Scippy

SCIP

Solving Constraint Integer Programs

prob.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) 2002-2020 Konrad-Zuse-Zentrum */
7 /* fuer Informationstechnik Berlin */
8 /* */
9 /* SCIP is distributed under the terms of the ZIB Academic License. */
10 /* */
11 /* You should have received a copy of the ZIB Academic License */
12 /* along with SCIP; see the file COPYING. If not visit scipopt.org. */
13 /* */
14 /* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
15 
16 /**@file prob.c
17  * @ingroup OTHER_CFILES
18  * @brief Methods and datastructures for storing and manipulating the main problem
19  * @author Tobias Achterberg
20  */
21 
22 /*---+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8----+----9----+----0----+----1----+----2*/
23 
24 #include "scip/branch.h"
25 #include "scip/conflictstore.h"
26 #include "scip/cons.h"
27 #include "scip/event.h"
28 #include "scip/lp.h"
29 #include "scip/primal.h"
30 #include "scip/prob.h"
31 #include "scip/pub_cons.h"
32 #include "scip/pub_lp.h"
33 #include "scip/pub_message.h"
34 #include "scip/pub_misc.h"
35 #include "scip/pub_misc_sort.h"
36 #include "scip/pub_var.h"
37 #include "scip/set.h"
38 #include "scip/stat.h"
39 #include "scip/struct_cons.h"
40 #include "scip/struct_lp.h"
41 #include "scip/struct_prob.h"
42 #include "scip/struct_set.h"
43 #include "scip/struct_stat.h"
44 #include "scip/struct_var.h"
45 #include "scip/var.h"
46 #include <string.h>
47 
48 
49 #define OBJSCALE_MAXDNOM 1000000LL /**< maximal denominator in objective integral scaling */
50 #define OBJSCALE_MAXSCALE 1000000.0 /**< maximal scalar to reach objective integrality */
51 #define OBJSCALE_MAXFINALSCALE 1000.0 /**< maximal final value to apply as scaling */
52 
53 
54 
55 /*
56  * dymanic memory arrays
57  */
58 
59 /** resizes vars array to be able to store at least num entries */
60 static
62  SCIP_PROB* prob, /**< problem data */
63  SCIP_SET* set, /**< global SCIP settings */
64  int num /**< minimal number of slots in array */
65  )
66 {
67  assert(prob != NULL);
68  assert(set != NULL);
69 
70  if( num > prob->varssize )
71  {
72  int newsize;
73 
74  newsize = SCIPsetCalcMemGrowSize(set, num);
75  SCIP_ALLOC( BMSreallocMemoryArray(&prob->vars, newsize) );
76  prob->varssize = newsize;
77  }
78  assert(num <= prob->varssize);
79 
80  return SCIP_OKAY;
81 }
82 
83 /** resizes fixedvars array to be able to store at least num entries */
84 static
86  SCIP_PROB* prob, /**< problem data */
87  SCIP_SET* set, /**< global SCIP settings */
88  int num /**< minimal number of slots in array */
89  )
90 {
91  assert(prob != NULL);
92  assert(set != NULL);
93 
94  if( num > prob->fixedvarssize )
95  {
96  int newsize;
97 
98  newsize = SCIPsetCalcMemGrowSize(set, num);
99  SCIP_ALLOC( BMSreallocMemoryArray(&prob->fixedvars, newsize) );
100  prob->fixedvarssize = newsize;
101  }
102  assert(num <= prob->fixedvarssize);
103 
104  return SCIP_OKAY;
105 }
106 
107 /** resizes deletedvars array to be able to store at least num entries */
108 static
110  SCIP_PROB* prob, /**< problem data */
111  SCIP_SET* set, /**< global SCIP settings */
112  int num /**< minimal number of slots in array */
113  )
114 {
115  assert(prob != NULL);
116  assert(set != NULL);
117 
118  if( num > prob->deletedvarssize )
119  {
120  int newsize;
121 
122  newsize = SCIPsetCalcMemGrowSize(set, num);
123  SCIP_ALLOC( BMSreallocMemoryArray(&prob->deletedvars, newsize) );
124  prob->deletedvarssize = newsize;
125  }
126  assert(num <= prob->deletedvarssize);
127 
128  return SCIP_OKAY;
129 }
130 
131 /** resizes conss array to be able to store at least num entries */
132 static
134  SCIP_PROB* prob, /**< problem data */
135  SCIP_SET* set, /**< global SCIP settings */
136  int num /**< minimal number of slots in array */
137  )
138 {
139  assert(prob != NULL);
140  assert(set != NULL);
141 
142  if( num > prob->consssize )
143  {
144  int newsize;
145 
146  newsize = SCIPsetCalcMemGrowSize(set, num);
147  SCIP_ALLOC( BMSreallocMemoryArray(&prob->conss, newsize) );
148  prob->consssize = newsize;
149  }
150  assert(num <= prob->consssize);
151 
152  return SCIP_OKAY;
153 }
154 
155 /** returns whether the constraint has a name */
156 static
158  SCIP_CONS* cons /**< constraint */
159  )
160 {
161  const char* name;
162 
163  name = SCIPconsGetName(cons);
164 
165  return (name != NULL && name[0] != '\0');
166 }
167 
168 /** returns whether the variable has a name */
169 static
171  SCIP_VAR* var /**< variable */
172  )
173 {
174  const char* name;
175 
176  name = SCIPvarGetName(var);
177 
178  return (name != NULL && name[0] != '\0');
179 }
180 
181 
182 
183 /*
184  * problem creation
185  */
186 
187 /** creates problem data structure by copying the source problem
188  *
189  * If the problem type requires the use of variable pricers, these pricers should be activated with calls
190  * to SCIPactivatePricer(). These pricers are automatically deactivated, when the problem is freed.
191  */
193  SCIP_PROB** prob, /**< pointer to problem data structure */
194  BMS_BLKMEM* blkmem, /**< block memory */
195  SCIP_SET* set, /**< global SCIP settings */
196  const char* name, /**< problem name */
197  SCIP* sourcescip, /**< source SCIP data structure */
198  SCIP_PROB* sourceprob, /**< source problem structure */
199  SCIP_HASHMAP* varmap, /**< a hashmap to store the mapping of source variables corresponding
200  * target variables */
201  SCIP_HASHMAP* consmap, /**< a hashmap to store the mapping of source constraints to the corresponding
202  * target constraints */
203  SCIP_Bool global /**< create a global or a local copy? */
204  )
205 {
206  SCIP_PROBDATA* targetdata = NULL;
207  SCIP_RESULT result = SCIP_DIDNOTRUN;
208 
209  assert(prob != NULL);
210  assert(set != NULL);
211  assert(blkmem != NULL);
212  assert(sourcescip != NULL);
213  assert(sourceprob != NULL);
214  assert(varmap != NULL);
215  assert(consmap != NULL);
216 
217  /* create problem and initialize callbacks with NULL */
218  SCIP_CALL( SCIPprobCreate(prob, blkmem, set, name, NULL, NULL, NULL, NULL, NULL, NULL, NULL, FALSE) );
219 
220  /* call user copy callback method */
221  if( sourceprob->probdata != NULL && sourceprob->probcopy != NULL )
222  {
223  SCIP_CALL( sourceprob->probcopy(set->scip, sourcescip, sourceprob->probdata, varmap, consmap, &targetdata, global, &result) );
224 
225  /* evaluate result */
226  if( result != SCIP_DIDNOTRUN && result != SCIP_SUCCESS )
227  {
228  SCIPerrorMessage("probdata copying method returned invalid result <%d>\n", result);
229  return SCIP_INVALIDRESULT;
230  }
231 
232  assert(targetdata == NULL || result == SCIP_SUCCESS);
233 
234  /* if copying was successful, add data and callbacks */
235  if( result == SCIP_SUCCESS )
236  {
237  assert( targetdata != NULL );
238  (*prob)->probdelorig = sourceprob->probdelorig;
239  (*prob)->probtrans = sourceprob->probtrans;
240  (*prob)->probdeltrans = sourceprob->probdeltrans;
241  (*prob)->probinitsol = sourceprob->probinitsol;
242  (*prob)->probexitsol = sourceprob->probexitsol;
243  (*prob)->probcopy = sourceprob->probcopy;
244  (*prob)->probdata = targetdata;
245  }
246  }
247 
248  return SCIP_OKAY;
249 }
250 
251 /** creates problem data structure
252  * If the problem type requires the use of variable pricers, these pricers should be activated with calls
253  * to SCIPactivatePricer(). These pricers are automatically deactivated, when the problem is freed.
254  */
256  SCIP_PROB** prob, /**< pointer to problem data structure */
257  BMS_BLKMEM* blkmem, /**< block memory */
258  SCIP_SET* set, /**< global SCIP settings */
259  const char* name, /**< problem name */
260  SCIP_DECL_PROBDELORIG ((*probdelorig)), /**< frees user data of original problem */
261  SCIP_DECL_PROBTRANS ((*probtrans)), /**< creates user data of transformed problem by transforming original user data */
262  SCIP_DECL_PROBDELTRANS((*probdeltrans)), /**< frees user data of transformed problem */
263  SCIP_DECL_PROBINITSOL ((*probinitsol)), /**< solving process initialization method of transformed data */
264  SCIP_DECL_PROBEXITSOL ((*probexitsol)), /**< solving process deinitialization method of transformed data */
265  SCIP_DECL_PROBCOPY ((*probcopy)), /**< copies user data if you want to copy it to a subscip, or NULL */
266  SCIP_PROBDATA* probdata, /**< user problem data set by the reader */
267  SCIP_Bool transformed /**< is this the transformed problem? */
268  )
269 {
270  assert(prob != NULL);
271 
272  SCIP_ALLOC( BMSallocMemory(prob) );
273  SCIP_ALLOC( BMSduplicateMemoryArray(&(*prob)->name, name, strlen(name)+1) );
274 
275  (*prob)->probdata = probdata;
276  (*prob)->probcopy = probcopy;
277  (*prob)->probdelorig = probdelorig;
278  (*prob)->probtrans = probtrans;
279  (*prob)->probdeltrans = probdeltrans;
280  (*prob)->probinitsol = probinitsol;
281  (*prob)->probexitsol = probexitsol;
282  if( set->misc_usevartable )
283  {
284  SCIP_CALL( SCIPhashtableCreate(&(*prob)->varnames, blkmem,
285  (set->misc_usesmalltables ? SCIP_HASHSIZE_NAMES_SMALL : SCIP_HASHSIZE_NAMES),
286  SCIPhashGetKeyVar, SCIPhashKeyEqString, SCIPhashKeyValString, NULL) );
287  }
288  else
289  (*prob)->varnames = NULL;
290  (*prob)->vars = NULL;
291  (*prob)->varssize = 0;
292  (*prob)->nvars = 0;
293  (*prob)->nbinvars = 0;
294  (*prob)->nintvars = 0;
295  (*prob)->nimplvars = 0;
296  (*prob)->ncontvars = 0;
297  (*prob)->ncolvars = 0;
298  (*prob)->fixedvars = NULL;
299  (*prob)->fixedvarssize = 0;
300  (*prob)->nfixedvars = 0;
301  (*prob)->deletedvars = NULL;
302  (*prob)->deletedvarssize = 0;
303  (*prob)->ndeletedvars = 0;
304  (*prob)->nobjvars = 0;
305  if( set->misc_useconstable )
306  {
307  SCIP_CALL( SCIPhashtableCreate(&(*prob)->consnames, blkmem,
308  (set->misc_usesmalltables ? SCIP_HASHSIZE_NAMES_SMALL : SCIP_HASHSIZE_NAMES),
309  SCIPhashGetKeyCons, SCIPhashKeyEqString, SCIPhashKeyValString, NULL) );
310  }
311  else
312  (*prob)->consnames = NULL;
313  (*prob)->conss = NULL;
314  (*prob)->consssize = 0;
315  (*prob)->nconss = 0;
316  (*prob)->maxnconss = 0;
317  (*prob)->startnvars = 0;
318  (*prob)->startnconss = 0;
319  (*prob)->objsense = SCIP_OBJSENSE_MINIMIZE;
320  (*prob)->objoffset = 0.0;
321  (*prob)->objscale = 1.0;
322  (*prob)->objlim = SCIP_INVALID;
323  (*prob)->dualbound = SCIP_INVALID;
324  (*prob)->objisintegral = FALSE;
325  (*prob)->transformed = transformed;
326  (*prob)->nlpenabled = FALSE;
327  (*prob)->permuted = FALSE;
328  (*prob)->conscompression = FALSE;
329 
330  return SCIP_OKAY;
331 }
332 
333 /** sets callback to free user data of original problem */
335  SCIP_PROB* prob, /**< problem */
336  SCIP_DECL_PROBDELORIG ((*probdelorig)) /**< frees user data of original problem */
337  )
338 {
339  assert(prob != NULL);
340 
341  prob->probdelorig = probdelorig;
342 }
343 
344 /** sets callback to create user data of transformed problem by transforming original user data */
346  SCIP_PROB* prob, /**< problem */
347  SCIP_DECL_PROBTRANS ((*probtrans)) /**< creates user data of transformed problem by transforming original user data */
348  )
349 {
350  assert(prob != NULL);
351 
352  prob->probtrans = probtrans;
353 }
354 
355 /** sets callback to free user data of transformed problem */
357  SCIP_PROB* prob, /**< problem */
358  SCIP_DECL_PROBDELTRANS((*probdeltrans)) /**< frees user data of transformed problem */
359  )
360 {
361  assert(prob != NULL);
362 
363  prob->probdeltrans = probdeltrans;
364 }
365 
366 /** sets solving process initialization callback of transformed data */
368  SCIP_PROB* prob, /**< problem */
369  SCIP_DECL_PROBINITSOL ((*probinitsol)) /**< solving process initialization callback of transformed data */
370  )
371 {
372  assert(prob != NULL);
373 
374  prob->probinitsol= probinitsol;
375 }
376 
377 /** sets solving process deinitialization callback of transformed data */
379  SCIP_PROB* prob, /**< problem */
380  SCIP_DECL_PROBEXITSOL ((*probexitsol)) /**< solving process deinitialization callback of transformed data */
381  )
382 {
383  assert(prob != NULL);
384 
385  prob->probexitsol= probexitsol;
386 }
387 
388 /** sets callback to copy user data to copy it to a subscip, or NULL */
390  SCIP_PROB* prob, /**< problem */
391  SCIP_DECL_PROBCOPY ((*probcopy)) /**< copies user data if you want to copy it to a subscip, or NULL */
392  )
393 {
394  assert(prob != NULL);
395 
396  prob->probcopy= probcopy;
397 }
398 
399 /** frees problem data structure */
401  SCIP_PROB** prob, /**< pointer to problem data structure */
402  SCIP_MESSAGEHDLR* messagehdlr, /**< message handler */
403  BMS_BLKMEM* blkmem, /**< block memory buffer */
404  SCIP_SET* set, /**< global SCIP settings */
405  SCIP_STAT* stat, /**< dynamic problem statistics */
406  SCIP_EVENTQUEUE* eventqueue, /**< event queue */
407  SCIP_LP* lp /**< current LP data (or NULL, if it's the original problem) */
408  )
409 {
410  int v;
411 #ifndef NDEBUG
412  SCIP_Bool unreleasedvar = FALSE;
413 #endif
414 
415  assert(prob != NULL);
416  assert(*prob != NULL);
417  assert(set != NULL);
418 
