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//usr/lib/python2.4/site-packages/mx/DateTime/DateTime.py
""" Python part of the low-level DateTime[Delta] type implementation. Copyright (c) 1998-2001, Marc-Andre Lemburg; mailto:mal@lemburg.com Copyright (c) 2000-2001, eGenix.com Software GmbH; mailto:info@egenix.com See the documentation for further information on copyrights, or contact the author. All Rights Reserved. """ # Import C extension module from mxDateTime import * from mxDateTime import __version__ # Singletons oneSecond = DateTimeDelta(0,0,0,1) oneMinute = DateTimeDelta(0,0,1) oneHour = DateTimeDelta(0,1) oneDay = DateTimeDelta(1) oneWeek = DateTimeDelta(7) Epoch = DateTimeFromAbsDateTime(1,0) # Shortcuts for pickle; for backward compatibility only (they are now # defined in __init__.py to further reduce the pickles length) def _DT(absdate,abstime): return DateTimeFromAbsDateTime(absdate,abstime) def _DTD(seconds): return DateTimeDeltaFromSeconds(seconds) # Module init class modinit: global _time,_string,_math import time,string,math _time = time _string = string _math = math del modinit # Aliases and functions to make 'from mx.DateTime import *' work much # like 'from time import *' def localtime(ticks=None, # Locals: time=_time.time,float=float,localtime=_time.localtime, round=round,int=int,DateTime=DateTime,floor=_math.floor): """localtime(ticks=None) Construct a DateTime instance using local time from ticks. If ticks are not given, it defaults to the current time. The result is similar to time.localtime(). Fractions of a second are rounded to the nearest micro-second. """ if ticks is None: ticks = time() else: ticks = float(ticks) ticks = round(ticks, 6) fticks = floor(ticks) Y,M,D,h,m,s = localtime(fticks)[:6] s = s + (ticks - fticks) return DateTime(Y,M,D,h,m,s) def gmtime(ticks=None, # Locals: time=_time.time,float=float,gmtime=_time.gmtime, round=round,int=int,DateTime=DateTime,floor=_math.floor): """gmtime(ticks=None) Construct a DateTime instance using UTC time from ticks. If ticks are not given, it defaults to the current time. The result is similar to time.gmtime(). Fractions of a second are rounded to the nearest micro-second. """ if ticks is None: ticks = time() else: ticks = float(ticks) ticks = round(ticks, 6) fticks = floor(ticks) Y,M,D,h,m,s = gmtime(ticks)[:6] s = s + (ticks - fticks) return DateTime(Y,M,D,h,m,s) def mktime((year,month,day,hour,minute,second,dow,doy,dst), # Locals: DateTime=DateTime): """mktime((year,month,day,hour,minute,second,dow,doy,dst)) Same as the DateTime() constructor accept that the interface used is compatible to the similar time.mktime() API. Note that the tuple elements dow, doy and dst are not used in any way. """ return DateTime(year,month,day,hour,minute,second) def ctime(datetime): """ctime(datetime) Returns a string representation of the given DateTime instance using the current locale's default settings. """ return datetime.strftime('%c') def today(hour=0,minute=0,second=0.0, # Locals: localtime=_time.localtime,time=_time.time,DateTime=DateTime): """today(hour=0,minute=0,second=0.0) Returns a DateTime instance for today (in local time) at the given time (defaults to midnight). """ Y,M,D = localtime(time())[:3] return DateTime(Y,M,D,hour,minute,second) def TimeDelta(hours=0.0,minutes=0.0,seconds=0.0, # Locals: DateTimeDelta=DateTimeDelta): """TimeDelta(hours=0.0,minutes=0.0,seconds=0.0) Returns a DateTimeDelta-object reflecting the given time delta. Seconds can be given as float to indicate fractions. """ return DateTimeDelta(0,hours,minutes,seconds) def gm2local(datetime): """ gm2local(datetime) Convert a DateTime instance holding UTC time to a DateTime instance