Source code for pyspark.pandas.base

#
# Licensed to the Apache Software Foundation (ASF) under one or more
# contributor license agreements.  See the NOTICE file distributed with
# this work for additional information regarding copyright ownership.
# The ASF licenses this file to You under the Apache License, Version 2.0
# (the "License"); you may not use this file except in compliance with
# the License.  You may obtain a copy of the License at
#
#    http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
#

"""
Base and utility classes for pandas-on-Spark objects.
"""
from abc import ABCMeta, abstractmethod
from functools import wraps, partial
from itertools import chain
from typing import Any, Callable, Optional, Sequence, Tuple, Union, cast, TYPE_CHECKING

import numpy as np
import pandas as pd
from pandas.api.types import is_list_like, CategoricalDtype  # type: ignore[attr-defined]
from pyspark.sql import functions as F, Column, Window
from pyspark.sql.types import LongType, BooleanType, NumericType

from pyspark import pandas as ps  # For running doctests and reference resolution in PyCharm.
from pyspark.pandas._typing import Axis, Dtype, IndexOpsLike, Label, SeriesOrIndex
from pyspark.pandas.config import get_option, option_context
from pyspark.pandas.internal import (
    InternalField,
    InternalFrame,
    NATURAL_ORDER_COLUMN_NAME,
    SPARK_DEFAULT_INDEX_NAME,
)
from pyspark.pandas.spark import functions as SF
from pyspark.pandas.spark.accessors import SparkIndexOpsMethods
from pyspark.pandas.typedef import extension_dtypes
from pyspark.pandas.utils import (
    combine_frames,
    same_anchor,
    scol_for,
    validate_axis,
    ERROR_MESSAGE_CANNOT_COMBINE,
)
from pyspark.pandas.frame import DataFrame

if TYPE_CHECKING:
    from pyspark.sql._typing import ColumnOrName

    from pyspark.pandas.data_type_ops.base import DataTypeOps
    from pyspark.pandas.series import Series


def should_alignment_for_column_op(self: SeriesOrIndex, other: SeriesOrIndex) -> bool:
    from pyspark.pandas.series import Series

    if isinstance(self, Series) and isinstance(other, Series):
        return not same_anchor(self, other)
    else:
        return self._internal.spark_frame is not other._internal.spark_frame


def align_diff_index_ops(
    func: Callable[..., Column], this_index_ops: SeriesOrIndex, *args: Any
) -> SeriesOrIndex:
    """
    Align the `IndexOpsMixin` objects and apply the function.

    Parameters
    ----------
    func : The function to apply
    this_index_ops : IndexOpsMixin
        A base `IndexOpsMixin` object
    args : list of other arguments including other `IndexOpsMixin` objects

    Returns
    -------
    `Index` if all `this_index_ops` and arguments are `Index`; otherwise `Series`
    """
    from pyspark.pandas.indexes import Index
    from pyspark.pandas.series import Series, first_series

    cols = [arg for arg in args if isinstance(arg, IndexOpsMixin)]

    if isinstance(this_index_ops, Series) and all(isinstance(col, Series) for col in cols):
        combined = combine_frames(
            this_index_ops.to_frame(),
            *[cast(Series, col).rename(i) for i, col in enumerate(cols)],
            how="full",
        )

        return column_op(func)(
            combined["this"]._psser_for(combined["this"]._internal.column_labels[0]),
            *[
                combined["that"]._psser_for(label)
                for label in combined["that"]._internal.column_labels
            ],
        ).rename(this_index_ops.name)
    else:
        # This could cause as many counts, reset_index calls, joins for combining
        # as the number of `Index`s in `args`. So far it's fine since we can assume the ops
        # only work between at most two `Index`s. We might need to fix it in the future.

        self_len = len(this_index_ops)
        if any(len(col) != self_len for col in args if isinstance(col, IndexOpsMixin)):
            raise ValueError("operands could not be broadcast together with shapes")

        with option_context("compute.default_index_type", "distributed-sequence"):
            if isinstance(this_index_ops, Index) and all(isinstance(col, Index) for col in cols):
                return Index(
                    column_op(func)(
                        this_index_ops.to_series().reset_index(drop=True),
                        *[
                            arg.to_series().reset_index(drop=True)
                            if isinstance(arg, Index)
                            else arg
                            for arg in args
                        ],
                    ).sort_index(),
                    name=this_index_ops.name,
                )
            elif isinstance(this_index_ops, Series):
                this = cast(DataFrame, this_index_ops.reset_index())
                that = [
                    cast(Series, col.to_series() if isinstance(col, Index) else col)
                    .rename(i)
                    .reset_index(drop=True)
                    for i, col in enumerate(cols)
                ]

                combined = combine_frames(this, *that, how="full").sort_index()
                combined = combined.set_index(
                    combined._internal.column_labels[: this_index_ops._internal.index_level]
                )
                combined.index.names = this_index_ops._internal.index_names

                return column_op(func)(
                    first_series(combined["this"]),
                    *[
                        combined["that"]._psser_for(label)
                        for label in combined["that"]._internal.column_labels
                    ],
                ).rename(this_index_ops.name)
            else:
                this = this_index_ops.to_frame().reset_index(drop=True)

                that_series = next(col for col in cols if isinstance(col, Series))
                that_frame = that_series._psdf[
                    [
                        cast(Series, col.to_series() if isinstance(col, Index) else col).rename(i)
                        for i, col in enumerate(cols)
                    ]
                ]

                combined = combine_frames(this, that_frame.reset_index()).sort_index()

                self_index = (
                    combined["this"].set_index(combined["this"]._internal.column_labels).index
                )

                other = combined["that"].set_index(
                    combined["that"]._internal.column_labels[: that_series._internal.index_level]
                )
                other.index.names = that_series._internal.index_names

                return column_op(func)(
                    self_index,
                    *[
                        other._psser_for(label)
                        for label, col in zip(other._internal.column_labels, cols)
                    ],
                ).rename(that_series.name)


def booleanize_null(scol: Column, f: Callable[..., Column]) -> Column:
    """
    Booleanize Null in Spark Column
    """
    comp_ops = [
        getattr(Column, "__{}__".format(comp_op))
        for comp_op in ["eq", "ne", "lt", "le", "ge", "gt"]
    ]

    if f in comp_ops:
        # if `f` is "!=", fill null with True otherwise False
        filler = f == Column.__ne__
        scol = F.when(scol.isNull(), filler).otherwise(scol)

    return scol


def column_op(f: Callable[..., Column]) -> Callable[..., SeriesOrIndex]:
    """
    A decorator that wraps APIs taking/returning Spark Column so that pandas-on-Spark Series can be
    supported too. If this decorator is used for the `f` function that takes Spark Column and
    returns Spark Column, decorated `f` takes pandas-on-Spark Series as well and returns
    pandas-on-Spark Series.

