lapack_int LAPACKE_clacgv( lapack_int n, lapack_complex_float* x,
lapack_int incx )
{
#ifndef LAPACK_DISABLE_NAN_CHECK
/* Optionally check input matrices for NaNs */
if( LAPACKE_c_nancheck( 1+(n-1)*ABS(incx), x, incx ) ) {
return -2;
}
#endif
return LAPACKE_clacgv_work( n, x, incx );
}
int CORE_ctsqrt(int M, int N, int IB,
PLASMA_Complex32_t *A1, int LDA1,
PLASMA_Complex32_t *A2, int LDA2,
PLASMA_Complex32_t *T, int LDT,
PLASMA_Complex32_t *TAU, PLASMA_Complex32_t *WORK)
{
static PLASMA_Complex32_t zone = 1.0;
static PLASMA_Complex32_t zzero = 0.0;
PLASMA_Complex32_t alpha;
int i, ii, sb;
/* Check input arguments */
if (M < 0) {
coreblas_error(1, "Illegal value of M");
return -1;
}
if (N < 0) {
coreblas_error(2, "Illegal value of N");
return -2;
}
if (IB < 0) {
coreblas_error(3, "Illegal value of IB");
return -3;
}
if ((LDA2 < max(1,M)) && (M > 0)) {
coreblas_error(8, "Illegal value of LDA2");
return -8;
}
/* Quick return */
if ((M == 0) || (N == 0) || (IB == 0))
return PLASMA_SUCCESS;
for(ii = 0; ii < N; ii += IB) {
sb = min(N-ii, IB);
for(i = 0; i < sb; i++) {
/*
* Generate elementary reflector H( II*IB+I ) to annihilate
* A( II*IB+I:M, II*IB+I )
*/
LAPACKE_clarfg_work(M+1, &A1[LDA1*(ii+i)+ii+i], &A2[LDA2*(ii+i)], 1, &TAU[ii+i]);
if (ii+i+1 < N) {
/*
* Apply H( II*IB+I ) to A( II*IB+I:M, II*IB+I+1:II*IB+IB ) from the left
*/
alpha = -conjf(TAU[ii+i]);
cblas_ccopy(
sb-i-1,
&A1[LDA1*(ii+i+1)+(ii+i)], LDA1,
WORK, 1);
#ifdef COMPLEX
LAPACKE_clacgv_work(sb-i-1, WORK, 1);
#endif
cblas_cgemv(
CblasColMajor, (CBLAS_TRANSPOSE)PlasmaConjTrans,
M, sb-i-1,
CBLAS_SADDR(zone), &A2[LDA2*(ii+i+1)], LDA2,
&A2[LDA2*(ii+i)], 1,
CBLAS_SADDR(zone), WORK, 1);
#ifdef COMPLEX
LAPACKE_clacgv_work(sb-i-1, WORK, 1 );
#endif
cblas_caxpy(
sb-i-1, CBLAS_SADDR(alpha),
WORK, 1,
&A1[LDA1*(ii+i+1)+ii+i], LDA1);
#ifdef COMPLEX
LAPACKE_clacgv_work(sb-i-1, WORK, 1 );
#endif
cblas_cgerc(
CblasColMajor, M, sb-i-1, CBLAS_SADDR(alpha),
&A2[LDA2*(ii+i)], 1,
WORK, 1,
&A2[LDA2*(ii+i+1)], LDA2);
}
/*
* Calculate T
*/
alpha = -TAU[ii+i];
cblas_cgemv(
CblasColMajor, (CBLAS_TRANSPOSE)PlasmaConjTrans, M, i,
CBLAS_SADDR(alpha), &A2[LDA2*ii], LDA2,
&A2[LDA2*(ii+i)], 1,
CBLAS_SADDR(zzero), &T[LDT*(ii+i)], 1);
cblas_ctrmv(
CblasColMajor, (CBLAS_UPLO)PlasmaUpper,
(CBLAS_TRANSPOSE)PlasmaNoTrans, (CBLAS_DIAG)PlasmaNonUnit, i,
&T[LDT*ii], LDT,
&T[LDT*(ii+i)], 1);
T[LDT*(ii+i)+i] = TAU[ii+i];
}
if (N > ii+sb) {
CORE_ctsmqr(
PlasmaLeft, PlasmaConjTrans,
sb, N-(ii+sb), M, N-(ii+sb), IB, IB,
&A1[LDA1*(ii+sb)+ii], LDA1,
&A2[LDA2*(ii+sb)], LDA2,
&A2[LDA2*ii], LDA2,
&T[LDT*ii], LDT,
WORK, sb);
}
}
return PLASMA_SUCCESS;
}
int CORE_cttqrt(int M, int N, int IB,
PLASMA_Complex32_t *A1, int LDA1,
PLASMA_Complex32_t *A2, int LDA2,
PLASMA_Complex32_t *T, int LDT,
PLASMA_Complex32_t *TAU, PLASMA_Complex32_t *WORK)
{
static PLASMA_Complex32_t zone = 1.0;
static PLASMA_Complex32_t zzero = 0.0;
static int ione = 1;
PLASMA_Complex32_t alpha;
int i, j, ii, sb, mi, ni;
/* Check input arguments */
if (M < 0) {
coreblas_error(1, "Illegal value of M");
return -1;
}
if (N < 0) {
coreblas_error(2, "Illegal value of N");
return -2;
}
if (IB < 0) {
coreblas_error(3, "Illegal value of IB");
return -3;
}
if ((LDA2 < max(1,M)) && (M > 0)) {
coreblas_error(7, "Illegal value of LDA2");
return -7;
}
/* Quick return */
if ((M == 0) || (N == 0) || (IB == 0))
return PLASMA_SUCCESS;
for(ii = 0; ii < N; ii += IB) {
sb = min(N-ii, IB);
for(i = 0; i < sb; i++) {
/*
* Generate elementary reflector H( II*IB+I ) to annihilate
* A( II*IB+I:mi, II*IB+I ).
