void SPVEC_double_delete( SPVEC_double *A)
{
if (A==NULL)
return;
blas_free(A->val_);
blas_free(A->index_);
blas_free(A);
}
void SPBLASI_delete_Matrix(int h)
{
SPBLASI_Matrix S = SPBLASI_get_Matrix(h);
if (S==NULL)
return;
if (S->state_ == unused)
return;
DCSR_free(S->mat_.dcsr_);
S->state_ = unused;
SPBLASI_Table_num_active_matrices--;
if (SPBLASI_Table_num_active_matrices < 1)
{
blas_free(SPBLASI_Table);
SPBLASI_Table_size = 0;
}
}
void BLAS_ztrmv_c_testgen(int norm, enum blas_order_type order,
enum blas_uplo_type uplo,
enum blas_trans_type trans,
enum blas_diag_type diag, int n, void *alpha,
int alpha_flag, void *T, int ldt, void *x,
int *seed, double *head_r_true, double *tail_r_true)
/*
* Purpose
* =======
*
* Generates alpha, T and x, where T is a triangular matrix; and
* computes r_true.
*
* Arguments
* =========
*
* norm (input) blas_norm_type
*
* order (input) blas_order_type
* Order of T; row or column major
*
* uplo (input) blas_uplo_type
* Whether T is upper or lower
*
* trans (input) blas_trans_type
* No trans, trans, conj trans
*
* diag (input) blas_diag_type
* non unit, unit
*
* n (input) int
* Dimension of AP and the length of vector x
*
* alpha (input/output) void*
* If alpha_flag = 1, alpha is input.
* If alpha_flag = 0, alpha is output.
*
* alpha_flag (input) int
* = 0 : alpha is free, and is output.
* = 1 : alpha is fixed on input.
*
* T (output) void*
*
* x (input/output) void*
*
* seed (input/output) int
*
* head_r_true (output) double*
* The leading part of the truth in double-double.
*
* tail_r_true (output) double*
* The trailing part of the truth in double-double.
*
*/
{
double *x_i = (double *) x;
float *T_i = (float *) T;
double *alpha_i = (double *) alpha;
double *x_vec;
float *t_vec;
double beta[2];
double r[2];
double head_r_true_elem[2], tail_r_true_elem[2];
double x_elem[2];
float t_elem[2];
int inc_tvec = 1, inc_xvec = 1;
int xvec_i, tvec_j;
int xi;
int ti, tij;
int inc_ti, inc_tij;
int inc_xi;
int i, j;
r[0] = r[1] = 0.0;
beta[0] = beta[1] = 0.0;
inc_tvec *= 2;
inc_xvec *= 2;
t_vec = (float *) blas_malloc(n * sizeof(float) * 2);
if (n > 0 && t_vec == NULL) {
BLAS_error("blas_malloc", 0, 0, "malloc failed.\n");
};
x_vec = (double *) blas_malloc(n * sizeof(double) * 2);
if (n > 0 && x_vec == NULL) {
BLAS_error("blas_malloc", 0, 0, "malloc failed.\n");
};
if (trans == blas_no_trans) {
if (uplo == blas_upper) {
inc_xi = -1;
if (order == blas_rowmajor) {
inc_ti = -ldt;
inc_tij = -1;
} else {
inc_ti = -1;
inc_tij = -ldt;
}
} else {
inc_xi = 1;
if (order == blas_rowmajor) {
inc_ti = ldt;
inc_tij = 1;
} else {
inc_ti = 1;
inc_tij = ldt;
}
}
} else {
if (uplo == blas_upper) {
inc_xi = 1;
if (order == blas_rowmajor) {
inc_ti = 1;
inc_tij = ldt;
} else {
inc_ti = ldt;
inc_tij = 1;
}
} else {
inc_xi = -1;
if (order == blas_rowmajor) {
inc_ti = -1;
inc_tij = -ldt;
} else {
inc_ti = -ldt;
inc_tij = -1;
}
}
}
inc_xi *= 2;
inc_ti *= 2;
inc_tij *= 2;
/* Call dot_testgen n times. Each call will generate
* one row of T and one element of x. */
ti = (inc_ti > 0 ? 0 : -(n - 1) * inc_ti);
xi = (inc_xi > 0 ? 0 : -(n - 1) * inc_xi);
xvec_i = 0;
for (i = 0; i < n; i++) {
/* Generate the i-th element of x_vec and all of t_vec. */
if (diag == blas_unit_diag) {
/* Since we need alpha = beta, we fix alpha if alpha_flag = 0. */
if (i == 0 && alpha_flag == 0) {
alpha_i[0] = xrand(seed);
alpha_i[1] = xrand(seed);
}
BLAS_zdot_z_c_testgen(i, 0, i, norm, blas_no_conj, alpha_i,
1, alpha_i, 1, x_vec, t_vec,
seed, r, head_r_true_elem, tail_r_true_elem);
/* Copy generated t_vec to T. */
tvec_j = 0;
tij = (inc_tij > 0 ? ti : ti - (n - 1) * inc_tij);
for (j = 0; j < i; j++) {
t_elem[0] = t_vec[tvec_j];
t_elem[1] = t_vec[tvec_j + 1];
if (trans == blas_conj_trans) {
t_elem[1] = -t_elem[1];
}
T_i[tij] = t_elem[0];
T_i[tij + 1] = t_elem[1];
tvec_j += inc_tvec;
tij += inc_tij;
}
/* Set the diagonal element to 1. */
t_elem[0] = 1.0;
t_elem[1] = 0.0;
T_i[tij] = t_elem[0];
T_i[tij + 1] = t_elem[1];
/* Set x[i] to be r. */
x_i[xi] = r[0];
x_i[xi + 1] = r[1];
x_vec[xvec_i] = r[0];
x_vec[xvec_i + 1] = r[1];
} else {
BLAS_zdot_z_c_testgen(i + 1, 0, i, norm, blas_no_conj, alpha,
(i == 0 ? alpha_flag : 1), beta, 1, x_vec, t_vec,
seed, r, head_r_true_elem, tail_r_true_elem);
/* Copy generated t_vec to T. */
tvec_j = 0;
tij = (inc_tij > 0 ? ti : ti - (n - 1) * inc_tij);
for (j = 0; j <= i; j++) {
t_elem[0] = t_vec[tvec_j];
t_elem[1] = t_vec[tvec_j + 1];
if (trans == blas_conj_trans) {
t_elem[1] = -t_elem[1];
}
T_i[tij] = t_elem[0];
T_i[tij + 1] = t_elem[1];
tvec_j += inc_tvec;
tij += inc_tij;
}
/* Copy generated x_vec[i] to appropriate position in x. */
x_elem[0] = x_vec[xvec_i];
x_elem[1] = x_vec[xvec_i + 1];
x_i[xi] = x_elem[0];
x_i[xi + 1] = x_elem[1];
}
/* Copy r_true */
head_r_true[xi] = head_r_true_elem[0];
head_r_true[xi + 1] = head_r_true_elem[1];
tail_r_true[xi] = tail_r_true_elem[0];
tail_r_true[xi + 1] = tail_r_true_elem[1];
xvec_i += inc_xvec;
xi += inc_xi;
ti += inc_ti;
}
blas_free(x_vec);
blas_free(t_vec);
}
