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Code Editor : _zoneinfo.py
import bisect import calendar import collections import functools import re import weakref from datetime import datetime, timedelta, tzinfo from . import _common, _tzpath EPOCH = datetime(1970, 1, 1) EPOCHORDINAL = datetime(1970, 1, 1).toordinal() # It is relatively expensive to construct new timedelta objects, and in most # cases we're looking at the same deltas, like integer numbers of hours, etc. # To improve speed and memory use, we'll keep a dictionary with references # to the ones we've already used so far. # # Loading every time zone in the 2020a version of the time zone database # requires 447 timedeltas, which requires approximately the amount of space # that ZoneInfo("America/New_York") with 236 transitions takes up, so we will # set the cache size to 512 so that in the common case we always get cache # hits, but specifically crafted ZoneInfo objects don't leak arbitrary amounts # of memory. @functools.lru_cache(maxsize=512) def _load_timedelta(seconds): return timedelta(seconds=seconds) class ZoneInfo(tzinfo): _strong_cache_size = 8 _strong_cache = collections.OrderedDict() _weak_cache = weakref.WeakValueDictionary() __module__ = "zoneinfo" def __init_subclass__(cls): cls._strong_cache = collections.OrderedDict() cls._weak_cache = weakref.WeakValueDictionary() def __new__(cls, key): instance = cls._weak_cache.get(key, None) if instance is None: instance = cls._weak_cache.setdefault(key, cls._new_instance(key)) instance._from_cache = True # Update the "strong" cache cls._strong_cache[key] = cls._strong_cache.pop(key, instance) if len(cls._strong_cache) > cls._strong_cache_size: cls._strong_cache.popitem(last=False) return instance @classmethod def no_cache(cls, key): obj = cls._new_instance(key) obj._from_cache = False return obj @classmethod def _new_instance(cls, key): obj = super().__new__(cls) obj._key = key obj._file_path = obj._find_tzfile(key) if obj._file_path is not None: file_obj = open(obj._file_path, "rb") else: file_obj = _common.load_tzdata(key) with file_obj as f: obj._load_file(f) return obj @classmethod def from_file(cls, fobj, /, key=None): obj = super().__new__(cls) obj._key = key obj._file_path = None obj._load_file(fobj) obj._file_repr = repr(fobj) # Disable pickling for objects created from files obj.__reduce__ = obj._file_reduce return obj @classmethod def clear_cache(cls, *, only_keys=None): if only_keys is not None: for key in only_keys: cls._weak_cache.pop(key, None) cls._strong_cache.pop(key, None) else: cls._weak_cache.clear() cls._strong_cache.clear() @property def key(self): return self._key def utcoffset(self, dt): return self._find_trans(dt).utcoff def dst(self, dt): return self._find_trans(dt).dstoff def tzname(self, dt): return self._find_trans(dt).tzname def fromutc(self, dt): """Convert from datetime in UTC to datetime in local time""" if not isinstance(dt, datetime): raise TypeError("fromutc() requires a datetime argument") if dt.tzinfo is not self: raise ValueError("dt.tzinfo is not self") timestamp = self._get_local_timestamp(dt) num_trans = len(self._trans_utc) if num_trans >= 1 and timestamp < self._trans_utc[0]: tti = self._tti_before fold = 0 elif ( num_trans == 0 or timestamp > self._trans_utc[-1] ) and not isinstance(self._tz_after, _ttinfo): tti, fold = self._tz_after.get_trans_info_fromutc( timestamp, dt.year ) elif num_trans == 0: tti = self._tz_after fold = 0 else: idx = bisect.bisect_right(self._trans_utc, timestamp) if num_trans > 1 and timestamp >= self._trans_utc[1]: tti_prev, tti = self._ttinfos[idx - 2 : idx] elif timestamp > self._trans_utc[-1]: tti_prev = self._ttinfos[-1] tti = self._tz_after else: tti_prev = self._tti_before tti = self._ttinfos[0] # Detect fold shift = tti_prev.utcoff - tti.utcoff fold = shift.total_seconds() > timestamp - self._trans_utc[idx - 1] dt += tti.utcoff if fold: return dt.replace(fold=1) else: return dt def _find_trans(self, dt): if dt is None: if self._fixed_offset: return self._tz_after else: return _NO_TTINFO ts = self._get_local_timestamp(dt) lt = self._trans_local[dt.fold] num_trans = len(lt) if num_trans and ts < lt[0]: return self._tti_before elif not num_trans or ts > lt[-1]: if isinstance(self._tz_after, _TZStr): return self._tz_after.get_trans_info(ts, dt.year, dt.fold) else: return self._tz_after else: # idx is the transition that occurs after this timestamp, so we # subtract off 1 to get the current ttinfo idx = bisect.bisect_right(lt, ts) - 1 assert idx >= 0 return self._ttinfos[idx] def _get_local_timestamp(self, dt): return ( (dt.toordinal() - EPOCHORDINAL) * 86400 + dt.hour * 3600 + dt.minute * 60 + dt.second ) def __str__(self): if self._key is not None: return f"{self._key}" else: return repr(self) def __repr__(self): if self._key is not None: return f"{self.__class__.__name__}(key={self._key!r})" else: return f"{self.__class__.__name__}.from_file({self._file_repr})" def __reduce__(self): return (self.__class__._unpickle, (self._key, self._from_cache)) def _file_reduce(self): import pickle raise pickle.PicklingError( "Cannot pickle a ZoneInfo file created from a file stream." ) @classmethod def _unpickle(cls, key, from_cache, /): if from_cache: return cls(key) else: return cls.no_cache(key) def _find_tzfile(self, key): return _tzpath.find_tzfile(key) def _load_file(self, fobj): # Retrieve all the data as it exists in the zoneinfo file trans_idx, trans_utc, utcoff, isdst, abbr, tz_str = _common.load_data( fobj ) # Infer the DST offsets (needed for .dst()) from the data dstoff = self._utcoff_to_dstoff(trans_idx, utcoff, isdst) # Convert all the transition times (UTC) into "seconds since 1970-01-01 local time" trans_local = self._ts_to_local(trans_idx, trans_utc, utcoff) # Construct `_ttinfo` objects for each transition in the file _ttinfo_list = [ _ttinfo( _load_timedelta(utcoffset), _load_timedelta(dstoffset), tzname ) for utcoffset, dstoffset, tzname in zip(utcoff, dstoff, abbr) ] self._trans_utc = trans_utc self._trans_local = trans_local self._ttinfos = [_ttinfo_list[idx] for idx in trans_idx] # Find the first non-DST transition for i in range(len(isdst)): if not isdst[i]: self._tti_before = _ttinfo_list[i] break else: if self._ttinfos: self._tti_before = self._ttinfos[0] else: self._tti_before = None # Set the "fallback" time zone if tz_str is not None and tz_str != b"": self._tz_after = _parse_tz_str(tz_str.decode()) else: if not self._ttinfos and not _ttinfo_list: raise ValueError("No time zone information found.") if self._ttinfos: self._tz_after = self._ttinfos[-1] else: self._tz_after = _ttinfo_list[-1] # Determine if this is a "fixed offset" zone, meaning that the output # of the utcoffset, dst and tzname functions does not depend on the # specific datetime passed. # # We make three simplifying assumptions here: # # 1. If _tz_after is not a _ttinfo, it has transitions that might # actually occur (it is possible to construct TZ strings that # specify STD and DST but no transitions ever occur, such as # AAA0BBB,0/0,J365/25). # 2. If _ttinfo_list contains more than one _ttinfo object, the objects # represent different offsets. # 3. _ttinfo_list contains no unused _ttinfos (in which case an # otherwise fixed-offset zone with extra _ttinfos defined may # appear to *not* be a fixed offset zone). # # Violations to these assumptions would be fairly exotic, and exotic # zones should almost certainly not be used with datetime.time (the # only thing that would be affected by this). if len(_ttinfo_list) > 1 or not isinstance(self._tz_after, _ttinfo): self._fixed_offset = False elif not _ttinfo_list: self._fixed_offset = True else: self._fixed_offset = _ttinfo_list[0] == self._tz_after @staticmethod def _utcoff_to_dstoff(trans_idx, utcoffsets, isdsts): # Now we must transform our ttis and abbrs into `_ttinfo` objects, # but there is an issue: .dst() must return a timedelta with the # difference between utcoffset() and the "standard" offset, but # the "base offset" and "DST offset" are not encoded in the file; # we can infer what they are from the isdst flag, but it is not # sufficient to just look at the last standard offset, because # occasionally countries will shift both DST offset and base offset. typecnt = len(isdsts) dstoffs = [0] * typecnt # Provisionally assign all to 0. dst_cnt = sum(isdsts) dst_found = 0 for i in range(1, len(trans_idx)): if dst_cnt == dst_found: break idx = trans_idx[i] dst = isdsts[idx] # We're only going to look at daylight saving time if not dst: continue # Skip any offsets that have already been assigned if dstoffs[idx] != 0: continue dstoff = 0 utcoff = utcoffsets[idx] comp_idx = trans_idx[i - 1] if not isdsts[comp_idx]: dstoff = utcoff - utcoffsets[comp_idx] if not dstoff and idx < (typecnt - 1): comp_idx = trans_idx[i + 1] # If the following transition is also DST and we couldn't # find the DST offset by this point, we're going to have to # skip it and hope this transition gets assigned later if isdsts[comp_idx]: continue dstoff = utcoff - utcoffsets[comp_idx] if dstoff: dst_found += 1 dstoffs[idx] = dstoff else: # If we didn't find a valid value for a given index, we'll end up # with dstoff = 0 for something where `isdst=1`. This is obviously # wrong - one hour will be a much better guess than 0 for idx in range(typecnt): if not dstoffs[idx] and isdsts[idx]: dstoffs[idx] = 3600 return dstoffs @staticmethod def _ts_to_local(trans_idx, trans_list_utc, utcoffsets): """Generate number of seconds since 1970 *in the local time*. This is necessary to easily find the transition times in local time""" if not trans_list_utc: return [[], []] # Start with the timestamps and modify in-place trans_list_wall = [list(trans_list_utc), list(trans_list_utc)] if len(utcoffsets) > 1: offset_0 = utcoffsets[0] offset_1 = utcoffsets[trans_idx[0]] if offset_1 > offset_0: offset_1, offset_0 = offset_0, offset_1 else: offset_0 = offset_1 = utcoffsets[0] trans_list_wall[0][0] += offset_0 trans_list_wall[1][0] += offset_1 for i in range(1, len(trans_idx)): offset_0 = utcoffsets[trans_idx[i - 1]] offset_1 = utcoffsets[trans_idx[i]] if offset_1 > offset_0: offset_1, offset_0 = offset_0, offset_1 trans_list_wall[0][i] += offset_0 trans_list_wall[1][i] += offset_1 return trans_list_wall class _ttinfo: __slots__ = ["utcoff", "dstoff", "tzname"] def __init__(self, utcoff, dstoff, tzname): self.utcoff = utcoff self.dstoff = dstoff self.tzname = tzname def __eq__(self, other): return ( self.utcoff == other.utcoff and self.dstoff == other.dstoff and self.tzname == other.tzname ) def __repr__(self): # pragma: nocover return ( f"{self.__class__.__name__}" + f"({self.utcoff}, {self.dstoff}, {self.tzname})" ) _NO_TTINFO = _ttinfo(None, None, None) class _TZStr: __slots__ = ( "std", "dst", "start", "end", "get_trans_info", "get_trans_info_fromutc", "dst_diff", ) def __init__( self, std_abbr, std_offset, dst_abbr, dst_offset, start=None, end=None ): self.dst_diff = dst_offset - std_offset std_offset = _load_timedelta(std_offset) self.std = _ttinfo( utcoff=std_offset, dstoff=_load_timedelta(0), tzname=std_abbr ) self.start = start self.end = end dst_offset = _load_timedelta(dst_offset) delta = _load_timedelta(self.dst_diff) self.dst = _ttinfo(utcoff=dst_offset, dstoff=delta, tzname=dst_abbr) # These are assertions because the constructor should only be called # by functions that would fail before passing start or end assert start is not None, "No transition start specified" assert end is not None, "No transition end specified" self.get_trans_info = self._get_trans_info