from collections import deque import string import numpy as np import pytest import pandas as pd import pandas._testing as tm from pandas.arrays import SparseArray UNARY_UFUNCS = [np.positive, np.floor, np.exp] BINARY_UFUNCS = [np.add, np.logaddexp] # dunder op SPARSE = [True, False] SPARSE_IDS = ["sparse", "dense"] SHUFFLE = [True, False] @pytest.fixture def arrays_for_binary_ufunc(): """ A pair of random, length-100 integer-dtype arrays, that are mostly 0. """ a1 = np.random.randint(0, 10, 100, dtype="int64") a2 = np.random.randint(0, 10, 100, dtype="int64") a1[::3] = 0 a2[::4] = 0 return a1, a2 @pytest.mark.parametrize("ufunc", UNARY_UFUNCS) @pytest.mark.parametrize("sparse", SPARSE, ids=SPARSE_IDS) def test_unary_ufunc(ufunc, sparse): # Test that ufunc(Series) == Series(ufunc) array = np.random.randint(0, 10, 10, dtype="int64") array[::2] = 0 if sparse: array = SparseArray(array, dtype=pd.SparseDtype("int64", 0)) index = list(string.ascii_letters[:10]) name = "name" series = pd.Series(array, index=index, name=name) result = ufunc(series) expected = pd.Series(ufunc(array), index=index, name=name) tm.assert_series_equal(result, expected) @pytest.mark.parametrize("ufunc", BINARY_UFUNCS) @pytest.mark.parametrize("sparse", SPARSE, ids=SPARSE_IDS) @pytest.mark.parametrize("flip", [True, False], ids=["flipped", "straight"]) def test_binary_ufunc_with_array(flip, sparse, ufunc, arrays_for_binary_ufunc): # Test that ufunc(Series(a), array) == Series(ufunc(a, b)) a1, a2 = arrays_for_binary_ufunc if sparse: a1 = SparseArray(a1, dtype=pd.SparseDtype("int64", 0)) a2 = SparseArray(a2, dtype=pd.SparseDtype("int64", 0)) name = "name" # op(Series, array) preserves the name. series = pd.Series(a1, name=name) other = a2 array_args = (a1, a2) series_args = (series, other) # ufunc(series, array) if flip: array_args = reversed(array_args) series_args = reversed(series_args) # ufunc(array, series) expected = pd.Series(ufunc(*array_args), name=name) result = ufunc(*series_args) tm.assert_series_equal(result, expected) @pytest.mark.parametrize("ufunc", BINARY_UFUNCS) @pytest.mark.parametrize("sparse", SPARSE, ids=SPARSE_IDS) @pytest.mark.parametrize("flip", [True, False], ids=["flipped", "straight"]) def test_binary_ufunc_with_index(flip, sparse, ufunc, arrays_for_binary_ufunc): # Test that # * func(Series(a), Series(b)) == Series(ufunc(a, b)) # * ufunc(Index, Series) dispatches to Series (returns a Series) a1, a2 = arrays_for_binary_ufunc if sparse: a1 = SparseArray(a1, dtype=pd.SparseDtype("int64", 0)) a2 = SparseArray(a2, dtype=pd.SparseDtype("int64", 0)) name = "name" # op(Series, array) preserves the name. series = pd.Series(a1, name=name) other = pd.Index(a2, name=name).astype("int64") array_args = (a1, a2) series_args = (series, other) # ufunc(series, array) if flip: array_args = reversed(array_args) series_args = reversed(series_args) # ufunc(array, series) expected = pd.Series(ufunc(*array_args), name=name) result = ufunc(*series_args) tm.assert_series_equal(result, expected) @pytest.mark.parametrize("ufunc", BINARY_UFUNCS) @pytest.mark.parametrize("sparse", SPARSE, ids=SPARSE_IDS) @pytest.mark.parametrize("shuffle", [True, False], ids=["unaligned", "aligned"]) @pytest.mark.parametrize("flip", [True, False], ids=["flipped", "straight"]) def test_binary_ufunc_with_series( flip, shuffle, sparse, ufunc, arrays_for_binary_ufunc ): # Test that # * func(Series(a), Series(b)) == Series(ufunc(a, b)) # with alignment between the indices a1, a2 = arrays_for_binary_ufunc if sparse: a1 = SparseArray(a1, dtype=pd.SparseDtype("int64", 0)) a2 = SparseArray(a2, dtype=pd.SparseDtype("int64", 0)) name = "name" # op(Series, array) preserves the name. series = pd.Series(a1, name=name) other = pd.Series(a2, name=name) idx = np.random.permutation(len(a1)) if shuffle: other = other.take(idx) if flip: index = other.align(series)[0].index else: index = series.align(other)[0].index else: index = series.index array_args = (a1, a2) series_args = (series, other) # ufunc(series, array) if flip: array_args = tuple(reversed(array_args)) series_args = tuple(reversed(series_args)) # ufunc(array, series) expected = pd.Series(ufunc(*array_args), index=index, name=name) result = ufunc(*series_args) tm.assert_series_equal(result, expected) @pytest.mark.parametrize("ufunc", BINARY_UFUNCS) @pytest.mark.parametrize("sparse", SPARSE, ids=SPARSE_IDS) @pytest.mark.parametrize("flip", [True, False]) def