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SickRage/lib/regex/regex.py

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#
# Secret Labs' Regular Expression Engine
#
# Copyright (c) 1998-2001 by Secret Labs AB. All rights reserved.
#
# This version of the SRE library can be redistributed under CNRI's
# Python 1.6 license. For any other use, please contact Secret Labs
# AB (info@pythonware.com).
#
# Portions of this engine have been developed in cooperation with
# CNRI. Hewlett-Packard provided funding for 1.6 integration and
# other compatibility work.
#
# 2010-01-16 mrab Python front-end re-written and extended
r"""Support for regular expressions (RE).
This module provides regular expression matching operations similar to those
found in Perl. It supports both 8-bit and Unicode strings; both the pattern and
the strings being processed can contain null bytes and characters outside the
US ASCII range.
Regular expressions can contain both special and ordinary characters. Most
ordinary characters, like "A", "a", or "0", are the simplest regular
expressions; they simply match themselves. You can concatenate ordinary
characters, so last matches the string 'last'.
There are a few differences between the old (legacy) behaviour and the new
(enhanced) behaviour, which are indicated by VERSION0 or VERSION1.
The special characters are:
"." Matches any character except a newline.
"^" Matches the start of the string.
"$" Matches the end of the string or just before the
newline at the end of the string.
"*" Matches 0 or more (greedy) repetitions of the preceding
RE. Greedy means that it will match as many repetitions
as possible.
"+" Matches 1 or more (greedy) repetitions of the preceding
RE.
"?" Matches 0 or 1 (greedy) of the preceding RE.
*?,+?,?? Non-greedy versions of the previous three special
characters.
*+,++,?+ Possessive versions of the previous three special
characters.
{m,n} Matches from m to n repetitions of the preceding RE.
{m,n}? Non-greedy version of the above.
{m,n}+ Possessive version of the above.
{...} Fuzzy matching constraints.
"\\" Either escapes special characters or signals a special
sequence.
[...] Indicates a set of characters. A "^" as the first
character indicates a complementing set.
"|" A|B, creates an RE that will match either A or B.
(...) Matches the RE inside the parentheses. The contents are
captured and can be retrieved or matched later in the
string.
(?flags-flags) VERSION1: Sets/clears the flags for the remainder of
the group or pattern; VERSION0: Sets the flags for the
entire pattern.
(?:...) Non-capturing version of regular parentheses.
(?>...) Atomic non-capturing version of regular parentheses.
(?flags-flags:...) Non-capturing version of regular parentheses with local
flags.
(?P<name>...) The substring matched by the group is accessible by
name.
(?<name>...) The substring matched by the group is accessible by
name.
(?P=name) Matches the text matched earlier by the group named
name.
(?#...) A comment; ignored.
(?=...) Matches if ... matches next, but doesn't consume the
string.
(?!...) Matches if ... doesn't match next.
(?<=...) Matches if preceded by ....
(?<!...) Matches if not preceded by ....
(?(id)yes|no) Matches yes pattern if group id matched, the (optional)
no pattern otherwise.
(?|...|...) (?|A|B), creates an RE that will match either A or B,
but reuses capture group numbers across the
alternatives.
The fuzzy matching constraints are: "i" to permit insertions, "d" to permit
deletions, "s" to permit substitutions, "e" to permit any of these. Limits are
optional with "<=" and "<". If any type of error is provided then any type not
provided is not permitted.
A cost equation may be provided.
Examples:
(?:fuzzy){i<=2}
(?:fuzzy){i<=1,s<=2,d<=1,1i+1s+1d<3}
VERSION1: Set operators are supported, and a set can include nested sets. The
set operators, in order of increasing precedence, are:
|| Set union ("x||y" means "x or y").
~~ (double tilde) Symmetric set difference ("x~~y" means "x or y, but not
both").
&& Set intersection ("x&&y" means "x and y").
-- (double dash) Set difference ("x--y" means "x but not y").
Implicit union, ie, simple juxtaposition like in [ab], has the highest
precedence.
