fr/fr_env/lib/python3.8/site-packages/matplotlib/figure.py

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2021-02-17 12:26:31 +05:30
"""
`matplotlib.figure` implements the following classes:
`Figure`
Top level `~matplotlib.artist.Artist`, which holds all plot elements.
`SubplotParams`
Control the default spacing between subplots.
"""
import inspect
import logging
from numbers import Integral
import numpy as np
import matplotlib as mpl
from matplotlib import docstring, projections
from matplotlib import __version__ as _mpl_version
import matplotlib.artist as martist
from matplotlib.artist import Artist, allow_rasterization
from matplotlib.backend_bases import (
FigureCanvasBase, NonGuiException, MouseButton)
import matplotlib.cbook as cbook
import matplotlib.colorbar as cbar
import matplotlib.image as mimage
from matplotlib.axes import Axes, SubplotBase, subplot_class_factory
from matplotlib.blocking_input import BlockingMouseInput, BlockingKeyMouseInput
from matplotlib.gridspec import GridSpec, SubplotSpec # noqa: F401
import matplotlib.legend as mlegend
from matplotlib.patches import Rectangle
from matplotlib.text import Text
from matplotlib.transforms import (Affine2D, Bbox, BboxTransformTo,
TransformedBbox)
import matplotlib._layoutbox as layoutbox
_log = logging.getLogger(__name__)
def _stale_figure_callback(self, val):
if self.figure:
self.figure.stale = val
class _AxesStack(cbook.Stack):
"""
Specialization of `.Stack`, to handle all tracking of `~.axes.Axes` in a
`.Figure`.
This stack stores ``key, (ind, axes)`` pairs, where:
* **key** is a hash of the args and kwargs used in generating the Axes.
* **ind** is a serial index tracking the order in which axes were added.
AxesStack is a callable; calling it returns the current axes.
The `current_key_axes` method returns the current key and associated axes.
"""
def __init__(self):
super().__init__()
self._ind = 0
def as_list(self):
"""
Return a list of the Axes instances that have been added to the figure.
"""
ia_list = [a for k, a in self._elements]
ia_list.sort()
return [a for i, a in ia_list]
def get(self, key):
"""
Return the Axes instance that was added with *key*.
If it is not present, return *None*.
"""
item = dict(self._elements).get(key)
if item is None:
return None
cbook.warn_deprecated(
"2.1",
message="Adding an axes using the same arguments as a previous "
"axes currently reuses the earlier instance. In a future "
"version, a new instance will always be created and returned. "
"Meanwhile, this warning can be suppressed, and the future "
"behavior ensured, by passing a unique label to each axes "
"instance.")
return item[1]
def _entry_from_axes(self, e):
ind, k = {a: (ind, k) for k, (ind, a) in self._elements}[e]
return (k, (ind, e))
def remove(self, a):
"""Remove the axes from the stack."""
super().remove(self._entry_from_axes(a))
def bubble(self, a):
"""
Move the given axes, which must already exist in the
stack, to the top.
"""
return super().bubble(self._entry_from_axes(a))
def add(self, key, a):
"""
Add Axes *a*, with key *key*, to the stack, and return the stack.
If *key* is unhashable, replace it by a unique, arbitrary object.
If *a* is already on the stack, don't add it again, but
return *None*.
"""
# All the error checking may be unnecessary; but this method
# is called so seldom that the overhead is negligible.
cbook._check_isinstance(Axes, a=a)
try:
hash(key)
except TypeError:
key = object()
a_existing = self.get(key)
if a_existing is not None:
super().remove((key, a_existing))
cbook._warn_external(
"key {!r} already existed; Axes is being replaced".format(key))
# I don't think the above should ever happen.
if a in self:
return None
self._ind += 1
return super().push((key, (self._ind, a)))
def current_key_axes(self):
"""
Return a tuple of ``(key, axes)`` for the active axes.
If no axes exists on the stack, then returns ``(None, None)``.
"""
if not len(self._elements):
return self._default, self._default
else:
key, (index, axes) = self._elements[self._pos]
return key, axes
def __call__(self):
return self.current_key_axes()[1]
def __contains__(self, a):
return a in self.as_list()
@cbook.deprecated("3.2")
class AxesStack(_AxesStack):
pass
class SubplotParams:
"""
A class to hold the parameters for a subplot.
"""
def __init__(self, left=None, bottom=None, right=None, top=None,
wspace=None, hspace=None):
"""
Defaults are given by :rc:`figure.subplot.[name]`.
Parameters
----------
left : float
The position of the left edge of the subplots,
as a fraction of the figure width.
right : float
The position of the right edge of the subplots,
as a fraction of the figure width.
bottom : float
The position of the bottom edge of the subplots,
as a fraction of the figure height.
top : float
The position of the top edge of the subplots,
as a fraction of the figure height.
wspace : float
The width of the padding between subplots,
as a fraction of the average axes width.
hspace : float
The height of the padding between subplots,
as a fraction of the average axes height.
"""
self.validate = True
for key in ["left", "bottom", "right", "top", "wspace", "hspace"]:
setattr(self, key, mpl.rcParams[f"figure.subplot.{key}"])
self.update(left, bottom, right, top, wspace, hspace)
def update(self, left=None, bottom=None, right=None, top=None,
wspace=None, hspace=None):
"""
Update the dimensions of the passed parameters. *None* means unchanged.
"""
if self.validate:
if ((left if left is not None else self.left)
>= (right if right is not None else self.right)):
raise ValueError('left cannot be >= right')
if ((bottom if bottom is not None else self.bottom)
>= (top if top is not None else self.top)):
raise ValueError('bottom cannot be >= top')
if left is not None:
self.left = left
if right is not None:
self.right = right
if bottom is not None:
self.bottom = bottom
if top is not None:
self.top = top
if wspace is not None:
self.wspace = wspace
if hspace is not None:
self.hspace = hspace
class Figure(Artist):
"""
The top level container for all the plot elements.
The Figure instance supports callbacks through a *callbacks* attribute
which is a `.CallbackRegistry` instance. The events you can connect to
are 'dpi_changed', and the callback will be called with ``func(fig)`` where
fig is the `Figure` instance.
Attributes
----------
patch
The `.Rectangle` instance representing the figure background patch.
suppressComposite
For multiple figure images, the figure will make composite images
depending on the renderer option_image_nocomposite function. If
*suppressComposite* is a boolean, this will override the renderer.
"""
def __str__(self):
return "Figure(%gx%g)" % tuple(self.bbox.size)
def __repr__(self):
return "<{clsname} size {h:g}x{w:g} with {naxes} Axes>".format(
clsname=self.__class__.__name__,
h=self.bbox.size[0], w=self.bbox.size[1],
naxes=len(self.axes),
)
def __init__(self,
figsize=None,
dpi=None,
facecolor=None,
edgecolor=None,
linewidth=0.0,
frameon=None,
subplotpars=None, # rc figure.subplot.*
tight_layout=None, # rc figure.autolayout
constrained_layout=None, # rc figure.constrained_layout.use
):
"""
Parameters
----------
figsize : 2-tuple of floats, default: :rc:`figure.figsize`
Figure dimension ``(width, height)`` in inches.
dpi : float, default: :rc:`figure.dpi`
Dots per inch.
facecolor : default: :rc:`figure.facecolor`
The figure patch facecolor.
edgecolor : default: :rc:`figure.edgecolor`
The figure patch edge color.
linewidth : float
The linewidth of the frame (i.e. the edge linewidth of the figure
patch).
frameon : bool, default: :rc:`figure.frameon`
If ``False``, suppress drawing the figure background patch.
subplotpars : `SubplotParams`
Subplot parameters. If not given, the default subplot
parameters :rc:`figure.subplot.*` are used.
tight_layout : bool or dict, default: :rc:`figure.autolayout`
If ``False`` use *subplotpars*. If ``True`` adjust subplot
parameters using `.tight_layout` with default padding.
When providing a dict containing the keys ``pad``, ``w_pad``,
``h_pad``, and ``rect``, the default `.tight_layout` paddings
will be overridden.
constrained_layout : bool, default: :rc:`figure.constrained_layout.use`
If ``True`` use constrained layout to adjust positioning of plot
elements. Like ``tight_layout``, but designed to be more
flexible. See
:doc:`/tutorials/intermediate/constrainedlayout_guide`
for examples. (Note: does not work with `add_subplot` or
`~.pyplot.subplot2grid`.)
"""
super().__init__()
# remove the non-figure artist _axes property
# as it makes no sense for a figure to be _in_ an axes
# this is used by the property methods in the artist base class
# which are over-ridden in this class
del self._axes
self.callbacks = cbook.CallbackRegistry()
if figsize is None:
figsize = mpl.rcParams['figure.figsize']
if dpi is None:
dpi = mpl.rcParams['figure.dpi']
if facecolor is None:
facecolor = mpl.rcParams['figure.facecolor']
if edgecolor is None:
edgecolor = mpl.rcParams['figure.edgecolor']
if frameon is None:
frameon = mpl.rcParams['figure.frameon']
if not np.isfinite(figsize).all() or (np.array(figsize) < 0).any():
raise ValueError('figure size must be positive finite not '
f'{figsize}')
self.bbox_inches = Bbox.from_bounds(0, 0, *figsize)
self.dpi_scale_trans = Affine2D().scale(dpi)
# do not use property as it will trigger
self._dpi = dpi
self.bbox = TransformedBbox(self.bbox_inches, self.dpi_scale_trans)
self.transFigure = BboxTransformTo(self.bbox)
self.patch = Rectangle(
xy=(0, 0), width=1, height=1, visible=frameon,
facecolor=facecolor, edgecolor=edgecolor, linewidth=linewidth,
# Don't let the figure patch influence bbox calculation.
in_layout=False)
self._set_artist_props(self.patch)
self.patch.set_antialiased(False)
FigureCanvasBase(self) # Set self.canvas.
self._suptitle = None
if subplotpars is None:
subplotpars = SubplotParams()
self.subplotpars = subplotpars
# constrained_layout:
self._layoutbox = None
# set in set_constrained_layout_pads()
self.set_constrained_layout(constrained_layout)
self.set_tight_layout(tight_layout)
self._axstack = _AxesStack() # track all figure axes and current axes
self.clf()
self._cachedRenderer = None
# groupers to keep track of x and y labels we want to align.
# see self.align_xlabels and self.align_ylabels and
# axis._get_tick_boxes_siblings
self._align_xlabel_grp = cbook.Grouper()
self._align_ylabel_grp = cbook.Grouper()
# list of child gridspecs for this figure
self._gridspecs = []
# TODO: I'd like to dynamically add the _repr_html_ method
# to the figure in the right context, but then IPython doesn't
# use it, for some reason.
def _repr_html_(self):
# We can't use "isinstance" here, because then we'd end up importing
# webagg unconditionally.
if 'WebAgg' in type(self.canvas).__name__:
from matplotlib.backends import backend_webagg
return backend_webagg.ipython_inline_display(self)
def show(self, warn=True):
"""
If using a GUI backend with pyplot, display the figure window.
