src/math/MatVec3.c

/*
 * Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
 *
 * The University of Notre Dame grants you ("Licensee") a
 * non-exclusive, royalty free, license to use, modify and
 * redistribute this software in source and binary code form, provided
 * that the following conditions are met:
 *
 * 1. Acknowledgement of the program authors must be made in any
 *    publication of scientific results based in part on use of the
 *    program.  An acceptable form of acknowledgement is citation of
 *    the article in which the program was described (Matthew
 *    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
 *    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
 *    Parallel Simulation Engine for Molecular Dynamics,"
 *    J. Comput. Chem. 26, pp. 252-271 (2005))
 *
 * 2. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 *
 * 3. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the
 *    distribution.
 *
 * This software is provided "AS IS," without a warranty of any
 * kind. All express or implied conditions, representations and
 * warranties, including any implied warranty of merchantability,
 * fitness for a particular purpose or non-infringement, are hereby
 * excluded.  The University of Notre Dame and its licensors shall not
 * be liable for any damages suffered by licensee as a result of
 * using, modifying or distributing the software or its
 * derivatives. In no event will the University of Notre Dame or its
 * licensors be liable for any lost revenue, profit or data, or for
 * direct, indirect, special, consequential, incidental or punitive
 * damages, however caused and regardless of the theory of liability,
 * arising out of the use of or inability to use software, even if the
 * University of Notre Dame has been advised of the possibility of
 * such damages.
 */
 
#include <stdio.h>
#include <math.h>
#include <stdlib.h>
#include "math/MatVec3.h"

/* 
 * Contains various utilities for dealing with 3x3 matrices and 
 * length 3 vectors
 */

void identityMat3(double A[3][3]) {
  int i;
  for (i = 0; i < 3; i++) {
    A[i][0] = A[i][1] = A[i][2] = 0.0;
    A[i][i] = 1.0;
  }
}

void swapVectors3(double v1[3], double v2[3]) {
  int i;
  for (i = 0; i < 3; i++) {
    double tmp = v1[i];
    v1[i] = v2[i];
    v2[i] = tmp;
  }
}

double normalize3(double x[3]) {
  double den; 
  int i;
  if ( (den = norm3(x)) != 0.0 ) {
    for (i=0; i < 3; i++)
      {
        x[i] /= den;
      }
  }
  return den;
}

void matMul3(double a[3][3], double b[3][3], double c[3][3]) {
  double r00, r01, r02, r10, r11, r12, r20, r21, r22;
  
  r00 = a[0][0]*b[0][0] + a[0][1]*b[1][0] + a[0][2]*b[2][0];
  r01 = a[0][0]*b[0][1] + a[0][1]*b[1][1] + a[0][2]*b[2][1];
  r02 = a[0][0]*b[0][2] + a[0][1]*b[1][2] + a[0][2]*b[2][2];
  
  r10 = a[1][0]*b[0][0] + a[1][1]*b[1][0] + a[1][2]*b[2][0];
  r11 = a[1][0]*b[0][1] + a[1][1]*b[1][1] + a[1][2]*b[2][1];
  r12 = a[1][0]*b[0][2] + a[1][1]*b[1][2] + a[1][2]*b[2][2];
  
  r20 = a[2][0]*b[0][0] + a[2][1]*b[1][0] + a[2][2]*b[2][0];
  r21 = a[2][0]*b[0][1] + a[2][1]*b[1][1] + a[2][2]*b[2][1];
  r22 = a[2][0]*b[0][2] + a[2][1]*b[1][2] + a[2][2]*b[2][2];
  
  c[0][0] = r00; c[0][1] = r01; c[0][2] = r02;
  c[1][0] = r10; c[1][1] = r11; c[1][2] = r12;
  c[2][0] = r20; c[2][1] = r21; c[2][2] = r22;
}

void matVecMul3(double m[3][3], double inVec[3], double outVec[3]) {
  double a0, a1, a2;
  
  a0 = inVec[0];  a1 = inVec[1];  a2 = inVec[2];
  
  outVec[0] = m[0][0]*a0 + m[0][1]*a1 + m[0][2]*a2;
  outVec[1] = m[1][0]*a0 + m[1][1]*a1 + m[1][2]*a2;
  outVec[2] = m[2][0]*a0 + m[2][1]*a1 + m[2][2]*a2;
}

double matDet3(double a[3][3]) {
  int i, j, k;
  double determinant;
  
  determinant = 0.0;
  
  for(i = 0; i < 3; i++) {
    j = (i+1)%3;
    k = (i+2)%3;
    