using local time. """ return localtime(datetime.gmticks()) def local2gm(datetime): """ local2gm(datetime) Convert a DateTime instance holding local time to a DateTime instance using UTC time. """ return gmtime(datetime.ticks()) # Alias gmt = utc # Default value for DateTimeFromTJD's tjd_myriad parameter current_myriad = localtime().tjd_myriad def DateTimeFromTJD(tjd,tjd_myriad=current_myriad): """ DateTimeFromTJD(tjd[,myriad]) Return a DateTime instance for the given Truncated Julian Day. myriad defaults to the TJD myriad current at package import time. Note that this version of Truncated Julian Day number does real truncation of important information. It's use is discouraged and unsupported. """ return DateTimeFromAbsDays(tjd + tjd_myriad * 10000.0 - 1721425.0) def DateTimeFromJDN(jdn): """ DateTimeFromJDN(jdn) Return a DateTime instance for the given Julian Day Number. References: ----------- Gregorian 2000-01-01 12:00:00 corresponds to JDN 2451545.0. Gregorian 1858-11-17 00:00:00.00 corresponds to JDN 2400000.5; MJD 0.0. Julian -4712-01-01 12:00:00.00 corresponds to JDN 0.0. Gregorian -4713-11-24 12:00:00.00 corresponds to JDN 0.0. """ return DateTimeFromAbsDays(jdn - 1721425.5) def DateTimeFromMJD(mjd): """ DateTimeFromMJD(mjd) Return a DateTime instance for the given Modified Julian Day (MJD). The MJD is calculated the same way as the JDN except that 1858-11-17 00:00:00.00 is taken as origin of the scale. """ return DateTimeFromAbsDays(mjd + 678575.0) def DateTimeFrom(*args,**kws): """ DateTimeFrom(*args,**kws) Generic DateTime instance constructor. Can handle parsing strings, numbers and keywords. """ import types if len(args) == 1: # Single argument arg = args[0] if type(arg) is types.StringType: import Parser return Parser.DateTimeFromString(arg) elif type(arg) is DateTimeType: return arg elif type(arg) is DateTimeDeltaType: raise TypeError,'cannot convert DateTimeDelta to DateTime' else: try: value = float(arg) except TypeError: value = int(arg) return DateTimeFromTicks(value) elif len(args) > 1: # More than one argument if len(args) == 2 and \ type(args[0]) is types.StringType and \ type(args[1]) is types.StringType: # interpret as date and time string import Parser return Parser.DateTimeFromString(args[0] + ' ' + args[1]) # Assume the arguments are the same as for DateTime() return apply(DateTime,args) elif len(kws) > 0: # Keyword arguments; add defaults... today at 0:00:00 hour = kws.get('hour',0) minute = kws.get('minute',0) second = kws.get('second',0) today = now() day = kws.get('day',today.day) month = kws.get('month',today.month) year = kws.get('year',today.year) return DateTime(year,month,day,hour,minute,second) else: raise TypeError,'cannot convert arguments to DateTime' def DateTimeDeltaFrom(*args,**kws): """ DateTimeDeltaFrom(*args,**kws) Generic DateTimeDelta instance constructor. Can handle parsing strings, numbers and keywords. """ import types if len(args) == 1: # Single argument arg = args[0] if type(arg) is types.StringType: import Parser return Parser.DateTimeDeltaFromString(arg) elif type(arg) is DateTimeDeltaType: return arg elif type(arg) is DateTimeType: raise TypeError,'cannot convert DateTime to DateTimeDelta' else: try: value = float(arg) except TypeError: value = int(arg) return DateTimeDeltaFromSeconds(value) elif len(args) > 1: # Assume the arguments are the same as for DateTimeDelta() return apply(DateTimeDelta,args) elif len(kws) > 0: # Keyword arguments; default: 00:00:00:00.00 hours = kws.get('hours',0) minutes = kws.get('minutes',0) seconds = kws.get('seconds',0.0) days = kws.get('days',0) return DateTimeDelta(days,hours,minutes,seconds) else: raise TypeError,'cannot convert arguments to