[9] | 1 | /* glpios10.c (feasibility pump heuristic) */ |
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| 2 | |
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| 3 | /*********************************************************************** |
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| 4 | * This code is part of GLPK (GNU Linear Programming Kit). |
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| 5 | * |
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| 6 | * Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008, |
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| 7 | * 2009, 2010, 2011 Andrew Makhorin, Department for Applied Informatics, |
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| 8 | * Moscow Aviation Institute, Moscow, Russia. All rights reserved. |
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| 9 | * E-mail: <mao@gnu.org>. |
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| 10 | * |
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| 11 | * GLPK is free software: you can redistribute it and/or modify it |
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| 12 | * under the terms of the GNU General Public License as published by |
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| 13 | * the Free Software Foundation, either version 3 of the License, or |
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| 14 | * (at your option) any later version. |
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| 15 | * |
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| 16 | * GLPK is distributed in the hope that it will be useful, but WITHOUT |
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| 17 | * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY |
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| 18 | * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public |
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| 19 | * License for more details. |
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| 20 | * |
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| 21 | * You should have received a copy of the GNU General Public License |
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| 22 | * along with GLPK. If not, see <http://www.gnu.org/licenses/>. |
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| 23 | ***********************************************************************/ |
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| 24 | |
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| 25 | #include "glpios.h" |
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| 26 | #include "glprng.h" |
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| 27 | |
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| 28 | /*********************************************************************** |
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| 29 | * NAME |
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| 30 | * |
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| 31 | * ios_feas_pump - feasibility pump heuristic |
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| 32 | * |
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| 33 | * SYNOPSIS |
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| 34 | * |
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| 35 | * #include "glpios.h" |
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| 36 | * void ios_feas_pump(glp_tree *T); |
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| 37 | * |
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| 38 | * DESCRIPTION |
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| 39 | * |
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| 40 | * The routine ios_feas_pump is a simple implementation of the Feasi- |
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| 41 | * bility Pump heuristic. |
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| 42 | * |
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| 43 | * REFERENCES |
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| 44 | * |
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| 45 | * M.Fischetti, F.Glover, and A.Lodi. "The feasibility pump." Math. |
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| 46 | * Program., Ser. A 104, pp. 91-104 (2005). */ |
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| 47 | |
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| 48 | struct VAR |
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| 49 | { /* binary variable */ |
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| 50 | int j; |
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| 51 | /* ordinal number */ |
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| 52 | int x; |
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| 53 | /* value in the rounded solution (0 or 1) */ |
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| 54 | double d; |
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| 55 | /* sorting key */ |
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| 56 | }; |
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| 57 | |
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| 58 | static int fcmp(const void *x, const void *y) |
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| 59 | { /* comparison routine */ |
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| 60 | const struct VAR *vx = x, *vy = y; |
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| 61 | if (vx->d > vy->d) |
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| 62 | return -1; |
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| 63 | else if (vx->d < vy->d) |
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| 64 | return +1; |
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| 65 | else |
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| 66 | return 0; |
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| 67 | } |
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| 68 | |
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| 69 | void ios_feas_pump(glp_tree *T) |
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| 70 | { glp_prob *P = T->mip; |
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| 71 | int n = P->n; |
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| 72 | glp_prob *lp = NULL; |
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| 73 | struct VAR *var = NULL; |
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| 74 | RNG *rand = NULL; |
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| 75 | GLPCOL *col; |
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| 76 | glp_smcp parm; |
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| 77 | int j, k, new_x, nfail, npass, nv, ret, stalling; |
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| 78 | double dist, tol; |
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| 79 | xassert(glp_get_status(P) == GLP_OPT); |
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| 80 | /* this heuristic is applied only once on the root level */ |
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| 81 | if (!(T->curr->level == 0 && T->curr->solved == 1)) goto done; |
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| 82 | /* determine number of binary variables */ |
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| 83 | nv = 0; |
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| 84 | for (j = 1; j <= n; j++) |
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| 85 | { col = P->col[j]; |
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| 86 | /* if x[j] is continuous, skip it */ |
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| 87 | if (col->kind == GLP_CV) continue; |
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| 88 | /* if x[j] is fixed, skip it */ |
