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	"""
	Matplotlib provides sophisticated date plotting capabilities, standing on the
	shoulders of python :mod:`datetime` and the add-on module dateutil_.

	By default, Matplotlib uses the units machinery described in
	`~matplotlib.units` to convert `datetime.datetime`, and `numpy.datetime64`
	objects when plotted on an x- or y-axis. The user does not
	need to do anything for dates to be formatted, but dates often have strict
	formatting needs, so this module provides many tick locators and formatters.
	A basic example using `numpy.datetime64` is::

	import numpy as np

	times = np.arange(np.datetime64('2001-01-02'),
	np.datetime64('2002-02-03'), np.timedelta64(75, 'm'))
	y = np.random.randn(len(times))

	fig, ax = plt.subplots()
	ax.plot(times, y)

	.. seealso::

	- :doc:`/gallery/text_labels_and_annotations/date`
	- :doc:`/gallery/ticks/date_concise_formatter`
	- :doc:`/gallery/ticks/date_demo_convert`

	.. _date-format:

	Matplotlib date format
	----------------------

	Matplotlib represents dates using floating point numbers specifying the number
	of days since a default epoch of 1970-01-01 UTC; for example,
	1970-01-01, 06:00 is the floating point number 0.25. The formatters and
	locators require the use of `datetime.datetime` objects, so only dates between
	year 0001 and 9999 can be represented. Microsecond precision
	is achievable for (approximately) 70 years on either side of the epoch, and
	20 microseconds for the rest of the allowable range of dates (year 0001 to
	9999). The epoch can be changed at import time via `.dates.set_epoch` or
	:rc:`date.epoch` to other dates if necessary; see
	:doc:`/gallery/ticks/date_precision_and_epochs` for a discussion.

	.. note::

	Before Matplotlib 3.3, the epoch was 0000-12-31 which lost modern
	microsecond precision and also made the default axis limit of 0 an invalid
	datetime. In 3.3 the epoch was changed as above. To convert old
	ordinal floats to the new epoch, users can do::

	new_ordinal = old_ordinal + mdates.date2num(np.datetime64('0000-12-31'))


	There are a number of helper functions to convert between :mod:`datetime`
	objects and Matplotlib dates:

	.. currentmodule:: matplotlib.dates

	.. autosummary::
	:nosignatures:

	datestr2num
	date2num
	num2date
	num2timedelta
	drange
	set_epoch
	get_epoch

	.. note::

	Like Python's `datetime.datetime`, Matplotlib uses the Gregorian calendar
	for all conversions between dates and floating point numbers. This practice
	is not universal, and calendar differences can cause confusing
	differences between what Python and Matplotlib give as the number of days
	since 0001-01-01 and what other software and databases yield. For
	example, the US Naval Observatory uses a calendar that switches
	from Julian to Gregorian in October, 1582. Hence, using their
	calculator, the number of days between 0001-01-01 and 2006-04-01 is
	732403, whereas using the Gregorian calendar via the datetime
	module we find::

	In [1]: date(2006, 4, 1).toordinal() - date(1, 1, 1).toordinal()
	Out[1]: 732401

	All the Matplotlib date converters, locators and formatters are timezone aware.
	If no explicit timezone is provided, :rc:`timezone` is assumed, provided as a
	string. If you want to use a different timezone, pass the tz keyword
	argument of `num2date` to any date tick locators or formatters you create. This
	can be either a `datetime.tzinfo` instance or a string with the timezone name
	that can be parsed by `~dateutil.tz.gettz`.

	A wide range of specific and general purpose date tick locators and
	formatters are provided in this module. See
	:mod:`matplotlib.ticker` for general information on tick locators
	and formatters. These are described below.

	The dateutil_ module provides additional code to handle date ticking, making it
	easy to place ticks on any kinds of dates. See examples below.

	.. _dateutil: https://dateutil.readthedocs.io

	.. _date-locators:

	Date tick locators
	------------------

	Most of the date tick locators can locate single or multiple ticks. For example::

	# import constants for the days of the week
	from matplotlib.dates import MO, TU, WE, TH, FR, SA, SU

	# tick on Mondays every week
	loc = WeekdayLocator(byweekday=MO, tz=tz)

	# tick on Mondays and Saturdays
	loc = WeekdayLocator(byweekday=(MO, SA))

	In addition, most of the constructors take an interval argument::

	# tick on Mondays every second week
	loc = WeekdayLocator(byweekday=MO, interval=2)

	The rrule locator allows completely general date ticking::

	# tick every 5th easter
	rule = rrulewrapper(YEARLY, byeaster=1, interval=5)
	loc = RRuleLocator(rule)

	The available date tick locators are:

	* `MicrosecondLocator`: Locate microseconds.

	* `SecondLocator`: Locate seconds.

	* `MinuteLocator`: Locate minutes.

	* `HourLocator`: Locate hours.

	* `DayLocator`: Locate specified days of the month.

	* `WeekdayLocator`: Locate days of the week, e.g., MO, TU.

	* `MonthLocator`: Locate months, e.g., 7 for July.

	* `YearLocator`: Locate years that are multiples of base.

	* `RRuleLocator`: Locate using a `rrulewrapper`.
	`rrulewrapper` is a simple wrapper around dateutil_'s `dateutil.rrule`
	which allow almost arbitrary date tick specifications.
	See :doc:`rrule example </gallery/ticks/date_demo_rrule>`.

	* `AutoDateLocator`: On autoscale, this class picks the best `DateLocator`
	(e.g., `RRuleLocator`) to set the view limits and the tick locations. If
	called with ``interval_multiples=True`` it will make ticks line up with
	sensible multiples of the tick intervals. For example, if the interval is
	4 hours, it will pick hours 0, 4, 8, etc. as ticks. This behaviour is not
	guaranteed by default.

	.. _date-formatters:

	Date formatters
	---------------

	The available date formatters are:

	* `AutoDateFormatter`: attempts to figure out the best format to use. This is
	most useful when used with the `AutoDateLocator`.

	* `ConciseDateFormatter`: also attempts to figure out the best format to use,
	and to make the format as compact as possible while still having complete
	date information. This is most useful when used with the `AutoDateLocator`.

	* `DateFormatter`: use `~datetime.datetime.strftime` format strings.
	"""

	import datetime
	import functools
	import logging
	import re

	from dateutil.rrule import (rrule, MO, TU, WE, TH, FR, SA, SU, YEARLY,
	MONTHLY, WEEKLY, DAILY, HOURLY, MINUTELY,
	SECONDLY)
	from dateutil.relativedelta import relativedelta
	import dateutil.parser
	import dateutil.tz
	import numpy as np

	import matplotlib as mpl
	from matplotlib import _api, cbook, ticker, units

	__all__ = ('datestr2num', 'date2num', 'num2date', 'num2timedelta', 'drange',
	'set_epoch', 'get_epoch', 'DateFormatter', 'ConciseDateFormatter',
	'AutoDateFormatter', 'DateLocator', 'RRuleLocator',
	'AutoDateLocator', 'YearLocator', 'MonthLocator', 'WeekdayLocator',
	'DayLocator', 'HourLocator', 'MinuteLocator',
	'SecondLocator', 'MicrosecondLocator',
	'rrule', 'MO', 'TU', 'WE', 'TH', 'FR', 'SA', 'SU',
	'YEARLY', 'MONTHLY', 'WEEKLY', 'DAILY',
	'HOURLY', 'MINUTELY', 'SECONDLY', 'MICROSECONDLY', 'relativedelta',
	'DateConverter', 'ConciseDateConverter', 'rrulewrapper')


	_log = logging.getLogger(__name__)
	UTC = datetime.timezone.utc


	def _get_tzinfo(tz=None):
	"""
	Generate `~datetime.tzinfo` from a string or return `~datetime.tzinfo`.
	If None, retrieve the preferred timezone from the rcParams dictionary.
	"""
	tz = mpl._val_or_rc(tz, 'timezone')
	if tz == 'UTC':
	return UTC
	if isinstance(tz, str):
	tzinfo = dateutil.tz.gettz(tz)
	if tzinfo is None:
	raise ValueError(f"{tz} is not a valid timezone as parsed by"
	" dateutil.tz.gettz.")
	return tzinfo
	if isinstance(tz, datetime.tzinfo):
	return tz
	raise TypeError(f"tz must be string or tzinfo subclass, not {tz!r}.")


