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Consider the following pseudocode:

expected = null;
if (variable == expected)
{
    atomic_compare_exchange_strong(
        &variable, expected, desired(), memory_order_acq_rel, memory_order_acq);
}
return variable;

Observe there are no "acquire" semantics when the variable == expected check is performed.

It seems to me that desired will be called at least once in total, and at most once per thread.
Furthermore, if desired never returns null, then this code will never return null.

Now, I have three questions:

  1. Is the above necessarily true? i.e., can we really have well-ordered reads of shared variables even in the absence of fences on every read?

  2. Is it possible to implement this in C++? If so, how? If not, why?
    (Hopefully with a rationale, not just "because the standard says so".)

  3. If the answer to (2) is yes, then is it also possible to implement this in C++ without requiring variable == expected to perform an atomic read of variable?

Basically, my goal is to understand if it is possible to perform lazy-initialization of a shared variable in a manner that has performance identical to that of a non-shared variable once the code has been executed at least once by each thread?

(This is somewhat of a "language-lawyer" question. So that implies the question isn't about whether this is a good or useful idea, but rather about whether it's technically possible to do this correctly.)

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@nosid: No. See #3. The question is also about whether or not atomicity is required at all, regardless of memory ordering issues. –  Mehrdad May 1 '14 at 9:51
    
@nosid: I didn't mention it because the first thing I mentioned is that this is pseudocode, so don't expect it to be valid C++. The focus is on the concept; C++ is just one aspect of the overall question. –  Mehrdad May 1 '14 at 9:57
1  
So, what if variable is large so that atomic_compare_exchange_strong has to use a mutex? You'd try to access variable == expected while the object is being changed, which means that e.g. its class invariants don't have to hold. –  dyp May 1 '14 at 11:11
    
The pseudo code has little meaning without a memory model to describe how multi-threaded reads/writes work. C++11 has a memory model, but your pseudo-code is not C++, as C++ variables have types, and those types impact how they behave under the C++11 memory model. –  Yakk May 1 '14 at 11:21
    
@Yakk: I hesitate to use the C++ memory model because most of the question is conceptual, not C++ specific. Only part of it asks if this could be achieved in C++, and for that section, you can give the variables whatever types you deem appropriate to make it work. Can you imagine this failing on any (sane) memory model with a convincing rationale (i.e. not just because "the memory model says so" but rather why it might say so)? –  Mehrdad May 1 '14 at 15:23

2 Answers 2

Regarding the question whether it is possible to perform lazy initialisation of a shared variable in C++, that has a performance (almost) identical to that of a non-shared variable:

The answer is, that it depends on the hardware architecture, and the implementation of the compiler and run-time environment. At least, it is possible in some environments. In particular on x86 with GCC and Clang.

On x86, atomic reads can be implemented without memory fences. Basically, an atomic read is identical to a non-atomic read. Take a look at the following compilation unit:

std::atomic<int> global_value;
int load_global_value() { return global_value.load(std::memory_order_seq_cst); }

Although I used an atomic operation with sequential consistency (the default), there is nothing special in the generated code. The assembler code generated by GCC and Clang looks as follows:

load_global_value():
    movl global_value(%rip), %eax
    retq

I said almost identical, because there are other reasons that might impact the performance. For example:

  • although there is no fence, the atomic operations still prevent some compiler optimisations, e.g. reordering instructions and elimination of stores and loads
  • if there is at least one thread, that writes to a different memory location on the same cache line, it will have a huge impact on the performance (known as false sharing)

Having said that, the recommended way to implement lazy initialisation is to use std::call_once. That should give you the best result for all compilers, environments and target architectures.

std::once_flag _init;
std::unique_ptr<gadget> _gadget;

auto get_gadget() -> gadget&
{
    std::call_once(_init, [this] { _gadget.reset(new gadget{...}); });
    return *_gadget;
}
share|improve this answer
    
+1 although this isn't the direction I was going. I wasn't trying to ask an architecture-specific question; I was wondering if I could be sure that this could be done on all architectures, assuming they implemented atomic_compare_and_swap_strong in a sane fashion. The real question is why an unprotected read might be insufficient on some architectures, not whether a particular architecture might be able to do it. –  Mehrdad May 1 '14 at 14:53
    
@Mehrdad The std::call_once is guaranteed to work on all platforms. And the statement "On x86, atomic reads can be implemented without memory fences" isn't really true; the processor can reorder reads (but not, I think, writes, at least with older processors). –  James Kanze May 1 '14 at 15:03
    
@James: yes but neither of those answers my question. My question was neither about call_once more about a specific architecture like x86. –  Mehrdad May 1 '14 at 15:19
    
@JamesKanze: Are you sure about the reorderings? As I said, both Clang and GCC use an ordinary load. The following page on Wikipedia also created the impression, that loads can not be reordered (as long as we are not talking about ancient machines): en.wikipedia.org/wiki/Memory_ordering –  nosid May 1 '14 at 15:28
    
@nosid Intel is certainly less permissive than processors like the Sparc and the Alpha, but it definitely allows some reordering, see intel.com/content/dam/www/public/us/en/documents/manuals/…. (More importantly, perhaps: the ordering guarantees have been loosed once in the past, so one can assume that they will be loosened again in the future.) –  James Kanze May 1 '14 at 16:06

This is undefined behavior. You're modifying variable, at least in some thread, which means that all accesses to variable must be protected. In particular, when you're executing the atomic_compare_exchange_strong in one thread, there is nothing to guarantee that another thread might see the new value of variable before it sees the writes that might have occurred in desired(). (atomic_compare_exchange_strong only guarantees any ordering in the thread that executes it.)

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I'm not sure I understand. Are you worried about memory writes that desired might have performed? Would your answer change if desired didn't perform any memory writes, and instead just returned a value that was significant on its own? (say it was returning an integer instead of a pointer, or say desired had a memory barrier inside that ensured everything is visible before it returned.) Furthermore, the crux of the question is, why should every access be protected? Wouldn't not protecting the read of variable still result in correct code, because of the compare and swap later? –  Mehrdad May 1 '14 at 14:50
    
There's not really much to understand. If an object may be accessed in more than one thread, and you modify it in any thread, then all accesses to it must be synchronized, or you have undefined behavior. The issue concerning writes in desired was just an example of the sort of things that can go wrong. –  James Kanze May 1 '14 at 15:00
    
I'm not asking what can go wrong (which is what the standard says), rather I'm asking why it could go wrong (the rationale behind what the standard might say). So I don't understand what could possibly go wrong in this code for any other reason than "because the standard says so". –  Mehrdad May 1 '14 at 15:18
    
@Mehrdad Why it could go wrong is simple: modern processors reorder how reads and writes appear on the external bus, to different degrees, depending on the processor. All of them have various fence or membar instructions to guarantee the order, when it is needed. Your code is basically a variant of double-checked locking, which has been proven unsafe without additional hardware synchronization on the load in the if. –  James Kanze May 1 '14 at 16:10
    
No, I think this is different from double checked locking, at least the typical kind. There is no other location of memory that is shared here, but in double checked locking a new object is constructed whose initialization needs to happen after the variable is written to, so the relative ordering is an issue there. Correct? –  Mehrdad May 1 '14 at 16:15

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