upstream/ipython Commit - r3671:24641d17

move old parallel figures into newparallel dir

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docs/source/parallelz/asian_call.pdf

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docs/source/parallelz/parallel_demos.txt

0 +4 -4

             approximately 1,000 times, but that with only 10,000 digits the
             statistical fluctuations are still rather large:
-            .. image:: ../parallel/single_digits.*
+            .. image:: single_digits.*
             It is clear that to reduce the relative fluctuations in the counts, we need
             to look at many more digits of pi. That brings us to the parallel calculation.
             show that the relative size of the statistical fluctuations have decreased
             compared to the 10,000 digit calculation.
-            .. image:: ../parallel/two_digit_counts.*
+            .. image:: two_digit_counts.*
             Parallel options pricing
             took 30 seconds in parallel, giving a speedup of 7.7x, which is comparable
             to the speedup observed in our previous example.
-            .. image:: ../parallel/asian_call.*
+            .. image:: asian_call.*
-            .. image:: ../parallel/asian_put.*
+            .. image:: asian_put.*
             Conclusion
             ==========

docs/source/parallelz/parallel_details.txt

0 +147 -3

@@ -363,11 +363,151 b' Reference'
363	Results	363	Results
364	=======	364	=======
365		365
366	AsyncResults are the primary class	366	AsyncResults
		367	------------
367		368
368	get_result	369	Our primary representation is the AsyncResult object, based on the object of the same name in
		370	the built-in :mod:`multiprocessing.pool` module. Our version provides a superset of that
		371	interface.
369		372
370	results, metadata	373	The basic principle of the AsyncResult is the encapsulation of one or more results not yet completed. Execution methods (including data movement, such as push/pull) will all return
		374	AsyncResults when `block=False`.
		375
		376	The mp.pool.AsyncResult interface
		377	---------------------------------
		378
		379	The basic interface of the AsyncResult is exactly that of the AsyncResult in :mod:`multiprocessing.pool`, and consists of four methods:
		380
		381	.. AsyncResult spec directly from docs.python.org
		382
		383	.. class:: AsyncResult
		384
		385	The stdlib AsyncResult spec
		386
		387	.. method:: wait([timeout])
		388
		389	Wait until the result is available or until timeout seconds pass. This
		390	method always returns ``None``.
		391
		392	.. method:: ready()
		393
		394	Return whether the call has completed.
		395
		396	.. method:: successful()
		397
		398	Return whether the call completed without raising an exception. Will
		399	raise :exc:`AssertionError` if the result is not ready.
		400
		401	.. method:: get([timeout])
		402
		403	Return the result when it arrives. If timeout is not ``None`` and the
		404	result does not arrive within timeout seconds then
		405	:exc:`TimeoutError` is raised. If the remote call raised
		406	an exception then that exception will be reraised as a :exc:`RemoteError`
		407	by :meth:`get`.
		408
		409
		410	While an AsyncResult is not done, you can check on it with its :meth:`ready` method, which will
		411	return whether the AR is done. You can also wait on an AsyncResult with its :meth:`wait` method.
		412	This method blocks until the result arrives. If you don't want to wait forever, you can pass a
		413	timeout (in seconds) as an argument to :meth:`wait`. :meth:`wait` will always return None, and
		414	should never raise an error.
		415
		416	:meth:`ready` and :meth:`wait` are insensitive to the success or failure of the call. After a
		417	result is done, :meth:`successful` will tell you whether the call completed without raising an
		418	exception.
		419
		420	If you actually want the result of the call, you can use :meth:`get`. Initially, :meth:`get`
		421	behaves just like :meth:`wait`, in that it will block until the result is ready, or until a
