import numpy as np import pytest import pandas as pd from pandas import ( Categorical, CategoricalIndex, Index, Series, ) import pandas._testing as tm class TestSeriesValueCounts: def test_value_counts_datetime(self): # most dtypes are tested in tests/base values = [ pd.Timestamp("2011-01-01 09:00"), pd.Timestamp("2011-01-01 10:00"), pd.Timestamp("2011-01-01 11:00"), pd.Timestamp("2011-01-01 09:00"), pd.Timestamp("2011-01-01 09:00"), pd.Timestamp("2011-01-01 11:00"), ] exp_idx = pd.DatetimeIndex( ["2011-01-01 09:00", "2011-01-01 11:00", "2011-01-01 10:00"], name="xxx", ) exp = Series([3, 2, 1], index=exp_idx, name="count") ser = Series(values, name="xxx") tm.assert_series_equal(ser.value_counts(), exp) # check DatetimeIndex outputs the same result idx = pd.DatetimeIndex(values, name="xxx") tm.assert_series_equal(idx.value_counts(), exp) # normalize exp = Series(np.array([3.0, 2.0, 1]) / 6.0, index=exp_idx, name="proportion") tm.assert_series_equal(ser.value_counts(normalize=True), exp) tm.assert_series_equal(idx.value_counts(normalize=True), exp) def test_value_counts_datetime_tz(self): values = [ pd.Timestamp("2011-01-01 09:00", tz="US/Eastern"), pd.Timestamp("2011-01-01 10:00", tz="US/Eastern"), pd.Timestamp("2011-01-01 11:00", tz="US/Eastern"), pd.Timestamp("2011-01-01 09:00", tz="US/Eastern"), pd.Timestamp("2011-01-01 09:00", tz="US/Eastern"), pd.Timestamp("2011-01-01 11:00", tz="US/Eastern"), ] exp_idx = pd.DatetimeIndex( ["2011-01-01 09:00", "2011-01-01 11:00", "2011-01-01 10:00"], tz="US/Eastern", name="xxx", ) exp = Series([3, 2, 1], index=exp_idx, name="count") ser = Series(values, name="xxx") tm.assert_series_equal(ser.value_counts(), exp) idx = pd.DatetimeIndex(values, name="xxx") tm.assert_series_equal(idx.value_counts(), exp) exp = Series(np.array([3.0, 2.0, 1]) / 6.0, index=exp_idx, name="proportion") tm.assert_series_equal(ser.value_counts(normalize=True), exp) tm.assert_series_equal(idx.value_counts(normalize=True), exp) def test_value_counts_period(self): values = [ pd.Period("2011-01", freq="M"), pd.Period("2011-02", freq="M"), pd.Period("2011-03", freq="M"), pd.Period("2011-01", freq="M"), pd.Period("2011-01", freq="M"), pd.Period("2011-03", freq="M"), ] exp_idx = pd.PeriodIndex( ["2011-01", "2011-03", "2011-02"], freq="M", name="xxx" ) exp = Series([3, 2, 1], index=exp_idx, name="count") ser = Series(values, name="xxx") tm.assert_series_equal(ser.value_counts(), exp) # check DatetimeIndex outputs the same result idx = pd.PeriodIndex(values, name="xxx") tm.assert_series_equal(idx.value_counts(), exp) # normalize exp = Series(np.array([3.0, 2.0, 1]) / 6.0, index=exp_idx, name="proportion") tm.assert_series_equal(ser.value_counts(normalize=True), exp) tm.assert_series_equal(idx.value_counts(normalize=True), exp) def test_value_counts_categorical_ordered(self): # most dtypes are tested in tests/base values = Categorical([1, 2, 3, 1, 1, 3], ordered=True) exp_idx = CategoricalIndex( [1, 3, 2], categories=[1, 2, 3], ordered=True, name="xxx" ) exp = Series([3, 2, 1], index=exp_idx, name="count") ser = Series(values, name="xxx") tm.assert_series_equal(ser.value_counts(), exp) # check CategoricalIndex outputs the same result idx = CategoricalIndex(values, name="xxx") tm.assert_series_equal(idx.value_counts(), exp) # normalize exp = Series(np.array([3.0, 2.0, 1]) / 6.0, index=exp_idx, name="proportion") tm.assert_series_equal(ser.value_counts(normalize=True), exp) tm.assert_series_equal(idx.value_counts(normalize=True), exp) def test_value_counts_categorical_not_ordered(self): values = Categorical([1, 2, 3, 1, 1, 3], ordered=False) exp_idx = CategoricalIndex( [1, 3, 