from collections.abc import Iterable, Sequence from contextlib import ExitStack import functools import inspect import logging from numbers import Real from operator import attrgetter import types import numpy as np import matplotlib as mpl from matplotlib import _api, cbook, _docstring, offsetbox import matplotlib.artist as martist import matplotlib.axis as maxis from matplotlib.cbook import _OrderedSet, _check_1d, index_of import matplotlib.collections as mcoll import matplotlib.colors as mcolors import matplotlib.font_manager as font_manager from matplotlib.gridspec import SubplotSpec import matplotlib.image as mimage import matplotlib.lines as mlines import matplotlib.patches as mpatches from matplotlib.rcsetup import cycler, validate_axisbelow import matplotlib.spines as mspines import matplotlib.table as mtable import matplotlib.text as mtext import matplotlib.ticker as mticker import matplotlib.transforms as mtransforms _log = logging.getLogger(__name__) class _axis_method_wrapper: """ Helper to generate Axes methods wrapping Axis methods. After :: get_foo = _axis_method_wrapper("xaxis", "get_bar") (in the body of a class) ``get_foo`` is a method that forwards it arguments to the ``get_bar`` method of the ``xaxis`` attribute, and gets its signature and docstring from ``Axis.get_bar``. The docstring of ``get_foo`` is built by replacing "this Axis" by "the {attr_name}" (i.e., "the xaxis", "the yaxis") in the wrapped method's dedented docstring; additional replacements can be given in *doc_sub*. """ def __init__(self, attr_name, method_name, *, doc_sub=None): self.attr_name = attr_name self.method_name = method_name # Immediately put the docstring in ``self.__doc__`` so that docstring # manipulations within the class body work as expected. doc = inspect.getdoc(getattr(maxis.Axis, method_name)) self._missing_subs = [] if doc: doc_sub = {"this Axis": f"the {self.attr_name}", **(doc_sub or {})} for k, v in doc_sub.items(): if k not in doc: # Delay raising error until we know qualname. self._missing_subs.append(k) doc = doc.replace(k, v) self.__doc__ = doc def __set_name__(self, owner, name): # This is called at the end of the class body as # ``self.__set_name__(cls, name_under_which_self_is_assigned)``; we # rely on that to give the wrapper the correct __name__/__qualname__. get_method = attrgetter(f"{self.attr_name}.{self.method_name}") def wrapper(self, *args, **kwargs): return get_method(self)(*args, **kwargs) wrapper.__module__ = owner.__module__ wrapper.__name__ = name wrapper.__qualname__ = f"{owner.__qualname__}.{name}" wrapper.__doc__ = self.__doc__ # Manually copy the signature instead of using functools.wraps because # displaying the Axis method source when asking for the Axes method # source would be confusing. wrapper.__signature__ = inspect.signature( getattr(maxis.Axis, self.method_name)) if self._missing_subs: raise ValueError( "The definition of {} expected that the docstring of Axis.{} " "contains {!r} as substrings".format( wrapper.__qualname__, self.method_name, ", ".join(map(repr, self._missing_subs)))) setattr(owner, name, wrapper) class _TransformedBoundsLocator: """ Axes locator for `.Axes.inset_axes` and similarly positioned Axes. The locator is a callable object used in `.Axes.set_aspect` to compute the Axes location depending on the renderer. """ def __init__(self, bounds, transform): """ *bounds* (a ``[l, b, w, h]`` rectangle) and *transform* together specify the position of the inset Axes. """ self._bounds = bounds self._transform = transform def __call__(self, ax, renderer): # Subtracting transSubfigure will typically rely on inverted(), # freezing the transform; thus, this needs to be delayed until draw # time as transSubfigure may otherwise change after this is evaluated. return mtransforms.TransformedBbox( mtransforms.Bbox.from_bounds(*self._bounds), self._transform - ax.figure.transSubfigure) def _process_plot_format(fmt, *, ambiguous_fmt_datakey=False): """ Convert a MATLAB style color/line style format string to a (*linestyle*, *marker*, *color*) tuple. Example format strings include: * 'ko': black circles * '.b': blue dots * 'r--': red dashed lines * 'C2--': the third color in the color cycle, dashed lines The format is absolute in the sense that if a linestyle or marker is not defined in *fmt*, there is no line or marker. This is expressed by returning 'None' for the respective quantity. See Also -------- matplotlib.Line2D.lineStyles, matplotlib.colors.cnames All possible styles and color format strings. """ linestyle = None marker = None color = None # Is fmt just a colorspec? try: color = mcolors.to_rgba(fmt) # We need to differentiate grayscale '1.0' from tri_down marker '1' try: fmtint = str(int(fmt)) except ValueError: return linestyle, marker, color # Yes else: if fmt != fmtint: # user definitely doesn't want tri_down marker return linestyle, marker, color # Yes else: # ignore converted color color = None except ValueError: pass # No, not just a color. errfmt = ("{!r} is neither a data key nor a valid format string ({})" if ambiguous_fmt_datakey else "{!r} is not a valid format string ({})") i = 0 while i < len(fmt): c = fmt[i] if fmt[i:i+2] in mlines.lineStyles: # First, the two-char styles. if linestyle is not None: raise ValueError(errfmt.format(fmt, "two linestyle symbols")) linestyle = fmt[i:i+2] i += 2 elif c in mlines.lineStyles: if linestyle is not None: raise ValueError(errfmt.format(fmt, "two linestyle symbols")) linestyle = c i += 1 elif c in mlines.lineMarkers: if marker is not None: raise ValueError(errfmt.format(fmt, "two marker symbols")) marker = c i += 1 elif c in mcolors.get_named_colors_mapping(): if color is not None: raise ValueError(errfmt.format(fmt, "two color symbols")) color = c i += 1 elif c == 'C' and i < len(fmt) - 1: color_cycle_number = int(fmt[i + 1]) color = mcolors.to_rgba(f"C{color_cycle_number}") i += 2 else: raise ValueError( errfmt.format(fmt, f"unrecognized character {c!r}")) if linestyle is None and marker is None: linestyle = mpl.rcParams['lines.linestyle'] if linestyle is None: linestyle = 'None' if marker is None: marker = 'None' return linestyle, marker, color class _process_plot_var_args: """ Process variable length arguments to `~.Axes.plot`, to support :: plot(t, s) plot(t1, s1, t2, s2) plot(t1, s1, 'ko', t2, s2) plot(t1, s1, 'ko', t2, s2, 'r--', t3, e3) an arbitrary number of *x*, *y*, *fmt* are allowed """ def __init__(self, command='plot'): self.command = command self.set_prop_cycle(None) def set_prop_cycle(self, cycler): if cycler is None: cycler = mpl.rcParams['axes.prop_cycle'] self._idx = 0 self._cycler_items = [*cycler] self._prop_keys = cycler.keys # This should make a copy def __call__(self, axes, *args, data=None, **kwargs): axes._process_unit_info(kwargs=kwargs) for pos_only in "xy": if pos_only in kwargs: raise _api.kwarg_error(self.command, pos_only) if not args: return if data is None: # Process dict views args = [cbook.sanitize_sequence(a) for a in args] else: # Process the 'data' kwarg. replaced = [mpl._replacer(data, arg) for arg in args] if len(args) == 1: label_namer_idx = 0 elif len(args) == 2: # Can be x, y or y, c. # Figure out what the second argument is. # 1) If the second argument cannot be a format shorthand, the # second argument is the label_namer. # 2) Otherwise (it could have been a format shorthand), # a) if we did perform a substitution, emit a warning, and # use it as label_namer. # b) otherwise, it is indeed a format shorthand; use the # first argument as label_namer. try: _process_plot_format(args[1]) except ValueError: # case 1) label_namer_idx = 1 else: if replaced[1] is not args[1]: # case 2a) _api.warn_external( f"Second argument {args[1]!r} is ambiguous: could " f"be a format string but is in 'data'; using as " f"data. If it was intended as data, set the " f"format string to an empty string to suppress " f"this warning. If it was intended as a format " f"string, explicitly pass the x-values as well. " f"Alternatively, rename the entry in 'data'.", RuntimeWarning) label_namer_idx = 1 else: # case 2b) label_namer_idx = 0 elif len(args) == 3: label_namer_idx = 1 else: raise ValueError( "Using arbitrary long args with data is not supported due " "to ambiguity of arguments; use multiple plotting calls " "instead") if kwargs.get("label") is None: kwargs["label"] = mpl._label_from_arg( replaced[label_namer_idx], args[label_namer_idx]) args = replaced ambiguous_fmt_datakey = data is not None and len(args) == 2 if len(args) >= 4 and not cbook.is_scalar_or_string( kwargs.get("label")): raise ValueError("plot() with multiple groups of data (i.e., " "pairs of x and y) does not support multiple " "labels") # Repeatedly grab (x, y) or (x, y, format) from the front of args and # massage them into arguments to plot() or fill(). while args: this, args = args[:2], args[2:] if args and isinstance(args[0], str): this += args[0], args = args[1:] yield from self._plot_args( axes, this, kwargs, ambiguous_fmt_datakey=ambiguous_fmt_datakey) def get_next_color(self): """Return the next color in the cycle.""" if 'color' not in self._prop_keys: return 'k' c = self._cycler_items[self._idx]['color'] self._idx = (self._idx + 1) % len(self._cycler_items) return c def _getdefaults(self, ignore, kw): """ If some keys in the property cycle (excluding those in the set *ignore*) are absent or set to None in the dict *kw*, return a copy of the next entry in the property cycle, excluding keys in *ignore*. Otherwise, don't advance the property cycle, and return an empty dict. """ prop_keys = self._prop_keys - ignore if any(kw.get(k, None) is None for k in prop_keys): # Need to copy this dictionary or else the next time around # in the cycle, the dictionary could be missing entries. default_dict = self._cycler_items[self._idx].copy() self._idx = (self._idx + 1) % len(self._cycler_items) for p in ignore: default_dict.pop(p, None) else: default_dict = {} return default_dict def _setdefaults(self, defaults, kw): """ Add to the dict *kw* the entries in the dict *default* that are absent or set to None in *kw*. """ for k in defaults: if kw.get(k, None) is None: kw[k] = defaults[k] def _makeline(self, axes, x, y, kw, kwargs): kw = {**kw, **kwargs} # Don't modify the original kw. default_dict = self._getdefaults(set(), kw) self._setdefaults(default_dict, kw) seg = mlines.Line2D(x, y, **kw) return seg, kw def _makefill(self, axes, x, y, kw, kwargs): # Polygon doesn't directly support unitized inputs. x = axes.convert_xunits(x) y = axes.convert_yunits(y) kw = kw.copy() # Don't modify the original kw. kwargs = kwargs.copy() # Ignore 'marker'-related properties as they aren't Polygon # properties, but they are Line2D properties, and so they are # likely to appear in the default cycler construction. # This is done here to the defaults dictionary as opposed to the # other two dictionaries because we do want to capture when a # *user* explicitly specifies a marker which should be an error. # We also want to prevent advancing the cycler if there are no # defaults needed after ignoring the given properties. ignores = {'marker', 'markersize', 'markeredgecolor', 'markerfacecolor', 'markeredgewidth'} # Also ignore anything provided by *kwargs*. for k, v in kwargs.items(): if v is not None: ignores.add(k) # Only using the first dictionary to use as basis # for getting defaults for back-compat reasons. # Doing it with both seems to mess things up in # various places (probably due to logic bugs elsewhere). default_dict = self._getdefaults(ignores, kw) self._setdefaults(default_dict, kw) # Looks like we don't want "color" to be interpreted to # mean both facecolor and edgecolor for some reason. # So the "kw" dictionary is thrown out, and only its # 'color' value is kept and translated as a 'facecolor'. # This design should probably be revisited as it increases # complexity. facecolor = kw.get('color', None) # Throw out 'color' as it is now handled as a facecolor default_dict.pop('color', None) # To get other properties set from the cycler # modify the kwargs dictionary. self._setdefaults(default_dict, kwargs) seg = mpatches.Polygon(np.column_stack((x, y)), facecolor=facecolor, fill=kwargs.get('fill', True), closed=kw['closed']) seg.set(**kwargs) return seg, kwargs def _plot_args(self, axes, tup, kwargs, *, return_kwargs=False, ambiguous_fmt_datakey=False): """ Process the arguments of ``plot([x], y, [fmt], **kwargs)`` calls. This processes a single set of ([x], y, [fmt]) parameters; i.e. for ``plot(x, y, x2, y2)`` it will be called twice. Once for (x, y) and once for (x2, y2). x and y may be 2D and thus can still represent multiple datasets. For multiple datasets, if the keyword argument *label* is a list, this will unpack the list and assign the individual labels to the datasets. Parameters ---------- tup : tuple A tuple of the positional parameters. This can be one of - (y,) - (x, y) - (y, fmt) - (x, y, fmt) kwargs : dict The keyword arguments passed to ``plot()``. return_kwargs : bool Whether to also return the effective keyword arguments after label unpacking as well. ambiguous_fmt_datakey : bool Whether the format string in *tup* could also have been a misspelled data key. Returns ------- result If *return_kwargs* is false, a list of Artists representing the dataset(s). If *return_kwargs* is true, a list of (Artist, effective_kwargs) representing the dataset(s). See *return_kwargs*. The Artist is either `.Line2D` (if called from ``plot()``) or `.Polygon` otherwise. """ if len(tup) > 1 and isinstance(tup[-1], str): # xy is tup with fmt stripped (could still be (y,) only) *xy, fmt = tup linestyle, marker, color = _process_plot_format( fmt, ambiguous_fmt_datakey=ambiguous_fmt_datakey) elif len(tup) == 3: raise ValueError('third arg must be a format string') else: xy = tup linestyle, marker, color = None, None, None # Don't allow any None value; these would be up-converted to one # element array of None which causes problems downstream. if any(v is None for v in tup): raise ValueError("x, y, and format string must not be None") kw = {} for prop_name, val in zip(('linestyle', 'marker', 'color'), (linestyle, marker, color)): if val is not None: # check for conflicts between fmt and kwargs if (fmt.lower() != 'none' and prop_name in kwargs and val != 'None'): # Technically ``plot(x, y, 'o', ls='--')`` is a conflict # because 'o' implicitly unsets the linestyle # (linestyle='None'). # We'll gracefully not warn in this case because an # explicit set via kwargs can be seen as intention to # override an implicit unset. # Note: We don't val.lower() != 'none' because val is not # necessarily a string (can be a tuple for colors). This # is safe, because *val* comes from _process_plot_format() # which only returns 'None'. _api.warn_external( f"{prop_name} is redundantly defined by the " f"'{prop_name}' keyword argument and the fmt string " f'"{fmt}" (-> {prop_name}={val!r}). The keyword ' f"argument will take precedence.") kw[prop_name] = val if len(xy) == 2: x = _check_1d(xy[0]) y = _check_1d(xy[1]) else: x, y = index_of(xy[-1]) if axes.xaxis is not None: axes.xaxis.update_units(x) if axes.yaxis is not None: axes.yaxis.update_units(y) if x.shape[0] != y.shape[0]: raise ValueError(f"x and y must have same first dimension, but " f"have shapes {x.shape} and {y.shape}") if x.ndim > 2 or y.ndim > 2: raise ValueError(f"x and y can be no greater than 2D, but have " f"shapes {x.shape} and {y.shape}") if x.ndim == 1: x = x[:, np.newaxis] if y.ndim == 1: y = y[:, np.newaxis] if self.command == 'plot': make_artist = self._makeline else: kw['closed'] = kwargs.get('closed', True) make_artist = self._makefill ncx, ncy = x.shape[1], y.shape[1] if ncx > 1 and ncy > 1 and ncx != ncy: raise ValueError(f"x has {ncx} columns but y has {ncy} columns") if ncx == 0 or ncy == 0: return [] label = kwargs.get('label') n_datasets = max(ncx, ncy) if n_datasets > 1 and not cbook.is_scalar_or_string(label): if len(label) != n_datasets: raise ValueError(f"label must be scalar or have the same " f"length as the input data, but found " f"{len(label)} for {n_datasets} datasets.") labels = label else: labels = [label] * n_datasets result = (make_artist(axes, x[:, j % ncx], y[:, j % ncy], kw, {**kwargs, 'label': label}) for j, label in enumerate(labels)) if return_kwargs: return list(result) else: return [l[0] for l in result] @_api.define_aliases({"facecolor": ["fc"]}) class _AxesBase(martist.Artist): name = "rectilinear" # axis names are the prefixes for the attributes that contain the # respective axis; e.g. 'x' <-> self.xaxis, containing an XAxis. # Note that PolarAxes uses these attributes as well, so that we have # 'x' <-> self.xaxis, containing a ThetaAxis. In particular we do not # have 'theta' in _axis_names. # In practice, this is ('x', 'y') for all 2D Axes and ('x', 'y', 'z') # for Axes3D. _axis_names = ("x", "y") _shared_axes = {name: cbook.Grouper() for name in _axis_names} _twinned_axes = cbook.Grouper() _subclass_uses_cla = False @property def _axis_map(self): """A mapping of axis names, e.g. 