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added py4science demos as examples + NetworkX DAG dependencies

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ipython_qt.txt
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.. _ipython_qt:
====================
IPython Qt interface
====================
Abstract
--------
This is about the implementation of a Qt-based Graphical User Interface (GUI)
to execute Python code with an interpreter that runs in a separate process and
the two systems (GUI frontend and interpreter kernel) communicating via the
ZeroMQ Messaging library. The bulk of the implementation will be done without
dependencies on IPython (only on Zmq). Once the key features are ready,
IPython-specific features can be added using the IPython codebase.
Project details
---------------
For a long time there has been demand for a graphical user interface for
IPython, and the project already ships Wx-based prototypes thereof. But these
run all code in a single process, making them extremely brittle, as a crash of
the Python interpreter kills the entire user session. Here I propose to build
a Qt-based GUI that will communicate with a separate process for the code
execution, so that if the interpreter kernel dies, the frontend can continue to
function after restarting a new kernel (and offering the user the option to
re-execute all inputs, which the frontend can know).
This GUI will allow for the easy editing of multi-line input and the convenient
re-editing of previous blocks of input, which can be displayed in a 2-d
workspace instead of a line-driven one like today's IPython. This makes it much
easier to incrementally build and tune a code, by combining the rapid feedback
cycle of IPython with the ability to edit multiline code with good graphical
support.
2-process model pyzmq base
~~~~~~~~~~~~~~~~~~~~~~~~~~
Since the necessity of a user to keep his data safe, the design is based in a
2-process model that will be achieved with a simple client/server system with
`pyzmq <http://www.zeromq.org/bindings:python>`_, so the GUI session do not
crash if the the kernel process does. This will be achieved using this test
`code
<http://github.com/fperez/pyzmq/blob/completer/examples/kernel/kernel.py>`_ and
customizing it to the necessities of the GUI such as queue management with
discrimination for different frontends connected to the same kernel and tab
completion. A piece of drafted code for the kernel (server) should look like
this::
def main():
c = zmq.Context(1, 1)
rep_conn = connection % port_base
pub_conn = connection % (port_base+1)
print >>sys.__stdout__, "Starting the kernel..."
print >>sys.__stdout__, "On:",rep_conn, pub_conn
session = Session(username=u'kernel')
reply_socket = c.socket(zmq.XREP)
reply_socket.bind(rep_conn)
pub_socket = c.socket(zmq.PUB)
pub_socket.bind(pub_conn)
stdout = OutStream(session, pub_socket, u'stdout')
stderr = OutStream(session, pub_socket, u'stderr')
sys.stdout = stdout
sys.stderr = stderr
display_hook = DisplayHook(session, pub_socket)
sys.displayhook = display_hook
kernel = Kernel(session, reply_socket, pub_socket)
This kernel will use two queues (output and input), the input queue will have
the id of the process(frontend) making the request, type(execute, complete,
help, etc) and id of the request itself and the string of code to be executed,
the output queue will have basically the same information just that the string
is the to be displayed. This model is because the kernel needs to maintain
control of timeouts when multiple requests are sent and keep them indexed.
Qt based GUI
~~~~~~~~~~~~
Design of the interface is going to be based in cells of code executed on the
previous defined kernel. It will also have GUI facilities such toolboxes,
tooltips to autocomplete code and function summary, highlighting and
autoindentation. It will have the cell kind of multiline edition mode so each
block of code can be edited and executed independently, this can be achieved
queuing QTextEdit objects (the cell) giving them format so we can discriminate
outputs from inputs. One of the main characteristics will be the debug support
that will show the requested outputs as the debugger (that will be on a popup
widget) "walks" through the code, this design is to be reviewed with the
mentor. `This <http://gfif.udea.edu.co/IPythonQt_snapshot.png>`_ is a
tentative view of the main window.
The GUI will check continuously the output queue from the kernel for new
information to handle. This information have to be handled with care since any
output will come at anytime and possibly in a different order than requested or
maybe not appear at all, this could be possible due to a variety of reasons(for
example tab completion request while the kernel is busy processing another
frontend's request). This is, if the kernel is busy it won't be possible to
fulfill the request for a while so the GUI will be prepared to abandon waiting
for the reply if the user moves on or a certain timeout expires.
POSSIBLE FUTURE DIRECTIONS
---------------------------
The near future will bring the feature of saving and loading sessions, also
importing and exporting to different formats like rst, html, pdf and
python/ipython code, a discussion about this is taking place in the ipython-dev
mailing list. Also the interaction with a remote kernel and distributed
computation which is an IPython's project already in development.
The idea of a mathematica-like help widget (i.e. there will be parts of it that
will execute as a native session of IPythonQt) is still to be discussed in the
development mailing list but it's definitively a great idea.