    :param f: a function that takes Spark Column and returns Spark Column.
    :param self: pandas-on-Spark Series
    :param args: arguments that the function `f` takes.
    """

    @wraps(f)
    def wrapper(self: SeriesOrIndex, *args: Any) -> SeriesOrIndex:
        from pyspark.pandas.indexes.base import Index
        from pyspark.pandas.series import Series

        # It is possible for the function `f` takes other arguments than Spark Column.
        # To cover this case, explicitly check if the argument is pandas-on-Spark Series and
        # extract Spark Column. For other arguments, they are used as are.
        cols = [arg for arg in args if isinstance(arg, (Series, Index))]

        if all(not should_alignment_for_column_op(self, col) for col in cols):
            # Same DataFrame anchors
            scol = f(
                self.spark.column,
                *[arg.spark.column if isinstance(arg, IndexOpsMixin) else arg for arg in args],
            )

            field = InternalField.from_struct_field(
                self._internal.spark_frame.select(scol).schema[0],
                use_extension_dtypes=any(
                    isinstance(col.dtype, extension_dtypes) for col in [self] + cols
                ),
            )

            if not field.is_extension_dtype:
                scol = booleanize_null(scol, f).alias(field.name)

            if isinstance(self, Series) or not any(isinstance(col, Series) for col in cols):
                index_ops = self._with_new_scol(scol, field=field)
            else:
                psser = next(col for col in cols if isinstance(col, Series))
                index_ops = psser._with_new_scol(scol, field=field)
        elif get_option("compute.ops_on_diff_frames"):
            index_ops = align_diff_index_ops(f, self, *args)
        else:
            raise ValueError(ERROR_MESSAGE_CANNOT_COMBINE)

        if not all(self.name == col.name for col in cols):
            index_ops = index_ops.rename(None)

        return index_ops

    return wrapper


def numpy_column_op(f: Callable[..., Column]) -> Callable[..., SeriesOrIndex]:
    @wraps(f)
    def wrapper(self: SeriesOrIndex, *args: Any) -> SeriesOrIndex:
        # PySpark does not support NumPy type out of the box. For now, we convert NumPy types
        # into some primitive types understandable in PySpark.
        new_args = []
        for arg in args:
            # TODO: This is a quick hack to support NumPy type. We should revisit this.
            if isinstance(self.spark.data_type, LongType) and isinstance(arg, np.timedelta64):
                new_args.append(float(arg / np.timedelta64(1, "s")))
            else:
                new_args.append(arg)
        return column_op(f)(self, *new_args)

    return wrapper


class IndexOpsMixin(object, metaclass=ABCMeta):
    """common ops mixin to support a unified interface / docs for Series / Index

    Assuming there are following attributes or properties and function.
    """

    @property
    @abstractmethod
    def _internal(self) -> InternalFrame:
        pass

    @property
    @abstractmethod
    def _psdf(self) -> DataFrame:
        pass

    @abstractmethod
    def _with_new_scol(
        self: IndexOpsLike, scol: Column, *, field: Optional[InternalField] = None
    ) -> IndexOpsLike:
        pass

    @property
    @abstractmethod
    def _column_label(self) -> Optional[Label]:
        pass

    @property
    @abstractmethod
    def spark(self: IndexOpsLike) -> SparkIndexOpsMethods[IndexOpsLike]:
        pass

    @property
    def _dtype_op(self) -> "DataTypeOps":
        from pyspark.pandas.data_type_ops.base import DataTypeOps

        return DataTypeOps(self.dtype, self.spark.data_type)

    @abstractmethod
    def copy(self: IndexOpsLike) -> IndexOpsLike:
        pass

    # arithmetic operators
    def __neg__(self: IndexOpsLike) -> IndexOpsLike:
        return self._dtype_op.neg(self)

    def __add__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.add(self, other)

    def __sub__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.sub(self, other)

    def __mul__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.mul(self, other)

    def __truediv__(self, other: Any) -> SeriesOrIndex:
        """
        __truediv__ has different behaviour between pandas and PySpark for several cases.
        1. When divide np.inf by zero, PySpark returns null whereas pandas returns np.inf
        2. When divide positive number by zero, PySpark returns null whereas pandas returns np.inf
        3. When divide -np.inf by zero, PySpark returns null whereas pandas returns -np.inf
        4. When divide negative number by zero, PySpark returns null whereas pandas returns -np.inf

        +-------------------------------------------+
        | dividend (divisor: 0) | PySpark |  pandas |
        |-----------------------|---------|---------|
        |         np.inf        |   null  |  np.inf |
        |        -np.inf        |   null  | -np.inf |
        |           10          |   null  |  np.inf |
        |          -10          |   null  | -np.inf |
        +-----------------------|---------|---------+
        """
        return self._dtype_op.truediv(self, other)

    def __mod__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.mod(self, other)

    def __radd__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.radd(self, other)

    def __rsub__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.rsub(self, other)

    def __rmul__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.rmul(self, other)

    def __rtruediv__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.rtruediv(self, other)

    def __floordiv__(self, other: Any) -> SeriesOrIndex:
        """
        __floordiv__ has different behaviour between pandas and PySpark for several cases.
        1. When divide np.inf by zero, PySpark returns null whereas pandas returns np.inf
        2. When divide positive number by zero, PySpark returns null whereas pandas returns np.inf
        3. When divide -np.inf by zero, PySpark returns null whereas pandas returns -np.inf
        4. When divide negative number by zero, PySpark returns null whereas pandas returns -np.inf

        +-------------------------------------------+
        | dividend (divisor: 0) | PySpark |  pandas |
        |-----------------------|---------|---------|
        |         np.inf        |   null  |  np.inf |
        |        -np.inf        |   null  | -np.inf |
        |           10          |   null  |  np.inf |
        |          -10          |   null  | -np.inf |
        +-----------------------|---------|---------+
        """
        return self._dtype_op.floordiv(self, other)

    def __rfloordiv__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.rfloordiv(self, other)

    def __rmod__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.rmod(self, other)

    def __pow__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.pow(self, other)

    def __rpow__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.rpow(self, other)

    def __abs__(self: IndexOpsLike) -> IndexOpsLike:
        return self._dtype_op.abs(self)

