AIM-PIbd-32-Kurbanova-A-A/aimenv/Lib/site-packages/fontTools/pens/ttGlyphPen.py

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2024-10-02 22:15:59 +04:00
from array import array
from typing import Any, Callable, Dict, Optional, Tuple
from fontTools.misc.fixedTools import MAX_F2DOT14, floatToFixedToFloat
from fontTools.misc.loggingTools import LogMixin
from fontTools.pens.pointPen import AbstractPointPen
from fontTools.misc.roundTools import otRound
from fontTools.pens.basePen import LoggingPen, PenError
from fontTools.pens.transformPen import TransformPen, TransformPointPen
from fontTools.ttLib.tables import ttProgram
from fontTools.ttLib.tables._g_l_y_f import flagOnCurve, flagCubic
from fontTools.ttLib.tables._g_l_y_f import Glyph
from fontTools.ttLib.tables._g_l_y_f import GlyphComponent
from fontTools.ttLib.tables._g_l_y_f import GlyphCoordinates
from fontTools.ttLib.tables._g_l_y_f import dropImpliedOnCurvePoints
import math
__all__ = ["TTGlyphPen", "TTGlyphPointPen"]
class _TTGlyphBasePen:
def __init__(
self,
glyphSet: Optional[Dict[str, Any]],
handleOverflowingTransforms: bool = True,
) -> None:
"""
Construct a new pen.
Args:
glyphSet (Dict[str, Any]): A glyphset object, used to resolve components.
handleOverflowingTransforms (bool): See below.
If ``handleOverflowingTransforms`` is True, the components' transform values
are checked that they don't overflow the limits of a F2Dot14 number:
-2.0 <= v < +2.0. If any transform value exceeds these, the composite
glyph is decomposed.
An exception to this rule is done for values that are very close to +2.0
(both for consistency with the -2.0 case, and for the relative frequency
these occur in real fonts). When almost +2.0 values occur (and all other
values are within the range -2.0 <= x <= +2.0), they are clamped to the
maximum positive value that can still be encoded as an F2Dot14: i.e.
1.99993896484375.
If False, no check is done and all components are translated unmodified
into the glyf table, followed by an inevitable ``struct.error`` once an
attempt is made to compile them.
If both contours and components are present in a glyph, the components
are decomposed.
"""
self.glyphSet = glyphSet
self.handleOverflowingTransforms = handleOverflowingTransforms
self.init()
def _decompose(
self,
glyphName: str,
transformation: Tuple[float, float, float, float, float, float],
):
tpen = self.transformPen(self, transformation)
getattr(self.glyphSet[glyphName], self.drawMethod)(tpen)
def _isClosed(self):
"""
Check if the current path is closed.
"""
raise NotImplementedError
def init(self) -> None:
self.points = []
self.endPts = []
self.types = []
self.components = []
def addComponent(
self,
baseGlyphName: str,
transformation: Tuple[float, float, float, float, float, float],
identifier: Optional[str] = None,
**kwargs: Any,
) -> None:
"""
Add a sub glyph.
"""
self.components.append((baseGlyphName, transformation))
def _buildComponents(self, componentFlags):
if self.handleOverflowingTransforms:
# we can't encode transform values > 2 or < -2 in F2Dot14,
# so we must decompose the glyph if any transform exceeds these
overflowing = any(
s > 2 or s < -2
for (glyphName, transformation) in self.components
for s in transformation[:4]
)
components = []
for glyphName, transformation in self.components:
if glyphName not in self.glyphSet:
self.log.warning(f"skipped non-existing component '{glyphName}'")
continue
if self.points or (self.handleOverflowingTransforms and overflowing):
# can't have both coordinates and components, so decompose
self._decompose(glyphName, transformation)
continue
component = GlyphComponent()
component.glyphName = glyphName
component.x, component.y = (otRound(v) for v in transformation[4:])
# quantize floats to F2Dot14 so we get same values as when decompiled
# from a binary glyf table
transformation = tuple(
floatToFixedToFloat(v, 14) for v in transformation[:4]
)
if transformation != (1, 0, 0, 1):
if self.handleOverflowingTransforms and any(
MAX_F2DOT14 < s <= 2 for s in transformation
):
# clamp values ~= +2.0 so we can keep the component
transformation = tuple(
MAX_F2DOT14 if MAX_F2DOT14 < s <= 2 else s
for s in transformation
)
component.transform = (transformation[:2], transformation[2:])
component.flags = componentFlags
components.append(component)
return components
def glyph(
self,
componentFlags: int = 0x04,
dropImpliedOnCurves: bool = False,
*,
round: Callable[[float], int] = otRound,
) -> Glyph:
"""
Returns a :py:class:`~._g_l_y_f.Glyph` object representing the glyph.
