############################################################################## # # Copyright (c) 2001 Zope Corporation and Contributors. All Rights Reserved. # # This software is subject to the provisions of the Zope Public License, # Version 2.0 (ZPL). A copy of the ZPL should accompany this distribution. # THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED # WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED # WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS # FOR A PARTICULAR PURPOSE # ############################################################################## """Encapsulation of date/time values""" __version__='$Revision: 1.81 $'[11:-2] import re,sys, os, math, DateTimeZone from time import time, gmtime, localtime, asctime from time import daylight, timezone, altzone, strftime from types import InstanceType,IntType,FloatType,StringType,UnicodeType try: from time import tzname except: tzname=('UNKNOWN','UNKNOWN') # To control rounding errors, we round system time to the nearest # millisecond. Then delicate calculations can rely on that the # maximum precision that needs to be preserved is known. _system_time = time def time(): return round(_system_time(), 3) # Determine machine epoch tm=((0, 0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334), (0, 0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335)) yr,mo,dy,hr,mn,sc=gmtime(0)[:6] i=int(yr-1) to_year =int(i*365+i/4-i/100+i/400-693960.0) to_month=tm[yr%4==0 and (yr%100!=0 or yr%400==0)][mo] EPOCH =(to_year+to_month+dy+(hr/24.0+mn/1440.0+sc/86400.0))*86400 jd1901 =2415385L numericTimeZoneMatch=re.compile(r'[+-][0-9][0-9][0-9][0-9]').match #TS class _timezone: def __init__(self,data): self.name,self.timect,self.typect, \ self.ttrans,self.tindex,self.tinfo,self.az=data def default_index(self): if self.timect == 0: return 0 for i in range(self.typect): if self.tinfo[i][1] == 0: return i return 0 def index(self,t=None): t=t or time() if self.timect==0: idx=(0, 0, 0) elif t < self.ttrans[0]: i=self.default_index() idx=(i, ord(self.tindex[0]),i) elif t >= self.ttrans[-1]: if self.timect > 1: idx=(ord(self.tindex[-1]),ord(self.tindex[-1]), ord(self.tindex[-2])) else: idx=(ord(self.tindex[-1]),ord(self.tindex[-1]), self.default_index()) else: for i in range(self.timect-1): if t < self.ttrans[i+1]: if i==0: idx=(ord(self.tindex[0]),ord(self.tindex[1]), self.default_index()) else: idx=(ord(self.tindex[i]),ord(self.tindex[i+1]), ord(self.tindex[i-1])) break return idx def info(self,t=None): idx=self.index(t)[0] zs =self.az[self.tinfo[idx][2]:] return self.tinfo[idx][0],self.tinfo[idx][1],zs[:zs.find('\000')] class _cache: _zlst=['Brazil/Acre','Brazil/DeNoronha','Brazil/East', 'Brazil/West','Canada/Atlantic','Canada/Central', 'Canada/Eastern','Canada/East-Saskatchewan', 'Canada/Mountain','Canada/Newfoundland', 'Canada/Pacific','Canada/Yukon', 'Chile/Continental','Chile/EasterIsland','CST','Cuba', 'Egypt','EST','GB-Eire','Greenwich','Hongkong','Iceland', 'Iran','Israel','Jamaica','Japan','Mexico/BajaNorte', 'Mexico/BajaSur','Mexico/General','MST','Poland','PST', 'Singapore','Turkey','Universal','US/Alaska','US/Aleutian', 'US/Arizona','US/Central','US/Eastern','US/East-Indiana', 'US/Hawaii','US/Indiana-Starke','US/Michigan', 'US/Mountain','US/Pacific','US/Samoa','UTC','UCT','GMT', 'GMT+0100','GMT+0200','GMT+0300','GMT+0400','GMT+0500', 'GMT+0600','GMT+0700','GMT+0800','GMT+0900','GMT+1000', 'GMT+1100','GMT+1200','GMT+1300','GMT-0100','GMT-0200', 'GMT-0300','GMT-0400','GMT-0500','GMT-0600','GMT-0700', 'GMT-0800','GMT-0900','GMT-1000','GMT-1100','GMT-1200', 'GMT+1', 'GMT+0130', 'GMT+0230', 'GMT+0330', 'GMT+0430', 'GMT+0530', 'GMT+0630', 'GMT+0730', 'GMT+0830', 'GMT+0930', 'GMT+1030', 'GMT+1130', 'GMT+1230', 'GMT-0130', 'GMT-0230', 'GMT-0330', 'GMT-0430', 'GMT-0530', 'GMT-0630', 'GMT-0730', 'GMT-0830', 'GMT-0930', 'GMT-1030', 'GMT-1130', 'GMT-1230', 'UT','BST','MEST','SST','FST','WADT','EADT','NZDT', 'WET','WAT','AT','AST','NT','IDLW','CET','MET', 'MEWT','SWT','FWT','EET','EEST','BT','ZP4','ZP5','ZP6', 'WAST','CCT','JST','EAST','GST','NZT','NZST','IDLE'] _zmap={'aest':'GMT+1000', 'aedt':'GMT+1100', 'aus eastern standard time':'GMT+1000', 'sydney standard time':'GMT+1000', 'tasmania standard time':'GMT+1000', 'e. australia standard time':'GMT+1000', 'aus central standard time':'GMT+0930', 'cen. australia standard time':'GMT+0930', 'w. australia standard time':'GMT+0800', 'brazil/acre':'Brazil/Acre', 'brazil/denoronha':'Brazil/Denoronha', 'brazil/east':'Brazil/East','brazil/west':'Brazil/West', 'canada/atlantic':'Canada/Atlantic', 'canada/central':'Canada/Central', 'canada/eastern':'Canada/Eastern', 'canada/east-saskatchewan':'Canada/East-Saskatchewan', 'canada/mountain':'Canada/Mountain', 'canada/newfoundland':'Canada/Newfoundland', 'canada/pacific':'Canada/Pacific','canada/yukon':'Canada/Yukon', 'central europe standard time':'GMT+0100', 'chile/continental':'Chile/Continental', 'chile/easterisland':'Chile/EasterIsland', 'cst':'US/Central','cuba':'Cuba','est':'US/Eastern','egypt':'Egypt', 'eastern standard time':'US/Eastern', 'us eastern standard time':'US/Eastern', 'central standard time':'US/Central', 'mountain standard time':'US/Mountain', 'pacific standard time':'US/Pacific', 'gb-eire':'GB-Eire','gmt':'GMT', 'gmt+0000':'GMT+0', 'gmt+0':'GMT+0', 'gmt+0100':'GMT+1', 'gmt+0200':'GMT+2', 'gmt+0300':'GMT+3', 'gmt+0400':'GMT+4', 'gmt+0500':'GMT+5', 'gmt+0600':'GMT+6', 'gmt+0700':'GMT+7', 'gmt+0800':'GMT+8', 'gmt+0900':'GMT+9', 