Commit 0e7a58de authored by Hieram Neumann-Heyme's avatar Hieram Neumann-Heyme

Small issue with arh-files / append index, fixed a few typos

parent 57d26e55
......@@ -100,7 +100,7 @@ namespace AMDiS {
{
FUNCNAME("OEMSolver::solveSystem()");
TEST_EXIT(false)
("This linear solver is not suitable for sequentiell problems\n");
("This linear solver is not suitable for sequential problems\n");
return -1;
}
......@@ -122,7 +122,7 @@ namespace AMDiS {
{
FUNCNAME("OEMSolver::solveSystem()");
TEST_EXIT(false)
("This linear solver is not suitable for domaindecomposition problems\n");
("This linear solver is not suitable for domain decomposition problems\n");
return -1;
}
#endif
......
......@@ -39,7 +39,7 @@ namespace AMDiS {
class SurfaceAssembler : public Assembler
{
public:
/// Creates a SurfaceAssembler conforming to operat for the given \ref coords.
/// Creates a SurfaceAssembler conforming to operate for the given \ref coords.
SurfaceAssembler(Operator *operat,
const FiniteElemSpace *rowFeSpace,
const FiniteElemSpace *colFeSpace,
......
......@@ -104,7 +104,7 @@ namespace AMDiS {
SubAssembler* subAssembler,
Quadrature *quad = NULL);
/// Implementation of \ref OperatorTerm::initElement() for multilpe meshes.
/// Implementation of \ref OperatorTerm::initElement() for multiple meshes.
void initElement(const ElInfo* smallElInfo,
const ElInfo* largeElInfo,
SubAssembler* subAssembler,
......@@ -288,7 +288,7 @@ namespace AMDiS {
void initElement(const ElInfo* elInfo, SubAssembler* subAssembler,
Quadrature *quad = NULL);
/// Implements SecondOrderTerm::getC().
/// Implements ZeroOrderTerm::getC().
void getC(const ElInfo *elInfo, int nPoints, ElementVector& C);
/// Implements ZeroOrderTerm::eval().
......@@ -456,7 +456,7 @@ namespace AMDiS {
void initElement(const ElInfo* elInfo, SubAssembler* subAssembler,
Quadrature *quad = NULL);
/// Implements SecondOrderTerm::getC().
/// Implements ZeroOrderTerm::getC().
void getC(const ElInfo *elInfo, int nPoints, ElementVector& C);
/// Implements ZeroOrderTerm::eval().
......@@ -470,7 +470,7 @@ namespace AMDiS {
protected:
DOFVectorBase<double>* vec;
/// Function wich maps \ref gradAtQPs to a double.
/// Function which maps \ref gradAtQPs to a double.
AbstractFunction<double, WorldVector<double> > *f;
/** \brief
......
......@@ -249,7 +249,7 @@ namespace AMDiS {
double timestep;
/** \brief
* Stores information about which mesh(es) must be travesed to estimate
* Stores information about which mesh(es) must be traversed to estimate
* the error on the component matrices.
*/
ComponentTraverseInfo traverseInfo;
......
......@@ -195,7 +195,7 @@ namespace AMDiS {
ArhWriter::write(paraFilename + ".arh", feSpace->getMesh(), solutionVecs);
#else
if (writeArhFormat)
ArhWriter::write(filename + ".arh", feSpace->getMesh(), solutionVecs);
ArhWriter::write(fn + ".arh", feSpace->getMesh(), solutionVecs);
#endif
......
......@@ -196,9 +196,9 @@ namespace AMDiS {
* This function must be used if the values of a DOFVector must be
* synchronised over all ranks. That means, that each rank sends the
* values of the DOFs, which are owned by the rank and lie on an interior
* bounday, to all other ranks also having these DOFs.
* boundary, to all other ranks also having these DOFs.
*
* This function must be used, for example, after the lineary system is
* This function must be used, for example, after the linear system is
* solved, or after the DOFVector is set by some user defined functions,
* e.g., initial solution functions.
*/
......@@ -348,7 +348,7 @@ namespace AMDiS {
const FiniteElemSpace *feSpace);
protected:
/// Creates an initial paritioning of the mesh.
/// Creates an initial partitioning of the mesh.
void createInitialPartitioning();
/// Set for each element on the partitioning level the number of
......
......@@ -64,7 +64,7 @@ namespace AMDiS {
virtual ~MeshPartitioner() {}
/** \brief
* Creates an initial paritioning of the AMDiS mesh. This partitioning
* Creates an initial partitioning of the AMDiS mesh. This partitioning
* can be arbitrary, the only requirement is that each macro element
* must be uniquely assign to a rank.
*
......@@ -84,7 +84,7 @@ namespace AMDiS {
* elements in this macro element.
* \param[in] mode Most external partitioning libraries can make
* a difference whether we want to create a
* first partitioning or we alread have created
* first partitioning or we already have created
* one using this library but due to some mesh
* adaptivity we want to repartition the mesh. In
* the later case, the libraries also consider the
......@@ -162,9 +162,9 @@ namespace AMDiS {
/// The mesh partitioner can be used in to different modes, the standard
/// mode and the so called "box partitioning". The standard mode assigns
/// macro elements to ranks. If box partitioning is enabled, which makes
/// only sence if the macro mesh results from meshconv's "lego mesher",
/// only sense if the macro mesh results from meshconv's "lego mesher",
/// then in 2D boxed (2 macro elements) and in 3D cubes (6 macro
/// elements) are assigned as a uniion to ranks.
/// elements) are assigned as a union to ranks.
bool boxPartitioning;
/// In box partitioning mode this map stores for each box number the set
......@@ -188,7 +188,7 @@ namespace AMDiS {
map<int, bool> elementInRank;
/// Maps to each macro element index (or box index in box
/// partitiong mode) the rank number the element belongs to.
/// partitioning mode) the rank number the element belongs to.
map<int, int> partitionMap;
/// After mesh repartitioning these maps stores which elements are communicated
......
......@@ -9,9 +9,16 @@ using namespace AMDiS;
namespace experimental {
/// Extended recovery gradient assuming mirror/point symmetry (pointSym=false/true)
/// of the solution at domain boundaries
/// --> Simon, es hat sich herausgestellt, dass meine ursprüngliche Version mit *nrm
/// effizienter ist, da Speicher nur für einige Ausnahmeknoten belegt wird (ok, ist
/// vielleicht etwas unübersichtlich)
inline void getRecoveryGradientSym(const DOFVector<double> *u,
DOFVector<WorldVector<double> > *result,
bool asym = true)
bool pointSym = false)
{
FUNCNAME("getRecoveryGradientSym()");
const FiniteElemSpace *feSpace = u->getFeSpace();
......@@ -59,7 +66,7 @@ namespace experimental {
WorldVector<double> n, rgrd;
elInfo->getNormal(i, n);
if (asym)
if (pointSym)
rgrd = grd;
else
rgrd = grd - 2.0*n*(grd*n); // reflect gradient at boundary
......@@ -95,7 +102,7 @@ namespace experimental {
u->getLocalVector(elInfo->getElement(), localUh);
basFcts->evalGrdUh(bary, grdLambda, localUh, grd);
if (asym)
if (pointSym)
rgrd= grd;
else {
n = 1.0/norm(nrm[localIndices[i]]) * nrm[localIndices[i]];
......@@ -120,4 +127,4 @@ namespace experimental {
} // end namespace experimental
#endif // GRADIENT_CALCULATIONS_H
\ No newline at end of file
#endif // GRADIENT_CALCULATIONS_H
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