.. only:: html
.. note::
:class: sphx-glr-download-link-note
Click :ref:`here ` to download the full example code
.. rst-class:: sphx-glr-example-title
.. _sphx_glr_tutorials_intermediate_artists.py:
===============
Artist tutorial
===============
Using Artist objects to render on the canvas.
There are three layers to the matplotlib API.
* the :class:`matplotlib.backend_bases.FigureCanvas` is the area onto which
the figure is drawn
* the :class:`matplotlib.backend_bases.Renderer` is
the object which knows how to draw on the
:class:`~matplotlib.backend_bases.FigureCanvas`
* and the :class:`matplotlib.artist.Artist` is the object that knows how to use
a renderer to paint onto the canvas.
The :class:`~matplotlib.backend_bases.FigureCanvas` and
:class:`~matplotlib.backend_bases.Renderer` handle all the details of
talking to user interface toolkits like `wxPython
`_ or drawing languages like PostScript®, and
the ``Artist`` handles all the high level constructs like representing
and laying out the figure, text, and lines. The typical user will
spend 95% of their time working with the ``Artists``.
There are two types of ``Artists``: primitives and containers. The primitives
represent the standard graphical objects we want to paint onto our canvas:
:class:`~matplotlib.lines.Line2D`, :class:`~matplotlib.patches.Rectangle`,
:class:`~matplotlib.text.Text`, :class:`~matplotlib.image.AxesImage`, etc., and
the containers are places to put them (:class:`~matplotlib.axis.Axis`,
:class:`~matplotlib.axes.Axes` and :class:`~matplotlib.figure.Figure`). The
standard use is to create a :class:`~matplotlib.figure.Figure` instance, use
the ``Figure`` to create one or more :class:`~matplotlib.axes.Axes` or
:class:`~matplotlib.axes.Subplot` instances, and use the ``Axes`` instance
helper methods to create the primitives. In the example below, we create a
``Figure`` instance using :func:`matplotlib.pyplot.figure`, which is a
convenience method for instantiating ``Figure`` instances and connecting them
with your user interface or drawing toolkit ``FigureCanvas``. As we will
discuss below, this is not necessary -- you can work directly with PostScript,
PDF Gtk+, or wxPython ``FigureCanvas`` instances, instantiate your ``Figures``
directly and connect them yourselves -- but since we are focusing here on the
``Artist`` API we'll let :mod:`~matplotlib.pyplot` handle some of those details
for us::
import matplotlib.pyplot as plt
fig = plt.figure()
ax = fig.add_subplot(2, 1, 1) # two rows, one column, first plot
The :class:`~matplotlib.axes.Axes` is probably the most important
class in the matplotlib API, and the one you will be working with most
of the time. This is because the ``Axes`` is the plotting area into
which most of the objects go, and the ``Axes`` has many special helper
methods (:meth:`~matplotlib.axes.Axes.plot`,
:meth:`~matplotlib.axes.Axes.text`,
:meth:`~matplotlib.axes.Axes.hist`,
:meth:`~matplotlib.axes.Axes.imshow`) to create the most common
graphics primitives (:class:`~matplotlib.lines.Line2D`,
:class:`~matplotlib.text.Text`,
:class:`~matplotlib.patches.Rectangle`,
:class:`~matplotlib.image.AxesImage`, respectively). These helper methods
will take your data (e.g., ``numpy`` arrays and strings) and create
primitive ``Artist`` instances as needed (e.g., ``Line2D``), add them to
the relevant containers, and draw them when requested. Most of you
are probably familiar with the :class:`~matplotlib.axes.Subplot`,
which is just a special case of an ``Axes`` that lives on a regular
rows by columns grid of ``Subplot`` instances. If you want to create
an ``Axes`` at an arbitrary location, simply use the
:meth:`~matplotlib.figure.Figure.add_axes` method which takes a list
of ``[left, bottom, width, height]`` values in 0-1 relative figure
coordinates::
fig2 = plt.figure()
ax2 = fig2.add_axes([0.15, 0.1, 0.7, 0.3])
Continuing with our example::
import numpy as np
t = np.arange(0.0, 1.0, 0.01)
s = np.sin(2*np.pi*t)
line, = ax.plot(t, s, color='blue', lw=2)
In this example, ``ax`` is the ``Axes`` instance created by the
``fig.add_subplot`` call above (remember ``Subplot`` is just a
subclass of ``Axes``) and when you call ``ax.plot``, it creates a
``Line2D`` instance and adds it to the :attr:`Axes.lines
` list. In the interactive `ipython
`_ session below, you can see that the
``Axes.lines`` list is length one and contains the same line that was
returned by the ``line, = ax.plot...`` call:
.. sourcecode:: ipython
In [101]: ax.lines[0]
Out[101]:
In [102]: line
Out[102]:
If you make subsequent calls to ``ax.plot`` (and the hold state is "on"
which is the default) then additional lines will be added to the list.
