parallel_details.txt
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r3663 | .. _parallel_details: | ||
| ========================================== | ||||
| Details of Parallel Computing with IPython | ||||
| ========================================== | ||||
| .. note:: | ||||
|
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r4109 | There are still many sections to fill out in this doc | ||
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r3663 | |||
| Caveats | ||||
| ======= | ||||
| First, some caveats about the detailed workings of parallel computing with 0MQ and IPython. | ||||
| Non-copying sends and numpy arrays | ||||
| ---------------------------------- | ||||
| When numpy arrays are passed as arguments to apply or via data-movement methods, they are not | ||||
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MinRK
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r3664 | copied. This means that you must be careful if you are sending an array that you intend to work | ||
| on. PyZMQ does allow you to track when a message has been sent so you can know when it is safe | ||||
| to edit the buffer, but IPython only allows for this. | ||||
|
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r3663 | |||
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r3664 | It is also important to note that the non-copying receive of a message is *read-only*. That | ||
| means that if you intend to work in-place on an array that you have sent or received, you must | ||||
| copy it. This is true for both numpy arrays sent to engines and numpy arrays retrieved as | ||||
| results. | ||||
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r3663 | |||
| The following will fail: | ||||
| .. sourcecode:: ipython | ||||
| In [3]: A = numpy.zeros(2) | ||||
| In [4]: def setter(a): | ||||
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r7470 | ...: a[0]=1 | ||
| ...: return a | ||||
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r3663 | |||
| In [5]: rc[0].apply_sync(setter, A) | ||||
| --------------------------------------------------------------------------- | ||||
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r7470 | RuntimeError Traceback (most recent call last)<string> in <module>() | ||
| <ipython-input-12-c3e7afeb3075> in setter(a) | ||||
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r3663 | RuntimeError: array is not writeable | ||
| If you do need to edit the array in-place, just remember to copy the array if it's read-only. | ||||
| The :attr:`ndarray.flags.writeable` flag will tell you if you can write to an array. | ||||
| .. sourcecode:: ipython | ||||
| In [3]: A = numpy.zeros(2) | ||||
| In [4]: def setter(a): | ||||
| ...: """only copy read-only arrays""" | ||||
| ...: if not a.flags.writeable: | ||||
| ...: a=a.copy() | ||||
| ...: a[0]=1 | ||||
| ...: return a | ||||
| In [5]: rc[0].apply_sync(setter, A) | ||||
| Out[5]: array([ 1., 0.]) | ||||
| # note that results will also be read-only: | ||||
| In [6]: _.flags.writeable | ||||
| Out[6]: False | ||||
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r4109 | If you want to safely edit an array in-place after *sending* it, you must use the `track=True` | ||
| flag. IPython always performs non-copying sends of arrays, which return immediately. You must | ||||
| instruct IPython track those messages *at send time* in order to know for sure that the send has | ||||
| completed. AsyncResults have a :attr:`sent` property, and :meth:`wait_on_send` method for | ||||
| checking and waiting for 0MQ to finish with a buffer. | ||||
|
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r3664 | |||
| .. sourcecode:: ipython | ||||
| In [5]: A = numpy.random.random((1024,1024)) | ||||
| In [6]: view.track=True | ||||
| In [7]: ar = view.apply_async(lambda x: 2*x, A) | ||||
| In [8]: ar.sent | ||||
| Out[8]: False | ||||
| In [9]: ar.wait_on_send() # blocks until sent is True | ||||
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r3663 | What is sendable? | ||
| ----------------- | ||||
| If IPython doesn't know what to do with an object, it will pickle it. There is a short list of | ||||
| objects that are not pickled: ``buffers``, ``str/bytes`` objects, and ``numpy`` | ||||
| arrays. These are handled specially by IPython in order to prevent the copying of data. Sending | ||||
| bytes or numpy arrays will result in exactly zero in-memory copies of your data (unless the data | ||||
| is very small). | ||||
| If you have an object that provides a Python buffer interface, then you can always send that | ||||
| buffer without copying - and reconstruct the object on the other side in your own code. It is | ||||
| possible that the object reconstruction will become extensible, so you can add your own | ||||
| non-copying types, but this does not yet exist. | ||||
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r3664 | Closures | ||
| ******** | ||||
| Just about anything in Python is pickleable. The one notable exception is objects (generally | ||||
| functions) with *closures*. Closures can be a complicated topic, but the basic principal is that | ||||
