bool checkLTSumConsistency(LinearTermPtr a, LinearTermPtr b, DofOrderingPtr dofOrdering, BasisCachePtr basisCache)
{
double tol = 1e-14;
int numCells = basisCache->cellIDs().size();
int numDofs = dofOrdering->totalDofs();
bool forceBoundaryTerm = false;
FieldContainer<double> aValues(numCells,numDofs), bValues(numCells,numDofs), sumValues(numCells,numDofs);
a->integrate(aValues,dofOrdering,basisCache,forceBoundaryTerm);
b->integrate(bValues,dofOrdering,basisCache,forceBoundaryTerm);
(a+b)->integrate(sumValues, dofOrdering, basisCache, forceBoundaryTerm);
int size = aValues.size();
for (int i=0; i<size; i++)
{
double expectedValue = aValues[i] + bValues[i];
double diff = abs( expectedValue - sumValues[i] );
if (diff > tol)
{
return false;
}
}
return true;
}
double integralOverMesh(LinearTermPtr testTerm, VarPtr testVar, FunctionPtr fxnToSubstitute) {
map<int, FunctionPtr > varAsFunction;
varAsFunction[testVar->ID()] = fxnToSubstitute;
FunctionPtr substituteOnBoundary = testTerm->evaluate(varAsFunction, true);
FunctionPtr substituteOnInterior = testTerm->evaluate(varAsFunction, false);
double integral = substituteOnBoundary->integrate(mesh);
integral += substituteOnInterior->integrate(mesh);
return integral;
}
PreviousSolutionFunction::PreviousSolutionFunction(SolutionPtr soln, LinearTermPtr solnExpression, bool multiplyFluxesByCellParity) : Function(solnExpression->rank()) {
_soln = soln;
_solnExpression = solnExpression;
_overrideMeshCheck = false;
if ((solnExpression->termType() == FLUX) && multiplyFluxesByCellParity) {
FunctionPtr parity = Teuchos::rcp( new SideParityFunction );
_solnExpression = parity * solnExpression;
}
}
PreviousSolutionFunction<Scalar>::PreviousSolutionFunction(TSolutionPtr<Scalar> soln, LinearTermPtr solnExpression, bool multiplyFluxesByCellParity) : TFunction<Scalar>(solnExpression->rank())
{
_soln = soln;
_solnExpression = solnExpression;
_overrideMeshCheck = false;
if ((solnExpression->termType() == FLUX) && multiplyFluxesByCellParity)
{
TFunctionPtr<double> parity = TFunction<double>::sideParity();
_solnExpression = parity * solnExpression;
}
}
void LagrangeConstraints::getCoefficients(FieldContainer<double> &lhs, FieldContainer<double> &rhs,
int elemConstraintIndex, DofOrderingPtr trialOrdering,
BasisCachePtr basisCache)
{
LinearTermPtr lt = _constraints[elemConstraintIndex].linearTerm();
TFunctionPtr<double> f = _constraints[elemConstraintIndex].f();
lt->integrate(lhs, trialOrdering, basisCache);
bool onBoundary = f->boundaryValueOnly();
if ( !onBoundary )
{
f->integrate(rhs, basisCache);
}
else
{
int numSides = basisCache->cellTopology()->getSideCount();
rhs.initialize(0);
for (int sideIndex=0; sideIndex<numSides; sideIndex++)
{
f->integrate(rhs, basisCache->getSideBasisCache(sideIndex), true); // true: sumInto
}
}
}
bool LinearTermTests::testLinearTermEvaluation()
{
bool success = true;
double eps = .1;
FunctionPtr one = Function::constant(1.0);
vector<double> e1,e2;
e1.push_back(1.0);
e1.push_back(0.0);
e2.push_back(0.0);
e2.push_back(1.0);
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr tau = varFactory->testVar("\\tau", HDIV);
VarPtr v = varFactory->testVar("v", HGRAD);
// define a couple LinearTerms
LinearTermPtr vVecLT = Teuchos::rcp(new LinearTerm);
LinearTermPtr tauVecLT = Teuchos::rcp(new LinearTerm);
vVecLT->addTerm(sqrt(eps)*v->grad());
tauVecLT->addTerm((1/sqrt(eps))*tau);
//////////////////// evaluate LinearTerms /////////////////
map<int,FunctionPtr> errRepMap;
errRepMap[v->ID()] = one;
errRepMap[tau->ID()] = one*e1+one*e2; // vector valued fxn (1,1)
FunctionPtr errTau = tauVecLT->evaluate(errRepMap,false);
FunctionPtr errV = vVecLT->evaluate(errRepMap,false);
try
{
bool xTauZero = errTau->x()->isZero();
bool yTauZero = errTau->y()->isZero();
bool xVZero = errV->dx()->isZero();
bool yVZero = errV->dy()->isZero();
}
catch (...)
{
cout << "testLinearTermEvaluation: Caught exception.\n";
success = false;
}
/*
FunctionPtr xErr = (errTau->x())*(errTau->x()) + (errV->dx())*(errV->dx());
FunctionPtr yErr = (errTau->y())*(errTau->y()) + (errV->dy())*(errV->dy());
double xErrVal = xErr->integrate(mesh,15,true);
*/
// if we don't crash, return success
return success;
}
int main(int argc, char *argv[]) {
#ifdef HAVE_MPI
Teuchos::GlobalMPISession mpiSession(&argc, &argv,0);
choice::MpiArgs args( argc, argv );
#else
choice::Args args( argc, argv );
#endif
int rank = Teuchos::GlobalMPISession::getRank();
int numProcs = Teuchos::GlobalMPISession::getNProc();
int nCells = args.Input<int>("--nCells", "num cells",2);
int numSteps = args.Input<int>("--numSteps", "num NR steps",20);
int polyOrder = 0;
// define our manufactured solution or problem bilinear form:
bool useTriangles = false;
int pToAdd = 1;
args.Process();
int H1Order = polyOrder + 1;
////////////////////////////////////////////////////////////////////
// DEFINE VARIABLES
////////////////////////////////////////////////////////////////////
// new-style bilinear form definition
VarFactory varFactory;
VarPtr fn = varFactory.fluxVar("\\widehat{\\beta_n_u}");
VarPtr u = varFactory.fieldVar("u");
VarPtr v = varFactory.testVar("v",HGRAD);
BFPtr bf = Teuchos::rcp( new BF(varFactory) ); // initialize bilinear form
////////////////////////////////////////////////////////////////////
// CREATE MESH
////////////////////////////////////////////////////////////////////
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells , bf, H1Order, H1Order+pToAdd);
////////////////////////////////////////////////////////////////////
// INITIALIZE BACKGROUND FLOW FUNCTIONS
////////////////////////////////////////////////////////////////////
BCPtr nullBC = Teuchos::rcp((BC*)NULL); RHSPtr nullRHS = Teuchos::rcp((RHS*)NULL); IPPtr nullIP = Teuchos::rcp((IP*)NULL);
SolutionPtr backgroundFlow = Teuchos::rcp(new Solution(mesh, nullBC, nullRHS, nullIP) );
SolutionPtr solnPerturbation = Teuchos::rcp(new Solution(mesh, nullBC, nullRHS, nullIP) );
vector<double> e1(2),e2(2);
e1[0] = 1; e2[1] = 1;
FunctionPtr u_prev = Teuchos::rcp( new PreviousSolutionFunction(backgroundFlow, u) );
FunctionPtr beta = e1 * u_prev + Teuchos::rcp( new ConstantVectorFunction( e2 ) );
////////////////////////////////////////////////////////////////////
// DEFINE BILINEAR FORM
////////////////////////////////////////////////////////////////////
// v:
bf->addTerm( -u, beta * v->grad());
bf->addTerm( fn, v);
////////////////////////////////////////////////////////////////////
// DEFINE RHS
////////////////////////////////////////////////////////////////////
Teuchos::RCP<RHSEasy> rhs = Teuchos::rcp( new RHSEasy );
FunctionPtr u_prev_squared_div2 = 0.5 * u_prev * u_prev;
rhs->addTerm((e1 * u_prev_squared_div2 + e2 * u_prev) * v->grad());
// ==================== SET INITIAL GUESS ==========================
mesh->registerSolution(backgroundFlow);
FunctionPtr zero = Function::constant(0.0);
FunctionPtr u0 = Teuchos::rcp( new U0 );
FunctionPtr n = Teuchos::rcp( new UnitNormalFunction );
// FunctionPtr parity = Teuchos::rcp(new SideParityFunction);
FunctionPtr u0_squared_div_2 = 0.5 * u0 * u0;
map<int, Teuchos::RCP<Function> > functionMap;
functionMap[u->ID()] = u0;
// functionMap[fn->ID()] = -(e1 * u0_squared_div_2 + e2 * u0) * n * parity;
backgroundFlow->projectOntoMesh(functionMap);
// ==================== END SET INITIAL GUESS ==========================
////////////////////////////////////////////////////////////////////
// DEFINE INNER PRODUCT
////////////////////////////////////////////////////////////////////
IPPtr ip = Teuchos::rcp( new IP );
ip->addTerm( v );
ip->addTerm(v->grad());
// ip->addTerm( beta * v->grad() ); // omitting term to make IP non-dependent on u
////////////////////////////////////////////////////////////////////
// DEFINE DIRICHLET BC
////////////////////////////////////////////////////////////////////
SpatialFilterPtr outflowBoundary = Teuchos::rcp( new TopBoundary);
SpatialFilterPtr inflowBoundary = Teuchos::rcp( new NegatedSpatialFilter(outflowBoundary) );
Teuchos::RCP<BCEasy> inflowBC = Teuchos::rcp( new BCEasy );
inflowBC->addDirichlet(fn,inflowBoundary,
( e1 * u0_squared_div_2 + e2 * u0) * n );
////////////////////////////////////////////////////////////////////
// CREATE SOLUTION OBJECT
////////////////////////////////////////////////////////////////////
Teuchos::RCP<Solution> solution = Teuchos::rcp(new Solution(mesh, inflowBC, rhs, ip));
mesh->registerSolution(solution); solution->setCubatureEnrichmentDegree(10);
////////////////////////////////////////////////////////////////////
// HESSIAN BIT + CHECKS ON GRADIENT + HESSIAN
////////////////////////////////////////////////////////////////////
VarFactory hessianVars = varFactory.getBubnovFactory(VarFactory::BUBNOV_TRIAL);
VarPtr du = hessianVars.test(u->ID());
// BFPtr hessianBF = Teuchos::rcp( new BF(hessianVars) ); // initialize bilinear form
FunctionPtr du_current = Teuchos::rcp( new PreviousSolutionFunction(solution, u) );
FunctionPtr fnhat = Teuchos::rcp(new PreviousSolutionFunction(solution,fn));
LinearTermPtr residual = Teuchos::rcp(new LinearTerm);// residual
residual->addTerm(fnhat*v,true);
residual->addTerm( - (e1 * (u_prev_squared_div2) + e2 * (u_prev)) * v->grad(),true);
LinearTermPtr Bdu = Teuchos::rcp(new LinearTerm);// residual
Bdu->addTerm( - du_current*(beta*v->grad()));
Teuchos::RCP<RieszRep> riesz = Teuchos::rcp(new RieszRep(mesh, ip, residual));
Teuchos::RCP<RieszRep> duRiesz = Teuchos::rcp(new RieszRep(mesh, ip, Bdu));
riesz->computeRieszRep();
FunctionPtr e_v = Teuchos::rcp(new RepFunction(v,riesz));
e_v->writeValuesToMATLABFile(mesh, "e_v.m");
FunctionPtr posErrPart = Teuchos::rcp(new PositivePart(e_v->dx()));
// hessianBF->addTerm(e_v->dx()*u,du);
// hessianBF->addTerm(posErrPart*u,du);
// Teuchos::RCP<NullFilter> nullFilter = Teuchos::rcp(new NullFilter);
// Teuchos::RCP<HessianFilter> hessianFilter = Teuchos::rcp(new HessianFilter(hessianBF));
Teuchos::RCP< LineSearchStep > LS_Step = Teuchos::rcp(new LineSearchStep(riesz));
double NL_residual = 9e99;
for (int i = 0;i<numSteps;i++){
// write matrix to file and then resollve without hessian
/*
solution->setFilter(hessianFilter);
stringstream oss;
oss << "hessianMatrix" << i << ".dat";
solution->setWriteMatrixToFile(true,oss.str());
solution->solve(false);
solution->setFilter(nullFilter);
oss.str(""); // clear
oss << "stiffnessMatrix" << i << ".dat";
solution->setWriteMatrixToFile(false,oss.str());
*/
solution->solve(false); // do one solve to initialize things...
double stepLength = 1.0;
stepLength = LS_Step->stepSize(backgroundFlow,solution, NL_residual);
// solution->setWriteMatrixToFile(true,"stiffness.dat");
backgroundFlow->addSolution(solution,stepLength);
NL_residual = LS_Step->getNLResidual();
if (rank==0){
cout << "NL residual after adding = " << NL_residual << " with step size " << stepLength << endl;
}
double fd_gradient;
for (int dofIndex = 0;dofIndex<mesh->numGlobalDofs();dofIndex++){
TestingUtilities::initializeSolnCoeffs(solnPerturbation);
TestingUtilities::setSolnCoeffForGlobalDofIndex(solnPerturbation,1.0,dofIndex);
fd_gradient = FiniteDifferenceUtilities::finiteDifferenceGradient(mesh, riesz, backgroundFlow, dofIndex);
// CHECK GRADIENT
LinearTermPtr b_u = bf->testFunctional(solnPerturbation);
map<int,FunctionPtr> NL_err_rep_map;
NL_err_rep_map[v->ID()] = Teuchos::rcp(new RepFunction(v,riesz));
FunctionPtr gradient = b_u->evaluate(NL_err_rep_map, TestingUtilities::isFluxOrTraceDof(mesh,dofIndex)); // use boundary part only if flux or trace
double grad;
if (TestingUtilities::isFluxOrTraceDof(mesh,dofIndex)){
grad = gradient->integralOfJump(mesh,10);
}else{
grad = gradient->integrate(mesh,10);
}
double fdgrad = fd_gradient;
double diff = grad-fdgrad;
if (abs(diff)>1e-6 && i>0){
cout << "Found difference of " << diff << ", " << " with fd val = " << fdgrad << " and gradient = " << grad << " in dof " << dofIndex << ", isTraceDof = " << TestingUtilities::isFluxOrTraceDof(mesh,dofIndex) << endl;
}
}
}
VTKExporter exporter(solution, mesh, varFactory);
if (rank==0){
exporter.exportSolution("qopt");
cout << endl;
}
return 0;
}
// tests residual computation on simple convection
bool ScratchPadTests::testLTResidualSimple()
{
double tol = 1e-11;
int rank = Teuchos::GlobalMPISession::getRank();
bool success = true;
int nCells = 2;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr v = varFactory->testVar("v", HGRAD);
// define trial variables
VarPtr beta_n_u = varFactory->fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory->fieldVar("u");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(1.0);
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// v terms:
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u, v);
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
// robust test norm
IPPtr ip = Teuchos::rcp(new IP);
// choose the mesh-independent norm even though it may have BLs
ip->addTerm(v->grad());
ip->addTerm(v);
//////////////////// SPECIFY RHS AND HELPFUL FUNCTIONS ///////////////////////
FunctionPtr n = Function::normal();
vector<double> e1,e2;
e1.push_back(1.0);
e1.push_back(0.0);
e2.push_back(0.0);
e2.push_back(1.0);
FunctionPtr one = Function::constant(1.0);
FunctionPtr zero = Function::constant(0.0);
RHSPtr rhs = RHS::rhs();
FunctionPtr f = one;
rhs->addTerm( f * v );
//////////////////// CREATE BCs ///////////////////////
BCPtr bc = BC::bc();
SpatialFilterPtr boundary = Teuchos::rcp( new InflowSquareBoundary );
FunctionPtr u_in = Teuchos::rcp(new Uinflow);
bc->addDirichlet(beta_n_u, boundary, beta*n*u_in);
//////////////////// BUILD MESH ///////////////////////
// define nodes for mesh
int order = 2;
int H1Order = order+1;
int pToAdd = 2;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells,confusionBF, H1Order, H1Order+pToAdd);
//////////////////// SOLVE & REFINE ///////////////////////
int cubEnrich = 0;
Teuchos::RCP<Solution> solution;
solution = Teuchos::rcp( new Solution(mesh, bc, rhs, ip) );
solution->solve(false);
double energyError = solution->energyErrorTotal();
LinearTermPtr residual = rhs->linearTermCopy();
residual->addTerm(-confusionBF->testFunctional(solution),true);
Teuchos::RCP<RieszRep> rieszResidual = Teuchos::rcp(new RieszRep(mesh, ip, residual));
rieszResidual->computeRieszRep(cubEnrich);
double energyErrorLT = rieszResidual->getNorm();
bool testVsTest = true;
FunctionPtr e_v = RieszRep::repFunction(v,rieszResidual);
map<int,FunctionPtr> errFxns;
errFxns[v->ID()] = e_v;
FunctionPtr err = (ip->evaluate(errFxns,false))->evaluate(errFxns,false); // don't need boundary terms unless they're in IP
double energyErrorIntegrated = sqrt(err->integrate(mesh,cubEnrich,testVsTest));
// check that energy error computed thru Solution and through rieszRep are the same
success = abs(energyError-energyErrorLT) < tol;
if (success==false)
{
if (rank==0)
cout << "Failed testLTResidualSimple; energy error = " << energyError << ", while linearTerm error is computed to be " << energyErrorLT << endl;
return success;
}
// checks that matrix-computed and integrated errors are the same
success = abs(energyErrorLT-energyErrorIntegrated)<tol;
if (success==false)
{
if (rank==0)
cout << "Failed testLTResidualSimple; energy error = " << energyError << ", while error computed via integration is " << energyErrorIntegrated << endl;
return success;
}
return success;
}
int main(int argc, char *argv[]) {
#ifdef HAVE_MPI
Teuchos::GlobalMPISession mpiSession(&argc, &argv,0);
choice::MpiArgs args( argc, argv );
#else
choice::Args args( argc, argv );
#endif
int rank = Teuchos::GlobalMPISession::getRank();
int numProcs = Teuchos::GlobalMPISession::getNProc();
int nCells = args.Input<int>("--nCells", "num cells",2);
int numRefs = args.Input<int>("--numRefs","num adaptive refinements",0);
int numPreRefs = args.Input<int>("--numPreRefs","num preemptive adaptive refinements",0);
int order = args.Input<int>("--order","order of approximation",2);
double eps = args.Input<double>("--epsilon","diffusion parameter",1e-2);
double energyThreshold = args.Input<double>("-energyThreshold","energy thresh for adaptivity", .5);
double rampHeight = args.Input<double>("--rampHeight","ramp height at x = 2", 0.0);
double ipSwitch = args.Input<double>("--ipSwitch","point at which to switch to graph norm", 0.0); // default to 0 to remain on robust norm
bool useAnisotropy = args.Input<bool>("--useAnisotropy","aniso flag ", false);
int H1Order = order+1;
int pToAdd = args.Input<int>("--pToAdd","test space enrichment", 2);
FunctionPtr zero = Function::constant(0.0);
FunctionPtr one = Function::constant(1.0);
FunctionPtr n = Teuchos::rcp( new UnitNormalFunction );
vector<double> e1,e2;
e1.push_back(1.0);e1.push_back(0.0);
e2.push_back(0.0);e2.push_back(1.0);
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactory varFactory;
VarPtr tau = varFactory.testVar("\\tau", HDIV);
VarPtr v = varFactory.testVar("v", HGRAD);
// define trial variables
VarPtr uhat = varFactory.traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory.fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory.fieldVar("u");
VarPtr sigma1 = varFactory.fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory.fieldVar("\\sigma_2");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// tau terms:
confusionBF->addTerm(sigma1 / eps, tau->x());
confusionBF->addTerm(sigma2 / eps, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(uhat, -tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
// first order term with magnitude alpha
double alpha = 0.0;
// confusionBF->addTerm(alpha * u, v);
//////////////////// BUILD MESH ///////////////////////
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells,confusionBF, H1Order, H1Order+pToAdd);
mesh->setPartitionPolicy(Teuchos::rcp(new ZoltanMeshPartitionPolicy("HSFC")));
MeshInfo meshInfo(mesh); // gets info like cell measure, etc
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
IPPtr ip = Teuchos::rcp(new IP);
/*
// robust test norm
FunctionPtr C_h = Teuchos::rcp( new EpsilonScaling(eps) );
FunctionPtr invH = Teuchos::rcp(new InvHScaling);
FunctionPtr invSqrtH = Teuchos::rcp(new InvSqrtHScaling);
FunctionPtr sqrtH = Teuchos::rcp(new SqrtHScaling);
FunctionPtr hSwitch = Teuchos::rcp(new HSwitch(ipSwitch,mesh));
ip->addTerm(hSwitch*sqrt(eps) * v->grad() );
ip->addTerm(hSwitch*beta * v->grad() );
ip->addTerm(hSwitch*tau->div() );
// graph norm
ip->addTerm( (one-hSwitch)*((1.0/eps) * tau + v->grad()));
ip->addTerm( (one-hSwitch)*(beta * v->grad() - tau->div()));
// regularizing terms
ip->addTerm(C_h/sqrt(eps) * tau );
ip->addTerm(invSqrtH*v);
*/
// robust test norm
IPPtr robIP = Teuchos::rcp(new IP);
FunctionPtr C_h = Teuchos::rcp( new EpsilonScaling(eps) );
FunctionPtr invH = Teuchos::rcp(new InvHScaling);
FunctionPtr invSqrtH = Teuchos::rcp(new InvSqrtHScaling);
FunctionPtr sqrtH = Teuchos::rcp(new SqrtHScaling);
FunctionPtr hSwitch = Teuchos::rcp(new HSwitch(ipSwitch,mesh));
robIP->addTerm(sqrt(eps) * v->grad() );
robIP->addTerm(beta * v->grad() );
robIP->addTerm(tau->div() );
// regularizing terms
robIP->addTerm(C_h/sqrt(eps) * tau );
robIP->addTerm(invSqrtH*v);
IPPtr graphIP = confusionBF->graphNorm();
graphIP->addTerm(invSqrtH*v);
// graphIP->addTerm(C_h/sqrt(eps) * tau );
IPPtr switchIP = Teuchos::rcp(new IPSwitcher(robIP,graphIP,ipSwitch)); // rob IP for h>ipSwitch mesh size, graph norm o/w
ip = switchIP;
LinearTermPtr vVecLT = Teuchos::rcp(new LinearTerm);
LinearTermPtr tauVecLT = Teuchos::rcp(new LinearTerm);
vVecLT->addTerm(sqrt(eps)*v->grad());
tauVecLT->addTerm(C_h/sqrt(eps)*tau);
LinearTermPtr restLT = Teuchos::rcp(new LinearTerm);
restLT->addTerm(alpha*v);
restLT->addTerm(invSqrtH*v);
restLT = restLT + beta * v->grad();
restLT = restLT + tau->div();
//////////////////// SPECIFY RHS ///////////////////////
Teuchos::RCP<RHSEasy> rhs = Teuchos::rcp( new RHSEasy );
FunctionPtr f = zero;
// f = one;
rhs->addTerm( f * v ); // obviously, with f = 0 adding this term is not necessary!