If the figure was not created using `~.pyplot.figure`, it will lack
a `~.backend_bases.FigureManagerBase`, and this method will raise an
AttributeError.
.. warning::
This does not manage an GUI event loop. Consequently, the figure
may only be shown briefly or not shown at all if you or your
environment are not managing an event loop.
Proper use cases for `.Figure.show` include running this from a
GUI application or an IPython shell.
If you're running a pure python shell or executing a non-GUI
python script, you should use `matplotlib.pyplot.show` instead,
which takes care of managing the event loop for you.
Parameters
----------
warn : bool, default: True
If ``True`` and we are not running headless (i.e. on Linux with an
unset DISPLAY), issue warning when called on a non-GUI backend.
"""
if self.canvas.manager is None:
raise AttributeError(
"Figure.show works only for figures managed by pyplot, "
"normally created by pyplot.figure()")
try:
self.canvas.manager.show()
except NonGuiException as exc:
cbook._warn_external(str(exc))
def get_axes(self):
"""
Return a list of axes in the Figure. You can access and modify the
axes in the Figure through this list.
Do not modify the list itself. Instead, use `~Figure.add_axes`,
`~.Figure.add_subplot` or `~.Figure.delaxes` to add or remove an axes.
Note: This is equivalent to the property `~.Figure.axes`.
"""
return self._axstack.as_list()
axes = property(get_axes, doc="""
List of axes in the Figure. You can access and modify the axes in the
Figure through this list.
Do not modify the list itself. Instead, use "`~Figure.add_axes`,
`~.Figure.add_subplot` or `~.Figure.delaxes` to add or remove an axes.
""")
def _get_dpi(self):
return self._dpi
def _set_dpi(self, dpi, forward=True):
"""
Parameters
----------
dpi : float
forward : bool
Passed on to `~.Figure.set_size_inches`
"""
if dpi == self._dpi:
# We don't want to cause undue events in backends.
return
self._dpi = dpi
self.dpi_scale_trans.clear().scale(dpi)
w, h = self.get_size_inches()
self.set_size_inches(w, h, forward=forward)
self.callbacks.process('dpi_changed', self)
dpi = property(_get_dpi, _set_dpi, doc="The resolution in dots per inch.")
def get_tight_layout(self):
"""Return whether `.tight_layout` is called when drawing."""
return self._tight
def set_tight_layout(self, tight):
"""
Set whether and how `.tight_layout` is called when drawing.
Parameters
----------
tight : bool or dict with keys "pad", "w_pad", "h_pad", "rect" or None
If a bool, sets whether to call `.tight_layout` upon drawing.
If ``None``, use the ``figure.autolayout`` rcparam instead.
If a dict, pass it as kwargs to `.tight_layout`, overriding the
default paddings.
"""
if tight is None:
tight = mpl.rcParams['figure.autolayout']
self._tight = bool(tight)
self._tight_parameters = tight if isinstance(tight, dict) else {}
self.stale = True
def get_constrained_layout(self):
"""
Return whether constrained layout is being used.
See :doc:`/tutorials/intermediate/constrainedlayout_guide`.
"""
return self._constrained
def set_constrained_layout(self, constrained):
"""
Set whether ``constrained_layout`` is used upon drawing. If None,
:rc:`figure.constrained_layout.use` value will be used.
When providing a dict containing the keys `w_pad`, `h_pad`
the default ``constrained_layout`` paddings will be
overridden. These pads are in inches and default to 3.0/72.0.
``w_pad`` is the width padding and ``h_pad`` is the height padding.
See :doc:`/tutorials/intermediate/constrainedlayout_guide`.
Parameters
----------
constrained : bool or dict or None
"""
self._constrained_layout_pads = dict()
self._constrained_layout_pads['w_pad'] = None
self._constrained_layout_pads['h_pad'] = None
self._constrained_layout_pads['wspace'] = None
self._constrained_layout_pads['hspace'] = None
if constrained is None:
constrained = mpl.rcParams['figure.constrained_layout.use']
self._constrained = bool(constrained)
if isinstance(constrained, dict):
self.set_constrained_layout_pads(**constrained)
else:
self.set_constrained_layout_pads()
self.stale = True
def set_constrained_layout_pads(self, **kwargs):
"""
Set padding for ``constrained_layout``. Note the kwargs can be passed
as a dictionary ``fig.set_constrained_layout(**paddict)``.
See :doc:`/tutorials/intermediate/constrainedlayout_guide`.
Parameters
----------
w_pad : float
Width padding in inches. This is the pad around axes
and is meant to make sure there is enough room for fonts to
look good. Defaults to 3 pts = 0.04167 inches
h_pad : float
Height padding in inches. Defaults to 3 pts.
wspace : float
Width padding between subplots, expressed as a fraction of the
subplot width. The total padding ends up being w_pad + wspace.
hspace : float
Height padding between subplots, expressed as a fraction of the
subplot width. The total padding ends up being h_pad + hspace.
"""
todo = ['w_pad', 'h_pad', 'wspace', 'hspace']
for td in todo:
if td in kwargs and kwargs[td] is not None:
self._constrained_layout_pads[td] = kwargs[td]
else:
self._constrained_layout_pads[td] = (
mpl.rcParams['figure.constrained_layout.' + td])
def get_constrained_layout_pads(self, relative=False):
"""
Get padding for ``constrained_layout``.
Returns a list of ``w_pad, h_pad`` in inches and
``wspace`` and ``hspace`` as fractions of the subplot.
See :doc:`/tutorials/intermediate/constrainedlayout_guide`.
Parameters
----------
relative : bool
If `True`, then convert from inches to figure relative.
"""
w_pad = self._constrained_layout_pads['w_pad']
h_pad = self._constrained_layout_pads['h_pad']
wspace = self._constrained_layout_pads['wspace']
hspace = self._constrained_layout_pads['hspace']
if relative and (w_pad is not None or h_pad is not None):
renderer0 = layoutbox.get_renderer(self)
dpi = renderer0.dpi
w_pad = w_pad * dpi / renderer0.width
h_pad = h_pad * dpi / renderer0.height
return w_pad, h_pad, wspace, hspace
def autofmt_xdate(
self, bottom=0.2, rotation=30, ha='right', which='major'):
"""
Date ticklabels often overlap, so it is useful to rotate them
and right align them. Also, a common use case is a number of
subplots with shared xaxes where the x-axis is date data. The
ticklabels are often long, and it helps to rotate them on the
bottom subplot and turn them off on other subplots, as well as
turn off xlabels.
Parameters
----------
bottom : float, default: 0.2
The bottom of the subplots for `subplots_adjust`.
rotation : float, default: 30 degrees
The rotation angle of the xtick labels in degrees.
ha : {'left', 'center', 'right'}, default: 'right'
The horizontal alignment of the xticklabels.
which : {'major', 'minor', 'both'}, default: 'major'
Selects which ticklabels to rotate.
"""
if which is None:
cbook.warn_deprecated(
"3.3", message="Support for passing which=None to mean "
"which='major' is deprecated since %(since)s and will be "
"removed %(removal)s.")
allsubplots = all(hasattr(ax, 'is_last_row') for ax in self.axes)
if len(self.axes) == 1:
for label in self.axes[0].get_xticklabels(which=which):
label.set_ha(ha)
label.set_rotation(rotation)
else:
if allsubplots:
for ax in self.get_axes():
if ax.is_last_row():
for label in ax.get_xticklabels(which=which):
label.set_ha(ha)
label.set_rotation(rotation)
else:
for label in ax.get_xticklabels(which=which):
label.set_visible(False)
ax.set_xlabel('')
if allsubplots:
self.subplots_adjust(bottom=bottom)
self.stale = True
def get_children(self):
"""Get a list of artists contained in the figure."""
return [self.patch,
*self.artists,
*self.axes,
*self.lines,
*self.patches,
*self.texts,
*self.images,
*self.legends]
def contains(self, mouseevent):
"""
Test whether the mouse event occurred on the figure.
Returns
-------
bool, {}
"""
inside, info = self._default_contains(mouseevent, figure=self)
if inside is not None:
return inside, info
inside = self.bbox.contains(mouseevent.x, mouseevent.y)
return inside, {}
def get_window_extent(self, *args, **kwargs):
"""
Return the figure bounding box in display space. Arguments are ignored.
"""
return self.bbox
def suptitle(self, t, **kwargs):
"""
Add a centered title to the figure.
Parameters
----------
t : str
The title text.
x : float, default 0.5
The x location of the text in figure coordinates.
y : float, default 0.98
The y location of the text in figure coordinates.
horizontalalignment, ha : {'center', 'left', right'}, default: 'center'
The horizontal alignment of the text relative to (*x*, *y*).
verticalalignment, va : {'top', 'center', 'bottom', 'baseline'}, \
default: 'top'
The vertical alignment of the text relative to (*x*, *y*).
fontsize, size : default: :rc:`figure.titlesize`
The font size of the text. See `.Text.set_size` for possible
values.
fontweight, weight : default: :rc:`figure.titleweight`
The font weight of the text. See `.Text.set_weight` for possible
values.
Returns
-------
text
The `.Text` instance of the title.
Other Parameters
----------------
fontproperties : None or dict, optional
A dict of font properties. If *fontproperties* is given the
default values for font size and weight are taken from the
`.FontProperties` defaults. :rc:`figure.titlesize` and
:rc:`figure.titleweight` are ignored in this case.
**kwargs
Additional kwargs are `matplotlib.text.Text` properties.
