new build infrastructure
[PyX/mjg.git] / pyx / normpath.py
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1 # -*- encoding: utf-8 -*-
4 # Copyright (C) 2002-2011 Jörg Lehmann <joergl@users.sourceforge.net>
5 # Copyright (C) 2003-2006 Michael Schindler <m-schindler@users.sourceforge.net>
6 # Copyright (C) 2002-2011 André Wobst <wobsta@users.sourceforge.net>
8 # This file is part of PyX (http://pyx.sourceforge.net/).
10 # PyX is free software; you can redistribute it and/or modify
11 # it under the terms of the GNU General Public License as published by
12 # the Free Software Foundation; either version 2 of the License, or
13 # (at your option) any later version.
15 # PyX is distributed in the hope that it will be useful,
16 # but WITHOUT ANY WARRANTY; without even the implied warranty of
17 # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18 # GNU General Public License for more details.
20 # You should have received a copy of the GNU General Public License
21 # along with PyX; if not, write to the Free Software
22 # Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
24 import math
25 import mathutils, path, trafo, unit
26 import bbox as bboxmodule
29 # use new style classes when possible
30 __metaclass__ = type
32 class _marker: pass
34 ################################################################################
36 # specific exception for normpath-related problems
37 class NormpathException(Exception): pass
39 # invalid result marker
40 class _invalid:
42 """invalid result marker class
44 The following norm(sub)path(item) methods:
45 - trafo
46 - rotation
47 - tangent_pt
48 - tangent
49 - curvature_pt
50 - curvradius_pt
51 return list of result values, which might contain the invalid instance
52 defined below to signal points, where the result is undefined due to
53 properties of the norm(sub)path(item). Accessing invalid leads to an
54 NormpathException, but you can test the result values by "is invalid".
55 """
57 def invalid1(self):
58 raise NormpathException("invalid result (the requested value is undefined due to path properties)")
59 __str__ = __repr__ = __neg__ = invalid1
61 def invalid2(self, other):
62 self.invalid1()
63 __cmp__ = __add__ = __iadd__ = __sub__ = __isub__ = __mul__ = __imul__ = __div__ = __truediv__ = __idiv__ = invalid2
65 invalid = _invalid()
67 ################################################################################
69 # global epsilon (default precision of normsubpaths)
70 _epsilon = 1e-5
71 # minimal relative speed (abort condition for tangent information)
72 _minrelspeed = 1e-5
74 def set(epsilon=None, minrelspeed=None):
75 global _epsilon
76 global _minrelspeed
77 if epsilon is not None:
78 _epsilon = epsilon
79 if minrelspeed is not None:
80 _minrelspeed = minrelspeed
83 ################################################################################
84 # normsubpathitems
85 ################################################################################
87 class normsubpathitem:
89 """element of a normalized sub path
91 Various operations on normsubpathitems might be subject of
92 approximitions. Those methods get the finite precision epsilon,
93 which is the accuracy needed expressed as a length in pts.
95 normsubpathitems should never be modified inplace, since references
96 might be shared between several normsubpaths.
97 """
99 def arclen_pt(self, epsilon):
100 """return arc length in pts"""
101 pass
103 def _arclentoparam_pt(self, lengths_pt, epsilon):
104 """return a tuple of params and the total length arc length in pts"""
105 pass
107 def arclentoparam_pt(self, lengths_pt, epsilon):
108 """return a tuple of params"""
109 pass
111 def at_pt(self, params):
112 """return coordinates at params in pts"""
113 pass
115 def atbegin_pt(self):
116 """return coordinates of first point in pts"""
117 pass
119 def atend_pt(self):
120 """return coordinates of last point in pts"""
121 pass
123 def bbox(self):
124 """return bounding box of normsubpathitem"""
125 pass
127 def cbox(self):
128 """return control box of normsubpathitem
130 The control box also fully encloses the normsubpathitem but in the case of a Bezier
131 curve it is not the minimal box doing so. On the other hand, it is much faster
132 to calculate.
134 pass
136 def curvature_pt(self, params):
137 """return the curvature at params in 1/pts
139 The result contains the invalid instance at positions, where the
140 curvature is undefined."""
141 pass
143 def curveradius_pt(self, params):
144 """return the curvature radius at params in pts
146 The curvature radius is the inverse of the curvature. Where the
147 curvature is undefined, the invalid instance is returned. Note that
148 this radius can be negative or positive, depending on the sign of the
149 curvature."""
150 pass
152 def intersect(self, other, epsilon):
153 """intersect self with other normsubpathitem"""
154 pass
156 def modifiedbegin_pt(self, x_pt, y_pt):
157 """return a normsubpathitem with a modified beginning point"""
158 pass
160 def modifiedend_pt(self, x_pt, y_pt):
161 """return a normsubpathitem with a modified end point"""
162 pass
164 def _paramtoarclen_pt(self, param, epsilon):
165 """return a tuple of arc lengths and the total arc length in pts"""
166 pass
168 def pathitem(self):
169 """return pathitem corresponding to normsubpathitem"""
171 def reversed(self):
172 """return reversed normsubpathitem"""
173 pass
175 def rotation(self, params):
176 """return rotation trafos (i.e. trafos without translations) at params"""
177 pass
179 def segments(self, params):
180 """return segments of the normsubpathitem
182 The returned list of normsubpathitems for the segments between
183 the params. params needs to contain at least two values.
185 pass
187 def trafo(self, params):
188 """return transformations at params"""
190 def transformed(self, trafo):
191 """return transformed normsubpathitem according to trafo"""
192 pass
194 def outputPS(self, file, writer):
195 """write PS code corresponding to normsubpathitem to file"""
196 pass
198 def outputPDF(self, file, writer):
199 """write PDF code corresponding to normsubpathitem to file"""
200 pass
203 class normline_pt(normsubpathitem):
205 """Straight line from (x0_pt, y0_pt) to (x1_pt, y1_pt) (coordinates in pts)"""
207 __slots__ = "x0_pt", "y0_pt", "x1_pt", "y1_pt"
209 def __init__(self, x0_pt, y0_pt, x1_pt, y1_pt):
210 self.x0_pt = x0_pt
211 self.y0_pt = y0_pt
212 self.x1_pt = x1_pt
213 self.y1_pt = y1_pt
215 def __str__(self):
216 return "normline_pt(%g, %g, %g, %g)" % (self.x0_pt, self.y0_pt, self.x1_pt, self.y1_pt)
218 def _arclentoparam_pt(self, lengths_pt, epsilon):
219 # do self.arclen_pt inplace for performance reasons
220 l_pt = math.hypot(self.x0_pt-self.x1_pt, self.y0_pt-self.y1_pt)
221 return [length_pt/l_pt for length_pt in lengths_pt], l_pt
223 def arclentoparam_pt(self, lengths_pt, epsilon):
224 """return a tuple of params"""
225 return self._arclentoparam_pt(lengths_pt, epsilon)[0]
227 def arclen_pt(self, epsilon):
228 return math.hypot(self.x0_pt-self.x1_pt, self.y0_pt-self.y1_pt)
230 def at_pt(self, params):
231 return [(self.x0_pt+(self.x1_pt-self.x0_pt)*t, self.y0_pt+(self.y1_pt-self.y0_pt)*t)
232 for t in params]
234 def atbegin_pt(self):
235 return self.x0_pt, self.y0_pt
237 def atend_pt(self):
238 return self.x1_pt, self.y1_pt
240 def bbox(self):
241 return bboxmodule.bbox_pt(min(self.x0_pt, self.x1_pt), min(self.y0_pt, self.y1_pt),
242 max(self.x0_pt, self.x1_pt), max(self.y0_pt, self.y1_pt))
244 cbox = bbox
246 def curvature_pt(self, params):
247 return [0] * len(params)
249 def curveradius_pt(self, params):
250 return [invalid] * len(params)
252 def intersect(self, other, epsilon):
253 if isinstance(other, normline_pt):
254 a_deltax_pt = self.x1_pt - self.x0_pt
255 a_deltay_pt = self.y1_pt - self.y0_pt
257 b_deltax_pt = other.x1_pt - other.x0_pt
258 b_deltay_pt = other.y1_pt - other.y0_pt
259 try:
260 det = 1.0 / (b_deltax_pt * a_deltay_pt - b_deltay_pt * a_deltax_pt)
261 except ArithmeticError:
262 return []
264 ba_deltax0_pt = other.x0_pt - self.x0_pt
265 ba_deltay0_pt = other.y0_pt - self.y0_pt
267 a_t = (b_deltax_pt * ba_deltay0_pt - b_deltay_pt * ba_deltax0_pt) * det
268 b_t = (a_deltax_pt * ba_deltay0_pt - a_deltay_pt * ba_deltax0_pt) * det
270 # check for intersections out of bound
271 # TODO: we might allow for a small out of bound errors.
