from fontTools.misc.loggingTools import CapturingLogHandler
from fontTools.misc.testTools import parseXML
from fontTools.misc.textTools import deHexStr, hexStr
from fontTools.misc.xmlWriter import XMLWriter
from fontTools.ttLib.tables.TupleVariation import (
log,
TupleVariation,
compileSharedTuples,
decompileSharedTuples,
compileTupleVariationStore,
decompileTupleVariationStore,
inferRegion_,
)
from io import BytesIO
import random
import unittest
def hexencode(s):
h = hexStr(s).upper()
return " ".join([h[i : i + 2] for i in range(0, len(h), 2)])
AXES = {
"wdth": (0.25, 0.375, 0.5),
"wght": (0.0, 1.0, 1.0),
"opsz": (-0.75, -0.75, 0.0),
}
# Shared tuples in the 'gvar' table of the Skia font, as printed
# in Apple's TrueType specification.
# https://developer.apple.com/fonts/TrueType-Reference-Manual/RM06/Chap6gvar.html
SKIA_GVAR_SHARED_TUPLES_DATA = deHexStr(
"40 00 00 00 C0 00 00 00 00 00 40 00 00 00 C0 00 "
"C0 00 C0 00 40 00 C0 00 40 00 40 00 C0 00 40 00"
)
SKIA_GVAR_SHARED_TUPLES = [
{"wght": 1.0, "wdth": 0.0},
{"wght": -1.0, "wdth": 0.0},
{"wght": 0.0, "wdth": 1.0},
{"wght": 0.0, "wdth": -1.0},
{"wght": -1.0, "wdth": -1.0},
{"wght": 1.0, "wdth": -1.0},
{"wght": 1.0, "wdth": 1.0},
{"wght": -1.0, "wdth": 1.0},
]
# Tuple Variation Store of uppercase I in the Skia font, as printed in Apple's
# TrueType spec. The actual Skia font uses a different table for uppercase I
# than what is printed in Apple's spec, but we still want to make sure that
# we can parse the data as it appears in the specification.
# https://developer.apple.com/fonts/TrueType-Reference-Manual/RM06/Chap6gvar.html
SKIA_GVAR_I_DATA = deHexStr(
"00 08 00 24 00 33 20 00 00 15 20 01 00 1B 20 02 "
"00 24 20 03 00 15 20 04 00 26 20 07 00 0D 20 06 "
"00 1A 20 05 00 40 01 01 01 81 80 43 FF 7E FF 7E "
"FF 7E FF 7E 00 81 45 01 01 01 03 01 04 01 04 01 "
"04 01 02 80 40 00 82 81 81 04 3A 5A 3E 43 20 81 "
"04 0E 40 15 45 7C 83 00 0D 9E F3 F2 F0 F0 F0 F0 "
"F3 9E A0 A1 A1 A1 9F 80 00 91 81 91 00 0D 0A 0A "
"09 0A 0A 0A 0A 0A 0A 0A 0A 0A 0A 0B 80 00 15 81 "
"81 00 C4 89 00 C4 83 00 0D 80 99 98 96 96 96 96 "
"99 80 82 83 83 83 81 80 40 FF 18 81 81 04 E6 F9 "
"10 21 02 81 04 E8 E5 EB 4D DA 83 00 0D CE D3 D4 "
"D3 D3 D3 D5 D2 CE CC CD CD CD CD 80 00 A1 81 91 "
"00 0D 07 03 04 02 02 02 03 03 07 07 08 08 08 07 "
"80 00 09 81 81 00 28 40 00 A4 02 24 24 66 81 04 "
"08 FA FA FA 28 83 00 82 02 FF FF FF 83 02 01 01 "
"01 84 91 00 80 06 07 08 08 08 08 0A 07 80 03 FE "
"FF FF FF 81 00 08 81 82 02 EE EE EE 8B 6D 00"
)
class TupleVariationTest(unittest.TestCase):
def __init__(self, methodName):
unittest.TestCase.__init__(self, methodName)