Examples
--------
>>> fig.suptitle('This is the figure title', fontsize=12)
"""
manual_position = ('x' in kwargs or 'y' in kwargs)
x = kwargs.pop('x', 0.5)
y = kwargs.pop('y', 0.98)
if 'horizontalalignment' not in kwargs and 'ha' not in kwargs:
kwargs['horizontalalignment'] = 'center'
if 'verticalalignment' not in kwargs and 'va' not in kwargs:
kwargs['verticalalignment'] = 'top'
if 'fontproperties' not in kwargs:
if 'fontsize' not in kwargs and 'size' not in kwargs:
kwargs['size'] = mpl.rcParams['figure.titlesize']
if 'fontweight' not in kwargs and 'weight' not in kwargs:
kwargs['weight'] = mpl.rcParams['figure.titleweight']
sup = self.text(x, y, t, **kwargs)
if self._suptitle is not None:
self._suptitle.set_text(t)
self._suptitle.set_position((x, y))
self._suptitle.update_from(sup)
sup.remove()
else:
self._suptitle = sup
self._suptitle._layoutbox = None
if self._layoutbox is not None and not manual_position:
w_pad, h_pad, wspace, hspace = \
self.get_constrained_layout_pads(relative=True)
figlb = self._layoutbox
self._suptitle._layoutbox = layoutbox.LayoutBox(
parent=figlb, artist=self._suptitle,
name=figlb.name+'.suptitle')
# stack the suptitle on top of all the children.
# Some day this should be on top of all the children in the
# gridspec only.
for child in figlb.children:
if child is not self._suptitle._layoutbox:
layoutbox.vstack([self._suptitle._layoutbox,
child],
padding=h_pad*2., strength='required')
self.stale = True
return self._suptitle
def set_canvas(self, canvas):
"""
Set the canvas that contains the figure
Parameters
----------
canvas : FigureCanvas
"""
self.canvas = canvas
def figimage(self, X, xo=0, yo=0, alpha=None, norm=None, cmap=None,
vmin=None, vmax=None, origin=None, resize=False, **kwargs):
"""
Add a non-resampled image to the figure.
The image is attached to the lower or upper left corner depending on
*origin*.
Parameters
----------
X
The image data. This is an array of one of the following shapes:
- MxN: luminance (grayscale) values
- MxNx3: RGB values
- MxNx4: RGBA values
xo, yo : int
The *x*/*y* image offset in pixels.
alpha : None or float
The alpha blending value.
norm : `matplotlib.colors.Normalize`
A `.Normalize` instance to map the luminance to the
interval [0, 1].
cmap : str or `matplotlib.colors.Colormap`, default: :rc:`image.cmap`
The colormap to use.
vmin, vmax : float
If *norm* is not given, these values set the data limits for the
colormap.
origin : {'upper', 'lower'}, default: :rc:`image.origin`
Indicates where the [0, 0] index of the array is in the upper left
or lower left corner of the axes.
resize : bool
If *True*, resize the figure to match the given image size.
Returns
-------
`matplotlib.image.FigureImage`
Other Parameters
----------------
**kwargs
Additional kwargs are `.Artist` kwargs passed on to `.FigureImage`.
Notes
-----
figimage complements the axes image (`~matplotlib.axes.Axes.imshow`)
which will be resampled to fit the current axes. If you want
a resampled image to fill the entire figure, you can define an
`~matplotlib.axes.Axes` with extent [0, 0, 1, 1].
Examples
--------
::
f = plt.figure()
nx = int(f.get_figwidth() * f.dpi)
ny = int(f.get_figheight() * f.dpi)
data = np.random.random((ny, nx))
f.figimage(data)
plt.show()
"""
if resize:
dpi = self.get_dpi()
figsize = [x / dpi for x in (X.shape[1], X.shape[0])]
self.set_size_inches(figsize, forward=True)
im = mimage.FigureImage(self, cmap, norm, xo, yo, origin, **kwargs)
im.stale_callback = _stale_figure_callback
im.set_array(X)
im.set_alpha(alpha)
if norm is None:
im.set_clim(vmin, vmax)
self.images.append(im)
im._remove_method = self.images.remove
self.stale = True
return im
def set_size_inches(self, w, h=None, forward=True):
"""
Set the figure size in inches.
Call signatures::
fig.set_size_inches(w, h) # OR
fig.set_size_inches((w, h))
Parameters
----------
w : (float, float) or float
Width and height in inches (if height not specified as a separate
argument) or width.
h : float
Height in inches.
forward : bool, default: True
If ``True``, the canvas size is automatically updated, e.g.,
you can resize the figure window from the shell.
See Also
--------
matplotlib.figure.Figure.get_size_inches
matplotlib.figure.Figure.set_figwidth
matplotlib.figure.Figure.set_figheight
Notes
-----
To transform from pixels to inches divide by `Figure.dpi`.
"""
if h is None: # Got called with a single pair as argument.
w, h = w
size = np.array([w, h])
if not np.isfinite(size).all() or (size < 0).any():
raise ValueError(f'figure size must be positive finite not {size}')
self.bbox_inches.p1 = size
if forward:
canvas = getattr(self, 'canvas')
if canvas is not None:
dpi_ratio = getattr(canvas, '_dpi_ratio', 1)
manager = getattr(canvas, 'manager', None)
if manager is not None:
manager.resize(*(size * self.dpi / dpi_ratio).astype(int))
self.stale = True
def get_size_inches(self):
"""
Return the current size of the figure in inches.
Returns
-------
ndarray
The size (width, height) of the figure in inches.
See Also
--------
matplotlib.figure.Figure.set_size_inches
matplotlib.figure.Figure.get_figwidth
matplotlib.figure.Figure.get_figheight
Notes
-----
The size in pixels can be obtained by multiplying with `Figure.dpi`.
"""
return np.array(self.bbox_inches.p1)
def get_edgecolor(self):
"""Get the edge color of the Figure rectangle."""
return self.patch.get_edgecolor()
def get_facecolor(self):
"""Get the face color of the Figure rectangle."""
return self.patch.get_facecolor()
def get_figwidth(self):
"""Return the figure width in inches."""
return self.bbox_inches.width
def get_figheight(self):
"""Return the figure height in inches."""
return self.bbox_inches.height
def get_dpi(self):
"""Return the resolution in dots per inch as a float."""
return self.dpi
def get_frameon(self):
"""
Return the figure's background patch visibility, i.e.
whether the figure background will be drawn. Equivalent to
``Figure.patch.get_visible()``.
"""
return self.patch.get_visible()
def set_edgecolor(self, color):
"""
Set the edge color of the Figure rectangle.
Parameters
----------
color : color
"""
self.patch.set_edgecolor(color)
def set_facecolor(self, color):
"""
Set the face color of the Figure rectangle.
Parameters
----------
color : color
"""
self.patch.set_facecolor(color)
def set_dpi(self, val):
"""
Set the resolution of the figure in dots-per-inch.
Parameters
----------
val : float
"""
self.dpi = val
self.stale = True
def set_figwidth(self, val, forward=True):
"""
Set the width of the figure in inches.
Parameters
----------
val : float
forward : bool
See `set_size_inches`.
See Also
--------
matplotlib.figure.Figure.set_figheight
matplotlib.figure.Figure.set_size_inches
"""
self.set_size_inches(val, self.get_figheight(), forward=forward)
def set_figheight(self, val, forward=True):
"""
Set the height of the figure in inches.
Parameters
----------
val : float
forward : bool
See `set_size_inches`.
See Also
--------
matplotlib.figure.Figure.set_figwidth
matplotlib.figure.Figure.set_size_inches
"""
self.set_size_inches(self.get_figwidth(), val, forward=forward)
def set_frameon(self, b):
"""
Set the figure's background patch visibility, i.e.
whether the figure background will be drawn. Equivalent to
``Figure.patch.set_visible()``.
Parameters
----------
b : bool
"""
self.patch.set_visible(b)
self.stale = True
frameon = property(get_frameon, set_frameon)
def add_artist(self, artist, clip=False):
"""
Add an `.Artist` to the figure.
Usually artists are added to axes objects using `.Axes.add_artist`;
this method can be used in the rare cases where one needs to add
artists directly to the figure instead.
Parameters
----------
artist : `~matplotlib.artist.Artist`
The artist to add to the figure. If the added artist has no
transform previously set, its transform will be set to
``figure.transFigure``.
clip : bool, default: False
Whether the added artist should be clipped by the figure patch.
Returns
-------
`~matplotlib.artist.Artist`
The added artist.
"""
artist.set_figure(self)
self.artists.append(artist)
artist._remove_method = self.artists.remove
if not artist.is_transform_set():
artist.set_transform(self.transFigure)
if clip:
artist.set_clip_path(self.patch)
self.stale = True
return artist
def _make_key(self, *args, **kwargs):
"""Make a hashable key out of args and kwargs."""
def fixitems(items):
# items may have arrays and lists in them, so convert them
# to tuples for the key
ret = []
for k, v in items:
# some objects can define __getitem__ without being
# iterable and in those cases the conversion to tuples
# will fail. So instead of using the np.iterable(v) function
# we simply try and convert to a tuple, and proceed if not.
try:
v = tuple(v)
except Exception:
pass
ret.append((k, v))
return tuple(ret)
def fixlist(args):
ret = []
for a in args:
if np.iterable(a):
a = tuple(a)
ret.append(a)
return tuple(ret)
key = fixlist(args), fixitems(kwargs.items())
return key
def _process_projection_requirements(
self, *args, polar=False, projection=None, **kwargs):
"""
Handle the args/kwargs to add_axes/add_subplot/gca, returning::
(axes_proj_class, proj_class_kwargs, proj_stack_key)
which can be used for new axes initialization/identification.
"""
if polar:
if projection is not None and projection != 'polar':
raise ValueError(
"polar=True, yet projection=%r. "
"Only one of these arguments should be supplied." %
projection)
projection = 'polar'
if isinstance(projection, str) or projection is None:
projection_class = projections.get_projection_class(projection)
elif hasattr(projection, '_as_mpl_axes'):
projection_class, extra_kwargs = projection._as_mpl_axes()
kwargs.update(**extra_kwargs)
else:
raise TypeError('projection must be a string, None or implement a '
'_as_mpl_axes method. Got %r' % projection)
# Make the key without projection kwargs, this is used as a unique
# lookup for axes instances
key = self._make_key(*args, **kwargs)
return projection_class, kwargs, key
@docstring.dedent_interpd
def add_axes(self, *args, **kwargs):
"""
Add an axes to the figure.
