lemon/lemon_reader.h
author klao
Fri, 03 Feb 2006 14:07:52 +0000
changeset 1951 cb7a6e0573bc
parent 1909 2d806130e700
child 1956 a055123339d5
permissions -rw-r--r--
graph_adaptor.h: probably a doxygen bug: in tex formulas there should be
whitespace after the opening and before the closing \f$
     1 /* -*- C++ -*-
     2  * lemon/lemon_reader.h - Part of LEMON, a generic C++ optimization library
     3  *
     4  * Copyright (C) 2006 Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
     5  * (Egervary Research Group on Combinatorial Optimization, EGRES).
     6  *
     7  * Permission to use, modify and distribute this software is granted
     8  * provided that this copyright notice appears in all copies. For
     9  * precise terms see the accompanying LICENSE file.
    10  *
    11  * This software is provided "AS IS" with no warranty of any kind,
    12  * express or implied, and with no claim as to its suitability for any
    13  * purpose.
    14  *
    15  */
    16 
    17 ///\ingroup io_group
    18 ///\file
    19 ///\brief Lemon Format reader.
    20 
    21 
    22 #ifndef LEMON_LEMON_READER_H
    23 #define LEMON_LEMON_READER_H
    24 
    25 
    26 #include <iostream>
    27 #include <fstream>
    28 #include <string>
    29 #include <vector>
    30 #include <algorithm>
    31 #include <map>
    32 #include <memory>
    33 
    34 #include <lemon/error.h>
    35 #include <lemon/graph_utils.h>
    36 #include <lemon/utility.h>
    37 #include <lemon/bits/item_reader.h>
    38 
    39 #include <lemon/xy.h>
    40 
    41 #include <lemon/concept_check.h>
    42 #include <lemon/concept/maps.h>
    43 
    44 namespace lemon {
    45 
    46   namespace _reader_bits {
    47 
    48     template <typename T>
    49     bool operator<(T, T) {
    50       throw DataFormatError("Label is not comparable");
    51     }
    52 
    53     template <typename T>
    54     struct Less {
    55       bool operator()(const T& p, const T& q) const {
    56 	return p < q;
    57       }
    58     };
    59 
    60     template <typename Item>
    61     class ItemLabelReader {
    62     public:
    63 
    64       bool isLabelReader() { return true; }
    65 
    66       void readLabel(std::istream&, Item&) {}
    67       
    68       template <class _ItemLabelReader>
    69       struct Constraints {
    70 	void constraints() {
    71 	  bool b = reader.isLabelReader();
    72 	  ignore_unused_variable_warning(b);
    73 	  Item item;
    74 	  reader.readLabel(is, item);
    75 	}
    76 	_ItemLabelReader& reader;
    77 	std::istream& is;
    78       };
    79 
    80     };
    81 
    82     template <typename Item>
    83     class ItemReader {
    84     public:
    85       void read(std::istream&, Item&) {}
    86       
    87       template <class _ItemReader>
    88       struct Constraints {
    89 	void constraints() {
    90 	  Item item;
    91 	  reader.read(is, item);
    92 	}
    93 	_ItemReader& reader;
    94 	std::istream& is;
    95       };
    96 
    97     };
    98 
    99     template <typename Map>
   100     struct Ref { typedef Map& Type; };
   101     template <typename Map>
   102     struct Arg { typedef Map& Type; };
   103 
   104     template <typename Graph, typename Map>
   105     class ForwardComposeMap {
   106     public:
   107       typedef typename Graph::UEdge Key;
   108       typedef typename Map::Value Value;
   109 
   110       ForwardComposeMap(const Graph& _graph, typename Arg<Map>::Type _map) 
   111 	: graph(_graph), map(_map) {}
   112       
   113       void set(const Key& key, const Value& val) {
   114 	map.set(graph.direct(key, true), val);
   115       }
   116 
   117     private:
   118       typename Ref<Map>::Type map;
   119       const Graph& graph;
   120     };
   121 
   122     template <typename Graph, typename Map>
   123     ForwardComposeMap<Graph, Map>
   124     forwardComposeMap(const Graph& graph, const Map& map) {
   125       return ForwardComposeMap<Graph, Map>(graph, map);
   126     }
   127 
   128     template <typename Graph, typename Map>
   129     ForwardComposeMap<Graph, Map>
   130     forwardComposeMap(const Graph& graph, Map& map) {
   131       return ForwardComposeMap<Graph, Map>(graph, map);
   132     }
   133 
   134     template <typename Graph, typename Map>
   135     class BackwardComposeMap {
   136     public:
   137       typedef typename Graph::UEdge Key;
   138       typedef typename Map::Value Value;
   139 
   140       BackwardComposeMap(const Graph& _graph, typename Arg<Map>::Type _map) 
   141 	: graph(_graph), map(_map) {}
   142       
   143       void set(const Key& key, const Value& val) {
   144 	map.set(graph.direct(key, false), val);
   145       }
   146 
   147     private:
   148       typename Ref<Map>::Type map;
   149       const Graph& graph;
   150     };
   151 
   152 
   153     template <typename Graph, typename Map>
   154     BackwardComposeMap<Graph, Map>
   155     backwardComposeMap(const Graph& graph, const Map& map) {
   156       return BackwardComposeMap<Graph, Map>(graph, map);
   157     }
   158 
   159     template <typename Graph, typename Map>
   160     BackwardComposeMap<Graph, Map>
   161     backwardComposeMap(const Graph& graph, Map& map) {
   162       return BackwardComposeMap<Graph, Map>(graph, map);
   163     }
   164 
   165     template <typename Graph, typename Map>
   166     struct Ref<ForwardComposeMap<Graph, Map> > { 
   167       typedef ForwardComposeMap<Graph, Map> Type;
   168     };
   169     template <typename Graph, typename Map>
   170     struct Arg<ForwardComposeMap<Graph, Map> > { 
   171       typedef const ForwardComposeMap<Graph, Map>& Type;
   172     };
   173 
   174     template <typename Graph, typename Map>
   175     struct Ref<BackwardComposeMap<Graph, Map> > { 
   176       typedef BackwardComposeMap<Graph, Map> Type; 
   177     };
   178     template <typename Graph, typename Map>
   179     struct Arg<BackwardComposeMap<Graph, Map> > { 
   180       typedef const BackwardComposeMap<Graph, Map>& Type; 
   181     };
   182 
   183     template <typename Map>
   184     struct Ref<XMap<Map> > { 
   185       typedef XMap<Map> Type;
   186     };
   187     template <typename Map>
   188     struct Arg<XMap<Map> > { 
   189       typedef const XMap<Map>& Type;
   190     };
   191 
   192     template <typename Map>
   193     struct Ref<YMap<Map> > { 
   194       typedef YMap<Map> Type;
   195     };
   196     template <typename Map>
   197     struct Arg<YMap<Map> > { 
   198       typedef const YMap<Map>& Type;
   199     };
   200 
   201 
   202     template <typename _Item>
   203     class MapReaderBase;
   204     
   205     template <typename _Item>
   206     class MapInverterBase : public MapReaderBase<_Item> {
   207     public:
   208       typedef _Item Item;
   209       virtual void read(std::istream&, const Item&) = 0;
   210       virtual Item read(std::istream&) const = 0;
   211 
   212       virtual MapInverterBase<_Item>* getInverter() {
   213 	return this;
   214       }
   215     };
   216 
   217     template <typename _Item, typename _Map, typename _Reader>
   218     class MapReaderInverter : public MapInverterBase<_Item> {
   219     public:
   220       typedef _Item Item;
   221       typedef _Reader Reader;
   222       typedef typename Reader::Value Value;
   223       typedef _Map Map;
   224       typedef std::map<Value, Item, _reader_bits::Less<Value> > Inverse;
   225 
   226       typename _reader_bits::Ref<Map>::Type map;
   227       Reader reader;
   228       Inverse inverse;
   229 
   230       MapReaderInverter(typename _reader_bits::Arg<Map>::Type _map,
   231 			const Reader& _reader) 
   232 	: map(_map), reader(_reader) {}
   233 
   234       virtual ~MapReaderInverter() {}
   235 
   236       virtual void read(std::istream& is, const Item& item) {
   237 	Value value;
   238 	reader.read(is, value);
   239 	map.set(item, value);
   240 	typename Inverse::iterator it = inverse.find(value);
   241 	if (it == inverse.end()) {
   242 	  inverse.insert(std::make_pair(value, item));
   243 	} else {
   244 	  throw DataFormatError("Multiple label occurence");
   245 	}
   246       }
   247 
   248       virtual Item read(std::istream& is) const {
   249 	Value value;
   250 	reader.read(is, value);	
   251 	typename Inverse::const_iterator it = inverse.find(value);
   252 	if (it != inverse.end()) {
   253 	  return it->second;
   254 	} else {
   255 	  throw DataFormatError("Invalid label error");
   256 	}
   257       }      
   258     };
   259 
   260     template <typename _Item, typename _Reader>
   261     class SkipReaderInverter : public MapInverterBase<_Item> {
   262     public:
   263       typedef _Item Item;
   264       typedef _Reader Reader;
   265       typedef typename Reader::Value Value;
   266       typedef std::map<Value, Item, _reader_bits::Less<Value> > Inverse;
   267 
   268       Reader reader;
   269 
   270       SkipReaderInverter(const Reader& _reader) 
   271 	: reader(_reader) {}
   272 
   273       virtual ~SkipReaderInverter() {}
   274 
   275       virtual void read(std::istream& is, const Item& item) {
   276 	Value value;
   277 	reader.read(is, value);
   278 	typename Inverse::iterator it = inverse.find(value);
   279 	if (it == inverse.end()) {
   280 	  inverse.insert(std::make_pair(value, item));
   281 	} else {
   282 	  throw DataFormatError("Multiple label occurence error");
   283 	}
   284       }
   285 
   286       virtual Item read(std::istream& is) const {
   287 	Value value;
   288 	reader.read(is, value);	
   289 	typename Inverse::const_iterator it = inverse.find(value);
   290 	if (it != inverse.end()) {
   291 	  return it->second;
   292 	} else {
   293 	  throw DataFormatError("Invalid label error");
   294 	}
   295       }
   296 
   297     private:
   298       Inverse inverse;
   299     };
   300 
   301     template <typename _Item>    
   302     class MapReaderBase {
   303     public:
   304       typedef _Item Item;
   305 
   306       MapReaderBase() { _touched = false; }
   307       
   308       void touch() { _touched = true; }
   309       bool touched() const { return _touched; }
   310 
   311       virtual ~MapReaderBase() {}
   312 
   313       virtual void read(std::istream& is, const Item& item) = 0;
   314       virtual MapInverterBase<_Item>* getInverter() = 0;
   315 
   316     private:      
   317       bool _touched;
   318 
   319     };
   320 
   321     template <typename _Item, typename _Map, typename _Reader>
   322     class MapReader : public MapReaderBase<_Item> {
   323     public:
