/
dviread.py
1107 lines (952 loc) · 40.4 KB
/
dviread.py
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"""
A module for reading dvi files output by TeX. Several limitations make
this not (currently) useful as a general-purpose dvi preprocessor, but
it is currently used by the pdf backend for processing usetex text.
Interface::
with Dvi(filename, 72) as dvi:
# iterate over pages:
for page in dvi:
w, h, d = page.width, page.height, page.descent
for x, y, font, glyph, width in page.text:
fontname = font.texname
pointsize = font.size
...
for x, y, height, width in page.boxes:
...
"""
from collections import namedtuple
import enum
from functools import lru_cache, partial, wraps
import logging
import os
from pathlib import Path
import re
import struct
import subprocess
import sys
import numpy as np
from matplotlib import _api, cbook
_log = logging.getLogger(__name__)
# Many dvi related files are looked for by external processes, require
# additional parsing, and are used many times per rendering, which is why they
# are cached using lru_cache().
# Dvi is a bytecode format documented in
# https://ctan.org/pkg/dvitype
# https://texdoc.org/serve/dvitype.pdf/0
#
# The file consists of a preamble, some number of pages, a postamble,
# and a finale. Different opcodes are allowed in different contexts,
# so the Dvi object has a parser state:
#
# pre: expecting the preamble
# outer: between pages (followed by a page or the postamble,
# also e.g. font definitions are allowed)
# page: processing a page
# post_post: state after the postamble (our current implementation
# just stops reading)
# finale: the finale (unimplemented in our current implementation)
_dvistate = enum.Enum('DviState', 'pre outer inpage post_post finale')
# The marks on a page consist of text and boxes. A page also has dimensions.
Page = namedtuple('Page', 'text boxes height width descent')
Box = namedtuple('Box', 'x y height width')
# Also a namedtuple, for backcompat.
class Text(namedtuple('Text', 'x y font glyph width')):
"""
A glyph in the dvi file.
The *x* and *y* attributes directly position the glyph. The *font*,
*glyph*, and *width* attributes are kept public for back-compatibility,
but users wanting to draw the glyph themselves are encouraged to instead
load the font specified by `font_path` at `font_size`, warp it with the
effects specified by `font_effects`, and load the glyph specified by
`glyph_name_or_index`.
"""
def _get_pdftexmap_entry(self):
return PsfontsMap(find_tex_file("pdftex.map"))[self.font.texname]
@property
def font_path(self):
"""The `~pathlib.Path` to the font for this glyph."""
psfont = self._get_pdftexmap_entry()
if psfont.filename is None:
raise ValueError("No usable font file found for {} ({}); "
"the font may lack a Type-1 version"
.format(psfont.psname.decode("ascii"),
psfont.texname.decode("ascii")))
return Path(psfont.filename)
@property
def font_size(self):
"""The font size."""
return self.font.size
@property
def font_effects(self):
"""
The "font effects" dict for this glyph.
This dict contains the values for this glyph of SlantFont and
ExtendFont (if any), read off :file:`pdftex.map`.
"""
return self._get_pdftexmap_entry().effects
@property
def glyph_name_or_index(self):
"""
Either the glyph name or the native charmap glyph index.
If :file:`pdftex.map` specifies an encoding for this glyph's font, that
is a mapping of glyph indices to Adobe glyph names; use it to convert
dvi indices to glyph names. Callers can then convert glyph names to
glyph indices (with FT_Get_Name_Index/get_name_index), and load the
glyph using FT_Load_Glyph/load_glyph.
If :file:`pdftex.map` specifies no encoding, the indices directly map
to the font's "native" charmap; glyphs should directly load using
FT_Load_Char/load_char after selecting the native charmap.