    determinant += a[0][i] * (a[1][j]*a[2][k] - a[1][k]*a[2][j]);
  }
  
  return determinant;
}

void invertMat3(double a[3][3], double b[3][3]) {
  
  int  i, j, k, l, m, n;
  double determinant;
  
  determinant = matDet3( a );
  
  if (determinant == 0.0) {
    sprintf( painCave.errMsg,
             "Can't invert a matrix with a zero determinant!\n");
    painCave.isFatal = 1;
    simError();
  }
  
  for (i=0; i < 3; i++) {
    j = (i+1)%3;
    k = (i+2)%3;
    for(l = 0; l < 3; l++) {
      m = (l+1)%3;
      n = (l+2)%3;
      
      b[l][i] = (a[j][m]*a[k][n] - a[j][n]*a[k][m]) / determinant;
    }
  }
}

void transposeMat3(double in[3][3], double out[3][3]) {
  double temp[3][3];
  int i, j;
  
  for (i = 0; i < 3; i++) {
    for (j = 0; j < 3; j++) {
      temp[j][i] = in[i][j];
    }
  }
  for (i = 0; i < 3; i++) {
    for (j = 0; j < 3; j++) {
      out[i][j] = temp[i][j];
    }
  }
}

void printMat3(double A[3][3] ){
  
  fprintf(stderr, "[ %g, %g, %g ]\n[ %g, %g, %g ]\n[ %g, %g, %g ]\n",          
          A[0][0] , A[0][1] , A[0][2], 
          A[1][0] , A[1][1] , A[1][2], 
          A[2][0] , A[2][1] , A[2][2]) ;
}

void printMat9(double A[9] ){
  
  fprintf(stderr, "[ %g, %g, %g ]\n[ %g, %g, %g ]\n[ %g, %g, %g ]\n",          
          A[0], A[1], A[2],
          A[3], A[4], A[5],
          A[6], A[7], A[8]);
}

double matTrace3(double m[3][3]){
  double trace;
  trace = m[0][0] + m[1][1] + m[2][2];
  
  return trace;
}

void crossProduct3(double a[3],double b[3], double out[3]){
  
  out[0] = a[1] * b[2] - a[2] * b[1];
  out[1] = a[2] * b[0] - a[0] * b[2] ;
  out[2] = a[0] * b[1] - a[1] * b[0];
  
}

double dotProduct3(double a[3], double b[3]){
  return a[0]*b[0] + a[1]*b[1]+ a[2]*b[2];
}

/*----------------------------------------------------------------------------*/
/* Extract the eigenvalues and eigenvectors from a 3x3 matrix.*/
/* The eigenvectors (the columns of V) will be normalized. */
/* The eigenvectors are aligned optimally with the x, y, and z*/
/* axes respectively.*/

void diagonalize3x3(const double A[3][3], double w[3], double V[3][3]) {
  int i,j,k,maxI;
  double tmp, maxVal;

  /* do the matrix[3][3] to **matrix conversion for Jacobi*/
  double C[3][3];
  double *ATemp[3],*VTemp[3];
  for (i = 0; i < 3; i++)
    {
      C[i][0] = A[i][0];
      C[i][1] = A[i][1];
      C[i][2] = A[i][2];
      ATemp[i] = C[i];
      VTemp[i] = V[i];
    }
  
  /* diagonalize using Jacobi*/
  JacobiN(ATemp,3,w,VTemp);
  
  /* if all the eigenvalues are the same, return identity matrix*/
  if (w[0] == w[1] && w[0] == w[2])
    {
      identityMat3(V);
      return;
    }
  
  /* transpose temporarily, it makes it easier to sort the eigenvectors*/
  transposeMat3(V,V);
  
  /* if two eigenvalues are the same, re-orthogonalize to optimally line*/
  /* up the eigenvectors with the x, y, and z axes*/
  for (i = 0; i < 3; i++)
    {
      if (w[(i+1)%3] == w[(i+2)%3]) /* two eigenvalues are the same*/
        {
          /* find maximum element of the independant eigenvector*/
          maxVal = fabs(V[i][0]);
          maxI = 0;
          for (j = 1; j < 3; j++)
            {
              if (maxVal < (tmp = fabs(V[i][j])))
                {
                  maxVal = tmp;
                  maxI = j;
                }
            }
          /* swap the eigenvector into its proper position*/
          if (maxI != i)
            {
              tmp = w[maxI];
              w[maxI] = w[i];
              w[i] = tmp;
              swapVectors3(V[i],V[maxI]);
            }
          /* maximum element of eigenvector should be positive*/
          if (V[maxI][maxI] < 0)
            {
              V[maxI][0] = -V[maxI][0];
              V[maxI][1] = -V[maxI][1];
              V[maxI][2] = -V[maxI][2];
            }
          
