''' Colorbar toolkit with two classes and a function:
:class:`ColorbarBase` the base class with full colorbar drawing functionality. It can be used as-is to make a colorbar for a given colormap; a mappable object (e.g., image) is not needed.
:class:`Colorbar` the derived class for use with images or contour plots.
:func:`make_axes` a function for resizing an axes and adding a second axes suitable for a colorbar
The :meth:`~matplotlib.figure.Figure.colorbar` method uses :func:`make_axes` and :class:`Colorbar`; the :func:`~matplotlib.pyplot.colorbar` function is a thin wrapper over :meth:`~matplotlib.figure.Figure.colorbar`.
'''
============= ==================================================== Property Description ============= ==================================================== *orientation* vertical or horizontal *fraction* 0.15; fraction of original axes to use for colorbar *pad* 0.05 if vertical, 0.15 if horizontal; fraction of original axes between colorbar and new image axes *shrink* 1.0; fraction by which to multiply the size of the colorbar *aspect* 20; ratio of long to short dimensions *anchor* (0.0, 0.5) if vertical; (0.5, 1.0) if horizontal; the anchor point of the colorbar axes *panchor* (1.0, 0.5) if vertical; (0.5, 0.0) if horizontal; the anchor point of the colorbar parent axes. If False, the parent axes' anchor will be unchanged ============= ====================================================
'''
============ ==================================================== Property Description ============ ==================================================== *extend* [ 'neither' | 'both' | 'min' | 'max' ] If not 'neither', make pointed end(s) for out-of- range values. These are set for a given colormap using the colormap set_under and set_over methods. *extendfrac* [ *None* | 'auto' | length | lengths ] If set to *None*, both the minimum and maximum triangular colorbar extensions with have a length of 5% of the interior colorbar length (this is the default setting). If set to 'auto', makes the triangular colorbar extensions the same lengths as the interior boxes (when *spacing* is set to 'uniform') or the same lengths as the respective adjacent interior boxes (when *spacing* is set to 'proportional'). If a scalar, indicates the length of both the minimum and maximum triangular colorbar extensions as a fraction of the interior colorbar length. A two-element sequence of fractions may also be given, indicating the lengths of the minimum and maximum colorbar extensions respectively as a fraction of the interior colorbar length. *extendrect* bool If *False* the minimum and maximum colorbar extensions will be triangular (the default). If *True* the extensions will be rectangular. *spacing* [ 'uniform' | 'proportional' ] Uniform spacing gives each discrete color the same space; proportional makes the space proportional to the data interval. *ticks* [ None | list of ticks | Locator object ] If None, ticks are determined automatically from the input. *format* [ None | format string | Formatter object ] If None, the :class:`~matplotlib.ticker.ScalarFormatter` is used. If a format string is given, e.g., '%.3f', that is used. An alternative :class:`~matplotlib.ticker.Formatter` object may be given instead. *drawedges* bool Whether to draw lines at color boundaries. ============ ====================================================
The following will probably be useful only in the context of indexed colors (that is, when the mappable has norm=NoNorm()), or other unusual circumstances.
============ =================================================== Property Description ============ =================================================== *boundaries* None or a sequence *values* None or a sequence which must be of length 1 less than the sequence of *boundaries*. For each region delimited by adjacent entries in *boundaries*, the color mapped to the corresponding value in values will be used. ============ ===================================================
'''
Add a colorbar to a plot.
Function signatures for the :mod:`~matplotlib.pyplot` interface; all but the first are also method signatures for the :meth:`~matplotlib.figure.Figure.colorbar` method::
colorbar(**kwargs) colorbar(mappable, **kwargs) colorbar(mappable, cax=cax, **kwargs) colorbar(mappable, ax=ax, **kwargs)
Parameters ---------- mappable : The :class:`~matplotlib.image.Image`, :class:`~matplotlib.contour.ContourSet`, etc. to which the colorbar applies; this argument is mandatory for the Figure :meth:`~matplotlib.figure.Figure.colorbar` method but optional for the pyplot :func:`~matplotlib.pyplot.colorbar` function, which sets the default to the current image.
cax : :class:`~matplotlib.axes.Axes` object, optional Axes into which the colorbar will be drawn.
ax : :class:`~matplotlib.axes.Axes`, list of Axes, optional Parent axes from which space for a new colorbar axes will be stolen. If a list of axes is given they will all be resized to make room for the colorbar axes.
use_gridspec : bool, optional If *cax* is ``None``, a new *cax* is created as an instance of Axes. If *ax* is an instance of Subplot and *use_gridspec* is ``True``, *cax* is created as an instance of Subplot using the grid_spec module.
Returns ------- :class:`~matplotlib.colorbar.Colorbar` instance See also its base class, :class:`~matplotlib.colorbar.ColorbarBase`. Call the :meth:`~matplotlib.colorbar.ColorbarBase.set_label` method to label the colorbar.
