docs/release_2017.1/CardiacElectroMechanicsProblem_8cpp_source.html

 /*

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 */

 #include "CardiacElectroMechanicsProblem.hpp"

 #include "OutputFileHandler.hpp"
 #include "ReplicatableVector.hpp"
 #include "HeartConfig.hpp"
 #include "LogFile.hpp"
 #include "ChastePoint.hpp"
 #include "Element.hpp"
 #include "BoundaryConditionsContainer.hpp"
 #include "AbstractDynamicLinearPdeSolver.hpp"
 #include "TimeStepper.hpp"
 #include "TrianglesMeshWriter.hpp"
 #include "Hdf5ToMeshalyzerConverter.hpp"
 #include "Hdf5ToCmguiConverter.hpp"
 #include "MeshalyzerMeshWriter.hpp"
 #include "PetscTools.hpp"
 #include "ImplicitCardiacMechanicsSolver.hpp"
 #include "ExplicitCardiacMechanicsSolver.hpp"
 #include "CmguiDeformedSolutionsWriter.hpp"
 #include "VoltageInterpolaterOntoMechanicsMesh.hpp"
 #include "BidomainProblem.hpp"


 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 void CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::DetermineWatchedNodes()
 {
     assert(mIsWatchedLocation);

     // find the nearest electrics mesh node
     double min_dist = DBL_MAX;
     unsigned node_index = UNSIGNED_UNSET;
     for (unsigned i=0; i<mpElectricsMesh->GetNumNodes(); i++)
     {
         double dist = norm_2(mWatchedLocation - mpElectricsMesh->GetNode(i)->rGetLocation());
         if (dist < min_dist)
         {
             min_dist = dist;
             node_index = i;
         }
     }

     // set up watched node, if close enough
     assert(node_index != UNSIGNED_UNSET); // should def have found something
     c_vector<double,DIM> pos = mpElectricsMesh->GetNode(node_index)->rGetLocation();

     if (min_dist > 1e-8)
     {
         // LCOV_EXCL_START
         std::cout << "ERROR: Could not find an electrics node very close to requested watched location - "
                   << "min distance was " << min_dist << " for node " << node_index
                   << " at location " << pos << std::flush;;

         //EXCEPTION("Could not find an electrics node very close to requested watched location");
         NEVER_REACHED;
         // LCOV_EXCL_STOP
     }
     else
     {
         LOG(2,"Chosen electrics node "<<node_index<<" at location " << pos << " to be watched");
         mWatchedElectricsNodeIndex = node_index;
     }

     // find nearest mechanics mesh
     min_dist = DBL_MAX;
     node_index = UNSIGNED_UNSET;
     c_vector<double,DIM> pos_at_min;

     for (unsigned i=0; i<mpMechanicsMesh->GetNumNodes(); i++)
     {
         c_vector<double,DIM> position = mpMechanicsMesh->GetNode(i)->rGetLocation();

         double dist = norm_2(position-mWatchedLocation);

         if (dist < min_dist)
         {
             min_dist = dist;
             node_index = i;
             pos_at_min = position;
         }
     }

     // set up watched node, if close enough
     assert(node_index != UNSIGNED_UNSET); // should def have found something

     if (min_dist > 1e-8)
     {
         // LCOV_EXCL_START
         std::cout << "ERROR: Could not find a mechanics node very close to requested watched location - "
                   << "min distance was " << min_dist << " for node " << node_index
                   << " at location " << pos_at_min;

         //EXCEPTION("Could not find a mechanics node very close to requested watched location");
         NEVER_REACHED;
         // LCOV_EXCL_STOP
     }
     else
     {
         LOG(2,"Chosen mechanics node "<<node_index<<" at location " << pos << " to be watched");
         mWatchedMechanicsNodeIndex = node_index;
     }

     OutputFileHandler handler(mOutputDirectory,false);
     mpWatchedLocationFile = handler.OpenOutputFile("watched.txt");
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 void CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::WriteWatchedLocationData(double time, Vec voltage)
 {
     assert(mIsWatchedLocation);

     std::vector<c_vector<double,DIM> >& deformed_position = mpMechanicsSolver->rGetDeformedPosition();

     ReplicatableVector voltage_replicated(voltage);
     double V = voltage_replicated[mWatchedElectricsNodeIndex];

     //     // Metadata is currently being added to CellML models and then this will be avoided by asking for Calcium.
     //    double Ca = mpElectricsProblem->GetMonodomainTissue()->GetCardiacCell(mWatchedElectricsNodeIndex)->GetIntracellularCalciumConcentration();

     *mpWatchedLocationFile << time << " ";
     for (unsigned i=0; i<DIM; i++)
     {
         *mpWatchedLocationFile << deformed_position[mWatchedMechanicsNodeIndex](i) << " ";
     }
     *mpWatchedLocationFile << V << "\n";
     mpWatchedLocationFile->flush();
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 c_matrix<double,DIM,DIM>& CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::rCalculateModifiedConductivityTensor(unsigned elementIndex, const c_matrix<double,DIM,DIM>& rOriginalConductivity, unsigned domainIndex)
 {

     // first get the deformation gradient for this electrics element
     unsigned containing_mechanics_elem = mpMeshPair->rGetCoarseElementsForFineElementCentroids()[elementIndex];
     c_matrix<double,DIM,DIM>& r_deformation_gradient = mDeformationGradientsForEachMechanicsElement[containing_mechanics_elem];

     // compute sigma_def = F^{-1} sigma_undef F^{-T}
     c_matrix<double,DIM,DIM> inv_F = Inverse(r_deformation_gradient);
     mModifiedConductivityTensor = prod(inv_F, rOriginalConductivity);
     mModifiedConductivityTensor = prod(mModifiedConductivityTensor, trans(inv_F));

     return mModifiedConductivityTensor;
 }


 template<unsigned DIM, unsigned PROBLEM_DIM>
 class CreateElectricsProblem
 {
 public:
     static AbstractCardiacProblem<DIM, DIM, PROBLEM_DIM>* Create(ElectricsProblemType problemType,
                                                                  AbstractCardiacCellFactory<DIM>* pCellFactory);
 };

 template<unsigned DIM>
 class CreateElectricsProblem<DIM, 1u>
 {
 public:
     static AbstractCardiacProblem<DIM, DIM, 1u>* Create(ElectricsProblemType problemType,
                                                         AbstractCardiacCellFactory<DIM>* pCellFactory)
     {
         if (problemType == MONODOMAIN)
         {
             return new MonodomainProblem<DIM>(pCellFactory);
         }
         EXCEPTION("The second template parameter should be 2 when a bidomain problem is chosen");
     }
 };

 template<unsigned DIM>
 class CreateElectricsProblem<DIM, 2u>
 {
 public:
     static AbstractCardiacProblem<DIM, DIM, 2u>* Create(ElectricsProblemType problemType,
                                                         AbstractCardiacCellFactory<DIM>* pCellFactory)
     {
         if (problemType == BIDOMAIN)
         {
             return new BidomainProblem<DIM>(pCellFactory, false);//false-> no bath
         }
         if (problemType == BIDOMAIN_WITH_BATH)
         {
             return new BidomainProblem<DIM>(pCellFactory, true);// true-> bath
         }
         EXCEPTION("The second template parameter should be 1 when a monodomain problem is chosen");
     }
 };


