/usr/include/gmsh/functionSpace.h

// Gmsh - Copyright (C) 1997-2015 C. Geuzaine, J.-F. Remacle
//
// See the LICENSE.txt file for license information. Please report all
// bugs and problems to the public mailing list <gmsh@geuz.org>.

#ifndef _FUNCTION_SPACE_H_
#define _FUNCTION_SPACE_H_

#include "SVector3.h"
#include "STensor3.h"
#include "STensor33.h"
#include "STensor43.h"
#include <vector>
#include <iterator>
#include <iostream>
#include "Numeric.h"
#include "MElement.h"
#include "dofManager.h"
#include "simpleFunction.h"

//class SVoid{};
template<class T> struct TensorialTraits
{
  typedef T ValType;
  typedef T GradType[3];
  typedef T HessType[3][3];
  typedef T ThirdDevType[3][3][3];
/*  typedef SVoid DivType;
  typedef SVoid CurlType;*/
};

template<> struct TensorialTraits<double>
{
  typedef double ValType;
  typedef SVector3 GradType;
  typedef STensor3 HessType;
  typedef double TensProdType;
  typedef STensor33 ThirdDevType;
/*  typedef SVoid DivType;
  typedef SVoid CurlType;*/
};

template<> struct TensorialTraits<SVector3>
{
  typedef SVector3 ValType;
  typedef STensor3 GradType;
  typedef STensor3 HessType;
  typedef STensor3 TensProdType;
  typedef STensor3 ThirdDevType;
//  typedef double DivType;
//  typedef SVector3 CurlType;
};

template<> struct TensorialTraits<STensor3>
{
  typedef STensor3 ValType;
//  typedef STensor3 GradType;
//  typedef STensor3 HessType;
//  typedef STensor3 TensProdType;
  typedef STensor43 TensProdType;
//  typedef double DivType;
//  typedef SVector3 CurlType;
};


class FunctionSpaceBase
{
 public:
  virtual ~FunctionSpaceBase(){}
  virtual int getNumKeys(MElement *ele) = 0; // if one needs the number of dofs
  virtual void getKeys(MElement *ele, std::vector<Dof> &keys) = 0;
  virtual void getKeysOnVertex(MElement* ele, MVertex* v, const std::vector<int>& comp, std::vector<Dof>& keys){
    Msg::Warning("this function is defined to get Dofs of vertex %d on element %d",v->getNum(),ele->getNum());
  }
  virtual FunctionSpaceBase* clone(const std::vector<int>& comp) const {return NULL;}
};

template<class T>
class FunctionSpace : public FunctionSpaceBase
{
 public:
  typedef typename TensorialTraits<T>::ValType ValType;
  typedef typename TensorialTraits<T>::GradType GradType;
  typedef typename TensorialTraits<T>::HessType HessType;
  typedef typename TensorialTraits<T>::ThirdDevType ThirdDevType;
  virtual void f(MElement *ele, double u, double v, double w, std::vector<ValType> &vals) = 0;
  virtual void fuvw(MElement *ele, double u, double v, double w, std::vector<ValType> &vals) {} // should return to pure virtual once all is done.
  virtual void gradf(MElement *ele, double u, double v, double w, std::vector<GradType> &grads) = 0;
  virtual void gradfuvw(MElement *ele, double u, double v, double w, std::vector<GradType> &grads) {} // should return to pure virtual once all is done.
  virtual void hessfuvw(MElement *ele, double u, double v, double w, std::vector<HessType> &hess) = 0;
  virtual void hessf(MElement *ele, double u, double v, double w,std::vector<HessType> &hess) {} //need to high order fem
  virtual void thirdDevfuvw(MElement *ele, double u, double v, double w,std::vector<ThirdDevType> &third){}; //need to high order fem
  virtual void thirdDevf(MElement *ele, double u, double v, double w,std::vector<ThirdDevType> &third){}; //need to high order fem

  virtual int getNumKeys(MElement *ele) = 0; // if one needs the number of dofs
  virtual void getKeys(MElement *ele, std::vector<Dof> &keys) = 0;
};

class ScalarLagrangeFunctionSpaceOfElement : public FunctionSpace<double>
{
 public:
  typedef TensorialTraits<double>::ValType ValType;
  typedef TensorialTraits<double>::GradType GradType;
  typedef TensorialTraits<double>::HessType HessType;

