craftbeerpi4-pione/venv/lib/python3.8/site-packages/pandas/tests/extension/test_numpy.py

492 lines
16 KiB
Python

import numpy as np
import pytest
import pandas as pd
import pandas._testing as tm
from pandas.core.arrays.numpy_ import PandasArray, PandasDtype
from . import base
@pytest.fixture(params=["float", "object"])
def dtype(request):
return PandasDtype(np.dtype(request.param))
@pytest.fixture
def allow_in_pandas(monkeypatch):
"""
A monkeypatch to tells pandas to let us in.
By default, passing a PandasArray to an index / series / frame
constructor will unbox that PandasArray to an ndarray, and treat
it as a non-EA column. We don't want people using EAs without
reason.
The mechanism for this is a check against ABCPandasArray
in each constructor.
But, for testing, we need to allow them in pandas. So we patch
the _typ of PandasArray, so that we evade the ABCPandasArray
check.
"""
with monkeypatch.context() as m:
m.setattr(PandasArray, "_typ", "extension")
yield
@pytest.fixture
def data(allow_in_pandas, dtype):
if dtype.numpy_dtype == "object":
return pd.Series([(i,) for i in range(100)]).array
return PandasArray(np.arange(1, 101, dtype=dtype._dtype))
@pytest.fixture
def data_missing(allow_in_pandas, dtype):
if dtype.numpy_dtype == "object":
return PandasArray(np.array([np.nan, (1,)], dtype=object))
return PandasArray(np.array([np.nan, 1.0]))
@pytest.fixture
def na_value():
return np.nan
@pytest.fixture
def na_cmp():
def cmp(a, b):
return np.isnan(a) and np.isnan(b)
return cmp
@pytest.fixture
def data_for_sorting(allow_in_pandas, dtype):
"""Length-3 array with a known sort order.
This should be three items [B, C, A] with
A < B < C
"""
if dtype.numpy_dtype == "object":
# Use an empty tuple for first element, then remove,
# to disable np.array's shape inference.
return PandasArray(np.array([(), (2,), (3,), (1,)], dtype=object)[1:])
return PandasArray(np.array([1, 2, 0]))
@pytest.fixture
def data_missing_for_sorting(allow_in_pandas, dtype):
"""Length-3 array with a known sort order.
This should be three items [B, NA, A] with
A < B and NA missing.
"""
if dtype.numpy_dtype == "object":
return PandasArray(np.array([(1,), np.nan, (0,)], dtype=object))
return PandasArray(np.array([1, np.nan, 0]))
@pytest.fixture
def data_for_grouping(allow_in_pandas, dtype):
"""Data for factorization, grouping, and unique tests.
Expected to be like [B, B, NA, NA, A, A, B, C]
Where A < B < C and NA is missing
"""
if dtype.numpy_dtype == "object":
a, b, c = (1,), (2,), (3,)
else:
a, b, c = np.arange(3)
return PandasArray(
np.array([b, b, np.nan, np.nan, a, a, b, c], dtype=dtype.numpy_dtype)
)
@pytest.fixture
def skip_numpy_object(dtype):
"""
Tests for PandasArray with nested data. Users typically won't create
these objects via `pd.array`, but they can show up through `.array`
on a Series with nested data. Many of the base tests fail, as they aren't
appropriate for nested data.
This fixture allows these tests to be skipped when used as a usefixtures
marker to either an individual test or a test class.
