ISO C++ doesn't define
__m256, so we need to look at what does define their behaviour on the implementations that support them.
Intel's intrinsics define vector-pointers like
__m256* as being allowed to alias anything else, the same way ISO C++ defines
char* as being allowed to alias.
So yes, it's safe to dereference a
__m256* instead of using a
_mm256_load_ps() aligned-load intrinsic.
But especially for float/double, it's often easier to use the intrinsics because they take care of casting from
float*, too. For integers, the AVX512 load/store intrinsics are defined as taking
void*, but before that you need an extra
(__m256i*) which is just a lot of clutter.
In gcc, this is implemented by defining
__m256 with a
may_alias attribute: from gcc7.3's
avxintrin.h (one of the headers that
/* The Intel API is flexible enough that we must allow aliasing with other
vector types, and their scalar components. */
typedef float __m256 __attribute__ ((__vector_size__ (32),
typedef long long __m256i __attribute__ ((__vector_size__ (32),
typedef double __m256d __attribute__ ((__vector_size__ (32),
/* Unaligned version of the same types. */
typedef float __m256_u __attribute__ ((__vector_size__ (32),
typedef long long __m256i_u __attribute__ ((__vector_size__ (32),
typedef double __m256d_u __attribute__ ((__vector_size__ (32),
(In case you were wondering, this is why dereferencing a
__m256* is like
GNU C native vectors without
may_alias are allowed to alias their scalar type, e.g. even without the
may_alias, you could safely cast between
float* and a hypothetical
v8sf type. But
may_alias makes it safe to load from an array of
char, or whatever.
I'm talking about how GCC implements Intel's intrinsics only because that's what I'm familiar with. I've heard from gcc developers that they chose that implementation because it was required for compatibility with Intel.
Other behaviour Intel's intrinsics require to be defined
Using Intel's API for
_mm_storeu_si128( (__m128i*)&arr[i], vec); requires you to create potentially-unaligned pointers which would fault if you deferenced them. And
_mm_storeu_ps to a location that isn't 4-byte aligned requires creating an under-aligned
Just creating unaligned pointers, or pointers outside an object, is UB in ISO C++, even if you don't dereference them. I guess this allows implementations on exotic hardware which do some kinds of checks on pointers when creating them (possibly instead of when dereferencing), or maybe which can't store the low bits of pointers. (I have no idea if any specific hardware exists where more efficient code is possible because of this UB.)
But implementations which support Intel's intrinsics must define the behaviour, at least for the
__m* types and
double*. This is trivial for compilers targeting any normal modern CPU, including x86 with a flat memory model (no segmentation); pointers in asm are just integers kept in the same registers as data. (m68k has address vs. data registers, but it never faults from keeping bit-patterns that aren't valid addresses in A registers, as long as you don't deref them.)
Going the other way: element access of a vector.
may_alias, like the
char* aliasing rule, only goes one way: it is not guaranteed to be safe to use
int32_t* to read a
__m256. It might not even be safe to use
float* to read a
__m256. Just like it's not safe to do
int *p = (int*)buf;.
Reading/writing through a
char* can alias anything, but when you have a
char object, strict-aliasing does make it UB to read it through other types. (I'm not sure if the major implementations on x86 do define that behaviour, but you don't need to rely on it because they optimize away
memcpy of 4 bytes into an
int32_t. You can and should use
memcpy to express an unaligned load from a
char buffer, because auto-vectorization with a wider type is allowed to assume 2-byte alignment for
int16_t*, and make code that fails if it's not: Why does unaligned access to mmap'ed memory sometimes segfault on AMD64?)
To insert/extract vector elements, use shuffle intrinsics, SSE2
_mm_extract_epi16 or SSE4.1 insert /
_mm_extract_epi8/32/64. For float, there are no insert/extract intrinsics that you should use with scalar
Or store to an array and read the array. (print a __m128i variable). This does actually optimize away to vector extract instructions.
GNU C vector syntax provides the
 operator for vectors, like
__m256 v = ...;
v = 1.25;. MSVC defines vector types as a union with a
.m128_f32 member for per-element access.
There are wrapper libraries like Agner Fog's (GPL licensed) Vector Class Library which provide portable
operator overloads for their vector types, and operator
<< and so on. It's quite nice, especially for integer types where having different types for different element widths make
v1 + v2 work with the right size. (GNU C native vector syntax does that for float/double vectors, and defines
__m128i as a vector of signed int64_t, but MSVC doesn't provide operators on the base
You can also use union type-punning between a vector and an array of some type, which is safe in ISO C99, and in GNU C++, but not in ISO C++. I think it's officially safe in MSVC, too, because I think the way they define
__m128 as a normal union.
There's no guarantee you'll get efficient code from any of these element-access methods, though. Do not use inside inner loops, and have a look at the resulting asm if performance matters.