[1] | 1 | /* glpios11.c (process cuts stored in the local cut pool) */ |
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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 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 | |
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| 27 | /*********************************************************************** |
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| 28 | * NAME |
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| 29 | * |
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| 30 | * ios_process_cuts - process cuts stored in the local cut pool |
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| 31 | * |
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| 32 | * SYNOPSIS |
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| 33 | * |
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| 34 | * #include "glpios.h" |
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| 35 | * void ios_process_cuts(glp_tree *T); |
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| 36 | * |
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| 37 | * DESCRIPTION |
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| 38 | * |
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| 39 | * The routine ios_process_cuts analyzes each cut currently stored in |
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| 40 | * the local cut pool, which must be non-empty, and either adds the cut |
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| 41 | * to the current subproblem or just discards it. All cuts are assumed |
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| 42 | * to be locally valid. On exit the local cut pool remains unchanged. |
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| 43 | * |
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| 44 | * REFERENCES |
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| 45 | * |
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| 46 | * 1. E.Balas, S.Ceria, G.Cornuejols, "Mixed 0-1 Programming by |
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| 47 | * Lift-and-Project in a Branch-and-Cut Framework", Management Sc., |
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| 48 | * 42 (1996) 1229-1246. |
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| 49 | * |
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| 50 | * 2. G.Andreello, A.Caprara, and M.Fischetti, "Embedding Cuts in |
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| 51 | * a Branch&Cut Framework: a Computational Study with {0,1/2}-Cuts", |
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| 52 | * Preliminary Draft, October 28, 2003, pp.6-8. */ |
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| 53 | |
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| 54 | struct info |
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| 55 | { /* estimated cut efficiency */ |
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| 56 | IOSCUT *cut; |
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| 57 | /* pointer to cut in the cut pool */ |
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| 58 | char flag; |
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| 59 | /* if this flag is set, the cut is included into the current |
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| 60 | subproblem */ |
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| 61 | double eff; |
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| 62 | /* cut efficacy (normalized residual) */ |
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| 63 | double deg; |
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| 64 | /* lower bound to objective degradation */ |
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| 65 | }; |
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| 66 | |
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| 67 | static int fcmp(const void *arg1, const void *arg2) |
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| 68 | { const struct info *info1 = arg1, *info2 = arg2; |
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| 69 | if (info1->deg == 0.0 && info2->deg == 0.0) |
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| 70 | { if (info1->eff > info2->eff) return -1; |
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| 71 | if (info1->eff < info2->eff) return +1; |
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| 72 | } |
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| 73 | else |
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| 74 | { if (info1->deg > info2->deg) return -1; |
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| 75 | if (info1->deg < info2->deg) return +1; |
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| 76 | } |
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| 77 | return 0; |
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| 78 | } |
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| 79 | |
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| 80 | static double parallel(IOSCUT *a, IOSCUT *b, double work[]); |
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| 81 | |
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| 82 | void ios_process_cuts(glp_tree *T) |
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| 83 | { IOSPOOL *pool; |
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| 84 | IOSCUT *cut; |
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| 85 | IOSAIJ *aij; |
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| 86 | struct info *info; |
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| 87 | int k, kk, max_cuts, len, ret, *ind; |
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| 88 | double *val, *work; |
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| 89 | /* the current subproblem must exist */ |
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| 90 | xassert(T->curr != NULL); |
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| 91 | /* the pool must exist and be non-empty */ |
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| 92 | pool = T->local; |
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| 93 | xassert(pool != NULL); |
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| 94 | xassert(pool->size > 0); |
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| 95 | /* allocate working arrays */ |
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| 96 | info = xcalloc(1+pool->size, sizeof(struct info)); |
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| 97 | ind = xcalloc(1+T->n, sizeof(int)); |
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| 98 | val = xcalloc(1+T->n, sizeof(double)); |
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| 99 | work = xcalloc(1+T->n, sizeof(double)); |
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| 100 | for (k = 1; k <= T->n; k++) work[k] = 0.0; |
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| 101 | /* build the list of cuts stored in the cut pool */ |
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| 102 | for (k = 0, cut = pool->head; cut != NULL; cut = cut->next) |
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| 103 | k++, info[k].cut = cut, info[k].flag = 0; |
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| 104 | xassert(k == pool->size); |
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| 105 | /* estimate efficiency of all cuts in the cut pool */ |
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| 106 | for (k = 1; k <= pool->size; k++) |
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| 107 | { double temp, dy, dz; |
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| 108 | cut = info[k].cut; |
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| 109 | /* build the vector of cut coefficients and compute its |
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| 110 | Euclidean norm */ |
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| 111 | len = 0; temp = 0.0; |
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| 112 | for (aij = cut->ptr; aij != NULL; aij = aij->next) |
