Epetra Package Browser (Single Doxygen Collection)  Development
Epetra_SerialDenseSVD.h
Go to the documentation of this file.
1 /*
2 //@HEADER
3 // ************************************************************************
4 //
5 // Epetra: Linear Algebra Services Package
6 // Copyright 2011 Sandia Corporation
7 //
8 // Under the terms of Contract DE-AC04-94AL85000 with Sandia Corporation,
9 // the U.S. Government retains certain rights in this software.
10 //
11 // Redistribution and use in source and binary forms, with or without
12 // modification, are permitted provided that the following conditions are
13 // met:
14 //
15 // 1. Redistributions of source code must retain the above copyright
16 // notice, this list of conditions and the following disclaimer.
17 //
18 // 2. Redistributions in binary form must reproduce the above copyright
19 // notice, this list of conditions and the following disclaimer in the
20 // documentation and/or other materials provided with the distribution.
21 //
22 // 3. Neither the name of the Corporation nor the names of the
23 // contributors may be used to endorse or promote products derived from
24 // this software without specific prior written permission.
25 //
26 // THIS SOFTWARE IS PROVIDED BY SANDIA CORPORATION "AS IS" AND ANY
27 // EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
28 // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
29 // PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL SANDIA CORPORATION OR THE
30 // CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
31 // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
32 // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
33 // PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
34 // LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
35 // NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
36 // SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
37 //
38 // Questions? Contact Michael A. Heroux (maherou@sandia.gov)
39 //
40 // ************************************************************************
41 //@HEADER
42 */
43 
44 #ifndef _EPETRA_SERIALDENSESVD_H_
45 #define _EPETRA_SERIALDENSESVD_H_
46 
47 #include "Epetra_SerialDenseOperator.h"
48 #include "Epetra_SerialDenseMatrix.h"
49 #include "Epetra_Object.h"
50 #include "Epetra_CompObject.h"
51 #include "Epetra_BLAS.h"
52 #include "Epetra_LAPACK.h"
53 
54 
56 
114 //=========================================================================
115 class Epetra_SerialDenseSVD : public virtual Epetra_SerialDenseOperator, public Epetra_CompObject, public virtual Epetra_Object, public Epetra_BLAS, public Epetra_LAPACK{
116  public:
117 
119 
120  Epetra_SerialDenseSVD();
122 
124  virtual ~Epetra_SerialDenseSVD();
126 
128 
129 
131  int SetMatrix(Epetra_SerialDenseMatrix & A);
132 
134 
137  int SetVectors(Epetra_SerialDenseMatrix & X, Epetra_SerialDenseMatrix & B);
139 
141 
142 
144 
146 // void FactorWithEquilibration(bool Flag) {Equilibrate_ = Flag; return;};
147 
149  void SolveWithTranspose(bool Flag) {Transpose_ = Flag; if (Flag) TRANS_ = 'T'; else TRANS_ = 'N'; return;};
150 
152 // void SolveToRefinedSolution(bool Flag) {RefineSolution_ = Flag; return;};
153 
154  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
155  // Causes all solves to estimate the forward and backward solution error.
156  /* Error estimates will be in the arrays FERR and BERR, resp, after the solve step is complete.
157  These arrays are accessible via the FERR() and BERR() access functions.
158  */
159 // void EstimateSolutionErrors(bool Flag) {EstimateSolutionErrors_ = Flag; return;};
161 
163 
164 
165  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
166  // Computes the SVD factorization of the matrix using the LAPACK routine \e DGESVD.
167  /*
168  \return Integer error code, set to 0 if successful.
169  */
170 // virtual int Factor(void);
171  virtual int Factor(void);
172 
174 
177  virtual int Solve(void);
178 
180 
183  virtual int Invert( double rthresh = 0.0, double athresh = 0.0 );
184 
185  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
186  // Computes the scaling vector S(i) = 1/sqrt(A(i,i) of the \e this matrix.
187  /*
188  \return Integer error code, set to 0 if successful. Otherwise returns the LAPACK error code INFO.
189  */
190 // virtual int ComputeEquilibrateScaling(void);
191 
192  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
193  // Equilibrates the \e this matrix.
