ai-content-maker/.venv/Lib/site-packages/pandas/compat/numpy/function.py

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2024-05-03 04:18:51 +03:00
"""
For compatibility with numpy libraries, pandas functions or methods have to
accept '*args' and '**kwargs' parameters to accommodate numpy arguments that
are not actually used or respected in the pandas implementation.
To ensure that users do not abuse these parameters, validation is performed in
'validators.py' to make sure that any extra parameters passed correspond ONLY
to those in the numpy signature. Part of that validation includes whether or
not the user attempted to pass in non-default values for these extraneous
parameters. As we want to discourage users from relying on these parameters
when calling the pandas implementation, we want them only to pass in the
default values for these parameters.
This module provides a set of commonly used default arguments for functions and
methods that are spread throughout the codebase. This module will make it
easier to adjust to future upstream changes in the analogous numpy signatures.
"""
from __future__ import annotations
from typing import (
Any,
TypeVar,
overload,
)
from numpy import ndarray
from pandas._libs.lib import (
is_bool,
is_integer,
)
from pandas._typing import Axis
from pandas.errors import UnsupportedFunctionCall
from pandas.util._validators import (
validate_args,
validate_args_and_kwargs,
validate_kwargs,
)
AxisNoneT = TypeVar("AxisNoneT", Axis, None)
class CompatValidator:
def __init__(
self,
defaults,
fname=None,
method: str | None = None,
max_fname_arg_count=None,
) -> None:
self.fname = fname
self.method = method
self.defaults = defaults
self.max_fname_arg_count = max_fname_arg_count
def __call__(
self,
args,
kwargs,
fname=None,
max_fname_arg_count=None,
method: str | None = None,
) -> None:
if args or kwargs:
fname = self.fname if fname is None else fname
max_fname_arg_count = (
self.max_fname_arg_count
if max_fname_arg_count is None
else max_fname_arg_count
)
method = self.method if method is None else method
if method == "args":
validate_args(fname, args, max_fname_arg_count, self.defaults)
elif method == "kwargs":
validate_kwargs(fname, kwargs, self.defaults)
elif method == "both":
validate_args_and_kwargs(
fname, args, kwargs, max_fname_arg_count, self.defaults
)
else:
raise ValueError(f"invalid validation method '{method}'")
ARGMINMAX_DEFAULTS = {"out": None}
validate_argmin = CompatValidator(
ARGMINMAX_DEFAULTS, fname="argmin", method="both", max_fname_arg_count=1
)
validate_argmax = CompatValidator(
ARGMINMAX_DEFAULTS, fname="argmax", method="both", max_fname_arg_count=1
)
def process_skipna(skipna: bool | ndarray | None, args) -> tuple[bool, Any]:
if isinstance(skipna, ndarray) or skipna is None:
args = (skipna,) + args
skipna = True
return skipna, args
def validate_argmin_with_skipna(skipna: bool | ndarray | None, args, kwargs) -> bool:
"""
If 'Series.argmin' is called via the 'numpy' library, the third parameter
in its signature is 'out', which takes either an ndarray or 'None', so
check if the 'skipna' parameter is either an instance of ndarray or is
None, since 'skipna' itself should be a boolean
"""
skipna, args = process_skipna(skipna, args)
validate_argmin(args, kwargs)
return skipna
def validate_argmax_with_skipna(skipna: bool | ndarray | None, args, kwargs) -> bool:
"""
If 'Series.argmax' is called via the 'numpy' library, the third parameter
in its signature is 'out', which takes either an ndarray or 'None', so
check if the 'skipna' parameter is either an instance of ndarray or is
None, since 'skipna' itself should be a boolean
"""
skipna, args = process_skipna(skipna, args)
validate_argmax(args, kwargs)
return skipna
ARGSORT_DEFAULTS: dict[str, int | str | None] = {}
ARGSORT_DEFAULTS["axis"] = -1
ARGSORT_DEFAULTS["kind"] = "quicksort"
ARGSORT_DEFAULTS["order"] = None
ARGSORT_DEFAULTS["kind"] = None
validate_argsort = CompatValidator(
ARGSORT_DEFAULTS, fname="argsort", max_fname_arg_count=0, method="both"
)
# two different signatures of argsort, this second validation for when the
# `kind` param is supported
ARGSORT_DEFAULTS_KIND: dict[str, int | None] = {}
ARGSORT_DEFAULTS_KIND["axis"] = -1
ARGSORT_DEFAULTS_KIND["order"] = None
validate_argsort_kind = CompatValidator(
ARGSORT_DEFAULTS_KIND, fname="argsort", max_fname_arg_count=0, method="both"
)
def validate_argsort_with_ascending(ascending: bool | int | None, args, kwargs) -> bool:
"""
If 'Categorical.argsort' is called via the 'numpy' library, the first
parameter in its signature is 'axis', which takes either an integer or
'None', so check if the 'ascending' parameter has either integer type or is
None, since 'ascending' itself should be a boolean
"""
if is_integer(ascending) or ascending is None:
args = (ascending,) + args
ascending = True
validate_argsort_kind(args, kwargs, max_fname_arg_count=3)
# error: Incompatible return value type (got "int", expected "bool")
return ascending # type: ignore[return-value]
CLIP_DEFAULTS: dict[str, Any] = {"out": None}
validate_clip = CompatValidator(
CLIP_DEFAULTS, fname="clip", method="both", max_fname_arg_count=3
)
@overload
def validate_clip_with_axis(axis: ndarray, args, kwargs) -> None:
...