	# Time-related constants.
	EPOCH_OFFSET = float(datetime.datetime(1970, 1, 1).toordinal())
	# EPOCH_OFFSET is not used by matplotlib
	MICROSECONDLY = SECONDLY + 1
	HOURS_PER_DAY = 24.
	MIN_PER_HOUR = 60.
	SEC_PER_MIN = 60.
	MONTHS_PER_YEAR = 12.

	DAYS_PER_WEEK = 7.
	DAYS_PER_MONTH = 30.
	DAYS_PER_YEAR = 365.0

	MINUTES_PER_DAY = MIN_PER_HOUR * HOURS_PER_DAY

	SEC_PER_HOUR = SEC_PER_MIN * MIN_PER_HOUR
	SEC_PER_DAY = SEC_PER_HOUR * HOURS_PER_DAY
	SEC_PER_WEEK = SEC_PER_DAY * DAYS_PER_WEEK

	MUSECONDS_PER_DAY = 1e6 * SEC_PER_DAY

	MONDAY, TUESDAY, WEDNESDAY, THURSDAY, FRIDAY, SATURDAY, SUNDAY = (
	MO, TU, WE, TH, FR, SA, SU)
	WEEKDAYS = (MONDAY, TUESDAY, WEDNESDAY, THURSDAY, FRIDAY, SATURDAY, SUNDAY)

	# default epoch: passed to np.datetime64...
	_epoch = None


	def _reset_epoch_test_example():
	"""
	Reset the Matplotlib date epoch so it can be set again.

	Only for use in tests and examples.
	"""
	global _epoch
	_epoch = None


	def set_epoch(epoch):
	"""
	Set the epoch (origin for dates) for datetime calculations.

	The default epoch is :rc:`date.epoch`.

	If microsecond accuracy is desired, the date being plotted needs to be
	within approximately 70 years of the epoch. Matplotlib internally
	represents dates as days since the epoch, so floating point dynamic
	range needs to be within a factor of 2^52.

	`~.dates.set_epoch` must be called before any dates are converted
	(i.e. near the import section) or a RuntimeError will be raised.

	See also :doc:`/gallery/ticks/date_precision_and_epochs`.

	Parameters
	----------
	epoch : str
	valid UTC date parsable by `numpy.datetime64` (do not include
	timezone).

	"""
	global _epoch
	if _epoch is not None:
	raise RuntimeError('set_epoch must be called before dates plotted.')
	_epoch = epoch


	def get_epoch():
	"""
	Get the epoch used by `.dates`.

	Returns
	-------
	epoch : str
	String for the epoch (parsable by `numpy.datetime64`).
	"""
	global _epoch

	_epoch = mpl._val_or_rc(_epoch, 'date.epoch')
	return _epoch


	def _dt64_to_ordinalf(d):
	"""
	Convert `numpy.datetime64` or an `numpy.ndarray` of those types to
	Gregorian date as UTC float relative to the epoch (see `.get_epoch`).
	Roundoff is float64 precision. Practically: microseconds for dates
	between 290301 BC, 294241 AD, milliseconds for larger dates
	(see `numpy.datetime64`).
	"""

	# the "extra" ensures that we at least allow the dynamic range out to
	# seconds. That should get out to +/-2e11 years.
	dseconds = d.astype('datetime64[s]')
	extra = (d - dseconds).astype('timedelta64[ns]')
	t0 = np.datetime64(get_epoch(), 's')
	dt = (dseconds - t0).astype(np.float64)
	dt += extra.astype(np.float64) / 1.0e9
	dt = dt / SEC_PER_DAY

	NaT_int = np.datetime64('NaT').astype(np.int64)
	d_int = d.astype(np.int64)
	dt[d_int == NaT_int] = np.nan
	return dt


	def _from_ordinalf(x, tz=None):
	"""
	Convert Gregorian float of the date, preserving hours, minutes,
	seconds and microseconds. Return value is a `.datetime`.

	The input date x is a float in ordinal days at UTC, and the output will
	be the specified `.datetime` object corresponding to that time in
	timezone tz, or if tz is ``None``, in the timezone specified in
	:rc:`timezone`.
	"""

	tz = _get_tzinfo(tz)

	dt = (np.datetime64(get_epoch()) +
	np.timedelta64(int(np.round(x * MUSECONDS_PER_DAY)), 'us'))
	if dt < np.datetime64('0001-01-01') or dt >= np.datetime64('10000-01-01'):
	raise ValueError(f'Date ordinal {x} converts to {dt} (using '
	f'epoch {get_epoch()}), but Matplotlib dates must be '
	'between year 0001 and 9999.')
	# convert from datetime64 to datetime:
	dt = dt.tolist()

	# datetime64 is always UTC:
	dt = dt.replace(tzinfo=dateutil.tz.gettz('UTC'))
	# but maybe we are working in a different timezone so move.
	dt = dt.astimezone(tz)
	# fix round off errors
	if np.abs(x) > 70 * 365:
	# if x is big, round off to nearest twenty microseconds.
	# This avoids floating point roundoff error
	ms = round(dt.microsecond / 20) * 20
	if ms == 1000000:
	dt = dt.replace(microsecond=0) + datetime.timedelta(seconds=1)
	else:
	dt = dt.replace(microsecond=ms)

	return dt


	# a version of _from_ordinalf that can operate on numpy arrays
	_from_ordinalf_np_vectorized = np.vectorize(_from_ordinalf, otypes="O")
	# a version of dateutil.parser.parse that can operate on numpy arrays
	_dateutil_parser_parse_np_vectorized = np.vectorize(dateutil.parser.parse)


	def datestr2num(d, default=None):
	"""
	Convert a date string to a datenum using `dateutil.parser.parse`.

	Parameters
	----------
	d : str or sequence of str
	The dates to convert.

	default : datetime.datetime, optional
	The default date to use when fields are missing in d.
	"""
	if isinstance(d, str):
	dt = dateutil.parser.parse(d, default=default)
	return date2num(dt)
	else:
	if default is not None:
	d = [date2num(dateutil.parser.parse(s, default=default))
	for s in d]
	return np.asarray(d)
	d = np.asarray(d)
	if not d.size:
	return d
	return date2num(_dateutil_parser_parse_np_vectorized(d))


	def date2num(d):
	"""
	Convert datetime objects to Matplotlib dates.

	Parameters
	----------
	d : `datetime.datetime` or `numpy.datetime64` or sequences of these

	Returns
	-------
	float or sequence of floats
	Number of days since the epoch. See `.get_epoch` for the
	epoch, which can be changed by :rc:`date.epoch` or `.set_epoch`. If
	the epoch is "1970-01-01T00:00:00" (default) then noon Jan 1 1970
	("1970-01-01T12:00:00") returns 0.5.