//////////////////// CREATE BCs ///////////////////////
Teuchos::RCP<BCEasy> bc = Teuchos::rcp( new BCEasy );
SpatialFilterPtr Inflow = Teuchos::rcp(new LeftInflow);
SpatialFilterPtr wallBoundary = Teuchos::rcp(new WallBoundary);//MeshUtilities::rampBoundary(rampHeight);
SpatialFilterPtr freeStream = Teuchos::rcp(new FreeStreamBoundary);
bc->addDirichlet(uhat, wallBoundary, one);
// bc->addDirichlet(uhat, wallBoundary, Teuchos::rcp(new WallSmoothBC(eps)));
bc->addDirichlet(beta_n_u_minus_sigma_n, Inflow, zero);
bc->addDirichlet(beta_n_u_minus_sigma_n, freeStream, zero);
//////////////////// SOLVE & REFINE ///////////////////////
Teuchos::RCP<Solution> solution;
solution = Teuchos::rcp( new Solution(mesh, bc, rhs, ip) );
BCPtr nullBC = Teuchos::rcp((BC*)NULL); RHSPtr nullRHS = Teuchos::rcp((RHS*)NULL); IPPtr nullIP = Teuchos::rcp((IP*)NULL);
SolutionPtr backgroundFlow = Teuchos::rcp(new Solution(mesh, nullBC, nullRHS, nullIP) );
mesh->registerSolution(backgroundFlow); // to trigger issue with p-refinements
map<int, Teuchos::RCP<Function> > functionMap; functionMap[u->ID()] = Function::constant(3.14);
backgroundFlow->projectOntoMesh(functionMap);
// lower p to p = 1 at SINGULARITY only
vector<int> ids;
/*
for (int i = 0;i<mesh->numActiveElements();i++){
bool cellIDset = false;
int cellID = mesh->activeElements()[i]->cellID();
int elemOrder = mesh->cellPolyOrder(cellID)-1;
FieldContainer<double> vv(4,2); mesh->verticesForCell(vv, cellID);
bool vertexOnWall = false; bool vertexAtSingularity = false;
for (int j = 0;j<4;j++){
if ((abs(vv(j,0)-.5) + abs(vv(j,1)))<1e-10){
vertexAtSingularity = true;
cellIDset = true;
}
}
if (!vertexAtSingularity && elemOrder<2 && !cellIDset ){
ids.push_back(cellID);
cout << "celliD = " << cellID << endl;
}
}
*/
ids.push_back(1);
ids.push_back(3);
mesh->pRefine(ids); // to put order = 1
return 0;
LinearTermPtr residual = rhs->linearTermCopy();
residual->addTerm(-confusionBF->testFunctional(solution));
RieszRepPtr rieszResidual = Teuchos::rcp(new RieszRep(mesh, ip, residual));
rieszResidual->computeRieszRep();
FunctionPtr e_v = Teuchos::rcp(new RepFunction(v,rieszResidual));
FunctionPtr e_tau = Teuchos::rcp(new RepFunction(tau,rieszResidual));
map<int,FunctionPtr> errRepMap;
errRepMap[v->ID()] = e_v;
errRepMap[tau->ID()] = e_tau;
FunctionPtr errTau = tauVecLT->evaluate(errRepMap,false);
FunctionPtr errV = vVecLT->evaluate(errRepMap,false);
FunctionPtr errRest = restLT->evaluate(errRepMap,false);
FunctionPtr xErr = (errTau->x())*(errTau->x()) + (errV->dx())*(errV->dx());
FunctionPtr yErr = (errTau->y())*(errTau->y()) + (errV->dy())*(errV->dy());
FunctionPtr restErr = errRest*errRest;
RefinementStrategy refinementStrategy( solution, energyThreshold );
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// PRE REFINEMENTS
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
if (rank==0){
cout << "Number of pre-refinements = " << numPreRefs << endl;
}
for (int i =0;i<=numPreRefs;i++){
vector<ElementPtr> elems = mesh->activeElements();
vector<ElementPtr>::iterator elemIt;
vector<int> wallCells;
for (elemIt=elems.begin();elemIt != elems.end();elemIt++){
int cellID = (*elemIt)->cellID();
int numSides = mesh->getElement(cellID)->numSides();
FieldContainer<double> vertices(numSides,2); //for quads
mesh->verticesForCell(vertices, cellID);
bool cellIDset = false;
for (int j = 0;j<numSides;j++){
if ((abs(vertices(j,0)-.5)<1e-7) && (abs(vertices(j,1))<1e-7) && !cellIDset){ // if at singularity, i.e. if a vertex is (1,0)
wallCells.push_back(cellID);
cellIDset = true;
}
}
}
if (i<numPreRefs){
refinementStrategy.refineCells(wallCells);
}
}
double minSideLength = meshInfo.getMinCellSideLength() ;
double minCellMeasure = meshInfo.getMinCellMeasure() ;
if (rank==0){
cout << "after prerefs, sqrt min cell measure = " << sqrt(minCellMeasure) << ", min side length = " << minSideLength << endl;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VTKExporter exporter(solution, mesh, varFactory);
for (int refIndex=0;refIndex<numRefs;refIndex++){
if (rank==0){
cout << "on ref index " << refIndex << endl;
}
rieszResidual->computeRieszRep(); // in preparation to get anisotropy
vector<int> cellIDs;
refinementStrategy.getCellsAboveErrorThreshhold(cellIDs);
map<int,double> energyError = solution->energyError();
map<int,double> xErrMap = xErr->cellIntegrals(cellIDs,mesh,5,true);
map<int,double> yErrMap = yErr->cellIntegrals(cellIDs,mesh,5,true);
map<int,double> restErrMap = restErr->cellIntegrals(cellIDs,mesh,5,true);
for (vector<ElementPtr>::iterator elemIt = mesh->activeElements().begin();elemIt!=mesh->activeElements().end();elemIt++){
int cellID = (*elemIt)->cellID();
double err = xErrMap[cellID]+ yErrMap[cellID] + restErrMap[cellID];
// if (rank==0)
// cout << "err thru LT = " << sqrt(err) << ", while energy err = " << energyError[cellID] << endl;
}
/*
map<int,double> ratio,xErr,yErr;
vector<ElementPtr> elems = mesh->activeElements();
for (vector<ElementPtr>::iterator elemIt = elems.begin();elemIt!=elems.end();elemIt++){
int cellID = (*elemIt)->cellID();
ratio[cellID] = 0.0;
xErr[cellID] = 0.0;
yErr[cellID] = 0.0;
if (std::find(cellIDs.begin(),cellIDs.end(),cellID)!=cellIDs.end()){ // if this cell is above energy thresh
ratio[cellID] = yErrMap[cellID]/xErrMap[cellID];
xErr[cellID] = xErrMap[cellID];
yErr[cellID] = yErrMap[cellID];
}
}
FunctionPtr ratioFxn = Teuchos::rcp(new EnergyErrorFunction(ratio));
FunctionPtr xErrFxn = Teuchos::rcp(new EnergyErrorFunction(xErr));
FunctionPtr yErrFxn = Teuchos::rcp(new EnergyErrorFunction(yErr));
exporter.exportFunction(ratioFxn, string("ratio")+oss.str());
exporter.exportFunction(xErrFxn, string("xErr")+oss.str());
exporter.exportFunction(yErrFxn, string("yErr")+oss.str());
*/
if (useAnisotropy){
refinementStrategy.refine(rank==0,xErrMap,yErrMap); //anisotropic refinements
}else{
refinementStrategy.refine(rank==0); // no anisotropy
}
// lower p to p = 1 at SINGULARITY only
vector<int> ids;
for (int i = 0;i<mesh->numActiveElements();i++){
int cellID = mesh->activeElements()[i]->cellID();
int elemOrder = mesh->cellPolyOrder(cellID)-1;
FieldContainer<double> vv(4,2); mesh->verticesForCell(vv, cellID);
bool vertexOnWall = false; bool vertexAtSingularity = false;
for (int j = 0;j<4;j++){
if ((abs(vv(j,0)-.5) + abs(vv(j,1)))<1e-10)
vertexAtSingularity = true;
}
if (!vertexAtSingularity && elemOrder<2){
ids.push_back(cellID);
}
}
mesh->pRefine(ids); // to put order = 1
/*
if (elemOrder>1){
if (vertexAtSingularity){
vector<int> ids;
ids.push_back(cellID);
mesh->pRefine(ids,1-(elemOrder-1)); // to put order = 1
// mesh->pRefine(ids); // to put order = 1
if (rank==0)
cout << "p unrefining elem with elemOrder = " << elemOrder << endl;
}
}else{
if (!vertexAtSingularity){
vector<int> ids;
ids.push_back(cellID);
mesh->pRefine(ids,2-elemOrder);
}
}
*/
double minSideLength = meshInfo.getMinCellSideLength() ;
if (rank==0)
cout << "minSideLength is " << minSideLength << endl;
solution->condensedSolve();
std::ostringstream oss;
oss << refIndex;
}
// final solve on final mesh
solution->setWriteMatrixToFile(true,"K.mat");
solution->condensedSolve();
////////////////////////////////////////////////////////////////////////////////////////////////////////////
// CHECK CONDITIONING
////////////////////////////////////////////////////////////////////////////////////////////////////////////
bool checkConditioning = true;
if (checkConditioning){
double minSideLength = meshInfo.getMinCellSideLength() ;
StandardAssembler assembler(solution);
double maxCond = 0.0;
int maxCellID = 0;
for (int i = 0;i<mesh->numActiveElements();i++){
int cellID = mesh->getActiveElement(i)->cellID();
FieldContainer<double> ipMat = assembler.getIPMatrix(mesh->getElement(cellID));
double cond = SerialDenseWrapper::getMatrixConditionNumber(ipMat);
if (cond>maxCond){
maxCond = cond;
maxCellID = cellID;
}
}
if (rank==0){
cout << "cell ID " << maxCellID << " has minCellLength " << minSideLength << " and condition estimate " << maxCond << endl;
}
string ipMatName = string("ipMat.mat");
ElementPtr maxCondElem = mesh->getElement(maxCellID);
FieldContainer<double> ipMat = assembler.getIPMatrix(maxCondElem);
SerialDenseWrapper::writeMatrixToMatlabFile(ipMatName,ipMat);
}
//////////////////// print to file ///////////////////////
if (rank==0){
exporter.exportSolution(string("robustIP"));
cout << endl;
}
return 0;
}
int main(int argc, char *argv[])
{
int rank = 0;
#ifdef HAVE_MPI
// TODO: figure out the right thing to do here...
// may want to modify argc and argv before we make the following call:
Teuchos::GlobalMPISession mpiSession(&argc, &argv,0);
rank=mpiSession.getRank();
#else
#endif
bool useLineSearch = false;
int pToAdd = 2; // for optimal test function approximation
int pToAddForStreamFunction = 2;
double nonlinearStepSize = 1.0;
double dt = 0.5;
double nonlinearRelativeEnergyTolerance = 0.015; // used to determine convergence of the nonlinear solution
// double nonlinearRelativeEnergyTolerance = 0.15; // used to determine convergence of the nonlinear solution
double eps = 1.0/64.0; // width of ramp up to 1.0 for top BC; eps == 0 ==> soln not in H1
// epsilon above is chosen to match our initial 16x16 mesh, to avoid quadrature errors.
// double eps = 0.0; // John Evans's problem: not in H^1
bool enforceLocalConservation = false;
bool enforceOneIrregularity = true;
bool reportPerCellErrors = true;
bool useMumps = true;
int horizontalCells, verticalCells;
int maxIters = 50; // for nonlinear steps
vector<double> ReValues;
// usage: polyOrder [numRefinements]
// parse args:
if (argc < 6)
{
cout << "Usage: NavierStokesCavityFlowContinuationFixedMesh fieldPolyOrder hCells vCells energyErrorGoal Re0 [Re1 ...]\n";
return -1;
}
int polyOrder = atoi(argv[1]);
horizontalCells = atoi(argv[2]);
verticalCells = atoi(argv[3]);
double energyErrorGoal = atof(argv[4]);
for (int i=5; i<argc; i++)
{
ReValues.push_back(atof(argv[i]));
}
if (rank == 0)
{
cout << "L^2 order: " << polyOrder << endl;
cout << "initial mesh size: " << horizontalCells << " x " << verticalCells << endl;
cout << "energy error goal: " << energyErrorGoal << endl;
cout << "Reynolds number values for continuation:\n";
for (int i=0; i<ReValues.size(); i++)
{
cout << ReValues[i] << ", ";
}
cout << endl;
}
FieldContainer<double> quadPoints(4,2);
quadPoints(0,0) = 0.0; // x1
quadPoints(0,1) = 0.0; // y1
quadPoints(1,0) = 1.0;
quadPoints(1,1) = 0.0;
quadPoints(2,0) = 1.0;
quadPoints(2,1) = 1.0;
quadPoints(3,0) = 0.0;
quadPoints(3,1) = 1.0;
// define meshes:
int H1Order = polyOrder + 1;
bool useTriangles = false;
bool meshHasTriangles = useTriangles;
double minL2Increment = 1e-8;
// get variable definitions:
VarFactory varFactory = VGPStokesFormulation::vgpVarFactory();
u1 = varFactory.fieldVar(VGP_U1_S);
u2 = varFactory.fieldVar(VGP_U2_S);
sigma11 = varFactory.fieldVar(VGP_SIGMA11_S);
sigma12 = varFactory.fieldVar(VGP_SIGMA12_S);
sigma21 = varFactory.fieldVar(VGP_SIGMA21_S);
sigma22 = varFactory.fieldVar(VGP_SIGMA22_S);
p = varFactory.fieldVar(VGP_P_S);
u1hat = varFactory.traceVar(VGP_U1HAT_S);
u2hat = varFactory.traceVar(VGP_U2HAT_S);
t1n = varFactory.fluxVar(VGP_T1HAT_S);
t2n = varFactory.fluxVar(VGP_T2HAT_S);
v1 = varFactory.testVar(VGP_V1_S, HGRAD);
v2 = varFactory.testVar(VGP_V2_S, HGRAD);
tau1 = varFactory.testVar(VGP_TAU1_S, HDIV);
tau2 = varFactory.testVar(VGP_TAU2_S, HDIV);
q = varFactory.testVar(VGP_Q_S, HGRAD);
FunctionPtr u1_0 = Teuchos::rcp( new U1_0(eps) );
FunctionPtr u2_0 = Teuchos::rcp( new U2_0 );
FunctionPtr zero = Function::zero();
ParameterFunctionPtr Re_param = ParameterFunction::parameterFunction(1);
VGPNavierStokesProblem problem = VGPNavierStokesProblem(Re_param,quadPoints,
horizontalCells,verticalCells,
H1Order, pToAdd,
u1_0, u2_0, // BC for u
zero, zero); // zero forcing function
SolutionPtr solution = problem.backgroundFlow();
SolutionPtr solnIncrement = problem.solutionIncrement();
Teuchos::RCP<Mesh> mesh = problem.mesh();
mesh->registerSolution(solution);
mesh->registerSolution(solnIncrement);
///////////////////////////////////////////////////////////////////////////
// define bilinear form for stream function:
VarFactory streamVarFactory;
VarPtr phi_hat = streamVarFactory.traceVar("\\widehat{\\phi}");
VarPtr psin_hat = streamVarFactory.fluxVar("\\widehat{\\psi}_n");
VarPtr psi_1 = streamVarFactory.fieldVar("\\psi_1");
VarPtr psi_2 = streamVarFactory.fieldVar("\\psi_2");
VarPtr phi = streamVarFactory.fieldVar("\\phi");
VarPtr q_s = streamVarFactory.testVar("q_s", HGRAD);
VarPtr v_s = streamVarFactory.testVar("v_s", HDIV);
BFPtr streamBF = Teuchos::rcp( new BF(streamVarFactory) );
streamBF->addTerm(psi_1, q_s->dx());
streamBF->addTerm(psi_2, q_s->dy());
streamBF->addTerm(-psin_hat, q_s);
streamBF->addTerm(psi_1, v_s->x());
streamBF->addTerm(psi_2, v_s->y());
streamBF->addTerm(phi, v_s->div());
streamBF->addTerm(-phi_hat, v_s->dot_normal());
Teuchos::RCP<Mesh> streamMesh, overkillMesh;
streamMesh = MeshFactory::buildQuadMesh(quadPoints, horizontalCells, verticalCells,
streamBF, H1Order+pToAddForStreamFunction,
H1Order+pToAdd+pToAddForStreamFunction, useTriangles);
mesh->registerObserver(streamMesh); // will refine streamMesh in the same way as mesh.
map<int, double> dofsToL2error; // key: numGlobalDofs, value: total L2error compared with overkill
vector< VarPtr > fields;
fields.push_back(u1);
fields.push_back(u2);
fields.push_back(sigma11);
fields.push_back(sigma12);
fields.push_back(sigma21);
fields.push_back(sigma22);
fields.push_back(p);
if (rank == 0)
{
cout << "Starting mesh has " << horizontalCells << " x " << verticalCells << " elements and ";
cout << mesh->numGlobalDofs() << " total dofs.\n";
cout << "polyOrder = " << polyOrder << endl;
cout << "pToAdd = " << pToAdd << endl;
cout << "eps for top BC = " << eps << endl;
if (useTriangles)
{
cout << "Using triangles.\n";
}
if (enforceLocalConservation)
{
cout << "Enforcing local conservation.\n";
}
else
{
cout << "NOT enforcing local conservation.\n";
}
if (enforceOneIrregularity)
{
cout << "Enforcing 1-irregularity.\n";
}
else
{
cout << "NOT enforcing 1-irregularity.\n";
}
}
//////////////////// CREATE BCs ///////////////////////
SpatialFilterPtr entireBoundary = Teuchos::rcp( new SpatialFilterUnfiltered );
FunctionPtr u1_prev = Function::solution(u1,solution);
FunctionPtr u2_prev = Function::solution(u2,solution);
FunctionPtr u1hat_prev = Function::solution(u1hat,solution);
FunctionPtr u2hat_prev = Function::solution(u2hat,solution);
//////////////////// SOLVE & REFINE ///////////////////////
FunctionPtr vorticity = Teuchos::rcp( new PreviousSolutionFunction(solution, - u1->dy() + u2->dx() ) );
// FunctionPtr vorticity = Teuchos::rcp( new PreviousSolutionFunction(solution,sigma12 - sigma21) );
RHSPtr streamRHS = RHS::rhs();
streamRHS->addTerm(vorticity * q_s);
((PreviousSolutionFunction*) vorticity.get())->setOverrideMeshCheck(true);
((PreviousSolutionFunction*) u1_prev.get())->setOverrideMeshCheck(true);
((PreviousSolutionFunction*) u2_prev.get())->setOverrideMeshCheck(true);
BCPtr streamBC = BC::bc();
// streamBC->addDirichlet(psin_hat, entireBoundary, u0_cross_n);
streamBC->addDirichlet(phi_hat, entireBoundary, zero);
// streamBC->addZeroMeanConstraint(phi);
IPPtr streamIP = Teuchos::rcp( new IP );
streamIP->addTerm(q_s);
streamIP->addTerm(q_s->grad());
streamIP->addTerm(v_s);
streamIP->addTerm(v_s->div());
SolutionPtr streamSolution = Teuchos::rcp( new Solution( streamMesh, streamBC, streamRHS, streamIP ) );
if (enforceLocalConservation)
{
FunctionPtr zero = Function::zero();
solution->lagrangeConstraints()->addConstraint(u1hat->times_normal_x() + u2hat->times_normal_y()==zero);
solnIncrement->lagrangeConstraints()->addConstraint(u1hat->times_normal_x() + u2hat->times_normal_y()==zero);
}
if (true)
{
FunctionPtr u1_incr = Function::solution(u1, solnIncrement);
FunctionPtr u2_incr = Function::solution(u2, solnIncrement);
FunctionPtr sigma11_incr = Function::solution(sigma11, solnIncrement);
FunctionPtr sigma12_incr = Function::solution(sigma12, solnIncrement);
FunctionPtr sigma21_incr = Function::solution(sigma21, solnIncrement);
FunctionPtr sigma22_incr = Function::solution(sigma22, solnIncrement);
FunctionPtr p_incr = Function::solution(p, solnIncrement);
FunctionPtr l2_incr = u1_incr * u1_incr + u2_incr * u2_incr + p_incr * p_incr
+ sigma11_incr * sigma11_incr + sigma12_incr * sigma12_incr
+ sigma21_incr * sigma21_incr + sigma22_incr * sigma22_incr;
double energyThreshold = 0.20;
Teuchos::RCP< RefinementStrategy > refinementStrategy = Teuchos::rcp( new RefinementStrategy( solnIncrement, energyThreshold ));
for (int i=0; i<ReValues.size(); i++)
{
double Re = ReValues[i];
Re_param->setValue(Re);
if (rank==0) cout << "Solving with Re = " << Re << ":\n";
double energyErrorTotal;
do
{
double incr_norm;
do
{
problem.iterate(useLineSearch);
incr_norm = sqrt(l2_incr->integrate(problem.mesh()));
if (rank==0)
{
cout << "\x1B[2K"; // Erase the entire current line.
cout << "\x1B[0E"; // Move to the beginning of the current line.
cout << "Iteration: " << problem.iterationCount() << "; L^2(incr) = " << incr_norm;
flush(cout);
}
}
while ((incr_norm > minL2Increment ) && (problem.iterationCount() < maxIters));
if (rank==0) cout << endl;
problem.setIterationCount(1); // 1 means reuse background flow (which we must, given that we want continuation in Re...)
