# being a bit too dynamic from math import ceil import warnings import matplotlib.table import matplotlib.ticker as ticker import numpy as np from pandas.core.dtypes.common import is_list_like from pandas.core.dtypes.generic import ABCDataFrame, ABCIndexClass, ABCSeries from pandas.plotting._matplotlib import compat def format_date_labels(ax, rot): # mini version of autofmt_xdate for label in ax.get_xticklabels(): label.set_ha("right") label.set_rotation(rot) fig = ax.get_figure() fig.subplots_adjust(bottom=0.2) def table(ax, data, rowLabels=None, colLabels=None, **kwargs): if isinstance(data, ABCSeries): data = data.to_frame() elif isinstance(data, ABCDataFrame): pass else: raise ValueError("Input data must be DataFrame or Series") if rowLabels is None: rowLabels = data.index if colLabels is None: colLabels = data.columns cellText = data.values table = matplotlib.table.table( ax, cellText=cellText, rowLabels=rowLabels, colLabels=colLabels, **kwargs ) return table def _get_layout(nplots, layout=None, layout_type="box"): if layout is not None: if not isinstance(layout, (tuple, list)) or len(layout) != 2: raise ValueError("Layout must be a tuple of (rows, columns)") nrows, ncols = layout # Python 2 compat ceil_ = lambda x: int(ceil(x)) if nrows == -1 and ncols > 0: layout = nrows, ncols = (ceil_(float(nplots) / ncols), ncols) elif ncols == -1 and nrows > 0: layout = nrows, ncols = (nrows, ceil_(float(nplots) / nrows)) elif ncols <= 0 and nrows <= 0: msg = "At least one dimension of layout must be positive" raise ValueError(msg) if nrows * ncols < nplots: raise ValueError( f"Layout of {nrows}x{ncols} must be larger than required size {nplots}" ) return layout if layout_type == "single": return (1, 1) elif layout_type == "horizontal": return (1, nplots) elif layout_type == "vertical": return (nplots, 1) layouts = {1: (1, 1), 2: (1, 2), 3: (2, 2), 4: (2, 2)} try: return layouts[nplots] except KeyError: k = 1 while k ** 2 < nplots: k += 1 if (k - 1) * k >= nplots: return k, (k - 1) else: return k, k # copied from matplotlib/pyplot.py and modified for pandas.plotting def _subplots( naxes=None, sharex=False, sharey=False, squeeze=True, subplot_kw=None, ax=None, layout=None, layout_type="box", **fig_kw, ): """ Create a figure with a set of subplots already made. This utility wrapper makes it convenient to create common layouts of subplots, including the enclosing figure object, in a single call. Parameters ---------- naxes : int Number of required axes. Exceeded axes are set invisible. Default is nrows * ncols. sharex : bool If True, the X axis will be shared amongst all subplots. sharey : bool If True, the Y axis will be shared amongst all subplots. squeeze : bool If True, extra dimensions are squeezed out from the returned axis object: - if only one subplot is constructed (nrows=ncols=1), the resulting single Axis object is returned as a scalar. - for Nx1 or 1xN subplots, the returned object is a 1-d numpy object array of Axis objects are returned as numpy 1-d arrays. - for NxM subplots with N>1 and M>1 are returned as a 2d array. If False, no squeezing is done: the returned axis object is always a 2-d array containing Axis instances, even if it ends up being 1x1. subplot_kw : dict Dict with keywords passed to the add_subplot() call used to create each subplots. ax : Matplotlib axis object, optional layout : tuple Number of rows and columns of the subplot grid. If not specified, calculated from naxes and layout_type layout_type : {'box', 'horizontal', 'vertical'}, default 'box' Specify how to layout the subplot grid. fig_kw : Other keyword arguments to be passed to the figure() call. Note that all keywords not recognized above will be automatically included here. Returns ------- fig, ax : tuple - fig is the Matplotlib Figure object - ax can be either a single axis object or an array of axis objects if more than one subplot was created. The dimensions of the resulting array can be controlled with the squeeze keyword, see above. Examples -------- x = np.linspace(0, 2*np.pi, 400) y = np.sin(x**2) # Just a figure and one subplot f, ax = plt.subplots() ax.plot(x, y) ax.set_title('Simple plot') # Two subplots, unpack the output array immediately f, (ax1, ax2) = plt.subplots(1, 2, sharey=True) ax1.plot(x, y) ax1.set_title('Sharing Y axis') ax2.scatter(x, y) # Four polar axes plt.subplots(2, 2, subplot_kw=dict(polar=True)) """ import matplotlib.pyplot as plt if subplot_kw is None: subplot_kw = {} if ax is None: fig = plt.figure(**fig_kw) else: if is_list_like(ax): ax = _flatten(ax) if layout is not None: warnings.warn( "When passing multiple axes, layout keyword is ignored", UserWarning ) if sharex or sharey: warnings.warn( "When passing multiple axes, sharex and sharey " "are ignored. These settings must be specified when creating axes", UserWarning, stacklevel=4, ) if len(ax) == naxes: fig = ax[0].get_figure() return fig, ax else: raise ValueError( f"The number of passed axes must be {naxes}, the " "same as the output plot" ) fig = ax.get_figure() # if ax is passed and a number of subplots is 1, return ax as it is if naxes == 1: if squeeze: return fig, ax else: return fig, _flatten(ax) else: warnings.warn( "To output multiple subplots, the figure containing " "the passed axes is being cleared", UserWarning, stacklevel=4, ) fig.clear() nrows, ncols = _get_layout(naxes, layout=layout, layout_type=layout_type) nplots = nrows * ncols # Create empty object array to hold all axes. It's easiest to make it 1-d # so we can just append subplots upon creation, and then axarr = np.empty(nplots, dtype=object) # Create first subplot separately, so we can share it if requested ax0 = fig.add_subplot(nrows, ncols, 1, **subplot_kw) if sharex: subplot_kw["sharex"] = ax0 if sharey: subplot_kw["sharey"] = ax0 axarr[0] = ax0 # Note off-by-one counting because add_subplot uses the MATLAB 1-based # convention. for i in range(1, nplots): kwds = subplot_kw.copy() # Set sharex and sharey to None for blank/dummy axes, these can # interfere with proper axis limits on the visible axes if # they share axes e.g. issue #7528 if i >= naxes: kwds["sharex"] = None kwds["sharey"] = None ax = fig.add_subplot(nrows, ncols, i + 1, **kwds) axarr[i] = ax if naxes != nplots: for ax in axarr[naxes:]: ax.set_visible(False) _handle_shared_axes(axarr, nplots, naxes, nrows, ncols, sharex, sharey) if squeeze: # Reshape the array to have the final desired dimension (nrow,ncol), # though discarding unneeded dimensions that equal 1. If we only have # one subplot, just return it instead of a 1-element array. if nplots == 1: axes = axarr[0] else: axes = axarr.reshape(nrows, ncols).squeeze() else: # returned axis array will be always 2-d, even if nrows=ncols=1 axes = axarr.reshape(nrows, ncols) return fig, axes def _remove_labels_from_axis(axis): for t in axis.get_majorticklabels(): t.set_visible(False) # set_visible will not be effective if # minor axis has NullLocator and NullFormatter (default) if isinstance(axis.get_minor_locator(), ticker.NullLocator): axis.set_minor_locator(ticker.AutoLocator()) if isinstance(axis.get_minor_formatter(), ticker.NullFormatter): axis.set_minor_formatter(ticker.FormatStrFormatter("")) for t in axis.get_minorticklabels(): t.set_visible(False) axis.get_label().set_visible(False) def _handle_shared_axes(axarr, nplots, naxes, nrows, ncols, sharex, sharey): if nplots > 1: if compat._mpl_ge_3_2_0(): row_num = lambda x: x.get_subplotspec().rowspan.start col_num = lambda x: x.get_subplotspec().colspan.start else: row_num = lambda x: x.rowNum col_num = lambda x: x.colNum if nrows > 1: try: # first find out the ax layout, # so that we can correctly handle 'gaps" layout = np.zeros((nrows + 1, ncols + 1), dtype=np.bool_) for ax in axarr: layout[row_num(ax), col_num(ax)] = ax.get_visible() for ax in axarr: # only the last row of subplots should get x labels -> all # other off layout handles the case that the subplot is # the last in the column, because below is no subplot/gap. if not layout[row_num(ax) + 1, col_num(ax)]: continue if sharex or len(ax.get_shared_x_axes().get_siblings(ax)) > 1: _remove_labels_from_axis(ax.xaxis) except IndexError: # if gridspec is used, ax.rowNum and ax.colNum may different # from layout shape. in this case, use last_row logic for ax in axarr: if ax.is_last_row(): continue if sharex or len(ax.get_shared_x_axes().get_siblings(ax)) > 1: _remove_labels_from_axis(ax.xaxis) if ncols > 1: for ax in axarr: # only the first column should get y labels -> set all other to # off as we only have labels in the first column and we always # have a subplot there, we can skip the layout test if ax.is_first_col(): continue if sharey or len(ax.get_shared_y_axes().get_siblings(ax)) > 1: _remove_labels_from_axis(ax.yaxis) def _flatten(axes): if not is_list_like(axes): return np.array([axes]) elif isinstance(axes, (np.ndarray, ABCIndexClass)): return axes.ravel() return np.array(axes) def _set_ticks_props(axes, xlabelsize=None, xrot=None, ylabelsize=None, yrot=None): import matplotlib.pyplot as plt for ax in _flatten(axes): if xlabelsize is not None: plt.setp(ax.get_xticklabels(), fontsize=xlabelsize) if xrot is not None: plt.setp(ax.get_xticklabels(), rotation=xrot) if ylabelsize is not None: plt.setp(ax.get_yticklabels(), fontsize=ylabelsize) if yrot is not None: plt.setp(ax.get_yticklabels(), rotation=yrot) return axes def _get_all_lines(ax): lines = ax.get_lines() if hasattr(ax, "right_ax"): lines += ax.right_ax.get_lines() if hasattr(ax, "left_ax"): lines += ax.left_ax.get_lines() return lines def _get_xlim(lines): left, right = np.inf, -np.inf for l in lines: x = l.get_xdata(orig=False) left = min(np.nanmin(x), left) right = max(np.nanmax(x), right) return left, right