| functions that refer to variables in their parent scope have closures. | ||||
| An example of a function that uses a closure: | ||||
| .. sourcecode:: python | ||||
| def f(a): | ||||
| def inner(): | ||||
| # inner will have a closure | ||||
| return a | ||||
Maxim Grechkin
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r10396 | return inner | ||
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r3664 | |||
| f1 = f(1) | ||||
| f2 = f(2) | ||||
| f1() # returns 1 | ||||
| f2() # returns 2 | ||||
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r4109 | ``f1`` and ``f2`` will have closures referring to the scope in which `inner` was defined, | ||
| because they use the variable 'a'. As a result, you would not be able to send ``f1`` or ``f2`` | ||||
| with IPython. Note that you *would* be able to send `f`. This is only true for interactively | ||||
| defined functions (as are often used in decorators), and only when there are variables used | ||||
| inside the inner function, that are defined in the outer function. If the names are *not* in the | ||||
| outer function, then there will not be a closure, and the generated function will look in | ||||
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r3664 | ``globals()`` for the name: | ||
| .. sourcecode:: python | ||||
| def g(b): | ||||
| # note that `b` is not referenced in inner's scope | ||||
| def inner(): | ||||
| # this inner will *not* have a closure | ||||
| return a | ||||
|
Maxim Grechkin
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r10396 | return inner | ||
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r3664 | g1 = g(1) | ||
| g2 = g(2) | ||||
| g1() # raises NameError on 'a' | ||||
| a=5 | ||||
| g2() # returns 5 | ||||
| `g1` and `g2` *will* be sendable with IPython, and will treat the engine's namespace as | ||||
John Zwinck
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r10916 | globals(). The :meth:`pull` method is implemented based on this principle. If we did not | ||
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r3664 | provide pull, you could implement it yourself with `apply`, by simply returning objects out | ||
| of the global namespace: | ||||
| .. sourcecode:: ipython | ||||
| In [10]: view.apply(lambda : a) | ||||
| # is equivalent to | ||||
| In [11]: view.pull('a') | ||||
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r3663 | |||
| Running Code | ||||
| ============ | ||||
| There are two principal units of execution in Python: strings of Python code (e.g. 'a=5'), | ||||
| and Python functions. IPython is designed around the use of functions via the core | ||||
| Client method, called `apply`. | ||||
| Apply | ||||
| ----- | ||||
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r4109 | The principal method of remote execution is :meth:`apply`, of | ||
| :class:`~IPython.parallel.client.view.View` objects. The Client provides the full execution and | ||||
| communication API for engines via its low-level :meth:`send_apply_message` method, which is used | ||||
| by all higher level methods of its Views. | ||||
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r3663 | |||
| f : function | ||||
| The fuction to be called remotely | ||||
| args : tuple/list | ||||
| The positional arguments passed to `f` | ||||
| kwargs : dict | ||||
| The keyword arguments passed to `f` | ||||
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r3666 | |||
| flags for all views: | ||||
| block : bool (default: view.block) | ||||
|
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r3663 | Whether to wait for the result, or return immediately. | ||
| False: | ||||
| returns AsyncResult | ||||
| True: | ||||
| returns actual result(s) of f(*args, **kwargs) | ||||
| if multiple targets: | ||||
| list of results, matching `targets` | ||||
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r3666 | track : bool [default view.track] | ||
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r3663 | whether to track non-copying sends. | ||
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r3666 | targets : int,list of ints, 'all', None [default view.targets] | ||
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r3663 | Specify the destination of the job. | ||
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r3666 | if 'all' or None: | ||
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r3663 | Run on all active engines | ||
| if list: | ||||
| Run on each specified engine | ||||
| if int: | ||||
| Run on single engine | ||||
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r3666 | Note that LoadBalancedView uses targets to restrict possible destinations. LoadBalanced calls | ||
| will always execute in just one location. | ||||
| flags only in LoadBalancedViews: | ||||
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r3663 | after : Dependency or collection of msg_ids | ||
| Only for load-balanced execution (targets=None) | ||||
| Specify a list of msg_ids as a time-based dependency. | ||||
| This job will only be run *after* the dependencies | ||||
| have been met. | ||||
