Mercurial > hg > octave-lyh
view scripts/plot/trisurf.m @ 17182:c3c1ebfaa7dc
maint: Use common indentation for switch statement.
* scripts/general/interp1.m, scripts/geometry/delaunay.m,
scripts/help/__unimplemented__.m, scripts/image/cmunique.m,
scripts/miscellaneous/edit.m, scripts/optimization/fzero.m,
scripts/optimization/sqp.m, scripts/plot/__gnuplot_drawnow__.m,
scripts/plot/hidden.m, scripts/plot/legend.m, scripts/plot/print.m,
scripts/plot/printd.m, scripts/plot/private/__contour__.m,
scripts/plot/private/__fltk_print__.m,
scripts/plot/private/__gnuplot_print__.m,
scripts/plot/private/__go_draw_axes__.m,
scripts/plot/private/__print_parse_opts__.m, scripts/signal/periodogram.m,
scripts/sparse/bicg.m, test/slice.tst, test/switch.tst:
Use common indentation for switch statement.
| author | Rik <rik@octave.org> |
|---|---|
| date | Sun, 04 Aug 2013 15:11:34 -0700 |
| parents | 26589abbc78d |
| children | 0fa126e9944e |
line wrap: on
line source
## Copyright (C) 2007-2012 David Bateman ## ## 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} {} trisurf (@var{tri}, @var{x}, @var{y}, @var{z}, @var{c}) ## @deftypefnx {Function File} {} trisurf (@var{tri}, @var{x}, @var{y}, @var{z}) ## @deftypefnx {Function File} {} trisurf (@dots{}, @var{prop}, @var{val}, @dots{}) ## @deftypefnx {Function File} {@var{h} =} trisurf (@dots{}) ## Plot a 3-D triangular surface. ## ## In contrast to @code{surf}, which plots a surface mesh using rectangles, ## @code{trisurf} plots the mesh using triangles. ## ## @var{tri} is typically the output of a Delaunay triangulation over the ## grid of @var{x}, @var{y}. Every row of @var{tri} represents one triangle ## and contains three indices into [@var{x}, @var{y}] which are the ## vertices of the triangles in the x-y plane. @var{z} determines the ## height above the plane of each vertex. ## ## The color of the trimesh is computed by linearly scaling the @var{z} values ## to fit the range of the current colormap. Use @code{caxis} and/or ## change the colormap to control the appearance. ## ## Optionally, the color of the mesh can be specified independently of @var{z} ## by supplying a color matrix, @var{c}. ## ## Any property/value pairs are passed directly to the underlying patch object. ## ## The optional return value @var{h} is a graphics handle to the created patch ## object. ## @seealso{surf, triplot, trimesh, delaunay, patch, shading} ## @end deftypefn function h = trisurf (tri, x, y, z, varargin) if (nargin < 3) print_usage (); endif if (nargin == 3) triplot (tri, x, y); elseif (ischar (z)) triplot (tri, x, y, z, varargin{:}); else if (nargin > 4 && isnumeric (varargin{1})) c = varargin{1}; varargin(1) = []; else c = z; endif if (! any (strcmpi (varargin, "FaceColor"))) nfc = numel (varargin) + 1; varargin(nfc+(0:1)) = {"FaceColor", "flat"}; else nfc = find (any (strcmpi (varargin, "FaceColor")), 1); endif if (! any (strcmpi (varargin, "EdgeColor")) && strcmpi (varargin{nfc+1}, "interp")) varargin(end+(1:2)) = {"EdgeColor", "none"}; endif hax = newplot (); htmp = patch ("Faces", tri, "Vertices", [x(:), y(:), z(:)], "FaceVertexCData", reshape (c, numel (c), 1), varargin{:}); if (nargout > 0) h = htmp; endif if (! ishold ()) set (hax, "view", [-37.5, 30], "xgrid", "on", "ygrid", "on", "zgrid", "on"); endif endif endfunction %!demo %! clf; %! colormap ('default'); %! N = 31; %! [x, y] = meshgrid (1:N); %! tri = delaunay (x(:), y(:)); %! z = peaks (N); %! h = trisurf (tri, x, y, z, 'facecolor', 'interp'); %! axis tight; %! zlim auto; %! title (sprintf ('facecolor = %s', get (h, 'facecolor'))); %!demo %! clf; %! colormap ('default'); %! N = 31; %! [x, y] = meshgrid (1:N); %! tri = delaunay (x(:), y(:)); %! z = peaks (N); %! h = trisurf (tri, x, y, z, 'facecolor', 'flat'); %! axis tight; %! zlim auto; %! title (sprintf ('facecolor = %s', get (h, 'facecolor'))); %!demo %! clf; %! colormap ('default'); %! old_state = rand ('state'); %! restore_state = onCleanup (@() rand ('state', old_state)); %! rand ('state', 10); %! N = 10; %! x = 3 - 6 * rand (N, N); %! y = 3 - 6 * rand (N, N); %! z = peaks (x, y); %! tri = delaunay (x(:), y(:)); %! trisurf (tri, x(:), y(:), z(:)); %!demo %! clf; %! colormap ('default'); %! x = rand (100, 1); %! y = rand (100, 1); %! z = x.^2 + y.^2; %! tri = delaunay (x, y); %! trisurf (tri, x, y, z); %!demo %! clf; %! colormap ('default'); %! x = rand (100, 1); %! y = rand (100, 1); %! z = x.^2 + y.^2; %! tri = delaunay (x, y); %! trisurf (tri, x, y, z, 'facecolor', 'interp'); %!demo %! clf; %! colormap ('default'); %! x = rand (100, 1); %! y = rand (100, 1); %! z = x.^2 + y.^2; %! tri = delaunay (x, y); %! trisurf (tri, x, y, z, 'facecolor', 'interp', 'edgecolor', 'k');