Operator.cc 86.8 KB
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#include "Operator.h"
#include "ElInfo.h"
#include "Assembler.h"
#include "FixVec.h"
#include "DOFVector.h"
#include "Quadrature.h"
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#include "OpenMP.h"
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namespace AMDiS {

  const Flag OperatorTerm::PW_CONST = 1;
  const Flag OperatorTerm::SYMMETRIC = 2;

  const Flag Operator::MATRIX_OPERATOR = 1;
  const Flag Operator::VECTOR_OPERATOR = 2;


  int Operator::getQuadratureDegree(int order, FirstOrderType firstOrderType) 
  {
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    std::vector<OperatorTerm*>* terms = NULL;
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    int myRank = omp_get_thread_num();
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    switch(order) {
    case 0:
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      terms = &zeroOrder[myRank];
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      break;
    case 1:
      if (firstOrderType == GRD_PHI)
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	terms = &firstOrderGrdPhi[myRank];
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      else 
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	terms = &firstOrderGrdPsi[myRank];
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      break;
    case 2:
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      terms = &secondOrder[myRank];
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      break;
    }

    const BasisFunction *psi = rowFESpace->getBasisFcts();
    const BasisFunction *phi = colFESpace->getBasisFcts();

    int psiDegree = psi->getDegree();
    int phiDegree = phi->getDegree();
    int maxTermDegree = 0;

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    for (int i = 0; i < static_cast<int>(terms->size()); i++) {
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      OperatorTerm *term = (*terms)[i];
      maxTermDegree = max(maxTermDegree, term->degree);
    }
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    return psiDegree + phiDegree - order + maxTermDegree;
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  }


  void OperatorTerm::setSymmetric(bool symm)
  {
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    if (symm) {
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      properties.setFlag(SYMMETRIC);
    } else {
      properties.unsetFlag(SYMMETRIC);   
    }
  }

  bool OperatorTerm::isSymmetric()
  {
    return properties.isSet(SYMMETRIC);
  }

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  double *OperatorTerm::getVectorAtQPs(DOFVectorBase<double>* vec,
				       const ElInfo* elInfo, 
				       SubAssembler* subAssembler,
				       Quadrature *quad)
  {
    FUNCNAME("OperatorTerm::getVectorAtQPs()");

    TEST_EXIT(elInfo->getMesh() == vec->getFESpace()->getMesh())
      ("There is something wrong!\n");
      
    return subAssembler->getVectorAtQPs(vec, elInfo, quad);
  }

  double *OperatorTerm::getVectorAtQPs(DOFVectorBase<double>* vec,
				       const ElInfo* smallElInfo, 
				       const ElInfo* largeElInfo, 
				       SubAssembler* subAssembler,
				       Quadrature *quad)
  {
    FUNCNAME("OperatorTerm::getVectorAtQPs()");

    TEST_EXIT(smallElInfo->getMesh() == vec->getFESpace()->getMesh() ||
	      largeElInfo->getMesh() == vec->getFESpace()->getMesh())
      ("There is something wrong!\n");

    if (smallElInfo->getLevel() == largeElInfo->getLevel()) {

      // Both elements have the same size, so we can use the simple procedure
      // to determine the vecAtQPs.
      
      if (vec->getFESpace()->getMesh() == smallElInfo->getMesh()) {
	return subAssembler->getVectorAtQPs(vec, smallElInfo, quad);
      } else {
	return subAssembler->getVectorAtQPs(vec, largeElInfo, quad);
      }

    } else {

      // The two elements are different. If the vector is defined on the mesh of the
      // small element, we can still use the simple procedure to determine the vecAtQPs.

      if (vec->getFESpace()->getMesh() == largeElInfo->getMesh()) {
	return subAssembler->getVectorAtQPs(vec, smallElInfo, largeElInfo, quad);
      } else {
	return subAssembler->getVectorAtQPs(vec, smallElInfo, quad);
      }

    }
  }

  WorldVector<double>* OperatorTerm::getGradientsAtQPs(DOFVectorBase<double>* vec,
						       const ElInfo* elInfo,
						       SubAssembler* subAssembler,
						       Quadrature *quad)
  {
    FUNCNAME("OperatorTerm::getGradientsAtQPs()");

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    TEST_EXIT_DBG(elInfo->getMesh() == vec->getFESpace()->getMesh())
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      ("There is something wrong!\n");

    return subAssembler->getGradientsAtQPs(vec, elInfo, quad);
  }

  WorldVector<double>* OperatorTerm::getGradientsAtQPs(DOFVectorBase<double>* vec,
						       const ElInfo* smallElInfo, 
						       const ElInfo* largeElInfo,
						       SubAssembler* subAssembler,
						       Quadrature *quad)
  {
    FUNCNAME("OperatorTerm::getGradientsAtQPs()");