    # comparison operators
    def __eq__(self, other: Any) -> SeriesOrIndex:  # type: ignore[override]
        # pandas always returns False for all items with dict and set.
        if isinstance(other, (dict, set)):
            return self != self
        else:
            return self._dtype_op.eq(self, other)

    def __ne__(self, other: Any) -> SeriesOrIndex:  # type: ignore[override]
        return self._dtype_op.ne(self, other)

    def __lt__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.lt(self, other)

    def __le__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.le(self, other)

    def __ge__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.ge(self, other)

    def __gt__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.gt(self, other)

    def __invert__(self: IndexOpsLike) -> IndexOpsLike:
        return self._dtype_op.invert(self)

    # `and`, `or`, `not` cannot be overloaded in Python,
    # so use bitwise operators as boolean operators
    def __and__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.__and__(self, other)

    def __or__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.__or__(self, other)

    def __rand__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.rand(self, other)

    def __ror__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.ror(self, other)

    def __xor__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.xor(self, other)

    def __rxor__(self, other: Any) -> SeriesOrIndex:
        return self._dtype_op.rxor(self, other)

    def __len__(self) -> int:
        return len(self._psdf)

    # NDArray Compat
    def __array_ufunc__(
        self, ufunc: Callable, method: str, *inputs: Any, **kwargs: Any
    ) -> SeriesOrIndex:
        from pyspark.pandas import numpy_compat

        # Try dunder methods first.
        result = numpy_compat.maybe_dispatch_ufunc_to_dunder_op(
            self, ufunc, method, *inputs, **kwargs
        )

        # After that, we try with PySpark APIs.
        if result is NotImplemented:
            result = numpy_compat.maybe_dispatch_ufunc_to_spark_func(
                self, ufunc, method, *inputs, **kwargs
            )

        if result is not NotImplemented:
            return cast(SeriesOrIndex, result)
        else:
            # TODO: support more APIs?
            raise NotImplementedError(
                "pandas-on-Spark objects currently do not support %s." % ufunc
            )

    @property
    def dtype(self) -> Dtype:
        """Return the dtype object of the underlying data.

        Examples
        --------
        >>> s = ps.Series([1, 2, 3])
        >>> s.dtype
        dtype('int64')

        >>> s = ps.Series(list('abc'))
        >>> s.dtype
        dtype('O')

        >>> s = ps.Series(pd.date_range('20130101', periods=3))
        >>> s.dtype
        dtype('<M8[ns]')

        >>> s.rename("a").to_frame().set_index("a").index.dtype
        dtype('<M8[ns]')
        """
        return self._internal.data_fields[0].dtype

    @property
    def empty(self) -> bool:
        """
        Returns true if the current object is empty. Otherwise, returns false.

        >>> ps.range(10).id.empty
        False

        >>> ps.range(0).id.empty
        True

        >>> ps.DataFrame({}, index=list('abc')).index.empty
        False
        """
        return self._internal.resolved_copy.spark_frame.rdd.isEmpty()

    @property
    def hasnans(self) -> bool:
        """
        Return True if it has any missing values. Otherwise, it returns False.

        >>> ps.DataFrame({}, index=list('abc')).index.hasnans
        False

        >>> ps.Series(['a', None]).hasnans
        True

        >>> ps.Series([1.0, 2.0, np.nan]).hasnans
        True

        >>> ps.Series([1, 2, 3]).hasnans
        False

        >>> (ps.Series([1.0, 2.0, np.nan]) + 1).hasnans
        True

        >>> ps.Series([1, 2, 3]).rename("a").to_frame().set_index("a").index.hasnans
        False
        """
        return self.isnull().any()

    @property
    def is_monotonic(self) -> bool:
        """
        Return boolean if values in the object are monotonically increasing.

        .. note:: the current implementation of is_monotonic requires to shuffle
            and aggregate multiple times to check the order locally and globally,
            which is potentially expensive. In case of multi-index, all data are
            transferred to single node which can easily cause out-of-memory error currently.

        .. note:: Disable the Spark config `spark.sql.optimizer.nestedSchemaPruning.enabled`
            for multi-index if you're using pandas-on-Spark < 1.7.0 with PySpark 3.1.1.

        Returns
        -------
        is_monotonic : bool

        Examples
        --------
        >>> ser = ps.Series(['1/1/2018', '3/1/2018', '4/1/2018'])
        >>> ser.is_monotonic
        True

        >>> df = ps.DataFrame({'dates': [None, '1/1/2018', '2/1/2018', '3/1/2018']})
        >>> df.dates.is_monotonic
        False

        >>> df.index.is_monotonic
        True

        >>> ser = ps.Series([1])
        >>> ser.is_monotonic
        True

        >>> ser = ps.Series([])
        >>> ser.is_monotonic
        True

        >>> ser.rename("a").to_frame().set_index("a").index.is_monotonic
        True

        >>> ser = ps.Series([5, 4, 3, 2, 1], index=[1, 2, 3, 4, 5])
        >>> ser.is_monotonic
        False

        >>> ser.index.is_monotonic
        True

        Support for MultiIndex

        >>> midx = ps.MultiIndex.from_tuples(
        ... [('x', 'a'), ('x', 'b'), ('y', 'c'), ('y', 'd'), ('z', 'e')])
        >>> midx  # doctest: +SKIP
        MultiIndex([('x', 'a'),
                    ('x', 'b'),
                    ('y', 'c'),
                    ('y', 'd'),
                    ('z', 'e')],
                   )
        >>> midx.is_monotonic
        True

        >>> midx = ps.MultiIndex.from_tuples(
        ... [('z', 'a'), ('z', 'b'), ('y', 'c'), ('y', 'd'), ('x', 'e')])
        >>> midx  # doctest: +SKIP
        MultiIndex([('z', 'a'),
                    ('z', 'b'),
                    ('y', 'c'),
                    ('y', 'd'),
                    ('x', 'e')],
                   )
        >>> midx.is_monotonic
        False
        """
        return self._is_monotonic("increasing")

    is_monotonic_increasing = is_monotonic

    @property
    def is_monotonic_decreasing(self) -> bool:
        """
        Return boolean if values in the object are monotonically decreasing.

        .. note:: the current implementation of is_monotonic_decreasing requires to shuffle
            and aggregate multiple times to check the order locally and globally,
            which is potentially expensive. In case of multi-index, all data are transferred
            to single node which can easily cause out-of-memory error currently.