You can remove lines later simply by calling the list methods; either
of these will work::
del ax.lines[0]
ax.lines.remove(line) # one or the other, not both!
The Axes also has helper methods to configure and decorate the x-axis
and y-axis tick, tick labels and axis labels::
xtext = ax.set_xlabel('my xdata') # returns a Text instance
ytext = ax.set_ylabel('my ydata')
When you call :meth:`ax.set_xlabel `,
it passes the information on the :class:`~matplotlib.text.Text`
instance of the :class:`~matplotlib.axis.XAxis`. Each ``Axes``
instance contains an :class:`~matplotlib.axis.XAxis` and a
:class:`~matplotlib.axis.YAxis` instance, which handle the layout and
drawing of the ticks, tick labels and axis labels.
Try creating the figure below.
.. code-block:: default
import numpy as np
import matplotlib.pyplot as plt
fig = plt.figure()
fig.subplots_adjust(top=0.8)
ax1 = fig.add_subplot(211)
ax1.set_ylabel('volts')
ax1.set_title('a sine wave')
t = np.arange(0.0, 1.0, 0.01)
s = np.sin(2*np.pi*t)
line, = ax1.plot(t, s, color='blue', lw=2)
# Fixing random state for reproducibility
np.random.seed(19680801)
ax2 = fig.add_axes([0.15, 0.1, 0.7, 0.3])
n, bins, patches = ax2.hist(np.random.randn(1000), 50,
facecolor='yellow', edgecolor='yellow')
ax2.set_xlabel('time (s)')
plt.show()
.. image:: /tutorials/intermediate/images/sphx_glr_artists_001.png
:alt: a sine wave
:class: sphx-glr-single-img
.. _customizing-artists:
Customizing your objects
========================
Every element in the figure is represented by a Matplotlib
:class:`~matplotlib.artist.Artist`, and each has an extensive list of
properties to configure its appearance. The figure itself contains a
:class:`~matplotlib.patches.Rectangle` exactly the size of the figure,
which you can use to set the background color and transparency of the
figures. Likewise, each :class:`~matplotlib.axes.Axes` bounding box
(the standard white box with black edges in the typical Matplotlib
plot, has a ``Rectangle`` instance that determines the color,
transparency, and other properties of the Axes. These instances are
stored as member variables :attr:`Figure.patch
` and :attr:`Axes.patch
` ("Patch" is a name inherited from
MATLAB, and is a 2D "patch" of color on the figure, e.g., rectangles,
circles and polygons). Every Matplotlib ``Artist`` has the following
properties
========== =================================================================
Property Description
========== =================================================================
alpha The transparency - a scalar from 0-1
animated A boolean that is used to facilitate animated drawing
axes The axes that the Artist lives in, possibly None
clip_box The bounding box that clips the Artist
clip_on Whether clipping is enabled
clip_path The path the artist is clipped to
contains A picking function to test whether the artist contains the pick
point
figure The figure instance the artist lives in, possibly None
label A text label (e.g., for auto-labeling)
picker A python object that controls object picking
transform The transformation
visible A boolean whether the artist should be drawn
zorder A number which determines the drawing order
rasterized Boolean; Turns vectors into raster graphics (for compression &
eps transparency)
========== =================================================================
Each of the properties is accessed with an old-fashioned setter or
getter (yes we know this irritates Pythonistas and we plan to support
direct access via properties or traits but it hasn't been done yet).
