alpar@906
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/* -*- C++ -*-
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alpar@921
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* src/lemon/path.h - Part of LEMON, a generic C++ optimization library
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alpar@906
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*
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alpar@906
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* Copyright (C) 2004 Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
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* (Egervary Combinatorial Optimization Research Group, EGRES).
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*
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* Permission to use, modify and distribute this software is granted
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* provided that this copyright notice appears in all copies. For
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* precise terms see the accompanying LICENSE file.
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alpar@906
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*
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alpar@906
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* This software is provided "AS IS" with no warranty of any kind,
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* express or implied, and with no claim as to its suitability for any
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* purpose.
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*
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*/
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/**
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@defgroup paths Path Structures
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@ingroup datas
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\brief Path structures implemented in LEMON.
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LEMON provides flexible data structures
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to work with paths.
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All of them have the same interface, especially they can be built or extended
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using a standard Builder subclass. This make is easy to have e.g. the Dijkstra
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algorithm to store its result in any kind of path structure.
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\sa lemon::concept::Path
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*/
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///\ingroup paths
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///\file
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///\brief Classes for representing paths in graphs.
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#ifndef LEMON_PATH_H
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#define LEMON_PATH_H
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#include <deque>
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#include <vector>
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#include <algorithm>
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#include <lemon/invalid.h>
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namespace lemon {
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/// \addtogroup paths
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/// @{
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//! \brief A structure for representing directed paths in a graph.
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//!
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//! A structure for representing directed path in a graph.
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//! \param Graph The graph type in which the path is.
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//! \param DM DebugMode, defaults to DefaultDebugMode.
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//!
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//! In a sense, the path can be treated as a graph, for is has \c NodeIt
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//! and \c EdgeIt with the same usage. These types converts to the \c Node
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//! and \c Edge of the original graph.
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//!
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//! \todo Thoroughfully check all the range and consistency tests.
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template<typename Graph>
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class DirPath {
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public:
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/// Edge type of the underlying graph.
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typedef typename Graph::Edge GraphEdge;
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/// Node type of the underlying graph.
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typedef typename Graph::Node GraphNode;
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class NodeIt;
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class EdgeIt;
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protected:
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const Graph *gr;
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typedef std::vector<GraphEdge> Container;
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Container edges;
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public:
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/// \param _G The graph in which the path is.
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///
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DirPath(const Graph &_G) : gr(&_G) {}
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/// \brief Subpath constructor.
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///
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/// Subpath defined by two nodes.
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/// \warning It is an error if the two edges are not in order!
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DirPath(const DirPath &P, const NodeIt &a, const NodeIt &b) {
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gr = P.gr;
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edges.insert(edges.end(), P.edges.begin()+a.idx, P.edges.begin()+b.idx);
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}
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/// \brief Subpath constructor.
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///
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/// Subpath defined by two edges. Contains edges in [a,b)
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/// \warning It is an error if the two edges are not in order!
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DirPath(const DirPath &P, const EdgeIt &a, const EdgeIt &b) {
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gr = P.gr;
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edges.insert(edges.end(), P.edges.begin()+a.idx, P.edges.begin()+b.idx);
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}
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/// Length of the path.
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size_t length() const { return edges.size(); }
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/// Returns whether the path is empty.
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bool empty() const { return edges.empty(); }
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/// Resets the path to an empty path.
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void clear() { edges.clear(); }
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/// \brief Starting point of the path.
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///
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/// Starting point of the path.
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/// Returns INVALID if the path is empty.
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GraphNode tail() const {
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return empty() ? INVALID : gr->tail(edges[0]);
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}
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/// \brief End point of the path.
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///
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/// End point of the path.
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/// Returns INVALID if the path is empty.
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GraphNode head() const {
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return empty() ? INVALID : gr->head(edges[length()-1]);
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}
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/// \brief Initializes node or edge iterator to point to the first
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/// node or edge.
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///
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/// \sa nth
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template<typename It>
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It& first(It &i) const { return i=It(*this); }
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/// \brief Initializes node iterator to point to the node of a given index.
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NodeIt& nth(NodeIt &i, int n) const {
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return i=NodeIt(*this, n);
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}
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/// \brief Initializes edge iterator to point to the edge of a given index.
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EdgeIt& nth(EdgeIt &i, int n) const {
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return i=EdgeIt(*this, n);
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}
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/// \brief Returns node iterator pointing to the head node of the
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/// given edge iterator.
