#include "graph.hpp" // always include corresponding header first /** * Note this included everything from the header similar to copy-pasting it here, * including our two classes, the function declarations and all the includes. * In this file we will actually implement the in- and output routines though, * so we need to include the actual implementation of std::istream and std::ostream. */ #include /** * We are also going to use stringstream in order to treat a line, * which we have already read from the input, like an input stream. */ #include /** * The execption header is used to terminate our program * in the case of unexpected input, * which is often the best way to handle such input. * More complex programs may want to catch exceptions in * surrouding code and either try to recover or help debug them. */ #include #include // Anonymous name spaces may be used to show the reader // that a function will only be used in the current file. namespace { // Using a function for converting the DIMACS node ids to and from our node ids // makes the in and output code more understandable. ED::NodeId from_dimacs_id(ED::size_type dimacs_node_id) { if (dimacs_node_id <= 0) { throw std::runtime_error("Non-positive DIMACS node id can not be converted."); } return dimacs_node_id - 1; } ED::size_type to_dimacs_id(ED::NodeId node_id) { return node_id + 1; } // Returns the first line which is not a comment, i.e. does not start with c. std::string read_next_non_comment_line(std::istream & input) { std::string line; do { if (!std::getline(input, line)) { throw std::runtime_error("Unexpected end of DIMACS stream."); } } while (line[0] == 'c'); return line; } } // end of anonymous namespace namespace ED { ///////////////////////////////////////////// //! \c Node definitions ///////////////////////////////////////////// void Node::add_neighbor(NodeId const id) { _neighbors.push_back(id); } ///////////////////////////////////////////// //! \c Graph definitions ///////////////////////////////////////////// // Whenever reasonably possible you should prefer to use `:` // to initalize the members of your class, instead of // assigning values to them after they were default initialized. // Note you should initialize them in the same order // they were declare in back in the class body! Graph::Graph(NodeId const num_nodes) : _nodes(num_nodes) , _num_edges(0) {} void Graph::add_edge(NodeId node1_id, NodeId node2_id) { // It is ok if your program crashes for garbage input, // but it should be an explicit, deliberate choice, e.g. like this. if (node1_id == node2_id) { throw std::runtime_error("ED::Graph class does not support loops!"); } _nodes[node1_id].add_neighbor(node2_id); _nodes[node2_id].add_neighbor(node1_id); ++_num_edges; } Graph Graph::read_dimacs(std::istream & input) { // Unfortunatley the common std input functions require us to first declare // our variables and assign them the correct values only later. // Because we want to avoid unitizalized variables, we use a new syntax // added in c++17 to call the constuctor with no arguments, // often called the default constructor: We write {} behind the variable name. // When parsing the DIMACS format, there are some words we are not interested in. // We read them into this variable and never use the afterwards. std::string unused_word{}; // As we need to watch out for comments, we first need to read the input by line. // In order to split non-comment lines into multiple variables we use a std::stringstream. std::stringstream first_buffering_stream{}; // Note if you do not plan to modify a variable, always declare it as constant. // This does not only prevent you from doing so accidently, // but also helps anybody reading your code understand what you are doing, // as there are less possiblities what can happen. std::string const first_line = read_next_non_comment_line(input); size_type num_nodes{}; size_type num_edges{}; first_buffering_stream << first_line; first_buffering_stream >> unused_word >> unused_word >> num_nodes >> num_edges; // Now we successively add edges to our graph; Graph graph(num_nodes); for (size_type i = 1; i <= num_edges; ++i) { // This works just as parsing the first line! std::stringstream ith_buffering_stream{}; std::string const ith_line = read_next_non_comment_line(input); size_type dimacs_node1{}; size_type dimacs_node2{}; ith_buffering_stream << ith_line; ith_buffering_stream >> unused_word >> dimacs_node1 >> dimacs_node2; graph.add_edge(from_dimacs_id(dimacs_node1), from_dimacs_id(dimacs_node2)); } return graph; } std::ostream & operator<<(std::ostream & output, Graph const & graph) { // We use std::endl to write new lines here. // If you prefer the new line character, \n on linux, that one works fine, too. output << "p edge " << graph.num_nodes() << " " << graph.num_edges() << std::endl; // We will need the id of the node we are at, so we write a plain old loop here. for (NodeId node_id = 0; node_id < graph.num_nodes(); ++node_id) { Node const & node = graph.node(node_id); // We do not need to keep track of the index neighbor_id has in node, // so we can use this cool loop syntax introduced in c++11. for (NodeId const & neighbor_id : node.neighbors()) { // Note we iterate over each edge two times, so we use the following // comparism to check if the edge was not yet written to str! if (node_id < neighbor_id) { output << "e " << to_dimacs_id(node_id) << " " << to_dimacs_id(neighbor_id) << std::endl; } } } // Streams sometimes buffer their output. // Once one is done with some output routine, it can make sense to flush them, // which clears the buffer and writes the remaining output. output << std::flush; return output; } void Graph::reset_forest() { NodeId cur_id = 0; for(auto & node : _nodes) { node.phi = cur_id; node.rho = cur_id; node.scanned = false; // Note that we do not change the matching itself here ++cur_id; } } void Graph::reset_matching() { NodeId cur_id = 0; for(auto & node : _nodes) { node.matched_neighbor = cur_id; ++cur_id; } } } // namespace ED