    TEST_EXIT(smallElInfo->getMesh() == vec->getFESpace()->getMesh() ||
	      largeElInfo->getMesh() == vec->getFESpace()->getMesh())
      ("There is something wrong!\n");

    if (smallElInfo->getLevel() == largeElInfo->getLevel()) {

      // Both elements have the same size, so we can use the simple procedure
      // to determine the gradients.
      
      if (vec->getFESpace()->getMesh() == smallElInfo->getMesh()) {
	return subAssembler->getGradientsAtQPs(vec, smallElInfo, quad);
      } else {
	return subAssembler->getGradientsAtQPs(vec, largeElInfo, quad);
      }

    } else {

      // The two elements are different. If the vector is defined on the mesh of the
      // small element, we can still use the simple procedure to determine the gradients.

      if (vec->getFESpace()->getMesh() == largeElInfo->getMesh()) {
	return subAssembler->getGradientsAtQPs(vec, smallElInfo, largeElInfo, quad);
      } else {
	return subAssembler->getGradientsAtQPs(vec, smallElInfo, quad);
      }

    }
  }

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  void OperatorTerm::lalt(const DimVec<WorldVector<double> >& Lambda,
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			  const WorldMatrix<double>& matrix,
			  DimMat<double>& LALt,
			  bool symm,
			  double factor)
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  {
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    int j, k, l;
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    const int dimOfWorld = Global::getGeo(WORLD);
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    int dim = LALt.getNumRows() - 1;
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    double val = 0.0;

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    if (symm) {
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      for (int i = 0; i <= dim; i++) {
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	val = 0.0;
	for (k = 0; k < dimOfWorld; k++)
	  for (l = 0; l < dimOfWorld; l++)
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	    val += Lambda[i][k] * matrix[k][l] * Lambda[i][l];
	val *= factor;
	LALt[i][i] += val;
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	for (j = i + 1; j <= dim; j++) {
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	  val = 0.0;
	  for (k = 0; k < dimOfWorld; k++)
	    for (l = 0; l < dimOfWorld; l++)
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	      val += Lambda[i][k] * matrix[k][l] * Lambda[j][l];
	  val *= factor;
	  LALt[i][j] += val;
	  LALt[j][i] += val;
	}
      }    
    } else {	
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      for (int i = 0; i <= dim; i++) {
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	for (j = 0; j <= dim; j++) {
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	  val = 0.0;
	  for (k = 0; k < dimOfWorld; k++)
	    for (l = 0; l < dimOfWorld; l++) 
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	      val += Lambda[i][k] * matrix[k][l] * Lambda[j][l];
	  val *= factor;
	  LALt[i][j] += val;
	}
      }    
    }      
  }

  void OperatorTerm::lalt_kl(const DimVec<WorldVector<double> >& Lambda,
			     int k, int l,
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			     DimMat<double>& LALt,
			     double factor)
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  {
    int dim = LALt.getNumRows() - 1;

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    for (int i = 0; i <= dim; i++)
      for (int j = 0; j <= dim; j++)
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	LALt[i][j] += factor * Lambda[i][k] * Lambda[j][l];
  }

  void OperatorTerm::l1lt(const DimVec<WorldVector<double> >& Lambda,
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			  DimMat<double>& LALt,
			  double factor)
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  {
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    const int dimOfWorld = Global::getGeo(WORLD);
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    int dim = LALt.getNumRows() - 1;
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    for (int i = 0; i <= dim; i++) {
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      double val = 0.0;
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      for (int k = 0; k < dimOfWorld; k++)
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	val += Lambda[i][k] * Lambda[i][k];
      val *= factor;
      LALt[i][i] += val;
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      for (int j = i + 1; j <= dim; j++) {
	val = 0.0;
	for (int k = 0; k < dimOfWorld; k++)
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	  val += Lambda[i][k] * Lambda[j][k];
	val *= factor;
	LALt[i][j] += val;
	LALt[j][i] += val;
      }    
    }      
  }

  void OperatorTerm::lb(const DimVec<WorldVector<double> >& Lambda,
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			const WorldVector<double>& b,
			DimVec<double>& Lb,
			double factor)
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  {
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    int dim = Lb.getSize() - 1;
    const int dimOfWorld = Global::getGeo(WORLD);
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    for (int i = 0; i <= dim; i++) {
      double val = 0.0;
      for (int j = 0; j < dimOfWorld; j++)
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	val += Lambda[i][j] * b[j];
      val *= factor;
      Lb[i] += val;
    }    
  }

