mpi_test_solver_newton_cg.cc
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Created: Sat, Apr 27, 16:07

mpi_test_solver_newton_cg.cc
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	/**
	* @file test_solver_newton_cg.cc
	*
	* @author Till Junge <till.junge@epfl.ch>
	*
	* @date 20 Dec 2017
	*
	* @brief Tests for the standard Newton-Raphson + Conjugate Gradient solver
	*
	* Copyright © 2017 Till Junge
	*
	* µSpectre is free software; you can redistribute it and/or
	* modify it under the terms of the GNU General Public License as
	* published by the Free Software Foundation, either version 3, or (at
	* your option) any later version.
	*
	* µSpectre is distributed in the hope that it will be useful, but
	* WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with µSpectre; see the file COPYING. If not, write to the
	* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
	* Boston, MA 02111-1307, USA.
	*/

	#include "tests.hh"
	#include "mpi_context.hh"
	#include "solver/deprecated_solvers.hh"
	#include "solver/deprecated_solver_cg.hh"
	#include "solver/deprecated_solver_cg_eigen.hh"
	#include "fft/fftwmpi_engine.hh"
	#include "fft/projection_finite_strain_fast.hh"
	#include "materials/material_linear_elastic1.hh"
	#include "common/iterators.hh"
	#include "common/ccoord_operations.hh"
	#include "cell/cell_factory.hh"

	namespace muSpectre {

	BOOST_AUTO_TEST_SUITE(newton_cg_tests);

	BOOST_AUTO_TEST_CASE(manual_construction_test) {
	const Communicator & comm = MPIContext::get_context().comm;

	// constexpr Dim_t dim{twoD};
	constexpr Dim_t dim{threeD};

	// constexpr Ccoord_t<dim> resolutions{3, 3};
	// constexpr Rcoord_t<dim> lengths{2.3, 2.7};
	constexpr Ccoord_t<dim> resolutions{5, 5, 5};
	constexpr Rcoord_t<dim> lengths{5, 5, 5};
	auto fft_ptr{std::make_unique<FFTWMPIEngine<dim>>(resolutions, dim*dim, comm)};
	auto proj_ptr{std::make_unique<ProjectionFiniteStrainFast<dim, dim>>(std::move(fft_ptr), lengths)};
	CellBase<dim, dim> sys(std::move(proj_ptr));

	using Mat_t = MaterialLinearElastic1<dim, dim>;
	//const Real Young{210e9}, Poisson{.33};
	const Real Young{1.0030648180242636}, Poisson{0.29930675909878679};
	// const Real lambda{YoungPoisson/((1+Poisson)(1-2*Poisson))};
	// const Real mu{Young/(2*(1+Poisson))};

	auto& Material_hard = Mat_t::make(sys, "hard", 10*Young, Poisson);
	auto& Material_soft = Mat_t::make(sys, "soft", Young, Poisson);

	auto& loc = sys.get_subdomain_locations();
	for (auto && tup: akantu::enumerate(sys)) {
	auto && pixel = std::get<1>(tup);
	if (loc == Ccoord_t<threeD>{0, 0} && std::get<0>(tup) == 0) {
	Material_hard.add_pixel(pixel);
	} else {
	Material_soft.add_pixel(pixel);
	}
	}
	sys.initialise();

	Grad_t<dim> delF0;
	delF0 << 0, 1., 0, 0, 0, 0, 0, 0, 0;
	constexpr Real cg_tol{1e-8}, newton_tol{1e-5};
	constexpr Uint maxiter{CcoordOps::get_size(resolutions)ipow(dim, secondOrder)10};
	constexpr bool verbose{false};

	GradIncrements<dim> grads; grads.push_back(delF0);
	DeprecatedSolverCG<dim> cg{sys, cg_tol, maxiter, bool(verbose)};
	Eigen::ArrayXXd res1{deprecated_de_geus(sys, grads, cg, newton_tol, verbose)[0].grad};

	DeprecatedSolverCG<dim> cg2{sys, cg_tol, maxiter, bool(verbose)};
	Eigen::ArrayXXd res2{deprecated_newton_cg(sys, grads, cg2, newton_tol, verbose)[0].grad};
	BOOST_CHECK_LE(abs(res1-res2).mean(), cg_tol);
	}

	BOOST_AUTO_TEST_CASE(small_strain_patch_test) {
	const Communicator & comm = MPIContext::get_context().comm;
	constexpr Dim_t dim{twoD};
	using Ccoord = Ccoord_t<dim>;
	using Rcoord = Rcoord_t<dim>;
	constexpr Ccoord resolutions{CcoordOps::get_cube<dim>(3)};
	constexpr Rcoord lengths{CcoordOps::get_cube<dim>(1.)};
	constexpr Formulation form{Formulation::small_strain};

