from typing import TYPE_CHECKING, List, Optional, Tuple import warnings from matplotlib.artist import Artist import numpy as np from pandas._typing import Label from pandas.errors import AbstractMethodError from pandas.util._decorators import cache_readonly from pandas.core.dtypes.common import ( is_extension_array_dtype, is_float, is_float_dtype, is_hashable, is_integer, is_integer_dtype, is_iterator, is_list_like, is_number, is_numeric_dtype, ) from pandas.core.dtypes.generic import ( ABCDataFrame, ABCIndexClass, ABCMultiIndex, ABCPeriodIndex, ABCSeries, ) from pandas.core.dtypes.missing import isna, notna import pandas.core.common as com from pandas.io.formats.printing import pprint_thing from pandas.plotting._matplotlib.compat import mpl_ge_3_0_0 from pandas.plotting._matplotlib.converter import register_pandas_matplotlib_converters from pandas.plotting._matplotlib.style import get_standard_colors from pandas.plotting._matplotlib.timeseries import ( decorate_axes, format_dateaxis, maybe_convert_index, maybe_resample, use_dynamic_x, ) from pandas.plotting._matplotlib.tools import ( create_subplots, flatten_axes, format_date_labels, get_all_lines, get_xlim, handle_shared_axes, table, ) if TYPE_CHECKING: from matplotlib.axes import Axes from matplotlib.axis import Axis def _color_in_style(style: str) -> bool: """ Check if there is a color letter in the style string. """ from matplotlib.colors import BASE_COLORS return not set(BASE_COLORS).isdisjoint(style) class MPLPlot: """ Base class for assembling a pandas plot using matplotlib Parameters ---------- data : """ @property def _kind(self): """Specify kind str. Must be overridden in child class""" raise NotImplementedError _layout_type = "vertical" _default_rot = 0 orientation: Optional[str] = None axes: np.ndarray # of Axes objects def __init__( self, data, kind=None, by=None, subplots=False, sharex=None, sharey=False, use_index=True, figsize=None, grid=None, legend=True, rot=None, ax=None, fig=None, title=None, xlim=None, ylim=None, xticks=None, yticks=None, xlabel: Optional[Label] = None, ylabel: Optional[Label] = None, sort_columns=False, fontsize=None, secondary_y=False, colormap=None, table=False, layout=None, include_bool=False, **kwds, ): import matplotlib.pyplot as plt self.data = data self.by = by self.kind = kind self.sort_columns = sort_columns self.subplots = subplots if sharex is None: if ax is None: self.sharex = True else: # if we get an axis, the users should do the visibility # setting... self.sharex = False else: self.sharex = sharex self.sharey = sharey self.figsize = figsize self.layout = layout self.xticks = xticks self.yticks = yticks self.xlim = xlim self.ylim = ylim self.title = title self.use_index = use_index self.xlabel = xlabel self.ylabel = ylabel self.fontsize = fontsize if rot is not None: self.rot = rot # need to know for format_date_labels since it's rotated to 30 by # default self._rot_set = True else: self._rot_set = False self.rot = self._default_rot if grid is None: grid = False if secondary_y else plt.rcParams["axes.grid"] self.grid = grid self.legend = legend self.legend_handles: List[Artist] = [] self.legend_labels: List[Label] = [] self.logx = kwds.pop("logx", False) self.logy = kwds.pop("logy", False) self.loglog = kwds.pop("loglog", False) self.label = kwds.pop("label", None) self.style = kwds.pop("style", None) self.mark_right = kwds.pop("mark_right", True) self.stacked = kwds.pop("stacked", False) self.ax = ax self.fig = fig self.axes = np.array([], dtype=object) # "real" version get set in `generate` # parse errorbar input if given xerr = kwds.pop("xerr", None) yerr = kwds.pop("yerr", None) self.errors = { kw: self._parse_errorbars(kw, err) for kw, err in zip(["xerr", "yerr"], [xerr, yerr]) } if not isinstance(secondary_y, (bool, tuple, list, np.ndarray, ABCIndexClass)): secondary_y = [secondary_y] self.secondary_y = secondary_y # ugly TypeError if user passes matplotlib's `cmap` name. # Probably better to accept either. if "cmap" in kwds and colormap: raise TypeError("Only specify one of `cmap` and `colormap`.") elif "cmap" in kwds: self.colormap = kwds.pop("cmap") else: self.colormap = colormap self.table = table self.include_bool = include_bool self.kwds = kwds self._validate_color_args() def _validate_color_args(self): if ( "color" in self.kwds and self.nseries == 1 and not is_list_like(self.kwds["color"]) ): # support series.plot(color='green') self.kwds["color"] = [self.kwds["color"]] if ( "color" in self.kwds and isinstance(self.kwds["color"], tuple) and self.nseries == 1 and len(self.kwds["color"]) in (3, 4) ): # support RGB and RGBA tuples in series plot self.kwds["color"] = [self.kwds["color"]] if ( "color" in self.kwds or "colors" in self.kwds ) and self.colormap is not None: warnings.warn( "'color' and 'colormap' cannot be used simultaneously. Using 'color'" ) if "color" in self.kwds and self.style is not None: if is_list_like(self.style): styles = self.style else: styles = [self.style] # need only