forked from lijiext/lammps
420 lines
15 KiB
C++
420 lines
15 KiB
C++
// ATC_Transfer Headers
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#include "AtomicRegulator.h"
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#include "CG.h"
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#include "ATC_Error.h"
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#include "PrescribedDataManager.h"
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#include "TimeIntegrator.h"
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namespace ATC {
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Class AtomicRegulator
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//--------------------------------------------------------
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Constructor
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//--------------------------------------------------------
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AtomicRegulator::AtomicRegulator(ATC_Transfer * atcTransfer) :
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atcTransfer_(atcTransfer),
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howOften_(1),
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timeFilter_(NULL),
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regulatorMethod_(NULL),
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boundaryIntegrationType_(ATC_Transfer::NO_QUADRATURE),
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nNodes_(0),
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nsd_(0),
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nLocal_(0),
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needReset_(true),
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resetData_(true)
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{
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// nothing to do
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}
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//--------------------------------------------------------
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// Destructor
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//--------------------------------------------------------
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AtomicRegulator::~AtomicRegulator()
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{
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if (timeFilter_)
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delete timeFilter_;
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destroy();
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}
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//--------------------------------------------------------
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// destroy:
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// deallocates all memory
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//--------------------------------------------------------
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void AtomicRegulator::destroy()
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{
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if (regulatorMethod_)
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delete regulatorMethod_;
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}
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//--------------------------------------------------------
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// modify:
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// parses and adjusts controller state based on
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// user input, in the style of LAMMPS user input
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//--------------------------------------------------------
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bool AtomicRegulator::modify(int narg, char **arg)
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{
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bool foundMatch = false;
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return foundMatch;
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}
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//--------------------------------------------------------
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// reset_nlocal:
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// resizes lambda force if necessary
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//--------------------------------------------------------
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void AtomicRegulator::reset_nlocal()
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{
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nLocal_ = atcTransfer_->get_nlocal();
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if (nLocal_ > 0)
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lambdaForce_.reset(nLocal_,nsd_);
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if (regulatorMethod_)
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regulatorMethod_->reset_nlocal();
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}
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//--------------------------------------------------------
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// reset_data:
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// sets up storage for all data structures
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//--------------------------------------------------------
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void AtomicRegulator::reset_data()
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{
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nNodes_ = atcTransfer_->get_nNodes();
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nsd_ = atcTransfer_->get_nsd();
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if (timeFilter_)
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delete timeFilter_;
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timeFilter_ = NULL;
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resetData_ = false;
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}
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//--------------------------------------------------------
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// reset_method:
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// sets up methods, if necessary
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//--------------------------------------------------------
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void AtomicRegulator::reset_method()
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{
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// set up defaults for anything that didn't get set
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if (!regulatorMethod_)
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regulatorMethod_ = new RegulatorMethod(this);
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if (!timeFilter_)
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timeFilter_ = (atcTransfer_->get_time_filter_manager())->construct();
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needReset_ = false;
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}
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//--------------------------------------------------------
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// initialize:
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// sets up methods before a run
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//--------------------------------------------------------
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void AtomicRegulator::initialize()
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{
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// make sure consistent boundary integration is being used
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atcTransfer_->set_boundary_integration_type(boundaryIntegrationType_);
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// reset data related to local atom count
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reset_nlocal();
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}
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//--------------------------------------------------------
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// output:
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// pass through to appropriate output methods
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//--------------------------------------------------------
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void AtomicRegulator::output(double dt, OUTPUT_LIST & outputData) const
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{
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regulatorMethod_->output(dt,outputData);
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}
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//--------------------------------------------------------
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// apply_pre_predictor:
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// applies the controller in the pre-predictor
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// phase of the time integrator
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//--------------------------------------------------------
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void AtomicRegulator::apply_pre_predictor(double dt, int timeStep)
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{
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if (timeStep % howOften_==0) // apply full integration scheme, including filter
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regulatorMethod_->apply_pre_predictor(dt);
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}
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//--------------------------------------------------------
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// apply_mid_predictor:
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// applies the controller in the mid-predictor
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// phase of the time integrator
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//--------------------------------------------------------
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void AtomicRegulator::apply_mid_predictor(double dt, int timeStep)
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{
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if (timeStep % howOften_==0) // apply full integration scheme, including filter
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regulatorMethod_->apply_mid_predictor(dt);
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}
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//--------------------------------------------------------
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// apply_post_predictor:
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// applies the controller in the post-predictor
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// phase of the time integrator
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//--------------------------------------------------------
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void AtomicRegulator::apply_post_predictor(double dt, int timeStep)
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{
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if (timeStep % howOften_==0) // apply full integration scheme, including filter
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regulatorMethod_->apply_post_predictor(dt);
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}
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//--------------------------------------------------------
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// apply_pre_corrector:
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// applies the controller in the pre-corrector phase
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// of the time integrator
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//--------------------------------------------------------
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void AtomicRegulator::apply_pre_corrector(double dt, int timeStep)
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{
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if (timeStep % howOften_==0) // apply full integration scheme, including filter
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regulatorMethod_->apply_pre_corrector(dt);
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}
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//--------------------------------------------------------
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// apply_post_corrector:
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// applies the controller in the post-corrector phase
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// of the time integrator
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//--------------------------------------------------------
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void AtomicRegulator::apply_post_corrector(double dt, int timeStep)
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{
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if (timeStep % howOften_==0) // apply full integration scheme, including filter
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regulatorMethod_->apply_post_corrector(dt);
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}
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//--------------------------------------------------------
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// compute_boundary_flux:
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// computes the boundary flux to be consistent with
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// the controller
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//--------------------------------------------------------
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void AtomicRegulator::compute_boundary_flux(FIELDS & fields)
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{
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regulatorMethod_->compute_boundary_flux(fields);
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}
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//--------------------------------------------------------
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// add_to_rhs:
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// adds any controller contributions to the FE rhs
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//--------------------------------------------------------
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void AtomicRegulator::add_to_rhs(FIELDS & rhs)
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{
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regulatorMethod_->add_to_rhs(rhs);
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}
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Class RegulatorMethod
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//--------------------------------------------------------
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Constructor
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//--------------------------------------------------------
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RegulatorMethod::RegulatorMethod(AtomicRegulator * atomicRegulator) :
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atomicRegulator_(atomicRegulator),
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atcTransfer_(atomicRegulator->get_atc_transfer()),
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fieldMask_(NUM_FIELDS,NUM_FLUX),
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boundaryFlux_(atcTransfer_->get_boundary_fluxes()),
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nNodes_(atomicRegulator_->get_nNodes())
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{
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fieldMask_ = false;
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}
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//--------------------------------------------------------
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// compute_boundary_flux
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// default computation of boundary flux based on
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// finite
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//--------------------------------------------------------
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void RegulatorMethod::compute_boundary_flux(FIELDS & fields)
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{
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atcTransfer_->compute_boundary_flux(fieldMask_,
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fields,
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boundaryFlux_);
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}
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Class RegulatorShapeFunction
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//--------------------------------------------------------
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Constructor
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//--------------------------------------------------------
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RegulatorShapeFunction::RegulatorShapeFunction(AtomicRegulator * atomicRegulator) :
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RegulatorMethod(atomicRegulator),
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maxIterations_(50),
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tolerance_(1.e-10),
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nNodeOverlap_(atcTransfer_->get_nNode_overlap()),
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nsd_(atomicRegulator_->get_nsd()),
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lambda_(atomicRegulator_->get_lambda()),
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shapeFunctionMatrix_(atcTransfer_->get_nhat_overlap()),
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glcMatrixTemplate_(atcTransfer_->get_m_t_template()),
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shapeFunctionGhost_(atcTransfer_->get_shape_function_ghost_overlap()),
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internalToAtom_(atcTransfer_->get_internal_to_atom_map()),
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internalToOverlapMap_(atcTransfer_->get_atom_to_overlap_map()),
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ghostToAtom_(atcTransfer_->get_ghost_to_atom_map()),
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nLocal_(0),
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nLocalLambda_(0),
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nLocalGhost_(0)
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{
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if (atcTransfer_->use_lumped_lambda_solve())
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matrixSolver_ = new LambdaMatrixSolverLumped(glcMatrixTemplate_,
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shapeFunctionMatrix_,
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maxIterations_,
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tolerance_);
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else
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matrixSolver_ = new LambdaMatrixSolverCg(glcMatrixTemplate_,
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shapeFunctionMatrix_,
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maxIterations_,
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tolerance_);
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}
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//--------------------------------------------------------
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// Destructor
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//--------------------------------------------------------