 protected:
  int _iField; // field number (used to build dof keys)

 private:
  virtual void getKeys(MVertex *ver, std::vector<Dof> &keys)
  {
    keys.push_back(Dof(ver->getNum(), _iField));
  }

 public:
  ScalarLagrangeFunctionSpaceOfElement(int i = 0) : _iField(i) {}
  virtual int getId(void) const {return _iField;}
  virtual void f(MElement *ele, double u, double v, double w, std::vector<ValType> &vals)
  {
    if(ele->getParent()) {
      if(ele->getTypeForMSH() == MSH_LIN_B || ele->getTypeForMSH() == MSH_TRI_B ||
         ele->getTypeForMSH() == MSH_POLYG_B) { //FIXME MPolygonBorders...
        ele->movePointFromParentSpaceToElementSpace(u, v, w);
      }
    }
    int ndofs = ele->getNumShapeFunctions();
    int curpos = vals.size();
    vals.resize(curpos + ndofs);
    ele->getShapeFunctions(u, v, w, &(vals[curpos]));
  }
  // Fonction renvoyant un vecteur contenant le grandient de chaque FF
  virtual void gradf(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
  {
    if(ele->getParent()) {
      if(ele->getTypeForMSH() == MSH_LIN_B || ele->getTypeForMSH() == MSH_TRI_B ||
         ele->getTypeForMSH() == MSH_POLYG_B) { //FIXME MPolygonBorders...
        ele->movePointFromParentSpaceToElementSpace(u, v, w);
      }
    }
    int ndofs = ele->getNumShapeFunctions();
    grads.reserve(grads.size() + ndofs);
    double gradsuvw[256][3];
    ele->getGradShapeFunctions(u, v, w, gradsuvw);
    double jac[3][3];
    double invjac[3][3];
    ele->getJacobian(u, v, w, jac); // redondant : on fait cet appel a l'exterieur
    inv3x3(jac, invjac);
    for(int i = 0; i < ndofs; ++i)
      grads.push_back(GradType(
      invjac[0][0] * gradsuvw[i][0] + invjac[0][1] * gradsuvw[i][1] + invjac[0][2] * gradsuvw[i][2],
      invjac[1][0] * gradsuvw[i][0] + invjac[1][1] * gradsuvw[i][1] + invjac[1][2] * gradsuvw[i][2],
      invjac[2][0] * gradsuvw[i][0] + invjac[2][1] * gradsuvw[i][1] + invjac[2][2] * gradsuvw[i][2]));
  }
  // Fonction renvoyant un vecteur contenant le hessien [][] de chaque FF dans l'espace ISOPARAMETRIQUE
  virtual void hessfuvw(MElement *ele, double u, double v, double w, std::vector<HessType> &hess)
  {
    if(ele->getParent()) {
      if(ele->getTypeForMSH() == MSH_LIN_B || ele->getTypeForMSH() == MSH_TRI_B ||
         ele->getTypeForMSH() == MSH_POLYG_B) { //FIXME MPolygonBorders...
        ele->movePointFromParentSpaceToElementSpace(u, v, w);
      }
    }
    int ndofs = ele->getNumShapeFunctions();
    hess.reserve(hess.size() + ndofs);   // permet de mettre les composantes suivantes à la suite du vecteur
    double hessuvw[256][3][3];
    ele->getHessShapeFunctions(u, v, w, hessuvw);
    HessType hesst;
    for(int i = 0; i < ndofs; ++i){
      hesst(0,0) = hessuvw[i][0][0]; hesst(0,1) = hessuvw[i][0][1]; hesst(0,2) = hessuvw[i][0][2];
      hesst(1,0) = hessuvw[i][1][0]; hesst(1,1) = hessuvw[i][1][1]; hesst(1,2) = hessuvw[i][1][2];
      hesst(2,0) = hessuvw[i][2][0]; hesst(2,1) = hessuvw[i][2][1]; hesst(2,2) = hessuvw[i][2][2];
      hess.push_back(hesst);
    }
  }
  virtual void gradfuvw(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
  {
    if(ele->getParent()) {
      if(ele->getTypeForMSH() == MSH_LIN_B || ele->getTypeForMSH() == MSH_TRI_B ||
         ele->getTypeForMSH() == MSH_POLYG_B) { //FIXME MPolygonBorders...
        ele->movePointFromParentSpaceToElementSpace(u, v, w);
      }
    }
    int ndofs = ele->getNumShapeFunctions();
    grads.reserve(grads.size() + ndofs);
    double gradsuvw[256][3];
    ele->getGradShapeFunctions(u, v, w, gradsuvw);
    for(int i = 0; i < ndofs; ++i)
      grads.push_back(GradType(gradsuvw[i][0], gradsuvw[i][1], gradsuvw[i][2]));
  }
  virtual int getNumKeys(MElement *ele)
  {
    return ele->getNumShapeFunctions();
  }
  virtual void getKeys(MElement *ele, std::vector<Dof> &keys) // appends ...
  {
    int ndofs = ele->getNumShapeFunctions();
    keys.reserve(keys.size() + ndofs);
    for(int i = 0; i < ndofs; ++i)
      getKeys(ele->getShapeFunctionNode(i), keys);
  }
};