a single match for s in styles: if _color_in_style(s): raise ValueError( "Cannot pass 'style' string with a color symbol and " "'color' keyword argument. Please use one or the " "other or pass 'style' without a color symbol" ) def _iter_data(self, data=None, keep_index=False, fillna=None): if data is None: data = self.data if fillna is not None: data = data.fillna(fillna) for col, values in data.items(): if keep_index is True: yield col, values else: yield col, values.values @property def nseries(self) -> int: if self.data.ndim == 1: return 1 else: return self.data.shape[1] def draw(self): self.plt.draw_if_interactive() def generate(self): self._args_adjust() self._compute_plot_data() self._setup_subplots() self._make_plot() self._add_table() self._make_legend() self._adorn_subplots() for ax in self.axes: self._post_plot_logic_common(ax, self.data) self._post_plot_logic(ax, self.data) def _args_adjust(self): pass def _has_plotted_object(self, ax: "Axes") -> bool: """check whether ax has data""" return len(ax.lines) != 0 or len(ax.artists) != 0 or len(ax.containers) != 0 def _maybe_right_yaxis(self, ax: "Axes", axes_num): if not self.on_right(axes_num): # secondary axes may be passed via ax kw return self._get_ax_layer(ax) if hasattr(ax, "right_ax"): # if it has right_ax property, ``ax`` must be left axes return ax.right_ax elif hasattr(ax, "left_ax"): # if it has left_ax property, ``ax`` must be right axes return ax else: # otherwise, create twin axes orig_ax, new_ax = ax, ax.twinx() # TODO: use Matplotlib public API when available new_ax._get_lines = orig_ax._get_lines new_ax._get_patches_for_fill = orig_ax._get_patches_for_fill orig_ax.right_ax, new_ax.left_ax = new_ax, orig_ax if not self._has_plotted_object(orig_ax): # no data on left y orig_ax.get_yaxis().set_visible(False) if self.logy is True or self.loglog is True: new_ax.set_yscale("log") elif self.logy == "sym" or self.loglog == "sym": new_ax.set_yscale("symlog") return new_ax def _setup_subplots(self): if self.subplots: fig, axes = create_subplots( naxes=self.nseries, sharex=self.sharex, sharey=self.sharey, figsize=self.figsize, ax=self.ax, layout=self.layout, layout_type=self._layout_type, ) else: if self.ax is None: fig = self.plt.figure(figsize=self.figsize) axes = fig.add_subplot(111) else: fig = self.ax.get_figure() if self.figsize is not None: fig.set_size_inches(self.figsize) axes = self.ax axes = flatten_axes(axes) valid_log = {False, True, "sym", None} input_log = {self.logx, self.logy, self.loglog} if input_log - valid_log: invalid_log = next(iter(input_log - valid_log)) raise ValueError( f"Boolean, None and 'sym' are valid options, '{invalid_log}' is given." ) if self.logx is True or self.loglog is True: [a.set_xscale("log") for a in axes] elif self.logx == "sym" or self.loglog == "sym": [a.set_xscale("symlog") for a in axes] if self.logy is True or self.loglog is True: [a.set_yscale("log") for a in axes] elif self.logy == "sym" or self.loglog == "sym": [a.set_yscale("symlog") for a in axes] self.fig = fig self.axes = axes @property def result(self): """ Return result axes """ if self.subplots: if self.layout is not None and not is_list_like(self.ax): return self.axes.reshape(*self.layout) else: return self.axes else: sec_true = isinstance(self.secondary_y, bool) and self.secondary_y all_sec = ( is_list_like(self.secondary_y) and len(self.secondary_y) == self.nseries ) if sec_true or all_sec: # if all data is plotted on secondary, return right axes return self._get_ax_layer(self.axes[0], primary=False) else: return self.axes[0] def _convert_to_ndarray(self, data): # GH32073: cast to float if values contain nulled integers if ( is_integer_dtype(data.dtype) or is_float_dtype(data.dtype) ) and is_extension_array_dtype(data.dtype): return data.to_numpy(dtype="float", na_value=np.nan) # GH25587: cast ExtensionArray of pandas (IntegerArray, etc.) to # np.ndarray before plot. if len(data) > 0: return np.asarray(data) return data def _compute_plot_data(self): data = self.data if isinstance(data, ABCSeries): label = self.label if label is None and data.name is None: label = "None" data = data.to_frame(name=label) # GH16953, _convert is needed as fallback, for ``Series`` # with ``dtype == object`` data = data._convert(datetime=True, timedelta=True) include_type = [np.number, "datetime", "datetimetz", "timedelta"] # GH23719, allow plotting boolean if self.include_bool is True: include_type.append(np.bool_) # GH22799, exclude datetime-like type for boxplot exclude_type = None if self._kind == "box": # TODO: change after solving issue 27881 include_type = [np.number] exclude_type = ["timedelta"] # GH 18755, include object and category type for scatter plot if self._kind == "scatter": include_type.extend(["object", "category"]) numeric_data = data.select_dtypes(include=include_type, exclude=exclude_type) try: is_empty = numeric_data.columns.empty except AttributeError: is_empty = not len(numeric_data) # no non-numeric frames or series allowed if