/******************************************************** * ██████╗ ██████╗████████╗██╗ * ██╔════╝ ██╔════╝╚══██╔══╝██║ * ██║ ███╗██║ ██║ ██║ * ██║ ██║██║ ██║ ██║ * ╚██████╔╝╚██████╗ ██║ ███████╗ * ╚═════╝ ╚═════╝ ╚═╝ ╚══════╝ * Geophysical Computational Tools & Library (GCTL) * * Copyright (c) 2023 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 "tri2d_mesh.h" void gctl::triangle2d_mesh::init(std::string in_name, std::string in_info, const array &in_nodes_, const array &in_triangles) { check_initiated(true); // 检查是否已经初始化 base_mesh::init(TRI_TET_MESH, MESH_2D, in_name, in_info); node_num_ = in_nodes_.size(); ele_num_ = in_triangles.size(); nodes_.resize(node_num_); for (int i = 0; i < node_num_; i++) { nodes_[i] = in_nodes_[i]; } elems_.resize(ele_num_); for (int i = 0; i < ele_num_; i++) { elems_[i].id = i; for (int j = 0; j < 3; j++) { elems_[i].vert[j] = nodes_.get(in_triangles[i].vert[j]->id); } } initialized_ = true; return; } void gctl::triangle2d_mesh::show_mesh_dimension(std::ostream &os) const { os << "Node num: " << node_num_ << std::endl; os << "Elem num: " << ele_num_ << std::endl; return; } void gctl::triangle2d_mesh::load_binary(std::string filename) { check_initiated(true); // 检查是否已经初始化 std::ifstream infile; gctl::open_infile(infile, filename, ".2m", std::ios::in|std::ios::binary); // 读入网格头信息 load_headinfo(infile, TRI_TET_MESH, MESH_2D); // 读入网格信息 infile.read((char*)&node_num_, sizeof(int)); infile.read((char*)&ele_num_, sizeof(int)); nodes_.resize(node_num_); elems_.resize(ele_num_); for (int i = 0; i < node_num_; i++) { infile.read((char*)nodes_.get(i), sizeof(gctl::vertex2dc)); } int in_index; for (int i = 0; i < ele_num_; i++) { elems_[i].id = i; for (int j = 0; j < 3; j++) { infile.read((char*)&in_index, sizeof(int)); elems_[i].vert[j] = nodes_.get(in_index); } } // 读入模型数据单元 load_datablock(infile); infile.close(); initialized_ = true; return; } void gctl::triangle2d_mesh::save_binary(std::string filename) { check_initiated(); // 检查是否已经初始化 std::ofstream outfile; gctl::open_outfile(outfile, filename, ".2m", std::ios::out|std::ios::binary); // 首先输出网格的头信息 save_headinfo(outfile); // 输出网格信息 outfile.write((char*)&node_num_, sizeof(int)); outfile.write((char*)&ele_num_, sizeof(int)); for (int i = 0; i < node_num_; i++) { outfile.write((char*)nodes_.get(i), sizeof(gctl::vertex2dc)); } int in_index; for (int i = 0; i < ele_num_; i++) { for (int j = 0; j < 3; j++) { in_index = elems_[i].vert[j]->id; outfile.write((char*)&in_index, sizeof(int)); } } // 输出的模型数据单元 save_datablock(outfile); outfile.close(); return; } gctl::triangle2d_mesh::triangle2d_mesh() : base_mesh::base_mesh(){} gctl::triangle2d_mesh::triangle2d_mesh(std::string in_name, std::string in_info, const array &in_nodes_, const array &in_triangles) { init(in_name, in_info, in_nodes_, in_triangles); } gctl::triangle2d_mesh::~triangle2d_mesh(){} const gctl::array &gctl::triangle2d_mesh::get_nodes() const { check_initiated(); // 检查是否已经初始化 return nodes_; } const gctl::array &gctl::triangle2d_mesh::get_elements() const { check_initiated(); // 检查是否已经初始化 return elems_; } void gctl::triangle2d_mesh::reorder2anticlockwise() { check_initiated(); // 检查是否已经初始化 vertex2dc *v_ptr; for (size_t i = 0; i < get_elenum(); i++) { if (cross(*elems_[i].vert[1] - *elems_[i].vert[0], *elems_[i].vert[2] - *elems_[i].vert[0]) < 0) { v_ptr = elems_[i].vert[1]; elems_[i].vert[1] = elems_[i].vert[2]; elems_[i].vert[2] = v_ptr; } } return; } void gctl::triangle2d_mesh::load_triangle(std::string filename, index_packed_e packed) { gctl::read_Triangle_node(filename, nodes_, packed); gctl::read_Triangle_element(filename, elems_, nodes_, packed); // 设置名称与信息等 node_num_ = nodes_.size(); ele_num_ = elems_.size(); base_mesh::init(TRI_TET_MESH, MESH_2D, filename, "Imported from a .node and .ele file."); initialized_ = true; return; } void gctl::triangle2d_mesh::load_gmsh(std::string filename, index_packed_e packed) { meshio_.init_file(filename, Input); meshio_.set_packed(packed, Input); meshio_.read_mesh(elems_, nodes_, &elems_tag_); // 设置名称与信息等 node_num_ = nodes_.size(); ele_num_ = elems_.size(); base_mesh::init(TRI_TET_MESH, MESH_2D, filename, "Imported from a .msh file."); initialized_ = true; return; } void gctl::triangle2d_mesh::load_gmsh_groups() { check_initiated(); // 检查是否已经初始化 meshio_.read_physical_groups(groups_); return; } void gctl::triangle2d_mesh::save_gmsh(std::string filename, index_packed_e packed) { std::ofstream outfile; gctl::open_outfile(outfile, filename, ".msh"); gctl::save2gmsh(outfile, elems_, nodes_, packed); outfile.close(); meshio_.init_file(filename, Output); meshio_.set_packed(packed, Output); meshio_.save_mesh(elems_, nodes_); return; } void gctl::triangle2d_mesh::groups2data(std::string datname, _1s_vector phynames, _1d_vector phyvals) { check_initiated(); // 检查是否已经初始化 if (phynames.size() != phyvals.size() || phynames.empty()) { throw std::invalid_argument("The size of phynames and phyvals must be the same and non-empty."); } if (groups_.empty() || elems_tag_.empty()) { throw std::invalid_argument("No physical groups found."); } if (elems_tag_.empty()) throw std::invalid_argument("No physical tags found."); for (size_t i = 0; i < ele_num_; i++) { if (elems_tag_[i].empty()) throw std::invalid_argument("No physical tags found."); } array tag_idx(phynames.size()); for (size_t i = 0; i < phynames.size(); i++) { tag_idx[i] = meshio_.physical_name2tag(groups_, phynames[i]); } if (saved(datname)) { meshdata &dat = get_data(datname); if (dat.loctype_ != ElemData) throw std::invalid_argument("The data type must be ElemData."); for (size_t i = 0; i < ele_num_; i++) { for (size_t e = 0; e < phynames.size(); e++) { if (elems_tag_[i][0] == tag_idx[e]) { dat.datval_[i] = phyvals[e]; break; } } } } else { meshdata &newdat = add_data(ElemData, Scalar, datname, 0.0); for (size_t i = 0; i < ele_num_; i++) { for (size_t e = 0; e < phynames.size(); e++) { if (elems_tag_[i][0] == tag_idx[e]) { newdat.datval_[i] = phyvals[e]; break; } } } } return; }