# Python 3 renamed assertRaisesRegexp to assertRaisesRegex,
# and fires deprecation warnings if a program uses the old name.
if not hasattr(self, "assertRaisesRegex"):
self.assertRaisesRegex = self.assertRaisesRegexp
def test_equal(self):
var1 = TupleVariation({"wght": (0.0, 1.0, 1.0)}, [(0, 0), (9, 8), (7, 6)])
var2 = TupleVariation({"wght": (0.0, 1.0, 1.0)}, [(0, 0), (9, 8), (7, 6)])
self.assertEqual(var1, var2)
def test_equal_differentAxes(self):
var1 = TupleVariation({"wght": (0.0, 1.0, 1.0)}, [(0, 0), (9, 8), (7, 6)])
var2 = TupleVariation({"wght": (0.7, 0.8, 0.9)}, [(0, 0), (9, 8), (7, 6)])
self.assertNotEqual(var1, var2)
def test_equal_differentCoordinates(self):
var1 = TupleVariation({"wght": (0.0, 1.0, 1.0)}, [(0, 0), (9, 8), (7, 6)])
var2 = TupleVariation({"wght": (0.0, 1.0, 1.0)}, [(0, 0), (9, 8)])
self.assertNotEqual(var1, var2)
def test_hasImpact_someDeltasNotZero(self):
axes = {"wght": (0.0, 1.0, 1.0)}
var = TupleVariation(axes, [(0, 0), (9, 8), (7, 6)])
self.assertTrue(var.hasImpact())
def test_hasImpact_allDeltasZero(self):
axes = {"wght": (0.0, 1.0, 1.0)}
var = TupleVariation(axes, [(0, 0), (0, 0), (0, 0)])
self.assertTrue(var.hasImpact())
def test_hasImpact_allDeltasNone(self):
axes = {"wght": (0.0, 1.0, 1.0)}
var = TupleVariation(axes, [None, None, None])
self.assertFalse(var.hasImpact())
def test_toXML_badDeltaFormat(self):
writer = XMLWriter(BytesIO())
g = TupleVariation(AXES, ["String"])
with CapturingLogHandler(log, "ERROR") as captor:
g.toXML(writer, ["wdth"])
self.assertIn("bad delta format", [r.msg for r in captor.records])
self.assertEqual(
[
"",
'',
"",
"",
],
TupleVariationTest.xml_lines(writer),
)
def test_toXML_constants(self):
writer = XMLWriter(BytesIO())
g = TupleVariation(AXES, [42, None, 23, 0, -17, None])
g.toXML(writer, ["wdth", "wght", "opsz"])
self.assertEqual(
[
"",
'',
'',
'',
'',
'',
'',
'',
"",
],
TupleVariationTest.xml_lines(writer),
)
def test_toXML_points(self):
writer = XMLWriter(BytesIO())
g = TupleVariation(AXES, [(9, 8), None, (7, 6), (0, 0), (-1, -2), None])
g.toXML(writer, ["wdth", "wght", "opsz"])
self.assertEqual(
[
"",
'',
'',
'',
'',
'',
'',
'',
"",
],
TupleVariationTest.xml_lines(writer),
)
def test_toXML_allDeltasNone(self):
writer = XMLWriter(BytesIO())
axes = {"wght": (0.0, 1.0, 1.0)}
g = TupleVariation(axes, [None] * 5)
g.toXML(writer, ["wght", "wdth"])
self.assertEqual(
[
"",
'',
"",
"",
],
TupleVariationTest.xml_lines(writer),
)
def test_toXML_axes_floats(self):
writer = XMLWriter(BytesIO())
axes = {
"wght": (0.0, 0.2999878, 0.7000122),
"wdth": (0.0, 0.4000244, 0.4000244),
}
g = TupleVariation(axes, [None] * 5)
g.toXML(writer, ["wght", "wdth"])
self.assertEqual(
[
'',
'',
],
TupleVariationTest.xml_lines(writer)[1:3],
)
def test_fromXML_badDeltaFormat(self):
g = TupleVariation({}, [])
with CapturingLogHandler(log, "WARNING") as captor:
for name, attrs, content in parseXML(''):
g.fromXML(name, attrs, content)
self.assertIn("bad delta format: a, b", [r.msg for r in captor.records])
def test_fromXML_constants(self):
g = TupleVariation({}, [None] * 4)
for name, attrs, content in parseXML(
''
''
''
''
''
):
g.fromXML(name, attrs, content)
self.assertEqual(AXES, g.axes)
self.assertEqual([None, 42, -23, None], g.coordinates)
def test_fromXML_points(self):
g = TupleVariation({}, [None] * 4)
for name, attrs, content in parseXML(
''
''
''
''
''
):
g.fromXML(name, attrs, content)
self.assertEqual(AXES, g.axes)
self.assertEqual([None, (33, 44), (-2, 170), None], g.coordinates)
def test_fromXML_axes_floats(self):
g = TupleVariation({}, [None] * 4)
for name, attrs, content in parseXML(
''
''
):
g.fromXML(name, attrs, content)
self.assertEqual(g.axes["wght"][0], 0)
self.assertAlmostEqual(g.axes["wght"][1], 0.2999878)
self.assertAlmostEqual(g.axes["wght"][2], 0.7000122)
self.assertEqual(g.axes["wdth"][0], 0)
self.assertAlmostEqual(g.axes["wdth"][1], 0.4000244)
self.assertAlmostEqual(g.axes["wdth"][2], 0.4000244)
def test_compile_sharedPeaks_nonIntermediate_sharedPoints(self):
var = TupleVariation(
{"wght": (0.0, 0.5, 0.5), "wdth": (0.0, 0.8, 0.8)}, [(7, 4), (8, 5), (9, 6)]
)
axisTags = ["wght", "wdth"]
sharedPeakIndices = {var.compileCoord(axisTags): 0x77}
tup, deltas = var.compile(axisTags, sharedPeakIndices, pointData=b"")
# len(deltas)=8; flags=None; tupleIndex=0x77
# embeddedPeaks=[]; intermediateCoord=[]
self.assertEqual("00 08 00 77", hexencode(tup))