| follow : Dependency or collection of msg_ids | ||||
| Only for load-balanced execution (targets=None) | ||||
| Specify a list of msg_ids as a location-based dependency. | ||||
| This job will only be run on an engine where this dependency | ||||
| is met. | ||||
| timeout : float/int or None | ||||
| Only for load-balanced execution (targets=None) | ||||
| Specify an amount of time (in seconds) for the scheduler to | ||||
| wait for dependencies to be met before failing with a | ||||
| DependencyTimeout. | ||||
| execute and run | ||||
| --------------- | ||||
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r4109 | For executing strings of Python code, :class:`DirectView` 's also provide an :meth:`execute` and | ||
| a :meth:`run` method, which rather than take functions and arguments, take simple strings. | ||||
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r3664 | `execute` simply takes a string of Python code to execute, and sends it to the Engine(s). `run` | ||
| is the same as `execute`, but for a *file*, rather than a string. It is simply a wrapper that | ||||
| does something very similar to ``execute(open(f).read())``. | ||||
|
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r3663 | |||
| .. note:: | ||||
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r4109 | TODO: Examples for execute and run | ||
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r3663 | |||
| Views | ||||
| ===== | ||||
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r4109 | The principal extension of the :class:`~parallel.Client` is the :class:`~parallel.View` | ||
| class. The client is typically a singleton for connecting to a cluster, and presents a | ||||
| low-level interface to the Hub and Engines. Most real usage will involve creating one or more | ||||
| :class:`~parallel.View` objects for working with engines in various ways. | ||||
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r3663 | |||
| DirectView | ||||
| ---------- | ||||
| The :class:`.DirectView` is the class for the IPython :ref:`Multiplexing Interface | ||||
| <parallel_multiengine>`. | ||||
| Creating a DirectView | ||||
| ********************* | ||||
| DirectViews can be created in two ways, by index access to a client, or by a client's | ||||
| :meth:`view` method. Index access to a Client works in a few ways. First, you can create | ||||
| DirectViews to single engines simply by accessing the client by engine id: | ||||
| .. sourcecode:: ipython | ||||
| In [2]: rc[0] | ||||
| Out[2]: <DirectView 0> | ||||
| You can also create a DirectView with a list of engines: | ||||
| .. sourcecode:: ipython | ||||
| In [2]: rc[0,1,2] | ||||
| Out[2]: <DirectView [0,1,2]> | ||||
| Other methods for accessing elements, such as slicing and negative indexing, work by passing | ||||
| the index directly to the client's :attr:`ids` list, so: | ||||
| .. sourcecode:: ipython | ||||
| # negative index | ||||
| In [2]: rc[-1] | ||||
| Out[2]: <DirectView 3> | ||||
| # or slicing: | ||||
| In [3]: rc[::2] | ||||
| Out[3]: <DirectView [0,2]> | ||||
| are always the same as: | ||||
| .. sourcecode:: ipython | ||||
| In [2]: rc[rc.ids[-1]] | ||||
| Out[2]: <DirectView 3> | ||||
| In [3]: rc[rc.ids[::2]] | ||||
| Out[3]: <DirectView [0,2]> | ||||
| Also note that the slice is evaluated at the time of construction of the DirectView, so the | ||||
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r3666 | targets will not change over time if engines are added/removed from the cluster. | ||
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r3663 | |||
| Execution via DirectView | ||||
| ************************ | ||||
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r3666 | The DirectView is the simplest way to work with one or more engines directly (hence the name). | ||
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r3663 | |||
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r4109 | For instance, to get the process ID of all your engines: | ||
| .. sourcecode:: ipython | ||||
| In [5]: import os | ||||
| In [6]: dview.apply_sync(os.getpid) | ||||
| Out[6]: [1354, 1356, 1358, 1360] | ||||
| Or to see the hostname of the machine they are on: | ||||
| .. sourcecode:: ipython | ||||
| In [5]: import socket | ||||
| In [6]: dview.apply_sync(socket.gethostname) | ||||
| Out[6]: ['tesla', 'tesla', 'edison', 'edison', 'edison'] | ||||
| .. note:: | ||||
| TODO: expand on direct execution | ||||
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MinRK
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r3663 | |||
| Data movement via DirectView | ||||
| **************************** | ||||
| Since a Python namespace is just a :class:`dict`, :class:`DirectView` objects provide | ||||
| dictionary-style access by key and methods such as :meth:`get` and | ||||
| :meth:`update` for convenience. This make the remote namespaces of the engines | ||||
| appear as a local dictionary. Underneath, these methods call :meth:`apply`: | ||||
| .. sourcecode:: ipython | ||||
| In [51]: dview['a']=['foo','bar'] | ||||
| In [52]: dview['a'] | ||||
