""" Axislines includes modified implementation of the Axes class. The biggest difference is that the artists responsible for drawing the axis spine, ticks, ticklabels and axis labels are separated out from Matplotlib's Axis class. Originally, this change was motivated to support curvilinear grid. Here are a few reasons that I came up with a new axes class: * "top" and "bottom" x-axis (or "left" and "right" y-axis) can have different ticks (tick locations and labels). This is not possible with the current Matplotlib, although some twin axes trick can help. * Curvilinear grid. * angled ticks. In the new axes class, xaxis and yaxis is set to not visible by default, and new set of artist (AxisArtist) are defined to draw axis line, ticks, ticklabels and axis label. Axes.axis attribute serves as a dictionary of these artists, i.e., ax.axis["left"] is a AxisArtist instance responsible to draw left y-axis. The default Axes.axis contains "bottom", "left", "top" and "right". AxisArtist can be considered as a container artist and has the following children artists which will draw ticks, labels, etc. * line * major_ticks, major_ticklabels * minor_ticks, minor_ticklabels * offsetText * label Note that these are separate artists from `matplotlib.axis.Axis`, thus most tick-related functions in Matplotlib won't work. For example, color and markerwidth of the ``ax.axis["bottom"].major_ticks`` will follow those of Axes.xaxis unless explicitly specified. In addition to AxisArtist, the Axes will have *gridlines* attribute, which obviously draws grid lines. The gridlines needs to be separated from the axis as some gridlines can never pass any axis. """ import numpy as np import matplotlib as mpl from matplotlib import _api import matplotlib.axes as maxes from matplotlib.path import Path from mpl_toolkits.axes_grid1 import mpl_axes from .axisline_style import AxislineStyle # noqa from .axis_artist import AxisArtist, GridlinesCollection class _AxisArtistHelperBase: """ Base class for axis helper. Subclasses should define the methods listed below. The *axes* argument will be the ``.axes`` attribute of the caller artist. :: # Construct the spine. def get_line_transform(self, axes): return transform def get_line(self, axes): return path # Construct the label. def get_axislabel_transform(self, axes): return transform def get_axislabel_pos_angle(self, axes): return (x, y), angle # Construct the ticks. def get_tick_transform(self, axes): return transform def get_tick_iterators(self, axes): # A pair of iterables (one for major ticks, one for minor ticks) # that yield (tick_position, tick_angle, tick_label). return iter_major, iter_minor """ def update_lim(self, axes): pass def _to_xy(self, values, const): """ Create a (*values.shape, 2)-shape array representing (x, y) pairs. The other coordinate is filled with the constant *const*. Example:: >>> self.nth_coord = 0 >>> self._to_xy([1, 2, 3], const=0) array([[1, 0], [2, 0], [3, 0]]) """ if self.nth_coord == 0: return np.stack(np.broadcast_arrays(values, const), axis=-1) elif self.nth_coord == 1: return np.stack(np.broadcast_arrays(const, values), axis=-1) else: raise ValueError("Unexpected nth_coord") class _FixedAxisArtistHelperBase(_AxisArtistHelperBase): """Helper class for a fixed (in the axes coordinate) axis.""" passthru_pt = _api.deprecated("3.7")(property( lambda self: {"left": (0, 0), "right": (1, 0), "bottom": (0, 0), "top": (0, 1)}[self._loc])) def __init__(self, loc, nth_coord=None): """``nth_coord = 0``: x-axis; ``nth_coord = 1``: y-axis.""" self.nth_coord = ( nth_coord if nth_coord is not None else _api.check_getitem( {"bottom": 0, "top": 0, "left": 1, "right": 1}, loc=loc)) if (nth_coord == 0 and loc not in ["left", "right"] or nth_coord == 1 and loc not in ["bottom", "top"]): _api.warn_deprecated( "3.7", message=f"{loc=!r} is incompatible with " "{nth_coord=}; support is deprecated since %(since)s") self._loc = loc self._pos = {"bottom": 0, "top": 1, "left": 0, "right": 1}[loc] super().__init__() # axis line in transAxes self._path = Path(self._to_xy((0, 1), const=self._pos)) def get_nth_coord(self): return self.nth_coord # LINE def get_line(self, axes): return self._path def get_line_transform(self, axes): return axes.transAxes # LABEL def get_axislabel_transform(self, axes): return axes.transAxes def get_axislabel_pos_angle(self, axes): """ Return the label reference position in transAxes. get_label_transform() returns a transform of (transAxes+offset) """ return dict(left=((0., 0.5), 90), # (position, angle_tangent) right=((1., 0.5), 90), bottom=((0.5, 0.), 0), top=((0.5, 1.), 0))[self._loc] # TICK def get_tick_transform(self, axes): return [axes.get_xaxis_transform(), axes.get_yaxis_transform()][self.nth_coord] class _FloatingAxisArtistHelperBase(_AxisArtistHelperBase): def __init__(self, nth_coord, value): self.nth_coord = nth_coord self._value = value super().