#include "common.h"
CMatrix::CMatrix(void)
{
m_attachment = nil;
m_hasRwMatrix = false;
}
CMatrix::CMatrix(CMatrix const &m)
{
m_attachment = nil;
m_hasRwMatrix = false;
*this = m;
}
CMatrix::CMatrix(RwMatrix *matrix, bool owner)
{
m_attachment = nil;
Attach(matrix, owner);
}
CMatrix::~CMatrix(void)
{
if (m_hasRwMatrix && m_attachment)
RwMatrixDestroy(m_attachment);
}
void
CMatrix::Attach(RwMatrix *matrix, bool owner)
{
#ifdef FIX_BUGS
if (m_attachment && m_hasRwMatrix)
#else
if (m_hasRwMatrix && m_attachment)
#endif
RwMatrixDestroy(m_attachment);
m_attachment = matrix;
m_hasRwMatrix = owner;
Update();
}
void
CMatrix::AttachRW(RwMatrix *matrix, bool owner)
{
if (m_hasRwMatrix && m_attachment)
RwMatrixDestroy(m_attachment);
m_attachment = matrix;
m_hasRwMatrix = owner;
UpdateRW();
}
void
CMatrix::Detach(void)
{
if (m_hasRwMatrix && m_attachment)
RwMatrixDestroy(m_attachment);
m_attachment = nil;
}
void
CMatrix::Update(void)
{
GetRight() = m_attachment->right;
GetForward() = m_attachment->up;
GetUp() = m_attachment->at;
GetPosition() = m_attachment->pos;
}
void
CMatrix::UpdateRW(void)
{
if (m_attachment) {
m_attachment->right = GetRight();
m_attachment->up = GetForward();
m_attachment->at = GetUp();
m_attachment->pos = GetPosition();
RwMatrixUpdate(m_attachment);
}
}
void
CMatrix::operator=(CMatrix const &rhs)
{
memcpy(this, &rhs, sizeof(f));
if (m_attachment)
UpdateRW();
}
void
CMatrix::CopyOnlyMatrix(const CMatrix &other)
{
memcpy(this, &other, sizeof(f));
}
CMatrix &
CMatrix::operator+=(CMatrix const &rhs)
{
GetRight() += rhs.GetRight();
GetForward() += rhs.GetForward();
GetUp() += rhs.GetUp();
GetPosition() += rhs.GetPosition();
return *this;
}
void
CMatrix::SetUnity(void)
{
rx = 1.0f;
ry = 0.0f;
rz = 0.0f;
fx = 0.0f;
fy = 1.0f;
fz = 0.0f;
ux = 0.0f;
uy = 0.0f;
uz = 1.0f;
px = 0.0f;
py = 0.0f;
pz = 0.0f;
}
void
CMatrix::ResetOrientation(void)
{
rx = 1.0f;
ry = 0.0f;
rz = 0.0f;
fx = 0.0f;
fy = 1.0f;
fz = 0.0f;
ux = 0.0f;
uy = 0.0f;
uz = 1.0f;
}
void
CMatrix::SetScale(float s)
{
rx = s;
ry = 0.0f;
rz = 0.0f;
fx = 0.0f;
fy = s;
fz = 0.0f;
ux = 0.0f;
uy = 0.0f;
uz = s;
px = 0.0f;
py = 0.0f;
pz = 0.0f;
}
void
CMatrix::SetTranslate(float x, float y, float z)
{
rx = 1.0f;
ry = 0.0f;
rz = 0.0f;
fx = 0.0f;
fy = 1.0f;
fz = 0.0f;
ux = 0.0f;
uy = 0.0f;
uz = 1.0f;
px = x;
py = y;
pz = z;
}
void
CMatrix::SetRotateXOnly(float angle)
{
float c = Cos(angle);
float s = Sin(angle);
rx = 1.0f;
ry = 0.0f;
rz = 0.0f;
fx = 0.0f;
fy = c;
fz = s;
ux = 0.0f;
uy = -s;
uz = c;
}
void
CMatrix::SetRotateYOnly(float angle)
{
float c = Cos(angle);
float s = Sin(angle);
rx = c;
ry = 0.0f;
rz = -s;
fx = 0.0f;
fy = 1.0f;
fz = 0.0f;
ux = s;
uy = 0.0f;
uz = c;
}
void
CMatrix::SetRotateZOnly(float angle)
{
float c = Cos(angle);
float s = Sin(angle);
rx = c;
ry = s;
rz = 0.0f;
fx = -s;
fy = c;
fz = 0.0f;
ux = 0.0f;
uy = 0.0f;
uz = 1.0f;
}
void
CMatrix::SetRotateX(float angle)
{
SetRotateXOnly(angle);
px = 0.0f;
py = 0.0f;
pz = 0.0f;
}
void
CMatrix::SetRotateY(float angle)
{
SetRotateYOnly(angle);
px = 0.0f;
py = 0.0f;
pz = 0.0f;
}
void
CMatrix::SetRotateZ(float angle)
{
SetRotateZOnly(angle);
px = 0.0f;
py = 0.0f;
pz = 0.0f;
}
void