419  /* remove all constraints from the problem */
420  while( (*prob)->nconss > 0 )
421  {
422  /*@todo for debug mode it even might sense, to sort them downwards after their arraypos */
423  assert((*prob)->conss != NULL);
424  SCIP_CALL( SCIPprobDelCons(*prob, blkmem, set, stat, (*prob)->conss[(*prob)->nconss - 1]) );
425  }
426 
427  if( (*prob)->transformed )
428  {
429  int h;
430 
431  /* unlock variables for all constraint handlers that don't need constraints */
432  for( h = 0; h < set->nconshdlrs; ++h )
433  {
434  if( !SCIPconshdlrNeedsCons(set->conshdlrs[h]) )
435  {
436  SCIP_CALL( SCIPconshdlrUnlockVars(set->conshdlrs[h], set) );
437  }
438  }
439  }
440 
441  /* free constraint array */
442  BMSfreeMemoryArrayNull(&(*prob)->conss);
443 
444  /* free user problem data */
445  if( (*prob)->transformed )
446  {
447  if( (*prob)->probdeltrans != NULL )
448  {
449  SCIP_CALL( (*prob)->probdeltrans(set->scip, &(*prob)->probdata) );
450  }
451  }
452  else
453  {
454  if( (*prob)->probdelorig != NULL )
455  {
456  SCIP_CALL( (*prob)->probdelorig(set->scip, &(*prob)->probdata) );
457  }
458  }
459 
460  /* release problem variables */
461  for( v = (*prob)->nvars - 1; v >= 0; --v )
462  {
463  assert(SCIPvarGetProbindex((*prob)->vars[v]) >= 0);
464 
465  if( SCIPvarGetNUses((*prob)->vars[v]) > 1 )
466  {
467  SCIPmessageFPrintWarning(messagehdlr, "%s variable <%s> not released when freeing SCIP.\n",
468  (*prob)->transformed ? "Transformed" : "Original", SCIPvarGetName((*prob)->vars[v]));
469 #ifndef NDEBUG
470  unreleasedvar = TRUE;
471 #endif
472  }
473 
474  SCIP_CALL( SCIPvarRemove((*prob)->vars[v], blkmem, NULL, set, TRUE) );
475  SCIP_CALL( SCIPvarRelease(&(*prob)->vars[v], blkmem, set, eventqueue, lp) );
476  }
477  BMSfreeMemoryArrayNull(&(*prob)->vars);
478 
479  /* release fixed problem variables */
480  for( v = (*prob)->nfixedvars - 1; v >= 0; --v )
481  {
482  assert(SCIPvarGetProbindex((*prob)->fixedvars[v]) == -1);
483 
484  if( SCIPvarGetNUses((*prob)->fixedvars[v]) > 1 )
485  {
486  SCIPmessageFPrintWarning(messagehdlr, "%s variable <%s> not released when freeing SCIP.\n",
487  (*prob)->transformed ? "Transformed" : "Original", SCIPvarGetName((*prob)->fixedvars[v]));
488 #ifndef NDEBUG
489  unreleasedvar = TRUE;
490 #endif
491  }
492 
493  SCIP_CALL( SCIPvarRelease(&(*prob)->fixedvars[v], blkmem, set, eventqueue, lp) );
494  }
495  BMSfreeMemoryArrayNull(&(*prob)->fixedvars);
496 
497  assert(! unreleasedvar);
498 
499  /* free deleted problem variables array */
500  BMSfreeMemoryArrayNull(&(*prob)->deletedvars);
501 
502  /* free hash tables for names */
503  if( (*prob)->varnames != NULL )
504  {
505  SCIPhashtableFree(&(*prob)->varnames);
506  }
507  if( (*prob)->consnames != NULL )
508  {
509  SCIPhashtableFree(&(*prob)->consnames);
510  }
511  BMSfreeMemoryArray(&(*prob)->name);
512  BMSfreeMemory(prob);
513 
514  return SCIP_OKAY;
515 }
516 
517 /** transform problem data into normalized form */
519  SCIP_PROB* source, /**< problem to transform */
520  BMS_BLKMEM* blkmem, /**< block memory buffer */
521  SCIP_SET* set, /**< global SCIP settings */
522  SCIP_STAT* stat, /**< problem statistics */
523  SCIP_PRIMAL* primal, /**< primal data */
524  SCIP_TREE* tree, /**< branch and bound tree */
525  SCIP_REOPT* reopt, /**< reoptimization data structure */
526  SCIP_LP* lp, /**< current LP data */
527  SCIP_BRANCHCAND* branchcand, /**< branching candidate storage */
528  SCIP_EVENTFILTER* eventfilter, /**< event filter for global (not variable dependent) events */
529  SCIP_EVENTQUEUE* eventqueue, /**< event queue */
530  SCIP_CONFLICTSTORE* conflictstore, /**< conflict store */
531  SCIP_PROB** target /**< pointer to target problem data structure */
532  )
533 {
534  SCIP_VAR* targetvar;
535  SCIP_CONS* targetcons;
536  char transname[SCIP_MAXSTRLEN];
537  int v;
538  int c;
539  int h;
540 
541  assert(set != NULL);
542  assert(source != NULL);
543  assert(blkmem != NULL);
544  assert(target != NULL);
545 
546  SCIPsetDebugMsg(set, "transform problem: original has %d variables\n", source->nvars);
547 
548  /* create target problem data (probdelorig and probtrans are not needed, probdata is set later) */
549  (void) SCIPsnprintf(transname, SCIP_MAXSTRLEN, "t_%s", source->name);
550  SCIP_CALL( SCIPprobCreate(target, blkmem, set, transname, source->probdelorig, source->probtrans, source->probdeltrans,
551  source->probinitsol, source->probexitsol, source->probcopy, NULL, TRUE) );
552  SCIPprobSetObjsense(*target, source->objsense);
553 
554  /* transform objective limit */
555  if( source->objlim < SCIP_INVALID )
556  SCIPprobSetObjlim(*target, source->objlim);
557 
558  /* transform dual bound */
559  if( source->dualbound < SCIP_INVALID )
560  SCIPprobSetDualbound(*target, source->dualbound);
561 
562  /* transform and copy all variables to target problem */
563  SCIP_CALL( probEnsureVarsMem(*target, set, source->nvars) );
564  for( v = 0; v < source->nvars; ++v )
565  {
566  SCIP_CALL( SCIPvarTransform(source->vars[v], blkmem, set, stat, source->objsense, &targetvar) );
567  SCIP_CALL( SCIPprobAddVar(*target, blkmem, set, lp, branchcand, eventfilter, eventqueue, targetvar) );
568  SCIP_CALL( SCIPvarRelease(&targetvar, blkmem, set, eventqueue, NULL) );
569  }
570  assert((*target)->nvars == source->nvars);
571  assert((*target)->nobjvars == SCIPprobGetNObjVars(*target, set));
572 
573  /* call user data transformation */
574  if( source->probtrans != NULL )
575  {
576  SCIP_CALL( source->probtrans(set->scip, source->probdata, &(*target)->probdata) );
577  }
578  else
579  (*target)->probdata = source->probdata;
580 
581  /* transform and copy all constraints to target problem */
582  for( c = 0; c < source->nconss; ++c )
583  {
584  SCIP_CALL( SCIPconsTransform(source->conss[c], blkmem, set, &targetcons) );
585  SCIP_CALL( SCIPprobAddCons(*target, set, stat, targetcons) );
586  SCIP_CALL( SCIPconsRelease(&targetcons, blkmem, set) );
587  }
588 
589  /* lock variables for all constraint handlers that don't need constraints */
590  for( h = 0; h < set->nconshdlrs; ++h )
591  {
592  if( !SCIPconshdlrNeedsCons(set->conshdlrs[h]) )
593  {
594  SCIP_CALL( SCIPconshdlrLockVars(set->conshdlrs[h], set) );
595  }
596  }
597 
598  /* objective value is always integral, iff original objective value is always integral and shift is integral */
599  (*target)->objisintegral = source->objisintegral && SCIPsetIsIntegral(set, (*target)->objoffset);
600 
601  /* check, whether objective value is always integral by inspecting the problem, if it is the case adjust the
602  * cutoff bound if primal solution is already known
603  */
604  SCIP_CALL( SCIPprobCheckObjIntegral(*target, source, blkmem, set, stat, primal, tree, reopt, lp, eventfilter, eventqueue) );
605 
606  /* copy the nlpenabled flag */
607  (*target)->nlpenabled = source->nlpenabled;
608 
609  /* mark the transformed problem to be permuted iff the source problem is permuted */
610  (*target)->permuted = source->permuted;
611 
612  /* transform the conflict pool */
613  SCIP_CALL( SCIPconflictstoreTransform(conflictstore, blkmem, set, stat, tree, *target, reopt) );
614 
615  return SCIP_OKAY;
616 }
617 
618 /** resets the global and local bounds of original variables in original problem to their original values */
620  SCIP_PROB* prob, /**< original problem data */
621  BMS_BLKMEM* blkmem, /**< block memory */
622  SCIP_SET* set, /**< global SCIP settings */
623  SCIP_STAT* stat /**< problem statistics */
624  )
625 {
626  int v;
627 
628  assert(prob != NULL);
629  assert(prob->nfixedvars == 0);
630 
631  for( v = 0; v < prob->nvars; ++v )
632  {
633  SCIP_CALL( SCIPvarResetBounds(prob->vars[v], blkmem, set, stat) );
634  }
635 
636  return SCIP_OKAY;
637 }
638 
639 /** (Re)Sort the variables, which appear in the four categories (binary, integer, implicit, continuous) after presolve
640  * with respect to their original index (within their categories). Adjust the problem index afterwards which is
641  * supposed to reflect the position in the variable array. This additional (re)sorting is supposed to get more robust
642  * against the order presolving fixed variables. (We also reobtain a possible block structure induced by the user
643  * model)
644  */
646  SCIP_PROB* prob /**< problem data */
647  )
648 {
649  SCIP_VAR** vars;
650  int nbinvars;
651  int nintvars;
652  int nimplvars;
653  int ncontvars;
654  int nvars;
655  int v;
656 
657  vars = prob->vars;
658  nvars = prob->nvars;
659  nbinvars = prob->nbinvars;
660  nintvars = prob->nintvars;
661  nimplvars = prob->nimplvars;
662  ncontvars = prob->ncontvars;
663 
664  if( nvars == 0 )
665  return;
666 
667  assert(vars != NULL);
668  assert(nbinvars + nintvars + nimplvars + ncontvars == nvars);
669 
670  SCIPdebugMessage("entering sorting with respect to original block structure! \n");
671 
672  /* sort binaries */
673  if( nbinvars > 0 )
674  SCIPsortPtr((void**)vars, SCIPvarComp, nbinvars);
675 
676  /* sort integers */
677  if( nintvars > 0 )
678  SCIPsortPtr((void**)&vars[nbinvars], SCIPvarComp, nintvars);
679 
680  /* sort implicit variables */
681  if( nimplvars > 0 )
682  SCIPsortPtr((void**)&vars[nbinvars + nintvars], SCIPvarComp, nimplvars);
683 
684  /* sort continuous variables*/
685  if( ncontvars > 0 )
686  SCIPsortPtr((void**)&vars[nbinvars + nintvars + nimplvars], SCIPvarComp, ncontvars);
687 
688  /* after sorting, the problem index of each variable has to be adjusted */
689  for( v = 0; v < nvars; ++v )
690  {
691  vars[v]->probindex = v;
692  SCIPdebugMessage("Variable: Problem index <%d>, original index <%d> \n", vars[v]->probindex, vars[v]->index);
693  }
694 }
695 
696 
697 
698 /*
699  * problem modification
700  */
701 
702 /** sets user problem data */
704  SCIP_PROB* prob, /**< problem */
705  SCIP_PROBDATA* probdata /**< user problem data to use */
706  )
707 {
708  assert(prob != NULL);
709 
710  prob->probdata = probdata;
711 }
712 
713 /** inserts variable at the correct position in vars array, depending on its type */
714 static
716  SCIP_PROB* prob, /**< problem data */
717  SCIP_VAR* var /**< variable to insert */
718  )
719 {
720  int insertpos;
721  int intstart;
722  int implstart;
723  int contstart;
724 
725  assert(prob != NULL);
726  assert(prob->vars != NULL);
727  assert(prob->nvars < prob->varssize);
728  assert(var != NULL);
729  assert(SCIPvarGetProbindex(var) == -1);
733  /* original variables cannot go into transformed problem and transformed variables cannot go into original problem */
734  assert((SCIPvarGetStatus(var) != SCIP_VARSTATUS_ORIGINAL) == prob->transformed);
735 
736  /* insert variable in array */
737  insertpos = prob->nvars;
738  intstart = prob->nbinvars;
739  implstart = intstart + prob->nintvars;
740  contstart = implstart + prob->nimplvars;
741 
743  prob->ncontvars++;
744  else
745  {
746  if( insertpos > contstart )
747  {
748  prob->vars[insertpos] = prob->vars[contstart];
749  SCIPvarSetProbindex(prob->vars[insertpos], insertpos);
750  insertpos = contstart;
751  }
752  assert(insertpos == contstart);
753 
755  prob->nimplvars++;
756  else
757  {
758  if( insertpos > implstart )
759  {
760  prob->vars[insertpos] = prob->vars[implstart];
761  SCIPvarSetProbindex(prob->vars[insertpos], insertpos);
762  insertpos = implstart;
763  }
764  assert(insertpos == implstart);
765 
767  prob->nintvars++;
768  else
769  {
770  assert(SCIPvarGetType(var) == SCIP_VARTYPE_BINARY);
771  if( insertpos > intstart )
772  {
773  prob->vars[insertpos] = prob->vars[intstart];
774  SCIPvarSetProbindex(prob->vars[insertpos], insertpos);
775  insertpos = intstart;
776  }
777  assert(insertpos == intstart);
778 
779  prob->nbinvars++;
780  }
781  }
782  }
783  prob->nvars++;
784 
785  assert(prob->nvars == prob->nbinvars + prob->nintvars + prob->nimplvars + prob->ncontvars);
786  assert((SCIPvarGetType(var) == SCIP_VARTYPE_BINARY && insertpos == prob->nbinvars - 1)
787  || (SCIPvarGetType(var) == SCIP_VARTYPE_INTEGER && insertpos == prob->nbinvars + prob->nintvars - 1)
788  || (SCIPvarGetType(var) == SCIP_VARTYPE_IMPLINT && insertpos == prob->nbinvars + prob->nintvars + prob->nimplvars - 1)
790  && insertpos == prob->nbinvars + prob->nintvars + prob->nimplvars + prob->ncontvars - 1));
791 
792  prob->vars[insertpos] = var;
793  SCIPvarSetProbindex(var, insertpos);
794 
795  /* update number of column variables in problem */
797  prob->ncolvars++;
798  assert(0 <= prob->ncolvars && prob->ncolvars <= prob->nvars);
799 }
800 
801 /** removes variable from vars array */
802 static
804  SCIP_PROB* prob, /**< problem data */
805  BMS_BLKMEM* blkmem, /**< block memory */
806  SCIP_CLIQUETABLE* cliquetable, /**< clique table data structure */
807  SCIP_SET* set, /**< global SCIP settings */
808  SCIP_VAR* var /**< variable to remove */
809  )
810 {
811  int freepos;
812  int intstart;
813  int implstart;
814  int contstart;
815 
816  assert(prob != NULL);
817  assert(var != NULL);
818  assert(SCIPvarGetProbindex(var) >= 0);
819  assert(prob->vars != NULL);
