cons_knapsack.c
Go to the documentation of this file.
17 * @brief Constraint handler for knapsack constraints of the form \f$a^T x \le b\f$, x binary and \f$a \ge 0\f$.
25 /*---+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8----+----9----+----0----+----1----+----2*/
71 #define CONSHDLR_ENFOPRIORITY -600000 /**< priority of the constraint handler for constraint enforcing */
72 #define CONSHDLR_CHECKPRIORITY -600000 /**< priority of the constraint handler for checking feasibility */
73 #define CONSHDLR_SEPAFREQ 0 /**< frequency for separating cuts; zero means to separate only in the root node */
74 #define CONSHDLR_PROPFREQ 1 /**< frequency for propagating domains; zero means only preprocessing propagation */
75 #define CONSHDLR_EAGERFREQ 100 /**< frequency for using all instead of only the useful constraints in separation,
77 #define CONSHDLR_MAXPREROUNDS -1 /**< maximal number of presolving rounds the constraint handler participates in (-1: no limit) */
78 #define CONSHDLR_DELAYSEPA FALSE /**< should separation method be delayed, if other separators found cuts? */
79 #define CONSHDLR_DELAYPROP FALSE /**< should propagation method be delayed, if other propagators found reductions? */
80 #define CONSHDLR_NEEDSCONS TRUE /**< should the constraint handler be skipped, if no constraints are available? */
93 #define LINCONSUPGD_PRIORITY +100000 /**< priority of the constraint handler for upgrading of linear constraints */
95 #define MAX_USECLIQUES_SIZE 1000 /**< maximal number of items in knapsack where clique information is used */
96 #define MAX_ZEROITEMS_SIZE 10000 /**< maximal number of items to store in the zero list in preprocessing */
98 #define KNAPSACKRELAX_MAXDELTA 0.1 /**< maximal allowed rounding distance for scaling in knapsack relaxation */
99 #define KNAPSACKRELAX_MAXDNOM 1000LL /**< maximal allowed denominator in knapsack rational relaxation */
100 #define KNAPSACKRELAX_MAXSCALE 1000.0 /**< maximal allowed scaling factor in knapsack rational relaxation */
102 #define DEFAULT_SEPACARDFREQ 1 /**< multiplier on separation frequency, how often knapsack cuts are separated */
103 #define DEFAULT_MAXROUNDS 5 /**< maximal number of separation rounds per node (-1: unlimited) */
104 #define DEFAULT_MAXROUNDSROOT -1 /**< maximal number of separation rounds in the root node (-1: unlimited) */
106 #define DEFAULT_MAXSEPACUTSROOT 200 /**< maximal number of cuts separated per separation round in the root node */
107 #define DEFAULT_MAXCARDBOUNDDIST 0.0 /**< maximal relative distance from current node's dual bound to primal bound compared
109 #define DEFAULT_DISAGGREGATION TRUE /**< should disaggregation of knapsack constraints be allowed in preprocessing? */
111 #define DEFAULT_NEGATEDCLIQUE TRUE /**< should negated clique information be used in solving process */
113 #define MAXABSVBCOEF 1e+5 /**< maximal absolute coefficient in variable bounds used for knapsack relaxation */
114 #define USESUPADDLIFT FALSE /**< should lifted minimal cover inequalities using superadditive up-lifting be separated in addition */
116 #define DEFAULT_PRESOLUSEHASHING TRUE /**< should hash table be used for detecting redundant constraints in advance */
117 #define HASHSIZE_KNAPSACKCONS 500 /**< minimal size of hash table in linear constraint tables */
119 #define DEFAULT_PRESOLPAIRWISE TRUE /**< should pairwise constraint comparison be performed in presolving? */
121 #define MINGAINPERNMINCOMPARISONS 1e-06 /**< minimal gain per minimal pairwise presolving comparisons to repeat pairwise
124 #define DEFAULT_DETECTCUTOFFBOUND TRUE /**< should presolving try to detect constraints parallel to the objective
127 #define DEFAULT_DETECTLOWERBOUND TRUE /**< should presolving try to detect constraints parallel to the objective
130 #define DEFAULT_CLIQUEEXTRACTFACTOR 0.5 /**< lower clique size limit for greedy clique extraction algorithm (relative to largest clique) */
131 #define MAXCOVERSIZEITERLEWI 1000 /**< maximal size for which LEWI are iteratively separated by reducing the feasible set */
135 #define GUBSPLITGNC1GUBS FALSE /**< should GNC1 GUB conss without F vars be split into GOC1 and GR GUB conss? */
136 #define DEFAULT_CLQPARTUPDATEFAC 1.5 /**< factor on the growth of global cliques to decide when to update a previous
138 #define DEFAULT_UPDATECLIQUEPARTITIONS FALSE /**< should clique partition information be updated when old partition seems outdated? */
139 #define MAXNCLIQUEVARSCOMP 1000000 /**< limit on number of pairwise comparisons in clique partitioning algorithm */
141 #define DEFAULT_UPGDCARDINALITY FALSE /**< if TRUE then try to update knapsack constraints to cardinality constraints */
144 /* @todo maybe use event SCIP_EVENTTYPE_VARUNLOCKED to decide for another dual-presolving run on a constraint */
157 SCIP_Longint* longints1; /**< cleared memory array, all entries are set to zero in initpre, if you use this
159 SCIP_Longint* longints2; /**< cleared memory array, all entries are set to zero in initpre, if you use this
161 SCIP_Bool* bools1; /**< cleared memory array, all entries are set to zero in initpre, if you use this
163 SCIP_Bool* bools2; /**< cleared memory array, all entries are set to zero in initpre, if you use this
165 SCIP_Bool* bools3; /**< cleared memory array, all entries are set to zero in initpre, if you use this
167 SCIP_Bool* bools4; /**< cleared memory array, all entries are set to zero in initpre, if you use this
169 SCIP_Real* reals1; /**< cleared memory array, all entries are set to zero in consinit, if you use this
181 SCIP_Real maxcardbounddist; /**< maximal relative distance from current node's dual bound to primal bound compared
183 int sepacardfreq; /**< multiplier on separation frequency, how often knapsack cuts are separated */
187 int maxsepacutsroot; /**< maximal number of cuts separated per separation round in the root node */
188 SCIP_Bool disaggregation; /**< should disaggregation of knapsack constraints be allowed in preprocessing? */
189 SCIP_Bool simplifyinequalities;/**< should presolving try to cancel down or delete coefficients in inequalities */
191 SCIP_Bool presolpairwise; /**< should pairwise constraint comparison be performed in presolving? */
192 SCIP_Bool presolusehashing; /**< should hash table be used for detecting redundant constraints in advance */
195 SCIP_Bool detectcutoffbound; /**< should presolving try to detect constraints parallel to the objective
198 SCIP_Bool detectlowerbound; /**< should presolving try to detect constraints parallel to the objective
201 SCIP_Bool updatecliquepartitions; /**< should clique partition information be updated when old partition seems outdated? */
202 SCIP_Real cliqueextractfactor;/**< lower clique size limit for greedy clique extraction algorithm (relative to largest clique) */
203 SCIP_Real clqpartupdatefac; /**< factor on the growth of global cliques to decide when to update a previous
206 SCIP_Bool upgdcardinality; /**< if TRUE then try to update knapsack constraints to cardinality constraints */
207 SCIP_Bool upgradedcard; /**< whether we have already upgraded knapsack constraints to cardinality constraints */
225 int ncliqueslastnegpart;/**< number of global cliques the last time a negated clique partition was computed */
226 int ncliqueslastpart; /**< number of global cliques the last time a clique partition was computed */
230 unsigned int presolvedtiming:5; /**< max level in which the knapsack constraint is already presolved */
235 unsigned int cliquesadded:1; /**< were the cliques of the knapsack already added to clique table? */
266 };
271 {
274 GUBCONSSTATUS_BELONGSTOSET_GF = 1, /** all GUB variables are in noncovervars F (and noncovervars R) */
276 GUBCONSSTATUS_BELONGSTOSET_GNC1 = 3, /** some GUB variables are in covervars C1, others in noncovervars R or F */
278 };
283 {
293 {
300 };
368 assert(consdata->nvars == 0 || (consdata->cliquepartition != NULL && consdata->negcliquepartition != NULL));
387 /* sort all items with same weight according to their variable index, used for hash value for fast pairwise comparison of all constraints */
397 /* sort all corresponding parts of arrays for which the weights are equal by using the variable index */
409 /* we need to make sure that our clique numbers of our normal clique will be in increasing order without gaps */
416 /* if the clique number in the normal clique at position pos is greater than the last found clique number the
427 /* we need to make sure that our clique numbers of our negated clique will be in increasing order without gaps */
434 /* if the clique number in the negated clique at position pos is greater than the last found clique number the
471 assert(consdata->nvars == 0 || (consdata->cliquepartition != NULL && consdata->negcliquepartition != NULL));
475 && SCIPgetNCliques(scip) >= (int)(conshdlrdata->clqpartupdatefac * consdata->ncliqueslastpart));
479 SCIP_CALL( SCIPcalcCliquePartition(scip, consdata->vars, consdata->nvars, consdata->cliquepartition, &consdata->ncliques) );
484 /* rerun eventually if number of global cliques increased considerably since last negated partition */
486 && SCIPgetNCliques(scip) >= (int)(conshdlrdata->clqpartupdatefac * consdata->ncliqueslastnegpart));
490 SCIP_CALL( SCIPcalcNegatedCliquePartition(scip, consdata->vars, consdata->nvars, consdata->negcliquepartition, &consdata->nnegcliques) );
588 assert(consdata->nvars <= consdata->varssize);
596 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &consdata->weights, consdata->varssize, newsize) );
599 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &consdata->eventdata, consdata->varssize, newsize) );
600 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &consdata->cliquepartition, consdata->varssize, newsize) );
601 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &consdata->negcliquepartition, consdata->varssize, newsize) );
646 {
679 if( SCIPisConsCompressionEnabled(scip) && SCIPvarGetLbGlobal(vars[v]) > SCIPvarGetUbGlobal(vars[v]) - 0.5 )
737 SCIP_CALL( SCIPgetTransformedVars(scip, (*consdata)->nvars, (*consdata)->vars, (*consdata)->vars) );
743 (*consdata)->existmultaggr = (*consdata)->existmultaggr || (SCIPvarGetStatus(var) == SCIP_VARSTATUS_MULTAGGR);
748 SCIP_CALL( SCIPallocBlockMemoryArray(scip, &(*consdata)->cliquepartition, (*consdata)->nvars) );
749 SCIP_CALL( SCIPallocBlockMemoryArray(scip, &(*consdata)->negcliquepartition, (*consdata)->nvars) );
866 SCIP_CALL( SCIPcreateEmptyRowCons(scip, &consdata->row, SCIPconsGetHdlr(cons), SCIPconsGetName(cons),
873 SCIP_CALL( SCIPaddVarToRow(scip, consdata->row, consdata->vars[i], (SCIP_Real)consdata->weights[i]) );
905 SCIPdebugMsg(scip, "adding relaxation of knapsack constraint <%s> (capacity %" SCIP_LONGINT_FORMAT "): ",
914 /** checks knapsack constraint for feasibility of given solution: returns TRUE iff constraint is feasible */
920 SCIP_Bool checklprows, /**< Do constraints represented by rows in the current LP have to be checked? */
924 {
932 SCIPdebugMsg(scip, "checking knapsack constraint <%s> for feasibility of solution %p (lprows=%u)\n",
946 /* increase age of constraint; age is reset to zero, if a violation was found only in case we are in
1018 * @note in case you provide the solitems or nonsolitems array you also have to provide the counter part, as well
1025 * @todo If only the objective is relevant, it is easy to change the code to use only one slice with O(capacity) space.
1026 * There are recursive methods (see the book by Kellerer et al.) that require O(capacity) space, but it remains
1028 * Dembo and Hammer (see Kellerer et al. Section 5.1.3, page 126) found a method that relies on a fast probing method.
1334 /* If the greedy solution is optimal by comparing to the LP solution, we take this solution. This happens if:
1336 * - the greedy solution has an objective that is at least the LP value rounded down in case that all profits are integer, too. */
1337 greedyupperbound = greedysolvalue + myprofits[j] * (SCIP_Real) (capacity - greedysolweight)/((SCIP_Real) myweights[j]);
1383 /* this condition checks whether we will try to allocate a correct number of bytes and do not have an overflow, while
1386 if( intcap < 0 || (intcap > 0 && (((size_t)nmyitems) > (SIZE_MAX / (size_t)intcap / sizeof(*optvalues)) || ((size_t)nmyitems) * ((size_t)intcap) * sizeof(*optvalues) > ((size_t)INT_MAX) )) ) /*lint !e571*/
1388 SCIPdebugMsg(scip, "Too much memory (%lu) would be consumed.\n", (unsigned long) (((size_t)nmyitems) * ((size_t)intcap) * sizeof(*optvalues))); /*lint !e571*/
1410 /* we memorize at each step the current minimal weight to later on know which value in our optvalues matrix is valid;
1411 * each value entries of the j-th row of optvalues is valid if the index is >= allcurrminweight[j], otherwise it is
1412 * invalid; a second possibility would be to clear the whole optvalues, which should be more expensive than storing
1440 /* if index d < current minweight then optvalues[IDX(j-1,d)] is not initialized, i.e. should be 0 */
1481 /* collect solution items; the first condition means that no further item can fit anymore, but this does */
1529 /** solves knapsack problem in maximization form approximately by solving the LP-relaxation of the problem using Dantzig's
1530 * method and rounding down the solution; if needed, one can provide arrays to store all selected items and all not
1576 /* partially sort indices such that all elements that are larger than the break item appear first */
1577 SCIPselectWeightedDownRealLongRealInt(tempsort, weights, profits, items, realweights, (SCIP_Real)capacity, nitems, &criticalindex);
1761 /* delete variable from GUB by swapping it replacing in by the last variable in the GUB constraint */
1766 /* decrease space allocated for the GUB constraint, if the last GUBCONSGROWVALUE+1 array entries are now empty */
1782 /** moves variable from current GUB constraint to a different existing (nonempty) GUB constraint */
1792 {
1807 SCIPdebugMsg(scip, " moving variable<%s> from GUB<%d> to GUB<%d>\n", SCIPvarGetName(vars[var]), oldgubcons, newgubcons);
1811 /* delete variable from old GUB constraint by replacing it by the last variable of the GUB constraint */
1814 /* in GUB set, update stored index of variable in old GUB constraint for the variable used for replacement;
1823 assert(gubset->gubconss[newgubcons]->gubvars[gubset->gubconss[newgubcons]->ngubvars-1] == var);
1825 /* in GUB set, update stored index of GUB of moved variable and stored index of variable in this GUB constraint */
1840 /* if empty GUB was not the last one in GUB set data structure, replace it by last GUB constraint */
1846 /* in GUB set, update stored index of GUB constraint for all variable of the GUB constraint used for replacement;
1859 /* variable should be at given new position, unless new GUB constraint replaced empty old GUB constraint
1913 /** initializes partition of knapsack variables into nonoverlapping trivial GUB constraints (GUB with one variable) */
1954 /* already updated status of variable in GUB constraint if it exceeds the capacity of the knapsack */
1956 (*gubset)->gubconss[(*gubset)->gubconssidx[i]]->gubvarsstatus[(*gubset)->gubvarsidx[i]] = GUBVARSTATUS_CAPACITYEXCEEDED;
2017 /* checks for all knapsack vars consistency of stored index of associated gubcons and corresponding index in gubvars */
2025 SCIPdebugMsg(scip, " var<%d> should be in GUB<%d> at position<%d>, but stored is var<%d> instead\n", i,
2062 /* @todo: in case we used also negated cliques for the GUB partition, this assert has to be changed */
2074 * afterwards the output array contains one value for each variable, such that two variables got the same value iff they
2076 * the first variable is always assigned to clique 0, and a variable can only be assigned to clique i if at least one of
2078 * note: in contrast to SCIPcalcCliquePartition(), variables with LP value 1 are put into trivial cliques (with one
2079 * variable) and for the remaining variables, a partition with a small number of cliques is constructed
2085 SCIP_VAR**const vars, /**< binary variables in the clique from which at most one can be set to 1 */
2088 int*const ncliques, /**< pointer to store number of cliques actually contained in the partition */
2091 {
2134 /* ignore variables with LP value 1 (will be assigned to trivial GUBs at the end) and sort remaining variables
2149 /* remaining variables are put to the front of varseq array and will be sorted by their number of cliques */
2157 /* sort variables with LP value less than 1 by nondecreasing order of the number of cliques they are in */
2218 /* if we had too many variables fill up the cliquepartition and put each variable in a separate clique */
2239 /** constructs sophisticated partition of knapsack variables into non-overlapping GUBs; current partition uses trivial GUBs */
2268 SCIP_CALL( GUBsetCalcCliquePartition(scip, vars, nvars, cliquepartition, &ncliques, solvals) );
2291 /* corresponding GUB constraint in GUB set data structure was already constructed (as initial trivial GUB);
2292 * note: no assert for gubconssidx, because it can changed due to deleting empty GUBs in GUBsetMoveVar()
2305 /* move variable to GUB constraint defined by clique partition; index of this GUB constraint is given by the
2309 assert(newgubconsidx != currentgubconsidx); /* because initially every variable is in a different GUB */
2333 /** gets a most violated cover C (\f$\sum_{j \in C} a_j > a_0\f$) for a given knapsack constraint \f$\sum_{j \in N} a_j x_j \leq a_0\f$
2334 * taking into consideration the following fixing: \f$j \in C\f$, if \f$j \in N_1 = \{j \in N : x^*_j = 1\}\f$ and
2351 SCIP_Bool modtransused, /**< should modified transformed separation problem be used to find cover */
2353 SCIP_Bool* fractional /**< pointer to store whether the LP sol for knapsack vars is fractional */
2449 /* sets whether the LP solution x* for the knapsack variables is fractional; if it is not fractional we stop
2518 /* solves (modified) transformed knapsack problem approximately by solving the LP-relaxation of the (modified)
2524 SCIP_CALL( SCIPsolveKnapsackApproximately(scip, nitems, transweights, transprofits, transcapacity, items,
2526 /*assert(checkSolveKnapsack(scip, nitems, transweights, transprofits, items, weights, solvals, modtransused));*/
2577 )
2596 /* checks if all variables before index j cannot be removed, i.e. i cannot be the next minweightidx */
2608 /** gets partition \f$(C_1,C_2)\f$ of minimal cover \f$C\f$, i.e. \f$C_1 \cup C_2 = C\f$ and \f$C_1 \cap C_2 = \emptyset\f$,
2609 * with \f$C_1\f$ not empty; chooses partition as follows \f$C_2 = \{ j \in C : x^*_j = 1 \}\f$ and \f$C_1 = C \setminus C_2\f$
2657 /** changes given partition (C_1,C_2) of minimal cover C, if |C1| = 1, by moving one and two (if possible) variables from
2669 {
2699 /** changes given partition (C_1,C_2) of feasible set C, if |C1| = 1, by moving one variable from C2 to C1 */
2709 {
2737 /** gets partition \f$(F,R)\f$ of \f$N \setminus C\f$ where \f$C\f$ is a minimal cover, i.e. \f$F \cup R = N \setminus C\f$
2738 * and \f$F \cap R = \emptyset\f$; chooses partition as follows \f$R = \{ j \in N \setminus C : x^*_j = 0 \}\f$ and
2786 /** sorts variables in F, C_2, and R according to the second level lifting sequence that will be used in the sequential
2825 * sequence 1: non-increasing absolute difference between x*_j and the value the variable is fixed to, i.e.
