def test_astype_object(self, period_index): pi = period_index arr = PeriodArray(pi) asobj = arr.astype('O') assert isinstance(asobj, np.ndarray) assert asobj.dtype == 'O' assert list(asobj) == list(pi)
def test_to_timestamp(self, how, period_index): pi = period_index arr = PeriodArray(pi) expected = DatetimeArray(pi.to_timestamp(how=how)) result = arr.to_timestamp(how=how) assert isinstance(result, DatetimeArray) # placeholder until these become actual EA subclasses and we can use # an EA-specific tm.assert_ function tm.assert_index_equal(pd.Index(result), pd.Index(expected))
def test_from_datetime64_freq_changes(): # https://github.com/pandas-dev/pandas/issues/23438 arr = pd.date_range("2017", periods=3, freq="D") result = PeriodArray._from_datetime64(arr, freq="M") expected = period_array(['2017-01-01', '2017-01-01', '2017-01-01'], freq="M") tm.assert_period_array_equal(result, expected)
def test_end_time_timevalues(self, input_vals): # GH 17157 # Check that the time part of the Period is adjusted by end_time # when using the dt accessor on a Series input_vals = PeriodArray._from_sequence(np.asarray(input_vals)) s = Series(input_vals) result = s.dt.end_time expected = s.apply(lambda x: x.end_time) tm.assert_series_equal(result, expected)
def data_missing_for_sorting(dtype): return PeriodArray([2018, iNaT, 2017], freq=dtype.freq)
def data_for_sorting(dtype): return PeriodArray([2018, 2019, 2017], freq=dtype.freq)
def data_missing(dtype): return PeriodArray([iNaT, 2017], freq=dtype.freq)
def array( data: Sequence[object] | AnyArrayLike, dtype: Dtype | None = None, copy: bool = True, ) -> ExtensionArray: """ Create an array. Parameters ---------- data : Sequence of objects The scalars inside `data` should be instances of the scalar type for `dtype`. It's expected that `data` represents a 1-dimensional array of data. When `data` is an Index or Series, the underlying array will be extracted from `data`. dtype : str, np.dtype, or ExtensionDtype, optional The dtype to use for the array. This may be a NumPy dtype or an extension type registered with pandas using :meth:`pandas.api.extensions.register_extension_dtype`. If not specified, there are two possibilities: 1. When `data` is a :class:`Series`, :class:`Index`, or :class:`ExtensionArray`, the `dtype` will be taken from the data. 2. Otherwise, pandas will attempt to infer the `dtype` from the data. Note that when `data` is a NumPy array, ``data.dtype`` is *not* used for inferring the array type. This is because NumPy cannot represent all the types of data that can be held in extension arrays. Currently, pandas will infer an extension dtype for sequences of ============================== ======================================= Scalar Type Array Type ============================== ======================================= :class:`pandas.Interval` :class:`pandas.arrays.IntervalArray` :class:`pandas.Period` :class:`pandas.arrays.PeriodArray` :class:`datetime.datetime` :class:`pandas.arrays.DatetimeArray` :class:`datetime.timedelta` :class:`pandas.arrays.TimedeltaArray` :class:`int` :class:`pandas.arrays.IntegerArray` :class:`float` :class:`pandas.arrays.FloatingArray` :class:`str` :class:`pandas.arrays.StringArray` or :class:`pandas.arrays.ArrowStringArray` :class:`bool` :class:`pandas.arrays.BooleanArray` ============================== ======================================= The ExtensionArray created when the scalar type is :class:`str` is determined by ``pd.options.mode.string_storage`` if the dtype is not explicitly given. For all other cases, NumPy's usual inference rules will be used. .. versionchanged:: 1.0.0 Pandas