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Let's say I define a following C++ object:

class AClass
    AClass() : foo(0) {}
    uint32_t getFoo() { return foo; }
    void changeFoo() { foo = 5; }
    uint32_t foo;
} aObject;

The object is shared by two threads, T1 and T2. T1 is constantly calling getFoo() in a loop to obtain a number (which will be always 0 if changeFoo() was not called before). At some point, T2 calls changeFoo() to change it (without any thread synchronization).

Is there any practical chance that the values ever obtained by T1 will be different than 0 or 5 with modern computer architectures and compilers? All the assembler code I investigated so far was using 32-bit memory reads and writes, which seems to save the integrity of the operation.

What about other primitive types?

Practical means that you can give an example of an existing architecture or a standard-compliant compiler where this (or a similar situation with a different code) is theoretically possible. I leave the word modern a bit subjective.

Edit: I can see many people noticing that I should not expect 5 to be read ever. That is perfectly fine to me and I did not say I do (though thanks for pointing this aspect out). My question was more about what kind of data integrity violation can happen with the above code.

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The last paragraph makes little sense. A practical example of something where a certain outcome is theoretically possible? I suggest you remove one of those two words. :) –  jalf Feb 22 '13 at 9:15
It is theoretically possible that it will happen on every existing architecture with every standard-compliant compiler, because a standard-compliant compiler can choose to do whatever it likes when it encounters UB. In practice, compilers tend to be forgiving about UB, but it is certainly theoretically possible that they do all sorts of other weird things. –  jalf Feb 22 '13 at 9:16
@jalf It doesn't really matter here, since the code won't work as expected (that the reading thread will eventually see 5) on any architecture I know (certainly not with VC++ under Windows, g++ under Linux, or Sun CC under Solaris). –  James Kanze Feb 22 '13 at 9:18
Simply add volatile to your variable to avoid optimization surpirses: volatile uint32_t foo; –  KBart Feb 22 '13 at 9:23
James Kanze: volatile doesn't help compiler optimization, it hinders it. It directs the compiler that reads and writes cannot be folded / optimized away. The primary purpose is for accessing (memory-mapped) hardware registers. –  davmac Feb 22 '13 at 9:53

7 Answers 7

up vote 3 down vote accepted

In practice, all mainstream 32-bit architectures perform 32-bit reads and writes atomically. You'll never see anything other than 0 or 5.

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That is wrong. The compiler could change your program so that the changes will never be visible to other threads. –  bamboon Feb 22 '13 at 8:59
@bamboon: I made two claims. Which of them is false? –  Marcelo Cantos Feb 22 '13 at 9:00
Sorry, for being imprecise, I meant the later part. Two threads accessing a variable where one is a write and another is a read results in a race-condition which is UB per standard. –  bamboon Feb 22 '13 at 9:03
@bamboon: It's not a race condition if the load and store are atomic, which is exactly what I said in my response. –  Ed S. Feb 22 '13 at 9:05
+1 for a practical answer, not based on any religious beliefs. If you store/read variable in an atomic operation, there is no race condition and no undefined behaviour. –  KBart Feb 22 '13 at 9:10

In practice, you will not see anything else than 0 or 5 as far as I know (maybe some weird 16 bits architecture with 32 bits int where this is not the case).

However whether you actually see 5 at all is not guaranteed.

Suppose I am the compiler.

I see:

while (aObject.getFoo() == 0) {

I know that:

  • printf cannot change aObject
  • sleep cannot change aObject
  • getFoo does not change aObject (thanks inline definition)

And therefore I can safely transform the code:

while (true) {

Because there is no-one else accessing aObject during this loop, according to the C++ Standard.

That is what undefined behavior means: blown up expectations.