CMatrix::SetRotate(float xAngle, float yAngle, float zAngle)
{
float cX = Cos(xAngle);
float sX = Sin(xAngle);
float cY = Cos(yAngle);
float sY = Sin(yAngle);
float cZ = Cos(zAngle);
float sZ = Sin(zAngle);
rx = cZ * cY - (sZ * sX) * sY;
ry = (cZ * sX) * sY + sZ * cY;
rz = -cX * sY;
fx = -sZ * cX;
fy = cZ * cX;
fz = sX;
ux = (sZ * sX) * cY + cZ * sY;
uy = sZ * sY - (cZ * sX) * cY;
uz = cX * cY;
px = 0.0f;
py = 0.0f;
pz = 0.0f;
}
void
CMatrix::RotateX(float x)
{
float c = Cos(x);
float s = Sin(x);
float ry = this->ry;
float rz = this->rz;
float uy = this->fy;
float uz = this->fz;
float ay = this->uy;
float az = this->uz;
float py = this->py;
float pz = this->pz;
this->ry = c * ry - s * rz;
this->rz = c * rz + s * ry;
this->fy = c * uy - s * uz;
this->fz = c * uz + s * uy;
this->uy = c * ay - s * az;
this->uz = c * az + s * ay;
this->py = c * py - s * pz;
this->pz = c * pz + s * py;
}
void
CMatrix::RotateY(float y)
{
float c = Cos(y);
float s = Sin(y);
float rx = this->rx;
float rz = this->rz;
float ux = this->fx;
float uz = this->fz;
float ax = this->ux;
float az = this->uz;
float px = this->px;
float pz = this->pz;
this->rx = c * rx + s * rz;
this->rz = c * rz - s * rx;
this->fx = c * ux + s * uz;
this->fz = c * uz - s * ux;
this->ux = c * ax + s * az;
this->uz = c * az - s * ax;
this->px = c * px + s * pz;
this->pz = c * pz - s * px;
}
void
CMatrix::RotateZ(float z)
{
float c = Cos(z);
float s = Sin(z);
float ry = this->ry;
float rx = this->rx;
float uy = this->fy;
float ux = this->fx;
float ay = this->uy;
float ax = this->ux;
float py = this->py;
float px = this->px;
this->rx = c * rx - s * ry;
this->ry = c * ry + s * rx;
this->fx = c * ux - s * uy;
this->fy = c * uy + s * ux;
this->ux = c * ax - s * ay;
this->uy = c * ay + s * ax;
this->px = c * px - s * py;
this->py = c * py + s * px;
}
void
CMatrix::Rotate(float x, float y, float z)
{
float cX = Cos(x);
float sX = Sin(x);
float cY = Cos(y);
float sY = Sin(y);
float cZ = Cos(z);
float sZ = Sin(z);
float rx = this->rx;
float ry = this->ry;
float rz = this->rz;
float ux = this->fx;
float uy = this->fy;
float uz = this->fz;
float ax = this->ux;
float ay = this->uy;
float az = this->uz;
float px = this->px;
float py = this->py;
float pz = this->pz;
float x1 = cZ * cY - (sZ * sX) * sY;
float x2 = (cZ * sX) * sY + sZ * cY;
float x3 = -cX * sY;
float y1 = -sZ * cX;
float y2 = cZ * cX;
float y3 = sX;
float z1 = (sZ * sX) * cY + cZ * sY;
float z2 = sZ * sY - (cZ * sX) * cY;
float z3 = cX * cY;
this->rx = x1 * rx + y1 * ry + z1 * rz;
this->ry = x2 * rx + y2 * ry + z2 * rz;
this->rz = x3 * rx + y3 * ry + z3 * rz;
this->fx = x1 * ux + y1 * uy + z1 * uz;
this->fy = x2 * ux + y2 * uy + z2 * uz;
this->fz = x3 * ux + y3 * uy + z3 * uz;
this->ux = x1 * ax + y1 * ay + z1 * az;
this->uy = x2 * ax + y2 * ay + z2 * az;
this->uz = x3 * ax + y3 * ay + z3 * az;
this->px = x1 * px + y1 * py + z1 * pz;
this->py = x2 * px + y2 * py + z2 * pz;
this->pz = x3 * px + y3 * py + z3 * pz;
}
CMatrix &
CMatrix::operator*=(CMatrix const &rhs)
{
// TODO: VU0 code
*this = *this * rhs;
return *this;
}
void
CMatrix::Reorthogonalise(void)
{
CVector &r = GetRight();
CVector &f = GetForward();
CVector &u = GetUp();
