Scippy

SCIP

Solving Constraint Integer Programs

presol_dualagg.c
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1/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
2/* */
3/* This file is part of the program and library */
4/* SCIP --- Solving Constraint Integer Programs */
5/* */
6/* Copyright (c) 2002-2024 Zuse Institute Berlin (ZIB) */
7/* */
8/* Licensed under the Apache License, Version 2.0 (the "License"); */
9/* you may not use this file except in compliance with the License. */
10/* You may obtain a copy of the License at */
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23/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
24
25/**@file presol_dualagg.c
26 * @ingroup DEFPLUGINS_PRESOL
27 * @brief aggregate variables by dual arguments
28 * @author Dieter Weninger
29 *
30 * This presolver looks for variables which could not be handled by
31 * duality fixing because of one up-/downlock.
32 * If the constraint which delivers the up-/downlock has
33 * a specific structure, we can aggregate the corresponding variable.
34 *
35 * In more detail (for a minimization problem and the case of only one uplock):
36 *
37 * Given a variable \f$x_i\f$ with \f$c_i \leq 0\f$ and only one up lock (originating from a constraint c),
38 * we are looking for a binary variable \f$x_j\f$ such that:
39 * 1. if \f$x_j = 0\f$, constraint c can only be fulfilled for \f$x_i = lb_i\f$, and
40 * 2. if \f$x_j = 1\f$, constraint c becomes redundant and \f$x_i\f$ can be dual-fixed to its upper bound \f$ub_i\f$
41 * (or vice versa). Then we can perform the following aggregation: \f$x_i = lb_i + x_j (ub_i - lb_i)\f$.
42 *
43 * Similar arguments apply for the case of only one down lock and \f$c_i \geq 0\f$.
44 */
45
46/*---+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8----+----9----+----0----+----1----+----2*/
47
49#include "scip/presol_dualagg.h"
50#include "scip/pub_matrix.h"
51#include "scip/pub_message.h"
52#include "scip/pub_var.h"
53#include "scip/scip_general.h"
54#include "scip/scip_mem.h"
55#include "scip/scip_message.h"
56#include "scip/scip_nlp.h"
57#include "scip/scip_numerics.h"
58#include "scip/scip_presol.h"
59#include "scip/scip_pricer.h"
60#include "scip/scip_prob.h"
61#include "scip/scip_probing.h"
62#include "scip/scip_var.h"
63
64#define PRESOL_NAME "dualagg"
65#define PRESOL_DESC "aggregate variables by dual arguments"
66#define PRESOL_PRIORITY -12000 /**< priority of the presolver (>= 0: before, < 0: after constraint handlers) */
67#define PRESOL_MAXROUNDS 0 /**< maximal number of presolving rounds the presolver participates in (-1: no limit) */
68#define PRESOL_TIMING SCIP_PRESOLTIMING_EXHAUSTIVE /* timing of the presolver (fast, medium, or exhaustive) */
69
70/** type of aggregation */
72{
73 BIN0UBOUND = -1, /**< x_j = u_j + (l_j-u_j)x_i with x_i binary and x_j aggregation variable */
74 NOAGG = 0, /**< do not aggregate */
