319 lines
13 KiB
Python
319 lines
13 KiB
Python
|
#!/usr/bin/env python3
|
|||
|
'''
|
|||
|
Created by Danylo Horbatenko 2018, dnkxyz@gmail.com
|
|||
|
Copyright (C) 2018 George Fomitchev, gf@endurancerobots.com
|
|||
|
|
|||
|
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
|
|||
|
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
|
|||
|
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
|
|||
|
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
|
|||
|
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
|
|||
|
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
|
|||
|
SOFTWARE.
|
|||
|
'''
|
|||
|
#Version control: last edited by 01.03.2018 8:20
|
|||
|
import os
|
|||
|
import tempfile
|
|||
|
import shutil
|
|||
|
import subprocess
|
|||
|
import math
|
|||
|
import inkex
|
|||
|
import sys
|
|||
|
import fablabchemnitz_png
|
|||
|
from lxml import etree
|
|||
|
from inkex.paths import Path
|
|||
|
|
|||
|
def saw(x):
|
|||
|
#The function returns a symmetric triangle wave with period 4 and varying between -1 and 1
|
|||
|
x = math.fmod(x, 4.0)
|
|||
|
x = math.fabs(x)
|
|||
|
if x > 2.0:
|
|||
|
y = 3 - x
|
|||
|
else:
|
|||
|
y = x - 1
|
|||
|
return y
|
|||
|
|
|||
|
def square(x):
|
|||
|
#The function returns a square wave with period 4 and varying between -1 and 1
|
|||
|
x = math.fmod(x, 4.0)
|
|||
|
if 1.0 < x < 3.0:
|
|||
|
y = 1.0
|
|||
|
else:
|
|||
|
y = -1.0
|
|||
|
return y
|
|||
|
|
|||
|
class LineShading(inkex.Effect):
|
|||
|
def __init__(self):
|
|||
|
inkex.Effect.__init__(self)
|
|||
|
self.arg_parser.add_argument('--palette', help='Choose the colors...')
|
|||
|
self.arg_parser.add_argument("--waveform", help="Select the shape of the curve")
|
|||
|
self.arg_parser.add_argument("--num_lines", type=int, help="Number of lines")
|
|||
|
self.arg_parser.add_argument("--min_period", type=float, help="Minimum period (corresponds to black pixels)")
|
|||
|
self.arg_parser.add_argument("--max_period", type=float, help="Maximum period (corresponds to white pixels)")
|
|||
|
self.arg_parser.add_argument("--min_amplitude", type=float, help="Minimum amplitude (corresponds to white pixels)")
|
|||
|
self.arg_parser.add_argument("--max_amplitude", type=float, help="Maximum amplitude (corresponds to black pixels)")
|
|||
|
self.arg_parser.add_argument("--gamma", type=float, help="Maximum amplitude (corresponds to black pixels)")
|
|||
|
self.arg_parser.add_argument("--line_width", type=float, help="Line width")
|
|||
|
self.arg_parser.add_argument("--units", help="Units for line thickness")
|
|||
|
self.arg_parser.add_argument("--remove", type=inkex.Boolean, help="If True, source image is removed")
|
|||
|
self.arg_parser.add_argument("--active-tab", help="The selected UI-tab when OK was pressed")
|
|||
|
|
|||
|
def drawfunction(self, image_w, image_h, file):
|
|||
|
reader = fablabchemnitz_png.Reader(file)
|
|||
|
w, h, pixels, metadata = reader.read_flat()
|
|||
|
matrice = [[1.0 for i in range(w)]for j in range(h)]
|
|||
|
if metadata['alpha']:
|
|||
|
n = 4
|
|||
|
else:
|
|||
|
n = 3
|
|||
|
#RGB convert to grayscale 0.21R + 0.72G + 0.07B
|
|||
|
for y in range(h):
|
|||
|
for x in range(w):
|
|||
|
