voronoi2svg.py revision b93ce4197e7f5026a1c8deeb79cbd00aa3f86d91
#!/usr/bin/env python
"""
voronoi2svg.py
Create Voronoi diagram from seeds (midpoints of selected objects)
- Voronoi Diagram algorithm and C code by Steven Fortune, 1987, http://ect.bell-labs.com/who/sjf/
- Python translation to file voronoi.py by Bill Simons, 2005, http://www.oxfish.com/
Copyright (C) 2011 Vincent Nivoliers and contributors
Contributors
~suv, <suv-sf@users.sf.net>
This program 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 2 of the License, or
(at your option) any later version.
This program 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 this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
"""
import sys, os
import inkex, simplestyle, simplepath, simpletransform
import voronoi
import gettext
_ = gettext.gettext
class Point:
def __init__(self,x,y):
self.x = x
self.y = y
class Voronoi2svg(inkex.Effect):
def __init__(self):
inkex.Effect.__init__(self)
#{{{ Additional options
self.OptionParser.add_option(
"--tab",
action="store",
type="string",
dest="tab")
self.OptionParser.add_option(
'--diagram-type',
action = 'store',
type = 'choice', choices=['Voronoi','Delaunay','Both'],
default = 'Voronoi',
dest='diagramType',
help = 'Defines the type of the diagram')
self.OptionParser.add_option(
'--clip-box',
action = 'store',
type = 'choice', choices=['Page','Automatic from seeds'],
default = 'Page',
dest='clipBox',
help = 'Defines the bounding box of the Voronoi diagram')
self.OptionParser.add_option(
'--show-clip-box',
action = 'store',
type = 'inkbool',
default = False,
dest='showClipBox',
help = 'Set this to true to write the bounding box')
#}}}
#{{{ Clipping a line by a bounding box
def dot(self,x,y):
return x[0]*y[0] + x[1]*y[1]
def intersectLineSegment(self,line,v1,v2):
s1 = self.dot(line,v1) - line[2]
s2 = self.dot(line,v2) - line[2]
if s1*s2 > 0:
return (0,0,False)
else:
tmp = self.dot(line,v1)-self.dot(line,v2)
if tmp == 0:
return(0,0,False)
u = (line[2]-self.dot(line,v2))/tmp
v = 1-u
return (u*v1[0]+v*v2[0],u*v1[1]+v*v2[1],True)
def clipEdge(self,vertices, lines, edge, bbox):
#bounding box corners
bbc = []
bbc.append((bbox[0],bbox[2]))
bbc.append((bbox[1],bbox[2]))
bbc.append((bbox[1],bbox[3]))
bbc.append((bbox[0],bbox[3]))
#record intersections of the line with bounding box edges
line = (lines[edge[0]])
interpoints = []
for i in range(4):
p = self.intersectLineSegment(line,bbc[i],bbc[(i+1)%4])
if (p[2]):
interpoints.append(p)
#if the edge has no intersection, return empty intersection
if (len(interpoints)<2):
return []
if (len(interpoints)>2): #happens when the edge crosses the corner of the box
interpoints = list(set(interpoints)) #remove doubles
#points of the edge
v1 = vertices[edge[1]]
interpoints.append((v1[0],v1[1],False))
v2 = vertices[edge[2]]
interpoints.append((v2[0],v2[1],False))
#sorting the points in the widest range to get them in order on the line
minx = interpoints[0][0]
maxx = interpoints[0][0]
miny = interpoints[0][1]
maxy = interpoints[0][1]
for point in interpoints:
minx = min(point[0],minx)
maxx = max(point[0],maxx)
miny = min(point[1],miny)
maxy = max(point[1],maxy)
if (maxx-minx) > (maxy-miny):
interpoints.sort()
else:
interpoints.sort(key=lambda pt: pt[1])
start = []
inside = False #true when the part of the line studied is in the clip box
startWrite = False #true when the part of the line is in the edge segment
for point in interpoints:
if point[2]: #The point is a bounding box intersection
if inside:
if startWrite:
return [[start[0],start[1]],[point[0],point[1]]]
else:
return []
else:
if startWrite:
start = point
inside = not inside
else: #The point is a segment endpoint
if startWrite:
if inside:
#a vertex ends the line inside the bounding box
return [[start[0],start[1]],[point[0],point[1]]]
else:
return []
else:
if inside:
start = point
startWrite = not startWrite
#}}}
#{{{ Transformation helpers
def invertTransform(self,mat):
det = mat[0][0]*mat[1][1] - mat[0][1]*mat[1][0]
if det !=0: #det is 0 only in case of 0 scaling
#invert the rotation/scaling part
a11 = mat[1][1]/det
a12 = -mat[0][1]/det
a21 = -mat[1][0]/det
a22 = mat[0][0]/det
#invert the translational part
a13 = -(a11*mat[0][2] + a12*mat[1][2])
a23 = -(a21*mat[0][2] + a22*mat[1][2])
return [[a11,a12,a13],[a21,a22,a23]]
else:
return[[0,0,-mat[0][2]],[0,0,-mat[1][2]]]
def getGlobalTransform(self,node):
parent = node.getparent()
myTrans = simpletransform.parseTransform(node.get('transform'))
if myTrans:
if parent is not None:
parentTrans = self.getGlobalTransform(parent)
if parentTrans:
return simpletransform.composeTransform(parentTrans,myTrans)
else:
return myTrans
else:
if parent is not None:
return self.getGlobalTransform(parent)
else:
return None
#}}}
def effect(self):
#{{{ Check that elements have been selected
if len(self.options.ids) == 0:
inkex.errormsg(_("Please select objects!"))
