from __future__ import absolute_import import logging import re import sys from datetime import datetime from datetime import time from datetime import timedelta from datetime import tzinfo from decimal import Decimal from functools import partial __version__ = "1.20.1" __all__ = ["parse", "search", "findall", "with_pattern"] log = logging.getLogger(__name__) def with_pattern(pattern, regex_group_count=None): r"""Attach a regular expression pattern matcher to a custom type converter function. This annotates the type converter with the :attr:`pattern` attribute. EXAMPLE: >>> import parse >>> @parse.with_pattern(r"\d+") ... def parse_number(text): ... return int(text) is equivalent to: >>> def parse_number(text): ... return int(text) >>> parse_number.pattern = r"\d+" :param pattern: regular expression pattern (as text) :param regex_group_count: Indicates how many regex-groups are in pattern. :return: wrapped function """ def decorator(func): func.pattern = pattern func.regex_group_count = regex_group_count return func return decorator class int_convert: """Convert a string to an integer. The string may start with a sign. It may be of a base other than 2, 8, 10 or 16. If base isn't specified, it will be detected automatically based on a string format. When string starts with a base indicator, 0#nnnn, it overrides the default base of 10. It may also have other non-numeric characters that we can ignore. """ CHARS = "0123456789abcdefghijklmnopqrstuvwxyz" def __init__(self, base=None): self.base = base def __call__(self, string, match): if string[0] == "-": sign = -1 number_start = 1 elif string[0] == "+": sign = 1 number_start = 1 else: sign = 1 number_start = 0 base = self.base # If base wasn't specified, detect it automatically if base is None: # Assume decimal number, unless different base is detected base = 10 # For number formats starting with 0b, 0o, 0x, use corresponding base ... if string[number_start] == "0" and len(string) - number_start > 2: if string[number_start + 1] in "bB": base = 2 elif string[number_start + 1] in "oO": base = 8 elif string[number_start + 1] in "xX": base = 16 chars = int_convert.CHARS[:base] string = re.sub("[^%s]" % chars, "", string.lower()) return sign * int(string, base) class convert_first: """Convert the first element of a pair. This equivalent to lambda s,m: converter(s). But unlike a lambda function, it can be pickled """ def __init__(self, converter): self.converter = converter def __call__(self, string, match): return self.converter(string) def percentage(string, match): return float(string[:-1]) / 100.0 class FixedTzOffset(tzinfo): """Fixed offset in minutes east from UTC.""" ZERO = timedelta(0) def __init__(self, offset, name): self._offset = timedelta(minutes=offset) self._name = name def __repr__(self): return "<%s %s %s>" % (self.__class__.__name__, self._name, self._offset) def utcoffset(self, dt): return self._offset def tzname(self, dt): return self._name def dst(self, dt): return self.ZERO def __eq__(self, other): if not isinstance(other, FixedTzOffset): return NotImplemented return self._name == other._name and self._offset == other._offset MONTHS_MAP = { "Jan": 1, "January": 1, "Feb": 2, "February": 2, "Mar": 3, "March": 3, "Apr": 4, "April": 4, "May": 5, "Jun": 6, "June": 6, "Jul": 7, "July": 7, "Aug": 8, "August": 8, "Sep": 9, "September": 9, "Oct": 10, "October": 10, "Nov": 11, "November": 11, "Dec": 12, "December": 12, } DAYS_PAT = r"(Mon|Tue|Wed|Thu|Fri|Sat|Sun)" MONTHS_PAT = r"(Jan|Feb|Mar|Apr|May|Jun|Jul|Aug|Sep|Oct|Nov|Dec)" ALL_MONTHS_PAT = r"(%s)" % "|".join(MONTHS_MAP) TIME_PAT = r"(\d{1,2}:\d{1,2}(:\d{1,2}(\.\d+)?)?)" AM_PAT = r"(\s+[AP]M)" TZ_PAT = r"(\s+[-+]\d\d?:?