Mercurial > octave
view scripts/plot/draw/stream3.m @ 32062:ada96a467a28
quiver: Improve plotting with non-float numeric inputs (bug #59695)
* scripts/plot/draw/private/__quiver__.m: Change firstnonnumeric check to look
for char instead of numeric to allow for logical inputs. Recast all inputs
up to firstnonnumeric as doubles. Check if firstnonnumeric element is 'off'
and if so set scale factor to 0 and increment firstnonnumeric.
* scripts/plot/draw/quiver.m: Update docstring to include scaling factor
option 'off'. Add BIST for int and logical input types.
* scripts/plot/draw/quiver3.m: Update docstring to include scaling factor
option 'off'. Add BISTs for too-few inputs.
* etc/NEWS.9.md: Appended details of changes to quiver note under General
Improvements and noted it also applies to quiver3.
| author | Nicholas R. Jankowski <jankowski.nicholas@gmail.com> |
|---|---|
| date | Wed, 26 Apr 2023 17:18:50 -0400 |
| parents | 597f3ee61a48 |
| children | 2e484f9f1f18 |
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######################################################################## ## ## Copyright (C) 2019-2023 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 {} {@var{xyz} =} stream3 (@var{x}, @var{y}, @var{z}, @var{u}, @var{v}, @var{w}, @var{sx}, @var{sy}, @var{sz}) ## @deftypefnx {} {@var{xyz} =} stream3 (@var{u}, @var{v}, @var{w}, @var{sx}, @var{sy}, @var{sz}) ## @deftypefnx {} {@var{xyz} =} stream3 (@dots{}, @var{options}) ## Compute 3-D streamline data. ## ## Calculate streamlines of a vector field given by @code{[@var{u}, @var{v}, ## @var{w}]}. The vector field is defined over a rectangular grid given by ## @code{[@var{x}, @var{y}, @var{z}]}. The streamlines start at the seed ## points @code{[@var{sx}, @var{sy}, @var{sz}]}. The returned value @var{xyz} ## contains a cell array of vertex arrays. If the starting point is outside ## the vector field, @code{[]} is returned. ## ## The input parameter @var{options} is a 2-D vector of the form ## @code{[@var{stepsize}, @var{max_vertices}]}. The first parameter ## specifies the step size used for trajectory integration (default 0.1). A ## negative value is allowed which will reverse the direction of integration. ## The second parameter specifies the maximum number of segments used to ## create a streamline (default 10,000). ## ## The return value @var{xyz} is a @nospell{nverts x 3} matrix containing the ## coordinates of the field line segments. ## ## Example: ## ## @example ## @group ## [x, y, z] = meshgrid (0:3); ## u = 2 * x; ## v = y; ## w = 3 * z; ## xyz = stream3 (x, y, z, u, v, w, 1.0, 0.5, 0.0); ## @end group ## @end example ## ## @seealso{stream2, streamline, streamribbon, streamtube, ostreamtube} ## @end deftypefn ## References: ## ## @article{ ## title = {Particle Tracing Algorithms for 3D Curvilinear Grids}, ## year = {2000}, ## author = {Nielson, Gregory and Uller, H. and Sadarjoen, I. and Walsum, Theo and Hin, Andrea and Post, Frits} ## } ## ## @article{ ## title = {Sources of error in the graphical analysis of CFD results}, ## publisher = {Journal of Scientific Computing}, ## year = {1988}, ## volume = {3}, ## number = {2}, ## pages = {149--164}, ## author = {Buning, Pieter G.}, ## } function xyz = stream3 (varargin) options = []; switch (numel (varargin)) case {6,7} if (numel (varargin) == 6) [u, v, w, spx, spy, spz] = varargin{:}; else [u, v, w, spx, spy, spz, options] = varargin{:}; endif [m, n, p] = size (u); [x, y, z] = meshgrid (1:n, 1:m, 1:p); case 9 [x, y, z, u, v, w, spx, spy, spz] = varargin{:}; case 10 [x, y, z, u, v, w, spx, spy, spz, options] = varargin{:}; otherwise print_usage (); endswitch stepsize = 0.1; max_vertices = 10_000; if (! isempty (options)) switch (numel (options)) case 1 stepsize = options(1); case 2 stepsize = options(1); max_vertices = options(2); otherwise error ("stream3: OPTIONS must be a 1- or 2-element vector"); endswitch if (! isreal (stepsize) || stepsize == 0) error ("stream2: STEPSIZE must be a real scalar != 0"); endif if (! isreal (max_vertices) || max_vertices < 1) error ("stream2: MAX_VERTICES must be an integer > 0"); endif max_vertices = fix (max_vertices); endif if (! (size_equal (u, v, w, x, y, z) && size_equal (spx, spy, spz))) error ("stream3: matrix dimensions must match"); endif if (iscomplex (u) || iscomplex (v) || iscomplex (w) || iscomplex (x) || iscomplex (y) || iscomplex (z) || iscomplex (spx) || iscomplex (spy) || iscomplex (spz)) error ("stream3: all inputs must be real-valued"); endif gx = x(1, :, 