energyErrorTotal = solnIncrement->energyErrorTotal(); //solution->energyErrorTotal();
if (energyErrorTotal > energyErrorGoal)
{
refinementStrategy->refine(false);
}
if (rank==0)
{
cout << "Energy error: " << energyErrorTotal << endl;
}
}
while (energyErrorTotal > energyErrorGoal);
}
}
double energyErrorTotal = solution->energyErrorTotal();
double incrementalEnergyErrorTotal = solnIncrement->energyErrorTotal();
if (rank == 0)
{
cout << "final mesh has " << mesh->numActiveElements() << " elements and " << mesh->numGlobalDofs() << " dofs.\n";
cout << "energy error: " << energyErrorTotal << endl;
cout << " (Incremental solution's energy error is " << incrementalEnergyErrorTotal << ".)\n";
}
FunctionPtr u1_sq = u1_prev * u1_prev;
FunctionPtr u_dot_u = u1_sq + (u2_prev * u2_prev);
FunctionPtr u_mag = Teuchos::rcp( new SqrtFunction( u_dot_u ) );
FunctionPtr u_div = Teuchos::rcp( new PreviousSolutionFunction(solution, u1->dx() + u2->dy() ) );
FunctionPtr massFlux = Teuchos::rcp( new PreviousSolutionFunction(solution, u1hat->times_normal_x() + u2hat->times_normal_y()) );
// check that the zero mean pressure is being correctly imposed:
FunctionPtr p_prev = Teuchos::rcp( new PreviousSolutionFunction(solution,p) );
double p_avg = p_prev->integrate(mesh);
if (rank==0)
cout << "Integral of pressure: " << p_avg << endl;
// integrate massFlux over each element (a test):
// fake a new bilinear form so we can integrate against 1
VarPtr testOne = varFactory.testVar("1",CONSTANT_SCALAR);
BFPtr fakeBF = Teuchos::rcp( new BF(varFactory) );
LinearTermPtr massFluxTerm = massFlux * testOne;
CellTopoPtrLegacy quadTopoPtr = Teuchos::rcp(new shards::CellTopology(shards::getCellTopologyData<shards::Quadrilateral<4> >() ));
DofOrderingFactory dofOrderingFactory(fakeBF);
int fakeTestOrder = H1Order;
DofOrderingPtr testOrdering = dofOrderingFactory.testOrdering(fakeTestOrder, *quadTopoPtr);
int testOneIndex = testOrdering->getDofIndex(testOne->ID(),0);
vector< ElementTypePtr > elemTypes = mesh->elementTypes(); // global element types
map<int, double> massFluxIntegral; // cellID -> integral
double maxMassFluxIntegral = 0.0;
double totalMassFlux = 0.0;
double totalAbsMassFlux = 0.0;
double maxCellMeasure = 0;
double minCellMeasure = 1;
for (vector< ElementTypePtr >::iterator elemTypeIt = elemTypes.begin(); elemTypeIt != elemTypes.end(); elemTypeIt++)
{
ElementTypePtr elemType = *elemTypeIt;
vector< ElementPtr > elems = mesh->elementsOfTypeGlobal(elemType);
vector<GlobalIndexType> cellIDs;
for (int i=0; i<elems.size(); i++)
{
cellIDs.push_back(elems[i]->cellID());
}
FieldContainer<double> physicalCellNodes = mesh->physicalCellNodesGlobal(elemType);
BasisCachePtr basisCache = Teuchos::rcp( new BasisCache(elemType,mesh,polyOrder) ); // enrich by trial space order
basisCache->setPhysicalCellNodes(physicalCellNodes,cellIDs,true); // true: create side caches
FieldContainer<double> cellMeasures = basisCache->getCellMeasures();
FieldContainer<double> fakeRHSIntegrals(elems.size(),testOrdering->totalDofs());
massFluxTerm->integrate(fakeRHSIntegrals,testOrdering,basisCache,true); // true: force side evaluation
// cout << "fakeRHSIntegrals:\n" << fakeRHSIntegrals;
for (int i=0; i<elems.size(); i++)
{
int cellID = cellIDs[i];
// pick out the ones for testOne:
massFluxIntegral[cellID] = fakeRHSIntegrals(i,testOneIndex);
}
// find the largest:
for (int i=0; i<elems.size(); i++)
{
int cellID = cellIDs[i];
maxMassFluxIntegral = max(abs(massFluxIntegral[cellID]), maxMassFluxIntegral);
}
for (int i=0; i<elems.size(); i++)
{
int cellID = cellIDs[i];
maxCellMeasure = max(maxCellMeasure,cellMeasures(i));
minCellMeasure = min(minCellMeasure,cellMeasures(i));
maxMassFluxIntegral = max(abs(massFluxIntegral[cellID]), maxMassFluxIntegral);
totalMassFlux += massFluxIntegral[cellID];
totalAbsMassFlux += abs( massFluxIntegral[cellID] );
}
}
if (rank==0)
{
cout << "largest mass flux: " << maxMassFluxIntegral << endl;
cout << "total mass flux: " << totalMassFlux << endl;
cout << "sum of mass flux absolute value: " << totalAbsMassFlux << endl;
cout << "largest h: " << sqrt(maxCellMeasure) << endl;
cout << "smallest h: " << sqrt(minCellMeasure) << endl;
cout << "ratio of largest / smallest h: " << sqrt(maxCellMeasure) / sqrt(minCellMeasure) << endl;
}
if (rank == 0)
{
cout << "phi ID: " << phi->ID() << endl;
cout << "psi1 ID: " << psi_1->ID() << endl;
cout << "psi2 ID: " << psi_2->ID() << endl;
cout << "streamMesh has " << streamMesh->numActiveElements() << " elements.\n";
cout << "solving for approximate stream function...\n";
}
streamSolution->solve(useMumps);
energyErrorTotal = streamSolution->energyErrorTotal();
if (rank == 0)
{
cout << "...solved.\n";
cout << "Stream mesh has energy error: " << energyErrorTotal << endl;
}
if (rank==0)
{
solution->writeToVTK("nsCavitySoln.vtk");
if (! meshHasTriangles )
{
massFlux->writeBoundaryValuesToMATLABFile(solution->mesh(), "massFlux.dat");
u_mag->writeValuesToMATLABFile(solution->mesh(), "u_mag.m");
u_div->writeValuesToMATLABFile(solution->mesh(), "u_div.m");
solution->writeFieldsToFile(u1->ID(), "u1.m");
solution->writeFluxesToFile(u1hat->ID(), "u1_hat.dat");
solution->writeFieldsToFile(u2->ID(), "u2.m");
solution->writeFluxesToFile(u2hat->ID(), "u2_hat.dat");
solution->writeFieldsToFile(p->ID(), "p.m");
streamSolution->writeFieldsToFile(phi->ID(), "phi.m");
streamSolution->writeFluxesToFile(phi_hat->ID(), "phi_hat.dat");
streamSolution->writeFieldsToFile(psi_1->ID(), "psi1.m");
streamSolution->writeFieldsToFile(psi_2->ID(), "psi2.m");
vorticity->writeValuesToMATLABFile(streamMesh, "vorticity.m");
FunctionPtr ten = Teuchos::rcp( new ConstantScalarFunction(10) );
ten->writeBoundaryValuesToMATLABFile(solution->mesh(), "skeleton.dat");
cout << "wrote files: u_mag.m, u_div.m, u1.m, u1_hat.dat, u2.m, u2_hat.dat, p.m, phi.m, vorticity.m.\n";
}
else
{
solution->writeToFile(u1->ID(), "u1.dat");
solution->writeToFile(u2->ID(), "u2.dat");
solution->writeToFile(u2->ID(), "p.dat");
cout << "wrote files: u1.dat, u2.dat, p.dat\n";
}
FieldContainer<double> points = pointGrid(0, 1, 0, 1, 100);
FieldContainer<double> pointData = solutionData(points, streamSolution, phi);
GnuPlotUtil::writeXYPoints("phi_patch_navierStokes_cavity.dat", pointData);
set<double> patchContourLevels = diagonalContourLevels(pointData,1);
vector<string> patchDataPath;
patchDataPath.push_back("phi_patch_navierStokes_cavity.dat");
GnuPlotUtil::writeContourPlotScript(patchContourLevels, patchDataPath, "lidCavityNavierStokes.p");
GnuPlotUtil::writeExactMeshSkeleton("lid_navierStokes_continuation_adaptive", mesh, 2);
writePatchValues(0, 1, 0, 1, streamSolution, phi, "phi_patch.m");
writePatchValues(0, .1, 0, .1, streamSolution, phi, "phi_patch_detail.m");
writePatchValues(0, .01, 0, .01, streamSolution, phi, "phi_patch_minute_detail.m");
writePatchValues(0, .001, 0, .001, streamSolution, phi, "phi_patch_minute_minute_detail.m");
}
return 0;
}
int main(int argc, char *argv[])
{
#ifdef HAVE_MPI
Teuchos::GlobalMPISession mpiSession(&argc, &argv,0);
int rank=mpiSession.getRank();
int numProcs=mpiSession.getNProc();
#else
int rank = 0;
int numProcs = 1;
#endif
int polyOrder = 3;
int pToAdd = 2; // for tests
// define our manufactured solution or problem bilinear form:
bool useTriangles = false;
FieldContainer<double> meshPoints(4,2);
meshPoints(0,0) = 0.0; // x1
meshPoints(0,1) = 0.0; // y1
meshPoints(1,0) = 1.0;
meshPoints(1,1) = 0.0;
meshPoints(2,0) = 1.0;
meshPoints(2,1) = 1.0;
meshPoints(3,0) = 0.0;
meshPoints(3,1) = 1.0;
int H1Order = polyOrder + 1;
int horizontalCells = 4, verticalCells = 4;
double energyThreshold = 0.2; // for mesh refinements
double nonlinearStepSize = 0.5;
double nonlinearRelativeEnergyTolerance = 1e-8; // used to determine convergence of the nonlinear solution
////////////////////////////////////////////////////////////////////
// DEFINE VARIABLES
////////////////////////////////////////////////////////////////////
// new-style bilinear form definition
VarFactory varFactory;
VarPtr fhat = varFactory.fluxVar("\\widehat{f}");
VarPtr u = varFactory.fieldVar("u");
VarPtr v = varFactory.testVar("v",HGRAD);
BFPtr bf = Teuchos::rcp( new BF(varFactory) ); // initialize bilinear form
////////////////////////////////////////////////////////////////////
// CREATE MESH
////////////////////////////////////////////////////////////////////
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = Mesh::buildQuadMesh(meshPoints, horizontalCells,
verticalCells, bf, H1Order,
H1Order+pToAdd, useTriangles);
mesh->setPartitionPolicy(Teuchos::rcp(new ZoltanMeshPartitionPolicy("HSFC")));
////////////////////////////////////////////////////////////////////
// INITIALIZE BACKGROUND FLOW FUNCTIONS
////////////////////////////////////////////////////////////////////
BCPtr nullBC = Teuchos::rcp((BC*)NULL);
RHSPtr nullRHS = Teuchos::rcp((RHS*)NULL);
IPPtr nullIP = Teuchos::rcp((IP*)NULL);
SolutionPtr backgroundFlow = Teuchos::rcp(new Solution(mesh, nullBC,
nullRHS, nullIP) );
vector<double> e1(2); // (1,0)
e1[0] = 1;
vector<double> e2(2); // (0,1)
e2[1] = 1;
FunctionPtr u_prev = Teuchos::rcp( new PreviousSolutionFunction(backgroundFlow, u) );
FunctionPtr beta = e1 * u_prev + Teuchos::rcp( new ConstantVectorFunction( e2 ) );
////////////////////////////////////////////////////////////////////
// DEFINE BILINEAR FORM
////////////////////////////////////////////////////////////////////
// v:
// (sigma, grad v)_K - (sigma_hat_n, v)_dK - (u, beta dot grad v) + (u_hat * n dot beta, v)_dK
bf->addTerm( -u, beta * v->grad());
bf->addTerm( fhat, v);
// ==================== SET INITIAL GUESS ==========================
mesh->registerSolution(backgroundFlow);
FunctionPtr zero = Teuchos::rcp( new ConstantScalarFunction(0.0) );
FunctionPtr u0 = Teuchos::rcp( new U0 );
map<int, Teuchos::RCP<Function> > functionMap;
functionMap[u->ID()] = u0;
backgroundFlow->projectOntoMesh(functionMap);
// ==================== END SET INITIAL GUESS ==========================
////////////////////////////////////////////////////////////////////
// DEFINE INNER PRODUCT
////////////////////////////////////////////////////////////////////
IPPtr ip = Teuchos::rcp( new IP );
ip->addTerm( v );
ip->addTerm( beta * v->grad() );
////////////////////////////////////////////////////////////////////
// DEFINE RHS
////////////////////////////////////////////////////////////////////
Teuchos::RCP<RHSEasy> rhs = Teuchos::rcp( new RHSEasy );
FunctionPtr u_prev_squared_div2 = 0.5 * u_prev * u_prev;
rhs->addTerm( (e1 * u_prev_squared_div2 + e2 * u_prev) * v->grad());
////////////////////////////////////////////////////////////////////
// DEFINE DIRICHLET BC
////////////////////////////////////////////////////////////////////
Teuchos::RCP<BCEasy> inflowBC = Teuchos::rcp( new BCEasy );
// Create spatial filters
SpatialFilterPtr bottomBoundary = Teuchos::rcp( new BottomBoundary );
SpatialFilterPtr leftBoundary = Teuchos::rcp( new LeftBoundary );
SpatialFilterPtr rightBoundary = Teuchos::rcp( new LeftBoundary );
// Create BCs
FunctionPtr n = Teuchos::rcp( new UnitNormalFunction );
FunctionPtr u0_squared_div_2 = 0.5 * u0 * u0;
SimpleFunction* u0Ptr = static_cast<SimpleFunction *>(u0.get());
double u0Left = u0Ptr->value(0,0);
double u0Right = u0Ptr->value(1.0,0);
FunctionPtr leftVal = Teuchos::rcp( new ConstantScalarFunction( -0.5*u0Left*u0Left ) );
FunctionPtr rightVal = Teuchos::rcp( new ConstantScalarFunction( 0.5*u0Right*u0Right ) );
inflowBC->addDirichlet(fhat, bottomBoundary, -u0 );
inflowBC->addDirichlet(fhat, leftBoundary, leftVal );
inflowBC->addDirichlet(fhat, rightBoundary, rightVal );
////////////////////////////////////////////////////////////////////
// CREATE SOLUTION OBJECT
////////////////////////////////////////////////////////////////////
Teuchos::RCP<Solution> solution = Teuchos::rcp(new Solution(mesh, inflowBC, rhs, ip));
mesh->registerSolution(solution);
if (enforceLocalConservation)
{
FunctionPtr zero = Teuchos::rcp( new ConstantScalarFunction(0.0) );
solution->lagrangeConstraints()->addConstraint(fhat == zero);
}
////////////////////////////////////////////////////////////////////
// DEFINE REFINEMENT STRATEGY
////////////////////////////////////////////////////////////////////
Teuchos::RCP<RefinementStrategy> refinementStrategy;
refinementStrategy = Teuchos::rcp(new RefinementStrategy(solution,energyThreshold));
////////////////////////////////////////////////////////////////////
// SOLVE
////////////////////////////////////////////////////////////////////
for (int refIndex=0; refIndex<=numRefs; refIndex++)
{
double L2Update = 1e7;
int iterCount = 0;
while (L2Update > nonlinearRelativeEnergyTolerance && iterCount < maxNewtonIterations)
{
solution->solve();
L2Update = solution->L2NormOfSolutionGlobal(u->ID());
cout << "L2 Norm of Update = " << L2Update << endl;
// backgroundFlow->clear();
backgroundFlow->addSolution(solution, newtonStepSize);
iterCount++;
}
cout << endl;
// check conservation
VarPtr testOne = varFactory.testVar("1", CONSTANT_SCALAR);
// Create a fake bilinear form for the testing
BFPtr fakeBF = Teuchos::rcp( new BF(varFactory) );
// Define our mass flux
FunctionPtr massFlux = Teuchos::rcp( new PreviousSolutionFunction(solution, fhat) );
LinearTermPtr massFluxTerm = massFlux * testOne;
Teuchos::RCP<shards::CellTopology> quadTopoPtr = Teuchos::rcp(new shards::CellTopology(shards::getCellTopologyData<shards::Quadrilateral<4> >() ));
DofOrderingFactory dofOrderingFactory(fakeBF);
int fakeTestOrder = H1Order;
DofOrderingPtr testOrdering = dofOrderingFactory.testOrdering(fakeTestOrder, *quadTopoPtr);
int testOneIndex = testOrdering->getDofIndex(testOne->ID(),0);
vector< ElementTypePtr > elemTypes = mesh->elementTypes(); // global element types
map<int, double> massFluxIntegral; // cellID -> integral
double maxMassFluxIntegral = 0.0;
double totalMassFlux = 0.0;
double totalAbsMassFlux = 0.0;
for (vector< ElementTypePtr >::iterator elemTypeIt = elemTypes.begin(); elemTypeIt != elemTypes.end(); elemTypeIt++)
{
ElementTypePtr elemType = *elemTypeIt;
vector< ElementPtr > elems = mesh->elementsOfTypeGlobal(elemType);
vector<int> cellIDs;
for (int i=0; i<elems.size(); i++)
{
cellIDs.push_back(elems[i]->cellID());
}
FieldContainer<double> physicalCellNodes = mesh->physicalCellNodesGlobal(elemType);
BasisCachePtr basisCache = Teuchos::rcp( new BasisCache(elemType,mesh) );
basisCache->setPhysicalCellNodes(physicalCellNodes,cellIDs,true); // true: create side caches
FieldContainer<double> cellMeasures = basisCache->getCellMeasures();
FieldContainer<double> fakeRHSIntegrals(elems.size(),testOrdering->totalDofs());
massFluxTerm->integrate(fakeRHSIntegrals,testOrdering,basisCache,true); // true: force side evaluation
for (int i=0; i<elems.size(); i++)
{
int cellID = cellIDs[i];
// pick out the ones for testOne:
massFluxIntegral[cellID] = fakeRHSIntegrals(i,testOneIndex);
}
// find the largest:
for (int i=0; i<elems.size(); i++)
{
int cellID = cellIDs[i];
maxMassFluxIntegral = max(abs(massFluxIntegral[cellID]), maxMassFluxIntegral);
}
for (int i=0; i<elems.size(); i++)
{
int cellID = cellIDs[i];
maxMassFluxIntegral = max(abs(massFluxIntegral[cellID]), maxMassFluxIntegral);
totalMassFlux += massFluxIntegral[cellID];
totalAbsMassFlux += abs( massFluxIntegral[cellID] );
}
}
if (rank==0)
{
cout << endl;
cout << "largest mass flux: " << maxMassFluxIntegral << endl;
cout << "total mass flux: " << totalMassFlux << endl;
cout << "sum of mass flux absolute value: " << totalAbsMassFlux << endl;
cout << endl;
stringstream outfile;
outfile << "burgers_" << refIndex;
backgroundFlow->writeToVTK(outfile.str(), 5);
}
if (refIndex < numRefs)
refinementStrategy->refine(rank==0); // print to console on rank 0
}
return 0;
}
bool ScratchPadTests::testResidualMemoryError()
{
int rank = Teuchos::GlobalMPISession::getRank();
double tol = 1e-11;
bool success = true;
int nCells = 2;
double eps = 1e-2;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr tau = varFactory->testVar("\\tau", HDIV);
VarPtr v = varFactory->testVar("v", HGRAD);
// define trial variables
VarPtr uhat = varFactory->traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory->fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory->fieldVar("u");
VarPtr sigma1 = varFactory->fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory->fieldVar("\\sigma_2");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// tau terms:
confusionBF->addTerm(sigma1 / eps, tau->x());
confusionBF->addTerm(sigma2 / eps, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(uhat, -tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
// robust test norm
IPPtr robIP = Teuchos::rcp(new IP);
robIP->addTerm(tau);
robIP->addTerm(tau->div());
robIP->addTerm(v->grad());
robIP->addTerm(v);
//////////////////// SPECIFY RHS ///////////////////////
FunctionPtr zero = Function::constant(0.0);
FunctionPtr one = Function::constant(1.0);
RHSPtr rhs = RHS::rhs();
FunctionPtr f = zero;
// FunctionPtr f = one;
rhs->addTerm( f * v ); // obviously, with f = 0 adding this term is not necessary!
//////////////////// CREATE BCs ///////////////////////
BCPtr bc = BC::bc();
SpatialFilterPtr inflowBoundary = Teuchos::rcp( new LRInflowSquareBoundary );
SpatialFilterPtr outflowBoundary = Teuchos::rcp( new LROutflowSquareBoundary);
FunctionPtr n = Function::normal();
vector<double> e1,e2;
e1.push_back(1.0);
e1.push_back(0.0);
e2.push_back(0.0);
e2.push_back(1.0);
bc->addDirichlet(beta_n_u_minus_sigma_n, inflowBoundary, beta*n*one);
bc->addDirichlet(uhat, outflowBoundary, zero);
//////////////////// BUILD MESH ///////////////////////
// define nodes for mesh
int order = 2;
int H1Order = order+1;
int pToAdd = 2;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells,confusionBF, H1Order, H1Order+pToAdd);
// mesh->setPartitionPolicy(Teuchos::rcp(new ZoltanMeshPartitionPolicy("HSFC")));
//////////////////// SOLVE & REFINE ///////////////////////
Teuchos::RCP<Solution> solution;
solution = Teuchos::rcp( new Solution(mesh, bc, rhs, robIP) );
solution->solve(false);
mesh->registerSolution(solution);
double energyErr1 = solution->energyErrorTotal();
LinearTermPtr residual = rhs->linearTermCopy();
residual->addTerm(-confusionBF->testFunctional(solution));
RieszRepPtr rieszResidual = Teuchos::rcp(new RieszRep(mesh, robIP, residual));
rieszResidual->computeRieszRep();
FunctionPtr e_v = RieszRep::repFunction(v,rieszResidual);
FunctionPtr e_tau = RieszRep::repFunction(tau,rieszResidual);
double energyThreshold = 0.2; // for mesh refinements
RefinementStrategy refinementStrategy( solution, energyThreshold );
refinementStrategy.refine();
solution->solve(false);
double energyErr2 = solution->energyErrorTotal();
// if energy error rises
if (energyErr1 < energyErr2)
{
if (rank==0)
cout << "energy error increased from " << energyErr1 << " to " << energyErr2 << " after refinement.\n";
success = false;
}
return success;
}
bool LinearTermTests::testBoundaryPlusVolumeTerms()
{
bool success = true;
// notion is integration by parts:
// (div f, v) = < f * n, v > - (f, grad v)
// We perform two subtests for each test: first we try with a particular
// function substituted for the variable. Second, we integrate over the
// basis for the mesh (i.e. we test a whole bunch of functions, whose
// precise definition is a bit complicated).
// A third test is against the two-term LinearTerm::integrate() method.