75 BIN0LBOUND = 1 /**< x_j = l_j + (u_j-l_j)x_i with x_i binary and x_j aggregation variable */
76};
77typedef enum AggrType AGGRTYPE;
78
79/*
80 * Local methods
81 */
82
83/** find row which leads to the uplock of the given variable */
84static
86 SCIP_MATRIX* matrix, /**< constraint matrix */
87 int aggvaridx, /**< index of variable which should be aggregated */
88 int* rowidx, /**< pointer to store row index of uplock */
89 SCIP_Real* coef /**< pointer to store coefficient of variable */
90 )
91{
92 int* colpnt;
93 int* colend;
94 SCIP_Real* valpnt;
95
96 assert(rowidx != NULL);
97 assert(coef != NULL);
98 assert(SCIPmatrixGetColNUplocks(matrix, aggvaridx) == 1);
99
100 /* get nonzero entries of the variable in the matrix */
101 colpnt = SCIPmatrixGetColIdxPtr(matrix, aggvaridx);
102 colend = colpnt + SCIPmatrixGetColNNonzs(matrix, aggvaridx);
103 valpnt = SCIPmatrixGetColValPtr(matrix, aggvaridx);
104
105 /* iterate over all non-zero coefficients of the column */
106 *rowidx = -1;
107 for(; (colpnt < colend); colpnt++, valpnt++)
108 {
109 /* currently we support only >= relation */
110 if( !SCIPmatrixIsRowRhsInfinity(matrix, *colpnt) )
111 break;
112
113 /* coef < 0 for >= relation: this row provides an uplock for the variable */
114 if( *valpnt < 0.0 )
115 {
116 *rowidx = *colpnt;
117 *coef = *valpnt;
118 break;
119 }
120 }
121#ifndef NDEBUG
122 /* in debug mode, we check that the lock number is correct */
123 assert(colpnt < colend);
124 for(colpnt++, valpnt++; (colpnt < colend); colpnt++, valpnt++)
125 {
126 assert(*valpnt > 0.0);
127 }
128#endif
129}
130
131/** find row which leads to the downlock of the given variable */
132static
134 SCIP_MATRIX* matrix, /**< constraint matrix */
135 int aggvaridx, /**< index of variable which should be aggregated */
136 int* rowidx, /**< pointer to store row index of downlock */
137 SCIP_Real* coef /**< pointer to store coefficient of variable */
138 )
139{
140 int* colpnt;
141 int* colend;
142 SCIP_Real* valpnt;
143
144 assert(rowidx != NULL);
145 assert(coef != NULL);
146 assert(SCIPmatrixGetColNDownlocks(matrix, aggvaridx) == 1);
147
148 /* get nonzero entries of the variable in the matrix */
149 colpnt = SCIPmatrixGetColIdxPtr(matrix, aggvaridx);
150 colend = colpnt + SCIPmatrixGetColNNonzs(matrix, aggvaridx);
151 valpnt = SCIPmatrixGetColValPtr(matrix, aggvaridx);
152
153 /* iterate over all non-zero coefficients of the column */
154 *rowidx = -1;
155 for(; (colpnt < colend); colpnt++, valpnt++)
156 {
157 /* currently we support only >= relation */
158 if( !SCIPmatrixIsRowRhsInfinity(matrix, *colpnt) )
159 break;
160
161 /* coef > 0 for >= relation: this row provides a downlock for the variable */
162 if( *valpnt > 0.0 )
163 {
164 *rowidx = *colpnt;
165 *coef = *valpnt;
166 break;
167 }
168 }
169#ifndef NDEBUG
170 /* in debug mode, we check that the lock number is correct */
