Draft v2 after new `run_in_actor()` API

Revamp the docs after some feedback from @vodik. See #24 #25 for additional details.
2018-08-03 00:55:50 -04:00 · 2018-08-03 00:55:50 -04:00 · 99e2cf9a13
parent d4a6cbbc34
commit 99e2cf9a13
2 changed files with 216 additions and 175 deletions
--- a/README.rst
+++ b/README.rst
@ -1,36 +1,13 @@
 tractor
 =======
-A minimalist `actor model`_ built on multiprocessing_ and trio_.
+An async-native `actor model`_ built on trio_ and multiprocessing_.
 |travis|
 .. |travis| image:: https://img.shields.io/travis/tgoodlet/tractor/master.svg
    :target: https://travis-ci.org/tgoodlet/tractor
 ``tractor`` is an attempt to take trionic_ concurrency concepts and apply
 them to distributed-multicore Python.
 ``tractor`` lets you run and spawn Python *actors*: separate processes which are internally
 running a ``trio`` scheduler and task tree (also known as an `async sandwich`_).
 Actors communicate with each other by sending *messages* over channels_, but the details of this
 in ``tractor`` is by default hidden and *actors* can instead easily invoke remote asynchronous
 functions using *portals*.
 ``tractor``'s tenets non-comprehensively include:
 - no spawning of processes *willy-nilly*; causality_ is paramount!
 - `shared nothing architecture`_
 - remote errors `always propagate`_ back to the caller
 - verbatim support for ``trio``'s cancellation_ system
 - no use of *proxy* objects to wrap RPC calls
 - an immersive debugging experience
 - be simple, be small
 .. warning:: ``tractor`` is in alpha-alpha and is expected to change rapidly!
    Expect nothing to be set in stone and your ideas about where it should go
    to be greatly appreciated!
 .. _actor model: https://en.wikipedia.org/wiki/Actor_model
 .. _trio: https://github.com/python-trio/trio
 .. _multiprocessing: https://docs.python.org/3/library/multiprocessing.html
@ -41,6 +18,54 @@ functions using *portals*.
 .. _shared nothing architecture: https://en.wikipedia.org/wiki/Shared-nothing_architecture
 .. _cancellation: https://trio.readthedocs.io/en/latest/reference-core.html#cancellation-and-timeouts
 .. _channels: https://en.wikipedia.org/wiki/Channel_(programming)
 .. _chaos engineering: http://principlesofchaos.org/
 What's this? Spawning event loops in subprocesses?
 --------------------------------------------------
 Close, but not quite.
 ``tractor`` is an attempt to take trionic_ concurrency concepts and apply
 them to distributed multi-core Python.
 ``tractor`` lets you run and spawn *actors*: separate processes which run a ``trio``
 scheduler and task tree (also known as an `async sandwich`_).
 *Actors* communicate by sending messages_ over channels_ and avoid sharing any state.
 This `actor model`_ allows for highly distributed software architecture which works just as
 well on multiple cores as it does over many hosts.
 ``tractor`` takes much inspiration from pulsar_ and execnet_ but attempts to be much more
 focussed on sophistication of the lower level distributed architecture
 as well as have first class support for modern async Python.
 ``tractor`` does **not** use ``asyncio`` hence **no** event loops.
 The first step to grok ``tractor`` is to get the basics of ``trio``
 down. A great place to start is the `trio docs`_ and this `blog post`_
 by njsmith_.
 .. _messages: https://en.wikipedia.org/wiki/Message_passing
 .. _trio docs: https://trio.readthedocs.io/en/latest/
 .. _blog post: https://vorpus.org/blog/notes-on-structured-concurrency-or-go-statement-considered-harmful/
 .. _njsmith: https://github.com/njsmith/
 Philosophy
 ----------
 ``tractor``'s tenets non-comprehensively include:
 - no spawning of processes *willy-nilly*; causality_ is paramount!