return
#}}}
#{{{ Drawing styles
linestyle = {
'stroke' : '#000000',
'linewidth' : '1',
'fill' : 'none'
}
facestyle = {
'stroke' : '#ff0000',
'linewidth' : '1',
'fill' : 'none'
}
#}}}
#{{{ Handle the transformation of the current group
parentGroup = self.getParentNode(self.selected[self.options.ids[0]])
trans = self.getGlobalTransform(parentGroup)
invtrans = None
if trans:
invtrans = self.invertTransform(trans)
#}}}
#{{{ Recovery of the selected objects
pts = []
nodes = []
seeds = []
for id in self.options.ids:
node = self.selected[id]
nodes.append(node)
bbox = simpletransform.computeBBox([node])
if bbox:
cx = 0.5*(bbox[0]+bbox[1])
cy = 0.5*(bbox[2]+bbox[3])
pt = [cx,cy]
if trans:
simpletransform.applyTransformToPoint(trans,pt)
pts.append(Point(pt[0],pt[1]))
seeds.append(Point(cx,cy))
#}}}
#{{{ Creation of groups to store the result
if self.options.diagramType != 'Delaunay':
# Voronoi
groupVoronoi = inkex.etree.SubElement(parentGroup,inkex.addNS('g','svg'))
groupVoronoi.set(inkex.addNS('label', 'inkscape'), 'Voronoi')
if invtrans:
simpletransform.applyTransformToNode(invtrans,groupVoronoi)
if self.options.diagramType != 'Voronoi':
# Delaunay
groupDelaunay = inkex.etree.SubElement(parentGroup,inkex.addNS('g','svg'))
groupDelaunay.set(inkex.addNS('label', 'inkscape'), 'Delaunay')
#}}}
#{{{ Clipping box handling
if self.options.diagramType != 'Delaunay':
#Clipping bounding box creation
gBbox = simpletransform.computeBBox(nodes)
#Clipbox is the box to which the Voronoi diagram is restricted
clipBox = ()
if self.options.clipBox == 'Page':
svg = self.document.getroot()
w = inkex.unittouu(svg.get('width'))
h = inkex.unittouu(svg.get('height'))
clipBox = (0,w,0,h)
else:
clipBox = (2*gBbox[0]-gBbox[1],
2*gBbox[1]-gBbox[0],
2*gBbox[2]-gBbox[3],
2*gBbox[3]-gBbox[2])
#Safebox adds points so that no Voronoi edge in clipBox is infinite
safeBox = (2*clipBox[0]-clipBox[1],
2*clipBox[1]-clipBox[0],
2*clipBox[2]-clipBox[3],
2*clipBox[3]-clipBox[2])
pts.append(Point(safeBox[0],safeBox[2]))
pts.append(Point(safeBox[1],safeBox[2]))
pts.append(Point(safeBox[1],safeBox[3]))
pts.append(Point(safeBox[0],safeBox[3]))
if self.options.showClipBox:
#Add the clip box to the drawing
rect = inkex.etree.SubElement(groupVoronoi,inkex.addNS('rect','svg'))
rect.set('x',str(clipBox[0]))
rect.set('y',str(clipBox[2]))
rect.set('width',str(clipBox[1]-clipBox[0]))
rect.set('height',str(clipBox[3]-clipBox[2]))
rect.set('style',simplestyle.formatStyle(linestyle))
#}}}
#{{{ Voronoi diagram generation
if self.options.diagramType != 'Delaunay':
vertices,lines,edges = voronoi.computeVoronoiDiagram(pts)
for edge in edges:
line = edge[0]
vindex1 = edge[1]
vindex2 = edge[2]
if (vindex1 <0) or (vindex2 <0):
continue # infinite lines have no need to be handled in the clipped box
else:
segment = self.clipEdge(vertices,lines,edge,clipBox)
#segment = [vertices[vindex1],vertices[vindex2]] # deactivate clipping
if len(segment)>1:
v1 = segment[0]
v2 = segment[1]
cmds = [['M',[v1[0],v1[1]]],['L',[v2[0],v2[1]]]]
path = inkex.etree.Element(inkex.addNS('path','svg'))
path.set('d',simplepath.formatPath(cmds))
path.set('style',simplestyle.formatStyle(linestyle))
groupVoronoi.append(path)
if self.options.diagramType != 'Voronoi':
triangles = voronoi.computeDelaunayTriangulation(seeds)
for triangle in triangles:
p1 = seeds[triangle[0]]
p2 = seeds[triangle[1]]
p3 = seeds[triangle[2]]
cmds = [['M',[p1.x,p1.y]],
['L',[p2.x,p2.y]],
['L',[p3.x,p3.y]],
['Z',[]]]
path = inkex.etree.Element(inkex.addNS('path','svg'))
path.set('d',simplepath.formatPath(cmds))
path.set('style',simplestyle.formatStyle(facestyle))
groupDelaunay.append(path)
#}}}
if __name__ == "__main__":
e = Voronoi2svg()
e.affect()
# vim: expandtab shiftwidth=2 tabstop=2 softtabstop=2 fileencoding=utf-8 textwidth=99