 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::CardiacElectroMechanicsProblem(
             CompressibilityType compressibilityType,
             ElectricsProblemType electricsProblemType,
             TetrahedralMesh<DIM,DIM>* pElectricsMesh,
             QuadraticMesh<DIM>* pMechanicsMesh,
             AbstractCardiacCellFactory<DIM>* pCellFactory,
             ElectroMechanicsProblemDefinition<DIM>* pProblemDefinition,
             std::string outputDirectory)
       : mCompressibilityType(compressibilityType),
         mpCardiacMechSolver(NULL),
         mpMechanicsSolver(NULL),
         mpElectricsMesh(pElectricsMesh),
         mpMechanicsMesh(pMechanicsMesh),
         mpProblemDefinition(pProblemDefinition),
         mHasBath(false),
         mpMeshPair(NULL),
         mNoElectricsOutput(false),
         mIsWatchedLocation(false),
         mWatchedElectricsNodeIndex(UNSIGNED_UNSET),
         mWatchedMechanicsNodeIndex(UNSIGNED_UNSET),
         mNumTimestepsToOutputDeformationGradientsAndStress(UNSIGNED_UNSET)
 {
     // Do some initial set up...
     // However, NOTE, we don't use either the passed in meshes or the problem_definition.
     // These pointers are allowed to be NULL, in case a child constructor wants to set
     // them up (eg CardiacElectroMechProbRegularGeom).
     // The meshes and problem_defn are used for the first time in Initialise().


     // Start-up mechanics event handler..
     MechanicsEventHandler::Reset();
     MechanicsEventHandler::BeginEvent(MechanicsEventHandler::ALL);
     // disable the electric event handler, because we use a problem class but
     // don't call Solve, so we would have to worry about starting and ending any
     // events in AbstractCardiacProblem::Solve() (esp. calling EndEvent(EVERYTHING))
     // if we didn't disable it.
     HeartEventHandler::Disable();

     assert(HeartConfig::Instance()->GetSimulationDuration()>0.0);
     assert(HeartConfig::Instance()->GetPdeTimeStep()>0.0);

     // Create the monodomain problem.
     // **NOTE** WE ONLY USE THIS TO: set up the cells, get an initial condition
     // (voltage) vector, and get a solver. We won't ever call Solve on the cardiac problem class
     assert(pCellFactory != NULL);
     mpElectricsProblem = CreateElectricsProblem<DIM,ELEC_PROB_DIM>::Create(electricsProblemType, pCellFactory);

     if (electricsProblemType == BIDOMAIN_WITH_BATH)
     {
         mHasBath = true;
     }
     // check whether output is required
     mWriteOutput = (outputDirectory!="");
     if (mWriteOutput)
     {
         mOutputDirectory = outputDirectory;
         // create the directory
         OutputFileHandler handler(mOutputDirectory);
         mDeformationOutputDirectory = mOutputDirectory + "/deformation";
         HeartConfig::Instance()->SetOutputDirectory(mOutputDirectory + "/electrics");
         HeartConfig::Instance()->SetOutputFilenamePrefix("voltage");
     }
     else
     {
         mDeformationOutputDirectory = "";
     }

 //    mpImpactRegion=NULL;
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::~CardiacElectroMechanicsProblem()
 {
     // NOTE if SetWatchedLocation but not Initialise has been called, mpWatchedLocationFile
     // will be uninitialised and using it will cause a seg fault. Hence the mpMechanicsMesh!=NULL
     // it is true if Initialise has been called.
     if (mIsWatchedLocation && mpMechanicsMesh)
     {
         mpWatchedLocationFile->close();
     }

     delete mpElectricsProblem;
     delete mpCardiacMechSolver;
     delete mpMeshPair;

     LogFile::Close();
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 void CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::Initialise()
 {
     assert(mpElectricsMesh!=NULL);
     assert(mpMechanicsMesh!=NULL);
     assert(mpProblemDefinition!=NULL);
     assert(mpCardiacMechSolver==NULL);

     mNumElecTimestepsPerMechTimestep = (unsigned) floor((mpProblemDefinition->GetMechanicsSolveTimestep()/HeartConfig::Instance()->GetPdeTimeStep())+0.5);
     if (fabs(mNumElecTimestepsPerMechTimestep*HeartConfig::Instance()->GetPdeTimeStep() - mpProblemDefinition->GetMechanicsSolveTimestep()) > 1e-6)
     {
         EXCEPTION("Electrics PDE timestep does not divide mechanics solve timestep");
     }

     // Create the Logfile (note we have to do this after the output dir has been
     // created, else the log file might get cleaned away
     std::string log_dir = mOutputDirectory; // just the TESTOUTPUT dir if mOutputDir="";
     LogFile::Instance()->Set(2, mOutputDirectory);
     LogFile::Instance()->WriteHeader("Electromechanics");
     LOG(2, DIM << "d Implicit CardiacElectroMechanics Simulation:");
     LOG(2, "End time = " << HeartConfig::Instance()->GetSimulationDuration() << ", electrics time step = " << HeartConfig::Instance()->GetPdeTimeStep() << ", mechanics timestep = " << mpProblemDefinition->GetMechanicsSolveTimestep() << "\n");
     LOG(2, "Contraction model ode timestep " << mpProblemDefinition->GetContractionModelOdeTimestep());
     LOG(2, "Output is written to " << mOutputDirectory << "/[deformation/electrics]");

     LOG(2, "Electrics mesh has " << mpElectricsMesh->GetNumNodes() << " nodes");
     LOG(2, "Mechanics mesh has " << mpMechanicsMesh->GetNumNodes() << " nodes");

     LOG(2, "Initialising..");


     if (mIsWatchedLocation)
     {
         DetermineWatchedNodes();
     }

     // initialise electrics problem
     mpElectricsProblem->SetMesh(mpElectricsMesh);
     mpElectricsProblem->Initialise();

     if (mCompressibilityType==INCOMPRESSIBLE)
     {
         switch(mpProblemDefinition->GetSolverType())
         {
             case EXPLICIT:
                 mpCardiacMechSolver = new ExplicitCardiacMechanicsSolver<IncompressibleNonlinearElasticitySolver<DIM>,DIM>(
                                         *mpMechanicsMesh,*mpProblemDefinition,mDeformationOutputDirectory);
                 break;
             case IMPLICIT:
                 mpCardiacMechSolver = new ImplicitCardiacMechanicsSolver<IncompressibleNonlinearElasticitySolver<DIM>,DIM>(
                                         *mpMechanicsMesh,*mpProblemDefinition,mDeformationOutputDirectory);
                 break;
             default:
                 NEVER_REACHED;
         }
     }
     else
     {
         // repeat above with Compressible solver rather than incompressible -
         // not the neatest but avoids having to template this class.
         switch(mpProblemDefinition->GetSolverType())
         {
             case EXPLICIT:
                 mpCardiacMechSolver = new ExplicitCardiacMechanicsSolver<CompressibleNonlinearElasticitySolver<DIM>,DIM>(
                                         *mpMechanicsMesh,*mpProblemDefinition,mDeformationOutputDirectory);
                 break;
             case IMPLICIT:
                 mpCardiacMechSolver = new ImplicitCardiacMechanicsSolver<CompressibleNonlinearElasticitySolver<DIM>,DIM>(
                                         *mpMechanicsMesh,*mpProblemDefinition,mDeformationOutputDirectory);
                 break;
             default:
                 NEVER_REACHED;
         }
     }


     mpMechanicsSolver = dynamic_cast<AbstractNonlinearElasticitySolver<DIM>*>(mpCardiacMechSolver);
     assert(mpMechanicsSolver);

