libstdc++-v3/doc/xml/manual/concurrency_extensions.xml - gcc - Git at Google

 <chapter xmlns="http://docbook.org/ns/docbook" version="5.0"
 	 xml:id="manual.ext.concurrency" xreflabel="Concurrency Extensions">
 <?dbhtml filename="ext_concurrency.html"?>

 <info><title>Concurrency</title>
   <keywordset>
     <keyword>ISO C++</keyword>
     <keyword>library</keyword>
   </keywordset>
 </info>


 <section xml:id="manual.ext.concurrency.design" xreflabel="Design"><info><title>Design</title></info>


   <section xml:id="manual.ext.concurrency.design.threads" xreflabel="Threads API"><info><title>Interface to Locks and Mutexes</title></info>


 <para>The file <filename class="headerfile">&lt;ext/concurrence.h&gt;</filename>
 contains all the higher-level
 constructs for playing with threads. In contrast to the atomics layer,
 the concurrence layer consists largely of types. All types are defined within <code>namespace __gnu_cxx</code>.
 </para>

 <para>
 These types can be used in a portable manner, regardless of the
 specific environment. They are carefully designed to provide optimum
 efficiency and speed, abstracting out underlying thread calls and
 accesses when compiling for single-threaded situations (even on hosts
 that support multiple threads.)
 </para>

 <para>The enumerated type <code>_Lock_policy</code> details the set of
 available locking
 policies: <code>_S_single</code>, <code>_S_mutex</code>,
 and <code>_S_atomic</code>.
 </para>

 <itemizedlist>
 <listitem><para><code>_S_single</code></para>
 <para>Indicates single-threaded code that does not need locking.
 </para>

 </listitem>
 <listitem><para><code>_S_mutex</code></para>
 <para>Indicates multi-threaded code using thread-layer abstractions.
 </para>
 </listitem>
 <listitem><para><code>_S_atomic</code></para>
 <para>Indicates multi-threaded code using atomic operations.
 </para>
 </listitem>
 </itemizedlist>

 <para>The compile-time constant <code>__default_lock_policy</code> is set
 to one of the three values above, depending on characteristics of the
 host environment and the current compilation flags.
 </para>

 <para>Two more datatypes make up the rest of the
 interface: <code>__mutex</code>, and <code>__scoped_lock</code>.
 </para>

 <para>The scoped lock idiom is well-discussed within the C++
 community. This version takes a <code>__mutex</code> reference, and
 locks it during construction of <code>__scoped_lock</code> and
 unlocks it during destruction. This is an efficient way of locking
 critical sections, while retaining exception-safety.
 These types have been superseded in the ISO C++ 2011 standard by the
 mutex and lock types defined in the header
 <filename class="headerfile">&lt;mutex&gt;</filename>.
 </para>
   </section>

   <section xml:id="manual.ext.concurrency.design.atomics" xreflabel="Atomic API"><info><title>Interface to Atomic Functions</title></info>


 <para>
 Two functions and one type form the base of atomic support.
 </para>


 <para>The type <code>_Atomic_word</code> is a signed integral type
 supporting atomic operations.
 </para>

 <para>
 The two functions functions are:
 </para>

 <programlisting>
 _Atomic_word
 __exchange_and_add_dispatch(volatile _Atomic_word*, int);

 void
 __atomic_add_dispatch(volatile _Atomic_word*, int);
 </programlisting>

 <para>Both of these functions are declared in the header file
 &lt;ext/atomicity.h&gt;, and are in <code>namespace __gnu_cxx</code>.
 </para>

 <itemizedlist>
 <listitem><para>
 <code>
 __exchange_and_add_dispatch
 </code>
 </para>
 <para>Adds the second argument's value to the first argument. Returns the old value.
 </para>
 </listitem>
 <listitem><para>
 <code>
 __atomic_add_dispatch
 </code>
 </para>
 <para>Adds the second argument's value to the first argument. Has no return value.
 </para>
 </listitem>
 </itemizedlist>

 <para>
 These functions forward to one of several specialized helper
 functions, depending on the circumstances. For instance,
 </para>

 <para>
 <code>
 __exchange_and_add_dispatch
 </code>
 </para>

 <para>
 Calls through to either of:
 </para>

 <itemizedlist>
 <listitem><para><code>__exchange_and_add</code>
 </para>
 <para>Multi-thread version. Inlined if compiler-generated builtin atomics
 can be used, otherwise resolved at link time to a non-builtin code
 sequence.
 </para>
 </listitem>