272 if not (0<=a_t<=1 and 0<=b_t<=1):
273 return []
275 # return parameters of intersection
276 return [(a_t, b_t)]
277 else:
278 return [(s_t, o_t) for o_t, s_t in other.intersect(self, epsilon)]
280 def modifiedbegin_pt(self, x_pt, y_pt):
281 return normline_pt(x_pt, y_pt, self.x1_pt, self.y1_pt)
283 def modifiedend_pt(self, x_pt, y_pt):
284 return normline_pt(self.x0_pt, self.y0_pt, x_pt, y_pt)
286 def _paramtoarclen_pt(self, params, epsilon):
287 totalarclen_pt = self.arclen_pt(epsilon)
288 arclens_pt = [totalarclen_pt * param for param in params + [1]]
289 return arclens_pt[:-1], arclens_pt[-1]
291 def pathitem(self):
292 return path.lineto_pt(self.x1_pt, self.y1_pt)
294 def reversed(self):
295 return normline_pt(self.x1_pt, self.y1_pt, self.x0_pt, self.y0_pt)
297 def rotation(self, params):
298 return [trafo.rotate(math.degrees(math.atan2(self.y1_pt-self.y0_pt, self.x1_pt-self.x0_pt)))]*len(params)
300 def segments(self, params):
301 if len(params) < 2:
302 raise ValueError("at least two parameters needed in segments")
303 result = []
304 xl_pt = yl_pt = None
305 for t in params:
306 xr_pt = self.x0_pt + (self.x1_pt-self.x0_pt)*t
307 yr_pt = self.y0_pt + (self.y1_pt-self.y0_pt)*t
308 if xl_pt is not None:
309 result.append(normline_pt(xl_pt, yl_pt, xr_pt, yr_pt))
310 xl_pt = xr_pt
311 yl_pt = yr_pt
312 return result
314 def trafo(self, params):
315 rotate = trafo.rotate(math.degrees(math.atan2(self.y1_pt-self.y0_pt, self.x1_pt-self.x0_pt)))
316 return [trafo.translate_pt(*at_pt) * rotate
317 for param, at_pt in zip(params, self.at_pt(params))]
319 def transformed(self, trafo):
320 return normline_pt(*(trafo.apply_pt(self.x0_pt, self.y0_pt) + trafo.apply_pt(self.x1_pt, self.y1_pt)))
322 def outputPS(self, file, writer):
323 file.write("%g %g lineto\n" % (self.x1_pt, self.y1_pt))
325 def outputPDF(self, file, writer):
326 file.write("%f %f l\n" % (self.x1_pt, self.y1_pt))
329 class normcurve_pt(normsubpathitem):
331 """Bezier curve with control points x0_pt, y0_pt, x1_pt, y1_pt, x2_pt, y2_pt, x3_pt, y3_pt (coordinates in pts)"""
333 __slots__ = "x0_pt", "y0_pt", "x1_pt", "y1_pt", "x2_pt", "y2_pt", "x3_pt", "y3_pt"
335 def __init__(self, x0_pt, y0_pt, x1_pt, y1_pt, x2_pt, y2_pt, x3_pt, y3_pt):
336 self.x0_pt = x0_pt
337 self.y0_pt = y0_pt
338 self.x1_pt = x1_pt
339 self.y1_pt = y1_pt
340 self.x2_pt = x2_pt
341 self.y2_pt = y2_pt
342 self.x3_pt = x3_pt
343 self.y3_pt = y3_pt
345 def __str__(self):
346 return "normcurve_pt(%g, %g, %g, %g, %g, %g, %g, %g)" % (self.x0_pt, self.y0_pt, self.x1_pt, self.y1_pt,
347 self.x2_pt, self.y2_pt, self.x3_pt, self.y3_pt)
349 def _midpointsplit(self, epsilon):
350 """split curve into two parts
352 Helper method to reduce the complexity of a problem by turning
353 a normcurve_pt into several normline_pt segments. This method
354 returns normcurve_pt instances only, when they are not yet straight
355 enough to be replaceable by normcurve_pt instances. Thus a recursive
356 midpointsplitting will turn a curve into line segments with the
357 given precision epsilon.
360 # first, we have to calculate the midpoints between adjacent
361 # control points
362 x01_pt = 0.5*(self.x0_pt + self.x1_pt)
363 y01_pt = 0.5*(self.y0_pt + self.y1_pt)
364 x12_pt = 0.5*(self.x1_pt + self.x2_pt)
365 y12_pt = 0.5*(self.y1_pt + self.y2_pt)
366 x23_pt = 0.5*(self.x2_pt + self.x3_pt)
367 y23_pt = 0.5*(self.y2_pt + self.y3_pt)
369 # In the next iterative step, we need the midpoints between 01 and 12
370 # and between 12 and 23
371 x01_12_pt = 0.5*(x01_pt + x12_pt)
372 y01_12_pt = 0.5*(y01_pt + y12_pt)
373 x12_23_pt = 0.5*(x12_pt + x23_pt)
374 y12_23_pt = 0.5*(y12_pt + y23_pt)
376 # Finally the midpoint is given by
377 xmidpoint_pt = 0.5*(x01_12_pt + x12_23_pt)
378 ymidpoint_pt = 0.5*(y01_12_pt + y12_23_pt)
380 # Before returning the normcurves we check whether we can
381 # replace them by normlines within an error of epsilon pts.
382 # The maximal error value is given by the modulus of the
383 # difference between the length of the control polygon
384 # (i.e. |P1-P0|+|P2-P1|+|P3-P2|), which consitutes an upper
385 # bound for the length, and the length of the straight line
386 # between start and end point of the normcurve (i.e. |P3-P1|),
387 # which represents a lower bound.
388 l0_pt = math.hypot(xmidpoint_pt - self.x0_pt, ymidpoint_pt - self.y0_pt)
389 l1_pt = math.hypot(x01_pt - self.x0_pt, y01_pt - self.y0_pt)
390 l2_pt = math.hypot(x01_12_pt - x01_pt, y01_12_pt - y01_pt)
391 l3_pt = math.hypot(xmidpoint_pt - x01_12_pt, ymidpoint_pt - y01_12_pt)
392 if l1_pt+l2_pt+l3_pt-l0_pt < epsilon:
393 a = _leftnormline_pt(self.x0_pt, self.y0_pt, xmidpoint_pt, ymidpoint_pt, l1_pt, l2_pt, l3_pt)
394 else:
395 a = _leftnormcurve_pt(self.x0_pt, self.y0_pt,
396 x01_pt, y01_pt,
397 x01_12_pt, y01_12_pt,
398 xmidpoint_pt, ymidpoint_pt)
400 l0_pt = math.hypot(self.x3_pt - xmidpoint_pt, self.y3_pt - ymidpoint_pt)
401 l1_pt = math.hypot(x12_23_pt - xmidpoint_pt, y12_23_pt - ymidpoint_pt)
402 l2_pt = math.hypot(x23_pt - x12_23_pt, y23_pt - y12_23_pt)
403 l3_pt = math.hypot(self.x3_pt - x23_pt, self.y3_pt - y23_pt)
404 if l1_pt+l2_pt+l3_pt-l0_pt < epsilon:
405 b = _rightnormline_pt(xmidpoint_pt, ymidpoint_pt, self.x3_pt, self.y3_pt, l1_pt, l2_pt, l3_pt)
406 else:
407 b = _rightnormcurve_pt(xmidpoint_pt, ymidpoint_pt,
408 x12_23_pt, y12_23_pt,
409 x23_pt, y23_pt,
410 self.x3_pt, self.y3_pt)
412 return a, b
414 def _arclentoparam_pt(self, lengths_pt, epsilon):
415 a, b = self._midpointsplit(epsilon)
416 params_a, arclen_a_pt = a._arclentoparam_pt(lengths_pt, epsilon)
417 params_b, arclen_b_pt = b._arclentoparam_pt([length_pt - arclen_a_pt for length_pt in lengths_pt], epsilon)
418 params = []
419 for param_a, param_b, length_pt in zip(params_a, params_b, lengths_pt):
420 if length_pt > arclen_a_pt:
421 params.append(b.subparamtoparam(param_b))
422 else:
423 params.append(a.subparamtoparam(param_a))
424 return params, arclen_a_pt + arclen_b_pt
426 def arclentoparam_pt(self, lengths_pt, epsilon):
427 """return a tuple of params"""
428 return self._arclentoparam_pt(lengths_pt, epsilon)[0]
430 def arclen_pt(self, epsilon):
431 a, b = self._midpointsplit(epsilon)
432 return a.arclen_pt(epsilon) + b.arclen_pt(epsilon)
434 def at_pt(self, params):
435 return [( (-self.x0_pt+3*self.x1_pt-3*self.x2_pt+self.x3_pt)*t*t*t +
436 (3*self.x0_pt-6*self.x1_pt+3*self.x2_pt )*t*t +
437 (-3*self.x0_pt+3*self.x1_pt )*t +
438 self.x0_pt,
439 (-self.y0_pt+3*self.y1_pt-3*self.y2_pt+self.y3_pt)*t*t*t +
440 (3*self.y0_pt-6*self.y1_pt+3*self.y2_pt )*t*t +
441 (-3*self.y0_pt+3*self.y1_pt )*t +
442 self.y0_pt )
443 for t in params]
445 def atbegin_pt(self):
446 return self.x0_pt, self.y0_pt
448 def atend_pt(self):
449 return self.x3_pt, self.y3_pt
451 def bbox(self):
452 xmin_pt, xmax_pt = path._bezierpolyrange(self.x0_pt, self.x1_pt, self.x2_pt, self.x3_pt)
453 ymin_pt, ymax_pt = path._bezierpolyrange(self.y0_pt, self.y1_pt, self.y2_pt, self.y3_pt)
454 return bboxmodule.bbox_pt(xmin_pt, ymin_pt, xmax_pt, ymax_pt)
456 def cbox(self):
457 return bboxmodule.bbox_pt(min(self.x0_pt, self.x1_pt, self.x2_pt, self.x3_pt),
458 min(self.y0_pt, self.y1_pt, self.y2_pt, self.y3_pt),
459 max(self.x0_pt, self.x1_pt, self.x2_pt, self.x3_pt),
460 max(self.y0_pt, self.y1_pt, self.y2_pt, self.y3_pt))
462 def curvature_pt(self, params):
463 result = []
464 # see notes in rotation
465 approxarclen = (math.hypot(self.x1_pt-self.x0_pt, self.y1_pt-self.y0_pt) +
466 math.hypot(self.x2_pt-self.x1_pt, self.y2_pt-self.y1_pt) +
467 math.hypot(self.x3_pt-self.x2_pt, self.y3_pt-self.y2_pt))
468 for param in params:
469 xdot = ( 3 * (1-param)*(1-param) * (-self.x0_pt + self.x1_pt) +
470 6 * (1-param)*param * (-self.x1_pt + self.x2_pt) +
471 3 * param*param * (-self.x2_pt + self.x3_pt) )
472 ydot = ( 3 * (1-param)*(1-param) * (-self.y0_pt + self.y1_pt) +
473 6 * (1-param)*param * (-self.y1_pt + self.y2_pt) +
474 3 * param*param * (-self.y2_pt + self.y3_pt) )
475 xddot = ( 6 * (1-param) * (self.x0_pt - 2*self.x1_pt + self.x2_pt) +
476 6 * param * (self.x1_pt - 2*self.x2_pt + self.x3_pt) )
477 yddot = ( 6 * (1-param) * (self.y0_pt - 2*self.y1_pt + self.y2_pt) +
478 6 * param * (self.y1_pt - 2*self.y2_pt + self.y3_pt) )
480 hypot = math.hypot(xdot, ydot)
481 if hypot/approxarclen > _minrelspeed:
482 result.append((xdot*yddot - ydot*xddot) / hypot**3)
483 else:
484 result.append(invalid)
485 return result
487 def curveradius_pt(self, params):
488 result = []
489 # see notes in rotation
490 approxarclen = (math.hypot(self.x1_pt-self.x0_pt, self.y1_pt-self.y0_pt) +
491 math.hypot(self.x2_pt-self.x1_pt, self.y2_pt-self.y1_pt) +
492 math.hypot(self.x3_pt-self.x2_pt, self.y3_pt-self.y2_pt))
493 for param in params:
494 xdot = ( 3 * (1-param)*(1-param) * (-self.x0_pt + self.x1_pt) +
495 6 * (1-param)*param * (-self.x1_pt + self.x2_pt) +
496 3 * param*param * (-self.x2_pt + self.x3_pt) )
497 ydot = ( 3 * (1-param)*(1-param) * (-self.y0_pt + self.y1_pt) +
498 6 * (1-param)*param * (-self.y1_pt + self.y2_pt) +
499 3 * param*param * (-self.y2_pt + self.y3_pt) )
500 xddot = ( 6 * (1-param) * (self.x0_pt - 2*self.x1_pt + self.x2_pt) +
501 6 * param * (self.x1_pt - 2*self.x2_pt + self.x3_pt) )
502 yddot = ( 6 * (1-param) * (self.y0_pt - 2*self.y1_pt + self.y2_pt) +
503 6 * param * (self.y1_pt - 2*self.y2_pt + self.y3_pt) )
505 hypot = math.hypot(xdot, ydot)
506 if hypot/approxarclen > _minrelspeed:
507 result.append(hypot**3 / (xdot*yddot - ydot*xddot))
508 else:
509 result.append(invalid)
510 return result
512 def intersect(self, other, epsilon):
513 # There can be no intersection point, when the control boxes are not
514 # overlapping. Note that we use the control box instead of the bounding
515 # box here, because the former can be calculated more efficiently for
516 # Bezier curves.