   324       typedef _Map Map;
   325       typedef _Reader Reader;
   326       typedef typename Reader::Value Value;
   327       typedef _Item Item;
   328       
   329       typename _reader_bits::Ref<Map>::Type map;
   330       Reader reader;
   331 
   332       MapReader(typename _reader_bits::Arg<Map>::Type _map, 
   333 		const Reader& _reader) 
   334 	: map(_map), reader(_reader) {}
   335 
   336       virtual ~MapReader() {}
   337 
   338       virtual void read(std::istream& is, const Item& item) {
   339 	Value value;
   340 	reader.read(is, value);
   341 	map.set(item, value);
   342       }
   343 
   344       virtual MapInverterBase<_Item>* getInverter() {
   345 	return new MapReaderInverter<Item, Map, Reader>(map, reader);
   346       }
   347     };
   348 
   349 
   350     template <typename _Item, typename _Reader>
   351     class SkipReader : public MapReaderBase<_Item> {
   352     public:
   353       typedef _Reader Reader;
   354       typedef typename Reader::Value Value;
   355       typedef _Item Item;
   356 
   357       Reader reader;
   358       SkipReader(const Reader& _reader) : reader(_reader) {}
   359 
   360       virtual ~SkipReader() {}
   361 
   362       virtual void read(std::istream& is, const Item&) {
   363 	Value value;
   364 	reader.read(is, value);
   365       }      
   366 
   367       virtual MapInverterBase<Item>* getInverter() {
   368 	return new SkipReaderInverter<Item, Reader>(reader);
   369       }
   370     };
   371 
   372     template <typename _Item>
   373     class LabelReaderBase {
   374     public:
   375       typedef _Item Item;
   376       virtual ~LabelReaderBase() {}
   377       virtual Item read(std::istream& is) const = 0;
   378       virtual bool isLabelReader() const = 0;
   379     };
   380 
   381     template <typename _Item, typename _BoxedLabelReader>
   382     class LabelReader : public LabelReaderBase<_Item> {
   383     public:
   384       typedef _Item Item;
   385       typedef _BoxedLabelReader BoxedLabelReader;
   386       
   387       const BoxedLabelReader& boxedLabelReader;
   388 
   389       LabelReader(const BoxedLabelReader& _boxedLabelReader) 
   390 	: boxedLabelReader(_boxedLabelReader) {}
   391 
   392       virtual Item read(std::istream& is) const {
   393 	Item item;
   394 	boxedLabelReader.readLabel(is, item);
   395 	return item;
   396       }
   397 
   398       virtual bool isLabelReader() const {
   399 	return boxedLabelReader.isLabelReader();
   400       }
   401     };
   402 
   403     template <typename _Item>
   404     class ItemStore {
   405     public:
   406 
   407       typedef _Item Item;
   408 
   409       ItemStore(Item& _item) : item(&_item) { 
   410 	_touched = false; 
   411       }
   412       
   413       void touch() { _touched = true; }
   414       bool touched() const { return _touched; }
   415 
   416       void read(const Item& _item) {
   417 	*item = _item;
   418       }
   419       
   420     private:
   421       Item* item;
   422       bool _touched;
   423     };
   424 
   425     class ValueReaderBase {
   426     public:
   427       virtual void read(std::istream&) {};
   428       ValueReaderBase() { _touched = false; }
   429 
   430       void touch() { _touched = true; }
   431       bool touched() const { return _touched; }
   432 
   433       virtual ~ValueReaderBase() {}
   434     private:
   435       bool _touched;
   436     };
   437 
   438     template <typename _Value, typename _Reader>
   439     class ValueReader : public ValueReaderBase {
   440     public:
   441       typedef _Value Value;
   442       typedef _Reader Reader;
   443 
   444       ValueReader(Value& _value, const Reader& _reader)
   445  	: value(_value), reader(_reader) {}
   446 
   447       virtual void read(std::istream& is) {
   448 	reader.read(is, value);
   449       }
   450     private:
   451       Value& value;
   452       Reader reader;
   453     };
   454 
   455   }
   456 
   457   /// \ingroup io_group
   458   /// \brief Lemon Format reader class.
   459   /// 
   460   /// The Lemon Format contains several sections. We do not want to
   461   /// determine what sections are in a lemon file we give only a framework
   462   /// to read a section oriented format.
   463   ///
   464   /// In the Lemon Format each section starts with a line contains a \c \@
   465   /// character on the first not white space position. This line is the
   466   /// header line of the section. Each next lines belong to this section
   467   /// while it does not starts with \c \@ character. This line can start a 
   468   /// new section or if it can close the file with the \c \@end line.
   469   /// The file format ignore the empty and comment lines. The line is
   470   /// comment line if it starts with a \c # character. 
   471   ///
   472   /// The framework provides an abstract LemonReader::SectionReader class
   473   /// what defines the interface of a SectionReader. The SectionReader
   474   /// has the \c header() member function what get a header line string and
   475   /// decides if it want to process the next section. Several SectionReaders
   476   /// can be attached to an LemonReader and the first attached what can
   477   /// process the section will be used. Its \c read() member will called
   478   /// with a stream contains the section. From this stream the empty and
   479   /// comment lines are filtered out.
   480   ///
   481   /// \relates GraphReader
   482   /// \relates NodeSetReader
   483   /// \relates EdgeSetReader
   484   /// \relates NodesReader
   485   /// \relates EdgesReader
   486   /// \relates AttributeReader
   487   class LemonReader {
   488   private:
   489     
   490     class FilterStreamBuf : public std::streambuf {
   491     public:
   492 
   493       typedef std::streambuf Parent;
   494       typedef Parent::char_type char_type;
   495       FilterStreamBuf(std::istream& is, int& num) 
   496 	: _is(is), _base(0), _eptr(0), 
   497 	  _num(num), skip_state(after_endl) {}
   498 
   499     protected:
   500 
   501       enum skip_state_type {
   502 	no_skip,
   503 	after_endl,
   504 	comment_line
   505       };
   506 
   507       char_type small_buf[1];
   508 
   509 
   510       std::istream& _is;
   511 
   512       char_type* _base;
   513       char_type* _eptr;
   514 
   515       int& _num;
   516 
   517       skip_state_type skip_state;
   518 
   519 
   520       char_type* base() { return _base; }
   521 
   522       char_type* eptr() { return _eptr; }
   523 
   524       int blen() { return _eptr - _base; }
   525 
   526       void setb(char_type* buf, int len) {
   527 	_base = buf;
   528 	_eptr = buf + len;
   529       }
   530   
   531       virtual std::streambuf* setbuf(char *buf, std::streamsize len) {
   532 	if (base()) return 0;
   533 	if (buf != 0 && len >= (int)sizeof(small_buf)) {
   534 	  setb(buf, len);
   535 	} else {
   536 	  setb(small_buf, sizeof(small_buf));
   537 	}
   538 	setg(0, 0, 0);
   539 	return this;
   540       }
   541 
   542       bool put_char(char c) {
   543 	switch (skip_state) {
   544 	case no_skip:
   545 	  switch (c) {
   546 	  case '\n': 
   547 	    skip_state = after_endl;
   548 	    return true;
   549 	  default:
   550 	    return true;
   551 	  }
   552 	case after_endl:
   553 	  switch (c) {
   554 	  case '@':
   555 	    return false;
   556 	  case '\n': 
   557 	    return false;
   558 	  case '#':
   559 	    skip_state = comment_line;
   560 	    return false;
   561 	  default:
   562 	    if (!isspace(c)) {
   563 	      skip_state = no_skip;
   564 	      return true;
   565 	    } else {
   566 	      return false;
   567 	    }
   568 	  }
   569 	  break;
   570 	case comment_line:
   571 	  switch (c) {
   572 	  case '\n': 
   573 	    skip_state = after_endl;
   574 	    return false;
   575 	  default:
   576 	    return false;
   577 	  }
   578 	}
   579 	return false;
   580       }
   581 
   582       virtual int underflow() {
   583 	char c;
   584 	if (_is.read(&c, 1)) {
   585 	  _is.putback(c);
   586 	  if (c == '@') {
   587 	    return EOF;
   588 	  }
   589 	} else {
   590 	  return EOF;
   591 	}
   592 	char_type *ptr;
   593 	for (ptr = base(); ptr != eptr(); ++ptr) {
   594 	  if (_is.read(&c, 1)) {
   595 	    if (c == '\n') ++_num;
   596 	    if (put_char(c)) {
   597 	      *ptr = c;
   598 	    } else {
   599 	      if (skip_state == after_endl && c == '@') {
   600 		_is.putback('@');
   601 		break;
   602 	      }
   603 	      --ptr;
   604 	    }
   605 	  } else {
   606 	    break;
   607 	  }
   608 	}
   609 	setg(base(), base(), ptr);
   610 	return *base();
   611       }
   612 
   613       virtual int sync() {
   614 	return EOF;
   615       }
   616     };
   617 
   618   public:
   619 
   620     /// \brief Abstract base class for reading a section.
   621     ///
   622     /// This class has an \c header() member function what get a 
   623     /// header line string and decides if it want to process the next 
   624     /// section. Several SectionReaders can be attached to an LemonReader 
   625     /// and the first attached what can process the section will be used. 
   626     /// Its \c read() member will called with a stream contains the section. 
   627     /// From this stream the empty lines and comments are filtered out.
   628     class SectionReader {
   629       friend class LemonReader;
   630     protected:
   631       /// \brief Constructor for SectionReader.
   632       ///
   633       /// Constructor for SectionReader. It attach this reader to
   634       /// the given LemonReader.
   635       SectionReader(LemonReader& reader) {
   636 	reader.attach(*this);
   637       }
   638 
   639       virtual ~SectionReader() {}
   640 
   641       /// \brief Gives back true when the SectionReader can process 
   642       /// the section with the given header line.
   643       ///
   644       /// It gives back true when the SectionReader can process
   645       /// the section with the given header line.
   646       virtual bool header(const std::string& line) = 0;
   647 
   648       /// \brief Reader function of the section.
   649       ///
   650       /// It reads the content of the section.
   651       virtual void read(std::istream& is) = 0;
   652     };
   653 
   654     /// \brief Constructor for LemonReader.
   655     ///
   656     /// Constructor for LemonReader which reads from the given stream.
   657     LemonReader(std::istream& _is) 
   658       : is(&_is), own_is(false) {}
   659 
   660     /// \brief Constructor for LemonReader.
