XT_Function.cpp
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Created: Thu, Jul 11, 16:33

XT_Function.cpp
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	#include "XT_Function.h"
	#include "ATC_Error.h"

	namespace ATC {

	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// XT_Function
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	XT_Function::XT_Function(int narg, double* args)
	{
	// NOTE need to adjust scaling to match input nodal coordinates
	if (narg > 5 ) { // NOTE kludge for temporal only functions
	x0[0] = args[0];
	x0[1] = args[1];
	x0[2] = args[2];
	mask[0] = args[3];
	mask[1] = args[4];
	mask[2] = args[5];
	}
	else {
	x0[0] = 0.0;
	x0[1] = 0.0;
	x0[2] = 0.0;
	mask[0] = 0.0;
	mask[1] = 0.0;
	mask[2] = 0.0;
	}
	}
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// XT_Function_Mgr
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	XT_Function_Mgr * XT_Function_Mgr::myInstance_ = NULL;

	// -----------------------------------------------------------------
	// instance()
	// -----------------------------------------------------------------
	XT_Function_Mgr * XT_Function_Mgr::instance()
	{
	if (myInstance_ == NULL) {
	myInstance_ = new XT_Function_Mgr();
	}
	return myInstance_;
	}


	// Destructor
	XT_Function_Mgr::~XT_Function_Mgr()
	{
	// Delete all functions created using "new"
	for (int i = 0; i < xtFunctionVec_.size(); i++) {
	delete xtFunctionVec_[i];
	}
	}

	// add user function into the if statement and assign returnFunction to it
	XT_Function* XT_Function_Mgr::get_function(string & type, int nargs, double * args)
	{
	XT_Function * returnFunction;
	if (type=="constant") {
	returnFunction = new ConstantFunction(nargs,args);
	}
	else if (type=="temporal_ramp") {
	returnFunction = new TemporalRamp(nargs,args);
	}
	else if (type=="linear")
	returnFunction = new LinearFunction(nargs,args);
	else if (type=="quadratic")
	returnFunction = new QuadraticFunction(nargs,args);
	else if (type=="sine")
	returnFunction = new SineFunction(nargs,args);
	else if (type=="gaussian")
	returnFunction = new GaussianFunction(nargs,args);
	else if (type=="gaussian_temporal_ramp")
	returnFunction = new GaussianTemporalRamp(nargs,args);
	else
	throw ATC_Error(0,"Bad user function name");

	xtFunctionVec_.push_back(returnFunction);

	return returnFunction;
	}

	// add user function into the if statement and assign returnFunction to it
	XT_Function* XT_Function_Mgr::get_function(char ** args, int nargs)
	{
	string type = args[0];
	int narg = nargs -1;
	double dargs[narg];
	for (int i = 0; i < narg; ++i) dargs[i] = atof(args[i+1]);

	return get_function(type, narg, dargs);
	}

	// add constant function
	XT_Function* XT_Function_Mgr::get_constant_function(double c)
	{
	double args[1] = {c}; // NOTE kludge
	XT_Function * returnFunction = new ConstantFunction(1,args);
	xtFunctionVec_.push_back(returnFunction);
	return (returnFunction);
	}

	XT_Function* XT_Function_Mgr::copy_XT_function(XT_Function* other)
	{
	string tag = other->get_tag();

	XT_Function * returnFunction = NULL;
	if (tag=="linear") {
	LinearFunction * other_cast = (LinearFunction*) other;
	returnFunction = new LinearFunction(*other_cast);
	}
	if (tag=="quadratic") {
	QuadraticFunction * other_cast = (QuadraticFunction*) other;
	returnFunction = new QuadraticFunction(*other_cast);
	}
	else if (tag=="sine") {
	SineFunction * other_cast = (SineFunction*) other;
	returnFunction = new SineFunction(*other_cast);
	}
	else if (tag=="gaussian") {
	GaussianFunction * other_cast = (GaussianFunction*) other;
	returnFunction = new GaussianFunction(*other_cast);
	}
	else if (tag=="gaussian_temporal_ramp") {
	GaussianTemporalRamp * other_cast = (GaussianTemporalRamp*) other;
	returnFunction = new GaussianTemporalRamp(*other_cast);
	}
	else if (tag=="temporal_ramp") {
	TemporalRamp * other_cast = (TemporalRamp*) other;
	returnFunction = new TemporalRamp(*other_cast);
	}
	return returnFunction;
	}
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// ConstantFunction
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	ConstantFunction::ConstantFunction(int narg, double* args)
	: XT_Function(narg,args),
	C0(args[0])
	{
	tag = "constant";
	}
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// LinearFunction
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	LinearFunction::LinearFunction(int narg, double* args)
	: XT_Function(narg,args)
	{
	C0 = args[6];
	tag = "linear";
	}
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// QuadraticFunction
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	QuadraticFunction::QuadraticFunction(int narg, double* args)
	: XT_Function(narg,args)
	{
	C0 = args[6];
	C2[0] = args[7];
	C2[1] = args[8];
	C2[2] = args[9];
	C2[3] = args[10];
	C2[4] = args[11];
	C2[5] = args[12];
	tag = "quadratic";
	}
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// SineFunction
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	SineFunction::SineFunction(int narg, double* args)
	: XT_Function(narg,args)
	{
	C = args[6];
	w = args[7];
	tag = "sine";
	}
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// GaussianFunction
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	GaussianFunction::GaussianFunction(int narg, double* args)
	: XT_Function(narg,args)
	{
	tau = args[6];
	C = args[7];
	C0 = args[8];
	tag = "gaussian";
	}
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// GaussianTemporalRamp
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	GaussianTemporalRamp::GaussianTemporalRamp(int narg, double* args)
	: GaussianFunction(narg,args)
	{
	tau_initial = args[9];
	C_initial = args[10];
	C0_initial = args[11];
	double delta_t = args[12];

	tau_slope = (tau - tau_initial)/delta_t;
	C_slope = (C - C_initial)/delta_t;
	C0_slope = (C0 - C0_initial)/delta_t;

	tag = "gaussian_temporal_ramp";
	}
	double GaussianTemporalRamp::f(double* x, double t) {
	tau = tau_initial + tau_slope*t;
	C = C_initial + C_slope*t;
	C0 = C0_initial + C0_slope*t;
	return GaussianFunction::f(x,t);
	}
	double GaussianTemporalRamp::dfdt(double* x, double t) {
	tau = tau_initial + tau_slope*t;
	C = C_initial + C_slope*t;
	C0 = C0_initial + C0_slope*t;
	double dfdt = 0.;
	dfdt += C_slopeexp(-(mask[0](x[0]-x0[0])*(x[0]-x0[0])
	+mask[1](x[1]-x0[1])(x[1]-x0[1])
	+mask[2](x[2]-x0[2])(x[2]-x0[2]))
	/tau/tau);
	dfdt += Cexp(2.tau_slope(mask[0](x[0]-x0[0])*(x[0]-x0[0])
	+mask[1](x[1]-x0[1])(x[1]-x0[1])
	+mask[2](x[2]-x0[2])(x[2]-x0[2]))
	/tau/tau/tau);
	dfdt += C0_slope;
	return dfdt;
	}
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	// TemporalRamp
	//--------------------------------------------------------------------
	//--------------------------------------------------------------------
	TemporalRamp::TemporalRamp(int narg, double* args)
	: XT_Function(narg,args)
	{
	f_initial = args[0];
	double f_final = args[1];
	double delta_t = args[2];
	slope = (f_final - f_initial)/delta_t;
	tag = "temporal_ramp";
	}
	}

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