DateTimeDelta' def TimeDeltaFrom(*args,**kws): """ TimeDeltaFrom(*args,**kws) Generic TimeDelta instance constructor. Can handle parsing strings, numbers and keywords. """ if len(args) > 1: # Assume the arguments are the same as for TimeDelta(): without # days part ! return apply(DateTimeDelta,(0,)+args) else: # Otherwise treat the arguments just like for DateTimeDelta # instances. return apply(DateTimeDeltaFrom,args,kws) def DateFromTicks(ticks, # Locals: DateTime=DateTime,localtime=_time.localtime): """ DateFromTicks(ticks) Constructs a DateTime instance pointing to the local time date at 00:00:00.00 (midnight) indicated by the given ticks value. The time part is ignored. """ return apply(DateTime,localtime(ticks)[:3]) def TimestampFromTicks(ticks, # Locals: DateTime=DateTime,localtime=_time.localtime): """ TimestampFromTicks(ticks) Constructs a DateTime instance pointing to the local date and time indicated by the given ticks value. """ return apply(DateTime,localtime(ticks)[:6]) def TimeFromTicks(ticks, # Locals: DateTimeDelta=DateTimeDelta,localtime=_time.localtime): """ TimeFromTicks(ticks) Constructs a DateTimeDelta instance pointing to the local time indicated by the given ticks value. The date part is ignored. """ return apply(DateTimeDelta, (0,) + localtime(ticks)[3:6]) # Aliases utctime = gmtime utc2local = gm2local local2utc = local2gm DateTimeFromTicks = localtime Date = DateTime Time = TimeDelta Timestamp = DateTime DateFrom = DateTimeFrom TimeFrom = TimeDeltaFrom TimestampFrom = DateTimeFrom GregorianDateTime = DateTime GregorianDate = Date JulianDate = JulianDateTime ### For backward compatibility (these are depreciated): def gmticks(datetime): """gmticks(datetime) [DEPRECIATED: use the .gmticks() method] Returns a ticks value based on the values stored in datetime under the assumption that they are given in UTC, rather than local time. """ return datetime.gmticks() # Alias utcticks = gmticks def tz_offset(datetime, # Locals: oneSecond=oneSecond): """tz_offset(datetime) [DEPRECIATED: use the .gmtoffset() method] Returns a DateTimeDelta instance representing the UTC offset for datetime assuming that the stored values refer to local time. If you subtract this value from datetime, you'll get UTC time. """ return datetime.gmtoffset() ### Constants (only English; see Locale.py for other languages) # Weekdays Monday = 0 Tuesday = 1 Wednesday = 2 Thursday = 3 Friday = 4 Saturday = 5 Sunday = 6 # as mapping Weekday = {'Saturday': 5, 6: 'Sunday', 'Sunday': 6, 'Thursday': 3, 'Wednesday': 2, 'Friday': 4, 'Tuesday': 1, 'Monday': 0, 5: 'Saturday', 4: 'Friday', 3: 'Thursday', 2: 'Wednesday', 1: 'Tuesday', 0: 'Monday'} # Months January = 1 February = 2 March = 3 April = 4 May = 5 June = 6 July = 7 August = 8 September = 9 October = 10 November = 11 December = 12 # as mapping Month = {2: 'February', 3: 'March', None: 0, 'July': 7, 11: 'November', 'December': 12, 'June': 6, 'January': 1, 'September': 9, 'August': 8, 'March': 3, 'November': 11, 'April': 4, 12: 'December', 'May': 5, 10: 'October', 9: 'September', 8: 'August', 7: 'July', 6: 'June', 5: 'May', 4: 'April', 'October': 10, 'February': 2, 1: 'January', 0: None} # Limits (see also the range checks in mxDateTime.c) MaxDateTime = DateTime(5867440,12,31) MinDateTime = DateTime(-5851455,1,1) MaxDateTimeDelta = DateTimeDeltaFromSeconds(2147483647 * 86400.0) MinDateTimeDelta = -MaxDateTimeDelta ### class RelativeDateTime: """RelativeDateTime(years=0,months=0,days=0, hours=0,minutes=0,seconds=0, year=0,month=0,day=0, hour=None,minute=None,second=None, weekday=None,weeks=None) Returns a RelativeDateTime instance for the specified relative time. The constructor handles keywords, so you'll only have