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Revision 39b13612ebd645a65eda854771b517371f2f858a authored by ennetws on 13 March 2015, 18:17:18 UTC, committed by ennetws on 13 March 2015, 18:17:18 UTC
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Tip revision: 39b13612ebd645a65eda854771b517371f2f858a authored by ennetws on 13 March 2015, 18:17:18 UTC
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OBB_Volume_math.h
#pragma once
#define REAL double
const float FM_PI = 3.1415926535897932384626433832795028841971693993751f;
const float FM_DEG_TO_RAD = ((2.0f * FM_PI) / 360.0f);
const float FM_RAD_TO_DEG = (360.0f / (2.0f * FM_PI));
#include <float.h>
#include <math.h>
static REAL fm_dot(const REAL *p1,const REAL *p2)
{
return p1[0]*p2[0]+p1[1]*p2[1]+p1[2]*p2[2];
}
static void fm_cross(REAL *cross,const REAL *a,const REAL *b)
{
cross[0] = a[1]*b[2] - a[2]*b[1];
cross[1] = a[2]*b[0] - a[0]*b[2];
cross[2] = a[0]*b[1] - a[1]*b[0];
}
static REAL fm_normalize(REAL *n) // normalize this vector
{
REAL dist = (REAL)sqrt(n[0]*n[0] + n[1]*n[1] + n[2]*n[2]);
if ( dist > 0.0000001f )
{
REAL mag = 1.0f / dist;
n[0]*=mag;
n[1]*=mag;
n[2]*=mag;
}
else
{
n[0] = 1;
n[1] = 0;
n[2] = 0;
}
return dist;
}
static void fm_matrixMultiply(const REAL *pA,const REAL *pB,REAL *pM)
{
#if 1
REAL a = pA[0*4+0] * pB[0*4+0] + pA[0*4+1] * pB[1*4+0] + pA[0*4+2] * pB[2*4+0] + pA[0*4+3] * pB[3*4+0];
REAL b = pA[0*4+0] * pB[0*4+1] + pA[0*4+1] * pB[1*4+1] + pA[0*4+2] * pB[2*4+1] + pA[0*4+3] * pB[3*4+1];
REAL c = pA[0*4+0] * pB[0*4+2] + pA[0*4+1] * pB[1*4+2] + pA[0*4+2] * pB[2*4+2] + pA[0*4+3] * pB[3*4+2];
REAL d = pA[0*4+0] * pB[0*4+3] + pA[0*4+1] * pB[1*4+3] + pA[0*4+2] * pB[2*4+3] + pA[0*4+3] * pB[3*4+3];
REAL e = pA[1*4+0] * pB[0*4+0] + pA[1*4+1] * pB[1*4+0] + pA[1*4+2] * pB[2*4+0] + pA[1*4+3] * pB[3*4+0];
REAL f = pA[1*4+0] * pB[0*4+1] + pA[1*4+1] * pB[1*4+1] + pA[1*4+2] * pB[2*4+1] + pA[1*4+3] * pB[3*4+1];
REAL g = pA[1*4+0] * pB[0*4+2] + pA[1*4+1] * pB[1*4+2] + pA[1*4+2] * pB[2*4+2] + pA[1*4+3] * pB[3*4+2];
REAL h = pA[1*4+0] * pB[0*4+3] + pA[1*4+1] * pB[1*4+3] + pA[1*4+2] * pB[2*4+3] + pA[1*4+3] * pB[3*4+3];
REAL i = pA[2*4+0] * pB[0*4+0] + pA[2*4+1] * pB[1*4+0] + pA[2*4+2] * pB[2*4+0] + pA[2*4+3] * pB[3*4+0];
