In C++, can atomics suffer spurious stores?

For example, suppose that m and n are atomics and that m = 5 initially. In thread 1,

    m += 2;

In thread 2,

    n = m;

Result: the final value of n should be either 5 or 7, right? But could it spuriously be 6? Could it spuriously be 4 or 8, or even something else?

In other words, does the C++ memory model forbid thread 1 from behaving as though it did this?

    ++m;
    ++m;

Or, more weirdly, as though it did this?

    tmp  = m;
    m    = 4;
    tmp += 2;
    m    = tmp;

Reference: H.-J. Boehm & S. V. Adve, 2008, Figure 1. (If you follow the link, then, in the paper's section 1, see the first bulleted item: "The informal specifications provided by ...")

THE QUESTION IN ALTERNATE FORM

One answer (appreciated) shows that the question above can be misunderstood. If helpful, then here is the question in alternate form.

Suppose that the programmer tried to tell thread 1 to skip the operation:

    bool a = false;
    if (a) m += 2;

Does the C++ memory model forbid thread 1 from behaving, at run time, as though it did this?

    m += 2; // speculatively alter m
    m -= 2; // oops, should not have altered! reverse the alteration

I ask because Boehm and Adve, earlier linked, seem to explain that a multithreaded execution can

  • speculatively alter a variable, but then
  • later change the variable back to its original value when the speculative alteration turns out to have been unnecessary.

COMPILABLE SAMPLE CODE

Here is some code you can actually compile, if you wish.

#include <iostream>
#include <atomic>
#include <thread>

// For the orignial question, do_alter = true.
// For the question in alternate form, do_alter = false.
constexpr bool do_alter = true;

void f1(std::atomic_int *const p, const bool do_alter_)
{
    if (do_alter_) p->fetch_add(2, std::memory_order_relaxed);
}

void f2(const std::atomic_int *const p, std::atomic_int *const q)
{
    q->store(
        p->load(std::memory_order_relaxed),
        std::memory_order_relaxed
    );
}

int main()
{
    std::atomic_int m(5);
    std::atomic_int n(0);
    std::thread t1(f1, &m, do_alter);
    std::thread t2(f2, &m, &n);
    t2.join();
    t1.join();
    std::cout << n << "\n";
    return 0;
}

This code always prints 5 or 7 when I run it. (In fact, as far as I can tell, it always prints 7 when I run it.) However, I see nothing in the semantics that would prevent it from printing 6, 4 or 8.

The excellent Cppreference.com states, "Atomic objects are free of data races," which is nice, but in such a context as this, what does it mean?

Undoubtedly, all this means that I do not understand the semantics very well. Any illumination you can shed on the question would be appreciated.

ANSWERS

@Christophe, @ZalmanStern and @BenVoigt each illuminate the question with skill. Their answers cooperate rather than compete. In my opinion, readers should heed all three answers: @Christophe first; @ZalmanStern second; and @BenVoigt last to sum up.

  • 4
    Even for non-atomic addition addition and assignment, an integer variable can't get "spurious" values like you're worried about. And (in practice) that goes even for possible data-races like you could have. An operation as m += 2 is equal to m = m + 2, not two consecutive increments of one. – Some programmer dude Nov 5 '17 at 13:16
  • 4
    And why do you ask? Do you have an actual problem that leads to this question? Perhaps you should ask about that instead? – Some programmer dude Nov 5 '17 at 13:16
  • 10
    No they cannot. That's what "atomic" means. Indivisible, cannot observe separate parts. – nwp Nov 5 '17 at 13:21
  • 3
    @Someprogrammerdude: For non-atomic non-volatile operations, variables, including integer variables of all sizes, most certainly can contain intermediate spurious values. Torn writes are the most obviously example, but speculative writes as mentioned in the question are also possible. Atomic and volatile operations avoid these stores of spurious values. (But beware, while read and write are atomic for volatiles, read-modify-write operations are not) – Ben Voigt Nov 5 '17 at 18:28
  • 3
    @Someprogrammerdude: It is very much a possibility that multithreaded code has bugs that will very, very, very rarely show up in real life. Rarely, but not never. I very much prefer code where I know that it works to code that I haven't seen failing (yet). – gnasher729 Nov 5 '17 at 19:05
up vote 20 down vote accepted

The existing answers provide a lot of good explanation, but they fail to give a direct answer to your question. Here we go:

can atomics suffer spurious stores?