"""
entry = self._get_pdftexmap_entry()
return (_parse_enc(entry.encoding)[self.glyph]
if entry.encoding is not None else self.glyph)
# Opcode argument parsing
#
# Each of the following functions takes a Dvi object and delta, which is the
# difference between the opcode and the minimum opcode with the same meaning.
# Dvi opcodes often encode the number of argument bytes in this delta.
_arg_mapping = dict(
# raw: Return delta as is.
raw=lambda dvi, delta: delta,
# u1: Read 1 byte as an unsigned number.
u1=lambda dvi, delta: dvi._arg(1, signed=False),
# u4: Read 4 bytes as an unsigned number.
u4=lambda dvi, delta: dvi._arg(4, signed=False),
# s4: Read 4 bytes as a signed number.
s4=lambda dvi, delta: dvi._arg(4, signed=True),
# slen: Read delta bytes as a signed number, or None if delta is None.
slen=lambda dvi, delta: dvi._arg(delta, signed=True) if delta else None,
# slen1: Read (delta + 1) bytes as a signed number.
slen1=lambda dvi, delta: dvi._arg(delta + 1, signed=True),
# ulen1: Read (delta + 1) bytes as an unsigned number.
ulen1=lambda dvi, delta: dvi._arg(delta + 1, signed=False),
# olen1: Read (delta + 1) bytes as an unsigned number if less than 4 bytes,
# as a signed number if 4 bytes.
olen1=lambda dvi, delta: dvi._arg(delta + 1, signed=(delta == 3)),
)
def _dispatch(table, min, max=None, state=None, args=('raw',)):
"""
Decorator for dispatch by opcode. Sets the values in *table*
from *min* to *max* to this method, adds a check that the Dvi state
matches *state* if not None, reads arguments from the file according
to *args*.
Parameters
----------
table : dict[int, callable]
The dispatch table to be filled in.
min, max : int
Range of opcodes that calls the registered function; *max* defaults to
*min*.
state : _dvistate, optional
State of the Dvi object in which these opcodes are allowed.
args : list[str], default: ['raw']
Sequence of argument specifications:
- 'raw': opcode minus minimum
- 'u1': read one unsigned byte
- 'u4': read four bytes, treat as an unsigned number
- 's4': read four bytes, treat as a signed number
- 'slen': read (opcode - minimum) bytes, treat as signed
- 'slen1': read (opcode - minimum + 1) bytes, treat as signed
- 'ulen1': read (opcode - minimum + 1) bytes, treat as unsigned
- 'olen1': read (opcode - minimum + 1) bytes, treat as unsigned
if under four bytes, signed if four bytes
"""
def decorate(method):
get_args = [_arg_mapping[x] for x in args]
@wraps(method)
def wrapper(self, byte):
if state is not None and self.state != state:
raise ValueError("state precondition failed")
return method(self, *[f(self, byte-min) for f in get_args])
if max is None:
table[min] = wrapper
else:
for i in range(min, max+1):
assert table[i] is None
table[i] = wrapper
return wrapper
return decorate
class Dvi:
"""
A reader for a dvi ("device-independent") file, as produced by TeX.
The current implementation can only iterate through pages in order,
and does not even attempt to verify the postamble.
This class can be used as a context manager to close the underlying
file upon exit. Pages can be read via iteration. Here is an overly
simple way to extract text without trying to detect whitespace::
>>> with matplotlib.dviread.Dvi('input.dvi', 72) as dvi:
... for page in dvi:
... print(''.join(chr(t.glyph) for t in page.text))
"""
# dispatch table
_dtable = [None] * 256
_dispatch = partial(_dispatch, _dtable)
def __init__(self, filename, dpi):
"""
Read the data from the file named *filename* and convert
TeX's internal units to units of *dpi* per inch.
*dpi* only sets the units and does not limit the resolution.
Use None to return TeX's internal units.
"""
_log.debug('Dvi: %s', filename)
self.file = open(filename, 'rb')
self.dpi = dpi
self.fonts = {}
self.state = _dvistate.pre
def __enter__(self):
"""Context manager enter method, does nothing."""
return self
def __exit__(self, etype, evalue, etrace):
"""
Context manager exit method, closes the underlying file if it is open.
"""
self.close()
def __iter__(self):
"""
Iterate through the pages of the file.
Yields
------
Page
Details of all the text and box objects on the page.
The Page tuple contains lists of Text and Box tuples and
the page dimensions, and the Text and Box tuples contain
coordinates transformed into a standard Cartesian
coordinate system at the dpi value given when initializing.
