src/parsec/disk-image/parsec/parsec-benchmark/pkgs/libs/glib/src/docs/reference/glib/tmpl/atomic_operations.sgml - public/gem5-resources - Git at Google

 <!-- ##### SECTION Title ##### -->
 Atomic Operations

 <!-- ##### SECTION Short_Description ##### -->
 basic atomic integer and pointer operations

 <!-- ##### SECTION Long_Description ##### -->
 <para>
 The following functions can be used to atomically access integers and
 pointers. They are implemented as inline assembler function on most
 platforms and use slower fall-backs otherwise. Using them can sometimes
 save you from using a performance-expensive #GMutex to protect the
 integer or pointer.
 </para>

 <para>
 The most important usage is reference counting. Using
 g_atomic_int_inc() and g_atomic_int_dec_and_test() makes reference
 counting a very fast operation.
 </para>

 <note>
 <para>
 You must not directly read integers or pointers concurrently accessed
 by multiple threads, but use the atomic accessor functions instead.
 That is, always use g_atomic_int_get() and g_atomic_pointer_get() for
 read outs.
 They provide the neccessary synchonization mechanisms like memory
 barriers to access memory locations concurrently.
 </para>
 </note>

 <note>
 <para>
 If you are using those functions for anything apart from simple
 reference counting, you should really be aware of the implications of
 doing that. There are literally thousands of ways to shoot yourself in
 the foot. So if in doubt, use a #GMutex. If you don't know, what
 memory barriers are, do not use anything but g_atomic_int_inc() and
 g_atomic_int_dec_and_test().
 </para>
 </note>

 <note>
 <para>
 It is not safe to set an integer or pointer just by assigning to it,
 when it is concurrently accessed by other threads with the following
 functions. Use g_atomic_int_compare_and_exchange() or
 g_atomic_pointer_compare_and_exchange() respectively.
 </para>
 </note>

 <!-- ##### SECTION See_Also ##### -->
 <para>
 <variablelist>

 <varlistentry>
 <term>#GMutex</term>
 <listitem><para>GLib mutual exclusions.</para></listitem>
 </varlistentry>

 </variablelist>
 </para>

 <!-- ##### SECTION Stability_Level ##### -->


 <!-- ##### SECTION Image ##### -->


 <!-- ##### FUNCTION g_atomic_int_get ##### -->
 <para>
 Reads the value of the integer pointed to by @atomic. Also acts as
 a memory barrier.
 </para>

 @atomic: a pointer to an integer
 @Returns: the value of *@atomic
 @Since: 2.4


 <!-- ##### FUNCTION g_atomic_int_set ##### -->
 <para>
 Sets the value of the integer pointed to by @atomic.
 Also acts as a memory barrier.
 </para>

 @atomic: a pointer to an integer
 @newval: the new value
 @Since: 2.10


 <!-- ##### FUNCTION g_atomic_int_add ##### -->
 <para>
 Atomically adds @val to the integer pointed to by @atomic.
 Also acts as a memory barrier.
 </para>

 @atomic: a pointer to an integer.
 @val: the value to add to *@atomic.
 @Since: 2.4


 <!-- ##### FUNCTION g_atomic_int_exchange_and_add ##### -->
 <para>
 Atomically adds @val to the integer pointed to by @atomic. It returns
 the value of *@atomic just before the addition took place.
 Also acts as a memory barrier.
 </para>

 @atomic: a pointer to an integer.
 @val: the value to add to *@atomic.
 @Returns: the value of *@atomic before the addition.
 @Since: 2.4


 <!-- ##### FUNCTION g_atomic_int_compare_and_exchange ##### -->
 <para>
 Compares @oldval with the integer pointed to by @atomic and
 if they are equal, atomically exchanges *@atomic with @newval.
 Also acts as a memory barrier.
 </para>

 @atomic: a pointer to an integer.
 @oldval: the assumed old value of *@atomic.
 @newval: the new value of *@atomic.
 @Returns: %TRUE, if *@atomic was equal @oldval. %FALSE otherwise.
 @Since: 2.4


 <!-- ##### FUNCTION g_atomic_pointer_get ##### -->
 <para>
 Reads the value of the pointer pointed to by @atomic. Also acts as
 a memory barrier.
 </para>

 @atomic: a pointer to a #gpointer.
 @Returns: the value to add to *@atomic.
 @Since: 2.4


 <!-- ##### FUNCTION g_atomic_pointer_set ##### -->
 <para>
 Sets the value of the pointer pointed to by @atomic.
 Also acts as a memory barrier.
 </para>

 @atomic: a pointer to a #gpointer
 @newval: the new value
 @Since: 2.10


 <!-- ##### FUNCTION g_atomic_pointer_compare_and_exchange ##### -->
 <para>
 Compares @oldval with the pointer pointed to by @atomic and
 if they are equal, atomically exchanges *@atomic with @newval.
 Also acts as a memory barrier.
 </para>

 @atomic: a pointer to a #gpointer.
 @oldval: the assumed old value of *@atomic.
 @newval: the new value of *@atomic.
 @Returns: %TRUE, if *@atomic was equal @oldval. %FALSE otherwise.
 @Since: 2.4


 <!-- ##### FUNCTION g_atomic_int_inc ##### -->
 <para>
 Atomically increments the integer pointed to by @atomic by 1.
 </para>

 @atomic: a pointer to an integer.
 @Since: 2.4


 <!-- ##### FUNCTION g_atomic_int_dec_and_test ##### -->
 <para>
 Atomically decrements the integer pointed to by @atomic by 1.
 </para>

