FixVec.h 20.4 KB
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// ============================================================================
// ==                                                                        ==
// == AMDiS - Adaptive multidimensional simulations                          ==
// ==                                                                        ==
// ============================================================================
// ==                                                                        ==
// ==  crystal growth group                                                  ==
// ==                                                                        ==
// ==  Stiftung caesar                                                       ==
// ==  Ludwig-Erhard-Allee 2                                                 ==
// ==  53175 Bonn                                                            ==
// ==  germany                                                               ==
// ==                                                                        ==
// ============================================================================
// ==                                                                        ==
// ==  http://www.caesar.de/cg/AMDiS                                         ==
// ==                                                                        ==
// ============================================================================

/** \file FixVec.h */

#ifndef AMDIS_FIXVEC_H
#define AMDIS_FIXVEC_H

// ===========================================================================
// ===== includes ============================================================
// ===========================================================================

#include "Global.h"
#include "MemoryManager.h"
#include <iostream>
#include "MatrixVector.h"

namespace AMDiS {

  // ===========================================================================
  // ===== forward declarations ================================================
  // ===========================================================================

  class Mesh;
  template<typename T> class WorldVector;
  template<typename T> class WorldMatrix;


  // ===========================================================================
  // ===== definitions =========================================================
  // ===========================================================================

  /** determines how to initialize a FixVec when constructed */
  enum InitType 
    {
      NO_INIT = 0,       /**< no initialisation */
      VALUE_LIST = 1,    /**< a complete value list is given */
      DEFAULT_VALUE = 2, /**< all values ar set to a given default value */
      UNIT_VECTOR = 3,   /**< the i-th value is 1, all other values are 0 */
      UNIT_MATRIX = 4    /**< values at the diagonal of a matrix are set to one */
    };

  // ===========================================================================
  // ===== class FixVec ========================================================
  // ===========================================================================

  /** \ingroup Common
   * \brief
   * A FixVec is a template vector of a fixed size. 
   *
   * The size is determined at construction time and depends on the dimension
   * and the template parameter d. So a FixVec<int, VERTEX> is a integer vector
   * with 3 entries in 2d and with 4 entries in 3d. The dimension and the way
   * the vector should be initialized are specified by the constructor call.
   */
  template<typename T,GeoIndex d>
  class FixVec : public Vector<T>
  {
  public:
    MEMORY_MANAGED(FixVec<T COMMA d>);

    /** \brief
     * constructor without initialisation. initType must be NO_INIT. If dim is
     * not spezified, a FixVec for DIM_OF_WORLD is created.
     */
    FixVec(int dim = -1, InitType initType = NO_INIT)
      : Vector<T>(calcSize(dim))
    { 
      TEST_EXIT(initType == NO_INIT)("wrong initType or missing initializer\n");
    }

    /** \brief
     * constructor with value list initialisation. initType must be VALUE_LIST.
     * ini is an array which contains the initialisation values.
     */
    FixVec(int dim, InitType initType, const T* ini)
      : Vector<T>(calcSize(dim))
    {
      TEST_EXIT(initType == VALUE_LIST)("wrong initType or wrong initializer\n");
      setValues(ini);
    };

    /** \brief
     * constructor with default value initialisation. initType must be
     * DEFAULT_VALUE. All vector entries are set to ini.
     */
    FixVec(int dim, InitType initType, const T& ini)
      : Vector<T>(calcSize(dim))
    {
      TEST_EXIT(initType==DEFAULT_VALUE)("wrong initType or wrong initializer\n");
      this->set(ini);
    }

    /** \brief
     * Initialisation for dim.
     */
    inline void init(int dim) 
    {
      TEST_EXIT(this->getSize() == 0)("already initialized\n");
      resize(calcSize(dim));
    };

    /** \brief
     * Initialisation for size
     */
    inline void initSize(int size) 
    {
      //TEST_EXIT(getSize() == 0)("already initialized\n");
      this->resize(size);
    };  

