# How to optimise this 8-bit positional popcount using assembly?

This post is related to Golang assembly implement of _mm_add_epi32 , where it adds paired elements in two [8]int32 list, and returns the updated first one.

According to pprof profile, I found passing [8]int32 is expensive, so I think passing pointer of the list is much cheaper and the bech result verified this. Here's the go version:

(*x)[0] += (*y)[0]
(*x)[1] += (*y)[1]
(*x)[2] += (*y)[2]
(*x)[3] += (*y)[3]
(*x)[4] += (*y)[4]
(*x)[5] += (*y)[5]
(*x)[6] += (*y)[6]
(*x)[7] += (*y)[7]
}

This function is called in two levels of loop.

The algorithm computes a position population count over an array of bytes.

Thanks advice from @fuz , I know that writing whole algorithm in assembly is the best choice and makes sense, but it's beyond my ability since I never learn programming in assembly.

However, it should be easy to optimize the inner loop with assembly:

counts := make([][8]int32, numRowBytes)

for i, b = range byteSlice {
if b == 0 {                  // more than half of elements in byteSlice is 0.
continue
}
expand = _expand_byte[b]
}

// expands a byte into its bits
var _expand_byte = [256]*[8]int32{
&[8]int32{0, 0, 0, 0, 0, 0, 0, 0},
&[8]int32{0, 0, 0, 0, 0, 0, 0, 1},
&[8]int32{0, 0, 0, 0, 0, 0, 1, 0},
&[8]int32{0, 0, 0, 0, 0, 0, 1, 1},
&[8]int32{0, 0, 0, 0, 0, 1, 0, 0},
...
}

Can you help to write an assembly version of __mm_add_epi32_inplace_purego (this is enough for me), or even the whole loop? Thank you in advance.

• Also, what instruction set extensions are you allowed to use? Is it just SSE/SSE2? Your previous post hinted that you may be able to use everything up to AVX2. Is that correct? There are some ways to make the code a lot more efficient if certain instructions can be used.
– fuz
Aug 4, 2020 at 14:10
• @PeterCordes Should be possible to translate that code to Go-style assembly. It is possible to call C functions, but the overhead is non-trivial as it involves a stack switch and reconfiguration of the runtime.
– fuz
Aug 4, 2020 at 14:30
• @fuz: I'd start by compiling one and translating the compiler-generated asm. But yeah, positional popcount is non-trivial if you want to do it efficiently. A naive 256x __m256i lookup table would be one option, or just simple inverse movemask feeding vpaddd should be simple enough to code easily but still much faster than scalar. Aug 4, 2020 at 14:50
• @PeterCordes Does make a significant difference! I get 11.3 GB/s with the counters kept in registers. The gist has been updated.
– fuz
Aug 4, 2020 at 16:00
• @fuz: I tried it on my i7-6700k Skylake (3.9GHz, DDR4-2666), gcc10 -O2 on Arch Linux. I changed your harness to /dev/zero with len=1024ULL * 1024*1024; and got addreg 8.61424e+09 B/sec, addmem 7.20125e+09 B/s. (I left the warm-up runs, but commented 2 of the 3 benchmark calls, so I could perf stat it. Both ran almost exactly 3 IPC, but the addreg version ran longer, presumably because it finished in under 1 second in benchmark().) Did you try perf stat to check for front-end vs. back-end bottlenecks? Aug 4, 2020 at 16:21

The operation you want to perform is called a positional population count on bytes. This is a well-known operation used in machine learning and some research has been done on fast algorithms to solve this problem.

Unfortunately, the implementation of these algorithms is fairly involved. For this reason, I have developed a custom algorithm that is much simpler to implement but only yields roughly half the performance of the other other method. However, at measured 10 GB/s, it should still be a decent improvement over what you had previously.

The idea of this algorithm is to gather corresponding bits from groups of 32 bytes using vpmovmskb and then to take a scalar population count which is then added to the corresponding counter. This allows the dependency chains to be short and a consistent IPC of 3 to be reached.

Note that compared to your algorithm, my code flips the order of bits around. You can change this by editing which counts array elements the assembly code accesses if you want. However, in the interest of future readers, I'd like to leave this code with the more common convention where the least significant bit is considered bit 0.

# Source code

The complete source code can be found on github. The author has meanwhile developed this algorithm idea into a portable library that can be used like this:

import "github.com/clausecker/pospop"

var counts [8]int
pospop.Count8(counts, buf)  // add positional popcounts for buf to counts

The algorithm is provided in two variants and has been tested on a machine with a processor identified as “Intel(R) Xeon(R) W-2133 CPU @ 3.60GHz.”