__init__() def get_nth_coord(self): return self.nth_coord def get_line(self, axes): raise RuntimeError( "get_line method should be defined by the derived class") class FixedAxisArtistHelperRectilinear(_FixedAxisArtistHelperBase): def __init__(self, axes, loc, nth_coord=None): """ nth_coord = along which coordinate value varies in 2D, nth_coord = 0 -> x axis, nth_coord = 1 -> y axis """ super().__init__(loc, nth_coord) self.axis = [axes.xaxis, axes.yaxis][self.nth_coord] # TICK def get_tick_iterators(self, axes): """tick_loc, tick_angle, tick_label""" if self._loc in ["bottom", "top"]: angle_normal, angle_tangent = 90, 0 else: # "left", "right" angle_normal, angle_tangent = 0, 90 major = self.axis.major major_locs = major.locator() major_labels = major.formatter.format_ticks(major_locs) minor = self.axis.minor minor_locs = minor.locator() minor_labels = minor.formatter.format_ticks(minor_locs) tick_to_axes = self.get_tick_transform(axes) - axes.transAxes def _f(locs, labels): for loc, label in zip(locs, labels): c = self._to_xy(loc, const=self._pos) # check if the tick point is inside axes c2 = tick_to_axes.transform(c) if mpl.transforms._interval_contains_close( (0, 1), c2[self.nth_coord]): yield c, angle_normal, angle_tangent, label return _f(major_locs, major_labels), _f(minor_locs, minor_labels) class FloatingAxisArtistHelperRectilinear(_FloatingAxisArtistHelperBase): def __init__(self, axes, nth_coord, passingthrough_point, axis_direction="bottom"): super().__init__(nth_coord, passingthrough_point) self._axis_direction = axis_direction self.axis = [axes.xaxis, axes.yaxis][self.nth_coord] def get_line(self, axes): fixed_coord = 1 - self.nth_coord data_to_axes = axes.transData - axes.transAxes p = data_to_axes.transform([self._value, self._value]) return Path(self._to_xy((0, 1), const=p[fixed_coord])) def get_line_transform(self, axes): return axes.transAxes def get_axislabel_transform(self, axes): return axes.transAxes def get_axislabel_pos_angle(self, axes): """ Return the label reference position in transAxes. get_label_transform() returns a transform of (transAxes+offset) """ angle = [0, 90][self.nth_coord] fixed_coord = 1 - self.nth_coord data_to_axes = axes.transData - axes.transAxes p = data_to_axes.transform([self._value, self._value]) verts = self._to_xy(0.5, const=p[fixed_coord]) if 0 <= verts[fixed_coord] <= 1: return verts, angle else: return None, None def get_tick_transform(self, axes): return axes.transData def get_tick_iterators(self, axes): """tick_loc, tick_angle, tick_label""" if self.nth_coord == 0: angle_normal, angle_tangent = 90, 0 else: angle_normal, angle_tangent = 0, 90 major = self.axis.major major_locs = major.locator() major_labels = major.formatter.format_ticks(major_locs) minor = self.axis.minor minor_locs = minor.locator() minor_labels = minor.formatter.format_ticks(minor_locs) data_to_axes = axes.transData - axes.transAxes def _f(locs, labels): for loc, label in zip(locs, labels): c = self._to_xy(loc, const=self._value) c1, c2 = data_to_axes.transform(c) if 0 <= c1 <= 1 and 0 <= c2 <= 1: yield c, angle_normal, angle_tangent, label return _f(major_locs, major_labels), _f(minor_locs, minor_labels) class AxisArtistHelper: # Backcompat. Fixed = _FixedAxisArtistHelperBase Floating = _FloatingAxisArtistHelperBase class AxisArtistHelperRectlinear: # Backcompat. Fixed = FixedAxisArtistHelperRectilinear Floating = FloatingAxisArtistHelperRectilinear class GridHelperBase: def __init__(self): self._old_limits = None super().__init__() def update_lim(self, axes): x1, x2 = axes.get_xlim() y1, y2 = axes.get_ylim() if self._old_limits != (x1, x2, y1, y2): self._update_grid(x1, y1, x2, y2) self._old_limits = (x1, x2, y1, y2) def _update_grid(self, x1, y1, x2, y2): """Cache relevant computations when the axes limits have changed.""" def get_gridlines(self, which, axis): """ Return list of grid lines as a list of paths (list of points). Parameters ---------- which : {"both", "major", "minor"} axis : {"both", "x", "y"} """ return [] class GridHelperRectlinear(GridHelperBase): def __init__(self, axes): super().