manymanymany-varia-websites/venv/lib/python3.11/site-packages/PIL/PdfParser.py
2024-11-19 14:01:39 +01:00

995 lines
34 KiB
Python

import calendar
import codecs
import collections
import mmap
import os
import re
import time
import zlib
# see 7.9.2.2 Text String Type on page 86 and D.3 PDFDocEncoding Character Set
# on page 656
def encode_text(s):
return codecs.BOM_UTF16_BE + s.encode("utf_16_be")
PDFDocEncoding = {
0x16: "\u0017",
0x18: "\u02D8",
0x19: "\u02C7",
0x1A: "\u02C6",
0x1B: "\u02D9",
0x1C: "\u02DD",
0x1D: "\u02DB",
0x1E: "\u02DA",
0x1F: "\u02DC",
0x80: "\u2022",
0x81: "\u2020",
0x82: "\u2021",
0x83: "\u2026",
0x84: "\u2014",
0x85: "\u2013",
0x86: "\u0192",
0x87: "\u2044",
0x88: "\u2039",
0x89: "\u203A",
0x8A: "\u2212",
0x8B: "\u2030",
0x8C: "\u201E",
0x8D: "\u201C",
0x8E: "\u201D",
0x8F: "\u2018",
0x90: "\u2019",
0x91: "\u201A",
0x92: "\u2122",
0x93: "\uFB01",
0x94: "\uFB02",
0x95: "\u0141",
0x96: "\u0152",
0x97: "\u0160",
0x98: "\u0178",
0x99: "\u017D",
0x9A: "\u0131",
0x9B: "\u0142",
0x9C: "\u0153",
0x9D: "\u0161",
0x9E: "\u017E",
0xA0: "\u20AC",
}
def decode_text(b):
if b[: len(codecs.BOM_UTF16_BE)] == codecs.BOM_UTF16_BE:
return b[len(codecs.BOM_UTF16_BE) :].decode("utf_16_be")
else:
return "".join(PDFDocEncoding.get(byte, chr(byte)) for byte in b)
class PdfFormatError(RuntimeError):
"""An error that probably indicates a syntactic or semantic error in the
PDF file structure"""
pass
def check_format_condition(condition, error_message):
if not condition:
raise PdfFormatError(error_message)
class IndirectReference(
collections.namedtuple("IndirectReferenceTuple", ["object_id", "generation"])
):
def __str__(self):
return "%s %s R" % self
def __bytes__(self):
return self.__str__().encode("us-ascii")
def __eq__(self, other):
return (
other.__class__ is self.__class__
and other.object_id == self.object_id
and other.generation == self.generation
)
def __ne__(self, other):
return not (self == other)
def __hash__(self):
return hash((self.object_id, self.generation))
class IndirectObjectDef(IndirectReference):
def __str__(self):
return "%s %s obj" % self
class XrefTable:
def __init__(self):
self.existing_entries = {} # object ID => (offset, generation)
self.new_entries = {} # object ID => (offset, generation)
self.deleted_entries = {0: 65536} # object ID => generation
self.reading_finished = False
def __setitem__(self, key, value):
if self.reading_finished:
self.new_entries[key] = value
else:
self.existing_entries[key] = value
if key in self.deleted_entries:
del self.deleted_entries[key]
def __getitem__(self, key):
try:
return self.new_entries[key]
except KeyError:
return self.existing_entries[key]
def __delitem__(self, key):
if key in self.new_entries:
generation = self.new_entries[key][1] + 1
del self.new_entries[key]
self.deleted_entries[key] = generation
elif key in self.existing_entries:
generation = self.existing_entries[key][1] + 1
self.deleted_entries[key] = generation
elif key in self.deleted_entries:
generation = self.deleted_entries[key]
else:
raise IndexError(
"object ID " + str(key) + " cannot be deleted because it doesn't exist"
)
def __contains__(self, key):
return key in self.existing_entries or key in self.new_entries
def __len__(self):
return len(
set(self.existing_entries.keys())
| set(self.new_entries.keys())
| set(self.deleted_entries.keys())
)
def keys(self):
return (
set(self.existing_entries.keys()) - set(self.deleted_entries.keys())
) | set(self.new_entries.keys())
def write(self, f):
