/* spxchuzc.c */ /*********************************************************************** * This code is part of GLPK (GNU Linear Programming Kit). * * Copyright (C) 2015 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 "env.h" #include "spxchuzc.h" /*********************************************************************** * spx_chuzc_sel - select eligible non-basic variables * * This routine selects eligible non-basic variables xN[j], whose * reduced costs d[j] have "wrong" sign, i.e. changing such xN[j] in * feasible direction improves (decreases) the objective function. * * Reduced costs of non-basic variables should be placed in the array * locations d[1], ..., d[n-m]. * * Non-basic variable xN[j] is considered eligible if: * * d[j] <= -eps[j] and xN[j] can increase * * d[j] >= +eps[j] and xN[j] can decrease * * for * * eps[j] = tol + tol1 * |cN[j]|, * * where cN[j] is the objective coefficient at xN[j], tol and tol1 are * specified tolerances. * * On exit the routine stores indices j of eligible non-basic variables * xN[j] to the array locations list[1], ..., list[num] and returns the * number of such variables 0 <= num <= n-m. (If the parameter list is * specified as NULL, no indices are stored.) */ int spx_chuzc_sel(SPXLP *lp, const double d[/*1+n-m*/], double tol, double tol1, int list[/*1+n-m*/]) { int m = lp->m; int n = lp->n; double *c = lp->c; double *l = lp->l; double *u = lp->u; int *head = lp->head; char *flag = lp->flag; int j, k, num; double ck, eps; num = 0; /* walk thru list of non-basic variables */ for (j = 1; j <= n-m; j++) { k = head[m+j]; /* x[k] = xN[j] */ if (l[k] == u[k]) { /* xN[j] is fixed variable; skip it */ continue; } /* determine absolute tolerance eps[j] */ ck = c[k]; eps = tol + tol1 * (ck >= 0.0 ? +ck : -ck); /* check if xN[j] is eligible */ if (d[j] <= -eps) { /* xN[j] should be able to increase */ if (flag[j]) { /* but its upper bound is active */ continue; } } else if (d[j] >= +eps) { /* xN[j] should be able to decrease */ if (!flag[j] && l[k] != -DBL_MAX) { /* but its lower bound is active */ continue; } } else /* -eps < d[j] < +eps */ { /* xN[j] does not affect the objective function within the * specified tolerance */ continue; } /* xN[j] is eligible non-basic variable */ num++; if (list != NULL) list[num] = j; } return num; } /*********************************************************************** * spx_chuzc_std - choose non-basic variable (Dantzig's rule) * * This routine chooses most eligible non-basic variable xN[q] * according to Dantzig's ("standard") rule: * * d[q] = max |d[j]|, * j in J * * where J <= {1, ..., n-m} is the set of indices of eligible non-basic * variables, d[j] is the reduced cost of non-basic variable xN[j] in * the current basis. * * Reduced costs of non-basic variables should be placed in the array * locations d[1], ..., d[n-m]. * * Indices of eligible non-basic variables j in J should be placed in * the array locations list[1], ..., list[num], where num = |J| > 0 is * the total number of such variables. * * On exit the routine returns q, the index of the non-basic variable * xN[q] chosen. */ int spx_chuzc_std(SPXLP *lp, const double d[/*1+n-m*/], int num, const int list[]) { int m = lp->m; int n = lp->n; int j, q, t; double abs_dj, abs_dq; xassert(0 < num && num <= n-m); q = 0, abs_dq = -1.0; for (t = 1; t <= num; t++) { j = list[t]; abs_dj = (d[j] >= 0.0 ? +d[j] : -d[j]); if (abs_dq < abs_dj) q = j, abs_dq = abs_dj; } xassert(q != 0); return q; } /*********************************************************************** * spx_alloc_se - allocate pricing data block * * This routine allocates the memory for arrays used in the pricing * data block. */ void spx_alloc_se(SPXLP *lp, SPXSE *se) { int m = lp->m; int n = lp->n; se->valid = 0; se->refsp = talloc(1+n, char); se->gamma = talloc(1+n-m, double); se->work = talloc(1+m, double); return; } /*********************************************************************** * spx_reset_refsp - reset reference space * * This routine resets (re-initializes) the reference space composing * it from variables which are non-basic in the current basis, and sets * all weights gamma[j] to 1. */ void spx_reset_refsp(SPXLP *lp, SPXSE *se) { int m = lp->m; int n = lp->n; int *head = lp->head; char *refsp = se->refsp; double *gamma = se->gamma; int j, k; se->valid = 1; memset(&refsp[1], 0, n * sizeof(char)); for (j = 1; j <= n-m; j++) { k = head[m+j]; /* x[k] = xN[j] */ refsp[k] = 1; gamma[j] = 1.0; } return; } /*********************************************************************** * spx_eval_gamma_j - compute projected steepest edge weight directly * * This routine computes projected steepest edge weight gamma[j], * 1 <= j <= n-m, for the current basis directly with the formula: * * m * gamma[j] = delta[j] + sum eta[i] * T[i,j]**2, * i=1 * * where T[i,j] is element of the current simplex table, and * * ( 1, if xB[i] is in the reference space * eta[i] = { * ( 0, otherwise * * ( 1, if xN[j] is in the reference space * delta[j] = { * ( 0, otherwise * * NOTE: For testing/debugging only. */ double spx_eval_gamma_j(SPXLP *lp, SPXSE *se, int j) { int m = lp->m; int n = lp->n; int *head = lp->head; char *refsp = se->refsp; double *tcol = se->work; int i, k; double gamma_j; xassert(se->valid); xassert(1 <= j && j <= n-m); k = head[m+j]; /* x[k] = xN[j] */ gamma_j = (refsp[k] ? 