Mercurial > hg > octave-nkf

view scripts/plot/patch.m @ 17136:e4968b4613a5

Find changesets by keywords (author, files, the commit message), revision number or hash, or revset expression.
Overhaul default menubar (still not perfect). * scripts/plot/figure.m: Always call __add_default_menu__. * scripts/plot/private/__add_default_menu__.m: Check that toolkit is FLTK before proceeding. Don't do redundant check that input is figure handle. Don't turn off handlevisibility for submenus, they are already hidden from above. Restrict findall() search to a depth of 1. Add __default_menu__ tags to Edit and Help menus so they can be identified. Don't call drawnow unnecessarily in callback routines. Use gcbf() so that Save filename is stored on a per figure basis rather than globally. Eliminate assigning to unused variables. Add HACK to turn off menubar if property is set to "none" on figure.
author Rik <rik@octave.org>
date Thu, 01 Aug 2013 10:18:54 -0700
parents eaab03308c0b
children df4c4b7708a4
line wrap: on
line source

## Copyright (C) 2005-2012 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/>.

## -*- texinfo -*-
## @deftypefn  {Function File} {} patch ()
## @deftypefnx {Function File} {} patch (@var{x}, @var{y}, @var{c})
## @deftypefnx {Function File} {} patch (@var{x}, @var{y}, @var{z}, @var{c})
## @deftypefnx {Function File} {} patch (@var{fv})
## @deftypefnx {Function File} {} patch ("Faces", @var{faces}, "Vertices", @var{verts}, @dots{})
## @deftypefnx {Function File} {} patch (@dots{}, @var{prop}, @var{val}, @dots{})
## @deftypefnx {Function File} {} patch (@var{hax}, @dots{})
## @deftypefnx {Function File} {@var{h} =} patch (@dots{})
## Create patch object in the current axes with vertices at locations
## (@var{x}, @var{y}) and of color @var{c}.
##
## If the vertices are matrices of size @nospell{MxN} then each polygon patch
## has M vertices and a total of N polygons will be created.  If some polygons
## do not have M vertices use NaN to represent "no vertex".  If the @var{z}
## input is present then 3-D patches will be created.
##
## The color argument @var{c} can take many forms.  To create polygons
## which all share a single color use a string value (e.g., "r" for
## red), a scalar value which is scaled by @code{caxis} and indexed into the
## current colormap, or a 3-element RGB vector with the precise TrueColor.
##
## If @var{c} is a vector of length N then the ith polygon will have a color
## determined by scaling entry @var{c}(i) according to @code{caxis} and then
## indexing into the current colormap.  More complicated coloring situations
## require directly manipulating patch property/value pairs.
##
## Instead of specifying polygons by matrices @var{x} and @var{y}, it is
## possible to present a unique list of vertices and then a list of polygon
## faces created from those vertices.  In this case the "Vertices" matrix will
## be an @nospell{Nx2} (2-D patch) or @nospell{Nx3} (3-D path).  The
## @nospell{MxN} "Faces" matrix describes M polygons having N vertices---each
## row describes a single polygon and each column entry is an index into the
## "Vertices" matrix to identify a vertex.  The patch object can be created by
## directly passing the property/value pairs "Vertices"/@var{verts},
## "Faces"/@var{faces} as inputs.
##
## A third input form is to create a structure @var{fv} with the fields
## "vertices", "faces", and optionally "facevertexcdata".
##
## If the first argument @var{hax} is an axes handle, then plot into this axis,
## rather than the current axes returned by @code{gca}.
##
## The optional return value @var{h} is a graphics handle to the created patch
## object.
##
## Implementation Note: Patches are highly configurable objects.  To truly
## customize them requires setting patch properties directly.  Useful patch
## properties are: "cdata", "edgecolor", "facecolor", "faces",
## "facevertexcdata",
##
## @seealso{fill, get, set}
## @end deftypefn

## Author: jwe

function h = patch (varargin)

