// $Id: CbcFollowOn.hpp 1902 2013-04-10 16:58:16Z stefan $ // 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 11/10/2009-- carved out of CbcBranchActual #ifndef CbcFollowOn_H #define CbcFollowOn_H #include "CbcBranchBase.hpp" #include "OsiRowCut.hpp" #include "CoinHelperFunctions.hpp" #include "CoinPackedMatrix.hpp" /** Define a follow on class. The idea of this is that in air-crew scheduling problems crew may fly in on flight A and out on flight B or on some other flight. A useful branch is one which on one side fixes all which go out on flight B to 0, while the other branch fixes all those that do NOT go out on flight B to 0. This branching rule should be in addition to normal rules and have a high priority. */ class CbcFollowOn : public CbcObject { public: // Default Constructor CbcFollowOn (); /** Useful constructor */ CbcFollowOn (CbcModel * model); // Copy constructor CbcFollowOn ( const CbcFollowOn &); /// Clone virtual CbcObject * clone() const; // Assignment operator CbcFollowOn & operator=( const CbcFollowOn& rhs); // Destructor ~CbcFollowOn (); /// 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) ; /// As some computation is needed in more than one place - returns row virtual int gutsOfFollowOn(int & otherRow, int & preferredWay) const; protected: /// data /// Matrix CoinPackedMatrix matrix_; /// Matrix by row CoinPackedMatrix matrixByRow_; /// Possible rhs (if 0 then not possible) int * rhs_; }; /** General Branching Object class. Each way fixes some variables to lower bound */ class CbcFixingBranchingObject : public CbcBranchingObject { public: // Default Constructor CbcFixingBranchingObject (); // Useful constructor CbcFixingBranchingObject (CbcModel * model, int way, int numberOnDownSide, const int * down, int numberOnUpSide, const int * up); // Copy constructor CbcFixingBranchingObject ( const CbcFixingBranchingObject &); // Assignment operator CbcFixingBranchingObject & operator=( const CbcFixingBranchingObject& rhs); /// Clone virtual CbcBranchingObject * clone() const; // Destructor virtual ~CbcFixingBranchingObject (); using CbcBranchingObject::branch ; /// Does next branch and updates state virtual double branch(); #ifdef JJF_ZERO // No need to override. Default works fine. /** 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(); #endif 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 FollowOnBranchObj; } /** 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); private: /// data /// Number on down list int numberDown_; /// Number on up list int numberUp_; /// downList - variables to fix to lb on down branch int * downList_; /// upList - variables to fix to lb on up branch int * upList_; }; /** Define an idiotic idea class. The idea of this is that we take some integer variables away from integer and sum them with some randomness to get signed sum close to 0.5. We then can branch to exclude that gap. This branching rule should be in addition to normal rules and have a high priority. */ class CbcIdiotBranch : public CbcObject { public: // Default Constructor CbcIdiotBranch (); /** Useful constructor */ CbcIdiotBranch (CbcModel * model); // Copy constructor CbcIdiotBranch ( const CbcIdiotBranch &); /// Clone virtual CbcObject * clone() const; // Assignment operator CbcIdiotBranch & operator=( const CbcIdiotBranch& rhs); // Destructor ~CbcIdiotBranch (); /// 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) ; /// Initialize for branching virtual void initializeForBranching(CbcModel * ); protected: /// Build "cut" OsiRowCut buildCut(const OsiBranchingInformation * info,int type,int & preferredWay) const; /// data /// Thread specific random number generator mutable CoinThreadRandom randomNumberGenerator_; /// Saved version of thread specific random number generator mutable CoinThreadRandom savedRandomNumberGenerator_; }; #endif