16

cppreference.com documents this function as "fence between a thread and a signal handler executed in the same thread". But I found no example on the Internet.

I wonder whether or not the following psuedo-code correctly illustrates the function of std::atomic_signal_fence():

int n = 0;
SignalObject s;

void thread_1()
{
    s.wait();
    std::atomic_signal_fence(std::memory_order_acquire);
    assert(1 == n); // never fires ???
}

void thread_2()
{
    n = 1;
    s.signal();
}

int main()
{
    std::thread t1(thread_1);
    std::thread t2(thread_2);

    t1.join(); t2.join();
}
7
  • 4
    I think a signal handler is a from a unix system type signal, which has special threading rules. Jan 29, 2013 at 10:54
  • 7
    You don't have any signal handlers in your code, so no, the code does not demonstrate anything meaningful about atomic_signal_fence.
    – Kerrek SB
    Jan 29, 2013 at 12:04
  • 3
    @StefanDragnev - with proper fences there's no need for volatile. That's what atomics and fences are all about. Jan 29, 2013 at 14:04
  • 5
    @StefanDragnev - no, with a fence or any other atomic operation (with an appropriate memory access specifier) the compiler is not allowed to do that. In that context, volatile is redundant. Jan 29, 2013 at 15:28
  • 3
    A signal_fence is a "compiler" barrier: it prevents compile-time reordering/combining/hoisting of memory operations, but will never emit a hardware memory barrier instructions. Jeff Preshing's blog is excellent at explaining this stuff, definitely a must-read if you're unsure about memory-ordering stuff. Feb 15, 2016 at 17:37

2 Answers 2

23

No, your code does not demonstrate correct usage of atomic_signal_fence. As you quote cppreference.com, atomic_signal_fence only perform synchronization between a signal handler and other code running on the same thread. That means that it does not perform synchronization between two different threads. Your example code shows two different threads.

The C++ spec contains the following notes about this function:

Note: compiler optimizations and reorderings of loads and stores are inhibited in the same way as with atomic_thread_fence, but the hardware fence instructions that atomic_thread_fence would have inserted are not emitted.

Note: atomic_signal_fence can be used to specify the order in which actions performed by the thread become visible to the signal handler.

Here's an example of correct, if not motivating, usage:

static_assert(2 == ATOMIC_INT_LOCK_FREE, "this implementation does not guarantee that std::atomic<int> is always lock free.");

std::atomic<int> a = 0;
std::atomic<int> b = 0;

extern "C" void handler(int) {
    if (1 == a.load(std::memory_order_relaxed)) {
        std::atomic_signal_fence(std::memory_order_acquire);
        assert(1 == b.load(std::memory_order_relaxed));
    }

    std::exit(0);
}

int main() {
    std::signal(SIGTERM, &handler);

    b.store(1, std::memory_order_relaxed);
    std::atomic_signal_fence(std::memory_order_release);
    a.store(1, std::memory_order_relaxed);
}

The assertion, if encountered, is guaranteed to hold true.

2
  • Are A and B necessarily atomic in your example?
    – Alex
    Jul 2, 2017 at 22:02
  • @Alex They need to have atomicity. Technically, it's almost never guaranteed w/o atomic.
    – curiousguy
    Feb 17, 2019 at 22:36
6

In your example, you want to use std::atomic_thread_fence (which generates machine code to perform thread synchronization); not std::atomic_signal_fence (which only disables compiler memory reordering optimizations on atomic variables). As was said by others, std::atomic_signal_fence is only intended for signals on the same thread as the atomic operations (I believe it would also hold true for structured/vectored exception handlers on Windows, but don't quote me on that).

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