/* rdmcf.c (read min-cost flow problem data in DIMACS format) */ /*********************************************************************** * This code is part of GLPK (GNU Linear Programming Kit). * * Copyright (C) 2009-2016 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 . ***********************************************************************/ #include "dimacs.h" #include "glpk.h" #include "misc.h" #define error dmx_error #define warning dmx_warning #define read_char dmx_read_char #define read_designator dmx_read_designator #define read_field dmx_read_field #define end_of_line dmx_end_of_line #define check_int dmx_check_int /*********************************************************************** * NAME * * glp_read_mincost - read min-cost flow problem data in DIMACS format * * SYNOPSIS * * int glp_read_mincost(glp_graph *G, int v_rhs, int a_low, int a_cap, * int a_cost, const char *fname); * * DESCRIPTION * * The routine glp_read_mincost reads minimum cost flow problem data in * DIMACS format from a text file. * * RETURNS * * If the operation was successful, the routine returns zero. Otherwise * it prints an error message and returns non-zero. */ int glp_read_mincost(glp_graph *G, int v_rhs, int a_low, int a_cap, int a_cost, const char *fname) { DMX _csa, *csa = &_csa; glp_vertex *v; glp_arc *a; int i, j, k, nv, na, ret = 0; double rhs, low, cap, cost; char *flag = NULL; if (v_rhs >= 0 && v_rhs > G->v_size - (int)sizeof(double)) xerror("glp_read_mincost: v_rhs = %d; invalid offset\n", v_rhs); if (a_low >= 0 && a_low > G->a_size - (int)sizeof(double)) xerror("glp_read_mincost: a_low = %d; invalid offset\n", a_low); if (a_cap >= 0 && a_cap > G->a_size - (int)sizeof(double)) xerror("glp_read_mincost: a_cap = %d; invalid offset\n", a_cap); if (a_cost >= 0 && a_cost > G->a_size - (int)sizeof(double)) xerror("glp_read_mincost: a_cost = %d; invalid offset\n", a_cost); glp_erase_graph(G, G->v_size, G->a_size); if (setjmp(csa->jump)) { ret = 1; goto done; } csa->fname = fname; csa->fp = NULL; csa->count = 0; csa->c = '\n'; csa->field[0] = '\0'; csa->empty = csa->nonint = 0; xprintf("Reading min-cost flow problem data from '%s'...\n", fname); csa->fp = glp_open(fname, "r"); if (csa->fp == NULL) { xprintf("Unable to open '%s' - %s\n", fname, get_err_msg()); longjmp(csa->jump, 1); } /* read problem line */ read_designator(csa); if (strcmp(csa->field, "p") != 0) error(csa, "problem line missing or invalid"); read_field(csa); if (strcmp(csa->field, "min") != 0) error(csa, "wrong problem designator; 'min' expected"); read_field(csa); if (!(str2int(csa->field, &nv) == 0 && nv >= 0)) error(csa, "number of nodes missing or invalid"); read_field(csa); if (!(str2int(csa->field, &na) == 0 && na >= 0)) error(csa, "number of arcs missing or invalid"); xprintf("Flow network has %d node%s and %d arc%s\n", nv, nv == 1 ? "" : "s", na, na == 1 ? "" : "s"); if (nv > 0) glp_add_vertices(G, nv); end_of_line(csa); /* read node descriptor lines */ flag = xcalloc(1+nv, sizeof(char)); memset(&flag[1], 0, nv * sizeof(char)); if (v_rhs >= 0) { rhs = 0.0; for (i = 1; i <= nv; i++) { v = G->v[i]; memcpy((char *)v->data + v_rhs, &rhs, sizeof(double)); } } for (;;) { read_designator(csa); if (strcmp(csa->field, "n") != 0) break; read_field(csa); if (str2int(csa->field, &i) != 0) error(csa, "node number missing or invalid"); if (!(1 <= i && i <= nv)) error(csa, "node number %d out of range", i); if (flag[i]) error(csa, "duplicate descriptor of node %d", i); read_field(csa); if (str2num(csa->field, &rhs) != 0) error(csa, "node supply/demand missing or invalid"); check_int(csa, rhs); if (v_rhs >= 0) { v = G->v[i]; memcpy((char *)v->data + v_rhs, &rhs, sizeof(double)); } flag[i] = 1; end_of_line(csa); } xfree(flag), flag = NULL; /* read arc descriptor lines */ for (k = 1; k <= na; k++) { if (k > 1) read_designator(csa); if (strcmp(csa->field, "a") != 0) error(csa, "wrong line designator; 'a' expected"); read_field(csa); if (str2int(csa->field, &i) != 0) error(csa, "starting node number missing or invalid"); if (!(1 <= i && i <= nv)) error(csa, "starting node number %d out of range", i); read_field(csa); if (str2int(csa->field, &j) != 0) error(csa, "ending node number missing or invalid"); if (!(1 <= j && j <= nv)) error(csa, "ending node number %d out of range", j); read_field(csa); if (!(str2num(csa->field, &low) == 0 && low >= 0.0)) error(csa, "lower bound of arc flow missing or invalid"); check_int(csa, low); read_field(csa); if (!(str2num(csa->field, &cap) == 0 && cap >= low)) error(csa, "upper bound of arc flow missing or invalid"); check_int(csa, cap); read_field(csa); if (str2num(csa->field, &cost) != 0) error(csa, "per-unit cost of arc flow missing or invalid"); check_int(csa, cost); a = glp_add_arc(G, i, j); if (a_low >= 0) memcpy((char *)a->data + a_low, &low, sizeof(double)); if (a_cap >= 0) memcpy((char *)a->data + a_cap, &cap, sizeof(double)); if (a_cost >= 0) memcpy((char *)a->data + a_cost, &cost, sizeof(double)); end_of_line(csa); } xprintf("%d lines were read\n", csa->count); done: if (ret) glp_erase_graph(G, G->v_size, G->a_size); if (csa->fp != NULL) glp_close(csa->fp); if (flag != NULL) xfree(flag); return ret; } /* eof */