820  assert(prob->vars[SCIPvarGetProbindex(var)] == var);
821 
822  intstart = prob->nbinvars;
823  implstart = intstart + prob->nintvars;
824  contstart = implstart + prob->nimplvars;
825 
826  switch( SCIPvarGetType(var) )
827  {
828  case SCIP_VARTYPE_BINARY:
829  assert(0 <= SCIPvarGetProbindex(var) && SCIPvarGetProbindex(var) < intstart);
830  prob->nbinvars--;
831  break;
833  assert(intstart <= SCIPvarGetProbindex(var) && SCIPvarGetProbindex(var) < implstart);
834  prob->nintvars--;
835  break;
837  assert(implstart <= SCIPvarGetProbindex(var) && SCIPvarGetProbindex(var) < contstart);
838  prob->nimplvars--;
839  break;
841  assert(contstart <= SCIPvarGetProbindex(var) && SCIPvarGetProbindex(var) < prob->nvars);
842  prob->ncontvars--;
843  break;
844  default:
845  SCIPerrorMessage("unknown variable type\n");
846  SCIPABORT();
847  return SCIP_INVALIDDATA; /*lint !e527*/
848  }
849 
850  /* move last binary, last integer, last implicit, and last continuous variable forward to fill the free slot */
851  freepos = SCIPvarGetProbindex(var);
852  if( freepos < intstart-1 )
853  {
854  /* move last binary variable to free slot */
855  prob->vars[freepos] = prob->vars[intstart-1];
856  SCIPvarSetProbindex(prob->vars[freepos], freepos);
857  freepos = intstart-1;
858  }
859  if( freepos < implstart-1 )
860  {
861  /* move last integer variable to free slot */
862  prob->vars[freepos] = prob->vars[implstart-1];
863  SCIPvarSetProbindex(prob->vars[freepos], freepos);
864  freepos = implstart-1;
865  }
866  if( freepos < contstart-1 )
867  {
868  /* move last implicit integer variable to free slot */
869  prob->vars[freepos] = prob->vars[contstart-1];
870  SCIPvarSetProbindex(prob->vars[freepos], freepos);
871  freepos = contstart-1;
872  }
873  if( freepos < prob->nvars-1 )
874  {
875  /* move last implicit integer variable to free slot */
876  prob->vars[freepos] = prob->vars[prob->nvars-1];
877  SCIPvarSetProbindex(prob->vars[freepos], freepos);
878  freepos = prob->nvars-1;
879  }
880  assert(freepos == prob->nvars-1);
881 
882  prob->nvars--;
883  assert(prob->nvars == prob->nbinvars + prob->nintvars + prob->nimplvars + prob->ncontvars);
884 
885  /* update number of column variables in problem */
887  prob->ncolvars--;
888  assert(0 <= prob->ncolvars && prob->ncolvars <= prob->nvars);
889 
890  /* inform the variable that it is no longer in the problem; if necessary, delete it from the implication graph */
891  SCIP_CALL( SCIPvarRemove(var, blkmem, cliquetable, set, FALSE) );
892 
893  return SCIP_OKAY;
894 }
895 
896 /** adds variable's name to the namespace */
898  SCIP_PROB* prob, /**< problem data */
899  SCIP_VAR* var /**< variable */
900  )
901 {
902  assert(SCIPvarGetProbindex(var) != -1);
903 
904  if( varHasName(var) && prob->varnames != NULL )
905  {
906  SCIP_CALL( SCIPhashtableInsert(prob->varnames, (void*)var) );
907  }
908 
909  return SCIP_OKAY;
910 }
911 
912 /** removes variable's name from the namespace */
914  SCIP_PROB* prob, /**< problem data */
915  SCIP_VAR* var /**< variable */
916  )
917 {
918  if( varHasName(var) && prob->varnames != NULL )
919  {
920  assert(SCIPhashtableExists(prob->varnames, (void*)var));
921  SCIP_CALL( SCIPhashtableRemove(prob->varnames, (void*)var) );
922  }
923 
924  return SCIP_OKAY;
925 }
926 
927 /** adds variable to the problem and captures it */
929  SCIP_PROB* prob, /**< problem data */
930  BMS_BLKMEM* blkmem, /**< block memory buffers */
931  SCIP_SET* set, /**< global SCIP settings */
932  SCIP_LP* lp, /**< current LP data */
933  SCIP_BRANCHCAND* branchcand, /**< branching candidate storage */
934  SCIP_EVENTFILTER* eventfilter, /**< event filter for global (not variable dependent) events */
935  SCIP_EVENTQUEUE* eventqueue, /**< event queue */
936  SCIP_VAR* var /**< variable to add */
937  )
938 {
939  assert(prob != NULL);
940  assert(set != NULL);
941  assert(var != NULL);
942  assert(SCIPvarGetProbindex(var) == -1);
946  /* original variables cannot go into transformed problem and transformed variables cannot go into original problem */
947  assert((SCIPvarGetStatus(var) != SCIP_VARSTATUS_ORIGINAL) == prob->transformed);
948 
949 #ifndef NDEBUG
950  /* check if we add this variables to the same scip, where we created it */
951  if( var->scip != set->scip )
952  {
953  SCIPerrorMessage("variable belongs to a different scip instance\n");
954  return SCIP_INVALIDDATA;
955  }
956 #endif
957 
958  /* capture variable */
959  SCIPvarCapture(var);
960 
961  /* allocate additional memory */
962  SCIP_CALL( probEnsureVarsMem(prob, set, prob->nvars+1) );
963 
964  /* insert variable in vars array and mark it to be in problem */
965  probInsertVar(prob, var);
966 
967  /* add variable's name to the namespace */
968  SCIP_CALL( SCIPprobAddVarName(prob, var) );
969 
970  /* update branching candidates and pseudo and loose objective value in the LP */
972  {
973  SCIP_CALL( SCIPbranchcandUpdateVar(branchcand, set, var) );
974  SCIP_CALL( SCIPlpUpdateAddVar(lp, set, var) );
975  }
976 
977  SCIPsetDebugMsg(set, "added variable <%s> to problem (%d variables: %d binary, %d integer, %d implicit, %d continuous)\n",
978  SCIPvarGetName(var), prob->nvars, prob->nbinvars, prob->nintvars, prob->nimplvars, prob->ncontvars);
979 
980  if( prob->transformed )
981  {
982  SCIP_EVENT* event;
983 
984  /* issue VARADDED event */
985  SCIP_CALL( SCIPeventCreateVarAdded(&event, blkmem, var) );
986  SCIP_CALL( SCIPeventqueueAdd(eventqueue, blkmem, set, NULL, NULL, NULL, eventfilter, &event) );
987 
988  /* update the number of variables with non-zero objective coefficient */
989  SCIPprobUpdateNObjVars(prob, set, 0.0, SCIPvarGetObj(var));
990 
991  /* SCIP assumes that the status of objisintegral does not change after transformation. Thus, the objective of all
992  * new variables beyond that stage has to be compatible. */
993  assert( SCIPsetGetStage(set) == SCIP_STAGE_TRANSFORMING || ! prob->objisintegral || SCIPsetIsZero(set, SCIPvarGetObj(var)) ||
994  ( SCIPvarIsIntegral(var) && SCIPsetIsIntegral(set, SCIPvarGetObj(var)) ) );
995  }
996 
997  return SCIP_OKAY;
998 }
999 
1000 /** marks variable to be removed from the problem; however, the variable is NOT removed from the constraints */
1002  SCIP_PROB* prob, /**< problem data */
1003  BMS_BLKMEM* blkmem, /**< block memory */
1004  SCIP_SET* set, /**< global SCIP settings */
1005  SCIP_EVENTQUEUE* eventqueue, /**< event queue */
1006  SCIP_VAR* var, /**< problem variable */
1007  SCIP_Bool* deleted /**< pointer to store whether marking variable to be deleted was successful */
1008  )
1009 {
1010  assert(prob != NULL);
1011  assert(set != NULL);
1012  assert(var != NULL);
1013  assert(deleted != NULL);
1014  assert(SCIPvarGetProbindex(var) != -1);
1018 
1019  *deleted = FALSE;
1020 
1021  /* don't remove variables that are not in the problem */
1022  /**@todo what about negated variables? should the negation variable be removed instead? */
1023  if( SCIPvarGetProbindex(var) == -1 )
1024  return SCIP_OKAY;
1025 
1026  /* don't remove the direct counterpart of an original variable from the transformed problem, because otherwise
1027  * operations on the original variables would be applied to a NULL pointer
1028  */
1029  if( SCIPvarIsTransformedOrigvar(var) )
1030  return SCIP_OKAY;
1031 
1032  assert(SCIPvarGetNegatedVar(var) == NULL);
1033 
1034  SCIPsetDebugMsg(set, "deleting variable <%s> from problem (%d variables: %d binary, %d integer, %d implicit, %d continuous)\n",
1035  SCIPvarGetName(var), prob->nvars, prob->nbinvars, prob->nintvars, prob->nimplvars, prob->ncontvars);
1036 
1037  /* mark variable to be deleted from the problem */
1038  SCIPvarMarkDeleted(var);
1039 
1040  if( prob->transformed )
1041  {
1042  SCIP_EVENT* event;
1043 
1044  assert(eventqueue != NULL);
1045 
1046  /* issue VARDELETED event */
1047  SCIP_CALL( SCIPeventCreateVarDeleted(&event, blkmem, var) );
1048  SCIP_CALL( SCIPeventqueueAdd(eventqueue, blkmem, set, NULL, NULL, NULL, NULL, &event) );
1049  }
1050 
1051  /* remember that the variable should be deleted from the problem in SCIPprobPerformVarDeletions() */
1052  SCIP_CALL( probEnsureDeletedvarsMem(prob, set, prob->ndeletedvars+1) );
1053  prob->deletedvars[prob->ndeletedvars] = var;
1054  prob->ndeletedvars++;
1055 
1056  *deleted = TRUE;
1057 
1058  return SCIP_OKAY;
1059 }
1060 
1061 /** actually removes the deleted variables from the problem and releases them */
1063  SCIP_PROB* prob, /**< problem data */
1064  BMS_BLKMEM* blkmem, /**< block memory */
1065  SCIP_SET* set, /**< global SCIP settings */
1066  SCIP_STAT* stat, /**< dynamic problem statistics */
1067  SCIP_EVENTQUEUE* eventqueue, /**< event queue */
1068  SCIP_CLIQUETABLE* cliquetable, /**< clique table data structure */
1069  SCIP_LP* lp, /**< current LP data (may be NULL) */
1070  SCIP_BRANCHCAND* branchcand /**< branching candidate storage */
1071  )
1072 {
1073  int i;
1074 
1075  assert(prob != NULL);
1076  assert(set != NULL);
1077 
1078  /* delete variables from the constraints;
1079  * do this only in solving stage, in presolving, it is already handled by the constraint handlers
1080  */
1081  if( SCIPsetGetStage(set) == SCIP_STAGE_SOLVING )
1082  {
1083  for( i = 0; i < set->nconshdlrs; ++i )
1084  {
1085  SCIP_CALL( SCIPconshdlrDelVars(set->conshdlrs[i], blkmem, set, stat) );
1086  }
1087  }
1088 
1089  for( i = 0; i < prob->ndeletedvars; ++i )
1090  {
1091  SCIP_VAR* var;
1092 
1093  var = prob->deletedvars[i];
1094 
1095  /* don't delete the variable, if it was fixed or aggregated in the meantime */
1096  if( SCIPvarGetProbindex(var) >= 0 )
1097  {
1098  SCIPsetDebugMsg(set, "perform deletion of <%s> [%p]\n", SCIPvarGetName(var), (void*)var);
1099 
1100  /* convert column variable back into loose variable, free LP column */
1102  {
1103  SCIP_CALL( SCIPvarLoose(var, blkmem, set, eventqueue, prob, lp) );
1104  }
1105 
1106  /* update branching candidates and pseudo and loose objective value in the LP */
1108  {
1109  SCIP_CALL( SCIPlpUpdateDelVar(lp, set, var) );
1110  SCIP_CALL( SCIPbranchcandRemoveVar(branchcand, var) );
1111  }
1112 
1113  /* remove variable's name from the namespace */
1114  SCIP_CALL( SCIPprobRemoveVarName(prob, var) );
1115 
1116  /* remove variable from vars array and mark it to be not in problem */
1117  SCIP_CALL( probRemoveVar(prob, blkmem, cliquetable, set, var) );
1118 
1119  /* update the number of variables with non-zero objective coefficient */
1120  if( prob->transformed )
1121  SCIPprobUpdateNObjVars(prob, set, SCIPvarGetObj(var), 0.0);
1122 
1123  /* release variable */
1124  SCIP_CALL( SCIPvarRelease(&prob->deletedvars[i], blkmem, set, eventqueue, lp) );
1125  }
1126  }
1127  prob->ndeletedvars = 0;
1128 
1129  return SCIP_OKAY;
1130 }
1131 
1132 /** changes the type of a variable in the problem */
1134  SCIP_PROB* prob, /**< problem data */
1135  BMS_BLKMEM* blkmem, /**< block memory */
1136  SCIP_SET* set, /**< global SCIP settings */
1137  SCIP_PRIMAL* primal, /**< primal data */
1138  SCIP_LP* lp, /**< current LP data */
1139  SCIP_BRANCHCAND* branchcand, /**< branching candidate storage */
1140  SCIP_EVENTQUEUE* eventqueue, /**< event queue */
1141  SCIP_CLIQUETABLE* cliquetable, /**< clique table data structure */
1142  SCIP_VAR* var, /**< variable to add */
1143  SCIP_VARTYPE vartype /**< new type of variable */
1144  )
1145 {
1146  assert(prob != NULL);
1147  assert(var != NULL);
1148  assert(SCIPvarGetProbindex(var) >= 0);
1152  assert(branchcand != NULL || SCIPvarGetStatus(var) == SCIP_VARSTATUS_ORIGINAL);
1153 
1154  if( SCIPvarGetType(var) == vartype )
1155  return SCIP_OKAY;
1156 
1157  /* temporarily remove variable from branching candidates */
1158  if( branchcand != NULL )
1159  {
1160  SCIP_CALL( SCIPbranchcandRemoveVar(branchcand, var) );
1161  }
1162 
1163  /* temporarily remove variable from problem */
1164  SCIP_CALL( probRemoveVar(prob, blkmem, cliquetable, set, var) );
1165 
1166  /* change the type of the variable */
1167  SCIP_CALL( SCIPvarChgType(var, blkmem, set, primal, lp, eventqueue, vartype) );
1168 
1169  /* reinsert variable into problem */
1170  probInsertVar(prob, var);
1171 
1172  /* update branching candidates */
1173  if( branchcand != NULL )
1174  {
1175  SCIP_CALL( SCIPbranchcandUpdateVar(branchcand, set, var) );
1176  }
1177 
1178  return SCIP_OKAY;
1179 }
1180 
1181 /** informs problem, that the given loose problem variable changed its status */
1183  SCIP_PROB* prob, /**< problem data */
1184  BMS_BLKMEM* blkmem, /**< block memory */
1185  SCIP_SET* set, /**< global SCIP settings */
1186  SCIP_BRANCHCAND* branchcand, /**< branching candidate storage */
1187  SCIP_CLIQUETABLE* cliquetable, /**< clique table data structure */
1188  SCIP_VAR* var /**< problem variable */
1189  )
1190 {
1191  assert(prob != NULL);
1192  assert(var != NULL);
1193  assert(SCIPvarGetProbindex(var) != -1);
1194 
1195  /* get current status of variable */
1196  switch( SCIPvarGetStatus(var) )
1197  {
1199  SCIPerrorMessage("variables cannot switch to ORIGINAL status\n");