keys = sorted(set(self.new_entries.keys()) | set(self.deleted_entries.keys()))
deleted_keys = sorted(set(self.deleted_entries.keys()))
startxref = f.tell()
f.write(b"xref\n")
while keys:
# find a contiguous sequence of object IDs
prev = None
for index, key in enumerate(keys):
if prev is None or prev + 1 == key:
prev = key
else:
contiguous_keys = keys[:index]
keys = keys[index:]
break
else:
contiguous_keys = keys
keys = None
f.write(b"%d %d\n" % (contiguous_keys[0], len(contiguous_keys)))
for object_id in contiguous_keys:
if object_id in self.new_entries:
f.write(b"%010d %05d n \n" % self.new_entries[object_id])
else:
this_deleted_object_id = deleted_keys.pop(0)
check_format_condition(
object_id == this_deleted_object_id,
f"expected the next deleted object ID to be {object_id}, "
f"instead found {this_deleted_object_id}",
)
try:
next_in_linked_list = deleted_keys[0]
except IndexError:
next_in_linked_list = 0
f.write(
b"%010d %05d f \n"
% (next_in_linked_list, self.deleted_entries[object_id])
)
return startxref
class PdfName:
def __init__(self, name):
if isinstance(name, PdfName):
self.name = name.name
elif isinstance(name, bytes):
self.name = name
else:
self.name = name.encode("us-ascii")
def name_as_str(self):
return self.name.decode("us-ascii")
def __eq__(self, other):
return (
isinstance(other, PdfName) and other.name == self.name
) or other == self.name
def __hash__(self):
return hash(self.name)
def __repr__(self):
return f"PdfName({repr(self.name)})"
@classmethod
def from_pdf_stream(cls, data):
return cls(PdfParser.interpret_name(data))
allowed_chars = set(range(33, 127)) - {ord(c) for c in "#%/()<>[]{}"}
def __bytes__(self):
result = bytearray(b"/")
for b in self.name:
if b in self.allowed_chars:
result.append(b)
else:
result.extend(b"#%02X" % b)
return bytes(result)
class PdfArray(list):
def __bytes__(self):
return b"[ " + b" ".join(pdf_repr(x) for x in self) + b" ]"
class PdfDict(collections.UserDict):
def __setattr__(self, key, value):
if key == "data":
collections.UserDict.__setattr__(self, key, value)
else:
self[key.encode("us-ascii")] = value
def __getattr__(self, key):
try:
value = self[key.encode("us-ascii")]
except KeyError as e:
raise AttributeError(key) from e
if isinstance(value, bytes):
value = decode_text(value)
if key.endswith("Date"):
if value.startswith("D:"):
value = value[2:]
relationship = "Z"
if len(value) > 17:
relationship = value[14]
offset = int(value[15:17]) * 60
if len(value) > 20:
offset += int(value[18:20])
format = "%Y%m%d%H%M%S"[: len(value) - 2]
value = time.strptime(value[: len(format) + 2], format)
if relationship in ["+", "-"]:
offset *= 60
if relationship == "+":
offset *= -1
value = time.gmtime(calendar.timegm(value) + offset)
return value
def __bytes__(self):
out = bytearray(b"<<")
for key, value in self.items():
if value is None:
continue
value = pdf_repr(value)
out.extend(b"\n")
out.extend(bytes(PdfName(key)))
out.extend(b" ")
out.extend(value)
out.extend(b"\n>>")
return bytes(out)
class PdfBinary:
def __init__(self, data):
self.data = data
def __bytes__(self):
return b"<%s>" % b"".join(b"%02X" % b for b in self.data)
class PdfStream:
def __init__(self, dictionary, buf):
self.dictionary = dictionary
self.buf = buf
def decode(self):
try:
filter = self.dictionary.Filter
except AttributeError:
return self.buf
if filter == b"FlateDecode":
try:
expected_length = self.dictionary.DL
except AttributeError:
expected_length = self.dictionary.Length
return zlib.decompress(self.buf, bufsize=int(expected_length))