'gmt+1000':'GMT+10','gmt+1100':'GMT+11','gmt+1200':'GMT+12', 'gmt+1300':'GMT+13', 'gmt-0100':'GMT-1', 'gmt-0200':'GMT-2', 'gmt-0300':'GMT-3', 'gmt-0400':'GMT-4', 'gmt-0500':'GMT-5', 'gmt-0600':'GMT-6', 'gmt-0700':'GMT-7', 'gmt-0800':'GMT-8', 'gmt-0900':'GMT-9', 'gmt-1000':'GMT-10','gmt-1100':'GMT-11','gmt-1200':'GMT-12', 'gmt+1': 'GMT+1', 'gmt+2': 'GMT+2', 'gmt+3': 'GMT+3', 'gmt+4': 'GMT+4', 'gmt+5': 'GMT+5', 'gmt+6': 'GMT+6', 'gmt+7': 'GMT+7', 'gmt+8': 'GMT+8', 'gmt+9': 'GMT+9', 'gmt+10':'GMT+10','gmt+11':'GMT+11','gmt+12':'GMT+12', 'gmt+13':'GMT+13', 'gmt-1': 'GMT-1', 'gmt-2': 'GMT-2', 'gmt-3': 'GMT-3', 'gmt-4': 'GMT-4', 'gmt-5': 'GMT-5', 'gmt-6': 'GMT-6', 'gmt-7': 'GMT-7', 'gmt-8': 'GMT-8', 'gmt-9': 'GMT-9', 'gmt-10':'GMT-10','gmt-11':'GMT-11','gmt-12':'GMT-12', 'gmt+130':'GMT+0130', 'gmt+0130':'GMT+0130', 'gmt+230':'GMT+0230', 'gmt+0230':'GMT+0230', 'gmt+330':'GMT+0330', 'gmt+0330':'GMT+0330', 'gmt+430':'GMT+0430', 'gmt+0430':'GMT+0430', 'gmt+530':'GMT+0530', 'gmt+0530':'GMT+0530', 'gmt+630':'GMT+0630', 'gmt+0630':'GMT+0630', 'gmt+730':'GMT+0730', 'gmt+0730':'GMT+0730', 'gmt+830':'GMT+0830', 'gmt+0830':'GMT+0830', 'gmt+930':'GMT+0930', 'gmt+0930':'GMT+0930', 'gmt+1030':'GMT+1030', 'gmt+1130':'GMT+1130', 'gmt+1230':'GMT+1230', 'gmt-130':'GMT-0130', 'gmt-0130':'GMT-0130', 'gmt-230':'GMT-0230', 'gmt-0230':'GMT-0230', 'gmt-330':'GMT-0330', 'gmt-0330':'GMT-0330', 'gmt-430':'GMT-0430', 'gmt-0430':'GMT-0430', 'gmt-530':'GMT-0530', 'gmt-0530':'GMT-0530', 'gmt-630':'GMT-0630', 'gmt-0630':'GMT-0630', 'gmt-730':'GMT-0730', 'gmt-0730':'GMT-0730', 'gmt-830':'GMT-0830', 'gmt-0830':'GMT-0830', 'gmt-930':'GMT-0930', 'gmt-0930':'GMT-0930', 'gmt-1030':'GMT-1030', 'gmt-1130':'GMT-1130', 'gmt-1230':'GMT-1230', 'greenwich':'Greenwich','hongkong':'Hongkong', 'iceland':'Iceland','iran':'Iran','israel':'Israel', 'jamaica':'Jamaica','japan':'Japan', 'mexico/bajanorte':'Mexico/BajaNorte', 'mexico/bajasur':'Mexico/BajaSur','mexico/general':'Mexico/General', 'mst':'US/Mountain','pst':'US/Pacific','poland':'Poland', 'singapore':'Singapore','turkey':'Turkey','universal':'Universal', 'utc':'Universal','uct':'Universal','us/alaska':'US/Alaska', 'us/aleutian':'US/Aleutian','us/arizona':'US/Arizona', 'us/central':'US/Central','us/eastern':'US/Eastern', 'us/east-indiana':'US/East-Indiana','us/hawaii':'US/Hawaii', 'us/indiana-starke':'US/Indiana-Starke','us/michigan':'US/Michigan', 'us/mountain':'US/Mountain','us/pacific':'US/Pacific', 'us/samoa':'US/Samoa', 'ut':'Universal', 'bst':'GMT+1', 'mest':'GMT+2', 'sst':'GMT+2', 'fst':'GMT+2', 'wadt':'GMT+8', 'eadt':'GMT+11', 'nzdt':'GMT+13', 'wet':'GMT', 'wat':'GMT-1', 'at':'GMT-2', 'ast':'GMT-4', 'nt':'GMT-11', 'idlw':'GMT-12', 'cet':'GMT+1', 'cest':'GMT+2', 'met':'GMT+1', 'mewt':'GMT+1', 'swt':'GMT+1', 'fwt':'GMT+1', 'eet':'GMT+2', 'eest':'GMT+3', 'bt':'GMT+3', 'zp4':'GMT+4', 'zp5':'GMT+5', 'zp6':'GMT+6', 'wast':'GMT+7', 'cct':'GMT+8', 'jst':'GMT+9', 'east':'GMT+10', 'gst':'GMT+10', 'nzt':'GMT+12', 'nzst':'GMT+12', 'idle':'GMT+12', 'ret':'GMT+4' } def __init__(self): self._db=DateTimeZone._data self._d,self._zidx={},self._zmap.keys() def __getitem__(self,k): try: n=self._zmap[k.lower()] except KeyError: if numericTimeZoneMatch(k) == None: raise 'DateTimeError','Unrecognized timezone: %s' % k return k try: return self._d[n] except KeyError: z=self._d[n]=_timezone(self._db[n]) return z def _findLocalTimeZoneName(isDST): if not daylight: # Daylight savings does not occur in this time zone. isDST = 0 try: # Get the name of the current time zone depending # on DST. _localzone = _cache._zmap[tzname[isDST].lower()] except: try: # Generate a GMT-offset zone name. if isDST: localzone = altzone else: localzone = timezone offset=(-localzone/(60*60)) majorOffset=int(offset) if majorOffset != 0 : minorOffset=abs(int((offset % majorOffset) * 60.0)) else: minorOffset = 0 m=majorOffset >= 0 and '+' or '' lz='%s%0.02d%0.02d' % (m, majorOffset, minorOffset) _localzone = _cache._zmap[('GMT%s' % lz).lower()] except: _localzone = '' return _localzone # Some utility functions for calculating dates: def _calcSD(t): # Returns timezone-independent days since epoch and the fractional # part of the days. dd = t + EPOCH - 86400.0 d = dd / 86400.0 s = d - math.floor(d) return s, d def _calcDependentSecond(tz, t): # Calculates the timezone-dependent second (integer part only) # from the timezone-independent second. fset = _tzoffset(tz, t) return fset + long(math.floor(t)) + long(EPOCH) - 86400L def _calcDependentSecond2(yr,mo,dy,hr,mn,sc): # Calculates the timezone-dependent second (integer part only) # from the date given. ss = int(hr) * 3600 + int(mn) * 60 + int(sc) x = long(_julianday(yr,mo,dy)-jd1901) * 86400 + ss return x def _calcIndependentSecondEtc(tz, x, ms): # Derive the timezone-independent second from the timezone # dependent second. fsetAtEpoch = _tzoffset(tz, 0.0) nearTime = x - fsetAtEpoch - long(EPOCH) + 86400L + ms # nearTime is now within an hour of being correct. # Recalculate t according to DST. fset = long(_tzoffset(tz, nearTime)) x_adjusted = x - fset + ms d = x_adjusted / 86400.0 t = x_adjusted - long(EPOCH) + 86400L millis = (x + 86400 - fset) * 1000 + \ long(round(ms * 1000.0)) - long(EPOCH * 1000.0) s = d - math.floor(d) return s,d,t,millis def _calcHMS(x, ms): # hours, minutes, seconds from integer and float. hr = x / 3600 x = x - hr * 3600 mn = x / 60 sc = x - mn * 60 + ms return hr,mn,sc def _calcYMDHMS(x, ms): # x is a timezone-dependent integer of seconds. # Produces