\d\d)" def date_convert( string, match, ymd=None, mdy=None, dmy=None, d_m_y=None, hms=None, am=None, tz=None, mm=None, dd=None, ): """Convert the incoming string containing some date / time info into a datetime instance. """ groups = match.groups() time_only = False if mm and dd: y = datetime.today().year m = groups[mm] d = groups[dd] elif ymd is not None: y, m, d = re.split(r"[-/\s]", groups[ymd]) elif mdy is not None: m, d, y = re.split(r"[-/\s]", groups[mdy]) elif dmy is not None: d, m, y = re.split(r"[-/\s]", groups[dmy]) elif d_m_y is not None: d, m, y = d_m_y d = groups[d] m = groups[m] y = groups[y] else: time_only = True H = M = S = u = 0 if hms is not None and groups[hms]: t = groups[hms].split(":") if len(t) == 2: H, M = t else: H, M, S = t if "." in S: S, u = S.split(".") u = int(float("." + u) * 1000000) S = int(S) H = int(H) M = int(M) if am is not None: am = groups[am] if am: am = am.strip() if am == "AM" and H == 12: # correction for "12" hour functioning as "0" hour: 12:15 AM = 00:15 by 24 hr clock H -= 12 elif am == "PM" and H == 12: # no correction needed: 12PM is midday, 12:00 by 24 hour clock pass elif am == "PM": H += 12 if tz is not None: tz = groups[tz] if tz == "Z": tz = FixedTzOffset(0, "UTC") elif tz: tz = tz.strip() if tz.isupper(): # TODO use the awesome python TZ module? pass else: sign = tz[0] if ":" in tz: tzh, tzm = tz[1:].split(":") elif len(tz) == 4: # 'snnn' tzh, tzm = tz[1], tz[2:4] else: tzh, tzm = tz[1:3], tz[3:5] offset = int(tzm) + int(tzh) * 60 if sign == "-": offset = -offset tz = FixedTzOffset(offset, tz) if time_only: d = time(H, M, S, u, tzinfo=tz) else: y = int(y) if m.isdigit(): m = int(m) else: m = MONTHS_MAP[m] d = int(d) d = datetime(y, m, d, H, M, S, u, tzinfo=tz) return d def strf_date_convert(x, _, type): is_date = any("%" + x in type for x in "aAwdbBmyYjUW") is_time = any("%" + x in type for x in "HIpMSfz") dt = datetime.strptime(x, type) if "%y" not in type and "%Y" not in type: # year not specified dt = dt.replace(year=datetime.today().year) if is_date and is_time: return dt elif is_date: return dt.date() elif is_time: return dt.time() else: ValueError("Datetime not a date nor a time?") # ref: https://docs.python.org/3/library/datetime.html#strftime-and-strptime-format-codes dt_format_to_regex = { "%a": "(?:Sun|Mon|Tue|Wed|Thu|Fri|Sat)", "%A": "(?:Sunday|Monday|Tuesday|Wednesday|Thursday|Friday|Saturday)", "%w": "[0-6]", "%d": "[0-9]{1,2}", "%b": "(?:Jan|Feb|Mar|Apr|May|Jun|Jul|Aug|Sep|Oct|Nov|Dec)", "%B": "(?:January|February|March|April|May|June|July|August|September|October|November|December)", "%m": "[0-9]{1,2}", "%y": "[0-9]{2}", "%Y": "[0-9]{4}", "%H": "[0-9]{1,2}", "%I": "[0-9]{1,2}", "%p": "(?:AM|PM)", "%M": "[0-9]{2}", "%S": "[0-9]{2}", "%f": "[0-9]{1,6}", "%z": "[+|-][0-9]{2}(:?[0-9]{2})?(:?[0-9]{2})?", # "%Z": punt "%j": "[0-9]{1,3}", "%U": "[0-9]{1,2}", "%W": "[0-9]{1,2}", } # Compile a regular expression pattern that matches any date/time format symbol. dt_format_symbols_re = re.compile("|".join(dt_format_to_regex)) def get_regex_for_datetime_format(format_): """ Generate a regex pattern for a given datetime format string. Parameters: format_ (str): The datetime format string. Returns: str: A regex pattern corresponding to the datetime format string. """ # Replace all format symbols with their regex patterns. return dt_format_symbols_re.sub(lambda m: dt_format_to_regex[m.group(0)], format_) class TooManyFields(ValueError): pass class RepeatedNameError(ValueError): pass # note: {} are handled separately REGEX_SAFETY = re.compile(r"([?\\.[\]()*+^$!|])") # allowed field types ALLOWED_TYPES = set(list("nbox%fFegwWdDsSl") + ["t" + c for c in "ieahgcts"]) def extract_format(format, extra_types): """Pull apart the format [[fill]align][sign][0][width][.precision][type]""" fill = align = None if format[0] in "<>=^": align = format[0] format = format[1:] elif len(format) > 1 and format[1] in "<>=^": fill = format[0] align = format[1] format = format[2:] if format.startswith(("+", "-", " ")): format = format[1:] zero = False if format and format[0] == "0": zero = True format = format[1:] width = "" while format: if not format[0].isdigit(): break width += format[0] format = format[1:] if format.startswith("."): # Precision isn't needed but we need to capture it so that # the ValueError isn't raised. format = format[1:] # drop the '.' precision = "" while format: if not format[0].isdigit(): break precision += format[0] format = format[1:] # the rest is the type, if present type = format if ( type and type not in ALLOWED_TYPES and type not in extra_types and not any(k in type for k in dt_format_to_regex) ): raise ValueError("format spec %r not recognised" % type) return locals() PARSE_RE = re.compile(r"({{|}}|{\w*(?:\.