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I have two threads, one updating an int and one reading it. This is a statistic value where the order of the reads and writes is irrelevant.

My question is, do I need to synchronize access to this multi-byte value anyway? Or, put another way, can part of the write be complete and get interrupted, and then the read happen.

For example, think of a value = 0x0000FFFF that gets incremented value of 0x00010000.

Is there a time where the value looks like 0x0001FFFF that I should be worried about? Certainly the larger the type, the more possible something like this to happen.

I've always synchronized these types of accesses, but was curious what the community thinks.

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16 Answers 16

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Boy, what a question. The answer to which is:

Yes, no, hmmm, well, it depends

It all comes down to the architecture of the system. On an IA32 a correctly aligned address will be an atomic operation. Unaligned writes might be atomic, it depends on the caching system in use. If the memory lies within a single L1 cache line then it is atomic, otherwise it's not. The width of the bus between the CPU and RAM can affect the atomic nature: a correctly aligned 16bit write on an 8086 was atomic whereas the same write on an 8088 wasn't because the 8088 only had an 8 bit bus whereas the 8086 had a 16 bit bus.

Also, if you're using C/C++ don't forget to mark the shared value as volatile, otherwise the optimiser will think the variable is never updated in one of your threads.

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  • 25
    The volatile keyword is not useful in multithreaded programs stackoverflow.com/questions/2484980/…
    – user152949
    Jul 5, 2012 at 12:13
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    @IngeHenriksen: I'm not convinced by that link.
    – Skizz
    Jul 5, 2012 at 13:12
  • another source, but unfortunately very old (it predates std::atomic): web.archive.org/web/20190219170904/https://software.intel.com/… May 5, 2020 at 21:43
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    This answer is outdated. As of C++11, unsynchronized access to an int that is not std::atomic<int> is a data race, and is undefined behavior. So the current correct answer is a flat no. Oct 16, 2021 at 17:27
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    @NateEldredge: That's not entirely correct, undefined does not mean "a flat no". As I said in my answer, "it depends". Undefined just means there's no guarentee the operation is atomic, sometimes it is, sometimes it's not. The code is not going to be portable if you make assumptions about the atomic nature, but if you're targeting a fixed hardware and software configuration and comment the code appropriately then the assumption might work for you. But, like I said, it won;t be truely portable.
    – Skizz
    Oct 18, 2021 at 6:58
48

At first one might think that reads and writes of the native machine size are atomic but there are a number of issues to deal with including cache coherency between processors/cores. Use atomic operations like Interlocked* on Windows and the equivalent on Linux. C++0x will have an "atomic" template to wrap these in a nice and cross-platform interface. For now if you are using a platform abstraction layer it may provide these functions. ACE does, see the class template ACE_Atomic_Op.

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IF you're reading/writing 4-byte value AND it is DWORD-aligned in memory AND you're running on the I32 architecture, THEN reads and writes are atomic.

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    Where in the Intel architecture software developer's manuals is this stated? Jan 3, 2011 at 16:56
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    @DanielTrebbien: perhaps see stackoverflow.com/questions/5002046/…
    – sehe
    Sep 28, 2011 at 18:23
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    This is not true at the level of C++. The underlying machine instructions are atomic, but the compiler is allowed to optimize in ways that would break atomicity. Oct 16, 2021 at 17:44
  • @DanielTrebbien Why is integer assignment on a naturally aligned variable atomic on x86? quotes the Intel and AMD manuals for asm guarantees, after explaining that you need to use std::atomic<int> to get the compiler to make asm that actually does memory operations that match what you're doing to the C++ objects, even for pure-load and pure-store, not just atomic RMW like some other answers here are talking about. Sep 28, 2023 at 13:21
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Yes, you need to synchronize accesses. In C++0x it will be a data race, and undefined behaviour. With POSIX threads it's already undefined behaviour.