REAL j = pA[2*4+0] * pB[0*4+1] + pA[2*4+1] * pB[1*4+1] + pA[2*4+2] * pB[2*4+1] + pA[2*4+3] * pB[3*4+1];
REAL k = pA[2*4+0] * pB[0*4+2] + pA[2*4+1] * pB[1*4+2] + pA[2*4+2] * pB[2*4+2] + pA[2*4+3] * pB[3*4+2];
REAL l = pA[2*4+0] * pB[0*4+3] + pA[2*4+1] * pB[1*4+3] + pA[2*4+2] * pB[2*4+3] + pA[2*4+3] * pB[3*4+3];
REAL m = pA[3*4+0] * pB[0*4+0] + pA[3*4+1] * pB[1*4+0] + pA[3*4+2] * pB[2*4+0] + pA[3*4+3] * pB[3*4+0];
REAL n = pA[3*4+0] * pB[0*4+1] + pA[3*4+1] * pB[1*4+1] + pA[3*4+2] * pB[2*4+1] + pA[3*4+3] * pB[3*4+1];
REAL o = pA[3*4+0] * pB[0*4+2] + pA[3*4+1] * pB[1*4+2] + pA[3*4+2] * pB[2*4+2] + pA[3*4+3] * pB[3*4+2];
REAL p = pA[3*4+0] * pB[0*4+3] + pA[3*4+1] * pB[1*4+3] + pA[3*4+2] * pB[2*4+3] + pA[3*4+3] * pB[3*4+3];
pM[0] = a;
pM[1] = b;
pM[2] = c;
pM[3] = d;
pM[4] = e;
pM[5] = f;
pM[6] = g;
pM[7] = h;
pM[8] = i;
pM[9] = j;
pM[10] = k;
pM[11] = l;
pM[12] = m;
pM[13] = n;
pM[14] = o;
pM[15] = p;
#else
memset(pM, 0, sizeof(REAL)*16);
for(int i=0; i<4; i++ )
for(int j=0; j<4; j++ )
for(int k=0; k<4; k++ )
pM[4*i+j] += pA[4*i+k] * pB[4*k+j];
#endif
}
// inverse rotate translate the point.
static void fm_inverseRT(const REAL matrix[16],const REAL pos[3],REAL t[3])
{
REAL _x = pos[0] - matrix[3*4+0];
REAL _y = pos[1] - matrix[3*4+1];
REAL _z = pos[2] - matrix[3*4+2];
// Multiply inverse-translated source vector by inverted rotation transform
t[0] = (matrix[0*4+0] * _x) + (matrix[0*4+1] * _y) + (matrix[0*4+2] * _z);
t[1] = (matrix[1*4+0] * _x) + (matrix[1*4+1] * _y) + (matrix[1*4+2] * _z);
t[2] = (matrix[2*4+0] * _x) + (matrix[2*4+1] * _y) + (matrix[2*4+2] * _z);
}
// rotate and translate this point
static void fm_rotate(const REAL matrix[16],const REAL v[3],REAL t[3])
{
if ( matrix )
{
REAL tx = (matrix[0*4+0] * v[0]) + (matrix[1*4+0] * v[1]) + (matrix[2*4+0] * v[2]);
REAL ty = (matrix[0*4+1] * v[0]) + (matrix[1*4+1] * v[1]) + (matrix[2*4+1] * v[2]);
REAL tz = (matrix[0*4+2] * v[0]) + (matrix[1*4+2] * v[1]) + (matrix[2*4+2] * v[2]);
t[0] = tx;
t[1] = ty;
t[2] = tz;
}
else
{
t[0] = v[0];
t[1] = v[1];
t[2] = v[2];
}
}
template <class Type> class fm_Eigen
{
public:
void DecrSortEigenStuff(void)
{
Tridiagonal(); //diagonalize the matrix.
