src/math/SquareMatrix.hpp

/*
 * Copyright (C) 2000-2004  Object Oriented Parallel Simulation Engine (OOPSE) project
 * 
 * Contact: oopse@oopse.org
 * 
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public License
 * as published by the Free Software Foundation; either version 2.1
 * of the License, or (at your option) any later version.
 * All we ask is that proper credit is given for our work, which includes
 * - but is not limited to - adding the above copyright notice to the beginning
 * of your source code files, and to any copyright notice that you may distribute
 * with programs based on this work.
 * 
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU Lesser General Public License for more details.
 * 
 * You should have received a copy of the GNU Lesser General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA  02111-1307, USA.
 *
 */

/**
 * @file SquareMatrix.hpp
 * @author Teng Lin
 * @date 10/11/2004
 * @version 1.0
 */
 #ifndef MATH_SQUAREMATRIX_HPP 
#define MATH_SQUAREMATRIX_HPP 

#include "math/RectMatrix.hpp"

namespace oopse {

    /**
     * @class SquareMatrix SquareMatrix.hpp "math/SquareMatrix.hpp"
     * @brief A square matrix class
     * @template Real the element type
     * @template Dim the dimension of the square matrix
     */
    template<typename Real, int Dim>
    class SquareMatrix : public RectMatrix<Real, Dim, Dim> {
        public:
            typedef Real ElemType;
            typedef Real* ElemPoinerType;

            /** default constructor */
            SquareMatrix() {
                for (unsigned int i = 0; i < Dim; i++)
                    for (unsigned int j = 0; j < Dim; j++)
                        data_[i][j] = 0.0;
             }

            /** copy constructor */
            SquareMatrix(const RectMatrix<Real, Dim, Dim>& m) : RectMatrix<Real, Dim, Dim>(m) {
            }
            
            /** copy assignment operator */
            SquareMatrix<Real, Dim>& operator =(const RectMatrix<Real, Dim, Dim>& m) {
                RectMatrix<Real, Dim, Dim>::operator=(m);
                return *this;
            }
                                   
            /** Retunrs  an identity matrix*/

           static SquareMatrix<Real, Dim> identity() {
                SquareMatrix<Real, Dim> m;
                
                for (unsigned int i = 0; i < Dim; i++) 
                    for (unsigned int j = 0; j < Dim; j++) 
                        if (i == j)
                            m(i, j) = 1.0;
                        else
                            m(i, j) = 0.0;

                return m;
            }

            /** 
             * Retunrs  the inversion of this matrix. 
             * @todo need implementation
             */
             SquareMatrix<Real, Dim>  inverse() {
                 SquareMatrix<Real, Dim> result;

                 return result;
            }        

            /**
             * Returns the determinant of this matrix.
             * @todo need implementation
             */
            Real determinant() const {
                Real det;
                return det;
            }

            /** Returns the trace of this matrix. */
            Real trace() const {
               Real tmp = 0;
               
                for (unsigned int i = 0; i < Dim ; i++)
                    tmp += data_[i][i];

                return tmp;
            }

            /** Tests if this matrix is symmetrix. */            
            bool isSymmetric() const {
                for (unsigned int i = 0; i < Dim - 1; i++)
                    for (unsigned int j = i; j < Dim; j++)
                        if (fabs(data_[i][j] - data_[j][i]) > oopse::epsilon) 
                            return false;
                        
                return true;
            }

            /** Tests if this matrix is orthogonal. */            
            bool isOrthogonal() {
                SquareMatrix<Real, Dim> tmp;

                tmp = *this * transpose();

                return tmp.isDiagonal();
            }

            /** Tests if this matrix is diagonal. */
            bool isDiagonal() const {
                for (unsigned int i = 0; i < Dim ; i++)
                    for (unsigned int j = 0; j < Dim; j++)
                        if (i !=j && fabs(data_[i][j]) > oopse::epsilon) 
                            return false;
                        
                return true;
            }

            /** Tests if this matrix is the unit matrix. */
            bool isUnitMatrix() const {
                if (!isDiagonal())
                    return false;
                
                for (unsigned int i = 0; i < Dim ; i++)
                    if (fabs(data_[i][i] - 1) > oopse::epsilon)
                        return false;
                    
                return true;
            }         

            /** @todo need implementation */
            void diagonalize() {
                //jacobi(m, eigenValues, ortMat);
            }

