How does sig_atomic_t actually work?
How does the compiler or OS distinguish between sig_atomic_t type and a normal int type variable, and ensures that the operation will be atomic? Programs using both have same assembler code. How extra care is taken to make the operation atomic?
Solution 1:
sig_atomic_t
is not an atomic data type. It is just the data type that you are allowed to use in the context of a signal handler, that is all. So better read the name as "atomic relative to signal handling".
To guarantee communication with and from a signal handler, only one of the properties of atomic data types is needed, namely the fact that read and update will always see a consistent value. Other data types (such as perhaps long long
) could be written with several assembler instructions for the lower and higher part, e.g. sig_atomic_t
is guaranteed to be read and written in one go.
So a platform may choose any integer base type as sig_atomic_t
for which it can make the guarantee that volatile sig_atomic_t
can be safely used in signal handlers. Many platforms chose int
for this, because they know that for them int
is written with a single instruction.
The latest C standard, C11, has atomic types, but which are a completely different thing. Some of them (those that are "lockfree") may also be used in signal handlers, but that again is a completely different story.
Solution 2:
Note that sig_atomic_t
is not thread-safe, only async-signal safe.
Atomics involve two types of barriers:
- Compiler barrier. It makes sure that the compiler does not reorder reads/writes from/to an atomic variable relative to reads and writes to other variables. This is what
volatile
keyword does. - CPU barrier and visibility. It makes sure that the CPU does not reorder reads and writes. On x86 all loads and stores to aligned 1,2,4,8-byte storage are atomic. Visibility makes sure that stores become visible to other threads. Again, on Intel CPUs, stores are visible immediately to other threads due to cache coherence and memory coherence protocol MESI. But that may change in the future. See §8.1 LOCKED ATOMIC OPERATIONS in Intel® 64 and IA-32 Architectures Software Developer’s Manual Volume 3A for more details.
For comprehensive treatment of the subject watch atomic Weapons: The C++ Memory Model and Modern Hardware.
Solution 3:
sig_atomic_t
is often just a typedef
(to some system specific integral type, generally int
or long
). And it is very important to use volatile sig_atomic_t
(not just sig_atomic_t
alone).
When you add the volatile
keyword, the compiler has to avoid a lot of optimizations.
The recent C11 standard added _Atomic
and <stdatomic.h>
. You need a very recent GCC (e.g. 4.9) to have it supported.