1 /* glplux.h (LU-factorization, bignum arithmetic) */
3 /***********************************************************************
4 * This code is part of GLPK (GNU Linear Programming Kit).
6 * Copyright (C) 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008,
7 * 2009, 2010 Andrew Makhorin, Department for Applied Informatics,
8 * Moscow Aviation Institute, Moscow, Russia. All rights reserved.
9 * E-mail: <mao@gnu.org>.
11 * GLPK is free software: you can redistribute it and/or modify it
12 * under the terms of the GNU General Public License as published by
13 * the Free Software Foundation, either version 3 of the License, or
14 * (at your option) any later version.
16 * GLPK is distributed in the hope that it will be useful, but WITHOUT
17 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
18 * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
19 * License for more details.
21 * You should have received a copy of the GNU General Public License
22 * along with GLPK. If not, see <http://www.gnu.org/licenses/>.
23 ***********************************************************************/
31 /*----------------------------------------------------------------------
32 // The structure LUX defines LU-factorization of a square matrix A,
33 // which is the following quartet:
35 // [A] = (F, V, P, Q), (1)
37 // where F and V are such matrices that
41 // and P and Q are such permutation matrices that the matrix
43 // L = P * F * inv(P) (3)
45 // is lower triangular with unity diagonal, and the matrix
49 // is upper triangular. All the matrices have the order n.
51 // The matrices F and V are stored in row/column-wise sparse format as
52 // row and column linked lists of non-zero elements. Unity elements on
53 // the main diagonal of the matrix F are not stored. Pivot elements of
54 // the matrix V (that correspond to diagonal elements of the matrix U)
55 // are also missing from the row and column lists and stored separately
56 // in an ordinary array.
58 // The permutation matrices P and Q are stored as ordinary arrays using
59 // both row- and column-like formats.
61 // The matrices L and U being completely defined by the matrices F, V,
62 // P, and Q are not stored explicitly.
64 // It is easy to show that the factorization (1)-(3) is some version of
65 // LU-factorization. Indeed, from (3) and (4) it follows that:
67 // F = inv(P) * L * P,
69 // V = inv(P) * U * inv(Q),
71 // and substitution into (2) gives:
73 // A = F * V = inv(P) * L * U * inv(Q).
75 // For more details see the program documentation. */
77 typedef struct LUX LUX;
78 typedef struct LUXELM LUXELM;
79 typedef struct LUXWKA LUXWKA;
82 { /* LU-factorization of a square matrix */
84 /* the order of matrices A, F, V, P, Q */
86 /* memory pool for elements of matrices F and V */
87 LUXELM **F_row; /* LUXELM *F_row[1+n]; */
88 /* F_row[0] is not used;
89 F_row[i], 1 <= i <= n, is a pointer to the list of elements in
90 i-th row of matrix F (diagonal elements are not stored) */
91 LUXELM **F_col; /* LUXELM *F_col[1+n]; */
92 /* F_col[0] is not used;
93 F_col[j], 1 <= j <= n, is a pointer to the list of elements in
94 j-th column of matrix F (diagonal elements are not stored) */
95 mpq_t *V_piv; /* mpq_t V_piv[1+n]; */
96 /* V_piv[0] is not used;
97 V_piv[p], 1 <= p <= n, is a pivot element v[p,q] corresponding
98 to a diagonal element u[k,k] of matrix U = P*V*Q (used on k-th
99 elimination step, k = 1, 2, ..., n) */
100 LUXELM **V_row; /* LUXELM *V_row[1+n]; */
101 /* V_row[0] is not used;
102 V_row[i], 1 <= i <= n, is a pointer to the list of elements in
103 i-th row of matrix V (except pivot elements) */
104 LUXELM **V_col; /* LUXELM *V_col[1+n]; */
105 /* V_col[0] is not used;
106 V_col[j], 1 <= j <= n, is a pointer to the list of elements in
107 j-th column of matrix V (except pivot elements) */
108 int *P_row; /* int P_row[1+n]; */
109 /* P_row[0] is not used;
110 P_row[i] = j means that p[i,j] = 1, where p[i,j] is an element
111 of permutation matrix P */
