void BlockedOperatorStructure<BasisFunctionType, ResultType>::setBlock(
size_t row, size_t column,
const BoundaryOperator<BasisFunctionType, ResultType> &op) {
if (!op.isInitialized())
resetBlock(row, column);
else
m_blocks[Key(row, column)] = op;
}
BoundaryOperator<BasisFunctionType, ResultType>
modifiedHelmholtz3dSyntheticHypersingularBoundaryOperator(
const shared_ptr<const Context<BasisFunctionType, ResultType>> &context,
const shared_ptr<const Space<BasisFunctionType>> &domain,
const shared_ptr<const Space<BasisFunctionType>> &range,
const shared_ptr<const Space<BasisFunctionType>> &dualToRange,
KernelType waveNumber, std::string label, int internalSymmetry,
bool useInterpolation, int interpPtsPerWavelength,
const BoundaryOperator<BasisFunctionType, ResultType> &externalSlp) {
typedef typename ScalarTraits<BasisFunctionType>::RealType CoordinateType;
typedef Fiber::ScalarFunctionValueFunctor<CoordinateType> ValueFunctor;
typedef Fiber::ScalarFunctionValueTimesNormalFunctor<CoordinateType>
ValueTimesNormalFunctor;
typedef Fiber::SurfaceCurl3dFunctor<CoordinateType> CurlFunctor;
typedef Fiber::SingleComponentTestTrialIntegrandFunctor<
BasisFunctionType, ResultType> IntegrandFunctor;
typedef GeneralElementaryLocalOperator<BasisFunctionType, ResultType> LocalOp;
typedef SyntheticIntegralOperator<BasisFunctionType, ResultType> SyntheticOp;
if (!domain || !range || !dualToRange)
throw std::invalid_argument(
"modifiedHelmholtz3dSyntheticHypersingularBoundaryOperator(): "
"domain, range and dualToRange must not be null");
shared_ptr<const Space<BasisFunctionType>> newDomain = domain;
shared_ptr<const Space<BasisFunctionType>> newDualToRange = dualToRange;
bool isBarycentric =
(domain->isBarycentric() || dualToRange->isBarycentric());
if (isBarycentric) {
newDomain = domain->barycentricSpace(domain);
newDualToRange = dualToRange->barycentricSpace(dualToRange);
}
shared_ptr<const Context<BasisFunctionType, ResultType>> internalContext,
auxContext;
SyntheticOp::getContextsForInternalAndAuxiliaryOperators(
context, internalContext, auxContext);
shared_ptr<const Space<BasisFunctionType>> internalTrialSpace =
newDomain->discontinuousSpace(newDomain);
shared_ptr<const Space<BasisFunctionType>> internalTestSpace =
newDualToRange->discontinuousSpace(newDualToRange);
// Note: we don't really need to care about ranges and duals to domains of
// the internal operator. The only range space that matters is that of the
// leftmost operator in the product.
const char xyz[] = "xyz";
const size_t dimWorld = 3;
if (label.empty())
label =
AbstractBoundaryOperator<BasisFunctionType, ResultType>::uniqueLabel();
BoundaryOperator<BasisFunctionType, ResultType> slp;
if (!externalSlp.isInitialized()) {
slp = modifiedHelmholtz3dSingleLayerBoundaryOperator<
BasisFunctionType, KernelType, ResultType>(
internalContext, internalTrialSpace,
internalTestSpace /* or whatever */, internalTestSpace, waveNumber,
"(" + label + ")_internal_SLP", internalSymmetry, useInterpolation,
interpPtsPerWavelength);
} else {
slp = externalSlp;
}
// symmetry of the decomposition
int syntheseSymmetry = 0; // symmetry of the decomposition
if (newDomain == newDualToRange && internalTrialSpace == internalTestSpace)
syntheseSymmetry =
HERMITIAN | (boost::is_complex<BasisFunctionType>() ? 0 : SYMMETRIC);
std::vector<BoundaryOperator<BasisFunctionType, ResultType>> testLocalOps;
std::vector<BoundaryOperator<BasisFunctionType, ResultType>> trialLocalOps;