else:
raise NotImplementedError(
f"stream filter {repr(self.dictionary.Filter)} unknown/unsupported"
)
def pdf_repr(x):
if x is True:
return b"true"
elif x is False:
return b"false"
elif x is None:
return b"null"
elif isinstance(x, (PdfName, PdfDict, PdfArray, PdfBinary)):
return bytes(x)
elif isinstance(x, int):
return str(x).encode("us-ascii")
elif isinstance(x, time.struct_time):
return b"(D:" + time.strftime("%Y%m%d%H%M%SZ", x).encode("us-ascii") + b")"
elif isinstance(x, dict):
return bytes(PdfDict(x))
elif isinstance(x, list):
return bytes(PdfArray(x))
elif isinstance(x, str):
return pdf_repr(encode_text(x))
elif isinstance(x, bytes):
# XXX escape more chars? handle binary garbage
x = x.replace(b"\\", b"\\\\")
x = x.replace(b"(", b"\\(")
x = x.replace(b")", b"\\)")
return b"(" + x + b")"
else:
return bytes(x)
class PdfParser:
"""Based on
https://www.adobe.com/content/dam/acom/en/devnet/acrobat/pdfs/PDF32000_2008.pdf
Supports PDF up to 1.4
"""
def __init__(self, filename=None, f=None, buf=None, start_offset=0, mode="rb"):
if buf and f:
raise RuntimeError("specify buf or f or filename, but not both buf and f")
self.filename = filename
self.buf = buf
self.f = f
self.start_offset = start_offset
self.should_close_buf = False
self.should_close_file = False
if filename is not None and f is None:
self.f = f = open(filename, mode)
self.should_close_file = True
if f is not None:
self.buf = buf = self.get_buf_from_file(f)
self.should_close_buf = True
if not filename and hasattr(f, "name"):
self.filename = f.name
self.cached_objects = {}
if buf:
self.read_pdf_info()
else:
self.file_size_total = self.file_size_this = 0
self.root = PdfDict()
self.root_ref = None
self.info = PdfDict()
self.info_ref = None
self.page_tree_root = {}
self.pages = []
self.orig_pages = []
self.pages_ref = None
self.last_xref_section_offset = None
self.trailer_dict = {}
self.xref_table = XrefTable()
self.xref_table.reading_finished = True
if f:
self.seek_end()
def __enter__(self):
return self
def __exit__(self, exc_type, exc_value, traceback):
self.close()
return False # do not suppress exceptions
def start_writing(self):
self.close_buf()
self.seek_end()
def close_buf(self):
try:
self.buf.close()
except AttributeError:
pass
self.buf = None
def close(self):
if self.should_close_buf:
self.close_buf()
if self.f is not None and self.should_close_file:
self.f.close()
self.f = None
def seek_end(self):
self.f.seek(0, os.SEEK_END)
def write_header(self):
self.f.write(b"%PDF-1.4\n")
def write_comment(self, s):
self.f.write(f"% {s}\n".encode("utf-8"))
def write_catalog(self):
self.del_root()
self.root_ref = self.next_object_id(self.f.tell())
self.pages_ref = self.next_object_id(0)
self.rewrite_pages()
self.write_obj(self.root_ref, Type=PdfName(b"Catalog"), Pages=self.pages_ref)
self.write_obj(
self.pages_ref,
Type=PdfName(b"Pages"),
Count=len(self.pages),
Kids=self.pages,
)
return self.root_ref
def rewrite_pages(self):
pages_tree_nodes_to_delete = []
for i, page_ref in enumerate(self.orig_pages):
page_info = self.cached_objects[page_ref]
del self.xref_table[page_ref.object_id]
pages_tree_nodes_to_delete.append(page_info[PdfName(b"Parent")])
if page_ref not in self.pages:
# the page has been deleted
continue
# make dict keys into strings for passing to write_page
stringified_page_info = {}
for key, value in page_info.items():
# key should be a PdfName
stringified_page_info[key.name_as_str()] = value
stringified_page_info["Parent"] = self.pages_ref
