File: //home/arjun/projects/env/lib/python3.10/site-packages/pendulum/duration.py
from __future__ import absolute_import
from __future__ import division
from datetime import timedelta
import pendulum
from pendulum.utils._compat import PYPY
from pendulum.utils._compat import decode
from .constants import SECONDS_PER_DAY
from .constants import SECONDS_PER_HOUR
from .constants import SECONDS_PER_MINUTE
from .constants import US_PER_SECOND
def _divide_and_round(a, b):
"""divide a by b and round result to the nearest integer
When the ratio is exactly half-way between two integers,
the even integer is returned.
"""
# Based on the reference implementation for divmod_near
# in Objects/longobject.c.
q, r = divmod(a, b)
# round up if either r / b > 0.5, or r / b == 0.5 and q is odd.
# The expression r / b > 0.5 is equivalent to 2 * r > b if b is
# positive, 2 * r < b if b negative.
r *= 2
greater_than_half = r > b if b > 0 else r < b
if greater_than_half or r == b and q % 2 == 1:
q += 1
return q
class Duration(timedelta):
"""
Replacement for the standard timedelta class.
Provides several improvements over the base class.
"""
_y = None
_m = None
_w = None
_d = None
_h = None
_i = None
_s = None
_invert = None
def __new__(
cls,
days=0,
seconds=0,
microseconds=0,
milliseconds=0,
minutes=0,
hours=0,
weeks=0,
years=0,
months=0,
):
if not isinstance(years, int) or not isinstance(months, int):
raise ValueError("Float year and months are not supported")
self = timedelta.__new__(
cls,
days + years * 365 + months * 30,
seconds,
microseconds,
milliseconds,
minutes,
hours,
weeks,
)
# Intuitive normalization
total = self.total_seconds() - (years * 365 + months * 30) * SECONDS_PER_DAY
self._total = total
m = 1
if total < 0:
m = -1
self._microseconds = round(total % m * 1e6)
self._seconds = abs(int(total)) % SECONDS_PER_DAY * m
_days = abs(int(total)) // SECONDS_PER_DAY * m
self._days = _days
self._remaining_days = abs(_days) % 7 * m
self._weeks = abs(_days) // 7 * m
self._months = months
self._years = years
return self
def total_minutes(self):
return self.total_seconds() / SECONDS_PER_MINUTE
def total_hours(self):
return self.total_seconds() / SECONDS_PER_HOUR
def total_days(self):
return self.total_seconds() / SECONDS_PER_DAY
def total_weeks(self):
return self.total_days() / 7
if PYPY:
def total_seconds(self):
days = 0
if hasattr(self, "_years"):
days += self._years * 365
if hasattr(self, "_months"):
days += self._months * 30
if hasattr(self, "_remaining_days"):
days += self._weeks * 7 + self._remaining_days
else:
days += self._days
return (
(days * SECONDS_PER_DAY + self._seconds) * US_PER_SECOND
+ self._microseconds
) / US_PER_SECOND
@property
def years(self):
return self._years
@property
def months(self):
return self._months
@property
def weeks(self):
return self._weeks
if PYPY:
@property
def days(self):
return self._years * 365 + self._months * 30 + self._days
@property
def remaining_days(self):
return self._remaining_days
@property
def hours(self):
if self._h is None:
seconds = self._seconds
self._h = 0
if abs(seconds) >= 3600:
self._h = (abs(seconds) // 3600 % 24) * self._sign(seconds)
return self._h
@property
def minutes(self):
if self._i is None:
seconds = self._seconds
self._i = 0
if abs(seconds) >= 60:
self._i = (abs(seconds) // 60 % 60) * self._sign(seconds)
return self._i
@property
def seconds(self):
return self._seconds
@property
def remaining_seconds(self):
if self._s is None:
self._s = self._seconds
self._s = abs(self._s) % 60 * self._sign(self._s)
return self._s
@property
def microseconds(self):
return self._microseconds
@property
def invert(self):
if self._invert is None:
self._invert = self.total_seconds() < 0
return self._invert
def in_weeks(self):
return int(self.total_weeks())
def in_days(self):
return int(self.total_days())
def in_hours(self):
return int(self.total_hours())
def in_minutes(self):
return int(self.total_minutes())
def in_seconds(self):
return int(self.total_seconds())
def in_words(self, locale=None, separator=" "):
"""
Get the current interval in words in the current locale.
Ex: 6 jours 23 heures 58 minutes
:param locale: The locale to use. Defaults to current locale.
:type locale: str
:param separator: The separator to use between each unit
:type separator: str
:rtype: str
"""
periods = [
("year", self.years),
("month", self.months),
("week", self.weeks),
("day", self.remaining_days),
("hour", self.hours),
("minute", self.minutes),
("second", self.remaining_seconds),
]
if locale is None:
locale = pendulum.get_locale()
locale = pendulum.locale(locale)
parts = []
for period in periods:
unit, count = period
if abs(count) > 0:
translation = locale.translation(
"units.{}.{}".format(unit, locale.plural(abs(count)))
)
parts.append(translation.format(count))
if not parts:
if abs(self.microseconds) > 0:
unit = "units.second.{}".format(locale.plural(1))
count = "{:.2f}".format(abs(self.microseconds) / 1e6)
else:
unit = "units.microsecond.{}".format(locale.plural(0))
count = 0
translation = locale.translation(unit)
parts.append(translation.format(count))
return decode(separator.join(parts))
def _sign(self, value):
if value < 0:
return -1
return 1
def as_timedelta(self):
"""
Return the interval as a native timedelta.
