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Created: Mon, May 20, 10:01

reactive_transport_solver.cpp
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	#include "reactive_transport_solver.hpp"

	#include "staggers_base/staggers_base.hpp"

	#include "utils/log.hpp"

	#include "utils/timer.hpp"

	namespace specmicp {
	namespace reactmicp {
	namespace solver {

	namespace internal {

	// This contains internal information for the reactive transport solver
	// It is used to check the convergence
	struct ReactiveTransportResiduals
	{
	index_t nb_iterations;
	scalar_t transport_residual_0;
	scalar_t transport_residuals;
	scalar_t update;

	ReactiveTransportResiduals():
	nb_iterations(0),
	transport_residual_0(-1),
	transport_residuals(-1),
	update(-1)
	{}
	};

	} // end namespace internal

	// ReactiveTransportSolver::

	// Solve a timestep
	//
	// Attention : This function uses goto to handle return code and performance
	ReactiveTransportReturnCode ReactiveTransportSolver::solve_timestep(
	scalar_t timestep,
	VariablesBasePtr variables
	)
	{
	// start the timer
	Timer tot_timer;
	tot_timer.start();
	// initialization
	internal::ReactiveTransportResiduals residuals;
	reset_perfs();
	get_perfs().timestep = timestep;

	// copy of variables // ?
	m_transport_stagger->initialize_timestep(timestep, variables);
	m_chemistry_stagger->initialize_timestep(timestep, variables);
	m_upscaling_stagger->initialize_timestep(timestep, variables);

	//
	residuals.transport_residual_0 = m_transport_stagger->get_residual_0(variables);

	ReactiveTransportReturnCode retcode = one_iteration(variables, residuals);
	// check for failure
	if (retcode < ReactiveTransportReturnCode::StaggerFailure)
	{
	ERROR << "Failed to solve the iteration, return code : " << (int) retcode;
	goto set_return;
	}

	retcode = check_convergence(variables, residuals);

	++residuals.nb_iterations;
	// if sequential non-iterative algorithm
	if (get_options().is_snia())
	{
	goto end;
	}
	// else
	while (retcode == ReactiveTransportReturnCode::NotConvergedYet)
	{
	retcode = one_iteration(variables, residuals);
	// check for failure
	if (retcode < ReactiveTransportReturnCode::StaggerFailure)
	{
	ERROR << "Failed to solve the iteration, return code : " << (int) retcode;
	goto set_return;
	}

	retcode = check_convergence(variables, residuals);
	++residuals.nb_iterations;

	}
	// wrapup
	end:

	// upscaling, if needed
	if (not get_options().implicit_upscaling)
	{
	Timer timer;

	timer.start();
	m_upscaling_stagger->restart_timestep(variables);
	timer.stop();
	m_timer.upscaling_time += timer.elapsed_time();
	}
	// record performance and return code
	set_return:

	tot_timer.stop();

	get_perfs().total_time = tot_timer.elapsed_time();
	get_perfs().nb_iterations = residuals.nb_iterations;
	get_perfs().return_code = retcode;
	get_perfs().residuals = residuals.transport_residuals/residuals.transport_residual_0;

	return retcode;
	}

	ReactiveTransportReturnCode ReactiveTransportSolver::one_iteration(
	VariablesBasePtr variables,
	internal::ReactiveTransportResiduals& residuals
	)
	{
	Timer timer;

	// Transport
	// ---------
	timer.start();
	StaggerReturnCode transport_ret_code = m_transport_stagger->restart_timestep(variables);
	if (transport_ret_code <= StaggerReturnCode::NotConvergedYet)
	{
	return ReactiveTransportReturnCode::TransportFailure;
	}
	timer.stop();
	const scalar_t ttime = timer.elapsed_time();
	m_timer.transport_time += ttime;
	get_perfs().transport_time += ttime;

	// Chemistry
	// ---------

	timer.start();
	StaggerReturnCode chemistry_ret_code = m_chemistry_stagger->restart_timestep(variables);
	if (chemistry_ret_code <= StaggerReturnCode::NotConvergedYet)
	{
	return ReactiveTransportReturnCode::ChemistryFailure;
	}
	timer.stop();
	const scalar_t ctime = timer.elapsed_time();
	m_timer.chemistry_time += ctime;
	get_perfs().chemistry_time += ctime;

	// Upscaling0
	// ---------
	if (get_options().implicit_upscaling)
	{
	timer.start();
	StaggerReturnCode upscaling_ret_code = m_upscaling_stagger->restart_timestep(variables);
	if (upscaling_ret_code <= StaggerReturnCode::NotConvergedYet)
	{
	return ReactiveTransportReturnCode::UpscalingFailure;
	}
	timer.stop();
	m_timer.upscaling_time += timer.elapsed_time();
	}
	// Final residuals
	// ---------------
	residuals.transport_residuals = m_transport_stagger->get_residual(variables);
	residuals.update = m_transport_stagger->get_update(variables);
	return ReactiveTransportReturnCode::NotConvergedYet;
	}

	// Check the convergence
	ReactiveTransportReturnCode ReactiveTransportSolver::check_convergence(
	VariablesBasePtr _,
	const internal::ReactiveTransportResiduals& residuals
	)
	{
	// Residual
	if (residuals.transport_residuals/residuals.transport_residual_0 < get_options().residuals_tolerance
	or residuals.transport_residuals < get_options().absolute_residuals_tolerance)
	{
	return ReactiveTransportReturnCode::ResidualMinimized;
	}
	// Step
	if (residuals.update < get_options().step_tolerance)
	{
	if (residuals.transport_residuals/residuals.transport_residual_0 < get_options().good_enough_tolerance)
	{
	return ReactiveTransportReturnCode::ErrorMinimized;
	}
	else
	return ReactiveTransportReturnCode::StationaryPoint;
	}
	// Number of iterations
	if (residuals.nb_iterations >= get_options().maximum_iterations)
	{
	return ReactiveTransportReturnCode::MaximumIterationsReached;
	}
	return ReactiveTransportReturnCode::NotConvergedYet;
	}

	} // end namespace solver
	} // end namespace reactmicp
	} // end namespace specmicp

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