from datetime import datetime import warnings import numpy as np import pytest from pandas.core.dtypes.dtypes import CategoricalDtype import pandas as pd from pandas import ( DataFrame, MultiIndex, Series, Timestamp, date_range, ) import pandas._testing as tm from pandas.tests.frame.common import zip_frames def test_apply(float_frame): with np.errstate(all="ignore"): # ufunc result = np.sqrt(float_frame["A"]) expected = float_frame.apply(np.sqrt)["A"] tm.assert_series_equal(result, expected) # aggregator result = float_frame.apply(np.mean)["A"] expected = np.mean(float_frame["A"]) assert result == expected d = float_frame.index[0] result = float_frame.apply(np.mean, axis=1) expected = np.mean(float_frame.xs(d)) assert result[d] == expected assert result.index is float_frame.index def test_apply_categorical_func(): # GH 9573 df = DataFrame({"c0": ["A", "A", "B", "B"], "c1": ["C", "C", "D", "D"]}) result = df.apply(lambda ts: ts.astype("category")) assert result.shape == (4, 2) assert isinstance(result["c0"].dtype, CategoricalDtype) assert isinstance(result["c1"].dtype, CategoricalDtype) def test_apply_axis1_with_ea(): # GH#36785 expected = DataFrame({"A": [Timestamp("2013-01-01", tz="UTC")]}) result = expected.apply(lambda x: x, axis=1) tm.assert_frame_equal(result, expected) @pytest.mark.parametrize( "data, dtype", [(1, None), (1, CategoricalDtype([1])), (Timestamp("2013-01-01", tz="UTC"), None)], ) def test_agg_axis1_duplicate_index(data, dtype): # GH 42380 expected = DataFrame([[data], [data]], index=["a", "a"], dtype=dtype) result = expected.agg(lambda x: x, axis=1) tm.assert_frame_equal(result, expected) def test_apply_mixed_datetimelike(): # mixed datetimelike # GH 7778 expected = DataFrame( { "A": date_range("20130101", periods=3), "B": pd.to_timedelta(np.arange(3), unit="s"), } ) result = expected.apply(lambda x: x, axis=1) tm.assert_frame_equal(result, expected) @pytest.mark.parametrize("func", [np.sqrt, np.mean]) def test_apply_empty(func): # empty empty_frame = DataFrame() result = empty_frame.apply(func) assert result.empty def test_apply_float_frame(float_frame): no_rows = float_frame[:0] result = no_rows.apply(lambda x: x.mean()) expected = Series(np.nan, index=float_frame.columns) tm.assert_series_equal(result, expected) no_cols = float_frame.loc[:, []] result = no_cols.apply(lambda x: x.mean(), axis=1) expected = Series(np.nan, index=float_frame.index) tm.assert_series_equal(result, expected) def test_apply_empty_except_index(): # GH 2476 expected = DataFrame(index=["a"]) result = expected.apply(lambda x: x["a"], axis=1) tm.assert_frame_equal(result, expected) def test_apply_with_reduce_empty(): # reduce with an empty DataFrame empty_frame = DataFrame() x = [] result = empty_frame.apply(x.append, axis=1, result_type="expand") tm.assert_frame_equal(result, empty_frame) result = empty_frame.apply(x.append, axis=1, result_type="reduce") expected = Series([], index=pd.Index([], dtype=object), dtype=np.float64) tm.assert_series_equal(result, expected) empty_with_cols = DataFrame(columns=["a", "b", "c"]) result = empty_with_cols.apply(x.append, axis=1, result_type="expand") tm.assert_frame_equal(result, empty_with_cols) result = empty_with_cols.apply(x.append, axis=1, result_type="reduce") expected = Series([], index=pd.Index([], dtype=object), dtype=np.float64) tm.assert_series_equal(result, expected) # Ensure that x.append hasn't been called assert x == [] @pytest.mark.parametrize("func", ["sum", "prod", "any", "all"]) def test_apply_funcs_over_empty(func): # GH 28213 df = DataFrame(columns=["a", "b", "c"]) result = df.apply(getattr(np, func)) expected = getattr(df, func)() tm.assert_series_equal(result, expected) def test_nunique_empty(): # GH 28213 df = DataFrame(columns=["a", "b", "c"]) result = df.nunique() expected = Series(0, index=df.columns) tm.assert_series_equal(result, expected) result = df.T.nunique() expected = Series([], index=pd.Index([]), dtype=np.float64) tm.assert_series_equal(result, expected) def test_apply_standard_nonunique(): df = DataFrame([[1, 2, 3], [4, 5, 6], [7, 8, 9]], index=["a", "a", "c"]) result = df.apply(lambda s: s[0], axis=1) expected = Series([1, 4, 7], ["a", "a", "c"]) tm.assert_series_equal(result, expected) result = df.T.apply(lambda s: s[0], axis=0) tm.assert_series_equal(result, expected) def test_apply_broadcast_scalars(float_frame): # scalars result = float_frame.apply(np.mean, result_type="broadcast") expected = DataFrame([float_frame.mean()], index=float_frame.index) tm.assert_frame_equal(result, expected) def test_apply_broadcast_scalars_axis1(float_frame): result = float_frame.apply(np.mean, axis=1, result_type="broadcast") m = float_frame.mean(axis=1) expected = DataFrame({c: m for c in float_frame.columns}) tm.assert_frame_equal(result, expected) def