Yes, but you cannot observe them from a C++ program which is free from data races.

Only volatile is actually prohibited from performing extra memory accesses.

does the C++ memory model forbid thread 1 from behaving as though it did this?

++m;
++m;

Yes, but this one is allowed:

lock (shared_std_atomic_secret_lock)
{
    ++m;
    ++m;
}

It's allowed but stupid. A more realistic possibility is turning this:

std::atomic<int64_t> m;
++m;

into

memory_bus_lock
{
    ++m.low;
    if (last_operation_did_carry)
       ++m.high;
}

where memory_bus_lock and last_operation_did_carry are features of the hardware platform that can't be expressed in portable C++.

Note that peripherals sitting on the memory bus do see the intermediate value, but can interpret this situation correctly by looking at the memory bus lock. Software debuggers won't be able to see the intermediate value.

In other cases, atomic operations can be implemented by software locks, in which case:

  1. Software debuggers can see intermediate values, and have to be aware of the software lock to avoid misinterpretation
  2. Hardware peripherals will see changes to the software lock, and intermediate values of the atomic object. Some magic may be required for the peripheral to recognize the relationship between the two.
  3. If the atomic object is in shared memory, other processes can see the intermediate values and may not have any way to inspect the software lock / may have a separate copy of said software lock
  4. If other threads in the same C++ program break type safety in a way that causes a data race (For example, using memcpy to read the atomic object) they can observe intermediate values. Formally, that's undefined behavior.

One last important point. The "speculative write" is a very complex scenario. It's easier to see this if we rename the condition:

Thread #1

if (my_mutex.is_held) o += 2; // o is an ordinary variable, not atomic or volatile
return o;

Thread #2

{
    scoped_lock l(my_mutex);
    return o;
}

There's no data race here. If Thread #1 has the mutex locked, the write and read can't occur unordered. If it doesn't have the mutex locked, the threads run unordered but both are performing only reads.

Therefore the compiler cannot allow intermediate values to be seen. This C++ code is not a correct rewrite:

o += 2;
if (!my_mutex.is_held) o -= 2;

because the compiler invented a data race. However, if the hardware platform provides a mechanism for race-free speculative writes (Itanium perhaps?), the compiler can use it. So hardware might see intermediate values, even though C++ code cannot.

If intermediate values shouldn't be seen by hardware, you need to use volatile (possibly in addition to atomics, because volatile read-modify-write is not guaranteed atomic). With volatile, asking for an operation which can't be performed as-written will result in compilation failure, not spurious memory access.

  • 2
    The only thing I'm aware of that works like memory_bus_lock{ multiple ops } is transactional memory. (e.g. Intel's TSX. realworldtech.com/haswell-tm). AFAIK, that's the only way you could implement int64_t m; ++m using the algorithm you describe in assembly language on x86 or any typical RISC. (Most RISC CPUs support LL/SC, but not nested, so you can't atomically operate on a pair of words. – Peter Cordes Nov 5 '17 at 19:33
  • 2
    On x86, you can atomically increment a double-word integer (like int64_t on 32-bit x86) using a double-word CAS (which x86 does have even without TSX-NI transactional memory: cmpxchg8b). Load both words, increment in registers, then try to CAS that back into memory. Else retry. There aren't asm instructions to lock the memory bus. (And of course normally an atomic op only internally locks the one cache line it operates on, i.e. not responding to MESI requests to Invalidate or Share the cache line between the read and the write of an atomic RMW). – Peter Cordes Nov 5 '17 at 19:37
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    Anyway, upvoted because the mechanism you propose is allowed by the C++ standard. No mainstream hardware works that way, but it's an interesting thought experiment. And also for the suggestion to use volatile atomic<T> when you care about the internals. – Peter Cordes Nov 5 '17 at 19:38
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    @PeterCordes: Those weren't necessarily meant to correspond to assembly instructions, consider for example x86's #LOCK signal (which that cmpxchg8b uses, but can also be controlled from assembly via the LOCK prefix) along with multiple memory-bus actions, which can be seen by memory-mapped hardware, cache coherency snoops from other cores, etc. When you take "observable behavior" to the hardware level, it's about the (hierarchical) memory bus cycles not the number of instructions. – Ben Voigt Nov 5 '17 at 19:46
  • 1
    @PeterCordes: Anyway, I intended for that example to correspond to x86 LOCK INC m64 but I don't know what other actions might appear in the uop decode on a current-generation Core CPU. – Ben Voigt Nov 5 '17 at 19:53

Your code makes use of fetch_add() on the atomic, which gives the following guarantee:

Atomically replaces the current value with the result of arithmetic addition of the value and arg. The operation is read-modify-write operation. Memory is affected according to the value of order.