self.get_trans_info_fromutc = self._get_trans_info_fromutc def transitions(self, year): start = self.start.year_to_epoch(year) end = self.end.year_to_epoch(year) return start, end def _get_trans_info(self, ts, year, fold): """Get the information about the current transition - tti""" start, end = self.transitions(year) # With fold = 0, the period (denominated in local time) with the # smaller offset starts at the end of the gap and ends at the end of # the fold; with fold = 1, it runs from the start of the gap to the # beginning of the fold. # # So in order to determine the DST boundaries we need to know both # the fold and whether DST is positive or negative (rare), and it # turns out that this boils down to fold XOR is_positive. if fold == (self.dst_diff >= 0): end -= self.dst_diff else: start += self.dst_diff if start < end: isdst = start <= ts < end else: isdst = not (end <= ts < start) return self.dst if isdst else self.std def _get_trans_info_fromutc(self, ts, year): start, end = self.transitions(year) start -= self.std.utcoff.total_seconds() end -= self.dst.utcoff.total_seconds() if start < end: isdst = start <= ts < end else: isdst = not (end <= ts < start) # For positive DST, the ambiguous period is one dst_diff after the end # of DST; for negative DST, the ambiguous period is one dst_diff before # the start of DST. if self.dst_diff > 0: ambig_start = end ambig_end = end + self.dst_diff else: ambig_start = start ambig_end = start - self.dst_diff fold = ambig_start <= ts < ambig_end return (self.dst if isdst else self.std, fold) def _post_epoch_days_before_year(year): """Get the number of days between 1970-01-01 and YEAR-01-01""" y = year - 1 return y * 365 + y // 4 - y // 100 + y // 400 - EPOCHORDINAL class _DayOffset: __slots__ = ["d", "julian", "hour", "minute", "second"] def __init__(self, d, julian, hour=2, minute=0, second=0): if not (0 + julian) <= d <= 365: min_day = 0 + julian raise ValueError(f"d must be in [{min_day}, 365], not: {d}") self.d = d self.julian = julian self.hour = hour self.minute = minute self.second = second def year_to_epoch(self, year): days_before_year = _post_epoch_days_before_year(year) d = self.d if self.julian and d >= 59 and calendar.isleap(year): d += 1 epoch = (days_before_year + d) * 86400 epoch += self.hour * 3600 + self.minute * 60 + self.second return epoch class _CalendarOffset: __slots__ = ["m", "w", "d", "hour", "minute", "second"] _DAYS_BEFORE_MONTH = ( -1, 0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334, ) def __init__(self, m, w, d, hour=2, minute=0, second=0): if not 0 < m <= 12: raise ValueError("m must be in (0, 12]") if not 0 < w <= 5: raise ValueError("w must be in (0, 5]") if not 0 <= d <= 6: raise ValueError("d must be in [0, 6]") self.m = m self.w = w self.d = d self.hour = hour self.minute = minute self.second = second @classmethod def _ymd2ord(cls, year, month, day): return ( _post_epoch_days_before_year(year) + cls._DAYS_BEFORE_MONTH[month] + (month > 2 and calendar.isleap(year)) + day ) # TODO: These are not actually epoch dates as they are expressed in local time def year_to_epoch(self, year): """Calculates the datetime of the occurrence from the year""" # We know year and month, we need to convert w, d into day of month # # Week 1 is the first week in which day `d` (where 0 = Sunday) appears. # Week 5 represents the last occurrence of day `d`, so we need to know # the range of the month. first_day, days_in_month = calendar.monthrange(year, self.m) # This equation seems magical, so I'll break it down: # 1. calendar says 0 = Monday, POSIX says 0 = Sunday # so we need first_day + 1 to get 1 = Monday -> 7 = Sunday, # which is still equivalent because this math is mod 7 # 2. Get first day - desired day mod 7: -1 % 7 = 6, so we don't need # to do anything to adjust negative numbers. # 3. Add 1 because month days