test_apply_broadcast_lists_columns(float_frame): # lists result = float_frame.apply( lambda x: list(range(len(float_frame.columns))), axis=1, result_type="broadcast", ) m = list(range(len(float_frame.columns))) expected = DataFrame( [m] * len(float_frame.index), dtype="float64", index=float_frame.index, columns=float_frame.columns, ) tm.assert_frame_equal(result, expected) def test_apply_broadcast_lists_index(float_frame): result = float_frame.apply( lambda x: list(range(len(float_frame.index))), result_type="broadcast" ) m = list(range(len(float_frame.index))) expected = DataFrame( {c: m for c in float_frame.columns}, dtype="float64", index=float_frame.index, ) tm.assert_frame_equal(result, expected) def test_apply_broadcast_list_lambda_func(int_frame_const_col): # preserve columns df = int_frame_const_col result = df.apply(lambda x: [1, 2, 3], axis=1, result_type="broadcast") tm.assert_frame_equal(result, df) def test_apply_broadcast_series_lambda_func(int_frame_const_col): df = int_frame_const_col result = df.apply( lambda x: Series([1, 2, 3], index=list("abc")), axis=1, result_type="broadcast", ) expected = df.copy() tm.assert_frame_equal(result, expected) @pytest.mark.parametrize("axis", [0, 1]) def test_apply_raw_float_frame(float_frame, axis): def _assert_raw(x): assert isinstance(x, np.ndarray) assert x.ndim == 1 float_frame.apply(_assert_raw, axis=axis, raw=True) @pytest.mark.parametrize("axis", [0, 1]) def test_apply_raw_float_frame_lambda(float_frame, axis): result = float_frame.apply(np.mean, axis=axis, raw=True) expected = float_frame.apply(lambda x: x.values.mean(), axis=axis) tm.assert_series_equal(result, expected) def test_apply_raw_float_frame_no_reduction(float_frame): # no reduction result = float_frame.apply(lambda x: x * 2, raw=True) expected = float_frame * 2 tm.assert_frame_equal(result, expected) @pytest.mark.parametrize("axis", [0, 1]) def test_apply_raw_mixed_type_frame(mixed_type_frame, axis): def _assert_raw(x): assert isinstance(x, np.ndarray) assert x.ndim == 1 # Mixed dtype (GH-32423) mixed_type_frame.apply(_assert_raw, axis=axis, raw=True) def test_apply_axis1(float_frame): d = float_frame.index[0] result = float_frame.apply(np.mean, axis=1)[d] expected = np.mean(float_frame.xs(d)) assert result == expected def test_apply_mixed_dtype_corner(): df = DataFrame({"A": ["foo"], "B": [1.0]}) result = df[:0].apply(np.mean, axis=1) # the result here is actually kind of ambiguous, should it be a Series # or a DataFrame? expected = Series(np.nan, index=pd.Index([], dtype="int64")) tm.assert_series_equal(result, expected) def test_apply_mixed_dtype_corner_indexing(): df = DataFrame({"A": ["foo"], "B": [1.0]}) result = df.apply(lambda x: x["A"], axis=1) expected = Series(["foo"], index=[0]) tm.assert_series_equal(result, expected) result = df.apply(lambda x: x["B"], axis=1) expected = Series([1.0], index=[0]) tm.assert_series_equal(result, expected) @pytest.mark.parametrize("ax", ["index", "columns"]) @pytest.mark.parametrize( "func", [lambda x: x, lambda x: x.mean()], ids=["identity", "mean"] ) @pytest.mark.parametrize("raw", [True, False]) @pytest.mark.parametrize("axis", [0, 1]) def test_apply_empty_infer_type(ax, func, raw, axis): df = DataFrame(**{ax: ["a", "b", "c"]}) with np.errstate(all="ignore"): with warnings.catch_warnings(record=True): warnings.simplefilter("ignore", RuntimeWarning) test_res = func(np.array([], dtype="f8")) is_reduction = not isinstance(test_res, np.ndarray) result = df.apply(func, axis=axis, raw=raw) if is_reduction: agg_axis = df._get_agg_axis(axis) assert isinstance(result, Series) assert result.index is agg_axis else: assert isinstance(result, DataFrame) def test_apply_empty_infer_type_broadcast(): no_cols = DataFrame(index=["a", "b", "c"]) result = no_cols.apply(lambda x: x.mean(), result_type="broadcast") assert isinstance(result, DataFrame) def test_apply_with_args_kwds_add_some(float_frame): def add_some(x, howmuch=0): return x + howmuch result = float_frame.apply(add_some, howmuch=2) expected = float_frame.apply(lambda x: x + 2) tm.assert_frame_equal(result, expected) def test_apply_with_args_kwds_agg_and_add(float_frame): def agg_and_add(x, howmuch=0): return x.mean() + howmuch result = float_frame.apply(agg_and_add, howmuch=2) expected = float_frame.apply(lambda x: x.mean() + 2) tm.assert_series_equal(result, expected) def test_apply_with_args_kwds_subtract_and_divide(float_frame): def subtract_and_divide(x, sub, divide=1): return (x - sub) / divide result = float_frame.apply(subtract_and_divide, args=(2,), divide=2) expected = float_frame.apply(lambda x: (x - 2.0) / 2.0) tm.assert_frame_equal(result, expected) def test_apply_yield_list(float_frame): result = float_frame.apply(list) tm.assert_frame_equal(result, float_frame) def