   661     ///
   662     /// Constructor for LemonReader which reads from the given file.
   663     LemonReader(const std::string& filename) 
   664       : is(0), own_is(true) {
   665       is = new std::ifstream(filename.c_str());
   666       if (is->fail()) {
   667 	throw FileOpenError(filename);
   668       }
   669     }
   670 
   671     /// \brief Desctructor for LemonReader.
   672     ///
   673     /// Desctructor for LemonReader.
   674     ~LemonReader() {
   675       if (own_is) {
   676 	delete is;
   677       }
   678     }
   679 
   680   private:
   681     LemonReader(const LemonReader&);
   682     void operator=(const LemonReader&);
   683 
   684     void attach(SectionReader& reader) {
   685       readers.push_back(&reader);
   686     }
   687 
   688   public:
   689     /// \brief Executes the LemonReader.
   690     /// 
   691     /// It executes the LemonReader.
   692     void run() {
   693       int line_num = 0;
   694       std::string line;
   695       try {
   696 	while ((++line_num, getline(*is, line)) && line.find("@end") != 0) {
   697 	  SectionReaders::iterator it;
   698 	  for (it = readers.begin(); it != readers.end(); ++it) {
   699 	    if ((*it)->header(line)) {
   700 	      char buf[2048];
   701 	      FilterStreamBuf buffer(*is, line_num);
   702 	      buffer.pubsetbuf(buf, sizeof(buf));
   703 	      std::istream is(&buffer);
   704 	      (*it)->read(is);
   705 	      break;
   706 	    }
   707 	  }
   708 	}
   709       } catch (DataFormatError& error) {
   710 	error.line(line_num);
   711 	throw error;
   712       }	
   713     }
   714 
   715 
   716   private:
   717 
   718     std::istream* is;
   719     bool own_is;
   720 
   721     typedef std::vector<SectionReader*> SectionReaders;
   722     SectionReaders readers;
   723 
   724   };
   725 
   726   /// \ingroup io_group
   727   /// \brief SectionReader for reading a graph's nodeset.
   728   ///
   729   /// The lemon format can store multiple graph nodesets with several maps.
   730   /// The nodeset section's header line is \c \@nodeset \c nodeset_name, but the
   731   /// \c nodeset_name may be empty.
   732   ///
   733   /// The first line of the section contains the names of the maps separated
   734   /// with white spaces. Each next lines describes a node in the nodeset, and
   735   /// contains the mapped values for each map.
   736   ///
   737   /// If the nodeset contains an \c "label" named map then it will be regarded
   738   /// as id map. This map should contain only unique values and when the 
   739   /// \c readLabel() member will read a value from the given stream it will
   740   /// give back that node which is mapped to this value.
   741   ///
   742   /// \relates LemonReader
   743   template <typename _Graph, typename _Traits = DefaultReaderTraits>
   744   class NodeSetReader : public LemonReader::SectionReader {
   745     typedef LemonReader::SectionReader Parent;
   746   public:
   747 
   748     typedef _Graph Graph;
   749     typedef _Traits Traits;
   750     typedef typename Graph::Node Node;
   751     typedef typename Traits::Skipper DefaultSkipper;
   752 
   753     /// \brief Constructor.
   754     ///
   755     /// Constructor for NodeSetReader. It creates the NodeSetReader and
   756     /// attach it into the given LemonReader. The nodeset reader will
   757     /// add the readed nodes to the given Graph. The reader will read
   758     /// the section when the \c section_name and the \c _name are the same. 
   759     NodeSetReader(LemonReader& _reader, 
   760 		  Graph& _graph, 
   761 		  const std::string& _name = std::string(),
   762 		  const DefaultSkipper& _skipper = DefaultSkipper()) 
   763       : Parent(_reader), graph(_graph), name(_name), skipper(_skipper) {} 
   764 
   765 
   766     /// \brief Destructor.
   767     ///
   768     /// Destructor for NodeSetReader.
   769     virtual ~NodeSetReader() {
   770       for (typename MapReaders::iterator it = readers.begin(); 
   771 	   it != readers.end(); ++it) {
   772 	delete it->second;
   773       }
   774     }
   775 
   776   private:
   777     NodeSetReader(const NodeSetReader&);
   778     void operator=(const NodeSetReader&);
   779   
   780   public:
   781 
   782     /// \brief Add a new node map reader command for the reader.
   783     ///
   784     /// Add a new node map reader command for the reader.
   785     template <typename Map>
   786     NodeSetReader& readNodeMap(std::string name, Map& map) {
   787       return _readMap<
   788 	typename Traits::template Reader<typename Map::Value>, Map,
   789 	typename _reader_bits::Arg<Map>::Type>(name, map);
   790     }
   791 
   792     template <typename Map>
   793     NodeSetReader& readNodeMap(std::string name, const Map& map) {
   794       return _readMap<
   795 	typename Traits::template Reader<typename Map::Value>, Map,
   796 	typename _reader_bits::Arg<Map>::Type>(name, map);
   797     }
   798 
   799     /// \brief Add a new node map reader command for the reader.
   800     ///
   801     /// Add a new node map reader command for the reader.
   802     template <typename Reader, typename Map>
   803     NodeSetReader& readNodeMap(std::string name, Map& map, 
   804 			       const Reader& reader = Reader()) {
   805       return _readMap<Reader, Map, typename _reader_bits::Arg<Map>::Type>
   806 	(name, map, reader);
   807     }
   808 
   809     template <typename Reader, typename Map>
   810     NodeSetReader& readNodeMap(std::string name, const Map& map, 
   811 			       const Reader& reader = Reader()) {
   812       return _readMap<Reader, Map, typename _reader_bits::Arg<Map>::Type>
   813 	(name, map, reader);
   814     }
   815 
   816   private:
   817 
   818     template <typename Reader, typename Map, typename MapParameter>
   819     NodeSetReader& _readMap(std::string name, MapParameter map, 
   820 			    const Reader& reader = Reader()) {
   821       checkConcept<concept::WriteMap<Node, typename Map::Value>, Map>();
   822       checkConcept<_reader_bits::ItemReader<typename Map::Value>, Reader>();
   823       if (readers.find(name) != readers.end()) {
   824 	ErrorMessage msg;
   825 	msg << "Multiple read rule for node map: " << name;
   826 	throw IOParameterError(msg.message());
   827       }      
   828       readers.insert(
   829         make_pair(name, new _reader_bits::
   830 		  MapReader<Node, Map, Reader>(map, reader)));
   831       return *this;
   832     }
   833 
   834   public:
   835 
   836     /// \brief Add a new node map skipper command for the reader.
   837     ///
   838     /// Add a new node map skipper command for the reader.
   839     template <typename Reader>
   840     NodeSetReader& skipNodeMap(std::string name, 
   841 			   const Reader& reader = Reader()) {
   842       if (readers.find(name) != readers.end()) {
   843 	ErrorMessage msg;
   844 	msg << "Multiple read rule for node map: " << name;
   845 	throw IOParameterError(msg.message());
   846       }
   847       readers.insert(make_pair(name, new _reader_bits::
   848 			       SkipReader<Node, Reader>(reader)));
   849       return *this;
   850     }
   851 
   852   protected:
   853 
   854     /// \brief Gives back true when the SectionReader can process 
   855     /// the section with the given header line.
   856     ///
   857     /// It gives back true when the header line starts with \c \@nodeset,
   858     /// and the header line's name and the nodeset's name are the same.
   859     virtual bool header(const std::string& line) {
   860       std::istringstream ls(line);
   861       std::string command;
   862       std::string id;
   863       ls >> command >> name;
   864       return command == "@nodeset" && name == id;
   865     }
   866 
   867     /// \brief Reader function of the section.
   868     ///
   869     /// It reads the content of the section.
   870     virtual void read(std::istream& is) {
   871       std::vector<_reader_bits::MapReaderBase<Node>* > index;
   872       std::string line;
   873 
   874       getline(is, line);
   875       std::istringstream ls(line);
   876       std::string id;
   877       while (ls >> id) {
   878 	typename MapReaders::iterator it = readers.find(id);
   879 	if (it != readers.end()) {
   880 	  it->second->touch();
   881 	  index.push_back(it->second);
   882 	} else {
   883 	  index.push_back(&skipper);
   884 	}
   885 	if (id == "label" || (id =="id" && inverter.get() == 0)) {
   886 	  inverter.reset(index.back()->getInverter());
   887 	  index.back() = inverter.get();
   888 	}
   889       }
   890       for (typename MapReaders::iterator it = readers.begin();
   891 	   it != readers.end(); ++it) {
   892 	if (!it->second->touched()) {
   893 	  ErrorMessage msg;
   894 	  msg << "Map not found in file: " << it->first;
   895 	  throw IOParameterError(msg.message());
   896 	}
   897       }
   898       while (getline(is, line)) {	
   899 	Node node = graph.addNode();
   900 	std::istringstream ls(line);
   901 	for (int i = 0; i < (int)index.size(); ++i) {
   902 	  index[i]->read(ls, node);
   903 	}
   904       }
   905     }
   906 
   907   public:
   908 
   909     /// \brief Returns true if the nodeset can give back the node by its label.
   910     ///
   911     /// Returns true if the nodeset can give back the node by its label.
   912     /// It is possible only if an "label" named map was read.
   913     bool isLabelReader() const {
   914       return inverter.get() != 0;
   915     }
   916 
   917     /// \brief Gives back the node by its label.
   918     ///
   919     /// It reads an id from the stream and gives back which node belongs to
   920     /// it. It is possible only if there was read an "label" named map.
   921     void readLabel(std::istream& is, Node& node) const {
   922       node = inverter->read(is);
   923     } 
   924 
   925   private:
   926 
   927     typedef std::map<std::string, _reader_bits::MapReaderBase<Node>*> MapReaders;
   928     MapReaders readers;
   929    
   930     Graph& graph;   
   931     std::string name;
   932     _reader_bits::SkipReader<Node, DefaultSkipper> skipper;
   933 
   934     std::auto_ptr<_reader_bits::MapInverterBase<Node> > inverter;
   935   };
   936 
   937   /// \ingroup io_group
   938   /// \brief SectionReader for reading a graph's edgeset.
   939   ///
   940   /// The lemon format can store multiple graph edgesets with several maps.
   941   /// The edgeset section's header line is \c \@edgeset \c edgeset_name, but the
   942   /// \c edgeset_name may be empty.
   943   ///
   944   /// The first line of the section contains the names of the maps separated
   945   /// with white spaces. Each next lines describes an edge in the edgeset. The
   946   /// line contains the source and the target nodes' id and the mapped 
   947   /// values for each map.