171 assert(colpnt < colend);
172 for(colpnt++, valpnt++; (colpnt < colend); colpnt++, valpnt++)
173 {
174 assert(*valpnt < 0.0);
175 }
176#endif
177}
178
179/** find fitting binary variable aggregation for uplock case */
180static
182 SCIP* scip, /**< SCIP main data structure */
183 SCIP_MATRIX* matrix, /**< constraint matrix */
184 int aggvaridx, /**< index of variable which should be aggregated */
185 int* binvaridx, /**< pointer to store index of binary variable */
186 AGGRTYPE* aggtype /**< pointer to store type of aggregation */
187 )
188{
189 int rowidx;
190 SCIP_Real coef;
191 int* rowpnt;
192 int* rowend;
193 SCIP_Real* valpnt;
194 SCIP_Real minact;
195 SCIP_Real maxact;
196 SCIP_Real lhs;
197 SCIP_Real lb;
198
199 assert(binvaridx != NULL);
200 assert(aggtype != NULL);
201
202 *binvaridx = -1;
203 *aggtype = NOAGG;
204
205 getUplockRowIdx(matrix, aggvaridx, &rowidx, &coef);
206
207 if( rowidx < 0 )
208 return;
209
210 assert(coef < 0);
211 minact = SCIPmatrixGetRowMinActivity(matrix, rowidx);
212 maxact = SCIPmatrixGetRowMaxActivity(matrix, rowidx);
213
214 if( SCIPisInfinity(scip, -minact) || SCIPisInfinity(scip, maxact) )
215 return;
216
217 lhs = SCIPmatrixGetRowLhs(matrix, rowidx);
218 lb = SCIPmatrixGetColLb(matrix, aggvaridx);
219
220 /* search for appropriate binary variables */
221 rowpnt = SCIPmatrixGetRowIdxPtr(matrix, rowidx);
222 rowend = rowpnt + SCIPmatrixGetRowNNonzs(matrix, rowidx);
223 valpnt = SCIPmatrixGetRowValPtr(matrix, rowidx);
224 for( ; (rowpnt < rowend); rowpnt++, valpnt++ )
225 {
226 SCIP_VAR* var;
227
228 if( *rowpnt == aggvaridx )
229 continue;
230
231 var = SCIPmatrixGetVar(matrix, *rowpnt);
232
233 /* avoid cases where the binary variable has lb=ub=1 or lb=ub=0 */
235 SCIPmatrixGetColLb(matrix, *rowpnt) < 0.5 &&
236 SCIPmatrixGetColUb(matrix, *rowpnt) > 0.5 )
237 {
238 SCIP_Real bincoef;
239 bincoef = *valpnt;
240
241 if( bincoef < 0 )
242 {
243 /* binvar = 0 implies that the constraint is redundant */
244 if( SCIPisGE(scip, minact-bincoef, lhs) )
245 {
246 /* binvar = 1 implies that aggvar = lb */
247 SCIP_Real bnd;
248 bnd = (lhs - maxact + coef*lb - bincoef) / coef;
249 if( SCIPisGE(scip, lb, bnd) )
250 {
251 *binvaridx = *rowpnt;
252 *aggtype = BIN0UBOUND;
253 break;
254 }
255 }
256 }
257
258 if( bincoef > 0 )
259 {
260 /* binvar = 1 implies that the constraint is redundant */
261 if( SCIPisGE(scip, minact+bincoef, lhs) )
262 {
263 /* binvar = 0 implies that aggvar = lb */
264 SCIP_Real bnd;
265 bnd = (lhs - maxact + coef*lb + bincoef) / coef;
266 if( SCIPisGE(scip, lb, bnd) )
267 {
268 *binvaridx = *rowpnt;
269 *aggtype = BIN0LBOUND;
270 }
271 }
272 }
273 }
274 }
275}
276
277/** find fitting binary variable aggregation for downlock case */
278static
280 SCIP* scip, /**< SCIP main data structure */
281 SCIP_MATRIX* matrix, /**< constraint matrix */