     // set up mesh pair and determine the fine mesh elements and corresponding weights for each
     // quadrature point in the coarse mesh
     mpMeshPair = new FineCoarseMeshPair<DIM>(*mpElectricsMesh, *mpMechanicsMesh);
     mpMeshPair->SetUpBoxesOnFineMesh();
     mpMeshPair->ComputeFineElementsAndWeightsForCoarseQuadPoints(*(mpCardiacMechSolver->GetQuadratureRule()), false);
     mpMeshPair->DeleteFineBoxCollection();

     mpCardiacMechSolver->SetFineCoarseMeshPair(mpMeshPair);
     mpCardiacMechSolver->Initialise();

     unsigned num_quad_points = mpCardiacMechSolver->GetTotalNumQuadPoints();
     mInterpolatedCalciumConcs.assign(num_quad_points, 0.0);
     mInterpolatedVoltages.assign(num_quad_points, 0.0);

     if (mpProblemDefinition->ReadFibreSheetDirectionsFromFile())
     {
        mpCardiacMechSolver->SetVariableFibreSheetDirections(mpProblemDefinition->GetFibreSheetDirectionsFile(),
                                                             mpProblemDefinition->GetFibreSheetDirectionsDefinedPerQuadraturePoint());
     }


     if (mpProblemDefinition->GetDeformationAffectsConductivity() || mpProblemDefinition->GetDeformationAffectsCellModels())
     {
         mpMeshPair->SetUpBoxesOnCoarseMesh();
     }


     if (mpProblemDefinition->GetDeformationAffectsCellModels() || mpProblemDefinition->GetDeformationAffectsConductivity())
     {
         // initialise the stretches saved for each mechanics element
         mStretchesForEachMechanicsElement.resize(mpMechanicsMesh->GetNumElements(), 1.0);

         // initialise the store of the F in each mechanics element (one constant value of F) in each
         mDeformationGradientsForEachMechanicsElement.resize(mpMechanicsMesh->GetNumElements(),identity_matrix<double>(DIM));
     }


     if (mpProblemDefinition->GetDeformationAffectsCellModels())
     {
         // compute the coarse elements which contain each fine node -- for transferring stretch from
         // mechanics solve electrics cell models
         mpMeshPair->ComputeCoarseElementsForFineNodes(false);

     }

     if (mpProblemDefinition->GetDeformationAffectsConductivity())
     {
         // compute the coarse elements which contain each fine element centroid -- for transferring F from
         // mechanics solve to electrics mesh elements
         mpMeshPair->ComputeCoarseElementsForFineElementCentroids(false);

         // tell the abstract tissue class that the conductivities need to be modified, passing in this class
         // (which is of type AbstractConductivityModifier)
         mpElectricsProblem->GetTissue()->SetConductivityModifier(this);
     }

     if (mWriteOutput)
     {
         TrianglesMeshWriter<DIM,DIM> mesh_writer(mOutputDirectory,"electrics_mesh",false);
         mesh_writer.WriteFilesUsingMesh(*mpElectricsMesh);
     }
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 void CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::Solve()
 {
     // initialise the meshes and mechanics solver
     if (mpCardiacMechSolver==NULL)
     {
         Initialise();
     }

     bool verbose_during_solve = (    mpProblemDefinition->GetVerboseDuringSolve()
                                   || CommandLineArguments::Instance()->OptionExists("-mech_verbose")
                                   || CommandLineArguments::Instance()->OptionExists("-mech_very_verbose"));


     mpProblemDefinition->Validate();

     boost::shared_ptr<BoundaryConditionsContainer<DIM,DIM,ELEC_PROB_DIM> > p_bcc(new BoundaryConditionsContainer<DIM,DIM,ELEC_PROB_DIM>);
     p_bcc->DefineZeroNeumannOnMeshBoundary(mpElectricsMesh, 0);
     mpElectricsProblem->SetBoundaryConditionsContainer(p_bcc);

     // get an electrics solver from the problem. Note that we don't call
     // Solve() on the CardiacProblem class, we do the looping here.
     AbstractDynamicLinearPdeSolver<DIM,DIM,ELEC_PROB_DIM>* p_electrics_solver
        = mpElectricsProblem->CreateSolver();

     // set up initial voltage etc
     Vec electrics_solution=NULL; //This will be set and used later
     Vec calcium_data= mpElectricsMesh->GetDistributedVectorFactory()->CreateVec();
     Vec initial_voltage = mpElectricsProblem->CreateInitialCondition();

     // write the initial position
     unsigned counter = 0;

     TimeStepper stepper(0.0, HeartConfig::Instance()->GetSimulationDuration(), mpProblemDefinition->GetMechanicsSolveTimestep());

     CmguiDeformedSolutionsWriter<DIM>* p_cmgui_writer = NULL;

     std::vector<std::string> variable_names;

     if (mWriteOutput)
     {
         mpMechanicsSolver->SetWriteOutput();
         mpMechanicsSolver->WriteCurrentSpatialSolution("undeformed","nodes");

         p_cmgui_writer = new CmguiDeformedSolutionsWriter<DIM>(mOutputDirectory+"/deformation/cmgui",
                                                                "solution",
                                                                *(this->mpMechanicsMesh),
                                                                WRITE_QUADRATIC_MESH);
         variable_names.push_back("V");
         if (ELEC_PROB_DIM==2)
         {
             variable_names.push_back("Phi_e");
             if (mHasBath==true)
             {
                 std::vector<std::string> regions;
                 regions.push_back("tissue");
                 regions.push_back("bath");
                 p_cmgui_writer->SetRegionNames(regions);
             }
         }
         p_cmgui_writer->SetAdditionalFieldNames(variable_names);
         p_cmgui_writer->WriteInitialMesh("undeformed");
     }