   948   ///
   949   /// If the edgeset contains an \c "label" named map then it will be regarded
   950   /// as id map. This map should contain only unique values and when the 
   951   /// \c readLabel() member will read a value from the given stream it will
   952   /// give back that edge which is mapped to this value.
   953   ///
   954   /// The edgeset reader needs a node id reader to identify which nodes
   955   /// have to be connected. If a NodeSetReader reads an "label" named map,
   956   /// it will be able to resolve the nodes by ids.
   957   ///
   958   /// \relates LemonReader
   959   template <typename _Graph, typename _Traits = DefaultReaderTraits>
   960   class EdgeSetReader : public LemonReader::SectionReader {
   961     typedef LemonReader::SectionReader Parent;
   962   public:
   963 
   964     typedef _Graph Graph;
   965     typedef _Traits Traits;
   966     typedef typename Graph::Node Node;
   967     typedef typename Graph::Edge Edge;
   968     typedef typename Traits::Skipper DefaultSkipper;
   969 
   970     /// \brief Constructor.
   971     ///
   972     /// Constructor for EdgeSetReader. It creates the EdgeSetReader and
   973     /// attach it into the given LemonReader. The edgeset reader will
   974     /// add the readed edges to the given Graph. It will use the given
   975     /// node id reader to read the source and target nodes of the edges.
   976     /// The reader will read the section only if the \c _name and the 
   977     /// \c edgset_name are the same. 
   978     template <typename NodeLabelReader>
   979     EdgeSetReader(LemonReader& _reader, 
   980 		  Graph& _graph, 
   981 		  const NodeLabelReader& _nodeLabelReader, 
   982 		  const std::string& _name = std::string(),
   983 		  const DefaultSkipper& _skipper = DefaultSkipper()) 
   984       : Parent(_reader), graph(_graph), name(_name), skipper(_skipper) {
   985       checkConcept<_reader_bits::ItemLabelReader<Node>, NodeLabelReader>();
   986       nodeLabelReader.reset(new _reader_bits::
   987 			 LabelReader<Node, NodeLabelReader>(_nodeLabelReader));
   988     }
   989     /// \brief Destructor.
   990     ///
   991     /// Destructor for EdgeSetReader.
   992     virtual ~EdgeSetReader() {
   993       for (typename MapReaders::iterator it = readers.begin(); 
   994 	   it != readers.end(); ++it) {
   995 	delete it->second;
   996       }
   997     }
   998 
   999   private:
  1000     EdgeSetReader(const EdgeSetReader&);
  1001     void operator=(const EdgeSetReader&);
  1002 
  1003   public:
  1004 
  1005     /// \brief Add a new edge map reader command for the reader.
  1006     ///
  1007     /// Add a new edge map reader command for the reader.
  1008     template <typename Map>
  1009     EdgeSetReader& readEdgeMap(std::string name, Map& map) {
  1010       return _readMap<
  1011 	typename Traits::template Reader<typename Map::Value>, Map,
  1012 	typename _reader_bits::Arg<Map>::Type>(name, map);
  1013     }
  1014 
  1015     template <typename Map>
  1016     EdgeSetReader& readEdgeMap(std::string name, const Map& map) {
  1017       return _readMap<
  1018 	typename Traits::template Reader<typename Map::Value>, Map,
  1019 	typename _reader_bits::Arg<Map>::Type>(name, map);
  1020     }
  1021 
  1022     /// \brief Add a new edge map reader command for the reader.
  1023     ///
  1024     /// Add a new edge map reader command for the reader.
  1025     template <typename Reader, typename Map>
  1026     EdgeSetReader& readEdgeMap(std::string name, Map& map, 
  1027 			   const Reader& reader = Reader()) {
  1028       return _readMap<Reader, Map,
  1029 	typename _reader_bits::Arg<Map>::Type>(name, map, reader);
  1030     }
  1031 
  1032     template <typename Reader, typename Map>
  1033     EdgeSetReader& readEdgeMap(std::string name, const Map& map, 
  1034 			       const Reader& reader = Reader()) {
  1035       return _readMap<Reader, Map,
  1036 	typename _reader_bits::Arg<Map>::Type>(name, map, reader);
  1037     }
  1038 
  1039   private:
  1040 
  1041     template <typename Reader, typename Map, typename MapParameter>
  1042     EdgeSetReader& _readMap(std::string name, MapParameter map, 
  1043 			    const Reader& reader = Reader()) {
  1044       checkConcept<concept::WriteMap<Edge, typename Map::Value>, Map>();
  1045       checkConcept<_reader_bits::ItemReader<typename Map::Value>, Reader>();
  1046       if (readers.find(name) != readers.end()) {
  1047 	ErrorMessage msg;
  1048 	msg << "Multiple read rule for edge map: " << name;
  1049 	throw IOParameterError(msg.message());
  1050       }
  1051       readers.insert(
  1052 	make_pair(name, new _reader_bits::
  1053 		  MapReader<Edge, Map, Reader>(map, reader)));
  1054       return *this;
  1055     }
  1056 
  1057   public:
  1058 
  1059     /// \brief Add a new edge map skipper command for the reader.
  1060     ///
  1061     /// Add a new edge map skipper command for the reader.
  1062     template <typename Reader>
  1063     EdgeSetReader& skipEdgeMap(std::string name, 
  1064 			       const Reader& reader = Reader()) {
  1065       if (readers.find(name) != readers.end()) {
  1066 	ErrorMessage msg;
  1067 	msg << "Multiple read rule for edge map: " << name;
  1068 	throw IOParameterError(msg.message());
  1069       }
  1070       readers.insert(make_pair(name, new _reader_bits::
  1071 			       SkipReader<Edge, Reader>(reader)));
  1072       return *this;
  1073     }
  1074 
  1075   protected:
  1076 
  1077     /// \brief Gives back true when the SectionReader can process 
  1078     /// the section with the given header line.
  1079     ///
  1080     /// It gives back true when the header line starts with \c \@edgeset,
  1081     /// and the header line's name and the edgeset's name are the same.
  1082     virtual bool header(const std::string& line) {
  1083       std::istringstream ls(line);
  1084       std::string command;
  1085       std::string id;
  1086       ls >> command >> name;
  1087       return command == "@edgeset" && name == id;
  1088     }
  1089 
  1090     /// \brief Reader function of the section.
  1091     ///
  1092     /// It reads the content of the section.
  1093     virtual void read(std::istream& is) {
  1094       if (!nodeLabelReader->isLabelReader()) {
  1095 	throw DataFormatError("Cannot find nodeset or label map");
  1096       }
  1097       std::vector<_reader_bits::MapReaderBase<Edge>* > index;
  1098       std::string line;
  1099 
  1100       getline(is, line);
  1101       std::istringstream ls(line);	
  1102       std::string id;
  1103       while (ls >> id) {
  1104 	typename MapReaders::iterator it = readers.find(id);
  1105 	if (it != readers.end()) {
  1106 	  index.push_back(it->second);
  1107 	  it->second->touch();
  1108 	} else {
  1109 	  index.push_back(&skipper);
  1110 	}
  1111 	if (id == "label" || (id =="id" && inverter.get() == 0)) {
  1112 	  inverter.reset(index.back()->getInverter());
  1113 	  index.back() = inverter.get();
  1114 	}
  1115       }
  1116       for (typename MapReaders::iterator it = readers.begin();
  1117 	   it != readers.end(); ++it) {
  1118 	if (!it->second->touched()) {
  1119 	  ErrorMessage msg;
  1120 	  msg << "Map not found in file: " << it->first;
  1121 	  throw IOParameterError(msg.message());
  1122 	}
  1123       }
  1124       while (getline(is, line)) {	
  1125 	std::istringstream ls(line);
  1126 	Node from = nodeLabelReader->read(ls);
  1127 	Node to = nodeLabelReader->read(ls);
  1128 	Edge edge = graph.addEdge(from, to);
  1129 	for (int i = 0; i < (int)index.size(); ++i) {
  1130 	  index[i]->read(ls, edge);
  1131 	}
  1132       }
  1133     }
  1134 
  1135   public:
  1136 
  1137     /// \brief Returns true if the edgeset can give back the edge by its label.
  1138     ///
  1139     /// Returns true if the edgeset can give back the edge by its label.
  1140     /// It is possible only if an "label" named map was read.
  1141     bool isLabelReader() const {
  1142       return inverter.get() != 0;
  1143     }
  1144 
  1145     /// \brief Gives back the edge by its label.
  1146     ///
  1147     /// It reads an id from the stream and gives back which edge belongs to
  1148     /// it. It is possible only if there was read an "label" named map.
  1149     void readLabel(std::istream& is, Edge& edge) const {
  1150       edge = inverter->read(is);
  1151     } 
  1152 
  1153   private:
  1154 
  1155     typedef std::map<std::string, _reader_bits::MapReaderBase<Edge>*> MapReaders;
  1156     MapReaders readers;
  1157    
  1158     Graph& graph;   
  1159     std::string name;
  1160     _reader_bits::SkipReader<Edge, DefaultSkipper> skipper;
  1161 
  1162     std::auto_ptr<_reader_bits::MapInverterBase<Edge> > inverter;
  1163     std::auto_ptr<_reader_bits::LabelReaderBase<Node> > nodeLabelReader;
  1164   };
  1165 
  1166   /// \ingroup io_group
  1167   /// \brief SectionReader for reading a undirected graph's edgeset.
  1168   ///
  1169   /// The lemon format can store multiple undirected edgesets with several 
  1170   /// maps. The undirected edgeset section's header line is \c \@uedgeset 
  1171   /// \c uedgeset_name, but the \c uedgeset_name may be empty.
  1172   ///
  1173   /// The first line of the section contains the names of the maps separated
  1174   /// with white spaces. Each next lines describes an edge in the edgeset. The
  1175   /// line contains the connected nodes' id and the mapped values for each map.
  1176   ///
  1177   /// The section can handle the directed as a syntactical sugar. Two
  1178   /// undirected edge map describes one directed edge map. This two maps
  1179   /// are the forward map and the backward map and the names of this map
  1180   /// is near the same just with a prefix \c '+' or \c '-' character 
  1181   /// difference.
  1182   ///
  1183   /// If the edgeset contains an \c "label" named map then it will be regarded
  1184   /// as id map. This map should contain only unique values and when the 
  1185   /// \c readLabel() member will read a value from the given stream it will
  1186   /// give back that uicted edge which is mapped to this value.
  1187   ///
  1188   /// The undirected edgeset reader needs a node id reader to identify which 
  1189   /// nodes have to be connected. If a NodeSetReader reads an "label" named map,
  1190   /// it will be able to resolve the nodes by ids.