self.assertEqual(
"02 07 08 09 " "02 04 05 06", # deltaX: [7, 8, 9] # deltaY: [4, 5, 6]
hexencode(deltas),
)
def test_compile_sharedPeaks_intermediate_sharedPoints(self):
var = TupleVariation(
{"wght": (0.3, 0.5, 0.7), "wdth": (0.1, 0.8, 0.9)}, [(7, 4), (8, 5), (9, 6)]
)
axisTags = ["wght", "wdth"]
sharedPeakIndices = {var.compileCoord(axisTags): 0x77}
tup, deltas = var.compile(axisTags, sharedPeakIndices, pointData=b"")
# len(deltas)=8; flags=INTERMEDIATE_REGION; tupleIndex=0x77
# embeddedPeak=[]; intermediateCoord=[(0.3, 0.1), (0.7, 0.9)]
self.assertEqual("00 08 40 77 13 33 06 66 2C CD 39 9A", hexencode(tup))
self.assertEqual(
"02 07 08 09 " "02 04 05 06", # deltaX: [7, 8, 9] # deltaY: [4, 5, 6]
hexencode(deltas),
)
def test_compile_sharedPeaks_nonIntermediate_privatePoints(self):
var = TupleVariation(
{"wght": (0.0, 0.5, 0.5), "wdth": (0.0, 0.8, 0.8)}, [(7, 4), (8, 5), (9, 6)]
)
axisTags = ["wght", "wdth"]
sharedPeakIndices = {var.compileCoord(axisTags): 0x77}
tup, deltas = var.compile(axisTags, sharedPeakIndices)
# len(deltas)=9; flags=PRIVATE_POINT_NUMBERS; tupleIndex=0x77
# embeddedPeak=[]; intermediateCoord=[]
self.assertEqual("00 09 20 77", hexencode(tup))
self.assertEqual(
"00 " # all points in glyph
"02 07 08 09 " # deltaX: [7, 8, 9]
"02 04 05 06", # deltaY: [4, 5, 6]
hexencode(deltas),
)
def test_compile_sharedPeaks_intermediate_privatePoints(self):
var = TupleVariation(
{"wght": (0.0, 0.5, 1.0), "wdth": (0.0, 0.8, 1.0)}, [(7, 4), (8, 5), (9, 6)]
)
axisTags = ["wght", "wdth"]
sharedPeakIndices = {var.compileCoord(axisTags): 0x77}
tuple, deltas = var.compile(axisTags, sharedPeakIndices)
# len(deltas)=9; flags=PRIVATE_POINT_NUMBERS; tupleIndex=0x77
# embeddedPeak=[]; intermediateCoord=[(0.0, 0.0), (1.0, 1.0)]
self.assertEqual("00 09 60 77 00 00 00 00 40 00 40 00", hexencode(tuple))
self.assertEqual(
"00 " # all points in glyph
"02 07 08 09 " # deltaX: [7, 8, 9]
"02 04 05 06", # deltaY: [4, 5, 6]
hexencode(deltas),
)
def test_compile_embeddedPeak_nonIntermediate_sharedPoints(self):
var = TupleVariation(
{"wght": (0.0, 0.5, 0.5), "wdth": (0.0, 0.8, 0.8)}, [(7, 4), (8, 5), (9, 6)]
)
tup, deltas = var.compile(axisTags=["wght", "wdth"], pointData=b"")
# len(deltas)=8; flags=EMBEDDED_PEAK_TUPLE
# embeddedPeak=[(0.5, 0.8)]; intermediateCoord=[]
self.assertEqual("00 08 80 00 20 00 33 33", hexencode(tup))
self.assertEqual(
"02 07 08 09 " "02 04 05 06", # deltaX: [7, 8, 9] # deltaY: [4, 5, 6]
hexencode(deltas),
)
def test_compile_embeddedPeak_nonIntermediate_sharedConstants(self):
var = TupleVariation(
{"wght": (0.0, 0.5, 0.5), "wdth": (0.0, 0.8, 0.8)}, [3, 1, 4]
)
tup, deltas = var.compile(axisTags=["wght", "wdth"], pointData=b"")
# len(deltas)=4; flags=EMBEDDED_PEAK_TUPLE
# embeddedPeak=[(0.5, 0.8)]; intermediateCoord=[]
self.assertEqual("00 04 80 00 20 00 33 33", hexencode(tup))
self.assertEqual("02 03 01 04", hexencode(deltas)) # delta: [3, 1, 4]
def test_compile_embeddedPeak_intermediate_sharedPoints(self):
var = TupleVariation(
{"wght": (0.0, 0.5, 1.0), "wdth": (0.0, 0.8, 0.8)}, [(7, 4), (8, 5), (9, 6)]
)
tup, deltas = var.compile(axisTags=["wght", "wdth"], pointData=b"")
# len(deltas)=8; flags=EMBEDDED_PEAK_TUPLE
# embeddedPeak=[(0.5, 0.8)]; intermediateCoord=[(0.0, 0.0), (1.0, 0.8)]
self.assertEqual(
"00 08 C0 00 20 00 33 33 00 00 00 00 40 00 33 33", hexencode(tup)
)
self.assertEqual(
"02 07 08 09 " "02 04 05 06", # deltaX: [7, 8, 9] # deltaY: [4, 5, 6]
hexencode(deltas),
)
def test_compile_embeddedPeak_nonIntermediate_privatePoints(self):
var = TupleVariation(
{"wght": (0.0, 0.5, 0.5), "wdth": (0.0, 0.8, 0.8)}, [(7, 4), (8, 5), (9, 6)]
)
tup, deltas = var.compile(axisTags=["wght", "wdth"])
# len(deltas)=9; flags=PRIVATE_POINT_NUMBERS|EMBEDDED_PEAK_TUPLE
# embeddedPeak=[(0.5, 0.8)]; intermediateCoord=[]
self.assertEqual("00 09 A0 00 20 00 33 33", hexencode(tup))
self.assertEqual(
"00 " # all points in glyph
"02 07 08 09 " # deltaX: [7, 8, 9]
"02 04 05 06", # deltaY: [4, 5, 6]
hexencode(deltas),
)
def test_compile_embeddedPeak_nonIntermediate_privateConstants(self):
var = TupleVariation(
{"wght": (0.0, 0.5, 0.5), "wdth": (0.0, 0.8, 0.8)}, [7, 8, 9]
)
tup, deltas = var.compile(axisTags=["wght", "wdth"])
# len(deltas)=5; flags=PRIVATE_POINT_NUMBERS|EMBEDDED_PEAK_TUPLE
# embeddedPeak=[(0.5, 0.8)]; intermediateCoord=[]
self.assertEqual("00 05 A0 00 20 00 33 33", hexencode(tup))
