Scippy

SCIP

Solving Constraint Integer Programs

expr.c
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1/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
2/* */
3/* This file is part of the program and library */
4/* SCIP --- Solving Constraint Integer Programs */
5/* */
6/* Copyright (c) 2002-2024 Zuse Institute Berlin (ZIB) */
7/* */
8/* Licensed under the Apache License, Version 2.0 (the "License"); */
9/* you may not use this file except in compliance with the License. */
10/* You may obtain a copy of the License at */
11/* */
12/* http://www.apache.org/licenses/LICENSE-2.0 */
13/* */
14/* Unless required by applicable law or agreed to in writing, software */
15/* distributed under the License is distributed on an "AS IS" BASIS, */
16/* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. */
17/* See the License for the specific language governing permissions and */
18/* limitations under the License. */
19/* */
20/* You should have received a copy of the Apache-2.0 license */
21/* along with SCIP; see the file LICENSE. If not visit scipopt.org. */
22/* */
23/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
24
25/**@file expr.c
26 * @ingroup OTHER_CFILES
27 * @brief functions for algebraic expressions
28 * @author Ksenia Bestuzheva
29 * @author Benjamin Mueller
30 * @author Felipe Serrano
31 * @author Stefan Vigerske
32 */
33
34#include <assert.h>
35#include <ctype.h>
36
37#include "scip/expr.h"
38#include "scip/struct_expr.h"
39#include "scip/pub_misc.h"
40#include "scip/clock.h"
41#include "scip/set.h"
42#include "scip/pub_var.h"
43#include "scip/pub_message.h"
44#include "scip/sol.h"
45#include "scip/tree.h"
46#include "scip/struct_set.h"
47#include "scip/struct_stat.h"
48#include "scip/lapack_calls.h"
49
50/*lint -e440*/
51/*lint -e441*/
52/*lint -e777*/
53
54/*
55 * Data structures
56 */
57
58/** printing to file data */
59struct SCIP_ExprPrintData
60{
61 FILE* file; /**< file to print to */
62 SCIP_EXPRITER* iterator; /**< iterator to use */
63 SCIP_Bool closefile; /**< whether file need to be closed when finished printing */
64 SCIP_HASHMAP* leaveexprs; /**< hashmap storing leave (no children) expressions */
65 SCIP_EXPRPRINT_WHAT whattoprint; /**< flags that indicate what to print for each expression */
66};
67
68/*
69 * Local methods
70 */
71
72/** frees an expression */
73static
75 BMS_BLKMEM* blkmem, /**< block memory */
76 SCIP_EXPR** expr /**< pointer to free the expression */
77 )
78{
79 assert(expr != NULL);
80 assert(*expr != NULL);
81 assert((*expr)->nuses == 1);
82 assert((*expr)->quaddata == NULL);
83 assert((*expr)->ownerdata == NULL);
84
85 /* free children array, if any */
86 BMSfreeBlockMemoryArrayNull(blkmem, &(*expr)->children, (*expr)->childrensize);
87
88 BMSfreeBlockMemory(blkmem, expr);
89 assert(*expr == NULL);
90
91 return SCIP_OKAY;
92}
93
94/*
95 * quadratic representation of expression
96 */
97
98/** first time seen quadratically and
99 * seen before linearly --> --nlinterms; assign 2; ++nquadterms
100 * not seen before linearly --> assing 1; ++nquadterms
101 *
102 * seen before --> assign += 1
103 */
104static
106 SCIP_EXPR* expr, /**< the expression */
107 SCIP_HASHMAP* seenexpr, /**< hash map */
108 int* nquadterms, /**< number of quadratic terms */
109 int* nlinterms /**< number of linear terms */
110 )
111{
112 if( SCIPhashmapExists(seenexpr, (void*)expr) )
113 {
114 int nseen = SCIPhashmapGetImageInt(seenexpr, (void*)expr);
115
116 if( nseen < 0 )
117 {
118 /* only seen linearly before */
119 assert(nseen == -1);
120
121 --*nlinterms;
122 ++*nquadterms;
123 SCIP_CALL( SCIPhashmapSetImageInt(seenexpr, (void*)expr, 2) );
124 }
125 else
126 {
127 assert(nseen > 0);
128 SCIP_CALL( SCIPhashmapSetImageInt(seenexpr, (void*)expr, nseen + 1) );
129 }
130 }
131 else
132 {
133 ++*nquadterms;
134 SCIP_CALL( SCIPhashmapInsertInt(seenexpr, (void*)expr, 1) );
135 }
136
137 return SCIP_OKAY;
138}
139
140/** returns a quadexprterm that contains the expr
141 *
142 * it either finds one that already exists or creates a new one
143 */
144static
146 BMS_BLKMEM* blkmem, /**< block memory */
147 SCIP_EXPR* expr, /**< the expression */
148 SCIP_HASHMAP* expr2idx, /**< map: expr to index in quadexpr->quadexprterms */
149 SCIP_HASHMAP* seenexpr, /**< map: expr to number of times it was seen */
150 SCIP_QUADEXPR* quadexpr, /**< data of quadratic representation of expression */
151 SCIP_QUADEXPR_QUADTERM** quadexprterm /**< buffer to store quadexprterm */
152 )
153{
154 assert(expr != NULL);
155 assert(expr2idx != NULL);
156 assert(quadexpr != NULL);
157 assert(quadexprterm != NULL);
158
159 if( SCIPhashmapExists(expr2idx, (void*)expr) )
160 {
161 *quadexprterm = &quadexpr->quadexprterms[SCIPhashmapGetImageInt(expr2idx, (void*)expr)];
162 assert((*quadexprterm)->expr == expr);
163 }
164 else
165 {
166 SCIP_CALL( SCIPhashmapInsertInt(expr2idx, expr, quadexpr->nquadexprs) );
167 *quadexprterm = &quadexpr->quadexprterms[quadexpr->nquadexprs];
168 ++quadexpr->nquadexprs;
169
170 (*quadexprterm)->expr = expr;
171 (*quadexprterm)->sqrcoef = 0.0;
172 (*quadexprterm)->sqrexpr = NULL;
173 (*quadexprterm)->lincoef = 0.0;
174 (*quadexprterm)->nadjbilin = 0;
175 (*quadexprterm)->adjbilinsize = SCIPhashmapGetImageInt(seenexpr, (void*)expr);
176 SCIP_ALLOC( BMSallocBlockMemoryArray(blkmem, &(*quadexprterm)->adjbilin, (*quadexprterm)->adjbilinsize) );
177 }
178
179 return SCIP_OKAY;
180}
181
182
183/** evaluate and forward-differentiate expression
184 *
185 * also initializes derivative and bardot to 0.0
186 */
187static
189 SCIP_SET* set, /**< global SCIP settings */
190 SCIP_STAT* stat, /**< dynamic problem statistics */
191 BMS_BLKMEM* blkmem, /**< block memory */
192 SCIP_EXPR* expr, /**< expression to be evaluated */
193 SCIP_SOL* sol, /**< solution to be evaluated */
194 SCIP_Longint soltag, /**< tag that uniquely identifies the solution (with its values), or 0. */
195 SCIP_SOL* direction /**< direction for directional derivative */
196 )
197{
198 SCIP_EXPRITER* it;
199
200 assert(set != NULL);
201 assert(stat != NULL);
202 assert(blkmem != NULL);
203 assert(expr != NULL);
204
205 /* assume we'll get a domain error, so we don't have to get this expr back if we abort the iteration
206 * if there is no domain error, then we will overwrite the evalvalue in the last leaveexpr stage
207 */
208 expr->evalvalue = SCIP_INVALID;
209 expr->evaltag = soltag;
210 expr->dot = SCIP_INVALID;
211
212 /* start a new difftag */
213 ++stat->exprlastdifftag;
214
215 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
218
219 for( expr = SCIPexpriterGetCurrent(it); !SCIPexpriterIsEnd(it); expr = SCIPexpriterGetNext(it) )
220 {
221 /* evaluate expression only if necessary */
222 if( soltag == 0 || expr->evaltag != soltag )
223 {
224 SCIP_CALL( SCIPexprhdlrEvalExpr(expr->exprhdlr, set, NULL, expr, &expr->evalvalue, NULL, sol) );
225
226 expr->evaltag = soltag;
227 }
228
229 if( expr->evalvalue == SCIP_INVALID )
230 break;
231
232 if( expr->difftag != stat->exprlastdifftag )
233 {
234 /* compute forward diff */
235 SCIP_CALL( SCIPexprhdlrFwDiffExpr(expr->exprhdlr, set, expr, &expr->dot, direction) );
236
237 if( expr->dot == SCIP_INVALID )
238 break;
239
240 expr->derivative = 0.0;
241 expr->bardot = 0.0;
242 expr->difftag = stat->exprlastdifftag;
243 }
244 }
245
246 SCIPexpriterFree(&it);
247
248 return SCIP_OKAY;
249}
250
251
252/*
253 * Public methods
254 */
255
256/* Undo the defines from pub_expr.h, which exist if NDEBUG is defined. */
257#ifdef NDEBUG
258#undef SCIPexprhdlrSetCopyFreeHdlr
259#undef SCIPexprhdlrSetCopyFreeData
260#undef SCIPexprhdlrSetPrint
261#undef SCIPexprhdlrSetParse
262#undef SCIPexprhdlrSetCurvature
263#undef SCIPexprhdlrSetMonotonicity
264#undef SCIPexprhdlrSetIntegrality
265#undef SCIPexprhdlrSetHash
266#undef SCIPexprhdlrSetCompare
267#undef SCIPexprhdlrSetDiff
268#undef SCIPexprhdlrSetIntEval
269#undef SCIPexprhdlrSetSimplify
270#undef SCIPexprhdlrSetReverseProp
271#undef SCIPexprhdlrSetEstimate
272#undef SCIPexprhdlrSetGetSymdata
273#undef SCIPexprhdlrGetName
274#undef SCIPexprhdlrGetDescription
275#undef SCIPexprhdlrGetPrecedence
276#undef SCIPexprhdlrGetData
277#undef SCIPexprhdlrHasPrint
278#undef SCIPexprhdlrHasBwdiff
279#undef SCIPexprhdlrHasFwdiff
280#undef SCIPexprhdlrHasIntEval
281#undef SCIPexprhdlrHasEstimate
282#undef SCIPexprhdlrHasInitEstimates
283#undef SCIPexprhdlrHasSimplify
284#undef SCIPexprhdlrHasCurvature
285#undef SCIPexprhdlrHasMonotonicity
286#undef SCIPexprhdlrHasReverseProp
287#undef SCIPexprhdlrGetNCreated
288#undef SCIPexprhdlrGetNIntevalCalls
289#undef SCIPexprhdlrGetIntevalTime
290#undef SCIPexprhdlrGetNReversepropCalls
291#undef SCIPexprhdlrGetReversepropTime
292#undef SCIPexprhdlrGetNCutoffs
293#undef SCIPexprhdlrGetNDomainReductions
294#undef SCIPexprhdlrIncrementNDomainReductions
295#undef SCIPexprhdlrGetNEstimateCalls
296#undef SCIPexprhdlrGetEstimateTime
297#undef SCIPexprhdlrGetNBranchings
298#undef SCIPexprhdlrIncrementNBranchings
299#undef SCIPexprhdlrGetNSimplifyCalls
300#undef SCIPexprhdlrGetSimplifyTime
301#undef SCIPexprhdlrGetNSimplifications
302#endif
303
304/** create expression handler */
306 BMS_BLKMEM* blkmem, /**< block memory */
307 SCIP_EXPRHDLR** exprhdlr, /**< buffer where to store created expression handler */
308 const char* name, /**< name of expression handler (must not be NULL) */
309 const char* desc, /**< description of expression handler (can be NULL) */
310 unsigned int precedence, /**< precedence of expression operation (used for printing) */
311 SCIP_DECL_EXPREVAL((*eval)), /**< point evaluation callback (must not be NULL) */
312 SCIP_EXPRHDLRDATA* data /**< data of expression handler (can be NULL) */
313 )
314{
315 assert(exprhdlr != NULL);
316 assert(name != NULL);
317
318 SCIP_ALLOC( BMSallocClearBlockMemory(blkmem, exprhdlr) );
319
320 SCIP_ALLOC( BMSduplicateMemoryArray(&(*exprhdlr)->name, name, strlen(name)+1) );
321 if( desc != NULL )
322 {
323 SCIP_ALLOC( BMSduplicateMemoryArray(&(*exprhdlr)->desc, desc, strlen(desc)+1) );
324 }
325
326 (*exprhdlr)->precedence = precedence;
327 (*exprhdlr)->eval = eval;
328 (*exprhdlr)->data = data;
329
330 /* create clocks */
331 SCIP_CALL( SCIPclockCreate(&(*exprhdlr)->estimatetime, SCIP_CLOCKTYPE_DEFAULT) );
332 SCIP_CALL( SCIPclockCreate(&(*exprhdlr)->intevaltime, SCIP_CLOCKTYPE_DEFAULT) );
333 SCIP_CALL( SCIPclockCreate(&(*exprhdlr)->proptime, SCIP_CLOCKTYPE_DEFAULT) );
334 SCIP_CALL( SCIPclockCreate(&(*exprhdlr)->simplifytime, SCIP_CLOCKTYPE_DEFAULT) );
335
336 return SCIP_OKAY;
337}
338
339/** frees expression handler */
341 SCIP_EXPRHDLR** exprhdlr, /**< pointer to expression handler to be freed */
342 SCIP_SET* set, /**< global SCIP settings */
343 BMS_BLKMEM* blkmem /**< block memory */
344 )
345{
346 if( (*exprhdlr)->freehdlr != NULL )
347 {
348 SCIP_CALL( (*exprhdlr)->freehdlr(set->scip, *exprhdlr, &(*exprhdlr)->data) );
349 }
350
351 /* free clocks */
352 SCIPclockFree(&(*exprhdlr)->simplifytime);
353 SCIPclockFree(&(*exprhdlr)->intevaltime);
354 SCIPclockFree(&(*exprhdlr)->proptime);
355 SCIPclockFree(&(*exprhdlr)->estimatetime);
356
357 BMSfreeMemoryArrayNull(&(*exprhdlr)->desc);
358 BMSfreeMemoryArray(&(*exprhdlr)->name);
359
360 BMSfreeBlockMemory(blkmem, exprhdlr);
361
362 return SCIP_OKAY;
363}
364
365/**@addtogroup PublicExprHandlerMethods
366 * @{
367 */
368
369/** set the expression handler callbacks to copy and free an expression handler */
371 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
372 SCIP_DECL_EXPRCOPYHDLR((*copyhdlr)), /**< handler copy callback (can be NULL) */
373 SCIP_DECL_EXPRFREEHDLR((*freehdlr)) /**< handler free callback (can be NULL) */
374 )
375{
376 assert(exprhdlr != NULL);
377
378 exprhdlr->copyhdlr = copyhdlr;
379 exprhdlr->freehdlr = freehdlr;
380}
381
382/** set the expression handler callbacks to copy and free expression data */
384 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
385 SCIP_DECL_EXPRCOPYDATA((*copydata)), /**< expression data copy callback (can be NULL for expressions without data) */
386 SCIP_DECL_EXPRFREEDATA((*freedata)) /**< expression data free callback (can be NULL if data does not need to be freed) */
387 )
388{ /*lint --e{715}*/
389 assert(exprhdlr != NULL);
390
391 exprhdlr->copydata = copydata;
392 exprhdlr->freedata = freedata;
393}
394
395/** set the print callback of an expression handler */
397 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
398 SCIP_DECL_EXPRPRINT((*print)) /**< print callback (can be NULL) */
399 )
400{
401 assert(exprhdlr != NULL);
402
403 exprhdlr->print = print;
404}
405
406/** set the parse callback of an expression handler */
408 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
409 SCIP_DECL_EXPRPARSE((*parse)) /**< parse callback (can be NULL) */
410 )
411{
412 assert(exprhdlr != NULL);
413
414 exprhdlr->parse = parse;
415}
416
417/** set the curvature detection callback of an expression handler */
419 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
420 SCIP_DECL_EXPRCURVATURE((*curvature)) /**< curvature detection callback (can be NULL) */
421 )
422{
423 assert(exprhdlr != NULL);
424
425 exprhdlr->curvature = curvature;
426}
427
428/** set the monotonicity detection callback of an expression handler */
430 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
431 SCIP_DECL_EXPRMONOTONICITY((*monotonicity)) /**< monotonicity detection callback (can be NULL) */
432 )
433{
434 assert(exprhdlr != NULL);
435
436 exprhdlr->monotonicity = monotonicity;
437}
438
439/** set the integrality detection callback of an expression handler */
441 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
442 SCIP_DECL_EXPRINTEGRALITY((*integrality)) /**< integrality detection callback (can be NULL) */
443 )
444{
445 assert(exprhdlr != NULL);
446
447 exprhdlr->integrality = integrality;
448}
449
450/** set the hash callback of an expression handler */
452 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
453 SCIP_DECL_EXPRHASH((*hash)) /**< hash callback (can be NULL) */
454 )
455{
456 assert(exprhdlr != NULL);
457
458 exprhdlr->hash = hash;
459}
460
461/** set the compare callback of an expression handler */
463 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
464 SCIP_DECL_EXPRCOMPARE((*compare)) /**< compare callback (can be NULL) */
465 )
466{
467 assert(exprhdlr != NULL);
468
469 exprhdlr->compare = compare;
470}
471
472/** set differentiation callbacks of an expression handler */
474 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
475 SCIP_DECL_EXPRBWDIFF((*bwdiff)), /**< backward derivative evaluation callback (can be NULL) */
476 SCIP_DECL_EXPRFWDIFF((*fwdiff)), /**< forward derivative evaluation callback (can be NULL) */
477 SCIP_DECL_EXPRBWFWDIFF((*bwfwdiff)) /**< backward-forward derivative evaluation callback (can be NULL) */
478 )
479{
480 assert(exprhdlr != NULL);
481
482 exprhdlr->bwdiff = bwdiff;
483 exprhdlr->fwdiff = fwdiff;
484 exprhdlr->bwfwdiff = bwfwdiff;
485}
486
487/** set the interval evaluation callback of an expression handler */
489 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
490 SCIP_DECL_EXPRINTEVAL((*inteval)) /**< interval evaluation callback (can be NULL) */
491 )
492{
493 assert(exprhdlr != NULL);
494
495 exprhdlr->inteval = inteval;
496}
497
498/** set the simplify callback of an expression handler */
500 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
501 SCIP_DECL_EXPRSIMPLIFY((*simplify)) /**< simplify callback (can be NULL) */
502 )
503{
504 assert(exprhdlr != NULL);
505
506 exprhdlr->simplify = simplify;
507}
508
509/** set the reverse propagation callback of an expression handler */
511 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
512 SCIP_DECL_EXPRREVERSEPROP((*reverseprop)) /**< reverse propagation callback (can be NULL) */
513 )
514{
515 assert(exprhdlr != NULL);
516
517 exprhdlr->reverseprop = reverseprop;
518}
519
520/** set the symmetry information callback of an expression handler */
522 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
523 SCIP_DECL_EXPRGETSYMDATA((*getsymdata)) /**< symmetry information callback (can be NULL) */
524 )
525{
526 assert(exprhdlr != NULL);
527
528 exprhdlr->getsymdata = getsymdata;
529}
530
531/** set the estimation callbacks of an expression handler */
533 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
534 SCIP_DECL_EXPRINITESTIMATES((*initestimates)), /**< initial estimators callback (can be NULL) */
535 SCIP_DECL_EXPRESTIMATE((*estimate)) /**< estimator callback (can be NULL) */
536 )
537{
538 assert(exprhdlr != NULL);
539
540 exprhdlr->initestimates = initestimates;
541 exprhdlr->estimate = estimate;
542}
543
544/** gives the name of an expression handler */
546 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
547 )
548{
549 assert(exprhdlr != NULL);
550
551 return exprhdlr->name;
552}
553
554/** gives the description of an expression handler (can be NULL) */
556 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
557 )
558{
559 assert(exprhdlr != NULL);
560
561 return exprhdlr->desc;
562}
563
564/** gives the precedence of an expression handler */
566 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
567 )
568{
569 assert(exprhdlr != NULL);
570
571 return exprhdlr->precedence;
572}
573
574/** gives the data of an expression handler */
576 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
577 )
578{
579 assert(exprhdlr != NULL);
580
581 return exprhdlr->data;
582}
583
584/** returns whether expression handler implements the print callback */
586 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
587 )
588{
589 assert(exprhdlr != NULL);
590
591 return exprhdlr->print != NULL;
592}
593
594/** returns whether expression handler implements the backward differentiation callback */
596 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
597 )
598{
599 assert(exprhdlr != NULL);
600
601 return exprhdlr->bwdiff != NULL;
602}
603
604/** returns whether expression handler implements the forward differentiation callback */
606 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
607 )
608{
609 assert(exprhdlr != NULL);
610
611 return exprhdlr->fwdiff != NULL;
612}
613
614/** returns whether expression handler implements the interval evaluation callback */
616 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
617 )
618{
619 assert(exprhdlr != NULL);
620
621 return exprhdlr->inteval != NULL;
622}
623
624/** returns whether expression handler implements the estimator callback */
626 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
627 )
628{
629 assert(exprhdlr != NULL);
630
631 return exprhdlr->estimate != NULL;
632}
633
634/** returns whether expression handler implements the initial estimators callback */
636 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
637 )
638{
639 assert(exprhdlr != NULL);
640
641 return exprhdlr->initestimates != NULL;
642}
643
644/** returns whether expression handler implements the simplification callback */
646 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
647 )
648{
649 assert(exprhdlr != NULL);
650
651 return exprhdlr->simplify != NULL;
652}
653
654/** returns whether expression handler implements the curvature callback */
656 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
657 )
658{
659 assert(exprhdlr != NULL);
660
661 return exprhdlr->curvature != NULL;
662}
663
664/** returns whether expression handler implements the monotonicity callback */
666 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
667 )
668{
669 assert(exprhdlr != NULL);
670
671 return exprhdlr->monotonicity != NULL;
672}
673
674/** returns whether expression handler implements the reverse propagation callback */
676 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
677 )
678{
679 assert(exprhdlr != NULL);
680
681 return exprhdlr->reverseprop != NULL;
682}
683
684/** returns whether expression handler implements the symmetry information callback */
686 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
687 )
688{
689 assert(exprhdlr != NULL);
690
691 return exprhdlr->getsymdata != NULL;
692}
693
694/** compares two expression handler w.r.t. their name */
695SCIP_DECL_SORTPTRCOMP(SCIPexprhdlrComp)
696{
697 return strcmp(((SCIP_EXPRHDLR*)elem1)->name, ((SCIP_EXPRHDLR*)elem2)->name);
698}
699
700/** gets number of times an expression has been created with given expression handler */
702 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
703 )
704{
705 assert(exprhdlr != NULL);
706
707 return exprhdlr->ncreated;
708}
709
710/** gets number of times the interval evaluation callback was called */
712 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
713 )
714{
715 assert(exprhdlr != NULL);
716
717 return exprhdlr->nintevalcalls;
718}
719
720/** gets time spend in interval evaluation callback */
722 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
723 )
724{
725 assert(exprhdlr != NULL);
726
727 return SCIPclockGetTime(exprhdlr->intevaltime);
728}
729
730/** gets number of times the reverse propagation callback was called */
732 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
733 )
734{
735 assert(exprhdlr != NULL);
736
737 return exprhdlr->npropcalls;
738}
739
740/** gets time spend in reverse propagation callback */
742 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
743 )
744{
745 assert(exprhdlr != NULL);
746
747 return SCIPclockGetTime(exprhdlr->proptime);
748}
749
750/** gets number of times an empty interval was found in reverse propagation */
752 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
753 )
754{
755 assert(exprhdlr != NULL);
756
757 return exprhdlr->ncutoffs;
758}
759
760/** gets number of times a bound reduction was found in reverse propagation (and accepted by caller) */
762 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
763 )
764{
765 assert(exprhdlr != NULL);
766
767 return exprhdlr->ndomreds;
768}
769
770/** increments the domain reductions count of an expression handler */
772 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
773 int nreductions /**< number of reductions to add to counter */
774 )
775{
776 assert(exprhdlr != NULL);
777 assert(nreductions >= 0);
778
779 exprhdlr->ndomreds += nreductions;
780}
781
782/** gets number of times the estimation callback was called */
784 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
785 )
786{
787 assert(exprhdlr != NULL);
788
789 return exprhdlr->nestimatecalls;
790}
791
792/** gets time spend in estimation callback */
794 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
795 )
796{
797 assert(exprhdlr != NULL);
798
799 return SCIPclockGetTime(exprhdlr->estimatetime);
800}
801
802/** gets number of times branching candidates reported by of this expression handler were used to
803 * assemble branching candidates
804 *
805 * that is, how often did we consider branching on a child of this expression
806 */
808 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
809 )
810{
811 assert(exprhdlr != NULL);
812
813 return exprhdlr->nbranchscores;
814}
815
816/** increments the branching candidates count of an expression handler */
818 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
819 )
820{
821 assert(exprhdlr != NULL);
822
823 ++exprhdlr->nbranchscores;
824}
825
826/** gets number of times the simplify callback was called */
828 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
829 )
830{
831 assert(exprhdlr != NULL);
832
833 return exprhdlr->nsimplifycalls;
834}
835
836/** gets time spend in simplify callback */
838 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
839 )
840{
841 assert(exprhdlr != NULL);
842
843 return SCIPclockGetTime(exprhdlr->simplifytime);
844}
845
846/** gets number of times the simplify callback found a simplification */
848 SCIP_EXPRHDLR* exprhdlr /**< expression handler */
849 )
850{
851 assert(exprhdlr != NULL);
852
853 return exprhdlr->nsimplified;
854}
855
856/** @} */
857
858/** copies the given expression handler to a new scip */
860 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
861 SCIP_SET* targetset /**< SCIP_SET of SCIP to copy to */
862 )
863{
864 assert(exprhdlr != NULL);
865 assert(targetset != NULL);
866 assert(targetset->scip != NULL);
867
868 if( exprhdlr->copyhdlr != NULL )
869 {
870 SCIPsetDebugMsg(targetset, "including expression handler <%s> in subscip %p\n",
871 SCIPexprhdlrGetName(exprhdlr), (void*)targetset->scip);
872 SCIP_CALL( exprhdlr->copyhdlr(targetset->scip, exprhdlr) );
873 }
874 else
875 {
876 SCIPsetDebugMsg(targetset, "expression handler <%s> cannot be copied to subscip %p due "
877 "to missing copyhdlr callback\n", SCIPexprhdlrGetName(exprhdlr), (void*)targetset->scip);
878 }
879
880 return SCIP_OKAY;
881}
882
883/** initialization of expression handler (resets statistics) */
885 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
886 SCIP_SET* set /**< global SCIP settings */
887 )
888{
889 assert(exprhdlr != NULL);
890
891 if( set->misc_resetstat )
892 {
893 exprhdlr->ncreated = 0;
894 exprhdlr->nestimatecalls = 0;
895 exprhdlr->nintevalcalls = 0;
896 exprhdlr->npropcalls = 0;
897 exprhdlr->ncutoffs = 0;
898 exprhdlr->ndomreds = 0;
899 exprhdlr->nbranchscores = 0;
900 exprhdlr->nsimplifycalls = 0;
901 exprhdlr->nsimplified = 0;
902
903 SCIPclockReset(exprhdlr->estimatetime);
904 SCIPclockReset(exprhdlr->intevaltime);
905 SCIPclockReset(exprhdlr->proptime);
906 SCIPclockReset(exprhdlr->simplifytime);
907 }
908}
909
910/** calls the print callback of an expression handler
911 *
912 * The method prints an expression.