 <listitem><para><code>__exchange_and_add_single</code>
 </para>
 <para>Single threaded version. Inlined.</para>
 </listitem>
 </itemizedlist>

 <para>However, only <code>__exchange_and_add_dispatch</code>
 and <code>__atomic_add_dispatch</code> should be used. These functions
 can be used in a portable manner, regardless of the specific
 environment. They are carefully designed to provide optimum efficiency
 and speed, abstracting out atomic accesses when they are not required
 (even on hosts that support compiler intrinsics for atomic
 operations.)
 </para>

 <para>
 In addition, there are two macros
 </para>

 <para>
 <code>
 _GLIBCXX_READ_MEM_BARRIER
 </code>
 </para>
 <para>
 <code>
 _GLIBCXX_WRITE_MEM_BARRIER
 </code>
 </para>

 <para>
 Which expand to the appropriate write and read barrier required by the
 host hardware and operating system.
 </para>
   </section>

 </section>


 <section xml:id="manual.ext.concurrency.impl" xreflabel="Implementation"><info><title>Implementation</title></info>
   <?dbhtml filename="ext_concurrency_impl.html"?>

   <section xml:id="manual.ext.concurrency.impl.atomic_fallbacks" xreflabel="Atomic F"><info><title>Using Built-in Atomic Functions</title></info>


 <para>The functions for atomic operations described above are either
 implemented via compiler intrinsics (if the underlying host is
 capable) or by library fallbacks.</para>

 <para>Compiler intrinsics (builtins) are always preferred.  However, as
 the compiler builtins for atomics are not universally implemented,
 using them directly is problematic, and can result in undefined
 function calls.
 </para>

 <para>Prior to GCC 4.7 the older <code>__sync</code> intrinsics were used.
 An example of an undefined symbol from the use
 of <code>__sync_fetch_and_add</code> on an unsupported host is a
 missing reference to <code>__sync_fetch_and_add_4</code>.
 </para>

 <para>Current releases use the newer <code>__atomic</code> intrinsics,
 which are implemented by library calls if the hardware doesn't support them.
 Undefined references to functions like
 <code>__atomic_is_lock_free</code> should be resolved by linking to
 <filename class="libraryfile">libatomic</filename>, which is usually
 installed alongside libstdc++.
 </para>

 <para>In addition, on some hosts the compiler intrinsics are enabled
 conditionally, via the <code>-march</code> command line flag. This makes
 usage vary depending on the target hardware and the flags used during
 compile.
 </para>


 <para>
 <remark>
 Incomplete/inconsistent. This is only C++11.
 </remark>
 </para>

 <para>
 If builtins are possible for bool-sized integral types,
 <code>ATOMIC_BOOL_LOCK_FREE</code> will be defined.
 If builtins are possible for int-sized integral types,
 <code>ATOMIC_INT_LOCK_FREE</code> will be defined.
 </para>


 <para>For the following hosts, intrinsics are enabled by default.
 </para>

 <itemizedlist>
   <listitem><para>alpha</para></listitem>
   <listitem><para>ia64</para></listitem>
   <listitem><para>powerpc</para></listitem>
   <listitem><para>s390</para></listitem>
 </itemizedlist>

 <para>For others, some form of <code>-march</code> may work. On
 non-ancient x86 hardware, <code>-march=native</code> usually does the
 trick.</para>

 <para> For hosts without compiler intrinsics, but with capable
 hardware, hand-crafted assembly is selected. This is the case for the following hosts:
 </para>

 <itemizedlist>
   <listitem><para>cris</para></listitem>
   <listitem><para>hppa</para></listitem>
   <listitem><para>i386</para></listitem>
   <listitem><para>i486</para></listitem>
   <listitem><para>m48k</para></listitem>
   <listitem><para>mips</para></listitem>
   <listitem><para>sparc</para></listitem>
 </itemizedlist>

 <para>And for the rest, a simulated atomic lock via pthreads.
 </para>

 <para> Detailed information about compiler intrinsics for atomic operations can be found in the GCC <link xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="http://gcc.gnu.org/onlinedocs/gcc/_005f_005fatomic-Builtins.html"> documentation</link>.
 </para>

 <para> More details on the library fallbacks from the porting <link linkend="internals.thread_safety">section</link>.
 </para>


   </section>
   <section xml:id="manual.ext.concurrency.impl.thread" xreflabel="Pthread"><info><title>Thread Abstraction</title></info>


