He is example of atomic_read implementation:
#define atomic_read(v) (*(volatile int *)&(v)->counter)
Also, should we explicitly use memory barriers for atomic operations on arm?
He is example of atomic_read implementation:
A problematic one actually, which assumes that a cast is not a nop, which isn't guaranteed.
Also, should we explicitly use memory barriers for atomic operations on arm?
Probably. It depends on what you are doing and what you are expecting.
counter
itself is an atomic_t; it can be cached after a read. The important part is to read the entire value and not just a part of it and to do it at the sequence point. I think the accepted answer is wrong and was only adding a comment that your answer was more correct.
Oct 26, 2019 at 22:12
Yes, the casting to volatile is to prevent the compiler from assuming the value of v cannot change. As for using memory barriers, the GCC builtins already allow you to specify the memory ordering you desire, no need to do it manually: https://gcc.gnu.org/onlinedocs/gcc-9.2.0/gcc/_005f_005fatomic-Builtins.html#g_t_005f_005fatomic-Builtins
The default behavior on GCC is to use __ATOMIC_SEQ_CST
which will emit the barriers necessary on Arm to make sure your atomics execute in the order you place them in the code. To optimize performance on Arm, you will want to consider using weaker semantics to allow the compiler to elide barriers and let the hardware execute faster. For more information on the types of memory barriers the Arm architecture has, see https://developer.arm.com/docs/den0024/latest/memory-ordering/barriers.
register
). Notevolatile sig_atomic_t
is in standard C, and so it has also some meaning for all compilers (unlikeregister
that can be ignored).atomic_read_acquire()
andatomic_set_release()
defined, which provide memory ordering.