
return (a2 <= epsilon && a2 >= -epsilon &&
a3 <= epsilon && a3 >= -epsilon &&
a4 <= epsilon && a4 >= -epsilon &&
b1 <= epsilon && b1 >= -epsilon &&
b3 <= epsilon && b3 >= -epsilon &&
b4 <= epsilon && b4 >= -epsilon &&
c1 <= epsilon && c1 >= -epsilon &&
c2 <= epsilon && c2 >= -epsilon &&
c4 <= epsilon && c4 >= -epsilon &&
d1 <= epsilon && d1 >= -epsilon &&
d2 <= epsilon && d2 >= -epsilon &&
d3 <= epsilon && d3 >= -epsilon &&
a1 <= 1.f+epsilon && a1 >= 1.f-epsilon &&
b2 <= 1.f+epsilon && b2 >= 1.f-epsilon &&
c3 <= 1.f+epsilon && c3 >= 1.f-epsilon &&
d4 <= 1.f+epsilon && d4 >= 1.f-epsilon);
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::RotationX(TReal a, aiMatrix4x4t<TReal>& out) {
/*
| 1 0 0 0 |
M = | 0 cos(A) -sin(A) 0 |
| 0 sin(A) cos(A) 0 |
| 0 0 0 1 | */
out = aiMatrix4x4t<TReal>();
out.b2 = out.c3 = std::cos(a);
out.b3 = -(out.c2 = std::sin(a));
return out;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::RotationY(TReal a, aiMatrix4x4t<TReal>& out) {
/*
| cos(A) 0 sin(A) 0 |
M = | 0 1 0 0 |
| -sin(A) 0 cos(A) 0 |
| 0 0 0 1 |
*/
out = aiMatrix4x4t<TReal>();
out.a1 = out.c3 = std::cos(a);
out.c1 = -(out.a3 = std::sin(a));
return out;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::RotationZ(TReal a, aiMatrix4x4t<TReal>& out) {
/*
| cos(A) -sin(A) 0 0 |
M = | sin(A) cos(A) 0 0 |
| 0 0 1 0 |
| 0 0 0 1 | */
out = aiMatrix4x4t<TReal>();
out.a1 = out.b2 = std::cos(a);
out.a2 = -(out.b1 = std::sin(a));
return out;
}
// ----------------------------------------------------------------------------------------
// Returns a rotation matrix for a rotation around an arbitrary axis.
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::Rotation( TReal a, const aiVector3t<TReal>& axis, aiMatrix4x4t<TReal>& out) {
TReal c = std::cos( a), s = std::sin( a), t = 1 - c;
TReal x = axis.x, y = axis.y, z = axis.z;
// Many thanks to MathWorld and Wikipedia
out.a1 = t*x*x + c; out.a2 = t*x*y - s*z; out.a3 = t*x*z + s*y;
out.b1 = t*x*y + s*z; out.b2 = t*y*y + c; out.b3 = t*y*z - s*x;
out.c1 = t*x*z - s*y; out.c2 = t*y*z + s*x; out.c3 = t*z*z + c;
out.a4 = out.b4 = out.c4 = static_cast<TReal>(0.0);
out.d1 = out.d2 = out.d3 = static_cast<TReal>(0.0);
out.d4 = static_cast<TReal>(1.0);
return out;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::Translation( const aiVector3t<TReal>& v, aiMatrix4x4t<TReal>& out) {
out = aiMatrix4x4t<TReal>();
out.a4 = v.x;
out.b4 = v.y;
out.c4 = v.z;
return out;
}
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::Scaling( const aiVector3t<TReal>& v, aiMatrix4x4t<TReal>& out) {
out = aiMatrix4x4t<TReal>();
out.a1 = v.x;
out.b2 = v.y;
out.c3 = v.z;
return out;
}
// ----------------------------------------------------------------------------------------
/** A function for creating a rotation matrix that rotates a vector called
* "from" into another vector called "to".
* Input : from[3], to[3] which both must be *normalized* non-zero vectors
* Output: mtx[3][3] -- a 3x3 matrix in colum-major form
* Authors: Tomas Möller, John Hughes
* "Efficiently Building a Matrix to Rotate One Vector to Another"
* Journal of Graphics Tools, 4(4):1-4, 1999
*/
// ----------------------------------------------------------------------------------------
template <typename TReal>
AI_FORCE_INLINE
aiMatrix4x4t<TReal>& aiMatrix4x4t<TReal>::FromToMatrix(const aiVector3t<TReal>& from,
const aiVector3t<TReal>& to, aiMatrix4x4t<TReal>& mtx) {
aiMatrix3x3t<TReal> m3;
aiMatrix3x3t<TReal>::FromToMatrix(from,to,m3);
mtx = aiMatrix4x4t<TReal>(m3);
return mtx;
}
#endif // __cplusplus
#endif // AI_MATRIX4X4_INL_INC