  1191   ///
  1192   /// \relates LemonReader
  1193   template <typename _Graph, typename _Traits = DefaultReaderTraits>
  1194   class UEdgeSetReader : public LemonReader::SectionReader {
  1195     typedef LemonReader::SectionReader Parent;
  1196   public:
  1197 
  1198     typedef _Graph Graph;
  1199     typedef _Traits Traits;
  1200     typedef typename Graph::Node Node;
  1201     typedef typename Graph::Edge Edge;
  1202     typedef typename Graph::UEdge UEdge;
  1203     typedef typename Traits::Skipper DefaultSkipper;
  1204 
  1205     /// \brief Constructor.
  1206     ///
  1207     /// Constructor for UEdgeSetReader. It creates the UEdgeSetReader 
  1208     /// and attach it into the given LemonReader. The undirected edgeset 
  1209     /// reader will add the readed undirected edges to the given Graph. It 
  1210     /// will use the given node id reader to read the source and target 
  1211     /// nodes of the edges. The reader will read the section only if the 
  1212     /// \c _name and the \c uedgset_name are the same. 
  1213     template <typename NodeLabelReader>
  1214     UEdgeSetReader(LemonReader& _reader, 
  1215 		       Graph& _graph, 
  1216 		       const NodeLabelReader& _nodeLabelReader, 
  1217 		       const std::string& _name = std::string(),
  1218 		       const DefaultSkipper& _skipper = DefaultSkipper()) 
  1219       : Parent(_reader), graph(_graph), name(_name), skipper(_skipper) {
  1220       checkConcept<_reader_bits::ItemLabelReader<Node>, NodeLabelReader>();
  1221       nodeLabelReader.reset(new _reader_bits::
  1222 			 LabelReader<Node, NodeLabelReader>(_nodeLabelReader));
  1223     }
  1224     /// \brief Destructor.
  1225     ///
  1226     /// Destructor for UEdgeSetReader.
  1227     virtual ~UEdgeSetReader() {
  1228       for (typename MapReaders::iterator it = readers.begin(); 
  1229 	   it != readers.end(); ++it) {
  1230 	delete it->second;
  1231       }
  1232     }
  1233 
  1234   private:
  1235     UEdgeSetReader(const UEdgeSetReader&);
  1236     void operator=(const UEdgeSetReader&);
  1237 
  1238   public:
  1239 
  1240     /// \brief Add a new undirected edge map reader command for the reader.
  1241     ///
  1242     /// Add a new edge undirected map reader command for the reader.
  1243     template <typename Map>
  1244     UEdgeSetReader& readUEdgeMap(std::string name, Map& map) {
  1245       return _readMap<
  1246 	typename Traits::template Reader<typename Map::Value>, Map, 
  1247 	typename _reader_bits::Arg<Map>::Type>(name, map);
  1248     }
  1249 
  1250     template <typename Map>
  1251     UEdgeSetReader& readUEdgeMap(std::string name, const Map& map) {
  1252       return _readMap<
  1253 	typename Traits::template Reader<typename Map::Value>, Map, 
  1254 	typename _reader_bits::Arg<Map>::Type>(name, map);
  1255     }
  1256 
  1257     /// \brief Add a new undirected edge map reader command for the reader.
  1258     ///
  1259     /// Add a new edge undirected map reader command for the reader.
  1260     template <typename Reader, typename Map>
  1261     UEdgeSetReader& readUEdgeMap(std::string name, Map& map, 
  1262 					 const Reader& reader = Reader()) {
  1263       return _readMap<Reader, Map, typename _reader_bits::Arg<Map>::Type>
  1264 	(name, map, reader);
  1265     }
  1266 
  1267     template <typename Reader, typename Map>
  1268     UEdgeSetReader& readUEdgeMap(std::string name, const Map& map, 
  1269 					 const Reader& reader = Reader()) {
  1270       return _readMap<Reader, Map, typename _reader_bits::Arg<Map>::Type >
  1271 	(name, map, reader);
  1272     }
  1273 
  1274   private:
  1275 
  1276     template <typename Reader, typename Map, typename MapParameter>
  1277     UEdgeSetReader& _readMap(std::string name, MapParameter map,
  1278 				 const Reader& reader = Reader()) {
  1279       checkConcept<concept::WriteMap<UEdge, typename Map::Value>, Map>();
  1280       checkConcept<_reader_bits::ItemReader<typename Map::Value>, Reader>();
  1281       if (readers.find(name) != readers.end()) {
  1282 	ErrorMessage msg;
  1283 	msg << "Multiple read rule for edge map: " << name;
  1284 	throw IOParameterError(msg.message());
  1285       }
  1286       readers.insert(
  1287 	make_pair(name, new _reader_bits::
  1288 		  MapReader<UEdge, Map, Reader>(map, reader)));
  1289       return *this;
  1290     }
  1291 
  1292   public:
  1293 
  1294     /// \brief Add a new undirected edge map skipper command for the reader.
  1295     ///
  1296     /// Add a new undirected edge map skipper command for the reader.
  1297     template <typename Reader>
  1298     UEdgeSetReader& skipUEdgeMap(std::string name, 
  1299 					 const Reader& reader = Reader()) {
  1300       if (readers.find(name) != readers.end()) {
  1301 	ErrorMessage msg;
  1302 	msg << "Multiple read rule for node map: " << name;
  1303 	throw IOParameterError(msg.message());
  1304       }
  1305       readers.insert(make_pair(name, new _reader_bits::
  1306 			       SkipReader<UEdge, Reader>(reader)));
  1307       return *this;
  1308     }
  1309 
  1310     /// \brief Add a new directed edge map reader command for the reader.
  1311     ///
  1312     /// Add a new directed edge map reader command for the reader.
  1313     template <typename Map>
  1314     UEdgeSetReader& readEdgeMap(std::string name, Map& map) {
  1315       return _readDirMap<
  1316 	typename Traits::template Reader<typename Map::Value>, Map,
  1317 	typename _reader_bits::Arg<Map>::Type>(name, map);
  1318     }
  1319 
  1320     template <typename Map>
  1321     UEdgeSetReader& readEdgeMap(std::string name, const Map& map) {
  1322       return _readDirMap<
  1323 	typename Traits::template Reader<typename Map::Value>, Map,
  1324 	typename _reader_bits::Arg<Map>::Type>(name, map);
  1325     }
  1326 
  1327     /// \brief Add a new directed edge map reader command for the reader.
  1328     ///
  1329     /// Add a new directed edge map reader command for the reader.
  1330     template <typename Reader, typename Map>
  1331     UEdgeSetReader& readEdgeMap(std::string name, Map& map, 
  1332 				    const Reader& reader = Reader()) {
  1333       return _readDirMap<Reader, Map, typename _reader_bits::Arg<Map>::Type>
  1334 	(name, map, reader);
  1335     }
  1336 
  1337     template <typename Reader, typename Map>
  1338     UEdgeSetReader& readEdgeMap(std::string name, const Map& map, 
  1339 				    const Reader& reader = Reader()) {
  1340       return _readDirMap<Reader, Map, typename _reader_bits::Arg<Map>::Type>
  1341 	(name, map, reader);
  1342     }
  1343 
  1344   private:
  1345 
  1346     template <typename Reader, typename Map, typename MapParameter>
  1347     UEdgeSetReader& _readDirMap(std::string name, MapParameter map,
  1348 				    const Reader& reader = Reader()) { 
  1349       checkConcept<_reader_bits::ItemReader<typename Map::Value>, Reader>();
  1350       checkConcept<concept::WriteMap<Edge, typename Map::Value>, Map>();
  1351       readMap("+" + name, 
  1352 	      _reader_bits::forwardComposeMap(graph, map), reader);
  1353       readMap("-" + name, 
  1354 	      _reader_bits::backwardComposeMap(graph, map), reader);
  1355       return *this;      
  1356     }
  1357 
  1358   public:
  1359 
  1360     /// \brief Add a new directed edge map skipper command for the reader.
  1361     ///
  1362     /// Add a new directed edge map skipper command for the reader.
  1363     template <typename Reader>
  1364     UEdgeSetReader& skipEdgeMap(std::string name, 
  1365 				    const Reader& reader = Reader()) {
  1366       skipMap("+" + name, reader);
  1367       skipMap("-" + name, reader);
  1368       return *this;
  1369     }
  1370 
  1371   protected:
  1372 
  1373     /// \brief Gives back true when the SectionReader can process 
  1374     /// the section with the given header line.
  1375     ///
  1376     /// It gives back true when the header line starts with \c \@uedgeset,
  1377     /// and the header line's name and the edgeset's name are the same.
  1378     virtual bool header(const std::string& line) {
  1379       std::istringstream ls(line);
  1380       std::string command;
  1381       std::string id;
  1382       ls >> command >> name;
  1383       return command == "@uedgeset" && name == id;
  1384     }
  1385 
  1386     /// \brief Reader function of the section.
  1387     ///
  1388     /// It reads the content of the section.
  1389     virtual void read(std::istream& is) {
  1390       if (!nodeLabelReader->isLabelReader()) {
  1391 	throw DataFormatError("Cannot find nodeset or label map");
  1392       }
  1393       std::vector<_reader_bits::MapReaderBase<UEdge>* > index;
  1394       std::string line;
  1395 
  1396       getline(is, line);
  1397       std::istringstream ls(line);	
  1398       std::string id;
  1399       while (ls >> id) {
  1400 	typename MapReaders::iterator it = readers.find(id);
  1401 	if (it != readers.end()) {
  1402 	  index.push_back(it->second);
  1403 	  it->second->touch();
  1404 	} else {
  1405 	  index.push_back(&skipper);
  1406 	}
  1407 	if (id == "label" || (id =="id" && inverter.get() == 0)) {
  1408 	  inverter.reset(index.back()->getInverter());
  1409 	  index.back() = inverter.get();
  1410 	}
  1411       }
  1412       for (typename MapReaders::iterator it = readers.begin();
  1413 	   it != readers.end(); ++it) {
  1414 	if (!it->second->touched()) {
  1415 	  ErrorMessage msg;
  1416 	  msg << "Map not found in file: " << it->first;
  1417 	  throw IOParameterError(msg.message());
  1418 	}
  1419       }
  1420       while (getline(is, line)) {	
  1421 	std::istringstream ls(line);
  1422 	Node from = nodeLabelReader->read(ls);
  1423 	Node to = nodeLabelReader->read(ls);
  1424 	UEdge edge = graph.addEdge(from, to);
  1425 	for (int i = 0; i < (int)index.size(); ++i) {
  1426 	  index[i]->read(ls, edge);
  1427 	}
  1428       }
  1429     }
  1430 
  1431   public:
  1432 
  1433     /// \brief Returns true if the edgeset can give back the edge by its label.
