/******************************************************** * ██████╗ ██████╗████████╗██╗ * ██╔════╝ ██╔════╝╚══██╔══╝██║ * ██║ ███╗██║ ██║ ██║ * ██║ ██║██║ ██║ ██║ * ╚██████╔╝╚██████╗ ██║ ███████╗ * ╚═════╝ ╚═════╝ ╚═╝ ╚══════╝ * Geophysical Computational Tools & Library (GCTL) * * Copyright (c) 2022 Yi Zhang (yizhang-geo@zju.edu.cn) * * GCTL is distributed under a dual licensing scheme. You can redistribute * it and/or modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation, either version 2 * of the License, or (at your option) any later version. You should have * received a copy of the GNU Lesser General Public License along with this * program. If not, see . * * If the terms and conditions of the LGPL v.2. would prevent you from using * the GCTL, please consider the option to obtain a commercial license for a * fee. These licenses are offered by the GCTL's original author. As a rule, * licenses are provided "as-is", unlimited in time for a one time fee. Please * send corresponding requests to: yizhang-geo@zju.edu.cn. Please do not forget * to include some description of your company and the realm of its activities. * Also add information on how to contact you by electronic and paper mail. ******************************************************/ #include "gm_tet_mesh.h" gctl::gm_tetrahedron_mesh::gm_tetrahedron_mesh(){} gctl::gm_tetrahedron_mesh::gm_tetrahedron_mesh(std::string in_name, std::string in_info, const array &in_nodes, const array &in_tets) : tetrahedron_mesh::tetrahedron_mesh(in_name, in_info, in_nodes, in_tets){} gctl::gm_tetrahedron_mesh::~gm_tetrahedron_mesh(){} void gctl::gm_tetrahedron_mesh::gkernel(matrix &out_kernel, const array &obsp, gravitational_field_type_e comp_id, verbose_type_e verbose) { int e_num = get_elenum(); grav_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(grav_ele_.get(i), elements.get(i)); } callink_gravity_para(grav_ele_, grav_para_); gctl::gkernel(out_kernel, grav_ele_, obsp, comp_id, verbose); return; } void gctl::gm_tetrahedron_mesh::gkernel(matrix &out_kernel, const array &obsp, gravitational_field_type_e comp_id, verbose_type_e verbose) { int e_num = get_elenum(); grav_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(grav_ele_.get(i), elements.get(i)); } callink_gravity_para(grav_ele_, grav_para_); gctl::gkernel(out_kernel, grav_ele_, obsp, comp_id, verbose); return; } void gctl::gm_tetrahedron_mesh::gobser(array &out_obs, std::string data_name, const array &obsp, verbose_type_e verbose) { array rho(get_elenum(), 0.0); meshdata &data = get_data(data_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { rho[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::gobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); grav_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(grav_ele_.get(i), elements.get(i)); } callink_gravity_para(grav_ele_, grav_para_); gctl::gobser(out_obs, grav_ele_, obsp, rho, verbose); return; } void gctl::gm_tetrahedron_mesh::gobser(array &out_obs, std::string data_name, const array &obsp, verbose_type_e verbose) { array rho(get_elenum(), 0.0); meshdata &data = get_data(data_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { rho[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::gobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); grav_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(grav_ele_.get(i), elements.get(i)); } callink_gravity_para(grav_ele_, grav_para_); gctl::gobser(out_obs, grav_ele_, obsp, rho, verbose); return; } void gctl::gm_tetrahedron_mesh::gobser(array &out_obs, std::string data_name, const array &obsp, verbose_type_e verbose) { array rho(get_elenum(), 0.0); meshdata &data = get_data(data_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { rho[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::gobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); grav_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(grav_ele_.get(i), elements.get(i)); } callink_gravity_para(grav_ele_, grav_para_); gctl::gobser(out_obs, grav_ele_, obsp, rho, verbose); return; } void gctl::gm_tetrahedron_mesh::gobser(array &out_obs, std::string data_name, const array &obsp, verbose_type_e verbose) { array rho(get_elenum(), 0.0); meshdata &data = get_data(data_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { rho[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::gobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); grav_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(grav_ele_.get(i), elements.get(i)); } callink_gravity_para(grav_ele_, grav_para_); gctl::gobser(out_obs, grav_ele_, obsp, rho, verbose); return; } void gctl::gm_tetrahedron_mesh::gobser(array &out_obs, std::string data_name, const array &obsp, verbose_type_e verbose) { array rho(get_elenum(), 0.0); meshdata &data = get_data(data_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { rho[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::gobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); grav_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(grav_ele_.get(i), elements.get(i)); } callink_gravity_para(grav_ele_, grav_para_); gctl::gobser(out_obs, grav_ele_, obsp, rho, verbose); return; } void gctl::gm_tetrahedron_mesh::gobser(array &out_obs, std::string data_name, const array &obsp, verbose_type_e verbose) { array rho(get_elenum(), 