new_page_ref = self.write_page(None, **stringified_page_info)
for j, cur_page_ref in enumerate(self.pages):
if cur_page_ref == page_ref:
# replace the page reference with the new one
self.pages[j] = new_page_ref
# delete redundant Pages tree nodes from xref table
for pages_tree_node_ref in pages_tree_nodes_to_delete:
while pages_tree_node_ref:
pages_tree_node = self.cached_objects[pages_tree_node_ref]
if pages_tree_node_ref.object_id in self.xref_table:
del self.xref_table[pages_tree_node_ref.object_id]
pages_tree_node_ref = pages_tree_node.get(b"Parent", None)
self.orig_pages = []
def write_xref_and_trailer(self, new_root_ref=None):
if new_root_ref:
self.del_root()
self.root_ref = new_root_ref
if self.info:
self.info_ref = self.write_obj(None, self.info)
start_xref = self.xref_table.write(self.f)
num_entries = len(self.xref_table)
trailer_dict = {b"Root": self.root_ref, b"Size": num_entries}
if self.last_xref_section_offset is not None:
trailer_dict[b"Prev"] = self.last_xref_section_offset
if self.info:
trailer_dict[b"Info"] = self.info_ref
self.last_xref_section_offset = start_xref
self.f.write(
b"trailer\n"
+ bytes(PdfDict(trailer_dict))
+ b"\nstartxref\n%d\n%%%%EOF" % start_xref
)
def write_page(self, ref, *objs, **dict_obj):
if isinstance(ref, int):
ref = self.pages[ref]
if "Type" not in dict_obj:
dict_obj["Type"] = PdfName(b"Page")
if "Parent" not in dict_obj:
dict_obj["Parent"] = self.pages_ref
return self.write_obj(ref, *objs, **dict_obj)
def write_obj(self, ref, *objs, **dict_obj):
f = self.f
if ref is None:
ref = self.next_object_id(f.tell())
else:
self.xref_table[ref.object_id] = (f.tell(), ref.generation)
f.write(bytes(IndirectObjectDef(*ref)))
stream = dict_obj.pop("stream", None)
if stream is not None:
dict_obj["Length"] = len(stream)
if dict_obj:
f.write(pdf_repr(dict_obj))
for obj in objs:
f.write(pdf_repr(obj))
if stream is not None:
f.write(b"stream\n")
f.write(stream)
f.write(b"\nendstream\n")
f.write(b"endobj\n")
return ref
def del_root(self):
if self.root_ref is None:
return
del self.xref_table[self.root_ref.object_id]
del self.xref_table[self.root[b"Pages"].object_id]
@staticmethod
def get_buf_from_file(f):
if hasattr(f, "getbuffer"):
return f.getbuffer()
elif hasattr(f, "getvalue"):
return f.getvalue()
else:
try:
return mmap.mmap(f.fileno(), 0, access=mmap.ACCESS_READ)
except ValueError: # cannot mmap an empty file
return b""
def read_pdf_info(self):
self.file_size_total = len(self.buf)
self.file_size_this = self.file_size_total - self.start_offset
self.read_trailer()
self.root_ref = self.trailer_dict[b"Root"]
self.info_ref = self.trailer_dict.get(b"Info", None)
self.root = PdfDict(self.read_indirect(self.root_ref))
if self.info_ref is None:
self.info = PdfDict()
else:
self.info = PdfDict(self.read_indirect(self.info_ref))
check_format_condition(b"Type" in self.root, "/Type missing in Root")
check_format_condition(
self.root[b"Type"] == b"Catalog", "/Type in Root is not /Catalog"
)
check_format_condition(b"Pages" in self.root, "/Pages missing in Root")
check_format_condition(
isinstance(self.root[b"Pages"], IndirectReference),
"/Pages in Root is not an indirect reference",
)
self.pages_ref = self.root[b"Pages"]
self.page_tree_root = self.read_indirect(self.pages_ref)
self.pages = self.linearize_page_tree(self.page_tree_root)
# save the original list of page references
# in case the user modifies, adds or deletes some pages
# and we need to rewrite the pages and their list
self.orig_pages = self.pages[:]
def next_object_id(self, offset=None):