913 * It is called while iterating over the expression graph at different stages.
914 *
915 * @see SCIP_DECL_EXPRPRINT
916 */
918 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
919 SCIP_SET* set, /**< global SCIP settings */
920 SCIP_MESSAGEHDLR* messagehdlr, /**< message handler */
921 SCIP_EXPR* expr, /**< expression */
922 SCIP_EXPRITER_STAGE stage, /**< stage of expression iteration */
923 int currentchild, /**< index of current child if in stage visitingchild or visitedchild */
924 unsigned int parentprecedence, /**< precedence of parent */
925 FILE* file /**< the file to print to */
926 )
927{
928 assert(exprhdlr != NULL);
929 assert(set != NULL);
930 assert(expr != NULL);
931 assert(expr->exprhdlr == exprhdlr);
932 assert(messagehdlr != NULL);
933
934 if( SCIPexprhdlrHasPrint(exprhdlr) )
935 {
936 SCIP_CALL( exprhdlr->print(set->scip, expr, stage, currentchild, parentprecedence, file) );
937 }
938 else
939 {
940 /* default: <hdlrname>(<child1>, <child2>, ...) */
941 switch( stage )
942 {
944 {
945 SCIPmessageFPrintInfo(messagehdlr, file, "%s", SCIPexprhdlrGetName(expr->exprhdlr));
946 if( expr->nchildren > 0 )
947 {
948 SCIPmessageFPrintInfo(messagehdlr, file, "(");
949 }
950 break;
951 }
952
954 {
955 assert(currentchild >= 0);
956 assert(currentchild < expr->nchildren);
957 if( currentchild < expr->nchildren-1 )
958 {
959 SCIPmessageFPrintInfo(messagehdlr, file, ", ");
960 }
961 else
962 {
963 SCIPmessageFPrintInfo(messagehdlr, file, ")");
964 }
965
966 break;
967 }
968
971 default:
972 break;
973 }
974 }
975
976 return SCIP_OKAY;
977}
978
979/** calls the parse callback of an expression handler
980 *
981 * The method parses an expression.
982 * It should be called when parsing an expression and an operator with the expr handler name is found.
983 *
984 * @see SCIP_DECL_EXPRPARSE
985 */
987 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
988 SCIP_SET* set, /**< global SCIP settings */
989 const char* string, /**< string containing expression to be parse */
990 const char** endstring, /**< buffer to store the position of string after parsing */
991 SCIP_EXPR** expr, /**< buffer to store the parsed expression */
992 SCIP_Bool* success, /**< buffer to store whether the parsing was successful or not */
993 SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), /**< function to call on expression copy to create ownerdata */
994 void* ownercreatedata /**< data to pass to ownercreate */
995 )
996{
997 assert(exprhdlr != NULL);
998 assert(set != NULL);
999 assert(expr != NULL);
1000
1001 *expr = NULL;
1002
1003 if( exprhdlr->parse == NULL )
1004 {
1005 /* TODO we could just look for a comma separated list of operands and try to initialize the expr with this one?
1006 * That would be sufficient for sin, cos, exp, log, abs, for example.
1007 */
1008 SCIPdebugMessage("Expression handler <%s> has no parsing method.\n", SCIPexprhdlrGetName(exprhdlr));
1009 *success = FALSE;
1010 return SCIP_OKAY;
1011 }
1012
1013 /* give control to exprhdlr's parser */
1014 SCIP_CALL( exprhdlr->parse(set->scip, exprhdlr, string, endstring, expr, success, ownercreate, ownercreatedata) );
1015
1016 assert(*success || (*expr == NULL));
1017
1018 return SCIP_OKAY;
1019}
1020
1021/** calls the curvature check callback of an expression handler
1022 *
1023 * @see SCIP_DECL_EXPRCURVATURE
1024 */
1026 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1027 SCIP_SET* set, /**< global SCIP settings */
1028 SCIP_EXPR* expr, /**< expression to check the curvature for */
1029 SCIP_EXPRCURV exprcurvature, /**< desired curvature of this expression */
1030 SCIP_Bool* success, /**< buffer to store whether the desired curvature be obtained */
1031 SCIP_EXPRCURV* childcurv /**< array to store required curvature for each child */
1032 )
1033{
1034 assert(exprhdlr != NULL);
1035 assert(set != NULL);
1036 assert(expr != NULL);
1037 assert(expr->exprhdlr == exprhdlr);
1038 assert(success != NULL);
1039
1040 *success = FALSE;
1041
1042 if( exprhdlr->curvature != NULL )
1043 {
1044 SCIP_CALL( exprhdlr->curvature(set->scip, expr, exprcurvature, success, childcurv) );
1045 }
1046
1047 return SCIP_OKAY;
1048}
1049
1050/** calls the monotonicity check callback of an expression handler
1051 *
1052 * @see SCIP_DECL_EXPRMONOTONICITY
1053 */
1055 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1056 SCIP_SET* set, /**< global SCIP settings */
1057 SCIP_EXPR* expr, /**< expression to check the monotonicity for */
1058 int childidx, /**< index of the considered child expression */
1059 SCIP_MONOTONE* result /**< buffer to store the monotonicity */
1060 )
1061{
1062 assert(exprhdlr != NULL);
1063 assert(set != NULL);
1064 assert(expr != NULL);
1065 assert(expr->exprhdlr == exprhdlr);
1066 assert(result != NULL);
1067
1068 *result = SCIP_MONOTONE_UNKNOWN;
1069
1070 /* check whether the expression handler implements the monotonicity callback */
1071 if( exprhdlr->monotonicity != NULL )
1072 {
1073 SCIP_CALL( exprhdlr->monotonicity(set->scip, expr, childidx, result) );
1074 }
1075
1076 return SCIP_OKAY;
1077}
1078
1079/** calls the integrality check callback of an expression handler
1080 *
1081 * @see SCIP_DECL_EXPRINTEGRALITY
1082 */
1084 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1085 SCIP_SET* set, /**< global SCIP settings */
1086 SCIP_EXPR* expr, /**< expression to check integrality for */
1087 SCIP_Bool* isintegral /**< buffer to store whether expression is integral */
1088 )
1089{
1090 assert(exprhdlr != NULL);
1091 assert(set != NULL);
1092 assert(expr != NULL);
1093 assert(expr->exprhdlr == exprhdlr);
1094 assert(isintegral != NULL);
1095
1096 *isintegral = FALSE;
1097
1098 /* check whether the expression handler implements the monotonicity callback */
1099 if( exprhdlr->integrality != NULL )
1100 {
1101 SCIP_CALL( exprhdlr->integrality(set->scip, expr, isintegral) );
1102 }
1103
1104 return SCIP_OKAY;
1105}
1106
1107/** calls the hash callback of an expression handler
1108 *
1109 * The method hashes an expression by taking the hashes of its children into account.
1110 *
1111 * @see SCIP_DECL_EXPRHASH
1112 */
1114 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1115 SCIP_SET* set, /**< global SCIP settings */
1116 SCIP_EXPR* expr, /**< expression to be hashed */
1117 unsigned int* hashkey, /**< buffer to store the hash value */
1118 unsigned int* childrenhashes /**< array with hash values of children */
1119 )
1120{
1121 assert(exprhdlr != NULL);
1122 assert(set != NULL);
1123 assert(expr != NULL);
1124 assert(expr->exprhdlr == exprhdlr);
1125 assert(hashkey != NULL);
1126 assert(childrenhashes != NULL || expr->nchildren == 0);
1127
1128 if( expr->exprhdlr->hash != NULL )
1129 {
1130 SCIP_CALL( expr->exprhdlr->hash(set->scip, expr, hashkey, childrenhashes) );
1131 }
1132 else
1133 {
1134 int i;
1135
1136 /* compute initial hash from expression handler name if callback is not implemented
1137 * this can lead to more collisions and thus a larger number of expensive expression compare calls
1138 */
1139 *hashkey = 0;
1140 for( i = 0; expr->exprhdlr->name[i] != '\0'; i++ )
1141 *hashkey += (unsigned int) expr->exprhdlr->name[i]; /*lint !e571*/
1142
1143 *hashkey = SCIPcalcFibHash((SCIP_Real)*hashkey);
1144
1145 /* now make use of the hashkeys of the children */
1146 for( i = 0; i < expr->nchildren; ++i )
1147 *hashkey ^= childrenhashes[i];
1148 }
1149
1150 return SCIP_OKAY;
1151}
1152
1153/** calls the compare callback of an expression handler
1154 *
1155 * The method receives two expressions, expr1 and expr2, and returns
1156 * - -1 if expr1 < expr2,
1157 * - 0 if expr1 = expr2,
1158 * - 1 if expr1 > expr2.
1159 *
1160 * @see SCIP_DECL_EXPRCOMPARE
1161 */
1163 SCIP_SET* set, /**< global SCIP settings */
1164 SCIP_EXPR* expr1, /**< first expression in comparison */
1165 SCIP_EXPR* expr2 /**< second expression in comparison */
1166 )
1167{
1168 int i;
1169
1170 assert(expr1 != NULL);
1171 assert(expr2 != NULL);
1172 assert(expr1->exprhdlr == expr2->exprhdlr);
1173
1174 if( expr1->exprhdlr->compare != NULL )
1175 {
1176 /* enforces OR1-OR4 */
1177 return expr1->exprhdlr->compare(set->scip, expr1, expr2);
1178 }
1179
1180 /* enforces OR5: default comparison method of expressions of the same type:
1181 * expr1 < expr2 if and only if expr1_i = expr2_i for all i < k and expr1_k < expr2_k.
1182 * if there is no such k, use number of children to decide
1183 * if number of children is equal, both expressions are equal
1184 * @note: Warning, this method doesn't know about expression data. So if your expressions have special data,
1185 * you must implement the compare callback: SCIP_DECL_EXPRCOMPARE
1186 */
1187 for( i = 0; i < expr1->nchildren && i < expr2->nchildren; ++i )
1188 {
1189 int compareresult = SCIPexprCompare(set, expr1->children[i], expr2->children[i]);
1190 if( compareresult != 0 )
1191 return compareresult;
1192 }
1193
1194 return expr1->nchildren == expr2->nchildren ? 0 : expr1->nchildren < expr2->nchildren ? -1 : 1;
1195}
1196
1197/** calls the evaluation callback of an expression handler
1198 *
1199 * The method evaluates an expression by taking the values of its children into account.
1200 *
1201 * Further, allows to evaluate w.r.t. given expression and children values instead of those stored in children expressions.
1202 *
1203 * @see SCIP_DECL_EXPREVAL
1204 */
1206 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1207 SCIP_SET* set, /**< global SCIP settings */
1208 BMS_BUFMEM* bufmem, /**< buffer memory, can be NULL if childrenvals is NULL */
1209 SCIP_EXPR* expr, /**< expression to be evaluated */
1210 SCIP_Real* val, /**< buffer to store value of expression */
1211 SCIP_Real* childrenvals, /**< values for children, or NULL if values stored in children should be used */
1212 SCIP_SOL* sol /**< solution that is evaluated (can be NULL) */
1213 )
1214{
1215 SCIP_Real* origvals = NULL;
1216
1217 assert(exprhdlr != NULL);
1218 assert(set != NULL);
1219 assert(expr != NULL);
1220 assert(expr->exprhdlr == exprhdlr);
1221 assert(exprhdlr->eval != NULL);
1222 assert(val != NULL);
1223
1224 /* temporarily overwrite the evalvalue in all children with values from childrenvals */
1225 if( childrenvals != NULL && expr->nchildren > 0 )
1226 {
1227 int c;
1228
1229 assert(bufmem != NULL);
1230
1231 SCIP_ALLOC( BMSallocBufferMemoryArray(bufmem, &origvals, expr->nchildren) );
1232
1233 for( c = 0; c < expr->nchildren; ++c )
1234 {
1235 origvals[c] = expr->children[c]->evalvalue;
1236 expr->children[c]->evalvalue = childrenvals[c];
1237 }
1238 }
1239
1240 /* call expression eval callback */
1241 SCIP_CALL( exprhdlr->eval(set->scip, expr, val, sol) );
1242
1243 /* if there was some evaluation error (e.g., overflow) that hasn't been caught yet, then do so now */
1244 if( !SCIPisFinite(*val) )
1245 *val = SCIP_INVALID;
1246
1247 /* restore original evalvalues in children */
1248 if( origvals != NULL )
1249 {
1250 int c;
1251 for( c = 0; c < expr->nchildren; ++c )
1252 expr->children[c]->evalvalue = origvals[c];
1253
1254 BMSfreeBufferMemoryArray(bufmem, &origvals);
1255 }
1256
1257 return SCIP_OKAY;
1258}
1259
1260/** calls the backward derivative evaluation callback of an expression handler
1261 *
1262 * The method should compute the partial derivative of expr w.r.t its child at childidx.
1263 * That is, it returns
1264 * \f[
1265 * \frac{\partial \text{expr}}{\partial \text{child}_{\text{childidx}}}
1266 * \f]
1267 *
1268 * Further, allows to differentiate w.r.t. given expression and children values instead of those stored in children expressions.
1269 *
1270 * @see SCIP_DECL_EXPRBWDIFF
1271 */
1273 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1274 SCIP_SET* set, /**< global SCIP settings */
1275 BMS_BUFMEM* bufmem, /**< buffer memory, can be NULL if childrenvals is NULL */
1276 SCIP_EXPR* expr, /**< expression to be differentiated */
1277 int childidx, /**< index of the child */
1278 SCIP_Real* derivative, /**< buffer to store the partial derivative w.r.t. the i-th children */
1279 SCIP_Real* childrenvals, /**< values for children, or NULL if values stored in children should be used */
1280 SCIP_Real exprval /**< value for expression, used only if childrenvals is not NULL */
1281 )
1282{
1283 SCIP_Real* origchildrenvals;
1284 SCIP_Real origexprval = SCIP_INVALID;
1285 int c;
1286
1287 assert(exprhdlr != NULL);
1288 assert(set != NULL);
1289 assert(expr != NULL);
1290 assert(expr->exprhdlr == exprhdlr);
1291 assert(derivative != NULL);
1292
1293 if( exprhdlr->bwdiff == NULL )
1294 {
1295 *derivative = SCIP_INVALID;
1296 return SCIP_OKAY;
1297 }
1298
1299 if( childrenvals != NULL )
1300 {
1301 /* temporarily overwrite the evalvalue in all children and expr with values from childrenvals and exprval, resp. */
1302 if( expr->nchildren > 0 )
1303 {
1304 assert(bufmem != NULL);
1305 SCIP_ALLOC( BMSallocBufferMemoryArray(bufmem, &origchildrenvals, expr->nchildren) );
1306
1307 for( c = 0; c < expr->nchildren; ++c )
1308 {
1309 origchildrenvals[c] = expr->children[c]->evalvalue;
1310 expr->children[c]->evalvalue = childrenvals[c];
1311 }
1312 }
1313
1314 origexprval = expr->evalvalue;
1315 expr->evalvalue = exprval;
1316 }
1317
1318 SCIP_CALL( expr->exprhdlr->bwdiff(set->scip, expr, childidx, derivative) );
1319
1320 /* if there was some evaluation error (e.g., overflow) that hasn't been caught yet, then do so now */
1321 if( !SCIPisFinite(*derivative) )
1322 *derivative = SCIP_INVALID;
1323
1324 /* restore original evalvalues in children */
1325 if( childrenvals != NULL )
1326 {
1327 if( expr->nchildren > 0 )
1328 {
1329 for( c = 0; c < expr->nchildren; ++c )
1330 expr->children[c]->evalvalue = origchildrenvals[c]; /*lint !e644*/
1331
1332 BMSfreeBufferMemoryArray(bufmem, &origchildrenvals);
1333 }
1334
1335 expr->evalvalue = origexprval;
1336 }
1337
1338 return SCIP_OKAY;
1339}
1340
1341/** calls the forward differentiation callback of an expression handler
1342 *
1343 * @see SCIP_DECL_EXPRFWDIFF
1344 */
1346 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1347 SCIP_SET* set, /**< global SCIP settings */
1348 SCIP_EXPR* expr, /**< expression to be differentiated */
1349 SCIP_Real* dot, /**< buffer to store derivative value */
1350 SCIP_SOL* direction /**< direction of the derivative (useful only for var expressions) */
1351 )
1352{
1353 assert(exprhdlr != NULL);
1354 assert(set != NULL);
1355 assert(expr != NULL);
1356 assert(expr->exprhdlr == exprhdlr);
1357 assert(dot != NULL);
1358
1359 if( exprhdlr->fwdiff == NULL )
1360 {
1361 *dot = SCIP_INVALID;
1362 return SCIP_OKAY;
1363 }
1364
1365 SCIP_CALL( exprhdlr->fwdiff(set->scip, expr, dot, direction) );
1366
1367 /* if there was some evaluation error (e.g., overflow) that hasn't been caught yet, then do so now */
1368 if( !SCIPisFinite(*dot) )
1369 *dot = SCIP_INVALID;
1370
1371 return SCIP_OKAY;
1372}
1373
1374/** calls the evaluation and forward-differentiation callback of an expression handler
1375 *
1376 * The method evaluates an expression by taking the values of its children into account.
1377 * The method differentiates an expression by taking the values and directional derivatives of its children into account.
1378 *
1379 * Further, allows to evaluate and differentiate w.r.t. given values for children instead of those stored in children expressions.
1380 *
1381 * It probably doesn't make sense to call this function for a variable-expression if sol and/or direction are not given.
