more options to handle offset paths

extensions/fablabchemnitz/offset_paths/offset_paths.inx

@@ -31,6 +31,8 @@
 			<option value="4">Open Round</option>
 		</param>
 		<param name="copy_org" type="bool" gui-text="Keep original path" gui-description="If enabled, keeps original path as a copy">false</param>
+        <param name="individual" type="bool" gui-text="Separate into individual paths" gui-description="If enabled, each offset curve will be an individual svg element">false</param>
+
         </page>
         <page name="tab_about" gui-text="About">
             <label appearance="header">Offset Paths</label>

extensions/fablabchemnitz/offset_paths/offset_paths.py

@@ -15,6 +15,7 @@ import inkex
 import math
 from inkex.paths import CubicSuperPath
 import re
+import copy
 import pyclipper
 
 class OffsetPaths(inkex.EffectExtension):
@@ -25,89 +26,104 @@ class OffsetPaths(inkex.EffectExtension):
         pars.add_argument("--offset_count", type=int, default=1, help="Number of offset paths")
         pars.add_argument("--offset", type=float, default=1.000, help="Offset amount")
         pars.add_argument("--init_offset", type=float, default=0.000, help="Initial Offset Amount")
-        pars.add_argument("--copy_org", type=inkex.Boolean, default=True, help="copy original path")
         pars.add_argument("--offset_increase", type=float, default=0.000, help="Offset increase between iterations")
         pars.add_argument("--jointype", default="2", help="Join type")
         pars.add_argument("--endtype", default="3", help="End type")
         pars.add_argument("--miterlimit", type=float, default=3.0, help="Miter limit")
         pars.add_argument("--clipperscale", type=int, default=1024, help="Scaling factor. Should be a multiplicator of 2, like 2^4=16 or 2^10=1024. The higher the scale factor the higher the quality.")
+        pars.add_argument("--copy_org", type=inkex.Boolean, default=True, help="copy original path")
+        pars.add_argument("--individual", type=inkex.Boolean, default=True, help="Separate into individual paths")
+
+        
         
     def effect(self):
         unit_factor = 1.0 / self.svg.uutounit(1.0, self.options.unit)
-        paths = self.svg.selection.filter(inkex.PathElement).values()
-        count = sum(1 for path in paths)
-        paths = self.svg.selection.filter(inkex.PathElement).values() #we need to call this twice because the sum function consumes the generator
+        pathElements = self.svg.selection.filter(inkex.PathElement).values()
+        count = sum(1 for pathElement in pathElements)
+        pathElements = self.svg.selection.filter(inkex.PathElement).values() #we need to call this twice because the sum function consumes the generator
         if count == 0:
             inkex.errormsg("No paths selected.")
             exit()
-        for path in paths:
-            if path.tag == inkex.addNS('path','svg'):
-                p = CubicSuperPath(path.get('d'))
+        for pathElement in pathElements:
+            csp = CubicSuperPath(pathElement.get('d'))
 
-                scale_factor = self.options.clipperscale # 2 ** 32 = 1024 - see also https://github.com/fonttools/pyclipper/wiki/Deprecating-SCALING_FACTOR
+            scale_factor = self.options.clipperscale # 2 ** 32 = 1024 - see also https://github.com/fonttools/pyclipper/wiki/Deprecating-SCALING_FACTOR
 
-                pco = pyclipper.PyclipperOffset(self.options.miterlimit)
+            pco = pyclipper.PyclipperOffset(self.options.miterlimit)
+            
+            JT = None
+            if self.options.jointype == "0":
+                JT = pyclipper.JT_SQUARE
+            elif self.options.jointype == "1":
+                JT = pyclipper.JT_ROUND
+            elif self.options.jointype == "2":
+                JT = pyclipper.JT_MITER
                 
