.\" Copyright (c) 2011 Ed Schouten .\" All rights reserved. .\" .\" Redistribution and use in source and binary forms, with or without .\" modification, are permitted provided that the following conditions .\" are met: .\" 1. Redistributions of source code must retain the above copyright .\" notice, this list of conditions and the following disclaimer. .\" 2. Redistributions in binary form must reproduce the above copyright .\" notice, this list of conditions and the following disclaimer in the .\" documentation and/or other materials provided with the distribution. .\" .\" THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND .\" ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE .\" IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE .\" ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE .\" FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL .\" DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS .\" OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) .\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT .\" LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY .\" OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF .\" SUCH DAMAGE. .\" .\" $FreeBSD: head/share/man/man3/ATOMIC_VAR_INIT.3 276255 2014-12-26 21:11:33Z bapt $ .\" .Dd December 27, 2011 .Dt ATOMIC_VAR_INIT 3 .Os .Sh NAME .Nm ATOMIC_VAR_INIT , .Nm atomic_init , .Nm atomic_load , .Nm atomic_store , .Nm atomic_exchange , .Nm atomic_compare_exchange_strong , .Nm atomic_compare_exchange_weak , .Nm atomic_fetch_add , .Nm atomic_fetch_and , .Nm atomic_fetch_or , .Nm atomic_fetch_sub , .Nm atomic_fetch_xor , .Nm atomic_is_lock_free .Nd type-generic atomic operations .Sh SYNOPSIS .In stdatomic.h .Pp _Atomic(T) .Fa v = ATOMIC_VAR_INIT(c); .Ft void .Fn atomic_init "_Atomic(T) *object" "T value" .Ft T .Fn atomic_load "_Atomic(T) *object" .Ft T .Fn atomic_load_explicit "_Atomic(T) *object" "memory_order order" .Ft void .Fn atomic_store "_Atomic(T) *object" "T desired" .Ft void .Fn atomic_store_explicit "_Atomic(T) *object" "T desired" "memory_order order" .Ft T .Fn atomic_exchange "_Atomic(T) *object" "T desired" .Ft T .Fn atomic_exchange_explicit "_Atomic(T) *object" "T desired" "memory_order order" .Ft _Bool .Fn atomic_compare_exchange_strong "_Atomic(T) *object" "T *expected" "T desired" .Ft _Bool .Fn atomic_compare_exchange_strong_explicit "_Atomic(T) *object" "T *expected" "T desired" "memory_order success" "memory_order failure" .Ft _Bool .Fn atomic_compare_exchange_weak "_Atomic(T) *object" "T *expected" "T desired" .Ft _Bool .Fn atomic_compare_exchange_weak_explicit "_Atomic(T) *object" "T *expected" "T desired" "memory_order success" "memory_order failure" .Ft T .Fn atomic_fetch_add "_Atomic(T) *object" "T operand" .Ft T .Fn atomic_fetch_add_explicit "_Atomic(T) *object" "T operand" "memory_order order" .Ft T .Fn atomic_fetch_and "_Atomic(T) *object" "T operand" .Ft T .Fn atomic_fetch_and_explicit "_Atomic(T) *object" "T operand" "memory_order order" .Ft T .Fn atomic_fetch_or "_Atomic(T) *object" "T operand" .Ft T .Fn atomic_fetch_or_explicit "_Atomic(T) *object" "T operand" "memory_order order" .Ft T .Fn atomic_fetch_sub "_Atomic(T) *object" "T operand" .Ft T .Fn atomic_fetch_sub_explicit "_Atomic(T) *object" "T operand" "memory_order order" .Ft T .Fn atomic_fetch_xor "_Atomic(T) *object" "T operand" .Ft T .Fn atomic_fetch_xor_explicit "_Atomic(T) *object" "T operand" "memory_order order" .Ft _Bool .Fn atomic_is_lock_free "const _Atomic(T) *object" .Sh DESCRIPTION The header .In stdatomic.h provides type-generic macros for atomic operations. Atomic operations can be used by multithreaded programs to provide shared variables between threads that in most cases may be modified without acquiring locks. .Pp Atomic variables are declared using the .Fn _Atomic type specifier. These variables are not type-compatible with their non-atomic counterparts. Depending on the compiler used, atomic variables may be opaque and can therefore only be influenced using the macros described. .Pp The .Fn atomic_init macro initializes the atomic variable .Fa object with a .Fa value . Atomic variables can be initialized while being declared using .Fn ATOMIC_VAR_INIT . .Pp The .Fn atomic_load macro returns the value of atomic variable .Fa object . The .Fn atomic_store macro sets