"""
if dtype == "object":
raise pytest.skip("Skipping for object dtype.")
skip_nested = pytest.mark.usefixtures("skip_numpy_object")
class BaseNumPyTests:
pass
class TestCasting(BaseNumPyTests, base.BaseCastingTests):
@skip_nested
def test_astype_str(self, data):
# ValueError: setting an array element with a sequence
super().test_astype_str(data)
@skip_nested
def test_astype_string(self, data):
# GH-33465
# ValueError: setting an array element with a sequence
super().test_astype_string(data)
class TestConstructors(BaseNumPyTests, base.BaseConstructorsTests):
@pytest.mark.skip(reason="We don't register our dtype")
# We don't want to register. This test should probably be split in two.
def test_from_dtype(self, data):
pass
@skip_nested
def test_array_from_scalars(self, data):
# ValueError: PandasArray must be 1-dimensional.
super().test_array_from_scalars(data)
@skip_nested
def test_series_constructor_scalar_with_index(self, data, dtype):
# ValueError: Length of passed values is 1, index implies 3.
super().test_series_constructor_scalar_with_index(data, dtype)
class TestDtype(BaseNumPyTests, base.BaseDtypeTests):
@pytest.mark.skip(reason="Incorrect expected.")
# we unsurprisingly clash with a NumPy name.
def test_check_dtype(self, data):
pass
class TestGetitem(BaseNumPyTests, base.BaseGetitemTests):
@skip_nested
def test_getitem_scalar(self, data):
# AssertionError
super().test_getitem_scalar(data)
@skip_nested
def test_take_series(self, data):
# ValueError: PandasArray must be 1-dimensional.
super().test_take_series(data)
def test_loc_iloc_frame_single_dtype(self, data, request):
npdtype = data.dtype.numpy_dtype
if npdtype == object:
# GH#33125
mark = pytest.mark.xfail(
reason="GH#33125 astype doesn't recognize data.dtype"
)
request.node.add_marker(mark)
super().test_loc_iloc_frame_single_dtype(data)
class TestGroupby(BaseNumPyTests, base.BaseGroupbyTests):
@skip_nested
def test_groupby_extension_apply(
self, data_for_grouping, groupby_apply_op, request
):
super().test_groupby_extension_apply(data_for_grouping, groupby_apply_op)
class TestInterface(BaseNumPyTests, base.BaseInterfaceTests):
@skip_nested
def test_array_interface(self, data):
# NumPy array shape inference
super().test_array_interface(data)
class TestMethods(BaseNumPyTests, base.BaseMethodsTests):
@pytest.mark.skip(reason="TODO: remove?")
def test_value_counts(self, all_data, dropna):
pass
@pytest.mark.xfail(reason="not working. will be covered by #32028")
def test_value_counts_with_normalize(self, data):
return super().test_value_counts_with_normalize(data)
@pytest.mark.skip(reason="Incorrect expected")
# We have a bool dtype, so the result is an ExtensionArray
# but expected is not
def test_combine_le(self, data_repeated):
super().test_combine_le(data_repeated)
@skip_nested
def test_combine_add(self, data_repeated):
# Not numeric
super().test_combine_add(data_repeated)
@skip_nested
def test_shift_fill_value(self, data):
# np.array shape inference. Shift implementation fails.
super().test_shift_fill_value(data)
@skip_nested
@pytest.mark.parametrize("box", [pd.Series, lambda x: x])
@pytest.mark.parametrize("method", [lambda x: x.unique(), pd.unique])
def test_unique(self, data, box, method):
# Fails creating expected
super().test_unique(data, box, method)
@skip_nested
def test_fillna_copy_frame(self, data_missing):
# The "scalar" for this array isn't a scalar.
super().test_fillna_copy_frame(data_missing)
@skip_nested
def test_fillna_copy_series(self, data_missing):
# The "scalar" for this array isn't a scalar.
super().test_fillna_copy_series(data_missing)
@skip_nested
def test_hash_pandas_object_works(self, data, as_frame):
# ndarray of tuples not hashable
super().test_hash_pandas_object_works(data, as_frame)
@skip_nested
def test_searchsorted(self, data_for_sorting, as_series):
# Test setup fails.
super().test_searchsorted(data_for_sorting, as_series)
@skip_nested
def test_where_series(self, data, na_value, as_frame):