class ScalarLagrangeFunctionSpace : public FunctionSpace<double>
{
 public:
  typedef TensorialTraits<double>::ValType ValType;
  typedef TensorialTraits<double>::GradType GradType;
  typedef TensorialTraits<double>::HessType HessType;

 protected:
  int _iField; // field number (used to build dof keys)

 private:
  virtual void getKeys(MVertex *ver, std::vector<Dof> &keys)
  {
    keys.push_back(Dof(ver->getNum(), _iField));
  }
 public:
  ScalarLagrangeFunctionSpace(int i = 0) : _iField(i) {}
  virtual int getId(void) const {return _iField;}
  virtual void f(MElement *ele, double u, double v, double w, std::vector<ValType> &vals)
  {
    if(ele->getParent()) ele = ele->getParent();
    int ndofs = ele->getNumShapeFunctions();
    int curpos = vals.size();
    vals.resize(curpos + ndofs);
    ele->getShapeFunctions(u, v, w, &(vals[curpos]));
  }
  // Fonction renvoyant un vecteur contenant le grandient de chaque FF
  virtual void gradf(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
  {
    if(ele->getParent()) ele = ele->getParent();
    int ndofs = ele->getNumShapeFunctions();
    grads.reserve(grads.size() + ndofs);
    double gradsuvw[256][3];
    ele->getGradShapeFunctions(u, v, w, gradsuvw);
    double jac[3][3];
    double invjac[3][3];
    ele->getJacobian(u, v, w, jac); // redondant : on fait cet appel a l'exterieur
    inv3x3(jac, invjac);
    for(int i = 0; i < ndofs; ++i)
      grads.push_back(GradType(
      invjac[0][0] * gradsuvw[i][0] + invjac[0][1] * gradsuvw[i][1] + invjac[0][2] * gradsuvw[i][2],
      invjac[1][0] * gradsuvw[i][0] + invjac[1][1] * gradsuvw[i][1] + invjac[1][2] * gradsuvw[i][2],
      invjac[2][0] * gradsuvw[i][0] + invjac[2][1] * gradsuvw[i][1] + invjac[2][2] * gradsuvw[i][2]));
  }
  // Fonction renvoyant un vecteur contenant le hessien [][] de chaque FF dans l'espace ISOPARAMETRIQUE
  virtual void hessfuvw(MElement *ele, double u, double v, double w, std::vector<HessType> &hess)
  {
    if(ele->getParent()) ele = ele->getParent();
    int ndofs = ele->getNumShapeFunctions();
    hess.reserve(hess.size() + ndofs);   // permet de mettre les composantes suivantes à la suite du vecteur
    double hessuvw[256][3][3];
    ele->getHessShapeFunctions(u, v, w, hessuvw);
    HessType hesst;
    for(int i = 0; i < ndofs; ++i){
      hesst(0,0) = hessuvw[i][0][0]; hesst(0,1) = hessuvw[i][0][1]; hesst(0,2) = hessuvw[i][0][2];
      hesst(1,0) = hessuvw[i][1][0]; hesst(1,1) = hessuvw[i][1][1]; hesst(1,2) = hessuvw[i][1][2];
      hesst(2,0) = hessuvw[i][2][0]; hesst(2,1) = hessuvw[i][2][1]; hesst(2,2) = hessuvw[i][2][2];
      hess.push_back(hesst);
    }
  }
  virtual void gradfuvw(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
  {
    if(ele->getParent()) ele = ele->getParent();
    int ndofs = ele->getNumShapeFunctions();
    grads.reserve(grads.size() + ndofs);
    double gradsuvw[256][3];
    ele->getGradShapeFunctions(u, v, w, gradsuvw);
    for(int i = 0; i < ndofs; ++i)
      grads.push_back(GradType(gradsuvw[i][0], gradsuvw[i][1], gradsuvw[i][2]));
  }
  virtual void fuvw(MElement *ele, double u, double v, double w,std::vector<ValType> &vals)
  {
    if(ele->getParent()) ele = ele->getParent();
    int ndofs= ele->getNumShapeFunctions();
    vals.reserve(vals.size()+ndofs);
    double valsuvw[1256];
    ele->getShapeFunctions(u, v, w, valsuvw);
    for(int i = 0; i < ndofs; ++i)
      vals.push_back(valsuvw[i]);
  }
  virtual int getNumKeys(MElement *ele)
  {
    if(ele->getParent()) ele = ele->getParent();
    return ele->getNumShapeFunctions();
  }
  virtual void getKeys(MElement *ele, std::vector<Dof> &keys) // appends ...
  {
    if(ele->getParent()) ele = ele->getParent();
    int ndofs = ele->getNumShapeFunctions();
    keys.reserve(keys.size() + ndofs);
    for(int i = 0; i < ndofs; ++i)
      getKeys(ele->getShapeFunctionNode(i), keys);
  }
};