infers nullable-integer dtype for integer data, string dtype for string data, and nullable-boolean dtype for boolean data. .. versionchanged:: 1.2.0 Pandas now also infers nullable-floating dtype for float-like input data copy : bool, default True Whether to copy the data, even if not necessary. Depending on the type of `data`, creating the new array may require copying data, even if ``copy=False``. Returns ------- ExtensionArray The newly created array. Raises ------ ValueError When `data` is not 1-dimensional. See Also -------- numpy.array : Construct a NumPy array. Series : Construct a pandas Series. Index : Construct a pandas Index. arrays.PandasArray : ExtensionArray wrapping a NumPy array. Series.array : Extract the array stored within a Series. Notes ----- Omitting the `dtype` argument means pandas will attempt to infer the best array type from the values in the data. As new array types are added by pandas and 3rd party libraries, the "best" array type may change. We recommend specifying `dtype` to ensure that 1. the correct array type for the data is returned 2. the returned array type doesn't change as new extension types are added by pandas and third-party libraries Additionally, if the underlying memory representation of the returned array matters, we recommend specifying the `dtype` as a concrete object rather than a string alias or allowing it to be inferred. For example, a future version of pandas or a 3rd-party library may include a dedicated ExtensionArray for string data. In this event, the following would no longer return a :class:`arrays.PandasArray` backed by a NumPy array. >>> pd.array(['a', 'b'], dtype=str) <PandasArray> ['a', 'b'] Length: 2, dtype: str32 This would instead return the new ExtensionArray dedicated for string data. If you really need the new array to be backed by a NumPy array, specify that in the dtype. >>> pd.array(['a', 'b'], dtype=np.dtype("<U1")) <PandasArray> ['a', 'b'] Length: 2, dtype: str32 Finally, Pandas has arrays that mostly overlap with NumPy * :class:`arrays.DatetimeArray` * :class:`arrays.TimedeltaArray` When data with a ``datetime64[ns]`` or ``timedelta64[ns]`` dtype is passed, pandas will always return a ``DatetimeArray`` or ``TimedeltaArray`` rather than a ``PandasArray``. This is for symmetry with the case of timezone-aware data, which NumPy does not natively support. >>> pd.array(['2015', '2016'], dtype='datetime64[ns]') <DatetimeArray> ['2015-01-01 00:00:00', '2016-01-01 00:00:00'] Length: 2, dtype: datetime64[ns] >>> pd.array(["1H", "2H"], dtype='timedelta64[ns]') <TimedeltaArray> ['0 days 01:00:00', '0 days 02:00:00'] Length: 2, dtype: timedelta64[ns] Examples -------- If a dtype is not specified, pandas will infer the best dtype from the values. See the description of `dtype` for the types pandas infers for. >>> pd.array([1, 2]) <IntegerArray> [1, 2] Length: 2, dtype: Int64 >>> pd.array([1, 2, np.nan]) <IntegerArray> [1, 2, <NA>] Length: 3, dtype: Int64 >>> pd.array([1.1, 2.2]) <FloatingArray> [1.1, 2.2] Length: 2, dtype: Float64 >>> pd.array(["a", None, "c"]) <StringArray> ['a', <NA>, 'c'] Length: 3, dtype: string >>> with pd.option_context("string_storage", "pyarrow"): ... arr = pd.array(["a", None, "c"]) ... >>> arr <ArrowStringArray> ['a', <NA>, 'c'] Length: 3, dtype: string >>> pd.array([pd.Period('2000', freq="D"), pd.Period("2000", freq="D")]) <PeriodArray> ['2000-01-01', '2000-01-01'] Length: 2, dtype: period[D] You can use the string alias for `dtype` >>> pd.array(['a', 'b', 'a'], dtype='category') ['a', 'b', 'a'] Categories (2, object): ['a', 'b'] Or specify the actual dtype >>> pd.array(['a', 