import numpy as np import pytest from pandas.compat.numpy import ( np_percentile_argname, np_version_under1p21, ) import pandas as pd from pandas import ( DataFrame, Index, Series, Timestamp, ) import pandas._testing as tm @pytest.fixture( params=[["linear", "single"], ["nearest", "table"]], ids=lambda x: "-".join(x) ) def interp_method(request): """(interpolation, method) arguments for quantile""" return request.param class TestDataFrameQuantile: @pytest.mark.parametrize( "df,expected", [ [ DataFrame( { 0: Series(pd.arrays.SparseArray([1, 2])), 1: Series(pd.arrays.SparseArray([3, 4])), } ), Series([1.5, 3.5], name=0.5), ], [ DataFrame(Series([0.0, None, 1.0, 2.0], dtype="Sparse[float]")), Series([1.0], name=0.5), ], ], ) def test_quantile_sparse(self, df, expected): # GH#17198 # GH#24600 result = df.quantile() expected = expected.astype("Sparse[float]") tm.assert_series_equal(result, expected) def test_quantile( self, datetime_frame, interp_method, using_array_manager, request ): interpolation, method = interp_method df = datetime_frame result = df.quantile( 0.1, axis=0, numeric_only=True, interpolation=interpolation, method=method ) expected = Series( [np.percentile(df[col], 10) for col in df.columns], index=df.columns, name=0.1, ) if interpolation == "linear": # np.percentile values only comparable to linear interpolation tm.assert_series_equal(result, expected) else: tm.assert_index_equal(result.index, expected.index) request.node.add_marker( pytest.mark.xfail( using_array_manager, reason="Name set incorrectly for arraymanager" ) ) assert result.name == expected.name result = df.quantile( 0.9, axis=1, numeric_only=True, interpolation=interpolation, method=method ) expected = Series( [np.percentile(df.loc[date], 90) for date in df.index], index=df.index, name=0.9, ) if interpolation == "linear": # np.percentile values only comparable to linear interpolation tm.assert_series_equal(result, expected) else: tm.assert_index_equal(result.index, expected.index) request.node.add_marker( pytest.mark.xfail( using_array_manager, reason="Name set incorrectly for arraymanager" ) ) assert result.name == expected.name def test_empty(self, interp_method): interpolation, method = interp_method q = DataFrame({"x": [], "y": []}).quantile( 0.1, axis=0, numeric_only=True, interpolation=interpolation, method=method ) assert np.isnan(q["x"]) and np.isnan(q["y"]) def test_non_numeric_exclusion(self, interp_method, request, using_array_manager): interpolation, method = interp_method df = DataFrame({"col1": ["A", "A", "B", "B"], "col2": [1, 2, 3, 4]}) rs = df.quantile( 0.5, numeric_only=True, interpolation=interpolation, method=method ) xp = df.median(numeric_only=True).rename(0.5) if interpolation == "nearest": xp = (xp + 0.5).astype(np.int64) if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) tm.assert_series_equal(rs, xp) def test_axis(self, interp_method, request, using_array_manager): # axis interpolation, method = interp_method df = DataFrame({"A": [1, 2, 3], "B": [2, 3, 4]}, index=[1, 2, 3]) result = df.quantile(0.5, axis=1, interpolation=interpolation, method=method) expected = Series([1.5, 2.5, 3.5], index=[1, 2, 3], name=0.5) if interpolation == "nearest": expected = expected.astype(np.int64) if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) tm.assert_series_equal(result, expected) result = df.quantile( [0.5, 0.75], axis=1, interpolation=interpolation, method=method ) expected = DataFrame( {1: [1.5, 1.75], 2: [2.5, 2.75], 3: [3.5, 3.75]}, index=[0.5, 0.75] ) if interpolation == "nearest": expected.iloc[0, :] -= 0.5 expected.iloc[1, :] += 0.25 expected = expected.astype(np.int64) tm.assert_frame_equal(result, expected, check_index_type=True) def test_axis_numeric_only_true(self, interp_method, request, using_array_manager): # We may want to break API in the future to change this # so that we exclude non-numeric along the same axis # See GH #7312 interpolation, method = interp_method df = DataFrame([[1, 2, 3], ["a", "b", 4]]) result = df.quantile( 0.5, axis=1, numeric_only=True, interpolation=interpolation, method=method ) expected = Series([3.0, 4.0], index=[0, 1], name=0.5) if interpolation == "nearest": expected = expected.astype(np.int64) if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) tm.assert_series_equal(result, expected) def test_quantile_date_range(self, interp_method, request, using_array_manager): # GH 2460 interpolation, method = interp_method dti = pd.date_range("2016-01-01", periods=3, tz="US/Pacific") ser = Series(dti) df = DataFrame(ser) result = df.quantile( numeric_only=False, interpolation=interpolation, method=method ) expected = Series( ["2016-01-02 00:00:00"], name=0.5, dtype="datetime64[ns, US/Pacific]" ) if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) tm.assert_series_equal(result, expected) def test_quantile_axis_mixed(self, interp_method, request, using_array_manager): # mixed on axis=1 interpolation, method = interp_method df = DataFrame( { "A": [1, 2, 3], "B": [2.0, 3.0, 4.0], "C": pd.date_range("20130101", periods=3), "D": ["foo", "bar", "baz"], } ) result = df.quantile( 0.5, axis=1, numeric_only=True, interpolation=interpolation, method=method ) expected = Series([1.5, 2.5, 3.5], name=0.5) if interpolation == "nearest": expected -= 0.5 if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) tm.assert_series_equal(result, expected) # must raise msg = "'<' not supported between instances of 'Timestamp' and 'float'" with pytest.raises(TypeError, match=msg): df.quantile(0.5, axis=1, numeric_only=False) def test_quantile_axis_parameter(self, interp_method, request, using_array_manager): # GH 9543/9544 interpolation, method = interp_method if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) df = DataFrame({"A": [1, 2, 3], "B": [2, 3, 4]}, index=[1, 2, 3]) result = df.quantile(0.5, axis=0, interpolation=interpolation, method=method) expected = Series([2.0, 3.0], index=["A", "B"], name=0.5) if interpolation == "nearest": expected = expected.astype(np.int64) tm.assert_series_equal(result, expected) expected = df.quantile( 0.5, axis="index", interpolation=interpolation, method=method ) if interpolation == "nearest": expected = expected.astype(np.int64) tm.assert_series_equal(result, expected) result = df.quantile(0.5, axis=1, interpolation=interpolation, method=method) expected = Series([1.5, 2.5, 3.5], index=[1, 2, 3], name=0.5) if interpolation == "nearest": expected = expected.astype(np.int64) tm.assert_series_equal(result, expected) result = df.quantile( 0.5, axis="columns", interpolation=interpolation, method=method ) tm.assert_series_equal(result, expected) msg = "No axis named -1 for object type DataFrame" with pytest.raises(ValueError, match=msg): df.quantile(0.1, axis=-1, interpolation=interpolation, method=method) msg = "No