The coordinates are floating point numbers, but otherwise
precision is not lost and coordinate values are not clipped to
integers.
"""
while self._read():
yield self._output()
def close(self):
"""Close the underlying file if it is open."""
if not self.file.closed:
self.file.close()
def _output(self):
"""
Output the text and boxes belonging to the most recent page.
page = dvi._output()
"""
minx, miny, maxx, maxy = np.inf, np.inf, -np.inf, -np.inf
maxy_pure = -np.inf
for elt in self.text + self.boxes:
if isinstance(elt, Box):
x, y, h, w = elt
e = 0 # zero depth
else: # glyph
x, y, font, g, w = elt
h, e = font._height_depth_of(g)
minx = min(minx, x)
miny = min(miny, y - h)
maxx = max(maxx, x + w)
maxy = max(maxy, y + e)
maxy_pure = max(maxy_pure, y)
if self._baseline_v is not None:
maxy_pure = self._baseline_v # This should normally be the case.
self._baseline_v = None
if not self.text and not self.boxes: # Avoid infs/nans from inf+/-inf.
return Page(text=[], boxes=[], width=0, height=0, descent=0)
if self.dpi is None:
# special case for ease of debugging: output raw dvi coordinates
return Page(text=self.text, boxes=self.boxes,
width=maxx-minx, height=maxy_pure-miny,
descent=maxy-maxy_pure)
# convert from TeX's "scaled points" to dpi units
d = self.dpi / (72.27 * 2**16)
descent = (maxy - maxy_pure) * d
text = [Text((x-minx)*d, (maxy-y)*d - descent, f, g, w*d)
for (x, y, f, g, w) in self.text]
boxes = [Box((x-minx)*d, (maxy-y)*d - descent, h*d, w*d)
for (x, y, h, w) in self.boxes]
return Page(text=text, boxes=boxes, width=(maxx-minx)*d,
height=(maxy_pure-miny)*d, descent=descent)
def _read(self):
"""
Read one page from the file. Return True if successful,
False if there were no more pages.
"""
# Pages appear to start with the sequence
# bop (begin of page)
# xxx comment
# <push, ..., pop> # if using chemformula
# down
# push
# down
# <push, push, xxx, right, xxx, pop, pop> # if using xcolor
# down
# push
# down (possibly multiple)
# push <= here, v is the baseline position.
# etc.
# (dviasm is useful to explore this structure.)
# Thus, we use the vertical position at the first time the stack depth
# reaches 3, while at least three "downs" have been executed (excluding
# those popped out (corresponding to the chemformula preamble)), as the
# baseline (the "down" count is necessary to handle xcolor).
down_stack = [0]
self._baseline_v = None
while True:
byte = self.file.read(1)[0]
self._dtable[byte](self, byte)
name = self._dtable[byte].__name__
if name == "_push":
down_stack.append(down_stack[-1])
elif name == "_pop":
down_stack.pop()
elif name == "_down":
down_stack[-1] += 1
if (self._baseline_v is None
and len(getattr(self, "stack", [])) == 3
and down_stack[-1] >= 4):
self._baseline_v = self.v
if byte == 140: # end of page
return True
if self.state is _dvistate.post_post: # end of file
self.close()
return False
def _arg(self, nbytes, signed=False):
"""
Read and return a big-endian integer *nbytes* long.
Signedness is determined by the *signed* keyword.