Notes ----- Additional keyword arguments are of two kinds:
axes properties: %s colorbar properties: %s
If *mappable* is a :class:`~matplotlib.contours.ContourSet`, its *extend* kwarg is included automatically.
The *shrink* kwarg provides a simple way to scale the colorbar with respect to the axes. Note that if *cax* is specified it determines the size of the colorbar and *shrink* and *aspect* kwargs are ignored.
For more precise control, you can manually specify the positions of the axes objects in which the mappable and the colorbar are drawn. In this case, do not use any of the axes properties kwargs.
It is known that some vector graphics viewer (svg and pdf) renders white gaps between segments of the colorbar. This is due to bugs in the viewers not matplotlib. As a workaround the colorbar can be rendered with overlapping segments::
cbar = colorbar() cbar.solids.set_edgecolor("face") draw()
However this has negative consequences in other circumstances. Particularly with semi transparent images (alpha < 1) and colorbar extensions and is not enabled by default see (issue #1188).
''' % (make_axes_kw_doc, colormap_kw_doc)
# a top level function which gets put in at the axes' # set_xticks set_yticks by _patch_ax warnings.warn("Use the colorbar set_ticks() method instead.")
""" AutoLocator for Colorbar
This locator is just a `.MaxNLocator` except the min and max are clipped by the norm's min and max (i.e. vmin/vmax from the image/pcolor/contour object). This is necessary so ticks don't extrude into the "extend regions". """
""" This ticker needs to know the *colorbar* so that it can access its *vmin* and *vmax*. Otherwise it is the same as `~.ticker.AutoLocator`. """
""" AutoMinorLocator for Colorbar
This locator is just a `.AutoMinorLocator` except the min and max are clipped by the norm's min and max (i.e. vmin/vmax from the image/pcolor/contour object). This is necessary so that the minorticks don't extrude into the "extend regions". """
""" This ticker needs to know the *colorbar* so that it can access its *vmin* and *vmax*. """ self._colorbar = colorbar self.ndivs = n super().__init__(n=None)
vmin = self._colorbar.norm.vmin vmax = self._colorbar.norm.vmax ticks = super().__call__() rtol = (vmax - vmin) * 1e-10 return ticks[(ticks >= vmin - rtol) & (ticks <= vmax + rtol)]
""" LogLocator for Colorbarbar
This locator is just a `.LogLocator` except the min and max are clipped by the norm's min and max (i.e. vmin/vmax from the image/pcolor/contour object). This is necessary so ticks don't extrude into the "extend regions".
""" """ _ColorbarLogLocator(colorbar, *args, **kwargs)
This ticker needs to know the *colorbar* so that it can access its *vmin* and *vmax*. Otherwise it is the same as `~.ticker.LogLocator`. The ``*args`` and ``**kwargs`` are the same as `~.ticker.LogLocator`. """ self._colorbar = colorbar super().__init__(*args, **kwargs)
vmin = self._colorbar.norm.vmin vmax = self._colorbar.norm.vmax ticks = super().tick_values(vmin, vmax) rtol = (np.log10(vmax) - np.log10(vmin)) * 1e-10 ticks = ticks[(np.log10(ticks) >= np.log10(vmin) - rtol) & (np.log10(ticks) <= np.log10(vmax) + rtol)] return ticks
''' Draw a colorbar in an existing axes.
This is a base class for the :class:`Colorbar` class, which is the basis for the :func:`~matplotlib.pyplot.colorbar` function and the :meth:`~matplotlib.figure.Figure.colorbar` method, which are the usual ways of creating a colorbar.
It is also useful by itself for showing a colormap. If the *cmap* kwarg is given but *boundaries* and *values* are left as None, then the colormap will be displayed on a 0-1 scale. To show the under- and over-value colors, specify the *norm* as::
colors.Normalize(clip=False)
To show the colors versus index instead of on the 0-1 scale, use::
norm=colors.NoNorm.
Useful public methods are :meth:`set_label` and :meth:`add_lines`.
Attributes ---------- ax : Axes The `Axes` instance in which the colorbar is drawn.
lines : list A list of `LineCollection` if lines were drawn, otherwise an empty list.
dividers : LineCollection A LineCollection if *drawedges* is ``True``, otherwise ``None``. ''' 'both': slice(1, -1), 'min': slice(1, None), 'max': slice(0, -1)}
norm=None, alpha=None, values=None, boundaries=None, orientation='vertical', ticklocation='auto', extend='neither', spacing='uniform', # uniform or proportional ticks=None, format=None, drawedges=False, filled=True, extendfrac=None, extendrect=False, label='', ): #: The axes that this colorbar lives in. cmap = cm.get_cmap() norm = colors.Normalize()
self.locator = ticker.FixedLocator(ticks, nbins=len(ticks)) else: if isinstance(self.norm, colors.LogNorm): self.formatter = ticker.LogFormatterSciNotation() elif isinstance(self.norm, colors.SymLogNorm): self.formatter = ticker.LogFormatterSciNotation( linthresh=self.norm.linthresh) else: self.formatter = ticker.ScalarFormatter() self.formatter = ticker.FormatStrFormatter(format) else: # The rest is in a method so we can recalculate when clim changes.
