Mercurial > hg > octave-nkf
view scripts/plot/draw/plot.m @ 19016:87c3848cf3c0
Fix bug when hggroup used with primitive graphic object (bug #42532).
* image.m, text.m, line.m, patch.m: __plt_get_axis_arg__ will return axis and
hggroup when 'parent' property is used. Select the first returned object
which is the axes, rather than passing both axis and hggroup to further plot
subroutines.
| author | Rik <rik@octave.org> |
|---|---|
| date | Tue, 10 Jun 2014 14:03:09 -0700 |
| parents | d63878346099 |
| children | 446c46af4b42 |
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## Copyright (C) 1993-2013 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/>. ## -*- texinfo -*- ## @deftypefn {Function File} {} plot (@var{y}) ## @deftypefnx {Function File} {} plot (@var{x}, @var{y}) ## @deftypefnx {Function File} {} plot (@var{x}, @var{y}, @var{fmt}) ## @deftypefnx {Function File} {} plot (@dots{}, @var{property}, @var{value}, @dots{}) ## @deftypefnx {Function File} {} plot (@var{x1}, @var{y1}, @dots{}, @var{xn}, @var{yn}) ## @deftypefnx {Function File} {} plot (@var{hax}, @dots{}) ## @deftypefnx {Function File} {@var{h} =} plot (@dots{}) ## Produce 2-D plots. ## ## Many different combinations of arguments are possible. The simplest ## form is ## ## @example ## plot (@var{y}) ## @end example ## ## @noindent ## where the argument is taken as the set of @var{y} coordinates and the ## @var{x} coordinates are taken to be the range @code{1:numel (@var{y})}. ## ## If more than one argument is given, they are interpreted as ## ## @example ## plot (@var{y}, @var{property}, @var{value}, @dots{}) ## @end example ## ## @noindent ## or ## ## @example ## plot (@var{x}, @var{y}, @var{property}, @var{value}, @dots{}) ## @end example ## ## @noindent ## or ## ## @example ## plot (@var{x}, @var{y}, @var{fmt}, @dots{}) ## @end example ## ## @noindent ## and so on. Any number of argument sets may appear. The @var{x} and ## @var{y} values are interpreted as follows: ## ## @itemize @bullet ## @item ## If a single data argument is supplied, it is taken as the set of @var{y} ## coordinates and the @var{x} coordinates are taken to be the indices of ## the elements, starting with 1. ## ## @item ## If @var{x} and @var{y} are scalars, a single point is plotted. ## ## @item ## @code{squeeze()} is applied to arguments with more than two dimensions, ## but no more than two singleton dimensions. ## ## @item ## If both arguments are vectors, the elements of @var{y} are plotted versus ## the elements of @var{x}. ## ## @item ## If @var{x} is a vector and @var{y} is a matrix, then ## the columns (or rows) of @var{y} are plotted versus @var{x}. ## (using whichever combination matches, with columns tried first.) ## ## @item ## If the @var{x} is a matrix and @var{y} is a vector, ## @var{y} is plotted versus the columns (or rows) of @var{x}. ## (using whichever combination matches, with columns tried first.) ## ## @item ## If both arguments are matrices, the columns of @var{y} are plotted ## versus the columns of @var{x}. In this case, both matrices must have ## the same number of rows and columns and no attempt is made to transpose ## the arguments to make the number of rows match. ## @end itemize ## ## Multiple property-value pairs may be specified, but they must appear ## in pairs. These arguments are applied to the line objects drawn by ## @code{plot}. Useful properties to modify are @qcode{"linestyle"}, ## @qcode{"linewidth"}, @qcode{"color"}, @qcode{"marker"}, ## @qcode{"markersize"}, @qcode{"markeredgecolor"}, @qcode{"markerfacecolor"}. ## ## The @var{fmt} format argument can also be used to control the plot style. ## The format is composed of three parts: linestyle, markerstyle, color. ## When a markerstyle is specified, but no linestyle, only the markers are ## plotted. Similarly, if a linestyle is specified, but no markerstyle, then ## only lines are drawn. If both are specified then lines and markers will ## be plotted. If no @var{fmt} and no @var{property}/@var{value} pairs are ## given, then the default plot style is solid lines with no markers and the ## color determined by the @qcode{"colororder"} property of the current axes. ## ## Format arguments: ## ## @table @asis ## @item linestyle ## ## @multitable @columnfractions 0.06 0.94 ## @item @samp{-} @tab Use solid lines (default). ## @item @samp{--} @tab Use dashed lines. ## @item @samp{:} @tab Use dotted lines. ## @item @samp{-.