test_apply_reduce_Series(float_frame): float_frame["A"].iloc[::2] = np.nan expected = float_frame.mean(1) result = float_frame.apply(np.mean, axis=1) tm.assert_series_equal(result, expected) def test_apply_reduce_to_dict(): # GH 25196 37544 data = DataFrame([[1, 2], [3, 4]], columns=["c0", "c1"], index=["i0", "i1"]) result = data.apply(dict, axis=0) expected = Series([{"i0": 1, "i1": 3}, {"i0": 2, "i1": 4}], index=data.columns) tm.assert_series_equal(result, expected) result = data.apply(dict, axis=1) expected = Series([{"c0": 1, "c1": 2}, {"c0": 3, "c1": 4}], index=data.index) tm.assert_series_equal(result, expected) def test_apply_differently_indexed(): df = DataFrame(np.random.randn(20, 10)) result = df.apply(Series.describe, axis=0) expected = DataFrame({i: v.describe() for i, v in df.items()}, columns=df.columns) tm.assert_frame_equal(result, expected) result = df.apply(Series.describe, axis=1) expected = DataFrame({i: v.describe() for i, v in df.T.items()}, columns=df.index).T tm.assert_frame_equal(result, expected) def test_apply_bug(): # GH 6125 positions = DataFrame( [ [1, "ABC0", 50], [1, "YUM0", 20], [1, "DEF0", 20], [2, "ABC1", 50], [2, "YUM1", 20], [2, "DEF1", 20], ], columns=["a", "market", "position"], ) def f(r): return r["market"] expected = positions.apply(f, axis=1) positions = DataFrame( [ [datetime(2013, 1, 1), "ABC0", 50], [datetime(2013, 1, 2), "YUM0", 20], [datetime(2013, 1, 3), "DEF0", 20], [datetime(2013, 1, 4), "ABC1", 50], [datetime(2013, 1, 5), "YUM1", 20], [datetime(2013, 1, 6), "DEF1", 20], ], columns=["a", "market", "position"], ) result = positions.apply(f, axis=1) tm.assert_series_equal(result, expected) def test_apply_convert_objects(): expected = DataFrame( { "A": [ "foo", "foo", "foo", "foo", "bar", "bar", "bar", "bar", "foo", "foo", "foo", ], "B": [ "one", "one", "one", "two", "one", "one", "one", "two", "two", "two", "one", ], "C": [ "dull", "dull", "shiny", "dull", "dull", "shiny", "shiny", "dull", "shiny", "shiny", "shiny", ], "D": np.random.randn(11), "E": np.random.randn(11), "F": np.random.randn(11), } ) result = expected.apply(lambda x: x, axis=1)._convert(datetime=True) tm.assert_frame_equal(result, expected) def test_apply_attach_name(float_frame): result = float_frame.apply(lambda x: x.name) expected = Series(float_frame.columns, index=float_frame.columns) tm.assert_series_equal(result, expected) def test_apply_attach_name_axis1(float_frame): result = float_frame.apply(lambda x: x.name, axis=1) expected = Series(float_frame.index, index=float_frame.index) tm.assert_series_equal(result, expected) def test_apply_attach_name_non_reduction(float_frame): # non-reductions result = float_frame.apply(lambda x: np.repeat(x.name, len(x))) expected = DataFrame( np.tile(float_frame.columns, (len(float_frame.index), 1)), index=float_frame.index, columns=float_frame.columns, ) tm.assert_frame_equal(result, expected) def test_apply_attach_name_non_reduction_axis1(float_frame): result = float_frame.apply(lambda x: np.repeat(x.name, len(x)), axis=1) expected = Series( np.repeat(t[0], len(float_frame.columns)) for t in float_frame.itertuples() ) expected.index = float_frame.index tm.assert_series_equal(result, expected) def test_apply_multi_index(): index = MultiIndex.from_arrays([["a", "a", "b"], ["c", "d", "d"]]) s = DataFrame([[1, 2], [3, 4], [5, 6]], index=index, columns=["col1", "col2"]) result = s.apply(lambda x: Series({"min": min(x), "max": max(x)}), 1) expected = DataFrame([[1, 2], [3, 4], [5, 6]], index=index, columns=["min", "max"]) tm.assert_frame_equal(result, expected, check_like=True) @pytest.mark.parametrize( "df, dicts", [ [ DataFrame([["foo", "bar"], ["spam", "eggs"]]), Series([{0: "foo", 1: "spam"}, {0: "bar", 1: "eggs"}]), ], [DataFrame([[0, 1], [2, 3]]), Series([{0: 0, 1: 2}, {0: 1, 1: 3}])], ], ) def test_apply_dict(df, dicts): # GH 8735 fn = lambda x: x.to_dict() reduce_true = df.apply(fn, result_type="reduce") reduce_false = df.apply(fn, result_type="expand") reduce_none = df.apply(fn) tm.assert_series_equal(reduce_true, dicts) tm.assert_frame_equal(reduce_false, df) tm.assert_series_equal(reduce_none, dicts) def test_applymap(float_frame): applied = float_frame.applymap(lambda x: x * 2) tm.assert_frame_equal(applied, float_frame * 2) float_frame.applymap(type) # GH 465: function returning tuples result = float_frame.applymap(lambda x: (x, x))["A"][0] assert isinstance(result, tuple) @pytest.mark.parametrize("val", [1, 1.0]) def test_applymap_float_object_conversion(val): # GH 2909: object conversion to float in constructor? df = DataFrame(data=[val, "a"]) result = df.applymap(lambda x: x).dtypes[0] assert result == object def test_applymap_str(): # GH 2786 df = DataFrame(np.random.random((3, 4))) df2 = df.copy() cols = ["a", "a", "a", "a"] df.columns = cols expected = df2.applymap(str) expected.columns = cols result = df.applymap(str) tm.assert_frame_equal(result, expected) @pytest.mark.parametrize( "col, val", [["datetime", Timestamp("20130101")], ["timedelta", pd.Timedelta("1 min")]], ) def test_applymap_datetimelike(col, val): # datetime/timedelta df = DataFrame(np.random.random((3, 4))) df[col] = val result = df.applymap(str) assert result.loc[0, col] == str(df.loc[0, col]) @pytest.mark.parametrize( "expected", [ DataFrame(), DataFrame(columns=list("ABC")), DataFrame(index=list("ABC")), DataFrame({"A": [], "B": [], "C": []}), ], ) @pytest.mark.parametrize("func", [round, lambda x: x]) def test_applymap_empty(expected, func): # GH 8222 result = expected.applymap(func) tm.assert_frame_equal(result, expected) def test_applymap_kwargs(): # GH 40652 result = DataFrame([[1, 2], [3, 4]]).applymap(lambda x, y: x + y, y=2) expected = DataFrame([[3, 4], [5, 6]]) tm.assert_frame_equal(result, expected) def test_applymap_na_ignore(float_frame): # GH 23803 strlen_frame = float_frame.applymap(lambda x: len(str(x))) float_frame_with_na = float_frame.copy() mask = np.random.randint(0, 2, size=float_frame.shape, dtype=bool) float_frame_with_na[mask] = pd.NA strlen_frame_na_ignore = float_frame_with_na.applymap( lambda x: len(str(x)), na_action="ignore" ) strlen_frame_with_na = strlen_frame.copy() strlen_frame_with_na[mask] = pd.NA tm.assert_frame_equal(strlen_frame_na_ignore, strlen_frame_with_na) def test_applymap_box_timestamps(): # GH 2689, GH 2627 ser = Series(date_range("1/1/2000", periods=10)) def func(x): return (x.hour, x.day, x.month) # it works! DataFrame(ser).applymap(func) def test_applymap_box(): # ufunc will not be boxed. Same test cases as the test_map_box df = DataFrame( { "a": [Timestamp("2011-01-01"), Timestamp("2011-01-02")], "b": [ Timestamp("2011-01-01", tz="US/Eastern"), Timestamp("2011-01-02", tz="US/Eastern"), ], "c": [pd.Timedelta("1 days"), pd.Timedelta("2 days")], "d": [ pd.Period("2011-01-01", freq="M"), pd.Period("2011-01-02", freq="M"), ], } ) result = df.applymap(lambda x: type(x).__name__) expected = DataFrame( { "a": ["Timestamp", "Timestamp"], "b": ["Timestamp", "Timestamp"], "c": ["Timedelta", "Timedelta"], "d": ["Period", "Period"], } ) tm.assert_frame_equal(result, expected) def test_frame_apply_dont_convert_datetime64(): from pandas.tseries.offsets import BDay df = DataFrame({"x1": [datetime(1996, 1, 1)]}) df = df.applymap(lambda x: x + BDay()) df = df.applymap(lambda x: x + BDay()) result = df.x1.dtype assert result == "M8[ns]" def test_apply_non_numpy_dtype(): # GH 12244 df = DataFrame({"dt": date_range("2015-01-01", periods=3, tz="Europe/Brussels")}) result = df.apply(lambda x: x) tm.assert_frame_equal(result, df) result = df.apply(lambda x: x + pd.Timedelta("1day")) expected = DataFrame( {"dt": date_range("2015-01-02", periods=3, tz="Europe/Brussels")} ) tm.assert_frame_equal(result, expected) def test_apply_non_numpy_dtype_category(): df = DataFrame({"dt": ["a", "b", "c", "a"]}, dtype="category") result = df.apply(lambda x: x) tm.assert_frame_equal(result, df) def test_apply_dup_names_multi_agg(): # GH 21063 df = DataFrame([[0, 1], [2, 3]], columns=["a", "a"]) expected = DataFrame([[0, 1]], columns=["a", "a"], index=["min"]) result = df.agg(["min"]) tm.assert_frame_equal(result, expected) @pytest.mark.parametrize("op", ["apply", "agg"]) def test_apply_nested_result_axis_1(op): # GH 13820 def apply_list(row): return [2 * row["A"], 2 * row["C"], 2 * row["B"]] df = DataFrame(np.zeros((4, 4)), columns=list("ABCD")) result = getattr(df, op)(apply_list, axis=1) expected = Series( [[0.0, 0.0, 0.0], [0.0, 0.0, 0.0], [0.0, 0.0, 0.0], [0.0, 0.0, 0.0]] ) tm.assert_series_equal(result, expected) def test_apply_noreduction_tzaware_object(): # https://github.com/pandas-dev/pandas/issues/31505 expected = DataFrame( {"foo": [Timestamp("2020", tz="UTC")]}, dtype="datetime64[ns, UTC]" ) result = expected.apply(lambda x: x) tm.assert_frame_equal(result, expected) result = expected.apply(lambda x: x.copy()) tm.assert_frame_equal(result, expected) def test_apply_function_runs_once(): # https://github.com/pandas-dev/pandas/issues/30815 df = DataFrame({"a": [1, 2, 3]}) names = [] # Save row names function is applied to def reducing_function(row): names.append(row.name) def non_reducing_function(row): names.append(row.name) return row for func in [reducing_function, non_reducing_function]: del names[:] df.apply(func, axis=1) assert names == list(df.index) def test_apply_raw_function_runs_once(): # https://github.com/pandas-dev/pandas/issues/34506 df = DataFrame({"a": [1, 2, 3]}) values = [] # Save row values function is applied to def reducing_function(row): values.extend(row) def