2872 /** categorizes GUBs of knapsack GUB partion into GOC1, GNC1, GF, GC2, and GR and computes a lifting sequence of the GUBs
2897 int* ngubconscapexceed, /**< pointer to store number of GUBs with only capacity exceeding variables */
2960 * afterwards all GUBs (except GOC1 GUBs, which we do not need to lift) are sorted by a two level lifting sequence.
2963 * GFC1: non-increasing number of variables in F and non-increasing max{x*_k : k in GFC1_j} in case of equality
2985 * furthermore, sort C1 variables as needed for initializing the minweight table (non-increasing a_j).
3105 /* stores GUBs of group GC1 (GOC1+GNC1) and part of the GUBs of group GFC1 (GNC1 GUBs) and sorts variables in these GUBs
3124 /* current C1 variable is put to the front of its GUB where C1 part is stored by non-decreasing weigth;
3131 /* the GUB was already handled (status set and stored in its group) by another variable of the GUB */
3139 /* determine the status of the current GUB constraint, GOC1 or GNC1; GUBs involving R variables are split into
3163 if( solvals[gubset->gubconss[gubconsidx]->gubvars[j]] > sortkeypairsGFC1[*ngubconsGFC1]->key2 )
3209 assert(movevarstatus == GUBVARSTATUS_BELONGSTOSET_R || movevarstatus == GUBVARSTATUS_CAPACITYEXCEEDED);
3241 /* stores GUBs of group GC2 (only trivial GUBs); sorting is not required because the C2 variables (which we loop over)
3270 /* stores remaining part of the GUBs of group GFC1 (GF GUBs) and gets GUB sorting keys corresp. to following ordering
3285 /* the GUB was already handled (status set and stored in its group) by another variable of the GUB */
3307 if( solvals[gubset->gubconss[gubconsidx]->gubvars[j]] > sortkeypairsGFC1[*ngubconsGFC1]->key2 )
3321 /* stores GUBs of group GR; sorting is not required because the R variables (which we loop over) are already sorted
3335 /* the GUB was already handled (status set and stored in its group) by another variable of the GUB */
3357 /* update number of GUBs with only capacity exceeding variables (will not be used for lifting) */
3358 (*ngubconscapexceed) = ngubconss - (ngubconsGOC1 + (*ngubconsGC2) + (*ngubconsGFC1) + (*ngubconsGR));
3436 * sum_{j in M_1} x_j + sum_{j in F} alpha_j x_j + sum_{j in M_2} alpha_j x_j + sum_{j in R} alpha_j x_j
3440 * uses sequential up-lifting for the variables in F, sequential down-lifting for the variable in M_2, and
3441 * sequential up-lifting for the variables in R; procedure can be used to strengthen minimal cover inequalities and
3504 /* sets lifting coefficient of variables in M1, sorts variables in M1 such that a_1 <= a_2 <= ... <= a_|M1|
3559 * sets z = max { w : 0 <= w <= liftrhs, minweights_i[w] <= a_0 - fixedonesweight - a_{j_i} } = liftrhs,
3567 * uses binary search to find z = max { w : 0 <= w <= liftrhs, minweights_i[w] <= a_0 - fixedonesweight - a_{j_i} }
3575 assert((*liftrhs) + 1 >= minweightslen || minweights[(*liftrhs) + 1] > capacity - fixedonesweight - weight);
3602 /* minweight table and activity of current valid inequality will not change, if alpha_{j_i} = 0 */
3615 SCIP_CALL( enlargeMinweights(scip, &minweights, &minweightslen, &minweightssize, minweightslen + liftcoef) );
3657 * z = max { w : 0 <= w <= |M_1| + sum_{k=1}^{i-1} alpha_{j_k}, minweights_[w] <= a_0 - fixedonesweight + a_{j_i}}
3691 /* minweight table and activity of current valid inequality will not change, if alpha_{j_i} = 0 */
3704 SCIP_CALL( enlargeMinweights(scip, &minweights, &minweightslen, &minweightssize, minweightslen + liftcoef) );
3752 /* uses binary search to find z = max { w : 0 <= w <= liftrhs, minweights_i[w] <= a_0 - a_{j_i} }
3786 /* minweight table and activity of current valid inequality will not change, if alpha_{j_i} = 0 */
3885 * sum_{j in C_1} x_j + sum_{j in F} alpha_j x_j + sum_{j in C_2} alpha_j x_j + sum_{j in R} alpha_j x_j
3888 * S = { x in {0,1}^|N| : sum_{j in N} a_j x_j <= a_0; sum_{j in Q_i} x_j <= 1, forall i in I };
3993 /* gets GOC1 and GNC1 GUBs, sets lifting coefficient of variables in C1 and calculates activity of the current
4023 assert(ngubconsGOC1 + ngubconsGFC1 + ngubconsGC2 + ngubconsGR == ngubconss - ngubconscapexceed);
4026 /* initialize the minweight tables, defined as: for i = 1,...,m with m = |I| and w = 0,...,|gubconsGC1|;
4040 /* initialize finished table; note that variables in GOC1 GUBs (includes C1 and capacity exceeding variables)
4042 * GUBs in the group GCI are sorted by non-decreasing min{ a_k : k in GC1_j } where min{ a_k : k in GC1_j } always
4078 * GUBs in the group GCI are sorted by non-decreasing min{ a_k : k in GC1_j } where min{ a_k : k in GC1_j } always
4114 * we can directly initialize minweights instead of computing it from finished and unfinished (which would be more time
4148 /* gets sum of weights of variables fixed to one, i.e. sum of weights of C2 variables GC2 GUBs */
4171 /* GNC1 GUB: update unfinished table (remove current GUB, i.e., remove min weight of C1 vars in GUB) and
4181 /* get number of C1 variables of current GNC1 GUB and put them into array of variables in GUB that
4189 /* update unfinished table by removing current GNC1 GUB, i.e, remove C1 variable with minimal weight
4190 * unfinished[w] = MAX{unfinished[w], unfinished[w+1] - weight}, "weight" is the minimal weight of current GUB
4212 /* GF GUB: no update of unfinished table (and minweight table) required because GF GUBs have no C1 variables and
4224 /* compute lifting coefficient of F and R variables in GNC1 and GF GUBs (C1 vars have already liftcoef 1) */
4250 * sets z = max { w : 0 <= w <= liftrhs, minweights_i[w] <= a_0 - fixedonesweight - a_{j_i} } = liftrhs,
4258 * binary search to find z = max {w : 0 <= w <= liftrhs, minweights_i[w] <= a_0 - fixedonesweight - a_{j_i}}
4262 assert((*liftrhs) + 1 >= minweightslen || minweights[(*liftrhs) + 1] > capacity - fixedonesweight - weight);
4302 * and finished and minweight table can be updated easily as only C1 variables need to be considered;
4311 * finished[w] = MIN{finished[w], finished[w-1] + weight}, "weight" is the minimal weight of current GUB
4312 * minweights[w] = MIN{minweights[w], minweights[w-1] + weight}, "weight" is the minimal weight of current GUB
4335 * w = |gubconsGC1| + sum_{k=1,2,..,i-1}sum_{j in Q_k} alpha_j+1,..,|C1| + sum_{k=1,2,..,i}sum_{j in Q_k} alpha_j
4343 SCIP_CALL( enlargeMinweights(scip, &minweights, &minweightslen, &minweightssize, minweightslen + sumliftcoef) );
4346 * note that instead of computing minweight table from updated finished and updated unfinished table again
4347 * (for the lifting coefficient, we had to update unfinished table and compute minweight table), we here
4348 * only need to update the minweight table and the updated finished in the same way (i.e., computing for minweight
4349 * not needed because only finished table changed at this point and the change was "adding" one weight)
4394 /* note: now the unfinished table no longer exists, i.e., it is "0, MAX, MAX, ..." and minweight equals to finished;
4408 liftvar = gubset->gubconss[liftgubconsidx]->gubvars[0]; /* C2 GUBs contain only one variable */
4416 * z = max { w : 0 <= w <= |C_1| + sum_{k=1}^{i-1} alpha_{j_k}, minweights_[w] <= a_0 - fixedonesweight + a_{j_i}}
4432 assert(left == minweightslen - 1 || minweights[left + 1] > capacity - fixedonesweight + weight);
4450 /* minweight table and activity of current valid inequality will not change, if alpha_{j_i} = 0 */
4461 * w = |C1| + sum_{k=1,2,...,i-1}sum_{j in Q_k} alpha_j + 1 , ... , |C1| + sum_{k=1,2,...,i}sum_{j in Q_k} alpha_j
4463 SCIP_CALL( enlargeMinweights(scip, &minweights, &minweightslen, &minweightssize, minweightslen + liftcoef) );
4525 /* uses binary search to find z = max { w : 0 <= w <= liftrhs, minweights_i[w] <= a_0 - a_{j_i} }
4565 /* minweight table and activity of current valid inequality will not change if (sum of alpha_{j_i} in GUB) = 0 */
4642 SCIP_Real* liftcoefs, /**< pointer to store lifting coefficient of vars in knapsack constraint */
4678 /* sets lifting coefficient of variables in C, sorts variables in C such that a_1 >= a_2 >= ... >= a_|C|
4756 /** separates lifted minimal cover inequalities using sequential up- and down-lifting and GUB information, if wanted, for
4802 /* gets partition (C_1,C_2) of C, i.e. C_1 & C_2 = C and C_1 cap C_2 = emptyset, with C_1 not empty; chooses partition
4807 getPartitionCovervars(scip, solvals, mincovervars, nmincovervars, varsC1, varsC2, &nvarsC1, &nvarsC2);
4810 assert(nvarsC1 >= 0); /* nvarsC1 > 0 does not always hold, because relaxed knapsack conss may already be violated */
4812 /* changes partition (C_1,C_2) of minimal cover C, if |C1| = 1, by moving one variable from C2 to C1 */
4820 /* gets partition (F,R) of N\C, i.e. F & R = N\C and F cap R = emptyset; chooses partition as follows
4824 getPartitionNoncovervars(scip, solvals, nonmincovervars, nnonmincovervars, varsF, varsR, &nvarsF, &nvarsR);
4831 /* sorts variables in F, C_2, R according to the second level lifting sequence that will be used in the sequential
4834 SCIP_CALL( getLiftingSequence(scip, solvals, weights, varsF, varsC2, varsR, nvarsF, nvarsC2, nvarsR) );
4840 * to a valid inequality sum_{j in C_1} x_j + sum_{j in N\C_1} alpha_j x_j <= |C_1| - 1 + sum_{j in C_2} alpha_j for
4844 * uses sequential up-lifting for the variables in F, sequential down-lifting for the variable in C_2 and sequential
4847 SCIP_CALL( sequentialUpAndDownLifting(scip, vars, nvars, ntightened, weights, capacity, solvals, varsC1, varsC2,
4881 /* categorizies GUBs of knapsack GUB partion into GOC1, GNC1, GF, GC2, and GR and computes a lifting sequence of
4884 SCIP_CALL( getLiftingSequenceGUB(scip, gubset, solvals, weights, varsC1, varsC2, varsF, varsR, nvarsC1,
4885 nvarsC2, nvarsF, nvarsR, gubconsGC1, gubconsGC2, gubconsGFC1, gubconsGR, &ngubconsGC1, &ngubconsGC2,
4893 * to a valid inequality sum_{j in C_1} x_j + sum_{j in N\C_1} alpha_j x_j <= |C_1| - 1 + sum_{j in C_2} alpha_j for
4895 * S = { x in {0,1}^|N| : sum_{j in N} a_j x_j <= a_0, sum_{j in Q_i} x_j <= 1, forall i in I },
4901 SCIP_CALL( sequentialUpAndDownLiftingGUB(scip, gubset, vars, nconstightened, weights, capacity, solvals, gubconsGC1,
4923 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_mcseq%" SCIP_LONGINT_FORMAT "", SCIPconsGetName(cons), SCIPconshdlrGetNCutsFound(SCIPconsGetHdlr(cons)));
4924 SCIP_CALL( SCIPcreateEmptyRowCons(scip, &row, SCIPconsGetHdlr(cons), name, -SCIPinfinity(scip), (SCIP_Real)liftrhs,
4930 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_mcseq_%" SCIP_LONGINT_FORMAT "", SCIPsepaGetName(sepa), SCIPsepaGetNCutsFound(sepa));
4931 SCIP_CALL( SCIPcreateEmptyRowSepa(scip, &row, sepa, name, -SCIPinfinity(scip), (SCIP_Real)liftrhs, FALSE, FALSE, TRUE) );
4936 SCIP_CALL( SCIPcreateEmptyRowUnspec(scip, &row, name, -SCIPinfinity(scip), (SCIP_Real)liftrhs, FALSE, FALSE, TRUE) );
4939 /* adds all variables in the knapsack constraint with calculated lifting coefficient to the cut */
4992 /** separates lifted extended weight inequalities using sequential up- and down-lifting for given knapsack problem */
5036 /* gets partition (T_1,T_2) of T, i.e. T_1 & T_2 = T and T_1 cap T_2 = emptyset, with T_1 not empty; chooses partition
5041 getPartitionCovervars(scip, solvals, feassetvars, nfeassetvars, varsT1, varsT2, &nvarsT1, &nvarsT2);
5044 /* changes partition (T_1,T_2) of feasible set T, if |T1| = 0, by moving one variable from T2 to T1 */
5047 SCIP_CALL( changePartitionFeasiblesetvars(scip, weights, varsT1, varsT2, &nvarsT1, &nvarsT2) );
5052 /* gets partition (F,R) of N\T, i.e. F & R = N\T and F cap R = emptyset; chooses partition as follows
5056 getPartitionNoncovervars(scip, solvals, nonfeassetvars, nnonfeassetvars, varsF, varsR, &nvarsF, &nvarsR);
5060 /* sorts variables in F, T_2, and R according to the second level lifting sequence that will be used in the sequential
5061 * lifting procedure (the variable removed last from the initial cover does not have to be lifted first, therefore it
5064 SCIP_CALL( getLiftingSequence(scip, solvals, weights, varsF, varsT2, varsR, nvarsF, nvarsT2, nvarsR) );
5070 * to a valid inequality sum_{j in T_1} x_j + sum_{j in N\T_1} alpha_j x_j <= |T_1| + sum_{j in T_2} alpha_j for
5074 * uses sequential up-lifting for the variables in F, sequential down-lifting for the variable in T_2 and sequential
5077 SCIP_CALL( sequentialUpAndDownLifting(scip, vars, nvars, ntightened, weights, capacity, solvals, varsT1, varsT2, varsF, varsR,
5090 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_ewseq%" SCIP_LONGINT_FORMAT "", SCIPconsGetName(cons), SCIPconshdlrGetNCutsFound(SCIPconsGetHdlr(cons)));
5091 SCIP_CALL( SCIPcreateEmptyRowCons(scip, &row, SCIPconsGetHdlr(cons), name, -SCIPinfinity(scip), (SCIP_Real)liftrhs,
5097 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_ewseq_%" SCIP_LONGINT_FORMAT "", SCIPsepaGetName(sepa), SCIPsepaGetNCutsFound(sepa));
5098 SCIP_CALL( SCIPcreateEmptyRowSepa(scip, &row, sepa, name, -SCIPinfinity(scip), (SCIP_Real)liftrhs, FALSE, FALSE, TRUE) );
5103 SCIP_CALL( SCIPcreateEmptyRowUnspec(scip, &row, name, -SCIPinfinity(scip), (SCIP_Real)liftrhs, FALSE, FALSE, TRUE) );
5106 /* adds all variables in the knapsack constraint with calculated lifting coefficient to the cut */
5159 /** separates lifted minimal cover inequalities using superadditive up-lifting for given knapsack problem */
5202 SCIP_CALL( superadditiveUpLifting(scip, vars, nvars, ntightened, weights, capacity, solvals, mincovervars,
5217 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_mcsup%" SCIP_LONGINT_FORMAT "", SCIPconsGetName(cons), SCIPconshdlrGetNCutsFound(SCIPconsGetHdlr(cons)));
5218 SCIP_CALL( SCIPcreateEmptyRowCons(scip, &row, SCIPconsGetHdlr(cons), name, -SCIPinfinity(scip), (SCIP_Real)liftrhs,
5224 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_mcsup%" SCIP_LONGINT_FORMAT "", SCIPsepaGetName(sepa), SCIPsepaGetNCutsFound(sepa));
5225 SCIP_CALL( SCIPcreateEmptyRowSepa(scip, &row, sepa, name, -SCIPinfinity(scip), (SCIP_Real)liftrhs, FALSE, FALSE, TRUE) );
5230 SCIP_CALL( SCIPcreateEmptyRowUnspec(scip, &row, name, -SCIPinfinity(scip), (SCIP_Real)liftrhs, FALSE, FALSE, TRUE) );
5233 /* adds all variables in the knapsack constraint with calculated lifting coefficient to the cut */
5245 SCIP_CALL( SCIPaddVarToRow(scip, row, vars[nonmincovervars[j]], realliftcoefs[nonmincovervars[j]]) );
5269 /** converts given cover C to a minimal cover by removing variables in the reverse order in which the variables were chosen
5270 * to be in C, i.e. in the order of non-increasing (1 - x*_j)/a_j, if the transformed separation problem was used to find
5271 * C and in the order of non-increasing (1 - x*_j), if the modified transformed separation problem was used to find C;
5307 /* allocates temporary memory; we need two arrays for the keypairs in order to be able to free them in the correct
5314 * such that (1 - x*_1)/a_1 >= ... >= (1 - x*_|C|)/a_|C|, if trans separation problem was used to find C
5315 * such that (1 - x*_1) >= ... >= (1 - x*_|C|), if modified trans separation problem was used to find C
5316 * note that all variables with x*_j = 1 are in the end of the sorted C, so they will be removed last from C
5362 assert(checkMinweightidx(weights, capacity, covervars, *ncovervars, *coverweight, minweightidx, j));
5416 /** converts given initial cover C_init to a feasible set by removing variables in the reverse order in which
5419 * non-increasing (1 - x*_j), if modified transformed separation problem was used to find C_init.
