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Current Directory: /opt/saltstack/salt/lib/python3.10/site-packages/tempora
/opt/saltstack/salt/lib/python3.10/site-packages/tempora/
Viewing File: /opt/saltstack/salt/lib/python3.10/site-packages/tempora/__init__.py
"Objects and routines pertaining to date and time (tempora)" import datetime import time import re import numbers import functools import warnings import contextlib from jaraco.functools import once class Parser: """ *deprecated* Datetime parser: parses a date-time string using multiple possible formats. >>> p = Parser(('%H%M', '%H:%M')) >>> tuple(p.parse('1319')) (1900, 1, 1, 13, 19, 0, 0, 1, -1) >>> dateParser = Parser(('%m/%d/%Y', '%Y-%m-%d', '%d-%b-%Y')) >>> tuple(dateParser.parse('2003-12-20')) (2003, 12, 20, 0, 0, 0, 5, 354, -1) >>> tuple(dateParser.parse('16-Dec-1994')) (1994, 12, 16, 0, 0, 0, 4, 350, -1) >>> tuple(dateParser.parse('5/19/2003')) (2003, 5, 19, 0, 0, 0, 0, 139, -1) >>> dtParser = Parser(('%Y-%m-%d %H:%M:%S', '%a %b %d %H:%M:%S %Y')) >>> tuple(dtParser.parse('2003-12-20 19:13:26')) (2003, 12, 20, 19, 13, 26, 5, 354, -1) >>> tuple(dtParser.parse('Tue Jan 20 16:19:33 2004')) (2004, 1, 20, 16, 19, 33, 1, 20, -1) Be forewarned, a ValueError will be raised if more than one format matches: >>> Parser(('%H%M', '%H%M%S')).parse('732') Traceback (most recent call last): ... ValueError: More than one format string matched target 732. >>> Parser(('%H',)).parse('22:21') Traceback (most recent call last): ... ValueError: No format strings matched the target 22:21. """ formats = ('%m/%d/%Y', '%m/%d/%y', '%Y-%m-%d', '%d-%b-%Y', '%d-%b-%y') "some common default formats" def __init__(self, formats=None): warnings.warn("Use dateutil.parser", DeprecationWarning) if formats: self.formats = formats def parse(self, target): self.target = target results = tuple(filter(None, map(self._parse, self.formats))) del self.target if not results: tmpl = "No format strings matched the target {target}." raise ValueError(tmpl.format(**locals())) if not len(results) == 1: tmpl = "More than one format string matched target {target}." raise ValueError(tmpl.format(**locals())) return results[0] def _parse(self, format): try: result = time.strptime(self.target, format) except ValueError: result = False return result # some useful constants osc_per_year = 290091329207984000 """ mean vernal equinox year expressed in oscillations of atomic cesium at the year 2000 (see http://webexhibits.org/calendars/timeline.html for more info). """ osc_per_second = 9192631770 seconds_per_second = 1 seconds_per_year = 31556940 seconds_per_minute = 60 minutes_per_hour = 60 hours_per_day = 24 seconds_per_hour = seconds_per_minute * minutes_per_hour seconds_per_day = seconds_per_hour * hours_per_day days_per_year = seconds_per_year / seconds_per_day thirty_days = datetime.timedelta(days=30) # these values provide useful averages six_months = datetime.timedelta(days=days_per_year / 2) seconds_per_month = seconds_per_year / 12 hours_per_month = hours_per_day * days_per_year / 12 @once def _needs_year_help(): """ Some versions of Python render %Y with only three characters :( https://bugs.python.org/issue39103 """ return len(datetime.date(900, 1, 1).strftime('%Y')) != 4 def ensure_datetime(ob): """ Given a datetime or date or time object from the ``datetime`` module, always return a datetime using default values. """ if isinstance(ob, datetime.datetime): return ob date = time = ob if isinstance(ob, datetime.date): time = datetime.time() if isinstance(ob, datetime.time): date = datetime.date(1900, 1, 1) return datetime.datetime.combine(date, time) def strftime(fmt, t): """ Portable strftime. In the stdlib, strftime has `known portability problems <https://bugs.python.org/issue13305>`_. This function aims to smooth over those issues and provide a consistent experience across the major platforms. >>> strftime('%Y', datetime.datetime(1890, 1, 1)) '1890' >>> strftime('%Y', datetime.datetime(900, 1, 1)) '0900' Supports time.struct_time, tuples, and datetime.datetime objects. >>> strftime('%Y-%m-%d', (1976, 5, 7)) '1976-05-07' Also supports date objects >>> strftime('%Y', datetime.date(1976, 5, 7)) '1976' Also supports milliseconds using %s. >>> strftime('%s', datetime.time(microsecond=20000)) '020' Also supports microseconds (3 digits) using %µ >>> strftime('%µ', datetime.time(microsecond=123456)) '456' Historically, %u was used for microseconds, but now it honors the value rendered by stdlib. >>> strftime('%u', datetime.date(1976, 5, 7)) '5' Also supports microseconds (6 digits) using %f >>> strftime('%f', datetime.time(microsecond=23456)) '023456' Even supports time values on date objects (discouraged): >>> strftime('%f', datetime.date(1976, 1, 1)) '000000' >>> strftime('%µ', datetime.date(1976, 1, 1)) '000' >>> strftime('%s', datetime.date(1976, 1, 1)) '000' And vice-versa: >>> strftime('%Y', datetime.time()) '1900' """ if isinstance(t, (time.struct_time, tuple)): t = datetime.datetime(*t[:6]) t = ensure_datetime(t) subs = ( ('%s', '%03d' % (t.microsecond // 1000)), ('%µ', '%03d' % (t.microsecond % 1000)), ) if _needs_year_help(): # pragma: nocover subs += (('%Y', '%04d' % t.year),) def doSub(s, sub): return s.replace(*sub) def doSubs(s): return functools.reduce(doSub, subs, s) fmt = '%%'.join(map(doSubs, fmt.split('%%'))) return t.strftime(fmt) def datetime_mod(dt, period, start=None): """ Find the time which is the specified date/time truncated to the time delta relative to the start date/time. By default, the start time is midnight of the same day as the specified date/time. >>> datetime_mod(datetime.datetime(2004, 1, 2, 3), ... datetime.timedelta(days = 1.5), ... start = datetime.datetime(2004, 1, 1)) datetime.datetime(2004, 1, 1, 0, 0) >>> datetime_mod(datetime.datetime(2004, 1, 2, 13), ... datetime.timedelta(days = 1.5), ... start = datetime.datetime(2004, 1, 1)) datetime.datetime(2004, 1, 2, 12, 0) >>> datetime_mod(datetime.datetime(2004, 1, 2, 13), ... datetime.timedelta(days = 7), ... start = datetime.datetime(2004, 1, 1)) datetime.datetime(2004, 1, 1, 0, 0) >>> datetime_mod(datetime.datetime(2004, 1, 10, 13), ... datetime.timedelta(days = 7), ... start = datetime.datetime(2004, 1, 1)) datetime.datetime(2004, 1, 8, 0, 0) """ if start is None: # use midnight of the same day start = datetime.datetime.combine(dt.date(), datetime.time()) # calculate the difference between the specified time and the start date. delta = dt - start # now aggregate the delta and the period into microseconds # Use microseconds because that's the highest precision of these time # pieces. Also, using microseconds ensures perfect precision (no floating # point errors). def get_time_delta_microseconds(td): return (td.days * seconds_per_day + td.seconds) * 1000000 + td.microseconds delta, period = map(get_time_delta_microseconds, (delta, period)) offset = datetime.timedelta(microseconds=delta % period) # the result is the original specified time minus the offset result = dt - offset return result def datetime_round(dt, period, start=None): """ Find the nearest even period for the specified