 @atomic: a pointer to an integer.
 @Returns: %TRUE, if the integer pointed to by @atomic is 0 after
 decrementing it.
 @Since: 2.4
	<!-- ##### SECTION Title ##### -->
	Atomic Operations

	<!-- ##### SECTION Short_Description ##### -->
	basic atomic integer and pointer operations

	<!-- ##### SECTION Long_Description ##### -->
	<para>
	The following functions can be used to atomically access integers and
	pointers. They are implemented as inline assembler function on most
	platforms and use slower fall-backs otherwise. Using them can sometimes
	save you from using a performance-expensive #GMutex to protect the
	integer or pointer.
	</para>

	<para>
	The most important usage is reference counting. Using
	g_atomic_int_inc() and g_atomic_int_dec_and_test() makes reference
	counting a very fast operation.
	</para>

	<note>
	<para>
	You must not directly read integers or pointers concurrently accessed
	by multiple threads, but use the atomic accessor functions instead.
	That is, always use g_atomic_int_get() and g_atomic_pointer_get() for
	read outs.
	They provide the neccessary synchonization mechanisms like memory
	barriers to access memory locations concurrently.
	</para>
	</note>

	<note>
	<para>
	If you are using those functions for anything apart from simple
	reference counting, you should really be aware of the implications of
	doing that. There are literally thousands of ways to shoot yourself in
	the foot. So if in doubt, use a #GMutex. If you don't know, what
	memory barriers are, do not use anything but g_atomic_int_inc() and
	g_atomic_int_dec_and_test().
	</para>
	</note>

	<note>
	<para>
	It is not safe to set an integer or pointer just by assigning to it,
	when it is concurrently accessed by other threads with the following
	functions. Use g_atomic_int_compare_and_exchange() or
	g_atomic_pointer_compare_and_exchange() respectively.
	</para>
	</note>

	<!-- ##### SECTION See_Also ##### -->
	<para>
	<variablelist>

	<varlistentry>
	<term>#GMutex</term>
	<listitem><para>GLib mutual exclusions.</para></listitem>
	</varlistentry>

	</variablelist>
	</para>

	<!-- ##### SECTION Stability_Level ##### -->


	<!-- ##### SECTION Image ##### -->


	<!-- ##### FUNCTION g_atomic_int_get ##### -->
	<para>
	Reads the value of the integer pointed to by @atomic. Also acts as
	a memory barrier.
	</para>

	@atomic: a pointer to an integer
	@Returns: the value of *@atomic
	@Since: 2.4


	<!-- ##### FUNCTION g_atomic_int_set ##### -->
	<para>
	Sets the value of the integer pointed to by @atomic.
	Also acts as a memory barrier.
	</para>

	@atomic: a pointer to an integer
	@newval: the new value
	@Since: 2.10


	<!-- ##### FUNCTION g_atomic_int_add ##### -->
	<para>
	Atomically adds @val to the integer pointed to by @atomic.
	Also acts as a memory barrier.
	</para>

	@atomic: a pointer to an integer.
	@val: the value to add to *@atomic.
	@Since: 2.4


	<!-- ##### FUNCTION g_atomic_int_exchange_and_add ##### -->
	<para>
	Atomically adds @val to the integer pointed to by @atomic. It returns
	the value of *@atomic just before the addition took place.
	Also acts as a memory barrier.
	</para>

	@atomic: a pointer to an integer.
	@val: the value to add to *@atomic.
	@Returns: the value of *@atomic before the addition.
	@Since: 2.4


	<!-- ##### FUNCTION g_atomic_int_compare_and_exchange ##### -->
	<para>
	Compares @oldval with the integer pointed to by @atomic and
	if they are equal, atomically exchanges *@atomic with @newval.
	Also acts as a memory barrier.
	</para>

	@atomic: a pointer to an integer.
	@oldval: the assumed old value of *@atomic.
	@newval: the new value of *@atomic.
	@Returns: %TRUE, if *@atomic was equal @oldval. %FALSE otherwise.
	@Since: 2.4


	<!-- ##### FUNCTION g_atomic_pointer_get ##### -->
	<para>
	Reads the value of the pointer pointed to by @atomic. Also acts as
	a memory barrier.
	</para>

	@atomic: a pointer to a #gpointer.
	@Returns: the value to add to *@atomic.
	@Since: 2.4


	<!-- ##### FUNCTION g_atomic_pointer_set ##### -->
	<para>
	Sets the value of the pointer pointed to by @atomic.
	Also acts as a memory barrier.
	</para>

	@atomic: a pointer to a #gpointer
	@newval: the new value
	@Since: 2.10


	<!-- ##### FUNCTION g_atomic_pointer_compare_and_exchange ##### -->
	<para>
	Compares @oldval with the pointer pointed to by @atomic and
	if they are equal, atomically exchanges *@atomic with @newval.
	Also acts as a memory barrier.
	</para>

	@atomic: a pointer to a #gpointer.
	@oldval: the assumed old value of *@atomic.
	@newval: the new value of *@atomic.
	@Returns: %TRUE, if *@atomic was equal @oldval. %FALSE otherwise.
	@Since: 2.4


	<!-- ##### FUNCTION g_atomic_int_inc ##### -->
	<para>
	Atomically increments the integer pointed to by @atomic by 1.
	</para>

	@atomic: a pointer to an integer.
	@Since: 2.4


	<!-- ##### FUNCTION g_atomic_int_dec_and_test ##### -->
	<para>
	Atomically decrements the integer pointed to by @atomic by 1.
	</para>

	@atomic: a pointer to an integer.
	@Returns: %TRUE, if the integer pointed to by @atomic is 0 after
	decrementing it.
	@Since: 2.4