8 .. sectionauthor:: Jörg Lehmann <joergl@users.sourceforge.net>
11 The :mod:`path` module defines several important classes which are documented in
15 .. _postscript_like_paths:
17 Class :class:`path` --- PostScript-like paths
18 ---------------------------------------------
20 .. class:: path(*pathitems)
22 This class represents a PostScript like path consisting of the path elements
25 All possible path items are described in Sect. :ref:`path_pathitem`. Note that
26 there are restrictions on the first path element and likewise on each path
27 element after a :class:`closepath` directive. In both cases, no current point is
28 defined and the path element has to be an instance of one of the following
29 classes: :class:`moveto`, :class:`arc`, and :class:`arcn`.
31 Instances of the class :class:`path` provide the following methods (in
35 .. method:: path.append(pathitem)
37 Appends a *pathitem* to the end of the path.
40 .. method:: path.arclen()
42 Returns the total arc length of the path. [#normpathconvert]_
45 .. method:: path.arclentoparam(lengths)
47 Returns the parameter value(s) corresponding to the arc length(s) *lengths*.
51 .. method:: path.at(params)
53 Returns the coordinates (as 2-tuple) of the path point(s) corresponding to the
54 parameter value(s) *params*. [#normpathconvert]_ [#value_or_list]_
57 .. method:: path.atbegin()
59 Returns the coordinates (as 2-tuple) of the first point of the path. [#normpathconvert]_
62 .. method:: path.atend()
64 Returns the coordinates (as 2-tuple) of the end point of the path. [#normpathconvert]_
67 .. method:: path.bbox()
69 Returns the bounding box of the path.
72 .. method:: path.begin()
74 Returns the parameter value (a :class:`normpathparam` instance) of the first
78 .. method:: path.curveradius(params)
80 Returns the curvature radius/radii (or None if infinite) at parameter value(s)
81 *params*. [#value_or_list]_ This is the inverse of the curvature at this
82 parameter. Note that this radius can be negative or positive, depending on the
83 sign of the curvature. [#normpathconvert]_
86 .. method:: path.end()
88 Returns the parameter value (a :class:`normpathparam` instance) of the last
92 .. method:: path.extend(pathitems)
94 Appends the list *pathitems* to the end of the path.
97 .. method:: path.intersect(opath)
99 Returns a tuple consisting of two lists of parameter values corresponding to the
100 intersection points of the path with the other path *opath*, respectively.
101 [#normpathconvert]_ For intersection points which are not farther apart then
102 *epsilon* (defaulting to :math:`10^{-5}` PostScript points), only one is returned.
105 .. method:: path.joined(opath)
107 Appends *opath* to the end of the path, thereby merging the last subpath (which
108 must not be closed) of the path with the first sub path of *opath* and returns
109 the resulting new path. [#normpathconvert]_ Instead of using the
110 :meth:`joined` method, you can also join two paths together with help of the
111 ``<<`` operator, for instance ``p = p1 << p2``.
114 .. method:: path.normpath(epsilon=None)
116 Returns the equivalent :class:`normpath`. For the conversion and for later
117 calculations with this :class:`normpath` an accuracy of *epsilon* is used.
118 If *epsilon* is *None*, the global *epsilon* of the :mod:`path` module is
122 .. method:: path.paramtoarclen(params)
124 Returns the arc length(s) corresponding to the parameter value(s) *params*.
125 [#value_or_list]_ [#normpathconvert]_
128 .. method:: path.range()
130 Returns the maximal parameter value *param* that is allowed in the path methods.
133 .. method:: path.reversed()
135 Returns the reversed path. [#normpathconvert]_
138 .. method:: path.rotation(params)
140 Returns a transformation or a list of transformations, which rotate the
141 x-direction to the tangent vector and the y-direction to the normal vector
142 at the parameter value(s) *params*. [#value_or_list]_ [#normpathconvert]_
145 .. method:: path.split(params)
147 Splits the path at the parameter values *params*, which have to be sorted in
148 ascending order, and returns a corresponding list of :class:`normpath`
149 instances. [#normpathconvert]_
152 .. method:: path.tangent(params, length=1)
154 Return a :class:`line` instance or a list of :class:`line` instances,
155 corresponding to the tangent vectors at the parameter value(s) *params*.
156 [#value_or_list]_ The tangent vector will be scaled to the length *length*.
