ConcentrationRegulator.h
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Created: Sat, Jul 20, 23:50

ConcentrationRegulator.h
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	#ifndef CONCENTRATION_REGULATOR_H
	#define CONCENTRATION_REGULATOR_H

	#include <map>
	#include <string>

	#include "AtomicRegulator.h"
	#include "LammpsInterface.h"

	namespace ATC {

	/**
	* @class ConcentrationRegulator
	* @brief Manager class for atom-continuum control of charge and potential
	*/

	class ConcentrationRegulatorMethod;
	class ConcentrationRegulator : public AtomicRegulator {

	public:
	enum ConcentrationRegulatorType {NONE=0,TRANSITION};
	/** parser data */
	struct ConcentrationRegulatorParameters {
	ConcentrationRegulatorParameters():
	method(NONE),
	type(0),
	groupbit(0),
	transitionType(0),
	value(0),
	frequency(0),
	transitionInterval(0),
	maxEnergy(0),
	maxExchanges(0),
	maxAttempts(0) { };
	ConcentrationRegulatorType method;
	int type;
	int groupbit;
	int transitionType;
	double value;
	int frequency;
	int transitionInterval;
	double maxEnergy;
	int maxExchanges;
	int maxAttempts;
	std::string transitionTag;
	ESET elemset;
	};

	/** constructor */
	ConcentrationRegulator(ATC_Coupling *atc);
	/** destructor */
	~ConcentrationRegulator();
	/** parser/modifier */
	virtual bool modify(int narg, char **arg);
	/** construct methods */
	virtual void construct_methods();
	/** pre time integration */
	virtual void initialize();

	//WIP_JAT need a nicer way to consistently handle sets of regulators, not sure how yet
	// application steps
	/** apply the regulator in the pre-predictor phase */
	virtual void apply_pre_predictor(double dt, int timeStep){};
	/** apply the regulator in the mid-predictor phase */
	virtual void apply_mid_predictor(double dt, int timeStep){};
	/** apply the regulator in the post-predictor phase */
	virtual void apply_post_predictor(double dt, int timeStep){};
	/** apply the regulator in the pre-correction phase */
	virtual void apply_pre_corrector(double dt, int timeStep){};
	/** apply the regulator in the post-correction phase */
	virtual void apply_post_corrector(double dt, int timeStep){};
	/** compute the thermal boundary flux, must be consistent with regulator */
	virtual void compute_boundary_flux(FIELDS & fields){};
	/** add contributions (if any) to the finite element right-hand side */
	virtual void add_to_rhs(FIELDS & rhs){};

	/** prior to exchanges */
	virtual void pre_force();
	/** prior to exchanges */
	virtual void pre_exchange();
	/** following a run */
	virtual void finish();
	/** ATC output */
	virtual void output(OUTPUT_LIST & outputData) const;
	/** scalar output */
	virtual double compute_vector(int n) const;
	virtual int size_vector(int s) const;

	bool needs_temperature() { return regulators_.size() > 0; }

	protected:
	/** registry charge regulators */
	std::map<std::string,ConcentrationRegulatorMethod *> regulators_;
	std::map<std::string,ConcentrationRegulatorParameters> parameters_;

	private:
	ConcentrationRegulator(); // DO NOT define this
	};

	/**
	* @class ConcentrationRegulatorMethod
	* @brief Base class for ConcentrationRegulator algorithms
	*/

	class ConcentrationRegulatorMethod : public RegulatorShapeFunction {

	public:
	ConcentrationRegulatorMethod(ConcentrationRegulator *c)
	: RegulatorShapeFunction(c) {};
	~ConcentrationRegulatorMethod() {};
	void initialize(void) {};
	virtual void pre_force() {};
	virtual void pre_exchange() {};
	virtual void finish() {};
	virtual void set_weights() {};
	virtual double compute_vector(int n) const { return 0;}
	virtual void output(OUTPUT_LIST & outputData){};
	private:
	ConcentrationRegulatorMethod(); // DO NOT define this
	};

	/**
	* @class ConcentrationRegulatorMethodTransition
	* @brief GCMC + thermodynamic integration
	*/
	class ConcentrationRegulatorMethodTransition : public ConcentrationRegulatorMethod {

	public:
	/** constructor */
	ConcentrationRegulatorMethodTransition(
	ConcentrationRegulator *concentrationRegulator,
	ConcentrationRegulator::ConcentrationRegulatorParameters & parameters);
	/** destructor */
	~ConcentrationRegulatorMethodTransition(){
	if (randomNumberGenerator_) delete randomNumberGenerator_;
	}
	/** initialize */
	void initialize(void);
	/** prior to force evaluation */
	virtual void pre_force();
	/** prior to exchanges */
	virtual void pre_exchange();
	/** "thermo" output */
	virtual double compute_vector(int n) const;
	protected:
	/** set transition state: epsilon and charge */
	int mask(int type, int groupbit) {return 0;}
	int count(void) const;
	int excess(void) const;
	double energy(int id) const;
	double energy(double * x) const;
	double insertion_location(DENS_VEC & x) const;
	double deletion_id(ID_PAIR & id) const ;
	double deletion_id_consistent(ID_PAIR & id) const ;
	double deletion_id_free(ID_PAIR & id) const ;
	double insertion_factor(int c) const // a ramp
	{
	if (c < transitionInterval_) return ((double) c)/transitionInterval_;
	else return 1.0;
	}
	void transition();
	bool accept(double energy, double T = 0) const;
	bool delete_atoms(int n);
	bool insert_atoms(int n);
	int pick_element() const;
	void pick_coordinates(const int elem, DENS_VEC & xi, DENS_VEC& x ) const;
	void pick_velocity(DENS_VEC & v, const double T ) const;
	double uniform() const;
	double normal() const;

	/** pointer to conc regulator object for data */
	ConcentrationRegulator * concentrationRegulator_;

	/** interscale manager */
	class InterscaleManager * interscaleManager_;

	/** interscale manager */
	class LammpsInterface * lammpsInterface_;

	/** member data */
	class AtomInElementSet * list_;
	double targetConcentration_;
	double targetCount_;
	ESET elemset_;
	POTENTIAL p_;
	RNG_POINTER randomNumberGenerator_;
	DENS_VEC volumes_;
	double V_;
	double q0_;
	int controlType_;
	int controlIndex_;
	int transitionType_;
	int transitionInterval_;;
	int transitionCounter_;
	int nInTransition_;
	double transitionFactor_;
	DENS_VEC epsilon0_;
	ID_LIST deletionIds_, insertionIds_;
	int controlMask_;
	int frequency_;
	double maxEnergy_;
	int maxExchanges_;
	int maxAttempts_;
	int nexchanges_;
	bool initialized_;
	double sigma_;

	void sync_random_number_generators() const;
	mutable int _rngUniformCounter_; // for parallel consistency
	mutable int _rngNormalCounter_; // for parallel consistency

	private:
	ConcentrationRegulatorMethodTransition(); // DO NOT define this
	};
	};
	#endif

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