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I have a program which spawns multiple threads that may write the exact same value to the exact same memory location:

std::vector<int> vec(32, 1); // Initialize vec with 32 times 1
std::vector<std::thread> threads;
for (int i = 0 ; i < 8 ; ++i)
        for (std::size_t j = 0 ; j < vec.size() ; ++j)
            vec[j] = 0;

for (auto& thrd: threads)

// Read vec values

In this simplified code, all the threads may try to write the exact same value to the same memomry location in vec. Is this a data race likely to trigger undefined behavior, or is it safe since the values are never read before all the threads are joined again?

If there is a potentially hazardous data race, will using a std::vector<std::atomic<int>> instead with std::memory_order_relaxed stores instead be enough to prevent the data races?

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It is actually fairly easy to determine if something is data-race-UB or not: If more than one write, but no read, can be executed at the same time, you're in trouble. If more than one read, but no write happens, you're fine. If one write and at least one read happens at the same time, you're screwed again. Short: (>1 write) OR (write+read) is trouble. – stefan Apr 13 '14 at 13:23
Use atomics and you're safe. I see no reason to introduce UB here. – usr Apr 13 '14 at 13:47

3 Answers 3

up vote 4 down vote accepted

Language-lawyer answer, [intro.multithread] n3485

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. Any such data race results in undefined behavior.

4 Two expression evaluations conflict if one of them modifies a memory location and the other one accesses or modifies the same memory location.

will using a std::vector<std::atomic<int>> instead with std::memory_order_relaxed stores instead be enough to prevent the data races?

Yes. Those accesses are atomic, and there's a happens-before relationship introduced via the joining of the threads. Any subsequent read from the thread spawning those workers (which is synchronized via .join) is safe and defined.

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Implementation detail answer:

While the language standard classifies this as undefined behavior, you can actually feel quite safe as long as you are really writing the same data.

Why? The hardware sequentializes accesses to the same memory cell. The only thing that can go wrong is when several memory cells are written at the same time, because then you have no guarantee by the hardware that the accesses to several cells are sequentialized in the same way. For example, if one process writes 0x0000000000000000, and another writes 0xffffffffffffffff, your hardware may decide to sequentialize the accesses to the different bytes differently, resulting in something like 0x00000000ffffffff.

However, if the data written by both processes is the same, then there is no noticeable difference between the two possible serializations, the result is deterministic.

Modern hardware does not handle memory accesses in a byte by byte fashion, instead, CPUs communicate with the main memory in terms of cache lines, and cores can usually communicate with their caches in terms of 8-byte words. As such, setting a properly aligned pointer is an atomic operation which can be relied on to implement lockfree algorithms. This has been exploited in the Linux kernel before more powerful atomic operations became available. C++ formalizes this in the form of atomic<> types, adding support for the more high level hardware features like write after read, atomic increments and such.

But, of course, if you rely on your hardware details, you really should know what you are doing before you do it. Otherwise stick to language features like the atomic<> types to ensure proper operations and avoid UB.

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You also cannot rely on the compiler to not exploit the UB. The loop is essentially a memzero. Who knows what the compiler does to that? – usr Apr 13 '14 at 13:48
@usr Well, the optimizer can usually be relied on not to understand concurrency issues. It would make optimization far too complex, and the only effect would be to break multi-threaded code. And there is no UB behavior in the loop when you assume that there is only one thread. – cmaster Apr 13 '14 at 13:52
"Why? The hardware sequentializes accesses to the same memory cell." You have an oracle that knows every kind of hardware upon which the OPs program will ever run? – Casey Apr 13 '14 at 14:14
@Casey No, I don't, but I know how bytes are transfered to main memory; and I even have a bit of a notion about what is feasible in hardware, and what is not. Consequently, I'm quite certain that the OP's program will never run on a hardware where two concurrent writes of the same data lead to undefined behavior. But, of course, this is the implementation detail answer :-) – cmaster Apr 13 '14 at 15:11

It is a data race and compilers will eventually become smart enough to miscompile the code if they are not already. See How to miscompile programs with "benign" data races section 2.4 for why writes of the same value break the code.

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This was intended as a comment to the Language-lawyer answer by dyp to show that it actually has consequences, but I lack the required reputation. – nwp Apr 14 '14 at 10:53

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