type_benders.h
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31 /*---+----1----+----2----+----3----+----4----+----5----+----6----+----7----+----8----+----9----+----0----+----1----+----2*/
46 SCIP_BENDERSENFOTYPE_LP = 1, /**< the Benders' subproblems are solved during the enforcement of an LP solution */
47 SCIP_BENDERSENFOTYPE_RELAX = 2, /**< the Benders' subproblems are solved during the enforcement of a relaxation solution */
48 SCIP_BENDERSENFOTYPE_PSEUDO = 3, /**< the Benders' subproblems are solved during the enforcement of a pseudo solution */
49 SCIP_BENDERSENFOTYPE_CHECK = 4 /**< the Benders' subproblems are solved during the checking of a solution for feasibility */
51 typedef enum SCIP_BendersEnfoType SCIP_BENDERSENFOTYPE; /**< indicates the callback in cons_benders and cons_benderslp that triggered the subproblem solve */
60 typedef enum SCIP_BendersSolveLoop SCIP_BENDERSSOLVELOOP; /**< identifies the type of problem solved in each solve loop */
66 SCIP_BENDERSSUBSTATUS_AUXVIOL = 2, /**< the subproblem is optimal, but the auxiliary variable is violated */
73 SCIP_BENDERSSUBTYPE_CONVEXCONT = 0, /**< the subproblem has convex constraints and continuous variables */
74 SCIP_BENDERSSUBTYPE_CONVEXDIS = 1, /**< the subproblem has convex constraints and discrete variables */
75 SCIP_BENDERSSUBTYPE_NONCONVEXCONT = 2, /**< the subproblem has non-convex constraints and continuous variables */
76 SCIP_BENDERSSUBTYPE_NONCONVEXDIS = 3, /**< the subproblem has non-convex constraints and discrete variables */
82 typedef struct SCIP_BendersData SCIP_BENDERSDATA; /**< locally defined Benders' decomposition data */
83 typedef struct SCIP_SubproblemSolveStat SCIP_SUBPROBLEMSOLVESTAT; /**< the solving statistics of the subproblems */
86 /** copy method for Benders' decomposition plugins (called when SCIP copies plugins). If there is an active Benders'
87 * decomposition, all copies are not valid. As such, there is no valid parameter that is passed to the callback
95 #define SCIP_DECL_BENDERSCOPY(x) SCIP_RETCODE x (SCIP* scip, SCIP_BENDERS* benders, SCIP_Bool threadsafe)
105 /** initialization method of Benders' decomposition (called after problem was transformed and the Benders' decomposition
114 /** deinitialization method of Benders' decomposition (called before transformed problem is freed and the Benders'
123 /** presolving initialization method of the Benders' decomposition (called when presolving is about to begin)
125 * This function is called immediately after the auxiliary variables are created in the master problem. The callback
134 /** presolving deinitialization method of the Benders' decomposition (called after presolving has been finished)
142 /** solving process initialization method of Benders' decomposition (called when branch and bound process is about to begin)
144 * This method is called when the presolving was finished and the branch and bound process is about to begin.
145 * The Benders' decomposition may use this call to initialize its branch and bound specific data.
153 /** solving process deinitialization method of Benders' decomposition (called before branch and bound process data is freed)
164 /** the method for creating the Benders' decomposition subproblem. This method is called during the initialisation stage
167 * @note When the create subproblem callback is invoked, the mapping between the master problem and subproblem
168 * variables must be available. The create subproblem callback is invoked immediately after BENDERSINIT. So, it is
171 * This method must register the SCIP instance for the subproblem with the Benders' decomposition core by calling
172 * SCIPaddBendersSubproblem. Typically, the user must create the SCIP instances for the subproblems. These can be
173 * created within a reader or probdata and then registered with the Benders' decomposition core during the call of this
174 * callback. If there are any settings required for solving the subproblems, then they should be set here. However,
175 * some settings will be overridden by the standard solving method included in the Benders' decomposition framework.
176 * If a special solving method is desired, the user can implement the bendersSolvesubXyz callback. In this latter case,
177 * it is possible to provide a NULL pointer to SCIPaddBendersSubproblem. This will ensure that no internal solving
178 * methods available within the Benders' decomposition core are invoked during the solving process.