5420 * separates lifted extended weight inequalities using sequential up- and down-lifting for this feasible set
5468 * such that (1 - x*_1)/a_1 >= ... >= (1 - x*_|C|)/a_|C|, if trans separation problem was used to find C
5469 * such that (1 - x*_1) >= ... >= (1 - x*_|C|), if modified trans separation problem was used to find C
5470 * note that all variables with x*_j = 1 are in the end of the sorted C, so they will be removed last from C
5490 /* removes variables from C_init and separates lifted extended weight inequalities using sequential up- and down-lifting;
5507 SCIP_CALL( separateSequLiftedExtendedWeightInequality(scip, cons, sepa, vars, nvars, ntightened, weights, capacity, solvals,
5584 SCIPdebugMsgPrint(scip, "%+" SCIP_LONGINT_FORMAT "<%s>(%g)", weights[i], SCIPvarGetName(vars[i]), solvals[i]);
5590 /* LMCI1 (lifted minimal cover inequalities using sequential up- and down-lifting) using GUB information
5612 SCIP_CALL( getCover(scip, vars, nvars, weights, capacity, solvals, covervars, noncovervars, &ncovervars,
5631 /* converts initial cover C_init to a minimal cover C by removing variables in the reverse order in which the
5632 * variables were chosen to be in C_init; note that variables with x*_j = 1 will be removed last
5634 SCIP_CALL( makeCoverMinimal(scip, weights, capacity, solvals, covervars, noncovervars, &ncovervars,
5637 /* only separate with GUB information if we have at least one nontrivial GUB (with more than one variable) */
5640 /* separates lifted minimal cover inequalities using sequential up- and down-lifting and GUB information */
5641 SCIP_CALL( separateSequLiftedMinimalCoverInequality(scip, cons, sepa, vars, nvars, ntightened, weights, capacity,
5646 /* separates lifted minimal cover inequalities using sequential up- and down-lifting, but do not use trivial
5649 SCIP_CALL( separateSequLiftedMinimalCoverInequality(scip, cons, sepa, vars, nvars, ntightened, weights, capacity,
5671 SCIP_CALL( getCover(scip, vars, nvars, weights, capacity, solvals, covervars, noncovervars, &ncovervars,
5682 /* converts initial cover C_init to a minimal cover C by removing variables in the reverse order in which the
5683 * variables were chosen to be in C_init; note that variables with x*_j = 1 will be removed last
5685 SCIP_CALL( makeCoverMinimal(scip, weights, capacity, solvals, covervars, noncovervars, &ncovervars,
5689 SCIP_CALL( separateSequLiftedMinimalCoverInequality(scip, cons, sepa, vars, nvars, ntightened, weights, capacity,
5696 SCIP_CALL( separateSupLiftedMinimalCoverInequality(scip, cons, sepa, vars, nvars, ntightened, weights, capacity,
5697 solvals, covervars, noncovervars, ncovervars, nnoncovervars, coverweight, sol, cutoff, ncuts) );
5713 SCIP_CALL( getCover(scip, vars, nvars, weights, capacity, solvals, covervars, noncovervars, &ncovervars,
5721 /* converts initial cover C_init to a feasible set by removing variables in the reverse order in which
5722 * they were chosen to be in C_init and separates lifted extended weight inequalities using sequential
5725 SCIP_CALL( getFeasibleSet(scip, cons, sepa, vars, nvars, ntightened, weights, capacity, solvals, covervars, noncovervars,
5739 /* relaxes given general linear constraint into a knapsack constraint and separates lifted knapsack cover inequalities */
5746 SCIP_Real* knapvals, /**< coefficients of the variables in the continuous knapsack constraint */
5747 SCIP_Real valscale, /**< -1.0 if lhs of row is used as rhs of c. k. constraint, +1.0 otherwise */
5779 SCIPdebugMsg(scip, "separate linear constraint <%s> relaxed to knapsack\n", cons != NULL ? SCIPconsGetName(cons) : "-");
5784 /* all variables which are of integral type can be potentially of binary type; this can be checked via the method SCIPvarIsBinary(var) */
5815 /* increase array size to avoid an endless loop in the next block; this might happen if continuous variables
5820 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->reals1, conshdlrdata->reals1size, 1) );
5827 /* next if condition should normally not be true, because it means that presolving has created more binary
5828 * variables than binary + integer variables existed at the constraint initialization method, but for example if you would
5836 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->reals1, oldsize, conshdlrdata->reals1size) );
5837 BMSclearMemoryArray(&(conshdlrdata->reals1[oldsize]), conshdlrdata->reals1size - oldsize); /*lint !e866 */
5855 * - a_j < 0: x_j = lb or x_j = b*z + d with variable lower bound b*z + d with binary variable z
5856 * - a_j > 0: x_j = ub or x_j = b*z + d with variable upper bound b*z + d with binary variable z
5893 SCIPdebugMsg(scip, " -> binary variable %+.15g<%s>(%.15g)\n", valscale * knapvals[i], SCIPvarGetName(var), SCIPgetSolVal(scip, sol, var));
5921 if( (bvlb[j] >= 0.0 && SCIPisGT(scip, bvlb[j] * SCIPvarGetLbLocal(zvlb[j]) + dvlb[j], SCIPvarGetUbLocal(var))) ||
5922 (bvlb[j] <= 0.0 && SCIPisGT(scip, bvlb[j] * SCIPvarGetUbLocal(zvlb[j]) + dvlb[j], SCIPvarGetUbLocal(var))) )
5927 bvlb[j], SCIPvarGetName(zvlb[j]), SCIPvarGetLbLocal(zvlb[j]), SCIPvarGetUbLocal(zvlb[j]), dvlb[j]);
5948 SCIPdebugMsg(scip, " -> non-binary variable %+.15g<%s>(%.15g) replaced with lower bound %.15g (rhs=%.15g)\n",
5949 valscale * knapvals[i], SCIPvarGetName(var), SCIPgetSolVal(scip, sol, var), SCIPvarGetLbGlobal(var), rhs);
5953 assert(0 <= SCIPvarGetProbindex(zvlb[bestlbtype]) && SCIPvarGetProbindex(zvlb[bestlbtype]) < nbinvars);
5967 SCIPdebugMsg(scip, " -> non-binary variable %+.15g<%s>(%.15g) replaced with variable lower bound %+.15g<%s>(%.15g) %+.15g (rhs=%.15g)\n",
6001 if( (bvub[j] >= 0.0 && SCIPisLT(scip, bvub[j] * SCIPvarGetUbLocal(zvub[j]) + dvub[j], SCIPvarGetLbLocal(var))) ||
6002 (bvub[j] <= 0.0 && SCIPisLT(scip, bvub[j] * SCIPvarGetLbLocal(zvub[j]) + dvub[j], SCIPvarGetLbLocal(var))) )
6007 bvub[j], SCIPvarGetName(zvub[j]), SCIPvarGetLbLocal(zvub[j]), SCIPvarGetUbLocal(zvub[j]), dvub[j]);
6028 SCIPdebugMsg(scip, " -> non-binary variable %+.15g<%s>(%.15g) replaced with upper bound %.15g (rhs=%.15g)\n",
6029 valscale * knapvals[i], SCIPvarGetName(var), SCIPgetSolVal(scip, sol, var), SCIPvarGetUbGlobal(var), rhs);
6033 assert(0 <= SCIPvarGetProbindex(zvub[bestubtype]) && SCIPvarGetProbindex(zvub[bestubtype]) < nbinvars);
6047 SCIPdebugMsg(scip, " -> non-binary variable %+.15g<%s>(%.15g) replaced with variable upper bound %+.15g<%s>(%.15g) %+.15g (rhs=%.15g)\n",
6061 /* calculate scalar which makes all coefficients integral in relative allowed difference in between
6064 SCIP_CALL( SCIPcalcIntegralScalar(binvals, nbinvars, -SCIPepsilon(scip), KNAPSACKRELAX_MAXDELTA,
6068 /* if coefficients cannot be made integral, we have to use a scalar of 1.0 and only round fractional coefficients down */
6093 SCIPdebugMsg(scip, " -> positive scaled binary variable %+" SCIP_LONGINT_FORMAT "<%s> (unscaled %.15g): not changed (rhs=%.15g)\n",
6103 SCIPdebugMsg(scip, " -> negative scaled binary variable %+" SCIP_LONGINT_FORMAT "<%s> (unscaled %.15g): substituted by (1 - <%s>) (rhs=%.15g)\n",
6128 SCIPdebugMsg(scip, " -> linear constraint <%s> relaxed to knapsack:", cons != NULL ? SCIPconsGetName(cons) : "-");
6132 SCIPdebugMsgPrint(scip, " %+" SCIP_LONGINT_FORMAT "<%s>(%.15g)", consvals[i], SCIPvarGetName(consvars[i]),
6136 SCIPdebugMsgPrint(scip, " <= %" SCIP_LONGINT_FORMAT " (%.15g) [act: %.15g, min: %" SCIP_LONGINT_FORMAT " max: %" SCIP_LONGINT_FORMAT "]\n",
6151 SCIP_CALL( SCIPseparateKnapsackCuts(scip, cons, sepa, consvars, nconsvars, consvals, capacity, sol, usegubs, cutoff, ncuts) );
6187 )
6212 SCIP_CALL( SCIPseparateKnapsackCuts(scip, cons, NULL, consdata->vars, consdata->nvars, consdata->weights,
6255 SCIP_CALL( consdataEnsureVarsSize(scip, consdata, consdata->nvars+1, SCIPconsIsTransformed(cons)) );
6278 if( !consdata->existmultaggr && SCIPvarGetStatus(SCIPvarGetProbvar(var)) == SCIP_VARSTATUS_MULTAGGR )
6359 /* if the clique number is equal to the number of variables we have only cliques with one element, so we don't
6370 consdata->cliquepartitioned = FALSE; /* recalculate the clique partition after a coefficient was removed */
6376 /* if the old clique number was greater than the new one we have to check that before a bigger clique number
6385 consdata->cliquepartitioned = FALSE; /* recalculate the clique partition after a coefficient was removed */
6388 /* if we reached the end in the for loop, it means we have deleted the last element of the clique with
6394 /* if the old clique number was smaller than the new one we have to check the front for an element with
6399 for( i = pos - 1; i >= 0 && i >= cliquenumbefore && consdata->cliquepartition[i] < cliquenumbefore; --i ); /*lint !e722*/
6402 consdata->cliquepartitioned = FALSE; /* recalculate the clique partition after a coefficient was removed */
6404 /* if we deleted the last element of the clique with biggest index, we have to decrease the clique number */
6408 for( i = pos - 1; i >= 0 && i >= cliquenumbefore && consdata->cliquepartition[i] < cliquenumbefore; --i ); /*lint !e722*/
6423 /* if the clique number is equal to the number of variables we have only cliques with one element, so we don't
6434 consdata->negcliquepartitioned = FALSE; /* recalculate the clique partition after a coefficient was removed */
6440 /* if the old clique number was greater than the new one we have to check that, before a bigger clique number
6449 consdata->negcliquepartitioned = FALSE; /* recalculate the negated clique partition after a coefficient was removed */
6452 /* if we reached the end in the for loop, it means we have deleted the last element of the clique with
6458 /* if the old clique number was smaller than the new one we have to check the front for an element with
6463 for( i = pos - 1; i >= 0 && i >= cliquenumbefore && consdata->negcliquepartition[i] < cliquenumbefore; --i ); /*lint !e722*/
6466 consdata->negcliquepartitioned = FALSE; /* recalculate the negated clique partition after a coefficient was removed */
6468 /* if we deleted the last element of the clique with biggest index, we have to decrease the clique number */
6472 for( i = pos - 1; i >= 0 && i >= cliquenumbefore && consdata->negcliquepartition[i] < cliquenumbefore; --i ); /*lint !e722*/
6477 /* otherwise if the old clique number is equal to the new one the cliquepartition should be ok */
6588 SCIPsortPtrPtrLongIntInt((void**)consdata->vars, (void**)consdata->eventdata, consdata->weights,
6589 consdata->cliquepartition, consdata->negcliquepartition, SCIPvarCompActiveAndNegated, consdata->nvars);
6636 /* variables var1 and var2 are opposite: subtract smaller weight from larger weight, reduce capacity,
6643 SCIP_CALL( delCoefPos(scip, cons, v) ); /* this does not affect var2, because var2 stands before var1 */
6653 SCIP_CALL( delCoefPos(scip, cons, v) ); /* this does not affect var2, because var2 stands before var1 */
6664 assert(prev == 0 || ((prev > 0) && (SCIPvarIsActive(consdata->vars[prev - 1]) || SCIPvarGetStatus(consdata->vars[prev - 1]) == SCIP_VARSTATUS_NEGATED)) );
6665 /* either that was the last pair or both, the negated and "normal" variable in front doesn't match var1, so the order is irrelevant */
6666 if( prev == 0 || (var1 != consdata->vars[prev - 1] && var1 != SCIPvarGetNegatedVar(consdata->vars[prev - 1])) )
6696 /** in case the knapsack constraint is independent of every else, solve the knapsack problem (exactly) and apply the
6725 /* constraints for which the check flag is set to FALSE, did not contribute to the lock numbers; therefore, we cannot
6726 * use the locks to decide for a dual reduction using this constraint; for example after a restart the cuts which are
6745 /* check if we can apply the dual reduction; this can be done if the knapsack has the only locks on this constraint;
6786 SCIPdebugMsg(scip, "the knapsack constraint <%s> is independent to rest of the problem\n", SCIPconsGetName(cons));
6790 SCIP_CALL( SCIPsolveKnapsackExactly(scip, consdata->nvars, consdata->weights, profits, consdata->capacity,
6803 SCIPdebugMsg(scip, "variable <%s> only locked up in knapsack constraints: dual presolve <%s>[%.15g,%.15g] >= 1.0\n",
6816 SCIPdebugMsg(scip, "variable <%s> has no down locks: dual presolve <%s>[%.15g,%.15g] <= 0.0\n",
6838 /** check if the knapsack constraint is parallel to objective function; if so update the cutoff bound and avoid that the
6870 /* check if the knapsack constraints has the same number of variables as the objective function and if the initial
6876 /* There are no variables in the ojective function and in the constraint. Thus, the constraint is redundant. Since we
6904 /* if a variable has a zero objective coefficient the knapsack constraint is not parallel to objective function */
6943 /* avoid that the knapsack constraint enters the LP since it is parallel to the objective function */
6949 /* increase the cutoff bound value by an epsilon to ensue that solution with the value of the cutoff bound are
6954 SCIPdebugMsg(scip, "constraint <%s> is parallel to objective function and provids a cutoff bound <%g>\n",
6965 /* in case the cutoff bound is worse then currently known one we avoid additionaly enforcement and
6976 /* avoid that the knapsack constraint enters the LP since it is parallel to the objective function */
6982 SCIPdebugMsg(scip, "constraint <%s> is parallel to objective function and provids a lower bound <%g>\n",
6992 /** sort the variables and weights w.r.t. the clique partition; thereby ensure the current order of the variables when a
6993 * weight of one variable is greater or equal another weight and both variables are in the same cliques */
7003 {
7076 /* to reach the goal that all variables of each clique will be standing next to each other we will initialize the
7077 * starting pointers for each clique by adding the number of each clique to the last clique starting pointer
7078 * e.g. clique1 has 4 elements and clique2 has 3 elements the the starting pointer for clique1 will be the pointer
7079 * to vars[0], the starting pointer to clique2 will be the pointer to vars[4] and to clique3 it will be
7117 /** deletes all fixed variables from knapsack constraint, and replaces variables with binary representatives */
7204 /* @todo maybe resolve the problem that the eliminating of the multi-aggregation leads to a non-knapsack
7205 * constraint (converting into a linear constraint), for example the multi-aggregation consist of a non-binary
7206 * variable or due to resolving now their are non-integral coefficients or a non-integral capacity
7214 * 1b) If repvar is a negated variable of a multi-aggregated variable weight * repvar should be replaced by
7215 * weight - weight * (a_1*y_1 + ... + a_n*y_n + c), for better further use here we switch the sign of weight
7218 * 2a) weight * a_i < 0 than we add -weight * a_i * y_i_neg to the constraint and adjust the capacity through
7222 * 3b) If repvar was negated we need to subtract weight * (c - 1) from capacity(note we switched the sign of
7242 SCIPerrorMessage("try to resolve a multi-aggregation with a non-integral value for weight*aggrconst = %g\n", weight*aggrconst);
7257 SCIPerrorMessage("try to resolve a multi-aggregation with a non-binary variable <%s>\n", aggrvars[i]);
7262 SCIPerrorMessage("try to resolve a multi-aggregation with a non-integral value for weight*aggrscalars = %g\n", weight*aggrscalars[i]);
7265 /* if the new coefficient is smaller than zero, we need to add the negated variable instead and adjust the capacity */
7270 SCIP_CALL( addCoef(scip, cons, negvar, (SCIP_Longint)(SCIPfloor(scip, -weight * aggrscalars[i] + 0.5))) );
7275 SCIP_CALL( addCoef(scip, cons, aggrvars[i], (SCIP_Longint)(SCIPfloor(scip, weight * aggrscalars[i] + 0.5))) );
7281 /* adjust the capacity with the aggregation constant and if necessary the extra weight through the negation */
7314 /* if aggregated variables have been replaced, multiple entries of the same variable are possible and we have to
7338 {
7372 /* increase age of constraint; age is reset to zero, if a conflict or a propagation was found */
7382 assert(SCIPvarIsActive(consdata->vars[i]) || SCIPvarIsNegated(consdata->vars[i]) || SCIPvarGetStatus(consdata->vars[i]) == SCIP_VARSTATUS_FIXED);
7404 * - minweightsum = sum_{negated cliques C} ( sum(wi : i \in C) - W_max(C) ), where W_max(C) is the maximal weight of C
7406 * if for i \in C (a negated clique) oneweightsum + minweightsum - wi + W_max(C) > capacity => xi = 1
7438 /* save the end positions of the cliques because start positions are moved in the following loop */
7463 /* for summing up the minimum active weights due to cliques we have to omit the biggest weights of each
7464 * clique, we can only skip this clique if this variables is not fixed to zero, otherwise we have to fix all
7509 /* we found a fixed variable to zero so all other variables in this negated clique have to be fixed to one */
7518 SCIPdebugMsg(scip, " -> fixing variable <%s> to 1, due to negated clique information\n", SCIPvarGetName(myvars[v]));
7519 SCIP_CALL( SCIPinferBinvarCons(scip, myvars[v], TRUE, cons, SCIPvarGetIndex(myvars[i]), &infeasible, &tightened) );
7552 /* reset local minweightsum for clique because all fixed to one variables are now counted in consdata->onesweightsum */
7563 SCIPdebugMsg(scip, "knapsack constraint <%s> has minimum weight sum of <%" SCIP_LONGINT_FORMAT ">\n",
7590 /* no need to process this negated clique because all variables are already fixed (which we detect from a fixed maxvar) */
7596 /* if the sum of all weights of fixed variables to one plus the minimalweightsum (minimal weight which is already
7597 * used in this knapsack due to negated cliques) plus any weight minus the second largest weight in this clique
7600 if( consdata->onesweightsum + minweightsum + (maxcliqueweight - secondmaxweights[c]) > consdata->capacity )
7610 SCIP_CALL( SCIPinferBinvarCons(scip, maxvar, FALSE, cons, cliquestartposs[c], &infeasible, &tightened) );
7624 * the gain in any of the following negated cliques (the additional term if the maximum weight variable was set to 1, and the second
7627 * - the cliques are sorted by decreasing maximum weight -> for all c' >= c: maxweights[c'] <= maxcliqueweight
7630 else if( consdata->onesweightsum + minweightsum + (maxcliqueweight - consdata->weights[nvars - 1]) <= consdata->capacity )
7636 /* there should be no variable fixed to 0 between startvarposclique + 1 and endvarposclique unless we
7652 if( maxvarfixed || consdata->onesweightsum + minweightsum - myweights[i] + maxcliqueweight > consdata->capacity )
7657 SCIPdebugMsg(scip, " -> fixing variable <%s> to 1, due to negated clique information\n", SCIPvarGetName(myvars[i]));