| Out[52]: [ ['foo', 'bar'], ['foo', 'bar'], ['foo', 'bar'], ['foo', 'bar'] ] | ||||
| Scatter and gather | ||||
| ------------------ | ||||
| Sometimes it is useful to partition a sequence and push the partitions to | ||||
| different engines. In MPI language, this is know as scatter/gather and we | ||||
| follow that terminology. However, it is important to remember that in | ||||
| IPython's :class:`Client` class, :meth:`scatter` is from the | ||||
| interactive IPython session to the engines and :meth:`gather` is from the | ||||
| engines back to the interactive IPython session. For scatter/gather operations | ||||
| between engines, MPI should be used: | ||||
| .. sourcecode:: ipython | ||||
| In [58]: dview.scatter('a',range(16)) | ||||
| Out[58]: [None,None,None,None] | ||||
| In [59]: dview['a'] | ||||
| Out[59]: [ [0, 1, 2, 3], [4, 5, 6, 7], [8, 9, 10, 11], [12, 13, 14, 15] ] | ||||
| In [60]: dview.gather('a') | ||||
| Out[60]: [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15] | ||||
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r3666 | Push and pull | ||
| ------------- | ||||
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r4109 | :meth:`~IPython.parallel.client.view.DirectView.push` | ||
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r3666 | |||
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r4109 | :meth:`~IPython.parallel.client.view.DirectView.pull` | ||
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r3666 | |||
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r4109 | .. note:: | ||
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r3666 | |||
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r4109 | TODO: write this section | ||
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r3666 | |||
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r3663 | |||
| LoadBalancedView | ||||
| ---------------- | ||||
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r4109 | The :class:`~.LoadBalancedView` is the class for load-balanced execution via the task scheduler. | ||
| These views always run tasks on exactly one engine, but let the scheduler determine where that | ||||
| should be, allowing load-balancing of tasks. The LoadBalancedView does allow you to specify | ||||
| restrictions on where and when tasks can execute, for more complicated load-balanced workflows. | ||||
|
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r3663 | |||
| Data Movement | ||||
| ============= | ||||
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r4109 | Since the :class:`~.LoadBalancedView` does not know where execution will take place, explicit | ||
| data movement methods like push/pull and scatter/gather do not make sense, and are not provided. | ||||
|
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r3663 | |||
| Results | ||||
| ======= | ||||
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r3671 | AsyncResults | ||
| ------------ | ||||
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r3663 | |||
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r4109 | Our primary representation of the results of remote execution is the :class:`~.AsyncResult` | ||
| object, based on the object of the same name in the built-in :mod:`multiprocessing.pool` | ||||
| module. Our version provides a superset of that interface. | ||||
|
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r3663 | |||
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r3671 | 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 | ||
| AsyncResults when `block=False`. | ||||
| The mp.pool.AsyncResult interface | ||||
| --------------------------------- | ||||
| The basic interface of the AsyncResult is exactly that of the AsyncResult in :mod:`multiprocessing.pool`, and consists of four methods: | ||||
| .. AsyncResult spec directly from docs.python.org | ||||
| .. class:: AsyncResult | ||||
| The stdlib AsyncResult spec | ||||
| .. method:: wait([timeout]) | ||||
| Wait until the result is available or until *timeout* seconds pass. This | ||||
| method always returns ``None``. | ||||
| .. method:: ready() | ||||
| Return whether the call has completed. | ||||
| .. method:: successful() | ||||
| Return whether the call completed without raising an exception. Will | ||||
| raise :exc:`AssertionError` if the result is not ready. | ||||
| .. method:: get([timeout]) | ||||
| Return the result when it arrives. If *timeout* is not ``None`` and the | ||||
| result does not arrive within *timeout* seconds then | ||||
| :exc:`TimeoutError` is raised. If the remote call raised | ||||
| an exception then that exception will be reraised as a :exc:`RemoteError` | ||||
| by :meth:`get`. | ||||
| While an AsyncResult is not done, you can check on it with its :meth:`ready` method, which will | ||||
| return whether the AR is done. You can also wait on an AsyncResult with its :meth:`wait` method. | ||||
| This method blocks until the result arrives. If you don't want to wait forever, you can pass a | ||||
| timeout (in seconds) as an argument to :meth:`wait`. :meth:`wait` will *always return None*, and | ||||
| should never raise an error. | ||||
