Intelegentny_Pszczelarz/.venv/Lib/site-packages/numpy/polynomial/__init__.py

"""
A sub-package for efficiently dealing with polynomials.

Within the documentation for this sub-package, a "finite power series,"
i.e., a polynomial (also referred to simply as a "series") is represented
by a 1-D numpy array of the polynomial's coefficients, ordered from lowest
order term to highest.  For example, array([1,2,3]) represents
``P_0 + 2*P_1 + 3*P_2``, where P_n is the n-th order basis polynomial
applicable to the specific module in question, e.g., `polynomial` (which
"wraps" the "standard" basis) or `chebyshev`.  For optimal performance,
all operations on polynomials, including evaluation at an argument, are
implemented as operations on the coefficients.  Additional (module-specific)
information can be found in the docstring for the module of interest.

This package provides *convenience classes* for each of six different kinds
of polynomials:

         ========================    ================
         **Name**                    **Provides**
         ========================    ================
         `~polynomial.Polynomial`    Power series
         `~chebyshev.Chebyshev`      Chebyshev series
         `~legendre.Legendre`        Legendre series
         `~laguerre.Laguerre`        Laguerre series
         `~hermite.Hermite`          Hermite series
         `~hermite_e.HermiteE`       HermiteE series
         ========================    ================

These *convenience classes* provide a consistent interface for creating,
manipulating, and fitting data with polynomials of different bases.
The convenience classes are the preferred interface for the `~numpy.polynomial`
package, and are available from the ``numpy.polynomial`` namespace.
This eliminates the need to navigate to the corresponding submodules, e.g.
``np.polynomial.Polynomial`` or ``np.polynomial.Chebyshev`` instead of
``np.polynomial.polynomial.Polynomial`` or
``np.polynomial.chebyshev.Chebyshev``, respectively.
The classes provide a more consistent and concise interface than the
type-specific functions defined in the submodules for each type of polynomial.
For example, to fit a Chebyshev polynomial with degree ``1`` to data given
by arrays ``xdata`` and ``ydata``, the
`~chebyshev.Chebyshev.fit` class method::

    >>> from numpy.polynomial import Chebyshev
    >>> c = Chebyshev.fit(xdata, ydata, deg=1)

is preferred over the `chebyshev.chebfit` function from the
``np.polynomial.chebyshev`` module::

    >>> from numpy.polynomial.chebyshev import chebfit
    >>> c = chebfit(xdata, ydata, deg=1)

See :doc:`routines.polynomials.classes` for more details.

Convenience Classes
===================

The following lists the various constants and methods common to all of
the classes representing the various kinds of polynomials. In the following,
the term ``Poly`` represents any one of the convenience classes (e.g.
`~polynomial.Polynomial`, `~chebyshev.Chebyshev`, `~hermite.Hermite`, etc.)
while the lowercase ``p`` represents an **instance** of a polynomial class.

Constants
---------

- ``Poly.domain``     -- Default domain
- ``Poly.window``     -- Default window
- ``Poly.basis_name`` -- String used to represent the basis
- ``Poly.maxpower``   -- Maximum value ``n`` such that ``p**n`` is allowed
- ``Poly.nickname``   -- String used in printing

Creation
--------

Methods for creating polynomial instances.

- ``Poly.basis(degree)``    -- Basis polynomial of given degree
- ``Poly.identity()``       -- ``p`` where ``p(x) = x`` for all ``x``
- ``Poly.fit(x, y, deg)``   -- ``p`` of degree ``deg`` with coefficients
  determined by the least-squares fit to the data ``x``, ``y``
- ``Poly.fromroots(roots)`` -- ``p`` with specified roots
- ``p.copy()``              -- Create a copy of ``p``

Conversion
----------

Methods for converting a polynomial instance of one kind to another.

- ``p.cast(Poly)``    -- Convert ``p`` to instance of kind ``Poly``
- ``p.convert(Poly)`` -- Convert ``p`` to instance of kind ``Poly`` or map
  between ``domain`` and ``window``

Calculus
--------
- ``p.deriv()`` -- Take the derivative of ``p``
- ``p.integ()`` -- Integrate ``p``

Validation
----------
- ``Poly.has_samecoef(p1, p2)``   -- Check if coefficients match
- ``Poly.has_samedomain(p1, p2)`` -- Check if domains match
- ``Poly.has_sametype(p1, p2)``   -- Check if types match
- ``Poly.has_samewindow(p1, p2)`` -- Check if windows match

Misc
----
- ``p.linspace()`` -- Return ``x, p(x)`` at equally-spaced points in ``domain``
- ``p.mapparms()`` -- Return the parameters for the linear mapping between
  ``domain`` and ``window``.
- ``p.roots()``    -- Return the roots of `p`.
- ``p.trim()``     -- Remove trailing coefficients.
- ``p.cutdeg(degree)`` -- Truncate p to given degree
- ``p.truncate(size)`` -- Truncate p to given size

"""
from .polynomial import Polynomial
from .chebyshev import Chebyshev
from .legendre import Legendre
from .hermite import Hermite
from .hermite_e import HermiteE
from .laguerre import Laguerre

__all__ = [
    "set_default_printstyle",
    "polynomial", "Polynomial",
    "chebyshev", "Chebyshev",
    "legendre", "Legendre",
    "hermite", "Hermite",
    "hermite_e", "HermiteE",
    "laguerre", "Laguerre",
]


def set_default_printstyle(style):
    """
    Set the default format for the string representation of polynomials.

