# Transpose an 8x8 float using AVX/AVX2

Transposing a 8x8 matrix can be achieved by making four 4x4 matrices, and transposing each of them. This is not want I'm going for.

In another question, one answer gave a solution that would only require 24 instructions for an 8x8 matrix. However, this does not apply to floats.

Since the AVX2 contains registers of 256 bits, each register would fit eight 32 bits integers (floats). But the question is:

How to transpose an 8x8 float matrix, using AVX/AVX2, with the smallest instructions possible?

• Hei David. Jeg tror jeg ga deg det eksakte svaret til spørsmålet ditt. Hva mer vil du ha? – Z boson Sep 3 '14 at 20:50
• @Zboson: I've been really busy the past days, but just marked your answer as accepted. I greatly appreciate it! – DavidS Sep 3 '14 at 21:36

I already answered this question Fast memory transpose with SSE, AVX, and OpenMP.

Let me repeat the solution for transposing an 8x8 float matrix with AVX. Let me know if this is any faster than using 4x4 blocks and `_MM_TRANSPOSE4_PS`. I used it for a kernel in a larger matrix transpose which was memory bound so that was probably not a fair test.

``````inline void transpose8_ps(__m256 &row0, __m256 &row1, __m256 &row2, __m256 &row3, __m256 &row4, __m256 &row5, __m256 &row6, __m256 &row7) {
__m256 __t0, __t1, __t2, __t3, __t4, __t5, __t6, __t7;
__m256 __tt0, __tt1, __tt2, __tt3, __tt4, __tt5, __tt6, __tt7;
__t0 = _mm256_unpacklo_ps(row0, row1);
__t1 = _mm256_unpackhi_ps(row0, row1);
__t2 = _mm256_unpacklo_ps(row2, row3);
__t3 = _mm256_unpackhi_ps(row2, row3);
__t4 = _mm256_unpacklo_ps(row4, row5);
__t5 = _mm256_unpackhi_ps(row4, row5);
__t6 = _mm256_unpacklo_ps(row6, row7);
__t7 = _mm256_unpackhi_ps(row6, row7);
__tt0 = _mm256_shuffle_ps(__t0,__t2,_MM_SHUFFLE(1,0,1,0));
__tt1 = _mm256_shuffle_ps(__t0,__t2,_MM_SHUFFLE(3,2,3,2));
__tt2 = _mm256_shuffle_ps(__t1,__t3,_MM_SHUFFLE(1,0,1,0));
__tt3 = _mm256_shuffle_ps(__t1,__t3,_MM_SHUFFLE(3,2,3,2));
__tt4 = _mm256_shuffle_ps(__t4,__t6,_MM_SHUFFLE(1,0,1,0));
__tt5 = _mm256_shuffle_ps(__t4,__t6,_MM_SHUFFLE(3,2,3,2));
__tt6 = _mm256_shuffle_ps(__t5,__t7,_MM_SHUFFLE(1,0,1,0));
__tt7 = _mm256_shuffle_ps(__t5,__t7,_MM_SHUFFLE(3,2,3,2));
row0 = _mm256_permute2f128_ps(__tt0, __tt4, 0x20);
row1 = _mm256_permute2f128_ps(__tt1, __tt5, 0x20);
row2 = _mm256_permute2f128_ps(__tt2, __tt6, 0x20);
row3 = _mm256_permute2f128_ps(__tt3, __tt7, 0x20);
row4 = _mm256_permute2f128_ps(__tt0, __tt4, 0x31);
row5 = _mm256_permute2f128_ps(__tt1, __tt5, 0x31);
row6 = _mm256_permute2f128_ps(__tt2, __tt6, 0x31);
row7 = _mm256_permute2f128_ps(__tt3, __tt7, 0x31);
}
``````

Based on this comment I learned that there are more efficient methods which to do the 8x8 transpose. See Example 11-19 and and 11-20 in the Intel optimization manual under section "11.11 Handling Port 5 Pressure". Example 11-19 uses the same number of instructions but reduces the pressure on port5 by using blends which go to port0 as well. I may implement this with intrinsics at some point but I don't have a need for this at this point.

I looked more carefully into Example 11-19 and 11-20 in the Intel Manuals I mentioned above. It turns out that example 11-19 uses 4 more shuffle operations than necessary. It has 8 unpack, 12 shuffles, and 8 128-bit permutes. My method uses 4 fewer shuffles. They replace 8 of the shuffles with blends. So 4 shuffles and 8 blends. I doubt that's better than my method with only eight shuffles.