     LOG(2, "\nSolving for initial deformation");
     // LCOV_EXCL_START
     if (verbose_during_solve)
     {
         std::cout << "\n\n ** Solving for initial deformation\n";
     }
     // LCOV_EXCL_STOP

     mpMechanicsSolver->SetWriteOutput(false);

     mpMechanicsSolver->SetCurrentTime(0.0);
     MechanicsEventHandler::BeginEvent(MechanicsEventHandler::ALL_MECH);

     mpMechanicsSolver->SetIncludeActiveTension(false);
     if (mNumTimestepsToOutputDeformationGradientsAndStress!=UNSIGNED_UNSET)
     {
         mpMechanicsSolver->SetComputeAverageStressPerElementDuringSolve(true);
     }

     unsigned total_newton_iters = 0;
     for (unsigned index=1; index<=mpProblemDefinition->GetNumIncrementsForInitialDeformation(); index++)
     {
         // LCOV_EXCL_START
         if (verbose_during_solve)
         {
             std::cout << "    Increment " << index << " of " << mpProblemDefinition->GetNumIncrementsForInitialDeformation() << "\n";
         }
         // LCOV_EXCL_STOP

         if (mpProblemDefinition->GetTractionBoundaryConditionType()==PRESSURE_ON_DEFORMED)
         {
             mpProblemDefinition->SetPressureScaling(((double)index)/mpProblemDefinition->GetNumIncrementsForInitialDeformation());
         }
         mpMechanicsSolver->Solve();

         total_newton_iters += mpMechanicsSolver->GetNumNewtonIterations();
     }

     mpMechanicsSolver->SetIncludeActiveTension(true);
     MechanicsEventHandler::EndEvent(MechanicsEventHandler::ALL_MECH);
     LOG(2, "    Number of newton iterations = " << total_newton_iters);


     unsigned mech_writer_counter = 0;

     if (mWriteOutput)
     {
         LOG(2, "  Writing output");
         mpMechanicsSolver->SetWriteOutput();
         mpMechanicsSolver->WriteCurrentSpatialSolution("solution","nodes",mech_writer_counter);
         p_cmgui_writer->WriteDeformationPositions(rGetDeformedPosition(), mech_writer_counter);

         if (!mNoElectricsOutput)
         {
             // the writer inside monodomain problem uses the printing timestep
             // inside HeartConfig to estimate total number of timesteps, so make
             // sure this is set to what we will use.
             HeartConfig::Instance()->SetPrintingTimeStep(mpProblemDefinition->GetMechanicsSolveTimestep());

             // When we consider archiving these simulations we will need to get a bool back from the following
             // command to decide whether or not the file is being extended, and hence whether to write the
             // initial conditions into the .h5 file.
             mpElectricsProblem->InitialiseWriter();
             mpElectricsProblem->WriteOneStep(stepper.GetTime(), initial_voltage);
         }

         if (mIsWatchedLocation)
         {
             WriteWatchedLocationData(stepper.GetTime(), initial_voltage);
         }

         if (mNumTimestepsToOutputDeformationGradientsAndStress!=UNSIGNED_UNSET)
         {
             mpMechanicsSolver->WriteCurrentStrains(DEFORMATION_GRADIENT_F,"deformation_gradient",mech_writer_counter);
             mpMechanicsSolver->WriteCurrentAverageElementStresses("second_PK",mech_writer_counter);
         }
     }


     PrepareForSolve();

 //    std::vector<double> current_solution_previous_time_step = mpMechanicsSolver->rGetCurrentSolution();
 //    std::vector<double> current_solution_second_last_time_step = mpMechanicsSolver->rGetCurrentSolution();
 //    bool first_step = true;


     // reset this to false, may be reset again below
     mpMechanicsSolver->SetComputeAverageStressPerElementDuringSolve(false);

     while (!stepper.IsTimeAtEnd())
     {
         LOG(2, "\nCurrent time = " << stepper.GetTime());
         // LCOV_EXCL_START
         if (verbose_during_solve)
         {
             // also output time to screen as newton solve information will be output
             std::cout << "\n\n ** Current time = " << stepper.GetTime() << "\n";
         }
         // LCOV_EXCL_STOP

         if (mpProblemDefinition->GetDeformationAffectsCellModels() || mpProblemDefinition->GetDeformationAffectsConductivity())
         {
             //  Determine the stretch and deformation gradient on each element.
             //
             //  If mpProblemDefinition->GetDeformationAffectsCellModels()==true:
             //  Stretch will be passed to the cell models.
             //
             //  If mpProblemDefinition->GetDeformationAffectsConductivity()==true:
             //  The deformation gradient needs to be set up but does not need to be passed to the tissue
             //  so that F is used to compute the conductivity. Instead this is
             //  done through the line "mpElectricsProblem->GetMonodomainTissue()->SetConductivityModifier(this);" line above, which means
             //  rCalculateModifiedConductivityTensor() will be called on this class by the tissue, which then uses the F

             mpCardiacMechSolver->ComputeDeformationGradientAndStretchInEachElement(mDeformationGradientsForEachMechanicsElement, mStretchesForEachMechanicsElement);
         }

         if (mpProblemDefinition->GetDeformationAffectsCellModels())
         {
             //  Set the stretches on each of the cell models
             for (unsigned global_index = mpElectricsMesh->GetDistributedVectorFactory()->GetLow();
                          global_index < mpElectricsMesh->GetDistributedVectorFactory()->GetHigh();
                          global_index++)
             {
                 unsigned containing_elem = mpMeshPair->rGetCoarseElementsForFineNodes()[global_index];
                 double stretch = mStretchesForEachMechanicsElement[containing_elem];
                 mpElectricsProblem->GetTissue()->GetCardiacCell(global_index)->SetStretch(stretch);
             }
         }

         p_electrics_solver->SetTimeStep(HeartConfig::Instance()->GetPdeTimeStep());

         LOG(2, "  Solving electrics");
         MechanicsEventHandler::BeginEvent(MechanicsEventHandler::NON_MECH);
         for (unsigned i=0; i<mNumElecTimestepsPerMechTimestep; i++)
         {
             double current_time = stepper.GetTime() + i*HeartConfig::Instance()->GetPdeTimeStep();
             double next_time = stepper.GetTime() + (i+1)*HeartConfig::Instance()->GetPdeTimeStep();

             // solve the electrics
             p_electrics_solver->SetTimes(current_time, next_time);
             p_electrics_solver->SetInitialCondition( initial_voltage );

             electrics_solution = p_electrics_solver->Solve();

             PetscReal min_voltage, max_voltage;
             VecMax(electrics_solution,PETSC_NULL,&max_voltage); //the second param is where the index would be returned
             VecMin(electrics_solution,PETSC_NULL,&min_voltage);
             if (i==0)
             {
                 LOG(2, "  minimum and maximum voltage is " << min_voltage <<", "<<max_voltage);
             }
             else if (i==1)
             {
                 LOG(2, "  ..");
             }

             PetscTools::Destroy(initial_voltage);
             initial_voltage = electrics_solution;
         }

         if (mpProblemDefinition->GetDeformationAffectsConductivity())
         {
             p_electrics_solver->SetMatrixIsNotAssembled();
         }


         // compute Ca_I at each quad point (by interpolation, using the info on which
         // electrics element the quad point is in. Then set Ca_I on the mechanics solver
         LOG(2, "  Interpolating Ca_I and voltage");

         //Collect the distributed calcium data into one Vec to be later replicated
         for (unsigned node_index = 0; node_index<mpElectricsMesh->GetNumNodes(); node_index++)
         {
             if (mpElectricsMesh->GetDistributedVectorFactory()->IsGlobalIndexLocal(node_index))
             {
                 double calcium_value = mpElectricsProblem->GetTissue()->GetCardiacCell(node_index)->GetIntracellularCalciumConcentration();
                 VecSetValue(calcium_data, node_index ,calcium_value, INSERT_VALUES);
             }
         }
         PetscTools::Barrier();//not sure this is needed