// This doesn't do integration by parts, but rather tests that
// (u + u->dot_normal(), v) = (u,v) + (u->dot_normal(), v)
///////////// FIRST TEST ////////////////
// start simply: define f to be (x, 0)
// (div f, v) = (1, v)
// < f * n, v > - (f, grad v) = < x n1, v > - ( x, v->dx() )
FunctionPtr x = Function::xn(1);
FunctionPtr y = Function::yn(1);
FunctionPtr x2 = Function::xn(2);
FunctionPtr y2 = Function::yn(2);
FunctionPtr x3 = Function::xn(3);
FunctionPtr y3 = Function::yn(3);
vector< FunctionPtr > f_fxns;
f_fxns.push_back( Function::vectorize( x, Function::zero() ) ); // div of this = 1
f_fxns.push_back( Function::vectorize( x2 / 6.0, x2 * y / 2.0 ) ); // div of this = x / 3 + x^2 / 2
for ( vector< FunctionPtr >::iterator fIt = f_fxns.begin(); fIt != f_fxns.end(); fIt++)
{
FunctionPtr vector_fxn = *fIt;
LinearTermPtr lt_v = vector_fxn->div()*v1;
// part a: substitute v1 = x*y^2
FunctionPtr v1_value = x*y2;
map< int, FunctionPtr > var_values;
var_values[v1->ID()] = v1_value;
double expectedValue = lt_v->evaluate(var_values, false)->integrate(mesh);
FunctionPtr n = Function::normal();
LinearTermPtr ibp = vector_fxn * n * v1 - vector_fxn * v1->grad();
int numCells = basisCache->getPhysicalCubaturePoints().dimension(0);
int numPoints = basisCache->getPhysicalCubaturePoints().dimension(1);
int spaceDim = basisCache->getSpaceDim();
FieldContainer<double> vector_fxn_values(numCells,numPoints,spaceDim);
vector_fxn->values(vector_fxn_values,basisCache);
// cout << "vector_fxn values: \n" << vector_fxn_values;
double boundaryIntegralSum = ibp->evaluate(var_values,true)->integrate(mesh);
double volumeIntegralSum = ibp->evaluate(var_values,false)->integrate(mesh);
double actualValue = boundaryIntegralSum + volumeIntegralSum;
double tol = 1e-14;
if (abs(expectedValue - actualValue)>tol)
{
success = false;
}
// part b: integrate the bases over each of the cells:
int num_dofs = testOrder->totalDofs();
FieldContainer<double> integrals_expected( mesh->numActiveElements(), num_dofs );
FieldContainer<double> integrals_actual( mesh->numActiveElements(), num_dofs );
lt_v->integrate(integrals_expected,testOrder,basisCache);
ibp->integrate(integrals_actual,testOrder,basisCache);
double maxDiff = 0;
if (! fcsAgree(integrals_actual, integrals_expected, tol, maxDiff) )
{
cout << "LT integrated by parts does not agree with the original; maxDiff: " << maxDiff << endl;
success = false;
}
// just on the odd chance that ordering makes a difference, repeat this test with the opposite order in ibp:
ibp = - vector_fxn * v1->grad() + vector_fxn * n * v1;
ibp->integrate(integrals_actual,testOrder,basisCache, false, false);
maxDiff = 0;
if (! fcsAgree(integrals_actual, integrals_expected, tol, maxDiff) )
{
cout << "LT integrated by parts does not agree with the original; maxDiff: " << maxDiff << endl;
success = false;
}
// part c: two-term integrals
FieldContainer<double> integrals_expected_two_term( mesh->numActiveElements(), num_dofs, num_dofs);
FieldContainer<double> integrals_actual_two_term( mesh->numActiveElements(), num_dofs, num_dofs );
LinearTermPtr ibp1 = vector_fxn * n * v1;
LinearTermPtr ibp2 = - vector_fxn * v1->grad();
lt_v->integrate(integrals_expected_two_term, testOrder, ibp1 + ibp2, testOrder, basisCache, false, false);
lt_v->integrate(integrals_actual_two_term, testOrder, ibp1, testOrder, basisCache, false, false); // don't forceBoundary, don't sumInto
lt_v->integrate(integrals_actual_two_term, testOrder, ibp2, testOrder, basisCache, false, true); // DO sumInto
maxDiff = 0;
if (! fcsAgree(integrals_actual_two_term, integrals_expected_two_term, tol, maxDiff) )
{
cout << "two-term integration is not bilinear; maxDiff: " << maxDiff << endl;
success = false;
}
// now, same thing but with the roles of ibp{1|2} and lt_v reversed:
(ibp1 + ibp2)->integrate(integrals_expected_two_term, testOrder, lt_v, testOrder, basisCache, false, false);
ibp1->integrate(integrals_actual_two_term, testOrder, lt_v, testOrder, basisCache, false, false); // don't forceBoundary, don't sumInto
ibp2->integrate(integrals_actual_two_term, testOrder, lt_v, testOrder, basisCache, false, true); // DO sumInto
maxDiff = 0;
if (! fcsAgree(integrals_actual_two_term, integrals_expected_two_term, tol, maxDiff) )
{
cout << "two-term integration is not bilinear; maxDiff: " << maxDiff << endl;
success = false;
}
// now, test that two-term integration commutes in the two terms:
ibp1->integrate(integrals_expected_two_term, testOrder, lt_v, testOrder, basisCache, false, false);
lt_v->integrate(integrals_actual_two_term, testOrder, ibp1, testOrder, basisCache, false, false);
// we expect the integrals to commute up to a transpose, so let's transpose one of the containers:
transposeFieldContainer(integrals_expected_two_term);
maxDiff = 0;
if (! fcsAgree(integrals_actual_two_term, integrals_expected_two_term, tol, maxDiff) )
{
cout << "two-term integration does not commute for boundary value (ibp1); maxDiff: " << maxDiff << endl;
success = false;
}
ibp2->integrate(integrals_expected_two_term, testOrder, lt_v, testOrder, basisCache, false, false);
lt_v->integrate(integrals_actual_two_term, testOrder, ibp2, testOrder, basisCache, false, false);
// we expect the integrals to commute up to a transpose, so let's transpose one of the containers:
transposeFieldContainer(integrals_expected_two_term);
maxDiff = 0;
if (! fcsAgree(integrals_actual_two_term, integrals_expected_two_term, tol, maxDiff) )
{
cout << "two-term integration does not commute for volume value (ibp2); maxDiff: " << maxDiff << endl;
success = false;
}
// part d: to suss out where the integration failure happens in the non-commuting case:
// 1. Substitute v1 = 1 in ibp2; get a function ibp2_at_v1_equals_one back.
// 2. Substitute v1 = 1 in lt_v; get a function lt_v_at_v1_equals_one back.
// 3. Integrate ibp2_at_v1_equals_one * lt_v_at_v1_equals_one over the mesh. Get a double result.
// 4. Because basis is nodal, the representation for v1 = 1 is just all 1s for coefficients.
// Therefore, the sum of the entries in the integrals_*_two_term matrices will should match
// the function integral. Whichever doesn't match is wrong.
// first, let's confirm that the v1 basis *is* nodal:
BasisPtr v1Basis = testOrder->getBasis(v1->ID());
if (! v1Basis->isNodal())
{
cout << "testBoundaryPlusVolumeTerms: final part of test relies on a nodal basis, but the basis is not nodal.";
cout << " Exiting test early (with whatever success value we have thus far).\n";
return success;
}
map< int, FunctionPtr > v1_equals_one;
v1_equals_one[v1->ID()] = Function::constant(1.0);
FunctionPtr ibp1_at_v1_equals_one = ibp1->evaluate(v1_equals_one,true); // ibp1 has only a boundary term, so we just ask for this
FunctionPtr ibp2_at_v1_equals_one = ibp2->evaluate(v1_equals_one,false); // ibp2 has no boundary terms, so we don't ask for these
FunctionPtr lt_v_at_v1_equals_one = lt_v->evaluate(v1_equals_one,false); // lt_v also has no boundary terms
if (ibp1_at_v1_equals_one->isZero())
{
cout << "ibp1_at_v1_equals_one->isZero() = true.\n";
}
if (lt_v_at_v1_equals_one->isZero())
{
cout << "lt_v_at_v1_equals_one->isZero() = true.\n";
}
FieldContainer<double> integrals_lt_v_first( mesh->numActiveElements(), num_dofs, num_dofs );
FieldContainer<double> integrals_ibp1_first( mesh->numActiveElements(), num_dofs, num_dofs );
FieldContainer<double> integrals_ibp2_first( mesh->numActiveElements(), num_dofs, num_dofs );
double lt_v_first_integral = 0.0, ibp1_first_integral = 0.0, ibp2_first_integral = 0.0;
double integral = (ibp1_at_v1_equals_one * lt_v_at_v1_equals_one)->integrate(mesh);
ibp1->integrate(integrals_ibp1_first, testOrder, lt_v, testOrder, basisCache, false, false);
lt_v->integrate(integrals_lt_v_first, testOrder, ibp1, testOrder, basisCache, false, false);
for (int i=0; i<integrals_lt_v_first.size(); i++)
{
lt_v_first_integral += integrals_lt_v_first[i];
ibp1_first_integral += integrals_ibp1_first[i];
}
if (abs(lt_v_first_integral - integral) > tol)
{
double diff = abs(lt_v_first_integral - integral);
success = false;
cout << "Integral with v1=1 substituted does not match two-term integration of (lt_v,ibp1) with lt_v as this. diff = " << diff << "\n";
cout << "lt_v_first_integral = " << lt_v_first_integral << endl;
cout << " (true) integral = " << integral << endl;
}
if (abs(ibp1_first_integral - integral) > tol)
{
double diff = abs(ibp1_first_integral - integral);
success = false;
cout << "Integral with v1=1 substituted does not match two-term integration of (lt_v,ibp1) with ibp1 as this. diff = " << diff << "\n";
cout << "ibp1_first_integral = " << ibp1_first_integral << endl;
cout << " (true) integral = " << integral << endl;
}
// now, do the same but for ibp2
integral = (ibp2_at_v1_equals_one * lt_v_at_v1_equals_one)->integrate(mesh);
ibp2->integrate(integrals_ibp2_first, testOrder, lt_v, testOrder, basisCache, false, false);
lt_v->integrate(integrals_lt_v_first, testOrder, ibp2, testOrder, basisCache, false, false);
// reset the sums:
lt_v_first_integral = 0.0;
ibp1_first_integral = 0.0;
ibp2_first_integral = 0.0;
for (int i=0; i<integrals_lt_v_first.size(); i++)
{
lt_v_first_integral += integrals_lt_v_first[i];
ibp2_first_integral += integrals_ibp2_first[i];
}
if (abs(lt_v_first_integral - integral) > tol)
{
double diff = abs(lt_v_first_integral - integral);
success = false;
cout << "Integral with v1=1 substituted does not match two-term integration of (lt_v,ibp2) with lt_v as this. diff = " << diff << "\n";
cout << "lt_v_first_integral = " << lt_v_first_integral << endl;
cout << " (true) integral = " << integral << endl;
}
if (abs(ibp2_first_integral - integral) > tol)
{
double diff = abs(ibp2_first_integral - integral);
success = false;
cout << "Integral with v1=1 substituted does not match two-term integration of (lt_v,ibp2) with ibp2 as this. diff = " << diff << "\n";
cout << "ibp1_first_integral = " << ibp1_first_integral << endl;
cout << " (true) integral = " << integral << endl;
}
}
return success;
}
bool LinearTermTests::testSums()
{
bool success = true;
LinearTermPtr sum = v1 + v2;
if (sum->summands().size() != 2)
{
success = false;
cout << "sum has the wrong number of summands\n";
return success;
}
LinearSummand first_summand = sum->summands()[0];
LinearSummand second_summand = sum->summands()[1];
VarPtr first_var = first_summand.second;
Camellia::EOperator first_op = first_var->op();
VarPtr second_var = second_summand.second;
Camellia::EOperator second_op = second_var->op();
if (first_var->ID() != v1->ID())
{
success = false;
cout << "first summand isn't v1.\n";
}
if (first_var->op() != OP_VALUE)
{
success = false;
cout << "first op isn't VALUE.\n";
}
if (second_var->ID() != v2->ID())
{
success = false;
cout << "second summand isn't v2 (is named " << second_var->name() << ").\n";
}
if (second_var->op() != OP_VALUE)
{
success = false;
cout << "second op isn't VALUE.\n";
}
// check that sum reports having both varIDs
if (sum->varIDs().find(v1->ID()) == sum->varIDs().end())
{
cout << "sum->varIDs() doesn't include v1.\n";
success = false;
}
if (sum->varIDs().find(v2->ID()) == sum->varIDs().end())
{
cout << "sum->varIDs() doesn't include v2.\n";
success = false;
}
if (sum->varIDs().size() != 2)
{
cout << "sum->varIDs() doesn't have the expected size (expected 2; is " << sum->varIDs().size() << ").\n";
success = false;
}
// TODO: check that the sum is correct
return success;
}
int main(int argc, char *argv[])
{
#ifdef HAVE_MPI
Teuchos::GlobalMPISession mpiSession(&argc, &argv,0);
int rank=mpiSession.getRank();
int numProcs=mpiSession.getNProc();
#else
int rank = 0;
int numProcs = 1;
#endif
int polyOrder = 2;
// define our manufactured solution or problem bilinear form:
double epsilon = 1e-3;
bool useTriangles = false;
int pToAdd = 2;
int nCells = 2;
if ( argc > 1)
{
nCells = atoi(argv[1]);
if (rank==0)
{
cout << "numCells = " << nCells << endl;
}
}
int numSteps = 20;
if ( argc > 2)
{
numSteps = atoi(argv[2]);
if (rank==0)
{
cout << "num NR steps = " << numSteps << endl;
}
}
int useHessian = 0; // defaults to "not use"
if ( argc > 3)
{
useHessian = atoi(argv[3]);
if (rank==0)
{
cout << "useHessian = " << useHessian << endl;
}
}
int thresh = numSteps; // threshhold for when to apply linesearch/hessian
if ( argc > 4)
{
thresh = atoi(argv[4]);
if (rank==0)
{
cout << "thresh = " << thresh << endl;
}
}
int H1Order = polyOrder + 1;
double energyThreshold = 0.2; // for mesh refinements
double nonlinearStepSize = 0.5;
double nonlinearRelativeEnergyTolerance = 1e-8; // used to determine convergence of the nonlinear solution
////////////////////////////////////////////////////////////////////
// DEFINE VARIABLES
////////////////////////////////////////////////////////////////////
// new-style bilinear form definition
VarFactory varFactory;
VarPtr uhat = varFactory.traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_hat = varFactory.fluxVar("\\widehat{\\beta_n u - \\sigma_n}");
VarPtr u = varFactory.fieldVar("u");
VarPtr sigma1 = varFactory.fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory.fieldVar("\\sigma_2");
VarPtr tau = varFactory.testVar("\\tau",HDIV);
VarPtr v = varFactory.testVar("v",HGRAD);
BFPtr bf = Teuchos::rcp( new BF(varFactory) ); // initialize bilinear form
////////////////////////////////////////////////////////////////////
// CREATE MESH
////////////////////////////////////////////////////////////////////
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells, bf, H1Order, H1Order+pToAdd);
mesh->setPartitionPolicy(Teuchos::rcp(new ZoltanMeshPartitionPolicy("HSFC")));
////////////////////////////////////////////////////////////////////
// INITIALIZE BACKGROUND FLOW FUNCTIONS
////////////////////////////////////////////////////////////////////
BCPtr nullBC = Teuchos::rcp((BC*)NULL);
RHSPtr nullRHS = Teuchos::rcp((RHS*)NULL);
IPPtr nullIP = Teuchos::rcp((IP*)NULL);
SolutionPtr backgroundFlow = Teuchos::rcp(new Solution(mesh, nullBC,
nullRHS, nullIP) );
vector<double> e1(2); // (1,0)
e1[0] = 1;
vector<double> e2(2); // (0,1)
e2[1] = 1;
FunctionPtr u_prev = Teuchos::rcp( new PreviousSolutionFunction(backgroundFlow, u) );
FunctionPtr beta = e1 * u_prev + Teuchos::rcp( new ConstantVectorFunction( e2 ) );
////////////////////////////////////////////////////////////////////
// DEFINE BILINEAR FORM
////////////////////////////////////////////////////////////////////
// tau parts:
// 1/eps (sigma, tau)_K + (u, div tau)_K - (u_hat, tau_n)_dK
bf->addTerm(sigma1 / epsilon, tau->x());
bf->addTerm(sigma2 / epsilon, tau->y());
bf->addTerm(u, tau->div());
bf->addTerm( - uhat, tau->dot_normal() );
// v:
// (sigma, grad v)_K - (sigma_hat_n, v)_dK - (u, beta dot grad v) + (u_hat * n dot beta, v)_dK
bf->addTerm( sigma1, v->dx() );
bf->addTerm( sigma2, v->dy() );
bf->addTerm( -u, beta * v->grad());
bf->addTerm( beta_n_u_minus_sigma_hat, v);
// ==================== SET INITIAL GUESS ==========================
mesh->registerSolution(backgroundFlow);
FunctionPtr zero = Teuchos::rcp( new ConstantScalarFunction(0.0) );
FunctionPtr u0 = Teuchos::rcp( new U0 );
map<int, Teuchos::RCP<Function> > functionMap;
functionMap[u->ID()] = u0;
functionMap[sigma1->ID()] = zero;
functionMap[sigma2->ID()] = zero;
backgroundFlow->projectOntoMesh(functionMap);
// ==================== END SET INITIAL GUESS ==========================
////////////////////////////////////////////////////////////////////
// DEFINE INNER PRODUCT
////////////////////////////////////////////////////////////////////
// function to scale the squared guy by epsilon/h
FunctionPtr epsilonOverHScaling = Teuchos::rcp( new EpsilonScaling(epsilon) );
IPPtr ip = Teuchos::rcp( new IP );
ip->addTerm( epsilonOverHScaling * (1.0/sqrt(epsilon))* tau);
ip->addTerm( tau->div());
// ip->addTerm( epsilonOverHScaling * v );
ip->addTerm( v );
ip->addTerm( sqrt(epsilon) * v->grad() );
ip->addTerm(v->grad());
// ip->addTerm( beta * v->grad() );
////////////////////////////////////////////////////////////////////
// DEFINE RHS
////////////////////////////////////////////////////////////////////
RHSPtr rhs = RHS::rhs();
FunctionPtr u_prev_squared_div2 = 0.5 * u_prev * u_prev;
rhs->addTerm((e1 * u_prev_squared_div2 + e2 * u_prev) * v->grad() - u_prev * tau->div());
////////////////////////////////////////////////////////////////////
// DEFINE DIRICHLET BC
////////////////////////////////////////////////////////////////////
FunctionPtr n = Teuchos::rcp( new UnitNormalFunction );
SpatialFilterPtr outflowBoundary = Teuchos::rcp( new TopBoundary);
SpatialFilterPtr inflowBoundary = Teuchos::rcp( new NegatedSpatialFilter(outflowBoundary) );
BCPtr inflowBC = BC::bc();
FunctionPtr u0_squared_div_2 = 0.5 * u0 * u0;
inflowBC->addDirichlet(beta_n_u_minus_sigma_hat,inflowBoundary,
( e1 * u0_squared_div_2 + e2 * u0) * n );
////////////////////////////////////////////////////////////////////
// CREATE SOLUTION OBJECT
////////////////////////////////////////////////////////////////////
Teuchos::RCP<Solution> solution = Teuchos::rcp(new Solution(mesh, inflowBC, rhs, ip));
mesh->registerSolution(solution);
////////////////////////////////////////////////////////////////////
// WARNING: UNFINISHED HESSIAN BIT
////////////////////////////////////////////////////////////////////
VarFactory hessianVars = varFactory.getBubnovFactory(VarFactory::BUBNOV_TRIAL);
VarPtr du = hessianVars.test(u->ID());
BFPtr hessianBF = Teuchos::rcp( new BF(hessianVars) ); // initialize bilinear form
// FunctionPtr e_v = Function::constant(1.0); // dummy error rep function for now - should do nothing
FunctionPtr u_current = Teuchos::rcp( new PreviousSolutionFunction(solution, u) );
FunctionPtr sig1_prev = Teuchos::rcp( new PreviousSolutionFunction(solution, sigma1) );
FunctionPtr sig2_prev = Teuchos::rcp( new PreviousSolutionFunction(solution, sigma2) );
FunctionPtr sig_prev = (e1*sig1_prev + e2*sig2_prev);
FunctionPtr fnhat = Teuchos::rcp(new PreviousSolutionFunction(solution,beta_n_u_minus_sigma_hat));
FunctionPtr uhat_prev = Teuchos::rcp(new PreviousSolutionFunction(solution,uhat));
LinearTermPtr residual = Teuchos::rcp(new LinearTerm);// residual
residual->addTerm(fnhat*v - (e1 * (u_prev_squared_div2 - sig1_prev) + e2 * (u_prev - sig2_prev)) * v->grad());
residual->addTerm((1/epsilon)*sig_prev * tau + u_prev * tau->div() - uhat_prev*tau->dot_normal());
LinearTermPtr Bdu = Teuchos::rcp(new LinearTerm);// residual
Bdu->addTerm( u_current*tau->div() - u_current*(beta*v->grad()));
Teuchos::RCP<RieszRep> riesz = Teuchos::rcp(new RieszRep(mesh, ip, residual));
Teuchos::RCP<RieszRep> duRiesz = Teuchos::rcp(new RieszRep(mesh, ip, Bdu));
riesz->computeRieszRep();
FunctionPtr e_v = Teuchos::rcp(new RepFunction(v,riesz));
e_v->writeValuesToMATLABFile(mesh, "e_v.m");
FunctionPtr posErrPart = Teuchos::rcp(new PositivePart(e_v->dx()));
hessianBF->addTerm(e_v->dx()*u,du);
// hessianBF->addTerm(posErrPart*u,du);
Teuchos::RCP<HessianFilter> hessianFilter = Teuchos::rcp(new HessianFilter(hessianBF));
if (useHessian)
{
solution->setWriteMatrixToFile(true,"hessianStiffness.dat");
}
else
{
solution->setWriteMatrixToFile(true,"stiffness.dat");
}
Teuchos::RCP< LineSearchStep > LS_Step = Teuchos::rcp(new LineSearchStep(riesz));
ofstream out;
out.open("Burgers.txt");
double NL_residual = 9e99;
for (int i = 0; i<numSteps; i++)
{
solution->solve(false); // do one solve to initialize things...
double stepLength = 1.0;
stepLength = LS_Step->stepSize(backgroundFlow,solution, NL_residual);
if (useHessian)
{
solution->setFilter(hessianFilter);
}
backgroundFlow->addSolution(solution,stepLength);
NL_residual = LS_Step->getNLResidual();
if (rank==0)
{
cout << "NL residual after adding = " << NL_residual << " with step size " << stepLength << endl;
out << NL_residual << endl; // saves initial NL error
}
}
out.close();
////////////////////////////////////////////////////////////////////
// DEFINE REFINEMENT STRATEGY
////////////////////////////////////////////////////////////////////
Teuchos::RCP<RefinementStrategy> refinementStrategy;
refinementStrategy = Teuchos::rcp(new RefinementStrategy(solution,energyThreshold));
int numRefs = 0;
Teuchos::RCP<NonlinearStepSize> stepSize = Teuchos::rcp(new NonlinearStepSize(nonlinearStepSize));
Teuchos::RCP<NonlinearSolveStrategy> solveStrategy;
solveStrategy = Teuchos::rcp( new NonlinearSolveStrategy(backgroundFlow, solution, stepSize,
nonlinearRelativeEnergyTolerance));
////////////////////////////////////////////////////////////////////
// SOLVE
////////////////////////////////////////////////////////////////////
for (int refIndex=0; refIndex<numRefs; refIndex++)
{
solveStrategy->solve(rank==0); // print to console on rank 0
refinementStrategy->refine(rank==0); // print to console on rank 0
}
// solveStrategy->solve(rank==0);
if (rank==0)
{
backgroundFlow->writeToVTK("Burgers.vtu",min(H1Order+1,4));
solution->writeFluxesToFile(uhat->ID(), "burgers.dat");
cout << "wrote solution files" << endl;
}
return 0;
}
// tests to make sure that the rieszNorm computed via matrices is the same as the one computed thru direct integration
bool ScratchPadTests::testRieszIntegration()
{
double tol = 1e-11;
bool success = true;
int nCells = 2;
double eps = .25;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr tau = varFactory->testVar("\\tau", HDIV);
VarPtr v = varFactory->testVar("v", HGRAD);
// define trial variables
VarPtr uhat = varFactory->traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory->fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory->fieldVar("u");
VarPtr sigma1 = varFactory->fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory->fieldVar("\\sigma_2");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// tau terms:
confusionBF->addTerm(sigma1 / eps, tau->x());
confusionBF->addTerm(sigma2 / eps, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(uhat, -tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
// robust test norm
IPPtr ip = Teuchos::rcp(new IP);
// just H1 projection
ip->addTerm(v->grad());
ip->addTerm(v);
ip->addTerm(tau);
ip->addTerm(tau->div());
//////////////////// SPECIFY RHS AND HELPFUL FUNCTIONS ///////////////////////
FunctionPtr n = Function::normal();
vector<double> e1,e2;
e1.push_back(1.0);
e1.push_back(0.0);
e2.push_back(0.0);
e2.push_back(1.0);
FunctionPtr one = Function::constant(1.0);
FunctionPtr zero = Function::constant(0.0);
RHSPtr rhs = RHS::rhs();
FunctionPtr f = one;
rhs->addTerm( f * v ); // obviously, with f = 0 adding this term is not necessary!
