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======================
The AsyncResult object
======================
In non-blocking mode, :meth:`apply` submits the command to be executed and
then returns a :class:`~.AsyncResult` object immediately. The
AsyncResult object gives you a way of getting a result at a later
time through its :meth:`get` method, but it also collects metadata
on execution.
Beyond multiprocessing's AsyncResult
====================================
.. Note::
The :class:`~.AsyncResult` object provides a superset of the interface in
:py:class:`multiprocessing.pool.AsyncResult`. See the
`official Python documentation <http://docs.python.org/library/multiprocessing#multiprocessing.pool.AsyncResult>`_
for more on the basics of this interface.
Our AsyncResult objects add a number of convenient features for working with
parallel results, beyond what is provided by the original AsyncResult.
get_dict
--------
First, is :meth:`.AsyncResult.get_dict`, which pulls results as a dictionary
keyed by engine_id, rather than a flat list. This is useful for quickly
coordinating or distributing information about all of the engines.
As an example, here is a quick call that gives every engine a dict showing
the PID of every other engine:
.. sourcecode:: ipython
In [10]: ar = rc[:].apply_async(os.getpid)
In [11]: pids = ar.get_dict()
In [12]: rc[:]['pid_map'] = pids
This trick is particularly useful when setting up inter-engine communication,
as in IPython's :file:`examples/parallel/interengine` examples.
Metadata
========
IPython.parallel tracks some metadata about the tasks, which is stored
in the :attr:`.Client.metadata` dict. The AsyncResult object gives you an
interface for this information as well, including timestamps stdout/err,
and engine IDs.
Timing
------
IPython tracks various timestamps as :py:class:`.datetime` objects,
and the AsyncResult object has a few properties that turn these into useful
times (in seconds as floats).
For use while the tasks are still pending:
* :attr:`ar.elapsed` is just the elapsed seconds since submission, for use
before the AsyncResult is complete.
* :attr:`ar.progress` is the number of tasks that have completed. Fractional progress
would be::
1.0 * ar.progress / len(ar)
* :meth:`AsyncResult.wait_interactive` will wait for the result to finish, but
print out status updates on progress and elapsed time while it waits.
For use after the tasks are done:
* :attr:`ar.serial_time` is the sum of the computation time of all of the tasks
done in parallel.
* :attr:`ar.wall_time` is the time between the first task submitted and last result
received. This is the actual cost of computation, including IPython overhead.
.. note::
wall_time is only precise if the Client is waiting for results when
the task finished, because the `received` timestamp is made when the result is
unpacked by the Client, triggered by the :meth:`~Client.spin` call. If you
are doing work in the Client, and not waiting/spinning, then `received` might
be artificially high.
An often interesting metric is the time it actually cost to do the work in parallel
relative to the serial computation, and this can be given simply with
.. sourcecode:: python
speedup = ar.serial_time / ar.wall_time
Map results are iterable!
=========================
When an AsyncResult object has multiple results (e.g. the :class:`~AsyncMapResult`
MinRK
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r7480 object), you can actually iterate through results themselves, and act on them as they arrive:
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Thomas Kluyver
Fix example inclusions in docs
r16160 .. literalinclude:: ../../../examples/Parallel Computing/itermapresult.py
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timo
a line from the itermapresult.py file was missing
r7071 :lines: 20-67
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That is to say, if you treat an AsyncMapResult as if it were a list of your actual
results, it should behave as you would expect, with the only difference being
that you can start iterating through the results before they have even been computed.
This lets you do a dumb version of map/reduce with the builtin Python functions,
and the only difference between doing this locally and doing it remotely in parallel
is using the asynchronous view.map instead of the builtin map.
Here is a simple one-line RMS (root-mean-square) implemented with Python's builtin map/reduce.
.. sourcecode:: ipython
In [38]: X = np.linspace(0,100)
In [39]: from math import sqrt
In [40]: add = lambda a,b: a+b
In [41]: sq = lambda x: x*x
In [42]: sqrt(reduce(add, map(sq, X)) / len(X))
Out[42]: 58.028845747399714
In [43]: sqrt(reduce(add, view.map(sq, X)) / len(X))
Out[43]: 58.028845747399714
To break that down:
1. ``map(sq, X)`` Compute the square of each element in the list (locally, or in parallel)
2. ``reduce(add, sqX) / len(X)`` compute the mean by summing over the list (or AsyncMapResult)
and dividing by the size
3. take the square root of the resulting number
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.. seealso::
When AsyncResult or the AsyncMapResult don't provide what you need (for instance,
handling individual results as they arrive, but with metadata), you can always
just split the original result's ``msg_ids`` attribute, and handle them as you like.
Paul Ivanov
change docs/examples refs to be just examples...
r11998 For an example of this, see :file:`examples/parallel/customresult.py`