		422	timeout is met. However, unlike :meth:`wait`, :meth:`get` will raise a :exc:`TimeoutError` if
		423	the timeout is reached and the result is still not ready. If the result arrives before the
		424	timeout is reached, then :meth:`get` will return the result itself if no exception was raised,
		425	and will raise an exception if there was.
		426
		427	Here is where we start to expand on the multiprocessing interface. Rather than raising the
		428	original exception, a RemoteError will be raised, encapsulating the remote exception with some
		429	metadata. If the AsyncResult represents multiple calls (e.g. any time `targets` is plural), then
		430	a CompositeError, a subclass of RemoteError, will be raised.
		431
		432	.. seealso::
		433
		434	For more information on remote exceptions, see :ref:`the section in the Direct Interface
		435	<Parallel_exceptions>`.
		436
		437	Extended interface
		438	******************
		439
		440
		441	Other extensions of the AsyncResult interface include convenience wrappers for :meth:`get`.
		442	AsyncResults have a property, :attr:`result`, with the short alias :attr:`r`, which simply call
		443	:meth:`get`. Since our object is designed for representing parallel results, it is expected
		444	that many calls (any of those submitted via DirectView) will map results to engine IDs. We
		445	provide a :meth:`get_dict`, which is also a wrapper on :meth:`get`, which returns a dictionary
		446	of the individual results, keyed by engine ID.
		447
		448	You can also prevent a submitted job from actually executing, via the AsyncResult's :meth:`abort` method. This will instruct engines to not execute the job when it arrives.
		449
		450	The larger extension of the AsyncResult API is the :attr:`metadata` attribute. The metadata
		451	is a dictionary (with attribute access) that contains, logically enough, metadata about the
		452	execution.
		453
		454	Metadata keys:
		455
		456	timestamps
		457
		458	submitted
		459	When the task left the Client
		460	started
		461	When the task started execution on the engine
		462	completed
		463	When execution finished on the engine
		464	received
		465	When the result arrived on the Client
		466
		467	note that it is not known when the result arrived in 0MQ on the client, only when it
		468	arrived in Python via :meth:`Client.spin`, so in interactive use, this may not be
		469	strictly informative.
		470
		471	Information about the engine
		472
		473	engine_id
		474	The integer id
		475	engine_uuid
		476	The UUID of the engine
		477
		478	output of the call
		479
		480	pyerr
		481	Python exception, if there was one
		482	pyout
		483	Python output
		484	stderr
		485	stderr stream
		486	stdout
		487	stdout (e.g. print) stream
		488
		489	And some extended information
		490
		491	status
		492	either 'ok' or 'error'
		493	msg_id
		494	The UUID of the message
		495	after
		496	For tasks: the time-based msg_id dependencies
		497	follow
		498	For tasks: the location-based msg_id dependencies
		499
		500	While in most cases, the Clients that submitted a request will be the ones using the results,
		501	other Clients can also request results directly from the Hub. This is done via the Client's
		502	:meth:`get_result` method. This method will always return an AsyncResult object. If the call
		503	was not submitted by the client, then it will be a subclass, called :class:`AsyncHubResult`.
		504	These behave in the same way as an AsyncResult, but if the result is not ready, waiting on an
		505	AsyncHubResult polls the Hub, which is much more expensive than the passive polling used
		506	in regular AsyncResults.
		507
		508
		509	The Client keeps track of all results
		510	history, results, metadata
371		511
372	Querying the Hub	512	Querying the Hub
373	================	513	================
@@ -382,8 +522,12 b' queue_status'
382		522
383	result_status	523	result_status
384		524
		525	check on results
		526
385	purge_results	527	purge_results
386		528
		529	forget results (conserve resources)
		530
387	Controlling the Engines	531	Controlling the Engines
388	=======================	532	=======================
389		533