VERSION0 and VERSION1:
The special sequences consist of "\\" and a character from the list below. If
the ordinary character is not on the list, then the resulting RE will match the
second character.
\number Matches the contents of the group of the same number if
number is no more than 2 digits, otherwise the character
with the 3-digit octal code.
\a Matches the bell character.
\A Matches only at the start of the string.
\b Matches the empty string, but only at the start or end of a
word.
\B Matches the empty string, but not at the start or end of a
word.
\d Matches any decimal digit; equivalent to the set [0-9] when
matching a bytestring or a Unicode string with the ASCII
flag, or the whole range of Unicode digits when matching a
Unicode string.
\D Matches any non-digit character; equivalent to [^\d].
\f Matches the formfeed character.
\g<name> Matches the text matched by the group named name.
\G Matches the empty string, but only at the position where
the search started.
\L<name> Named list. The list is provided as a keyword argument.
\m Matches the empty string, but only at the start of a word.
\M Matches the empty string, but only at the end of a word.
\n Matches the newline character.
\N{name} Matches the named character.
\p{name=value} Matches the character if its property has the specified
value.
\P{name=value} Matches the character if its property hasn't the specified
value.
\r Matches the carriage-return character.
\s Matches any whitespace character; equivalent to
[ \t\n\r\f\v].
\S Matches any non-whitespace character; equivalent to [^\s].
\t Matches the tab character.
\uXXXX Matches the Unicode codepoint with 4-digit hex code XXXX.
\UXXXXXXXX Matches the Unicode codepoint with 8-digit hex code
XXXXXXXX.
\v Matches the vertical tab character.
\w Matches any alphanumeric character; equivalent to
[a-zA-Z0-9_] when matching a bytestring or a Unicode string
with the ASCII flag, or the whole range of Unicode
alphanumeric characters (letters plus digits plus
underscore) when matching a Unicode string. With LOCALE, it
will match the set [0-9_] plus characters defined as
letters for the current locale.
\W Matches the complement of \w; equivalent to [^\w].
\xXX Matches the character with 2-digit hex code XX.
\X Matches a grapheme.
\Z Matches only at the end of the string.
\\ Matches a literal backslash.
This module exports the following functions:
match Match a regular expression pattern at the beginning of a string.
fullmatch Match a regular expression pattern against all of a string.
search Search a string for the presence of a pattern.
sub Substitute occurrences of a pattern found in a string using a
template string.
subf Substitute occurrences of a pattern found in a string using a
format string.
subn Same as sub, but also return the number of substitutions made.
subfn Same as subf, but also return the number of substitutions made.
split Split a string by the occurrences of a pattern. VERSION1: will
split at zero-width match; VERSION0: won't split at zero-width
match.
splititer Return an iterator yielding the parts of a split string.
findall Find all occurrences of a pattern in a string.
finditer Return an iterator yielding a match object for each match.
compile Compile a pattern into a Pattern object.
purge Clear the regular expression cache.
escape Backslash all non-alphanumerics or special characters in a
string.
Most of the functions support a concurrent parameter: if True, the GIL will be
released during matching, allowing other Python threads to run concurrently. If
the string changes during matching, the behaviour is undefined. This parameter
is not needed when working on the builtin (immutable) string classes.
Some of the functions in this module take flags as optional parameters. Most of
these flags can also be set within an RE:
A a ASCII Make \w, \W, \b, \B, \d, and \D match the
corresponding ASCII character categories. Default
when matching a bytestring.
B b BESTMATCH Find the best fuzzy match (default is first).
D DEBUG Print the parsed pattern.
F f FULLCASE Use full case-folding when performing
case-insensitive matching in Unicode.
I i IGNORECASE Perform case-insensitive matching.
L L LOCALE Make \w, \W, \b, \B, \d, and \D dependent on the
current locale. (One byte per character only.)
M m MULTILINE "^" matches the beginning of lines (after a newline)
as well as the string. "$" matches the end of lines
(before a newline) as well as the end of the string.
E e ENHANCEMATCH Attempt to improve the fit after finding the first
fuzzy match.