'b', 'a'], ... dtype=pd.CategoricalDtype(['a', 'b', 'c'], ordered=True)) ['a', 'b', 'a'] Categories (3, object): ['a' < 'b' < 'c'] If pandas does not infer a dedicated extension type a :class:`arrays.PandasArray` is returned. >>> pd.array([1 + 1j, 3 + 2j]) <PandasArray> [(1+1j), (3+2j)] Length: 2, dtype: complex128 As mentioned in the "Notes" section, new extension types may be added in the future (by pandas or 3rd party libraries), causing the return value to no longer be a :class:`arrays.PandasArray`. Specify the `dtype` as a NumPy dtype if you need to ensure there's no future change in behavior. >>> pd.array([1, 2], dtype=np.dtype("int32")) <PandasArray> [1, 2] Length: 2, dtype: int32 `data` must be 1-dimensional. A ValueError is raised when the input has the wrong dimensionality. >>> pd.array(1) Traceback (most recent call last): ... ValueError: Cannot pass scalar '1' to 'pandas.array'. """ from pandas.core.arrays import ( BooleanArray, DatetimeArray, ExtensionArray, FloatingArray, IntegerArray, IntervalArray, PandasArray, PeriodArray, TimedeltaArray, ) from pandas.core.arrays.string_ import StringDtype if lib.is_scalar(data): msg = f"Cannot pass scalar '{data}' to 'pandas.array'." raise ValueError(msg) if dtype is None and isinstance(data, (ABCSeries, ABCIndex, ExtensionArray)): # Note: we exclude np.ndarray here, will do type inference on it dtype = data.dtype data = extract_array(data, extract_numpy=True) # this returns None for not-found dtypes. if isinstance(dtype, str): dtype = registry.find(dtype) or dtype if is_extension_array_dtype(dtype): cls = cast(ExtensionDtype, dtype).construct_array_type() return cls._from_sequence(data, dtype=dtype, copy=copy) if dtype is None: inferred_dtype = lib.infer_dtype(data, skipna=True) if inferred_dtype == "period": return PeriodArray._from_sequence(data, copy=copy) elif inferred_dtype == "interval": return IntervalArray(data, copy=copy) elif inferred_dtype.startswith("datetime"): # datetime, datetime64 try: return DatetimeArray._from_sequence(data, copy=copy) except ValueError: # Mixture of timezones, fall back to PandasArray pass elif inferred_dtype.startswith("timedelta"): # timedelta, timedelta64 return TimedeltaArray._from_sequence(data, copy=copy) elif inferred_dtype == "string": # StringArray/ArrowStringArray depending on pd.options.mode.string_storage return StringDtype().construct_array_type()._from_sequence( data, copy=copy) elif inferred_dtype == "integer": return IntegerArray._from_sequence(data, copy=copy) elif (inferred_dtype in ("floating", "mixed-integer-float") and getattr(data, "dtype", None) != np.float16): # GH#44715 Exclude np.float16 bc FloatingArray does not support it; # we will fall back to PandasArray. return FloatingArray._from_sequence(data, copy=copy) elif inferred_dtype == "boolean": return BooleanArray._from_sequence(data, copy=copy) # Pandas overrides NumPy for # 1. datetime64[ns] # 2. timedelta64[ns] # so that a DatetimeArray is returned. if is_datetime64_ns_dtype(dtype): return DatetimeArray._from_sequence(data, dtype=dtype, copy=copy) elif is_timedelta64_ns_dtype(dtype): return TimedeltaArray._from_sequence(data, dtype=dtype, copy=copy) return PandasArray._from_sequence(data, dtype=dtype, copy=copy)
def data_for_twos(dtype): return PeriodArray(np.ones(100) * 2, freq=dtype.freq)
def test_setitem_raises_length(): arr = PeriodArray(np.arange(3), freq="D") with pytest.raises(ValueError, match="length"): arr[[0, 1]] = [pd.Period("2000", freq="D")]
def test_period_array_non_period_series_raies(): ser = pd.Series([1, 2, 3]) with pytest.raises(TypeError, match='dtype'): PeriodArray(ser, freq='D')