pixel_pos = (x + y * w)*n
|
|||
|
p = 1.0 - (pixels[pixel_pos]*0.21 + pixels[(pixel_pos+1)]*0.72 + pixels[(pixel_pos+2)]*0.07)/255.0
|
|||
|
matrice[y][x] = math.pow(p, 1.0/self.options.gamma)
|
|||
|
|
|||
|
points = []
|
|||
|
step_y = image_h/h
|
|||
|
step_x = image_w/(w-1)
|
|||
|
min_amplitude = self.options.min_amplitude*step_y/2
|
|||
|
max_amplitude = self.options.max_amplitude*step_y/2
|
|||
|
min_period = self.options.min_period*step_y
|
|||
|
max_period = self.options.max_period*step_y
|
|||
|
min_frequency = 1.0/max_period
|
|||
|
max_frequency = 1.0/min_period
|
|||
|
|
|||
|
#Sinusoidal wave (optimized)
|
|||
|
if self.options.waveform == 'sin':
|
|||
|
for y in range(h):
|
|||
|
pi = math.pi
|
|||
|
phase = 0.0
|
|||
|
coord_x = 0.0
|
|||
|
amplitude = 0.0
|
|||
|
n_step = 0
|
|||
|
x0 = 0.0
|
|||
|
y0 = math.sin(phase)*(min_amplitude + (max_amplitude - min_amplitude)*matrice[y][x]) + (y+0.5)*step_y
|
|||
|
points.append(['M',[x0, y0]])
|
|||
|
for x in range(w):
|
|||
|
period = min_period + (max_period - min_period)*(1-matrice[y][x])
|
|||
|
#period = 1.0/(min_frequency + (max_frequency - min_frequency)*(matrice[y][x]))
|
|||
|
d_phase = 2.0*pi/period*step_x
|
|||
|
#calculate y
|
|||
|
if phase > 2.0*pi:
|
|||
|
if n_step > 0:
|
|||
|
x3 = coord_x
|
|||
|
y3 = -amplitude/n_step + (y+0.5)*step_y
|
|||
|
x2 = x3 - (x3-x0)*0.32
|
|||
|
y2 = y3
|
|||
|
x1 = x0 + (x3-x0)*0.34
|
|||
|
y1 = y0
|
|||
|
x0 = x3
|
|||
|
y0 = y3
|
|||
|
points.append(['C',[x1, y1, x2, y2, x3, y3]])
|
|||
|
n_step = 0
|
|||
|
amplitude = 0
|
|||
|
elif phase < pi < (phase + d_phase):
|
|||
|
if n_step > 0:
|
|||
|
x3 = coord_x
|
|||
|
y3 = amplitude/n_step + (y+0.5)*step_y
|
|||
|
x2 = x3 - (x3-x0)*0.34
|
|||
|
y2 = y3
|
|||
|
x1 = x0 + (x3-x0)*0.32
|
|||
|
y1 = y0
|
|||
|
x0 = x3
|
|||
|
y0 = y3
|
|||
|
points.append(['C',[x1, y1, x2, y2, x3, y3]])
|
|||
|
n_step = 0
|
|||
|
amplitude = 0
|
|||
|
phase = math.fmod(phase, 2.0*pi)
|
|||
|
#calculate x
|
|||
|
if phase < 0.5*pi < (phase + d_phase):
|
|||
|
coord_x = (x - (phase - 0.5*pi)/d_phase)*step_x
|
|||
|
elif phase < 1.5*pi < (phase + d_phase):
|
|||
|
coord_x = (x - (phase - 1.5*pi)/d_phase)*step_x
|
|||
|
phase += d_phase
|
|||
|
amplitude += (min_amplitude + (max_amplitude - min_amplitude)*matrice[y][x])
|
|||
|
n_step += 1
|
|||
|
#add last point
|
|||
|
if n_step > 0:
|
|||
|
phase = math.fmod(phase, 2.0*pi)
|
|||
|
if (0 < phase < 0.5*pi) or (pi < phase < 1.5*pi):
|
|||
|
x3 = (w-1)*step_x
|
|||
|
y3 = amplitude*math.sin(phase)/n_step + (y+0.5)*step_y
|
|||
|
x2 = x3
|
|||
|
y2 = y3
|
|||
|
x1 = x0 + (x3-x0)*0.33
|
|||
|
y1 = y0
|
|||
|
points.append(['C',[x1, y1, x2, y2, x3, y3]])
|
|||
|
else:
|
|||
|
if coord_x > (w-1)*step_x:
|
|||
|
coord_x = (w-1)*step_x
|
|||
|
x3 = coord_x
|
|||
|
y3 = math.copysign( amplitude , math.sin(phase))/n_step + (y+0.5)*step_y
|
|||
|
x2 = x3 - (x3-x0)*0.32
|
|||
|
y2 = y3
|
|||
|
x1 = x0 + (x3-x0)*0.34
|
|||
|
y1 = y0
|
|||
|
points.append(['C',[x1, y1, x2, y2, x3, y3]])
|
|||
|
if coord_x < (w-1)*step_x:
|
|||
|
x0 = x3
|
|||
|
y0 = y3
|
|||
|
x3 = (w-1)*step_x
|
|||
|
y3 = amplitude*math.sin(phase)/n_step + (y+0.5)*step_y
|
|||
|
x2 = x3
|
|||
|
y2 = y3
|
|||
|