Example 11-20 is, however, an improvement if you need to load the matrix from memory. This uses 8 unpacks, 8 inserts, 8 shuffles, 8 128-bit loads, and 8 stores. The 128-bit loads reduce the port pressure. I went ahead and implemented this using intrinsics.

``````//Example 11-20. 8x8 Matrix Transpose Using VINSERTF128 loads
void tran(float* mat, float* matT) {
__m256  r0, r1, r2, r3, r4, r5, r6, r7;
__m256  t0, t1, t2, t3, t4, t5, t6, t7;

t0 = _mm256_unpacklo_ps(r0,r1);
t1 = _mm256_unpackhi_ps(r0,r1);
t2 = _mm256_unpacklo_ps(r2,r3);
t3 = _mm256_unpackhi_ps(r2,r3);
t4 = _mm256_unpacklo_ps(r4,r5);
t5 = _mm256_unpackhi_ps(r4,r5);
t6 = _mm256_unpacklo_ps(r6,r7);
t7 = _mm256_unpackhi_ps(r6,r7);

r0 = _mm256_shuffle_ps(t0,t2, 0x44);
r1 = _mm256_shuffle_ps(t0,t2, 0xEE);
r2 = _mm256_shuffle_ps(t1,t3, 0x44);
r3 = _mm256_shuffle_ps(t1,t3, 0xEE);
r4 = _mm256_shuffle_ps(t4,t6, 0x44);
r5 = _mm256_shuffle_ps(t4,t6, 0xEE);
r6 = _mm256_shuffle_ps(t5,t7, 0x44);
r7 = _mm256_shuffle_ps(t5,t7, 0xEE);

_mm256_store_ps(&matT[0*8], r0);
_mm256_store_ps(&matT[1*8], r1);
_mm256_store_ps(&matT[2*8], r2);
_mm256_store_ps(&matT[3*8], r3);
_mm256_store_ps(&matT[4*8], r4);
_mm256_store_ps(&matT[5*8], r5);
_mm256_store_ps(&matT[6*8], r6);
_mm256_store_ps(&matT[7*8], r7);
}
``````

So I looked into example 11-19 again. The basic idea as far as I can tell is that two shuffle instructions (shufps) can be replaced by one shuffle and two blends. For example

``````r0 = _mm256_shuffle_ps(t0,t2, 0x44);
r1 = _mm256_shuffle_ps(t0,t2, 0xEE);
``````

can be replace with

``````v = _mm256_shuffle_ps(t0,t2, 0x4E);
r0 = _mm256_blend_ps(t0, v, 0xCC);
r1 = _mm256_blend_ps(t2, v, 0x33);
``````

This explains why my original code used 8 shuffles and Example 11-19 uses 4 shuffles and eight blends.

The blends are good for throughput because shuffles only go to one port (creating a bottleneck on the shuffle port), but blends can run on multiple ports and thus don't compete. But what is better: 8 shuffles or 4 shuffles and 8 blends?

This has to be tested, and can depend on surrounding code. If you mostly bottleneck on total uop throughput with a lot of other uops in the loop that don't need port 5, you might go for the pure shuffle version. Ideally you should do some computation on the transposed data before storing it, while it's already in registers. See https://agner.org/optimize/ and other performance links in the x86 tag wiki.

I don't, however, see a way to replace the unpack instructions with blends.

