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from fontTools.misc.arrayTools import pairwise
from fontTools.pens.filterPen import ContourFilterPen
__all__ = ["reversedContour", "ReverseContourPen"]
class ReverseContourPen(ContourFilterPen):
"""Filter pen that passes outline data to another pen, but reversing
the winding direction of all contours. Components are simply passed
through unchanged.
Closed contours are reversed in such a way that the first point remains
the first point.
"""
def __init__(self, outPen, outputImpliedClosingLine=False):
super().__init__(outPen)
self.outputImpliedClosingLine = outputImpliedClosingLine
def filterContour(self, contour):
return reversedContour(contour, self.outputImpliedClosingLine)
def reversedContour(contour, outputImpliedClosingLine=False):
"""Generator that takes a list of pen's (operator, operands) tuples,
and yields them with the winding direction reversed.
"""
if not contour:
return # nothing to do, stop iteration
# valid contours must have at least a starting and ending command,
# can't have one without the other
assert len(contour) > 1, "invalid contour"
# the type of the last command determines if the contour is closed
contourType = contour.pop()[0]
assert contourType in ("endPath", "closePath")
closed = contourType == "closePath"
firstType, firstPts = contour.pop(0)
assert firstType in ("moveTo", "qCurveTo"), (
"invalid initial segment type: %r" % firstType
)
firstOnCurve = firstPts[-1]
if firstType == "qCurveTo":
# special case for TrueType paths contaning only off-curve points
assert firstOnCurve is None, "off-curve only paths must end with 'None'"
assert not contour, "only one qCurveTo allowed per off-curve path"
firstPts = (firstPts[0],) + tuple(reversed(firstPts[1:-1])) + (None,)
if not contour:
# contour contains only one segment, nothing to reverse
if firstType == "moveTo":
closed = False # single-point paths can't be closed
else:
closed = True # off-curve paths are closed by definition
yield firstType, firstPts
else:
lastType, lastPts = contour[-1]
lastOnCurve = lastPts[-1]
if closed:
# for closed paths, we keep the starting point
yield firstType, firstPts
if firstOnCurve != lastOnCurve:
# emit an implied line between the last and first points
yield "lineTo", (lastOnCurve,)
contour[-1] = (lastType, tuple(lastPts[:-1]) + (firstOnCurve,))
if len(contour) > 1:
secondType, secondPts = contour[0]
else:
# contour has only two points, the second and last are the same
secondType, secondPts = lastType, lastPts
if not outputImpliedClosingLine:
# if a lineTo follows the initial moveTo, after reversing it
# will be implied by the closePath, so we don't emit one;
# unless the lineTo and moveTo overlap, in which case we keep the
# duplicate points
if secondType == "lineTo" and firstPts != secondPts:
del contour[0]
if contour:
contour[-1] = (lastType, tuple(lastPts[:-1]) + secondPts)
else:
# for open paths, the last point will become the first
yield firstType, (lastOnCurve,)
contour[-1] = (lastType, tuple(lastPts[:-1]) + (firstOnCurve,))
# we iterate over all segment pairs in reverse order, and yield
# each one with the off-curve points reversed (if any), and
# with the on-curve point of the following segment
for (curType, curPts), (_, nextPts) in pairwise(contour, reverse=True):
yield curType, tuple(reversed(curPts[:-1])) + (nextPts[-1],)
yield "closePath" if closed else "endPath", ()
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