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Given the code in this post, to implement Semaphore using only atomic<> and mutex.

I'm just curious that since count is already guarded by updateMutex, is atomic<> necessary?

struct Semaphore {
    int size;
    atomic<int> count;
    mutex updateMutex;

    Semaphore(int n) : size(n) { count.store(0); }

    void aquire() {
        while (1) {
            while (count >= size) {}
            updateMutex.lock();
            if (count >= size) {
                updateMutex.unlock();
                continue;
            }
            ++count;
            updateMutex.unlock();
            break;
        }
    }

    void release() {
        updateMutex.lock();
        if (count > 0) {
            --count;
        } // else log err
        updateMutex.unlock();
    }
};

Without atomic, I think the constructor would get synchronization problem. Assignment to count might not be visible if other threads are using it right after the construction.

If so, what about size? Does it also need to be protected by atomic<>?

Or the atomic<> is totally useless because both size and count will be visible no matter when other threads use them.

Thanks!

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How can a constructor have a synchronisation problem?! –  Kerrek SB Dec 29 '13 at 9:53
    
@KerrekSB Because the writes to size and count might not be immediately visible to threads on other core if no memory barrier is set, can't they? –  Xin Huang Dec 29 '13 at 9:57
    
How can the other threads even know of an object that doesn't exist? –  Kerrek SB Dec 29 '13 at 9:58
    
@KerrekSB You are right. If that do happen, then whatever synchronization is meaningless. –  Xin Huang Dec 29 '13 at 10:01
    
size and count are non-static members, so they cannot be accessed on other threads before constructor finishes: there is no object –  Drop Dec 29 '13 at 10:02

3 Answers 3

up vote 5 down vote accepted

There are multiple questions asked. All require that the underlying concept is understood: you have a data race if one object is written by at least one thread which is accessed (read or written) by another thread and the write and the access are not synchronized. The formal definition of data races is in 1.10 [intro.multithread] paragraph 21:

The execution of a program contains a data race if it contains two conflicting actions in different threads, at least one of which is not atomic, and neither happens before the other. [...]

A program which contains a data race has undefined behavior, i.e., the program needs to make sure that it is data race free. Now on to answering the different questions:

  1. Is it necessary to use synchronization in the constructor?

    It depends on whether the object may be access concurrently by different threads while it is still under construction. The only case I can imagine concurrent access to an object under construction is during static initialization where multiple thread are already kicked off accessing the shared object. Due to the weak constraints on the order of construction for global objects I can't imagine that global objects would be used anyway and construction of function local static objects is synchronized by the implementation. Otherwise, I would expect that a reference to the object would shared across threads using a suitably synchronized mechanism. That is, I would design the system such that the constructor doesn't require synchronization.

  2. There is a lock already. Does that mean that count doesn't have to be an atomic.

    Since count is accessed in the acquire() function before lock is obtained, it would be an unsynchronized access to an object which is written by another thread, i.e., you'd have a data race and, hence, undefined behavior. The count has to be atomic.

  3. Is it necessary for size to be synchronized, too.

    The size member is only modified in the constructor of Semaphore and it might be reasonable to enforce that by actually making it a const member. Assuming the object isn't concurrently accessed during construction (see 1. above) there is no potential for a data race when accessing size.

Note that you shouldn't really make unguarded use of the lock() and unlock() members of the mutex. Instead, you should use std::lock_guard<std::mutex> or std::unique_lock<std::mutex>, potentially with an auxiliary block. These two classes guarantee that an acquired lock will always be released. I'd also question if a busy wait for a semaphore acquiring a lock anyway is the right way to go.