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But the question is "Is there any practical chance that the values ever obtained by T1 will be different than 0 or 5 with modern computer architectures and compilers?", and the answer is "no", so long as the load and store are atomic. –  Ed S. Feb 22 '13 at 9:19
@EdS.: and as long as neither of the two are optimized out (because otherwise they won't reach the CPU at all, and then it doesn't matter if they'd be executed atomically or not), but as this answer points out, the optimizer is allowed to optimize it out –  jalf Feb 22 '13 at 9:20
@EdS.: you might not like it, but this answer brings up a very important point, in that it explains how this code could fail to work practically speaking. It gives a plausible reason why a real compiler might break this code, without resorting to "nasal demons" or "ordering pizza" or "the compiler hates you and just wants to spite you". This answer points out why the optimizer might break the code in its quest to make your code fast. I think that's pretty significant. Because it means that even if every compiler today accepts the code, the next version might fail –  jalf Feb 22 '13 at 9:24
@EdS.: no, as you are so keen to point out, he asked something else. He assumes that "oh, we'll certainly get the values 0 and 5 eventually", so he instead asked "but will we also get other intermediate values". And no, we (practically speaking) won't, but his premise is flawed, because we might never see the value 5 either. So you're right, it doesn't technically speaking answer the question, but it answers what he needs to know. Because the assumption that led to the question is wrong. –  jalf Feb 22 '13 at 9:27
@Andrew: I am too savvy about volatile but I think that yes it would prevent this optimization. However volatile was originally meant for hardware access, and therefore there may be issues in the context of multithread related to the order in which writes become apparent to another thread. TL;DR: just use std::atomic<int> and let the compiler optimize. –  Matthieu M. Feb 22 '13 at 9:44

Not sure what you're looking for. On most modern architectures, there is a very distinct possibility that getFoo() always returns 0, even after changeFoo has been called. With just about any decent compiler, it's almost guaranteed that getFoo(), will always return the same value, regardless of any calls to changeFoo, if it is called in a tight loop.

Of course, in any real program, there will be other reads and writes, which will be totally unsynchronized with regards to the changes in foo.

And finally, there are 16 bit processors, and there may also be a possibility with some compilers that the uint32_t isn't aligned, so that the accesses won't be atomic. (Of course, you're only changing bits in one of the bytes, so this might not be an issue.)

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+1 here, it does answer the question (I didn't see that you posted an answer during all of the commenting). –  Ed S. Feb 22 '13 at 9:41

In practice (for those who did not read the question), any potential problem boils down to whether or not a store operation for an unsigned int is an atomic operation which, on most (if not all) machines you will likely write code for, it will be.

Note that this is not stated by the standard; it is specific to the architecture you are targeting. I cannot envision a scenario in which a calling thread will red anything other than 0 or 5.

As to the title... I am unaware of varying degrees of "undefined behavior". UB is UB, it is a binary state.

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That is wrong. The compiler could change your program so that the changes will never be visible to other threads. –  bamboon Feb 22 '13 at 8:59
@bamboon: Care to explain how? –  Ed S. Feb 22 '13 at 9:01
Two threads accessing a variable where one is a write and another is a read results in a race-condition which is UB per standard. –  bamboon Feb 22 '13 at 9:03
First, the access to foo is not atomic in the sense the standard uses the term. Second, while I can't imagine a scenario where the reading thread would see anything but 0 or 5, I can imainge quite a few (including some very, very likely) where the reading thread will never see anything but 0, regardless of how many times changeFoo is called. –  James Kanze Feb 22 '13 at 9:07
@EdS.: You are forgetting something very important, the As If behavior. The compiler is entitled to produce whatever code it wants as long as the behavior is as if it had produced a literal translation; the rules that determine whether it's as if or not are given by the Standard, and whenever you read undefined behavior it means the compiler can suppose it will never happen. Therefore, it can lift getFoo out of the loop... if it can prove no call to changeFoo ever happens within this thread. And then you are damned. –  Matthieu M. Feb 22 '13 at 9:09

Is there any practical chance that the values ever obtained by T1 will be different than 0 or 5 with modern computer architectures and compilers? What about other primitive types?

Sure - there is no guarantee that the entire data will be written and read in an atomic manner. In practice, you may end up with a read which occurred during a partial write. What may be interrupted, and when that happens depends on several variables. So in practice, the results could easily vary as size and alignment of types vary. Naturally, that variance may also be introduced as your program moves from platform to platform and as ABIs change. Furthermore, observable results may vary as optimizations are added and other types/abstractions are introduced. A compiler is free to optimize away much of your program; perhaps completely, depending of the scope of the instance (yet another variable which is not considered in the OP).

Beyond optimizers, compilers, and hardware specific pipelines: The kernel can even affect the manner in which this memory region is handled. Does your program Guarantee where the memory of each object resides? Probably not. Your object's memory may exist on separate virtual memory pages -- what steps does your program take to ensure the memory is read and written in a consistent manner for all platforms/kernels? (none, apparently)

In short: If you cannot play by the rules defined by the abstract machine, you should not use the interface of said abstract machine (e.g. you should just understand and use assembly if the specification of C++'s abstract machine is truly inadequate for your needs -- highly improbable).

