boost_1_45_0/libs/graph/src/graphml.cpp - nest-learning-thermostat/5.1.7/boost - Git at Google

 // Copyright (C) 2006  Tiago de Paula Peixoto <tiago@forked.de>
 // Copyright (C) 2004,2009  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
 //           Jeremiah Willcock
 //           Andrew Lumsdaine
 //           Tiago de Paula Peixoto

 #define BOOST_GRAPH_SOURCE
 #include <boost/foreach.hpp>
 #include <boost/optional.hpp>
 #include <boost/throw_exception.hpp>
 #include <boost/graph/graphml.hpp>
 #include <boost/graph/dll_import_export.hpp>
 #include <boost/property_tree/ptree.hpp>
 #include <boost/property_tree/xml_parser.hpp>

 using namespace boost;

 class graphml_reader
 {
 public:
     graphml_reader(mutate_graph& g)
         : m_g(g) { }

     static boost::property_tree::ptree::path_type path(const std::string& str) {
       return boost::property_tree::ptree::path_type(str, '/');
     }

     static void get_graphs(const boost::property_tree::ptree& top,
                            std::vector<const boost::property_tree::ptree*>& result) {
       using boost::property_tree::ptree;
       BOOST_FOREACH(const ptree::value_type& n, top) {
         if (n.first == "graph") {
           result.push_back(&n.second);
           get_graphs(n.second, result);
         }
       }
     }

     void run(std::istream& in)
     {
       using boost::property_tree::ptree;
       ptree pt;
       read_xml(in, pt, boost::property_tree::xml_parser::no_comments | boost::property_tree::xml_parser::trim_whitespace);
       ptree gml = pt.get_child(path("graphml"));
       // Search for attributes
       BOOST_FOREACH(const ptree::value_type& child, gml) {
         if (child.first != "key") continue;
         std::string id = child.second.get(path("<xmlattr>/id"), "");
         std::string for_ = child.second.get(path("<xmlattr>/for"), "");
         std::string name = child.second.get(path("<xmlattr>/attr.name"), "");
         std::string type = child.second.get(path("<xmlattr>/attr.type"), "");
         key_kind kind = all_key;
         if (for_ == "graph") kind = graph_key;
         else if (for_ == "node") kind = node_key;
         else if (for_ == "edge") kind = edge_key;
         else if (for_ == "hyperedge") kind = hyperedge_key;
         else if (for_ == "port") kind = port_key;
         else if (for_ == "endpoint") kind = endpoint_key;
         else if (for_ == "all") kind = all_key;
         else {BOOST_THROW_EXCEPTION(parse_error("Attribute for is not valid: " + for_));}
         m_keys[id] = kind;
         m_key_name[id] = name;
         m_key_type[id] = type;
         boost::optional<std::string> default_ = child.second.get_optional<std::string>(path("default"));
         if (default_) m_key_default[id] = default_.get();
       }
       // Search for graphs
       std::vector<const ptree*> graphs;
       get_graphs(gml, graphs);
       BOOST_FOREACH(const ptree* gr, graphs) {
         // Search for nodes
         BOOST_FOREACH(const ptree::value_type& node, *gr) {
           if (node.first != "node") continue;
           std::string id = node.second.get<std::string>(path("<xmlattr>/id"));
           handle_vertex(id);
           BOOST_FOREACH(const ptree::value_type& attr, node.second) {
             if (attr.first != "data") continue;
             std::string key = attr.second.get<std::string>(path("<xmlattr>/key"));
             std::string value = attr.second.get_value("");
             handle_node_property(key, id, value);
           }
         }
       }
       BOOST_FOREACH(const ptree* gr, graphs) {
         bool default_directed = gr->get<std::string>(path("<xmlattr>/edgedefault")) == "directed";
         // Search for edges
         BOOST_FOREACH(const ptree::value_type& edge, *gr) {
           if (edge.first != "edge") continue;
           std::string id = edge.second.get<std::string>(path("<xmlattr>/id"));
           std::string source = edge.second.get<std::string>(path("<xmlattr>/source"));
           std::string target = edge.second.get<std::string>(path("<xmlattr>/target"));
           std::string local_directed = edge.second.get(path("<xmlattr>/directed"), "");
           bool is_directed = (local_directed == "" ? default_directed : local_directed == "true");
           if (is_directed != m_g.is_directed()) {
             if (is_directed) {
               BOOST_THROW_EXCEPTION(directed_graph_error());
             } else {
               BOOST_THROW_EXCEPTION(undirected_graph_error());
             }
           }
           size_t old_edges_size = m_edge.size();
           handle_edge(source, target);
           BOOST_FOREACH(const ptree::value_type& attr, edge.second) {
             if (attr.first != "data") continue;
             std::string key = attr.second.get<std::string>(path("<xmlattr>/key"));
             std::string value = attr.second.get_value("");
             handle_edge_property(key, old_edges_size, value);
           }
         }
       }
     }

