from datetime import timedelta import operator from typing import Any, Callable, List, Optional, Sequence, Type, Union import numpy as np from pandas._libs.tslibs import ( BaseOffset, NaT, NaTType, Timedelta, delta_to_nanoseconds, dt64arr_to_periodarr as c_dt64arr_to_periodarr, iNaT, period as libperiod, to_offset, ) from pandas._libs.tslibs.dtypes import FreqGroup from pandas._libs.tslibs.fields import isleapyear_arr from pandas._libs.tslibs.offsets import Tick, delta_to_tick from pandas._libs.tslibs.period import ( DIFFERENT_FREQ, IncompatibleFrequency, Period, PeriodMixin, get_period_field_arr, period_asfreq_arr, ) from pandas._typing import AnyArrayLike from pandas.util._decorators import cache_readonly from pandas.core.dtypes.common import ( TD64NS_DTYPE, ensure_object, is_datetime64_dtype, is_dtype_equal, is_float_dtype, is_period_dtype, pandas_dtype, ) from pandas.core.dtypes.dtypes import PeriodDtype from pandas.core.dtypes.generic import ( ABCIndexClass, ABCPeriodIndex, ABCSeries, ABCTimedeltaArray, ) from pandas.core.dtypes.missing import isna, notna import pandas.core.algorithms as algos from pandas.core.arrays import datetimelike as dtl import pandas.core.common as com def _field_accessor(name: str, docstring=None): def f(self): base = self.freq._period_dtype_code result = get_period_field_arr(name, self.asi8, base) return result f.__name__ = name f.__doc__ = docstring return property(f) class PeriodArray(PeriodMixin, dtl.DatelikeOps): """ Pandas ExtensionArray for storing Period data. Users should use :func:`period_range` to create new instances. Alternatively, :func:`array` can be used to create new instances from a sequence of Period scalars. Parameters ---------- values : Union[PeriodArray, Series[period], ndarray[int], PeriodIndex] The data to store. These should be arrays that can be directly converted to ordinals without inference or copy (PeriodArray, ndarray[int64]), or a box around such an array (Series[period], PeriodIndex). dtype : PeriodDtype, optional A PeriodDtype instance from which to extract a `freq`. If both `freq` and `dtype` are specified, then the frequencies must match. freq : str or DateOffset The `freq` to use for the array. Mostly applicable when `values` is an ndarray of integers, when `freq` is required. When `values` is a PeriodArray (or box around), it's checked that ``values.freq`` matches `freq`. copy : bool, default False Whether to copy the ordinals before storing. Attributes ---------- None Methods ------- None See Also -------- Period: Represents a period of time. PeriodIndex : Immutable Index for period data. period_range: Create a fixed-frequency PeriodArray. array: Construct a pandas array. Notes ----- There are two components to a PeriodArray - ordinals : integer ndarray - freq : pd.tseries.offsets.Offset The values are physically stored as a 1-D ndarray of integers. These are called "ordinals" and represent some kind of offset from a base. The `freq` indicates the span covered by each element of the array. All elements in the PeriodArray have the same `freq`. """ # array priority higher than numpy scalars __array_priority__ = 1000 _typ = "periodarray" # ABCPeriodArray _scalar_type = Period _recognized_scalars = (Period,) _is_recognized_dtype = is_period_dtype _infer_matches = ("period",) # Names others delegate to us _other_ops: List[str] = [] _bool_ops = ["is_leap_year"] _object_ops = ["start_time", "end_time", "freq"] _field_ops = [ "year", "month", "day", "hour", "minute", "second", "weekofyear", "weekday", "week", "dayofweek", "day_of_week", "dayofyear", "day_of_year", "quarter", "qyear", "days_in_month", "daysinmonth", ] _datetimelike_ops = _field_ops + _object_ops + _bool_ops _datetimelike_methods = ["strftime", "to_timestamp", "asfreq"] # -------------------------------------------------------------------- # Constructors def __init__(self, values, dtype=None, freq=None, copy=False): freq = validate_dtype_freq(dtype, freq) if freq is not None: freq = Period._maybe_convert_freq(freq) if isinstance(values, ABCSeries): values = values._values if not isinstance(values, type(self)): raise TypeError("Incorrect dtype") elif isinstance(values, ABCPeriodIndex): values = values._values if isinstance(values, type(self)): if freq is not None and freq != values.freq: raise raise_on_incompatible(values, freq) values, freq = values._data, values.freq values = np.array(values, dtype="int64", copy=copy) self._data = values if freq is None: raise ValueError("freq is not specified and cannot be inferred") self._dtype = PeriodDtype(freq) @classmethod def _simple_new( cls, values: np.ndarray, freq: Optional[BaseOffset] = None, dtype=None ) -> "PeriodArray": # alias for PeriodArray.__init__ assertion_msg = "Should be numpy array of type i8" assert isinstance(values, np.ndarray) and values.dtype == "i8", assertion_msg return cls(values, freq=freq, dtype=dtype) @classmethod def _from_sequence( cls: Type["PeriodArray"], scalars: Union[Sequence[Optional[Period]], AnyArrayLike], *, dtype: Optional[PeriodDtype] = None, copy: bool = False, ) -> "PeriodArray": if dtype: freq = dtype.freq else: freq = None if isinstance(scalars, cls): validate_dtype_freq(scalars.dtype, freq) if copy: scalars = scalars.copy() return scalars periods = np.asarray(scalars, dtype=object) freq = freq or libperiod.extract_freq(periods) ordinals = libperiod.extract_ordinals(periods, freq) return cls(ordinals, freq=freq) @classmethod def _from_sequence_of_strings( cls, strings, *, dtype=None, copy=False ) -> "PeriodArray": return cls._from_sequence(strings, dtype=dtype, copy=copy) @classmethod def _from_datetime64(cls, data, freq, tz=None) -> "PeriodArray": """ Construct a PeriodArray from a datetime64 array Parameters ---------- data : ndarray[datetime64[ns], datetime64[ns, tz]] freq : str or Tick tz : tzinfo, optional Returns ------- PeriodArray[freq] """ data, freq = dt64arr_to_periodarr(data, freq, tz) return cls(data, freq=freq) @classmethod def _generate_range(cls, start, end, periods, freq, fields): periods = dtl.validate_periods(periods) if freq is not None: freq = Period._maybe_convert_freq(freq) field_count = len(fields) if start is not None or end is not None: if field_count > 0: raise ValueError( "Can either instantiate from fields or endpoints, but not both" ) subarr, freq = _get_ordinal_range(start, end, periods, freq) elif field_count > 0: subarr, freq = _range_from_fields(freq=freq, **fields) else: raise ValueError("Not enough parameters to construct Period range") return subarr, freq # ----------------------------------------------------------------- # DatetimeLike Interface def _unbox_scalar( self, value: Union[Period, NaTType], setitem: bool = False ) -> int: if value is NaT: return np.int64(value.value) elif isinstance(value, self._scalar_type): self._check_compatible_with(value, setitem=setitem) return np.int64(value.ordinal) else: raise ValueError(f"'value' should be a Period. Got '{value}' instead.") def _scalar_from_string(self, value: str) -> Period: return Period(value, freq=self.freq) def _check_compatible_with(self, other, setitem: bool = False): if other is NaT: return if self.freqstr != other.freqstr: raise raise_on_incompatible(self, other) # -------------------------------------------------------------------- # Data / Attributes @cache_readonly def dtype(self) -> PeriodDtype: return self._dtype # error: Read-only property cannot override read-write property @property # type: ignore[misc] def freq(self) -> BaseOffset: """ Return the frequency object for this