Mercurial > octave

view scripts/plot/draw/surface.m @ 30564:796f54d4ddbf stable

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
update Octave Project Developers copyright for the new year In files that have the "Octave Project Developers" copyright notice, update for 2021. In all .txi and .texi files except gpl.txi and gpl.texi in the doc/liboctave and doc/interpreter directories, change the copyright to "Octave Project Developers", the same as used for other source files. Update copyright notices for 2022 (not done since 2019). For gpl.txi and gpl.texi, change the copyright notice to be "Free Software Foundation, Inc." and leave the date at 2007 only because this file only contains the text of the GPL, not anything created by the Octave Project Developers. Add Paul Thomas to contributors.in.
author John W. Eaton <jwe@octave.org>
date Tue, 28 Dec 2021 18:22:40 -0500
parents 7854d5752dd2
children 597f3ee61a48
line wrap: on
line source

########################################################################
##
## Copyright (C) 1993-2022 The Octave Project Developers
##
## See the file COPYRIGHT.md in the top-level directory of this
## distribution or <https://octave.org/copyright/>.
##
## 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/>.
##
########################################################################

## -*- texinfo -*-
## @deftypefn  {} {} surface (@var{x}, @var{y}, @var{z}, @var{c})
## @deftypefnx {} {} surface (@var{x}, @var{y}, @var{z})
## @deftypefnx {} {} surface (@var{z}, @var{c})
## @deftypefnx {} {} surface (@var{z})
## @deftypefnx {} {} surface (@dots{}, @var{prop}, @var{val}, @dots{})
## @deftypefnx {} {} surface (@var{hax}, @dots{})
## @deftypefnx {} {@var{h} =} surface (@dots{})
## Create a surface graphic object given matrices @var{x} and @var{y} from
## @code{meshgrid} and a matrix of values @var{z} corresponding to the
## @var{x} and @var{y} coordinates of the surface.
##
## If @var{x} and @var{y} are vectors, then a typical vertex is
## (@var{x}(j), @var{y}(i), @var{z}(i,j)).  Thus, columns of @var{z} correspond
## to different @var{x} values and rows of @var{z} correspond to different
## @var{y} values.  If only a single input @var{z} is given then @var{x} is
## taken to be @code{1:columns (@var{z})} and @var{y} is
## @code{1:rows (@var{z})}.
##
## Any property/value input pairs are assigned to the surface object.
##
## If the first argument @var{hax} is an axes handle, then plot into this axes,
## rather than the current axes returned by @code{gca}.
##
## The optional return value @var{h} is a graphics handle to the created
## surface object.
##
## Programming Note: The full list of properties is documented at
## @ref{Surface Properties}.
## @seealso{surf, mesh, patch, line}
## @end deftypefn

function h = surface (varargin)

  [hax, varargin] = __plt_get_axis_arg__ ("surface", varargin{:});

  if (isempty (hax))
    hax = gca ();
  else
    hax = hax(1);
  endif

  [htmp, bad_usage] = __surface__ (hax, varargin{:});

  if (bad_usage)
    print_usage ();
  endif

  if (nargout > 0)
    h = htmp;
  endif

endfunction

function [h, bad_usage] = __surface__ (ax, varargin)

  h = 0;
  bad_usage = false;
  firststring = find (cellfun ("isclass", varargin, "char"), 1);
  if (isempty (firststring))
    firststring = nargin;
  endif

  switch (firststring)
    case 5
      x = varargin{1};
      y = varargin{2};
      z = varargin{3};
      c = varargin{4};

      if (iscomplex (x) || iscomplex (y) || iscomplex (z) || iscomplex (c))
        error ("mesh: X, Y, Z, C arguments must be real");
      endif

      [z_nr, z_nc] = size (z);
      [c_nr, c_nc, c_np] = size (c);
      if (! (z_nr == c_nr && z_nc == c_nc && (c_np == 1 || c_np == 3)))
        error ("surface: Z and C must have the same size");
      endif

      if (isvector (x) && isvector (y) && ismatrix (z))
        if (rows (z) == length (y) && columns (z) == length (x))
          x = x(:)';
          y = y(:);
        else
          error ("surface: rows (Z) must be the same as length (Y) and columns (Z) must be the same as length (X)");
        endif
      elseif (ismatrix (x) && ismatrix (y) && ismatrix (z))
        if (! size_equal (x, y, z))
          error ("surface: X, Y, and Z must have the same dimensions");
        endif
      else
        error ("surface: X and Y must be vectors and Z must be a matrix");
      endif

    case 4
      x = varargin{1};
      y = varargin{2};
      z = varargin{3};
      c = z;

      if (iscomplex (x) || iscomplex (y) || iscomplex (z))
        error ("mesh: X, Y, Z arguments must be real");
      endif

      if (isvector (x) && isvector (y) && ismatrix (z))
        if (rows (z) == length (y) && columns (z) == length (x))
          x = x(:)';
          y = y(:);
        else
          error ("surface: rows (Z) must be the same as length (Y) and columns (Z) must be the same as length (X)");
        endif
      elseif (ismatrix (x) && ismatrix (y) && ismatrix (z))
        if (! size_equal (x, y, z))
          error ("surface: X, Y, and Z must have the same dimensions");
        endif
      else
        error ("surface: X and Y must be vectors and Z must be a matrix");
      endif

    case 3
      z = varargin{1};
      c = varargin{2};

      if (iscomplex (z) || iscomplex (c))
        error ("mesh: X, C arguments must be real");
      endif

      if (ismatrix (z) && ! isvector (z) && ! isscalar (z))
        [nr, nc] = size (z);
        x = 1:nc;
        y = (1:nr)';
      else
        error ("surface: Z argument must be a matrix");
      endif

    case 2
      z = varargin{1};
      c = z;

      if (iscomplex (z))
        error ("mesh: Z argument must be real");
      endif

      if (ismatrix (z) && ! isvector (z) && ! isscalar (z))
        [nr, nc] = size (z);
        x = 1:nc;
        y = (1:nr)';
      else
        error ("surface: Z argument must be a matrix");
      endif

    case 1
      x = 1:3;
      y = x';
      c = z = eye (3);

    otherwise
      bad_usage = true;
      return;

  endswitch

  if (firststring < nargin)
    other_args = varargin(firststring:end);
  else
    other_args = {};  # make a default surface object.
  endif
  h = __go_surface__ (ax, "xdata", x, "ydata", y, "zdata", z, "cdata", c,
                      other_args{:});

  ## FIXME: ishold called this way is very slow.
  if (! ishold (ax))
    set (ax, "view", [0, 90]);
  endif

endfunction


## Functional tests for surface() are in surf.m, surfc.m, surfl.m, and pcolor.m
%!test
%! hf = figure ("visible", "off");
%! unwind_protect
%!   h = surface ();
%!   assert (findobj (hf, "type", "surface"), h);
%!   assert (get (h, "xdata"), 1:3, eps);
%!   assert (get (h, "ydata"), (1:3)', eps);
%!   assert (get (h, "zdata"), eye (3));
%!   assert (get (h, "cdata"), eye (3));
%!   assert (get (h, "type"), "surface");
%!   assert (get (h, "linestyle"), get (0, "defaultsurfacelinestyle"));
%!   assert (get (h, "linewidth"), get (0, "defaultsurfacelinewidth"), eps);
%!   assert (get (h, "marker"), get (0, "defaultsurfacemarker"));
%!   assert (get (h, "markersize"), get (0, "defaultsurfacemarkersize"));
%! unwind_protect_cleanup
%!   close (hf);
%! end_unwind_protect