 <para>A thin layer above IEEE 1003.1 (i.e. pthreads) is used to abstract
 the thread interface for GCC. This layer is called "gthread," and is
 comprised of one header file that wraps the host's default thread layer with
 a POSIX-like interface.
 </para>

 <para> The file &lt;gthr-default.h&gt; points to the deduced wrapper for
 the current host. In libstdc++ implementation files,
 &lt;bits/gthr.h&gt; is used to select the proper gthreads file.
 </para>

 <para>Within libstdc++ sources, all calls to underlying thread functionality
 use this layer. More detail as to the specific interface can be found in the source <link xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="http://gcc.gnu.org/onlinedocs/libstdc++/latest-doxygen/index.html">documentation</link>.
 </para>

 <para>By design, the gthread layer is interoperable with the types,
 functions, and usage found in the usual &lt;pthread.h&gt; file,
 including <code>pthread_t</code>, <code>pthread_once_t</code>, <code>pthread_create</code>,
 etc.
 </para>

   </section>
 </section>

 <section xml:id="manual.ext.concurrency.use" xreflabel="Use"><info><title>Use</title></info>
 <?dbhtml filename="ext_concurrency_use.html"?>


 <para>Typical usage of the last two constructs is demonstrated as follows:
 </para>

 <programlisting>
 #include &lt;ext/concurrence.h&gt;

 namespace
 {
   __gnu_cxx::__mutex safe_base_mutex;
 } // anonymous namespace

 namespace other
 {
   void
   foo()
   {
     __gnu_cxx::__scoped_lock sentry(safe_base_mutex);
     for (int i = 0; i &lt; max;  ++i)
       {
 	_Safe_iterator_base* __old = __iter;
 	__iter = __iter-&lt;_M_next;
 	__old-&lt;_M_detach_single();
       }
 }
 </programlisting>

 <para>In this sample code, an anonymous namespace is used to keep
 the <code>__mutex</code> private to the compilation unit,
 and <code>__scoped_lock</code> is used to guard access to the critical
 section within the for loop, locking the mutex on creation and freeing
 the mutex as control moves out of this block.
 </para>

 <para>Several exception classes are used to keep track of
 concurrence-related errors. These classes
 are: <code>__concurrence_lock_error</code>, <code>__concurrence_unlock_error</code>, <code>__concurrence_wait_error</code>,
 and <code>__concurrence_broadcast_error</code>.
 </para>


 </section>

 </chapter>
	<chapter xmlns="http://docbook.org/ns/docbook" version="5.0"
	xml:id="manual.ext.concurrency" xreflabel="Concurrency Extensions">
	<?dbhtml filename="ext_concurrency.html"?>

	<info><title>Concurrency</title>
	<keywordset>
	<keyword>ISO C++</keyword>
	<keyword>library</keyword>
	</keywordset>
	</info>



	<section xml:id="manual.ext.concurrency.design" xreflabel="Design"><info><title>Design</title></info>


	<section xml:id="manual.ext.concurrency.design.threads" xreflabel="Threads API"><info><title>Interface to Locks and Mutexes</title></info>


	<para>The file <filename class="headerfile"><ext/concurrence.h></filename>
	contains all the higher-level
	constructs for playing with threads. In contrast to the atomics layer,
	the concurrence layer consists largely of types. All types are defined within <code>namespace __gnu_cxx</code>.
	</para>

	<para>
	These types can be used in a portable manner, regardless of the
	specific environment. They are carefully designed to provide optimum
	efficiency and speed, abstracting out underlying thread calls and
	accesses when compiling for single-threaded situations (even on hosts
	that support multiple threads.)
	</para>

	<para>The enumerated type <code>_Lock_policy</code> details the set of
	available locking
	policies: <code>_S_single</code>, <code>_S_mutex</code>,
	and <code>_S_atomic</code>.
	</para>

	<itemizedlist>
	<listitem><para><code>_S_single</code></para>
	<para>Indicates single-threaded code that does not need locking.
	</para>

	</listitem>
	<listitem><para><code>_S_mutex</code></para>
	<para>Indicates multi-threaded code using thread-layer abstractions.
	</para>
	</listitem>
	<listitem><para><code>_S_atomic</code></para>
	<para>Indicates multi-threaded code using atomic operations.
	</para>
	</listitem>
	</itemizedlist>

	<para>The compile-time constant <code>__default_lock_policy</code> is set
	to one of the three values above, depending on characteristics of the
	host environment and the current compilation flags.
	</para>