  1434     ///
  1435     /// Returns true if the edgeset can give back the undirected edge by its 
  1436     /// id. It is possible only if an "label" named map was read.
  1437     bool isLabelReader() const {
  1438       return inverter.get() != 0;
  1439     }
  1440 
  1441     /// \brief Gives back the undirected edge by its label.
  1442     ///
  1443     /// It reads an id from the stream and gives back which undirected edge 
  1444     /// belongs to it. It is possible only if there was read an "label" named map.
  1445     void readLabel(std::istream& is, UEdge& uEdge) const {
  1446       uEdge = inverter->read(is);
  1447     } 
  1448 
  1449     /// \brief Gives back the directed edge by its label.
  1450     ///
  1451     /// It reads an id from the stream and gives back which directed edge 
  1452     /// belongs to it. The directed edge id is the \c '+' or \c '-' character
  1453     /// and the undirected edge id. It is possible only if there was read 
  1454     /// an "label" named map.
  1455     void readLabel(std::istream& is, Edge& edge) const {
  1456       char c;
  1457       is >> c;
  1458       UEdge uEdge = inverter->read(is);
  1459       if (c == '+') {
  1460 	edge = graph.direct(uEdge, true);
  1461       } else if (c == '-') {
  1462         edge = graph.direct(uEdge, false);
  1463       } else {
  1464 	throw DataFormatError("Wrong id format for edge "
  1465 			      "in undirected edgeset");
  1466       }
  1467     } 
  1468 
  1469   private:
  1470 
  1471     typedef std::map<std::string, 
  1472 		     _reader_bits::MapReaderBase<UEdge>*> MapReaders;
  1473     MapReaders readers;
  1474    
  1475     Graph& graph;   
  1476     std::string name;
  1477     _reader_bits::SkipReader<UEdge, DefaultSkipper> skipper;
  1478 
  1479     std::auto_ptr<_reader_bits::MapInverterBase<UEdge> > inverter;
  1480     std::auto_ptr<_reader_bits::LabelReaderBase<Node> > nodeLabelReader;
  1481   };
  1482 
  1483   /// \ingroup io_group
  1484   /// \brief SectionReader for reading labeled nodes.
  1485   ///
  1486   /// The nodes section's header line is \c \@nodes \c nodes_name, but the
  1487   /// \c nodes_name may be empty.
  1488   ///
  1489   /// Each line in the section contains the name of the node 
  1490   /// and then the node id. 
  1491   ///
  1492   /// \relates LemonReader
  1493   template <typename _Graph>
  1494   class NodeReader : public LemonReader::SectionReader {
  1495     typedef LemonReader::SectionReader Parent;
  1496     typedef _Graph Graph;
  1497     typedef typename Graph::Node Node;
  1498   public:
  1499     
  1500     /// \brief Constructor.
  1501     ///
  1502     /// Constructor for NodeReader. It creates the NodeReader and
  1503     /// attach it into the given LemonReader. It will use the given
  1504     /// node id reader to give back the nodes. The reader will read the 
  1505     /// section only if the \c _name and the \c nodes_name are the same. 
  1506     template <typename _LabelReader>
  1507     NodeReader(LemonReader& _reader, const _LabelReader& _labelReader, 
  1508 	       const std::string& _name = std::string()) 
  1509       : Parent(_reader), name(_name) {
  1510       checkConcept<_reader_bits::ItemLabelReader<Node>, _LabelReader>();
  1511       nodeLabelReader.reset(new _reader_bits::
  1512 			 LabelReader<Node, _LabelReader>(_labelReader));
  1513     }
  1514 
  1515     /// \brief Destructor.
  1516     ///
  1517     /// Destructor for NodeReader.
  1518     virtual ~NodeReader() {}
  1519 
  1520   private:
  1521     NodeReader(const NodeReader&);
  1522     void operator=(const NodeReader&);
  1523 
  1524   public:
  1525 
  1526     /// \brief Add a node reader command for the NodeReader.
  1527     ///
  1528     /// Add a node reader command for the NodeReader.
  1529     void readNode(const std::string& name, Node& item) {
  1530       if (readers.find(name) != readers.end()) {
  1531 	ErrorMessage msg;
  1532 	msg << "Multiple read rule for node: " << name;
  1533 	throw IOParameterError(msg.message());
  1534       }
  1535       readers.insert(make_pair(name, _reader_bits::ItemStore<Node>(item)));
  1536     }
  1537 
  1538   protected:
  1539 
  1540     /// \brief Gives back true when the SectionReader can process 
  1541     /// the section with the given header line.
  1542     ///
  1543     /// It gives back true when the header line start with \c \@nodes,
  1544     /// and the header line's name and the reader's name are the same.
  1545     virtual bool header(const std::string& line) {
  1546       std::istringstream ls(line);
  1547       std::string command;
  1548       std::string id;
  1549       ls >> command >> name;
  1550       return command == "@nodes" && name == id;
  1551     }
  1552 
  1553     /// \brief Reader function of the section.
  1554     ///
  1555     /// It reads the content of the section.
  1556     virtual void read(std::istream& is) {
  1557       if (!nodeLabelReader->isLabelReader()) {
  1558 	throw DataFormatError("Cannot find nodeset or label map");
  1559       }
  1560       std::string line;
  1561       while (getline(is, line)) {
  1562 	std::istringstream ls(line);
  1563 	std::string id;
  1564 	ls >> id;
  1565 	typename NodeReaders::iterator it = readers.find(id);
  1566 	if (it != readers.end()) {
  1567 	  it->second.read(nodeLabelReader->read(ls));
  1568 	  it->second.touch();
  1569 	}	
  1570       }
  1571       for (typename NodeReaders::iterator it = readers.begin();
  1572 	   it != readers.end(); ++it) {
  1573 	if (!it->second.touched()) {
  1574 	  ErrorMessage msg;
  1575 	  msg << "Node not found in file: " << it->first;
  1576 	  throw IOParameterError(msg.message());
  1577 	}
  1578       }
  1579     }
  1580     
  1581   private:
  1582 
  1583     std::string name;
  1584 
  1585     typedef std::map<std::string, _reader_bits::ItemStore<Node> > NodeReaders;
  1586     NodeReaders readers;
  1587     std::auto_ptr<_reader_bits::LabelReaderBase<Node> > nodeLabelReader;
  1588   };
  1589 
  1590   /// \ingroup io_group
  1591   /// \brief SectionReader for reading labeled edges.
  1592   ///
  1593   /// The edges section's header line is \c \@edges \c edges_name, but the
  1594   /// \c edges_name may be empty.
  1595   ///
  1596   /// Each line in the section contains the name of the edge 
  1597   /// and then the edge id. 
  1598   ///
  1599   /// \relates LemonReader
  1600   template <typename _Graph>
  1601   class EdgeReader : public LemonReader::SectionReader {
  1602     typedef LemonReader::SectionReader Parent;
  1603     typedef _Graph Graph;
  1604     typedef typename Graph::Edge Edge;
  1605   public:
  1606     
  1607     /// \brief Constructor.
  1608     ///
  1609     /// Constructor for EdgeReader. It creates the EdgeReader and
  1610     /// attach it into the given LemonReader. It will use the given
  1611     /// edge id reader to give back the edges. The reader will read the 
  1612     /// section only if the \c _name and the \c edges_name are the same. 
  1613     template <typename _LabelReader>
  1614     EdgeReader(LemonReader& _reader, const _LabelReader& _labelReader, 
  1615 	       const std::string& _name = std::string()) 
  1616       : Parent(_reader), name(_name) {
  1617       checkConcept<_reader_bits::ItemLabelReader<Edge>, _LabelReader>();
  1618       edgeLabelReader.reset(new _reader_bits::
  1619 			 LabelReader<Edge, _LabelReader>(_labelReader));
  1620     }
  1621 
  1622     /// \brief Destructor.
  1623     ///
  1624     /// Destructor for EdgeReader.
  1625     virtual ~EdgeReader() {}
  1626   private:
  1627     EdgeReader(const EdgeReader&);
  1628     void operator=(const EdgeReader&);
  1629 
  1630   public:
  1631 
  1632     /// \brief Add an edge reader command for the EdgeReader.
  1633     ///
  1634     /// Add an edge reader command for the EdgeReader.
  1635     void readEdge(const std::string& name, Edge& item) {
  1636       if (readers.find(name) != readers.end()) {
  1637 	ErrorMessage msg;
  1638 	msg << "Multiple read rule for edge: " << name;
  1639 	throw IOParameterError(msg.message());
  1640       }
  1641       readers.insert(make_pair(name, _reader_bits::ItemStore<Edge>(item)));
  1642     }
  1643 
  1644   protected:
  1645 
  1646     /// \brief Gives back true when the SectionReader can process 
  1647     /// the section with the given header line.
  1648     ///
  1649     /// It gives back true when the header line start with \c \@edges,
  1650     /// and the header line's name and the reader's name are the same.
  1651     virtual bool header(const std::string& line) {
  1652       std::istringstream ls(line);
  1653       std::string command;
  1654       std::string id;
  1655       ls >> command >> name;
  1656       return command == "@edges" && name == id;
  1657     }
  1658 
  1659     /// \brief Reader function of the section.
  1660     ///
  1661     /// It reads the content of the section.
  1662     virtual void read(std::istream& is) {
  1663       if (!edgeLabelReader->isLabelReader()) {
  1664 	throw DataFormatError("Cannot find edgeset or label map");
  1665       }
  1666       std::string line;
  1667       while (getline(is, line)) {
  1668 	std::istringstream ls(line);
  1669 	std::string id;
  1670 	ls >> id;
  1671 	typename EdgeReaders::iterator it = readers.find(id);
  1672 	if (it != readers.end()) {
  1673 	  it->second.read(edgeLabelReader->read(ls));
  1674 	  it->second.touch();
  1675 	}	
  1676       }
  1677       for (typename EdgeReaders::iterator it = readers.begin();
  1678 	   it != readers.end(); ++it) {
  1679 	if (!it->second.touched()) {
  1680 	  ErrorMessage msg;
  1681 	  msg << "Edge not found in file: " << it->first;
  1682 	  throw IOParameterError(msg.message());
  1683 	}
  1684       }
  1685     }
  1686     
  1687   private:
  1688 
  1689     std::string name;
  1690 
  1691     typedef std::map<std::string, _reader_bits::ItemStore<Edge> > EdgeReaders;
  1692     EdgeReaders readers;
  1693     std::auto_ptr<_reader_bits::LabelReaderBase<Edge> > edgeLabelReader;
  1694   };
  1695 
  1696   /// \ingroup io_group
  1697   /// \brief SectionReader for reading labeled undirected edges.
  1698   ///
  1699   /// The undirected edges section's header line is \c \@uedges 
  1700   /// \c uedges_name, but the \c uedges_name may be empty.
