# When to use dsgesv versus dgesv to solve a system of linear equations

In the LAPACK documentation, it states that DSGESV (or ZCGESV for complex numbers) is:

The dsgesv and zcgesv are mixed precision iterative refinement subroutines for exploiting fast single precision hardware. They first attempt to factorize the matrix in single precision (dsgesv) or single complex precision (zcgesv) and use this factorization within an iterative refinement procedure to produce a solution with double precision (dsgesv) / double complex precision (zcgesv) normwise backward error quality (see below). If the approach fails, the method switches to a double precision or double complex precision factorization respectively and computes the solution.

The iterative refinement is not going to be a winning strategy if the ratio single precision performance over double precision performance is too small. A reasonable strategy should take the number of right-hand sides and the size of the matrix into account. This might be done with a call to ilaenv in the future. At present, iterative refinement is implemented.

But how can I know what the ratio of single precision performance over double precision performance is? There is the suggestion to take into account the size of the matrix, but I don't see how exactly the size of the matrix leads to an estimate of this performance ratio.

Would anyone be able to clarify these things?

My guess is that the best way to go is to test both dgesv() and dsgesv()...

Looking at the source code of the function dsgesv() of Lapack, here is what dsgesv() tries to perform:

• Cast the matrix A to float As
• Call sgetrf() : LU factorization, single precision
• Solve the system As.x=b using the LU factorization by calling sgetrs()
• Compute the double precision residue r=b-Ax and solve As.x'=r using sgetrs() again, add x=x+x'.

The last step is repeated until double precision is acheived (30 iterations max). The criteria defining success is:

$||r||_\infty\leq||x||_\infty.||A||_\infty.\varepsilon.n$

where $\varepsilon$ is the precision of double precison floating point numbers (approximately 1e-13) and $n$ is the size of the matrix. If it fails, dsgesv() resumes to dgesv() since it calls dgetrf() (factorization) and then dgetrs(). Hence dsgesv() is a mixed precision algorithm. See this article for instance.

Lastly, dsgesv() is expected to outperform dgesv() for small number of right-hand sides and large matrices, that is when the cost of the factorization sgetrf()/dgetrf() $O(n^3)$ is much higher than the one of the substitutions sgetrs()/dgetrs() $O(n^2.n_{rhs})$. Since the maximum number of iteration set in dsgesv() is 30, an approximate limit would be

$n\geq30.n_{rhs}$

Moreover, sgetrf() must proove significantly faster than dgetrf(). sgetrf() can be faster due to a limited available memory bandwidth or vector processing (look for SIMD, example from SSE: the instruction ADDPS).

The argument iter of dsgesv() can be tested to check whether the iterative refinement was useful. If it is negative, iterative refinement failed and using dsgesv() was just a waste of time !

Here is a C code to compare and time dgesv(), sgesv(), dsgesv(). It can be compiled by gcc main.c -o main -llapacke -llapack -lblas Feel free to test your own matrix !

#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include <time.h>

#include <lapacke.h>

int main(void){

srand (time(NULL));

//size of the matrix
int n=2000;
// number of right-hand size
int nb=3;

int nbrun=1000*100*100/n/n;

//memory initialization
double *aaa=malloc(n*n*sizeof(double));
if(aaa==NULL){fprintf(stderr,"malloc failed\n");exit(1);}
double *aa=malloc(n*n*sizeof(double));
if(aa==NULL){fprintf(stderr,"malloc failed\n");exit(1);}
double *bbb=malloc(n*nb*sizeof(double));
if(bbb==NULL){fprintf(stderr,"malloc failed\n");exit(1);}
double *x=malloc(n*nb*sizeof(double));
if(x==NULL){fprintf(stderr,"malloc failed\n");exit(1);}
double *bb=malloc(n*nb*sizeof(double));
if(bb==NULL){fprintf(stderr,"malloc failed\n");exit(1);}

float *aaas=malloc(n*n*sizeof(float));
if(aaas==NULL){fprintf(stderr,"malloc failed\n");exit(1);}
float *aas=malloc(n*n*sizeof(float));
if(aas==NULL){fprintf(stderr,"malloc failed\n");exit(1);}
float *bbbs=malloc(n*n*sizeof(float));
if(bbbs==NULL){fprintf(stderr,"malloc failed\n");exit(1);}
float *bbs=malloc(n*nb*sizeof(float));
if(bbs==NULL){fprintf(stderr,"malloc failed\n");exit(1);}

int *ipiv=malloc(n*nb*sizeof(int));
if(ipiv==NULL){fprintf(stderr,"malloc failed\n");exit(1);}

int i,j;