x1 = x0 + (x3-x0)*0.33
|
|||
|
y1 = y0
|
|||
|
points.append(['C',[x1, y1, x2, y2, x3, y3]])
|
|||
|
|
|||
|
#Sinusoidal wave (Brute-force)
|
|||
|
elif self.options.waveform == 'sin_b':
|
|||
|
pi2 = math.pi*2.0
|
|||
|
for y in range(h):
|
|||
|
phase = - pi2/4.0
|
|||
|
for x in range(w):
|
|||
|
period = min_period + (max_period - min_period)*(1-matrice[y][x])
|
|||
|
amplitude = min_amplitude + (max_amplitude - min_amplitude)*matrice[y][x]
|
|||
|
phase += pi2*step_x/period
|
|||
|
phase = math.fmod(phase, pi2)
|
|||
|
if x == 0:
|
|||
|
points.append(['M',[x*step_x, amplitude*math.sin(phase) + (y+0.5)*step_y]])
|
|||
|
else:
|
|||
|
points.append(['L',[x*step_x, amplitude*math.sin(phase) + (y+0.5)*step_y]])
|
|||
|
|
|||
|
#Saw wave
|
|||
|
elif self.options.waveform == 'saw':
|
|||
|
for y in range(h):
|
|||
|
phase = 0.0
|
|||
|
coord_x = 0.0
|
|||
|
amplitude = 0.0
|
|||
|
n_step = 0.0
|
|||
|
for x in range(w):
|
|||
|
period = min_period + (max_period - min_period)*(1-matrice[y][x])
|
|||
|
#period = 1.0/(min_frequency + (max_frequency - min_frequency)*(matrice[y][x]))
|
|||
|
d_phase = 4.0/period*step_x
|
|||
|
if phase > 4.0:
|
|||
|
coord_x = (x - (phase - 4.0)/d_phase)*step_x
|
|||
|
elif phase < 2.0 < (phase + d_phase):
|
|||
|
coord_x = (x - (phase - 2.0)/d_phase)*step_x
|
|||
|
phase = math.fmod(phase, 4.0)
|
|||
|
if (phase < 1.0 < (phase + d_phase)) or (phase < 3.0 < (phase + d_phase)):
|
|||
|
if n_step > 0:
|
|||
|
if coord_x == 0.0:
|
|||
|
points.append(['M',[coord_x, amplitude*square(phase - 1.0)/n_step + (y+0.5)*step_y]])
|
|||
|
else:
|
|||
|
points.append(['L',[coord_x, amplitude*square(phase - 1.0)/n_step + (y+0.5)*step_y]])
|
|||
|
n_step = 0
|
|||
|
amplitude = 0
|
|||
|
phase += d_phase
|
|||
|
n_step += 1.0
|
|||
|
amplitude += (min_amplitude + (max_amplitude - min_amplitude)*matrice[y][x])
|
|||
|
if n_step > 0:
|
|||
|
points.append(['L',[(w-1)*step_x, amplitude*saw(phase - 1.0)/n_step + (y+0.5)*step_y]])
|
|||
|
|
|||
|
#Square wave
|
|||
|
else:
|
|||
|
for y in range(h):
|
|||
|
phase = 0.0
|
|||
|
coord_x = 0.0
|
|||
|
amplitude = 0.0
|
|||
|
n_step = 0
|
|||
|
for x in range(w):
|
|||
|
period = min_period + (max_period - min_period)*(1-matrice[y][x])
|
|||
|
#period = 1.0/(min_frequency + (max_frequency - min_frequency)*(matrice[y][x]))
|
|||
|
d_phase = 4.0/period*step_x
|
|||
|
if phase > 4.0:
|
|||
|
coord_x = (x - (phase - 4.0)/d_phase)*step_x
|
|||
|
elif phase < 2.0 < (phase + d_phase):
|
|||
|
coord_x = (x - (phase - 2.0)/d_phase)*step_x
|
|||
|
phase = math.fmod(phase, 4.0)
|
|||
|
if phase < 1.0 < (phase + d_phase):
|
|||
|
if n_step > 0:
|
|||
|
if coord_x == 0.0:
|
|||
|
points.append(['M',[coord_x, amplitude/n_step + (y+0.5)*step_y]])
|
|||
|
else:
|
|||
|
points.append(['L',[coord_x, -amplitude/n_step + (y+0.5)*step_y]])
|
|||
|
points.append(['L',[coord_x, amplitude/n_step + (y+0.5)*step_y]])
|
|||
|
n_step = 0
|
|||
|
amplitude = 0
|
|||
|
elif phase < 3.0 < (phase + d_phase):
|
|||
|
if n_step > 0:
|
|||
|
if coord_x == 0.0:
|
|||
|
points.append(['M',[coord_x, -amplitude/n_step + (y+0.5)*step_y]])
|
|||
|
else:
|
|||
|
points.append(['L',[coord_x, amplitude/n_step + (y+0.5)*step_y]])
|
|||
|