7680 SCIP_Bool exceedscapacity = consdata->onesweightsum + minweightsum - myweights[i] + maxcliqueweight > consdata->capacity;
7703 SCIPdebugMsg(scip, " -> cutoff - fixed weight: %" SCIP_LONGINT_FORMAT ", capacity: %" SCIP_LONGINT_FORMAT " \n",
7710 if( (SCIPgetStage(scip) == SCIP_STAGE_SOLVING || SCIPinProbing(scip)) && SCIPisConflictAnalysisApplicable(scip) )
7712 /* start conflict analysis with the fixed-to-one variables, add only as many as needed to exceed the capacity */
7743 /* if all weights of fixed variables to one plus any weight exceeds the capacity the variables have to be fixed
7753 SCIP_CALL( SCIPinferBinvarCons(scip, consdata->vars[i], FALSE, cons, i, &infeasible, &tightened) );
7767 /* sum up the weights of all unfixed variables, plus the weight sum of all variables fixed to one already */
7779 /* we summed up all (unfixed and fixed to one) weights and did not exceed the capacity, so the constraint is redundant */
7780 SCIPdebugMsg(scip, " -> knapsack constraint <%s> is redundant: weightsum=%" SCIP_LONGINT_FORMAT ", unfixedweightsum=%" SCIP_LONGINT_FORMAT ", capacity=%" SCIP_LONGINT_FORMAT "\n",
7789 /** all but one variable fit into the knapsack constraint, so we can upgrade this constraint to an logicor constraint
7812 /* if the knapsack constraint consists only of two variables, we can upgrade it to a set-packing constraint */
7815 SCIPdebugMsg(scip, "upgrading knapsack constraint <%s> to a set-packing constraint", SCIPconsGetName(cons));
7817 SCIP_CALL( SCIPcreateConsSetpack(scip, &newcons, SCIPconsGetName(cons), consdata->nvars, consdata->vars,
7823 /* if the knapsack constraint consists of at least three variables, we can upgrade it to a logicor constraint
7830 SCIPdebugMsg(scip, "upgrading knapsack constraint <%s> to a logicor constraint", SCIPconsGetName(cons));
7835 SCIP_CALL( SCIPcreateConsLogicor(scip, &newcons, SCIPconsGetName(cons), consdata->nvars, consvars,
7856 * i.e. 5x1 + 5x2 + 5x3 + 2x4 + 1x5 <= 13 => x4, x5 always fits into the knapsack, so we can delete them
7858 * i.e. 5x1 + 5x2 + 5x3 + 2x4 + 1x5 <= 8 and we have the cliqueinformation (x1,x2,x3) is a clique
7861 * i.e. 5x1 + 5x2 + 5x3 + 1x4 + 1x5 <= 6 and we have the cliqueinformation (x1,x2,x3) is a clique and (x4,x5) too
7868 SCIP_Longint frontsum, /**< sum of front items which fit if we try to take from the first till the last */
7904 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal
7921 /* all rear items are redundant, because leaving one item in front and incl. of splitpos out the rear itmes always
7957 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal
7965 /* rear items can only be redundant, when the sum is smaller to the weight at splitpos and all rear items would
7966 * always fit into the knapsack, therefor the item directly after splitpos needs to be smaller than the one at
7980 SCIP_CALL( SCIPcalcCliquePartition(scip, &(consdata->vars[splitpos+1]), len, clqpart, &nclq) );
8002 /* all rear items are redundant due to clique information, if maxactduetoclq is smaller than the weight before,
8003 * so delete them and create for all clique the corresponding clique constraints and update the capacity
8013 SCIPdebugMsg(scip, "Found redundant variables in constraint <%s> due to clique information.\n", SCIPconsGetName(cons));
8030 /* we found a real clique so extract this constraint, because we do not know who this information generated so */
8036 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_clq_%" SCIP_LONGINT_FORMAT "_%d", SCIPconsGetName(cons), capacity, c);
8088 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal
8107 * i.e. 5x1 + 5x2 + 5x3 + 2x4 + 1x5 <= 13 => x4, x5 always fits into the knapsack, so we can delete them
8109 * i.e. 5x1 + 5x2 + 5x3 + 2x4 + 1x5 <= 8 and we have the cliqueinformation (x1,x2,x3) is a clique
8112 * i.e. 5x1 + 5x2 + 5x3 + 1x4 + 1x5 <= 6 and we have the cliqueinformation (x1,x2,x3) is a clique and (x4,x5) too
8124 {
8161 /* all but one variable fit into the knapsack, so we can upgrade this constraint to a logicor */
8176 /* all but one variable fit into the knapsack, so we can upgrade this constraint to a logicor */
8232 /* if all items fit, then delete the whole constraint but create clique constraints which led to this
8244 SCIPdebugMsg(scip, "Found redundant constraint <%s> due to clique information.\n", SCIPconsGetName(cons));
8263 /* we found a real clique so extract this constraint, because we do not know who this information generated so */
8269 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_clq_%" SCIP_LONGINT_FORMAT "_%d", SCIPconsGetName(cons), capacity, c);
8302 /** divides weights by their greatest common divisor and divides capacity by the same value, rounding down the result */
8332 assert(SCIPvarGetUbLocal(consdata->vars[i]) > 0.5); /* all fixed variables should have been removed */
8339 SCIPdebugMessage("knapsack constraint <%s>: dividing weights by %" SCIP_LONGINT_FORMAT "\n", SCIPconsGetName(cons), gcd);
8360 * 1. a) check if all two pairs exceed the capacity, then we can upgrade this constraint to a set-packing constraint
8361 * b) check if all but the smallest weight fit into the knapsack, then we can upgrade this constraint to a logicor
8364 * 2. check if besides big coefficients, that fit only by itself, for a certain amount of variables all combination of
8367 * +219y1 + 180y2 + 74x1 + 70x2 + 63x3 + 62x4 + 53x5 <= 219 <=> 3y1 + 3y2 + x1 + x2 + x3 + x4 + x5 <= 3
8369 * 3. use the duality between a^Tx <= capacity <=> a^T~x >= weightsum - capacity to tighten weights, e.g.
8386 {
8437 SCIPdebugMsg(scip, "upgrading knapsack constraint <%s> to a set-packing constraint", SCIPconsGetName(cons));
8439 SCIP_CALL( SCIPcreateConsSetpack(scip, &newcons, SCIPconsGetName(cons), consdata->nvars, consdata->vars,
8455 /* all but one variable fit into the knapsack, so we can upgrade this constraint to a logicor */
8464 /* early termination, if the pair with biggest coeffcients together does not exceed the dualcapacity */
8475 * the following is done without looking at the dualcapacity; it is enough to check whether for a certain amount of
8482 * +219y1 + 180y_2 +74x1 + 70x2 + 63x3 + 62x4 + 53x5 <= 219 <=> 3y1 + 3y2 + x1 + x2 + x3 + x4 + x5 <= 3
8534 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal
8544 /* a certain amount of small variables exceed the capacity, so check if this holds for all combinations of the
8560 /* if the same amount but with the smallest possible weights also exceed the capacity, it holds for all
8592 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal
8605 /* if the following assert fails we have either a redundant constraint or a set-packing constraint, this should
8614 * either choose x1, or all other variables (weightsum of x2 to x10 is 979 above), so we can tighten this
8655 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal
8691 /* any negated variable out of the first n - 1 items is enough to fulfill the constraint, so we can update it to a logicor
8714 /* we have a dual-knapsack constraint where we either need to choose one variable out of a subset (big
8721 * 3x1 + 3x2 + 2x3 + 2x4 + 2x5 + 2x6 + x7 <= 12 <=> 3~x1 + 3~x2 + 2~x3 + 2~x4 + 2~x5 + 2~x6 + ~x7 >= 3
8787 * e.g. 9x1 + 9x2 + 6x3 + 4x4 + 4x5 + 4x6 <= 27 <=> 9~x1 + 9~x2 + 6~x3 + 4~x4 + 4~x5 + 4~x6 >= 9
8814 /* we found redundant variables, which does not influence the feasibility of any integral solution, e.g.
8833 /* for performance reasons we do not update the capacity(, i.e. reduce it by reductionsum) and directly
8844 * e.g. 9x1 + 9x2 + 6x3 + 6x4 + 4x5 + 4x6 <= 29 <=> 9~x1 + 9~x2 + 6~x3 + 6~x4 + 4~x5 + 4~x6 >= 9
8849 if( weights[v] > 1 || (weights[startv] > (SCIP_Longint)nvars - v) || (startv > 0 && weights[0] == (SCIP_Longint)nvars - v + 1) )
8863 /* adjust middle sized coefficients, which when choosing also one small coefficients exceed the
8894 newcap = ((SCIP_Longint)startv - 1) * newweight + ((SCIP_Longint)v - startv) * (newweight - 1) + ((SCIP_Longint)nvars - v);
8903 assert(weights[v] == 1 && (weights[startv] == (SCIP_Longint)nvars - v) && (startv == 0 || weights[0] == (SCIP_Longint)nvars - v + 1));
8908 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal
8918 /* check if all rear items have the same weight as the last one, so we cannot tighten the constraint further */
8965 /* dualcapacity is odd, we can set the middle weights to dualcapacity but therefor need to multiply all
9009 /* @todo loop for "k" can be extended, same coefficient when determine next sumcoef can be left out */
9039 sumcoef = MIN(weights[nvars - 1] + weights[nvars - 5], weights[nvars - 2] + weights[nvars - 3]);
9043 sumcoef = MIN(weights[nvars - 1] + weights[nvars - 4], weights[nvars - 1] + weights[nvars - 2] + weights[nvars - 3]);
9050 /* tighten next coefficients that, pair with the current small coefficient, exceed the dualcapacity */
9058 /* @todo check for further reductions, when two times the minweight exceeds the dualcapacity */
9090 /* now check if a combination of small coefficients allows us to tighten big coefficients further */
9153 /* dualcapacity is odd, we can set the middle weights to dualcapacity but therefor need to multiply all
9211 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal
9236 /** fixes variables with weights bigger than the capacity and delete redundant constraints, also sort weights */
9335 * 1. use the duality between a^Tx <= capacity <=> -a^T~x <= capacity - weightsum to tighten weights, e.g.
9343 * 2. if variables in a constraint do not affect the (in-)feasibility of the constraint, we can delete them, e.g.
9347 * 3. Tries to use gcd information an all but one weight to change this not-included weight and normalize the
9350 * 9x1 + 6x2 + 6x3 + 5x4 <= 13 => 9x1 + 6x2 + 6x3 + 6x4 <= 12 => 3x1 + 2x2 + 2x3 + 2x4 <= 4 => 4x1 + 2x2 + 2x3 + 2x4 <= 4
9456 /* weight should still be sorted, because the reduction preserves this, but corresponding variables with equal weight
9479 /* determine coefficients as big as the capacity, these we do not need to take into account when calculating the
9498 /* calculate greatest common divisor over all integer and binary variables and determine the candidate where we might
9519 /* if the greatest commmon divisor has become 1, we might have found the possible coefficient to change or we
9530 /* if both first coefficients have a gcd of 1, both are candidates for the coefficient change */
9561 /* we should have found one coefficient, that led to a gcd of 1, otherwise we could normalize the constraint
9603 SCIPdebugMsg(scip, "gcd = %" SCIP_LONGINT_FORMAT ", rest = %" SCIP_LONGINT_FORMAT ", restweight = %" SCIP_LONGINT_FORMAT "; possible new weight of variable <%s> %" SCIP_LONGINT_FORMAT ", possible new capacity %" SCIP_LONGINT_FORMAT ", offset of coefficients as big as capacity %d\n", gcd, rest, restweight, SCIPvarGetName(vars[candpos]), newweight, consdata->capacity - rest, offsetv);
9605 /* must not change weights and capacity if one variable would be removed and we have a big coefficient,
9606 * e.g., 11x1 + 6x2 + 6x3 + 5x4 <= 11 => gcd = 6, offsetv = 1 => newweight = 0, but we would lose x1 = 1 => x4 = 0
9657 SCIPdebugMsg(scip, "we did %d coefficient changes and %d side changes on constraint %s when applying one round of the gcd algorithm\n", *nchgcoefs - oldnchgcoefs, *nchgsides - oldnchgsides, SCIPconsGetName(cons));
9706 /* we explicitly construct the complete implication graph where the knapsack variables are involved;
9711 SCIPdebugMsg(scip, "memory limit of %d bytes reached in knapsack preprocessing - abort collecting zero items\n",
9742 /** applies rule (3) of the weight tightening procedure, which can lift other variables into the knapsack:
9747 * - the weight of the variable or its negation (depending on v) can be increased as long as it has the same
9764 int* firstidxs[2]; /* first index in zeroitems for each binary variable/value pair, or zero for empty list */
9767 int* nextidxs; /* next index in zeroitems for the same binary variable, or zero for end of list */
9810 if( (!consdata->cliquepartitioned && nvars > MAX_USECLIQUES_SIZE) || consdata->ncliques > MAX_USECLIQUES_SIZE )
9819 /* we have to consider all integral variables since even integer and implicit integer variables can have binary bounds */
9840 /* next if conditions should normally not be true, because it means that presolving has created more binary variables
9841 * than binary + integer variables existed at the presolving initialization method, but for example if you would
9849 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->ints1, oldsize, conshdlrdata->ints1size) );
9850 BMSclearMemoryArray(&(conshdlrdata->ints1[oldsize]), conshdlrdata->ints1size - oldsize); /*lint !e866*/
9857 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->ints2, oldsize, conshdlrdata->ints2size) );
9858 BMSclearMemoryArray(&(conshdlrdata->ints2[oldsize]), conshdlrdata->ints2size - oldsize); /*lint !e866*/
9865 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->longints1, oldsize, conshdlrdata->longints1size) );
9866 BMSclearMemoryArray(&(conshdlrdata->longints1[oldsize]), conshdlrdata->longints1size - oldsize); /*lint !e866*/
9873 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->longints2, oldsize, conshdlrdata->longints2size) );
9874 BMSclearMemoryArray(&(conshdlrdata->longints2[oldsize]), conshdlrdata->longints2size - oldsize); /*lint !e866*/
9905 /* next if conditions should normally not be true, because it means that presolving has created more binary variables
9906 * than binary + integer variables existed at the presolving initialization method, but for example if you would
9914 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->bools1, oldsize, conshdlrdata->bools1size) );
9915 BMSclearMemoryArray(&(conshdlrdata->bools1[oldsize]), conshdlrdata->bools1size - oldsize); /*lint !e866*/
9922 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->bools2, oldsize, conshdlrdata->bools2size) );
9923 BMSclearMemoryArray(&(conshdlrdata->bools2[oldsize]), conshdlrdata->bools2size - oldsize); /*lint !e866*/
10067 /* calculate the clique partition and the maximal sum of weights using the clique information */
10073 /* next if condition should normally not be true, because it means that presolving has created more binary variables
10074 * in one constraint than binary + integer variables existed in the whole problem at the presolving initialization
10075 * method, but for example if you would transform all integers into their binary representation then it maybe happens
10082 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->bools3, oldsize, conshdlrdata->bools3size) );
10083 BMSclearMemoryArray(&(conshdlrdata->bools3[oldsize]), conshdlrdata->bools3size - oldsize); /*lint !e866*/
10117 /* next if condition should normally not be true, because it means that presolving has created more binary variables
10118 * in one constraint than binary + integer variables existed in the whole problem at the presolving initialization
10119 * method, but for example if you would transform all integers into their binary representation then it maybe happens
10126 SCIP_CALL( SCIPreallocBlockMemoryArray(scip, &conshdlrdata->bools4, oldsize, conshdlrdata->bools4size) );
10127 BMSclearMemoryArray(&conshdlrdata->bools4[oldsize], conshdlrdata->bools4size - oldsize); /*lint !e866*/
10138 /* for each binary variable xi and each fixing v, calculate the cliqueweightsum and update the weight of the
10139 * variable in the knapsack (this is sequence-dependent because the new or modified weights have to be
10165 /* mark the items that are implied to zero by setting the current variable to the current value */
10213 SCIPdebugMsg(scip, "knapsack constraint <%s>: adding lifted item %" SCIP_LONGINT_FORMAT "<%s>\n",
10250 /* if new items were added, multiple entries of the same variable are possible and we have to clean up the constraint */
10275 * - wi and capacity can be changed to have the same redundancy effect and the same results for
10276 * fixing xi to zero or one, but with a reduced wi and tightened capacity to tighten the LP relaxation
10280 * (2) increase weights from front to back(sortation is necessary) if there is no space left for another weight
10281 * - determine the four(can be adjusted) minimal weightsums of the knapsack, i.e. in increasing order
10282 * weights[nvars - 1], weights[nvars - 2], MIN(weights[nvars - 3], weights[nvars - 1] + weights[nvars - 2]),
10283 * MIN(MAX(weights[nvars - 3], weights[nvars - 1] + weights[nvars - 2]), weights[nvars - 4]), note that there
10285 * - check if summing up a minimal weightsum with a big weight exceeds the capacity, then we can increase the big
10296 * - weights wi, i in C, and capacity can be changed to have the same redundancy effect and the same results for
10297 * fixing xi, i in C, to zero or one, but with a reduced wi and tightened capacity to tighten the LP relaxation
10302 * This rule has to add the used cliques in order to ensure they are enforced - otherwise, the reduction might
10308 * - the weight of the variable or its negation (depending on v) can be increased as long as it has the same
10355 assert(consdata->weightsum > consdata->capacity); /* otherwise, the constraint is redundant */
10385 SCIPdebugMsg(scip, "knapsack constraint <%s>: changed weight of <%s> from %" SCIP_LONGINT_FORMAT " to %" SCIP_LONGINT_FORMAT ", capacity from %" SCIP_LONGINT_FORMAT " to %" SCIP_LONGINT_FORMAT "\n",
10416 /* @todo loop for "k" can be extended, same coefficient when determine next sumcoef can be left out */
10472 /* tighten next coefficients that, paired with the current small coefficient, exceed the capacity */
10479 SCIPdebugMsg(scip, "in constraint <%s> changing weight %" SCIP_LONGINT_FORMAT " to %" SCIP_LONGINT_FORMAT "\n",
10512 SCIPdebugMsg(scip, "in constraint <%s> changing weight %" SCIP_LONGINT_FORMAT " to %" SCIP_LONGINT_FORMAT "\n",
10525 /* apply rule (2) (don't apply, if the knapsack has too many items for applying this costly method) */
10528 if( conshdlrdata->disaggregation && consdata->nvars - pos <= MAX_USECLIQUES_SIZE && consdata->nvars >= 2 &&
10530 consdata->weights[pos - 1] == consdata->capacity && (pos == consdata->nvars || consdata->weights[pos] == 1) )
10546 SCIPdebugMsg(scip, "upgrading knapsack constraint <%s> to a set-packing constraint", SCIPconsGetName(cons));
10548 SCIP_CALL( SCIPcreateConsSetpack(scip, &cliquecons, SCIPconsGetName(cons), pos, consdata->vars,
10580 SCIPdebugMsg(scip, "Disaggregating knapsack constraint <%s> due to clique information.\n", SCIPconsGetName(cons));
