BaseProblem.h 4.46 KB
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/** \file BaseProblem.h */

#ifndef BASE_PROBLEM_H
#define BASE_PROBLEM_H

#include "AMDiS.h"
#include "time/RosenbrockStationary.h"
#include "CouplingTimeInterface.h"

using namespace AMDiS;

const Flag MESH_ADOPTED = 1<<2;
const Flag DATA_ADOPTED = 1<<3;

template<typename ProblemType=ProblemStat>
class BaseProblem : public ProblemIterationInterface,
		    public ProblemInstatBase
{
public:

  BaseProblem(const std::string &name_);
  ~BaseProblem()
  {
    delete prob;
  }

  /// Initialisation of the problem.
  virtual void initialize(Flag initFlag,
                  ProblemStat *adoptProblem = NULL,
                  Flag adoptFlag = INIT_NOTHING);

  /// Initialisation of DOFVectors and AbstractFunctions,
  /// is called in \ref initTimeInteface after feSpace and mesh are initialized
  virtual void initData() {};

  /// calls \ref initData, \ref fillOperators and \ref fillBoundaryConditions in this ordering
  virtual void initTimeInterface()
  { FUNCNAME("BaseProblem::initTimeInterface()");
    initData();
    fillOperators();
    fillBoundaryConditions();
  };

  /// read solution DOFVectors from .arh or .dat files
  virtual Flag initDataFromFile(AdaptInfo *adaptInfo);

  /// calls \ref initDataFromFile
  virtual void solveInitialProblem(AdaptInfo *adaptInfo)
  { FUNCNAME("BaseProblem::solveInitialProblem()");
    Flag initFlag = initDataFromFile(adaptInfo);
  };

  /// calls \ref writeFiles
  virtual void transferInitialSolution(AdaptInfo *adaptInfo)
  { FUNCNAME("BaseProblem::transferInitialSolution()");
    oldMeshChangeIdx = getMesh()->getChangeIndex();
    writeFiles(adaptInfo, false);
  };

  /// This method is called before \ref beginIteration, \ref oneIteration and \ref endIteration.
  virtual void initTimestep(AdaptInfo *adaptInfo) {};

  /// calls \ref writeFiles
  virtual void closeTimestep(AdaptInfo *adaptInfo);

  virtual void beginIteration(AdaptInfo *adaptInfo);
  virtual Flag oneIteration(AdaptInfo *adaptInfo, Flag toDo = FULL_ITERATION);
  virtual void endIteration(AdaptInfo *adaptInfo);

  /// Calls writeFiles of the problem
  virtual void writeFiles(AdaptInfo *adaptInfo, bool force)
  { FUNCNAME("BaseProblem::writeFiles()");
    prob->writeFiles(adaptInfo, force);
  };
  
  // getting methods

  /// pointer to the solution of the problem
  SystemVector *getSolution()
  {
    return prob->getSolution();
  }

  /// pointer to the mesh of the problem
  inline Mesh* getMesh(int comp = 0) 
  {
    return prob->getMesh(comp); 
  }

  /// pointer to the feSpace of the problem
  inline FiniteElemSpace* getFeSpace(int comp = 0) 
  {
    return prob->getFeSpace(comp); 
  }

  /// name of the baseBroblem
  std::string getName()
  {
    return name;
  };

  int getNumProblems() 
  {
    return 1;
  };
  
  int getNumComponents()
  {
    return prob->getNumComponents();
  };

  ProblemType *getProblem(int number= 0)
  {
    if (number<0 || number >= getNumProblems())
      throw(std::runtime_error("problem with given number does not exist"));
    if (number == 0)
      return prob;
  };

  ProblemType *getProblem(std::string name)
  {
    if (name == "prob")
      return prob;
    else
      throw(std::runtime_error("problem with given name '" + name + "' does not exist"));
  };

  // setting methods

  void setAssembleMatrixOnlyOnce_butTimestepChange(int i, int j)
  {
    fixedMatrixTimestep.push_back(std::make_pair(i,j));
  }

  void setNumberOfTimesteps(int nTimesteps_)
  {
    nTimesteps= nTimesteps_;
  }

  void serialize(std::ostream&) {};
  void deserialize(std::istream&) {};

  /// method where operators are added to the problem
  virtual void fillOperators() {};
  
  /// method where boundary conditions are added to the problem
  virtual void fillBoundaryConditions() {};

  /// classical backward-euler time-discretization
  void addTimeOperator(ProblemStat *prob, int i, int j);
  
  /// for rosenbrock-problems a special time-operator can be added
  void addTimeOperator(RosenbrockStationary *prob, int i, int j);
  
protected:

  ProblemType *prob;

  /// catch errors and exceptions in solve-block and continue with last iteration on failure
  /// standard: false
  bool secureIteration; 

  /// dimension of the mesh (set in \ref initialize(...) )
  unsigned dim;
  
  /// dimension of world (set in constructur)
  unsigned dow;

  int nTimesteps;
  int oldMeshChangeIdx;

  double oldTimestep;

private:

  std::vector<std::pair<int,int> > fixedMatrixTimestep;

};

#include "BaseProblem.hh"

typedef BaseProblem<ProblemStat> StandardBaseProblem;

#endif // BASE_PROBLEM_H