'x', to `Axis` instances.""" return {name: getattr(self, f"{name}axis") for name in self._axis_names} def __str__(self): return "{0}({1[0]:g},{1[1]:g};{1[2]:g}x{1[3]:g})".format( type(self).__name__, self._position.bounds) def __init__(self, fig, *args, facecolor=None, # defaults to rc axes.facecolor frameon=True, sharex=None, # use Axes instance's xaxis info sharey=None, # use Axes instance's yaxis info label='', xscale=None, yscale=None, box_aspect=None, **kwargs ): """ Build an Axes in a figure. Parameters ---------- fig : `~matplotlib.figure.Figure` The Axes is built in the `.Figure` *fig*. *args ``*args`` can be a single ``(left, bottom, width, height)`` rectangle or a single `.Bbox`. This specifies the rectangle (in figure coordinates) where the Axes is positioned. ``*args`` can also consist of three numbers or a single three-digit number; in the latter case, the digits are considered as independent numbers. The numbers are interpreted as ``(nrows, ncols, index)``: ``(nrows, ncols)`` specifies the size of an array of subplots, and ``index`` is the 1-based index of the subplot being created. Finally, ``*args`` can also directly be a `.SubplotSpec` instance. sharex, sharey : `~matplotlib.axes.Axes`, optional The x- or y-`~.matplotlib.axis` is shared with the x- or y-axis in the input `~.axes.Axes`. frameon : bool, default: True Whether the Axes frame is visible. box_aspect : float, optional Set a fixed aspect for the Axes box, i.e. the ratio of height to width. See `~.axes.Axes.set_box_aspect` for details. **kwargs Other optional keyword arguments: %(Axes:kwdoc)s Returns ------- `~.axes.Axes` The new `~.axes.Axes` object. """ super().__init__() if "rect" in kwargs: if args: raise TypeError( "'rect' cannot be used together with positional arguments") rect = kwargs.pop("rect") _api.check_isinstance((mtransforms.Bbox, Iterable), rect=rect) args = (rect,) subplotspec = None if len(args) == 1 and isinstance(args[0], mtransforms.Bbox): self._position = args[0] elif len(args) == 1 and np.iterable(args[0]): self._position = mtransforms.Bbox.from_bounds(*args[0]) else: self._position = self._originalPosition = mtransforms.Bbox.unit() subplotspec = SubplotSpec._from_subplot_args(fig, args) if self._position.width < 0 or self._position.height < 0: raise ValueError('Width and height specified must be non-negative') self._originalPosition = self._position.frozen() self.axes = self self._aspect = 'auto' self._adjustable = 'box' self._anchor = 'C' self._stale_viewlims = {name: False for name in self._axis_names} self._sharex = sharex self._sharey = sharey self.set_label(label) self.set_figure(fig) # The subplotspec needs to be set after the figure (so that # figure-level subplotpars are taken into account), but the figure # needs to be set after self._position is initialized. if subplotspec: self.set_subplotspec(subplotspec) else: self._subplotspec = None self.set_box_aspect(box_aspect) self._axes_locator = None # Optionally set via update(kwargs). self._children = [] # placeholder for any colorbars added that use this Axes. # (see colorbar.py): self._colorbars = [] self.spines = mspines.Spines.from_dict(self._gen_axes_spines()) # this call may differ for non-sep axes, e.g., polar self._init_axis() if facecolor is None: facecolor = mpl.rcParams['axes.facecolor'] self._facecolor = facecolor self._frameon = frameon self.set_axisbelow(mpl.rcParams['axes.axisbelow']) self._rasterization_zorder = None self.clear() # funcs used to format x and y - fall back on major formatters self.fmt_xdata = None self.fmt_ydata = None self.set_navigate(True) self.set_navigate_mode(None) if xscale: self.set_xscale(xscale) if yscale: self.set_yscale(yscale) self._internal_update(kwargs) for name, axis in self._axis_map.items(): axis.callbacks._connect_picklable( 'units', self._unit_change_handler(name)) rcParams = mpl.rcParams self.tick_params( top=rcParams['xtick.top'] and rcParams['xtick.minor.top'], bottom=rcParams['xtick.bottom'] and rcParams['xtick.minor.bottom'], labeltop=(rcParams['xtick.labeltop'] and rcParams['xtick.minor.top']), labelbottom=(rcParams['xtick.labelbottom'] and rcParams['xtick.minor.bottom']), left=rcParams['ytick.left'] and rcParams['ytick.minor.left'], right=rcParams['ytick.right'] and rcParams['ytick.minor.right'], labelleft=(rcParams['ytick.labelleft'] and rcParams['ytick.minor.left']), labelright=(rcParams['ytick.labelright'] and rcParams['ytick.minor.right']), which='minor') self.tick_params( top=rcParams['xtick.top'] and rcParams['xtick.major.top'], bottom=rcParams['xtick.bottom'] and rcParams['xtick.major.bottom'], labeltop=(rcParams['xtick.labeltop'] and rcParams['xtick.major.top']), labelbottom=(rcParams['xtick.labelbottom'] and rcParams['xtick.major.bottom']), left=rcParams['ytick.left'] and rcParams['ytick.major.left'], right=rcParams['ytick.right'] and rcParams['ytick.major.right'], labelleft=(rcParams['ytick.labelleft'] and rcParams['ytick.major.left']), labelright=(rcParams['ytick.labelright'] and rcParams['ytick.major.right']), which='major') def __init_subclass__(cls, **kwargs): parent_uses_cla = super(cls, cls)._subclass_uses_cla if 'cla' in cls.__dict__: _api.warn_deprecated( '3.6', pending=True, message=f'Overriding `Axes.cla` in {cls.__qualname__} is ' 'pending deprecation in %(since)s and will be fully ' 'deprecated in favor of `Axes.clear` in the future. ' 'Please report ' f'this to the {cls.__module__!r} author.') cls._subclass_uses_cla = 'cla' in cls.__dict__ or parent_uses_cla super().__init_subclass__(**kwargs) def __getstate__(self): state = super().__getstate__() # Prune the sharing & twinning info to only contain the current group. state["_shared_axes"] = { name: self._shared_axes[name].get_siblings(self) for name in self._axis_names if self in self._shared_axes[name]} state["_twinned_axes"] = (self._twinned_axes.get_siblings(self) if self in self._twinned_axes else None) return state def __setstate__(self, state): # Merge the grouping info back into the global groupers. shared_axes = state.pop("_shared_axes") for name, shared_siblings in shared_axes.items(): self._shared_axes[name].join(*shared_siblings) twinned_siblings = state.pop("_twinned_axes") if twinned_siblings: self._twinned_axes.join(*twinned_siblings) self.__dict__ = state self._stale = True def __repr__(self): fields = [] if self.get_label(): fields += [f"label={self.get_label()!r}"] if hasattr(self, "get_title"): titles = {} for k in ["left", "center", "right"]: title = self.get_title(loc=k) if title: titles[k] = title if titles: fields += [f"title={titles}"] for name, axis in self._axis_map.items(): if axis.get_label() and axis.get_label().get_text(): fields += [f"{name}label={axis.get_label().get_text()!r}"] return f"<{self.__class__.__name__}: " + ", ".join(fields) + ">" def get_subplotspec(self): """Return the `.SubplotSpec` associated with the subplot, or None.""" return self._subplotspec def set_subplotspec(self, subplotspec): """Set the `.SubplotSpec`. associated with the subplot.""" self._subplotspec = subplotspec self._set_position(subplotspec.get_position(self.figure)) def get_gridspec(self): """Return the `.GridSpec` associated with the subplot, or None.""" return self._subplotspec.get_gridspec() if self._subplotspec else None def get_window_extent(self, renderer=None): """ Return the Axes bounding box in display space. This bounding box does not include the spines, ticks, ticklabels, or other labels. For a bounding box including these elements use `~matplotlib.axes.Axes.get_tightbbox`. See Also -------- matplotlib.axes.Axes.get_tightbbox matplotlib.axis.Axis.get_tightbbox matplotlib.spines.Spine.get_window_extent """ return self.bbox def _init_axis(self): # This is moved out of __init__ because non-separable axes don't use it self.xaxis = maxis.XAxis(self, clear=False) self.spines.bottom.register_axis(self.xaxis) self.spines.top.register_axis(self.xaxis) self.yaxis = maxis.YAxis(self, clear=False) self.spines.left.register_axis(self.yaxis) self.spines.right.register_axis(self.yaxis) def set_figure(self, fig): # docstring inherited super().set_figure(fig) self.bbox = mtransforms.TransformedBbox(self._position, fig.transSubfigure) # these will be updated later as data is added self.dataLim = mtransforms.Bbox.null() self._viewLim = mtransforms.Bbox.unit() self.transScale = mtransforms.TransformWrapper( mtransforms.IdentityTransform()) self._set_lim_and_transforms() def _unstale_viewLim(self): # We should arrange to store this information once per share-group # instead of on every axis. need_scale = { name: any(ax._stale_viewlims[name] for ax in self._shared_axes[name].get_siblings(self)) for name in self._axis_names} if any(need_scale.values()): for name in need_scale: for ax in self._shared_axes[name].get_siblings(self): ax._stale_viewlims[name] = False self.autoscale_view(**{f"scale{name}": scale for name, scale in need_scale.items()}) @property def viewLim(self): self._unstale_viewLim() return self._viewLim def _request_autoscale_view(self, axis="all", tight=None): """ Mark a single axis, or all of them, as stale wrt. autoscaling. No computation is performed until the next autoscaling; thus, separate calls to control individual axises incur negligible performance cost. Parameters ---------- axis : str, default: "all" Either an element of ``self._axis_names``, or "all". tight : bool or None, default: None """ axis_names = _api.check_getitem( {**{k: [k] for k in self._axis_names}, "all": self._axis_names}, axis=axis) for name in axis_names: self._stale_viewlims[name] = True if tight is not None: self._tight = tight def _set_lim_and_transforms(self): """ Set the *_xaxis_transform*, *_yaxis_transform*, *transScale*, *transData*, *transLimits* and *transAxes* transformations. .. note:: This method is primarily used by rectilinear projections of the `~matplotlib.axes.Axes` class, and is meant to be overridden by new kinds of projection Axes that need different transformations and limits. (See `~matplotlib.projections.polar.PolarAxes` for an example.) """ self.transAxes = mtransforms.BboxTransformTo(self.bbox) # Transforms the x and y axis separately by a scale factor. # It is assumed that this part will have non-linear components # (e.g., for a log scale). self.transScale = mtransforms.TransformWrapper( mtransforms.IdentityTransform()) # An affine transformation on the data, generally to limit the # range of the axes self.transLimits = mtransforms.BboxTransformFrom( mtransforms.TransformedBbox(self._viewLim, self.transScale)) # The parentheses are important for efficiency here -- they # group the last two (which are usually affines) separately # from the first (which, with log-scaling can be non-affine). self.transData = self.transScale + (self.transLimits + self.transAxes) self._xaxis_transform = mtransforms.blended_transform_factory( self.transData, self.transAxes) self._yaxis_transform = mtransforms.blended_transform_factory( self.transAxes, self.transData) def get_xaxis_transform(self, which='grid'): """ Get the transformation used for drawing x-axis labels, ticks and gridlines. The x-direction is in data coordinates and the y-direction is in axis coordinates. .. note:: This transformation is primarily used by the `~matplotlib.axis.Axis` class, and is meant to be overridden by new kinds of projections that may need to place axis elements in different locations. Parameters ---------- which : {'grid', 'tick1', 'tick2'} """ if which == 'grid': return self._xaxis_transform elif which == 'tick1': # for cartesian projection, this is bottom spine return self.spines.bottom.get_spine_transform() elif which == 'tick2': # for cartesian projection, this is top spine return self.spines.top.get_spine_transform() else: raise ValueError(f'unknown value for which: {which!r}') def get_xaxis_text1_transform(self, pad_points): """ Returns ------- transform : Transform The transform used for drawing x-axis labels, which will add *pad_points* of padding (in points) between the axis and the label. The x-direction is in data coordinates and the y-direction is in axis coordinates valign : {'center', 'top', 'bottom', 'baseline', 'center_baseline'} The text vertical alignment. halign : {'center', 'left', 'right'} The text horizontal alignment. Notes ----- This transformation is primarily used by the `~matplotlib.axis.Axis` class, and is meant to be overridden by new kinds of projections that may need to place axis elements in different locations. """ labels_align = mpl.rcParams["xtick.alignment"] return (self.get_xaxis_transform(which='tick1') + mtransforms.ScaledTranslation(0, -1 * pad_points / 72, self.figure.dpi_scale_trans), "top", labels_align) def get_xaxis_text2_transform(self, pad_points): """ Returns ------- transform : Transform The transform used for drawing secondary x-axis labels, which will add *pad_points* of padding (in points) between the axis and the label. The x-direction is in data coordinates and the y-direction is in axis coordinates valign : {'center', 'top', 'bottom', 'baseline', 'center_baseline'} The text vertical alignment. halign : {'center', 'left', 'right'} The text horizontal alignment. Notes ----- This transformation is primarily used by the `~matplotlib.axis.Axis` class, and is meant to be overridden by new kinds of projections that may need to place axis elements in different locations. """ labels_align = mpl.rcParams["xtick.alignment"] return (self.get_xaxis_transform(which='tick2') + mtransforms.ScaledTranslation(0, pad_points / 72, self.figure.dpi_scale_trans), "bottom", labels_align) def get_yaxis_transform(self, which='grid'): """ Get the transformation used for drawing y-axis labels, ticks and gridlines. The x-direction is in axis coordinates and the y-direction is in data coordinates. .. note:: This transformation is primarily used by the `~matplotlib.axis.Axis` class, and is meant to be overridden by new kinds of projections that may need to place axis elements in different locations. Parameters ---------- which : {'grid', 'tick1', 'tick2'} """ if which == 'grid': return self._yaxis_transform elif which == 'tick1': # for cartesian projection, this is bottom spine return self.spines.left.get_spine_transform() elif which == 'tick2': # for cartesian projection, this is top spine return self.spines.right.get_spine_transform() else: raise ValueError(f'unknown value for which: {which!r}') def get_yaxis_text1_transform(self, pad_points): """ Returns ------- transform : Transform The transform used for drawing y-axis labels, which will add *pad_points* of padding (in points) between the axis and the label. The x-direction is in axis coordinates and the y-direction is in data coordinates valign : {'center', 'top', 'bottom', 'baseline', 'center_baseline'} The text vertical alignment. halign : {'center', 'left', 'right'} The text horizontal alignment. Notes ----- This transformation is primarily used by the `~matplotlib.axis.Axis` class, and is meant to be overridden by new kinds of projections that may need to place axis elements in different locations. """ labels_align = mpl.rcParams["ytick.alignment"] return (self.get_yaxis_transform(which='tick1') + mtransforms.ScaledTranslation(-1 * pad_points / 72, 0, self.figure.dpi_scale_trans), labels_align, "right") def get_yaxis_text2_transform(self, pad_points): """ Returns ------- transform : Transform The transform used for drawing secondart y-axis labels, which will add *pad_points* of padding (in points) between the axis and the label. The x-direction is in axis coordinates and the y-direction is in data coordinates valign : {'center', 'top', 'bottom', 'baseline', 'center_baseline'} The text vertical alignment. halign : {'center', 'left', 'right'} The text horizontal alignment. Notes ----- This transformation is primarily used by the `~matplotlib.axis.Axis` class, and is meant to be overridden by new kinds of projections that may need to place axis elements in different locations. """ labels_align = mpl.rcParams["ytick.alignment"] return (self.get_yaxis_transform(which='tick2') + mtransforms.ScaledTranslation(pad_points / 72, 0, self.figure.dpi_scale_trans), labels_align, "left") def _update_transScale(self): self.transScale.set( mtransforms.blended_transform_factory( self.xaxis.get_transform(), self.yaxis.get_transform())) def get_position(self, original=False): """ Return the position of the Axes within the figure as a `.Bbox`. Parameters ---------- original : bool If ``True``, return the original position. Otherwise, return the active position. For an explanation of the positions see `.set_position`. Returns ------- `.Bbox` """ if original: return self._originalPosition.frozen() else: locator = self.get_axes_locator() if not locator: self.apply_aspect() return self._position.frozen() def set_position(self, pos, which='both'): """ Set the Axes position. Axes have two position attributes. The 'original' position is the position allocated for the Axes. The 