Pracownia_programowania/venv/Lib/site-packages/matplotlib/axes/_secondary_axes.py

import collections
import numpy as np
import numbers

import warnings

import matplotlib.docstring as docstring
import matplotlib.ticker as mticker
import matplotlib.transforms as mtransforms
import matplotlib.scale as mscale
import matplotlib.cbook as cbook

from matplotlib.axes._base import _AxesBase

from matplotlib.ticker import (
    AutoLocator,
    AutoMinorLocator,
    FixedLocator,
    FuncFormatter,
    LogFormatterSciNotation,
    LogLocator,
    NullLocator,
    NullFormatter,
    ScalarFormatter
)

from matplotlib.scale import Log10Transform


def _make_secondary_locator(rect, parent):
    """
    Helper function to locate the secondary axes.

    A locator gets used in `Axes.set_aspect` to override the default
    locations...  It is a function that takes an axes object and
    a renderer and tells `set_aspect` where it is to be placed.

    This locator make the transform be in axes-relative co-coordinates
    because that is how we specify the "location" of the secondary axes.

    Here *rect* is a rectangle [l, b, w, h] that specifies the
    location for the axes in the transform given by *trans* on the
    *parent*.
    """
    _rect = mtransforms.Bbox.from_bounds(*rect)
    def secondary_locator(ax, renderer):
        # delay evaluating transform until draw time because the
        # parent transform may have changed (i.e. if window reesized)
        bb = mtransforms.TransformedBbox(_rect, parent.transAxes)
        tr = parent.figure.transFigure.inverted()
        bb = mtransforms.TransformedBbox(bb, tr)
        return bb

    return secondary_locator


class SecondaryAxis(_AxesBase):
    """
    General class to hold a Secondary_X/Yaxis.
    """

    def __init__(self, parent, orientation,
                  location, functions, **kwargs):
        """
        See `.secondary_xaxis` and `.secondary_yaxis` for the doc string.
        While there is no need for this to be private, it should really be
        called by those higher level functions.
        """

        self._functions = functions
        self._parent = parent
        self._orientation = orientation
        self._ticks_set = False

        if self._orientation == 'x':
            super().__init__(self._parent.figure, [0, 1., 1, 0.0001], **kwargs)
            self._axis = self.xaxis
            self._locstrings = ['top', 'bottom']
            self._otherstrings = ['left', 'right']
        elif self._orientation == 'y':
            super().__init__(self._parent.figure, [0, 1., 0.0001, 1], **kwargs)
            self._axis = self.yaxis
            self._locstrings = ['right', 'left']
            self._otherstrings = ['top', 'bottom']
        # this gets positioned w/o constrained_layout so exclude:
        self._layoutbox = None
        self._poslayoutbox = None

        self.set_location(location)
        self.set_functions(functions)

        # styling:
        if self._orientation == 'x':
            otheraxis = self.yaxis
        else:
            otheraxis = self.xaxis

        otheraxis.set_major_locator(mticker.NullLocator())
        otheraxis.set_ticks_position('none')

        for st in self._otherstrings:
            self.spines[st].set_visible(False)
        for st in self._locstrings:
            self.spines[st].set_visible(True)

        if self._pos < 0.5:
            # flip the location strings...
            self._locstrings = self._locstrings[::-1]
        self.set_alignment(self._locstrings[0])

    def set_alignment(self, align):
        """
        Set if axes spine and labels are drawn at top or bottom (or left/right)
        of the axes.

        Parameters
        ----------
        align :: string
            either 'top' or 'bottom' for orientation='x' or
            'left' or 'right' for orientation='y' axis

        """
        if align in self._locstrings:
            if align == self._locstrings[1]:
                # need to change the orientation.
                self._locstrings = self._locstrings[::-1]
            elif align != self._locstrings[0]:
                raise ValueError('"{}" is not a valid axis orientation, '
                                 'not changing the orientation;'
                                 'choose "{}" or "{}""'.format(align,
                                 self._locstrings[0], self._locstrings[1]))
            self.spines[self._locstrings[0]].set_visible(True)
            self.spines[self._locstrings[1]].set_visible(False)
            self._axis.set_ticks_position(align)
            self._axis.set_label_position(align)

    def set_location(self, location):
        """
        Set the vertical or horizontal location of the axes in
        parent-normalized co-ordinates.