"""
return int.from_bytes(self.file.read(nbytes), "big", signed=signed)
@_dispatch(min=0, max=127, state=_dvistate.inpage)
def _set_char_immediate(self, char):
self._put_char_real(char)
self.h += self.fonts[self.f]._width_of(char)
@_dispatch(min=128, max=131, state=_dvistate.inpage, args=('olen1',))
def _set_char(self, char):
self._put_char_real(char)
self.h += self.fonts[self.f]._width_of(char)
@_dispatch(132, state=_dvistate.inpage, args=('s4', 's4'))
def _set_rule(self, a, b):
self._put_rule_real(a, b)
self.h += b
@_dispatch(min=133, max=136, state=_dvistate.inpage, args=('olen1',))
def _put_char(self, char):
self._put_char_real(char)
def _put_char_real(self, char):
font = self.fonts[self.f]
if font._vf is None:
self.text.append(Text(self.h, self.v, font, char,
font._width_of(char)))
else:
scale = font._scale
for x, y, f, g, w in font._vf[char].text:
newf = DviFont(scale=_mul2012(scale, f._scale),
tfm=f._tfm, texname=f.texname, vf=f._vf)
self.text.append(Text(self.h + _mul2012(x, scale),
self.v + _mul2012(y, scale),
newf, g, newf._width_of(g)))
self.boxes.extend([Box(self.h + _mul2012(x, scale),
self.v + _mul2012(y, scale),
_mul2012(a, scale), _mul2012(b, scale))
for x, y, a, b in font._vf[char].boxes])
@_dispatch(137, state=_dvistate.inpage, args=('s4', 's4'))
def _put_rule(self, a, b):
self._put_rule_real(a, b)
def _put_rule_real(self, a, b):
if a > 0 and b > 0:
self.boxes.append(Box(self.h, self.v, a, b))
@_dispatch(138)
def _nop(self, _):
pass
@_dispatch(139, state=_dvistate.outer, args=('s4',)*11)
def _bop(self, c0, c1, c2, c3, c4, c5, c6, c7, c8, c9, p):
self.state = _dvistate.inpage
self.h, self.v, self.w, self.x, self.y, self.z = 0, 0, 0, 0, 0, 0
self.stack = []
self.text = [] # list of Text objects
self.boxes = [] # list of Box objects
@_dispatch(140, state=_dvistate.inpage)
def _eop(self, _):
self.state = _dvistate.outer
del self.h, self.v, self.w, self.x, self.y, self.z, self.stack
@_dispatch(141, state=_dvistate.inpage)
def _push(self, _):
self.stack.append((self.h, self.v, self.w, self.x, self.y, self.z))
@_dispatch(142, state=_dvistate.inpage)
def _pop(self, _):
self.h, self.v, self.w, self.x, self.y, self.z = self.stack.pop()
@_dispatch(min=143, max=146, state=_dvistate.inpage, args=('slen1',))
def _right(self, b):
self.h += b
@_dispatch(min=147, max=151, state=_dvistate.inpage, args=('slen',))
def _right_w(self, new_w):
if new_w is not None:
self.w = new_w
self.h += self.w
@_dispatch(min=152, max=156, state=_dvistate.inpage, args=('slen',))
def _right_x(self, new_x):
if new_x is not None:
self.x = new_x
self.h += self.x
@_dispatch(min=157, max=160, state=_dvistate.inpage, args=('slen1',))
def _down(self, a):
self.v += a
@_dispatch(min=161, max=165, state=_dvistate.inpage, args=('slen',))
def _down_y(self, new_y):
if new_y is not None:
self.y = new_y
self.v += self.y
@_dispatch(min=166, max=170, state=_dvistate.inpage, args=('slen',))
def _down_z(self, new_z):
if new_z is not None:
self.z = new_z
self.v += self.z
@_dispatch(min=171, max=234, state=_dvistate.inpage)
def _fnt_num_immediate(self, k):
self.f = k
@_dispatch(min=235, max=238, state=_dvistate.inpage, args=('olen1',))
def _fnt_num(self, new_f):
self.f = new_f
@_dispatch(min=239, max=242, args=('ulen1',))
def _xxx(self, datalen):
special = self.file.read(datalen)
_log.debug(
'Dvi._xxx: encountered special: %s',
''.join([chr(ch) if 32 <= ch < 127 else '<%02x>' % ch
for ch in special]))
@_dispatch(min=243, max=246, args=('olen1', 'u4', 'u4', 'u4', 'u1', 'u1'))
def _fnt_def(self, k, c, s, d, a, l):
self._fnt_def_real(k, c, s, d, a, l)
def _fnt_def_real(self, k, c, s, d, a, l):
n = self.file.read(a + l)
fontname = n[-l:].decode('ascii')
tfm = _tfmfile(fontname)
if c != 0 and tfm.checksum != 0 and c != tfm.checksum:
raise ValueError('tfm checksum mismatch: %s' % n)
try:
vf = _vffile(fontname)
except FileNotFoundError:
vf = None
self.fonts[k] = DviFont(scale=s, tfm=tfm, texname=n, vf=vf)
@_dispatch(247, state=_dvistate.pre, args=('u1', 'u4', 'u4', 'u4', 'u1'))
def _pre(self, i, num, den, mag, k):
self.file.read(k) # comment in the dvi file
if i != 2:
raise ValueError("Unknown dvi format %d" % i)
if num != 25400000 or den != 7227 * 2**16:
raise ValueError("Nonstandard units in dvi file")