194  /*
195  \return Integer error code, set to 0 if successful. Otherwise returns the LAPACK error code INFO.
196  */
197 // virtual int EquilibrateMatrix(void);
198 
199  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
200  // Equilibrates the current RHS.
201  /*
202  \return Integer error code, set to 0 if successful. Otherwise returns the LAPACK error code INFO.
203  */
204 // int EquilibrateRHS(void);
205 
206 
207  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
208  // Apply Iterative Refinement.
209  /*
210  \return Integer error code, set to 0 if successful. Otherwise returns the LAPACK error code INFO.
211  */
212 // virtual int ApplyRefinement(void);
213 
214  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
215  // Unscales the solution vectors if equilibration was used to solve the system.
216  /*
217  \return Integer error code, set to 0 if successful. Otherwise returns the LAPACK error code INFO.
218  */
219 // int UnequilibrateLHS(void);
220 
221  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
222  // Returns the reciprocal of the 1-norm condition number of the \e this matrix.
223  /*
224  \param Value Out
225  On return contains the reciprocal of the 1-norm condition number of the \e this matrix.
226 
227  \return Integer error code, set to 0 if successful. Otherwise returns the LAPACK error code INFO.
228  */
229 // virtual int ReciprocalConditionEstimate(double & Value);
231 
233 
234 
236  bool Transpose() {return(Transpose_);};
237 
239  bool Factored() {return(Factored_);};
240 
241  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
242  // Returns true if factor is equilibrated (factor available via AF() and LDAF()).
243 // bool A_Equilibrated() {return(A_Equilibrated_);};
244 
245  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
246  // Returns true if RHS is equilibrated (RHS available via B() and LDB()).
247 // bool B_Equilibrated() {return(B_Equilibrated_);};
248 
249  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
250  // Returns true if the LAPACK general rules for equilibration suggest you should equilibrate the system.
251 // virtual bool ShouldEquilibrate() {ComputeEquilibrateScaling(); return(ShouldEquilibrate_);};
252 
253  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
254  // Returns true if forward and backward error estimated have been computed (available via FERR() and BERR()).
255 // bool SolutionErrorsEstimated() {return(SolutionErrorsEstimated_);};
256 
258  bool Inverted() {return(Inverted_);};
259 
260  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
261  // Returns true if the condition number of the \e this matrix has been computed (value available via ReciprocalConditionEstimate()).
262 // bool ReciprocalConditionEstimated() {return(ReciprocalConditionEstimated_);};
263 
265  bool Solved() {return(Solved_);};
266 
267  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
268  // Returns true if the current set of vectors has been refined.
269 // bool SolutionRefined() {return(SolutionRefined_);};
271 
273 
274 
276  Epetra_SerialDenseMatrix * Matrix() const {return(Matrix_);};
277 
278  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
279  // Returns pointer to factored matrix (assuming factorization has been performed).
280 // Epetra_SerialDenseMatrix * FactoredMatrix() const {return(Factor_);};
281 
283  Epetra_SerialDenseMatrix * InvertedMatrix() const {return(Inverse_);};
284 
286  Epetra_SerialDenseMatrix * LHS() const {return(LHS_);};
287 
289  Epetra_SerialDenseMatrix * RHS() const {return(RHS_);};
290 
292  int M() const {return(M_);};
293 
295  int N() const {return(N_);};
296 
298  double * A() const {return(A_);};
299 
301  int LDA() const {return(LDA_);};
302 
304  double * B() const {return(B_);};
305 
307  int LDB() const {return(LDB_);};
308 
310  int NRHS() const {return(NRHS_);};
311 
313  double * X() const {return(X_);};
314 
316  int LDX() const {return(LDX_);};
317 
318  double * S() const {return(S_);};
319 
320  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
321  // Returns pointer to the factored matrix (may be the same as A() if factorization done in place).
322 // double * AF() const {return(AF_);};
323 
324  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
325  // Returns the leading dimension of the factored matrix.
326 // int LDAF() const {return(LDAF_);};
327 
329  double * AI() const {return(AI_);};
330 
332  int LDAI() const {return(LDAI_);};
333 
334  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
335  // Returns pointer to pivot vector (if factorization has been computed), zero otherwise.