        Parameters
        ----------
        location : string or scalar
            The position to put the secondary axis.  Strings can be 'top' or
            'bottom' for orientation='x' and 'right' or 'left' for
            orientation='y', scalar can be a float indicating the relative
            position on the parent axes to put the new axes, 0.0 being the
            bottom (or left) and 1.0 being the top (or right).
        """

        # This puts the rectangle into figure-relative coordinates.
        if isinstance(location, str):
            if location in ['top', 'right']:
                self._pos = 1.
            elif location in ['bottom', 'left']:
                self._pos = 0.
            else:
                raise ValueError("location must be '{}', '{}', or a "
                                 "float, not '{}'".format(location,
                                 self._locstrings[0], self._locstrings[1]))
        else:
            self._pos = location
        self._loc = location

        if self._orientation == 'x':
            bounds = [0, self._pos, 1., 1e-10]
        else:
            bounds = [self._pos, 0, 1e-10, 1]

        secondary_locator = _make_secondary_locator(bounds, self._parent)

        # this locator lets the axes move in the parent axes coordinates.
        # so it never needs to know where the parent is explicitly in
        # figure co-ordinates.
        # it gets called in `ax.apply_aspect() (of all places)
        self.set_axes_locator(secondary_locator)

    def apply_aspect(self, position=None):
        self._set_lims()
        super().apply_aspect(position)

    def set_ticks(self, ticks, minor=False):
        """
        Set the x ticks with list of *ticks*

        Parameters
        ----------
        ticks : list
            List of x-axis tick locations.

        minor : bool, optional
            If ``False`` sets major ticks, if ``True`` sets minor ticks.
            Default is ``False``.
        """
        ret = self._axis.set_ticks(ticks, minor=minor)
        self.stale = True
        self._ticks_set = True
        return ret

    def set_functions(self, functions):
        """
        Set how the secondary axis converts limits from the parent axes.

        Parameters
        ----------
        functions : 2-tuple of func, or `Transform` with an inverse.
            Transform between the parent axis values and the secondary axis
            values.

            If supplied as a 2-tuple of functions, the first function is
            the forward transform function and the second is the inverse
            transform.

            If a transform is supplied, then the transform must have an
            inverse.

        """

        if self._orientation == 'x':
            set_scale = self.set_xscale
            parent_scale = self._parent.get_xscale()
        else:
            set_scale = self.set_yscale
            parent_scale = self._parent.get_yscale()
        # we need to use a modified scale so the scale can receive the
        # transform.  Only types supported are linear and log10 for now.
        # Probably possible to add other transforms as a todo...
        if parent_scale == 'log':
            defscale = 'functionlog'
        else:
            defscale = 'function'

        if (isinstance(functions, tuple) and len(functions) == 2 and
            callable(functions[0]) and callable(functions[1])):
            # make an arbitrary convert from a two-tuple of functions
            # forward and inverse.
            self._functions = functions
        elif functions is None:
            self._functions = (lambda x: x, lambda x: x)
        else:
            raise ValueError('functions argument of secondary axes '
                             'must be a two-tuple of callable functions '
                             'with the first function being the transform '
                             'and the second being the inverse')
        # need to invert the roles here for the ticks to line up.
        set_scale(defscale, functions=self._functions[::-1])

    def draw(self, renderer=None, inframe=False):
        """
        Draw the secondary axes.

        Consults the parent axes for its limits and converts them
        using the converter specified by
        `~.axes._secondary_axes.set_functions` (or *functions*
        parameter when axes initialized.)

        """

        self._set_lims()
        # this sets the scale in case the parent has set its scale.
        self._set_scale()
        super().draw(renderer=renderer, inframe=inframe)

    def _set_scale(self):
        """
        Check if parent has set its scale
        """

        if self._orientation == 'x':
            pscale = self._parent.xaxis.get_scale()
            set_scale = self.set_xscale
        if self._orientation == 'y':
            pscale = self._parent.yaxis.get_scale()
            set_scale = self.set_yscale
        if pscale == 'log':
            defscale = 'functionlog'
        else:
            defscale = 'function'

        if self._ticks_set:
            ticks = self._axis.get_ticklocs()

        # need to invert the roles here for the ticks to line up.
        set_scale(defscale, functions=self._functions[::-1])

        # OK, set_scale sets the locators, but if we've called
        # axsecond.set_ticks, we want to keep those.
        if self._ticks_set:
            self._axis.set_major_locator(FixedLocator(ticks))

    def _set_lims(self):
        """
        Set the limits based on parent limits and the convert method
        between the parent and this secondary axes
        """
        if self._orientation == 'x':
            lims = self._parent.get_xlim()
            set_lim = self.set_xlim
            trans = self.xaxis.get_transform()
        if self._orientation == 'y':
            lims = self._parent.get_ylim()
            set_lim = self.set_ylim
            trans = self.yaxis.get_transform()
        order = lims[0] < lims[1]
        lims = self._functions[0](np.array(lims))
        neworder = lims[0] < lims[1]
        if neworder != order:
            # flip because the transform will take care of the flipping..
            lims = lims[::-1]
        set_lim(lims)

    def get_tightbbox(self, renderer, call_axes_locator=True):
        """
        Return the tight bounding box of the axes.
        The dimension of the Bbox in canvas coordinate.