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| 89 | if (col->type == GLP_FX) continue; |
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| 90 | /* x[j] is non-fixed integer */ |
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| 91 | xassert(col->kind == GLP_IV); |
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| 92 | if (col->type == GLP_DB && col->lb == 0.0 && col->ub == 1.0) |
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| 93 | { /* x[j] is binary */ |
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| 94 | nv++; |
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| 95 | } |
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| 96 | else |
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| 97 | { /* x[j] is general integer */ |
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| 98 | if (T->parm->msg_lev >= GLP_MSG_ALL) |
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| 99 | xprintf("FPUMP heuristic cannot be applied due to genera" |
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| 100 | "l integer variables\n"); |
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| 101 | goto done; |
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| 102 | } |
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| 103 | } |
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| 104 | /* there must be at least one binary variable */ |
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| 105 | if (nv == 0) goto done; |
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| 106 | if (T->parm->msg_lev >= GLP_MSG_ALL) |
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| 107 | xprintf("Applying FPUMP heuristic...\n"); |
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| 108 | /* build the list of binary variables */ |
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| 109 | var = xcalloc(1+nv, sizeof(struct VAR)); |
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| 110 | k = 0; |
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| 111 | for (j = 1; j <= n; j++) |
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| 112 | { col = P->col[j]; |
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| 113 | if (col->kind == GLP_IV && col->type == GLP_DB) |
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| 114 | var[++k].j = j; |
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| 115 | } |
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| 116 | xassert(k == nv); |
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| 117 | /* create working problem object */ |
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| 118 | lp = glp_create_prob(); |
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| 119 | more: /* copy the original problem object to keep it intact */ |
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| 120 | glp_copy_prob(lp, P, GLP_OFF); |
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| 121 | /* we are interested to find an integer feasible solution, which |
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| 122 | is better than the best known one */ |
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| 123 | if (P->mip_stat == GLP_FEAS) |
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| 124 | { int *ind; |
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| 125 | double *val, bnd; |
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| 126 | /* add a row and make it identical to the objective row */ |
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| 127 | glp_add_rows(lp, 1); |
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| 128 | ind = xcalloc(1+n, sizeof(int)); |
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| 129 | val = xcalloc(1+n, sizeof(double)); |
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| 130 | for (j = 1; j <= n; j++) |
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| 131 | { ind[j] = j; |
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| 132 | val[j] = P->col[j]->coef; |
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| 133 | } |
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| 134 | glp_set_mat_row(lp, lp->m, n, ind, val); |
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| 135 | xfree(ind); |
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| 136 | xfree(val); |
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| 137 | /* introduce upper (minimization) or lower (maximization) |
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| 138 | bound to the original objective function; note that this |
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| 139 | additional constraint is not violated at the optimal point |
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| 140 | to LP relaxation */ |
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| 141 | #if 0 /* modified by xypron <xypron.glpk@gmx.de> */ |
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| 142 | if (P->dir == GLP_MIN) |
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| 143 | { bnd = P->mip_obj - 0.10 * (1.0 + fabs(P->mip_obj)); |
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| 144 | if (bnd < P->obj_val) bnd = P->obj_val; |
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| 145 | glp_set_row_bnds(lp, lp->m, GLP_UP, 0.0, bnd - P->c0); |
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| 146 | } |
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| 147 | else if (P->dir == GLP_MAX) |
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| 148 | { bnd = P->mip_obj + 0.10 * (1.0 + fabs(P->mip_obj)); |
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| 149 | if (bnd > P->obj_val) bnd = P->obj_val; |
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| 150 | glp_set_row_bnds(lp, lp->m, GLP_LO, bnd - P->c0, 0.0); |
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| 151 | } |
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| 152 | else |
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| 153 | xassert(P != P); |
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| 154 | #else |
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| 155 | bnd = 0.1 * P->obj_val + 0.9 * P->mip_obj; |
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| 156 | /* xprintf("bnd = %f\n", bnd); */ |
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| 157 | if (P->dir == GLP_MIN) |
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| 158 | glp_set_row_bnds(lp, lp->m, GLP_UP, 0.0, bnd - P->c0); |
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| 159 | else if (P->dir == GLP_MAX) |
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| 160 | glp_set_row_bnds(lp, lp->m, GLP_LO, bnd - P->c0, 0.0); |
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| 161 | else |
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| 162 | xassert(P != P); |
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| 163 | #endif |
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| 164 | } |
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| 165 | /* reset pass count */ |
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| 166 | npass = 0; |
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| 167 | /* invalidate the rounded point */ |
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| 168 | for (k = 1; k <= nv; k++) |
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| 169 | var[k].x = -1; |
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| 170 | pass: /* next pass starts here */ |
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| 171 | npass++; |
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| 172 | if (T->parm->msg_lev >= GLP_MSG_ALL) |
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| 173 | xprintf("Pass %d\n", npass); |