//////////////////// CREATE BCs ///////////////////////
BCPtr bc = BC::bc();
SpatialFilterPtr squareBoundary = Teuchos::rcp( new SquareBoundary );
bc->addDirichlet(uhat, squareBoundary, zero);
//////////////////// BUILD MESH ///////////////////////
// define nodes for mesh
int order = 2;
int H1Order = order+1;
int pToAdd = 2;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells,confusionBF, H1Order, H1Order+pToAdd);
//////////////////// SOLVE & REFINE ///////////////////////
LinearTermPtr lt = Teuchos::rcp(new LinearTerm);
FunctionPtr fxn = Function::xn(1); // fxn = x
lt->addTerm(fxn*v + fxn->grad()*v->grad());
lt->addTerm(fxn*tau->x() + fxn*tau->y() + (fxn->dx() + fxn->dy())*tau->div());
Teuchos::RCP<RieszRep> rieszLT = Teuchos::rcp(new RieszRep(mesh, ip, lt));
rieszLT->computeRieszRep();
double rieszNorm = rieszLT->getNorm();
FunctionPtr e_v = RieszRep::repFunction(v,rieszLT);
FunctionPtr e_tau = RieszRep::repFunction(tau,rieszLT);
map<int,FunctionPtr> repFxns;
repFxns[v->ID()] = e_v;
repFxns[tau->ID()] = e_tau;
double integratedNorm = sqrt((lt->evaluate(repFxns,false))->integrate(mesh,5,true));
success = abs(rieszNorm-integratedNorm)<tol;
if (success==false)
{
cout << "Failed testRieszIntegration; riesz norm is computed to be = " << rieszNorm << ", while using integration it's computed to be " << integratedNorm << endl;
return success;
}
return success;
}
bool ScratchPadTests::testGalerkinOrthogonality()
{
double tol = 1e-11;
bool success = true;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr v = varFactory->testVar("v", HGRAD);
vector<double> beta;
beta.push_back(1.0);
beta.push_back(1.0);
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
// robust test norm
IPPtr ip = Teuchos::rcp(new IP);
ip->addTerm(v);
ip->addTerm(beta*v->grad());
// define trial variables
VarPtr beta_n_u = varFactory->fluxVar("\\widehat{\\beta \\cdot n }");
VarPtr u = varFactory->fieldVar("u");
//////////////////// BUILD MESH ///////////////////////
BFPtr convectionBF = Teuchos::rcp( new BF(varFactory) );
FunctionPtr n = Function::normal();
// v terms:
convectionBF->addTerm( -u, beta * v->grad() );
convectionBF->addTerm( beta_n_u, v);
// define nodes for mesh
int order = 2;
int H1Order = order+1;
int pToAdd = 1;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(4, convectionBF, H1Order, H1Order+pToAdd);
//////////////////// SOLVE ///////////////////////
RHSPtr rhs = RHS::rhs();
BCPtr bc = BC::bc();
SpatialFilterPtr inflowBoundary = Teuchos::rcp( new InflowSquareBoundary );
SpatialFilterPtr outflowBoundary = Teuchos::rcp( new NegatedSpatialFilter(inflowBoundary) );
FunctionPtr uIn;
uIn = Teuchos::rcp(new Uinflow); // uses a discontinuous piecewise-constant basis function on left and bottom sides of square
bc->addDirichlet(beta_n_u, inflowBoundary, beta*n*uIn);
Teuchos::RCP<Solution> solution;
solution = Teuchos::rcp( new Solution(mesh, bc, rhs, ip) );
solution->solve(false);
FunctionPtr uFxn = Function::solution(u, solution);
FunctionPtr fnhatFxn = Function::solution(beta_n_u,solution);
// make residual for riesz representation function
LinearTermPtr residual = Teuchos::rcp(new LinearTerm);// residual
FunctionPtr parity = Function::sideParity();
residual->addTerm(-fnhatFxn*v + (beta*uFxn)*v->grad());
Teuchos::RCP<RieszRep> riesz = Teuchos::rcp(new RieszRep(mesh, ip, residual));
riesz->computeRieszRep();
map<int,FunctionPtr> err_rep_map;
err_rep_map[v->ID()] = RieszRep::repFunction(v,riesz);
//////////////////// GET BOUNDARY CONDITION DATA ///////////////////////
FieldContainer<GlobalIndexType> bcGlobalIndices;
FieldContainer<double> bcGlobalValues;
mesh->boundary().bcsToImpose(bcGlobalIndices,bcGlobalValues,*(solution->bc()), NULL);
set<int> bcInds;
for (int i=0; i<bcGlobalIndices.dimension(0); i++)
{
bcInds.insert(bcGlobalIndices(i));
}
//////////////////// CHECK GALERKIN ORTHOGONALITY ///////////////////////
BCPtr nullBC;
RHSPtr nullRHS;
IPPtr nullIP;
SolutionPtr solnPerturbation = Teuchos::rcp(new Solution(mesh, nullBC, nullRHS, nullIP) );
map< int, vector<DofInfo> > infoMap = constructGlobalDofToLocalDofInfoMap(mesh);
for (map< int, vector<DofInfo> >::iterator mapIt = infoMap.begin();
mapIt != infoMap.end(); mapIt++)
{
int dofIndex = mapIt->first;
vector< DofInfo > dofInfoVector = mapIt->second; // all the local dofs that map to dofIndex
// create perturbation in direction du
solnPerturbation->clear(); // clear all solns
// set each corresponding local dof to 1.0
for (vector< DofInfo >::iterator dofInfoIt = dofInfoVector.begin();
dofInfoIt != dofInfoVector.end(); dofInfoIt++)
{
DofInfo info = *dofInfoIt;
FieldContainer<double> solnCoeffs(info.basisCardinality);
solnCoeffs(info.basisOrdinal) = 1.0;
solnPerturbation->setSolnCoeffsForCellID(solnCoeffs, info.cellID, info.trialID, info.sideIndex);
}
// solnPerturbation->setSolnCoeffForGlobalDofIndex(1.0,dofIndex);
LinearTermPtr b_du = convectionBF->testFunctional(solnPerturbation);
FunctionPtr gradient = b_du->evaluate(err_rep_map, TestingUtilities::isFluxOrTraceDof(mesh,dofIndex)); // use boundary part only if flux
double grad = gradient->integrate(mesh,10);
if (!TestingUtilities::isFluxOrTraceDof(mesh,dofIndex) && abs(grad)>tol) // if we're not single-precision zero FOR FIELDS
{
// int cellID = mesh->getGlobalToLocalMap()[dofIndex].first;
cout << "Failed testGalerkinOrthogonality() for fields with diff " << abs(grad) << " at dof " << dofIndex << "; info:" << endl;
cout << dofInfoString(infoMap[dofIndex]);
success = false;
}
}
FieldContainer<double> errorJumps(mesh->numGlobalDofs()); //initialized to zero
// just test fluxes ON INTERNAL SKELETON here
set<GlobalIndexType> activeCellIDs = mesh->getActiveCellIDsGlobal();
for (GlobalIndexType activeCellID : activeCellIDs)
{
ElementPtr elem = mesh->getElement(activeCellID);
for (int sideIndex = 0; sideIndex < 4; sideIndex++)
{
ElementTypePtr elemType = elem->elementType();
vector<int> localDofIndices = elemType->trialOrderPtr->getDofIndices(beta_n_u->ID(), sideIndex);
for (int i = 0; i<localDofIndices.size(); i++)
{
int globalDofIndex = mesh->globalDofIndex(elem->cellID(), localDofIndices[i]);
vector< DofInfo > dofInfoVector = infoMap[globalDofIndex];
solnPerturbation->clear();
TestingUtilities::setSolnCoeffForGlobalDofIndex(solnPerturbation,1.0,globalDofIndex);
// also add in BCs
for (int i = 0; i<bcGlobalIndices.dimension(0); i++)
{
TestingUtilities::setSolnCoeffForGlobalDofIndex(solnPerturbation,bcGlobalValues(i),bcGlobalIndices(i));
}
LinearTermPtr b_du = convectionBF->testFunctional(solnPerturbation);
FunctionPtr gradient = b_du->evaluate(err_rep_map, TestingUtilities::isFluxOrTraceDof(mesh,globalDofIndex)); // use boundary part only if flux
double jump = gradient->integrate(mesh,10);
errorJumps(globalDofIndex) += jump;
}
}
}
for (int i = 0; i<mesh->numGlobalDofs(); i++)
{
if (abs(errorJumps(i))>tol)
{
cout << "Failing Galerkin orthogonality test for fluxes with diff " << errorJumps(i) << " at dof " << i << endl;
cout << dofInfoString(infoMap[i]);
success = false;
}
}
return success;
}
// tests whether a mixed type LT
bool ScratchPadTests::testIntegrateDiscontinuousFunction()
{
bool success = true;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr v = varFactory->testVar("v", HGRAD);
vector<double> beta;
beta.push_back(1.0);
beta.push_back(1.0);
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
// robust test norm
IPPtr ip = Teuchos::rcp(new IP);
ip->addTerm(v);
ip->addTerm(beta*v->grad());
// for projections
IPPtr ipL2 = Teuchos::rcp(new IP);
ipL2->addTerm(v);
// define trial variables
VarPtr beta_n_u = varFactory->fluxVar("\\widehat{\\beta \\cdot n }");
VarPtr u = varFactory->fieldVar("u");
//////////////////// BUILD MESH ///////////////////////
BFPtr convectionBF = Teuchos::rcp( new BF(varFactory) );
// v terms:
convectionBF->addTerm( -u, beta * v->grad() );
convectionBF->addTerm( beta_n_u, v);
// define nodes for mesh
int order = 1;
int H1Order = order+1;
int pToAdd = 1;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(2, 1, convectionBF, H1Order, H1Order+pToAdd);
//////////////////// integrate discontinuous function - cellIDFunction ///////////////////////
// FunctionPtr cellIDFxn = Teuchos::rcp(new CellIDFunction); // should be 0 on cellID 0, 1 on cellID 1
set<int> cellIDs;
cellIDs.insert(1); // 0 on cell 0, 1 on cell 1
FunctionPtr indicator = Teuchos::rcp(new IndicatorFunction(cellIDs)); // should be 0 on cellID 0, 1 on cellID 1
double jumpWeight = 13.3; // some random number
FunctionPtr edgeRestrictionFxn = Teuchos::rcp(new EdgeFunction);
FunctionPtr X = Function::xn(1);
LinearTermPtr integrandLT = Function::constant(1.0)*v + Function::constant(jumpWeight)*X*edgeRestrictionFxn*v;
// make riesz representation function to more closely emulate the error rep
LinearTermPtr indicatorLT = Teuchos::rcp(new LinearTerm);// residual
indicatorLT->addTerm(indicator*v);
Teuchos::RCP<RieszRep> riesz = Teuchos::rcp(new RieszRep(mesh, ipL2, indicatorLT));
riesz->computeRieszRep();
map<int,FunctionPtr> vmap;
vmap[v->ID()] = RieszRep::repFunction(v,riesz); // SHOULD BE L2 projection = same thing!!!
FunctionPtr volumeIntegrand = integrandLT->evaluate(vmap,false);
FunctionPtr edgeRestrictedIntegrand = integrandLT->evaluate(vmap,true);
double edgeRestrictedValue = volumeIntegrand->integrate(mesh,10) + edgeRestrictedIntegrand->integrate(mesh,10);
double expectedValue = .5 + .5*jumpWeight;
double diff = abs(expectedValue-edgeRestrictedValue);
if (abs(diff)>1e-11)
{
success = false;
cout << "Failed testIntegrateDiscontinuousFunction() with expectedValue = " << expectedValue << " and actual value = " << edgeRestrictedValue << endl;
}
return success;
}
// tests whether a mixed type LT
bool ScratchPadTests::testLinearTermEvaluationConsistency()
{
bool success = true;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr v = varFactory->testVar("v", HGRAD);
vector<double> beta;
beta.push_back(1.0);
beta.push_back(1.0);
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
// robust test norm
IPPtr ip = Teuchos::rcp(new IP);
ip->addTerm(v);
ip->addTerm(beta*v->grad());
// define trial variables
VarPtr beta_n_u = varFactory->fluxVar("\\widehat{\\beta \\cdot n }");
VarPtr u = varFactory->fieldVar("u");
//////////////////// BUILD MESH ///////////////////////
BFPtr convectionBF = Teuchos::rcp( new BF(varFactory) );
// v terms:
convectionBF->addTerm( -u, beta * v->grad() );
convectionBF->addTerm( beta_n_u, v);
// define nodes for mesh
int order = 1;
int H1Order = order+1;
int pToAdd = 1;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(1, convectionBF, H1Order, H1Order+pToAdd);
//////////////////// get fake residual ///////////////////////
LinearTermPtr lt = Teuchos::rcp(new LinearTerm);
FunctionPtr edgeFxn = Teuchos::rcp(new EdgeFunction);
FunctionPtr Xsq = Function::xn(2);
FunctionPtr Ysq = Function::yn(2);
FunctionPtr XYsq = Xsq*Ysq;
lt->addTerm(edgeFxn*v + (beta*XYsq)*v->grad());
Teuchos::RCP<RieszRep> ltRiesz = Teuchos::rcp(new RieszRep(mesh, ip, lt));
ltRiesz->computeRieszRep();
FunctionPtr repFxn = RieszRep::repFunction(v,ltRiesz);
map<int,FunctionPtr> rep_map;
rep_map[v->ID()] = repFxn;
FunctionPtr edgeLt = lt->evaluate(rep_map, true) ;
FunctionPtr elemLt = lt->evaluate(rep_map, false);
double edgeVal = edgeLt->integrate(mesh,10);
double elemVal = elemLt->integrate(mesh,10);
LinearTermPtr edgeOnlyLt = Teuchos::rcp(new LinearTerm);// residual
edgeOnlyLt->addTerm(edgeFxn*v);
FunctionPtr edgeOnly = edgeOnlyLt->evaluate(rep_map,true);
double edgeOnlyVal = edgeOnly->integrate(mesh,10);
double diff = edgeOnlyVal-edgeVal;
if (abs(diff)>1e-11)
{
success = false;
cout << "Failed testLinearTermEvaluationConsistency() with diff = " << diff << endl;
}
return success;
}
bool LinearTermTests::testIntegrateMixedBasis()
{
bool success = true;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr v = varFactory->testVar("v", HGRAD);
// define trial variables
VarPtr beta_n_u_hat = varFactory->fluxVar("\\widehat{\\beta \\cdot n }");
VarPtr u = varFactory->fieldVar("u");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(1.0);
//////////////////// DEFINE BILINEAR FORM/Mesh ///////////////////////
BFPtr convectionBF = Teuchos::rcp( new BF(varFactory) );
// v terms:
convectionBF->addTerm( -u, beta * v->grad() );
convectionBF->addTerm( beta_n_u_hat, v);
convectionBF->addTerm( u, v);
// build CONSTANT SINGLE ELEMENT MESH
int order = 0;
int H1Order = order+1;
int pToAdd = 1;
int nCells = 2; // along a side
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells,convectionBF, H1Order, H1Order+pToAdd);
ElementTypePtr elemType = mesh->getElement(0)->elementType();
BasisCachePtr basisCache = Teuchos::rcp(new BasisCache(elemType, mesh));
vector<GlobalIndexType> cellIDs;
vector< ElementPtr > allElems = mesh->activeElements();
vector< ElementPtr >::iterator elemIt;
for (elemIt=allElems.begin(); elemIt!=allElems.end(); elemIt++)
{
cellIDs.push_back((*elemIt)->cellID());
}
bool createSideCacheToo = true;
basisCache->setPhysicalCellNodes(mesh->physicalCellNodesGlobal(elemType), cellIDs, createSideCacheToo);
int numTrialDofs = elemType->trialOrderPtr->totalDofs();
int numCells = mesh->numActiveElements();
double areaPerCell = 1.0 / numCells;
FieldContainer<double> integrals(numCells,numTrialDofs);
FieldContainer<double> expectedIntegrals(numCells,numTrialDofs);
double sidelengthOfCell = 1.0 / nCells;
DofOrderingPtr trialOrdering = elemType->trialOrderPtr;
int dofForField = trialOrdering->getDofIndex(u->ID(), 0);
vector<int> dofsForFlux;
const vector<int>* sidesForFlux = &trialOrdering->getSidesForVarID(beta_n_u_hat->ID());
for (vector<int>::const_iterator sideIt = sidesForFlux->begin(); sideIt != sidesForFlux->end(); sideIt++)
{
int sideIndex = *sideIt;
dofsForFlux.push_back(trialOrdering->getDofIndex(beta_n_u_hat->ID(), 0, sideIndex));
}
for (int cellIndex = 0; cellIndex < numCells; cellIndex++)
{
expectedIntegrals(cellIndex, dofForField) = areaPerCell;
for (vector<int>::iterator dofIt = dofsForFlux.begin(); dofIt != dofsForFlux.end(); dofIt++)
{
int fluxDofIndex = *dofIt;
expectedIntegrals(cellIndex, fluxDofIndex) = sidelengthOfCell;
}
}
// cout << "expectedIntegrals:\n" << expectedIntegrals;
// setup: with constant degrees of freedom, we expect that the integral of int_dK (flux) + int_K (field) will be ones for each degree of freedom, assuming the basis functions for these constants field/flux variables are just C = 1.0.
//
//On a unit square, int_K (constant) = 1.0, and int_dK (u_i) = 1, for i = 0,...,3.
LinearTermPtr lt = 1.0 * beta_n_u_hat;
LinearTermPtr field = 1.0 * u;
lt->addTerm(field,true);
lt->integrate(integrals, elemType->trialOrderPtr, basisCache);
double tol = 1e-12;
double maxDiff;
success = TestSuite::fcsAgree(integrals,expectedIntegrals,tol,maxDiff);
if (success==false)
{
cout << "Failed testIntegrateMixedBasis with maxDiff = " << maxDiff << endl;
}
return success;
}
bool LinearTermTests::testMixedTermConsistency()
{
bool success = true;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr tau = varFactory->testVar("\\tau", HDIV);
VarPtr v = varFactory->testVar("v", HGRAD);
// define trial variables
VarPtr uhat = varFactory->traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory->fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory->fieldVar("u");
VarPtr sigma1 = varFactory->fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory->fieldVar("\\sigma_2");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
double eps = .01;
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// tau terms:
confusionBF->addTerm(sigma1 / eps, tau->x());
confusionBF->addTerm(sigma2 / eps, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(uhat, -tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
//////////////////// BUILD MESH ///////////////////////
// define nodes for mesh
int H1Order = 1;
int pToAdd = 1;
FieldContainer<double> quadPoints(4,2);
quadPoints(0,0) = 0.0; // x1
quadPoints(0,1) = 0.0; // y1
quadPoints(1,0) = 1.0;
quadPoints(1,1) = 0.0;
quadPoints(2,0) = 1.0;
quadPoints(2,1) = 1.0;
quadPoints(3,0) = 0.0;
quadPoints(3,1) = 1.0;
int nCells = 1;
int horizontalCells = nCells, verticalCells = nCells;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> myMesh = MeshFactory::buildQuadMesh(quadPoints, horizontalCells, verticalCells,
confusionBF, H1Order, H1Order+pToAdd);
ElementTypePtr elemType = myMesh->getElement(0)->elementType();
// DofOrderingPtr testOrder = elemType->testOrderPtr;
BasisCachePtr basisCache = Teuchos::rcp(new BasisCache(elemType, myMesh, true));
LinearTermPtr integrandIBP = Teuchos::rcp(new LinearTerm);// residual
vector<double> e1(2); // (1,0)
vector<double> e2(2); // (0,1)
e1[0] = 1;
e2[1] = 1;
FunctionPtr n = Function::normal();
FunctionPtr X = Function::xn(1);
FunctionPtr Y = Function::yn(1);
FunctionPtr testFxn1 = X;
FunctionPtr testFxn2 = Y;
FunctionPtr divTestFxn = testFxn1->dx() + testFxn2->dy();
FunctionPtr vectorTest = testFxn1*e1 + testFxn2*e2;
integrandIBP->addTerm(vectorTest*n*v + -vectorTest*v->grad()); // boundary term
// define dummy IP to initialize riesz rep class, but just integrate RHS
IPPtr dummyIP = Teuchos::rcp(new IP);
dummyIP->addTerm(v);
Teuchos::RCP<RieszRep> riesz = Teuchos::rcp(new RieszRep(myMesh, dummyIP, integrandIBP));
map<GlobalIndexType,FieldContainer<double> > rieszRHS = riesz->integrateFunctional();
set<GlobalIndexType> cellIDs = myMesh->cellIDsInPartition();
for (set<GlobalIndexType>::iterator cellIDIt=cellIDs.begin(); cellIDIt !=cellIDs.end(); cellIDIt++)
{
GlobalIndexType cellID = *cellIDIt;
ElementTypePtr elemTypePtr = myMesh->getElementType(cellID);
DofOrderingPtr testOrderingPtr = elemTypePtr->testOrderPtr;
int numTestDofs = testOrderingPtr->totalDofs();
BasisCachePtr basisCache = BasisCache::basisCacheForCell(myMesh, cellID, true);
FieldContainer<double> rhsIBPValues(1,numTestDofs);
integrandIBP->integrate(rhsIBPValues, testOrderingPtr, basisCache);
FieldContainer<double> rieszValues(1,numTestDofs);
(riesz->getFunctional())->integrate(rieszValues, testOrderingPtr, basisCache);
double maxDiff;
double tol = 1e-13;
FieldContainer<double> rhsIBPVals(numTestDofs);
for (int i = 0; i< numTestDofs; i++)
{
rhsIBPVals(i) = rhsIBPValues(0,i);
// cout << "riesz rhs values = " << rieszRHS[cellID](i) << ", rhsIBPValues = " << rhsIBPVals(i) << ", riesz returned values = " << rieszValues(0,i) << endl;
}
bool fcsAgree = TestSuite::fcsAgree(rieszRHS[cellID],rhsIBPVals,tol,maxDiff);
if (!fcsAgree)
{
success=false;
cout << "Failed mixed term consistency test with maxDiff = " << maxDiff << " on cellID " << cellID<< endl;
}
}
return allSuccess(success);
}
// tests to make sure the energy error calculated thru direct integration works for vector valued test functions too
bool ScratchPadTests::testLTResidual()
{
double tol = 1e-11;
int rank = Teuchos::GlobalMPISession::getRank();
bool success = true;
int nCells = 2;
double eps = .1;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr tau = varFactory->testVar("\\tau", HDIV);
VarPtr v = varFactory->testVar("v", HGRAD);
// define trial variables
VarPtr uhat = varFactory->traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory->fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory->fieldVar("u");
VarPtr sigma1 = varFactory->fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory->fieldVar("\\sigma_2");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// tau terms:
confusionBF->addTerm(sigma1 / eps, tau->x());
confusionBF->addTerm(sigma2 / eps, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(uhat, -tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
// robust test norm
IPPtr ip = Teuchos::rcp(new IP);
// choose the mesh-independent norm even though it may have boundary layers
ip->addTerm(v->grad());
ip->addTerm(v);
ip->addTerm(tau);
ip->addTerm(tau->div());
//////////////////// SPECIFY RHS AND HELPFUL FUNCTIONS ///////////////////////
FunctionPtr n = Function::normal();
vector<double> e1,e2;
e1.push_back(1.0);
e1.push_back(0.0);
e2.push_back(0.0);
e2.push_back(1.0);
FunctionPtr one = Function::constant(1.0);
FunctionPtr zero = Function::constant(0.0);
RHSPtr rhs = RHS::rhs();
FunctionPtr f = one; // if this is set to zero instead, we pass the test (a clue?)
