I am having alignment issue while using ymm registers, with some snippets of code that seems fine to me. Here is a minimal working example:

#include <iostream> 
#include <immintrin.h>

inline void ones(float *a)
     __m256 out_aligned = _mm256_set1_ps(1.0f);

int main()
     size_t ss = 8;
     float *a = new float[ss];

     delete [] a;

     std::cout << "All Good!" << std::endl;
     return 0;

Certainly, sizeof(float) is 4 on my architecture (Intel(R) Xeon(R) CPU E5-2650 v2 @ 2.60GHz) and I'm compiling with gcc using -O3 -march=native flags. Of course the error goes away with unaligned memory access i.e. specifying _mm256_storeu_ps. I also do not have this problem on xmm registers, i.e.

inline void ones_sse(float *a)
     __m128 out_aligned = _mm_set1_ps(1.0f);

Am I doing anything foolish? what is the work-around for this?

  • 4
    A bit off topic, but remember to use delete [] when deleting something allocated with new []. – anorm Sep 16 '15 at 15:04
  • 1
    did you try _mm_malloc instead of new? – Alexander Sep 16 '15 at 15:16
  • @anorm true. Edited – romeric Sep 16 '15 at 15:18
  • 3
    I guess a simple summary would be because new/malloc return 16-byte aligned pointer on x64; it's enough for SSE, but AVX needs 32-byte alignment. – stgatilov Sep 16 '15 at 15:44
  • 1
    Perhaps this is interesting too: stackoverflow.com/questions/16376942/… – stgatilov Sep 16 '15 at 16:19

The standard allocators normally only align to alignof(maxalign_t), which is often 16B, e.g. long double in the x86-64 System V ABI. But in some 32-bit ABIs it's only 8B, so it's not even sufficient for dynamic allocation of aligned __m128 vectors and you'll need to go beyond simply calling new or malloc.

Static and automatic storage are easy: use alignas(32) float arr[N];

C++17 provides aligned new for aligned dynamic allocation that's compatible with delete:
float * arr = new (std::align_val_t(32)) float[numSteps];
See documentation for new/new[] and std::align_val_t

Other options for dynamic allocation are mostly compatible with malloc/free, not new/delete:

  • std::aligned_alloc: ISO C++17. major downside: size must be a multiple of alignment. This braindead requirement makes it inappropriate for allocating a 64B cache-line aligned array of an unknown number of floats, for example. Or especially a 2M-aligned array to take advantage of transparent hugepages.

    The C version of aligned_alloc was added in ISO C11. It's available in some but not all C++ compilers. As noted on the cppreference page, the C11 version wasn't required to fail when size isn't a multiple of alignment (it's undefined behaviour), so many implementations provided the obvious desired behaviour as an "extension". Discussion is underway to fix this, but for now I can't really recommend aligned_alloc as a portable way to allocate arbitrary-sized arrays.

    Also, commenters report it's unavailable in MSVC++. See best cross-platform method to get aligned memory for a viable #ifdef for Windows. But AFAIK there are no Windows aligned-allocation functions that produce pointers compatible with standard free.

  • posix_memalign: Part of POSIX 2001, not any ISO C or C++ standard. Clunky prototype/interface compared to aligned_alloc. I've seen gcc generate reloads of the pointer because it wasn't sure that stores into the buffer didn't modify the pointer. (Since posix_memalign is passed the address of the pointer.) So if you use this, copy the pointer into another C++ variable that hasn't had its address passed outside the function.

#include <stdlib.h>
int posix_memalign(void **memptr, size_t alignment, size_t size);  // POSIX 2001
void *aligned_alloc(size_t alignment, size_t size);                // C11 (and ISO C++17)
  • _mm_malloc: Available on any platform where _mm_whatever_ps is available, but you can't pass pointers from it to free. On many C and C++ implementations _mm_free and free are compatible, but it's not guaranteed to be portable. (And unlike the other two, it will fail at run-time, not compile time.) On MSVC on Windows, _mm_malloc uses _aligned_malloc, which is not compatible with free; it crashes in practice.

In C++11 and later: use alignas(32) float avx_array[1234] as the first member of a struct/class member (or on a plain array directly) so static and automatic storage objects of that type will have 32B alignment. std::aligned_storage documentation has an example of this technique to explain what std::aligned_storage does.

This doesn't actually work for dynamically-allocated storage (like a std::vector<my_class_with_aligned_member_array>), see Making std::vector allocate aligned memory.

In C++17, there might be a way to use aligned new for std::vector. TODO: find out how.