282 int aggvaridx, /**< index of variable which should be aggregated */
283 int* binvaridx, /**< pointer to store index of binary variable */
284 AGGRTYPE* aggtype /**< pointer to store type of aggregation */
285 )
286{
287 int rowidx;
288 SCIP_Real coef;
289 int* rowpnt;
290 int* rowend;
291 SCIP_Real* valpnt;
292 SCIP_Real minact;
293 SCIP_Real maxact;
294 SCIP_Real lhs;
295 SCIP_Real ub;
296
297 assert(binvaridx != NULL);
298 assert(aggtype != NULL);
299
300 *binvaridx = -1;
301 *aggtype = NOAGG;
302
303 getDownlockRowIdx(matrix, aggvaridx, &rowidx, &coef);
304
305 if( rowidx < 0 )
306 return;
307
308 assert(coef > 0);
309 minact = SCIPmatrixGetRowMinActivity(matrix, rowidx);
310 maxact = SCIPmatrixGetRowMaxActivity(matrix, rowidx);
311
312 if( SCIPisInfinity(scip, -minact) || SCIPisInfinity(scip, maxact) )
313 return;
314
315 lhs = SCIPmatrixGetRowLhs(matrix, rowidx);
316 ub = SCIPmatrixGetColUb(matrix, aggvaridx);
317
318 /* search for appropriate binary variables */
319 rowpnt = SCIPmatrixGetRowIdxPtr(matrix, rowidx);
320 rowend = rowpnt + SCIPmatrixGetRowNNonzs(matrix, rowidx);
321 valpnt = SCIPmatrixGetRowValPtr(matrix, rowidx);
322 for( ; (rowpnt < rowend); rowpnt++, valpnt++ )
323 {
324 SCIP_VAR* var;
325
326 if( *rowpnt == aggvaridx )
327 continue;
328
329 var = SCIPmatrixGetVar(matrix, *rowpnt);
330
331 /* avoid cases where the binary variable has lb=ub=1 or lb=ub=0 */
333 SCIPmatrixGetColLb(matrix, *rowpnt) < 0.5 &&
334 SCIPmatrixGetColUb(matrix, *rowpnt) > 0.5 )
335 {
336 SCIP_Real bincoef;
337
338 bincoef = *valpnt;
339
340 if( bincoef < 0 )
341 {
342 /* binvar = 0 implies that the constraint is redundant */
343 if( SCIPisGE(scip, minact-bincoef, lhs) )
344 {
345 /* binvar = 1 implies that aggvar = ub */
346 SCIP_Real bnd;
347 bnd = (lhs - maxact + coef*ub - bincoef) / coef;
348 if( SCIPisGE(scip, bnd, ub) )
349 {
350 *binvaridx = *rowpnt;
351 *aggtype = BIN0LBOUND;
352 break;
353 }
354 }
355 }
356
357 if( bincoef > 0 )
358 {
359 /* binvar = 1 implies that the constraint is redundant */
360 if( SCIPisGE(scip, minact+bincoef, lhs) )
361 {
362 /* binvar = 0 implies that aggvar = ub */
363 SCIP_Real bnd;
364 bnd = (lhs - maxact + coef*ub + bincoef) / coef;
365 if( SCIPisGE(scip, bnd, ub) )
366 {
367 *binvaridx = *rowpnt;
368 *aggtype = BIN0UBOUND;
369 break;
370 }
371 }
372 }
373 }
374 }
375}
376
377/** find variable aggregations for uplock case */
378static
380 SCIP* scip, /**< SCIP main data structure */
381 SCIP_MATRIX* matrix, /**< constraint matrix */
382 int* nvaragg, /**< number of redundant variables */
383 AGGRTYPE* aggtypes, /**< type of aggregations (in same order as variables in matrix) */
384 SCIP_VAR** binvars /**< pointers to the binary variables (in same order as variables in matrix) */
385 )
386{
387 int nvars;
388 int i;
389
390 assert(scip != NULL);
391 assert(matrix != NULL);
392 assert(nvaragg != NULL);
393 assert(aggtypes != NULL);