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NodeIt head(const EdgeIt& e) const {
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return NodeIt(*this, e.idx+1);
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}
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/// \brief Returns node iterator pointing to the tail node of the
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/// given edge iterator.
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NodeIt tail(const EdgeIt& e) const {
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return NodeIt(*this, e.idx);
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}
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/* Iterator classes */
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/**
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* \brief Iterator class to iterate on the edges of the paths
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*
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* \ingroup paths
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* This class is used to iterate on the edges of the paths
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*
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* Of course it converts to Graph::Edge
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*
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*/
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class EdgeIt {
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friend class DirPath;
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int idx;
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const DirPath *p;
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public:
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/// Default constructor
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EdgeIt() {}
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/// Invalid constructor
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EdgeIt(Invalid) : idx(-1), p(0) {}
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/// Constructor with starting point
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EdgeIt(const DirPath &_p, int _idx = 0) :
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idx(_idx), p(&_p) { validate(); }
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///Validity check
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bool valid() const { return idx!=-1; }
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///Conversion to Graph::Edge
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operator GraphEdge () const {
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return valid() ? p->edges[idx] : INVALID;
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}
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/// Next edge
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EdgeIt& operator++() { ++idx; validate(); return *this; }
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/// Comparison operator
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bool operator==(const EdgeIt& e) const { return idx==e.idx; }
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/// Comparison operator
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bool operator!=(const EdgeIt& e) const { return idx!=e.idx; }
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/// Comparison operator
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bool operator<(const EdgeIt& e) const { return idx<e.idx; }
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private:
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// FIXME: comparison between signed and unsigned...
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// Jo ez igy? Vagy esetleg legyen a length() int?
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void validate() { if( size_t(idx) >= p->length() ) idx=-1; }
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};
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/**
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* \brief Iterator class to iterate on the nodes of the paths
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*
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* \ingroup paths
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* This class is used to iterate on the nodes of the paths
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*
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* Of course it converts to Graph::Node
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*
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*/
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class NodeIt {
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friend class DirPath;
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int idx;
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const DirPath *p;
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public:
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/// Default constructor
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NodeIt() {}
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/// Invalid constructor
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NodeIt(Invalid) : idx(-1), p(0) {}
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/// Constructor with starting point
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NodeIt(const DirPath &_p, int _idx = 0) :
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idx(_idx), p(&_p) { validate(); }
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///Validity check
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bool valid() const { return idx!=-1; }
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///Conversion to Graph::Node
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operator const GraphNode& () const {
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if(idx >= p->length())
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return p->head();
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else if(idx >= 0)
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return p->gr->tail(p->edges[idx]);
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else
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return INVALID;
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}
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/// Next node
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NodeIt& operator++() { ++idx; validate(); return *this; }
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/// Comparison operator
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bool operator==(const NodeIt& e) const { return idx==e.idx; }
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/// Comparison operator
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bool operator!=(const NodeIt& e) const { return idx!=e.idx; }
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/// Comparison operator
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bool operator<(const NodeIt& e) const { return idx<e.idx; }
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private:
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void validate() { if( size_t(idx) > p->length() ) idx=-1; }
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};
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friend class Builder;
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/**
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* \brief Class to build paths
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*
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* \ingroup paths
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* This class is used to fill a path with edges.
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*
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* You can push new edges to the front and to the back of the path in
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* arbitrary order then you should commit these changes to the graph.
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*
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* Fundamentally, for most "Paths" (classes fulfilling the
|
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* PathConcept) while the builder is active (after the first modifying
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* operation and until the commit()) the original Path is in a
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* "transitional" state (operations on it have undefined result). But
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* in the case of DirPath the original path remains unchanged until the
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* commit. However we don't recomend that you use this feature.
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*/
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class Builder {
|
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DirPath &P;
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Container front, back;
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public:
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///\param _P the path you want to fill in.
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///
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Builder(DirPath &_P) : P(_P) {}
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/// Sets the starting node of the path.
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/// Sets the starting node of the path. Edge added to the path
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/// afterwards have to be incident to this node.
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/// It should be called if and only if
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/// the path is empty and before any call to
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/// \ref pushFront() or \ref pushBack()
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void setStartNode(const GraphNode &) {}
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///Push a new edge to the front of the path
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///Push a new edge to the front of the path.
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///\sa setStartNode
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void pushFront(const GraphEdge& e) {
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front.push_back(e);
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}
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///Push a new edge to the back of the path
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///Push a new edge to the back of the path.