template <class T> class ScalarToAnyFunctionSpace : public FunctionSpace<T>
{
public :
  typedef typename TensorialTraits<T>::ValType ValType;
  typedef typename TensorialTraits<T>::GradType GradType;
  typedef typename TensorialTraits<T>::HessType HessType;
protected :
  std::vector<T> multipliers;
  std::vector<int> comp;
  FunctionSpace<double> *ScalarFS;
public :
  template <class T2> ScalarToAnyFunctionSpace(const T2 &SFS, const T& mult, int comp_): ScalarFS(new T2(SFS))
  {
    multipliers.push_back(mult); comp.push_back(comp_);
  }

  template <class T2> ScalarToAnyFunctionSpace(const T2 &SFS, const T& mult1, int comp1_,
                          const T& mult2, int comp2_): ScalarFS(new T2(SFS))
  {
    multipliers.push_back(mult1); multipliers.push_back(mult2);
    comp.push_back(comp1_); comp.push_back(comp2_);
  }

  template <class T2> ScalarToAnyFunctionSpace(const T2 &SFS, const T& mult1, int comp1_,
                          const T& mult2, int comp2_, const T& mult3, int comp3_): ScalarFS(new T2(SFS))
  {
    multipliers.push_back(mult1); multipliers.push_back(mult2); multipliers.push_back(mult3);
    comp.push_back(comp1_); comp.push_back(comp2_); comp.push_back(comp3_);
  }

  virtual ~ScalarToAnyFunctionSpace() {delete ScalarFS;}

  virtual void f(MElement *ele, double u, double v, double w, std::vector<ValType> &vals)
  {
    std::vector<double> valsd;
    ScalarFS->f(ele, u, v, w, valsd);
    int nbdofs = valsd.size();
    int nbcomp = comp.size();
    int curpos = vals.size();
    vals.reserve(curpos + nbcomp * nbdofs);
    for(int j = 0; j < nbcomp; ++j){
      for(int i = 0; i < nbdofs; ++i)
        vals.push_back(multipliers[j] * valsd[i]);
    }
  }

