py-data-analysis/.venv/lib/python3.12/site-packages/pandas/tests/plotting/common.py

"""
Module consolidating common testing functions for checking plotting.
"""

from __future__ import annotations

from typing import TYPE_CHECKING

import numpy as np

from pandas.core.dtypes.api import is_list_like

import pandas as pd
from pandas import Series
import pandas._testing as tm

if TYPE_CHECKING:
    from collections.abc import Sequence

    from matplotlib.axes import Axes


def _check_legend_labels(axes, labels=None, visible=True):
    """
    Check each axes has expected legend labels

    Parameters
    ----------
    axes : matplotlib Axes object, or its list-like
    labels : list-like
        expected legend labels
    visible : bool
        expected legend visibility. labels are checked only when visible is
        True
    """
    if visible and (labels is None):
        raise ValueError("labels must be specified when visible is True")
    axes = _flatten_visible(axes)
    for ax in axes:
        if visible:
            assert ax.get_legend() is not None
            _check_text_labels(ax.get_legend().get_texts(), labels)
        else:
            assert ax.get_legend() is None


def _check_legend_marker(ax, expected_markers=None, visible=True):
    """
    Check ax has expected legend markers

    Parameters
    ----------
    ax : matplotlib Axes object
    expected_markers : list-like
        expected legend markers
    visible : bool
        expected legend visibility. labels are checked only when visible is
        True
    """
    if visible and (expected_markers is None):
        raise ValueError("Markers must be specified when visible is True")
    if visible:
        handles, _ = ax.get_legend_handles_labels()
        markers = [handle.get_marker() for handle in handles]
        assert markers == expected_markers
    else:
        assert ax.get_legend() is None


def _check_data(xp, rs):
    """
    Check each axes has identical lines

    Parameters
    ----------
    xp : matplotlib Axes object
    rs : matplotlib Axes object
    """
    import matplotlib.pyplot as plt

    xp_lines = xp.get_lines()
    rs_lines = rs.get_lines()

    assert len(xp_lines) == len(rs_lines)
    for xpl, rsl in zip(xp_lines, rs_lines):
        xpdata = xpl.get_xydata()
        rsdata = rsl.get_xydata()
        tm.assert_almost_equal(xpdata, rsdata)

    plt.close("all")


def _check_visible(collections, visible=True):
    """
    Check each artist is visible or not

    Parameters
    ----------
    collections : matplotlib Artist or its list-like
        target Artist or its list or collection
    visible : bool
        expected visibility
    """
    from matplotlib.collections import Collection

    if not isinstance(collections, Collection) and not is_list_like(collections):
        collections = [collections]

    for patch in collections:
        assert patch.get_visible() == visible


def _check_patches_all_filled(axes: Axes | Sequence[Axes], filled: bool = True) -> None:
    """
    Check for each artist whether it is filled or not

    Parameters
    ----------
    axes : matplotlib Axes object, or its list-like
    filled : bool
        expected filling
    """

    axes = _flatten_visible(axes)
    for ax in axes:
        for patch in ax.patches:
            assert patch.fill == filled


def _get_colors_mapped(series, colors):
    unique = series.unique()
    # unique and colors length can be differed
    # depending on slice value
    mapped = dict(zip(unique, colors))
    return [mapped[v] for v in series.values]


def _check_colors(collections, linecolors=None, facecolors=None, mapping=None):
    """
    Check each artist has expected line colors and face colors