rhs->addTerm( f * v );
//////////////////// CREATE BCs ///////////////////////
BCPtr bc = BC::bc();
SpatialFilterPtr squareBoundary = Teuchos::rcp( new SquareBoundary );
bc->addDirichlet(uhat, squareBoundary, one);
//////////////////// BUILD MESH ///////////////////////
// define nodes for mesh
int order = 2;
int H1Order = order+1;
int pToAdd = 2;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells,confusionBF, H1Order, H1Order+pToAdd);
//////////////////// SOLVE & REFINE ///////////////////////
Teuchos::RCP<Solution> solution;
solution = Teuchos::rcp( new Solution(mesh, bc, rhs, ip) );
solution->solve(false);
double energyError = solution->energyErrorTotal();
LinearTermPtr residual = rhs->linearTermCopy();
residual->addTerm(-confusionBF->testFunctional(solution),true);
// FunctionPtr uh = Function::solution(uhat,solution);
// FunctionPtr fn = Function::solution(beta_n_u_minus_sigma_n,solution);
// FunctionPtr uF = Function::solution(u,solution);
// FunctionPtr sigma = e1*Function::solution(sigma1,solution)+e2*Function::solution(sigma2,solution);
// residual->addTerm(- (fn*v - uh*tau->dot_normal()));
// residual->addTerm(- (uF*(tau->div() - beta*v->grad()) + sigma*((1/eps)*tau + v->grad())));
// residual->addTerm(-(fn*v - uF*beta*v->grad() + sigma*v->grad())); // just v portion
// residual->addTerm(uh*tau->dot_normal() - uF*tau->div() - sigma*((1/eps)*tau)); // just tau portion
Teuchos::RCP<RieszRep> rieszResidual = Teuchos::rcp(new RieszRep(mesh, ip, residual));
rieszResidual->computeRieszRep();
double energyErrorLT = rieszResidual->getNorm();
int cubEnrich = 0;
bool testVsTest = true;
FunctionPtr e_v = RieszRep::repFunction(v,rieszResidual);
FunctionPtr e_tau = RieszRep::repFunction(tau,rieszResidual);
// experiment by Nate: manually specify the error (this appears to produce identical results, as it should)
// FunctionPtr err = e_v * e_v + e_tau * e_tau + e_v->grad() * e_v->grad() + e_tau->div() * e_tau->div();
map<int,FunctionPtr> errFxns;
errFxns[v->ID()] = e_v;
errFxns[tau->ID()] = e_tau;
LinearTermPtr ipAtErrFxns = ip->evaluate(errFxns);
FunctionPtr err = ip->evaluate(errFxns)->evaluate(errFxns);
double energyErrorIntegrated = sqrt(err->integrate(mesh,cubEnrich,testVsTest));
// check that energy error computed thru Solution and through rieszRep are the same
bool success1 = abs(energyError-energyErrorLT)<tol;
// checks that matrix-computed and integrated errors are the same
bool success2 = abs(energyErrorLT-energyErrorIntegrated)<tol;
success = success1==true && success2==true;
if (!success)
{
if (rank==0)
cout << "Failed testLTResidual; energy error = " << energyError << ", while linearTerm error is computed to be " << energyErrorLT << ", and when computing through integration of the Riesz rep function, error = " << energyErrorIntegrated << endl;
}
// VTKExporter exporter(solution, mesh, varFactory);
// exporter.exportSolution("testLTRes");
// cout << endl;
return success;
}
int main(int argc, char *argv[])
{
#ifdef HAVE_MPI
Teuchos::GlobalMPISession mpiSession(&argc, &argv,0);
choice::MpiArgs args( argc, argv );
#else
choice::Args args( argc, argv );
#endif
int commRank = Teuchos::GlobalMPISession::getRank();
int numProcs = Teuchos::GlobalMPISession::getNProc();
// Required arguments
int numRefs = args.Input<int>("--numRefs", "number of refinement steps");
bool enforceLocalConservation = args.Input<bool>("--conserve", "enforce local conservation");
bool steady = args.Input<bool>("--steady", "run steady rather than transient");
// Optional arguments (have defaults)
double dt = args.Input("--dt", "time step", 0.25);
int numTimeSteps = args.Input("--nt", "number of time steps", 20);
halfWidth = args.Input("--halfWidth", "half width of inlet profile", 1.0);
args.Process();
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactory varFactory;
VarPtr v = varFactory.testVar("v", HGRAD);
// define trial variables
VarPtr beta_n_u_hat = varFactory.fluxVar("\\widehat{\\beta \\cdot n }");
VarPtr u = varFactory.fieldVar("u");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
//////////////////// BUILD MESH ///////////////////////
BFPtr bf = Teuchos::rcp( new BF(varFactory) );
// define nodes for mesh
FieldContainer<double> meshBoundary(4,2);
meshBoundary(0,0) = 0.0; // x1
meshBoundary(0,1) = -2.0; // y1
meshBoundary(1,0) = 4.0;
meshBoundary(1,1) = -2.0;
meshBoundary(2,0) = 4.0;
meshBoundary(2,1) = 2.0;
meshBoundary(3,0) = 0.0;
meshBoundary(3,1) = 2.0;
int horizontalCells = 8, verticalCells = 8;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = Mesh::buildQuadMesh(meshBoundary, horizontalCells, verticalCells,
bf, H1Order, H1Order+pToAdd);
////////////////////////////////////////////////////////////////////
// INITIALIZE FLOW FUNCTIONS
////////////////////////////////////////////////////////////////////
BCPtr nullBC = Teuchos::rcp((BC*)NULL);
RHSPtr nullRHS = Teuchos::rcp((RHS*)NULL);
IPPtr nullIP = Teuchos::rcp((IP*)NULL);
SolutionPtr prevTimeFlow = Teuchos::rcp(new Solution(mesh, nullBC, nullRHS, nullIP) );
SolutionPtr flowResidual = Teuchos::rcp(new Solution(mesh, nullBC, nullRHS, nullIP) );
FunctionPtr u_prev_time = Teuchos::rcp( new PreviousSolutionFunction(prevTimeFlow, u) );
//////////////////// DEFINE BILINEAR FORM ///////////////////////
Teuchos::RCP<RHSEasy> rhs = Teuchos::rcp( new RHSEasy );
FunctionPtr invDt = Teuchos::rcp(new ScalarParamFunction(1.0/dt));
// v terms:
bf->addTerm( beta * u, - v->grad() );
bf->addTerm( beta_n_u_hat, v);
if (!steady)
{
bf->addTerm( u, invDt*v );
rhs->addTerm( u_prev_time * invDt * v );
}
//////////////////// SPECIFY RHS ///////////////////////
FunctionPtr f = Teuchos::rcp( new ConstantScalarFunction(0.0) );
rhs->addTerm( f * v ); // obviously, with f = 0 adding this term is not necessary!
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
IPPtr ip = bf->graphNorm();
// ip->addTerm(v);
// ip->addTerm(beta*v->grad());
//////////////////// CREATE BCs ///////////////////////
Teuchos::RCP<BCEasy> bc = Teuchos::rcp( new BCEasy );
SpatialFilterPtr lBoundary = Teuchos::rcp( new LeftBoundary );
FunctionPtr u1 = Teuchos::rcp( new InletBC );
bc->addDirichlet(beta_n_u_hat, lBoundary, -u1);
Teuchos::RCP<Solution> solution = Teuchos::rcp( new Solution(mesh, bc, rhs, ip) );
// ==================== Register Solutions ==========================
mesh->registerSolution(solution);
mesh->registerSolution(prevTimeFlow);
mesh->registerSolution(flowResidual);
// ==================== SET INITIAL GUESS ==========================
double u_free = 0.0;
map<int, Teuchos::RCP<Function> > functionMap;
// functionMap[u->ID()] = Teuchos::rcp( new ConInletBC
functionMap[u->ID()] = Teuchos::rcp( new InletBC );
prevTimeFlow->projectOntoMesh(functionMap);
//////////////////// SOLVE & REFINE ///////////////////////
if (enforceLocalConservation)
{
if (steady)
{
FunctionPtr zero = Teuchos::rcp( new ConstantScalarFunction(0.0) );
solution->lagrangeConstraints()->addConstraint(beta_n_u_hat == zero);
}
else
{
// FunctionPtr parity = Teuchos::rcp<Function>( new SideParityFunction );
// LinearTermPtr conservedQuantity = Teuchos::rcp<LinearTerm>( new LinearTerm(parity, beta_n_u_minus_sigma_n) );
LinearTermPtr conservedQuantity = Teuchos::rcp<LinearTerm>( new LinearTerm(1.0, beta_n_u_hat) );
LinearTermPtr sourcePart = Teuchos::rcp<LinearTerm>( new LinearTerm(invDt, u) );
conservedQuantity->addTerm(sourcePart, true);
solution->lagrangeConstraints()->addConstraint(conservedQuantity == u_prev_time * invDt);
}
}
double energyThreshold = 0.2; // for mesh refinements
RefinementStrategy refinementStrategy( solution, energyThreshold );
VTKExporter exporter(solution, mesh, varFactory);
for (int refIndex=0; refIndex<=numRefs; refIndex++)
{
if (steady)
{
solution->solve(false);
if (commRank == 0)
{
stringstream outfile;
outfile << "Convection_" << refIndex;
exporter.exportSolution(outfile.str());
// Check local conservation
FunctionPtr flux = Teuchos::rcp( new PreviousSolutionFunction(solution, beta_n_u_hat) );
FunctionPtr zero = Teuchos::rcp( new ConstantScalarFunction(0.0) );
Teuchos::Tuple<double, 3> fluxImbalances = checkConservation(flux, zero, varFactory, mesh);
cout << "Mass flux: Largest Local = " << fluxImbalances[0]
<< ", Global = " << fluxImbalances[1] << ", Sum Abs = " << fluxImbalances[2] << endl;
}
}
else
{
int timestepCount = 0;
double time_tol = 1e-8;
double L2_time_residual = 1e9;
// cout << L2_time_residual <<" "<< time_tol << timestepCount << numTimeSteps << endl;
while((L2_time_residual > time_tol) && (timestepCount < numTimeSteps))
{
solution->solve(false);
// Subtract solutions to get residual
flowResidual->setSolution(solution);
flowResidual->addSolution(prevTimeFlow, -1.0);
L2_time_residual = flowResidual->L2NormOfSolutionGlobal(u->ID());
if (commRank == 0)
{
cout << endl << "Timestep: " << timestepCount << ", dt = " << dt << ", Time residual = " << L2_time_residual << endl;
stringstream outfile;
outfile << "TransientConvection_" << refIndex << "-" << timestepCount;
exporter.exportSolution(outfile.str());
// Check local conservation
FunctionPtr flux = Teuchos::rcp( new PreviousSolutionFunction(solution, beta_n_u_hat) );
FunctionPtr source = Teuchos::rcp( new PreviousSolutionFunction(flowResidual, u) );
source = -invDt * source;
Teuchos::Tuple<double, 3> fluxImbalances = checkConservation(flux, source, varFactory, mesh);
cout << "Mass flux: Largest Local = " << fluxImbalances[0]
<< ", Global = " << fluxImbalances[1] << ", Sum Abs = " << fluxImbalances[2] << endl;
}
prevTimeFlow->setSolution(solution); // reset previous time solution to current time sol
timestepCount++;
}
}
if (refIndex < numRefs)
refinementStrategy.refine(commRank==0); // print to console on commRank 0
}
return 0;
}
int main(int argc, char *argv[])
{
#ifdef HAVE_MPI
Teuchos::GlobalMPISession mpiSession(&argc, &argv,0);
choice::MpiArgs args( argc, argv );
#else
choice::Args args( argc, argv );
#endif
int rank = Teuchos::GlobalMPISession::getRank();
int numProcs = Teuchos::GlobalMPISession::getNProc();
int nCells = args.Input<int>("--nCells", "num cells",2);
int numRefs = args.Input<int>("--numRefs","num adaptive refinements",0);
int numPreRefs = args.Input<int>("--numPreRefs","num preemptive adaptive refinements",0);
int order = args.Input<int>("--order","order of approximation",2);
double eps = args.Input<double>("--epsilon","diffusion parameter",1e-2);
double energyThreshold = args.Input<double>("-energyThreshold","energy thresh for adaptivity", .5);
double rampHeight = args.Input<double>("--rampHeight","ramp height at x = 2", 0.0);
bool useAnisotropy = args.Input<bool>("--useAnisotropy","aniso flag ", false);
FunctionPtr zero = Function::constant(0.0);
FunctionPtr one = Function::constant(1.0);
FunctionPtr n = Teuchos::rcp( new UnitNormalFunction );
vector<double> e1,e2;
e1.push_back(1.0);
e1.push_back(0.0);
e2.push_back(0.0);
e2.push_back(1.0);
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactory varFactory;
VarPtr tau = varFactory.testVar("\\tau", HDIV);
VarPtr v = varFactory.testVar("v", HGRAD);
// define trial variables
VarPtr uhat = varFactory.traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory.fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory.fieldVar("u");
VarPtr sigma1 = varFactory.fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory.fieldVar("\\sigma_2");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// tau terms:
confusionBF->addTerm(sigma1 / eps, tau->x());
confusionBF->addTerm(sigma2 / eps, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(uhat, -tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
// first order term with magnitude alpha
double alpha = 0.0;
confusionBF->addTerm(alpha * u, v);
//////////////////// DEFINE INNER PRODUCT(S) ///////////////////////
// robust test norm
IPPtr robIP = Teuchos::rcp(new IP);
FunctionPtr C_h = Teuchos::rcp( new EpsilonScaling(eps) );
FunctionPtr invH = Teuchos::rcp(new InvHScaling);
FunctionPtr invSqrtH = Teuchos::rcp(new InvSqrtHScaling);
FunctionPtr sqrtH = Teuchos::rcp(new SqrtHScaling);
robIP->addTerm(v*alpha);
robIP->addTerm(invSqrtH*v);
// robIP->addTerm(v);
robIP->addTerm(sqrt(eps) * v->grad() );
robIP->addTerm(beta * v->grad() );
robIP->addTerm(tau->div() );
robIP->addTerm(C_h/sqrt(eps) * tau );
LinearTermPtr vVecLT = Teuchos::rcp(new LinearTerm);
LinearTermPtr tauVecLT = Teuchos::rcp(new LinearTerm);
vVecLT->addTerm(sqrt(eps)*v->grad());
tauVecLT->addTerm(C_h/sqrt(eps)*tau);
LinearTermPtr restLT = Teuchos::rcp(new LinearTerm);
restLT->addTerm(alpha*v);
restLT->addTerm(invSqrtH*v);
restLT = restLT + beta * v->grad();
restLT = restLT + tau->div();
//////////////////// SPECIFY RHS ///////////////////////
Teuchos::RCP<RHSEasy> rhs = Teuchos::rcp( new RHSEasy );
FunctionPtr f = zero;
// f = one;
rhs->addTerm( f * v ); // obviously, with f = 0 adding this term is not necessary!
//////////////////// CREATE BCs ///////////////////////
Teuchos::RCP<BCEasy> bc = Teuchos::rcp( new BCEasy );
// SpatialFilterPtr inflowBoundary = Teuchos::rcp( new InflowSquareBoundary );
// SpatialFilterPtr outflowBoundary = Teuchos::rcp( new OutflowSquareBoundary);
// bc->addDirichlet(beta_n_u_minus_sigma_n, inflowBoundary, zero);
// bc->addDirichlet(uhat, outflowBoundary, zero);
SpatialFilterPtr rampInflow = Teuchos::rcp(new LeftInflow);
SpatialFilterPtr rampBoundary = MeshUtilities::rampBoundary(rampHeight);
SpatialFilterPtr freeStream = Teuchos::rcp(new FreeStreamBoundary);
SpatialFilterPtr outflowBoundary = Teuchos::rcp(new OutflowBoundary);
bc->addDirichlet(uhat, rampBoundary, one);
// bc->addDirichlet(uhat, outflowBoundary, one);
bc->addDirichlet(beta_n_u_minus_sigma_n, rampInflow, zero);
bc->addDirichlet(beta_n_u_minus_sigma_n, freeStream, zero);
//////////////////// BUILD MESH ///////////////////////
// define nodes for mesh
int H1Order = order+1;
int pToAdd = 2;
// create a pointer to a new mesh:
// Teuchos::RCP<Mesh> mesh = MeshUtilities::buildUnitQuadMesh(nCells,confusionBF, H1Order, H1Order+pToAdd);
Teuchos::RCP<Mesh> mesh = MeshUtilities::buildRampMesh(rampHeight,confusionBF, H1Order, H1Order+pToAdd);
mesh->setPartitionPolicy(Teuchos::rcp(new ZoltanMeshPartitionPolicy("HSFC")));
//////////////////// SOLVE & REFINE ///////////////////////
Teuchos::RCP<Solution> solution;
solution = Teuchos::rcp( new Solution(mesh, bc, rhs, robIP) );
// solution->solve(false);
solution->condensedSolve();
LinearTermPtr residual = rhs->linearTermCopy();
residual->addTerm(-confusionBF->testFunctional(solution));
RieszRepPtr rieszResidual = Teuchos::rcp(new RieszRep(mesh, robIP, residual));
rieszResidual->computeRieszRep();
FunctionPtr e_v = Teuchos::rcp(new RepFunction(v,rieszResidual));
FunctionPtr e_tau = Teuchos::rcp(new RepFunction(tau,rieszResidual));
map<int,FunctionPtr> errRepMap;
errRepMap[v->ID()] = e_v;
errRepMap[tau->ID()] = e_tau;
FunctionPtr errTau = tauVecLT->evaluate(errRepMap,false);
FunctionPtr errV = vVecLT->evaluate(errRepMap,false);
FunctionPtr errRest = restLT->evaluate(errRepMap,false);
FunctionPtr xErr = (errTau->x())*(errTau->x()) + (errV->dx())*(errV->dx());
FunctionPtr yErr = (errTau->y())*(errTau->y()) + (errV->dy())*(errV->dy());
FunctionPtr restErr = errRest*errRest;
RefinementStrategy refinementStrategy( solution, energyThreshold );
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// PRE REFINEMENTS
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
if (rank==0)
{
cout << "Number of pre-refinements = " << numPreRefs << endl;
}
for (int i =0; i<=numPreRefs; i++)
{
vector<ElementPtr> elems = mesh->activeElements();
vector<ElementPtr>::iterator elemIt;
vector<int> wallCells;
for (elemIt=elems.begin(); elemIt != elems.end(); elemIt++)
{
int cellID = (*elemIt)->cellID();
int numSides = mesh->getElement(cellID)->numSides();
FieldContainer<double> vertices(numSides,2); //for quads
mesh->verticesForCell(vertices, cellID);
bool cellIDset = false;
for (int j = 0; j<numSides; j++)
{
if ((abs(vertices(j,0)-1.0)<1e-7) && (abs(vertices(j,1))<1e-7) && !cellIDset) // if at singularity, i.e. if a vertex is (1,0)
{
wallCells.push_back(cellID);
cellIDset = true;
}
}
}
if (i<numPreRefs)
{
refinementStrategy.refineCells(wallCells);
}
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VTKExporter exporter(solution, mesh, varFactory);
for (int refIndex=0; refIndex<numRefs; refIndex++)
{
if (rank==0)
{
cout << "on ref index " << refIndex << endl;
}
rieszResidual->computeRieszRep(); // in preparation to get anisotropy
vector<int> cellIDs;
refinementStrategy.getCellsAboveErrorThreshhold(cellIDs);
map<int,double> energyError = solution->energyError();
map<int,double> xErrMap = xErr->cellIntegrals(cellIDs,mesh,5,true);
map<int,double> yErrMap = yErr->cellIntegrals(cellIDs,mesh,5,true);
map<int,double> restErrMap = restErr->cellIntegrals(cellIDs,mesh,5,true);
for (vector<ElementPtr>::iterator elemIt = mesh->activeElements().begin(); elemIt!=mesh->activeElements().end(); elemIt++)
{
int cellID = (*elemIt)->cellID();
double err = xErrMap[cellID]+ yErrMap[cellID] + restErrMap[cellID];
if (rank==0)
cout << "err thru LT = " << sqrt(err) << ", while energy err = " << energyError[cellID] << endl;
}
map<int,double> ratio,xErr,yErr;
vector<ElementPtr> elems = mesh->activeElements();
for (vector<ElementPtr>::iterator elemIt = elems.begin(); elemIt!=elems.end(); elemIt++)
{
int cellID = (*elemIt)->cellID();
ratio[cellID] = 0.0;
xErr[cellID] = 0.0;
yErr[cellID] = 0.0;
if (std::find(cellIDs.begin(),cellIDs.end(),cellID)!=cellIDs.end()) // if this cell is above energy thresh
{
ratio[cellID] = yErrMap[cellID]/xErrMap[cellID];
xErr[cellID] = xErrMap[cellID];
yErr[cellID] = yErrMap[cellID];
}
}
FunctionPtr ratioFxn = Teuchos::rcp(new EnergyErrorFunction(ratio));
FunctionPtr xErrFxn = Teuchos::rcp(new EnergyErrorFunction(xErr));
FunctionPtr yErrFxn = Teuchos::rcp(new EnergyErrorFunction(yErr));
std::ostringstream oss;
oss << refIndex;
exporter.exportFunction(ratioFxn, string("ratio")+oss.str());
exporter.exportFunction(xErrFxn, string("xErr")+oss.str());
exporter.exportFunction(yErrFxn, string("yErr")+oss.str());
if (useAnisotropy)
{
refinementStrategy.refine(rank==0,xErrMap,yErrMap); //anisotropic refinements
}
else
{
refinementStrategy.refine(rank==0); // no anisotropy
}
solution->condensedSolve();
}
// final solve on final mesh
solution->condensedSolve();
//////////////////// print to file ///////////////////////
FunctionPtr orderFxn = Teuchos::rcp(new MeshPolyOrderFunction(mesh));
std::ostringstream oss;
oss << nCells;
if (rank==0)
{
exporter.exportSolution(string("robustIP")+oss.str());
exporter.exportFunction(orderFxn, "meshOrder");
cout << endl;
}
return 0;
}
bool LinearTermTests::testRieszInversionAsProjection()
{
bool success = true;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr tau = varFactory->testVar("\\tau", HDIV);
VarPtr v = varFactory->testVar("v", HGRAD);
// define trial variables
VarPtr uhat = varFactory->traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory->fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory->fieldVar("u");
VarPtr sigma1 = varFactory->fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory->fieldVar("\\sigma_2");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
double eps = .01;
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// tau terms:
confusionBF->addTerm(sigma1 / eps, tau->x());
confusionBF->addTerm(sigma2 / eps, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(uhat, -tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
//////////////////// BUILD MESH ///////////////////////
// define nodes for mesh
int H1Order = 2;
int pToAdd = 2;
FieldContainer<double> quadPoints(4,2);
quadPoints(0,0) = 0.0; // x1
quadPoints(0,1) = 0.0; // y1
quadPoints(1,0) = 1.0;
quadPoints(1,1) = 0.0;
quadPoints(2,0) = 1.0;
quadPoints(2,1) = 1.0;
quadPoints(3,0) = 0.0;
quadPoints(3,1) = 1.0;
int nCells = 2;
int horizontalCells = nCells, verticalCells = nCells;
// create a new mesh:
MeshPtr myMesh = MeshFactory::buildQuadMesh(quadPoints, horizontalCells, verticalCells, confusionBF, H1Order, H1Order+pToAdd);
ElementTypePtr elemType = myMesh->getElement(0)->elementType();
BasisCachePtr basisCache = Teuchos::rcp(new BasisCache(elemType, myMesh));
vector<GlobalIndexType> cellIDs = myMesh->cellIDsOfTypeGlobal(elemType);
bool createSideCacheToo = true;
basisCache->setPhysicalCellNodes(myMesh->physicalCellNodesGlobal(elemType), cellIDs, createSideCacheToo);
LinearTermPtr integrand = Teuchos::rcp(new LinearTerm); // residual
FunctionPtr x = Function::xn(1);
FunctionPtr y = Function::yn(1);
FunctionPtr testFxn1 = x;
FunctionPtr testFxn2 = y;
FunctionPtr fxnToProject = x * y + 1.0;
integrand->addTerm(fxnToProject * v);
IPPtr ip_L2 = Teuchos::rcp(new IP);
ip_L2->addTerm(v);
ip_L2->addTerm(tau);
Teuchos::RCP<RieszRep> riesz = Teuchos::rcp(new RieszRep(myMesh, ip_L2, integrand));
riesz->computeRieszRep();
FunctionPtr rieszFxn = RieszRep::repFunction(v,riesz);
int numCells = basisCache->getPhysicalCubaturePoints().dimension(0);
int numPts = basisCache->getPhysicalCubaturePoints().dimension(1);
FieldContainer<double> valProject( numCells, numPts );
FieldContainer<double> valExpected( numCells, numPts );
rieszFxn->values(valProject,basisCache);
fxnToProject->values(valExpected,basisCache);
// int rank = Teuchos::GlobalMPISession::getRank();
// if (rank==0) cout << "physicalCubaturePoints:\n" << basisCache->getPhysicalCubaturePoints();
double maxDiff;
double tol = 1e-12;
success = TestSuite::fcsAgree(valProject,valExpected,tol,maxDiff);
if (success==false)
{
cout << "Failed Riesz Inversion Projection test with maxDiff = " << maxDiff << endl;
serializeOutput("valExpected", valExpected);
serializeOutput("valProject", valProject);
serializeOutput("physicalPoints", basisCache->getPhysicalCubaturePoints());
}
return allSuccess(success);
}
int main(int argc, char *argv[]) {
// Process command line arguments
if (argc > 1)
numRefs = atof(argv[1]);
#ifdef HAVE_MPI
Teuchos::GlobalMPISession mpiSession(&argc, &argv,0);
int rank=mpiSession.getRank();
int numProcs=mpiSession.getNProc();
#else
int rank = 0;
int numProcs = 1;
#endif
FunctionPtr beta = Teuchos::rcp(new Beta());
////////////////////////////////////////////////////////////////////
// DEFINE VARIABLES
////////////////////////////////////////////////////////////////////
// test variables
VarFactory varFactory;
VarPtr tau = varFactory.testVar("\\tau", HDIV);
VarPtr v = varFactory.testVar("v", HGRAD);
// trial variables
VarPtr uhat = varFactory.traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory.fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory.fieldVar("u");
VarPtr sigma1 = varFactory.fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory.fieldVar("\\sigma_2");
////////////////////////////////////////////////////////////////////
// CREATE MESH
////////////////////////////////////////////////////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
FieldContainer<double> meshBoundary(4,2);
meshBoundary(0,0) = 0.0; // x1
meshBoundary(0,1) = -2.0; // y1
meshBoundary(1,0) = 4.0;
meshBoundary(1,1) = -2.0;
meshBoundary(2,0) = 4.0;
meshBoundary(2,1) = 2.0;
meshBoundary(3,0) = 0.0;
meshBoundary(3,1) = 2.0;
int horizontalCells = 4, verticalCells = 4;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> mesh = Mesh::buildQuadMesh(meshBoundary, horizontalCells, verticalCells,
confusionBF, H1Order, H1Order+pToAdd, false);
////////////////////////////////////////////////////////////////////
// INITIALIZE BACKGROUND FLOW FUNCTIONS
////////////////////////////////////////////////////////////////////
BCPtr nullBC = Teuchos::rcp((BC*)NULL);
RHSPtr nullRHS = Teuchos::rcp((RHS*)NULL);
IPPtr nullIP = Teuchos::rcp((IP*)NULL);
SolutionPtr prevTimeFlow = Teuchos::rcp(new Solution(mesh, nullBC, nullRHS, nullIP) );
SolutionPtr flowResidual = Teuchos::rcp(new Solution(mesh, nullBC, nullRHS, nullIP) );
FunctionPtr u_prev_time = Teuchos::rcp( new PreviousSolutionFunction(prevTimeFlow, u) );
// ==================== SET INITIAL GUESS ==========================
double u_free = 0.0;
double sigma1_free = 0.0;
double sigma2_free = 0.0;
map<int, Teuchos::RCP<Function> > functionMap;
functionMap[u->ID()] = Teuchos::rcp( new ConstantScalarFunction(u_free) );
functionMap[sigma1->ID()] = Teuchos::rcp( new ConstantScalarFunction(sigma1_free) );
functionMap[sigma2->ID()] = Teuchos::rcp( new ConstantScalarFunction(sigma2_free) );
prevTimeFlow->projectOntoMesh(functionMap);
// ==================== END SET INITIAL GUESS ==========================
////////////////////////////////////////////////////////////////////
// DEFINE BILINEAR FORM
////////////////////////////////////////////////////////////////////
// tau terms:
confusionBF->addTerm(sigma1 / epsilon, tau->x());
confusionBF->addTerm(sigma2 / epsilon, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(-uhat, tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( beta * u, - v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
////////////////////////////////////////////////////////////////////
// TIMESTEPPING TERMS
////////////////////////////////////////////////////////////////////
Teuchos::RCP<RHSEasy> rhs = Teuchos::rcp( new RHSEasy );
double dt = 0.25;
FunctionPtr invDt = Teuchos::rcp(new ScalarParamFunction(1.0/dt));
if (rank==0){
cout << "Timestep dt = " << dt << endl;
}
if (transient)
{
confusionBF->addTerm( u, invDt*v );
rhs->addTerm( u_prev_time * invDt * v );
}
////////////////////////////////////////////////////////////////////
// DEFINE INNER PRODUCT
////////////////////////////////////////////////////////////////////
// mathematician's norm
IPPtr mathIP = Teuchos::rcp(new IP());
mathIP->addTerm(tau);
mathIP->addTerm(tau->div());
mathIP->addTerm(v);
mathIP->addTerm(v->grad());
// quasi-optimal norm
IPPtr qoptIP = Teuchos::rcp(new IP);
qoptIP->addTerm( v );
qoptIP->addTerm( tau / epsilon + v->grad() );
qoptIP->addTerm( beta * v->grad() - tau->div() );
// robust test norm
IPPtr robIP = Teuchos::rcp(new IP);
FunctionPtr ip_scaling = Teuchos::rcp( new EpsilonScaling(epsilon) );
if (!enforceLocalConservation)
{
robIP->addTerm( ip_scaling * v );
if (transient)
robIP->addTerm( invDt * v );
}
robIP->addTerm( sqrt(epsilon) * v->grad() );
// Weight these two terms for inflow
FunctionPtr ip_weight = Teuchos::rcp( new IPWeight() );
robIP->addTerm( ip_weight * beta * v->grad() );
robIP->addTerm( ip_weight * tau->div() );
robIP->addTerm( ip_scaling/sqrt(epsilon) * tau );
if (enforceLocalConservation)
robIP->addZeroMeanTerm( v );
////////////////////////////////////////////////////////////////////
// DEFINE RHS
////////////////////////////////////////////////////////////////////
FunctionPtr f = Teuchos::rcp( new ConstantScalarFunction(0.0) );
rhs->addTerm( f * v ); // obviously, with f = 0 adding this term is not necessary!