 - `shared nothing architecture`_
 - remote errors `always propagate`_ back to the caller
 - verbatim support for ``trio``'s cancellation_ system
 - no use of *proxy* objects to wrap RPC calls
 - an immersive debugging experience
 - anti-fragility through `chaos engineering`_
 .. warning:: ``tractor`` is in alpha-alpha and is expected to change rapidly!
    Expect nothing to be set in stone. Your ideas about where it should go
    are greatly appreciated!
 .. _pulsar: http://quantmind.github.io/pulsar/design.html
 .. _execnet: https://codespeak.net/execnet/
 Install
@ -52,28 +77,10 @@ No PyPi release yet!
    pip install git+git://github.com/tgoodlet/tractor.git
 What's this? Spawning event loops in subprocesses?
 --------------------------------------------------
 Close, but not quite.
 The first step to grok ``tractor`` is to get the basics of ``trio``
 down. A great place to start is the `trio docs`_ and this `blog post`_
 by njsmith_.
 ``tractor`` takes much inspiration from pulsar_ and execnet_ but attempts to be much more
 minimal, focus on sophistication of the lower level distributed architecture,
 and of course does **not** use ``asyncio``, hence **no** event loops.
 .. _trio docs: https://trio.readthedocs.io/en/latest/
 .. _pulsar: http://quantmind.github.io/pulsar/design.html
 .. _execnet: https://codespeak.net/execnet/
 .. _blog post: https://vorpus.org/blog/notes-on-structured-concurrency-or-go-statement-considered-harmful/
 .. _njsmith: https://github.com/njsmith/
 A trynamic first scene
 ----------------------
-As a first example let's spawn a couple *actors* and have them run their lines:
+Let's direct a couple *actors* and have them run their lines for
 the hip new film we're shooting:
 .. code:: python
@ -101,51 +108,109 @@ As a first example let's spawn a couple *actors* and have them run their lines:
        async with tractor.open_nursery() as n:
            print("Alright... Action!")
-            donny = await n.start_actor(
+            donny = await n.run_in_actor(
                'donny',
-                main=partial(say_hello, 'gretchen'),
+                say_hello,
-                rpc_module_paths=[_this_module],
+                other_actor='gretchen',
                outlive_main=True
            )
-            gretchen = await n.start_actor(
+            gretchen = await n.run_in_actor(
                'gretchen',
-                main=partial(say_hello, 'donny'),
+                say_hello,
-                rpc_module_paths=[_this_module],
+                other_actor='donny',
            )
            print(await gretchen.result())
            print(await donny.result())
            await donny.cancel_actor()
-            print("CUTTTT CUUTT CUT!!?! Donny!! You're supposed to say...")
+            print("CUTTTT CUUTT CUT!!! Donny!! You're supposed to say...")
    tractor.run(main)
-Here, we've spawned two actors, *donny* and *gretchen* in separate
+We spawn two *actors*, *donny* and *gretchen*.
-processes. Each starts up and begins executing their *main task*
+Each actor starts up and executes their *main task* defined by an
-defined by an async function, ``say_hello()``.  The function instructs
+async function, ``say_hello()``.  The function instructs each actor
-each actor to find their partner and say hello by calling their
+to find their partner and say hello by calling their partner's
-partner's ``hi()`` function using a something called a *portal*. Each
+``hi()`` function using something called a *portal*. Each actor
-actor receives a response and relays that back to the parent actor (in
+receives a response and relays that back to the parent actor (in
-this case our "director").
+this case our "director" executing ``main()``).
 To gain more insight as to how ``tractor`` accomplishes all this please
 read on!
