File size: 5,748 Bytes

f7f4f4b

import builtins
from collections.abc import Callable, Sequence
from typing import (
    Any,
    overload,
    TypeVar,
    Literal as L,
)

import numpy as np
from numpy import (
    generic,
    number,
    timedelta64,
    datetime64,
    int_,
    intp,
    float64,
    signedinteger,
    floating,
    complexfloating,
    object_,
    _OrderCF,
)

from numpy._typing import (
    DTypeLike,
    _DTypeLike,
    ArrayLike,
    _ArrayLike,
    NDArray,
    _SupportsArrayFunc,
    _ArrayLikeInt_co,
    _ArrayLikeFloat_co,
    _ArrayLikeComplex_co,
    _ArrayLikeObject_co,
)

_T = TypeVar("_T")
_SCT = TypeVar("_SCT", bound=generic)

# The returned arrays dtype must be compatible with `np.equal`
_MaskFunc = Callable[
    [NDArray[int_], _T],
    NDArray[number[Any] | np.bool | timedelta64 | datetime64 | object_],
]

__all__: list[str]

@overload
def fliplr(m: _ArrayLike[_SCT]) -> NDArray[_SCT]: ...
@overload
def fliplr(m: ArrayLike) -> NDArray[Any]: ...

@overload
def flipud(m: _ArrayLike[_SCT]) -> NDArray[_SCT]: ...
@overload
def flipud(m: ArrayLike) -> NDArray[Any]: ...

@overload
def eye(

    N: int,

    M: None | int = ...,

    k: int = ...,

    dtype: None = ...,

    order: _OrderCF = ...,

    *,

    device: None | L["cpu"] = ...,

    like: None | _SupportsArrayFunc = ...,

) -> NDArray[float64]: ...
@overload
def eye(

    N: int,

    M: None | int = ...,

    k: int = ...,

    dtype: _DTypeLike[_SCT] = ...,

    order: _OrderCF = ...,

    *,

    device: None | L["cpu"] = ...,

    like: None | _SupportsArrayFunc = ...,

) -> NDArray[_SCT]: ...
@overload
def eye(

    N: int,

    M: None | int = ...,

    k: int = ...,

    dtype: DTypeLike = ...,

    order: _OrderCF = ...,

    *,

    device: None | L["cpu"] = ...,

    like: None | _SupportsArrayFunc = ...,

) -> NDArray[Any]: ...

@overload
def diag(v: _ArrayLike[_SCT], k: int = ...) -> NDArray[_SCT]: ...
@overload
def diag(v: ArrayLike, k: int = ...) -> NDArray[Any]: ...

@overload
def diagflat(v: _ArrayLike[_SCT], k: int = ...) -> NDArray[_SCT]: ...
@overload
def diagflat(v: ArrayLike, k: int = ...) -> NDArray[Any]: ...

@overload
def tri(

    N: int,

    M: None | int = ...,

    k: int = ...,

    dtype: None = ...,

    *,

    like: None | _SupportsArrayFunc = ...

) -> NDArray[float64]: ...
@overload
def tri(

    N: int,

    M: None | int = ...,

    k: int = ...,

    dtype: _DTypeLike[_SCT] = ...,

    *,

    like: None | _SupportsArrayFunc = ...

) -> NDArray[_SCT]: ...
@overload
def tri(

    N: int,

    M: None | int = ...,

    k: int = ...,

    dtype: DTypeLike = ...,

    *,

    like: None | _SupportsArrayFunc = ...

) -> NDArray[Any]: ...

@overload
def tril(v: _ArrayLike[_SCT], k: int = ...) -> NDArray[_SCT]: ...
@overload
def tril(v: ArrayLike, k: int = ...) -> NDArray[Any]: ...

@overload
def triu(v: _ArrayLike[_SCT], k: int = ...) -> NDArray[_SCT]: ...
@overload
def triu(v: ArrayLike, k: int = ...) -> NDArray[Any]: ...

@overload
def vander(  # type: ignore[misc]

    x: _ArrayLikeInt_co,

    N: None | int = ...,

    increasing: bool = ...,

) -> NDArray[signedinteger[Any]]: ...
@overload
def vander(  # type: ignore[misc]

    x: _ArrayLikeFloat_co,

    N: None | int = ...,

    increasing: bool = ...,

) -> NDArray[floating[Any]]: ...
@overload
def vander(

    x: _ArrayLikeComplex_co,

    N: None | int = ...,

    increasing: bool = ...,

) -> NDArray[complexfloating[Any, Any]]: ...
@overload
def vander(

    x: _ArrayLikeObject_co,

    N: None | int = ...,

    increasing: bool = ...,

) -> NDArray[object_]: ...

@overload
def histogram2d(  # type: ignore[misc]

    x: _ArrayLikeFloat_co,

    y: _ArrayLikeFloat_co,

    bins: int | Sequence[int] = ...,

    range: None | _ArrayLikeFloat_co = ...,

    density: None | bool = ...,

    weights: None | _ArrayLikeFloat_co = ...,

) -> tuple[
    NDArray[float64],
    NDArray[floating[Any]],
    NDArray[floating[Any]],
]: ...
@overload
def histogram2d(

    x: _ArrayLikeComplex_co,

    y: _ArrayLikeComplex_co,

    bins: int | Sequence[int] = ...,

    range: None | _ArrayLikeFloat_co = ...,

    density: None | bool = ...,

    weights: None | _ArrayLikeFloat_co = ...,

) -> tuple[
    NDArray[float64],
    NDArray[complexfloating[Any, Any]],
    NDArray[complexfloating[Any, Any]],
]: ...
@overload  # TODO: Sort out `bins`
def histogram2d(

    x: _ArrayLikeComplex_co,

    y: _ArrayLikeComplex_co,

    bins: Sequence[_ArrayLikeInt_co],

    range: None | _ArrayLikeFloat_co = ...,

    density: None | bool = ...,

    weights: None | _ArrayLikeFloat_co = ...,

) -> tuple[
    NDArray[float64],
    NDArray[Any],
    NDArray[Any],
]: ...

# NOTE: we're assuming/demanding here the `mask_func` returns
# an ndarray of shape `(n, n)`; otherwise there is the possibility
# of the output tuple having more or less than 2 elements
@overload
def mask_indices(

    n: int,

    mask_func: _MaskFunc[int],

    k: int = ...,

) -> tuple[NDArray[intp], NDArray[intp]]: ...
@overload
def mask_indices(

    n: int,

    mask_func: _MaskFunc[_T],

    k: _T,

) -> tuple[NDArray[intp], NDArray[intp]]: ...

def tril_indices(

    n: int,

    k: int = ...,

    m: None | int = ...,

) -> tuple[NDArray[int_], NDArray[int_]]: ...

def tril_indices_from(

    arr: NDArray[Any],

    k: int = ...,

) -> tuple[NDArray[int_], NDArray[int_]]: ...

def triu_indices(

    n: int,

    k: int = ...,

    m: None | int = ...,

) -> tuple[NDArray[int_], NDArray[int_]]: ...

def triu_indices_from(

    arr: NDArray[Any],

    k: int = ...,

) -> tuple[NDArray[int_], NDArray[int_]]: ...