test-kivy-app/kivy_venv/lib/python3.11/site-packages/PIL/PcfFontFile.py

#
# THIS IS WORK IN PROGRESS
#
# The Python Imaging Library
# $Id$
#
# portable compiled font file parser
#
# history:
# 1997-08-19 fl   created
# 2003-09-13 fl   fixed loading of unicode fonts
#
# Copyright (c) 1997-2003 by Secret Labs AB.
# Copyright (c) 1997-2003 by Fredrik Lundh.
#
# See the README file for information on usage and redistribution.
#
from __future__ import annotations

import io
from typing import BinaryIO, Callable

from . import FontFile, Image
from ._binary import i8
from ._binary import i16be as b16
from ._binary import i16le as l16
from ._binary import i32be as b32
from ._binary import i32le as l32

# --------------------------------------------------------------------
# declarations

PCF_MAGIC = 0x70636601  # "\x01fcp"

PCF_PROPERTIES = 1 << 0
PCF_ACCELERATORS = 1 << 1
PCF_METRICS = 1 << 2
PCF_BITMAPS = 1 << 3
PCF_INK_METRICS = 1 << 4
PCF_BDF_ENCODINGS = 1 << 5
PCF_SWIDTHS = 1 << 6
PCF_GLYPH_NAMES = 1 << 7
PCF_BDF_ACCELERATORS = 1 << 8

BYTES_PER_ROW: list[Callable[[int], int]] = [
    lambda bits: ((bits + 7) >> 3),
    lambda bits: ((bits + 15) >> 3) & ~1,
    lambda bits: ((bits + 31) >> 3) & ~3,
    lambda bits: ((bits + 63) >> 3) & ~7,
]


def sz(s: bytes, o: int) -> bytes:
    return s[o : s.index(b"\0", o)]


class PcfFontFile(FontFile.FontFile):
    """Font file plugin for the X11 PCF format."""

    name = "name"

    def __init__(self, fp: BinaryIO, charset_encoding: str = "iso8859-1"):
        self.charset_encoding = charset_encoding

        magic = l32(fp.read(4))
        if magic != PCF_MAGIC:
            msg = "not a PCF file"
            raise SyntaxError(msg)

        super().__init__()

        count = l32(fp.read(4))
        self.toc = {}
        for i in range(count):
            type = l32(fp.read(4))
            self.toc[type] = l32(fp.read(4)), l32(fp.read(4)), l32(fp.read(4))

        self.fp = fp

        self.info = self._load_properties()

        metrics = self._load_metrics()
        bitmaps = self._load_bitmaps(metrics)
        encoding = self._load_encoding()

        #
        # create glyph structure

        for ch, ix in enumerate(encoding):
            if ix is not None:
                (
                    xsize,
                    ysize,
                    left,
                    right,
                    width,
                    ascent,
                    descent,
                    attributes,
                ) = metrics[ix]
                self.glyph[ch] = (
                    (width, 0),
                    (left, descent - ysize, xsize + left, descent),
                    (0, 0, xsize, ysize),
                    bitmaps[ix],
                )

    def _getformat(
        self, tag: int
    ) -> tuple[BinaryIO, int, Callable[[bytes], int], Callable[[bytes], int]]:
        format, size, offset = self.toc[tag]

        fp = self.fp
        fp.seek(offset)

        format = l32(fp.read(4))

        if format & 4:
            i16, i32 = b16, b32
        else:
            i16, i32 = l16, l32

        return fp, format, i16, i32

    def _load_properties(self) -> dict[bytes, bytes | int]:
        #
        # font properties

        properties = {}

        fp, format, i16, i32 = self._getformat(PCF_PROPERTIES)

        nprops = i32(fp.read(4))