For example, to multiply the current alpha by a half::
a = o.get_alpha()
o.set_alpha(0.5*a)
If you want to set a number of properties at once, you can also use
the ``set`` method with keyword arguments. For example::
o.set(alpha=0.5, zorder=2)
If you are working interactively at the python shell, a handy way to
inspect the ``Artist`` properties is to use the
:func:`matplotlib.artist.getp` function (simply
:func:`~matplotlib.pyplot.getp` in pyplot), which lists the properties
and their values. This works for classes derived from ``Artist`` as
well, e.g., ``Figure`` and ``Rectangle``. Here are the ``Figure`` rectangle
properties mentioned above:
.. sourcecode:: ipython
In [149]: matplotlib.artist.getp(fig.patch)
agg_filter = None
alpha = None
animated = False
antialiased or aa = False
bbox = Bbox(x0=0.0, y0=0.0, x1=1.0, y1=1.0)
capstyle = butt
children = []
clip_box = None
clip_on = True
clip_path = None
contains = None
data_transform = BboxTransformTo( TransformedBbox( Bbox...
edgecolor or ec = (1.0, 1.0, 1.0, 1.0)
extents = Bbox(x0=0.0, y0=0.0, x1=640.0, y1=480.0)
facecolor or fc = (1.0, 1.0, 1.0, 1.0)
figure = Figure(640x480)
fill = True
gid = None
hatch = None
height = 1
in_layout = False
joinstyle = miter
label =
linestyle or ls = solid
linewidth or lw = 0.0
patch_transform = CompositeGenericTransform( BboxTransformTo( ...
path = Path(array([[0., 0.], [1., 0.], [1.,...
path_effects = []
picker = None
rasterized = None
sketch_params = None
snap = None
transform = CompositeGenericTransform( CompositeGenericTra...
transformed_clip_path_and_affine = (None, None)
url = None
verts = [[ 0. 0.] [640. 0.] [640. 480.] [ 0. 480....
visible = True
width = 1
window_extent = Bbox(x0=0.0, y0=0.0, x1=640.0, y1=480.0)
x = 0
xy = (0, 0)
y = 0
zorder = 1
The docstrings for all of the classes also contain the ``Artist``
properties, so you can consult the interactive "help" or the
:ref:`artist-api` for a listing of properties for a given object.
.. _object-containers:
Object containers
=================
Now that we know how to inspect and set the properties of a given
object we want to configure, we need to know how to get at that object.
As mentioned in the introduction, there are two kinds of objects:
primitives and containers. The primitives are usually the things you
want to configure (the font of a :class:`~matplotlib.text.Text`
instance, the width of a :class:`~matplotlib.lines.Line2D`) although
the containers also have some properties as well -- for example the
:class:`~matplotlib.axes.Axes` :class:`~matplotlib.artist.Artist` is a
container that contains many of the primitives in your plot, but it
also has properties like the ``xscale`` to control whether the xaxis
is 'linear' or 'log'. In this section we'll review where the various
container objects store the ``Artists`` that you want to get at.