is_empty: raise TypeError("no numeric data to plot") self.data = numeric_data.apply(self._convert_to_ndarray) def _make_plot(self): raise AbstractMethodError(self) def _add_table(self): if self.table is False: return elif self.table is True: data = self.data.transpose() else: data = self.table ax = self._get_ax(0) table(ax, data) def _post_plot_logic_common(self, ax, data): """Common post process for each axes""" if self.orientation == "vertical" or self.orientation is None: self._apply_axis_properties(ax.xaxis, rot=self.rot, fontsize=self.fontsize) self._apply_axis_properties(ax.yaxis, fontsize=self.fontsize) if hasattr(ax, "right_ax"): self._apply_axis_properties(ax.right_ax.yaxis, fontsize=self.fontsize) elif self.orientation == "horizontal": self._apply_axis_properties(ax.yaxis, rot=self.rot, fontsize=self.fontsize) self._apply_axis_properties(ax.xaxis, fontsize=self.fontsize) if hasattr(ax, "right_ax"): self._apply_axis_properties(ax.right_ax.yaxis, fontsize=self.fontsize) else: # pragma no cover raise ValueError def _post_plot_logic(self, ax, data): """Post process for each axes. Overridden in child classes""" pass def _adorn_subplots(self): """Common post process unrelated to data""" if len(self.axes) > 0: all_axes = self._get_subplots() nrows, ncols = self._get_axes_layout() handle_shared_axes( axarr=all_axes, nplots=len(all_axes), naxes=nrows * ncols, nrows=nrows, ncols=ncols, sharex=self.sharex, sharey=self.sharey, ) for ax in self.axes: if self.yticks is not None: ax.set_yticks(self.yticks) if self.xticks is not None: ax.set_xticks(self.xticks) if self.ylim is not None: ax.set_ylim(self.ylim) if self.xlim is not None: ax.set_xlim(self.xlim) # GH9093, currently Pandas does not show ylabel, so if users provide # ylabel will set it as ylabel in the plot. if self.ylabel is not None: ax.set_ylabel(pprint_thing(self.ylabel)) ax.grid(self.grid) if self.title: if self.subplots: if is_list_like(self.title): if len(self.title) != self.nseries: raise ValueError( "The length of `title` must equal the number " "of columns if using `title` of type `list` " "and `subplots=True`.\n" f"length of title = {len(self.title)}\n" f"number of columns = {self.nseries}" ) for (ax, title) in zip(self.axes, self.title): ax.set_title(title) else: self.fig.suptitle(self.title) else: if is_list_like(self.title): msg = ( "Using `title` of type `list` is not supported " "unless `subplots=True` is passed" ) raise ValueError(msg) self.axes[0].set_title(self.title) def _apply_axis_properties(self, axis: "Axis", rot=None, fontsize=None): """ Tick creation within matplotlib is reasonably expensive and is internally deferred until accessed as Ticks are created/destroyed multiple times per draw. It's therefore beneficial for us to avoid accessing unless we will act on the Tick. """ if rot is not None or fontsize is not None: # rot=0 is a valid setting, hence the explicit None check labels = axis.get_majorticklabels() + axis.get_minorticklabels() for label in labels: if rot is not None: label.set_rotation(rot) if fontsize is not None: label.set_fontsize(fontsize) @property def legend_title(self) -> Optional[str]: if not isinstance(self.data.columns, ABCMultiIndex): name = self.data.columns.name if name is not None: name = pprint_thing(name) return name else: stringified = map(pprint_thing, self.data.columns.names) return ",".join(stringified) def _add_legend_handle(self, handle, label, index=None): if label is not None: if self.mark_right and index is not None: if self.on_right(index): label = label + " (right)" self.legend_handles.append(handle) self.legend_labels.append(label) def _make_legend(self): ax, leg, handle = self._get_ax_legend_handle(self.axes[0]) handles = [] labels = [] title = "" if not self.subplots: if leg is not None: title = leg.get_title().get_text() # Replace leg.LegendHandles because it misses marker info handles.extend(handle) labels = [x.get_text() for x in leg.get_texts()] if self.legend: if self.legend == "reverse": # pandas\plotting\_matplotlib\core.py:578: error: # Incompatible types in assignment (expression has type # "Iterator[Any]", variable has type "List[Any]") # [assignment] self.legend_handles = reversed( # type: ignore[assignment] self.legend_handles ) # pandas\plotting\_matplotlib\core.py:579: error: # Incompatible types in assignment (expression has type # "Iterator[Optional[Hashable]]", variable has type # "List[Optional[Hashable]]") [assignment] self.legend_labels = reversed( # type: ignore[assignment] self.legend_labels ) handles += self.legend_handles labels += self.legend_labels if self.legend_title is not None: title = self.legend_title if len(handles) > 0: ax.legend(handles, labels, loc="best", title=title) elif self.subplots and self.legend: for ax in self.axes: if ax.get_visible(): ax.legend(loc="best") def _get_ax_legend_handle(self, ax: "Axes"): """ Take in axes and return ax, legend and handle under different scenarios """ leg = ax.get_legend() # Get handle from axes handle, _ = ax.get_legend_handles_labels() other_ax = getattr(ax, "left_ax", None) or getattr(ax, "right_ax", None) other_leg = None if other_ax is not None: other_leg = other_ax.get_legend() if leg is None and other_leg is not None: leg = other_leg ax = other_ax return ax, leg, handle @cache_readonly def plt(self): import matplotlib.pyplot as plt return plt _need_to_set_index = False def _get_xticks(self, convert_period: bool = False): index = self.data.index is_datetype = index.inferred_type in ("datetime", "date", "datetime64", "time") if self.use_index: if convert_period and isinstance(index, ABCPeriodIndex): self.data = self.data.reindex(index=index.sort_values()) x = self.data.index.to_timestamp()._mpl_repr() elif index.is_numeric(): """ Matplotlib supports numeric values or datetime objects as xaxis values. Taking LBYL approach here, by the time matplotlib raises exception when using non numeric/datetime values for xaxis, several actions are already taken by plt. """ x = index._mpl_repr() elif is_datetype: self.data = self.data[notna(self.data.index)] self.data = self.data.sort_index() x = self.data.index._mpl_repr() else: self._need_to_set_index = True x = list(range(len(index))) else: x = list(range(len(index))) return x @classmethod @register_pandas_matplotlib_converters def _plot(cls, ax: "Axes", x, y, style=None, is_errorbar: bool = False, **kwds): mask = isna(y) if mask.any(): y = np.ma.array(y) y = np.ma.masked_where(mask, y) if isinstance(x, ABCIndexClass): x = x._mpl_repr() if is_errorbar: if "xerr" in kwds: kwds["xerr"] = np.array(kwds.get("xerr")) if "yerr" in kwds: kwds["yerr"] = np.array(kwds.get("yerr")) return ax.errorbar(x, y, **kwds) else: # prevent style kwarg from going to errorbar, where it is # unsupported if style is not None: args = (x, y, style) else: args = (x, y) # type: ignore[assignment] return ax.plot(*args, **kwds) def _get_index_name(self) -> Optional[str]: if isinstance(self.data.index, ABCMultiIndex): name = self.data.index.names if com.any_not_none(*name): name = ",".join(pprint_thing(x) for x in name) else: name = None else: name = self.data.index.name if name is not None: name = pprint_thing(name) # GH 9093, override the default xlabel if xlabel is provided. if self.xlabel is not None: name = pprint_thing(self.xlabel) return name @classmethod def _get_ax_layer(cls, ax, primary=True): """get left (primary) or right (secondary) axes""" if primary: return getattr(ax, "left_ax", ax) else: return getattr(ax, "right_ax", ax) def _get_ax(self, i: int): # get the twinx ax if appropriate if self.subplots: ax = self.axes[i] ax = self._maybe_right_yaxis(ax, i) self.axes[i] = ax else: ax = self.axes[0] ax = self._maybe_right_yaxis(ax, i) ax.get_yaxis().set_visible(True) return ax @classmethod def get_default_ax(cls, ax): import matplotlib.pyplot as plt if ax is None and len(plt.get_fignums()) > 0: with plt.rc_context(): ax = plt.gca() ax = cls._get_ax_layer(ax) def on_right(self, i): if isinstance(self.secondary_y, bool): return self.secondary_y if isinstance(self.secondary_y, (tuple, list, np.ndarray, ABCIndexClass)): return self.data.columns[i] in self.secondary_y def _apply_style_colors(self, colors, kwds, col_num, label): """ Manage style and color based on column number and its label. Returns tuple of appropriate style and kwds which "color" may be added. """ style = None if self.style is not None: if isinstance(self.style, list): try: style = self.style[col_num] except IndexError: pass elif isinstance(self.style, dict): style = self.style.get(label, style) else: style = self.style has_color = "color" in kwds or self.colormap is not None nocolor_style = style is None or not _color_in_style(style) if (has_color or self.subplots) and nocolor_style: if isinstance(colors, dict): kwds["color"] = colors[label] else: kwds["color"] = colors[col_num % len(colors)] return style, kwds def _get_colors(self, num_colors=None, color_kwds="color"): if num_colors is None: num_colors = self.nseries return get_standard_colors( num_colors=num_colors, colormap=self.colormap, color=self.kwds.get(color_kwds), ) def _parse_errorbars(self, label, err): """ Look for error keyword arguments and return the actual errorbar data or return the error DataFrame/dict Error bars can be specified in several ways: Series: the user provides a pandas.Series object of the same length as the data ndarray: provides a np.ndarray of the same length as the data DataFrame/dict: error values are paired with keys matching the key in the plotted DataFrame str: the name of the column within the plotted DataFrame Asymmetrical error bars are also supported, however raw error values must be provided in this case. For a ``N`` length :class:`Series`, a ``2xN`` array should be provided indicating lower and upper (or left and right) errors. For a ``MxN`` :class:`DataFrame`, asymmetrical errors should be in a ``Mx2xN`` array. """ if err is None: return None def match_labels(data, e): e = e.reindex(data.index) return e # key-matched DataFrame