10606 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_clq_%" SCIP_LONGINT_FORMAT "_%d", SCIPconsGetName(cons), consdata->capacity, c);
10628 else if( consdata->nvars <= MAX_USECLIQUES_SIZE || (consdata->cliquepartitioned && consdata->ncliques <= MAX_USECLIQUES_SIZE) )
10700 SCIPdebugMsg(scip, "knapsack constraint <%s>: weights of clique %d (maxweight: %" SCIP_LONGINT_FORMAT ") can be tightened: cliqueweightsum=%" SCIP_LONGINT_FORMAT ", capacity=%" SCIP_LONGINT_FORMAT " -> delta: %" SCIP_LONGINT_FORMAT "\n",
10730 /* check if our clique information results out of this knapsack constraint and if so check if we would loose the clique information */
10757 SCIPdebugMsg(scip, " -> change capacity from %" SCIP_LONGINT_FORMAT " to %" SCIP_LONGINT_FORMAT " (forceclique:%u)\n",
10769 SCIPdebugMsg(scip, " -> change weight of <%s> from %" SCIP_LONGINT_FORMAT " to %" SCIP_LONGINT_FORMAT "\n",
10776 /* if before the weight update at least one pair of weights did not fit into the knapsack and now fits,
10777 * we have to make sure, the clique is enforced - the clique might have been constructed partially from
10778 * this constraint, and by reducing the weights, this clique information is not contained anymore in the
10791 (void) SCIPsnprintf(name, SCIP_MAXSTRLEN, "%s_clq_%" SCIP_LONGINT_FORMAT "_%d", SCIPconsGetName(cons), consdata->capacity, i);
10851 SCIPdebugMsg(scip, "knapsack constraint <%s>: changed weight of <%s> from %" SCIP_LONGINT_FORMAT " to %" SCIP_LONGINT_FORMAT "\n",
10854 consdataChgWeight(consdata, i, consdata->capacity); /* this does not destroy the weight order! */
10874 SCIPdebugMsg(scip, "knapsack constraint <%s>: changed weight of <%s> from %" SCIP_LONGINT_FORMAT " to %" SCIP_LONGINT_FORMAT "\n",
10875 SCIPconsGetName(cons), SCIPvarGetName(consdata->vars[consdata->nvars-1]), weight, consdata->capacity);
10877 consdataChgWeight(consdata, consdata->nvars-1, consdata->capacity); /* this does not destroy the weight order! */
10982 /* determine maximal weights for all negated cliques and calculate minimal weightsum due to negated cliques */
10985 assert(0 <= consdata->negcliquepartition[v] && consdata->negcliquepartition[v] <= nnegcliques);
11002 /* free capacity is the rest of not used capacity if the smallest amount of weights due to negated cliques are used */
11006 SCIPdebugMsg(scip, "Try to add negated cliques in knapsack constraint handler for constraint %s; capacity = %" SCIP_LONGINT_FORMAT ", minactivity(due to neg. cliques) = %" SCIP_LONGINT_FORMAT ", freecapacity = %" SCIP_LONGINT_FORMAT ".\n",
11017 /* if we would take the biggest weight instead of another what would we gain, take weight[v] instead of
11023 gainweights[nposcliquevars] = maxweights[consdata->negcliquepartition[v]] - consdata->weights[w];
11035 SCIPsortDownLongPtrInt(gainweights,(void**) poscliquevars, gaincliquepartition, nposcliquevars);
11048 /* taking bigger weights make the knapsack redundant so we will create cliques, only take items which are not
11050 for( w = v + 1; w < nposcliquevars && !cliqueused[gaincliquepartition[w]] && gainweights[w] + lastweight > freecapacity; ++w )
11074 /* try to replace the last item in the clique by a different item to obtain a slightly different clique */
11075 for( ++w; w < nposcliquevars && !cliqueused[gaincliquepartition[w]] && beforelastweight + gainweights[w] > freecapacity; ++w )
11103 * greedily detects cliques by first sorting the items by decreasing weights (optional) and then collecting greedily
11105 * 2) looping through the remaining items and finding the largest set of preceding items to build a clique => possibly many more cliques
11115 SCIP_Real cliqueextractfactor,/**< lower clique size limit for greedy clique extraction algorithm (relative to largest clique) */
11160 /* no more cliques to be found (don't know if this can actually happen, since the knapsack could be replaced by a set-packing constraint)*/
11167 /* try to replace the last item in the clique by a different item to obtain a slightly different clique */
11168 /* loop over remaining, smaller items and compare each item backwards against larger weights, starting with the second smallest weight */
11186 /* include this item together with all items that have a weight at least as large as the compare weight in a clique */
11205 /* choose a preceding, larger weight to compare small items against. Clique size is reduced by 1 simultaneously */
11222 SCIP_Real cliqueextractfactor,/**< lower clique size limit for greedy clique extraction algorithm (relative to largest clique) */
11283 /* calculate minimal activity due to negated cliques, and determine second maximal weight in each clique */
11312 /* free capacity is the rest of not used capacity if the smallest amount of weights due to negated cliques are used */
11316 SCIPdebugMsg(scip, "Try to add cliques in knapsack constraint handler for constraint %s; capacity = %" SCIP_LONGINT_FORMAT ", minactivity(due to neg. cliques) = %" SCIP_LONGINT_FORMAT ", freecapacity = %" SCIP_LONGINT_FORMAT ".\n",
11319 /* create negated cliques out of negated cliques, if we do not take the smallest weight of a cliques ... */
11342 SCIP_CALL( greedyCliqueAlgorithm(scip, poscliquevars, gainweights, nposcliquevars, freecapacity, FALSE, cliqueextractfactor, cutoff, nbdchgs) );
11350 SCIP_CALL( greedyCliqueAlgorithm(scip, consdata->vars, consdata->weights, nvars, consdata->capacity, TRUE, cliqueextractfactor, cutoff, nbdchgs) );
11371 /** returns TRUE iff both keys are equal; two constraints are equal if they have the same variables and the
11450 /** compares each constraint with all other constraints for possible redundancy and removes or changes constraint
11462 {
11519 /* constraint found: create a new constraint with same coefficients and best left and right hand side;
11550 /* update flags of constraint which caused the redundancy s.t. nonredundant information doesn't get lost */
11610 for( c = (consdata0->presolvedtiming == SCIP_PRESOLTIMING_EXHAUSTIVE ? firstchange : 0); c < chkind; ++c )
11630 if( consdata0->presolvedtiming >= SCIP_PRESOLTIMING_EXHAUSTIVE && consdata1->presolvedtiming >= SCIP_PRESOLTIMING_EXHAUSTIVE ) /*lint !e574*/
11660 SCIPdebugMsg(scip, "preprocess knapsack constraint pair <%s> and <%s>\n", SCIPconsGetName(cons0), SCIPconsGetName(cons1));
11697 /* if cons1 is possible contained in cons0 (consdata0->weights[v0] / quotient) must be greater equals consdata1->weights[v1] */
11698 if( iscons1incons0contained && SCIPisLT(scip, ((SCIP_Real) consdata0->weights[v0]) / quotient, (SCIP_Real) consdata1->weights[v1]) )
11704 /* if cons0 is possible contained in cons1 (consdata0->weight[v0] / quotient) must be less equals consdata1->weight[v1] */
11705 else if( iscons0incons1contained && SCIPisGT(scip, ((SCIP_Real) consdata0->weights[v0]) / quotient, (SCIP_Real) consdata1->weights[v1]) )
11733 /* neither one constraint was contained in another or we checked all variables of one constraint against the
11743 /* update flags of constraint which caused the redundancy s.t. nonredundant information doesn't get lost */
11754 /* update flags of constraint which caused the redundancy s.t. nonredundant information doesn't get lost */
11776 )
11787 SCIPdebugMsg(scip, "knapsack enforcement of %d/%d constraints for %s solution\n", nusefulconss, nconss,
11793 maxncuts = (SCIPgetDepth(scip) == 0 ? conshdlrdata->maxsepacutsroot : conshdlrdata->maxsepacuts);
11861 SCIP_Bool removable, /**< should the relaxation be removed from the LP due to aging or cleanup?
11863 SCIP_Bool stickingatnode /**< should the constraint always be kept at the node where it was added, even
11883 /* if the right hand side is non-infinite, we have to negate all variables with negative coefficient;
11884 * otherwise, we have to negate all variables with positive coefficient and multiply the row with -1
11918 initial, separate, enforce, check, propagate, local, modifiable, dynamic, removable, stickingatnode) );
11946 SCIPdebugMsg(scip, "upgrading constraint <%s> to knapsack constraint\n", SCIPconsGetName(cons));
11948 /* create the knapsack constraint (an automatically upgraded constraint is always unmodifiable) */
11950 SCIP_CALL( createNormalizedKnapsack(scip, upgdcons, SCIPconsGetName(cons), nvars, vars, vals, lhs, rhs,
11983 /** destructor of constraint handler to free constraint handler data (called when SCIP is exiting) */
12016 /* all variables which are of integral type can be binary; this can be checked via the method SCIPvarIsBinary(var) */
12025 /** deinitialization method of constraint handler (called before transformed problem is freed) */
12044 /** presolving initialization method of constraint handler (called when presolving is about to begin) */
12058 /* all variables which are of integral type can be binary; this can be checked via the method SCIPvarIsBinary(var) */
12087 /** presolving deinitialization method of constraint handler (called after presolving has been finished) */
12101 /* since we are not allowed to detect infeasibility in the exitpre stage, we dont give an infeasible pointer */
12131 /** solving process deinitialization method of constraint handler (called before branch and bound process data is freed) */
12204 SCIP_CALL( SCIPcreateCons(scip, targetcons, SCIPconsGetName(sourcecons), conshdlr, targetdata,
12205 SCIPconsIsInitial(sourcecons), SCIPconsIsSeparated(sourcecons), SCIPconsIsEnforced(sourcecons),
12208 SCIPconsIsDynamic(sourcecons), SCIPconsIsRemovable(sourcecons), SCIPconsIsStickingAtNode(sourcecons)) );
12217 /** LP initialization method of constraint handler (called before the initial LP relaxation at a node is solved) */
12267 if( (depth == 0 && conshdlrdata->maxroundsroot >= 0 && nrounds >= conshdlrdata->maxroundsroot)
12295 SCIP_CALL( separateCons(scip, conss[i], NULL, sepacardinality, conshdlrdata->usegubs, &cutoff, &ncuts) );
12336 if( (depth == 0 && conshdlrdata->maxroundsroot >= 0 && nrounds >= conshdlrdata->maxroundsroot)
12356 SCIP_CALL( separateCons(scip, conss[i], sol, sepacardinality, conshdlrdata->usegubs, &cutoff, &ncuts) );
12417 {
12449 /* do not propagate constraints with multi-aggregated variables, which should only happen in probing mode,
12459 SCIP_CALL( propagateCons(scip, conss[i], &cutoff, &redundant, &nfixedvars, conshdlrdata->negatedclique) );
12506 newchanges = (nrounds == 0 || nnewfixedvars > 0 || nnewaggrvars > 0 || nnewchgbds > 0 || nnewupgdconss > 0);
12558 SCIP_CALL( propagateCons(scip, cons, &cutoff, &redundant, nfixedvars, (presoltiming & SCIP_PRESOLTIMING_MEDIUM)) );
12581 /* check again for redundancy (applyFixings() might have decreased weightsum due to fixed-to-zero vars) */
12584 SCIPdebugMsg(scip, " -> knapsack constraint <%s> is redundant: weightsum=%" SCIP_LONGINT_FORMAT ", capacity=%" SCIP_LONGINT_FORMAT "\n",
12596 SCIP_CALL( simplifyInequalities(scip, cons, nfixedvars, ndelconss, nchgcoefs, nchgsides, naddconss, &cutoff) );
12613 SCIP_CALL( tightenWeights(scip, cons, presoltiming, nchgcoefs, nchgsides, naddconss, ndelconss, &cutoff) );
12619 if( conshdlrdata->dualpresolving && SCIPallowDualReds(scip) && (presoltiming & SCIP_PRESOLTIMING_MEDIUM) != 0 )
12621 /* in case the knapsack constraints is independent of everything else, solve the knapsack and apply the
12639 if( !cutoff && conshdlrdata->presolusehashing && (presoltiming & SCIP_PRESOLTIMING_MEDIUM) != 0 )
12641 /* detect redundant constraints; fast version with hash table instead of pairwise comparison */
12642 SCIP_CALL( detectRedundantConstraints(scip, SCIPblkmem(scip), conss, nconss, &cutoff, ndelconss) );
12645 if( (*ndelconss != oldndelconss) || (*nchgsides != oldnchgsides) || (*nchgcoefs != oldnchgcoefs) || (*naddconss != oldnaddconss) )
12650 if( !cutoff && firstchange < nconss && conshdlrdata->presolpairwise && (presoltiming & SCIP_PRESOLTIMING_EXHAUSTIVE) != 0 )
12665 npaircomparisons += ((SCIPconsGetData(cons)->presolvedtiming < SCIP_PRESOLTIMING_EXHAUSTIVE) ? (SCIP_Longint) c : ((SCIP_Longint) c - (SCIP_Longint) firstchange));
12671 if( (*ndelconss != oldndelconss) || (*nchgsides != oldnchgsides) || (*nchgcoefs != oldnchgcoefs) )
12673 if( ((SCIP_Real) (*ndelconss - oldndelconss) + ((SCIP_Real) (*nchgsides - oldnchgsides))/2.0 +
12674 ((SCIP_Real) (*nchgcoefs - oldnchgcoefs))/10.0) / ((SCIP_Real) npaircomparisons) < MINGAINPERNMINCOMPARISONS )
12684 /* @todo upgrade to cardinality constraints: the code below relies on disabling the checking of the knapsack
12685 * constraint in the original problem, because the upgrade ensures that at most the given number of continuous
12686 * variables has a nonzero value, but not that the binary variables corresponding to the continuous variables with
12687 * value zero are set to zero as well. This can cause problems if the user accesses the values of the binary
12688 * variables (as the MIPLIB solution checker does), or the transformed problem is freed and the original problem
12689 * (possibly with some user modifications) is re-optimized. Until there is a way to force the binary variables to 0
12691 /* upgrade to cardinality constraints - only try to upgrade towards the end of presolving, since the process below is quite expensive */
12692 if ( ! cutoff && conshdlrdata->upgdcardinality && (presoltiming & SCIP_PRESOLTIMING_EXHAUSTIVE) != 0 && SCIPisPresolveFinished(scip) && ! conshdlrdata->upgradedcard )
12710 * - First, determine for each binary variable the number of cardinality constraints that can be upgraded to a
12711 * knapsack constraint and contain this variable; this number has to coincide with the number of variable up
12712 * locks; otherwise it would be infeasible to delete the knapsack constraints after the constraint update.
12746 /* check whether all variables are of the form 0 <= x_v <= u_v y_v for y_v \in \{0,1\} and zero objective */
12828 /* for each variable: check whether the number of cardinality constraints that can be upgraded to a
12833 if ( SCIPvarGetNLocksUpType(vars[v], SCIP_LOCKTYPE_MODEL) != SCIPhashmapGetImageInt(varhash, vars[v]) )
12843 SCIPdebugMessage("Upgrading knapsack constraint <%s> to cardinality constraint ...\n", SCIPconsGetName(cons));
12847 SCIP_CALL( SCIPcreateConsCardinality(scip, &cardcons, SCIPconsGetName(cons), nvars, cardvars, (int) consdata->capacity, vars, cardweights,
12850 SCIPconsIsLocal(cons), SCIPconsIsDynamic(cons), SCIPconsIsRemovable(cons), SCIPconsIsStickingAtNode(cons)) );
12865 /* We need to disable the original knapsack constraint, since it might happen that the binary variables
12866 * are 1 although the continuous variables are 0. Thus, the knapsack constraint might be violated,
12932 /* according to negated cliques the minweightsum and all variables which are fixed to one which led to a fixing of
12933 * another negated clique variable to one, the inferinfo was chosen to be the negative of the position in the
12940 /* locate the inference variable and calculate the capacity that has to be used up to conclude infervar == 0;
12941 * inferinfo stores the position of the inference variable (but maybe the variables were resorted)
12954 /* add fixed-to-one variables up to the point, that their weight plus the weight of the conflict variable exceeds
12972 /* NOTE: It might be the case that capsum < consdata->capacity. This is due the fact that the fixing of the variable
12973 * to zero can included negated clique information. A negated clique means, that at most one of the clique
12974 * variables can be zero. These information can be used to compute a minimum activity of the constraint and
12977 * Even if capsum < consdata->capacity we still reported a complete reason since the minimum activity is based
12978 * on global variable bounds. It might even be the case that we reported to many variables which are fixed to
13076 -SCIPinfinity(scip), (SCIP_Real) SCIPgetCapacityKnapsack(sourcescip, sourcecons), varmap, consmap,
13077 initial, separate, enforce, check, propagate, local, modifiable, dynamic, removable, stickingatnode, global, valid) );
13156 SCIPverbMessage(scip, SCIP_VERBLEVEL_MINIMAL, NULL, "expected '<= ' at begin of '%s'\n", str);
13170 SCIPverbMessage(scip, SCIP_VERBLEVEL_MINIMAL, NULL, "error parsing capacity from '%s'\n", str);
13176 initial, separate, enforce, check, propagate, local, modifiable, dynamic, removable, stickingatnode) );
13208 /** constraint method of constraint handler which returns the number of variables (if possible) */
13253 case SCIP_EVENTTYPE_VARFIXED: /* the variable should be removed from the constraint in presolving */
13260 /* if the variable was aggregated or multiaggregated, we must signal to propagation that we are no longer merged */
13267 (SCIPvarGetStatus(var) == SCIP_VARSTATUS_NEGATED && SCIPvarGetStatus(SCIPvarGetNegatedVar(var)) == SCIP_VARSTATUS_AGGREGATED) )
13271 case SCIP_EVENTTYPE_IMPLADDED: /* further preprocessing might be possible due to additional implications */
13305 SCIP_CALL( SCIPincludeEventhdlrBasic(scip, &(conshdlrdata->eventhdlr), EVENTHDLR_NAME, EVENTHDLR_DESC,
13337 SCIP_CALL( SCIPsetConshdlrPresol(scip, conshdlr, consPresolKnapsack,CONSHDLR_MAXPREROUNDS, CONSHDLR_PRESOLTIMING) );
13339 SCIP_CALL( SCIPsetConshdlrProp(scip, conshdlr, consPropKnapsack, CONSHDLR_PROPFREQ, CONSHDLR_DELAYPROP,
13342 SCIP_CALL( SCIPsetConshdlrSepa(scip, conshdlr, consSepalpKnapsack, consSepasolKnapsack, CONSHDLR_SEPAFREQ,
13349 /* include the linear constraint to knapsack constraint upgrade in the linear constraint handler */
13350 SCIP_CALL( SCIPincludeLinconsUpgrade(scip, linconsUpgdKnapsack, LINCONSUPGD_PRIORITY, CONSHDLR_NAME) );
13356 "multiplier on separation frequency, how often knapsack cuts are separated (-1: never, 0: only at root)",
13357 &conshdlrdata->sepacardfreq, TRUE, DEFAULT_SEPACARDFREQ, -1, SCIP_MAXTREEDEPTH, NULL, NULL) );
13360 "maximal relative distance from current node's dual bound to primal bound compared to best node's dual bound for separating knapsack cuts",
13364 "lower clique size limit for greedy clique extraction algorithm (relative to largest clique)",
13365 &conshdlrdata->cliqueextractfactor, TRUE, DEFAULT_CLIQUEEXTRACTFACTOR, 0.0, 1.0, NULL, NULL) );
13412 "should presolving try to detect constraints parallel to the objective function defining an upper bound and prevent these constraints from entering the LP?",
13416 "should presolving try to detect constraints parallel to the objective function defining a lower bound and prevent these constraints from entering the LP?",
13438 * @note the constraint gets captured, hence at one point you have to release it using the method SCIPreleaseCons()