        # read property description
        p = [(i32(fp.read(4)), i8(fp.read(1)), i32(fp.read(4))) for _ in range(nprops)]

        if nprops & 3:
            fp.seek(4 - (nprops & 3), io.SEEK_CUR)  # pad

        data = fp.read(i32(fp.read(4)))

        for k, s, v in p:
            property_value: bytes | int = sz(data, v) if s else v
            properties[sz(data, k)] = property_value

        return properties

    def _load_metrics(self) -> list[tuple[int, int, int, int, int, int, int, int]]:
        #
        # font metrics

        metrics: list[tuple[int, int, int, int, int, int, int, int]] = []

        fp, format, i16, i32 = self._getformat(PCF_METRICS)

        append = metrics.append

        if (format & 0xFF00) == 0x100:
            # "compressed" metrics
            for i in range(i16(fp.read(2))):
                left = i8(fp.read(1)) - 128
                right = i8(fp.read(1)) - 128
                width = i8(fp.read(1)) - 128
                ascent = i8(fp.read(1)) - 128
                descent = i8(fp.read(1)) - 128
                xsize = right - left
                ysize = ascent + descent
                append((xsize, ysize, left, right, width, ascent, descent, 0))

        else:
            # "jumbo" metrics
            for i in range(i32(fp.read(4))):
                left = i16(fp.read(2))
                right = i16(fp.read(2))
                width = i16(fp.read(2))
                ascent = i16(fp.read(2))
                descent = i16(fp.read(2))
                attributes = i16(fp.read(2))
                xsize = right - left
                ysize = ascent + descent
                append((xsize, ysize, left, right, width, ascent, descent, attributes))

        return metrics

    def _load_bitmaps(
        self, metrics: list[tuple[int, int, int, int, int, int, int, int]]
    ) -> list[Image.Image]:
        #
        # bitmap data

        fp, format, i16, i32 = self._getformat(PCF_BITMAPS)

        nbitmaps = i32(fp.read(4))

        if nbitmaps != len(metrics):
            msg = "Wrong number of bitmaps"
            raise OSError(msg)

        offsets = [i32(fp.read(4)) for _ in range(nbitmaps)]

        bitmap_sizes = [i32(fp.read(4)) for _ in range(4)]

        # byteorder = format & 4  # non-zero => MSB
        bitorder = format & 8  # non-zero => MSB
        padindex = format & 3

        bitmapsize = bitmap_sizes[padindex]
        offsets.append(bitmapsize)

        data = fp.read(bitmapsize)

        pad = BYTES_PER_ROW[padindex]
        mode = "1;R"
        if bitorder:
            mode = "1"

        bitmaps = []
        for i in range(nbitmaps):
            xsize, ysize = metrics[i][:2]
            b, e = offsets[i : i + 2]
            bitmaps.append(
                Image.frombytes("1", (xsize, ysize), data[b:e], "raw", mode, pad(xsize))
            )

        return bitmaps

    def _load_encoding(self) -> list[int | None]:
        fp, format, i16, i32 = self._getformat(PCF_BDF_ENCODINGS)

        first_col, last_col = i16(fp.read(2)), i16(fp.read(2))
        first_row, last_row = i16(fp.read(2)), i16(fp.read(2))

        i16(fp.read(2))  # default

        nencoding = (last_col - first_col + 1) * (last_row - first_row + 1)

        # map character code to bitmap index
        encoding: list[int | None] = [None] * min(256, nencoding)

        encoding_offsets = [i16(fp.read(2)) for _ in range(nencoding)]

        for i in range(first_col, len(encoding)):
            try:
                encoding_offset = encoding_offsets[
                    ord(bytearray([i]).decode(self.charset_encoding))
                ]
                if encoding_offset != 0xFFFF:
                    encoding[i] = encoding_offset
            except UnicodeDecodeError:
                # character is not supported in selected encoding
                pass

        return encoding
first commit 2024-09-15 12:12:16 +00:00			`#`
			`# THIS IS WORK IN PROGRESS`
			`#`
			`# The Python Imaging Library`
			`# $Id$`
			`#`
			`# portable compiled font file parser`
			`#`
			`# history:`
			`# 1997-08-19 fl created`
			`# 2003-09-13 fl fixed loading of unicode fonts`
			`#`
			`# Copyright (c) 1997-2003 by Secret Labs AB.`
			`# Copyright (c) 1997-2003 by Fredrik Lundh.`
			`#`
			`# See the README file for information on usage and redistribution.`
			`#`
			`from __future__ import annotations`