  [hax, varargin] = __plt_get_axis_arg__ ("patch", varargin{:});
  
  if (isempty (hax))
    hax = gca ();
  endif
  
  [htmp, failed] = __patch__ (hax, varargin{:});

  if (failed)
    print_usage ();
  endif

  if (nargout > 0)
    h = htmp;
  endif

endfunction


%!demo
%! %% Patches with same number of vertices
%! clf;
%! t1 = (1/16:1/8:1)' * 2*pi;
%! t2 = ((1/16:1/8:1)' + 1/32) * 2*pi;
%! x1 = sin (t1) - 0.8;
%! y1 = cos (t1);
%! x2 = sin (t2) + 0.8;
%! y2 = cos (t2);
%! patch ([x1,x2], [y1,y2], 'r');

%!demo
%! %% Unclosed patch
%! clf;
%! t1 = (1/16:1/8:1)' * 2*pi;
%! t2 = ((1/16:1/16:1)' + 1/32) * 2*pi;
%! x1 = sin (t1) - 0.8;
%! y1 = cos (t1);
%! x2 = sin (t2) + 0.8;
%! y2 = cos (t2);
%! patch ([[x1;NaN(8,1)],x2], [[y1;NaN(8,1)],y2], 'r');

%!demo
%! %% Specify vertices and faces separately
%! clf;
%! t1 = (1/16:1/8:1)' * 2*pi;
%! t2 = ((1/16:1/16:1)' + 1/32) * 2*pi;
%! x1 = sin (t1) - 0.8;
%! y1 = cos (t1);
%! x2 = sin (t2) + 0.8;
%! y2 = cos (t2);
%! vert = [x1, y1; x2, y2];
%! fac = [1:8,NaN(1,8);9:24];
%! patch ('Faces',fac, 'Vertices',vert, 'FaceColor','r');

%!demo
%! %% Specify vertices and faces separately
%! clf;
%! t1 = (1/16:1/8:1)' * 2*pi;
%! t2 = ((1/16:1/16:1)' + 1/32) * 2*pi;
%! x1 = sin (t1) - 0.8;
%! y1 = cos (t1);
%! x2 = sin (t2) + 0.8;
%! y2 = cos (t2);
%! vert = [x1, y1; x2, y2];
%! fac = [1:8,NaN(1,8);9:24];
%! patch ('Faces',fac, 'Vertices',vert, 'FaceVertexCData',[0, 1, 0; 0, 0, 1]);

%!demo
%! %% Property change on multiple patches
%! clf;
%! t1 = (1/16:1/8:1)' * 2*pi;
%! t2 = ((1/16:1/8:1)' + 1/32) * 2*pi;
%! x1 = sin (t1) - 0.8;
%! y1 = cos (t1);
%! x2 = sin (t2) + 0.8;
%! y2 = cos (t2);
%! h = patch ([x1,x2], [y1,y2], cat (3, [0,0],[1,0],[0,1]));
%! pause (1);
%! set (h, 'FaceColor', 'r');

%!demo
%! clf;
%! vertices = [0, 0, 0;
%!             1, 0, 0;
%!             1, 1, 0;
%!             0, 1, 0;
%!             0.5, 0.5, 1];
%! faces = [1, 2, 5;
%!          2, 3, 5;
%!          3, 4, 5;
%!          4, 1, 5];
%! patch ('Vertices', vertices, 'Faces', faces, ...
%!        'FaceVertexCData', jet (4), 'FaceColor', 'flat');
%! view (-37.5, 30);

%!demo
%! clf;
%! vertices = [0, 0, 0;
%!             1, 0, 0;
%!             1, 1, 0;
%!             0, 1, 0;
%!             0.5, 0.5, 1];
%! faces = [1, 2, 5;
%!          2, 3, 5;
%!          3, 4, 5;
%!          4, 1, 5];
%! patch  ('Vertices', vertices, 'Faces', faces, ...
%!        'FaceVertexCData', jet (5), 'FaceColor', 'interp');
%! view (-37.5, 30);