 private:
     /// The kinds of keys. Not all of these are supported
     enum key_kind {
         graph_key,
         node_key,
         edge_key,
         hyperedge_key,
         port_key,
         endpoint_key,
         all_key
     };

     void
     handle_vertex(const std::string& v)
     {
         bool is_new = false;

         if (m_vertex.find(v) == m_vertex.end())
         {
             m_vertex[v] = m_g.do_add_vertex();
             is_new = true;
         }

         if (is_new)
         {
             std::map<std::string, std::string>::iterator iter;
             for (iter = m_key_default.begin(); iter != m_key_default.end(); ++iter)
             {
                 if (m_keys[iter->first] == node_key)
                     handle_node_property(iter->first, v, iter->second);
             }
         }
     }

     any
     get_vertex_descriptor(const std::string& v)
     {
       return m_vertex[v];
     }

     void
     handle_edge(const std::string& u, const std::string& v)
     {
         handle_vertex(u);
         handle_vertex(v);

         any source, target;
         source = get_vertex_descriptor(u);
         target = get_vertex_descriptor(v);

         any edge;
         bool added;
         boost::tie(edge, added) = m_g.do_add_edge(source, target);
         if (!added) {
             BOOST_THROW_EXCEPTION(bad_parallel_edge(u, v));
         }

         size_t e = m_edge.size();
         m_edge.push_back(edge);

         std::map<std::string, std::string>::iterator iter;
         for (iter = m_key_default.begin(); iter != m_key_default.end(); ++iter)
         {
             if (m_keys[iter->first] == edge_key)
                 handle_edge_property(iter->first, e, iter->second);
         }
     }

     void handle_node_property(const std::string& key_id, const std::string& descriptor, const std::string& value)
     {
       m_g.set_vertex_property(m_key_name[key_id], m_vertex[descriptor], value, m_key_type[key_id]);
     }

     void handle_edge_property(const std::string& key_id, size_t descriptor, const std::string& value)
     {
       m_g.set_edge_property(m_key_name[key_id], m_edge[descriptor], value, m_key_type[key_id]);
     }

     mutate_graph& m_g;
     std::map<std::string, key_kind> m_keys;
     std::map<std::string, std::string> m_key_name;
     std::map<std::string, std::string> m_key_type;
     std::map<std::string, std::string> m_key_default;
     std::map<std::string, any> m_vertex;
     std::vector<any> m_edge;
 };

 namespace boost
 {
 void BOOST_GRAPH_DECL
 read_graphml(std::istream& in, mutate_graph& g)
 {
     graphml_reader reader(g);
     reader.run(in);
 }
 }
	// Copyright (C) 2006 Tiago de Paula Peixoto <tiago@forked.de>
	// Copyright (C) 2004,2009 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
	// Jeremiah Willcock
	// Andrew Lumsdaine
	// Tiago de Paula Peixoto

	#define BOOST_GRAPH_SOURCE
	#include <boost/foreach.hpp>
	#include <boost/optional.hpp>
	#include <boost/throw_exception.hpp>
	#include <boost/graph/graphml.hpp>
	#include <boost/graph/dll_import_export.hpp>
	#include <boost/property_tree/ptree.hpp>
	#include <boost/property_tree/xml_parser.hpp>

	using namespace boost;

	class graphml_reader
	{
	public:
	graphml_reader(mutate_graph& g)
	: m_g(g) { }

	static boost::property_tree::ptree::path_type path(const std::string& str) {
	return boost::property_tree::ptree::path_type(str, '/');
	}

	static void get_graphs(const boost::property_tree::ptree& top,
	std::vector<const boost::property_tree::ptree*>& result) {
	using boost::property_tree::ptree;
	BOOST_FOREACH(const ptree::value_type& n, top) {
	if (n.first == "graph") {
	result.push_back(&n.second);
	get_graphs(n.second, result);
	}
	}
	}