non_reducing_function(row): values.extend(row) return row for func in [reducing_function, non_reducing_function]: del values[:] df.apply(func, raw=True, axis=1) assert values == list(df.a.to_list()) def test_applymap_function_runs_once(): df = DataFrame({"a": [1, 2, 3]}) values = [] # Save values function is applied to def reducing_function(val): values.append(val) def non_reducing_function(val): values.append(val) return val for func in [reducing_function, non_reducing_function]: del values[:] df.applymap(func) assert values == df.a.to_list() def test_apply_with_byte_string(): # GH 34529 df = DataFrame(np.array([b"abcd", b"efgh"]), columns=["col"]) expected = DataFrame(np.array([b"abcd", b"efgh"]), columns=["col"], dtype=object) # After we make the apply we expect a dataframe just # like the original but with the object datatype result = df.apply(lambda x: x.astype("object")) tm.assert_frame_equal(result, expected) @pytest.mark.parametrize("val", ["asd", 12, None, np.NaN]) def test_apply_category_equalness(val): # Check if categorical comparisons on apply, GH 21239 df_values = ["asd", None, 12, "asd", "cde", np.NaN] df = DataFrame({"a": df_values}, dtype="category") result = df.a.apply(lambda x: x == val) expected = Series( [np.NaN if pd.isnull(x) else x == val for x in df_values], name="a" ) tm.assert_series_equal(result, expected) # the user has supplied an opaque UDF where # they are transforming the input that requires # us to infer the output def test_infer_row_shape(): # GH 17437 # if row shape is changing, infer it df = DataFrame(np.random.rand(10, 2)) result = df.apply(np.fft.fft, axis=0).shape assert result == (10, 2) result = df.apply(np.fft.rfft, axis=0).shape assert result == (6, 2) def test_with_dictlike_columns(): # GH 17602 df = DataFrame([[1, 2], [1, 2]], columns=["a", "b"]) result = df.apply(lambda x: {"s": x["a"] + x["b"]}, axis=1) expected = Series([{"s": 3} for t in df.itertuples()]) tm.assert_series_equal(result, expected) df["tm"] = [ Timestamp("2017-05-01 00:00:00"), Timestamp("2017-05-02 00:00:00"), ] result = df.apply(lambda x: {"s": x["a"] + x["b"]}, axis=1) tm.assert_series_equal(result, expected) # compose a series result = (df["a"] + df["b"]).apply(lambda x: {"s": x}) expected = Series([{"s": 3}, {"s": 3}]) tm.assert_series_equal(result, expected) def test_with_dictlike_columns_with_datetime(): # GH 18775 df = DataFrame() df["author"] = ["X", "Y", "Z"] df["publisher"] = ["BBC", "NBC", "N24"] df["date"] = pd.to_datetime( ["17-10-2010 07:15:30", "13-05-2011 08:20:35", "15-01-2013 09:09:09"] ) result = df.apply(lambda x: {}, axis=1) expected = Series([{}, {}, {}]) tm.assert_series_equal(result, expected) def test_with_dictlike_columns_with_infer(): # GH 17602 df = DataFrame([[1, 2], [1, 2]], columns=["a", "b"]) result = df.apply(lambda x: {"s": x["a"] + x["b"]}, axis=1, result_type="expand") expected = DataFrame({"s": [3, 3]}) tm.assert_frame_equal(result, expected) df["tm"] = [ Timestamp("2017-05-01 00:00:00"), Timestamp("2017-05-02 00:00:00"), ] result = df.apply(lambda x: {"s": x["a"] + x["b"]}, axis=1, result_type="expand") tm.assert_frame_equal(result, expected) def test_with_listlike_columns(): # GH 17348 df = DataFrame( { "a": Series(np.random.randn(4)), "b": ["a", "list", "of", "words"], "ts": date_range("2016-10-01", periods=4, freq="H"), } ) result = df[["a", "b"]].apply(tuple, axis=1) expected = Series([t[1:] for t in df[["a", "b"]].itertuples()]) tm.assert_series_equal(result, expected) result = df[["a", "ts"]].apply(tuple, axis=1) expected = Series([t[1:] for t in df[["a", "ts"]].itertuples()]) tm.assert_series_equal(result, expected) def test_with_listlike_columns_returning_list(): # GH 18919 df = DataFrame({"x": Series([["a", "b"], ["q"]]), "y": Series([["z"], ["q", "t"]])}) df.index = MultiIndex.from_tuples([("i0", "j0"), ("i1", "j1")]) result = df.apply(lambda row: [el for el in row["x"] if el in row["y"]], axis=1) expected = Series([[], ["q"]], index=df.index) tm.assert_series_equal(result, expected) def test_infer_output_shape_columns(): # GH 18573 df = DataFrame( { "number": [1.0, 2.0], "string": ["foo", "bar"], "datetime": [ Timestamp("2017-11-29 03:30:00"), Timestamp("2017-11-29 03:45:00"), ], } ) result = df.apply(lambda row: (row.number, row.string), axis=1) expected = Series([(t.number, t.string) for t in df.itertuples()]) tm.assert_series_equal(result, expected) def test_infer_output_shape_listlike_columns(): # GH 16353 df = DataFrame(np.random.randn(6, 3), columns=["A", "B", "C"]) result = df.apply(lambda x: [1, 2, 3], axis=1) expected = Series([[1, 2, 3] for t in df.itertuples()]) tm.assert_series_equal(result, expected) result = df.apply(lambda x: [1, 2], axis=1) expected = Series([[1, 2] for t in