Scippy

SCIP

Solving Constraint Integer Programs

heur_shifting.c
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4/* SCIP --- Solving Constraint Integer Programs */
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24
25/**@file heur_shifting.c
26 * @ingroup DEFPLUGINS_HEUR
27 * @brief LP rounding heuristic that tries to recover from intermediate infeasibilities and shifts continuous variables
28 * @author Tobias Achterberg
29 */
30
31/*---+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8----+----9----+----0----+----1----+----2*/
32
34#include "scip/heur_shifting.h"
35#include "scip/pub_heur.h"
36#include "scip/pub_lp.h"
37#include "scip/pub_message.h"
38#include "scip/pub_misc.h"
39#include "scip/pub_var.h"
40#include "scip/scip_branch.h"
41#include "scip/scip_heur.h"
42#include "scip/scip_lp.h"
43#include "scip/scip_mem.h"
44#include "scip/scip_message.h"
45#include "scip/scip_numerics.h"
46#include "scip/scip_prob.h"
48#include "scip/scip_sol.h"
50#include <string.h>
51
52#define HEUR_NAME "shifting"
53#define HEUR_DESC "LP rounding heuristic with infeasibility recovering also using continuous variables"
54#define HEUR_DISPCHAR SCIP_HEURDISPCHAR_ROUNDING
55#define HEUR_PRIORITY -5000
56#define HEUR_FREQ 10
57#define HEUR_FREQOFS 0
58#define HEUR_MAXDEPTH -1
59#define HEUR_TIMING SCIP_HEURTIMING_DURINGLPLOOP
60#define HEUR_USESSUBSCIP FALSE /**< does the heuristic use a secondary SCIP instance? */
61
62#define MAXSHIFTINGS 50 /**< maximal number of non improving shiftings */
63#define WEIGHTFACTOR 1.1
64#define DEFAULT_RANDSEED 31 /**< initial random seed */
65
66
67/* locally defined heuristic data */
68struct SCIP_HeurData
69{
70 SCIP_SOL* sol; /**< working solution */
71 SCIP_RANDNUMGEN* randnumgen; /**< random number generator */
72 SCIP_Longint lastlp; /**< last LP number where the heuristic was applied */
73};
74
75
76/*
77 * local methods
78 */
79
80/** update row violation arrays after a row's activity value changed */
81static
83 SCIP* scip, /**< SCIP data structure */
84 SCIP_ROW* row, /**< LP row */
85 SCIP_ROW** violrows, /**< array with currently violated rows */
86 int* violrowpos, /**< position of LP rows in violrows array */
87 int* nviolrows, /**< pointer to the number of currently violated rows */
88 int* nviolfracrows, /**< pointer to the number of violated rows with fractional candidates */
89 int* nfracsinrow, /**< array with number of fractional variables for every row */
90 SCIP_Real oldactivity, /**< old activity value of LP row */
91 SCIP_Real newactivity /**< new activity value of LP row */
92 )
93{
94 SCIP_Real lhs;
95 SCIP_Real rhs;
96 SCIP_Bool oldviol;
97 SCIP_Bool newviol;
98
99 assert(violrows != NULL);
100 assert(violrowpos != NULL);
101 assert(nviolrows != NULL);
102
103 lhs = SCIProwGetLhs(row);
104 rhs = SCIProwGetRhs(row);
105
106 /* SCIPisFeasLT cannot handle comparing different infinities. To prevent this, we make a case distinction. */
107 if( !(SCIPisInfinity(scip, oldactivity) || SCIPisInfinity(scip, -oldactivity)) )
108 {
109 oldviol = (SCIPisFeasLT(scip, oldactivity, lhs) || SCIPisFeasGT(scip, oldactivity, rhs));
110 }
111 else
112 {
113 oldviol = (SCIPisInfinity(scip, -oldactivity) && !SCIPisInfinity(scip, -lhs)) ||
114 (SCIPisInfinity(scip, oldactivity) && !SCIPisInfinity(scip, rhs));
115 }
116
117 /* SCIPisFeasLT cannot handle comparing different infinities. To prevent this, we make a case distinction. */
118 if( !(SCIPisInfinity(scip, newactivity) || SCIPisInfinity(scip, -newactivity)) )
119 {
120 newviol = (SCIPisFeasLT(scip, newactivity, lhs) || SCIPisFeasGT(scip, newactivity, rhs));
121 }
122 else
123 {
124 newviol = (SCIPisInfinity(scip, -newactivity) && !SCIPisInfinity(scip, -lhs)) ||
125 (SCIPisInfinity(scip, newactivity) && !SCIPisInfinity(scip, rhs));
126 }
127
128 if( oldviol != newviol )
129 {
130 int rowpos;
131 int violpos;
132
133 rowpos = SCIProwGetLPPos(row);
134 assert(rowpos >= 0);
135
136 if( oldviol )
137 {
138 /* the row violation was repaired: remove row from violrows array, decrease violation count */
139 violpos = violrowpos[rowpos];
140 assert(0 <= violpos && violpos < *nviolrows);
141 assert(violrows[violpos] == row);
142 violrowpos[rowpos] = -1;
143
144 /* first, move the row to the end of the subset of violated rows with fractional variables */
145 if( nfracsinrow[rowpos] > 0 )
146 {
147 assert(violpos < *nviolfracrows);
148
149 /* replace with last violated row containing fractional variables */
150 if( violpos != *nviolfracrows - 1 )
151 {
152 violrows[violpos] = violrows[*nviolfracrows - 1];
153 violrowpos[SCIProwGetLPPos(violrows[violpos])] = violpos;
154 violpos = *nviolfracrows - 1;
155 }
156 (*nviolfracrows)--;
157 }
158
159 assert(violpos >= *nviolfracrows);
160
161 /* swap row at the end of the violated array to the position of this row and decrease the counter */
162 if( violpos != *nviolrows - 1 )
163 {
164 violrows[violpos] = violrows[*nviolrows - 1];
165 violrowpos[SCIProwGetLPPos(violrows[violpos])] = violpos;
166 }
167 (*nviolrows)--;
168 }
169 else
170 {
171 /* the row is now violated: add row to violrows array, increase violation count */
172 assert(violrowpos[rowpos] == -1);
173 violrows[*nviolrows] = row;
174 violrowpos[rowpos] = *nviolrows;
175 (*nviolrows)++;
176