PeriodArray. """ return self.dtype.freq def __array__(self, dtype=None) -> np.ndarray: if dtype == "i8": return self.asi8 elif dtype == bool: return ~self._isnan # This will raise TypeError for non-object dtypes return np.array(list(self), dtype=object) def __arrow_array__(self, type=None): """ Convert myself into a pyarrow Array. """ import pyarrow from pandas.core.arrays._arrow_utils import ArrowPeriodType if type is not None: if pyarrow.types.is_integer(type): return pyarrow.array(self._data, mask=self.isna(), type=type) elif isinstance(type, ArrowPeriodType): # ensure we have the same freq if self.freqstr != type.freq: raise TypeError( "Not supported to convert PeriodArray to array with different " f"'freq' ({self.freqstr} vs {type.freq})" ) else: raise TypeError( f"Not supported to convert PeriodArray to '{type}' type" ) period_type = ArrowPeriodType(self.freqstr) storage_array = pyarrow.array(self._data, mask=self.isna(), type="int64") return pyarrow.ExtensionArray.from_storage(period_type, storage_array) # -------------------------------------------------------------------- # Vectorized analogues of Period properties year = _field_accessor( "year", """ The year of the period. """, ) month = _field_accessor( "month", """ The month as January=1, December=12. """, ) day = _field_accessor( "day", """ The days of the period. """, ) hour = _field_accessor( "hour", """ The hour of the period. """, ) minute = _field_accessor( "minute", """ The minute of the period. """, ) second = _field_accessor( "second", """ The second of the period. """, ) weekofyear = _field_accessor( "week", """ The week ordinal of the year. """, ) week = weekofyear day_of_week = _field_accessor( "day_of_week", """ The day of the week with Monday=0, Sunday=6. """, ) dayofweek = day_of_week weekday = dayofweek dayofyear = day_of_year = _field_accessor( "day_of_year", """ The ordinal day of the year. """, ) quarter = _field_accessor( "quarter", """ The quarter of the date. """, ) qyear = _field_accessor("qyear") days_in_month = _field_accessor( "days_in_month", """ The number of days in the month. """, ) daysinmonth = days_in_month @property def is_leap_year(self) -> np.ndarray: """ Logical indicating if the date belongs to a leap year. """ return isleapyear_arr(np.asarray(self.year)) @property def start_time(self): return self.to_timestamp(how="start") @property def end_time(self): return self.to_timestamp(how="end") def to_timestamp(self, freq=None, how="start"): """ Cast to DatetimeArray/Index. Parameters ---------- freq : str or DateOffset, optional Target frequency. The default is 'D' for week or longer, 'S' otherwise. how : {'s', 'e', 'start', 'end'} Whether to use the start or end of the time period being converted. Returns ------- DatetimeArray/Index """ from pandas.core.arrays import DatetimeArray how = libperiod.validate_end_alias(how) end = how == "E" if end: if freq == "B" or self.freq == "B": # roll forward to ensure we land on B date adjust = Timedelta(1, "D") - Timedelta(1, "ns") return self.to_timestamp(how="start") + adjust else: adjust = Timedelta(1, "ns") return (self + self.freq).to_timestamp(how="start") - adjust if freq is None: freq = self._get_to_timestamp_base() base = freq else: freq = Period._maybe_convert_freq(freq) base = freq._period_dtype_code new_data = self.asfreq(freq, how=how) new_data = libperiod.periodarr_to_dt64arr(new_data.asi8, base) return DatetimeArray(new_data)._with_freq("infer") # -------------------------------------------------------------------- def _time_shift(self, periods, freq=None): """ Shift each value by `periods`. Note this is different from ExtensionArray.shift, which shifts the *position* of each element, padding the end with missing values. Parameters ---------- periods : int Number of periods to shift by. freq : pandas.DateOffset, pandas.Timedelta, or str Frequency increment to shift by. """ if freq is not None: raise TypeError( "`freq` argument is not supported for " f"{type(self).