# meaning: TeX always uses those exact values, so it
# should be enough for us to support those
# (There are 72.27 pt to an inch so 7227 pt =
# 7227 * 2**16 sp to 100 in. The numerator is multiplied
# by 10^5 to get units of 10**-7 meters.)
if mag != 1000:
raise ValueError("Nonstandard magnification in dvi file")
# meaning: LaTeX seems to frown on setting \mag, so
# I think we can assume this is constant
self.state = _dvistate.outer
@_dispatch(248, state=_dvistate.outer)
def _post(self, _):
self.state = _dvistate.post_post
# TODO: actually read the postamble and finale?
# currently post_post just triggers closing the file
@_dispatch(249)
def _post_post(self, _):
raise NotImplementedError
@_dispatch(min=250, max=255)
def _malformed(self, offset):
raise ValueError(f"unknown command: byte {250 + offset}")
class DviFont:
"""
Encapsulation of a font that a DVI file can refer to.
This class holds a font's texname and size, supports comparison,
and knows the widths of glyphs in the same units as the AFM file.
There are also internal attributes (for use by dviread.py) that
are *not* used for comparison.
The size is in Adobe points (converted from TeX points).
Parameters
----------
scale : float
Factor by which the font is scaled from its natural size.
tfm : Tfm
TeX font metrics for this font
texname : bytes
Name of the font as used internally by TeX and friends, as an ASCII
bytestring. This is usually very different from any external font
names; `PsfontsMap` can be used to find the external name of the font.
vf : Vf
A TeX "virtual font" file, or None if this font is not virtual.
Attributes
----------
texname : bytes
size : float
Size of the font in Adobe points, converted from the slightly
smaller TeX points.
widths : list
Widths of glyphs in glyph-space units, typically 1/1000ths of
the point size.
"""
__slots__ = ('texname', 'size', 'widths', '_scale', '_vf', '_tfm')
def __init__(self, scale, tfm, texname, vf):
_api.check_isinstance(bytes, texname=texname)
self._scale = scale
self._tfm = tfm
self.texname = texname
self._vf = vf
self.size = scale * (72.0 / (72.27 * 2**16))
try:
nchars = max(tfm.width) + 1
except ValueError:
nchars = 0
self.widths = [(1000*tfm.width.get(char, 0)) >> 20
for char in range(nchars)]
def __eq__(self, other):
return (type(self) is type(other)
and self.texname == other.texname and self.size == other.size)
def __ne__(self, other):
return not self.__eq__(other)
def __repr__(self):
return f"<{type(self).__name__}: {self.texname}>"
def _width_of(self, char):
"""Width of char in dvi units."""
width = self._tfm.width.get(char, None)
if width is not None:
return _mul2012(width, self._scale)
_log.debug('No width for char %d in font %s.', char, self.texname)
return 0
def _height_depth_of(self, char):
"""Height and depth of char in dvi units."""
result = []
for metric, name in ((self._tfm.height, "height"),
(self._tfm.depth, "depth")):
value = metric.get(char, None)
if value is None:
_log.debug('No %s for char %d in font %s',
name, char, self.texname)
result.append(0)
else:
result.append(_mul2012(value, self._scale))
# cmsyXX (symbols font) glyph 0 ("minus") has a nonzero descent
# so that TeX aligns equations properly
# (https://tex.stackexchange.com/q/526103/)
# but we actually care about the rasterization depth to align
# the dvipng-generated images.
if re.match(br'^cmsy\d+$', self.texname) and char == 0:
result[-1] = 0
return result
class Vf(Dvi):
r"""
A virtual font (\*.vf file) containing subroutines for dvi files.