			`import io`
			`from typing import BinaryIO, Callable`

			`from . import FontFile, Image`
			`from ._binary import i8`
			`from ._binary import i16be as b16`
			`from ._binary import i16le as l16`
			`from ._binary import i32be as b32`
			`from ._binary import i32le as l32`

			`# --------------------------------------------------------------------`
			`# declarations`

			`PCF_MAGIC = 0x70636601 # "\x01fcp"`

			`PCF_PROPERTIES = 1 << 0`
			`PCF_ACCELERATORS = 1 << 1`
			`PCF_METRICS = 1 << 2`
			`PCF_BITMAPS = 1 << 3`
			`PCF_INK_METRICS = 1 << 4`
			`PCF_BDF_ENCODINGS = 1 << 5`
			`PCF_SWIDTHS = 1 << 6`
			`PCF_GLYPH_NAMES = 1 << 7`
			`PCF_BDF_ACCELERATORS = 1 << 8`

			`BYTES_PER_ROW: list[Callable[[int], int]] = [`
			`lambda bits: ((bits + 7) >> 3),`
			`lambda bits: ((bits + 15) >> 3) & ~1,`
			`lambda bits: ((bits + 31) >> 3) & ~3,`
			`lambda bits: ((bits + 63) >> 3) & ~7,`
			`]`


			`def sz(s: bytes, o: int) -> bytes:`
			`return s[o : s.index(b"\0", o)]`


			`class PcfFontFile(FontFile.FontFile):`
			`"""Font file plugin for the X11 PCF format."""`

			`name = "name"`

			`def __init__(self, fp: BinaryIO, charset_encoding: str = "iso8859-1"):`
			`self.charset_encoding = charset_encoding`

			`magic = l32(fp.read(4))`
			`if magic != PCF_MAGIC:`
			`msg = "not a PCF file"`
			`raise SyntaxError(msg)`

			`super().__init__()`

			`count = l32(fp.read(4))`
			`self.toc = {}`
			`for i in range(count):`
			`type = l32(fp.read(4))`
			`self.toc[type] = l32(fp.read(4)), l32(fp.read(4)), l32(fp.read(4))`

			`self.fp = fp`

			`self.info = self._load_properties()`

			`metrics = self._load_metrics()`
			`bitmaps = self._load_bitmaps(metrics)`
			`encoding = self._load_encoding()`

			`#`
			`# create glyph structure`

			`for ch, ix in enumerate(encoding):`
			`if ix is not None:`
			`(`
			`xsize,`
			`ysize,`
			`left,`
			`right,`
			`width,`
			`ascent,`
			`descent,`
			`attributes,`
			`) = metrics[ix]`
			`self.glyph[ch] = (`
			`(width, 0),`
			`(left, descent - ysize, xsize + left, descent),`
			`(0, 0, xsize, ysize),`
			`bitmaps[ix],`
			`)`

			`def _getformat(`
			`self, tag: int`
			`) -> tuple[BinaryIO, int, Callable[[bytes], int], Callable[[bytes], int]]:`
			`format, size, offset = self.toc[tag]`

			`fp = self.fp`
			`fp.seek(offset)`

			`format = l32(fp.read(4))`

			`if format & 4:`
			`i16, i32 = b16, b32`
			`else:`
			`i16, i32 = l16, l32`

			`return fp, format, i16, i32`

			`def _load_properties(self) -> dict[bytes, bytes \| int]:`
			`#`
			`# font properties`

			`properties = {}`

			`fp, format, i16, i32 = self._getformat(PCF_PROPERTIES)`

			`nprops = i32(fp.read(4))`

			`# read property description`
			`p = [(i32(fp.read(4)), i8(fp.read(1)), i32(fp.read(4))) for _ in range(nprops)]`