1382 *
1383 * @see SCIP_DECL_EXPREVAL
1384 * @see SCIP_DECL_EXPRFWDIFF
1385 */
1387 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1388 SCIP_SET* set, /**< global SCIP settings */
1389 BMS_BUFMEM* bufmem, /**< buffer memory, can be NULL if childrenvals is NULL */
1390 SCIP_EXPR* expr, /**< expression to be evaluated */
1391 SCIP_Real* val, /**< buffer to store value of expression */
1392 SCIP_Real* dot, /**< buffer to store derivative value */
1393 SCIP_Real* childrenvals, /**< values for children, or NULL if values stored in children should be used */
1394 SCIP_SOL* sol, /**< solution that is evaluated (can be NULL) */
1395 SCIP_Real* childrendirs, /**< directional derivatives for children, or NULL if dot-values stored in children should be used */
1396 SCIP_SOL* direction /**< direction of the derivative (useful only for var expressions, can be NULL if childrendirs is given) */
1397 )
1398{
1399 SCIP_Real origval;
1400 SCIP_Real* origvals = NULL;
1401 SCIP_Real* origdots = NULL;
1402
1403 assert(exprhdlr != NULL);
1404 assert(set != NULL);
1405 assert(expr != NULL);
1406 assert(expr->exprhdlr == exprhdlr);
1407 assert(exprhdlr->eval != NULL);
1408 assert(val != NULL);
1409 assert(dot != NULL);
1410
1411 /* temporarily overwrite the evalvalue in all children with values from childrenvals */
1412 if( childrenvals != NULL && expr->nchildren > 0 )
1413 {
1414 int c;
1415
1416 assert(bufmem != NULL);
1417
1418 SCIP_ALLOC( BMSallocBufferMemoryArray(bufmem, &origvals, expr->nchildren) );
1419
1420 for( c = 0; c < expr->nchildren; ++c )
1421 {
1422 origvals[c] = expr->children[c]->evalvalue;
1423 expr->children[c]->evalvalue = childrenvals[c];
1424 }
1425 }
1426
1427 /* temporarily overwrite the dot in all children with values from childrendirs */
1428 if( childrendirs != NULL && expr->nchildren > 0 )
1429 {
1430 int c;
1431
1432 assert(bufmem != NULL);
1433
1434 SCIP_ALLOC( BMSallocBufferMemoryArray(bufmem, &origdots, expr->nchildren) );
1435
1436 for( c = 0; c < expr->nchildren; ++c )
1437 {
1438 origdots[c] = expr->children[c]->dot;
1439 expr->children[c]->dot = childrendirs[c];
1440 }
1441 }
1442
1443 /* remember original value */
1444 origval = expr->evalvalue;
1445
1446 /* call expression eval callback */
1447 SCIP_CALL( exprhdlr->eval(set->scip, expr, val, sol) );
1448
1449 /* if there was some evaluation error (e.g., overflow) that hasn't been caught yet, then do so now */
1450 if( !SCIPisFinite(*val) )
1451 *val = SCIP_INVALID;
1452
1453 /* temporarily overwrite evalvalue of expr, since some exprhdlr (e.g., product) access this value in fwdiff */
1454 expr->evalvalue = *val;
1455
1456 /* call forward-differentiation callback (if available) */
1457 SCIP_CALL( SCIPexprhdlrFwDiffExpr(exprhdlr, set, expr, dot, direction) );
1458
1459 /* restore original value */
1460 expr->evalvalue = origval;
1461
1462 /* restore original dots in children */
1463 if( origdots != NULL )
1464 {
1465 int c;
1466 for( c = 0; c < expr->nchildren; ++c )
1467 expr->children[c]->dot = origdots[c];
1468
1469 BMSfreeBufferMemoryArray(bufmem, &origdots);
1470 }
1471
1472 /* restore original evalvalues in children */
1473 if( origvals != NULL )
1474 {
1475 int c;
1476 for( c = 0; c < expr->nchildren; ++c )
1477 expr->children[c]->evalvalue = origvals[c];
1478
1479 BMSfreeBufferMemoryArray(bufmem, &origvals);
1480 }
1481
1482 return SCIP_OKAY;
1483}
1484
1485/** calls the evaluation callback for Hessian directions (backward over forward) of an expression handler
1486 *
1487 * @see SCIP_DECL_EXPRBWFWDIFF
1488 */
1490 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1491 SCIP_SET* set, /**< global SCIP settings */
1492 SCIP_EXPR* expr, /**< expression to be differentiated */
1493 int childidx, /**< index of the child */
1494 SCIP_Real* bardot, /**< buffer to store derivative value */
1495 SCIP_SOL* direction /**< direction of the derivative (useful only for var expressions) */
1496 )
1497{
1498 assert(exprhdlr != NULL);
1499 assert(set != NULL);
1500 assert(expr != NULL);
1501 assert(expr->exprhdlr == exprhdlr);
1502 assert(childidx >= 0);
1503 assert(childidx < expr->nchildren);
1504 assert(bardot != NULL);
1505
1506 if( exprhdlr->bwfwdiff == NULL )
1507 {
1508 *bardot = SCIP_INVALID;
1509 return SCIP_OKAY;
1510 }
1511
1512 SCIP_CALL( expr->exprhdlr->bwfwdiff(set->scip, expr, childidx, bardot, direction) );
1513
1514 /* if there was some evaluation error (e.g., overflow) that hasn't been caught yet, then do so now */
1515 if( !SCIPisFinite(*bardot) )
1516 *bardot = SCIP_INVALID;
1517
1518 return SCIP_OKAY;
1519}
1520
1521/** calls the interval evaluation callback of an expression handler
1522 *
1523 * @see SCIP_DECL_EXPRINTEVAL
1524 */
1526 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1527 SCIP_SET* set, /**< global SCIP settings */
1528 SCIP_EXPR* expr, /**< expression to be evaluated */
1529 SCIP_INTERVAL* interval, /**< buffer where to store interval */
1530 SCIP_DECL_EXPR_INTEVALVAR((*intevalvar)), /**< callback to be called when interval-evaluating a variable */
1531 void* intevalvardata /**< data to be passed to intevalvar callback */
1532 )
1533{
1534 assert(exprhdlr != NULL);
1535 assert(set != NULL);
1536 assert(expr != NULL);
1537 assert(expr->exprhdlr == exprhdlr);
1538 assert(interval != NULL);
1539
1540 if( exprhdlr->inteval != NULL )
1541 {
1542 SCIPclockStart(exprhdlr->intevaltime, set);
1543 SCIP_CALL( exprhdlr->inteval(set->scip, expr, interval, intevalvar, intevalvardata) );
1544 SCIPclockStop(exprhdlr->intevaltime, set);
1545
1546 ++exprhdlr->nintevalcalls;
1547 }
1548
1549 return SCIP_OKAY;
1550}
1551
1552/** calls the estimator callback of an expression handler
1553 *
1554 * @see SCIP_DECL_EXPRESTIMATE
1555 */
1557 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1558 SCIP_SET* set, /**< global SCIP settings */
1559 SCIP_EXPR* expr, /**< expression to be estimated */
1560 SCIP_INTERVAL* localbounds, /**< current bounds for children */
1561 SCIP_INTERVAL* globalbounds, /**< global bounds for children */
1562 SCIP_Real* refpoint, /**< children values for the reference point where to estimate */
1563 SCIP_Bool overestimate, /**< whether the expression needs to be over- or underestimated */
1564 SCIP_Real targetvalue, /**< a value that the estimator shall exceed, can be +/-infinity */
1565 SCIP_Real* coefs, /**< array to store coefficients of estimator */
1566 SCIP_Real* constant, /**< buffer to store constant part of estimator */
1567 SCIP_Bool* islocal, /**< buffer to store whether estimator is valid locally only */
1568 SCIP_Bool* success, /**< buffer to indicate whether an estimator could be computed */
1569 SCIP_Bool* branchcand /**< array to indicate which children (not) to consider for branching */
1570 )
1571{
1572 assert(exprhdlr != NULL);
1573 assert(set != NULL);
1574 assert(expr != NULL);
1575 assert(expr->exprhdlr == exprhdlr);
1576 assert(coefs != NULL);
1577 assert(islocal != NULL);
1578 assert(success != NULL);
1579
1580 *success = FALSE;
1581
1582 if( exprhdlr->estimate != NULL )
1583 {
1584 SCIPclockStart(exprhdlr->estimatetime, set);
1585 SCIP_CALL( exprhdlr->estimate(set->scip, expr, localbounds, globalbounds, refpoint, overestimate, targetvalue,
1586 coefs, constant, islocal, success, branchcand) );
1587 SCIPclockStop(exprhdlr->estimatetime, set);
1588
1589 /* update statistics */
1590 ++exprhdlr->nestimatecalls;
1591 }
1592
1593 return SCIP_OKAY;
1594}
1595
1596/** calls the intitial estimators callback of an expression handler
1597 *
1598 * @see SCIP_DECL_EXPRINITESTIMATES
1599 */
1601 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1602 SCIP_SET* set, /**< global SCIP settings */
1603 SCIP_EXPR* expr, /**< expression to be estimated */
1604 SCIP_INTERVAL* bounds, /**< bounds for children */
1605 SCIP_Bool overestimate, /**< whether the expression shall be overestimated or underestimated */
1606 SCIP_Real* coefs[SCIP_EXPR_MAXINITESTIMATES], /**< buffer to store coefficients of computed estimators */
1607 SCIP_Real constant[SCIP_EXPR_MAXINITESTIMATES], /**< buffer to store constant of computed estimators */
1608 int* nreturned /**< buffer to store number of estimators that have been computed */
1609 )
1610{
1611 assert(exprhdlr != NULL);
1612 assert(set != NULL);
1613 assert(expr != NULL);
1614 assert(expr->exprhdlr == exprhdlr);
1615 assert(nreturned != NULL);
1616
1617 *nreturned = 0;
1618
1619 if( exprhdlr->initestimates )
1620 {
1622 SCIP_CALL( exprhdlr->initestimates(set->scip, expr, bounds, overestimate, coefs, constant, nreturned) );
1624
1625 ++exprhdlr->nestimatecalls;
1626 }
1627
1628 return SCIP_OKAY;
1629}
1630
1631/** calls the simplification callback of an expression handler
1632 *
1633 * @see SCIP_DECL_EXPRSIMPLIFY
1634 */
1636 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1637 SCIP_SET* set, /**< global SCIP settings */
1638 SCIP_EXPR* expr, /**< expression to simplify */
1639 SCIP_EXPR** simplifiedexpr, /**< buffer to store the simplified expression */
1640 SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), /**< function to call on expression copy to create ownerdata */
1641 void* ownercreatedata /**< data to pass to ownercreate */
1642 )
1643{
1644 assert(exprhdlr != NULL);
1645 assert(set != NULL);
1646 assert(expr != NULL);
1647 assert(expr->exprhdlr == exprhdlr);
1648 assert(simplifiedexpr != NULL);
1649
1650 if( exprhdlr->simplify != NULL )
1651 {
1653 SCIP_CALL( exprhdlr->simplify(set->scip, expr, simplifiedexpr, ownercreate, ownercreatedata) );
1655
1656 /* update statistics */
1657 ++exprhdlr->nsimplifycalls;
1658 if( expr != *simplifiedexpr )
1659 ++exprhdlr->nsimplified;
1660 }
1661 else
1662 {
1663 *simplifiedexpr = expr;
1664
1665 /* if an expression handler doesn't implement simplify, we assume that it is already simplified
1666 * we have to capture it, since it must simulate a "normal" simplified call in which a new expression is created
1667 */
1668 SCIPexprCapture(expr);
1669 }
1670
1671 return SCIP_OKAY;
1672}
1673
1674/** calls the reverse propagation callback of an expression handler
1675 *
1676 * The method propagates given bounds over the children of an expression.
1677 *
1678 * @see SCIP_DECL_EXPRREVERSEPROP
1679 */
1681 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1682 SCIP_SET* set, /**< global SCIP settings */
1683 SCIP_EXPR* expr, /**< expression to propagate */
1684 SCIP_INTERVAL bounds, /**< the bounds on the expression that should be propagated */
1685 SCIP_INTERVAL* childrenbounds, /**< array to store computed bounds for children, initialized with current activity */
1686 SCIP_Bool* infeasible /**< buffer to store whether a children bounds were propagated to an empty interval */
1687 )
1688{
1689 assert(exprhdlr != NULL);
1690 assert(set != NULL);
1691 assert(expr != NULL);
1692 assert(expr->exprhdlr == exprhdlr);
1693 assert(childrenbounds != NULL || expr->nchildren == 0);
1694 assert(infeasible != NULL);
1695
1696 *infeasible = FALSE;
1697
1698 if( exprhdlr->reverseprop != NULL )
1699 {
1700 SCIPclockStart(exprhdlr->proptime, set);
1701 SCIP_CALL( exprhdlr->reverseprop(set->scip, expr, bounds, childrenbounds, infeasible) );
1702 SCIPclockStop(exprhdlr->proptime, set);
1703
1704 /* update statistics */
1705 if( *infeasible )
1706 ++expr->exprhdlr->ncutoffs;
1707 ++expr->exprhdlr->npropcalls;
1708 }
1709
1710 return SCIP_OKAY;
1711}
1712
1713/**@name Expression Methods */
1714/**@{ */
1715
1716/* from expr.h */
1717
1718#ifdef NDEBUG
1719#undef SCIPexprCapture
1720#undef SCIPexprIsVar
1721#undef SCIPexprIsValue
1722#undef SCIPexprIsSum
1723#undef SCIPexprIsProduct
1724#undef SCIPexprIsPower
1725#endif
1726
1727/** creates and captures an expression with given expression data and children */
1729 SCIP_SET* set, /**< global SCIP settings */
1730 BMS_BLKMEM* blkmem, /**< block memory */
1731 SCIP_EXPR** expr, /**< pointer where to store expression */
1732 SCIP_EXPRHDLR* exprhdlr, /**< expression handler */
1733 SCIP_EXPRDATA* exprdata, /**< expression data (expression assumes ownership) */
1734 int nchildren, /**< number of children */
1735 SCIP_EXPR** children, /**< children (can be NULL if nchildren is 0) */
1736 SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), /**< function to call to create ownerdata */
1737 void* ownercreatedata /**< data to pass to ownercreate */
1738 )
1739{
1740 int c;
1741
1742 assert(set != NULL);
1743 assert(blkmem != NULL);
1744 assert(expr != NULL);
1745 assert(exprhdlr != NULL);
1746 assert(children != NULL || nchildren == 0);
1747 assert(exprdata == NULL || exprhdlr->copydata != NULL); /* copydata must be available if there is expression data */
1748 assert(exprdata == NULL || exprhdlr->freedata != NULL); /* freedata must be available if there is expression data */
1749
1750 SCIP_ALLOC( BMSallocClearBlockMemory(blkmem, expr) );
1751
1752 (*expr)->exprhdlr = exprhdlr;
1753 (*expr)->exprdata = exprdata;
1754 (*expr)->activitytag = -1; /* to be less than initial domchgcount */
1755 (*expr)->curvature = SCIP_EXPRCURV_UNKNOWN;
1756
1757 /* initialize activity to entire interval */
1758 SCIPintervalSetEntire(SCIP_INTERVAL_INFINITY, &(*expr)->activity);
1759
1760 if( nchildren > 0 )
1761 {
1762 SCIP_ALLOC( BMSduplicateBlockMemoryArray(blkmem, &(*expr)->children, children, nchildren) );
1763 (*expr)->nchildren = nchildren;
1764 (*expr)->childrensize = nchildren;
1765
1766 for( c = 0; c < nchildren; ++c )
1767 SCIPexprCapture((*expr)->children[c]);
1768 }
1769
1770 SCIPexprCapture(*expr);
1771
1772 ++exprhdlr->ncreated;
1773
1774 /* initializes the ownerdata */
1775 if( ownercreate != NULL )
1776 {
1777 SCIP_CALL( ownercreate(set->scip, *expr, &(*expr)->ownerdata, &(*expr)->ownerfree, &(*expr)->ownerprint,
1778 &(*expr)->ownerevalactivity, ownercreatedata) );
1779 }
1780
1781 return SCIP_OKAY;
1782}
1783
1784/** appends child to the children list of expr */
1786 SCIP_SET* set, /**< global SCIP settings */
1787 BMS_BLKMEM* blkmem, /**< block memory */
1788 SCIP_EXPR* expr, /**< expression */
1789 SCIP_EXPR* child /**< expression to be appended */
1790 )
1791{
1792 assert(set != NULL);
1793 assert(blkmem != NULL);
1794 assert(child != NULL);
1795 assert(expr->nchildren <= expr->childrensize);
1796
1797 if( expr->nchildren == expr->childrensize )
1798 {
1800 SCIP_ALLOC( BMSreallocBlockMemoryArray(blkmem, &expr->children, expr->nchildren, expr->childrensize) );
1801 }
1802
1803 expr->children[expr->nchildren] = child;
1804 ++expr->nchildren;
1805
1806 /* capture child */
1807 SCIPexprCapture(child);
1808
1809 return SCIP_OKAY;
1810}
1811
1812/** overwrites/replaces a child of an expressions
1813 *
1814 * @note the old child is released and the newchild is captured, unless they are the same (=same pointer)
1815 */
1817 SCIP_SET* set, /**< global SCIP settings */
1818 SCIP_STAT* stat, /**< dynamic problem statistics */
1819 BMS_BLKMEM* blkmem, /**< block memory */
1820 SCIP_EXPR* expr, /**< expression where a child is going to be replaced */
1821 int childidx, /**< index of child being replaced */
1822 SCIP_EXPR* newchild /**< the new child */
1823 )
1824{
1825 assert(set != NULL);
1826 assert(blkmem != NULL);
1827 assert(expr != NULL);
1828 assert(newchild != NULL);
1829 assert(childidx >= 0);
1830 assert(childidx < expr->nchildren);
1831
1832 /* do nothing if child is not changing */
1833 if( newchild == expr->children[childidx] )
1834 return SCIP_OKAY;
1835
1836 /* capture new child (do this before releasing the old child in case there are equal */
1837 SCIPexprCapture(newchild);
1838
1839 SCIP_CALL( SCIPexprRelease(set, stat, blkmem, &(expr->children[childidx])) );
1840 expr->children[childidx] = newchild;
1841
1842 return SCIP_OKAY;
1843}
1844
1845/** remove all children of expr */
1847 SCIP_SET* set, /**< global SCIP settings */
1848 SCIP_STAT* stat, /**< dynamic problem statistics */
1849 BMS_BLKMEM* blkmem, /**< block memory */
1850 SCIP_EXPR* expr /**< expression */
1851 )
1852{
1853 int c;
1854
1855 assert(set != NULL);
1856 assert(blkmem != NULL);
1857 assert(expr != NULL);
1858
1859 for( c = 0; c < expr->nchildren; ++c )
1860 {
1861 assert(expr->children[c] != NULL);
1862 SCIP_CALL( SCIPexprRelease(set, stat, blkmem, &(expr->children[c])) );
1863 }
1864
1865 expr->nchildren = 0;
1866
1867 return SCIP_OKAY;
1868}
1869
1870/** copies an expression including subexpressions
1871 *
1872 * @note If copying fails due to an expression handler not being available in the targetscip, then *targetexpr will be set to NULL.
1873 *
1874 * For all or some expressions, a mapping to an existing expression can be specified via the mapexpr callback.
1875 * The mapped expression (including its children) will not be copied in this case and its ownerdata will not be touched.
1876 * If, however, the mapexpr callback returns NULL for the targetexpr, then the expr will be copied in the usual way.
1877 */
1879 SCIP_SET* set, /**< global SCIP settings */
1880 SCIP_STAT* stat, /**< dynamic problem statistics */
1881 BMS_BLKMEM* blkmem, /**< block memory */
1882 SCIP_SET* targetset, /**< global SCIP settings data structure where target expression will live */
1883 SCIP_STAT* targetstat, /**< dynamic problem statistics in target SCIP */
1884 BMS_BLKMEM* targetblkmem, /**< block memory in target SCIP */
1885 SCIP_EXPR* sourceexpr, /**< expression to be copied */
1886 SCIP_EXPR** targetexpr, /**< buffer to store pointer to copy of source expression */
1887 SCIP_DECL_EXPR_MAPEXPR((*mapexpr)), /**< expression mapping function, or NULL for creating new expressions */
1888 void* mapexprdata, /**< data of expression mapping function */
1889 SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), /**< function to call on expression copy to create ownerdata */
1890 void* ownercreatedata /**< data to pass to ownercreate */
1891 )
1892{
1893 SCIP_EXPRITER* it;
1894 SCIP_EXPRITER_USERDATA expriteruserdata;
1895 SCIP_EXPR* expr;
1896 SCIP* sourcescip = set->scip; /* SCIP data structure corresponding to source expression */
1897 SCIP* targetscip = targetset->scip; /* SCIP data structure where target expression will live */
1898
1899 assert(set != NULL);
1900 assert(stat != NULL);
1901 assert(blkmem != NULL);
1902 assert(targetset != NULL);
1903 assert(sourceexpr != NULL);
1904 assert(targetexpr != NULL);
1905 assert(sourcescip != NULL);
1906 assert(targetscip != NULL);
1907
1908 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
1909 SCIP_CALL( SCIPexpriterInit(it, sourceexpr, SCIP_EXPRITER_DFS, TRUE) ); /*TODO use FALSE, i.e., don't duplicate common subexpr? */
1911
1912 expr = sourceexpr;
1913 while( !SCIPexpriterIsEnd(it) )
1914 {
1915 switch( SCIPexpriterGetStageDFS(it) )
1916 {
1918 {
1919 /* create expr that will hold the copy */
1920 SCIP_EXPRHDLR* targetexprhdlr;
1921 SCIP_EXPRDATA* targetexprdata;
1922 SCIP_EXPR* exprcopy = NULL;
1923
1924 if( mapexpr != NULL )
1925 {
1926 SCIP_CALL( mapexpr(targetscip, &exprcopy, sourcescip, expr, ownercreate, ownercreatedata, mapexprdata) );
1927 if( exprcopy != NULL )
1928 {
1929 /* map callback gave us an expression to use for the copy */
1930 /* store targetexpr */
1931 expriteruserdata.ptrval = exprcopy;
1932 SCIPexpriterSetCurrentUserData(it, expriteruserdata);
1933
1934 /* skip subexpression (assume that exprcopy is a complete copy) and continue */
1935 expr = SCIPexpriterSkipDFS(it);
1936 continue;
1937 }
1938 }
1939
1940 /* get the exprhdlr of the target scip */
1941 if( targetscip != sourcescip )
1942 {
1943 targetexprhdlr = SCIPsetFindExprhdlr(targetset, expr->exprhdlr->name);
1944
1945 if( targetexprhdlr == NULL )
1946 {
1947 /* expression handler not in target scip (probably did not have a copy callback) -> abort */
1948 expriteruserdata.ptrval = NULL;
1949 SCIPexpriterSetCurrentUserData(it, expriteruserdata);
1950
1951 expr = SCIPexpriterSkipDFS(it);
1952 continue;
1953 }
1954 }
1955 else
1956 {
1957 targetexprhdlr = expr->exprhdlr;
1958 }
1959 assert(targetexprhdlr != NULL);
1960
1961 /* copy expression data */
1962 if( expr->exprdata != NULL )
1963 {
1964 assert(expr->exprhdlr->copydata != NULL);
1965 SCIP_CALL( expr->exprhdlr->copydata(targetscip, targetexprhdlr, &targetexprdata, sourcescip, expr) );
1966 }
1967 else
1968 {
1969 targetexprdata = NULL;
1970 }
1971
1972 /* create in targetexpr an expression of the same type as expr, but without children for now */
1973 SCIP_CALL( SCIPexprCreate(targetset, targetblkmem, &exprcopy, targetexprhdlr, targetexprdata, 0, NULL,
1974 ownercreate, ownercreatedata) );
1975
1976 /* store targetexpr */
1977 expriteruserdata.ptrval = exprcopy;
1978 SCIPexpriterSetCurrentUserData(it, expriteruserdata);
1979
1980 break;
1981 }
1982
1984 {
1985 /* just visited child so a copy of himself should be available; append it */
1986 SCIP_EXPR* exprcopy;
1987 SCIP_EXPR* childcopy;
1988
1990
1991 /* get copy of child */
1993 if( childcopy == NULL )
1994 {
1995 /* abort */
1996 /* release exprcopy (should free also the already copied children) */
1997 SCIP_CALL( SCIPexprRelease(targetset, targetstat, targetblkmem, (SCIP_EXPR**)&exprcopy) );
1998
1999 expriteruserdata.ptrval = NULL;
2000 SCIPexpriterSetCurrentUserData(it, expriteruserdata);
2001
2002 expr = SCIPexpriterSkipDFS(it);
2003 continue;
2004 }
2005
2006 /* append child to exprcopy */
2007 SCIP_CALL( SCIPexprAppendChild(targetset, targetblkmem, exprcopy, childcopy) );
2008
2009 /* release childcopy (still captured by exprcopy) */
2010 SCIP_CALL( SCIPexprRelease(targetset, targetstat, targetblkmem, &childcopy) );
2011
2012 break;
2013 }
2014
2015 default:
2016 /* we should never be called in this stage */
2017 SCIPABORT();
2018 break;
2019 }
2020
2021 expr = SCIPexpriterGetNext(it);
2022 }
2023
2024 /* the target expression should be stored in the userdata of the sourceexpr (can be NULL if aborted) */
2025 *targetexpr = (SCIP_EXPR*)SCIPexpriterGetExprUserData(it, sourceexpr).ptrval;
2026
2027 SCIPexpriterFree(&it);
2028
2029 return SCIP_OKAY;
2030}
2031
2032/** duplicates the given expression without its children */
2034 SCIP_SET* set, /**< global SCIP settings */
2035 BMS_BLKMEM* blkmem, /**< block memory */
2036 SCIP_EXPR* expr, /**< original expression */
2037 SCIP_EXPR** copyexpr, /**< buffer to store (shallow) duplicate of expr */
2038 SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), /**< function to call on expression copy to create ownerdata */
2039 void* ownercreatedata /**< data to pass to ownercreate */
2040 )
2041{
2042 SCIP_EXPRDATA* exprdatacopy = NULL;
2043
2044 assert(set != NULL);
2045 assert(blkmem != NULL);
2046 assert(expr != NULL);
2047 assert(copyexpr != NULL);
2048
2049 /* copy expression data */
2050 if( expr->exprdata != NULL )
2051 {
2052 assert(expr->exprhdlr->copydata != NULL);
2053 SCIP_CALL( expr->exprhdlr->copydata(set->scip, expr->exprhdlr, &exprdatacopy, set->scip, expr) );
2054 }
2055
2056 /* create expression with same handler and copied data, but without children */
2057 SCIP_CALL( SCIPexprCreate(set, blkmem, copyexpr, expr->exprhdlr, exprdatacopy, 0, NULL, ownercreate,
2058 ownercreatedata) );
2059
2060 return SCIP_OKAY;
2061}
2062
2063/** captures an expression (increments usage count) */
2065 SCIP_EXPR* expr /**< expression */
2066 )
2067{
2068 assert(expr != NULL);
2069
2070 ++expr->nuses;
2071}
2072
2073/** releases an expression (decrements usage count and possibly frees expression) */
2075 SCIP_SET* set, /**< global SCIP settings */
2076 SCIP_STAT* stat, /**< dynamic problem statistics */
2077 BMS_BLKMEM* blkmem, /**< block memory */
2078 SCIP_EXPR** rootexpr /**< pointer to expression */
2079 )
2080{
2081 SCIP_EXPRITER* it;
2082 SCIP_EXPR* expr;
2083
2084 assert(rootexpr != NULL);
2085 assert(*rootexpr != NULL);
2086 assert((*rootexpr)->nuses > 0);
2087
2088 if( (*rootexpr)->nuses > 1 )
2089 {
2090 --(*rootexpr)->nuses;
2091 *rootexpr = NULL;
2092
2093 return SCIP_OKAY;
2094 }
2095
2096 /* handle the root expr separately: free ownerdata, quaddata, and exprdata first */
2097
2098 /* call ownerfree callback, if given
2099 * we intentially call this also if ownerdata is NULL, so owner can be notified without storing data
2100 */
2101 if( (*rootexpr)->ownerfree != NULL )
2102 {
2103 SCIP_CALL( (*rootexpr)->ownerfree(set->scip, *rootexpr, &(*rootexpr)->ownerdata) );
2104 assert((*rootexpr)->ownerdata == NULL);
2105 }
2106
2107 /* free quadratic info */
2108 SCIPexprFreeQuadratic(blkmem, *rootexpr);
2109
2110 /* free expression data */
2111 if( (*rootexpr)->exprdata != NULL )
2112 {
2113 assert((*rootexpr)->exprhdlr->freedata != NULL);
2114 SCIP_CALL( (*rootexpr)->exprhdlr->freedata(set->scip, *rootexpr) );
2115 }
2116
2117 /* now release and free children, where no longer in use */
2118 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
2121 for( expr = SCIPexpriterGetCurrent(it); !SCIPexpriterIsEnd(it) ; )
2122 {
2123 /* expression should be used by its parent and maybe by the iterator (only the root!)
