#!/usr/bin/env python # coding=utf-8 # # Copyright (C) 2005,2007,2008 Aaron Spike, aaron@ekips.org # Copyright (C) 2008,2010 Alvin Penner, penner@vaxxine.com # # 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., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. # """ This file output script for Inkscape creates a AutoCAD R14 DXF file. The spec can be found here: http://www.autodesk.com/techpubs/autocad/acadr14/dxf/index.htm. File history: - template dxf_outlines.dxf added Feb 2008 by Alvin Penner - ROBO-Master output option added Aug 2008 - ROBO-Master multispline output added Sept 2008 - LWPOLYLINE output modification added Dec 2008 - toggle between LINE/LWPOLYLINE added Jan 2010 - support for transform elements added July 2010 - support for layers added July 2010 - support for rectangle added Dec 2010 """ from __future__ import print_function import inkex from inkex import ( colors, bezier, Transform, Group, Layer, Use, PathElement, Rectangle, Line, Circle, Ellipse, ) from inkex.localization import inkex_gettext as _ def get_matrix(u, i, j): if j == i + 2: return ( (u[i] - u[i - 1]) * (u[i] - u[i - 1]) / (u[i + 2] - u[i - 1]) / (u[i + 1] - u[i - 1]) ) elif j == i + 1: return ( (u[i] - u[i - 1]) * (u[i + 2] - u[i]) / (u[i + 2] - u[i - 1]) + (u[i + 1] - u[i]) * (u[i] - u[i - 2]) / (u[i + 1] - u[i - 2]) ) / (u[i + 1] - u[i - 1]) elif j == i: return ( (u[i + 1] - u[i]) * (u[i + 1] - u[i]) / (u[i + 1] - u[i - 2]) / (u[i + 1] - u[i - 1]) ) else: return 0 def get_fit(u, csp, col): return ( (1 - u) ** 3 * csp[0][col] + 3 * (1 - u) ** 2 * u * csp[1][col] + 3 * (1 - u) * u**2 * csp[2][col] + u**3 * csp[3][col] ) class DxfOutlines(inkex.OutputExtension): def add_arguments(self, pars): pars.add_argument("--tab") pars.add_argument("-R", "--ROBO", type=inkex.Boolean, default=False) pars.add_argument("-P", "--POLY", type=inkex.Boolean, default=False) pars.add_argument( "--unit_from_document", type=inkex.Boolean, default=True ) # px pars.add_argument("--units", default="px") # px pars.add_argument("--encoding", dest="char_encode", default="latin_1") pars.add_argument("--layer_option", default="all") pars.add_argument("--layer_name") self.dxf = [] self.handle = 255 # handle for DXF ENTITY self.layers = ["0"] self.layer = "0" # mandatory layer self.layernames = [] self.csp_old = [[0.0, 0.0]] * 4 # previous spline self.d = [0.0] # knot vector self.poly = [[0.0, 0.0]] # LWPOLYLINE data def save(self, stream): stream.write(b"".join(self.dxf)) def dxf_add(self, str): self.dxf.append(str.encode(self.options.char_encode)) def dxf_line(self, csp): """Draw a line in the DXF format""" self.handle += 1 self.dxf_add( " 0\nLINE\n 5\n%x\n100\nAcDbEntity\n 8\n%s\n 62\n%d\n100\nAcDbLine\n" % (self.handle, self.layer, self.color) ) self.dxf_add( " 10\n%f\n 20\n%f\n 30\n0.0\n 11\n%f\n 21\n%f\n 31\n0.0\n" % (csp[0][0], csp[0][1], csp[1][0], csp[1][1]) ) def LWPOLY_line(self, csp): if ( abs(csp[0][0] - self.poly[-1][0]) > 0.0001 or abs(csp[0][1] - self.poly[-1][1]) > 0.0001 or self.color_LWPOLY != self.color ): # THIS LINE IS NEW self.LWPOLY_output() # terminate current polyline self.poly = [csp[0]] # initiallize new polyline self.color_LWPOLY = self.color self.layer_LWPOLY = self.layer self.poly.append(csp[1]) def LWPOLY_output(self): if len(self.poly) == 1: return self.handle += 1 closed = 1 if ( abs(self.poly[0][0] - self.poly[-1][0]) > 0.0001 or abs(self.poly[0][1] - self.poly[-1][1]) > 0.0001 ): closed = 0 self.dxf_add( " 0\nLWPOLYLINE\n 5\n%x\n100\nAcDbEntity\n 8\n%s\n 62\n%d\n100\nAcDbPolyline\n 90\n%d\n 70\n%d\n" % ( self.handle, self.layer_LWPOLY, self.color_LWPOLY, len(self.poly) - closed, closed, ) ) for i in range(len(self.poly) - closed): self.dxf_add( " 10\n%f\n 20\n%f\n 30\n0.0\n" % (self.poly[i][0], self.poly[i][1]) ) def dxf_spline(self, csp): knots = 8 ctrls = 4 self.handle += 1 self.dxf_add( " 0\nSPLINE\n 5\n%x\n100\nAcDbEntity\n 8\n%s\n 62\n%d\n100\nAcDbSpline\n" % (self.handle, self.layer, self.color) ) self.dxf_add(" 70\n8\n 71\n3\n 72\n%d\n 73\n%d\n 74\n0\n" % (knots, ctrls)) for