            /**
             * Jacobi iteration routines for computing eigenvalues/eigenvectors of 
             * real symmetric matrix
             *
             * @return true if success, otherwise return false
             * @param a symmetric matrix whose eigenvectors are to be computed. On return, the matrix is
             *     overwritten
             * @param w will contain the eigenvalues of the matrix On return of this function
             * @param v the columns of this matrix will contain the eigenvectors. The eigenvectors are 
             *    normalized and mutually orthogonal. 
             */
           
            static int jacobi(SquareMatrix<Real, Dim>& a, Vector<Real, Dim>& d, 
                                  SquareMatrix<Real, Dim>& v);
    };//end SquareMatrix


/*=========================================================================

  Program:   Visualization Toolkit
  Module:    $RCSfile: SquareMatrix.hpp,v $

  Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
  All rights reserved.
  See Copyright.txt or http://www.kitware.com/Copyright.htm for details.

     This software is distributed WITHOUT ANY WARRANTY; without even
     the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
     PURPOSE.  See the above copyright notice for more information.

=========================================================================*/

#define VTK_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 VTK_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.
    template<typename Real, int Dim>
    int SquareMatrix<Real, Dim>::jacobi(SquareMatrix<Real, Dim>& a, Vector<Real, Dim>& w, 
                                  SquareMatrix<Real, Dim>& v) {
      const int n = Dim;  
      int i, j, k, iq, ip, numPos;
      Real tresh, theta, tau, t, sm, s, h, g, c, tmp;
      Real bspace[4], zspace[4];
      Real *b = bspace;
      Real *z = zspace;

      // only allocate memory if the matrix is large
      if (n > 4)
        {
        b = new Real[n];
        z = new Real[n]; 
        }

      // 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<VTK_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++) 
                {
                VTK_ROTATE(a,j,ip,j,iq);
                }
              // ip and iq already shifted left by 1 unit
              for (j = ip+1;j <= iq-1;j++) 
                {
                VTK_ROTATE(a,ip,j,j,iq);
                }
              // iq already shifted left by 1 unit
              for (j=iq+1; j<n; j++) 
                {
                VTK_ROTATE(a,ip,j,iq,j);
                }
              for (j=0; j<n; j++) 
                {
                VTK_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 >= VTK_MAX_ROTATIONS )
        {
           std::cout << "vtkMath::Jacobi: Error extracting eigenfunctions" << std::endl;
           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.
      int 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)
        {
        delete [] b;
        delete [] z;
        }
      return 1;
    }