177 /* if the row contains fractional variables, swap with the last violated row that has no fractional variables
178 * at position *nviolfracrows
179 */
180 if( nfracsinrow[rowpos] > 0 )
181 {
182 if( *nviolfracrows < *nviolrows - 1 )
183 {
184 assert(nfracsinrow[SCIProwGetLPPos(violrows[*nviolfracrows])] == 0);
185
186 violrows[*nviolrows - 1] = violrows[*nviolfracrows];
187 violrowpos[SCIProwGetLPPos(violrows[*nviolrows - 1])] = *nviolrows - 1;
188
189 violrows[*nviolfracrows] = row;
190 violrowpos[rowpos] = *nviolfracrows;
191 }
192 (*nviolfracrows)++;
193 }
194 }
195 }
196}
197
198/** update row activities after a variable's solution value changed */
199static
201 SCIP* scip, /**< SCIP data structure */
202 SCIP_Real* activities, /**< LP row activities */
203 SCIP_ROW** violrows, /**< array with currently violated rows */
204 int* violrowpos, /**< position of LP rows in violrows array */
205 int* nviolrows, /**< pointer to the number of currently violated rows */
206 int* nviolfracrows, /**< pointer to the number of violated rows with fractional candidates */
207 int* nfracsinrow, /**< array with number of fractional variables for every row */
208 int nlprows, /**< number of rows in current LP */
209 SCIP_VAR* var, /**< variable that has been changed */
210 SCIP_Real oldsolval, /**< old solution value of variable */
211 SCIP_Real newsolval /**< new solution value of variable */
212 )
213{
214 SCIP_COL* col;
215 SCIP_ROW** colrows;
216 SCIP_Real* colvals;
217 SCIP_Real delta;
218 int ncolrows;
219 int r;
220
221 assert(activities != NULL);
222 assert(nviolrows != NULL);
223 assert(0 <= *nviolrows && *nviolrows <= nlprows);
224
225 delta = newsolval - oldsolval;
226 col = SCIPvarGetCol(var);
227 colrows = SCIPcolGetRows(col);
228 colvals = SCIPcolGetVals(col);
229 ncolrows = SCIPcolGetNLPNonz(col);
230 assert(ncolrows == 0 || (colrows != NULL && colvals != NULL));
231
232 for( r = 0; r < ncolrows; ++r )
233 {
234 SCIP_ROW* row;
235 int rowpos;
236
237 row = colrows[r];
238 rowpos = SCIProwGetLPPos(row);
239 assert(-1 <= rowpos && rowpos < nlprows);
240
241 if( rowpos >= 0 && !SCIProwIsLocal(row) )
242 {
243 SCIP_Real oldactivity;
244 SCIP_Real newactivity;
245
246 assert(SCIProwIsInLP(row));
247
248 /* update row activity */
249 oldactivity = activities[rowpos];
250 if( !SCIPisInfinity(scip, -oldactivity) && !SCIPisInfinity(scip, oldactivity) )
251 {
252 newactivity = oldactivity + delta * colvals[r];
253 if( SCIPisInfinity(scip, newactivity) )
254 newactivity = SCIPinfinity(scip);
255 else if( SCIPisInfinity(scip, -newactivity) )
256 newactivity = -SCIPinfinity(scip);
257 activities[rowpos] = newactivity;
258
259 /* update row violation arrays */
260 updateViolations(scip, row, violrows, violrowpos, nviolrows, nviolfracrows, nfracsinrow, oldactivity, newactivity);
261 }
262 }
263 }
264
265 return SCIP_OKAY;
266}
267
268/** returns a variable, that pushes activity of the row in the given direction with minimal negative impact on other rows;
269 * if variables have equal impact, chooses the one with best objective value improvement in corresponding direction;
270 * prefer fractional integers over other variables in order to become integral during the process;
271 * shifting in a direction is forbidden, if this forces the objective value over the upper bound, or if the variable
272 * was already shifted in the opposite direction
273 */
274static
276 SCIP* scip, /**< SCIP data structure */
277 SCIP_SOL* sol, /**< primal solution */
278 SCIP_ROW* row, /**< LP row */
279 SCIP_Real rowactivity, /**< activity of LP row */
280 int direction, /**< should the activity be increased (+1) or decreased (-1)? */
281 SCIP_Real* nincreases, /**< array with weighted number of increasings per variables */
282 SCIP_Real* ndecreases, /**< array with weighted number of decreasings per variables */
283 SCIP_Real increaseweight, /**< current weight of increase/decrease updates */
284 SCIP_VAR** shiftvar, /**< pointer to store the shifting variable, returns NULL if impossible */
285 SCIP_Real* oldsolval, /**< pointer to store old solution value of shifting variable */
286 SCIP_Real* newsolval /**< pointer to store new (shifted) solution value of shifting variable */
287 )
288{
289 SCIP_COL** rowcols;
290 SCIP_Real* rowvals;
291 int nrowcols;
292 SCIP_Real activitydelta;
293 SCIP_Real bestshiftscore;
294 SCIP_Real bestdeltaobj;
295 int c;
296
297 assert(direction == +1 || direction == -1);
298 assert(nincreases != NULL);
299 assert(ndecreases != NULL);
300 assert(shiftvar != NULL);
301 assert(oldsolval != NULL);
302 assert(newsolval != NULL);
303
304 /* get row entries */
305 rowcols = SCIProwGetCols(row);
306 rowvals = SCIProwGetVals(row);
307 nrowcols = SCIProwGetNLPNonz(row);
308
309 /* calculate how much the activity must be shifted in order to become feasible */
310 activitydelta = (direction == +1 ? SCIProwGetLhs(row) - rowactivity : SCIProwGetRhs(row) - rowactivity);
311 assert((direction == +1 && SCIPisPositive(scip, activitydelta))
312 || (direction == -1 && SCIPisNegative(scip, activitydelta)));
313
314 /* select shifting variable */
315 bestshiftscore = SCIP_REAL_MAX;
316 bestdeltaobj = SCIPinfinity(scip);
317 *shiftvar = NULL;
318 *newsolval = 0.0;
319 *oldsolval = 0.0;