The semantics are crystal clear: before the operation it's m, after the operation it's m+2, and no thread accesses to what's between these two states because the operation is atomic.


Edit: additional elements regarding your alternate question

Whatever Boehm and Adve may say, the C++ compilers obey to the following standard clause:

1.9/5: A conforming implementation executing a well-formed program shall produce the same observable behavior as one of the possible executions of the corresponding instance of the abstract machine with the same program and the same input.

If a C++ compiler would generate code that could allow speculative updates to interfere with the observable behavior of the program (aka getting something else than 5 or 7), it would not be standard compliant, because it would fail to ensure the guarantee mentioned in my initial answer.

  • If you are still interested, I have edited the question to clarify why I understand (or misunderstand) Boehm and Adve to contradict your answer. To the question, I have added a new section, THE QUESTION IN ALTERNATE FORM. – thb Nov 5 '17 at 14:35
  • 1
    @thb I've edited my answer accordingly – Christophe Nov 5 '17 at 15:00
  • 3
    @thb: Boehm and Adve are pointing out problems with ordinary (non-atomic, non-volatile) memory access. atomic is the tool for avoiding the problems they point out. – Ben Voigt Nov 5 '17 at 18:31
  • 2
    @Christophe: However, one must also consider the meaning of "observable behavior" used by the Standard. It includes only observations made by code in the same program. Both C and C++ expressly allow for the possibility of using an explicit lock for implementing the atomic functions, and in that case observations which lack type-safety, such as OS cross-process memory access, memory-mapped hardware, or debugging tools, may still be able to observe violations of the "observable behavior" model. – Ben Voigt Nov 5 '17 at 18:42
  • @Christophe, atomic reads or writes are not observable behaviors, only I/O and volatile writes are observable behavior. A very smart compiler could actualy transform the m+=2; into m++ if the value of n were just used in a test as in if (n>5) std::cout<<"bingo"; and m not used for anything else than initializing n. – Oliv Nov 5 '17 at 19:58

Your revised question differs quite a bit from the first in that we've moved from sequential consistency to relaxed memory order.

Both reasoning about and specifying weak memory orderings can be fairly tricky. E.g. note the difference between C++11 and C++14 specification pointed out here: http://en.cppreference.com/w/cpp/atomic/memory_order#Relaxed_ordering . However, the definition of atomicity does prevent the fetch_add call from allowing any other thread to see values other than ones otherwise written to the variable or one of those plus 2. (A thread can do pretty much anything so long as it guarantees the intermediate values are not observable by other threads.)

(To get dreadfully specific, you likely want to search for "read-modify-write" in the C++ spec, e.g. http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2017/n4659.pdf .)

Perhaps giving a specific reference to the place in the linked paper that you have questions about would help. That paper predates the first C++ concurrent memory model specification (in C++11) by a tiny bit and we're now another rev beyond that so it may also be a bit out of date with respect to what the standard actually says, though I expect this is more an issue of it proposing things that could happen on non-atomic variables.

EDIT: I'll add a bit more about "the semantics" to perhaps help think about how to analyze this kind of thing.

The goal of memory ordering is to establish a set of possible orders between reads and writes to variables across threads. In weaker orderings, it is not guaranteed that there is any single global ordering that applies to all threads. This alone is already tricky enough that one should make sure it is fully understood before moving on.

Two things involved in specifying an ordering are addresses and synchronization operations. In effect a synchronization operation has two sides and those two sides are connected via sharing an address. (A fence can be thought of as applying to all addresses.) A lot of the confusion in the space comes from figuring out when a synchronization operation on one address guarantees something for other addresses. E.g. mutex lock and unlock operations only establish ordering via the acquire and release operations on the addresses inside the mutex, but that synchronization applies to all reads and writes by the threads locking and unlocking the mutex. An atomic variable accessed using relaxed ordering places few constraints on what happens, but those accesses may have ordering constraints imposed by more strongly ordered operations on other atomic variables or mutexes.