} @tab Use dash-dotted lines. ## @end multitable ## ## @item markerstyle ## ## @multitable @columnfractions 0.06 0.94 ## @item @samp{+} @tab crosshair ## @item @samp{o} @tab circle ## @item @samp{*} @tab star ## @item @samp{.} @tab point ## @item @samp{x} @tab cross ## @item @samp{s} @tab square ## @item @samp{d} @tab diamond ## @item @samp{^} @tab upward-facing triangle ## @item @samp{v} @tab downward-facing triangle ## @item @samp{>} @tab right-facing triangle ## @item @samp{<} @tab left-facing triangle ## @item @samp{p} @tab pentagram ## @item @samp{h} @tab hexagram ## @end multitable ## ## @item color ## ## @multitable @columnfractions 0.06 0.94 ## @item @samp{k} @tab blacK ## @item @samp{r} @tab Red ## @item @samp{g} @tab Green ## @item @samp{b} @tab Blue ## @item @samp{m} @tab Magenta ## @item @samp{c} @tab Cyan ## @item @samp{w} @tab White ## @end multitable ## ## @item @qcode{";key;"} ## Here @qcode{"key"} is the label to use for the plot legend. ## @end table ## ## The @var{fmt} argument may also be used to assign legend keys. ## To do so, include the desired label between semicolons after the ## formatting sequence described above, e.g., @qcode{"+b;Key Title;"}. ## Note that the last semicolon is required and Octave will generate ## an error if it is left out. ## ## Here are some plot examples: ## ## @example ## plot (x, y, "or", x, y2, x, y3, "m", x, y4, "+") ## @end example ## ## This command will plot @code{y} with red circles, @code{y2} with solid ## lines, @code{y3} with solid magenta lines, and @code{y4} with points ## displayed as @samp{+}. ## ## @example ## plot (b, "*", "markersize", 10) ## @end example ## ## This command will plot the data in the variable @code{b}, ## with points displayed as @samp{*} and a marker size of 10. ## ## @example ## @group ## t = 0:0.1:6.3; ## plot (t, cos(t), "-;cos(t);", t, sin(t), "-b;sin(t);"); ## @end group ## @end example ## ## This will plot the cosine and sine functions and label them accordingly ## in the legend. ## ## 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 vector of graphics handles to ## the created line objects. ## ## To save a plot, in one of several image formats such as PostScript ## or PNG, use the @code{print} command. ## ## @seealso{axis, box, grid, hold, legend, title, xlabel, ylabel, xlim, ylim, ezplot, errorbar, fplot, line, plot3, polar, loglog, semilogx, semilogy, subplot} ## @end deftypefn ## Author: jwe function h = plot (varargin) [hax, varargin, nargs] = __plt_get_axis_arg__ ("plot", varargin{:}); if (nargs < 1) print_usage (); endif oldfig = []; if (! isempty (hax)) oldfig = get (0, "currentfigure"); endif unwind_protect hax = newplot (hax); htmp = __plt__ ("plot", hax, varargin{:}); unwind_protect_cleanup if (! isempty (oldfig)) set (0, "currentfigure", oldfig); endif end_unwind_protect if (nargout > 0) h = htmp; endif endfunction %!demo %! x = 1:5; y = 1:5; %! plot (x,y,'g'); %! title ('plot() of green line at 45 degrees'); %!demo %! x = 1:5; y = 1:5; %! plot (x,y,'g*'); %! title ('plot() of green stars along a line at 45 degrees'); %!demo %! x1 = 1:5; y1 = 1:5; %! x2 = 5:9; y2 = 5:-1:1; %! plot (x1,y1,'bo-', x2,y2,'rs-'); %! axis ('tight'); %! title ({'plot() of blue circles ascending and red squares descending'; %! 'connecting lines drawn'}); %!demo %! x = 0:10; %! plot (x, rand (numel (x), 3)) %! axis ([0 10 0 1]) %! title ({'Three random variables', 'x[1x11], y[11x3]'}) %!demo %! x = 0:10; %! plot (x, rand (3, numel (x))) %! axis ([0 10 0 1]) %! title ({'Three random variables', 'x[1x11], y[3x11]'}) %!demo %! x = 0:10; %! plot (repmat (x, 2, 1), rand (2, numel (x)), '-s') %! axis ([0 10 0 1]) %! title ({'Vertical lines with random height and lengths', ... %! 'x[2x11], y[2,11]'}) %!demo %! x = 0:10; %! plot (repmat (x(:), 1, 2), rand (numel (x), 2)) %! axis ([0 10 0 1]) %! title ({'Two random variables', 'x[11x2], y[11x2]'}) %!demo %! x = 0:10; %! shape = [1, 1, numel(x), 2]; %! x = reshape (repmat (x(:), 1, 2), shape); %! y = rand (shape); %! plot (x, y) %! axis ([0 10 0 1]) %! title ({'Two random variables', 'squeezed from 4-d arrays'})