__name__}._time_shift" ) values = self.asi8 + periods * self.freq.n if self._hasnans: values[self._isnan] = iNaT return type(self)(values, freq=self.freq) def _box_func(self, x) -> Union[Period, NaTType]: return Period._from_ordinal(ordinal=x, freq=self.freq) def asfreq(self, freq=None, how: str = "E") -> "PeriodArray": """ Convert the Period Array/Index to the specified frequency `freq`. Parameters ---------- freq : str A frequency. how : str {'E', 'S'} Whether the elements should be aligned to the end or start within pa period. * 'E', 'END', or 'FINISH' for end, * 'S', 'START', or 'BEGIN' for start. January 31st ('END') vs. January 1st ('START') for example. Returns ------- Period Array/Index Constructed with the new frequency. Examples -------- >>> pidx = pd.period_range('2010-01-01', '2015-01-01', freq='A') >>> pidx PeriodIndex(['2010', '2011', '2012', '2013', '2014', '2015'], dtype='period[A-DEC]', freq='A-DEC') >>> pidx.asfreq('M') PeriodIndex(['2010-12', '2011-12', '2012-12', '2013-12', '2014-12', '2015-12'], dtype='period[M]', freq='M') >>> pidx.asfreq('M', how='S') PeriodIndex(['2010-01', '2011-01', '2012-01', '2013-01', '2014-01', '2015-01'], dtype='period[M]', freq='M') """ how = libperiod.validate_end_alias(how) freq = Period._maybe_convert_freq(freq) base1 = self.freq._period_dtype_code base2 = freq._period_dtype_code asi8 = self.asi8 # self.freq.n can't be negative or 0 end = how == "E" if end: ordinal = asi8 + self.freq.n - 1 else: ordinal = asi8 new_data = period_asfreq_arr(ordinal, base1, base2, end) if self._hasnans: new_data[self._isnan] = iNaT return type(self)(new_data, freq=freq) # ------------------------------------------------------------------ # Rendering Methods def _formatter(self, boxed: bool = False): if boxed: return str return "'{}'".format def _format_native_types(self, na_rep="NaT", date_format=None, **kwargs): """ actually format my specific types """ values = self.astype(object) if date_format: formatter = lambda dt: dt.strftime(date_format) else: formatter = lambda dt: str(dt) if self._hasnans: mask = self._isnan values[mask] = na_rep imask = ~mask values[imask] = np.array([formatter(dt) for dt in values[imask]]) else: values = np.array([formatter(dt) for dt in values]) return values # ------------------------------------------------------------------ def astype(self, dtype, copy: bool = True): # We handle Period[T] -> Period[U] # Our parent handles everything else. dtype = pandas_dtype(dtype) if is_dtype_equal(dtype, self._dtype): if not copy: return self else: return self.copy() if is_period_dtype(dtype): return self.asfreq(dtype.freq) return super().astype(dtype, copy=copy) def searchsorted(self, value, side="left", sorter=None) -> np.ndarray: value = self._validate_searchsorted_value(value).view("M8[ns]") # Cast to M8 to get datetime-like NaT placement m8arr = self._ndarray.view("M8[ns]") return m8arr.searchsorted(value, side=side, sorter=sorter) # ------------------------------------------------------------------ # Arithmetic Methods def _sub_datelike(self, other): assert other is not NaT return NotImplemented def _sub_period(self, other): # If the operation is well-defined, we return an object-Index # of DateOffsets. Null entries are filled with pd.NaT self._check_compatible_with(other) asi8 = self.asi8 new_data = asi8 - other.ordinal new_data = np.array([self.freq * x for x in new_data]) if self._hasnans: new_data[self._isnan] = NaT return new_data def _sub_period_array(self, other): """ Subtract a Period Array/Index from self. This is only valid if self is itself a Period Array/Index, raises otherwise. Both objects must have the same frequency. Parameters ---------- other : PeriodIndex or PeriodArray Returns ------- result : np.ndarray[object] Array of DateOffset objects; nulls represented by NaT. """ if self.freq != other.freq: msg = DIFFERENT_FREQ.format( cls=type(self).