336 // int * IPIV() const {return(IPIV_);};
337 
339  double ANORM() const {return(ANORM_);};
340 
341  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
342  // Returns the reciprocal of the condition number of the \e this matrix (returns -1 if not yet computed).
343 // double RCOND() const {return(RCOND_);};
344 
345  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
346  // Ratio of smallest to largest row scale factors for the \e this matrix (returns -1 if not yet computed).
347  /* If ROWCND() is >= 0.1 and AMAX() is not close to overflow or underflow, then equilibration is not needed.
348  */
349 // double ROWCND() const {return(ROWCND_);};
350 
351  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
352  // Ratio of smallest to largest column scale factors for the \e this matrix (returns -1 if not yet computed).
353  /* If COLCND() is >= 0.1 then equilibration is not needed.
354  */
355 // double COLCND() const {return(COLCND_);};
356 
357  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
358  // Returns the absolute value of the largest entry of the \e this matrix (returns -1 if not yet computed).
359 // double AMAX() const {return(AMAX_);};
360 
361  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
362  // Returns a pointer to the forward error estimates computed by LAPACK.
363 // double * FERR() const {return(FERR_);};
364 
365  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
366  // Returns a pointer to the backward error estimates computed by LAPACK.
367 // double * BERR() const {return(BERR_);};
368 
369  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
370  // Returns a pointer to the row scaling vector used for equilibration.
371 // double * R() const {return(R_);};
372 
373  // NOTE: doxygen-style documentation needs to be re-enabled if this function is re-enabled
374  // Returns a pointer to the column scale vector used for equilibration.
375 // double * C() const {return(C_);};
377 
379 
380  virtual void Print(std::ostream& os) const;
383 
385 
386 
388 
397  virtual int SetUseTranspose(bool use_transpose) { UseTranspose_ = use_transpose; return (0); }
398 
400 
408  virtual int Apply(const Epetra_SerialDenseMatrix& Xmat, Epetra_SerialDenseMatrix& Ymat)
409  { return Ymat.Multiply( UseTranspose_, false, 1.0, *Matrix(), Xmat, 0.0 ); }
410 
412 
421  virtual int ApplyInverse(const Epetra_SerialDenseMatrix & Xmat, Epetra_SerialDenseMatrix & Ymat)
422  { SetVectors(const_cast<Epetra_SerialDenseMatrix&>(Xmat),Ymat);
423  SolveWithTranspose(UseTranspose_);
424  return Solve(); }
425 
427  /* Returns the quantity \f$ \| A \|_\infty\f$ such that
428  \f[\| A \|_\infty = \max_{1\lei\lem} \sum_{j=1}^n |a_{ij}| \f].
429 
430  \warning This method must not be called unless HasNormInf() returns true.
431  */
432  virtual double NormInf() const { return Matrix()->NormInf(); }
433 
435  virtual const char * Label() const { return Epetra_Object::Label(); }
436 
438  virtual bool UseTranspose() const { return UseTranspose_; }
439 
441  virtual bool HasNormInf() const { return true; }
442 
444  virtual int RowDim() const { return M(); }
445 
447  virtual int ColDim() const { return N(); }
448 
450 
451  void AllocateWORK() {if (WORK_==0) {LWORK_ = 4*N_; WORK_ = new double[LWORK_];} return;};
452  void AllocateIWORK() {if (IWORK_==0) IWORK_ = new int[N_]; return;};
453  void InitPointers();
454  void DeleteArrays();
455  void ResetMatrix();
456  void ResetVectors();
457 
458 
459 // bool Equilibrate_;
460 // bool ShouldEquilibrate_;
461 // bool A_Equilibrated_;
462 // bool B_Equilibrated_;