axis named column for object type DataFrame" with pytest.raises(ValueError, match=msg): df.quantile(0.1, axis="column") def test_quantile_interpolation(self): # see gh-10174 # interpolation method other than default linear df = DataFrame({"A": [1, 2, 3], "B": [2, 3, 4]}, index=[1, 2, 3]) result = df.quantile(0.5, axis=1, interpolation="nearest") expected = Series([1, 2, 3], index=[1, 2, 3], name=0.5) tm.assert_series_equal(result, expected) # cross-check interpolation=nearest results in original dtype exp = np.percentile( np.array([[1, 2, 3], [2, 3, 4]]), 0.5, axis=0, **{np_percentile_argname: "nearest"}, ) expected = Series(exp, index=[1, 2, 3], name=0.5, dtype="int64") tm.assert_series_equal(result, expected) # float df = DataFrame({"A": [1.0, 2.0, 3.0], "B": [2.0, 3.0, 4.0]}, index=[1, 2, 3]) result = df.quantile(0.5, axis=1, interpolation="nearest") expected = Series([1.0, 2.0, 3.0], index=[1, 2, 3], name=0.5) tm.assert_series_equal(result, expected) exp = np.percentile( np.array([[1.0, 2.0, 3.0], [2.0, 3.0, 4.0]]), 0.5, axis=0, **{np_percentile_argname: "nearest"}, ) expected = Series(exp, index=[1, 2, 3], name=0.5, dtype="float64") tm.assert_series_equal(result, expected) # axis result = df.quantile([0.5, 0.75], axis=1, interpolation="lower") expected = DataFrame( {1: [1.0, 1.0], 2: [2.0, 2.0], 3: [3.0, 3.0]}, index=[0.5, 0.75] ) tm.assert_frame_equal(result, expected) # test degenerate case df = DataFrame({"x": [], "y": []}) q = df.quantile(0.1, axis=0, interpolation="higher") assert np.isnan(q["x"]) and np.isnan(q["y"]) # multi df = DataFrame([[1, 1, 1], [2, 2, 2], [3, 3, 3]], columns=["a", "b", "c"]) result = df.quantile([0.25, 0.5], interpolation="midpoint") # https://github.com/numpy/numpy/issues/7163 expected = DataFrame( [[1.5, 1.5, 1.5], [2.0, 2.0, 2.0]], index=[0.25, 0.5], columns=["a", "b", "c"], ) tm.assert_frame_equal(result, expected) def test_quantile_interpolation_datetime(self, datetime_frame): # see gh-10174 # interpolation = linear (default case) df = datetime_frame q = df.quantile(0.1, axis=0, numeric_only=True, interpolation="linear") assert q["A"] == np.percentile(df["A"], 10) def test_quantile_interpolation_int(self, int_frame): # see gh-10174 df = int_frame # interpolation = linear (default case) q = df.quantile(0.1) assert q["A"] == np.percentile(df["A"], 10) # test with and without interpolation keyword q1 = df.quantile(0.1, axis=0, interpolation="linear") assert q1["A"] == np.percentile(df["A"], 10) tm.assert_series_equal(q, q1) def test_quantile_multi(self, interp_method, request, using_array_manager): interpolation, method = interp_method df = DataFrame([[1, 1, 1], [2, 2, 2], [3, 3, 3]], columns=["a", "b", "c"]) result = df.quantile([0.25, 0.5], interpolation=interpolation, method=method) expected = DataFrame( [[1.5, 1.5, 1.5], [2.0, 2.0, 2.0]], index=[0.25, 0.5], columns=["a", "b", "c"], ) if interpolation == "nearest": expected = expected.astype(np.int64) if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) tm.assert_frame_equal(result, expected) def test_quantile_multi_axis_1(self, interp_method, request, using_array_manager): interpolation, method = interp_method df = DataFrame([[1, 1, 1], [2, 2, 2], [3, 3, 3]], columns=["a", "b", "c"]) result = df.quantile( [0.25, 0.5], axis=1, interpolation=interpolation, method=method ) expected = DataFrame( [[1.0, 2.0, 3.0]] * 2, index=[0.25, 0.5], columns=[0, 1, 