1200  return SCIP_INVALIDDATA;
1201 
1202  case SCIP_VARSTATUS_LOOSE:
1203  /* variable switched from column to loose */
1204  prob->ncolvars--;
1205  break;
1206 
1207  case SCIP_VARSTATUS_COLUMN:
1208  /* variable switched from non-column to column */
1209  prob->ncolvars++;
1210  break;
1211 
1212  case SCIP_VARSTATUS_FIXED:
1216  /* variable switched from unfixed to fixed (if it was fixed before, probindex would have been -1) */
1217 
1218  /* remove variable from problem */
1219  SCIP_CALL( probRemoveVar(prob, blkmem, cliquetable, set, var) );
1220 
1221  /* insert variable in fixedvars array */
1222  SCIP_CALL( probEnsureFixedvarsMem(prob, set, prob->nfixedvars+1) );
1223  prob->fixedvars[prob->nfixedvars] = var;
1224  prob->nfixedvars++;
1225 
1226  /* update branching candidates */
1227  SCIP_CALL( SCIPbranchcandUpdateVar(branchcand, set, var) );
1228  break;
1229 
1230  default:
1231  SCIPerrorMessage("invalid variable status <%d>\n", SCIPvarGetStatus(var));
1232  return SCIP_INVALIDDATA;
1233  }
1234  assert(0 <= prob->ncolvars && prob->ncolvars <= prob->nvars);
1235 
1236  return SCIP_OKAY;
1237 }
1238 
1239 /** adds constraint's name to the namespace */
1241  SCIP_PROB* prob, /**< problem data */
1242  SCIP_CONS* cons /**< constraint */
1243  )
1244 {
1245  /* add constraint's name to the namespace */
1246  if( consHasName(cons) && prob->consnames != NULL )
1247  {
1248  SCIP_CALL( SCIPhashtableInsert(prob->consnames, (void*)cons) );
1249  }
1250 
1251  return SCIP_OKAY;
1252 }
1253 
1254 /** remove constraint's name from the namespace */
1256  SCIP_PROB* prob, /**< problem data */
1257  SCIP_CONS* cons /**< constraint */
1258  )
1259 {
1260  /* remove constraint's name from the namespace */
1261  if( consHasName(cons) && prob->consnames != NULL )
1262  {
1263  SCIP_CONS* currentcons;
1264  currentcons = (SCIP_CONS*)SCIPhashtableRetrieve(prob->consnames, (void*)(cons->name));
1265  if( currentcons == cons )
1266  {
1267  SCIP_CALL( SCIPhashtableRemove(prob->consnames, (void*)cons) );
1268  }
1269  }
1270 
1271  return SCIP_OKAY;
1272 }
1273 
1274 /** adds constraint to the problem and captures it;
1275  * a local constraint is automatically upgraded into a global constraint
1276  */
1278  SCIP_PROB* prob, /**< problem data */
1279  SCIP_SET* set, /**< global SCIP settings */
1280  SCIP_STAT* stat, /**< dynamic problem statistics */
1281  SCIP_CONS* cons /**< constraint to add */
1282  )
1283 {
1284  assert(prob != NULL);
1285  assert(cons != NULL);
1286  assert(cons->addconssetchg == NULL);
1287  assert(cons->addarraypos == -1);
1288 
1289 #ifndef NDEBUG
1290  /* check if we add this constraint to the same scip, where we create the constraint */
1291  if( cons->scip != set->scip )
1292  {
1293  SCIPerrorMessage("constraint belongs to different scip instance\n");
1294  return SCIP_INVALIDDATA;
1295  }
1296 #endif
1297  SCIPsetDebugMsg(set, "adding constraint <%s> to global problem -> %d constraints\n",
1298  SCIPconsGetName(cons), prob->nconss+1);
1299 
1300  /* mark the constraint as problem constraint, and remember the constraint's position */
1301  cons->addconssetchg = NULL;
1302  cons->addarraypos = prob->nconss;
1303 
1304  /* add the constraint to the problem's constraint array */
1305  SCIP_CALL( probEnsureConssMem(prob, set, prob->nconss+1) );
1306  prob->conss[prob->nconss] = cons;
1307  prob->nconss++;
1308  prob->maxnconss = MAX(prob->maxnconss, prob->nconss);
1309  stat->nactiveconssadded++;
1310 
1311  /* undelete constraint, if it was globally deleted in the past */
1312  cons->deleted = FALSE;
1313 
1314  /* mark constraint to be globally valid */
1315  SCIPconsSetLocal(cons, FALSE);
1316 
1317  /* capture constraint */
1318  SCIPconsCapture(cons);
1319 
1320  /* add constraint's name to the namespace */
1321  SCIP_CALL( SCIPprobAddConsName(prob, cons) );
1322 
1323  /* if the problem is the transformed problem, activate and lock constraint */
1324  if( prob->transformed )
1325  {
1326  /* activate constraint */
1327  if( !SCIPconsIsActive(cons) )
1328  {
1329  SCIP_CALL( SCIPconsActivate(cons, set, stat, -1, (stat->nnodes <= 1)) );
1330  }
1331 
1332  /* if constraint is a check-constraint, lock roundings of constraint's variables */
1333  if( SCIPconsIsChecked(cons) )
1334  {
1335  SCIP_CALL( SCIPconsAddLocks(cons, set, SCIP_LOCKTYPE_MODEL, +1, 0) );
1336  }
1337  }
1338 
1339  return SCIP_OKAY;
1340 }
1341 
1342 /** releases and removes constraint from the problem; if the user has not captured the constraint for his own use, the
1343  * constraint may be invalid after the call
1344  */
1346  SCIP_PROB* prob, /**< problem data */
1347  BMS_BLKMEM* blkmem, /**< block memory */
1348  SCIP_SET* set, /**< global SCIP settings */
1349  SCIP_STAT* stat, /**< dynamic problem statistics */
1350  SCIP_CONS* cons /**< constraint to remove */
1351  )
1352 {
1353  int arraypos;
1354 
1355  assert(prob != NULL);
1356  assert(blkmem != NULL);
1357  assert(cons != NULL);
1358  assert(cons->addconssetchg == NULL);
1359  assert(0 <= cons->addarraypos && cons->addarraypos < prob->nconss);
1360  assert(prob->conss != NULL);
1361  assert(prob->conss[cons->addarraypos] == cons);
1362 
1363  /* if the problem is the transformed problem, deactivate and unlock constraint */
1364  if( prob->transformed )
1365  {
1366  /* if constraint is a check-constraint, unlock roundings of constraint's variables */
1367  if( SCIPconsIsChecked(cons) )
1368  {
1369  SCIP_CALL( SCIPconsAddLocks(cons, set, SCIP_LOCKTYPE_MODEL, -1, 0) );
1370  }
1371 
1372  /* deactivate constraint, if it is currently active */
1373  if( cons->active && !cons->updatedeactivate )
1374  {
1375  SCIP_CALL( SCIPconsDeactivate(cons, set, stat) );
1376  }
1377  }
1378  assert(!cons->active || cons->updatedeactivate);
1379  assert(!cons->enabled || cons->updatedeactivate);
1380 
1381  /* remove constraint's name from the namespace */
1382  SCIP_CALL( SCIPprobRemoveConsName(prob, cons) );
1383 
1384  /* remove the constraint from the problem's constraint array */
1385  arraypos = cons->addarraypos;
1386  prob->conss[arraypos] = prob->conss[prob->nconss-1];
1387  assert(prob->conss[arraypos] != NULL);
1388  assert(prob->conss[arraypos]->addconssetchg == NULL);
1389  prob->conss[arraypos]->addarraypos = arraypos;
1390  prob->nconss--;
1391 
1392  /* mark the constraint to be no longer in the problem */
1393  cons->addarraypos = -1;
1394 
1395  /* release constraint */
1396  SCIP_CALL( SCIPconsRelease(&cons, blkmem, set) );
1397 
1398  return SCIP_OKAY;
1399 }
1400 
1401 /** remembers the current number of constraints in the problem's internal data structure
1402  * - resets maximum number of constraints to current number of constraints
1403  * - remembers current number of constraints as starting number of constraints
1404  */
1406  SCIP_PROB* prob /**< problem data */
1407  )
1408 {
1409  assert(prob != NULL);
1410 
1411  /* remember number of constraints for statistic */
1412  prob->maxnconss = prob->nconss;
1413  prob->startnvars = prob->nvars;
1414  prob->startnconss = prob->nconss;
1415 }
1416 
1417 /** sets objective sense: minimization or maximization */
1419  SCIP_PROB* prob, /**< problem data */
1420  SCIP_OBJSENSE objsense /**< new objective sense */
1421  )
1422 {
1423  assert(prob != NULL);
1424  assert(prob->objsense == SCIP_OBJSENSE_MAXIMIZE || prob->objsense == SCIP_OBJSENSE_MINIMIZE);
1425  assert(objsense == SCIP_OBJSENSE_MAXIMIZE || objsense == SCIP_OBJSENSE_MINIMIZE);
1426 
1427  prob->objsense = objsense;
1428 }
1429 
1430 /** adds value to objective offset */
1432  SCIP_PROB* prob, /**< problem data */
1433  SCIP_Real addval /**< value to add to objective offset */
1434  )
1435 {
1436  assert(prob != NULL);
1437  assert(prob->transformed);
1438 
1439  SCIPdebugMessage("adding %g to objective offset %g: new offset = %g\n", addval, prob->objoffset, prob->objoffset + addval);
1440  prob->objoffset += addval;
1441 }
1442 
1443 /** sets the dual bound on objective function */
1445  SCIP_PROB* prob, /**< problem data */
1446  SCIP_Real dualbound /**< external dual bound */
1447  )
1448 {
1449  assert(prob != NULL);
1450 
1451  prob->dualbound = dualbound;
1452 }
1453 
1454 /** sets limit on objective function, such that only solutions better than this limit are accepted */
1456  SCIP_PROB* prob, /**< problem data */
1457  SCIP_Real objlim /**< external objective limit */
1458  )
1459 {
1460  assert(prob != NULL);
1461 
1462  prob->objlim = objlim;
1463 }
1464 
1465 /** informs the problem, that its objective value is always integral in every feasible solution */
1467  SCIP_PROB* prob /**< problem data */
1468  )
1469 {
1470  assert(prob != NULL);
1471 
1472  prob->objisintegral = TRUE;
1473 }
1474 
1475 /** sets integral objective value flag, if all variables with non-zero objective values are integral and have
1476  * integral objective value and also updates the cutoff bound if primal solution is already known
1477  */
1479  SCIP_PROB* transprob, /**< tranformed problem data */
1480  SCIP_PROB* origprob, /**< original problem data */
1481  BMS_BLKMEM* blkmem, /**< block memory */
1482  SCIP_SET* set, /**< global SCIP settings */
1483  SCIP_STAT* stat, /**< problem statistics data */
1484  SCIP_PRIMAL* primal, /**< primal data */
1485  SCIP_TREE* tree, /**< branch and bound tree */
1486  SCIP_REOPT* reopt, /**< reoptimization data structure */
1487  SCIP_LP* lp, /**< current LP data */
1488  SCIP_EVENTFILTER* eventfilter, /**< event filter for global (not variable dependent) events */
1489  SCIP_EVENTQUEUE* eventqueue /**< event queue */
1490  )
1491 {
1492  SCIP_Real obj;
1493  int v;
1494 
1495  assert(transprob != NULL);
1496  assert(origprob != NULL);
1497 
1498  /* if we know already, that the objective value is integral, nothing has to be done */
1499  if( transprob->objisintegral )
1500  return SCIP_OKAY;
1501 
1502  /* if there exist unknown variables, we cannot conclude that the objective value is always integral */
1503  if( set->nactivepricers != 0 || set->nactivebenders != 0 )
1504  return SCIP_OKAY;
1505 
1506  /* if the objective value offset is fractional, the value itself is possibly fractional */
1507  if( !SCIPsetIsIntegral(set, transprob->objoffset) )
1508  return SCIP_OKAY;
1509 
1510  /* scan through the variables */
1511  for( v = 0; v < transprob->nvars; ++v )
1512  {
1513  /* get objective value of variable */
1514  obj = SCIPvarGetObj(transprob->vars[v]);
1515 
1516  /* check, if objective value is non-zero */
1517  if( !SCIPsetIsZero(set, obj) )
1518  {
1519  /* if variable's objective value is fractional, the problem's objective value may also be fractional */
1520  if( !SCIPsetIsIntegral(set, obj) )
1521  break;
1522 
1523  /* if variable with non-zero objective value is continuous, the problem's objective value may be fractional */
1524  if( SCIPvarGetType(transprob->vars[v]) == SCIP_VARTYPE_CONTINUOUS )
1525  break;
1526  }
1527  }
1528 
1529  /* objective value is integral, if the variable loop scanned all variables */
1530  if( v == transprob->nvars )
1531  {
1532  transprob->objisintegral = TRUE;
1533 
1534  /* update upper bound and cutoff bound in primal data structure due to new internality information */
1535  SCIP_CALL( SCIPprimalUpdateObjoffset(primal, blkmem, set, stat, eventfilter, eventqueue, transprob, origprob, tree, reopt, lp) );
1536  }
1537 
1538  return SCIP_OKAY;
1539 }
1540 
1541 /** update the number of variables with non-zero objective coefficient */
1543  SCIP_PROB* prob, /**< problem data */
1544  SCIP_SET* set, /**< global SCIP settings */
1545  SCIP_Real oldobj, /**< old objective value for variable */
1546  SCIP_Real newobj /**< new objective value for variable */
1547  )
1548 {
1549  assert(prob->transformed);
1550 
1551  if( !SCIPsetIsZero(set, oldobj) )
1552  prob->nobjvars--;
1553 
1554  if( !SCIPsetIsZero(set, newobj) )
1555  prob->nobjvars++;
1556 }
1557 
1558 /** update the dual bound if its better as the current one */
1560  SCIP_PROB* prob, /**< problem data */
1561  SCIP_Real newbound /**< new dual bound for the node (if it's tighter than the old one) */
1562  )
1563 {
1564  if( prob->dualbound == SCIP_INVALID ) /*lint !e777*/
1565  SCIPprobSetDualbound(prob, newbound);
1566  else
1567  {
1568  switch( prob->objsense )
1569  {
1571  prob->dualbound = MAX(newbound, prob->dualbound);
1572  break;
1573 
1575  prob->dualbound = MIN(newbound, prob->dualbound);
1576  break;
1577 
1578  default:
1579  SCIPerrorMessage("invalid objective sense <%d>\n", prob->objsense);
1580  SCIPABORT();
1581  }
1582  }
1583 }
1584 
1585 /** invalidates the dual bound */
1587  SCIP_PROB* prob /**< problem data */
1588  )
1589 {
1590  assert(prob != NULL);
1591 
1592  prob->dualbound = SCIP_INVALID;
1593 }
1594 
1595 /** if possible, scales objective function such that it is integral with gcd = 1 */
1597  SCIP_PROB* transprob, /**< tranformed problem data */
1598  SCIP_PROB* origprob, /**< original problem data */
1599  BMS_BLKMEM* blkmem, /**< block memory */
1600  SCIP_SET* set, /**< global SCIP settings */
