This document will give you a brief tour of the capabilities of the IPython notebook.
You can view its contents by scrolling around, or execute each cell by typing Shift-Enter
.
After you conclude this brief high-level tour, you should read the accompanying notebook
titled 01_notebook_introduction
, which takes a more step-by-step approach to the features of the
system.
The rest of the notebooks in this directory illustrate various other aspects and capabilities of the IPython notebook; some of them may require additional libraries to be executed.
NOTE: This notebook must be run from its own directory, so you must cd
to this directory and then start the notebook, but do not use the --notebook-dir
option to run it from another location.
The first thing you need to know is that you are still controlling the same old IPython you're used to, so things like shell aliases and magic commands still work:
pwd
ls
message = 'The IPython notebook is great!'
# note: the echo command does not run on Windows, it's a unix command.
!echo $message
IPython adds an 'inline' matplotlib backend, which embeds any matplotlib figures into the notebook.
%pylab inline
x = linspace(0, 3*pi, 500)
plot(x, sin(x**2))
title('A simple chirp');
You can paste blocks of input with prompt markers, such as those from the official Python tutorial
>>> the_world_is_flat = 1
>>> if the_world_is_flat:
... print "Be careful not to fall off!"
Errors are shown in informative ways:
%run non_existent_file
x = 1
y = 4
z = y/(1-x)
When IPython needs to display additional information (such as providing details on an object via x?
it will automatically invoke a pager at the bottom of the screen:
magic
If you execute the next cell, you will see the output arriving as it is generated, not all at the end.
import time, sys
for i in range(8):
print i,
time.sleep(0.5)
We call the low-level system libc.time routine with the wrong argument via ctypes to segfault the Python interpreter:
import sys
from ctypes import CDLL
# This will crash a Linux or Mac system; equivalent calls can be made on Windows
dll = 'dylib' if sys.platform == 'darwin' else '.so.6'
libc = CDLL("libc.%s" % dll)
libc.time(-1) # BOOM!!
You can italicize, boldface
and embed code meant for illustration instead of execution in Python:
def f(x):
"""a docstring"""
return x**2
or other languages:
if (i=0; i<n; i++) {
printf("hello %d\n", i);
x += 4;
}
Courtesy of MathJax, you can include mathematical expressions both inline: $e^{i\pi} + 1 = 0$ and displayed:
$$e^x=\sum_{i=0}^\infty \frac{1}{i!}x^i$$
Note that we have an actual protocol for this, see the display_protocol
notebook for further details.
from IPython.display import Image
Image(filename='../../source/_static/logo.png')
An image can also be displayed from raw data or a url
Image(url='http://python.org/images/python-logo.gif')
SVG images are also supported out of the box (since modern browsers do a good job of rendering them):
from IPython.display import SVG
SVG(filename='python-logo.svg')
As of IPython 0.13, images are embedded by default for compatibility with QtConsole, and the ability to still be displayed offline.
Let's look at the differences:
# by default Image data are embedded
Embed = Image( 'http://scienceview.berkeley.edu/view/images/newview.jpg')
# if kwarg `url` is given, the embedding is assumed to be false
SoftLinked = Image(url='http://scienceview.berkeley.edu/view/images/newview.jpg')
# In each case, embed can be specified explicitly with the `embed` kwarg
# ForceEmbed = Image(url='http://scienceview.berkeley.edu/view/images/newview.jpg', embed=True)
Today's image from a webcam at Berkeley, (at the time I created this notebook). This should also work in the Qtconsole. Drawback is that the saved notebook will be larger, but the image will still be present offline.
Embed
Today's image from same webcam at Berkeley, (refreshed every minutes, if you reload the notebook), visible only with an active internet connexion, that should be different from the previous one. This will not work on Qtconsole. Notebook saved with this kind of image will be lighter and always reflect the current version of the source, but the image won't display offline.
SoftLinked
Of course, if you re-run the all notebook, the two images will be the same again.
And more exotic objects can also be displayed, as long as their representation supports the IPython display protocol.
For example, videos hosted externally on YouTube are easy to load (and writing a similar wrapper for other hosted content is trivial):
from IPython.display import YouTubeVideo
# a talk about IPython at Sage Days at U. Washington, Seattle.
# Video credit: William Stein.
YouTubeVideo('1j_HxD4iLn8')
Using the nascent video capabilities of modern browsers, you may also be able to display local
videos. At the moment this doesn't work very well in all browsers, so it may or may not work for you;
we will continue testing this and looking for ways to make it more robust.
The following cell loads a local file called animation.m4v
, encodes the raw video as base64 for http
transport, and uses the HTML5 video tag to load it. On Chrome 15 it works correctly, displaying a control
bar at the bottom with a play/pause button and a location slider.
from IPython.display import HTML
video = open("animation.m4v", "rb").read()
video_encoded = video.encode("base64")
video_tag = '<video controls alt="test" src="data:video/x-m4v;base64,{0}">'.format(video_encoded)
HTML(data=video_tag)
The above examples embed images and video from the notebook filesystem in the output
areas of code cells. It is also possible to request these files directly in markdown cells
if they reside in the notebook directory via relative urls prefixed with files/
:
files/[subdirectory/]<filename>
For example, in the example notebook folder, we have the Python logo, addressed as:
<img src="files/python-logo.svg" />
and a video with the HTML5 video tag:
<video controls src="files/animation.m4v" />
These do not embed the data into the notebook file,
and require that the files exist when you are viewing the notebook.