self.assertEqual(
"00 " "02 07 08 09", # all points in glyph # delta: [7, 8, 9]
hexencode(deltas),
)
def test_compile_embeddedPeak_intermediate_privatePoints(self):
var = TupleVariation(
{"wght": (0.4, 0.5, 0.6), "wdth": (0.7, 0.8, 0.9)}, [(7, 4), (8, 5), (9, 6)]
)
tup, deltas = var.compile(axisTags=["wght", "wdth"])
# len(deltas)=9;
# flags=PRIVATE_POINT_NUMBERS|INTERMEDIATE_REGION|EMBEDDED_PEAK_TUPLE
# embeddedPeak=(0.5, 0.8); intermediateCoord=[(0.4, 0.7), (0.6, 0.9)]
self.assertEqual(
"00 09 E0 00 20 00 33 33 19 9A 2C CD 26 66 39 9A", hexencode(tup)
)
self.assertEqual(
"00 " # all points in glyph
"02 07 08 09 " # deltaX: [7, 8, 9]
"02 04 05 06", # deltaY: [4, 5, 6]
hexencode(deltas),
)
def test_compile_embeddedPeak_intermediate_privateConstants(self):
var = TupleVariation(
{"wght": (0.4, 0.5, 0.6), "wdth": (0.7, 0.8, 0.9)}, [7, 8, 9]
)
tup, deltas = var.compile(axisTags=["wght", "wdth"])
# len(deltas)=5;
# flags=PRIVATE_POINT_NUMBERS|INTERMEDIATE_REGION|EMBEDDED_PEAK_TUPLE
# embeddedPeak=(0.5, 0.8); intermediateCoord=[(0.4, 0.7), (0.6, 0.9)]
self.assertEqual(
"00 05 E0 00 20 00 33 33 19 9A 2C CD 26 66 39 9A", hexencode(tup)
)
self.assertEqual(
"00 " "02 07 08 09", # all points in glyph # delta: [7, 8, 9]
hexencode(deltas),
)
def test_compileCoord(self):
var = TupleVariation(
{"wght": (-1.0, -1.0, -1.0), "wdth": (0.4, 0.5, 0.6)}, [None] * 4
)
self.assertEqual("C0 00 20 00", hexencode(var.compileCoord(["wght", "wdth"])))
self.assertEqual("20 00 C0 00", hexencode(var.compileCoord(["wdth", "wght"])))
self.assertEqual("C0 00", hexencode(var.compileCoord(["wght"])))
def test_compileIntermediateCoord(self):
var = TupleVariation(
{"wght": (-1.0, -1.0, 0.0), "wdth": (0.4, 0.5, 0.6)}, [None] * 4
)
self.assertEqual(
"C0 00 19 9A 00 00 26 66",
hexencode(var.compileIntermediateCoord(["wght", "wdth"])),
)
self.assertEqual(
"19 9A C0 00 26 66 00 00",
hexencode(var.compileIntermediateCoord(["wdth", "wght"])),
)
self.assertEqual(None, var.compileIntermediateCoord(["wght"]))
self.assertEqual(
"19 9A 26 66", hexencode(var.compileIntermediateCoord(["wdth"]))
)
def test_decompileCoord(self):
decompileCoord = TupleVariation.decompileCoord_
data = deHexStr("DE AD C0 00 20 00 DE AD")
self.assertEqual(
({"wght": -1.0, "wdth": 0.5}, 6), decompileCoord(["wght", "wdth"], data, 2)
)
def test_decompileCoord_roundTrip(self):
# Make sure we are not affected by https://github.com/fonttools/fonttools/issues/286
data = deHexStr("7F B9 80 35")
values, _ = TupleVariation.decompileCoord_(["wght", "wdth"], data, 0)
axisValues = {axis: (val, val, val) for axis, val in values.items()}
var = TupleVariation(axisValues, [None] * 4)
self.assertEqual("7F B9 80 35", hexencode(var.compileCoord(["wght", "wdth"])))
def test_compilePoints(self):
compilePoints = lambda p: TupleVariation.compilePoints(set(p))
self.assertEqual("00", hexencode(compilePoints(set()))) # all points in glyph
self.assertEqual("01 00 07", hexencode(compilePoints([7])))
self.assertEqual("01 80 FF FF", hexencode(compilePoints([65535])))
self.assertEqual("02 01 09 06", hexencode(compilePoints([9, 15])))
self.assertEqual(
"06 05 07 01 F7 02 01 F2",
hexencode(compilePoints([7, 8, 255, 257, 258, 500])),
)
self.assertEqual("03 01 07 01 80 01 EC", hexencode(compilePoints([7, 8, 500])))
self.assertEqual(
"04 01 07 01 81 BE E7 0C 0F",
hexencode(compilePoints([7, 8, 0xBEEF, 0xCAFE])),
)
self.maxDiff = None
self.assertEqual(
"81 2C"
+ " 7F 00" # 300 points (0x12c) in total
+ (127 * " 01")
+ " 7F" # first run, contains 128 points: [0 .. 127]
+ (128 * " 01")
+ " 2B" # second run, contains 128 points: [128 .. 255]
+ (44 * " 01"), # third run, contains 44 points: [256 .. 299]
hexencode(compilePoints(range(300))),
)
self.assertEqual(
"81 8F"
+ " 7F 00" # 399 points (0x18f) in total
+ (127 * " 01")
+ " 7F" # first run, contains 128 points: [0 .. 127]
+ (128 * " 01")
+ " 7F" # second run, contains 128 points: [128 .. 255]
+ (128 * " 01")
+ " 0E" # third run, contains 128 points: [256 .. 383]
+ (15 * " 01"), # fourth run, contains 15 points: [384 .. 398]
hexencode(compilePoints(range(399))),
)
def test_decompilePoints(self):
numPointsInGlyph = 65536
allPoints = list(range(numPointsInGlyph))
def decompilePoints(data, offset):
points, offset = TupleVariation.decompilePoints_(
numPointsInGlyph, deHexStr(data), offset, "gvar"
)
