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I'm trying to figure out whether load and store operations on primitive types are atomics when we load/store from shared memory in CUDA.

On the one hand, it seems that any load/store is compiled to the PTX instruction ld.weak.shared.cta which does not enforce atomicity. But on the other hand, it is said in the manual that loads are serialized (9.2.3.1):

However, if multiple addresses of a memory request map to the same memory bank, the accesses are serialized

which hints to load/store atomicity "per-default" in shared memory. Thus, would the instructions ld.weak.shared.cta and ld.relaxed.shared.cta have the same effect? Or is it an information the compiler needs anyway to avoid optimizing away load and store?

More generally, supposing variables are properly aligned, would __shared__ int and __shared__ cuda::atomic<int, cuda::thread_scope_block> provide the same guarantees (when considering only load and store operations)?

Bonus (relevant) question: with a primitive data type properly aligned, stored in global memory, accessed by threads from a single block, are __device__ int and __device__ cuda::atomic<int, cuda::thread_scope_block> equivalent in term of atomicity of load/store operations?

Thanks for any insight.

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  • I don't have a complete answer but note that a non-atomic access allows compiler optimizations that will definitely change behavior, e.g. reordering, removing redundant loads, etc. So a fairer comparison would be with __shared__ volatile int.
    – Homer512
    Jun 11 at 11:58
  • Loads and stores being serialized doesn't mean atomicity. E.g. two threads load the same value from one address, both add one to it and both write back. Even with all the accesses being serialized, this is still a race condition and resulting in +1 instead of +2.
    – paleonix
    Jun 11 at 18:06
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    So no you wont get atomicity without requesting it explicitly in any of these cases I would say.
    – paleonix
    Jun 11 at 18:09
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    Thanks but, actually, I mean load and store atomicity, not an atomicAdd. Let's suppose I'd be happy to get 1 as a result if load and store are atomic, and I avoid torn reads and writes (for instance).
    – Pierre T.
    Jun 12 at 13:07
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    Hm, okay than I just want to say that all the stuff about shared memory conflicts is normally in terms of a single warp, so I'm not sure if one can interpret anything about accesses from different warps in the same block from that line.
    – paleonix
    Jun 12 at 22:09

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