test_coupling.cpp
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Created: Sat, Aug 3, 10:10

test_coupling.cpp
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	#include "catch.hpp"

	#include "reactmicp/solver/staggers_base/staggers_base.hpp"
	#include "reactmicp/solver/reactive_transport_solver.hpp"

	#include <iostream>

	namespace test_internal
	{

	using namespace specmicp;
	using namespace specmicp::reactmicp;
	using namespace specmicp::reactmicp::solver;


	class TestVariables: public reactmicp::solver::VariablesBase
	{

	public:
	TestVariables(index_t neq):
	m_neq(neq),
	predictor(Vector::Zero(neq)),
	displacement(Vector::Zero(neq)),
	velocity(Vector::Zero(neq)),
	transport_rate(Vector::Zero(neq)),
	chemistry_rate(Vector::Zero(neq))
	{}

	index_t get_neq() {return m_neq;}
	Vector& get_disp() {return displacement;}
	Vector& get_vel() {return velocity;}
	Vector& get_pred() {return predictor;}

	Vector& get_transport_rate() {return transport_rate;}
	Vector& get_chemistry_rate() {return chemistry_rate;}

	void reset_main_variables() {
	const index_t neq = get_neq();
	predictor = Vector::Zero(neq);
	displacement = Vector::Zero(neq);
	velocity = Vector::Zero(neq);
	transport_rate = Vector::Zero(neq);
	chemistry_rate = Vector::Zero(neq);
	}

	private:
	index_t m_neq;
	Vector predictor;
	Vector displacement;
	Vector velocity;
	Vector transport_rate;
	Vector chemistry_rate;
	};

	using TestVariablesPtr = std::shared_ptr<TestVariables>;

	inline TestVariables* castvarptr(VariablesBase* varptr)
	{
	return static_cast<TestVariables * const>(varptr);
	}





	class TransportStagger: public reactmicp::solver::TransportStaggerBase
	{
	public:
	TransportStagger(Matrix the_linear_system):
	linear_system(the_linear_system)
	{}

	//! \brief Initialize the stagger at the beginning of the computation
	virtual void initialize(VariablesBase * const var) override {}

	//! \brief Initialize the stagger at the beginning of an iteration
	virtual void initialize_timestep(scalar_t dt, VariablesBase * const var) override
	{
	TestVariables * const truevar = castvarptr(var);
	truevar->get_pred() = truevar->get_disp();
	truevar->get_vel().setZero();
	m_dt = dt;
	}

	//! \brief Solve the equation for the timestep
	StaggerReturnCode restart_timestep(VariablesBase * const var) override
	{
	TestVariables * const truevar = castvarptr(var);

	truevar->get_transport_rate() = linear_system * truevar->get_disp();
	truevar->get_vel() = truevar->get_transport_rate() + truevar->get_chemistry_rate();

	truevar->get_disp() = truevar->get_pred() + m_dt*truevar->get_vel();

	return StaggerReturnCode::ResidualMinimized;
	}

	//! \brief Compute the residuals norm
	scalar_t get_residual(VariablesBase * const var) override
	{
	TestVariables * const truevar = castvarptr(var);
	Vector residuals = truevar->get_vel() - linear_system * truevar->get_disp() - truevar->get_chemistry_rate();
	return residuals.norm();
	}

	//! \brief Compute the residuals norm
	scalar_t get_residual_0(VariablesBase* const var) override
	{
	TestVariables * const truevar = castvarptr(var);
	Vector residuals = truevar->get_vel() - linear_system * truevar->get_disp() - truevar->get_chemistry_rate();
	return residuals.norm();
	}

	scalar_t get_update(VariablesBase* const var) override
	{
	TestVariables * const truevar = castvarptr(var);
	return truevar->get_vel().norm();
	}

	private:
	scalar_t m_dt;
	Matrix linear_system;
	};

	class ChemistryStagger: public reactmicp::solver::ChemistryStaggerBase
	{
	public:
	ChemistryStagger(Matrix the_linear_system):
	linear_system(the_linear_system)
	{}