\w+|\[[^]]+])*(?::[^}]+)?})") class Parser(object): """Encapsulate a format string that may be used to parse other strings.""" def __init__(self, format, extra_types=None, case_sensitive=False): # a mapping of a name as in {hello.world} to a regex-group compatible # name, like hello__world. It's used to prevent the transformation of # name-to-group and group to name to fail subtly, such as in: # hello_.world-> hello___world->hello._world self._group_to_name_map = {} # also store the original field name to group name mapping to allow # multiple instances of a name in the format string self._name_to_group_map = {} # and to sanity check the repeated instances store away the first # field type specification for the named field self._name_types = {} self._format = format if extra_types is None: extra_types = {} self._extra_types = extra_types if case_sensitive: self._re_flags = re.DOTALL else: self._re_flags = re.IGNORECASE | re.DOTALL self._fixed_fields = [] self._named_fields = [] self._group_index = 0 self._type_conversions = {} self._expression = self._generate_expression() self.__search_re = None self.__match_re = None log.debug("format %r -> %r", format, self._expression) def __repr__(self): if len(self._format) > 20: return "<%s %r>" % (self.__class__.__name__, self._format[:17] + "...") return "<%s %r>" % (self.__class__.__name__, self._format) @property def _search_re(self): if self.__search_re is None: try: self.__search_re = re.compile(self._expression, self._re_flags) except AssertionError: # access error through sys to keep py3k and backward compat e = str(sys.exc_info()[1]) if e.endswith("this version only supports 100 named groups"): raise TooManyFields( "sorry, you are attempting to parse too many complex fields" ) return self.__search_re @property def _match_re(self): if self.__match_re is None: expression = r"\A%s\Z" % self._expression try: self.__match_re = re.compile(expression, self._re_flags) except AssertionError: # access error through sys to keep py3k and backward compat e = str(sys.exc_info()[1]) if e.endswith("this version only supports 100 named groups"): raise TooManyFields( "sorry, you are attempting to parse too many complex fields" ) except re.error: raise NotImplementedError( "Group names (e.g. (?P) can " "cause failure, as they are not escaped properly: '%s'" % expression ) return self.__match_re @property def named_fields(self): return self._named_fields.copy() @property def fixed_fields(self): return self._fixed_fields.copy() @property def format(self): return self._format def parse(self, string, evaluate_result=True): """Match my format to the string exactly. Return a Result or Match instance or None if there's no match. """ m = self._match_re.match(string) if m is None: return None if evaluate_result: return self.evaluate_result(m) else: return Match(self, m) def search(self, string, pos=0, endpos=None, evaluate_result=True): """Search the string for my format. Optionally start the search at "pos" character index and limit the search to a maximum index of endpos - equivalent to search(string[:endpos]). If the ``evaluate_result`` argument is set to ``False`` a Match instance is returned instead of the actual Result instance. Return either a Result instance or None if there's no match. """ if endpos is None: endpos = len(string) m = self._search_re.search(string, pos, endpos) if