        .. note:: Disable the Spark config `spark.sql.optimizer.nestedSchemaPruning.enabled`
            for multi-index if you're using pandas-on-Spark < 1.7.0 with PySpark 3.1.1.

        Returns
        -------
        is_monotonic : bool

        Examples
        --------
        >>> ser = ps.Series(['4/1/2018', '3/1/2018', '1/1/2018'])
        >>> ser.is_monotonic_decreasing
        True

        >>> df = ps.DataFrame({'dates': [None, '3/1/2018', '2/1/2018', '1/1/2018']})
        >>> df.dates.is_monotonic_decreasing
        False

        >>> df.index.is_monotonic_decreasing
        False

        >>> ser = ps.Series([1])
        >>> ser.is_monotonic_decreasing
        True

        >>> ser = ps.Series([])
        >>> ser.is_monotonic_decreasing
        True

        >>> ser.rename("a").to_frame().set_index("a").index.is_monotonic_decreasing
        True

        >>> ser = ps.Series([5, 4, 3, 2, 1], index=[1, 2, 3, 4, 5])
        >>> ser.is_monotonic_decreasing
        True

        >>> ser.index.is_monotonic_decreasing
        False

        Support for MultiIndex

        >>> midx = ps.MultiIndex.from_tuples(
        ... [('x', 'a'), ('x', 'b'), ('y', 'c'), ('y', 'd'), ('z', 'e')])
        >>> midx  # doctest: +SKIP
        MultiIndex([('x', 'a'),
                    ('x', 'b'),
                    ('y', 'c'),
                    ('y', 'd'),
                    ('z', 'e')],
                   )
        >>> midx.is_monotonic_decreasing
        False

        >>> midx = ps.MultiIndex.from_tuples(
        ... [('z', 'e'), ('z', 'd'), ('y', 'c'), ('y', 'b'), ('x', 'a')])
        >>> midx  # doctest: +SKIP
        MultiIndex([('z', 'a'),
                    ('z', 'b'),
                    ('y', 'c'),
                    ('y', 'd'),
                    ('x', 'e')],
                   )
        >>> midx.is_monotonic_decreasing
        True
        """
        return self._is_monotonic("decreasing")

    def _is_locally_monotonic_spark_column(self, order: str) -> Column:
        window = (
            Window.partitionBy(F.col("__partition_id"))
            .orderBy(NATURAL_ORDER_COLUMN_NAME)
            .rowsBetween(-1, -1)
        )

        if order == "increasing":
            return (F.col("__origin") >= F.lag(F.col("__origin"), 1).over(window)) & F.col(
                "__origin"
            ).isNotNull()
        else:
            return (F.col("__origin") <= F.lag(F.col("__origin"), 1).over(window)) & F.col(
                "__origin"
            ).isNotNull()

    def _is_monotonic(self, order: str) -> bool:
        assert order in ("increasing", "decreasing")

        sdf = self._internal.spark_frame

        sdf = (
            sdf.select(
                F.spark_partition_id().alias(
                    "__partition_id"
                ),  # Make sure we use the same partition id in the whole job.
                F.col(NATURAL_ORDER_COLUMN_NAME),
                self.spark.column.alias("__origin"),
            )
            .select(
                F.col("__partition_id"),
                F.col("__origin"),
                self._is_locally_monotonic_spark_column(order).alias(
                    "__comparison_within_partition"
                ),
            )
            .groupby(F.col("__partition_id"))
            .agg(
                F.min(F.col("__origin")).alias("__partition_min"),
                F.max(F.col("__origin")).alias("__partition_max"),
                F.min(F.coalesce(F.col("__comparison_within_partition"), SF.lit(True))).alias(
                    "__comparison_within_partition"
                ),
            )
        )

        # Now we're windowing the aggregation results without partition specification.
        # The number of rows here will be as the same of partitions, which is expected
        # to be small.
        window = Window.orderBy(F.col("__partition_id")).rowsBetween(-1, -1)
        if order == "increasing":
            comparison_col = F.col("__partition_min") >= F.lag(F.col("__partition_max"), 1).over(
                window
            )
        else:
            comparison_col = F.col("__partition_min") <= F.lag(F.col("__partition_max"), 1).over(
                window
            )

        sdf = sdf.select(
            comparison_col.alias("__comparison_between_partitions"),
            F.col("__comparison_within_partition"),
        )

        ret = sdf.select(
            F.min(F.coalesce(F.col("__comparison_between_partitions"), SF.lit(True)))
            & F.min(F.coalesce(F.col("__comparison_within_partition"), SF.lit(True)))
        ).collect()[0][0]
        if ret is None:
            return True
        else:
            return ret

    @property
    def ndim(self) -> int:
        """
        Return an int representing the number of array dimensions.

        Return 1 for Series / Index / MultiIndex.

        Examples
        --------

        For Series

        >>> s = ps.Series([None, 1, 2, 3, 4], index=[4, 5, 2, 1, 8])
        >>> s.ndim
        1

        For Index

        >>> s.index.ndim
        1

        For MultiIndex

        >>> midx = pd.MultiIndex([['lama', 'cow', 'falcon'],
        ...                       ['speed', 'weight', 'length']],
        ...                      [[0, 0, 0, 1, 1, 1, 2, 2, 2],
        ...                       [1, 1, 1, 1, 1, 2, 1, 2, 2]])
        >>> s = ps.Series([45, 200, 1.2, 30, 250, 1.5, 320, 1, 0.3], index=midx)
        >>> s.index.ndim
        1
        """
        return 1

    def astype(self: IndexOpsLike, dtype: Union[str, type, Dtype]) -> IndexOpsLike:
        """
        Cast a pandas-on-Spark object to a specified dtype ``dtype``.

        Parameters
        ----------
        dtype : data type
            Use a numpy.dtype or Python type to cast entire pandas object to
            the same type.

        Returns
        -------
        casted : same type as caller

        See Also
        --------
        to_datetime : Convert argument to datetime.

        Examples
        --------
        >>> ser = ps.Series([1, 2], dtype='int32')
        >>> ser
        0    1
        1    2
        dtype: int32

        >>> ser.astype('int64')
        0    1
        1    2
        dtype: int64

        >>> ser.rename("a").to_frame().set_index("a").index.astype('int64')
        Int64Index([1, 2], dtype='int64', name='a')
        """
        return self._dtype_op.astype(self, dtype)

    def isin(self: IndexOpsLike, values: Sequence[Any]) -> IndexOpsLike:
        """
        Check whether `values` are contained in Series or Index.

        Return a boolean Series or Index showing whether each element in the Series
        matches an element in the passed sequence of `values` exactly.