    Parameters
    ----------
    collections : list-like
        list or collection of target artist
    linecolors : list-like which has the same length as collections
        list of expected line colors
    facecolors : list-like which has the same length as collections
        list of expected face colors
    mapping : Series
        Series used for color grouping key
        used for andrew_curves, parallel_coordinates, radviz test
    """
    from matplotlib import colors
    from matplotlib.collections import (
        Collection,
        LineCollection,
        PolyCollection,
    )
    from matplotlib.lines import Line2D

    conv = colors.ColorConverter
    if linecolors is not None:
        if mapping is not None:
            linecolors = _get_colors_mapped(mapping, linecolors)
            linecolors = linecolors[: len(collections)]

        assert len(collections) == len(linecolors)
        for patch, color in zip(collections, linecolors):
            if isinstance(patch, Line2D):
                result = patch.get_color()
                # Line2D may contains string color expression
                result = conv.to_rgba(result)
            elif isinstance(patch, (PolyCollection, LineCollection)):
                result = tuple(patch.get_edgecolor()[0])
            else:
                result = patch.get_edgecolor()

            expected = conv.to_rgba(color)
            assert result == expected

    if facecolors is not None:
        if mapping is not None:
            facecolors = _get_colors_mapped(mapping, facecolors)
            facecolors = facecolors[: len(collections)]

        assert len(collections) == len(facecolors)
        for patch, color in zip(collections, facecolors):
            if isinstance(patch, Collection):
                # returned as list of np.array
                result = patch.get_facecolor()[0]
            else:
                result = patch.get_facecolor()

            if isinstance(result, np.ndarray):
                result = tuple(result)

            expected = conv.to_rgba(color)
            assert result == expected


def _check_text_labels(texts, expected):
    """
    Check each text has expected labels

    Parameters
    ----------
    texts : matplotlib Text object, or its list-like
        target text, or its list
    expected : str or list-like which has the same length as texts
        expected text label, or its list
    """
    if not is_list_like(texts):
        assert texts.get_text() == expected
    else:
        labels = [t.get_text() for t in texts]
        assert len(labels) == len(expected)
        for label, e in zip(labels, expected):
            assert label == e


def _check_ticks_props(axes, xlabelsize=None, xrot=None, ylabelsize=None, yrot=None):
    """
    Check each axes has expected tick properties

    Parameters
    ----------
    axes : matplotlib Axes object, or its list-like
    xlabelsize : number
        expected xticks font size
    xrot : number
        expected xticks rotation
    ylabelsize : number
        expected yticks font size
    yrot : number
        expected yticks rotation
    """
    from matplotlib.ticker import NullFormatter

    axes = _flatten_visible(axes)
    for ax in axes:
        if xlabelsize is not None or xrot is not None:
            if isinstance(ax.xaxis.get_minor_formatter(), NullFormatter):
                # If minor ticks has NullFormatter, rot / fontsize are not
                # retained
                labels = ax.get_xticklabels()
            else:
                labels = ax.get_xticklabels() + ax.get_xticklabels(minor=True)

            for label in labels:
                if xlabelsize is not None:
                    tm.assert_almost_equal(label.get_fontsize(), xlabelsize)
                if xrot is not None:
                    tm.assert_almost_equal(label.get_rotation(), xrot)

        if ylabelsize is not None or yrot is not None:
            if isinstance(ax.yaxis.get_minor_formatter(), NullFormatter):
                labels = ax.get_yticklabels()
            else:
                labels = ax.get_yticklabels() + ax.get_yticklabels(minor=True)

            for label in labels:
                if ylabelsize is not None:
                    tm.assert_almost_equal(label.get_fontsize(), ylabelsize)
                if yrot is not None:
                    tm.assert_almost_equal(label.get_rotation(), yrot)


def _check_ax_scales(axes, xaxis="linear", yaxis="linear"):
    """
    Check each axes has expected scales

    Parameters
    ----------
    axes : matplotlib Axes object, or its list-like
    xaxis : {'linear', 'log'}
        expected xaxis scale
    yaxis : {'linear', 'log'}
        expected yaxis scale
    """
    axes = _flatten_visible(axes)
    for ax in axes:
        assert ax.xaxis.get_scale() == xaxis
        assert ax.yaxis.get_scale() == yaxis


def _check_axes_shape(axes, axes_num=None, layout=None, figsize=None):
    """
    Check expected number of axes is drawn in expected layout