463  bool Transpose_;
464  bool Factored_;
465 // bool EstimateSolutionErrors_;
466 // bool SolutionErrorsEstimated_;
467  bool Solved_;
468  bool Inverted_;
469 // bool ReciprocalConditionEstimated_;
470 // bool RefineSolution_;
471 // bool SolutionRefined_;
472 
473  char TRANS_;
474 
475  int M_;
476  int N_;
477  int Min_MN_;
478  int NRHS_;
479  int LDA_;
480 // int LDAF_;
481  int LDAI_;
482  int LDB_;
483  int LDX_;
484  int INFO_;
485  int LWORK_;
486 
487 // int * IPIV_;
488  int * IWORK_;
489 
490  double ANORM_;
491 // double RCOND_;
492 // double ROWCND_;
493 // double COLCND_;
494 // double AMAX_;
495 
496  Epetra_SerialDenseMatrix * Matrix_;
497  Epetra_SerialDenseMatrix * LHS_;
498  Epetra_SerialDenseMatrix * RHS_;
499 // Epetra_SerialDenseMatrix * Factor_;
500  Epetra_SerialDenseMatrix * Inverse_;
501 
502  double * A_;
503 // double * FERR_;
504 // double * BERR_;
505 // double * AF_;
506  double * AI_;
507  double * WORK_;
508 // double * R_;
509 // double * C_;
510  double * U_;
511  double * S_;
512  double * Vt_;
513 
514  double * B_;
515  double * X_;
516 
517  bool UseTranspose_;
518 
519  private:
520  // Epetra_SerialDenseSolver copy constructor (put here because we don't want user access)
521 
522  Epetra_SerialDenseSVD(const Epetra_SerialDenseSVD& Source);
523  Epetra_SerialDenseSVD & operator=(const Epetra_SerialDenseSVD& Source);
524 };
525 
526 #endif /* _EPETRA_SERIALDENSESVD_H_ */
Epetra_BLAS.h
Epetra_CompObject.h
Epetra_LAPACK.h
Epetra_Object.h
Epetra_SerialDenseMatrix.h
Epetra_SerialDenseOperator.h
Epetra_BLAS
Epetra_BLAS: The Epetra BLAS Wrapper Class.
Definition: Epetra_BLAS.h:70
Epetra_CompObject
Epetra_CompObject: Functionality and data that is common to all computational classes.
Definition: Epetra_CompObject.h:57
Epetra_LAPACK
Epetra_LAPACK: The Epetra LAPACK Wrapper Class.
Definition: Epetra_LAPACK.h:67
Epetra_Object
Epetra_Object: The base Epetra class.
Definition: Epetra_Object.h:57
Epetra_Object::Label
virtual const char * Label() const
Epetra_Object Label access funtion.
Definition: Epetra_Object.cpp:130
Epetra_SerialDenseMatrix
Epetra_SerialDenseMatrix: A class for constructing and using real double precision general dense matr...
Definition: Epetra_SerialDenseMatrix.h:107
Epetra_SerialDenseMatrix::NormInf
virtual double NormInf() const
Computes the Infinity-Norm of the this matrix.
Definition: Epetra_SerialDenseMatrix.cpp:384
Epetra_SerialDenseMatrix::Multiply
int Multiply(char TransA, char TransB, double ScalarAB, const Epetra_SerialDenseMatrix &A, const Epetra_SerialDenseMatrix &B, double ScalarThis)
Matrix-Matrix multiplication, this = ScalarThis*this + ScalarAB*A*B.
Definition: Epetra_SerialDenseMatrix.cpp:420
Epetra_SerialDenseOperator
Epetra_SerialDenseOperator: A pure virtual class for using real-valued double-precision operators.
Definition: Epetra_SerialDenseOperator.h:58
Epetra_SerialDenseSVD
Epetra_SerialDenseSVD: A class for SVDing dense linear problems.
Definition: Epetra_SerialDenseSVD.h:115
Epetra_SerialDenseSVD::N_
int N_
Definition: Epetra_SerialDenseSVD.h:476
Epetra_SerialDenseSVD::RHS_
Epetra_SerialDenseMatrix * RHS_
Definition: Epetra_SerialDenseSVD.h:498
Epetra_SerialDenseSVD::Inverse_
Epetra_SerialDenseMatrix * Inverse_
Definition: Epetra_SerialDenseSVD.h:500
Epetra_SerialDenseSVD::LWORK_
int LWORK_
Definition: Epetra_SerialDenseSVD.h:485
Epetra_SerialDenseSVD::Matrix_
Epetra_SerialDenseMatrix * Matrix_
Definition: Epetra_SerialDenseSVD.h:496
Epetra_SerialDenseSVD::Transpose
bool Transpose()
Returns true if transpose of this matrix has and will be used.
