/* spmatrix/getset_complex_source.c * * Copyright (C) 2012, 2013, 2014, 2015, 2016, 2017, 2018 Patrick Alken * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or (at * your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ static void * FUNCTION (tree, find) (const TYPE (gsl_spmatrix) * m, const size_t i, const size_t j); BASE FUNCTION (gsl_spmatrix, get) (const TYPE (gsl_spmatrix) * m, const size_t i, const size_t j) { BASE zero = ZERO; if (i >= m->size1) { GSL_ERROR_VAL("first index out of range", GSL_EINVAL, zero); } else if (j >= m->size2) { GSL_ERROR_VAL("second index out of range", GSL_EINVAL, zero); } else if (m->nz == 0) { /* no non-zero elements added to matrix */ return zero; } else { if (GSL_SPMATRIX_ISCOO(m)) { /* traverse binary tree to search for (i,j) element */ void *ptr = FUNCTION (tree, find) (m, i, j); BASE x = ptr ? *(BASE *) ptr : zero; return x; } else if (GSL_SPMATRIX_ISCSC(m)) { const int *mi = m->i; const int *mp = m->p; int p; /* loop over column j and search for row index i */ for (p = mp[j]; p < mp[j + 1]; ++p) { if (mi[p] == (int) i) return *(BASE *) &m->data[2 * p]; } } else if (GSL_SPMATRIX_ISCSR(m)) { const int *mj = m->i; const int *mp = m->p; int p; /* loop over row i and search for column index j */ for (p = mp[i]; p < mp[i + 1]; ++p) { if (mj[p] == (int) j) return *(BASE *) &m->data[2 * p]; } } else { GSL_ERROR_VAL("unknown sparse matrix type", GSL_EINVAL, zero); } /* element not found; return 0 */ return zero; } } int FUNCTION (gsl_spmatrix, set) (TYPE (gsl_spmatrix) * m, const size_t i, const size_t j, const BASE x) { if (!GSL_SPMATRIX_ISCOO(m)) { GSL_ERROR("matrix not in COO representation", GSL_EINVAL); } else if (!(m->spflags & GSL_SPMATRIX_FLG_GROW) && (i >= m->size1 || j >= m->size2)) { GSL_ERROR ("indices out of range", GSL_EINVAL); } else if (m->spflags & GSL_SPMATRIX_FLG_FIXED) { /* * sparsity pattern is fixed - no elements may be inserted, but existing * elements can be replaced */ void * ptr = FUNCTION (tree, find) (m, i, j); if (ptr == NULL) { GSL_ERROR("attempt to add new matrix element to fixed sparsity pattern", GSL_EINVAL); } else { *(BASE *) ptr = x; } return GSL_SUCCESS; } else { int status = GSL_SUCCESS; void *ptr; /* check if matrix needs to be reallocated */ if (m->nz >= m->nzmax) { status = FUNCTION (gsl_spmatrix, realloc) (2 * m->nzmax, m); if (status) return status; } /* store the triplet (i, j, x) */ m->i[m->nz] = i; m->p[m->nz] = j; m->data[2 * m->nz] = GSL_REAL (x); m->data[2 * m->nz + 1] = GSL_IMAG (x); ptr = gsl_bst_insert(&m->data[2 * m->nz], m->tree); if (ptr != NULL) { /* found duplicate entry (i,j), replace with new x */ *((BASE *) ptr) = x; } else { /* no duplicate (i,j) found */ /* increase matrix dimensions if needed */ if (m->spflags & GSL_SPMATRIX_FLG_GROW) { m->size1 = GSL_MAX(m->size1, i + 1); m->size2 = GSL_MAX(m->size2, j + 1); } ++(m->nz); } return status; } } BASE * FUNCTION (gsl_spmatrix, ptr) (const TYPE (gsl_spmatrix) * m, const size_t i, const size_t j) { if (i >= m->size1) { GSL_ERROR_NULL("first index out of range", GSL_EINVAL); } else if (j >= m->size2) { GSL_ERROR_NULL("second index out of range", GSL_EINVAL); } else { if (GSL_SPMATRIX_ISCOO(m)) { /* traverse binary tree to search for (i,j) element */ void *ptr = FUNCTION (tree, find) (m, i, j); return (BASE *) ptr; } else if (GSL_SPMATRIX_ISCSC(m)) { const int *mi = m->i; const int *mp = m->p; int p; /* loop over column j and search for row index i */ for (p = mp[j]; p < mp[j + 1]; ++p) { if (mi[p] == (int) i) return (BASE *) &(m->data[2 * p]); } } else if (GSL_SPMATRIX_ISCSR(m)) { const int *mj = m->i; const int *mp = m->p; int p; /* loop over row i and search for column index j */ for (p = mp[i]; p < mp[i + 1]; ++p) { if (mj[p] == (int) j) return (BASE *) &(m->data[2 * p]); } } else { GSL_ERROR_NULL("unknown sparse matrix type", GSL_EINVAL); } /* element not found; return NULL */ return NULL; } } /* tree_find() Find node in tree corresponding to matrix entry (i,j). Adapted from avl_find() Inputs: m - spmatrix i - row index j - column index Return: pointer to tree node data if found, NULL if not found */ static void * FUNCTION (tree, find) (const TYPE (gsl_spmatrix) * m, const size_t i, const size_t j) { const gsl_bst_avl_table *table = (const gsl_bst_avl_table *) &(m->tree->table.avl_table); struct gsl_bst_avl_node *p; for (p = table->avl_root; p != NULL; ) { size_t n = ((ATOMIC *) p->avl_data - m->data) >> 1; int pi = m->i[n]; int pj = m->p[n]; int cmp = GSL_SPMATRIX_COMPARE_ROWCOL(m, (int) i, (int) j, pi, pj); if (cmp < 0) p = p->avl_link[0]; else if (cmp > 0) p = p->avl_link[1]; else /* |cmp == 0| */ return p->avl_data; } return NULL; }