    Parameters
    ----------
    axes : matplotlib Axes object, or its list-like
    axes_num : number
        expected number of axes. Unnecessary axes should be set to
        invisible.
    layout : tuple
        expected layout, (expected number of rows , columns)
    figsize : tuple
        expected figsize. default is matplotlib default
    """
    from pandas.plotting._matplotlib.tools import flatten_axes

    if figsize is None:
        figsize = (6.4, 4.8)
    visible_axes = _flatten_visible(axes)

    if axes_num is not None:
        assert len(visible_axes) == axes_num
        for ax in visible_axes:
            # check something drawn on visible axes
            assert len(ax.get_children()) > 0

    if layout is not None:
        x_set = set()
        y_set = set()
        for ax in flatten_axes(axes):
            # check axes coordinates to estimate layout
            points = ax.get_position().get_points()
            x_set.add(points[0][0])
            y_set.add(points[0][1])
        result = (len(y_set), len(x_set))
        assert result == layout

    tm.assert_numpy_array_equal(
        visible_axes[0].figure.get_size_inches(),
        np.array(figsize, dtype=np.float64),
    )


def _flatten_visible(axes: Axes | Sequence[Axes]) -> Sequence[Axes]:
    """
    Flatten axes, and filter only visible

    Parameters
    ----------
    axes : matplotlib Axes object, or its list-like

    """
    from pandas.plotting._matplotlib.tools import flatten_axes

    axes_ndarray = flatten_axes(axes)
    axes = [ax for ax in axes_ndarray if ax.get_visible()]
    return axes


def _check_has_errorbars(axes, xerr=0, yerr=0):
    """
    Check axes has expected number of errorbars

    Parameters
    ----------
    axes : matplotlib Axes object, or its list-like
    xerr : number
        expected number of x errorbar
    yerr : number
        expected number of y errorbar
    """
    axes = _flatten_visible(axes)
    for ax in axes:
        containers = ax.containers
        xerr_count = 0
        yerr_count = 0
        for c in containers:
            has_xerr = getattr(c, "has_xerr", False)
            has_yerr = getattr(c, "has_yerr", False)
            if has_xerr:
                xerr_count += 1
            if has_yerr:
                yerr_count += 1
        assert xerr == xerr_count
        assert yerr == yerr_count


def _check_box_return_type(
    returned, return_type, expected_keys=None, check_ax_title=True
):
    """
    Check box returned type is correct

    Parameters
    ----------
    returned : object to be tested, returned from boxplot
    return_type : str
        return_type passed to boxplot
    expected_keys : list-like, optional
        group labels in subplot case. If not passed,
        the function checks assuming boxplot uses single ax
    check_ax_title : bool
        Whether to check the ax.title is the same as expected_key
        Intended to be checked by calling from ``boxplot``.
        Normal ``plot`` doesn't attach ``ax.title``, it must be disabled.
    """
    from matplotlib.axes import Axes

    types = {"dict": dict, "axes": Axes, "both": tuple}
    if expected_keys is None:
        # should be fixed when the returning default is changed
        if return_type is None:
            return_type = "dict"

        assert isinstance(returned, types[return_type])
        if return_type == "both":
            assert isinstance(returned.ax, Axes)
            assert isinstance(returned.lines, dict)
    else:
        # should be fixed when the returning default is changed
        if return_type is None:
            for r in _flatten_visible(returned):
                assert isinstance(r, Axes)
            return

        assert isinstance(returned, Series)

        assert sorted(returned.keys()) == sorted(expected_keys)
        for key, value in returned.items():
            assert isinstance(value, types[return_type])
            # check returned dict has correct mapping
            if return_type == "axes":
                if check_ax_title:
                    assert value.get_title() == key
            elif return_type == "both":
                if check_ax_title:
                    assert value.ax.get_title() == key
                assert isinstance(value.ax, Axes)
                assert isinstance(value.lines, dict)
            elif return_type == "dict":
                line = value["medians"][0]
                axes = line.axes
                if check_ax_title:
                    assert axes.get_title() == key
            else:
                raise AssertionError