i in range(2): for j in range(4): self.dxf_add(" 40\n%d\n" % i) for i in csp: self.dxf_add(" 10\n%f\n 20\n%f\n 30\n0.0\n" % (i[0], i[1])) def ROBO_spline(self, csp): """this spline has zero curvature at the endpoints, as in ROBO-Master""" if ( abs(csp[0][0] - self.csp_old[3][0]) > 0.0001 or abs(csp[0][1] - self.csp_old[3][1]) > 0.0001 or abs( (csp[1][1] - csp[0][1]) * (self.csp_old[3][0] - self.csp_old[2][0]) - (csp[1][0] - csp[0][0]) * (self.csp_old[3][1] - self.csp_old[2][1]) ) > 0.001 ): self.ROBO_output() # terminate current spline self.xfit = [csp[0][0]] # initiallize new spline self.yfit = [csp[0][1]] self.d = [0.0] self.color_ROBO = self.color self.layer_ROBO = self.layer self.xfit += 3 * [0.0] self.yfit += 3 * [0.0] self.d += 3 * [0.0] for i in range(1, 4): j = len(self.d) + i - 4 self.xfit[j] = get_fit(i / 3.0, csp, 0) self.yfit[j] = get_fit(i / 3.0, csp, 1) self.d[j] = self.d[j - 1] + bezier.pointdistance( (self.xfit[j - 1], self.yfit[j - 1]), (self.xfit[j], self.yfit[j]) ) self.csp_old = csp def ROBO_output(self): try: import numpy from numpy.linalg import solve except ImportError: inkex.errormsg( _( "Failed to import the numpy or numpy.linalg modules. " "These modules are required by the ROBO option." "Please install them and try again." ) ) return if len(self.d) == 1: return fits = len(self.d) ctrls = fits + 2 knots = ctrls + 4 self.xfit += 2 * [0.0] # pad with 2 endpoint constraints self.yfit += 2 * [0.0] self.d += 6 * [0.0] # pad with 3 duplicates at each end self.d[fits + 2] = self.d[fits + 1] = self.d[fits] = self.d[fits - 1] solmatrix = numpy.zeros((ctrls, ctrls), dtype=float) for i in range(fits): solmatrix[i, i] = get_matrix(self.d, i, i) solmatrix[i, i + 1] = get_matrix(self.d, i, i + 1) solmatrix[i, i + 2] = get_matrix(self.d, i, i + 2) solmatrix[fits, 0] = self.d[2] / self.d[fits - 1] # curvature at start = 0 solmatrix[fits, 1] = -(self.d[1] + self.d[2]) / self.d[fits - 1] solmatrix[fits, 2] = self.d[1] / self.d[fits - 1] solmatrix[fits + 1, fits - 1] = (self.d[fits - 1] - self.d[fits - 2]) / self.d[ fits - 1 ] # curvature at end = 0 solmatrix[fits + 1, fits] = ( self.d[fits - 3] + self.d[fits - 2] - 2 * self.d[fits - 1] ) / self.d[fits - 1] solmatrix[fits + 1, fits + 1] = (self.d[fits - 1] - self.d[fits - 3]) / self.d[ fits - 1 ] xctrl = solve(solmatrix, self.xfit) yctrl = solve(solmatrix, self.yfit) self.handle += 1 self.dxf_add( " 0\nSPLINE\n 5\n%x\n100\nAcDbEntity\n 8\n%s\n 62\n%d\n100\nAcDbSpline\n" % (self.handle, self.layer_ROBO, self.color_ROBO) ) self.dxf_add( " 70\n0\n 71\n3\n 72\n%d\n 73\n%d\n 74\n%d\n" % (knots, ctrls, fits) ) for i in range(knots): self.dxf_add(" 40\n%f\n" % self.d[i - 3]) for i in range(ctrls): self.dxf_add(" 10\n%f\n 20\n%f\n 30\n0.0\n" % (xctrl[i], yctrl[i])) for i in range(fits): self.dxf_add(" 11\n%f\n 21\n%f\n 31\n0.0\n" % (self.xfit[i], self.yfit[i])) def process_shape(self, node, mat): rgb = (0, 0, 0) style = node.style("stroke") if style is not None and isinstance(style, inkex.Color): rgb = style.to_rgb() hsl = colors.rgb_to_hsl(rgb[0] / 255.0, rgb[1] / 255.0, rgb[2] / 255.0) self.color = 7 # default is blac if hsl[2]: self.color = 1 + (int(6 * hsl[0] + 0.5) % 6) # use 6 hues if not isinstance(node, (PathElement, Rectangle, Line, Circle, Ellipse)): return # Transforming /after/ superpath is more reliable than before # because of some issues with arcs in transformations for sub in node.path.to_superpath().transform(Transform(mat) @ node.transform): for i in range(len(sub) - 1): s = sub[i] e = sub[i + 1] if s[1] == s[2] and e[0] == e[1]: if self.options.POLY: self.LWPOLY_line([s[1], e[1]]) else: self.dxf_line([s[1], e[1]]) elif self.options.ROBO: self.ROBO_spline([s[1], s[2], e[0], e[1]]) else: self.dxf_spline([s[1], s[2], e[0], e[1]]) def process_clone(self, node): """Process a clone node, looking for internal paths""" trans = node.get("transform") x = node.get("x") y = node.get("y") mat = Transform([[1.0, 0.0, 0.0], [0.0, 1.0, 0.0]]) if trans: mat @= Transform(trans) if x: mat @= Transform([[1.0, 