Some more test cases.
3 \page maps How to write your own maps
5 \section read-maps Readable Maps
7 The readable maps are very frequently used as the input of the
8 algorithms. For this purpose the most straightforward is to use the
9 maps provided by Hugo's graph structres. Very often however, it is more
10 convenient and/or more efficient to write your own readable map.
12 You can find some example below.
14 This simple map assigns \f$\pi\f$ to each edge.
19 typedef double ValueType;
20 double operator[](Graph::Edge e) const { return M_PI;}
24 An alternative way to define maps. For this, \c MapBase seems to
25 be a better name then \c NullMap
28 struct MyMap : public MapBase<Edge,double>
30 double operator[](Graph::Edge e) const { return M_PI;}
34 Or, if we had \c KeyType and \c ValueType
37 struct MyMap : public MapBase<Edge,double>
39 ValueType operator[](KeyType e) const { return M_PI;}
44 Here is a more complex example. It provides a length function which is obtained
45 from a base length function modified by a potential difference.
50 const Graph::EdgeMap &ol;
51 const Graph::NodeMap &pot;
54 typedef double ValueType;
56 double operator[](Graph::Edge e) const {
57 return ol.get(e)-pot.get(v)-pot.get(u);
60 MyComplexMap(const Graph::EdgeMap &o,const Graph::NodeMap &p) :
65 \todo Please improve on the english.
66 \todo Don't we need \e to \e require a 'typedef xxx KeyType' tag, as well?