@overload
def validate_clip_with_axis(axis: AxisNoneT, args, kwargs) -> AxisNoneT:
...
def validate_clip_with_axis(
axis: ndarray | AxisNoneT, args, kwargs
) -> AxisNoneT | None:
"""
If 'NDFrame.clip' is called via the numpy library, the third parameter in
its signature is 'out', which can takes an ndarray, so check if the 'axis'
parameter is an instance of ndarray, since 'axis' itself should either be
an integer or None
"""
if isinstance(axis, ndarray):
args = (axis,) + args
# error: Incompatible types in assignment (expression has type "None",
# variable has type "Union[ndarray[Any, Any], str, int]")
axis = None # type: ignore[assignment]
validate_clip(args, kwargs)
# error: Incompatible return value type (got "Union[ndarray[Any, Any],
# str, int]", expected "Union[str, int, None]")
return axis # type: ignore[return-value]
CUM_FUNC_DEFAULTS: dict[str, Any] = {}
CUM_FUNC_DEFAULTS["dtype"] = None
CUM_FUNC_DEFAULTS["out"] = None
validate_cum_func = CompatValidator(
CUM_FUNC_DEFAULTS, method="both", max_fname_arg_count=1
)
validate_cumsum = CompatValidator(
CUM_FUNC_DEFAULTS, fname="cumsum", method="both", max_fname_arg_count=1
)
def validate_cum_func_with_skipna(skipna, args, kwargs, name) -> bool:
"""
If this function is called via the 'numpy' library, the third parameter in
its signature is 'dtype', which takes either a 'numpy' dtype or 'None', so
check if the 'skipna' parameter is a boolean or not
"""
if not is_bool(skipna):
args = (skipna,) + args
skipna = True
validate_cum_func(args, kwargs, fname=name)
return skipna
ALLANY_DEFAULTS: dict[str, bool | None] = {}
ALLANY_DEFAULTS["dtype"] = None
ALLANY_DEFAULTS["out"] = None
ALLANY_DEFAULTS["keepdims"] = False
ALLANY_DEFAULTS["axis"] = None
validate_all = CompatValidator(
ALLANY_DEFAULTS, fname="all", method="both", max_fname_arg_count=1
)
validate_any = CompatValidator(
ALLANY_DEFAULTS, fname="any", method="both", max_fname_arg_count=1
)
LOGICAL_FUNC_DEFAULTS = {"out": None, "keepdims": False}
validate_logical_func = CompatValidator(LOGICAL_FUNC_DEFAULTS, method="kwargs")
MINMAX_DEFAULTS = {"axis": None, "out": None, "keepdims": False}
validate_min = CompatValidator(
MINMAX_DEFAULTS, fname="min", method="both", max_fname_arg_count=1
)
validate_max = CompatValidator(
MINMAX_DEFAULTS, fname="max", method="both", max_fname_arg_count=1
)
RESHAPE_DEFAULTS: dict[str, str] = {"order": "C"}
validate_reshape = CompatValidator(
RESHAPE_DEFAULTS, fname="reshape", method="both", max_fname_arg_count=1
)
REPEAT_DEFAULTS: dict[str, Any] = {"axis": None}
validate_repeat = CompatValidator(
REPEAT_DEFAULTS, fname="repeat", method="both", max_fname_arg_count=1
)
ROUND_DEFAULTS: dict[str, Any] = {"out": None}
validate_round = CompatValidator(
ROUND_DEFAULTS, fname="round", method="both", max_fname_arg_count=1
)
SORT_DEFAULTS: dict[str, int | str | None] = {}
SORT_DEFAULTS["axis"] = -1
SORT_DEFAULTS["kind"] = "quicksort"
SORT_DEFAULTS["order"] = None
validate_sort = CompatValidator(SORT_DEFAULTS, fname="sort", method="kwargs")
STAT_FUNC_DEFAULTS: dict[str, Any | None] = {}
STAT_FUNC_DEFAULTS["dtype"] = None
STAT_FUNC_DEFAULTS["out"] = None
SUM_DEFAULTS = STAT_FUNC_DEFAULTS.copy()
SUM_DEFAULTS["axis"] = None
SUM_DEFAULTS["keepdims"] = False
SUM_DEFAULTS["initial"] = None
PROD_DEFAULTS = STAT_FUNC_DEFAULTS.copy()
PROD_DEFAULTS["axis"] = None
PROD_DEFAULTS["keepdims"] = False
PROD_DEFAULTS["initial"] = None
MEDIAN_DEFAULTS = STAT_FUNC_DEFAULTS.copy()
MEDIAN_DEFAULTS["overwrite_input"] = False
MEDIAN_DEFAULTS["keepdims"] = False
STAT_FUNC_DEFAULTS["keepdims"] = False
validate_stat_func = CompatValidator(STAT_FUNC_DEFAULTS, method="kwargs")
validate_sum = CompatValidator(
SUM_DEFAULTS, fname="sum", method="both", max_fname_arg_count=1
)
validate_prod = CompatValidator(