"""Returns whether the lower limit is open ended."""
"""Returns whether the uper limit is open ended."""
# bind some methods to the axes to warn users # against using those methods.
''' Calculate any free parameters based on the current cmap and norm, and do all the drawing. '''
# sets self._boundaries and self._values in real data units. # takes into account extend values: # sets self.vmin and vmax in data units, but just for # the part of the colorbar that is not part of the extend # patch: # returns the X and Y mesh, *but* this was/is in normalized # units:
and self._use_auto_colorbar_locator()): # *both* axes are made log so that determining the # mid point is easier. ax.set_xscale('log') ax.set_yscale('log')
long_axis, short_axis = ax.yaxis, ax.xaxis else:
""" This code looks at the norm being used by the colorbar and decides what locator and formatter to use. If ``locator`` has already been set by hand, it just returns ``self.locator, self.formatter``. """ nv = len(self._values) base = 1 + int(nv / 10) locator = ticker.IndexLocator(base=base, offset=0) b = self.norm.boundaries locator = ticker.FixedLocator(b, nbins=10) locator = _ColorbarLogLocator(self) # The subs setting here should be replaced # by logic in the locator. locator = ticker.SymmetricalLogLocator( subs=np.arange(1, 10), linthresh=self.norm.linthresh, base=10) else: locator = ticker.MaxNLocator() else: else: b = self._boundaries[self._inside] locator = ticker.FixedLocator(b, nbins=10)
""" Return if we should use an adjustable tick locator or a fixed one. (check is used twice so factored out here...) """ and self.values is None and ((type(self.norm) == colors.Normalize) or (type(self.norm) == colors.LogNorm)))
""" Force the update of the ticks and ticklabels. This must be called whenever the tick locator and/or tick formatter changes. """ # get the locator and formatter. Defaults to # self.locator if not None..
long_axis, short_axis = ax.yaxis, ax.xaxis else:
long_axis.set_minor_locator(_ColorbarLogLocator(self, base=10., subs='auto')) long_axis.set_minor_formatter( ticker.LogFormatterSciNotation() ) else: _log.debug('Using fixed locator on colorbar') ticks, ticklabels, offset_string = self._ticker(locator, formatter) long_axis.set_ticks(ticks) long_axis.set_ticklabels(ticklabels) long_axis.get_major_formatter().set_offset_string(offset_string)
""" Set tick locations.
Parameters ---------- ticks : {None, sequence, :class:`~matplotlib.ticker.Locator` instance} If None, a default Locator will be used.
update_ticks : {True, False}, optional If True, tick locations are updated immediately. If False, use :meth:`update_ticks` to manually update the ticks.
""" if cbook.iterable(ticks): self.locator = ticker.FixedLocator(ticks, nbins=len(ticks)) else: self.locator = ticks
if update_ticks: self.update_ticks() self.stale = True
"""Return the x ticks as a list of locations""" if self._manual_tick_data_values is None: ax = self.ax if self.orientation == 'vertical': long_axis, short_axis = ax.yaxis, ax.xaxis else: long_axis, short_axis = ax.xaxis, ax.yaxis return long_axis.get_majorticklocs() else: # We made the axes manually, the old way, and the ylim is 0-1, # so the majorticklocs are in those units, not data units. return self._manual_tick_data_values
""" set tick labels. Tick labels are updated immediately unless update_ticks is *False*. To manually update the ticks, call *update_ticks* method explicitly. """ if isinstance(self.locator, ticker.FixedLocator): self.formatter = ticker.FixedFormatter(ticklabels) if update_ticks: self.update_ticks() else: warnings.warn("set_ticks() must have been called.") self.stale = True
''' Make an axes patch and outline. ''' self.outline.remove() xy, edgecolor=mpl.rcParams['axes.edgecolor'], facecolor='none', linewidth=mpl.rcParams['axes.linewidth'], closed=True, zorder=2) self.patch.remove() facecolor=c, linewidth=0.01, zorder=-1)
self.ax.set_ylabel(self._label, **self._labelkw) else:
''' Label the long axis of the colorbar '''
''' Return *x*, *y* arrays of colorbar bounding polygon, taking orientation into account. ''' return np.hstack((x, y))
''' Return the separator line segments; helper for _add_solids. ''' N = X.shape[0] # Using the non-array form of these line segments is much # simpler than making them into arrays. if self.orientation == 'vertical': return [list(zip(X[i], Y[i])) for i in range(1, N - 1)] else: return [list(zip(Y[i], X[i])) for i in range(1, N - 1)]
''' Draw the colors using :meth:`~matplotlib.axes.Axes.pcolormesh`; optionally add separators. ''' args = (X, Y, C) else: norm=self.norm, alpha=self.alpha, edgecolors='None') # self.add_observer(col) # We should observe, not be observed...
self.solids.remove() self.dividers.remove() self.dividers = None linewidths = (0.5 * mpl.rcParams['axes.linewidth'],) self.dividers = collections.LineCollection( self._edges(X, Y), colors=(mpl.rcParams['axes.edgecolor'],), linewidths=linewidths) self.ax.add_collection(self.dividers)
''' Draw lines on the colorbar.