Here is full code which combines Example 11-19 converting 2 shuffles to 1 shuffle and two blends and Example 11-20 which uses `vinsertf128` loads (which on Intel Haswell/Skylake CPUs are 2 uops: one ALU for any port, one memory. They unfortunately don't micro-fuse. `vinsertf128` with all register operands is 1 uop for the shuffle port on Intel, so this is good because the compiler folds the load into a memory operand for `vinsertf128`.) This has the advantage of only needing the source data 16-byte aligned for maximum performance, avoiding any cache-line splits.

``````#include <stdio.h>
#include <x86intrin.h>
#include <omp.h>

/*
void tran(float* mat, float* matT) {
__m256  r0, r1, r2, r3, r4, r5, r6, r7;
__m256  t0, t1, t2, t3, t4, t5, t6, t7;

t0 = _mm256_unpacklo_ps(r0, r1);
t1 = _mm256_unpackhi_ps(r0, r1);
t2 = _mm256_unpacklo_ps(r2, r3);
t3 = _mm256_unpackhi_ps(r2, r3);
t4 = _mm256_unpacklo_ps(r4, r5);
t5 = _mm256_unpackhi_ps(r4, r5);
t6 = _mm256_unpacklo_ps(r6, r7);
t7 = _mm256_unpackhi_ps(r6, r7);

r0 = _mm256_shuffle_ps(t0,t2,_MM_SHUFFLE(1,0,1,0));
r1 = _mm256_shuffle_ps(t0,t2,_MM_SHUFFLE(3,2,3,2));
r2 = _mm256_shuffle_ps(t1,t3,_MM_SHUFFLE(1,0,1,0));
r3 = _mm256_shuffle_ps(t1,t3,_MM_SHUFFLE(3,2,3,2));
r4 = _mm256_shuffle_ps(t4,t6,_MM_SHUFFLE(1,0,1,0));
r5 = _mm256_shuffle_ps(t4,t6,_MM_SHUFFLE(3,2,3,2));
r6 = _mm256_shuffle_ps(t5,t7,_MM_SHUFFLE(1,0,1,0));
r7 = _mm256_shuffle_ps(t5,t7,_MM_SHUFFLE(3,2,3,2));

t0 = _mm256_permute2f128_ps(r0, r4, 0x20);
t1 = _mm256_permute2f128_ps(r1, r5, 0x20);
t2 = _mm256_permute2f128_ps(r2, r6, 0x20);
t3 = _mm256_permute2f128_ps(r3, r7, 0x20);
t4 = _mm256_permute2f128_ps(r0, r4, 0x31);
t5 = _mm256_permute2f128_ps(r1, r5, 0x31);
t6 = _mm256_permute2f128_ps(r2, r6, 0x31);
t7 = _mm256_permute2f128_ps(r3, r7, 0x31);

_mm256_store_ps(&matT[0*8], t0);
_mm256_store_ps(&matT[1*8], t1);
_mm256_store_ps(&matT[2*8], t2);
_mm256_store_ps(&matT[3*8], t3);
_mm256_store_ps(&matT[4*8], t4);
_mm256_store_ps(&matT[5*8], t5);
_mm256_store_ps(&matT[6*8], t6);
_mm256_store_ps(&matT[7*8], t7);
}
*/

void tran(float* mat, float* matT) {
__m256  r0, r1, r2, r3, r4, r5, r6, r7;
__m256  t0, t1, t2, t3, t4, t5, t6, t7;

t0 = _mm256_unpacklo_ps(r0,r1);
t1 = _mm256_unpackhi_ps(r0,r1);
t2 = _mm256_unpacklo_ps(r2,r3);
t3 = _mm256_unpackhi_ps(r2,r3);
t4 = _mm256_unpacklo_ps(r4,r5);
t5 = _mm256_unpackhi_ps(r4,r5);
t6 = _mm256_unpacklo_ps(r6,r7);
t7 = _mm256_unpackhi_ps(r6,r7);

__m256 v;

//r0 = _mm256_shuffle_ps(t0,t2, 0x44);
//r1 = _mm256_shuffle_ps(t0,t2, 0xEE);
v = _mm256_shuffle_ps(t0,t2, 0x4E);
r0 = _mm256_blend_ps(t0, v, 0xCC);
r1 = _mm256_blend_ps(t2, v, 0x33);

//r2 = _mm256_shuffle_ps(t1,t3, 0x44);
//r3 = _mm256_shuffle_ps(t1,t3, 0xEE);
v = _mm256_shuffle_ps(t1,t3, 0x4E);
r2 = _mm256_blend_ps(t1, v, 0xCC);
r3 = _mm256_blend_ps(t3, v, 0x33);

//r4 = _mm256_shuffle_ps(t4,t6, 0x44);
//r5 = _mm256_shuffle_ps(t4,t6, 0xEE);
v = _mm256_shuffle_ps(t4,t6, 0x4E);
r4 = _mm256_blend_ps(t4, v, 0xCC);
r5 = _mm256_blend_ps(t6, v, 0x33);

//r6 = _mm256_shuffle_ps(t5,t7, 0x44);
//r7 = _mm256_shuffle_ps(t5,t7, 0xEE);
v = _mm256_shuffle_ps(t5,t7, 0x4E);
r6 = _mm256_blend_ps(t5, v, 0xCC);
r7 = _mm256_blend_ps(t7, v, 0x33);

_mm256_store_ps(&matT[0*8], r0);
_mm256_store_ps(&matT[1*8], r1);
_mm256_store_ps(&matT[2*8], r2);
_mm256_store_ps(&matT[3*8], r3);
_mm256_store_ps(&matT[4*8], r4);
_mm256_store_ps(&matT[5*8], r5);
_mm256_store_ps(&matT[6*8], r6);
_mm256_store_ps(&matT[7*8], r7);
}

int verify(float *mat) {
int i,j;
int error = 0;
for(i=0; i<8; i++) {
for(j=0; j<8; j++) {
if(mat[j*8+i] != 1.0f*i*8+j) error++;
}
}
return error;
}

void print_mat(float *mat) {
int i,j;
for(i=0; i<8; i++) {
for(j=0; j<8; j++) printf("%2.0f ", mat[i*8+j]);
puts("");
}
puts("");
}

int main(void) {
int i,j, rep;
float mat[64] __attribute__((aligned(64)));
float matT[64] __attribute__((aligned(64)));
double dtime;

rep = 10000000;
for(i=0; i<64; i++) mat[i] = i;
print_mat(mat);

tran(mat,matT);
//dtime = -omp_get_wtime();
//tran(mat, matT, rep);
//dtime += omp_get_wtime();
printf("errors %d\n", verify(matT));
//printf("dtime %f\n", dtime);
print_mat(matT);
}
``````
• Compile-time emulation. For testing, I have a set of headers that imitate a subset of the AVX512f intrinsics using only AVX and FMA3 so I can run it on both my Intel and AMD machines. (performance-wise, it's reasonably fast to run on a Haswell - only about 30% slower than a native AVX2 implementation) I can also compile to Knights Landing AVX512f. While I can't run it, I can at least look at the assembly to see if everything looks sane. – Mysticial Sep 2 '14 at 18:14
• Intel’s SDE also provides emulation to support development of AVX-512 software. – Stephen Canon Sep 2 '14 at 18:19
• On a CPU with one shuffle port, the second shuffle has a resource conflict so it can't run in parallel with the first shuffle anyway. On Haswell, the shuffle + 2 blends can produce both results in the second cycle, instead of one in the first cycle and one in the second. I haven't looked at it for KNL. But aren't there lots of independent shuffles to do in this transpose? KNL has enough out-of-order execution capability to exploit this ILP, and have execution catch up with the front-end before it runs out of ROB / RS resources, I'd guess. I'm not really looking at this in detail ATM :/ – Peter Cordes Dec 28 '16 at 7:19
• @PeterCordes, I just updated this answer converting 2 shuffles to 1 shuffle and 2 blends. One reason I count unpack and shuffle separately is that in some cases 2 shufps can be replace with shufps and blends but unpck/h cannot. – Z boson Dec 28 '16 at 9:47
• It is good to have different versions of the 8x8 transpose, because the performance may depend on the actual surrounding code. For example: 1. Is the input from memory or from registers after inlining `tran`? 2. Is `tran` used as a building block inside a large nxn transpose procedure, or is it used inbetween heavy floating point code? Note that vinsertf128 only avoids port 5 if the inserted data is a memory operand. – wim Dec 28 '16 at 10:02