'active' position is the position the Axes is actually drawn at. These positions are usually the same unless a fixed aspect is set to the Axes. See `.Axes.set_aspect` for details. Parameters ---------- pos : [left, bottom, width, height] or `~matplotlib.transforms.Bbox` The new position of the Axes in `.Figure` coordinates. which : {'both', 'active', 'original'}, default: 'both' Determines which position variables to change. See Also -------- matplotlib.transforms.Bbox.from_bounds matplotlib.transforms.Bbox.from_extents """ self._set_position(pos, which=which) # because this is being called externally to the library we # don't let it be in the layout. self.set_in_layout(False) def _set_position(self, pos, which='both'): """ Private version of set_position. Call this internally to get the same functionality of `set_position`, but not to take the axis out of the constrained_layout hierarchy. """ if not isinstance(pos, mtransforms.BboxBase): pos = mtransforms.Bbox.from_bounds(*pos) for ax in self._twinned_axes.get_siblings(self): if which in ('both', 'active'): ax._position.set(pos) if which in ('both', 'original'): ax._originalPosition.set(pos) self.stale = True def reset_position(self): """ Reset the active position to the original position. This undoes changes to the active position (as defined in `.set_position`) which may have been performed to satisfy fixed-aspect constraints. """ for ax in self._twinned_axes.get_siblings(self): pos = ax.get_position(original=True) ax.set_position(pos, which='active') def set_axes_locator(self, locator): """ Set the Axes locator. Parameters ---------- locator : Callable[[Axes, Renderer], Bbox] """ self._axes_locator = locator self.stale = True def get_axes_locator(self): """ Return the axes_locator. """ return self._axes_locator def _set_artist_props(self, a): """Set the boilerplate props for artists added to Axes.""" a.set_figure(self.figure) if not a.is_transform_set(): a.set_transform(self.transData) a.axes = self if a.get_mouseover(): self._mouseover_set.add(a) def _gen_axes_patch(self): """ Returns ------- Patch The patch used to draw the background of the Axes. It is also used as the clipping path for any data elements on the Axes. In the standard Axes, this is a rectangle, but in other projections it may not be. Notes ----- Intended to be overridden by new projection types. """ return mpatches.Rectangle((0.0, 0.0), 1.0, 1.0) def _gen_axes_spines(self, locations=None, offset=0.0, units='inches'): """ Returns ------- dict Mapping of spine names to `.Line2D` or `.Patch` instances that are used to draw Axes spines. In the standard Axes, spines are single line segments, but in other projections they may not be. Notes ----- Intended to be overridden by new projection types. """ return {side: mspines.Spine.linear_spine(self, side) for side in ['left', 'right', 'bottom', 'top']} def sharex(self, other): """ Share the x-axis with *other*. This is equivalent to passing ``sharex=other`` when constructing the Axes, and cannot be used if the x-axis is already being shared with another Axes. """ _api.check_isinstance(_AxesBase, other=other) if self._sharex is not None and other is not self._sharex: raise ValueError("x-axis is already shared") self._shared_axes["x"].join(self, other) self._sharex = other self.xaxis.major = other.xaxis.major # Ticker instances holding self.xaxis.minor = other.xaxis.minor # locator and formatter. x0, x1 = other.get_xlim() self.set_xlim(x0, x1, emit=False, auto=other.get_autoscalex_on()) self.xaxis._scale = other.xaxis._scale def sharey(self, other): """ Share the y-axis with *other*. This is equivalent to passing ``sharey=other`` when constructing the Axes, and cannot be used if the y-axis is already being shared with another Axes. """ _api.check_isinstance(_AxesBase, other=other) if self._sharey is not None and other is not self._sharey: raise ValueError("y-axis is already shared") self._shared_axes["y"].join(self, other) self._sharey = other self.yaxis.major = other.yaxis.major # Ticker instances holding self.yaxis.minor = other.yaxis.minor # locator and formatter. y0, y1 = other.get_ylim() self.set_ylim(y0, y1, emit=False, auto=other.get_autoscaley_on()) self.yaxis._scale = other.yaxis._scale def __clear(self): """Clear the Axes.""" # The actual implementation of clear() as long as clear() has to be # an adapter delegating to the correct implementation. # The implementation can move back into clear() when the # deprecation on cla() subclassing expires. # stash the current visibility state if hasattr(self, 'patch'): patch_visible = self.patch.get_visible() else: patch_visible = True xaxis_visible = self.xaxis.get_visible() yaxis_visible = self.yaxis.get_visible() for axis in self._axis_map.values(): axis.clear() # Also resets the scale to linear. for spine in self.spines.values(): spine._clear() # Use _clear to not clear Axis again self.ignore_existing_data_limits = True self.callbacks = cbook.CallbackRegistry( signals=["xlim_changed", "ylim_changed", "zlim_changed"]) # update the minor locator for x and y axis based on rcParams if mpl.rcParams['xtick.minor.visible']: self.xaxis.set_minor_locator(mticker.AutoMinorLocator()) if mpl.rcParams['ytick.minor.visible']: self.yaxis.set_minor_locator(mticker.AutoMinorLocator()) self._xmargin = mpl.rcParams['axes.xmargin'] self._ymargin = mpl.rcParams['axes.ymargin'] self._tight = None self._use_sticky_edges = True self._get_lines = _process_plot_var_args() self._get_patches_for_fill = _process_plot_var_args('fill') self._gridOn = mpl.rcParams['axes.grid'] old_children, self._children = self._children, [] for chld in old_children: chld.axes = chld.figure = None self._mouseover_set = _OrderedSet() self.child_axes = [] self._current_image = None # strictly for pyplot via _sci, _gci self._projection_init = None # strictly for pyplot.subplot self.legend_ = None self.containers = [] self.grid(False) # Disable grid on init to use rcParameter self.grid(self._gridOn, which=mpl.rcParams['axes.grid.which'], axis=mpl.rcParams['axes.grid.axis']) props = font_manager.FontProperties( size=mpl.rcParams['axes.titlesize'], weight=mpl.rcParams['axes.titleweight']) y = mpl.rcParams['axes.titley'] if y is None: y = 1.0 self._autotitlepos = True else: self._autotitlepos = False self.title = mtext.Text( x=0.5, y=y, text='', fontproperties=props, verticalalignment='baseline', horizontalalignment='center', ) self._left_title = mtext.Text( x=0.0, y=y, text='', fontproperties=props.copy(), verticalalignment='baseline', horizontalalignment='left', ) self._right_title = mtext.Text( x=1.0, y=y, text='', fontproperties=props.copy(), verticalalignment='baseline', horizontalalignment='right', ) title_offset_points = mpl.rcParams['axes.titlepad'] # refactor this out so it can be called in ax.set_title if # pad argument used... self._set_title_offset_trans(title_offset_points) for _title in (self.title, self._left_title, self._right_title): self._set_artist_props(_title) # The patch draws the background of the Axes. We want this to be below # the other artists. We use the frame to draw the edges so we are # setting the edgecolor to None. self.patch = self._gen_axes_patch() self.patch.set_figure(self.figure) self.patch.set_facecolor(self._facecolor) self.patch.set_edgecolor('none') self.patch.set_linewidth(0) self.patch.set_transform(self.transAxes) self.set_axis_on() self.xaxis.set_clip_path(self.patch) self.yaxis.set_clip_path(self.patch) if self._sharex is not None: self.xaxis.set_visible(xaxis_visible) self.patch.set_visible(patch_visible) if self._sharey is not None: self.yaxis.set_visible(yaxis_visible) self.patch.set_visible(patch_visible) # This comes last, as the call to _set_lim may trigger an autoscale (in # case of shared axes), requiring children to be already set up. for name, axis in self._axis_map.items(): share = getattr(self, f"_share{name}") if share is not None: getattr(self, f"share{name}")(share) else: # Although the scale was set to linear as part of clear, # polar requires that _set_scale is called again if self.name == "polar": axis._set_scale("linear") axis._set_lim(0, 1, auto=True) self._update_transScale() self.stale = True def clear(self): """Clear the Axes.""" # Act as an alias, or as the superclass implementation depending on the # subclass implementation. if self._subclass_uses_cla: self.cla() else: self.__clear() def cla(self): """Clear the Axes.""" # Act as an alias, or as the superclass implementation depending on the # subclass implementation. if self._subclass_uses_cla: self.__clear() else: self.clear() class ArtistList(Sequence): """ A sublist of Axes children based on their type. The type-specific children sublists were made immutable in Matplotlib 3.7. In the future these artist lists may be replaced by tuples. Use as if this is a tuple already. """ def __init__(self, axes, prop_name, valid_types=None, invalid_types=None): """ Parameters ---------- axes : `~matplotlib.axes.Axes` The Axes from which this sublist will pull the children Artists. prop_name : str The property name used to access this sublist from the Axes; used to generate deprecation warnings. valid_types : list of type, optional A list of types that determine which children will be returned by this sublist. If specified, then the Artists in the sublist must be instances of any of these types. If unspecified, then any type of Artist is valid (unless limited by *invalid_types*.) invalid_types : tuple, optional A list of types that determine which children will *not* be returned by this sublist. If specified, then Artists in the sublist will never be an instance of these types. Otherwise, no types will be excluded. """ self._axes = axes self._prop_name = prop_name self._type_check = lambda artist: ( (not valid_types or isinstance(artist, valid_types)) and (not invalid_types or not isinstance(artist, invalid_types)) ) def __repr__(self): return f'' def __len__(self): return sum(self._type_check(artist) for artist in self._axes._children) def __iter__(self): for artist in list(self._axes._children): if self._type_check(artist): yield artist def __getitem__(self, key): return [artist for artist in self._axes._children if self._type_check(artist)][key] def __add__(self, other): if isinstance(other, (list, _AxesBase.ArtistList)): return [*self, *other] if isinstance(other, (tuple, _AxesBase.ArtistList)): return (*self, *other) return NotImplemented def __radd__(self, other): if isinstance(other, list): return other + list(self) if isinstance(other, tuple): return other + tuple(self) return NotImplemented @property def artists(self): return self.ArtistList(self, 'artists', invalid_types=( mcoll.Collection, mimage.AxesImage, mlines.Line2D, mpatches.Patch, mtable.Table, mtext.Text)) @property def collections(self): return self.ArtistList(self, 'collections', valid_types=mcoll.Collection) @property def images(self): return self.ArtistList(self, 'images', valid_types=mimage.AxesImage) @property def lines(self): return self.ArtistList(self, 'lines', valid_types=mlines.Line2D) @property def patches(self): return self.ArtistList(self, 'patches', valid_types=mpatches.Patch) @property def tables(self): return self.ArtistList(self, 'tables', valid_types=mtable.Table) @property def texts(self): return self.ArtistList(self, 'texts', valid_types=mtext.Text) def get_facecolor(self): """Get the facecolor of the Axes.""" return self.patch.get_facecolor() def set_facecolor(self, color): """ Set the facecolor of the Axes. Parameters ---------- color : color """ self._facecolor = color self.stale = True return self.patch.set_facecolor(color) def _set_title_offset_trans(self, title_offset_points): """ Set the offset for the title either from :rc:`axes.titlepad` or from set_title kwarg ``pad``. """ self.titleOffsetTrans = mtransforms.ScaledTranslation( 0.0, title_offset_points / 72, self.figure.dpi_scale_trans) for _title in (self.title, self._left_title, self._right_title): _title.set_transform(self.transAxes + self.titleOffsetTrans) _title.set_clip_box(None) def set_prop_cycle(self, *args, **kwargs): """ Set the property cycle of the Axes. The property cycle controls the style properties such as color, marker and linestyle of future plot commands. The style properties of data already added to the Axes are not modified. Call signatures:: set_prop_cycle(cycler) set_prop_cycle(label=values[, label2=values2[, ...]]) set_prop_cycle(label, values) Form 1 sets given `~cycler.Cycler` object. Form 2 creates a `~cycler.Cycler` which cycles over one or more properties simultaneously and set it as the property cycle of the Axes. If multiple properties are given, their value lists must have the same length. This is just a shortcut for explicitly creating a cycler and passing it to the function, i.e. it's short for ``set_prop_cycle(cycler(label=values label2=values2, ...))``. Form 3 creates a `~cycler.Cycler` for a single property and set it as the property cycle of the Axes. This form exists for compatibility with the original `cycler.cycler` interface. Its use is discouraged in favor of the kwarg form, i.e. ``set_prop_cycle(label=values)``. Parameters ---------- cycler : `~cycler.Cycler` Set the given Cycler. *None* resets to the cycle defined by the current style. .. ACCEPTS: `~cycler.Cycler` label : str The property key. Must be a valid `.Artist` property. For example, 'color' or 'linestyle'. Aliases are allowed, such as 'c' for 'color' and 'lw' for 'linewidth'. values : iterable Finite-length iterable of the property values. These values are validated and will raise a ValueError if invalid. See Also -------- matplotlib.rcsetup.cycler Convenience function for creating validated cyclers for properties. cycler.cycler The original function for creating unvalidated cyclers. Examples -------- Setting the property cycle for a single property: >>> ax.set_prop_cycle(color=['red', 'green', 'blue']) Setting the property cycle for simultaneously cycling over multiple properties (e.g. red circle, green plus, blue cross): >>> ax.set_prop_cycle(color=['red', 'green', 'blue'], ... marker=['o', '+', 'x']) """ if args and kwargs: raise TypeError("Cannot supply both positional and keyword " "arguments to this method.") # Can't do `args == (None,)` as that crashes cycler. if len(args) == 1 and args[0] is None: prop_cycle = None else: prop_cycle = cycler(*args, **kwargs) self._get_lines.set_prop_cycle(prop_cycle) self._get_patches_for_fill.set_prop_cycle(prop_cycle) def get_aspect(self): """ Return the aspect ratio of the axes scaling. This is either "auto" or a float giving the ratio of y/x-scale. """ return self._aspect def set_aspect(self, aspect, adjustable=None, anchor=None, share=False): """ Set the aspect ratio of the axes scaling, i.e. y/x-scale. Parameters ---------- aspect : {'auto', 'equal'} or float Possible values: - 'auto': fill the position rectangle with data. - 'equal': same as ``aspect=1``, i.e. same scaling for x and y. - *float*: The displayed size of 1 unit in y-data coordinates will be *aspect* times the displayed size of 1 unit in x-data coordinates; e.g. for ``aspect=2`` a square in data coordinates will be rendered with a height of twice its width. adjustable : None or {'box', 'datalim'}, optional If not ``None``, this defines which parameter will be adjusted to meet the required aspect. See `.set_adjustable` for further details. anchor : None or str or (float, float), optional If not ``None``, this defines where the Axes will be drawn if there is extra space due to aspect constraints. The most common way to specify the anchor are abbreviations of cardinal directions: ===== ===================== value description ===== ===================== 'C' centered 'SW' lower left corner 'S' middle of bottom edge 'SE' lower right corner etc. ===== ===================== See `~.Axes.set_anchor` for further details. share : bool, default: False If ``True``, apply the settings to all shared Axes. See Also -------- matplotlib.axes.Axes.set_adjustable Set how the Axes adjusts to achieve the required aspect ratio. matplotlib.axes.Axes.set_anchor Set the position in case of extra space. """ if cbook._str_equal(aspect, 'equal'): aspect = 1 if not cbook._str_equal(aspect, 'auto'): aspect = float(aspect) # raise ValueError if necessary if aspect <= 0 or not np.isfinite(aspect): raise ValueError("aspect must be finite and positive ") if share: axes = {sibling for name in self._axis_names for sibling in self._shared_axes[name].get_siblings(self)} else: axes = [self] for ax in axes: ax._aspect = aspect if adjustable is None: adjustable = self._adjustable self.set_adjustable(adjustable, share=share) # Handle sharing. if anchor is not None: self.set_anchor(anchor, share=share) self.stale = True def get_adjustable(self): """ Return whether the Axes will adjust its physical dimension ('box') or its data limits ('datalim') to achieve the desired aspect ratio. See Also -------- matplotlib.axes.Axes.set_adjustable Set how the Axes adjusts to achieve the required aspect