.. _figure-container:
Figure container
----------------
The top level container ``Artist`` is the
:class:`matplotlib.figure.Figure`, and it contains everything in the
figure. The background of the figure is a
:class:`~matplotlib.patches.Rectangle` which is stored in
:attr:`Figure.patch `. As
you add subplots (:meth:`~matplotlib.figure.Figure.add_subplot`) and
axes (:meth:`~matplotlib.figure.Figure.add_axes`) to the figure
these will be appended to the :attr:`Figure.axes
`. These are also returned by the
methods that create them:
.. sourcecode:: ipython
In [156]: fig = plt.figure()
In [157]: ax1 = fig.add_subplot(211)
In [158]: ax2 = fig.add_axes([0.1, 0.1, 0.7, 0.3])
In [159]: ax1
Out[159]:
In [160]: print(fig.axes)
[, ]
Because the figure maintains the concept of the "current axes" (see
:meth:`Figure.gca ` and
:meth:`Figure.sca `) to support the
pylab/pyplot state machine, you should not insert or remove axes
directly from the axes list, but rather use the
:meth:`~matplotlib.figure.Figure.add_subplot` and
:meth:`~matplotlib.figure.Figure.add_axes` methods to insert, and the
:meth:`~matplotlib.figure.Figure.delaxes` method to delete. You are
free however, to iterate over the list of axes or index into it to get
access to ``Axes`` instances you want to customize. Here is an
example which turns all the axes grids on::
for ax in fig.axes:
ax.grid(True)
The figure also has its own text, lines, patches and images, which you
can use to add primitives directly. The default coordinate system for
the ``Figure`` will simply be in pixels (which is not usually what you
want) but you can control this by setting the transform property of
the ``Artist`` you are adding to the figure.
.. TODO: Is that still true?
More useful is "figure coordinates" where (0, 0) is the bottom-left of
the figure and (1, 1) is the top-right of the figure which you can
obtain by setting the ``Artist`` transform to :attr:`fig.transFigure
`:
.. code-block:: default
import matplotlib.lines as lines
fig = plt.figure()
l1 = lines.Line2D([0, 1], [0, 1], transform=fig.transFigure, figure=fig)
l2 = lines.Line2D([0, 1], [1, 0], transform=fig.transFigure, figure=fig)
fig.lines.extend([l1, l2])
plt.show()
.. image:: /tutorials/intermediate/images/sphx_glr_artists_002.png
:alt: artists
:class: sphx-glr-single-img
Here is a summary of the Artists the figure contains
.. TODO: Add xrefs to this table
================ ============================================================
Figure attribute Description
================ ============================================================
axes A list of Axes instances (includes Subplot)
patch The Rectangle background
images A list of FigureImage patches -
useful for raw pixel display
legends A list of Figure Legend instances
(different from Axes.legends)
lines A list of Figure Line2D instances
(rarely used, see Axes.lines)
patches A list of Figure patches (rarely used, see Axes.patches)
texts A list Figure Text instances
================ ============================================================
.. _axes-container:
Axes container
--------------
The :class:`matplotlib.axes.Axes` is the center of the Matplotlib
universe -- it contains the vast majority of all the ``Artists`` used
in a figure with many helper methods to create and add these
``Artists`` to itself, as well as helper methods to access and
customize the ``Artists`` it contains. Like the
:class:`~matplotlib.figure.Figure`, it contains a
:class:`~matplotlib.patches.Patch`
:attr:`~matplotlib.axes.Axes.patch` which is a
:class:`~matplotlib.patches.Rectangle` for Cartesian coordinates and a
:class:`~matplotlib.patches.Circle` for polar coordinates; this patch
determines the shape, background and border of the plotting region::