	// number of layers in the hard material
	constexpr Uint nb_lays{1};
	constexpr Real contrast{2};
	static_assert(nb_lays < resolutions[0],
	"the number or layers in the hard material must be smaller "
	"than the total number of layers in dimension 0");

	auto sys{make_parallel_cell(resolutions, lengths, form, comm)};

	using Mat_t = MaterialLinearElastic1<dim, dim>;
	constexpr Real Young{2.}, Poisson{.33};
	auto material_hard{std::make_unique<Mat_t>("hard", contrast*Young, Poisson)};
	auto material_soft{std::make_unique<Mat_t>("soft", Young, Poisson)};

	for (const auto & pixel: sys) {
	if (pixel[0] < Dim_t(nb_lays)) {
	material_hard->add_pixel(pixel);
	} else {
	material_soft->add_pixel(pixel);
	}
	}

	sys.add_material(std::move(material_hard));
	sys.add_material(std::move(material_soft));
	sys.initialise();

	Grad_t<dim> delEps0{Grad_t<dim>::Zero()};
	constexpr Real eps0 = 1.;
	//delEps0(0, 1) = delEps0(1, 0) = eps0;
	delEps0(0, 0) = eps0;

	constexpr Real cg_tol{1e-8}, newton_tol{1e-5}, equil_tol{1e-10};
	constexpr Uint maxiter{dim*10};
	constexpr Dim_t verbose{0};

	DeprecatedSolverCGEigen<dim> cg{sys, cg_tol, maxiter, bool(verbose)};
	auto result = deprecated_de_geus(sys, delEps0, cg, newton_tol,
	equil_tol, verbose);
	if (verbose) {
	std::cout << "result:" << std::endl << result.grad << std::endl;
	std::cout << "mean strain = " << std::endl
	<< sys.get_strain().get_map().mean() << std::endl;
	}

	/**
	* verification of resultant strains: subscript ₕ for hard and ₛ
	* for soft, Nₕ is nb_lays and Nₜₒₜ is resolutions, k is contrast
	*
	* Δl = εl = Δlₕ + Δlₛ = εₕlₕ+εₛlₛ
	* => ε = εₕ Nₕ/Nₜₒₜ + εₛ (Nₜₒₜ-Nₕ)/Nₜₒₜ
	*
	* σ is constant across all layers
	* σₕ = σₛ
	* => Eₕ εₕ = Eₛ εₛ
	* => εₕ = 1/k εₛ
	* => ε / (1/k Nₕ/Nₜₒₜ + (Nₜₒₜ-Nₕ)/Nₜₒₜ) = εₛ
	*/
	constexpr Real factor{1/contrast * Real(nb_lays)/resolutions[0]
	+ 1.-nb_lays/Real(resolutions[0])};
	constexpr Real eps_soft{eps0/factor};
	constexpr Real eps_hard{eps_soft/contrast};
	if (verbose) {
	std::cout << "εₕ = " << eps_hard << ", εₛ = " << eps_soft << std::endl;
	std::cout << "ε = εₕ Nₕ/Nₜₒₜ + εₛ (Nₜₒₜ-Nₕ)/Nₜₒₜ" << std::endl;
	}
	Grad_t<dim> Eps_hard; Eps_hard << eps_hard, 0, 0, 0;
	Grad_t<dim> Eps_soft; Eps_soft << eps_soft, 0, 0, 0;

	// verify uniaxial tension patch test
	for (const auto & pixel: sys) {
	if (pixel[0] < Dim_t(nb_lays)) {
	BOOST_CHECK_LE((Eps_hard-sys.get_strain().get_map()[pixel]).norm(), tol);
	} else {
	BOOST_CHECK_LE((Eps_soft-sys.get_strain().get_map()[pixel]).norm(), tol);
	}
	}

	delEps0 = Grad_t<dim>::Zero();
	delEps0(0, 1) = delEps0(1, 0) = eps0;

	DeprecatedSolverCG<dim> cg2{sys, cg_tol, maxiter, bool(verbose)};
	result = deprecated_newton_cg(sys, delEps0, cg2, newton_tol,
	equil_tol, verbose);
	Eps_hard << 0, eps_hard, eps_hard, 0;
	Eps_soft << 0, eps_soft, eps_soft, 0;

	// verify pure shear patch test
	for (const auto & pixel: sys) {
	if (pixel[0] < Dim_t(nb_lays)) {
	BOOST_CHECK_LE((Eps_hard-sys.get_strain().get_map()[pixel]).norm(), tol);
	} else {
	BOOST_CHECK_LE((Eps_soft-sys.get_strain().get_map()[pixel]).norm(), tol);
	}
	}
	}

	BOOST_AUTO_TEST_SUITE_END();

	} // muSpectre

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