 Actor spawning and causality
 ----------------------------
 ``tractor`` tries to take ``trio``'s concept of causal task lifetimes
-to multi-process land. Accordingly ``tractor``'s actor nursery behaves
+to multi-process land. Accordingly, ``tractor``'s *actor nursery* behaves
-similar to the nursery_ in ``trio``. That is, an ``ActorNursery``
+similar to ``trio``'s nursery_. That is, ``tractor.open_nursery()``
-created with ``tractor.open_nursery()`` waits on spawned sub-actors to
+opens an ``ActorNursery`` which waits on spawned *actors* to complete
-complete (or error) in the same causal_ way ``trio`` waits on spawned
+(or error) in the same causal_ way ``trio`` waits on spawned subtasks.
-subtasks. This includes errors from any one sub-actor causing all other
+This includes errors from any one actor causing all other actors
-actors spawned by the nursery to be cancelled_.
+spawned by the same nursery to be cancelled_.
-To spawn an actor open a *nursery block* and use the ``start_actor()``
+To spawn an actor and run a function in it, open a *nursery block*
 and use the ``run_in_actor()`` method:
 .. code:: python
    import tractor
        def cellar_door():
            return "Dang that's beautiful"
        async def main():
            """The main ``tractor`` routine.
            """
            async with tractor.open_nursery() as n:
                portal = await n.run_in_actor('frank', movie_theatre_question)
            # The ``async with`` will unblock here since the 'frank'
            # actor has completed its main task ``movie_theatre_question()``.
            print(await portal.result())
    tractor.run(main)
 What's going on?
 - an initial *actor* is started with ``tractor.run()`` and told to execute
  its main task_: ``main()``
 - inside ``main()`` an actor is *spawned* using an ``ActorNusery`` and is told
  to run a single function: ``cellar_door()``
 - a ``portal`` instance (we'll get to what it is shortly)
  returned from ``nursery.run_in_actor()`` is used to communicate with
  the newly spawned *sub-actor*
 - the second actor, *frank*, in a new *process* running a new ``trio`` task_
  then executes ``cellar_door()`` and returns its result over a *channel* back
  to the parent actor
 - the parent actor retrieves the subactor's (*frank*) *final result* using ``portal.result()``
  much like you'd expect from a future_.
 This ``run_in_actor()`` API should look very familiar to users of
 ``asyncio``'s run_in_executor_ which uses a ``concurrent.futures`` Executor_.
 Since you might also want to spawn long running *worker* or *daemon*
 actors, each actor's *lifetime* can be determined based on the spawn
 method:
 - if the actor is spawned using ``run_in_actor()`` it terminates when
  its *main* task completes (i.e. when the (async) function submitted
  to it *returns*). The ``with tractor.open_nursery()`` exits only once
  all actors' main function/task complete (just like the nursery_ in ``trio``)
 - actors can be spawned to *live forever* using the ``start_actor()``
  method and act like an RPC daemon that runs indefinitely (the
  ``with tractor.open_nursery()`` wont' exit) until cancelled_
 Had we wanted the latter form in our example it would have looked like:
 .. code:: python
    def movie_theatre_question():
@ -159,15 +224,15 @@ method:
        """The main ``tractor`` routine.
        """
        async with tractor.open_nursery() as n:
            portal = await n.start_actor(
                'frank',
                # enable the actor to run funcs from this current module
                rpc_module_paths=[__name__],
                outlive_main=True,
            )
            print(await portal.run(__name__, 'movie_theatre_question'))
-            # calls the subactor a 2nd time
+            # call the subactor a 2nd time
            print(await portal.run(__name__, 'movie_theatre_question'))
            # the async with will block here indefinitely waiting
@ -175,46 +240,13 @@ method:
            # "outlive_main" actor it will never end until cancelled
            await portal.cancel_actor()
 Notice the ``portal`` instance returned from ``nursery.start_actor()``,
 we'll get to that shortly.