Definition: Epetra_SerialDenseSVD.h:236
Epetra_SerialDenseSVD::UseTranspose_
bool UseTranspose_
Definition: Epetra_SerialDenseSVD.h:517
Epetra_SerialDenseSVD::B_
double * B_
Definition: Epetra_SerialDenseSVD.h:514
Epetra_SerialDenseSVD::HasNormInf
virtual bool HasNormInf() const
Returns true if the this object can provide an approximate Inf-norm, false otherwise.
Definition: Epetra_SerialDenseSVD.h:441
Epetra_SerialDenseSVD::WORK_
double * WORK_
Definition: Epetra_SerialDenseSVD.h:507
Epetra_SerialDenseSVD::LDX
int LDX() const
Returns the leading dimension of the solution.
Definition: Epetra_SerialDenseSVD.h:316
Epetra_SerialDenseSVD::RowDim
virtual int RowDim() const
Returns the row dimension of operator.
Definition: Epetra_SerialDenseSVD.h:444
Epetra_SerialDenseSVD::Solve
virtual int Solve(void)
Computes the solution X to AX = B for the this matrix and the B provided to SetVectors()....
Definition: Epetra_SerialDenseSVD.cpp:261
Epetra_SerialDenseSVD::ANORM
double ANORM() const
Returns the 1-Norm of the this matrix (returns -1 if not yet computed).
Definition: Epetra_SerialDenseSVD.h:339
Epetra_SerialDenseSVD::AllocateIWORK
void AllocateIWORK()
Definition: Epetra_SerialDenseSVD.h:452
Epetra_SerialDenseSVD::Inverted_
bool Inverted_
Definition: Epetra_SerialDenseSVD.h:468
Epetra_SerialDenseSVD::LDX_
int LDX_
Definition: Epetra_SerialDenseSVD.h:483
Epetra_SerialDenseSVD::Matrix
Epetra_SerialDenseMatrix * Matrix() const
Returns pointer to current matrix.
Definition: Epetra_SerialDenseSVD.h:276
Epetra_SerialDenseSVD::IWORK_
int * IWORK_
Definition: Epetra_SerialDenseSVD.h:488
Epetra_SerialDenseSVD::INFO_
int INFO_
Definition: Epetra_SerialDenseSVD.h:484
Epetra_SerialDenseSVD::X
double * X() const
Returns pointer to current solution.
Definition: Epetra_SerialDenseSVD.h:313
Epetra_SerialDenseSVD::SetVectors
int SetVectors(Epetra_SerialDenseMatrix &X, Epetra_SerialDenseMatrix &B)
Sets the pointers for left and right hand side vector(s).
Definition: Epetra_SerialDenseSVD.cpp:194
Epetra_SerialDenseSVD::Min_MN_
int Min_MN_
Definition: Epetra_SerialDenseSVD.h:477
Epetra_SerialDenseSVD::Transpose_
bool Transpose_
Definition: Epetra_SerialDenseSVD.h:463
Epetra_SerialDenseSVD::M_
int M_
Definition: Epetra_SerialDenseSVD.h:475
Epetra_SerialDenseSVD::Solved_
bool Solved_
Definition: Epetra_SerialDenseSVD.h:467
Epetra_SerialDenseSVD::NRHS
int NRHS() const
Returns the number of current right hand sides and solution vectors.
Definition: Epetra_SerialDenseSVD.h:310
Epetra_SerialDenseSVD::ApplyInverse
virtual int ApplyInverse(const Epetra_SerialDenseMatrix &Xmat, Epetra_SerialDenseMatrix &Ymat)
Returns the result of a Epetra_SerialDenseOperator inverse applied to an Epetra_SerialDenseMatrix X i...