date/time. >>> datetime_round(datetime.datetime(2004, 11, 13, 8, 11, 13), ... datetime.timedelta(hours = 1)) datetime.datetime(2004, 11, 13, 8, 0) >>> datetime_round(datetime.datetime(2004, 11, 13, 8, 31, 13), ... datetime.timedelta(hours = 1)) datetime.datetime(2004, 11, 13, 9, 0) >>> datetime_round(datetime.datetime(2004, 11, 13, 8, 30), ... datetime.timedelta(hours = 1)) datetime.datetime(2004, 11, 13, 9, 0) """ result = datetime_mod(dt, period, start) if abs(dt - result) >= period // 2: result += period return result def get_nearest_year_for_day(day): """ Returns the nearest year to now inferred from a Julian date. >>> freezer = getfixture('freezer') >>> freezer.move_to('2019-05-20') >>> get_nearest_year_for_day(20) 2019 >>> get_nearest_year_for_day(340) 2018 >>> freezer.move_to('2019-12-15') >>> get_nearest_year_for_day(20) 2020 """ now = time.gmtime() result = now.tm_year # if the day is far greater than today, it must be from last year if day - now.tm_yday > 365 // 2: result -= 1 # if the day is far less than today, it must be for next year. if now.tm_yday - day > 365 // 2: result += 1 return result def gregorian_date(year, julian_day): """ Gregorian Date is defined as a year and a julian day (1-based index into the days of the year). >>> gregorian_date(2007, 15) datetime.date(2007, 1, 15) """ result = datetime.date(year, 1, 1) result += datetime.timedelta(days=julian_day - 1) return result def get_period_seconds(period): """ return the number of seconds in the specified period >>> get_period_seconds('day') 86400 >>> get_period_seconds(86400) 86400 >>> get_period_seconds(datetime.timedelta(hours=24)) 86400 >>> get_period_seconds('day + os.system("rm -Rf *")') Traceback (most recent call last): ... ValueError: period not in (second, minute, hour, day, month, year) """ if isinstance(period, str): try: name = 'seconds_per_' + period.lower() result = globals()[name] except KeyError: msg = "period not in (second, minute, hour, day, month, year)" raise ValueError(msg) elif isinstance(period, numbers.Number): result = period elif isinstance(period, datetime.timedelta): result = period.days * get_period_seconds('day') + period.seconds else: raise TypeError('period must be a string or integer') return result def get_date_format_string(period): """ For a given period (e.g. 'month', 'day', or some numeric interval such as 3600 (in secs)), return the format string that can be used with strftime to format that time to specify the times across that interval, but no more detailed. For example, >>> get_date_format_string('month') '%Y-%m' >>> get_date_format_string(3600) '%Y-%m-%d %H' >>> get_date_format_string('hour') '%Y-%m-%d %H' >>> get_date_format_string(None) Traceback (most recent call last): ... TypeError: period must be a string or integer >>> get_date_format_string('garbage') Traceback (most recent call last): ... ValueError: period not in (second, minute, hour, day, month, year) """ # handle the special case of 'month' which doesn't have # a static interval in seconds if isinstance(period, str) and period.lower() == 'month': return '%Y-%m' file_period_secs = get_period_seconds(period) format_pieces = ('%Y', '-%m-%d', ' %H', '-%M', '-%S') seconds_per_second = 1 intervals = ( seconds_per_year, seconds_per_day, seconds_per_hour, seconds_per_minute, seconds_per_second, ) mods = list(map(lambda interval: file_period_secs % interval, intervals)) format_pieces = format_pieces[: mods.index(0) + 1] return ''.join(format_pieces) def divide_timedelta_float(td, divisor): """ Divide a timedelta by a float value >>> one_day = datetime.timedelta(days=1) >>> half_day = datetime.timedelta(days=.5) >>> divide_timedelta_float(one_day, 2.0) == half_day True >>> divide_timedelta_float(one_day, 2) == half_day True """ warnings.warn("Use native division", DeprecationWarning) return td / divisor def calculate_prorated_values(): """ >>> monkeypatch = getfixture('monkeypatch') >>> import builtins >>> monkeypatch.setattr(builtins, 'input', lambda prompt: '3/hour') >>> calculate_prorated_values() per minute: 0.05 per hour: 3.0 per day: 72.0 per month: 2191.454166666667 per year: 26297.45 """ rate = input("Enter the rate (3/hour, 50/month)> ") for period, value in _prorated_values(rate): print("per {period}: {value}".format(**locals())) def _prorated_values(rate): """ Given a rate (a string in units per unit time), and return that same rate for various time periods. >>> for period, value in _prorated_values('20/hour'): ... print('{period}: {value:0.3f}'.format(**locals())) minute: 0.333 hour: 20.000 day: 480.000 month: 14609.694 year: 175316.333 """ res = re.match(r'(?P<value>[\d.]+)/(?P<period>\w+)$', rate).groupdict() value = float(res['value']) value_per_second = value / get_period_seconds(res['period']) for period in ('minute', 'hour', 'day', 'month', 'year'): period_value = value_per_second * get_period_seconds(period) yield period, period_value def parse_timedelta(str): """ Take a string representing a span of time and parse it to a time delta. Accepts any string of comma-separated numbers each with a unit indicator. >>> parse_timedelta('1 day') datetime.timedelta(days=1) >>> parse_timedelta('1 day, 30 seconds') datetime.timedelta(days=1, seconds=30) >>> parse_timedelta('47.32 days, 20 minutes, 15.4 milliseconds') datetime.timedelta(days=47, seconds=28848, microseconds=15400) Supports weeks, months, years >>> parse_timedelta('1 week') datetime.timedelta(days=7) >>> parse_timedelta('1 year, 1 month') datetime.timedelta(days=395, seconds=58685) Note that months and years strict intervals, not aligned to a calendar: >>> now = datetime.datetime.now() >>> later = now + parse_timedelta('1 year') >>> diff = later.replace(year=now.year) - now >>> diff.seconds 20940 >>> parse_timedelta('14 seconds foo') Traceback (most recent call last): ... ValueError: Unexpected 'foo' Supports abbreviations: >>> parse_timedelta('1s') datetime.timedelta(seconds=1) >>> parse_timedelta('1sec') datetime.timedelta(seconds=1) >>> parse_timedelta('5min1sec') datetime.timedelta(seconds=301) >>> parse_timedelta('1 ms') datetime.timedelta(microseconds=1000) >>> parse_timedelta('1 µs') datetime.timedelta(microseconds=1) >>> parse_timedelta('1 us') datetime.timedelta(microseconds=1) And supports the common colon-separated duration: >>> parse_timedelta('14:00:35.362') datetime.timedelta(seconds=50435, microseconds=362000) TODO: Should this be 14 hours or 14 minutes? >>> parse_timedelta('14:00') datetime.timedelta(seconds=50400) >>> parse_timedelta('14:00 minutes') Traceback (most recent call last): ... ValueError: Cannot specify units with composite delta Nanoseconds get rounded to the nearest microsecond: >>> parse_timedelta('600 ns') datetime.timedelta(microseconds=1) >>> parse_timedelta('.002 µs, 499 ns') datetime.timedelta(microseconds=1) """ return _parse_timedelta_nanos(str).resolve() def _parse_timedelta_nanos(str): parts = re.finditer(r'(?P<value>[\d.:]+)\s?