*colors* and *linewidths* must be scalars or sequences the same length as *levels*.
Set *erase* to False to add lines without first removing any previously added lines. ''' y = self._locate(levels) rtol = (self._y[-1] - self._y[0]) * 1e-10 igood = (y < self._y[-1] + rtol) & (y > self._y[0] - rtol) y = y[igood] if cbook.iterable(colors): colors = np.asarray(colors)[igood] if cbook.iterable(linewidths): linewidths = np.asarray(linewidths)[igood] X, Y = np.meshgrid([self._y[0], self._y[-1]], y) if self.orientation == 'vertical': xy = np.stack([X, Y], axis=-1) else: xy = np.stack([Y, X], axis=-1) col = collections.LineCollection(xy, linewidths=linewidths)
if erase and self.lines: for lc in self.lines: lc.remove() self.lines = [] self.lines.append(col) col.set_color(colors) self.ax.add_collection(col) self.stale = True
''' Return the sequence of ticks (colorbar data locations), ticklabels (strings), and the corresponding offset string. ''' if isinstance(self.norm, colors.NoNorm) and self.boundaries is None: intv = self._values[0], self._values[-1] else: intv = self.vmin, self.vmax locator.create_dummy_axis(minpos=intv[0]) formatter.create_dummy_axis(minpos=intv[0]) locator.set_view_interval(*intv) locator.set_data_interval(*intv) formatter.set_view_interval(*intv) formatter.set_data_interval(*intv)
b = np.array(locator()) if isinstance(locator, ticker.LogLocator): eps = 1e-10 b = b[(b <= intv[1] * (1 + eps)) & (b >= intv[0] * (1 - eps))] else: eps = (intv[1] - intv[0]) * 1e-10 b = b[(b <= intv[1] + eps) & (b >= intv[0] - eps)] self._manual_tick_data_values = b ticks = self._locate(b) formatter.set_locs(b) ticklabels = [formatter(t, i) for i, t in enumerate(b)] offset_string = formatter.get_offset() return ticks, ticklabels, offset_string
''' Set the :attr:`_boundaries` and :attr:`_values` attributes based on the input boundaries and values. Input boundaries can be *self.boundaries* or the argument *b*. ''' + self._boundaries[1:]) self._values = (self._values + 0.00001).astype(np.int16) self._values = np.array(self.values) return self._values = np.array(self.values) if self.boundaries is None: b = np.zeros(len(self.values) + 1, 'd') b[1:-1] = 0.5 * (self._values[:-1] - self._values[1:]) b[0] = 2.0 * b[1] - b[2] b[-1] = 2.0 * b[-2] - b[-3] self._boundaries = b return self._boundaries = np.array(self.boundaries) return # Neither boundaries nor values are specified; # make reasonable ones based on cmap and norm. b = self._uniform_y(self.cmap.N + 1) * self.cmap.N - 0.5 v = np.zeros((len(b) - 1,), dtype=np.int16) v[self._inside] = np.arange(self.cmap.N, dtype=np.int16) if self._extend_lower(): v[0] = -1 if self._extend_upper(): v[-1] = self.cmap.N self._boundaries = b self._values = v return b = list(self.norm.boundaries) if self._extend_lower(): b = [b[0] - 1] + b if self._extend_upper(): b = b + [b[-1] + 1] b = np.array(b) v = np.zeros((len(b) - 1,), dtype=float) bi = self.norm.boundaries v[self._inside] = 0.5 * (bi[:-1] + bi[1:]) if self._extend_lower(): v[0] = b[0] - 1 if self._extend_upper(): v[-1] = b[-1] + 1 self._boundaries = b self._values = v return else: self.norm.vmin = 0 self.norm.vmax = 1
self.norm.vmin, self.norm.vmax, expander=0.1)
# If using a lognorm or powernorm, ensure extensions don't # go negative if self._extend_lower(): b[0] = 0.9 * b[0] if self._extend_upper(): b[-1] = 1.1 * b[-1] else: b[0] = b[0] - 1 b[-1] = b[-1] + 1
''' Set :attr:`vmin` and :attr:`vmax` attributes to the first and last boundary excluding extended end boundaries. '''
'''number of boundaries **before** extension of ends''' nb -= 2 nb -= 1
''' Based on the colormap and extend variable, return the number of boundaries. ''' N = self.cmap.N + 1 if self.extend == 'both': N += 2 elif self.extend in ('min', 'max'): N += 1 return N
''' Get the lengths of colorbar extensions.