2124 * in VISITEDCHILD we assert that expression is only used by its parent
2125 */
2126 assert(expr != NULL);
2127 assert(0 <= expr->nuses && expr->nuses <= 2);
2128
2129 switch( SCIPexpriterGetStageDFS(it) )
2130 {
2132 {
2133 /* check whether a child needs to be visited (nuses == 1)
2134 * if not, then we still have to release it
2135 */
2136 SCIP_EXPR* child;
2137
2138 child = SCIPexpriterGetChildExprDFS(it);
2139 if( child->nuses > 1 )
2140 {
2141 /* child is not going to be freed: just release it */
2142 SCIP_CALL( SCIPexprRelease(set, stat, blkmem, &child) );
2143 expr = SCIPexpriterSkipDFS(it);
2144 continue;
2145 }
2146
2147 assert(child->nuses == 1);
2148
2149 /* free child's quaddata, ownerdata, and exprdata when entering child */
2150 if( child->ownerfree != NULL )
2151 {
2152 SCIP_CALL( child->ownerfree(set->scip, child, &child->ownerdata) );
2153 assert(child->ownerdata == NULL);
2154 }
2155
2156 /* free quadratic info */
2157 SCIPexprFreeQuadratic(blkmem, child);
2158
2159 /* free expression data */
2160 if( child->exprdata != NULL )
2161 {
2162 assert(child->exprhdlr->freedata != NULL);
2163 SCIP_CALL( child->exprhdlr->freedata(set->scip, child) );
2164 assert(child->exprdata == NULL);
2165 }
2166
2167 break;
2168 }
2169
2171 {
2172 /* free child after visiting it */
2173 SCIP_EXPR* child;
2174
2175 child = SCIPexpriterGetChildExprDFS(it);
2176 /* child should only be used by its parent */
2177 assert(child->nuses == 1);
2178
2179 /* child should have no data associated */
2180 assert(child->exprdata == NULL);
2181
2182 /* free child expression */
2183 SCIP_CALL( freeExpr(blkmem, &child) );
2185
2186 break;
2187 }
2188
2189 default:
2190 SCIPABORT(); /* we should never be called in this stage */
2191 break;
2192 }
2193
2194 expr = SCIPexpriterGetNext(it);
2195 }
2196
2197 SCIPexpriterFree(&it);
2198
2199 /* handle the root expr separately: free its children and itself here */
2200 SCIP_CALL( freeExpr(blkmem, rootexpr) );
2201
2202 return SCIP_OKAY;
2203}
2204
2205/** returns whether an expression is a variable expression */
2207 SCIP_SET* set, /**< global SCIP settings */
2208 SCIP_EXPR* expr /**< expression */
2209 )
2210{
2211 assert(set != NULL);
2212 assert(expr != NULL);
2213
2214 return expr->exprhdlr == set->exprhdlrvar;
2215}
2216
2217/** returns whether an expression is a value expression */
2219 SCIP_SET* set, /**< global SCIP settings */
2220 SCIP_EXPR* expr /**< expression */
2221 )
2222{
2223 assert(set != NULL);
2224 assert(expr != NULL);
2225
2226 return expr->exprhdlr == set->exprhdlrval;
2227}
2228
2229/** returns whether an expression is a sum expression */
2231 SCIP_SET* set, /**< global SCIP settings */
2232 SCIP_EXPR* expr /**< expression */
2233 )
2234{
2235 assert(set != NULL);
2236 assert(expr != NULL);
2237
2238 return expr->exprhdlr == set->exprhdlrsum;
2239}
2240
2241/** returns whether an expression is a product expression */
2243 SCIP_SET* set, /**< global SCIP settings */
2244 SCIP_EXPR* expr /**< expression */
2245 )
2246{
2247 assert(set != NULL);
2248 assert(expr != NULL);
2249
2250 return expr->exprhdlr == set->exprhdlrproduct;
2251}
2252
2253/** returns whether an expression is a power expression */
2255 SCIP_SET* set, /**< global SCIP settings */
2256 SCIP_EXPR* expr /**< expression */
2257 )
2258{
2259 assert(set != NULL);
2260 assert(expr != NULL);
2261
2262 return expr->exprhdlr == set->exprhdlrpow;
2263}
2264
2265/** print an expression as info-message */
2267 SCIP_SET* set, /**< global SCIP settings */
2268 SCIP_STAT* stat, /**< dynamic problem statistics */
2269 BMS_BLKMEM* blkmem, /**< block memory */
2270 SCIP_MESSAGEHDLR* messagehdlr, /**< message handler */
2271 FILE* file, /**< file to print to, or NULL for stdout */
2272 SCIP_EXPR* expr /**< expression to be printed */
2273 )
2274{
2275 SCIP_EXPRITER* it;
2276 SCIP_EXPRITER_STAGE stage;
2277 int currentchild;
2278 unsigned int parentprecedence;
2279
2280 assert(set != NULL);
2281 assert(blkmem != NULL);
2282 assert(expr != NULL);
2283
2284 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
2287
2288 while( !SCIPexpriterIsEnd(it) )
2289 {
2290 assert(expr->exprhdlr != NULL);
2291 stage = SCIPexpriterGetStageDFS(it);
2292
2294 currentchild = SCIPexpriterGetChildIdxDFS(it);
2295 else
2296 currentchild = -1;
2297
2298 if( SCIPexpriterGetParentDFS(it) != NULL )
2300 else
2301 parentprecedence = 0;
2302
2303 SCIP_CALL( SCIPexprhdlrPrintExpr(expr->exprhdlr, set, messagehdlr, expr, stage, currentchild,
2304 parentprecedence, file) );
2305
2306 expr = SCIPexpriterGetNext(it);
2307 }
2308
2309 SCIPexpriterFree(&it);
2310
2311 return SCIP_OKAY;
2312}
2313
2314/** initializes printing of expressions in dot format to a give FILE* pointer */
2316 SCIP_SET* set, /**< global SCIP settings */
2317 SCIP_STAT* stat, /**< dynamic problem statistics */
2318 BMS_BLKMEM* blkmem, /**< block memory */
2319 SCIP_EXPRPRINTDATA** printdata, /**< buffer to store dot printing data */
2320 FILE* file, /**< file to print to, or NULL for stdout */
2321 SCIP_EXPRPRINT_WHAT whattoprint /**< info on what to print for each expression */
2322 )
2323{
2324 assert(set != NULL);
2325 assert(stat != NULL);
2326 assert(blkmem != NULL);
2327 assert(printdata != NULL);
2328
2329 if( file == NULL )
2330 file = stdout;
2331
2332 SCIP_ALLOC( BMSallocBlockMemory(blkmem, printdata) );
2333
2334 (*printdata)->file = file;
2335 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &(*printdata)->iterator) );
2336 (*printdata)->closefile = FALSE;
2337 (*printdata)->whattoprint = whattoprint;
2338 SCIP_CALL( SCIPhashmapCreate(&(*printdata)->leaveexprs, blkmem, 100) );
2339
2340 fputs("strict digraph exprgraph {\n", file);
2341 fputs("node [fontcolor=white, style=filled, rankdir=LR]\n", file);
2342
2343 return SCIP_OKAY;
2344}
2345
2346/** initializes printing of expressions in dot format to a file with given filename */
2348 SCIP_SET* set, /**< global SCIP settings */
2349 SCIP_STAT* stat, /**< dynamic problem statistics */
2350 BMS_BLKMEM* blkmem, /**< block memory */
2351 SCIP_EXPRPRINTDATA** printdata, /**< buffer to store dot printing data */
2352 const char* filename, /**< name of file to print to */
2353 SCIP_EXPRPRINT_WHAT whattoprint /**< info on what to print for each expression */
2354 )
2355{
2356 FILE* f;
2357
2358 assert(set != NULL);
2359 assert(stat != NULL);
2360 assert(blkmem != NULL);
2361 assert(printdata != NULL);
2362 assert(filename != NULL);
2363
2364 f = fopen(filename, "w");
2365 if( f == NULL )
2366 {
2367 SCIPerrorMessage("could not open file <%s> for writing\n", filename); /* error code would be in errno */
2368 return SCIP_FILECREATEERROR;
2369 }
2370
2371 SCIP_CALL_FINALLY( SCIPexprPrintDotInit(set, stat, blkmem, printdata, f, whattoprint),
2372 fclose(f) );
2373 (*printdata)->closefile = TRUE;
2374
2375 return SCIP_OKAY;
2376} /*lint !e429*/
2377
2378/** main part of printing an expression in dot format */
2380 SCIP_SET* set, /**< global SCIP settings */
2381 SCIP_MESSAGEHDLR* messagehdlr, /**< message handler */
2382 SCIP_EXPRPRINTDATA* printdata, /**< data as initialized by \ref SCIPprintExprDotInit() */
2383 SCIP_EXPR* expr /**< expression to be printed */
2384 )
2385{
2386 SCIP_Real color;
2387 int c;
2388
2389 assert(set != NULL);
2390 assert(printdata != NULL);
2391 assert(expr != NULL);
2392 assert(expr->exprhdlr != NULL);
2393
2394 SCIP_CALL( SCIPexpriterInit(printdata->iterator, expr, SCIP_EXPRITER_DFS, FALSE) );
2395
2396 while( !SCIPexpriterIsEnd(printdata->iterator) )
2397 {
2398 /* print expression as dot node */
2399
2400 if( expr->nchildren == 0 )
2401 {
2402 SCIP_CALL( SCIPhashmapInsert(printdata->leaveexprs, (void*)expr, NULL) );
2403 }
2404
2405 /* make up some color from the expression type (it's name) */
2406 color = 0.0;
2407 for( c = 0; expr->exprhdlr->name[c] != '\0'; ++c )
2408 color += (tolower(expr->exprhdlr->name[c]) - 'a') / 26.0;
2409 color = SCIPsetFrac(set, color);
2410 fprintf(printdata->file, "n%p [fillcolor=\"%g,%g,%g\", label=\"", (void*)expr, color, color, color);
2411
2412 if( printdata->whattoprint & SCIP_EXPRPRINT_EXPRHDLR )
2413 {
2414 fprintf(printdata->file, "%s\\n", expr->exprhdlr->name);
2415 }
2416
2417 if( printdata->whattoprint & SCIP_EXPRPRINT_EXPRSTRING )
2418 {
2419 SCIP_CALL( SCIPexprhdlrPrintExpr(expr->exprhdlr, set, messagehdlr, expr, SCIP_EXPRITER_ENTEREXPR, -1, 0,
2420 printdata->file) );
2421 for( c = 0; c < expr->nchildren; ++c )
2422 {
2423 SCIP_CALL( SCIPexprhdlrPrintExpr(expr->exprhdlr, set, messagehdlr, expr, SCIP_EXPRITER_VISITINGCHILD,
2424 c, 0, printdata->file) );
2425 fprintf(printdata->file, "c%d", c);
2426 SCIP_CALL( SCIPexprhdlrPrintExpr(expr->exprhdlr, set, messagehdlr, expr, SCIP_EXPRITER_VISITEDCHILD,
2427 c, 0, printdata->file) );
2428 }
2429 SCIP_CALL( SCIPexprhdlrPrintExpr(expr->exprhdlr, set, messagehdlr, expr, SCIP_EXPRITER_LEAVEEXPR, -1, 0,
2430 printdata->file) );
2431
2432 fputs("\\n", printdata->file);
2433 }
2434
2435 if( printdata->whattoprint & SCIP_EXPRPRINT_NUSES )
2436 {
2437 /* print number of uses */
2438 fprintf(printdata->file, "%d uses\\n", expr->nuses);
2439 }
2440
2441 if( printdata->whattoprint & SCIP_EXPRPRINT_OWNER )
2442 {
2443 /* print ownerdata */
2444 if( expr->ownerprint != NULL )
2445 {
2446 SCIP_CALL( expr->ownerprint(set->scip, printdata->file, expr, expr->ownerdata) );
2447 }
2448 else if( expr->ownerdata != NULL )
2449 {
2450 fprintf(printdata->file, "owner=%p\\n", (void*)expr->ownerdata);
2451 }
2452 }
2453
2454 if( printdata->whattoprint & SCIP_EXPRPRINT_EVALVALUE )
2455 {
2456 /* print eval value */
2457 fprintf(printdata->file, "val=%g", expr->evalvalue);
2458
2459 if( (printdata->whattoprint & SCIP_EXPRPRINT_EVALTAG) == SCIP_EXPRPRINT_EVALTAG )
2460 {
2461 /* print also eval tag */
2462 fprintf(printdata->file, " (%" SCIP_LONGINT_FORMAT ")", expr->evaltag);
2463 }
2464 fputs("\\n", printdata->file);
2465 }
2466
2467 if( printdata->whattoprint & SCIP_EXPRPRINT_ACTIVITY )
2468 {
2469 /* print activity */
2470 fprintf(printdata->file, "[%g,%g]", expr->activity.inf, expr->activity.sup);
2471
2472 if( (printdata->whattoprint & SCIP_EXPRPRINT_ACTIVITYTAG) == SCIP_EXPRPRINT_ACTIVITYTAG )
2473 {
2474 /* print also activity eval tag */
2475 fprintf(printdata->file, " (%" SCIP_LONGINT_FORMAT ")", expr->activitytag);
2476 }
2477 fputs("\\n", printdata->file);
2478 }
2479
2480 fputs("\"]\n", printdata->file); /* end of label and end of node */
2481
2482 /* add edges from expr to its children */
2483 for( c = 0; c < expr->nchildren; ++c )
2484 fprintf(printdata->file, "n%p -> n%p [label=\"c%d\"]\n", (void*)expr, (void*)expr->children[c], c);
2485
2486 expr = SCIPexpriterGetNext(printdata->iterator);
2487 }
2488
2489 return SCIP_OKAY;
2490}
2491
2492/** finishes printing of expressions in dot format */
2494 SCIP_SET* set, /**< global SCIP settings */
2495 SCIP_STAT* stat, /**< dynamic problem statistics */
2496 BMS_BLKMEM* blkmem, /**< block memory */
2497 SCIP_EXPRPRINTDATA** printdata /**< buffer where dot printing data has been stored */
2498 )
2499{
2500 SCIP_EXPR* expr;
2501 SCIP_HASHMAPENTRY* entry;
2502 FILE* file;
2503 int i;
2504
2505 assert(set != NULL);
2506 assert(stat != NULL);
2507 assert(blkmem != NULL);
2508 assert(printdata != NULL);
2509 assert(*printdata != NULL);
2510
2511 file = (*printdata)->file;
2512 assert(file != NULL);
2513
2514 /* iterate through all entries of the map */
2515 fputs("{rank=same;", file);
2516 for( i = 0; i < SCIPhashmapGetNEntries((*printdata)->leaveexprs); ++i )
2517 {
2518 entry = SCIPhashmapGetEntry((*printdata)->leaveexprs, i);
2519
2520 if( entry != NULL )
2521 {
2522 expr = (SCIP_EXPR*) SCIPhashmapEntryGetOrigin(entry);
2523 assert(expr != NULL);
2524 assert(expr->nchildren == 0);
2525
2526 fprintf(file, " n%p", (void*)expr);
2527 }
2528 }
2529 fprintf(file, "}\n");
2530
2531 fprintf(file, "}\n");
2532
2533 SCIPhashmapFree(&(*printdata)->leaveexprs);
2534
2535 SCIPexpriterFree(&(*printdata)->iterator);
2536
2537 if( (*printdata)->closefile )
2538 fclose((*printdata)->file);
2539
2540 BMSfreeBlockMemory(blkmem, printdata);
2541
2542 return SCIP_OKAY;
2543}
2544
2545/** prints structure of an expression a la Maple's dismantle */
2547 SCIP_SET* set, /**< global SCIP settings */
2548 SCIP_STAT* stat, /**< dynamic problem statistics */
2549 BMS_BLKMEM* blkmem, /**< block memory */
2550 SCIP_MESSAGEHDLR* messagehdlr, /**< message handler */
2551 FILE* file, /**< file to print to, or NULL for stdout */
2552 SCIP_EXPR* expr /**< expression to dismantle */
2553 )
2554{
2555 SCIP_EXPRITER* it;
2556 int depth = -1;
2557
2558 assert(set != NULL);
2559 assert(stat != NULL);
2560 assert(blkmem != NULL);
2561 assert(messagehdlr != NULL);
2562 assert(expr != NULL);
2563
2564 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
2567
2568 for( ; !SCIPexpriterIsEnd(it); expr = SCIPexpriterGetNext(it) )
2569 {
2570 switch( SCIPexpriterGetStageDFS(it) )
2571 {
2573 {
2574 int nspaces;
2575
2576 ++depth;
2577 nspaces = 3 * depth;
2578
2579 /* use depth of expression to align output */
2580 SCIPmessageFPrintInfo(messagehdlr, file, "%*s[%s]: ", nspaces, "", expr->exprhdlr->name);
2581
2582 if( SCIPexprIsVar(set, expr) )
2583 {
2584 SCIP_VAR* var;
2585
2586 var = SCIPgetVarExprVar(expr);
2587 SCIPmessageFPrintInfo(messagehdlr, file, "%s in [%g, %g]", SCIPvarGetName(var), SCIPvarGetLbLocal(var),
2588 SCIPvarGetUbLocal(var));
2589 }
2590 else if( SCIPexprIsSum(set, expr) )
2591 SCIPmessageFPrintInfo(messagehdlr, file, "%g", SCIPgetConstantExprSum(expr));
2592 else if( SCIPexprIsProduct(set, expr) )
2593 SCIPmessageFPrintInfo(messagehdlr, file, "%g", SCIPgetCoefExprProduct(expr));
2594 else if( SCIPexprIsValue(set, expr) )
2595 SCIPmessageFPrintInfo(messagehdlr, file, "%g", SCIPgetValueExprValue(expr));
2596 else if( SCIPexprIsPower(set, expr) || strcmp(expr->exprhdlr->name, "signpower") == 0)
2597 SCIPmessageFPrintInfo(messagehdlr, file, "%g", SCIPgetExponentExprPow(expr));
2598
2599 SCIPmessageFPrintInfo(messagehdlr, file, "\n");
2600
2601 if( expr->ownerprint != NULL )
2602 {
2603 SCIPmessageFPrintInfo(messagehdlr, file, "%*s ", nspaces, "");
2604 SCIP_CALL( expr->ownerprint(set->scip, file, expr, expr->ownerdata) );
2605 }
2606
2607 break;
2608 }
2609
2611 {
2612 int nspaces = 3 * depth;
2613
2614 if( SCIPexprIsSum(set, expr) )
2615 {
2616 SCIPmessageFPrintInfo(messagehdlr, file, "%*s ", nspaces, "");
2617 SCIPmessageFPrintInfo(messagehdlr, file, "[coef]: %g\n", SCIPgetCoefsExprSum(expr)[SCIPexpriterGetChildIdxDFS(it)]);
2618 }
2619
2620 break;
2621 }
2622
2624 {
2625 --depth;
2626 break;
2627 }
2628
2629 default:
2630 /* shouldn't be here */
2631 SCIPABORT();
2632 break;
2633 }
2634 }
2635
2636 SCIPexpriterFree(&it);
2637
2638 return SCIP_OKAY;
2639}
2640
2641/** evaluate an expression in a point
2642 *
2643 * Iterates over expressions to also evaluate children, if necessary.
2644 * Value can be received via SCIPexprGetEvalValue().
2645 * If an evaluation error (division by zero, ...) occurs, this value will
2646 * be set to SCIP_INVALID.
2647 *
2648 * If a nonzero \p soltag is passed, then only (sub)expressions are
2649 * reevaluated that have a different solution tag. If a soltag of 0
2650 * is passed, then subexpressions are always reevaluated.
2651 * The tag is stored together with the value and can be received via
2652 * SCIPexprGetEvalTag().
2653 */
2655 SCIP_SET* set, /**< global SCIP settings */
2656 SCIP_STAT* stat, /**< dynamic problem statistics */
2657 BMS_BLKMEM* blkmem, /**< block memory */
2658 SCIP_EXPR* expr, /**< expression to be evaluated */
2659 SCIP_SOL* sol, /**< solution to be evaluated */
2660 SCIP_Longint soltag /**< tag that uniquely identifies the solution (with its values), or 0. */
2661 )
2662{
2663 SCIP_EXPRITER* it;
2664
2665 assert(set != NULL);
2666 assert(stat != NULL);
2667 assert(blkmem != NULL);
2668 assert(expr != NULL);
2669
2670 /* if value is up-to-date, then nothing to do */
2671 if( soltag != 0 && expr->evaltag == soltag )
2672 return SCIP_OKAY;
2673
2674 /* assume we'll get a domain error, so we don't have to get this expr back if we abort the iteration
2675 * if there is no domain error, then we will overwrite the evalvalue in the last leaveexpr stage
2676 */
2677 expr->evalvalue = SCIP_INVALID;
2678 expr->evaltag = soltag;
2679
2680 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
2683
2684 while( !SCIPexpriterIsEnd(it) )
2685 {
2686 switch( SCIPexpriterGetStageDFS(it) )
2687 {
2689 {
2690 SCIP_EXPR* child;
2691
2692 if( soltag == 0 )
2693 break;
2694
2695 /* check whether child has been evaluated for that solution already */
2696 child = SCIPexpriterGetChildExprDFS(it);
2697 if( soltag == child->evaltag )
2698 {
2699 if( child->evalvalue == SCIP_INVALID )
2700 goto TERMINATE;
2701
2702 /* skip this child
2703 * this already returns the next one, so continue with loop
2704 */
2705 expr = SCIPexpriterSkipDFS(it);
2706 continue;
2707 }
2708
2709 break;
2710 }
2711
2713 {
2714 SCIP_CALL( SCIPexprhdlrEvalExpr(expr->exprhdlr, set, NULL , expr, &expr->evalvalue, NULL, sol) );
2715 expr->evaltag = soltag;
2716
2717 if( expr->evalvalue == SCIP_INVALID )
2718 goto TERMINATE;
2719
2720 break;
2721 }
2722
2723 default :
2724 /* we should never be here */
2725 SCIPABORT();
2726 break;
2727 }
2728
2729 expr = SCIPexpriterGetNext(it);
2730 }
2731
2732TERMINATE:
2733 SCIPexpriterFree(&it);
2734
2735 return SCIP_OKAY;
2736}
2737
2738/** evaluates gradient of an expression for a given point
2739 *
2740 * Initiates an expression walk to also evaluate children, if necessary.
2741 * Value can be received via SCIPgetExprPartialDiffNonlinear().
2742 * If an error (division by zero, ...) occurs, this value will
2743 * be set to SCIP_INVALID.
2744 */
2746 SCIP_SET* set, /**< global SCIP settings */
2747 SCIP_STAT* stat, /**< dynamic problem statistics */
2748 BMS_BLKMEM* blkmem, /**< block memory */
2749 SCIP_EXPR* rootexpr, /**< expression to be evaluated */
2750 SCIP_SOL* sol, /**< solution to be evaluated (NULL for the current LP solution) */
2751 SCIP_Longint soltag /**< tag that uniquely identifies the solution (with its values), or 0. */
2752 )
2753{
2754 SCIP_EXPRITER* it;
2755 SCIP_EXPR* expr;
2756 SCIP_EXPR* child;
2757 SCIP_Real derivative;
2758 SCIP_Longint difftag;
2759
2760 assert(set != NULL);
2761 assert(stat != NULL);
2762 assert(blkmem != NULL);
2763 assert(rootexpr != NULL);
2764
2765 /* ensure expression is evaluated */
2766 SCIP_CALL( SCIPexprEval(set, stat, blkmem, rootexpr, sol, soltag) );
2767
2768 /* check if expression could not be evaluated */
2769 if( SCIPexprGetEvalValue(rootexpr) == SCIP_INVALID )
2770 {
2771 rootexpr->derivative = SCIP_INVALID;
2772 return SCIP_OKAY;
2773 }
2774
2775 if( SCIPexprIsValue(set, rootexpr) )
2776 {
2777 rootexpr->derivative = 0.0;
2778 return SCIP_OKAY;
2779 }
2780
2781 difftag = ++(stat->exprlastdifftag);
2782
2783 rootexpr->derivative = 1.0;
2784 rootexpr->difftag = difftag;
2785
2786 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
2789
2790 for( expr = SCIPexpriterGetCurrent(it); !SCIPexpriterIsEnd(it); expr = SCIPexpriterGetNext(it) )
2791 {
2792 assert(expr->evalvalue != SCIP_INVALID);
2793
2794 child = SCIPexpriterGetChildExprDFS(it);
2795 assert(child != NULL);
2796
2797 /* reset the value of the partial derivative w.r.t. a variable expression if we see it for the first time */
2798 if( child->difftag != difftag && SCIPexprIsVar(set, child) )
2799 child->derivative = 0.0;
2800
2801 /* update differentiation tag of the child */
2802 child->difftag = difftag;
2803
2804 /* call backward differentiation callback */
2805 if( SCIPexprIsValue(set, child) )
2806 {
2807 derivative = 0.0;
2808 }
2809 else
2810 {
2811 derivative = SCIP_INVALID;
2813 &derivative, NULL, 0.0) );
2814
2815 if( derivative == SCIP_INVALID )
2816 {
2817 rootexpr->derivative = SCIP_INVALID;
2818 break;
2819 }
2820 }
2821
2822 /* update partial derivative stored in the child expression
2823 * for a variable, we have to sum up the partial derivatives of the root w.r.t. this variable over all parents
2824 * for other intermediate expressions, we only store the partial derivative of the root w.r.t. this expression
2825 */
2826 if( !SCIPexprIsVar(set, child) )
2827 child->derivative = expr->derivative * derivative;
2828 else
2829 child->derivative += expr->derivative * derivative;
2830 }
2831
2832 SCIPexpriterFree(&it);
2833
2834 return SCIP_OKAY;
2835}
2836
2837/** evaluates Hessian-vector product of an expression for a given point and direction
2838 *
2839 * Evaluates children, if necessary.