	Notes
	-----
	The Gregorian calendar is assumed; this is not universal practice.
	For details see the module docstring.
	"""
	# Unpack in case of e.g. Pandas or xarray object
	d = cbook._unpack_to_numpy(d)

	# make an iterable, but save state to unpack later:
	iterable = np.iterable(d)
	if not iterable:
	d = [d]

	masked = np.ma.is_masked(d)
	mask = np.ma.getmask(d)
	d = np.asarray(d)

	# convert to datetime64 arrays, if not already:
	if not np.issubdtype(d.dtype, np.datetime64):
	# datetime arrays
	if not d.size:
	# deals with an empty array...
	return d
	tzi = getattr(d[0], 'tzinfo', None)
	if tzi is not None:
	# make datetime naive:
	d = [dt.astimezone(UTC).replace(tzinfo=None) for dt in d]
	d = np.asarray(d)
	d = d.astype('datetime64[us]')

	d = np.ma.masked_array(d, mask=mask) if masked else d
	d = _dt64_to_ordinalf(d)

	return d if iterable else d[0]


	def num2date(x, tz=None):
	"""
	Convert Matplotlib dates to `~datetime.datetime` objects.

	Parameters
	----------
	x : float or sequence of floats
	Number of days (fraction part represents hours, minutes, seconds)
	since the epoch. See `.get_epoch` for the
	epoch, which can be changed by :rc:`date.epoch` or `.set_epoch`.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Timezone of x. If a string, tz is passed to `dateutil.tz`.

	Returns
	-------
	`~datetime.datetime` or sequence of `~datetime.datetime`
	Dates are returned in timezone tz.

	If x is a sequence, a sequence of `~datetime.datetime` objects will
	be returned.

	Notes
	-----
	The Gregorian calendar is assumed; this is not universal practice.
	For details, see the module docstring.
	"""
	tz = _get_tzinfo(tz)
	return _from_ordinalf_np_vectorized(x, tz).tolist()


	_ordinalf_to_timedelta_np_vectorized = np.vectorize(
	lambda x: datetime.timedelta(days=x), otypes="O")


	def num2timedelta(x):
	"""
	Convert number of days to a `~datetime.timedelta` object.

	If x is a sequence, a sequence of `~datetime.timedelta` objects will
	be returned.

	Parameters
	----------
	x : float, sequence of floats
	Number of days. The fraction part represents hours, minutes, seconds.

	Returns
	-------
	`datetime.timedelta` or list[`datetime.timedelta`]
	"""
	return _ordinalf_to_timedelta_np_vectorized(x).tolist()


	def drange(dstart, dend, delta):
	"""
	Return a sequence of equally spaced Matplotlib dates.

	The dates start at dstart and reach up to, but not including dend.
	They are spaced by delta.

	Parameters
	----------
	dstart, dend : `~datetime.datetime`
	The date limits.
	delta : `datetime.timedelta`
	Spacing of the dates.

	Returns
	-------
	`numpy.array`
	A list floats representing Matplotlib dates.

	"""
	f1 = date2num(dstart)
	f2 = date2num(dend)
	step = delta.total_seconds() / SEC_PER_DAY

	# calculate the difference between dend and dstart in times of delta
	num = int(np.ceil((f2 - f1) / step))

	# calculate end of the interval which will be generated
	dinterval_end = dstart + num * delta

	# ensure, that an half open interval will be generated [dstart, dend)
	if dinterval_end >= dend:
	# if the endpoint is greater than or equal to dend,
	# just subtract one delta
	dinterval_end -= delta
	num -= 1

	f2 = date2num(dinterval_end) # new float-endpoint
	return np.linspace(f1, f2, num + 1)


	def _wrap_in_tex(text):
	p = r'([a-zA-Z]+)'
	ret_text = re.sub(p, r'}$\1$\\mathdefault{', text)

	# Braces ensure symbols are not spaced like binary operators.
	ret_text = ret_text.replace('-', '{-}').replace(':', '{:}')
	# To not concatenate space between numbers.
	ret_text = ret_text.replace(' ', r'\;')
	ret_text = '$\\mathdefault{' + ret_text + '}$'
	ret_text = ret_text.replace('$\\mathdefault{}$', '')
	return ret_text


	## date tick locators and formatters ###


	class DateFormatter(ticker.Formatter):
	"""
	Format a tick (in days since the epoch) with a
	`~datetime.datetime.strftime` format string.
	"""

	def __init__(self, fmt, tz=None, *, usetex=None):
	"""
	Parameters
	----------
	fmt : str
	`~datetime.datetime.strftime` format string
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	usetex : bool, default: :rc:`text.usetex`
	To enable/disable the use of TeX's math mode for rendering the
	results of the formatter.
	"""
	self.tz = _get_tzinfo(tz)
	self.fmt = fmt
	self._usetex = mpl._val_or_rc(usetex, 'text.usetex')

	def __call__(self, x, pos=0):
	result = num2date(x, self.tz).strftime(self.fmt)
	return _wrap_in_tex(result) if self._usetex else result

	def set_tzinfo(self, tz):
	self.tz = _get_tzinfo(tz)


	class ConciseDateFormatter(ticker.Formatter):
	"""
	A `.Formatter` which attempts to figure out the best format to use for the
	date, and to make it as compact as possible, but still be complete. This is
	most useful when used with the `AutoDateLocator`::

	>>> locator = AutoDateLocator()
	>>> formatter = ConciseDateFormatter(locator)

	Parameters
	----------
	locator : `.ticker.Locator`
	Locator that this axis is using.

	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone, passed to `.dates.num2date`.

	formats : list of 6 strings, optional
	Format strings for 6 levels of tick labelling: mostly years,
	months, days, hours, minutes, and seconds. Strings use
	the same format codes as `~datetime.datetime.strftime`. Default is
	``['%Y', '%b', '%d', '%H:%M', '%H:%M', '%S.%f']``

	zero_formats : list of 6 strings, optional
	Format strings for tick labels that are "zeros" for a given tick
	level. For instance, if most ticks are months, ticks around 1 Jan 2005
	will be labeled "Dec", "2005", "Feb". The default is
	``['', '%Y', '%b', '%b-%d', '%H:%M', '%H:%M']``

	offset_formats : list of 6 strings, optional
	Format strings for the 6 levels that is applied to the "offset"
	string found on the right side of an x-axis, or top of a y-axis.
	Combined with the tick labels this should completely specify the
	date. The default is::

	['', '%Y', '%Y-%b', '%Y-%b-%d', '%Y-%b-%d', '%Y-%b-%d %H:%M']

	show_offset : bool, default: True
	Whether to show the offset or not.

	usetex : bool, default: :rc:`text.usetex`
	To enable/disable the use of TeX's math mode for rendering the results
	of the formatter.

	Examples
	--------
	See :doc:`/gallery/ticks/date_concise_formatter`

	.. plot::

	import datetime
	import matplotlib.dates as mdates

	base = datetime.datetime(2005, 2, 1)
	dates = np.array([base + datetime.timedelta(hours=(2 * i))
	for i in range(732)])
	N = len(dates)
	np.random.seed(19680801)
	y = np.cumsum(np.random.randn(N))

	fig, ax = plt.subplots(constrained_layout=True)
	locator = mdates.AutoDateLocator()
	formatter = mdates.ConciseDateFormatter(locator)
	ax.xaxis.set_major_locator(locator)
	ax.xaxis.set_major_formatter(formatter)

	ax.plot(dates, y)
	ax.set_title('Concise Date Formatter')

