Puzzling GCC behaviour with respect to vectorization and loop size

Question

Initially investigating the effect of the #pragma omp simd directive, I came across a behaviour that I cannot explain, related to the vectorization of a simple for loop. The following code sample can be tested on this awesome compiler explorer, provided the -O3 directive is applied and we're on the x86 architecture.

Could anybody explain me the logic behind the following observations ?

#include <stdint.h> 

void test(uint8_t* out, uint8_t const* in, uint32_t length)
{
    unsigned const l1 = (length * 32)/32;  // This is vectorized
    unsigned const l2 = (length / 32)*32;  // This is not vectorized

    unsigned const l3 = (length << 5)>>5;  // This is vectorized
    unsigned const l4 = (length >> 5)<<5;  // This is not vectorized

    unsigned const l5 = length -length%32; // This is not vectorized
    unsigned const l6 = length & ~(32 -1); // This is not vectorized

    for (unsigned i = 0; i<l1 /*pick your choice*/; ++i)
    {
      out[i] = in[i*2];
    }
}

What puzzles me is that both l1 and l3 generate vectorized code in spite of not beeing guaranteed to be multiples of 32. All of the other lengths do not produce vectorized code, but should be multiples of 32. Is there a reason behind this ?

As an aside, using the #pragma omp simd directive doesn't actually change anything.

Edit: After further investigation, the difference of behaviour disappears when the index type is size_t (and no boundary manipulation is even needed), meaning that this generates vectorized code :

#include <stdint.h> 
#include <string>

void test(uint8_t* out, uint8_t const* in, size_t length)
{
    for (size_t i = 0; i<length; ++i)
    {
        out[i] = in[i*2];
    }
}

If somebody know why the loop vectorizing is so dependent on the index type then, I'd be curious to know more !

Edit2, thanks to Mark Lakata, O3 is actually needed

Answer 1

The issue is apparent conversion¹ from unsigned to size_t in the array index: in[i*2];

If you use l1 or l3 then the computation of i*2 will always fit into the type size_t. This means that the type unsigned practically behaves as if it were size_t.

But when you use the other options, the result of the computation i*2 can possibly not fit into size_t as the value might wrap and the conversion must be made.

if you take your first example, not choosing options l1 or l3, and do the cast:

out[i] = in[( size_t )i*2];

the compiler optimizes, if you cast the whole expression:

out[i] = in[( size_t )(i*2)];

it doesn't.

---

¹ The Standard doesn't actually specify that the type in the index must be size_t, but it is a logical step from the compiler perspective.

Answer 2

I believe you are confusing optimization with vectorization. I used your compiler explorer and set -O2 for x86, and none of the examples are "vectorized".

Here is l1

test(unsigned char*, unsigned char const*, unsigned int):
        xorl    %eax, %eax
        andl    $134217727, %edx
        je      .L1
.L5:
        movzbl  (%rsi,%rax,2), %ecx
        movb    %cl, (%rdi,%rax)
        addq    $1, %rax
        cmpl    %eax, %edx
        ja      .L5
.L1:
        rep ret

Here is l2

test(unsigned char*, unsigned char const*, unsigned int):
        andl    $-32, %edx
        je      .L1
        leal    -1(%rdx), %eax
        leaq    1(%rdi,%rax), %rcx
        xorl    %eax, %eax
.L4:
        movl    %eax, %edx
        addq    $1, %rdi
        addl    $2, %eax
        movzbl  (%rsi,%rdx), %edx
        movb    %dl, -1(%rdi)
        cmpq    %rcx, %rdi
        jne     .L4
.L1:
        rep ret

That is not surprising, because what you are doing is essentially a "gather" load operation, where the load indices are not the same as the store indices. There is no support in x86 for gather/scatter. It is only introduced in AVX2 and AVX512, and that is not selected.

The slightly longer code is dealing with the signed/unsigned issues, but there is no vectorization going on.