# ZGEMM using SSE, not giving speedup

I'm performing a matrix matrix multiplication of complex doubles (ZGEMM) and thought using SSE will help, but its not, in fact its slowing the code down. I wanted to know if, maybe, its because its memory bound?

Heres the pseudocode:

For multiplying two complex doubles I use the following, as proposed by intel (assuming real and complex are stored contiguously):

If M=(a+ib) and IN= (c+id):

``````M1 = _mm_loaddup_pd(&M[0]);//M1->|a|a|
T1 = _mm_mul_pd(M1,I1);//T1->|a*d|a*c|

I1 = _mm_shuffle_pd(I1,I1,1);//I1->|c|d|
I1 = _mm_mul_pd(M1,I1);//I1->|b*c|b*d|

``````

Thus T1 stores the result of the complex multiplication.

This is the matrix multiplication(`C[i][j] += A[i][k]*B[k][j]`):

``````/*Assumes real and imaginary elements are stored contiguously*/
/*Used loop order: ikj for better cache locality and used 2*2 block matrix mult*/
for(i=0;i<N;i+=2){
for(k=0;k<N;k+=2){
/*Perform the _mm_loaddup() part here for A[i][k],A[i][k+1],A[i+1][k],A[i+1][k+1] since im blocking for 2*2 matrix mult i.e will load duplicates of 8 double values into 8 SIMD registers here*/
for(j=0;j<N;j+=2){
double out[8] = {0,0,0,0,0,0,0,0};
op00=op01=op10=op11=_mm_setzero_pd();

B00_r = _mm_shuffle_pd(B00,B00,1);
B01_r = _mm_shuffle_pd(B01,B01,1);

/*Perform A[i][k]*B[k][j], A[i][k]*B[k][j+1], A[i+1][k]*B[k][j], A[i+1][k]*B[k][j+1]  and assign it to op00,op01,op10,op11 respectively -> takes 8 _mm_mul_pd() and 4 _mm_addsub_pd()*/

T1 = _mm_mul_pd(A00r,B00);
T2 = _mm_mul_pd(A00i,B00_r);

T1 = _mm_mul_pd(A00r,B01);
T2 = _mm_mul_pd(A00i,B01_r);

T1 = _mm_mul_pd(A10r,B00);
T2 = _mm_mul_pd(A10i,B00_r);

T1 = _mm_mul_pd(A10r,B01);
T2 = _mm_mul_pd(A10i,B01_r);

B00_r = _mm_shuffle_pd(B00,B00,1);
B00_r = _mm_shuffle_pd(B01,B01,1);

T1 = _mm_mul_pd(A01r,B10);
T2 = _mm_mul_pd(A01i,B10_r);

T1 = _mm_mul_pd(A01r,B11);
T2 = _mm_mul_pd(A01i,B11_r);

T1 = _mm_mul_pd(A11r,B10);
T2 = _mm_mul_pd(A11i,B10_r);

T1 = _mm_mul_pd(A11r,B11);
T2 = _mm_mul_pd(A11i,B11_r);

/*Store op00,op01,op10,op11 into out[0],out[2],out[4] and out[6] -> 4 stores*/

_mm_storeu_pd(&out[0],op00);
_mm_storeu_pd(&out[2],op01);
_mm_storeu_pd(&out[4],op10);
_mm_storeu_pd(&out[6],op11);
/*Perform the following 8 operations*/
C[(i*N+j)*2+0] += out[0];
C[(i*N+j)*2+1] += out[1];
.
.
.
C[((i+1)*N+j)*2+3] += out[7];
}
}
}
``````

The L1 cache is of 32KB, so I used cache blocking too (tile size of 16*16 which makes the working set size to be 12KB(3*2^4*2^4*2^3*2)) but it didn't help much. I'm only getting about 50% of the theoretical peak performance. Any pointers on how I could improve this?

-
Where's the actual SSE computation? I see almost none. –  Mysticial Feb 18 '13 at 3:39
@Mysticial: It is when I perform the multiplications. For example, if I perform A[i][k]*B[k][j], and I have stored the real and imaginary parts of A[i][k] in A_r and A_i, B_ri stores real and imaginary parts of B[k][j] contiguously and B_ri_r stores them in reverse order, I'll have to do: T1 = _mm_mul_pd(A_r,B_ri);T2 = _mm_mul_pd(A_i,B_ri_r);op00 = _mm_addsub_pd(T1,T2); –  user1715122 Feb 18 '13 at 3:46
I guess that's the "almost none". Yeah, you simply have too little computation with respect to the amount of shuffling and data movement. –  Mysticial Feb 18 '13 at 3:48
Edited to show complete computations. It is surprising this is memory bound since zgemm by BLAS gives peak performance –  user1715122 Feb 18 '13 at 4:09
@Mystical: In the following post: stackoverflow.com/questions/8389648/… where you mention that "Each of these 12 instructions blocks are completely independent from each other - and take on average 6 cycles to execute.", does it mean that the 6 _mm_mul_pd() all get executed within 5 cycles? –  user1715122 Feb 18 '13 at 5:31