112 int *P_col; /* int P_col[1+n]; */
113 /* P_col[0] is not used;
114 P_col[j] = i means that p[i,j] = 1, where p[i,j] is an element
115 of permutation matrix P */
116 /* if i-th row or column of matrix F is i'-th row or column of
117 matrix L = P*F*inv(P), or if i-th row of matrix V is i'-th row
118 of matrix U = P*V*Q, then P_row[i'] = i and P_col[i] = i' */
119 int *Q_row; /* int Q_row[1+n]; */
120 /* Q_row[0] is not used;
121 Q_row[i] = j means that q[i,j] = 1, where q[i,j] is an element
122 of permutation matrix Q */
123 int *Q_col; /* int Q_col[1+n]; */
124 /* Q_col[0] is not used;
125 Q_col[j] = i means that q[i,j] = 1, where q[i,j] is an element
126 of permutation matrix Q */
127 /* if j-th column of matrix V is j'-th column of matrix U = P*V*Q,
128 then Q_row[j] = j' and Q_col[j'] = j */
130 /* the (exact) rank of matrices A and V */
134 { /* element of matrix F or V */
136 /* row index, 1 <= i <= m */
138 /* column index, 1 <= j <= n */
140 /* numeric (non-zero) element value */
142 /* pointer to previous element in the same row */
144 /* pointer to next element in the same row */
146 /* pointer to previous element in the same column */
148 /* pointer to next element in the same column */
152 { /* working area (used only during factorization) */
153 /* in order to efficiently implement Markowitz strategy and Duff
154 search technique there are two families {R[0], R[1], ..., R[n]}
155 and {C[0], C[1], ..., C[n]}; member R[k] is a set of active
156 rows of matrix V having k non-zeros, and member C[k] is a set
157 of active columns of matrix V having k non-zeros (in the active
158 submatrix); each set R[k] and C[k] is implemented as a separate
159 doubly linked list */
160 int *R_len; /* int R_len[1+n]; */
161 /* R_len[0] is not used;
162 R_len[i], 1 <= i <= n, is the number of non-zero elements in
163 i-th row of matrix V (that is the length of i-th row) */
164 int *R_head; /* int R_head[1+n]; */
165 /* R_head[k], 0 <= k <= n, is the number of a first row, which is
166 active and whose length is k */
167 int *R_prev; /* int R_prev[1+n]; */
168 /* R_prev[0] is not used;
169 R_prev[i], 1 <= i <= n, is the number of a previous row, which
170 is active and has the same length as i-th row */
171 int *R_next; /* int R_next[1+n]; */
172 /* R_prev[0] is not used;
173 R_prev[i], 1 <= i <= n, is the number of a next row, which is
174 active and has the same length as i-th row */
175 int *C_len; /* int C_len[1+n]; */
176 /* C_len[0] is not used;
177 C_len[j], 1 <= j <= n, is the number of non-zero elements in
178 j-th column of the active submatrix of matrix V (that is the
179 length of j-th column in the active submatrix) */
180 int *C_head; /* int C_head[1+n]; */
181 /* C_head[k], 0 <= k <= n, is the number of a first column, which
182 is active and whose length is k */
183 int *C_prev; /* int C_prev[1+n]; */
184 /* C_prev[0] is not used;
185 C_prev[j], 1 <= j <= n, is the number of a previous column,
186 which is active and has the same length as j-th column */
187 int *C_next; /* int C_next[1+n]; */
188 /* C_next[0] is not used;
189 C_next[j], 1 <= j <= n, is the number of a next column, which
190 is active and has the same length as j-th column */
193 #define lux_create _glp_lux_create
194 #define lux_decomp _glp_lux_decomp
195 #define lux_f_solve _glp_lux_f_solve
196 #define lux_v_solve _glp_lux_v_solve
197 #define lux_solve _glp_lux_solve
198 #define lux_delete _glp_lux_delete
200 LUX *lux_create(int n);
201 /* create LU-factorization */
203 int lux_decomp(LUX *lux, int (*col)(void *info, int j, int ind[],
204 mpq_t val[]), void *info);
205 /* compute LU-factorization */
207 void lux_f_solve(LUX *lux, int tr, mpq_t x[]);
208 /* solve system F*x = b or F'*x = b */
210 void lux_v_solve(LUX *lux, int tr, mpq_t x[]);
211 /* solve system V*x = b or V'*x = b */
213 void lux_solve(LUX *lux, int tr, mpq_t x[]);
214 /* solve system A*x = b or A'*x = b */
216 void lux_delete(LUX *lux);
217 /* delete LU-factorization */