__init__() self.axes = axes def new_fixed_axis(self, loc, nth_coord=None, axis_direction=None, offset=None, axes=None, ): if axes is None: _api.warn_external( "'new_fixed_axis' explicitly requires the axes keyword.") axes = self.axes if axis_direction is None: axis_direction = loc helper = FixedAxisArtistHelperRectilinear(axes, loc, nth_coord) axisline = AxisArtist(axes, helper, offset=offset, axis_direction=axis_direction) return axisline def new_floating_axis(self, nth_coord, value, axis_direction="bottom", axes=None, ): if axes is None: _api.warn_external( "'new_floating_axis' explicitly requires the axes keyword.") axes = self.axes helper = FloatingAxisArtistHelperRectilinear( axes, nth_coord, value, axis_direction) axisline = AxisArtist(axes, helper, axis_direction=axis_direction) axisline.line.set_clip_on(True) axisline.line.set_clip_box(axisline.axes.bbox) return axisline def get_gridlines(self, which="major", axis="both"): """ Return list of gridline coordinates in data coordinates. Parameters ---------- which : {"both", "major", "minor"} axis : {"both", "x", "y"} """ _api.check_in_list(["both", "major", "minor"], which=which) _api.check_in_list(["both", "x", "y"], axis=axis) gridlines = [] if axis in ("both", "x"): locs = [] y1, y2 = self.axes.get_ylim() if which in ("both", "major"): locs.extend(self.axes.xaxis.major.locator()) if which in ("both", "minor"): locs.extend(self.axes.xaxis.minor.locator()) for x in locs: gridlines.append([[x, x], [y1, y2]]) if axis in ("both", "y"): x1, x2 = self.axes.get_xlim() locs = [] if self.axes.yaxis._major_tick_kw["gridOn"]: locs.extend(self.axes.yaxis.major.locator()) if self.axes.yaxis._minor_tick_kw["gridOn"]: locs.extend(self.axes.yaxis.minor.locator()) for y in locs: gridlines.append([[x1, x2], [y, y]]) return gridlines class Axes(maxes.Axes): @_api.deprecated("3.8", alternative="ax.axis") def __call__(self, *args, **kwargs): return maxes.Axes.axis(self.axes, *args, **kwargs) def __init__(self, *args, grid_helper=None, **kwargs): self._axisline_on = True self._grid_helper = (grid_helper if grid_helper else GridHelperRectlinear(self)) super().__init__(*args, **kwargs) self.toggle_axisline(True) def toggle_axisline(self, b=None): if b is None: b = not self._axisline_on if b: self._axisline_on = True self.spines[:].set_visible(False) self.xaxis.set_visible(False) self.yaxis.set_visible(False) else: self._axisline_on = False self.spines[:].set_visible(True) self.xaxis.set_visible(True) self.yaxis.set_visible(True) @property def axis(self): return self._axislines def clear(self): # docstring inherited # Init gridlines before clear() as clear() calls grid(). self.gridlines = gridlines = GridlinesCollection( [], colors=mpl.rcParams['grid.color'], linestyles=mpl.rcParams['grid.linestyle'], linewidths=mpl.rcParams['grid.linewidth']) self._set_artist_props(gridlines) gridlines.set_grid_helper(self.get_grid_helper()) super().clear() # clip_path is set after Axes.clear(): that's when a patch is created. gridlines.set_clip_path(self.axes.patch) # Init axis artists. self._axislines = mpl_axes.Axes.AxisDict(self) new_fixed_axis = self.get_grid_helper().new_fixed_axis self._axislines.update({ loc: new_fixed_axis(loc=loc, axes=self, axis_direction=loc) for loc in ["bottom", "top", "left", "right"]}) for axisline in [self._axislines["top"], self._axislines["right"]]: axisline.label.set_visible(False) axisline.major_ticklabels.set_visible(False) axisline.minor_ticklabels.set_visible(False) def get_grid_helper(self): return self._grid_helper def grid(self, visible=None, which='major', axis="both", **kwargs): """ Toggle the gridlines, and optionally set the properties of the lines. """ # There are some discrepancies in the behavior of grid() between # axes_grid and Matplotlib, because axes_grid explicitly sets the # visibility of the gridlines. super().grid(visible, which=which, axis=axis, **kwargs) if not self._axisline_on: return if visible is None: visible = (self.axes.xaxis._minor_tick_kw["gridOn"] or self.axes.xaxis._major_tick_kw["gridOn"] or self.axes.yaxis._minor_tick_kw["gridOn"] or self.axes.yaxis._major_tick_kw["gridOn"]) self.gridlines.set(which=which, axis=axis, visible=visible) self.gridlines.set(**kwargs) def get_children(self): if self._axisline_on: children = [*self._axislines.values(), self.gridlines] else: children = [] children.extend(super().get_children()) return children def new_fixed_axis(self, loc, offset=None): gh = self.get_grid_helper() axis = gh.new_fixed_axis(loc, nth_coord=None, axis_direction=None, offset=offset, axes=self, ) return axis def new_floating_axis(self, nth_coord, value, axis_direction="bottom"): gh = self.get_grid_helper() axis = gh.new_floating_axis(nth_coord, value, axis_direction=axis_direction, axes=self) return axis class AxesZero(Axes): def clear(self): super().clear() new_floating_axis = self.get_grid_helper().new_floating_axis self._axislines.update( xzero=new_floating_axis( nth_coord=0, value=0., axis_direction="bottom", axes=self), yzero=new_floating_axis( nth_coord=1, value=0., axis_direction="left", axes=self), ) for k in ["xzero", "yzero"]: self._axislines[k].line.set_clip_path(self.patch) self._axislines[k].set_visible(False) Subplot = Axes SubplotZero = AxesZero