Here's an AVX2 solution which works for 8 x 8 32 bit ints. You can of course cast float vectors to int and back if you want to transpose 8 x 8 floats. It might also be possible to do an AVX-only version (i.e. not requiring AVX2) just for floats but I haven't tried that yet.

``````//
// tranpose_8_8_avx2.c
//

#include <stdio.h>

#include <immintrin.h>

#define V_ELEMS 8

static inline void _mm256_merge_epi32(const __m256i v0, const __m256i v1, __m256i *vl, __m256i *vh)
{
__m256i va = _mm256_permute4x64_epi64(v0, _MM_SHUFFLE(3, 1, 2, 0));
__m256i vb = _mm256_permute4x64_epi64(v1, _MM_SHUFFLE(3, 1, 2, 0));
*vl = _mm256_unpacklo_epi32(va, vb);
*vh = _mm256_unpackhi_epi32(va, vb);
}

static inline void _mm256_merge_epi64(const __m256i v0, const __m256i v1, __m256i *vl, __m256i *vh)
{
__m256i va = _mm256_permute4x64_epi64(v0, _MM_SHUFFLE(3, 1, 2, 0));
__m256i vb = _mm256_permute4x64_epi64(v1, _MM_SHUFFLE(3, 1, 2, 0));
*vl = _mm256_unpacklo_epi64(va, vb);
*vh = _mm256_unpackhi_epi64(va, vb);
}

static inline void _mm256_merge_si128(const __m256i v0, const __m256i v1, __m256i *vl, __m256i *vh)
{
*vl = _mm256_permute2x128_si256(v0, v1, _MM_SHUFFLE(0, 2, 0, 0));
*vh = _mm256_permute2x128_si256(v0, v1, _MM_SHUFFLE(0, 3, 0, 1));
}

//
// Transpose_8_8
//
// in place transpose of 8 x 8 int array
//

static void Transpose_8_8(
__m256i *v0,
__m256i *v1,
__m256i *v2,
__m256i *v3,
__m256i *v4,
__m256i *v5,
__m256i *v6,
__m256i *v7)
{
__m256i w0, w1, w2, w3, w4, w5, w6, w7;
__m256i x0, x1, x2, x3, x4, x5, x6, x7;

_mm256_merge_epi32(*v0, *v1, &w0, &w1);
_mm256_merge_epi32(*v2, *v3, &w2, &w3);
_mm256_merge_epi32(*v4, *v5, &w4, &w5);
_mm256_merge_epi32(*v6, *v7, &w6, &w7);

_mm256_merge_epi64(w0, w2, &x0, &x1);
_mm256_merge_epi64(w1, w3, &x2, &x3);
_mm256_merge_epi64(w4, w6, &x4, &x5);
_mm256_merge_epi64(w5, w7, &x6, &x7);

_mm256_merge_si128(x0, x4, v0, v1);
_mm256_merge_si128(x1, x5, v2, v3);
_mm256_merge_si128(x2, x6, v4, v5);
_mm256_merge_si128(x3, x7, v6, v7);
}

int main(void)
{
int32_t buff[V_ELEMS][V_ELEMS] __attribute__ ((aligned(32)));
int i, j;
int k = 0;

// init buff
for (i = 0; i < V_ELEMS; ++i)
{
for (j = 0; j < V_ELEMS; ++j)
{
buff[i][j] = k++;
}
}

// print buff
printf("\nBEFORE:\n");
for (i = 0; i < V_ELEMS; ++i)
{
for (j = 0; j < V_ELEMS; ++j)
{
printf("%4d", buff[i][j]);
}
printf("\n");
}

// transpose
Transpose_8_8((__m256i *)buff[0], (__m256i *)buff[1], (__m256i *)buff[2], (__m256i *)buff[3], (__m256i *)buff[4], (__m256i *)buff[5], (__m256i *)buff[6], (__m256i *)buff[7]);

// print buff
printf("\nAFTER:\n");
for (i = 0; i < V_ELEMS; ++i)
{
for (j = 0; j < V_ELEMS; ++j)
{
printf("%4d", buff[i][j]);
}
printf("\n");
}

// transpose
Transpose_8_8((__m256i *)buff[0], (__m256i *)buff[1], (__m256i *)buff[2], (__m256i *)buff[3], (__m256i *)buff[4], (__m256i *)buff[5], (__m256i *)buff[6], (__m256i *)buff[7]);

// print buff
printf("\nAFTER x2:\n");
for (i = 0; i < V_ELEMS; ++i)
{
for (j = 0; j < V_ELEMS; ++j)
{
printf("%4d", buff[i][j]);
}
printf("\n");
}

return 0;
}
``````

`Transpose_8_8` compiles to around 56 instructions with clang, including loads and stores - I think it should be possible to improve on this with some more effort.