Call signatures::
add_axes(rect, projection=None, polar=False, **kwargs)
add_axes(ax)
Parameters
----------
rect : sequence of float
The dimensions [left, bottom, width, height] of the new axes. All
quantities are in fractions of figure width and height.
projection : {None, 'aitoff', 'hammer', 'lambert', 'mollweide', \
'polar', 'rectilinear', str}, optional
The projection type of the `~.axes.Axes`. *str* is the name of
a custom projection, see `~matplotlib.projections`. The default
None results in a 'rectilinear' projection.
polar : bool, default: False
If True, equivalent to projection='polar'.
sharex, sharey : `~.axes.Axes`, optional
Share the x or y `~matplotlib.axis` with sharex and/or sharey.
The axis will have the same limits, ticks, and scale as the axis
of the shared axes.
label : str
A label for the returned axes.
Returns
-------
`~.axes.Axes`, or a subclass of `~.axes.Axes`
The returned axes class depends on the projection used. It is
`~.axes.Axes` if rectilinear projection is used and
`.projections.polar.PolarAxes` if polar projection is used.
Other Parameters
----------------
**kwargs
This method also takes the keyword arguments for
the returned axes class. The keyword arguments for the
rectilinear axes class `~.axes.Axes` can be found in
the following table but there might also be other keyword
arguments if another projection is used, see the actual axes
class.
%(Axes)s
Notes
-----
If the figure already has an axes with key (*args*,
*kwargs*) then it will simply make that axes current and
return it. This behavior is deprecated. Meanwhile, if you do
not want this behavior (i.e., you want to force the creation of a
new axes), you must use a unique set of args and kwargs. The axes
*label* attribute has been exposed for this purpose: if you want
two axes that are otherwise identical to be added to the figure,
make sure you give them unique labels.
In rare circumstances, `.add_axes` may be called with a single
argument, a axes instance already created in the present figure but
not in the figure's list of axes.
See Also
--------
.Figure.add_subplot
.pyplot.subplot
.pyplot.axes
.Figure.subplots
.pyplot.subplots
Examples
--------
Some simple examples::
rect = l, b, w, h
fig = plt.figure()
fig.add_axes(rect, label=label1)
fig.add_axes(rect, label=label2)
fig.add_axes(rect, frameon=False, facecolor='g')
fig.add_axes(rect, polar=True)
ax = fig.add_axes(rect, projection='polar')
fig.delaxes(ax)
fig.add_axes(ax)
"""
if not len(args) and 'rect' not in kwargs:
cbook.warn_deprecated(
"3.3",
message="Calling add_axes() without argument is "
"deprecated since %(since)s and will be removed %(removal)s. "
"You may want to use add_subplot() instead.")
return
elif 'rect' in kwargs:
if len(args):
raise TypeError(
"add_axes() got multiple values for argument 'rect'")
args = (kwargs.pop('rect'), )
# shortcut the projection "key" modifications later on, if an axes
# with the exact args/kwargs exists, return it immediately.
key = self._make_key(*args, **kwargs)
ax = self._axstack.get(key)
if ax is not None:
self.sca(ax)
return ax
if isinstance(args[0], Axes):
a = args[0]
if a.get_figure() is not self:
raise ValueError(
"The Axes must have been created in the present figure")
else:
rect = args[0]
if not np.isfinite(rect).all():
raise ValueError('all entries in rect must be finite '
'not {}'.format(rect))
projection_class, kwargs, key = \
self._process_projection_requirements(*args, **kwargs)
# check that an axes of this type doesn't already exist, if it
# does, set it as active and return it
ax = self._axstack.get(key)
if isinstance(ax, projection_class):
self.sca(ax)
return ax
# create the new axes using the axes class given
a = projection_class(self, rect, **kwargs)
return self._add_axes_internal(key, a)
@docstring.dedent_interpd
def add_subplot(self, *args, **kwargs):
"""
Add an `~.axes.Axes` to the figure as part of a subplot arrangement.
Call signatures::
add_subplot(nrows, ncols, index, **kwargs)
add_subplot(pos, **kwargs)
add_subplot(ax)
add_subplot()
Parameters
----------
*args : int, (int, int, *index*), or `.SubplotSpec`, default: (1, 1, 1)
The position of the subplot described by one of
- Three integers (*nrows*, *ncols*, *index*). The subplot will
take the *index* position on a grid with *nrows* rows and
*ncols* columns. *index* starts at 1 in the upper left corner
and increases to the right. *index* can also be a two-tuple
specifying the (*first*, *last*) indices (1-based, and including
*last*) of the subplot, e.g., ``fig.add_subplot(3, 1, (1, 2))``
makes a subplot that spans the upper 2/3 of the figure.
- A 3-digit integer. The digits are interpreted as if given
separately as three single-digit integers, i.e.
``fig.add_subplot(235)`` is the same as
``fig.add_subplot(2, 3, 5)``. Note that this can only be used
if there are no more than 9 subplots.
- A `.SubplotSpec`.
In rare circumstances, `.add_subplot` may be called with a single
argument, a subplot axes instance already created in the
present figure but not in the figure's list of axes.
projection : {None, 'aitoff', 'hammer', 'lambert', 'mollweide', \
'polar', 'rectilinear', str}, optional
The projection type of the subplot (`~.axes.Axes`). *str* is the
name of a custom projection, see `~matplotlib.projections`. The
default None results in a 'rectilinear' projection.
polar : bool, default: False
If True, equivalent to projection='polar'.
sharex, sharey : `~.axes.Axes`, optional
Share the x or y `~matplotlib.axis` with sharex and/or sharey.
The axis will have the same limits, ticks, and scale as the axis
of the shared axes.
label : str
A label for the returned axes.
Returns
-------
`.axes.SubplotBase`, or another subclass of `~.axes.Axes`
The axes of the subplot. The returned axes base class depends on
the projection used. It is `~.axes.Axes` if rectilinear projection
is used and `.projections.polar.PolarAxes` if polar projection
is used. The returned axes is then a subplot subclass of the
base class.
Other Parameters
----------------
**kwargs
This method also takes the keyword arguments for the returned axes
base class; except for the *figure* argument. The keyword arguments
for the rectilinear base class `~.axes.Axes` can be found in
the following table but there might also be other keyword
arguments if another projection is used.
%(Axes)s
Notes
-----
If the figure already has a subplot with key (*args*,
*kwargs*) then it will simply make that subplot current and
return it. This behavior is deprecated. Meanwhile, if you do
not want this behavior (i.e., you want to force the creation of a
new subplot), you must use a unique set of args and kwargs. The axes
*label* attribute has been exposed for this purpose: if you want
two subplots that are otherwise identical to be added to the figure,
make sure you give them unique labels.
See Also
--------
.Figure.add_axes
.pyplot.subplot
.pyplot.axes
.Figure.subplots
.pyplot.subplots
Examples
--------
::
fig = plt.figure()
fig.add_subplot(231)
ax1 = fig.add_subplot(2, 3, 1) # equivalent but more general
fig.add_subplot(232, frameon=False) # subplot with no frame
fig.add_subplot(233, projection='polar') # polar subplot
fig.add_subplot(234, sharex=ax1) # subplot sharing x-axis with ax1
fig.add_subplot(235, facecolor="red") # red subplot
ax1.remove() # delete ax1 from the figure
fig.add_subplot(ax1) # add ax1 back to the figure
"""
if 'figure' in kwargs:
# Axes itself allows for a 'figure' kwarg, but since we want to
# bind the created Axes to self, it is not allowed here.
raise TypeError(
"add_subplot() got an unexpected keyword argument 'figure'")
if len(args) == 1 and isinstance(args[0], SubplotBase):
ax = args[0]
if ax.get_figure() is not self:
raise ValueError("The Subplot must have been created in "
"the present figure")
# make a key for the subplot (which includes the axes object id
# in the hash)
key = self._make_key(*args, **kwargs)
else:
if not args:
args = (1, 1, 1)
# Normalize correct ijk values to (i, j, k) here so that
# add_subplot(111) == add_subplot(1, 1, 1). Invalid values will
# trigger errors later (via SubplotSpec._from_subplot_args).
if (len(args) == 1 and isinstance(args[0], Integral)
and 100 <= args[0] <= 999):
args = tuple(map(int, str(args[0])))
projection_class, kwargs, key = \
self._process_projection_requirements(*args, **kwargs)
ax = self._axstack.get(key) # search axes with this key in stack
if ax is not None:
if isinstance(ax, projection_class):
# the axes already existed, so set it as active & return
self.sca(ax)
return ax
else:
# Undocumented convenience behavior:
# subplot(111); subplot(111, projection='polar')
# will replace the first with the second.
# Without this, add_subplot would be simpler and
# more similar to add_axes.
self._axstack.remove(ax)
ax = subplot_class_factory(projection_class)(self, *args, **kwargs)
return self._add_axes_internal(key, ax)
def _add_axes_internal(self, key, ax):
"""Private helper for `add_axes` and `add_subplot`."""
self._axstack.add(key, ax)
self.sca(ax)
ax._remove_method = self.delaxes
self.stale = True
ax.stale_callback = _stale_figure_callback
return ax
@cbook._make_keyword_only("3.3", "sharex")
def subplots(self, nrows=1, ncols=1, sharex=False, sharey=False,
squeeze=True, subplot_kw=None, gridspec_kw=None):
"""
Add a set of subplots to this figure.
This utility wrapper makes it convenient to create common layouts of
subplots in a single call.
Parameters
----------
nrows, ncols : int, default: 1
Number of rows/columns of the subplot grid.
sharex, sharey : bool or {'none', 'all', 'row', 'col'}, default: False
Controls sharing of properties among x (*sharex*) or y (*sharey*)
axes:
- True or 'all': x- or y-axis will be shared among all subplots.
- False or 'none': each subplot x- or y-axis will be independent.
- 'row': each subplot row will share an x- or y-axis.
- 'col': each subplot column will share an x- or y-axis.
When subplots have a shared x-axis along a column, only the x tick
labels of the bottom subplot are created. Similarly, when subplots
have a shared y-axis along a row, only the y tick labels of the
first column subplot are created. To later turn other subplots'
ticklabels on, use `~matplotlib.axes.Axes.tick_params`.
squeeze : bool, default: True
- If True, extra dimensions are squeezed out from the returned
array of Axes:
- if only one subplot is constructed (nrows=ncols=1), the
resulting single Axes object is returned as a scalar.