320 for( c = 0; c < nrowcols; ++c )
321 {
322 SCIP_COL* col;
323 SCIP_VAR* var;
324 SCIP_Real val;
325 SCIP_Real solval;
326 SCIP_Real shiftval;
327 SCIP_Real shiftscore;
328 SCIP_Bool isinteger;
329 SCIP_Bool isfrac;
330 SCIP_Bool increase;
331
332 col = rowcols[c];
333 var = SCIPcolGetVar(col);
334 val = rowvals[c];
335 assert(!SCIPisZero(scip, val));
336 solval = SCIPgetSolVal(scip, sol, var);
337
339 isfrac = (isinteger && !SCIPisFeasIntegral(scip, solval));
340 increase = (direction * val > 0.0);
341
342 /* calculate the score of the shifting (prefer smaller values) */
343 if( isfrac )
344 shiftscore = increase ? -1.0 / (SCIPvarGetNLocksUpType(var, SCIP_LOCKTYPE_MODEL) + 1.0) :
346 else
347 {
348 int probindex;
349 probindex = SCIPvarGetProbindex(var);
350
351 if( increase )
352 shiftscore = ndecreases[probindex]/increaseweight;
353 else
354 shiftscore = nincreases[probindex]/increaseweight;
355 if( isinteger )
356 shiftscore += 1.0;
357 }
358
359 if( shiftscore <= bestshiftscore )
360 {
361 SCIP_Real deltaobj;
362
363 if( !increase )
364 {
365 /* shifting down */
366 assert(direction * val < 0.0);
367 if( isfrac )
368 shiftval = SCIPfeasFloor(scip, solval);
369 else
370 {
371 SCIP_Real lb;
372
373 assert(activitydelta/val < 0.0);
374 shiftval = solval + activitydelta/val;
375 assert(shiftval <= solval); /* may be equal due to numerical digit erasement in the subtraction */
376 if( SCIPvarIsIntegral(var) )
377 shiftval = SCIPfeasFloor(scip, shiftval);
378 lb = SCIPvarGetLbGlobal(var);
379 shiftval = MAX(shiftval, lb);
380 }
381 }
382 else
383 {
384 /* shifting up */
385 assert(direction * val > 0.0);
386 if( isfrac )
387 shiftval = SCIPfeasCeil(scip, solval);
388 else
389 {
390 SCIP_Real ub;
391
392 assert(activitydelta/val > 0.0);
393 shiftval = solval + activitydelta/val;
394 assert(shiftval >= solval); /* may be equal due to numerical digit erasement in the subtraction */
395 if( SCIPvarIsIntegral(var) )
396 shiftval = SCIPfeasCeil(scip, shiftval);
397 ub = SCIPvarGetUbGlobal(var);
398 shiftval = MIN(shiftval, ub);
399 }
400 }
401
402 if( (SCIPisInfinity(scip, shiftval) && SCIPisInfinity(scip, SCIPvarGetUbGlobal(var)))
403 || (SCIPisInfinity(scip, -shiftval) && SCIPisInfinity(scip, -SCIPvarGetLbGlobal(var)))
404 || SCIPisEQ(scip, shiftval, solval) )
405 continue;
406
407 deltaobj = SCIPvarGetObj(var) * (shiftval - solval);
408 if( shiftscore < bestshiftscore || deltaobj < bestdeltaobj )
409 {
410 bestshiftscore = shiftscore;
411 bestdeltaobj = deltaobj;
412 *shiftvar = var;
413 *oldsolval = solval;
414 *newsolval = shiftval;
415 }
416 }
417 }
418
419 return SCIP_OKAY;
420}
421
422/** returns a fractional variable, that has most impact on rows in opposite direction, i.e. that is most crucial to
423 * fix in the other direction;
424 * if variables have equal impact, chooses the one with best objective value improvement in corresponding direction;
425 * shifting in a direction is forbidden, if this forces the objective value over the upper bound
426 */
427static
429 SCIP* scip, /**< SCIP data structure */
430 SCIP_SOL* sol, /**< primal solution */
431 SCIP_Real minobj, /**< minimal objective value possible after shifting remaining fractional vars */
432 SCIP_VAR** lpcands, /**< fractional variables in LP */
433 int nlpcands, /**< number of fractional variables in LP */
434 SCIP_VAR** shiftvar, /**< pointer to store the shifting variable, returns NULL if impossible */
435 SCIP_Real* oldsolval, /**< old (fractional) solution value of shifting variable */
436 SCIP_Real* newsolval /**< new (shifted) solution value of shifting variable */
437 )
438{
439 SCIP_VAR* var;
440 SCIP_Real solval;
441 SCIP_Real shiftval;
442 SCIP_Real obj;
443 SCIP_Real deltaobj;
444 SCIP_Real bestdeltaobj;
445 int maxnlocks;
446 int nlocks;
447 int v;
448
449 assert(shiftvar != NULL);
450 assert(oldsolval != NULL);
451 assert(newsolval != NULL);
452
453 /* select shifting variable */
454 maxnlocks = -1;
455 bestdeltaobj = SCIPinfinity(scip);
456 *shiftvar = NULL;
457 for( v = 0; v < nlpcands; ++v )
458 {
459 var = lpcands[v];
461
462 solval = SCIPgetSolVal(scip, sol, var);
463 if( !SCIPisFeasIntegral(scip, solval) )
464 {
465 obj = SCIPvarGetObj(var);
466
467 /* shifting down */
469 if( nlocks >= maxnlocks )
470 {
471 shiftval = SCIPfeasFloor(scip, solval);
472 deltaobj = obj * (shiftval - solval);
473 if( (nlocks > maxnlocks || deltaobj < bestdeltaobj) && minobj - obj < SCIPgetCutoffbound(scip) )
474 {
475 maxnlocks = nlocks;
476 bestdeltaobj = deltaobj;
477 *shiftvar = var;
478 *oldsolval = solval;
479 *newsolval = shiftval;
480 }
481 }
482
483 /* shifting up */
485 if( nlocks >= maxnlocks )
486 {
487 shiftval = SCIPfeasCeil(scip, solval);
488 deltaobj = obj * (shiftval - solval);
489 if( (nlocks > maxnlocks || deltaobj < bestdeltaobj) && minobj + obj < SCIPgetCutoffbound(scip) )
490 {
491 maxnlocks = nlocks;
492 bestdeltaobj = deltaobj;
493 *shiftvar = var;
494 *oldsolval = solval;
495 *newsolval = shiftval;
496 }
497 }
498 }
499 }
500
501 return SCIP_OKAY;
502}
503
504/** adds a given value to the fractionality counters of the rows in which the given variable appears */
505static
507 int* nfracsinrow, /**< array to store number of fractional variables per row */
508 SCIP_ROW** violrows, /**< array with currently violated rows */