R r REVERSE Searches backwards.
S s DOTALL "." matches any character at all, including the
newline.
U u UNICODE Make \w, \W, \b, \B, \d, and \D dependent on the
Unicode locale. Default when matching a Unicode
string.
V0 V0 VERSION0 Turn on the old legacy behaviour.
V1 V1 VERSION1 Turn on the new enhanced behaviour. This flag
includes the FULLCASE flag.
W w WORD Make \b and \B work with default Unicode word breaks
and make ".", "^" and "$" work with Unicode line
breaks.
X x VERBOSE Ignore whitespace and comments for nicer looking REs.
This module also defines an exception 'error'.
"""
# Public symbols.
__all__ = ["compile", "escape", "findall", "finditer", "fullmatch", "match",
"purge", "search", "split", "splititer", "sub", "subf", "subfn", "subn",
"template", "Scanner", "A", "ASCII", "B", "BESTMATCH", "D", "DEBUG", "E",
"ENHANCEMATCH", "S", "DOTALL", "F", "FULLCASE", "I", "IGNORECASE", "L",
"LOCALE", "M", "MULTILINE", "R", "REVERSE", "T", "TEMPLATE", "U", "UNICODE",
"V0", "VERSION0", "V1", "VERSION1", "X", "VERBOSE", "W", "WORD", "error",
"Regex"]
__version__ = "2.4.45"
# --------------------------------------------------------------------
# Public interface.
def match(pattern, string, flags=0, pos=None, endpos=None, partial=False,
concurrent=None, **kwargs):
"""Try to apply the pattern at the start of the string, returning a match
object, or None if no match was found."""
return _compile(pattern, flags, kwargs).match(string, pos, endpos,
concurrent, partial)
def fullmatch(pattern, string, flags=0, pos=None, endpos=None, partial=False,
concurrent=None, **kwargs):
"""Try to apply the pattern against all of the string, returning a match
object, or None if no match was found."""
return _compile(pattern, flags, kwargs).fullmatch(string, pos, endpos,
concurrent, partial)
def search(pattern, string, flags=0, pos=None, endpos=None, partial=False,
concurrent=None, **kwargs):
"""Search through string looking for a match to the pattern, returning a
match object, or None if no match was found."""
return _compile(pattern, flags, kwargs).search(string, pos, endpos,
concurrent, partial)
def sub(pattern, repl, string, count=0, flags=0, pos=None, endpos=None,
concurrent=None, **kwargs):
"""Return the string obtained by replacing the leftmost (or rightmost with a
reverse pattern) non-overlapping occurrences of the pattern in string by the
replacement repl. repl can be either a string or a callable; if a string,
backslash escapes in it are processed; if a callable, it's passed the match
object and must return a replacement string to be used."""
return _compile(pattern, flags, kwargs).sub(repl, string, count, pos,
endpos, concurrent)
def subf(pattern, format, string, count=0, flags=0, pos=None, endpos=None,
concurrent=None, **kwargs):
"""Return the string obtained by replacing the leftmost (or rightmost with a
reverse pattern) non-overlapping occurrences of the pattern in string by the
replacement format. format can be either a string or a callable; if a string,
it's treated as a format string; if a callable, it's passed the match object
and must return a replacement string to be used."""
return _compile(pattern, flags, kwargs).subf(format, string, count, pos,
endpos, concurrent)
def subn(pattern, repl, string, count=0, flags=0, pos=None, endpos=None,
concurrent=None, **kwargs):
"""Return a 2-tuple containing (new_string, number). new_string is the string
obtained by replacing the leftmost (or rightmost with a reverse pattern)
non-overlapping occurrences of the pattern in the source string by the
replacement repl. number is the number of substitutions that were made. repl
can be either a string or a callable; if a string, backslash escapes in it
are processed; if a callable, it's passed the match object and must return a
replacement string to be used."""