//matrix initialization
double cond=1e3;
for(i=0;i<n;i++){
for(j=0;j<n;j++){
if(j==i){
aaa[i*n+j]=pow(cond,(i+1)/(double)n);
}else{
aaa[i*n+j]=1.9*(rand()/(double)RAND_MAX-0.5)*pow(cond,(i+1)/(double)n)/(double)n;
//aaa[i*n+j]=(rand()/(double)RAND_MAX-0.5)/(double)n;
//aaa[i*n+j]=0;
}
}
bbb[i]=i;
}

for(i=0;i<n;i++){
for(j=0;j<n;j++){
aaas[i*n+j]=aaa[i*n+j];
}
bbbs[i]=bbb[i];
}

int k=0;
int ierr;

//estimating the condition number of the matrix
memcpy(aa,aaa,n*n*sizeof(double));
double anorm;
double rcond;
//anorm=LAPACKE_dlange( LAPACK_ROW_MAJOR, 'i', n,n, aa, n);
double work[n];
anorm=LAPACKE_dlange_work(LAPACK_ROW_MAJOR, 'i', n, n, aa, n, work );
ierr=LAPACKE_dgetrf( LAPACK_ROW_MAJOR, n, n,aa, n,ipiv );
if(ierr<0){LAPACKE_xerbla( "LAPACKE_dgetrf", ierr );}
ierr=LAPACKE_dgecon(LAPACK_ROW_MAJOR, 'i', n,aa, n,anorm,&rcond );
if(ierr<0){LAPACKE_xerbla( "LAPACKE_dgecon", ierr );}
printf("condition number is %g\n",anorm,1./rcond);

//testing dgesv()
clock_t t;
t = clock();
for(k=0;k<nbrun;k++){

memcpy(bb,bbb,n*nb*sizeof(double));
memcpy(aa,aaa,n*n*sizeof(double));

ierr=LAPACKE_dgesv(LAPACK_ROW_MAJOR,n,nb,aa,n,ipiv,bb,nb);
if(ierr<0){LAPACKE_xerbla( "LAPACKE_dgesv", ierr );}

}

//testing sgesv()
t = clock() - t;
printf ("dgesv()x%d took me %d clicks (%f seconds).\n",nbrun,t,((float)t)/CLOCKS_PER_SEC);

t = clock();
for(k=0;k<nbrun;k++){

memcpy(bbs,bbbs,n*nb*sizeof(float));
memcpy(aas,aaas,n*n*sizeof(float));

ierr=LAPACKE_sgesv(LAPACK_ROW_MAJOR,n,nb,aas,n,ipiv,bbs,nb);
if(ierr<0){LAPACKE_xerbla( "LAPACKE_sgesv", ierr );}

}

//testing dsgesv()
t = clock() - t;
printf ("sgesv()x%d took me %d clicks (%f seconds).\n",nbrun,t,((float)t)/CLOCKS_PER_SEC);

int iter;
t = clock();
for(k=0;k<nbrun;k++){

memcpy(bb,bbb,n*nb*sizeof(double));
memcpy(aa,aaa,n*n*sizeof(double));

ierr=LAPACKE_dsgesv(LAPACK_ROW_MAJOR,n,nb,aa,n,ipiv,bb,nb,x,nb,&iter);
if(ierr<0){LAPACKE_xerbla( "LAPACKE_dsgesv", ierr );}

}
t = clock() - t;
printf ("dsgesv()x%d took me %d clicks (%f seconds).\n",nbrun,t,((float)t)/CLOCKS_PER_SEC);

if(iter>0){
printf("iterative refinement has succeded, %d iterations\n");
}else{
printf("iterative refinement has failed due to");
if(iter==-1){
printf(" implementation- or machine-specific reasons\n");
}
if(iter==-2){
printf(" overflow in iterations\n");
}
if(iter==-3){
printf(" failure of single precision factorization sgetrf() (ill-conditionned?)\n");
}
if(iter==-31){
printf(" max number of iterations\n");
}
}
free(aaa);
free(aa);
free(bbb);
free(bb);
free(x);

free(aaas);
free(aas);
free(bbbs);
free(bbs);

free(ipiv);

return 0;
}


Output for n=2000:

condition number is 1475.26

dgesv()x2 took me 5260000 clicks (5.260000 seconds).

sgesv()x2 took me 3560000 clicks (3.560000 seconds).

dsgesv()x2 took me 3790000 clicks (3.790000 seconds).

iterative refinement has succeded, 11 iterations