test_binary_ufunc_scalar(ufunc, sparse, flip, arrays_for_binary_ufunc): # Test that # * ufunc(Series, scalar) == Series(ufunc(array, scalar)) # * ufunc(Series, scalar) == ufunc(scalar, Series) array, _ = arrays_for_binary_ufunc if sparse: array = SparseArray(array) other = 2 series = pd.Series(array, name="name") series_args = (series, other) array_args = (array, other) if flip: series_args = tuple(reversed(series_args)) array_args = tuple(reversed(array_args)) expected = pd.Series(ufunc(*array_args), name="name") result = ufunc(*series_args) tm.assert_series_equal(result, expected) @pytest.mark.parametrize("ufunc", [np.divmod]) # any others? @pytest.mark.parametrize("sparse", SPARSE, ids=SPARSE_IDS) @pytest.mark.parametrize("shuffle", SHUFFLE) @pytest.mark.filterwarnings("ignore:divide by zero:RuntimeWarning") def test_multiple_output_binary_ufuncs(ufunc, sparse, shuffle, arrays_for_binary_ufunc): # Test that # the same conditions from binary_ufunc_scalar apply to # ufuncs with multiple outputs. if sparse and ufunc is np.divmod: pytest.skip("sparse divmod not implemented.") a1, a2 = arrays_for_binary_ufunc # work around https://github.com/pandas-dev/pandas/issues/26987 a1[a1 == 0] = 1 a2[a2 == 0] = 1 if sparse: a1 = SparseArray(a1, dtype=pd.SparseDtype("int64", 0)) a2 = SparseArray(a2, dtype=pd.SparseDtype("int64", 0)) s1 = pd.Series(a1) s2 = pd.Series(a2) if shuffle: # ensure we align before applying the ufunc s2 = s2.sample(frac=1) expected = ufunc(a1, a2) assert isinstance(expected, tuple) result = ufunc(s1, s2) assert isinstance(result, tuple) tm.assert_series_equal(result[0], pd.Series(expected[0])) tm.assert_series_equal(result[1], pd.Series(expected[1])) @pytest.mark.parametrize("sparse", SPARSE, ids=SPARSE_IDS) def test_multiple_output_ufunc(sparse, arrays_for_binary_ufunc): # Test that the same conditions from unary input apply to multi-output # ufuncs array, _ = arrays_for_binary_ufunc if sparse: array = SparseArray(array) series = pd.Series(array, name="name") result = np.modf(series) expected = np.modf(array) assert isinstance(result, tuple) assert isinstance(expected, tuple) tm.assert_series_equal(result[0], pd.Series(expected[0], name="name")) tm.assert_series_equal(result[1], pd.Series(expected[1], name="name")) @pytest.mark.parametrize("sparse", SPARSE, ids=SPARSE_IDS) @pytest.mark.parametrize("ufunc", BINARY_UFUNCS) def test_binary_ufunc_drops_series_name(ufunc, sparse, arrays_for_binary_ufunc): # Drop the names when they differ. a1, a2 = arrays_for_binary_ufunc s1 = pd.Series(a1, name="a") s2 = pd.Series(a2, name="b") result = ufunc(s1, s2) assert result.name is None def test_object_series_ok(): class Dummy: def __init__(self, value): self.value = value def __add__(self, other): return self.value + other.value arr = np.array([Dummy(0), Dummy(1)]) ser = pd.Series(arr) tm.assert_series_equal(np.add(ser, ser), pd.Series(np.add(ser, arr))) tm.assert_series_equal(np.add(ser, Dummy(1)), pd.Series(np.add(ser, Dummy(1)))) @pytest.mark.parametrize( "values", [ pd.array([1, 3, 2], dtype="int64"), pd.array([1, 10, 0], dtype="Sparse[int]"), pd.to_datetime(["2000", "2010", "2001"]), pd.to_datetime(["2000", "2010", "2001"]).tz_localize("CET"), pd.to_datetime(["2000", "2010", "2001"]).to_period(freq="D"), ], ) def test_reduce(values): a = pd.Series(values) assert np.maximum.reduce(a) == values[1] @pytest.mark.parametrize("type_", [list, deque, tuple]) def test_binary_ufunc_other_types(type_): a = pd.Series([1, 2, 3], name="name") b = type_([3, 4, 5]) result = np.add(a, b) expected = pd.Series(np.add(a.to_numpy(), b), name="name") tm.assert_series_equal(result, expected) def test_object_dtype_ok(): class Thing: def __init__(self, value): self.value = value def __add__(self, other): other = getattr(other, "value", other) return type(self)(self.value + other) def __eq__(self, other) -> bool: return type(other) is Thing and self.value == other.value def __repr__(self) -> str: return f"Thing({self.value})" s = pd.Series([Thing(1), Thing(2)]) result = np.add(s, Thing(1)) expected = pd.Series([Thing(2), Thing(3)]) tm.assert_series_equal(result, expected) def test_outer(): # https://github.com/pandas-dev/pandas/issues/27186 s = pd.Series([1, 2, 3]) o = np.array([1, 2, 3]) with pytest.raises(NotImplementedError): np.subtract.outer(s, o)