From: alvinpenner Date: Sat, 6 Sep 2008 13:20:33 +0000 (+0000) Subject: add support for ROBO-Master multi-spline X-Git-Url: https://git.tokkee.org/?a=commitdiff_plain;h=28cbc6fdfabf47e2e3a31e12bcfd16365b375ef5;p=inkscape.git add support for ROBO-Master multi-spline --- diff --git a/share/extensions/dxf_outlines.py b/share/extensions/dxf_outlines.py index f5f9ce19f..bd7e91822 100755 --- a/share/extensions/dxf_outlines.py +++ b/share/extensions/dxf_outlines.py @@ -5,6 +5,7 @@ Copyright (C) 2008 Alvin Penner, penner@vaxxine.com - template dxf_outlines.dxf added Feb 2008 by Alvin Penner - ROBO-Master output option added Aug 2008 by Alvin Penner +- ROBO-Master multispline output added Sept 2008 by Alvin Penner 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 @@ -26,8 +27,8 @@ try: from numpy import * from numpy.linalg import solve except: - inkex.errormsg(_("Failed to import the numpy or numpy.linalg modules. These modules are required by this extension. Please install them and try again.")) - sys.exit() + inkex.errormsg("Failed to import the numpy or numpy.linalg modules. These modules are required by this extension. Please install them and try again.") + inkex.sys.exit() def pointdistance((x1,y1),(x2,y2)): return math.sqrt(((x2 - x1) ** 2) + ((y2 - y1) ** 2)) @@ -35,12 +36,24 @@ def pointdistance((x1,y1),(x2,y2)): 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] +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 + class MyEffect(inkex.Effect): def __init__(self): inkex.Effect.__init__(self) self.OptionParser.add_option("-R", "--ROBO", action="store", type="string", dest="ROBO") self.dxf = [] - self.handle = 255 # initiallize handle for DXF ENTITY + self.handle = 255 # handle for DXF ENTITY + self.csp_old = [[0.0,0.0]]*4 # previous spline + self.d = array([0], float) # knot vector def output(self): print ''.join(self.dxf) def dxf_add(self, str): @@ -54,59 +67,59 @@ class MyEffect(inkex.Effect): self.dxf_add(" 0\nSPLINE\n 5\n%x\n100\nAcDbEntity\n 8\n0\n100\nAcDbSpline\n" % self.handle) 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): + 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 - knots = 10 - ctrls = 6 - fits = 4 - xfit = zeros((6), dtype=float64) - xfit[0] = csp[0][0] - xfit[1] = get_fit(.333, csp, 0) - xfit[2] = get_fit(.667, csp, 0) - xfit[3] = csp[3][0] - yfit = zeros((6), dtype=float64) - yfit[0] = csp[0][1] - yfit[1] = get_fit(.333, csp, 1) - yfit[2] = get_fit(.667, csp, 1) - yfit[3] = csp[3][1] - d1 = pointdistance((xfit[0],yfit[0]),(xfit[1],yfit[1])) - d2 = pointdistance((xfit[1],yfit[1]),(xfit[2],yfit[2])) - d3 = pointdistance((xfit[2],yfit[2]),(xfit[3],yfit[3])) - u1 = d1/(d1 + d2 + d3) - u2 = (d1 + d2)/(d1 + d2 + d3) - solmatrix = zeros((6,6), dtype=float64) - solmatrix[0,0] = 1 - solmatrix[1,1] = (1 - u1/u2)**2 - solmatrix[1,2] = (2*u2 - u1*u2 - u1)*u1/u2/u2 - solmatrix[1,3] = u1*u1/u2 - solmatrix[2,2] = (1 - u2)**2/(1 - u1) - solmatrix[2,3] = (2*u2 - u1*u2 - u1)*(1 - u2)/(1 - u1)/(1 - u1) - solmatrix[2,4] = ((u2 - u1)/(1 - u1))**2 - solmatrix[3,5] = 1 - solmatrix[4,0] = u2 - solmatrix[4,1] = -u1 - u2 - solmatrix[4,2] = u1 - solmatrix[5,3] = 1 - u2 - solmatrix[5,4] = u1 + u2 - 2 - solmatrix[5,5] = 1 - u1 - xctrl = solve(solmatrix, xfit) - yctrl = solve(solmatrix, yfit) + if (abs(csp[0][0] - self.csp_old[3][0]) > .0001 + or abs(csp[0][1] - self.csp_old[3][1]) > .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])) > .001): + self.ROBO_output() # terminate current spline + self.xfit = array([csp[0][0]], float) # initiallize new spline + self.yfit = array([csp[0][1]], float) + self.d = array([0], float) + self.xfit = concatenate((self.xfit, zeros((3)))) # append to current spline + self.yfit = concatenate((self.yfit, zeros((3)))) + self.d = concatenate((self.d, zeros((3)))) + 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] + pointdistance((self.xfit[j-1],self.yfit[j-1]),(self.xfit[j],self.yfit[j])) + self.csp_old = csp + def ROBO_output(self): + if len(self.d) == 1: + return + fits = len(self.d) + ctrls = fits + 2 + knots = ctrls + 4 + self.xfit = concatenate((self.xfit, zeros((2)))) # pad with 2 endpoint constraints + self.yfit = concatenate((self.yfit, zeros((2)))) # pad with 2 endpoint constraints + self.d = concatenate((self.d, zeros((6)))) # pad with 3 duplicates at each end + self.d[fits+2] = self.d[fits+1] = self.d[fits] = self.d[fits-1] + solmatrix = 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.dxf_add(" 0\nSPLINE\n 5\n%x\n100\nAcDbEntity\n 8\n0\n100\nAcDbSpline\n" % self.handle) 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(4): - self.dxf_add(" 40\n0\n") - self.dxf_add(" 40\n%f\n" % u1) - self.dxf_add(" 40\n%f\n" % u2) - for i in range(4): - self.dxf_add(" 40\n1\n") - for i in range(6): + 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(4): - self.dxf_add(" 11\n%f\n 21\n%f\n 31\n0.0\n" % (xfit[i],yfit[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 effect(self): #References: Minimum Requirements for Creating a DXF File of a 3D Model By Paul Bourke @@ -136,7 +149,9 @@ class MyEffect(inkex.Effect): self.ROBO_spline([s[1],s[2],e[0],e[1]]) else: self.dxf_spline([s[1],s[2],e[0],e[1]]) - + if self.options.ROBO == 'true': + self.handle += 1 + self.ROBO_output() self.dxf_add(dxf_templates.r14_footer) if __name__ == '__main__':