I need a fast memory transpose algorithm for my Gaussian convolution function in C/C++. What I do now is

```
convolute_1D
transpose
convolute_1D
transpose
```

It turns out that with this method the filter size has to be large (or larger than I expected) or the transpose takes longer than the convolution (e.g. for a 1920x1080 matrix the convolution takes the same time as the transpose for a filter size of 35). The current transpose algorithm I am using uses loop blocking/tiling along with SSE and OpenMP. I have tried a version using AVX but it's no faster. Any suggestions on how I can speed this up?

```
inline void transpose4x4_SSE(float *A, float *B, const int lda, const int ldb) {
__m128 row1 = _mm_load_ps(&A[0*lda]);
__m128 row2 = _mm_load_ps(&A[1*lda]);
__m128 row3 = _mm_load_ps(&A[2*lda]);
__m128 row4 = _mm_load_ps(&A[3*lda]);
_MM_TRANSPOSE4_PS(row1, row2, row3, row4);
_mm_store_ps(&B[0*ldb], row1);
_mm_store_ps(&B[1*ldb], row2);
_mm_store_ps(&B[2*ldb], row3);
_mm_store_ps(&B[3*ldb], row4);
}
//block_size = 16 works best
inline void transpose_block_SSE4x4(float *A, float *B, const int n, const int m, const int lda, const int ldb ,const int block_size) {
#pragma omp parallel for
for(int i=0; i<n; i+=block_size) {
for(int j=0; j<m; j+=block_size) {
int max_i2 = i+block_size < n ? i + block_size : n;
int max_j2 = j+block_size < m ? j + block_size : m;
for(int i2=i; i2<max_i2; i2+=4) {
for(int j2=j; j2<max_j2; j2+=4) {
transpose4x4_SSE(&A[i2*lda +j2], &B[j2*ldb + i2], lda, ldb);
}
}
}
}
}
```

Transpose 8x8 float matrix using AVX. It's no faster than four 4x4 transposes.

```
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);
}
inline void transpose8x8_avx(float *A, float *B, const int lda, const int ldb) {
__m256 row0 = _mm256_load_ps(&A[0*lda]);
__m256 row1 = _mm256_load_ps(&A[1*lda]);
__m256 row2 = _mm256_load_ps(&A[2*lda]);
__m256 row3 = _mm256_load_ps(&A[3*lda]);
__m256 row4 = _mm256_load_ps(&A[4*lda]);
__m256 row5 = _mm256_load_ps(&A[5*lda]);
__m256 row6 = _mm256_load_ps(&A[6*lda]);
__m256 row7 = _mm256_load_ps(&A[7*lda]);
transpose8_ps(row0, row1, row2, row3, row4, row5, row6, row7);
_mm256_store_ps(&B[0*ldb], row0);
_mm256_store_ps(&B[1*ldb], row1);
_mm256_store_ps(&B[2*ldb], row2);
_mm256_store_ps(&B[3*ldb], row3);
_mm256_store_ps(&B[4*ldb], row4);
_mm256_store_ps(&B[5*ldb], row5);
_mm256_store_ps(&B[6*ldb], row6);
_mm256_store_ps(&B[7*ldb], row7);
}
```