13467 SCIP_Bool removable, /**< should the relaxation be removed from the LP due to aging or cleanup?
13469 SCIP_Bool stickingatnode /**< should the constraint always be kept at the node where it was added, even
13495 SCIP_CALL( SCIPcreateCons(scip, cons, name, conshdlr, consdata, initial, separate, enforce, check, propagate,
13509 * in its most basic version, i. e., all constraint flags are set to their basic value as explained for the
13510 * method SCIPcreateConsKnapsack(); all flags can be set via SCIPsetConsFLAGNAME-methods in scip.h
13514 * @note the constraint gets captured, hence at one point you have to release it using the method SCIPreleaseCons()
13524 )
13564 {
13617 {
13629 /** gets the array of variables in the knapsack constraint; the user must not modify this array! */
13638 {
13650 /** gets the array of weights in the knapsack constraint; the user must not modify this array! */
13659 {
13680 {
13704 {
13719 /** returns the linear relaxation of the given knapsack constraint; may return NULL if no LP row was yet created;
13730 {
SCIP_Bool SCIPisEQ(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:436
SCIP_RETCODE SCIPcalcCliquePartition(SCIP *const scip, SCIP_VAR **const vars, int const nvars, int *const cliquepartition, int *const ncliques)
Definition: scip_var.c:7166
void SCIPconshdlrSetData(SCIP_CONSHDLR *conshdlr, SCIP_CONSHDLRDATA *conshdlrdata)
Definition: cons.c:4221
#define SCIPreallocBlockMemoryArray(scip, ptr, oldnum, newnum)
Definition: scip_mem.h:86
Definition: cons_knapsack.c:271
static SCIP_RETCODE GUBsetFree(SCIP *scip, SCIP_GUBSET **gubset)
Definition: cons_knapsack.c:1972
Definition: type_result.h:33
SCIP_EXPORT SCIP_Bool SCIPvarIsTransformed(SCIP_VAR *var)
Definition: var.c:16880
static SCIP_RETCODE performVarDeletions(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_CONS **conss, int nconss)
Definition: cons_knapsack.c:6523
Definition: type_result.h:37
static SCIP_RETCODE mergeMultiples(SCIP *scip, SCIP_CONS *cons, SCIP_Bool *cutoff)
Definition: cons_knapsack.c:6565
SCIP_RETCODE SCIPcreateConsLogicor(SCIP *scip, SCIP_CONS **cons, const char *name, int nvars, SCIP_VAR **vars, SCIP_Bool initial, SCIP_Bool separate, SCIP_Bool enforce, SCIP_Bool check, SCIP_Bool propagate, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool dynamic, SCIP_Bool removable, SCIP_Bool stickingatnode)
Definition: cons_logicor.c:5166
SCIP_Bool SCIPisConflictAnalysisApplicable(SCIP *scip)
Definition: scip_conflict.c:291
SCIP_RETCODE SCIPsetConshdlrTrans(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSTRANS((*constrans)))
Definition: scip_cons.c:585
static SCIP_RETCODE getCover(SCIP *scip, SCIP_VAR **vars, int nvars, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *covervars, int *noncovervars, int *ncovervars, int *nnoncovervars, SCIP_Longint *coverweight, SCIP_Bool *found, SCIP_Bool modtransused, int *ntightened, SCIP_Bool *fractional)
Definition: cons_knapsack.c:2346
SCIP_RETCODE SCIPhashtableInsert(SCIP_HASHTABLE *hashtable, void *element)
Definition: misc.c:2364
SCIP_CONSHDLR * SCIPfindConshdlr(SCIP *scip, const char *name)
Definition: scip_cons.c:876
SCIP_RETCODE SCIPseparateKnapsackCuts(SCIP *scip, SCIP_CONS *cons, SCIP_SEPA *sepa, SCIP_VAR **vars, int nvars, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_SOL *sol, SCIP_Bool usegubs, SCIP_Bool *cutoff, int *ncuts)
Definition: cons_knapsack.c:5531
public methods for SCIP parameter handling
SCIP_Real SCIPgetVarLbAtIndex(SCIP *scip, SCIP_VAR *var, SCIP_BDCHGIDX *bdchgidx, SCIP_Bool after)
Definition: scip_var.c:1994
SCIP_CONS * SCIPfindOrigCons(SCIP *scip, const char *name)
Definition: scip_prob.c:2893
static SCIP_RETCODE GUBsetCalcCliquePartition(SCIP *const scip, SCIP_VAR **const vars, int const nvars, int *const cliquepartition, int *const ncliques, SCIP_Real *solvals)
Definition: cons_knapsack.c:2091
SCIP_RETCODE SCIPwriteVarName(SCIP *scip, FILE *file, SCIP_VAR *var, SCIP_Bool type)
Definition: scip_var.c:220
SCIP_RETCODE SCIPsetConshdlrExitsol(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSEXITSOL((*consexitsol)))
Definition: scip_cons.c:452
static SCIP_DECL_CONSRESPROP(consRespropKnapsack)
Definition: cons_knapsack.c:12913
SCIP_Bool SCIPisGE(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:488
Definition: struct_scip.h:58
static SCIP_RETCODE GUBsetMoveVar(SCIP *scip, SCIP_GUBSET *gubset, SCIP_VAR **vars, int var, int oldgubcons, int newgubcons)
Definition: cons_knapsack.c:1792
SCIP_RETCODE SCIPtightenVarLb(SCIP *scip, SCIP_VAR *var, SCIP_Real newbound, SCIP_Bool force, SCIP_Bool *infeasible, SCIP_Bool *tightened)
Definition: scip_var.c:5121
static SCIP_RETCODE addNegatedCliques(SCIP *const scip, SCIP_CONS *const cons, SCIP_Bool *const cutoff, int *const nbdchgs)
Definition: cons_knapsack.c:10914
SCIP_RETCODE SCIPcreateCons(SCIP *scip, SCIP_CONS **cons, const char *name, SCIP_CONSHDLR *conshdlr, SCIP_CONSDATA *consdata, SCIP_Bool initial, SCIP_Bool separate, SCIP_Bool enforce, SCIP_Bool check, SCIP_Bool propagate, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool dynamic, SCIP_Bool removable, SCIP_Bool stickingatnode)
Definition: scip_cons.c:933
SCIP_EXPORT int SCIPvarGetNLocksUpType(SCIP_VAR *var, SCIP_LOCKTYPE locktype)
Definition: var.c:3241
public methods for memory management
Definition: type_conflict.h:50
SCIP_RETCODE SCIPsetConshdlrEnforelax(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSENFORELAX((*consenforelax)))
Definition: scip_cons.c:307
static SCIP_DECL_HASHKEYVAL(hashKeyValKnapsackcons)
Definition: cons_knapsack.c:11426
#define SCIPallocClearBufferArray(scip, ptr, num)
Definition: scip_mem.h:113
public methods for implications, variable bounds, and cliques
static SCIP_RETCODE separateCons(SCIP *scip, SCIP_CONS *cons, SCIP_SOL *sol, SCIP_Bool sepacuts, SCIP_Bool usegubs, SCIP_Bool *cutoff, int *ncuts)
Definition: cons_knapsack.c:6187
SCIP_RETCODE SCIPmarkConsPropagate(SCIP *scip, SCIP_CONS *cons)
Definition: scip_cons.c:1950
SCIP_RETCODE SCIPincludeConshdlrBasic(SCIP *scip, SCIP_CONSHDLR **conshdlrptr, const char *name, const char *desc, int enfopriority, int chckpriority, int eagerfreq, SCIP_Bool needscons, SCIP_DECL_CONSENFOLP((*consenfolp)), SCIP_DECL_CONSENFOPS((*consenfops)), SCIP_DECL_CONSCHECK((*conscheck)), SCIP_DECL_CONSLOCK((*conslock)), SCIP_CONSHDLRDATA *conshdlrdata)
Definition: scip_cons.c:165
SCIP_RETCODE SCIPaddVarLocksType(SCIP *scip, SCIP_VAR *var, SCIP_LOCKTYPE locktype, int nlocksdown, int nlocksup)
Definition: scip_var.c:4200
SCIP_RETCODE SCIPgetTransformedVars(SCIP *scip, int nvars, SCIP_VAR **vars, SCIP_VAR **transvars)
Definition: scip_var.c:1483
public methods for conflict handler plugins and conflict analysis
SCIP_RETCODE SCIPgetNegatedVars(SCIP *scip, int nvars, SCIP_VAR **vars, SCIP_VAR **negvars)
Definition: scip_var.c:1563
#define SCIPallocClearBlockMemoryArray(scip, ptr, num)
Definition: scip_mem.h:84
SCIP_RETCODE SCIPinferBinvarCons(SCIP *scip, SCIP_VAR *var, SCIP_Bool fixedval, SCIP_CONS *infercons, int inferinfo, SCIP_Bool *infeasible, SCIP_Bool *tightened)
Definition: scip_var.c:5637
static void updateWeightSums(SCIP_CONSDATA *consdata, SCIP_VAR *var, SCIP_Longint weightdelta)
Definition: cons_knapsack.c:626
Definition: type_result.h:49
void * SCIPhashtableRetrieve(SCIP_HASHTABLE *hashtable, void *key)
Definition: misc.c:2425
SCIP_RETCODE SCIPsetConshdlrGetVars(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSGETVARS((*consgetvars)))
Definition: scip_cons.c:815
SCIP_RETCODE SCIPgetBinvarRepresentative(SCIP *scip, SCIP_VAR *var, SCIP_VAR **repvar, SCIP_Bool *negated)
Definition: scip_var.c:1600
SCIP_Real SCIPgetSolVal(SCIP *scip, SCIP_SOL *sol, SCIP_VAR *var)
Definition: scip_sol.c:1352
SCIP_EXPORT void SCIPsortDownLongPtrPtrIntInt(SCIP_Longint *longarray, void **ptrarray1, void **ptrarray2, int *intarray1, int *intarray2, int len)
SCIP_RETCODE SCIPtightenVarUb(SCIP *scip, SCIP_VAR *var, SCIP_Real newbound, SCIP_Bool force, SCIP_Bool *infeasible, SCIP_Bool *tightened)
Definition: scip_var.c:5237
static SCIP_RETCODE getLiftingSequenceGUB(SCIP *scip, SCIP_GUBSET *gubset, SCIP_Real *solvals, SCIP_Longint *weights, int *varsC1, int *varsC2, int *varsF, int *varsR, int nvarsC1, int nvarsC2, int nvarsF, int nvarsR, int *gubconsGC1, int *gubconsGC2, int *gubconsGFC1, int *gubconsGR, int *ngubconsGC1, int *ngubconsGC2, int *ngubconsGFC1, int *ngubconsGR, int *ngubconscapexceed, int *maxgubvarssize)
Definition: cons_knapsack.c:2884
Definition: type_set.h:37
SCIP_EXPORT SCIP_Longint SCIPsepaGetNCutsFound(SCIP_SEPA *sepa)
Definition: sepa.c:843
static SCIP_RETCODE separateSequLiftedMinimalCoverInequality(SCIP *scip, SCIP_CONS *cons, SCIP_SEPA *sepa, SCIP_VAR **vars, int nvars, int ntightened, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *mincovervars, int *nonmincovervars, int nmincovervars, int nnonmincovervars, SCIP_SOL *sol, SCIP_GUBSET *gubset, SCIP_Bool *cutoff, int *ncuts)
Definition: cons_knapsack.c:4768
SCIP_RETCODE SCIPprintRow(SCIP *scip, SCIP_ROW *row, FILE *file)
Definition: scip_lp.c:2031
SCIP_Longint SCIPcalcGreComDiv(SCIP_Longint val1, SCIP_Longint val2)
Definition: misc.c:8690
static SCIP_RETCODE addCoef(SCIP *scip, SCIP_CONS *cons, SCIP_VAR *var, SCIP_Longint weight)
Definition: cons_knapsack.c:6229
static SCIP_DECL_CONSINITLP(consInitlpKnapsack)
Definition: cons_knapsack.c:12227
SCIP_RETCODE SCIPsetConshdlrPrint(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSPRINT((*consprint)))
Definition: scip_cons.c:769
Definition: struct_var.h:198
SCIP_RETCODE SCIPinitConflictAnalysis(SCIP *scip, SCIP_CONFTYPE conftype, SCIP_Bool iscutoffinvolved)
Definition: scip_conflict.c:313
SCIP_EXPORT void SCIPsortDownLongPtrInt(SCIP_Longint *longarray, void **ptrarray, int *intarray, int len)
static SCIP_RETCODE checkParallelObjective(SCIP *scip, SCIP_CONS *cons, SCIP_CONSHDLRDATA *conshdlrdata)
Definition: cons_knapsack.c:6850
static SCIP_RETCODE separateSupLiftedMinimalCoverInequality(SCIP *scip, SCIP_CONS *cons, SCIP_SEPA *sepa, SCIP_VAR **vars, int nvars, int ntightened, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *mincovervars, int *nonmincovervars, int nmincovervars, int nnonmincovervars, SCIP_Longint mincoverweight, SCIP_SOL *sol, SCIP_Bool *cutoff, int *ncuts)
Definition: cons_knapsack.c:5169
int SCIPgetNVarsKnapsack(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:13617
SCIP_RETCODE SCIPsetConshdlrDelvars(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSDELVARS((*consdelvars)))
Definition: scip_cons.c:746
SCIP_RETCODE SCIPhashmapInsertInt(SCIP_HASHMAP *hashmap, void *origin, int image)
Definition: misc.c:3009
static SCIP_RETCODE dualWeightsTightening(SCIP *scip, SCIP_CONS *cons, int *ndelconss, int *nchgcoefs, int *nchgsides, int *naddconss)
Definition: cons_knapsack.c:8386
static SCIP_RETCODE consdataFree(SCIP *scip, SCIP_CONSDATA **consdata, SCIP_EVENTHDLR *eventhdlr)
Definition: cons_knapsack.c:774
static SCIP_RETCODE propagateCons(SCIP *scip, SCIP_CONS *cons, SCIP_Bool *cutoff, SCIP_Bool *redundant, int *nfixedvars, SCIP_Bool usenegatedclique)
Definition: cons_knapsack.c:7338
SCIP_EXPORT SCIP_VAR ** SCIPvarGetImplVars(SCIP_VAR *var, SCIP_Bool varfixing)
Definition: var.c:17647
Definition: cons_knapsack.c:281
void SCIPverbMessage(SCIP *scip, SCIP_VERBLEVEL msgverblevel, FILE *file, const char *formatstr,...)