points.append(['L',[coord_x, -amplitude/n_step + (y+0.5)*step_y]])
|
|||
|
n_step = 0
|
|||
|
amplitude = 0
|
|||
|
phase += d_phase
|
|||
|
n_step += 1
|
|||
|
amplitude += (min_amplitude + (max_amplitude - min_amplitude)*matrice[y][x])
|
|||
|
if n_step > 0:
|
|||
|
if 3.0 > phase > 1.0:
|
|||
|
points.append(['L',[(w-1)*step_x, amplitude/n_step + (y+0.5)*step_y]])
|
|||
|
else:
|
|||
|
points.append(['L',[(w-1)*step_x, -amplitude/n_step + (y+0.5)*step_y]])
|
|||
|
return points
|
|||
|
|
|||
|
def draw_path(self, node, file):
|
|||
|
newpath = etree.Element(inkex.addNS('path','svg'))
|
|||
|
line_width = self.options.line_width
|
|||
|
units = self.options.units
|
|||
|
s = {'stroke': '#000000', 'fill': 'none', 'stroke-linejoin': 'round', 'stroke-linecap': 'round', 'stroke-width': str(self.svg.unittouu(str(line_width) + units))}
|
|||
|
newpath.set('style', str(inkex.Style(s)))
|
|||
|
x = node.get('x')
|
|||
|
y = node.get('y')
|
|||
|
t = 'translate('+ x +','+ y +')'
|
|||
|
newpath.set('transform', t)
|
|||
|
image_w = float(node.get('width'))
|
|||
|
image_h = float(node.get('height'))
|
|||
|
newpath.set('d', str(Path(self.drawfunction(image_w, image_h, file))))
|
|||
|
newpath.set('title', 'Line_Shading')
|
|||
|
node.getparent().append(newpath)
|
|||
|
newpath.set('x', x)
|
|||
|
|
|||
|
def export_png(self, node, file):
|
|||
|
image_w = float(node.get('width'))
|
|||
|
image_h = float(node.get('height'))
|
|||
|
min_period = self.options.min_period
|
|||
|
max_period = self.options.min_period
|
|||
|
poinnt_per_min_period = 8.0
|
|||
|
current_file = self.options.input_file
|
|||
|
h_png = str(self.options.num_lines)
|
|||
|
if min_period < max_period:
|
|||
|
w_png = str(round(poinnt_per_min_period*image_w*float(h_png)/min_period/image_h))
|
|||
|
else:
|
|||
|
w_png = str(round(poinnt_per_min_period*image_w*float(h_png)/max_period/image_h))
|
|||
|
id = node.get('id')
|
|||
|
cmd = ["inkscape", current_file, "--export-filename="+file, "--actions=export-width:"+w_png+";export-height:"+h_png+";export-background:rgb(255, 255, 255);export-background-opacity:255;export-id:"+id]
|
|||
|
#inkex.errormsg(cmd)
|
|||
|
proc = subprocess.Popen(cmd, shell=True, stdout=subprocess.PIPE, stderr=subprocess.PIPE)
|
|||
|
#inkex.debug(proc.communicate())
|
|||
|
#sys.exit(0)
|
|||
|
#return_code = proc.wait()
|
|||
|
#sys.exit(0)
|
|||
|
f = proc.stdout
|
|||
|
err = proc.stderr
|
|||
|
f.close()
|
|||
|
err.close()
|
|||
|
proc.wait()
|
|||
|
#inkex.errormsg(proc.stdout.read())
|
|||
|
|
|||
|
def effect(self):
|
|||
|
image_selected_flag = False
|
|||
|
for id, node in self.svg.selected.items():
|
|||
|
if node.tag == inkex.addNS('image','svg'):
|
|||
|
image_selected_flag = True
|
|||
|
tmp_dir = tempfile.mkdtemp()
|
|||
|
png_temp_file = os.path.join(tmp_dir, "LineShading.png")
|
|||
|
self.export_png(node, png_temp_file)
|
|||
|
self.draw_path(node, png_temp_file)
|
|||
|
shutil.rmtree(tmp_dir)
|
|||
|
if self.options.remove:
|
|||
|
node.getparent().remove(node)
|
|||
|
return
|
|||
|
if not image_selected_flag:
|
|||
|
inkex.errormsg(_("Please select an image"))
|
|||
|
|
|||
|
# Create effect instance and apply it.
|
|||
|
LineShading().run()
|