testLocalOps.resize(dimWorld);
for (size_t i = 0; i < dimWorld; ++i)
testLocalOps[i] = BoundaryOperator<BasisFunctionType, ResultType>(
auxContext, boost::make_shared<LocalOp>(
internalTestSpace, range, newDualToRange,
("(" + label + ")_test_curl_") + xyz[i], NO_SYMMETRY,
CurlFunctor(), ValueFunctor(), IntegrandFunctor(i, 0)));
if (!syntheseSymmetry) {
trialLocalOps.resize(dimWorld);
for (size_t i = 0; i < dimWorld; ++i)
trialLocalOps[i] = BoundaryOperator<BasisFunctionType, ResultType>(
auxContext,
boost::make_shared<LocalOp>(
newDomain, internalTrialSpace /* or whatever */,
internalTrialSpace, ("(" + label + ")_trial_curl_") + xyz[i],
NO_SYMMETRY, ValueFunctor(), CurlFunctor(),
IntegrandFunctor(0, i)));
}
// It might be more prudent to distinguish between the symmetry of the total
// operator and the symmetry of the decomposition
BoundaryOperator<BasisFunctionType, ResultType> term0(
context, boost::make_shared<SyntheticOp>(testLocalOps, slp, trialLocalOps,
label, syntheseSymmetry));
for (size_t i = 0; i < dimWorld; ++i)
testLocalOps[i] = BoundaryOperator<BasisFunctionType, ResultType>(
auxContext,
boost::make_shared<LocalOp>(
internalTestSpace, range, newDualToRange,
("(" + label + ")_test_k_value_n_") + xyz[i], NO_SYMMETRY,
ValueTimesNormalFunctor(), ValueFunctor(), IntegrandFunctor(i, 0)));
if (!syntheseSymmetry)
for (size_t i = 0; i < dimWorld; ++i)
trialLocalOps[i] = BoundaryOperator<BasisFunctionType, ResultType>(
auxContext,
boost::make_shared<LocalOp>(
newDomain, internalTrialSpace /* or whatever */,
internalTrialSpace, ("(" + label + ")_trial_k_value_n_") + xyz[i],
NO_SYMMETRY, ValueFunctor(), ValueTimesNormalFunctor(),
IntegrandFunctor(0, i)));
BoundaryOperator<BasisFunctionType, ResultType> slp_waveNumberSq =
(waveNumber * waveNumber) * slp;
BoundaryOperator<BasisFunctionType, ResultType> term1(
context,
boost::make_shared<SyntheticOp>(testLocalOps, slp_waveNumberSq,
trialLocalOps, label, syntheseSymmetry));
return term0 + term1;
}
BoundaryOperator<BasisFunctionType, ResultType>
modifiedHelmholtz3dHypersingularBoundaryOperator(
const shared_ptr<const Context<BasisFunctionType, ResultType>> &context,
const shared_ptr<const Space<BasisFunctionType>> &domain,
const shared_ptr<const Space<BasisFunctionType>> &range,
const shared_ptr<const Space<BasisFunctionType>> &dualToRange,
KernelType waveNumber, const std::string &label, int symmetry,
bool useInterpolation, int interpPtsPerWavelength,
const BoundaryOperator<BasisFunctionType, ResultType> &externalSlp) {
const AssemblyOptions &assemblyOptions = context->assemblyOptions();
if ((assemblyOptions.assemblyMode() == AssemblyOptions::ACA &&
assemblyOptions.acaOptions().mode == AcaOptions::LOCAL_ASSEMBLY) ||
externalSlp.isInitialized())
return modifiedHelmholtz3dSyntheticHypersingularBoundaryOperator(
context, domain, range, dualToRange, waveNumber, label, symmetry,
useInterpolation, interpPtsPerWavelength, externalSlp);
typedef typename ScalarTraits<BasisFunctionType>::RealType CoordinateType;
typedef Fiber::ModifiedHelmholtz3dHypersingularKernelFunctor<KernelType>
NoninterpolatedKernelFunctor;
typedef Fiber::ModifiedHelmholtz3dHypersingularKernelInterpolatedFunctor<
KernelType> InterpolatedKernelFunctor;
typedef Fiber::ModifiedHelmholtz3dHypersingularTransformationFunctor<
CoordinateType> TransformationFunctor;
typedef Fiber::ModifiedHelmholtz3dHypersingularIntegrandFunctor2<