ax = fig.add_subplot(111)
rect = ax.patch # a Rectangle instance
rect.set_facecolor('green')
When you call a plotting method, e.g., the canonical
:meth:`~matplotlib.axes.Axes.plot` and pass in arrays or lists of
values, the method will create a :meth:`matplotlib.lines.Line2D`
instance, update the line with all the ``Line2D`` properties passed as
keyword arguments, add the line to the :attr:`Axes.lines
` container, and returns it to you:
.. sourcecode:: ipython
In [213]: x, y = np.random.rand(2, 100)
In [214]: line, = ax.plot(x, y, '-', color='blue', linewidth=2)
``plot`` returns a list of lines because you can pass in multiple x, y
pairs to plot, and we are unpacking the first element of the length
one list into the line variable. The line has been added to the
``Axes.lines`` list:
.. sourcecode:: ipython
In [229]: print(ax.lines)
[]
Similarly, methods that create patches, like
:meth:`~matplotlib.axes.Axes.bar` creates a list of rectangles, will
add the patches to the :attr:`Axes.patches
` list:
.. sourcecode:: ipython
In [233]: n, bins, rectangles = ax.hist(np.random.randn(1000), 50)
In [234]: rectangles
Out[234]:
In [235]: print(len(ax.patches))
Out[235]: 50
You should not add objects directly to the ``Axes.lines`` or
``Axes.patches`` lists unless you know exactly what you are doing,
because the ``Axes`` needs to do a few things when it creates and adds
an object. It sets the figure and axes property of the ``Artist``, as
well as the default ``Axes`` transformation (unless a transformation
is set). It also inspects the data contained in the ``Artist`` to
update the data structures controlling auto-scaling, so that the view
limits can be adjusted to contain the plotted data. You can,
nonetheless, create objects yourself and add them directly to the
``Axes`` using helper methods like
:meth:`~matplotlib.axes.Axes.add_line` and
:meth:`~matplotlib.axes.Axes.add_patch`. Here is an annotated
interactive session illustrating what is going on:
.. sourcecode:: ipython
In [262]: fig, ax = plt.subplots()
# create a rectangle instance
In [263]: rect = matplotlib.patches.Rectangle((1, 1), width=5, height=12)
# by default the axes instance is None
In [264]: print(rect.axes)
None
# and the transformation instance is set to the "identity transform"
In [265]: print(rect.get_data_transform())
IdentityTransform()
# now we add the Rectangle to the Axes
In [266]: ax.add_patch(rect)
# and notice that the ax.add_patch method has set the axes
# instance
In [267]: print(rect.axes)
Axes(0.125,0.1;0.775x0.8)
# and the transformation has been set too
In [268]: print(rect.get_data_transform())
CompositeGenericTransform(
TransformWrapper(
BlendedAffine2D(
IdentityTransform(),
IdentityTransform())),
CompositeGenericTransform(
BboxTransformFrom(
TransformedBbox(
Bbox(x0=0.0, y0=0.0, x1=1.0, y1=1.0),
TransformWrapper(
BlendedAffine2D(
IdentityTransform(),
IdentityTransform())))),
BboxTransformTo(
TransformedBbox(
Bbox(x0=0.125, y0=0.10999999999999999, x1=0.9, y1=0.88),
BboxTransformTo(
TransformedBbox(
Bbox(x0=0.0, y0=0.0, x1=6.4, y1=4.8),
Affine2D(
[[100. 0. 0.]
[ 0. 100. 0.]
[ 0. 0. 1.]])))))))
# the default axes transformation is ax.transData
In [269]: print(ax.transData)
CompositeGenericTransform(
TransformWrapper(
BlendedAffine2D(
IdentityTransform(),
IdentityTransform())),
CompositeGenericTransform(
BboxTransformFrom(
TransformedBbox(
Bbox(x0=0.0, y0=0.0, x1=1.0, y1=1.0),
TransformWrapper(
BlendedAffine2D(
IdentityTransform(),
IdentityTransform())))),
BboxTransformTo(
TransformedBbox(
Bbox(x0=0.125, y0=0.10999999999999999, x1=0.9, y1=0.88),
BboxTransformTo(
TransformedBbox(
Bbox(x0=0.0, y0=0.0, x1=6.4, y1=4.8),
Affine2D(
[[100. 0. 0.]
[ 0. 100. 0.]
[ 0. 0. 1.]])))))))