1.0 : 0.0); spx_eval_tcol(lp, j, tcol); for (i = 1; i <= m; i++) { k = head[i]; /* x[k] = xB[i] */ if (refsp[k]) gamma_j += tcol[i] * tcol[i]; } return gamma_j; } /*********************************************************************** * spx_chuzc_pse - choose non-basic variable (projected steepest edge) * * This routine chooses most eligible non-basic variable xN[q] * according to the projected steepest edge method: * * d[q]**2 d[j]**2 * -------- = max -------- , * gamma[q] j in J gamma[j] * * where J <= {1, ..., n-m} is the set of indices of eligible non-basic * variable, d[j] is the reduced cost of non-basic variable xN[j] in * the current basis, gamma[j] is the projected steepest edge weight. * * Reduced costs of non-basic variables should be placed in the array * locations d[1], ..., d[n-m]. * * Indices of eligible non-basic variables j in J should be placed in * the array locations list[1], ..., list[num], where num = |J| > 0 is * the total number of such variables. * * On exit the routine returns q, the index of the non-basic variable * xN[q] chosen. */ int spx_chuzc_pse(SPXLP *lp, SPXSE *se, const double d[/*1+n-m*/], int num, const int list[]) { int m = lp->m; int n = lp->n; double *gamma = se->gamma; int j, q, t; double best, temp; xassert(se->valid); xassert(0 < num && num <= n-m); q = 0, best = -1.0; for (t = 1; t <= num; t++) { j = list[t]; /* FIXME */ if (gamma[j] < DBL_EPSILON) temp = 0.0; else temp = (d[j] * d[j]) / gamma[j]; if (best < temp) q = j, best = temp; } xassert(q != 0); return q; } /*********************************************************************** * spx_update_gamma - update projected steepest edge weights exactly * * This routine updates the vector gamma = (gamma[j]) of projected * steepest edge weights exactly, for the adjacent basis. * * On entry to the routine the content of the se object should be valid * and should correspond to the current basis. * * The parameter 1 <= p <= m specifies basic variable xB[p] which * becomes non-basic variable xN[q] in the adjacent basis. * * The parameter 1 <= q <= n-m specified non-basic variable xN[q] which * becomes basic variable xB[p] in the adjacent basis. * * It is assumed that the array trow contains elements of p-th (pivot) * row T'[p] of the simplex table in locations trow[1], ..., trow[n-m]. * It is also assumed that the array tcol contains elements of q-th * (pivot) column T[q] of the simple table in locations tcol[1], ..., * tcol[m]. (These row and column should be computed for the current * basis.) * * For details about the formulae used see the program documentation. * * The routine also computes the relative error: * * e = |gamma[q] - gamma'[q]| / (1 + |gamma[q]|), * * where gamma'[q] is the weight for xN[q] on entry to the routine, * and returns e on exit. (If e happens to be large enough, the calling * program may reset the reference space, since other weights also may * be inaccurate.) */ double spx_update_gamma(SPXLP *lp, SPXSE *se, int p, int q, const double trow[/*1+n-m*/], const double tcol[/*1+m*/]) { int m = lp->m; int n = lp->n; int *head = lp->head; char *refsp = se->refsp; double *gamma = se->gamma; double *u = se->work; int i, j, k, ptr, end; double gamma_q, delta_q, e, r, s, t1, t2; xassert(se->valid); xassert(1 <= p && p <= m); xassert(1 <= q && q <= n-m); /* compute gamma[q] in current basis more accurately; also * compute auxiliary vector u */ k = head[m+q]; /* x[k] = xN[q] */ gamma_q = delta_q = (refsp[k] ? 1.0 : 0.0); for (i = 1; i <= m; i++) { k = head[i]; /* x[k] = xB[i] */ if (refsp[k]) { gamma_q += tcol[i] * tcol[i]; u[i] = tcol[i]; } else u[i] = 0.0; } bfd_btran(lp->bfd, u); /* compute relative error in gamma[q] */ e = fabs(gamma_q - gamma[q]) / (1.0 + gamma_q); /* compute new gamma[q] */ gamma[q] = gamma_q / (tcol[p] * tcol[p]); /* compute new gamma[j] for all j != q */ for (j = 1; j <= n-m; j++) { if (j == q) continue; if (-1e-9 < trow[j] && trow[j] < +1e-9) { /* T[p,j] is close to zero; gamma[j] is not changed */ continue; } /* compute r[j] = T[p,j] / T[p,q] */ r = trow[j] / tcol[p]; /* compute inner product s[j] = N'[j] * u, where N[j] = A[k] * is constraint matrix column corresponding to xN[j] */ s = 0.0; k = head[m+j]; /* x[k] = xN[j] */ ptr = lp->A_ptr[k]; end = lp->A_ptr[k+1]; for (; ptr < end; ptr++) s += lp->A_val[ptr] * u[lp->A_ind[ptr]]; /* compute new gamma[j] */ t1 = gamma[j] + r * (r * gamma_q + s + s); t2 = (refsp[k] ? 1.0 : 0.0) + delta_q * r * r; gamma[j] = (t1 >= t2 ? t1 : t2); } return e; } /*********************************************************************** * spx_free_se - deallocate pricing data block * * This routine deallocates the memory used for arrays in the pricing * data block. */ void spx_free_se(SPXLP *lp, SPXSE *se) { xassert(lp == lp); tfree(se->refsp); tfree(se->gamma); tfree(se->work); return; } /* eof */