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=================
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IPython reference
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=================
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.. _command_line_options:
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Command-line usage
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==================
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You start IPython with the command::
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$ ipython [options] files
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.. note::
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For IPython on Python 3, use ``ipython3`` in place of ``ipython``.
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If invoked with no options, it executes all the files listed in sequence
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and drops you into the interpreter while still acknowledging any options
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you may have set in your ipython_config.py. This behavior is different from
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standard Python, which when called as python -i will only execute one
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file and ignore your configuration setup.
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Please note that some of the configuration options are not available at
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the command line, simply because they are not practical here. Look into
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your configuration files for details on those. There are separate configuration
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files for each profile, and the files look like "ipython_config.py" or
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"ipython_config_<frontendname>.py". Profile directories look like
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"profile_profilename" and are typically installed in the IPYTHON_DIR directory.
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For Linux users, this will be $HOME/.config/ipython, and for other users it
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will be $HOME/.ipython. For Windows users, $HOME resolves to C:\\Documents and
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Settings\\YourUserName in most instances.
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Eventloop integration
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---------------------
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Previously IPython had command line options for controlling GUI event loop
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integration (-gthread, -qthread, -q4thread, -wthread, -pylab). As of IPython
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version 0.11, these have been removed. Please see the new ``%gui``
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magic command or :ref:`this section <gui_support>` for details on the new
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interface, or specify the gui at the commandline::
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$ ipython --gui=qt
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Command-line Options
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--------------------
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To see the options IPython accepts, use ``ipython --help`` (and you probably
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should run the output through a pager such as ``ipython --help | less`` for
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more convenient reading). This shows all the options that have a single-word
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alias to control them, but IPython lets you configure all of its objects from
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the command-line by passing the full class name and a corresponding value; type
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``ipython --help-all`` to see this full list. For example::
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ipython --pylab qt
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is equivalent to::
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ipython --TerminalIPythonApp.pylab='qt'
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Note that in the second form, you *must* use the equal sign, as the expression
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is evaluated as an actual Python assignment. While in the above example the
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short form is more convenient, only the most common options have a short form,
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while any configurable variable in IPython can be set at the command-line by
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using the long form. This long form is the same syntax used in the
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configuration files, if you want to set these options permanently.
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Interactive use
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===============
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IPython is meant to work as a drop-in replacement for the standard interactive
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interpreter. As such, any code which is valid python should execute normally
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under IPython (cases where this is not true should be reported as bugs). It
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does, however, offer many features which are not available at a standard python
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prompt. What follows is a list of these.
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Caution for Windows users
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-------------------------
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Windows, unfortunately, uses the '\\' character as a path separator. This is a
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terrible choice, because '\\' also represents the escape character in most
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modern programming languages, including Python. For this reason, using '/'
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character is recommended if you have problems with ``\``. However, in Windows
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commands '/' flags options, so you can not use it for the root directory. This
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means that paths beginning at the root must be typed in a contrived manner
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like: ``%copy \opt/foo/bar.txt \tmp``
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.. _magic:
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Magic command system
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--------------------
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IPython will treat any line whose first character is a % as a special
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call to a 'magic' function. These allow you to control the behavior of
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IPython itself, plus a lot of system-type features. They are all
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prefixed with a % character, but parameters are given without
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parentheses or quotes.
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Example: typing ``%cd mydir`` changes your working directory to 'mydir', if it
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exists.
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If you have 'automagic' enabled (as it by default), you don't need
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to type in the % explicitly. IPython will scan its internal list of
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magic functions and call one if it exists. With automagic on you can
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then just type ``cd mydir`` to go to directory 'mydir'. The automagic
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system has the lowest possible precedence in name searches, so defining
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an identifier with the same name as an existing magic function will
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shadow it for automagic use. You can still access the shadowed magic
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function by explicitly using the % character at the beginning of the line.
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An example (with automagic on) should clarify all this:
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.. sourcecode:: ipython
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In [1]: cd ipython # %cd is called by automagic
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/home/fperez/ipython
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In [2]: cd=1 # now cd is just a variable
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In [3]: cd .. # and doesn't work as a function anymore
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File "<ipython-input-3-9fedb3aff56c>", line 1
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cd ..
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^
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SyntaxError: invalid syntax
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In [4]: %cd .. # but %cd always works
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/home/fperez
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In [5]: del cd # if you remove the cd variable, automagic works again
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In [6]: cd ipython
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/home/fperez/ipython
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You can define your own magic functions to extend the system. The
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following example defines a new magic command, %impall:
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.. sourcecode:: python
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ip = get_ipython()
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def doimp(self, arg):
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ip = self.api
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ip.ex("import %s; reload(%s); from %s import *" % (arg,arg,arg) )
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ip.define_magic('impall', doimp)
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Type ``%magic`` for more information, including a list of all available magic
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functions at any time and their docstrings. You can also type
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``%magic_function_name?`` (see :ref:`below <dynamic_object_info>` for information on
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the '?' system) to get information about any particular magic function you are
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interested in.
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The API documentation for the :mod:`IPython.core.magic` module contains the full
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docstrings of all currently available magic commands.