2840 * Value can be received via SCIPgetExprPartialDiffGradientDirNonlinear()
2841 * If an error (division by zero, ...) occurs, this value will
2842 * be set to SCIP_INVALID.
2843 */
2845 SCIP_SET* set, /**< global SCIP settings */
2846 SCIP_STAT* stat, /**< dynamic problem statistics */
2847 BMS_BLKMEM* blkmem, /**< block memory */
2848 SCIP_EXPR* rootexpr, /**< expression to be evaluated */
2849 SCIP_SOL* sol, /**< solution to be evaluated (NULL for the current LP solution) */
2850 SCIP_Longint soltag, /**< tag that uniquely identifies the solution (with its values), or 0. */
2851 SCIP_SOL* direction /**< direction */
2852 )
2853{
2854 SCIP_EXPRITER* it;
2855 SCIP_EXPR* expr;
2856 SCIP_EXPR* child;
2857 SCIP_Real derivative;
2858 SCIP_Real hessiandir;
2859
2860 assert(set != NULL);
2861 assert(stat != NULL);
2862 assert(blkmem != NULL);
2863 assert(rootexpr != NULL);
2864
2865 if( SCIPexprIsValue(set, rootexpr) )
2866 {
2867 rootexpr->dot = 0.0;
2868 rootexpr->bardot = 0.0;
2869 return SCIP_OKAY;
2870 }
2871
2872 /* evaluate expression and directional derivative */
2873 SCIP_CALL( evalAndDiff(set, stat, blkmem, rootexpr, sol, soltag, direction) );
2874
2875 if( rootexpr->evalvalue == SCIP_INVALID )
2876 {
2877 rootexpr->derivative = SCIP_INVALID;
2878 rootexpr->bardot = SCIP_INVALID;
2879 return SCIP_OKAY;
2880 }
2881
2882 rootexpr->derivative = 1.0;
2883
2884 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
2887
2888 /* compute reverse diff and bardots: i.e. hessian times direction */
2889 for( expr = SCIPexpriterGetCurrent(it); !SCIPexpriterIsEnd(it); expr = SCIPexpriterGetNext(it) )
2890 {
2891 assert(expr->evalvalue != SCIP_INVALID);
2892
2893 child = SCIPexpriterGetChildExprDFS(it);
2894 assert(child != NULL);
2895
2896 /* call backward and forward-backward differentiation callback */
2897 if( SCIPexprIsValue(set, child) )
2898 {
2899 derivative = 0.0;
2900 hessiandir = 0.0;
2901 }
2902 else
2903 {
2904 derivative = SCIP_INVALID;
2905 hessiandir = SCIP_INVALID;
2907 &derivative, NULL, SCIP_INVALID) );
2909 &hessiandir, NULL) );
2910
2911 if( derivative == SCIP_INVALID || hessiandir == SCIP_INVALID )
2912 {
2913 rootexpr->derivative = SCIP_INVALID;
2914 rootexpr->bardot = SCIP_INVALID;
2915 break;
2916 }
2917 }
2918
2919 /* update partial derivative and hessian stored in the child expression
2920 * for a variable, we have to sum up the partial derivatives of the root w.r.t. this variable over all parents
2921 * for other intermediate expressions, we only store the partial derivative of the root w.r.t. this expression
2922 */
2923 if( !SCIPexprIsVar(set, child) )
2924 {
2925 child->derivative = expr->derivative * derivative;
2926 child->bardot = expr->bardot * derivative + expr->derivative * hessiandir;
2927 }
2928 else
2929 {
2930 child->derivative += expr->derivative * derivative;
2931 child->bardot += expr->bardot * derivative + expr->derivative * hessiandir;
2932 }
2933 }
2934
2935 SCIPexpriterFree(&it);
2936
2937 return SCIP_OKAY;
2938}
2939
2940/** possibly reevaluates and then returns the activity of the expression
2941 *
2942 * Reevaluate activity if currently stored is no longer uptodate.
2943 * If the expr owner provided a evalactivity-callback, then call this.
2944 * Otherwise, loop over descendants and compare activitytag with stat's domchgcount, i.e.,
2945 * whether some bound was changed since last evaluation, to check whether exprhdlrs INTEVAL should be called.
2946 *
2947 * @note If expression is set to be integral, then activities are tightened to integral values.
2948 * Thus, ensure that the integrality information is valid (if set to TRUE; the default (FALSE) is always ok).
2949 */
2951 SCIP_SET* set, /**< global SCIP settings */
2952 SCIP_STAT* stat, /**< dynamic problem statistics */
2953 BMS_BLKMEM* blkmem, /**< block memory */
2954 SCIP_EXPR* rootexpr /**< expression */
2955 )
2956{
2957 SCIP_EXPRITER* it;
2958 SCIP_EXPR* expr;
2959
2960 assert(set != NULL);
2961 assert(stat != NULL);
2962 assert(blkmem != NULL);
2963 assert(rootexpr != NULL);
2964
2965 if( rootexpr->ownerevalactivity != NULL )
2966 {
2967 /* call owner callback for activity-eval */
2968 SCIP_CALL( rootexpr->ownerevalactivity(set->scip, rootexpr, rootexpr->ownerdata) );
2969
2970 return SCIP_OKAY;
2971 }
2972
2973 /* fallback if no callback is given */
2974
2975 assert(rootexpr->activitytag <= stat->domchgcount);
2976
2977 /* if value is up-to-date, then nothing to do */
2978 if( rootexpr->activitytag == stat->domchgcount )
2979 {
2980#ifdef DEBUG_PROP
2981 SCIPsetDebugMsg(set, "activitytag of root expr equals domchgcount (%u), skip evalactivity\n", stat->domchgcount);
2982#endif
2983
2984 return SCIP_OKAY;
2985 }
2986
2987 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
2990
2991 for( expr = SCIPexpriterGetCurrent(it); !SCIPexpriterIsEnd(it); )
2992 {
2993 switch( SCIPexpriterGetStageDFS(it) )
2994 {
2996 {
2997 /* skip child if it has been evaluated already */
2998 SCIP_EXPR* child;
2999
3000 child = SCIPexpriterGetChildExprDFS(it);
3001 if( child->activitytag == stat->domchgcount )
3002 {
3003 expr = SCIPexpriterSkipDFS(it);
3004 continue;
3005 }
3006
3007 break;
3008 }
3009
3011 {
3012 /* we should not have entered this expression if its activity was already uptodate */
3013 assert(expr->activitytag < stat->domchgcount);
3014
3015 /* reset activity to entire if invalid, so we can use it as starting point below */
3017
3018#ifdef DEBUG_PROP
3019 SCIPsetDebugMsg(set, "interval evaluation of expr %p ", (void*)expr);
3020 SCIP_CALL( SCIPprintExpr(set->scip, expr, NULL) );
3022#endif
3023
3024 /* call the inteval callback of the exprhdlr */
3025 SCIP_CALL( SCIPexprhdlrIntEvalExpr(expr->exprhdlr, set, expr, &expr->activity, NULL, NULL) );
3026#ifdef DEBUG_PROP
3027 SCIPsetDebugMsg(set, " exprhdlr <%s>::inteval = [%.20g, %.20g]", expr->exprhdlr->name, expr->activity.inf,
3028 expr->activity.sup);
3029#endif
3030
3031 /* if expression is integral, then we try to tighten the interval bounds a bit
3032 * this should undo the addition of some unnecessary safety added by use of nextafter() in interval
3033 * arithmetics, e.g., when doing pow() it would be ok to use ceil() and floor(), but for safety we
3034 * use SCIPceil and SCIPfloor for now the default intevalVar does not relax variables, so can omit
3035 * expressions without children (constants should be ok, too)
3036 */
3037 if( expr->isintegral && expr->nchildren > 0 )
3038 {
3039 if( expr->activity.inf > -SCIP_INTERVAL_INFINITY )
3040 expr->activity.inf = SCIPsetCeil(set, expr->activity.inf);
3041 if( expr->activity.sup < SCIP_INTERVAL_INFINITY )
3042 expr->activity.sup = SCIPsetFloor(set, expr->activity.sup);
3043#ifdef DEBUG_PROP
3044 SCIPsetDebugMsg(set, " applying integrality: [%.20g, %.20g]\n", expr->activity.inf, expr->activity.sup);
3045#endif
3046 }
3047
3048 /* mark activity as empty if either the lower/upper bound is above/below +/- SCIPinfinity()
3049 * TODO this is a problem if dual-presolve fixed a variable to +/- infinity
3050 */
3051 if( SCIPsetIsInfinity(set, expr->activity.inf) || SCIPsetIsInfinity(set, -expr->activity.sup) )
3052 {
3053 SCIPsetDebugMsg(set, "treat activity [%g,%g] as empty as beyond infinity\n", expr->activity.inf, expr->activity.sup);
3054 SCIPintervalSetEmpty(&expr->activity);
3055 }
3056
3057 /* remember that activity is uptodate now */
3058 expr->activitytag = stat->domchgcount;
3059
3060 break;
3061 }
3062
3063 default:
3064 /* you should never be here */
3065 SCIPABORT();
3066 break;
3067 }
3068
3069 expr = SCIPexpriterGetNext(it);
3070 }
3071
3072 SCIPexpriterFree(&it);
3073
3074 return SCIP_OKAY;
3075}
3076
3077/** compare expressions
3078 *
3079 * @return -1, 0 or 1 if expr1 <, =, > expr2, respectively
3080 * @note The given expressions are assumed to be simplified.
3081 */
3083 SCIP_SET* set, /**< global SCIP settings */
3084 SCIP_EXPR* expr1, /**< first expression */
3085 SCIP_EXPR* expr2 /**< second expression */
3086 )
3087{
3088 SCIP_EXPRHDLR* exprhdlr1;
3089 SCIP_EXPRHDLR* exprhdlr2;
3090 int retval;
3091
3092 exprhdlr1 = expr1->exprhdlr;
3093 exprhdlr2 = expr2->exprhdlr;
3094
3095 /* expressions are of the same kind/type; use compare callback or default method */
3096 if( exprhdlr1 == exprhdlr2 )
3097 return SCIPexprhdlrCompareExpr(set, expr1, expr2);
3098
3099 /* expressions are of different kind/type */
3100 /* enforces OR6 */
3101 if( SCIPexprIsValue(set, expr1) )
3102 {
3103 return -1;
3104 }
3105 /* enforces OR12 */
3106 if( SCIPexprIsValue(set, expr2) )
3107 return -SCIPexprCompare(set, expr2, expr1);
3108
3109 /* enforces OR7 */
3110 if( SCIPexprIsSum(set, expr1) )
3111 {
3112 int compareresult;
3113 int nchildren;
3114
3115 nchildren = expr1->nchildren;
3116 compareresult = SCIPexprCompare(set, expr1->children[nchildren-1], expr2);
3117
3118 if( compareresult != 0 )
3119 return compareresult;
3120
3121 /* "base" of the largest expression of the sum is equal to expr2, coefficient might tell us that
3122 * expr2 is larger */
3123 if( SCIPgetCoefsExprSum(expr1)[nchildren-1] < 1.0 )
3124 return -1;
3125
3126 /* largest expression of sum is larger or equal than expr2 => expr1 > expr2 */
3127 return 1;
3128 }
3129 /* enforces OR12 */
3130 if( SCIPexprIsSum(set, expr2) )
3131 return -SCIPexprCompare(set, expr2, expr1);
3132
3133 /* enforces OR8 */
3134 if( SCIPexprIsProduct(set, expr1) )
3135 {
3136 int compareresult;
3137 int nchildren;
3138
3139 nchildren = expr1->nchildren;
3140 compareresult = SCIPexprCompare(set, expr1->children[nchildren-1], expr2);
3141
3142 if( compareresult != 0 )
3143 return compareresult;
3144
3145 /* largest expression of product is larger or equal than expr2 => expr1 > expr2 */
3146 return 1;
3147 }
3148 /* enforces OR12 */
3149 if( SCIPexprIsProduct(set, expr2) )
3150 return -SCIPexprCompare(set, expr2, expr1);
3151
3152 /* enforces OR9 */
3153 if( SCIPexprIsPower(set, expr1) )
3154 {
3155 int compareresult;
3156
3157 compareresult = SCIPexprCompare(set, expr1->children[0], expr2);
3158
3159 if( compareresult != 0 )
3160 return compareresult;
3161
3162 /* base equal to expr2, exponent might tell us that expr2 is larger */
3163 if( SCIPgetExponentExprPow(expr1) < 1.0 )
3164 return -1;
3165
3166 /* power expression is larger => expr1 > expr2 */
3167 return 1;
3168 }
3169 /* enforces OR12 */
3170 if( SCIPexprIsPower(set, expr2) )
3171 return -SCIPexprCompare(set, expr2, expr1);
3172
3173 /* enforces OR10 */
3174 if( SCIPexprIsVar(set, expr1) )
3175 return -1;
3176 /* enforces OR12 */
3177 if( SCIPexprIsVar(set, expr2) )
3178 return -SCIPexprCompare(set, expr2, expr1);
3179
3180 /* enforces OR11 */
3181 retval = strcmp(SCIPexprhdlrGetName(exprhdlr1), SCIPexprhdlrGetName(exprhdlr2));
3182 return retval == 0 ? 0 : retval < 0 ? -1 : 1;
3183}
3184
3185/** simplifies an expression
3186 *
3187 * @see SCIPsimplifyExpr
3188 */
3190 SCIP_SET* set, /**< global SCIP settings */
3191 SCIP_STAT* stat, /**< dynamic problem statistics */
3192 BMS_BLKMEM* blkmem, /**< block memory */
3193 SCIP_EXPR* rootexpr, /**< expression to be simplified */
3194 SCIP_EXPR** simplified, /**< buffer to store simplified expression */
3195 SCIP_Bool* changed, /**< buffer to store if rootexpr actually changed */
3196 SCIP_Bool* infeasible, /**< buffer to store whether infeasibility has been detected */
3197 SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), /**< function to call to create ownerdata */
3198 void* ownercreatedata /**< data to pass to ownercreate */
3199 )
3200{
3201 SCIP_EXPR* expr;
3202 SCIP_EXPRITER* it;
3203
3204 assert(rootexpr != NULL);
3205 assert(simplified != NULL);
3206 assert(changed != NULL);
3207 assert(infeasible != NULL);
3208
3209 /* simplify bottom up
3210 * when leaving an expression it simplifies it and stores the simplified expr in its iterators expression data
3211 * after the child was visited, it is replaced with the simplified expr
3212 */
3213 SCIP_CALL( SCIPexpriterCreate(stat, blkmem, &it) );
3214 SCIP_CALL( SCIPexpriterInit(it, rootexpr, SCIP_EXPRITER_DFS, TRUE) ); /* TODO can we set allowrevisited to FALSE?*/
3216
3217 *changed = FALSE;
3218 *infeasible = FALSE;
3219 for( expr = SCIPexpriterGetCurrent(it); !SCIPexpriterIsEnd(it); expr = SCIPexpriterGetNext(it) )
3220 {
3221 switch( SCIPexpriterGetStageDFS(it) )
3222 {
3224 {
3225 SCIP_EXPR* newchild;
3226 SCIP_EXPR* child;
3227
3229 child = SCIPexpriterGetChildExprDFS(it);
3230 assert(newchild != NULL);
3231
3232 /* if child got simplified, replace it with the new child */
3233 if( newchild != child )
3234 {
3235 SCIP_CALL( SCIPexprReplaceChild(set, stat, blkmem, expr, SCIPexpriterGetChildIdxDFS(it), newchild) );
3236 }
3237
3238 /* we do not need to hold newchild anymore */
3239 SCIP_CALL( SCIPexprRelease(set, stat, blkmem, &newchild) );
3240
3241 break;
3242 }
3243
3245 {
3246 SCIP_EXPR* refexpr = NULL;
3247 SCIP_EXPRITER_USERDATA iterdata;
3248
3249 /* TODO we should do constant folding (handle that all children are value-expressions) here in a generic way
3250 * instead of reimplementing it in every handler
3251 */
3252
3253 /* use simplification of expression handlers */
3254 SCIP_CALL( SCIPexprhdlrSimplifyExpr(expr->exprhdlr, set, expr, &refexpr, ownercreate, ownercreatedata) );
3255 assert(refexpr != NULL);
3256 if( expr != refexpr )
3257 *changed = TRUE;
3258
3259 iterdata.ptrval = (void*) refexpr;
3260 SCIPexpriterSetCurrentUserData(it, iterdata);
3261
3262 break;
3263 }
3264
3265 default:
3266 SCIPABORT(); /* we should never be called in this stage */
3267 break;
3268 }
3269 }
3270
3271 *simplified = (SCIP_EXPR*)SCIPexpriterGetExprUserData(it, rootexpr).ptrval;
3272 assert(*simplified != NULL);
3273
3274 SCIPexpriterFree(&it);
3275
3276 return SCIP_OKAY;
3277}
3278
3279/** method to retrieve symmetry information from an expression
3280 *
3281 * @see SCIPgetSymDataExpr
3282 */
3284 SCIP_SET* set, /**< global SCIP settings */
3285 SCIP_EXPR* expr, /**< expression from which information is retrieved */
3286 SYM_EXPRDATA** symdata /**< buffer to store symmetry information */
3287 )
3288{
3289 SCIP_EXPRHDLR* exprhdlr;
3290
3291 assert(set != NULL);
3292 assert(expr != NULL);
3293 assert(symdata != NULL);
3294
3295 exprhdlr = SCIPexprGetHdlr(expr);
3296 assert(exprhdlr != NULL);
3297
3298 if( exprhdlr->getsymdata != NULL )
3299 {
3300 SCIP_CALL( exprhdlr->getsymdata(set->scip, expr, symdata) );
3301 }
3302 else
3303 *symdata = NULL;
3304
3305 return SCIP_OKAY;
3306}
3307
3308/** checks whether an expression is quadratic
3309 *
3310 * An expression is quadratic if it is either a power expression with exponent 2.0, a product of two expressions,
3311 * or a sum of terms where at least one is a square or a product of two.
3312 *
3313 * Use \ref SCIPexprGetQuadraticData to get data about the representation as quadratic.