m is None: return None if evaluate_result: return self.evaluate_result(m) else: return Match(self, m) def findall( self, string, pos=0, endpos=None, extra_types=None, evaluate_result=True ): """Search "string" for all occurrences of "format". Optionally start the search at "pos" character index and limit the search to a maximum index of endpos - equivalent to search(string[:endpos]). Returns an iterator that holds Result or Match instances for each format match found. """ if endpos is None: endpos = len(string) return ResultIterator( self, string, pos, endpos, evaluate_result=evaluate_result ) def _expand_named_fields(self, named_fields): result = {} for field, value in named_fields.items(): # split 'aaa[bbb][ccc]...' into 'aaa' and '[bbb][ccc]...' n = field.find("[") if n == -1: basename, subkeys = field, "" else: basename, subkeys = field[:n], field[n:] # create nested dictionaries {'aaa': {'bbb': {'ccc': ...}}} d = result k = basename if subkeys: for subkey in re.findall(r"\[[^]]+]", subkeys): d = d.setdefault(k, {}) k = subkey[1:-1] # assign the value to the last key d[k] = value return result def evaluate_result(self, m): """Generate a Result instance for the given regex match object""" # ok, figure the fixed fields we've pulled out and type convert them fixed_fields = list(m.groups()) for n in self._fixed_fields: if n in self._type_conversions: fixed_fields[n] = self._type_conversions[n](fixed_fields[n], m) fixed_fields = tuple(fixed_fields[n] for n in self._fixed_fields) # grab the named fields, converting where requested groupdict = m.groupdict() named_fields = {} name_map = {} for k in self._named_fields: korig = self._group_to_name_map[k] name_map[korig] = k if k in self._type_conversions: value = self._type_conversions[k](groupdict[k], m) else: value = groupdict[k] named_fields[korig] = value # now figure the match spans spans = {n: m.span(name_map[n]) for n in named_fields} spans.update((i, m.span(n + 1)) for i, n in enumerate(self._fixed_fields)) # and that's our result return Result(fixed_fields, self._expand_named_fields(named_fields), spans) def _regex_replace(self, match): return "\\" + match.group(1) def _generate_expression(self): # turn my _format attribute into the _expression attribute e = [] for part in PARSE_RE.split(self._format): if not part: continue elif part == "{{": e.append(r"\{") elif part == "}}": e.append(r"\}") elif part[0] == "{" and part[-1] == "}": # this will be a braces-delimited field to handle e.append(self._handle_field(part)) else: # just some text to match e.append(REGEX_SAFETY.sub(self._regex_replace, part)) return "".join(e) def _to_group_name(self, field): # return a version of field which can be used as capture group, even # though it might contain '.' group = field.replace(".", "_").replace("[", "_").replace("]", "_") # make sure we don't collide ("a.b" colliding with "a_b") n = 1 while group in self._group_to_name_map: n += 1 if "." in field: group = field.replace(".", "_" * n) elif "_" in field: group = field.replace("_", "_" * n) else: raise KeyError("duplicated group name %r" % (field,)) # save off the mapping self._group_to_name_map[group] = field self._name_to_group_map[field] = group return group def _handle_field(self, field): # first: lose the braces field = field[1:-1] # now figure whether this is an anonymous or named field, and whether # there's any format specification format = "" if ":" in field: name, format = field.split(":", 1) else: name = field # This *should* be more flexible, but parsing complicated structures # out of the string is hard (and not necessarily useful) ... and I'm # being lazy. So for now `identifier` is "anything starting with a # letter" and digit args don't get attribute or element stuff. if name and name[0].isalpha(): if name in self._name_to_group_map: if self._name_types[name] != format: raise RepeatedNameError( 'field type %r for field "%s" ' "does not match previous seen type %r" % (format, name, self._name_types[name]) ) group = self._name_to_group_map[name] # match previously-seen value return r"(?P=%s)" % group else: group = self._to_group_name(name) self._name_types[name] = format self._named_fields.append(group) # this will become a group, which must not contain dots wrap = r"(?P<%s>%%s)" % group else: self._fixed_fields.append(self._group_index) wrap = r"(%s)" group = self._group_index # simplest case: no type specifier ({} or {name}) if not format: self._group_index += 1 return wrap % r".