yr,mo,dy,hr,mn,sc. yr,mo,dy=_calendarday(x / 86400 + jd1901) x = int(x - (x / 86400) * 86400) hr = x / 3600 x = x - hr * 3600 mn = x / 60 sc = x - mn * 60 + ms return yr,mo,dy,hr,mn,sc def _julianday(yr,mo,dy): y,m,d=long(yr),long(mo),long(dy) if m > 12L: y=y+m/12L m=m%12L elif m < 1L: m=-m y=y-m/12L-1L m=12L-m%12L if y > 0L: yr_correct=0L else: yr_correct=3L if m < 3L: y, m=y-1L,m+12L if y*10000L+m*100L+d > 15821014L: b=2L-y/100L+y/400L else: b=0L return (1461L*y-yr_correct)/4L+306001L*(m+1L)/10000L+d+1720994L+b def _calendarday(j): j=long(j) if(j < 2299160L): b=j+1525L else: a=(4L*j-7468861L)/146097L b=j+1526L+a-a/4L c=(20L*b-2442L)/7305L d=1461L*c/4L e=10000L*(b-d)/306001L dy=int(b-d-306001L*e/10000L) mo=(e < 14L) and int(e-1L) or int(e-13L) yr=(mo > 2) and (c-4716L) or (c-4715L) return int(yr),int(mo),int(dy) def _tzoffset(tz, t): try: return DateTime._tzinfo[tz].info(t)[0] except: if numericTimeZoneMatch(tz) is not None: return -int(tz[1:3])*3600-int(tz[3:5])*60 else: return 0 # ?? def _correctYear(year): # Y2K patch. if year >= 0 and year < 100: # 00-69 means 2000-2069, 70-99 means 1970-1999. if year < 70: year = 2000 + year else: year = 1900 + year return year def safegmtime(t): '''gmtime with a safety zone.''' try: t_int = int(t) return gmtime(t_int) except (IOError, OverflowError): raise 'TimeError', 'The time %f is beyond the range ' \ 'of this Python implementation.' % float(t) def safelocaltime(t): '''localtime with a safety zone.''' try: t_int = int(t) except OverflowError: raise 'TimeError', 'The time %f is beyond the range ' \ 'of this Python implementation.' % float(t) rval = localtime(t_int) return rval def _tzoffset2rfc822zone(seconds): return "%+03d%02d" % divmod( (-seconds/60), 60) class DateTime: """DateTime objects represent instants in time and provide interfaces for controlling its representation without affecting the absolute value of the object. DateTime objects may be created from a wide variety of string or numeric data, or may be computed from other DateTime objects. DateTimes support the ability to convert their representations to many major timezones, as well as the ablility to create a DateTime object in the context of a given timezone. DateTime objects provide partial numerical behavior: - Two date-time objects can be subtracted to obtain a time, in days between the two. - A date-time object and a positive or negative number may be added to obtain a new date-time object that is the given number of days later than the input date-time object. - A positive or negative number and a date-time object may be added to obtain a new date-time object that is the given number of days later than the input date-time object. - A positive or negative number may be subtracted from a date-time object to obtain a new date-time object that is the given number of days earlier than the input date-time object. DateTime objects may be converted to integer, long, or float numbers of days since January 1, 1901, using the standard int, long, and float functions (Compatibility Note: int, long and float return the number of days since 1901 in GMT rather than local machine timezone). DateTime objects also provide access to their value in a float format usable with the python time module, provided that the value of the object falls in the range of the epoch-based time module. A DateTime object should be considered immutable; all conversion and numeric operations return a new DateTime object rather than modify the current object.""" # For security machinery: __roles__=None __allow_access_to_unprotected_subobjects__=1 def __init__(self,*args): """Return a new date-time object A DateTime object always maintains its value as an absolute UTC time, and is represented in the context of some timezone based on the arguments used to create the object. A DateTime object's methods return values based on the timezone context. Note that in all cases the local machine timezone is used for representation if no timezone is specified. DateTimes may be created with from zero to seven arguments. - If the function is called with no arguments, then the current date/time is returned, represented in the timezone of the local machine. - If the function is invoked with a single string argument which is a recognized timezone name, an object representing the current time is returned, represented in the specified timezone. - If the function is invoked with a single string argument representing a valid date/time, an object representing that date/time will be returned. As a general rule, any date-time representation that is recognized and unambigous to a resident of North America is acceptable.(The reason for this qualification is that in North America, a date like: 2/1/1994 is interpreted as February 1, 1994, while in some parts of the world, it is interpreted as January 2, 1994.) A date/time string consists of two components, a date component and an optional time component, separated by one or more spaces. If the time component is omited, 12:00am is assumed. Any recognized timezone name specified as the final element of the date/time string will be used for computing the date/time value. (If you create a DateTime with the string 'Mar 9, 1997 1:45pm US/Pacific', the value will essentially be the same as if you had captured time.time() at the specified date and time on a machine in that timezone)

            e=DateTime('US/Eastern')
            # returns current date/time, represented in US/Eastern.

            x=DateTime('1997/3/9 1:45pm')
