Extract set bytes position from SIMD vector

I run a bench of computations using SIMD intructions. These instructions return a vector of 16 bytes as result, named `compare`, with each byte being `0x00` or `0xff` :

``````             0    1    2    3    4    5    6    7       15   16
compare : 0x00 0x00 0x00 0x00 0xff 0x00 0x00 0x00 ... 0xff 0x00
``````

Bytes set to `0xff` mean I need to run the function `do_operation(i)` with i being the position of the byte.

For instance, the above `compare` vector mean, I need to run this sequence of operations :

``````do_operation(4);
do_operation(15);
``````

Here is the fastest solution I came up with until now :

``````for(...) {
//
// SIMD computations
//
__m128i compare = ... // Result of SIMD computations

// Extract high and low quadwords for compare vector
std::uint64_t cmp_low = (_mm_cvtsi128_si64(compare));
std::uint64_t cmp_high = (_mm_extract_epi64(compare, 1));

if (cmp_low) {
const std::uint64_t low_possible_positions = 0x0706050403020100;
const std::uint64_t match_positions = _pext_u64(
low_possible_positions, cmp_low);
const int match_count = _popcnt64(cmp_low) / 8;
const std::uint8_t* match_pos_array =
reinterpret_cast<const std::uint8_t*>(&match_positions);

for (int i = 0; i < match_count; ++i) {
do_operation(i);
}
}

if (cmp_high) {

const std::uint64_t high_possible_positions = 0x0f0e0d0c0b0a0908;
const std::uint64_t match_positions = _pext_u64(
high_possible_positions, cmp_high);
const int match_count = _popcnt64(cmp_high) / 8;
const std::uint8_t* match_pos_array =
reinterpret_cast<const std::uint8_t*>(&match_positions);

for(int i = 0; i < match_count; ++i) {
do_operation(i);
}
}
}
``````

I start with extracting the first and second 64 bits integers of the 128 bits vector (`cmp_low` and `cmp_high`). Then I use `popcount` to compute the number of bytes set to `0xff` (number of bits set to 1 divided by 8). Finally, I use `pext` to get positions, without zeros, like this :

``````0x0706050403020100
0x000000ff00ff0000
|
PEXT
|
0x0000000000000402
``````

I would like to find a faster solution to extract the positions of the bytes set to `0xff` in the `compare` vector. More precisely, the are very often only 0, 1 or 2 bytes set to `0xff` in the `compare` vector and I would like to use this information to avoid some branches.

• I use GCC 4.9.1 for now but I'm okay with other versions of GCC or Clang. – Xion345 Feb 14 '15 at 10:05
• Why not have `do_operation` use SIMD? – Z boson Feb 16 '15 at 8:58

Here's a quick outline of how you could reduce the number of tests:

• First use a function to project all the lsb or msb of each byte of your 128bit integer into a 16bit value (for instance, there's a SSE2 assembly instruction for that on X86 cpus: `pmovmskb`, which is supported on Intel and MS compilers with the `_mm_movemask_pi8` intrinsic, and gcc has also an intrinsic: `__builtin_ia32_ppmovmskb128`, );

• Then split that value in 4 nibbles;

• define functions to handle each possible values of a nibble (from 0 to 15) and put these in an array;

• Finally call the function indexed by each nibble (with extra parameters to indicate which nibble in the 16bits it is).

• It's a detail but GCC also has the _mm_movemask_pi8 intrinsic. I think I cannot afford a function call (do_operation is inlined), but I'm going to try a variant of this solution with a jump table/switch case statement. – Xion345 Feb 14 '15 at 10:07
• I came back to edit my post to include the idea of a switch instead of a function table, and I see your comment :) – didierc Feb 15 '15 at 10:44
• You can loop over the set bits. Find its position with `__builtin_ctz`, and clear it with `x &= (x-1)` (blsr), repeat until `x == 0`. Oh, wim already posted that as an answer :P – Peter Cordes Nov 21 '19 at 9:30

Since in your case very often only 0, 1 or 2 bytes are set to 0xff in the `compare` vector, a short while-loop on the bitmask might be more efficient than a solution based on the `pext` instruction. See also my answer on a similar question.

``````/*
gcc -O3 -Wall -m64 -mavx2 -march=broadwell esbsimd.c
*/

#include <stdio.h>
#include <immintrin.h>

int do_operation(int i){           /* some arbitrary do_operation() */
printf("i = %d\n",i);
return 0;
}

int main(){

__m128i compare = _mm_set_epi8(0xFF,0,0,0,  0,0,0,0, 0,0,0,0xFF, 0,0,0,0);   /* Take some randon value for compare */

while (k){
int i=_tzcnt_u32(k);                                /* Count the number of trailing zero bits in k.  BMI1 instruction set, Haswell or newer. */
do_operation(i);
k=_blsr_u32(k);                                     /* Clear the lowest set bit in k.                                                        */
}
return 0;
}

/*
Output:

i = 4
i = 15

*/
``````
• You can write this as `__builtin_ctz` and `k &= k-1` so it can compile to BSF and plain instructions (only requiring SSE2), but it can still optimize to tzcnt and/or BLSR depending on target options. Compilers do know about `blsr` as a peephole for that expression. – Peter Cordes Nov 21 '19 at 9:32