    /** \brief
     * Returns the \ref size_ of the FixVec.
     */
    inline int size() const { 
      return this->getSize(); 
    }; 

  protected:
    /** \brief
     * Determines needed vector size.
     */
    static int calcSize(int dim) {
      if (dim < 0) {
	//TEST_EXIT(d==WORLD)("dimension needed\n");
	return Global::getGeo(WORLD);
      } else {
	return Global::getGeo(d, dim);
      }
    };

  public:
    friend class GLWindow;
  };


  // ===========================================================================
  // ===== class VectorOfFixVecs ===============================================
  // ===========================================================================

  /** \ingroup Common
   * \brief
   * Contains an vector of FixVecs of same type. To simply allocate an array of 
   * FixVecs
   * isn't possible, because the FixVec constructor normally needs at least
   * the corresponding dimension. So you must create an array of FixVec pointers
   * and call the constructor of each FixVec manually. When you use 
   * VectorOfFixVecs, this work is done by VectorOfFixVecs's constructor.
   */
  template<typename FixVecType>
  class VectorOfFixVecs
  {
  public:
    MEMORY_MANAGED(VectorOfFixVecs<FixVecType>);

    /** \brief
     * constructs a VectorOfFixVecs without initialisation. dim is passed to 
     * FixVec's constructors. size_ is the number of contained FixVecs. initType
     * must be NO_INIT.
     */
    VectorOfFixVecs(int dim, int size, InitType initType) : size_(size)
    {
      TEST_EXIT(initType==NO_INIT)("wrong initType or wrong initializer\n");
      //vec = GET_MEMORY(FixVecType*, size);
      vec = GET_MEMORY(FixVecType*, size_);
      for(FixVecType** i=&vec[0]; i < &vec[size_]; i++) {
	*i = NEW FixVecType(dim, NO_INIT);
      }
    }

    /** \brief
     * constructs a VectorOfFixVecs via an value list.  dim is passed to 
     * FixVec's constructors. size_ is the number of contained FixVecs. initType
     * must be VALUE_LIST. ini contains the initialisation values.
     */
    VectorOfFixVecs(int dim, int s, InitType initType, const FixVecType* ini)
      : size_(s)
    {
      TEST_EXIT(initType==VALUE_LIST)("wrong initType or wrong initializer\n");
      vec = GET_MEMORY(FixVecType*, size_);
      //vec = new FixVecType*[size];
      for(FixVecType** i=&vec[0]; i < &vec[size_]; i++) {
	*i = NEW FixVecType(ini[i]);
      }    
    }

    /** \brief
     * constructs a VectorOfFixVecs with an default value.  dim is passed to 
     * FixVec's constructors. size_ is the number of contained FixVecs. initType
     * must be DEFAULT_VALUE. All entries are set to ini.
     */
    VectorOfFixVecs(int /*dim*/, int s, InitType initType, const FixVecType& ini)
      : size_(s)
    {
      TEST_EXIT(initType==DEFAULT_VALUE)
	("wrong initType or wrong initializer\n");
      vec = GET_MEMORY(FixVecType*, size_);
      //vec = new FixVecType*[size];
      for(FixVecType** i=&vec[0]; i < &vec[size_]; i++) {
	*i = NEW FixVecType(ini);
      }    
    }

    /** \brief
     * copy constructor
     */
    VectorOfFixVecs(const VectorOfFixVecs<FixVecType>& rhs)
    {
      size_ = rhs.getSize();
      vec = GET_MEMORY(FixVecType*, size_);
      int i;

      for(i=0; i < size_; i++) {
	vec[i] = NEW FixVecType(*(rhs.vec[i]));
      }
    };

    /** \brief
     * destructor
     */
    virtual ~VectorOfFixVecs()
    {
      for(FixVecType** i=&vec[0]; i<&vec[size_]; i++) {
	DELETE *i;
      }
      FREE_MEMORY(vec, FixVecType*, size_);
      //delete [] vec;
    };

    /** \brief
     * Allows the access like in a normal array via []. Used for const objects.
     */
    inline const FixVecType& operator[](int index) const
    {
      TEST_EXIT(index >= 0 && index < size_)("invalid index\n");
      return *(vec[index]);
    };

    /** \brief
     * Allows the access like in a normal array via []. 
     */
    inline FixVecType& operator[](int index)
    {
      TEST_EXIT(index >= 0 && index < size_)("invalid index\n");
      return *(vec[index]);
    };

