Provided by: libatomic-ops-dev_7.4.2-3ubuntu1_amd64 
NAME
libatomic-ops - Library providing user level atomic operations
SYNOPSIS
#include <atomic_ops.h>
cc ... -latomic_ops
Note that all operations have an additional barrier option that can be set explicitly.
void AO_load(AO_t *addr)
void AO_store(AO_t *addr, AO_t val)
int AO_test_and_set (AO_t *addr)
AO_t AO_fetch_and_add(AO_t *addr, AO_t incr)
AO_t AO_fetch_and_add1(AO_t *addr)
AO_t AO_fetch_and_sub1(AO_t *addr)
void AO_or(AO_t *p, AO_t incr)
int AO_compare_and_swap(AO_t *addr, AO_t old, AO_t new_val)
DESCRIPTION
libatomic-ops offers a programming interface to a comprehensive range of atomic operations
at user level.
We define various atomic operations on memory in a machine-specific way. Unfortunately,
this is complicated by the fact that these may or may not be combined with various memory
barriers. Thus the actual operations we define have the form AO_<atomic-op>_<barrier> for
all plausible combinations of <atomic-op> and <barrier>.
The valid barrier suffixes are
_release
Earlier operations may not be delayed past it.
_acquire
Later operations may not move ahead of it.
_read Subsequent reads must follow this operation and preceding reads.
_write Earlier writes precede both this operation and later writes.
_full Ordered with respect to both earlier and later memops.
_release_write
Ordered with respect to earlier writes.
_acquire_read
Ordered with repsect to later reads.
This of course results in a mild combinatorial explosion.
The library will find the least expensive way to implement your operations on the
applicable hardware. In many cases that will involve, for example, a stronger memory
barrier, or a combination of hardware primitives.
Note that atomicity guarantees are valid only if both readers and writers use AO_
operations to access the shared value, while ordering constraints are intended to apply
all memory operations. If a location can potentially be accessed simultaneously from
multiple threads, and one of those accesses may be a write access, then all such accesses
to that location should be through AO_ primitives. However if AO_ operations enforce
sufficient ordering to ensure that a location x cannot be accessed concurrently, or can
only be read concurrently, then x can be accessed via ordinary references and assignments.
All operations operate on an AO_t value, which is the natural word size for the
architecture.
AO_load and AO_store load and store the specified pointer address.
AO_test_and_set atomically replaces an address with AO_TS_SET and returns the prior value.
An AO_TS_t location can be reset with the AO_CLEAR macro, which usually uses
AO_store_release
AO_fetch_and_add takes an address and a value to add.
AO_fetch_and_add1 and AO_fetch_and_sub1 are provided since they may have faster
implemenations on some hardware
AO_or atomically ors an AO_t value into a memory location, but does not provide access to
the original
AO_compare_and_swap takes an address, an old value and a new value and returns an int.
non-zero indicates the compare and swap succeeded.
SEE ALSO
libatomic-stack(3), libatomic-malloc(3)
AUTHOR
This manual page was written by Ian Wienand <ianw@gelato.unsw.edu.au>, based on comments
in the source code. It was written for the Debian project (but may be used by others).