  Operator::Operator(Flag operatorType,
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		     const FiniteElemSpace *row,
		     const FiniteElemSpace *col)
    : rowFESpace(row), 
      colFESpace(col ? col : row),
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      type(operatorType), 
      fillFlag(Mesh::CALL_LEAF_EL | Mesh::FILL_COORDS | 
	       Mesh::FILL_DET | Mesh::FILL_GRD_LAMBDA),
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      needDualTraverse(false),
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      uhOld(NULL),
      optimized(true)
  {
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    int maxThreads = omp_get_overall_max_threads();
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    assembler.resize(maxThreads);
    secondOrder.resize(maxThreads);
    firstOrderGrdPsi.resize(maxThreads);
    firstOrderGrdPhi.resize(maxThreads);
    zeroOrder.resize(maxThreads);

    for (int i = 0; i < maxThreads; i++) {
      assembler[i] = NULL;
      secondOrder[i].resize(0);
      firstOrderGrdPsi[i].resize(0);
      firstOrderGrdPhi[i].resize(0);
      zeroOrder[i].resize(0);
    }

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    nRow = rowFESpace->getBasisFcts()->getNumber();
    nCol = colFESpace->getBasisFcts()->getNumber();
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  }
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  void Operator::setUhOld(const DOFVectorBase<double> *uhOld_)
  {
    uhOld = uhOld_;
  }

  void Operator::getElementMatrix(const ElInfo *elInfo, 
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				  ElementMatrix& userMat, 
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				  double factor)
  {
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    int myRank = omp_get_thread_num();

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    if (!assembler[myRank])
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      initAssembler(myRank, NULL, NULL, NULL, NULL);
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    assembler[myRank]->calculateElementMatrix(elInfo, userMat, factor);
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  }

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  void Operator::getElementMatrix(const ElInfo *rowElInfo, const ElInfo *colElInfo,
				  const ElInfo *smallElInfo, const ElInfo *largeElInfo,
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				  ElementMatrix& userMat, 
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				  double factor)
  {
    int myRank = omp_get_thread_num();

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    if (!assembler[myRank])
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      initAssembler(myRank, NULL, NULL, NULL, NULL);

    assembler[myRank]->calculateElementMatrix(rowElInfo, colElInfo, 
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					      smallElInfo, largeElInfo,
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    					      userMat, factor);
  }

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  void Operator::getElementVector(const ElInfo *elInfo, 
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				  ElementVector& userVec, 
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				  double factor)
  {
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    int myRank = omp_get_thread_num();

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    if (!assembler[myRank])
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      initAssembler(myRank, NULL, NULL, NULL, NULL);
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    assembler[myRank]->calculateElementVector(elInfo, userVec, factor);
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  }

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  void Operator::getElementVector(const ElInfo *mainElInfo, const ElInfo *auxElInfo,
				  const ElInfo *smallElInfo, const ElInfo *largeElInfo,
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				  ElementVector& userVec,
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				  double factor)
  {
    int myRank = omp_get_thread_num();

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    if (!assembler[myRank])
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      initAssembler(myRank, NULL, NULL, NULL, NULL);

    assembler[myRank]->calculateElementVector(mainElInfo, auxElInfo, 
					      smallElInfo, largeElInfo,
					      userVec, factor);
  }

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  void Operator::initAssembler(int rank,
			       Quadrature *quad2,
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			       Quadrature *quad1GrdPsi,
			       Quadrature *quad1GrdPhi,
			       Quadrature *quad0) 
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  {    
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#ifdef _OPENMP
#pragma omp critical (initAssembler)
#endif
      {
	if (optimized) {
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	  assembler[rank] = new OptimizedAssembler(this,
						   quad2, quad1GrdPsi, quad1GrdPhi, quad0,
						   rowFESpace, colFESpace);
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	} else {
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	  assembler[rank] = new StandardAssembler(this,
						  quad2, quad1GrdPsi, quad1GrdPhi, quad0,
						  rowFESpace, colFESpace);
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	}
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      }
  }

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  void Operator::finishAssembling()
  {
    assembler[omp_get_thread_num()]->finishAssembling();
  }

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  VecAtQP_ZOT::VecAtQP_ZOT(DOFVectorBase<double> *dv,
			   AbstractFunction<double, double> *af)
    : ZeroOrderTerm(af ? af->getDegree() : 0), vec(dv), f(af)
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());        
  }