## Positional Population Count 32 Bytes at a Time.

The counters are kept in general purpose registers for best performance. Memory is prefetched well in advance for better streaming behaviour. The scalar tail is processed using a very simple SHRL/ADCL combination. A performance of up to 11 GB/s is achieved.

#include "textflag.h"

// func PospopcntReg(counts *[8]int32, buf []byte)
TEXT ·PospopcntReg(SB),NOSPLIT,\$0-32
MOVQ counts+0(FP), DI
MOVQ buf_base+8(FP), SI     // SI = &buf[0]
MOVQ buf_len+16(FP), CX     // CX = len(buf)

// load counts into register R8--R15
MOVL 4*0(DI), R8
MOVL 4*1(DI), R9
MOVL 4*2(DI), R10
MOVL 4*3(DI), R11
MOVL 4*4(DI), R12
MOVL 4*5(DI), R13
MOVL 4*6(DI), R14
MOVL 4*7(DI), R15

SUBQ \$32, CX            // pre-subtract 32 bit from CX
JL scalar

vector: VMOVDQU (SI), Y0        // load 32 bytes from buf
PREFETCHT0 384(SI)      // prefetch some data

VPMOVMSKB Y0, AX        // move MSB of Y0 bytes to AX
POPCNTL AX, AX          // count population of AX
VPADDD Y0, Y0, Y0       // shift Y0 left by one place

VPMOVMSKB Y0, AX        // move MSB of Y0 bytes to AX
POPCNTL AX, AX          // count population of AX
VPADDD Y0, Y0, Y0       // shift Y0 left by one place

VPMOVMSKB Y0, AX        // move MSB of Y0 bytes to AX
POPCNTL AX, AX          // count population of AX
VPADDD Y0, Y0, Y0       // shift Y0 left by one place

VPMOVMSKB Y0, AX        // move MSB of Y0 bytes to AX
POPCNTL AX, AX          // count population of AX
VPADDD Y0, Y0, Y0       // shift Y0 left by one place

VPMOVMSKB Y0, AX        // move MSB of Y0 bytes to AX
POPCNTL AX, AX          // count population of AX
VPADDD Y0, Y0, Y0       // shift Y0 left by one place

VPMOVMSKB Y0, AX        // move MSB of Y0 bytes to AX
POPCNTL AX, AX          // count population of AX
VPADDD Y0, Y0, Y0       // shift Y0 left by one place

VPMOVMSKB Y0, AX        // move MSB of Y0 bytes to AX
POPCNTL AX, AX          // count population of AX
VPADDD Y0, Y0, Y0       // shift Y0 left by one place

VPMOVMSKB Y0, AX        // move MSB of Y0 bytes to AX
POPCNTL AX, AX          // count population of AX

SUBQ \$32, CX
JGE vector          // repeat as long as bytes are left

scalar: ADDQ \$32, CX            // undo last subtraction
JE done             // if CX=0, there's nothing left

loop:   MOVBLZX (SI), AX        // load a byte from buf
INCQ SI             // advance past it

SHRL \$1, AX         // CF=LSB, shift byte to the right

SHRL \$1, AX

SHRL \$1, AX

SHRL \$1, AX

SHRL \$1, AX

SHRL \$1, AX

SHRL \$1, AX

SHRL \$1, AX

DECQ CX             // mark this byte as done
JNE loop            // and proceed if any bytes are left

// write R8--R15 back to counts
done:   MOVL R8, 4*0(DI)
MOVL R9, 4*1(DI)
MOVL R10, 4*2(DI)
MOVL R11, 4*3(DI)
MOVL R12, 4*4(DI)
MOVL R13, 4*5(DI)
MOVL R14, 4*6(DI)
MOVL R15, 4*7(DI)

VZEROUPPER          // restore SSE-compatibility
RET

# Positional Population Count 96 Bytes at a Time with CSA

This variant performs all of the optimisations above but reduces 96 bytes to 64 using a single CSA step beforehand. As expected, this improves the performance by roughly 30% and achieves up to 16 GB/s.