517 if not self.cbox().intersects(other.cbox()):
518 return []
519 a, b = self._midpointsplit(epsilon)
520 # To improve the performance in the general case we alternate the
521 # splitting process between the two normsubpathitems
522 return ( [(a.subparamtoparam(a_t), o_t) for o_t, a_t in other.intersect(a, epsilon)] +
523 [(b.subparamtoparam(b_t), o_t) for o_t, b_t in other.intersect(b, epsilon)] )
525 def modifiedbegin_pt(self, x_pt, y_pt):
526 return normcurve_pt(x_pt, y_pt,
527 self.x1_pt, self.y1_pt,
528 self.x2_pt, self.y2_pt,
529 self.x3_pt, self.y3_pt)
531 def modifiedend_pt(self, x_pt, y_pt):
532 return normcurve_pt(self.x0_pt, self.y0_pt,
533 self.x1_pt, self.y1_pt,
534 self.x2_pt, self.y2_pt,
535 x_pt, y_pt)
537 def _paramtoarclen_pt(self, params, epsilon):
538 arclens_pt = [segment.arclen_pt(epsilon) for segment in self.segments([0] + list(params) + [1])]
539 for i in range(1, len(arclens_pt)):
540 arclens_pt[i] += arclens_pt[i-1]
541 return arclens_pt[:-1], arclens_pt[-1]
543 def pathitem(self):
544 return path.curveto_pt(self.x1_pt, self.y1_pt, self.x2_pt, self.y2_pt, self.x3_pt, self.y3_pt)
546 def reversed(self):
547 return normcurve_pt(self.x3_pt, self.y3_pt, self.x2_pt, self.y2_pt, self.x1_pt, self.y1_pt, self.x0_pt, self.y0_pt)
549 def rotation(self, params):
550 result = []
551 # We need to take care of the case of tdx_pt and tdy_pt close to zero.
552 # We should not compare those values to epsilon (which is a length) directly.
553 # Furthermore we want this "speed" in general and it's abort condition in
554 # particular to be invariant on the actual size of the normcurve. Hence we
555 # first calculate a crude approximation for the arclen.
556 approxarclen = (math.hypot(self.x1_pt-self.x0_pt, self.y1_pt-self.y0_pt) +
557 math.hypot(self.x2_pt-self.x1_pt, self.y2_pt-self.y1_pt) +
558 math.hypot(self.x3_pt-self.x2_pt, self.y3_pt-self.y2_pt))
559 for param in params:
560 tdx_pt = (3*( -self.x0_pt+3*self.x1_pt-3*self.x2_pt+self.x3_pt)*param*param +
561 2*( 3*self.x0_pt-6*self.x1_pt+3*self.x2_pt )*param +
562 (-3*self.x0_pt+3*self.x1_pt ))
563 tdy_pt = (3*( -self.y0_pt+3*self.y1_pt-3*self.y2_pt+self.y3_pt)*param*param +
564 2*( 3*self.y0_pt-6*self.y1_pt+3*self.y2_pt )*param +
565 (-3*self.y0_pt+3*self.y1_pt ))
566 # We scale the speed such the "relative speed" of a line is 1 independend of
567 # the length of the line. For curves we want this "relative speed" to be higher than
568 # _minrelspeed:
569 if math.hypot(tdx_pt, tdy_pt)/approxarclen > _minrelspeed:
570 result.append(trafo.rotate(math.degrees(math.atan2(tdy_pt, tdx_pt))))
571 else:
572 # Note that we can't use the rule of l'Hopital here, since it would
573 # not provide us with a sign for the tangent. Hence we wouldn't
574 # notice whether the sign changes (which is a typical case at cusps).
575 result.append(invalid)
576 return result
578 def segments(self, params):
579 if len(params) < 2:
580 raise ValueError("at least two parameters needed in segments")
582 # first, we calculate the coefficients corresponding to our
583 # original bezier curve. These represent a useful starting
584 # point for the following change of the polynomial parameter
585 a0x_pt = self.x0_pt
586 a0y_pt = self.y0_pt
587 a1x_pt = 3*(-self.x0_pt+self.x1_pt)
588 a1y_pt = 3*(-self.y0_pt+self.y1_pt)
589 a2x_pt = 3*(self.x0_pt-2*self.x1_pt+self.x2_pt)
590 a2y_pt = 3*(self.y0_pt-2*self.y1_pt+self.y2_pt)
591 a3x_pt = -self.x0_pt+3*(self.x1_pt-self.x2_pt)+self.x3_pt
592 a3y_pt = -self.y0_pt+3*(self.y1_pt-self.y2_pt)+self.y3_pt
594 result = []
596 for i in range(len(params)-1):
597 t1 = params[i]
598 dt = params[i+1]-t1
600 # [t1,t2] part
602 # the new coefficients of the [t1,t1+dt] part of the bezier curve
603 # are then given by expanding
604 # a0 + a1*(t1+dt*u) + a2*(t1+dt*u)**2 +
605 # a3*(t1+dt*u)**3 in u, yielding
607 # a0 + a1*t1 + a2*t1**2 + a3*t1**3 +
608 # ( a1 + 2*a2 + 3*a3*t1**2 )*dt * u +
609 # ( a2 + 3*a3*t1 )*dt**2 * u**2 +
610 # a3*dt**3 * u**3
612 # from this values we obtain the new control points by inversion
614 # TODO: we could do this more efficiently by reusing for
615 # (x0_pt, y0_pt) the control point (x3_pt, y3_pt) from the previous
616 # Bezier curve
618 x0_pt = a0x_pt + a1x_pt*t1 + a2x_pt*t1*t1 + a3x_pt*t1*t1*t1
619 y0_pt = a0y_pt + a1y_pt*t1 + a2y_pt*t1*t1 + a3y_pt*t1*t1*t1
620 x1_pt = (a1x_pt+2*a2x_pt*t1+3*a3x_pt*t1*t1)*dt/3.0 + x0_pt
621 y1_pt = (a1y_pt+2*a2y_pt*t1+3*a3y_pt*t1*t1)*dt/3.0 + y0_pt
622 x2_pt = (a2x_pt+3*a3x_pt*t1)*dt*dt/3.0 - x0_pt + 2*x1_pt
623 y2_pt = (a2y_pt+3*a3y_pt*t1)*dt*dt/3.0 - y0_pt + 2*y1_pt
624 x3_pt = a3x_pt*dt*dt*dt + x0_pt - 3*x1_pt + 3*x2_pt
625 y3_pt = a3y_pt*dt*dt*dt + y0_pt - 3*y1_pt + 3*y2_pt
627 result.append(normcurve_pt(x0_pt, y0_pt, x1_pt, y1_pt, x2_pt, y2_pt, x3_pt, y3_pt))
629 return result
631 def trafo(self, params):
632 result = []
633 for rotation, at_pt in zip(self.rotation(params), self.at_pt(params)):
634 if rotation is invalid:
635 result.append(rotation)
636 else:
637 result.append(trafo.translate_pt(*at_pt) * rotation)
638 return result
640 def transformed(self, trafo):
641 x0_pt, y0_pt = trafo.apply_pt(self.x0_pt, self.y0_pt)
642 x1_pt, y1_pt = trafo.apply_pt(self.x1_pt, self.y1_pt)
643 x2_pt, y2_pt = trafo.apply_pt(self.x2_pt, self.y2_pt)
644 x3_pt, y3_pt = trafo.apply_pt(self.x3_pt, self.y3_pt)
645 return normcurve_pt(x0_pt, y0_pt, x1_pt, y1_pt, x2_pt, y2_pt, x3_pt, y3_pt)
647 def outputPS(self, file, writer):
648 file.write("%g %g %g %g %g %g curveto\n" % (self.x1_pt, self.y1_pt, self.x2_pt, self.y2_pt, self.x3_pt, self.y3_pt))
650 def outputPDF(self, file, writer):
651 file.write("%f %f %f %f %f %f c\n" % (self.x1_pt, self.y1_pt, self.x2_pt, self.y2_pt, self.x3_pt, self.y3_pt))
653 def x_pt(self, t):
654 return ((( self.x3_pt-3*self.x2_pt+3*self.x1_pt-self.x0_pt)*t +
655 3*self.x0_pt-6*self.x1_pt+3*self.x2_pt)*t +
656 3*self.x1_pt-3*self.x0_pt)*t + self.x0_pt
658 def xdot_pt(self, t):
659 return ((3*self.x3_pt-9*self.x2_pt+9*self.x1_pt-3*self.x0_pt)*t +
660 6*self.x0_pt-12*self.x1_pt+6*self.x2_pt)*t + 3*self.x1_pt - 3*self.x0_pt
662 def xddot_pt(self, t):
663 return (6*self.x3_pt-18*self.x2_pt+18*self.x1_pt-6*self.x0_pt)*t + 6*self.x0_pt - 12*self.x1_pt + 6*self.x2_pt
665 def xdddot_pt(self, t):
666 return 6*self.x3_pt-18*self.x2_pt+18*self.x1_pt-6*self.x0_pt
668 def y_pt(self, t):
669 return ((( self.y3_pt-3*self.y2_pt+3*self.y1_pt-self.y0_pt)*t +
670 3*self.y0_pt-6*self.y1_pt+3*self.y2_pt)*t +
671 3*self.y1_pt-3*self.y0_pt)*t + self.y0_pt
673 def ydot_pt(self, t):
674 return ((3*self.y3_pt-9*self.y2_pt+9*self.y1_pt-3*self.y0_pt)*t +
675 6*self.y0_pt-12*self.y1_pt+6*self.y2_pt)*t + 3*self.y1_pt - 3*self.y0_pt
677 def yddot_pt(self, t):
678 return (6*self.y3_pt-18*self.y2_pt+18*self.y1_pt-6*self.y0_pt)*t + 6*self.y0_pt - 12*self.y1_pt + 6*self.y2_pt
680 def ydddot_pt(self, t):
681 return 6*self.y3_pt-18*self.y2_pt+18*self.y1_pt-6*self.y0_pt
684 # curve replacements used by midpointsplit:
685 # The replacements are normline_pt and normcurve_pt instances with an
686 # additional subparamtoparam function for proper conversion of the
687 # parametrization. Note that we only one direction (when a parameter
688 # gets calculated), since the other way around direction midpointsplit
689 # is not needed at all
691 class _leftnormline_pt(normline_pt):
693 __slots__ = "x0_pt", "y0_pt", "x1_pt", "y1_pt", "l1_pt", "l2_pt", "l3_pt"
695 def __init__(self, x0_pt, y0_pt, x1_pt, y1_pt, l1_pt, l2_pt, l3_pt):
696 normline_pt.__init__(self, x0_pt, y0_pt, x1_pt, y1_pt)
697 self.l1_pt = l1_pt
698 self.l2_pt = l2_pt
699 self.l3_pt = l3_pt
701 def subparamtoparam(self, param):
702 if 0 <= param <= 1:
703 params = mathutils.realpolyroots(self.l1_pt-2*self.l2_pt+self.l3_pt,
704 -3*self.l1_pt+3*self.l2_pt,
705 3*self.l1_pt,
706 -param*(self.l1_pt+self.l2_pt+self.l3_pt))