  1701   ///
  1702   /// Each line in the section contains the name of the undirected edge 
  1703   /// and then the undirected edge id. 
  1704   ///
  1705   /// \relates LemonReader
  1706   template <typename _Graph>
  1707   class UEdgeReader : public LemonReader::SectionReader {
  1708     typedef LemonReader::SectionReader Parent;
  1709     typedef _Graph Graph;
  1710     typedef typename Graph::Edge Edge;
  1711     typedef typename Graph::UEdge UEdge;
  1712   public:
  1713     
  1714     /// \brief Constructor.
  1715     ///
  1716     /// Constructor for UEdgeReader. It creates the UEdgeReader and
  1717     /// attach it into the given LemonReader. It will use the given
  1718     /// undirected edge id reader to give back the edges. The reader will 
  1719     /// read the section only if the \c _name and the \c uedges_name are 
  1720     /// the same. 
  1721     template <typename _LabelReader>
  1722     UEdgeReader(LemonReader& _reader, const _LabelReader& _labelReader, 
  1723 	       const std::string& _name = std::string()) 
  1724       : Parent(_reader), name(_name) {
  1725       checkConcept<_reader_bits::ItemLabelReader<UEdge>, _LabelReader>();
  1726       checkConcept<_reader_bits::ItemLabelReader<Edge>, _LabelReader>();
  1727       uEdgeLabelReader.reset(new _reader_bits::
  1728 			      LabelReader<UEdge, _LabelReader>(_labelReader));
  1729       edgeLabelReader.reset(new _reader_bits::
  1730 			 LabelReader<Edge, _LabelReader>(_labelReader));
  1731     }
  1732 
  1733     /// \brief Destructor.
  1734     ///
  1735     /// Destructor for UEdgeReader.
  1736     virtual ~UEdgeReader() {}
  1737   private:
  1738     UEdgeReader(const UEdgeReader&);
  1739     void operator=(const UEdgeReader&);
  1740 
  1741   public:
  1742 
  1743     /// \brief Add an undirected edge reader command for the UEdgeReader.
  1744     ///
  1745     /// Add an undirected edge reader command for the UEdgeReader.
  1746     void readUEdge(const std::string& name, UEdge& item) {
  1747       if (uEdgeReaders.find(name) != uEdgeReaders.end()) {
  1748 	ErrorMessage msg;
  1749 	msg << "Multiple read rule for undirected edge: " << name;
  1750 	throw IOParameterError(msg.message());
  1751       }
  1752       uEdgeReaders.insert(make_pair(name, _reader_bits::
  1753 					ItemStore<UEdge>(item)));
  1754     }
  1755 
  1756     /// \brief Add an edge reader command for the UEdgeReader.
  1757     ///
  1758     /// Add an edge reader command for the UEdgeReader.
  1759     void readEdge(const std::string& name, Edge& item) {
  1760       if (edgeReaders.find(name) != edgeReaders.end()) {
  1761 	ErrorMessage msg;
  1762 	msg << "Multiple read rule for edge: " << name;
  1763 	throw IOParameterError(msg.message());
  1764       }
  1765       edgeReaders.insert(make_pair(name, _reader_bits::ItemStore<Edge>(item)));
  1766     }
  1767 
  1768   protected:
  1769 
  1770     /// \brief Gives back true when the SectionReader can process 
  1771     /// the section with the given header line.
  1772     ///
  1773     /// It gives back true when the header line start with \c \@edges,
  1774     /// and the header line's name and the reader's name are the same.
  1775     virtual bool header(const std::string& line) {
  1776       std::istringstream ls(line);
  1777       std::string command;
  1778       std::string id;
  1779       ls >> command >> name;
  1780       return command == "@uedges" && name == id;
  1781     }
  1782 
  1783     /// \brief Reader function of the section.
  1784     ///
  1785     /// It reads the content of the section.
  1786     virtual void read(std::istream& is) {
  1787       if (!edgeLabelReader->isLabelReader()) {
  1788 	throw DataFormatError("Cannot find undirected edgeset or label map");
  1789       }
  1790       if (!uEdgeLabelReader->isLabelReader()) {
  1791 	throw DataFormatError("Cannot find undirected edgeset or label map");
  1792       }
  1793       std::string line;
  1794       while (getline(is, line)) {
  1795 	std::istringstream ls(line);
  1796 	std::string id;
  1797 	ls >> id;
  1798 	{
  1799 	  typename UEdgeReaders::iterator it = uEdgeReaders.find(id);
  1800 	  if (it != uEdgeReaders.end()) {
  1801 	    it->second.read(uEdgeLabelReader->read(ls));
  1802 	    it->second.touch();
  1803 	    continue;
  1804 	  }	
  1805 	} {
  1806 	  typename EdgeReaders::iterator it = edgeReaders.find(id);
  1807 	  if (it != edgeReaders.end()) {
  1808 	    it->second.read(edgeLabelReader->read(ls));
  1809 	    it->second.touch();
  1810 	    continue;
  1811 	  }	
  1812 	}
  1813       }
  1814       for (typename EdgeReaders::iterator it = edgeReaders.begin();
  1815 	   it != edgeReaders.end(); ++it) {
  1816 	if (!it->second.touched()) {
  1817 	  ErrorMessage msg;
  1818 	  msg << "Edge not found in file: " << it->first;
  1819 	  throw IOParameterError(msg.message());
  1820 	}
  1821       }
  1822       for (typename UEdgeReaders::iterator it = uEdgeReaders.begin();
  1823 	   it != uEdgeReaders.end(); ++it) {
  1824 	if (!it->second.touched()) {
  1825 	  ErrorMessage msg;
  1826 	  msg << "UEdge not found in file: " << it->first;
  1827 	  throw IOParameterError(msg.message());
  1828 	}
  1829       }
  1830     }
  1831     
  1832   private:
  1833 
  1834     std::string name;
  1835 
  1836     typedef std::map<std::string, 
  1837 		     _reader_bits::ItemStore<UEdge> > UEdgeReaders;
  1838     UEdgeReaders uEdgeReaders;
  1839     std::auto_ptr<_reader_bits::LabelReaderBase<UEdge> > uEdgeLabelReader;
  1840 
  1841     typedef std::map<std::string, _reader_bits::ItemStore<Edge> > EdgeReaders;
  1842     EdgeReaders edgeReaders;
  1843     std::auto_ptr<_reader_bits::LabelReaderBase<Edge> > edgeLabelReader;
  1844   };
  1845 
  1846   /// \ingroup io_group
  1847   /// \brief SectionReader for attributes.
  1848   ///
  1849   /// The lemon format can store multiple attribute set. Each set has
  1850   /// the header line \c \@attributes \c attributeset_name, but the 
  1851   /// attributeset_name may be empty.
  1852   ///
  1853   /// The attributeset section contains several lines. Each of them starts
  1854   /// with an attribute and then a the value for the id.
  1855   ///
  1856   /// \relates LemonReader
  1857   template <typename _Traits = DefaultReaderTraits>
  1858   class AttributeReader : public LemonReader::SectionReader {
  1859     typedef LemonReader::SectionReader Parent;
  1860     typedef _Traits Traits; 
  1861   public:
  1862     /// \brief Constructor.
  1863     ///
  1864     /// Constructor for AttributeReader. It creates the AttributeReader and
  1865     /// attach it into the given LemonReader. The reader process a section
  1866     /// only if the \c section_name and the \c _name are the same.
  1867     AttributeReader(LemonReader& _reader, 
  1868 		    const std::string& _name = std::string()) 
  1869       : Parent(_reader), name(_name) {}
  1870 
  1871     /// \brief Destructor.
  1872     ///
  1873     /// Destructor for AttributeReader.
  1874     virtual ~AttributeReader() {
  1875       for (typename Readers::iterator it = readers.begin(); 
  1876 	   it != readers.end(); ++it) {
  1877 	delete it->second;
  1878       }
  1879     }
  1880 
  1881   private:
  1882     AttributeReader(const AttributeReader&);
  1883     void operator=(AttributeReader&);
  1884 
  1885   public:
  1886     /// \brief Add an attribute reader command for the reader.
  1887     ///
  1888     /// Add an attribute reader command for the reader.
  1889     template <typename Value>
  1890     AttributeReader& readAttribute(const std::string& id, Value& value) {
  1891       return readAttribute<typename Traits::template Reader<Value> >
  1892 	(id, value);
  1893     }
  1894 
  1895     /// \brief Add an attribute reader command for the reader.
  1896     ///
  1897     /// Add an attribute reader command for the reader.
  1898     template <typename Reader, typename Value>
  1899     AttributeReader& readAttribute(const std::string& name, Value& value,
  1900 				   const Reader& reader = Reader()) {
  1901       checkConcept<_reader_bits::ItemReader<Value>, Reader>();
  1902       if (readers.find(name) != readers.end()) {
  1903 	ErrorMessage msg;
  1904 	msg << "Multiple read rule for attribute: " << name;
  1905 	throw IOParameterError(msg.message());
  1906       }
  1907       readers.insert(make_pair(name, new _reader_bits::
  1908 			       ValueReader<Value, Reader>(value, reader)));
  1909       return *this;
  1910     }
  1911 
  1912   protected:
  1913 
  1914     /// \brief Gives back true when the SectionReader can process 
  1915     /// the section with the given header line.
  1916     ///
  1917     /// It gives back true when the header line start with \c \@attributes,
  1918     /// and the header line's id and the attributeset's id are the same.
  1919     bool header(const std::string& line) {
  1920       std::istringstream ls(line);
  1921       std::string command;
  1922       std::string id;
  1923       ls >> command >> name;
  1924       return command == "@attributes" && name == id;
  1925     }
  1926 
  1927     /// \brief Reader function of the section.
  1928     ///
  1929     /// It reads the content of the section.
  1930     void read(std::istream& is) {
  1931       std::string line;
  1932       while (getline(is, line)) {
  1933 	std::istringstream ls(line);
  1934 	std::string id;
  1935 	ls >> id;
  1936 	typename Readers::iterator it = readers.find(id);
  1937 	if (it != readers.end()) {
  1938 	  it->second->read(ls);
  1939  	  it->second->touch();
  1940 	}
  1941       }
  1942       for (typename Readers::iterator it = readers.begin();
  1943 	   it != readers.end(); ++it) {
  1944 	if (!it->second->touched()) {
  1945 	  ErrorMessage msg;
  1946 	  msg << "Attribute not found in file: " << it->first;
  1947 	  throw IOParameterError(msg.message());
  1948 	}	
  1949       }
  1950     }    
  1951 
  1952   private:
  1953     std::string name;
  1954 
  1955     typedef std::map<std::string, _reader_bits::ValueReaderBase*> Readers;
  1956     Readers readers;  
  1957   };
  1958 
  1959   /// \ingroup io_group
  1960   /// \brief SectionReader for retrieve what is in the file.
