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325 lines
7.4 KiB
Lua
325 lines
7.4 KiB
Lua
--[[ $Id: x16.lua 10304 2009-08-20 09:05:43Z andrewross $
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plshade demo, using color fill.
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Copyright (C) 2008 Werner Smekal
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This file is part of PLplot.
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PLplot is free software you can redistribute it and/or modify
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it under the terms of the GNU General Library Public License as published
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by the Free Software Foundation either version 2 of the License, or
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(at your option) any later version.
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PLplot is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU Library General Public License for more details.
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You should have received a copy of the GNU Library General Public License
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along with PLplot if not, write to the Free Software
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Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
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--]]
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-- initialise Lua bindings for PLplot examples.
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dofile("plplot_examples.lua")
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-- Fundamental settings. See notes[] for more info.
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ns = 20 -- Default number of shade levels
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nx = 35 -- Default number of data points in x
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ny = 46 -- Default number of data points in y
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exclude = 0 -- By default do not plot a page illustrating
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-- exclusion. API is probably going to change
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-- anyway, and cannot be reproduced by any
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-- front end other than the C one.
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-- polar plot data
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PERIMETERPTS = 100
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-- Transformation function
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tr = {}
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function mypltr(x, y)
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tx = tr[1] * x + tr[2] * y + tr[3]
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ty = tr[4] * x + tr[5] * y + tr[6]
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return tx, ty
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end
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----------------------------------------------------------------------------
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-- f2mnmx
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--
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-- Returns min & max of input 2d array.
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----------------------------------------------------------------------------
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function f2mnmx(f, nx, ny)
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fmax = f[1][1]
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fmin = fmax
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for i = 1, nx do
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for j = 1, ny do
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fmax = math.max(fmax, f[i][j])
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fmin = math.min(fmin, f[i][j])
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end
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end
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return fmin, fmax
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end
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function zdefined(x, y)
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z = math.sqrt(x^2 + y^2)
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return z<0.4 or z>0.6
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end
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----------------------------------------------------------------------------
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-- main
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--
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-- Does several shade plots using different coordinate mappings.
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----------------------------------------------------------------------------
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px = {}
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py = {}
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fill_width = 2
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cont_color = 0
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cont_width = 0
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-- Parse and process command line arguments
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pl.parseopts(arg, pl.PL_PARSE_FULL)
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-- Load colour palettes
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pl.spal0("cmap0_black_on_white.pal");
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pl.spal1("cmap1_gray.pal",1);
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-- Reduce colors in cmap 0 so that cmap 1 is useful on a 16-color display
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pl.scmap0n(3)
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-- Initialize plplot
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pl.init()
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-- Set up transformation function
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tr = { 2/(nx-1), 0, -1, 0, 2/(ny-1), -1 }
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-- Allocate data structures
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clevel = {}
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shedge = {}
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z = {}
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w = {}
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-- Set up data array
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for i = 1, nx do
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x = (i-1 - math.floor(nx/2))/math.floor(nx/2)
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z[i] = {}
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w[i] = {}
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for j = 1, ny do
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y = (j-1 - math.floor(ny/2))/math.floor(ny/2)-1
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z[i][j] = -math.sin(7*x) * math.cos(7*y) + x^2 - y^2
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w[i][j] = -math.cos(7*x) * math.sin(7*y) + 2*x*y
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end
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end
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zmin, zmax = f2mnmx(z, nx, ny)
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for i = 1, ns do
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clevel[i] = zmin + (zmax-zmin)*(i-0.5)/ns
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end
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for i = 1, ns+1 do
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shedge[i] = zmin + (zmax-zmin)*(i-1)/ns
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end
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-- Set up coordinate grids
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cgrid1 = {}
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cgrid1["xg"] = {}
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cgrid1["yg"] = {}
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cgrid1["nx"] = nx
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cgrid1["ny"] = ny
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cgrid2 = {}
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cgrid2["xg"] = {}
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cgrid2["yg"] = {}
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cgrid2["nx"] = nx
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cgrid2["ny"] = ny
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for i = 1, nx do
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cgrid2["xg"][i] = {}
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cgrid2["yg"][i] = {}
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for j = 1, ny do
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x, y = mypltr(i-1, j-1)
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argx = x*math.pi/2
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argy = y*math.pi/2
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distort = 0.4
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cgrid1["xg"][i] = x + distort * math.cos(argx)
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cgrid1["yg"][j] = y - distort * math.cos(argy)
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cgrid2["xg"][i][j] = x + distort * math.cos(argx) * math.cos(argy)
