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
  • Isn't _mm_malloc an informally-supported, un-standardized Intel extension? How could that be more platform independent than POSIX? – Useless Sep 16 '15 at 15:49
  • 3
    @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
  • 1
    @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

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

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.