707 # we might get several solutions and choose the one closest to 0.5
708 # (we want the solution to be in the range 0 <= param <= 1; in case
709 # we get several solutions in this range, they all will be close to
710 # each other since l1_pt+l2_pt+l3_pt-l0_pt < epsilon)
711 params.sort(lambda t1, t2: cmp(abs(t1-0.5), abs(t2-0.5)))
712 return 0.5*params[0]
713 else:
714 # when we are outside the proper parameter range, we skip the non-linear
715 # transformation, since it becomes slow and it might even start to be
716 # numerically instable
717 return 0.5*param
720 class _rightnormline_pt(_leftnormline_pt):
722 __slots__ = "x0_pt", "y0_pt", "x1_pt", "y1_pt", "l1_pt", "l2_pt", "l3_pt"
724 def subparamtoparam(self, param):
725 return 0.5+_leftnormline_pt.subparamtoparam(self, param)
728 class _leftnormcurve_pt(normcurve_pt):
730 __slots__ = "x0_pt", "y0_pt", "x1_pt", "y1_pt", "x2_pt", "y2_pt", "x3_pt", "y3_pt"
732 def subparamtoparam(self, param):
733 return 0.5*param
736 class _rightnormcurve_pt(normcurve_pt):
738 __slots__ = "x0_pt", "y0_pt", "x1_pt", "y1_pt", "x2_pt", "y2_pt", "x3_pt", "y3_pt"
740 def subparamtoparam(self, param):
741 return 0.5+0.5*param
744 ################################################################################
745 # normsubpath
746 ################################################################################
748 class normsubpath:
750 """sub path of a normalized path
752 A subpath consists of a list of normsubpathitems, i.e., normlines_pt and
753 normcurves_pt and can either be closed or not.
755 Some invariants, which have to be obeyed:
756 - All normsubpathitems have to be longer than epsilon pts.
757 - At the end there may be a normline (stored in self.skippedline) whose
758 length is shorter than epsilon -- it has to be taken into account
759 when adding further normsubpathitems
760 - The last point of a normsubpathitem and the first point of the next
761 element have to be equal.
762 - When the path is closed, the last point of last normsubpathitem has
763 to be equal to the first point of the first normsubpathitem.
764 - epsilon might be none, disallowing any numerics, but allowing for
765 arbitrary short paths. This is used in pdf output, where all paths need
766 to be transformed to normpaths.
769 __slots__ = "normsubpathitems", "closed", "epsilon", "skippedline"
771 def __init__(self, normsubpathitems=[], closed=0, epsilon=_marker):
772 """construct a normsubpath"""
773 if epsilon is _marker:
774 epsilon = _epsilon
775 self.epsilon = epsilon
776 # If one or more items appended to the normsubpath have been
777 # skipped (because their total length was shorter than epsilon),
778 # we remember this fact by a line because we have to take it
779 # properly into account when appending further normsubpathitems
780 self.skippedline = None
782 self.normsubpathitems = []
783 self.closed = 0
785 # a test (might be temporary)
786 for anormsubpathitem in normsubpathitems:
787 assert isinstance(anormsubpathitem, normsubpathitem), "only list of normsubpathitem instances allowed"
789 self.extend(normsubpathitems)
791 if closed:
792 self.close()
794 def __getitem__(self, i):
795 """return normsubpathitem i"""
796 return self.normsubpathitems[i]
798 def __len__(self):
799 """return number of normsubpathitems"""
800 return len(self.normsubpathitems)
802 def __str__(self):
803 l = ", ".join(map(str, self.normsubpathitems))
804 if self.closed:
805 return "normsubpath([%s], closed=1)" % l
806 else:
807 return "normsubpath([%s])" % l
809 def _distributeparams(self, params):
810 """return a dictionary mapping normsubpathitemindices to a tuple
811 of a paramindices and normsubpathitemparams.
813 normsubpathitemindex specifies a normsubpathitem containing
814 one or several positions. paramindex specify the index of the
815 param in the original list and normsubpathitemparam is the
816 parameter value in the normsubpathitem.
819 result = {}
820 for i, param in enumerate(params):
821 if param > 0:
822 index = int(param)
823 if index > len(self.normsubpathitems) - 1:
824 index = len(self.normsubpathitems) - 1
825 else:
826 index = 0
827 result.setdefault(index, ([], []))
828 result[index][0].append(i)
829 result[index][1].append(param - index)
830 return result
832 def append(self, anormsubpathitem):
833 """append normsubpathitem
835 Fails on closed normsubpath.
837 if self.epsilon is None:
838 self.normsubpathitems.append(anormsubpathitem)
839 else:
840 # consitency tests (might be temporary)
841 assert isinstance(anormsubpathitem, normsubpathitem), "only normsubpathitem instances allowed"
842 if self.skippedline:
843 assert math.hypot(*[x-y for x, y in zip(self.skippedline.atend_pt(), anormsubpathitem.atbegin_pt())]) < self.epsilon, "normsubpathitems do not match"
844 elif self.normsubpathitems:
845 assert math.hypot(*[x-y for x, y in zip(self.normsubpathitems[-1].atend_pt(), anormsubpathitem.atbegin_pt())]) < self.epsilon, "normsubpathitems do not match"
847 if self.closed:
848 raise NormpathException("Cannot append to closed normsubpath")
850 if self.skippedline:
851 xs_pt, ys_pt = self.skippedline.atbegin_pt()
852 else:
853 xs_pt, ys_pt = anormsubpathitem.atbegin_pt()
854 xe_pt, ye_pt = anormsubpathitem.atend_pt()
856 if (math.hypot(xe_pt-xs_pt, ye_pt-ys_pt) >= self.epsilon or
857 anormsubpathitem.arclen_pt(self.epsilon) >= self.epsilon):
858 if self.skippedline:
859 anormsubpathitem = anormsubpathitem.modifiedbegin_pt(xs_pt, ys_pt)
860 self.normsubpathitems.append(anormsubpathitem)
861 self.skippedline = None
862 else:
863 self.skippedline = normline_pt(xs_pt, ys_pt, xe_pt, ye_pt)
865 def arclen_pt(self):
866 """return arc length in pts"""
867 return sum([npitem.arclen_pt(self.epsilon) for npitem in self.normsubpathitems])
869 def _arclentoparam_pt(self, lengths_pt):
870 """return a tuple of params and the total length arc length in pts"""
871 # work on a copy which is counted down to negative values
872 lengths_pt = lengths_pt[:]
873 results = [None] * len(lengths_pt)
875 totalarclen = 0
876 for normsubpathindex, normsubpathitem in enumerate(self.normsubpathitems):
877 params, arclen = normsubpathitem._arclentoparam_pt(lengths_pt, self.epsilon)
878 for i in range(len(results)):
879 if results[i] is None:
880 lengths_pt[i] -= arclen
881 if lengths_pt[i] < 0 or normsubpathindex == len(self.normsubpathitems) - 1:
882 # overwrite the results until the length has become negative
883 results[i] = normsubpathindex + params[i]
884 totalarclen += arclen
886 return results, totalarclen
888 def arclentoparam_pt(self, lengths_pt):
889 """return a tuple of params"""
890 return self._arclentoparam_pt(lengths_pt)[0]
892 def at_pt(self, params):
893 """return coordinates at params in pts"""
894 if not self.normsubpathitems and self.skippedline:
895 return [self.skippedline.atbegin_pt()]*len(params)
896 result = [None] * len(params)
897 for normsubpathitemindex, (indices, params) in self._distributeparams(params).items():
898 for index, point_pt in zip(indices, self.normsubpathitems[normsubpathitemindex].at_pt(params)):
899 result[index] = point_pt
900 return result
902 def atbegin_pt(self):
903 """return coordinates of first point in pts"""
904 if not self.normsubpathitems and self.skippedline:
905 return self.skippedline.atbegin_pt()
906 return self.normsubpathitems[0].atbegin_pt()
908 def atend_pt(self):
909 """return coordinates of last point in pts"""
910 if self.skippedline:
911 return self.skippedline.atend_pt()
912 return self.normsubpathitems[-1].atend_pt()
914 def bbox(self):
915 """return bounding box of normsubpath"""
916 if self.normsubpathitems:
917 abbox = self.normsubpathitems[0].bbox()
918 for anormpathitem in self.normsubpathitems[1:]:
919 abbox += anormpathitem.bbox()
920 return abbox
921 else:
922 return bboxmodule.empty()
924 def close(self):
