4

Given the following test program:

#include <atomic>
#include <iostream>

int64_t process_one() {
        int64_t a;
        //Should be atomic on my haswell
        int64_t assign = 42;
        a = assign;
        return a;
}

int64_t process_two() {
        std::atomic<int64_t> a;
        int64_t assign = 42;
        a = assign;
        return a;
}

int main() {
        auto res_one = process_one();
        auto res_two = process_two();
        std::cout << res_one << std::endl;
        std::cout << res_two << std::endl;
}

Compiled with:

g++ --std=c++17 -O3 -march=native main.cpp

The code generated the following asm for the two functions:

00000000004007c0 <_Z11process_onev>:
  4007c0:       b8 2a 00 00 00          mov    $0x2a,%eax
  4007c5:       c3                      retq
  4007c6:       66 2e 0f 1f 84 00 00    nopw   %cs:0x0(%rax,%rax,1)
  4007cd:       00 00 00

00000000004007d0 <_Z11process_twov>:
  4007d0:       48 c7 44 24 f8 2a 00    movq   $0x2a,-0x8(%rsp)
  4007d7:       00 00
  4007d9:       0f ae f0                mfence
  4007dc:       48 8b 44 24 f8          mov    -0x8(%rsp),%rax
  4007e1:       c3                      retq
  4007e2:       66 2e 0f 1f 84 00 00    nopw   %cs:0x0(%rax,%rax,1)
  4007e9:       00 00 00
  4007ec:       0f 1f 40 00             nopl   0x0(%rax)

Personally I don't speak much assembler but (and I might be mistaken here) it seems that process_two compiled to include all of process_one's and then some.

However, as far as I know, 'modern' x86-64 processors (e.g. Haswell, on which I compiled this) will do assignment atomically without the need for any extra operations (in this case I believe the extra operation is the mfence instruction in process_two).

So why wouldn't gcc just optimize the code in process two to behave exactly the case as process one ? Given the flags I compiled with.

Are there still cases where an atomic store behaves differently than an assignment to a normal variable given that they are both on 8 bytes.

13
  • You are aware that -Ofast breaks floating-point math? Jul 20, 2017 at 9:09
  • I don't see any floating point operations here, @Henri, so I'm not sure how that is relevant. George, the concept of "atomicity" doesn't make any sense when applied to local, temporary variables in a single-threaded process. Could G++ have noticed that and transformed std::atomic in process_two to a no-op? Probably. But why should it bother making that optimization? If you don't need atomic semantics, then don't use a type that provides them.
    – Cody Gray
    Jul 20, 2017 at 9:12
  • 1
    @PaulR Not so fast with conclusions. Move that atomic variable outside the function scope as it would be in real MT program and situation changes. Jul 20, 2017 at 11:28
  • 2
    @MarekVitek: you may be right, but I was just using the OP's code as it appears above and comparing how different compilers deal with it.
    – Paul R
    Jul 20, 2017 at 11:55
  • 1
    @CodyGray - on reason it would be good to optimize such a pattern (e.g., by noting that the atomic variable is local and does not escape and eliding the atomic stuff) is for generic code. Imagine a template function that sums values by creating a local T on the stack as the accumulator. The writer doesn't know the type of T, but if someone passes an atomic it would be nice to have the writes to the local be non-atomic (of course the reads still need to be atomic).
    – BeeOnRope
    Jul 23, 2017 at 23:29

2 Answers 2

10

The reason for it is that default use of std::atomic also implies memory order

std::memory_order order = std::memory_order_seq_cst

To achieve this consistency the compiler has to tell processor to not reorder instructions. And it does by using mfence instruction.

Change your

    a = assign;

to

    a.store(assign, std::memory_order_relaxed);

and your output will change from

process_two():
        mov     QWORD PTR [rsp-8], 42
        mfence
        mov     rax, QWORD PTR [rsp-8]
        ret

to

process_two():
        mov     QWORD PTR [rsp-8], 42
        mov     rax, QWORD PTR [rsp-8]
        ret

Just as you expected it to be.