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///\sa setStartNode
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void pushBack(const GraphEdge& e) {
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back.push_back(e);
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}
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///Commit the changes to the path.
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void commit() {
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if( !front.empty() || !back.empty() ) {
|
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308 |
Container tmp;
|
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309 |
tmp.reserve(front.size()+back.size()+P.length());
|
hegyi@819
|
310 |
tmp.insert(tmp.end(), front.rbegin(), front.rend());
|
hegyi@819
|
311 |
tmp.insert(tmp.end(), P.edges.begin(), P.edges.end());
|
hegyi@819
|
312 |
tmp.insert(tmp.end(), back.begin(), back.end());
|
hegyi@819
|
313 |
P.edges.swap(tmp);
|
hegyi@819
|
314 |
front.clear();
|
hegyi@819
|
315 |
back.clear();
|
hegyi@819
|
316 |
}
|
hegyi@819
|
317 |
}
|
hegyi@819
|
318 |
|
hegyi@819
|
319 |
///Reserve storage for the builder in advance.
|
hegyi@819
|
320 |
|
hegyi@837
|
321 |
///If you know a reasonable upper bound of the number of the edges
|
hegyi@837
|
322 |
///to add to the front, using this function you can speed up the building.
|
hegyi@819
|
323 |
|
hegyi@837
|
324 |
void reserveFront(size_t r) {front.reserve(r);}
|
hegyi@837
|
325 |
|
hegyi@837
|
326 |
///Reserve storage for the builder in advance.
|
hegyi@837
|
327 |
|
hegyi@837
|
328 |
///If you know a reasonable upper bound of the number of the edges
|
hegyi@837
|
329 |
///to add to the back, using this function you can speed up the building.
|
hegyi@837
|
330 |
|
hegyi@837
|
331 |
void reserveBack(size_t r) {back.reserve(r);}
|
hegyi@831
|
332 |
|
hegyi@819
|
333 |
private:
|
hegyi@819
|
334 |
bool empty() {
|
hegyi@819
|
335 |
return front.empty() && back.empty() && P.empty();
|
hegyi@819
|
336 |
}
|
hegyi@819
|
337 |
|
hegyi@831
|
338 |
GraphNode tail() const {
|
hegyi@819
|
339 |
if( ! front.empty() )
|
hegyi@819
|
340 |
return P.gr->tail(front[front.size()-1]);
|
hegyi@819
|
341 |
else if( ! P.empty() )
|
hegyi@819
|
342 |
return P.gr->tail(P.edges[0]);
|
hegyi@819
|
343 |
else if( ! back.empty() )
|
hegyi@819
|
344 |
return P.gr->tail(back[0]);
|
hegyi@819
|
345 |
else
|
hegyi@819
|
346 |
return INVALID;
|
hegyi@819
|
347 |
}
|
hegyi@831
|
348 |
GraphNode head() const {
|
hegyi@819
|
349 |
if( ! back.empty() )
|
hegyi@819
|
350 |
return P.gr->head(back[back.size()-1]);
|
hegyi@819
|
351 |
else if( ! P.empty() )
|
hegyi@819
|
352 |
return P.gr->head(P.edges[P.length()-1]);
|
hegyi@819
|
353 |
else if( ! front.empty() )
|
hegyi@819
|
354 |
return P.gr->head(front[0]);
|
hegyi@819
|
355 |
else
|
hegyi@819
|
356 |
return INVALID;
|
hegyi@819
|
357 |
}
|
hegyi@819
|
358 |
|
hegyi@819
|
359 |
};
|
hegyi@819
|
360 |
|
hegyi@819
|
361 |
};
|
hegyi@819
|
362 |
|
hegyi@819
|
363 |
|
hegyi@819
|
364 |
|
hegyi@819
|
365 |
|
hegyi@819
|
366 |
|
hegyi@819
|
367 |
|
hegyi@819
|
368 |
|
hegyi@819
|
369 |
|
hegyi@819
|
370 |
|
hegyi@819
|
371 |
|
hegyi@819
|
372 |
/**********************************************************************/
|
hegyi@819
|
373 |
|
hegyi@819
|
374 |
|
hegyi@819
|
375 |
//! \brief A structure for representing undirected path in a graph.
|
hegyi@819
|
376 |
//!
|
hegyi@819
|
377 |
//! A structure for representing undirected path in a graph. Ie. this is
|
hegyi@819
|
378 |
//! a path in a \e directed graph but the edges should not be directed
|
hegyi@819
|
379 |
//! forward.