try:
# TODO: support reuse of deleted objects
reference = IndirectReference(max(self.xref_table.keys()) + 1, 0)
except ValueError:
reference = IndirectReference(1, 0)
if offset is not None:
self.xref_table[reference.object_id] = (offset, 0)
return reference
delimiter = br"[][()<>{}/%]"
delimiter_or_ws = br"[][()<>{}/%\000\011\012\014\015\040]"
whitespace = br"[\000\011\012\014\015\040]"
whitespace_or_hex = br"[\000\011\012\014\015\0400-9a-fA-F]"
whitespace_optional = whitespace + b"*"
whitespace_mandatory = whitespace + b"+"
newline_only = br"[\r\n]+"
newline = whitespace_optional + newline_only + whitespace_optional
re_trailer_end = re.compile(
whitespace_mandatory
+ br"trailer"
+ whitespace_optional
+ br"\<\<(.*\>\>)"
+ newline
+ br"startxref"
+ newline
+ br"([0-9]+)"
+ newline
+ br"%%EOF"
+ whitespace_optional
+ br"$",
re.DOTALL,
)
re_trailer_prev = re.compile(
whitespace_optional
+ br"trailer"
+ whitespace_optional
+ br"\<\<(.*?\>\>)"
+ newline
+ br"startxref"
+ newline
+ br"([0-9]+)"
+ newline
+ br"%%EOF"
+ whitespace_optional,
re.DOTALL,
)
def read_trailer(self):
search_start_offset = len(self.buf) - 16384
if search_start_offset < self.start_offset:
search_start_offset = self.start_offset
m = self.re_trailer_end.search(self.buf, search_start_offset)
check_format_condition(m, "trailer end not found")
# make sure we found the LAST trailer
last_match = m
while m:
last_match = m
m = self.re_trailer_end.search(self.buf, m.start() + 16)
if not m:
m = last_match
trailer_data = m.group(1)
self.last_xref_section_offset = int(m.group(2))
self.trailer_dict = self.interpret_trailer(trailer_data)
self.xref_table = XrefTable()
self.read_xref_table(xref_section_offset=self.last_xref_section_offset)
if b"Prev" in self.trailer_dict:
self.read_prev_trailer(self.trailer_dict[b"Prev"])
def read_prev_trailer(self, xref_section_offset):
trailer_offset = self.read_xref_table(xref_section_offset=xref_section_offset)
m = self.re_trailer_prev.search(
self.buf[trailer_offset : trailer_offset + 16384]
)
check_format_condition(m, "previous trailer not found")
trailer_data = m.group(1)
check_format_condition(
int(m.group(2)) == xref_section_offset,
"xref section offset in previous trailer doesn't match what was expected",
)
trailer_dict = self.interpret_trailer(trailer_data)
if b"Prev" in trailer_dict:
self.read_prev_trailer(trailer_dict[b"Prev"])
re_whitespace_optional = re.compile(whitespace_optional)
re_name = re.compile(
whitespace_optional
+ br"/([!-$&'*-.0-;=?-Z\\^-z|~]+)(?="
+ delimiter_or_ws
+ br")"
)
re_dict_start = re.compile(whitespace_optional + br"\<\<")
re_dict_end = re.compile(whitespace_optional + br"\>\>" + whitespace_optional)
@classmethod
def interpret_trailer(cls, trailer_data):
trailer = {}
offset = 0
while True:
m = cls.re_name.match(trailer_data, offset)
if not m:
m = cls.re_dict_end.match(trailer_data, offset)
check_format_condition(
m and m.end() == len(trailer_data),
"name not found in trailer, remaining data: "
+ repr(trailer_data[offset:]),
)
break
key = cls.interpret_name(m.group(1))
value, offset = cls.get_value(trailer_data, m.end())
trailer[key] = value
check_format_condition(
b"Size" in trailer and isinstance(trailer[b"Size"], int),
"/Size not in trailer or not an integer",
)
check_format_condition(
b"Root" in trailer and isinstance(trailer[b"Root"], IndirectReference),
"/Root not in trailer or not an indirect reference",
)
return trailer
re_hashes_in_name = re.compile(br"([^#]*)(#([0-9a-fA-F]{2}))?")