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Access to the standard Python help
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----------------------------------
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Simply type ``help()`` to access Python's standard help system. You can
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also type ``help(object)`` for information about a given object, or
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``help('keyword')`` for information on a keyword. You may need to configure your
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PYTHONDOCS environment variable for this feature to work correctly.
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.. _dynamic_object_info:
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Dynamic object information
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--------------------------
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Typing ``?word`` or ``word?`` prints detailed information about an object. If
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certain strings in the object are too long (e.g. function signatures) they get
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snipped in the center for brevity. This system gives access variable types and
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values, docstrings, function prototypes and other useful information.
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If the information will not fit in the terminal, it is displayed in a pager
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(``less`` if available, otherwise a basic internal pager).
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Typing ``??word`` or ``word??`` gives access to the full information, including
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the source code where possible. Long strings are not snipped.
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The following magic functions are particularly useful for gathering
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information about your working environment. You can get more details by
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typing ``%magic`` or querying them individually (``%function_name?``);
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this is just a summary:
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* **%pdoc <object>**: Print (or run through a pager if too long) the
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docstring for an object. If the given object is a class, it will
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print both the class and the constructor docstrings.
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* **%pdef <object>**: Print the definition header for any callable
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object. If the object is a class, print the constructor information.
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* **%psource <object>**: Print (or run through a pager if too long)
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the source code for an object.
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* **%pfile <object>**: Show the entire source file where an object was
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defined via a pager, opening it at the line where the object
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definition begins.
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* **%who/%whos**: These functions give information about identifiers
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you have defined interactively (not things you loaded or defined
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in your configuration files). %who just prints a list of
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identifiers and %whos prints a table with some basic details about
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each identifier.
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Note that the dynamic object information functions (?/??, ``%pdoc``,
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``%pfile``, ``%pdef``, ``%psource``) work on object attributes, as well as
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directly on variables. For example, after doing ``import os``, you can use
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``os.path.abspath??``.
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.. _readline:
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Readline-based features
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-----------------------
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These features require the GNU readline library, so they won't work if your
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Python installation lacks readline support. We will first describe the default
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behavior IPython uses, and then how to change it to suit your preferences.
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Command line completion
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+++++++++++++++++++++++
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At any time, hitting TAB will complete any available python commands or
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variable names, and show you a list of the possible completions if
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there's no unambiguous one. It will also complete filenames in the
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current directory if no python names match what you've typed so far.
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Search command history
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++++++++++++++++++++++
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IPython provides two ways for searching through previous input and thus
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reduce the need for repetitive typing:
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1. Start typing, and then use Ctrl-p (previous,up) and Ctrl-n
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(next,down) to search through only the history items that match
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what you've typed so far. If you use Ctrl-p/Ctrl-n at a blank
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prompt, they just behave like normal arrow keys.
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2. Hit Ctrl-r: opens a search prompt. Begin typing and the system
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searches your history for lines that contain what you've typed so
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far, completing as much as it can.
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Persistent command history across sessions
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++++++++++++++++++++++++++++++++++++++++++
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IPython will save your input history when it leaves and reload it next
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time you restart it. By default, the history file is named
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$IPYTHON_DIR/profile_<name>/history.sqlite. This allows you to keep
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separate histories related to various tasks: commands related to
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numerical work will not be clobbered by a system shell history, for
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example.
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Autoindent
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++++++++++
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IPython can recognize lines ending in ':' and indent the next line,
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while also un-indenting automatically after 'raise' or 'return'.
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This feature uses the readline library, so it will honor your
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:file:`~/.inputrc` configuration (or whatever file your INPUTRC variable points
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to). Adding the following lines to your :file:`.inputrc` file can make
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indenting/unindenting more convenient (M-i indents, M-u unindents)::
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$if Python
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"\M-i": " "
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"\M-u": "\d\d\d\d"
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$endif
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Note that there are 4 spaces between the quote marks after "M-i" above.
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.. warning::
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Setting the above indents will cause problems with unicode text entry in
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the terminal.
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.. warning::
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Autoindent is ON by default, but it can cause problems with the pasting of
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multi-line indented code (the pasted code gets re-indented on each line). A
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magic function %autoindent allows you to toggle it on/off at runtime. You
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can also disable it permanently on in your :file:`ipython_config.py` file
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(set TerminalInteractiveShell.autoindent=False).
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If you want to paste multiple lines in the terminal, it is recommended that
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you use ``%paste``.
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Customizing readline behavior
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+++++++++++++++++++++++++++++
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All these features are based on the GNU readline library, which has an
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extremely customizable interface. Normally, readline is configured via a
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file which defines the behavior of the library; the details of the
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syntax for this can be found in the readline documentation available
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with your system or on the Internet. IPython doesn't read this file (if
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it exists) directly, but it does support passing to readline valid
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options via a simple interface. In brief, you can customize readline by
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setting the following options in your configuration file (note
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that these options can not be specified at the command line):
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* **readline_parse_and_bind**: this holds a list of strings to be executed
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via a readline.parse_and_bind() command. The syntax for valid commands
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of this kind can be found by reading the documentation for the GNU
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readline library, as these commands are of the kind which readline
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accepts in its configuration file.