*/
mi = ii + i + 1;
LAPACKE_clarfg_work(mi+1, &A1[LDA1*(ii+i)+ii+i], &A2[LDA2*(ii+i)], ione, &TAU[ii+i]);
if (sb-i-1>0) {
/*
* Apply H( II*IB+I ) to A( II*IB+I:M, II*IB+I+1:II*IB+IB ) from the left.
*/
ni = sb-i-1;
cblas_ccopy(
ni,
&A1[LDA1*(ii+i+1)+(ii+i)], LDA1,
WORK, 1);
#ifdef COMPLEX
LAPACKE_clacgv_work(ni, WORK, ione);
#endif
cblas_cgemv(
CblasColMajor, (CBLAS_TRANSPOSE)PlasmaConjTrans,
mi, ni,
CBLAS_SADDR(zone), &A2[LDA2*(ii+i+1)], LDA2,
&A2[LDA2*(ii+i)], 1,
CBLAS_SADDR(zone), WORK, 1);
#ifdef COMPLEX
LAPACKE_clacgv_work(ni, WORK, ione);
#endif
alpha = -conjf(TAU[ii+i]);
cblas_caxpy(
ni, CBLAS_SADDR(alpha),
WORK, 1,
&A1[LDA1*(ii+i+1)+ii+i], LDA1);
#ifdef COMPLEX
LAPACKE_clacgv_work(ni, WORK, ione);
#endif
cblas_cgerc(
CblasColMajor, mi, ni,
CBLAS_SADDR(alpha), &A2[LDA2*(ii+i)], 1,
WORK, 1,
&A2[LDA2*(ii+i+1)], LDA2);
}
/*
* Calculate T.
*/
if (i > 0 ) {
cblas_ccopy(i, &A2[LDA2*(ii+i)+ii], 1, &WORK[ii], 1);
cblas_ctrmv(
CblasColMajor, (CBLAS_UPLO)PlasmaUpper,
(CBLAS_TRANSPOSE)PlasmaConjTrans, (CBLAS_DIAG)PlasmaNonUnit,
i, &A2[LDA2*ii+ii], LDA2,
&WORK[ii], 1);
alpha = -(TAU[ii+i]);
for(j = 0; j < i; j++) {
WORK[ii+j] = alpha * WORK[ii+j];
}
if (ii > 0) {
cblas_cgemv(
CblasColMajor, (CBLAS_TRANSPOSE)PlasmaConjTrans, ii, i,
CBLAS_SADDR(alpha), &A2[LDA2*ii], LDA2,
&A2[LDA2*(ii+i)], 1,
CBLAS_SADDR(zzero), WORK, 1);
cblas_caxpy(i, CBLAS_SADDR(zone), &WORK[ii], 1, WORK, 1);
}
cblas_ccopy(i, WORK, 1, &T[LDT*(ii+i)], 1);
cblas_ctrmv(
CblasColMajor, (CBLAS_UPLO)PlasmaUpper,
(CBLAS_TRANSPOSE)PlasmaNoTrans, (CBLAS_DIAG)PlasmaNonUnit,
i, &T[LDT*ii], LDT,
&T[LDT*(ii+i)], 1);
}
T[LDT*(ii+i)+i] = TAU[ii+i];
}
/* Apply Q' to the rest of the matrix to the left */
if (N > ii+sb) {
CORE_cttrfb(
PlasmaLeft, PlasmaConjTrans,
PlasmaForward, PlasmaColumnwise,
sb, N-(ii+sb), ii+sb, N-(ii+sb), sb,
&A1[LDA1*(ii+sb)+ii], LDA1,
&A2[LDA2*(ii+sb)], LDA2,
&A2[LDA2*ii], LDA2,
&T[LDT*ii], LDT,
WORK, sb);
}
}
return PLASMA_SUCCESS;
}