|
hegyi@819
|
380 |
//!
|
hegyi@819
|
381 |
//! \param Graph The graph type in which the path is.
|
hegyi@819
|
382 |
//! \param DM DebugMode, defaults to DefaultDebugMode.
|
hegyi@837
|
383 |
//!
|
hegyi@819
|
384 |
//! In a sense, the path can be treated as a graph, for is has \c NodeIt
|
hegyi@819
|
385 |
//! and \c EdgeIt with the same usage. These types converts to the \c Node
|
hegyi@819
|
386 |
//! and \c Edge of the original graph.
|
hegyi@819
|
387 |
//!
|
hegyi@819
|
388 |
//! \todo Thoroughfully check all the range and consistency tests.
|
hegyi@831
|
389 |
template<typename Graph>
|
hegyi@819
|
390 |
class UndirPath {
|
hegyi@819
|
391 |
public:
|
hegyi@819
|
392 |
/// Edge type of the underlying graph.
|
hegyi@819
|
393 |
typedef typename Graph::Edge GraphEdge;
|
hegyi@819
|
394 |
/// Node type of the underlying graph.
|
hegyi@819
|
395 |
typedef typename Graph::Node GraphNode;
|
hegyi@819
|
396 |
class NodeIt;
|
hegyi@819
|
397 |
class EdgeIt;
|
hegyi@819
|
398 |
|
hegyi@819
|
399 |
protected:
|
hegyi@819
|
400 |
const Graph *gr;
|
hegyi@819
|
401 |
typedef std::vector<GraphEdge> Container;
|
hegyi@819
|
402 |
Container edges;
|
hegyi@819
|
403 |
|
hegyi@819
|
404 |
public:
|
hegyi@819
|
405 |
|
hegyi@819
|
406 |
/// \param _G The graph in which the path is.
|
hegyi@819
|
407 |
///
|
hegyi@819
|
408 |
UndirPath(const Graph &_G) : gr(&_G) {}
|
hegyi@819
|
409 |
|
hegyi@819
|
410 |
/// \brief Subpath constructor.
|
hegyi@819
|
411 |
///
|
hegyi@819
|
412 |
/// Subpath defined by two nodes.
|
hegyi@819
|
413 |
/// \warning It is an error if the two edges are not in order!
|
hegyi@819
|
414 |
UndirPath(const UndirPath &P, const NodeIt &a, const NodeIt &b) {
|
hegyi@819
|
415 |
gr = P.gr;
|
hegyi@819
|
416 |
edges.insert(edges.end(), P.edges.begin()+a.idx, P.edges.begin()+b.idx);
|
hegyi@819
|
417 |
}
|
hegyi@819
|
418 |
|
hegyi@819
|
419 |
/// \brief Subpath constructor.
|
hegyi@819
|
420 |
///
|
hegyi@819
|
421 |
/// Subpath defined by two edges. Contains edges in [a,b)
|
hegyi@819
|
422 |
/// \warning It is an error if the two edges are not in order!
|
hegyi@819
|
423 |
UndirPath(const UndirPath &P, const EdgeIt &a, const EdgeIt &b) {
|
hegyi@819
|
424 |
gr = P.gr;
|
hegyi@819
|
425 |
edges.insert(edges.end(), P.edges.begin()+a.idx, P.edges.begin()+b.idx);
|
hegyi@819
|
426 |
}
|
hegyi@819
|
427 |
|
hegyi@819
|
428 |
/// Length of the path.
|
hegyi@819
|
429 |
size_t length() const { return edges.size(); }
|
hegyi@819
|
430 |
/// Returns whether the path is empty.
|
hegyi@819
|
431 |
bool empty() const { return edges.empty(); }
|
hegyi@819
|
432 |
|
hegyi@819
|
433 |
/// Resets the path to an empty path.
|
hegyi@819
|
434 |
void clear() { edges.clear(); }
|
hegyi@819
|
435 |
|
hegyi@819
|
436 |
/// \brief Starting point of the path.
|
hegyi@819
|
437 |
///
|
hegyi@819
|
438 |
/// Starting point of the path.
|
hegyi@819
|
439 |
/// Returns INVALID if the path is empty.
|
hegyi@831
|
440 |
GraphNode tail() const {
|
hegyi@819
|
441 |
return empty() ? INVALID : gr->tail(edges[0]);
|
hegyi@819
|
442 |
}
|
hegyi@819
|
443 |
/// \brief End point of the path.
