Mario Voigt
4175b377bd
's/fablabchemnitz_//g' *.inx;sed -i 's/>fablabchemnitz_/>/g' *.inx;sed -i 's/fablabchemnitz_//g' *.py; rename 's/fablabchemnitz_//g' *.svg"
334 lines
12 KiB
Python
334 lines
12 KiB
Python
#!/usr/bin/env python3
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# eggbot_sineandlace.py
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#
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# Generate sinusoidal and "lace" curves. The curves are described in SVG
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# along with the data necessary to regenerate them. The same data can be
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# used to generate new curves which are bounded by a pair of previously
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# generated curves.
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# Written by Daniel C. Newman for the Eggbot Project
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# dan newman @ mtbaldy us
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# Last updated 28 November 2010
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# 15 October 2010
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# This program is free software; you can redistribute it and/or modify
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# it under the terms of the GNU General Public License as published by
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# 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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#
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# This program 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 General Public License for more details.
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#
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# You should have received a copy of the GNU General Public License
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# along with this program; if not, write to the Free Software
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# Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
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from math import pi, cos, sin
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from lxml import etree
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import inkex
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from inkex.paths import Path
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VERSION = 1
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def parseDesc(str):
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"""
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Create a dictionary from string description
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"""
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if str is None:
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return {}
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else:
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return dict([tok.split(':') for tok in str.split(';') if len(tok)])
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def formatDesc(d):
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"""
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Format an inline name1:value1;name2:value2;... style attribute value
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from a dictionary
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"""
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return ';'.join([atr + ':' + str(val) for atr, val in d.iteritems()])
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def drawSine(cycles=8, rn=0, rm=0, nPoints=50, offset=None,
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height=200, width=3200, rescale=0.98, bound1='', bound2='', fun='sine', spline=True):
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"""
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cycles
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Number of periods to plot within the rectangle of width 'width'
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rn, rm
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Start the function (on the left edge) at the value x = 2 * pi * rn / rm.
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When rm = 0, function is started at x = 0.
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nPoints
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The number of points to sample the function at. Since the function is
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approximated using Bezier cubic splines, this isn't the number of points
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to plot.
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offset
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(x, y) coordinate of the lower left corner of the bounding rectangle
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in which to plot the function.
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height, width
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The height and width of the rectangle in which to plot the function.
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Ignored when bounding functions, bound1 and bound2, are supplied.
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rescale
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Multiplicative Y-scaling factor by which to rescale the plotted function
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so that it does not fully reach the vertical limits of its bounds. This
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aids in Eggbot plots by preventing lines from touching and overlapping.
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bound1, bound2
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Descriptions of upper and lower bounding functions by which to limit the
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vertical range of the function to be plotted.
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fun
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May be either 'sine' or 'lace'.
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"""
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"""
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A complicated way of plotting y = sin(x)
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Complicated because we wish to generate the sine wave using a
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parametric representation. For plotting a single sine wave in
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Cartesian coordinates, this is overkill. However, it's useful
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for when we want to compress and expand the amplitude of the
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sine wave in accord with upper and lower boundaries which themselves
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are functions. By parameterizing everything in sight with the
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same parameter s and restricting s to the range [0, 1], our life
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is made much easier.