  MultVecAtQP_ZOT::MultVecAtQP_ZOT(DOFVectorBase<double> *dv1,
				   DOFVectorBase<double> *dv2,
				   AbstractFunction<double, double> *af1,
				   AbstractFunction<double, double> *af2)
    : ZeroOrderTerm(af1->getDegree() + af2->getDegree()), 
      vec1(dv1), vec2(dv2), f1(af1), f2(af2)
  {
    TEST_EXIT(dv1)("No first vector!\n");
    TEST_EXIT(dv2)("No second vector!\n");

    auxFESpaces.push_back(dv1->getFESpace());
    auxFESpaces.push_back(dv2->getFESpace());
  }

  Vec2AtQP_ZOT::Vec2AtQP_ZOT(DOFVectorBase<double> *dv1,
			     DOFVectorBase<double> *dv2,
			     BinaryAbstractFunction<double, double, double> *af)
    : ZeroOrderTerm(af->getDegree()), vec1(dv1), vec2(dv2), f(af)
  {
    TEST_EXIT(dv1)("No first vector!\n");
    TEST_EXIT(dv2)("No second vector!\n");

    auxFESpaces.push_back(dv1->getFESpace());
    auxFESpaces.push_back(dv2->getFESpace());
  }

  Vec3AtQP_ZOT::Vec3AtQP_ZOT(DOFVectorBase<double> *dv1,
			     DOFVectorBase<double> *dv2,
			     DOFVectorBase<double> *dv3,
			     TertiaryAbstractFunction<double, double, double, double> *af)
    : ZeroOrderTerm(af->getDegree()), vec1(dv1), vec2(dv2), vec3(dv3), f(af)
  {
    TEST_EXIT(dv1)("No first vector!\n");
    TEST_EXIT(dv2)("No second vector!\n");
    TEST_EXIT(dv3)("No thierd vector!\n");

    auxFESpaces.push_back(dv1->getFESpace());
    auxFESpaces.push_back(dv2->getFESpace());
    auxFESpaces.push_back(dv3->getFESpace());
  }

  FctGradientCoords_ZOT::FctGradientCoords_ZOT(DOFVectorBase<double> *dv,
					       BinaryAbstractFunction<double, WorldVector<double>, WorldVector<double> > *af)
    : ZeroOrderTerm(af->getDegree()), vec(dv), f(af)
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecGradCoordsAtQP_ZOT::VecGradCoordsAtQP_ZOT(DOFVectorBase<double> *dv,
					       TertiaryAbstractFunction<double, double, WorldVector<double>, WorldVector<double> > *af)
    : ZeroOrderTerm(af->getDegree()), vec(dv), f(af) 
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecAndCoordsAtQP_ZOT::VecAndCoordsAtQP_ZOT(DOFVectorBase<double> *dv,
					     BinaryAbstractFunction<double, double, WorldVector<double> > *af)
    : ZeroOrderTerm(af->getDegree()), vec(dv), f(af) 
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  Vec2AndGradAtQP_ZOT::Vec2AndGradAtQP_ZOT(DOFVectorBase<double> *dv1, DOFVectorBase<double> *dv2,
					   TertiaryAbstractFunction<double, double, WorldVector<double>, double > *af)
    : ZeroOrderTerm(af->getDegree()), vec1(dv1), vec2(dv2), f(af) 
  {
    TEST_EXIT(dv1)("No first vector!\n");
    TEST_EXIT(dv2)("No second vector!\n");

    auxFESpaces.push_back(dv1->getFESpace());
    auxFESpaces.push_back(dv2->getFESpace());
  }

  FctGradient_ZOT::FctGradient_ZOT(DOFVectorBase<double> *dv,
				   AbstractFunction<double, WorldVector<double> > *af)
    : ZeroOrderTerm(af->getDegree()), vec(dv), f(af)
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecAndGradAtQP_ZOT::VecAndGradAtQP_ZOT(DOFVectorBase<double> *dv,
					 BinaryAbstractFunction<double, double, WorldVector<double> > *af)
    : ZeroOrderTerm(af->getDegree()), vec(dv), f(af) 
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecAndGradVecAtQP_ZOT::VecAndGradVecAtQP_ZOT(DOFVectorBase<double> *dv, 
					       DOFVectorBase<double> *dGrd,
					       BinaryAbstractFunction<double, double, WorldVector<double> > *af) 
    : ZeroOrderTerm(af->getDegree()), vec(dv), vecGrd(dGrd), f(af) 
  {
    TEST_EXIT(dv)("No vector!\n");
    TEST_EXIT(dGrd)("No gradient vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
    auxFESpaces.push_back(dGrd->getFESpace());
  }