are a 1-based index. month_day = (self.d - (first_day + 1)) % 7 + 1 # Now use a 0-based index version of `w` to calculate the w-th # occurrence of `d` month_day += (self.w - 1) * 7 # month_day will only be > days_in_month if w was 5, and `w` means # "last occurrence of `d`", so now we just check if we over-shot the # end of the month and if so knock off 1 week. if month_day > days_in_month: month_day -= 7 ordinal = self._ymd2ord(year, self.m, month_day) epoch = ordinal * 86400 epoch += self.hour * 3600 + self.minute * 60 + self.second return epoch def _parse_tz_str(tz_str): # The tz string has the format: # # std[offset[dst[offset],start[/time],end[/time]]] # # std and dst must be 3 or more characters long and must not contain # a leading colon, embedded digits, commas, nor a plus or minus signs; # The spaces between "std" and "offset" are only for display and are # not actually present in the string. # # The format of the offset is ``[+|-]hh[:mm[:ss]]`` offset_str, *start_end_str = tz_str.split(",", 1) # fmt: off parser_re = re.compile( r"(?P<std>[^<0-9:.+-]+|<[a-zA-Z0-9+\-]+>)" + r"((?P<stdoff>[+-]?\d{1,2}(:\d{2}(:\d{2})?)?)" + r"((?P<dst>[^0-9:.+-]+|<[a-zA-Z0-9+\-]+>)" + r"((?P<dstoff>[+-]?\d{1,2}(:\d{2}(:\d{2})?)?))?" + r")?" + # dst r")?$" # stdoff ) # fmt: on m = parser_re.match(offset_str) if m is None: raise ValueError(f"{tz_str} is not a valid TZ string") std_abbr = m.group("std") dst_abbr = m.group("dst") dst_offset = None std_abbr = std_abbr.strip("<>") if dst_abbr: dst_abbr = dst_abbr.strip("<>") if std_offset := m.group("stdoff"): try: std_offset = _parse_tz_delta(std_offset) except ValueError as e: raise ValueError(f"Invalid STD offset in {tz_str}") from e else: std_offset = 0 if dst_abbr is not None: if dst_offset := m.group("dstoff"): try: dst_offset = _parse_tz_delta(dst_offset) except ValueError as e: raise ValueError(f"Invalid DST offset in {tz_str}") from e else: dst_offset = std_offset + 3600 if not start_end_str: raise ValueError(f"Missing transition rules: {tz_str}") start_end_strs = start_end_str[0].split(",", 1) try: start, end = (_parse_dst_start_end(x) for x in start_end_strs) except ValueError as e: raise ValueError(f"Invalid TZ string: {tz_str}") from e return _TZStr(std_abbr, std_offset, dst_abbr, dst_offset, start, end) elif start_end_str: raise ValueError(f"Transition rule present without DST: {tz_str}") else: # This is a static ttinfo, don't return _TZStr return _ttinfo( _load_timedelta(std_offset), _load_timedelta(0), std_abbr ) def _parse_dst_start_end(dststr): date, *time = dststr.split("/") if date[0] == "M": n_is_julian = False m = re.match(r"M(\d{1,2})\.(\d).(\d)$", date) if m is None: raise ValueError(f"Invalid dst start/end date: {dststr}") date_offset = tuple(map(int, m.groups())) offset = _CalendarOffset(*date_offset) else: if date[0] == "J": n_is_julian = True date = date[1:] else: n_is_julian = False doy = int(date) offset = _DayOffset(doy, n_is_julian) if time: time_components = list(map(int, time[0].split(":"))) n_components = len(time_components) if n_components < 3: time_components.extend([0] * (3 - n_components)) offset.hour, offset.minute, offset.second = time_components return offset def _parse_tz_delta(tz_delta): match = re.match( r"(?P<sign>[+-])?(?P<h>\d{1,2})(:(?P<m>\d{2})(:(?P<s>\d{2}))?)?", tz_delta, ) # Anything passed to this function should already have hit an equivalent # regular expression to find the section to parse. assert match is not None, tz_delta h, m, s = ( int(v) if v is not None else 0 for v in map(match.group, ("h", "m", "s")) ) total = h * 3600 + m * 60 + s if not -86400 < total < 86400: raise ValueError( f"Offset must be strictly between -24h and +24h: {tz_delta}" ) # Yes, +5 maps to an offset of -5h if match.group("sign") != "-": total *= -1 return total
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