- for Nx1 or 1xM subplots, the returned object is a 1D numpy
object array of Axes objects.
- for NxM, subplots with N>1 and M>1 are returned as a 2D array.
- If False, no squeezing at all is done: the returned Axes object
is always a 2D array containing Axes instances, even if it ends
up being 1x1.
subplot_kw : dict, optional
Dict with keywords passed to the `.Figure.add_subplot` call used to
create each subplot.
gridspec_kw : dict, optional
Dict with keywords passed to the
`~matplotlib.gridspec.GridSpec` constructor used to create
the grid the subplots are placed on.
Returns
-------
`~.axes.Axes` or array of Axes
Either a single `~matplotlib.axes.Axes` object or an array of Axes
objects if more than one subplot was created. The dimensions of the
resulting array can be controlled with the *squeeze* keyword, see
above.
See Also
--------
.pyplot.subplots
.Figure.add_subplot
.pyplot.subplot
Examples
--------
::
# First create some toy data:
x = np.linspace(0, 2*np.pi, 400)
y = np.sin(x**2)
# Create a figure
plt.figure()
# Create a subplot
ax = fig.subplots()
ax.plot(x, y)
ax.set_title('Simple plot')
# Create two subplots and unpack the output array immediately
ax1, ax2 = fig.subplots(1, 2, sharey=True)
ax1.plot(x, y)
ax1.set_title('Sharing Y axis')
ax2.scatter(x, y)
# Create four polar axes and access them through the returned array
axes = fig.subplots(2, 2, subplot_kw=dict(polar=True))
axes[0, 0].plot(x, y)
axes[1, 1].scatter(x, y)
# Share a X axis with each column of subplots
fig.subplots(2, 2, sharex='col')
# Share a Y axis with each row of subplots
fig.subplots(2, 2, sharey='row')
# Share both X and Y axes with all subplots
fig.subplots(2, 2, sharex='all', sharey='all')
# Note that this is the same as
fig.subplots(2, 2, sharex=True, sharey=True)
"""
if gridspec_kw is None:
gridspec_kw = {}
return (self.add_gridspec(nrows, ncols, figure=self, **gridspec_kw)
.subplots(sharex=sharex, sharey=sharey, squeeze=squeeze,
subplot_kw=subplot_kw))
@staticmethod
def _normalize_grid_string(layout):
layout = inspect.cleandoc(layout)
return [list(ln) for ln in layout.strip('\n').split('\n')]
def subplot_mosaic(self, layout, *, subplot_kw=None, gridspec_kw=None,
empty_sentinel='.'):
"""
Build a layout of Axes based on ASCII art or nested lists.
This is a helper function to build complex GridSpec layouts visually.
.. note ::
This API is provisional and may be revised in the future based on
early user feedback.
Parameters
----------
layout : list of list of {hashable or nested} or str
A visual layout of how you want your Axes to be arranged
labeled as strings. For example ::
x = [['A panel', 'A panel', 'edge'],
['C panel', '.', 'edge']]
Produces 4 axes:
- 'A panel' which is 1 row high and spans the first two columns
- 'edge' which is 2 rows high and is on the right edge
- 'C panel' which in 1 row and 1 column wide in the bottom left
- a blank space 1 row and 1 column wide in the bottom center
Any of the entries in the layout can be a list of lists
of the same form to create nested layouts.
If input is a str, then it must be of the form ::
'''
AAE
C.E
'''
where each character is a column and each line is a row.
This only allows only single character Axes labels and does
not allow nesting but is very terse.
subplot_kw : dict, optional
Dictionary with keywords passed to the `.Figure.add_subplot` call
used to create each subplot.
gridspec_kw : dict, optional
Dictionary with keywords passed to the `.GridSpec` constructor used
to create the grid the subplots are placed on.
empty_sentinel : object, optional
Entry in the layout to mean "leave this space empty". Defaults
to ``'.'``. Note, if *layout* is a string, it is processed via
`inspect.cleandoc` to remove leading white space, which may
interfere with using white-space as the empty sentinel.
Returns
-------
dict[label, Axes]
A dictionary mapping the labels to the Axes objects.
"""
subplot_kw = subplot_kw or {}
gridspec_kw = gridspec_kw or {}
# special-case string input
if isinstance(layout, str):
layout = self._normalize_grid_string(layout)
def _make_array(inp):
"""
Convert input into 2D array
We need to have this internal function rather than
``np.asarray(..., dtype=object)`` so that a list of lists
of lists does not get converted to an array of dimension >
2
Returns
-------
2D object array
"""
r0, *rest = inp
for j, r in enumerate(rest, start=1):
if isinstance(r, str):
raise ValueError('List layout specification must be 2D')
if len(r0) != len(r):
raise ValueError(
"All of the rows must be the same length, however "
f"the first row ({r0!r}) has length {len(r0)} "
f"and row {j} ({r!r}) has length {len(r)}."
)
out = np.zeros((len(inp), len(r0)), dtype=object)
for j, r in enumerate(inp):
for k, v in enumerate(r):
out[j, k] = v
return out
def _identify_keys_and_nested(layout):
"""
Given a 2D object array, identify unique IDs and nested layouts
Parameters
----------
layout : 2D numpy object array
Returns
-------
unique_ids : Set[object]
The unique non-sub layout entries in this layout
nested : Dict[Tuple[int, int]], 2D object array
"""
unique_ids = set()
nested = {}
for j, row in enumerate(layout):
for k, v in enumerate(row):
if v == empty_sentinel:
continue
elif not cbook.is_scalar_or_string(v):
nested[(j, k)] = _make_array(v)
else:
unique_ids.add(v)
return unique_ids, nested
def _do_layout(gs, layout, unique_ids, nested):
"""
Recursively do the layout.
Parameters
----------
gs : GridSpec
layout : 2D object array
The input converted to a 2D numpy array for this level.
unique_ids : Set[object]
The identified scalar labels at this level of nesting.
nested : Dict[Tuple[int, int]], 2D object array
The identified nested layouts if any.
Returns
-------
Dict[label, Axes]
A flat dict of all of the Axes created.
"""
rows, cols = layout.shape
output = dict()
# create the Axes at this level of nesting
for name in unique_ids:
indx = np.argwhere(layout == name)
start_row, start_col = np.min(indx, axis=0)
end_row, end_col = np.max(indx, axis=0) + 1
slc = (slice(start_row, end_row), slice(start_col, end_col))
if (layout[slc] != name).any():
raise ValueError(
f"While trying to layout\n{layout!r}\n"
f"we found that the label {name!r} specifies a "
"non-rectangular or non-contiguous area.")
ax = self.add_subplot(
gs[slc], **{'label': str(name), **subplot_kw}
)
output[name] = ax
# do any sub-layouts
for (j, k), nested_layout in nested.items():
rows, cols = nested_layout.shape
nested_output = _do_layout(
gs[j, k].subgridspec(rows, cols, **gridspec_kw),
nested_layout,
*_identify_keys_and_nested(nested_layout)
)
overlap = set(output) & set(nested_output)
if overlap:
raise ValueError(f"There are duplicate keys {overlap} "
f"between the outer layout\n{layout!r}\n"
f"and the nested layout\n{nested_layout}")
output.update(nested_output)
return output
layout = _make_array(layout)
rows, cols = layout.shape
gs = self.add_gridspec(rows, cols, **gridspec_kw)
ret = _do_layout(gs, layout, *_identify_keys_and_nested(layout))
for k, ax in ret.items():
if isinstance(k, str):
ax.set_label(k)
return ret
def delaxes(self, ax):
"""
Remove the `~.axes.Axes` *ax* from the figure; update the current axes.
"""
def _reset_locators_and_formatters(axis):
# Set the formatters and locators to be associated with axis
# (where previously they may have been associated with another
# Axis instance)
#
# Because set_major_formatter() etc. force isDefault_* to be False,
# we have to manually check if the original formatter was a
# default and manually set isDefault_* if that was the case.
majfmt = axis.get_major_formatter()
isDefault = majfmt.axis.isDefault_majfmt
axis.set_major_formatter(majfmt)
if isDefault:
majfmt.axis.isDefault_majfmt = True
majloc = axis.get_major_locator()
isDefault = majloc.axis.isDefault_majloc
axis.set_major_locator(majloc)
if isDefault:
majloc.axis.isDefault_majloc = True
minfmt = axis.get_minor_formatter()
isDefault = majloc.axis.isDefault_minfmt
axis.set_minor_formatter(minfmt)
if isDefault:
minfmt.axis.isDefault_minfmt = True
minloc = axis.get_minor_locator()
isDefault = majloc.axis.isDefault_minloc
axis.set_minor_locator(minloc)
if isDefault:
minloc.axis.isDefault_minloc = True
def _break_share_link(ax, grouper):
siblings = grouper.get_siblings(ax)
if len(siblings) > 1:
grouper.remove(ax)
for last_ax in siblings:
if ax is not last_ax:
return last_ax
return None
self._axstack.remove(ax)
self._axobservers.process("_axes_change_event", self)
self.stale = True
last_ax = _break_share_link(ax, ax._shared_y_axes)
if last_ax is not None:
_reset_locators_and_formatters(last_ax.yaxis)
last_ax = _break_share_link(ax, ax._shared_x_axes)
if last_ax is not None:
_reset_locators_and_formatters(last_ax.xaxis)
def clf(self, keep_observers=False):
"""
Clear the figure.
Set *keep_observers* to True if, for example,
a gui widget is tracking the axes in the figure.