  VecAndGradVec2AtQP_ZOT::VecAndGradVec2AtQP_ZOT(DOFVectorBase<double> *dv, 
						 DOFVectorBase<double> *dGrd1, 
						 DOFVectorBase<double> *dGrd2, 
						 TertiaryAbstractFunction<double, double, WorldVector<double>, WorldVector<double> > *af) 
    : ZeroOrderTerm(af->getDegree()), vec(dv), vecGrd1(dGrd1), vecGrd2(dGrd2), f(af) 
  {
    TEST_EXIT(dv)("No vector!\n");
    TEST_EXIT(dGrd1)("No first gradient vector!\n");
    TEST_EXIT(dGrd2)("No second gradient vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
    auxFESpaces.push_back(dGrd1->getFESpace());
    auxFESpaces.push_back(dGrd2->getFESpace());
  }

  VecOfDOFVecsAtQP_ZOT::VecOfDOFVecsAtQP_ZOT(const std::vector<DOFVectorBase<double>*>& dv, 
					     AbstractFunction<double, std::vector<double> > *af)
    : ZeroOrderTerm(af->getDegree()), vecs(dv), f(af) 
  {
    vecsAtQPs.resize(vecs.size());

    for (int i = 0; i < static_cast<int>(dv.size()); i++) {
      TEST_EXIT(dv[i])("One vector is NULL!\n");

      auxFESpaces.push_back(dv[i]->getFESpace());
    }
  } 

  VecOfGradientsAtQP_ZOT::VecOfGradientsAtQP_ZOT(const std::vector<DOFVectorBase<double>*>& dv,
						 AbstractFunction<double, std::vector<WorldVector<double>*> > *af) 
    : ZeroOrderTerm(af->getDegree()), vecs(dv), f(af) 
  {
    gradsAtQPs.resize(vecs.size());

    for (int i = 0; i < static_cast<int>(dv.size()); i++) {
      TEST_EXIT(dv[i])("One vector is NULL!\n");

      auxFESpaces.push_back(dv[i]->getFESpace());
    }
  } 

  VecDivergence_ZOT::VecDivergence_ZOT(int nComponents,
				       DOFVectorBase<double> *vec0,
				       DOFVectorBase<double> *vec1,
				       DOFVectorBase<double> *vec2)
    : ZeroOrderTerm(0)
  {
    vecs.resize(nComponents);
    gradsAtQPs.resize(nComponents);
    vecs[0] = vec0;
    vecs[1] = vec1;
    vecs[2] = vec2;

    auxFESpaces.push_back(vec0->getFESpace());
    if (vec1) 
      auxFESpaces.push_back(vec1->getFESpace());
    if (vec2) 
      auxFESpaces.push_back(vec2->getFESpace());
  }


  VecAndVecOfGradientsAtQP_ZOT::VecAndVecOfGradientsAtQP_ZOT(DOFVector<double> *v,
							     const std::vector<DOFVector<double>*>& dv,
							     BinaryAbstractFunction<double, double, std::vector<WorldVector<double>*> > *af)
    : ZeroOrderTerm(af->getDegree()), vec(v), vecs(dv), f(af)
  {
    gradsAtQPs.resize(vecs.size());

    TEST_EXIT(v)("No vector!\n");

    auxFESpaces.push_back(v->getFESpace());
    for (int i = 0; i < static_cast<int>(dv.size()); i++) {
      TEST_EXIT(dv[i])("One gradient vector is NULL!\n");

      auxFESpaces.push_back(dv[i]->getFESpace());
    }
  }

  General_ZOT::General_ZOT(std::vector<DOFVectorBase<double>*> vecs,
			   std::vector<DOFVectorBase<double>*> grads,
			   TertiaryAbstractFunction<double, WorldVector<double>, std::vector<double>, std::vector<WorldVector<double> > > *af)
    : ZeroOrderTerm(af->getDegree()), vecs_(vecs), grads_(grads), f_(af)
  {
    vecsAtQPs_.resize(vecs_.size());
    gradsAtQPs_.resize(grads_.size());

    for (int i = 0; i < static_cast<int>(vecs.size()); i++) {
      TEST_EXIT(vecs[i])("One vector is NULL!\n");

      auxFESpaces.push_back(vecs[i]->getFESpace());
    }   

    for (int i = 0; i < static_cast<int>(grads.size()); i++) {
      TEST_EXIT(grads[i])("One gradient vector is NULL!\n");

      auxFESpaces.push_back(grads[i]->getFESpace());
    }   
  }

  GeneralParametric_ZOT::GeneralParametric_ZOT(std::vector<DOFVectorBase<double>*> vecs,
					       std::vector<DOFVectorBase<double>*> grads,
					       QuartAbstractFunction<double, 
					       WorldVector<double>,
					       WorldVector<double>,
					       std::vector<double>, 
					       std::vector<WorldVector<double> > > *af)
    : ZeroOrderTerm(af->getDegree()), vecs_(vecs), grads_(grads), f_(af)
  {
    vecsAtQPs_.resize(vecs_.size());
    gradsAtQPs_.resize(grads_.size());