QLAlgorithm(); //
DecreasingSort();
GuaranteeRotation();
}
void Tridiagonal(void)
{
Type fM00 = mElement[0][0];
Type fM01 = mElement[0][1];
Type fM02 = mElement[0][2];
Type fM11 = mElement[1][1];
Type fM12 = mElement[1][2];
Type fM22 = mElement[2][2];
m_afDiag[0] = fM00;
m_afSubd[2] = 0;
if (fM02 != (Type)0.0)
{
Type fLength = sqrt(fM01*fM01+fM02*fM02);
Type fInvLength = ((Type)1.0)/fLength;
fM01 *= fInvLength;
fM02 *= fInvLength;
Type fQ = ((Type)2.0)*fM01*fM12+fM02*(fM22-fM11);
m_afDiag[1] = fM11+fM02*fQ;
m_afDiag[2] = fM22-fM02*fQ;
m_afSubd[0] = fLength;
m_afSubd[1] = fM12-fM01*fQ;
mElement[0][0] = (Type)1.0;
mElement[0][1] = (Type)0.0;
mElement[0][2] = (Type)0.0;
mElement[1][0] = (Type)0.0;
mElement[1][1] = fM01;
mElement[1][2] = fM02;
mElement[2][0] = (Type)0.0;
mElement[2][1] = fM02;
mElement[2][2] = -fM01;
m_bIsRotation = false;
}
else
{
m_afDiag[1] = fM11;
m_afDiag[2] = fM22;
m_afSubd[0] = fM01;
m_afSubd[1] = fM12;
mElement[0][0] = (Type)1.0;
mElement[0][1] = (Type)0.0;
mElement[0][2] = (Type)0.0;
mElement[1][0] = (Type)0.0;
mElement[1][1] = (Type)1.0;
mElement[1][2] = (Type)0.0;
mElement[2][0] = (Type)0.0;
mElement[2][1] = (Type)0.0;
mElement[2][2] = (Type)1.0;
m_bIsRotation = true;
}
}
bool QLAlgorithm(void)
{
const int iMaxIter = 32;
for (int i0 = 0; i0 <3; i0++)
{
int i1;
for (i1 = 0; i1 < iMaxIter; i1++)
{
int i2;
for (i2 = i0; i2 <= (3-2); i2++)
{
Type fTmp = fabs(m_afDiag[i2]) + fabs(m_afDiag[i2+1]);
if ( fabs(m_afSubd[i2]) + fTmp == fTmp )
break;
}
if (i2 == i0)
{
break;
}
Type fG = (m_afDiag[i0+1] - m_afDiag[i0])/(((Type)2.0) * m_afSubd[i0]);
Type fR = sqrt(fG*fG+(Type)1.0);
if (fG < (Type)0.0)
{
fG = m_afDiag[i2]-m_afDiag[i0]+m_afSubd[i0]/(fG-fR);
}
else
{
fG = m_afDiag[i2]-m_afDiag[i0]+m_afSubd[i0]/(fG+fR);
}
Type fSin = (Type)1.0, fCos = (Type)1.0, fP = (Type)0.0;
for (int i3 = i2-1; i3 >= i0; i3--)
{
Type fF = fSin*m_afSubd[i3];
Type fB = fCos*m_afSubd[i3];
if (fabs(fF) >= fabs(fG))
{
fCos = fG/fF;
fR = sqrt(fCos*fCos+(Type)1.0);
m_afSubd[i3+1] = fF*fR;
fSin = ((Type)1.0)/fR;
fCos *= fSin;
}
else
{
fSin = fF/fG;
fR = sqrt(fSin*fSin+(Type)1.0);
m_afSubd[i3+1] = fG*fR;
fCos = ((Type)1.0)/fR;
fSin *= fCos;
}
fG = m_afDiag[i3+1]-fP;
fR = (m_afDiag[i3]-fG)*fSin+((Type)2.0)*fB*fCos;
fP = fSin*fR;
m_afDiag[i3+1] = fG+fP;
fG = fCos*fR-fB;
for (int i4 = 0; i4 < 3; i4++)
{
fF = mElement[i4][i3+1];
mElement[i4][i3+1] = fSin*mElement[i4][i3]+fCos*fF;
