op-scm-m.cc

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/*

Copyright (C) 2004-2018 David Bateman
Copyright (C) 1998-2004 Andy Adler

This file is part of Octave.

Octave is free software: you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.

Octave 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 General Public License for more details.

You should have received a copy of the GNU General Public License
along with Octave; see the file COPYING.  If not, see
<https://www.gnu.org/licenses/>.

*/

#if defined (HAVE_CONFIG_H)
#  include "config.h"
#endif

#include "errwarn.h"
#include "ovl.h"
#include "ov.h"
#include "ov-typeinfo.h"
#include "ov-re-mat.h"
#include "ov-cx-mat.h"
#include "ops.h"
#include "xdiv.h"

#include "sparse-xpow.h"
#include "sparse-xdiv.h"
#include "smx-scm-m.h"
#include "smx-m-scm.h"
#include "ov-cx-sparse.h"

// sparse complex matrix by matrix ops.

DEFBINOP_OP (add, sparse_complex_matrix, matrix, +)
DEFBINOP_OP (sub, sparse_complex_matrix, matrix, -)

DEFBINOP_OP (mul, sparse_complex_matrix, matrix, *)

DEFBINOP (div, sparse_complex_matrix, matrix)
{
  const octave_sparse_complex_matrix& v1
    = dynamic_cast<const octave_sparse_complex_matrix&> (a1);
  const octave_matrix& v2 = dynamic_cast<const octave_matrix&> (a2);
  MatrixType typ = v2.matrix_type ();

  ComplexMatrix ret = xdiv (v1.complex_matrix_value (),
                            v2.matrix_value (), typ);

  v2.matrix_type (typ);
  return ret;
}

DEFBINOPX (pow, sparse_complex_matrix, matrix)
{
  error ("can't do A ^ B for A and B both matrices");
}

DEFBINOP (ldiv, sparse_complex_matrix, matrix)
{
  const octave_sparse_complex_matrix& v1
    = dynamic_cast<const octave_sparse_complex_matrix&> (a1);
  const octave_matrix& v2 = dynamic_cast<const octave_matrix&> (a2);

  if (v1.rows () == 1 && v1.columns () == 1)
    {
      Complex d = v1.complex_value ();

      if (d == 0.0)
        warn_divide_by_zero ();

      return octave_value (v2.array_value () / d);
    }
  else
    {
      MatrixType typ = v1.matrix_type ();

      ComplexMatrix ret = xleftdiv (v1.sparse_complex_matrix_value (),
                                    v2.matrix_value (), typ);

      v1.matrix_type (typ);
      return ret;
    }
}

DEFBINOP_FN (lt, sparse_complex_matrix, matrix, mx_el_lt)
DEFBINOP_FN (le, sparse_complex_matrix, matrix, mx_el_le)
DEFBINOP_FN (eq, sparse_complex_matrix, matrix, mx_el_eq)
DEFBINOP_FN (ge, sparse_complex_matrix, matrix, mx_el_ge)
DEFBINOP_FN (gt, sparse_complex_matrix, matrix, mx_el_gt)
DEFBINOP_FN (ne, sparse_complex_matrix, matrix, mx_el_ne)

DEFBINOP_FN (el_mul, sparse_complex_matrix, matrix, product)
DEFBINOP_FN (el_div, sparse_complex_matrix, matrix, quotient)

DEFBINOP (el_pow, sparse_complex_matrix, matrix)
{
  const octave_sparse_complex_matrix& v1
    = dynamic_cast<const octave_sparse_complex_matrix&> (a1);
  const octave_matrix& v2 = dynamic_cast<const octave_matrix&> (a2);

  return octave_value
         (elem_xpow (v1.sparse_complex_matrix_value (), SparseMatrix
                     (v2.matrix_value ())));
}