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* **readline_remove_delims**: a string of characters to be removed
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from the default word-delimiters list used by readline, so that
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completions may be performed on strings which contain them. Do not
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change the default value unless you know what you're doing.
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You will find the default values in your configuration file.
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Session logging and restoring
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-----------------------------
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You can log all input from a session either by starting IPython with the
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command line switch ``--logfile=foo.py`` (see :ref:`here <command_line_options>`)
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or by activating the logging at any moment with the magic function %logstart.
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Log files can later be reloaded by running them as scripts and IPython
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will attempt to 'replay' the log by executing all the lines in it, thus
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restoring the state of a previous session. This feature is not quite
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perfect, but can still be useful in many cases.
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The log files can also be used as a way to have a permanent record of
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any code you wrote while experimenting. Log files are regular text files
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which you can later open in your favorite text editor to extract code or
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to 'clean them up' before using them to replay a session.
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The `%logstart` function for activating logging in mid-session is used as
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follows::
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%logstart [log_name [log_mode]]
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If no name is given, it defaults to a file named 'ipython_log.py' in your
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current working directory, in 'rotate' mode (see below).
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'%logstart name' saves to file 'name' in 'backup' mode. It saves your
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history up to that point and then continues logging.
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%logstart takes a second optional parameter: logging mode. This can be
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one of (note that the modes are given unquoted):
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* [over:] overwrite existing log_name.
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* [backup:] rename (if exists) to log_name~ and start log_name.
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* [append:] well, that says it.
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* [rotate:] create rotating logs log_name.1~, log_name.2~, etc.
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The %logoff and %logon functions allow you to temporarily stop and
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resume logging to a file which had previously been started with
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%logstart. They will fail (with an explanation) if you try to use them
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before logging has been started.
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.. _system_shell_access:
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System shell access
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-------------------
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Any input line beginning with a ! character is passed verbatim (minus
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the !, of course) to the underlying operating system. For example,
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typing ``!ls`` will run 'ls' in the current directory.
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Manual capture of command output
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--------------------------------
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You can assign the result of a system command to a Python variable with the
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syntax ``myfiles = !ls``. This gets machine readable output from stdout
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(e.g. without colours), and splits on newlines. To explicitly get this sort of
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output without assigning to a variable, use two exclamation marks (``!!ls``) or
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the ``%sx`` magic command.
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The captured list has some convenience features. ``myfiles.n`` or ``myfiles.s``
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returns a string delimited by newlines or spaces, respectively. ``myfiles.p``
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produces `path objects <http://pypi.python.org/pypi/path.py>`_ from the list items.
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See :ref:`string_lists` for details.
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IPython also allows you to expand the value of python variables when
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making system calls. Wrap variables or expressions in {braces}::
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In [1]: pyvar = 'Hello world'
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In [2]: !echo "A python variable: {pyvar}"
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A python variable: Hello world
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In [3]: import math
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In [4]: x = 8
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In [5]: !echo {math.factorial(x)}
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40320
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For simple cases, you can alternatively prepend $ to a variable name::
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In [6]: !echo $sys.argv
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[/home/fperez/usr/bin/ipython]
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In [7]: !echo "A system variable: $$HOME" # Use $$ for literal $
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A system variable: /home/fperez
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System command aliases
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----------------------
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The %alias magic function allows you to define magic functions which are in fact
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system shell commands. These aliases can have parameters.
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``%alias alias_name cmd`` defines 'alias_name' as an alias for 'cmd'
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Then, typing ``alias_name params`` will execute the system command 'cmd
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params' (from your underlying operating system).
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You can also define aliases with parameters using %s specifiers (one per
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parameter). The following example defines the parts function as an
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alias to the command 'echo first %s second %s' where each %s will be
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replaced by a positional parameter to the call to %parts::
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In [1]: %alias parts echo first %s second %s
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In [2]: parts A B
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first A second B
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In [3]: parts A
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ERROR: Alias <parts> requires 2 arguments, 1 given.
|
|
|
|
|
|
If called with no parameters, %alias prints the table of currently
|
|
|
defined aliases.
|
|
|
|
|
|
The %rehashx magic allows you to load your entire $PATH as
|
|
|
ipython aliases. See its docstring for further details.
|
|
|
|
|
|
|
|
|
.. _dreload:
|
|
|
|
|
|
Recursive reload
|
|
|
----------------
|
|
|
|
|
|
The :mod:`IPython.lib.deepreload` module allows you to recursively reload a
|
|
|
module: changes made to any of its dependencies will be reloaded without
|
|
|
having to exit. To start using it, do::
|
|
|
|
|
|
from IPython.lib.deepreload import reload as dreload
|
|
|
|
|
|
|
|
|
Verbose and colored exception traceback printouts
|
|
|
-------------------------------------------------
|
|
|
|
|
|
IPython provides the option to see very detailed exception tracebacks,
|
|
|
which can be especially useful when debugging large programs. You can
|
|
|
run any Python file with the %run function to benefit from these
|
|
|
detailed tracebacks. Furthermore, both normal and verbose tracebacks can
|
|
|
be colored (if your terminal supports it) which makes them much easier
|
|
|
to parse visually.