def data_for_grouping(dtype): B = 2018 NA = iNaT A = 2017 C = 2019 return PeriodArray([B, B, NA, NA, A, A, B, C], freq=dtype.freq)
def maybe_downcast_to_dtype(result, dtype): """ try to cast to the specified dtype (e.g. convert back to bool/int or could be an astype of float64->float32 """ do_round = False if is_scalar(result): return result elif isinstance(result, ABCDataFrame): # occurs in pivot_table doctest return result if isinstance(dtype, str): if dtype == "infer": inferred_type = lib.infer_dtype(ensure_object(result.ravel()), skipna=False) if inferred_type == "boolean": dtype = "bool" elif inferred_type == "integer": dtype = "int64" elif inferred_type == "datetime64": dtype = "datetime64[ns]" elif inferred_type == "timedelta64": dtype = "timedelta64[ns]" # try to upcast here elif inferred_type == "floating": dtype = "int64" if issubclass(result.dtype.type, np.number): do_round = True else: dtype = "object" dtype = np.dtype(dtype) converted = maybe_downcast_numeric(result, dtype, do_round) if converted is not result: return converted # a datetimelike # GH12821, iNaT is casted to float if dtype.kind in ["M", "m"] and result.dtype.kind in ["i", "f"]: if hasattr(dtype, "tz"): # not a numpy dtype if dtype.tz: # convert to datetime and change timezone from pandas import to_datetime result = to_datetime(result).tz_localize("utc") result = result.tz_convert(dtype.tz) else: result = result.astype(dtype) elif dtype.type is Period: # TODO(DatetimeArray): merge with previous elif from pandas.core.arrays import PeriodArray try: return PeriodArray(result, freq=dtype.freq) except TypeError: # e.g. TypeError: int() argument must be a string, a # bytes-like object or a number, not 'Period pass return result
def test_period_array_non_period_series_raies(): ser = pd.Series([1, 2, 3]) with tm.assert_raises_regex(TypeError, 'dtype'): PeriodArray(ser, freq='D')
def test_from_datetime64_raises(): arr = pd.date_range("2017", periods=3, freq="D") with tm.assert_raises_regex(IncompatibleFrequency, "freq"): PeriodArray._from_datetime64(arr, freq="M")
def test_setitem_raises_type(): arr = PeriodArray(np.arange(3), freq="D") with tm.assert_raises_regex(TypeError, "int"): arr[0] = 1
def test_setitem_raises_length(): arr = PeriodArray(np.arange(3), freq="D") with tm.assert_raises_regex(ValueError, "length"): arr[[0, 1]] = [pd.Period("2000", freq="D")]
def test_from_datetime64_freq_changes(): # https://github.com/pandas-dev/pandas/issues/23438 arr = pd.date_range("2017", periods=3, freq="D") result = PeriodArray._from_datetime64(arr, freq="M") expected = period_array(["2017-01-01", "2017-01-01", "2017-01-01"], freq="M") tm.assert_period_array_equal(result, expected)
def decode(obj): """ Decoder for deserializing numpy data types. """ typ = obj.get(u'typ') if typ is None: return obj elif typ == u'timestamp': freq = obj[u'freq'] if 'freq' in obj else obj[u'offset'] return Timestamp(obj[u'value'], tz=obj[u'tz'], freq=freq) elif typ == u'nat': return NaT elif typ == u'period': return Period(ordinal=obj[u'ordinal'], freq=obj[u'freq']) elif typ == u'index': dtype = dtype_for(obj[u'dtype']) data = unconvert(obj[u'data'], dtype, obj.get(u'compress')) return globals()[obj[u'klass']](data, dtype=dtype, name=obj[u'name']) elif typ == u'range_index': return globals()[obj[u'klass']](obj[u'start'], obj[u'stop'], obj[u'step'], name=obj[u'name']) elif typ == u'multi_index': dtype = dtype_for(obj[u'dtype']) data = unconvert(obj[u'data'], dtype, obj.get(u'compress')) data = [tuple(x) for x in data] return globals()[obj[u'klass']].from_tuples(data, names=obj[u'names']) elif typ == u'period_index': data = unconvert(obj[u'data'], np.int64, obj.get(u'compress')) d = dict(name=obj[u'name'], freq=obj[u'freq']) freq = d.pop('freq', None) return globals()[obj[u'klass']](PeriodArray(data, freq), **d) elif typ == u'datetime_index': data = unconvert(obj[u'data'], np.int64, obj.get(u'compress')) d = dict(name=obj[u'name'], freq=obj[u'freq'], verify_integrity=False) result = globals()[obj[u'klass']](data, **d) tz = obj[u'tz'] # reverse tz conversion if tz is not None: result = result.tz_localize('UTC').tz_convert(tz) return result elif typ in (u'interval_index', 'interval_array'): return globals()[obj[u'klass']].from_arrays(obj[u'left'], obj[u'right'], obj[u'closed'], name=obj[u'name']) elif typ == u'category': from_codes = globals()[obj[u'klass']].from_codes return from_codes(codes=obj[u'codes'], categories=obj[u'categories'], ordered=obj[u'ordered']) elif typ == u'interval': return Interval(obj[u'left'], obj[u'right'], obj[u'closed']) elif typ == u'series': dtype = dtype_for(obj[u'dtype']) pd_dtype = pandas_dtype(dtype) index = obj[u'index'] result = globals()[obj[u'klass']](unconvert(obj[u'data'], dtype, obj[u'compress']), index=index, dtype=pd_dtype, name=obj[u'name']) return result elif typ == u'block_manager': axes = obj[u'axes'] def create_block(b): values = _safe_reshape( unconvert(b[u'values'], dtype_for(b[u'dtype']), b[u'compress']), b[u'shape']) # locs handles duplicate column names, and should be used instead # of items; see GH 9618 if u'locs' in b: placement = b[u'locs'] else: placement = axes[0].get_indexer(b[u'items']) return make_block(values=values, klass=getattr(internals, b[u'klass']), placement=placement, dtype=b[u'dtype']) blocks = [create_block(b) for b in obj[u'blocks']] return globals()[obj[u'klass']](BlockManager(blocks, axes)) elif typ == u'datetime': return parse(obj[u'data']) elif typ == u'datetime64': return np.datetime64(parse(obj[u'data'])) elif typ == u'date': return parse(obj[u'data']).date() elif typ == u'timedelta': return timedelta(*obj[u'data']) elif typ == u'timedelta64': return np.timedelta64(int(obj[u'data'])) # elif typ == 'sparse_series': # dtype = dtype_for(obj['dtype']) # return globals()[obj['klass']]( # unconvert(obj['sp_values'], dtype, obj['compress']), # sparse_index=obj['sp_index'], index=obj['index'], # fill_value=obj['fill_value'], kind=obj['kind'], name=obj['name']) # elif typ == 'sparse_dataframe': # return globals()[obj['klass']]( # obj['data'], columns=obj['columns'], # default_fill_value=obj['default_fill_value'], # default_kind=obj['default_kind'] # ) # elif typ == 'sparse_panel': # return globals()[obj['klass']]( # obj['data'], items=obj['items'], # default_fill_value=obj['default_fill_value'], # default_kind=obj['default_kind']) elif typ == u'block_index': return globals()[obj[u'klass']](obj[u'length'], obj[u'blocs'], obj[u'blengths']) elif typ == u'int_index': return globals()[obj[u'klass']](obj[u'length'], obj[u'indices']) elif typ == u'ndarray': return unconvert(obj[u'data'], np.typeDict[obj[u'dtype']], obj.get(u'compress')).reshape(obj[u'shape']) elif typ == u'np_scalar': if obj.get(u'sub_typ') == u'np_complex': return c2f(obj[u'real'], obj[u'imag'], obj[u'dtype']) else: dtype = dtype_for(obj[u'dtype']) try: return dtype(obj[u'data']) except (ValueError, TypeError): return dtype.type(obj[u'data']) elif typ == u'np_complex': return complex(obj[u'real'] + u'+' + obj[u'imag'] + u'j') elif isinstance(obj, (dict, list, set)): return obj else: return obj
def test_strftime(self, period_index): arr = PeriodArray(period_index) result = arr.strftime("%Y") expected = np.array(period_index.strftime("%Y")) tm.assert_numpy_array_equal(result, expected)
