doc/read_write_bg.dox
author deba
Fri, 19 Oct 2007 16:24:31 +0000
changeset 2499 c97596611d59
parent 2216 1e45cdeea3cc
child 2553 bfced05fa852
permissions -rw-r--r--
Planar Grid Embedding
     1 /* -*- C++ -*-
     2  *
     3  * This file is a part of LEMON, a generic C++ optimization library
     4  *
     5  * Copyright (C) 2003-2007
     6  * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
     7  * (Egervary Research Group on Combinatorial Optimization, EGRES).
     8  *
     9  * Permission to use, modify and distribute this software is granted
    10  * provided that this copyright notice appears in all copies. For
    11  * precise terms see the accompanying LICENSE file.
    12  *
    13  * This software is provided "AS IS" with no warranty of any kind,
    14  * express or implied, and with no claim as to its suitability for any
    15  * purpose.
    16  *
    17  */
    18 
    19 namespace lemon {
    20 /*!
    21 \page read_write_bg Background of Reading and Writing
    22 
    23 To read a map (on the nodes or edges)
    24 the \ref lemon::GraphReader "GraphReader"
    25 should know how to read a Value from the given map.
    26 By the default implementation the input operator reads a value from
    27 the stream and the type of the read value is the value type of the given map.
    28 When the reader should skip a value in the stream, because you do not
    29 want to store it in a map, the reader skips a character sequence without 
    30 whitespaces. 
    31 
    32 If you want to change the functionality of the reader, you can use
    33 template parameters to specialize it. When you give a reading
    34 command for a map you can give a Reader type as template parameter.
    35 With this template parameter you can control how the Reader reads
    36 a value from the stream.
    37 
    38 The reader has the next structure: 
    39 \code
    40 struct TypeReader {
    41   typedef TypeName Value;
    42 
    43   void read(std::istream& is, Value& value);
    44 };
    45 \endcode
    46 
    47 For example, the \c "strings" nodemap contains strings and you do not need
    48 the value of the string just the length. Then you can implement an own Reader
    49 struct.
    50 
    51 \code
    52 struct LengthReader {
    53   typedef int Value;
    54 
    55   void read(std::istream& is, Value& value) {
    56     std::string tmp;
    57     is >> tmp;
    58     value = tmp.length();
    59   }
    60 };
    61 ...
    62 reader.readNodeMap<LengthReader>("strings", lengthMap);
    63 \endcode  
    64 
    65 The global functionality of the reader class can be changed by giving a
    66 special template parameter to the GraphReader class. By default, the
    67 template parameter is \c DefaultReaderTraits. A reader traits class 
    68 should provide a nested template class Reader for each type, and a 
    69 DefaultReader for skipping a value.
    70 
    71 The specialization of writing is very similar to that of reading.
    72 
    73 \section u Undirected graphs
    74 
    75 In a file describing an undirected graph (ugraph, for short) you find an
    76 \c uedgeset section instead of the \c edgeset section. The first line of
    77 the section describes the names of the maps on the undirected egdes and all
    78 next lines describe one undirected edge with the the incident nodes and the
    79 values of the map.
    80 
    81 The format handles directed edge maps as a syntactical sugar???, if there
    82 are two maps with names being the same with a \c '+' and a \c '-' prefix
    83 then this will be read as a directed map.
    84 
    85 \code
    86 @uedgeset
    87              label      capacity        +flow   -flow
    88 32   2       1          4.3             2.0     0.0
    89 21   21      5          2.6             0.0     2.6
    90 21   12      8          3.4             0.0     0.0
    91 \endcode
    92 
    93 The \c edges section is changed to \c uedges section. This section
    94 describes labeled edges and undirected edges. The directed edge label
    95 should start with a \c '+' or a \c '-' prefix to decide the direction
    96 of the edge. 
    97 
    98 \code
    99 @uedges
   100 uedge 1
   101 +edge 5
   102 -back 5
   103 \endcode
   104 
   105 There are similar classes to the \ref lemon::GraphReader "GraphReader" and
   106 \ref lemon::GraphWriter "GraphWriter" which
   107 handle the undirected graphs. These classes are
   108 the \ref lemon::UGraphReader "UGraphReader"
   109 and \ref lemon::UGraphWriter "UGraphWriter".
   110 
   111 The \ref lemon::UGraphReader::readUEdgeMap() "readUEdgeMap()"
   112 function reads an undirected map and the
   113 \ref lemon::UGraphReader::readUEdge() "readUEdge()"
   114 reads an undirected edge from the file, 
   115 
   116 \code
   117 reader.readUEdgeMap("capacity", capacityMap);
   118 reader.readEdgeMap("flow", flowMap);
   119 ...