docs/source/parallelz/parallel_transition.txt

0 +6 -16

             The result of a non-blocking call to `apply` is now an AsyncResult_ object, described below.
-            MultiEngine
+            MultiEngine to DirectView
-            ===========
+            =========================
             The multiplexing interface previously provided by the MultiEngineClient is now provided by the
             DirectView. Once you have a Client connected, you can create a DirectView with index-access
             to use stdout as your results, due to stream decoupling and the asynchronous nature of how the
             stdout streams are handled in the new system.
-            Task
+            Task to LoadBalancedView
-            ====
+            ========================
             Load-Balancing has changed more than Multiplexing.  This is because there is no longer a notion
             of a StringTask or a MapTask, there are simply Python functions to call.  Tasks are now
                 LoadBalancedView.
-            .. _AsyncResult:
-            PendingResults
+            There are still some things that behave the same as IPython.kernel:
-            ==============
-            Since we no longer use Twisted, we also lose the use of Deferred objects. The results of
-            non-blocking calls were represented as PendingDeferred or PendingResult objects. The object used
-            for this in the new code is an AsyncResult object. The AsyncResult object is based on the object
-            of the same name in the built-in :py-mod:`multiprocessing.pool` module. Our version provides a
-            superset of that interface.
-            Some things that behave the same:
             .. sourcecode:: ipython
                 Out[6]: [5, 5]
                 # new
-                In [5]: ar = rc[0,1].pull('a', block=False)
+                In [5]: ar = dview.pull('a', targets=[0,1], block=False)
                 In [6]: ar.r
                 Out[6]: [5, 5]

docs/source/parallelz/parallel_winhpc.txt

0 +8 -11

             scientific computing on Windows. The following dependencies are needed to run
             IPython on Windows:
-            * Python 2.5 or 2.6 (http://www.python.org)
+            * Python 2.6 or 2.7 (http://www.python.org)
             * pywin32 (http://sourceforge.net/projects/pywin32/)
             * PyReadline (https://launchpad.net/pyreadline)
-            * zope.interface and Twisted (http://twistedmatrix.com)
+            * pyzmq (http://github.com/zeromq/pyzmq/downloads)
-            * Foolcap (http://foolscap.lothar.com/trac)
-            * pyOpenSSL (https://launchpad.net/pyopenssl)
             * IPython (http://ipython.scipy.org)
             In addition, the following dependencies are needed to run the demos described
             in this document.
             * NumPy and SciPy (http://www.scipy.org)
-            * wxPython (http://www.wxpython.org)
             * Matplotlib (http://matplotlib.sourceforge.net/)
             The easiest way of obtaining these dependencies is through the Enthought
 . Install all of the packages listed above, either individually or using EPD
                on the head node, compute nodes and user workstations.
-. Make sure that :file:`C:\\Python25` and :file:`C:\\Python25\\Scripts` are
+. Make sure that :file:`C:\\Python27` and :file:`C:\\Python27\\Scripts` are
                in the system :envvar:`%PATH%` variable on each node.
 . Install the latest development version of IPython. This can be done by
             start IPython's interactive shell and you should see something like the
             following screenshot:
-            .. image:: ../parallel/ipython_shell.*
+            .. image:: ipython_shell.*
             Starting an IPython cluster
             ===========================
             "IPython cluster: started". The result should look something like the following
             screenshot:
-            .. image:: ../parallel/ipcluster_start.*
+            .. image:: ipcluster_start.*
             At this point, the controller and two engines are running on your local host.
             This configuration is useful for testing and for situations where you want to
             :command:`ipclusterz` prints out the location of the newly created cluster
             directory.
-            .. image:: ../parallel/ipcluster_create.*
+            .. image:: ipcluster_create.*
             Configuring a cluster profile
             -----------------------------
             following screenshot shows what the HPC Job Manager interface looks like
             with a running IPython cluster.
-            .. image:: ../parallel/hpc_job_manager.*
+            .. image:: hpc_job_manager.*
             Performing a simple interactive parallel computation
             ====================================================
             function, but runs the calculation in parallel. More involved examples of using
             :class:`MultiEngineClient` are provided in the examples that follow.
-            .. image:: ../parallel/mec_simple.*
+            .. image:: mec_simple.*

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