// $Id: CbcSOS.hpp 2070 2014-09-08 09:24:45Z forrest $ // Copyright (C) 2002, International Business Machines // Corporation and others. All Rights Reserved. // This code is licensed under the terms of the Eclipse Public License (EPL). // Edwin 11/9/2009-- carved out of CbcBranchActual #ifndef CbcSOS_H #define CbcSOS_H /** \brief Branching object for Special Ordered Sets of type 1 and 2. SOS1 are an ordered set of variables where at most one variable can be non-zero. SOS1 are commonly defined with binary variables (interpreted as selection between alternatives) but this is not necessary. An SOS1 with all binary variables is a special case of a clique (setting any one variable to 1 forces all others to 0). In theory, the implementation makes no assumptions about integrality in Type 1 sets. In practice, there are places where the code seems to have been written with a binary SOS mindset. Current development of SOS branching objects is proceeding in OsiSOS. SOS2 are an ordered set of variables in which at most two consecutive variables can be non-zero and must sum to 1 (interpreted as interpolation between two discrete values). By definition the variables are non-integer. */ class CbcSOS : public CbcObject { public: // Default Constructor CbcSOS (); /** \brief Constructor with SOS type and member information Type specifies SOS 1 or 2. Identifier is an arbitrary value. Which should be an array of variable indices with numberMembers entries. Weights can be used to assign arbitrary weights to variables, in the order they are specified in which. If no weights are provided, a default array of 0, 1, 2, ... is generated. */ CbcSOS (CbcModel * model, int numberMembers, const int * which, const double * weights, int identifier, int type = 1); // Copy constructor CbcSOS ( const CbcSOS &); /// Clone virtual CbcObject * clone() const; // Assignment operator CbcSOS & operator=( const CbcSOS& rhs); // Destructor virtual ~CbcSOS (); /// Infeasibility - large is 0.5 virtual double infeasibility(const OsiBranchingInformation * info, int &preferredWay) const; using CbcObject::feasibleRegion ; /// This looks at solution and sets bounds to contain solution virtual void feasibleRegion(); /// Creates a branching object virtual CbcBranchingObject * createCbcBranch(OsiSolverInterface * solver, const OsiBranchingInformation * info, int way) ; /** Pass in information on branch just done and create CbcObjectUpdateData instance. If object does not need data then backward pointer will be NULL. Assumes can get information from solver */ virtual CbcObjectUpdateData createUpdateInformation(const OsiSolverInterface * solver, const CbcNode * node, const CbcBranchingObject * branchingObject); /// Update object by CbcObjectUpdateData virtual void updateInformation(const CbcObjectUpdateData & data) ; using CbcObject::solverBranch ; /** Create an OsiSolverBranch object This returns NULL if branch not represented by bound changes */ virtual OsiSolverBranch * solverBranch() const; /// Redoes data when sequence numbers change virtual void redoSequenceEtc(CbcModel * model, int numberColumns, const int * originalColumns); /// Construct an OsiSOS object OsiSOS * osiObject(const OsiSolverInterface * solver) const; /// Number of members inline int numberMembers() const { return numberMembers_; } /// Members (indices in range 0 ... numberColumns-1) inline const int * members() const { return members_; } /// SOS type inline int sosType() const { return sosType_; } /// Down number times inline int numberTimesDown() const { return numberTimesDown_; } /// Up number times inline int numberTimesUp() const { return numberTimesUp_; } /** Array of weights */ inline const double * weights() const { return weights_; } /// Set number of members inline void setNumberMembers(int n) { numberMembers_ = n; } /// Members (indices in range 0 ... numberColumns-1) inline int * mutableMembers() const { return members_; } /** Array of weights */ inline double * mutableWeights() const { return weights_; } /** \brief Return true if object can take part in normal heuristics */ virtual bool canDoHeuristics() const { return (sosType_ == 1 && integerValued_); } /// Set whether set is integer valued or not inline void setIntegerValued(bool yesNo) { integerValued_ = yesNo; } private: /// data /// Members (indices in range 0 ... numberColumns-1) int * members_; /** \brief Weights for individual members Arbitrary weights for members. Can be used to attach meaning to variable values independent of objective coefficients. For example, if the SOS set comprises binary variables used to choose a facility of a given size, the weight could be the corresponding facilty size. Fractional values of the SOS variables can then be used to estimate ideal facility size. Weights cannot be completely arbitrary. From the code, they must be differ by at least 1.0e-7 */ double * weights_; /// Current pseudo-shadow price estimate down mutable double shadowEstimateDown_; /// Current pseudo-shadow price estimate up mutable double shadowEstimateUp_; /// Down pseudo ratio double downDynamicPseudoRatio_; /// Up pseudo ratio double upDynamicPseudoRatio_; /// Number of times we have gone down int numberTimesDown_; /// Number of times we have gone up int numberTimesUp_; /// Number of members int numberMembers_; /// SOS type int sosType_; /// Whether integer valued bool integerValued_; /// Whether odd values e.g. negative bool oddValues_; }; /** Branching object for Special ordered sets Variable_ is the set id number (redundant, as the object also holds a pointer to the set. */ class CbcSOSBranchingObject : public CbcBranchingObject { public: // Default Constructor CbcSOSBranchingObject (); // Useful constructor CbcSOSBranchingObject (CbcModel * model, const CbcSOS * clique, int way, double separator); // Copy constructor CbcSOSBranchingObject ( const CbcSOSBranchingObject &); // Assignment operator CbcSOSBranchingObject & operator=( const CbcSOSBranchingObject& rhs); /// Clone virtual CbcBranchingObject * clone() const; // Destructor virtual ~CbcSOSBranchingObject (); using CbcBranchingObject::branch ; /// Does next branch and updates state virtual double branch(); /** Update bounds in solver as in 'branch' and update given bounds. branchState is -1 for 'down' +1 for 'up' */ virtual void fix(OsiSolverInterface * solver, double * lower, double * upper, int branchState) const ; /** Reset every information so that the branching object appears to point to the previous child. This method does not need to modify anything in any solver. */ virtual void previousBranch() { CbcBranchingObject::previousBranch(); computeNonzeroRange(); } using CbcBranchingObject::print ; /** \brief Print something about branch - only if log level high */ virtual void print(); /** Return the type (an integer identifier) of \c this */ virtual CbcBranchObjType type() const { return SoSBranchObj; } /** Compare the original object of \c this with the original object of \c brObj. Assumes that there is an ordering of the original objects. This method should be invoked only if \c this and brObj are of the same type. Return negative/0/positive depending on whether \c this is smaller/same/larger than the argument. */ virtual int compareOriginalObject(const CbcBranchingObject* brObj) const; /** Compare the \c this with \c brObj. \c this and \c brObj must be os the same type and must have the same original object, but they may have different feasible regions. Return the appropriate CbcRangeCompare value (first argument being the sub/superset if that's the case). In case of overlap (and if \c replaceIfOverlap is true) replace the current branching object with one whose feasible region is the overlap. */ virtual CbcRangeCompare compareBranchingObject (const CbcBranchingObject* brObj, const bool replaceIfOverlap = false); /** Fill out the \c firstNonzero_ and \c lastNonzero_ data members */ void computeNonzeroRange(); private: /// data const CbcSOS * set_; /// separator double separator_; /** The following two members describe the range in the members_ of the original object that whose upper bound is not fixed to 0. This is not necessary for Cbc to function correctly, this is there for heuristics so that separate branching decisions on the same object can be pooled into one branching object. */ int firstNonzero_; int lastNonzero_; }; #endif