df.itertuples()]) tm.assert_series_equal(result, expected) @pytest.mark.parametrize("val", [1, 2]) def test_infer_output_shape_listlike_columns_np_func(val): # GH 17970 df = DataFrame({"a": [1, 2, 3]}, index=list("abc")) result = df.apply(lambda row: np.ones(val), axis=1) expected = Series([np.ones(val) for t in df.itertuples()], index=df.index) tm.assert_series_equal(result, expected) def test_infer_output_shape_listlike_columns_with_timestamp(): # GH 17892 df = DataFrame( { "a": [ Timestamp("2010-02-01"), Timestamp("2010-02-04"), Timestamp("2010-02-05"), Timestamp("2010-02-06"), ], "b": [9, 5, 4, 3], "c": [5, 3, 4, 2], "d": [1, 2, 3, 4], } ) def fun(x): return (1, 2) result = df.apply(fun, axis=1) expected = Series([(1, 2) for t in df.itertuples()]) tm.assert_series_equal(result, expected) @pytest.mark.parametrize("lst", [[1, 2, 3], [1, 2]]) def test_consistent_coerce_for_shapes(lst): # we want column names to NOT be propagated # just because the shape matches the input shape df = DataFrame(np.random.randn(4, 3), columns=["A", "B", "C"]) result = df.apply(lambda x: lst, axis=1) expected = Series([lst for t in df.itertuples()]) tm.assert_series_equal(result, expected) def test_consistent_names(int_frame_const_col): # if a Series is returned, we should use the resulting index names df = int_frame_const_col result = df.apply( lambda x: Series([1, 2, 3], index=["test", "other", "cols"]), axis=1 ) expected = int_frame_const_col.rename( columns={"A": "test", "B": "other", "C": "cols"} ) tm.assert_frame_equal(result, expected) result = df.apply(lambda x: Series([1, 2], index=["test", "other"]), axis=1) expected = expected[["test", "other"]] tm.assert_frame_equal(result, expected) def test_result_type(int_frame_const_col): # result_type should be consistent no matter which # path we take in the code df = int_frame_const_col result = df.apply(lambda x: [1, 2, 3], axis=1, result_type="expand") expected = df.copy() expected.columns = [0, 1, 2] tm.assert_frame_equal(result, expected) def test_result_type_shorter_list(int_frame_const_col): # result_type should be consistent no matter which # path we take in the code df = int_frame_const_col result = df.apply(lambda x: [1, 2], axis=1, result_type="expand") expected = df[["A", "B"]].copy() expected.columns = [0, 1] tm.assert_frame_equal(result, expected) def test_result_type_broadcast(int_frame_const_col): # result_type should be consistent no matter which # path we take in the code df = int_frame_const_col # broadcast result result = df.apply(lambda x: [1, 2, 3], axis=1, result_type="broadcast") expected = df.copy() tm.assert_frame_equal(result, expected) def test_result_type_broadcast_series_func(int_frame_const_col): # result_type should be consistent no matter which # path we take in the code df = int_frame_const_col columns = ["other", "col", "names"] result = df.apply( lambda x: Series([1, 2, 3], index=columns), axis=1, result_type="broadcast" ) expected = df.copy() tm.assert_frame_equal(result, expected) def test_result_type_series_result(int_frame_const_col): # result_type should be consistent no matter which # path we take in the code df = int_frame_const_col # series result result = df.apply(lambda x: Series([1, 2, 3], index=x.index), axis=1) expected = df.copy() tm.assert_frame_equal(result, expected) def test_result_type_series_result_other_index(int_frame_const_col): # result_type should be consistent no matter which # path we take in the code df = int_frame_const_col # series result with other index columns = ["other", "col", "names"] result = df.apply(lambda x: Series([1, 2, 3], index=columns), axis=1) expected = df.copy() expected.columns = columns tm.assert_frame_equal(result, expected) @pytest.mark.parametrize( "box", [lambda x: list(x), lambda x: tuple(x), lambda x: np.array(x, dtype="int64")], ids=["list", "tuple", "array"], ) def test_consistency_for_boxed(box, int_frame_const_col): # passing an array or list should not affect the output shape df = int_frame_const_col result = df.apply(lambda x: box([1, 2]), axis=1) expected = Series([box([1, 2]) for t in df.itertuples()]) tm.assert_series_equal(result, expected) result = df.apply(lambda x: box([1, 2]), axis=1, result_type="expand") expected = int_frame_const_col[["A", "B"]].rename(columns={"A": 0, "B": 1}) tm.assert_frame_equal(result, expected) def test_agg_transform(axis, float_frame): other_axis = 1 if axis in {0, "index"} else 0 with np.errstate(all="ignore"): f_abs = np.abs(float_frame) f_sqrt = np.sqrt(float_frame) # ufunc expected = f_sqrt.copy() result = float_frame.apply(np.sqrt, axis=axis) tm.assert_frame_equal(result, expected) # list-like result = float_frame.apply([np.sqrt], axis=axis) expected = f_sqrt.copy() if axis in {0, "index"}: expected.columns = MultiIndex.from_product([float_frame.columns, ["sqrt"]]) else: expected.index = MultiIndex.from_product([float_frame.index, ["sqrt"]]) tm.assert_frame_equal(result, expected) # multiple items in list # these are in the order as if we are applying both # functions per series and then concatting result = float_frame.apply([np.abs, np.sqrt], axis=axis) expected = zip_frames([f_abs, f_sqrt], axis=other_axis) if axis in {0, "index"}: expected.columns = MultiIndex.from_product( [float_frame.columns, ["absolute", "sqrt"]] ) else: expected.index = MultiIndex.from_product( [float_frame.index, ["absolute", "sqrt"]] ) tm.assert_frame_equal(result, expected) def test_demo(): # demonstration tests df = DataFrame({"A": range(5), "B": 5}) result = df.agg(["min", "max"]) expected = DataFrame( {"A": [0, 4], "B": [5, 5]}, columns=["A", "B"], index=["min", "max"] ) tm.assert_frame_equal(result, expected) def test_demo_dict_agg(): # demonstration tests df = DataFrame({"A": range(5), "B": 5}) result = df.agg({"A": ["min", "max"], "B": ["sum", "max"]}) expected = DataFrame( {"A": [4.0, 0.0, np.nan], "B": [5.0, np.nan, 25.0]}, columns=["A", "B"], index=["max", "min", "sum"], ) tm.assert_frame_equal(result.reindex_like(expected), expected) def test_agg_with_name_as_column_name(): # GH 36212 - Column name is "name" data = {"name": ["foo", "bar"]} df = DataFrame(data) # result's name should be None result = df.agg({"name": "count"}) expected = Series({"name": 2}) tm.assert_series_equal(result, expected) # Check if name is still preserved when aggregating series instead result = df["name"].agg({"name": "count"}) expected = Series({"name": 2}, name="name") tm.assert_series_equal(result, expected) def test_agg_multiple_mixed_no_warning(): # GH 20909 mdf = DataFrame( { "A": [1, 2, 3], "B": [1.0, 2.0, 3.0], "C": ["foo", "bar", "baz"], "D": date_range("20130101", periods=3), } ) expected = DataFrame( { "A": [1, 6], "B": [1.0, 6.0], "C": ["bar", "foobarbaz"], "D": [Timestamp("2013-01-01"), pd.NaT], }, index=["min", "sum"], ) # sorted index with tm.assert_produces_warning( FutureWarning, match=r"\['D'\] did not aggregate successfully" ): result = mdf.agg(["min", "sum"]) tm.assert_frame_equal(result, expected) with tm.assert_produces_warning( FutureWarning, match=r"\['D'\] did not aggregate successfully" ): result = mdf[["D", "C", "B", "A"]].agg(["sum", "min"]) # GH40420: the result of .agg should have an index that is sorted # according to the arguments provided to agg. expected = expected[["D", "C", "B", "A"]].reindex(["sum", "min"]) tm.assert_frame_equal(result, expected) def test_agg_reduce(axis, float_frame): other_axis = 1 if axis in {0, "index"} else 0 name1, name2 = float_frame.axes[other_axis].unique()[:2].sort_values() # all reducers expected = pd.concat( [ float_frame.mean(axis=axis), float_frame.max(axis=axis), float_frame.sum(axis=axis), ], axis=1, ) expected.columns = ["mean", "max", "sum"] expected = expected.T if axis in {0, "index"} else expected result = float_frame.agg(["mean", "max", "sum"], axis=axis) tm.assert_frame_equal(result, expected) # dict input with scalars func = {name1: "mean", name2: "sum"} result = float_frame.agg(func, axis=axis) expected = Series( [ float_frame.loc(other_axis)[name1].mean(), float_frame.loc(other_axis)[name2].sum(), ], index=[name1, name2], ) tm.assert_series_equal(result, expected) # dict input with lists func = {name1: ["mean"], name2: ["sum"]} result = float_frame.agg(func, axis=axis) expected = DataFrame( { name1: Series([float_frame.loc(other_axis)[name1].mean()], index=["mean"]), name2: Series([float_frame.loc(other_axis)[name2].sum()], index=["sum"]), } ) expected = expected.T if axis in {1, "columns"} else expected tm.assert_frame_equal(result, expected) # dict input with lists with multiple func = {name1: ["mean", "sum"], name2: ["sum", "max"]} result = float_frame.agg(func, axis=axis) expected = pd.concat( { name1: Series( [ float_frame.loc(other_axis)[name1].mean(), float_frame.loc(other_axis)[name1].sum(), ], index=["mean", "sum"], ), name2: Series( [ float_frame.loc(other_axis)[name2].sum(), float_frame.loc(other_axis)[name2].max(), ], index=["sum", "max"], ), }, axis=1, ) expected = expected.T if axis in {1, "columns"} else expected tm.assert_frame_equal(result, expected) def test_nuiscance_columns(): # GH 15015 df = DataFrame( { "A": [1, 2, 3], "B": [1.0, 2.0, 3.0], "C": ["foo", "bar", "baz"], "D": date_range("20130101", periods=3), } ) result = df.agg("min") expected = Series([1, 1.0, "bar", Timestamp("20130101")], index=df.columns) tm.assert_series_equal(result, expected) result = df.agg(["min"]) expected = DataFrame( [[1, 1.0, "bar", Timestamp("20130101")]], index=["min"], columns=df.columns, ) tm.assert_frame_equal(result, expected) with tm.assert_produces_warning(FutureWarning, match="Select