# Conversion to list needed for Python 3.
return (list(points), offset)
# all points in glyph
self.assertEqual((allPoints, 1), decompilePoints("00", 0))
# all points in glyph (in overly verbose encoding, not explicitly prohibited by spec)
self.assertEqual((allPoints, 2), decompilePoints("80 00", 0))
# 2 points; first run: [9, 9+6]
self.assertEqual(([9, 15], 4), decompilePoints("02 01 09 06", 0))
# 2 points; first run: [0xBEEF, 0xCAFE]. (0x0C0F = 0xCAFE - 0xBEEF)
self.assertEqual(([0xBEEF, 0xCAFE], 6), decompilePoints("02 81 BE EF 0C 0F", 0))
# 1 point; first run: [7]
self.assertEqual(([7], 3), decompilePoints("01 00 07", 0))
# 1 point; first run: [7] in overly verbose encoding
self.assertEqual(([7], 4), decompilePoints("01 80 00 07", 0))
# 1 point; first run: [65535]; requires words to be treated as unsigned numbers
self.assertEqual(([65535], 4), decompilePoints("01 80 FF FF", 0))
# 4 points; first run: [7, 8]; second run: [255, 257]. 257 is stored in delta-encoded bytes (0xFF + 2).
self.assertEqual(
([7, 8, 263, 265], 7), decompilePoints("04 01 07 01 01 FF 02", 0)
)
# combination of all encodings, preceded and followed by 4 bytes of unused data
data = "DE AD DE AD 04 01 07 01 81 BE E7 0C 0F DE AD DE AD"
self.assertEqual(([7, 8, 0xBEEF, 0xCAFE], 13), decompilePoints(data, 4))
self.assertSetEqual(
set(range(300)),
set(
decompilePoints(
"81 2C"
+ " 7F 00" # 300 points (0x12c) in total
+ (127 * " 01")
+ " 7F" # first run, contains 128 points: [0 .. 127]
+ (128 * " 01")
+ " AB" # second run, contains 128 points: [128 .. 255]
+ (44 * " 00 01"), # third run, contains 44 points: [256 .. 299]
0,
)[0]
),
)
self.assertSetEqual(
set(range(399)),
set(
decompilePoints(
"81 8F"
+ " 7F 00" # 399 points (0x18f) in total
+ (127 * " 01")
+ " 7F" # first run, contains 128 points: [0 .. 127]
+ (128 * " 01")
+ " FF" # second run, contains 128 points: [128 .. 255]
+ (128 * " 00 01")
+ " 8E" # third run, contains 128 points: [256 .. 383]
+ (15 * " 00 01"), # fourth run, contains 15 points: [384 .. 398]
0,
)[0]
),
)
def test_decompilePoints_shouldAcceptBadPointNumbers(self):
decompilePoints = TupleVariation.decompilePoints_
# 2 points; first run: [3, 9].
numPointsInGlyph = 8
with CapturingLogHandler(log, "WARNING") as captor:
decompilePoints(numPointsInGlyph, deHexStr("02 01 03 06"), 0, "cvar")
self.assertIn(
"point 9 out of range in 'cvar' table", [r.msg for r in captor.records]
)
def test_decompilePoints_roundTrip(self):
numPointsInGlyph = (
500 # greater than 255, so we also exercise code path for 16-bit encoding
)
compile = lambda points: TupleVariation.compilePoints(points)
decompile = lambda data: set(
TupleVariation.decompilePoints_(numPointsInGlyph, data, 0, "gvar")[0]
)
for i in range(50):
points = set(random.sample(range(numPointsInGlyph), 30))
self.assertSetEqual(
points,
decompile(compile(points)),
"failed round-trip decompile/compilePoints; points=%s" % points,
)
allPoints = set(range(numPointsInGlyph))
self.assertSetEqual(allPoints, decompile(compile(allPoints)))
self.assertSetEqual(allPoints, decompile(compile(set())))
def test_compileDeltas_points(self):
var = TupleVariation({}, [None, (1, 0), (2, 0), None, (4, 0), None])
# deltaX for points: [1, 2, 4]; deltaY for points: [0, 0, 0]
self.assertEqual("02 01 02 04 82", hexencode(var.compileDeltas()))
def test_compileDeltas_constants(self):
var = TupleVariation({}, [None, 1, 2, None, 4, None])
# delta for cvts: [1, 2, 4]
self.assertEqual("02 01 02 04", hexencode(var.compileDeltas()))
def test_compileDeltaValues(self):
compileDeltaValues = lambda values: hexencode(
TupleVariation.compileDeltaValues_(values)
)
# zeroes
self.assertEqual("80", compileDeltaValues([0]))