PROD_DEFAULTS, fname="prod", method="both", max_fname_arg_count=1
)
validate_mean = CompatValidator(
STAT_FUNC_DEFAULTS, fname="mean", method="both", max_fname_arg_count=1
)
validate_median = CompatValidator(
MEDIAN_DEFAULTS, fname="median", method="both", max_fname_arg_count=1
)
STAT_DDOF_FUNC_DEFAULTS: dict[str, bool | None] = {}
STAT_DDOF_FUNC_DEFAULTS["dtype"] = None
STAT_DDOF_FUNC_DEFAULTS["out"] = None
STAT_DDOF_FUNC_DEFAULTS["keepdims"] = False
validate_stat_ddof_func = CompatValidator(STAT_DDOF_FUNC_DEFAULTS, method="kwargs")
TAKE_DEFAULTS: dict[str, str | None] = {}
TAKE_DEFAULTS["out"] = None
TAKE_DEFAULTS["mode"] = "raise"
validate_take = CompatValidator(TAKE_DEFAULTS, fname="take", method="kwargs")
def validate_take_with_convert(convert: ndarray | bool | None, args, kwargs) -> bool:
"""
If this function is called via the 'numpy' library, the third parameter in
its signature is 'axis', which takes either an ndarray or 'None', so check
if the 'convert' parameter is either an instance of ndarray or is None
"""
if isinstance(convert, ndarray) or convert is None:
args = (convert,) + args
convert = True
validate_take(args, kwargs, max_fname_arg_count=3, method="both")
return convert
TRANSPOSE_DEFAULTS = {"axes": None}
validate_transpose = CompatValidator(
TRANSPOSE_DEFAULTS, fname="transpose", method="both", max_fname_arg_count=0
)
def validate_window_func(name, args, kwargs) -> None:
numpy_args = ("axis", "dtype", "out")
msg = (
f"numpy operations are not valid with window objects. "
f"Use .{name}() directly instead "
)
if len(args) > 0:
raise UnsupportedFunctionCall(msg)
for arg in numpy_args:
if arg in kwargs:
raise UnsupportedFunctionCall(msg)
def validate_rolling_func(name, args, kwargs) -> None:
numpy_args = ("axis", "dtype", "out")
msg = (
f"numpy operations are not valid with window objects. "
f"Use .rolling(...).{name}() instead "
)
if len(args) > 0:
raise UnsupportedFunctionCall(msg)
for arg in numpy_args:
if arg in kwargs:
raise UnsupportedFunctionCall(msg)
def validate_expanding_func(name, args, kwargs) -> None:
numpy_args = ("axis", "dtype", "out")
msg = (
f"numpy operations are not valid with window objects. "
f"Use .expanding(...).{name}() instead "
)
if len(args) > 0:
raise UnsupportedFunctionCall(msg)
for arg in numpy_args:
if arg in kwargs:
raise UnsupportedFunctionCall(msg)
def validate_groupby_func(name, args, kwargs, allowed=None) -> None:
"""
'args' and 'kwargs' should be empty, except for allowed kwargs because all
of their necessary parameters are explicitly listed in the function
signature
"""
if allowed is None:
allowed = []
kwargs = set(kwargs) - set(allowed)
if len(args) + len(kwargs) > 0:
raise UnsupportedFunctionCall(
"numpy operations are not valid with groupby. "
f"Use .groupby(...).{name}() instead"
)
RESAMPLER_NUMPY_OPS = ("min", "max", "sum", "prod", "mean", "std", "var")
def validate_resampler_func(method: str, args, kwargs) -> None:
"""
'args' and 'kwargs' should be empty because all of their necessary
parameters are explicitly listed in the function signature
"""
if len(args) + len(kwargs) > 0:
if method in RESAMPLER_NUMPY_OPS:
raise UnsupportedFunctionCall(
"numpy operations are not valid with resample. "
f"Use .resample(...).{method}() instead"
)
else:
raise TypeError("too many arguments passed in")
def validate_minmax_axis(axis: int | None, ndim: int = 1) -> None:
"""
Ensure that the axis argument passed to min, max, argmin, or argmax is zero
or None, as otherwise it will be incorrectly ignored.
Parameters
----------
axis : int or None
ndim : int, default 1
Raises
------
ValueError
"""
if axis is None:
return
if axis >= ndim or (axis < 0 and ndim + axis < 0):
raise ValueError(f"`axis` must be fewer than the number of dimensions ({ndim})")