Compile and test:

``````\$ gcc -Wall -mavx2 -O3 transpose_8_8_avx2.c && ./a.out

BEFORE:
0   1   2   3   4   5   6   7
8   9  10  11  12  13  14  15
16  17  18  19  20  21  22  23
24  25  26  27  28  29  30  31
32  33  34  35  36  37  38  39
40  41  42  43  44  45  46  47
48  49  50  51  52  53  54  55
56  57  58  59  60  61  62  63

AFTER:
0   8  16  24  32  40  48  56
1   9  17  25  33  41  49  57
2  10  18  26  34  42  50  58
3  11  19  27  35  43  51  59
4  12  20  28  36  44  52  60
5  13  21  29  37  45  53  61
6  14  22  30  38  46  54  62
7  15  23  31  39  47  55  63

AFTER x2:
0   1   2   3   4   5   6   7
8   9  10  11  12  13  14  15
16  17  18  19  20  21  22  23
24  25  26  27  28  29  30  31
32  33  34  35  36  37  38  39
40  41  42  43  44  45  46  47
48  49  50  51  52  53  54  55
56  57  58  59  60  61  62  63

\$
``````

I decided to do a full test of 3 different routines in an apples to apples comparison.

``````  // transpose.cpp :
/*
Transpose8x8Shuff 100,000,000 times
(0.750000 seconds).
Transpose8x8Permute 100,000,000 times
(0.749000 seconds).
Transpose8x8Insert 100,000,000 times
(0.858000 seconds).
*/

#include <stdio.h>
#include <time.h>
#include <chrono>
#include <xmmintrin.h>
#include <emmintrin.h>
#include <tmmintrin.h>
#include <immintrin.h>

inline void Transpose8x8Shuff(unsigned long *in)
{
__m256 *inI = reinterpret_cast<__m256 *>(in);
__m256 rI[8];
rI[0] = _mm256_unpacklo_ps(inI[0], inI[1]);
rI[1] = _mm256_unpackhi_ps(inI[0], inI[1]);
rI[2] = _mm256_unpacklo_ps(inI[2], inI[3]);
rI[3] = _mm256_unpackhi_ps(inI[2], inI[3]);
rI[4] = _mm256_unpacklo_ps(inI[4], inI[5]);
rI[5] = _mm256_unpackhi_ps(inI[4], inI[5]);
rI[6] = _mm256_unpacklo_ps(inI[6], inI[7]);
rI[7] = _mm256_unpackhi_ps(inI[6], inI[7]);

__m256 rrF[8];
__m256 *rF = reinterpret_cast<__m256 *>(rI);
rrF[0] = _mm256_shuffle_ps(rF[0], rF[2], _MM_SHUFFLE(1,0,1,0));
rrF[1] = _mm256_shuffle_ps(rF[0], rF[2], _MM_SHUFFLE(3,2,3,2));
rrF[2] = _mm256_shuffle_ps(rF[1], rF[3], _MM_SHUFFLE(1,0,1,0));
rrF[3] = _mm256_shuffle_ps(rF[1], rF[3], _MM_SHUFFLE(3,2,3,2));
rrF[4] = _mm256_shuffle_ps(rF[4], rF[6], _MM_SHUFFLE(1,0,1,0));
rrF[5] = _mm256_shuffle_ps(rF[4], rF[6], _MM_SHUFFLE(3,2,3,2));
rrF[6] = _mm256_shuffle_ps(rF[5], rF[7], _MM_SHUFFLE(1,0,1,0));
rrF[7] = _mm256_shuffle_ps(rF[5], rF[7], _MM_SHUFFLE(3,2,3,2));

rF = reinterpret_cast<__m256 *>(in);
rF[0] = _mm256_permute2f128_ps(rrF[0], rrF[4], 0x20);
rF[1] = _mm256_permute2f128_ps(rrF[1], rrF[5], 0x20);
rF[2] = _mm256_permute2f128_ps(rrF[2], rrF[6], 0x20);
rF[3] = _mm256_permute2f128_ps(rrF[3], rrF[7], 0x20);
rF[4] = _mm256_permute2f128_ps(rrF[0], rrF[4], 0x31);
rF[5] = _mm256_permute2f128_ps(rrF[1], rrF[5], 0x31);
rF[6] = _mm256_permute2f128_ps(rrF[2], rrF[6], 0x31);
rF[7] = _mm256_permute2f128_ps(rrF[3], rrF[7], 0x31);
}

inline void Transpose8x8Permute(unsigned long *in)
{
__m256i *inI = reinterpret_cast<__m256i *>(in);
__m256i rI[8];
rI[0] = _mm256_permute2f128_si256(inI[0], inI[4], 0x20);
rI[1] = _mm256_permute2f128_si256(inI[0], inI[4], 0x31);
rI[2] = _mm256_permute2f128_si256(inI[1], inI[5], 0x20);
rI[3] = _mm256_permute2f128_si256(inI[1], inI[5], 0x31);
rI[4] = _mm256_permute2f128_si256(inI[2], inI[6], 0x20);
rI[5] = _mm256_permute2f128_si256(inI[2], inI[6], 0x31);
rI[6] = _mm256_permute2f128_si256(inI[3], inI[7], 0x20);
rI[7] = _mm256_permute2f128_si256(inI[3], inI[7], 0x31);