mElement[i4][i3] = fCos*mElement[i4][i3]-fSin*fF;
}
}
m_afDiag[i0] -= fP;
m_afSubd[i0] = fG;
m_afSubd[i2] = (Type)0.0;
}
if (i1 == iMaxIter)
{
return false;
}
}
return true;
}
void DecreasingSort(void)
{
//sort eigenvalues in decreasing order, e[0] >= ... >= e[iSize-1]
for (int i0 = 0, i1; i0 <= 3-2; i0++)
{
// locate maximum eigenvalue
i1 = i0;
Type fMax = m_afDiag[i1];
int i2;
for (i2 = i0+1; i2 < 3; i2++)
{
if (m_afDiag[i2] > fMax)
{
i1 = i2;
fMax = m_afDiag[i1];
}
}
if (i1 != i0)
{
// swap eigenvalues
m_afDiag[i1] = m_afDiag[i0];
m_afDiag[i0] = fMax;
// swap eigenvectors
for (i2 = 0; i2 < 3; i2++)
{
Type fTmp = mElement[i2][i0];
mElement[i2][i0] = mElement[i2][i1];
mElement[i2][i1] = fTmp;
m_bIsRotation = !m_bIsRotation;
}
}
}
}
void GuaranteeRotation(void)
{
if (!m_bIsRotation)
{
// change sign on the first column
for (int iRow = 0; iRow <3; iRow++)
{
mElement[iRow][0] = -mElement[iRow][0];
}
}
}
Type mElement[3][3];
Type m_afDiag[3];
Type m_afSubd[3];
bool m_bIsRotation;
};
static bool fm_computeBestFitPlane(size_t vcount,const REAL *points,size_t vstride,const REAL *weights,size_t wstride, REAL *plane)
{
bool ret = false;
REAL kOrigin[3] = { 0, 0, 0 };
REAL wtotal = 0;
{
const char *source = (const char *) points;
const char *wsource = (const char *) weights;
for (size_t i=0; i<vcount; i++)
{
const REAL *p = (const REAL *) source;
REAL w = 1;
if ( wsource )
{
const REAL *ws = (const REAL *) wsource;
w = *ws; //
wsource+=wstride;
}
kOrigin[0]+=p[0]*w;
kOrigin[1]+=p[1]*w;
kOrigin[2]+=p[2]*w;
wtotal+=w;
source+=vstride;
}
}
REAL recip = 1.0f / wtotal; // reciprocol of total weighting
kOrigin[0]*=recip;
kOrigin[1]*=recip;
kOrigin[2]*=recip;
REAL fSumXX=0;
REAL fSumXY=0;
REAL fSumXZ=0;
REAL fSumYY=0;
REAL fSumYZ=0;
REAL fSumZZ=0;
{
const char *source = (const char *) points;
const char *wsource = (const char *) weights;
for (size_t i=0; i<vcount; i++)
{
const REAL *p = (const REAL *) source;
REAL w = 1;
if ( wsource )
{
const REAL *ws = (const REAL *) wsource;
w = *ws; //
wsource+=wstride;
}
REAL kDiff[3];
kDiff[0] = w*(p[0] - kOrigin[0]); // apply vertex weighting!
kDiff[1] = w*(p[1] - kOrigin[1]);
kDiff[2] = w*(p[2] - kOrigin[2]);
fSumXX+= kDiff[0] * kDiff[0]; // sume of the squares of the differences.
fSumXY+= kDiff[0] * kDiff[1]; // sume of the squares of the differences.
fSumXZ+= kDiff[0] * kDiff[2]; // sume of the squares of the differences.