925 """close subnormpath
927 Fails on closed normsubpath.
929 if self.closed:
930 raise NormpathException("Cannot close already closed normsubpath")
931 if not self.normsubpathitems:
932 if self.skippedline is None:
933 raise NormpathException("Cannot close empty normsubpath")
934 else:
935 raise NormpathException("Normsubpath too short, cannot be closed")
937 xs_pt, ys_pt = self.normsubpathitems[-1].atend_pt()
938 xe_pt, ye_pt = self.normsubpathitems[0].atbegin_pt()
939 self.append(normline_pt(xs_pt, ys_pt, xe_pt, ye_pt))
940 self.flushskippedline()
941 self.closed = 1
943 def copy(self):
944 """return copy of normsubpath"""
945 # Since normsubpathitems are never modified inplace, we just
946 # need to copy the normsubpathitems list. We do not pass the
947 # normsubpathitems to the constructor to not repeat the checks
948 # for minimal length of each normsubpathitem.
949 result = normsubpath(epsilon=self.epsilon)
950 result.normsubpathitems = self.normsubpathitems[:]
951 result.closed = self.closed
953 # We can share the reference to skippedline, since it is a
954 # normsubpathitem as well and thus not modified in place either.
955 result.skippedline = self.skippedline
957 return result
959 def curvature_pt(self, params):
960 """return the curvature at params in 1/pts
962 The result contain the invalid instance at positions, where the
963 curvature is undefined."""
964 result = [None] * len(params)
965 for normsubpathitemindex, (indices, params) in self._distributeparams(params).items():
966 for index, curvature_pt in zip(indices, self.normsubpathitems[normsubpathitemindex].curvature_pt(params)):
967 result[index] = curvature_pt
968 return result
970 def curveradius_pt(self, params):
971 """return the curvature radius at params in pts
973 The curvature radius is the inverse of the curvature. When the
974 curvature is 0, the invalid instance is returned. Note that this radius can be negative
975 or positive, depending on the sign of the curvature."""
976 result = [None] * len(params)
977 for normsubpathitemindex, (indices, params) in self._distributeparams(params).items():
978 for index, radius_pt in zip(indices, self.normsubpathitems[normsubpathitemindex].curveradius_pt(params)):
979 result[index] = radius_pt
980 return result
982 def extend(self, normsubpathitems):
983 """extend path by normsubpathitems
985 Fails on closed normsubpath.
987 for normsubpathitem in normsubpathitems:
988 self.append(normsubpathitem)
990 def flushskippedline(self):
991 """flush the skippedline, i.e. apply it to the normsubpath
993 remove the skippedline by modifying the end point of the existing normsubpath
995 while self.skippedline:
996 try:
997 lastnormsubpathitem = self.normsubpathitems.pop()
998 except IndexError:
999 raise ValueError("normsubpath too short to flush the skippedline")
1000 lastnormsubpathitem = lastnormsubpathitem.modifiedend_pt(*self.skippedline.atend_pt())
1001 self.skippedline = None
1002 self.append(lastnormsubpathitem)
1004 def intersect(self, other):
1005 """intersect self with other normsubpath
1007 Returns a tuple of lists consisting of the parameter values
1008 of the intersection points of the corresponding normsubpath.
1010 intersections_a = []
1011 intersections_b = []
1012 epsilon = min(self.epsilon, other.epsilon)
1013 # Intersect all subpaths of self with the subpaths of other, possibly including
1014 # one intersection point several times
1015 for t_a, pitem_a in enumerate(self.normsubpathitems):
1016 for t_b, pitem_b in enumerate(other.normsubpathitems):
1017 for intersection_a, intersection_b in pitem_a.intersect(pitem_b, epsilon):
1018 intersections_a.append(intersection_a + t_a)
1019 intersections_b.append(intersection_b + t_b)
1021 # although intersectipns_a are sorted for the different normsubpathitems,
1022 # within a normsubpathitem, the ordering has to be ensured separately:
1023 intersections = zip(intersections_a, intersections_b)
1024 intersections.sort()
1025 intersections_a = [a for a, b in intersections]
1026 intersections_b = [b for a, b in intersections]
1028 # for symmetry reasons we enumerate intersections_a as well, although
1029 # they are already sorted (note we do not need to sort intersections_a)
1030 intersections_a = zip(intersections_a, range(len(intersections_a)))
1031 intersections_b = zip(intersections_b, range(len(intersections_b)))
1032 intersections_b.sort()
1034 # now we search for intersections points which are closer together than epsilon
1035 # This task is handled by the following function
1036 def closepoints(normsubpath, intersections):
1037 split = normsubpath.segments([0] + [intersection for intersection, index in intersections] + [len(normsubpath)])
1038 result = []
1039 if normsubpath.closed:
1040 # note that the number of segments of a closed path is off by one
1041 # compared to an open path
1042 i = 0
1043 while i < len(split):
1044 splitnormsubpath = split[i]
1045 j = i
1046 while not splitnormsubpath.normsubpathitems: # i.e. while "is short"
1047 ip1, ip2 = intersections[i-1][1], intersections[j][1]
1048 if ip1<ip2:
1049 result.append((ip1, ip2))
1050 else:
1051 result.append((ip2, ip1))
1052 j += 1
1053 if j == len(split):
1054 j = 0
1055 if j < len(split):
1056 splitnormsubpath = splitnormsubpath.joined(split[j])
1057 else:
1058 break
1059 i += 1
1060 else:
1061 i = 1
1062 while i < len(split)-1:
1063 splitnormsubpath = split[i]
1064 j = i
1065 while not splitnormsubpath.normsubpathitems: # i.e. while "is short"
1066 ip1, ip2 = intersections[i-1][1], intersections[j][1]
1067 if ip1<ip2:
1068 result.append((ip1, ip2))
1069 else:
1070 result.append((ip2, ip1))
1071 j += 1
1072 if j < len(split)-1:
1073 splitnormsubpath = splitnormsubpath.joined(split[j])
1074 else:
1075 break
1076 i += 1
1077 return result
1079 closepoints_a = closepoints(self, intersections_a)
1080 closepoints_b = closepoints(other, intersections_b)
1082 # map intersection point to lowest point which is equivalent to the
1083 # point
1084 equivalentpoints = list(range(len(intersections_a)))
1086 for closepoint_a in closepoints_a:
1087 for closepoint_b in closepoints_b:
1088 if closepoint_a == closepoint_b:
1089 for i in range(closepoint_a[1], len(equivalentpoints)):
1090 if equivalentpoints[i] == closepoint_a[1]:
1091 equivalentpoints[i] = closepoint_a[0]
1093 # determine the remaining intersection points
1094 intersectionpoints = {}
1095 for point in equivalentpoints:
1096 intersectionpoints[point] = 1
1098 # build result
1099 result = []
1100 intersectionpointskeys = intersectionpoints.keys()
1101 intersectionpointskeys.sort()
1102 for point in intersectionpointskeys:
1103 for intersection_a, index_a in intersections_a:
1104 if index_a == point:
1105 result_a = intersection_a
1106 for intersection_b, index_b in intersections_b:
1107 if index_b == point:
1108 result_b = intersection_b
1109 result.append((result_a, result_b))
1110 # note that the result is sorted in a, since we sorted
1111 # intersections_a in the very beginning
1113 return [x for x, y in result], [y for x, y in result]
1115 def join(self, other):
1116 """join other normsubpath inplace
1118 Fails on closed normsubpath. Fails to join closed normsubpath.
1120 if other.closed:
1121 raise NormpathException("Cannot join closed normsubpath")
1123 if self.normsubpathitems:
1124 # insert connection line
1125 x0_pt, y0_pt = self.atend_pt()
1126 x1_pt, y1_pt = other.atbegin_pt()
1127 self.append(normline_pt(x0_pt, y0_pt, x1_pt, y1_pt))
1129 # append other normsubpathitems
1130 self.extend(other.normsubpathitems)
1131 if other.skippedline:
1132 self.append(other.skippedline)
1134 def joined(self, other):