self.assertEqual("BF", compileDeltaValues([0] * 64))
self.assertEqual("BF 80", compileDeltaValues([0] * 65))
self.assertEqual("BF A3", compileDeltaValues([0] * 100))
self.assertEqual("BF BF BF BF", compileDeltaValues([0] * 256))
# bytes
self.assertEqual("00 01", compileDeltaValues([1]))
self.assertEqual(
"06 01 02 03 7F 80 FF FE", compileDeltaValues([1, 2, 3, 127, -128, -1, -2])
)
self.assertEqual("3F" + (64 * " 7F"), compileDeltaValues([127] * 64))
self.assertEqual("3F" + (64 * " 7F") + " 00 7F", compileDeltaValues([127] * 65))
# words
self.assertEqual("40 66 66", compileDeltaValues([0x6666]))
self.assertEqual(
"43 66 66 7F FF FF FF 80 00",
compileDeltaValues([0x6666, 32767, -1, -32768]),
)
self.assertEqual("7F" + (64 * " 11 22"), compileDeltaValues([0x1122] * 64))
self.assertEqual(
"7F" + (64 * " 11 22") + " 40 11 22", compileDeltaValues([0x1122] * 65)
)
# bytes, zeroes, bytes: a single zero is more compact when encoded as part of the bytes run
self.assertEqual(
"04 7F 7F 00 7F 7F", compileDeltaValues([127, 127, 0, 127, 127])
)
self.assertEqual(
"01 7F 7F 81 01 7F 7F", compileDeltaValues([127, 127, 0, 0, 127, 127])
)
self.assertEqual(
"01 7F 7F 82 01 7F 7F", compileDeltaValues([127, 127, 0, 0, 0, 127, 127])
)
self.assertEqual(
"01 7F 7F 83 01 7F 7F", compileDeltaValues([127, 127, 0, 0, 0, 0, 127, 127])
)
# bytes, zeroes
self.assertEqual("01 01 00", compileDeltaValues([1, 0]))
self.assertEqual("00 01 81", compileDeltaValues([1, 0, 0]))
# words, bytes, words: a single byte is more compact when encoded as part of the words run
self.assertEqual(
"42 66 66 00 02 77 77", compileDeltaValues([0x6666, 2, 0x7777])
)
self.assertEqual(
"40 66 66 01 02 02 40 77 77", compileDeltaValues([0x6666, 2, 2, 0x7777])
)
# words, zeroes, words
self.assertEqual(
"40 66 66 80 40 77 77", compileDeltaValues([0x6666, 0, 0x7777])
)
self.assertEqual(
"40 66 66 81 40 77 77", compileDeltaValues([0x6666, 0, 0, 0x7777])
)
self.assertEqual(
"40 66 66 82 40 77 77", compileDeltaValues([0x6666, 0, 0, 0, 0x7777])
)
# words, zeroes, bytes
self.assertEqual(
"40 66 66 80 02 01 02 03", compileDeltaValues([0x6666, 0, 1, 2, 3])
)
self.assertEqual(
"40 66 66 81 02 01 02 03", compileDeltaValues([0x6666, 0, 0, 1, 2, 3])
)
self.assertEqual(
"40 66 66 82 02 01 02 03", compileDeltaValues([0x6666, 0, 0, 0, 1, 2, 3])
)
# words, zeroes
self.assertEqual("40 66 66 80", compileDeltaValues([0x6666, 0]))
self.assertEqual("40 66 66 81", compileDeltaValues([0x6666, 0, 0]))
def test_decompileDeltas(self):
decompileDeltas = TupleVariation.decompileDeltas_
# 83 = zero values (0x80), count = 4 (1 + 0x83 & 0x3F)
self.assertEqual(([0, 0, 0, 0], 1), decompileDeltas(4, deHexStr("83"), 0))
# 41 01 02 FF FF = signed 16-bit values (0x40), count = 2 (1 + 0x41 & 0x3F)
self.assertEqual(
([258, -1], 5), decompileDeltas(2, deHexStr("41 01 02 FF FF"), 0)
)
# 01 81 07 = signed 8-bit values, count = 2 (1 + 0x01 & 0x3F)
self.assertEqual(([-127, 7], 3), decompileDeltas(2, deHexStr("01 81 07"), 0))
# combination of all three encodings, preceded and followed by 4 bytes of unused data
data = deHexStr("DE AD BE EF 83 40 01 02 01 81 80 DE AD BE EF")
self.assertEqual(
([0, 0, 0, 0, 258, -127, -128], 11), decompileDeltas(7, data, 4)
)
def test_decompileDeltas_roundTrip(self):
numDeltas = 30
compile = TupleVariation.compileDeltaValues_
decompile = lambda data: TupleVariation.decompileDeltas_(numDeltas, data, 0)[0]
for i in range(50):
deltas = random.sample(range(-128, 127), 10)
deltas.extend(random.sample(range(-32768, 32767), 10))
deltas.extend([0] * 10)
random.shuffle(deltas)
self.assertListEqual(deltas, decompile(compile(deltas)))
def test_compileSharedTuples(self):