|
|
|
|
|
|
See the magic xmode and colors functions for details (just type %magic).
|
|
|
|
|
|
These features are basically a terminal version of Ka-Ping Yee's cgitb
|
|
|
module, now part of the standard Python library.
|
|
|
|
|
|
|
|
|
.. _input_caching:
|
|
|
|
|
|
Input caching system
|
|
|
--------------------
|
|
|
|
|
|
IPython offers numbered prompts (In/Out) with input and output caching
|
|
|
(also referred to as 'input history'). All input is saved and can be
|
|
|
retrieved as variables (besides the usual arrow key recall), in
|
|
|
addition to the %rep magic command that brings a history entry
|
|
|
up for editing on the next command line.
|
|
|
|
|
|
The following GLOBAL variables always exist (so don't overwrite them!):
|
|
|
|
|
|
* _i, _ii, _iii: store previous, next previous and next-next previous inputs.
|
|
|
* In, _ih : a list of all inputs; _ih[n] is the input from line n. If you
|
|
|
overwrite In with a variable of your own, you can remake the assignment to the
|
|
|
internal list with a simple ``In=_ih``.
|
|
|
|
|
|
Additionally, global variables named _i<n> are dynamically created (<n>
|
|
|
being the prompt counter), so ``_i<n> == _ih[<n>] == In[<n>]``.
|
|
|
|
|
|
For example, what you typed at prompt 14 is available as _i14, _ih[14]
|
|
|
and In[14].
|
|
|
|
|
|
This allows you to easily cut and paste multi line interactive prompts
|
|
|
by printing them out: they print like a clean string, without prompt
|
|
|
characters. You can also manipulate them like regular variables (they
|
|
|
are strings), modify or exec them (typing ``exec _i9`` will re-execute the
|
|
|
contents of input prompt 9.
|
|
|
|
|
|
You can also re-execute multiple lines of input easily by using the
|
|
|
magic %rerun or %macro functions. The macro system also allows you to re-execute
|
|
|
previous lines which include magic function calls (which require special
|
|
|
processing). Type %macro? for more details on the macro system.
|
|
|
|
|
|
A history function %hist allows you to see any part of your input
|
|
|
history by printing a range of the _i variables.
|
|
|
|
|
|
You can also search ('grep') through your history by typing
|
|
|
``%hist -g somestring``. This is handy for searching for URLs, IP addresses,
|
|
|
etc. You can bring history entries listed by '%hist -g' up for editing
|
|
|
with the %recall command, or run them immediately with %rerun.
|
|
|
|
|
|
.. _output_caching:
|
|
|
|
|
|
Output caching system
|
|
|
---------------------
|
|
|
|
|
|
For output that is returned from actions, a system similar to the input
|
|
|
cache exists but using _ instead of _i. Only actions that produce a
|
|
|
result (NOT assignments, for example) are cached. If you are familiar
|
|
|
with Mathematica, IPython's _ variables behave exactly like
|
|
|
Mathematica's % variables.
|
|
|
|
|
|
The following GLOBAL variables always exist (so don't overwrite them!):
|
|
|
|
|
|
* [_] (a single underscore) : stores previous output, like Python's
|
|
|
default interpreter.
|
|
|
* [__] (two underscores): next previous.
|
|
|
* [___] (three underscores): next-next previous.
|
|
|
|
|
|
Additionally, global variables named _<n> are dynamically created (<n>
|
|
|
being the prompt counter), such that the result of output <n> is always
|
|
|
available as _<n> (don't use the angle brackets, just the number, e.g.
|
|
|
_21).
|
|
|
|
|
|
These variables are also stored in a global dictionary (not a
|
|
|
list, since it only has entries for lines which returned a result)
|
|
|
available under the names _oh and Out (similar to _ih and In). So the
|
|
|
output from line 12 can be obtained as _12, Out[12] or _oh[12]. If you
|
|
|
accidentally overwrite the Out variable you can recover it by typing
|
|
|
'Out=_oh' at the prompt.
|
|
|
|
|
|
This system obviously can potentially put heavy memory demands on your
|
|
|
system, since it prevents Python's garbage collector from removing any
|
|
|
previously computed results. You can control how many results are kept
|
|
|
in memory with the option (at the command line or in your configuration
|
|
|
file) cache_size. If you set it to 0, the whole system is completely
|
|
|
disabled and the prompts revert to the classic '>>>' of normal Python.
|
|
|
|
|
|
|
|
|
Directory history
|
|
|
-----------------
|
|
|
|
|
|
Your history of visited directories is kept in the global list _dh, and
|
|
|
the magic %cd command can be used to go to any entry in that list. The
|
|
|
%dhist command allows you to view this history. Do ``cd -<TAB>`` to
|
|
|
conveniently view the directory history.
