doc/graph_io.dox
author deba
Thu, 11 Aug 2005 15:55:17 +0000
changeset 1627 3fd1ba6e9872
parent 1532 aa7428d22aaf
child 1631 e15162d8eca1
permissions -rw-r--r--
Some modification on the undirected graph interface.
Doc improvments
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namespace lemon {
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/*!
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\page graph-io-page Graph Input-Output
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The standard graph IO enables one to store graphs and additional maps
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(i.e. functions on the nodes or edges) in a flexible and efficient way. 
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Before you read this page you should be familiar with LEMON 
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\ref graphs "graphs" and \ref maps-page "maps".
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\section format The general file format
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The file contains sections in the following order:
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\li nodeset
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\li edgeset
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\li nodes
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\li edges
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\li attributes
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Some of these sections can be omitted, but you will basicly need the nodeset
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section (unless your graph has no nodes at all) and the edgeset section
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(unless your graph has no edges at all). 
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The nodeset section describes the nodes of your graph: it identifies the nodes
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and gives the maps defined on them, if any. It starts with the
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following line:
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<tt>\@nodeset</tt>
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The next line contains the names of the nodemaps, separated by whitespaces.  Each
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following line describes a node in the graph: it contains the values of the
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maps in the right order. The map named "id" should contain unique values
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because it is regarded as an ID-map. These ids need not be numbers but they
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must identify the nodes uniquely for later reference. For example:
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\code
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@nodeset
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id  x-coord  y-coord  color
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3   1.0      4.0      blue
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5   2.3      5.7      red
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12  7.8      2.3      green
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\endcode
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The edgeset section is very similar to the nodeset section, it has
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the same coloumn oriented structure. It starts with the line 
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<tt>\@edgeset</tt>
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The next line contains the whitespace separated list of names of the edge
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maps.  Each of the next lines describes one edge. The first two elements in
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the line are the IDs of the source and target (or tail and head) nodes of the
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edge as they occur in the ID node map of the nodeset section. You can also
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have an optional ID map on the edges for later reference (which has to be
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unique in this case).
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\code
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@edgeset
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             id    weight   label
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3   5        a     4.3      a-edge
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5   12       c     2.6      c-edge
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3   12       g     3.4      g-edge
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\endcode
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The \e nodes section contains <em>labeled (distinguished) nodes</em> 
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(i.e. nodes having a special
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label on them). The section starts with
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<tt> \@nodes </tt>
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Each of the next lines contains a label for a node in the graph 
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and then the ID as described in the \e nodeset section.
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\code
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@nodes 
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source 3
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target 12
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\endcode
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The last section describes the <em>labeled (distinguished) edges</em>
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(i.e. edges having a special label on them). It starts with \c \@edges
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and then each line contains the name of the edge and the ID.
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\code
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@edges 
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observed c
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\endcode
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The file may contain empty lines and comment lines. The comment lines
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start with an \c # character.
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The attributes section can handle some information about the graph. It
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contains key-value pairs in each line (a key and the mapped value to key). The
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key should be a string without whitespaces, the value can be of various types.
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\code
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@attributes
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title "Four colored plan graph"
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author "Balazs DEZSO"
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copyright "Lemon Library"
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version 12
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\endcode
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<tt> \@end </tt>
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line.
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\section use Using graph input-output
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The easiest way of using graph input and output is using the versions of the
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  public \ref readGraph() and \ref writeGraph() functions; if you don't need
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  very sophisticated behaviour then you might be satisfied with
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  those. Otherwise go on reading this page.
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The graph input and output is based on <em> reading and writing
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commands</em>. The user gives reading and writing commands to the reader or
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writer class, then he calls the \c run() method that executes all the given
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commands.
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\subsection write Writing a graph
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The \c GraphWriter class provides the graph output. To write a graph
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you should first give writing commands to the writer. You can declare
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writing command as \c NodeMap or \c EdgeMap writing and labeled Node and
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Edge writing.
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\code
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GraphWriter<ListGraph> writer(std::cout, graph);
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\endcode
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The \c writeNodeMap() function declares a \c NodeMap writing command in the
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\c GraphWriter. You should give a name to the map and the map
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object as parameters. The NodeMap writing command with name "id" should write a 
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unique map because it will be regarded as an ID map.
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\see IdMap, DescriptorMap  
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\code
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IdMap<ListGraph, Node> nodeIdMap;
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writer.writeNodeMap("id", nodeIdMap);
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writer.writeNodeMap("x-coord", xCoordMap);
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writer.writeNodeMap("y-coord", yCoordMap);
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writer.writeNodeMap("color", colorMap);
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\endcode
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With the \c writeEdgeMap() member function you can give an edge map
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writing command similar to the NodeMaps.