%!demo
%! clf;
%! colormap (jet (64));
%! x = [0 1 1 0];
%! y = [0 0 1 1];
%! subplot (2,1,1);
%!  title ('Blue, Light-Green, and Red Horizontal Bars');
%!  patch (x, y + 0, 1);
%!  patch (x, y + 1, 2);
%!  patch (x, y + 2, 3);
%! subplot (2,1,2);
%!  title ('Blue, Light-Green, and Red Vertical Bars');
%!  patch (x + 0, y, 1 * ones (size (x)));
%!  patch (x + 1, y, 2 * ones (size (x)));
%!  patch (x + 2, y, 3 * ones (size (x)));

%!demo
%! clf;
%! colormap (jet (64));
%! x = [0 1 1 0];
%! y = [0 0 1 1];
%! subplot (2,1,1);
%!  title ('Blue horizontal bars: Dark to Light');
%!  patch (x, y + 0, 1, 'cdatamapping', 'direct');
%!  patch (x, y + 1, 9, 'cdatamapping', 'direct');
%!  patch (x, y + 2, 17, 'cdatamapping', 'direct');
%! subplot (2,1,2);
%!  title ('Blue vertical bars: Dark to Light');
%!  patch (x + 0, y, 1 * ones (size (x)), 'cdatamapping', 'direct');
%!  patch (x + 1, y, 9 * ones (size (x)), 'cdatamapping', 'direct');
%!  patch (x + 2, y, 17 * ones (size (x)), 'cdatamapping', 'direct');

%!demo
%! clf;
%! colormap (jet (64));
%! x = [ 0 0; 1 1; 1 0 ];
%! y = [ 0 0; 0 1; 1 1 ];
%! p = patch (x, y, 'facecolor', 'b');
%! title ('Two blue triangles');
%! set (p, 'cdatamapping', 'direct', 'facecolor', 'flat', 'cdata', [1 32]);
%! title ('Direct mapping of colors: Light-Green UL and Blue LR triangles');

%!demo
%! clf;
%! colormap (jet (64));
%! x = [ 0 0; 1 1; 1 0 ];
%! y = [ 0 0; 0 1; 1 1 ];
%! p = patch (x, y, [1 32]);
%! title ('Autoscaling of colors: Red UL and Blue LR triangles');

%!test
%! hf = figure ("visible", "off");
%! unwind_protect
%!   h = patch ();
%!   assert (findobj (hf, "type", "patch"), h);
%!   assert (get (h, "xdata"), [0; 1; 0], eps);
%!   assert (get (h, "ydata"), [1; 1; 0], eps);
%!   assert (isempty (get (h, "zdata")));
%!   assert (isempty (get (h, "cdata")));
%!   assert (get (h, "faces"), [1, 2, 3], eps);
%!   assert (get (h, "vertices"), [0 1; 1 1; 0 0], eps);
%!   assert (get (h, "type"), "patch");
%!   assert (get (h, "facecolor"), [0 0 0]);
%!   assert (get (h, "linestyle"), get (0, "defaultpatchlinestyle"));
%!   assert (get (h, "linewidth"), get (0, "defaultpatchlinewidth"), eps);
%!   assert (get (h, "marker"), get (0, "defaultpatchmarker"));
%!   assert (get (h, "markersize"), get (0, "defaultpatchmarkersize"));
%! unwind_protect_cleanup
%!   close (hf);
%! end_unwind_protect

%!test
%! hf = figure ("visible", "off");
%! c = 0.9;
%! unwind_protect
%!   h = patch ([0 1 0], [0 1 1], c);
%!   assert (get (gca, "clim"), [c - 1, c + 1]);
%!   h = patch ([0 1 0], [0 1 1], 2 * c);
%!   assert (get (gca, "clim"), [c, 2 * c]);
%! unwind_protect_cleanup
%!   close (hf);
%! end_unwind_protect