          /* re-orthogonalize the other two eigenvectors*/
          j = (maxI+1)%3;
          k = (maxI+2)%3;
          
          V[j][0] = 0.0; 
          V[j][1] = 0.0; 
          V[j][2] = 0.0;
          V[j][j] = 1.0;
          crossProduct3(V[maxI],V[j],V[k]);
          normalize3(V[k]);
          crossProduct3(V[k],V[maxI],V[j]);

          /* transpose vectors back to columns*/
          transposeMat3(V,V);
          return;
        }
    }
  
  /* the three eigenvalues are different, just sort the eigenvectors*/
  /* to align them with the x, y, and z axes*/
  
  /* find the vector with the largest x element, make that vector*/
  /* the first vector*/
  maxVal = fabs(V[0][0]);
  maxI = 0;
  for (i = 1; i < 3; i++)
    {
      if (maxVal < (tmp = fabs(V[i][0])))
        {
          maxVal = tmp;
          maxI = i;
        }
    }
  /* swap eigenvalue and eigenvector*/
  if (maxI != 0)
    {
      tmp = w[maxI];
      w[maxI] = w[0];
      w[0] = tmp;
      swapVectors3(V[maxI],V[0]);
    }
  /* do the same for the y element*/
  if (fabs(V[1][1]) < fabs(V[2][1]))
    {
      tmp = w[2];
      w[2] = w[1];
      w[1] = tmp;
      swapVectors3(V[2],V[1]);
    }
  
  /* ensure that the sign of the eigenvectors is correct*/
  for (i = 0; i < 2; i++)
    {
      if (V[i][i] < 0)
        {
          V[i][0] = -V[i][0];
          V[i][1] = -V[i][1];
          V[i][2] = -V[i][2];
        }
    }
  /* set sign of final eigenvector to ensure that determinant is positive*/
  if (matDet3(V) < 0)
    {
      V[2][0] = -V[2][0];
      V[2][1] = -V[2][1];
      V[2][2] = -V[2][2];
    }
  
  /* transpose the eigenvectors back again*/
  transposeMat3(V,V);
}


#define MAT_ROTATE(a,i,j,k,l) g=a[i][j];h=a[k][l];a[i][j]=g-s*(h+g*tau); a[k][l]=h+s*(g-h*tau);

#define MAX_ROTATIONS 20

/* Jacobi iteration for the solution of eigenvectors/eigenvalues of a nxn*/
/* real symmetric matrix. Square nxn matrix a; size of matrix in n;*/
/* output eigenvalues in w; and output eigenvectors in v. Resulting*/
/* eigenvalues/vectors are sorted in decreasing order; eigenvectors are*/
/* normalized.*/
int JacobiN(double **a, int n, double *w, double **v) {

  int i, j, k, iq, ip, numPos;
  int ceil_half_n;
  double tresh, theta, tau, t, sm, s, h, g, c, tmp;
  double bspace[4], zspace[4];
  double *b = bspace;
  double *z = zspace;
  

  /* only allocate memory if the matrix is large*/
  if (n > 4)
    {
      b = (double *) calloc(n, sizeof(double));
      z = (double *) calloc(n, sizeof(double));
    }
  
  /* initialize*/
  for (ip=0; ip<n; ip++) 
    {
      for (iq=0; iq<n; iq++)
        {
          v[ip][iq] = 0.0;
        }
      v[ip][ip] = 1.0;
    }
  for (ip=0; ip<n; ip++) 
    {
      b[ip] = w[ip] = a[ip][ip];
      z[ip] = 0.0;
    }
  
  /* begin rotation sequence*/
  for (i=0; i<MAX_ROTATIONS; i++) 
    {
      sm = 0.0;
      for (ip=0; ip<n-1; ip++) 
        {
          for (iq=ip+1; iq<n; iq++)
            {
              sm += fabs(a[ip][iq]);
            }
        }
      if (sm == 0.0)
        {
          break;
        }
      
      if (i < 3)                                /* first 3 sweeps*/
        {
          tresh = 0.2*sm/(n*n);
        }
      else
        {
          tresh = 0.0;
        }
      
      for (ip=0; ip<n-1; ip++) 
        {
          for (iq=ip+1; iq<n; iq++) 
            {
              g = 100.0*fabs(a[ip][iq]);
              