"""
self.suppressComposite = None
self.callbacks = cbook.CallbackRegistry()
for ax in tuple(self.axes): # Iterate over the copy.
ax.cla()
self.delaxes(ax) # removes ax from self._axstack
toolbar = getattr(self.canvas, 'toolbar', None)
if toolbar is not None:
toolbar.update()
self._axstack.clear()
self.artists = []
self.lines = []
self.patches = []
self.texts = []
self.images = []
self.legends = []
if not keep_observers:
self._axobservers = cbook.CallbackRegistry()
self._suptitle = None
if self.get_constrained_layout():
layoutbox.nonetree(self._layoutbox)
self.stale = True
def clear(self, keep_observers=False):
"""Clear the figure -- synonym for `clf`."""
self.clf(keep_observers=keep_observers)
@allow_rasterization
def draw(self, renderer):
# docstring inherited
self._cachedRenderer = renderer
# draw the figure bounding box, perhaps none for white figure
if not self.get_visible():
return
artists = self.get_children()
artists.remove(self.patch)
artists = sorted(
(artist for artist in artists if not artist.get_animated()),
key=lambda artist: artist.get_zorder())
for ax in self.axes:
locator = ax.get_axes_locator()
if locator:
pos = locator(ax, renderer)
ax.apply_aspect(pos)
else:
ax.apply_aspect()
for child in ax.get_children():
if hasattr(child, 'apply_aspect'):
locator = child.get_axes_locator()
if locator:
pos = locator(child, renderer)
child.apply_aspect(pos)
else:
child.apply_aspect()
try:
renderer.open_group('figure', gid=self.get_gid())
if self.get_constrained_layout() and self.axes:
self.execute_constrained_layout(renderer)
if self.get_tight_layout() and self.axes:
try:
self.tight_layout(**self._tight_parameters)
except ValueError:
pass
# ValueError can occur when resizing a window.
self.patch.draw(renderer)
mimage._draw_list_compositing_images(
renderer, self, artists, self.suppressComposite)
renderer.close_group('figure')
finally:
self.stale = False
self.canvas.draw_event(renderer)
def draw_artist(self, a):
"""
Draw `.Artist` instance *a* only.
This can only be called after the figure has been drawn.
"""
if self._cachedRenderer is None:
raise AttributeError("draw_artist can only be used after an "
"initial draw which caches the renderer")
a.draw(self._cachedRenderer)
# Note: in the docstring below, the newlines in the examples after the
# calls to legend() allow replacing it with figlegend() to generate the
# docstring of pyplot.figlegend.
@docstring.dedent_interpd
def legend(self, *args, **kwargs):
"""
Place a legend on the figure.
To make a legend from existing artists on every axes::
legend()
To make a legend for a list of lines and labels::
legend(
(line1, line2, line3),
('label1', 'label2', 'label3'),
loc='upper right')
These can also be specified by keyword::
legend(
handles=(line1, line2, line3),
labels=('label1', 'label2', 'label3'),
loc='upper right')
Parameters
----------
handles : list of `.Artist`, optional
A list of Artists (lines, patches) to be added to the legend.
Use this together with *labels*, if you need full control on what
is shown in the legend and the automatic mechanism described above
is not sufficient.
The length of handles and labels should be the same in this
case. If they are not, they are truncated to the smaller length.
labels : list of str, optional
A list of labels to show next to the artists.
Use this together with *handles*, if you need full control on what
is shown in the legend and the automatic mechanism described above
is not sufficient.
Returns
-------
`~matplotlib.legend.Legend`
Other Parameters
----------------
%(_legend_kw_doc)s
Notes
-----
Some artists are not supported by this function. See
:doc:`/tutorials/intermediate/legend_guide` for details.
"""
handles, labels, extra_args, kwargs = mlegend._parse_legend_args(
self.axes,
*args,
**kwargs)
# check for third arg
if len(extra_args):
# cbook.warn_deprecated(
# "2.1",
# message="Figure.legend will accept no more than two "
# "positional arguments in the future. Use "
# "'fig.legend(handles, labels, loc=location)' "
# "instead.")
# kwargs['loc'] = extra_args[0]
# extra_args = extra_args[1:]
pass
transform = kwargs.pop('bbox_transform', self.transFigure)
# explicitly set the bbox transform if the user hasn't.
l = mlegend.Legend(self, handles, labels, *extra_args,
bbox_transform=transform, **kwargs)
self.legends.append(l)
l._remove_method = self.legends.remove
self.stale = True
return l
@docstring.dedent_interpd
def text(self, x, y, s, fontdict=None, **kwargs):
"""
Add text to figure.
Parameters
----------
x, y : float
The position to place the text. By default, this is in figure
coordinates, floats in [0, 1]. The coordinate system can be changed
using the *transform* keyword.
s : str
The text string.
fontdict : dict, optional
A dictionary to override the default text properties. If not given,
the defaults are determined by :rc:`font.*`. Properties passed as
*kwargs* override the corresponding ones given in *fontdict*.
Returns
-------
`~.text.Text`
Other Parameters
----------------
**kwargs : `~matplotlib.text.Text` properties
Other miscellaneous text parameters.
%(Text)s
See Also
--------
.Axes.text
.pyplot.text
"""
effective_kwargs = {
'transform': self.transFigure,
**(fontdict if fontdict is not None else {}),
**kwargs,
}
text = Text(x=x, y=y, text=s, **effective_kwargs)
text.set_figure(self)
text.stale_callback = _stale_figure_callback
self.texts.append(text)
text._remove_method = self.texts.remove
self.stale = True
return text
def _set_artist_props(self, a):
if a != self:
a.set_figure(self)
a.stale_callback = _stale_figure_callback
a.set_transform(self.transFigure)
@docstring.dedent_interpd
def gca(self, **kwargs):
"""
Get the current axes, creating one if necessary.
The following kwargs are supported for ensuring the returned axes
adheres to the given projection etc., and for axes creation if
the active axes does not exist:
%(Axes)s
"""
ckey, cax = self._axstack.current_key_axes()
# if there exists an axes on the stack see if it matches
# the desired axes configuration
if cax is not None:
# if no kwargs are given just return the current axes
# this is a convenience for gca() on axes such as polar etc.
if not kwargs:
return cax
# if the user has specified particular projection detail
# then build up a key which can represent this
else:
projection_class, _, key = \
self._process_projection_requirements(**kwargs)
# let the returned axes have any gridspec by removing it from
# the key
ckey = ckey[1:]
key = key[1:]
# if the cax matches this key then return the axes, otherwise
# continue and a new axes will be created
if key == ckey and isinstance(cax, projection_class):
return cax
else:
cbook._warn_external('Requested projection is different '
'from current axis projection, '
'creating new axis with requested '
'projection.')
# no axes found, so create one which spans the figure
return self.add_subplot(1, 1, 1, **kwargs)
def sca(self, a):
"""Set the current axes to be *a* and return *a*."""
self._axstack.bubble(a)
self._axobservers.process("_axes_change_event", self)
return a
def _gci(self):
# Helper for `~matplotlib.pyplot.gci`. Do not use elsewhere.
"""
Get the current colorable artist.
Specifically, returns the current `.ScalarMappable` instance (`.Image`
created by `imshow` or `figimage`, `.Collection` created by `pcolor` or
`scatter`, etc.), or *None* if no such instance has been defined.
The current image is an attribute of the current axes, or the nearest
earlier axes in the current figure that contains an image.
Notes
-----
Historically, the only colorable artists were images; hence the name
``gci`` (get current image).
"""
# Look first for an image in the current Axes:
cax = self._axstack.current_key_axes()[1]
if cax is None:
return None
im = cax._gci()
if im is not None:
return im
# If there is no image in the current Axes, search for
# one in a previously created Axes. Whether this makes
# sense is debatable, but it is the documented behavior.
for ax in reversed(self.axes):
im = ax._gci()
if im is not None:
return im
return None
def __getstate__(self):
state = super().__getstate__()
# The canvas cannot currently be pickled, but this has the benefit
# of meaning that a figure can be detached from one canvas, and
# re-attached to another.
state.pop("canvas")
# Set cached renderer to None -- it can't be pickled.
state["_cachedRenderer"] = None
# add version information to the state
state['__mpl_version__'] = _mpl_version
# check whether the figure manager (if any) is registered with pyplot
from matplotlib import _pylab_helpers
if getattr(self.canvas, 'manager', None) \
in _pylab_helpers.Gcf.figs.values():
state['_restore_to_pylab'] = True
# set all the layoutbox information to None. kiwisolver objects can't
# be pickled, so we lose the layout options at this point.
state.pop('_layoutbox', None)
# suptitle:
if self._suptitle is not None:
self._suptitle._layoutbox = None
return state
def __setstate__(self, state):
version = state.pop('__mpl_version__')
restore_to_pylab = state.pop('_restore_to_pylab', False)
if version != _mpl_version:
cbook._warn_external(
f"This figure was saved with matplotlib version {version} and "
f"is unlikely to function correctly.")
self.__dict__ = state
# re-initialise some of the unstored state information
FigureCanvasBase(self) # Set self.canvas.
self._layoutbox = None
if restore_to_pylab:
# lazy import to avoid circularity
import matplotlib.pyplot as plt
import matplotlib._pylab_helpers as pylab_helpers
allnums = plt.get_fignums()
num = max(allnums) + 1 if allnums else 1
mgr = plt._backend_mod.new_figure_manager_given_figure(num, self)
pylab_helpers.Gcf._set_new_active_manager(mgr)
plt.draw_if_interactive()
self.stale = True
def add_axobserver(self, func):
"""Whenever the axes state change, ``func(self)`` will be called."""
# Connect a wrapper lambda and not func itself, to avoid it being
# weakref-collected.
self._axobservers.connect("_axes_change_event", lambda arg: func(arg))
def savefig(self, fname, *, transparent=None, **kwargs):
"""
Save the current figure.
Call signature::
savefig(fname, dpi=None, facecolor='w', edgecolor='w',
orientation='portrait', papertype=None, format=None,
transparent=False, bbox_inches=None, pad_inches=0.1,
frameon=None, metadata=None)
The available output formats depend on the backend being used.
Parameters
----------
fname : str or path-like or file-like
A path, or a Python file-like object, or
possibly some backend-dependent object such as
`matplotlib.backends.backend_pdf.PdfPages`.
If *format* is set, it determines the output format, and the file
is saved as *fname*. Note that *fname* is used verbatim, and there
is no attempt to make the extension, if any, of *fname* match
*format*, and no extension is appended.
If *format* is not set, then the format is inferred from the
extension of *fname*, if there is one. If *format* is not
set and *fname* has no extension, then the file is saved with
:rc:`savefig.format` and the appropriate extension is appended to
*fname*.
Other Parameters
----------------
dpi : float or 'figure', default: :rc:`savefig.dpi`
The resolution in dots per inch. If 'figure', use the figure's
dpi value.
quality : int, default: :rc:`savefig.jpeg_quality`
Applicable only if *format* is 'jpg' or 'jpeg', ignored otherwise.
The image quality, on a scale from 1 (worst) to 95 (best).
Values above 95 should be avoided; 100 disables portions of
the JPEG compression algorithm, and results in large files
with hardly any gain in image quality.