394 assert(binvars != NULL);
395
396 nvars = SCIPmatrixGetNColumns(matrix);
397
398 for( i = 0; i < nvars; i++ )
399 {
400 /* column has only one uplock which keeps it from being fixed by duality fixing */
401 if( SCIPmatrixGetColNUplocks(matrix, i) == 1 &&
402 SCIPisLE(scip, SCIPvarGetObj(SCIPmatrixGetVar(matrix, i)), 0.0) )
403 {
404 SCIP_Real lb;
405 SCIP_Real ub;
406
407 lb = SCIPmatrixGetColLb(matrix, i);
408 ub = SCIPmatrixGetColUb(matrix, i);
409 assert(lb == SCIPvarGetLbGlobal(SCIPmatrixGetVar(matrix, i))); /*lint !e777*/
410 assert(ub == SCIPvarGetUbGlobal(SCIPmatrixGetVar(matrix, i))); /*lint !e777*/
411
412 /* the variable needs to have finite bounds to allow an agregation */
413 if( !SCIPisInfinity(scip, -lb) && !SCIPisInfinity(scip, ub) )
414 {
415 int binvaridx;
416 AGGRTYPE aggtype;
417
418 getBinVarIdxInUplockRow(scip, matrix, i, &binvaridx, &aggtype);
419
420 if( binvaridx >= 0 )
421 {
422 aggtypes[i] = aggtype;
423 binvars[i] = SCIPmatrixGetVar(matrix, binvaridx);
424 (*nvaragg)++;
425 }
426 }
427 }
428 }
429
430 return SCIP_OKAY;
431}
432
433/** find variable aggregations for downlock case */
434static
436 SCIP* scip, /**< SCIP main data structure */
437 SCIP_MATRIX* matrix, /**< constraint matrix */
438 int* nvaragg, /**< number of redundant variables */
439 AGGRTYPE* aggtypes, /**< type of aggregations (in same order as variables in matrix) */
440 SCIP_VAR** binvars /**< pointers to the binary variables (in same order as variables in matrix) */
441 )
442{
443 int nvars;
444 int i;
445
446 assert(scip != NULL);
447 assert(matrix != NULL);
448 assert(nvaragg != NULL);
449 assert(aggtypes != NULL);
450 assert(binvars != NULL);
451
452 nvars = SCIPmatrixGetNColumns(matrix);
453
454 for( i = 0; i < nvars; i++ )
455 {
456 /* column has only one downlock which keeps it from being fixed by duality fixing;
457 * only handle variable if it was not yet aggregated due to a single uplock
458 */
459 if( SCIPmatrixGetColNDownlocks(matrix, i) == 1 &&
460 SCIPisGE(scip, SCIPvarGetObj(SCIPmatrixGetVar(matrix, i)), 0.0) &&
461 aggtypes[i] == NOAGG )
462 {
463 SCIP_Real lb;
464 SCIP_Real ub;
465
466 lb = SCIPmatrixGetColLb(matrix, i);
467 ub = SCIPmatrixGetColUb(matrix, i);
468 assert(lb == SCIPvarGetLbGlobal(SCIPmatrixGetVar(matrix, i))); /*lint !e777*/
469 assert(ub == SCIPvarGetUbGlobal(SCIPmatrixGetVar(matrix, i))); /*lint !e777*/
470
471 /* the variable needs to have finite bounds to allow an agregation */
472 if( !SCIPisInfinity(scip, -lb) && !SCIPisInfinity(scip, ub) )
473 {
474 int binvaridx;
475 AGGRTYPE aggtype;
476 getBinVarIdxInDownlockRow(scip, matrix, i, &binvaridx, &aggtype);
477
478 if( binvaridx >= 0 )
479 {
480 aggtypes[i] = aggtype;
481 binvars[i] = SCIPmatrixGetVar(matrix, binvaridx);
482 (*nvaragg)++;
483 }
484 }
485 }
486 }
487
488 return SCIP_OKAY;
489}
490
491/*
492 * Callback methods of presolver
493 */
494
495