              /* after 4 sweeps*/
              if (i > 3 && (fabs(w[ip])+g) == fabs(w[ip])
                  && (fabs(w[iq])+g) == fabs(w[iq]))
                {
                  a[ip][iq] = 0.0;
                }
              else if (fabs(a[ip][iq]) > tresh) 
                {
                  h = w[iq] - w[ip];
                  if ( (fabs(h)+g) == fabs(h))
                    {
                      t = (a[ip][iq]) / h;
                    }
                  else 
                    {
                      theta = 0.5*h / (a[ip][iq]);
                      t = 1.0 / (fabs(theta)+sqrt(1.0+theta*theta));
                      if (theta < 0.0)
                        {
                          t = -t;
                        }
                    }
                  c = 1.0 / sqrt(1+t*t);
                  s = t*c;
                  tau = s/(1.0+c);
                  h = t*a[ip][iq];
                  z[ip] -= h;
                  z[iq] += h;
                  w[ip] -= h;
                  w[iq] += h;
                  a[ip][iq]=0.0;
                  
                  /* ip already shifted left by 1 unit*/
                  for (j = 0;j <= ip-1;j++) 
                    {
                      MAT_ROTATE(a,j,ip,j,iq)
                        }
                  /* ip and iq already shifted left by 1 unit*/
                  for (j = ip+1;j <= iq-1;j++) 
                    {
                      MAT_ROTATE(a,ip,j,j,iq)
                        }
                  /* iq already shifted left by 1 unit*/
                  for (j=iq+1; j<n; j++) 
                    {
                      MAT_ROTATE(a,ip,j,iq,j)
                        }
                  for (j=0; j<n; j++) 
                    {
                      MAT_ROTATE(v,j,ip,j,iq)
                        }
                }
            }
        }
      
      for (ip=0; ip<n; ip++) 
        {
          b[ip] += z[ip];
          w[ip] = b[ip];
          z[ip] = 0.0;
        }
    }
  
  /*// this is NEVER called*/
  if ( i >= MAX_ROTATIONS )
    {
      sprintf( painCave.errMsg,
               "Jacobi: Error extracting eigenfunctions!\n");
      painCave.isFatal = 1;
      simError();      
      return 0;
    }
  
  /* sort eigenfunctions                 these changes do not affect accuracy */
  for (j=0; j<n-1; j++)                  /* boundary incorrect*/
    {
      k = j;
      tmp = w[k];
      for (i=j+1; i<n; i++)             /* boundary incorrect, shifted already*/
        {
          if (w[i] >= tmp)                   /* why exchage if same?*/
            {
              k = i;
              tmp = w[k];
            }
        }
      if (k != j) 
        {
          w[k] = w[j];
          w[j] = tmp;
          for (i=0; i<n; i++) 
            {
              tmp = v[i][j];
              v[i][j] = v[i][k];
              v[i][k] = tmp;
            }
        }
    }
  /* insure eigenvector consistency (i.e., Jacobi can compute vectors that*/
  /* are negative of one another (.707,.707,0) and (-.707,-.707,0). This can*/
  /* reek havoc in hyperstreamline/other stuff. We will select the most*/
  /* positive eigenvector.*/
  ceil_half_n = (n >> 1) + (n & 1);
  for (j=0; j<n; j++)
    {
      for (numPos=0, i=0; i<n; i++)
        {
          if ( v[i][j] >= 0.0 )
            {
              numPos++;
            }
        }
      /*    if ( numPos < ceil(double(n)/double(2.0)) )*/
      if ( numPos < ceil_half_n)
        {
          for(i=0; i<n; i++)
            {
              v[i][j] *= -1.0;
            }
        }
    }
  