1135 """return joined self and other
1137 Fails on closed normsubpath. Fails to join closed normsubpath.
1139 result = self.copy()
1140 result.join(other)
1141 return result
1143 def _paramtoarclen_pt(self, params):
1144 """return a tuple of arc lengths and the total arc length in pts"""
1145 if not self.normsubpathitems:
1146 return [0] * len(params), 0
1147 result = [None] * len(params)
1148 totalarclen_pt = 0
1149 distributeparams = self._distributeparams(params)
1150 for normsubpathitemindex in range(len(self.normsubpathitems)):
1151 if distributeparams.has_key(normsubpathitemindex):
1152 indices, params = distributeparams[normsubpathitemindex]
1153 arclens_pt, normsubpathitemarclen_pt = self.normsubpathitems[normsubpathitemindex]._paramtoarclen_pt(params, self.epsilon)
1154 for index, arclen_pt in zip(indices, arclens_pt):
1155 result[index] = totalarclen_pt + arclen_pt
1156 totalarclen_pt += normsubpathitemarclen_pt
1157 else:
1158 totalarclen_pt += self.normsubpathitems[normsubpathitemindex].arclen_pt(self.epsilon)
1159 return result, totalarclen_pt
1161 def pathitems(self):
1162 """return list of pathitems"""
1163 if not self.normsubpathitems:
1164 return []
1166 # remove trailing normline_pt of closed subpaths
1167 if self.closed and isinstance(self.normsubpathitems[-1], normline_pt):
1168 normsubpathitems = self.normsubpathitems[:-1]
1169 else:
1170 normsubpathitems = self.normsubpathitems
1172 result = [path.moveto_pt(*self.atbegin_pt())]
1173 for normsubpathitem in normsubpathitems:
1174 result.append(normsubpathitem.pathitem())
1175 if self.closed:
1176 result.append(path.closepath())
1177 return result
1179 def reversed(self):
1180 """return reversed normsubpath"""
1181 nnormpathitems = []
1182 for i in range(len(self.normsubpathitems)):
1183 nnormpathitems.append(self.normsubpathitems[-(i+1)].reversed())
1184 return normsubpath(nnormpathitems, self.closed, self.epsilon)
1186 def rotation(self, params):
1187 """return rotations at params"""
1188 result = [None] * len(params)
1189 for normsubpathitemindex, (indices, params) in self._distributeparams(params).items():
1190 for index, rotation in zip(indices, self.normsubpathitems[normsubpathitemindex].rotation(params)):
1191 result[index] = rotation
1192 return result
1194 def segments(self, params):
1195 """return segments of the normsubpath
1197 The returned list of normsubpaths for the segments between
1198 the params. params need to contain at least two values.
1200 For a closed normsubpath the last segment result is joined to
1201 the first one when params starts with 0 and ends with len(self).
1202 or params starts with len(self) and ends with 0. Thus a segments
1203 operation on a closed normsubpath might properly join those the
1204 first and the last part to take into account the closed nature of
1205 the normsubpath. However, for intermediate parameters, closepath
1206 is not taken into account, i.e. when walking backwards you do not
1207 loop over the closepath forwardly. The special values 0 and
1208 len(self) for the first and the last parameter should be given as
1209 integers, i.e. no finite precision is used when checking for
1210 equality."""
1212 if len(params) < 2:
1213 raise ValueError("at least two parameters needed in segments")
1215 result = [normsubpath(epsilon=self.epsilon)]
1217 # instead of distribute the parameters, we need to keep their
1218 # order and collect parameters for the needed segments of
1219 # normsubpathitem with index collectindex
1220 collectparams = []
1221 collectindex = None
1222 for param in params:
1223 # calculate index and parameter for corresponding normsubpathitem
1224 if param > 0:
1225 index = int(param)
1226 if index > len(self.normsubpathitems) - 1:
1227 index = len(self.normsubpathitems) - 1
1228 param -= index
1229 else:
1230 index = 0
1231 if index != collectindex:
1232 if collectindex is not None:
1233 # append end point depening on the forthcoming index
1234 if index > collectindex:
1235 collectparams.append(1)
1236 else:
1237 collectparams.append(0)
1238 # get segments of the normsubpathitem and add them to the result
1239 segments = self.normsubpathitems[collectindex].segments(collectparams)
1240 result[-1].append(segments[0])
1241 result.extend([normsubpath([segment], epsilon=self.epsilon) for segment in segments[1:]])
1242 # add normsubpathitems and first segment parameter to close the
1243 # gap to the forthcoming index
1244 if index > collectindex:
1245 for i in range(collectindex+1, index):
1246 result[-1].append(self.normsubpathitems[i])
1247 collectparams = [0]
1248 else:
1249 for i in range(collectindex-1, index, -1):
1250 result[-1].append(self.normsubpathitems[i].reversed())
1251 collectparams = [1]
1252 collectindex = index
1253 collectparams.append(param)
1254 # add remaining collectparams to the result
1255 segments = self.normsubpathitems[collectindex].segments(collectparams)
1256 result[-1].append(segments[0])
1257 result.extend([normsubpath([segment], epsilon=self.epsilon) for segment in segments[1:]])
1259 if self.closed:
1260 # join last and first segment together if the normsubpath was
1261 # originally closed and first and the last parameters are the
1262 # beginning and end points of the normsubpath
1263 if ( ( params[0] == 0 and params[-1] == len(self.normsubpathitems) ) or
1264 ( params[-1] == 0 and params[0] == len(self.normsubpathitems) ) ):
1265 result[-1].normsubpathitems.extend(result[0].normsubpathitems)
1266 result = result[-1:] + result[1:-1]
1268 return result
1270 def trafo(self, params):
1271 """return transformations at params"""
1272 result = [None] * len(params)
1273 for normsubpathitemindex, (indices, params) in self._distributeparams(params).items():
1274 for index, trafo in zip(indices, self.normsubpathitems[normsubpathitemindex].trafo(params)):
1275 result[index] = trafo
1276 return result
1278 def transformed(self, trafo):
1279 """return transformed path"""
1280 nnormsubpath = normsubpath(epsilon=self.epsilon)
1281 for pitem in self.normsubpathitems:
1282 nnormsubpath.append(pitem.transformed(trafo))
1283 if self.closed:
1284 nnormsubpath.close()
1285 elif self.skippedline is not None:
1286 nnormsubpath.append(self.skippedline.transformed(trafo))
1287 return nnormsubpath
1289 def outputPS(self, file, writer):
1290 # if the normsubpath is closed, we must not output a normline at
1291 # the end
1292 if not self.normsubpathitems:
1293 return
1294 if self.closed and isinstance(self.normsubpathitems[-1], normline_pt):
1295 assert len(self.normsubpathitems) > 1, "a closed normsubpath should contain more than a single normline_pt"
1296 normsubpathitems = self.normsubpathitems[:-1]
1297 else:
1298 normsubpathitems = self.normsubpathitems
1299 file.write("%g %g moveto\n" % self.atbegin_pt())
1300 for anormsubpathitem in normsubpathitems:
1301 anormsubpathitem.outputPS(file, writer)
1302 if self.closed:
1303 file.write("closepath\n")
1305 def outputPDF(self, file, writer):
1306 # if the normsubpath is closed, we must not output a normline at
1307 # the end
1308 if not self.normsubpathitems:
1309 return
1310 if self.closed and isinstance(self.normsubpathitems[-1], normline_pt):
1311 assert len(self.normsubpathitems) > 1, "a closed normsubpath should contain more than a single normline_pt"
1312 normsubpathitems = self.normsubpathitems[:-1]
1313 else:
1314 normsubpathitems = self.normsubpathitems
1315 file.write("%f %f m\n" % self.atbegin_pt())
1316 for anormsubpathitem in normsubpathitems:
1317 anormsubpathitem.outputPDF(file, writer)
1318 if self.closed:
1319 file.write("h\n")
1322 ################################################################################
1323 # normpath
1324 ################################################################################
1326 class normpathparam:
1328 """parameter of a certain point along a normpath"""
1330 __slots__ = "normpath", "normsubpathindex", "normsubpathparam"
1332 def __init__(self, normpath, normsubpathindex, normsubpathparam):
1333 self.normpath = normpath
1334 self.normsubpathindex = normsubpathindex
1335 self.normsubpathparam = normsubpathparam
1336 float(normsubpathparam)
1338 def __str__(self):
1339 return "normpathparam(%s, %s, %s)" % (self.normpath, self.normsubpathindex, self.normsubpathparam)
1341 def __add__(self, other):
1342 if isinstance(other, normpathparam):
1343 assert self.normpath is other.normpath, "normpathparams have to belong to the same normpath"
1344 return self.normpath.arclentoparam_pt(self.normpath.paramtoarclen_pt(self) +
1345 other.normpath.paramtoarclen_pt(other))
1346 else:
1347 return self.normpath.arclentoparam_pt(self.normpath.paramtoarclen_pt(self) + unit.topt(other))
1349 __radd__ = __add__
1351 def __sub__(self, other):
1352 if isinstance(other, normpathparam):
1353 assert self.normpath is other.normpath, "normpathparams have to belong to the same normpath"
1354 return self.normpath.arclentoparam_pt(self.normpath.paramtoarclen_pt(self) -
1355 other.normpath.paramtoarclen_pt(other))
1356 else:
1357 return self.normpath.arclentoparam_pt(self.normpath.paramtoarclen_pt(self) - unit.topt(other))
1359 def __rsub__(self, other):
1360 # other has to be a length in this case
1361 return self.normpath.arclentoparam_pt(-self.normpath.paramtoarclen_pt(self) + unit.topt(other))
1363 def __mul__(self, factor):
1364 return self.normpath.arclentoparam_pt(self.normpath.paramtoarclen_pt(self) * factor)
1366 __rmul__ = __mul__
1368 def __div__(self, divisor):
1369 return self.normpath.arclentoparam_pt(self.normpath.paramtoarclen_pt(self) / divisor)
1371 def __neg__(self):
1372 return self.normpath.arclentoparam_pt(-self.normpath.paramtoarclen_pt(self))
1374 def __cmp__(self, other):
1375 if isinstance(other, normpathparam):
1376 assert self.normpath is other.normpath, "normpathparams have to belong to the same normpath"
1377 return cmp((self.normsubpathindex, self.normsubpathparam), (other.normsubpathindex, other.normsubpathparam))
1378 else:
1379 return cmp(self.normpath.paramtoarclen_pt(self), unit.topt(other))
1381 def arclen_pt(self):
1382 """return arc length in pts corresponding to the normpathparam """
1383 return self.normpath.paramtoarclen_pt(self)
1385 def arclen(self):
1386 """return arc length corresponding to the normpathparam """
1387 return self.normpath.paramtoarclen(self)
1390 def _valueorlistmethod(method):
1391 """Creates a method which takes a single argument or a list and
1392 returns a single value or a list out of method, which always
1393 works on lists."""