|
|
|
|
|
|
|
|
|
Automatic parentheses and quotes
|
|
|
--------------------------------
|
|
|
|
|
|
These features were adapted from Nathan Gray's LazyPython. They are
|
|
|
meant to allow less typing for common situations.
|
|
|
|
|
|
|
|
|
Automatic parentheses
|
|
|
+++++++++++++++++++++
|
|
|
|
|
|
Callable objects (i.e. functions, methods, etc) can be invoked like this
|
|
|
(notice the commas between the arguments)::
|
|
|
|
|
|
In [1]: callable_ob arg1, arg2, arg3
|
|
|
------> callable_ob(arg1, arg2, arg3)
|
|
|
|
|
|
You can force automatic parentheses by using '/' as the first character
|
|
|
of a line. For example::
|
|
|
|
|
|
In [2]: /globals # becomes 'globals()'
|
|
|
|
|
|
Note that the '/' MUST be the first character on the line! This won't work::
|
|
|
|
|
|
In [3]: print /globals # syntax error
|
|
|
|
|
|
In most cases the automatic algorithm should work, so you should rarely
|
|
|
need to explicitly invoke /. One notable exception is if you are trying
|
|
|
to call a function with a list of tuples as arguments (the parenthesis
|
|
|
will confuse IPython)::
|
|
|
|
|
|
In [4]: zip (1,2,3),(4,5,6) # won't work
|
|
|
|
|
|
but this will work::
|
|
|
|
|
|
In [5]: /zip (1,2,3),(4,5,6)
|
|
|
------> zip ((1,2,3),(4,5,6))
|
|
|
Out[5]: [(1, 4), (2, 5), (3, 6)]
|
|
|
|
|
|
IPython tells you that it has altered your command line by displaying
|
|
|
the new command line preceded by ->. e.g.::
|
|
|
|
|
|
In [6]: callable list
|
|
|
------> callable(list)
|
|
|
|
|
|
|
|
|
Automatic quoting
|
|
|
+++++++++++++++++
|
|
|
|
|
|
You can force automatic quoting of a function's arguments by using ','
|
|
|
or ';' as the first character of a line. For example::
|
|
|
|
|
|
In [1]: ,my_function /home/me # becomes my_function("/home/me")
|
|
|
|
|
|
If you use ';' the whole argument is quoted as a single string, while ',' splits
|
|
|
on whitespace::
|
|
|
|
|
|
In [2]: ,my_function a b c # becomes my_function("a","b","c")
|
|
|
|
|
|
In [3]: ;my_function a b c # becomes my_function("a b c")
|
|
|
|
|
|
Note that the ',' or ';' MUST be the first character on the line! This
|
|
|
won't work::
|
|
|
|
|
|
In [4]: x = ,my_function /home/me # syntax error
|
|
|
|
|
|
IPython as your default Python environment
|
|
|
==========================================
|
|
|
|
|
|
Python honors the environment variable PYTHONSTARTUP and will execute at
|
|
|
startup the file referenced by this variable. If you put the following code at
|
|
|
the end of that file, then IPython will be your working environment anytime you
|
|
|
start Python::
|
|
|
|
|
|
from IPython.frontend.terminal.ipapp import launch_new_instance
|
|
|
launch_new_instance()
|
|
|
raise SystemExit
|
|
|
|
|
|
The ``raise SystemExit`` is needed to exit Python when
|
|
|
it finishes, otherwise you'll be back at the normal Python '>>>'
|
|
|
prompt.
|
|
|
|
|
|
This is probably useful to developers who manage multiple Python
|
|
|
versions and don't want to have correspondingly multiple IPython
|
|
|
versions. Note that in this mode, there is no way to pass IPython any
|
|
|
command-line options, as those are trapped first by Python itself.
|
|
|
|
|
|
.. _Embedding:
|
|
|
|
|
|
Embedding IPython
|
|
|
=================
|
|
|
|
|
|
It is possible to start an IPython instance inside your own Python
|
|
|
programs. This allows you to evaluate dynamically the state of your
|
|
|
code, operate with your variables, analyze them, etc. Note however that
|
|
|
any changes you make to values while in the shell do not propagate back
|
|
|
to the running code, so it is safe to modify your values because you
|
|
|
won't break your code in bizarre ways by doing so.
|
|
|
|
|
|
.. note::
|
|
|
|
|
|
At present, trying to embed IPython from inside IPython causes problems. Run
|
|
|
the code samples below outside IPython.
|
|
|
|
|
|
This feature allows you to easily have a fully functional python
|
|
|
environment for doing object introspection anywhere in your code with a
|
|
|
simple function call. In some cases a simple print statement is enough,
|
|
|
but if you need to do more detailed analysis of a code fragment this
|
|
|
feature can be very valuable.
|
|
|
|
|
|
It can also be useful in scientific computing situations where it is
|
|
|
common to need to do some automatic, computationally intensive part and
|
|
|
then stop to look at data, plots, etc.
|
|
|
Opening an IPython instance will give you full access to your data and
|
|
|
functions, and you can resume program execution once you are done with
|
|
|
the interactive part (perhaps to stop again later, as many times as
|
|
|
needed).