| :meth:`ready` and :meth:`wait` are insensitive to the success or failure of the call. After a | ||||
| result is done, :meth:`successful` will tell you whether the call completed without raising an | ||||
| exception. | ||||
| If you actually want the result of the call, you can use :meth:`get`. Initially, :meth:`get` | ||||
| behaves just like :meth:`wait`, in that it will block until the result is ready, or until a | ||||
| timeout is met. However, unlike :meth:`wait`, :meth:`get` will raise a :exc:`TimeoutError` if | ||||
| the timeout is reached and the result is still not ready. If the result arrives before the | ||||
| timeout is reached, then :meth:`get` will return the result itself if no exception was raised, | ||||
| and will raise an exception if there was. | ||||
| Here is where we start to expand on the multiprocessing interface. Rather than raising the | ||||
| original exception, a RemoteError will be raised, encapsulating the remote exception with some | ||||
| metadata. If the AsyncResult represents multiple calls (e.g. any time `targets` is plural), then | ||||
| a CompositeError, a subclass of RemoteError, will be raised. | ||||
| .. seealso:: | ||||
| For more information on remote exceptions, see :ref:`the section in the Direct Interface | ||||
|
MinRK
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r4109 | <parallel_exceptions>`. | ||
|
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r3671 | |||
| Extended interface | ||||
| ****************** | ||||
| Other extensions of the AsyncResult interface include convenience wrappers for :meth:`get`. | ||||
| AsyncResults have a property, :attr:`result`, with the short alias :attr:`r`, which simply call | ||||
| :meth:`get`. Since our object is designed for representing *parallel* results, it is expected | ||||
| that many calls (any of those submitted via DirectView) will map results to engine IDs. We | ||||
| provide a :meth:`get_dict`, which is also a wrapper on :meth:`get`, which returns a dictionary | ||||
| of the individual results, keyed by engine ID. | ||||
|
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r4109 | 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. | ||||
|
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r3671 | |||
| The larger extension of the AsyncResult API is the :attr:`metadata` attribute. The metadata | ||||
| is a dictionary (with attribute access) that contains, logically enough, metadata about the | ||||
| execution. | ||||
| Metadata keys: | ||||
| timestamps | ||||
| submitted | ||||
| When the task left the Client | ||||
| started | ||||
| When the task started execution on the engine | ||||
| completed | ||||
| When execution finished on the engine | ||||
| received | ||||
| When the result arrived on the Client | ||||
| note that it is not known when the result arrived in 0MQ on the client, only when it | ||||
| arrived in Python via :meth:`Client.spin`, so in interactive use, this may not be | ||||
| strictly informative. | ||||
| Information about the engine | ||||
| engine_id | ||||
| The integer id | ||||
| engine_uuid | ||||
| The UUID of the engine | ||||
| output of the call | ||||
| pyerr | ||||
| Python exception, if there was one | ||||
| pyout | ||||
| Python output | ||||
| stderr | ||||
| stderr stream | ||||
| stdout | ||||
| stdout (e.g. print) stream | ||||
| And some extended information | ||||
| status | ||||
| either 'ok' or 'error' | ||||
| msg_id | ||||
| The UUID of the message | ||||
| after | ||||
| For tasks: the time-based msg_id dependencies | ||||
| follow | ||||
| For tasks: the location-based msg_id dependencies | ||||
| While in most cases, the Clients that submitted a request will be the ones using the results, | ||||
| other Clients can also request results directly from the Hub. This is done via the Client's | ||||
| :meth:`get_result` method. This method will *always* return an AsyncResult object. If the call | ||||
| was not submitted by the client, then it will be a subclass, called :class:`AsyncHubResult`. | ||||
| These behave in the same way as an AsyncResult, but if the result is not ready, waiting on an | ||||
| AsyncHubResult polls the Hub, which is much more expensive than the passive polling used | ||||
| in regular AsyncResults. | ||||
| The Client keeps track of all results | ||||
| history, results, metadata | ||||
|
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r3663 | |||
| Querying the Hub | ||||
| ================ | ||||
| The Hub sees all traffic that may pass through the schedulers between engines and clients. | ||||
| It does this so that it can track state, allowing multiple clients to retrieve results of | ||||
| computations submitted by their peers, as well as persisting the state to a database. | ||||
| queue_status | ||||
| You can check the status of the queues of the engines with this command. | ||||
| result_status | ||||
|
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r3671 | check on results | ||
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r3663 | purge_results | ||
|