the atomic variable .Fa object to its .Fa desired value. .Pp The .Fn atomic_exchange macro combines the behaviour of .Fn atomic_load and .Fn atomic_store . It sets the atomic variable .Fa object to its desired .Fa value and returns the original contents of the atomic variable. .Pp The .Fn atomic_compare_exchange_strong macro stores a .Fa desired value into atomic variable .Fa object , only if the atomic variable is equal to its .Fa expected value. Upon success, the macro returns .Dv true . Upon failure, the .Fa desired value is overwritten with the value of the atomic variable and .Dv false is returned. The .Fn atomic_compare_exchange_weak macro is identical to .Fn atomic_compare_exchange_strong , but is allowed to fail even if atomic variable .Fa object is equal to its .Fa expected value. .Pp The .Fn atomic_fetch_add macro adds the value .Fa operand to atomic variable .Fa object and returns the original contents of the atomic variable. .Pp The .Fn atomic_fetch_and macro applies the .Em and operator to atomic variable .Fa object and .Fa operand and stores the value into .Fa object , while returning the original contents of the atomic variable. .Pp The .Fn atomic_fetch_or macro applies the .Em or operator to atomic variable .Fa object and .Fa operand and stores the value into .Fa object , while returning the original contents of the atomic variable. .Pp The .Fn atomic_fetch_sub macro subtracts the value .Fa operand from atomic variable .Fa object and returns the original contents of the atomic variable. .Pp The .Fn atomic_fetch_xor macro applies the .Em xor operator to atomic variable .Fa object and .Fa operand and stores the value into .Fa object , while returning the original contents of the atomic variable. .Pp The .Fn atomic_is_lock_free macro returns whether atomic variable .Fa object uses locks when using atomic operations. .Sh BARRIERS The atomic operations described previously are implemented in such a way that they disallow both the compiler and the executing processor to re-order any nearby memory operations across the atomic operation. In certain cases this behaviour may cause suboptimal performance. To mitigate this, every atomic operation has an .Fn _explicit version that allows the re-ordering to be configured. .Pp The .Fa order parameter of these .Fn _explicit macros can have one of the following values. .Bl -tag -width memory_order_relaxed .It Dv memory_order_relaxed No operation orders memory. .It Dv memory_order_consume Perform consume operation. .It Dv memory_order_acquire Acquire fence. .It Dv memory_order_release Release fence. .It Dv memory_order_acq_rel Acquire and release fence. .It Dv memory_order_seq_cst Sequentially consistent acquire and release fence. .El .Pp The previously described macros are identical to the .Fn _explicit macros, when .Fa order is .Dv memory_order_seq_cst . .Sh COMPILER SUPPORT These atomic operations are typically implemented by the compiler, as they must be implemented type-generically and must often use special hardware instructions. As this interface has not been adopted by most compilers yet, the .In stdatomic.h header implements these macros on top of existing compiler intrinsics to provide forward compatibility. .Pp This means that certain aspects of the interface, such as support for different barrier types may simply be ignored. When using GCC, all atomic operations are executed as if they are using .Dv memory_order_seq_cst . .Pp Instead of using the atomic operations provided by this interface, .St -isoC-2011 allows the atomic variables to be modified directly using built-in language operators. This behaviour cannot be emulated for older compilers. To prevent unintended non-atomic access to these variables, this header file places the atomic variable in a structure when using an older compiler. .Pp When using GCC on architectures on which it lacks support for built-in atomic intrinsics, these macros may emit function calls to fallback routines. These fallback routines are only implemented for 32-bits and 64-bits datatypes, if supported by the CPU. .Sh SEE ALSO .Xr pthread 3 , .Xr atomic 9 .Sh STANDARDS These macros attempt to conform to .St -isoC-2011 . .Sh HISTORY These macros appeared in .Fx 10.0 . .Sh AUTHORS .An \&Ed Schouten Aq Mt ed@FreeBSD.org .An David Chisnall Aq Mt theraven@FreeBSD.org