This parameter is deprecated.
optimize : bool, default: False
Applicable only if *format* is 'jpg' or 'jpeg', ignored otherwise.
Whether the encoder should make an extra pass over the image
in order to select optimal encoder settings.
This parameter is deprecated.
progressive : bool, default: False
Applicable only if *format* is 'jpg' or 'jpeg', ignored otherwise.
Whether the image should be stored as a progressive JPEG file.
This parameter is deprecated.
facecolor : color or 'auto', default: :rc:`savefig.facecolor`
The facecolor of the figure. If 'auto', use the current figure
facecolor.
edgecolor : color or 'auto', default: :rc:`savefig.edgecolor`
The edgecolor of the figure. If 'auto', use the current figure
edgecolor.
orientation : {'landscape', 'portrait'}
Currently only supported by the postscript backend.
papertype : str
One of 'letter', 'legal', 'executive', 'ledger', 'a0' through
'a10', 'b0' through 'b10'. Only supported for postscript
output.
format : str
The file format, e.g. 'png', 'pdf', 'svg', ... The behavior when
this is unset is documented under *fname*.
transparent : bool
If *True*, the axes patches will all be transparent; the
figure patch will also be transparent unless facecolor
and/or edgecolor are specified via kwargs.
This is useful, for example, for displaying
a plot on top of a colored background on a web page. The
transparency of these patches will be restored to their
original values upon exit of this function.
bbox_inches : str or `.Bbox`, default: :rc:`savefig.bbox`
Bounding box in inches: only the given portion of the figure is
saved. If 'tight', try to figure out the tight bbox of the figure.
pad_inches : float, default: :rc:`savefig.pad_inches`
Amount of padding around the figure when bbox_inches is 'tight'.
bbox_extra_artists : list of `~matplotlib.artist.Artist`, optional
A list of extra artists that will be considered when the
tight bbox is calculated.
backend : str, optional
Use a non-default backend to render the file, e.g. to render a
png file with the "cairo" backend rather than the default "agg",
or a pdf file with the "pgf" backend rather than the default
"pdf". Note that the default backend is normally sufficient. See
:ref:`the-builtin-backends` for a list of valid backends for each
file format. Custom backends can be referenced as "module://...".
metadata : dict, optional
Key/value pairs to store in the image metadata. The supported keys
and defaults depend on the image format and backend:
- 'png' with Agg backend: See the parameter ``metadata`` of
`~.FigureCanvasAgg.print_png`.
- 'pdf' with pdf backend: See the parameter ``metadata`` of
`~.backend_pdf.PdfPages`.
- 'svg' with svg backend: See the parameter ``metadata`` of
`~.FigureCanvasSVG.print_svg`.
- 'eps' and 'ps' with PS backend: Only 'Creator' is supported.
pil_kwargs : dict, optional
Additional keyword arguments that are passed to
`PIL.Image.Image.save` when saving the figure.
"""
kwargs.setdefault('dpi', mpl.rcParams['savefig.dpi'])
if transparent is None:
transparent = mpl.rcParams['savefig.transparent']
if transparent:
kwargs.setdefault('facecolor', 'none')
kwargs.setdefault('edgecolor', 'none')
original_axes_colors = []
for ax in self.axes:
patch = ax.patch
original_axes_colors.append((patch.get_facecolor(),
patch.get_edgecolor()))
patch.set_facecolor('none')
patch.set_edgecolor('none')
self.canvas.print_figure(fname, **kwargs)
if transparent:
for ax, cc in zip(self.axes, original_axes_colors):
ax.patch.set_facecolor(cc[0])
ax.patch.set_edgecolor(cc[1])
@docstring.dedent_interpd
def colorbar(self, mappable, cax=None, ax=None, use_gridspec=True, **kw):
"""
Create a colorbar for a ScalarMappable instance, *mappable*.
Documentation for the pyplot thin wrapper:
%(colorbar_doc)s
"""
if ax is None:
ax = self.gca()
# Store the value of gca so that we can set it back later on.
current_ax = self.gca()
if cax is None:
if use_gridspec and isinstance(ax, SubplotBase) \
and (not self.get_constrained_layout()):
cax, kw = cbar.make_axes_gridspec(ax, **kw)
else:
cax, kw = cbar.make_axes(ax, **kw)
# need to remove kws that cannot be passed to Colorbar
NON_COLORBAR_KEYS = ['fraction', 'pad', 'shrink', 'aspect', 'anchor',
'panchor']
cb_kw = {k: v for k, v in kw.items() if k not in NON_COLORBAR_KEYS}
cb = cbar.colorbar_factory(cax, mappable, **cb_kw)
self.sca(current_ax)
self.stale = True
return cb
def subplots_adjust(self, left=None, bottom=None, right=None, top=None,
wspace=None, hspace=None):
"""
Adjust the subplot layout parameters.
Unset parameters are left unmodified; initial values are given by
:rc:`figure.subplot.[name]`.
Parameters
----------
left : float, optional
The position of the left edge of the subplots,
as a fraction of the figure width.
right : float, optional
The position of the right edge of the subplots,
as a fraction of the figure width.
bottom : float, optional
The position of the bottom edge of the subplots,
as a fraction of the figure height.
top : float, optional
The position of the top edge of the subplots,
as a fraction of the figure height.
wspace : float, optional
The width of the padding between subplots,
as a fraction of the average axes width.
hspace : float, optional
The height of the padding between subplots,
as a fraction of the average axes height.
"""
if self.get_constrained_layout():
self.set_constrained_layout(False)
cbook._warn_external("This figure was using "
"constrained_layout==True, but that is "
"incompatible with subplots_adjust and or "
"tight_layout: setting "
"constrained_layout==False. ")
self.subplotpars.update(left, bottom, right, top, wspace, hspace)
for ax in self.axes:
if not isinstance(ax, SubplotBase):
# Check if sharing a subplots axis
if isinstance(ax._sharex, SubplotBase):
ax._sharex.update_params()
ax.set_position(ax._sharex.figbox)
elif isinstance(ax._sharey, SubplotBase):
ax._sharey.update_params()
ax.set_position(ax._sharey.figbox)
else:
ax.update_params()
ax.set_position(ax.figbox)
self.stale = True
def ginput(self, n=1, timeout=30, show_clicks=True,
mouse_add=MouseButton.LEFT,
mouse_pop=MouseButton.RIGHT,
mouse_stop=MouseButton.MIDDLE):
"""
Blocking call to interact with a figure.
Wait until the user clicks *n* times on the figure, and return the
coordinates of each click in a list.
There are three possible interactions:
- Add a point.
- Remove the most recently added point.
- Stop the interaction and return the points added so far.
The actions are assigned to mouse buttons via the arguments
*mouse_add*, *mouse_pop* and *mouse_stop*.
Parameters
----------
n : int, default: 1
Number of mouse clicks to accumulate. If negative, accumulate
clicks until the input is terminated manually.
timeout : float, default: 30 seconds
Number of seconds to wait before timing out. If zero or negative
will never timeout.
show_clicks : bool, default: True
If True, show a red cross at the location of each click.
mouse_add : `.MouseButton` or None, default: `.MouseButton.LEFT`
Mouse button used to add points.
mouse_pop : `.MouseButton` or None, default: `.MouseButton.RIGHT`
Mouse button used to remove the most recently added point.
mouse_stop : `.MouseButton` or None, default: `.MouseButton.MIDDLE`
Mouse button used to stop input.
Returns
-------
list of tuples
A list of the clicked (x, y) coordinates.
Notes
-----
The keyboard can also be used to select points in case your mouse
does not have one or more of the buttons. The delete and backspace
keys act like right clicking (i.e., remove last point), the enter key
terminates input and any other key (not already used by the window
manager) selects a point.
"""
blocking_mouse_input = BlockingMouseInput(self,
mouse_add=mouse_add,
mouse_pop=mouse_pop,
mouse_stop=mouse_stop)
return blocking_mouse_input(n=n, timeout=timeout,
show_clicks=show_clicks)
def waitforbuttonpress(self, timeout=-1):
"""
Blocking call to interact with the figure.
Wait for user input and return True if a key was pressed, False if a
mouse button was pressed and None if no input was given within
*timeout* seconds. Negative values deactivate *timeout*.
"""
blocking_input = BlockingKeyMouseInput(self)
return blocking_input(timeout=timeout)
def get_default_bbox_extra_artists(self):
bbox_artists = [artist for artist in self.get_children()
if (artist.get_visible() and artist.get_in_layout())]
for ax in self.axes:
if ax.get_visible():
bbox_artists.extend(ax.get_default_bbox_extra_artists())
return bbox_artists
def get_tightbbox(self, renderer, bbox_extra_artists=None):
"""
Return a (tight) bounding box of the figure in inches.
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 each axes are
included in the tight bounding box.
Returns
-------
`.BboxBase`
containing the bounding box (in figure inches).
"""
bb = []
if bbox_extra_artists is None:
artists = self.get_default_bbox_extra_artists()
else:
artists = bbox_extra_artists
for a in artists:
bbox = a.get_tightbbox(renderer)
if bbox is not None and (bbox.width != 0 or bbox.height != 0):
bb.append(bbox)
for ax in self.axes:
if ax.get_visible():
# some axes don't take the bbox_extra_artists kwarg so we
# need this conditional....
try:
bbox = ax.get_tightbbox(
renderer, bbox_extra_artists=bbox_extra_artists)
except TypeError:
bbox = ax.get_tightbbox(renderer)
bb.append(bbox)
bb = [b for b in bb
if (np.isfinite(b.width) and np.isfinite(b.height)
and (b.width != 0 or b.height != 0))]
if len(bb) == 0:
return self.bbox_inches
_bbox = Bbox.union(bb)
bbox_inches = TransformedBbox(_bbox, Affine2D().scale(1 / self.dpi))
return bbox_inches
def init_layoutbox(self):
"""Initialize the layoutbox for use in constrained_layout."""
if self._layoutbox is None:
self._layoutbox = layoutbox.LayoutBox(
parent=None, name='figlb', artist=self)
self._layoutbox.constrain_geometry(0., 0., 1., 1.)
def execute_constrained_layout(self, renderer=None):
"""
Use ``layoutbox`` to determine pos positions within axes.
See also `.set_constrained_layout_pads`.