12
  • 4
    Correct. Minor nitpick: "tell processor to not reorder instructions" is not 100% correct (since mfence doesn't serialise). I can't come with a short sentence describing all the nuisances of memory ordering and visibility on x86. I think something like "tell the processor to respect the memory ordering and visibility" might do. :) Jul 20, 2017 at 10:33
  • @MargaretBloom Yes you are right. It tells CPU that instructions that come before mfence will be executed before no matter in what order and instructions that come after will be executed after mfence. In other words stores before mfence will be visible to loads after. Jul 20, 2017 at 10:57
  • 1
    Or maybe words from documentation "wait on following loads and stores until the preceding loads and stores are globally visible" Jul 20, 2017 at 11:13
  • Without the mfence instruction, is it possible that two threads will view a difference value of the variable a "at the same time" ? Or does mfence only affect the order in which threads that reach that instruction execute the operation (e.g. if thread x and y reach the instruction whoever reaches it first executes it first)
    – George
    Jul 20, 2017 at 12:15
  • mfence just ensures that instructions around it are in expected order. Let's say you have variable you want to pass to other thread and guard variable. You write to your variable some data and then you write to guard variable, that data are available. In other thred you check guard and then read data. Just imagine if the write to guard will be moved before write to data. Then in other thread you might think data are in place while they are not. Maybe check this SO for some more info. It might shed some more light on your question. Jul 20, 2017 at 12:30
2

It's just a missed optimization. For example, clang does just fine with it - both functions compile identically as a single mov eax, 42.

Now, you'd have to dig into the gcc internals to be sure, but it seems to be that gcc has not yet implemented many common and legal optimizations around atomic variables, including merging consecutive reads and writes. In fact, none of clang, icc or gcc seem to optimize much of anything yet except that clang handles local atomics (including passed-by-value) by essentially removing their atomic nature, which is useful in some cases such as generic code. Sometimes icc seems to generate especially bad code - see two_reads here, for example: it seems to only ever want to use rax as the address and as the accumulator, resulting in a stream of mov instructions shuffling things around.

Some more complex issues around atomic optimization are discussed here and I expect compilers will get better at this over time.

6
  • Migrating the comment responses here, I agree that the template example is a good case where this optimization would be handy (and the standard go-to case for C++ code). I'm certainly not going to disagree that compilers should implement optimizations. :-) I think there are two basic reasons that atomic operations aren't optimized. One is the obvious: complexity, and the desire to avoid bugs. The second is just that std::atomic is pretty new on the scene, as far as things go, and compiler vendors haven't had much time to optimize around it.
    – Cody Gray
    Jul 24, 2017 at 11:06
  • Some compilers just recently added support (looking at you, MSVC). I was just trying to figure out exactly what the question being asked here was. I interpreted it much the same way as you: why isn't the compiler optimizing this? And the answer is, of course, a simple missed optimization opportunity. But it seems that Marek interpreted the question in a slightly different way, and therefore took his answer in a different direction. Both are correct, of course, but I was hesitant to post an answer of my own until I could narrow down better what was being asked. Glad to see this posted too.
    – Cody Gray
    Jul 24, 2017 at 11:08
  • Yes, I think they fail mostly because of the newness of the formal memory model and the std::atomic stuff, although perhaps I wasn't clear enough in my answer. Note that you don't need to invoke templates to make the "local atomic" optimization make sense: simply imagine any std::atomic member of a class: when that class is used as a local, you'd like not to pay the atomic cost and this kind of "escape analysis" can do it. FWIW I found that clang's optimization are actually quite limited - they get the assigned above, but if you change it to += they emit atomic instructions.
    – BeeOnRope
    Jul 24, 2017 at 19:32
  • @CodyGray - yup, if I really tried to the read the mind of the OP, I would say that he probably wanted to ask the question that Marek answered, which is something like "Why does simple assignment need fences/lock prefix when it is already atomic in the hardware" - since he mentions that. I'm answering the question posed by his code, which is "Why doesn't gcc optimize atomics which are provably restricted to one thread" which perhaps also useful to someone :)
    – BeeOnRope
    Jul 24, 2017 at 19:35
  • This is an assignment with memory_order_seq_cst. It must make sure that all preceding stores become visible to other threads and subsequent loads do not get reordered before this store. Hence mfence. The compiler is doing the right thing here. Sep 25, 2017 at 14:50

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