Args:
componentFlags: Flags to use for component glyphs. (default: 0x04)
dropImpliedOnCurves: Whether to remove implied-oncurve points. (default: False)
"""
if not self._isClosed():
raise PenError("Didn't close last contour.")
components = self._buildComponents(componentFlags)
glyph = Glyph()
glyph.coordinates = GlyphCoordinates(self.points)
glyph.endPtsOfContours = self.endPts
glyph.flags = array("B", self.types)
self.init()
if components:
# If both components and contours were present, they have by now
# been decomposed by _buildComponents.
glyph.components = components
glyph.numberOfContours = -1
else:
glyph.numberOfContours = len(glyph.endPtsOfContours)
glyph.program = ttProgram.Program()
glyph.program.fromBytecode(b"")
if dropImpliedOnCurves:
dropImpliedOnCurvePoints(glyph)
glyph.coordinates.toInt(round=round)
return glyph
class TTGlyphPen(_TTGlyphBasePen, LoggingPen):
"""
Pen used for drawing to a TrueType glyph.
This pen can be used to construct or modify glyphs in a TrueType format
font. After using the pen to draw, use the ``.glyph()`` method to retrieve
a :py:class:`~._g_l_y_f.Glyph` object representing the glyph.
"""
drawMethod = "draw"
transformPen = TransformPen
def __init__(
self,
glyphSet: Optional[Dict[str, Any]] = None,
handleOverflowingTransforms: bool = True,
outputImpliedClosingLine: bool = False,
) -> None:
super().__init__(glyphSet, handleOverflowingTransforms)
self.outputImpliedClosingLine = outputImpliedClosingLine
def _addPoint(self, pt: Tuple[float, float], tp: int) -> None:
self.points.append(pt)
self.types.append(tp)
def _popPoint(self) -> None:
self.points.pop()
self.types.pop()
def _isClosed(self) -> bool:
return (not self.points) or (
self.endPts and self.endPts[-1] == len(self.points) - 1
)
def lineTo(self, pt: Tuple[float, float]) -> None:
self._addPoint(pt, flagOnCurve)
def moveTo(self, pt: Tuple[float, float]) -> None:
if not self._isClosed():
raise PenError('"move"-type point must begin a new contour.')
self._addPoint(pt, flagOnCurve)
def curveTo(self, *points) -> None:
assert len(points) % 2 == 1
for pt in points[:-1]:
self._addPoint(pt, flagCubic)
# last point is None if there are no on-curve points
if points[-1] is not None:
self._addPoint(points[-1], 1)
def qCurveTo(self, *points) -> None:
assert len(points) >= 1
for pt in points[:-1]:
self._addPoint(pt, 0)
# last point is None if there are no on-curve points
if points[-1] is not None:
self._addPoint(points[-1], 1)
def closePath(self) -> None:
endPt = len(self.points) - 1
# ignore anchors (one-point paths)
if endPt == 0 or (self.endPts and endPt == self.endPts[-1] + 1):
self._popPoint()
return
if not self.outputImpliedClosingLine:
# if first and last point on this path are the same, remove last
startPt = 0
if self.endPts:
startPt = self.endPts[-1] + 1
if self.points[startPt] == self.points[endPt]:
self._popPoint()
endPt -= 1
self.endPts.append(endPt)
def endPath(self) -> None:
# TrueType contours are always "closed"
self.closePath()
class TTGlyphPointPen(_TTGlyphBasePen, LogMixin, AbstractPointPen):
"""
Point pen used for drawing to a TrueType glyph.
This pen can be used to construct or modify glyphs in a TrueType format
font. After using the pen to draw, use the ``.glyph()`` method to retrieve
a :py:class:`~._g_l_y_f.Glyph` object representing the glyph.
"""
drawMethod = "drawPoints"
transformPen = TransformPointPen
def init(self) -> None:
super().init()
self._currentContourStartIndex = None
def _isClosed(self) -> bool:
return self._currentContourStartIndex is None
def beginPath(self, identifier: Optional[str] = None, **kwargs: Any) -> None:
"""
Start a new sub path.
"""
if not self._isClosed():
raise PenError("Didn't close previous contour.")
self._currentContourStartIndex = len(self.points)
def endPath(self) -> None:
"""
End the current sub path.
"""
# TrueType contours are always "closed"
if self._isClosed():
raise PenError("Contour is already closed.")
if self._currentContourStartIndex == len(self.points):
# ignore empty contours
self._currentContourStartIndex = None
return
contourStart = self.endPts[-1] + 1 if self.endPts else 0
self.endPts.append(len(self.points) - 1)
self._currentContourStartIndex = None
# Resolve types for any cubic segments
flags = self.types
for i in range(contourStart, len(flags)):
if flags[i] == "curve":
j = i - 1
if j < contourStart:
j = len(flags) - 1
while flags[j] == 0:
flags[j] = flagCubic
j -= 1
flags[i] = flagOnCurve
def addPoint(
self,
pt: Tuple[float, float],
segmentType: Optional[str] = None,
smooth: bool = False,
name: Optional[str] = None,
identifier: Optional[str] = None,
**kwargs: Any,
) -> None:
"""
Add a point to the current sub path.
"""
if self._isClosed():
raise PenError("Can't add a point to a closed contour.")
if segmentType is None:
self.types.append(0)
elif segmentType in ("line", "move"):
self.types.append(flagOnCurve)
elif segmentType == "qcurve":
self.types.append(flagOnCurve)
elif segmentType == "curve":
self.types.append("curve")
else:
raise AssertionError(segmentType)
self.points.append(pt)