void StringFunction::operator()(MDArray& input_phy_points, MDArray& output_values,
const stk::mesh::Bucket& bucket, const MDArray& parametric_coordinates, double time_value_optional)
{
PRINT("tmp srk StringFunction::operator(bucket) getName()= " << getName() << " input_phy_points= " << input_phy_points << " output_values= " << output_values);
VERIFY_OP(input_phy_points.rank(), ==, 3, "StringFunction::operator() must pass in input_phy_points(numCells, numPointsPerCell, spaceDim)");
int nPoints = input_phy_points.dimension(1);
int nSpaceDim = input_phy_points.dimension(2);
int nOutDim = output_values.dimension(2);
MDArray input_phy_points_one(1, nPoints, nSpaceDim);
MDArray output_values_one (1, nPoints, nOutDim);
const unsigned num_elements_in_bucket = bucket.size();
for (unsigned iElement = 0; iElement < num_elements_in_bucket; iElement++)
{
stk::mesh::Entity& element = bucket[iElement];
for (int iPoint = 0; iPoint<nPoints; iPoint++)
{
for (int iSpaceDim=0; iSpaceDim < nSpaceDim; iSpaceDim++)
{
input_phy_points_one(0, iPoint, iSpaceDim) = input_phy_points(iElement, iPoint, iSpaceDim);
}
}
(*this)(input_phy_points_one, output_values_one, element, parametric_coordinates, time_value_optional);
for (int iPoint = 0; iPoint<nPoints; iPoint++)
{
for (int iDOF = 0; iDOF < nOutDim; iDOF++)
{
output_values(iElement, iPoint, iDOF) = output_values_one(0, iPoint, iDOF);
}
}
}
}
/** Evaluate the function at this input point (or points) returning value(s) in output_field_values
*
* In the following, the arrays are dimensioned using the notation (from Intrepid's doc):
*
* [C] - num. integration domains (cells/elements)
* [F] - num. Intrepid "fields" (number of bases within an element == num. nodes typically)
* [P] - num. integration (or interpolation) points within the element
* [D] - spatial dimension
* [D1], [D2] - spatial dimension
*
* Locally, we introduce this notation:
*
* [DOF] - number of degrees-of-freedom per node of the interpolated stk Field. For example, a vector field in 3D has [DOF] = 3
*
* Dimensions of input_phy_points are required to be either ([D]) or ([P],[D])
* Dimensions of output_field_values are required to be ([DOF]) or ([P],[DOF]) respectively
*
* [R] is used for the rank of MDArray's
*/
void FieldFunction::operator()(MDArray& input_phy_points, MDArray& output_field_values, double time)
{
EXCEPTWATCH;
argsAreValid(input_phy_points, output_field_values);
m_found_on_local_owned_part = false;
//// single point only (for now)
unsigned found_it = 0;
int D_ = last_dimension(input_phy_points);
MDArray found_parametric_coordinates_one(1, D_);
setup_searcher(D_);
MDArray output_field_values_local = output_field_values;
int R_output = output_field_values.rank();
int R_input = input_phy_points.rank();
int P_ = (R_input == 1 ? 1 : input_phy_points.dimension(R_input-2));
// FIXME for tensor valued fields
int DOF_ = last_dimension(output_field_values_local);
MDArray input_phy_points_one(1,D_);
MDArray output_field_values_one(1,DOF_);
int C_ = 1;
if (R_input == 3)
{
C_ = input_phy_points.dimension(0);
}
for (int iC = 0; iC < C_; iC++)
{
for (int iP = 0; iP < P_; iP++)
{
for (int iD = 0; iD < D_; iD++)
{
switch(R_input)
{
case 1: input_phy_points_one(0, iD) = input_phy_points(iD); break;
case 2: input_phy_points_one(0, iD) = input_phy_points(iP, iD); break;
case 3: input_phy_points_one(0, iD) = input_phy_points(iC, iP, iD); break;
default: VERIFY_1("bad rank");
}
}
const stk_classic::mesh::Entity *found_element = 0;
{
EXCEPTWATCH;
//if (m_searchType==STK_SEARCH) std::cout << "find" << std::endl;
found_element = m_searcher->findElement(input_phy_points_one, found_parametric_coordinates_one, found_it, m_cachedElement);
//if (m_searchType==STK_SEARCH) std::cout << "find..done found_it=" << found_it << std::endl;
}
// if found element on the local owned part, evaluate
if (found_it)
{
m_found_on_local_owned_part = true;
if (( EXTRA_PRINT) && m_searchType==STK_SEARCH)
std::cout << "FieldFunction::operator() found element # = " << found_element->identifier() << std::endl;
(*this)(input_phy_points_one, output_field_values_one, *found_element, found_parametric_coordinates_one);
for (int iDOF = 0; iDOF < DOF_; iDOF++)
{
switch (R_output)
{
case 1: output_field_values_local( iDOF) = output_field_values_one(0, iDOF); break;
case 2: output_field_values_local(iP, iDOF) = output_field_values_one(0, iDOF); break;
case 3: output_field_values_local(iC, iP, iDOF) = output_field_values_one(0, iDOF); break;
default: VERIFY_1("bad rank");
}
}
}
else
{
if (!m_parallelEval)
{
std::cout << "P[" << Util::get_rank() << "] FieldFunction::operator() found_it = " << found_it << " points= "
<< input_phy_points_one
<< std::endl;
throw std::runtime_error("FieldFunction::operator() in local eval mode and didn't find element - logic error");
}
double max_val = std::numeric_limits<double>::max();
output_field_values_local.initialize(max_val);
}
// make sure it is found somewhere
if (m_parallelEval)
{
all_reduce( m_bulkData->parallel() , ReduceMax<1>( & found_it ) );
}
if (EXTRA_PRINT) std::cout << "FieldFunction::operator() global found_it = " << found_it << std::endl;
if (!found_it)
{
throw std::runtime_error("FieldFunction::operator() couldn't find element");
}
if (m_parallelEval)
{
stk_percept_global_lex_min( m_bulkData->parallel(), output_field_values.size(), &output_field_values_local[0], &output_field_values[0]);
}
else
{
output_field_values = output_field_values_local;
}
m_cachedElement = found_element;
}
}
}