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\see IdMap, DescriptorMap  
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\code
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DescriptorMap<ListGraph, Edge, ListGraph::EdgeMap<int> > edgeDescMap(graph);
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writer.writeEdgeMap("descriptor", edgeDescMap);
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writer.writeEdgeMap("weight", weightMap);
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writer.writeEdgeMap("label", labelMap);
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\endcode
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With \c writeNode() and \c writeEdge() functions you can designate Nodes and
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Edges in the graph. For example, you can write out the source and target node
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of a maximum flow instance.
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\code
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writer.writeNode("source", sourceNode);
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writer.writeNode("target", targetNode);
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writer.writeEdge("observed", edge);
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\endcode
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With \c writeAttribute() function you can write an attribute to the file.
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\code
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writer.writeAttribute("author", "Balazs DEZSO");
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writer.writeAttribute("version", 12);
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\endcode
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After you give all write commands you must call the \c run() member
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function, which executes all the writing commands.
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\code
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writer.run();
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\endcode
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\subsection reading Reading a graph
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The file to be read may contain several maps and labeled nodes or edges.
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If you read a graph you need not read all the maps and items just those
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that you need. The interface of the \c GraphReader is very similar to
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the GraphWriter but the reading method does not depend on the order of the
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given commands.
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The reader object assumes that each not readed value does not contain 
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whitespaces, therefore it has some extra possibilities to control how
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it should skip the values when the string representation contains spaces.
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\code
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GraphReader<ListGraph> reader(std::cin, graph);
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\endcode
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The \c readNodeMap() function reads a map from the \c nodeset section.
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If there is a map that you do not want to read from the file and there are
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whitespaces in the string represenation of the values then you should
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call the \c skipNodeMap() template member function with proper parameters.
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\see QuotedStringReader
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\code
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reader.readNodeMap("x-coord", xCoordMap);
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reader.readNodeMap("y-coord", yCoordMap);
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reader.readNodeMap<QuotedStringReader>("label", labelMap);
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reader.skipNodeMap<QuotedStringReader>("description");
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reader.readNodeMap("color", colorMap);
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\endcode
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With the \c readEdgeMap() member function you can give an edge map
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reading command similar to the NodeMaps. 
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\code
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reader.readEdgeMap("weight", weightMap);
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reader.readEdgeMap("label", labelMap);
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\endcode
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With \c readNode() and \c readEdge() functions you can read labeled Nodes and
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Edges.
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\code
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reader.readNode("source", sourceNode);
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reader.readNode("target", targetNode);
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reader.readEdge("observed", edge);
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\endcode
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With \c readAttribute() function you can read an attribute from the file.
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\code
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std::string author;
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writer.readAttribute("author", author);
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int version;
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writer.writeAttribute("version", version);
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\endcode
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After you give all read commands you must call the \c run() member
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function, which executes all the commands.
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\code
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reader.run();
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\endcode
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\anchor rwbackground
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\section types Background of Reading and Writing
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To read a map (on the nodes or edges)
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the \c GraphReader should know how to read a Value from the given map.
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By the default implementation the input operator reads a value from
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the stream and the type of the readed value is the value type of the given map.
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When the reader should skip a value in the stream, because you do not
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want to store it in a map, the reader skips a character sequence without 
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whitespaces. 
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If you want to change the functionality of the reader, you can use
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template parameters to specialize it. When you give a reading
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command for a map you can give a Reader type as template parameter.
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With this template parameter you can control how the Reader reads
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a value from the stream.
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The reader has the next structure: 
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\code
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struct TypeReader {
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  typedef TypeName Value;
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  void read(std::istream& is, Value& value);
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};
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\endcode
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For example, the \c "strings" nodemap contains strings and you do not need
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the value of the string just the length. Then you can implement an own Reader
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struct.
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\code
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struct LengthReader {
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  typedef int Value;
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  void read(std::istream& is, Value& value) {
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    std::string tmp;
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    is >> tmp;
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    value = tmp.length();
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  }
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};
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...
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reader.readNodeMap<LengthReader>("strings", lengthMap);
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\endcode  
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The global functionality of the reader class can be changed by giving a
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special template parameter to the GraphReader class. By default, the
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template parameter is \c DefaultReaderTraits. A reader traits class 
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should provide an inner template class Reader for each type, and a 
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DefaultReader for skipping a value.
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The specialization of  writing is very similar to that of reading.
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\section undir Undirected graphs
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In a file describing an undirected graph (undir graph, for short) you find an
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\c undiredgeset section instead of the \c edgeset section. The first line of
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the section describes the names of the maps on the undirected egdes and all
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next lines describe one undirected edge with the the incident nodes and the
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values of the map.