# notice that the xlimits of the Axes have not been changed
In [270]: print(ax.get_xlim())
(0.0, 1.0)
# but the data limits have been updated to encompass the rectangle
In [271]: print(ax.dataLim.bounds)
(1.0, 1.0, 5.0, 12.0)
# we can manually invoke the auto-scaling machinery
In [272]: ax.autoscale_view()
# and now the xlim are updated to encompass the rectangle, plus margins
In [273]: print(ax.get_xlim())
(0.75, 6.25)
# we have to manually force a figure draw
In [274]: fig.canvas.draw()
There are many, many ``Axes`` helper methods for creating primitive
``Artists`` and adding them to their respective containers. The table
below summarizes a small sampling of them, the kinds of ``Artist`` they
create, and where they store them
============================== ==================== =======================
Helper method Artist Container
============================== ==================== =======================
ax.annotate - text annotations Annotate ax.texts
ax.bar - bar charts Rectangle ax.patches
ax.errorbar - error bar plots Line2D and Rectangle ax.lines and ax.patches
ax.fill - shared area Polygon ax.patches
ax.hist - histograms Rectangle ax.patches
ax.imshow - image data AxesImage ax.images
ax.legend - axes legends Legend ax.legends
ax.plot - xy plots Line2D ax.lines
ax.scatter - scatter charts PolygonCollection ax.collections
ax.text - text Text ax.texts
============================== ==================== =======================
In addition to all of these ``Artists``, the ``Axes`` contains two
important ``Artist`` containers: the :class:`~matplotlib.axis.XAxis`
and :class:`~matplotlib.axis.YAxis`, which handle the drawing of the
ticks and labels. These are stored as instance variables
:attr:`~matplotlib.axes.Axes.xaxis` and
:attr:`~matplotlib.axes.Axes.yaxis`. The ``XAxis`` and ``YAxis``
containers will be detailed below, but note that the ``Axes`` contains
many helper methods which forward calls on to the
:class:`~matplotlib.axis.Axis` instances so you often do not need to
work with them directly unless you want to. For example, you can set
the font color of the ``XAxis`` ticklabels using the ``Axes`` helper
method::
for label in ax.get_xticklabels():
label.set_color('orange')
Below is a summary of the Artists that the Axes contains
============== ======================================
Axes attribute Description
============== ======================================
artists A list of Artist instances
patch Rectangle instance for Axes background
collections A list of Collection instances
images A list of AxesImage
legends A list of Legend instances
lines A list of Line2D instances
patches A list of Patch instances
texts A list of Text instances
xaxis matplotlib.axis.XAxis instance
yaxis matplotlib.axis.YAxis instance
============== ======================================
.. _axis-container:
Axis containers
---------------
The :class:`matplotlib.axis.Axis` instances handle the drawing of the
tick lines, the grid lines, the tick labels and the axis label. You
can configure the left and right ticks separately for the y-axis, and
the upper and lower ticks separately for the x-axis. The ``Axis``
also stores the data and view intervals used in auto-scaling, panning
and zooming, as well as the :class:`~matplotlib.ticker.Locator` and
:class:`~matplotlib.ticker.Formatter` instances which control where
the ticks are placed and how they are represented as strings.
Each ``Axis`` object contains a :attr:`~matplotlib.axis.Axis.label` attribute
(this is what :mod:`.pyplot` modifies in calls to `~.pyplot.xlabel` and
`~.pyplot.ylabel`) as well as a list of major and minor ticks. The ticks are
`.axis.XTick` and `.axis.YTick` instances, which contain the actual line and
text primitives that render the ticks and ticklabels. Because the ticks are
dynamically created as needed (e.g., when panning and zooming), you should
access the lists of major and minor ticks through their accessor methods
`.axis.Axis.get_major_ticks` and `.axis.Axis.get_minor_ticks`. Although
the ticks contain all the primitives and will be covered below, ``Axis``
instances have accessor methods that return the tick lines, tick labels, tick
locations etc.:
.. code-block:: default
fig, ax = plt.subplots()
axis = ax.xaxis
axis.get_ticklocs()
.. image:: /tutorials/intermediate/images/sphx_glr_artists_003.png
:alt: artists
:class: sphx-glr-single-img
.. rst-class:: sphx-glr-script-out
Out:
.. code-block:: none
array([0. , 0.2, 0.4, 0.6, 0.8, 1. ])
.. code-block:: default
axis.get_ticklabels()
.. rst-class:: sphx-glr-script-out
Out:
.. code-block:: none
[Text(0.0, 0, '0.0'), Text(0.2, 0, '0.2'), Text(0.4, 0, '0.4'), Text(0.6000000000000001, 0, '0.6'), Text(0.8, 0, '0.8'), Text(1.0, 0, '1.0')]
note there are twice as many ticklines as labels because by default there are
tick lines at the top and bottom but only tick labels below the xaxis;
however, this can be customized.