if isinstance(err, ABCDataFrame): err = match_labels(self.data, err) # key-matched dict elif isinstance(err, dict): pass # Series of error values elif isinstance(err, ABCSeries): # broadcast error series across data err = match_labels(self.data, err) err = np.atleast_2d(err) err = np.tile(err, (self.nseries, 1)) # errors are a column in the dataframe elif isinstance(err, str): evalues = self.data[err].values self.data = self.data[self.data.columns.drop(err)] err = np.atleast_2d(evalues) err = np.tile(err, (self.nseries, 1)) elif is_list_like(err): if is_iterator(err): err = np.atleast_2d(list(err)) else: # raw error values err = np.atleast_2d(err) err_shape = err.shape # asymmetrical error bars if isinstance(self.data, ABCSeries) and err_shape[0] == 2: err = np.expand_dims(err, 0) err_shape = err.shape if err_shape[2] != len(self.data): raise ValueError( "Asymmetrical error bars should be provided " f"with the shape (2, {len(self.data)})" ) elif isinstance(self.data, ABCDataFrame) and err.ndim == 3: if ( (err_shape[0] != self.nseries) or (err_shape[1] != 2) or (err_shape[2] != len(self.data)) ): raise ValueError( "Asymmetrical error bars should be provided " f"with the shape ({self.nseries}, 2, {len(self.data)})" ) # broadcast errors to each data series if len(err) == 1: err = np.tile(err, (self.nseries, 1)) elif is_number(err): err = np.tile([err], (self.nseries, len(self.data))) else: msg = f"No valid {label} detected" raise ValueError(msg) return err def _get_errorbars(self, label=None, index=None, xerr=True, yerr=True): errors = {} for kw, flag in zip(["xerr", "yerr"], [xerr, yerr]): if flag: err = self.errors[kw] # user provided label-matched dataframe of errors if isinstance(err, (ABCDataFrame, dict)): if label is not None and label in err.keys(): err = err[label] else: err = None elif index is not None and err is not None: err = err[index] if err is not None: errors[kw] = err return errors def _get_subplots(self): from matplotlib.axes import Subplot return [ ax for ax in self.axes[0].get_figure().get_axes() if isinstance(ax, Subplot) ] def _get_axes_layout(self) -> Tuple[int, int]: axes = self._get_subplots() x_set = set() y_set = set() for ax in 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]) return (len(y_set), len(x_set)) class PlanePlot(MPLPlot): """ Abstract class for plotting on plane, currently scatter and hexbin. """ _layout_type = "single" def __init__(self, data, x, y, **kwargs): MPLPlot.__init__(self, data, **kwargs) if x is None or y is None: raise ValueError(self._kind + " requires an x and y column") if is_integer(x) and not self.data.columns.holds_integer(): x = self.data.columns[x] if is_integer(y) and not self.data.columns.holds_integer(): y = self.data.columns[y] # Scatter plot allows to plot objects data if self._kind == "hexbin": if len(self.data[x]._get_numeric_data()) == 0: raise ValueError(self._kind + " requires x column to be numeric") if len(self.data[y]._get_numeric_data()) == 0: raise ValueError(self._kind + " requires y column to be numeric") self.x = x self.y = y @property def nseries(self) -> int: return 1 def _post_plot_logic(self, ax: "Axes", data): x, y = self.x, self.y xlabel = self.xlabel if self.xlabel is not None else pprint_thing(x) ylabel = self.ylabel if self.ylabel is not None else pprint_thing(y) ax.set_xlabel(xlabel) ax.set_ylabel(ylabel) def _plot_colorbar(self, ax: "Axes", **kwds): # Addresses issues #10611 and #10678: # When plotting scatterplots and hexbinplots in IPython # inline backend the colorbar axis height tends not to # exactly match the parent axis height. # The difference is due to small fractional differences # in floating points with similar representation. # To deal with this, this method forces the colorbar # height to take the height of the parent axes. # For a more detailed description of the issue # see the following link: # https://github.com/ipython/ipython/issues/11215 # GH33389, if ax is used multiple times, we should always # use the last one which contains the latest information # about the ax img = ax.collections[-1] cbar = self.fig.colorbar(img, ax=ax, **kwds) if mpl_ge_3_0_0(): # The workaround below is no longer necessary. return points = ax.get_position().get_points() cbar_points = cbar.ax.get_position().get_points() cbar.ax.set_position( [ cbar_points[0, 0], points[0, 1], cbar_points[1, 0] - cbar_points[0, 0], points[1, 1] - points[0, 1], ] ) # To see the discrepancy in axis heights uncomment # the following two lines: # print(points[1, 1] - points[0, 1]) # print(cbar_points[1, 1] - cbar_points[0, 1]) class ScatterPlot(PlanePlot): _kind = "scatter" def __init__(self, data, x, y, s=None, c=None, **kwargs): if s is None: # hide the matplotlib default for size, in case we want to change # the handling of this argument later s = 20 elif is_hashable(s) and s in data.columns: s = data[s] super().