/* $Id: CbcHeuristicDiveCoefficient.cpp 1902 2013-04-10 16:58:16Z stefan $ */ // Copyright (C) 2008, International Business Machines // Corporation and others. All Rights Reserved. // This code is licensed under the terms of the Eclipse Public License (EPL). #if defined(_MSC_VER) // Turn off compiler warning about long names # pragma warning(disable:4786) #endif //#define PRINT_DEBUG #include "CbcHeuristicDiveCoefficient.hpp" #include "CbcStrategy.hpp" // Default Constructor CbcHeuristicDiveCoefficient::CbcHeuristicDiveCoefficient() : CbcHeuristicDive() { } // Constructor from model CbcHeuristicDiveCoefficient::CbcHeuristicDiveCoefficient(CbcModel & model) : CbcHeuristicDive(model) { } // Destructor CbcHeuristicDiveCoefficient::~CbcHeuristicDiveCoefficient () { } // Clone CbcHeuristicDiveCoefficient * CbcHeuristicDiveCoefficient::clone() const { return new CbcHeuristicDiveCoefficient(*this); } // Create C++ lines to get to current state void CbcHeuristicDiveCoefficient::generateCpp( FILE * fp) { CbcHeuristicDiveCoefficient other; fprintf(fp, "0#include \"CbcHeuristicDiveCoefficient.hpp\"\n"); fprintf(fp, "3 CbcHeuristicDiveCoefficient heuristicDiveCoefficient(*cbcModel);\n"); CbcHeuristic::generateCpp(fp, "heuristicDiveCoefficient"); fprintf(fp, "3 cbcModel->addHeuristic(&heuristicDiveCoefficient);\n"); } // Copy constructor CbcHeuristicDiveCoefficient::CbcHeuristicDiveCoefficient(const CbcHeuristicDiveCoefficient & rhs) : CbcHeuristicDive(rhs) { } // Assignment operator CbcHeuristicDiveCoefficient & CbcHeuristicDiveCoefficient::operator=( const CbcHeuristicDiveCoefficient & rhs) { if (this != &rhs) { CbcHeuristicDive::operator=(rhs); } return *this; } bool CbcHeuristicDiveCoefficient::selectVariableToBranch(OsiSolverInterface* solver, const double* newSolution, int& bestColumn, int& bestRound) { int numberIntegers = model_->numberIntegers(); const int * integerVariable = model_->integerVariable(); double integerTolerance = model_->getDblParam(CbcModel::CbcIntegerTolerance); bestColumn = -1; bestRound = -1; // -1 rounds down, +1 rounds up double bestFraction = COIN_DBL_MAX; int bestLocks = COIN_INT_MAX; bool allTriviallyRoundableSoFar = true; for (int i = 0; i < numberIntegers; i++) { int iColumn = integerVariable[i]; double value = newSolution[iColumn]; double fraction = value - floor(value); int round = 0; if (fabs(floor(value + 0.5) - value) > integerTolerance) { int nDownLocks = downLocks_[i]; int nUpLocks = upLocks_[i]; if (allTriviallyRoundableSoFar || (nDownLocks > 0 && nUpLocks > 0)) { if (allTriviallyRoundableSoFar && nDownLocks > 0 && nUpLocks > 0) { allTriviallyRoundableSoFar = false; bestFraction = COIN_DBL_MAX; bestLocks = COIN_INT_MAX; } // the variable cannot be rounded int nLocks = nDownLocks; if (nDownLocks < nUpLocks) round = -1; else if (nDownLocks > nUpLocks) { round = 1; fraction = 1.0 - fraction; nLocks = nUpLocks; } else if (fraction < 0.5) round = -1; else { round = 1; fraction = 1.0 - fraction; nLocks = nUpLocks; } // if variable is not binary, penalize it if (!solver->isBinary(iColumn)) fraction *= 1000.0; if (nLocks < bestLocks || (nLocks == bestLocks && fraction < bestFraction)) { bestColumn = iColumn; bestLocks = nLocks; bestFraction = fraction; bestRound = round; } } } } return allTriviallyRoundableSoFar; }