	"""

	def __init__(self, locator, tz=None, formats=None, offset_formats=None,
	zero_formats=None, show_offset=True, *, usetex=None):
	"""
	Autoformat the date labels. The default format is used to form an
	initial string, and then redundant elements are removed.
	"""
	self._locator = locator
	self._tz = tz
	self.defaultfmt = '%Y'
	# there are 6 levels with each level getting a specific format
	# 0: mostly years, 1: months, 2: days,
	# 3: hours, 4: minutes, 5: seconds
	if formats:
	if len(formats) != 6:
	raise ValueError('formats argument must be a list of '
	'6 format strings (or None)')
	self.formats = formats
	else:
	self.formats = ['%Y', # ticks are mostly years
	'%b', # ticks are mostly months
	'%d', # ticks are mostly days
	'%H:%M', # hrs
	'%H:%M', # min
	'%S.%f', # secs
	]
	# fmt for zeros ticks at this level. These are
	# ticks that should be labeled w/ info the level above.
	# like 1 Jan can just be labelled "Jan". 02:02:00 can
	# just be labeled 02:02.
	if zero_formats:
	if len(zero_formats) != 6:
	raise ValueError('zero_formats argument must be a list of '
	'6 format strings (or None)')
	self.zero_formats = zero_formats
	elif formats:
	# use the users formats for the zero tick formats
	self.zero_formats = [''] + self.formats[:-1]
	else:
	# make the defaults a bit nicer:
	self.zero_formats = [''] + self.formats[:-1]
	self.zero_formats[3] = '%b-%d'

	if offset_formats:
	if len(offset_formats) != 6:
	raise ValueError('offset_formats argument must be a list of '
	'6 format strings (or None)')
	self.offset_formats = offset_formats
	else:
	self.offset_formats = ['',
	'%Y',
	'%Y-%b',
	'%Y-%b-%d',
	'%Y-%b-%d',
	'%Y-%b-%d %H:%M']
	self.offset_string = ''
	self.show_offset = show_offset
	self._usetex = mpl._val_or_rc(usetex, 'text.usetex')

	def __call__(self, x, pos=None):
	formatter = DateFormatter(self.defaultfmt, self._tz,
	usetex=self._usetex)
	return formatter(x, pos=pos)

	def format_ticks(self, values):
	tickdatetime = [num2date(value, tz=self._tz) for value in values]
	tickdate = np.array([tdt.timetuple()[:6] for tdt in tickdatetime])

	# basic algorithm:
	# 1) only display a part of the date if it changes over the ticks.
	# 2) don't display the smaller part of the date if:
	# it is always the same or if it is the start of the
	# year, month, day etc.
	# fmt for most ticks at this level
	fmts = self.formats
	# format beginnings of days, months, years, etc.
	zerofmts = self.zero_formats
	# offset fmt are for the offset in the upper left of the
	# or lower right of the axis.
	offsetfmts = self.offset_formats
	show_offset = self.show_offset

	# determine the level we will label at:
	# mostly 0: years, 1: months, 2: days,
	# 3: hours, 4: minutes, 5: seconds, 6: microseconds
	for level in range(5, -1, -1):
	unique = np.unique(tickdate[:, level])
	if len(unique) > 1:
	# if 1 is included in unique, the year is shown in ticks
	if level < 2 and np.any(unique == 1):
	show_offset = False
	break
	elif level == 0:
	# all tickdate are the same, so only micros might be different
	# set to the most precise (6: microseconds doesn't exist...)
	level = 5

	# level is the basic level we will label at.
	# now loop through and decide the actual ticklabels
	zerovals = [0, 1, 1, 0, 0, 0, 0]
	labels = [''] * len(tickdate)
	for nn in range(len(tickdate)):
	if level < 5:
	if tickdate[nn][level] == zerovals[level]:
	fmt = zerofmts[level]
	else:
	fmt = fmts[level]
	else:
	# special handling for seconds + microseconds
	if (tickdatetime[nn].second == tickdatetime[nn].microsecond
	== 0):
	fmt = zerofmts[level]
	else:
	fmt = fmts[level]
	labels[nn] = tickdatetime[nn].strftime(fmt)

	# special handling of seconds and microseconds:
	# strip extra zeros and decimal if possible.
	# this is complicated by two factors. 1) we have some level-4 strings
	# here (i.e. 03:00, '0.50000', '1.000') 2) we would like to have the
	# same number of decimals for each string (i.e. 0.5 and 1.0).
	if level >= 5:
	trailing_zeros = min(
	(len(s) - len(s.rstrip('0')) for s in labels if '.' in s),
	default=None)
	if trailing_zeros:
	for nn in range(len(labels)):
	if '.' in labels[nn]:
	labels[nn] = labels[nn][:-trailing_zeros].rstrip('.')

	if show_offset:
	# set the offset string:
	if (self._locator.axis and
	self._locator.axis.__name__ in ('xaxis', 'yaxis')
	and self._locator.axis.get_inverted()):
	self.offset_string = tickdatetime[0].strftime(offsetfmts[level])
	else:
	self.offset_string = tickdatetime[-1].strftime(offsetfmts[level])
	if self._usetex:
	self.offset_string = _wrap_in_tex(self.offset_string)
	else:
	self.offset_string = ''

	if self._usetex:
	return [_wrap_in_tex(l) for l in labels]
	else:
	return labels

	def get_offset(self):
	return self.offset_string

	def format_data_short(self, value):
	return num2date(value, tz=self._tz).strftime('%Y-%m-%d %H:%M:%S')


	class AutoDateFormatter(ticker.Formatter):
	"""
	A `.Formatter` which attempts to figure out the best format to use. This
	is most useful when used with the `AutoDateLocator`.

	`.AutoDateFormatter` has a ``.scale`` dictionary that maps tick scales (the
	interval in days between one major tick) to format strings; this dictionary
	defaults to ::

	self.scaled = {
	DAYS_PER_YEAR: rcParams['date.autoformatter.year'],
	DAYS_PER_MONTH: rcParams['date.autoformatter.month'],
	1: rcParams['date.autoformatter.day'],
	1 / HOURS_PER_DAY: rcParams['date.autoformatter.hour'],
	1 / MINUTES_PER_DAY: rcParams['date.autoformatter.minute'],
	1 / SEC_PER_DAY: rcParams['date.autoformatter.second'],
	1 / MUSECONDS_PER_DAY: rcParams['date.autoformatter.microsecond'],
	}

	The formatter uses the format string corresponding to the lowest key in
	the dictionary that is greater or equal to the current scale. Dictionary
	entries can be customized::

	locator = AutoDateLocator()
	formatter = AutoDateFormatter(locator)
	formatter.scaled[1/(24*60)] = '%M:%S' # only show min and sec

	Custom callables can also be used instead of format strings. The following
	example shows how to use a custom format function to strip trailing zeros
	from decimal seconds and adds the date to the first ticklabel::

	def my_format_function(x, pos=None):
	x = matplotlib.dates.num2date(x)
	if pos == 0:
	fmt = '%D %H:%M:%S.%f'
	else:
	fmt = '%H:%M:%S.%f'
	label = x.strftime(fmt)
	label = label.rstrip("0")
	label = label.rstrip(".")
	return label

	formatter.scaled[1/(24*60)] = my_format_function
	"""

	# This can be improved by providing some user-level direction on
	# how to choose the best format (precedence, etc.).

	# Perhaps a 'struct' that has a field for each time-type where a
	# zero would indicate "don't show" and a number would indicate
	# "show" with some sort of priority. Same priorities could mean
	# show all with the same priority.

	# Or more simply, perhaps just a format string for each
	# possibility...

	def __init__(self, locator, tz=None, defaultfmt='%Y-%m-%d', *,
	usetex=None):
	"""
	Autoformat the date labels.

	Parameters
	----------
	locator : `.ticker.Locator`
	Locator that this axis is using.