A helper method for _uniform_y and _proportional_y. ''' # Set the default value. extendlength = np.array([default, default]) if isinstance(frac, str): if frac.lower() == 'auto': # Use the provided values when 'auto' is required. extendlength[:] = [automin, automax] else: # Any other string is invalid. raise ValueError('invalid value for extendfrac') elif frac is not None: try: # Try to set min and max extension fractions directly. extendlength[:] = frac # If frac is a sequence containing None then NaN may # be encountered. This is an error. if np.isnan(extendlength).any(): raise ValueError() except (TypeError, ValueError): # Raise an error on encountering an invalid value for frac. raise ValueError('invalid value for extendfrac') return extendlength
''' Return colorbar data coordinates for *N* uniformly spaced boundaries, plus ends if required. ''' else: automin = automax = 1. / (N - 1.) extendlength = self._get_extension_lengths(self.extendfrac, automin, automax, default=0.05) if self.extend == 'both': y = np.zeros(N + 2, 'd') y[0] = 0. - extendlength[0] y[-1] = 1. + extendlength[1] elif self.extend == 'min': y = np.zeros(N + 1, 'd') y[0] = 0. - extendlength[0] else: y = np.zeros(N + 1, 'd') y[-1] = 1. + extendlength[1] y[self._inside] = np.linspace(0, 1, N)
''' Return colorbar data coordinates for the boundaries of a proportional colorbar. ''' if isinstance(self.norm, colors.BoundaryNorm): y = (self._boundaries - self._boundaries[0]) y = y / (self._boundaries[-1] - self._boundaries[0]) else: y = self.norm(self._boundaries.copy()) y = np.ma.filled(y, np.nan) if self.extend == 'min': # Exclude leftmost interval of y. clen = y[-1] - y[1] automin = (y[2] - y[1]) / clen automax = (y[-1] - y[-2]) / clen elif self.extend == 'max': # Exclude rightmost interval in y. clen = y[-2] - y[0] automin = (y[1] - y[0]) / clen automax = (y[-2] - y[-3]) / clen elif self.extend == 'both': # Exclude leftmost and rightmost intervals in y. clen = y[-2] - y[1] automin = (y[2] - y[1]) / clen automax = (y[-2] - y[-3]) / clen if self.extend in ('both', 'min', 'max'): extendlength = self._get_extension_lengths(self.extendfrac, automin, automax, default=0.05) if self.extend in ('both', 'min'): y[0] = 0. - extendlength[0] if self.extend in ('both', 'max'): y[-1] = 1. + extendlength[1] yi = y[self._inside] norm = colors.Normalize(yi[0], yi[-1]) y[self._inside] = np.ma.filled(norm(yi), np.nan) return y
''' Return X,Y, the coordinate arrays for the colorbar pcolormesh. These are suitable for a vertical colorbar; swapping and transposition for a horizontal colorbar are done outside this function. ''' # if boundaries and values are None, then we can go ahead and # scale this up for Auto tick location. Otherwise we # want to keep normalized between 0 and 1 and use manual tick # locations.
else: y = self._proportional_y() else: xmid = 0.5 X[0, :] = xmid X[-1, :] = xmid
''' Given a set of color data values, return their corresponding colorbar data coordinates. ''' if isinstance(self.norm, (colors.NoNorm, colors.BoundaryNorm)): b = self._boundaries xn = x else: # Do calculations using normalized coordinates so # as to make the interpolation more accurate. b = self.norm(self._boundaries, clip=False).filled() xn = self.norm(x, clip=False).filled()
# The rest is linear interpolation with extrapolation at ends. ii = np.searchsorted(b, xn) i0 = ii - 1 itop = (ii == len(b)) ibot = (ii == 0) i0[itop] -= 1 ii[itop] -= 1 i0[ibot] += 1 ii[ibot] += 1
db = np.take(b, ii) - np.take(b, i0) y = self._y dy = np.take(y, ii) - np.take(y, i0) z = np.take(y, i0) + (xn - np.take(b, i0)) * dy / db return z
self.alpha = alpha
""" Remove this colorbar from the figure """
fig = self.ax.figure fig.delaxes(self.ax)
""" This class connects a :class:`ColorbarBase` to a :class:`~matplotlib.cm.ScalarMappable` such as a :class:`~matplotlib.image.AxesImage` generated via :meth:`~matplotlib.axes.Axes.imshow`.
It is not intended to be instantiated directly; instead, use :meth:`~matplotlib.figure.Figure.colorbar` or :func:`~matplotlib.pyplot.colorbar` to make your colorbar.