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"""
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if offset is None:
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offset = [0, 0]
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bounded = False
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if bound1 and bound2:
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func = parseDesc(bound1)
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if len(func) == 0:
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return None, None
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m1 = int(func['rm'])
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if m1 == 0:
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x_min1 = 0.0
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else:
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x_min1 = 2 * pi * float(func['rn']) / float(m1)
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x_max1 = x_min1 + 2 * pi * float(func['cycles'])
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y_min1 = -1.0
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y_max1 = 1.0
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y_scale1 = float(func['height']) / (y_max1 - y_min1)
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y_offset1 = float(func['y'])
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Y1s = lambda s: y_offset1 - y_scale1 * sin(x_min1 + (x_max1 - x_min1) * s)
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func = parseDesc(bound2)
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if len(func) == 0:
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return None, None
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m2 = int(func['rm'])
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if m2 == 0:
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x_min2 = 0.0
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else:
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x_min2 = 2 * pi * float(func['rn']) / float(m2)
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x_max2 = x_min2 + 2 * pi * float(func['cycles'])
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y_min2 = -1.0
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y_max2 = 1.0
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y_scale2 = float(func['height']) / (y_max2 - y_min2)
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y_offset2 = float(func['y'])
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Y2s = lambda s: y_offset2 - y_scale2 * sin(x_min2 + (x_max2 - x_min2) * s)
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bounded = True
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rescale = float(rescale)
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x_offset = float(offset[0])
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y_offset = float(offset[1])
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# Each cycle is 2pi
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r = 2 * pi * float(cycles)
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if (int(rm) == 0) or (int(rn) == 0):
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x_min = 0.0
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else:
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x_min = 2 * pi * float(rn) / float(rm)
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x_max = x_min + r
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x_scale = float(width) / r # width / ( x_max - x_min )
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y_min = -1.0
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y_max = 1.0
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y_scale = float(height) / (y_max - y_min)
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# Our parametric equations which map the results to our drawing window
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# Note the "-y_scale" that's because in SVG, the y-axis runs "backwards"
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if not fun:
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fun = 'sine'
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fun = fun.lower()
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if fun == 'sine':
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Xs = lambda s: x_offset + x_scale * (x_max - x_min) * s
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Ys = lambda s: y_offset - y_scale * sin(x_min + (x_max - x_min) * s)
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dYdXs = lambda s: -y_scale * cos(x_min + (x_max - x_min) * s) / x_scale
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elif fun == 'lace':
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Xs = lambda s: x_offset + x_scale * ((x_max - x_min) * s + 2 * sin(2 * s * (x_max - x_min) + pi))
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dXs = lambda s: x_scale * (x_max - x_min) * (1.0 + 4.0 * cos(2 * s * (x_max - x_min) + pi))
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Ys = lambda s: y_offset - y_scale * sin(x_min + (x_max - x_min) * s)
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dYs = lambda s: -y_scale * cos(x_min + (x_max - x_min) * s) * (x_max - x_min)
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dYdXs = lambda s: dYs(s) / dXs(s)
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else:
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inkex.errormsg('Unknown function {0} specified'.format(fun))
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return
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# Derivatives: remember the chain rule....
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# dXs = lambda s: x_scale * ( x_max - x_min )
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# dYs = lambda s: -y_scale * cos( x_min + ( x_max - x_min ) * s ) * ( x_max - x_min )
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# x_third is 1/3 the step size
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nPoints = int(nPoints)
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# x_third is 1/3 the step size; note that Xs(1) - Xs(0) = x_scale * ( x_max - x_min )
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x_third = (Xs(1.0) - Xs(0.0)) / float(3 * (nPoints - 1))
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if bounded:
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y_upper = Y2s(0.0)
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y_lower = Y1s(0.0)
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y_offset = 0.5 * (y_upper + y_lower)
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y_upper = y_offset + rescale * (y_upper - y_offset)
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y_lower = y_offset + rescale * (y_lower - y_offset)
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y_scale = (y_upper - y_lower) / (y_max - y_min)
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x1 = Xs(0.0)
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y1 = Ys(0.0)
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dx1 = 1.0
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dy1 = dYdXs(0.0)
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# Starting point in the path is ( x, sin(x) )
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path_data = []
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path_data.append(['M', [x1, y1]])
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for i in range(1, nPoints):
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s = float(i) / float(nPoints - 1)
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if bounded:
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y_upper = Y2s(s)
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y_lower = Y1s(s)
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y_offset = 0.5 * (y_upper + y_lower)
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y_upper = y_offset + rescale * (y_upper - y_offset)
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y_lower = y_offset + rescale * (y_lower - y_offset)
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y_scale = (y_upper - y_lower) / (y_max - y_min)
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x2 = Xs(s)
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y2 = Ys(s)
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dx2 = 1.0
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dy2 = dYdXs(s)
