/* sva.h (sparse vector area) */ /*********************************************************************** * This code is part of GLPK (GNU Linear Programming Kit). * * Copyright (C) 2012-2013 Andrew Makhorin, Department for Applied * Informatics, Moscow Aviation Institute, Moscow, Russia. All rights * reserved. E-mail: . * * GLPK 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. * * GLPK 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 GLPK. If not, see . ***********************************************************************/ #ifndef SVA_H #define SVA_H /*********************************************************************** * Sparse Vector Area (SVA) is a container for sparse vectors. This * program object is used mainly on computing factorization, where the * sparse vectors are rows and columns of sparse matrices. * * The SVA storage is a set of locations numbered 1, 2, ..., size, * where size is the size of SVA, which is the total number of * locations currently allocated. Each location is identified by its * pointer p, 1 <= p <= size, and is the pair (ind[p], val[p]), where * ind[p] and val[p] are, respectively, the index and value fields used * to store the index and numeric value of a particular vector element. * * Each sparse vector is identified by its reference number k, * 1 <= k <= n, where n is the total number of vectors currently stored * in SVA, and defined by the triplet (ptr[k], len[k], cap[k]), where: * ptr[k] is a pointer to the first location of the vector; len[k] is * the vector length, which is the number of its non-zero elements, * len[k] >= 0; and cap[k] is the capacity of the vector, which is the * total number of adjacent locations allocated to that vector, * cap[k] >= len[k]. Thus, non-zero elements of k-th vector are stored * in locations ptr[k], ptr[k]+1, ..., ptr[k]+len[k]-1, and locations * ptr[k]+len[k], ptr[k]+len[k]+1, ..., ptr[k]+cap[k]-1 are reserved. * * The SVA storage is divided into three parts as follows: * * Locations 1, 2, ..., m_ptr-1 constitute the left (dynamic) part of * SVA. This part is used to store vectors, whose capacity may change. * Note that all vectors stored in the left part are also included in * a doubly linked list, where they are ordered by increasing their * pointers ptr[k] (this list is needed for efficient implementation * of the garbage collector used to defragment the left part of SVA); * * Locations m_ptr, m_ptr+1, ..., r_ptr-1 are free and constitute the * middle (free) part of SVA. * * Locations r_ptr, r_ptr+1, ..., size constitute the right (static) * part of SVA. This part is used to store vectors, whose capacity is * not changed. */ typedef struct SVA SVA; struct SVA { /* sparse vector area */ int n_max; /* maximal value of n (enlarged automatically) */ int n; /* number of currently allocated vectors, 0 <= n <= n_max */ int *ptr; /* int ptr[1+n_max]; */ /* ptr[0] is not used; * ptr[k], 1 <= i <= n, is pointer to first location of k-th * vector in the arrays ind and val */ int *len; /* int len[1+n_max]; */ /* len[0] is not used; * len[k], 1 <= k <= n, is length of k-th vector, len[k] >= 0 */ int *cap; /* int cap[1+n_max]; */ /* cap[0] is not used; * cap[k], 1 <= k <= n, is capacity of k-th vector (the number * of adjacent locations allocated to it), cap[k] >= len[k] */ /* NOTE: if cap[k] = 0, then ptr[k] = 0 and len[k] = 0 */ int size; /* total number of locations in SVA */ int m_ptr, r_ptr; /* partitioning pointers that define the left, middle, and right * parts of SVA (see above); 1 <= m_ptr <= r_ptr <= size+1 */ int head; /* number of first (leftmost) vector in the linked list */ int tail; /* number of last (rightmost) vector in the linked list */ int *prev; /* int prev[1+n_max]; */ /* prev[0] is not used; * prev[k] is number of vector which precedes k-th vector in the * linked list; * prev[k] < 0 means that k-th vector is not in the list */ int *next; /* int next[1+n_max]; */ /* next[0] is not used; * next[k] is number of vector which succedes k-th vector in the * linked list; * next[k] < 0 means that k-th vector is not in the list */ /* NOTE: only vectors having non-zero capacity and stored in the * left part of SVA are included in this linked list */ int *ind; /* int ind[1+size]; */ /* ind[0] is not used; * ind[p], 1 <= p <= size, is index field of location p */ double *val; /* double val[1+size]; */ /* val[0] is not used; * val[p], 1 <= p <= size, is value field of location p */ #if 1 int talky; /* option to enable talky mode */ #endif }; #define sva_create_area _glp_sva_create_area SVA *sva_create_area(int n_max, int size); /* create sparse vector area (SVA) */ #define sva_alloc_vecs _glp_sva_alloc_vecs int sva_alloc_vecs(SVA *sva, int nnn); /* allocate new vectors in SVA */ #define sva_resize_area _glp_sva_resize_area void sva_resize_area(SVA *sva, int delta); /* change size of SVA storage */ #define sva_defrag_area _glp_sva_defrag_area void sva_defrag_area(SVA *sva); /* defragment left part of SVA */ #define sva_more_space _glp_sva_more_space void sva_more_space(SVA *sva, int m_size); /* increase size of middle (free) part of SVA */ #define sva_enlarge_cap _glp_sva_enlarge_cap void sva_enlarge_cap(SVA *sva, int k, int new_cap, int skip); /* enlarge capacity of specified vector */ #define sva_reserve_cap _glp_sva_reserve_cap void sva_reserve_cap(SVA *sva, int k, int new_cap); /* reserve locations for specified vector */ #define sva_make_static _glp_sva_make_static void sva_make_static(SVA *sva, int k); /* relocate specified vector to right part of SVA */ #define sva_check_area _glp_sva_check_area void sva_check_area(SVA *sva); /* check sparse vector area (SVA) */ #define sva_delete_area _glp_sva_delete_area void sva_delete_area(SVA *sva); /* delete sparse vector area (SVA) */ #endif /* eof */