Definition: scip_message.c:215
SCIP_RETCODE SCIPseparateRelaxedKnapsack(SCIP *scip, SCIP_CONS *cons, SCIP_SEPA *sepa, int nknapvars, SCIP_VAR **knapvars, SCIP_Real *knapvals, SCIP_Real valscale, SCIP_Real rhs, SCIP_SOL *sol, SCIP_Bool *cutoff, int *ncuts)
Definition: cons_knapsack.c:5748
SCIP_RETCODE SCIPcreateConsKnapsack(SCIP *scip, SCIP_CONS **cons, const char *name, int nvars, SCIP_VAR **vars, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Bool initial, SCIP_Bool separate, SCIP_Bool enforce, SCIP_Bool check, SCIP_Bool propagate, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool dynamic, SCIP_Bool removable, SCIP_Bool stickingatnode)
Definition: cons_knapsack.c:13449
Definition: cons_knapsack.c:273
Definition: cons_knapsack.c:290
static SCIP_RETCODE insertZerolist(SCIP *scip, int **liftcands, int *nliftcands, int **firstidxs, SCIP_Longint **zeroweightsums, int **zeroitems, int **nextidxs, int *zeroitemssize, int *nzeroitems, int probindex, SCIP_Bool value, int knapsackidx, SCIP_Longint knapsackweight, SCIP_Bool *memlimitreached)
Definition: cons_knapsack.c:9675
SCIP_RETCODE SCIPcreateEmptyRowUnspec(SCIP *scip, SCIP_ROW **row, const char *name, SCIP_Real lhs, SCIP_Real rhs, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool removable)
Definition: scip_lp.c:1326
static SCIP_RETCODE separateSequLiftedExtendedWeightInequality(SCIP *scip, SCIP_CONS *cons, SCIP_SEPA *sepa, SCIP_VAR **vars, int nvars, int ntightened, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *feassetvars, int *nonfeassetvars, int nfeassetvars, int nnonfeassetvars, SCIP_SOL *sol, SCIP_Bool *cutoff, int *ncuts)
Definition: cons_knapsack.c:5002
SCIP_RETCODE SCIPdelConsLocal(SCIP *scip, SCIP_CONS *cons)
Definition: scip_prob.c:3470
static void consdataChgWeight(SCIP_CONSDATA *consdata, int item, SCIP_Longint newweight)
Definition: cons_knapsack.c:824
SCIP_RETCODE SCIPparseVarName(SCIP *scip, const char *str, SCIP_VAR **var, char **endptr)
Definition: scip_var.c:523
void SCIPupdateSolLPConsViolation(SCIP *scip, SCIP_SOL *sol, SCIP_Real absviol, SCIP_Real relviol)
Definition: scip_sol.c:276
SCIP_RETCODE SCIPsetConshdlrDelete(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSDELETE((*consdelete)))
Definition: scip_cons.c:562
SCIP_Bool SCIPisFeasLE(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:797
SCIP_ROW * SCIPgetRowKnapsack(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:13730
static void getPartitionNoncovervars(SCIP *scip, SCIP_Real *solvals, int *noncovervars, int nnoncovervars, int *varsF, int *varsR, int *nvarsF, int *nvarsR)
Definition: cons_knapsack.c:2750
public methods for problem variables
SCIP_RETCODE SCIPaddBoolParam(SCIP *scip, const char *name, const char *desc, SCIP_Bool *valueptr, SCIP_Bool isadvanced, SCIP_Bool defaultvalue, SCIP_DECL_PARAMCHGD((*paramchgd)), SCIP_PARAMDATA *paramdata)
Definition: scip_param.c:47
SCIP_RETCODE SCIPupdateLocalLowerbound(SCIP *scip, SCIP_Real newbound)
Definition: scip_prob.c:3692
SCIP_RETCODE SCIPchgCapacityKnapsack(SCIP *scip, SCIP_CONS *cons, SCIP_Longint capacity)
Definition: cons_knapsack.c:13588
SCIP_EXPORT SCIP_Real * SCIPvarGetImplBounds(SCIP_VAR *var, SCIP_Bool varfixing)
Definition: var.c:17676
SCIP_RETCODE SCIPhashtableRemove(SCIP_HASHTABLE *hashtable, void *element)
Definition: misc.c:2494
Definition: type_result.h:40
SCIP_RETCODE SCIPflushRowExtensions(SCIP *scip, SCIP_ROW *row)
Definition: scip_lp.c:1502
SCIP_RETCODE SCIPsetConsSeparated(SCIP *scip, SCIP_CONS *cons, SCIP_Bool separate)
Definition: scip_cons.c:1232
#define SCIPduplicateBufferArray(scip, ptr, source, num)
Definition: scip_mem.h:119
SCIP_Longint * SCIPgetWeightsKnapsack(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:13659
SCIP_RETCODE SCIPsetConshdlrPresol(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSPRESOL((*conspresol)), int maxprerounds, SCIP_PRESOLTIMING presoltiming)
Definition: scip_cons.c:524
Definition: struct_sepa.h:37
SCIP_RETCODE SCIPsetConshdlrInit(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSINIT((*consinit)))
Definition: scip_cons.c:380
SCIP_RETCODE SCIPsetConsEnforced(SCIP *scip, SCIP_CONS *cons, SCIP_Bool enforce)
Definition: scip_cons.c:1257
SCIP_RETCODE SCIPsetConshdlrGetNVars(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSGETNVARS((*consgetnvars)))
Definition: scip_cons.c:838
Constraint handler for the set partitioning / packing / covering constraints .
public methods for SCIP variables
SCIP_RETCODE SCIPsolveKnapsackExactly(SCIP *scip, int nitems, SCIP_Longint *weights, SCIP_Real *profits, SCIP_Longint capacity, int *items, int *solitems, int *nonsolitems, int *nsolitems, int *nnonsolitems, SCIP_Real *solval, SCIP_Bool *success)
Definition: cons_knapsack.c:1042
SCIP_RETCODE SCIPsetConshdlrExitpre(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSEXITPRE((*consexitpre)))
Definition: scip_cons.c:500
static SCIP_RETCODE addRelaxation(SCIP *scip, SCIP_CONS *cons, SCIP_Bool *cutoff)
Definition: cons_knapsack.c:890
SCIP_Bool SCIPisFeasIntegral(SCIP *scip, SCIP_Real val)
Definition: scip_numerics.c:872
SCIP_RETCODE SCIPlockVarCons(SCIP *scip, SCIP_VAR *var, SCIP_CONS *cons, SCIP_Bool lockdown, SCIP_Bool lockup)
Definition: scip_var.c:4291
static SCIP_RETCODE GUBsetGetCliquePartition(SCIP *scip, SCIP_GUBSET *gubset, SCIP_VAR **vars, SCIP_Real *solvals)
Definition: cons_knapsack.c:2249
SCIP_EXPORT void SCIPsortPtrPtrLongIntInt(void **ptrarray1, void **ptrarray2, SCIP_Longint *longarray, int *intarray1, int *intarray2, SCIP_DECL_SORTPTRCOMP((*ptrcomp)), int len)
SCIP_RETCODE SCIPsetConshdlrFree(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSFREE((*consfree)))
Definition: scip_cons.c:356
SCIP_RETCODE SCIPupdateConsFlags(SCIP *scip, SCIP_CONS *cons0, SCIP_CONS *cons1)
Definition: scip_cons.c:1460
SCIP_EXPORT void SCIPsortDownRealIntLong(SCIP_Real *realarray, int *intarray, SCIP_Longint *longarray, int len)
public methods for numerical tolerances
SCIP_EXPORT SCIP_Real * SCIPvarGetMultaggrScalars(SCIP_VAR *var)
Definition: var.c:17144
SCIP_RETCODE SCIPhashtableCreate(SCIP_HASHTABLE **hashtable, BMS_BLKMEM *blkmem, int tablesize, SCIP_DECL_HASHGETKEY((*hashgetkey)), SCIP_DECL_HASHKEYEQ((*hashkeyeq)), SCIP_DECL_HASHKEYVAL((*hashkeyval)), void *userptr)
Definition: misc.c:2113
Definition: cons_knapsack.c:280
static SCIP_DECL_CONSDELETE(consDeleteKnapsack)
Definition: cons_knapsack.c:12165
public methods for querying solving statistics
Definition: struct_sol.h:63
static SCIP_RETCODE enforceConstraint(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_CONS **conss, int nconss, int nusefulconss, SCIP_SOL *sol, SCIP_RESULT *result)
Definition: cons_knapsack.c:11776
SCIP_Bool SCIPisLE(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:462
Definition: cons_knapsack.c:300
int SCIPhashmapGetImageInt(SCIP_HASHMAP *hashmap, void *origin)
Definition: misc.c:3098
static SCIP_RETCODE GUBconsFree(SCIP *scip, SCIP_GUBCONS **gubcons)
Definition: cons_knapsack.c:1700
public methods for the branch-and-bound tree
static SCIP_DECL_HASHGETKEY(hashGetKeyKnapsackcons)
Definition: cons_knapsack.c:11373
static SCIP_RETCODE GUBconsDelVar(SCIP *scip, SCIP_GUBCONS *gubcons, int var, int gubvarsidx)
Definition: cons_knapsack.c:1755
SCIP_RETCODE SCIPgetNegatedVar(SCIP *scip, SCIP_VAR *var, SCIP_VAR **negvar)
Definition: scip_var.c:1530
static SCIP_RETCODE stableSort(SCIP *scip, SCIP_CONSDATA *consdata, SCIP_VAR **vars, SCIP_Longint *weights, int *cliquestartposs, SCIP_Bool usenegatedclique)
Definition: cons_knapsack.c:7003
SCIP_Bool SCIPhashmapExists(SCIP_HASHMAP *hashmap, void *origin)
Definition: misc.c:3240
#define SCIPduplicateBlockMemoryArray(scip, ptr, source, num)
Definition: scip_mem.h:92
static SCIP_RETCODE checkCons(SCIP *scip, SCIP_CONS *cons, SCIP_SOL *sol, SCIP_Bool checklprows, SCIP_Bool printreason, SCIP_Bool *violated)
Definition: cons_knapsack.c:924
Definition: struct_misc.h:127
static SCIP_RETCODE applyFixings(SCIP *scip, SCIP_CONS *cons, SCIP_Bool *cutoff)
Definition: cons_knapsack.c:7127
public methods for managing constraints
Constraint handler for knapsack constraints of the form , x binary and .
SCIP_RETCODE SCIPcacheRowExtensions(SCIP *scip, SCIP_ROW *row)
Definition: scip_lp.c:1479
SCIP_RETCODE SCIPsetConshdlrExit(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSEXIT((*consexit)))
Definition: scip_cons.c:404
SCIP_EXPORT void SCIPsortDownRealInt(SCIP_Real *realarray, int *intarray, int len)
static SCIP_DECL_HASHKEYEQ(hashKeyEqKnapsackcons)
Definition: cons_knapsack.c:11383
static SCIP_DECL_CONSEXITSOL(consExitsolKnapsack)
Definition: cons_knapsack.c:12141
static void getPartitionCovervars(SCIP *scip, SCIP_Real *solvals, int *covervars, int ncovervars, int *varsC1, int *varsC2, int *nvarsC1, int *nvarsC2)
Definition: cons_knapsack.c:2620
Definition: type_result.h:35
static SCIP_RETCODE simplifyInequalities(SCIP *scip, SCIP_CONS *cons, int *nfixedvars, int *ndelconss, int *nchgcoefs, int *nchgsides, int *naddconss, SCIP_Bool *cutoff)
Definition: cons_knapsack.c:9363
Definition: struct_cons.h:37
SCIP_EXPORT SCIP_RETCODE SCIPvarsGetProbvarBinary(SCIP_VAR ***vars, SCIP_Bool **negatedarr, int nvars)
Definition: var.c:11772
SCIP_EXPORT void SCIPsortDownLongPtr(SCIP_Longint *longarray, void **ptrarray, int len)
SCIP_EXPORT SCIP_VAR * SCIPvarGetNegatedVar(SCIP_VAR *var)
Definition: var.c:17168
SCIP_EXPORT int SCIPvarGetNImpls(SCIP_VAR *var, SCIP_Bool varfixing)
Definition: var.c:17630
Definition: struct_cons.h:117
static SCIP_DECL_CONSDELVARS(consDelvarsKnapsack)
Definition: cons_knapsack.c:13017
static SCIP_RETCODE catchEvents(SCIP *scip, SCIP_CONS *cons, SCIP_CONSDATA *consdata, SCIP_EVENTHDLR *eventhdlr)
Definition: cons_knapsack.c:536
public methods for event handler plugins and event handlers
SCIP_Bool SCIPisFeasEQ(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:771
static void GUBsetSwapVars(SCIP *scip, SCIP_GUBSET *gubset, int var1, int var2)
Definition: cons_knapsack.c:1883
Constraint handler for logicor constraints (equivalent to set covering, but algorithms are suited fo...
SCIP_RETCODE SCIPcreateConsBasicKnapsack(SCIP *scip, SCIP_CONS **cons, const char *name, int nvars, SCIP_VAR **vars, SCIP_Longint *weights, SCIP_Longint capacity)
Definition: cons_knapsack.c:13524
static SCIP_RETCODE sequentialUpAndDownLiftingGUB(SCIP *scip, SCIP_GUBSET *gubset, SCIP_VAR **vars, int ngubconscapexceed, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *gubconsGC1, int *gubconsGC2, int *gubconsGFC1, int *gubconsGR, int ngubconsGC1, int ngubconsGC2, int ngubconsGFC1, int ngubconsGR, int alpha0, int *liftcoefs, SCIP_Real *cutact, int *liftrhs, int maxgubvarssize)
Definition: cons_knapsack.c:3902
static SCIP_DECL_CONSINITPRE(consInitpreKnapsack)
Definition: cons_knapsack.c:12054
Definition: cons_knapsack.c:268
Definition: type_result.h:36
static SCIP_DECL_CONSENFORELAX(consEnforelaxKnapsack)
Definition: cons_knapsack.c:12387
SCIP_EXPORT void SCIPsortPtrPtrIntInt(void **ptrarray1, void **ptrarray2, int *intarray1, int *intarray2, SCIP_DECL_SORTPTRCOMP((*ptrcomp)), int len)
static SCIP_Longint safeAddMinweightsGUB(SCIP_Longint val1, SCIP_Longint val2)
Definition: cons_knapsack.c:3831
Definition: type_var.h:44
SCIP_EXPORT void SCIPsortPtrInt(void **ptrarray, int *intarray, SCIP_DECL_SORTPTRCOMP((*ptrcomp)), int len)
Definition: type_set.h:43
Definition: type_retcode.h:33
public methods for problem copies
SCIP_Bool SCIPisConsCompressionEnabled(SCIP *scip)
Definition: scip_copy.c:622
SCIP_RETCODE SCIPsetConshdlrInitpre(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSINITPRE((*consinitpre)))
Definition: scip_cons.c:476
SCIP_RETCODE SCIPsetConshdlrResprop(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSRESPROP((*consresprop)))
Definition: scip_cons.c:631
static SCIP_DECL_CONSENFOPS(consEnfopsKnapsack)
Definition: cons_knapsack.c:12396
Definition: type_result.h:42
Definition: grphload.c:88
static SCIP_RETCODE createRelaxation(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:862
SCIP_RETCODE SCIPcalcNegatedCliquePartition(SCIP *const scip, SCIP_VAR **const vars, int const nvars, int *const cliquepartition, int *const ncliques)
Definition: scip_var.c:7385
static SCIP_RETCODE getLiftingSequence(SCIP *scip, SCIP_Real *solvals, SCIP_Longint *weights, int *varsF, int *varsC2, int *varsR, int nvarsF, int nvarsC2, int nvarsR)
Definition: cons_knapsack.c:2798
public methods for constraint handler plugins and constraints
Definition: type_retcode.h:34
SCIP_RETCODE SCIPresetConsAge(SCIP *scip, SCIP_CONS *cons)
Definition: scip_cons.c:1748
static SCIP_DECL_CONSPRESOL(consPresolKnapsack)
Definition: cons_knapsack.c:12486
static SCIP_RETCODE consdataEnsureVarsSize(SCIP *scip, SCIP_CONSDATA *consdata, int num, SCIP_Bool transformed)
Definition: cons_knapsack.c:588
static SCIP_RETCODE delCoefPos(SCIP *scip, SCIP_CONS *cons, int pos)
Definition: cons_knapsack.c:6309
SCIP_RETCODE SCIPcopyConsLinear(SCIP *scip, SCIP_CONS **cons, SCIP *sourcescip, const char *name, int nvars, SCIP_VAR **sourcevars, SCIP_Real *sourcecoefs, SCIP_Real lhs, SCIP_Real rhs, SCIP_HASHMAP *varmap, SCIP_HASHMAP *consmap, SCIP_Bool initial, SCIP_Bool separate, SCIP_Bool enforce, SCIP_Bool check, SCIP_Bool propagate, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool dynamic, SCIP_Bool removable, SCIP_Bool stickingatnode, SCIP_Bool global, SCIP_Bool *valid)
Definition: cons_linear.c:17745
SCIP_RETCODE SCIPsetConshdlrSepa(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSSEPALP((*conssepalp)), SCIP_DECL_CONSSEPASOL((*conssepasol)), int sepafreq, int sepapriority, SCIP_Bool delaysepa)
Definition: scip_cons.c:219
public data structures and miscellaneous methods
static SCIP_RETCODE enlargeMinweights(SCIP *scip, SCIP_Longint **minweightsptr, int *minweightslen, int *minweightssize, int newlen)
Definition: cons_knapsack.c:3403
SCIP_RETCODE SCIPunlockVarCons(SCIP *scip, SCIP_VAR *var, SCIP_CONS *cons, SCIP_Bool lockdown, SCIP_Bool lockup)
Definition: scip_var.c:4376
SCIP_EXPORT void SCIPsortRealInt(SCIP_Real *realarray, int *intarray, int len)
SCIP_RETCODE SCIPdropVarEvent(SCIP *scip, SCIP_VAR *var, SCIP_EVENTTYPE eventtype, SCIP_EVENTHDLR *eventhdlr, SCIP_EVENTDATA *eventdata, int filterpos)
Definition: scip_event.c:390
SCIP_EXPORT SCIP_Real SCIPvarGetMultaggrConstant(SCIP_VAR *var)
Definition: var.c:17156
SCIP_RETCODE SCIPsetConsInitial(SCIP *scip, SCIP_CONS *cons, SCIP_Bool initial)
Definition: scip_cons.c:1207
SCIP_RETCODE SCIPhashmapCreate(SCIP_HASHMAP **hashmap, BMS_BLKMEM *blkmem, int mapsize)
Definition: misc.c:2891
static SCIP_RETCODE calcCliquepartition(SCIP *scip, SCIP_CONSHDLRDATA *conshdlrdata, SCIP_CONSDATA *consdata, SCIP_Bool normalclique, SCIP_Bool negatedclique)
Definition: cons_knapsack.c:468
SCIP_EXPORT void SCIPsortIntInt(int *intarray1, int *intarray2, int len)
static SCIP_RETCODE superadditiveUpLifting(SCIP *scip, SCIP_VAR **vars, int nvars, int ntightened, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *covervars, int *noncovervars, int ncovervars, int nnoncovervars, SCIP_Longint coverweight, SCIP_Real *liftcoefs, SCIP_Real *cutact)
Definition: cons_knapsack.c:4637
SCIP_RETCODE SCIPsetConshdlrCopy(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSHDLRCOPY((*conshdlrcopy)), SCIP_DECL_CONSCOPY((*conscopy)))
Definition: scip_cons.c:331
SCIP_RETCODE SCIPprintCons(SCIP *scip, SCIP_CONS *cons, FILE *file)
Definition: scip_cons.c:2472
Definition: type_message.h:43
Definition: type_var.h:46
static SCIP_RETCODE greedyCliqueAlgorithm(SCIP *const scip, SCIP_VAR **items, SCIP_Longint *weights, int nitems, SCIP_Longint capacity, SCIP_Bool sorteditems, SCIP_Real cliqueextractfactor, SCIP_Bool *const cutoff, int *const nbdchgs)
Definition: cons_knapsack.c:11116
SCIP_CONSHDLRDATA * SCIPconshdlrGetData(SCIP_CONSHDLR *conshdlr)
Definition: cons.c:4211
static SCIP_DECL_CONSEXITPRE(consExitpreKnapsack)
Definition: cons_knapsack.c:12097
static SCIP_RETCODE consdataCreate(SCIP *scip, SCIP_CONSDATA **consdata, int nvars, SCIP_VAR **vars, SCIP_Longint *weights, SCIP_Longint capacity)
Definition: cons_knapsack.c:646
Definition: struct_lp.h:192
static SCIP_RETCODE eventdataCreate(SCIP *scip, SCIP_EVENTDATA **eventdata, SCIP_CONS *cons, SCIP_Longint weight)
Definition: cons_knapsack.c:336
SCIP_RETCODE SCIPsetConsPropagated(SCIP *scip, SCIP_CONS *cons, SCIP_Bool propagate)
Definition: scip_cons.c:1307
SCIP_RETCODE SCIPcreateEmptyRowCons(SCIP *scip, SCIP_ROW **row, SCIP_CONSHDLR *conshdlr, const char *name, SCIP_Real lhs, SCIP_Real rhs, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool removable)
Definition: scip_lp.c:1268
public methods for LP management
static SCIP_RETCODE GUBsetCreate(SCIP *scip, SCIP_GUBSET **gubset, int nvars, SCIP_Longint *weights, SCIP_Longint capacity)
Definition: cons_knapsack.c:1923
public methods for cuts and aggregation rows
SCIP_VAR ** SCIPgetVarsKnapsack(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:13638
SCIP_RETCODE SCIPupdateCutoffbound(SCIP *scip, SCIP_Real cutoffbound)
Definition: scip_solvingstats.c:1496
Definition: type_var.h:45
SCIP_Bool SCIPisCutEfficacious(SCIP *scip, SCIP_SOL *sol, SCIP_ROW *cut)
Definition: scip_cut.c:87
SCIP_RETCODE SCIPaddConflictBinvar(SCIP *scip, SCIP_VAR *var)
Definition: scip_conflict.c:546
SCIP_Real SCIPgetDualsolKnapsack(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:13680
Definition: cons_knapsack.c:272
SCIP_RETCODE SCIPfixVar(SCIP *scip, SCIP_VAR *var, SCIP_Real fixedval, SCIP_Bool *infeasible, SCIP_Bool *fixed)
Definition: scip_var.c:8180
static void normalizeWeights(SCIP_CONS *cons, int *nchgcoefs, int *nchgsides)
Definition: cons_knapsack.c:8312
Constraint handler for linear constraints in their most general form, .
