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.. _overview:
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============
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Introduction
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============
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Overview
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========
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One of Python's most useful features is its interactive interpreter.
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This system allows very fast testing of ideas without the overhead of
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creating test files as is typical in most programming languages.
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However, the interpreter supplied with the standard Python distribution
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is somewhat limited for extended interactive use.
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The goal of IPython is to create a comprehensive environment for
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interactive and exploratory computing. To support this goal, IPython
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has three main components:
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* An enhanced interactive Python shell.
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* A decoupled two-process communication model, which allows for multiple
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clients to connect to a computation kernel, most notably the web-based
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:ref:`notebook <htmlnotebook>`
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* An architecture for interactive parallel computing.
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All of IPython is open source (released under the revised BSD license).
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Enhanced interactive Python shell
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=================================
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IPython's interactive shell (:command:`ipython`), has the following goals,
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amongst others:
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1. Provide an interactive shell superior to Python's default. IPython
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has many features for object introspection, system shell access,
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and its own special command system for adding functionality when
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working interactively. It tries to be a very efficient environment
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both for Python code development and for exploration of problems
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using Python objects (in situations like data analysis).
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2. Serve as an embeddable, ready to use interpreter for your own
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programs. IPython can be started with a single call from inside
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another program, providing access to the current namespace. This
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can be very useful both for debugging purposes and for situations
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where a blend of batch-processing and interactive exploration are
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needed. New in the 0.9 version of IPython is a reusable wxPython
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based IPython widget.
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3. Offer a flexible framework which can be used as the base
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environment for other systems with Python as the underlying
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language. Specifically scientific environments like Mathematica,
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IDL and Matlab inspired its design, but similar ideas can be
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useful in many fields.
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4. Allow interactive testing of threaded graphical toolkits. IPython
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has support for interactive, non-blocking control of GTK, Qt and
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WX applications via special threading flags. The normal Python
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shell can only do this for Tkinter applications.
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Main features of the interactive shell
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--------------------------------------
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* Dynamic object introspection. One can access docstrings, function
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definition prototypes, source code, source files and other details
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of any object accessible to the interpreter with a single
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keystroke (:samp:`?`, and using :samp:`??` provides additional detail).
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* Searching through modules and namespaces with :samp:`*` wildcards, both
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when using the :samp:`?` system and via the :samp:`%psearch` command.
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* Completion in the local namespace, by typing :kbd:`TAB` at the prompt.
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This works for keywords, modules, methods, variables and files in the
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current directory. This is supported via the readline library, and
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full access to configuring readline's behavior is provided.
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Custom completers can be implemented easily for different purposes
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(system commands, magic arguments etc.)
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* Numbered input/output prompts with command history (persistent
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across sessions and tied to each profile), full searching in this
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history and caching of all input and output.
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* User-extensible 'magic' commands. A set of commands prefixed with
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:samp:`%` is available for controlling IPython itself and provides
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directory control, namespace information and many aliases to
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common system shell commands.
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* Alias facility for defining your own system aliases.
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* Complete system shell access. Lines starting with :samp:`!` are passed
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directly to the system shell, and using :samp:`!!` or :samp:`var = !cmd`
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captures shell output into python variables for further use.
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* Background execution of Python commands in a separate thread.
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IPython has an internal job manager called jobs, and a
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convenience backgrounding magic function called :samp:`%bg`.
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* The ability to expand python variables when calling the system shell. In a
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shell command, any python variable prefixed with :samp:`$` is expanded. A
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double :samp:`$$` allows passing a literal :samp:`$` to the shell (for access
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to shell and environment variables like :envvar:`PATH`).
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* Filesystem navigation, via a magic :samp:`%cd` command, along with a
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persistent bookmark system (using :samp:`%bookmark`) for fast access to
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frequently visited directories.
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* A lightweight persistence framework via the :samp:`%store` command, which
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allows you to save arbitrary Python variables. These get restored
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automatically when your session restarts.
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* Automatic indentation (optional) of code as you type (through the
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readline library).
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* Macro system for quickly re-executing multiple lines of previous
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input with a single name. Macros can be stored persistently via
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:samp:`%store` and edited via :samp:`%edit`.
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* Session logging (you can then later use these logs as code in your
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programs). Logs can optionally timestamp all input, and also store
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session output (marked as comments, so the log remains valid
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Python source code).
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* Session restoring: logs can be replayed to restore a previous
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session to the state where you left it.
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* Verbose and colored exception traceback printouts. Easier to parse
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visually, and in verbose mode they produce a lot of useful
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debugging information (basically a terminal version of the cgitb
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module).
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* Auto-parentheses: callable objects can be executed without
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parentheses: :samp:`sin 3` is automatically converted to :samp:`sin(3)`.
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* Auto-quoting: using :samp:`,`, or :samp:`;` as the first character forces
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auto-quoting of the rest of the line: :samp:`,my_function a b` becomes
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automatically :samp:`my_function("a","b")`, while :samp:`;my_function a b`
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becomes :samp:`my_function("a b")`.
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* Extensible input syntax. You can define filters that pre-process
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user input to simplify input in special situations. This allows
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for example pasting multi-line code fragments which start with
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:samp:`>>>` or :samp:`...` such as those from other python sessions or the
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standard Python documentation.