509 int* violrowpos, /**< position of LP rows in violrows array */
510 int* nviolfracrows, /**< pointer to store the number of violated rows with fractional variables */
511 int nviolrows, /**< the number of currently violated rows (stays unchanged in this method) */
512 int nlprows, /**< number of rows in LP */
513 SCIP_VAR* var, /**< variable for which the counting should be updated */
514 int incval /**< value that should be added to the corresponding array entries */
515 )
516{
517 SCIP_COL* col;
518 SCIP_ROW** rows;
519 int nrows;
520 int r;
521
522 assert(incval != 0);
523 assert(nviolrows >= *nviolfracrows);
524 col = SCIPvarGetCol(var);
525 rows = SCIPcolGetRows(col);
526 nrows = SCIPcolGetNLPNonz(col);
527 for( r = 0; r < nrows; ++r )
528 {
529 int rowlppos;
530 int theviolrowpos;
531
532 rowlppos = SCIProwGetLPPos(rows[r]);
533 assert(0 <= rowlppos && rowlppos < nlprows);
534 assert(!SCIProwIsLocal(rows[r]) || violrowpos[rowlppos] == -1);
535
536 /* skip local rows */
537 if( SCIProwIsLocal(rows[r]) )
538 continue;
539
540 nfracsinrow[rowlppos] += incval;
541 assert(nfracsinrow[rowlppos] >= 0);
542 theviolrowpos = violrowpos[rowlppos];
543
544 /* swap positions in violrows array if fractionality has changed to 0 */
545 if( theviolrowpos >= 0 )
546 {
547 /* first case: the number of fractional variables has become zero: swap row in violrows array to the
548 * second part, containing only violated rows without fractional variables
549 */
550 if( nfracsinrow[rowlppos] == 0 )
551 {
552 assert(theviolrowpos <= *nviolfracrows - 1);
553
554 /* nothing to do if row is already at the end of the first part, otherwise, swap it to the last position
555 * and decrease the counter */
556 if( theviolrowpos < *nviolfracrows - 1 )
557 {
558 violrows[theviolrowpos] = violrows[*nviolfracrows - 1];
559 violrows[*nviolfracrows - 1] = rows[r];
560
561 violrowpos[SCIProwGetLPPos(violrows[theviolrowpos])] = theviolrowpos;
562 violrowpos[rowlppos] = *nviolfracrows - 1;
563 }
564 (*nviolfracrows)--;
565 }
566 /* second interesting case: the number of fractional variables was zero before, swap it with the first
567 * violated row without fractional variables
568 */
569 else if( nfracsinrow[rowlppos] == incval )
570 {
571 assert(theviolrowpos >= *nviolfracrows);
572
573 /* nothing to do if the row is exactly located at index *nviolfracrows */
574 if( theviolrowpos > *nviolfracrows )
575 {
576 violrows[theviolrowpos] = violrows[*nviolfracrows];
577 violrows[*nviolfracrows] = rows[r];
578
579 violrowpos[SCIProwGetLPPos(violrows[theviolrowpos])] = theviolrowpos;
580 violrowpos[rowlppos] = *nviolfracrows;
581 }
582 (*nviolfracrows)++;
583 }
584 }
585 }
586}
587
588
589/*
590 * Callback methods
591 */
592
593/** copy method for primal heuristic plugins (called when SCIP copies plugins) */
594static
595SCIP_DECL_HEURCOPY(heurCopyShifting)
596{ /*lint --e{715}*/
597 assert(scip != NULL);
598 assert(heur != NULL);
599 assert(strcmp(SCIPheurGetName(heur), HEUR_NAME) == 0);
600
601 /* call inclusion method of primal heuristic */
603
604 return SCIP_OKAY;
605}
606
607
608/** initialization method of primal heuristic (called after problem was transformed) */
609static
610SCIP_DECL_HEURINIT(heurInitShifting) /*lint --e{715}*/
611{ /*lint --e{715}*/
612 SCIP_HEURDATA* heurdata;
613
614 assert(strcmp(SCIPheurGetName(heur), HEUR_NAME) == 0);
615 assert(SCIPheurGetData(heur) == NULL);
616
617 /* create heuristic data */
618 SCIP_CALL( SCIPallocBlockMemory(scip, &heurdata) );
619 SCIP_CALL( SCIPcreateSol(scip, &heurdata->sol, heur) );
620 heurdata->lastlp = -1;
621
622 /* create random number generator */
623 SCIP_CALL( SCIPcreateRandom(scip, &heurdata->randnumgen,
625
626 SCIPheurSetData(heur, heurdata);
627
628 return SCIP_OKAY;
629}
630
631/** deinitialization method of primal heuristic (called before transformed problem is freed) */
632static
633SCIP_DECL_HEUREXIT(heurExitShifting) /*lint --e{715}*/
634{ /*lint --e{715}*/
635 SCIP_HEURDATA* heurdata;
636
637 assert(strcmp(SCIPheurGetName(heur), HEUR_NAME) == 0);
638
639 /* free heuristic data */
640 heurdata = SCIPheurGetData(heur);
641 assert(heurdata != NULL);
642 SCIP_CALL( SCIPfreeSol(scip, &heurdata->sol) );
643
644 /* free random number generator */
645 SCIPfreeRandom(scip, &heurdata->randnumgen);
646
647 SCIPfreeBlockMemory(scip, &heurdata);
648 SCIPheurSetData(heur, NULL);
649
650 return SCIP_OKAY;
651}
652
653/** solving process initialization method of primal heuristic (called when branch and bound process is about to begin) */
654static
655SCIP_DECL_HEURINITSOL(heurInitsolShifting)
656{
657 SCIP_HEURDATA* heurdata;
658
659 assert(strcmp(SCIPheurGetName(heur), HEUR_NAME) == 0);
660
661 heurdata = SCIPheurGetData(heur);
662 assert(heurdata != NULL);
663 heurdata->lastlp = -1;
664
665 return SCIP_OKAY;
666}
667
668
669/** execution method of primal heuristic */
670static
671SCIP_DECL_HEUREXEC(heurExecShifting) /*lint --e{715}*/
672{ /*lint --e{715}*/
673 SCIP_HEURDATA* heurdata;
674 SCIP_SOL* sol;
675 SCIP_VAR** lpcands;
676 SCIP_Real* lpcandssol;
677 SCIP_ROW** lprows;
678 SCIP_Real* activities;
679 SCIP_ROW** violrows;
680 SCIP_Real* nincreases;
681 SCIP_Real* ndecreases;
682 int* violrowpos;
683 int* nfracsinrow;
684 SCIP_Real increaseweight;