            # returns specified time, represented in local machine zone.

            y=DateTime('Mar 9, 1997 13:45:00')
            # y is equal to x


            
New in Zope 2.4: The DateTime constructor automatically detects and handles ISO8601 compliant dates (YYYY-MM-DDThh:ss:mmTZD). See http://www.w3.org/TR/NOTE-datetime for full specs. The date component consists of year, month, and day values. The year value must be a one-, two-, or four-digit integer. If a one- or two-digit year is used, the year is assumed to be in the twentieth century. The month may an integer, from 1 to 12, a month name, or a month abreviation, where a period may optionally follow the abreviation. The day must be an integer from 1 to the number of days in the month. The year, month, and day values may be separated by periods, hyphens, forward, shashes, or spaces. Extra spaces are permitted around the delimiters. Year, month, and day values may be given in any order as long as it is possible to distinguish the components. If all three components are numbers that are less than 13, then a a month-day-year ordering is assumed. The time component consists of hour, minute, and second values separated by colons. The hour value must be an integer between 0 and 23 inclusively. The minute value must be an integer between 0 and 59 inclusively. The second value may be an integer value between 0 and 59.999 inclusively. The second value or both the minute and second values may be ommitted. The time may be followed by am or pm in upper or lower case, in which case a 12-hour clock is assumed. - If the DateTime function is invoked with a single Numeric argument, the number is assumed to be a floating point value such as that returned by time.time(). A DateTime object is returned that represents the gmt value of the time.time() float represented in the local machine's timezone. - If the function is invoked with two numeric arguments, then the first is taken to be an integer year and the second argument is taken to be an offset in days from the beginning of the year, in the context of the local machine timezone. The date-time value returned is the given offset number of days from the beginning of the given year, represented in the timezone of the local machine. The offset may be positive or negative. Two-digit years are assumed to be in the twentieth century. - If the function is invoked with two arguments, the first a float representing a number of seconds past the epoch in gmt (such as those returned by time.time()) and the second a string naming a recognized timezone, a DateTime with a value of that gmt time will be returned, represented in the given timezone.
            import time
            t=time.time()

            now_east=DateTime(t,'US/Eastern')
            # Time t represented as US/Eastern

            now_west=DateTime(t,'US/Pacific')
            # Time t represented as US/Pacific

            # now_east == now_west
            # only their representations are different

            
- If the function is invoked with three or more numeric arguments, then the first is taken to be an integer year, the second is taken to be an integer month, and the third is taken to be an integer day. If the combination of values is not valid, then a DateError is raised. Two-digit years are assumed to be in the twentieth century. The fourth, fifth, and sixth arguments specify a time in hours, minutes, and seconds; hours and minutes should be positive integers and seconds is a positive floating point value, all of these default to zero if not given. An optional string may be given as the final argument to indicate timezone (the effect of this is as if you had taken the value of time.time() at that time on a machine in the specified timezone). In any case that a floating point number of seconds is given or derived, it's rounded to the nearest millisecond. If a string argument passed to the DateTime constructor cannot be parsed, it will raise DateTime.SyntaxError. Invalid date components will raise a DateError, while invalid time or timezone components will raise a DateTimeError. The module function Timezones() will return a list of the timezones recognized by the DateTime module. Recognition of timezone names is case-insensitive.""" #' d=t=s=None ac=len(args) millisecs = None if ac and args[0]==None: return elif ac==10: # Internal format called only by DateTime yr,mo,dy,hr,mn,sc,tz,t,d,s=args elif ac == 11: # Internal format that includes milliseconds. yr,mo,dy,hr,mn,sc,tz,t,d,s,millisecs=args elif not args: # Current time, to be displayed in local timezone t = time() lt = safelocaltime(t) tz = self.localZone(lt) ms = (t - math.floor(t)) s,d = _calcSD(t) yr,mo,dy,hr,mn,sc=lt[:6] sc=sc+ms elif ac==1: arg=args[0] if arg=='': raise self.SyntaxError, arg if type(arg) in [StringType,UnicodeType] and arg.lower() in self._tzinfo._zidx: # Current time, to be displayed in specified timezone t,tz=time(),self._tzinfo._zmap[arg.lower()] ms=(t-math.floor(t)) # Use integer arithmetic as much as possible. s,d = _calcSD(t) x = _calcDependentSecond(tz, t) yr,mo,dy,hr,mn,sc = _calcYMDHMS(x, ms) elif type(arg) in [StringType,UnicodeType]: # Date/time string if arg.find(' ')==-1 and arg[4]=='-': yr,mo,dy,hr,mn,sc,tz=self._parse_iso8601(arg) else: yr,mo,dy,hr,mn,sc,tz=self._parse(arg) if not self._validDate(yr,mo,dy): raise self.DateTimeError, 'Invalid date: %s' % arg if not self._validTime(hr,mn,int(sc)): raise self.DateTimeError, 'Invalid time: %s' % arg ms = sc - math.floor(sc) x = _calcDependentSecond2(yr,mo,dy,hr,mn,sc) if tz: try: tz=self._tzinfo._zmap[tz.lower()] except KeyError: if numericTimeZoneMatch(tz) is None: raise self.DateTimeError, \ 'Unknown time zone in date: %s' % arg else: tz = self._calcTimezoneName(x, ms) s,d,t,millisecs = _calcIndependentSecondEtc(tz, x, ms) else: # Seconds from epoch, gmt t = arg lt = safelocaltime(t) tz = self.localZone(lt) ms=(t-math.floor(t)) s,d = _calcSD(t) yr,mo,dy,hr,mn,sc=lt[:6] sc=sc+ms elif ac==2: if type(args[1])==StringType: # Seconds from epoch (gmt) and timezone t,tz=args ms = (t - math.floor(t)) tz=self._tzinfo._zmap[tz.lower()] # Use integer arithmetic as much as possible. s,d = _calcSD(t) x = _calcDependentSecond(tz, t) yr,mo,dy,hr,mn,sc = _calcYMDHMS(x, ms) else: # Year, julian expressed in local zone t = time() lt = safelocaltime(t) tz = self.localZone(lt) yr,jul=args yr = _correctYear(yr) d=(_julianday(yr,1,0)-jd1901)+jul x_float = d * 86400.0 x_floor = math.floor(x_float) ms = x_float - x_floor x = long(x_floor) yr,mo,dy,hr,mn,sc = _calcYMDHMS(x, ms) s,d,t,millisecs = _calcIndependentSecondEtc(tz, x, ms) else: # Explicit format yr,mo,dy=args[:3] hr,mn,sc,tz=0,0,0,0 yr = _correctYear(yr) if not self._validDate(yr,mo,dy): raise self.DateTimeError, 'Invalid date: %s' % (args,) args=args[3:] if args: hr,args=args[0],args[1:] if args: mn,args=args[0],args[1:] if args: sc,args=args[0],args[1:] if args: tz,args=args[0],args[1:] if args: raise self.DateTimeError,'Too many arguments' if not self._validTime(hr,mn,sc): raise self.DateTimeError, 'Invalid time: %s' % `args` leap = (yr % 4 == 0) and (yr % 100 != 0 or yr % 400 == 0) x = _calcDependentSecond2(yr,mo,dy,hr,mn,sc) ms = sc - math.floor(sc) if tz: try: tz=self._tzinfo._zmap[tz.lower()] except KeyError: if numericTimeZoneMatch(tz) is None: raise self.DateTimeError, \ 'Unknown time zone: %s' % tz else: # Get local time zone name tz = self._calcTimezoneName(x, ms) s,d,t,millisecs = _calcIndependentSecondEtc(tz, x, ms) if hr>12: self._pmhour=hr-12 self._pm='pm' else: self._pmhour=hr or 12 self._pm= (hr==12) and 'pm' or 'am' self._dayoffset=dx=int((_julianday(yr,mo,dy)+2L)%7) self._fmon,self._amon,self._pmon= \ self._months[mo],self._months_a[mo],self._months_p[mo] self._fday,self._aday,self._pday= \ self._days[dx],self._days_a[dx],self._days_p[dx] # Round to nearest millisecond in platform-independent way. You # cannot rely on C sprintf (Python '%') formatting to round # consistently; doing it ourselves ensures that all but truly # horrid C sprintf implementations will yield the same result # x-platform, provided the format asks for exactly 3 digits after # the decimal point. sc = round(sc, 3) if sc >= 60.0: # can happen if, e.g., orig sc was 59.9999 sc = 59.999 self._nearsec=math.floor(sc) self._year,self._month,self._day =yr,mo,dy self._hour,self._minute,self._second =hr,mn,sc self.time,self._d,self._t,self._tz =s,d,t,tz if millisecs is None: millisecs = long(math.floor(t * 1000.0)) self._millis = millisecs # self._millis is the time since the epoch # in long integer milliseconds. DateTimeError='DateTimeError' SyntaxError ='Invalid Date-Time String' DateError ='Invalid Date Components' int_pattern =re.compile(r'([0-9]+)') #AJ flt_pattern =re.compile(r':([0-9]+\.[0-9]+)') #AJ name_pattern =re.compile(r'([a-zA-Z]+)', re.I) #AJ space_chars =' \t\n' delimiters ='-/.:,+' _month_len =((0, 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31), (0, 31, 29, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31)) _until_month=((0, 0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334), (0, 0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335)) _months =['','January','February','March','April','May','June','July', 'August', 'September', 'October', 'November', 'December'] _months_a =['','Jan', 'Feb', 'Mar', 'Apr', 'May', 'Jun', 'Jul', 'Aug', 'Sep', 'Oct', 'Nov', 'Dec'] _months_p =['','Jan.', 'Feb.', 'Mar.', 'Apr.', 'May', 'June', 'July', 'Aug.', 'Sep.', 'Oct.', 'Nov.', 'Dec.'] _monthmap ={'january': 1, 'jan': 1, 'february': 2, 'feb': 2, 'march': 3, 'mar': 3, 'april': 4, 'apr': 4, 'may': 5, 'june': 6, 'jun': 6, 'july': 7, 'jul': 7, 'august': 8, 'aug': 8, 'september': 9, 'sep': 9, 'sept': 9, 'october': 10, 'oct': 10, 'november': 11, 'nov': 11, 'december': 12, 'dec': 12} _days =['Sunday','Monday','Tuesday','Wednesday', 'Thursday','Friday','Saturday'] _days_a =['Sun', 'Mon', 'Tue', 'Wed', 'Thu', 'Fri', 'Sat' ] _days_p =['Sun.', 'Mon.', 'Tue.', 'Wed.', 'Thu.', 'Fri.', 'Sat.'] _daymap ={'sunday': 1, 'sun': 1, 'monday': 2, 'mon': 2, 'tuesday': 3, 'tues': 3, 'tue': 3, 'wednesday': 4, 'wed': 4, 'thursday': 5, 'thurs': 5, 'thur': 5, 'thu': 5, 'friday': 6, 'fri': 6, 'saturday': 7, 'sat': 7} _localzone0 = _findLocalTimeZoneName(0) _localzone1 = _findLocalTimeZoneName(1) _multipleZones = (_localzone0 != _localzone1) # For backward compatibility only: _isDST = localtime(time())[8] _localzone = _isDST and _localzone1 or _localzone0 _tzinfo = _cache() def localZone(self, ltm=None): '''Returns the time zone on the given date. The time zone can change according to daylight savings.''' if not DateTime._multipleZones: return DateTime._localzone0 if ltm == None: ltm = localtime(time()) isDST = ltm[8] lz = isDST and DateTime._localzone1 or DateTime._localzone0 return lz def _calcTimezoneName(self, x, ms): # Derive the name of the local time zone at the given # timezone-dependent second. if not DateTime._multipleZones: return DateTime._localzone0 fsetAtEpoch = _tzoffset(DateTime._localzone0, 0.0) nearTime = x - fsetAtEpoch - long(EPOCH) + 86400L + ms # nearTime is within an hour of being correct. try: ltm = safelocaltime(nearTime) except: # We are beyond the range of Python's date support. # Hopefully we can assume that daylight savings schedules # repeat every 28 years. Calculate the name of the # time zone using a supported range of years. yr,mo,dy,hr,mn,sc = _calcYMDHMS(x, 0) yr = ((yr - 1970) % 28) + 1970 x = _calcDependentSecond2(yr,mo,dy,hr,mn,sc) nearTime = x - fsetAtEpoch - long(EPOCH) + 86400L + ms ltm = safelocaltime(nearTime) tz = self.localZone(ltm) return tz def _parse(self,st): # Parse date-time components from a string month=year=tz=tm=None spaces =self.space_chars intpat =self.int_pattern fltpat =self.flt_pattern wordpat =self.name_pattern delimiters =self.delimiters MonthNumbers =self._monthmap DayOfWeekNames=self._daymap ValidZones =self._tzinfo._zidx TimeModifiers =['am','pm'] # Find timezone first, since it should always be the last # element, and may contain a slash, confusing the parser. st= st.strip() sp=st.split() tz=sp[-1] if tz and (tz.lower() in ValidZones): st=' '.join(sp[:-1]) else: tz = None # Decide later, since the default time zone # could depend on the date. ints,dels=[],[] i,l=0,len(st) while i < l: while i < l and st[i] in spaces : i=i+1 if i < l and st[i] in delimiters: d=st[i] i=i+1 else: d='' while i < l and st[i] in spaces : i=i+1 # The float pattern needs to look back 1 character, because it # actually looks for a preceding colon like ':33.33'. This is # needed to avoid accidentally matching the date part of a # dot-separated date string such as '1999.12.31'. if i > 0: b=i-1 else: b=i ts_results = fltpat.match(st, b) if ts_results: s=ts_results.group(1) i=i+len(s) ints.append(float(s)) continue #AJ ts_results = intpat.match(st, i) if ts_results: s=ts_results.group(0) ls=len(s) i=i+ls if (ls==4 and d and d in '+-' and (len(ints) + (not not month) >= 3)): tz='%s%s' % (d,s) else: v=int(s) ints.append(v) continue ts_results = wordpat.match(st, i) if ts_results: o,s=ts_results.group(0),ts_results.group(0).lower() i=i+len(s) if i < l and st[i]=='.': i=i+1 # Check for month name: if MonthNumbers.has_key(s): v=MonthNumbers[s] if month is None: month=v else: raise self.SyntaxError, st continue # Check for time modifier: if s in TimeModifiers: if tm is None: tm=s else: raise self.SyntaxError, st continue # Check for and skip day of week: if DayOfWeekNames.has_key(s): continue raise self.SyntaxError, st day=None if ints[-1] > 60 and d not in ['.',':'] and len(ints) > 2: year=ints[-1] del ints[-1] if month: day=ints[0] del ints[:1] else: month=ints[0] day=ints[1] del ints[:2] elif month: if len(ints) > 1: if ints[0] > 31: year=ints[0] day=ints[1] else: year=ints[1] day=ints[0] del ints[:2] elif len(ints) > 2: if ints[0] > 31: year=ints[0] if ints[1] > 12: day=ints[1] month=ints[2] else: day=ints[2] month=ints[1] if ints[1] > 31: year=ints[1] if ints[0] > 12 and ints[2] <= 12: day=ints[0] month=ints[2] elif ints[2] > 12 and ints[0] <= 12: day=ints[2] month=ints[0] elif ints[2] > 31: year=ints[2] if ints[0] > 12: day=ints[0] month=ints[1] else: day=ints[1] month=ints[0] elif ints[0] <= 12: month=ints[0] day=ints[1] year=ints[2] del ints[:3] if day is None: # Use today's date. year,month,day = localtime(time())[:3] year = _correctYear(year) if year < 1000: raise self.SyntaxError, st leap = year%4==0 and (year%100!