// (C) Copyright International Business Machines Corporation 2007 // All Rights Reserved. // This code is published under the Eclipse Public License. // // Authors : // Pierre Bonami, International Business Machines Corporation // // Date : 04/19/2007 #ifndef BonCbc_H #define BonCbc_H //#include "BonBabSetupBase.hpp" #include "CbcModel.hpp" namespace Bonmin { class BabSetupBase; class Bab { public: /** Integer optimization return codes.*/ enum MipStatuses {FeasibleOptimal /** Optimum solution has been found and its optimality proved.*/, ProvenInfeasible /** Problem has been proven to be infeasible.*/, Feasible /** An integer solution to the problem has been found.*/, UnboundedOrInfeasible /*Coninuous relaxation is unbounded.*/, NoSolutionKnown/** No feasible solution to the problem is known*/, NumMipStats}; /** Constructor.*/ Bab(); /** destructor.*/ virtual ~Bab(); /** Perform a branch-and-bound using given setup.*/ virtual void branchAndBound(BabSetupBase & s); /**operator() performs the branchAndBound*/ virtual void operator()(BabSetupBase & s); /**operator() performs the branchAndBound*/ virtual void operator()(BabSetupBase * s){ operator()(*s);} /** get the best solution known to the problem (is optimal if MipStatus is FeasibleOptimal). if no solution is known returns NULL.*/ const double * bestSolution() const { return bestSolution_; } /** return objective value of the bestSolution */ double bestObj() const { return bestObj_; } /** return Mip Status */ MipStatuses mipStatus() const { return mipStatus_; } /** return the best known lower bound on the objective value*/ double bestBound(); /** return the total number of nodes explored.*/ int numNodes() const { return numNodes_; } /** return the total number of iterations in the last mip solved.*/ int iterationCount() { return mipIterationCount_; } /** returns the value of the continuous relaxation. */ double continuousRelaxation() { return continuousRelaxation_; } /** virtual callback function to eventually modify objects for integer variable (replace with user set). This is called after CbcModel::findIntegers */ virtual void replaceIntegers(OsiObject ** objects, int numberObjects) {} /** Get cbc model used to solve. */ const CbcModel& model() const { return model_; } /** Get cbc model used to solve as non-const, in case we want to change options before things happen */ CbcModel& model() { return model_; } protected: /** Stores the solution of MIP. */ double * bestSolution_; /** Status of the mip solved*/ MipStatuses mipStatus_; /** objValue of MIP */ double bestObj_; /** best known (lower) bound.*/ double bestBound_; /** Continuous relaxation of the problem */ double continuousRelaxation_; /** Number of nodes enumerated.*/ int numNodes_; /** get total number of iterations in last mip solved.*/ int mipIterationCount_; /** CbcModel used to solve problem.*/ CbcModel model_; /** Message handler for CbcModel. */ CoinMessageHandler * modelHandler_; /** \brief OsiObjects of the model. * this is not null if and only if there are some non-simple-integer branching objects such as SOS constraints. * It is up to Bab to pass them over to appropriate components of the algorithm. */ OsiObject** objects_; /** number of objects.*/ int nObjects_; }; } #endif