def test_setitem(key, value, expected): arr = PeriodArray(np.arange(3), freq="D") expected = PeriodArray(expected, freq="D") arr[key] = value tm.assert_period_array_equal(arr, expected)
def decode(obj): """ Decoder for deserializing numpy data types. """ typ = obj.get("typ") if typ is None: return obj elif typ == "timestamp": freq = obj["freq"] if "freq" in obj else obj["offset"] return Timestamp(obj["value"], tz=obj["tz"], freq=freq) elif typ == "nat": return NaT elif typ == "period": return Period(ordinal=obj["ordinal"], freq=obj["freq"]) elif typ == "index": dtype = dtype_for(obj["dtype"]) data = unconvert(obj["data"], dtype, obj.get("compress")) return Index(data, dtype=dtype, name=obj["name"]) elif typ == "range_index": return RangeIndex(obj["start"], obj["stop"], obj["step"], name=obj["name"]) elif typ == "multi_index": dtype = dtype_for(obj["dtype"]) data = unconvert(obj["data"], dtype, obj.get("compress")) data = [tuple(x) for x in data] return MultiIndex.from_tuples(data, names=obj["names"]) elif typ == "period_index": data = unconvert(obj["data"], np.int64, obj.get("compress")) d = dict(name=obj["name"], freq=obj["freq"]) freq = d.pop("freq", None) return PeriodIndex(PeriodArray(data, freq), **d) elif typ == "datetime_index": data = unconvert(obj["data"], np.int64, obj.get("compress")) d = dict(name=obj["name"], freq=obj["freq"]) result = DatetimeIndex(data, **d) tz = obj["tz"] # reverse tz conversion if tz is not None: result = result.tz_localize("UTC").tz_convert(tz) return result elif typ in ("interval_index", "interval_array"): return globals()[obj["klass"]].from_arrays( obj["left"], obj["right"], obj["closed"], name=obj["name"] ) elif typ == "category": from_codes = globals()[obj["klass"]].from_codes return from_codes( codes=obj["codes"], categories=obj["categories"], ordered=obj["ordered"] ) elif typ == "interval": return Interval(obj["left"], obj["right"], obj["closed"]) elif typ == "series": dtype = dtype_for(obj["dtype"]) index = obj["index"] data = unconvert(obj["data"], dtype, obj["compress"]) return Series(data, index=index, dtype=dtype, name=obj["name"]) elif typ == "block_manager": axes = obj["axes"] def create_block(b): values = _safe_reshape( unconvert(b["values"], dtype_for(b["dtype"]), b["compress"]), b["shape"] ) # locs handles duplicate column names, and should be used instead # of items; see GH 9618 if "locs" in b: placement = b["locs"] else: placement = axes[0].get_indexer(b["items"]) if is_datetime64tz_dtype(b["dtype"]): assert isinstance(values, np.ndarray), type(values) assert values.dtype == "M8[ns]", values.dtype values = DatetimeArray(values, dtype=b["dtype"]) return make_block( values=values, klass=getattr(internals, b["klass"]), placement=placement, dtype=b["dtype"], ) blocks = [create_block(b) for b in obj["blocks"]] return globals()[obj["klass"]](BlockManager(blocks, axes)) elif typ == "datetime": return parse(obj["data"]) elif typ == "datetime64": return np.datetime64(parse(obj["data"])) elif typ == "date": return parse(obj["data"]).date() elif typ == "timedelta": return timedelta(*obj["data"]) elif typ == "timedelta64": return np.timedelta64(int(obj["data"])) # elif typ == 'sparse_series': # dtype = dtype_for(obj['dtype']) # return SparseSeries( # unconvert(obj['sp_values'], dtype, obj['compress']), # sparse_index=obj['sp_index'], index=obj['index'], # fill_value=obj['fill_value'], kind=obj['kind'], name=obj['name']) # elif typ == 'sparse_dataframe': # return SparseDataFrame( # obj['data'], columns=obj['columns'], # default_fill_value=obj['default_fill_value'], # default_kind=obj['default_kind'] # ) elif