        Parameters
        ----------
        values : set or list-like
            The sequence of values to test.

        Returns
        -------
        isin : Series (bool dtype) or Index (bool dtype)

        Examples
        --------
        >>> s = ps.Series(['lama', 'cow', 'lama', 'beetle', 'lama',
        ...                'hippo'], name='animal')
        >>> s.isin(['cow', 'lama'])
        0     True
        1     True
        2     True
        3    False
        4     True
        5    False
        Name: animal, dtype: bool

        Passing a single string as ``s.isin('lama')`` will raise an error. Use
        a list of one element instead:

        >>> s.isin(['lama'])
        0     True
        1    False
        2     True
        3    False
        4     True
        5    False
        Name: animal, dtype: bool

        >>> s.rename("a").to_frame().set_index("a").index.isin(['lama'])
        Index([True, False, True, False, True, False], dtype='object', name='a')
        """
        if not is_list_like(values):
            raise TypeError(
                "only list-like objects are allowed to be passed"
                " to isin(), you passed a [{values_type}]".format(values_type=type(values).__name__)
            )

        values = (
            cast(np.ndarray, values).tolist() if isinstance(values, np.ndarray) else list(values)
        )

        other = [SF.lit(v) for v in values]
        scol = self.spark.column.isin(other)
        field = self._internal.data_fields[0].copy(
            dtype=np.dtype("bool"), spark_type=BooleanType(), nullable=False
        )
        return self._with_new_scol(scol=F.coalesce(scol, F.lit(False)), field=field)

    def isnull(self: IndexOpsLike) -> IndexOpsLike:
        """
        Detect existing (non-missing) values.

        Return a boolean same-sized object indicating if the values are NA.
        NA values, such as None or numpy.NaN, gets mapped to True values.
        Everything else gets mapped to False values. Characters such as empty strings '' or
        numpy.inf are not considered NA values
        (unless you set pandas.options.mode.use_inf_as_na = True).

        Returns
        -------
        Series or Index : Mask of bool values for each element in Series
            that indicates whether an element is not an NA value.

        Examples
        --------
        >>> ser = ps.Series([5, 6, np.NaN])
        >>> ser.isna()  # doctest: +NORMALIZE_WHITESPACE
        0    False
        1    False
        2     True
        dtype: bool

        >>> ser.rename("a").to_frame().set_index("a").index.isna()
        Index([False, False, True], dtype='object', name='a')
        """
        from pyspark.pandas.indexes import MultiIndex

        if isinstance(self, MultiIndex):
            raise NotImplementedError("isna is not defined for MultiIndex")

        return self._dtype_op.isnull(self)

    isna = isnull

    def notnull(self: IndexOpsLike) -> IndexOpsLike:
        """
        Detect existing (non-missing) values.
        Return a boolean same-sized object indicating if the values are not NA.
        Non-missing values get mapped to True.
        Characters such as empty strings '' or numpy.inf are not considered NA values
        (unless you set pandas.options.mode.use_inf_as_na = True).
        NA values, such as None or numpy.NaN, get mapped to False values.

        Returns
        -------
        Series or Index : Mask of bool values for each element in Series
            that indicates whether an element is not an NA value.

        Examples
        --------
        Show which entries in a Series are not NA.

        >>> ser = ps.Series([5, 6, np.NaN])
        >>> ser
        0    5.0
        1    6.0
        2    NaN
        dtype: float64

        >>> ser.notna()
        0     True
        1     True
        2    False
        dtype: bool

        >>> ser.rename("a").to_frame().set_index("a").index.notna()
        Index([True, True, False], dtype='object', name='a')
        """
        from pyspark.pandas.indexes import MultiIndex

        if isinstance(self, MultiIndex):
            raise NotImplementedError("notna is not defined for MultiIndex")
        return (~self.isnull()).rename(self.name)  # type: ignore[attr-defined]

    notna = notnull

    # TODO: axis and many arguments should be implemented.
    def all(self, axis: Axis = 0, skipna: bool = True) -> bool:
        """
        Return whether all elements are True.

        Returns True unless there at least one element within a series that is
        False or equivalent (e.g. zero or empty)

        Parameters
        ----------
        axis : {0 or 'index'}, default 0
            Indicate which axis or axes should be reduced.

            * 0 / 'index' : reduce the index, return a Series whose index is the
              original column labels.

        skipna : boolean, default True
            Exclude NA/null values. If an entire row/column is NA and skipna is True,
            then the result will be True, as for an empty row/column.
            If skipna is False, then NA are treated as True, because these are not equal to zero.

        Examples
        --------
        >>> ps.Series([True, True]).all()
        True

        >>> ps.Series([True, False]).all()
        False

        >>> ps.Series([0, 1]).all()
        False

        >>> ps.Series([1, 2, 3]).all()
        True

        >>> ps.Series([True, True, None]).all()
        True

        >>> ps.Series([True, True, None]).all(skipna=False)
        False

        >>> ps.Series([True, False, None]).all()
        False

        >>> ps.Series([]).all()
        True

        >>> ps.Series([np.nan]).all()
        True

        >>> ps.Series([np.nan]).all(skipna=False)
        True

        >>> ps.Series([None]).all()
        True

        >>> ps.Series([None]).all(skipna=False)
        False

        >>> df = ps.Series([True, False, None]).rename("a").to_frame()
        >>> df.set_index("a").index.all()
        False
        """
        axis = validate_axis(axis)
        if axis != 0:
            raise NotImplementedError('axis should be either 0 or "index" currently.')

        sdf = self._internal.spark_frame.select(self.spark.column)
        col = scol_for(sdf, sdf.columns[0])

        # `any` and `every` was added as of Spark 3.0.
        # ret = sdf.select(F.expr("every(CAST(`%s` AS BOOLEAN))" % sdf.columns[0])).collect()[0][0]
        # We use min as its alternative as below.
        if isinstance(self.spark.data_type, NumericType) or skipna:
            # np.nan takes no effect to the result; None takes no effect if `skipna`
            ret = sdf.select(F.min(F.coalesce(col.cast("boolean"), SF.lit(True)))).collect()[0][0]
        else:
            # Take None as False when not `skipna`
            ret = sdf.select(
                F.min(F.when(col.isNull(), SF.lit(False)).otherwise(col.cast("boolean")))
            ).collect()[0][0]

        if ret is None:
            return True
        else:
            return ret

    # TODO: axis, skipna, and many arguments should be implemented.
    def any(self, axis: Axis = 0) -> bool:
        """
        Return whether any element is True.