496/** execution method of presolver */
497static
498SCIP_DECL_PRESOLEXEC(presolExecDualagg)
499{ /*lint --e{715}*/
500 SCIP_MATRIX* matrix;
501 SCIP_Bool initialized;
502 SCIP_Bool complete;
503 SCIP_Bool infeasible;
504
505 assert(result != NULL);
506 *result = SCIP_DIDNOTRUN;
507
509 return SCIP_OKAY;
510
512 return SCIP_OKAY;
513
514 if( SCIPgetNBinVars(scip) == 0 )
515 return SCIP_OKAY;
516
518 return SCIP_OKAY;
519
520 *result = SCIP_DIDNOTFIND;
521
522 matrix = NULL;
523
524 SCIP_CALL( SCIPmatrixCreate(scip, &matrix, TRUE, &initialized, &complete, &infeasible,
525 naddconss, ndelconss, nchgcoefs, nchgbds, nfixedvars) );
526
527 /* if infeasibility was detected during matrix creation, return here */
528 if( infeasible )
529 {
530 if( initialized )
531 SCIPmatrixFree(scip, &matrix);
532
533 *result = SCIP_CUTOFF;
534 return SCIP_OKAY;
535 }
536
537 /* we only work on pure MIPs currently */
538 if( initialized && complete )
539 {
540 AGGRTYPE* aggtypes;
541 SCIP_VAR** binvars;
542 int nvaragg;
543 int ncols;
544
545 ncols = SCIPmatrixGetNColumns(matrix);
546 nvaragg = 0;
547
548 SCIP_CALL( SCIPallocBufferArray(scip, &aggtypes, ncols) );
549 BMSclearMemoryArray(aggtypes, ncols);
550
551 SCIP_CALL( SCIPallocBufferArray(scip, &binvars, ncols) );
552 SCIPdebug( BMSclearMemoryArray(binvars, ncols) );
553
554 /* search for aggregations */
555 SCIP_CALL( findUplockAggregations(scip, matrix, &nvaragg, aggtypes, binvars) );
556 SCIP_CALL( findDownlockAggregations(scip, matrix, &nvaragg, aggtypes, binvars) );
557
558 /* apply aggregations, if we found any */
559 if( nvaragg > 0 )
560 {
561 int v;
562
563 for( v = 0; v < ncols; v++ )
564 {
565 if( aggtypes[v] != NOAGG )
566 {
567 SCIP_Bool redundant;
568 SCIP_Bool aggregated;
569 SCIP_Real ub;
570 SCIP_Real lb;
571
572 ub = SCIPmatrixGetColUb(matrix, v);
573 lb = SCIPmatrixGetColLb(matrix, v);
574
575 /* aggregate variable */
576 assert(binvars[v] != NULL);
577 if( aggtypes[v] == BIN0UBOUND )
578 {
579 SCIP_CALL( SCIPaggregateVars(scip, SCIPmatrixGetVar(matrix, v), binvars[v], 1.0, ub-lb,
580 ub, &infeasible, &redundant, &aggregated) );
581 }
582 else
583 {
584 assert(aggtypes[v] == BIN0LBOUND);
585 SCIP_CALL( SCIPaggregateVars(scip, SCIPmatrixGetVar(matrix, v), binvars[v], 1.0, lb-ub,
586 lb, &infeasible, &redundant, &aggregated) );
587 }
588
589 /* infeasible aggregation */
590 if( infeasible )
591 {
592 SCIPdebugMsg(scip, " -> infeasible aggregation\n");
593 *result = SCIP_CUTOFF;
594 return SCIP_OKAY;
595 }
596
597 if( aggregated )
598 (*naggrvars)++;
599 }
600 }
601
602 /* set result pointer */
603 if( (*naggrvars) > 0 )
604 *result = SCIP_SUCCESS;
605 }
606
607 SCIPfreeBufferArray(scip, &binvars);
608 SCIPfreeBufferArray(scip, &aggtypes);
609 }
610
611 SCIPmatrixFree(scip, &matrix);
612
613 return SCIP_OKAY;
614}
615
616/*
617 * presolver specific interface methods
618 */
619