180 * If the user defines a subproblem solving method, then in BENDERSCREATESUB, the user must explicitly specify the
181 * subproblem type. This is necessary because the dual solutions from convex problems can be used to generate cuts.
182 * The classical Benders' optimality and feasibility cuts require that the subproblems are convex. The subproblem type
183 * is specified by calling SCIPbendersSetSubproblemType. The available subproblem types are defined in
186 * If the user does NOT implement a subproblem solving method, then the convexity of the problem is determined
194 #define SCIP_DECL_BENDERSCREATESUB(x) SCIP_RETCODE x (SCIP* scip, SCIP_BENDERS* benders, int probnumber)
196 /** called before the subproblem solving loop for Benders' decomposition. The pre subproblem solve function gives the
205 * - infeasible : flag to return whether the master problem in infeasible with respect to the added cuts
208 * - result : a result to be returned to the Benders' constraint handler if the solve is skipped. If the
211 * possible return values for *result (if more than one applies, the first in the list should be used):
212 * - SCIP_DIDNOTRUN : the subproblem was not solved in this iteration. Other decompositions will be checked.
213 * - SCIP_CONSADDED : a constraint has been added to the master problem. No other decompositions will be checked.
214 * - SCIP_SEPARATED : a cut has been added to the master problem. No other decompositions will be checked.
215 * - SCIP_FEASIBLE : feasibility of the solution is reported to SCIP. Other decompositions will be checked.
216 * - SCIP_INFEASIBLE : infeasibility of the solution is reported to SCIP. No other decompositions will be checked.
218 #define SCIP_DECL_BENDERSPRESUBSOLVE(x) SCIP_RETCODE x (SCIP* scip, SCIP_BENDERS* benders, SCIP_SOL* sol,\
219 SCIP_BENDERSENFOTYPE type, SCIP_Bool checkint, SCIP_Bool* infeasible, SCIP_Bool* auxviol, SCIP_Bool* skipsolve,\
222 /** the solving method for a convex Benders' decomposition subproblem. This call back is provided to solve problems
223 * for which the dual soluitons are used to generate Benders' decomposition cuts. In the classical Benders'
224 * decomposition implementation, this would be an LP. However, it can be any convex problem where the dual solutions
227 * In the Benders' decomposition subproblem solving process, there are two solving loops. The first is where the convex
228 * subproblems, and the convex relaxations of subproblems, are solved. If no cuts are generated after this solving
229 * loop, then the second loop solves subproblems defined as CIPs. This callback is executed during the FIRST solving
232 * In the classical Benders' decomposition implementation, if the subproblems are all LPs the only the
233 * BENDERSSOLVESUBCONVEX need to be implemented. If the subproblems are MIPs, then it is useful to only implement a
234 * single SCIP instance for the subproblem and then change the variable types of the appropriate variables to
248 * - onlyconvexcheck : flag to indicate that only the convex relaxations will be checked in this solving loop. This is
253 * possible return values for *result (if more than one applies, the first in the list should be used):
259 #define SCIP_DECL_BENDERSSOLVESUBCONVEX(x) SCIP_RETCODE x (SCIP* scip, SCIP_BENDERS* benders, SCIP_SOL* sol,\
262 /** the solving method for a Benders' decomposition subproblem as a CIP. This call back is provided to solve problems
263 * for which the dual solutions are not well defined. In this case, the cuts are typically generated from the primal
264 * solution to the CIP. In the classical Benders' decomposition implementation, this would be a MIP. However, it can
267 * In the Benders' decomposition subproblem solving process, there are two solving loops. The first is where the convex
268 * subproblems, and the convex relaxations of subproblems, are solved. If no cuts are generated after this solving
269 * loop, then the second loop solves subproblems defined as CIPs. This callback is executed during the SECOND solving
286 * possible return values for *result (if more than one applies, the first in the list should be used):
292 #define SCIP_DECL_BENDERSSOLVESUB(x) SCIP_RETCODE x (SCIP* scip, SCIP_BENDERS* benders, SCIP_SOL* sol, int probnumber,\
295 /** the post-solve method for Benders' decomposition. The post-solve method is called after the subproblems have
296 * been solved but before they have been freed. After the solving of the Benders' decomposition subproblems, the
297 * subproblem solving data is freed in the SCIP_DECL_BENDERSFREESUB callback. However, it is not necessary to implement
300 * If SCIP_DECL_BENDERSFREESUB is not implemented, then the Benders' decomposition framework will perform a default
301 * freeing of the subproblems. If a subproblem is an LP, then they will be in probing mode for the subproblem
302 * solve. So the freeing process involves ending the probing mode. If the subproblem is a MIP, then the subproblem is
303 * solved by calling SCIPsolve. As such, the transformed problem must be freed after each subproblem solve.