    /** \brief
     * assignment operator
     */
    VectorOfFixVecs<FixVecType>& 
    operator=(const VectorOfFixVecs<FixVecType>& rhs)
    {
      TEST_EXIT(size_==rhs.size_)("vectors of different size\n");
      if (this!=&rhs) {
	FixVecType **i, **j;
	for(i=&vec[0], j=&(rhs.vec[0]); i < &vec[size_]; i++, j++) { 
	  **i = **j; 
	}
      }
      return *this;
    };

    /** \brief
     * Returns the \ref size of this VectorOfFixVecs
     */
    inline int getSize() const { return size_; };

    /** \brief
     * Returns the size of the contained FixVecs
     */
    inline int getSizeOfFixVec() const { return vec[0]->getSize(); }

  protected:
    /** \brief
     * number of contained FixVecs
     */
    int size_;

    /** \brief
     * array of pointers to FixVecs
     */
    FixVecType **vec;
  };

  // ===========================================================================
  // ===== class MatrixOfFixVecs ===============================================
  // ===========================================================================

  /** \ingroup Common
   * \brief
   * Like the class VectorOfFixVecs contains a vector of FixVecs, this class
   * contains a matrix of FixVecs of same type.
   */
  template<typename FixVecType>
  class MatrixOfFixVecs
  {
  public:
    MEMORY_MANAGED(MatrixOfFixVecs<FixVecType>);

    /** \brief
     * Constructs the matrix without initialisation. r is the number of rows,
     * c is the number of columns. The other parameters are analog to the
     * VectorOfFixVecs constructors.
     */
    MatrixOfFixVecs(int dim, int r, int c, InitType initType)
      : rows(r), columns(c)
    {
      TEST_EXIT(initType==NO_INIT)("wrong initType or wrong initializer\n");
      vec = GET_MEMORY(VectorOfFixVecs<FixVecType>*, rows);
      //vec = new VectorOfFixVecs<FixVecType>*[rows];
      for(VectorOfFixVecs<FixVecType>** i=&vec[0]; i<&vec[rows]; i++) {
	*i = NEW VectorOfFixVecs<FixVecType>(dim, columns, NO_INIT);
      }
    };


    /** \brief
     * destructor
     */
    virtual ~MatrixOfFixVecs()
    {
      for(VectorOfFixVecs<FixVecType>** i=&vec[0]; i<&vec[rows]; i++) {
	DELETE *i;
      }
      FREE_MEMORY(vec, VectorOfFixVecs<FixVecType>*, rows);
    };

    /** \brief
     * assignment operator
     */
    inline VectorOfFixVecs<FixVecType >& operator[](int index)
    {
      TEST_EXIT(index >= 0 && index < rows)("invalid index\n");
      return *(vec[index]);
    };

    /** \brief
     * assignment operator
     */
    inline const VectorOfFixVecs<FixVecType >& operator[](int index) const
    {
      TEST_EXIT(index >= 0 && index < rows)("invalid index\n");
      return *(vec[index]);
    };

    /** \brief
     * Returns \ref rows
     */
    inline int getNumberOfRows() const { 
      return rows; 
    };

    /** \brief
     * Returns \ref columns
     */
    inline int getNumberOfColumns() const { 
      return columns; 
    };

  private:
    /** \brief
     * number of rows of the matrix
     */

    int rows;

    /** \brief
     * number of columns of the matrix
     */
    int columns;

    /** \brief
     * array of pointers to VectorOfFixVecs
     */
    VectorOfFixVecs<FixVecType> **vec;
  };


  // ===========================================================================
  // ===== class DimVec ========================================================
  // ===========================================================================

  /** \ingroup Common
   * \brief
   * A DimVec is a FixVec with dim + 1 entries. It can be used for storing
   * barycentric coordinates or information associated to vertices or
   * parts of an element.
   */
  template<typename T>
  class DimVec : public FixVec<T,PARTS> {
  public:
    MEMORY_MANAGED(DimVec<T>);

    DimVec() {};

    /** \brief
     * Calls the corresponding constructor of FixVec
     */
    DimVec(int dim, InitType initType=NO_INIT)
      : FixVec<T,PARTS>(dim, initType)
    {};