+?" # decode the format specification format = extract_format(format, self._extra_types) # figure type conversions, if any type = format["type"] is_numeric = type and type in "n%fegdobx" conv = self._type_conversions if type in self._extra_types: type_converter = self._extra_types[type] s = getattr(type_converter, "pattern", r".+?") regex_group_count = getattr(type_converter, "regex_group_count", 0) if regex_group_count is None: regex_group_count = 0 self._group_index += regex_group_count conv[group] = convert_first(type_converter) elif type == "n": s = r"\d{1,3}([,.]\d{3})*" self._group_index += 1 conv[group] = int_convert(10) elif type == "b": s = r"(0[bB])?[01]+" conv[group] = int_convert(2) self._group_index += 1 elif type == "o": s = r"(0[oO])?[0-7]+" conv[group] = int_convert(8) self._group_index += 1 elif type == "x": s = r"(0[xX])?[0-9a-fA-F]+" conv[group] = int_convert(16) self._group_index += 1 elif type == "%": s = r"\d+(\.\d+)?%" self._group_index += 1 conv[group] = percentage elif type == "f": s = r"\d*\.\d+" conv[group] = convert_first(float) elif type == "F": s = r"\d*\.\d+" conv[group] = convert_first(Decimal) elif type == "e": s = r"\d*\.\d+[eE][-+]?\d+|nan|NAN|[-+]?inf|[-+]?INF" conv[group] = convert_first(float) elif type == "g": s = r"\d+(\.\d+)?([eE][-+]?\d+)?|nan|NAN|[-+]?inf|[-+]?INF" self._group_index += 2 conv[group] = convert_first(float) elif type == "d": if format.get("width"): width = r"{1,%s}" % int(format["width"]) else: width = "+" s = r"\d{w}|[-+ ]?0[xX][0-9a-fA-F]{w}|[-+ ]?0[bB][01]{w}|[-+ ]?0[oO][0-7]{w}".format( w=width ) conv[group] = int_convert() # do not specify number base, determine it automatically elif any(k in type for k in dt_format_to_regex): s = get_regex_for_datetime_format(type) conv[group] = partial(strf_date_convert, type=type) elif type == "ti": s = r"(\d{4}-\d\d-\d\d)((\s+|T)%s)?(Z|\s*[-+]\d\d:?\d\d)?" % TIME_PAT n = self._group_index conv[group] = partial(date_convert, ymd=n + 1, hms=n + 4, tz=n + 7) self._group_index += 7 elif type == "tg": s = r"(\d{1,2}[-/](\d{1,2}|%s)[-/]\d{4})(\s+%s)?%s?%s?" s %= (ALL_MONTHS_PAT, TIME_PAT, AM_PAT, TZ_PAT) n = self._group_index conv[group] = partial( date_convert, dmy=n + 1, hms=n + 5, am=n + 8, tz=n + 9 ) self._group_index += 9 elif type == "ta": s = r"((\d{1,2}|%s)[-/]\d{1,2}[-/]\d{4})(\s+%s)?%s?%s?" s %= (ALL_MONTHS_PAT, TIME_PAT, AM_PAT, TZ_PAT) n = self._group_index conv[group] = partial( date_convert, mdy=n + 1, hms=n + 5, am=n + 8, tz=n + 9 ) self._group_index += 9 elif type == "te": # this will allow microseconds through if they're present, but meh s = r"(%s,\s+)?(\d{1,2}\s+%s\s+\d{4})\s+%s%s" s %= (DAYS_PAT, MONTHS_PAT, TIME_PAT, TZ_PAT) n = self._group_index conv[group] = partial(date_convert, dmy=n + 3, hms=n + 5, tz=n + 8) self._group_index += 8 elif type == "th": # slight flexibility here from the stock Apache format s = r"(\d{1,2}[-/]%s[-/]\d{4}):%s%s" % (MONTHS_PAT, TIME_PAT, TZ_PAT) n = self._group_index conv[group] = partial(date_convert, dmy=n + 1, hms=n + 3, tz=n + 6) self._group_index += 6 elif type == "tc": s = r"(%s)\s+%s\s+(\d{1,2})\s+%s\s+(\d{4})" s %= (DAYS_PAT, MONTHS_PAT, TIME_PAT) n = self._group_index conv[group] = partial(date_convert, d_m_y=(n + 4, n + 3, n + 8), hms=n + 5) self._group_index += 8 elif type == "tt": s = r"%s?%s?