to give those parameters which should be changed when you add the relative to an absolute DateTime instance. Adding RelativeDateTime instances is supported with the following rules: deltas will be added together, right side absolute values override left side ones. Adding RelativeDateTime instances to DateTime instances will return DateTime instances with the appropriate calculations applied, e.g. to get a DateTime instance for the first of next month, you'd call now() + RelativeDateTime(months=+1,day=1). """ years = 0 months = 0 days = 0 year = None month = 0 day = 0 hours = 0 minutes = 0 seconds = 0 hour = None minute = None second = None weekday = None def __init__(self, years=0,months=0,days=0, hours=0,minutes=0,seconds=0, year=None,month=None,day=None, hour=None,minute=None,second=None, weekday=None,weeks=0): self.years = years self.months = months self.days = days + weeks*7 self.year = year self.month = month self.day = day self.hours = hours self.minutes = minutes self.seconds = seconds self.hour = hour self.minute = minute self.second = second if weekday: # Make sure we've got a 2-tuple len(weekday) == 2 self.weekday = weekday def __add__(self,other, # Locals: isinstance=isinstance): if isinstance(other,RelativeDateTime): # RelativeDateTime (self) + RelativeDateTime (other) r = RelativeDateTime() # date deltas r.years = self.years + other.years r.months = self.months + other.months r.days = self.days + other.days # absolute entries of other override those in self, if given r.year = other.year or self.year r.month = other.month or self.month r.day = other.day or self.day r.weekday = other.weekday or self.weekday # time deltas r.hours = self.hours + other.hours r.minutes = self.minutes + other.minutes r.seconds = self.seconds + other.seconds # absolute entries of other override those in self, if given r.hour = other.hour or self.hour r.minute = other.minute or self.minute r.second = other.second or self.second return r else: raise TypeError,"can't add the two types" def __radd__(self,other, # Locals: isinstance=isinstance,DateTimeType=DateTimeType, DateTime=DateTime,DateTimeDelta=DateTimeDelta): if isinstance(other,DateTimeType): # DateTime (other) + RelativeDateTime (self) # date if self.year is None: year = other.year + self.years else: year = self.year + self.years if self.month is None: month = other.month + self.months else: month = self.month + self.months if self.day is None: day = other.day else: day = self.day if day < 0: # fix negative day values month = month + 1 day = day + 1 day = day + self.days # time if self.hour is None: hour = other.hour + self.hours else: hour = self.hour + self.hours if self.minute is None: minute = other.minute + self.minutes else: minute = self.minute + self.minutes if self.second is None: second = other.second + self.seconds else: second = self.second + self.seconds # Refit into proper ranges: if month < 1 or month > 12: month = month - 1 year = year + month / 12 month = month % 12 + 1 if self.weekday is None: return DateTime(year, month, 1) + \ DateTimeDelta(day-1,hour,minute,second) # Adjust to the correct weekday day_of_week,index = self.weekday d = DateTime(year, month, 1) + \ DateTimeDelta(day-1,hour,minute,second) if index == 0: return d + (day_of_week - d.day_of_week) elif index > 0: first = d - (d.day - 1) diff = day_of_week - first.day_of_week if diff >= 0: return first + (diff + (index-1) * 7) else: return first + (diff + index * 7) else: last = d + (d.days_in_month - d.day) diff = day_of_week - last.day_of_week if diff <= 0: return last + (diff + (index+1) * 7) else: return last + (diff + index * 7) else: raise TypeError,"can't add the two types" def __sub__(self,other): if