Mercurial > hg > octave-lyh
view scripts/sparse/treeplot.m @ 14237:11949c9795a0
Revamp %!demos in m-files to use Octave coding conventions on spacing, etc.
Add clf() to all demos using plot features to get reproducibility.
Use 64 as input to all colormaps (jet (64)) to get reproducibility.
* bicubic.m, cell2mat.m, celldisp.m, cplxpair.m, interp1.m, interp2.m,
interpft.m, interpn.m, profile.m, profshow.m, convhull.m, delaunay.m,
griddata.m, inpolygon.m, voronoi.m, autumn.m, bone.m, contrast.m, cool.m,
copper.m, flag.m, gmap40.m, gray.m, hot.m, hsv.m, image.m, imshow.m, jet.m,
ocean.m, pink.m, prism.m, rainbow.m, spring.m, summer.m, white.m, winter.m,
condest.m, onenormest.m, axis.m, clabel.m, colorbar.m, comet.m, comet3.m,
compass.m, contour.m, contour3.m, contourf.m, cylinder.m, daspect.m,
ellipsoid.m, errorbar.m, ezcontour.m, ezcontourf.m, ezmesh.m, ezmeshc.m,
ezplot.m, ezplot3.m, ezpolar.m, ezsurf.m, ezsurfc.m, feather.m, fill.m,
fplot.m, grid.m, hold.m, isosurface.m, legend.m, loglog.m, loglogerr.m,
pareto.m, patch.m, pbaspect.m, pcolor.m, pie.m, pie3.m, plot3.m, plotmatrix.m,
plotyy.m, polar.m, quiver.m, quiver3.m, rectangle.m, refreshdata.m, ribbon.m,
rose.m, scatter.m, scatter3.m, semilogx.m, semilogxerr.m, semilogy.m,
semilogyerr.m, shading.m, slice.m, sombrero.m, stairs.m, stem.m, stem3.m,
subplot.m, surf.m, surfc.m, surfl.m, surfnorm.m, text.m, title.m, trimesh.m,
triplot.m, trisurf.m, uigetdir.m, uigetfile.m, uimenu.m, uiputfile.m,
waitbar.m, xlim.m, ylim.m, zlim.m, mkpp.m, pchip.m, polyaffine.m, spline.m,
bicgstab.m, cgs.m, gplot.m, pcg.m, pcr.m, treeplot.m, strtok.m, demo.m,
example.m, rundemos.m, speed.m, test.m, calendar.m, datestr.m, datetick.m,
weekday.m: Revamp %!demos to use Octave coding conventions on spacing, etc.
| author | Rik <octave@nomad.inbox5.com> |
|---|---|
| date | Fri, 20 Jan 2012 12:59:53 -0800 |
| parents | 72c96de7a403 |
| children | 5d3a684236b0 |
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## Copyright (C) 2005-2012 Ivana Varekova ## ## 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} {} treeplot (@var{tree}) ## @deftypefnx {Function File} {} treeplot (@var{tree}, @var{node_style}, @var{edge_style}) ## Produce a graph of tree or forest. The first argument is vector of ## predecessors, optional parameters @var{node_style} and @var{edge_style} ## define the output style. The complexity of the algorithm is O(n) in ## terms of is time and memory requirements. ## @seealso{etreeplot, gplot} ## @end deftypefn function treeplot (tree, node_style = "ko", edge_style = "r") if (nargin < 1 || nargin > 3 || nargout > 0) print_usage (); endif if (! ismatrix (tree) || rows (tree) != 1 || ! isnumeric (tree) || ! isvector (tree) || any (tree > length (tree))) error ("treeplot: TREE must be a vector of predecessors"); endif ## Verify node_style if (nargin > 1) if (isempty (regexp (node_style, '[ox+*]', 'once'))) node_style = [node_style, "o"]; endif endif ## Make it a row vector. tree = tree(:)'; ## The count of nodes of the graph. num_nodes = length (tree); ## The number of children. num_children = zeros (1, num_nodes+1); for i = 1:num_nodes ## VEC_OF_CHILD is helping vector which is used to speed up the ## choose of descendant nodes. num_children(tree(i)+1) = num_children(tree(i)+1) + 1; endfor pos = 1; start = zeros (1, num_nodes+1); xhelp = zeros (1, num_nodes+1); stop = zeros (1, num_nodes+1); for i = 1:num_nodes+1 start(i) = pos; xhelp(i) = pos; pos += num_children(i); stop(i) = pos; endfor for i = 1:num_nodes vec_of_child(xhelp(tree(i)+1)) = i; xhelp(tree(i)+1) = xhelp(tree(i)+1)+1; endfor ## The number of "parent" (actual) node (it's