# Test setup fails.
super().test_where_series(data, na_value, as_frame)
@skip_nested
@pytest.mark.parametrize("repeats", [0, 1, 2, [1, 2, 3]])
def test_repeat(self, data, repeats, as_series, use_numpy):
# Fails creating expected
super().test_repeat(data, repeats, as_series, use_numpy)
@pytest.mark.xfail(reason="PandasArray.diff may fail on dtype")
def test_diff(self, data, periods):
return super().test_diff(data, periods)
@skip_nested
@pytest.mark.parametrize("box", [pd.array, pd.Series, pd.DataFrame])
def test_equals(self, data, na_value, as_series, box):
# Fails creating with _from_sequence
super().test_equals(data, na_value, as_series, box)
@skip_nested
class TestArithmetics(BaseNumPyTests, base.BaseArithmeticOpsTests):
divmod_exc = None
series_scalar_exc = None
frame_scalar_exc = None
series_array_exc = None
def test_divmod_series_array(self, data):
s = pd.Series(data)
self._check_divmod_op(s, divmod, data, exc=None)
@pytest.mark.skip("We implement ops")
def test_error(self, data, all_arithmetic_operators):
pass
def test_arith_series_with_scalar(self, data, all_arithmetic_operators):
super().test_arith_series_with_scalar(data, all_arithmetic_operators)
def test_arith_series_with_array(self, data, all_arithmetic_operators):
super().test_arith_series_with_array(data, all_arithmetic_operators)
class TestPrinting(BaseNumPyTests, base.BasePrintingTests):
pass
@skip_nested
class TestNumericReduce(BaseNumPyTests, base.BaseNumericReduceTests):
def check_reduce(self, s, op_name, skipna):
result = getattr(s, op_name)(skipna=skipna)
# avoid coercing int -> float. Just cast to the actual numpy type.
expected = getattr(s.astype(s.dtype._dtype), op_name)(skipna=skipna)
tm.assert_almost_equal(result, expected)
@skip_nested
class TestBooleanReduce(BaseNumPyTests, base.BaseBooleanReduceTests):
pass
class TestMissing(BaseNumPyTests, base.BaseMissingTests):
@skip_nested
def test_fillna_scalar(self, data_missing):
# Non-scalar "scalar" values.
super().test_fillna_scalar(data_missing)
@skip_nested
def test_fillna_series_method(self, data_missing, fillna_method):
# Non-scalar "scalar" values.
super().test_fillna_series_method(data_missing, fillna_method)
@skip_nested
def test_fillna_series(self, data_missing):
# Non-scalar "scalar" values.
super().test_fillna_series(data_missing)
@skip_nested
def test_fillna_frame(self, data_missing):
# Non-scalar "scalar" values.
super().test_fillna_frame(data_missing)
@pytest.mark.skip("Invalid test")
def test_fillna_fill_other(self, data):
# inplace update doesn't work correctly with patched extension arrays
# extract_array returns PandasArray, while dtype is a numpy dtype
super().test_fillna_fill_other(data_missing)
class TestReshaping(BaseNumPyTests, base.BaseReshapingTests):
@pytest.mark.skip("Incorrect parent test")
# not actually a mixed concat, since we concat int and int.
def test_concat_mixed_dtypes(self, data):
super().test_concat_mixed_dtypes(data)
@pytest.mark.xfail(
reason="GH#33125 PandasArray.astype does not recognize PandasDtype"
)
def test_concat(self, data, in_frame):
super().test_concat(data, in_frame)
@pytest.mark.xfail(
reason="GH#33125 PandasArray.astype does not recognize PandasDtype"
)
def test_concat_all_na_block(self, data_missing, in_frame):
super().test_concat_all_na_block(data_missing, in_frame)
@skip_nested
def test_merge(self, data, na_value):
# Fails creating expected
super().test_merge(data, na_value)
@skip_nested
def test_merge_on_extension_array(self, data):
# Fails creating expected
super().test_merge_on_extension_array(data)
@skip_nested
def test_merge_on_extension_array_duplicates(self, data):
# Fails creating expected
super().test_merge_on_extension_array_duplicates(data)
@skip_nested
def test_transpose_frame(self, data):
super().test_transpose_frame(data)
class TestSetitem(BaseNumPyTests, base.BaseSetitemTests):
@skip_nested
def test_setitem_scalar_series(self, data, box_in_series):
# AssertionError
super().test_setitem_scalar_series(data, box_in_series)
@skip_nested
def test_setitem_sequence(self, data, box_in_series):
# ValueError: shape mismatch: value array of shape (2,1) could not
# be broadcast to indexing result of shape (2,)
super().test_setitem_sequence(data, box_in_series)
@skip_nested
def test_setitem_sequence_mismatched_length_raises(self, data, as_array):
