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I want to verify that my understanding is correct. This kind of thing is tricky so I'm almost sure I am missing something. I have a program consisting of a real-time thread and a non-real-time thread. I want the non-RT thread to be able to swap a pointer to memory that is used by the RT thread.
From the docs, my understanding is that this can be accomplished in g++ with:
// global
Data *rt_data;
Data *swap_data(Data *new_data)
{
#ifdef __GNUC__
// Atomic pointer swap.
Data *old_d = __sync_lock_test_and_set(&rt_data, new_data);
#else
// Non-atomic, cross your fingers.
Data *old_d = rt_data;
rt_data = new_data;
#endif
return old_d;
}
This is the only place in the program (other than initial setup) where rt_data is modified. When rt_data is used in the real-time context, it is copied to a local pointer. For old_d, later on when it is sure that the old memory is not used, it will be freed in the non-RT thread. Is this correct? Do I need volatile anywhere? Are there other synchronization primitives I should be calling?
By the way I am doing this in C++, although I'm interested in whether the answer differs for C.
Thanks ahead of time.
Generally don't use
volatilewhen writing concurrent code inC/C++. The semantics ofvolatileare so close to what you want that it is tempting but in the end volatile is not enough. UnfortunatelyJava/C# volatile != C/C++ volatile. Herb Sutter has a great article explaining the confusing mess.What you really want is a memory fence.
__sync_lock_test_and_setprovides the fencing for you.You will also need a memory fence when you copy (load) the rt_data pointer to your local copy.
Lock free programming is tricky. If you're willing to use Gcc's c++0x extensions, it's a bit easier:
Update: This answer is not correct, as I am missing the fact that
volatileguarantees that accesses tovolatilevariables are not reordered, but provides no such guarantees with respect to other non-volatileaccesses and manipulations. A memory fence does provide such guarantees, and is necessary for this application. My original answer is below, but do not act on it. See this answer for a good explanation in the hole in my understanding that led to the following incorrect response.Original answer:
Yes, you need
volatileon yourrt_datadeclaration; any time a variable can be modified outside the flow of control of a thread accessing it, it should be declaredvolatile. While you may be able to get away withoutvolatilesince you're copying to a local pointer,volatileat least helps with documentation and also inhibits some compiler optimizations that can cause problems. Consider the following example, adopted from DDJ:If it is possible for
ato have its value changed betweena=1andb=a, thenashould be declaredvolatile(unless, of course, assigning an out-of-date value tobis acceptable). Multithreading, particularly with atomic primitives, constitutes such a situation. The situation is also triggered with variables modified by signal handlers and by variables mapped to odd memory locations (e.g. hardware I/O registers). See also this question.Otherwise, it looks fine to me.
In C, I would probably use the atomic primitives provided by GLib for this. They'll use an atomic operation where available and fall back to a slow-but-correct mutex-based implementation if the atomic operations are not available. Boost may provide something similar for C++.