-                JT = None
-                if self.options.jointype == "0":
-                    JT = pyclipper.JT_SQUARE
-                elif self.options.jointype == "1":
-                    JT = pyclipper.JT_ROUND
-                elif self.options.jointype == "2":
-                    JT = pyclipper.JT_MITER
-                    
-                ET = None
-                if self.options.endtype == "0":
-                    ET = pyclipper.ET_CLOSEDPOLYGON
-                elif self.options.endtype == "1":
-                    ET = pyclipper.ET_CLOSEDLINE
-                elif self.options.endtype == "2":
-                    ET = pyclipper.ET_OPENBUTT
-                elif self.options.endtype == "3":
-                    ET = pyclipper.ET_OPENSQUARE
-                elif self.options.endtype == "4":                 
-                    ET = pyclipper.ET_OPENROUND
-                
-                new = []
+            ET = None
+            if self.options.endtype == "0":
+                ET = pyclipper.ET_CLOSEDPOLYGON
+            elif self.options.endtype == "1":
+                ET = pyclipper.ET_CLOSEDLINE
+            elif self.options.endtype == "2":
+                ET = pyclipper.ET_OPENBUTT
+            elif self.options.endtype == "3":
+                ET = pyclipper.ET_OPENSQUARE
+            elif self.options.endtype == "4":                 
+                ET = pyclipper.ET_OPENROUND
+            
+            newPaths = []
 
-                # load in initial paths
-                for sub in p:
-                    sub_simple = []
-                    for item in sub:
-                        itemx = [float(z) * scale_factor for z in item[1]]
-                        sub_simple.append(itemx)
-                    pco.AddPath(sub_simple, JT, ET)
+            # load in initial paths
+            for subPath in csp:
+                sub_simple = []
+                for item in subPath:
+                    itemx = [float(z) * scale_factor for z in item[1]]
+                    sub_simple.append(itemx)
+                pco.AddPath(sub_simple, JT, ET)
 
-                # calculate offset paths for different offset amounts
-                offset_list = []
-                offset_list.append(self.options.init_offset * unit_factor)
-                for i in range(0, self.options.offset_count):
-                    ofs_increase = +math.pow(float(i) * self.options.offset_increase * unit_factor, 2)
-                    if self.options.offset_increase < 0:
-                        ofs_increase = -ofs_increase
-                    offset_list.append(offset_list[0] + float(i) * self.options.offset * unit_factor + ofs_increase * unit_factor)
+            # calculate offset paths for different offset amounts
+            offset_list = []
+            offset_list.append(self.options.init_offset * unit_factor)
+            for i in range(0, self.options.offset_count):
+                ofs_increase = +math.pow(float(i) * self.options.offset_increase * unit_factor, 2)
+                if self.options.offset_increase < 0:
+                    ofs_increase = -ofs_increase
+                offset_list.append(offset_list[0] + float(i) * self.options.offset * unit_factor + ofs_increase * unit_factor)
 
-                solutions = []
-                for offset in offset_list:
-                    solution = pco.Execute(offset * scale_factor)
-                    solutions.append(solution)
-                    if len(solution)<=0:
-                        continue # no more loops to go, will provide no results.
+            solutions = []
+            for offset in offset_list:
+                solution = pco.Execute(offset * scale_factor)
+                solutions.append(solution)
+                if len(solution)<=0:
+                    continue # no more loops to go, will provide no results.
 
-                # re-arrange solutions to fit expected format & add to array
-                for solution in solutions:
-                    for sol in solution:
-                        solx = [[float(s[0]) / scale_factor, float(s[1]) / scale_factor] for s in sol]
-                        sol_p = [[a, a, a] for a in solx]
-                        sol_p.append(sol_p[0][:])
-                        new.append(sol_p)
+            # re-arrange solutions to fit expected format & add to array
+            for solution in solutions:
+                for sol in solution:
+                    solx = [[float(s[0]) / scale_factor, float(s[1]) / scale_factor] for s in sol]
+                    sol_p = [[a, a, a] for a in solx]
+                    sol_p.append(sol_p[0][:])
+                    if sol_p not in newPaths:
+                        newPaths.append(sol_p)
 
-                # add old, just to keep (make optional!)
-                if self.options.copy_org:
-                    for sub in p:
-                        new.append(sub)
-
-                path.set('d', CubicSuperPath(new))
+            if self.options.individual is True:
+                parent = pathElement.getparent()
+                idx = parent.index(pathElement)
+                idSuffix = 0
+                for newPath in newPaths:
+                    copyElement = copy.copy(pathElement)
+                    elementId = copyElement.get('id')
+                    copyElement.path = CubicSuperPath(newPath)
+                    copyElement.set('id', elementId + str(idSuffix))
+                    parent.insert(idx, copyElement)
+                    idSuffix += 1
+                if self.options.copy_org is False:
+                    pathElement.delete()
+            else:
+                if self.options.copy_org is True:
+                    for subPath in csp:
+                        newPaths.append(subPath)
+                pathElement.set('d', CubicSuperPath(newPaths))
 
 if __name__ == '__main__':
     OffsetPaths().run()