2], categories=[1, 2, 3], ordered=False, name="xxx" ) exp = Series([3, 2, 1], index=exp_idx, name="count") ser = Series(values, name="xxx") tm.assert_series_equal(ser.value_counts(), exp) # check CategoricalIndex outputs the same result idx = CategoricalIndex(values, name="xxx") tm.assert_series_equal(idx.value_counts(), exp) # normalize exp = Series(np.array([3.0, 2.0, 1]) / 6.0, index=exp_idx, name="proportion") tm.assert_series_equal(ser.value_counts(normalize=True), exp) tm.assert_series_equal(idx.value_counts(normalize=True), exp) def test_value_counts_categorical(self): # GH#12835 cats = Categorical(list("abcccb"), categories=list("cabd")) ser = Series(cats, name="xxx") res = ser.value_counts(sort=False) exp_index = CategoricalIndex( list("cabd"), categories=cats.categories, name="xxx" ) exp = Series([3, 1, 2, 0], name="count", index=exp_index) tm.assert_series_equal(res, exp) res = ser.value_counts(sort=True) exp_index = CategoricalIndex( list("cbad"), categories=cats.categories, name="xxx" ) exp = Series([3, 2, 1, 0], name="count", index=exp_index) tm.assert_series_equal(res, exp) # check object dtype handles the Series.name as the same # (tested in tests/base) ser = Series(["a", "b", "c", "c", "c", "b"], name="xxx") res = ser.value_counts() exp = Series([3, 2, 1], name="count", index=Index(["c", "b", "a"], name="xxx")) tm.assert_series_equal(res, exp) def test_value_counts_categorical_with_nan(self): # see GH#9443 # sanity check ser = Series(["a", "b", "a"], dtype="category") exp = Series([2, 1], index=CategoricalIndex(["a", "b"]), name="count") res = ser.value_counts(dropna=True) tm.assert_series_equal(res, exp) res = ser.value_counts(dropna=True) tm.assert_series_equal(res, exp) # same Series via two different constructions --> same behaviour series = [ Series(["a", "b", None, "a", None, None], dtype="category"), Series( Categorical(["a", "b", None, "a", None, None], categories=["a", "b"]) ), ] for ser in series: # None is a NaN value, so we exclude its count here exp = Series([2, 1], index=CategoricalIndex(["a", "b"]), name="count") res = ser.value_counts(dropna=True) tm.assert_series_equal(res, exp) # we don't exclude the count of None and sort by counts exp = Series( [3, 2, 1], index=CategoricalIndex([np.nan, "a", "b"]), name="count" ) res = ser.value_counts(dropna=False) tm.assert_series_equal(res, exp) # When we aren't sorting by counts, and np.nan isn't a # category, it should be last. exp = Series( [2, 1, 3], index=CategoricalIndex(["a", "b", np.nan]), name="count" ) res = ser.value_counts(dropna=False, sort=False) tm.assert_series_equal(res, exp) @pytest.mark.parametrize( "ser, dropna, exp", [ ( Series([False, True, True, pd.NA]), False, Series([2, 1, 1], index=[True, False, pd.NA], name="count"), ), ( Series([False, True, True, pd.NA]), True, Series([2, 1], index=Index([True, False], dtype=object), name="count"), ), ( Series(range(3), index=[True, False, np.nan]).index, False, Series([1, 1, 1], index=[True, False, np.nan], name="count"), ), ], ) def test_value_counts_bool_with_nan(self, ser, dropna, exp): # GH32146 out = ser.value_counts(dropna=dropna) tm.assert_series_equal(out, exp) @pytest.mark.parametrize( "input_array,expected", [ ( [1 + 1j, 1 + 1j, 1, 3j, 3j, 3j], Series( [3, 2, 1], index=Index([3j, 1 + 1j, 1], dtype=np.complex128), name="count", ), ), ( np.array([1 + 1j, 1 + 1j, 1, 3j, 3j, 3j], dtype=np.complex64), Series( [3, 2, 1], index=Index([3j, 1 + 1j, 1], dtype=np.complex64), name="count", ), ), ], ) def test_value_counts_complex_numbers(self, input_array, expected): # GH 17927 result = Series(input_array).value_counts() tm.assert_series_equal(result, expected)