        If *call_axes_locator* is *False*, it does not call the
        _axes_locator attribute, which is necessary to get the correct
        bounding box. ``call_axes_locator==False`` can be used if the
        caller is only intereted in the relative size of the tightbbox
        compared to the axes bbox.
        """

        bb = []

        if not self.get_visible():
            return None

        self._set_lims()
        locator = self.get_axes_locator()
        if locator and call_axes_locator:
            pos = locator(self, renderer)
            self.apply_aspect(pos)
        else:
            self.apply_aspect()

        if self._orientation == 'x':
            bb_axis = self.xaxis.get_tightbbox(renderer)
        else:
            bb_axis = self.yaxis.get_tightbbox(renderer)
        if bb_axis:
            bb.append(bb_axis)

        bb.append(self.get_window_extent(renderer))
        _bbox = mtransforms.Bbox.union(
            [b for b in bb if b.width != 0 or b.height != 0])

        return _bbox

    def set_aspect(self, *args, **kwargs):
        """
        Secondary axes cannot set the aspect ratio, so calling this just
        sets a warning.
        """
        cbook._warn_external("Secondary axes can't set the aspect ratio")

    def set_xlabel(self, xlabel, fontdict=None, labelpad=None, **kwargs):
        """
        Set the label for the x-axis.

        Parameters
        ----------
        xlabel : str
            The label text.

        labelpad : scalar, optional, default: None
            Spacing in points between the label and the x-axis.

        Other Parameters
        ----------------
        **kwargs : `.Text` properties
            `.Text` properties control the appearance of the label.

        See also
        --------
        text : for information on how override and the optional args work
        """
        if labelpad is not None:
            self.xaxis.labelpad = labelpad
        return self.xaxis.set_label_text(xlabel, fontdict, **kwargs)

    def set_ylabel(self, ylabel, fontdict=None, labelpad=None, **kwargs):
        """
        Set the label for the x-axis.

        Parameters
        ----------
        ylabel : str
            The label text.

        labelpad : scalar, optional, default: None
            Spacing in points between the label and the x-axis.

        Other Parameters
        ----------------
        **kwargs : `.Text` properties
            `.Text` properties control the appearance of the label.

        See also
        --------
        text : for information on how override and the optional args work
        """
        if labelpad is not None:
            self.yaxis.labelpad = labelpad
        return self.yaxis.set_label_text(ylabel, fontdict, **kwargs)

    def set_color(self, color):
        """
        Change the color of the secondary axes and all decorators
        Parameters
        ----------
        color : Matplotlib color
        """

        if self._orientation == 'x':
            self.tick_params(axis='x', colors=color)
            self.spines['bottom'].set_color(color)
            self.spines['top'].set_color(color)
            self.xaxis.label.set_color(color)
        else:
            self.tick_params(axis='y', colors=color)
            self.spines['left'].set_color(color)
            self.spines['right'].set_color(color)
            self.yaxis.label.set_color(color)


_secax_docstring = '''
Warnings
--------

This method is experimental as of 3.1, and the API may change.

Parameters
----------
location : string or scalar
    The position to put the secondary axis.  Strings can be 'top' or
    'bottom', for x-oriented axises or 'left' or 'right' for y-oriented axises
    or a scalar can be a float indicating the relative position
    on the axes to put the new axes (0 being the bottom (left), and 1.0 being
    the top (right).)

functions : 2-tuple of func, or Transform with an inverse

    If a 2-tuple of functions, the user specifies the transform
    function and its inverse.  i.e.
    `functions=(lambda x: 2 / x, lambda x: 2 / x)` would be an
    reciprocal transform with a factor of 2.

    The user can also directly supply a subclass of
    `.transforms.Transform` so long as it has an inverse.

    See :doc:`/gallery/subplots_axes_and_figures/secondary_axis`
    for examples of making these conversions.


Other Parameters
----------------
**kwargs : `~matplotlib.axes.Axes` properties.
    Other miscellaneous axes parameters.

Returns
-------
ax : axes._secondary_axes.SecondaryAxis
'''
docstring.interpd.update(_secax_docstring=_secax_docstring)