	<para>Two more datatypes make up the rest of the
	interface: <code>__mutex</code>, and <code>__scoped_lock</code>.
	</para>

	<para>The scoped lock idiom is well-discussed within the C++
	community. This version takes a <code>__mutex</code> reference, and
	locks it during construction of <code>__scoped_lock</code> and
	unlocks it during destruction. This is an efficient way of locking
	critical sections, while retaining exception-safety.
	These types have been superseded in the ISO C++ 2011 standard by the
	mutex and lock types defined in the header
	<filename class="headerfile"><mutex></filename>.
	</para>
	</section>

	<section xml:id="manual.ext.concurrency.design.atomics" xreflabel="Atomic API"><info><title>Interface to Atomic Functions</title></info>



	<para>
	Two functions and one type form the base of atomic support.
	</para>


	<para>The type <code>_Atomic_word</code> is a signed integral type
	supporting atomic operations.
	</para>

	<para>
	The two functions functions are:
	</para>

	<programlisting>
	_Atomic_word
	__exchange_and_add_dispatch(volatile _Atomic_word*, int);

	void
	__atomic_add_dispatch(volatile _Atomic_word*, int);
	</programlisting>

	<para>Both of these functions are declared in the header file
	<ext/atomicity.h>, and are in <code>namespace __gnu_cxx</code>.
	</para>

	<itemizedlist>
	<listitem><para>
	<code>
	__exchange_and_add_dispatch
	</code>
	</para>
	<para>Adds the second argument's value to the first argument. Returns the old value.
	</para>
	</listitem>
	<listitem><para>
	<code>
	__atomic_add_dispatch
	</code>
	</para>
	<para>Adds the second argument's value to the first argument. Has no return value.
	</para>
	</listitem>
	</itemizedlist>

	<para>
	These functions forward to one of several specialized helper
	functions, depending on the circumstances. For instance,
	</para>

	<para>
	<code>
	__exchange_and_add_dispatch
	</code>
	</para>

	<para>
	Calls through to either of:
	</para>

	<itemizedlist>
	<listitem><para><code>__exchange_and_add</code>
	</para>
	<para>Multi-thread version. Inlined if compiler-generated builtin atomics
	can be used, otherwise resolved at link time to a non-builtin code
	sequence.
	</para>
	</listitem>

	<listitem><para><code>__exchange_and_add_single</code>
	</para>
	<para>Single threaded version. Inlined.</para>
	</listitem>
	</itemizedlist>

	<para>However, only <code>__exchange_and_add_dispatch</code>
	and <code>__atomic_add_dispatch</code> should be used. These functions
	can be used in a portable manner, regardless of the specific
	environment. They are carefully designed to provide optimum efficiency
	and speed, abstracting out atomic accesses when they are not required
	(even on hosts that support compiler intrinsics for atomic
	operations.)
	</para>

	<para>
	In addition, there are two macros
	</para>

	<para>
	<code>
	_GLIBCXX_READ_MEM_BARRIER
	</code>
	</para>
	<para>
	<code>
	_GLIBCXX_WRITE_MEM_BARRIER
	</code>
	</para>

	<para>
	Which expand to the appropriate write and read barrier required by the
	host hardware and operating system.
	</para>
	</section>

	</section>


	<section xml:id="manual.ext.concurrency.impl" xreflabel="Implementation"><info><title>Implementation</title></info>
	<?dbhtml filename="ext_concurrency_impl.html"?>

	<section xml:id="manual.ext.concurrency.impl.atomic_fallbacks" xreflabel="Atomic F"><info><title>Using Built-in Atomic Functions</title></info>


	<para>The functions for atomic operations described above are either
	implemented via compiler intrinsics (if the underlying host is
	capable) or by library fallbacks.</para>

	<para>Compiler intrinsics (builtins) are always preferred. However, as
	the compiler builtins for atomics are not universally implemented,
	using them directly is problematic, and can result in undefined
	function calls.
	</para>

	<para>Prior to GCC 4.7 the older <code>__sync</code> intrinsics were used.
	An example of an undefined symbol from the use
	of <code>__sync_fetch_and_add</code> on an unsupported host is a
	missing reference to <code>__sync_fetch_and_add_4</code>.
	</para>

	<para>Current releases use the newer <code>__atomic</code> intrinsics,
	which are implemented by library calls if the hardware doesn't support them.
	Undefined references to functions like
	<code>__atomic_is_lock_free</code> should be resolved by linking to
	<filename class="libraryfile">libatomic</filename>, which is usually
	installed alongside libstdc++.
	</para>