__m256 rrF[8];
__m256 *rF = reinterpret_cast<__m256 *>(rI);
rrF[0] = _mm256_unpacklo_ps(rF[0], rF[4]);
rrF[1] = _mm256_unpackhi_ps(rF[0], rF[4]);
rrF[2] = _mm256_unpacklo_ps(rF[1], rF[5]);
rrF[3] = _mm256_unpackhi_ps(rF[1], rF[5]);
rrF[4] = _mm256_unpacklo_ps(rF[2], rF[6]);
rrF[5] = _mm256_unpackhi_ps(rF[2], rF[6]);
rrF[6] = _mm256_unpacklo_ps(rF[3], rF[7]);
rrF[7] = _mm256_unpackhi_ps(rF[3], rF[7]);

rF = reinterpret_cast<__m256 *>(in);
rF[0] = _mm256_unpacklo_ps(rrF[0], rrF[4]);
rF[1] = _mm256_unpackhi_ps(rrF[0], rrF[4]);
rF[2] = _mm256_unpacklo_ps(rrF[1], rrF[5]);
rF[3] = _mm256_unpackhi_ps(rrF[1], rrF[5]);
rF[4] = _mm256_unpacklo_ps(rrF[2], rrF[6]);
rF[5] = _mm256_unpackhi_ps(rrF[2], rrF[6]);
rF[6] = _mm256_unpacklo_ps(rrF[3], rrF[7]);
rF[7] = _mm256_unpackhi_ps(rrF[3], rrF[7]);
}

inline void Transpose8x8Insert(unsigned long *in)
{
__m256i *inIa = reinterpret_cast<__m256i *>(in);
__m256i *inIb = reinterpret_cast<__m256i *>(&reinterpret_cast<__m128i *>(in)[1]);
__m128i *inI128 = reinterpret_cast<__m128i *>(in);
__m256i rI[8];
rI[0] = _mm256_insertf128_si256(inIa[0], inI128[8], 1);
rI[1] = _mm256_insertf128_si256(inIb[0], inI128[9], 1);
rI[2] = _mm256_insertf128_si256(inIa[1], inI128[10], 1);
rI[3] = _mm256_insertf128_si256(inIb[1], inI128[11], 1);
rI[4] = _mm256_insertf128_si256(inIa[2], inI128[12], 1);
rI[5] = _mm256_insertf128_si256(inIb[2], inI128[13], 1);
rI[6] = _mm256_insertf128_si256(inIa[3], inI128[14], 1);
rI[7] = _mm256_insertf128_si256(inIb[3], inI128[15], 1);

__m256 rrF[8];
__m256 *rF = reinterpret_cast<__m256 *>(rI);
rrF[0] = _mm256_unpacklo_ps(rF[0], rF[4]);
rrF[1] = _mm256_unpackhi_ps(rF[0], rF[4]);
rrF[2] = _mm256_unpacklo_ps(rF[1], rF[5]);
rrF[3] = _mm256_unpackhi_ps(rF[1], rF[5]);
rrF[4] = _mm256_unpacklo_ps(rF[2], rF[6]);
rrF[5] = _mm256_unpackhi_ps(rF[2], rF[6]);
rrF[6] = _mm256_unpacklo_ps(rF[3], rF[7]);
rrF[7] = _mm256_unpackhi_ps(rF[3], rF[7]);

rF = reinterpret_cast<__m256 *>(in);
rF[0] = _mm256_unpacklo_ps(rrF[0], rrF[4]);
rF[1] = _mm256_unpackhi_ps(rrF[0], rrF[4]);
rF[2] = _mm256_unpacklo_ps(rrF[1], rrF[5]);
rF[3] = _mm256_unpackhi_ps(rrF[1], rrF[5]);
rF[4] = _mm256_unpacklo_ps(rrF[2], rrF[6]);
rF[5] = _mm256_unpackhi_ps(rrF[2], rrF[6]);
rF[6] = _mm256_unpacklo_ps(rrF[3], rrF[7]);
rF[7] = _mm256_unpackhi_ps(rrF[3], rrF[7]);
}

int main()
{
#define dwordCount 64
alignas(32) unsigned long mat[dwordCount];
for (int i = 0; i < dwordCount; i++) {
mat[i] = i;
}
clock_t t;
printf ("Transpose8x8Shuff 100,000,000 times\n");
Transpose8x8Shuff(mat);
t = clock();
int i = 100000000;
do {
Transpose8x8Shuff(mat);
} while (--i >= 0);
t = clock() - t;
volatile int dummy = mat[2];
printf ("(%f seconds).\n",((float)t)/CLOCKS_PER_SEC);
printf ("Transpose8x8Permute 100,000,000 times\n");
Transpose8x8Permute(mat);
t = clock();
i = 100000000;
do {
Transpose8x8Permute(mat);
} while (--i >= 0);
t = clock() - t;
volatile int dummy = mat[2];
printf ("(%f seconds).\n",((float)t)/CLOCKS_PER_SEC);
printf ("Transpose8x8Insert 100,000,000 times\n");
Transpose8x8Insert(mat);
t = clock();
i = 100000000;
do {
Transpose8x8Insert(mat);
} while (--i >= 0);
t = clock() - t;
volatile int dummy = mat[2];
printf ("(%f seconds).\n",((float)t)/CLOCKS_PER_SEC);
char c = getchar();
return 0;
}
``````

This is benchmarking latency, not throughput (because the output for one transpose is the input for the next), but it probably bottlenecks on shuffle throughput anyway.