1395 def wrappedmethod(self, valueorlist, *args, **kwargs):
1396 try:
1397 for item in valueorlist:
1398 break
1399 except:
1400 return method(self, [valueorlist], *args, **kwargs)[0]
1401 return method(self, valueorlist, *args, **kwargs)
1402 return wrappedmethod
1405 class normpath:
1407 """normalized path
1409 A normalized path consists of a list of normsubpaths.
1412 def __init__(self, normsubpaths=None):
1413 """construct a normpath from a list of normsubpaths"""
1415 if normsubpaths is None:
1416 self.normsubpaths = [] # make a fresh list
1417 else:
1418 self.normsubpaths = normsubpaths
1419 for subpath in normsubpaths:
1420 assert isinstance(subpath, normsubpath), "only list of normsubpath instances allowed"
1422 def __add__(self, other):
1423 """create new normpath out of self and other"""
1424 result = self.copy()
1425 result += other
1426 return result
1428 def __iadd__(self, other):
1429 """add other inplace"""
1430 for normsubpath in other.normpath().normsubpaths:
1431 self.normsubpaths.append(normsubpath.copy())
1432 return self
1434 def __getitem__(self, i):
1435 """return normsubpath i"""
1436 return self.normsubpaths[i]
1438 def __len__(self):
1439 """return the number of normsubpaths"""
1440 return len(self.normsubpaths)
1442 def __str__(self):
1443 return "normpath([%s])" % ", ".join(map(str, self.normsubpaths))
1445 def _convertparams(self, params, convertmethod):
1446 """return params with all non-normpathparam arguments converted by convertmethod
1448 usecases:
1449 - self._convertparams(params, self.arclentoparam_pt)
1450 - self._convertparams(params, self.arclentoparam)
1453 converttoparams = []
1454 convertparamindices = []
1455 for i, param in enumerate(params):
1456 if not isinstance(param, normpathparam):
1457 converttoparams.append(param)
1458 convertparamindices.append(i)
1459 if converttoparams:
1460 params = params[:]
1461 for i, param in zip(convertparamindices, convertmethod(converttoparams)):
1462 params[i] = param
1463 return params
1465 def _distributeparams(self, params):
1466 """return a dictionary mapping subpathindices to a tuple of a paramindices and subpathparams
1468 subpathindex specifies a subpath containing one or several positions.
1469 paramindex specify the index of the normpathparam in the original list and
1470 subpathparam is the parameter value in the subpath.
1473 result = {}
1474 for i, param in enumerate(params):
1475 assert param.normpath is self, "normpathparam has to belong to this path"
1476 result.setdefault(param.normsubpathindex, ([], []))
1477 result[param.normsubpathindex][0].append(i)
1478 result[param.normsubpathindex][1].append(param.normsubpathparam)
1479 return result
1481 def append(self, item):
1482 """append a normpath by a normsubpath or a pathitem"""
1483 if isinstance(item, normsubpath):
1484 # the normsubpaths list can be appended by a normsubpath only
1485 self.normsubpaths.append(item)
1486 elif isinstance(item, path.pathitem):
1487 # ... but we are kind and allow for regular path items as well
1488 # in order to make a normpath to behave more like a regular path
1489 if self.normsubpaths:
1490 context = path.context(*(self.normsubpaths[-1].atend_pt() +
1491 self.normsubpaths[-1].atbegin_pt()))
1492 item.updatenormpath(self, context)
1493 else:
1494 self.normsubpaths = item.createnormpath(self).normsubpaths
1496 def arclen_pt(self):
1497 """return arc length in pts"""
1498 return sum([normsubpath.arclen_pt() for normsubpath in self.normsubpaths])
1500 def arclen(self):
1501 """return arc length"""
1502 return self.arclen_pt() * unit.t_pt
1504 def _arclentoparam_pt(self, lengths_pt):
1505 """return the params matching the given lengths_pt"""
1506 # work on a copy which is counted down to negative values
1507 lengths_pt = lengths_pt[:]
1508 results = [None] * len(lengths_pt)
1510 for normsubpathindex, normsubpath in enumerate(self.normsubpaths):
1511 params, arclen = normsubpath._arclentoparam_pt(lengths_pt)
1512 done = 1
1513 for i, result in enumerate(results):
1514 if results[i] is None:
1515 lengths_pt[i] -= arclen
1516 if lengths_pt[i] < 0 or normsubpathindex == len(self.normsubpaths) - 1:
1517 # overwrite the results until the length has become negative
1518 results[i] = normpathparam(self, normsubpathindex, params[i])
1519 done = 0
1520 if done:
1521 break
1523 return results
1525 def arclentoparam_pt(self, lengths_pt):
1526 """return the param(s) matching the given length(s)_pt in pts"""
1527 pass
1528 arclentoparam_pt = _valueorlistmethod(_arclentoparam_pt)
1530 def arclentoparam(self, lengths):
1531 """return the param(s) matching the given length(s)"""
1532 return self._arclentoparam_pt([unit.topt(l) for l in lengths])
1533 arclentoparam = _valueorlistmethod(arclentoparam)
1535 def _at_pt(self, params):
1536 """return coordinates of normpath in pts at params"""
1537 result = [None] * len(params)
1538 for normsubpathindex, (indices, params) in self._distributeparams(params).items():
1539 for index, point_pt in zip(indices, self.normsubpaths[normsubpathindex].at_pt(params)):
1540 result[index] = point_pt
1541 return result
1543 def at_pt(self, params):
1544 """return coordinates of normpath in pts at param(s) or lengths in pts"""
1545 return self._at_pt(self._convertparams(params, self.arclentoparam_pt))
1546 at_pt = _valueorlistmethod(at_pt)
1548 def at(self, params):
1549 """return coordinates of normpath at param(s) or arc lengths"""
1550 return [(x_pt * unit.t_pt, y_pt * unit.t_pt)
1551 for x_pt, y_pt in self._at_pt(self._convertparams(params, self.arclentoparam))]
1552 at = _valueorlistmethod(at)
1554 def atbegin_pt(self):
1555 """return coordinates of the beginning of first subpath in normpath in pts"""
1556 if self.normsubpaths:
1557 return self.normsubpaths[0].atbegin_pt()
1558 else:
1559 raise NormpathException("cannot return first point of empty path")
1561 def atbegin(self):
1562 """return coordinates of the beginning of first subpath in normpath"""
1563 x, y = self.atbegin_pt()
1564 return x * unit.t_pt, y * unit.t_pt
1566 def atend_pt(self):
1567 """return coordinates of the end of last subpath in normpath in pts"""
1568 if self.normsubpaths:
1569 return self.normsubpaths[-1].atend_pt()
1570 else:
1571 raise NormpathException("cannot return last point of empty path")
1573 def atend(self):
1574 """return coordinates of the end of last subpath in normpath"""
1575 x, y = self.atend_pt()
1576 return x * unit.t_pt, y * unit.t_pt
1578 def bbox(self):
1579 """return bbox of normpath"""
1580 abbox = bboxmodule.empty()
1581 for normsubpath in self.normsubpaths:
1582 abbox += normsubpath.bbox()
1583 return abbox
1585 def begin(self):
1586 """return param corresponding of the beginning of the normpath"""
1587 if self.normsubpaths:
1588 return normpathparam(self, 0, 0)
1589 else:
1590 raise NormpathException("empty path")
1592 def copy(self):
1593 """return copy of normpath"""
1594 result = normpath()
1595 for normsubpath in self.normsubpaths:
1596 result.append(normsubpath.copy())
1597 return result
1599 def _curvature_pt(self, params):
1600 """return the curvature in 1/pts at params
1602 When the curvature is undefined, the invalid instance is returned."""
1604 result = [None] * len(params)
1605 for normsubpathindex, (indices, params) in self._distributeparams(params).items():
1606 for index, curvature_pt in zip(indices, self.normsubpaths[normsubpathindex].curvature_pt(params)):
1607 result[index] = curvature_pt
1608 return result
1610 def curvature_pt(self, params):
1611 """return the curvature in 1/pt at params
1613 The curvature radius is the inverse of the curvature. When the
1614 curvature is undefined, the invalid instance is returned. Note that
1615 this radius can be negative or positive, depending on the sign of the
1616 curvature."""
1618 result = [None] * len(params)
1619 for normsubpathindex, (indices, params) in self._distributeparams(params).items():
1620 for index, curv_pt in zip(indices, self.normsubpaths[normsubpathindex].curvature_pt(params)):
1621 result[index] = curv_pt
1622 return result
1623 curvature_pt = _valueorlistmethod(curvature_pt)
1625 def _curveradius_pt(self, params):
1626 """return the curvature radius at params in pts
1628 The curvature radius is the inverse of the curvature. When the
1629 curvature is 0, None is returned. Note that this radius can be negative
1630 or positive, depending on the sign of the curvature."""
1632 result = [None] * len(params)
1633 for normsubpathindex, (indices, params) in self._distributeparams(params).items():
1634 for index, radius_pt in zip(indices, self.normsubpaths[normsubpathindex].curveradius_pt(params)):
1635 result[index] = radius_pt
1636 return result
1638 def curveradius_pt(self, params):
1639 """return the curvature radius in pts at param(s) or arc length(s) in pts
1641 The curvature radius is the inverse of the curvature. When the
1642 curvature is 0, None is returned. Note that this radius can be negative
1643 or positive, depending on the sign of the curvature."""
1645 return self._curveradius_pt(self._convertparams(params, self.arclentoparam_pt))
1646 curveradius_pt = _valueorlistmethod(curveradius_pt)
1648 def curveradius(self, params):
1649 """return the curvature radius at param(s) or arc length(s)
1651 The curvature radius is the inverse of the curvature. When the
1652 curvature is 0, None is returned. Note that this radius can be negative
1653 or positive, depending on the sign of the curvature."""