### Security of local files
Note that this means that the IPython notebook server also acts as a generic file server
for files inside the same tree as your notebooks. Access is not granted outside the
notebook folder so you have strict control over what files are visible, but for this
reason it is highly recommended that you do not run the notebook server with a notebook
directory at a high level in your filesystem (e.g. your home directory).
When you run the notebook in a password-protected manner, local file access is restricted
to authenticated users unless read-only views are active.
It is also possible to link directly to files or directories so they can be opened in the browser. This is especially convenient if you're interacting with a tool within IPython that generates HTML pages, and you'd like to easily be able to open those in a new browser window. Alternatively, if your IPython notebook server is on a remote system, creating links provides an easy way to download any files that get generated.
As we saw above, there are a bunch of .ipynb
files in our current directory.
ls
If we want to create a link to one of them, we can call use the FileLink
object.
from IPython.display import FileLink
FileLink('00_notebook_tour.ipynb')
Alternatively, if we want to link to all of them, we can use the FileLinks
object, passing '.'
to indicate that we want links generated for the current working directory. Note that if there were other directories under the current directory, FileLinks
would work in a recursive manner creating links to files in all sub-directories as well.
from IPython.display import FileLinks
FileLinks('.')
You can even embed an entire page from another site in an iframe; for example this is today's Wikipedia page for mobile users:
HTML('<iframe src=http://en.mobile.wikipedia.org/?useformat=mobile width=700 height=350></iframe>')
And we also support the display of mathematical expressions typeset in LaTeX, which is rendered
in the browser thanks to the MathJax library.
Note that this is different from the above examples. Above we were typing mathematical expressions
in Markdown cells (along with normal text) and letting the browser render them; now we are displaying
the output of a Python computation as a LaTeX expression wrapped by the Math()
object so the browser
renders it. The Math
object will add the needed LaTeX delimiters ($$
) if they are not provided:
from IPython.display import Math
Math(r'F(k) = \int_{-\infty}^{\infty} f(x) e^{2\pi i k} dx')
With the Latex
class, you have to include the delimiters yourself. This allows you to use other LaTeX modes such as eqnarray
:
from IPython.display import Latex
Latex(r"""\begin{eqnarray}
\nabla \times \vec{\mathbf{B}} -\, \frac1c\, \frac{\partial\vec{\mathbf{E}}}{\partial t} & = \frac{4\pi}{c}\vec{\mathbf{j}} \\
\nabla \cdot \vec{\mathbf{E}} & = 4 \pi \rho \\
\nabla \times \vec{\mathbf{E}}\, +\, \frac1c\, \frac{\partial\vec{\mathbf{B}}}{\partial t} & = \vec{\mathbf{0}} \\
\nabla \cdot \vec{\mathbf{B}} & = 0
\end{eqnarray}""")
Or you can enter latex directly with the %%latex
cell magic:
%%latex
\begin{aligned}
\nabla \times \vec{\mathbf{B}} -\, \frac1c\, \frac{\partial\vec{\mathbf{E}}}{\partial t} & = \frac{4\pi}{c}\vec{\mathbf{j}} \\
\nabla \cdot \vec{\mathbf{E}} & = 4 \pi \rho \\
\nabla \times \vec{\mathbf{E}}\, +\, \frac1c\, \frac{\partial\vec{\mathbf{B}}}{\partial t} & = \vec{\mathbf{0}} \\
\nabla \cdot \vec{\mathbf{B}} & = 0
\end{aligned}
There is also a %%javascript
cell magic for running javascript directly,
and %%svg
for manually entering SVG content.
.py
in the dashboard%load
with any local or remote url: the Matplotlib Gallery!In this notebook we've kept the output saved so you can see the result, but you should run the next cell yourself (with an active internet connection).
Let's make sure we have pylab again, in case we have restarted the kernel due to the crash demo above
%pylab inline
%load http://matplotlib.sourceforge.net/mpl_examples/pylab_examples/integral_demo.py
#!/usr/bin/env python
# implement the example graphs/integral from pyx
from pylab import *
from matplotlib.patches import Polygon
def func(x):
return (x-3)*(x-5)*(x-7)+85
ax = subplot(111)
a, b = 2, 9 # integral area
x = arange(0, 10, 0.01)
y = func(x)
plot(x, y, linewidth=1)
# make the shaded region
ix = arange(a, b, 0.01)
iy = func(ix)
verts = [(a,0)] + zip(ix,iy) + [(b,0)]
poly = Polygon(verts, facecolor='0.8', edgecolor='k')
ax.add_patch(poly)
text(0.5 * (a + b), 30,
r"$\int_a^b f(x)\mathrm{d}x$", horizontalalignment='center',
fontsize=20)
axis([0,10, 0, 180])
figtext(0.9, 0.05, 'x')
figtext(0.1, 0.9, 'y')
ax.set_xticks((a,b))
ax.set_xticklabels(('a','b'))
ax.set_yticks([])
show()