__init__(data, x, y, s=s, **kwargs) if is_integer(c) and not self.data.columns.holds_integer(): c = self.data.columns[c] self.c = c def _make_plot(self): x, y, c, data = self.x, self.y, self.c, self.data ax = self.axes[0] c_is_column = is_hashable(c) and c in self.data.columns # pandas uses colormap, matplotlib uses cmap. cmap = self.colormap or "Greys" cmap = self.plt.cm.get_cmap(cmap) color = self.kwds.pop("color", None) if c is not None and color is not None: raise TypeError("Specify exactly one of `c` and `color`") elif c is None and color is None: c_values = self.plt.rcParams["patch.facecolor"] elif color is not None: c_values = color elif c_is_column: c_values = self.data[c].values else: c_values = c # plot colorbar if # 1. colormap is assigned, and # 2.`c` is a column containing only numeric values plot_colorbar = self.colormap or c_is_column cb = self.kwds.pop("colorbar", is_numeric_dtype(c_values) and plot_colorbar) if self.legend and hasattr(self, "label"): label = self.label else: label = None scatter = ax.scatter( data[x].values, data[y].values, c=c_values, label=label, cmap=cmap, **self.kwds, ) if cb: cbar_label = c if c_is_column else "" self._plot_colorbar(ax, label=cbar_label) if label is not None: self._add_legend_handle(scatter, label) else: self.legend = False errors_x = self._get_errorbars(label=x, index=0, yerr=False) errors_y = self._get_errorbars(label=y, index=0, xerr=False) if len(errors_x) > 0 or len(errors_y) > 0: err_kwds = dict(errors_x, **errors_y) err_kwds["ecolor"] = scatter.get_facecolor()[0] ax.errorbar(data[x].values, data[y].values, linestyle="none", **err_kwds) class HexBinPlot(PlanePlot): _kind = "hexbin" def __init__(self, data, x, y, C=None, **kwargs): super().__init__(data, x, y, **kwargs) if is_integer(C) and not self.data.columns.holds_integer(): C = self.data.columns[C] self.C = C def _make_plot(self): x, y, data, C = self.x, self.y, self.data, self.C ax = self.axes[0] # pandas uses colormap, matplotlib uses cmap. cmap = self.colormap or "BuGn" cmap = self.plt.cm.get_cmap(cmap) cb = self.kwds.pop("colorbar", True) if C is None: c_values = None else: c_values = data[C].values ax.hexbin(data[x].values, data[y].values, C=c_values, cmap=cmap, **self.kwds) if cb: self._plot_colorbar(ax) def _make_legend(self): pass class LinePlot(MPLPlot): _kind = "line" _default_rot = 0 orientation = "vertical" def __init__(self, data, **kwargs): from pandas.plotting import plot_params MPLPlot.__init__(self, data, **kwargs) if self.stacked: self.data = self.data.fillna(value=0) self.x_compat = plot_params["x_compat"] if "x_compat" in self.kwds: self.x_compat = bool(self.kwds.pop("x_compat")) def _is_ts_plot(self) -> bool: # this is slightly deceptive return not self.x_compat and self.use_index and self._use_dynamic_x() def _use_dynamic_x(self): return use_dynamic_x(self._get_ax(0), self.data) def _make_plot(self): if self._is_ts_plot(): data = maybe_convert_index(self._get_ax(0), self.data) x = data.index # dummy, not used plotf = self._ts_plot it = self._iter_data(data=data, keep_index=True) else: x = self._get_xticks(convert_period=True) # pandas\plotting\_matplotlib\core.py:1100: error: Incompatible # types in assignment (expression has type "Callable[[Any, Any, # Any, Any, Any, Any, KwArg(Any)], Any]", variable has type # "Callable[[Any, Any, Any, Any, KwArg(Any)], Any]") [assignment] plotf = self._plot # type: ignore[assignment] it = self._iter_data() stacking_id = self._get_stacking_id() is_errorbar = com.any_not_none(*self.errors.values()) colors = self._get_colors() for i, (label, y) in enumerate(it): ax = self._get_ax(i) kwds = self.kwds.copy() style, kwds = self._apply_style_colors(colors, kwds, i, label) errors = self._get_errorbars(label=label, index=i) kwds = dict(kwds, **errors) label = pprint_thing(label) # .encode('utf-8') kwds["label"] = label newlines = plotf( ax, x, y, style=style, column_num=i, stacking_id=stacking_id, is_errorbar=is_errorbar, **kwds, ) self._add_legend_handle(newlines[0], label, index=i) if self._is_ts_plot(): # reset of xlim should be used for ts data # TODO: GH28021, should find a way to change view limit on xaxis lines = get_all_lines(ax) left, right = get_xlim(lines) ax.set_xlim(left, right) @classmethod def _plot( cls, ax: "Axes", x, y, style=None, column_num=None, stacking_id=None, **kwds ): # column_num is used to get the target column from plotf in line and # area plots if column_num == 0: cls._initialize_stacker(ax, stacking_id, len(y)) y_values = cls._get_stacked_values(ax, stacking_id, y, kwds["label"]) lines = MPLPlot._plot(ax, x, y_values, style=style, **kwds) cls._update_stacker(ax, stacking_id, y) return lines @classmethod def _ts_plot(cls, ax: "Axes", x, data, style=None, **kwds): # accept x to be consistent with normal plot func, # x is not passed to tsplot as it uses data.index as x coordinate # column_num must be in kwds for stacking purpose freq, data = maybe_resample(data, ax, kwds) # Set ax with freq info decorate_axes(ax, freq, kwds) # digging deeper if hasattr(ax, "left_ax"): decorate_axes(ax.left_ax, freq, kwds) if