        Returns False unless there at least one element within a series that is
        True or equivalent (e.g. non-zero or non-empty).

        Parameters
        ----------
        axis : {0 or 'index'}, default 0
            Indicate which axis or axes should be reduced.

            * 0 / 'index' : reduce the index, return a Series whose index is the
              original column labels.

        Examples
        --------
        >>> ps.Series([False, False]).any()
        False

        >>> ps.Series([True, False]).any()
        True

        >>> ps.Series([0, 0]).any()
        False

        >>> ps.Series([0, 1, 2]).any()
        True

        >>> ps.Series([False, False, None]).any()
        False

        >>> ps.Series([True, False, None]).any()
        True

        >>> ps.Series([]).any()
        False

        >>> ps.Series([np.nan]).any()
        False

        >>> df = ps.Series([True, False, None]).rename("a").to_frame()
        >>> df.set_index("a").index.any()
        True
        """
        axis = validate_axis(axis)
        if axis != 0:
            raise NotImplementedError('axis should be either 0 or "index" currently.')

        sdf = self._internal.spark_frame.select(self.spark.column)
        col = scol_for(sdf, sdf.columns[0])

        # Note that we're ignoring `None`s here for now.
        # any and every was added as of Spark 3.0
        # ret = sdf.select(F.expr("any(CAST(`%s` AS BOOLEAN))" % sdf.columns[0])).collect()[0][0]
        # Here we use max as its alternative:
        ret = sdf.select(F.max(F.coalesce(col.cast("boolean"), SF.lit(False)))).collect()[0][0]
        if ret is None:
            return False
        else:
            return ret

    # TODO: add frep and axis parameter
    def shift(
        self: IndexOpsLike, periods: int = 1, fill_value: Optional[Any] = None
    ) -> IndexOpsLike:
        """
        Shift Series/Index by desired number of periods.

        .. note:: the current implementation of shift uses Spark's Window without
            specifying partition specification. This leads to move all data into
            single partition in single machine and could cause serious
            performance degradation. Avoid this method against very large dataset.

        Parameters
        ----------
        periods : int
            Number of periods to shift. Can be positive or negative.
        fill_value : object, optional
            The scalar value to use for newly introduced missing values.
            The default depends on the dtype of self. For numeric data, np.nan is used.

        Returns
        -------
        Copy of input Series/Index, shifted.

        Examples
        --------
        >>> df = ps.DataFrame({'Col1': [10, 20, 15, 30, 45],
        ...                    'Col2': [13, 23, 18, 33, 48],
        ...                    'Col3': [17, 27, 22, 37, 52]},
        ...                   columns=['Col1', 'Col2', 'Col3'])

        >>> df.Col1.shift(periods=3)
        0     NaN
        1     NaN
        2     NaN
        3    10.0
        4    20.0
        Name: Col1, dtype: float64

        >>> df.Col2.shift(periods=3, fill_value=0)
        0     0
        1     0
        2     0
        3    13
        4    23
        Name: Col2, dtype: int64

        >>> df.index.shift(periods=3, fill_value=0)
        Int64Index([0, 0, 0, 0, 1], dtype='int64')
        """
        return self._shift(periods, fill_value).spark.analyzed

    def _shift(
        self: IndexOpsLike,
        periods: int,
        fill_value: Any,
        *,
        part_cols: Sequence["ColumnOrName"] = (),
    ) -> IndexOpsLike:
        if not isinstance(periods, int):
            raise TypeError("periods should be an int; however, got [%s]" % type(periods).__name__)

        col = self.spark.column
        window = (
            Window.partitionBy(*part_cols)
            .orderBy(NATURAL_ORDER_COLUMN_NAME)
            .rowsBetween(-periods, -periods)
        )
        lag_col = F.lag(col, periods).over(window)
        col = F.when(lag_col.isNull() | F.isnan(lag_col), fill_value).otherwise(lag_col)
        return self._with_new_scol(col, field=self._internal.data_fields[0].copy(nullable=True))

    # TODO: Update Documentation for Bins Parameter when its supported
    def value_counts(
        self,
        normalize: bool = False,
        sort: bool = True,
        ascending: bool = False,
        bins: None = None,
        dropna: bool = True,
    ) -> "Series":
        """
        Return a Series containing counts of unique values.
        The resulting object will be in descending order so that the
        first element is the most frequently-occurring element.
        Excludes NA values by default.

        Parameters
        ----------
        normalize : boolean, default False
            If True then the object returned will contain the relative
            frequencies of the unique values.
        sort : boolean, default True
            Sort by values.
        ascending : boolean, default False
            Sort in ascending order.
        bins : Not Yet Supported
        dropna : boolean, default True
            Don't include counts of NaN.

        Returns
        -------
        counts : Series

        See Also
        --------
        Series.count: Number of non-NA elements in a Series.

        Examples
        --------
        For Series

        >>> df = ps.DataFrame({'x':[0, 0, 1, 1, 1, np.nan]})
        >>> df.x.value_counts()  # doctest: +NORMALIZE_WHITESPACE
        1.0    3
        0.0    2
        Name: x, dtype: int64

        With `normalize` set to `True`, returns the relative frequency by
        dividing all values by the sum of values.

        >>> df.x.value_counts(normalize=True)  # doctest: +NORMALIZE_WHITESPACE
        1.0    0.6
        0.0    0.4
        Name: x, dtype: float64

        **dropna**
        With `dropna` set to `False` we can also see NaN index values.

        >>> df.x.value_counts(dropna=False)  # doctest: +NORMALIZE_WHITESPACE
        1.0    3
        0.0    2
        NaN    1
        Name: x, dtype: int64

        For Index

        >>> idx = ps.Index([3, 1, 2, 3, 4, np.nan])
        >>> idx
        Float64Index([3.0, 1.0, 2.0, 3.0, 4.0, nan], dtype='float64')

        >>> idx.value_counts().sort_index()
        1.0    1
        2.0    1
        3.0    2
        4.0    1
        dtype: int64

        **sort**

        With `sort` set to `False`, the result wouldn't be sorted by number of count.

        >>> idx.value_counts(sort=True).sort_index()
        1.0    1
        2.0    1
        3.0    2
        4.0    1
        dtype: int64

        **normalize**

        With `normalize` set to `True`, returns the relative frequency by
        dividing all values by the sum of values.

        >>> idx.value_counts(normalize=True).sort_index()
        1.0    0.2
        2.0    0.2
        3.0    0.4
        4.0    0.2
        dtype: float64

        **dropna**

        With `dropna` set to `False` we can also see NaN index values.

