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If I want to process data in a std::vector with SSE, I need 16 byte alignment. How can I achieve that? Do I need to write my own allocator? Or does the default allocator already align to 16 byte boundaries?

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In C++11, there's an aligned_storage. Maybe there's also an aligned_allocator? Lemme check. –  Xeo Dec 10 '11 at 11:40
possible duplicate of SSE and C++ containers –  Paul R Dec 10 '11 at 11:43

6 Answers 6

up vote 7 down vote accepted

C++ standard requires allocation functions (malloc() and operator new()) to allocate memory suitably aligned for any standard type. As these functions don't receive the alignment requirement as an argument, on practice it means that the alignment for all allocations is the same and is the alignment of a standard type with the largest alignment requirement, which often is long double and/or long long (see boost max_align union).

Vector instructions, such as SSE and AVX, have stronger alignment requirements (16-byte aligned for 128-bit access and 32-byte aligned for 256-bit access) than that provided by the standard C++ allocation functions. posix_memalign() or memalign() can be used to satisfy such allocations with stronger alignment requirements.

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You should use a custom allocator with std:: containers, such as vector. Can't remember who wrote the following one, but I used it for some time and it seems to work (you might have to change _aligned_malloc to _mm_malloc, depending on compiler/platform):


#include <stdlib.h>
#include <malloc.h>

template <typename T, std::size_t N = 16>
class AlignmentAllocator {
  typedef T value_type;
  typedef std::size_t size_type;
  typedef std::ptrdiff_t difference_type;

  typedef T * pointer;
  typedef const T * const_pointer;

  typedef T & reference;
  typedef const T & const_reference;

  inline AlignmentAllocator () throw () { }

  template <typename T2>
  inline AlignmentAllocator (const AlignmentAllocator<T2, N> &) throw () { }

  inline ~AlignmentAllocator () throw () { }

  inline pointer adress (reference r) {
    return &r;

  inline const_pointer adress (const_reference r) const {
    return &r;

  inline pointer allocate (size_type n) {
     return (pointer)_aligned_malloc(n*sizeof(value_type), N);

  inline void deallocate (pointer p, size_type) {
    _aligned_free (p);

  inline void construct (pointer p, const value_type & wert) {
     new (p) value_type (wert);

  inline void destroy (pointer p) {
    p->~value_type ();

  inline size_type max_size () const throw () {
    return size_type (-1) / sizeof (value_type);

  template <typename T2>
  struct rebind {
    typedef AlignmentAllocator<T2, N> other;

  bool operator!=(const AlignmentAllocator<T,N>& other) const  {
    return !(*this == other);

  // Returns true if and only if storage allocated from *this
  // can be deallocated from other, and vice versa.
  // Always returns true for stateless allocators.
  bool operator==(const AlignmentAllocator<T,N>& other) const {
    return true;


Use it like this (change the 16 to another alignment, if needed):

std::vector<T, AlignmentAllocator<T, 16> > bla;

This, however, only makes sure the memory block std::vector uses is 16-bytes aligned. If sizeof(T) is not a multiple of 16, some of your elements will not be aligned. Depending on your data-type, this might be a non-issue. If T is int (4 bytes), only load elements whose index is a multiple of 4. If it's double (8 bytes), only multiples of 2, etc.

The real issue is if you use classes as T, in which case you will have to specify your alignment requirements in the class itself (again, depending on compiler, this might be different; the example is for GCC):

class __attribute__ ((aligned (16))) Foo {
    __attribute__ ((aligned (16))) double u[2];

We're almost done! If you use Visual C++ (at least, version 2010), you won't be able to use an std::vector with classes whose alignment you specified, because of std::vector::resize.

When compiling, if you get the following error:

C:\Program Files\Microsoft Visual Studio 10.0\VC\include\vector(870):
error C2719: '_Val': formal parameter with __declspec(align('16')) won't be aligned

You will have to hack your stl::vector header file:

  1. Locate the vector header file [C:\Program Files\Microsoft Visual Studio 10.0\VC\include\vector]
  2. Locate the void resize( _Ty _Val ) method [line 870 on VC2010]
  3. Change it to void resize( const _Ty& _Val ).
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Write your own allocator. allocate and deallocate are the important ones. Here is one example:

pointer allocate( size_type size, const void * pBuff = 0 )
    char * p;

    int difference;

    if( size > ( INT_MAX - 16 ) )
        return NULL;

    p = (char*)malloc( size + 16 );

    if( !p )
        return NULL;

    difference = ( (-(int)p - 1 ) & 15 ) + 1;

    p += difference;
    p[ -1 ] = (char)difference;

    return (T*)p;

void deallocate( pointer p, size_type num )
    char * pBuffer = (char*)p;

    free( (void*)(((char*)p) - pBuffer[ -1 ] ) );
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Your code won't probably work on a 64-bit platform. You should rather use intptr_t (which is guaranteed to have the size of a pointer) instead of int and remove this INT_MAX (size is most probably unsigned anyway). –  Christian Rau Dec 10 '11 at 15:00
@Christian, it's just an idea on how to solve the problem. I can explain better with C/C++ while the rest of falks are just commenting. That's why I wrote that. Fred is the only one who knows how exactly is he gonna solve it. I hope this will lead him in the right direction. –  moose Dec 10 '11 at 15:27
While I understand your argument it isn't that hard to turn this code into something more robust with just a few changes that won't make it more complicated. But you got my +1. –  Christian Rau Dec 10 '11 at 15:32