hasattr(ax, "right_ax"): decorate_axes(ax.right_ax, freq, kwds) ax._plot_data.append((data, cls._kind, kwds)) lines = cls._plot(ax, data.index, data.values, style=style, **kwds) # set date formatter, locators and rescale limits format_dateaxis(ax, ax.freq, data.index) return lines def _get_stacking_id(self): if self.stacked: return id(self.data) else: return None @classmethod def _initialize_stacker(cls, ax: "Axes", stacking_id, n: int): if stacking_id is None: return if not hasattr(ax, "_stacker_pos_prior"): ax._stacker_pos_prior = {} if not hasattr(ax, "_stacker_neg_prior"): ax._stacker_neg_prior = {} ax._stacker_pos_prior[stacking_id] = np.zeros(n) ax._stacker_neg_prior[stacking_id] = np.zeros(n) @classmethod def _get_stacked_values(cls, ax: "Axes", stacking_id, values, label): if stacking_id is None: return values if not hasattr(ax, "_stacker_pos_prior"): # stacker may not be initialized for subplots cls._initialize_stacker(ax, stacking_id, len(values)) if (values >= 0).all(): return ax._stacker_pos_prior[stacking_id] + values elif (values <= 0).all(): return ax._stacker_neg_prior[stacking_id] + values raise ValueError( "When stacked is True, each column must be either " "all positive or negative." f"{label} contains both positive and negative values" ) @classmethod def _update_stacker(cls, ax: "Axes", stacking_id, values): if stacking_id is None: return if (values >= 0).all(): ax._stacker_pos_prior[stacking_id] += values elif (values <= 0).all(): ax._stacker_neg_prior[stacking_id] += values def _post_plot_logic(self, ax: "Axes", data): from matplotlib.ticker import FixedLocator def get_label(i): if is_float(i) and i.is_integer(): i = int(i) try: return pprint_thing(data.index[i]) except Exception: return "" if self._need_to_set_index: xticks = ax.get_xticks() xticklabels = [get_label(x) for x in xticks] ax.xaxis.set_major_locator(FixedLocator(xticks)) ax.set_xticklabels(xticklabels) # If the index is an irregular time series, then by default # we rotate the tick labels. The exception is if there are # subplots which don't share their x-axes, in which we case # we don't rotate the ticklabels as by default the subplots # would be too close together. condition = ( not self._use_dynamic_x() and (data.index._is_all_dates and self.use_index) and (not self.subplots or (self.subplots and self.sharex)) ) index_name = self._get_index_name() if condition: # irregular TS rotated 30 deg. by default # probably a better place to check / set this. if not self._rot_set: self.rot = 30 format_date_labels(ax, rot=self.rot) if index_name is not None and self.use_index: ax.set_xlabel(index_name) class AreaPlot(LinePlot): _kind = "area" def __init__(self, data, **kwargs): kwargs.setdefault("stacked", True) data = data.fillna(value=0) LinePlot.__init__(self, data, **kwargs) if not self.stacked: # use smaller alpha to distinguish overlap self.kwds.setdefault("alpha", 0.5) if self.logy or self.loglog: raise ValueError("Log-y scales are not supported in area plot") @classmethod def _plot( cls, ax: "Axes", x, y, style=None, column_num=None, stacking_id=None, is_errorbar=False, **kwds, ): if column_num == 0: cls._initialize_stacker(ax, stacking_id, len(y)) y_values = cls._get_stacked_values(ax, stacking_id, y, kwds["label"]) # need to remove label, because subplots uses mpl legend as it is line_kwds = kwds.copy() line_kwds.pop("label") lines = MPLPlot._plot(ax, x, y_values, style=style, **line_kwds) # get data from the line to get coordinates for fill_between xdata, y_values = lines[0].get_data(orig=False) # unable to use ``_get_stacked_values`` here to get starting point if stacking_id is None: start = np.zeros(len(y)) elif (y >= 0).all(): start = ax._stacker_pos_prior[stacking_id] elif (y <= 0).all(): start = ax._stacker_neg_prior[stacking_id] else: start = np.zeros(len(y)) if "color" not in kwds: kwds["color"] = lines[0].get_color() rect = ax.fill_between(xdata, start, y_values, **kwds) cls._update_stacker(ax, stacking_id, y) # LinePlot expects list of artists res = [rect] return res def _post_plot_logic(self, ax: "Axes", data): LinePlot._post_plot_logic(self, ax, data) is_shared_y = len(list(ax.get_shared_y_axes())) > 0 # do not override the default axis behaviour in case of shared y axes if self.ylim is None and not is_shared_y: if (data >= 0).all().all(): ax.set_ylim(0, None) elif (data <= 0).all().all(): ax.set_ylim(None, 0) class BarPlot(MPLPlot): _kind = "bar" _default_rot = 90 orientation = "vertical" def __init__(self, data, **kwargs): # we have to treat a series differently than a # 1-column DataFrame w.r.t. color handling self._is_series = isinstance(data, ABCSeries) self.bar_width = kwargs.pop("width", 0.5) pos = kwargs.pop("position", 0.5) kwargs.setdefault("align", "center") self.tick_pos = np.arange(len(data)) self.bottom = kwargs.pop("bottom", 0) self.left = kwargs.pop("left", 0) self.log = kwargs.pop("log", False) MPLPlot.