""" # Ensure the given mappable's norm has appropriate vmin and vmax set # even if mappable.draw has not yet been called.
CS = mappable kw['alpha'] = mappable.get_alpha() kw['boundaries'] = CS._levels kw['values'] = CS.cvalues kw['extend'] = CS.extend #kw['ticks'] = CS._levels kw.setdefault('ticks', ticker.FixedLocator(CS.levels, nbins=10)) kw['filled'] = CS.filled ColorbarBase.__init__(self, ax, **kw) if not CS.filled: self.add_lines(CS) else: kw.setdefault('extend', cmap.colorbar_extend)
kw['alpha'] = mappable.get_alpha()
""" Updates this colorbar to match the mappable's properties.
Typically this is automatically registered as an event handler by :func:`colorbar_factory` and should not be called manually.
""" self.set_cmap(mappable.get_cmap()) self.set_clim(mappable.get_clim()) self.update_normal(mappable)
''' Add the lines from a non-filled :class:`~matplotlib.contour.ContourSet` to the colorbar.
Set *erase* to False if these lines should be added to any pre-existing lines. ''' if not isinstance(CS, contour.ContourSet) or CS.filled: raise ValueError('add_lines is only for a ContourSet of lines') tcolors = [c[0] for c in CS.tcolors] tlinewidths = [t[0] for t in CS.tlinewidths] # The following was an attempt to get the colorbar lines # to follow subsequent changes in the contour lines, # but more work is needed: specifically, a careful # look at event sequences, and at how # to make one object track another automatically. #tcolors = [col.get_colors()[0] for col in CS.collections] #tlinewidths = [col.get_linewidth()[0] for lw in CS.collections] ColorbarBase.add_lines(self, CS.levels, tcolors, tlinewidths, erase=erase)
''' update solid, lines, etc. Unlike update_bruteforce, it does not clear the axes. This is meant to be called when the image or contour plot to which this colorbar belongs is changed. ''' self.draw_all() if isinstance(self.mappable, contour.ContourSet): CS = self.mappable if not CS.filled: self.add_lines(CS) self.stale = True
''' Destroy and rebuild the colorbar. This is intended to become obsolete, and will probably be deprecated and then removed. It is not called when the pyplot.colorbar function or the Figure.colorbar method are used to create the colorbar.
''' # We are using an ugly brute-force method: clearing and # redrawing the whole thing. The problem is that if any # properties have been changed by methods other than the # colorbar methods, those changes will be lost. self.ax.cla() # clearing the axes will delete outline, patch, solids, and lines: self.outline = None self.patch = None self.solids = None self.lines = list() self.dividers = None self.set_alpha(mappable.get_alpha()) self.cmap = mappable.cmap self.norm = mappable.norm self.draw_all() if isinstance(self.mappable, contour.ContourSet): CS = self.mappable if not CS.filled: self.add_lines(CS) #if self.lines is not None: # tcolors = [c[0] for c in CS.tcolors] # self.lines.set_color(tcolors) #Fixme? Recalculate boundaries, ticks if vmin, vmax have changed. #Fixme: Some refactoring may be needed; we should not # be recalculating everything if there was a simple alpha # change.
""" Remove this colorbar from the figure. If the colorbar was created with ``use_gridspec=True`` then restore the gridspec to its previous value. """
ColorbarBase.remove(self) self.mappable.callbacksSM.disconnect(self.mappable.colorbar_cid) self.mappable.colorbar = None self.mappable.colorbar_cid = None
try: ax = self.mappable.axes except AttributeError: return
try: gs = ax.get_subplotspec().get_gridspec() subplotspec = gs.get_topmost_subplotspec() except AttributeError: # use_gridspec was False pos = ax.get_position(original=True) ax._set_position(pos) else: # use_gridspec was True ax.set_subplotspec(subplotspec)
""" Turns on the minor ticks on the colorbar without extruding into the "extend regions". """ ax = self.ax long_axis = ax.yaxis if self.orientation == 'vertical' else ax.xaxis
if long_axis.get_scale() == 'log': warnings.warn('minorticks_on() has no effect on a ' 'logarithmic colorbar axis') else: long_axis.set_minor_locator(_ColorbarAutoMinorLocator(self))
""" Turns off the minor ticks on the colorbar. """ ax = self.ax long_axis = ax.yaxis if self.orientation == 'vertical' else ax.xaxis
if long_axis.get_scale() == 'log': warnings.warn('minorticks_off() has no effect on a ' 'logarithmic colorbar axis') else: long_axis.set_minor_locator(ticker.NullLocator())
shrink=1.0, aspect=20, **kw): ''' Resize and reposition parent axes, and return a child axes suitable for a colorbar.
