boost_1_45_0/libs/asio/doc/overview/threads.qbk - nest-learning-thermostat/5.0/boost - Git at Google

 [/
  / Copyright (c) 2003-2010 Christopher M. Kohlhoff (chris at kohlhoff dot com)
  /
  / Distributed under the Boost Software License, Version 1.0. (See accompanying
  / file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
  /]

 [section:threads Threads and Boost.Asio]

 [heading Thread Safety]

 In general, it is safe to make concurrent use of distinct objects, but unsafe
 to make concurrent use of a single object. However, types such as `io_service`
 provide a stronger guarantee that it is safe to use a single object
 concurrently.

 [heading Thread Pools]

 Multiple threads may call `io_service::run()` to set up a pool of threads from
 which completion handlers may be invoked. This approach may also be used with
 `io_service::post()` to use a means to perform any computational tasks across a
 thread pool.

 Note that all threads that have joined an `io_service`'s pool are considered
 equivalent, and the `io_service` may distribute work across them in an
 arbitrary fashion.

 [heading Internal Threads]

 The implementation of this library for a particular platform may make use of
 one or more internal threads to emulate asynchronicity. As far as possible,
 these threads must be invisible to the library user. In particular, the threads:

 * must not call the user's code directly; and

 * must block all signals.

 This approach is complemented by the following guarantee:

 * Asynchronous completion handlers will only be called from threads that are
   currently calling `io_service::run()`.

 Consequently, it is the library user's responsibility to create and manage all
 threads to which the notifications will be delivered.

 The reasons for this approach include:

 * By only calling `io_service::run()` from a single thread, the user's code can
   avoid the development complexity associated with synchronisation. For
   example, a library user can implement scalable servers that are
   single-threaded (from the user's point of view).

 * A library user may need to perform initialisation in a thread shortly after
   the thread starts and before any other application code is executed. For
   example, users of Microsoft's COM must call `CoInitializeEx` before any other
   COM operations can be called from that thread.

 * The library interface is decoupled from interfaces for thread creation and
   management, and permits implementations on platforms where threads are not
   available.

 [heading See Also]

 [link boost_asio.reference.io_service io_service].

 [endsect]
	[/
	/ Copyright (c) 2003-2010 Christopher M. Kohlhoff (chris at kohlhoff dot com)
	/
	/ Distributed under the Boost Software License, Version 1.0. (See accompanying
	/ file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
	/]

	[section:threads Threads and Boost.Asio]

	[heading Thread Safety]

	In general, it is safe to make concurrent use of distinct objects, but unsafe
	to make concurrent use of a single object. However, types such as `io_service`
	provide a stronger guarantee that it is safe to use a single object
	concurrently.

	[heading Thread Pools]

	Multiple threads may call `io_service::run()` to set up a pool of threads from
	which completion handlers may be invoked. This approach may also be used with
	`io_service::post()` to use a means to perform any computational tasks across a
	thread pool.

	Note that all threads that have joined an `io_service`'s pool are considered
	equivalent, and the `io_service` may distribute work across them in an
	arbitrary fashion.

	[heading Internal Threads]

	The implementation of this library for a particular platform may make use of
	one or more internal threads to emulate asynchronicity. As far as possible,
	these threads must be invisible to the library user. In particular, the threads:

	* must not call the user's code directly; and

	* must block all signals.

	This approach is complemented by the following guarantee:

	* Asynchronous completion handlers will only be called from threads that are
	currently calling `io_service::run()`.

	Consequently, it is the library user's responsibility to create and manage all
	threads to which the notifications will be delivered.

	The reasons for this approach include:

	* By only calling `io_service::run()` from a single thread, the user's code can
	avoid the development complexity associated with synchronisation. For
	example, a library user can implement scalable servers that are
	single-threaded (from the user's point of view).

	* A library user may need to perform initialisation in a thread shortly after
	the thread starts and before any other application code is executed. For
	example, users of Microsoft's COM must call `CoInitializeEx` before any other
	COM operations can be called from that thread.

	* The library interface is decoupled from interfaces for thread creation and
	management, and permits implementations on platforms where threads are not
	available.

	[heading See Also]

	[link boost_asio.reference.io_service io_service].

	[endsect]