:rtype: timedelta
"""
return timedelta(seconds=self.total_seconds())
def __str__(self):
return self.in_words()
def __repr__(self):
rep = "{}(".format(self.__class__.__name__)
if self._years:
rep += "years={}, ".format(self._years)
if self._months:
rep += "months={}, ".format(self._months)
if self._weeks:
rep += "weeks={}, ".format(self._weeks)
if self._days:
rep += "days={}, ".format(self._remaining_days)
if self.hours:
rep += "hours={}, ".format(self.hours)
if self.minutes:
rep += "minutes={}, ".format(self.minutes)
if self.remaining_seconds:
rep += "seconds={}, ".format(self.remaining_seconds)
if self.microseconds:
rep += "microseconds={}, ".format(self.microseconds)
rep += ")"
return rep.replace(", )", ")")
def __add__(self, other):
if isinstance(other, timedelta):
return self.__class__(seconds=self.total_seconds() + other.total_seconds())
return NotImplemented
__radd__ = __add__
def __sub__(self, other):
if isinstance(other, timedelta):
return self.__class__(seconds=self.total_seconds() - other.total_seconds())
return NotImplemented
def __neg__(self):
return self.__class__(
years=-self._years,
months=-self._months,
weeks=-self._weeks,
days=-self._remaining_days,
seconds=-self._seconds,
microseconds=-self._microseconds,
)
def _to_microseconds(self):
return (self._days * (24 * 3600) + self._seconds) * 1000000 + self._microseconds
def __mul__(self, other):
if isinstance(other, int):
return self.__class__(
years=self._years * other,
months=self._months * other,
seconds=self._total * other,
)
if isinstance(other, float):
usec = self._to_microseconds()
a, b = other.as_integer_ratio()
return self.__class__(0, 0, _divide_and_round(usec * a, b))
return NotImplemented
__rmul__ = __mul__
def __floordiv__(self, other):
if not isinstance(other, (int, timedelta)):
return NotImplemented
usec = self._to_microseconds()
if isinstance(other, timedelta):
return usec // other._to_microseconds()
if isinstance(other, int):
return self.__class__(
0,
0,
usec // other,
years=self._years // other,
months=self._months // other,
)
def __truediv__(self, other):
if not isinstance(other, (int, float, timedelta)):
return NotImplemented
usec = self._to_microseconds()
if isinstance(other, timedelta):
return usec / other._to_microseconds()
if isinstance(other, int):
return self.__class__(
0,
0,
_divide_and_round(usec, other),
years=_divide_and_round(self._years, other),
months=_divide_and_round(self._months, other),
)
if isinstance(other, float):
a, b = other.as_integer_ratio()
return self.__class__(
0,
0,
_divide_and_round(b * usec, a),
years=_divide_and_round(self._years * b, a),
months=_divide_and_round(self._months, other),
)
__div__ = __floordiv__
def __mod__(self, other):
if isinstance(other, timedelta):
r = self._to_microseconds() % other._to_microseconds()
return self.__class__(0, 0, r)
return NotImplemented
def __divmod__(self, other):
if isinstance(other, timedelta):
q, r = divmod(self._to_microseconds(), other._to_microseconds())
return q, self.__class__(0, 0, r)
return NotImplemented
Duration.min = Duration(days=-999999999)
Duration.max = Duration(
days=999999999, hours=23, minutes=59, seconds=59, microseconds=999999
)
Duration.resolution = Duration(microseconds=1)
class AbsoluteDuration(Duration):
"""
Duration that expresses a time difference in absolute values.
"""
def __new__(
cls,
days=0,
seconds=0,
microseconds=0,
milliseconds=0,
minutes=0,
hours=0,
weeks=0,
years=0,
months=0,
):
if not isinstance(years, int) or not isinstance(months, int):
raise ValueError("Float year and months are not supported")
self = timedelta.__new__(
cls, days, seconds, microseconds, milliseconds, minutes, hours, weeks
)
# We need to compute the total_seconds() value
# on a native timedelta object
delta = timedelta(
days, seconds, microseconds, milliseconds, minutes, hours, weeks
)
# Intuitive normalization
self._total = delta.total_seconds()
total = abs(self._total)
self._microseconds = round(total % 1 * 1e6)
self._seconds = int(total) % SECONDS_PER_DAY
days = int(total) // SECONDS_PER_DAY
self._days = abs(days + years * 365 + months * 30)
self._remaining_days = days % 7
self._weeks = days // 7
self._months = abs(months)
self._years = abs(years)
return self
def total_seconds(self):
return abs(self._total)
@property
def invert(self):
if self._invert is None:
self._invert = self._total < 0
return self._invert