  virtual void gradf(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
  {
    std::vector<SVector3> gradsd;
    ScalarFS->gradf(ele, u, v, w, gradsd);
    int nbdofs = gradsd.size();
    int nbcomp = comp.size();
    int curpos = grads.size();
    grads.reserve(curpos + nbcomp * nbdofs);
    GradType val;
    for(int j = 0; j < nbcomp; ++j){
      for(int i = 0; i < nbdofs; ++i){
        tensprod(multipliers[j], gradsd[i], val);
        grads.push_back(val);
      }
    }
  }
  virtual void hessfuvw(MElement *ele, double u, double v, double w, std::vector<HessType> &hess)
  {
    ScalarFS->hessfuvw(ele, u, v, w, hess);
  }
  virtual void gradfuvw(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
  {
    std::vector<SVector3> gradsd;
    ScalarFS->gradfuvw(ele, u, v, w, gradsd);
    int nbdofs = gradsd.size();
    int nbcomp = comp.size();
    int curpos = grads.size();
    grads.reserve(curpos + nbcomp * nbdofs);
    GradType val;
    for(int j = 0; j < nbcomp; ++j){
      for(int i = 0; i < nbdofs; ++i){
        tensprod(multipliers[j], gradsd[i], val);
        grads.push_back(val);
      }
    }
  }

  virtual int getNumKeys(MElement *ele) {return ScalarFS->getNumKeys(ele) * comp.size();}

  virtual void getKeys(MElement *ele, std::vector<Dof> &keys)
  {
    int nk = ScalarFS->getNumKeys(ele);
    std::vector<Dof> bufk;
    bufk.reserve(nk);
    ScalarFS->getKeys(ele, bufk);
    int nbdofs = bufk.size();
    int nbcomp = comp.size();
    int curpos = keys.size();
    keys.reserve(curpos + nbcomp * nbdofs);
    for(int j = 0; j < nbcomp; ++j){
      for(int i = 0; i < nk; ++i){
        int i1, i2;
        Dof::getTwoIntsFromType(bufk[i].getType(), i1, i2);
        keys.push_back(Dof(bufk[i].getEntity(), Dof::createTypeWithTwoInts(comp[j], i1)));
      }
    }
  }
};

class VectorLagrangeFunctionSpaceOfElement : public ScalarToAnyFunctionSpace<SVector3>
{
 protected:
  static const SVector3 BasisVectors[3];
 public:
  enum Along { VECTOR_X = 0, VECTOR_Y = 1, VECTOR_Z = 2 };
  typedef TensorialTraits<SVector3>::ValType ValType;
  typedef TensorialTraits<SVector3>::GradType GradType;
  VectorLagrangeFunctionSpaceOfElement(int id) :
          ScalarToAnyFunctionSpace<SVector3>::ScalarToAnyFunctionSpace(ScalarLagrangeFunctionSpaceOfElement(id),
          SVector3(1.,0.,0.), VECTOR_X, SVector3(0.,1.,0.), VECTOR_Y, SVector3(0.,0.,1.), VECTOR_Z)
  {}
  VectorLagrangeFunctionSpaceOfElement(int id, Along comp1) :
          ScalarToAnyFunctionSpace<SVector3>::ScalarToAnyFunctionSpace(ScalarLagrangeFunctionSpaceOfElement(id),
          BasisVectors[comp1], comp1)
  {}
  VectorLagrangeFunctionSpaceOfElement(int id, Along comp1, Along comp2) :
          ScalarToAnyFunctionSpace<SVector3>::ScalarToAnyFunctionSpace(ScalarLagrangeFunctionSpaceOfElement(id),
          BasisVectors[comp1], comp1, BasisVectors[comp2], comp2)
  {}
  VectorLagrangeFunctionSpaceOfElement(int id, Along comp1, Along comp2, Along comp3) :
          ScalarToAnyFunctionSpace<SVector3>::ScalarToAnyFunctionSpace(ScalarLagrangeFunctionSpaceOfElement(id),
          BasisVectors[comp1], comp1, BasisVectors[comp2], comp2, BasisVectors[comp3], comp3)
  {}
};