 Spawned actor lifetimes can be configured in one of two ways:
 - the actor terminates when its *main* task completes (the default if
  the ``main`` kwarg is provided)
 - the actor can be told to ``outlive_main=True`` and thus act like an RPC
  daemon where it runs indefinitely until cancelled
 Had we wanted the former in our example it would have been much simpler:
 .. code:: python
    def cellar_door():
        return "Dang that's beautiful"
    async def main():
        """The main ``tractor`` routine.
        """
        async with tractor.open_nursery() as n:
            portal = await n.start_actor('some_linguist', main=cellar_door)
        # The ``async with`` will unblock here since the 'some_linguist'
        # actor has completed its main task ``cellar_door``.
        print(await portal.result())
 Note that the main task's *final result(s)* (returned from the provided
 ``main`` function) is **always** accessed using ``Portal.result()`` much
 like you'd expect from a future_.
 The ``rpc_module_paths`` `kwarg` above is a list of module path
 strings that will be loaded and made accessible for execution in the
 remote actor through a call to ``Portal.run()``. For now this is
 a simple mechanism to restrict the functionality of the remote
-(daemonized) actor and uses Python's module system to limit the
+(and possibly daemonized) actor and uses Python's module system to
-allowed remote function namespace(s).
+limit the allowed remote function namespace(s).
 ``tractor`` is opinionated about the underlying threading model used for
 each *actor*. Since Python has a GIL and an actor model by definition
@ -223,15 +255,18 @@ shares no state between actors, it fits naturally to use a multiprocessing_
 hardware but also distribute over many hardware hosts (each *actor* can talk
 to all others with ease over standard network protocols).
 .. _task: https://trio.readthedocs.io/en/latest/reference-core.html#tasks-let-you-do-multiple-things-at-once
 .. _nursery: https://trio.readthedocs.io/en/latest/reference-core.html#nurseries-and-spawning
 .. _causal: https://vorpus.org/blog/some-thoughts-on-asynchronous-api-design-in-a-post-asyncawait-world/#causality
 .. _cancelled: https://trio.readthedocs.io/en/latest/reference-core.html#child-tasks-and-cancellation
 .. _run_in_executor: https://docs.python.org/3/library/asyncio-eventloop.html#executor
 .. _Executor: https://docs.python.org/3/library/concurrent.futures.html#concurrent.futures.Executor
-Transparent function calling using *portals*
+Transparent remote function calling using *portals*
--------------------------------------------
+---------------------------------------------------
-``tractor`` introdces the concept of a *portal* which is an API
+``tractor`` introduces the concept of a *portal* which is an API
-borrowed_ from ``trio``. A portal may seems similar to the idea of
+borrowed_ from ``trio``. A portal may seem similar to the idea of
 a RPC future_ except a *portal* allows invoking remote *async* functions and
 generators and intermittently blocking to receive responses. This allows
 for fully async-native IPC between actors.
@ -255,11 +290,53 @@ This *portal* approach turns out to be paricularly exciting with the
 introduction of `asynchronous generators`_ in Python 3.6! It means that
 actors can compose nicely in a data processing pipeline.
 As an example here's an actor that streams for 1 second from a remote async
 generator function running in a separate actor:
 .. code:: python
    from itertools import repeat
    import trio
    import tractor
    async def stream_forever():
        for i in repeat("I can see these little future bubble things"):
            # each yielded value is sent over the ``Channel`` to the
            # parent actor
            yield i
            await trio.sleep(0.01)
    async def main():
        # stream for at most 1 seconds
        with trio.move_on_after(1) as cancel_scope:
            async with tractor.open_nursery() as n:
                portal = await n.start_actor(
                    f'donny',
                    rpc_module_paths=[__name__],
                )
                # this async for loop streams values from the above
                # async generator running in a separate process
                async for letter in await portal.run(__name__, 'stream_forever'):
                    print(letter)
        # we support trio's cancellation system
        assert cancel_scope.cancelled_caught
        assert n.cancelled
    tractor.run(main)
 Alright, let's get fancy.