    Values for ``style`` must be valid inputs to ``__format__``, i.e. 'ascii'
    or 'unicode'.

    Parameters
    ----------
    style : str
        Format string for default printing style. Must be either 'ascii' or
        'unicode'.

    Notes
    -----
    The default format depends on the platform: 'unicode' is used on
    Unix-based systems and 'ascii' on Windows. This determination is based on
    default font support for the unicode superscript and subscript ranges.

    Examples
    --------
    >>> p = np.polynomial.Polynomial([1, 2, 3])
    >>> c = np.polynomial.Chebyshev([1, 2, 3])
    >>> np.polynomial.set_default_printstyle('unicode')
    >>> print(p)
    1.0 + 2.0·x¹ + 3.0·x²
    >>> print(c)
    1.0 + 2.0·T₁(x) + 3.0·T₂(x)
    >>> np.polynomial.set_default_printstyle('ascii')
    >>> print(p)
    1.0 + 2.0 x**1 + 3.0 x**2
    >>> print(c)
    1.0 + 2.0 T_1(x) + 3.0 T_2(x)
    >>> # Formatting supersedes all class/package-level defaults
    >>> print(f"{p:unicode}")
    1.0 + 2.0·x¹ + 3.0·x²
    """
    if style not in ('unicode', 'ascii'):
        raise ValueError(
            f"Unsupported format string '{style}'. Valid options are 'ascii' "
            f"and 'unicode'"
        )
    _use_unicode = True
    if style == 'ascii':
        _use_unicode = False
    from ._polybase import ABCPolyBase
    ABCPolyBase._use_unicode = _use_unicode


from numpy._pytesttester import PytestTester
test = PytestTester(__name__)
del PytestTester
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`"""`
			`A sub-package for efficiently dealing with polynomials.`

			`Within the documentation for this sub-package, a "finite power series,"`
			`i.e., a polynomial (also referred to simply as a "series") is represented`
			`by a 1-D numpy array of the polynomial's coefficients, ordered from lowest`
			`order term to highest. For example, array([1,2,3]) represents`
			``P_0 + 2P_1 + 3P_2``, where P_n is the n-th order basis polynomial
			applicable to the specific module in question, e.g., `polynomial` (which
			"wraps" the "standard" basis) or `chebyshev`. For optimal performance,
			`all operations on polynomials, including evaluation at an argument, are`
			`implemented as operations on the coefficients. Additional (module-specific)`
			`information can be found in the docstring for the module of interest.`

			`This package provides convenience classes for each of six different kinds`
			`of polynomials:`

			`======================== ================`
			`Name Provides`
			`======================== ================`
			`~polynomial.Polynomial` Power series
			`~chebyshev.Chebyshev` Chebyshev series
			`~legendre.Legendre` Legendre series
			`~laguerre.Laguerre` Laguerre series
			`~hermite.Hermite` Hermite series
			`~hermite_e.HermiteE` HermiteE series
			`======================== ================`

			`These convenience classes provide a consistent interface for creating,`
			`manipulating, and fitting data with polynomials of different bases.`
			The convenience classes are the preferred interface for the `~numpy.polynomial`
			package, and are available from the ``numpy.polynomial`` namespace.
			`This eliminates the need to navigate to the corresponding submodules, e.g.`
			``np.polynomial.Polynomial`` or ``np.polynomial.Chebyshev`` instead of
			``np.polynomial.polynomial.Polynomial`` or
			``np.polynomial.chebyshev.Chebyshev``, respectively.
			`The classes provide a more consistent and concise interface than the`
			`type-specific functions defined in the submodules for each type of polynomial.`
			For example, to fit a Chebyshev polynomial with degree ``1`` to data given
			by arrays ``xdata`` and ``ydata``, the
			`~chebyshev.Chebyshev.fit` class method::

			`>>> from numpy.polynomial import Chebyshev`
			`>>> c = Chebyshev.fit(xdata, ydata, deg=1)`

			is preferred over the `chebyshev.chebfit` function from the
			``np.polynomial.chebyshev`` module::

			`>>> from numpy.polynomial.chebyshev import chebfit`
			`>>> c = chebfit(xdata, ydata, deg=1)`

			See :doc:`routines.polynomials.classes` for more details.

			`Convenience Classes`
			`===================`

			`The following lists the various constants and methods common to all of`
			`the classes representing the various kinds of polynomials. In the following,`
			the term ``Poly`` represents any one of the convenience classes (e.g.
			`~polynomial.Polynomial`, `~chebyshev.Chebyshev`, `~hermite.Hermite`, etc.)
			while the lowercase ``p`` represents an instance of a polynomial class.