class VectorLagrangeFunctionSpace : public ScalarToAnyFunctionSpace<SVector3>
{
 protected:
  static const SVector3 BasisVectors[3];
 public:
  enum Along { VECTOR_X = 0, VECTOR_Y = 1, VECTOR_Z = 2 };
  typedef TensorialTraits<SVector3>::ValType ValType;
  typedef TensorialTraits<SVector3>::GradType GradType;
  VectorLagrangeFunctionSpace(int id) :
          ScalarToAnyFunctionSpace<SVector3>::ScalarToAnyFunctionSpace(ScalarLagrangeFunctionSpace(id),
          SVector3(1.,0.,0.), VECTOR_X, SVector3(0.,1.,0.), VECTOR_Y, SVector3(0.,0.,1.), VECTOR_Z)
  {}
  VectorLagrangeFunctionSpace(int id, Along comp1) :
          ScalarToAnyFunctionSpace<SVector3>::ScalarToAnyFunctionSpace(ScalarLagrangeFunctionSpace(id),
          BasisVectors[comp1], comp1)
  {}
  VectorLagrangeFunctionSpace(int id, Along comp1, Along comp2) :
          ScalarToAnyFunctionSpace<SVector3>::ScalarToAnyFunctionSpace(ScalarLagrangeFunctionSpace(id),
          BasisVectors[comp1], comp1, BasisVectors[comp2], comp2)
  {}
  VectorLagrangeFunctionSpace(int id, Along comp1, Along comp2, Along comp3) :
          ScalarToAnyFunctionSpace<SVector3>::ScalarToAnyFunctionSpace(ScalarLagrangeFunctionSpace(id),
          BasisVectors[comp1], comp1, BasisVectors[comp2], comp2, BasisVectors[comp3], comp3)
  {}
};

template<class T>
class CompositeFunctionSpace : public FunctionSpace<T>
{
 public:
  typedef typename TensorialTraits<T>::ValType ValType;
  typedef typename TensorialTraits<T>::GradType GradType;
  typedef typename TensorialTraits<T>::HessType HessType;
  typedef typename std::vector<FunctionSpace<T>* >::iterator iterFS;
 protected:

  std::vector<FunctionSpace<T>* > _spaces;
 public:
  template <class T1> CompositeFunctionSpace(const T1& t) { _spaces.push_back(new T1(t));}
  template <class T1, class T2> CompositeFunctionSpace(const T1& t1, const T2& t2)
  { _spaces.push_back(new T1(t1));
    _spaces.push_back(new T2(t2)); }
  template <class T1, class T2, class T3> CompositeFunctionSpace(const T1& t1, const T2& t2, const T3& t3)
  { _spaces.push_back(new T1(t1));
    _spaces.push_back(new T2(t2));
    _spaces.push_back(new T3(t3)); }
  template <class T1, class T2, class T3, class T4> CompositeFunctionSpace(const T1& t1, const T2& t2, const T3& t3, const T4& t4)
  { _spaces.push_back(new T1(t1));
    _spaces.push_back(new T2(t2));
    _spaces.push_back(new T3(t3));
    _spaces.push_back(new T4(t4)); }
  template <class T1> void insert(const T1& t)
  {
    _spaces.push_back(new T(t));
  }
  ~CompositeFunctionSpace(void)
  {
    for (iterFS it = _spaces.begin(); it != _spaces.end(); ++it)
      delete (*it);
  }
  virtual void f(MElement *ele, double u, double v, double w, std::vector<ValType> &vals)
  {
    for (iterFS it = _spaces.begin(); it != _spaces.end(); ++it)
      (*it)->f(ele, u, v, w, vals);
  }

  virtual void gradf(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
  {
    for (iterFS it = _spaces.begin(); it != _spaces.end(); ++it)
      (*it)->gradf(ele, u, v, w, grads);
  }

  virtual void hessfuvw(MElement *ele, double u, double v, double w, std::vector<HessType> &hess)
  {
    for (iterFS it = _spaces.begin(); it != _spaces.end(); ++it)
      (*it)->hessfuvw(ele, u, v, w, hess);
  }

  virtual int getNumKeys(MElement *ele)
  {
    int ndofs = 0;
    for (iterFS it = _spaces.begin(); it != _spaces.end(); ++it)
      ndofs += (*it)->getNumKeys(ele);
    return ndofs;
  }

  virtual void getKeys(MElement *ele, std::vector<Dof> &keys)
  {
    for (iterFS it = _spaces.begin(); it != _spaces.end(); ++it)
      (*it)->getKeys(ele, keys);
  }
};

template<class T>
class xFemFunctionSpace : public FunctionSpace<T>
{
 public:
  typedef typename TensorialTraits<T>::ValType ValType;
  typedef typename TensorialTraits<T>::GradType GradType;
  typedef typename TensorialTraits<T>::HessType HessType;
 protected:
   FunctionSpace<T>* _spacebase;
   simpleFunctionOnElement<double> *_funcEnrichment;