ratio. matplotlib.axes.Axes.set_aspect For a description of aspect handling. """ return self._adjustable def set_adjustable(self, adjustable, share=False): """ Set how the Axes adjusts to achieve the required aspect ratio. Parameters ---------- adjustable : {'box', 'datalim'} If 'box', change the physical dimensions of the Axes. If 'datalim', change the ``x`` or ``y`` data limits. share : bool, default: False If ``True``, apply the settings to all shared Axes. See Also -------- matplotlib.axes.Axes.set_aspect For a description of aspect handling. Notes ----- Shared Axes (of which twinned Axes are a special case) impose restrictions on how aspect ratios can be imposed. For twinned Axes, use 'datalim'. For Axes that share both x and y, use 'box'. Otherwise, either 'datalim' or 'box' may be used. These limitations are partly a requirement to avoid over-specification, and partly a result of the particular implementation we are currently using, in which the adjustments for aspect ratios are done sequentially and independently on each Axes as it is drawn. """ _api.check_in_list(["box", "datalim"], adjustable=adjustable) if share: axs = {sibling for name in self._axis_names for sibling in self._shared_axes[name].get_siblings(self)} else: axs = [self] if (adjustable == "datalim" and any(getattr(ax.get_data_ratio, "__func__", None) != _AxesBase.get_data_ratio for ax in axs)): # Limits adjustment by apply_aspect assumes that the axes' aspect # ratio can be computed from the data limits and scales. raise ValueError("Cannot set Axes adjustable to 'datalim' for " "Axes which override 'get_data_ratio'") for ax in axs: ax._adjustable = adjustable self.stale = True def get_box_aspect(self): """ Return the Axes box aspect, i.e. the ratio of height to width. The box aspect is ``None`` (i.e. chosen depending on the available figure space) unless explicitly specified. See Also -------- matplotlib.axes.Axes.set_box_aspect for a description of box aspect. matplotlib.axes.Axes.set_aspect for a description of aspect handling. """ return self._box_aspect def set_box_aspect(self, aspect=None): """ Set the Axes box aspect, i.e. the ratio of height to width. This defines the aspect of the Axes in figure space and is not to be confused with the data aspect (see `~.Axes.set_aspect`). Parameters ---------- aspect : float or None Changes the physical dimensions of the Axes, such that the ratio of the Axes height to the Axes width in physical units is equal to *aspect*. Defining a box aspect will change the *adjustable* property to 'datalim' (see `~.Axes.set_adjustable`). *None* will disable a fixed box aspect so that height and width of the Axes are chosen independently. See Also -------- matplotlib.axes.Axes.set_aspect for a description of aspect handling. """ axs = {*self._twinned_axes.get_siblings(self), *self._twinned_axes.get_siblings(self)} if aspect is not None: aspect = float(aspect) # when box_aspect is set to other than ´None`, # adjustable must be "datalim" for ax in axs: ax.set_adjustable("datalim") for ax in axs: ax._box_aspect = aspect ax.stale = True def get_anchor(self): """ Get the anchor location. See Also -------- matplotlib.axes.Axes.set_anchor for a description of the anchor. matplotlib.axes.Axes.set_aspect for a description of aspect handling. """ return self._anchor def set_anchor(self, anchor, share=False): """ Define the anchor location. The actual drawing area (active position) of the Axes may be smaller than the Bbox (original position) when a fixed aspect is required. The anchor defines where the drawing area will be located within the available space. Parameters ---------- anchor : (float, float) or {'C', 'SW', 'S', 'SE', 'E', 'NE', ...} Either an (*x*, *y*) pair of relative coordinates (0 is left or bottom, 1 is right or top), 'C' (center), or a cardinal direction ('SW', southwest, is bottom left, etc.). str inputs are shorthands for (*x*, *y*) coordinates, as shown in the following diagram:: ┌─────────────────┬─────────────────┬─────────────────┐ │ 'NW' (0.0, 1.0) │ 'N' (0.5, 1.0) │ 'NE' (1.0, 1.0) │ ├─────────────────┼─────────────────┼─────────────────┤ │ 'W' (0.0, 0.5) │ 'C' (0.5, 0.5) │ 'E' (1.0, 0.5) │ ├─────────────────┼─────────────────┼─────────────────┤ │ 'SW' (0.0, 0.0) │ 'S' (0.5, 0.0) │ 'SE' (1.0, 0.0) │ └─────────────────┴─────────────────┴─────────────────┘ share : bool, default: False If ``True``, apply the settings to all shared Axes. See Also -------- matplotlib.axes.Axes.set_aspect for a description of aspect handling. """ if not (anchor in mtransforms.Bbox.coefs or len(anchor) == 2): raise ValueError('argument must be among %s' % ', '.join(mtransforms.Bbox.coefs)) if share: axes = {sibling for name in self._axis_names for sibling in self._shared_axes[name].get_siblings(self)} else: axes = [self] for ax in axes: ax._anchor = anchor self.stale = True def get_data_ratio(self): """ Return the aspect ratio of the scaled data. Notes ----- This method is intended to be overridden by new projection types. """ txmin, txmax = self.xaxis.get_transform().transform(self.get_xbound()) tymin, tymax = self.yaxis.get_transform().transform(self.get_ybound()) xsize = max(abs(txmax - txmin), 1e-30) ysize = max(abs(tymax - tymin), 1e-30) return ysize / xsize def apply_aspect(self, position=None): """ Adjust the Axes for a specified data aspect ratio. Depending on `.get_adjustable` this will modify either the Axes box (position) or the view limits. In the former case, `~matplotlib.axes.Axes.get_anchor` will affect the position. Parameters ---------- position : None or .Bbox If not ``None``, this defines the position of the Axes within the figure as a Bbox. See `~.Axes.get_position` for further details. Notes ----- This is called automatically when each Axes is drawn. You may need to call it yourself if you need to update the Axes position and/or view limits before the Figure is drawn. See Also -------- matplotlib.axes.Axes.set_aspect For a description of aspect ratio handling. matplotlib.axes.Axes.set_adjustable Set how the Axes adjusts to achieve the required aspect ratio. matplotlib.axes.Axes.set_anchor Set the position in case of extra space. """ if position is None: position = self.get_position(original=True) aspect = self.get_aspect() if aspect == 'auto' and self._box_aspect is None: self._set_position(position, which='active') return trans = self.get_figure().transSubfigure bb = mtransforms.Bbox.unit().transformed(trans) # this is the physical aspect of the panel (or figure): fig_aspect = bb.height / bb.width if self._adjustable == 'box': if self in self._twinned_axes: raise RuntimeError("Adjustable 'box' is not allowed in a " "twinned Axes; use 'datalim' instead") box_aspect = aspect * self.get_data_ratio() pb = position.frozen() pb1 = pb.shrunk_to_aspect(box_aspect, pb, fig_aspect) self._set_position(pb1.anchored(self.get_anchor(), pb), 'active') return # The following is only seen if self._adjustable == 'datalim' if self._box_aspect is not None: pb = position.frozen() pb1 = pb.shrunk_to_aspect(self._box_aspect, pb, fig_aspect) self._set_position(pb1.anchored(self.get_anchor(), pb), 'active') if aspect == "auto": return # reset active to original in case it had been changed by prior use # of 'box' if self._box_aspect is None: self._set_position(position, which='active') else: position = pb1.anchored(self.get_anchor(), pb) x_trf = self.xaxis.get_transform() y_trf = self.yaxis.get_transform() xmin, xmax = x_trf.transform(self.get_xbound()) ymin, ymax = y_trf.transform(self.get_ybound()) xsize = max(abs(xmax - xmin), 1e-30) ysize = max(abs(ymax - ymin), 1e-30) box_aspect = fig_aspect * (position.height / position.width) data_ratio = box_aspect / aspect y_expander = data_ratio * xsize / ysize - 1 # If y_expander > 0, the dy/dx viewLim ratio needs to increase if abs(y_expander) < 0.005: return dL = self.dataLim x0, x1 = x_trf.transform(dL.intervalx) y0, y1 = y_trf.transform(dL.intervaly) xr = 1.05 * (x1 - x0) yr = 1.05 * (y1 - y0) xmarg = xsize - xr ymarg = ysize - yr Ysize = data_ratio * xsize Xsize = ysize / data_ratio Xmarg = Xsize - xr Ymarg = Ysize - yr # Setting these targets to, e.g., 0.05*xr does not seem to help. xm = 0 ym = 0 shared_x = self in self._shared_axes["x"] shared_y = self in self._shared_axes["y"] if shared_x and shared_y: raise RuntimeError("set_aspect(..., adjustable='datalim') or " "axis('equal') are not allowed when both axes " "are shared. Try set_aspect(..., " "adjustable='box').") # If y is shared, then we are only allowed to change x, etc. if shared_y: adjust_y = False else: if xmarg > xm and ymarg > ym: adjy = ((Ymarg > 0 and y_expander < 0) or (Xmarg < 0 and y_expander > 0)) else: adjy = y_expander > 0 adjust_y = shared_x or adjy # (Ymarg > xmarg) if adjust_y: yc = 0.5 * (ymin + ymax) y0 = yc - Ysize / 2.0 y1 = yc + Ysize / 2.0 self.set_ybound(y_trf.inverted().transform([y0, y1])) else: xc = 0.5 * (xmin + xmax) x0 = xc - Xsize / 2.0 x1 = xc + Xsize / 2.0 self.set_xbound(x_trf.inverted().transform([x0, x1])) def axis(self, arg=None, /, *, emit=True, **kwargs): """ Convenience method to get or set some axis properties. Call signatures:: xmin, xmax, ymin, ymax = axis() xmin, xmax, ymin, ymax = axis([xmin, xmax, ymin, ymax]) xmin, xmax, ymin, ymax = axis(option) xmin, xmax, ymin, ymax = axis(**kwargs) Parameters ---------- xmin, xmax, ymin, ymax : float, optional The axis limits to be set. This can also be achieved using :: ax.set(xlim=(xmin, xmax), ylim=(ymin, ymax)) option : bool or str If a bool, turns axis lines and labels on or off. If a string, possible values are: ================ =========================================================== Value Description ================ =========================================================== 'off' or `False` Hide all axis decorations, i.e. axis labels, spines, tick marks, tick labels, and grid lines. This is the same as `~.Axes.set_axis_off()`. 'on' or `True` Do not hide all axis decorations, i.e. axis labels, spines, tick marks, tick labels, and grid lines. This is the same as `~.Axes.set_axis_on()`. 'equal' Set equal scaling (i.e., make circles circular) by changing the axis limits. This is the same as ``ax.set_aspect('equal', adjustable='datalim')``. Explicit data limits may not be respected in this case. 'scaled' Set equal scaling (i.e., make circles circular) by changing dimensions of the plot box. This is the same as ``ax.set_aspect('equal', adjustable='box', anchor='C')``. Additionally, further autoscaling will be disabled. 'tight' Set limits just large enough to show all data, then disable further autoscaling. 'auto' Automatic scaling (fill plot box with data). 'image' 'scaled' with axis limits equal to data limits. 'square' Square plot; similar to 'scaled', but initially forcing ``xmax-xmin == ymax-ymin``. ================ =========================================================== emit : bool, default: True Whether observers are notified of the axis limit change. This option is passed on to `~.Axes.set_xlim` and `~.Axes.set_ylim`. Returns ------- xmin, xmax, ymin, ymax : float The axis limits. See Also -------- matplotlib.axes.Axes.set_xlim matplotlib.axes.Axes.set_ylim Notes ----- For 3D axes, this method additionally takes *zmin*, *zmax* as parameters and likewise returns them. """ if isinstance(arg, (str, bool)): if arg is True: arg = 'on' if arg is False: arg = 'off' arg = arg.lower() if arg == 'on': self.set_axis_on() elif arg == 'off': self.set_axis_off() elif arg in [ 'equal', 'tight', 'scaled', 'auto', 'image', 'square']: self.set_autoscale_on(True) self.set_aspect('auto') self.autoscale_view(tight=False) if arg == 'equal': self.set_aspect('equal', adjustable='datalim') elif arg == 'scaled': self.set_aspect('equal', adjustable='box', anchor='C') self.set_autoscale_on(False) # Req. by Mark Bakker elif arg == 'tight': self.autoscale_view(tight=True) self.set_autoscale_on(False) elif arg == 'image': self.autoscale_view(tight=True) self.set_autoscale_on(False) self.set_aspect('equal', adjustable='box', anchor='C') elif arg == 'square': self.set_aspect('equal', adjustable='box', anchor='C') self.set_autoscale_on(False) xlim = self.get_xlim() ylim = self.get_ylim() edge_size = max(np.diff(xlim), np.diff(ylim))[0] self.set_xlim([xlim[0], xlim[0] + edge_size], emit=emit, auto=False) self.set_ylim([ylim[0], ylim[0] + edge_size], emit=emit, auto=False) else: raise ValueError(f"Unrecognized string {arg!r} to axis; " "try 'on' or 'off'") else: if arg is not None: if len(arg) != 2*len(self._axis_names): raise TypeError( "The first argument to axis() must be an iterable of the form " "[{}]".format(", ".join( f"{name}min, {name}max" for name in self._axis_names))) limits = { name: arg[2*i:2*(i+1)] for i, name in enumerate(self._axis_names) } else: limits = {} for name in self._axis_names: ax_min = kwargs.pop(f'{name}min', None) ax_max = kwargs.pop(f'{name}max', None) limits[name] = (ax_min, ax_max) for name, (ax_min, ax_max) in limits.items(): ax_auto = (None # Keep autoscale state as is. if ax_min is None and ax_max is None else False) # Turn off autoscale. set_ax_lim = getattr(self, f'set_{name}lim') set_ax_lim(ax_min, ax_max, emit=emit, auto=ax_auto) if kwargs: raise _api.kwarg_error("axis", kwargs) lims = () for name in self._axis_names: get_ax_lim = getattr(self, f'get_{name}lim') lims += get_ax_lim() return lims def get_legend(self): """Return the `.Legend` instance, or None if no legend is defined.""" return self.legend_ def get_images(self): r"""Return a list of `.AxesImage`\s contained by the Axes.""" return cbook.silent_list('AxesImage', self.images) def get_lines(self): """Return a list of lines contained by the Axes.""" return cbook.silent_list('Line2D', self.lines) def get_xaxis(self): """ [*Discouraged*] Return the XAxis instance. .. admonition:: Discouraged The use of this function is discouraged. You should instead directly access the attribute ``ax.xaxis``. """ return self.xaxis def get_yaxis(self): """ [*Discouraged*] Return the YAxis instance. .. admonition:: Discouraged The use of this function is discouraged. You should instead directly access the attribute ``ax.yaxis``. """ return self.yaxis get_xgridlines = _axis_method_wrapper("xaxis", "get_gridlines") get_xticklines = _axis_method_wrapper("xaxis", "get_ticklines") get_ygridlines = _axis_method_wrapper("yaxis", "get_gridlines") get_yticklines = _axis_method_wrapper("yaxis", "get_ticklines") # Adding and tracking artists def _sci(self, im): """ Set the current image. This image will be the target of colormap functions like ``pyplot.viridis``, and other functions such as `~.pyplot.clim`. The current image is an attribute of the current Axes. """ _api.check_isinstance((mcoll.Collection, mimage.AxesImage), im=im) if im not in self._children: raise ValueError("Argument must be an image or collection in this Axes") self._current_image = im def _gci(self): """Helper for `~matplotlib.pyplot.gci`; do not use elsewhere.""" return self._current_image def has_data(self): """ Return whether any artists have been added to the Axes. This should not be used to determine whether the *dataLim* need to be updated, and may not actually be useful for anything. """ return any(isinstance(a, (mcoll.Collection, mimage.AxesImage, mlines.Line2D, mpatches.Patch)) for a in self._children) def add_artist(self, a): """ Add an `.Artist` to the Axes; return the artist. Use `add_artist` only for artists for which there is no dedicated "add" method; and if necessary, use a method such as `update_datalim` to manually update the dataLim if the artist is to be included in autoscaling. If no ``transform`` has been specified when creating the artist (e.g. ``artist.get_transform() == None``) then the transform is set to ``ax.transData``. """ a.axes = self self._children.append(a) a._remove_method = self._children.remove self._set_artist_props(a) if a.get_clip_path() is None: a.set_clip_path(self.patch) self.stale = True return a def add_child_axes(self, ax): """ Add an `.AxesBase` to the Axes' children; return the child Axes. This is the lowlevel version. See `.axes.Axes.inset_axes`. """ # normally Axes have themselves as the Axes, but these need to have # their parent... # Need to bypass the getter... ax._axes = self ax.stale_callback = martist._stale_axes_callback self.child_axes.append(ax) ax._remove_method = functools.partial( self.figure._remove_axes, owners=[self.child_axes]) self.stale = True return ax def add_collection(self, collection, autolim=True): """ Add a `.Collection` to the Axes; return the collection. """ _api.check_isinstance(mcoll.Collection, collection=collection) if not collection.get_label(): collection.set_label(f'_child{len(self._children)}') self._children.append(collection) collection._remove_method = self._children.remove self._set_artist_props(collection) if collection.get_clip_path() is None: collection.set_clip_path(self.patch) if autolim: # Make sure viewLim is not stale (mostly to match # pre-lazy-autoscale behavior, which is