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r3671 | forget results (conserve resources) | ||
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r3663 | Controlling the Engines | ||
| ======================= | ||||
| There are a few actions you can do with Engines that do not involve execution. These | ||||
| messages are sent via the Control socket, and bypass any long queues of waiting execution | ||||
| jobs | ||||
| abort | ||||
| Sometimes you may want to prevent a job you have submitted from actually running. The method | ||||
| for this is :meth:`abort`. It takes a container of msg_ids, and instructs the Engines to not | ||||
| run the jobs if they arrive. The jobs will then fail with an AbortedTask error. | ||||
| clear | ||||
| You may want to purge the Engine(s) namespace of any data you have left in it. After | ||||
| running `clear`, there will be no names in the Engine's namespace | ||||
| shutdown | ||||
| You can also instruct engines (and the Controller) to terminate from a Client. This | ||||
| can be useful when a job is finished, since you can shutdown all the processes with a | ||||
| single command. | ||||
| Synchronization | ||||
| =============== | ||||
| Since the Client is a synchronous object, events do not automatically trigger in your | ||||
| interactive session - you must poll the 0MQ sockets for incoming messages. Note that | ||||
| this polling *does not* actually make any network requests. It simply performs a `select` | ||||
| operation, to check if messages are already in local memory, waiting to be handled. | ||||
|
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r3664 | The method that handles incoming messages is :meth:`spin`. This method flushes any waiting | ||
| messages on the various incoming sockets, and updates the state of the Client. | ||||
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r3664 | If you need to wait for particular results to finish, you can use the :meth:`wait` method, | ||
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r3663 | which will call :meth:`spin` until the messages are no longer outstanding. Anything that | ||
| represents a collection of messages, such as a list of msg_ids or one or more AsyncResult | ||||
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r3664 | objects, can be passed as argument to wait. A timeout can be specified, which will prevent | ||
| the call from blocking for more than a specified time, but the default behavior is to wait | ||||
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r3663 | forever. | ||
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r4109 | The client also has an ``outstanding`` attribute - a ``set`` of msg_ids that are awaiting | ||
| replies. This is the default if wait is called with no arguments - i.e. wait on *all* | ||||
| outstanding messages. | ||||
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| .. note:: | ||||
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r3664 | TODO wait example | ||
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| Map | ||||
| === | ||||
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r4109 | Many parallel computing problems can be expressed as a ``map``, or running a single program with | ||
| a variety of different inputs. Python has a built-in :py:func:`map`, which does exactly this, | ||||
| and many parallel execution tools in Python, such as the built-in | ||||
| :py:class:`multiprocessing.Pool` object provide implementations of `map`. All View objects | ||||
| provide a :meth:`map` method as well, but the load-balanced and direct implementations differ. | ||||
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r3663 | |||
| Views' map methods can be called on any number of sequences, but they can also take the `block` | ||||
| and `bound` keyword arguments, just like :meth:`~client.apply`, but *only as keywords*. | ||||
| .. sourcecode:: python | ||||
| dview.map(*sequences, block=None) | ||||
| * iter, map_async, reduce | ||||
| Decorators and RemoteFunctions | ||||
| ============================== | ||||
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r4109 | .. note:: | ||
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r4109 | TODO: write this section | ||
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r4109 | :func:`~IPython.parallel.client.remotefunction.@parallel` | ||
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r4109 | :func:`~IPython.parallel.client.remotefunction.@remote` | ||
| :class:`~IPython.parallel.client.remotefunction.RemoteFunction` | ||||
| :class:`~IPython.parallel.client.remotefunction.ParallelFunction` | ||||
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| Dependencies | ||||
| ============ | ||||
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r4109 | .. note:: | ||
| TODO: write this section | ||||
| :func:`~IPython.parallel.controller.dependency.@depend` | ||||
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r4109 | :func:`~IPython.parallel.controller.dependency.@require` | ||
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r4109 | :class:`~IPython.parallel.controller.dependency.Dependency` | ||