   120 reader.readUEdge("u_edge", u_edge);
   121 reader.readEdge("edge", edge);
   122 \endcode
   123 
   124 \section advanced Advanced features
   125 
   126 The graph reader and writer classes give an easy way to read and write
   127 graphs. But sometimes we want more advanced features. In this case we can
   128 use the more general <tt>lemon reader and writer</tt> interface.
   129 
   130 The LEMON file format is a section oriented file format. It contains one or
   131 more sections, each starting with a line identifying its type 
   132 (the word starting with the \c \@  character).
   133 The content of the section this way cannot contain line with \c \@ first
   134 character. The file may contains comment lines with \c # first character.
   135 
   136 The \ref lemon::LemonReader "LemonReader"
   137 and \ref lemon::LemonWriter "LemonWriter"
   138 gives a framework to read and
   139 write sections. There are various section reader and section writer
   140 classes which can be attached to a \ref lemon::LemonReader "LemonReader"
   141 or a \ref lemon::LemonWriter "LemonWriter".
   142 
   143 There are default section readers and writers for reading and writing
   144 item sets, and labeled items in the graph. These read and write
   145 the format described above. Other type of data can be handled with own
   146 section reader and writer classes which are inherited from the
   147 \c LemonReader::SectionReader or the
   148 \ref lemon::LemonWriter::SectionWriter "LemonWriter::SectionWriter"
   149 classes.
   150 
   151 The next example defines a special section reader which reads the
   152 \c \@description sections into a string:
   153 
   154 \code 
   155 class DescriptionReader : LemonReader::SectionReader {
   156 protected:
   157   virtual bool header(const std::string& line) {
   158     std::istringstream ls(line);
   159     std::string head;
   160     ls >> head;
   161     return head == "@description";
   162   }
   163 
   164   virtual void read(std::istream& is) {
   165     std::string line;
   166     while (getline(is, line)) {
   167       desc += line;
   168     }
   169   }
   170 public:
   171 
   172   typedef LemonReader::SectionReader Parent;
   173   
   174   DescriptionReader(LemonReader& reader) : Parent(reader) {}
   175 
   176   const std::string& description() const {
   177     return description;
   178   }
   179 
   180 private:
   181   std::string desc;
   182 };
   183 \endcode
   184 
   185 The other advanced stuff of the generalized file format is that 
   186 multiple edgesets can be stored to the same nodeset. It can be used 
   187 for example as a network traffic matrix.
   188 
   189 In our example there is a network with symmetric links and there are assymetric
   190 traffic request on the network. This construction can be stored in an
   191 undirected graph and in a directed \c ListEdgeSet class. The example
   192 shows the input with the \ref lemon::LemonReader "LemonReader" class:
   193 
   194 \code
   195 ListUGraph network;
   196 ListUGraph::UEdgeMap<double> capacity;
   197 ListEdgeSet<ListUGraph> traffic(network);
   198 ListEdgeSet<ListUGraph>::EdgeMap<double> request(network);
   199 
   200 LemonReader reader(std::cin);
   201 NodeSetReader<ListUGraph> nodesetReader(reader, network);
   202 UEdgeSetReader<ListUGraph> 
   203   uEdgesetReader(reader, network, nodesetReader);
   204 uEdgesetReader.readEdgeMap("capacity", capacity);
   205 EdgeSetReader<ListEdgeSet<ListUGraph> > 
   206   edgesetReader(reader, traffic, nodesetReader, "traffic");
   207 edgesetReader.readEdgeMap("request", request);
   208 
   209 reader.run();
   210 \endcode
   211 
   212 Because both the \ref lemon::GraphReader "GraphReader"
   213 and the \ref lemon::UGraphReader "UGraphReader" can be converted
   214 to \ref lemon::LemonReader "LemonReader"
   215 and it can resolve the label's of the items, the previous
   216 result can be achived with the \ref lemon::UGraphReader "UGraphReader"
   217 class, too.
   218 
   219 
   220 \code
   221 ListUGraph network;
   222 ListUGraph::UEdgeSet<double> capacity;
   223 ListEdgeSet<ListUGraph> traffic(network);
   224 ListEdgeSet<ListUGraph>::EdgeMap<double> request(network);
   225 
   226 UGraphReader<ListUGraph> reader(std::cin, network);
   227 reader.readEdgeMap("capacity", capacity);
   228 EdgeSetReader<ListEdgeSet<ListUGraph> > 
   229   edgesetReader(reader, traffic, reader, "traffic");
   230 edgesetReader.readEdgeMap("request", request);
   231 
   232 reader.run();
   233 \endcode
   234 
   235 \author Balazs Dezso
   236 */
   237 }