A global variable is shared across 2 concurrently running threads on 2 different cores. The threads writes to and read from the variables. For the atomic variable can one thread read a stale value? Each core might have a value of the shared variable in its cache and when one threads writes to its copy in a cache the other thread on a different core might read stale value from its own cache. Or the compiler does strong memory ordering to read the latest value from the other cache? The c++11 standard library has std::atomic support. How this is different from the volatile keyword? How volatile and atomic types will behave differently in the above scenario?

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    Volatile is for reading from tape drives. Atomics are for concurrency. One has nothing to do with the other.
    – Kerrek SB
    Jan 11, 2012 at 12:32
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    @KerrekSB Volatile is about interactions that aren't known or understandable by the compiler. It's about making sure that stuff happens according to the ABI. It's about predictability. It has a lot to do with MT.
    – curiousguy
    Sep 12, 2019 at 13:08
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    Related: When to use volatile with multi threading? (never: use mo_relaxed to get the same behaviour / performance from portable code). But my answer there explains how cache-coherency works. Dec 9, 2019 at 11:16

4 Answers 4


Firstly, volatile does not imply atomic access. It is designed for things like memory mapped I/O and signal handling. volatile is completely unnecessary when used with std::atomic, and unless your platform documents otherwise, volatile has no bearing on atomic access or memory ordering between threads.

If you have a global variable which is shared between threads, such as:

std::atomic<int> ai;

then the visibility and ordering constraints depend on the memory ordering parameter you use for operations, and the synchronization effects of locks, threads and accesses to other atomic variables.

In the absence of any additional synchronization, if one thread writes a value to ai then there is nothing that guarantees that another thread will see the value in any given time period. The standard specifies that it should be visible "in a reasonable period of time", but any given access may return a stale value.

The default memory ordering of std::memory_order_seq_cst provides a single global total order for all std::memory_order_seq_cst operations across all variables. This doesn't mean that you can't get stale values, but it does mean that the value you do get determines and is determined by where in this total order your operation lies.

If you have 2 shared variables x and y, initially zero, and have one thread write 1 to x and another write 2 to y, then a third thread that reads both may see either (0,0), (1,0), (0,2) or (1,2) since there is no ordering constraint between the operations, and thus the operations may appear in any order in the global order.

If both writes are from the same thread, which does x=1 before y=2 and the reading thread reads y before x then (0,2) is no longer a valid option, since the read of y==2 implies that the earlier write to x is visible. The other 3 pairings (0,0), (1,0) and (1,2) are still possible, depending how the 2 reads interleave with the 2 writes.

If you use other memory orderings such as std::memory_order_relaxed or std::memory_order_acquire then the constraints are relaxed even further, and the single global ordering no longer applies. Threads don't even necessarily have to agree on the ordering of two stores to separate variables if there is no additional synchronization.

The only way to guarantee you have the "latest" value is to use a read-modify-write operation such as exchange(), compare_exchange_strong() or fetch_add(). Read-modify-write operations have an additional constraint that they always operate on the "latest" value, so a sequence of ai.fetch_add(1) operations by a series of threads will return a sequence of values with no duplicates or gaps. In the absence of additional constraints, there's still no guarantee which threads will see which values though. In particular, it is important to note that the use of an RMW operation does not force changes from other threads to become visible any quicker, it just means that if the changes are not seen by the RMW then all threads must agree that they are later in the modification order of that atomic variable than the RMW operation. Stores from different threads can still be delayed by arbitrary amounts of time, depending on when the CPU actually issues the store to memory (rather than just its own store buffer), physically how far apart the CPUs executing the threads are (in the case of a multi-processor system), and the details of the cache coherency protocol.

Working with atomic operations is a complex topic. I suggest you read a lot of background material, and examine published code before writing production code with atomics. In most cases it is easier to write code that uses locks, and not noticeably less efficient.

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    I would add that the question is not well defined. Whether a value is stale or not depends on additional synchronization. If you have one variable and one thread keeps writing a sequence of values to it (e.g., 1, 2...), and another thread reads, say 3, is the 3 a stale value or not? You need some other confirmation that indeed 4 has already been written when you read 3. But that requires some other observation that is in a happens-before relationship with your read of 3. Somebody must have communicated to you the read of 4 before your read or 3. This won't happen with SC accesses. Jan 12, 2012 at 17:46
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    I's still struggling with the use of volatile with atomics: "volatile is completely unnecessary when used with std::atomic". What about the loop optimization of while(x.load(memory_order_relaxed)) ; => bool tmp = x.load(memory_order_relaxed); while(tmp) ; The standard is wishy washy about this and Hans turns into a diplomat when asked this question directly ;-) Jan 12, 2012 at 17:53
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    VS does NOT issue a memory barrier instruction for volatile accesses. What they do is forward the processor's guarantee that loads are always load-acquire and stores are always store-release up to the C/C++ code level, and inhibit certain optimizations so that this is the case. This is not the same as a std::atomic with std::memory_order_seq_cst, which does require an MFENCE or LOCKed instruction along with stores and/or loads. Jan 13, 2012 at 7:37
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    @BartoszMilewski: I don't believe that the loop optimization you ask about is valid. The compiler may change it to a read every N iterations for some large N, but may not remove the read from the loop entirely, as it would violate the "should be visible within a reasonable time period" clause. It's only a "should", not a "must", but I cannot see any reasonable implementation violating it. Jan 13, 2012 at 7:39
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    @BartoszMilewski: My interpretation of "stale" is that a later value has been written by some thread than the one read. Unless there is some synchronization constraint that makes the later read observable then this isn't a problem. Jan 13, 2012 at 7:41

volatile and the atomic operations have a different background, and were introduced with a different intent.

