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The following question is related, however answers are old, and comment from user Marc Glisse suggests there are new approaches since C++17 to this problem that might not be adequately discussed.

I'm trying to get aligned memory working properly for SIMD, while still having access to all of the data.

On Intel, if I create a float vector of type __m256, and reduce my size by a factor of 8, it gives me aligned memory.

E.g. std::vector<__m256> mvec_a((N*M)/8);

In a slightly hacky way, I can cast pointers to vector elements to float, which allows me to access individual float values.

Instead, I would prefer to have an std::vector<float> which is correctly aligned, and thus can be loaded into __m256 and other SIMD types without segfaulting.

I've been looking into aligned_alloc.

This can give me a C-style array that is correctly aligned:

auto align_sz = static_cast<std::size_t> (32);
float* marr_a = (float*)aligned_alloc(align_sz, N*M*sizeof(float));

However I'm unsure how to do this for std::vector<float>. Giving the std::vector<float> ownership of marr_a doesn't seem to be possible.

I've seen some suggestions that I should write a custom allocator, but this seems like a lot of work, and perhaps with modern C++ there is a better way?

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    without segfaulting... or without potential slowdowns from cache-line splits when you use _mm256_loadu_ps(&vec[i]). (Although note that with default tuning options, GCC splits not-guaranteed-aligned 256-bit loads/stores into vmovups xmm / vinsertf128. So there is an advantage to using _mm256_load over loadu if you care about how your code compiles on GCC if someone forgets to use -mtune=... or -march= options.) Feb 11 '20 at 13:29
  • @PrunusPersica Did you end up getting this to work ? I have the same problem. We can work together if you wish ?
    – gansub
    Aug 25 '20 at 15:39
  • @gansub I ended up using the code of boost::alignment::aligned_allocator. Then I could allocate the vector with std::vector<T, aligned_allocator<float>>. It does make normal std::vectors not directly compatible with this type of aligned vector, but you can always write ways around that. Aug 28 '20 at 17:28
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All containers in the standard C++ library, including vectors, have an optional template parameter that specifies the container's allocator, and it is not really a lot of work to implement your own one:

class my_awesome_allocator {
};

std::vector<float, my_awesome_allocator> awesomely_allocated_vector;

You will have to write a little bit of code that implements your allocator, but it wouldn't be much more code than you already written. If you don't need pre-C++17 support you only need to implement the allocate() and deallocate() methods, that's it.

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  • They also need to specialize allocator_traits Feb 11 '20 at 13:43
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    This might be a good place for a canonical answer with an example that people can copy/paste to jump through C++'s annoying hoops. (Bonus points if there's a way to let std::vector try to realloc in-place instead of the usual braindead C++ always alloc+copy.) Also of course note that this vector<float, MAA> is not type-compatible with vector<float> (and can't be because anything that does .push_back on a plain std::vector<float> compiled without this allocator could do a new allocation and copy into minimally-aligned memory. And new/delete isn't compatible with aligned_alloc/free) Feb 11 '20 at 13:43
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    I don't think there is any guarantee that the pointer returned from the allocator is directly used as the base address of the std::vector's array. For example, I could imagine an implementation of std::vector using just one pointer to the allocated memory which stores the end/capacity/allocator in the memory prior to the range of values. That could easily foil the alignment done by the allocator. Feb 11 '20 at 14:10
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    Except that std::vector guarantees it. That's what it uses it for. Perhaps you should review what the C++ standard specifies here. Feb 11 '20 at 14:23
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    > They also need to specialize allocator_traits -- No, they don't. All that's needed is to implement a compliant allocator. Feb 11 '20 at 14:26

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