1601  SCIP_STAT* stat, /**< problem statistics data */
1602  SCIP_PRIMAL* primal, /**< primal data */
1603  SCIP_TREE* tree, /**< branch and bound tree */
1604  SCIP_REOPT* reopt, /**< reoptimization data structure */
1605  SCIP_LP* lp, /**< current LP data */
1606  SCIP_EVENTFILTER* eventfilter, /**< event filter for global (not variable dependent) events */
1607  SCIP_EVENTQUEUE* eventqueue /**< event queue */
1608  )
1609 {
1610  int v;
1611  int nints;
1612 
1613  assert(transprob != NULL);
1614  assert(set != NULL);
1615 
1616  /* do not change objective if there are pricers involved */
1617  if( set->nactivepricers != 0 || set->nactivebenders != 0 || !set->misc_scaleobj )
1618  return SCIP_OKAY;
1619 
1620  nints = transprob->nvars - transprob->ncontvars;
1621 
1622  /* scan through the continuous variables */
1623  for( v = nints; v < transprob->nvars; ++v )
1624  {
1625  SCIP_Real obj;
1626 
1627  /* get objective value of variable; it it is non-zero, no scaling can be applied */
1628  obj = SCIPvarGetObj(transprob->vars[v]);
1629  if( !SCIPsetIsZero(set, obj) )
1630  break;
1631  }
1632 
1633  /* only continue if all continuous variables have obj = 0 */
1634  if( v == transprob->nvars )
1635  {
1636  SCIP_Real* objvals;
1637  SCIP_Real intscalar;
1638  SCIP_Bool success;
1639 
1640  /* get temporary memory */
1641  SCIP_CALL( SCIPsetAllocBufferArray(set, &objvals, nints) );
1642 
1643  /* get objective values of integer variables */
1644  for( v = 0; v < nints; ++v )
1645  objvals[v] = SCIPvarGetObj(transprob->vars[v]);
1646 
1647  /* calculate integral scalar */
1649  &intscalar, &success) );
1650 
1651  SCIPsetDebugMsg(set, "integral objective scalar: success=%u, intscalar=%g\n", success, intscalar);
1652 
1653  if( success )
1654  {
1655  SCIP_Longint gcd;
1656 
1657  assert(intscalar > 0.0);
1658 
1659  /* calculate gcd of resulting integral coefficients */
1660  gcd = 0;
1661  for( v = 0; v < nints && gcd != 1; ++v )
1662  {
1663  SCIP_Longint absobj;
1664 
1665  /* if absobj exceeds maximum SCIP_Longint value, return */
1666  if( REALABS(objvals[v]) * intscalar + 0.5 > SCIP_LONGINT_MAX )
1667  {
1668  SCIPsetFreeBufferArray(set, &objvals);
1669  return SCIP_OKAY;
1670  }
1671 
1672  absobj = (SCIP_Longint)(REALABS(objvals[v]) * intscalar + 0.5);
1673  if( gcd == 0 )
1674  gcd = absobj;
1675  else if( absobj > 0 )
1676  gcd = SCIPcalcGreComDiv(gcd, absobj);
1677  }
1678  if( gcd != 0 )
1679  intscalar /= gcd;
1680  SCIPsetDebugMsg(set, "integral objective scalar: gcd=%" SCIP_LONGINT_FORMAT ", intscalar=%g\n", gcd, intscalar);
1681 
1682  /* only apply scaling if the final scalar is small enough */
1683  if( intscalar <= OBJSCALE_MAXFINALSCALE )
1684  {
1685  /* apply scaling */
1686  if( !SCIPsetIsEQ(set, intscalar, 1.0) )
1687  {
1688  /* calculate scaled objective values */
1689  for( v = 0; v < nints; ++v )
1690  {
1691  SCIP_Real newobj;
1692 
1693  /* check if new obj is really integral */
1694  newobj = intscalar * SCIPvarGetObj(transprob->vars[v]);
1695  if( !SCIPsetIsFeasIntegral(set, newobj) )
1696  break;
1697  objvals[v] = SCIPsetFeasFloor(set, newobj);
1698  }
1699 
1700  /* change the variables' objective values and adjust objscale and objoffset */
1701  if( v == nints )
1702  {
1703  for( v = 0; v < nints; ++v )
1704  {
1705  SCIPsetDebugMsg(set, " -> var <%s>: newobj = %.6f\n", SCIPvarGetName(transprob->vars[v]), objvals[v]);
1706  SCIP_CALL( SCIPvarChgObj(transprob->vars[v], blkmem, set, transprob, primal, lp, eventqueue, objvals[v]) );
1707  }
1708  transprob->objoffset *= intscalar;
1709  transprob->objscale /= intscalar;
1710  transprob->objisintegral = TRUE;
1711  SCIPsetDebugMsg(set, "integral objective scalar: objscale=%g\n", transprob->objscale);
1712 
1713  /* update upperbound and cutoffbound in primal data structure */
1714  SCIP_CALL( SCIPprimalUpdateObjoffset(primal, blkmem, set, stat, eventfilter, eventqueue, transprob, origprob, tree, reopt, lp) );
1715  }
1716  }
1717  }
1718  }
1719 
1720  /* free temporary memory */
1721  SCIPsetFreeBufferArray(set, &objvals);
1722  }
1723 
1724  return SCIP_OKAY;
1725 }
1726 
1727 /** remembers the current solution as root solution in the problem variables */
1729  SCIP_PROB* prob, /**< problem data */
1730  SCIP_SET* set, /**< global SCIP settings */
1731  SCIP_STAT* stat, /**< SCIP statistics */
1732  SCIP_LP* lp, /**< current LP data */
1733  SCIP_Bool roothaslp /**< is the root solution from LP? */
1734  )
1735 {
1736  int v;
1737 
1738  assert(prob != NULL);
1739  assert(prob->transformed);
1740 
1741  if( roothaslp )
1742  {
1743  for( v = 0; v < prob->nvars; ++v )
1744  SCIPvarStoreRootSol(prob->vars[v], roothaslp);
1745 
1747  SCIPlpStoreRootObjval(lp, set, prob);
1748 
1749  /* compute root LP best-estimate */
1750  SCIPstatComputeRootLPBestEstimate(stat, set, SCIPlpGetColumnObjval(lp), prob->vars, prob->nbinvars + prob->nintvars + prob->nimplvars);
1751  }
1752 }
1753 
1754 /** remembers the best solution w.r.t. root reduced cost propagation as root solution in the problem variables */
1756  SCIP_PROB* prob, /**< problem data */
1757  SCIP_SET* set, /**< global SCIP settings */
1758  SCIP_STAT* stat, /**< problem statistics */
1759  SCIP_LP* lp /**< current LP data */
1760  )
1761 {
1762  SCIP_Real rootlpobjval;
1763  int v;
1764 
1765  assert(prob != NULL);
1766  assert(lp != NULL);
1767  assert(prob->transformed);
1768  assert(lp->lpsolstat == SCIP_LPSOLSTAT_OPTIMAL);
1769 
1770  /* in case we have a zero objective fucntion, we skip the root reduced cost update */
1771  if( SCIPprobGetNObjVars(prob, set) == 0 )
1772  return;
1773 
1774  if( !SCIPlpIsDualReliable(lp) )
1775  return;
1776 
1777  SCIPsetDebugMsg(set, "update root reduced costs\n");
1778 
1779  /* compute current root LP objective value */
1780  rootlpobjval = SCIPlpGetObjval(lp, set, prob);
1781  assert(rootlpobjval != SCIP_INVALID); /*lint !e777*/
1782 
1783  for( v = 0; v < prob->nvars; ++v )
1784  {
1785  SCIP_VAR* var;
1786  SCIP_COL* col;
1787  SCIP_Real rootsol = 0.0;
1788  SCIP_Real rootredcost = 0.0;
1789 
1790  var = prob->vars[v];
1791  assert(var != NULL);
1792 
1793  /* check if the variable is part of the LP */
1795  continue;
1796 
1797  col = SCIPvarGetCol(var);
1798  assert(col != NULL);
1799 
1801 
1802  if( !SCIPvarIsBinary(var) )
1803  {
1804  rootsol = SCIPvarGetSol(var, TRUE);
1805  rootredcost = SCIPcolGetRedcost(col, stat, lp);
1806  }
1807  else
1808  {
1809  SCIP_Real primsol;
1810  SCIP_BASESTAT basestat;
1811  SCIP_Bool lpissolbasic;
1812 
1813  basestat = SCIPcolGetBasisStatus(col);
1814  lpissolbasic = SCIPlpIsSolBasic(lp);
1815  primsol = SCIPcolGetPrimsol(col);
1816 
1817  if( (lpissolbasic && (basestat == SCIP_BASESTAT_LOWER || basestat == SCIP_BASESTAT_UPPER)) ||
1818  (!lpissolbasic && (SCIPsetIsFeasEQ(set, SCIPvarGetLbLocal(var), primsol) ||
1819  SCIPsetIsFeasEQ(set, SCIPvarGetUbLocal(var), primsol))) )
1820  {
1821  SCIP_Real lbrootredcost;
1822  SCIP_Real ubrootredcost;
1823 
1824  /* get reduced cost if the variable gets fixed to zero */
1825  lbrootredcost = SCIPvarGetImplRedcost(var, set, FALSE, stat, prob, lp);
1826  assert( !SCIPsetIsDualfeasPositive(set, lbrootredcost)
1828 
1829  /* get reduced cost if the variable gets fixed to one */
1830  ubrootredcost = SCIPvarGetImplRedcost(var, set, TRUE, stat, prob, lp);
1831  assert( !SCIPsetIsDualfeasNegative(set, ubrootredcost)
1833 
1834  if( -lbrootredcost > ubrootredcost )
1835  {
1836  rootredcost = lbrootredcost;
1837  rootsol = 1.0;
1838  }
1839  else
1840  {
1841  rootredcost = ubrootredcost;
1842  rootsol = 0.0;
1843  }
1844  }
1845  }
1846 
1847  /* update the current solution as best root solution in the problem variables if it is better */
1848  SCIPvarUpdateBestRootSol(var, set, rootsol, rootredcost, rootlpobjval);
1849  }
1850 }
1851 
1852 /** informs problem, that the presolving process was finished, and updates all internal data structures */ /*lint -e715*/
1854  SCIP_PROB* prob, /**< problem data */
1855  SCIP_SET* set /**< global SCIP settings */
1856  )
1857 { /*lint --e{715}*/
1858  return SCIP_OKAY;
1859 }
1860 
1861 /** initializes problem for branch and bound process and resets all constraint's ages and histories of current run */
1863  SCIP_PROB* prob, /**< problem data */
1864  SCIP_SET* set /**< global SCIP settings */
1865  )
1866 {
1867  int c;
1868  int v;
1869 
1870  assert(prob != NULL);
1871  assert(prob->transformed);
1872  assert(set != NULL);
1873 
1874  /* reset constraint's ages */
1875  for( c = 0; c < prob->nconss; ++c )
1876  {
1877  SCIP_CALL( SCIPconsResetAge(prob->conss[c], set) );
1878  }
1879 
1880  /* initialize variables for solving */
1881  for( v = 0; v < prob->nvars; ++v )
1882  SCIPvarInitSolve(prob->vars[v]);
1883 
1884  /* call user data function */
1885  if( prob->probinitsol != NULL )
1886  {
1887  SCIP_CALL( prob->probinitsol(set->scip, prob->probdata) );
1888  }
1889 
1890  /* assert that the counter for variables with nonzero objective is correct */
1891  assert(prob->nobjvars == SCIPprobGetNObjVars(prob, set));
1892 
1893  return SCIP_OKAY;
1894 }
1895 
1896 /** deinitializes problem after branch and bound process, and converts all COLUMN variables back into LOOSE variables */
1898  SCIP_PROB* prob, /**< problem data */
1899  BMS_BLKMEM* blkmem, /**< block memory */
1900  SCIP_SET* set, /**< global SCIP settings */
1901  SCIP_EVENTQUEUE* eventqueue, /**< event queue */
1902  SCIP_LP* lp, /**< current LP data */
1903  SCIP_Bool restart /**< was this exit solve call triggered by a restart? */
1904  )
1905 {
1906  SCIP_VAR* var;
1907  int v;
1908 
1909  assert(prob != NULL);
1910  assert(prob->transformed);
1911  assert(set != NULL);
1912 
1913  /* call user data function */
1914  if( prob->probexitsol != NULL )
1915  {
1916  SCIP_CALL( prob->probexitsol(set->scip, prob->probdata, restart) );
1917  }
1918 
1919  /* convert all COLUMN variables back into LOOSE variables */
1920  if( prob->ncolvars > 0 )
1921  {
1922  for( v = 0; v < prob->nvars; ++v )
1923  {
1924  var = prob->vars[v];
1926  {
1927  SCIP_CALL( SCIPvarLoose(var, blkmem, set, eventqueue, prob, lp) );
1928  }
1929 
1930  /* invalided root reduced cost, root reduced solution, and root LP objective value for each variable */
1931  SCIPvarSetBestRootSol(var, 0.0, 0.0, SCIP_INVALID);
1932  }
1933  }
1934  assert(prob->ncolvars == 0);
1935 
1936  return SCIP_OKAY;
1937 }
1938 
1939 
1940 
1941 
1942 /*
1943  * problem information
1944  */
1945 
1946 /** sets problem name */
1948  SCIP_PROB* prob, /**< problem data */
1949  const char* name /**< name to be set */
1950  )
1951 {
1952  assert(prob != NULL);
1953 
1954  BMSfreeMemoryArray(&(prob->name));
1955  SCIP_ALLOC( BMSduplicateMemoryArray(&(prob->name), name, strlen(name)+1) );
1956 
1957  return SCIP_OKAY;
1958 }
1959 
1960 /** returns the number of implicit binary variables, meaning variable of vartype != SCIP_VARTYPE_BINARY and !=
1961  * SCIP_VARTYPE_CONTINUOUS but with global bounds [0,1]
1962  *
1963  * @note this number needs to be computed, because it cannot be updated like the other counters for binary and integer
1964  * variables, each time the variable type changes(, we would need to update this counter each time a global bound
1965  * changes), even at the end of presolving this cannot be computed, because some variable can change to an
1966  * implicit binary status
1967  */
1969  SCIP_PROB* prob /**< problem data */
1970  )
1971 {
1972  int v;
1973  int nimplbinvars = 0;
1974 
1975  for( v = prob->nbinvars + prob->nintvars + prob->nimplvars - 1; v >= prob->nbinvars; --v )
1976  {
1977  if( SCIPvarIsBinary(prob->vars[v]) )
1978  ++nimplbinvars;
1979  }
1980 
1981  return nimplbinvars;
1982 }
1983 
1984 /** returns the number of variables with non-zero objective coefficient */
1986  SCIP_PROB* prob, /**< problem data */
1987  SCIP_SET* set /**< global SCIP settings */
1988  )
1989 {
1990  if( prob->transformed )
1991  {
1992  /* this is much too expensive, to check it in each debug run */
1993 #ifdef SCIP_MORE_DEBUG
1994  int nobjvars;
1995  int v;
1996 
1997  nobjvars = 0;
1998 
1999  for( v = prob->nvars - 1; v >= 0; --v )
2000  {
2001  if( !SCIPsetIsZero(set, SCIPvarGetObj(prob->vars[v])) )
2002  nobjvars++;
2003  }
2004 
2005  /* check that the internal count is correct */
2006  assert(prob->nobjvars == nobjvars);
2007 #endif
2008  return prob->nobjvars;
2009  }
2010  else
2011  {
2012  int nobjvars;
2013  int v;
2014 
2015  nobjvars = 0;
2016 
2017  for( v = prob->nvars - 1; v >= 0; --v )
2018  {
2019  if( !SCIPsetIsZero(set, SCIPvarGetObj(prob->vars[v])) )
2020  nobjvars++;
2021  }
2022  return nobjvars;
2023  }
2024 }
2025 
2026 /** returns the minimal absolute non-zero objective coefficient
2027  *
2028  * @note currently, this is only used for statistics and printed after the solving process. if this information is
2029  * needed during the (pre)solving process this should be implemented more efficiently, e.g., updating the minimal
2030  * absolute non-zero coefficient every time an objective coefficient has changed.