         //Replicate electrics solution and calcium (replication is inside this constructor of ReplicatableVector)
         ReplicatableVector electrics_solution_repl(electrics_solution);//size=(number of electrics nodes)*ELEC_PROB_DIM
         ReplicatableVector calcium_repl(calcium_data);//size = number of electrics nodes

         //interpolate values onto mechanics mesh
         for (unsigned i=0; i<mpMeshPair->rGetElementsAndWeights().size(); i++)
         {
             double interpolated_CaI = 0;
             double interpolated_voltage = 0;

             Element<DIM,DIM>& element = *(mpElectricsMesh->GetElement(mpMeshPair->rGetElementsAndWeights()[i].ElementNum));

             for (unsigned node_index = 0; node_index<element.GetNumNodes(); node_index++)
             {
                 unsigned global_index = element.GetNodeGlobalIndex(node_index);
                 double CaI_at_node =  calcium_repl[global_index];
                 interpolated_CaI += CaI_at_node*mpMeshPair->rGetElementsAndWeights()[i].Weights(node_index);
                 //the following line assumes interleaved solution for ELEC_PROB_DIM>1 (e.g, [Vm_0, phi_e_0, Vm1, phi_e_1...])
                 interpolated_voltage += electrics_solution_repl[global_index*ELEC_PROB_DIM]*mpMeshPair->rGetElementsAndWeights()[i].Weights(node_index);
             }

             assert(i<mInterpolatedCalciumConcs.size());
             assert(i<mInterpolatedVoltages.size());
             mInterpolatedCalciumConcs[i] = interpolated_CaI;
             mInterpolatedVoltages[i] = interpolated_voltage;
         }

         LOG(2, "  Setting Ca_I. max value = " << Max(mInterpolatedCalciumConcs));

         // NOTE IF NHS: HERE WE SHOULD PERHAPS CHECK WHETHER THE CELL MODELS HAVE Ca_Trop
         // AND UPDATE FROM NHS TO CELL_MODEL, BUT NOT SURE HOW TO DO THIS.. (esp for implicit)

         // set [Ca], V, t
         mpCardiacMechSolver->SetCalciumAndVoltage(mInterpolatedCalciumConcs, mInterpolatedVoltages);
         MechanicsEventHandler::EndEvent(MechanicsEventHandler::NON_MECH);


         LOG(2, "  Solving mechanics ");
         mpMechanicsSolver->SetWriteOutput(false);

         // make sure the mechanics solver knows the current time (in case
         // the traction say is time-dependent).
         mpMechanicsSolver->SetCurrentTime(stepper.GetTime());

         // see if we will need to output stresses at the end of this timestep
         if (mNumTimestepsToOutputDeformationGradientsAndStress!=UNSIGNED_UNSET
             && (counter+1)%mNumTimestepsToOutputDeformationGradientsAndStress == 0)
         {
             mpMechanicsSolver->SetComputeAverageStressPerElementDuringSolve(true);
         }

 //        for (unsigned i=0; i<mpMechanicsSolver->rGetCurrentSolution().size(); i++)
 //        {
 //            double current = mpMechanicsSolver->rGetCurrentSolution()[i];
 //            double previous = current_solution_previous_time_step[i];
 //            double second_last = current_solution_second_last_time_step[i];
 //            //double guess = 2*current - previous;
 //            double guess = 3*current - 3*previous + second_last;
 //
 //            if (!first_step)
 //            {
 //                current_solution_second_last_time_step[i] = current_solution_previous_time_step[i];
 //            }
 //            current_solution_previous_time_step[i] = mpMechanicsSolver->rGetCurrentSolution()[i];
 //            mpMechanicsSolver->rGetCurrentSolution()[i] = guess;
 //        }
 //        first_step = false;

         MechanicsEventHandler::BeginEvent(MechanicsEventHandler::ALL_MECH);
         mpCardiacMechSolver->Solve(stepper.GetTime(), stepper.GetNextTime(), mpProblemDefinition->GetContractionModelOdeTimestep());
         MechanicsEventHandler::EndEvent(MechanicsEventHandler::ALL_MECH);

         LOG(2, "    Number of newton iterations = " << mpMechanicsSolver->GetNumNewtonIterations());

          // update the current time
         stepper.AdvanceOneTimeStep();
         counter++;


         MechanicsEventHandler::BeginEvent(MechanicsEventHandler::OUTPUT);
         if (mWriteOutput && (counter%WRITE_EVERY_NTH_TIME==0))
         {
             LOG(2, "  Writing output");
             // write deformed position
             mech_writer_counter++;
             mpMechanicsSolver->SetWriteOutput();
             mpMechanicsSolver->WriteCurrentSpatialSolution("solution","nodes",mech_writer_counter);

             p_cmgui_writer->WriteDeformationPositions(rGetDeformedPosition(), counter);

             if (!mNoElectricsOutput)
             {
                 mpElectricsProblem->mpWriter->AdvanceAlongUnlimitedDimension();
                 mpElectricsProblem->WriteOneStep(stepper.GetTime(), electrics_solution);
             }

             if (mIsWatchedLocation)
             {
                 WriteWatchedLocationData(stepper.GetTime(), electrics_solution);
             }
             OnEndOfTimeStep(counter);

             if (mNumTimestepsToOutputDeformationGradientsAndStress!=UNSIGNED_UNSET && counter%mNumTimestepsToOutputDeformationGradientsAndStress==0)
             {
                 mpMechanicsSolver->WriteCurrentStrains(DEFORMATION_GRADIENT_F,"deformation_gradient",mech_writer_counter);
                 mpMechanicsSolver->WriteCurrentAverageElementStresses("second_PK",mech_writer_counter);
             }
             mpMechanicsSolver->SetComputeAverageStressPerElementDuringSolve(false);
         }
         MechanicsEventHandler::EndEvent(MechanicsEventHandler::OUTPUT);

         // write the total elapsed time..
         LogFile::Instance()->WriteElapsedTime("  ");
     }

     if ((mWriteOutput) && (!mNoElectricsOutput))
     {
         HeartConfig::Instance()->Reset();
         mpElectricsProblem->mpWriter->Close();
         delete mpElectricsProblem->mpWriter;

         std::string input_dir = mOutputDirectory+"/electrics";

         // Convert simulation data to meshalyzer format - commented
         std::string config_directory = HeartConfig::Instance()->GetOutputDirectory();
         HeartConfig::Instance()->SetOutputDirectory(input_dir);

 //      Hdf5ToMeshalyzerConverter<DIM,DIM> meshalyzer_converter(FileFinder(input_dir, RelativeTo::ChasteTestOutput),
 //                                                              "voltage", mpElectricsMesh,
 //                                                                HeartConfig::Instance()->GetOutputUsingOriginalNodeOrdering(),
 //                                                                HeartConfig::Instance()->GetVisualizerOutputPrecision() );