  if (n > 4)
    {
      free(b);
      free(z);
    }
  return 1;
}

#undef MAT_ROTATE
#undef MAX_ROTATIONS
Revision:	564
Committed:	Wed Jul 13 15:54:00 2005 UTC (20 years, 3 months ago) by tim
Content type:	text/plain
File size:	14896 byte(s)
Log Message:	replace c++ style comment in c files
#	Content
1	/*
2	* Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3	*
4	* The University of Notre Dame grants you ("Licensee") a
5	* non-exclusive, royalty free, license to use, modify and
6	* redistribute this software in source and binary code form, provided
7	* that the following conditions are met:
8	*
9	* 1. Acknowledgement of the program authors must be made in any
10	* publication of scientific results based in part on use of the
11	* program. An acceptable form of acknowledgement is citation of
12	* the article in which the program was described (Matthew
13	* A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
14	* J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
15	* Parallel Simulation Engine for Molecular Dynamics,"
16	* J. Comput. Chem. 26, pp. 252-271 (2005))
17	*
18	* 2. Redistributions of source code must retain the above copyright
19	* notice, this list of conditions and the following disclaimer.
20	*
21	* 3. Redistributions in binary form must reproduce the above copyright
22	* notice, this list of conditions and the following disclaimer in the
23	* documentation and/or other materials provided with the
24	* distribution.
25	*
26	* This software is provided "AS IS," without a warranty of any
27	* kind. All express or implied conditions, representations and
28	* warranties, including any implied warranty of merchantability,
29	* fitness for a particular purpose or non-infringement, are hereby
30	* excluded. The University of Notre Dame and its licensors shall not
31	* be liable for any damages suffered by licensee as a result of
32	* using, modifying or distributing the software or its
33	* derivatives. In no event will the University of Notre Dame or its
34	* licensors be liable for any lost revenue, profit or data, or for
35	* direct, indirect, special, consequential, incidental or punitive
36	* damages, however caused and regardless of the theory of liability,
37	* arising out of the use of or inability to use software, even if the
38	* University of Notre Dame has been advised of the possibility of
39	* such damages.
40	*/
41
42	#include <stdio.h>
43	#include <math.h>
44	#include <stdlib.h>
45	#include "math/MatVec3.h"
46
47	/*
48	* Contains various utilities for dealing with 3x3 matrices and
49	* length 3 vectors
50	*/
51
52	void identityMat3(double A[3][3]) {
53	int i;
54	for (i = 0; i < 3; i++) {
55	A[i][0] = A[i][1] = A[i][2] = 0.0;
56	A[i][i] = 1.0;
57	}
58	}
59
60	void swapVectors3(double v1[3], double v2[3]) {
61	int i;
62	for (i = 0; i < 3; i++) {
63	double tmp = v1[i];
64	v1[i] = v2[i];
65	v2[i] = tmp;
66	}
67	}
68
69	double normalize3(double x[3]) {
70	double den;
71	int i;
72	if ( (den = norm3(x)) != 0.0 ) {
73	for (i=0; i < 3; i++)
74	{
75	x[i] /= den;
76	}
77	}
78	return den;
79	}
80
81	void matMul3(double a[3][3], double b[3][3], double c[3][3]) {
82	double r00, r01, r02, r10, r11, r12, r20, r21, r22;
83
84	r00 = a[0][0]b[0][0] + a[0][1]b[1][0] + a[0][2]*b[2][0];
85	r01 = a[0][0]b[0][1] + a[0][1]b[1][1] + a[0][2]*b[2][1];
86	r02 = a[0][0]b[0][2] + a[0][1]b[1][2] + a[0][2]*b[2][2];
87
88	r10 = a[1][0]b[0][0] + a[1][1]b[1][0] + a[1][2]*b[2][0];