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if dy2 > 10.0:
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dy2 = 10.0
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elif dy2 < -10.0:
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dy2 = -10.0
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# Add another segment to the plot
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if spline:
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path_data.append(['C',
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[x1 + (dx1 * x_third),
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y1 + (dy1 * x_third),
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x2 - (dx2 * x_third),
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y2 - (dy2 * x_third),
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x2, y2]])
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else:
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path_data.append(['L', [x1, y1]])
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path_data.append(['L', [x2, y2]])
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x1 = x2
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y1 = y2
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dx1 = dx2
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dy1 = dy2
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path_desc = \
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'version:{0:d};style:linear;function:sin(x);'.format(VERSION) + \
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'cycles:{0:f};rn:{1:d};rm:{2:d};points:{3:d};'.format(cycles, rn, rm, nPoints) + \
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'width:{0:d};height:{1:d};x:{2:d};y:{3:d}'.format(width, height, offset[0], offset[1])
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return path_data, path_desc
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class SpiroSine(inkex.Effect):
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nsURI = 'http://sample.com/ns'
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nsPrefix = 'doof'
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def __init__(self):
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inkex.Effect.__init__(self)
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self.arg_parser.add_argument("--tab", help="The active tab when Apply was pressed")
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self.arg_parser.add_argument('--fCycles', type=float, default=10.0, help='Number of cycles (periods)')
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self.arg_parser.add_argument('--nrN', type=int, default=0, help='Start x at 2 * pi * n / m')
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self.arg_parser.add_argument('--nrM', type=int, default=0, help='Start x at 2 * pi * n / m')
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self.arg_parser.add_argument('--fRecess', type=float, default=2.0, help='Recede from envelope by factor')
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self.arg_parser.add_argument("--nSamples", type=int, default=50.0, help="Number of points to sample")
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self.arg_parser.add_argument("--nWidth", type=int, default=3200, help="Width in pixels")
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self.arg_parser.add_argument("--nHeight", type=int, default=100, help="Height in pixels")
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self.arg_parser.add_argument("--nOffsetX", type=int, default=0, help="Starting x coordinate (pixels)")
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self.arg_parser.add_argument("--nOffsetY", type=int, default=400, help="Starting y coordinate (pixels)")
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self.arg_parser.add_argument('--bLace', type=inkex.Boolean, default=False, help='Lace')
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self.arg_parser.add_argument('--bSpline', type=inkex.Boolean, default=True, help='Spline')
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self.recess = 0.95
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def effect(self):
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inkex.NSS[self.nsPrefix] = self.nsURI
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if self.options.bLace:
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func = 'lace'
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else:
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func = 'sine'
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f_recess = 1.0
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if self.options.fRecess > 0.0:
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f_recess = 1.0 - self.options.fRecess / 100.0
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if f_recess <= 0.0:
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f_recess = 0.0
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if self.options.ids:
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if len(self.options.ids) == 2:
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desc1 = self.selected[self.options.ids[0]].get(inkex.addNS('desc', self.nsPrefix))
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desc2 = self.selected[self.options.ids[1]].get(inkex.addNS('desc', self.nsPrefix))
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if (not desc1) or (not desc2):
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inkex.errormsg('Selected objects do not smell right')
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return
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path_data, path_desc = drawSine(self.options.fCycles,
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self.options.nrN,
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self.options.nrM,
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self.options.nSamples,
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[self.options.nOffsetX, self.options.nOffsetY],
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self.options.nHeight,
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self.options.nWidth,
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f_recess,
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desc1, desc2, func, self.options.bSpline)
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else:
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inkex.errormsg('Exactly two objects must be selected')
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return
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else:
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self.document.getroot().set(inkex.addNS(self.nsPrefix, 'xmlns'), self.nsURI)
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path_data, path_desc = drawSine(self.options.fCycles,
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self.options.nrN,
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self.options.nrM,
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self.options.nSamples,
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[self.options.nOffsetX, self.options.nOffsetY],
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self.options.nHeight,
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self.options.nWidth,
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f_recess,
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'',
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'',
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func,
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self.options.bSpline)
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style = {'stroke': 'black', 'stroke-width': '1', 'fill': 'none'}
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path_attrs = {
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'style': str(inkex.Style(style)),
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'd': str(Path(path_data)),
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inkex.addNS('desc', self.nsPrefix): path_desc}
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newpath = etree.SubElement(self.document.getroot(),
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inkex.addNS('path', 'svg'), path_attrs, nsmap=inkex.NSS)
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if __name__ == '__main__':
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SpiroSine().run() |