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| 174 | /* initialize minimal distance between the basic point and the |
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| 175 | rounded one obtained during this pass */ |
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| 176 | dist = DBL_MAX; |
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| 177 | /* reset failure count (the number of succeeded iterations failed |
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| 178 | to improve the distance) */ |
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| 179 | nfail = 0; |
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| 180 | /* if it is not the first pass, perturb the last rounded point |
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| 181 | rather than construct it from the basic solution */ |
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| 182 | if (npass > 1) |
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| 183 | { double rho, temp; |
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| 184 | if (rand == NULL) |
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| 185 | rand = rng_create_rand(); |
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| 186 | for (k = 1; k <= nv; k++) |
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| 187 | { j = var[k].j; |
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| 188 | col = lp->col[j]; |
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| 189 | rho = rng_uniform(rand, -0.3, 0.7); |
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| 190 | if (rho < 0.0) rho = 0.0; |
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| 191 | temp = fabs((double)var[k].x - col->prim); |
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| 192 | if (temp + rho > 0.5) var[k].x = 1 - var[k].x; |
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| 193 | } |
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| 194 | goto skip; |
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| 195 | } |
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| 196 | loop: /* innermost loop begins here */ |
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| 197 | /* round basic solution (which is assumed primal feasible) */ |
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| 198 | stalling = 1; |
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| 199 | for (k = 1; k <= nv; k++) |
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| 200 | { col = lp->col[var[k].j]; |
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| 201 | if (col->prim < 0.5) |
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| 202 | { /* rounded value is 0 */ |
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| 203 | new_x = 0; |
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| 204 | } |
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| 205 | else |
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| 206 | { /* rounded value is 1 */ |
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| 207 | new_x = 1; |
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| 208 | } |
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| 209 | if (var[k].x != new_x) |
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| 210 | { stalling = 0; |
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| 211 | var[k].x = new_x; |
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| 212 | } |
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| 213 | } |
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| 214 | /* if the rounded point has not changed (stalling), choose and |
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| 215 | flip some its entries heuristically */ |
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| 216 | if (stalling) |
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| 217 | { /* compute d[j] = |x[j] - round(x[j])| */ |
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| 218 | for (k = 1; k <= nv; k++) |
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| 219 | { col = lp->col[var[k].j]; |
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| 220 | var[k].d = fabs(col->prim - (double)var[k].x); |
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| 221 | } |
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| 222 | /* sort the list of binary variables by descending d[j] */ |
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| 223 | qsort(&var[1], nv, sizeof(struct VAR), fcmp); |
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| 224 | /* choose and flip some rounded components */ |
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| 225 | for (k = 1; k <= nv; k++) |
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| 226 | { if (k >= 5 && var[k].d < 0.35 || k >= 10) break; |
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| 227 | var[k].x = 1 - var[k].x; |
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| 228 | } |
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| 229 | } |
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| 230 | skip: /* check if the time limit has been exhausted */ |
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| 231 | if (T->parm->tm_lim < INT_MAX && |
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| 232 | (double)(T->parm->tm_lim - 1) <= |
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| 233 | 1000.0 * xdifftime(xtime(), T->tm_beg)) goto done; |
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| 234 | /* build the objective, which is the distance between the current |
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| 235 | (basic) point and the rounded one */ |
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| 236 | lp->dir = GLP_MIN; |
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| 237 | lp->c0 = 0.0; |
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| 238 | for (j = 1; j <= n; j++) |
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| 239 | lp->col[j]->coef = 0.0; |
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| 240 | for (k = 1; k <= nv; k++) |
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| 241 | { j = var[k].j; |
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| 242 | if (var[k].x == 0) |
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| 243 | lp->col[j]->coef = +1.0; |
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| 244 | else |
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| 245 | { lp->col[j]->coef = -1.0; |
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| 246 | lp->c0 += 1.0; |
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| 247 | } |
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| 248 | } |
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| 249 | /* minimize the distance with the simplex method */ |
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| 250 | glp_init_smcp(&parm); |
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| 251 | if (T->parm->msg_lev <= GLP_MSG_ERR) |
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| 252 | parm.msg_lev = T->parm->msg_lev; |
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| 253 | else if (T->parm->msg_lev <= GLP_MSG_ALL) |
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| 254 | { parm.msg_lev = GLP_MSG_ON; |
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| 255 | parm.out_dly = 10000; |
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| 256 | } |
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| 257 | ret = glp_simplex(lp, &parm); |
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| 258 | if (ret != 0) |
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| 259 | { if (T->parm->msg_lev >= GLP_MSG_ERR) |
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| 260 | xprintf("Warning: glp_simplex returned %d\n", ret); |
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| 261 | goto done; |