////////////////////////////////////////////////////////////////////
// DEFINE BC
////////////////////////////////////////////////////////////////////
Teuchos::RCP<BCEasy> bc = Teuchos::rcp( new BCEasy );
// Teuchos::RCP<PenaltyConstraints> pc = Teuchos::rcp( new PenaltyConstraints );
SpatialFilterPtr lBoundary = Teuchos::rcp( new LeftBoundary );
SpatialFilterPtr tbBoundary = Teuchos::rcp( new TopBottomBoundary );
SpatialFilterPtr rBoundary = Teuchos::rcp( new RightBoundary );
FunctionPtr u0 = Teuchos::rcp( new ZeroBC );
FunctionPtr u_inlet = Teuchos::rcp( new InletBC );
// FunctionPtr n = Teuchos::rcp( new UnitNormalFunction );
bc->addDirichlet(beta_n_u_minus_sigma_n, lBoundary, u_inlet);
bc->addDirichlet(beta_n_u_minus_sigma_n, tbBoundary, u0);
bc->addDirichlet(uhat, rBoundary, u0);
// pc->addConstraint(beta_n_u_minus_sigma_n - uhat == u0, rBoundary);
////////////////////////////////////////////////////////////////////
// CREATE SOLUTION OBJECT
////////////////////////////////////////////////////////////////////
Teuchos::RCP<Solution> solution = Teuchos::rcp( new Solution(mesh, bc, rhs, robIP) );
// solution->setFilter(pc);
// ==================== Enforce Local Conservation ==================
if (enforceLocalConservation) {
if (transient)
{
FunctionPtr conserved_rhs = u_prev_time * invDt;
LinearTermPtr conserved_quantity = invDt * u;
LinearTermPtr flux_part = Teuchos::rcp(new LinearTerm(-1.0, beta_n_u_minus_sigma_n));
conserved_quantity->addTerm(flux_part, true);
// conserved_quantity = conserved_quantity - beta_n_u_minus_sigma_n;
solution->lagrangeConstraints()->addConstraint(conserved_quantity == conserved_rhs);
}
else
{
FunctionPtr zero = Teuchos::rcp( new ConstantScalarFunction(0.0) );
solution->lagrangeConstraints()->addConstraint(beta_n_u_minus_sigma_n == zero);
}
}
// ==================== Register Solutions ==========================
mesh->registerSolution(solution);
mesh->registerSolution(prevTimeFlow); // u_t(i-1)
mesh->registerSolution(flowResidual); // u_t(i-1)
double energyThreshold = 0.25; // for mesh refinements
Teuchos::RCP<RefinementStrategy> refinementStrategy;
refinementStrategy = Teuchos::rcp(new RefinementStrategy(solution,energyThreshold));
////////////////////////////////////////////////////////////////////
// PSEUDO-TIME SOLVE STRATEGY
////////////////////////////////////////////////////////////////////
double time_tol = 1e-8;
for (int refIndex=0; refIndex<=numRefs; refIndex++)
{
double L2_time_residual = 1e7;
int timestepCount = 0;
if (!transient)
numTimeSteps = 1;
while((L2_time_residual > time_tol) && (timestepCount < numTimeSteps))
{
solution->solve(false);
// subtract solutions to get residual
flowResidual->setSolution(solution); // reset previous time solution to current time sol
flowResidual->addSolution(prevTimeFlow, -1.0);
double L2u = flowResidual->L2NormOfSolutionGlobal(u->ID());
double L2sigma1 = flowResidual->L2NormOfSolutionGlobal(sigma1->ID());
double L2sigma2 = flowResidual->L2NormOfSolutionGlobal(sigma2->ID());
L2_time_residual = sqrt(L2u*L2u + L2sigma1*L2sigma1 + L2sigma2*L2sigma2);
cout << endl << "Timestep: " << timestepCount << ", dt = " << dt << ", Time residual = " << L2_time_residual << endl;
if (rank == 0)
{
stringstream outfile;
if (transient)
outfile << "TransientConfusion_" << refIndex << "_" << timestepCount;
else
outfile << "TransientConfusion_" << refIndex;
solution->writeToVTK(outfile.str(), 5);
}
//////////////////////////////////////////////////////////////////////////
// Check conservation by testing against one
//////////////////////////////////////////////////////////////////////////
VarPtr testOne = varFactory.testVar("1", CONSTANT_SCALAR);
// Create a fake bilinear form for the testing
BFPtr fakeBF = Teuchos::rcp( new BF(varFactory) );
// Define our mass flux
FunctionPtr flux_current_time = Teuchos::rcp( new PreviousSolutionFunction(solution, beta_n_u_minus_sigma_n) );
FunctionPtr delta_u = Teuchos::rcp( new PreviousSolutionFunction(flowResidual, u) );
LinearTermPtr surfaceFlux = -1.0 * flux_current_time * testOne;
LinearTermPtr volumeChange = invDt * delta_u * testOne;
LinearTermPtr massFluxTerm;
if (transient)
{
massFluxTerm = volumeChange;
// massFluxTerm->addTerm(surfaceFlux);
}
else
{
massFluxTerm = surfaceFlux;
}
// cout << "surface case = " << surfaceFlux->summands()[0].first->boundaryValueOnly() << " volume case = " << volumeChange->summands()[0].first->boundaryValueOnly() << endl;
// FunctionPtr massFlux= Teuchos::rcp( new PreviousSolutionFunction(solution, beta_n_u_minus_sigma_n) );
// LinearTermPtr massFluxTerm = massFlux * testOne;
Teuchos::RCP<shards::CellTopology> quadTopoPtr = Teuchos::rcp(new shards::CellTopology(shards::getCellTopologyData<shards::Quadrilateral<4> >() ));
DofOrderingFactory dofOrderingFactory(fakeBF);
int fakeTestOrder = H1Order;
DofOrderingPtr testOrdering = dofOrderingFactory.testOrdering(fakeTestOrder, *quadTopoPtr);
int testOneIndex = testOrdering->getDofIndex(testOne->ID(),0);
vector< ElementTypePtr > elemTypes = mesh->elementTypes(); // global element types
map<int, double> massFluxIntegral; // cellID -> integral
double maxMassFluxIntegral = 0.0;
double totalMassFlux = 0.0;
double totalAbsMassFlux = 0.0;
for (vector< ElementTypePtr >::iterator elemTypeIt = elemTypes.begin(); elemTypeIt != elemTypes.end(); elemTypeIt++)
{
ElementTypePtr elemType = *elemTypeIt;
vector< ElementPtr > elems = mesh->elementsOfTypeGlobal(elemType);
vector<int> cellIDs;
for (int i=0; i<elems.size(); i++) {
cellIDs.push_back(elems[i]->cellID());
}
FieldContainer<double> physicalCellNodes = mesh->physicalCellNodesGlobal(elemType);
BasisCachePtr basisCache = Teuchos::rcp( new BasisCache(elemType,mesh) );
basisCache->setPhysicalCellNodes(physicalCellNodes,cellIDs,true); // true: create side caches
FieldContainer<double> cellMeasures = basisCache->getCellMeasures();
FieldContainer<double> fakeRHSIntegrals(elems.size(),testOrdering->totalDofs());
massFluxTerm->integrate(fakeRHSIntegrals,testOrdering,basisCache,true); // true: force side evaluation
for (int i=0; i<elems.size(); i++) {
int cellID = cellIDs[i];
// pick out the ones for testOne:
massFluxIntegral[cellID] = fakeRHSIntegrals(i,testOneIndex);
}
// find the largest:
for (int i=0; i<elems.size(); i++) {
int cellID = cellIDs[i];
maxMassFluxIntegral = max(abs(massFluxIntegral[cellID]), maxMassFluxIntegral);
}
for (int i=0; i<elems.size(); i++) {
int cellID = cellIDs[i];
maxMassFluxIntegral = max(abs(massFluxIntegral[cellID]), maxMassFluxIntegral);
totalMassFlux += massFluxIntegral[cellID];
totalAbsMassFlux += abs( massFluxIntegral[cellID] );
}
}
// Print results from processor with rank 0
if (rank == 0)
{
cout << "largest mass flux: " << maxMassFluxIntegral << endl;
cout << "total mass flux: " << totalMassFlux << endl;
cout << "sum of mass flux absolute value: " << totalAbsMassFlux << endl;
}
prevTimeFlow->setSolution(solution); // reset previous time solution to current time sol
timestepCount++;
}
if (refIndex < numRefs){
if (rank==0){
cout << "Performing refinement number " << refIndex << endl;
}
refinementStrategy->refine(rank==0);
// RESET solution every refinement - make sure discretization error doesn't creep in
// prevTimeFlow->projectOntoMesh(functionMap);
}
}
return 0;
}
// tests Riesz inversion by integration by parts
bool LinearTermTests::testRieszInversion()
{
bool success = true;
//////////////////// DECLARE VARIABLES ///////////////////////
// define test variables
VarFactoryPtr varFactory = VarFactory::varFactory();
VarPtr tau = varFactory->testVar("\\tau", HDIV);
VarPtr v = varFactory->testVar("v", HGRAD);
// define trial variables
VarPtr uhat = varFactory->traceVar("\\widehat{u}");
VarPtr beta_n_u_minus_sigma_n = varFactory->fluxVar("\\widehat{\\beta \\cdot n u - \\sigma_{n}}");
VarPtr u = varFactory->fieldVar("u");
VarPtr sigma1 = varFactory->fieldVar("\\sigma_1");
VarPtr sigma2 = varFactory->fieldVar("\\sigma_2");
vector<double> beta;
beta.push_back(1.0);
beta.push_back(0.0);
double eps = .01;
//////////////////// DEFINE BILINEAR FORM ///////////////////////
BFPtr confusionBF = Teuchos::rcp( new BF(varFactory) );
// tau terms:
confusionBF->addTerm(sigma1 / eps, tau->x());
confusionBF->addTerm(sigma2 / eps, tau->y());
confusionBF->addTerm(u, tau->div());
confusionBF->addTerm(uhat, -tau->dot_normal());
// v terms:
confusionBF->addTerm( sigma1, v->dx() );
confusionBF->addTerm( sigma2, v->dy() );
confusionBF->addTerm( -u, beta * v->grad() );
confusionBF->addTerm( beta_n_u_minus_sigma_n, v);
//////////////////// BUILD MESH ///////////////////////
// define nodes for mesh
int H1Order = 1;
int pToAdd = 1;
FieldContainer<double> quadPoints(4,2);
quadPoints(0,0) = 0.0; // x1
quadPoints(0,1) = 0.0; // y1
quadPoints(1,0) = 1.0;
quadPoints(1,1) = 0.0;
quadPoints(2,0) = 1.0;
quadPoints(2,1) = 1.0;
quadPoints(3,0) = 0.0;
quadPoints(3,1) = 1.0;
int nCells = 1;
int horizontalCells = nCells, verticalCells = nCells;
// create a pointer to a new mesh:
Teuchos::RCP<Mesh> myMesh = MeshFactory::buildQuadMesh(quadPoints, horizontalCells, verticalCells,
confusionBF, H1Order, H1Order+pToAdd);
ElementTypePtr elemType = myMesh->getElement(0)->elementType();
BasisCachePtr basisCache = Teuchos::rcp(new BasisCache(elemType, myMesh));
vector<GlobalIndexType> cellIDs;
vector<ElementPtr> elems = myMesh->activeElements();
vector<ElementPtr>::iterator elemIt;
for (elemIt=elems.begin(); elemIt!=elems.end(); elemIt++)
{
int cellID = (*elemIt)->cellID();
cellIDs.push_back(cellID);
}
bool createSideCacheToo = true;
basisCache->setPhysicalCellNodes(myMesh->physicalCellNodesGlobal(elemType), cellIDs, createSideCacheToo);
LinearTermPtr integrand = Teuchos::rcp(new LinearTerm);// residual
LinearTermPtr integrandIBP = Teuchos::rcp(new LinearTerm);// residual
vector<double> e1(2); // (1,0)
vector<double> e2(2); // (0,1)
e1[0] = 1;
e2[1] = 1;
FunctionPtr n = Function::normal();
FunctionPtr X = Function::xn(1);
FunctionPtr Y = Function::yn(1);
FunctionPtr testFxn1 = X;
FunctionPtr testFxn2 = Y;
FunctionPtr divTestFxn = testFxn1->dx() + testFxn2->dy();
FunctionPtr vectorTest = testFxn1*e1 + testFxn2*e2;
integrand->addTerm(divTestFxn*v);
integrandIBP->addTerm(vectorTest*n*v - vectorTest*v->grad()); // boundary term
IPPtr sobolevIP = Teuchos::rcp(new IP);
sobolevIP->addTerm(v);
sobolevIP->addTerm(tau);
Teuchos::RCP<RieszRep> riesz = Teuchos::rcp(new RieszRep(myMesh, sobolevIP, integrand));
// riesz->setPrintOption(true);
riesz->computeRieszRep();
Teuchos::RCP<RieszRep> rieszIBP = Teuchos::rcp(new RieszRep(myMesh, sobolevIP, integrandIBP));
riesz->setFunctional(integrandIBP);
// rieszIBP->setPrintOption(true);
rieszIBP->computeRieszRep();
FunctionPtr rieszOrigFxn = RieszRep::repFunction(v,riesz);
FunctionPtr rieszIBPFxn = RieszRep::repFunction(v,rieszIBP);
int numCells = basisCache->getPhysicalCubaturePoints().dimension(0);
int numPts = basisCache->getPhysicalCubaturePoints().dimension(1);
FieldContainer<double> valOriginal( numCells, numPts);
FieldContainer<double> valIBP( numCells, numPts);
rieszOrigFxn->values(valOriginal,basisCache);
rieszIBPFxn->values(valIBP,basisCache);
double maxDiff;
double tol = 1e-14;
success = TestSuite::fcsAgree(valOriginal,valIBP,tol,maxDiff);
if (success==false)
{
cout << "Failed TestRieszInversion with maxDiff = " << maxDiff << endl;
}
return success;
}
virtual void localStiffnessMatrixAndRHS(FieldContainer<double> &localStiffness, FieldContainer<double> &rhsVector,
IPPtr ip, BasisCachePtr ipBasisCache,
RHSPtr rhs, BasisCachePtr basisCache) {
double testMatrixAssemblyTime = 0, testMatrixInversionTime = 0, localStiffnessDeterminationFromTestsTime = 0;
#ifdef HAVE_MPI
Epetra_MpiComm Comm(MPI_COMM_WORLD);
//cout << "rank: " << rank << " of " << numProcs << endl;
#else
Epetra_SerialComm Comm;
#endif
Epetra_Time timer(Comm);
// localStiffness should have dim. (numCells, numTrialFields, numTrialFields)
MeshPtr mesh = basisCache->mesh();
if (mesh.get() == NULL) {
cout << "localStiffnessMatrix requires BasisCache to have mesh set.\n";
TEUCHOS_TEST_FOR_EXCEPTION(true, std::invalid_argument, "localStiffnessMatrix requires BasisCache to have mesh set.");
}
const vector<GlobalIndexType>* cellIDs = &basisCache->cellIDs();
int numCells = cellIDs->size();
if (numCells != localStiffness.dimension(0)) {
cout << "localStiffnessMatrix requires basisCache->cellIDs() to have the same # of cells as the first dimension of localStiffness\n";
TEUCHOS_TEST_FOR_EXCEPTION(true, std::invalid_argument, "localStiffnessMatrix requires basisCache->cellIDs() to have the same # of cells as the first dimension of localStiffness");
}
ElementTypePtr elemType = mesh->getElementType((*cellIDs)[0]); // we assume all cells provided are of the same type
DofOrderingPtr trialOrder = elemType->trialOrderPtr;
DofOrderingPtr fieldOrder = mesh->getDofOrderingFactory().getFieldOrdering(trialOrder);
DofOrderingPtr traceOrder = mesh->getDofOrderingFactory().getTraceOrdering(trialOrder);
map<int, int> stiffnessIndexForTraceIndex;
map<int, int> stiffnessIndexForFieldIndex;
set<int> varIDs = trialOrder->getVarIDs();
for (set<int>::iterator varIt = varIDs.begin(); varIt != varIDs.end(); varIt++) {
int varID = *varIt;
const vector<int>* sidesForVar = &trialOrder->getSidesForVarID(varID);
bool isTrace = (sidesForVar->size() > 1);
for (vector<int>::const_iterator sideIt = sidesForVar->begin(); sideIt != sidesForVar->end(); sideIt++) {
int sideOrdinal = *sideIt;
vector<int> dofIndices = trialOrder->getDofIndices(varID,sideOrdinal);
if (isTrace) {
vector<int> traceDofIndices = traceOrder->getDofIndices(varID,sideOrdinal);
for (int i=0; i<traceDofIndices.size(); i++) {
stiffnessIndexForTraceIndex[traceDofIndices[i]] = dofIndices[i];
}
} else {
vector<int> fieldDofIndices = fieldOrder->getDofIndices(varID);
for (int i=0; i<fieldDofIndices.size(); i++) {
stiffnessIndexForFieldIndex[fieldDofIndices[i]] = dofIndices[i];
}
}
}
}
int numTrialDofs = trialOrder->totalDofs();
if ((numTrialDofs != localStiffness.dimension(1)) || (numTrialDofs != localStiffness.dimension(2))) {
cout << "localStiffness should have dimensions (C,numTrialFields,numTrialFields).\n";
TEUCHOS_TEST_FOR_EXCEPTION(true, std::invalid_argument, "localStiffness should have dimensions (C,numTrialFields,numTrialFields).");
}
map<int,int> traceTestMap, fieldTestMap;
int numEquations = _virtualTerms.getFieldTestVars().size();
for (int eqn=0; eqn<numEquations; eqn++) {
VarPtr testVar = _virtualTerms.getFieldTestVars()[eqn];
VarPtr traceVar = _virtualTerms.getAssociatedTrace(testVar);
VarPtr fieldVar = _virtualTerms.getAssociatedField(testVar);
traceTestMap[traceVar->ID()] = testVar->ID();
fieldTestMap[fieldVar->ID()] = testVar->ID();
}
int maxDegreeField = fieldOrder->maxBasisDegree();
int testDegreeInterior = maxDegreeField + _virtualTerms.getTestEnrichment();
int testDegreeTrace = testDegreeInterior + 2;
cout << "ERROR in Virtual: getRelabeledDofOrdering() is commented out in DofOrderingFactory. Need to rewrite for the new caching scheme.\n";
DofOrderingPtr testOrderInterior; // = mesh->getDofOrderingFactory().getRelabeledDofOrdering(fieldOrder, fieldTestMap);
testOrderInterior = mesh->getDofOrderingFactory().setBasisDegree(testOrderInterior, testDegreeInterior, false);
DofOrderingPtr testOrderTrace = mesh->getDofOrderingFactory().setBasisDegree(testOrderInterior, testDegreeTrace, true); // this has a bunch of extra dofs (interior guys)
map<int, int> remappedTraceIndices; // go from the index that includes the interior dofs to one that doesn't
set<int> testIDs = testOrderTrace->getVarIDs();
int testTraceIndex = 0;
for (set<int>::iterator testIDIt = testIDs.begin(); testIDIt != testIDs.end(); testIDIt++) {
int testID = *testIDIt;
BasisPtr basis = testOrderTrace->getBasis(testID);
vector<int> interiorDofs = basis->dofOrdinalsForInterior();
for (int basisOrdinal=0; basisOrdinal<basis->getCardinality(); basisOrdinal++) {
if (std::find(interiorDofs.begin(),interiorDofs.end(),basisOrdinal) == interiorDofs.end()) {
int dofIndex = testOrderTrace->getDofIndex(testID, basisOrdinal);
remappedTraceIndices[dofIndex] = testTraceIndex;
testTraceIndex++;
}
}
}
// DofOrderingPtr testOrderTrace = mesh->getDofOrderingFactory().getRelabeledDofOrdering(traceOrder, traceTestMap);
// testOrderTrace = mesh->getDofOrderingFactory().setBasisDegree(testOrderTrace, testDegreeTrace);
int numTestInteriorDofs = testOrderInterior->totalDofs();
int numTestTraceDofsIncludingInterior = testOrderTrace->totalDofs();
int numTestTraceDofs = testTraceIndex;
int numTestDofs = numTestTraceDofs + numTestInteriorDofs;
timer.ResetStartTime();
bool printTimings = true;
if (printTimings) {
cout << "numCells: " << numCells << endl;
cout << "numTestDofs: " << numTestDofs << endl;
}
FieldContainer<double> rhsVectorTest(numCells,testOrderInterior->totalDofs()); // rhsVector is zero for the "trace" test dofs
{
// project the load f onto the space of interior test dofs.