=0 or year%400==0) try: if not day or day > self._month_len[leap][month]: raise self.DateError, st except IndexError: raise self.DateError, st tod=0 if ints: i=ints[0] # Modify hour to reflect am/pm if tm and (tm=='pm') and i<12: i=i+12 if tm and (tm=='am') and i==12: i=0 if i > 24: raise self.DateTimeError, st tod = tod + int(i) * 3600 del ints[0] if ints: i=ints[0] if i > 60: raise self.DateTimeError, st tod = tod + int(i) * 60 del ints[0] if ints: i=ints[0] if i > 60: raise self.DateTimeError, st tod = tod + i del ints[0] if ints: raise self.SyntaxError,st tod_int = int(math.floor(tod)) ms = tod - tod_int hr,mn,sc = _calcHMS(tod_int, ms) if not tz: # Figure out what time zone it is in the local area # on the given date. x = _calcDependentSecond2(year,month,day,hr,mn,sc) tz = self._calcTimezoneName(x, ms) return year,month,day,hr,mn,sc,tz # Internal methods def __getinitargs__(self): return (None,) def _validDate(self,y,m,d): if m<1 or m>12 or y<0 or d<1 or d>31: return 0 return d<=self._month_len[(y%4==0 and (y%100!=0 or y%400==0))][m] def _validTime(self,h,m,s): return h>=0 and h<=23 and m>=0 and m<=59 and s>=0 and s < 60 def __getattr__(self, name): if '%' in name: return strftimeFormatter(self, name) raise AttributeError, name # Conversion and comparison methods def timeTime(self): """Return the date/time as a floating-point number in UTC, in the format used by the python time module. Note that it is possible to create date/time values with DateTime that have no meaningful value to the time module.""" return self._t def toZone(self, z): """Return a DateTime with the value as the current object, represented in the indicated timezone.""" t,tz=self._t,self._tzinfo._zmap[z.lower()] millis = self.millis() #if (t>0 and ((t/86400.0) < 24837)): try: # Try to use time module for speed. yr,mo,dy,hr,mn,sc=safegmtime(t+_tzoffset(tz, t))[:6] sc=self._second return self.__class__(yr,mo,dy,hr,mn,sc,tz,t, self._d,self.time,millis) except: # gmtime can't perform the calculation in the given range. # Calculate the difference between the two time zones. tzdiff = _tzoffset(tz, t) - _tzoffset(self._tz, t) if tzdiff == 0: return self sc = self._second ms = sc - math.floor(sc) x = _calcDependentSecond2(self._year, self._month, self._day, self._hour, self._minute, sc) x_new = x + tzdiff yr,mo,dy,hr,mn,sc = _calcYMDHMS(x_new, ms) return self.__class__(yr,mo,dy,hr,mn,sc,tz,t, self._d,self.time,millis) def isFuture(self): """Return true if this object represents a date/time later than the time of the call""" return (self._t > time()) def isPast(self): """Return true if this object represents a date/time earlier than the time of the call""" return (self._t < time()) def isCurrentYear(self): """Return true if this object represents a date/time that falls within the current year, in the context of this object\'s timezone representation""" t=time() return safegmtime(t+_tzoffset(self._tz, t))[0]==self._year def isCurrentMonth(self): """Return true if this object represents a date/time that falls within the current month, in the context of this object\'s timezone representation""" t=time() gmt=safegmtime(t+_tzoffset(self._tz, t)) return gmt[0]==self._year and gmt[1]==self._month def isCurrentDay(self): """Return true if this object represents a date/time that falls within the current day, in the context of this object\'s timezone representation""" t=time() gmt=safegmtime(t+_tzoffset(self._tz, t)) return gmt[0]==self._year and gmt[1]==self._month and gmt[2]==self._day def isCurrentHour(self): """Return true if this object represents a date/time that falls within the current hour, in the context of this object\'s timezone representation""" t=time() gmt=safegmtime(t+_tzoffset(self._tz, t)) return (gmt[0]==self._year and gmt[1]==self._month and gmt[2]==self._day and gmt[3]==self._hour) def isCurrentMinute(self): """Return true if this object represents a date/time that falls within the current minute, in the context of this object\'s timezone representation""" t=time() gmt=safegmtime(t+_tzoffset(self._tz, t)) return (gmt[0]==self._year and gmt[1]==self._month and gmt[2]==self._day and gmt[3]==self._hour and gmt[4]==self._minute) def earliestTime(self): """Return a new DateTime object that represents the earliest possible time (in whole seconds) that still falls within the current object\'s day, in the object\'s timezone context""" return self.__class__(self._year,self._month,self._day,0,0,0,self._tz) def latestTime(self): """Return a new DateTime object that represents the latest possible time (in whole seconds) that still falls within the current object\'s day, in the object\'s timezone context""" return self.__class__(self._year,self._month,self._day, 23,59,59,self._tz) def greaterThan(self,t): """Compare this DateTime object to another DateTime object OR a floating point number such as that which is returned by the python time module. Returns true if the object represents a date/time greater than the specified DateTime or time module style time. Revised to give more correct results through comparison of long integer milliseconds. """ # Optimized for sorting speed try: return (self._millis > t._millis) except AttributeError: try: self._millis except AttributeError: self._upgrade_old() return (self._t > t) __gt__ = greaterThan def greaterThanEqualTo(self,t): """Compare this DateTime object to another DateTime object OR a floating point number such as that which is returned by the python time module. Returns true if the object represents a date/time greater than or equal to the specified DateTime or time module style time. Revised to give more correct results through comparison of long integer milliseconds. """ # Optimized for sorting speed try: return (self._millis >= t._millis) except AttributeError: try: self._millis except AttributeError: self._upgrade_old() return (self._t >= t) __ge__ = greaterThanEqualTo def equalTo(self,t): """Compare this DateTime object