import numpy as np import pytest from pandas._libs import groupby as libgroupby from pandas._libs.groupby import ( group_cumprod_float64, group_cumsum, group_mean, group_var, ) from pandas.core.dtypes.common import ensure_platform_int from pandas import isna import pandas._testing as tm class GroupVarTestMixin: def test_group_var_generic_1d(self): prng = np.random.RandomState(1234) out = (np.nan * np.ones((5, 1))).astype(self.dtype) counts = np.zeros(5, dtype="int64") values = 10 * prng.rand(15, 1).astype(self.dtype) labels = np.tile(np.arange(5), (3,)).astype("intp") expected_out = ( np.squeeze(values).reshape((5, 3), order="F").std(axis=1, ddof=1) ** 2 )[:, np.newaxis] expected_counts = counts + 3 self.algo(out, counts, values, labels) assert np.allclose(out, expected_out, self.rtol) tm.assert_numpy_array_equal(counts, expected_counts) def test_group_var_generic_1d_flat_labels(self): prng = np.random.RandomState(1234) out = (np.nan * np.ones((1, 1))).astype(self.dtype) counts = np.zeros(1, dtype="int64") values = 10 * prng.rand(5, 1).astype(self.dtype) labels = np.zeros(5, dtype="intp") expected_out = np.array([[values.std(ddof=1) ** 2]]) expected_counts = counts + 5 self.algo(out, counts, values, labels) assert np.allclose(out, expected_out, self.rtol) tm.assert_numpy_array_equal(counts, expected_counts) def test_group_var_generic_2d_all_finite(self): prng = np.random.RandomState(1234) out = (np.nan * np.ones((5, 2))).astype(self.dtype) counts = np.zeros(5, dtype="int64") values = 10 * prng.rand(10, 2).astype(self.dtype) labels = np.tile(np.arange(5), (2,)).astype("intp") expected_out = np.std(values.reshape(2, 5, 2), ddof=1, axis=0) ** 2 expected_counts = counts + 2 self.algo(out, counts, values, labels) assert np.allclose(out, expected_out, self.rtol) tm.assert_numpy_array_equal(counts, expected_counts) def test_group_var_generic_2d_some_nan(self): prng = np.random.RandomState(1234) out = (np.nan * np.ones((5, 2))).astype(self.dtype) counts = np.zeros(5, dtype="int64") values = 10 * prng.rand(10, 2).astype(self.dtype) values[:, 1] = np.nan labels = np.tile(np.arange(5), (2,)).astype("intp") expected_out = np.vstack( [ values[:, 0].reshape(5, 2, order="F").std(ddof=1, axis=1) ** 2, np.nan * np.ones(5), ] ).T.astype(self.dtype) expected_counts = counts + 2 self.algo(out, counts, values, labels) tm.assert_almost_equal(out, expected_out, rtol=0.5e-06) tm.assert_numpy_array_equal(counts, expected_counts) def test_group_var_constant(self): # Regression test from GH 10448. out = np.array([[np.nan]], dtype=self.dtype) counts = np.array([0], dtype="int64") values = 0.832845131556193 * np.ones((3, 1), dtype=self.dtype) labels = np.zeros(3, dtype="intp") self.algo(out, counts, values, labels) assert counts[0] == 3 assert out[0, 0] >= 0 tm.assert_almost_equal(out[0, 0], 0.0) class TestGroupVarFloat64(GroupVarTestMixin): __test__ = True algo = staticmethod(group_var) dtype = np.float64 rtol = 1e-5 def test_group_var_large_inputs(self): prng = np.random.RandomState(1234) out = np.array([[np.nan]], dtype=self.dtype) counts = np.array([0], dtype="int64") values = (prng.rand(10**6) + 10**12).astype(self.dtype) values.shape = (10**6, 1) labels = np.zeros(10**6, dtype="intp") self.algo(out, counts, values, labels) assert counts[0] == 10**6 tm.assert_almost_equal(out[0, 0], 1.0 / 12, rtol=0.5e-3) class TestGroupVarFloat32(GroupVarTestMixin): __test__ = True algo = staticmethod(group_var) dtype = np.float32 rtol = 1e-2 @pytest.mark.parametrize("dtype", ["float32", "float64"]) def test_group_ohlc(dtype): obj = np.array(np.random.randn(20), dtype=dtype) bins = np.array([6, 12, 20]) out = np.zeros((3, 4), dtype) counts = np.zeros(len(out), dtype=np.int64) labels = ensure_platform_int(np.repeat(np.arange(3), np.diff(np.r_[0, bins]))) func = libgroupby.group_ohlc func(out, counts, obj[:, None], labels) def _ohlc(group): if