Results on Skylake i7-6700k @ 3.9GHz for a modified version of the above code (see it on the Godbolt compiler explorer), fixing the following bugs:

• `printf` outside the timed regions, before starting the `clock()`
• `volatile dummy = in[2]` at the end so all the transposes don't optimize away (which gcc actually does otherwise).
• portable C++11, doesn't require MSVC (`alignas(32)` instead of `__declspec`, and don't include `stdafx.h`.)
• sleep removed so the CPU won't downclock to idle speed between tests.

I didn't fix the unnecessary mixing of `__m256i*` / `__m256*`, and I didn't check if that led to worse code-gen with gcc or clang. I also didn't use a `std::chrono` high-rez clock because `clock()` was accurate enough for this many repeats.

g++7.3 `-O3 -march=native` on Arch Linux: Z Boson's version is fastest

``````Transpose8x8Shuff 100,000,000 times
(0.637479 seconds).
Transpose8x8Permute 100,000,000 times
(0.792658 seconds).
Transpose8x8Insert 100,000,000 times
(0.846590 seconds).
``````

clang++ 5.0.1 `-O3 -march=native`: 8x8Permute gets optimized to something even faster than anything gcc did, but 8x8Insert is pessimized horribly.

``````Transpose8x8Shuff 100,000,000 times
(0.642185 seconds).
Transpose8x8Permute 100,000,000 times
(0.622157 seconds).
Transpose8x8Insert 100,000,000 times
(2.149958 seconds).
``````

The asm instructions generated from the source won't match the intrinsics exactly: especially clang has a shuffle optimizer that really compiles the shuffles the same way it optimizes scalar code like `+` on integers. `Transpose8x8Insert` should not be that much slower, so clang must have chosen poorly.

• C intrinsics and variables aren't exactly instructions or registers. Loads and stores take extra instructions. (AVX mostly avoids extra register-copy instructions, though.) Why would you want to force the compiler to emit store instructions to update `in[]` when you could have used local variables? Same amount of store instructions, but when compiling for x86-64, they'll all fit in registers and the stores can be optimized away. (Also, `_mm256_permute2f128_ps` instead of si256 avoids casting the pointers to two different types.) – Peter Cordes Aug 17 '18 at 2:27
• Without `__restrict`, the compiler doesn't know if the input and output overlap, so it actually does all the stores, including to `outI[]`. Fixing that makes your version about the same instruction count as Z Boson's (adapted to read and write in/out array instead of modify references in-place) with `gcc -m32 -O3 -march=haswell`: godbolt.org/g/bEwS4r. gcc aligns the stack by 32 and spills temporaries to the stack in both versions. So your idea of using `in[]` to avoid extra spills didn't work, and just leads to more work done in the asm. – Peter Cordes Aug 17 '18 at 3:01
• gcc does optimize some of the `_mm256_permute2f128_si256` into 128-bit load + `vinserti128`, like Z Boson did by hand in the 2nd version. (Yes, it used the integer version because you used `si256` instead of `ps`). – Peter Cordes Aug 17 '18 at 3:02
• I fixed the issues you brought up. It now uses local scratch areas to prevent the overlap issue. Indeed when I ran it without the local scratch areas it came out around 0.9s. An advantage of doing the _mm256_permute2f128_si256 to pre lane the data is, this can be extended to work on bytes and words. So to transpose a byte matrix you could _mm256_unpacklo_epi8 4 times. – Andrew Hallendorff Aug 17 '18 at 18:22
• Votes aren't permanent, and they reflect the quality of the answer at the time (just a code dump with some bogus reasoning that seemed to think avoiding `_mm256_load_ps` counted as saving asm instructions), not how much effort you put in. Once you improved your answer to make the code not suck, and included benchmarks (presumably from MSVC because you used non-portable `__declspec` instead of C++11 `alignas(32)`), I upvoted. You could improve this further by mentioning which compiler + options you used, and including some of your comments in the answer (e.g. byte matrix). – Peter Cordes Aug 18 '18 at 2:07

Further to previous answers, the usage of shuffleps is pretty much overkill in this scenario, since we can just unpacklo/unpackhi our way to the result. shuffle & unpack instructions have the same latency/throughput, however shuffle generates an additional byte in the machine code op (i.e. 5 bytes for shuffle, 4 for unpack).

At some point, we will require 8 permutes across lanes. This is a slower operation (at 3 cycles latency), so we want to kick off those ops earlier if possible. Assuming the transpose8f method gets inlined (it should do!), then any loads required for the a->h args should be fused into the unpack instructions.

The only minor issue you may face is that because you are using more than 8 registers here, you may spill into YMM9 and up. That can cause VEX2 ops to be generated as VEX3, which will add a byte per op.