All the assembler code I investigated so far was using 32-bit memory reads and writes, which seems to save the integrity of the operation.

That's a very shallow definition of "integrity". All you have is (pseudo-)sequential consistency. As well, the compiler needs only to behave as if in such a scenario -- which is far from strict consistency. The shallow expectation means that even if the compiler actually made no breaking optimization and performed reads and writes in accordance with some ideal or intention, that the result would be practically useless -- your program would observe changes typically 'long' after its occurrence.

The subject remains irrelevant, given what specifically you can Guarantee.

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The last sentence is the very important one. –  bamboon Feb 22 '13 at 9:48
@justin: I can't agree with the last paragraph: Imagine a case (and this was actually the root of my question) where I have several threads that perform tasks in a loops and they count (=>write) the number of executions just for the statistics and I want to display (=>read) this number to see statistics. It doesn't statistically matter to me whether the number is 1000000 or 1000042. If unsynchronized write-read can possibly make the program crash, it IS an issue for me. But if it just makes me see fake number, I can live with it. So the result COULD be practically useful. –  Andrew Feb 22 '13 at 10:31
@Andrew How does that make sense? Why would you want to create statistics which could be totally wrong. What would the purpose be of creating false data? They could potentially differ by numbers much larger than 42. –  bamboon Feb 22 '13 at 10:37
@Andrew most obvious case in that scenario: since you are not guaranteed strict consistency, read and write operations to the shared counter are ultimately divisible. therefore, the accumulator value will be exact only in very specific scenarios (scenarios you cannot guarantee using the abstract machine in combination with sequential consistency alone). illustration: say you have 15 threads and they all perform 1 million operations/increments, sharing one counter - consider it a miracle (read: purely chance) if your program's operation counter consistently reaches 15 million. –  justin Feb 22 '13 at 11:27
@Andrew that also means that the accuracy of the counter can vary dramatically as the compilers, hardware, optimizations, machine's workload during execution, etc. changes. so it could be 99% accurate in one run, and 96% accurate the next time you run it. –  justin Feb 22 '13 at 11:35

Undefined behavior is guaranteed to be as undefined as the word undefined.
Technically, the observable behavior is pointless because it is simply undefined behavior, the compiler is not needed to show you any particular behavior. It may work as you think it should or not or may burn your computer, anything and everything is possible.

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I don't remember any specs saying that 'race condition' implies 'undefined behavior' in a way the term is used by the specs. Or does it? –  Andrew Feb 22 '13 at 8:59
@Andrew Unfortunately, yes. [intro.multithread]§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. –  Angew Feb 22 '13 at 9:03
I have trouble finding this part in pre-C++11 specifications. It means that your answer is correct only for those compilers that comply to C++11 (and provided that I activate C++11 features like in gcc). For those that don't, this is not undefined behavior. But maybe I took a wrong document, did I? –  Andrew Feb 22 '13 at 9:38
@Andrew Before C++11 the standard wasn't aware of multithreading at all which means that basically any multithreading was UB or lets rather say implementation defined to the specific implementation you were using(e.g. pthreads). –  bamboon Feb 22 '13 at 9:42
@Andrew: Pre C++11 standards do not have any mention of multithreading. Pre C++11 standards provide some guarantees on simultaneous access for objects but not in a elaborated way. The answer though is true for both pre C++11 as well as C++11 compliant compilers. –  Alok Save Feb 22 '13 at 9:44

Undefined behavior means that the compiler can do what ever he wants. He could basically change your program to do what ever he likes, e.g. order a pizza.

See, @Matthieu M. answer for a less sarcastic version than this one. I won't delete this as I think the comments are important for the discussion.

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This addresses the title of the question, but not the question itself. –  Ed S. Feb 22 '13 at 9:00
It does, because the rest is irrelevant in the presence of UB. –  bamboon Feb 22 '13 at 9:01
Where is the UB exactly? –  Ed S. Feb 22 '13 at 9:01
Two threads accessing a variable where one is a write and another is a read. –  bamboon Feb 22 '13 at 9:02
@Andrew: much the same applies here. If it is UB, then it is UB, and the compiler can in theory just generate just generate whatever code it likes. Now, unless you are running the program with very restrictive privileges ,then it is most likely able to make HTTP requests. Which means that it could theoretically order pizza, and do so with the OS's blessing. :) –  jalf Feb 22 '13 at 9:12

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