        >>> idx.value_counts(dropna=False).sort_index()  # doctest: +SKIP
        1.0    1
        2.0    1
        3.0    2
        4.0    1
        NaN    1
        dtype: int64

        For MultiIndex.

        >>> midx = pd.MultiIndex([['lama', 'cow', 'falcon'],
        ...                       ['speed', 'weight', 'length']],
        ...                      [[0, 0, 0, 1, 1, 1, 2, 2, 2],
        ...                       [1, 1, 1, 1, 1, 2, 1, 2, 2]])
        >>> s = ps.Series([45, 200, 1.2, 30, 250, 1.5, 320, 1, 0.3], index=midx)
        >>> s.index  # doctest: +SKIP
        MultiIndex([(  'lama', 'weight'),
                    (  'lama', 'weight'),
                    (  'lama', 'weight'),
                    (   'cow', 'weight'),
                    (   'cow', 'weight'),
                    (   'cow', 'length'),
                    ('falcon', 'weight'),
                    ('falcon', 'length'),
                    ('falcon', 'length')],
                   )

        >>> s.index.value_counts().sort_index()
        (cow, length)       1
        (cow, weight)       2
        (falcon, length)    2
        (falcon, weight)    1
        (lama, weight)      3
        dtype: int64

        >>> s.index.value_counts(normalize=True).sort_index()
        (cow, length)       0.111111
        (cow, weight)       0.222222
        (falcon, length)    0.222222
        (falcon, weight)    0.111111
        (lama, weight)      0.333333
        dtype: float64

        If Index has name, keep the name up.

        >>> idx = ps.Index([0, 0, 0, 1, 1, 2, 3], name='pandas-on-Spark')
        >>> idx.value_counts().sort_index()
        0    3
        1    2
        2    1
        3    1
        Name: pandas-on-Spark, dtype: int64
        """
        from pyspark.pandas.series import first_series

        if bins is not None:
            raise NotImplementedError("value_counts currently does not support bins")

        if dropna:
            sdf_dropna = self._internal.spark_frame.select(self.spark.column).dropna()
        else:
            sdf_dropna = self._internal.spark_frame.select(self.spark.column)
        index_name = SPARK_DEFAULT_INDEX_NAME
        column_name = self._internal.data_spark_column_names[0]
        sdf = sdf_dropna.groupby(scol_for(sdf_dropna, column_name).alias(index_name)).count()
        if sort:
            if ascending:
                sdf = sdf.orderBy(F.col("count"))
            else:
                sdf = sdf.orderBy(F.col("count").desc())

        if normalize:
            drop_sum = sdf_dropna.count()
            sdf = sdf.withColumn("count", F.col("count") / SF.lit(drop_sum))

        internal = InternalFrame(
            spark_frame=sdf,
            index_spark_columns=[scol_for(sdf, index_name)],
            column_labels=self._internal.column_labels,
            data_spark_columns=[scol_for(sdf, "count")],
            column_label_names=self._internal.column_label_names,
        )

        return first_series(DataFrame(internal))

    def nunique(self, dropna: bool = True, approx: bool = False, rsd: float = 0.05) -> int:
        """
        Return number of unique elements in the object.
        Excludes NA values by default.

        Parameters
        ----------
        dropna : bool, default True
            Don’t include NaN in the count.
        approx: bool, default False
            If False, will use the exact algorithm and return the exact number of unique.
            If True, it uses the HyperLogLog approximate algorithm, which is significantly faster
            for large amount of data.
            Note: This parameter is specific to pandas-on-Spark and is not found in pandas.
        rsd: float, default 0.05
            Maximum estimation error allowed in the HyperLogLog algorithm.
            Note: Just like ``approx`` this parameter is specific to pandas-on-Spark.

        Returns
        -------
        int

        See Also
        --------
        DataFrame.nunique: Method nunique for DataFrame.
        Series.count: Count non-NA/null observations in the Series.

        Examples
        --------
        >>> ps.Series([1, 2, 3, np.nan]).nunique()
        3

        >>> ps.Series([1, 2, 3, np.nan]).nunique(dropna=False)
        4

        On big data, we recommend using the approximate algorithm to speed up this function.
        The result will be very close to the exact unique count.

        >>> ps.Series([1, 2, 3, np.nan]).nunique(approx=True)
        3

        >>> idx = ps.Index([1, 1, 2, None])
        >>> idx
        Float64Index([1.0, 1.0, 2.0, nan], dtype='float64')

        >>> idx.nunique()
        2

        >>> idx.nunique(dropna=False)
        3
        """
        res = self._internal.spark_frame.select([self._nunique(dropna, approx, rsd)])
        return res.collect()[0][0]

    def _nunique(self, dropna: bool = True, approx: bool = False, rsd: float = 0.05) -> Column:
        colname = self._internal.data_spark_column_names[0]
        count_fn = cast(
            Callable[[Column], Column],
            partial(F.approx_count_distinct, rsd=rsd) if approx else F.countDistinct,
        )
        if dropna:
            return count_fn(self.spark.column).alias(colname)
        else:
            return (
                count_fn(self.spark.column)
                + F.when(
                    F.count(F.when(self.spark.column.isNull(), 1).otherwise(None)) >= 1, 1
                ).otherwise(0)
            ).alias(colname)

    def take(self: IndexOpsLike, indices: Sequence[int]) -> IndexOpsLike:
        """
        Return the elements in the given *positional* indices along an axis.

        This means that we are not indexing according to actual values in
        the index attribute of the object. We are indexing according to the
        actual position of the element in the object.

        Parameters
        ----------
        indices : array-like
            An array of ints indicating which positions to take.

        Returns
        -------
        taken : same type as caller
            An array-like containing the elements taken from the object.

        See Also
        --------
        DataFrame.loc : Select a subset of a DataFrame by labels.
        DataFrame.iloc : Select a subset of a DataFrame by positions.
        numpy.take : Take elements from an array along an axis.

