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view libinterp/corefcn/kron.cc @ 18961:52e01aa1fe8b

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Overhaul FLTK pan, rotate, zoom * graphics.in.h: add axes properties pan, rotate3d, mouse_wheel_zoom and custom set_pan which disables rotate3d. * graphics.cc: add custom set_rotate3d and link with pan property. Disable rotate3d for 2D plots. * __init_fltk__.cc: replace gui_mode and mouse_wheel_zoom with axes properties pan, rotate3d and mouse_wheel_zoom. Disable pan for legends, move them instead. * __add_default_menu__.m: Add new menu entries for new pan and zoom modes. * findall.m: Update test for added uimenus. Each axes now has its own properties for interactive GUI control of pan, rotate3d and mouse_wheel_zoom. Now it's possible to have several figures and set pan for the 2D plot in figure x and rotate3d for the 3D plot in figure y. There are two new pan modes: "Pan x only" and "Pan y only". The toolbar buttons "P" and "R" set pan and rotate3d for the last clicked axes object or the object below the center of the canvas if none was clicked yet. The legend can now be moved with the mouse.
author Andreas Weber <andy.weber.aw@gmail.com>
date Sun, 27 Jul 2014 22:31:14 +0200
parents aa9ca67f09fb
children
line wrap: on
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/*

Copyright (C) 2002-2013 John W. Eaton

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
<http://www.gnu.org/licenses/>.

*/

// Author: Paul Kienzle <pkienzle@users.sf.net>

#ifdef HAVE_CONFIG_H
#include <config.h>
#endif

#include "dMatrix.h"
#include "fMatrix.h"
#include "CMatrix.h"
#include "fCMatrix.h"

#include "dSparse.h"
#include "CSparse.h"

#include "dDiagMatrix.h"
#include "fDiagMatrix.h"
#include "CDiagMatrix.h"
#include "fCDiagMatrix.h"

#include "PermMatrix.h"

#include "mx-inlines.cc"
#include "quit.h"

#include "defun.h"
#include "error.h"
#include "oct-obj.h"

template <class R, class T>
static MArray<T>
kron (const MArray<R>& a, const MArray<T>& b)
{
  assert (a.ndims () == 2);
  assert (b.ndims () == 2);

  octave_idx_type nra = a.rows ();
  octave_idx_type nrb = b.rows ();
  octave_idx_type nca = a.cols ();
  octave_idx_type ncb = b.cols ();

  MArray<T> c (dim_vector (nra*nrb, nca*ncb));
  T *cv = c.fortran_vec ();

  for (octave_idx_type ja = 0; ja < nca; ja++)
    for (octave_idx_type jb = 0; jb < ncb; jb++)
      for (octave_idx_type ia = 0; ia < nra; ia++)
        {
          octave_quit ();
          mx_inline_mul (nrb, cv, a(ia, ja), b.data () + nrb*jb);
          cv += nrb;
        }

  return c;
}

template <class R, class T>
static MArray<T>
kron (const MDiagArray2<R>& a, const MArray<T>& b)
{
  assert (b.ndims () == 2);

  octave_idx_type nra = a.rows ();
  octave_idx_type nrb = b.rows ();
  octave_idx_type dla = a.diag_length ();
  octave_idx_type nca = a.cols ();
  octave_idx_type ncb = b.cols ();

  MArray<T> c (dim_vector (nra*nrb, nca*ncb), T ());

  for (octave_idx_type ja = 0; ja < dla; ja++)
    for (octave_idx_type jb = 0; jb < ncb; jb++)
      {
        octave_quit ();
        mx_inline_mul (nrb, &c.xelem (ja*nrb, ja*ncb + jb), a.dgelem (ja),
                       b.data () + nrb*jb);
      }

  return c;
}

template <class T>
static MSparse<T>
kron (const MSparse<T>& A, const MSparse<T>& B)
{
  octave_idx_type idx = 0;
  MSparse<T> C (A.rows () * B.rows (), A.columns () * B.columns (),
                A.nnz () * B.nnz ());

  C.cidx (0) = 0;

  for (octave_idx_type Aj = 0; Aj < A.columns (); Aj++)
    for (octave_idx_type Bj = 0; Bj < B.columns (); Bj++)
      {
        octave_quit ();
        for (octave_idx_type Ai = A.cidx (Aj); Ai < A.cidx (Aj+1); Ai++)
          {
            octave_idx_type Ci = A.ridx (Ai) * B.rows ();
            const T v = A.data (Ai);

            for (octave_idx_type Bi = B.cidx (Bj); Bi < B.cidx (Bj+1); Bi++)
              {
                C.data (idx) = v * B.data (Bi);
                C.ridx (idx++) = Ci + B.ridx (Bi);
              }
          }
        C.cidx (Aj * B.columns () + Bj + 1) = idx;
      }

  return C;
}

static PermMatrix
kron (const PermMatrix& a, const PermMatrix& b)
{
  octave_idx_type na = a.rows ();
  octave_idx_type nb = b.rows ();
  const Array<octave_idx_type>& pa = a.col_perm_vec ();
  const Array<octave_idx_type>& pb = b.col_perm_vec ();
  Array<octave_idx_type> res_perm;
  octave_idx_type rescol = 0;
  for (octave_idx_type i = 0; i < na; i++)
    {
      octave_idx_type a_add = pa(i) * nb;
      for (octave_idx_type j = 0; j < nb; j++)
        res_perm.xelem (rescol++) = a_add + pb(j);
    }