Parameters
----------
filename : str or path-like
Notes
-----
The virtual font format is a derivative of dvi:
http://mirrors.ctan.org/info/knuth/virtual-fonts
This class reuses some of the machinery of `Dvi`
but replaces the `_read` loop and dispatch mechanism.
Examples
--------
::
vf = Vf(filename)
glyph = vf[code]
glyph.text, glyph.boxes, glyph.width
"""
def __init__(self, filename):
super().__init__(filename, 0)
try:
self._first_font = None
self._chars = {}
self._read()
finally:
self.close()
def __getitem__(self, code):
return self._chars[code]
def _read(self):
"""
Read one page from the file. Return True if successful,
False if there were no more pages.
"""
packet_char, packet_ends = None, None
packet_len, packet_width = None, None
while True:
byte = self.file.read(1)[0]
# If we are in a packet, execute the dvi instructions
if self.state is _dvistate.inpage:
byte_at = self.file.tell()-1
if byte_at == packet_ends:
self._finalize_packet(packet_char, packet_width)
packet_len, packet_char, packet_width = None, None, None
# fall through to out-of-packet code
elif byte_at > packet_ends:
raise ValueError("Packet length mismatch in vf file")
else:
if byte in (139, 140) or byte >= 243:
raise ValueError(
"Inappropriate opcode %d in vf file" % byte)
Dvi._dtable[byte](self, byte)
continue
# We are outside a packet
if byte < 242: # a short packet (length given by byte)
packet_len = byte
packet_char, packet_width = self._arg(1), self._arg(3)
packet_ends = self._init_packet(byte)
self.state = _dvistate.inpage
elif byte == 242: # a long packet
packet_len, packet_char, packet_width = \
[self._arg(x) for x in (4, 4, 4)]
self._init_packet(packet_len)
elif 243 <= byte <= 246:
k = self._arg(byte - 242, byte == 246)
c, s, d, a, l = [self._arg(x) for x in (4, 4, 4, 1, 1)]
self._fnt_def_real(k, c, s, d, a, l)
if self._first_font is None:
self._first_font = k
elif byte == 247: # preamble
i, k = self._arg(1), self._arg(1)
x = self.file.read(k)
cs, ds = self._arg(4), self._arg(4)
self._pre(i, x, cs, ds)
elif byte == 248: # postamble (just some number of 248s)
break
else:
raise ValueError("Unknown vf opcode %d" % byte)
def _init_packet(self, pl):
if self.state != _dvistate.outer:
raise ValueError("Misplaced packet in vf file")
self.h, self.v, self.w, self.x, self.y, self.z = 0, 0, 0, 0, 0, 0
self.stack, self.text, self.boxes = [], [], []
self.f = self._first_font
return self.file.tell() + pl
def _finalize_packet(self, packet_char, packet_width):
self._chars[packet_char] = Page(
text=self.text, boxes=self.boxes, width=packet_width,
height=None, descent=None)
self.state = _dvistate.outer
def _pre(self, i, x, cs, ds):
if self.state is not _dvistate.pre:
raise ValueError("pre command in middle of vf file")
if i != 202:
raise ValueError("Unknown vf format %d" % i)
if len(x):
_log.debug('vf file comment: %s', x)
self.state = _dvistate.outer
# cs = checksum, ds = design size
def _mul2012(num1, num2):
"""Multiply two numbers in 20.12 fixed point format."""
# Separated into a function because >> has surprising precedence
return (num1*num2) >> 20
class Tfm:
"""
A TeX Font Metric file.
This implementation covers only the bare minimum needed by the Dvi class.
Parameters
----------
filename : str or path-like
Attributes
----------
checksum : int
Used for verifying against the dvi file.
design_size : int
Design size of the font (unknown units)
width, height, depth : dict
Dimensions of each character, need to be scaled by the factor
specified in the dvi file. These are dicts because indexing may
not start from 0.