|
|
|
|
|
|
The following code snippet is the bare minimum you need to include in
|
|
|
your Python programs for this to work (detailed examples follow later)::
|
|
|
|
|
|
from IPython import embed
|
|
|
|
|
|
embed() # this call anywhere in your program will start IPython
|
|
|
|
|
|
You can run embedded instances even in code which is itself being run at
|
|
|
the IPython interactive prompt with '%run <filename>'. Since it's easy
|
|
|
to get lost as to where you are (in your top-level IPython or in your
|
|
|
embedded one), it's a good idea in such cases to set the in/out prompts
|
|
|
to something different for the embedded instances. The code examples
|
|
|
below illustrate this.
|
|
|
|
|
|
You can also have multiple IPython instances in your program and open
|
|
|
them separately, for example with different options for data
|
|
|
presentation. If you close and open the same instance multiple times,
|
|
|
its prompt counters simply continue from each execution to the next.
|
|
|
|
|
|
Please look at the docstrings in the :mod:`~IPython.frontend.terminal.embed`
|
|
|
module for more details on the use of this system.
|
|
|
|
|
|
The following sample file illustrating how to use the embedding
|
|
|
functionality is provided in the examples directory as example-embed.py.
|
|
|
It should be fairly self-explanatory:
|
|
|
|
|
|
.. literalinclude:: ../../examples/core/example-embed.py
|
|
|
:language: python
|
|
|
|
|
|
Once you understand how the system functions, you can use the following
|
|
|
code fragments in your programs which are ready for cut and paste:
|
|
|
|
|
|
.. literalinclude:: ../../examples/core/example-embed-short.py
|
|
|
:language: python
|
|
|
|
|
|
Using the Python debugger (pdb)
|
|
|
===============================
|
|
|
|
|
|
Running entire programs via pdb
|
|
|
-------------------------------
|
|
|
|
|
|
pdb, the Python debugger, is a powerful interactive debugger which
|
|
|
allows you to step through code, set breakpoints, watch variables,
|
|
|
etc. IPython makes it very easy to start any script under the control
|
|
|
of pdb, regardless of whether you have wrapped it into a 'main()'
|
|
|
function or not. For this, simply type '%run -d myscript' at an
|
|
|
IPython prompt. See the %run command's documentation (via '%run?' or
|
|
|
in Sec. magic_ for more details, including how to control where pdb
|
|
|
will stop execution first.
|
|
|
|
|
|
For more information on the use of the pdb debugger, read the included
|
|
|
pdb.doc file (part of the standard Python distribution). On a stock
|
|
|
Linux system it is located at /usr/lib/python2.3/pdb.doc, but the
|
|
|
easiest way to read it is by using the help() function of the pdb module
|
|
|
as follows (in an IPython prompt)::
|
|
|
|
|
|
In [1]: import pdb
|
|
|
In [2]: pdb.help()
|
|
|
|
|
|
This will load the pdb.doc document in a file viewer for you automatically.
|
|
|
|
|
|
|
|
|
Automatic invocation of pdb on exceptions
|
|
|
-----------------------------------------
|
|
|
|
|
|
IPython, if started with the ``--pdb`` option (or if the option is set in
|
|
|
your config file) can call the Python pdb debugger every time your code
|
|
|
triggers an uncaught exception. This feature
|
|
|
can also be toggled at any time with the %pdb magic command. This can be
|
|
|
extremely useful in order to find the origin of subtle bugs, because pdb
|
|
|
opens up at the point in your code which triggered the exception, and
|
|
|
while your program is at this point 'dead', all the data is still
|
|
|
available and you can walk up and down the stack frame and understand
|
|
|
the origin of the problem.
|
|
|
|
|
|
Furthermore, you can use these debugging facilities both with the
|
|
|
embedded IPython mode and without IPython at all. For an embedded shell
|
|
|
(see sec. Embedding_), simply call the constructor with
|
|
|
``--pdb`` in the argument string and pdb will automatically be called if an
|
|
|
uncaught exception is triggered by your code.
|
|
|
|
|
|
For stand-alone use of the feature in your programs which do not use
|
|
|
IPython at all, put the following lines toward the top of your 'main'
|
|
|
routine::
|
|
|
|
|
|
import sys
|
|
|
from IPython.core import ultratb
|
|
|
sys.excepthook = ultratb.FormattedTB(mode='Verbose',
|
|
|
color_scheme='Linux', call_pdb=1)
|
|
|
|
|
|
The mode keyword can be either 'Verbose' or 'Plain', giving either very
|
|
|
detailed or normal tracebacks respectively. The color_scheme keyword can
|
|
|
be one of 'NoColor', 'Linux' (default) or 'LightBG'. These are the same
|
|
|
options which can be set in IPython with ``--colors`` and ``--xmode``.
|
|
|
|
|
|
This will give any of your programs detailed, colored tracebacks with
|
|
|
automatic invocation of pdb.