__name__, own_freq=self.freqstr, other_freq=other.freqstr ) raise IncompatibleFrequency(msg) new_values = algos.checked_add_with_arr( self.asi8, -other.asi8, arr_mask=self._isnan, b_mask=other._isnan ) new_values = np.array([self.freq.base * x for x in new_values]) if self._hasnans or other._hasnans: mask = self._isnan | other._isnan new_values[mask] = NaT return new_values def _addsub_int_array( self, other: np.ndarray, op: Callable[[Any, Any], Any] ) -> "PeriodArray": """ Add or subtract array of integers; equivalent to applying `_time_shift` pointwise. Parameters ---------- other : np.ndarray[integer-dtype] op : {operator.add, operator.sub} Returns ------- result : PeriodArray """ assert op in [operator.add, operator.sub] if op is operator.sub: other = -other res_values = algos.checked_add_with_arr(self.asi8, other, arr_mask=self._isnan) res_values = res_values.view("i8") np.putmask(res_values, self._isnan, iNaT) return type(self)(res_values, freq=self.freq) def _add_offset(self, other: BaseOffset): assert not isinstance(other, Tick) if other.base != self.freq.base: raise raise_on_incompatible(self, other) # Note: when calling parent class's _add_timedeltalike_scalar, # it will call delta_to_nanoseconds(delta). Because delta here # is an integer, delta_to_nanoseconds will return it unchanged. result = super()._add_timedeltalike_scalar(other.n) return type(self)(result, freq=self.freq) def _add_timedeltalike_scalar(self, other): """ Parameters ---------- other : timedelta, Tick, np.timedelta64 Returns ------- PeriodArray """ if not isinstance(self.freq, Tick): # We cannot add timedelta-like to non-tick PeriodArray raise raise_on_incompatible(self, other) if notna(other): # special handling for np.timedelta64("NaT"), avoid calling # _check_timedeltalike_freq_compat as that would raise TypeError other = self._check_timedeltalike_freq_compat(other) # Note: when calling parent class's _add_timedeltalike_scalar, # it will call delta_to_nanoseconds(delta). Because delta here # is an integer, delta_to_nanoseconds will return it unchanged. return super()._add_timedeltalike_scalar(other) def _add_timedelta_arraylike(self, other): """ Parameters ---------- other : TimedeltaArray or ndarray[timedelta64] Returns ------- result : ndarray[int64] """ if not isinstance(self.freq, Tick): # We cannot add timedelta-like to non-tick PeriodArray raise TypeError( f"Cannot add or subtract timedelta64[ns] dtype from {self.dtype}" ) if not np.all(isna(other)): delta = self._check_timedeltalike_freq_compat(other) else: # all-NaT TimedeltaIndex is equivalent to a single scalar td64 NaT return self + np.timedelta64("NaT") ordinals = self._addsub_int_array(delta, operator.add).asi8 return type(self)(ordinals, dtype=self.dtype) def _check_timedeltalike_freq_compat(self, other): """ Arithmetic operations with timedelta-like scalars or array `other` are only valid if `other` is an integer multiple of `self.freq`. If the operation is valid, find that integer multiple. Otherwise, raise because the operation is invalid. Parameters ---------- other : timedelta, np.timedelta64, Tick, ndarray[timedelta64], TimedeltaArray, TimedeltaIndex Returns ------- multiple : int or ndarray[int64] Raises ------ IncompatibleFrequency """ assert isinstance(self.freq, Tick) # checked by calling function base_nanos = self.freq.base.nanos if isinstance(other, (timedelta, np.timedelta64, Tick)): nanos = delta_to_nanoseconds(other) elif