Definition: Epetra_SerialDenseSVD.h:421
Epetra_SerialDenseSVD::operator=
Epetra_SerialDenseSVD & operator=(const Epetra_SerialDenseSVD &Source)
Epetra_SerialDenseSVD::TRANS_
char TRANS_
Definition: Epetra_SerialDenseSVD.h:473
Epetra_SerialDenseSVD::Invert
virtual int Invert(double rthresh=0.0, double athresh=0.0)
Inverts the this matrix.
Definition: Epetra_SerialDenseSVD.cpp:480
Epetra_SerialDenseSVD::S
double * S() const
Definition: Epetra_SerialDenseSVD.h:318
Epetra_SerialDenseSVD::ResetVectors
void ResetVectors()
Definition: Epetra_SerialDenseSVD.cpp:178
Epetra_SerialDenseSVD::NRHS_
int NRHS_
Definition: Epetra_SerialDenseSVD.h:478
Epetra_SerialDenseSVD::M
int M() const
Returns row dimension of system.
Definition: Epetra_SerialDenseSVD.h:292
Epetra_SerialDenseSVD::~Epetra_SerialDenseSVD
virtual ~Epetra_SerialDenseSVD()
Epetra_SerialDenseSVD destructor.
Definition: Epetra_SerialDenseSVD.cpp:89
Epetra_SerialDenseSVD::N
int N() const
Returns column dimension of system.
Definition: Epetra_SerialDenseSVD.h:295
Epetra_SerialDenseSVD::LHS_
Epetra_SerialDenseMatrix * LHS_
Definition: Epetra_SerialDenseSVD.h:497
Epetra_SerialDenseSVD::NormInf
virtual double NormInf() const
Returns the infinity norm of the global matrix.
Definition: Epetra_SerialDenseSVD.h:432
Epetra_SerialDenseSVD::ResetMatrix
void ResetMatrix()
Definition: Epetra_SerialDenseSVD.cpp:136
Epetra_SerialDenseSVD::AI_
double * AI_
Definition: Epetra_SerialDenseSVD.h:506
Epetra_SerialDenseSVD::A
double * A() const
Returns pointer to the this matrix.
Definition: Epetra_SerialDenseSVD.h:298
Epetra_SerialDenseSVD::SetMatrix
int SetMatrix(Epetra_SerialDenseMatrix &A)
Sets the pointers for coefficient matrix.
Definition: Epetra_SerialDenseSVD.cpp:164
Epetra_SerialDenseSVD::ColDim
virtual int ColDim() const
Returns the column dimension of operator.
Definition: Epetra_SerialDenseSVD.h:447
Epetra_SerialDenseSVD::ANORM_
double ANORM_
Definition: Epetra_SerialDenseSVD.h:490
Epetra_SerialDenseSVD::Vt_
double * Vt_
Definition: Epetra_SerialDenseSVD.h:512
Epetra_SerialDenseSVD::X_
double * X_
Definition: Epetra_SerialDenseSVD.h:515
Epetra_SerialDenseSVD::InitPointers
void InitPointers()
Definition: Epetra_SerialDenseSVD.cpp:94
Epetra_SerialDenseSVD::DeleteArrays
void DeleteArrays()
Definition: Epetra_SerialDenseSVD.cpp:114
Epetra_SerialDenseSVD::LDAI_
int LDAI_
Definition: Epetra_SerialDenseSVD.h:481
Epetra_SerialDenseSVD::SolveWithTranspose
void SolveWithTranspose(bool Flag)
Causes equilibration to be called just before the matrix factorization as part of the call to Factor.
Definition: Epetra_SerialDenseSVD.h:149
Epetra_SerialDenseSVD::S_
double * S_
Definition: Epetra_SerialDenseSVD.h:511
Epetra_SerialDenseSVD::U_
double * U_
Definition: Epetra_SerialDenseSVD.h:510
Epetra_SerialDenseSVD::Inverted
bool Inverted()
Returns true if matrix inverse has been computed (inverse available via AF() and LDAF()).
Definition: Epetra_SerialDenseSVD.h:258
Epetra_SerialDenseSVD::Epetra_SerialDenseSVD
Epetra_SerialDenseSVD()
Default constructor; matrix should be set using SetMatrix(), LHS and RHS set with SetVectors().