u = CrossProduct(r, f);
u.Normalise();
r = CrossProduct(f, u);
r.Normalise();
f = CrossProduct(u, r);
}
CMatrix
operator*(const CMatrix &m1, const CMatrix &m2)
{
// TODO: VU0 code
CMatrix out;
out.rx = m1.rx * m2.rx + m1.fx * m2.ry + m1.ux * m2.rz;
out.ry = m1.ry * m2.rx + m1.fy * m2.ry + m1.uy * m2.rz;
out.rz = m1.rz * m2.rx + m1.fz * m2.ry + m1.uz * m2.rz;
out.fx = m1.rx * m2.fx + m1.fx * m2.fy + m1.ux * m2.fz;
out.fy = m1.ry * m2.fx + m1.fy * m2.fy + m1.uy * m2.fz;
out.fz = m1.rz * m2.fx + m1.fz * m2.fy + m1.uz * m2.fz;
out.ux = m1.rx * m2.ux + m1.fx * m2.uy + m1.ux * m2.uz;
out.uy = m1.ry * m2.ux + m1.fy * m2.uy + m1.uy * m2.uz;
out.uz = m1.rz * m2.ux + m1.fz * m2.uy + m1.uz * m2.uz;
out.px = m1.rx * m2.px + m1.fx * m2.py + m1.ux * m2.pz + m1.px;
out.py = m1.ry * m2.px + m1.fy * m2.py + m1.uy * m2.pz + m1.py;
out.pz = m1.rz * m2.px + m1.fz * m2.py + m1.uz * m2.pz + m1.pz;
return out;
}
CMatrix &
Invert(const CMatrix &src, CMatrix &dst)
{
// TODO: VU0 code
// GTA handles this as a raw 4x4 orthonormal matrix
// and trashes the RW flags, let's not do that
dst.f[3][0] = dst.f[3][1] = dst.f[3][2] = 0.0f;
#ifndef FIX_BUGS
dst.f[3][3] = src.f[3][3];
#endif
dst.f[0][0] = src.f[0][0];
dst.f[0][1] = src.f[1][0];
dst.f[0][2] = src.f[2][0];
#ifndef FIX_BUGS
dst.f[0][3] = src.f[3][0];
#endif
dst.f[1][0] = src.f[0][1];
dst.f[1][1] = src.f[1][1];
dst.f[1][2] = src.f[2][1];
#ifndef FIX_BUGS
dst.f[1][3] = src.f[3][1];
#endif
dst.f[2][0] = src.f[0][2];
dst.f[2][1] = src.f[1][2];
dst.f[2][2] = src.f[2][2];
#ifndef FIX_BUGS
dst.f[2][3] = src.f[3][2];
#endif
dst.f[3][0] += dst.f[0][0] * src.f[3][0];
dst.f[3][1] += dst.f[0][1] * src.f[3][0];
dst.f[3][2] += dst.f[0][2] * src.f[3][0];
#ifndef FIX_BUGS
dst.f[3][3] += dst.f[0][3] * src.f[3][0];
#endif
dst.f[3][0] += dst.f[1][0] * src.f[3][1];
dst.f[3][1] += dst.f[1][1] * src.f[3][1];
dst.f[3][2] += dst.f[1][2] * src.f[3][1];
#ifndef FIX_BUGS
dst.f[3][3] += dst.f[1][3] * src.f[3][1];
#endif
dst.f[3][0] += dst.f[2][0] * src.f[3][2];
dst.f[3][1] += dst.f[2][1] * src.f[3][2];
dst.f[3][2] += dst.f[2][2] * src.f[3][2];
#ifndef FIX_BUGS
dst.f[3][3] += dst.f[2][3] * src.f[3][2];
#endif
dst.f[3][0] = -dst.f[3][0];
dst.f[3][1] = -dst.f[3][1];
dst.f[3][2] = -dst.f[3][2];
#ifndef FIX_BUGS
dst.f[3][3] = src.f[3][3] - dst.f[3][3];
#endif
return dst;
}
CMatrix
Invert(const CMatrix &matrix)
{
CMatrix inv;
return Invert(matrix, inv);
}
void
CCompressedMatrixNotAligned::CompressFromFullMatrix(CMatrix &other)
{
m_rightX = 127.0f * other.GetRight().x;
m_rightY = 127.0f * other.GetRight().y;
m_rightZ = 127.0f * other.GetRight().z;
m_upX = 127.0f * other.GetForward().x;
m_upY = 127.0f * other.GetForward().y;
m_upZ = 127.0f * other.GetForward().z;
m_vecPos = other.GetPosition();
}
void
CCompressedMatrixNotAligned::DecompressIntoFullMatrix(CMatrix &other)
{
other.GetRight().x = m_rightX / 127.0f;
other.GetRight().y = m_rightY / 127.0f;
other.GetRight().z = m_rightZ / 127.0f;
other.GetForward().x = m_upX / 127.0f;
other.GetForward().y = m_upY / 127.0f;
other.GetForward().z = m_upZ / 127.0f;
other.GetUp() = CrossProduct(other.GetRight(), other.GetForward());
other.GetPosition() = m_vecPos;
other.Reorthogonalise();
}