}
#endif //MATH_SQUAREMATRIX_HPP 

Revision:	137
Committed:	Thu Oct 21 21:31:39 2004 UTC (21 years ago) by tim
File size:	12083 byte(s)
Log Message:	Snapshot and SnapshotManager in progress
#	Content
1	/*
2	* Copyright (C) 2000-2004 Object Oriented Parallel Simulation Engine (OOPSE) project
3	*
4	* Contact: oopse@oopse.org
5	*
6	* This program is free software; you can redistribute it and/or
7	* modify it under the terms of the GNU Lesser General Public License
8	* as published by the Free Software Foundation; either version 2.1
9	* of the License, or (at your option) any later version.
10	* All we ask is that proper credit is given for our work, which includes
11	* - but is not limited to - adding the above copyright notice to the beginning
12	* of your source code files, and to any copyright notice that you may distribute
13	* with programs based on this work.
14	*
15	* This program is distributed in the hope that it will be useful,
16	* but WITHOUT ANY WARRANTY; without even the implied warranty of
17	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18	* GNU Lesser General Public License for more details.
19	*
20	* You should have received a copy of the GNU Lesser General Public License
21	* along with this program; if not, write to the Free Software
22	* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
23	*
24	*/
25
26	/**
27	* @file SquareMatrix.hpp
28	* @author Teng Lin
29	* @date 10/11/2004
30	* @version 1.0
31	*/
32	#ifndef MATH_SQUAREMATRIX_HPP
33	#define MATH_SQUAREMATRIX_HPP
34
35	#include "math/RectMatrix.hpp"
36
37	namespace oopse {
38
39	/**
40	* @class SquareMatrix SquareMatrix.hpp "math/SquareMatrix.hpp"
41	* @brief A square matrix class
42	* @template Real the element type
43	* @template Dim the dimension of the square matrix
44	*/
45	template<typename Real, int Dim>
46	class SquareMatrix : public RectMatrix<Real, Dim, Dim> {
47	public:
48	typedef Real ElemType;
49	typedef Real* ElemPoinerType;
50
51	/** default constructor */
52	SquareMatrix() {
53	for (unsigned int i = 0; i < Dim; i++)
54	for (unsigned int j = 0; j < Dim; j++)
55	data_[i][j] = 0.0;
56	}
57
58	/** copy constructor */
59	SquareMatrix(const RectMatrix<Real, Dim, Dim>& m) : RectMatrix<Real, Dim, Dim>(m) {
60	}
61
62	/** copy assignment operator */
63	SquareMatrix<Real, Dim>& operator =(const RectMatrix<Real, Dim, Dim>& m) {
64	RectMatrix<Real, Dim, Dim>::operator=(m);
65	return *this;
66	}
67
68	/** Retunrs an identity matrix*/
69
70	static SquareMatrix<Real, Dim> identity() {
71	SquareMatrix<Real, Dim> m;
72
73	for (unsigned int i = 0; i < Dim; i++)
74	for (unsigned int j = 0; j < Dim; j++)
75	if (i == j)
76	m(i, j) = 1.0;
77	else
78	m(i, j) = 0.0;
79
80	return m;
81	}
82
83	/**
84	* Retunrs the inversion of this matrix.
85	* @todo need implementation
86	*/
87	SquareMatrix<Real, Dim> inverse() {
88	SquareMatrix<Real, Dim> result;
89
90	return result;
91	}
92
93	/**
94	* Returns the determinant of this matrix.
95	* @todo need implementation
96	*/
97	Real determinant() const {
98	Real det;
99	return det;
100	}
101
102	/** Returns the trace of this matrix. */
103	Real trace() const {
104	Real tmp = 0;
105
106	for (unsigned int i = 0; i < Dim ; i++)
107	tmp += data_[i][i];
108
109	return tmp;
110	}