|
|
|
|
|
|
|
|
|
Extensions for syntax processing
|
|
|
================================
|
|
|
|
|
|
This isn't for the faint of heart, because the potential for breaking
|
|
|
things is quite high. But it can be a very powerful and useful feature.
|
|
|
In a nutshell, you can redefine the way IPython processes the user input
|
|
|
line to accept new, special extensions to the syntax without needing to
|
|
|
change any of IPython's own code.
|
|
|
|
|
|
In the IPython/extensions directory you will find some examples
|
|
|
supplied, which we will briefly describe now. These can be used 'as is'
|
|
|
(and both provide very useful functionality), or you can use them as a
|
|
|
starting point for writing your own extensions.
|
|
|
|
|
|
.. _pasting_with_prompts:
|
|
|
|
|
|
Pasting of code starting with Python or IPython prompts
|
|
|
-------------------------------------------------------
|
|
|
|
|
|
IPython is smart enough to filter out input prompts, be they plain Python ones
|
|
|
(``>>>`` and ``...``) or IPython ones (``In [N]:`` and `` ...:``). You can
|
|
|
therefore copy and paste from existing interactive sessions without worry.
|
|
|
|
|
|
The following is a 'screenshot' of how things work, copying an example from the
|
|
|
standard Python tutorial::
|
|
|
|
|
|
In [1]: >>> # Fibonacci series:
|
|
|
|
|
|
In [2]: ... # the sum of two elements defines the next
|
|
|
|
|
|
In [3]: ... a, b = 0, 1
|
|
|
|
|
|
In [4]: >>> while b < 10:
|
|
|
...: ... print b
|
|
|
...: ... a, b = b, a+b
|
|
|
...:
|
|
|
1
|
|
|
1
|
|
|
2
|
|
|
3
|
|
|
5
|
|
|
8
|
|
|
|
|
|
And pasting from IPython sessions works equally well::
|
|
|
|
|
|
In [1]: In [5]: def f(x):
|
|
|
...: ...: "A simple function"
|
|
|
...: ...: return x**2
|
|
|
...: ...:
|
|
|
|
|
|
In [2]: f(3)
|
|
|
Out[2]: 9
|
|
|
|
|
|
.. _gui_support:
|
|
|
|
|
|
GUI event loop support
|
|
|
======================
|
|
|
|
|
|
.. versionadded:: 0.11
|
|
|
The ``%gui`` magic and :mod:`IPython.lib.inputhook`.
|
|
|
|
|
|
IPython has excellent support for working interactively with Graphical User
|
|
|
Interface (GUI) toolkits, such as wxPython, PyQt4/PySide, PyGTK and Tk. This is
|
|
|
implemented using Python's builtin ``PyOSInputHook`` hook. This implementation
|
|
|
is extremely robust compared to our previous thread-based version. The
|
|
|
advantages of this are:
|
|
|
|
|
|
* GUIs can be enabled and disabled dynamically at runtime.
|
|
|
* The active GUI can be switched dynamically at runtime.
|
|
|
* In some cases, multiple GUIs can run simultaneously with no problems.
|
|
|
* There is a developer API in :mod:`IPython.lib.inputhook` for customizing
|
|
|
all of these things.
|
|
|
|
|
|
For users, enabling GUI event loop integration is simple. You simple use the
|
|
|
``%gui`` magic as follows::
|
|
|
|
|
|
%gui [GUINAME]
|
|
|
|
|
|
With no arguments, ``%gui`` removes all GUI support. Valid ``GUINAME``
|
|
|
arguments are ``wx``, ``qt``, ``gtk`` and ``tk``.
|
|
|
|
|
|
Thus, to use wxPython interactively and create a running :class:`wx.App`
|
|
|
object, do::
|
|
|
|
|
|
%gui wx
|
|
|
|
|
|
For information on IPython's Matplotlib integration (and the ``pylab`` mode)
|
|
|
see :ref:`this section <matplotlib_support>`.
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For developers that want to use IPython's GUI event loop integration in the
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form of a library, these capabilities are exposed in library form in the
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:mod:`IPython.lib.inputhook` and :mod:`IPython.lib.guisupport` modules.
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Interested developers should see the module docstrings for more information,
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but there are a few points that should be mentioned here.
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First, the ``PyOSInputHook`` approach only works in command line settings
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where readline is activated. The integration with various eventloops
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is handled somewhat differently (and more simply) when using the standalone
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kernel, as in the qtconsole and notebook.
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Second, when using the ``PyOSInputHook`` approach, a GUI application should
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*not* start its event loop. Instead all of this is handled by the
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``PyOSInputHook``. This means that applications that are meant to be used both
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in IPython and as standalone apps need to have special code to detects how the
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application is being run. We highly recommend using IPython's support for this.
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Since the details vary slightly between toolkits, we point you to the various
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examples in our source directory :file:`docs/examples/lib` that demonstrate
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these capabilities.
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Third, unlike previous versions of IPython, we no longer "hijack" (replace
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them with no-ops) the event loops. This is done to allow applications that
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actually need to run the real event loops to do so. This is often needed to
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process pending events at critical points.
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Finally, we also have a number of examples in our source directory
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:file:`docs/examples/lib` that demonstrate these capabilities.