 Say you wanted to spawn two actors which each pulling data feeds from
 two different sources (and wanted this work spread across 2 cpus).
 You also want to aggregate these feeds, do some processing on them and then
-deliver the final result stream to a client (or in this case parent)
+deliver the final result stream to a client (or in this case parent) actor
-actor and print the results to your screen:
+and print the results to your screen:
 .. code:: python
@ -287,7 +364,6 @@ actor and print the results to your screen:
                portal = await nursery.start_actor(
                    name=f'streamer_{i}',
                    rpc_module_paths=[__name__],
                    outlive_main=True,  # daemonize these actors
                )
                portals.append(portal)
@ -337,15 +413,15 @@ actor and print the results to your screen:
            import time
            pre_start = time.time()
-            portal = await nursery.start_actor(
+            portal = await nursery.run_in_actor(
-                name='aggregator',
+                'aggregator',
-                # executed in the actor's "main task" immediately
+                aggregate,
-                main=partial(aggregate, seed),
+                seed=seed,
            )
            start = time.time()
            # the portal call returns exactly what you'd expect
-            # as if the remote "main" function was called locally
+            # as if the remote "aggregate" function was called locally
            result_stream = []
            async for value in await portal.result():
                result_stream.append(value)
@ -360,16 +436,12 @@ actor and print the results to your screen:
 Here there's four actors running in separate processes (using all the
-cores on you machine). Two are streaming (by **yielding** value in the
+cores on you machine). Two are streaming by *yielding* values from the
 ``stream_data()`` async generator, one is aggregating values from
 those two in ``aggregate()`` (also an async generator) and shipping the
 single stream of unique values up the parent actor (the ``'MainProcess'``
 as ``multiprocessing`` calls it) which is running ``main()``. 
 There has also been some discussion about adding support for reactive
 programming primitives and native support for asyncitertools_ like libs -
 so keep an eye out for that!
 .. _future: https://en.wikipedia.org/wiki/Futures_and_promises
 .. _borrowed:
    https://trio.readthedocs.io/en/latest/reference-core.html#getting-back-into-the-trio-thread-from-another-thread
@ -380,38 +452,7 @@ so keep an eye out for that!
 Cancellation
 ------------
-``tractor`` supports ``trio``'s cancellation_ system verbatim:
+``tractor`` supports ``trio``'s cancellation_ system verbatim.
 .. code:: python
    import trio
    import tractor
    from itertools import repeat
    async def stream_forever():
        for i in repeat("I can see these little future bubble things"):
            yield i
            await trio.sleep(0.01)
    async def main():
        # stream for at most 1 second
        with trio.move_on_after(1) as cancel_scope:
            async with tractor.open_nursery() as n:
                portal = await n.start_actor(
                    f'donny',
                    rpc_module_paths=[__name__],
                    outlive_main=True
                )
                async for letter in await portal.run(__name__, 'stream_forever'):
                    print(letter)
        assert cancel_scope.cancelled_caught
        assert n.cancelled
    tractor.run(main)
 Cancelling a nursery block cancels all actors spawned by it.
 Eventually ``tractor`` plans to support different `supervision strategies`_ like ``erlang``.
@ -421,7 +462,7 @@ Eventually ``tractor`` plans to support different `supervision strategies`_ like
 Remote error propagation
 ------------------------
 Any task invoked in a remote actor should ship any error(s) back to the calling
-actor where it is raised and expected to be dealt with. This way remote actor's
+actor where it is raised and expected to be dealt with. This way remote actors
 are never cancelled unless explicitly asked or there's a bug in ``tractor`` itself.