89	r11 = a[1][0]b[0][1] + a[1][1]b[1][1] + a[1][2]*b[2][1];
90	r12 = a[1][0]b[0][2] + a[1][1]b[1][2] + a[1][2]*b[2][2];
91
92	r20 = a[2][0]b[0][0] + a[2][1]b[1][0] + a[2][2]*b[2][0];
93	r21 = a[2][0]b[0][1] + a[2][1]b[1][1] + a[2][2]*b[2][1];
94	r22 = a[2][0]b[0][2] + a[2][1]b[1][2] + a[2][2]*b[2][2];
95
96	c[0][0] = r00; c[0][1] = r01; c[0][2] = r02;
97	c[1][0] = r10; c[1][1] = r11; c[1][2] = r12;
98	c[2][0] = r20; c[2][1] = r21; c[2][2] = r22;
99	}
100
101	void matVecMul3(double m[3][3], double inVec[3], double outVec[3]) {
102	double a0, a1, a2;
103
104	a0 = inVec[0]; a1 = inVec[1]; a2 = inVec[2];
105
106	outVec[0] = m[0][0]a0 + m[0][1]a1 + m[0][2]*a2;
107	outVec[1] = m[1][0]a0 + m[1][1]a1 + m[1][2]*a2;
108	outVec[2] = m[2][0]a0 + m[2][1]a1 + m[2][2]*a2;
109	}
110
111	double matDet3(double a[3][3]) {
112	int i, j, k;
113	double determinant;
114
115	determinant = 0.0;
116
117	for(i = 0; i < 3; i++) {
118	j = (i+1)%3;
119	k = (i+2)%3;
120
121	determinant += a[0][i] * (a[1][j]a[2][k] - a[1][k]a[2][j]);
122	}
123
124	return determinant;
125	}
126
127	void invertMat3(double a[3][3], double b[3][3]) {
128
129	int i, j, k, l, m, n;
130	double determinant;
131
132	determinant = matDet3( a );
133
134	if (determinant == 0.0) {
135	sprintf( painCave.errMsg,
136	"Can't invert a matrix with a zero determinant!\n");
137	painCave.isFatal = 1;
138	simError();
139	}
140
141	for (i=0; i < 3; i++) {
142	j = (i+1)%3;
143	k = (i+2)%3;
144	for(l = 0; l < 3; l++) {
145	m = (l+1)%3;
146	n = (l+2)%3;
147
148	b[l][i] = (a[j][m]a[k][n] - a[j][n]a[k][m]) / determinant;
149	}
150	}
151	}
152
153	void transposeMat3(double in[3][3], double out[3][3]) {
154	double temp[3][3];
155	int i, j;
156
157	for (i = 0; i < 3; i++) {
158	for (j = 0; j < 3; j++) {
159	temp[j][i] = in[i][j];
160	}
161	}
162	for (i = 0; i < 3; i++) {
163	for (j = 0; j < 3; j++) {
164	out[i][j] = temp[i][j];
165	}
166	}
167	}
168
169	void printMat3(double A[3][3] ){
170
171	fprintf(stderr, "[ %g, %g, %g ]\n[ %g, %g, %g ]\n[ %g, %g, %g ]\n",
172	A[0][0] , A[0][1] , A[0][2],
173	A[1][0] , A[1][1] , A[1][2],
174	A[2][0] , A[2][1] , A[2][2]) ;
175	}
176
177	void printMat9(double A[9] ){
178
179	fprintf(stderr, "[ %g, %g, %g ]\n[ %g, %g, %g ]\n[ %g, %g, %g ]\n",
180	A[0], A[1], A[2],
181	A[3], A[4], A[5],
182	A[6], A[7], A[8]);
183	}
184
185	double matTrace3(double m[3][3]){
186	double trace;
187	trace = m[0][0] + m[1][1] + m[2][2];
188
189	return trace;
190	}
191
192	void crossProduct3(double a[3],double b[3], double out[3]){
193
194	out[0] = a[1] * b[2] - a[2] * b[1];
195	out[1] = a[2] * b[0] - a[0] * b[2] ;
196	out[2] = a[0] * b[1] - a[1] * b[0];
197
198	}
199
200	double dotProduct3(double a[3], double b[3]){
201	return a[0]b[0] + a[1]b[1]+ a[2]*b[2];
202	}
203
204	/----------------------------------------------------------------------------/
205	/* Extract the eigenvalues and eigenvectors from a 3x3 matrix.*/
206	/* The eigenvectors (the columns of V) will be normalized. */
207	/* The eigenvectors are aligned optimally with the x, y, and z*/
208	/* axes respectively.*/
209
210	void diagonalize3x3(const double A[3][3], double w[3], double V[3][3]) {
211	int i,j,k,maxI;
212	double tmp, maxVal;
213
214	/* do the matrix[3][3] to *matrix conversion for Jacobi/
215	double C[3][3];
216	double ATemp[3],VTemp[3];
217	for (i = 0; i < 3; i++)
218	{
219	C[i][0] = A[i][0];
220	C[i][1] = A[i][1];
221	C[i][2] = A[i][2];
222	ATemp[i] = C[i];
223	VTemp[i] = V[i];