620/** creates the dualagg presolver and includes it in SCIP */
622 SCIP* scip /**< SCIP data structure */
623 )
624{
625 SCIP_PRESOL* presol;
626
627 /* include presolver */
629 PRESOL_TIMING, presolExecDualagg, NULL) );
630
631 return SCIP_OKAY;
632}
#define NULL
Definition: def.h:266
#define SCIP_Bool
Definition: def.h:91
#define SCIP_Real
Definition: def.h:172
#define TRUE
Definition: def.h:93
#define SCIP_CALL(x)
Definition: def.h:373
SCIP_Bool SCIPisStopped(SCIP *scip)
Definition: scip_general.c:734
SCIP_STAGE SCIPgetStage(SCIP *scip)
Definition: scip_general.c:390
int SCIPgetNBinVars(SCIP *scip)
Definition: scip_prob.c:2037
#define SCIPdebugMsg
Definition: scip_message.h:78
SCIP_RETCODE SCIPincludePresolDualagg(SCIP *scip)
#define SCIPallocBufferArray(scip, ptr, num)
Definition: scip_mem.h:124
#define SCIPfreeBufferArray(scip, ptr)
Definition: scip_mem.h:136
SCIP_Bool SCIPisNLPEnabled(SCIP *scip)
Definition: scip_nlp.c:74
SCIP_RETCODE SCIPincludePresolBasic(SCIP *scip, SCIP_PRESOL **presolptr, const char *name, const char *desc, int priority, int maxrounds, SCIP_PRESOLTIMING timing, SCIP_DECL_PRESOLEXEC((*presolexec)), SCIP_PRESOLDATA *presoldata)
Definition: scip_presol.c:105
int SCIPgetNActivePricers(SCIP *scip)
Definition: scip_pricer.c:348
SCIP_Bool SCIPinProbing(SCIP *scip)
Definition: scip_probing.c:97
SCIP_Bool SCIPisGE(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
SCIP_Bool SCIPisLE(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
SCIP_Bool SCIPisInfinity(SCIP *scip, SCIP_Real val)
SCIP_RETCODE SCIPaggregateVars(SCIP *scip, SCIP_VAR *varx, SCIP_VAR *vary, SCIP_Real scalarx, SCIP_Real scalary, SCIP_Real rhs, SCIP_Bool *infeasible, SCIP_Bool *redundant, SCIP_Bool *aggregated)
Definition: scip_var.c:8524
SCIP_Real SCIPvarGetObj(SCIP_VAR *var)
Definition: var.c:17925
SCIP_VARTYPE SCIPvarGetType(SCIP_VAR *var)
Definition: var.c:17583
SCIP_Real SCIPvarGetUbGlobal(SCIP_VAR *var)
Definition: var.c:18087
SCIP_Real SCIPvarGetLbGlobal(SCIP_VAR *var)
Definition: var.c:18077
SCIP_Bool SCIPallowStrongDualReds(SCIP *scip)
Definition: scip_var.c:8752
int * SCIPmatrixGetColIdxPtr(SCIP_MATRIX *matrix, int col)
Definition: matrix.c:1580
int SCIPmatrixGetRowNNonzs(SCIP_MATRIX *matrix, int row)
Definition: matrix.c:1708
int SCIPmatrixGetColNDownlocks(SCIP_MATRIX *matrix, int col)
Definition: matrix.c:1648
int SCIPmatrixGetColNNonzs(SCIP_MATRIX *matrix, int col)
Definition: matrix.c:1592
SCIP_Bool SCIPmatrixIsRowRhsInfinity(SCIP_MATRIX *matrix, int row)
Definition: matrix.c:1766
int SCIPmatrixGetColNUplocks(SCIP_MATRIX *matrix, int col)
Definition: matrix.c:1636
SCIP_Real SCIPmatrixGetRowMaxActivity(SCIP_MATRIX *matrix, int row)
Definition: matrix.c:1800
SCIP_Real SCIPmatrixGetColLb(SCIP_MATRIX *matrix, int col)
Definition: matrix.c:1625
SCIP_Real SCIPmatrixGetRowLhs(SCIP_MATRIX *matrix, int row)
Definition: matrix.c:1742