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cgrid2["yg"][i][j] = y - distort * math.cos(argx) * math.cos(argy)
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end
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end
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-- Plot using identity transform
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pl.adv(0)
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pl.vpor(0.1, 0.9, 0.1, 0.9)
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pl.wind(-1, 1, -1, 1)
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pl.psty(0)
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pl.shades(z, -1, 1, -1, 1, shedge, fill_width, cont_color, cont_width, 1)
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pl.col0(1)
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pl.box("bcnst", 0, 0, "bcnstv", 0, 0)
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pl.col0(2)
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--pl.cont(w, 1, nx, 1, ny, clevel, mypltr, {})
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pl.lab("distance", "altitude", "Bogon density")
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-- Plot using 1d coordinate transform
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-- Load colour palettes
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pl.spal0("cmap0_black_on_white.pal");
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pl.spal1("cmap1_blue_yellow.pal",1);
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-- Reduce colors in cmap 0 so that cmap 1 is useful on a 16-color display
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pl.scmap0n(3);
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pl.adv(0)
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pl.vpor(0.1, 0.9, 0.1, 0.9)
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pl.wind(-1, 1, -1, 1)
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pl.psty(0)
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pl.shades(z, -1, 1, -1, 1, shedge, fill_width, cont_color, cont_width, 1, "pltr1", cgrid1)
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pl.col0(1)
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pl.box("bcnst", 0, 0, "bcnstv", 0, 0)
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pl.col0(2)
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pl.lab("distance", "altitude", "Bogon density")
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-- Plot using 2d coordinate transform
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-- Load colour palettes
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pl.spal0("cmap0_black_on_white.pal");
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pl.spal1("cmap1_blue_red.pal",1);
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-- Reduce colors in cmap 0 so that cmap 1 is useful on a 16-color display
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pl.scmap0n(3);
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pl.adv(0)
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pl.vpor(0.1, 0.9, 0.1, 0.9)
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pl.wind(-1, 1, -1, 1)
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pl.psty(0)
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pl.shades(z, -1, 1, -1, 1, shedge, fill_width, cont_color, cont_width, 0, "pltr2", cgrid2)
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pl.col0(1)
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pl.box("bcnst", 0, 0, "bcnstv", 0, 0)
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pl.col0(2)
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pl.cont(w, 1, nx, 1, ny, clevel, "pltr2", cgrid2)
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pl.lab("distance", "altitude", "Bogon density, with streamlines")
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-- Plot using 2d coordinate transform
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-- Load colour palettes
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pl.spal0("");
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pl.spal1("",1);
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-- Reduce colors in cmap 0 so that cmap 1 is useful on a 16-color display
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pl.scmap0n(3);
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pl.adv(0)
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pl.vpor(0.1, 0.9, 0.1, 0.9)
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pl.wind(-1, 1, -1, 1)
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pl.psty(0)
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pl.shades(z, -1, 1, -1, 1, shedge, fill_width, 2, 3, 0, "pltr2", cgrid2)
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pl.col0(1)
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pl.box("bcnst", 0, 0, "bcnstv", 0, 0)
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pl.col0(2)
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pl.lab("distance", "altitude", "Bogon density")
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-- Note this exclusion API will probably change.
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-- Plot using 2d coordinate transform and exclusion
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if exclude~=0 then
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-- Load colour palettes
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pl.spal0("cmap0_black_on_white.pal");
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pl.spal1("cmap1_gray.pal",1);
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-- Reduce colors in cmap 0 so that cmap 1 is useful on a 16-color display
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pl.scmap0n(3);
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pl.adv(0)
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pl.vpor(0.1, 0.9, 0.1, 0.9)
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pl.wind(-1, 1, -1, 1)
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plpsty(0)
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pl.shades(z, zdefined, -1, 1, -1, 1, shedge, fill_width, cont_color, cont_width,
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0, "pltr2", cgrid2)
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pl.col0(1)
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pl.box("bcnst", 0, 0, "bcnstv", 0, 0)
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pl.lab("distance", "altitude", "Bogon density with exclusion")
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end
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-- Example with polar coordinates.
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-- Load colour palettes
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pl.spal0("cmap0_black_on_white.pal");
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pl.spal1("cmap1_gray.pal",1);
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-- Reduce colors in cmap 0 so that cmap 1 is useful on a 16-color display
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pl.scmap0n(3);
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pl.adv(0)
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pl.vpor(.1, .9, .1, .9)
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pl.wind(-1, 1, -1, 1)
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pl.psty(0)
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-- Build new coordinate matrices.
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for i = 1, nx do
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r = (i-1)/(nx-1)
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for j = 1, ny do
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t = 2*math.pi/(ny-1)*(j-1)
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cgrid2["xg"][i][j] = r*math.cos(t)
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cgrid2["yg"][i][j] = r*math.sin(t)
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z[i][j] = math.exp(-r^2)*math.cos(5*math.pi*r)*math.cos(5*t)
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end
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end
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-- Need a new shedge to go along with the new data set.
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zmin, zmax = f2mnmx(z, nx, ny)
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for i = 1, ns+1 do
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shedge[i] = zmin + (zmax-zmin)*(i-1)/ns
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end
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-- Now we can shade the interior region.
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pl.shades(z, -1, 1, -1, 1, shedge, fill_width, cont_color, cont_width, 0, "pltr2", cgrid2)
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-- Now we can draw the perimeter. (If do before, shade stuff may overlap.)
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for i = 1, PERIMETERPTS do
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t = 2*math.pi/(PERIMETERPTS-1)*(i-1)
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px[i] = math.cos(t)
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py[i] = math.sin(t)
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end
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pl.col0(1)
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pl.line(px, py)
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-- And label the plot.
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pl.col0(2)
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pl.lab( "", "", "Tokamak Bogon Instability" )
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pl.plend()
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