not really better). self._unstale_viewLim() datalim = collection.get_datalim(self.transData) points = datalim.get_points() if not np.isinf(datalim.minpos).all(): # By definition, if minpos (minimum positive value) is set # (i.e., non-inf), then min(points) <= minpos <= max(points), # and minpos would be superfluous. However, we add minpos to # the call so that self.dataLim will update its own minpos. # This ensures that log scales see the correct minimum. points = np.concatenate([points, [datalim.minpos]]) self.update_datalim(points) self.stale = True return collection def add_image(self, image): """ Add an `.AxesImage` to the Axes; return the image. """ _api.check_isinstance(mimage.AxesImage, image=image) self._set_artist_props(image) if not image.get_label(): image.set_label(f'_child{len(self._children)}') self._children.append(image) image._remove_method = self._children.remove self.stale = True return image def _update_image_limits(self, image): xmin, xmax, ymin, ymax = image.get_extent() self.axes.update_datalim(((xmin, ymin), (xmax, ymax))) def add_line(self, line): """ Add a `.Line2D` to the Axes; return the line. """ _api.check_isinstance(mlines.Line2D, line=line) self._set_artist_props(line) if line.get_clip_path() is None: line.set_clip_path(self.patch) self._update_line_limits(line) if not line.get_label(): line.set_label(f'_child{len(self._children)}') self._children.append(line) line._remove_method = self._children.remove self.stale = True return line def _add_text(self, txt): """ Add a `.Text` to the Axes; return the text. """ _api.check_isinstance(mtext.Text, txt=txt) self._set_artist_props(txt) self._children.append(txt) txt._remove_method = self._children.remove self.stale = True return txt def _update_line_limits(self, line): """ Figures out the data limit of the given line, updating self.dataLim. """ path = line.get_path() if path.vertices.size == 0: return line_trf = line.get_transform() if line_trf == self.transData: data_path = path elif any(line_trf.contains_branch_seperately(self.transData)): # Compute the transform from line coordinates to data coordinates. trf_to_data = line_trf - self.transData # If transData is affine we can use the cached non-affine component # of line's path (since the non-affine part of line_trf is # entirely encapsulated in trf_to_data). if self.transData.is_affine: line_trans_path = line._get_transformed_path() na_path, _ = line_trans_path.get_transformed_path_and_affine() data_path = trf_to_data.transform_path_affine(na_path) else: data_path = trf_to_data.transform_path(path) else: # For backwards compatibility we update the dataLim with the # coordinate range of the given path, even though the coordinate # systems are completely different. This may occur in situations # such as when ax.transAxes is passed through for absolute # positioning. data_path = path if not data_path.vertices.size: return updatex, updatey = line_trf.contains_branch_seperately(self.transData) if self.name != "rectilinear": # This block is mostly intended to handle axvline in polar plots, # for which updatey would otherwise be True. if updatex and line_trf == self.get_yaxis_transform(): updatex = False if updatey and line_trf == self.get_xaxis_transform(): updatey = False self.dataLim.update_from_path(data_path, self.ignore_existing_data_limits, updatex=updatex, updatey=updatey) self.ignore_existing_data_limits = False def add_patch(self, p): """ Add a `.Patch` to the Axes; return the patch. """ _api.check_isinstance(mpatches.Patch, p=p) self._set_artist_props(p) if p.get_clip_path() is None: p.set_clip_path(self.patch) self._update_patch_limits(p) self._children.append(p) p._remove_method = self._children.remove return p def _update_patch_limits(self, patch): """Update the data limits for the given patch.""" # hist can add zero height Rectangles, which is useful to keep # the bins, counts and patches lined up, but it throws off log # scaling. We'll ignore rects with zero height or width in # the auto-scaling # cannot check for '==0' since unitized data may not compare to zero # issue #2150 - we update the limits if patch has non zero width # or height. if (isinstance(patch, mpatches.Rectangle) and ((not patch.get_width()) and (not patch.get_height()))): return p = patch.get_path() # Get all vertices on the path # Loop through each segment to get extrema for Bezier curve sections vertices = [] for curve, code in p.iter_bezier(simplify=False): # Get distance along the curve of any extrema _, dzeros = curve.axis_aligned_extrema() # Calculate vertices of start, end and any extrema in between vertices.append(curve([0, *dzeros, 1])) if len(vertices): vertices = np.vstack(vertices) patch_trf = patch.get_transform() updatex, updatey = patch_trf.contains_branch_seperately(self.transData) if not (updatex or updatey): return if self.name != "rectilinear": # As in _update_line_limits, but for axvspan. if updatex and patch_trf == self.get_yaxis_transform(): updatex = False if updatey and patch_trf == self.get_xaxis_transform(): updatey = False trf_to_data = patch_trf - self.transData xys = trf_to_data.transform(vertices) self.update_datalim(xys, updatex=updatex, updatey=updatey) def add_table(self, tab): """ Add a `.Table` to the Axes; return the table. """ _api.check_isinstance(mtable.Table, tab=tab) self._set_artist_props(tab) self._children.append(tab) if tab.get_clip_path() is None: tab.set_clip_path(self.patch) tab._remove_method = self._children.remove return tab def add_container(self, container): """ Add a `.Container` to the Axes' containers; return the container. """ label = container.get_label() if not label: container.set_label('_container%d' % len(self.containers)) self.containers.append(container) container._remove_method = self.containers.remove return container def _unit_change_handler(self, axis_name, event=None): """ Process axis units changes: requests updates to data and view limits. """ if event is None: # Allow connecting `self._unit_change_handler(name)` return functools.partial( self._unit_change_handler, axis_name, event=object()) _api.check_in_list(self._axis_map, axis_name=axis_name) for line in self.lines: line.recache_always() self.relim() self._request_autoscale_view(axis_name) def relim(self, visible_only=False): """ Recompute the data limits based on current artists. At present, `.Collection` instances are not supported. Parameters ---------- visible_only : bool, default: False Whether to exclude invisible artists. """ # Collections are deliberately not supported (yet); see # the TODO note in artists.py. self.dataLim.ignore(True) self.dataLim.set_points(mtransforms.Bbox.null().get_points()) self.ignore_existing_data_limits = True for artist in self._children: if not visible_only or artist.get_visible(): if isinstance(artist, mlines.Line2D): self._update_line_limits(artist) elif isinstance(artist, mpatches.Patch): self._update_patch_limits(artist) elif isinstance(artist, mimage.AxesImage): self._update_image_limits(artist) def update_datalim(self, xys, updatex=True, updatey=True): """ Extend the `~.Axes.dataLim` Bbox to include the given points. If no data is set currently, the Bbox will ignore its limits and set the bound to be the bounds of the xydata (*xys*). Otherwise, it will compute the bounds of the union of its current data and the data in *xys*. Parameters ---------- xys : 2D array-like The points to include in the data limits Bbox. This can be either a list of (x, y) tuples or a (N, 2) array. updatex, updatey : bool, default: True Whether to update the x/y limits. """ xys = np.asarray(xys) if not np.any(np.isfinite(xys)): return self.dataLim.update_from_data_xy(xys, self.ignore_existing_data_limits, updatex=updatex, updatey=updatey) self.ignore_existing_data_limits = False def _process_unit_info(self, datasets=None, kwargs=None, *, convert=True): """ Set axis units based on *datasets* and *kwargs*, and optionally apply unit conversions to *datasets*. Parameters ---------- datasets : list List of (axis_name, dataset) pairs (where the axis name is defined as in `._axis_map`). Individual datasets can also be None (which gets passed through). kwargs : dict Other parameters from which unit info (i.e., the *xunits*, *yunits*, *zunits* (for 3D Axes), *runits* and *thetaunits* (for polar) entries) is popped, if present. Note that this dict is mutated in-place! convert : bool, default: True Whether to return the original datasets or the converted ones. Returns ------- list Either the original datasets if *convert* is False, or the converted ones if *convert* is True (the default). """ # The API makes datasets a list of pairs rather than an axis_name to # dataset mapping because it is sometimes necessary to process multiple # datasets for a single axis, and concatenating them may be tricky # (e.g. if some are scalars, etc.). datasets = datasets or [] kwargs = kwargs or {} axis_map = self._axis_map for axis_name, data in datasets: try: axis = axis_map[axis_name] except KeyError: raise ValueError(f"Invalid axis name: {axis_name!r}") from None # Update from data if axis is already set but no unit is set yet. if axis is not None and data is not None and not axis.have_units(): axis.update_units(data) for axis_name, axis in axis_map.items(): # Return if no axis is set. if axis is None: continue # Check for units in the kwargs, and if present update axis. units = kwargs.pop(f"{axis_name}units", axis.units) if self.name == "polar": # Special case: polar supports "thetaunits"/"runits". polar_units = {"x": "thetaunits", "y": "runits"} units = kwargs.pop(polar_units[axis_name], units) if units != axis.units and units is not None: axis.set_units(units) # If the units being set imply a different converter, # we need to update again. for dataset_axis_name, data in datasets: if dataset_axis_name == axis_name and data is not None: axis.update_units(data) return [axis_map[axis_name].convert_units(data) if convert and data is not None else data for axis_name, data in datasets] def in_axes(self, mouseevent): """ Return whether the given event (in display coords) is in the Axes. """ return self.patch.contains(mouseevent)[0] get_autoscalex_on = _axis_method_wrapper("xaxis", "_get_autoscale_on") get_autoscaley_on = _axis_method_wrapper("yaxis", "_get_autoscale_on") set_autoscalex_on = _axis_method_wrapper("xaxis", "_set_autoscale_on") set_autoscaley_on = _axis_method_wrapper("yaxis", "_set_autoscale_on") def get_autoscale_on(self): """Return True if each axis is autoscaled, False otherwise.""" return all(axis._get_autoscale_on() for axis in self._axis_map.values()) def set_autoscale_on(self, b): """ Set whether autoscaling is applied to each axis on the next draw or call to `.Axes.autoscale_view`. Parameters ---------- b : bool """ for axis in self._axis_map.values(): axis._set_autoscale_on(b) @property def use_sticky_edges(self): """ When autoscaling, whether to obey all `Artist.sticky_edges`. Default is ``True``. Setting this to ``False`` ensures that the specified margins will be applied, even if the plot includes an image, for example, which would otherwise force a view limit to coincide with its data limit. The changing this property does not change the plot until `autoscale` or `autoscale_view` is called. """ return self._use_sticky_edges @use_sticky_edges.setter def use_sticky_edges(self, b): self._use_sticky_edges = bool(b) # No effect until next autoscaling, which will mark the Axes as stale. def set_xmargin(self, m): """ Set padding of X data limits prior to autoscaling. *m* times the data interval will be added to each end of that interval before it is used in autoscaling. If *m* is negative, this will clip the data range instead of expanding it. For example, if your data is in the range [0, 2], a margin of 0.1 will result in a range [-0.2, 2.2]; a margin of -0.1 will result in a range of [0.2, 1.8]. Parameters ---------- m : float greater than -0.5 """ if m <= -0.5: raise ValueError("margin must be greater than -0.5") self._xmargin = m self._request_autoscale_view("x") self.stale = True def set_ymargin(self, m): """ Set padding of Y data limits prior to autoscaling. *m* times the data interval will be added to each end of that interval before it is used in autoscaling. If *m* is negative, this will clip the data range instead of expanding it. For example, if your data is in the range [0, 2], a margin of 0.1 will result in a range [-0.2, 2.2]; a margin of -0.1 will result in a range of [0.2, 1.8]. Parameters ---------- m : float greater than -0.5 """ if m <= -0.5: raise ValueError("margin must be greater than -0.5") self._ymargin = m self._request_autoscale_view("y") self.stale = True def margins(self, *margins, x=None, y=None, tight=True): """ Set or retrieve autoscaling margins. The padding added to each limit of the Axes is the *margin* times the data interval. All input parameters must be floats greater than -0.5. Passing both positional and keyword arguments is invalid and will raise a TypeError. If no arguments (positional or otherwise) are provided, the current margins will remain unchanged and simply be returned. Specifying any margin changes only the autoscaling; for example, if *xmargin* is not None, then *xmargin* times the X data interval will be added to each end of that interval before it is used in autoscaling. Parameters ---------- *margins : float, optional If a single positional argument is provided, it specifies both margins of the x-axis and y-axis limits. If two positional arguments are provided, they will be interpreted as *xmargin*, *ymargin*. If setting the margin on a single axis is desired, use the keyword arguments described below. x, y : float, optional Specific margin values for the x-axis and y-axis, respectively. These cannot be used with positional arguments, but can be used individually to alter on e.g., only the y-axis. tight : bool or None, default: True The *tight* parameter is passed to `~.axes.Axes.autoscale_view`, which is executed after a margin is changed; the default here is *True*, on the assumption that when margins are specified, no additional padding to match tick marks is usually desired. Setting *tight* to *None* preserves the previous setting. Returns ------- xmargin, ymargin : float Notes ----- If a previously used Axes method such as :meth:`pcolor` has set :attr:`use_sticky_edges` to `True`, only the limits not set by the "sticky artists" will be modified. To force all of the margins to be set, set :attr:`use_sticky_edges` to `False` before calling :meth:`margins`. """ if margins and (x is not None or y is not None): raise TypeError('Cannot pass both positional and keyword ' 'arguments for x and/or y.') elif len(margins) == 1: x = y = margins[0] elif len(margins) == 2: x, y = margins elif margins: raise TypeError('Must pass a single positional argument for all ' 'margins, or one for each margin (x, y).') if x is None and y is None: if tight is not True: _api.warn_external(f'ignoring tight={tight!r} in get mode') return self._xmargin, self._ymargin if tight is not None: self._tight = tight if x is not None: self.set_xmargin(x) if y is not None: self.set_ymargin(y) def set_rasterization_zorder(self, z): """ Set the zorder threshold for rasterization for vector graphics output. All artists with a zorder below the given value will be rasterized if they support rasterization. This setting is ignored for pixel-based output. See also :doc:`/gallery/misc/rasterization_demo`. Parameters ---------- z : float or None The zorder below which artists are rasterized. If ``None`` rasterization based on zorder is deactivated. """ self._rasterization_zorder = z self.stale = True def get_rasterization_zorder(self): """Return the zorder value below which artists will be rasterized.""" return self._rasterization_zorder def autoscale(self, enable=True, axis='both', tight=None): """ Autoscale the axis view to the data (toggle). Convenience method for simple axis view autoscaling. It turns autoscaling on or off, and then, if autoscaling for either axis is on, it performs the autoscaling on the specified axis or Axes. Parameters ---------- enable : bool or None, default: True True turns autoscaling on, False turns it off. None leaves the autoscaling state unchanged. axis : {'both', 'x', 'y'}, default: 'both' The axis on which to operate. (For 3D Axes, *axis* can also be set to 'z', and 'both' refers to all three axes.) tight : bool or None, default: None If True, first set the margins to zero. Then, this argument is forwarded to `~.axes.Axes.autoscale_view` (regardless of its value); see the description of its behavior there. """ if enable is None: scalex = True scaley = True else: if axis in ['x', 'both']: self.set_autoscalex_on(bool(enable)) scalex = self.get_autoscalex_on() else: scalex = False if axis in ['y', 'both']: self.set_autoscaley_on(bool(enable)) scaley = self.get_autoscaley_on() else: scaley = False if tight and scalex: self._xmargin = 0 if tight and scaley: self._ymargin = 0 if scalex: self._request_autoscale_view("x", tight=tight) if scaley: self._request_autoscale_view("y", tight=tight) def autoscale_view(self, tight=None, scalex=True, scaley=True): """ Autoscale the view limits using the data limits. Parameters ---------- tight : bool or None If *True*, only expand the axis limits using the margins. Note that unlike for `autoscale`, ``tight=True`` does *not* set the margins to zero. If *False* and :rc:`axes.autolimit_mode` is 'round_numbers', then after expansion by the margins, further expand the axis limits using the axis major locator. If None (the default), reuse the value set in the previous call to `autoscale_view` (the initial value is False, but the default style sets :rc:`axes.autolimit_mode` to 'data', in which case this behaves like True). scalex : bool, default: True Whether to autoscale the x-axis. scaley : bool, default: True Whether to autoscale the y-axis. Notes ----- The autoscaling preserves any preexisting axis direction reversal. The data limits are not updated automatically when artist data are changed after the artist has been added to an Axes instance. In that case, use :meth:`matplotlib.axes.Axes.relim` prior to calling autoscale_view. If the views of the Axes are fixed, e.g. via `set_xlim`, they will not be changed by autoscale_view(). See :meth:`matplotlib.axes.Axes.autoscale` for an alternative. """ if tight is not None: self._tight = bool(tight) x_stickies = y_stickies = np.array([]) if self.use_sticky_edges: if self._xmargin and scalex and self.get_autoscalex_on(): x_stickies = np.sort(np.concatenate([ artist.sticky_edges.x for ax in self._shared_axes["x"].get_siblings(self) for artist in ax.get_children()])) if self._ymargin and scaley and self.get_autoscaley_on(): y_stickies = np.sort(np.concatenate([ artist.sticky_edges.y for ax in self._shared_axes["y"].get_siblings(self) for artist in ax.get_children()])) if self.get_xscale() == 'log': x_stickies = x_stickies[x_stickies > 0] if self.get_yscale() == 'log': y_stickies = y_stickies[y_stickies > 0] def handle_single_axis( scale, shared_axes, name, axis, margin, stickies, set_bound): if not (scale and axis._get_autoscale_on()): return # nothing to do... shared = shared_axes.get_siblings(self) # Base autoscaling on finite data limits when there is at least one # finite data limit among all the shared_axes and intervals. values = [val for ax in shared for val in getattr(ax.dataLim, f"interval{name}") if np.isfinite(val)] if values: x0, x1 = (min(values), max(values)) elif getattr(self._viewLim, f"mutated{name}")(): # No data, but explicit viewLims already set: # in mutatedx or mutatedy. return else: x0, x1 = (-np.inf, np.inf) # If x0 and x1 are nonfinite, get default limits from the locator. locator = axis.get_major_locator() x0, x1 = locator.nonsingular(x0, x1) # Find the minimum minpos for use in the margin calculation. minimum_minpos = min( getattr(ax.dataLim, f"minpos{name}") for ax in shared) # Prevent margin addition from crossing a sticky value. A small # tolerance must be added due to floating point issues with # streamplot; it is defined relative to x0, x1, x1-x0 but has # no absolute term (e.g. "+1e-8") to avoid issues when working with # datasets where all values are tiny (less than 1e-8). tol = 1e-5 * max(abs(x0), abs(x1), abs(x1 - x0)) # Index of largest element < x0 + tol, if any. i0 = stickies.searchsorted(x0 + tol) - 1 x0bound = stickies[i0] if i0 != -1 else None # Index of smallest element > x1 - tol, if any. i1 = stickies.searchsorted(x1 - tol) x1bound = stickies[i1] if i1 != len(stickies) else None # Add the margin in figure space and then transform back, to handle # non-linear scales. transform = axis.get_transform() inverse_trans = transform.inverted() x0, x1 = axis._scale.limit_range_for_scale(x0, x1, minimum_minpos) x0t, x1t = transform.transform([x0, x1]) delta = (x1t - x0t) * margin if not np.isfinite(delta): delta = 0 # If a bound isn't finite, set margin to zero. x0, x1 = inverse_trans.transform([x0t - delta, x1t + delta]) # Apply sticky bounds. if x0bound is not None: x0 = max(x0, x0bound) if x1bound is not None: x1 = min(x1, x1bound) if not self._tight: x0, x1 = locator.view_limits(x0, x1) set_bound(x0, x1) # End of definition of internal function 'handle_single_axis'. handle_single_axis( scalex, self._shared_axes["x"], 'x', self.xaxis, self._xmargin, x_stickies, self.set_xbound) handle_single_axis( scaley, self._shared_axes["y"], 'y', self.yaxis, self._ymargin, y_stickies, self.set_ybound) def _update_title_position(self, renderer): """ Update the title position based on the bounding box enclosing all the ticklabels and x-axis spine and xlabel... """ if self._autotitlepos is not None and not self._autotitlepos: _log.debug('title position was updated manually, not adjusting') return titles = (self.title, self._left_title, self._right_title) # Need to check all our twins too, and all the children as well. axs = self._twinned_axes.get_siblings(self) + self.child_axes for ax in self.child_axes: # Child positions must be updated first. locator = ax.get_axes_locator() ax.apply_aspect(locator(self, renderer) if locator else None) for title in titles: x, _ = title.get_position() # need to start again in case of window resizing title.set_position((x, 1.0)) top = -np.inf for ax in axs: bb = None if (ax.xaxis.get_ticks_position() in ['top', 'unknown'] or ax.xaxis.get_label_position() == 'top'): bb = ax.xaxis.get_tightbbox(renderer) if bb is None: if 'outline' in ax.spines: # Special case for colorbars: bb = ax.spines['outline'].get_window_extent() else: bb = ax.get_window_extent(renderer) top = max(top, bb.ymax) if title.get_text(): ax.yaxis.get_tightbbox(renderer) # update offsetText if ax.yaxis.offsetText.get_text(): bb = ax.yaxis.offsetText.get_tightbbox(renderer) if bb.intersection(title.get_tightbbox(renderer), bb): top = bb.ymax if top < 0: # the top of Axes is not even on the figure, so don't try and # automatically place it. _log.debug('top of Axes not in the figure, so title not moved') return if title.get_window_extent(renderer).ymin < top: _, y = self.transAxes.inverted().transform((0, top)) title.set_position((x, y)) # empirically, this doesn't always get the min to top, # so we need to adjust again. if title.get_window_extent(renderer).ymin < top: _, y = self.transAxes.inverted().transform( (0., 2 * top - title.get_window_extent(renderer).ymin)) title.set_position((x, y)) ymax = max(title.get_position()[1] for title in titles) for title in titles: # now line up all the titles at the highest baseline. x, _ = title.get_position() title.set_position((x, ymax)) # Drawing @martist.allow_rasterization def draw(self, renderer): # docstring inherited if renderer is None: raise RuntimeError('No renderer defined') if not self.get_visible(): return self._unstale_viewLim() renderer.open_group('axes', gid=self.get_gid()) # prevent triggering call backs during the draw process self._stale = True # loop over self and child Axes... locator = self.get_axes_locator() self.apply_aspect(locator(self, renderer) if locator else None) artists = self.get_children() artists.remove(self.patch) # the frame draws the edges around the Axes patch -- we # decouple these so the patch can be in the background and the # frame in the foreground. Do this before drawing the axis # objects so that the spine has the opportunity to update them. if not (self.axison and self._frameon): for spine in self.spines.values(): artists.remove(spine) self._update_title_position(renderer) if not self.axison: for _axis in self._axis_map.values(): artists.remove(_axis) if not self.figure.canvas.is_saving(): artists = [ a for a in artists if not a.get_animated() or isinstance(a, mimage.AxesImage)] artists = sorted(artists, key=attrgetter('zorder')) # rasterize artists with negative zorder # if the minimum zorder is negative, start rasterization rasterization_zorder = self._rasterization_zorder if (rasterization_zorder is not None and artists and artists[0].zorder < rasterization_zorder): split_index = np.searchsorted( [art.zorder for art in artists], rasterization_zorder, side='right' ) artists_rasterized = artists[:split_index] artists = artists[split_index:] else: artists_rasterized = [] if self.axison and self._frameon: if artists_rasterized: artists_rasterized = [self.patch] + artists_rasterized else: artists = [self.patch] + artists if artists_rasterized: _draw_rasterized(self.figure, artists_rasterized, renderer) mimage._draw_list_compositing_images( renderer, self, artists, self.figure.suppressComposite) renderer.close_group('axes') self.stale = False def draw_artist(self, a): """ Efficiently redraw a single artist. """ a.draw(self.figure.canvas.get_renderer()) def redraw_in_frame(self): """ Efficiently redraw Axes data, but not axis ticks, labels, etc. """ with ExitStack() as stack: for artist in [*self._axis_map.values(), self.title, self._left_title, self._right_title]: stack.enter_context(artist._cm_set(visible=False)) self.draw(self.figure.canvas.get_renderer()) # Axes rectangle characteristics def get_frame_on(self): """Get whether the Axes rectangle patch is drawn.""" return self._frameon def set_frame_on(self, b): """ Set whether the Axes rectangle patch is drawn. Parameters ---------- b : bool """ self._frameon = b self.stale = True def get_axisbelow(self): """ Get whether axis ticks and gridlines are above or below most artists. Returns ------- bool or 'line' See Also -------- set_axisbelow """ return self._axisbelow def set_axisbelow(self, b): """ Set whether axis ticks and gridlines are above or below most artists. This controls the zorder of the ticks and gridlines. For more information on the zorder see :doc:`/gallery/misc/zorder_demo`. Parameters ---------- b : bool or 'line' Possible values: - *True* (zorder = 0.5): Ticks and gridlines are below all Artists. - 'line' (zorder = 1.5): Ticks and gridlines are above patches (e.g. rectangles, with default zorder = 1) but still below lines and markers (with their default zorder = 2). - *False* (zorder = 2.5): Ticks and gridlines are above patches and lines / markers. See Also -------- get_axisbelow """ # Check that b is True, False or 'line' self._axisbelow = axisbelow = validate_axisbelow(b) zorder = { True: 0.5, 'line': 1.5, False: 2.5, }[axisbelow] for axis in self._axis_map.values(): axis.set_zorder(zorder) self.stale = True @_docstring.dedent_interpd def grid(self, visible=None, which='major', axis='both', **kwargs): """ Configure the grid lines. Parameters ---------- visible : bool or None, optional Whether to show the grid lines. If any *kwargs* are supplied, it is assumed you want the grid on and *visible* will be set to True. If *visible* is *None* and there are no *kwargs*, this toggles the visibility of the lines. which : {'major', 'minor', 'both'}, optional The grid lines to apply the changes on. axis : {'both', 'x', 'y'}, optional The axis to apply the changes on. **kwargs : `~matplotlib.lines.Line2D` properties Define the line properties of the grid, e.g.:: grid(color='r', linestyle='-', linewidth=2) Valid keyword arguments are: %(Line2D:kwdoc)s Notes ----- The axis is drawn as a unit, so the effective zorder for drawing the grid is determined by the zorder of each axis, not by the zorder of the `.Line2D` objects comprising the grid. Therefore, to set grid zorder, use `.set_axisbelow` or, for more control, call the `~.Artist.set_zorder` method of each axis. """ _api.check_in_list(['x', 'y', 'both'], axis=axis) if axis in ['x', 'both']: self.xaxis.grid(visible, which=which, **kwargs) if axis in ['y', 'both']: self.yaxis.grid(visible, which=which, **kwargs) def ticklabel_format(self, *, axis='both', style='', scilimits=None, useOffset=None, useLocale=None, useMathText=None): r""" Configure the `.ScalarFormatter` used by default for linear Axes. If a parameter is not set, the corresponding property of the formatter is left unchanged. Parameters ---------- axis : {'x', 'y', 'both'}, default: 'both' The axis to configure. Only major ticks are affected. style : {'sci', 'scientific', 'plain'} Whether to use scientific notation. The formatter default is to use scientific notation. scilimits : pair of ints (m, n) Scientific notation is used only for numbers outside the range 10\ :sup:`m` to 10\ :sup:`n` (and only if the formatter is configured to use scientific notation at all). Use (0, 0) to include all numbers. Use (m, m) where m != 0 to fix the order of magnitude to 10\ :sup:`m`. The formatter default is :rc:`axes.formatter.limits`. useOffset : bool or float If True, the offset is calculated as needed. If False, no offset is used. If a numeric value, it sets the offset. The formatter default is :rc:`axes.formatter.useoffset`. useLocale : bool Whether to format the number using the current locale or using the C (English) locale. This affects e.g. the decimal separator. The formatter default is :rc:`axes.formatter.use_locale`. useMathText : bool Render the offset and scientific notation in mathtext. The formatter default is :rc:`axes.formatter.use_mathtext`. Raises ------ AttributeError If the current formatter is not a `.ScalarFormatter`. """ style = style.lower() axis = axis.lower() if scilimits is not None: try: m, n = scilimits m + n + 1 # check that both are numbers except (ValueError, TypeError) as err: raise ValueError("scilimits must be a sequence of 2 integers" ) from err STYLES = {'sci': True, 'scientific': True, 'plain': False, '': None} is_sci_style = _api.check_getitem(STYLES, style=style) axis_map = {**{k: [v] for k, v in self._axis_map.items()}, 'both': list(self._axis_map.values())} axises = _api.check_getitem(axis_map, axis=axis) try: for axis in axises: if is_sci_style is not None: axis.major.formatter.set_scientific(is_sci_style) if scilimits is not None: axis.major.formatter.set_powerlimits(scilimits) if useOffset is not None: axis.major.formatter.set_useOffset(useOffset) if useLocale is not None: axis.major.formatter.set_useLocale(useLocale) if useMathText is not None: axis.major.formatter.set_useMathText(useMathText) except AttributeError as err: raise AttributeError( "This method only works with the ScalarFormatter") from err def locator_params(self, axis='both', tight=None, **kwargs): """ Control behavior of major tick locators. Because the locator is involved in autoscaling, `~.Axes.autoscale_view` is called automatically after the parameters are changed. Parameters ---------- axis : {'both', 'x', 'y'}, default: 'both' The axis on which to operate. (For 3D Axes, *axis* can also be set to 'z', and 'both' refers to all three axes.) tight : bool or None, optional Parameter passed to `~.Axes.autoscale_view`. Default is None, for no change. Other Parameters ---------------- **kwargs Remaining keyword arguments are passed to directly to the ``set_params()`` method of the locator. Supported keywords depend on the type of the locator. See for example `~.ticker.MaxNLocator.set_params` for the `.ticker.MaxNLocator` used by default for linear. Examples -------- When plotting small subplots, one might want to reduce the maximum number of ticks and use tight bounds, for example:: ax.locator_params(tight=True, nbins=4) """ _api.check_in_list([*self._axis_names, "both"], axis=axis) for name in self._axis_names: if axis in [name, "both"]: loc = self._axis_map[name].get_major_locator() loc.set_params(**kwargs) self._request_autoscale_view(name, tight=tight) self.stale = True def tick_params(self, axis='both', **kwargs): """ Change the appearance of ticks, tick labels, and gridlines. Tick properties that are not explicitly set using the keyword arguments remain unchanged unless *reset* is True. For the current style settings, see `.Axis.get_tick_params`. Parameters ---------- axis : {'x', 'y', 'both'}, default: 'both' The axis to which the parameters are applied. which : {'major', 'minor', 'both'}, default: 'major' The group of ticks to which the parameters are applied. reset : bool, default: False Whether to reset the ticks to defaults before updating them. Other Parameters ---------------- direction : {'in', 'out', 'inout'} Puts ticks inside the Axes, outside the Axes, or both. length : float Tick length in points. width : float Tick width in points. color : color Tick color. pad : float Distance in points between tick and label. labelsize : float or str Tick label font size in points or as a string (e.g., 'large'). labelcolor : color Tick label color. labelfontfamily : str Tick label font. colors : color Tick color and label color. zorder : float Tick and label zorder. bottom, top, left, right : bool Whether to draw the respective ticks. labelbottom, labeltop, labelleft, labelright : bool Whether to draw the respective tick labels. labelrotation : float Tick label rotation grid_color : color Gridline color. grid_alpha : float Transparency of gridlines: 0 (transparent) to 1 (opaque). grid_linewidth : float Width of gridlines in points. grid_linestyle : str Any valid `.Line2D` line style spec. Examples -------- :: ax.tick_params(direction='out', length=6, width=2, colors='r', grid_color='r', grid_alpha=0.5) This will make all major ticks be red, pointing out of the box, and with dimensions 6 points by 2 points. Tick labels will also be red. Gridlines will be red and translucent. """ _api.check_in_list(['x', 'y', 'both'], axis=axis) if axis in ['x', 'both']: xkw = dict(kwargs) xkw.pop('left', None) xkw.pop('right', None) xkw.pop('labelleft', None) xkw.pop('labelright', None) self.xaxis.set_tick_params(**xkw) if axis in ['y', 'both']: ykw = dict(kwargs) ykw.pop('top', None) ykw.pop('bottom', None) ykw.pop('labeltop', None) ykw.pop('labelbottom', None) self.yaxis.set_tick_params(**ykw) def set_axis_off(self): """ Hide all visual components of the x- and y-axis. This sets a flag to suppress drawing of all axis decorations, i.e. axis labels, axis spines, and the axis tick component (tick markers, tick labels, and grid lines). Individual visibility settings of these components are ignored as long as `set_axis_off()` is in effect. """ self.axison = False self.stale = True def set_axis_on(self): """ Do not hide all visual components of the x- and y-axis. This reverts the effect of a prior `.set_axis_off()` call. Whether the individual axis decorations are drawn is controlled by their respective visibility settings. This is on by default. """ self.axison = True self.stale = True # data limits, ticks, tick labels, and formatting def get_xlabel(self): """ Get the xlabel text string. """ label = self.xaxis.get_label() return label.get_text() def set_xlabel(self, xlabel, fontdict=None, labelpad=None, *, loc=None, **kwargs): """ Set the label for the x-axis. Parameters ---------- xlabel : str The label text. labelpad : float, default: :rc:`axes.labelpad` Spacing in points from the Axes bounding box including ticks and tick labels. If None, the previous value is left as is. loc : {'left', 'center', 'right'}, default: :rc:`xaxis.labellocation` The label position. This is a high-level alternative for passing parameters *x* and *horizontalalignment*. Other Parameters ---------------- **kwargs : `~matplotlib.text.Text` properties `.Text` properties control the appearance of the label. See Also -------- text : Documents the properties supported by `.Text`. """ if labelpad is not None: self.xaxis.labelpad = labelpad protected_kw = ['x', 'horizontalalignment', 'ha'] if {*kwargs} & {*protected_kw}: if loc is not None: raise TypeError(f"Specifying 'loc' is disallowed when any of " f"its corresponding low level keyword " f"arguments ({protected_kw}) are also " f"supplied") else: loc = (loc if loc is not None else mpl.rcParams['xaxis.labellocation']) _api.check_in_list(('left', 'center', 'right'), loc=loc) x = { 'left': 0, 'center': 0.5, 'right': 1, }[loc] kwargs.update(x=x, horizontalalignment=loc) return self.xaxis.set_label_text(xlabel, fontdict, **kwargs) def invert_xaxis(self): """ Invert the x-axis. See Also -------- xaxis_inverted get_xlim, set_xlim get_xbound, set_xbound """ self.xaxis.set_inverted(not self.xaxis.get_inverted()) xaxis_inverted = _axis_method_wrapper("xaxis", "get_inverted") def get_xbound(self): """ Return the lower and upper x-axis bounds, in increasing order. See Also -------- set_xbound get_xlim, set_xlim invert_xaxis, xaxis_inverted """ left, right = self.get_xlim() if left < right: return left, right else: return right, left def set_xbound(self, lower=None, upper=None): """ Set the lower and upper numerical bounds of the x-axis. This method will honor axis inversion regardless of parameter order. It will not change the autoscaling setting (`.get_autoscalex_on()`). Parameters ---------- lower, upper : float or None The lower and upper bounds. If *None*, the respective axis bound is not modified. .. ACCEPTS: (lower: float, upper: float) See Also -------- get_xbound get_xlim, set_xlim invert_xaxis, xaxis_inverted """ if upper is None and np.iterable(lower): lower, upper = lower old_lower, old_upper = self.get_xbound() if lower is None: lower = old_lower if upper is None: upper = old_upper self.set_xlim(sorted((lower, upper), reverse=bool(self.xaxis_inverted())), auto=None) def get_xlim(self): """ Return the x-axis view limits. Returns ------- left, right : (float, float) The current x-axis limits in data coordinates. See Also -------- .Axes.set_xlim .Axes.set_xbound, .Axes.get_xbound .Axes.invert_xaxis, .Axes.xaxis_inverted Notes ----- The x-axis may be inverted, in which case the *left* value will be greater than the *right* value. """ return tuple(self.viewLim.intervalx) def _validate_converted_limits(self, limit, convert): """ Raise ValueError if converted limits are non-finite. Note that this function also accepts None as a limit argument. Returns ------- The limit value after call to convert(), or None if limit is None. """ if limit is not None: converted_limit = convert(limit) if isinstance(converted_limit, np.ndarray): converted_limit = converted_limit.squeeze() if (isinstance(converted_limit, Real) and not np.isfinite(converted_limit)): raise ValueError("Axis limits cannot be NaN or Inf") return converted_limit def set_xlim(self, left=None, right=None, *, emit=True, auto=False, xmin=None, xmax=None): """ Set the x-axis view limits. Parameters ---------- left : float, optional The left xlim in data coordinates. Passing *None* leaves the limit unchanged. The left and right xlims may also be passed as the tuple (*left*, *right*) as the first positional argument (or as the *left* keyword argument). .. ACCEPTS: (left: float, right: float) right : float, optional The right xlim in data coordinates. Passing *None* leaves the limit unchanged. emit : bool, default: True Whether to notify observers of limit change. auto : bool or None, default: False Whether to turn on autoscaling of the x-axis. True turns on, False turns off, None leaves unchanged. xmin, xmax : float, optional They are equivalent to left and right respectively, and it is an error to pass both *xmin* and *left* or *xmax* and *right*. Returns ------- left, right : (float, float) The new x-axis limits in data coordinates. See Also -------- get_xlim set_xbound, get_xbound invert_xaxis, xaxis_inverted Notes ----- The *left* value may be greater than the *right* value, in which case the x-axis values will decrease from left to right. Examples -------- >>> set_xlim(left, right) >>> set_xlim((left, right)) >>> left, right = set_xlim(left, right) One limit may be left unchanged. >>> set_xlim(right=right_lim) Limits may be passed in reverse order to flip the direction of the x-axis. For example, suppose *x* represents the number of years before present. The x-axis limits might be set like the following so 5000 years ago is on the left of the plot and the present is on the right. >>> set_xlim(5000, 0) """ if right is None and np.iterable(left): left, right = left if xmin is not None: if left is not None: raise TypeError("Cannot pass both 'left' and 'xmin'") left = xmin if xmax is not None: if right is not None: raise TypeError("Cannot pass both 'right' and 'xmax'") right = xmax return self.xaxis._set_lim(left, right, emit=emit, auto=auto) get_xscale = _axis_method_wrapper("xaxis", "get_scale") set_xscale = _axis_method_wrapper("xaxis", "_set_axes_scale") get_xticks = _axis_method_wrapper("xaxis", "get_ticklocs") set_xticks = _axis_method_wrapper("xaxis", "set_ticks", doc_sub={'set_ticks': 'set_xticks'}) get_xmajorticklabels = _axis_method_wrapper("xaxis", "get_majorticklabels") get_xminorticklabels = _axis_method_wrapper("xaxis", "get_minorticklabels") get_xticklabels = _axis_method_wrapper("xaxis", "get_ticklabels") set_xticklabels = _axis_method_wrapper( "xaxis", "set_ticklabels", doc_sub={"Axis.set_ticks": "Axes.set_xticks"}) def get_ylabel(self): """ Get the ylabel text string. """ label = self.yaxis.get_label() return label.get_text() def set_ylabel(self, ylabel, fontdict=None, labelpad=None, *, loc=None, **kwargs): """ Set the label for the y-axis. Parameters ---------- ylabel : str The label text. labelpad : float, default: :rc:`axes.labelpad` Spacing in points from the Axes bounding box including ticks and tick labels. If None, the previous value is left as is. loc : {'bottom', 'center', 'top'}, default: :rc:`yaxis.labellocation` The label position. This is a high-level alternative for passing parameters *y* and *horizontalalignment*. Other Parameters ---------------- **kwargs : `~matplotlib.text.Text` properties `.Text` properties control the appearance of the label. See Also -------- text : Documents the properties supported by `.Text`. """ if labelpad is not None: self.yaxis.labelpad = labelpad protected_kw = ['y', 'horizontalalignment', 'ha'] if {*kwargs} & {*protected_kw}: if loc is not None: raise TypeError(f"Specifying 'loc' is disallowed when any of " f"its corresponding low level keyword " f"arguments ({protected_kw}) are also " f"supplied") else: loc = (loc if loc is not None else mpl.rcParams['yaxis.labellocation']) _api.check_in_list(('bottom', 'center', 'top'), loc=loc) y, ha = { 'bottom': (0, 'left'), 'center': (0.5, 'center'), 'top': (1, 'right') }[loc] kwargs.update(y=y, horizontalalignment=ha) return self.yaxis.set_label_text(ylabel, fontdict, **kwargs) def invert_yaxis(self): """ Invert the y-axis. See Also -------- yaxis_inverted get_ylim, set_ylim get_ybound, set_ybound """ self.yaxis.set_inverted(not self.yaxis.get_inverted()) yaxis_inverted = _axis_method_wrapper("yaxis", "get_inverted") def get_ybound(self): """ Return the lower and upper y-axis bounds, in increasing order. See Also -------- set_ybound get_ylim, set_ylim invert_yaxis, yaxis_inverted """ bottom, top = self.get_ylim() if bottom < top: return bottom, top else: return top, bottom def set_ybound(self, lower=None, upper=None): """ Set the lower and upper numerical bounds of the y-axis. This method will honor axis inversion regardless of parameter order. It will not change the autoscaling setting (`.get_autoscaley_on()`). Parameters ---------- lower, upper : float or None The lower and upper bounds. If *None*, the respective axis bound is not modified. .. ACCEPTS: (lower: float, upper: float) See Also -------- get_ybound get_ylim, set_ylim invert_yaxis, yaxis_inverted """ if upper is None and np.iterable(lower): lower, upper = lower old_lower, old_upper = self.get_ybound() if lower is None: lower = old_lower if upper is None: upper = old_upper self.set_ylim(sorted((lower, upper), reverse=bool(self.yaxis_inverted())), auto=None) def get_ylim(self): """ Return the y-axis view limits. Returns ------- bottom, top : (float, float) The current y-axis limits in data coordinates. See Also -------- .Axes.set_ylim .Axes.set_ybound, .Axes.get_ybound .Axes.invert_yaxis, .Axes.yaxis_inverted Notes ----- The y-axis may be inverted, in which case the *bottom* value will be greater than the *top* value. """ return tuple(self.viewLim.intervaly) def set_ylim(self, bottom=None, top=None, *, emit=True, auto=False, ymin=None, ymax=None): """ Set the y-axis view limits. Parameters ---------- bottom : float, optional The bottom ylim in data coordinates. Passing *None* leaves the limit unchanged. The bottom and top ylims may also be passed as the tuple (*bottom*, *top*) as the first positional argument (or as the *bottom* keyword argument). .. ACCEPTS: (bottom: float, top: float) top : float, optional The top ylim in data coordinates. Passing *None* leaves the limit unchanged. emit : bool, default: True Whether to notify observers of limit change. auto : bool or None, default: False Whether to turn on autoscaling of the y-axis. *True* turns on, *False* turns off, *None* leaves unchanged. ymin, ymax : float, optional They are equivalent to bottom and top respectively, and it is an error to pass both *ymin* and *bottom* or *ymax* and *top*. Returns ------- bottom, top : (float, float) The new y-axis limits in data coordinates. See Also -------- get_ylim set_ybound, get_ybound invert_yaxis, yaxis_inverted Notes ----- The *bottom* value may be greater than the *top* value, in which case the y-axis values will decrease from *bottom* to *top*. Examples -------- >>> set_ylim(bottom, top) >>> set_ylim((bottom, top)) >>> bottom, top = set_ylim(bottom, top) One limit may be left unchanged. >>> set_ylim(top=top_lim) Limits may be passed in reverse order to flip the direction of the y-axis. For example, suppose ``y`` represents depth of the ocean in m. The y-axis limits might be set like the following so 5000 m depth is at the bottom of the plot and the surface, 0 m, is at the top. >>> set_ylim(5000, 0) """ if top is None and np.iterable(bottom): bottom, top = bottom if ymin is not None: if bottom is not None: raise TypeError("Cannot pass both 'bottom' and 'ymin'") bottom = ymin if ymax is not None: if top is not None: raise TypeError("Cannot pass both 'top' and 'ymax'") top = ymax return self.yaxis._set_lim(bottom, top, emit=emit, auto=auto) get_yscale = _axis_method_wrapper("yaxis", "get_scale") set_yscale = _axis_method_wrapper("yaxis", "_set_axes_scale") get_yticks = _axis_method_wrapper("yaxis", "get_ticklocs") set_yticks = _axis_method_wrapper("yaxis", "set_ticks", doc_sub={'set_ticks': 'set_yticks'}) get_ymajorticklabels = _axis_method_wrapper("yaxis", "get_majorticklabels") get_yminorticklabels = _axis_method_wrapper("yaxis", "get_minorticklabels") get_yticklabels = _axis_method_wrapper("yaxis", "get_ticklabels") set_yticklabels = _axis_method_wrapper( "yaxis", "set_ticklabels", doc_sub={"Axis.set_ticks": "Axes.set_yticks"}) xaxis_date = _axis_method_wrapper("xaxis", "axis_date") yaxis_date = _axis_method_wrapper("yaxis", "axis_date") def format_xdata(self, x): """ Return *x* formatted as an x-value. This function will use the `.fmt_xdata` attribute if it is not None, else will fall back on the xaxis major formatter. """ return (self.fmt_xdata if self.fmt_xdata is not None else self.xaxis.get_major_formatter().format_data_short)(x) def format_ydata(self, y): """ Return *y* formatted as a y-value. This function will use the `.fmt_ydata` attribute if it is not None, else will fall back on the yaxis major formatter. """ return (self.fmt_ydata if self.fmt_ydata is not None else self.yaxis.get_major_formatter().format_data_short)(y) def format_coord(self, x, y): """Return a format string formatting the *x*, *y* coordinates.""" return "x={} y={}".format( "???" if x is None else self.format_xdata(x), "???" if y is None else self.format_ydata(y), ) def minorticks_on(self): """ Display minor ticks on the Axes. Displaying minor ticks may reduce performance; you may turn them off using `minorticks_off()` if drawing speed is a problem. """ for ax in (self.xaxis, self.yaxis): scale = ax.get_scale() if scale == 'log': s = ax._scale ax.set_minor_locator(mticker.LogLocator(s.base, s.subs)) elif scale == 'symlog': s = ax._scale ax.set_minor_locator( mticker.SymmetricalLogLocator(s._transform, s.subs)) else: ax.set_minor_locator(mticker.AutoMinorLocator()) def minorticks_off(self): """Remove minor ticks from the Axes.""" self.xaxis.set_minor_locator(mticker.NullLocator()) self.yaxis.set_minor_locator(mticker.NullLocator()) # Interactive manipulation def can_zoom(self): """ Return whether this Axes supports the zoom box button functionality. """ return True def can_pan(self): """ Return whether this Axes supports any pan/zoom button functionality. """ return True def get_navigate(self): """ Get whether the Axes responds to navigation commands. """ return self._navigate def set_navigate(self, b): """ Set whether the Axes responds to navigation toolbar commands. Parameters ---------- b : bool """ self._navigate = b def get_navigate_mode(self): """ Get the navigation toolbar button status: 'PAN', 'ZOOM', or None. """ return self._navigate_mode def set_navigate_mode(self, b): """ Set the navigation toolbar button status. .. warning:: This is not a user-API function. """ self._navigate_mode = b def _get_view(self): """ Save information required to reproduce the current view. This method is called before a view is changed, such as during a pan or zoom initiated by the user. It returns an opaque object that describes the current view, in a format compatible with :meth:`_set_view`. The default implementation saves the view limits and autoscaling state. Subclasses may override this as needed, as long as :meth:`_set_view` is also adjusted accordingly. """ return { "xlim": self.get_xlim(), "autoscalex_on": self.get_autoscalex_on(), "ylim": self.get_ylim(), "autoscaley_on": self.get_autoscaley_on(), } def _set_view(self, view): """ Apply a previously saved view. This method is called when restoring a view (with the return value of :meth:`_get_view` as argument), such as with the navigation buttons. Subclasses that override :meth:`_get_view` also need to override this method accordingly. """ self.set(**view) def _prepare_view_from_bbox(self, bbox, direction='in', mode=None, twinx=False, twiny=False): """ Helper function to prepare the new bounds from a bbox. This helper function returns the new x and y