3314 */
3316 SCIP_SET* set, /**< global SCIP settings */
3317 BMS_BLKMEM* blkmem, /**< block memory */
3318 SCIP_EXPR* expr, /**< expression */
3319 SCIP_Bool* isquadratic /**< buffer to store result */
3320 )
3321{
3322 SCIP_HASHMAP* expr2idx;
3323 SCIP_HASHMAP* seenexpr = NULL;
3324 int nquadterms = 0;
3325 int nlinterms = 0;
3326 int nbilinterms = 0;
3327 int c;
3328
3329 assert(set != NULL);
3330 assert(blkmem != NULL);
3331 assert(expr != NULL);
3332 assert(isquadratic != NULL);
3333
3334 if( expr->quadchecked )
3335 {
3336 *isquadratic = expr->quaddata != NULL;
3337 return SCIP_OKAY;
3338 }
3339 assert(expr->quaddata == NULL);
3340
3341 expr->quadchecked = TRUE;
3342 *isquadratic = FALSE;
3343
3344 /* check if expression is a quadratic expression */
3345 SCIPsetDebugMsg(set, "checking if expr %p is quadratic\n", (void*)expr);
3346
3347 /* handle single square term */
3348 if( SCIPexprIsPower(set, expr) && SCIPgetExponentExprPow(expr) == 2.0 )
3349 {
3350 SCIPsetDebugMsg(set, "expr %p looks like square: fill data structures\n", (void*)expr);
3351 SCIP_ALLOC( BMSallocClearBlockMemory(blkmem, &expr->quaddata) );
3352
3353 expr->quaddata->nquadexprs = 1;
3354 SCIP_ALLOC( BMSallocClearBlockMemoryArray(blkmem, &expr->quaddata->quadexprterms, 1) );
3355 expr->quaddata->quadexprterms[0].expr = expr->children[0];
3356 expr->quaddata->quadexprterms[0].sqrcoef = 1.0;
3357
3358 expr->quaddata->allexprsarevars = SCIPexprIsVar(set, expr->quaddata->quadexprterms[0].expr);
3359
3360 *isquadratic = TRUE;
3361 return SCIP_OKAY;
3362 }
3363
3364 /* handle single bilinear term */
3365 if( SCIPexprIsProduct(set, expr) && SCIPexprGetNChildren(expr) == 2 )
3366 {
3367 SCIPsetDebugMsg(set, "expr %p looks like bilinear product: fill data structures\n", (void*)expr);
3368 SCIP_ALLOC( BMSallocClearBlockMemory(blkmem, &expr->quaddata) );
3369 expr->quaddata->nquadexprs = 2;
3370
3371 SCIP_ALLOC( BMSallocClearBlockMemoryArray(blkmem, &expr->quaddata->quadexprterms, 2) );
3372 expr->quaddata->quadexprterms[0].expr = SCIPexprGetChildren(expr)[0];
3373 expr->quaddata->quadexprterms[0].nadjbilin = 1;
3374 SCIP_ALLOC( BMSallocBlockMemoryArray(blkmem, &expr->quaddata->quadexprterms[0].adjbilin, 1) );
3375 expr->quaddata->quadexprterms[0].adjbilin[0] = 0;
3376
3377 expr->quaddata->quadexprterms[1].expr = SCIPexprGetChildren(expr)[1];
3378 expr->quaddata->quadexprterms[1].nadjbilin = 1;
3379 SCIP_ALLOC( BMSallocBlockMemoryArray(blkmem, &expr->quaddata->quadexprterms[1].adjbilin, 1) );
3380 expr->quaddata->quadexprterms[1].adjbilin[0] = 0;
3381
3382 expr->quaddata->nbilinexprterms = 1;
3383 SCIP_ALLOC( BMSallocClearBlockMemoryArray(blkmem, &expr->quaddata->bilinexprterms, 1) );
3384 expr->quaddata->bilinexprterms[0].expr1 = SCIPexprGetChildren(expr)[1];
3385 expr->quaddata->bilinexprterms[0].expr2 = SCIPexprGetChildren(expr)[0];
3386 expr->quaddata->bilinexprterms[0].coef = 1.0;
3387
3388 expr->quaddata->allexprsarevars = SCIPexprIsVar(set, expr->quaddata->quadexprterms[0].expr)
3389 && SCIPexprIsVar(set, expr->quaddata->quadexprterms[1].expr);
3390
3391 *isquadratic = TRUE;
3392 return SCIP_OKAY;
3393 }
3394
3395 /* neither a sum, nor a square, nor a bilinear term */
3396 if( !SCIPexprIsSum(set, expr) )
3397 return SCIP_OKAY;
3398
3399 SCIP_CALL( SCIPhashmapCreate(&seenexpr, blkmem, 2*SCIPexprGetNChildren(expr)) );
3400 for( c = 0; c < SCIPexprGetNChildren(expr); ++c )
3401 {
3402 SCIP_EXPR* child;
3403 SCIP_Real coef;
3404
3405 child = SCIPexprGetChildren(expr)[c];
3406 assert(child != NULL);
3407
3408 coef = SCIPgetCoefsExprSum(expr)[c];
3409 if( coef == 0.0 )
3410 continue;
3411
3412 if( SCIPexprIsPower(set, child) && SCIPgetExponentExprPow(child) == 2.0 ) /* quadratic term */
3413 {
3414 SCIP_CALL( quadDetectProcessExpr(SCIPexprGetChildren(child)[0], seenexpr, &nquadterms, &nlinterms) );
3415 }
3416 else if( SCIPexprIsProduct(set, child) && SCIPexprGetNChildren(child) == 2 ) /* bilinear term */
3417 {
3418 ++nbilinterms;
3419 SCIP_CALL( quadDetectProcessExpr(SCIPexprGetChildren(child)[0], seenexpr, &nquadterms, &nlinterms) );
3420 SCIP_CALL( quadDetectProcessExpr(SCIPexprGetChildren(child)[1], seenexpr, &nquadterms, &nlinterms) );
3421 }
3422 else
3423 {
3424 /* first time seen linearly --> assign -1; ++nlinterms
3425 * not first time --> assign +=1;
3426 */
3427 if( SCIPhashmapExists(seenexpr, (void*)child) )
3428 {
3429 assert(SCIPhashmapGetImageInt(seenexpr, (void*)child) > 0);
3430
3431 SCIP_CALL( SCIPhashmapSetImageInt(seenexpr, (void*)child, SCIPhashmapGetImageInt(seenexpr, (void*)child) + 1) );
3432 }
3433 else
3434 {
3435 ++nlinterms;
3436 SCIP_CALL( SCIPhashmapInsertInt(seenexpr, (void*)child, -1) );
3437 }
3438 }
3439 }
3440
3441 if( nquadterms == 0 )
3442 {
3443 /* only linear sum */
3444 SCIPhashmapFree(&seenexpr);
3445 return SCIP_OKAY;
3446 }
3447
3448 SCIPsetDebugMsg(set, "expr %p looks quadratic: fill data structures\n", (void*)expr);
3449
3450 /* expr2idx maps expressions to indices; if index > 0, it is its index in the linexprs array, otherwise -index-1 is
3451 * its index in the quadexprterms array
3452 */
3453 SCIP_CALL( SCIPhashmapCreate(&expr2idx, blkmem, nquadterms + nlinterms) );
3454
3455 /* allocate memory, etc */
3456 SCIP_ALLOC( BMSallocClearBlockMemory(blkmem, &expr->quaddata) );
3457 SCIP_ALLOC( BMSallocBlockMemoryArray(blkmem, &expr->quaddata->quadexprterms, nquadterms) );
3458 SCIP_ALLOC( BMSallocBlockMemoryArray(blkmem, &expr->quaddata->linexprs, nlinterms) );
3459 SCIP_ALLOC( BMSallocBlockMemoryArray(blkmem, &expr->quaddata->lincoefs, nlinterms) );
3460 SCIP_ALLOC( BMSallocBlockMemoryArray(blkmem, &expr->quaddata->bilinexprterms, nbilinterms) );
3461
3463
3464 expr->quaddata->allexprsarevars = TRUE;
3465 /* for every term of the sum-expr */
3466 for( c = 0; c < SCIPexprGetNChildren(expr); ++c )
3467 {
3468 SCIP_EXPR* child;
3469 SCIP_Real coef;
3470
3471 child = SCIPexprGetChildren(expr)[c];
3472 assert(child != NULL);
3473
3474 coef = SCIPgetCoefsExprSum(expr)[c];
3475 if( coef == 0.0 )
3476 continue;
3477
3478 if( SCIPexprIsPower(set, child) && SCIPgetExponentExprPow(child) == 2.0 ) /* quadratic term */
3479 {
3480 SCIP_QUADEXPR_QUADTERM* quadexprterm;
3481 assert(SCIPexprGetNChildren(child) == 1);
3482
3483 child = SCIPexprGetChildren(child)[0];
3484 assert(SCIPhashmapGetImageInt(seenexpr, (void *)child) > 0);
3485
3486 SCIP_CALL( quadDetectGetQuadexprterm(blkmem, child, expr2idx, seenexpr, expr->quaddata, &quadexprterm) );
3487 assert(quadexprterm->expr == child);
3488 quadexprterm->sqrcoef = coef;
3489 quadexprterm->sqrexpr = SCIPexprGetChildren(expr)[c];
3490
3491 if( expr->quaddata->allexprsarevars )
3492 expr->quaddata->allexprsarevars = SCIPexprIsVar(set, quadexprterm->expr);
3493 }
3494 else if( SCIPexprIsProduct(set, child) && SCIPexprGetNChildren(child) == 2 ) /* bilinear term */
3495 {
3496 SCIP_QUADEXPR_BILINTERM* bilinexprterm;
3497 SCIP_QUADEXPR_QUADTERM* quadexprterm;
3498 SCIP_EXPR* expr1;
3499 SCIP_EXPR* expr2;
3500
3501 assert(SCIPgetCoefExprProduct(child) == 1.0);
3502
3503 expr1 = SCIPexprGetChildren(child)[0];
3504 expr2 = SCIPexprGetChildren(child)[1];
3505 assert(expr1 != NULL && expr2 != NULL);
3506
3507 bilinexprterm = &expr->quaddata->bilinexprterms[expr->quaddata->nbilinexprterms];
3508
3509 bilinexprterm->coef = coef;
3510 if( SCIPhashmapGetImageInt(seenexpr, (void*)expr1) >= SCIPhashmapGetImageInt(seenexpr, (void*)expr2) )
3511 {
3512 bilinexprterm->expr1 = expr1;
3513 bilinexprterm->expr2 = expr2;
3514 }
3515 else
3516 {
3517 bilinexprterm->expr1 = expr2;
3518 bilinexprterm->expr2 = expr1;
3519 }
3520 bilinexprterm->prodexpr = child;
3521
3522 SCIP_CALL( quadDetectGetQuadexprterm(blkmem, expr1, expr2idx, seenexpr, expr->quaddata, &quadexprterm) );
3523 assert(quadexprterm->expr == expr1);
3524 quadexprterm->adjbilin[quadexprterm->nadjbilin] = expr->quaddata->nbilinexprterms;
3525 ++quadexprterm->nadjbilin;
3526
3527 if( expr->quaddata->allexprsarevars )
3528 expr->quaddata->allexprsarevars = SCIPexprIsVar(set, quadexprterm->expr);
3529
3530 SCIP_CALL( quadDetectGetQuadexprterm(blkmem, expr2, expr2idx, seenexpr, expr->quaddata, &quadexprterm) );
3531 assert(quadexprterm->expr == expr2);
3532 quadexprterm->adjbilin[quadexprterm->nadjbilin] = expr->quaddata->nbilinexprterms;
3533 ++quadexprterm->nadjbilin;
3534
3535 if( expr->quaddata->allexprsarevars )
3536 expr->quaddata->allexprsarevars = SCIPexprIsVar(set, quadexprterm->expr);
3537
3538 ++expr->quaddata->nbilinexprterms;
3539
3540 /* store position of second factor in quadexprterms */
3541 bilinexprterm->pos2 = SCIPhashmapGetImageInt(expr2idx, (void*)bilinexprterm->expr2);
3542 }
3543 else /* linear term */
3544 {
3545 if( SCIPhashmapGetImageInt(seenexpr, (void*)child) < 0 )
3546 {
3547 assert(SCIPhashmapGetImageInt(seenexpr, (void*)child) == -1);
3548
3549 /* expression only appears linearly */
3550 expr->quaddata->linexprs[expr->quaddata->nlinexprs] = child;
3551 expr->quaddata->lincoefs[expr->quaddata->nlinexprs] = coef;
3552 expr->quaddata->nlinexprs++;
3553
3554 if( expr->quaddata->allexprsarevars )
3555 expr->quaddata->allexprsarevars = SCIPexprIsVar(set, child);
3556 }
3557 else
3558 {
3559 /* expression appears non-linearly: set lin coef */
3560 SCIP_QUADEXPR_QUADTERM* quadexprterm;
3561 assert(SCIPhashmapGetImageInt(seenexpr, (void*)child) > 0);
3562
3563 SCIP_CALL( quadDetectGetQuadexprterm(blkmem, child, expr2idx, seenexpr, expr->quaddata, &quadexprterm) );
3564 assert(quadexprterm->expr == child);
3565 quadexprterm->lincoef = coef;
3566
3567 if( expr->quaddata->allexprsarevars )
3568 expr->quaddata->allexprsarevars = SCIPexprIsVar(set, quadexprterm->expr);
3569 }
3570 }
3571 }
3572 assert(expr->quaddata->nquadexprs == nquadterms);
3573 assert(expr->quaddata->nlinexprs == nlinterms);
3574 assert(expr->quaddata->nbilinexprterms == nbilinterms);
3575
3576 SCIPhashmapFree(&seenexpr);
3577 SCIPhashmapFree(&expr2idx);
3578
3579 *isquadratic = TRUE;
3580
3581 return SCIP_OKAY;
3582}
3583
3584/** frees information on quadratic representation of an expression
3585 *
3586 * Reverts SCIPexprCheckQuadratic().
3587 * Before doing changes to an expression, it can be useful to call this function.
3588 */
3590 BMS_BLKMEM* blkmem, /**< block memory */
3591 SCIP_EXPR* expr /**< expression */
3592 )
3593{
3594 int i;
3595 int n;
3596
3597 assert(blkmem != NULL);
3598 assert(expr != NULL);
3599
3600 expr->quadchecked = FALSE;
3601
3602 if( expr->quaddata == NULL )
3603 return;
3604
3605 n = expr->quaddata->nquadexprs;
3606
3611 if( expr->quaddata->eigenvectors != NULL ) /* check for NULL here before calculating n*n to avoid (harmless) overflow in case of large n */
3612 BMSfreeBlockMemoryArray(blkmem, &expr->quaddata->eigenvectors, n * n); /*lint !e647*/
3613
3614 for( i = 0; i < n; ++i )
3615 {
3618 }
3620
3621 BMSfreeBlockMemory(blkmem, &expr->quaddata);
3622}
3623
3624/** Checks the curvature of the quadratic function stored in quaddata
3625 *
3626 * For this, it builds the matrix Q of quadratic coefficients and computes its eigenvalues using LAPACK.
3627 * If Q is
3628 * - semidefinite positive -> curv is set to convex,
3629 * - semidefinite negative -> curv is set to concave,
3630 * - otherwise -> curv is set to unknown.
3631 *
3632 * If `assumevarfixed` is given and some expressions in quadratic terms correspond to variables present in
3633 * this hashmap, then the corresponding rows and columns are ignored in the matrix Q.
3634 */
3636 SCIP_SET* set, /**< global SCIP settings */
3637 BMS_BLKMEM* blkmem, /**< block memory */
3638 BMS_BUFMEM* bufmem, /**< buffer memory */
3639 SCIP_MESSAGEHDLR* messagehdlr, /**< message handler */
3640 SCIP_EXPR* expr, /**< quadratic expression */
3641 SCIP_EXPRCURV* curv, /**< pointer to store the curvature of quadratics */
3642 SCIP_HASHMAP* assumevarfixed, /**< hashmap containing variables that should be assumed to be fixed, or NULL */
3643 SCIP_Bool storeeigeninfo /**< whether the eigenvalues and eigenvectors should be stored */
3644 )
3645{
3646 SCIP_QUADEXPR* quaddata;
3647 SCIP_HASHMAP* expr2matrix;
3648 double* matrix;
3649 double* alleigval;
3650 int nvars;
3651 int nn;
3652 int n;
3653 int i;
3654
3655 assert(set != NULL);
3656 assert(blkmem != NULL);
3657 assert(bufmem != NULL);
3658 assert(messagehdlr != NULL);
3659 assert(expr != NULL);
3660 assert(curv != NULL);
3661
3662 quaddata = expr->quaddata;
3663 assert(quaddata != NULL);
3664
3665 /* do not store eigen information if we are not considering full matrix */
3666 if( assumevarfixed != NULL )
3667 storeeigeninfo = FALSE;
3668
3669 if( quaddata->eigeninfostored || (quaddata->curvaturechecked && !storeeigeninfo) )
3670 {
3671 *curv = quaddata->curvature;
3672 /* if we are convex or concave on the full set of variables, then we will also be so on a subset */
3673 if( assumevarfixed == NULL || quaddata->curvature != SCIP_EXPRCURV_UNKNOWN )
3674 return SCIP_OKAY;
3675 }
3676 assert(quaddata->curvature == SCIP_EXPRCURV_UNKNOWN || assumevarfixed != NULL
3677 || (storeeigeninfo && !quaddata->eigeninfostored));
3678
3679 *curv = SCIP_EXPRCURV_UNKNOWN;
3680
3681 n = quaddata->nquadexprs;
3682
3683 /* do not check curvature if nn will be too large
3684 * we want nn * sizeof(real) to fit into an unsigned int, so n must be <= sqrt(unit_max/sizeof(real))
3685 * sqrt(2*214748364/8) = 7327.1475350234
3686 */
3687 if( n > 7000 )
3688 {
3689 SCIPmessageFPrintVerbInfo(messagehdlr, set->disp_verblevel, SCIP_VERBLEVEL_FULL, NULL,
3690 "number of quadratic variables is too large (%d) to check the curvature\n", n);
3691 return SCIP_OKAY;
3692 }
3693
3694 /* TODO do some simple tests first; like diagonal entries don't change sign, etc */
3695
3696 if( ! SCIPlapackIsAvailable() )
3697 return SCIP_OKAY;
3698
3699 nn = n * n;
3700 assert(nn > 0);
3701 assert((unsigned)nn < UINT_MAX / sizeof(SCIP_Real));
3702
3703 if( storeeigeninfo )
3704 {
3705 SCIP_ALLOC( BMSallocBlockMemoryArray(blkmem, &quaddata->eigenvalues, n));
3706 SCIP_ALLOC( BMSallocClearBlockMemoryArray(blkmem, &quaddata->eigenvectors, nn));
3707
3708 alleigval = quaddata->eigenvalues;
3709 matrix = quaddata->eigenvectors;
3710 }
3711 else
3712 {
3713 SCIP_ALLOC( BMSallocBufferMemoryArray(bufmem, &alleigval, n) );
3714 SCIP_ALLOC( BMSallocClearBufferMemoryArray(bufmem, &matrix, nn) );
3715 }
3716
3717 SCIP_CALL( SCIPhashmapCreate(&expr2matrix, blkmem, n) );
3718
3719 /* fill matrix's diagonal */
3720 nvars = 0;
3721 for( i = 0; i < n; ++i )
3722 {
3723 SCIP_QUADEXPR_QUADTERM quadexprterm;
3724
3725 quadexprterm = quaddata->quadexprterms[i];
3726
3727 assert(!SCIPhashmapExists(expr2matrix, (void*)quadexprterm.expr));
3728
3729 /* skip expr if it is a variable mentioned in assumevarfixed */
3730 if( assumevarfixed != NULL && SCIPexprIsVar(set, quadexprterm.expr)
3731 && SCIPhashmapExists(assumevarfixed, (void*)SCIPgetVarExprVar(quadexprterm.expr)) )
3732 continue;
3733
3734 if( quadexprterm.sqrcoef == 0.0 && ! storeeigeninfo )
3735 {
3736 assert(quadexprterm.nadjbilin > 0);
3737 /* SCIPdebugMsg(scip, "var <%s> appears in bilinear term but is not squared
3738 * --> indefinite quadratic\n", SCIPvarGetName(quadexprterm.var)); */
3739 goto CLEANUP;
3740 }
3741
3742 matrix[nvars * n + nvars] = quadexprterm.sqrcoef;
3743
3744 /* remember row of variable in matrix */
3745 SCIP_CALL( SCIPhashmapInsert(expr2matrix, (void *)quadexprterm.expr, (void *)(size_t)nvars) );
3746 nvars++;
3747 }
3748
3749 /* fill matrix's upper-diagonal */
3750 for( i = 0; i < quaddata->nbilinexprterms; ++i )
3751 {
3752 SCIP_QUADEXPR_BILINTERM bilinexprterm;
3753 int col;
3754 int row;
3755
3756 bilinexprterm = quaddata->bilinexprterms[i];
3757
3758 /* each factor should have been added to expr2matrix unless it corresponds to a variable mentioned in assumevarfixed */
3759 assert(SCIPhashmapExists(expr2matrix, (void*)bilinexprterm.expr1)
3760 || (assumevarfixed != NULL && SCIPexprIsVar(set, bilinexprterm.expr1)
3761 && SCIPhashmapExists(assumevarfixed, (void*)SCIPgetVarExprVar(bilinexprterm.expr1))));
3762 assert(SCIPhashmapExists(expr2matrix, (void*)bilinexprterm.expr2)
3763 || (assumevarfixed != NULL && SCIPexprIsVar(set, bilinexprterm.expr2)
3764 && SCIPhashmapExists(assumevarfixed, (void*)SCIPgetVarExprVar(bilinexprterm.expr2))));
3765
3766 /* skip bilinear terms where at least one of the factors should be assumed to be fixed
3767 * (i.e., not present in expr2matrix map) */
3768 if( !SCIPhashmapExists(expr2matrix, (void*)bilinexprterm.expr1)
3769 || !SCIPhashmapExists(expr2matrix, (void*)bilinexprterm.expr2) )
3770 continue;
3771
3772 row = (int)(size_t)SCIPhashmapGetImage(expr2matrix, bilinexprterm.expr1);
3773 col = (int)(size_t)SCIPhashmapGetImage(expr2matrix, bilinexprterm.expr2);
3774
3775 assert(row != col);
3776
3777 if( row < col )
3778 matrix[row * n + col] = bilinexprterm.coef / 2.0;
3779 else
3780 matrix[col * n + row] = bilinexprterm.coef / 2.0;
3781 }
3782
3783 /* compute eigenvalues */
3784 if( SCIPlapackComputeEigenvalues(bufmem, storeeigeninfo, n, matrix, alleigval) != SCIP_OKAY )
3785 {
3786 SCIPmessagePrintWarning(messagehdlr, "Failed to compute eigenvalues of quadratic coefficient "
3787 "matrix --> don't know curvature\n");
3788 goto CLEANUP;
3789 }
3790
3791 /* check convexity */
3792 if( !SCIPsetIsNegative(set, alleigval[0]) )
3793 *curv = SCIP_EXPRCURV_CONVEX;
3794 else if( !SCIPsetIsPositive(set, alleigval[n-1]) )
3795 *curv = SCIP_EXPRCURV_CONCAVE;
3796
3797CLEANUP:
3798 SCIPhashmapFree(&expr2matrix);
3799
3800 if( !storeeigeninfo )
3801 {
3802 BMSfreeBufferMemoryArray(bufmem, &matrix);
3803 BMSfreeBufferMemoryArray(bufmem, &alleigval);
3804 }
3805 else
3806 {
3807 assert(!quaddata->eigeninfostored);
3808 quaddata->eigeninfostored = TRUE;
3809 }
3810
3811 /* if checked convexity on full Q matrix, then remember it
3812 * if indefinite on submatrix, then it will also be indefinite on full matrix, so can remember that, too */
3813 if( assumevarfixed == NULL || *curv == SCIP_EXPRCURV_UNKNOWN )
3814 {
3815 quaddata->curvature = *curv;
3816 quaddata->curvaturechecked = TRUE;
3817 }
3818
3819 return SCIP_OKAY;
3820}
3821
3822
3823/* from pub_expr.h */
3824
3825#ifdef NDEBUG
3826#undef SCIPexprGetNUses
3827#undef SCIPexprGetNChildren
3828#undef SCIPexprGetChildren
3829#undef SCIPexprGetHdlr
3830#undef SCIPexprGetData
3831#undef SCIPexprSetData
3832#undef SCIPexprGetOwnerData
3833#undef SCIPexprGetEvalValue
3834#undef SCIPexprGetEvalTag
3835#undef SCIPexprGetDerivative
3836#undef SCIPexprGetDot
3837#undef SCIPexprGetBardot
3838#undef SCIPexprGetDiffTag
3839#undef SCIPexprGetActivity
3840#undef SCIPexprGetActivityTag
3841#undef SCIPexprSetActivity
3842#undef SCIPexprGetCurvature
3843#undef SCIPexprSetCurvature
3844#undef SCIPexprIsIntegral
3845#undef SCIPexprSetIntegrality
3846#undef SCIPexprAreQuadraticExprsVariables
3847#endif
3848
3849/** gets the number of times the expression is currently captured */
3851 SCIP_EXPR* expr /**< expression */
3852 )
3853{
3854 assert(expr != NULL);
3855
3856 return expr->nuses;
3857}
3858
3859/** gives the number of children of an expression */
3861 SCIP_EXPR* expr /**< expression */
3862 )
3863{
3864 assert(expr != NULL);
3865
3866 return expr->nchildren;
3867}
3868
3869/** gives the children of an expression (can be NULL if no children) */
3871 SCIP_EXPR* expr /**< expression */
3872 )
3873{
3874 assert(expr != NULL);
3875
3876 return expr->children;
3877}
3878
3879/** gets the expression handler of an expression
3880 *
3881 * This identifies the type of the expression (sum, variable, ...).
3882 */
3884 SCIP_EXPR* expr /**< expression */
3885 )
3886{
3887 assert(expr != NULL);
3888
3889 return expr->exprhdlr;
3890}
3891
3892/** gets the expression data of an expression */
3894 SCIP_EXPR* expr /**< expression */
3895 )
3896{
3897 assert(expr != NULL);
3898
3899 return expr->exprdata;
3900}
3901
3902/** sets the expression data of an expression
3903 *
3904 * The pointer to possible old data is overwritten and the
3905 * freedata-callback is not called before.
3906 * This function is intended to be used by expression handler only.
3907 */
3909 SCIP_EXPR* expr, /**< expression */
3910 SCIP_EXPRDATA* exprdata /**< expression data to be set (can be NULL) */
3911 )
3912{
3913 assert(expr != NULL);
3914 assert(exprdata == NULL || expr->exprhdlr->copydata != NULL); /* copydata must be available if there is expression data */
3915 assert(exprdata == NULL || expr->exprhdlr->freedata != NULL); /* freedata must be available if there is expression data */
3916
3917 expr->exprdata = exprdata;
3918}
3919
3920/** gets the data that the owner of an expression has stored in an expression */
3922 SCIP_EXPR* expr /**< expression */
3923 )
3924{
3925 assert(expr != NULL);
3926
3927 return expr->ownerdata;
3928}
3929
3930/** gives the value from the last evaluation of an expression (or SCIP_INVALID if there was an eval error)
3931 *
3932 * @see SCIPevalExpr to evaluate the expression at a given solution.
3933 */
3935 SCIP_EXPR* expr /**< expression */
3936 )
3937{
3938 assert(expr != NULL);
3939
3940 return expr->evalvalue;
3941}
3942
3943/** gives the evaluation tag from the last evaluation, or 0
3944 *
3945 * @see SCIPevalExpr
3946 */
3948 SCIP_EXPR* expr /**< expression */
3949 )
3950{
3951 assert(expr != NULL);
3952
3953 return expr->evaltag;
3954}
3955
3956/** returns the derivative stored in an expression (or SCIP_INVALID if there was an evaluation error)
3957 *
3958 * @see SCIPevalExprGradient
3959 */
3961 SCIP_EXPR* expr /**< expression */
3962 )
3963{
3964 assert(expr != NULL);
3965
3966 return expr->derivative;
3967}
3968
3969/** gives the value of directional derivative from the last evaluation of a directional derivative of
3970 * expression (or SCIP_INVALID if there was an error)
3971 *
3972 * @see SCIPevalExprHessianDir
3973 */
3975 SCIP_EXPR* expr /**< expression */
3976 )
3977{
3978 assert(expr != NULL);
3979
3980 return expr->dot;
3981}
3982
3983/** gives the value of directional derivative from the last evaluation of a directional derivative of
3984 * derivative of root (or SCIP_INVALID if there was an error)
3985 *
3986 * @see SCIPevalExprHessianDir
3987 */
3989 SCIP_EXPR* expr /**< expression */
3990 )
3991{
3992 assert(expr != NULL);
3993
3994 return expr->bardot;
3995}
3996
3997/** returns the difftag stored in an expression
3998 *
3999 * can be used to check whether partial derivative value is valid
4000 *
4001 * @see SCIPevalExprGradient
4002 */
4004 SCIP_EXPR* expr /**< expression */
4005 )
4006{
4007 assert(expr != NULL);
4008
4009 return expr->difftag;
4010}
4011
4012/** returns the activity that is currently stored for an expression
4013 *
4014 * @see SCIPevalExprActivity
4015 */
4017 SCIP_EXPR* expr /**< expression */
4018 )
4019{
4020 assert(expr != NULL);
4021
4022 return expr->activity;
4023}
4024
4025/** returns the tag associated with the activity of the expression
4026 *
4027 * It can depend on the owner of the expression how to interpret this tag.
4028 * SCIPevalExprActivity() compares with `stat->domchgcount`.
4029 *
4030 * @see SCIPevalExprActivity
4031 */
4033 SCIP_EXPR* expr /**< expression */
4034 )
4035{
4036 assert(expr != NULL);
4037
4038 return expr->activitytag;
4039}
4040
4041/** set the activity with tag for an expression */
4043 SCIP_EXPR* expr, /**< expression */
4044 SCIP_INTERVAL activity, /**< new activity */
4045 SCIP_Longint activitytag /**< tag associated with activity */
4046 )
4047{
4048 assert(expr != NULL);
4049
4050 expr->activity = activity;
4051 expr->activitytag = activitytag;
4052}
4053
4054/** returns the curvature of an expression
4055 *
4056 * @note Call SCIPcomputeExprCurvature() before calling this function.
