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#include "tools.h"
void CpzagemvAt(trans, M, N, alpha, A, IA, JA, descA, X0, IX0, JX0, descX0,
incX0, beta0, Y0, IY0, JY0, descY0, incY0)
F_CHAR trans;
int M;
int N;
double alpha;
double *A;
int IA;
int JA;
int *descA;
double *X0;
int IX0;
int JX0;
int *descX0;
int incX0;
double beta0;
double *Y0;
int IY0;
int JY0;
int *descY0;
int incY0;
/*
* ======(Y)======
* N
* ---------------
* || | | A - M x N
* || | | Y - 1 x N
* || | | X - M x 1
* (X) | (A) | M
* || | | X will be replicated across all columns
* || | | Y will have space on all rows
* || | |
* || | |
* ---------------
*/
{
/*
* .. External routines ..
*/
char *ptop();
void pchkmat();
void pchkvec();
void pberror_();
void Cinfog2l();
int Cnumroc2();
void Cblacs_gridinfo();
void Cdgebs2d();
void Cdgebr2d();
void Cdgsum2d();
F_INTG_FCT dgemv_();
void Cpzdvabs1();
void Cpdscal1();
void Cpdcopy1();
void Cpdaxpy1();
char *top;
int ctxt, nprow, npcol, myrow, mycol;
int IX, JX, descX[DLEN_], incX, IY, JY, descY[DLEN_], incY;
int i, j, k, h, arow, acol, LOCp, LOCq, nb, info=0, one=1;
double *absX, *Y, *absA, *x, *y, *a, *aa, beta=0.0;
int IXr, JXr, incXr, descXr[DLEN_];
double *Xr, *xr;
ctxt = descA[CTXT_];
Cblacs_gridinfo(ctxt, &nprow, &npcol, &myrow, &mycol);
pchkmat(M, 2, N, 3, IA+1, JA+1, descA, 8, &info, nprow, npcol, myrow, mycol);
pchkvec(N, 3, IX0+1, JX0+1, descX0, incX0, 12, &info, nprow, npcol,
myrow, mycol);
pchkvec(M, 2, IY0+1, JY0+1, descY0, incY0, 18, &info, nprow, npcol,
myrow, mycol);
if (descA[CTXT_] != descX0[CTXT_])
{
if (info == 0) info = -(1200+CTXT_+1);
}
else if (descX0[CTXT_] != descY0[CTXT_])
{
if (info == 0) info = -(1800+CTXT_+1);
}
if (info)
{
pberror_(&ctxt, "PZAGEMV", &info);
return;
}
/*
* Quick return, if possible
*/
if ( (M == 0) || (N == 0) || ((alpha == 0.0) && (beta0 == 1.0)) ) return;
/*
* Scale Y0 by beta: Y0 = beta * Y0; this allows us to later add in
* alpha*A*x to get Y0 = alpha*A*x + Y0*beta
*/
Cpdscal1(N, beta0, Y0, IY0, JY0, descY0, incY0);
/*
* Collapse complex X down to real Xr
*/
Cpzdvabs1(M, X0, IX0, JX0, descX0, incX0, &Xr, &IXr, &JXr, descXr, &incXr);
/*
* Get local information about our matrix
*/
Cinfog2l(IA, JA, descA, nprow, npcol, myrow, mycol, &i, &j, &arow, &acol);
a = &A[ 2*(i+j*descA[LLD_]) ];
nb = descA[NB_];
LOCp = Cnumroc2(M, IA, descA[MB_], myrow, descA[RSRC_], nprow);
LOCq = Cnumroc2(N, JA, nb, mycol, descA[CSRC_], npcol);
/*
* Set up absX, a column vector aligned with A, copy abs( X ) to it,
* and give all process columns a copy
*/
IX = IA % descA[MB_];
JX = 0;
Mmalloc(absX, double, IX+LOCp, h, ctxt);
Mdescset(descX, M + IX, 1, descA[MB_], 1, arow, descXr[CSRC_], ctxt, LOCp+IX+1);
incX = 1;
Cpdcopy1(M, Xr, IXr, JXr, descXr, incXr, absX, IX, JX, descX, incX);
if (Xr) free(Xr);
/*
* Set local pointer into absX
*/
if (myrow == descX[RSRC_]) x = &absX[IX];
else x = absX;
top = ptop("B", "R", "!");
if (mycol == descX[CSRC_]) Cdgebs2d(ctxt, "r", top, LOCp, 1, x, LOCp);
else Cdgebr2d(ctxt, "r", top, LOCp, 1, x, LOCp, myrow, descX[CSRC_]);
/*
* Get memory for Y and absA
*/
j = JA % nb + LOCq;
Mmalloc(Y, double, j+nb*LOCp, h, ctxt);
absA = &Y[j];
/*
* Set up Y, a row vector aligned with A
*/
IY = 0;
JY = JA % nb;
Mdescset(descY, 1, N+JY, 1, nb,
MCindxg2p(IY0, descY0[MB_], descY0[RSRC_], nprow), acol, ctxt, 1);
incY = 1;
/*
* Set local pointer into Y
*/
if (mycol == descY[CSRC_]) y = &Y[JY];
else y = Y;
/*
* Figure local portion of abs matrix vector product by looping over NB wide panels
*/
if (LOCq != 0)
{
if (LOCp != 0)
{
j = 0;
do
{
aa = absA;
h = MIN(nb, LOCq-j);
for (k=0; k != h; k++) /* Set absA = abs( sub(A) ) */
{
for(i=0; i != LOCp; i++) aa[i] = ABS( a[2*i] ) + ABS( a[2*i+1] );
a += 2*descA[LLD_];
aa += LOCp;
}
dgemv_(trans, &LOCp, &h, &alpha, absA, &LOCp, x, &one, &beta,
&y[j], &one);
j += nb;
}
while (j < LOCq);
}
else for (i=0; i != LOCq; i++) y[i] = 0.0;
/*
* Figure global answer
*/
top = ptop("C", "C", "!");
Cdgsum2d(ctxt, "col", top, LOCq, 1, y, LOCq, descY[RSRC_], mycol);
}
/*
* Y contains ALPHA*A*x. Y0 contains BETA*y. Use pdaxpy to set
* Y0 = ALPHA*A*x + BETA*y
*/
Cpdaxpy1(N, 1.0, Y, IY, JY, descY, incY, Y0, IY0, JY0, descY0, incY0);
if (absX) free(absX);
if (Y) free(Y);
}
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