111
112	/** Tests if this matrix is symmetrix. */
113	bool isSymmetric() const {
114	for (unsigned int i = 0; i < Dim - 1; i++)
115	for (unsigned int j = i; j < Dim; j++)
116	if (fabs(data_[i][j] - data_[j][i]) > oopse::epsilon)
117	return false;
118
119	return true;
120	}
121
122	/** Tests if this matrix is orthogonal. */
123	bool isOrthogonal() {
124	SquareMatrix<Real, Dim> tmp;
125
126	tmp = this transpose();
127
128	return tmp.isDiagonal();
129	}
130
131	/** Tests if this matrix is diagonal. */
132	bool isDiagonal() const {
133	for (unsigned int i = 0; i < Dim ; i++)
134	for (unsigned int j = 0; j < Dim; j++)
135	if (i !=j && fabs(data_[i][j]) > oopse::epsilon)
136	return false;
137
138	return true;
139	}
140
141	/** Tests if this matrix is the unit matrix. */
142	bool isUnitMatrix() const {
143	if (!isDiagonal())
144	return false;
145
146	for (unsigned int i = 0; i < Dim ; i++)
147	if (fabs(data_[i][i] - 1) > oopse::epsilon)
148	return false;
149
150	return true;
151	}
152
153	/** @todo need implementation */
154	void diagonalize() {
155	//jacobi(m, eigenValues, ortMat);
156	}
157
158	/**
159	* Jacobi iteration routines for computing eigenvalues/eigenvectors of
160	* real symmetric matrix
161	*
162	* @return true if success, otherwise return false
163	* @param a symmetric matrix whose eigenvectors are to be computed. On return, the matrix is
164	* overwritten
165	* @param w will contain the eigenvalues of the matrix On return of this function
166	* @param v the columns of this matrix will contain the eigenvectors. The eigenvectors are
167	* normalized and mutually orthogonal.
168	*/
169
170	static int jacobi(SquareMatrix<Real, Dim>& a, Vector<Real, Dim>& d,
171	SquareMatrix<Real, Dim>& v);
172	};//end SquareMatrix
173
174
175	/*=========================================================================
176
177	Program: Visualization Toolkit
178	Module: $RCSfile: SquareMatrix.hpp,v $
179
180	Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
181	All rights reserved.
182	See Copyright.txt or http://www.kitware.com/Copyright.htm for details.
183
184	This software is distributed WITHOUT ANY WARRANTY; without even
185	the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
186	PURPOSE. See the above copyright notice for more information.
187
188	=========================================================================*/
189
190	#define VTK_ROTATE(a,i,j,k,l) g=a(i, j);h=a(k, l);a(i, j)=g-s(h+gtau);\
191	a(k, l)=h+s(g-htau)
192
193	#define VTK_MAX_ROTATIONS 20
194
195	// Jacobi iteration for the solution of eigenvectors/eigenvalues of a nxn
196	// real symmetric matrix. Square nxn matrix a; size of matrix in n;
197	// output eigenvalues in w; and output eigenvectors in v. Resulting
198	// eigenvalues/vectors are sorted in decreasing order; eigenvectors are
199	// normalized.
200	template<typename Real, int Dim>
201	int SquareMatrix<Real, Dim>::jacobi(SquareMatrix<Real, Dim>& a, Vector<Real, Dim>& w,
202	SquareMatrix<Real, Dim>& v) {
203	const int n = Dim;
204	int i, j, k, iq, ip, numPos;
205	Real tresh, theta, tau, t, sm, s, h, g, c, tmp;
206	Real bspace[4], zspace[4];
207	Real *b = bspace;
208	Real *z = zspace;
209
210	// only allocate memory if the matrix is large
211	if (n > 4)
212	{