BasisFunctionType, KernelType, ResultType> IntegrandFunctor;
typedef Fiber::ModifiedHelmholtz3dHypersingularTransformationFunctor2<
CoordinateType> TransformationFunctorWithBlas;
typedef Fiber::
ModifiedHelmholtz3dHypersingularOffDiagonalInterpolatedKernelFunctor<
KernelType> OffDiagonalInterpolatedKernelFunctor;
typedef Fiber::ModifiedHelmholtz3dHypersingularOffDiagonalKernelFunctor<
KernelType> OffDiagonalNoninterpolatedKernelFunctor;
typedef Fiber::ScalarFunctionValueFunctor<CoordinateType>
OffDiagonalTransformationFunctor;
typedef Fiber::SimpleTestScalarKernelTrialIntegrandFunctorExt<
BasisFunctionType, KernelType, ResultType, 1> OffDiagonalIntegrandFunctor;
CoordinateType maxDistance_ =
static_cast<CoordinateType>(1.1) *
maxDistance(*domain->grid(), *dualToRange->grid());
shared_ptr<Fiber::TestKernelTrialIntegral<BasisFunctionType, KernelType,
ResultType>> integral,
offDiagonalIntegral;
if (shouldUseBlasInQuadrature(assemblyOptions, *domain, *dualToRange)) {
integral.reset(new Fiber::TypicalTestScalarKernelTrialIntegral<
BasisFunctionType, KernelType, ResultType>());
offDiagonalIntegral = integral;
} else {
integral.reset(new Fiber::DefaultTestKernelTrialIntegral<IntegrandFunctor>(
IntegrandFunctor()));
offDiagonalIntegral.reset(
new Fiber::DefaultTestKernelTrialIntegral<OffDiagonalIntegrandFunctor>(
OffDiagonalIntegrandFunctor()));
}
typedef GeneralHypersingularIntegralOperator<BasisFunctionType, KernelType,
ResultType> Op;
shared_ptr<Op> newOp;
if (shouldUseBlasInQuadrature(assemblyOptions, *domain, *dualToRange)) {
shared_ptr<Fiber::TestKernelTrialIntegral<BasisFunctionType, KernelType,
ResultType>> integral,
offDiagonalIntegral;
integral.reset(new Fiber::TypicalTestScalarKernelTrialIntegral<
BasisFunctionType, KernelType, ResultType>());
offDiagonalIntegral = integral;
if (useInterpolation)
newOp.reset(new Op(
domain, range, dualToRange, label, symmetry,
InterpolatedKernelFunctor(waveNumber, maxDistance_,
interpPtsPerWavelength),
TransformationFunctorWithBlas(), TransformationFunctorWithBlas(),
integral, OffDiagonalInterpolatedKernelFunctor(
waveNumber, maxDistance_, interpPtsPerWavelength),
OffDiagonalTransformationFunctor(),
OffDiagonalTransformationFunctor(), offDiagonalIntegral));
else
newOp.reset(new Op(
domain, range, dualToRange, label, symmetry,
NoninterpolatedKernelFunctor(waveNumber),
TransformationFunctorWithBlas(), TransformationFunctorWithBlas(),
integral, OffDiagonalNoninterpolatedKernelFunctor(waveNumber),
OffDiagonalTransformationFunctor(),
OffDiagonalTransformationFunctor(), offDiagonalIntegral));
} else { // no blas
if (useInterpolation)
newOp.reset(new Op(
domain, range, dualToRange, label, symmetry,
InterpolatedKernelFunctor(waveNumber, maxDistance_,
interpPtsPerWavelength),
TransformationFunctor(), TransformationFunctor(), IntegrandFunctor(),
OffDiagonalInterpolatedKernelFunctor(waveNumber, maxDistance_,
interpPtsPerWavelength),
OffDiagonalTransformationFunctor(),
OffDiagonalTransformationFunctor(), OffDiagonalIntegrandFunctor()));
else
newOp.reset(new Op(
domain, range, dualToRange, label, symmetry,
NoninterpolatedKernelFunctor(waveNumber), TransformationFunctor(),
TransformationFunctor(), IntegrandFunctor(),
OffDiagonalNoninterpolatedKernelFunctor(waveNumber),
OffDiagonalTransformationFunctor(),
OffDiagonalTransformationFunctor(), OffDiagonalIntegrandFunctor()));
}
return BoundaryOperator<BasisFunctionType, ResultType>(context, newOp);
}