# ValueError: PandasArray must be 1-dimensional.
super().test_setitem_sequence_mismatched_length_raises(data, as_array)
@skip_nested
def test_setitem_sequence_broadcasts(self, data, box_in_series):
# ValueError: cannot set using a list-like indexer with a different
# length than the value
super().test_setitem_sequence_broadcasts(data, box_in_series)
@skip_nested
def test_setitem_loc_scalar_mixed(self, data):
# AssertionError
super().test_setitem_loc_scalar_mixed(data)
@skip_nested
def test_setitem_loc_scalar_multiple_homogoneous(self, data):
# AssertionError
super().test_setitem_loc_scalar_multiple_homogoneous(data)
@skip_nested
def test_setitem_iloc_scalar_mixed(self, data):
# AssertionError
super().test_setitem_iloc_scalar_mixed(data)
@skip_nested
def test_setitem_iloc_scalar_multiple_homogoneous(self, data):
# AssertionError
super().test_setitem_iloc_scalar_multiple_homogoneous(data)
@skip_nested
@pytest.mark.parametrize("setter", ["loc", None])
def test_setitem_mask_broadcast(self, data, setter):
# ValueError: cannot set using a list-like indexer with a different
# length than the value
super().test_setitem_mask_broadcast(data, setter)
@skip_nested
def test_setitem_scalar_key_sequence_raise(self, data):
# Failed: DID NOT RAISE <class 'ValueError'>
super().test_setitem_scalar_key_sequence_raise(data)
# TODO: there is some issue with PandasArray, therefore,
# skip the setitem test for now, and fix it later (GH 31446)
@skip_nested
@pytest.mark.parametrize(
"mask",
[
np.array([True, True, True, False, False]),
pd.array([True, True, True, False, False], dtype="boolean"),
],
ids=["numpy-array", "boolean-array"],
)
def test_setitem_mask(self, data, mask, box_in_series):
super().test_setitem_mask(data, mask, box_in_series)
@skip_nested
def test_setitem_mask_raises(self, data, box_in_series):
super().test_setitem_mask_raises(data, box_in_series)
@skip_nested
@pytest.mark.parametrize(
"idx",
[[0, 1, 2], pd.array([0, 1, 2], dtype="Int64"), np.array([0, 1, 2])],
ids=["list", "integer-array", "numpy-array"],
)
def test_setitem_integer_array(self, data, idx, box_in_series):
super().test_setitem_integer_array(data, idx, box_in_series)
@skip_nested
@pytest.mark.parametrize(
"idx, box_in_series",
[
([0, 1, 2, pd.NA], False),
pytest.param([0, 1, 2, pd.NA], True, marks=pytest.mark.xfail),
(pd.array([0, 1, 2, pd.NA], dtype="Int64"), False),
(pd.array([0, 1, 2, pd.NA], dtype="Int64"), False),
],
ids=["list-False", "list-True", "integer-array-False", "integer-array-True"],
)
def test_setitem_integer_with_missing_raises(self, data, idx, box_in_series):
super().test_setitem_integer_with_missing_raises(data, idx, box_in_series)
@skip_nested
def test_setitem_slice(self, data, box_in_series):
super().test_setitem_slice(data, box_in_series)
@skip_nested
def test_setitem_loc_iloc_slice(self, data):
super().test_setitem_loc_iloc_slice(data)
@skip_nested
class TestParsing(BaseNumPyTests, base.BaseParsingTests):
pass