	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.

	defaultfmt : str
	The default format to use if none of the values in ``self.scaled``
	are greater than the unit returned by ``locator._get_unit()``.

	usetex : bool, default: :rc:`text.usetex`
	To enable/disable the use of TeX's math mode for rendering the
	results of the formatter. If any entries in ``self.scaled`` are set
	as functions, then it is up to the customized function to enable or
	disable TeX's math mode itself.
	"""
	self._locator = locator
	self._tz = tz
	self.defaultfmt = defaultfmt
	self._formatter = DateFormatter(self.defaultfmt, tz)
	rcParams = mpl.rcParams
	self._usetex = mpl._val_or_rc(usetex, 'text.usetex')
	self.scaled = {
	DAYS_PER_YEAR: rcParams['date.autoformatter.year'],
	DAYS_PER_MONTH: rcParams['date.autoformatter.month'],
	1: rcParams['date.autoformatter.day'],
	1 / HOURS_PER_DAY: rcParams['date.autoformatter.hour'],
	1 / MINUTES_PER_DAY: rcParams['date.autoformatter.minute'],
	1 / SEC_PER_DAY: rcParams['date.autoformatter.second'],
	1 / MUSECONDS_PER_DAY: rcParams['date.autoformatter.microsecond']
	}

	def _set_locator(self, locator):
	self._locator = locator

	def __call__(self, x, pos=None):
	try:
	locator_unit_scale = float(self._locator._get_unit())
	except AttributeError:
	locator_unit_scale = 1
	# Pick the first scale which is greater than the locator unit.
	fmt = next((fmt for scale, fmt in sorted(self.scaled.items())
	if scale >= locator_unit_scale),
	self.defaultfmt)

	if isinstance(fmt, str):
	self._formatter = DateFormatter(fmt, self._tz, usetex=self._usetex)
	result = self._formatter(x, pos)
	elif callable(fmt):
	result = fmt(x, pos)
	else:
	raise TypeError(f'Unexpected type passed to {self!r}.')

	return result


	class rrulewrapper:
	"""
	A simple wrapper around a `dateutil.rrule` allowing flexible
	date tick specifications.
	"""
	def __init__(self, freq, tzinfo=None, **kwargs):
	"""
	Parameters
	----------
	freq : {YEARLY, MONTHLY, WEEKLY, DAILY, HOURLY, MINUTELY, SECONDLY}
	Tick frequency. These constants are defined in `dateutil.rrule`,
	but they are accessible from `matplotlib.dates` as well.
	tzinfo : `datetime.tzinfo`, optional
	Time zone information. The default is None.
	**kwargs
	Additional keyword arguments are passed to the `dateutil.rrule`.
	"""
	kwargs['freq'] = freq
	self._base_tzinfo = tzinfo

	self._update_rrule(**kwargs)

	def set(self, **kwargs):
	"""Set parameters for an existing wrapper."""
	self._construct.update(kwargs)

	self._update_rrule(**self._construct)

	def _update_rrule(self, **kwargs):
	tzinfo = self._base_tzinfo

	# rrule does not play nicely with timezones - especially pytz time
	# zones, it's best to use naive zones and attach timezones once the
	# datetimes are returned
	if 'dtstart' in kwargs:
	dtstart = kwargs['dtstart']
	if dtstart.tzinfo is not None:
	if tzinfo is None:
	tzinfo = dtstart.tzinfo
	else:
	dtstart = dtstart.astimezone(tzinfo)

	kwargs['dtstart'] = dtstart.replace(tzinfo=None)

	if 'until' in kwargs:
	until = kwargs['until']
	if until.tzinfo is not None:
	if tzinfo is not None:
	until = until.astimezone(tzinfo)
	else:
	raise ValueError('until cannot be aware if dtstart '
	'is naive and tzinfo is None')

	kwargs['until'] = until.replace(tzinfo=None)

	self._construct = kwargs.copy()
	self._tzinfo = tzinfo
	self._rrule = rrule(**self._construct)

	def _attach_tzinfo(self, dt, tzinfo):
	# pytz zones are attached by "localizing" the datetime
	if hasattr(tzinfo, 'localize'):
	return tzinfo.localize(dt, is_dst=True)

	return dt.replace(tzinfo=tzinfo)

	def _aware_return_wrapper(self, f, returns_list=False):
	"""Decorator function that allows rrule methods to handle tzinfo."""
	# This is only necessary if we're actually attaching a tzinfo
	if self._tzinfo is None:
	return f

	# All datetime arguments must be naive. If they are not naive, they are
	# converted to the _tzinfo zone before dropping the zone.
	def normalize_arg(arg):
	if isinstance(arg, datetime.datetime) and arg.tzinfo is not None:
	if arg.tzinfo is not self._tzinfo:
	arg = arg.astimezone(self._tzinfo)

	return arg.replace(tzinfo=None)

	return arg

	def normalize_args(args, kwargs):
	args = tuple(normalize_arg(arg) for arg in args)
	kwargs = {kw: normalize_arg(arg) for kw, arg in kwargs.items()}

	return args, kwargs

	# There are two kinds of functions we care about - ones that return
	# dates and ones that return lists of dates.
	if not returns_list:
	def inner_func(args, *kwargs):
	args, kwargs = normalize_args(args, kwargs)
	dt = f(args, *kwargs)
	return self._attach_tzinfo(dt, self._tzinfo)
	else:
	def inner_func(args, *kwargs):
	args, kwargs = normalize_args(args, kwargs)
	dts = f(args, *kwargs)
	return [self._attach_tzinfo(dt, self._tzinfo) for dt in dts]

	return functools.wraps(f)(inner_func)

	def __getattr__(self, name):
	if name in self.__dict__:
	return self.__dict__[name]

	f = getattr(self._rrule, name)

	if name in {'after', 'before'}:
	return self._aware_return_wrapper(f)
	elif name in {'xafter', 'xbefore', 'between'}:
	return self._aware_return_wrapper(f, returns_list=True)
	else:
	return f

	def __setstate__(self, state):
	self.__dict__.update(state)


	class DateLocator(ticker.Locator):
	"""
	Determines the tick locations when plotting dates.

	This class is subclassed by other Locators and
	is not meant to be used on its own.
	"""
	hms0d = {'byhour': 0, 'byminute': 0, 'bysecond': 0}

	def __init__(self, tz=None):
	"""
	Parameters
	----------
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	self.tz = _get_tzinfo(tz)

	def set_tzinfo(self, tz):
	"""
	Set timezone info.

	Parameters
	----------
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	self.tz = _get_tzinfo(tz)

	def datalim_to_dt(self):
	"""Convert axis data interval to datetime objects."""
	dmin, dmax = self.axis.get_data_interval()
	if dmin > dmax:
	dmin, dmax = dmax, dmin

	return num2date(dmin, self.tz), num2date(dmax, self.tz)

	def viewlim_to_dt(self):
	"""Convert the view interval to datetime objects."""
	vmin, vmax = self.axis.get_view_interval()
	if vmin > vmax:
	vmin, vmax = vmax, vmin
	return num2date(vmin, self.tz), num2date(vmax, self.tz)

	def _get_unit(self):
	"""
	Return how many days a unit of the locator is; used for
	intelligent autoscaling.
	"""
	return 1

	def _get_interval(self):
	"""
	Return the number of units for each tick.
	"""
	return 1

	def nonsingular(self, vmin, vmax):
	"""
	Given the proposed upper and lower extent, adjust the range
	if it is too close to being singular (i.e. a range of ~0).
	"""
	if not np.isfinite(vmin) or not np.isfinite(vmax):
	# Except if there is no data, then use 1970 as default.
	return (date2num(datetime.date(1970, 1, 1)),
	date2num(datetime.date(1970, 1, 2)))
	if vmax < vmin:
	vmin, vmax = vmax, vmin
	unit = self._get_unit()
	interval = self._get_interval()
	if abs(vmax - vmin) < 1e-6:
	vmin -= 2 * unit * interval
	vmax += 2 * unit * interval
	return vmin, vmax


	class RRuleLocator(DateLocator):
	# use the dateutil rrule instance

	def __init__(self, o, tz=None):
	super().__init__(tz)
	self.rule = o

	def __call__(self):
	# if no data have been set, this will tank with a ValueError
	try:
	dmin, dmax = self.viewlim_to_dt()
	except ValueError:
	return []

	return self.tick_values(dmin, dmax)

	def tick_values(self, vmin, vmax):
	start, stop = self._create_rrule(vmin, vmax)
	dates = self.rule.between(start, stop, True)
	if len(dates) == 0:
	return date2num([vmin, vmax])
	return self.raise_if_exceeds(date2num(dates))

	def _create_rrule(self, vmin, vmax):
	# set appropriate rrule dtstart and until and return
	# start and end
	delta = relativedelta(vmax, vmin)

