I tried to translate the following code into AVX intrinsics in order to improve the performance:

```
for (int alpha = 0; alpha < 4; alpha++) {
for (int k = 0; k < 3; k++) {
for (int beta = 0; beta < 4; beta++) {
for (int l = 0; l < 4 ; l++) {
d2_phi[(alpha*3+k)*16 + beta*4+l] =
- (d2_phi[(alpha*3+k)*16 + beta*dim+l]
+ b[k] * ( lam_12[ beta][alpha] * a[l]
+ lam_22[alpha][ beta] * b[l]
+ lam_23[alpha][ beta] * rjk[l] )
+ rjk[k] * ( lam_13[ beta][alpha] * a[l]
+ lam_23[ beta][alpha] * b[l]
+ lam_33[alpha][ beta] * rjk[l] )
) / sqrt_gamma;
}
}
}
}
```

and tried this the following way:

```
// load sqrt_gamma, because it is constant
__m256d ymm7 = _mm256_broadcast_sd(&sqrt_gamma);
for (int alpha=0; alpha < 4; alpha++) {
for (int k=0; k < 3; k++) {
// Load values that are only dependent on k
__m256d ymm9 = _mm256_broadcast_sd(b+k); // all b[k]
__m256d ymm8 = _mm256_broadcast_sd(rjk+k); // all rjk[k]
for (int beta=0; beta < 4; beta++) {
// Load the lambdas, because they will stay the same for nine iterations
__m256d ymm15 = _mm256_broadcast_sd(lam_12_p + 4*beta + alpha); // all lam_12[ beta][alpha]
__m256d ymm14 = _mm256_broadcast_sd(lam_22_p + 4*alpha + beta); // all lam_22[alpha][ beta]
__m256d ymm13 = _mm256_broadcast_sd(lam_23_p + 4*alpha + beta); // all lam_23[alpha][ beta]
__m256d ymm12 = _mm256_broadcast_sd(lam_13_p + 4*beta + alpha); // all lam_13[ beta][alpha]
__m256d ymm11 = _mm256_broadcast_sd(lam_23_p + 4*beta + alpha); // all lam_23[ beta][alpha]
__m256d ymm10 = _mm256_broadcast_sd(lam_33_p + 4*alpha + beta); // lam_33[alpha][ beta]
// Load the values that depend on the innermost loop, which is removed do to AVX
__m256d ymm6 =_mm256_load_pd(a); // a[i] until a[l+3]
__m256d ymm5 =_mm256_load_pd(b); // b[i] until b[l+3]
__m256d ymm4 =_mm256_load_pd(rjk); // rjk[i] until rjk[l+3]
//__m256d ymm3 =_mm256_load_pd(d2_phi_p + (alpha*3+k)*16 + beta*dim); // d2_phi[(alpha*3+k)*12 + beta*dim] until d2_phi[(alpha*3+k)*12 + beta*dim +3]
__m256d ymm3 =_mm256_load_pd(d2_phi_p + 4*s);
// Block that is later on multiplied with b[k]
__m256d ymm2 = _mm256_mul_pd(ymm15, ymm6); // lam_12[ beta][alpha] * a[l]
__m256d ymm1 = _mm256_mul_pd(ymm14, ymm5); // lam_22[alpha][ beta] * b[l];
__m256d ymm0 = _mm256_add_pd(ymm2, ymm1); // lam_12[ beta][alpha] * a[l] + lam_22[alpha][ beta]*b[l];
ymm2 = _mm256_mul_pd(ymm13, ymm4); // lam_23[alpha][ beta] * rjk[l]
ymm0 = _mm256_add_pd(ymm2, ymm0); // lam_12[ beta][alpha] * a[l] + lam_22[alpha][ beta]*b[l] + lam_23[alpha][ beta] * b[i];
ymm0 = _mm256_mul_pd(ymm9, ymm0); // b[k] * (first sum of three)
// Block that is later on multiplied with rjk[k]
ymm2 = _mm256_mul_pd(ymm12, ymm6); // lam_13[ beta][alpha] * a[l]
ymm1 = _mm256_mul_pd(ymm11, ymm5); // lam_23[ beta][alpha] * b[l]
ymm2 = _mm256_add_pd(ymm2, ymm1); // lam_13[ beta][alpha] * a[l] + lam_22[alpha][ beta]*b[l];
ymm1 = _mm256_mul_pd(ymm10, ymm4); // lam_33[alpha][ beta] * rjk[l]
ymm2 = _mm256_add_pd(ymm2, ymm1); // lam_13[ beta][alpha] * a[l] + lam_22[alpha][ beta]*b[l] + lam_33[alpha][ beta] *rjk[l]
ymm2 = _mm256_mul_pd(ymm2, ymm8); // rjk[k] * (second sum of three)
ymm0 = _mm256_add_pd(ymm0, ymm2); // add to temporal result in ymm0
ymm0 = _mm256_add_pd(ymm3, ymm0); // Old value of d2 Phi;
ymm0 = _mm256_div_pd(ymm0, ymm7); // all divided by sqrt_gamma
_mm256_store_pd(d2_phi_p + (alpha*3+k)*16 + beta*dim, ymm0);
}
}
}
```

But the peformance is bad. It is even slower than auto-vectorized code generated by Intel compiler. I tried the following things:

- All data arrays are 64-byte aligned by
`__declspec(align(64))`

- The store at the end was replaced by a streaming store
`_mm256_stream_pd`

When I look into the created assembly code, I see, that the auto-code fetches all parameters every iteration (and not as I did, only in the loops they belong to). It also contains more arithmetic operations. As a last point the store at the end only need half of the time of mine (I repeat the code fragment 1000000 times) and I don't see a reason for that. (I used the Intel VTune Amplifier to look at the assembly and the spent time.)

Thanks for all help in advance!