1655 result = []
1656 for radius_pt in self._curveradius_pt(self._convertparams(params, self.arclentoparam)):
1657 if radius_pt is not invalid:
1658 result.append(radius_pt * unit.t_pt)
1659 else:
1660 result.append(invalid)
1661 return result
1662 curveradius = _valueorlistmethod(curveradius)
1664 def end(self):
1665 """return param corresponding of the end of the path"""
1666 if self.normsubpaths:
1667 return normpathparam(self, len(self)-1, len(self.normsubpaths[-1]))
1668 else:
1669 raise NormpathException("empty path")
1671 def extend(self, normsubpaths):
1672 """extend path by normsubpaths or pathitems"""
1673 for anormsubpath in normsubpaths:
1674 # use append to properly handle regular path items as well as normsubpaths
1675 self.append(anormsubpath)
1677 def intersect(self, other):
1678 """intersect self with other path
1680 Returns a tuple of lists consisting of the parameter values
1681 of the intersection points of the corresponding normpath.
1683 other = other.normpath()
1685 # here we build up the result
1686 intersections = ([], [])
1688 # Intersect all normsubpaths of self with the normsubpaths of
1689 # other.
1690 for ia, normsubpath_a in enumerate(self.normsubpaths):
1691 for ib, normsubpath_b in enumerate(other.normsubpaths):
1692 for intersection in zip(*normsubpath_a.intersect(normsubpath_b)):
1693 intersections[0].append(normpathparam(self, ia, intersection[0]))
1694 intersections[1].append(normpathparam(other, ib, intersection[1]))
1695 return intersections
1697 def join(self, other):
1698 """join other normsubpath inplace
1700 Both normpaths must contain at least one normsubpath.
1701 The last normsubpath of self will be joined to the first
1702 normsubpath of other.
1704 other = other.normpath()
1706 if not self.normsubpaths:
1707 raise NormpathException("cannot join to empty path")
1708 if not other.normsubpaths:
1709 raise NormpathException("cannot join empty path")
1710 self.normsubpaths[-1].join(other.normsubpaths[0])
1711 self.normsubpaths.extend(other.normsubpaths[1:])
1713 def joined(self, other):
1714 """return joined self and other
1716 Both normpaths must contain at least one normsubpath.
1717 The last normsubpath of self will be joined to the first
1718 normsubpath of other.
1720 result = self.copy()
1721 result.join(other.normpath())
1722 return result
1724 # << operator also designates joining
1725 __lshift__ = joined
1727 def normpath(self):
1728 """return a normpath, i.e. self"""
1729 return self
1731 def _paramtoarclen_pt(self, params):
1732 """return arc lengths in pts matching the given params"""
1733 result = [None] * len(params)
1734 totalarclen_pt = 0
1735 distributeparams = self._distributeparams(params)
1736 for normsubpathindex in range(max(distributeparams.keys()) + 1):
1737 if distributeparams.has_key(normsubpathindex):
1738 indices, params = distributeparams[normsubpathindex]
1739 arclens_pt, normsubpatharclen_pt = self.normsubpaths[normsubpathindex]._paramtoarclen_pt(params)
1740 for index, arclen_pt in zip(indices, arclens_pt):
1741 result[index] = totalarclen_pt + arclen_pt
1742 totalarclen_pt += normsubpatharclen_pt
1743 else:
1744 totalarclen_pt += self.normsubpaths[normsubpathindex].arclen_pt()
1745 return result
1747 def paramtoarclen_pt(self, params):
1748 """return arc length(s) in pts matching the given param(s)"""
1749 paramtoarclen_pt = _valueorlistmethod(_paramtoarclen_pt)
1751 def paramtoarclen(self, params):
1752 """return arc length(s) matching the given param(s)"""
1753 return [arclen_pt * unit.t_pt for arclen_pt in self._paramtoarclen_pt(params)]
1754 paramtoarclen = _valueorlistmethod(paramtoarclen)
1756 def path(self):
1757 """return path corresponding to normpath"""
1758 pathitems = []
1759 for normsubpath in self.normsubpaths:
1760 pathitems.extend(normsubpath.pathitems())
1761 return path.path(*pathitems)
1763 def reversed(self):
1764 """return reversed path"""
1765 nnormpath = normpath()
1766 for i in range(len(self.normsubpaths)):
1767 nnormpath.normsubpaths.append(self.normsubpaths[-(i+1)].reversed())
1768 return nnormpath
1770 def _rotation(self, params):
1771 """return rotation at params"""
1772 result = [None] * len(params)
1773 for normsubpathindex, (indices, params) in self._distributeparams(params).items():
1774 for index, rotation in zip(indices, self.normsubpaths[normsubpathindex].rotation(params)):
1775 result[index] = rotation
1776 return result
1778 def rotation_pt(self, params):
1779 """return rotation at param(s) or arc length(s) in pts"""
1780 return self._rotation(self._convertparams(params, self.arclentoparam_pt))
1781 rotation_pt = _valueorlistmethod(rotation_pt)
1783 def rotation(self, params):
1784 """return rotation at param(s) or arc length(s)"""
1785 return self._rotation(self._convertparams(params, self.arclentoparam))
1786 rotation = _valueorlistmethod(rotation)
1788 def _split_pt(self, params):
1789 """split path at params and return list of normpaths"""
1790 if not params:
1791 return [self.copy()]
1793 # instead of distributing the parameters, we need to keep their
1794 # order and collect parameters for splitting of normsubpathitem
1795 # with index collectindex
1796 collectindex = None
1797 for param in params:
1798 if param.normsubpathindex != collectindex:
1799 if collectindex is not None:
1800 # append end point depening on the forthcoming index
1801 if param.normsubpathindex > collectindex:
1802 collectparams.append(len(self.normsubpaths[collectindex]))
1803 else:
1804 collectparams.append(0)
1805 # get segments of the normsubpath and add them to the result
1806 segments = self.normsubpaths[collectindex].segments(collectparams)
1807 result[-1].append(segments[0])
1808 result.extend([normpath([segment]) for segment in segments[1:]])
1809 # add normsubpathitems and first segment parameter to close the
1810 # gap to the forthcoming index
1811 if param.normsubpathindex > collectindex:
1812 for i in range(collectindex+1, param.normsubpathindex):
1813 result[-1].append(self.normsubpaths[i])
1814 collectparams = [0]
1815 else:
1816 for i in range(collectindex-1, param.normsubpathindex, -1):
1817 result[-1].append(self.normsubpaths[i].reversed())
1818 collectparams = [len(self.normsubpaths[param.normsubpathindex])]
1819 else:
1820 result = [normpath(self.normsubpaths[:param.normsubpathindex])]
1821 collectparams = [0]
1822 collectindex = param.normsubpathindex
1823 collectparams.append(param.normsubpathparam)
1824 # add remaining collectparams to the result
1825 collectparams.append(len(self.normsubpaths[collectindex]))
1826 segments = self.normsubpaths[collectindex].segments(collectparams)
1827 result[-1].append(segments[0])
1828 result.extend([normpath([segment]) for segment in segments[1:]])
1829 result[-1].extend(self.normsubpaths[collectindex+1:])
1830 return result
1832 def split_pt(self, params):
1833 """split path at param(s) or arc length(s) in pts and return list of normpaths"""
1834 try:
1835 for param in params:
1836 break
1837 except:
1838 params = [params]
1839 return self._split_pt(self._convertparams(params, self.arclentoparam_pt))
1841 def split(self, params):
1842 """split path at param(s) or arc length(s) and return list of normpaths"""
1843 try:
1844 for param in params:
1845 break
1846 except:
1847 params = [params]
1848 return self._split_pt(self._convertparams(params, self.arclentoparam))
1850 def _tangent(self, params, length_pt):
1851 """return tangent vector of path at params
1853 If length_pt in pts is not None, the tangent vector will be scaled to
1854 the desired length.
1857 result = [None] * len(params)
1858 tangenttemplate = path.line_pt(0, 0, length_pt, 0).normpath()
1859 for normsubpathindex, (indices, params) in self._distributeparams(params).items():
1860 for index, atrafo in zip(indices, self.normsubpaths[normsubpathindex].trafo(params)):
1861 if atrafo is invalid:
1862 result[index] = invalid
1863 else:
1864 result[index] = tangenttemplate.transformed(atrafo)
1865 return result
1867 def tangent_pt(self, params, length_pt):
1868 """return tangent vector of path at param(s) or arc length(s) in pts
1870 If length in pts is not None, the tangent vector will be scaled to
1871 the desired length.
1873 return self._tangent(self._convertparams(params, self.arclentoparam_pt), length_pt)
1874 tangent_pt = _valueorlistmethod(tangent_pt)
1876 def tangent(self, params, length=1):
1877 """return tangent vector of path at param(s) or arc length(s)
1879 If length is not None, the tangent vector will be scaled to
1880 the desired length.
1882 return self._tangent(self._convertparams(params, self.arclentoparam), unit.topt(length))
1883 tangent = _valueorlistmethod(tangent)
1885 def _trafo(self, params):
1886 """return transformation at params"""
1887 result = [None] * len(params)
1888 for normsubpathindex, (indices, params) in self._distributeparams(params).items():
1889 for index, trafo in zip(indices, self.normsubpaths[normsubpathindex].trafo(params)):
1890 result[index] = trafo
1891 return result
1893 def trafo_pt(self, params):
1894 """return transformation at param(s) or arc length(s) in pts"""
1895 return self._trafo(self._convertparams(params, self.arclentoparam_pt))
1896 trafo_pt = _valueorlistmethod(trafo_pt)
1898 def trafo(self, params):
1899 """return transformation at param(s) or arc length(s)"""
1900 return self._trafo(self._convertparams(params, self.arclentoparam))
1901 trafo = _valueorlistmethod(trafo)
1903 def transformed(self, trafo):
1904 """return transformed normpath"""
1905 return normpath([normsubpath.transformed(trafo) for normsubpath in self.normsubpaths])
1907 def outputPS(self, file, writer):
1908 for normsubpath in self.normsubpaths:
1909 normsubpath.outputPS(file, writer)
1911 def outputPDF(self, file, writer):
1912 for normsubpath in self.normsubpaths:
1913 normsubpath.outputPDF(file, writer)