160 .. method:: path.trafo(params)
162 Returns a transformation or a list of tranformations, which translate the
163 origin to a point on the path corresponding to parameter value(s) *params*
164 and rotate the x-direction to the tangent vector and the y-direction to the
165 normal vector. [#normpathconvert]_
168 .. method:: path.transformed(trafo)
170 Returns the path transformed according to the linear transformation *trafo*.
171 Here, ``trafo`` must be an instance of the :class:`trafo.trafo` class.
175 .. [#normpathconvert]
176 This method requires a prior conversion of the path into a :class:`normpath`
177 instance. This is done automatically (using the precision *epsilon* set
178 globally using :meth:`path.set`). If you need a different *epsilon* for a
179 normpath, you also can perform the conversion manually.
182 In these methods, *params* may either be a single value or a
183 list. In the latter case, the result of the method will be a list consisting of
184 the results for each parameter. The parameter itself may either be a length
185 (or a number which is then interpreted as a user length) or an instance of the
186 class :class:`normpathparam`. In the former case, the length refers to the arc
187 length along the path.
195 The class :class:`pathitem` is the superclass of all PostScript path
196 construction primitives. It is never used directly, but only by instantiating
197 its subclasses, which correspond one by one to the PostScript primitives.
199 Except for the path elements ending in ``_pt``, all coordinates passed to the
200 path elements can be given as number (in which case they are interpreted as user
201 units with the currently set default type) or in PyX lengths.
203 The following operation move the current point and open a new subpath:
206 .. class:: moveto(x, y)
208 Path element which sets the current point to the absolute coordinates (*x*,
209 *y*). This operation opens a new subpath.
212 .. class:: rmoveto(dx, dy)
214 Path element which moves the current point by (*dx*, *dy*). This operation
217 Drawing a straight line can be accomplished using:
220 .. class:: lineto(x, y)
222 Path element which appends a straight line from the current point to the point
223 with absolute coordinates (*x*, *y*), which becomes the new current point.
226 .. class:: rlineto(dx, dy)
228 Path element which appends a straight line from the current point to the point
229 with relative coordinates (*dx*, *dy*), which becomes the new current point.
231 For the construction of arc segments, the following three operations are
235 .. class:: arc(x, y, r, angle1, angle2)
237 Path element which appends an arc segment in counterclockwise direction with
238 absolute coordinates (*x*, *y*) of the center and radius *r* from *angle1* to
239 *angle2* (in degrees). If before the operation, the current point is defined, a
240 straight line from the current point to the beginning of the arc segment is
241 prepended. Otherwise, a subpath, which thus is the first one in the path, is
242 opened. After the operation, the current point is at the end of the arc segment.
245 .. class:: arcn(x, y, r, angle1, angle2)
247 Same as :class:`arc` but in clockwise direction.
250 .. class:: arct(x1, y1, x2, y2, r)
252 Path element consisting of a line followed by an arc of radius *r*. The arc
253 is part of the circle inscribed to the angle at *x1*, *y1* given by lines in
254 the directions to the current point and to *x2*, *y2*. The initial line
255 connects the current point to the point where the circle touches the line
256 through the current point and *x1*, *y1*. The arc then continues to the
257 point where the circle touches the line through *x1*, *y1* and *x2*, *y2*.
259 Bézier curves can be constructed using:
261 .. class:: curveto(x1, y1, x2, y2, x3, y3)
263 Path element which appends a Bézier curve with the current point as first
264 control point and the other control points (*x1*, *y1*), (*x2*, *y2*), and
268 .. class:: rcurveto(dx1, dy1, dx2, dy2, dx3, dy3)
270 Path element which appends a Bézier curve with the current point as first
271 control point and the other control points defined relative to the current point
272 by the coordinates (*dx1*, *dy1*), (*dx2*, *dy2*), and (*dx3*, *dy3*).
274 Note that when calculating the bounding box (see Sect. :mod:`bbox`) of Bézier
275 curves, PyX uses for performance reasons the so-called control box, i.e., the
276 smallest rectangle enclosing the four control points of the Bézier curve. In
277 general, this is not the smallest rectangle enclosing the Bézier curve.
279 Finally, an open subpath can be closed using:
282 .. class:: closepath()
284 Path element which closes the current subpath.
286 For performance reasons, two non-PostScript path elements are defined, which
287 perform multiple identical operations:
290 .. class:: multilineto_pt(points_pt)
292 Path element which appends straight line segments starting from the current
293 point and going through the list of points given in the *points_pt*
294 argument. All coordinates have to be given in PostScript points.