And finally, the last option is so bad it's not even part of the list: allocate a larger buffer and add do p+=31; p&=~31ULL with appropriate casting. Too many drawbacks (hard to free, wastes memory) to be worth discussing, since aligned-allocation functions are available on every platform that support Intel _mm256 intrinsics. But there are even library functions that will help you do this, IIRC.

The requirement to use _mm_free instead of free probably exists to for the possibility of implementing _mm_malloc on top of a plain old malloc using this technique.

  • Could you please explain why you prefer POSIX-only function over platform independent _mm_malloc? – stgatilov Sep 16 '15 at 15:38
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    @Useless: If you're using _mm_whatever intrinsics for SSE / AVX / other instructions, you will also have _mm_malloc available. If keeping your aligned allocs separate from your unaligned allocs isn't a problem, or you can just use _mm_malloc / _mm_free everywhere in your program, and don't interact with any libraries that allocate or free anything, then that's a valid option, too. – Peter Cordes Sep 16 '15 at 15:58
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    @PeterCordes aligned_alloc looks best of the lot to me. Is there any general consensus on which one, one should use? – romeric Sep 16 '15 at 16:08
  • 1
    Since you mention C++17: alignas+dynamic allocation was finally fixed there. – Marc Glisse May 1 '17 at 7:42
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    @matejk: I'm not sure if you have to write your own allocator or if there's already a template allocator you can customize. I'm totally unimpressed with C++ as far as alignment support for dynamic allocation, or exposing efficient realloc or calloc for std::vector to take advantage of. It's also just ridiculous how bad it is, and that it took until C++17 for new __m256[] to even work. I don't get WTF is so hard about making alignment a template parameter that becomes part of the type. And even C is missing a portable aligned realloc or calloc, AFAIK. – Peter Cordes Aug 2 at 9:13

There are the two intrinsics for memory management. _mm_malloc operates like a standard malloc, but it takes an additional parameter that specifies the desired alignment. In this case, a 32 byte alignment. When this allocation method is used, memory must be freed by the corresponding _mm_free call.

float *a = static_cast<float*>(_mm_malloc(sizeof(float) * ss , 32));

You'll need aligned allocators.

But there isn't a reason you can't bundle them up:

template<class T, size_t align>
struct aligned_free {
  void operator()(T* t)const{
    ASSERT(!(uint_ptr(t) % align));
  aligned_free() = default;
  aligned_free(aligned_free const&) = default;
  aligned_free(aligned_free&&) = default;
  // allow assignment from things that are
  // more aligned than we are:
  template<size_t o,
    std::enable_if_t< !(o % align) >* = nullptr
  aligned_free( aligned_free<T, o> ) {}
template<class T>
struct aligned_free<T[]>:aligned_free<T>{};

template<class T, size_t align=1>
using mm_ptr = std::unique_ptr< T, aligned_free<T, align> >;
template<class T, size_t align>
struct aligned_make;
template<class T, size_t align>
struct aligned_make<T[],align> {
  mm_ptr<T, align> operator()(size_t N)const {
    return mm_ptr<T, align>(static_cast<T*>(_mm_malloc(sizeof(T)*N, align)));
template<class T, size_t align>
struct aligned_make {
  mm_ptr<T, align> operator()()const {
    return aligned_make<T[],align>{}(1);
template<class T, size_t N, size_t align>
struct aligned_make<T[N], align> {
  mm_ptr<T, align> operator()()const {
    return aligned_make<T[],align>{}(N);
// T[N] and T versions:
template<class T, size_t align>
auto make_aligned()
-> std::result_of_t<aligned_make<T,align>()>
  return aligned_make<T,align>{}();
// T[] version:
template<class T, size_t align>
auto make_aligned(size_t N)
-> std::result_of_t<aligned_make<T,align>(size_t)>
  return aligned_make<T,align>{}(N);

now mm_ptr<float[], 4> is a unique pointer to an array of floats that is 4 byte aligned. You create it via make_aligned<float[], 4>(20), which creates 20 floats 4-byte aligned, or make_aligned<float[20], 4>() (compile-time constant only in that syntax). make_aligned<float[20],4> returns mm_ptr<float[],4> not mm_ptr<float[20],4>.

A mm_ptr<float[], 8> can move-construct a mm_ptr<float[],4> but not vice-versa, which I think is nice.

mm_ptr<float[]> can take any alignment, but guarantees none.

Overhead, like with a std::unique_ptr, is basically zero per pointer. Code overhead can be minimized by aggressive inlineing.

  • I like the idea of move-construction from less to a more aligned pointer. – romeric Sep 16 '15 at 21:36
  • @romeric from more to less – Yakk - Adam Nevraumont Sep 16 '15 at 22:03
  • Oh right yeah, jeez! – romeric Sep 17 '15 at 2:22

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