How to treat result of vaddv_u8 in arm64 as a neon register

Question

vaddv_u8 and some other similar new v-intrinsics from AArch64 (arm64) return uint8_t. How can I treat result of this intrinsic as a neon register instead of plain C type?

For example:

void paddClz(uint8_t* x)
{
    uint8x8_t ret = vdup_n_u8(0);
    for (int i = 0; i < 8; ++i, x += 8)
    {
        uint8x8_t x8 = vld1_u8(x);
        uint8_t sum = vaddv_u8(x8);
        uint8x8_t r = vdup_n_u8(sum); //or: r = vset_lane_u8(sum, r, 0);
        r = vclz_u8(r);
        ret = vext_u8(ret, r, 1);
    }
    vst1_u8(x, ret);
}

what clang generated:

paddClz(unsigned char*): // @paddClz(unsigned char*)
  mov x8, xzr
  movi d0, #0000000000000000
.LBB0_1: // =>This Inner Loop Header: Depth=1
  ldr d1, [x0, x8]
  add x8, x8, #8 // =8
  cmp w8, #64 // =64
  addv b1, v1.8b
  dup v1.8b, v1.b[0]   <<== useless! I only need/use/care about v1.b[0]
  clz v1.8b, v1.8b
  ext v0.8b, v0.8b, v1.8b, #1
  b.ne .LBB0_1
  str d0, [x0, #64]
  ret

As you can see there is a useless dup intrinsic required to get the uint8_t vaddv_u8 result converted to a type that will work as an argument for vclz_u8. I take only first lane from the subsequent vclz_u8 result, so actually duplicating it to all lanes would be wasted work.

How can I write it in intrinsics to get that sum in neon typed variable without making the compiler emit useless opcodes? (And preferably without this extra noise in the source code.) To make it clear and obvious if it wasn't: I'm not asking to optimize or improve that piece of code that I posted; I simply wrote it to show the issue.

Answer 1

You should really get a test device with an in-order SoC. Apple's A series chips are all out-of-order, by far the most powerful ones to be precise.

Your implementation might run adequately fast on your iPhone, but will be barely any faster than the simplest C versions on in-order cores, straight unusable.

Think twice before you rush into writing loops on NEON. You can avoid the so-called "horizontal" operations altogether most of the time by transposing the matrix, then do the "vertical" math instead.

---

#define vuzp8(a, b, c) ({ \
    c = vuzp_u8(a, b); \
    a = c.val[0]; \
    b = c.val[1]; \
})

void foo(uint8_t *pDst, uint8_t *pSrc)
{
    uint8x8x4_t top, bottom;
    uint8x8x2_t temp;

    top = vld4_u8(pSrc);
    pSrc += 32;
    bottom = vld4_u8(pSrc);

    vuzp8(top.val[0], bottom.val[0], temp);
    vuzp8(top.val[1], bottom.val[1], temp);
    vuzp8(top.val[2], bottom.val[2], temp);
    vuzp8(top.val[3], bottom.val[3], temp);

    top.val[0] += bottom.val[0];
    top.val[1] += bottom.val[1];
    top.val[2] += bottom.val[2];
    top.val[3] += bottom.val[3];

    top.val[0] += top.val[1];
    top.val[2] += top.val[3];

    top.val[0] += top.val[2];

    top.val[0] = vclz_u8(top.val[0]);

    vst1_u8(pDst, top.val[0]);
}

---

Another example where you ask yourself if intrinsux makes sense at all. Its clumsiness makes the code much more complex, and it isn't expressive enough to do three 128bit plus one 64bit adds instead of six 64bit ones.

In addition, you have to double check if the compiler didn't mess up anything, again, especially when you do permutations(vzip, vuzp, vtrn)

I think the machine code will be fine on aarch32, but I'm not so sure about aarch64 where the permutation instructions are vastly different.

I think that you understand by now why I hate intrinsux like the pest. It's more nuisance than any help.

PS: The Teclast P10 Android tablet is quite a good candidate as an aarch64 test device: All the eight cores are the same, Android 7.12 64bit is installed, and it only costs around $100.

Answer 2

Your workaround potentially makes the performance worse. Your problem is written as if you want a scalar result from your single vector of uint8_t's. There's nothing wrong with the vaddv_u8 instruction returning a scalar value. On ARMv8, the "NEON unit" is now fully integrated and doesn't have a large penalty for moving data between NEON and ARM registers. Just use the C intrinsic to count leading zeros of the result and you'll have what you need:

int paddClz(const uint8_t* x)
{
    uint8x8_t x8 = vld1_u8(x);
    uint8_t sum = vaddv_u8(x8);
    return __builtin_clz(sum) - 24;
}

The intrisic will get compiled into the single ARM instruction (CLZ).

If you're working with a larger data set, then write the C code to properly reflect that fact.

Answer 3

It seems that I can do this in clang:

int paddClz(const uint8_t* x)
{
    uint8x8_t x8 = vld1_u8(x);
    uint8_t sum = vaddv_u8(x8);
    uint8x8_t r;
    r = vset_lane_u8(sum, r, 0);
    r = vclz_u8(r);
    return vget_lane_u8(r, 0);
}

This produces exactly what I want:

addv b0, v0.8b
clz v0.8b, v0.8b

However, gcc produces some mess from that code. The other issue is that it uses uninitialized r and depending on how you setup your build it might not be acceptable. More over, it doesn't seem to work in more complex scenarios. Is there a better/proper way to do it?