685 SCIP_Real obj;
686 SCIP_Real bestshiftval;
687 SCIP_Real minobj;
688 int nlpcands;
689 int nlprows;
690 int nvars;
691 int nfrac;
692 int nviolrows;
693 int nviolfracrows;
694 int nprevviolrows;
695 int minnviolrows;
696 int nnonimprovingshifts;
697 int c;
698 int r;
699 SCIP_Longint nlps;
700 SCIP_Longint ncalls;
701 SCIP_Longint nsolsfound;
703
704 assert(strcmp(SCIPheurGetName(heur), HEUR_NAME) == 0);
705 assert(scip != NULL);
706 assert(result != NULL);
707 assert(SCIPhasCurrentNodeLP(scip));
708
709 *result = SCIP_DIDNOTRUN;
710
711 /* only call heuristic, if an optimal LP solution is at hand */
713 return SCIP_OKAY;
714
715 /* only call heuristic, if the LP objective value is smaller than the cutoff bound */
717 return SCIP_OKAY;
718
719 /* get heuristic data */
720 heurdata = SCIPheurGetData(heur);
721 assert(heurdata != NULL);
722
723 /* don't call heuristic, if we have already processed the current LP solution */
724 nlps = SCIPgetNLPs(scip);
725 if( nlps == heurdata->lastlp )
726 return SCIP_OKAY;
727 heurdata->lastlp = nlps;
728
729 /* don't call heuristic, if it was not successful enough in the past */
730 ncalls = SCIPheurGetNCalls(heur);
731 nsolsfound = 10*SCIPheurGetNBestSolsFound(heur) + SCIPheurGetNSolsFound(heur);
733 if( nnodes % ((ncalls/100)/(nsolsfound+1)+1) != 0 )
734 return SCIP_OKAY;
735
736 /* get fractional variables, that should be integral */
737 /* todo check if heuristic should include implicit integer variables for its calculations */
738 SCIP_CALL( SCIPgetLPBranchCands(scip, &lpcands, &lpcandssol, NULL, &nlpcands, NULL, NULL) );
739 nfrac = nlpcands;
740
741 /* only call heuristic, if LP solution is fractional */
742 if( nfrac == 0 )
743 return SCIP_OKAY;
744
745 *result = SCIP_DIDNOTFIND;
746
747 /* get LP rows */
748 SCIP_CALL( SCIPgetLPRowsData(scip, &lprows, &nlprows) );
749
750 SCIPdebugMsg(scip, "executing shifting heuristic: %d LP rows, %d fractionals\n", nlprows, nfrac);
751
752 /* get memory for activities, violated rows, and row violation positions */
753 nvars = SCIPgetNVars(scip);
754 SCIP_CALL( SCIPallocBufferArray(scip, &activities, nlprows) );
755 SCIP_CALL( SCIPallocBufferArray(scip, &violrows, nlprows) );
756 SCIP_CALL( SCIPallocBufferArray(scip, &violrowpos, nlprows) );
757 SCIP_CALL( SCIPallocBufferArray(scip, &nfracsinrow, nlprows) );
758 SCIP_CALL( SCIPallocBufferArray(scip, &nincreases, nvars) );
759 SCIP_CALL( SCIPallocBufferArray(scip, &ndecreases, nvars) );
760 BMSclearMemoryArray(nfracsinrow, nlprows);
761 BMSclearMemoryArray(nincreases, nvars);
762 BMSclearMemoryArray(ndecreases, nvars);
763
764 /* get the activities for all globally valid rows;
765 * the rows should be feasible, but due to numerical inaccuracies in the LP solver, they can be violated
766 */
767 nviolrows = 0;
768 for( r = 0; r < nlprows; ++r )
769 {
770 SCIP_ROW* row;
771
772 row = lprows[r];
773 assert(SCIProwGetLPPos(row) == r);
774
775 if( !SCIProwIsLocal(row) )
776 {
777 activities[r] = SCIPgetRowActivity(scip, row);
778 if( SCIPisFeasLT(scip, activities[r], SCIProwGetLhs(row))
779 || SCIPisFeasGT(scip, activities[r], SCIProwGetRhs(row)) )
780 {
781 violrows[nviolrows] = row;
782 violrowpos[r] = nviolrows;
783 nviolrows++;
784 }
785 else
786 violrowpos[r] = -1;
787 }
788 else
789 violrowpos[r] = -1;
790 }
791
792 nviolfracrows = 0;
793 /* calc the current number of fractional variables in rows */
794 for( c = 0; c < nlpcands; ++c )
795 addFracCounter(nfracsinrow, violrows, violrowpos, &nviolfracrows, nviolrows, nlprows, lpcands[c], +1);
796
797 /* get the working solution from heuristic's local data */
798 sol = heurdata->sol;
799 assert(sol != NULL);
800
801 /* copy the current LP solution to the working solution */
803
804 /* calculate the minimal objective value possible after rounding fractional variables */
805 minobj = SCIPgetSolTransObj(scip, sol);
806 assert(minobj < SCIPgetCutoffbound(scip));
807 for( c = 0; c < nlpcands; ++c )
808 {
809 obj = SCIPvarGetObj(lpcands[c]);
810 bestshiftval = obj > 0.0 ? SCIPfeasFloor(scip, lpcandssol[c]) : SCIPfeasCeil(scip, lpcandssol[c]);
811 minobj += obj * (bestshiftval - lpcandssol[c]);
812 }
813
814 /* try to shift remaining variables in order to become/stay feasible */
815 nnonimprovingshifts = 0;
816 minnviolrows = INT_MAX;
817 increaseweight = 1.0;
818 while( (nfrac > 0 || nviolrows > 0) && nnonimprovingshifts < MAXSHIFTINGS )
819 {
820 SCIP_VAR* shiftvar;
821 SCIP_Real oldsolval;
822 SCIP_Real newsolval;
823 SCIP_Bool oldsolvalisfrac;
824 int probindex;
825
826 SCIPdebugMsg(scip, "shifting heuristic: nfrac=%d, nviolrows=%d, obj=%g (best possible obj: %g), cutoff=%g\n",
827 nfrac, nviolrows, SCIPgetSolOrigObj(scip, sol), SCIPretransformObj(scip, minobj),
829
830 nprevviolrows = nviolrows;
831
832 /* choose next variable to process:
833 * - if a violated row exists, shift a variable decreasing the violation, that has least impact on other rows
834 * - otherwise, shift a variable, that has strongest devastating impact on rows in opposite direction
835 */
836 shiftvar = NULL;
837 oldsolval = 0.0;
838 newsolval = 0.0;
839 if( nviolrows > 0 && (nfrac == 0 || nnonimprovingshifts < MAXSHIFTINGS-1) )
840 {
841 SCIP_ROW* row;
842 int rowidx;
843 int rowpos;
844 int direction;
845