only valid"): result = df.agg("sum") expected = Series([6, 6.0, "foobarbaz"], index=["A", "B", "C"]) tm.assert_series_equal(result, expected) with tm.assert_produces_warning( FutureWarning, match=r"\['D'\] did not aggregate successfully" ): result = df.agg(["sum"]) expected = DataFrame( [[6, 6.0, "foobarbaz"]], index=["sum"], columns=["A", "B", "C"] ) tm.assert_frame_equal(result, expected) @pytest.mark.parametrize("method", ["agg", "apply", "transform"]) def test_numeric_only_warning_numpy(method): # GH#50538 df = DataFrame({"a": [1, 1, 2], "b": list("xyz")}) if method == "agg": msg = "The operation ", ""] ) tm.assert_frame_equal(result, expected) def test_apply_raw_returns_string(): # https://github.com/pandas-dev/pandas/issues/35940 df = DataFrame({"A": ["aa", "bbb"]}) result = df.apply(lambda x: x[0], axis=1, raw=True) expected = Series(["aa", "bbb"]) tm.assert_series_equal(result, expected) def test_aggregation_func_column_order(): # GH40420: the result of .agg should have an index that is sorted # according to the arguments provided to agg. df = DataFrame( [ ("1", 1, 0, 0), ("2", 2, 0, 0), ("3", 3, 0, 0), ("4", 4, 5, 4), ("5", 5, 6, 6), ("6", 6, 7, 7), ], columns=("item", "att1", "att2", "att3"), ) def foo(s): return s.sum() / 2 aggs = ["sum", foo, "count", "min"] with tm.assert_produces_warning( FutureWarning, match=r"\['item'\] did not aggregate successfully" ): result = df.agg(aggs) expected = DataFrame( { "item": ["123456", np.nan, 6, "1"], "att1": [21.0, 10.5, 6.0, 1.0], "att2": [18.0, 9.0, 6.0, 0.0], "att3": [17.0, 8.5, 6.0, 0.0], }, index=["sum", "foo", "count", "min"], ) tm.assert_frame_equal(result, expected) def test_apply_getitem_axis_1(): # GH 13427 df = DataFrame({"a": [0, 1, 2], "b": [1, 2, 3]}) result = df[["a", "a"]].apply(lambda x: x[0] + x[1], axis=1) expected = Series([0, 2, 4]) tm.assert_series_equal(result, expected) def test_nuisance_depr_passes_through_warnings(): # GH 43740 # DataFrame.agg with list-likes may emit warnings for both individual # args and for entire columns, but we only want to emit once. We # catch and suppress the warnings for individual args, but need to make # sure if some other warnings were raised, they get passed through to # the user. def foo(x): warnings.warn("Hello, World!") return x.sum() df = DataFrame({"a": [1, 2, 3]}) with tm.assert_produces_warning(UserWarning, match="Hello, World!"): df.agg([foo]) def test_apply_type(): # GH 46719 df = DataFrame( {"col1": [3, "string", float], "col2": [0.25, datetime(2020, 1, 1), np.nan]}, index=["a", "b", "c"], ) # applymap result = df.applymap(type) expected = DataFrame( {"col1": [int, str, type], "col2": [float, datetime, float]}, index=["a", "b", "c"], ) tm.assert_frame_equal(result, expected) # axis=0 result = df.apply(type, axis=0) expected = Series({"col1": Series, "col2": Series}) tm.assert_series_equal(result, expected) # axis=1 result = df.apply(type, axis=1) expected = Series({"a": Series, "b": Series, "c": Series}) tm.assert_series_equal(result, expected) def test_apply_on_empty_dataframe(): # GH 39111 df = DataFrame({"a": [1, 2], "b": [3, 0]}) result = df.head(0).apply(lambda x: max(x["a"], x["b"]), axis=1) expected = Series([], dtype=np.float64) tm.assert_series_equal(result, expected) @pytest.mark.parametrize( "test, constant", [ ({"a": [1, 2, 3], "b": [1, 1, 1]}, {"a": [1, 2, 3], "b": [1]}), ({"a": [2, 2, 2], "b": [1, 1, 1]}, {"a": [2], "b": [1]}), ], ) def test_unique_agg_type_is_series(test, constant): # GH#22558 df1 = DataFrame(test) expected = Series(data=constant, index=["a", "b"], dtype="object") aggregation = {"a": "unique", "b": "unique"} result = df1.agg(aggregation) tm.assert_series_equal(result, expected) def test_any_non_keyword_deprecation(): df = DataFrame({"A": [1, 2], "B": [0, 2], "C": [0, 0]}) msg = ( "In a future version of pandas all arguments of " "DataFrame.any and Series.any will be keyword-only." ) with tm.assert_produces_warning(FutureWarning, match=msg): result = df.any("index", None) expected = Series({"A": True, "B": True, "C": False}) tm.assert_series_equal(result, expected) s = Series([False, False, False]) msg = ( "In a future version of pandas all arguments of " "DataFrame.any and Series.any will be keyword-only." ) with tm.assert_produces_warning(FutureWarning, match=msg): result = s.any("index") expected = False tm.assert_equal(result, expected) def test_any_apply_keyword_non_zero_axis_regression(): # https://github.com/pandas-dev/pandas/issues/48656 df = DataFrame({"A": [1, 2, 0], "B": [0, 2, 0], "C": [0, 0, 0]}) expected = Series([True, True, False]) tm.assert_series_equal(df.any(axis=1), expected) result = df.apply("any", axis=1) tm.assert_series_equal(result, expected) result = df.apply("any", 1) tm.assert_series_equal(result, expected)