SCIP_RETCODE SCIPanalyzeConflictCons(SCIP *scip, SCIP_CONS *cons, SCIP_Bool *success)
Definition: scip_conflict.c:693
SCIP_EXPORT SCIP_CLIQUE ** SCIPvarGetCliques(SCIP_VAR *var, SCIP_Bool varfixing)
Definition: var.c:17715
SCIP_RETCODE SCIPcreateConsCardinality(SCIP *scip, SCIP_CONS **cons, const char *name, int nvars, SCIP_VAR **vars, int cardval, SCIP_VAR **indvars, SCIP_Real *weights, SCIP_Bool initial, SCIP_Bool separate, SCIP_Bool enforce, SCIP_Bool check, SCIP_Bool propagate, SCIP_Bool local, SCIP_Bool dynamic, SCIP_Bool removable, SCIP_Bool stickingatnode)
Definition: cons_cardinality.c:3296
SCIP_Bool SCIPisFeasGE(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:823
static SCIP_RETCODE prepareCons(SCIP *scip, SCIP_CONS *cons, int *nfixedvars, int *ndelconss, int *nchgcoefs)
Definition: cons_knapsack.c:9246
static SCIP_RETCODE deleteRedundantVars(SCIP *scip, SCIP_CONS *cons, SCIP_Longint frontsum, int splitpos, int *nchgcoefs, int *nchgsides, int *naddconss)
Definition: cons_knapsack.c:7873
static SCIP_RETCODE changePartitionCovervars(SCIP *scip, SCIP_Longint *weights, int *varsC1, int *varsC2, int *nvarsC1, int *nvarsC2)
Definition: cons_knapsack.c:2669
SCIP_RETCODE SCIPincludeEventhdlrBasic(SCIP *scip, SCIP_EVENTHDLR **eventhdlrptr, const char *name, const char *desc, SCIP_DECL_EVENTEXEC((*eventexec)), SCIP_EVENTHDLRDATA *eventhdlrdata)
Definition: scip_event.c:94
SCIP_RETCODE SCIPaddRealParam(SCIP *scip, const char *name, const char *desc, SCIP_Real *valueptr, SCIP_Bool isadvanced, SCIP_Real defaultvalue, SCIP_Real minvalue, SCIP_Real maxvalue, SCIP_DECL_PARAMCHGD((*paramchgd)), SCIP_PARAMDATA *paramdata)
Definition: scip_param.c:129
SCIP_RETCODE SCIPunmarkConsPropagate(SCIP *scip, SCIP_CONS *cons)
Definition: scip_cons.c:1978
static SCIP_RETCODE dropEvents(SCIP *scip, SCIP_CONSDATA *consdata, SCIP_EVENTHDLR *eventhdlr)
Definition: cons_knapsack.c:563
public methods for the LP relaxation, rows and columns
SCIP_Real SCIPgetVarUbAtIndex(SCIP *scip, SCIP_VAR *var, SCIP_BDCHGIDX *bdchgidx, SCIP_Bool after)
Definition: scip_var.c:2130
static SCIP_RETCODE dualPresolving(SCIP *scip, SCIP_CONS *cons, int *nfixedvars, int *ndelconss, SCIP_Bool *deleted)
Definition: cons_knapsack.c:6708
SCIP_EXPORT int SCIPvarGetNLocksDownType(SCIP_VAR *var, SCIP_LOCKTYPE locktype)
Definition: var.c:3184
SCIP_EXPORT void SCIPselectWeightedDownRealLongRealInt(SCIP_Real *realarray1, SCIP_Longint *longarray, SCIP_Real *realarray3, int *intarray, SCIP_Real *weights, SCIP_Real capacity, int len, int *medianpos)
static SCIP_RETCODE upgradeCons(SCIP *scip, SCIP_CONS *cons, int *ndelconss, int *naddconss)
Definition: cons_knapsack.c:7801
static SCIP_DECL_CONSSEPALP(consSepalpKnapsack)
Definition: cons_knapsack.c:12244
Definition: type_set.h:36
methods for sorting joint arrays of various types
SCIP_RETCODE SCIPgetSolVals(SCIP *scip, SCIP_SOL *sol, int nvars, SCIP_VAR **vars, SCIP_Real *vals)
Definition: scip_sol.c:1389
static SCIP_RETCODE sequentialUpAndDownLifting(SCIP *scip, SCIP_VAR **vars, int nvars, int ntightened, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *varsM1, int *varsM2, int *varsF, int *varsR, int nvarsM1, int nvarsM2, int nvarsF, int nvarsR, int alpha0, int *liftcoefs, SCIP_Real *cutact, int *liftrhs)
Definition: cons_knapsack.c:3453
public methods for branching rule plugins and branching
static SCIP_RETCODE createNormalizedKnapsack(SCIP *scip, SCIP_CONS **cons, const char *name, int nvars, SCIP_VAR **vars, SCIP_Real *vals, SCIP_Real lhs, SCIP_Real rhs, SCIP_Bool initial, SCIP_Bool separate, SCIP_Bool enforce, SCIP_Bool check, SCIP_Bool propagate, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool dynamic, SCIP_Bool removable, SCIP_Bool stickingatnode)
Definition: cons_knapsack.c:11842
static SCIP_DECL_LINCONSUPGD(linconsUpgdKnapsack)
Definition: cons_knapsack.c:11937
SCIP_RETCODE SCIPaddRow(SCIP *scip, SCIP_ROW *row, SCIP_Bool forcecut, SCIP_Bool *infeasible)
Definition: scip_cut.c:220
Definition: struct_misc.h:79
static SCIP_RETCODE GUBconsCreate(SCIP *scip, SCIP_GUBCONS **gubcons)
Definition: cons_knapsack.c:1679
public methods for managing events
general public methods
static SCIP_RETCODE GUBsetCheck(SCIP *scip, SCIP_GUBSET *gubset, SCIP_VAR **vars)
Definition: cons_knapsack.c:2006
SCIP_Bool SCIPisFeasGT(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:810
static SCIP_DECL_CONSGETNVARS(consGetNVarsKnapsack)
Definition: cons_knapsack.c:13218
SCIP_Real SCIPgetDualfarkasKnapsack(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:13704
public methods for solutions
SCIP_EXPORT void SCIPsortDownPtrInt(void **ptrarray, int *intarray, SCIP_DECL_SORTPTRCOMP((*ptrcomp)), int len)
static SCIP_RETCODE detectRedundantConstraints(SCIP *scip, BMS_BLKMEM *blkmem, SCIP_CONS **conss, int nconss, SCIP_Bool *cutoff, int *ndelconss)
Definition: cons_knapsack.c:11462
Definition: type_lp.h:48
public methods for the probing mode
SCIP_Bool SCIPisFeasLT(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:784
constraint handler for cardinality constraints
SCIP_RETCODE SCIPaddVarToRow(SCIP *scip, SCIP_ROW *row, SCIP_VAR *var, SCIP_Real val)
Definition: scip_lp.c:1539
static SCIP_Bool checkMinweightidx(SCIP_Longint *weights, SCIP_Longint capacity, int *covervars, int ncovervars, SCIP_Longint coverweight, int minweightidx, int j)
Definition: cons_knapsack.c:2577
SCIP_EXPORT int SCIPvarGetMultaggrNVars(SCIP_VAR *var)
Definition: var.c:17120
Definition: cons_knapsack.c:270
public methods for message output
SCIP_EXPORT SCIP_Real * SCIPvarGetVlbConstants(SCIP_VAR *var)
Definition: var.c:17576
SCIP_RETCODE SCIPaddClique(SCIP *scip, SCIP_VAR **vars, SCIP_Bool *values, int nvars, SCIP_Bool isequation, SCIP_Bool *infeasible, int *nbdchgs)
Definition: scip_var.c:6831
Definition: type_var.h:84
SCIP_RETCODE SCIPaddIntParam(SCIP *scip, const char *name, const char *desc, int *valueptr, SCIP_Bool isadvanced, int defaultvalue, int minvalue, int maxvalue, SCIP_DECL_PARAMCHGD((*paramchgd)), SCIP_PARAMDATA *paramdata)
Definition: scip_param.c:73
static SCIP_DECL_CONSGETVARS(consGetVarsKnapsack)
Definition: cons_knapsack.c:13196
Definition: cons_knapsack.c:282
static SCIP_RETCODE GUBconsAddVar(SCIP *scip, SCIP_GUBCONS *gubcons, int var)
Definition: cons_knapsack.c:1720
static SCIP_RETCODE unlockRounding(SCIP *scip, SCIP_CONS *cons, SCIP_VAR *var)
Definition: cons_knapsack.c:523
Definition: struct_implics.h:66
SCIP_Bool SCIPisLT(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:449
public methods for message handling
static SCIP_DECL_CONSSEPASOL(consSepasolKnapsack)
Definition: cons_knapsack.c:12318
SCIP_Bool SCIPisGT(SCIP *scip, SCIP_Real val1, SCIP_Real val2)
Definition: scip_numerics.c:475
static SCIP_RETCODE tightenWeights(SCIP *scip, SCIP_CONS *cons, SCIP_PRESOLTIMING presoltiming, int *nchgcoefs, int *nchgsides, int *naddconss, int *ndelconss, SCIP_Bool *cutoff)
Definition: cons_knapsack.c:10325
static SCIP_DECL_CONSENFOLP(consEnfolpKnapsack)
Definition: cons_knapsack.c:12378
static SCIP_RETCODE removeZeroWeights(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:6499
Definition: cons_knapsack.c:269
SCIP_RETCODE SCIPsolveKnapsackApproximately(SCIP *scip, int nitems, SCIP_Longint *weights, SCIP_Real *profits, SCIP_Longint capacity, int *items, int *solitems, int *nonsolitems, int *nsolitems, int *nnonsolitems, SCIP_Real *solval)
Definition: cons_knapsack.c:1541
SCIP_EXPORT SCIP_BOUNDTYPE * SCIPvarGetImplTypes(SCIP_VAR *var, SCIP_Bool varfixing)
Definition: var.c:17662
Definition: type_retcode.h:45
SCIP_EXPORT SCIP_Bool SCIPvarsHaveCommonClique(SCIP_VAR *var1, SCIP_Bool value1, SCIP_VAR *var2, SCIP_Bool value2, SCIP_Bool regardimplics)
Definition: var.c:10972
Definition: type_set.h:44
static SCIP_RETCODE makeCoverMinimal(SCIP *scip, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *covervars, int *noncovervars, int *ncovervars, int *nnoncovervars, SCIP_Longint *coverweight, SCIP_Bool modtransused)
Definition: cons_knapsack.c:5283
SCIP_RETCODE SCIPcatchVarEvent(SCIP *scip, SCIP_VAR *var, SCIP_EVENTTYPE eventtype, SCIP_EVENTHDLR *eventhdlr, SCIP_EVENTDATA *eventdata, int *filterpos)
Definition: scip_event.c:344
SCIP_EXPORT SCIP_RETCODE SCIPvarGetProbvarBinary(SCIP_VAR **var, SCIP_Bool *negated)
Definition: var.c:11804
#define SCIPfreeBlockMemoryArrayNull(scip, ptr, num)
Definition: scip_mem.h:98
static SCIP_RETCODE getFeasibleSet(SCIP *scip, SCIP_CONS *cons, SCIP_SEPA *sepa, SCIP_VAR **vars, int nvars, int ntightened, SCIP_Longint *weights, SCIP_Longint capacity, SCIP_Real *solvals, int *covervars, int *noncovervars, int *ncovervars, int *nnoncovervars, SCIP_Longint *coverweight, SCIP_Bool modtransused, SCIP_SOL *sol, SCIP_Bool *cutoff, int *ncuts)
Definition: cons_knapsack.c:5432
static SCIP_RETCODE preprocessConstraintPairs(SCIP *scip, SCIP_CONS **conss, int firstchange, int chkind, int *ndelconss)
Definition: cons_knapsack.c:11586
static SCIP_RETCODE lockRounding(SCIP *scip, SCIP_CONS *cons, SCIP_VAR *var)
Definition: cons_knapsack.c:510
public methods for separators
Definition: type_retcode.h:35
SCIP_RETCODE SCIPcreateConsSetpack(SCIP *scip, SCIP_CONS **cons, const char *name, int nvars, SCIP_VAR **vars, SCIP_Bool initial, SCIP_Bool separate, SCIP_Bool enforce, SCIP_Bool check, SCIP_Bool propagate, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool dynamic, SCIP_Bool removable, SCIP_Bool stickingatnode)
Definition: cons_setppc.c:9119
SCIP_RETCODE SCIPaddCoefKnapsack(SCIP *scip, SCIP_CONS *cons, SCIP_VAR *var, SCIP_Longint weight)
Definition: cons_knapsack.c:13543
static SCIP_RETCODE eventdataFree(SCIP *scip, SCIP_EVENTDATA **eventdata)
Definition: cons_knapsack.c:354
static SCIP_RETCODE detectRedundantVars(SCIP *scip, SCIP_CONS *cons, int *ndelconss, int *nchgcoefs, int *nchgsides, int *naddconss)
Definition: cons_knapsack.c:8124
void SCIPinfoMessage(SCIP *scip, FILE *file, const char *formatstr,...)
Definition: scip_message.c:198
SCIP_EXPORT int SCIPvarGetNCliques(SCIP_VAR *var, SCIP_Bool varfixing)
Definition: var.c:17704
SCIP_RETCODE SCIPflattenVarAggregationGraph(SCIP *scip, SCIP_VAR *var)
Definition: scip_var.c:1696
Definition: type_retcode.h:43
SCIP_RETCODE SCIPreleaseCons(SCIP *scip, SCIP_CONS **cons)
Definition: scip_cons.c:1109
SCIP_RETCODE SCIPincludeLinconsUpgrade(SCIP *scip, SCIP_DECL_LINCONSUPGD((*linconsupgd)), int priority, const char *conshdlrname)
Definition: cons_linear.c:17494
SCIP_RETCODE SCIPincludeConshdlrKnapsack(SCIP *scip)
Definition: cons_knapsack.c:13299
SCIP_RETCODE SCIPsetConshdlrParse(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSPARSE((*consparse)))
Definition: scip_cons.c:792
Definition: objbenders.h:33
SCIP_RETCODE SCIPsetConshdlrProp(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSPROP((*consprop)), int propfreq, SCIP_Bool delayprop, SCIP_PROPTIMING proptiming)
Definition: scip_cons.c:265
SCIP_RETCODE SCIPcalcIntegralScalar(SCIP_Real *vals, int nvals, SCIP_Real mindelta, SCIP_Real maxdelta, SCIP_Longint maxdnom, SCIP_Real maxscale, SCIP_Real *intscalar, SCIP_Bool *success)
Definition: misc.c:9123
static SCIP_DECL_CONSHDLRCOPY(conshdlrCopyKnapsack)
Definition: cons_knapsack.c:11976
public methods for global and local (sub)problems
Definition: type_var.h:43
SCIP_EXPORT SCIP_Real * SCIPvarGetVubConstants(SCIP_VAR *var)
Definition: var.c:17618
static SCIP_RETCODE changePartitionFeasiblesetvars(SCIP *scip, SCIP_Longint *weights, int *varsC1, int *varsC2, int *nvarsC1, int *nvarsC2)
Definition: cons_knapsack.c:2709
static SCIP_RETCODE tightenWeightsLift(SCIP *scip, SCIP_CONS *cons, int *nchgcoefs, SCIP_Bool *cutoff)
Definition: cons_knapsack.c:9761
SCIP_Bool SCIPisEfficacious(SCIP *scip, SCIP_Real efficacy)
Definition: scip_cut.c:105
static SCIP_RETCODE addCliques(SCIP *const scip, SCIP_CONS *const cons, SCIP_Real cliqueextractfactor, SCIP_Bool *const cutoff, int *const nbdchgs)
Definition: cons_knapsack.c:11227
SCIP_EXPORT SCIP_VAR ** SCIPvarGetMultaggrVars(SCIP_VAR *var)
Definition: var.c:17132
Definition: type_result.h:39
Definition: struct_event.h:186
SCIP_RETCODE SCIPsetConshdlrInitlp(SCIP *scip, SCIP_CONSHDLR *conshdlr, SCIP_DECL_CONSINITLP((*consinitlp)))
Definition: scip_cons.c:608
SCIP_Longint SCIPgetCapacityKnapsack(SCIP *scip, SCIP_CONS *cons)
Definition: cons_knapsack.c:13564
SCIP_RETCODE SCIPcreateEmptyRowSepa(SCIP *scip, SCIP_ROW **row, SCIP_SEPA *sepa, const char *name, SCIP_Real lhs, SCIP_Real rhs, SCIP_Bool local, SCIP_Bool modifiable, SCIP_Bool removable)
Definition: scip_lp.c:1297
SCIP_Longint SCIPconshdlrGetNCutsFound(SCIP_CONSHDLR *conshdlr)
Definition: cons.c:4847
static void computeMinweightsGUB(SCIP_Longint *minweights, SCIP_Longint *finished, SCIP_Longint *unfinished, int minweightslen)
Definition: cons_knapsack.c:3850
methods for selecting (weighted) k-medians
SCIP_Bool SCIPisFeasPositive(SCIP *scip, SCIP_Real val)
Definition: scip_numerics.c:848
SCIP_RETCODE SCIPsetConsChecked(SCIP *scip, SCIP_CONS *cons, SCIP_Bool check)
Definition: scip_cons.c:1282
SCIP_RETCODE SCIPhashmapSetImageInt(SCIP_HASHMAP *hashmap, void *origin, int image)
Definition: misc.c:3174
memory allocation routines