.. code-block:: default
axis.get_ticklines()
.. rst-class:: sphx-glr-script-out
Out:
.. code-block:: none
And with the above methods, you only get lists of major ticks back by
default, but you can also ask for the minor ticks:
.. code-block:: default
axis.get_ticklabels(minor=True)
axis.get_ticklines(minor=True)
.. rst-class:: sphx-glr-script-out
Out:
.. code-block:: none
Here is a summary of some of the useful accessor methods of the ``Axis``
(these have corresponding setters where useful, such as
:meth:`~matplotlib.axis.Axis.set_major_formatter`.)
==================== =====================================================
Accessor method Description
==================== =====================================================
get_scale The scale of the axis, e.g., 'log' or 'linear'
get_view_interval The interval instance of the axis view limits
get_data_interval The interval instance of the axis data limits
get_gridlines A list of grid lines for the Axis
get_label The axis label - a Text instance
get_ticklabels A list of Text instances - keyword minor=True|False
get_ticklines A list of Line2D instances - keyword minor=True|False
get_ticklocs A list of Tick locations - keyword minor=True|False
get_major_locator The `.ticker.Locator` instance for major ticks
get_major_formatter The `.ticker.Formatter` instance for major ticks
get_minor_locator The `.ticker.Locator` instance for minor ticks
get_minor_formatter The `.ticker.Formatter` instance for minor ticks
get_major_ticks A list of Tick instances for major ticks
get_minor_ticks A list of Tick instances for minor ticks
grid Turn the grid on or off for the major or minor ticks
==================== =====================================================
Here is an example, not recommended for its beauty, which customizes
the axes and tick properties
.. code-block:: default
# plt.figure creates a matplotlib.figure.Figure instance
fig = plt.figure()
rect = fig.patch # a rectangle instance
rect.set_facecolor('lightgoldenrodyellow')
ax1 = fig.add_axes([0.1, 0.3, 0.4, 0.4])
rect = ax1.patch
rect.set_facecolor('lightslategray')
for label in ax1.xaxis.get_ticklabels():
# label is a Text instance
label.set_color('red')
label.set_rotation(45)
label.set_fontsize(16)
for line in ax1.yaxis.get_ticklines():
# line is a Line2D instance
line.set_color('green')
line.set_markersize(25)
line.set_markeredgewidth(3)
plt.show()
.. image:: /tutorials/intermediate/images/sphx_glr_artists_004.png
:alt: artists
:class: sphx-glr-single-img
.. _tick-container:
Tick containers
---------------
The :class:`matplotlib.axis.Tick` is the final container object in our
descent from the :class:`~matplotlib.figure.Figure` to the
:class:`~matplotlib.axes.Axes` to the :class:`~matplotlib.axis.Axis`
to the :class:`~matplotlib.axis.Tick`. The ``Tick`` contains the tick
and grid line instances, as well as the label instances for the upper
and lower ticks. Each of these is accessible directly as an attribute
of the ``Tick``.
============== ==========================================================
Tick attribute Description
============== ==========================================================
tick1line Line2D instance
tick2line Line2D instance
gridline Line2D instance
label1 Text instance
label2 Text instance
============== ==========================================================
Here is an example which sets the formatter for the right side ticks with
dollar signs and colors them green on the right side of the yaxis.
.. include:: ../../gallery/pyplots/dollar_ticks.rst
:start-after: y axis labels.
:end-before: -------
.. rst-class:: sphx-glr-timing
**Total running time of the script:** ( 0 minutes 1.092 seconds)
.. _sphx_glr_download_tutorials_intermediate_artists.py:
.. only :: html
.. container:: sphx-glr-footer
:class: sphx-glr-footer-example
.. container:: sphx-glr-download sphx-glr-download-python
:download:`Download Python source code: artists.py `
.. container:: sphx-glr-download sphx-glr-download-jupyter
:download:`Download Jupyter notebook: artists.ipynb `
.. only:: html
.. rst-class:: sphx-glr-signature
Keywords: matplotlib code example, codex, python plot, pyplot
`Gallery generated by Sphinx-Gallery
`_