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| 262 | } |
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| 263 | ret = glp_get_status(lp); |
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| 264 | if (ret != GLP_OPT) |
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| 265 | { if (T->parm->msg_lev >= GLP_MSG_ERR) |
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| 266 | xprintf("Warning: glp_get_status returned %d\n", ret); |
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| 267 | goto done; |
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| 268 | } |
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| 269 | if (T->parm->msg_lev >= GLP_MSG_DBG) |
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| 270 | xprintf("delta = %g\n", lp->obj_val); |
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| 271 | /* check if the basic solution is integer feasible; note that it |
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| 272 | may be so even if the minimial distance is positive */ |
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| 273 | tol = 0.3 * T->parm->tol_int; |
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| 274 | for (k = 1; k <= nv; k++) |
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| 275 | { col = lp->col[var[k].j]; |
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| 276 | if (tol < col->prim && col->prim < 1.0 - tol) break; |
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| 277 | } |
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| 278 | if (k > nv) |
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| 279 | { /* okay; the basic solution seems to be integer feasible */ |
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| 280 | double *x = xcalloc(1+n, sizeof(double)); |
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| 281 | for (j = 1; j <= n; j++) |
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| 282 | { x[j] = lp->col[j]->prim; |
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| 283 | if (P->col[j]->kind == GLP_IV) x[j] = floor(x[j] + 0.5); |
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| 284 | } |
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| 285 | #if 1 /* modified by xypron <xypron.glpk@gmx.de> */ |
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| 286 | /* reset direction and right-hand side of objective */ |
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| 287 | lp->c0 = P->c0; |
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| 288 | lp->dir = P->dir; |
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| 289 | /* fix integer variables */ |
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| 290 | for (k = 1; k <= nv; k++) |
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| 291 | { lp->col[var[k].j]->lb = x[var[k].j]; |
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| 292 | lp->col[var[k].j]->ub = x[var[k].j]; |
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| 293 | lp->col[var[k].j]->type = GLP_FX; |
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| 294 | } |
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| 295 | /* copy original objective function */ |
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| 296 | for (j = 1; j <= n; j++) |
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| 297 | lp->col[j]->coef = P->col[j]->coef; |
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| 298 | /* solve original LP and copy result */ |
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| 299 | ret = glp_simplex(lp, &parm); |
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| 300 | if (ret != 0) |
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| 301 | { if (T->parm->msg_lev >= GLP_MSG_ERR) |
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| 302 | xprintf("Warning: glp_simplex returned %d\n", ret); |
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| 303 | goto done; |
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| 304 | } |
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| 305 | ret = glp_get_status(lp); |
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| 306 | if (ret != GLP_OPT) |
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| 307 | { if (T->parm->msg_lev >= GLP_MSG_ERR) |
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| 308 | xprintf("Warning: glp_get_status returned %d\n", ret); |
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| 309 | goto done; |
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| 310 | } |
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| 311 | for (j = 1; j <= n; j++) |
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| 312 | if (P->col[j]->kind != GLP_IV) x[j] = lp->col[j]->prim; |
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| 313 | #endif |
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| 314 | ret = glp_ios_heur_sol(T, x); |
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| 315 | xfree(x); |
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| 316 | if (ret == 0) |
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| 317 | { /* the integer solution is accepted */ |
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| 318 | if (ios_is_hopeful(T, T->curr->bound)) |
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| 319 | { /* it is reasonable to apply the heuristic once again */ |
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| 320 | goto more; |
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| 321 | } |
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| 322 | else |
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| 323 | { /* the best known integer feasible solution just found |
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| 324 | is close to optimal solution to LP relaxation */ |
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| 325 | goto done; |
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| 326 | } |
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| 327 | } |
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| 328 | } |
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| 329 | /* the basic solution is fractional */ |
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| 330 | if (dist == DBL_MAX || |
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| 331 | lp->obj_val <= dist - 1e-6 * (1.0 + dist)) |
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| 332 | { /* the distance is reducing */ |
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| 333 | nfail = 0, dist = lp->obj_val; |
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| 334 | } |
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| 335 | else |
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| 336 | { /* improving the distance failed */ |
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| 337 | nfail++; |
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| 338 | } |
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| 339 | if (nfail < 3) goto loop; |
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| 340 | if (npass < 5) goto pass; |
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| 341 | done: /* delete working objects */ |
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| 342 | if (lp != NULL) glp_delete_prob(lp); |
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| 343 | if (var != NULL) xfree(var); |
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| 344 | if (rand != NULL) rng_delete_rand(rand); |
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| 345 | return; |
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| 346 | } |
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| 347 | |
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| 348 | /* eof */ |
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