2] ) if interpolation == "nearest": expected = expected.astype(np.int64) if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) tm.assert_frame_equal(result, expected) def test_quantile_multi_empty(self, interp_method): interpolation, method = interp_method result = DataFrame({"x": [], "y": []}).quantile( [0.1, 0.9], axis=0, interpolation=interpolation, method=method ) expected = DataFrame( {"x": [np.nan, np.nan], "y": [np.nan, np.nan]}, index=[0.1, 0.9] ) tm.assert_frame_equal(result, expected) def test_quantile_datetime(self): df = DataFrame({"a": pd.to_datetime(["2010", "2011"]), "b": [0, 5]}) # exclude datetime result = df.quantile(0.5, numeric_only=True) expected = Series([2.5], index=["b"], name=0.5) tm.assert_series_equal(result, expected) # datetime result = df.quantile(0.5, numeric_only=False) expected = Series( [Timestamp("2010-07-02 12:00:00"), 2.5], index=["a", "b"], name=0.5 ) tm.assert_series_equal(result, expected) # datetime w/ multi result = df.quantile([0.5], numeric_only=False) expected = DataFrame( [[Timestamp("2010-07-02 12:00:00"), 2.5]], index=[0.5], columns=["a", "b"] ) tm.assert_frame_equal(result, expected) # axis = 1 df["c"] = pd.to_datetime(["2011", "2012"]) result = df[["a", "c"]].quantile(0.5, axis=1, numeric_only=False) expected = Series( [Timestamp("2010-07-02 12:00:00"), Timestamp("2011-07-02 12:00:00")], index=[0, 1], name=0.5, ) tm.assert_series_equal(result, expected) result = df[["a", "c"]].quantile([0.5], axis=1, numeric_only=False) expected = DataFrame( [[Timestamp("2010-07-02 12:00:00"), Timestamp("2011-07-02 12:00:00")]], index=[0.5], columns=[0, 1], ) tm.assert_frame_equal(result, expected) # empty when numeric_only=True result = df[["a", "c"]].quantile(0.5, numeric_only=True) expected = Series([], index=[], dtype=np.float64, name=0.5) tm.assert_series_equal(result, expected) result = df[["a", "c"]].quantile([0.5], numeric_only=True) expected = DataFrame(index=[0.5], columns=[]) tm.assert_frame_equal(result, expected) @pytest.mark.parametrize( "dtype", [ "datetime64[ns]", "datetime64[ns, US/Pacific]", "timedelta64[ns]", "Period[D]", ], ) def test_quantile_dt64_empty(self, dtype, interp_method): # GH#41544 interpolation, method = interp_method df = DataFrame(columns=["a", "b"], dtype=dtype) res = df.quantile( 0.5, axis=1, numeric_only=False, interpolation=interpolation, method=method ) expected = Series([], index=[], name=0.5, dtype=dtype) tm.assert_series_equal(res, expected) # no columns in result, so no dtype preservation res = df.quantile( [0.5], axis=1, numeric_only=False, interpolation=interpolation, method=method, ) expected = DataFrame(index=[0.5], columns=[]) tm.assert_frame_equal(res, expected) @pytest.mark.parametrize("invalid", [-1, 2, [0.5, -1], [0.5, 2]]) def test_quantile_invalid(self, invalid, datetime_frame, interp_method): msg = "percentiles should all be in the interval \\[0, 1\\]" interpolation, method = interp_method with pytest.raises(ValueError, match=msg): datetime_frame.quantile(invalid, interpolation=interpolation, method=method) def test_quantile_box(self, interp_method, request, using_array_manager): interpolation, method = interp_method if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) df = DataFrame( { "A": [ Timestamp("2011-01-01"), Timestamp("2011-01-02"), Timestamp("2011-01-03"), ], "B": [ Timestamp("2011-01-01", tz="US/Eastern"), Timestamp("2011-01-02", tz="US/Eastern"), Timestamp("2011-01-03", tz="US/Eastern"), ], "C": [ pd.Timedelta("1 days"), pd.Timedelta("2 days"), pd.Timedelta("3 days"), ], } ) res = df.quantile( 0.5, numeric_only=False, interpolation=interpolation, method=method ) exp = Series( [ Timestamp("2011-01-02"), Timestamp("2011-01-02", tz="US/Eastern"), pd.Timedelta("2 days"), ], name=0.5, index=["A", "B", "C"], ) tm.assert_series_equal(res, exp) res = df.quantile( [0.5], numeric_only=False, interpolation=interpolation, method=method ) exp = DataFrame( [ [ Timestamp("2011-01-02"), Timestamp("2011-01-02", tz="US/Eastern"), pd.Timedelta("2 days"), ] ], index=[0.5], columns=["A", "B", "C"], ) tm.assert_frame_equal(res, exp) def test_quantile_box_nat(self): # DatetimeLikeBlock may be consolidated and contain NaT in different loc df = DataFrame( { "A": [ Timestamp("2011-01-01"), pd.NaT, Timestamp("2011-01-02"), Timestamp("2011-01-03"), ], "a": [ Timestamp("2011-01-01"), Timestamp("2011-01-02"), pd.NaT, Timestamp("2011-01-03"), ], "B": [ Timestamp("2011-01-01", tz="US/Eastern"), pd.NaT, Timestamp("2011-01-02", tz="US/Eastern"), Timestamp("2011-01-03", tz="US/Eastern"), ], "b": [ Timestamp("2011-01-01", tz="US/Eastern"), Timestamp("2011-01-02", tz="US/Eastern"), pd.NaT, Timestamp("2011-01-03", tz="US/Eastern"), ], "C": [ pd.Timedelta("1 days"), pd.Timedelta("2 days"), pd.Timedelta("3 days"), pd.NaT, ], "c": [ pd.NaT, pd.Timedelta("1 days"), pd.Timedelta("2 days"), pd.Timedelta("3 days"), ], }, columns=list("AaBbCc"), ) res = df.quantile(0.5, numeric_only=False) exp = Series( [ Timestamp("2011-01-02"), Timestamp("2011-01-02"), Timestamp("2011-01-02", tz="US/Eastern"), Timestamp("2011-01-02", tz="US/Eastern"), pd.Timedelta("2 days"), pd.Timedelta("2 days"), ], name=0.5, index=list("AaBbCc"), ) tm.assert_series_equal(res, exp) res = df.quantile([0.5], numeric_only=False) exp = DataFrame( [ [ Timestamp("2011-01-02"), Timestamp("2011-01-02"), Timestamp("2011-01-02", tz="US/Eastern"), Timestamp("2011-01-02", tz="US/Eastern"), pd.Timedelta("2 days"), pd.Timedelta("2 days"), ] ], index=[0.5], columns=list("AaBbCc"), ) tm.assert_frame_equal(res, exp) def test_quantile_nan(self, interp_method, request, using_array_manager): interpolation, method = interp_method if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) # GH 14357 - float block where some cols have missing values df = DataFrame({"a": np.arange(1, 6.0), "b": np.arange(1, 6.0)}) df.iloc[-1, 1] = np.nan res = df.quantile(0.5, interpolation=interpolation, method=method) exp = Series( [3.0, 2.5 if interpolation == "linear" else 3.0], index=["a", "b"], name=0.5 ) tm.assert_series_equal(res, exp) res = df.quantile([0.5, 0.75], interpolation=interpolation, method=method) exp = DataFrame( { "a": [3.0, 4.0], "b": [2.5, 3.25] if interpolation == "linear" else [3.0, 4.0], }, index=[0.5, 0.75], ) tm.assert_frame_equal(res, exp) res = df.quantile(0.5, axis=1, interpolation=interpolation, method=method) exp = Series(np.arange(1.0, 6.0), name=0.5) tm.assert_series_equal(res, exp) res = df.quantile( [0.5, 0.75], axis=1, interpolation=interpolation, method=method ) exp = DataFrame([np.arange(1.0, 6.0)] * 2, index=[0.5, 0.75]) if interpolation == "nearest": exp.iloc[1, -1] = np.nan tm.assert_frame_equal(res, exp) # full-nan column df["b"] = np.nan res = df.quantile(0.5, interpolation=interpolation, method=method) exp = Series([3.0, np.nan], index=["a", "b"], name=0.5) tm.assert_series_equal(res, exp) res = df.quantile([0.5, 0.75], interpolation=interpolation, method=method) exp = DataFrame({"a": [3.0, 4.0], "b": [np.nan, np.nan]}, index=[0.5, 0.75]) tm.assert_frame_equal(res, exp) def test_quantile_nat(self, interp_method, request, using_array_manager): interpolation, method = interp_method if method == "table" and using_array_manager: request.node.add_marker( pytest.mark.xfail(reason="Axis name incorrectly set.") ) # full NaT column df = DataFrame({"a": [pd.NaT, pd.NaT, pd.NaT]}) res = df.quantile( 0.5, numeric_only=False, interpolation=interpolation, method=method ) exp = Series([pd.NaT], index=["a"], name=0.5) tm.assert_series_equal(res, exp) res = df.quantile( [0.5], numeric_only=False, interpolation=interpolation, method=method ) exp = DataFrame({"a": [pd.NaT]}, index=[0.5]) tm.assert_frame_equal(res, exp) # mixed non-null / full null column df = DataFrame( { "a": [ Timestamp("2012-01-01"), Timestamp("2012-01-02"), Timestamp("2012-01-03"), ], "b": [pd.NaT, pd.NaT, pd.NaT], } ) res = df.quantile( 0.5, numeric_only=False, interpolation=interpolation, method=method ) exp = Series([Timestamp("2012-01-02"), pd.NaT], index=["a", "b"], name=0.5) tm.assert_series_equal(res, exp) res = df.quantile( [0.5], numeric_only=False, interpolation=interpolation, method=method ) exp = DataFrame( [[Timestamp("2012-01-02"), pd.NaT]], index=[0.5], columns=["a", "b"] ) tm.assert_frame_equal(res, exp) def test_quantile_empty_no_rows_floats(self, interp_method): interpolation, method = interp_method df = DataFrame(columns=["a", "b"], dtype="float64") res = df.quantile(0.5, interpolation=interpolation, method=method) exp = Series([np.nan, np.nan], index=["a", "b"], name=0.5) tm.assert_series_equal(res, exp) res = df.quantile([0.5], interpolation=interpolation, method=method) exp = DataFrame([[np.nan, np.nan]], columns=["a", "b"], index=[0.5]) tm.assert_frame_equal(res, exp) res = df.quantile(0.5, axis=1, interpolation=interpolation, method=method) exp = Series([], index=[], dtype="float64", name=0.5) tm.assert_series_equal(res, exp) res = df.quantile([0.5], axis=1, interpolation=interpolation, method=method) exp = DataFrame(columns=[], index=[0.5]) tm.assert_frame_equal(res, exp) def test_quantile_empty_no_rows_ints(self, interp_method): interpolation, method = interp_method df = DataFrame(columns=["a", "b"], dtype="int64") res = df.quantile(0.5, interpolation=interpolation, method=method) exp = Series([np.nan, np.nan], index=["a", "b"], name=0.5) tm.assert_series_equal(res, exp) def test_quantile_empty_no_rows_dt64(self, interp_method): interpolation, method = interp_method # datetimes df = DataFrame(columns=["a", "b"], dtype="datetime64[ns]") res = df.quantile( 0.5, numeric_only=False, interpolation=interpolation, method=method ) exp = Series( [pd.NaT, pd.NaT], index=["a", "b"], dtype="datetime64[ns]", name=0.5 ) tm.assert_series_equal(res, exp) # Mixed dt64/dt64tz df["a"] = df["a"].dt.tz_localize("US/Central") res = df.quantile( 0.5, numeric_only=False, interpolation=interpolation, method=method ) exp = exp.astype(object) tm.assert_series_equal(res, exp) # both dt64tz df["b"] = df["b"].dt.tz_localize("US/Central") res = df.quantile( 0.5, numeric_only=False, interpolation=interpolation, method=method ) exp = exp.astype(df["b"].dtype) tm.assert_series_equal(res, exp) def test_quantile_empty_no_columns(self, interp_method): # GH#23925 _get_numeric_data may drop all columns interpolation, method = interp_method df = DataFrame(pd.date_range("1/1/18", periods=5)) df.columns.name = "captain tightpants" result = df.quantile( 0.5, numeric_only=True, interpolation=interpolation, method=method ) expected = Series([], index=[], name=0.5, dtype=np.float64) expected.index.name = "captain tightpants" tm.assert_series_equal(result, expected) result = df.quantile( [0.5], numeric_only=True, interpolation=interpolation, method=method ) expected = DataFrame([], index=[0.5], columns=[]) expected.columns.name = "captain tightpants" tm.assert_frame_equal(result, expected) def test_quantile_item_cache( self, using_array_manager, interp_method, using_copy_on_write ): # previous behavior incorrect retained an invalid _item_cache entry interpolation, method = interp_method df = DataFrame(np.random.randn(4, 3), columns=["A", "B", "C"]) df["D"] = df["A"] * 2 ser = df["A"] if not using_array_manager: assert len(df._mgr.blocks) == 2 df.quantile(numeric_only=False, interpolation=interpolation, method=method) if using_copy_on_write: ser.iloc[0] = 99 assert df.iloc[0, 0] == df["A"][0] assert df.iloc[0, 0] != 99 else: ser.values[0] = 99 assert df.iloc[0, 0] == df["A"][0] assert df.iloc[0, 0] == 99 def test_invalid_method(self): with pytest.raises(ValueError, match="Invalid method: foo"): DataFrame(range(1)).quantile(0.5, method="foo") def test_table_invalid_interpolation(self): with pytest.raises(ValueError, match="Invalid interpolation: foo"): DataFrame(range(1)).quantile(0.5, method="table", interpolation="foo") class TestQuantileExtensionDtype: # TODO: tests for axis=1? # TODO: empty case? @pytest.fixture( params=[ pytest.param( pd.IntervalIndex.from_breaks(range(10)), marks=pytest.mark.xfail(reason="raises when trying to add Intervals"), ), pd.period_range("2016-01-01", periods=9, freq="D"), pd.date_range("2016-01-01", periods=9, tz="US/Pacific"), pd.timedelta_range("1 Day", periods=9), pd.array(np.arange(9), dtype="Int64"), pd.array(np.arange(9), dtype="Float64"), ], ids=lambda x: str(x.dtype), ) def index(self, request): # NB: not actually an Index object idx = request.param idx.name = "A" return idx @pytest.fixture def obj(self, index, frame_or_series): # bc index is not always an Index (yet), we need to re-patch .name obj = frame_or_series(index).copy() if frame_or_series is Series: obj.name = "A" else: obj.columns = ["A"] return obj def compute_quantile(self, obj, qs): if isinstance(obj, Series): result = obj.quantile(qs) else: result = obj.quantile(qs, numeric_only=False) return result def test_quantile_ea(self, request, obj, index): # result should be invariant to shuffling indexer = np.arange(len(index), dtype=np.intp) np.random.shuffle(indexer) obj = obj.iloc[indexer] qs = [0.5, 0, 1] result = self.compute_quantile(obj, qs) if np_version_under1p21 and index.dtype == "timedelta64[ns]": msg = "failed on Numpy 1.20.3; TypeError: data type 'Int64' not understood" mark = pytest.mark.xfail(reason=msg, raises=TypeError) request.node.add_marker(mark) exp_dtype = index.dtype if index.dtype == "Int64": # match non-nullable casting behavior exp_dtype = "Float64" # expected here assumes len(index) == 9 expected = Series( [index[4], index[0], index[-1]], dtype=exp_dtype, index=qs, name="A" ) expected = type(obj)(expected) tm.assert_equal(result, expected) def