	void run(std::istream& in)
	{
	using boost::property_tree::ptree;
	ptree pt;
	read_xml(in, pt, boost::property_tree::xml_parser::no_comments \| boost::property_tree::xml_parser::trim_whitespace);
	ptree gml = pt.get_child(path("graphml"));
	// Search for attributes
	BOOST_FOREACH(const ptree::value_type& child, gml) {
	if (child.first != "key") continue;
	std::string id = child.second.get(path("<xmlattr>/id"), "");
	std::string for_ = child.second.get(path("<xmlattr>/for"), "");
	std::string name = child.second.get(path("<xmlattr>/attr.name"), "");
	std::string type = child.second.get(path("<xmlattr>/attr.type"), "");
	key_kind kind = all_key;
	if (for_ == "graph") kind = graph_key;
	else if (for_ == "node") kind = node_key;
	else if (for_ == "edge") kind = edge_key;
	else if (for_ == "hyperedge") kind = hyperedge_key;
	else if (for_ == "port") kind = port_key;
	else if (for_ == "endpoint") kind = endpoint_key;
	else if (for_ == "all") kind = all_key;
	else {BOOST_THROW_EXCEPTION(parse_error("Attribute for is not valid: " + for_));}
	m_keys[id] = kind;
	m_key_name[id] = name;
	m_key_type[id] = type;
	boost::optional<std::string> default_ = child.second.get_optional<std::string>(path("default"));
	if (default_) m_key_default[id] = default_.get();
	}
	// Search for graphs
	std::vector<const ptree*> graphs;
	get_graphs(gml, graphs);
	BOOST_FOREACH(const ptree* gr, graphs) {
	// Search for nodes
	BOOST_FOREACH(const ptree::value_type& node, *gr) {
	if (node.first != "node") continue;
	std::string id = node.second.get<std::string>(path("<xmlattr>/id"));
	handle_vertex(id);
	BOOST_FOREACH(const ptree::value_type& attr, node.second) {
	if (attr.first != "data") continue;
	std::string key = attr.second.get<std::string>(path("<xmlattr>/key"));
	std::string value = attr.second.get_value("");
	handle_node_property(key, id, value);
	}
	}
	}
	BOOST_FOREACH(const ptree* gr, graphs) {
	bool default_directed = gr->get<std::string>(path("<xmlattr>/edgedefault")) == "directed";
	// Search for edges
	BOOST_FOREACH(const ptree::value_type& edge, *gr) {
	if (edge.first != "edge") continue;
	std::string id = edge.second.get<std::string>(path("<xmlattr>/id"));
	std::string source = edge.second.get<std::string>(path("<xmlattr>/source"));
	std::string target = edge.second.get<std::string>(path("<xmlattr>/target"));
	std::string local_directed = edge.second.get(path("<xmlattr>/directed"), "");
	bool is_directed = (local_directed == "" ? default_directed : local_directed == "true");
	if (is_directed != m_g.is_directed()) {
	if (is_directed) {
	BOOST_THROW_EXCEPTION(directed_graph_error());
	} else {
	BOOST_THROW_EXCEPTION(undirected_graph_error());
	}
	}
	size_t old_edges_size = m_edge.size();
	handle_edge(source, target);
	BOOST_FOREACH(const ptree::value_type& attr, edge.second) {
	if (attr.first != "data") continue;
	std::string key = attr.second.get<std::string>(path("<xmlattr>/key"));
	std::string value = attr.second.get_value("");
	handle_edge_property(key, old_edges_size, value);
	}
	}
	}
	}

	private:
	/// The kinds of keys. Not all of these are supported
	enum key_kind {
	graph_key,
	node_key,
	edge_key,
	hyperedge_key,
	port_key,
	endpoint_key,
	all_key
	};

	void
	handle_vertex(const std::string& v)
	{
	bool is_new = false;

	if (m_vertex.find(v) == m_vertex.end())
	{
	m_vertex[v] = m_g.do_add_vertex();
	is_new = true;
	}

	if (is_new)
	{
	std::map<std::string, std::string>::iterator iter;
	for (iter = m_key_default.begin(); iter != m_key_default.end(); ++iter)
	{
	if (m_keys[iter->first] == node_key)
	handle_node_property(iter->first, v, iter->second);
	}
	}
	}

	any
	get_vertex_descriptor(const std::string& v)
	{
	return m_vertex[v];
	}

	void
	handle_edge(const std::string& u, const std::string& v)
	{
	handle_vertex(u);
	handle_vertex(v);

	any source, target;
	source = get_vertex_descriptor(u);
	target = get_vertex_descriptor(v);

	any edge;
	bool added;
	boost::tie(edge, added) = m_g.do_add_edge(source, target);
	if (!added) {
	BOOST_THROW_EXCEPTION(bad_parallel_edge(u, v));
	}

	size_t e = m_edge.size();
	m_edge.push_back(edge);

	std::map<std::string, std::string>::iterator iter;
	for (iter = m_key_default.begin(); iter != m_key_default.end(); ++iter)
	{
	if (m_keys[iter->first] == edge_key)
	handle_edge_property(iter->first, e, iter->second);
	}
	}

	void handle_node_property(const std::string& key_id, const std::string& descriptor, const std::string& value)
	{
	m_g.set_vertex_property(m_key_name[key_id], m_vertex[descriptor], value, m_key_type[key_id]);
	}

	void handle_edge_property(const std::string& key_id, size_t descriptor, const std::string& value)
	{
	m_g.set_edge_property(m_key_name[key_id], m_edge[descriptor], value, m_key_type[key_id]);
	}

	mutate_graph& m_g;
	std::map<std::string, key_kind> m_keys;
	std::map<std::string, std::string> m_key_name;
	std::map<std::string, std::string> m_key_type;
	std::map<std::string, std::string> m_key_default;
	std::map<std::string, any> m_vertex;
	std::vector<any> m_edge;
	};

	namespace boost
	{
	void BOOST_GRAPH_DECL
	read_graphml(std::istream& in, mutate_graph& g)
	{
	graphml_reader reader(g);
	reader.run(in);
	}
	}