bounds from the zoom bbox. This a convenience method to abstract the bbox logic out of the base setter. """ if len(bbox) == 3: xp, yp, scl = bbox # Zooming code if scl == 0: # Should not happen scl = 1. if scl > 1: direction = 'in' else: direction = 'out' scl = 1/scl # get the limits of the axes (xmin, ymin), (xmax, ymax) = self.transData.transform( np.transpose([self.get_xlim(), self.get_ylim()])) # set the range xwidth = xmax - xmin ywidth = ymax - ymin xcen = (xmax + xmin)*.5 ycen = (ymax + ymin)*.5 xzc = (xp*(scl - 1) + xcen)/scl yzc = (yp*(scl - 1) + ycen)/scl bbox = [xzc - xwidth/2./scl, yzc - ywidth/2./scl, xzc + xwidth/2./scl, yzc + ywidth/2./scl] elif len(bbox) != 4: # should be len 3 or 4 but nothing else _api.warn_external( "Warning in _set_view_from_bbox: bounding box is not a tuple " "of length 3 or 4. Ignoring the view change.") return # Original limits. xmin0, xmax0 = self.get_xbound() ymin0, ymax0 = self.get_ybound() # The zoom box in screen coords. startx, starty, stopx, stopy = bbox # Convert to data coords. (startx, starty), (stopx, stopy) = self.transData.inverted().transform( [(startx, starty), (stopx, stopy)]) # Clip to axes limits. xmin, xmax = np.clip(sorted([startx, stopx]), xmin0, xmax0) ymin, ymax = np.clip(sorted([starty, stopy]), ymin0, ymax0) # Don't double-zoom twinned axes or if zooming only the other axis. if twinx or mode == "y": xmin, xmax = xmin0, xmax0 if twiny or mode == "x": ymin, ymax = ymin0, ymax0 if direction == "in": new_xbound = xmin, xmax new_ybound = ymin, ymax elif direction == "out": x_trf = self.xaxis.get_transform() sxmin0, sxmax0, sxmin, sxmax = x_trf.transform( [xmin0, xmax0, xmin, xmax]) # To screen space. factor = (sxmax0 - sxmin0) / (sxmax - sxmin) # Unzoom factor. # Move original bounds away by # (factor) x (distance between unzoom box and Axes bbox). sxmin1 = sxmin0 - factor * (sxmin - sxmin0) sxmax1 = sxmax0 + factor * (sxmax0 - sxmax) # And back to data space. new_xbound = x_trf.inverted().transform([sxmin1, sxmax1]) y_trf = self.yaxis.get_transform() symin0, symax0, symin, symax = y_trf.transform( [ymin0, ymax0, ymin, ymax]) factor = (symax0 - symin0) / (symax - symin) symin1 = symin0 - factor * (symin - symin0) symax1 = symax0 + factor * (symax0 - symax) new_ybound = y_trf.inverted().transform([symin1, symax1]) return new_xbound, new_ybound def _set_view_from_bbox(self, bbox, direction='in', mode=None, twinx=False, twiny=False): """ Update view from a selection bbox. .. note:: Intended to be overridden by new projection types, but if not, the default implementation sets the view limits to the bbox directly. Parameters ---------- bbox : 4-tuple or 3 tuple * If bbox is a 4 tuple, it is the selected bounding box limits, in *display* coordinates. * If bbox is a 3 tuple, it is an (xp, yp, scl) triple, where (xp, yp) is the center of zooming and scl the scale factor to zoom by. direction : str The direction to apply the bounding box. * `'in'` - The bounding box describes the view directly, i.e., it zooms in. * `'out'` - The bounding box describes the size to make the existing view, i.e., it zooms out. mode : str or None The selection mode, whether to apply the bounding box in only the `'x'` direction, `'y'` direction or both (`None`). twinx : bool Whether this axis is twinned in the *x*-direction. twiny : bool Whether this axis is twinned in the *y*-direction. """ new_xbound, new_ybound = self._prepare_view_from_bbox( bbox, direction=direction, mode=mode, twinx=twinx, twiny=twiny) if not twinx and mode != "y": self.set_xbound(new_xbound) self.set_autoscalex_on(False) if not twiny and mode != "x": self.set_ybound(new_ybound) self.set_autoscaley_on(False) def start_pan(self, x, y, button): """ Called when a pan operation has started. Parameters ---------- x, y : float The mouse coordinates in display coords. button : `.MouseButton` The pressed mouse button. Notes ----- This is intended to be overridden by new projection types. """ self._pan_start = types.SimpleNamespace( lim=self.viewLim.frozen(), trans=self.transData.frozen(), trans_inverse=self.transData.inverted().frozen(), bbox=self.bbox.frozen(), x=x, y=y) def end_pan(self): """ Called when a pan operation completes (when the mouse button is up.) Notes ----- This is intended to be overridden by new projection types. """ del self._pan_start def _get_pan_points(self, button, key, x, y): """ Helper function to return the new points after a pan. This helper function returns the points on the axis after a pan has occurred. This is a convenience method to abstract the pan logic out of the base setter. """ def format_deltas(key, dx, dy): if key == 'control': if abs(dx) > abs(dy): dy = dx else: dx = dy elif key == 'x': dy = 0 elif key == 'y': dx = 0 elif key == 'shift': if 2 * abs(dx) < abs(dy): dx = 0 elif 2 * abs(dy) < abs(dx): dy = 0 elif abs(dx) > abs(dy): dy = dy / abs(dy) * abs(dx) else: dx = dx / abs(dx) * abs(dy) return dx, dy p = self._pan_start dx = x - p.x dy = y - p.y if dx == dy == 0: return if button == 1: dx, dy = format_deltas(key, dx, dy) result = p.bbox.translated(-dx, -dy).transformed(p.trans_inverse) elif button == 3: try: dx = -dx / self.bbox.width dy = -dy / self.bbox.height dx, dy = format_deltas(key, dx, dy) if self.get_aspect() != 'auto': dx = dy = 0.5 * (dx + dy) alpha = np.power(10.0, (dx, dy)) start = np.array([p.x, p.y]) oldpoints = p.lim.transformed(p.trans) newpoints = start + alpha * (oldpoints - start) result = (mtransforms.Bbox(newpoints) .transformed(p.trans_inverse)) except OverflowError: _api.warn_external('Overflow while panning') return else: return valid = np.isfinite(result.transformed(p.trans)) points = result.get_points().astype(object) # Just ignore invalid limits (typically, underflow in log-scale). points[~valid] = None return points def drag_pan(self, button, key, x, y): """ Called when the mouse moves during a pan operation. Parameters ---------- button : `.MouseButton` The pressed mouse button. key : str or None The pressed key, if any. x, y : float The mouse coordinates in display coords. Notes ----- This is intended to be overridden by new projection types. """ points = self._get_pan_points(button, key, x, y) if points is not None: self.set_xlim(points[:, 0]) self.set_ylim(points[:, 1]) def get_children(self): # docstring inherited. return [ *self._children, *self.spines.values(), *self._axis_map.values(), self.title, self._left_title, self._right_title, *self.child_axes, *([self.legend_] if self.legend_ is not None else []), self.patch, ] def contains(self, mouseevent): # docstring inherited. return self.patch.contains(mouseevent) def contains_point(self, point): """ Return whether *point* (pair of pixel coordinates) is inside the Axes patch. """ return self.patch.contains_point(point, radius=1.0) def get_default_bbox_extra_artists(self): """ Return a default list of artists that are used for the bounding box calculation. Artists are excluded either by not being visible or ``artist.set_in_layout(False)``. """ artists = self.get_children() for axis in self._axis_map.values(): # axis tight bboxes are calculated separately inside # Axes.get_tightbbox() using for_layout_only=True artists.remove(axis) if not (self.axison and self._frameon): # don't do bbox on spines if frame not on. for spine in self.spines.values(): artists.remove(spine) artists.remove(self.title) artists.remove(self._left_title) artists.remove(self._right_title) # always include types that do not internally implement clipping # to Axes. may have clip_on set to True and clip_box equivalent # to ax.bbox but then ignore these properties during draws. noclip = (_AxesBase, maxis.Axis, offsetbox.AnnotationBbox, offsetbox.OffsetBox) return [a for a in artists if a.get_visible() and a.get_in_layout() and (isinstance(a, noclip) or not a._fully_clipped_to_axes())] @_api.make_keyword_only("3.8", "call_axes_locator") def get_tightbbox(self, renderer=None, call_axes_locator=True, bbox_extra_artists=None, *, for_layout_only=False): """ Return the tight bounding box of the Axes, including axis and their decorators (xlabel, title, etc). Artists that have ``artist.set_in_layout(False)`` are not included in the bbox. Parameters ---------- renderer : `.RendererBase` subclass renderer that will be used to draw the figures (i.e. ``fig.canvas.get_renderer()``) bbox_extra_artists : list of `.Artist` or ``None`` List of artists to include in the tight bounding box. If ``None`` (default), then all artist children of the Axes are included in the tight bounding box. call_axes_locator : bool, default: True 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 interested in the relative size of the tightbbox compared to the Axes bbox. for_layout_only : default: False The bounding box will *not* include the x-extent of the title and the xlabel, or the y-extent of the ylabel. Returns ------- `.BboxBase` Bounding box in figure pixel coordinates. See Also -------- matplotlib.axes.Axes.get_window_extent matplotlib.axis.Axis.get_tightbbox matplotlib.spines.Spine.get_window_extent """ bb = [] if renderer is None: renderer = self.figure._get_renderer() if not self.get_visible(): return None locator = self.get_axes_locator() self.apply_aspect( locator(self, renderer) if locator and call_axes_locator else None) for axis in self._axis_map.values(): if self.axison and axis.get_visible(): ba = martist._get_tightbbox_for_layout_only(axis, renderer) if ba: bb.append(ba) self._update_title_position(renderer) axbbox = self.get_window_extent(renderer) bb.append(axbbox) for title in [self.title, self._left_title, self._right_title]: if title.get_visible(): bt = title.get_window_extent(renderer) if for_layout_only and bt.width > 0: # make the title bbox 1 pixel wide so its width # is not accounted for in bbox calculations in # tight/constrained_layout bt.x0 = (bt.x0 + bt.x1) / 2 - 0.5 bt.x1 = bt.x0 + 1.0 bb.append(bt) bbox_artists = bbox_extra_artists if bbox_artists is None: bbox_artists = self.get_default_bbox_extra_artists() for a in bbox_artists: bbox = a.get_tightbbox(renderer) if (bbox is not None and 0 < bbox.width < np.inf and 0 < bbox.height < np.inf): bb.append(bbox) return mtransforms.Bbox.union( [b for b in bb if b.width != 0 or b.height != 0]) def _make_twin_axes(self, *args, **kwargs): """Make a twinx Axes of self. This is used for twinx and twiny.""" if 'sharex' in kwargs and 'sharey' in kwargs: # The following line is added in v2.2 to avoid breaking Seaborn, # which currently uses this internal API. if kwargs["sharex"] is not self and kwargs["sharey"] is not self: raise ValueError("Twinned Axes may share only one axis") ss = self.get_subplotspec() if ss: twin = self.figure.add_subplot(ss, *args, **kwargs) else: twin = self.figure.add_axes( self.get_position(True), *args, **kwargs, axes_locator=_TransformedBoundsLocator( [0, 0, 1, 1], self.transAxes)) self.set_adjustable('datalim') twin.set_adjustable('datalim') self._twinned_axes.join(self, twin) return twin def twinx(self): """ Create a twin Axes sharing the xaxis. Create a new Axes with an invisible x-axis and an independent y-axis positioned opposite to the original one (i.e. at right). The x-axis autoscale setting will be inherited from the original Axes. To ensure that the tick marks of both y-axes align, see `~matplotlib.ticker.LinearLocator`. Returns ------- Axes The newly created Axes instance Notes ----- For those who are 'picking' artists while using twinx, pick events are only called for the artists in the top-most Axes. """ ax2 = self._make_twin_axes(sharex=self) ax2.yaxis.tick_right() ax2.yaxis.set_label_position('right') ax2.yaxis.set_offset_position('right') ax2.set_autoscalex_on(self.get_autoscalex_on()) self.yaxis.tick_left() ax2.xaxis.set_visible(False) ax2.patch.set_visible(False) ax2.xaxis.units = self.xaxis.units return ax2 def twiny(self): """ Create a twin Axes sharing the yaxis. Create a new Axes with an invisible y-axis and an independent x-axis positioned opposite to the original one (i.e. at top). The y-axis autoscale setting will be inherited from the original Axes. To ensure that the tick marks of both x-axes align, see `~matplotlib.ticker.LinearLocator`. Returns ------- Axes The newly created Axes instance Notes ----- For those who are 'picking' artists while using twiny, pick events are only called for the artists in the top-most Axes. """ ax2 = self._make_twin_axes(sharey=self) ax2.xaxis.tick_top() ax2.xaxis.set_label_position('top') ax2.set_autoscaley_on(self.get_autoscaley_on()) self.xaxis.tick_bottom() ax2.yaxis.set_visible(False) ax2.patch.set_visible(False) ax2.yaxis.units = self.yaxis.units return ax2 def get_shared_x_axes(self): """Return an immutable view on the shared x-axes Grouper.""" return cbook.GrouperView(self._shared_axes["x"]) def get_shared_y_axes(self): """Return an immutable view on the shared y-axes Grouper.""" return cbook.GrouperView(self._shared_axes["y"]) def label_outer(self, remove_inner_ticks=False): """ Only show "outer" labels and tick labels. x-labels are only kept for subplots on the last row (or first row, if labels are on the top side); y-labels only for subplots on the first column (or last column, if labels are on the right side). Parameters ---------- remove_inner_ticks : bool, default: False If True, remove the inner ticks as well (not only tick labels). .. versionadded:: 3.8 """ self._label_outer_xaxis(skip_non_rectangular_axes=False, remove_inner_ticks=remove_inner_ticks) self._label_outer_yaxis(skip_non_rectangular_axes=False, remove_inner_ticks=remove_inner_ticks) def _label_outer_xaxis(self, *, skip_non_rectangular_axes, remove_inner_ticks=False): # see documentation in label_outer. if skip_non_rectangular_axes and not isinstance(self.patch, mpl.patches.Rectangle): return ss = self.get_subplotspec() if not ss: return label_position = self.xaxis.get_label_position() if not ss.is_first_row(): # Remove top label/ticklabels/offsettext. if label_position == "top": self.set_xlabel("") top_kw = {'top': False} if remove_inner_ticks else {} self.xaxis.set_tick_params( which="both", labeltop=False, **top_kw) if self.xaxis.offsetText.get_position()[1] == 1: self.xaxis.offsetText.set_visible(False) if not ss.is_last_row(): # Remove bottom label/ticklabels/offsettext. if label_position == "bottom": self.set_xlabel("") bottom_kw = {'bottom': False} if remove_inner_ticks else {} self.xaxis.set_tick_params( which="both", labelbottom=False, **bottom_kw) if self.xaxis.offsetText.get_position()[1] == 0: self.xaxis.offsetText.set_visible(False) def _label_outer_yaxis(self, *, skip_non_rectangular_axes, remove_inner_ticks=False): # see documentation in label_outer. if skip_non_rectangular_axes and not isinstance(self.patch, mpl.patches.Rectangle): return ss = self.get_subplotspec() if not ss: return label_position = self.yaxis.get_label_position() if not ss.is_first_col(): # Remove left label/ticklabels/offsettext. if label_position == "left": self.set_ylabel("") left_kw = {'left': False} if remove_inner_ticks else {} self.yaxis.set_tick_params( which="both", labelleft=False, **left_kw) if self.yaxis.offsetText.get_position()[0] == 0: self.yaxis.offsetText.set_visible(False) if not ss.is_last_col(): # Remove right label/ticklabels/offsettext. if label_position == "right": self.set_ylabel("") right_kw = {'right': False} if remove_inner_ticks else {} self.yaxis.set_tick_params( which="both", labelright=False, **right_kw) if self.yaxis.offsetText.get_position()[0] == 1: self.yaxis.offsetText.set_visible(False) def _draw_rasterized(figure, artists, renderer): """ A helper function for rasterizing the list of artists. The bookkeeping to track if we are or are not in rasterizing mode with the mixed-mode backends is relatively complicated and is now handled in the matplotlib.artist.allow_rasterization decorator. This helper defines the absolute minimum methods and attributes on a shim class to be compatible with that decorator and then uses it to rasterize the list of artists. This is maybe too-clever, but allows us to re-use the same code that is used on normal artists to participate in the "are we rasterizing" accounting. Please do not use this outside of the "rasterize below a given zorder" functionality of Axes. Parameters ---------- figure : matplotlib.figure.Figure The figure all of the artists belong to (not checked). We need this because we can at the figure level suppress composition and insert each rasterized artist as its own image. artists : List[matplotlib.artist.Artist] The list of Artists to be rasterized. These are assumed to all be in the same Figure. renderer : matplotlib.backendbases.RendererBase The currently active renderer Returns ------- None """ class _MinimalArtist: def get_rasterized(self): return True def get_agg_filter(self): return None def __init__(self, figure, artists): self.figure = figure self.artists = artists @martist.allow_rasterization def draw(self, renderer): for a in self.artists: a.draw(renderer) return _MinimalArtist(figure, artists).draw(renderer)