SCIP_Real * SCIPmatrixGetRowValPtr(SCIP_MATRIX *matrix, int row)
Definition: matrix.c:1684
SCIP_Real * SCIPmatrixGetColValPtr(SCIP_MATRIX *matrix, int col)
Definition: matrix.c:1568
SCIP_RETCODE SCIPmatrixCreate(SCIP *scip, SCIP_MATRIX **matrixptr, SCIP_Bool onlyifcomplete, SCIP_Bool *initialized, SCIP_Bool *complete, SCIP_Bool *infeasible, int *naddconss, int *ndelconss, int *nchgcoefs, int *nchgbds, int *nfixedvars)
Definition: matrix.c:454
int SCIPmatrixGetNColumns(SCIP_MATRIX *matrix)
Definition: matrix.c:1604
SCIP_Real SCIPmatrixGetRowMinActivity(SCIP_MATRIX *matrix, int row)
Definition: matrix.c:1788
void SCIPmatrixFree(SCIP *scip, SCIP_MATRIX **matrix)
Definition: matrix.c:1072
SCIP_VAR * SCIPmatrixGetVar(SCIP_MATRIX *matrix, int col)
Definition: matrix.c:1660
int * SCIPmatrixGetRowIdxPtr(SCIP_MATRIX *matrix, int row)
Definition: matrix.c:1696
SCIP_Real SCIPmatrixGetColUb(SCIP_MATRIX *matrix, int col)
Definition: matrix.c:1614
memory allocation routines
#define BMSclearMemoryArray(ptr, num)
Definition: memory.h:130
#define PRESOL_NAME
static void getBinVarIdxInDownlockRow(SCIP *scip, SCIP_MATRIX *matrix, int aggvaridx, int *binvaridx, AGGRTYPE *aggtype)
static void getUplockRowIdx(SCIP_MATRIX *matrix, int aggvaridx, int *rowidx, SCIP_Real *coef)
static void getDownlockRowIdx(SCIP_MATRIX *matrix, int aggvaridx, int *rowidx, SCIP_Real *coef)
#define PRESOL_PRIORITY
static SCIP_RETCODE findUplockAggregations(SCIP *scip, SCIP_MATRIX *matrix, int *nvaragg, AGGRTYPE *aggtypes, SCIP_VAR **binvars)
AggrType
@ BIN0UBOUND
@ BIN0LBOUND
@ NOAGG
static void getBinVarIdxInUplockRow(SCIP *scip, SCIP_MATRIX *matrix, int aggvaridx, int *binvaridx, AGGRTYPE *aggtype)
static SCIP_DECL_PRESOLEXEC(presolExecDualagg)
#define PRESOL_MAXROUNDS
#define PRESOL_TIMING
static SCIP_RETCODE findDownlockAggregations(SCIP *scip, SCIP_MATRIX *matrix, int *nvaragg, AGGRTYPE *aggtypes, SCIP_VAR **binvars)
enum AggrType AGGRTYPE
#define PRESOL_DESC
aggregate variables by dual arguments
public methods for matrix
public methods for message output
#define SCIPdebug(x)
Definition: pub_message.h:93
public methods for problem variables
general public methods
public methods for memory management
public methods for message handling
public methods for nonlinear relaxation
public methods for numerical tolerances
public methods for presolving plugins
public methods for variable pricer plugins
public methods for global and local (sub)problems
public methods for the probing mode
public methods for SCIP variables
@ SCIP_DIDNOTRUN
Definition: type_result.h:42
@ SCIP_CUTOFF
Definition: type_result.h:48
@ SCIP_DIDNOTFIND
Definition: type_result.h:44
@ SCIP_SUCCESS
Definition: type_result.h:58
@ SCIP_OKAY
Definition: type_retcode.h:42
enum SCIP_Retcode SCIP_RETCODE
Definition: type_retcode.h:63
@ SCIP_STAGE_PRESOLVING
Definition: type_set.h:49
@ SCIP_VARTYPE_BINARY
Definition: type_var.h:62