# Below, the peak coordinate {"wght": 1.0, "wdth": 0.8} appears
# three times (most frequent sorted first); {"wght": 1.0, "wdth": 0.5}
# and {"wght": 1.0, "wdth": 0.7} both appears two times (tie) and
# are sorted alphanumerically to ensure determinism.
# The peak coordinate {"wght": 1.0, "wdth": 0.9} appears only once
# and is thus ignored.
# Because the start and end of variation ranges is not encoded
# into the shared pool, they should get ignored.
deltas = [None] * 4
variations = [
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (0.5, 0.7, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (0.2, 0.7, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (0.2, 0.8, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (0.3, 0.5, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (0.3, 0.8, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (0.3, 0.9, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (0.4, 0.8, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (0.5, 0.5, 1.0)}, deltas),
]
result = compileSharedTuples(["wght", "wdth"], variations)
self.assertEqual(
[hexencode(c) for c in result],
["40 00 33 33", "40 00 20 00", "40 00 2C CD"],
)
def test_decompileSharedTuples_Skia(self):
sharedTuples = decompileSharedTuples(
axisTags=["wght", "wdth"],
sharedTupleCount=8,
data=SKIA_GVAR_SHARED_TUPLES_DATA,
offset=0,
)
self.assertEqual(sharedTuples, SKIA_GVAR_SHARED_TUPLES)
def test_decompileSharedTuples_empty(self):
self.assertEqual(decompileSharedTuples(["wght"], 0, b"", 0), [])
def test_compileTupleVariationStore_allVariationsRedundant(self):
axes = {"wght": (0.3, 0.4, 0.5), "opsz": (0.7, 0.8, 0.9)}
variations = [
TupleVariation(axes, [None] * 4),
TupleVariation(axes, [None] * 4),
TupleVariation(axes, [None] * 4),
]
self.assertEqual(
compileTupleVariationStore(
variations,
pointCount=8,
axisTags=["wght", "opsz"],
sharedTupleIndices={},
),
(0, b"", b""),
)
def test_compileTupleVariationStore_noVariations(self):
self.assertEqual(
compileTupleVariationStore(
variations=[],
pointCount=8,
axisTags=["wght", "opsz"],
sharedTupleIndices={},
),
(0, b"", b""),
)
def test_compileTupleVariationStore_roundTrip_cvar(self):
deltas = [1, 2, 3, 4]
variations = [
TupleVariation({"wght": (0.5, 1.0, 1.0), "wdth": (1.0, 1.0, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (1.0, 1.0, 1.0)}, deltas),
]
tupleVariationCount, tuples, data = compileTupleVariationStore(
variations, pointCount=4, axisTags=["wght", "wdth"], sharedTupleIndices={}
)
self.assertEqual(
decompileTupleVariationStore(
"cvar",
["wght", "wdth"],
tupleVariationCount,
pointCount=4,
sharedTuples={},
data=(tuples + data),
pos=0,
dataPos=len(tuples),
),
variations,
)
def test_compileTupleVariationStore_roundTrip_gvar(self):
deltas = [(1, 1), (2, 2), (3, 3), (4, 4)]
variations = [
TupleVariation({"wght": (0.5, 1.0, 1.0), "wdth": (1.0, 1.0, 1.0)}, deltas),
TupleVariation({"wght": (1.0, 1.0, 1.0), "wdth": (1.0, 1.0, 1.0)}, deltas),
]
tupleVariationCount, tuples, data = compileTupleVariationStore(
variations, pointCount=4, axisTags=["wght", "wdth"], sharedTupleIndices={}
)
self.assertEqual(
decompileTupleVariationStore(
"gvar",
["wght", "wdth"],
tupleVariationCount,
pointCount=4,
sharedTuples={},
data=(tuples + data),
pos=0,
dataPos=len(tuples),
),
variations,
)
def test_decompileTupleVariationStore_Skia_I(self):
tvar = decompileTupleVariationStore(
tableTag="gvar",
axisTags=["wght", "wdth"],
tupleVariationCount=8,
pointCount=18,
sharedTuples=SKIA_GVAR_SHARED_TUPLES,
data=SKIA_GVAR_I_DATA,
pos=4,
dataPos=36,
)
self.assertEqual(len(tvar), 8)
self.assertEqual(tvar[0].axes, {"wght": (0.0, 1.0, 1.0)})
self.assertEqual(
" ".join(["%d,%d" % c for c in tvar[0].coordinates]),
"257,0 -127,0 -128,58 -130,90 -130,62 -130,67 -130,32 -127,0 "
"257,0 259,14 260,64 260,21 260,69 258,124 0,0 130,0 0,0 0,0",
)
def test_decompileTupleVariationStore_empty(self):
self.assertEqual(
decompileTupleVariationStore(
tableTag="gvar",
axisTags=[],
tupleVariationCount=0,
pointCount=5,
sharedTuples=[],
data=b"",
pos=4,
dataPos=4,
),
[],
)
def test_getTupleSize(self):
getTupleSize = TupleVariation.getTupleSize_
numAxes = 3
self.assertEqual(4 + numAxes * 2, getTupleSize(0x8042, numAxes))
self.assertEqual(4 + numAxes * 4, getTupleSize(0x4077, numAxes))
self.assertEqual(4, getTupleSize(0x2077, numAxes))
self.assertEqual(4, getTupleSize(11, numAxes))
def test_inferRegion(self):
start, end = inferRegion_({"wght": -0.3, "wdth": 0.7})
self.assertEqual(start, {"wght": -0.3, "wdth": 0.0})
self.assertEqual(end, {"wght": 0.0, "wdth": 0.7})
@staticmethod
def xml_lines(writer):
content = writer.file.getvalue().decode("utf-8")
return [line.strip() for line in content.splitlines()][1:]