Keyword arguments may include the following (with defaults):
location : [None|'left'|'right'|'top'|'bottom'] The position, relative to **parents**, where the colorbar axes should be created. If None, the value will either come from the given ``orientation``, else it will default to 'right'.
orientation : [None|'vertical'|'horizontal'] The orientation of the colorbar. Typically, this keyword shouldn't be used, as it can be derived from the ``location`` keyword.
%s
Returns (cax, kw), the child axes and the reduced kw dictionary to be passed when creating the colorbar instance. '''
locations = ["left", "right", "top", "bottom"] if orientation is not None and location is not None: raise TypeError('position and orientation are mutually exclusive. ' 'Consider setting the position to any of {}' .format(', '.join(locations)))
# provide a default location if location is None and orientation is None: location = 'right'
# allow the user to not specify the location by specifying the # orientation instead if location is None: location = 'right' if orientation == 'vertical' else 'bottom'
if location not in locations: raise ValueError('Invalid colorbar location. Must be one ' 'of %s' % ', '.join(locations))
default_location_settings = {'left': {'anchor': (1.0, 0.5), 'panchor': (0.0, 0.5), 'pad': 0.10, 'orientation': 'vertical'}, 'right': {'anchor': (0.0, 0.5), 'panchor': (1.0, 0.5), 'pad': 0.05, 'orientation': 'vertical'}, 'top': {'anchor': (0.5, 0.0), 'panchor': (0.5, 1.0), 'pad': 0.05, 'orientation': 'horizontal'}, 'bottom': {'anchor': (0.5, 1.0), 'panchor': (0.5, 0.0), 'pad': 0.15, # backwards compat 'orientation': 'horizontal'}, }
loc_settings = default_location_settings[location]
# put appropriate values into the kw dict for passing back to # the Colorbar class kw['orientation'] = loc_settings['orientation'] kw['ticklocation'] = location
anchor = kw.pop('anchor', loc_settings['anchor']) parent_anchor = kw.pop('panchor', loc_settings['panchor'])
parents_iterable = cbook.iterable(parents) # turn parents into a list if it is not already. We do this w/ np # because `plt.subplots` can return an ndarray and is natural to # pass to `colorbar`. parents = np.atleast_1d(parents).ravel()
# check if using constrained_layout: try: gs = parents[0].get_subplotspec().get_gridspec() using_constrained_layout = (gs._layoutbox is not None) except AttributeError: using_constrained_layout = False
# defaults are not appropriate for constrained_layout: pad0 = loc_settings['pad'] if using_constrained_layout: pad0 = 0.02 pad = kw.pop('pad', pad0)
fig = parents[0].get_figure() if not all(fig is ax.get_figure() for ax in parents): raise ValueError('Unable to create a colorbar axes as not all ' 'parents share the same figure.')
# take a bounding box around all of the given axes parents_bbox = mtransforms.Bbox.union( [ax.get_position(original=True).frozen() for ax in parents])
pb = parents_bbox if location in ('left', 'right'): if location == 'left': pbcb, _, pb1 = pb.splitx(fraction, fraction + pad) else: pb1, _, pbcb = pb.splitx(1 - fraction - pad, 1 - fraction) pbcb = pbcb.shrunk(1.0, shrink).anchored(anchor, pbcb) else: if location == 'bottom': pbcb, _, pb1 = pb.splity(fraction, fraction + pad) else: pb1, _, pbcb = pb.splity(1 - fraction - pad, 1 - fraction) pbcb = pbcb.shrunk(shrink, 1.0).anchored(anchor, pbcb)
# define the aspect ratio in terms of y's per x rather than x's per y aspect = 1.0 / aspect
# define a transform which takes us from old axes coordinates to # new axes coordinates shrinking_trans = mtransforms.BboxTransform(parents_bbox, pb1)
# transform each of the axes in parents using the new transform for ax in parents: new_posn = shrinking_trans.transform(ax.get_position(original=True)) new_posn = mtransforms.Bbox(new_posn) ax._set_position(new_posn) if parent_anchor is not False: ax.set_anchor(parent_anchor)
cax = fig.add_axes(pbcb)
# OK, now make a layoutbox for the cb axis. Later, we will use this # to make the colorbar fit nicely. if not using_constrained_layout: # no layout boxes: lb = None lbpos = None # and we need to set the aspect ratio by hand... cax.set_aspect(aspect, anchor=anchor, adjustable='box') else: if not parents_iterable: # this is a single axis... ax = parents[0] lb, lbpos = constrained_layout.layoutcolorbarsingle( ax, cax, shrink, aspect, location, pad=pad) else: # there is more than one parent, so lets use gridspec # the colorbar will be a sibling of this gridspec, so the # parent is the same parent as the gridspec. Either the figure, # or a subplotspec.
lb, lbpos = constrained_layout.layoutcolorbargridspec( parents, cax, shrink, aspect, location, pad)
cax._layoutbox = lb cax._poslayoutbox = lbpos
return cax, kw
''' Resize and reposition a parent axes, and return a child axes suitable for a colorbar. This function is similar to make_axes. Prmary differences are
* *make_axes_gridspec* only handles the *orientation* keyword and cannot handle the "location" keyword.