descendants will be ## browse in the next iteration). par_number = 0; ## The x-coordinate of the left most descendant of "parent node" ## this value is increased in each leaf. left_most = 0; ## The level of "parent" node (root level is num_nodes). level = num_nodes; ## Num_nodes - max_ht is the height of this graph. max_ht = num_nodes; ## Main stack - each item consists of two numbers - the number of ## node and the number it's of parent node on the top of stack ## there is "parent node". stk = [-1, 0]; ## Stack which is use to draw the graph edge (it have to be ## uninterupted line). skelet = 0; ## The top of the stack. while (par_number != -1) if (start(par_number+1) < stop(par_number+1)) idx = vec_of_child(start(par_number+1):stop(par_number+1)-1); else idx = zeros (1, 0); endif ## Add to idx the vector of parent descendants. stk = [stk; [idx', ones(fliplr(size(idx)))*par_number]]; ## Add to stack the records relevant to parent descandant s. if (par_number != 0) skelet = [skelet; ([ones(size(idx))*par_number; idx])(:)]; endif ## If there is not any descendant of "parent node": if (stk(end,2) != par_number) left_most++; x_coordinate_r(par_number) = left_most; max_ht = min (max_ht, level); if (length(stk) > 1 && find ((shift(stk,1)-stk) == 0) > 1 && stk(end,2) != stk(end-1,2)) ## Return to the nearest branching the position to return ## position is the position on the stack, where should be ## started further search (there are two nodes which has the ## same parent node). position = (find ((shift(stk(:,2),1)-stk(:,2)) == 0))(end) + 1; par_number_vec = stk(position:end,2); ## The vector of removed nodes (the content of stack form ## position to end). skelet = [skelet; flipud(par_number_vec)]; level += length (par_number_vec); ## The level have to be decreased. x_coordinate_r(par_number_vec) = left_most; stk(position:end,:) = []; endif ## Remove the next node from "searched branch". stk(end,:) = []; ## Choose new "parent node". par_number = stk(end,1); ## If there is another branch start to search it. if (par_number != -1) skelet = [skelet; stk(end,2); par_number]; y_coordinate(par_number) = level; x_coordinate_l(par_number) = left_most + 1; endif else ## There were descendants of "parent nod" choose the last of ## them and go on through it. level--; par_number = stk(end,1); y_coordinate(par_number) = level; x_coordinate_l(par_number) = left_most + 1; endif endwhile ## Calculate the x coordinates (the known values are the position ## of most left and most right descendants). x_coordinate = (x_coordinate_l + x_coordinate_r) / 2; ## FIXME -- we should probably stuff all the arguments into a cell ## array and make a single call to plot here so we can avoid ## setting the hold state... hold_is_on = ishold (); unwind_protect ## Plot graph nodes. plot (x_coordinate, y_coordinate, node_style); ## Helping command - usable for plotting edges skelet = [skelet; 0]; ## Draw graph edges. idx = find (skelet == 0); hold ("on"); ## Plot each tree component in one loop. for i = 2:length(idx) ## Tree component start. istart = idx(i-1) + 1; ## Tree component end. istop = idx(i) - 1; if (istop - istart < 1) continue; endif plot (x_coordinate(skelet(istart:istop)), y_coordinate(skelet(istart:istop)), edge_style); endfor ## Set axis and graph size. axis ([0.5, left_most+0.5, max_ht-0.5, num_nodes-0.5], "nolabel"); unwind_protect_cleanup if (! hold_is_on) hold ("off"); endif end_unwind_protect endfunction %!demo %! clf; %! treeplot ([2 4 2 0 6 4 6]); %! % Plot a simple tree plot %!demo %! clf; %! treeplot ([2 4 2 0 6 4 6], "b+", "g"); %! % Plot a simple tree plot defining the edge and node styles