305 * This callback provides the opportunity for the user to clean up any data structures that should not exist beyond the current
307 * The user has full access to the master and subproblems in this callback. So it is possible to construct solution for
309 * Additionally, if there are any subproblems that are infeasibility and this can not be resolved, then the it is
310 * possible to merge these subproblems into the master problem. The subproblem indices are given in the mergecands
311 * array. The merging can be perform by a user defined function or by calling SCIPmergeBendersSubproblemIntoMaster. If a
319 * - mergecands : the subproblems that are candidates for merging into the master problem, the first
323 * - nmergecands : the total number of subproblems that are candidates for merging into the master problem
328 #define SCIP_DECL_BENDERSPOSTSOLVE(x) SCIP_RETCODE x (SCIP* scip, SCIP_BENDERS* benders, SCIP_SOL* sol,\
329 SCIP_BENDERSENFOTYPE type, int* mergecands, int npriomergecands, int nmergecands, SCIP_Bool checkint,\
332 /** frees the subproblem so that it can be resolved in the next iteration. As stated above, it is not necessary to
333 * implement this callback. If the callback is implemented, the subproblems should be freed by calling
334 * SCIPfreeTransform(). However, if the subproblems are LPs, then it could be more efficient to put the subproblem
335 * into probing mode prior to solving and then exiting the probing mode during the callback. To put the subproblem into
336 * probing mode, the subproblem must be in SCIP_STAGE_SOLVING. This can be achieved by using eventhandlers.
338 * If SCIP_DECL_BENDERSFREESUB is not implemented, then the Benders' decomposition framework will perform a default
339 * freeing of the subproblems. If a subproblem is an LP, then they will be in probing mode for the subproblem
340 * solve. So the freeing process involves ending the probing mode. If the subproblem is a MIP, then the subproblem is
341 * solved by calling SCIPsolve. As such, the transformed problem must be freed after each subproblem solve.
350 #define SCIP_DECL_BENDERSFREESUB(x) SCIP_RETCODE x (SCIP* scip, SCIP_BENDERS* benders, int probnumber)
352 /** the variable mapping from the subproblem to the master problem. It is neccessary to have a mapping between every
353 * master problem variable and its counterpart in the subproblem. This mapping must go both ways: from master to sub
356 * This method is called when generating the cuts. The cuts are generated by using the solution to the subproblem to
362 * - var : the variable for which the corresponding variable in the master or subproblem is required
364 * - probnumber : the number of the subproblem that the desired variable belongs to, -1 for the master problem
366 #define SCIP_DECL_BENDERSGETVAR(x) SCIP_RETCODE x (SCIP* scip, SCIP_BENDERS* benders, SCIP_VAR* var,\
Definition: type_benders.h:67
Definition: type_benders.h:49
Definition: type_benders.h:55
Definition: type_benders.h:73
type definitions for return codes for SCIP methods
Definition: type_benders.h:46
Definition: struct_benders.h:57
Definition: type_benders.h:48
Definition: type_benders.h:64
Definition: type_benders.h:56
type definitions for SCIP's main datastructure
Definition: struct_benders.h:179
Definition: type_benders.h:47
Definition: type_benders.h:77
Definition: type_benders.h:66
Definition: type_benders.h:65
Definition: type_benders.h:58
common defines and data types used in all packages of SCIP
Definition: type_benders.h:74