	# We need to cap at the endpoints of valid datetime
	try:
	start = vmin - delta
	except (ValueError, OverflowError):
	# cap
	start = datetime.datetime(1, 1, 1, 0, 0, 0,
	tzinfo=datetime.timezone.utc)

	try:
	stop = vmax + delta
	except (ValueError, OverflowError):
	# cap
	stop = datetime.datetime(9999, 12, 31, 23, 59, 59,
	tzinfo=datetime.timezone.utc)

	self.rule.set(dtstart=start, until=stop)

	return vmin, vmax

	def _get_unit(self):
	# docstring inherited
	freq = self.rule._rrule._freq
	return self.get_unit_generic(freq)

	@staticmethod
	def get_unit_generic(freq):
	if freq == YEARLY:
	return DAYS_PER_YEAR
	elif freq == MONTHLY:
	return DAYS_PER_MONTH
	elif freq == WEEKLY:
	return DAYS_PER_WEEK
	elif freq == DAILY:
	return 1.0
	elif freq == HOURLY:
	return 1.0 / HOURS_PER_DAY
	elif freq == MINUTELY:
	return 1.0 / MINUTES_PER_DAY
	elif freq == SECONDLY:
	return 1.0 / SEC_PER_DAY
	else:
	# error
	return -1 # or should this just return '1'?

	def _get_interval(self):
	return self.rule._rrule._interval


	class AutoDateLocator(DateLocator):
	"""
	On autoscale, this class picks the best `DateLocator` to set the view
	limits and the tick locations.

	Attributes
	----------
	intervald : dict

	Mapping of tick frequencies to multiples allowed for that ticking.
	The default is ::

	self.intervald = {
	YEARLY : [1, 2, 4, 5, 10, 20, 40, 50, 100, 200, 400, 500,
	1000, 2000, 4000, 5000, 10000],
	MONTHLY : [1, 2, 3, 4, 6],
	DAILY : [1, 2, 3, 7, 14, 21],
	HOURLY : [1, 2, 3, 4, 6, 12],
	MINUTELY: [1, 5, 10, 15, 30],
	SECONDLY: [1, 5, 10, 15, 30],
	MICROSECONDLY: [1, 2, 5, 10, 20, 50, 100, 200, 500,
	1000, 2000, 5000, 10000, 20000, 50000,
	100000, 200000, 500000, 1000000],
	}

	where the keys are defined in `dateutil.rrule`.

	The interval is used to specify multiples that are appropriate for
	the frequency of ticking. For instance, every 7 days is sensible
	for daily ticks, but for minutes/seconds, 15 or 30 make sense.

	When customizing, you should only modify the values for the existing
	keys. You should not add or delete entries.

	Example for forcing ticks every 3 hours::

	locator = AutoDateLocator()
	locator.intervald[HOURLY] = [3] # only show every 3 hours
	"""

	def __init__(self, tz=None, minticks=5, maxticks=None,
	interval_multiples=True):
	"""
	Parameters
	----------
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	minticks : int
	The minimum number of ticks desired; controls whether ticks occur
	yearly, monthly, etc.
	maxticks : int
	The maximum number of ticks desired; controls the interval between
	ticks (ticking every other, every 3, etc.). For fine-grained
	control, this can be a dictionary mapping individual rrule
	frequency constants (YEARLY, MONTHLY, etc.) to their own maximum
	number of ticks. This can be used to keep the number of ticks
	appropriate to the format chosen in `AutoDateFormatter`. Any
	frequency not specified in this dictionary is given a default
	value.
	interval_multiples : bool, default: True
	Whether ticks should be chosen to be multiple of the interval,
	locking them to 'nicer' locations. For example, this will force
	the ticks to be at hours 0, 6, 12, 18 when hourly ticking is done
	at 6 hour intervals.
	"""
	super().__init__(tz=tz)
	self._freq = YEARLY
	self._freqs = [YEARLY, MONTHLY, DAILY, HOURLY, MINUTELY,
	SECONDLY, MICROSECONDLY]
	self.minticks = minticks

	self.maxticks = {YEARLY: 11, MONTHLY: 12, DAILY: 11, HOURLY: 12,
	MINUTELY: 11, SECONDLY: 11, MICROSECONDLY: 8}
	if maxticks is not None:
	try:
	self.maxticks.update(maxticks)
	except TypeError:
	# Assume we were given an integer. Use this as the maximum
	# number of ticks for every frequency and create a
	# dictionary for this
	self.maxticks = dict.fromkeys(self._freqs, maxticks)
	self.interval_multiples = interval_multiples
	self.intervald = {
	YEARLY: [1, 2, 4, 5, 10, 20, 40, 50, 100, 200, 400, 500,
	1000, 2000, 4000, 5000, 10000],
	MONTHLY: [1, 2, 3, 4, 6],
	DAILY: [1, 2, 3, 7, 14, 21],
	HOURLY: [1, 2, 3, 4, 6, 12],
	MINUTELY: [1, 5, 10, 15, 30],
	SECONDLY: [1, 5, 10, 15, 30],
	MICROSECONDLY: [1, 2, 5, 10, 20, 50, 100, 200, 500, 1000, 2000,
	5000, 10000, 20000, 50000, 100000, 200000, 500000,
	1000000],
	}
	if interval_multiples:
	# Swap "3" for "4" in the DAILY list; If we use 3 we get bad
	# tick loc for months w/ 31 days: 1, 4, ..., 28, 31, 1
	# If we use 4 then we get: 1, 5, ... 25, 29, 1
	self.intervald[DAILY] = [1, 2, 4, 7, 14]

	self._byranges = [None, range(1, 13), range(1, 32),
	range(0, 24), range(0, 60), range(0, 60), None]

	def __call__(self):
	# docstring inherited
	dmin, dmax = self.viewlim_to_dt()
	locator = self.get_locator(dmin, dmax)
	return locator()

	def tick_values(self, vmin, vmax):
	return self.get_locator(vmin, vmax).tick_values(vmin, vmax)

	def nonsingular(self, vmin, vmax):
	# whatever is thrown at us, we can scale the unit.
	# But default nonsingular date plots at an ~4 year period.
	if not np.isfinite(vmin) or not np.isfinite(vmax):
	# Except if there is no data, then use 1970 as default.
	return (date2num(datetime.date(1970, 1, 1)),
	date2num(datetime.date(1970, 1, 2)))
	if vmax < vmin:
	vmin, vmax = vmax, vmin
	if vmin == vmax:
	vmin = vmin - DAYS_PER_YEAR * 2
	vmax = vmax + DAYS_PER_YEAR * 2
	return vmin, vmax

	def _get_unit(self):
	if self._freq in [MICROSECONDLY]:
	return 1. / MUSECONDS_PER_DAY
	else:
	return RRuleLocator.get_unit_generic(self._freq)

	def get_locator(self, dmin, dmax):
	"""Pick the best locator based on a distance."""
	delta = relativedelta(dmax, dmin)
	tdelta = dmax - dmin