1); gy = y(:, 1, 1).'; tmp = z(1, 1, :); gz = tmp(:).'; ## Jacobian Matrix dx = diff (gx); dy = diff (gy); dz = diff (gz); ## "<" used to check if the mesh is ascending if (any (dx <= 0) || any (dy <= 0) || any (dz <= 0) || any (isnan (dx)) || any (isnan (dy)) || any (isnan (dz))) error ("stream3: non-monotonically increasing or NaN values found in mesh"); endif tx = 1 ./ dx; ty = 1 ./ dy; tz = 1 ./ dz; ## "Don't cares" used for handling points located on the border tx(end + 1) = 0; ty(end + 1) = 0; tz(end + 1) = 0; dx(end + 1) = 0; dy(end + 1) = 0; dz(end + 1) = 0; px = spx(:); py = spy(:); pz = spz(:); for nseed = 1 : numel (px) xp = px(nseed); yp = py(nseed); zp = pz(nseed); idx = find (diff (gx <= xp), 1); if (gx(end) == xp) idx = numel (gx); endif idy = find (diff (gy <= yp), 1); if (gy(end) == yp) idy = numel (gy); endif idz = find (diff (gz <= zp), 1); if (gz(end) == zp) idz = numel (gz); endif if (isempty (idx) || isempty (idy) || isempty (idz)) xyz{nseed} = []; else ## Transform seed from P coordinates to C coordinates zeta = (idx - 1) + (xp - gx(idx)) * tx(idx); xi = (idy - 1) + (yp - gy(idy)) * ty(idy); rho = (idz - 1) + (zp - gz(idz)) * tz(idz); C = __streameuler3d__ (u, v, w, tx, ty, tz, zeta, xi, rho, ... stepsize, max_vertices); ## Transform from C coordinates to P coordinates idu = floor (C(:, 1)); idv = floor (C(:, 2)); idw = floor (C(:, 3)); xyz{nseed} = [gx(idu + 1).' + (C(:, 1) - idu).*(dx(idu + 1).'), ... gy(idv + 1).' + (C(:, 2) - idv).*(dy(idv + 1).'), ... gz(idw + 1).' + (C(:, 3) - idw).*(dz(idw + 1).')]; endif endfor endfunction %!demo %! clf; %! [x, y, z] = meshgrid (-30:1:30, -30:1:30, 0:1:50); %! s = 10; %! b = 8 / 3; %! r = 28; %! u = s * (y - x); %! v = r * x - y - x.*z; %! w = x.*y - b * z; %! hold on; %! sx = 0.1; %! sy = 0.1; %! sz = 0.1; %! plot3 (sx, sy, sz, ".r", "markersize", 15); %! h = streamline (x, y, z, u, v, w, sx, sy, sz, [0.1, 50000]); %! set (h, "color", "r"); %! view (3); %! title ("Lorenz System"); %! grid on; %! axis equal; %!test %! [u, v, w] = meshgrid (0:3, 0:3, 0:3); %! xyz = stream3 (u, v, w, 2, 2, 2, [0.01,5]); %! assert (numel (xyz{:}), 15); ## Test input validation %!error <Invalid call> stream3 () %!error <Invalid call> stream3 (1) %!error <Invalid call> stream3 (1,2) %!error <Invalid call> stream3 (1,2,3) %!error <Invalid call> stream3 (1,2,3,4) %!error <Invalid call> stream3 (1,2,3,4,5) %!error <Invalid call> stream3 (1,2,3,4,5,6,7,8) %!error <OPTIONS must be a 1- or 2-element> stream3 (1,2,3,4,5,6, [1,2,3]) %!error <STEPSIZE must be a real scalar != 0> stream3 (1,2,3,4,5,6, [1i]) %!error <STEPSIZE must be a real scalar != 0> stream3 (1,2,3,4,5,6, [0]) %!error <MAX_VERTICES must be an integer> stream3 (1,2,3,4,5,6, [1, 1i]) %!error <MAX_VERTICES must be an integer> stream3 (1,2,3,4,5,6, [1, 0]) %!error <matrix dimensions must match> stream3 ([1 1],2,3,4,5,6) %!error <matrix dimensions must match> stream3 (1,[2 2],3,4,5,6) %!error <matrix dimensions must match> stream3 (1,2,[3 3],4,5,6) %!error <matrix dimensions must match> stream3 (1,2,3,[4 4],5,6) %!error <matrix dimensions must match> stream3 (1,2,3,4,[5 5],6) %!error <matrix dimensions must match> stream3 (1,2,3,4,5,[6 6]) %!error <all inputs must be real-valued> stream3 (1i,2,3,4,5,6) %!error <all inputs must be real-valued> stream3 (1,2i,3,4,5,6) %!error <all inputs must be real-valued> stream3 (1,2,3i,4,5,6) %!error <all inputs must be real-valued> stream3 (1,2,3,4i,5,6) %!error <all inputs must be real-valued> stream3 (1,2,3,4,5i,6) %!error <all inputs must be real-valued> stream3 (1,2,3,4,5,6i) %!error <non-monotonically increasing or NaN values found in mesh> %! stream3 ([2 1], [1 2], [3 3], [4 4], [5 5], [6 6], [7 7], [8 8], [9 9]); %!error <non-monotonically increasing or NaN values found in mesh> %! stream3 ([1 NaN], [1 2], [3 3], [4 4], [5 5], [6 6], [7 7], [8 8], [9 9]); ## FIXME: vectors representing x, y, z mesh are not accepted. %#!error <non-monotonically increasing or NaN values found in mesh> %! stream3 ([1 2], [2 1], [3 3], [4 4], [5 5], [6 6], [7 7], [8 8], [9 9]); %#!error <non-monotonically increasing or NaN values found in mesh> %! stream3 ([1 2], [1 NaN], [3 3], [4 4], [5 5], [6 6], [7 7], [8 8], [9 9]); %#!error <non-monotonically increasing or NaN values found in mesh> %! stream3 ([1 2], [1 2], [2 1], [4 4], [5 5], [6 6], [7 7], [8 8], [9 9]); %#!error <non-monotonically increasing or NaN values found in mesh> %! stream3 ([1 2], [1 2], [1 NaN], [4 4], [5 5], [6 6], [7 7], [8 8], [9 9]);