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* Flexible configuration system. It uses a configuration file which
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allows permanent setting of all command-line options, module
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loading, code and file execution. The system allows recursive file
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inclusion, so you can have a base file with defaults and layers
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which load other customizations for particular projects.
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* Embeddable. You can call IPython as a python shell inside your own
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python programs. This can be used both for debugging code or for
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providing interactive abilities to your programs with knowledge
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about the local namespaces (very useful in debugging and data
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analysis situations).
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* Easy debugger access. You can set IPython to call up an enhanced version of
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the Python debugger (pdb) every time there is an uncaught exception. This
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drops you inside the code which triggered the exception with all the data
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live and it is possible to navigate the stack to rapidly isolate the source
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of a bug. The :samp:`%run` magic command (with the :samp:`-d` option) can run
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any script under pdb's control, automatically setting initial breakpoints for
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you. This version of pdb has IPython-specific improvements, including
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tab-completion and traceback coloring support. For even easier debugger
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access, try :samp:`%debug` after seeing an exception. winpdb is also
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supported, see ipy_winpdb extension.
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* Profiler support. You can run single statements (similar to
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:samp:`profile.run()`) or complete programs under the profiler's control.
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While this is possible with standard cProfile or profile modules,
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IPython wraps this functionality with magic commands (see :samp:`%prun`
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and :samp:`%run -p`) convenient for rapid interactive work.
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* Doctest support. The special :samp:`%doctest_mode` command toggles a mode
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that allows you to paste existing doctests (with leading :samp:`>>>`
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prompts and whitespace) and uses doctest-compatible prompts and
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output, so you can use IPython sessions as doctest code.
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.. _ipythonzmq:
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Decoupled two-process model
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==============================
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IPython has abstracted and extended the notion of a traditional
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*Read-Evaluate-Print Loop* (REPL) environment by decoupling the *evaluation*
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into its own process. We call this process a kernel: it receives execution
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instructions from clients and communicates the results back to them.
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This decoupling allows us to have several clients connected to the same
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kernel, and even allows clients and kernels to live on different machines.
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With the exclusion of the traditional single process terminal-based IPython
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(what you start if you run ``ipython`` without any subcommands), all
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other IPython machinery uses this two-process model. This includes ``ipython
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console``, ``ipython qtconsole``, and ``ipython notebook``.
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As an example, this means that when you start ``ipython qtconsole``, you're
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really starting two processes, a kernel and a Qt-based client can send
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commands to and receive results from that kernel. If there is already a kernel
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running that you want to connect to, you can pass the ``--existing`` flag
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which will skip initiating a new kernel and connect to the most recent kernel,
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instead. To connect to a specific kernel once you have several kernels
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running, use the ``%connect_info`` magic to get the unique connection file,
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which will be something like ``--existing kernel-19732.json`` but with
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different numbers which correspond to the Process ID of the kernel.
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You can read more about using :ref:`ipython qtconsole <qtconsole>`, and
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:ref:`ipython notebook <htmlnotebook>`. There is also a :ref:`message spec
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<messaging>` which documents the protocol for communication between kernels
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and clients.
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Interactive parallel computing
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==============================
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Increasingly, parallel computer hardware, such as multicore CPUs, clusters and
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supercomputers, is becoming ubiquitous. Over the last several years, we have
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developed an architecture within IPython that allows such hardware to be used
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quickly and easily from Python. Moreover, this architecture is designed to
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support interactive and collaborative parallel computing.
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The main features of this system are:
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* Quickly parallelize Python code from an interactive Python/IPython session.
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* A flexible and dynamic process model that be deployed on anything from
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multicore workstations to supercomputers.
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* An architecture that supports many different styles of parallelism, from
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message passing to task farming. And all of these styles can be handled
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interactively.
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* Both blocking and fully asynchronous interfaces.
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* High level APIs that enable many things to be parallelized in a few lines
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of code.
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* Write parallel code that will run unchanged on everything from multicore
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workstations to supercomputers.
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* Full integration with Message Passing libraries (MPI).
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* Capabilities based security model with full encryption of network connections.
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* Share live parallel jobs with other users securely. We call this
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collaborative parallel computing.
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* Dynamically load balanced task farming system.
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* Robust error handling. Python exceptions raised in parallel execution are
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gathered and presented to the top-level code.
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For more information, see our :ref:`overview <parallel_index>` of using IPython
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for parallel computing.
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Portability and Python requirements
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-----------------------------------
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As of the 0.11 release, IPython works with Python 2.6 and 2.7. Versions 0.9 and
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0.10 worked with Python 2.4 and above. IPython now also supports Python 3,
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although for now the code for this is separate, and kept up to date with the
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main IPython repository. In the future, these will converge to a single codebase
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which can be automatically translated using 2to3.
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IPython is known to work on the following operating systems:
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* Linux
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* Most other Unix-like OSs (AIX, Solaris, BSD, etc.)
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* Mac OS X
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* Windows (CygWin, XP, Vista, etc.)
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See :ref:`here <install_index>` for instructions on how to install IPython.
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