846 assert(nviolfracrows == 0 || nfrac > 0);
847 /* violated rows containing fractional variables are preferred; if such a row exists, choose the last one from the list
848 * (at position nviolfracrows - 1) because removing this row will cause one swapping operation less than other rows
849 */
850 if( nviolfracrows > 0 )
851 rowidx = nviolfracrows - 1;
852 else
853 /* there is no violated row containing a fractional variable, select a violated row uniformly at random */
854 rowidx = SCIPrandomGetInt(heurdata->randnumgen, 0, nviolrows-1);
855
856 assert(0 <= rowidx && rowidx < nviolrows);
857 row = violrows[rowidx];
858 rowpos = SCIProwGetLPPos(row);
859 assert(0 <= rowpos && rowpos < nlprows);
860 assert(violrowpos[rowpos] == rowidx);
861 assert(nfracsinrow[rowpos] == 0 || rowidx == nviolfracrows - 1);
862
863 SCIPdebugMsg(scip, "shifting heuristic: try to fix violated row <%s>: %g <= %g <= %g\n",
864 SCIProwGetName(row), SCIProwGetLhs(row), activities[rowpos], SCIProwGetRhs(row));
866
867 /* get direction in which activity must be shifted */
868 assert(SCIPisFeasLT(scip, activities[rowpos], SCIProwGetLhs(row))
869 || SCIPisFeasGT(scip, activities[rowpos], SCIProwGetRhs(row)));
870 direction = SCIPisFeasLT(scip, activities[rowpos], SCIProwGetLhs(row)) ? +1 : -1;
871
872 /* search a variable that can shift the activity in the necessary direction */
873 SCIP_CALL( selectShifting(scip, sol, row, activities[rowpos], direction,
874 nincreases, ndecreases, increaseweight, &shiftvar, &oldsolval, &newsolval) );
875 }
876
877 if( shiftvar == NULL && nfrac > 0 )
878 {
879 SCIPdebugMsg(scip, "shifting heuristic: search rounding variable and try to stay feasible\n");
880 SCIP_CALL( selectEssentialRounding(scip, sol, minobj, lpcands, nlpcands, &shiftvar, &oldsolval, &newsolval) );
881 }
882
883 /* check, whether shifting was possible */
884 if( shiftvar == NULL || SCIPisEQ(scip, oldsolval, newsolval) )
885 {
886 SCIPdebugMsg(scip, "shifting heuristic: -> didn't find a shifting variable\n");
887 break;
888 }
889
890 SCIPdebugMsg(scip, "shifting heuristic: -> shift var <%s>[%g,%g], type=%d, oldval=%g, newval=%g, obj=%g\n",
891 SCIPvarGetName(shiftvar), SCIPvarGetLbGlobal(shiftvar), SCIPvarGetUbGlobal(shiftvar), SCIPvarGetType(shiftvar),
892 oldsolval, newsolval, SCIPvarGetObj(shiftvar));
893
894 /* update row activities of globally valid rows */
895 SCIP_CALL( updateActivities(scip, activities, violrows, violrowpos, &nviolrows, &nviolfracrows, nfracsinrow, nlprows,
896 shiftvar, oldsolval, newsolval) );
897 if( nviolrows >= nprevviolrows )
898 nnonimprovingshifts++;
899 else if( nviolrows < minnviolrows )
900 {
901 minnviolrows = nviolrows;
902 nnonimprovingshifts = 0;
903 }
904
905 /* store new solution value and decrease fractionality counter */
906 SCIP_CALL( SCIPsetSolVal(scip, sol, shiftvar, newsolval) );
907
908 /* update fractionality counter and minimal objective value possible after shifting remaining variables */
909 oldsolvalisfrac = !SCIPisFeasIntegral(scip, oldsolval)
911 obj = SCIPvarGetObj(shiftvar);
913 && oldsolvalisfrac )
914 {
915 assert(SCIPisFeasIntegral(scip, newsolval));
916 nfrac--;
917 nnonimprovingshifts = 0;
918 minnviolrows = INT_MAX;
919 addFracCounter(nfracsinrow, violrows, violrowpos, &nviolfracrows, nviolrows, nlprows, shiftvar, -1);
920
921 /* the rounding was already calculated into the minobj -> update only if rounding in "wrong" direction */
922 if( obj > 0.0 && newsolval > oldsolval )
923 minobj += obj;
924 else if( obj < 0.0 && newsolval < oldsolval )
925 minobj -= obj;
926 }
927 else
928 {
929 /* update minimal possible objective value */
930 minobj += obj * (newsolval - oldsolval);
931 }
932
933 /* update increase/decrease arrays */
934 if( !oldsolvalisfrac )
935 {
936 probindex = SCIPvarGetProbindex(shiftvar);
937 assert(0 <= probindex && probindex < nvars);
938 increaseweight *= WEIGHTFACTOR;
939 if( newsolval < oldsolval )
940 ndecreases[probindex] += increaseweight;
941 else
942 nincreases[probindex] += increaseweight;
943 if( increaseweight >= 1e+09 )
944 {
945 int i;
946
947 for( i = 0; i < nvars; ++i )
948 {
949 nincreases[i] /= increaseweight;
950 ndecreases[i] /= increaseweight;
951 }
952 increaseweight = 1.0;
953 }
954 }
955
956 SCIPdebugMsg(scip, "shifting heuristic: -> nfrac=%d, nviolrows=%d, obj=%g (best possible obj: %g)\n",
957 nfrac, nviolrows, SCIPgetSolOrigObj(scip, sol), SCIPretransformObj(scip, minobj));
958 }
959
960 /* check, if the new solution is feasible */
961 if( nfrac == 0 && nviolrows == 0 )
962 {
963 SCIP_Bool stored;
964
965 /* check solution for feasibility, and add it to solution store if possible
966 * neither integrality nor feasibility of LP rows has to be checked, because this is already
967 * done in the shifting heuristic itself; however, we better check feasibility of LP rows,
968 * because of numerical problems with activity updating
969 */
970 SCIP_CALL( SCIPtrySol(scip, sol, FALSE, FALSE, FALSE, FALSE, TRUE, &stored) );
971
972 if( stored )
973 {
974 SCIPdebugMsg(scip, "found feasible shifted solution:\n");
976 *result = SCIP_FOUNDSOL;
977 }
978 }
979
980 /* free memory buffers */
981 SCIPfreeBufferArray(scip, &ndecreases);
982 SCIPfreeBufferArray(scip, &nincreases);
983 SCIPfreeBufferArray(scip, &nfracsinrow);