return _compile(pattern, flags, kwargs).subn(repl, string, count, pos,
endpos, concurrent)
def subfn(pattern, format, string, count=0, flags=0, pos=None, endpos=None,
concurrent=None, **kwargs):
"""Return a 2-tuple containing (new_string, number). new_string is the string
obtained by replacing the leftmost (or rightmost with a reverse pattern)
non-overlapping occurrences of the pattern in the source string by the
replacement format. number is the number of substitutions that were made. format
can be either a string or a callable; if a string, it's treated as a format
string; if a callable, it's passed the match object and must return a
replacement string to be used."""
return _compile(pattern, flags, kwargs).subfn(format, string, count, pos,
endpos, concurrent)
def split(pattern, string, maxsplit=0, flags=0, concurrent=None, **kwargs):
"""Split the source string by the occurrences of the pattern, returning a
list containing the resulting substrings. If capturing parentheses are used
in pattern, then the text of all groups in the pattern are also returned as
part of the resulting list. If maxsplit is nonzero, at most maxsplit splits
occur, and the remainder of the string is returned as the final element of
the list."""
return _compile(pattern, flags, kwargs).split(string, maxsplit, concurrent)
def splititer(pattern, string, maxsplit=0, flags=0, concurrent=None, **kwargs):
"Return an iterator yielding the parts of a split string."
return _compile(pattern, flags, kwargs).splititer(string, maxsplit,
concurrent)
def findall(pattern, string, flags=0, pos=None, endpos=None, overlapped=False,
concurrent=None, **kwargs):
"""Return a list of all matches in the string. The matches may be overlapped
if overlapped is True. If one or more groups are present in the pattern,
return a list of groups; this will be a list of tuples if the pattern has
more than one group. Empty matches are included in the result."""
return _compile(pattern, flags, kwargs).findall(string, pos, endpos,
overlapped, concurrent)
def finditer(pattern, string, flags=0, pos=None, endpos=None, overlapped=False,
partial=False, concurrent=None, **kwargs):
"""Return an iterator over all matches in the string. The matches may be
overlapped if overlapped is True. For each match, the iterator returns a
match object. Empty matches are included in the result."""
return _compile(pattern, flags, kwargs).finditer(string, pos, endpos,
overlapped, concurrent, partial)
def compile(pattern, flags=0, **kwargs):
"Compile a regular expression pattern, returning a pattern object."
return _compile(pattern, flags, kwargs)
def purge():
"Clear the regular expression cache"
_cache.clear()
def template(pattern, flags=0):
"Compile a template pattern, returning a pattern object."
return _compile(pattern, flags | TEMPLATE)
def escape(pattern, special_only=False):
"Escape all non-alphanumeric characters or special characters in pattern."
if isinstance(pattern, unicode):
s = []
if special_only:
for c in pattern:
if c in _METACHARS:
s.append(u"\\")
s.append(c)
elif c == u"\x00":
s.append(u"\\000")
else:
s.append(c)
else:
for c in pattern:
if c in _ALNUM:
s.append(c)
elif c == u"\x00":
s.append(u"\\000")
else:
s.append(u"\\")
s.append(c)
return u"".join(s)
else:
s = []
if special_only:
for c in pattern:
if c in _METACHARS:
s.append("\\")
s.append(c)
elif c == "\x00":
s.append("\\000")
else:
s.append(c)
else:
for c in pattern:
if c in _ALNUM:
s.append(c)
elif c == "\x00":
s.append("\\000")
else:
s.append("\\")
s.append(c)
return "".join(s)
# --------------------------------------------------------------------
# Internals.
import _regex_core
import sys
if sys.version_info < (2, 6):
from Python25 import _regex
elif sys.version_info < (2, 7):
from Python26 import _regex
else:
from Python27 import _regex
from threading import RLock as _RLock
from _regex_core import *
from _regex_core import (_ALL_VERSIONS, _ALL_ENCODINGS, _FirstSetError,
_UnscopedFlagSet, _check_group_features, _compile_firstset,
_compile_replacement, _flatten_code, _fold_case, _get_required_string,
_parse_pattern, _shrink_cache)
from _regex_core import (ALNUM as _ALNUM, Info as _Info, OP as _OP, Source as
_Source, Fuzzy as _Fuzzy)
# Version 0 is the old behaviour, compatible with the original 're' module.
# Version 1 is the new behaviour, which differs slightly.
DEFAULT_VERSION = VERSION0
_METACHARS = frozenset("()[]{}?*+|^$\\.")