isinstance(other, np.ndarray): # numpy timedelta64 array; all entries must be compatible assert other.dtype.kind == "m" if other.dtype != TD64NS_DTYPE: # i.e. non-nano unit # TODO: disallow unit-less timedelta64 other = other.astype(TD64NS_DTYPE) nanos = other.view("i8") else: # TimedeltaArray/Index nanos = other.asi8 if np.all(nanos % base_nanos == 0): # nanos being added is an integer multiple of the # base-frequency to self.freq delta = nanos // base_nanos # delta is the integer (or integer-array) number of periods # by which will be added to self. return delta raise raise_on_incompatible(self, other) def raise_on_incompatible(left, right): """ Helper function to render a consistent error message when raising IncompatibleFrequency. Parameters ---------- left : PeriodArray right : None, DateOffset, Period, ndarray, or timedelta-like Returns ------- IncompatibleFrequency Exception to be raised by the caller. """ # GH#24283 error message format depends on whether right is scalar if isinstance(right, (np.ndarray, ABCTimedeltaArray)) or right is None: other_freq = None elif isinstance(right, (ABCPeriodIndex, PeriodArray, Period, BaseOffset)): other_freq = right.freqstr else: other_freq = delta_to_tick(Timedelta(right)).freqstr msg = DIFFERENT_FREQ.format( cls=type(left).__name__, own_freq=left.freqstr, other_freq=other_freq ) return IncompatibleFrequency(msg) # ------------------------------------------------------------------- # Constructor Helpers def period_array( data: Union[Sequence[Optional[Period]], AnyArrayLike], freq: Optional[Union[str, Tick]] = None, copy: bool = False, ) -> PeriodArray: """ Construct a new PeriodArray from a sequence of Period scalars. Parameters ---------- data : Sequence of Period objects A sequence of Period objects. These are required to all have the same ``freq.`` Missing values can be indicated by ``None`` or ``pandas.NaT``. freq : str, Tick, or Offset The frequency of every element of the array. This can be specified to avoid inferring the `freq` from `data`. copy : bool, default False Whether to ensure a copy of the data is made. Returns ------- PeriodArray See Also -------- PeriodArray pandas.PeriodIndex Examples -------- >>> period_array([pd.Period('2017', freq='A'), ... pd.Period('2018', freq='A')]) ['2017', '2018'] Length: 2, dtype: period[A-DEC] >>> period_array([pd.Period('2017', freq='A'), ... pd.Period('2018', freq='A'), ... pd.NaT]) ['2017', '2018', 'NaT'] Length: 3, dtype: period[A-DEC] Integers that look like years are handled >>> period_array([2000, 2001, 2002], freq='D') ['2000-01-01', '2001-01-01', '2002-01-01'] Length: 3, dtype: period[D] Datetime-like strings may also be passed >>> period_array(['2000-Q1', '2000-Q2', '2000-Q3', '2000-Q4'], freq='Q') ['2000Q1', '2000Q2', '2000Q3', '2000Q4'] Length: 4, dtype: period[Q-DEC] """ data_dtype = getattr(data, "dtype", None) if is_datetime64_dtype(data_dtype): return PeriodArray._from_datetime64(data, freq) if is_period_dtype(data_dtype): return PeriodArray(data, freq=freq) # other iterable of some kind if not isinstance(data, (np.ndarray, list, tuple, ABCSeries)): data = list(data) data = np.asarray(data) dtype: Optional[PeriodDtype] if freq: dtype = PeriodDtype(freq) else: dtype = None if is_float_dtype(data) and len(data) > 0: raise TypeError("PeriodIndex does not allow floating point in construction") data = ensure_object(data) return PeriodArray._from_sequence(data, dtype=dtype) def validate_dtype_freq(dtype, freq): """ If both a dtype and a freq are available, ensure they match. If only dtype is available, extract the implied freq. Parameters ---------- dtype : dtype freq : DateOffset or None Returns ------- freq : DateOffset Raises ------ ValueError : non-period dtype IncompatibleFrequency : mismatch between