volatile dates from way back, and is principally designed to prevent compiler optimizations when accessing memory mapped IO. Modern compilers tend to do no more than suppress optimizations for volatile, although on some machines, this isn't sufficient for even memory mapped IO. Except for the special case of signal handlers, and setjmp, longjmp and getjmp sequences (where the C standard, and in the case of signals, the Posix standard, gives additional guarantees), it must be considered useless on a modern machine, where without special additional instructions (fences or memory barriers), the hardware may reorder or even suppress certain accesses. Since you shouldn't be using setjmp et al. in C++, this more or less leaves signal handlers, and in a multithreaded environment, at least under Unix, there are better solutions for those as well. And possibly memory mapped IO, if you're working on kernal code and can ensure that the compiler generates whatever is needed for the platform in question. (According to the standard, volatile access is observable behavior, which the compiler must respect. But the compiler gets to define what is meant by “access”, and most seem to define it as “a load or store machine instruction was executed”. Which, on a modern processor, doesn't even mean that there is necessarily a read or write cycle on the bus, much less that it's in the order you expect.)

Given this situation, the C++ standard added atomic access, which does provide a certain number of guarantees across threads; in particular, the code generated around an atomic access will contain the necessary additional instructions to prevent the hardware from reordering the accesses, and to ensure that the accesses propagate down to the global memory shared between cores on a multicore machine. (At one point in the standardization effort, Microsoft proposed adding these semantics to volatile, and I think some of their C++ compilers do. After discussion of the issues in the committee, however, the general consensus—including the Microsoft representative—was that it was better to leave volatile with its orginal meaning, and to define the atomic types.) Or just use the system level primitives, like mutexes, which execute whatever instructions are needed in their code. (They have to. You can't implement a mutex without some guarantees concerning the order of memory accesses.)

  • I think it's worth emphasising that atomics (as well as mutex primitives) cannot possibly be implemented with some sort of hardware support. (On the other hand, volatile is a mere compiler hint.)
    – Kerrek SB
    Jan 11, 2012 at 13:13
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    You meant without, didn't you? Jan 11, 2012 at 13:14
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    @KerrekSB Nothing can be implemented without some sort of hardware support:-). The language defines the semantics (more or less, in the case of volatile); it's up to the compiler to generate whatever is necessary. (Arguably, the intent of volatile would require some extra machine instructions on many machines, since memory access reordering in the CPU will also affect memory mapped IO.) Jan 11, 2012 at 14:09
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    @JamesKanze: Hm, yes, that's true of course. I suppose what I should have said is that atomics cannot be implemented as pure library code that only uses the rest of the standard library, if that makes sense. That is, the addition of atomics (whether in C++ or delegated through the C library) requires platform support and isn't just added library code. (You'll need some variant of atomic compare-and-swap at the hardware level.)
    – Kerrek SB
    Jan 11, 2012 at 14:12
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    "At one point in the standardization effort, Microsoft proposed adding these semantics to volatile, and I think some of their C++ compilers do." This is correct -- with VC++ 2003 and onward, volatile implies a full memory barrier.
    – ildjarn
    Jan 11, 2012 at 16:38

Here's a basic synopsis of what the 2 things are:

1) Volatile keyword:
Tells the compiler that this value could alter at any moment and therefore it should not EVER cache it in a register. Look up the old "register" keyword in C. "Volatile" is basically the "-" operator to "register"'s "+". Modern compilers now do the optimization that "register" used to explicitly request by default, so you only see 'volatile' anymore. Using the volatile qualifier will guarantee that your processing never uses a stale value, but nothing more.

2) Atomic:
Atomic operations modify data in a single clock tick, so that it is impossible for ANY other thread to access the data in the middle of such an update. They're usually limited to whatever single-clock assembly instructions the hardware supports; things like ++,--, and swapping 2 pointers. Note that this says nothing about the ORDER the different threads will RUN the atomic instructions, only that they will never run in parallel. That's why you have all those additional options for forcing an ordering.

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    Atomic operations very often abtract to a single hardware clock cycle, but afaik this is neither 100% guaranteed/necessary, nor the only requirement (e.g. many architectures require certain alignments too). One should always declare intent, not depend on 'well it works the right way on X architecture'. Jul 14, 2015 at 19:24
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    Except that volatile might force the compiler to put a variable in a register, so that it doesn't read it twice when the coder only instructed to read once. Mar 1, 2018 at 16:29
  • val1 = x; /* some code not using x */ val2 = x; A smart (optimizing) compiler might notice that you use x twice without changing its value. It would temporarily store the x value in a register. C Primer 6th edition.
    – M22
    Sep 23, 2023 at 19:09

Volatile and Atomic serve different purposes.

Volatile : Informs the compiler to avoid optimization. This keyword is used for variables that shall change unexpectedly. So, it can be used to represent the Hardware status registers, variables of ISR, Variables shared in a multi-threaded application.

Atomic : It is also used in case of multi-threaded application. However, this ensures that there is no lock/stall while using in a multi-threaded application. Atomic operations are free of races and indivisble. Few of the key scenario of usage is to check whether a lock is free or used, atomically add to the value and return the added value etc. in multi-threaded application.

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