fSumYY+= kDiff[1] * kDiff[1];
fSumYZ+= kDiff[1] * kDiff[2];
fSumZZ+= kDiff[2] * kDiff[2];
source+=vstride;
}
}
fSumXX *= recip;
fSumXY *= recip;
fSumXZ *= recip;
fSumYY *= recip;
fSumYZ *= recip;
fSumZZ *= recip;
// setup the eigensolver
fm_Eigen<REAL> kES;
kES.mElement[0][0] = fSumXX;
kES.mElement[0][1] = fSumXY;
kES.mElement[0][2] = fSumXZ;
kES.mElement[1][0] = fSumXY;
kES.mElement[1][1] = fSumYY;
kES.mElement[1][2] = fSumYZ;
kES.mElement[2][0] = fSumXZ;
kES.mElement[2][1] = fSumYZ;
kES.mElement[2][2] = fSumZZ;
// compute eigenstuff, smallest eigenvalue is in last position
kES.DecrSortEigenStuff();
REAL kNormal[3];
kNormal[0] = kES.mElement[0][2];
kNormal[1] = kES.mElement[1][2];
kNormal[2] = kES.mElement[2][2];
// the minimum energy
plane[0] = kNormal[0];
plane[1] = kNormal[1];
plane[2] = kNormal[2];
plane[3] = 0 - fm_dot(kNormal,kOrigin);
ret = true;
return ret;
}
static void fm_eulerToQuat(REAL roll,REAL pitch,REAL yaw,REAL *quat) // convert euler angles to quaternion.
{
roll *= 0.5f;
pitch *= 0.5f;
yaw *= 0.5f;
REAL cr = cos(roll);
REAL cp = cos(pitch);
REAL cy = cos(yaw);
REAL sr = sin(roll);
REAL sp = sin(pitch);
REAL sy = sin(yaw);
REAL cpcy = cp * cy;
REAL spsy = sp * sy;
REAL spcy = sp * cy;
REAL cpsy = cp * sy;
quat[0] = ( sr * cpcy - cr * spsy);
quat[1] = ( cr * spcy + sr * cpsy);
quat[2] = ( cr * cpsy - sr * spcy);
quat[3] = cr * cpcy + sr * spsy;
}
static void fm_eulerToQuat(const REAL *euler,REAL *quat) // convert euler angles to quaternion.
{
fm_eulerToQuat(euler[0],euler[1],euler[2],quat);
}
static void fm_quatToMatrix(const REAL *quat,REAL *matrix) // convert quaterinion rotation to matrix, zeros out the translation component.
{
REAL xx = quat[0]*quat[0];
REAL yy = quat[1]*quat[1];
REAL zz = quat[2]*quat[2];
REAL xy = quat[0]*quat[1];
REAL xz = quat[0]*quat[2];
REAL yz = quat[1]*quat[2];
REAL wx = quat[3]*quat[0];
REAL wy = quat[3]*quat[1];
REAL wz = quat[3]*quat[2];
matrix[0*4+0] = 1 - 2 * ( yy + zz );
matrix[1*4+0] = 2 * ( xy - wz );
matrix[2*4+0] = 2 * ( xz + wy );
matrix[0*4+1] = 2 * ( xy + wz );
matrix[1*4+1] = 1 - 2 * ( xx + zz );
matrix[2*4+1] = 2 * ( yz - wx );
matrix[0*4+2] = 2 * ( xz - wy );
matrix[1*4+2] = 2 * ( yz + wx );
matrix[2*4+2] = 1 - 2 * ( xx + yy );
matrix[3*4+0] = matrix[3*4+1] = matrix[3*4+2] = (REAL) 0.0f;
matrix[0*4+3] = matrix[1*4+3] = matrix[2*4+3] = (REAL) 0.0f;
matrix[3*4+3] =(REAL) 1.0f;
}
// convert the 3x3 portion of a 4x4 matrix into a quaterion as x,y,z,w
static void fm_matrixToQuat(const REAL *matrix,REAL *quat)
{
REAL tr = matrix[0*4+0] + matrix[1*4+1] + matrix[2*4+2];