    for (int i = 0; i < static_cast<int>(vecs.size()); i++) {
      TEST_EXIT(vecs[i])("One vector is NULL!\n");

      auxFESpaces.push_back(vecs[i]->getFESpace());
    }   

    for (int i = 0; i < static_cast<int>(grads.size()); i++) {
      TEST_EXIT(grads[i])("One gradient vector is NULL!\n");

      auxFESpaces.push_back(grads[i]->getFESpace());
    }   
  }

  VecAtQP_FOT::VecAtQP_FOT(DOFVectorBase<double> *dv,
			   AbstractFunction<double, double> *af,
			   WorldVector<double> *wv)
    : FirstOrderTerm(af->getDegree()), vec(dv), f(af), b(wv)
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VectorGradient_FOT::VectorGradient_FOT(DOFVectorBase<double> *dv,
					 AbstractFunction<WorldVector<double>, WorldVector<double> > *af)
    : FirstOrderTerm(af->getDegree()), vec(dv), f(af)
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VectorFct_FOT::VectorFct_FOT(DOFVectorBase<double> *dv,
			       AbstractFunction<WorldVector<double>, double> *fct)
    : FirstOrderTerm(fct->getDegree()), vec(dv), vecFct(fct) 
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecGrad_FOT::VecGrad_FOT(DOFVectorBase<double> *dv1, DOFVectorBase<double> *dv2,
			   BinaryAbstractFunction<WorldVector<double>, double, WorldVector<double> > *fct)
    : FirstOrderTerm(fct->getDegree()), vec1(dv1), vec2(dv2), vecFct(fct) 
  {
    TEST_EXIT(dv1)("No first vector!\n");
    TEST_EXIT(dv2)("No second vector!\n");

    auxFESpaces.push_back(dv1->getFESpace());
    auxFESpaces.push_back(dv2->getFESpace());    
  }

  General_FOT::General_FOT(std::vector<DOFVectorBase<double>*> vecs,
			   std::vector<DOFVectorBase<double>*> grads,
			   TertiaryAbstractFunction<WorldVector<double>, 
			   WorldVector<double>,
			   std::vector<double>, 
			   std::vector<WorldVector<double> > > *af)
    : FirstOrderTerm(af->getDegree()), vecs_(vecs), grads_(grads), f_(af)
  {
    vecsAtQPs_.resize(vecs_.size());
    gradsAtQPs_.resize(grads_.size());

    for (int i = 0; i < static_cast<int>(vecs.size()); i++) {
      TEST_EXIT(vecs[i])("One vector is NULL!\n");

      auxFESpaces.push_back(vecs[i]->getFESpace());
    }   

    for (int i = 0; i < static_cast<int>(grads.size()); i++) {
      TEST_EXIT(grads[i])("One gradient vector is NULL!\n");

      auxFESpaces.push_back(grads[i]->getFESpace());
    }   
  }

  GeneralParametric_FOT::GeneralParametric_FOT(std::vector<DOFVectorBase<double>*> vecs,
					       std::vector<DOFVectorBase<double>*> grads,
					       QuartAbstractFunction<WorldVector<double>, 
					       WorldVector<double>,
					       WorldVector<double>,
					       std::vector<double>, 
					       std::vector<WorldVector<double> > > *af)
    : FirstOrderTerm(af->getDegree()), vecs_(vecs), grads_(grads), f_(af)
  {
    vecsAtQPs_.resize(vecs_.size());
    gradsAtQPs_.resize(grads_.size());

    for (int i = 0; i < static_cast<int>(vecs.size()); i++) {
      TEST_EXIT(vecs[i])("One vector is NULL!\n");

      auxFESpaces.push_back(vecs[i]->getFESpace());
    }   

    for (int i = 0; i < static_cast<int>(grads.size()); i++) {
      TEST_EXIT(grads[i])("One gradient vector is NULL!\n");

      auxFESpaces.push_back(grads[i]->getFESpace());
    }   
  }

  MatrixFct_SOT::MatrixFct_SOT(DOFVectorBase<double> *dv, 
			       AbstractFunction<WorldMatrix<double>, double> *fct,
			       AbstractFunction<WorldVector<double>, WorldMatrix<double> > *div,
			       bool sym)
    : SecondOrderTerm(fct->getDegree()), 
      vec(dv), 
      matrixFct(fct), 
      divFct(div),
      symmetric(sym)
  {
    setSymmetric(symmetric);

    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecAtQP_SOT::VecAtQP_SOT(DOFVectorBase<double> *dv, 
			   AbstractFunction<double, double> *af)
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af)
  {
    setSymmetric(true);