	//! \brief Initialize the stagger at the beginning of the computation
	virtual void initialize(VariablesBase * const var) override {}

	//! \brief Initialize the stagger at the beginning of an iteration
	virtual void initialize_timestep(
	scalar_t dt,
	VariablesBase * const var
	) override
	{
	m_dt = dt;
	}

	//! \brief Solve the equation for the timestep
	virtual StaggerReturnCode restart_timestep(
	VariablesBase * const var) override
	{
	TestVariables * const truevar = castvarptr(var);

	truevar->get_chemistry_rate() = linear_system * truevar->get_disp();
	truevar->get_vel() = truevar->get_transport_rate() + truevar->get_chemistry_rate();

	truevar->get_disp() = truevar->get_pred() + m_dt*truevar->get_vel();

	return StaggerReturnCode::ResidualMinimized;
	}

	private:
	scalar_t m_dt;
	Matrix linear_system;
	};

	class VoidUpscalingStagger: public UpscalingStaggerBase
	{

	public:

	scalar_t tot_time = 0;

	//! \brief Initialize the stagger at the beginning of the computation
	virtual void initialize(VariablesBase * const var) override {}

	//! \brief Initialize the stagger at the beginning of an iteration
	virtual void initialize_timestep(
	scalar_t dt,
	VariablesBase * const var
	) override {}

	//! \brief Solve the equation for the timestep
	virtual StaggerReturnCode restart_timestep(
	VariablesBase * const var) override {
	return StaggerReturnCode::ResidualMinimized;
	}

	virtual void set_clock(scalar_t clock_time) {
	tot_time = clock_time;
	}
	};

	} //end namespace test_internal


	TEST_CASE("ReactiveTransport solver", "[solver, fixed point]") {

	SECTION("Test", "") {

	specmicp::index_t neq = 2;

	test_internal::TestVariablesPtr var = std::make_shared<test_internal::TestVariables>(neq);
	var->get_disp() << 3, 1;

	specmicp::Matrix transport_system(neq, neq);
	transport_system << 3, -1, 2, -2;

	specmicp::Matrix chemistry_system(neq, neq);
	chemistry_system << 2, 0, 2, 0;


	std::shared_ptr<specmicp::reactmicp::solver::TransportStaggerBase> tstag =
	std::make_shared<test_internal::TransportStagger>(transport_system);

	std::shared_ptr<specmicp::reactmicp::solver::ChemistryStaggerBase> cstag =
	std::make_shared<test_internal::ChemistryStagger>(chemistry_system);

	std::shared_ptr<specmicp::reactmicp::solver::UpscalingStaggerBase> ustag =
	std::make_shared<test_internal::VoidUpscalingStagger>();

	specmicp::reactmicp::solver::ReactiveTransportSolver solver(tstag, cstag, ustag);
	solver.get_options().maximum_iterations = 100;

	solver.set_clock(0.1);
	CHECK(static_cast<test_internal::VoidUpscalingStagger*>(ustag.get())->tot_time == 0.1);
	specmicp::reactmicp::solver::ReactiveTransportReturnCode retcode = solver.solve_timestep(0.1, var);

	REQUIRE(retcode > specmicp::reactmicp::solver::ReactiveTransportReturnCode::NotConvergedYet);

	std::cout << "nb iterations 1 : " << solver.get_perfs().nb_iterations
	<< " - residuals : " << solver.get_perfs().residuals << std::endl;

	solver.set_clock(0.2);
	CHECK(static_cast<test_internal::VoidUpscalingStagger*>(ustag.get())->tot_time == 0.2);
	retcode = solver.solve_timestep(0.1, var);


	REQUIRE(retcode > specmicp::reactmicp::solver::ReactiveTransportReturnCode::NotConvergedYet);

	std::cout << "nb iterations 2 : " << solver.get_perfs().nb_iterations
	<< " - residuals : " << solver.get_perfs().residuals << std::endl;

	}
	}

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