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Sometimes people write code like while (dontstop) { run(); }, where dontstop is a non-atomic variable controlled in another thread. Like in this case, it's read-only. I think the "undefined behavior" refers to the value read from count is undetermined, am I right? –  Xin Huang Dec 31 '13 at 12:24
1  
@XinHuang: If dontstop is a non-synchronized object, e.g., a bool, char, int, ..., which is written by another thread, there is a data race and the program has undefined behavior. The rule as simple: if one thread writes and another thread reads synchronization is needed. Without synchronization you have undefined behavior. No exceptions. Have a look at this article on "benign" data races. –  Dietmar Kühl Dec 31 '13 at 13:17

I think the real reason for count to be an atomic<int> is that is is read in aquire() outside of the mutex-protected area in this line:

while (count >= size) {}

Without atomic, the compile is allowed to assume that reading it once is enough and it will not poll it for changed values from other threads.

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The why of your answer is practically correct, but the how of it describes volatility (volatile) rather than atomicity (atomic<T>). –  pilcrow Dec 29 '13 at 15:03
    
@pilcrow The "how" I referred to only shows one aspect of atomic that is used in this case. volatile shares this aspect but it is different as it would allow re-ordering of other memory accesses and it doesn't allow the compiler to understand what you are really trying to achieve. Maybe that's not a problem in this particular case, but in general I'd prefer atomic for multi-threaded code and volatile for accessing hardware registers. –  Daniel Frey Dec 29 '13 at 15:13
    
Yes. I'm aware of that. But sometimes people write code like while (dontstop) { run(); }, where dontstop is a non-atomic variable controlled in another thread. It's read-only, and there's guard with lock following. Would be atomic necessary? –  Xin Huang Dec 31 '13 at 12:23
    
@XinHuang If the compiler can see that run() does not touch dontstop and dontstop is non-atomic, the compiler is allowed to turn the code into if(dontstop) while(true) run();. No memory barrier will help you then. Technically, it's undefined behaviour so anything can happen. So yes, atomic is needed. –  Daniel Frey Dec 31 '13 at 13:00

Yes. There is a theoretical risk that:

count = 0;

in the constructor would not be observed by a different threading running on another CPU in time for a subsequent call to either acquire() or release(). The possibility of this happening is likely to be vanishingly small as the in order to use the semaphore object, the constructor must complete and somehow another thread needs to get hold of the object.

This is to say that the other CPU's view of the memory occupied by count would not be synchronised between CPUs, and another could read an old (e.g. uninitialised) value.

Using an std::atomic<int> here by default generates memory barriers around the loads (in this case via overloaded operators) and stores. By default, this is ultra-conservative. .

You could also lock and unlock the mutex in the constructor for the same effect - but this is even more expensive.

It must be said that this is a pretty nasty way of implementing a counting semaphore - but it was afterall an interview question, and as such has a lot of facets.

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So, thread A could construct an object, pass the resulting address to thread B, and thread B receives this address, but the memory operations that happened in the constructor have not been synchronized there? Doesn’t that violate the sequential consistency of the memory model? Or is this an effect that could only transpire for placement new? –  Christopher Creutzig Dec 29 '13 at 10:25
    
There are no guarantees of the order in which memory writes complete with respect to memory. It's entirely possible that a write of a pointer to a semaphore object could complete and be visible to thread B before data stored in the object. I'd hazard a guess that the C++ standard is not mandating a store barrier in every constructor? –  marko Dec 29 '13 at 10:29
    
The C++11 memory model has the basic sequential consistency guarantee for programs without race conditions, I thought? I believe that is what Scott Meyers teaches, anyway. So, if I store the address of the object after its constructor has succeeded, anyone who sees that stored address will also see initialized members, no? –  Christopher Creutzig Dec 29 '13 at 10:44
    
@ChristopherCreutzig: No, there is no reason to believe the address becomes visible to the second thread after the rest of the data is visible. Why? Because you haven't performed any synchronization. It is entirely possible that the second thread sees the address before the contents at that location are up-to-date. –  Mehrdad Dec 29 '13 at 11:00
    
Thanks. I re-watched Herb Sutter’s atomic<> Weapons talk and think I’ve learned a little bit more today. –  Christopher Creutzig Dec 29 '13 at 12:58

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