4057 */
4059 SCIP_EXPR* expr /**< expression */
4060 )
4061{
4062 assert(expr != NULL);
4063
4064 return expr->curvature;
4065}
4066
4067/** sets the curvature of an expression */
4069 SCIP_EXPR* expr, /**< expression */
4070 SCIP_EXPRCURV curvature /**< curvature of the expression */
4071 )
4072{
4073 assert(expr != NULL);
4074
4075 expr->curvature = curvature;
4076}
4077
4078/** returns whether an expression is integral */
4080 SCIP_EXPR* expr /**< expression */
4081 )
4082{
4083 assert(expr != NULL);
4084
4085 return expr->isintegral;
4086}
4087
4088/** sets the integrality flag of an expression */
4090 SCIP_EXPR* expr, /**< expression */
4091 SCIP_Bool isintegral /**< integrality of the expression */
4092 )
4093{
4094 assert(expr != NULL);
4095
4096 expr->isintegral = isintegral;
4097}
4098
4099/** gives the coefficients and expressions that define a quadratic expression
4100 *
4101 * It can return the constant part, the number, arguments, and coefficients of the purely linear part
4102 * and the number of quadratic terms and bilinear terms.
4103 * Note that for arguments that appear in the quadratic part, a linear coefficient is
4104 * stored with the quadratic term.
4105 * Use SCIPexprGetQuadraticQuadTerm() and SCIPexprGetQuadraticBilinTerm()
4106 * to access the data for a quadratic or bilinear term.
4107 *
4108 * It can also return the eigenvalues and the eigenvectors of the matrix \f$Q\f$ when the quadratic is written
4109 * as \f$x^T Q x + b^T x + c^T y + d\f$, where \f$c^T y\f$ defines the purely linear part.
4110 * Note, however, that to have access to them one needs to call SCIPcomputeExprQuadraticCurvature()
4111 * with `storeeigeninfo=TRUE`. If the eigen information was not stored or it failed to be computed,
4112 * `eigenvalues` and `eigenvectors` will be set to NULL.
4113 *
4114 * This function returns pointers to internal data in linexprs and lincoefs.
4115 * The user must not change this data.
4116 *
4117 * @attention SCIPcheckExprQuadratic() needs to be called first to check whether expression is quadratic and initialize the data of the quadratic representation.
4118 */
4120 SCIP_EXPR* expr, /**< quadratic expression */
4121 SCIP_Real* constant, /**< buffer to store constant term, or NULL */
4122 int* nlinexprs, /**< buffer to store number of expressions that appear linearly, or NULL */
4123 SCIP_EXPR*** linexprs, /**< buffer to store pointer to array of expressions that appear linearly, or NULL */
4124 SCIP_Real** lincoefs, /**< buffer to store pointer to array of coefficients of expressions that appear linearly, or NULL */
4125 int* nquadexprs, /**< buffer to store number of expressions in quadratic terms, or NULL */
4126 int* nbilinexprs, /**< buffer to store number of bilinear expressions terms, or NULL */
4127 SCIP_Real** eigenvalues, /**< buffer to store pointer to array of eigenvalues of Q, or NULL */
4128 SCIP_Real** eigenvectors /**< buffer to store pointer to array of eigenvectors of Q, or NULL */
4129 )
4130{
4131 SCIP_QUADEXPR* quaddata;
4132
4133 assert(expr != NULL);
4134
4135 quaddata = expr->quaddata;
4136 assert(quaddata != NULL);
4137
4138 if( constant != NULL )
4139 *constant = quaddata->constant;
4140 if( nlinexprs != NULL )
4141 *nlinexprs = quaddata->nlinexprs;
4142 if( linexprs != NULL )
4143 *linexprs = quaddata->linexprs;
4144 if( lincoefs != NULL )
4145 *lincoefs = quaddata->lincoefs;
4146 if( nquadexprs != NULL )
4147 *nquadexprs = quaddata->nquadexprs;
4148 if( nbilinexprs != NULL )
4149 *nbilinexprs = quaddata->nbilinexprterms;
4150 if( eigenvalues != NULL )
4151 *eigenvalues = quaddata->eigenvalues;
4152 if( eigenvectors != NULL )
4153 *eigenvectors = quaddata->eigenvectors;
4154}
4155
4156/** gives the data of a quadratic expression term
4157 *
4158 * For a term \f$a \cdot \text{expr}^2 + b \cdot \text{expr} + \sum_i (c_i \cdot \text{expr} \cdot \text{otherexpr}_i)\f$, returns
4159 * `expr`, \f$a\f$, \f$b\f$, the number of summands, and indices of bilinear terms in the quadratic expressions `bilinexprterms`.
4160 *
4161 * This function returns pointers to internal data in adjbilin.
4162 * The user must not change this data.
4163 */
4165 SCIP_EXPR* quadexpr, /**< quadratic expression */
4166 int termidx, /**< index of quadratic term */
4167 SCIP_EXPR** expr, /**< buffer to store pointer to argument expression (the 'x') of this term, or NULL */
4168 SCIP_Real* lincoef, /**< buffer to store linear coefficient of variable, or NULL */
4169 SCIP_Real* sqrcoef, /**< buffer to store square coefficient of variable, or NULL */
4170 int* nadjbilin, /**< buffer to store number of bilinear terms this variable is involved in, or NULL */
4171 int** adjbilin, /**< buffer to store pointer to indices of associated bilinear terms, or NULL */
4172 SCIP_EXPR** sqrexpr /**< buffer to store pointer to square expression (the 'x^2') of this term or NULL if no square expression, or NULL */
4173 )
4174{
4175 SCIP_QUADEXPR_QUADTERM* quadexprterm;
4176
4177 assert(quadexpr != NULL);
4178 assert(quadexpr->quaddata != NULL);
4179 assert(quadexpr->quaddata->quadexprterms != NULL);
4180 assert(termidx >= 0);
4181 assert(termidx < quadexpr->quaddata->nquadexprs);
4182
4183 quadexprterm = &quadexpr->quaddata->quadexprterms[termidx];
4184
4185 if( expr != NULL )
4186 *expr = quadexprterm->expr;
4187 if( lincoef != NULL )
4188 *lincoef = quadexprterm->lincoef;
4189 if( sqrcoef != NULL )
4190 *sqrcoef = quadexprterm->sqrcoef;
4191 if( nadjbilin != NULL )
4192 *nadjbilin = quadexprterm->nadjbilin;
4193 if( adjbilin != NULL )
4194 *adjbilin = quadexprterm->adjbilin;
4195 if( sqrexpr != NULL )
4196 *sqrexpr = quadexprterm->sqrexpr;
4197}
4198
4199/** gives the data of a bilinear expression term
4200 *
4201 * For a term a*expr1*expr2, returns expr1, expr2, a, and
4202 * the position of the quadratic expression term that uses expr2 in the quadratic expressions `quadexprterms`.
4203 */
4205 SCIP_EXPR* expr, /**< quadratic expression */
4206 int termidx, /**< index of bilinear term */
4207 SCIP_EXPR** expr1, /**< buffer to store first factor, or NULL */
4208 SCIP_EXPR** expr2, /**< buffer to store second factor, or NULL */
4209 SCIP_Real* coef, /**< buffer to coefficient, or NULL */
4210 int* pos2, /**< buffer to position of expr2 in quadexprterms array of quadratic expression, or NULL */
4211 SCIP_EXPR** prodexpr /**< buffer to store pointer to expression that is product if first and second factor, or NULL */
4212 )
4213{
4214 SCIP_QUADEXPR_BILINTERM* bilinexprterm;
4215
4216 assert(expr != NULL);
4217 assert(expr->quaddata != NULL);
4218 assert(expr->quaddata->bilinexprterms != NULL);
4219 assert(termidx >= 0);
4220 assert(termidx < expr->quaddata->nbilinexprterms);
4221
4222 bilinexprterm = &expr->quaddata->bilinexprterms[termidx];
4223
4224 if( expr1 != NULL )
4225 *expr1 = bilinexprterm->expr1;
4226 if( expr2 != NULL )
4227 *expr2 = bilinexprterm->expr2;
4228 if( coef != NULL )
4229 *coef = bilinexprterm->coef;
4230 if( pos2 != NULL )
4231 *pos2 = bilinexprterm->pos2;
4232 if( prodexpr != NULL )
4233 *prodexpr = bilinexprterm->prodexpr;
4234}
4235
4236/** returns whether all expressions that are used in a quadratic expression are variable expressions
4237 *
4238 * @return TRUE iff all `linexprs` and `quadexprterms[.].expr` are variable expressions
4239 */
4241 SCIP_EXPR* expr /**< quadratic expression */
4242 )
4243{
4244 assert(expr != NULL);
4245 assert(expr->quaddata != NULL);
4246
4247 return expr->quaddata->allexprsarevars;
4248}
4249
4250/** returns a monomial representation of a product expression
4251 *
4252 * The array to store all factor expressions needs to be of size the number of
4253 * children in the expression which is given by SCIPexprGetNChildren().
4254 *
4255 * Given a non-trivial monomial expression, the function finds its representation as \f$cx^\alpha\f$, where
4256 * \f$c\f$ is a real coefficient, \f$x\f$ is a vector of auxiliary or original variables (where some entries can
4257 * be NULL is the auxiliary variable has not been created yet), and \f$\alpha\f$ is a real vector of exponents.
4258 *
4259 * A non-trivial monomial is a product of a least two expressions.
4260 */
4262 SCIP_SET* set, /**< global SCIP settings */
4263 BMS_BLKMEM* blkmem, /**< block memory */
4264 SCIP_EXPR* expr, /**< expression */
4265 SCIP_Real* coef, /**< coefficient \f$c\f$ */
4266 SCIP_Real* exponents, /**< exponents \f$\alpha\f$ */
4267 SCIP_EXPR** factors /**< factor expressions \f$x\f$ */
4268 )
4269{
4270 SCIP_EXPR* child;
4271 int c;
4272 int nexprs;
4273
4274 assert(set != NULL);
4275 assert(blkmem != NULL);
4276 assert(expr != NULL);
4277 assert(coef != NULL);
4278 assert(exponents != NULL);
4279 assert(factors != NULL);
4280
4281 assert(SCIPexprIsProduct(set, expr));
4282
4283 *coef = SCIPgetCoefExprProduct(expr);
4284 nexprs = SCIPexprGetNChildren(expr);
4285
4286 for( c = 0; c < nexprs; ++c )
4287 {
4288 child = SCIPexprGetChildren(expr)[c];
4289
4290 if( SCIPexprIsPower(set, child) )
4291 {
4292 exponents[c] = SCIPgetExponentExprPow(child);
4293 factors[c] = SCIPexprGetChildren(child)[0];
4294 }
4295 else
4296 {
4297 exponents[c] = 1.0;
4298 factors[c] = child;
4299 }
4300 }
4301
4302 return SCIP_OKAY;
4303}
4304
4305/**@} */
void SCIPclockStop(SCIP_CLOCK *clck, SCIP_SET *set)
Definition: clock.c:360
void SCIPclockStart(SCIP_CLOCK *clck, SCIP_SET *set)
Definition: clock.c:290
SCIP_Real SCIPclockGetTime(SCIP_CLOCK *clck)
Definition: clock.c:438
void SCIPclockReset(SCIP_CLOCK *clck)
Definition: clock.c:209
void SCIPclockFree(SCIP_CLOCK **clck)
Definition: clock.c:185
SCIP_RETCODE SCIPclockCreate(SCIP_CLOCK **clck, SCIP_CLOCKTYPE clocktype)
Definition: clock.c:170
internal methods for clocks and timing issues
#define NULL
Definition: def.h:266
#define SCIP_Longint
Definition: def.h:157
#define SCIP_INVALID
Definition: def.h:192
#define SCIP_INTERVAL_INFINITY
Definition: def.h:194
#define SCIP_Bool
Definition: def.h:91
#define SCIP_ALLOC(x)
Definition: def.h:384
#define SCIP_Real
Definition: def.h:172
#define TRUE
Definition: def.h:93
#define FALSE
Definition: def.h:94
#define SCIP_LONGINT_FORMAT
Definition: def.h:164
#define SCIPABORT()
Definition: def.h:345
#define SCIP_CALL(x)
Definition: def.h:373
#define SCIP_CALL_FINALLY(x, y)
Definition: def.h:415
SCIP_RETCODE SCIPexprPrint(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_MESSAGEHDLR *messagehdlr, FILE *file, SCIP_EXPR *expr)
Definition: expr.c:2266
SCIP_Bool SCIPexprIsPower(SCIP_SET *set, SCIP_EXPR *expr)
Definition: expr.c:2254
SCIP_RETCODE SCIPexprhdlrBwDiffExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, BMS_BUFMEM *bufmem, SCIP_EXPR *expr, int childidx, SCIP_Real *derivative, SCIP_Real *childrenvals, SCIP_Real exprval)
Definition: expr.c:1272
SCIP_RETCODE SCIPexprEvalActivity(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR *rootexpr)
Definition: expr.c:2950
static SCIP_RETCODE evalAndDiff(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR *expr, SCIP_SOL *sol, SCIP_Longint soltag, SCIP_SOL *direction)
Definition: expr.c:188
SCIP_RETCODE SCIPexprPrintDotInit(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPRPRINTDATA **printdata, FILE *file, SCIP_EXPRPRINT_WHAT whattoprint)
Definition: expr.c:2315
SCIP_RETCODE SCIPexprhdlrIntegralityExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, SCIP_Bool *isintegral)
Definition: expr.c:1083
SCIP_RETCODE SCIPexprCopy(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_SET *targetset, SCIP_STAT *targetstat, BMS_BLKMEM *targetblkmem, SCIP_EXPR *sourceexpr, SCIP_EXPR **targetexpr, SCIP_DECL_EXPR_MAPEXPR((*mapexpr)), void *mapexprdata, SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), void *ownercreatedata)
Definition: expr.c:1878
SCIP_RETCODE SCIPexprPrintDotInit2(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPRPRINTDATA **printdata, const char *filename, SCIP_EXPRPRINT_WHAT whattoprint)
Definition: expr.c:2347
SCIP_RETCODE SCIPexprSimplify(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR *rootexpr, SCIP_EXPR **simplified, SCIP_Bool *changed, SCIP_Bool *infeasible, SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), void *ownercreatedata)
Definition: expr.c:3189
SCIP_RETCODE SCIPexprhdlrInitEstimatesExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, SCIP_INTERVAL *bounds, SCIP_Bool overestimate, SCIP_Real *coefs[SCIP_EXPR_MAXINITESTIMATES], SCIP_Real constant[SCIP_EXPR_MAXINITESTIMATES], int *nreturned)
Definition: expr.c:1600
SCIP_RETCODE SCIPexprComputeQuadraticCurvature(SCIP_SET *set, BMS_BLKMEM *blkmem, BMS_BUFMEM *bufmem, SCIP_MESSAGEHDLR *messagehdlr, SCIP_EXPR *expr, SCIP_EXPRCURV *curv, SCIP_HASHMAP *assumevarfixed, SCIP_Bool storeeigeninfo)
Definition: expr.c:3635
SCIP_RETCODE SCIPexprGetSymData(SCIP_SET *set, SCIP_EXPR *expr, SYM_EXPRDATA **symdata)
Definition: expr.c:3283
SCIP_RETCODE SCIPexprhdlrSimplifyExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, SCIP_EXPR **simplifiedexpr, SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), void *ownercreatedata)
Definition: expr.c:1635
SCIP_RETCODE SCIPexprEvalGradient(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR *rootexpr, SCIP_SOL *sol, SCIP_Longint soltag)
Definition: expr.c:2745
SCIP_RETCODE SCIPexprReplaceChild(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR *expr, int childidx, SCIP_EXPR *newchild)
Definition: expr.c:1816
SCIP_RETCODE SCIPexprhdlrReversePropExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, SCIP_INTERVAL bounds, SCIP_INTERVAL *childrenbounds, SCIP_Bool *infeasible)
Definition: expr.c:1680
SCIP_Bool SCIPexprIsVar(SCIP_SET *set, SCIP_EXPR *expr)
Definition: expr.c:2206
static SCIP_RETCODE freeExpr(BMS_BLKMEM *blkmem, SCIP_EXPR **expr)
Definition: expr.c:74
SCIP_RETCODE SCIPexprCheckQuadratic(SCIP_SET *set, BMS_BLKMEM *blkmem, SCIP_EXPR *expr, SCIP_Bool *isquadratic)
Definition: expr.c:3315
SCIP_RETCODE SCIPexprhdlrFree(SCIP_EXPRHDLR **exprhdlr, SCIP_SET *set, BMS_BLKMEM *blkmem)
Definition: expr.c:340
SCIP_RETCODE SCIPexprhdlrPrintExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_MESSAGEHDLR *messagehdlr, SCIP_EXPR *expr, SCIP_EXPRITER_STAGE stage, int currentchild, unsigned int parentprecedence, FILE *file)
Definition: expr.c:917
SCIP_RETCODE SCIPexprEvalHessianDir(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR *rootexpr, SCIP_SOL *sol, SCIP_Longint soltag, SCIP_SOL *direction)
Definition: expr.c:2844
int SCIPexprCompare(SCIP_SET *set, SCIP_EXPR *expr1, SCIP_EXPR *expr2)
Definition: expr.c:3082
SCIP_RETCODE SCIPexprhdlrMonotonicityExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, int childidx, SCIP_MONOTONE *result)
Definition: expr.c:1054
SCIP_RETCODE SCIPexprhdlrEvalExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, BMS_BUFMEM *bufmem, SCIP_EXPR *expr, SCIP_Real *val, SCIP_Real *childrenvals, SCIP_SOL *sol)
Definition: expr.c:1205
void SCIPexprhdlrInit(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set)
Definition: expr.c:884
SCIP_RETCODE SCIPexprRemoveChildren(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR *expr)
Definition: expr.c:1846
SCIP_RETCODE SCIPexprhdlrCopyInclude(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *targetset)
Definition: expr.c:859
SCIP_RETCODE SCIPexprhdlrHashExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, unsigned int *hashkey, unsigned int *childrenhashes)
Definition: expr.c:1113
SCIP_Bool SCIPexprIsValue(SCIP_SET *set, SCIP_EXPR *expr)
Definition: expr.c:2218
SCIP_RETCODE SCIPexprhdlrFwDiffExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, SCIP_Real *dot, SCIP_SOL *direction)
Definition: expr.c:1345
void SCIPexprCapture(SCIP_EXPR *expr)
Definition: expr.c:2064
SCIP_RETCODE SCIPexprhdlrIntEvalExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, SCIP_INTERVAL *interval, SCIP_DECL_EXPR_INTEVALVAR((*intevalvar)), void *intevalvardata)
Definition: expr.c:1525
static SCIP_RETCODE quadDetectProcessExpr(SCIP_EXPR *expr, SCIP_HASHMAP *seenexpr, int *nquadterms, int *nlinterms)
Definition: expr.c:105
SCIP_RETCODE SCIPexprhdlrBwFwDiffExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, int childidx, SCIP_Real *bardot, SCIP_SOL *direction)
Definition: expr.c:1489
SCIP_RETCODE SCIPexprPrintDotFinal(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPRPRINTDATA **printdata)
Definition: expr.c:2493
SCIP_RETCODE SCIPexprAppendChild(SCIP_SET *set, BMS_BLKMEM *blkmem, SCIP_EXPR *expr, SCIP_EXPR *child)
Definition: expr.c:1785
SCIP_RETCODE SCIPexprDuplicateShallow(SCIP_SET *set, BMS_BLKMEM *blkmem, SCIP_EXPR *expr, SCIP_EXPR **copyexpr, SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), void *ownercreatedata)
Definition: expr.c:2033
SCIP_RETCODE SCIPexprhdlrParseExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, const char *string, const char **endstring, SCIP_EXPR **expr, SCIP_Bool *success, SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), void *ownercreatedata)
Definition: expr.c:986
SCIP_RETCODE SCIPexprGetMonomialData(SCIP_SET *set, BMS_BLKMEM *blkmem, SCIP_EXPR *expr, SCIP_Real *coef, SCIP_Real *exponents, SCIP_EXPR **factors)
Definition: expr.c:4261
int SCIPexprhdlrCompareExpr(SCIP_SET *set, SCIP_EXPR *expr1, SCIP_EXPR *expr2)
Definition: expr.c:1162
SCIP_RETCODE SCIPexprhdlrCurvatureExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, SCIP_EXPRCURV exprcurvature, SCIP_Bool *success, SCIP_EXPRCURV *childcurv)
Definition: expr.c:1025
SCIP_RETCODE SCIPexprDismantle(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_MESSAGEHDLR *messagehdlr, FILE *file, SCIP_EXPR *expr)
Definition: expr.c:2546
SCIP_RETCODE SCIPexprCreate(SCIP_SET *set, BMS_BLKMEM *blkmem, SCIP_EXPR **expr, SCIP_EXPRHDLR *exprhdlr, SCIP_EXPRDATA *exprdata, int nchildren, SCIP_EXPR **children, SCIP_DECL_EXPR_OWNERCREATE((*ownercreate)), void *ownercreatedata)
Definition: expr.c:1728
SCIP_Bool SCIPexprIsProduct(SCIP_SET *set, SCIP_EXPR *expr)
Definition: expr.c:2242
SCIP_RETCODE SCIPexprPrintDot(SCIP_SET *set, SCIP_MESSAGEHDLR *messagehdlr, SCIP_EXPRPRINTDATA *printdata, SCIP_EXPR *expr)
Definition: expr.c:2379
SCIP_Bool SCIPexprIsSum(SCIP_SET *set, SCIP_EXPR *expr)
Definition: expr.c:2230
SCIP_RETCODE SCIPexprRelease(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR **rootexpr)
Definition: expr.c:2074
SCIP_RETCODE SCIPexprhdlrEstimateExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, SCIP_EXPR *expr, SCIP_INTERVAL *localbounds, SCIP_INTERVAL *globalbounds, SCIP_Real *refpoint, SCIP_Bool overestimate, SCIP_Real targetvalue, SCIP_Real *coefs, SCIP_Real *constant, SCIP_Bool *islocal, SCIP_Bool *success, SCIP_Bool *branchcand)
Definition: expr.c:1556
SCIP_RETCODE SCIPexprhdlrEvalFwDiffExpr(SCIP_EXPRHDLR *exprhdlr, SCIP_SET *set, BMS_BUFMEM *bufmem, SCIP_EXPR *expr, SCIP_Real *val, SCIP_Real *dot, SCIP_Real *childrenvals, SCIP_SOL *sol, SCIP_Real *childrendirs, SCIP_SOL *direction)
Definition: expr.c:1386
SCIP_RETCODE SCIPexprhdlrCreate(BMS_BLKMEM *blkmem, SCIP_EXPRHDLR **exprhdlr, const char *name, const char *desc, unsigned int precedence, SCIP_DECL_EXPREVAL((*eval)), SCIP_EXPRHDLRDATA *data)
Definition: expr.c:305
static SCIP_RETCODE quadDetectGetQuadexprterm(BMS_BLKMEM *blkmem, SCIP_EXPR *expr, SCIP_HASHMAP *expr2idx, SCIP_HASHMAP *seenexpr, SCIP_QUADEXPR *quadexpr, SCIP_QUADEXPR_QUADTERM **quadexprterm)
Definition: expr.c:145
void SCIPexprFreeQuadratic(BMS_BLKMEM *blkmem, SCIP_EXPR *expr)
Definition: expr.c:3589
SCIP_RETCODE SCIPexprEval(SCIP_SET *set, SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPR *expr, SCIP_SOL *sol, SCIP_Longint soltag)
Definition: expr.c:2654
private functions to work with algebraic expressions
void SCIPexpriterFree(SCIP_EXPRITER **iterator)
Definition: expriter.c:446
SCIP_RETCODE SCIPexpriterCreate(SCIP_STAT *stat, BMS_BLKMEM *blkmem, SCIP_EXPRITER **iterator)
Definition: expriter.c:427