Definition: Epetra_SerialDenseSVD.cpp:48
Epetra_SerialDenseSVD::LDA_
int LDA_
Definition: Epetra_SerialDenseSVD.h:479
Epetra_SerialDenseSVD::AI
double * AI() const
Returns pointer to the inverted matrix (may be the same as A() if factorization done in place).
Definition: Epetra_SerialDenseSVD.h:329
Epetra_SerialDenseSVD::Apply
virtual int Apply(const Epetra_SerialDenseMatrix &Xmat, Epetra_SerialDenseMatrix &Ymat)
Returns the result of a Epetra_SerialDenseOperator applied to a Epetra_SerialDenseMatrix X in Y.
Definition: Epetra_SerialDenseSVD.h:408
Epetra_SerialDenseSVD::Print
virtual void Print(std::ostream &os) const
Print service methods; defines behavior of ostream << operator.
Definition: Epetra_SerialDenseSVD.cpp:560
Epetra_SerialDenseSVD::AllocateWORK
void AllocateWORK()
Definition: Epetra_SerialDenseSVD.h:451
Epetra_SerialDenseSVD::Epetra_SerialDenseSVD
Epetra_SerialDenseSVD(const Epetra_SerialDenseSVD &Source)
Epetra_SerialDenseSVD::LHS
Epetra_SerialDenseMatrix * LHS() const
Returns pointer to current LHS.
Definition: Epetra_SerialDenseSVD.h:286
Epetra_SerialDenseSVD::Factored_
bool Factored_
Definition: Epetra_SerialDenseSVD.h:464
Epetra_SerialDenseSVD::LDA
int LDA() const
Returns the leading dimension of the this matrix.
Definition: Epetra_SerialDenseSVD.h:301
Epetra_SerialDenseSVD::InvertedMatrix
Epetra_SerialDenseMatrix * InvertedMatrix() const
Returns pointer to inverted matrix (assuming inverse has been performed).
Definition: Epetra_SerialDenseSVD.h:283
Epetra_SerialDenseSVD::Label
virtual const char * Label() const
Returns a character string describing the operator.
Definition: Epetra_SerialDenseSVD.h:435
Epetra_SerialDenseSVD::A_
double * A_
Definition: Epetra_SerialDenseSVD.h:502
Epetra_SerialDenseSVD::RHS
Epetra_SerialDenseMatrix * RHS() const
Returns pointer to current RHS.
Definition: Epetra_SerialDenseSVD.h:289
Epetra_SerialDenseSVD::LDB_
int LDB_
Definition: Epetra_SerialDenseSVD.h:482
Epetra_SerialDenseSVD::LDB
int LDB() const
Returns the leading dimension of the RHS.
Definition: Epetra_SerialDenseSVD.h:307
Epetra_SerialDenseSVD::SetUseTranspose
virtual int SetUseTranspose(bool use_transpose)
If set true, transpose of this operator will be applied.
Definition: Epetra_SerialDenseSVD.h:397
Epetra_SerialDenseSVD::UseTranspose
virtual bool UseTranspose() const
Returns the current UseTranspose setting.
Definition: Epetra_SerialDenseSVD.h:438
Epetra_SerialDenseSVD::LDAI
int LDAI() const
Returns the leading dimension of the inverted matrix.
Definition: Epetra_SerialDenseSVD.h:332
Epetra_SerialDenseSVD::B
double * B() const
Returns pointer to current RHS.
Definition: Epetra_SerialDenseSVD.h:304
Epetra_SerialDenseSVD::Factor
virtual int Factor(void)
Definition: Epetra_SerialDenseSVD.cpp:214
Epetra_SerialDenseSVD::Factored
bool Factored()
Returns true if matrix is factored (factor available via AF() and LDAF()).
Definition: Epetra_SerialDenseSVD.h:239
Epetra_SerialDenseSVD::Solved
bool Solved()
Returns true if the current set of vectors has been solved.
Definition: Epetra_SerialDenseSVD.h:265
Generated by doxygen 1.9.1