  return PermMatrix (res_perm, true);
}

template <class MTA, class MTB>
octave_value
do_kron (const octave_value& a, const octave_value& b)
{
  MTA am = octave_value_extract<MTA> (a);
  MTB bm = octave_value_extract<MTB> (b);
  return octave_value (kron (am, bm));
}

octave_value
dispatch_kron (const octave_value& a, const octave_value& b)
{
  octave_value retval;
  if (a.is_perm_matrix () && b.is_perm_matrix ())
    retval = do_kron<PermMatrix, PermMatrix> (a, b);
  else if (a.is_sparse_type () || b.is_sparse_type ())
    {
      if (a.is_complex_type () || b.is_complex_type ())
        retval = do_kron<SparseComplexMatrix, SparseComplexMatrix> (a, b);
      else
        retval = do_kron<SparseMatrix, SparseMatrix> (a, b);
    }
  else if (a.is_diag_matrix ())
    {
      if (b.is_diag_matrix () && a.rows () == a.columns ()
          && b.rows () == b.columns ())
        {
          // We have two diagonal matrices, the product of those will be
          // another diagonal matrix.  To do that efficiently, extract
          // the diagonals as vectors and compute the product.  That
          // will be another vector, which we then use to construct a
          // diagonal matrix object.  Note that this will fail if our
          // digaonal matrix object is modified to allow the nonzero
          // values to be stored off of the principal diagonal (i.e., if
          // diag ([1,2], 3) is modified to return a diagonal matrix
          // object instead of a full matrix object).

          octave_value tmp = dispatch_kron (a.diag (), b.diag ());
          retval = tmp.diag ();
        }
      else if (a.is_single_type () || b.is_single_type ())
        {
          if (a.is_complex_type ())
            retval = do_kron<FloatComplexDiagMatrix, FloatComplexMatrix> (a, b);
          else if (b.is_complex_type ())
            retval = do_kron<FloatDiagMatrix, FloatComplexMatrix> (a, b);
          else
            retval = do_kron<FloatDiagMatrix, FloatMatrix> (a, b);
        }
      else
        {
          if (a.is_complex_type ())
            retval = do_kron<ComplexDiagMatrix, ComplexMatrix> (a, b);
          else if (b.is_complex_type ())
            retval = do_kron<DiagMatrix, ComplexMatrix> (a, b);
          else
            retval = do_kron<DiagMatrix, Matrix> (a, b);
        }
    }
  else if (a.is_single_type () || b.is_single_type ())
    {
      if (a.is_complex_type ())
        retval = do_kron<FloatComplexMatrix, FloatComplexMatrix> (a, b);
      else if (b.is_complex_type ())
        retval = do_kron<FloatMatrix, FloatComplexMatrix> (a, b);
      else
        retval = do_kron<FloatMatrix, FloatMatrix> (a, b);
    }
  else
    {
      if (a.is_complex_type ())
        retval = do_kron<ComplexMatrix, ComplexMatrix> (a, b);
      else if (b.is_complex_type ())
        retval = do_kron<Matrix, ComplexMatrix> (a, b);
      else
        retval = do_kron<Matrix, Matrix> (a, b);
    }
  return retval;
}


DEFUN (kron, args, , "-*- texinfo -*-\n\
@deftypefn  {Built-in Function} {} kron (@var{A}, @var{B})\n\
@deftypefnx {Built-in Function} {} kron (@var{A1}, @var{A2}, @dots{})\n\
Form the Kronecker product of two or more matrices, defined block by \n\
block as\n\
\n\
@example\n\
x = [ a(i,j)*b ]\n\
@end example\n\
\n\
For example:\n\
\n\
@example\n\
@group\n\
kron (1:4, ones (3, 1))\n\
     @result{}  1  2  3  4\n\
         1  2  3  4\n\
         1  2  3  4\n\
@end group\n\
@end example\n\
\n\
If there are more than two input arguments @var{A1}, @var{A2}, @dots{}, \n\
@var{An} the Kronecker product is computed as\n\
\n\
@example\n\
kron (kron (@var{A1}, @var{A2}), @dots{}, @var{An})\n\
@end example\n\
\n\
@noindent\n\
Since the Kronecker product is associative, this is well-defined.\n\
@end deftypefn")
{
  octave_value retval;

  int nargin = args.length ();

  if (nargin >= 2)
    {
      octave_value a = args(0);
      octave_value b = args(1);
      retval = dispatch_kron (a, b);
      for (octave_idx_type i = 2; i < nargin; i++)
        retval = dispatch_kron (retval, args(i));
    }
  else
    print_usage ();

  return retval;
}


/*
%!test
%! x = ones (2);
%! assert (kron (x, x), ones (4));

%!shared x, y, z
%! x =  [1, 2];
%! y =  [-1, -2];
%! z =  [1,  2,  3,  4; 1,  2,  3,  4; 1,  2,  3,  4];
%!assert (kron (1:4, ones (3, 1)), z)
%!assert (kron (x, y, z), kron (kron (x, y), z))
%!assert (kron (x, y, z), kron (x, kron (y, z)))

%!assert (kron (diag ([1, 2]), diag ([3, 4])), diag ([3, 4, 6, 8]))

%% Test for two diag matrices.  See the comments above in
%% dispatch_kron for this case.
%%
%!test
%! expected = zeros (16, 16);
%! expected (1, 11) = 3;
%! expected (2, 12) = 4;
%! expected (5, 15) = 6;
%! expected (6, 16) = 8;
%! assert (kron (diag ([1, 2], 2), diag ([3, 4], 2)), expected)
*/