    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  Vec2AtQP_SOT::Vec2AtQP_SOT(DOFVectorBase<double> *dv1, DOFVectorBase<double> *dv2, 
			     BinaryAbstractFunction<double, double, double> *af)
    : SecondOrderTerm(af->getDegree()), vec1(dv1), vec2(dv2), f(af)
  {
    setSymmetric(true);

    TEST_EXIT(dv1)("No first vector!\n");
    TEST_EXIT(dv2)("No second vector!\n");

    auxFESpaces.push_back(dv1->getFESpace());
    auxFESpaces.push_back(dv2->getFESpace());
  }

  MatrixGradient_SOT::MatrixGradient_SOT(DOFVectorBase<double> *dv,
					 AbstractFunction<WorldMatrix<double>, WorldVector<double> > *af,
					 AbstractFunction<WorldVector<double>, WorldMatrix<double> > *divAf,
					 bool symm) 
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af), divFct(divAf), symmetric(symm)
  {
    setSymmetric(symmetric);

    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  FctGradient_SOT::FctGradient_SOT(DOFVectorBase<double> *dv,
				   AbstractFunction<double, WorldVector<double> > *af)
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af)
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecAndGradientAtQP_SOT::VecAndGradientAtQP_SOT(DOFVectorBase<double> *dv,
						 BinaryAbstractFunction<double, double, WorldVector<double> > *af)
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af)
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecMatrixGradientAtQP_SOT::VecMatrixGradientAtQP_SOT(DOFVectorBase<double> *dv,
						       BinaryAbstractFunction<WorldMatrix<double>, double, WorldVector<double> > *af,
						       AbstractFunction<WorldVector<double>, WorldMatrix<double> > *divAf,
						       bool symm)
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af), 
      divFct(divAf), symmetric(symm)
  {
    setSymmetric(symmetric);

    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecGradCoordsAtQP_SOT::VecGradCoordsAtQP_SOT(DOFVectorBase<double> *dv,
					       TertiaryAbstractFunction<double, double,
					       WorldVector<double>, WorldVector<double> > *af)
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af)
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecAndCoordsAtQP_SOT::VecAndCoordsAtQP_SOT(DOFVectorBase<double> *dv, 
					     BinaryAbstractFunction<double, double, WorldVector<double> > *af)
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af)
  {
    setSymmetric(true);

    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  MatrixGradientAndCoords_SOT::MatrixGradientAndCoords_SOT(DOFVectorBase<double> *dv,
							   BinaryAbstractFunction<WorldMatrix<double>,
							   WorldVector<double>, WorldVector<double> > *af,
							   AbstractFunction<WorldVector<double>,
							   WorldMatrix<double> > *divAf,
							   bool symm) 
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af), divFct(divAf), symmetric(symm)
  {
    setSymmetric(symmetric);

    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  General_SOT::General_SOT(std::vector<DOFVectorBase<double>*> vecs,
			   std::vector<DOFVectorBase<double>*> grads,
			   TertiaryAbstractFunction<WorldMatrix<double>, 
  			     WorldVector<double>,
			     std::vector<double>, 
			     std::vector<WorldVector<double> > > *f,
			   AbstractFunction<WorldVector<double>, 
			     WorldMatrix<double> > *divFct,
			     bool symmetric)
      : SecondOrderTerm(f->getDegree()),
	vecs_(vecs),
	grads_(grads),
	f_(f),
	divFct_(divFct),
	symmetric_(symmetric)
  {
    vecsAtQPs_.resize(vecs_.size());
    gradsAtQPs_.resize(grads_.size());

    for (int i = 0; i < static_cast<int>(vecs.size()); i++) {
      TEST_EXIT(vecs[i])("One vector is NULL!\n");

      auxFESpaces.push_back(vecs[i]->getFESpace());
    }   

    for (int i = 0; i < static_cast<int>(grads.size()); i++) {
      TEST_EXIT(grads[i])("One gradient vector is NULL!\n");

      auxFESpaces.push_back(grads[i]->getFESpace());
    }
  }

  GeneralParametric_SOT::GeneralParametric_SOT(std::vector<DOFVectorBase<double>*> vecs,
					       std::vector<DOFVectorBase<double>*> grads,
					       QuartAbstractFunction<WorldMatrix<double>, 
					         WorldVector<double>,
					         WorldVector<double>,
					         std::vector<double>, 
					         std::vector<WorldVector<double> > > *f,
					       AbstractFunction<WorldVector<double>, 
					         WorldMatrix<double> > *divFct,
					       bool symmetric)
    : SecondOrderTerm(f->getDegree()),
      vecs_(vecs),
      grads_(grads),
      f_(f),
      divFct_(divFct),
      symmetric_(symmetric)
  {
    vecsAtQPs_.resize(vecs_.size());
    gradsAtQPs_.resize(grads_.size());