"""
from matplotlib._constrained_layout import do_constrained_layout
_log.debug('Executing constrainedlayout')
if self._layoutbox is None:
cbook._warn_external("Calling figure.constrained_layout, but "
"figure not setup to do constrained layout. "
" You either called GridSpec without the "
"fig keyword, you are using plt.subplot, "
"or you need to call figure or subplots "
"with the constrained_layout=True kwarg.")
return
w_pad, h_pad, wspace, hspace = self.get_constrained_layout_pads()
# convert to unit-relative lengths
fig = self
width, height = fig.get_size_inches()
w_pad = w_pad / width
h_pad = h_pad / height
if renderer is None:
renderer = layoutbox.get_renderer(fig)
do_constrained_layout(fig, renderer, h_pad, w_pad, hspace, wspace)
@cbook._delete_parameter("3.2", "renderer")
def tight_layout(self, renderer=None, pad=1.08, h_pad=None, w_pad=None,
rect=None):
"""
Adjust the padding between and around subplots.
To exclude an artist on the axes from the bounding box calculation
that determines the subplot parameters (i.e. legend, or annotation),
set ``a.set_in_layout(False)`` for that artist.
Parameters
----------
renderer : subclass of `~.backend_bases.RendererBase`, optional
Defaults to the renderer for the figure. Deprecated.
pad : float, default: 1.08
Padding between the figure edge and the edges of subplots,
as a fraction of the font size.
h_pad, w_pad : float, default: *pad*
Padding (height/width) between edges of adjacent subplots,
as a fraction of the font size.
rect : tuple (left, bottom, right, top), default: (0, 0, 1, 1)
A rectangle in normalized figure coordinates into which the whole
subplots area (including labels) will fit.
See Also
--------
.Figure.set_tight_layout
.pyplot.tight_layout
"""
from .tight_layout import (
get_renderer, get_subplotspec_list, get_tight_layout_figure)
from contextlib import suppress
subplotspec_list = get_subplotspec_list(self.axes)
if None in subplotspec_list:
cbook._warn_external("This figure includes Axes that are not "
"compatible with tight_layout, so results "
"might be incorrect.")
if renderer is None:
renderer = get_renderer(self)
ctx = (renderer._draw_disabled()
if hasattr(renderer, '_draw_disabled')
else suppress())
with ctx:
kwargs = get_tight_layout_figure(
self, self.axes, subplotspec_list, renderer,
pad=pad, h_pad=h_pad, w_pad=w_pad, rect=rect)
if kwargs:
self.subplots_adjust(**kwargs)
def align_xlabels(self, axs=None):
"""
Align the xlabels of subplots in the same subplot column if label
alignment is being done automatically (i.e. the label position is
not manually set).
Alignment persists for draw events after this is called.
If a label is on the bottom, it is aligned with labels on axes that
also have their label on the bottom and that have the same
bottom-most subplot row. If the label is on the top,
it is aligned with labels on axes with the same top-most row.
Parameters
----------
axs : list of `~matplotlib.axes.Axes`
Optional list of (or ndarray) `~matplotlib.axes.Axes`
to align the xlabels.
Default is to align all axes on the figure.
See Also
--------
matplotlib.figure.Figure.align_ylabels
matplotlib.figure.Figure.align_labels
Notes
-----
This assumes that ``axs`` are from the same `.GridSpec`, so that
their `.SubplotSpec` positions correspond to figure positions.
Examples
--------
Example with rotated xtick labels::
fig, axs = plt.subplots(1, 2)
for tick in axs[0].get_xticklabels():
tick.set_rotation(55)
axs[0].set_xlabel('XLabel 0')
axs[1].set_xlabel('XLabel 1')
fig.align_xlabels()
"""
if axs is None:
axs = self.axes
axs = np.ravel(axs)
for ax in axs:
_log.debug(' Working on: %s', ax.get_xlabel())
rowspan = ax.get_subplotspec().rowspan
pos = ax.xaxis.get_label_position() # top or bottom
# Search through other axes for label positions that are same as
# this one and that share the appropriate row number.
# Add to a grouper associated with each axes of siblings.
# This list is inspected in `axis.draw` by
# `axis._update_label_position`.
for axc in axs:
if axc.xaxis.get_label_position() == pos:
rowspanc = axc.get_subplotspec().rowspan
if (pos == 'top' and rowspan.start == rowspanc.start or
pos == 'bottom' and rowspan.stop == rowspanc.stop):
# grouper for groups of xlabels to align
self._align_xlabel_grp.join(ax, axc)
def align_ylabels(self, axs=None):
"""
Align the ylabels of subplots in the same subplot column if label
alignment is being done automatically (i.e. the label position is
not manually set).
Alignment persists for draw events after this is called.
If a label is on the left, it is aligned with labels on axes that
also have their label on the left and that have the same
left-most subplot column. If the label is on the right,
it is aligned with labels on axes with the same right-most column.
Parameters
----------
axs : list of `~matplotlib.axes.Axes`
Optional list (or ndarray) of `~matplotlib.axes.Axes`
to align the ylabels.
Default is to align all axes on the figure.
See Also
--------
matplotlib.figure.Figure.align_xlabels
matplotlib.figure.Figure.align_labels
Notes
-----
This assumes that ``axs`` are from the same `.GridSpec`, so that
their `.SubplotSpec` positions correspond to figure positions.
Examples
--------
Example with large yticks labels::
fig, axs = plt.subplots(2, 1)
axs[0].plot(np.arange(0, 1000, 50))
axs[0].set_ylabel('YLabel 0')
axs[1].set_ylabel('YLabel 1')
fig.align_ylabels()
"""
if axs is None:
axs = self.axes
axs = np.ravel(axs)
for ax in axs:
_log.debug(' Working on: %s', ax.get_ylabel())
colspan = ax.get_subplotspec().colspan
pos = ax.yaxis.get_label_position() # left or right
# Search through other axes for label positions that are same as
# this one and that share the appropriate column number.
# Add to a list associated with each axes of siblings.
# This list is inspected in `axis.draw` by
# `axis._update_label_position`.
for axc in axs:
if axc.yaxis.get_label_position() == pos:
colspanc = axc.get_subplotspec().colspan
if (pos == 'left' and colspan.start == colspanc.start or
pos == 'right' and colspan.stop == colspanc.stop):
# grouper for groups of ylabels to align
self._align_ylabel_grp.join(ax, axc)
def align_labels(self, axs=None):
"""
Align the xlabels and ylabels of subplots with the same subplots
row or column (respectively) if label alignment is being
done automatically (i.e. the label position is not manually set).
Alignment persists for draw events after this is called.
Parameters
----------
axs : list of `~matplotlib.axes.Axes`
Optional list (or ndarray) of `~matplotlib.axes.Axes`
to align the labels.
Default is to align all axes on the figure.
See Also
--------
matplotlib.figure.Figure.align_xlabels
matplotlib.figure.Figure.align_ylabels
"""
self.align_xlabels(axs=axs)
self.align_ylabels(axs=axs)
def add_gridspec(self, nrows=1, ncols=1, **kwargs):
"""
Return a `.GridSpec` that has this figure as a parent. This allows
complex layout of axes in the figure.
Parameters
----------
nrows : int, default: 1
Number of rows in grid.
ncols : int, default: 1
Number or columns in grid.
Returns
-------
`.GridSpec`
Other Parameters
----------------
**kwargs
Keyword arguments are passed to `.GridSpec`.
See Also
--------
matplotlib.pyplot.subplots
Examples
--------
Adding a subplot that spans two rows::
fig = plt.figure()
gs = fig.add_gridspec(2, 2)
ax1 = fig.add_subplot(gs[0, 0])
ax2 = fig.add_subplot(gs[1, 0])
# spans two rows:
ax3 = fig.add_subplot(gs[:, 1])
"""
_ = kwargs.pop('figure', None) # pop in case user has added this...
gs = GridSpec(nrows=nrows, ncols=ncols, figure=self, **kwargs)
self._gridspecs.append(gs)
return gs
def figaspect(arg):
"""
Calculate the width and height for a figure with a specified aspect ratio.
While the height is taken from :rc:`figure.figsize`, the width is
adjusted to match the desired aspect ratio. Additionally, it is ensured
that the width is in the range [4., 16.] and the height is in the range
[2., 16.]. If necessary, the default height is adjusted to ensure this.
Parameters
----------
arg : float or 2d array
If a float, this defines the aspect ratio (i.e. the ratio height /
width).
In case of an array the aspect ratio is number of rows / number of
columns, so that the array could be fitted in the figure undistorted.
Returns
-------
width, height
The figure size in inches.
Notes
-----
If you want to create an axes within the figure, that still preserves the
aspect ratio, be sure to create it with equal width and height. See
examples below.
Thanks to Fernando Perez for this function.
Examples
--------
Make a figure twice as tall as it is wide::
w, h = figaspect(2.)
fig = Figure(figsize=(w, h))
ax = fig.add_axes([0.1, 0.1, 0.8, 0.8])
ax.imshow(A, **kwargs)
Make a figure with the proper aspect for an array::
A = rand(5, 3)
w, h = figaspect(A)
fig = Figure(figsize=(w, h))
ax = fig.add_axes([0.1, 0.1, 0.8, 0.8])
ax.imshow(A, **kwargs)
"""
isarray = hasattr(arg, 'shape') and not np.isscalar(arg)
# min/max sizes to respect when autoscaling. If John likes the idea, they
# could become rc parameters, for now they're hardwired.
figsize_min = np.array((4.0, 2.0)) # min length for width/height
figsize_max = np.array((16.0, 16.0)) # max length for width/height
# Extract the aspect ratio of the array
if isarray:
nr, nc = arg.shape[:2]
arr_ratio = nr / nc
else:
arr_ratio = arg
# Height of user figure defaults
fig_height = mpl.rcParams['figure.figsize'][1]
# New size for the figure, keeping the aspect ratio of the caller
newsize = np.array((fig_height / arr_ratio, fig_height))
# Sanity checks, don't drop either dimension below figsize_min
newsize /= min(1.0, *(newsize / figsize_min))
# Avoid humongous windows as well
newsize /= max(1.0, *(newsize / figsize_max))
# Finally, if we have a really funky aspect ratio, break it but respect
# the min/max dimensions (we don't want figures 10 feet tall!)
newsize = np.clip(newsize, figsize_min, figsize_max)
return newsize
docstring.interpd.update(Figure=martist.kwdoc(Figure))