dtype and freq """ if freq is not None: freq = to_offset(freq) if dtype is not None: dtype = pandas_dtype(dtype) if not is_period_dtype(dtype): raise ValueError("dtype must be PeriodDtype") if freq is None: freq = dtype.freq elif freq != dtype.freq: raise IncompatibleFrequency("specified freq and dtype are different") return freq def dt64arr_to_periodarr(data, freq, tz=None): """ Convert an datetime-like array to values Period ordinals. Parameters ---------- data : Union[Series[datetime64[ns]], DatetimeIndex, ndarray[datetime64ns]] freq : Optional[Union[str, Tick]] Must match the `freq` on the `data` if `data` is a DatetimeIndex or Series. tz : Optional[tzinfo] Returns ------- ordinals : ndarray[int] freq : Tick The frequency extracted from the Series or DatetimeIndex if that's used. """ if data.dtype != np.dtype("M8[ns]"): raise ValueError(f"Wrong dtype: {data.dtype}") if freq is None: if isinstance(data, ABCIndexClass): data, freq = data._values, data.freq elif isinstance(data, ABCSeries): data, freq = data._values, data.dt.freq freq = Period._maybe_convert_freq(freq) if isinstance(data, (ABCIndexClass, ABCSeries)): data = data._values base = freq._period_dtype_code return c_dt64arr_to_periodarr(data.view("i8"), base, tz), freq def _get_ordinal_range(start, end, periods, freq, mult=1): if com.count_not_none(start, end, periods) != 2: raise ValueError( "Of the three parameters: start, end, and periods, " "exactly two must be specified" ) if freq is not None: freq = to_offset(freq) mult = freq.n if start is not None: start = Period(start, freq) if end is not None: end = Period(end, freq) is_start_per = isinstance(start, Period) is_end_per = isinstance(end, Period) if is_start_per and is_end_per and start.freq != end.freq: raise ValueError("start and end must have same freq") if start is NaT or end is NaT: raise ValueError("start and end must not be NaT") if freq is None: if is_start_per: freq = start.freq elif is_end_per: freq = end.freq else: # pragma: no cover raise ValueError("Could not infer freq from start/end") if periods is not None: periods = periods * mult if start is None: data = np.arange( end.ordinal - periods + mult, end.ordinal + 1, mult, dtype=np.int64 ) else: data = np.arange( start.ordinal, start.ordinal + periods, mult, dtype=np.int64 ) else: data = np.arange(start.ordinal, end.ordinal + 1, mult, dtype=np.int64) return data, freq def _range_from_fields( year=None, month=None, quarter=None, day=None, hour=None, minute=None, second=None, freq=None, ): if hour is None: hour = 0 if minute is None: minute = 0 if second is None: second = 0 if day is None: day = 1 ordinals = [] if quarter is not None: if freq is None: freq = to_offset("Q") base = FreqGroup.FR_QTR else: freq = to_offset(freq) base = libperiod.freq_to_dtype_code(freq) if base != FreqGroup.FR_QTR: raise AssertionError("base must equal FR_QTR") freqstr = freq.freqstr year, quarter = _make_field_arrays(year, quarter) for y, q in zip(year, quarter): y, m = libperiod.quarter_to_myear(y, q, freqstr) val = libperiod.period_ordinal(y, m, 1, 1, 1, 1, 0, 0, base) ordinals.append(val) else: freq = to_offset(freq) base = libperiod.freq_to_dtype_code(freq) arrays = _make_field_arrays(year, month, day, hour, minute, second) for y, mth, d, h, mn, s in zip(*arrays): ordinals.append(libperiod.period_ordinal(y, mth, d, h, mn, s, 0, 0, base)) return np.array(ordinals, dtype=np.int64), freq def _make_field_arrays(*fields): length = None for x in fields: if isinstance(x, (list, np.ndarray, ABCSeries)): if length is not None and len(x) != length: raise ValueError("Mismatched Period array lengths") elif length is None: length = len(x) return [ np.asarray(x) if isinstance(x, (np.ndarray, list, ABCSeries)) else np.repeat(x, length) for x in fields ]