2031  */
2033  SCIP_PROB* prob, /**< problem data */
2034  SCIP_SET* set /**< global SCIP settings */
2035  )
2036 {
2037  SCIP_Real absmin;
2038  int v;
2039 
2040  absmin = SCIPsetInfinity(set);
2041 
2042  for( v = 0; v < prob->nvars; v++ )
2043  {
2044  SCIP_Real objcoef = SCIPvarGetObj(prob->vars[v]);
2045 
2046  if( !SCIPsetIsZero(set, objcoef) && SCIPsetIsLT(set, REALABS(objcoef), absmin) )
2047  absmin = REALABS(objcoef);
2048  }
2049 
2050  return absmin;
2051 }
2052 
2053 /** returns the maximal absolute non-zero objective coefficient
2054  *
2055  * @note currently, this is only used for statistics and printed after the solving process. if this information is
2056  * needed during the (pre)solving process this should be implemented more efficiently, e.g., updating the maximal
2057  * absolute non-zero coefficient every time an objective coefficient has changed.
2058  */
2060  SCIP_PROB* prob, /**< problem data */
2061  SCIP_SET* set /**< global SCIP settings */
2062  )
2063 {
2064  SCIP_Real absmax;
2065  int v;
2066 
2067  absmax = -SCIPsetInfinity(set);
2068 
2069  for( v = 0; v < prob->nvars; v++ )
2070  {
2071  SCIP_Real objcoef = SCIPvarGetObj(prob->vars[v]);
2072 
2073  if( !SCIPsetIsZero(set, objcoef) && SCIPsetIsGT(set, REALABS(objcoef), absmax) )
2074  absmax = REALABS(objcoef);
2075  }
2076 
2077  return absmax;
2078 }
2079 
2080 
2081 /** returns the external value of the given internal objective value */
2083  SCIP_PROB* transprob, /**< tranformed problem data */
2084  SCIP_PROB* origprob, /**< original problem data */
2085  SCIP_SET* set, /**< global SCIP settings */
2086  SCIP_Real objval /**< internal objective value */
2087  )
2088 {
2089  assert(set != NULL);
2090  assert(origprob != NULL);
2091  assert(transprob != NULL);
2092  assert(transprob->transformed);
2093  assert(transprob->objscale > 0.0);
2094 
2095  if( SCIPsetIsInfinity(set, objval) )
2096  return (SCIP_Real)transprob->objsense * SCIPsetInfinity(set);
2097  else if( SCIPsetIsInfinity(set, -objval) )
2098  return -(SCIP_Real)transprob->objsense * SCIPsetInfinity(set);
2099  else
2100  return (SCIP_Real)transprob->objsense * transprob->objscale * (objval + transprob->objoffset) + origprob->objoffset;
2101 }
2102 
2103 /** returns the internal value of the given external objective value */
2105  SCIP_PROB* transprob, /**< tranformed problem data */
2106  SCIP_PROB* origprob, /**< original problem data */
2107  SCIP_SET* set, /**< global SCIP settings */
2108  SCIP_Real objval /**< external objective value */
2109  )
2110 {
2111  assert(set != NULL);
2112  assert(origprob != NULL);
2113  assert(transprob != NULL);
2114  assert(transprob->transformed);
2115  assert(transprob->objscale > 0.0);
2116 
2117  if( SCIPsetIsInfinity(set, objval) )
2118  return (SCIP_Real)transprob->objsense * SCIPsetInfinity(set);
2119  else if( SCIPsetIsInfinity(set, -objval) )
2120  return -(SCIP_Real)transprob->objsense * SCIPsetInfinity(set);
2121  else
2122  return (SCIP_Real)transprob->objsense * (objval - origprob->objoffset)/transprob->objscale - transprob->objoffset;
2123 }
2124 
2125 /** returns variable of the problem with given name */
2127  SCIP_PROB* prob, /**< problem data */
2128  const char* name /**< name of variable to find */
2129  )
2130 {
2131  assert(prob != NULL);
2132  assert(name != NULL);
2133 
2134  if( prob->varnames == NULL )
2135  {
2136  SCIPerrorMessage("Cannot find variable if variable-names hashtable was disabled (due to parameter <misc/usevartable>)\n");
2137  SCIPABORT();/*lint --e{527}*/ /* only in debug mode */
2138  return NULL;
2139  }
2140 
2141  return (SCIP_VAR*)(SCIPhashtableRetrieve(prob->varnames, (char*)name));
2142 }
2143 
2144 /** returns constraint of the problem with given name */
2146  SCIP_PROB* prob, /**< problem data */
2147  const char* name /**< name of variable to find */
2148  )
2149 {
2150  assert(prob != NULL);
2151  assert(name != NULL);
2152 
2153  if( prob->consnames == NULL )
2154  {
2155  SCIPerrorMessage("Cannot find constraint if constraint-names hashtable was disabled (due to parameter <misc/useconstable>)\n");
2156  SCIPABORT();/*lint --e{527}*/ /* only in debug mode */
2157  return NULL;
2158  }
2159 
2160  return (SCIP_CONS*)(SCIPhashtableRetrieve(prob->consnames, (char*)name));
2161 }
2162 
2163 /** displays current pseudo solution */
2165  SCIP_PROB* prob, /**< problem data */
2166  SCIP_SET* set, /**< global SCIP settings */
2167  SCIP_MESSAGEHDLR* messagehdlr /**< message handler */
2168  )
2169 {
2170  SCIP_VAR* var;
2171  SCIP_Real solval;
2172  int v;
2173 
2174  for( v = 0; v < prob->nvars; ++v )
2175  {
2176  var = prob->vars[v];
2177  assert(var != NULL);
2178  solval = SCIPvarGetPseudoSol(var);
2179  if( !SCIPsetIsZero(set, solval) )
2180  SCIPmessagePrintInfo(messagehdlr, " <%s>=%.15g", SCIPvarGetName(var), solval);
2181  }
2182  SCIPmessagePrintInfo(messagehdlr, "\n");
2183 }
2184 
2185 /** outputs problem statistics */
2187  SCIP_PROB* prob, /**< problem data */
2188  SCIP_SET* set, /**< global SCIP settings */
2189  SCIP_MESSAGEHDLR* messagehdlr, /**< message handler */
2190  FILE* file /**< output file (or NULL for standard output) */
2191  )
2192 {
2193  assert(prob != NULL);
2194 
2195  SCIPmessageFPrintInfo(messagehdlr, file, " Problem name : %s\n", prob->name);
2196  SCIPmessageFPrintInfo(messagehdlr, file, " Variables : %d (%d binary, %d integer, %d implicit integer, %d continuous)\n",
2197  prob->nvars, prob->nbinvars, prob->nintvars, prob->nimplvars, prob->ncontvars);
2198  SCIPmessageFPrintInfo(messagehdlr, file, " Constraints : %d initial, %d maximal\n", prob->startnconss, prob->maxnconss);
2199  SCIPmessageFPrintInfo(messagehdlr, file, " Objective : %s, %d non-zeros (abs.min = %g, abs.max = %g)\n",
2200  !prob->transformed ? (prob->objsense == SCIP_OBJSENSE_MINIMIZE ? "minimize" : "maximize") : "minimize",
2201  SCIPprobGetNObjVars(prob, set), SCIPprobGetAbsMinObjCoef(prob, set), SCIPprobGetAbsMaxObjCoef(prob, set));
2202 }
2203 
2204 
2205 #ifndef NDEBUG
2206 
2207 /* In debug mode, the following methods are implemented as function calls to ensure
2208  * type validity.
2209  * In optimized mode, the methods are implemented as defines to improve performance.
2210  * However, we want to have them in the library anyways, so we have to undef the defines.
2211  */
2212 
2213 #undef SCIPprobIsPermuted
2214 #undef SCIPprobMarkPermuted
2215 #undef SCIPprobIsTransformed
2216 #undef SCIPprobIsObjIntegral
2217 #undef SCIPprobAllColsInLP
2218 #undef SCIPprobGetObjlim
2219 #undef SCIPprobGetData
2220 #undef SCIPprobGetName
2221 #undef SCIPprobGetNVars
2222 #undef SCIPprobGetNBinVars
2223 #undef SCIPprobGetNIntVars
2224 #undef SCIPprobGetNImplVars
2225 #undef SCIPprobGetNContVars
2226 #undef SCIPprobGetNConss
2227 #undef SCIPprobGetVars
2228 #undef SCIPprobGetObjoffset
2229 #undef SCIPisConsCompressedEnabled
2230 #undef SCIPprobEnableConsCompression
2231 
2232 /** is the problem permuted */
2234  SCIP_PROB* prob
2235  )
2236 {
2237  assert(prob != NULL);
2238 
2239  return prob->permuted;
2240 }
2241 
2242 /** mark the problem as permuted */
2244  SCIP_PROB* prob
2245  )
2246 {
2247  assert(prob != NULL);
2248 
2249  prob->permuted = TRUE;
2250 }
2251 
2252 /** is the problem data transformed */
2254  SCIP_PROB* prob /**< problem data */
2255  )
2256 {
2257  assert(prob != NULL);
2258 
2259  return prob->transformed;
2260 }
2261 
2262 /** returns whether the objective value is known to be integral in every feasible solution */
2264  SCIP_PROB* prob /**< problem data */
2265  )
2266 {
2267  assert(prob != NULL);
2268 
2269  return prob->objisintegral;
2270 }
2271 
2272 /** returns TRUE iff all columns, i.e. every variable with non-empty column w.r.t. all ever created rows, are present
2273  * in the LP, and FALSE, if there are additional already existing columns, that may be added to the LP in pricing
2274  */
2276  SCIP_PROB* prob, /**< problem data */
2277  SCIP_SET* set, /**< global SCIP settings */
2278  SCIP_LP* lp /**< current LP data */
2279  )
2280 {
2281  assert(SCIPlpGetNCols(lp) <= prob->ncolvars && prob->ncolvars <= prob->nvars);
2282 
2283  return (SCIPlpGetNCols(lp) == prob->ncolvars && set->nactivepricers == 0);
2284 }
2285 
2286 /** gets limit on objective function in external space */
2288  SCIP_PROB* prob, /**< problem data */
2289  SCIP_SET* set /**< global SCIP settings */
2290  )
2291 {
2292  assert(prob != NULL);
2293  assert(set != NULL);
2294 
2295  return prob->objlim >= SCIP_INVALID ? (SCIP_Real)(prob->objsense) * SCIPsetInfinity(set) : prob->objlim;
2296 }
2297 
2298 /** gets user problem data */
2300  SCIP_PROB* prob /**< problem */
2301  )
2302 {
2303  assert(prob != NULL);
2304 
2305  return prob->probdata;
2306 }
2307 
2308 /** gets problem name */
2309 const char* SCIPprobGetName(
2310  SCIP_PROB* prob /**< problem data */
2311  )
2312 {
2313  assert(prob != NULL);
2314  return prob->name;
2315 }
2316 
2317 /** gets number of problem variables */
2319  SCIP_PROB* prob /**< problem data */
2320  )
2321 {
2322  assert(prob != NULL);
2323  return prob->nvars;
2324 }
2325 
2326 /** gets number of binary problem variables */
2328  SCIP_PROB* prob /**< problem data */
2329  )
2330 {
2331  assert(prob != NULL);
2332  return prob->nbinvars;
2333 }
2334 
2335 /** gets number of integer problem variables */
2337  SCIP_PROB* prob /**< problem data */
2338  )
2339 {
2340  assert(prob != NULL);
2341  return prob->nintvars;
2342 }
2343 
2344 /** gets number of implicit integer problem variables */
2346  SCIP_PROB* prob /**< problem data */
2347  )
2348 {
2349  assert(prob != NULL);
2350  return prob->nimplvars;
2351 }
2352 
2353 /** gets number of continuous problem variables */
2355  SCIP_PROB* prob /**< problem data */
2356  )
2357 {
2358  assert(prob != NULL);
2359  return prob->ncontvars;
2360 }
2361 
2362 /** gets problem variables */
2364  SCIP_PROB* prob /**< problem data */
2365  )
2366 {
2367  assert(prob != NULL);
2368  return prob->vars;
2369 }
2370 
2371 /** gets number of problem constraints */
2373  SCIP_PROB* prob /**< problem data */
2374  )
2375 {
2376  assert(prob != NULL);
2377  return prob->nconss;
2378 }
2379 
2380 /** gets the objective offset */
2382  SCIP_PROB* prob /**< problem data */
2383  )
2384 {
2385  assert(prob != NULL);
2386  return prob->objoffset;
2387 }
2388 
2389 /** gets the objective scalar */
2391  SCIP_PROB* prob /**< problem data */
2392  )
2393 {
2394  assert(prob != NULL);
2395  return prob->objscale;
2396 }
2397 
2398 /** is constraint compression enabled for this problem? */
2400  SCIP_PROB* prob /**< problem data */
2401  )
2402 {
2403  assert(prob != NULL);
2404 
2405  return prob->conscompression;
2406 }
2407 
2408 /** enable problem compression, i.e., constraints can reduce memory size by removing fixed variables during creation */
2410  SCIP_PROB* prob /**< problem data */
2411  )
2412 {
2413  assert(prob != NULL);
2414 
2415  prob->conscompression = TRUE;
2416 }
2417 
2418 #endif
enum SCIP_Result SCIP_RESULT
Definition: type_result.h:52
SCIP_RETCODE SCIPprobCheckObjIntegral(SCIP_PROB *transprob, SCIP_PROB *origprob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_PRIMAL *primal, SCIP_TREE *tree, SCIP_REOPT *reopt, SCIP_LP *lp, SCIP_EVENTFILTER *eventfilter, SCIP_EVENTQUEUE *eventqueue)
Definition: prob.c:1478
SCIP_Bool SCIPsetIsInfinity(SCIP_SET *set, SCIP_Real val)
Definition: set.c:5980
internal methods for managing events
SCIP_Bool SCIPconshdlrNeedsCons(SCIP_CONSHDLR *conshdlr)
Definition: cons.c:5118
SCIP_VAR * SCIPprobFindVar(SCIP_PROB *prob, const char *name)
Definition: prob.c:2126
SCIP_RETCODE SCIPhashtableInsert(SCIP_HASHTABLE *hashtable, void *element)
Definition: misc.c:2486
SCIP_EXPORT int SCIPvarGetNUses(SCIP_VAR *var)
Definition: var.c:17022
int SCIPprobGetNBinVars(SCIP_PROB *prob)
Definition: prob.c:2327
void SCIPvarUpdateBestRootSol(SCIP_VAR *var, SCIP_SET *set, SCIP_Real rootsol, SCIP_Real rootredcost, SCIP_Real rootlpobjval)
Definition: var.c:13044