213	b = new Real[n];
214	z = new Real[n];
215	}
216
217	// initialize
218	for (ip=0; ip<n; ip++)
219	{
220	for (iq=0; iq<n; iq++)
221	{
222	v(ip, iq) = 0.0;
223	}
224	v(ip, ip) = 1.0;
225	}
226	for (ip=0; ip<n; ip++)
227	{
228	b[ip] = w[ip] = a(ip, ip);
229	z[ip] = 0.0;
230	}
231
232	// begin rotation sequence
233	for (i=0; i<VTK_MAX_ROTATIONS; i++)
234	{
235	sm = 0.0;
236	for (ip=0; ip<n-1; ip++)
237	{
238	for (iq=ip+1; iq<n; iq++)
239	{
240	sm += fabs(a(ip, iq));
241	}
242	}
243	if (sm == 0.0)
244	{
245	break;
246	}
247
248	if (i < 3) // first 3 sweeps
249	{
250	tresh = 0.2sm/(nn);
251	}
252	else
253	{
254	tresh = 0.0;
255	}
256
257	for (ip=0; ip<n-1; ip++)
258	{
259	for (iq=ip+1; iq<n; iq++)
260	{
261	g = 100.0*fabs(a(ip, iq));
262
263	// after 4 sweeps
264	if (i > 3 && (fabs(w[ip])+g) == fabs(w[ip])
265	&& (fabs(w[iq])+g) == fabs(w[iq]))
266	{
267	a(ip, iq) = 0.0;
268	}
269	else if (fabs(a(ip, iq)) > tresh)
270	{
271	h = w[iq] - w[ip];
272	if ( (fabs(h)+g) == fabs(h))
273	{
274	t = (a(ip, iq)) / h;
275	}
276	else
277	{
278	theta = 0.5*h / (a(ip, iq));
279	t = 1.0 / (fabs(theta)+sqrt(1.0+theta*theta));
280	if (theta < 0.0)
281	{
282	t = -t;
283	}
284	}
285	c = 1.0 / sqrt(1+t*t);
286	s = t*c;
287	tau = s/(1.0+c);
288	h = t*a(ip, iq);
289	z[ip] -= h;
290	z[iq] += h;
291	w[ip] -= h;
292	w[iq] += h;
293	a(ip, iq)=0.0;
294
295	// ip already shifted left by 1 unit
296	for (j = 0;j <= ip-1;j++)
297	{
298	VTK_ROTATE(a,j,ip,j,iq);
299	}
300	// ip and iq already shifted left by 1 unit
301	for (j = ip+1;j <= iq-1;j++)
302	{
303	VTK_ROTATE(a,ip,j,j,iq);
304	}
305	// iq already shifted left by 1 unit
306	for (j=iq+1; j<n; j++)
307	{
308	VTK_ROTATE(a,ip,j,iq,j);
309	}
310	for (j=0; j<n; j++)
311	{
312	VTK_ROTATE(v,j,ip,j,iq);
313	}
314	}
315	}
316	}
317
318	for (ip=0; ip<n; ip++)
319	{
320	b[ip] += z[ip];
321	w[ip] = b[ip];
322	z[ip] = 0.0;
323	}
324	}
325
326	//// this is NEVER called
327	if ( i >= VTK_MAX_ROTATIONS )
328	{
329	std::cout << "vtkMath::Jacobi: Error extracting eigenfunctions" << std::endl;
330	return 0;
331	}
332
333	// sort eigenfunctions these changes do not affect accuracy
334	for (j=0; j<n-1; j++) // boundary incorrect
335	{
336	k = j;
337	tmp = w[k];
338	for (i=j+1; i<n; i++) // boundary incorrect, shifted already
339	{
340	if (w[i] >= tmp) // why exchage if same?
341	{
342	k = i;
343	tmp = w[k];
344	}
345	}
346	if (k != j)
347	{
348	w[k] = w[j];
349	w[j] = tmp;
350	for (i=0; i<n; i++)
351	{
352	tmp = v(i, j);
353	v(i, j) = v(i, k);
354	v(i, k) = tmp;
355	}
356	}
357	}
358	// insure eigenvector consistency (i.e., Jacobi can compute vectors that
359	// are negative of one another (.707,.707,0) and (-.707,-.707,0). This can
360	// reek havoc in hyperstreamline/other stuff. We will select the most
361	// positive eigenvector.
362	int ceil_half_n = (n >> 1) + (n & 1);
363	for (j=0; j<n; j++)
364	{
365	for (numPos=0, i=0; i<n; i++)
366	{
367	if ( v(i, j) >= 0.0 )
368	{
369	numPos++;
370	}
371	}
372	// if ( numPos < ceil(double(n)/double(2.0)) )
373	if ( numPos < ceil_half_n)
374	{
375	for(i=0; i<n; i++)
376	{
377	v(i, j) *= -1.0;
378	}
379	}
380	}
381
382	if (n > 4)
383	{
384	delete [] b;
385	delete [] z;
386	}
387	return 1;
388	}
389
390
391	}
392	#endif //MATH_SQUAREMATRIX_HPP
393