Пример #1
0
//#############################################################################
bool
MibSHeuristic::checkLowerFeasibility1(double * solution)
{

  bool feasible(true);
  MibSModel * model = MibSModel_;
  int * lRowIndices = model->getLowerRowInd();
  int lRows(model->getLowerRowNum());
  const double * origRowLb = model->getOrigRowLb();
  const double * origRowUb = model->getOrigRowUb();
  const CoinPackedMatrix * matrix = model->getSolver()->getMatrixByRow();
  const double * matElements = matrix->getElements();
  const int * matIndices = matrix->getIndices();
  const int * matStarts = matrix->getVectorStarts();


  double lhs(0.0);
  int i(0), j(0), index1(0), index2(0), start(0), end(0);

  for(i = 0; i < lRows; i++){
    index1 = lRowIndices[i];
    start = matStarts[index1];
    end = start + matrix->getVectorSize(index1);
    for(j = start; j < end; j++){
      index2 = matIndices[j];
      lhs += matElements[j] * solution[index2];
    }
    if((origRowLb[index1] > lhs) || (lhs > origRowUb[index1]))
      feasible = false;
    lhs = 0.0;
  }

  return feasible;
}
Пример #2
0
//#############################################################################
bfSol*
MibSHeuristic::getBilevelSolution1(const double * sol)
{

  /* 
     Find a bilevel feasible solution by solving the LL problem
     for a fixed UL solution, given by the UL portion of sol
  */


  MibSModel * model = MibSModel_;
  OsiSolverInterface * oSolver = model->getSolver();
  OsiSolverInterface * lSolver = new OsiCbcSolverInterface(oSolver);
  
  //double uObjSense(model->getSolver()->getObjSense());
  double lObjSense(model->getLowerObjSense());  
  int lCols(model->getLowerDim());
  int uCols(model->getUpperDim());
  int * lColIndices = model->getLowerColInd();
  int uRowNum = model->getUpperRowNum();
  int lRowNum = model->getLowerRowNum();
  int * uRowIndices = model->getUpperRowInd();
  int * lRowIndices = model->getLowerRowInd();
  int * uColIndices = model->getUpperColInd();
  double * lObjCoeffs = model->getLowerObjCoeffs();

  int tCols(uCols + lCols); 
  int i(0), index(0);

  /* delete the UL rows */
  lSolver->deleteRows(uRowNum, uRowIndices);

  /* Fix the UL variables to their current value in sol */

  for(i = 0; i < uCols; i++){
    index = uColIndices[i];
    lSolver->setColLower(index, sol[index]);
    lSolver->setColUpper(index, sol[index]);
  }

  /* Set the objective to the LL objective coefficients */

  double * nObjCoeffs = new double[tCols];
  CoinZeroN(nObjCoeffs, tCols);
      
  for(i = 0; i < lCols; i++){
    index = lColIndices[i];
    nObjCoeffs[index] = lObjCoeffs[i] * lObjSense;
  }
  
  lSolver->setObjective(nObjCoeffs);

  if(0){
    dynamic_cast<OsiCbcSolverInterface *> 
      (lSolver)->getModelPtr()->messageHandler()->setLogLevel(0);
  }
  else{
     dynamic_cast<OsiSymSolverInterface *> 
	(lSolver)->setSymParam("prep_level", -1);
     
     dynamic_cast<OsiSymSolverInterface *> 
	(lSolver)->setSymParam("verbosity", -2);
     
     dynamic_cast<OsiSymSolverInterface *> 
	(lSolver)->setSymParam("max_active_nodes", 1);
  }

  lSolver->branchAndBound();

  if(lSolver->isProvenOptimal()){

    double objVal(0.0);

    for(i = 0; i < tCols; i++)
      objVal += lSolver->getColSolution()[i] * oSolver->getObjCoefficients()[i];
    
    double * colsol = new double[tCols];
    CoinCopyN(lSolver->getColSolution(), tCols, colsol);
 
    bfSol * bfsol = 
      new bfSol(objVal, colsol);
    delete lSolver;
    return bfsol;
  }
  else{
    delete lSolver;
    return NULL;
  }

}