	<para>In addition, on some hosts the compiler intrinsics are enabled
	conditionally, via the <code>-march</code> command line flag. This makes
	usage vary depending on the target hardware and the flags used during
	compile.
	</para>



	<para>
	<remark>
	Incomplete/inconsistent. This is only C++11.
	</remark>
	</para>

	<para>
	If builtins are possible for bool-sized integral types,
	<code>ATOMIC_BOOL_LOCK_FREE</code> will be defined.
	If builtins are possible for int-sized integral types,
	<code>ATOMIC_INT_LOCK_FREE</code> will be defined.
	</para>


	<para>For the following hosts, intrinsics are enabled by default.
	</para>

	<itemizedlist>
	<listitem><para>alpha</para></listitem>
	<listitem><para>ia64</para></listitem>
	<listitem><para>powerpc</para></listitem>
	<listitem><para>s390</para></listitem>
	</itemizedlist>

	<para>For others, some form of <code>-march</code> may work. On
	non-ancient x86 hardware, <code>-march=native</code> usually does the
	trick.</para>

	<para> For hosts without compiler intrinsics, but with capable
	hardware, hand-crafted assembly is selected. This is the case for the following hosts:
	</para>

	<itemizedlist>
	<listitem><para>cris</para></listitem>
	<listitem><para>hppa</para></listitem>
	<listitem><para>i386</para></listitem>
	<listitem><para>i486</para></listitem>
	<listitem><para>m48k</para></listitem>
	<listitem><para>mips</para></listitem>
	<listitem><para>sparc</para></listitem>
	</itemizedlist>

	<para>And for the rest, a simulated atomic lock via pthreads.
	</para>

	<para> Detailed information about compiler intrinsics for atomic operations can be found in the GCC <link xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="http://gcc.gnu.org/onlinedocs/gcc/_005f_005fatomic-Builtins.html"> documentation</link>.
	</para>

	<para> More details on the library fallbacks from the porting <link linkend="internals.thread_safety">section</link>.
	</para>


	</section>
	<section xml:id="manual.ext.concurrency.impl.thread" xreflabel="Pthread"><info><title>Thread Abstraction</title></info>


	<para>A thin layer above IEEE 1003.1 (i.e. pthreads) is used to abstract
	the thread interface for GCC. This layer is called "gthread," and is
	comprised of one header file that wraps the host's default thread layer with
	a POSIX-like interface.
	</para>

	<para> The file <gthr-default.h> points to the deduced wrapper for
	the current host. In libstdc++ implementation files,
	<bits/gthr.h> is used to select the proper gthreads file.
	</para>

	<para>Within libstdc++ sources, all calls to underlying thread functionality
	use this layer. More detail as to the specific interface can be found in the source <link xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="http://gcc.gnu.org/onlinedocs/libstdc++/latest-doxygen/index.html">documentation</link>.
	</para>

	<para>By design, the gthread layer is interoperable with the types,
	functions, and usage found in the usual <pthread.h> file,
	including <code>pthread_t</code>, <code>pthread_once_t</code>, <code>pthread_create</code>,
	etc.
	</para>

	</section>
	</section>

	<section xml:id="manual.ext.concurrency.use" xreflabel="Use"><info><title>Use</title></info>
	<?dbhtml filename="ext_concurrency_use.html"?>


	<para>Typical usage of the last two constructs is demonstrated as follows:
	</para>

	<programlisting>
	#include <ext/concurrence.h>

	namespace
	{
	__gnu_cxx::__mutex safe_base_mutex;
	} // anonymous namespace

	namespace other
	{
	void
	foo()
	{
	__gnu_cxx::__scoped_lock sentry(safe_base_mutex);
	for (int i = 0; i < max; ++i)
	{
	_Safe_iterator_base* __old = __iter;
	__iter = __iter-<_M_next;
	__old-<_M_detach_single();
	}
	}
	</programlisting>

	<para>In this sample code, an anonymous namespace is used to keep
	the <code>__mutex</code> private to the compilation unit,
	and <code>__scoped_lock</code> is used to guard access to the critical
	section within the for loop, locking the mutex on creation and freeing
	the mutex as control moves out of this block.
	</para>

	<para>Several exception classes are used to keep track of
	concurrence-related errors. These classes
	are: <code>__concurrence_lock_error</code>, <code>__concurrence_unlock_error</code>, <code>__concurrence_wait_error</code>,
	and <code>__concurrence_broadcast_error</code>.
	</para>


	</section>

	</chapter>