@classmethod
def interpret_name(cls, raw, as_text=False):
name = b""
for m in cls.re_hashes_in_name.finditer(raw):
if m.group(3):
name += m.group(1) + bytearray.fromhex(m.group(3).decode("us-ascii"))
else:
name += m.group(1)
if as_text:
return name.decode("utf-8")
else:
return bytes(name)
re_null = re.compile(whitespace_optional + br"null(?=" + delimiter_or_ws + br")")
re_true = re.compile(whitespace_optional + br"true(?=" + delimiter_or_ws + br")")
re_false = re.compile(whitespace_optional + br"false(?=" + delimiter_or_ws + br")")
re_int = re.compile(
whitespace_optional + br"([-+]?[0-9]+)(?=" + delimiter_or_ws + br")"
)
re_real = re.compile(
whitespace_optional
+ br"([-+]?([0-9]+\.[0-9]*|[0-9]*\.[0-9]+))(?="
+ delimiter_or_ws
+ br")"
)
re_array_start = re.compile(whitespace_optional + br"\[")
re_array_end = re.compile(whitespace_optional + br"]")
re_string_hex = re.compile(
whitespace_optional + br"\<(" + whitespace_or_hex + br"*)\>"
)
re_string_lit = re.compile(whitespace_optional + br"\(")
re_indirect_reference = re.compile(
whitespace_optional
+ br"([-+]?[0-9]+)"
+ whitespace_mandatory
+ br"([-+]?[0-9]+)"
+ whitespace_mandatory
+ br"R(?="
+ delimiter_or_ws
+ br")"
)
re_indirect_def_start = re.compile(
whitespace_optional
+ br"([-+]?[0-9]+)"
+ whitespace_mandatory
+ br"([-+]?[0-9]+)"
+ whitespace_mandatory
+ br"obj(?="
+ delimiter_or_ws
+ br")"
)
re_indirect_def_end = re.compile(
whitespace_optional + br"endobj(?=" + delimiter_or_ws + br")"
)
re_comment = re.compile(
br"(" + whitespace_optional + br"%[^\r\n]*" + newline + br")*"
)
re_stream_start = re.compile(whitespace_optional + br"stream\r?\n")
re_stream_end = re.compile(
whitespace_optional + br"endstream(?=" + delimiter_or_ws + br")"
)
@classmethod
def get_value(cls, data, offset, expect_indirect=None, max_nesting=-1):
if max_nesting == 0:
return None, None
m = cls.re_comment.match(data, offset)
if m:
offset = m.end()
m = cls.re_indirect_def_start.match(data, offset)
if m:
check_format_condition(
int(m.group(1)) > 0,
"indirect object definition: object ID must be greater than 0",
)
check_format_condition(
int(m.group(2)) >= 0,
"indirect object definition: generation must be non-negative",
)
check_format_condition(
expect_indirect is None
or expect_indirect
== IndirectReference(int(m.group(1)), int(m.group(2))),
"indirect object definition different than expected",
)
object, offset = cls.get_value(data, m.end(), max_nesting=max_nesting - 1)
if offset is None:
return object, None
m = cls.re_indirect_def_end.match(data, offset)
check_format_condition(m, "indirect object definition end not found")
return object, m.end()
check_format_condition(
not expect_indirect, "indirect object definition not found"
)
m = cls.re_indirect_reference.match(data, offset)
if m:
check_format_condition(
int(m.group(1)) > 0,
"indirect object reference: object ID must be greater than 0",
)
check_format_condition(
int(m.group(2)) >= 0,
"indirect object reference: generation must be non-negative",
)
return IndirectReference(int(m.group(1)), int(m.group(2))), m.end()
m = cls.re_dict_start.match(data, offset)
if m:
offset = m.end()
result = {}
m = cls.re_dict_end.match(data, offset)
while not m:
key, offset = cls.get_value(data, offset, max_nesting=max_nesting - 1)
if offset is None:
return result, None
value, offset = cls.get_value(data, offset, max_nesting=max_nesting - 1)
result[key] = value
if offset is None:
return result, None
m = cls.re_dict_end.match(data, offset)
offset = m.end()
m = cls.re_stream_start.match(data, offset)
if m:
try:
stream_len = int(result[b"Length"])
except (TypeError, KeyError, ValueError) as e:
raise PdfFormatError(
"bad or missing Length in stream dict (%r)"
% result.get(b"Length", None)
) from e
stream_data = data[m.end() : m.end() + stream_len]
m = cls.re_stream_end.match(data, m.end() + stream_len)
check_format_condition(m, "stream end not found")
offset = m.end()
result = PdfStream(PdfDict(result), stream_data)
else:
result = PdfDict(result)
return result, offset
m = cls.re_array_start.match(data, offset)
if m:
offset = m.end()
result = []
m = cls.re_array_end.match(data, offset)
while not m:
value, offset = cls.get_value(data, offset, max_nesting=max_nesting - 1)
result.append(value)
if offset is None:
return result, None
m = cls.re_array_end.match(data, offset)
return result, m.end()
m = cls.re_null.match(data, offset)
if m:
return None, m.end()
m = cls.re_true.match(data, offset)
if m:
return True, m.end()
m = cls.re_false.match(data, offset)
if m:
return False, m.end()
m = cls.re_name.match(data, offset)
if m:
return PdfName(cls.interpret_name(m.group(1))), m.end()
m = cls.re_int.match(data, offset)
if m:
return int(m.group(1)), m.end()
m = cls.re_real.match(data, offset)
if m:
# XXX Decimal instead of float???
return float(m.group(1)), m.end()
m = cls.re_string_hex.match(data, offset)
if m:
# filter out whitespace
hex_string = bytearray(
[b for b in m.group(1) if b in b"0123456789abcdefABCDEF"]
)
if len(hex_string) % 2 == 1:
# append a 0 if the length is not even - yes, at the end
hex_string.append(ord(b"0"))
return bytearray.fromhex(hex_string.decode("us-ascii")), m.end()
m = cls.re_string_lit.match(data, offset)
if m:
return cls.get_literal_string(data, m.end())
# return None, offset # fallback (only for debugging)
raise PdfFormatError("unrecognized object: " + repr(data[offset : offset + 32]))
re_lit_str_token = re.compile(
br"(\\[nrtbf()\\])|(\\[0-9]{1,3})|(\\(\r\n|\r|\n))|(\r\n|\r|\n)|(\()|(\))"
)
escaped_chars = {
b"n": b"\n",
b"r": b"\r",
b"t": b"\t",
b"b": b"\b",
b"f": b"\f",
b"(": b"(",
b")": b")",
b"\\": b"\\",
ord(b"n"): b"\n",
ord(b"r"): b"\r",
ord(b"t"): b"\t",
ord(b"b"): b"\b",
ord(b"f"): b"\f",
ord(b"("): b"(",
ord(b")"): b")",
ord(b"\\"): b"\\",
}
@classmethod
def get_literal_string(cls, data, offset):
nesting_depth = 0
result = bytearray()
for m in cls.re_lit_str_token.finditer(data, offset):
result.extend(data[offset : m.start()])
if m.group(1):
result.extend(cls.escaped_chars[m.group(1)[1]])
elif m.group(2):
result.append(int(m.group(2)[1:], 8))
elif m.group(3):
pass
elif m.group(5):
result.extend(b"\n")
elif m.group(6):
result.extend(b"(")
nesting_depth += 1
elif m.group(7):
if nesting_depth == 0:
return bytes(result), m.end()
result.extend(b")")
nesting_depth -= 1
offset = m.end()
raise PdfFormatError("unfinished literal string")
re_xref_section_start = re.compile(whitespace_optional + br"xref" + newline)
re_xref_subsection_start = re.compile(
whitespace_optional
+ br"([0-9]+)"
+ whitespace_mandatory
+ br"([0-9]+)"
+ whitespace_optional
+ newline_only
)
re_xref_entry = re.compile(br"([0-9]{10}) ([0-9]{5}) ([fn])( \r| \n|\r\n)")
def read_xref_table(self, xref_section_offset):
subsection_found = False
m = self.re_xref_section_start.match(
self.buf, xref_section_offset + self.start_offset
)
check_format_condition(m, "xref section start not found")
offset = m.end()
while True:
m = self.re_xref_subsection_start.match(self.buf, offset)
if not m:
check_format_condition(
subsection_found, "xref subsection start not found"
)
break
subsection_found = True
offset = m.end()
first_object = int(m.group(1))
num_objects = int(m.group(2))
for i in range(first_object, first_object + num_objects):
m = self.re_xref_entry.match(self.buf, offset)
check_format_condition(m, "xref entry not found")
offset = m.end()
is_free = m.group(3) == b"f"
generation = int(m.group(2))
if not is_free:
new_entry = (int(m.group(1)), generation)
check_format_condition(
i not in self.xref_table or self.xref_table[i] == new_entry,
"xref entry duplicated (and not identical)",
)
self.xref_table[i] = new_entry
return offset
def read_indirect(self, ref, max_nesting=-1):
offset, generation = self.xref_table[ref[0]]
check_format_condition(
generation == ref[1],
f"expected to find generation {ref[1]} for object ID {ref[0]} in xref "
f"table, instead found generation {generation} at offset {offset}",
)
value = self.get_value(
self.buf,
offset + self.start_offset,
expect_indirect=IndirectReference(*ref),
max_nesting=max_nesting,
)[0]
self.cached_objects[ref] = value
return value
def linearize_page_tree(self, node=None):
if node is None:
node = self.page_tree_root
check_format_condition(
node[b"Type"] == b"Pages", "/Type of page tree node is not /Pages"
)
pages = []
for kid in node[b"Kids"]:
kid_object = self.read_indirect(kid)
if kid_object[b"Type"] == b"Page":
pages.append(kid)
else:
pages.extend(self.linearize_page_tree(node=kid_object))
return pages