As a result, with a bit of jiggling around, you'll end up with this:

``````typedef __m256 f256;
#define unpacklo8f _mm256_unpacklo_ps
#define unpackhi8f _mm256_unpackhi_ps

template<uint8_t X, uint8_t Y>
inline f256 permute128f(const f256 a, const f256 b)
{
return _mm256_permute2f128_ps(a, b, X | (Y << 4));
}

inline void transpose8f(
const f256 a, const f256 b, const f256 c, const f256 d,
const f256 e, const f256 f, const f256 g, const f256 h,
f256& s, f256& t, f256& u, f256& v,
f256& x, f256& y, f256& z, f256& w)
{
const f256 t00 = unpacklo8f(a, c);
const f256 t02 = unpacklo8f(b, d);
const f256 t20 = unpacklo8f(e, g);
const f256 t22 = unpacklo8f(f, h);

const f256 t10 = unpacklo8f(t00, t02);
const f256 t30 = unpacklo8f(t20, t22);
const f256 t11 = unpackhi8f(t00, t02);
s = permute128f<0, 2>(t10, t30);
const f256 t31 = unpackhi8f(t20, t22);
x = permute128f<1, 3>(t10, t30);
const f256 t01 = unpackhi8f(a, c);
t = permute128f<0, 2>(t11, t31);
const f256 t21 = unpackhi8f(e, g);
y = permute128f<1, 3>(t11, t31);
const f256 t03 = unpackhi8f(b, d);
const f256 t23 = unpackhi8f(f, h);

const f256 t12 = unpacklo8f(t01, t03);
const f256 t13 = unpackhi8f(t01, t03);
const f256 t32 = unpacklo8f(t21, t23);
const f256 t33 = unpackhi8f(t21, t23);

u = permute128f<0, 2>(t12, t32);
z = permute128f<1, 3>(t12, t32);
v = permute128f<0, 2>(t13, t33);
w = permute128f<1, 3>(t13, t33);
}
``````

You won't improve on this (You can do the 128bit permutes first, and unpacks second, but they'll end up being identical).

This is my solution with less instructions and the performance is very good about 8 times faster. I've tested using ICC, GCC and Clang in Fedora.

``````#include <stdio.h>
#include <x86intrin.h>
#define MAX1    128
#define MAX2 MAX1

float __attribute__(( aligned(32))) a_tra[MAX2][MAX1], __attribute__(( aligned(32))) a[MAX1][MAX2] ;
int main()
{

int i,j;//, ii=0,jj=0;
// variables for vector section
int vindexm [8]={0, MAX1, MAX1*2, MAX1*3, MAX1*4, MAX1*5, MAX1*6, MAX1*7 };
__m256i vindex = _mm256_load_si256((__m256i *) &vindexm[0]);
__m256 vec1, vec2, vec3, vec4, vec5, vec6, vec7, vec8;

for(i=0; i<MAX1;  i+=8){
for(j=0; j<MAX2;  j+=8){
vec1 = _mm256_i32gather_ps (&a[i][j+0],vindex,4);
vec2 = _mm256_i32gather_ps (&a[i][j+1],vindex,4);
vec3 = _mm256_i32gather_ps (&a[i][j+2],vindex,4);
vec4 = _mm256_i32gather_ps (&a[i][j+3],vindex,4);
vec5 = _mm256_i32gather_ps (&a[i][j+4],vindex,4);
vec6 = _mm256_i32gather_ps (&a[i][j+5],vindex,4);
vec7 = _mm256_i32gather_ps (&a[i][j+6],vindex,4);
vec8 = _mm256_i32gather_ps (&a[i][j+7],vindex,4);

//storing to the rows
_mm256_store_ps(&a_tra[j+0][i], vec1);
_mm256_store_ps(&a_tra[j+1][i], vec2);
_mm256_store_ps(&a_tra[j+2][i], vec3);
_mm256_store_ps(&a_tra[j+3][i], vec4);
_mm256_store_ps(&a_tra[j+4][i], vec5);
_mm256_store_ps(&a_tra[j+5][i], vec6);
_mm256_store_ps(&a_tra[j+6][i], vec7);
_mm256_store_ps(&a_tra[j+7][i], vec8);
}
}
return 0;
}
``````
• On what CPU? I assume on Skylake, because earlier architectures have worse gather throughput. Are you sure you tested the same amount of work? 8x faster doesn't seem reasonable unless you did something wrong like compile without optimization. Also note that your code is unsafe: You forgot to use `alignas(32) int vindexm[8]`, so your code avoids faulting on an aligned load only because your compiler notices that the array is being used for a 256-bit load and chooses to align it. Just use `_mm256_setr_epi32(0, MAX1, MAX1*2, ...)` like a normal person instead of a non-`const` array at all. – Peter Cordes Oct 29 '18 at 0:30
• @PeterCordes, your assumption is right I have tested this on Skylake. You've taught me optimization before and yes I have noticed that. The scalar and intrinsic versions are compiled with `gcc/clang -march=native -O3 -fno-tree-vectorize -fno-slp-vectorize` and `icc -O3 -novec`. Thank you for your suggestions I remember them in future researches. I haven't tested Haswell microarchitecture because I only have a Skylake CPU Core i7 6700HQ – Martin Oct 29 '18 at 10:19
• Wait, you were only comparing this against scalar, not against the other answers here? – Peter Cordes Oct 29 '18 at 10:21
• @PeterCordes, even in Skylake if you mix gather instruction with other computations you'll lose performance. Gather instructions and store are almost pure memory operations and that's the reason that I gain performance. – Martin Oct 29 '18 at 10:21
• @PeterCordes, no only scalar. the other answer's performance must be almost the same as this answer but this answer uses less instructions and is more readable – Martin Oct 29 '18 at 10:23