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If I don't care whether Thread1 changes Flag1 at the same time Thread2 changes Flag1, is there anything else to worry about besides logic errors? Will it cause a crash etc if:

  1. Thread1 and Thread2 read Flag1 at the exact same time?
  2. Thread1 is writing to Flag1 at the same time as Thread2 is reading Flag1?

In these examples, Flag1 is a bool.

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You might want to think carefully about what "the exact same time" really means and how these operation occur on a digital device. – dmckee May 20 '12 at 23:30
Neither will acsue a crash by itself unless the flag is a property of an objecttyat might not be instanced. But you could miss changes in state, or detect the same one in both threads. So what would happen would depend on what the change in state does. Making it thread safe is much easier than trying to cope with the fallout of it being unsafe – Tony Hopkinson May 20 '12 at 23:40
"besides logic errors" since you don't care about program logic, why do you even bother? A simpler program is "hello world". It may not do what you wanted to do, but when you don't care about logic errors... – curiousguy Aug 14 '15 at 8:24
up vote 6 down vote accepted

According to the rules of the C++11 memory model:

  1. Thread1 and Thread2 read Flag1 at the exact same time? This is always safe.
  2. Thread1 is writing to Flag1 at the same times as Thread2 is reading flag1? This is a data race.

A data race is undefined behaviour. Although it's unlikely to crash on any sane hardware, it's undefined behaviour, so anything could happen.

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Who said it's C++11? – Eitan T May 21 '12 at 0:05
C++03 doesn't mention threading so there's no guarantee of anything working at all. C++11 offers guarantees whih are agreed on by compiler and hardware vendors, and mostly represent a formalisation of existing practice. Do you have a better source for what's guaranteed and what isn't? I don't, so can only answer in terms of the C++11 memory model. – Jonathan Wakely May 21 '12 at 0:09
@EitanT: The question is tagged "c++ multithreading". There is no concept of "thread" in C++03, so by inference this must be C++11, and Jonathan's answer is the only correct one so far. If the questioner wants to know about some platform-specific threading model, he needs to identify the platform. – Nemo May 21 '12 at 0:13
So do you have a better reference for the semantics of data races in C++? – Jonathan Wakely May 21 '12 at 0:25
@EitanT, no, it's not irrelevant, because the C++11 memory model is in many ways a formal definition of existing practice. Do you know any compilers which plan to implement a different memory model now or in the future? If not, then surely advising people to follow those rules is sensible. – Jonathan Wakely May 21 '12 at 0:55

As far as I know, 2 threads cannot access the same memory in the exact same time.

Even on parallel computing, these assumptions would be handled automatically by the processor. http://en.wikipedia.org/wiki/Parallel_Random_Access_Machine

So the answer is no crash. You will have logic errors of course but since you don't care :p.

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"2 threads cannot access the same memory in the same time." And what about shared memory? – Eitan T May 20 '12 at 23:37
Same time meaning in clock time. They actually take turns to access memory. – Samy Arous May 20 '12 at 23:39
I see what you mean now, but I'd say that your phrasing is somewhat misleading. – Eitan T May 20 '12 at 23:41
yes but I can't find a better way. any help? – Samy Arous May 20 '12 at 23:42
I would say that in the simplest model (that I believe the OP is referring to), two threads may be said to run concurrently but technically they don't. And therefore simultaneous physical access to the same address is impossible. – Eitan T May 21 '12 at 0:59

The flag should be marked as volatile. This will ensure your compiler does not optimize read/writes in a way that is inconsistant.

I believe read/writes to bool are atomic - so I don't think you will have any other issues if you don't care about the order of access.

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No, volatile has nothing to do with threading, and no, accesses to bool are not guaranteed to be atomic in general (some hardware might give stronger guarantees, but that's not portable.) Although volatile will prevent the compiler re-ordering reads and writes it does nothing to prevent the hardware re-ordering them. Use atomic types or atomic operations to get the correct semantics. – Jonathan Wakely May 21 '12 at 0:01
@JonathanWakely umm.. I'm sorry I don't understand - why do you say volatile has nothing to do with threading? – Chip May 21 '12 at 0:06
@JonathanWakely - he doesn't care about re-ordering – Chip May 21 '12 at 0:08
So why suggest volatile? It has nothing to do with threading, see hpl.hp.com/personal/Hans_Boehm/c++mm/user-faq.html – Jonathan Wakely May 21 '12 at 0:14
@JonathanWakely I specifically mentioned that volatile is to prevent the compiler from making optimizations. Its a best effort suggestion. We don't want the compiler to optimize out the whole condition on the flag, do we? Clearly, he doesn't care about the order - so no-need to use atomic. – Chip May 21 '12 at 0:27

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