In practice, you might get bad values if the data type is larger than the native word size. Also, another thread might never see the value written due to optimizations moving the read and/or write.

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You must synchronize, but on certain architectures there are efficient ways to do it.

Best is to use subroutines (perhaps masked behind macros) so that you can conditionally replace implementations with platform-specific ones.

The Linux kernel already has some of this code.

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On Windows, Interlocked***Exchange***Add is guaranteed to be atomic.

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To echo what everyone said upstairs, the language pre-C++0x cannot guarantee anything about shared memory access from multiple threads. Any guarantees would be up to the compiler.

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Some people think that ++c is atomic, but have a eye on the assembly generated. For example with 'gcc -S' :

movl    cpt.1586(%rip), %eax
addl    $1, %eax
movl    %eax, cpt.1586(%rip)

To increment an int, the compiler first load it into a register, and stores it back into the memory. This is not atomic.

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    This is not an issue if only one thread is writing to the variable, since there's no tearing.
    – Ben Voigt
    Apr 17, 2012 at 22:40
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No, they aren't (or at least you can't assume they are). Having said that, there are some tricks to do this atomically, but they typically aren't portable (see Compare-and-swap).

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I agree with many and especially Jason. On windows, one would likely use InterlockedAdd and its friends.

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Asside from the cache issue mentioned above...

If you port the code to a processor with a smaller register size it will not be atomic anymore.

IMO, threading issues are too thorny to risk it.

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Definitively NO ! That answer from our highest C++ authority, M. Boost:
Operations on "ordinary" variables are not guaranteed to be atomic.

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    that link only says arithmetic operation which consists of a read-update-write sequence on 'ordinary' variables are not atomic, not whether read or write operation on 'ordinary' variables are atomic or not.
    – D3Hunter
    Feb 24, 2018 at 7:48
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The only portable way is to use the sig_atomic_t type defined in signal.h header for your compiler. In most C and C++ implementations, that is an int. Then declare your variable as "volatile sig_atomic_t."

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  • volatile doesn't do what you think it does stackoverflow.com/questions/2484980/…
    – Sam Miller
    Jul 8, 2010 at 2:48
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    sig_atomic_t is atomic with respect to signals, but not with respect to threads. Since C++11, accessing such an object from multiple threads is a data race and UB. Oct 16, 2021 at 17:29
-1

Lets take this example

int x;
x++;
x=x+5;

The first statement is assumed to be atomic because it translates to a single INC assembly directive that takes a single CPU cycle. However, the second assignment requires several operations so it's clearly not an atomic operation.

Another e.g,

x=5;

Again, you have to disassemble the code to see what exactly happens here.

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tc, I think the moment you use a constant ( like 6) , the instruction wouldn't be completed in one machine cycle. Try to see the instruction set of x+=6 as compared to x++

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  • This looks like it was supposed to be a reply to a comment on your earlier answer. It's also wrong; on a uniprocessor machine where your original premise was right that a single instruction RMW is atomic even without the lock prefix, add dword [rdi], 6 is not different from inc dword [rdi]. Both can be made actually atomic with a lock prefix Sep 28, 2023 at 13:26
  • Neither one can execute in a single cycle, though: the load, add, and store uops all depend on each other, and even an L1d cache hit has a few cycles of load latency. Out-of-order exec pipelines can run this and 3 or more other instructions in the same cycle, though, if they're independent (not incrementing the same memory location or register). Sep 28, 2023 at 13:26
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Reads and writes are atomic, but you also need to worry about the compiler re-ordering your code. Compiler optimizations may violate happens-before relationship of statements in your code. By using atomic you don't have to worry about that. ... atomic i;

soap_status = GOT_RESPONSE ; i = 1

In the above example, the variable 'i' will only be set to 1 after we get a soap response.

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    This is not true. Reads and writes of int are not guaranteed atomic in standard C++, and the resulting data race causes undefined behavior. Oct 16, 2021 at 17:28

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