	# take absolute difference
	if dmin > dmax:
	delta = -delta
	tdelta = -tdelta
	# The following uses a mix of calls to relativedelta and timedelta
	# methods because there is incomplete overlap in the functionality of
	# these similar functions, and it's best to avoid doing our own math
	# whenever possible.
	numYears = float(delta.years)
	numMonths = numYears * MONTHS_PER_YEAR + delta.months
	numDays = tdelta.days # Avoids estimates of days/month, days/year.
	numHours = numDays * HOURS_PER_DAY + delta.hours
	numMinutes = numHours * MIN_PER_HOUR + delta.minutes
	numSeconds = np.floor(tdelta.total_seconds())
	numMicroseconds = np.floor(tdelta.total_seconds() * 1e6)

	nums = [numYears, numMonths, numDays, numHours, numMinutes,
	numSeconds, numMicroseconds]

	use_rrule_locator = [True] * 6 + [False]

	# Default setting of bymonth, etc. to pass to rrule
	# [unused (for year), bymonth, bymonthday, byhour, byminute,
	# bysecond, unused (for microseconds)]
	byranges = [None, 1, 1, 0, 0, 0, None]

	# Loop over all the frequencies and try to find one that gives at
	# least a minticks tick positions. Once this is found, look for
	# an interval from a list specific to that frequency that gives no
	# more than maxticks tick positions. Also, set up some ranges
	# (bymonth, etc.) as appropriate to be passed to rrulewrapper.
	for i, (freq, num) in enumerate(zip(self._freqs, nums)):
	# If this particular frequency doesn't give enough ticks, continue
	if num < self.minticks:
	# Since we're not using this particular frequency, set
	# the corresponding by_ to None so the rrule can act as
	# appropriate
	byranges[i] = None
	continue

	# Find the first available interval that doesn't give too many
	# ticks
	for interval in self.intervald[freq]:
	if num <= interval * (self.maxticks[freq] - 1):
	break
	else:
	if not (self.interval_multiples and freq == DAILY):
	_api.warn_external(
	f"AutoDateLocator was unable to pick an appropriate "
	f"interval for this date range. It may be necessary "
	f"to add an interval value to the AutoDateLocator's "
	f"intervald dictionary. Defaulting to {interval}.")

	# Set some parameters as appropriate
	self._freq = freq

	if self._byranges[i] and self.interval_multiples:
	byranges[i] = self._byranges[i][::interval]
	if i in (DAILY, WEEKLY):
	if interval == 14:
	# just make first and 15th. Avoids 30th.
	byranges[i] = [1, 15]
	elif interval == 7:
	byranges[i] = [1, 8, 15, 22]

	interval = 1
	else:
	byranges[i] = self._byranges[i]
	break
	else:
	interval = 1

	if (freq == YEARLY) and self.interval_multiples:
	locator = YearLocator(interval, tz=self.tz)
	elif use_rrule_locator[i]:
	_, bymonth, bymonthday, byhour, byminute, bysecond, _ = byranges
	rrule = rrulewrapper(self._freq, interval=interval,
	dtstart=dmin, until=dmax,
	bymonth=bymonth, bymonthday=bymonthday,
	byhour=byhour, byminute=byminute,
	bysecond=bysecond)

	locator = RRuleLocator(rrule, tz=self.tz)
	else:
	locator = MicrosecondLocator(interval, tz=self.tz)
	if date2num(dmin) > 70 * 365 and interval < 1000:
	_api.warn_external(
	'Plotting microsecond time intervals for dates far from '
	f'the epoch (time origin: {get_epoch()}) is not well-'
	'supported. See matplotlib.dates.set_epoch to change the '
	'epoch.')

	locator.set_axis(self.axis)
	return locator


	class YearLocator(RRuleLocator):
	"""
	Make ticks on a given day of each year that is a multiple of base.

	Examples::

	# Tick every year on Jan 1st
	locator = YearLocator()

	# Tick every 5 years on July 4th
	locator = YearLocator(5, month=7, day=4)
	"""
	def __init__(self, base=1, month=1, day=1, tz=None):
	"""
	Parameters
	----------
	base : int, default: 1
	Mark ticks every base years.
	month : int, default: 1
	The month on which to place the ticks, starting from 1. Default is
	January.
	day : int, default: 1
	The day on which to place the ticks.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	rule = rrulewrapper(YEARLY, interval=base, bymonth=month,
	bymonthday=day, **self.hms0d)
	super().__init__(rule, tz=tz)
	self.base = ticker._Edge_integer(base, 0)

	def _create_rrule(self, vmin, vmax):
	# 'start' needs to be a multiple of the interval to create ticks on
	# interval multiples when the tick frequency is YEARLY
	ymin = max(self.base.le(vmin.year) * self.base.step, 1)
	ymax = min(self.base.ge(vmax.year) * self.base.step, 9999)

	c = self.rule._construct
	replace = {'year': ymin,
	'month': c.get('bymonth', 1),
	'day': c.get('bymonthday', 1),
	'hour': 0, 'minute': 0, 'second': 0}

	start = vmin.replace(**replace)
	stop = start.replace(year=ymax)
	self.rule.set(dtstart=start, until=stop)

	return start, stop


	class MonthLocator(RRuleLocator):
	"""
	Make ticks on occurrences of each month, e.g., 1, 3, 12.
	"""
	def __init__(self, bymonth=None, bymonthday=1, interval=1, tz=None):
	"""
	Parameters
	----------
	bymonth : int or list of int, default: all months
	Ticks will be placed on every month in bymonth. Default is
	``range(1, 13)``, i.e. every month.
	bymonthday : int, default: 1
	The day on which to place the ticks.
	interval : int, default: 1
	The interval between each iteration. For example, if
	``interval=2``, mark every second occurrence.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	if bymonth is None:
	bymonth = range(1, 13)

	rule = rrulewrapper(MONTHLY, bymonth=bymonth, bymonthday=bymonthday,
	interval=interval, **self.hms0d)
	super().__init__(rule, tz=tz)


	class WeekdayLocator(RRuleLocator):
	"""
	Make ticks on occurrences of each weekday.
	"""

	def __init__(self, byweekday=1, interval=1, tz=None):
	"""
	Parameters
	----------
	byweekday : int or list of int, default: all days
	Ticks will be placed on every weekday in byweekday. Default is
	every day.

	Elements of byweekday must be one of MO, TU, WE, TH, FR, SA,
	SU, the constants from :mod:`dateutil.rrule`, which have been
	imported into the :mod:`matplotlib.dates` namespace.
	interval : int, default: 1
	The interval between each iteration. For example, if
	``interval=2``, mark every second occurrence.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	rule = rrulewrapper(DAILY, byweekday=byweekday,
	interval=interval, **self.hms0d)
	super().__init__(rule, tz=tz)


	class DayLocator(RRuleLocator):
	"""
	Make ticks on occurrences of each day of the month. For example,
	1, 15, 30.
	"""
	def __init__(self, bymonthday=None, interval=1, tz=None):
	"""
	Parameters
	----------
	bymonthday : int or list of int, default: all days
	Ticks will be placed on every day in bymonthday. Default is
	``bymonthday=range(1, 32)``, i.e., every day of the month.
	interval : int, default: 1
	The interval between each iteration. For example, if
	``interval=2``, mark every second occurrence.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	if interval != int(interval) or interval < 1:
	raise ValueError("interval must be an integer greater than 0")
	if bymonthday is None:
	bymonthday = range(1, 32)

	rule = rrulewrapper(DAILY, bymonthday=bymonthday,
	interval=interval, **self.hms0d)
	super().__init__(rule, tz=tz)