#include "textflag.h"

// func PospopcntRegCSA(counts *[8]int32, buf []byte)
TEXT ·PospopcntRegCSA(SB),NOSPLIT,\$0-32
MOVQ counts+0(FP), DI
MOVQ buf_base+8(FP), SI     // SI = &buf[0]
MOVQ buf_len+16(FP), CX     // CX = len(buf)

// load counts into register R8--R15
MOVL 4*0(DI), R8
MOVL 4*1(DI), R9
MOVL 4*2(DI), R10
MOVL 4*3(DI), R11
MOVL 4*4(DI), R12
MOVL 4*5(DI), R13
MOVL 4*6(DI), R14
MOVL 4*7(DI), R15

SUBQ \$96, CX            // pre-subtract 32 bit from CX
JL scalar

vector: VMOVDQU (SI), Y0        // load 96 bytes from buf into Y0--Y2
VMOVDQU 32(SI), Y1
VMOVDQU 64(SI), Y2
PREFETCHT0 320(SI)
PREFETCHT0 384(SI)

VPXOR Y0, Y1, Y3        // first adder: sum
VPAND Y0, Y1, Y0        // first adder: carry out
VPAND Y2, Y3, Y1        // second adder: carry out
VPXOR Y2, Y3, Y2        // second adder: sum (full sum)
VPOR Y0, Y1, Y0         // full adder: carry out

VPMOVMSKB Y0, AX        // MSB of carry out bytes
VPMOVMSKB Y2, DX        // MSB of sum bytes
VPADDB Y0, Y0, Y0       // shift carry out bytes left
VPADDB Y2, Y2, Y2       // shift sum bytes left
POPCNTL AX, AX          // carry bytes population count
POPCNTL DX, DX          // sum bytes population count
LEAL (DX)(AX*2), AX     // sum popcount plus 2x carry popcount

VPMOVMSKB Y0, AX        // MSB of carry out bytes
VPMOVMSKB Y2, DX        // MSB of sum bytes
VPADDB Y0, Y0, Y0       // shift carry out bytes left
VPADDB Y2, Y2, Y2       // shift sum bytes left
POPCNTL AX, AX          // carry bytes population count
POPCNTL DX, DX          // sum bytes population count
LEAL (DX)(AX*2), AX     // sum popcount plus 2x carry popcount

VPMOVMSKB Y0, AX        // MSB of carry out bytes
VPMOVMSKB Y2, DX        // MSB of sum bytes
VPADDB Y0, Y0, Y0       // shift carry out bytes left
VPADDB Y2, Y2, Y2       // shift sum bytes left
POPCNTL AX, AX          // carry bytes population count
POPCNTL DX, DX          // sum bytes population count
LEAL (DX)(AX*2), AX     // sum popcount plus 2x carry popcount

VPMOVMSKB Y0, AX        // MSB of carry out bytes
VPMOVMSKB Y2, DX        // MSB of sum bytes
VPADDB Y0, Y0, Y0       // shift carry out bytes left
VPADDB Y2, Y2, Y2       // shift sum bytes left
POPCNTL AX, AX          // carry bytes population count
POPCNTL DX, DX          // sum bytes population count
LEAL (DX)(AX*2), AX     // sum popcount plus 2x carry popcount

VPMOVMSKB Y0, AX        // MSB of carry out bytes
VPMOVMSKB Y2, DX        // MSB of sum bytes
VPADDB Y0, Y0, Y0       // shift carry out bytes left
VPADDB Y2, Y2, Y2       // shift sum bytes left
POPCNTL AX, AX          // carry bytes population count
POPCNTL DX, DX          // sum bytes population count
LEAL (DX)(AX*2), AX     // sum popcount plus 2x carry popcount

VPMOVMSKB Y0, AX        // MSB of carry out bytes
VPMOVMSKB Y2, DX        // MSB of sum bytes
VPADDB Y0, Y0, Y0       // shift carry out bytes left
VPADDB Y2, Y2, Y2       // shift sum bytes left
POPCNTL AX, AX          // carry bytes population count
POPCNTL DX, DX          // sum bytes population count
LEAL (DX)(AX*2), AX     // sum popcount plus 2x carry popcount

VPMOVMSKB Y0, AX        // MSB of carry out bytes
VPMOVMSKB Y2, DX        // MSB of sum bytes
VPADDB Y0, Y0, Y0       // shift carry out bytes left
VPADDB Y2, Y2, Y2       // shift sum bytes left
POPCNTL AX, AX          // carry bytes population count
POPCNTL DX, DX          // sum bytes population count
LEAL (DX)(AX*2), AX     // sum popcount plus 2x carry popcount

VPMOVMSKB Y0, AX        // MSB of carry out bytes
VPMOVMSKB Y2, DX        // MSB of sum bytes
POPCNTL AX, AX          // carry bytes population count
POPCNTL DX, DX          // sum bytes population count
LEAL (DX)(AX*2), AX     // sum popcount plus 2x carry popcount

SUBQ \$96, CX
JGE vector          // repeat as long as bytes are left

scalar: ADDQ \$96, CX            // undo last subtraction
JE done             // if CX=0, there's nothing left

loop:   MOVBLZX (SI), AX        // load a byte from buf
INCQ SI             // advance past it

SHRL \$1, AX         // is bit 0 set?