    /** \brief
     * Calls the corresponding constructor of FixVec
     */
    DimVec(int dim, InitType initType, T* ini)
      : FixVec<T,PARTS>(dim, initType, ini)
    {};

    /** \brief
     * Calls the corresponding constructor of FixVec
     */
    DimVec(int dim, InitType initType, const T& ini)
      : FixVec<T,PARTS>(dim, initType, ini)
    {};
  };

  // ===========================================================================
  // ===== class DimMat ========================================================
  // ===========================================================================

  /** \ingroup Common
   * \brief
   * A DimMat is a VectorOfFixVecs of dim+1 DimVecs. 
   */
  template<typename T>
  class DimMat : public Matrix<T>
  {
  public:
    MEMORY_MANAGED(DimMat<T>);

    /** \brief
     * Calls the corresponding constructor of VectorOfFixVecs
     */
    DimMat(int dim, InitType initType=NO_INIT)
      : Matrix<T>(dim+1, dim+1)
    {};

    /** \brief
     * Calls the corresponding constructor of VectorOfFixVecs
     */
    DimMat(int dim, InitType initType, const T& ini)
      : Matrix<T>(dim+1, dim+1)
    {
      TEST_EXIT(initType==DEFAULT_VALUE)
	("wrong initType or wrong initializer\n");    
      this->set(ini);
    };

    /** \brief
     * Calls the corresponding constructor of VectorOfFixVecs
     */
    DimMat(int dim, InitType initType, T* ini)
      : Matrix<T>(dim+1, dim+1)
    {
      TEST_EXIT(initType==VALUE_LIST)("wrong initType or wrong initializer\n");
      setValues(ini);
    };
  };

  // ===========================================================================
  // ===== class WorldVector ===================================================
  // ===========================================================================

  /** \ingroup Common
   * \brief
   * A WorldVector is an AlgoVec with DIM_OF_WORLD entries of type double.
   * Can be used for storing world coordinates.
   */
  template<typename T>
  class WorldVector : public FixVec<T, WORLD>
  {
  public:
    MEMORY_MANAGED(WorldVector<T>);

    /** \brief
     * Calls the corresponding constructor of AlgoVec
     */
    WorldVector() 
      : FixVec<T, WORLD>(Global::getGeo(WORLD), NO_INIT) 
    {};

    /** \brief
     * Calls the corresponding constructor of AlgoVec
     */
    WorldVector(InitType initType, T* ini) 
      : FixVec<T, WORLD>(Global::getGeo(WORLD), initType, ini)
    {};

    /** \brief
     * Calls the corresponding constructor of AlgoVec
     */
    WorldVector(InitType initType, const T& ini)
      : FixVec<T, WORLD>(Global::getGeo(WORLD), initType, ini)
    {};

    /** \brief
     * Sets all entries to d
     */
    inline const WorldVector<T>& operator=(const T& d)
    {
      this->set(d);
      return (*this);
    };

    /** \brief
     * Multplication of a matrix with a vector.
     */
    void multMatrixVec(WorldMatrix<T> &m, WorldVector<T> &v);
  };


  // ===========================================================================
  // ===== class WorldMatrix ===================================================
  // ===========================================================================

  /** \ingroup Common
   * \brief
   * A WorldMatrix is a FixVec with DIM_OF_WORLD WorldVector entries.
   * So it can be seen as matrix with DIM_OF_WORLD x DIM_OF_WORLD double 
   * entries.
   * Here it's not necessary to use the VectorOfFixVecs class, because the 
   * FixVec constructor assumes dim = DIM_OF_WORLD, if no dim is spezified, 
   * what is the right assumption in this case.
   */
  template<typename T>
  class WorldMatrix : public Matrix<T>
  {
  public:
    MEMORY_MANAGED(WorldMatrix<T>);

    /** \brief
     * Calls the corresponding constructor of FixVec
     */
    WorldMatrix()
      : Matrix<T>(Global::getGeo(WORLD), Global::getGeo(WORLD))
    {};