def test_getCoordWidth(self):
empty = TupleVariation({}, [])
self.assertEqual(empty.getCoordWidth(), 0)
empty = TupleVariation({}, [None])
self.assertEqual(empty.getCoordWidth(), 0)
gvarTuple = TupleVariation({}, [None, (0, 0)])
self.assertEqual(gvarTuple.getCoordWidth(), 2)
cvarTuple = TupleVariation({}, [None, 0])
self.assertEqual(cvarTuple.getCoordWidth(), 1)
cvarTuple.coordinates[1] *= 1.0
self.assertEqual(cvarTuple.getCoordWidth(), 1)
with self.assertRaises(TypeError):
TupleVariation({}, [None, "a"]).getCoordWidth()
def test_scaleDeltas_cvar(self):
var = TupleVariation({}, [100, None])
var.scaleDeltas(1.0)
self.assertEqual(var.coordinates, [100, None])
var.scaleDeltas(0.333)
self.assertAlmostEqual(var.coordinates[0], 33.3)
self.assertIsNone(var.coordinates[1])
var.scaleDeltas(0.0)
self.assertEqual(var.coordinates, [0, None])
def test_scaleDeltas_gvar(self):
var = TupleVariation({}, [(100, 200), None])
var.scaleDeltas(1.0)
self.assertEqual(var.coordinates, [(100, 200), None])
var.scaleDeltas(0.333)
self.assertAlmostEqual(var.coordinates[0][0], 33.3)
self.assertAlmostEqual(var.coordinates[0][1], 66.6)
self.assertIsNone(var.coordinates[1])
var.scaleDeltas(0.0)
self.assertEqual(var.coordinates, [(0, 0), None])
def test_roundDeltas_cvar(self):
var = TupleVariation({}, [55.5, None, 99.9])
var.roundDeltas()
self.assertEqual(var.coordinates, [56, None, 100])
def test_roundDeltas_gvar(self):
var = TupleVariation({}, [(55.5, 100.0), None, (99.9, 100.0)])
var.roundDeltas()
self.assertEqual(var.coordinates, [(56, 100), None, (100, 100)])
def test_calcInferredDeltas(self):
var = TupleVariation({}, [(0, 0), None, None, None])
coords = [(1, 1), (1, 1), (1, 1), (1, 1)]
var.calcInferredDeltas(coords, [])
self.assertEqual(var.coordinates, [(0, 0), (0, 0), (0, 0), (0, 0)])
def test_calcInferredDeltas_invalid(self):
# cvar tuples can't have inferred deltas
with self.assertRaises(TypeError):
TupleVariation({}, [0]).calcInferredDeltas([], [])
# origCoords must have same length as self.coordinates
with self.assertRaises(ValueError):
TupleVariation({}, [(0, 0), None]).calcInferredDeltas([], [])
# at least 4 phantom points required
with self.assertRaises(AssertionError):
TupleVariation({}, [(0, 0), None]).calcInferredDeltas([(0, 0), (0, 0)], [])
with self.assertRaises(AssertionError):
TupleVariation({}, [(0, 0)] + [None] * 5).calcInferredDeltas(
[(0, 0)] * 6, [1, 0] # endPts not in increasing order
)
def test_optimize(self):
var = TupleVariation({"wght": (0.0, 1.0, 1.0)}, [(0, 0)] * 5)
var.optimize([(0, 0)] * 5, [0])
self.assertEqual(var.coordinates, [None, None, None, None, None])
def test_optimize_isComposite(self):
# when a composite glyph's deltas are all (0, 0), we still want
# to write out an entry in gvar, else macOS doesn't apply any
# variations to the composite glyph (even if its individual components
# do vary).
# https://github.com/fonttools/fonttools/issues/1381
var = TupleVariation({"wght": (0.0, 1.0, 1.0)}, [(0, 0)] * 5)
var.optimize([(0, 0)] * 5, [0], isComposite=True)
self.assertEqual(var.coordinates, [(0, 0)] * 5)
# it takes more than 128 (0, 0) deltas before the optimized tuple with
# (None) inferred deltas (except for the first) becomes smaller than
# the un-optimized one that has all deltas explicitly set to (0, 0).
var = TupleVariation({"wght": (0.0, 1.0, 1.0)}, [(0, 0)] * 129)
var.optimize([(0, 0)] * 129, list(range(129 - 4)), isComposite=True)
self.assertEqual(var.coordinates, [(0, 0)] + [None] * 128)
def test_sum_deltas_gvar(self):
var1 = TupleVariation(
{},
[
(-20, 0),
(-20, 0),
(20, 0),
(20, 0),
(0, 0),
(0, 0),
(0, 0),
(0, 0),
],
)
var2 = TupleVariation(
{},
[
(-10, 0),
(-10, 0),
(10, 0),
(10, 0),
(0, 0),
(20, 0),
(0, 0),
(0, 0),
],
)
var1 += var2
self.assertEqual(
var1.coordinates,
[
(-30, 0),
(-30, 0),
(30, 0),
(30, 0),
(0, 0),
(20, 0),
(0, 0),
(0, 0),
],
)
def test_sum_deltas_gvar_invalid_length(self):
var1 = TupleVariation({}, [(1, 2)])
var2 = TupleVariation({}, [(1, 2), (3, 4)])
with self.assertRaisesRegex(ValueError, "deltas with different lengths"):
var1 += var2
def test_sum_deltas_gvar_with_inferred_points(self):
var1 = TupleVariation({}, [(1, 2), None])
var2 = TupleVariation({}, [(2, 3), None])
with self.assertRaisesRegex(ValueError, "deltas with inferred points"):
var1 += var2
def test_sum_deltas_cvar(self):
axes = {"wght": (0.0, 1.0, 1.0)}
var1 = TupleVariation(axes, [0, 1, None, None])
var2 = TupleVariation(axes, [None, 2, None, 3])
var3 = TupleVariation(axes, [None, None, None, 4])
var1 += var2
var1 += var3
self.assertEqual(var1.coordinates, [0, 3, None, 7])
if __name__ == "__main__":
import sys
sys.exit(unittest.main())