isna(group).all(): return np.repeat(np.nan, 4) return [group[0], group.max(), group.min(), group[-1]] expected = np.array([_ohlc(obj[:6]), _ohlc(obj[6:12]), _ohlc(obj[12:])]) tm.assert_almost_equal(out, expected) tm.assert_numpy_array_equal(counts, np.array([6, 6, 8], dtype=np.int64)) obj[:6] = np.nan func(out, counts, obj[:, None], labels) expected[0] = np.nan tm.assert_almost_equal(out, expected) def _check_cython_group_transform_cumulative(pd_op, np_op, dtype): """ Check a group transform that executes a cumulative function. Parameters ---------- pd_op : callable The pandas cumulative function. np_op : callable The analogous one in NumPy. dtype : type The specified dtype of the data. """ is_datetimelike = False data = np.array([[1], [2], [3], [4]], dtype=dtype) answer = np.zeros_like(data) labels = np.array([0, 0, 0, 0], dtype=np.intp) ngroups = 1 pd_op(answer, data, labels, ngroups, is_datetimelike) tm.assert_numpy_array_equal(np_op(data), answer[:, 0], check_dtype=False) @pytest.mark.parametrize("np_dtype", ["int64", "uint64", "float32", "float64"]) def test_cython_group_transform_cumsum(np_dtype): # see gh-4095 dtype = np.dtype(np_dtype).type pd_op, np_op = group_cumsum, np.cumsum _check_cython_group_transform_cumulative(pd_op, np_op, dtype) def test_cython_group_transform_cumprod(): # see gh-4095 dtype = np.float64 pd_op, np_op = group_cumprod_float64, np.cumproduct _check_cython_group_transform_cumulative(pd_op, np_op, dtype) def test_cython_group_transform_algos(): # see gh-4095 is_datetimelike = False # with nans labels = np.array([0, 0, 0, 0, 0], dtype=np.intp) ngroups = 1 data = np.array([[1], [2], [3], [np.nan], [4]], dtype="float64") actual = np.zeros_like(data) actual.fill(np.nan) group_cumprod_float64(actual, data, labels, ngroups, is_datetimelike) expected = np.array([1, 2, 6, np.nan, 24], dtype="float64") tm.assert_numpy_array_equal(actual[:, 0], expected) actual = np.zeros_like(data) actual.fill(np.nan) group_cumsum(actual, data, labels, ngroups, is_datetimelike) expected = np.array([1, 3, 6, np.nan, 10], dtype="float64") tm.assert_numpy_array_equal(actual[:, 0], expected) # timedelta is_datetimelike = True data = np.array([np.timedelta64(1, "ns")] * 5, dtype="m8[ns]")[:, None] actual = np.zeros_like(data, dtype="int64") group_cumsum(actual, data.view("int64"), labels, ngroups, is_datetimelike) expected = np.array( [ np.timedelta64(1, "ns"), np.timedelta64(2, "ns"), np.timedelta64(3, "ns"), np.timedelta64(4, "ns"), np.timedelta64(5, "ns"), ] ) tm.assert_numpy_array_equal(actual[:, 0].view("m8[ns]"), expected) def test_cython_group_mean_datetimelike(): actual = np.zeros(shape=(1, 1), dtype="float64") counts = np.array([0], dtype="int64") data = ( np.array( [np.timedelta64(2, "ns"), np.timedelta64(4, "ns"), np.timedelta64("NaT")], dtype="m8[ns]", )[:, None] .view("int64") .astype("float64") ) labels = np.zeros(len(data), dtype=np.intp) group_mean(actual, counts, data, labels, is_datetimelike=True) tm.assert_numpy_array_equal(actual[:, 0], np.array([3], dtype="float64")) def test_cython_group_mean_wrong_min_count(): actual = np.zeros(shape=(1, 1), dtype="float64") counts = np.zeros(1, dtype="int64") data = np.zeros(1, dtype="float64")[:, None] labels = np.zeros(1, dtype=np.intp) with pytest.raises(AssertionError, match="min_count"): group_mean(actual, counts, data, labels, is_datetimelike=True, min_count=0) def test_cython_group_mean_not_datetimelike_but_has_NaT_values(): actual = np.zeros(shape=(1, 1), dtype="float64") counts = np.array([0], dtype="int64") data = ( np.array( [np.timedelta64("NaT"), np.timedelta64("NaT")], dtype="m8[ns]", )[:, None] .view("int64") .astype("float64") ) labels = np.zeros(len(data), dtype=np.intp) group_mean(actual, counts, data, labels, is_datetimelike=False) tm.assert_numpy_array_equal( actual[:, 0], np.array(np.divide(np.add(data[0], data[1]), 2), dtype="float64") )