0.0); meshdata &data = get_data(data_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { rho[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::gobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); grav_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(grav_ele_.get(i), elements.get(i)); } callink_gravity_para(grav_ele_, grav_para_); gctl::gobser(out_obs, grav_ele_, obsp, rho, verbose); return; } void gctl::gm_tetrahedron_mesh::magkernel(matrix &out_kernel, std::string sus_name, const array &obsp, double inclina_deg, double declina_deg, verbose_type_e verbose) { meshdata &data = get_data(sus_name); mesh_data_value_e vtype = data.valtype_; array sus(get_elenum(), 0.0); if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { sus[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_earth(mag_ele_, mag_para_, inclina_deg, declina_deg); gctl::magkernel(out_kernel, mag_ele_, obsp, verbose); return; } void gctl::gm_tetrahedron_mesh::magkernel(matrix &out_kernel, std::string sus_name, const array &obsp, double inclina_deg, double declina_deg, verbose_type_e verbose) { meshdata &data = get_data(sus_name); mesh_data_value_e vtype = data.valtype_; array sus(get_elenum(), 0.0); if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { sus[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_earth(mag_ele_, mag_para_, inclina_deg, declina_deg); gctl::magkernel(out_kernel, mag_ele_, obsp, verbose); return; } void gctl::gm_tetrahedron_mesh::magkernel(matrix &out_kernel, std::string sus_name, const array &obsp, double inclina_deg, double declina_deg, verbose_type_e verbose) { meshdata &data = get_data(sus_name); mesh_data_value_e vtype = data.valtype_; array sus(get_elenum(), 0.0); if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { sus[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_earth(mag_ele_, mag_para_, inclina_deg, declina_deg); gctl::magkernel(out_kernel, mag_ele_, obsp, verbose); return; } void gctl::gm_tetrahedron_mesh::magobser(array &out_obs, std::string sus_name, const array &obsp, double inclina_deg, double declina_deg, verbose_type_e verbose) { meshdata &data = get_data(sus_name); mesh_data_value_e vtype = data.valtype_; array sus(get_elenum(), 0.0); if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { sus[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_earth(mag_ele_, mag_para_, inclina_deg, declina_deg); gctl::magobser(out_obs, mag_ele_, obsp, sus, verbose); return; } void gctl::gm_tetrahedron_mesh::magobser(array &out_obs, std::string sus_name, const array &obsp, double inclina_deg, double declina_deg, verbose_type_e verbose) { meshdata &data = get_data(sus_name); mesh_data_value_e vtype = data.valtype_; array sus(get_elenum(), 0.0); if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { sus[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_earth(mag_ele_, mag_para_, inclina_deg, declina_deg); gctl::magobser(out_obs, mag_ele_, obsp, sus, verbose); return; } void gctl::gm_tetrahedron_mesh::magobser(array &out_obs, std::string sus_name, const array &obsp, double inclina_deg, double declina_deg, verbose_type_e verbose) { meshdata &data = get_data(sus_name); mesh_data_value_e vtype = data.valtype_; array sus(get_elenum(), 0.0); if (vtype == Scalar) { for (int i = 0; i < data.datval_.size(); i++) { if (!std::isnan(data.datval_[i])) { sus[i] = data.datval_[i]; } } } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magobser(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_earth(mag_ele_, mag_para_, inclina_deg, declina_deg); gctl::magobser(out_obs, mag_ele_, obsp, sus, verbose); return; } void gctl::gm_tetrahedron_mesh::magobser(array &out_obs, std::string magz_name, const array &obsp, verbose_type_e verbose) { array magz(get_elenum(), point3dc(0.0, 0.0, 0.0)); meshdata &data = get_data(magz_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Vector) { magz = data.export_vector(); } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magkernel(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_direct(mag_ele_, mag_para_, magz); gctl::magobser(out_obs, mag_ele_, obsp, verbose); return; } void gctl::gm_tetrahedron_mesh::magobser(array &out_obs, std::string magz_name, const array &obsp, verbose_type_e verbose) { array magz(get_elenum(), point3dc(0.0, 0.0, 0.0)); meshdata &data = get_data(magz_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Vector) { magz = data.export_vector(); } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magkernel(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_direct(mag_ele_, mag_para_, magz); gctl::magobser(out_obs, mag_ele_, obsp, verbose); return; } void gctl::gm_tetrahedron_mesh::magobser(array &out_obs, std::string magz_name, const array &obsp, verbose_type_e verbose) { array magz(get_elenum(), point3dc(0.0, 0.0, 0.0)); meshdata &data = get_data(magz_name); mesh_data_value_e vtype = data.valtype_; if (vtype == Vector) { magz = data.export_vector(); } else { std::string err_str = "Unsupported data value type. From gctl::gm_tetrahedron_mesh::magkernel(...)"; throw runtime_error(err_str); } int e_num = get_elenum(); mag_ele_.resize(e_num); for (size_t i = 0; i < e_num; i++) { copy_type_tetrahedron(mag_ele_.get(i), elements.get(i)); } callink_magnetic_para_direct(mag_ele_, mag_para_, magz); gctl::magobser(out_obs, mag_ele_, obsp, verbose); return; }