// Copyright (C) 2006 Tiago de Paula Peixoto // Copyright (C) 2004 The Trustees of Indiana University. // // Use, modification and distribution is subject to the Boost Software // License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // // Authors: Douglas Gregor // Andrew Lumsdaine // Tiago de Paula Peixoto #ifndef BOOST_GRAPH_GRAPHML_HPP #define BOOST_GRAPH_GRAPHML_HPP #include #include #include #include #include #include // for exceptions #include #include #include #include #include #include #include #include #include namespace boost { ///////////////////////////////////////////////////////////////////////////// // Graph reader exceptions ///////////////////////////////////////////////////////////////////////////// struct BOOST_SYMBOL_VISIBLE parse_error : public graph_exception { parse_error(const std::string& err) { error = err; statement = "parse error: " + error; } ~parse_error() throw() BOOST_OVERRIDE {} const char* what() const throw() BOOST_OVERRIDE { return statement.c_str(); } std::string statement; std::string error; }; class mutate_graph { public: virtual ~mutate_graph() {} virtual bool is_directed() const = 0; virtual boost::any do_add_vertex() = 0; virtual std::pair< boost::any, bool > do_add_edge( boost::any source, boost::any target) = 0; virtual void set_graph_property(const std::string& name, const std::string& value, const std::string& value_type) = 0; virtual void set_vertex_property(const std::string& name, boost::any vertex, const std::string& value, const std::string& value_type) = 0; virtual void set_edge_property(const std::string& name, boost::any edge, const std::string& value, const std::string& value_type) = 0; }; template < typename MutableGraph > class mutate_graph_impl : public mutate_graph { typedef typename graph_traits< MutableGraph >::vertex_descriptor vertex_descriptor; typedef typename graph_traits< MutableGraph >::edge_descriptor edge_descriptor; public: mutate_graph_impl(MutableGraph& g, dynamic_properties& dp) : m_g(g), m_dp(dp) { } bool is_directed() const BOOST_OVERRIDE { return is_convertible< typename graph_traits< MutableGraph >::directed_category, directed_tag >::value; } any do_add_vertex() BOOST_OVERRIDE { return any(add_vertex(m_g)); } std::pair< any, bool > do_add_edge(any source, any target) BOOST_OVERRIDE { std::pair< edge_descriptor, bool > retval = add_edge(any_cast< vertex_descriptor >(source), any_cast< vertex_descriptor >(target), m_g); return std::make_pair(any(retval.first), retval.second); } void set_graph_property(const std::string& name, const std::string& value, const std::string& value_type) BOOST_OVERRIDE { bool type_found = false; try { mpl::for_each< value_types >( put_property< MutableGraph*, value_types >(name, m_dp, &m_g, value, value_type, m_type_names, type_found)); } catch (const bad_lexical_cast&) { BOOST_THROW_EXCEPTION(parse_error("invalid value \"" + value + "\" for key " + name + " of type " + value_type)); } if (!type_found) { BOOST_THROW_EXCEPTION(parse_error( "unrecognized type \"" + value_type + "\" for key " + name)); } } void set_vertex_property(const std::string& name, any vertex, const std::string& value, const std::string& value_type) BOOST_OVERRIDE { bool type_found = false; try { mpl::for_each< value_types >( put_property< vertex_descriptor, value_types >(name, m_dp, any_cast< vertex_descriptor >(vertex), value, value_type, m_type_names, type_found)); } catch (const bad_lexical_cast&) { BOOST_THROW_EXCEPTION(parse_error("invalid value \"" + value + "\" for key " + name + " of type " + value_type)); } if (!type_found) { BOOST_THROW_EXCEPTION(parse_error( "unrecognized type \"" + value_type + "\" for key " + name)); } } void set_edge_property(const std::string& name, any edge, const std::string& value, const std::string& value_type) BOOST_OVERRIDE { bool type_found = false; try { mpl::for_each< value_types >( put_property< edge_descriptor, value_types >(name, m_dp, any_cast< edge_descriptor >(edge), value, value_type, m_type_names, type_found)); } catch (const bad_lexical_cast&) { BOOST_THROW_EXCEPTION(parse_error("invalid value \"" + value + "\" for key " + name + " of type " + value_type)); } if (!type_found) { BOOST_THROW_EXCEPTION(parse_error( "unrecognized type \"" + value_type + "\" for key " + name)); } } template < typename Key, typename ValueVector > class put_property { public: put_property(const std::string& name, dynamic_properties& dp, const Key& key, const std::string& value, const std::string& value_type, const char** type_names, bool& type_found) : m_name(name) , m_dp(dp) , m_key(key) , m_value(value) , m_value_type(value_type) , m_type_names(type_names) , m_type_found(type_found) { } template < class Value > void operator()(Value) { if (m_value_type == m_type_names[mpl::find< ValueVector, Value >::type::pos::value]) { put(m_name, m_dp, m_key, lexical_cast< Value >(m_value)); m_type_found = true; } } private: const std::string& m_name; dynamic_properties& m_dp; const Key& m_key; const std::string& m_value; const std::string& m_value_type; const char** m_type_names; bool& m_type_found; }; protected: MutableGraph& m_g; dynamic_properties& m_dp; typedef mpl::vector< bool, int, long, float, double, std::string > value_types; static const char* m_type_names[]; }; template < typename MutableGraph > const char* mutate_graph_impl< MutableGraph >::m_type_names[] = { "boolean", "int", "long", "float", "double", "string" }; void BOOST_GRAPH_DECL read_graphml( std::istream& in, mutate_graph& g, size_t desired_idx); template < typename MutableGraph > void read_graphml(std::istream& in, MutableGraph& g, dynamic_properties& dp, size_t desired_idx = 0) { mutate_graph_impl< MutableGraph > mg(g, dp); read_graphml(in, mg, desired_idx); } template < typename Types > class get_type_name { public: get_type_name(const std::type_info& type, const char** type_names, std::string& type_name) : m_type(type), m_type_names(type_names), m_type_name(type_name) { } template < typename Type > void operator()(Type) { if (typeid(Type) == m_type) m_type_name = m_type_names[mpl::find< Types, Type >::type::pos::value]; } private: const std::type_info& m_type; const char** m_type_names; std::string& m_type_name; }; template < typename Graph, typename VertexIndexMap > void write_graphml(std::ostream& out, const Graph& g, VertexIndexMap vertex_index, const dynamic_properties& dp, bool ordered_vertices = false) { typedef typename graph_traits< Graph >::directed_category directed_category; typedef typename graph_traits< Graph >::edge_descriptor edge_descriptor; typedef typename graph_traits< Graph >::vertex_descriptor vertex_descriptor; using boost::property_tree::xml_parser::encode_char_entities; BOOST_STATIC_CONSTANT(bool, graph_is_directed = (is_convertible< directed_category*, directed_tag* >::value)); out << "\n" << "\n"; typedef mpl::vector< bool, short, unsigned short, int, unsigned int, long, unsigned long, long long, unsigned long long, float, double, long double, std::string > value_types; const char* type_names[] = { "boolean", "int", "int", "int", "int", "long", "long", "long", "long", "float", "double", "double", "string" }; std::map< std::string, std::string > graph_key_ids; std::map< std::string, std::string > vertex_key_ids; std::map< std::string, std::string > edge_key_ids; int key_count = 0; // Output keys for (dynamic_properties::const_iterator i = dp.begin(); i != dp.end(); ++i) { std::string key_id = "key" + lexical_cast< std::string >(key_count++); if (i->second->key() == typeid(Graph*)) graph_key_ids[i->first] = key_id; else if (i->second->key() == typeid(vertex_descriptor)) vertex_key_ids[i->first] = key_id; else if (i->second->key() == typeid(edge_descriptor)) edge_key_ids[i->first] = key_id; else continue; std::string type_name = "string"; mpl::for_each< value_types >(get_type_name< value_types >( i->second->value(), type_names, type_name)); out << " second->key() == typeid(Graph*) ? "graph" : (i->second->key() == typeid(vertex_descriptor) ? "node" : "edge")) << "\"" << " attr.name=\"" << i->first << "\"" << " attr.type=\"" << type_name << "\"" << " />\n"; } out << " \n"; // Output graph data for (dynamic_properties::const_iterator i = dp.begin(); i != dp.end(); ++i) { if (i->second->key() == typeid(Graph*)) { // The const_cast here is just to get typeid correct for property // map key; the graph should not be mutated using it. out << " first] << "\">" << encode_char_entities( i->second->get_string(const_cast< Graph* >(&g))) << "\n"; } } typedef typename graph_traits< Graph >::vertex_iterator vertex_iterator; vertex_iterator v, v_end; for (boost::tie(v, v_end) = vertices(g); v != v_end; ++v) { out << " \n"; // Output data for (dynamic_properties::const_iterator i = dp.begin(); i != dp.end(); ++i) { if (i->second->key() == typeid(vertex_descriptor)) { out << " first] << "\">" << encode_char_entities(i->second->get_string(*v)) << "\n"; } } out << " \n"; } typedef typename graph_traits< Graph >::edge_iterator edge_iterator; edge_iterator e, e_end; typename graph_traits< Graph >::edges_size_type edge_count = 0; for (boost::tie(e, e_end) = edges(g); e != e_end; ++e) { out << " \n"; // Output data for (dynamic_properties::const_iterator i = dp.begin(); i != dp.end(); ++i) { if (i->second->key() == typeid(edge_descriptor)) { out << " first] << "\">" << encode_char_entities(i->second->get_string(*e)) << "\n"; } } out << " \n"; } out << " \n" << "\n"; } template < typename Graph > void write_graphml(std::ostream& out, const Graph& g, const dynamic_properties& dp, bool ordered_vertices = false) { write_graphml(out, g, get(vertex_index, g), dp, ordered_vertices); } } // boost namespace #endif // BOOST_GRAPH_GRAPHML_HPP