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| 113 | { xassert(1 <= aij->j && aij->j <= T->n); |
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| 114 | len++, ind[len] = aij->j, val[len] = aij->val; |
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| 115 | temp += aij->val * aij->val; |
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| 116 | } |
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| 117 | if (temp < DBL_EPSILON * DBL_EPSILON) temp = DBL_EPSILON; |
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| 118 | /* transform the cut to express it only through non-basic |
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| 119 | (auxiliary and structural) variables */ |
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| 120 | len = glp_transform_row(T->mip, len, ind, val); |
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| 121 | /* determine change in the cut value and in the objective |
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| 122 | value for the adjacent basis by simulating one step of the |
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| 123 | dual simplex */ |
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| 124 | ret = _glp_analyze_row(T->mip, len, ind, val, cut->type, |
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| 125 | cut->rhs, 1e-9, NULL, NULL, NULL, NULL, &dy, &dz); |
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| 126 | /* determine normalized residual and lower bound to objective |
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| 127 | degradation */ |
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| 128 | if (ret == 0) |
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| 129 | { info[k].eff = fabs(dy) / sqrt(temp); |
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| 130 | /* if some reduced costs violates (slightly) their zero |
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| 131 | bounds (i.e. have wrong signs) due to round-off errors, |
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| 132 | dz also may have wrong sign being close to zero */ |
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| 133 | if (T->mip->dir == GLP_MIN) |
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| 134 | { if (dz < 0.0) dz = 0.0; |
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| 135 | info[k].deg = + dz; |
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| 136 | } |
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| 137 | else /* GLP_MAX */ |
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| 138 | { if (dz > 0.0) dz = 0.0; |
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| 139 | info[k].deg = - dz; |
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| 140 | } |
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| 141 | } |
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| 142 | else if (ret == 1) |
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| 143 | { /* the constraint is not violated at the current point */ |
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| 144 | info[k].eff = info[k].deg = 0.0; |
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| 145 | } |
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| 146 | else if (ret == 2) |
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| 147 | { /* no dual feasible adjacent basis exists */ |
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| 148 | info[k].eff = 1.0; |
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| 149 | info[k].deg = DBL_MAX; |
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| 150 | } |
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| 151 | else |
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| 152 | xassert(ret != ret); |
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| 153 | /* if the degradation is too small, just ignore it */ |
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| 154 | if (info[k].deg < 0.01) info[k].deg = 0.0; |
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| 155 | } |
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| 156 | /* sort the list of cuts by decreasing objective degradation and |
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| 157 | then by decreasing efficacy */ |
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| 158 | qsort(&info[1], pool->size, sizeof(struct info), fcmp); |
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| 159 | /* only first (most efficient) max_cuts in the list are qualified |
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| 160 | as candidates to be added to the current subproblem */ |
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| 161 | max_cuts = (T->curr->level == 0 ? 90 : 10); |
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| 162 | if (max_cuts > pool->size) max_cuts = pool->size; |
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| 163 | /* add cuts to the current subproblem */ |
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| 164 | #if 0 |
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| 165 | xprintf("*** adding cuts ***\n"); |
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| 166 | #endif |
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| 167 | for (k = 1; k <= max_cuts; k++) |
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| 168 | { int i, len; |
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| 169 | /* if this cut seems to be inefficient, skip it */ |
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| 170 | if (info[k].deg < 0.01 && info[k].eff < 0.01) continue; |
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| 171 | /* if the angle between this cut and every other cut included |
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| 172 | in the current subproblem is small, skip this cut */ |
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| 173 | for (kk = 1; kk < k; kk++) |
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| 174 | { if (info[kk].flag) |
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| 175 | { if (parallel(info[k].cut, info[kk].cut, work) > 0.90) |
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| 176 | break; |
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| 177 | } |
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| 178 | } |
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| 179 | if (kk < k) continue; |
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| 180 | /* add this cut to the current subproblem */ |
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| 181 | #if 0 |
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| 182 | xprintf("eff = %g; deg = %g\n", info[k].eff, info[k].deg); |
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| 183 | #endif |
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| 184 | cut = info[k].cut, info[k].flag = 1; |
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| 185 | i = glp_add_rows(T->mip, 1); |
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| 186 | if (cut->name != NULL) |
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| 187 | glp_set_row_name(T->mip, i, cut->name); |
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| 188 | xassert(T->mip->row[i]->origin == GLP_RF_CUT); |
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| 189 | T->mip->row[i]->klass = cut->klass; |
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| 190 | len = 0; |
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| 191 | for (aij = cut->ptr; aij != NULL; aij = aij->next) |
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| 192 | len++, ind[len] = aij->j, val[len] = aij->val; |
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| 193 | glp_set_mat_row(T->mip, i, len, ind, val); |
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| 194 | xassert(cut->type == GLP_LO || cut->type == GLP_UP); |
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| 195 | glp_set_row_bnds(T->mip, i, cut->type, cut->rhs, cut->rhs); |