SHRL \$1, AX         // is bit 0 set?

SHRL \$1, AX         // is bit 0 set?

SHRL \$1, AX         // is bit 0 set?

SHRL \$1, AX         // is bit 0 set?

SHRL \$1, AX         // is bit 0 set?

SHRL \$1, AX         // is bit 0 set?

SHRL \$1, AX         // is bit 0 set?

DECQ CX             // mark this byte as done
JNE loop            // and proceed if any bytes are left

// write R8--R15 back to counts
done:   MOVL R8, 4*0(DI)
MOVL R9, 4*1(DI)
MOVL R10, 4*2(DI)
MOVL R11, 4*3(DI)
MOVL R12, 4*4(DI)
MOVL R13, 4*5(DI)
MOVL R14, 4*6(DI)
MOVL R15, 4*7(DI)

VZEROUPPER          // restore SSE-compatibility
RET

# Benchmarks

Here are benchmarks for the two algorithms and a naïve reference implementation in pure Go. Full benchmarks can be found in the github repository.

BenchmarkReference/10-12    12448764            80.9 ns/op   123.67 MB/s
BenchmarkReference/32-12     4357808           258 ns/op     124.25 MB/s
BenchmarkReference/1000-12            151173          7889 ns/op     126.76 MB/s
BenchmarkReference/2000-12             68959         15774 ns/op     126.79 MB/s
BenchmarkReference/4000-12             36481         31619 ns/op     126.51 MB/s
BenchmarkReference/10000-12            14804         78917 ns/op     126.72 MB/s
BenchmarkReference/100000-12            1540        789450 ns/op     126.67 MB/s
BenchmarkReference/10000000-12            14      77782267 ns/op     128.56 MB/s
BenchmarkReference/1000000000-12           1    7781360044 ns/op     128.51 MB/s
BenchmarkReg/10-12                  49255107            24.5 ns/op   407.42 MB/s
BenchmarkReg/32-12                  186935192            6.40 ns/op 4998.53 MB/s
BenchmarkReg/1000-12                 8778610           115 ns/op    8677.33 MB/s
BenchmarkReg/2000-12                 5358495           208 ns/op    9635.30 MB/s
BenchmarkReg/4000-12                 3385945           357 ns/op    11200.23 MB/s
BenchmarkReg/10000-12                1298670           901 ns/op    11099.24 MB/s
BenchmarkReg/100000-12                115629          8662 ns/op    11544.98 MB/s
BenchmarkReg/10000000-12                1270        916817 ns/op    10907.30 MB/s
BenchmarkReg/1000000000-12                12      93609392 ns/op    10682.69 MB/s
BenchmarkRegCSA/10-12               48337226            23.9 ns/op   417.92 MB/s
BenchmarkRegCSA/32-12               12843939            80.2 ns/op   398.86 MB/s
BenchmarkRegCSA/1000-12              7175629           150 ns/op    6655.70 MB/s
BenchmarkRegCSA/2000-12              3988408           295 ns/op    6776.20 MB/s
BenchmarkRegCSA/4000-12              3016693           382 ns/op    10467.41 MB/s
BenchmarkRegCSA/10000-12             1810195           642 ns/op    15575.65 MB/s
BenchmarkRegCSA/100000-12             191974          6229 ns/op    16053.40 MB/s
BenchmarkRegCSA/10000000-12             1622        698856 ns/op    14309.10 MB/s
BenchmarkRegCSA/1000000000-12             16      68540642 ns/op    14589.88 MB/s
• you're amazing, the implements are awesome, lightning fast. But my case is pospopcnt on column-wise bytes array in a byte matrix, so I have to prepare []byte for a column before counting, where however popping single byte from rows is very slow with NOPL instruction costing too much time. Aug 5, 2020 at 0:32
• This turns another problem: how to fast transpose byte matrix [][]byte in Golang assembly Aug 5, 2020 at 1:32
• After searching I found no assembly implement and just used pure go and carefully tuned the matrix row size which effect the performance too (decreased when > 512 or < 32). After last your PospopcntReg brings a 2X speedup, thank you @fuz . Aug 5, 2020 at 2:29
• Well, transpose is a whol new can of worms. It is possible to do that using scater/gather operations, but it's not going to be fast. Consider changing the layout of yor data structure if possible.
– fuz
Aug 5, 2020 at 6:58
• I created another post. stackoverflow.com/questions/63257822/… . And I've used fixed size (64) of rows and 64×n columns in original matrix which is cache-friendly for transposing to [][64]byte and later being passed to pospopcnt. This improves the performance a little. Aug 5, 2020 at 8:08