			`if nprops & 3:`
			`fp.seek(4 - (nprops & 3), io.SEEK_CUR) # pad`

			`data = fp.read(i32(fp.read(4)))`

			`for k, s, v in p:`
			`property_value: bytes \| int = sz(data, v) if s else v`
			`properties[sz(data, k)] = property_value`

			`return properties`

			`def _load_metrics(self) -> list[tuple[int, int, int, int, int, int, int, int]]:`
			`#`
			`# font metrics`

			`metrics: list[tuple[int, int, int, int, int, int, int, int]] = []`

			`fp, format, i16, i32 = self._getformat(PCF_METRICS)`

			`append = metrics.append`

			`if (format & 0xFF00) == 0x100:`
			`# "compressed" metrics`
			`for i in range(i16(fp.read(2))):`
			`left = i8(fp.read(1)) - 128`
			`right = i8(fp.read(1)) - 128`
			`width = i8(fp.read(1)) - 128`
			`ascent = i8(fp.read(1)) - 128`
			`descent = i8(fp.read(1)) - 128`
			`xsize = right - left`
			`ysize = ascent + descent`
			`append((xsize, ysize, left, right, width, ascent, descent, 0))`

			`else:`
			`# "jumbo" metrics`
			`for i in range(i32(fp.read(4))):`
			`left = i16(fp.read(2))`
			`right = i16(fp.read(2))`
			`width = i16(fp.read(2))`
			`ascent = i16(fp.read(2))`
			`descent = i16(fp.read(2))`
			`attributes = i16(fp.read(2))`
			`xsize = right - left`
			`ysize = ascent + descent`
			`append((xsize, ysize, left, right, width, ascent, descent, attributes))`

			`return metrics`

			`def _load_bitmaps(`
			`self, metrics: list[tuple[int, int, int, int, int, int, int, int]]`
			`) -> list[Image.Image]:`
			`#`
			`# bitmap data`

			`fp, format, i16, i32 = self._getformat(PCF_BITMAPS)`

			`nbitmaps = i32(fp.read(4))`

			`if nbitmaps != len(metrics):`
			`msg = "Wrong number of bitmaps"`
			`raise OSError(msg)`

			`offsets = [i32(fp.read(4)) for _ in range(nbitmaps)]`

			`bitmap_sizes = [i32(fp.read(4)) for _ in range(4)]`

			`# byteorder = format & 4 # non-zero => MSB`
			`bitorder = format & 8 # non-zero => MSB`
			`padindex = format & 3`

			`bitmapsize = bitmap_sizes[padindex]`
			`offsets.append(bitmapsize)`

			`data = fp.read(bitmapsize)`

			`pad = BYTES_PER_ROW[padindex]`
			`mode = "1;R"`
			`if bitorder:`
			`mode = "1"`

			`bitmaps = []`
			`for i in range(nbitmaps):`
			`xsize, ysize = metrics[i][:2]`
			`b, e = offsets[i : i + 2]`
			`bitmaps.append(`
			`Image.frombytes("1", (xsize, ysize), data[b:e], "raw", mode, pad(xsize))`
			`)`

			`return bitmaps`

			`def _load_encoding(self) -> list[int \| None]:`
			`fp, format, i16, i32 = self._getformat(PCF_BDF_ENCODINGS)`

			`first_col, last_col = i16(fp.read(2)), i16(fp.read(2))`
			`first_row, last_row = i16(fp.read(2)), i16(fp.read(2))`

			`i16(fp.read(2)) # default`

			`nencoding = (last_col - first_col + 1) * (last_row - first_row + 1)`

			`# map character code to bitmap index`
			`encoding: list[int \| None] = [None] * min(256, nencoding)`

			`encoding_offsets = [i16(fp.read(2)) for _ in range(nencoding)]`

			`for i in range(first_col, len(encoding)):`
			`try:`
			`encoding_offset = encoding_offsets[`
			`ord(bytearray([i]).decode(self.charset_encoding))`
			`]`
			`if encoding_offset != 0xFFFF:`
			`encoding[i] = encoding_offset`
			`except UnicodeDecodeError:`
			`# character is not supported in selected encoding`
			`pass`

			`return encoding`