    for (int i = 0; i < static_cast<int>(vecs.size()); i++) {
      TEST_EXIT(vecs[i])("One vector is NULL!\n");

      auxFESpaces.push_back(vecs[i]->getFESpace());
    }   

    for (int i = 0; i < static_cast<int>(grads.size()); i++) {
      TEST_EXIT(grads[i])("One gradient vector is NULL!\n");

      auxFESpaces.push_back(grads[i]->getFESpace());
    }
  }

  VecAndGradAtQP_SOT::VecAndGradAtQP_SOT(DOFVectorBase<double> *dv,
					 BinaryAbstractFunction<double, double, WorldVector<double> > *af)
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af) 
  {
    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }

  VecAtQP_IJ_SOT::VecAtQP_IJ_SOT(DOFVectorBase<double> *dv, 
				 AbstractFunction<double, double> *af,
				 int x_i, int x_j)
    : SecondOrderTerm(af->getDegree()), vec(dv), f(af), xi(x_i), xj(x_j)
  {
    setSymmetric(xi == xj);

    TEST_EXIT(dv)("No vector!\n");

    auxFESpaces.push_back(dv->getFESpace());
  }



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  void MatrixFct_SOT::initElement(const ElInfo* elInfo, 
				  SubAssembler* subAssembler,
				  Quadrature *quad) 
  {
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    vecAtQPs = getVectorAtQPs(vec, elInfo, subAssembler, quad);
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  }
 
  void VecAtQP_SOT::initElement(const ElInfo* elInfo, 
				SubAssembler* subAssembler,
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				Quadrature* quad) 
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  {
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    vecAtQPs = getVectorAtQPs(vec, elInfo, subAssembler, quad);
  }

  void VecAtQP_SOT::initElement(const ElInfo* smallElInfo, 
				const ElInfo* largeElInfo,
				SubAssembler* subAssembler,
				Quadrature* quad) 
  {
    vecAtQPs = getVectorAtQPs(vec, smallElInfo, largeElInfo, subAssembler, quad);
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  }
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  void Vec2AtQP_SOT::initElement(const ElInfo* elInfo, 
				 SubAssembler* subAssembler,
				 Quadrature *quad) 
  {
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    vecAtQPs1 = getVectorAtQPs(vec1, elInfo, subAssembler, quad);
    vecAtQPs2 = getVectorAtQPs(vec2, elInfo, subAssembler, quad);
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  }
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  void CoordsAtQP_SOT::initElement(const ElInfo* elInfo, 
				   SubAssembler* subAssembler,
				   Quadrature *quad) 
  {
    coordsAtQPs = subAssembler->getCoordsAtQPs(elInfo, quad);
  }

  void MatrixGradient_SOT::initElement(const ElInfo* elInfo, 
				       SubAssembler* subAssembler,
				       Quadrature *quad) 
  {
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    gradAtQPs = getGradientsAtQPs(vec, elInfo, subAssembler, quad);
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  }

  void FctGradient_SOT::initElement(const ElInfo* elInfo, 
				    SubAssembler* subAssembler,
				    Quadrature *quad) 
  {
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    gradAtQPs = getGradientsAtQPs(vec, elInfo, subAssembler, quad);
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  }

  void VecAndGradientAtQP_SOT::initElement(const ElInfo* elInfo, 
					   SubAssembler* subAssembler,
					   Quadrature *quad) 
  {
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    vecAtQPs = getVectorAtQPs(vec, elInfo, subAssembler, quad);
    gradAtQPs = getGradientsAtQPs(vec, elInfo, subAssembler, quad);
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  }

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  void VecMatrixGradientAtQP_SOT::initElement(const ElInfo* elInfo, 
					      SubAssembler* subAssembler,
					      Quadrature *quad) 
  {
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    vecAtQPs = getVectorAtQPs(vec, elInfo, subAssembler, quad);
    gradAtQPs = getGradientsAtQPs(vec, elInfo, subAssembler, quad);
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  }
  
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  void VecAndCoordsAtQP_SOT::initElement(const ElInfo* elInfo, 
					 SubAssembler* subAssembler,
					 Quadrature *quad) 
  {
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    vecAtQPs = getVectorAtQPs(vec, elInfo, subAssembler, quad);
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    coordsAtQPs = subAssembler->getCoordsAtQPs(elInfo, quad);
  }
 
  void MatrixGradientAndCoords_SOT::initElement(const ElInfo* elInfo, 
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