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RegulatorShapeFunction::~RegulatorShapeFunction()
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{
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if (matrixSolver_)
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delete matrixSolver_;
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}
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//--------------------------------------------------------
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// solve_for_lambda
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// solves matrix equation for lambda using given rhs
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//--------------------------------------------------------
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void RegulatorShapeFunction::solve_for_lambda(const DENS_MAT & rhs)
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{
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// set up weighting matrix
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DIAG_MAT weights;
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if (nLocalLambda_>0)
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set_weights(weights);
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// solve on overlap nodes
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DENS_MAT rhsOverlap(nNodeOverlap_,rhs.nCols());
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atcTransfer_->map_unique_to_overlap(rhs, rhsOverlap);
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DENS_MAT lambdaOverlap(nNodeOverlap_,lambda_.nCols());
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for (int i = 0; i < rhs.nCols(); i++) {
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CLON_VEC tempRHS(rhsOverlap,CLONE_COL,i);
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CLON_VEC tempLambda(lambdaOverlap,CLONE_COL,i);
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matrixSolver_->execute(tempRHS,tempLambda,weights,atcTransfer_);
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}
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// map solution back to all nodes
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atcTransfer_->map_overlap_to_unique(lambdaOverlap,lambda_);
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}
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//--------------------------------------------------------
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// reset_nlocal:
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// resets data dependent on local atom count
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//--------------------------------------------------------
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void RegulatorShapeFunction::reset_nlocal()
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{
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RegulatorMethod::reset_nlocal();
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nLocal_ = atomicRegulator_->get_nLocal();
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nLocalLambda_ = atcTransfer_->get_nlocal_lambda();
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nLocalGhost_ = atcTransfer_->get_nlocal_ghost();
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}
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Class LambdaMatrixSolver
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//--------------------------------------------------------
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Constructor
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// Grab references to necessary data
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//--------------------------------------------------------
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LambdaMatrixSolver::LambdaMatrixSolver(SPAR_MAT & matrixTemplate, SPAR_MAT & shapeFunctionMatrix, int maxIterations, double tolerance) :
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matrixTemplate_(matrixTemplate),
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shapeFunctionMatrix_(shapeFunctionMatrix),
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maxIterations_(maxIterations),
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tolerance_(tolerance)
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{
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// do nothing
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}
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Class LambdaMatrixSolverLumped
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//--------------------------------------------------------
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Constructor
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// Grab references to necessary data
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//--------------------------------------------------------
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LambdaMatrixSolverLumped::LambdaMatrixSolverLumped(SPAR_MAT & matrixTemplate, SPAR_MAT & shapeFunctionMatrix, int maxIterations, double tolerance) :
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LambdaMatrixSolver(matrixTemplate,shapeFunctionMatrix,maxIterations,tolerance)
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{
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// do nothing
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}
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void LambdaMatrixSolverLumped::execute(VECTOR & rhs, VECTOR & lambda, DIAG_MAT & weights, ATC_Transfer * atcTransfer)
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{
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// form matrix : sum_a N_Ia * W_a * N_Ja
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SPAR_MAT myMatrixLocal(matrixTemplate_);
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if (weights.nRows()>0)
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myMatrixLocal.WeightedLeastSquares(shapeFunctionMatrix_,weights);
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// swap contributions
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SPAR_MAT myMatrix(matrixTemplate_);
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LammpsInterface::instance()->allsum(myMatrixLocal.get_ptr(),
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myMatrix.get_ptr(), myMatrix.size());
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DIAG_MAT lumpedMatrix(myMatrix.nRows(),myMatrix.nCols());
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for (int i = 0; i < myMatrix.nRows(); i++)
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for (int j = 0; j < myMatrix.nCols(); j++)
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lumpedMatrix(i,i) += myMatrix(i,j);
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// solve lumped equation
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for (int i = 0; i < rhs.size(); i++)
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lambda(i) = rhs(i)/lumpedMatrix(i,i);
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}
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Class LambdaMatrixSolverCg
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//--------------------------------------------------------
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//--------------------------------------------------------
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//--------------------------------------------------------
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// Constructor
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// Grab references to necessary data
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//--------------------------------------------------------
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LambdaMatrixSolverCg::LambdaMatrixSolverCg(SPAR_MAT & matrixTemplate, SPAR_MAT & shapeFunctionMatrix, int maxIterations, double tolerance) :
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LambdaMatrixSolver(matrixTemplate,shapeFunctionMatrix,maxIterations,tolerance)
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{
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// do nothing
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}
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void LambdaMatrixSolverCg::execute(VECTOR & rhs, VECTOR & lambda, DIAG_MAT & weights, ATC_Transfer * atcTransfer)
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{
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// form matrix : sum_a N_Ia * W_a * N_Ja
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SPAR_MAT myMatrixLocal(matrixTemplate_);
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if (weights.nRows()>0)
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myMatrixLocal.WeightedLeastSquares(shapeFunctionMatrix_,weights);
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// swap contributions
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SPAR_MAT myMatrix(matrixTemplate_);
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LammpsInterface::instance()->allsum(myMatrixLocal.get_ptr(),
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myMatrix.get_ptr(), myMatrix.size());
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DIAG_MAT preConditioner = myMatrix.get_diag();
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int myMaxIt = 2*myMatrix.nRows(); // note could also use the fixed parameter
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double myTol = tolerance_;
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int convergence = CG(myMatrix, lambda, rhs, preConditioner, myMaxIt, myTol);
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// error if didn't converge
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if (convergence>0)
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throw ATC_Error(0,"CG solver did not converge in LambdaMatrixSolverCg::execute()");
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}
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};
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