to another DateTime object OR a floating point number such as that which is returned by the python time module. Returns true if the object represents a date/time equal to the specified DateTime or time module style time. Revised to give more correct results through comparison of long integer milliseconds. """ # Optimized for sorting speed try: return (self._millis == t._millis) except AttributeError: try: self._millis except AttributeError: self._upgrade_old() return (self._t == t) __eq__ = equalTo def notEqualTo(self,t): """Compare this DateTime object to another DateTime object OR a floating point number such as that which is returned by the python time module. Returns true if the object represents a date/time not equal to the specified DateTime or time module style time. Revised to give more correct results through comparison of long integer milliseconds. """ # Optimized for sorting speed try: return (self._millis != t._millis) except AttributeError: try: self._millis except AttributeError: self._upgrade_old() return (self._t != t) __ne__ = notEqualTo def lessThan(self,t): """Compare this DateTime object to another DateTime object OR a floating point number such as that which is returned by the python time module. Returns true if the object represents a date/time less than the specified DateTime or time module style time. Revised to give more correct results through comparison of long integer milliseconds. """ # Optimized for sorting speed try: return (self._millis < t._millis) except AttributeError: try: self._millis except AttributeError: self._upgrade_old() return (self._t < t) __lt__ = lessThan def lessThanEqualTo(self,t): """Compare this DateTime object to another DateTime object OR a floating point number such as that which is returned by the python time module. Returns true if the object represents a date/time less than or equal to the specified DateTime or time module style time. Revised to give more correct results through comparison of long integer milliseconds. """ # Optimized for sorting speed try: return (self._millis <= t._millis) except AttributeError: try: self._millis except AttributeError: self._upgrade_old() return (self._t <= t) __le__ = lessThanEqualTo def isLeapYear(self): """Return true if the current year (in the context of the object\'s timezone) is a leap year""" return self._year%4==0 and (self._year%100!=0 or self._year%400==0) def dayOfYear(self): """Return the day of the year, in context of the timezone representation of the object""" d=int(self._d+(_tzoffset(self._tz, self._t)/86400.0)) return int((d+jd1901)-_julianday(self._year,1,0)) # Component access def parts(self): """Return a tuple containing the calendar year, month, day, hour, minute second and timezone of the object""" return self._year, self._month, self._day, self._hour, \ self._minute, self._second, self._tz def timezone(self): """Return the timezone in which the object is represented.""" return self._tz def year(self): """Return the calendar year of the object""" return self._year def month(self): """Return the month of the object as an integer""" return self._month def Month(self): """Return the full month name""" return self._fmon def aMonth(self): """Return the abreviated month name.""" return self._amon def Mon(self): """Compatibility: see aMonth""" return self._amon def pMonth(self): """Return the abreviated (with period) month name.""" return self._pmon def Mon_(self): """Compatibility: see pMonth""" return self._pmon def day(self): """Return the integer day""" return self._day def Day(self): """Return the full name of the day of the week""" return self._fday def DayOfWeek(self): """Compatibility: see Day""" return self._fday def aDay(self): """Return the abreviated name of the day of the week""" return self._aday def pDay(self): """Return the abreviated (with period) name of the day of the week""" return self._pday def Day_(self): """Compatibility: see pDay""" return self._pday def dow(self): """Return the integer day of the week, where sunday is 0""" return self._dayoffset def dow_1(self): """Return the integer day of the week, where sunday is 1""" return self._dayoffset+1 def h_12(self): """Return the 12-hour clock representation of the hour""" return self._pmhour def h_24(self): """Return the 24-hour clock representation of the hour""" return self._hour def ampm(self): """Return the appropriate time modifier (am or pm)""" return self._pm def hour(self): """Return the 24-hour clock representation of the hour""" return self._hour def minute(self): """Return the minute""" return self._minute def second(self): """Return the second""" return self._second def millis(self): """Return the millisecond since the epoch in GMT.""" try: return self._millis except AttributeError: return self._upgrade_old() def _upgrade_old(self): """Upgrades a previously pickled DateTime object.""" millis = long(math.floor(self._t * 1000.0)) self._millis = millis return millis def strftime(self, format): # Format the date/time using the *current timezone representation*. diff = _tzoffset(self._tz, self._t) format = re.sub('(^\|[^%])%z', '\\1%+05d' % (diff / 36), format) return strftime(format, safegmtime(self.timeTime() + diff)) # General formats from previous DateTime def Date(self): """Return the date string for the object.""" return "%s/%2.2d/%2.2d" % (self._year, self._month, self._day) def Time(self): """Return the time string for an object to the nearest second.""" return '%2.2d:%2.2d:%2.2d' % (self._hour,self._minute,self._nearsec) def TimeMinutes(self): """Return the time string for an object not showing seconds.""" return '%2.2d:%2.2d' % (self._hour,self._minute) def AMPM(self): """Return the time string for an object to the nearest second.""" return '%2.2d:%2.2d:%2.2d %s' % ( self._pmhour,self._minute,self._nearsec,self._pm) def AMPMMinutes(self): """Return the time string for an object not showing seconds.""" return '%2.2d:%2.2d %s' % (self._pmhour,self._minute,self._pm) def PreciseTime(self): """Return the time string for the object.""" return '%2.2d:%2.2d:%06.3f' % (self._hour,self._minute,self._second) def PreciseAMPM(self): """Return the time string for the object.""" return '%2.2d:%2.2d:%06.3f %s' % ( self._pmhour,self._minute,self._second,self._pm) def yy(self): """Return calendar year as a 2 digit string""" return str(self._year)[-2:] def mm(self): """Return month as a 2 digit string""" return '%02d' % self._month def dd(self): """Return day as a 2 digit string""" return '%02d' % self._day def rfc822(self): """Return the date in RFC 822 format""" if self._tz == self._localzone0: #Use local standard time tzoffset = _tzoffset2rfc822zone(timezone) elif self._tz == self._localzone1: # Use local daylight saving time tzoffset = _tzoffset2rfc822zone(altzone) else: tzoffset = '-0000' # unknown time zone offset return '%s, %2.2d %s %d %2.2d:%2.2d:%2.2d %s' % ( self._aday,self._day,self._amon,self._year, self._hour,self._minute,self._nearsec,tzoffset) # New formats def fCommon(self): """Return a string representing the object\'s value in the format: March 1, 1997 1:45 pm""" return '%s %s, %4.4d %s:%2.2d %s' % ( self._fmon,self._day,self._year,self._pmhour, self._minute,self._pm) def fCommonZ(self): """Return a string representing the object\'s value in the format: March 1, 1997 1:45 pm US/Eastern""" return '%s %s, %4.4d %d:%2.2d %s %s' % ( self._fmon,self._day,self._year,self._pmhour, self._minute,self._pm,self._tz) def aCommon(self): """Return a string representing the object\'s value in the format: Mar 1, 1997 1:45 pm""" return '%s %s, %4.4d %s:%2.2d %s' % ( self._amon,self._day,self._year,self._pmhour, self._minute,self._pm) def aCommonZ(self): """Return a string representing the object\'s value in the format: Mar 1, 1997 1:45 pm US/Eastern""" return '%s %s, %4.4d %d:%2.2d %s %s' % ( self._amon,self._day,self._year,self._pmhour, self._minute,self._pm,self._tz) def pCommon(self): """Return a string representing the object\'s value in the format: Mar. 1, 1997 1:45 pm""" return '%s %s, %4.4d %s:%2.2d %s' % ( self._pmon,self._day,self._year,self._pmhour, self._minute,self._pm) def pCommonZ(self): """Return a string representing the object\'s value in the format: Mar. 1, 1997 1:45 pm US/Eastern""" return '%s %s, %4.4d %d:%2.2d %s %s' % ( self._pmon,self._day,self._year,self._pmhour, self._minute,self._pm,self._tz) def ISO(self): """Return the object in ISO standard format Dates are output as: YYYY-MM-DD HH:MM:SS """ return "%.4d-%.2d-%.2d %.2d:%.2d:%.2d" % ( self._year, self._month, self._day, self._hour, self._minute, self._second) def HTML4(self): """Return the object in the format used in the HTML4.0 specification, one of the standard forms in ISO8601. See http://www.w3.org/TR/NOTE-datetime Dates are output as: YYYY-MM-DDTHH:MM:SSZ T, Z are literal characters. The time is in UTC. """ newdate = self.toZone('UTC') return "%0.4d-%0.2d-%0.2dT%0.2d:%0.2d:%0.2dZ" % ( newdate._year, newdate._month, newdate._day, newdate._hour, newdate._minute, newdate._second) def __add__(self,other): """A DateTime may be added to a number and a number may be added to a DateTime; two DateTimes cannot be added.""" if hasattr(other,'_t'): raise self.DateTimeError,'Cannot add two DateTimes' o=float(other) tz = self._tz t = (self._t + (o*86400.0)) d = (self._d + o) s = d - math.floor(d) ms = t - math.floor(t) x = _calcDependentSecond(tz, t) yr,mo,dy,hr,mn,sc = _calcYMDHMS(x, ms) return self.__class__(yr,mo,dy,hr,mn,sc,self._tz,t,d,s) __radd__=__add__ def __sub__(self,other): """Either a DateTime or a number may be subtracted from a DateTime, however, a DateTime may not be subtracted from a number.""" if hasattr(other, '_d'): if 0: # This logic seems right but is incorrect. my_t = self._t + _tzoffset(self._tz, self._t) ob_t = other._t + _tzoffset(other._tz, other._t) return (my_t - ob_t) / 86400.0 return self._d - other._d else: return self.__add__(-(other)) def __repr__(self): """Convert a DateTime to a string that looks like a Python expression.""" return '%s(\'%s\')' % (self.__class__.__name__,str(self)) def __str__(self): """Convert a DateTime to a string.""" y,m,d =self._year,self._month,self._day h,mn,s,t=self._hour,self._minute,self._second,self._tz if h == mn == s == 0: # hh:mm:ss all zero -- suppress the time. return '%4.4d/%2.2d/%2.2d' % (y, m, d) elif s == int(s): # A whole number of seconds -- suppress milliseconds. return '%4.4d/%2.2d/%2.2d %2.2d:%2.2d:%2.2d %s' % ( y, m, d, h, mn, s, t) else: # s is already rounded to the nearest millisecond, and # it's not a whole number of seconds. Be sure to print # 2 digits before the decimal point. return '%4.4d/%2.2d/%2.2d %2.2d:%2.2d:%06.3f %s' % ( y, m, d, h, mn, s, t) def __cmp__(self,obj): """Compare a DateTime with another DateTime object, or a float such as those returned by time.time(). NOTE: __cmp__ support is provided for backward compatibility only, and mixing DateTimes with ExtensionClasses could cause __cmp__ to break. You should use the methods lessThan, greaterThan, lessThanEqualTo, greaterThanEqualTo, equalTo and notEqualTo to avoid potential problems later!!""" # Optimized for sorting speed. try: return cmp(self._millis, obj._millis) except AttributeError: try: self._millis except AttributeError: self._upgrade_old() return cmp(self._t,obj) def __hash__(self): """Compute a hash value for a DateTime""" return int(((self._year%100*12+self._month)*31+ self._day+self.time)*100) def __int__(self): """Convert to an integer number of seconds since the epoch (gmt)""" return int(self.millis() / 1000) def __long__(self): """Convert to a long-int number of seconds since the epoch (gmt)""" return long(self.millis() / 1000) def __float__(self): """Convert to floating-point number of seconds since the epoch (gmt)""" return float(self._t) def _parse_iso8601(self,s): try: return self.__parse_iso8601(s) except IndexError: raise self.DateError,'Not an ISO 8601 compliant date string: "%s"' % s def __parse_iso8601(self,s): """ parse an ISO 8601 compliant date """ year=0 month=day=1 hour=minute=seconds=hour_off=min_off=0 datereg = re.compile('([0-9]{4})(-([0-9][0-9]))?(-([0-9][0-9]))?') timereg = re.compile('([0-9]{2})(:([0-9][0-9]))?(:([0-9][0-9]))?(\.[0-9]{1,20})?') # Date part fields = datereg.split(s.strip()) if fields[1]: year = int(fields[1]) if fields[3]: month = int(fields[3]) if fields[5]: day = int(fields[5]) if s.find('T')>-1: fields = timereg.split(s[s.find('T')+1:]) if fields[1]: hour = int(fields[1]) if fields[3]: minute = int(fields[3]) if fields[5]: seconds = int(fields[5]) if fields[6]: seconds = seconds+float(fields[6]) if s.find('Z')>-1: pass if s[-3]==':' and s[-6] in ['+','-']: hour_off = int(s[-6:-3]) min_off = int(s[-2:]) return year,month,day,hour,minute,seconds,'GMT%+03d%02d' % (hour_off,min_off) def JulianDay(self): """ Return the Julian day according to http://www.tondering.dk/claus/cal/node3.html#sec-calcjd """ a = (14 - self._month)/12 #integer division, discard remainder y = self._year + 4800 - a m = self._month + (12*a) - 3 return self._day + (153*m+2)/5 + 365*y + y/4 - y/100 + y/400 - 32045 def week(self): """ Return the week number according to ISO see http://www.tondering.dk/claus/cal/node6.html#SECTION00670000000000000000 """ J = self.JulianDay() d4 = (J + 31741 - (J % 7)) % 146097 % 36524 % 1461 L = d4/1460 d1 = (( d4 - L) % 365) + L return d1/7 + 1 class strftimeFormatter: def __init__(self, dt, format): self._dt=dt self._f=format def __call__(self): return self._dt.strftime(self._f) # Module methods def Timezones(): """Return the list of recognized timezone names""" return _cache._zlst