The main synchronization operations are acquire and release. See: http://en.cppreference.com/w/cpp/atomic/memory_order . These are names per what happens with a mutex. The acquire operation applies to loads and prevents any memory operations on the current thread from being reordered past the point where the acquire happens. It also establishes an ordering with any prior release operations on the same variable. The last bit is governed by the value loaded. I.e. if the load returns a value from a given write with release synchronization, the load is now ordered against that write and all other memory operations by those threads fall into place according to the ordering rules.

Atomic, or read-modify-write, operations are their own little sequence in the larger ordering. It is guaranteed that the read, the operation, and the write happen atomically. Any other ordering is given by the memory order parameter to the operation. E.g. specifying relaxed ordering says no constraints otherwise apply to any other variables. I.e. there is no acquire or release implied by the operation. Specifying memory_order_acq_rel says that not only is the operation atomic, but that the read is an acquire and the write is a release -- if the thread reads a value from another write with release semantics, all other atomics now have the appropriate ordering constraint in this thread.

A fetch_add with relaxed memory order might be used for an statistics counter in profiling. At the end of the operation, all threads will have done something else to assure all those counter increments are now visible to the final reader, but in the intermediate state we don't care so long as the final total adds up. However this does not imply that intermediate reads can sample values that were never part of the count. E.g. if we're always adding even values to a counter starting at 0, no thread should ever read an odd value regardless of ordering.

I am a bit put off by not being able to point to a specific piece of text in the standard which says there can be no side effects to atomic variables other than those explicitly encoded in the program somehow. Lots of things mention side effects, but it seems to be taken for granted that the side effects are those specified by the source and not anything made up by the compiler. Don't have time to track this down right now, but there is a lot of stuff that would not work if this were not guaranteed and part of the point of std::atomic is to get this constraint as it is not guaranteed by other variables. (It is somewhat provided by volatile, or at least is intended to be. Part of the reason we have this degree of specification for memory ordering around std::atomic is because volatile never became well enough specified to reason about in detail and no one set of constraints met all needs.)

  • +1. I have edited the question to give a specific reference to the place in the linked paper. Good advice. Good answer. You say that reasoning can be fairly tricky. This is just what I am trying to do now: I am trying to learn the trick! – thb Nov 5 '17 at 15:47
  • 1
    That text is indeed describing things that can happen in absence of the constraints of a concurrency model. This paper was part of a lead up to specifying all this rather complex stuff in the standard. However those specific possibilities do not seem to apply to std:atomic at all. I'll add a bit to my answer on how to think about "the semantics." – Zalman Stern Nov 5 '17 at 15:58
  • @Zalman: The reason that the Standard doesn't contain the statement you are looking for is that it isn't true. On some architectures, atomic variables are implemented using a sequence of sub-operations protected by a lock. Actually, that's true on nearly every architecture, the key differences are whether the lock is a hardware or software lock. The guarantee made by std::atomic is that C++ code cannot observe the intermediate values. If you need to prevent hardware from observing sub-operations, you need volatile (and operations which aren't implemented atomically in hardware will fail) – Ben Voigt Nov 5 '17 at 18:36
  • 1
    @ZalmanStern: I agree with you. A thread performing C++ atomic reads cannot see the intermediate values. But they might be detectable by other means (hardware DMA, bus sniffer, debugging software, inter-process memory access). If someone were performing memory-mapped I/O, or shared memory, and thinking of using std::atomic to do so, they might ask this exact question. So I think it is valuable to distinguish between "it can't happen" and "when all accesses are through std::atomic you can't see it happen" – Ben Voigt Nov 5 '17 at 19:21
  • 1
    @ZalmanStern: N4140 29.3.3 (3.3) might be what you're looking for. An atomic load will always see "the result of some modification of M", not some other made-up result that doesn't appear in the C++ abstract machine. (If there's a release-sequence, then there are requirements on which modification of M you're allowed to see, so the wording gets super complicated). – Peter Cordes Nov 5 '17 at 20:06

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