(?P<unit>[^\W\d_]+)?', str) chk_parts = _check_unmatched(parts, str) deltas = map(_parse_timedelta_part, chk_parts) return sum(deltas, _Saved_NS()) def _check_unmatched(matches, text): """ Ensure no words appear in unmatched text. """ def check_unmatched(unmatched): found = re.search(r'\w+', unmatched) if found: raise ValueError(f"Unexpected {found.group(0)!r}") pos = 0 for match in matches: check_unmatched(text[pos : match.start()]) yield match pos = match.end() check_unmatched(text[match.end() :]) _unit_lookup = { 'µs': 'microsecond', 'µsec': 'microsecond', 'us': 'microsecond', 'usec': 'microsecond', 'micros': 'microsecond', 'ms': 'millisecond', 'msec': 'millisecond', 'millis': 'millisecond', 's': 'second', 'sec': 'second', 'h': 'hour', 'hr': 'hour', 'm': 'minute', 'min': 'minute', 'w': 'week', 'wk': 'week', 'd': 'day', 'ns': 'nanosecond', 'nsec': 'nanosecond', 'nanos': 'nanosecond', } def _resolve_unit(raw_match): if raw_match is None: return 'second' text = raw_match.lower() return _unit_lookup.get(text, text) def _parse_timedelta_composite(raw_value, unit): if unit != 'seconds': raise ValueError("Cannot specify units with composite delta") values = raw_value.split(':') units = 'hours', 'minutes', 'seconds' composed = ' '.join(f'{value} {unit}' for value, unit in zip(values, units)) return _parse_timedelta_nanos(composed) def _parse_timedelta_part(match): unit = _resolve_unit(match.group('unit')) if not unit.endswith('s'): unit += 's' raw_value = match.group('value') if ':' in raw_value: return _parse_timedelta_composite(raw_value, unit) value = float(raw_value) if unit == 'months': unit = 'years' value = value / 12 if unit == 'years': unit = 'days' value = value * days_per_year return _Saved_NS.derive(unit, value) class _Saved_NS: """ Bundle a timedelta with nanoseconds. >>> _Saved_NS.derive('microseconds', .001) _Saved_NS(td=datetime.timedelta(0), nanoseconds=1) """ td = datetime.timedelta() nanoseconds = 0 multiplier = dict( seconds=1000000000, milliseconds=1000000, microseconds=1000, ) def __init__(self, **kwargs): vars(self).update(kwargs) @classmethod def derive(cls, unit, value): if unit == 'nanoseconds': return _Saved_NS(nanoseconds=value) res = _Saved_NS(td=datetime.timedelta(**{unit: value})) with contextlib.suppress(KeyError): res.nanoseconds = int(value * cls.multiplier[unit]) % 1000 return res def __add__(self, other): return _Saved_NS( td=self.td + other.td, nanoseconds=self.nanoseconds + other.nanoseconds ) def resolve(self): """ Resolve any nanoseconds into the microseconds field, discarding any nanosecond resolution (but honoring partial microseconds). """ addl_micros = round(self.nanoseconds / 1000) return self.td + datetime.timedelta(microseconds=addl_micros) def __repr__(self): return f'_Saved_NS(td={self.td!r}, nanoseconds={self.nanoseconds!r})' def divide_timedelta(td1, td2): """ Get the ratio of two timedeltas >>> one_day = datetime.timedelta(days=1) >>> one_hour = datetime.timedelta(hours=1) >>> divide_timedelta(one_hour, one_day) == 1 / 24 True """ warnings.warn("Use native division", DeprecationWarning) return td1 / td2 def date_range(start=None, stop=None, step=None): """ Much like the built-in function range, but works with dates >>> range_items = date_range( ... datetime.datetime(2005,12,21), ... datetime.datetime(2005,12,25), ... ) >>> my_range = tuple(range_items) >>> datetime.datetime(2005,12,21) in my_range True >>> datetime.datetime(2005,12,22) in my_range True >>> datetime.datetime(2005,12,25) in my_range False >>> from_now = date_range(stop=datetime.datetime(2099, 12, 31)) >>> next(from_now) datetime.datetime(...) """ if step is None: step = datetime.timedelta(days=1) if start is None: start = datetime.datetime.now() while start < stop: yield start start += step
webs 1.0 - Enhanced UI