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The format handles directed edge maps as a syntactical sugar???, if there
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are two maps with names being the same with a \c '+' and a \c '-' prefix
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then this will be read as a directed map.
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\code
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@undiredgeset
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             id    capacity +flow -flow
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32   2       1     4.3      2.0	  0.0
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21   21      5     2.6      0.0   2.6
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21   12      8     3.4      0.0   0.0
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\endcode
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The \c edges section is changed to \c undiredges section. This section
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describes labeled edges and undirected edges. The directed edge label
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should start with a \c '+' or a \c '-' prefix to decide the direction
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of the edge. 
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\code
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@undiredges
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undiredge 1
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+edge 5
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-back 5
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\endcode
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There are similar classes to the \c GraphReader ans \c GraphWriter
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which handle the undirected graphs. These classes are the 
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\c UndirGraphReader and \UndirGraphWriter.
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The \c readUndirMap() function reads an undirected map and the
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\c readUndirEdge() reads an undirected edge from the file, 
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\code
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reader.readUndirEdgeMap("capacity", capacityMap);
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reader.readEdgeMap("flow", flowMap);
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...
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reader.readUndirEdge("undir_edge", undir_edge);
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reader.readEdge("edge", edge);
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\endcode
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\section advanced Advanced features
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The graph reader and writer classes give an easy way to read and write
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graphs. But sometimes we want more advanced features. In this case we can
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use the more general <tt>lemon reader and writer</tt> interface.
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The LEMON file format is a section oriented file format. It contains one or
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more sections, each starting with a line identifying its type 
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(the word starting with the \c \@  character).
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The content of the section this way cannot contain line with \c \@ first
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character. The file may contains comment lines with \c # first character.
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The \c LemonReader and \c LemonWriter gives a framework to read and
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write sections. There are various section reader and section writer
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classes which can be attached to a \c LemonReader or a \c LemonWriter.
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There are default section readers and writers for reading and writing
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item sets, and labeled items in the graph. These read and write
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the format described above. Other type of data can be handled with own
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section reader and writer classes which are inherited from the
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\c LemonReader::SectionReader or the \c LemonWriter::SectionWriter classes.
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The next example defines a special section reader which reads the
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\c \@description sections into a string:
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\code 
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class DescriptionReader : LemonReader::SectionReader {
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protected:
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  virtual bool header(const std::string& line) {
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    std::istringstream ls(line);
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    std::string head;
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    ls >> head;
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    return head == "@description";
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  }
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  virtual void read(std::istream& is) {
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    std::string line;
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    while (getline(is, line)) {
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      desc += line;
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    }
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  }
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public:
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  typedef LemonReader::SectionReader Parent;
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  DescriptionReader(LemonReader& reader) : Parent(reader) {}
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  const std::string& description() const {
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    return description;
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  }
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private:
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  std::string desc;
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};
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\endcode
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The other advanced stuff of the generalized file format is that 
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multiple edgesets can be stored to the same nodeset. It can be used 
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for example as a network traffic matrix.
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In our example there is a network with symmetric links and there are assymetric
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traffic request on the network. This construction can be stored in an
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undirected graph and in a directed NewEdgeSetAdaptor class. The example
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shows the input with the LemonReader class:
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\code
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UndirListGraph network;
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UndirListGraph::UndirEdgeSet<double> capacity;
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NewEdgeSetAdaptor<UndirListGraph> traffic(network);
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NewEdgeSetAdaptor<UndirListGraph>::EdgeSet<double> request(network);
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LemonReader reader(std::cin);
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NodeSetReader nodesetReader(reader, network);
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UndirEdgeSetReader undirEdgesetReader(reader, network, nodesetReader);
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undirEdgesetReader.readEdgeMap("capacity", capacity);
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EdgeSetReader edgesetReader(reader, traffic, nodesetReader);
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edgesetReader.readEdgeMap("request", request);
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reader.run();
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\endcode
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Because the GraphReader and the UndirGraphReader can be converted
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to LemonReader and it can resolve the ID's of the items, the previous
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result can be achived with the UndirGraphReader class, too.
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\code
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UndirListGraph network;
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UndirListGraph::UndirEdgeSet<double> capacity;
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NewEdgeSetAdaptor<UndirListGraph> traffic(network);
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NewEdgeSetAdaptor<UndirListGraph>::EdgeSet<double> request(network);
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UndirGraphReader reader(std::cin, network);
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reader.readEdgeMap("capacity", capacity);
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EdgeSetReader edgesetReader(reader, traffic, reader);
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edgesetReader.readEdgeMap("request", request);
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reader.run();
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\endcode
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\author Balazs Dezso
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*/
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}