 public:
  virtual void hessfuvw(MElement *ele, double u, double v, double w,std::vector<HessType> &hess){}
  xFemFunctionSpace(FunctionSpace<T>* spacebase,simpleFunctionOnElement<double> *funcEnrichment) :
    _spacebase(spacebase),_funcEnrichment(funcEnrichment){}
  virtual void f(MElement *ele, double u, double v, double w,std::vector<ValType> &vals);
  virtual void gradf(MElement *ele, double u, double v, double w,std::vector<GradType> &grads);
  virtual int getNumKeys(MElement *ele);
  virtual void getKeys(MElement *ele, std::vector<Dof> &keys);
};


template<class T, class F>
class FilteredFunctionSpace : public FunctionSpace<T>
{
 public :
  typedef typename TensorialTraits<T>::ValType ValType;
  typedef typename TensorialTraits<T>::GradType GradType;
  typedef typename TensorialTraits<T>::HessType HessType;
 protected:
  FunctionSpace<T>* _spacebase;
  F *_filter;
 public:
  virtual void hessfuvw(MElement *ele, double u, double v, double w, std::vector<HessType> &hess){}
  FilteredFunctionSpace<T,F>(FunctionSpace<T>* spacebase,F * filter) : _spacebase(spacebase), _filter(filter){}
  virtual void f(MElement *ele, double u, double v, double w, std::vector<ValType> &vals);
  virtual void gradf(MElement *ele, double u, double v, double w, std::vector<GradType> &grads);
  virtual int getNumKeys(MElement *ele);
  virtual void getKeys(MElement *ele, std::vector<Dof> &keys);
};


template <class T> void xFemFunctionSpace<T>::f(MElement *ele, double u, double v, double w, std::vector<ValType> &vals)
{
   // We need parent parameters
  MElement * elep;
  if (ele->getParent()) elep = ele->getParent();
  else elep = ele;

    // Get the spacebase valsd
  std::vector<ValType> valsd;
  xFemFunctionSpace<T>::_spacebase->f(elep, u, v, w, valsd);

  int nbdofs = valsd.size();
  int curpos = vals.size();  // if in composite function space
  vals.reserve(curpos + nbdofs);

  // then enriched dofs so the order is ex:(a2x,a2y,a3x,a3y)
  if (nbdofs > 0){ // if enriched
    // Enrichment function calcul
    SPoint3 p;
    elep->pnt(u, v, w, p); // parametric to cartesian coordinates
    double func;
    _funcEnrichment->setElement(elep);
    func = (*_funcEnrichment)(p.x(), p.y(), p.z());
    for (int i = 0 ; i < nbdofs; i++){
      vals.push_back(valsd[i] * func);
    }
  }
}

template <class T> void xFemFunctionSpace<T>::gradf(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
{

    // We need parent parameters
  MElement *elep;
  if (ele->getParent()) elep = ele->getParent();
  else elep = ele;

    // Get the spacebase gradsd
  std::vector<GradType> gradsd;
  xFemFunctionSpace<T>::_spacebase->gradf(elep, u, v, w, gradsd);

  int nbdofs=gradsd.size();

    // We need spacebase valsd to compute total gradient
  std::vector<ValType> valsd;
  xFemFunctionSpace<T>::_spacebase->f(elep, u, v, w, valsd);

  int curpos = grads.size();  // if in composite function space
  grads.reserve(curpos + nbdofs);

    // then enriched dofs so the order is ex:(a2x,a2y,a3x,a3y)
  if (nbdofs > 0){ // if enriched
    double df[3];
    SPoint3 p;
    elep->pnt(u, v, w, p);
    _funcEnrichment->setElement(elep);
    _funcEnrichment->gradient (p.x(), p.y(), p.z(), df[0], df[1], df[2]);
    ValType gradfuncenrich(df[0], df[1], df[2]);