static SCIP_RETCODE eval(SCIP *scip, SCIP_EXPR *expr, SCIP_EXPRINTDATA *exprintdata, const vector< Type > &x, Type &val)
void SCIPhashmapFree(SCIP_HASHMAP **hashmap)
Definition: misc.c:3111
int SCIPhashmapGetImageInt(SCIP_HASHMAP *hashmap, void *origin)
Definition: misc.c:3284
void * SCIPhashmapGetImage(SCIP_HASHMAP *hashmap, void *origin)
Definition: misc.c:3264
SCIP_RETCODE SCIPhashmapInsert(SCIP_HASHMAP *hashmap, void *origin, void *image)
Definition: misc.c:3159
int SCIPhashmapGetNEntries(SCIP_HASHMAP *hashmap)
Definition: misc.c:3544
SCIP_HASHMAPENTRY * SCIPhashmapGetEntry(SCIP_HASHMAP *hashmap, int entryidx)
Definition: misc.c:3552
SCIP_RETCODE SCIPhashmapCreate(SCIP_HASHMAP **hashmap, BMS_BLKMEM *blkmem, int mapsize)
Definition: misc.c:3077
void * SCIPhashmapEntryGetOrigin(SCIP_HASHMAPENTRY *entry)
Definition: misc.c:3563
SCIP_Bool SCIPhashmapExists(SCIP_HASHMAP *hashmap, void *origin)
Definition: misc.c:3426
SCIP_RETCODE SCIPhashmapInsertInt(SCIP_HASHMAP *hashmap, void *origin, int image)
Definition: misc.c:3195
SCIP_RETCODE SCIPhashmapSetImageInt(SCIP_HASHMAP *hashmap, void *origin, int image)
Definition: misc.c:3360
#define SCIPisFinite(x)
Definition: pub_misc.h:1933
unsigned int SCIPcalcFibHash(SCIP_Real v)
Definition: misc.c:10350
const char * SCIPexprhdlrGetName(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:545
SCIP_Real SCIPexprhdlrGetEstimateTime(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:793
SCIP_Bool SCIPexprhdlrHasSimplify(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:645
SCIP_Longint SCIPexprhdlrGetNDomainReductions(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:761
void SCIPexprhdlrSetIntegrality(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRINTEGRALITY((*integrality)))
Definition: expr.c:440
void SCIPexprhdlrSetCopyFreeData(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRCOPYDATA((*copydata)), SCIP_DECL_EXPRFREEDATA((*freedata)))
Definition: expr.c:383
void SCIPexprhdlrSetPrint(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRPRINT((*print)))
Definition: expr.c:396
void SCIPexprhdlrSetGetSymdata(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRGETSYMDATA((*getsymdata)))
Definition: expr.c:521
SCIP_Bool SCIPexprhdlrHasCurvature(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:655
void SCIPexprhdlrSetHash(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRHASH((*hash)))
Definition: expr.c:451
void SCIPexprhdlrIncrementNDomainReductions(SCIP_EXPRHDLR *exprhdlr, int nreductions)
Definition: expr.c:771
SCIP_EXPRHDLRDATA * SCIPexprhdlrGetData(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:575
SCIP_Real SCIPexprhdlrGetReversepropTime(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:741
unsigned int SCIPexprhdlrGetPrecedence(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:565
void SCIPexprhdlrIncrementNBranchings(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:817
SCIP_Longint SCIPexprhdlrGetNReversepropCalls(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:731
SCIP_DECL_SORTPTRCOMP(SCIPexprhdlrComp)
Definition: expr.c:695
void SCIPexprhdlrSetCopyFreeHdlr(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRCOPYHDLR((*copyhdlr)), SCIP_DECL_EXPRFREEHDLR((*freehdlr)))
Definition: expr.c:370
const char * SCIPexprhdlrGetDescription(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:555
SCIP_Bool SCIPexprhdlrHasFwdiff(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:605
SCIP_Bool SCIPexprhdlrHasGetSymData(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:685
SCIP_Bool SCIPexprhdlrHasMonotonicity(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:665
void SCIPexprhdlrSetDiff(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRBWDIFF((*bwdiff)), SCIP_DECL_EXPRFWDIFF((*fwdiff)), SCIP_DECL_EXPRBWFWDIFF((*bwfwdiff)))
Definition: expr.c:473
SCIP_Bool SCIPexprhdlrHasReverseProp(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:675
unsigned int SCIPexprhdlrGetNCreated(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:701
SCIP_Bool SCIPexprhdlrHasInitEstimates(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:635
SCIP_Longint SCIPexprhdlrGetNBranchings(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:807
SCIP_Bool SCIPexprhdlrHasPrint(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:585
void SCIPexprhdlrSetReverseProp(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRREVERSEPROP((*reverseprop)))
Definition: expr.c:510
void SCIPexprhdlrSetParse(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRPARSE((*parse)))
Definition: expr.c:407
SCIP_Longint SCIPexprhdlrGetNSimplifyCalls(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:827
SCIP_Real SCIPexprhdlrGetIntevalTime(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:721
void SCIPexprhdlrSetEstimate(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRINITESTIMATES((*initestimates)), SCIP_DECL_EXPRESTIMATE((*estimate)))
Definition: expr.c:532
void SCIPexprhdlrSetMonotonicity(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRMONOTONICITY((*monotonicity)))
Definition: expr.c:429
void SCIPexprhdlrSetIntEval(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRINTEVAL((*inteval)))
Definition: expr.c:488
void SCIPexprhdlrSetCurvature(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRCURVATURE((*curvature)))
Definition: expr.c:418
SCIP_Bool SCIPexprhdlrHasEstimate(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:625
SCIP_Real SCIPexprhdlrGetSimplifyTime(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:837
void SCIPexprhdlrSetCompare(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRCOMPARE((*compare)))
Definition: expr.c:462
SCIP_Longint SCIPexprhdlrGetNIntevalCalls(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:711
SCIP_Longint SCIPexprhdlrGetNSimplifications(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:847
SCIP_Longint SCIPexprhdlrGetNCutoffs(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:751
SCIP_Bool SCIPexprhdlrHasIntEval(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:615
void SCIPexprhdlrSetSimplify(SCIP_EXPRHDLR *exprhdlr, SCIP_DECL_EXPRSIMPLIFY((*simplify)))
Definition: expr.c:499
SCIP_Bool SCIPexprhdlrHasBwdiff(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:595
SCIP_Longint SCIPexprhdlrGetNEstimateCalls(SCIP_EXPRHDLR *exprhdlr)
Definition: expr.c:783
void SCIPexprSetActivity(SCIP_EXPR *expr, SCIP_INTERVAL activity, SCIP_Longint activitytag)
Definition: expr.c:4042
void SCIPexprSetData(SCIP_EXPR *expr, SCIP_EXPRDATA *exprdata)
Definition: expr.c:3908
int SCIPexprGetNChildren(SCIP_EXPR *expr)
Definition: expr.c:3860
void SCIPexprGetQuadraticBilinTerm(SCIP_EXPR *expr, int termidx, SCIP_EXPR **expr1, SCIP_EXPR **expr2, SCIP_Real *coef, int *pos2, SCIP_EXPR **prodexpr)
Definition: expr.c:4204
SCIP_Real SCIPgetExponentExprPow(SCIP_EXPR *expr)
Definition: expr_pow.c:3456
SCIP_Bool SCIPexpriterIsEnd(SCIP_EXPRITER *iterator)
Definition: expriter.c:969
void SCIPexprSetCurvature(SCIP_EXPR *expr, SCIP_EXPRCURV curvature)
Definition: expr.c:4068
SCIP_EXPR * SCIPexpriterSkipDFS(SCIP_EXPRITER *iterator)
Definition: expriter.c:930
SCIP_EXPR_OWNERDATA * SCIPexprGetOwnerData(SCIP_EXPR *expr)
Definition: expr.c:3921
SCIP_Real SCIPexprGetDerivative(SCIP_EXPR *expr)
Definition: expr.c:3960
SCIP_Longint SCIPexprGetEvalTag(SCIP_EXPR *expr)
Definition: expr.c:3947
SCIP_Bool SCIPexprIsIntegral(SCIP_EXPR *expr)
Definition: expr.c:4079
SCIP_Bool SCIPexprAreQuadraticExprsVariables(SCIP_EXPR *expr)
Definition: expr.c:4240
void SCIPexprGetQuadraticData(SCIP_EXPR *expr, SCIP_Real *constant, int *nlinexprs, SCIP_EXPR ***linexprs, SCIP_Real **lincoefs, int *nquadexprs, int *nbilinexprs, SCIP_Real **eigenvalues, SCIP_Real **eigenvectors)
Definition: expr.c:4119
SCIP_Real * SCIPgetCoefsExprSum(SCIP_EXPR *expr)
Definition: expr_sum.c:1552
SCIP_EXPRITER_USERDATA SCIPexpriterGetCurrentUserData(SCIP_EXPRITER *iterator)
Definition: expriter.c:756
SCIP_Real SCIPgetCoefExprProduct(SCIP_EXPR *expr)
SCIP_EXPR * SCIPexpriterGetCurrent(SCIP_EXPRITER *iterator)
Definition: expriter.c:683
void SCIPexpriterSetStagesDFS(SCIP_EXPRITER *iterator, SCIP_EXPRITER_STAGE stopstages)
Definition: expriter.c:664
SCIP_Real SCIPexprGetDot(SCIP_EXPR *expr)
Definition: expr.c:3974
SCIP_EXPRDATA * SCIPexprGetData(SCIP_EXPR *expr)
Definition: expr.c:3893
void SCIPexprSetIntegrality(SCIP_EXPR *expr, SCIP_Bool isintegral)
Definition: expr.c:4089
SCIP_RETCODE SCIPprintExpr(SCIP *scip, SCIP_EXPR *expr, FILE *file)
Definition: scip_expr.c:1486
SCIP_EXPRCURV SCIPexprGetCurvature(SCIP_EXPR *expr)
Definition: expr.c:4058
SCIP_EXPR * SCIPexpriterGetParentDFS(SCIP_EXPRITER *iterator)
Definition: expriter.c:740
SCIP_Real SCIPgetValueExprValue(SCIP_EXPR *expr)
Definition: expr_value.c:294
void SCIPexpriterSetCurrentUserData(SCIP_EXPRITER *iterator, SCIP_EXPRITER_USERDATA userdata)
Definition: expriter.c:806
SCIP_Real SCIPexprGetEvalValue(SCIP_EXPR *expr)
Definition: expr.c:3934
SCIP_Longint SCIPexprGetActivityTag(SCIP_EXPR *expr)
Definition: expr.c:4032
SCIP_EXPR * SCIPexpriterGetNext(SCIP_EXPRITER *iterator)
Definition: expriter.c:858
SCIP_Real SCIPexprGetBardot(SCIP_EXPR *expr)
Definition: expr.c:3988
SCIP_EXPR ** SCIPexprGetChildren(SCIP_EXPR *expr)
Definition: expr.c:3870
SCIP_Real SCIPgetConstantExprSum(SCIP_EXPR *expr)
Definition: expr_sum.c:1567
SCIP_VAR * SCIPgetVarExprVar(SCIP_EXPR *expr)
Definition: expr_var.c:416
SCIP_INTERVAL SCIPexprGetActivity(SCIP_EXPR *expr)
Definition: expr.c:4016
void SCIPexprGetQuadraticQuadTerm(SCIP_EXPR *quadexpr, int termidx, SCIP_EXPR **expr, SCIP_Real *lincoef, SCIP_Real *sqrcoef, int *nadjbilin, int **adjbilin, SCIP_EXPR **sqrexpr)
Definition: expr.c:4164
int SCIPexpriterGetChildIdxDFS(SCIP_EXPRITER *iterator)
Definition: expriter.c:707
SCIP_EXPRITER_USERDATA SCIPexpriterGetChildUserDataDFS(SCIP_EXPRITER *iterator)
Definition: expriter.c:771
SCIP_EXPRITER_STAGE SCIPexpriterGetStageDFS(SCIP_EXPRITER *iterator)
Definition: expriter.c:696
SCIP_RETCODE SCIPexpriterInit(SCIP_EXPRITER *iterator, SCIP_EXPR *expr, SCIP_EXPRITER_TYPE type, SCIP_Bool allowrevisit)
Definition: expriter.c:501
int SCIPexprGetNUses(SCIP_EXPR *expr)
Definition: expr.c:3850
SCIP_EXPRITER_USERDATA SCIPexpriterGetExprUserData(SCIP_EXPRITER *iterator, SCIP_EXPR *expr)
Definition: expriter.c:790
SCIP_Longint SCIPexprGetDiffTag(SCIP_EXPR *expr)
Definition: expr.c:4003
SCIP_EXPRHDLR * SCIPexprGetHdlr(SCIP_EXPR *expr)
Definition: expr.c:3883
SCIP_EXPR * SCIPexpriterGetChildExprDFS(SCIP_EXPRITER *iterator)
Definition: expriter.c:721
void SCIPintervalSetEntire(SCIP_Real infinity, SCIP_INTERVAL *resultant)
void SCIPintervalSetEmpty(SCIP_INTERVAL *resultant)
SCIP_Real SCIPvarGetUbLocal(SCIP_VAR *var)
Definition: var.c:18143
const char * SCIPvarGetName(SCIP_VAR *var)
Definition: var.c:17418
SCIP_Real SCIPvarGetLbLocal(SCIP_VAR *var)
Definition: var.c:18133
SCIP_Bool SCIPlapackIsAvailable(void)
Definition: lapack_calls.c:121
SCIP_RETCODE SCIPlapackComputeEigenvalues(BMS_BUFMEM *bufmem, SCIP_Bool geteigenvectors, int N, SCIP_Real *a, SCIP_Real *w)
Definition: lapack_calls.c:352
interface methods for lapack functions
#define BMSduplicateBlockMemoryArray(mem, ptr, source, num)
Definition: memory.h:462
#define BMSfreeBlockMemory(mem, ptr)
Definition: memory.h:465
#define BMSallocBlockMemory(mem, ptr)
Definition: memory.h:451
#define BMSfreeBlockMemoryArrayNull(mem, ptr, num)
Definition: memory.h:468
#define BMSduplicateMemoryArray(ptr, source, num)
Definition: memory.h:143
#define BMSfreeBufferMemoryArray(mem, ptr)
Definition: memory.h:742
#define BMSfreeMemoryArray(ptr)
Definition: memory.h:147
#define BMSallocBlockMemoryArray(mem, ptr, num)
Definition: memory.h:454
#define BMSfreeBlockMemoryArray(mem, ptr, num)
Definition: memory.h:467
#define BMSreallocBlockMemoryArray(mem, ptr, oldnum, newnum)
Definition: memory.h:458
#define BMSallocClearBlockMemoryArray(mem, ptr, num)
Definition: memory.h:455
#define BMSallocBufferMemoryArray(mem, ptr, num)
Definition: memory.h:731
#define BMSallocClearBlockMemory(mem, ptr)
Definition: memory.h:452
#define BMSallocClearBufferMemoryArray(mem, ptr, num)
Definition: memory.h:732
struct BMS_BlkMem BMS_BLKMEM
Definition: memory.h:437
#define BMSfreeMemoryArrayNull(ptr)
Definition: memory.h:148
void SCIPmessageFPrintVerbInfo(SCIP_MESSAGEHDLR *messagehdlr, SCIP_VERBLEVEL verblevel, SCIP_VERBLEVEL msgverblevel, FILE *file, const char *formatstr,...)
Definition: message.c:706
void SCIPmessageFPrintInfo(SCIP_MESSAGEHDLR *messagehdlr, FILE *file, const char *formatstr,...)
Definition: message.c:618
void SCIPmessagePrintWarning(SCIP_MESSAGEHDLR *messagehdlr, const char *formatstr,...)
Definition: message.c:427
public methods for message output
#define SCIPerrorMessage
Definition: pub_message.h:64
#define SCIPdebugMessage
Definition: pub_message.h:96
public data structures and miscellaneous methods
public methods for problem variables
SCIP_Real SCIPsetFloor(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6386
SCIP_EXPRHDLR * SCIPsetFindExprhdlr(SCIP_SET *set, const char *name)
Definition: set.c:5110
SCIP_Real SCIPsetCeil(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6397
SCIP_Bool SCIPsetIsPositive(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6322
SCIP_Real SCIPsetFrac(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6419
SCIP_Bool SCIPsetIsInfinity(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6199
int SCIPsetCalcMemGrowSize(SCIP_SET *set, int num)
Definition: set.c:5764
SCIP_Bool SCIPsetIsNegative(SCIP_SET *set, SCIP_Real val)
Definition: set.c:6333
internal methods for global SCIP settings
#define SCIPsetDebugMsgPrint
Definition: set.h:1785
#define SCIPsetDebugMsg
Definition: set.h:1784
internal methods for storing primal CIP solutions
SCIP_Real dot
Definition: struct_expr.h:126
SCIP_EXPRCURV curvature
Definition: struct_expr.h:138
SCIP_EXPRDATA * exprdata
Definition: struct_expr.h:108
SCIP_Real evalvalue
Definition: struct_expr.h:124
SCIP_INTERVAL activity
Definition: struct_expr.h:134
SCIP_Longint difftag
Definition: struct_expr.h:129
SCIP_EXPRHDLR * exprhdlr
Definition: struct_expr.h:107
SCIP_EXPR_OWNERDATA * ownerdata
Definition: struct_expr.h:118
SCIP_Bool quadchecked
Definition: struct_expr.h:145
SCIP_Longint evaltag
Definition: struct_expr.h:128
SCIP_Longint activitytag
Definition: struct_expr.h:135
int childrensize
Definition: struct_expr.h:111
SCIP_Real derivative
Definition: struct_expr.h:125
SCIP_EXPR ** children
Definition: struct_expr.h:112
SCIP_Real bardot
Definition: struct_expr.h:127
SCIP_QUADEXPR * quaddata
Definition: struct_expr.h:144
int nchildren
Definition: struct_expr.h:110
SCIP_Bool isintegral
Definition: struct_expr.h:141
SCIP_Longint nsimplifycalls
Definition: struct_expr.h:80
SCIP_CLOCK * intevaltime
Definition: struct_expr.h:85
SCIP_Longint npropcalls
Definition: struct_expr.h:77
SCIP_Longint nestimatecalls
Definition: struct_expr.h:75
SCIP_CLOCK * simplifytime
Definition: struct_expr.h:87
unsigned int precedence
Definition: struct_expr.h:48
SCIP_Longint ncutoffs
Definition: struct_expr.h:78
unsigned int ncreated
Definition: struct_expr.h:74
SCIP_Longint nsimplified
Definition: struct_expr.h:81
SCIP_CLOCK * proptime
Definition: struct_expr.h:86
SCIP_Longint ndomreds
Definition: struct_expr.h:79
SCIP_CLOCK * estimatetime
Definition: struct_expr.h:84
SCIP_Longint nintevalcalls
Definition: struct_expr.h:76
SCIP_Longint nbranchscores
Definition: struct_expr.h:82
SCIP_EXPRHDLRDATA * data
Definition: struct_expr.h:47
SCIP_Bool curvaturechecked
Definition: struct_expr.h:166
SCIP_QUADEXPR_QUADTERM * quadexprterms
Definition: struct_expr.h:158
SCIP_Bool eigeninfostored
Definition: struct_expr.h:169
SCIP_Real * lincoefs
Definition: struct_expr.h:155
SCIP_EXPR ** linexprs
Definition: struct_expr.h:154
SCIP_Bool allexprsarevars
Definition: struct_expr.h:163
SCIP_Real constant
Definition: struct_expr.h:151
SCIP_EXPRCURV curvature
Definition: struct_expr.h:165
SCIP_QUADEXPR_BILINTERM * bilinexprterms
Definition: struct_expr.h:161
SCIP_Real * eigenvalues
Definition: struct_expr.h:170
SCIP_Real * eigenvectors
Definition: struct_expr.h:171
SCIP * scip
Definition: struct_set.h:76
SCIP_Longint domchgcount
Definition: struct_stat.h:114
SCIP_Longint exprlastdifftag
Definition: struct_stat.h:128
structure definitions related to algebraic expressions
datastructures for global SCIP settings
datastructures for problem statistics
Definition: heur_padm.c:135
internal methods for branch and bound tree
@ SCIP_CLOCKTYPE_DEFAULT
Definition: type_clock.h:43
#define SCIP_DECL_EXPR_OWNERCREATE(x)
Definition: type_expr.h:143
#define SCIP_DECL_EXPRREVERSEPROP(x)
Definition: type_expr.h:657
#define SCIP_DECL_EXPRINITESTIMATES(x)
Definition: type_expr.h:608
#define SCIP_DECL_EXPRBWFWDIFF(x)
Definition: type_expr.h:520
#define SCIP_DECL_EXPRCURVATURE(x)
Definition: type_expr.h:340
struct SCIP_ExprhdlrData SCIP_EXPRHDLRDATA
Definition: type_expr.h:195
struct SCIP_ExprData SCIP_EXPRDATA
Definition: type_expr.h:54
#define SCIP_EXPRPRINT_EXPRSTRING
Definition: type_expr.h:728
#define SCIP_DECL_EXPRFREEDATA(x)
Definition: type_expr.h:268
SCIP_EXPRCURV
Definition: type_expr.h:61
@ SCIP_EXPRCURV_CONVEX
Definition: type_expr.h:63
@ SCIP_EXPRCURV_UNKNOWN
Definition: type_expr.h:62
@ SCIP_EXPRCURV_CONCAVE
Definition: type_expr.h:64
#define SCIP_EXPR_MAXINITESTIMATES
Definition: type_expr.h:198
#define SCIP_DECL_EXPRPARSE(x)
Definition: type_expr.h:312
#define SCIP_DECL_EXPRBWDIFF(x)
Definition: type_expr.h:449
#define SCIP_DECL_EXPRINTEVAL(x)
Definition: type_expr.h:539
#define SCIP_EXPRPRINT_OWNER
Definition: type_expr.h:735
#define SCIP_EXPRPRINT_ACTIVITYTAG
Definition: type_expr.h:734
#define SCIP_DECL_EXPRMONOTONICITY(x)
Definition: type_expr.h:358
#define SCIP_EXPRITER_VISITINGCHILD
Definition: type_expr.h:693
struct SCIP_Expr_OwnerData SCIP_EXPR_OWNERDATA
Definition: type_expr.h:80
SCIP_MONOTONE
Definition: type_expr.h:70
@ SCIP_MONOTONE_UNKNOWN
Definition: type_expr.h:71
unsigned int SCIP_EXPRPRINT_WHAT
Definition: type_expr.h:740
#define SCIP_DECL_EXPR_INTEVALVAR(x)
Definition: type_expr.h:163
#define SCIP_DECL_EXPRCOMPARE(x)
Definition: type_expr.h:410
#define SCIP_DECL_EXPRSIMPLIFY(x)
Definition: type_expr.h:632
#define SCIP_DECL_EXPREVAL(x)
Definition: type_expr.h:426
#define SCIP_DECL_EXPRFWDIFF(x)
Definition: type_expr.h:480
@ SCIP_EXPRITER_DFS
Definition: type_expr.h:716
#define SCIP_EXPRPRINT_ACTIVITY
Definition: type_expr.h:733
#define SCIP_DECL_EXPRHASH(x)
Definition: type_expr.h:391
#define SCIP_DECL_EXPRCOPYHDLR(x)
Definition: type_expr.h:210
#define SCIP_DECL_EXPRPRINT(x)
Definition: type_expr.h:289
#define SCIP_EXPRPRINT_EVALVALUE
Definition: type_expr.h:731
#define SCIP_DECL_EXPRFREEHDLR(x)
Definition: type_expr.h:224
#define SCIP_DECL_EXPR_MAPEXPR(x)
Definition: type_expr.h:182
#define SCIP_EXPRPRINT_EXPRHDLR
Definition: type_expr.h:729
#define SCIP_EXPRPRINT_EVALTAG
Definition: type_expr.h:732
#define SCIP_DECL_EXPRINTEGRALITY(x)
Definition: type_expr.h:375
#define SCIP_EXPRPRINT_NUSES
Definition: type_expr.h:730
#define SCIP_EXPRITER_VISITEDCHILD
Definition: type_expr.h:694
#define SCIP_DECL_EXPRGETSYMDATA(x)
Definition: type_expr.h:672
struct SCIP_ExprPrintData SCIP_EXPRPRINTDATA
Definition: type_expr.h:741
#define SCIP_DECL_EXPRCOPYDATA(x)
Definition: type_expr.h:249
#define SCIP_EXPRITER_LEAVEEXPR
Definition: type_expr.h:695
#define SCIP_EXPRITER_ALLSTAGES
Definition: type_expr.h:696
#define SCIP_DECL_EXPRESTIMATE(x)
Definition: type_expr.h:575
#define SCIP_EXPRITER_ENTEREXPR
Definition: type_expr.h:692
unsigned int SCIP_EXPRITER_STAGE
Definition: type_expr.h:699
@ SCIP_VERBLEVEL_FULL
Definition: type_message.h:57
@ SCIP_FILECREATEERROR
Definition: type_retcode.h:48
@ SCIP_OKAY
Definition: type_retcode.h:42
enum SCIP_Retcode SCIP_RETCODE
Definition: type_retcode.h:63