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PyQt and PySide
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---------------
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.. attempt at explanation of the complete mess that is Qt support
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When you use ``--gui=qt`` or ``--pylab=qt``, IPython can work with either
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PyQt4 or PySide. There are three options for configuration here, because
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PyQt4 has two APIs for QString and QVariant - v1, which is the default on
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Python 2, and the more natural v2, which is the only API supported by PySide.
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v2 is also the default for PyQt4 on Python 3. IPython's code for the QtConsole
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uses v2, but you can still use any interface in your code, since the
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Qt frontend is in a different process.
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The default will be to import PyQt4 without configuration of the APIs, thus
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matching what most applications would expect. It will fall back of PySide if
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PyQt4 is unavailable.
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If specified, IPython will respect the environment variable ``QT_API`` used
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by ETS. ETS 4.0 also works with both PyQt4 and PySide, but it requires
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PyQt4 to use its v2 API. So if ``QT_API=pyside`` PySide will be used,
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and if ``QT_API=pyqt`` then PyQt4 will be used *with the v2 API* for
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QString and QVariant, so ETS codes like MayaVi will also work with IPython.
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If you launch IPython in pylab mode with ``ipython --pylab=qt``, then IPython
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will ask matplotlib which Qt library to use (only if QT_API is *not set*), via
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the 'backend.qt4' rcParam. If matplotlib is version 1.0.1 or older, then
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IPython will always use PyQt4 without setting the v2 APIs, since neither v2
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PyQt nor PySide work.
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.. warning::
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Note that this means for ETS 4 to work with PyQt4, ``QT_API`` *must* be set
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to work with IPython's qt integration, because otherwise PyQt4 will be
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loaded in an incompatible mode.
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It also means that you must *not* have ``QT_API`` set if you want to
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use ``--gui=qt`` with code that requires PyQt4 API v1.
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.. _matplotlib_support:
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Plotting with matplotlib
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========================
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`Matplotlib`_ provides high quality 2D and 3D plotting for Python. Matplotlib
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can produce plots on screen using a variety of GUI toolkits, including Tk,
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PyGTK, PyQt4 and wxPython. It also provides a number of commands useful for
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scientific computing, all with a syntax compatible with that of the popular
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Matlab program.
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To start IPython with matplotlib support, use the ``--pylab`` switch. If no
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arguments are given, IPython will automatically detect your choice of
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matplotlib backend. You can also request a specific backend with ``--pylab
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backend``, where ``backend`` must be one of: 'tk', 'qt', 'wx', 'gtk', 'osx'.
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In the web notebook and Qt console, 'inline' is also a valid backend value,
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which produces static figures inlined inside the application window instead of
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matplotlib's interactive figures that live in separate windows.
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.. _Matplotlib: http://matplotlib.sourceforge.net
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.. _interactive_demos:
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Interactive demos with IPython
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|
==============================
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IPython ships with a basic system for running scripts interactively in
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sections, useful when presenting code to audiences. A few tags embedded
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in comments (so that the script remains valid Python code) divide a file
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into separate blocks, and the demo can be run one block at a time, with
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IPython printing (with syntax highlighting) the block before executing
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it, and returning to the interactive prompt after each block. The
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interactive namespace is updated after each block is run with the
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contents of the demo's namespace.
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This allows you to show a piece of code, run it and then execute
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|
interactively commands based on the variables just created. Once you
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|
want to continue, you simply execute the next block of the demo. The
|
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|
following listing shows the markup necessary for dividing a script into
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|
sections for execution as a demo:
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|
.. literalinclude:: ../../examples/lib/example-demo.py
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:language: python
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|
In order to run a file as a demo, you must first make a Demo object out
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|
of it. If the file is named myscript.py, the following code will make a
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demo::
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|
from IPython.lib.demo import Demo
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|
mydemo = Demo('myscript.py')
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|
This creates the mydemo object, whose blocks you run one at a time by
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|
simply calling the object with no arguments. If you have autocall active
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|
in IPython (the default), all you need to do is type::
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|
mydemo
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|
and IPython will call it, executing each block. Demo objects can be
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|
restarted, you can move forward or back skipping blocks, re-execute the
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|
last block, etc. Simply use the Tab key on a demo object to see its
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|
methods, and call '?' on them to see their docstrings for more usage
|
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|
details. In addition, the demo module itself contains a comprehensive
|
|
|
docstring, which you can access via::
|
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|
|
|
from IPython.lib import demo
|
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|
|
|
|
demo?
|
|
|
|
|
|
Limitations: It is important to note that these demos are limited to
|
|
|
fairly simple uses. In particular, you cannot break up sections within
|
|
|
indented code (loops, if statements, function definitions, etc.)
|
|
|
Supporting something like this would basically require tracking the
|
|
|
internal execution state of the Python interpreter, so only top-level
|
|
|
divisions are allowed. If you want to be able to open an IPython
|
|
|
instance at an arbitrary point in a program, you can use IPython's
|
|
|
embedding facilities, see :func:`IPython.embed` for details.
|
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|