test_quantile_ea_with_na(self, obj, index): obj.iloc[0] = index._na_value obj.iloc[-1] = index._na_value # result should be invariant to shuffling indexer = np.arange(len(index), dtype=np.intp) np.random.shuffle(indexer) obj = obj.iloc[indexer] qs = [0.5, 0, 1] result = self.compute_quantile(obj, qs) # expected here assumes len(index) == 9 expected = Series( [index[4], index[1], index[-2]], dtype=index.dtype, index=qs, name="A" ) expected = type(obj)(expected) tm.assert_equal(result, expected) def test_quantile_ea_all_na(self, request, obj, index): obj.iloc[:] = index._na_value # Check dtypes were preserved; this was once a problem see GH#39763 assert np.all(obj.dtypes == index.dtype) # result should be invariant to shuffling indexer = np.arange(len(index), dtype=np.intp) np.random.shuffle(indexer) obj = obj.iloc[indexer] qs = [0.5, 0, 1] result = self.compute_quantile(obj, qs) expected = index.take([-1, -1, -1], allow_fill=True, fill_value=index._na_value) expected = Series(expected, index=qs, name="A") expected = type(obj)(expected) tm.assert_equal(result, expected) def test_quantile_ea_scalar(self, request, obj, index): # scalar qs # result should be invariant to shuffling indexer = np.arange(len(index), dtype=np.intp) np.random.shuffle(indexer) obj = obj.iloc[indexer] qs = 0.5 result = self.compute_quantile(obj, qs) if np_version_under1p21 and index.dtype == "timedelta64[ns]": msg = "failed on Numpy 1.20.3; TypeError: data type 'Int64' not understood" mark = pytest.mark.xfail(reason=msg, raises=TypeError) request.node.add_marker(mark) exp_dtype = index.dtype if index.dtype == "Int64": exp_dtype = "Float64" expected = Series({"A": index[4]}, dtype=exp_dtype, name=0.5) if isinstance(obj, Series): expected = expected["A"] assert result == expected else: tm.assert_series_equal(result, expected) @pytest.mark.parametrize( "dtype, expected_data, expected_index, axis", [ ["float64", [], [], 1], ["int64", [], [], 1], ["float64", [np.nan, np.nan], ["a", "b"], 0], ["int64", [np.nan, np.nan], ["a", "b"], 0], ], ) def test_empty_numeric(self, dtype, expected_data, expected_index, axis): # GH 14564 df = DataFrame(columns=["a", "b"], dtype=dtype) result = df.quantile(0.5, axis=axis) expected = Series( expected_data, name=0.5, index=Index(expected_index), dtype="float64" ) tm.assert_series_equal(result, expected) @pytest.mark.parametrize( "dtype, expected_data, expected_index, axis, expected_dtype", [ ["datetime64[ns]", [], [], 1, "datetime64[ns]"], ["datetime64[ns]", [pd.NaT, pd.NaT], ["a", "b"], 0, "datetime64[ns]"], ], ) def test_empty_datelike( self, dtype, expected_data, expected_index, axis, expected_dtype ): # GH 14564 df = DataFrame(columns=["a", "b"], dtype=dtype) result = df.quantile(0.5, axis=axis, numeric_only=False) expected = Series( expected_data, name=0.5, index=Index(expected_index), dtype=expected_dtype ) tm.assert_series_equal(result, expected) @pytest.mark.parametrize( "expected_data, expected_index, axis", [ [[np.nan, np.nan], range(2), 1], [[], [], 0], ], ) def test_datelike_numeric_only(self, expected_data, expected_index, axis): # GH 14564 df = DataFrame( { "a": pd.to_datetime(["2010", "2011"]), "b": [0, 5], "c": pd.to_datetime(["2011", "2012"]), } ) result = df[["a", "c"]].quantile(0.5, axis=axis, numeric_only=True) expected = Series( expected_data, name=0.5, index=Index(expected_index), dtype=np.float64 ) tm.assert_series_equal(result, expected)