"""
__slots__ = ('checksum', 'design_size', 'width', 'height', 'depth')
def __init__(self, filename):
_log.debug('opening tfm file %s', filename)
with open(filename, 'rb') as file:
header1 = file.read(24)
lh, bc, ec, nw, nh, nd = struct.unpack('!6H', header1[2:14])
_log.debug('lh=%d, bc=%d, ec=%d, nw=%d, nh=%d, nd=%d',
lh, bc, ec, nw, nh, nd)
header2 = file.read(4*lh)
self.checksum, self.design_size = struct.unpack('!2I', header2[:8])
# there is also encoding information etc.
char_info = file.read(4*(ec-bc+1))
widths = struct.unpack(f'!{nw}i', file.read(4*nw))
heights = struct.unpack(f'!{nh}i', file.read(4*nh))
depths = struct.unpack(f'!{nd}i', file.read(4*nd))
self.width, self.height, self.depth = {}, {}, {}
for idx, char in enumerate(range(bc, ec+1)):
byte0 = char_info[4*idx]
byte1 = char_info[4*idx+1]
self.width[char] = widths[byte0]
self.height[char] = heights[byte1 >> 4]
self.depth[char] = depths[byte1 & 0xf]
PsFont = namedtuple('PsFont', 'texname psname effects encoding filename')
class PsfontsMap:
"""
A psfonts.map formatted file, mapping TeX fonts to PS fonts.
Parameters
----------
filename : str or path-like
Notes
-----
For historical reasons, TeX knows many Type-1 fonts by different
names than the outside world. (For one thing, the names have to
fit in eight characters.) Also, TeX's native fonts are not Type-1
but Metafont, which is nontrivial to convert to PostScript except
as a bitmap. While high-quality conversions to Type-1 format exist
and are shipped with modern TeX distributions, we need to know
which Type-1 fonts are the counterparts of which native fonts. For
these reasons a mapping is needed from internal font names to font
file names.
A texmf tree typically includes mapping files called e.g.
:file:`psfonts.map`, :file:`pdftex.map`, or :file:`dvipdfm.map`.
The file :file:`psfonts.map` is used by :program:`dvips`,
:file:`pdftex.map` by :program:`pdfTeX`, and :file:`dvipdfm.map`
by :program:`dvipdfm`. :file:`psfonts.map` might avoid embedding
the 35 PostScript fonts (i.e., have no filename for them, as in
the Times-Bold example above), while the pdf-related files perhaps
only avoid the "Base 14" pdf fonts. But the user may have
configured these files differently.
Examples
--------
>>> map = PsfontsMap(find_tex_file('pdftex.map'))
>>> entry = map[b'ptmbo8r']
>>> entry.texname
b'ptmbo8r'
>>> entry.psname
b'Times-Bold'
>>> entry.encoding
'/usr/local/texlive/2008/texmf-dist/fonts/enc/dvips/base/8r.enc'
>>> entry.effects
{'slant': 0.16700000000000001}
>>> entry.filename
"""
__slots__ = ('_filename', '_unparsed', '_parsed')
# Create a filename -> PsfontsMap cache, so that calling
# `PsfontsMap(filename)` with the same filename a second time immediately
# returns the same object.
@lru_cache
def __new__(cls, filename):
self = object.__new__(cls)
self._filename = os.fsdecode(filename)
# Some TeX distributions have enormous pdftex.map files which would
# take hundreds of milliseconds to parse, but it is easy enough to just
# store the unparsed lines (keyed by the first word, which is the
# texname) and parse them on-demand.
with open(filename, 'rb') as file:
self._unparsed = {}
for line in file:
tfmname = line.split(b' ', 1)[0]
self._unparsed.setdefault(tfmname, []).append(line)
self._parsed = {}
return self
def __getitem__(self, texname):
assert isinstance(texname, bytes)
if texname in self._unparsed:
for line in self._unparsed.pop(texname):
if self._parse_and_cache_line(line):
break
try:
return self._parsed[texname]
except KeyError:
raise LookupError(
f"An associated PostScript font (required by Matplotlib) "
f"could not be found for TeX font {texname.decode('ascii')!r} "
f"in {self._filename!r}; this problem can often be solved by "
f"installing a suitable PostScript font package in your TeX "
f"package manager") from None
def _parse_and_cache_line(self, line):
"""
Parse a line in the font mapping file.