         // convert output to CMGUI format
         Hdf5ToCmguiConverter<DIM,DIM> cmgui_converter(FileFinder(input_dir, RelativeTo::ChasteTestOutput),
                                                       "voltage", mpElectricsMesh, mHasBath,
                                                       HeartConfig::Instance()->GetVisualizerOutputPrecision());

         // Write mesh in a suitable form for meshalyzer
         //std::string output_directory =  mOutputDirectory + "/electrics/output";
         // Write the mesh
         //MeshalyzerMeshWriter<DIM,DIM> mesh_writer(output_directory, "mesh", false);
         //mesh_writer.WriteFilesUsingMesh(*mpElectricsMesh);
         // Write the parameters out
         //HeartConfig::Instance()->Write();

         // interpolate the electrical data onto the mechanics mesh nodes and write CMGUI...
         // Note: this calculates the data on ALL nodes of the mechanics mesh (incl internal,
         // non-vertex ones), which won't be used if linear CMGUI visualisation
         // of the mechanics solution is used.
         VoltageInterpolaterOntoMechanicsMesh<DIM> converter(*mpElectricsMesh,*mpMechanicsMesh,variable_names,input_dir,"voltage");

         // reset to the default value
         HeartConfig::Instance()->SetOutputDirectory(config_directory);
     }

     if (p_cmgui_writer)
     {
         if (mNoElectricsOutput)
         {
             p_cmgui_writer->WriteCmguiScript("","undeformed");
         }
         else
         {
             p_cmgui_writer->WriteCmguiScript("../../electrics/cmgui_output/voltage_mechanics_mesh","undeformed");
         }
         delete p_cmgui_writer;
     }
     PetscTools::Destroy(electrics_solution);
     PetscTools::Destroy(calcium_data);
     delete p_electrics_solver;

     MechanicsEventHandler::EndEvent(MechanicsEventHandler::ALL);
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 double CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::Max(std::vector<double>& vec)
 {
     double max = -1e200;
     for (unsigned i=0; i<vec.size(); i++)
     {
         if (vec[i]>max) max=vec[i];
     }
     return max;
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 void CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::SetNoElectricsOutput()
 {
     mNoElectricsOutput = true;
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 void CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::SetWatchedPosition(c_vector<double,DIM> watchedLocation)
 {
     mIsWatchedLocation = true;
     mWatchedLocation = watchedLocation;
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 void CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::SetOutputDeformationGradientsAndStress(double timeStep)
 {
     mNumTimestepsToOutputDeformationGradientsAndStress = (unsigned) floor((timeStep/mpProblemDefinition->GetMechanicsSolveTimestep())+0.5);
     if (fabs(mNumTimestepsToOutputDeformationGradientsAndStress*mpProblemDefinition->GetMechanicsSolveTimestep() - timeStep) > 1e-6)
     {
         EXCEPTION("Timestep provided for SetOutputDeformationGradientsAndStress() is not a multiple of mechanics solve timestep");
     }
 }

 template<unsigned DIM, unsigned ELEC_PROB_DIM>
 std::vector<c_vector<double,DIM> >& CardiacElectroMechanicsProblem<DIM,ELEC_PROB_DIM>::rGetDeformedPosition()
 {
     return mpMechanicsSolver->rGetDeformedPosition();
 }

 // Explicit instantiation

 //note: 1d incompressible material doesn't make sense
 template class CardiacElectroMechanicsProblem<2,1>;
 template class CardiacElectroMechanicsProblem<3,1>;
 template class CardiacElectroMechanicsProblem<2,2>;
 template class CardiacElectroMechanicsProblem<3,2>;
CardiacElectroMechanicsProblem::mpCardiacMechSolver
AbstractCardiacMechanicsSolverInterface< DIM > * mpCardiacMechSolver
Definition: CardiacElectroMechanicsProblem.hpp:112

AbstractCardiacProblem::WriteOneStep
virtual void WriteOneStep(double time, Vec voltageVec)=0

AbstractMesh::GetDistributedVectorFactory
virtual DistributedVectorFactory * GetDistributedVectorFactory()
Definition: AbstractMesh.cpp:133

CardiacElectroMechanicsProblem::mNumTimestepsToOutputDeformationGradientsAndStress
unsigned mNumTimestepsToOutputDeformationGradientsAndStress
Definition: CardiacElectroMechanicsProblem.hpp:170

QuadraticMesh
Definition: QuadraticMesh.hpp:51

CardiacElectroMechanicsProblem::mWriteOutput
bool mWriteOutput
Definition: CardiacElectroMechanicsProblem.hpp:151

LogFile::Set
void Set(unsigned level, const std::string &rDirectory, const std::string &rFileName="log.txt")
Definition: LogFile.cpp:73

DistributedVectorFactory::GetLow
unsigned GetLow() const
Definition: DistributedVectorFactory.hpp:212

CardiacElectroMechanicsProblem::mDeformationOutputDirectory
std::string mDeformationOutputDirectory
Definition: CardiacElectroMechanicsProblem.hpp:149

CardiacElectroMechanicsProblem::PrepareForSolve
virtual void PrepareForSolve()
Definition: CardiacElectroMechanicsProblem.hpp:285

AbstractCardiacCellFactory< DIM >

AbstractCardiacProblem::mpWriter
Hdf5DataWriter * mpWriter
Definition: AbstractCardiacProblem.hpp:472

CardiacElectroMechanicsProblem::OnEndOfTimeStep
virtual void OnEndOfTimeStep(unsigned counter)
Definition: CardiacElectroMechanicsProblem.hpp:291

HeartConfig::SetOutputDirectory
void SetOutputDirectory(const std::string &rOutputDirectory)
Definition: HeartConfig.cpp:2188

AbstractCardiacProblem::InitialiseWriter
bool InitialiseWriter()
Definition: AbstractCardiacProblem.cpp:803

VoltageInterpolaterOntoMechanicsMesh
Definition: VoltageInterpolaterOntoMechanicsMesh.hpp:52

CardiacElectroMechanicsProblem::WriteWatchedLocationData
void WriteWatchedLocationData(double time, Vec voltage)
Definition: CardiacElectroMechanicsProblem.cpp:144

PetscTools::Barrier
static void Barrier(const std::string callerId="")
Definition: PetscTools.cpp:134

Inverse
boost::numeric::ublas::c_matrix< T, 1, 1 > Inverse(const boost::numeric::ublas::c_matrix< T, 1, 1 > &rM)
Definition: UblasCustomFunctions.hpp:367

AbstractElement::GetNodeGlobalIndex
unsigned GetNodeGlobalIndex(unsigned localIndex) const
Definition: AbstractElement.cpp:109

CardiacElectroMechanicsProblem::mHasBath
bool mHasBath
Definition: CardiacElectroMechanicsProblem.hpp:141

AbstractDynamicLinearPdeSolver
Definition: AbstractDynamicLinearPdeSolver.hpp:56

EXCEPTION
#define EXCEPTION(message)
Definition: Exception.hpp:143

Hdf5DataWriter::Close
void Close()
Definition: Hdf5DataWriter.cpp:1182

CardiacElectroMechanicsProblem::Max
double Max(std::vector< double > &vec)
Definition: CardiacElectroMechanicsProblem.cpp:946