  1961   ///
  1962   /// SectionReader for retrieve what is in the file. If you want
  1963   /// to know which sections, maps and items are in the file
  1964   /// use the next code:
  1965   ///\code
  1966   /// LemonReader reader("input.lgf");
  1967   /// ContentReader content(reader);
  1968   /// reader.run();
  1969   ///\endcode
  1970   class ContentReader : public LemonReader::SectionReader {
  1971     typedef LemonReader::SectionReader Parent;
  1972   public:
  1973     /// \brief Constructor.
  1974     ///
  1975     /// Constructor for
  1976     ContentReader(LemonReader& _reader) : Parent(_reader) {}
  1977 
  1978     /// \brief Desctructor.
  1979     ///
  1980     /// Desctructor.
  1981     virtual ~ContentReader() {}
  1982 
  1983     /// \brief Gives back how many nodesets are in the file.
  1984     ///
  1985     /// Gives back how many nodesets are in the file.
  1986     int nodeSetNum() const {
  1987       return nodesets.size();
  1988     }
  1989 
  1990     /// \brief Gives back the name of nodeset on the indiced position.
  1991     ///
  1992     /// Gives back the name of nodeset on the indiced position.
  1993     std::string nodeSetName(int index) const {
  1994       return nodesets[index].name;
  1995     }
  1996 
  1997     /// \brief Gives back the map names of nodeset on the indiced position.
  1998     ///
  1999     /// Gives back the map names of nodeset on the indiced position.
  2000     const std::vector<std::string>& nodeSetMaps(int index) const {
  2001       return nodesets[index].items;
  2002     }
  2003 
  2004     /// \brief Gives back how many edgesets are in the file.
  2005     ///
  2006     /// Gives back how many edgesets are in the file.
  2007     int edgeSetNum() const {
  2008       return edgesets.size();
  2009     }
  2010 
  2011     /// \brief Gives back the name of edgeset on the indiced position.
  2012     ///
  2013     /// Gives back the name of edgeset on the indiced position.
  2014     std::string edgeSetName(int index) const {
  2015       return edgesets[index].name;
  2016     }
  2017 
  2018     /// \brief Gives back the map names of edgeset on the indiced position.
  2019     ///
  2020     /// Gives back the map names of edgeset on the indiced position.
  2021     const std::vector<std::string>& edgeSetMaps(int index) const {
  2022       return edgesets[index].items;
  2023     }
  2024 
  2025     /// \brief Gives back how many undirected edgesets are in the file.
  2026     ///
  2027     /// Gives back how many undirected edgesets are in the file.
  2028     int uEdgeSetNum() const {
  2029       return uedgesets.size();
  2030     }
  2031 
  2032     /// \brief Gives back the name of undirected edgeset on the indiced 
  2033     /// position.
  2034     ///
  2035     /// Gives back the name of undirected edgeset on the indiced position.
  2036     std::string uEdgeSetName(int index) const {
  2037       return uedgesets[index].name;
  2038     }
  2039 
  2040     /// \brief Gives back the map names of undirected edgeset on the indiced 
  2041     /// position.
  2042     ///
  2043     /// Gives back the map names of undirected edgeset on the indiced position.
  2044     const std::vector<std::string>& uEdgeSetMaps(int index) const {
  2045       return uedgesets[index].items;
  2046     }
  2047 
  2048     /// \brief Gives back how many labeled nodes section are in the file.
  2049     ///
  2050     /// Gives back how many labeled nodes section are in the file.
  2051     int nodesNum() const {
  2052       return nodes.size();
  2053     }
  2054 
  2055     /// \brief Gives back the name of labeled nodes section on the indiced 
  2056     /// position.
  2057     ///
  2058     /// Gives back the name of labeled nodes section on the indiced position.
  2059     std::string nodesName(int index) const {
  2060       return nodes[index].name;
  2061     }
  2062 
  2063     /// \brief Gives back the names of the labeled nodes in the indiced 
  2064     /// section.
  2065     ///
  2066     /// Gives back the names of the labeled nodes in the indiced section.
  2067     const std::vector<std::string>& nodesItems(int index) const {
  2068       return nodes[index].items;
  2069     }
  2070 
  2071     /// \brief Gives back how many labeled edges section are in the file.
  2072     ///
  2073     /// Gives back how many labeled edges section are in the file.
  2074     int edgesNum() const {
  2075       return edges.size();
  2076     }
  2077 
  2078     /// \brief Gives back the name of labeled edges section on the indiced 
  2079     /// position.
  2080     ///
  2081     /// Gives back the name of labeled edges section on the indiced position.
  2082     std::string edgesName(int index) const {
  2083       return edges[index].name;
  2084     }
  2085 
  2086     /// \brief Gives back the names of the labeled edges in the indiced 
  2087     /// section.
  2088     ///
  2089     /// Gives back the names of the labeled edges in the indiced section.
  2090     const std::vector<std::string>& edgesItems(int index) const {
  2091       return edges[index].items;
  2092     }
  2093  
  2094     /// \brief Gives back how many labeled undirected edges section are 
  2095     /// in the file.
  2096     ///
  2097     /// Gives back how many labeled undirected edges section are in the file.
  2098     int uEdgesNum() const {
  2099       return uedges.size();
  2100     }
  2101 
  2102     /// \brief Gives back the name of labeled undirected edges section 
  2103     /// on the indiced position.
  2104     ///
  2105     /// Gives back the name of labeled undirected edges section on the 
  2106     /// indiced position.
  2107     std::string uEdgesName(int index) const {
  2108       return uedges[index].name;
  2109     }
  2110 
  2111     /// \brief Gives back the names of the labeled undirected edges in 
  2112     /// the indiced section.
  2113     ///
  2114     /// Gives back the names of the labeled undirected edges in the 
  2115     /// indiced section.
  2116     const std::vector<std::string>& uEdgesItems(int index) const {
  2117       return uedges[index].items;
  2118     }
  2119 
  2120  
  2121     /// \brief Gives back how many attributes section are in the file.
  2122     ///
  2123     /// Gives back how many attributes section are in the file.
  2124     int attributesNum() const {
  2125       return attributes.size();
  2126     }
  2127 
  2128     /// \brief Gives back the name of attributes section on the indiced 
  2129     /// position.
  2130     ///
  2131     /// Gives back the name of attributes section on the indiced position.
  2132     std::string attributesName(int index) const {
  2133       return attributes[index].name;
  2134     }
  2135 
  2136     /// \brief Gives back the names of the attributes in the indiced section.
  2137     ///
  2138     /// Gives back the names of the attributes in the indiced section.
  2139     const std::vector<std::string>& attributesItems(int index) const {
  2140       return attributes[index].items;
  2141     }
  2142 
  2143     const std::vector<std::string>& otherSections() const {
  2144       return sections;
  2145     }
  2146 
  2147   protected:
  2148     
  2149     /// \brief Gives back true when the SectionReader can process 
  2150     /// the section with the given header line.
  2151     ///
  2152     /// It gives back true when the section is common section.
  2153     bool header(const std::string& line) {
  2154       std::istringstream ls(line);
  2155       std::string command, name;
  2156       ls >> command >> name;
  2157       if (command == "@nodeset") {
  2158 	current = command;
  2159 	nodesets.push_back(SectionInfo(name));
  2160       } else if (command == "@edgeset") {
  2161 	current = command;
  2162 	edgesets.push_back(SectionInfo(name));
  2163       } else if (command == "@uedgeset") {
  2164 	current = command;
  2165 	uedgesets.push_back(SectionInfo(name));
  2166       } else if (command == "@nodes") {
  2167 	current = command;
  2168 	nodes.push_back(SectionInfo(name));
  2169       } else if (command == "@edges") {
  2170 	current = command;
  2171 	edges.push_back(SectionInfo(name));
  2172       } else if (command == "@uedges") {
  2173 	current = command;
  2174 	uedges.push_back(SectionInfo(name));
  2175       } else if (command == "@attributes") {
  2176 	current = command;
  2177 	attributes.push_back(SectionInfo(name));
  2178       } else {
  2179 	sections.push_back(line);
  2180 	return false;
  2181       }
  2182       return true;
  2183     }
  2184 
  2185     /// \brief Retrieve the items from various sections.
  2186     ///
  2187     /// Retrieve the items from various sections.
  2188     void read(std::istream& is) {
  2189       if (current == "@nodeset") {
  2190 	readMapNames(is, nodesets.back().items);
  2191       } else if (current == "@edgeset") {
  2192 	readMapNames(is, edgesets.back().items);
  2193       } else if (current == "@uedgeset") {
  2194 	readMapNames(is, uedgesets.back().items);
  2195       } else if (current == "@nodes") {
  2196 	readItemNames(is, nodes.back().items);
  2197       } else if (current == "@edges") {
  2198 	readItemNames(is, edges.back().items);
  2199       } else if (current == "@uedges") {
  2200 	readItemNames(is, uedges.back().items);
  2201       } else if (current == "@attributes") {
  2202 	readItemNames(is, attributes.back().items);
  2203       }
  2204     }    
  2205 
  2206   private:
  2207 
  2208     void readMapNames(std::istream& is, std::vector<std::string>& maps) {
  2209       std::string line, name;
  2210       std::getline(is, line);
  2211       std::istringstream ls(line);
  2212       while (ls >> name) {
  2213 	maps.push_back(name);
  2214       }
  2215       while (getline(is, line));
  2216     }
  2217 
  2218     void readItemNames(std::istream& is, std::vector<std::string>& maps) {
  2219       std::string line, name;
  2220       while (std::getline(is, line)) {
  2221 	std::istringstream ls(line);
  2222 	ls >> name;
  2223 	maps.push_back(name);
  2224       }
  2225     }
  2226 
  2227     struct SectionInfo {
  2228       std::string name;
  2229       std::vector<std::string> items;
  2230 
  2231       SectionInfo(const std::string& _name) : name(_name) {}
  2232     };
  2233 
  2234     std::vector<SectionInfo> nodesets;
  2235     std::vector<SectionInfo> edgesets;
  2236     std::vector<SectionInfo> uedgesets;
  2237 
  2238     std::vector<SectionInfo> nodes;
  2239     std::vector<SectionInfo> edges;
  2240     std::vector<SectionInfo> uedges;
  2241 
  2242     std::vector<SectionInfo> attributes;
  2243 
  2244     std::vector<std::string> sections;
  2245 
  2246     std::string current;
  2247 
  2248   };
  2249 
  2250 }
  2251 #endif