224	}
225
226	/* diagonalize using Jacobi*/
227	JacobiN(ATemp,3,w,VTemp);
228
229	/* if all the eigenvalues are the same, return identity matrix*/
230	if (w[0] == w[1] && w[0] == w[2])
231	{
232	identityMat3(V);
233	return;
234	}
235
236	/* transpose temporarily, it makes it easier to sort the eigenvectors*/
237	transposeMat3(V,V);
238
239	/* if two eigenvalues are the same, re-orthogonalize to optimally line*/
240	/* up the eigenvectors with the x, y, and z axes*/
241	for (i = 0; i < 3; i++)
242	{
243	if (w[(i+1)%3] == w[(i+2)%3]) /* two eigenvalues are the same*/
244	{
245	/* find maximum element of the independant eigenvector*/
246	maxVal = fabs(V[i][0]);
247	maxI = 0;
248	for (j = 1; j < 3; j++)
249	{
250	if (maxVal < (tmp = fabs(V[i][j])))
251	{
252	maxVal = tmp;
253	maxI = j;
254	}
255	}
256	/* swap the eigenvector into its proper position*/
257	if (maxI != i)
258	{
259	tmp = w[maxI];
260	w[maxI] = w[i];
261	w[i] = tmp;
262	swapVectors3(V[i],V[maxI]);
263	}
264	/* maximum element of eigenvector should be positive*/
265	if (V[maxI][maxI] < 0)
266	{
267	V[maxI][0] = -V[maxI][0];
268	V[maxI][1] = -V[maxI][1];
269	V[maxI][2] = -V[maxI][2];
270	}
271
272	/* re-orthogonalize the other two eigenvectors*/
273	j = (maxI+1)%3;
274	k = (maxI+2)%3;
275
276	V[j][0] = 0.0;
277	V[j][1] = 0.0;
278	V[j][2] = 0.0;
279	V[j][j] = 1.0;
280	crossProduct3(V[maxI],V[j],V[k]);
281	normalize3(V[k]);
282	crossProduct3(V[k],V[maxI],V[j]);
283
284	/* transpose vectors back to columns*/
285	transposeMat3(V,V);
286	return;
287	}
288	}
289
290	/* the three eigenvalues are different, just sort the eigenvectors*/
291	/* to align them with the x, y, and z axes*/
292
293	/* find the vector with the largest x element, make that vector*/
294	/* the first vector*/
295	maxVal = fabs(V[0][0]);
296	maxI = 0;
297	for (i = 1; i < 3; i++)
298	{
299	if (maxVal < (tmp = fabs(V[i][0])))
300	{
301	maxVal = tmp;
302	maxI = i;
303	}
304	}
305	/* swap eigenvalue and eigenvector*/
306	if (maxI != 0)
307	{
308	tmp = w[maxI];
309	w[maxI] = w[0];
310	w[0] = tmp;
311	swapVectors3(V[maxI],V[0]);
312	}
313	/* do the same for the y element*/
314	if (fabs(V[1][1]) < fabs(V[2][1]))
315	{
316	tmp = w[2];
317	w[2] = w[1];
318	w[1] = tmp;
319	swapVectors3(V[2],V[1]);
320	}
321
322	/* ensure that the sign of the eigenvectors is correct*/
323	for (i = 0; i < 2; i++)
324	{
325	if (V[i][i] < 0)
326	{
327	V[i][0] = -V[i][0];
328	V[i][1] = -V[i][1];
329	V[i][2] = -V[i][2];
330	}
331	}
332	/* set sign of final eigenvector to ensure that determinant is positive*/
333	if (matDet3(V) < 0)
334	{
335	V[2][0] = -V[2][0];
336	V[2][1] = -V[2][1];
337	V[2][2] = -V[2][2];
338	}
339
340	/* transpose the eigenvectors back again*/
341	transposeMat3(V,V);
342	}
343
344
345	#define MAT_ROTATE(a,i,j,k,l) g=a[i][j];h=a[k][l];a[i][j]=g-s(h+gtau); a[k][l]=h+s(g-htau);
346
347	#define MAX_ROTATIONS 20
348
349	/* Jacobi iteration for the solution of eigenvectors/eigenvalues of a nxn*/
350	/* real symmetric matrix. Square nxn matrix a; size of matrix in n;*/
351	/* output eigenvalues in w; and output eigenvectors in v. Resulting*/
352	/* eigenvalues/vectors are sorted in decreasing order; eigenvectors are*/
353	/* normalized.*/
354	int JacobiN(double *a, int n, double w, double **v) {
355
356	int i, j, k, iq, ip, numPos;
357	int ceil_half_n;
358	double tresh, theta, tau, t, sm, s, h, g, c, tmp;
359	double bspace[4], zspace[4];
360	double *b = bspace;