297 .. class:: multicurveto_pt(points_pt)
299 Path element which appends Bézier curve segments starting from the current
300 point. *points_pt* is a sequence of 6-tuples containing the coordinates of
301 the two control points and the end point of a multicurveto segment.
306 Class :class:`normpath`
307 -----------------------
309 The :class:`normpath` class is used internally for all non-trivial path
310 operations, cf. footnote [#normpathconvert]_ in Sect. :ref:`postscript_like_paths`.
311 It represents a path as a list of subpaths, which are
312 instances of the class :class:`normsubpath`. These :class:`normsubpath`\ s
313 themselves consist of a list of :class:`normsubpathitems` which are either
314 straight lines (:class:`normline`) or Bézier curves (:class:`normcurve`).
316 A given path ``p`` can easily be converted to the corresponding
317 :class:`normpath` ``np`` by::
321 Additionally, the accuracy that is used in all :class:`normpath` calculations can be
322 specified by means of the argument *epsilon*, which defaults to
323 :math:`10^{-5}`, where units of PostScript points are understood. This default
324 value can also be changed using the module function :func:`path.set`.
326 To construct a :class:`normpath` from a list of :class:`normsubpath` instances,
327 they are passed to the :class:`normpath` constructor:
329 .. class:: normpath(normsubpaths=[])
331 Construct a :class:`normpath` consisting of *subnormpaths*, which is a list of
332 :class:`subnormpath` instances.
334 Instances of :class:`normpath` offer all methods of regular :class:`path` instances,
335 which also have the same semantics. An exception are the methods :meth:`append`
336 and :meth:`extend`. While they allow for adding of instances of
337 :class:`subnormpath` to the :class:`normpath` instance, they also keep the
338 functionality of a regular path and allow for regular path elements to be
339 appended. The latter are converted to the proper normpath representation during
342 In addition to the :class:`path` methods, a :class:`normpath` instance also
343 offers the following methods, which operate on the instance itself, i.e., modify
347 .. method:: normpath.join(other)
349 Join *other*, which has to be a :class:`path` instance, to the :class:`normpath`
353 .. method:: normpath.reverse()
355 Reverses the :class:`normpath` instance.
358 .. method:: normpath.transform(trafo)
360 Transforms the :class:`normpath` instance according to the linear transformation
363 Finally, we remark that the sum of a :class:`normpath` and a :class:`path`
364 always yields a :class:`normpath`.
367 Class :class:`normsubpath`
368 --------------------------
371 .. class:: normsubpath(normsubpathitems=[], closed=0, epsilon=1e-5)
373 Construct a :class:`normsubpath` consisting of *normsubpathitems*, which is a
374 list of :class:`normsubpathitem` instances. If *closed* is set, the
375 :class:`normsubpath` will be closed, thereby appending a straight line segment
376 from the first to the last point, if it is not already present. All calculations
377 with the :class:`normsubpath` are performed with an accuracy of *epsilon*
378 (in units of PostScript points).
380 Most :class:`normsubpath` methods behave like the ones of a :class:`path`.
385 .. method:: normsubpath.append(anormsubpathitem)
387 Append the *normsubpathitem* to the end of the :class:`normsubpath` instance.
388 This is only possible if the :class:`normsubpath` is not closed, otherwise an
389 :exc:`NormpathException` is raised.
392 .. method:: normsubpath.extend(normsubpathitems)
394 Extend the :class:`normsubpath` instances by *normsubpathitems*, which has to be
395 a list of :class:`normsubpathitem` instances. This is only possible if the
396 :class:`normsubpath` is not closed, otherwise an :exc:`NormpathException` is
400 .. method:: normsubpath.close()
402 Close the :class:`normsubpath` instance by appending a straight line
403 segment from the first to the last point, if not already present.
412 For convenience, some often used paths are already predefined. All of them are
413 subclasses of the :class:`path` class.
416 .. class:: line(x0, y0, x1, y1)
418 A straight line from the point (*x0*, *y0*) to the point (*x1*, *y1*).
421 .. class:: curve(x0, y0, x1, y1, x2, y2, x3, y3)
423 A Bézier curve with control points (*x0*, *y0*), :math:`\dots`, (*x3*, *y3*).\
426 .. class:: rect(x, y, w, h)
428 A closed rectangle with lower left point (*x*, *y*), width *w*, and height *h*.
431 .. class:: circle(x, y, r)
433 A closed circle with center (*x*, *y*) and radius *r*.