AbstractDynamicLinearPdeSolver::SetTimeStep
void SetTimeStep(double dt)
Definition: AbstractDynamicLinearPdeSolver.hpp:296

GenericEventHandler< 7, MechanicsEventHandler >::BeginEvent
static void BeginEvent(unsigned event)
Definition: GenericEventHandler.hpp:133

AbstractDynamicLinearPdeSolver::SetInitialCondition
void SetInitialCondition(Vec initialCondition)
Definition: AbstractDynamicLinearPdeSolver.hpp:307

AbstractCardiacProblem::CreateInitialCondition
virtual Vec CreateInitialCondition()
Definition: AbstractCardiacProblem.cpp:267

TimeStepper
Definition: TimeStepper.hpp:52

AbstractTetrahedralMesh::GetElement
Element< ELEMENT_DIM, SPACE_DIM > * GetElement(unsigned index) const
Definition: AbstractTetrahedralMesh.cpp:141

BoundaryConditionsContainer
Definition: BoundaryConditionsContainer.hpp:67

TrianglesMeshWriter
Definition: TrianglesMeshWriter.hpp:48

CreateElectricsProblem< DIM, 2u >::Create
static AbstractCardiacProblem< DIM, DIM, 2u > * Create(ElectricsProblemType problemType, AbstractCardiacCellFactory< DIM > *pCellFactory)
Definition: CardiacElectroMechanicsProblem.cpp:239

unsigned

BidomainProblem
Definition: AbstractCardiacProblem.hpp:809

CardiacElectroMechanicsProblem::mpMechanicsMesh
QuadraticMesh< DIM > * mpMechanicsMesh
Definition: CardiacElectroMechanicsProblem.hpp:135

AbstractMesh::GetNumNodes
virtual unsigned GetNumNodes() const
Definition: AbstractMesh.cpp:66

CardiacElectroMechanicsProblem::mInterpolatedVoltages
std::vector< double > mInterpolatedVoltages
Definition: CardiacElectroMechanicsProblem.hpp:130

AbstractDynamicLinearPdeSolver::Solve
virtual Vec Solve()
Definition: AbstractDynamicLinearPdeSolver.hpp:328

FileFinder
Definition: FileFinder.hpp:69

HeartConfig::GetPdeTimeStep
double GetPdeTimeStep() const
Definition: HeartConfig.cpp:1592

ReplicatableVector
Definition: ReplicatableVector.hpp:45

AbstractCardiacProblem::Initialise
void Initialise()
Definition: AbstractCardiacProblem.cpp:119

NEVER_REACHED
#define NEVER_REACHED
Definition: Exception.hpp:206

OutputFileHandler
Definition: OutputFileHandler.hpp:54

TetrahedralMesh< DIM, DIM >

ImplicitCardiacMechanicsSolver
Definition: ImplicitCardiacMechanicsSolver.hpp:59

CommandLineArguments::OptionExists
bool OptionExists(const std::string &rOption)
Definition: CommandLineArguments.cpp:61

CardiacElectroMechanicsProblem::mNumElecTimestepsPerMechTimestep
unsigned mNumElecTimestepsPerMechTimestep
Definition: CardiacElectroMechanicsProblem.hpp:118

CardiacElectroMechanicsProblem::mpMeshPair
FineCoarseMeshPair< DIM > * mpMeshPair
Definition: CardiacElectroMechanicsProblem.hpp:144

DistributedVectorFactory::IsGlobalIndexLocal
bool IsGlobalIndexLocal(unsigned globalIndex)
Definition: DistributedVectorFactory.cpp:149

AbstractDynamicLinearPdeSolver::SetTimes
void SetTimes(double tStart, double tEnd)
Definition: AbstractDynamicLinearPdeSolver.hpp:282

CardiacElectroMechanicsProblem::rGetDeformedPosition
std::vector< c_vector< double, DIM > > & rGetDeformedPosition()
Definition: CardiacElectroMechanicsProblem.cpp:980

OutputFileHandler::OpenOutputFile
out_stream OpenOutputFile(const std::string &rFileName, std::ios_base::openmode mode=std::ios::out|std::ios::trunc) const
Definition: OutputFileHandler.cpp:248

CardiacElectroMechanicsProblem::CardiacElectroMechanicsProblem
CardiacElectroMechanicsProblem(CompressibilityType compressibilityType, ElectricsProblemType electricsProblemType, TetrahedralMesh< DIM, DIM > *pElectricsMesh, QuadraticMesh< DIM > *pMechanicsMesh, AbstractCardiacCellFactory< DIM > *pCellFactory, ElectroMechanicsProblemDefinition< DIM > *pProblemDefinition, std::string outputDirectory)
Definition: CardiacElectroMechanicsProblem.cpp:256

Vec

GenericEventHandler< 16, HeartEventHandler >::Disable
static void Disable()
Definition: GenericEventHandler.hpp:190

CardiacElectroMechanicsProblem
Definition: CardiacElectroMechanicsProblem.hpp:94

CardiacElectroMechanicsProblem::SetNoElectricsOutput
void SetNoElectricsOutput()
Definition: CardiacElectroMechanicsProblem.cpp:957

LogFile::Close
static void Close()
Definition: LogFile.cpp:101

CardiacElectroMechanicsProblem::mOutputDirectory
std::string mOutputDirectory
Definition: CardiacElectroMechanicsProblem.hpp:147

CardiacElectroMechanicsProblem::DetermineWatchedNodes
void DetermineWatchedNodes()
Definition: CardiacElectroMechanicsProblem.cpp:60

CardiacElectroMechanicsProblem::mCompressibilityType
CompressibilityType mCompressibilityType
Definition: CardiacElectroMechanicsProblem.hpp:105

AbstractNonlinearElasticitySolver
Definition: AbstractNonlinearElasticitySolver.hpp:133

CardiacElectroMechanicsProblem::mpProblemDefinition
ElectroMechanicsProblemDefinition< DIM > * mpProblemDefinition
Definition: CardiacElectroMechanicsProblem.hpp:138

AbstractCardiacProblem::GetTissue
AbstractCardiacTissue< ELEMENT_DIM, SPACE_DIM > * GetTissue()
Definition: AbstractCardiacProblem.cpp:347

AbstractElement::GetNumNodes
unsigned GetNumNodes() const
Definition: AbstractElement.cpp:123

Hdf5DataWriter::AdvanceAlongUnlimitedDimension
void AdvanceAlongUnlimitedDimension()
Definition: Hdf5DataWriter.cpp:1225

CardiacElectroMechanicsProblem::mInterpolatedCalciumConcs
std::vector< double > mInterpolatedCalciumConcs
Definition: CardiacElectroMechanicsProblem.hpp:124

UNSIGNED_UNSET
const unsigned UNSIGNED_UNSET
Definition: Exception.hpp:52

CardiacElectroMechanicsProblem::Initialise
void Initialise()
Definition: CardiacElectroMechanicsProblem.cpp:345

Element
Definition: Element.hpp:53

CardiacElectroMechanicsProblem::SetOutputDeformationGradientsAndStress
void SetOutputDeformationGradientsAndStress(double timestep)
Definition: CardiacElectroMechanicsProblem.cpp:970