%s?" % (TIME_PAT, AM_PAT, TZ_PAT) n = self._group_index conv[group] = partial(date_convert, hms=n + 1, am=n + 4, tz=n + 5) self._group_index += 5 elif type == "ts": s = r"%s(\s+)(\d+)(\s+)(\d{1,2}:\d{1,2}:\d{1,2})?" % MONTHS_PAT n = self._group_index conv[group] = partial(date_convert, mm=n + 1, dd=n + 3, hms=n + 5) self._group_index += 5 elif type == "l": s = r"[A-Za-z]+" elif type: s = r"\%s+" % type elif format.get("precision"): if format.get("width"): s = r".{%s,%s}?" % (format["width"], format["precision"]) else: s = r".{1,%s}?" % format["precision"] elif format.get("width"): s = r".{%s,}?" % format["width"] else: s = r".+?" align = format["align"] fill = format["fill"] # handle some numeric-specific things like fill and sign if is_numeric: # prefix with something (align "=" trumps zero) if align == "=": # special case - align "=" acts like the zero above but with # configurable fill defaulting to "0" if not fill: fill = "0" s = r"%s*" % fill + s # allow numbers to be prefixed with a sign s = r"[-+ ]?" + s if not fill: fill = " " # Place into a group now - this captures the value we want to keep. # Everything else from now is just padding to be stripped off if wrap: s = wrap % s self._group_index += 1 if format["width"]: # all we really care about is that if the format originally # specified a width then there will probably be padding - without # an explicit alignment that'll mean right alignment with spaces # padding if not align: align = ">" if fill in r".\+?*[](){}^$": fill = "\\" + fill # align "=" has been handled if align == "<": s = "%s%s*" % (s, fill) elif align == ">": s = "%s*%s" % (fill, s) elif align == "^": s = "%s*%s%s*" % (fill, s, fill) return s class Result(object): """The result of a parse() or search(). Fixed results may be looked up using `result[index]`. Slices of fixed results may also be looked up. Named results may be looked up using `result['name']`. Named results may be tested for existence using `'name' in result`. """ def __init__(self, fixed, named, spans): self.fixed = fixed self.named = named self.spans = spans def __getitem__(self, item): if isinstance(item, (int, slice)): return self.fixed[item] return self.named[item] def __repr__(self): return "<%s %r %r>" % (self.__class__.__name__, self.fixed, self.named) def __contains__(self, name): return name in self.named class Match(object): """The result of a parse() or search() if no results are generated. This class is only used to expose internal used regex match objects to the user and use them for external Parser.evaluate_result calls. """ def __init__(self, parser, match): self.parser = parser self.match = match def evaluate_result(self): """Generate results for this Match""" return self.parser.evaluate_result(self.match) class ResultIterator(object): """The result of a findall() operation. Each element is a Result instance. """ def __init__(self, parser, string, pos, endpos, evaluate_result=True): self.parser = parser self.string = string self.pos = pos self.endpos = endpos self.evaluate_result = evaluate_result def __iter__(self): return self def __next__(self): m = self.parser._search_re.search(self.string, self.pos, self.endpos) if m is None: raise StopIteration() self.pos = m.end() if self.evaluate_result: return self.parser.evaluate_result(m) else: return Match(self.parser, m) # pre-py3k compat next = __next__ def parse(format, string, extra_types=None, evaluate_result=True, case_sensitive=False): """Using "format" attempt to pull values from "string". The format must match the string contents exactly. If the value you're looking for is instead just a part of the string use search(). If ``evaluate_result`` is True the return value will be an Result instance with two attributes: .fixed - tuple of fixed-position values from the string .named - dict of named values from the string If ``evaluate_result`` is False the return value will be a Match instance with one method: .evaluate_result() - This will return a Result instance like you would get with ``evaluate_result`` set to True The default behaviour is to match strings case insensitively. You may match with case by specifying case_sensitive=True. If the format is invalid a ValueError will be raised. See the module documentation for the use of "extra_types". In the case there is no match parse() will return None. """ p = Parser(format, extra_types=extra_types, case_sensitive=case_sensitive) return p.parse(string, evaluate_result=evaluate_result) def search( format, string, pos=0, endpos=None, extra_types=None, evaluate_result=True, case_sensitive=False, ): """Search "string" for the first occurrence of "format". The format may occur anywhere within the string. If instead you wish for the format to exactly match the string use parse(). Optionally start the search at "pos" character index and limit the search to a maximum index of endpos - equivalent to search(string[:endpos]). If ``evaluate_result`` is True the return value will be an Result instance with two attributes: .fixed - tuple of fixed-position values from the string .named - dict of named values from the string If ``evaluate_result`` is False the return value will be a Match instance with one method: .evaluate_result() - This will return a Result instance like you would get with ``evaluate_result`` set to True The default behaviour is to match strings case insensitively. You may match with case by specifying case_sensitive=True. If the format is invalid a ValueError will be raised. See the module documentation for the use of "extra_types". In the case there is no match parse() will return None. """ p = Parser(format, extra_types=extra_types, case_sensitive=case_sensitive) return p.search(string, pos, endpos, evaluate_result=evaluate_result) def findall( format, string, pos=0, endpos=None, extra_types=None, evaluate_result=True, case_sensitive=False, ): """Search "string" for all occurrences of "format". You will be returned an iterator that holds Result instances for each format match found. Optionally start the search at "pos" character index and limit the search to a maximum index of endpos - equivalent to search(string[:endpos]). If ``evaluate_result`` is True each returned Result instance has two attributes: .fixed - tuple of fixed-position values from the string .named - dict of named values from the string If ``evaluate_result`` is False each returned value is a Match instance with one method: .evaluate_result() - This will return a Result instance like you would get with ``evaluate_result`` set to True The default behaviour is to match strings case insensitively. You may match with case by specifying case_sensitive=True. If the format is invalid a ValueError will be raised. See the module documentation for the use of "extra_types". """ p = Parser(format, extra_types=extra_types, case_sensitive=case_sensitive) return p.findall(string, pos, endpos, evaluate_result=evaluate_result) def compile(format, extra_types=None, case_sensitive=False): """Create a Parser instance to parse "format". The resultant Parser has a method .parse(string) which behaves in the same manner as parse(format, string). The default behaviour is to match strings case insensitively. You may match with case by specifying case_sensitive=True. Use this function if you intend to parse many strings with the same format. See the module documentation for the use of "extra_types". Returns a Parser instance. """ return Parser(format, extra_types=extra_types, case_sensitive=case_sensitive) # Copyright (c) 2012-2020 Richard Jones # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files (the "Software"), to deal # in the Software without restriction, including without limitation the rights # to use, copy, modify, merge, publish, distribute, sublicense, and/or sell # copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in # all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE # SOFTWARE. # vim: set filetype=python ts=4 sw=4 et si tw=75