DEFBINOP (el_ldiv, sparse_complex_matrix, matrix)
{
  const octave_sparse_complex_matrix& v1
    = dynamic_cast<const octave_sparse_complex_matrix&> (a1);
  const octave_matrix& v2 = dynamic_cast<const octave_matrix&> (a2);

  return octave_value
         (quotient (v2.matrix_value (), v1.sparse_complex_matrix_value ()));
}

DEFBINOP_FN (el_and, sparse_complex_matrix, matrix, mx_el_and)
DEFBINOP_FN (el_or,  sparse_complex_matrix, matrix, mx_el_or)

DEFCATOP (scm_m, sparse_complex_matrix, matrix)
{
  octave_sparse_complex_matrix& v1
    = dynamic_cast<octave_sparse_complex_matrix&> (a1);
  const octave_matrix& v2 = dynamic_cast<const octave_matrix&> (a2);
  SparseMatrix tmp (v2.matrix_value ());
  return octave_value
         (v1.sparse_complex_matrix_value ().concat (tmp, ra_idx));
}

DEFASSIGNOP (assign, sparse_complex_matrix, matrix)
{
  octave_sparse_complex_matrix& v1
    = dynamic_cast<octave_sparse_complex_matrix&> (a1);
  const octave_matrix& v2 = dynamic_cast<const octave_matrix&> (a2);

  SparseComplexMatrix tmp (v2.complex_matrix_value ());
  v1.assign (idx, tmp);
  return octave_value ();
}

void
install_scm_m_ops (octave::type_info& ti)
{
  INSTALL_BINOP_TI (ti, op_add, octave_sparse_complex_matrix, octave_matrix, add);
  INSTALL_BINOP_TI (ti, op_sub, octave_sparse_complex_matrix, octave_matrix, sub);
  INSTALL_BINOP_TI (ti, op_mul, octave_sparse_complex_matrix, octave_matrix, mul);
  INSTALL_BINOP_TI (ti, op_div, octave_sparse_complex_matrix, octave_matrix, div);
  INSTALL_BINOP_TI (ti, op_pow, octave_sparse_complex_matrix, octave_matrix, pow);
  INSTALL_BINOP_TI (ti, op_ldiv, octave_sparse_complex_matrix, octave_matrix,
                    ldiv);
  INSTALL_BINOP_TI (ti, op_lt, octave_sparse_complex_matrix, octave_matrix, lt);
  INSTALL_BINOP_TI (ti, op_le, octave_sparse_complex_matrix, octave_matrix, le);
  INSTALL_BINOP_TI (ti, op_eq, octave_sparse_complex_matrix, octave_matrix, eq);
  INSTALL_BINOP_TI (ti, op_ge, octave_sparse_complex_matrix, octave_matrix, ge);
  INSTALL_BINOP_TI (ti, op_gt, octave_sparse_complex_matrix, octave_matrix, gt);
  INSTALL_BINOP_TI (ti, op_ne, octave_sparse_complex_matrix, octave_matrix, ne);
  INSTALL_BINOP_TI (ti, op_el_mul, octave_sparse_complex_matrix, octave_matrix,
                    el_mul);
  INSTALL_BINOP_TI (ti, op_el_div, octave_sparse_complex_matrix, octave_matrix,
                    el_div);
  INSTALL_BINOP_TI (ti, op_el_pow, octave_sparse_complex_matrix, octave_matrix,
                    el_pow);
  INSTALL_BINOP_TI (ti, op_el_ldiv, octave_sparse_complex_matrix, octave_matrix,
                    el_ldiv);
  INSTALL_BINOP_TI (ti, op_el_and, octave_sparse_complex_matrix, octave_matrix,
                    el_and);
  INSTALL_BINOP_TI (ti, op_el_or, octave_sparse_complex_matrix, octave_matrix,
                    el_or);

  INSTALL_CATOP_TI (ti, octave_sparse_complex_matrix, octave_matrix, scm_m);

  INSTALL_ASSIGNOP_TI (ti, op_asn_eq, octave_sparse_complex_matrix, octave_matrix,
                       assign);
}