        Examples
        --------

        Series

        >>> psser = ps.Series([100, 200, 300, 400, 500])
        >>> psser
        0    100
        1    200
        2    300
        3    400
        4    500
        dtype: int64

        >>> psser.take([0, 2, 4]).sort_index()
        0    100
        2    300
        4    500
        dtype: int64

        Index

        >>> psidx = ps.Index([100, 200, 300, 400, 500])
        >>> psidx
        Int64Index([100, 200, 300, 400, 500], dtype='int64')

        >>> psidx.take([0, 2, 4]).sort_values()
        Int64Index([100, 300, 500], dtype='int64')

        MultiIndex

        >>> psmidx = ps.MultiIndex.from_tuples([("x", "a"), ("x", "b"), ("x", "c")])
        >>> psmidx  # doctest: +SKIP
        MultiIndex([('x', 'a'),
                    ('x', 'b'),
                    ('x', 'c')],
                   )

        >>> psmidx.take([0, 2])  # doctest: +SKIP
        MultiIndex([('x', 'a'),
                    ('x', 'c')],
                   )
        """
        if not is_list_like(indices) or isinstance(indices, (dict, set)):
            raise TypeError("`indices` must be a list-like except dict or set")
        if isinstance(self, ps.Series):
            return cast(IndexOpsLike, self.iloc[indices])
        else:
            return cast(IndexOpsLike, self._psdf.iloc[indices].index)

    def factorize(
        self: IndexOpsLike, sort: bool = True, na_sentinel: Optional[int] = -1
    ) -> Tuple[IndexOpsLike, pd.Index]:
        """
        Encode the object as an enumerated type or categorical variable.

        This method is useful for obtaining a numeric representation of an
        array when all that matters is identifying distinct values.

        Parameters
        ----------
        sort : bool, default True
        na_sentinel : int or None, default -1
            Value to mark "not found". If None, will not drop the NaN
            from the uniques of the values.

        Returns
        -------
        codes : Series or Index
            A Series or Index that's an indexer into `uniques`.
            ``uniques.take(codes)`` will have the same values as `values`.
        uniques : pd.Index
            The unique valid values.

            .. note ::

               Even if there's a missing value in `values`, `uniques` will
               *not* contain an entry for it.

        Examples
        --------
        >>> psser = ps.Series(['b', None, 'a', 'c', 'b'])
        >>> codes, uniques = psser.factorize()
        >>> codes
        0    1
        1   -1
        2    0
        3    2
        4    1
        dtype: int32
        >>> uniques
        Index(['a', 'b', 'c'], dtype='object')

        >>> codes, uniques = psser.factorize(na_sentinel=None)
        >>> codes
        0    1
        1    3
        2    0
        3    2
        4    1
        dtype: int32
        >>> uniques
        Index(['a', 'b', 'c', None], dtype='object')

        >>> codes, uniques = psser.factorize(na_sentinel=-2)
        >>> codes
        0    1
        1   -2
        2    0
        3    2
        4    1
        dtype: int32
        >>> uniques
        Index(['a', 'b', 'c'], dtype='object')

        For Index:

        >>> psidx = ps.Index(['b', None, 'a', 'c', 'b'])
        >>> codes, uniques = psidx.factorize()
        >>> codes
        Int64Index([1, -1, 0, 2, 1], dtype='int64')
        >>> uniques
        Index(['a', 'b', 'c'], dtype='object')
        """
        from pyspark.pandas.series import first_series

        assert (na_sentinel is None) or isinstance(na_sentinel, int)
        assert sort is True

        if isinstance(self.dtype, CategoricalDtype):
            categories = self.dtype.categories
            if len(categories) == 0:
                scol = SF.lit(None)
            else:
                kvs = list(
                    chain(
                        *[
                            (SF.lit(code), SF.lit(category))
                            for code, category in enumerate(categories)
                        ]
                    )
                )
                map_scol = F.create_map(*kvs)
                scol = map_scol[self.spark.column]
            codes, uniques = self._with_new_scol(
                scol.alias(self._internal.data_spark_column_names[0])
            ).factorize(na_sentinel=na_sentinel)
            return codes, uniques.astype(self.dtype)

        uniq_sdf = self._internal.spark_frame.select(self.spark.column).distinct()

        # Check number of uniques and constructs sorted `uniques_list`
        max_compute_count = get_option("compute.max_rows")
        if max_compute_count is not None:
            uniq_pdf = uniq_sdf.limit(max_compute_count + 1).toPandas()
            if len(uniq_pdf) > max_compute_count:
                raise ValueError(
                    "Current Series has more then {0} unique values. "
                    "Please set 'compute.max_rows' by using 'pyspark.pandas.config.set_option' "
                    "to more than {0} rows. Note that, before changing the "
                    "'compute.max_rows', this operation is considerably expensive.".format(
                        max_compute_count
                    )
                )
        else:
            uniq_pdf = uniq_sdf.toPandas()
        # pandas takes both NaN and null in Spark to np.nan, so de-duplication is required
        uniq_series = first_series(uniq_pdf).drop_duplicates()
        uniques_list = uniq_series.tolist()
        uniques_list = sorted(uniques_list, key=lambda x: (pd.isna(x), x))

        # Constructs `unique_to_code` mapping non-na unique to code
        unique_to_code = {}
        if na_sentinel is not None:
            na_sentinel_code = na_sentinel
        code = 0
        for unique in uniques_list:
            if pd.isna(unique):
                if na_sentinel is None:
                    na_sentinel_code = code
            else:
                unique_to_code[unique] = code
            code += 1

        kvs = list(
            chain(*([(SF.lit(unique), SF.lit(code)) for unique, code in unique_to_code.items()]))
        )

        if len(kvs) == 0:  # uniques are all missing values
            new_scol = SF.lit(na_sentinel_code)
        else:
            map_scol = F.create_map(*kvs)
            null_scol = F.when(self.isnull().spark.column, SF.lit(na_sentinel_code))
            new_scol = null_scol.otherwise(map_scol[self.spark.column])

        codes = self._with_new_scol(new_scol.alias(self._internal.data_spark_column_names[0]))

        if na_sentinel is not None:
            # Drops the NaN from the uniques of the values
            uniques_list = [x for x in uniques_list if not pd.isna(x)]

        uniques = pd.Index(uniques_list)

        return codes, uniques


def _test() -> None:
    import os
    import doctest
    import sys
    from pyspark.sql import SparkSession
    import pyspark.pandas.base

    os.chdir(os.environ["SPARK_HOME"])

    globs = pyspark.pandas.base.__dict__.copy()
    globs["ps"] = pyspark.pandas
    spark = (
        SparkSession.builder.master("local[4]").appName("pyspark.pandas.base tests").getOrCreate()
    )
    (failure_count, test_count) = doctest.testmod(
        pyspark.pandas.base,
        globs=globs,
        optionflags=doctest.ELLIPSIS | doctest.NORMALIZE_WHITESPACE,
    )
    spark.stop()
    if failure_count:
        sys.exit(-1)


if __name__ == "__main__":
    _test()