__init__(self, data, **kwargs) if self.stacked or self.subplots: self.tickoffset = self.bar_width * pos if kwargs["align"] == "edge": self.lim_offset = self.bar_width / 2 else: self.lim_offset = 0 else: if kwargs["align"] == "edge": w = self.bar_width / self.nseries self.tickoffset = self.bar_width * (pos - 0.5) + w * 0.5 self.lim_offset = w * 0.5 else: self.tickoffset = self.bar_width * pos self.lim_offset = 0 self.ax_pos = self.tick_pos - self.tickoffset def _args_adjust(self): if is_list_like(self.bottom): self.bottom = np.array(self.bottom) if is_list_like(self.left): self.left = np.array(self.left) @classmethod def _plot(cls, ax: "Axes", x, y, w, start=0, log=False, **kwds): return ax.bar(x, y, w, bottom=start, log=log, **kwds) @property def _start_base(self): return self.bottom def _make_plot(self): import matplotlib as mpl colors = self._get_colors() ncolors = len(colors) pos_prior = neg_prior = np.zeros(len(self.data)) K = self.nseries for i, (label, y) in enumerate(self._iter_data(fillna=0)): ax = self._get_ax(i) kwds = self.kwds.copy() if self._is_series: kwds["color"] = colors elif isinstance(colors, dict): kwds["color"] = colors[label] else: kwds["color"] = colors[i % ncolors] errors = self._get_errorbars(label=label, index=i) kwds = dict(kwds, **errors) label = pprint_thing(label) if (("yerr" in kwds) or ("xerr" in kwds)) and (kwds.get("ecolor") is None): kwds["ecolor"] = mpl.rcParams["xtick.color"] start = 0 if self.log and (y >= 1).all(): start = 1 start = start + self._start_base if self.subplots: w = self.bar_width / 2 rect = self._plot( ax, self.ax_pos + w, y, self.bar_width, start=start, label=label, log=self.log, **kwds, ) ax.set_title(label) elif self.stacked: mask = y > 0 start = np.where(mask, pos_prior, neg_prior) + self._start_base w = self.bar_width / 2 rect = self._plot( ax, self.ax_pos + w, y, self.bar_width, start=start, label=label, log=self.log, **kwds, ) pos_prior = pos_prior + np.where(mask, y, 0) neg_prior = neg_prior + np.where(mask, 0, y) else: w = self.bar_width / K rect = self._plot( ax, self.ax_pos + (i + 0.5) * w, y, w, start=start, label=label, log=self.log, **kwds, ) self._add_legend_handle(rect, label, index=i) def _post_plot_logic(self, ax: "Axes", data): if self.use_index: str_index = [pprint_thing(key) for key in data.index] else: str_index = [pprint_thing(key) for key in range(data.shape[0])] name = self._get_index_name() s_edge = self.ax_pos[0] - 0.25 + self.lim_offset e_edge = self.ax_pos[-1] + 0.25 + self.bar_width + self.lim_offset self._decorate_ticks(ax, name, str_index, s_edge, e_edge) def _decorate_ticks(self, ax: "Axes", name, ticklabels, start_edge, end_edge): ax.set_xlim((start_edge, end_edge)) if self.xticks is not None: ax.set_xticks(np.array(self.xticks)) else: ax.set_xticks(self.tick_pos) ax.set_xticklabels(ticklabels) if name is not None and self.use_index: ax.set_xlabel(name) class BarhPlot(BarPlot): _kind = "barh" _default_rot = 0 orientation = "horizontal" @property def _start_base(self): return self.left @classmethod def _plot(cls, ax: "Axes", x, y, w, start=0, log=False, **kwds): return ax.barh(x, y, w, left=start, log=log, **kwds) def _decorate_ticks(self, ax: "Axes", name, ticklabels, start_edge, end_edge): # horizontal bars ax.set_ylim((start_edge, end_edge)) ax.set_yticks(self.tick_pos) ax.set_yticklabels(ticklabels) if name is not None and self.use_index: ax.set_ylabel(name) class PiePlot(MPLPlot): _kind = "pie" _layout_type = "horizontal" def __init__(self, data, kind=None, **kwargs): data = data.fillna(value=0) if (data < 0).any().any(): raise ValueError(f"{kind} doesn't allow negative values") MPLPlot.__init__(self, data, kind=kind, **kwargs) def _args_adjust(self): self.grid = False self.logy = False self.logx = False self.loglog = False def _validate_color_args(self): pass def _make_plot(self): colors = self._get_colors(num_colors=len(self.data), color_kwds="colors") self.kwds.setdefault("colors", colors) for i, (label, y) in enumerate(self._iter_data()): ax = self._get_ax(i) if label is not None: label = pprint_thing(label) ax.set_ylabel(label) kwds = self.kwds.copy() def blank_labeler(label, value): if value == 0: return "" else: return label idx = [pprint_thing(v) for v in self.data.index] labels = kwds.pop("labels", idx) # labels is used for each wedge's labels # Blank out labels for values of 0 so they don't overlap # with nonzero wedges if labels is not None: blabels = [blank_labeler(left, value) for left, value in zip(labels, y)] else: # pandas\plotting\_matplotlib\core.py:1546: error: Incompatible # types in assignment (expression has type "None", variable has # type "List[Any]") [assignment] blabels = None # type: ignore[assignment] results = ax.pie(y, labels=blabels, **kwds) if kwds.get("autopct", None) is not None: patches, texts, autotexts = results else: patches, texts = results autotexts = [] if self.fontsize is not None: for t in texts + autotexts: t.set_fontsize(self.fontsize) # leglabels is used for legend labels leglabels = labels if labels is not None else idx for p, l in zip(patches, leglabels): self._add_legend_handle(p, l)