CardiacElectroMechanicsProblem::mDeformationGradientsForEachMechanicsElement
std::vector< c_matrix< double, DIM, DIM > > mDeformationGradientsForEachMechanicsElement
Definition: CardiacElectroMechanicsProblem.hpp:175

GenericEventHandler< 7, MechanicsEventHandler >::Reset
static void Reset()
Definition: GenericEventHandler.hpp:123

CreateElectricsProblem< DIM, 1u >::Create
static AbstractCardiacProblem< DIM, DIM, 1u > * Create(ElectricsProblemType problemType, AbstractCardiacCellFactory< DIM > *pCellFactory)
Definition: CardiacElectroMechanicsProblem.cpp:215

PetscTools::Destroy
static void Destroy(Vec &rVec)
Definition: PetscTools.hpp:352

CardiacElectroMechanicsProblem::rCalculateModifiedConductivityTensor
c_matrix< double, DIM, DIM > & rCalculateModifiedConductivityTensor(unsigned elementIndex, const c_matrix< double, DIM, DIM > &rOriginalConductivity, unsigned domainIndex)
Definition: CardiacElectroMechanicsProblem.cpp:169

AbstractCardiacProblem::SetMesh
void SetMesh(AbstractTetrahedralMesh< ELEMENT_DIM, SPACE_DIM > *pMesh)
Definition: AbstractCardiacProblem.cpp:297

CardiacElectroMechanicsProblem::mpWatchedLocationFile
out_stream mpWatchedLocationFile
Definition: CardiacElectroMechanicsProblem.hpp:167

ExplicitCardiacMechanicsSolver
Definition: ExplicitCardiacMechanicsSolver.hpp:61

LogFile::WriteHeader
void WriteHeader(std::string simulationType="")
Definition: LogFile.cpp:111

PetscTools.hpp

CardiacElectroMechanicsProblem::~CardiacElectroMechanicsProblem
virtual ~CardiacElectroMechanicsProblem()
Definition: CardiacElectroMechanicsProblem.cpp:327

CardiacElectroMechanicsProblem::mpMechanicsSolver
AbstractNonlinearElasticitySolver< DIM > * mpMechanicsSolver
Definition: CardiacElectroMechanicsProblem.hpp:115

CardiacElectroMechanicsProblem::mIsWatchedLocation
bool mIsWatchedLocation
Definition: CardiacElectroMechanicsProblem.hpp:159

AbstractCardiacProblem::SetBoundaryConditionsContainer
void SetBoundaryConditionsContainer(BccType pBcc)
Definition: AbstractCardiacProblem.cpp:225

CardiacElectroMechanicsProblem::Solve
void Solve()
Definition: CardiacElectroMechanicsProblem.cpp:488

CardiacElectroMechanicsProblem::mpElectricsProblem
AbstractCardiacProblem< DIM, DIM, ELEC_PROB_DIM > * mpElectricsProblem
Definition: CardiacElectroMechanicsProblem.hpp:108

LogFile::WriteElapsedTime
void WriteElapsedTime(std::string pre="")
Definition: LogFile.cpp:116

DistributedVectorFactory::GetHigh
unsigned GetHigh() const
Definition: DistributedVectorFactory.hpp:204

CommandLineArguments::Instance
static CommandLineArguments * Instance()
Definition: CommandLineArguments.cpp:50

FineCoarseMeshPair
Definition: FineCoarseMeshPair.hpp:106

HeartConfig::GetOutputDirectory
std::string GetOutputDirectory() const
Definition: HeartConfig.cpp:1372

CmguiDeformedSolutionsWriter
Definition: CmguiDeformedSolutionsWriter.hpp:65

RelativeTo::ChasteTestOutput
Definition: FileFinder.hpp:56

CardiacElectroMechanicsProblem::mStretchesForEachMechanicsElement
std::vector< double > mStretchesForEachMechanicsElement
Definition: CardiacElectroMechanicsProblem.hpp:173

LogFile::Instance
static LogFile * Instance()
Definition: LogFile.cpp:52

GenericEventHandler< 7, MechanicsEventHandler >::EndEvent
static void EndEvent(unsigned event)
Definition: GenericEventHandler.hpp:143

ElectroMechanicsProblemDefinition
Definition: ElectroMechanicsProblemDefinition.hpp:52

Hdf5ToCmguiConverter
Definition: Hdf5ToCmguiConverter.hpp:64

AbstractTetrahedralMeshWriter::WriteFilesUsingMesh
virtual void WriteFilesUsingMesh(AbstractTetrahedralMesh< ELEMENT_DIM, SPACE_DIM > &rMesh, bool keepOriginalElementIndexing=true)
Definition: AbstractTetrahedralMeshWriter.cpp:441

AbstractDynamicLinearPdeSolver::SetMatrixIsNotAssembled
void SetMatrixIsNotAssembled()
Definition: AbstractDynamicLinearPdeSolver.hpp:500

HeartConfig::Reset
static void Reset()
Definition: HeartConfig.cpp:665

AbstractCardiacProblem::CreateSolver
virtual AbstractDynamicLinearPdeSolver< ELEMENT_DIM, SPACE_DIM, PROBLEM_DIM > * CreateSolver()=0

HeartConfig::SetPrintingTimeStep
void SetPrintingTimeStep(double printingTimeStep)
Definition: HeartConfig.cpp:2379

HeartConfig::SetOutputFilenamePrefix
void SetOutputFilenamePrefix(const std::string &rOutputFilenamePrefix)
Definition: HeartConfig.cpp:2193

MonodomainProblem
Definition: MonodomainProblem.hpp:54

CardiacElectroMechanicsProblem::WRITE_EVERY_NTH_TIME
static const int WRITE_EVERY_NTH_TIME
Definition: CardiacElectroMechanicsProblem.hpp:156

HeartConfig::Instance
static HeartConfig * Instance()
Definition: HeartConfig.cpp:207

AbstractCardiacProblem
Definition: AbstractCardiacProblem.hpp:113

CardiacElectroMechanicsProblem::mNoElectricsOutput
bool mNoElectricsOutput
Definition: CardiacElectroMechanicsProblem.hpp:153

CreateElectricsProblem::Create
static AbstractCardiacProblem< DIM, DIM, PROBLEM_DIM > * Create(ElectricsProblemType problemType, AbstractCardiacCellFactory< DIM > *pCellFactory)

CardiacElectroMechanicsProblem::mpElectricsMesh
TetrahedralMesh< DIM, DIM > * mpElectricsMesh
Definition: CardiacElectroMechanicsProblem.hpp:133

CardiacElectroMechanicsProblem::mWatchedLocation
c_vector< double, DIM > mWatchedLocation
Definition: CardiacElectroMechanicsProblem.hpp:161

DistributedVectorFactory::CreateVec
Vec CreateVec()
Definition: DistributedVectorFactory.cpp:154

CardiacElectroMechanicsProblem::SetWatchedPosition
void SetWatchedPosition(c_vector< double, DIM > watchedLocation)
Definition: CardiacElectroMechanicsProblem.cpp:963

CreateElectricsProblem
Definition: CardiacElectroMechanicsProblem.cpp:189