984 SCIPfreeBufferArray(scip, &violrowpos);
985 SCIPfreeBufferArray(scip, &violrows);
986 SCIPfreeBufferArray(scip, &activities);
987
988 return SCIP_OKAY;
989}
990
991
992/*
993 * heuristic specific interface methods
994 */
995
996/** creates the shifting heuristic with infeasibility recovering and includes it in SCIP */
998 SCIP* scip /**< SCIP data structure */
999 )
1000{
1001 SCIP_HEUR* heur;
1002
1003 /* include primal heuristic */
1006 HEUR_MAXDEPTH, HEUR_TIMING, HEUR_USESSUBSCIP, heurExecShifting, NULL) );
1007
1008 assert(heur != NULL);
1009
1010 /* set non-NULL pointers to callback methods */
1011 SCIP_CALL( SCIPsetHeurCopy(scip, heur, heurCopyShifting) );
1012 SCIP_CALL( SCIPsetHeurInit(scip, heur, heurInitShifting) );
1013 SCIP_CALL( SCIPsetHeurExit(scip, heur, heurExitShifting) );
1014 SCIP_CALL( SCIPsetHeurInitsol(scip, heur, heurInitsolShifting) );
1015
1016 return SCIP_OKAY;
1017}
1018
SCIP_Real * r
Definition: circlepacking.c:59
#define NULL
Definition: def.h:266
#define SCIP_Longint
Definition: def.h:157
#define SCIP_REAL_MAX
Definition: def.h:173
#define SCIP_Bool
Definition: def.h:91
#define MIN(x, y)
Definition: def.h:242
#define SCIP_Real
Definition: def.h:172
#define TRUE
Definition: def.h:93
#define FALSE
Definition: def.h:94
#define MAX(x, y)
Definition: def.h:238
#define SCIP_CALL(x)
Definition: def.h:373
#define nnodes
Definition: gastrans.c:74
int SCIPgetNVars(SCIP *scip)
Definition: scip_prob.c:1992
#define SCIPdebugMsg
Definition: scip_message.h:78
SCIP_RETCODE SCIPincludeHeurShifting(SCIP *scip)
SCIP_RETCODE SCIPgetLPBranchCands(SCIP *scip, SCIP_VAR ***lpcands, SCIP_Real **lpcandssol, SCIP_Real **lpcandsfrac, int *nlpcands, int *npriolpcands, int *nfracimplvars)
Definition: scip_branch.c:395
SCIP_VAR * SCIPcolGetVar(SCIP_COL *col)
Definition: lp.c:17042
SCIP_Real * SCIPcolGetVals(SCIP_COL *col)
Definition: lp.c:17161
SCIP_ROW ** SCIPcolGetRows(SCIP_COL *col)
Definition: lp.c:17151
int SCIPcolGetNLPNonz(SCIP_COL *col)
Definition: lp.c:17140
SCIP_RETCODE SCIPsetHeurCopy(SCIP *scip, SCIP_HEUR *heur, SCIP_DECL_HEURCOPY((*heurcopy)))
Definition: scip_heur.c:162
SCIP_HEURDATA * SCIPheurGetData(SCIP_HEUR *heur)
Definition: heur.c:1364
SCIP_RETCODE SCIPincludeHeurBasic(SCIP *scip, SCIP_HEUR **heur, const char *name, const char *desc, char dispchar, int priority, int freq, int freqofs, int maxdepth, SCIP_HEURTIMING timingmask, SCIP_Bool usessubscip, SCIP_DECL_HEUREXEC((*heurexec)), SCIP_HEURDATA *heurdata)
Definition: scip_heur.c:117
SCIP_Longint SCIPheurGetNSolsFound(SCIP_HEUR *heur)
Definition: heur.c:1589
SCIP_RETCODE SCIPsetHeurExit(SCIP *scip, SCIP_HEUR *heur, SCIP_DECL_HEUREXIT((*heurexit)))
Definition: scip_heur.c:210
SCIP_Longint SCIPheurGetNBestSolsFound(SCIP_HEUR *heur)
Definition: heur.c:1599
SCIP_Longint SCIPheurGetNCalls(SCIP_HEUR *heur)
Definition: heur.c:1579
SCIP_RETCODE SCIPsetHeurInitsol(SCIP *scip, SCIP_HEUR *heur, SCIP_DECL_HEURINITSOL((*heurinitsol)))
Definition: scip_heur.c:226
SCIP_RETCODE SCIPsetHeurInit(SCIP *scip, SCIP_HEUR *heur, SCIP_DECL_HEURINIT((*heurinit)))
Definition: scip_heur.c:194
const char * SCIPheurGetName(SCIP_HEUR *heur)
Definition: heur.c:1453
void SCIPheurSetData(SCIP_HEUR *heur, SCIP_HEURDATA *heurdata)
Definition: heur.c:1374
SCIP_Bool SCIPhasCurrentNodeLP(SCIP *scip)
Definition: scip_lp.c:83
SCIP_RETCODE SCIPgetLPRowsData(SCIP *scip, SCIP_ROW ***rows, int *nrows)
Definition: scip_lp.c:570
SCIP_LPSOLSTAT SCIPgetLPSolstat(SCIP *scip)
Definition: scip_lp.c:168
SCIP_Real SCIPgetLPObjval(SCIP *scip)
Definition: scip_lp.c:247
#define SCIPallocBufferArray(scip, ptr, num)
Definition: scip_mem.h:124
#define SCIPfreeBufferArray(scip, ptr)
Definition: scip_mem.h:136
#define SCIPfreeBlockMemory(scip, ptr)
Definition: scip_mem.h:108
#define SCIPallocBlockMemory(scip, ptr)
Definition: scip_mem.h:89
SCIP_Real SCIProwGetLhs(SCIP_ROW *row)
Definition: lp.c:17292
SCIP_COL ** SCIProwGetCols(SCIP_ROW *row)
Definition: lp.c:17238
SCIP_Real SCIProwGetRhs(SCIP_ROW *row)
Definition: lp.c:17302
int SCIProwGetNLPNonz(SCIP_ROW *row)
Definition: lp.c:17227
int SCIProwGetLPPos(SCIP_ROW *row)
Definition: lp.c:17501
SCIP_Bool SCIProwIsLocal(SCIP_ROW *row)
Definition: lp.c:17401
SCIP_RETCODE SCIPprintRow(SCIP *scip, SCIP_ROW *row, FILE *file)
Definition: scip_lp.c:2212
const char * SCIProwGetName(SCIP_ROW *row)
Definition: lp.c:17351
SCIP_Real SCIPgetRowActivity(SCIP *scip, SCIP_ROW *row)
Definition: scip_lp.c:2104
SCIP_Bool SCIProwIsInLP(SCIP_ROW *row)
Definition: lp.c:17523
SCIP_Real * SCIProwGetVals(SCIP_ROW *row)
Definition: lp.c:17248
SCIP_RETCODE SCIPcreateSol(SCIP *scip, SCIP_SOL **sol, SCIP_HEUR *heur)
Definition: scip_sol.c:180
SCIP_RETCODE SCIPfreeSol(SCIP *scip, SCIP_SOL **sol)
Definition: scip_sol.c:837
SCIP_RETCODE SCIPprintSol(SCIP *scip, SCIP_SOL *sol, FILE *file, SCIP_Bool printzeros)
Definition: scip_sol.c:1627
SCIP_RETCODE SCIPtrySol(SCIP *scip, SCIP_SOL *sol, SCIP_Bool printreason, SCIP_Bool completely, SCIP_Bool checkbounds, SCIP_Bool checkintegrality, SCIP_Bool checklprows, SCIP_Bool *stored)
Definition: scip_sol.c:2950
SCIP_RETCODE SCIPlinkLPSol(SCIP *scip, SCIP_SOL *sol)
Definition: scip_sol.c:878
SCIP_Real SCIPgetSolOrigObj(SCIP *scip, SCIP_SOL *sol)
Definition: scip_sol.c:1296
SCIP_RETCODE SCIPsetSolVal(SCIP *scip, SCIP_SOL *sol, SCIP_VAR *var, SCIP_Real val)