_regex_core.DEFAULT_VERSION = DEFAULT_VERSION
# Caches for the patterns and replacements.
_cache = {}
_cache_lock = _RLock()
_named_args = {}
_replacement_cache = {}
# Maximum size of the cache.
_MAXCACHE = 500
_MAXREPCACHE = 500
def _compile(pattern, flags=0, kwargs={}):
"Compiles a regular expression to a PatternObject."
try:
# Do we know what keyword arguments are needed?
args_key = pattern, type(pattern), flags
args_needed = _named_args[args_key]
# Are we being provided with its required keyword arguments?
args_supplied = set()
if args_needed:
for k, v in args_needed:
try:
args_supplied.add((k, frozenset(kwargs[k])))
except KeyError:
raise error("missing named list")
args_supplied = frozenset(args_supplied)
# Have we already seen this regular expression and named list?
pattern_key = (pattern, type(pattern), flags, args_supplied,
DEFAULT_VERSION)
return _cache[pattern_key]
except KeyError:
# It's a new pattern, or new named list for a known pattern.
pass
# Guess the encoding from the class of the pattern string.
if isinstance(pattern, unicode):
guess_encoding = UNICODE
elif isinstance(pattern, str):
guess_encoding = ASCII
elif isinstance(pattern, _pattern_type):
if flags:
raise ValueError("can't process flags argument with a compiled pattern")
return pattern
else:
raise TypeError("first argument must be a string or compiled pattern")
# Set the default version in the core code in case it has been changed.
_regex_core.DEFAULT_VERSION = DEFAULT_VERSION
caught_exception = None
global_flags = flags
while True:
try:
source = _Source(pattern)
info = _Info(global_flags, source.char_type, kwargs)
info.guess_encoding = guess_encoding
source.ignore_space = bool(info.flags & VERBOSE)
parsed = _parse_pattern(source, info)
break
except _UnscopedFlagSet:
# Remember the global flags for the next attempt.
global_flags = info.global_flags
except error, e:
caught_exception = e
if caught_exception:
raise error(str(caught_exception))
if not source.at_end():
raise error("trailing characters in pattern at position %d" % source.pos)
# Check the global flags for conflicts.
version = (info.flags & _ALL_VERSIONS) or DEFAULT_VERSION
if version not in (0, VERSION0, VERSION1):
raise ValueError("VERSION0 and VERSION1 flags are mutually incompatible")
if (info.flags & _ALL_ENCODINGS) not in (0, ASCII, LOCALE, UNICODE):
raise ValueError("ASCII, LOCALE and UNICODE flags are mutually incompatible")
if not (info.flags & _ALL_ENCODINGS):
if isinstance(pattern, unicode):
info.flags |= UNICODE
else:
info.flags |= ASCII
reverse = bool(info.flags & REVERSE)
fuzzy = isinstance(parsed, _Fuzzy)
# Should we print the parsed pattern?
if flags & DEBUG:
parsed.dump(indent=0, reverse=reverse)
# Fix the group references.
parsed.fix_groups(reverse, False)
# Optimise the parsed pattern.
parsed = parsed.optimise(info)
parsed = parsed.pack_characters(info)
# Get the required string.
req_offset, req_chars, req_flags = _get_required_string(parsed, info.flags)
# Build the named lists.
named_lists = {}
named_list_indexes = [None] * len(info.named_lists_used)
args_needed = set()
for key, index in info.named_lists_used.items():
name, case_flags = key
values = frozenset(kwargs[name])
if case_flags:
items = frozenset(_fold_case(info, v) for v in values)
else:
items = values
named_lists[name] = values
named_list_indexes[index] = items
args_needed.add((name, values))