Short Answer:

If sizeof(T)*vector.size() > 16 then Yes.
Assuming you vector uses normal allocators

Long Answer:

If it is aligned for anything that is greater than 16 it is also aligned correctly for 16.

3.11 Alignment (Paragraph 4/5)

Alignments are represented as values of the type std::size_t. Valid alignments include only those values returned by an alignof expression for the fundamental types plus an additional implementation-defined set of values, which may be empty. Every alignment value shall be a non-negative integral power of two.

Alignments have an order from weaker to stronger or stricter alignments. Stricter alignments have larger alignment values. An address that satisfies an alignment requirement also satisfies any weaker valid alignment requirement.

new and new[] return values that are aligned so that objects are correctly aligned for their size:

5.3.4 New (paragraph 14)

[ Note: when the allocation function returns a value other than null, it must be a pointer to a block of storage in which space for the object has been reserved. The block of storage is assumed to be appropriately aligned and of the requested size. The address of the created object will not necessarily be the same as that of the block if the object is an array. — end note ]

Thus as long as your vector memory allocated is greater than 16 bytes it will be correctly aligned on 16 byte boundaries.

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What is the reference for these quotations? –  mabraham May 27 '13 at 8:52
The C++ standard: stackoverflow.com/a/4653479/14065 –  Loki Astari May 27 '13 at 16:58

Don't assume anything about STL containers. Their interface/behaviour is defined, but not what's behind them. If you need raw access, you'll have to write your own implementation that follows the rules you'd like to have.

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std::vector<..> is an exception in that it guarantees that the underlying memory is a contiguous block. (in C++03, but also in C++11) –  Simon Dec 10 '11 at 12:05
-1 vector uses new which has gurantees about alignment. –  Loki Astari Dec 10 '11 at 18:10
Loki: I'm rather sure the older standards didn't define it for vectors (as Simon suggests). Also, just due to new keeping the base address aligned, doesn't mean all elements following are aligned too (e.g. due to length, packing, etc.). –  Mario Dec 11 '11 at 10:19
Actually, rereading the question, it's not really clear, if the OP wants to access all elements through one pointer moving or simply wants to pass each element to some SSE call. In later case, sure, you're right about the alignment. –  Mario Dec 11 '11 at 10:23
Loki: std::vector does not use new it uses the supplied allocator defaulting to std::allocator. –  Florian Oct 12 '12 at 19:56

The Standard mandates that new and new[] return data aligned for any data type, which should include SSE. Whether or not MSVC actually follows that rule is another question.

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Where did @Fred say anything about MSVC? –  Xeo Dec 10 '11 at 11:59
"which should include SSE" - but typically doesn't. Last I checked, both Windows and Linux only guaranteed 8-alignment for allocated memory, and neither MSVC nor glibc did anything to increase the alignment. I believe the weasel-wording is that since SSE operations are non-standard, they can have any behavior the implementer chooses, including it being undefined to perform SSE ops on memory that is not 16-aligned. You can store extended SSE types in 8-aligned memory, so lip service is paid to the standard, but in practice you have to read it as not applying to non-standard types. –  Steve Jessop Dec 10 '11 at 12:12
Really for any type? So if I myself come up with a data type that needs 4096-alignment that would be supported, too? Of course this example is rubbish, but I hope you see that the any is a bit misplaced. I guess it's any standard type, to which I'm pretty sure SSE types don't belong as the C++ standard doesn't make any mentioning of SSE. –  Christian Rau Dec 10 '11 at 12:43
Why has this answer been voted up - it is utter and complete rubbish. –  Jared Krumsie Dec 10 '11 at 19:48
@ChristianRau: It means any alignment requirement imposed by the implementation on a type. Yes, you could write a library which takes a char* or MYTHING* pointer parameter, and checks whether that pointer is 4096-aligned, and aborts, throws, or does something undefined if it isn't. This does not imply that char or MYTHING has a 4096 alignment requirement within the meaning of the standard. I think the standard did intend that any alignment requirement imposed by the implementation would be catered for by malloc and new, but implementers deemed it impractical due to wasted space. –  Steve Jessop Dec 12 '11 at 9:43

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