			`Constants`
			`---------`

			- ``Poly.domain`` -- Default domain
			- ``Poly.window`` -- Default window
			- ``Poly.basis_name`` -- String used to represent the basis
			- ``Poly.maxpower`` -- Maximum value ``n`` such that ``p**n`` is allowed
			- ``Poly.nickname`` -- String used in printing

			`Creation`
			`--------`

			`Methods for creating polynomial instances.`

			- ``Poly.basis(degree)`` -- Basis polynomial of given degree
			- ``Poly.identity()`` -- ``p`` where ``p(x) = x`` for all ``x``
			- ``Poly.fit(x, y, deg)`` -- ``p`` of degree ``deg`` with coefficients
			determined by the least-squares fit to the data ``x``, ``y``
			- ``Poly.fromroots(roots)`` -- ``p`` with specified roots
			- ``p.copy()`` -- Create a copy of ``p``

			`Conversion`
			`----------`

			`Methods for converting a polynomial instance of one kind to another.`

			- ``p.cast(Poly)`` -- Convert ``p`` to instance of kind ``Poly``
			- ``p.convert(Poly)`` -- Convert ``p`` to instance of kind ``Poly`` or map
			between ``domain`` and ``window``

			`Calculus`
			`--------`
			- ``p.deriv()`` -- Take the derivative of ``p``
			- ``p.integ()`` -- Integrate ``p``

			`Validation`
			`----------`
			- ``Poly.has_samecoef(p1, p2)`` -- Check if coefficients match
			- ``Poly.has_samedomain(p1, p2)`` -- Check if domains match
			- ``Poly.has_sametype(p1, p2)`` -- Check if types match
			- ``Poly.has_samewindow(p1, p2)`` -- Check if windows match

			`Misc`
			`----`
			- ``p.linspace()`` -- Return ``x, p(x)`` at equally-spaced points in ``domain``
			- ``p.mapparms()`` -- Return the parameters for the linear mapping between
			``domain`` and ``window``.
			- ``p.roots()`` -- Return the roots of `p`.
			- ``p.trim()`` -- Remove trailing coefficients.
			- ``p.cutdeg(degree)`` -- Truncate p to given degree
			- ``p.truncate(size)`` -- Truncate p to given size

			`"""`
			`from .polynomial import Polynomial`
			`from .chebyshev import Chebyshev`
			`from .legendre import Legendre`
			`from .hermite import Hermite`
			`from .hermite_e import HermiteE`
			`from .laguerre import Laguerre`

			`__all__ = [`
			`"set_default_printstyle",`
			`"polynomial", "Polynomial",`
			`"chebyshev", "Chebyshev",`
			`"legendre", "Legendre",`
			`"hermite", "Hermite",`
			`"hermite_e", "HermiteE",`
			`"laguerre", "Laguerre",`
			`]`


			`def set_default_printstyle(style):`
			`"""`
			`Set the default format for the string representation of polynomials.`

			Values for ``style`` must be valid inputs to ``__format__``, i.e. 'ascii'
			`or 'unicode'.`

			`Parameters`
			`----------`
			`style : str`
			`Format string for default printing style. Must be either 'ascii' or`
			`'unicode'.`

			`Notes`
			`-----`
			`The default format depends on the platform: 'unicode' is used on`
			`Unix-based systems and 'ascii' on Windows. This determination is based on`
			`default font support for the unicode superscript and subscript ranges.`

			`Examples`
			`--------`
			`>>> p = np.polynomial.Polynomial([1, 2, 3])`
			`>>> c = np.polynomial.Chebyshev([1, 2, 3])`
			`>>> np.polynomial.set_default_printstyle('unicode')`
			`>>> print(p)`
			`1.0 + 2.0·x¹ + 3.0·x²`
			`>>> print(c)`
			`1.0 + 2.0·T₁(x) + 3.0·T₂(x)`
			`>>> np.polynomial.set_default_printstyle('ascii')`
			`>>> print(p)`
			`1.0 + 2.0 x1 + 3.0 x2`
			`>>> print(c)`
			`1.0 + 2.0 T_1(x) + 3.0 T_2(x)`
			`>>> # Formatting supersedes all class/package-level defaults`
			`>>> print(f"{p:unicode}")`
			`1.0 + 2.0·x¹ + 3.0·x²`
			`"""`
			`if style not in ('unicode', 'ascii'):`
			`raise ValueError(`
			`f"Unsupported format string '{style}'. Valid options are 'ascii' "`
			`f"and 'unicode'"`
			`)`
			`_use_unicode = True`
			`if style == 'ascii':`
			`_use_unicode = False`
			`from ._polybase import ABCPolyBase`
			`ABCPolyBase._use_unicode = _use_unicode`


			`from numpy._pytesttester import PytestTester`
			`test = PytestTester(__name__)`
			`del PytestTester`