doc/getfem_reference/gmm__dense__sylvester_8h_source.html

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 /** @file gmm_dense_sylvester.h

     @author  Yves Renard <Yves.Renard@insa-lyon.fr>

     @date June 5, 2003.

     @brief Sylvester equation solver.

 */

 #ifndef GMM_DENSE_SYLVESTER_H

 #define GMM_DENSE_SYLVESTER_H


 #include "gmm_kernel.h"


 namespace gmm {


   /* ********************************************************************* */

   /*   Kronecker system matrix.                                            */

   /* ********************************************************************* */

   template <typename MAT1, typename MAT2, typename MAT3>

   void kron(const MAT1 &m1, const MAT2 &m2, const MAT3 &m3_,

             bool init = true) {

     MAT3 &m3 = const_cast<MAT3 &>(m3_);

     size_type m = mat_nrows(m1), n = mat_ncols(m1);

     size_type l = mat_nrows(m2), k = mat_ncols(m2);


     GMM_ASSERT2(mat_nrows(m3) == m*l && mat_ncols(m3) == n*k,

                 "dimensions mismatch");


     for (size_type i = 0; i < m; ++i)

       for (size_type j = 0; j < m; ++j)

         if (init)

           gmm::copy(gmm::scaled(m2, m1(i,j)),

                     gmm::sub_matrix(m3, sub_interval(l*i, l),

                                     sub_interval(k*j, k)));

         else

           gmm::add(gmm::scaled(m2, m1(i,j)),

                     gmm::sub_matrix(m3, sub_interval(l*i, l),

                                     sub_interval(k*j, k)));

   }


   /* ********************************************************************* */

   /*   Copy a matrix into a vector.                                        */

   /* ********************************************************************* */


   template <typename MAT, typename VECT>

   colmatrix_to_vector(const MAT &A, VECT &v, col_major) {

     size_type m = mat_nrows(A), n = mat_ncols(A);

     GMM_ASSERT2(m*n == vect_size(v), "dimensions mismatch");

     for (size_type i = 0; i < n; ++i)

       gmm::copy(mat_col(A, i), sub_vector(v, sub_interval(i*m, m)));

   }


   template <typename MAT, typename VECT>

   colmatrix_to_vector(const MAT &A, VECT &v, row_and_col)

   { colmatrix_to_vector(A, v, col_major()); }


   template <typename MAT, typename VECT>

   colmatrix_to_vector(const MAT &A, VECT &v, col_and_row)

   { colmatrix_to_vector(A, v, col_major()); }


   template <typename MAT, typename VECT>

   colmatrix_to_vector(const MAT &A, VECT &v, row_major) {

     size_type m = mat_nrows(mat), n = mat_ncols(A);

     GMM_ASSERT2(m*n == vect_size(v), "dimensions mismatch");

     for (size_type i = 0; i < m; ++i)

       gmm::copy(mat_row(A, i), sub_vector(v, sub_slice(i, n, m)));

   }


   template <typename MAT, typename VECT> inline

   colmatrix_to_vector(const MAT &A, const VECT &v_) {

     VECT &v = const_cast<VECT &>(v_);

     colmatrix_to_vector(A, v, typename linalg_traits<MAT>::sub_orientation());

   }


   /* ********************************************************************* */

   /*   Copy a vector into a matrix.                                        */

   /* ********************************************************************* */


   template <typename MAT, typename VECT>

   vector_to_colmatrix(const VECT &v, MAT &A, col_major) {

     size_type m = mat_nrows(A), n = mat_ncols(A);

     GMM_ASSERT2(m*n == vect_size(v), "dimensions mismatch");

     for (size_type i = 0; i < n; ++i)

       gmm::copy(sub_vector(v, sub_interval(i*m, m)), mat_col(A, i));

   }


   template <typename MAT, typename VECT>

   vector_to_colmatrix(const VECT &v, MAT &A, row_and_col)

   { vector_to_colmatrix(v, A, col_major()); }


   template <typename MAT, typename VECT>

   vector_to_colmatrix(const VECT &v, MAT &A, col_and_row)

   { vector_to_colmatrix(v, A, col_major()); }


   template <typename MAT, typename VECT>

   vector_to_colmatrix(const VECT &v, MAT &A, row_major) {

     size_type m = mat_nrows(mat), n = mat_ncols(A);

     GMM_ASSERT2(m*n == vect_size(v), "dimensions mismatch");

     for (size_type i = 0; i < m; ++i)

       gmm::copy(sub_vector(v, sub_slice(i, n, m)), mat_row(A, i));

   }


   template <typename MAT, typename VECT> inline

   vector_to_colmatrix(const VECT &v, const MAT &A_) {

     MAT &A = const_cast<MAT &>(A_);

     vector_to_colmatrix(v, A, typename linalg_traits<MAT>::sub_orientation());

   }


   /* ********************************************************************* */

   /*   Solve sylvester equation.                                           */

   /* ********************************************************************* */


   // very prohibitive solver, to be replaced ...

   template <typename MAT1, typename MAT2, typename MAT3, typename MAT4 >

   void sylvester(const MAT1 &m1, const MAT2 &m2, const MAT3 &m3,

                  const MAT4 &m4_) {

     typedef typename linalg_traits<Mat>::value_type T;


     MAT3 &m4 = const_cast<MAT4 &>(m4_);

     size_type m = mat_nrows(m1), n = mat_ncols(m1);

     size_type l = mat_nrows(m2), k = mat_ncols(m2);


     GMM_ASSERT2(m == n && l == k && m == mat_nrows(m3) &&

                 l == mat_ncols(m3) && m == mat_nrows(m4) && l == mat_ncols(m4),

                 "dimensions mismatch");


     gmm::dense_matrix<T> akronb(m*l, m*l);

     gmm::dense_matrix<T> idm(m, m), idl(l,l);

     gmm::copy(identity_matrix(), idm);

     gmm::copy(identity_matrix(), idl);

     std::vector<T> x(m*l), c(m*l);


     kron(idl, m1, akronb);

     kron(gmm::transposed(m2), idm, akronb, false);


     colmatrix_to_vector(m3, c);

     lu_solve(akronb, c, x);

     vector_to_colmatrix(x, m4);


   }

 }


 #endif


gmm::copy
void copy(const L1 &l1, L2 &l2)
*‍/
Definition: gmm_blas.h:976

gmm::add
void add(const L1 &l1, L2 &l2)
*‍/
Definition: gmm_blas.h:1275

gmm::lu_solve
void lu_solve(const DenseMatrix &LU, const Pvector &pvector, VectorX &x, const VectorB &b)
LU Solve : Solve equation Ax=b, given an LU factored matrix.
Definition: gmm_dense_lu.h:129

gmm_kernel.h
Include the base gmm files.

bgeot::size_type
size_t size_type
used as the common size type in the library
Definition: bgeot_poly.h:48