361	double *z = zspace;
362
363
364	/* only allocate memory if the matrix is large*/
365	if (n > 4)
366	{
367	b = (double *) calloc(n, sizeof(double));
368	z = (double *) calloc(n, sizeof(double));
369	}
370
371	/* initialize*/
372	for (ip=0; ip<n; ip++)
373	{
374	for (iq=0; iq<n; iq++)
375	{
376	v[ip][iq] = 0.0;
377	}
378	v[ip][ip] = 1.0;
379	}
380	for (ip=0; ip<n; ip++)
381	{
382	b[ip] = w[ip] = a[ip][ip];
383	z[ip] = 0.0;
384	}
385
386	/* begin rotation sequence*/
387	for (i=0; i<MAX_ROTATIONS; i++)
388	{
389	sm = 0.0;
390	for (ip=0; ip<n-1; ip++)
391	{
392	for (iq=ip+1; iq<n; iq++)
393	{
394	sm += fabs(a[ip][iq]);
395	}
396	}
397	if (sm == 0.0)
398	{
399	break;
400	}
401
402	if (i < 3) /* first 3 sweeps*/
403	{
404	tresh = 0.2sm/(nn);
405	}
406	else
407	{
408	tresh = 0.0;
409	}
410
411	for (ip=0; ip<n-1; ip++)
412	{
413	for (iq=ip+1; iq<n; iq++)
414	{
415	g = 100.0*fabs(a[ip][iq]);
416
417	/* after 4 sweeps*/
418	if (i > 3 && (fabs(w[ip])+g) == fabs(w[ip])
419	&& (fabs(w[iq])+g) == fabs(w[iq]))
420	{
421	a[ip][iq] = 0.0;
422	}
423	else if (fabs(a[ip][iq]) > tresh)
424	{
425	h = w[iq] - w[ip];
426	if ( (fabs(h)+g) == fabs(h))
427	{
428	t = (a[ip][iq]) / h;
429	}
430	else
431	{
432	theta = 0.5*h / (a[ip][iq]);
433	t = 1.0 / (fabs(theta)+sqrt(1.0+theta*theta));
434	if (theta < 0.0)
435	{
436	t = -t;
437	}
438	}
439	c = 1.0 / sqrt(1+t*t);
440	s = t*c;
441	tau = s/(1.0+c);
442	h = t*a[ip][iq];
443	z[ip] -= h;
444	z[iq] += h;
445	w[ip] -= h;
446	w[iq] += h;
447	a[ip][iq]=0.0;
448
449	/* ip already shifted left by 1 unit*/
450	for (j = 0;j <= ip-1;j++)
451	{
452	MAT_ROTATE(a,j,ip,j,iq)
453	}
454	/* ip and iq already shifted left by 1 unit*/
455	for (j = ip+1;j <= iq-1;j++)
456	{
457	MAT_ROTATE(a,ip,j,j,iq)
458	}
459	/* iq already shifted left by 1 unit*/
460	for (j=iq+1; j<n; j++)
461	{
462	MAT_ROTATE(a,ip,j,iq,j)
463	}
464	for (j=0; j<n; j++)
465	{
466	MAT_ROTATE(v,j,ip,j,iq)
467	}
468	}
469	}
470	}
471
472	for (ip=0; ip<n; ip++)
473	{
474	b[ip] += z[ip];
475	w[ip] = b[ip];
476	z[ip] = 0.0;
477	}
478	}
479
480	/// this is NEVER called/
481	if ( i >= MAX_ROTATIONS )
482	{
483	sprintf( painCave.errMsg,
484	"Jacobi: Error extracting eigenfunctions!\n");
485	painCave.isFatal = 1;
486	simError();
487	return 0;
488	}
489
490	/* sort eigenfunctions these changes do not affect accuracy */
491	for (j=0; j<n-1; j++) /* boundary incorrect*/
492	{
493	k = j;
494	tmp = w[k];
495	for (i=j+1; i<n; i++) /* boundary incorrect, shifted already*/
496	{
497	if (w[i] >= tmp) /* why exchage if same?*/
498	{
499	k = i;
500	tmp = w[k];
501	}
502	}
503	if (k != j)
504	{
505	w[k] = w[j];
506	w[j] = tmp;
507	for (i=0; i<n; i++)
508	{
509	tmp = v[i][j];
510	v[i][j] = v[i][k];
511	v[i][k] = tmp;
512	}
513	}
514	}
515	/* insure eigenvector consistency (i.e., Jacobi can compute vectors that*/
516	/* are negative of one another (.707,.707,0) and (-.707,-.707,0). This can*/
517	/* reek havoc in hyperstreamline/other stuff. We will select the most*/
518	/* positive eigenvector.*/
519	ceil_half_n = (n >> 1) + (n & 1);
520	for (j=0; j<n; j++)
521	{
522	for (numPos=0, i=0; i<n; i++)
523	{
524	if ( v[i][j] >= 0.0 )
525	{
526	numPos++;
527	}
528	}
529	/* if ( numPos < ceil(double(n)/double(2.0)) )*/
530	if ( numPos < ceil_half_n)
531	{
532	for(i=0; i<n; i++)
533	{
534	v[i][j] *= -1.0;
535	}
536	}
537	}
538
539	if (n > 4)
540	{
541	free(b);
542	free(z);
543	}
544	return 1;
545	}
546
547	#undef MAT_ROTATE
548	#undef MAX_ROTATIONS