typ == "block_index": return globals()[obj["klass"]](obj["length"], obj["blocs"], obj["blengths"]) elif typ == "int_index": return globals()[obj["klass"]](obj["length"], obj["indices"]) elif typ == "ndarray": return unconvert( obj["data"], np.typeDict[obj["dtype"]], obj.get("compress") ).reshape(obj["shape"]) elif typ == "np_scalar": if obj.get("sub_typ") == "np_complex": return c2f(obj["real"], obj["imag"], obj["dtype"]) else: dtype = dtype_for(obj["dtype"]) try: return dtype(obj["data"]) except (ValueError, TypeError): return dtype.type(obj["data"]) elif typ == "np_complex": return complex(obj["real"] + "+" + obj["imag"] + "j") elif isinstance(obj, (dict, list, set)): return obj else: return obj
def test_setitem_raises_type(): arr = PeriodArray(np.arange(3), freq="D") with pytest.raises(TypeError, match="int"): arr[0] = 1
def test_strftime(self, period_index): arr = PeriodArray(period_index) result = arr.strftime("%Y") expected = np.array([per.strftime("%Y") for per in arr], dtype=object) tm.assert_numpy_array_equal(result, expected)
def maybe_downcast_to_dtype(result, dtype): """ try to cast to the specified dtype (e.g. convert back to bool/int or could be an astype of float64->float32 """ if is_scalar(result): return result def trans(x): return x if isinstance(dtype, str): if dtype == 'infer': inferred_type = lib.infer_dtype(ensure_object(result.ravel()), skipna=False) if inferred_type == 'boolean': dtype = 'bool' elif inferred_type == 'integer': dtype = 'int64' elif inferred_type == 'datetime64': dtype = 'datetime64[ns]' elif inferred_type == 'timedelta64': dtype = 'timedelta64[ns]' # try to upcast here elif inferred_type == 'floating': dtype = 'int64' if issubclass(result.dtype.type, np.number): def trans(x): # noqa return x.round() else: dtype = 'object' if isinstance(dtype, str): dtype = np.dtype(dtype) try: # don't allow upcasts here (except if empty) if dtype.kind == result.dtype.kind: if (result.dtype.itemsize <= dtype.itemsize and np.prod(result.shape)): return result if is_bool_dtype(dtype) or is_integer_dtype(dtype): # if we don't have any elements, just astype it if not np.prod(result.shape): return trans(result).astype(dtype) # do a test on the first element, if it fails then we are done r = result.ravel() arr = np.array([r[0]]) # if we have any nulls, then we are done if (isna(arr).any() or not np.allclose(arr, trans(arr).astype(dtype), rtol=0)): return result # a comparable, e.g. a Decimal may slip in here elif not isinstance( r[0], (np.integer, np.floating, np.bool, int, float, bool)): return result if (issubclass(result.dtype.type, (np.object_, np.number)) and notna(result).all()): new_result = trans(result).astype(dtype) try: if np.allclose(new_result, result, rtol=0): return new_result except Exception: # comparison of an object dtype with a number type could # hit here if (new_result == result).all(): return new_result elif (issubclass(dtype.type, np.floating) and not is_bool_dtype(result.dtype)): return result.astype(dtype) # a datetimelike # GH12821, iNaT is casted to float elif dtype.kind in ['M', 'm'] and result.dtype.kind in ['i', 'f']: try: result = result.astype(dtype) except Exception: if dtype.tz: # convert to datetime and change timezone from pandas import to_datetime result = to_datetime(result).tz_localize('utc') result = result.tz_convert(dtype.tz) elif dtype.type == Period: # TODO(DatetimeArray): merge with previous elif from pandas.core.arrays import PeriodArray return PeriodArray(result, freq=dtype.freq) except Exception: pass return result
def data(dtype): return PeriodArray(np.arange(1970, 2070), freq=dtype.freq)