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| 196 | } |
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| 197 | /* free working arrays */ |
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| 198 | xfree(info); |
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| 199 | xfree(ind); |
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| 200 | xfree(val); |
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| 201 | xfree(work); |
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| 202 | return; |
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| 203 | } |
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| 204 | |
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| 205 | #if 0 |
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| 206 | /*********************************************************************** |
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| 207 | * Given a cut a * x >= b (<= b) the routine efficacy computes the cut |
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| 208 | * efficacy as follows: |
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| 209 | * |
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| 210 | * eff = d * (a * x~ - b) / ||a||, |
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| 211 | * |
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| 212 | * where d is -1 (in case of '>= b') or +1 (in case of '<= b'), x~ is |
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| 213 | * the vector of values of structural variables in optimal solution to |
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| 214 | * LP relaxation of the current subproblem, ||a|| is the Euclidean norm |
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| 215 | * of the vector of cut coefficients. |
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| 216 | * |
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| 217 | * If the cut is violated at point x~, the efficacy eff is positive, |
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| 218 | * and its value is the Euclidean distance between x~ and the cut plane |
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| 219 | * a * x = b in the space of structural variables. |
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| 220 | * |
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| 221 | * Following geometrical intuition, it is quite natural to consider |
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| 222 | * this distance as a first-order measure of the expected efficacy of |
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| 223 | * the cut: the larger the distance the better the cut [1]. */ |
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| 224 | |
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| 225 | static double efficacy(glp_tree *T, IOSCUT *cut) |
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| 226 | { glp_prob *mip = T->mip; |
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| 227 | IOSAIJ *aij; |
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| 228 | double s = 0.0, t = 0.0, temp; |
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| 229 | for (aij = cut->ptr; aij != NULL; aij = aij->next) |
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| 230 | { xassert(1 <= aij->j && aij->j <= mip->n); |
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| 231 | s += aij->val * mip->col[aij->j]->prim; |
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| 232 | t += aij->val * aij->val; |
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| 233 | } |
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| 234 | temp = sqrt(t); |
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| 235 | if (temp < DBL_EPSILON) temp = DBL_EPSILON; |
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| 236 | if (cut->type == GLP_LO) |
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| 237 | temp = (s >= cut->rhs ? 0.0 : (cut->rhs - s) / temp); |
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| 238 | else if (cut->type == GLP_UP) |
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| 239 | temp = (s <= cut->rhs ? 0.0 : (s - cut->rhs) / temp); |
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| 240 | else |
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| 241 | xassert(cut != cut); |
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| 242 | return temp; |
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| 243 | } |
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| 244 | #endif |
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| 245 | |
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| 246 | /*********************************************************************** |
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| 247 | * Given two cuts a1 * x >= b1 (<= b1) and a2 * x >= b2 (<= b2) the |
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| 248 | * routine parallel computes the cosine of angle between the cut planes |
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| 249 | * a1 * x = b1 and a2 * x = b2 (which is the acute angle between two |
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| 250 | * normals to these planes) in the space of structural variables as |
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| 251 | * follows: |
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| 252 | * |
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| 253 | * cos phi = (a1' * a2) / (||a1|| * ||a2||), |
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| 254 | * |
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| 255 | * where (a1' * a2) is a dot product of vectors of cut coefficients, |
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| 256 | * ||a1|| and ||a2|| are Euclidean norms of vectors a1 and a2. |
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| 257 | * |
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| 258 | * Note that requirement cos phi = 0 forces the cuts to be orthogonal, |
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| 259 | * i.e. with disjoint support, while requirement cos phi <= 0.999 means |
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| 260 | * only avoiding duplicate (parallel) cuts [1]. */ |
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| 261 | |
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| 262 | static double parallel(IOSCUT *a, IOSCUT *b, double work[]) |
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| 263 | { IOSAIJ *aij; |
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| 264 | double s = 0.0, sa = 0.0, sb = 0.0, temp; |
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| 265 | for (aij = a->ptr; aij != NULL; aij = aij->next) |
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| 266 | { work[aij->j] = aij->val; |
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| 267 | sa += aij->val * aij->val; |
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| 268 | } |
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| 269 | for (aij = b->ptr; aij != NULL; aij = aij->next) |
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| 270 | { s += work[aij->j] * aij->val; |
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| 271 | sb += aij->val * aij->val; |
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| 272 | } |
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| 273 | for (aij = a->ptr; aij != NULL; aij = aij->next) |
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| 274 | work[aij->j] = 0.0; |
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| 275 | temp = sqrt(sa) * sqrt(sb); |
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| 276 | if (temp < DBL_EPSILON * DBL_EPSILON) temp = DBL_EPSILON; |
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| 277 | return s / temp; |
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| 278 | } |
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| 279 | |
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| 280 | /* eof */ |
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