Document context api

2019-01-16 23:19:29 -05:00 · 2019-01-16 23:19:29 -05:00 · b403a20f32
parent 76f7ae5cf4
commit b403a20f32
1 changed files with 56 additions and 20 deletions
--- a/README.rst
+++ b/README.rst
@ -61,7 +61,6 @@ Philosophy
 .. _pulsar: http://quantmind.github.io/pulsar/design.html
 .. _execnet: https://codespeak.net/execnet/
 Install
 -------
 No PyPi release yet!
@ -199,7 +198,7 @@ method:
 - 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_
+  ``with tractor.open_nursery()`` won't exit) until cancelled_
 Had we wanted the latter form in our example it would have looked like:
@ -255,8 +254,8 @@ to all others with ease over standard network protocols).
 .. _Executor: https://docs.python.org/3/library/concurrent.futures.html#concurrent.futures.Executor
-Transparent remote function calling using *portals*
+Async IPC using *portals*
---------------------------------------------------
+-------------------------
 ``tractor`` introduces the concept of a *portal* which is an API
 borrowed_ from ``trio``. A portal may seem similar to the idea of
 a RPC future_ except a *portal* allows invoking remote *async* functions and
@ -494,12 +493,12 @@ a ``Supervisor`` type.
 .. _erlang strategies: http://learnyousomeerlang.com/supervisors
-Shared task state
+Actor local variables
-----------------
+---------------------
 Although ``tractor`` uses a *shared-nothing* architecture between processes
-you can of course share state within an actor.  ``trio`` tasks spawned via
+you can of course share state between tasks running *within* an actor.
-multiple RPC calls to an actor can access global data using the per actor
+``trio`` tasks spawned via multiple RPC calls to an actor can access global
-``statespace`` dictionary:
+state using the per actor ``statespace`` dictionary:
 .. code:: python
@ -561,16 +560,45 @@ The ``name`` value you should pass to ``find_actor()`` is the one you passed as
 *first* argument to either ``tractor.run()`` or ``ActorNursery.start_actor()``.
-Using ``Channel`` directly (undocumented)
+Streaming and using channels and contexts
 -----------------------------------------
-You can use the ``Channel`` api if necessary by simply defining a
+A ``Channel`` is the API which wraps an underlying *transport* and *interchange*
-``chan`` and ``cid`` *kwarg* in your async function definition.
+format to support *inter-actor-communication* (IAC). In its present state ``tractor``
-``tractor`` will treat such async functions like async generators on
+uses TCP and msgpack_ but hopefully more alternatives in the future.
-the calling side (for now anyway) such that you can push stream values
+
-a little more granularly if you find *yielding* values to be restrictive.
+If you aren't fond of having to write an async generator to stream data
-I am purposely not documenting this feature with code because I'm not yet
+between actors (or need something more flexible) you can instead use a
-sure yet how it should be used correctly. If you'd like more details
+``Context``. A context wraps an actor-local spawned task and a ``Channel``
-please feel free to ask me on the `trio gitter channel`_.
+so that tasks executing across multiple processes can stream data
 to one another using a low level, request oriented, API.
 As an example if you wanted to create a streaming server without writing
 an async generator that *yields* values (which are implicitly
 shipped over a channel to the caller) you instead define an async
 function:
 .. code:: python
   async def streamer(ctx, rate=2):
      """A simple web response streaming server.
      """
      while True:
         val = await web_request('http://data.feed.com')
         # this is the same as ``yield`` in the async gen case
         await ctx.send_yield(val)
         await trio.sleep(1 / rate)
 All that's required is declaring a ``ctx`` argument name somewhere in
 your function signature and ``tractor`` will treat the async function
 like async generator as a streaming function on the client task's side.
 As you can imagine, this turns out to be handy particularly if you have
 multiple tasks streaming responses concurrently.
 The context idea comes from the `protocol context`_ in nanomsg_.
 It allows you to perfom IPC in a task or protocol specific way.
 Running actors standalone (without spawning)
@ -616,12 +644,20 @@ Stuff I'd like to see ``tractor`` do real soon:
 - 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`_!
+Feel like saying hi?
 --------------------
 This project is very much coupled to the ongoing development of
 ``trio`` (i.e. ``tractor`` gets all its ideas from that brilliant
 community). If you want to help, have suggestions or just want to
 say hi, please feel free to ping me on the `trio gitter channel`_!
 .. _supervisors: https://github.com/tgoodlet/tractor/issues/22
 .. _nanomsg: https://github.com/tgoodlet/tractor/issues/19
 .. _nng context: https://github.com/tgoodlet/tractor/issues/19
 .. _gossip protocol: https://en.wikipedia.org/wiki/Gossip_protocol
 .. _trio gitter channel: https://gitter.im/python-trio/general
 .. _celery: http://docs.celeryproject.org/en/latest/userguide/debugging.html
 .. _pdb++: https://github.com/antocuni/pdb
 .. _msgpack: https://en.wikipedia.org/wiki/MessagePack