        // Enrichment function calcul
    double func;
    _funcEnrichment->setElement(elep);
    func = (*_funcEnrichment)(p.x(), p.y(), p.z());

    for (int i = 0 ; i < nbdofs; i++){
      GradType GradFunc;
      tensprod(valsd[i], gradfuncenrich, GradFunc);
      grads.push_back(gradsd[i] * func + GradFunc);
    }
  }
}

template <class T> int xFemFunctionSpace<T>::getNumKeys(MElement *ele)
{
  MElement *elep;
  if (ele->getParent()) elep = ele->getParent();
  else elep = ele;
  int nbdofs = xFemFunctionSpace<T>::_spacebase->getNumKeys(elep);
  return nbdofs;
}

template <class T> void xFemFunctionSpace<T>::getKeys(MElement *ele, std::vector<Dof> &keys)
{
  MElement *elep;
  if (ele->getParent()) elep = ele->getParent();
  else elep = ele;

  int normalk = xFemFunctionSpace<T>::_spacebase->getNumKeys(elep);

  std::vector<Dof> bufk;
  bufk.reserve(normalk);
  xFemFunctionSpace<T>::_spacebase->getKeys(elep, bufk);
  int normaldofs = bufk.size();
  int nbdofs = normaldofs;

  int curpos = keys.size();
  keys.reserve(curpos + nbdofs);

    // get keys so the order is ex:(a2x,a2y,a3x,a3y)
    // enriched dof tagged with ( i2 -> i2 + 1 )
  for (int i = 0 ;i < nbdofs; i++){
    int i1, i2;
    Dof::getTwoIntsFromType(bufk[i].getType(), i1, i2);
    keys.push_back(Dof(bufk[i].getEntity(), Dof::createTypeWithTwoInts(i1, i2 + 1)));
  }
}


// Filtered function space
//

template <class T,class F> void FilteredFunctionSpace<T,F>::f(MElement *ele, double u, double v, double w, std::vector<ValType> &vals)
{
    // We need parent parameters
  MElement *elep;
  if (ele->getParent()) elep = ele->getParent();
  else elep = ele;

  std::vector<ValType> valsd;

  _spacebase->f(elep, u, v, w, valsd);

  int normalk = _spacebase->getNumKeys(elep);
  std::vector<Dof> bufk;
  bufk.reserve(normalk);
  _spacebase->getKeys(elep, bufk);

  for (int i = 0; i < bufk.size(); i++){
    if ((*_filter)(bufk[i]))
      vals.push_back(valsd[i]);
  }
}


template <class T,class F> void FilteredFunctionSpace<T,F>::gradf(MElement *ele, double u, double v, double w, std::vector<GradType> &grads)
{
    // We need parent parameters
  MElement *elep;
  if (ele->getParent()) elep = ele->getParent();
  else elep = ele;

    // Get space base gradsd
  std::vector<GradType> gradsd;
  _spacebase->gradf(elep, u, v, w, gradsd);

    // Get numkeys
  int normalk = _spacebase->getNumKeys(elep);
  std::vector<Dof> bufk;
  bufk.reserve(normalk);
  _spacebase->getKeys(elep, bufk);

  for (int i = 0; i < bufk.size(); i++){
    if ((*_filter)(bufk[i]))
      grads.push_back(gradsd[i]);
  }
}

template <class T,class F> int FilteredFunctionSpace<T,F>::getNumKeys(MElement *ele)
{
  MElement *elep;
  if (ele->getParent()) elep = ele->getParent();
  else elep = ele;

  int nbdofs = 0;

  int normalk = _spacebase->getNumKeys(elep);
  std::vector<Dof> bufk;
  bufk.reserve(normalk);
  _spacebase->getKeys(elep, bufk);

  for (int i = 0; i < bufk.size(); i++){
    if ((*_filter)(bufk[i]))
      nbdofs = nbdofs + 1;
  }
  return nbdofs;
}

template <class T, class F> void FilteredFunctionSpace<T, F>::getKeys(MElement *ele, std::vector<Dof> &keys)
{
  MElement *elep;
  if (ele->getParent()) elep = ele->getParent();
  else elep = ele;

  int normalk = _spacebase->getNumKeys(elep);

  std::vector<Dof> bufk;
  bufk.reserve(normalk);
  _spacebase->getKeys(elep, bufk);

  for (int i = 0; i < bufk.size(); i++){
    if ((*_filter)(bufk[i]))
      keys.push_back(bufk[i]);
  }
}


#endif
libgmsh-dev 2.10.1+dfsg1-1ubuntu4 / usr / include / gmsh / functionSpace.h