    /** \brief
     * Calls the corresponding constructor of FixVec
     */
    WorldMatrix(InitType initType, T* ini)
      : Matrix<T>(Global::getGeo(WORLD), Global::getGeo(WORLD))
    {
      TEST_EXIT(initType == VALUE_LIST)("???\n");
      setValues(ini);
    };

    /** \brief
     * Calls the corresponding constructor of FixVec and sets all matrix entries
     * to ini
     */
    WorldMatrix(InitType initType, const T& ini)
      : Matrix<T>(Global::getGeo(WORLD), Global::getGeo(WORLD))
    {
      TEST_EXIT(initType == DEFAULT_VALUE)("wrong initType or wrong initializer\n");
      this->set(ini);
    };
  
    /** \brief
     * Returns true if the matrix is a diagonal matrix, returns false otherwise.
     */
    bool isDiagMatrix() const;

    /** \brief
     * Returns true if the matrix is symmetric, returns false otherwise.
     */
    bool isSymmetric() const;

    /** \brief
     * Sets the diagonal entries to the given value.
     */
    void setDiag(T value);

    /** \brief
     * Creates a matrix from the "multiplication" of two vectors.
     *
     * 2d-Example:
     *
     * /a\   /c\   /ac ad\
     * | | * | | = |     |
     * \b/   \d/   \bc bd/
     */
    void vecProduct(const WorldVector<T>& v1, const WorldVector<T>& v2);
  };


  // ===========================================================================
  // ===== global functions ====================================================
  // ===========================================================================


  /** \brief
   * returns the euclidian distance of a and b
   */
  template<typename T, GeoIndex d>
  double absteukl(const FixVec<T,d>& a,const FixVec<T,d>& b);

  /** \brief
   * FixVec operator for stream output
   */
  template<typename T, GeoIndex d>
  std::ostream& operator <<(::std::ostream& out, const FixVec<T,d>& fixvec)
  {
    for(int i=0; i < fixvec.getSize()-1; i++) {
      out << fixvec[i] << " ";
    }
    out << fixvec[fixvec.getSize()-1];
    return out;
  }

  /** \brief
   * creates and inits a VectorOfFixVecs<DimVec<double> >
   */
  VectorOfFixVecs<DimVec<double> > *createAndInit(int dim, int size, ...);

  /** \brief
   * creates and inits and double array
   */
  double *createAndInitArray(int size, ...); 

  inline WorldVector<double> operator*(const WorldVector<double>& v, double d) {
    WorldVector<double> result = v;
    result *= d;
    return result;
  };

  inline WorldVector<double> operator+(const WorldVector<double>& v1,
				       const WorldVector<double>& v2) 
  {
    WorldVector<double> result = v1;
    result += v2;
    return result;
  };

  inline WorldVector<int> operator+(const WorldVector<int>& v1,
				    const WorldVector<int>& v2) 
  {
    WorldVector<int> result = v1;
    result += v2;
    return result;
  };

  inline WorldVector<double> operator-(const WorldVector<double>& v1,
				       const WorldVector<double>& v2) 
  {
    WorldVector<double> result = v1;
    result -= v2;
    return result;
  };

  inline bool operator<(const WorldVector<double>& v1,
			const WorldVector<double>& v2) 
  {
    int i, dow = Global::getGeo(WORLD);
    for(i = 0; i < dow; i++) {
      if(abs(v1[i] - v2[i]) < DBL_TOL) continue;
      return v1[i] < v2[i];
    }
    return false;
  };

  inline bool operator==(const WorldVector<double>& v1,
			 const WorldVector<double>& v2) 
  {
    int i, dow = Global::getGeo(WORLD);
    for(i = 0; i < dow; i++) {
      if(abs(v1[i] - v2[i]) > DBL_TOL) return false;
    }
    return true;
  };

  template<typename T>
  const WorldMatrix<T>& operator*=(WorldMatrix<T>& m, T scal);

  template<typename T>
    const WorldMatrix<T>& operator-=(WorldMatrix<T>& m1, const WorldMatrix<T>& m2);

  template<typename T>
    const WorldMatrix<T>& operator+=(WorldMatrix<T>& m1, const WorldMatrix<T>& m2);
}

#include "FixVec.hh"

#endif // AMDIS_FIXVEC_H