* *make_axes_gridspec* should only be used with a subplot parent.
* *make_axes* creates an instance of Axes. *make_axes_gridspec* creates an instance of Subplot.
* *make_axes* updates the position of the parent. *make_axes_gridspec* replaces the grid_spec attribute of the parent with a new one.
While this function is meant to be compatible with *make_axes*, there could be some minor differences.
Keyword arguments may include the following (with defaults):
*orientation* 'vertical' or 'horizontal'
%s
All but the first of these are stripped from the input kw set.
Returns (cax, kw), the child axes and the reduced kw dictionary to be passed when creating the colorbar instance. '''
orientation = kw.setdefault('orientation', 'vertical') kw['ticklocation'] = 'auto'
x1 = 1 - fraction
# for shrinking pad_s = (1 - shrink) * 0.5 wh_ratios = [pad_s, shrink, pad_s]
# we need to none the tree of layoutboxes because # constrained_layout can't remove and replace the tree # hierarchy w/o a seg fault. gs = parent.get_subplotspec().get_gridspec() layoutbox.nonetree(gs._layoutbox) gs_from_subplotspec = gridspec.GridSpecFromSubplotSpec if orientation == 'vertical': pad = kw.pop('pad', 0.05) wh_space = 2 * pad / (1 - pad) gs = gs_from_subplotspec(1, 2, subplot_spec=parent.get_subplotspec(), wspace=wh_space, width_ratios=[x1 - pad, fraction]) gs2 = gs_from_subplotspec(3, 1, subplot_spec=gs[1], hspace=0., height_ratios=wh_ratios) anchor = (0.0, 0.5) panchor = (1.0, 0.5) else: pad = kw.pop('pad', 0.15) wh_space = 2 * pad / (1 - pad) gs = gs_from_subplotspec(2, 1, subplot_spec=parent.get_subplotspec(), hspace=wh_space, height_ratios=[x1 - pad, fraction]) gs2 = gs_from_subplotspec(1, 3, subplot_spec=gs[1], wspace=0., width_ratios=wh_ratios) aspect = 1 / aspect anchor = (0.5, 1.0) panchor = (0.5, 0.0)
parent.set_subplotspec(gs[0]) parent.update_params() parent._set_position(parent.figbox) parent.set_anchor(panchor)
fig = parent.get_figure() cax = fig.add_subplot(gs2[1]) cax.set_aspect(aspect, anchor=anchor, adjustable='box') return cax, kw
""" A Colorbar which is created using :class:`~matplotlib.patches.Patch` rather than the default :func:`~matplotlib.axes.pcolor`.
It uses a list of Patch instances instead of a :class:`~matplotlib.collections.PatchCollection` because the latter does not allow the hatch pattern to vary among the members of the collection. """ # we do not want to override the behaviour of solids # so add a new attribute which will be a list of the # colored patches in the colorbar self.solids_patches = [] Colorbar.__init__(self, ax, mappable, **kw)
""" Draw the colors using :class:`~matplotlib.patches.Patch`; optionally add separators. """ kw = {'alpha': self.alpha, }
n_segments = len(C)
# ensure there are sufficient hatches hatches = self.mappable.hatches * n_segments
patches = [] for i in range(len(X) - 1): val = C[i][0] hatch = hatches[i]
xy = np.array([[X[i][0], Y[i][0]], [X[i][1], Y[i][0]], [X[i + 1][1], Y[i + 1][0]], [X[i + 1][0], Y[i + 1][1]]])
if self.orientation == 'horizontal': # if horizontal swap the xs and ys xy = xy[..., ::-1]
patch = mpatches.PathPatch(mpath.Path(xy), facecolor=self.cmap(self.norm(val)), hatch=hatch, linewidth=0, antialiased=False, **kw) self.ax.add_patch(patch) patches.append(patch)
if self.solids_patches: for solid in self.solids_patches: solid.remove()
self.solids_patches = patches
if self.dividers is not None: self.dividers.remove() self.dividers = None
if self.drawedges: self.dividers = collections.LineCollection( self._edges(X, Y), colors=(mpl.rcParams['axes.edgecolor'],), linewidths=(0.5 * mpl.rcParams['axes.linewidth'],)) self.ax.add_collection(self.dividers)
""" Creates a colorbar on the given axes for the given mappable.
Typically, for automatic colorbar placement given only a mappable use :meth:`~matplotlib.figure.Figure.colorbar`.
""" # if the given mappable is a contourset with any hatching, use # ColorbarPatch else use Colorbar and any(hatch is not None for hatch in mappable.hatches)): cb = ColorbarPatch(cax, mappable, **kwargs) else:
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