def _check_grid_settings(obj, kinds, kws={}):
    # Make sure plot defaults to rcParams['axes.grid'] setting, GH 9792

    import matplotlib as mpl

    def is_grid_on():
        xticks = mpl.pyplot.gca().xaxis.get_major_ticks()
        yticks = mpl.pyplot.gca().yaxis.get_major_ticks()
        xoff = all(not g.gridline.get_visible() for g in xticks)
        yoff = all(not g.gridline.get_visible() for g in yticks)

        return not (xoff and yoff)

    spndx = 1
    for kind in kinds:
        mpl.pyplot.subplot(1, 4 * len(kinds), spndx)
        spndx += 1
        mpl.rc("axes", grid=False)
        obj.plot(kind=kind, **kws)
        assert not is_grid_on()
        mpl.pyplot.clf()

        mpl.pyplot.subplot(1, 4 * len(kinds), spndx)
        spndx += 1
        mpl.rc("axes", grid=True)
        obj.plot(kind=kind, grid=False, **kws)
        assert not is_grid_on()
        mpl.pyplot.clf()

        if kind not in ["pie", "hexbin", "scatter"]:
            mpl.pyplot.subplot(1, 4 * len(kinds), spndx)
            spndx += 1
            mpl.rc("axes", grid=True)
            obj.plot(kind=kind, **kws)
            assert is_grid_on()
            mpl.pyplot.clf()

            mpl.pyplot.subplot(1, 4 * len(kinds), spndx)
            spndx += 1
            mpl.rc("axes", grid=False)
            obj.plot(kind=kind, grid=True, **kws)
            assert is_grid_on()
            mpl.pyplot.clf()


def _unpack_cycler(rcParams, field="color"):
    """
    Auxiliary function for correctly unpacking cycler after MPL >= 1.5
    """
    return [v[field] for v in rcParams["axes.prop_cycle"]]


def get_x_axis(ax):
    return ax._shared_axes["x"]


def get_y_axis(ax):
    return ax._shared_axes["y"]


def _check_plot_works(f, default_axes=False, **kwargs):
    """
    Create plot and ensure that plot return object is valid.

    Parameters
    ----------
    f : func
        Plotting function.
    default_axes : bool, optional
        If False (default):
            - If `ax` not in `kwargs`, then create subplot(211) and plot there
            - Create new subplot(212) and plot there as well
            - Mind special corner case for bootstrap_plot (see `_gen_two_subplots`)
        If True:
            - Simply run plotting function with kwargs provided
            - All required axes instances will be created automatically
            - It is recommended to use it when the plotting function
            creates multiple axes itself. It helps avoid warnings like
            'UserWarning: To output multiple subplots,
            the figure containing the passed axes is being cleared'
    **kwargs
        Keyword arguments passed to the plotting function.

    Returns
    -------
    Plot object returned by the last plotting.
    """
    import matplotlib.pyplot as plt

    if default_axes:
        gen_plots = _gen_default_plot
    else:
        gen_plots = _gen_two_subplots

    ret = None
    try:
        fig = kwargs.get("figure", plt.gcf())
        plt.clf()

        for ret in gen_plots(f, fig, **kwargs):
            tm.assert_is_valid_plot_return_object(ret)

    finally:
        plt.close(fig)

    return ret


def _gen_default_plot(f, fig, **kwargs):
    """
    Create plot in a default way.
    """
    yield f(**kwargs)


def _gen_two_subplots(f, fig, **kwargs):
    """
    Create plot on two subplots forcefully created.
    """
    if "ax" not in kwargs:
        fig.add_subplot(211)
    yield f(**kwargs)

    if f is pd.plotting.bootstrap_plot:
        assert "ax" not in kwargs
    else:
        kwargs["ax"] = fig.add_subplot(212)
    yield f(**kwargs)