LinearTermPtr f = rhs->linearTerm();
set<int> testIDs = f->varIDs();
for (int eqn=0; eqn<numEquations; eqn++) {
VarPtr v = _virtualTerms.getFieldTestVars()[eqn];
if (testIDs.find(v->ID()) != testIDs.end()) {
BasisPtr testInteriorBasis = testOrderInterior->getBasis(v->ID());
FieldContainer<double> fValues(numCells,testInteriorBasis->getCardinality());
// DofOrderingPtr oneVarOrderingTest = Teuchos::rcp(new DofOrdering(testInteriorBasis->domainTopology()));
DofOrderingPtr oneVarOrderingTest = Teuchos::rcp(new DofOrdering);
oneVarOrderingTest->addEntry(v->ID(), testInteriorBasis, testInteriorBasis->rangeRank());
LinearTermPtr f_v = Teuchos::rcp( new LinearTerm );
typedef pair< FunctionPtr, VarPtr > LinearSummand;
vector<LinearSummand> summands = f->summands();
for (int i=0; i<summands.size(); i++) {
FunctionPtr f = summands[i].first;
if (v->ID() == summands[i].second->ID()) {
f_v->addTerm(f * v);
f_v->integrate(fValues, oneVarOrderingTest, basisCache);
}
}
LinearTermPtr v_lt = 1.0 * v;
FieldContainer<double> l2(numCells,testInteriorBasis->getCardinality(),testInteriorBasis->getCardinality());
v_lt->integrate(l2,oneVarOrderingTest,v_lt,oneVarOrderingTest,basisCache,basisCache->isSideCache());
Teuchos::Array<int> testTestDim(2), testOneDim(2);
testTestDim[0] = testInteriorBasis->getCardinality();
testTestDim[1] = testInteriorBasis->getCardinality();
testOneDim[0] = testInteriorBasis->getCardinality();
testOneDim[1] = 1;
FieldContainer<double> projection(testOneDim);
for (int cellOrdinal=0; cellOrdinal<numCells; cellOrdinal++) {
FieldContainer<double> l2cell(testTestDim,&l2(cellOrdinal,0,0));
FieldContainer<double> f_cell(testOneDim,&fValues(cellOrdinal,0));
SerialDenseWrapper::solveSystemUsingQR(projection, l2cell, f_cell);
// rows in projection correspond to Ae_i, columns to the e_j. I.e. projection coefficients for e_i are found in the ith row
for (int basisOrdinal_j=0; basisOrdinal_j<projection.dimension(0); basisOrdinal_j++) {
int testIndex = testOrderInterior->getDofIndex(v->ID(), basisOrdinal_j);
rhsVectorTest(cellOrdinal,testIndex) = projection(basisOrdinal_j,0);
}
}
}
}
}
// project strong operator applied to field terms, and use this to populate the top left portion of stiffness matrix:
{
FieldContainer<double> trialFieldTestInterior(numCells, fieldOrder->totalDofs(), testOrderInterior->totalDofs());
for (int eqn=0; eqn<numEquations; eqn++) {
LinearTermPtr Au = _virtualTerms.getFieldOperators()[eqn];
VarPtr v = _virtualTerms.getFieldTestVars()[eqn];
set<int> fieldIDs = Au->varIDs();
for (set<int>::iterator fieldIt = fieldIDs.begin(); fieldIt != fieldIDs.end(); fieldIt++) {
int fieldID = *fieldIt;
// int testID = fieldTestMap[fieldID];
//
// LinearTermPtr testInteriorVar = 1.0 * this->varFactory().test(testID);
BasisPtr vBasis = testOrderInterior->getBasis(v->ID());
BasisPtr fieldTrialBasis = fieldOrder->getBasis(fieldID);
// DofOrderingPtr oneVarOrderingTest = Teuchos::rcp(new DofOrdering(vBasis->domainTopology()));
DofOrderingPtr oneVarOrderingTest = Teuchos::rcp(new DofOrdering());
oneVarOrderingTest->addEntry(v->ID(), vBasis, vBasis->rangeRank());
FieldContainer<double> Au_values(numCells,vBasis->getCardinality(),fieldTrialBasis->getCardinality());
FieldContainer<double> l2(numCells,vBasis->getCardinality(),vBasis->getCardinality());
DofOrderingPtr oneVarOrderingTrial = Teuchos::rcp(new DofOrdering());
// DofOrderingPtr oneVarOrderingTrial = Teuchos::rcp(new DofOrdering(fieldTrialBasis->domainTopology()));
oneVarOrderingTrial->addEntry(fieldID, fieldTrialBasis, fieldTrialBasis->rangeRank());
LinearTermPtr Au_restricted_to_field = Teuchos::rcp( new LinearTerm );
typedef pair< FunctionPtr, VarPtr > LinearSummand;
vector<LinearSummand> summands = Au->summands();
for (int i=0; i<summands.size(); i++) {
FunctionPtr f = summands[i].first;
VarPtr v = summands[i].second;
if (v->ID() == fieldID) {
Au_restricted_to_field->addTerm(f * v);
}
}
LinearTermPtr v_lt = 1.0 * v;
Au_restricted_to_field->integrate(Au_values,oneVarOrderingTrial,v_lt,oneVarOrderingTest,basisCache,basisCache->isSideCache());
v_lt->integrate(l2,oneVarOrderingTest,v_lt,oneVarOrderingTest,basisCache,basisCache->isSideCache());
double maxValue = 0;
for (int i=0; i<l2.size(); i++) {
maxValue = max(abs(l2[i]),maxValue);
}
cout << "maxValue in l2 is " << maxValue << endl;
Teuchos::Array<int> testTestDim(2), trialTestDim(2);
testTestDim[0] = vBasis->getCardinality();
testTestDim[1] = vBasis->getCardinality();
trialTestDim[0] = vBasis->getCardinality();
trialTestDim[1] = fieldTrialBasis->getCardinality();
FieldContainer<double> projection(trialTestDim);
for (int cellOrdinal=0; cellOrdinal<numCells; cellOrdinal++) {
FieldContainer<double> l2cell(testTestDim,&l2(cellOrdinal,0,0));
FieldContainer<double> AuCell(trialTestDim,&Au_values(cellOrdinal,0,0));
// TODO: confirm that I'm doing the right projection here. I could be missing a key point, but it seems to me that we must
// project onto an *orthonormal* basis here, to achieve the required identity structure of the (field,field) part of the
// Gram matrix. OTOH, it looks to me like the computation here achieves exactly that, even though I didn't initially
// have that in mind...
// SerialDenseWrapper::solveSystemUsingQR(projection, l2cell, AuCell);
SerialDenseWrapper::solveSystemMultipleRHS(projection, l2cell, AuCell);
// rows in projection correspond to Ae_i, columns to the e_j. I.e. projection coefficients for e_i are found in the ith row
for (int basisOrdinal_i=0; basisOrdinal_i<projection.dimension(0); basisOrdinal_i++) {
int testIndex = testOrderInterior->getDofIndex(v->ID(), basisOrdinal_i);
for (int basisOrdinal_j=0; basisOrdinal_j<projection.dimension(1); basisOrdinal_j++) {
int trialIndex = fieldOrder->getDofIndex(fieldID, basisOrdinal_j); // in the *trial* space
trialFieldTestInterior(cellOrdinal,trialIndex,testIndex) = projection(basisOrdinal_i,basisOrdinal_j);
}
}
}
}
}
Teuchos::Array<int> trialTestDim(2);
trialTestDim[0] = fieldOrder->totalDofs();
trialTestDim[1] = testOrderInterior->totalDofs();
for (int cellOrdinal=0; cellOrdinal<numCells; cellOrdinal++) {
FieldContainer<double> trialFieldTrialField(fieldOrder->totalDofs(), fieldOrder->totalDofs());
FieldContainer<double> trialTestCell(trialTestDim, &trialFieldTestInterior(cellOrdinal,0,0));
SerialDenseWrapper::multiply(trialFieldTrialField, trialTestCell, trialTestCell, 'N', 'T'); // transpose the second one
// now, accumulate into localStiffness
for (int i=0; i<trialFieldTrialField.dimension(0); i++) {
int stiff_i = stiffnessIndexForFieldIndex[i];
for (int j=0; j<trialFieldTrialField.dimension(1); j++) {
int stiff_j = stiffnessIndexForFieldIndex[j];
localStiffness(cellOrdinal,stiff_i,stiff_j) = trialFieldTrialField(i,j);
}
}
}
// multiply RHS integrated against the interior test space by the trialFieldTestInterior
for (int cellOrdinal=0; cellOrdinal<numCells; cellOrdinal++) {
Teuchos::Array<int> trialTestDim(2), oneTestDim(2);
trialTestDim[0] = fieldOrder->totalDofs();
trialTestDim[1] = testOrderInterior->totalDofs();
oneTestDim[0] = 1;
oneTestDim[1] = testOrderInterior->totalDofs();
FieldContainer<double> trialTestCell(trialTestDim, &trialFieldTestInterior(cellOrdinal,0,0));
FieldContainer<double> rhsTestCell(oneTestDim, &rhsVectorTest(cellOrdinal,0));
FieldContainer<double> rhsTrialCell(1, fieldOrder->totalDofs());
SerialDenseWrapper::multiply(rhsTrialCell, rhsTestCell, trialTestCell, 'N', 'T');
for (int fieldIndex=0; fieldIndex<fieldOrder->totalDofs(); fieldIndex++) {
int stiffIndex = stiffnessIndexForFieldIndex[fieldIndex];
rhsVector(cellOrdinal,stiffIndex) = rhsTrialCell(0, fieldIndex);
}
}
}
FieldContainer<double> ipMatrixTraceIncludingInterior(numCells,numTestTraceDofsIncludingInterior,numTestTraceDofsIncludingInterior);
int numTestTerms = _virtualTerms.getTestNormOperators().size();
for (int i=0; i<numTestTerms; i++) {
LinearTermPtr testTerm = _virtualTerms.getTestNormOperators()[i];
LinearTermPtr boundaryTerm = _virtualTerms.getTestNormBoundaryOperators()[i];
testTerm->integrate(ipMatrixTraceIncludingInterior,testOrderTrace,boundaryTerm,testOrderTrace,ipBasisCache,ipBasisCache->isSideCache());
}
FieldContainer<double> ipMatrixTrace(numCells,numTestTraceDofs,numTestTraceDofs);
for (int cellOrdinal=0; cellOrdinal<numCells; cellOrdinal++) {
for (int i_dofIndex=0; i_dofIndex<numTestTraceDofsIncludingInterior; i_dofIndex++) {
if (remappedTraceIndices.find(i_dofIndex) == remappedTraceIndices.end()) {
continue;
}
int i_remapped = remappedTraceIndices[i_dofIndex];
for (int j_dofIndex=0; j_dofIndex<numTestTraceDofsIncludingInterior; j_dofIndex++) {
if (remappedTraceIndices.find(j_dofIndex) == remappedTraceIndices.end()) {
continue;
}
int j_remapped = remappedTraceIndices[j_dofIndex];
ipMatrixTrace(cellOrdinal,i_remapped,j_remapped) = ipMatrixTraceIncludingInterior(cellOrdinal,i_dofIndex,j_dofIndex);
}
}
}
testMatrixAssemblyTime += timer.ElapsedTime();
// cout << "ipMatrix:\n" << ipMatrix;
timer.ResetStartTime();
cout << "NOTE: we do not yet enforce continuity on the trace test space.\n"; // I *think* this is fine, but I'm not dead certain -- we do of course in the end enforce continuity in GDAMinimumRule
// now, determine the trace part of the bilinear form matrix
FieldContainer<double> bfMatrixTraceTraceIncludingTestInterior(numCells,testOrderTrace->totalDofs(),traceOrder->totalDofs());
FieldContainer<double> bfMatrixFieldTraceIncludingTestInterior(numCells,testOrderTrace->totalDofs(),fieldOrder->totalDofs());
for (int eqn=0; eqn<numEquations; eqn++) {
VarPtr traceVar = _virtualTerms.getTraceVars()[eqn];
LinearTermPtr termTraced = traceVar->termTraced();
LinearTermPtr strongOperator = _virtualTerms.getFieldOperators()[eqn];
VarPtr testVar = _virtualTerms.getFieldTestVars()[eqn];
// want to determine \hat{C}(\hat{e}_i, \phi_j) for \phi_j with support on the boundary
// the \phi_j's with support on the boundary are the ones associated with the trace
LinearTermPtr trialTerm = 1.0 * traceVar;
LinearTermPtr testTerm;
if (traceVar->varType() == TRACE) {
testTerm = Function::normal() * testVar;
} else {
testTerm = 1.0 * testVar;
}
// trialTerm->integrate(bfMatrixTrace,traceOrder,testTerm,testOrderTrace,basisCache,basisCache->isSideCache());
trialTerm->integrate(bfMatrixTraceTraceIncludingTestInterior,traceOrder,testTerm,testOrderTrace,basisCache,basisCache->isSideCache());
termTraced->integrate(bfMatrixFieldTraceIncludingTestInterior,fieldOrder,-testTerm,testOrderTrace,basisCache,basisCache->isSideCache());
}
FieldContainer<double> bfMatrixFieldTrace(numCells,numTestTraceDofs,bfMatrixFieldTraceIncludingTestInterior.dimension(2));
FieldContainer<double> bfMatrixTraceTrace(numCells,numTestTraceDofs,bfMatrixTraceTraceIncludingTestInterior.dimension(2));
for (int cellOrdinal=0; cellOrdinal<numCells; cellOrdinal++) {
for (int i_dofIndex=0; i_dofIndex<numTestTraceDofsIncludingInterior; i_dofIndex++) {
if (remappedTraceIndices.find(i_dofIndex) == remappedTraceIndices.end()) {
continue;
}
int i_remapped = remappedTraceIndices[i_dofIndex];
for (int j_dofIndex=0; j_dofIndex<bfMatrixFieldTrace.dimension(2); j_dofIndex++) {
bfMatrixFieldTrace(cellOrdinal,i_remapped,j_dofIndex) = bfMatrixFieldTraceIncludingTestInterior(cellOrdinal,i_dofIndex,j_dofIndex);
}
for (int j_dofIndex=0; j_dofIndex<bfMatrixTraceTrace.dimension(2); j_dofIndex++) {
bfMatrixTraceTrace(cellOrdinal,i_remapped,j_dofIndex) = bfMatrixTraceTraceIncludingTestInterior(cellOrdinal,i_dofIndex,j_dofIndex);
}
}
}
Teuchos::Array<int> ipMatrixDim(2), bfMatrixTraceTraceDim(2), bfMatrixFieldTraceDim(2);
Teuchos::Array<int> traceTraceStiffDim(2), fieldTraceStiffDim(2), fieldFieldStiffDim(2);
ipMatrixDim[0] = ipMatrixTrace.dimension(1);
ipMatrixDim[1] = ipMatrixTrace.dimension(2);
bfMatrixTraceTraceDim[0] = bfMatrixTraceTrace.dimension(1);
bfMatrixTraceTraceDim[1] = bfMatrixTraceTrace.dimension(2);
bfMatrixFieldTraceDim[0] = bfMatrixFieldTrace.dimension(1);
bfMatrixFieldTraceDim[1] = bfMatrixFieldTrace.dimension(2);
traceTraceStiffDim[0] = traceOrder->totalDofs();
traceTraceStiffDim[1] = traceTraceStiffDim[0];
fieldTraceStiffDim[0] = fieldOrder->totalDofs();
fieldTraceStiffDim[1] = traceOrder->totalDofs(); // rectangular
fieldFieldStiffDim[0] = fieldOrder->totalDofs();
fieldFieldStiffDim[1] = fieldOrder->totalDofs();
FieldContainer<double> traceTraceStiffCell(traceTraceStiffDim);
FieldContainer<double> fieldTraceStiffCell(fieldTraceStiffDim);
FieldContainer<double> fieldFieldStiffCell(fieldFieldStiffDim);
for (int cellOrdinal=0; cellOrdinal<numCells; cellOrdinal++) {
FieldContainer<double> ipMatrixCell(ipMatrixDim,&ipMatrixTrace(cellOrdinal,0,0));
FieldContainer<double> optTestCoeffsTraceTrace(numTestTraceDofs,traceOrder->totalDofs());
FieldContainer<double> bfMatrixTraceTraceCell(bfMatrixTraceTraceDim,&bfMatrixTraceTrace(cellOrdinal,0,0));
int result = SerialDenseWrapper::solveSystemUsingQR(optTestCoeffsTraceTrace, ipMatrixCell, bfMatrixTraceTraceCell);
SerialDenseWrapper::multiply(traceTraceStiffCell, bfMatrixTraceTraceCell, optTestCoeffsTraceTrace, 'T', 'N');
// copy into the appropriate spot in localStiffness:
for (int i=0; i<traceTraceStiffDim[0]; i++) {
int i_stiff = stiffnessIndexForTraceIndex[i];
for (int j=0; j<traceTraceStiffDim[1]; j++) {
int j_stiff = stiffnessIndexForTraceIndex[j];
localStiffness(cellOrdinal,i_stiff,j_stiff) = traceTraceStiffCell(i,j);
}
}
// because of the way the matrix blocks line up, we actually don't have to do a second inversion of ipMatrixCell for this part
FieldContainer<double> bfMatrixFieldTraceCell(bfMatrixFieldTraceDim,&bfMatrixFieldTrace(cellOrdinal,0,0));
SerialDenseWrapper::multiply(fieldTraceStiffCell, bfMatrixFieldTraceCell, optTestCoeffsTraceTrace, 'T', 'N');
// copy into the appropriate spots in localStiffness (taking advantage of symmetry):
for (int i=0; i<fieldTraceStiffDim[0]; i++) {
int i_stiff = stiffnessIndexForFieldIndex[i];
for (int j=0; j<fieldTraceStiffDim[1]; j++) {
int j_stiff = stiffnessIndexForTraceIndex[j];
localStiffness(cellOrdinal,i_stiff,j_stiff) = fieldTraceStiffCell(i,j);
localStiffness(cellOrdinal,j_stiff,i_stiff) = fieldTraceStiffCell(i,j);
}
}
// because of the way the matrix blocks line up, we do have some trace contributions in the (field, field) portion of the matrix
// these get added to the field contributions (hence the +=)
FieldContainer<double> optTestCoeffsFieldTrace(numTestTraceDofs,fieldOrder->totalDofs());
result = SerialDenseWrapper::solveSystemUsingQR(optTestCoeffsFieldTrace, ipMatrixCell, bfMatrixFieldTraceCell);
SerialDenseWrapper::multiply(fieldFieldStiffCell, bfMatrixFieldTraceCell, optTestCoeffsFieldTrace, 'T', 'N');
for (int i=0; i<fieldFieldStiffDim[0]; i++) {
int i_stiff = stiffnessIndexForFieldIndex[i];
for (int j=0; j<fieldFieldStiffDim[1]; j++) {
int j_stiff = stiffnessIndexForFieldIndex[j];
localStiffness(cellOrdinal,i_stiff,j_stiff) += fieldFieldStiffCell(i,j);
}
}
}
testMatrixInversionTime += timer.ElapsedTime();
// cout << "optTestCoeffs:\n" << optTestCoeffs;
if (printTimings) {
cout << "testMatrixAssemblyTime: " << testMatrixAssemblyTime << " seconds.\n";
cout << "testMatrixInversionTime: " << testMatrixInversionTime << " seconds.\n";
cout << "localStiffnessDeterminationFromTestsTime: " << localStiffnessDeterminationFromTestsTime << " seconds.\n";
}
}