SCIP_RETCODE SCIPprimalUpdateObjoffset(SCIP_PRIMAL *primal, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_EVENTFILTER *eventfilter, SCIP_EVENTQUEUE *eventqueue, SCIP_PROB *transprob, SCIP_PROB *origprob, SCIP_TREE *tree, SCIP_REOPT *reopt, SCIP_LP *lp)
Definition: primal.c:478
SCIP_RETCODE SCIPlpUpdateAddVar(SCIP_LP *lp, SCIP_SET *set, SCIP_VAR *var)
Definition: lp.c:13972
static void probInsertVar(SCIP_PROB *prob, SCIP_VAR *var)
Definition: prob.c:715
void SCIPstatComputeRootLPBestEstimate(SCIP_STAT *stat, SCIP_SET *set, SCIP_Real rootlpobjval, SCIP_VAR **vars, int nvars)
Definition: stat.c:763
SCIP_HASHTABLE * varnames
Definition: struct_prob.h:54
SCIP_RETCODE SCIPconsActivate(SCIP_CONS *cons, SCIP_SET *set, SCIP_STAT *stat, int depth, SCIP_Bool focusnode)
Definition: cons.c:6733
#define BMSfreeMemoryArrayNull(ptr)
Definition: memory.h:140
int SCIPprobGetNConss(SCIP_PROB *prob)
Definition: prob.c:2372
unsigned int active
Definition: struct_cons.h:76
SCIP_Bool SCIPprobIsConsCompressionEnabled(SCIP_PROB *prob)
Definition: prob.c:2399
void SCIPprobSetData(SCIP_PROB *prob, SCIP_PROBDATA *probdata)
Definition: prob.c:703
SCIP_PROBDATA * SCIPprobGetData(SCIP_PROB *prob)
Definition: prob.c:2299
void SCIPprobUpdateBestRootSol(SCIP_PROB *prob, SCIP_SET *set, SCIP_STAT *stat, SCIP_LP *lp)
Definition: prob.c:1755
SCIP_Bool SCIPsetIsFeasEQ(SCIP_SET *set, SCIP_Real val1, SCIP_Real val2)
Definition: set.c:6378
enum SCIP_BaseStat SCIP_BASESTAT
Definition: type_lpi.h:87
#define SCIP_DECL_PROBINITSOL(x)
Definition: type_prob.h:97
SCIP_Bool SCIPconsIsChecked(SCIP_CONS *cons)
Definition: cons.c:8288
void SCIPlpSetRootLPIsRelax(SCIP_LP *lp, SCIP_Bool isrelax)
Definition: lp.c:17541
SCIP_RETCODE SCIPeventqueueAdd(SCIP_EVENTQUEUE *eventqueue, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_PRIMAL *primal, SCIP_LP *lp, SCIP_BRANCHCAND *branchcand, SCIP_EVENTFILTER *eventfilter, SCIP_EVENT **event)
Definition: event.c:2231
SCIP_Bool SCIPhashtableExists(SCIP_HASHTABLE *hashtable, void *element)
Definition: misc.c:2598
#define SCIP_MAXSTRLEN
Definition: def.h:273
SCIP_RETCODE SCIPconflictstoreTransform(SCIP_CONFLICTSTORE *conflictstore, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_TREE *tree, SCIP_PROB *transprob, SCIP_REOPT *reopt)
#define SCIP_DECL_PROBDELORIG(x)
Definition: type_prob.h:55
void * SCIPhashtableRetrieve(SCIP_HASHTABLE *hashtable, void *key)
Definition: misc.c:2547
SCIP_RETCODE SCIPprobScaleObj(SCIP_PROB *transprob, SCIP_PROB *origprob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_PRIMAL *primal, SCIP_TREE *tree, SCIP_REOPT *reopt, SCIP_LP *lp, SCIP_EVENTFILTER *eventfilter, SCIP_EVENTQUEUE *eventqueue)
Definition: prob.c:1596
SCIP_RETCODE SCIPprobVarChangedStatus(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_BRANCHCAND *branchcand, SCIP_CLIQUETABLE *cliquetable, SCIP_VAR *var)
Definition: prob.c:1182
int nintvars
Definition: struct_prob.h:63
SCIP_Longint SCIPcalcGreComDiv(SCIP_Longint val1, SCIP_Longint val2)
Definition: misc.c:9008
void SCIPprobAddObjoffset(SCIP_PROB *prob, SCIP_Real addval)
Definition: prob.c:1431
SCIP_Real SCIPsetInfinity(SCIP_SET *set)
Definition: set.c:5845
SCIP_Longint nactiveconssadded
Definition: struct_stat.h:115
int SCIPprobGetNVars(SCIP_PROB *prob)
Definition: prob.c:2318
int startnconss
Definition: struct_prob.h:76
SCIP_EXPORT SCIP_Real SCIPvarGetPseudoSol(SCIP_VAR *var)
Definition: var.c:18114
#define SCIP_DECL_PROBDELTRANS(x)
Definition: type_prob.h:86
SCIP_EXPORT SCIP_Bool SCIPvarIsBinary(SCIP_VAR *var)
Definition: var.c:17192
void SCIPvarSetProbindex(SCIP_VAR *var, int probindex)
Definition: var.c:5867
SCIP_Bool SCIPconsIsActive(SCIP_CONS *cons)
Definition: cons.c:8150
datastructures for constraints and constraint handlers
static SCIP_Bool consHasName(SCIP_CONS *cons)
Definition: prob.c:157
#define FALSE
Definition: def.h:73
SCIP_Bool SCIPlpIsSolBasic(SCIP_LP *lp)
Definition: lp.c:17659
SCIP_Bool SCIPsetIsFeasIntegral(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6521
SCIP_Real objoffset
Definition: struct_prob.h:41
SCIP_EXPORT SCIP_Real SCIPvarGetObj(SCIP_VAR *var)
Definition: var.c:17510
SCIP_RETCODE SCIPvarTransform(SCIP_VAR *origvar, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_OBJSENSE objsense, SCIP_VAR **transvar)
Definition: var.c:3357
SCIP_Bool SCIPsetIsZero(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6092
SCIP_EXPORT SCIP_VARTYPE SCIPvarGetType(SCIP_VAR *var)
Definition: var.c:17177
#define TRUE
Definition: def.h:72
void SCIPprobSetExitsol(SCIP_PROB *prob, SCIP_DECL_PROBEXITSOL((*probexitsol)))
Definition: prob.c:378
void SCIPprobMarkNConss(SCIP_PROB *prob)
Definition: prob.c:1405
enum SCIP_Retcode SCIP_RETCODE
Definition: type_retcode.h:54
unsigned int enabled
Definition: struct_cons.h:82
SCIP_Real SCIPprobInternObjval(SCIP_PROB *transprob, SCIP_PROB *origprob, SCIP_SET *set, SCIP_Real objval)
Definition: prob.c:2104
#define SCIPsetAllocBufferArray(set, ptr, num)
Definition: set.h:1685
SCIP_EXPORT SCIP_Bool SCIPvarIsTransformedOrigvar(SCIP_VAR *var)
Definition: var.c:12627
internal methods for branching rules and branching candidate storage
int SCIPsetCalcMemGrowSize(SCIP_SET *set, int num)
Definition: set.c:5573
void SCIPvarInitSolve(SCIP_VAR *var)
Definition: var.c:2831
SCIP_RETCODE SCIPprobInitSolve(SCIP_PROB *prob, SCIP_SET *set)
Definition: prob.c:1862
public methods for problem variables
SCIP_VAR ** fixedvars
Definition: struct_prob.h:56
SCIP_RETCODE SCIPhashtableRemove(SCIP_HASHTABLE *hashtable, void *element)
Definition: misc.c:2616
#define SCIPdebugMessage
Definition: pub_message.h:87
void SCIPprobUpdateNObjVars(SCIP_PROB *prob, SCIP_SET *set, SCIP_Real oldobj, SCIP_Real newobj)
Definition: prob.c:1542
SCIP_EXPORT SCIP_VARSTATUS SCIPvarGetStatus(SCIP_VAR *var)
Definition: var.c:17131
int nimplvars
Definition: struct_prob.h:64
#define SCIP_DECL_PROBCOPY(x)
Definition: type_prob.h:140
SCIP_RETCODE SCIPvarChgType(SCIP_VAR *var, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_PRIMAL *primal, SCIP_LP *lp, SCIP_EVENTQUEUE *eventqueue, SCIP_VARTYPE vartype)
Definition: var.c:5982
#define SCIP_LONGINT_MAX
Definition: def.h:149
SCIP_RETCODE SCIPprobChgVarType(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_PRIMAL *primal, SCIP_LP *lp, SCIP_BRANCHCAND *branchcand, SCIP_EVENTQUEUE *eventqueue, SCIP_CLIQUETABLE *cliquetable, SCIP_VAR *var, SCIP_VARTYPE vartype)
Definition: prob.c:1133
#define SCIPsetFreeBufferArray(set, ptr)
Definition: set.h:1692
#define BMSfreeMemory(ptr)
Definition: memory.h:137
SCIP_LPSOLSTAT SCIPlpGetSolstat(SCIP_LP *lp)
Definition: lp.c:13047
internal methods for LP management
SCIP_RETCODE SCIPconsAddLocks(SCIP_CONS *cons, SCIP_SET *set, SCIP_LOCKTYPE locktype, int nlockspos, int nlocksneg)
Definition: cons.c:7253
Definition: heur_padm.c:125
SCIP_RETCODE SCIPconsResetAge(SCIP_CONS *cons, SCIP_SET *set)
Definition: cons.c:7152
SCIP_HASHTABLE * consnames
Definition: struct_prob.h:58
internal methods for collecting primal CIP solutions and primal informations
SCIP_RETCODE SCIPhashtableCreate(SCIP_HASHTABLE **hashtable, BMS_BLKMEM *blkmem, int tablesize, SCIP_DECL_HASHGETKEY((*hashgetkey)), SCIP_DECL_HASHKEYEQ((*hashkeyeq)), SCIP_DECL_HASHKEYVAL((*hashkeyval)), void *userptr)
Definition: misc.c:2235
SCIP_CONSSETCHG * addconssetchg
Definition: struct_cons.h:48
void SCIPprobSetObjIntegral(SCIP_PROB *prob)
Definition: prob.c:1466
int SCIPlpGetNCols(SCIP_LP *lp)
Definition: lp.c:17424
int nobjvars
Definition: struct_prob.h:71
SCIP_Real dualbound
Definition: struct_prob.h:45
void SCIPprobPrintPseudoSol(SCIP_PROB *prob, SCIP_SET *set, SCIP_MESSAGEHDLR *messagehdlr)
Definition: prob.c:2164
SCIP_RETCODE SCIPprobFree(SCIP_PROB **prob, SCIP_MESSAGEHDLR *messagehdlr, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_EVENTQUEUE *eventqueue, SCIP_LP *lp)
Definition: prob.c:400
void SCIPprobPrintStatistics(SCIP_PROB *prob, SCIP_SET *set, SCIP_MESSAGEHDLR *messagehdlr, FILE *file)
Definition: prob.c:2186
SCIP_Real SCIPprobGetObjlim(SCIP_PROB *prob, SCIP_SET *set)
Definition: prob.c:2287
int ndeletedvars
Definition: struct_prob.h:70
unsigned int deleted
Definition: struct_cons.h:85
SCIP_RETCODE SCIPprobAddConsName(SCIP_PROB *prob, SCIP_CONS *cons)
Definition: prob.c:1240
void SCIPprobSetInitsol(SCIP_PROB *prob, SCIP_DECL_PROBINITSOL((*probinitsol)))
Definition: prob.c:367
SCIP_Bool SCIPsetIsLT(SCIP_SET *set, SCIP_Real val1, SCIP_Real val2)
Definition: set.c:6020
SCIP_Real SCIPprobGetObjscale(SCIP_PROB *prob)
Definition: prob.c:2390
static SCIP_RETCODE probEnsureVarsMem(SCIP_PROB *prob, SCIP_SET *set, int num)
Definition: prob.c:61
void SCIPprobSetCopy(SCIP_PROB *prob, SCIP_DECL_PROBCOPY((*probcopy)))
Definition: prob.c:389
public methods for managing constraints
SCIP_Real SCIPvarGetImplRedcost(SCIP_VAR *var, SCIP_SET *set, SCIP_Bool varfixing, SCIP_STAT *stat, SCIP_PROB *prob, SCIP_LP *lp)
Definition: var.c:13231
SCIP_RETCODE SCIPprobPerformVarDeletions(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_EVENTQUEUE *eventqueue, SCIP_CLIQUETABLE *cliquetable, SCIP_LP *lp, SCIP_BRANCHCAND *branchcand)
Definition: prob.c:1062
static SCIP_RETCODE probEnsureDeletedvarsMem(SCIP_PROB *prob, SCIP_SET *set, int num)
Definition: prob.c:109
SCIP_RETCODE SCIPprobRemoveVarName(SCIP_PROB *prob, SCIP_VAR *var)
Definition: prob.c:913
void SCIPprobSetObjsense(SCIP_PROB *prob, SCIP_OBJSENSE objsense)
Definition: prob.c:1418
SCIP_EXPORT SCIP_Real SCIPvarGetSol(SCIP_VAR *var, SCIP_Bool getlpval)
Definition: var.c:13021
int SCIPprobGetNImplVars(SCIP_PROB *prob)
Definition: prob.c:2345
SCIP_EXPORT const char * SCIPvarGetName(SCIP_VAR *var)
Definition: var.c:17012
#define BMSfreeMemoryArray(ptr)
Definition: memory.h:139
#define OBJSCALE_MAXFINALSCALE
Definition: prob.c:51
SCIP_EXPORT SCIP_Bool SCIPvarIsIntegral(SCIP_VAR *var)
Definition: var.c:17203
SCIP_Bool permuted
Definition: struct_prob.h:81
internal methods for storing and manipulating the main problem
#define SCIPerrorMessage
Definition: pub_message.h:55
SCIP_RETCODE SCIPconsTransform(SCIP_CONS *origcons, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_CONS **transcons)
Definition: cons.c:6414
SCIP_Bool SCIPlpIsDualReliable(SCIP_LP *lp)
Definition: lp.c:17649
SCIP_RETCODE SCIPprobExitSolve(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_EVENTQUEUE *eventqueue, SCIP_LP *lp, SCIP_Bool restart)
Definition: prob.c:1897
#define OBJSCALE_MAXDNOM
Definition: prob.c:49
SCIP_EXPORT SCIP_VAR * SCIPvarGetNegatedVar(SCIP_VAR *var)
Definition: var.c:17478
SCIP_CONS * SCIPprobFindCons(SCIP_PROB *prob, const char *name)
Definition: prob.c:2145
SCIP_RETCODE SCIPvarChgObj(SCIP_VAR *var, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_PROB *prob, SCIP_PRIMAL *primal, SCIP_LP *lp, SCIP_EVENTQUEUE *eventqueue, SCIP_Real newobj)
Definition: var.c:6069
int varssize
Definition: struct_prob.h:60
void SCIPprobEnableConsCompression(SCIP_PROB *prob)
Definition: prob.c:2409
SCIP_RETCODE SCIPvarRelease(SCIP_VAR **var, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_EVENTQUEUE *eventqueue, SCIP_LP *lp)
Definition: var.c:2786
SCIP_RETCODE SCIPeventCreateVarAdded(SCIP_EVENT **event, BMS_BLKMEM *blkmem, SCIP_VAR *var)
Definition: event.c:517
SCIP_RETCODE SCIPconshdlrDelVars(SCIP_CONSHDLR *conshdlr, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat)
Definition: cons.c:4118
SCIP_Bool objisintegral
Definition: struct_prob.h:78
SCIP_OBJSENSE objsense
Definition: struct_prob.h:77
static SCIP_RETCODE probEnsureConssMem(SCIP_PROB *prob, SCIP_SET *set, int num)
Definition: prob.c:133
int SCIPprobGetNObjVars(SCIP_PROB *prob, SCIP_SET *set)
Definition: prob.c:1985
#define NULL
Definition: lpi_spx1.cpp:155
char * name
Definition: struct_prob.h:46
#define REALABS(x)
Definition: def.h:187
SCIP_RETCODE SCIPprobSetName(SCIP_PROB *prob, const char *name)
Definition: prob.c:1947
SCIP_Bool SCIPprobIsObjIntegral(SCIP_PROB *prob)
Definition: prob.c:2263
internal methods for global SCIP settings
internal methods for storing conflicts
SCIP * scip
Definition: struct_cons.h:40
#define SCIP_CALL(x)
Definition: def.h:364
void SCIPmessageFPrintWarning(SCIP_MESSAGEHDLR *messagehdlr, const char *formatstr,...)