# Check the features of the groups.
_check_group_features(info, parsed)
# Compile the parsed pattern. The result is a list of tuples.
code = parsed.compile(reverse)
# Is there a group call to the pattern as a whole?
key = (0, reverse, fuzzy)
ref = info.call_refs.get(key)
if ref is not None:
code = [(_OP.CALL_REF, ref)] + code + [(_OP.END, )]
# Add the final 'success' opcode.
code += [(_OP.SUCCESS, )]
# Compile the additional copies of the groups that we need.
for group, rev, fuz in info.additional_groups:
code += group.compile(rev, fuz)
# Flatten the code into a list of ints.
code = _flatten_code(code)
if not parsed.has_simple_start():
# Get the first set, if possible.
try:
fs_code = _compile_firstset(info, parsed.get_firstset(reverse))
fs_code = _flatten_code(fs_code)
code = fs_code + code
except _FirstSetError:
pass
# The named capture groups.
index_group = dict((v, n) for n, v in info.group_index.items())
# Create the PatternObject.
#
# Local flags like IGNORECASE affect the code generation, but aren't needed
# by the PatternObject itself. Conversely, global flags like LOCALE _don't_
# affect the code generation but _are_ needed by the PatternObject.
compiled_pattern = _regex.compile(pattern, info.flags | version, code,
info.group_index, index_group, named_lists, named_list_indexes,
req_offset, req_chars, req_flags, info.group_count)
# Do we need to reduce the size of the cache?
if len(_cache) >= _MAXCACHE:
_cache_lock.acquire()
try:
_shrink_cache(_cache, _named_args, _MAXCACHE)
finally:
_cache_lock.release()
args_needed = frozenset(args_needed)
# Store this regular expression and named list.
pattern_key = (pattern, type(pattern), flags, args_needed, DEFAULT_VERSION)
_cache[pattern_key] = compiled_pattern
# Store what keyword arguments are needed.
_named_args[args_key] = args_needed
return compiled_pattern
def _compile_replacement_helper(pattern, template):
"Compiles a replacement template."
# This function is called by the _regex module.
# Have we seen this before?
key = pattern.pattern, pattern.flags, template
compiled = _replacement_cache.get(key)
if compiled is not None:
return compiled
if len(_replacement_cache) >= _MAXREPCACHE:
_replacement_cache.clear()
is_unicode = isinstance(template, unicode)
source = _Source(template)
if is_unicode:
def make_string(char_codes):
return u"".join(unichr(c) for c in char_codes)
else:
def make_string(char_codes):
return "".join(chr(c) for c in char_codes)
compiled = []
literal = []
while True:
ch = source.get()
if not ch:
break
if ch == "\\":
# '_compile_replacement' will return either an int group reference
# or a string literal. It returns items (plural) in order to handle
# a 2-character literal (an invalid escape sequence).
is_group, items = _compile_replacement(source, pattern, is_unicode)
if is_group:
# It's a group, so first flush the literal.
if literal:
compiled.append(make_string(literal))
literal = []
compiled.extend(items)
else:
literal.extend(items)
else:
literal.append(ord(ch))
# Flush the literal.
if literal:
compiled.append(make_string(literal))
_replacement_cache[key] = compiled
return compiled
# We define _pattern_type here after all the support objects have been defined.
_pattern_type = type(_compile("", 0, {}))
# We'll define an alias for the 'compile' function so that the repr of a
# pattern object is eval-able.
Regex = compile
# Register myself for pickling.
import copy_reg as _copy_reg
def _pickle(p):
return _compile, (p.pattern, p.flags)
_copy_reg.pickle(_pattern_type, _pickle, _compile)
if not hasattr(str, "format"):
# Strings don't have the .format method (below Python 2.6).
while True:
_start = __doc__.find(" subf")
if _start < 0:
break
_end = __doc__.find("\n", _start) + 1
while __doc__.startswith(" ", _end):
_end = __doc__.find("\n", _end) + 1
__doc__ = __doc__[ : _start] + __doc__[_end : ]
__all__ = [_name for _name in __all__ if not _name.startswith("subf")]
del _start, _end
del subf, subfn