// check the diagonal
if (tr > 0.0f )
{
REAL s = (REAL) sqrt ( (double) (tr + 1.0f) );
quat[3] = s * 0.5f;
s = 0.5f / s;
quat[0] = (matrix[1*4+2] - matrix[2*4+1]) * s;
quat[1] = (matrix[2*4+0] - matrix[0*4+2]) * s;
quat[2] = (matrix[0*4+1] - matrix[1*4+0]) * s;
}
else
{
// diagonal is negative
int nxt[3] = {1, 2, 0};
REAL qa[4];
int i = 0;
if (matrix[1*4+1] > matrix[0*4+0]) i = 1;
if (matrix[2*4+2] > matrix[i*4+i]) i = 2;
int j = nxt[i];
int k = nxt[j];
REAL s = sqrt ( ((matrix[i*4+i] - (matrix[j*4+j] + matrix[k*4+k])) + 1.0f) );
qa[i] = s * 0.5f;
if (s != 0.0f ) s = 0.5f / s;
qa[3] = (matrix[j*4+k] - matrix[k*4+j]) * s;
qa[j] = (matrix[i*4+j] + matrix[j*4+i]) * s;
qa[k] = (matrix[i*4+k] + matrix[k*4+i]) * s;
quat[0] = qa[0];
quat[1] = qa[1];
quat[2] = qa[2];
quat[3] = qa[3];
}
}
// rotate and translate this point
static void fm_transform(const REAL matrix[16],const REAL v[3],REAL t[3])
{
if ( matrix )
{
REAL tx = (matrix[0*4+0] * v[0]) + (matrix[1*4+0] * v[1]) + (matrix[2*4+0] * v[2]) + matrix[3*4+0];
REAL ty = (matrix[0*4+1] * v[0]) + (matrix[1*4+1] * v[1]) + (matrix[2*4+1] * v[2]) + matrix[3*4+1];
REAL tz = (matrix[0*4+2] * v[0]) + (matrix[1*4+2] * v[1]) + (matrix[2*4+2] * v[2]) + matrix[3*4+2];
t[0] = tx;
t[1] = ty;
t[2] = tz;
}
else
{
t[0] = v[0];
t[1] = v[1];
t[2] = v[2];
}
}
static void fm_setTranslation(const REAL *translation,REAL *matrix)
{
matrix[12] = translation[0];
matrix[13] = translation[1];
matrix[14] = translation[2];
}
static void fm_getTranslation(const REAL *matrix,REAL *t)
{
t[0] = matrix[3*4+0];
t[1] = matrix[3*4+1];
t[2] = matrix[3*4+2];
}
// Reference, from Stan Melax in Game Gems I
// Quaternion q;
// vector3 c = CrossProduct(v0,v1);
// REAL d = DotProduct(v0,v1);
// REAL s = (REAL)sqrt((1+d)*2);
// q.x = c.x / s;
// q.y = c.y / s;
// q.z = c.z / s;
// q.w = s /2.0f;
// return q;
static void fm_rotationArc(const REAL *v0,const REAL *v1,REAL *quat)
{
REAL cross[3];
fm_cross(cross,v0,v1);
REAL d = fm_dot(v0,v1);
REAL s = sqrt((1+d)*2);
REAL recip = 1.0f / s;
quat[0] = cross[0] * recip;
quat[1] = cross[1] * recip;
quat[2] = cross[2] * recip;
quat[3] = s * 0.5f;
}
// convert a plane equation to a 4x4 rotation matrix
static void fm_planeToMatrix(const REAL *plane,REAL *matrix)
{
REAL ref[3] = { 0, 1, 0 };
REAL quat[4];
fm_rotationArc(ref,plane,quat);
fm_quatToMatrix(quat,matrix);
REAL origin[3] = { 0, -plane[3], 0 };
REAL center[3];
fm_transform(matrix,origin,center);
fm_setTranslation(center,matrix);
}
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