isinstance(other,RelativeDateTime): # RelativeDateTime (self) - RelativeDateTime (other) r = RelativeDateTime() # date deltas r.years = self.years - other.years r.months = self.months - other.months r.days = self.days - other.days # absolute entries of other override those in self, if given r.year = other.year or self.year r.month = other.month or self.month r.day = other.day or self.day r.weekday = other.weekday or self.weekday # time deltas r.hours = self.hours - other.hours r.minutes = self.minutes - other.minutes r.seconds = self.seconds - other.seconds # absolute entries of other override those in self, if given r.hour = other.hour or self.hour r.minute = other.minute or self.minute r.second = other.second or self.second return r else: raise TypeError,"can't subtract the two types" def __rsub__(self,other, # Locals: isinstance=isinstance,DateTime=DateTime): if isinstance(other,DateTimeType): # DateTime (other) - RelativeDateTime (self) return other + self.__neg__() else: raise TypeError,"can't subtract the two types" def __neg__(self): # - RelativeDateTime(self) r = RelativeDateTime() # negate date deltas r.years = - self.years r.months = - self.months r.days = - self.days # absolute entries don't change r.year = self.year r.month = self.month r.day = self.day r.weekday = self.weekday # negate time deltas r.hours = - self.hours r.minutes = - self.minutes r.seconds = - self.seconds # absolute entries don't change r.hour = self.hour r.minute = self.minute r.second = self.second return r def __nonzero__(self): # RelativeDateTime instances are considered false in case # they do not define any alterations if (self.year is None and self.years == 0 and self.month is None and self.months == 0 and self.day is None and self.weekday is None and self.days == 0 and self.hour is None and self.hours == 0 and self.minute is None and self.minutes == 0 and self.second is None and self.seconds == 0): return 0 else: return 1 def __mul__(self,other): # RelativeDateTime (self) * Number (other) factor = float(other) r = RelativeDateTime() # date deltas r.years = factor * self.years r.months = factor * self.months r.days = factor * self.days # time deltas r.hours = factor * self.hours r.minutes = factor * self.minutes r.seconds = factor * self.seconds return r __rmul__ = __mul__ def __div__(self,other): # RelativeDateTime (self) / Number (other) return self.__mul__(1/float(other)) def __str__(self, join=_string.join): l = [] append = l.append if self.year is not None: append('%04i-' % self.year) elif self.years: append('(%0+5i)-' % self.years) else: append('YYYY-') if self.month is not None: append('%02i-' % self.month) elif self.months: append('(%0+3i)-' % self.months) else: append('MM-') if self.day is not None: append('%02i' % self.day) elif self.days: append('(%0+3i)' % self.days) else: append('DD') if self.weekday: append(' %s:%i' % (Weekday[self.weekday[0]][:3],self.weekday[1])) append(' ') if self.hour is not None: append('%02i:' % self.hour) elif self.hours: append('(%0+3i):' % self.hours) else: append('HH:') if self.minute is not None: append('%02i:' % self.minute) elif self.minutes: append('(%0+3i):' % self.minutes) else: append('MM:') if self.second is not None: append('%02i' % self.second) elif self.seconds: append('(%0+3i)' % self.seconds) else: append('SS') return join(l,'') def __repr__(self): return "<%s instance for '%s' at 0x%x>" % ( self.__class__.__name__, self.