 .. code:: python
@ -429,6 +470,7 @@ are never cancelled unless explicitly asked or there's a bug in ``tractor`` itse
    async def assert_err():
        assert 0
    async def main():
        async with tractor.open_nursery() as n:
            real_actors = []
@ -436,11 +478,10 @@ are never cancelled unless explicitly asked or there's a bug in ``tractor`` itse
                real_actors.append(await n.start_actor(
                    f'actor_{i}',
                    rpc_module_paths=[__name__],
                    outlive_main=True
                ))
            # start one actor that will fail immediately
-            await n.start_actor('extra', main=assert_err)
+            await n.run_in_actor('extra', assert_err)
        # should error here with a ``RemoteActorError`` containing
        # an ``AssertionError`` and all the other actors have been cancelled
@ -482,8 +523,9 @@ multiple RPC calls to an actor can access global data using the per actor
        async def main():
            async with tractor.open_nursery() as n:
-                await n.start_actor(
+                await n.run_in_actor(
-                    'checker', main=check_statespace,
+                    'checker',
                    check_statespace,
                    statespace=statespace
                )
@ -579,6 +621,8 @@ Stuff I'd like to see ``tractor`` do one day:
 - a distributed log ledger for tracking cluster behaviour
 - a slick multi-process aware debugger much like in celery_
  but with better `pdb++`_ support
 - an extensive `chaos engineering`_ test suite
 - support for reactive programming primitives and native support for asyncitertools_ like libs
 If you're interested in tackling any of these please do shout about it on the
 `trio gitter channel`_!
--- a/tests/test_tractor.py
+++ b/tests/test_tractor.py
@ -168,6 +168,8 @@ def test_remote_error(arb_addr):
 async def stream_forever():
    for i in repeat("I can see these little future bubble things"):
        # each yielded value is sent over the ``Channel`` to the
        # parent actor
        yield i
        await trio.sleep(0.01)
@ -175,16 +177,20 @@ async def stream_forever():
@tractor_test
 async def test_cancel_infinite_streamer():
-    # stream for at most 5 seconds
+    # stream for at most 1 seconds
    with trio.move_on_after(1) as cancel_scope:
        async with tractor.open_nursery() as n:
            portal = await n.start_actor(
                f'donny',
                rpc_module_paths=[__name__],
            )
            # this async for loop streams values from the above
            # async generator running in a separate process
            async for letter in await portal.run(__name__, 'stream_forever'):
                print(letter)
    # we support trio's cancellation system
    assert cancel_scope.cancelled_caught
    assert n.cancelled
@ -230,6 +236,7 @@ async def test_movie_theatre_convo():
    """The main ``tractor`` routine.
    """
    async with tractor.open_nursery() as n:
        portal = await n.start_actor(
            'frank',
            # enable the actor to run funcs from this current module
@ -237,7 +244,7 @@ async def test_movie_theatre_convo():
        )
        print(await portal.run(__name__, 'movie_theatre_question'))
-        # calls the subactor a 2nd time
+        # call the subactor a 2nd time
        print(await portal.run(__name__, 'movie_theatre_question'))
        # the async with will block here indefinitely waiting
@ -246,17 +253,6 @@ async def test_movie_theatre_convo():
        await portal.cancel_actor()
@tractor_test
 async def test_movie_theatre_convo_main_task():
    async with tractor.open_nursery() as n:
        portal = await n.run_in_actor('frank', movie_theatre_question)
    # The ``async with`` will unblock here since the 'frank'
    # actor has completed its main task ``movie_theatre_question()``.
    print(await portal.result())
 def cellar_door():
    return "Dang that's beautiful"
@ -266,6 +262,7 @@ async def test_most_beautiful_word():
    """The main ``tractor`` routine.
    """
    async with tractor.open_nursery() as n:
        portal = await n.run_in_actor('some_linguist', cellar_door)
    # The ``async with`` will unblock here since the 'some_linguist'
@ -370,7 +367,7 @@ async def a_quadruple_example():
        start = time.time()
        # the portal call returns exactly what you'd expect
-        # as if the remote "main" function was called locally
+        # as if the remote "aggregate" function was called locally
        result_stream = []
        async for value in await portal.result():
            result_stream.append(value)