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Suppose I have several threads accessing the same memory location. And, if at all, they all write the same value and none of them reads it. After that, all threads converge (through locks) and only then I read the value. Do I need to use an atomic for this? This is for an x86_64 system. The value is an int32.

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    You’ve tagged this with both assembly and C and C++. The answer for assembly is definitely different from the other two. In assembly, each write to a dword is atomic if it is 4-byte aligned. (And usually even if it isn’t aligned.) – prl Aug 25 '20 at 17:47
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    As a general rule, if you think it needs to be atomic, it probably does. – doron Aug 25 '20 at 18:02
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    Do you care whose value appears in the memory location? Last to write or any old value? – Erik Eidt Aug 25 '20 at 18:30
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    In C and C++ you need an atomic, as at most one concurrent writer is allowed without synchronization. In addition in C and C++ the compiler isn't required to write anything to memory until a sync event (the as-if rule). – rustyx Aug 25 '20 at 18:32
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    @ThomasMatthews It does, as of C11. – G.M. Aug 25 '20 at 18:46
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According to §5.1.2.4 ¶25 and ¶4 of the official ISO C standard, two different threads writing to the same memory location using non-atomic operations in an unordered fashion causes undefined behavior. The ISO C standard makes no exception to this rule if all threads are writing the same value.

Although writing a 32-bit integer to a 4-byte aligned address is guaranteed to be atomic by the Intel/AMD specifications for x86/x64 CPUs, such an operation is not guaranteed to be atomic by the ISO C standard, unless you are using a data type that is guaranteed to be atomic by the ISO C standard (such as atomic_int_least32_t). Therefore, even if your threads write a value of type int32_t to a 4-byte aligned address, according to the ISO C standard, your program will still cause undefined behavior.

However, for practical purposes, it is probably safe to assume that the compiler is generating assembly instructions that perform the operation atomically, provided that the alignment requirements are met.

Even if the memory writes were not aligned and the CPU wouldn't execute the write instructions atomically, it is likely that your program will still work as intended. It should not matter if a write operation is split up into two write operations, because all threads are writing the exact same value.

If you decide not to use an atomic variable, then you should at least declare the variable as volatile. Otherwise, the compiler may emit assembly instructions that cause the variable to be only stored in a CPU register, so that the other CPUs may never see any changes to that variable.

So, to answer your question: It is probably not necessary to declare your variable as atomic. However, it is still highly recommended. Generally, all operations on variables that are accessed by several threads should either be atomic or be protected by a mutex. The only exception to this rule is if all threads are performing read-only operations on this variable.

Playing around with undefined behavior can be dangerous and is generally not recommended. In particular, if the compiler detects code that causes undefined behavior, it is allowed to treat that code as unreachable and optimize it away. In certain situations, some compilers actually do that. See this very interesting post by Microsoft Blogger Raymond Chen for more information.

Also, beware that several threads writing to the same location (or even the same cache line) can disrupt the CPU pipeline, because the x86/x64 architecture guarantees strong memory ordering which must be enforced. If the CPU's cache coherency protocol detects a possible memory order violation due to another CPU writing to the same cache line, the whole CPU pipeline may have to be cleared. For this reason, it may be more efficient for all threads to write to different memory locations (in different cache lines, at least 64 bytes apart) and to analyze the written data after all threads have been synchronized.

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    it is probably safe to assume that the compiler is generating assembly instructions that perform the operation atomically - Yes, but it's not safe to assume that the stores or loads happen at all. They can be sunk or hoisted out of loops, unless you roll your own atomics with volatile – Peter Cordes Aug 25 '20 at 22:25
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    False-sharing is a problem even on CPUs with weakly-ordered memory models. They still need to maintain coherency, so a store can't commit from the store buffer to L1d cache unless the line is exclusively owned by this core. (In MESI Exclusive or Modified state.) But yes, on x86 false sharing can also have the extra bad effect on readers of memory-order mis-speculation pipeline nukes. That's not a stall per-se; without speculative early loads x86 CPUs would have to actually do loads in program order and stall on every cache miss load. – Peter Cordes Aug 25 '20 at 22:28
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    @HadiBrais: You're assuming that 2 threads writing the same value don't conflict. But the standard does define the term "conflict" early more strictly: p4 of the same section: Two expression evaluations conflict if one of them modifies a memory location and the other one reads or modifies the same memory location. No exception is made for writing the same value; this is technically data-race UB. – Peter Cordes Aug 25 '20 at 22:36
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    @HadiBrais: I was trying to guess what your exact argument was, thanks for clarifying. My understanding of that wording is that there's no "happens-before" relationship between the two assignments / stores. i.e. x = 42; in two separate threads without any mutual exclusion via locking or a release/acquire synchronization via some other variable. I don't see any way that writing the same value could change whether or not one "happens before" the other. – Peter Cordes Aug 25 '20 at 23:03
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    @HadiBrais: I'm not disputing that it will work in practice on real compilers, with synchronization before the read. Just that it's UB in ISO C++, and therefore a DeathStation 9000 compiler for x86 could do that mov [x], 41 / inc [x] code-gen if it wanted to (with invented reads from x), because that only breaks code with data-race UB. And yes, as you say, atomicity isn't required if the unsynchronized part compiles to pure writes. (But you'll have atomicity anyway because real compilers use alignof(int)=4.) – Peter Cordes Aug 25 '20 at 23:54

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