__str__(), id(self)) # Alias RelativeDate = RelativeDateTime def RelativeDateTimeFrom(*args,**kws): """ RelativeDateTimeFrom(*args,**kws) Generic RelativeDateTime instance constructor. Can handle parsing strings and keywords. """ if len(args) == 1: # Single argument arg = args[0] import types if type(arg) is types.StringType: import Parser return Parser.RelativeDateTimeFromString(arg) elif isinstance(arg, RelativeDateTime): return arg else: raise TypeError,\ 'cannot convert argument to RelativeDateTime' else: return apply(RelativeDateTime,args,kws) def RelativeDateTimeDiff(date1,date2, floor=_math.floor,int=int,divmod=divmod, RelativeDateTime=RelativeDateTime): """ RelativeDateTimeDiff(date1,date2) Returns a RelativeDateTime instance representing the difference between date1 and date2 in relative terms. The following should hold: date2 + RelativeDateDiff(date1,date2) == date1 for all dates date1 and date2. Note that due to the algorithm used by this function, not the whole range of DateTime instances is supported; there could also be a loss of precision. XXX There are still some problems left (thanks to Carel Fellinger for pointing these out): 29 1 1901 -> 1 3 1901 = 1 month 29 1 1901 -> 1 3 1900 = -10 month and -28 days, but 29 1 1901 -> 28 2 1900 = -11 month and -1 day and even worse: >>> print RelativeDateDiff(Date(1900,3,1),Date(1901,2,1)) YYYY-(-11)-DD HH:MM:SS with: >>> print Date(1901,1,29) + RelativeDateTime(months=-11) 1900-03-01 00:00:00.00 >>> print Date(1901,2,1) + RelativeDateTime(months=-11) 1900-03-01 00:00:00.00 """ diff = date1 - date2 if diff.days == 0: return RelativeDateTime() date1months = date1.year * 12 + (date1.month - 1) date2months = date2.year * 12 + (date2.month - 1) #print 'months',date1months,date2months # Calculate the months difference diffmonths = date1months - date2months #print 'diffmonths',diffmonths if diff.days > 0: years,months = divmod(diffmonths,12) else: years,months = divmod(diffmonths,-12) years = -years date3 = date2 + RelativeDateTime(years=years,months=months) diff3 = date1 - date3 days = date1.absdays - date3.absdays #print 'date3',date3,'diff3',diff3,'days',days # Correction to ensure that all relative parts have the same sign while days * diff.days < 0: if diff.days > 0: diffmonths = diffmonths - 1 years,months = divmod(diffmonths,12) else: diffmonths = diffmonths + 1 years,months = divmod(diffmonths,-12) years = -years #print 'diffmonths',diffmonths date3 = date2 + RelativeDateTime(years=years,months=months) diff3 = date1 - date3 days = date1.absdays - date3.absdays #print 'date3',date3,'diff3',diff3,'days',days # Drop the fraction part of days if days > 0: days = int(floor(days)) else: days = int(-floor(-days)) return RelativeDateTime(years=years, months=months, days=days, hours=diff3.hour, minutes=diff3.minute, seconds=diff3.second) # Aliases RelativeDateDiff = RelativeDateTimeDiff Age = RelativeDateTimeDiff ### def add_century(year, current_year=now().year, current_century=(now().year / 100) * 100): """ Sliding window approach to the Y2K problem: adds a suitable century to the given year and returns it as integer. The window used depends on the current year (at import time). If adding the current century to the given year gives a year within the range current_year-70...current_year+30 [both inclusive], then the current century is added. Otherwise the century (current + 1 or - 1) producing the least difference is chosen. """ if year > 99: # Take it as-is return year year = year + current_century diff = year - current_year if diff >= -70 and diff <= 30: return year elif diff < -70: return year + 100 else: return year - 100 # Reference formulas for JDN taken from the Calendar FAQ: def gregorian_jdn(year,month,day): a = (14-month)/12 y = year+4800-a m = month + 12*a - 3 return day + (306*m+5)/10 + y*365 + y/4 - y/100 + y/400 - 32045 def julian_jdn(year,month,day): a = (14-month)/12 y = year+4800-a m = month + 12*a - 3 return day + (306*m+5)/10 + y*365 + y/4 - 32083