The format is (partially) documented at
http://mirrors.ctan.org/systems/doc/pdftex/manual/pdftex-a.pdf
https://tug.org/texinfohtml/dvips.html#psfonts_002emap
Each line can have the following fields:
- tfmname (first, only required field),
- psname (defaults to tfmname, must come immediately after tfmname if
present),
- fontflags (integer, must come immediately after psname if present,
ignored by us),
- special (SlantFont and ExtendFont, only field that is double-quoted),
- fontfile, encodingfile (optional, prefixed by <, <<, or <[; << always
precedes a font, <[ always precedes an encoding, < can precede either
but then an encoding file must have extension .enc; < and << also
request different font subsetting behaviors but we ignore that; < can
be separated from the filename by whitespace).
special, fontfile, and encodingfile can appear in any order.
"""
# If the map file specifies multiple encodings for a font, we
# follow pdfTeX in choosing the last one specified. Such
# entries are probably mistakes but they have occurred.
# https://tex.stackexchange.com/q/10826/
if not line or line.startswith((b" ", b"%", b"*", b";", b"#")):
return
tfmname = basename = special = encodingfile = fontfile = None
is_subsetted = is_t1 = is_truetype = False
matches = re.finditer(br'"([^"]*)(?:"|$)|(\S+)', line)
for match in matches:
quoted, unquoted = match.groups()
if unquoted:
if unquoted.startswith(b"<<"): # font
fontfile = unquoted[2:]
elif unquoted.startswith(b"<["): # encoding
encodingfile = unquoted[2:]
elif unquoted.startswith(b"<"): # font or encoding
word = (
# <foo => foo
unquoted[1:]
# < by itself => read the next word
or next(filter(None, next(matches).groups())))
if word.endswith(b".enc"):
encodingfile = word
else:
fontfile = word
is_subsetted = True
elif tfmname is None:
tfmname = unquoted
elif basename is None:
basename = unquoted
elif quoted:
special = quoted
effects = {}
if special:
words = reversed(special.split())
for word in words:
if word == b"SlantFont":
effects["slant"] = float(next(words))
elif word == b"ExtendFont":
effects["extend"] = float(next(words))
# Verify some properties of the line that would cause it to be ignored
# otherwise.
if fontfile is not None:
if fontfile.endswith((b".ttf", b".ttc")):
is_truetype = True
elif not fontfile.endswith(b".otf"):
is_t1 = True
elif basename is not None:
is_t1 = True
if is_truetype and is_subsetted and encodingfile is None:
return
if not is_t1 and ("slant" in effects or "extend" in effects):
return
if abs(effects.get("slant", 0)) > 1:
return
if abs(effects.get("extend", 0)) > 2:
return
if basename is None:
basename = tfmname
if encodingfile is not None:
encodingfile = find_tex_file(encodingfile)
if fontfile is not None:
fontfile = find_tex_file(fontfile)
self._parsed[tfmname] = PsFont(
texname=tfmname, psname=basename, effects=effects,
encoding=encodingfile, filename=fontfile)
return True
def _parse_enc(path):
r"""
Parse a \*.enc file referenced from a psfonts.map style file.
The format supported by this function is a tiny subset of PostScript.
Parameters
----------
path : `os.PathLike`
Returns
-------
list
The nth entry of the list is the PostScript glyph name of the nth
glyph.
"""
no_comments = re.sub("%.*", "", Path(path).read_text(encoding="ascii"))
array = re.search(r"(?s)\[(.*)\]", no_comments).group(1)
lines = [line for line in array.split() if line]
if all(line.startswith("/") for line in lines):
return [line[1:] for line in lines]
else:
raise ValueError(f"Failed to parse {path} as Postscript encoding")
class _LuatexKpsewhich:
@lru_cache # A singleton.
def __new__(cls):
self = object.__new__(cls)
self._proc = self._new_proc()
return self
def _new_proc(self):
return subprocess.Popen(
["luatex", "--luaonly",