Definition: message.c:442
SCIP_RETCODE SCIPprobAddVarName(SCIP_PROB *prob, SCIP_VAR *var)
Definition: prob.c:897
SCIP_RETCODE SCIPprobResetBounds(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat)
Definition: prob.c:619
SCIP_Real SCIPcolGetPrimsol(SCIP_COL *col)
Definition: lp.c:16855
SCIP_VAR * h
Definition: circlepacking.c:59
void SCIPmessagePrintInfo(SCIP_MESSAGEHDLR *messagehdlr, const char *formatstr,...)
Definition: message.c:585
int SCIPprobGetNContVars(SCIP_PROB *prob)
Definition: prob.c:2354
SCIP_RETCODE SCIPprobCreate(SCIP_PROB **prob, BMS_BLKMEM *blkmem, SCIP_SET *set, const char *name, SCIP_DECL_PROBDELORIG((*probdelorig)), SCIP_DECL_PROBTRANS((*probtrans)), SCIP_DECL_PROBDELTRANS((*probdeltrans)), SCIP_DECL_PROBINITSOL((*probinitsol)), SCIP_DECL_PROBEXITSOL((*probexitsol)), SCIP_DECL_PROBCOPY((*probcopy)), SCIP_PROBDATA *probdata, SCIP_Bool transformed)
Definition: prob.c:255
SCIP_Bool SCIPsetIsEQ(SCIP_SET *set, SCIP_Real val1, SCIP_Real val2)
Definition: set.c:6002
SCIP_Bool conscompression
Definition: struct_prob.h:82
SCIP_Real SCIPlpGetObjval(SCIP_LP *lp, SCIP_SET *set, SCIP_PROB *prob)
Definition: lp.c:13063
void SCIPprobResortVars(SCIP_PROB *prob)
Definition: prob.c:645
SCIP_EXPORT void SCIPsortPtr(void **ptrarray, SCIP_DECL_SORTPTRCOMP((*ptrcomp)), int len)
int SCIPprobGetNIntVars(SCIP_PROB *prob)
Definition: prob.c:2336
#define BMSduplicateMemoryArray(ptr, source, num)
Definition: memory.h:135
SCIP_RETCODE SCIPconshdlrUnlockVars(SCIP_CONSHDLR *conshdlr, SCIP_SET *set)
Definition: cons.c:4164
#define SCIP_DECL_PROBTRANS(x)
Definition: type_prob.h:74
SCIP_EXPORT SCIP_COL * SCIPvarGetCol(SCIP_VAR *var)
Definition: var.c:17376
internal methods for problem variables
SCIP_Bool SCIPsetIsIntegral(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6125
public data structures and miscellaneous methods
SCIP_PROBDATA * probdata
Definition: struct_prob.h:53
void SCIPhashtableFree(SCIP_HASHTABLE **hashtable)
Definition: misc.c:2285
#define SCIP_Bool
Definition: def.h:70
#define SCIP_DECL_PROBEXITSOL(x)
Definition: type_prob.h:110
void SCIPvarCapture(SCIP_VAR *var)
Definition: var.c:2774
SCIP_Bool SCIPprobIsPermuted(SCIP_PROB *prob)
Definition: prob.c:2233
char * name
Definition: struct_cons.h:43
int ncontvars
Definition: struct_prob.h:65
int nbinvars
Definition: struct_prob.h:62
SCIP_Real SCIPprobGetObjoffset(SCIP_PROB *prob)
Definition: prob.c:2381
enum SCIP_Objsense SCIP_OBJSENSE
Definition: type_prob.h:41
SCIP_RETCODE SCIPvarRemove(SCIP_VAR *var, BMS_BLKMEM *blkmem, SCIP_CLIQUETABLE *cliquetable, SCIP_SET *set, SCIP_Bool final)
Definition: var.c:5900
SCIP_RETCODE SCIPconsRelease(SCIP_CONS **cons, BMS_BLKMEM *blkmem, SCIP_SET *set)
Definition: cons.c:6207
void SCIPvarStoreRootSol(SCIP_VAR *var, SCIP_Bool roothaslp)
Definition: var.c:13033
#define MAX(x, y)
Definition: tclique_def.h:83
void SCIPprobSetTrans(SCIP_PROB *prob, SCIP_DECL_PROBTRANS((*probtrans)))
Definition: prob.c:345
public methods for LP management
#define SCIPsetDebugMsg
Definition: set.h:1721
SCIP_RETCODE SCIPeventCreateVarDeleted(SCIP_EVENT **event, BMS_BLKMEM *blkmem, SCIP_VAR *var)
Definition: event.c:535
SCIP_Bool SCIPprobAllColsInLP(SCIP_PROB *prob, SCIP_SET *set, SCIP_LP *lp)
Definition: prob.c:2275
SCIP_RETCODE SCIPprobRemoveConsName(SCIP_PROB *prob, SCIP_CONS *cons)
Definition: prob.c:1255
SCIP_VAR ** deletedvars
Definition: struct_prob.h:57
SCIP_RETCODE SCIPprobTransform(SCIP_PROB *source, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_PRIMAL *primal, SCIP_TREE *tree, SCIP_REOPT *reopt, SCIP_LP *lp, SCIP_BRANCHCAND *branchcand, SCIP_EVENTFILTER *eventfilter, SCIP_EVENTQUEUE *eventqueue, SCIP_CONFLICTSTORE *conflictstore, SCIP_PROB **target)
Definition: prob.c:518
SCIP_RETCODE SCIPbranchcandUpdateVar(SCIP_BRANCHCAND *branchcand, SCIP_SET *set, SCIP_VAR *var)
Definition: branch.c:1136
SCIP_Real SCIPprobGetAbsMaxObjCoef(SCIP_PROB *prob, SCIP_SET *set)
Definition: prob.c:2059
datastructures for problem statistics
SCIP_Bool transformed
Definition: struct_prob.h:79
void SCIPprobSetObjlim(SCIP_PROB *prob, SCIP_Real objlim)
Definition: prob.c:1455
int maxnconss
Definition: struct_prob.h:74
SCIP_RETCODE SCIPprobDelCons(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat, SCIP_CONS *cons)
Definition: prob.c:1345
SCIP_EXPORT SCIP_Real SCIPvarGetLbLocal(SCIP_VAR *var)
Definition: var.c:17718
int nfixedvars
Definition: struct_prob.h:68
int ncolvars
Definition: struct_prob.h:66
SCIP * scip
Definition: struct_var.h:201
void SCIPprobStoreRootSol(SCIP_PROB *prob, SCIP_SET *set, SCIP_STAT *stat, SCIP_LP *lp, SCIP_Bool roothaslp)
Definition: prob.c:1728
SCIP_Bool SCIPprobIsTransformed(SCIP_PROB *prob)
Definition: prob.c:2253
#define SCIP_HASHSIZE_NAMES
Definition: def.h:283
SCIP_Bool SCIPsetIsDualfeasPositive(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6710
datastructures for storing and manipulating the main problem
SCIP_RETCODE SCIPvarLoose(SCIP_VAR *var, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_EVENTQUEUE *eventqueue, SCIP_PROB *prob, SCIP_LP *lp)
Definition: var.c:3508
SCIP_Real SCIPprobGetAbsMinObjCoef(SCIP_PROB *prob, SCIP_SET *set)
Definition: prob.c:2032
SCIP_EXPORT SCIP_Real SCIPvarGetUbLocal(SCIP_VAR *var)
Definition: var.c:17728
methods for sorting joint arrays of various types
SCIP_Real SCIPsetFeasFloor(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6545
void SCIPlpStoreRootObjval(SCIP_LP *lp, SCIP_SET *set, SCIP_PROB *prob)
Definition: lp.c:13122
SCIP_Real objlim
Definition: struct_prob.h:44
void SCIPconsCapture(SCIP_CONS *cons)
Definition: cons.c:6195
struct SCIP_ProbData SCIP_PROBDATA
Definition: type_prob.h:44
SCIP_Bool nlpenabled
Definition: struct_prob.h:80
int fixedvarssize
Definition: struct_prob.h:67
static SCIP_RETCODE probEnsureFixedvarsMem(SCIP_PROB *prob, SCIP_SET *set, int num)
Definition: prob.c:85
static SCIP_RETCODE probRemoveVar(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_CLIQUETABLE *cliquetable, SCIP_SET *set, SCIP_VAR *var)
Definition: prob.c:803
SCIP_RETCODE SCIPprobCopy(SCIP_PROB **prob, BMS_BLKMEM *blkmem, SCIP_SET *set, const char *name, SCIP *sourcescip, SCIP_PROB *sourceprob, SCIP_HASHMAP *varmap, SCIP_HASHMAP *consmap, SCIP_Bool global)
Definition: prob.c:192
int nconss
Definition: struct_prob.h:73
#define SCIP_HASHSIZE_NAMES_SMALL
Definition: def.h:286
public methods for message output
data structures for LP management
void SCIPprobUpdateDualbound(SCIP_PROB *prob, SCIP_Real newbound)
Definition: prob.c:1559
void SCIPprobSetDelorig(SCIP_PROB *prob, SCIP_DECL_PROBDELORIG((*probdelorig)))
Definition: prob.c:334
int SCIPsnprintf(char *t, int len, const char *s,...)
Definition: misc.c:10590
void SCIPmessageFPrintInfo(SCIP_MESSAGEHDLR *messagehdlr, FILE *file, const char *formatstr,...)
Definition: message.c:609
SCIP_Bool SCIPsetIsGT(SCIP_SET *set, SCIP_Real val1, SCIP_Real val2)
Definition: set.c:6056
datastructures for problem variables
SCIP_RETCODE SCIPvarResetBounds(SCIP_VAR *var, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_STAT *stat)
Definition: var.c:9035
const char * SCIPconsGetName(SCIP_CONS *cons)
Definition: cons.c:8089
#define SCIP_Real
Definition: def.h:163
internal methods for problem statistics
SCIP_VAR ** vars
Definition: struct_prob.h:55
void SCIPprobSetDualbound(SCIP_PROB *prob, SCIP_Real dualbound)
Definition: prob.c:1444
int consssize
Definition: struct_prob.h:72
SCIP_VAR ** SCIPprobGetVars(SCIP_PROB *prob)
Definition: prob.c:2363
#define BMSallocMemory(ptr)
Definition: memory.h:111
SCIP_CONS ** conss
Definition: struct_prob.h:59
#define SCIP_INVALID
Definition: def.h:183
#define BMSreallocMemoryArray(ptr, num)
Definition: memory.h:119
internal methods for constraints and constraint handlers
SCIP_Bool SCIPlpIsRelax(SCIP_LP *lp)
Definition: lp.c:17619
#define SCIP_Longint
Definition: def.h:148
int SCIPprobGetNImplBinVars(SCIP_PROB *prob)
Definition: prob.c:1968
SCIP_RETCODE SCIPbranchcandRemoveVar(SCIP_BRANCHCAND *branchcand, SCIP_VAR *var)
Definition: branch.c:1119
void SCIPprobInvalidateDualbound(SCIP_PROB *prob)
Definition: prob.c:1586
void SCIPprobSetDeltrans(SCIP_PROB *prob, SCIP_DECL_PROBDELTRANS((*probdeltrans)))
Definition: prob.c:356
SCIP_BASESTAT SCIPcolGetBasisStatus(SCIP_COL *col)
Definition: lp.c:16890
SCIP_Real SCIPsetEpsilon(SCIP_SET *set)
Definition: set.c:5867
SCIP_STAGE SCIPsetGetStage(SCIP_SET *set)
Definition: set.c:2917
SCIP_EXPORT int SCIPvarGetProbindex(SCIP_VAR *var)
Definition: var.c:17355
unsigned int updatedeactivate
Definition: struct_cons.h:89
enum SCIP_Vartype SCIP_VARTYPE
Definition: type_var.h:60
SCIP_Real SCIPprobExternObjval(SCIP_PROB *transprob, SCIP_PROB *origprob, SCIP_SET *set, SCIP_Real objval)
Definition: prob.c:2082
static SCIP_Bool varHasName(SCIP_VAR *var)
Definition: prob.c:170
SCIP_RETCODE SCIPprobAddCons(SCIP_PROB *prob, SCIP_SET *set, SCIP_STAT *stat, SCIP_CONS *cons)
Definition: prob.c:1277
int addarraypos
Definition: struct_cons.h:50
SCIP_RETCODE SCIPconsDeactivate(SCIP_CONS *cons, SCIP_SET *set, SCIP_STAT *stat)
Definition: cons.c:6775
SCIP_Bool SCIPsetIsDualfeasNegative(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6721
void SCIPconsSetLocal(SCIP_CONS *cons, SCIP_Bool local)
Definition: cons.c:6651
SCIP_RETCODE SCIPprobDelVar(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_EVENTQUEUE *eventqueue, SCIP_VAR *var, SCIP_Bool *deleted)
Definition: prob.c:1001
SCIP_EXPORT void SCIPvarSetBestRootSol(SCIP_VAR *var, SCIP_Real rootsol, SCIP_Real rootredcost, SCIP_Real rootlpobjval)
Definition: var.c:13609
SCIP_Longint nnodes
Definition: struct_stat.h:73
SCIP_RETCODE SCIPprobExitPresolve(SCIP_PROB *prob, SCIP_SET *set)
Definition: prob.c:1853
struct BMS_BlkMem BMS_BLKMEM
Definition: memory.h:429
SCIP_RETCODE SCIPlpUpdateDelVar(SCIP_LP *lp, SCIP_SET *set, SCIP_VAR *var)
Definition: lp.c:13993
int startnvars
Definition: struct_prob.h:75
SCIP_RETCODE SCIPcalcIntegralScalar(SCIP_Real *vals, int nvals, SCIP_Real mindelta, SCIP_Real maxdelta, SCIP_Longint maxdnom, SCIP_Real maxscale, SCIP_Real *intscalar, SCIP_Bool *success)
Definition: misc.c:9444
SCIP_Real SCIPcolGetRedcost(SCIP_COL *col, SCIP_STAT *stat, SCIP_LP *lp)
Definition: lp.c:3941
#define SCIP_ALLOC(x)
Definition: def.h:375
SCIP_Real SCIPlpGetColumnObjval(SCIP_LP *lp)
Definition: lp.c:13091
#define SCIPABORT()
Definition: def.h:336
SCIP_LPSOLSTAT lpsolstat
Definition: struct_lp.h:343
SCIP_RETCODE SCIPconshdlrLockVars(SCIP_CONSHDLR *conshdlr, SCIP_SET *set)
Definition: cons.c:4149
const char * SCIPprobGetName(SCIP_PROB *prob)
Definition: prob.c:2309
datastructures for global SCIP settings
void SCIPprobMarkPermuted(SCIP_PROB *prob)
Definition: prob.c:2243
void SCIPvarMarkDeleted(SCIP_VAR *var)
Definition: var.c:5936
#define OBJSCALE_MAXSCALE
Definition: prob.c:50
SCIP_RETCODE SCIPprobAddVar(SCIP_PROB *prob, BMS_BLKMEM *blkmem, SCIP_SET *set, SCIP_LP *lp, SCIP_BRANCHCAND *branchcand, SCIP_EVENTFILTER *eventfilter, SCIP_EVENTQUEUE *eventqueue, SCIP_VAR *var)
Definition: prob.c:928
SCIP_Real objscale
Definition: struct_prob.h:42
int deletedvarssize
Definition: struct_prob.h:69