	class HourLocator(RRuleLocator):
	"""
	Make ticks on occurrences of each hour.
	"""
	def __init__(self, byhour=None, interval=1, tz=None):
	"""
	Parameters
	----------
	byhour : int or list of int, default: all hours
	Ticks will be placed on every hour in byhour. Default is
	``byhour=range(24)``, i.e., every hour.
	interval : int, default: 1
	The interval between each iteration. For example, if
	``interval=2``, mark every second occurrence.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	if byhour is None:
	byhour = range(24)

	rule = rrulewrapper(HOURLY, byhour=byhour, interval=interval,
	byminute=0, bysecond=0)
	super().__init__(rule, tz=tz)


	class MinuteLocator(RRuleLocator):
	"""
	Make ticks on occurrences of each minute.
	"""
	def __init__(self, byminute=None, interval=1, tz=None):
	"""
	Parameters
	----------
	byminute : int or list of int, default: all minutes
	Ticks will be placed on every minute in byminute. Default is
	``byminute=range(60)``, i.e., every minute.
	interval : int, default: 1
	The interval between each iteration. For example, if
	``interval=2``, mark every second occurrence.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	if byminute is None:
	byminute = range(60)

	rule = rrulewrapper(MINUTELY, byminute=byminute, interval=interval,
	bysecond=0)
	super().__init__(rule, tz=tz)


	class SecondLocator(RRuleLocator):
	"""
	Make ticks on occurrences of each second.
	"""
	def __init__(self, bysecond=None, interval=1, tz=None):
	"""
	Parameters
	----------
	bysecond : int or list of int, default: all seconds
	Ticks will be placed on every second in bysecond. Default is
	``bysecond = range(60)``, i.e., every second.
	interval : int, default: 1
	The interval between each iteration. For example, if
	``interval=2``, mark every second occurrence.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	if bysecond is None:
	bysecond = range(60)

	rule = rrulewrapper(SECONDLY, bysecond=bysecond, interval=interval)
	super().__init__(rule, tz=tz)


	class MicrosecondLocator(DateLocator):
	"""
	Make ticks on regular intervals of one or more microsecond(s).

	.. note::

	By default, Matplotlib uses a floating point representation of time in
	days since the epoch, so plotting data with
	microsecond time resolution does not work well for
	dates that are far (about 70 years) from the epoch (check with
	`~.dates.get_epoch`).

	If you want sub-microsecond resolution time plots, it is strongly
	recommended to use floating point seconds, not datetime-like
	time representation.

	If you really must use datetime.datetime() or similar and still
	need microsecond precision, change the time origin via
	`.dates.set_epoch` to something closer to the dates being plotted.
	See :doc:`/gallery/ticks/date_precision_and_epochs`.

	"""
	def __init__(self, interval=1, tz=None):
	"""
	Parameters
	----------
	interval : int, default: 1
	The interval between each iteration. For example, if
	``interval=2``, mark every second occurrence.
	tz : str or `~datetime.tzinfo`, default: :rc:`timezone`
	Ticks timezone. If a string, tz is passed to `dateutil.tz`.
	"""
	super().__init__(tz=tz)
	self._interval = interval
	self._wrapped_locator = ticker.MultipleLocator(interval)

	def set_axis(self, axis):
	self._wrapped_locator.set_axis(axis)
	return super().set_axis(axis)

	def __call__(self):
	# if no data have been set, this will tank with a ValueError
	try:
	dmin, dmax = self.viewlim_to_dt()
	except ValueError:
	return []

	return self.tick_values(dmin, dmax)

	def tick_values(self, vmin, vmax):
	nmin, nmax = date2num((vmin, vmax))
	t0 = np.floor(nmin)
	nmax = nmax - t0
	nmin = nmin - t0
	nmin *= MUSECONDS_PER_DAY
	nmax *= MUSECONDS_PER_DAY

	ticks = self._wrapped_locator.tick_values(nmin, nmax)

	ticks = ticks / MUSECONDS_PER_DAY + t0
	return ticks

	def _get_unit(self):
	# docstring inherited
	return 1. / MUSECONDS_PER_DAY

	def _get_interval(self):
	# docstring inherited
	return self._interval


	class DateConverter(units.ConversionInterface):
	"""
	Converter for `datetime.date` and `datetime.datetime` data, or for
	date/time data represented as it would be converted by `date2num`.

	The 'unit' tag for such data is None or a `~datetime.tzinfo` instance.
	"""

	def __init__(self, *, interval_multiples=True):
	self._interval_multiples = interval_multiples
	super().__init__()

	def axisinfo(self, unit, axis):
	"""
	Return the `~matplotlib.units.AxisInfo` for unit.

	unit is a `~datetime.tzinfo` instance or None.
	The axis argument is required but not used.
	"""
	tz = unit

	majloc = AutoDateLocator(tz=tz,
	interval_multiples=self._interval_multiples)
	majfmt = AutoDateFormatter(majloc, tz=tz)
	datemin = datetime.date(1970, 1, 1)
	datemax = datetime.date(1970, 1, 2)

	return units.AxisInfo(majloc=majloc, majfmt=majfmt, label='',
	default_limits=(datemin, datemax))

	@staticmethod
	def convert(value, unit, axis):
	"""
	If value is not already a number or sequence of numbers, convert it
	with `date2num`.

	The unit and axis arguments are not used.
	"""
	return date2num(value)

	@staticmethod
	def default_units(x, axis):
	"""
	Return the `~datetime.tzinfo` instance of x or of its first element,
	or None
	"""
	if isinstance(x, np.ndarray):
	x = x.ravel()

	try:
	x = cbook._safe_first_finite(x)
	except (TypeError, StopIteration):
	pass

	try:
	return x.tzinfo
	except AttributeError:
	pass
	return None


	class ConciseDateConverter(DateConverter):
	# docstring inherited

	def __init__(self, formats=None, zero_formats=None, offset_formats=None,
	show_offset=True, *, interval_multiples=True):
	self._formats = formats
	self._zero_formats = zero_formats
	self._offset_formats = offset_formats
	self._show_offset = show_offset
	self._interval_multiples = interval_multiples
	super().__init__()

	def axisinfo(self, unit, axis):
	# docstring inherited
	tz = unit
	majloc = AutoDateLocator(tz=tz,
	interval_multiples=self._interval_multiples)
	majfmt = ConciseDateFormatter(majloc, tz=tz, formats=self._formats,
	zero_formats=self._zero_formats,
	offset_formats=self._offset_formats,
	show_offset=self._show_offset)
	datemin = datetime.date(1970, 1, 1)
	datemax = datetime.date(1970, 1, 2)
	return units.AxisInfo(majloc=majloc, majfmt=majfmt, label='',
	default_limits=(datemin, datemax))


	class _SwitchableDateConverter:
	"""
	Helper converter-like object that generates and dispatches to
	temporary ConciseDateConverter or DateConverter instances based on
	:rc:`date.converter` and :rc:`date.interval_multiples`.
	"""

	@staticmethod
	def _get_converter():
	converter_cls = {
	"concise": ConciseDateConverter, "auto": DateConverter}[
	mpl.rcParams["date.converter"]]
	interval_multiples = mpl.rcParams["date.interval_multiples"]
	return converter_cls(interval_multiples=interval_multiples)

	def axisinfo(self, args, *kwargs):
	return self._get_converter().axisinfo(args, *kwargs)

	def default_units(self, args, *kwargs):
	return self._get_converter().default_units(args, *kwargs)

	def convert(self, args, *kwargs):
	return self._get_converter().convert(args, *kwargs)


	units.registry[np.datetime64] = \
	units.registry[datetime.date] = \
	units.registry[datetime.datetime] = \
	_SwitchableDateConverter()