Definition: scip_sol.c:1073
SCIP_Real SCIPgetSolVal(SCIP *scip, SCIP_SOL *sol, SCIP_VAR *var)
Definition: scip_sol.c:1213
SCIP_Real SCIPgetSolTransObj(SCIP *scip, SCIP_SOL *sol)
Definition: scip_sol.c:1343
SCIP_Real SCIPretransformObj(SCIP *scip, SCIP_Real obj)
Definition: scip_sol.c:1428
SCIP_Longint SCIPgetNNodes(SCIP *scip)
SCIP_Longint SCIPgetNLPs(SCIP *scip)
SCIP_Real SCIPgetCutoffbound(SCIP *scip)
SCIP_Real SCIPinfinity(SCIP *scip)
SCIP_Bool SCIPisGE(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
SCIP_Bool SCIPisPositive(SCIP *scip, SCIP_Real val)
SCIP_Real SCIPfeasCeil(SCIP *scip, SCIP_Real val)
SCIP_Real SCIPfeasFloor(SCIP *scip, SCIP_Real val)
SCIP_Bool SCIPisInfinity(SCIP *scip, SCIP_Real val)
SCIP_Bool SCIPisFeasLT(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
SCIP_Bool SCIPisFeasIntegral(SCIP *scip, SCIP_Real val)
SCIP_Bool SCIPisNegative(SCIP *scip, SCIP_Real val)
SCIP_Bool SCIPisFeasGT(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
SCIP_Bool SCIPisEQ(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
SCIP_Bool SCIPisZero(SCIP *scip, SCIP_Real val)
SCIP_COL * SCIPvarGetCol(SCIP_VAR *var)
Definition: var.c:17788
int SCIPvarGetNLocksUpType(SCIP_VAR *var, SCIP_LOCKTYPE locktype)
Definition: var.c:3353
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
int SCIPvarGetProbindex(SCIP_VAR *var)
Definition: var.c:17767
const char * SCIPvarGetName(SCIP_VAR *var)
Definition: var.c:17418
SCIP_Bool SCIPvarIsIntegral(SCIP_VAR *var)
Definition: var.c:17609
SCIP_Real SCIPvarGetLbGlobal(SCIP_VAR *var)
Definition: var.c:18077
int SCIPvarGetNLocksDownType(SCIP_VAR *var, SCIP_LOCKTYPE locktype)
Definition: var.c:3295
void SCIPfreeRandom(SCIP *scip, SCIP_RANDNUMGEN **randnumgen)
int SCIPrandomGetInt(SCIP_RANDNUMGEN *randnumgen, int minrandval, int maxrandval)
Definition: misc.c:10111
SCIP_RETCODE SCIPcreateRandom(SCIP *scip, SCIP_RANDNUMGEN **randnumgen, unsigned int initialseed, SCIP_Bool useglobalseed)
static SCIP_RETCODE selectEssentialRounding(SCIP *scip, SCIP_SOL *sol, SCIP_Real minobj, SCIP_VAR **lpcands, int nlpcands, SCIP_VAR **shiftvar, SCIP_Real *oldsolval, SCIP_Real *newsolval)
static SCIP_DECL_HEURINITSOL(heurInitsolShifting)
#define HEUR_TIMING
Definition: heur_shifting.c:59
static void addFracCounter(int *nfracsinrow, SCIP_ROW **violrows, int *violrowpos, int *nviolfracrows, int nviolrows, int nlprows, SCIP_VAR *var, int incval)
static SCIP_DECL_HEUREXIT(heurExitShifting)
#define HEUR_FREQOFS
Definition: heur_shifting.c:57
#define HEUR_DESC
Definition: heur_shifting.c:53
#define HEUR_DISPCHAR
Definition: heur_shifting.c:54
#define HEUR_MAXDEPTH
Definition: heur_shifting.c:58
#define HEUR_PRIORITY
Definition: heur_shifting.c:55
static SCIP_DECL_HEUREXEC(heurExecShifting)
static SCIP_DECL_HEURCOPY(heurCopyShifting)
#define HEUR_NAME
Definition: heur_shifting.c:52
static SCIP_RETCODE updateActivities(SCIP *scip, SCIP_Real *activities, SCIP_ROW **violrows, int *violrowpos, int *nviolrows, int *nviolfracrows, int *nfracsinrow, int nlprows, SCIP_VAR *var, SCIP_Real oldsolval, SCIP_Real newsolval)
static void updateViolations(SCIP *scip, SCIP_ROW *row, SCIP_ROW **violrows, int *violrowpos, int *nviolrows, int *nviolfracrows, int *nfracsinrow, SCIP_Real oldactivity, SCIP_Real newactivity)
Definition: heur_shifting.c:82
#define DEFAULT_RANDSEED
Definition: heur_shifting.c:64
static SCIP_DECL_HEURINIT(heurInitShifting)
#define HEUR_FREQ
Definition: heur_shifting.c:56
static SCIP_RETCODE selectShifting(SCIP *scip, SCIP_SOL *sol, SCIP_ROW *row, SCIP_Real rowactivity, int direction, SCIP_Real *nincreases, SCIP_Real *ndecreases, SCIP_Real increaseweight, SCIP_VAR **shiftvar, SCIP_Real *oldsolval, SCIP_Real *newsolval)
#define HEUR_USESSUBSCIP
Definition: heur_shifting.c:60
#define WEIGHTFACTOR
Definition: heur_shifting.c:63
#define MAXSHIFTINGS
Definition: heur_shifting.c:62
LP rounding heuristic that tries to recover from intermediate infeasibilities and shifts continuous v...
memory allocation routines
#define BMSclearMemoryArray(ptr, num)
Definition: memory.h:130
public methods for primal heuristics
public methods for LP management
public methods for message output
#define SCIPdebug(x)
Definition: pub_message.h:93
public data structures and miscellaneous methods
public methods for problem variables
public methods for branching rule plugins and branching
public methods for primal heuristic plugins and divesets
public methods for the LP relaxation, rows and columns
public methods for memory management
public methods for message handling
public methods for numerical tolerances
public methods for global and local (sub)problems
public methods for random numbers
public methods for solutions
public methods for querying solving statistics
struct SCIP_HeurData SCIP_HEURDATA
Definition: type_heur.h:77
@ SCIP_LPSOLSTAT_OPTIMAL
Definition: type_lp.h:43
@ SCIP_DIDNOTRUN
Definition: type_result.h:42
@ SCIP_DIDNOTFIND
Definition: type_result.h:44
@ SCIP_FOUNDSOL
Definition: type_result.h:56
@ SCIP_OKAY
Definition: type_retcode.h:42
enum SCIP_Retcode SCIP_RETCODE
Definition: type_retcode.h:63
@ SCIP_VARTYPE_INTEGER
Definition: type_var.h:63
@ SCIP_VARTYPE_BINARY
Definition: type_var.h:62
@ SCIP_LOCKTYPE_MODEL
Definition: type_var.h:97