0.0, float(x)], [0.0, 1.0, 0.0]]) if y: mat @= Transform([[1.0, 0.0, 0.0], [0.0, 1.0, float(y)]]) # push transform if trans or x or y: self.groupmat.append(Transform(self.groupmat[-1]) @ mat) # get referenced node refid = node.get("xlink:href") refnode = self.svg.getElementById(refid[1:]) if refnode is not None: if isinstance(refnode, Group): self.process_group(refnode) elif isinstance(refnode, Use): self.process_clone(refnode) else: self.process_shape(refnode, self.groupmat[-1]) # pop transform if trans or x or y: self.groupmat.pop() def process_group(self, group): """Process group elements""" if isinstance(group, Layer): style = group.style if ( style("display") == "none" and self.options.layer_option and self.options.layer_option == "visible" ): return layer = group.label if self.options.layer_name and self.options.layer_option == "name": if not layer.lower() in self.options.layer_name: return layer = layer.replace(" ", "_") if layer in self.layers: self.layer = layer trans = group.get("transform") if trans: self.groupmat.append(Transform(self.groupmat[-1]) @ Transform(trans)) for node in group: try: if isinstance(node, Group): self.process_group(node) elif isinstance(node, Use): self.process_clone(node) else: self.process_shape(node, self.groupmat[-1]) except RecursionError as e: raise inkex.AbortExtension( _( 'Too many nested groups. Please use the "Deep Ungroup" extension first.' ) ) from e # pylint: disable=line-too-long if trans: self.groupmat.pop() def effect(self): # Warn user if name match field is empty if ( self.options.layer_option and self.options.layer_option == "name" and not self.options.layer_name ): return inkex.errormsg( _( "Error: Field 'Layer match name' must be filled when using " "'By name match' option" ) ) # Split user layer data into a list: "layerA,layerb,LAYERC" becomes ["layera", "layerb", "layerc"] if self.options.layer_name: self.options.layer_name = self.options.layer_name.lower().split(",") # References: Minimum Requirements for Creating a DXF File of a 3D Model By Paul Bourke # NURB Curves: A Guide for the Uninitiated By Philip J. Schneider # The NURBS Book By Les Piegl and Wayne Tiller (Springer, 1995) # self.dxf_add("999\nDXF created by Inkscape\n") # Some programs do not take comments in DXF files (KLayout 0.21.12 for example) if self.options.unit_from_document: unit = self.svg.document_unit else: unit = self.options.units with open(self.get_resource("dxf14_header.txt"), "r") as fhl: header = fhl.read() unit_map = {"px": 0, "in": 1, "ft": 2, "mm": 4, "cm": 5, "m": 6} header = header.replace("", str(unit_map[unit])) self.dxf_add(header) for node in self.svg.xpath("//svg:g"): if isinstance(node, Layer): layer = node.label self.layernames.append(layer.lower()) if ( self.options.layer_name and self.options.layer_option and self.options.layer_option == "name" and not layer.lower() in self.options.layer_name ): continue layer = layer.replace(" ", "_") if layer and layer not in self.layers: self.layers.append(layer) self.dxf_add( " 2\nLAYER\n 5\n2\n100\nAcDbSymbolTable\n 70\n%s\n" % len(self.layers) ) for i in range(len(self.layers)): self.dxf_add( " 0\nLAYER\n 5\n%x\n100\nAcDbSymbolTableRecord\n100\nAcDbLayerTableRecord\n 2\n%s\n 70\n0\n 6\nCONTINUOUS\n" % (i + 80, self.layers[i]) ) with open(self.get_resource("dxf14_style.txt"), "r") as fhl: self.dxf_add(fhl.read()) # Set toplevel transform scale = self.svg.inkscape_scale self.groupmat = [ [[scale, 0.0, 0.0], [0.0, -scale, self.svg.viewbox_height * scale]] ] self.process_group(self.svg) if self.options.ROBO: self.ROBO_output() if self.options.POLY: self.LWPOLY_output() with open(self.get_resource("dxf14_footer.txt"), "r") as fhl: self.dxf_add(fhl.read()) # Warn user if layer data seems wrong if ( self.options.layer_name and self.options.layer_option and self.options.layer_option == "name" ): for layer in self.options.layer_name: if layer not in self.layernames: inkex.errormsg(_("Warning: Layer '{}' not found!").format(layer)) if __name__ == "__main__": DxfOutlines().run()