|
hegyi@819
|
444 |
///
|
hegyi@819
|
445 |
/// End point of the path.
|
hegyi@819
|
446 |
/// Returns INVALID if the path is empty.
|
hegyi@831
|
447 |
GraphNode head() const {
|
hegyi@819
|
448 |
return empty() ? INVALID : gr->head(edges[length()-1]);
|
hegyi@819
|
449 |
}
|
hegyi@819
|
450 |
|
hegyi@819
|
451 |
/// \brief Initializes node or edge iterator to point to the first
|
hegyi@819
|
452 |
/// node or edge.
|
hegyi@819
|
453 |
///
|
hegyi@819
|
454 |
/// \sa nth
|
hegyi@819
|
455 |
template<typename It>
|
hegyi@819
|
456 |
It& first(It &i) const { return i=It(*this); }
|
hegyi@819
|
457 |
|
hegyi@819
|
458 |
/// \brief Initializes node iterator to point to the node of a given index.
|
hegyi@819
|
459 |
NodeIt& nth(NodeIt &i, int n) const {
|
hegyi@819
|
460 |
return i=NodeIt(*this, n);
|
hegyi@819
|
461 |
}
|
hegyi@819
|
462 |
|
hegyi@819
|
463 |
/// \brief Initializes edge iterator to point to the edge of a given index.
|
hegyi@819
|
464 |
EdgeIt& nth(EdgeIt &i, int n) const {
|
hegyi@819
|
465 |
return i=EdgeIt(*this, n);
|
hegyi@819
|
466 |
}
|
hegyi@819
|
467 |
|
hegyi@819
|
468 |
/// Checks validity of a node or edge iterator.
|
hegyi@819
|
469 |
template<typename It>
|
hegyi@819
|
470 |
static
|
hegyi@819
|
471 |
bool valid(const It &i) { return i.valid(); }
|
hegyi@819
|
472 |
|
hegyi@819
|
473 |
/// Steps the given node or edge iterator.
|
hegyi@819
|
474 |
template<typename It>
|
hegyi@819
|
475 |
static
|
hegyi@819
|
476 |
It& next(It &e) {
|
hegyi@819
|
477 |
return ++e;
|
hegyi@819
|
478 |
}
|
hegyi@819
|
479 |
|
hegyi@819
|
480 |
/// \brief Returns node iterator pointing to the head node of the
|
hegyi@819
|
481 |
/// given edge iterator.
|
hegyi@819
|
482 |
NodeIt head(const EdgeIt& e) const {
|
hegyi@819
|
483 |
return NodeIt(*this, e.idx+1);
|
hegyi@819
|
484 |
}
|
hegyi@819
|
485 |
|
hegyi@819
|
486 |
/// \brief Returns node iterator pointing to the tail node of the
|
hegyi@819
|
487 |
/// given edge iterator.
|
hegyi@819
|
488 |
NodeIt tail(const EdgeIt& e) const {
|
hegyi@819
|
489 |
return NodeIt(*this, e.idx);
|
hegyi@819
|
490 |
}
|
hegyi@819
|
491 |
|
hegyi@819
|
492 |
|
hegyi@819
|
493 |
|
hegyi@819
|
494 |
/**
|
hegyi@819
|
495 |
* \brief Iterator class to iterate on the edges of the paths
|
hegyi@837
|
496 |
*
|
hegyi@819
|
497 |
* \ingroup paths
|
hegyi@819
|
498 |
* This class is used to iterate on the edges of the paths
|
hegyi@819
|
499 |
*
|
hegyi@819
|
500 |
* Of course it converts to Graph::Edge
|
hegyi@837
|
501 |
*
|
hegyi@819
|
502 |
* \todo Its interface differs from the standard edge iterator.
|
hegyi@819
|
503 |
* Yes, it shouldn't.
|
hegyi@819
|
504 |
*/
|
hegyi@819
|
505 |
class EdgeIt {
|
hegyi@819
|
506 |
friend class UndirPath;
|
hegyi@819
|
507 |
|
hegyi@819
|
508 |
int idx;
|
hegyi@819
|
509 |
const UndirPath *p;
|
hegyi@819
|
510 |
public:
|
hegyi@819
|
511 |
/// Default constructor
|
hegyi@819
|
512 |
EdgeIt() {}
|
hegyi@819
|
513 |
/// Invalid constructor
|
hegyi@819
|
514 |
EdgeIt(Invalid) : idx(-1), p(0) {}
|
hegyi@819
|
515 |
/// Constructor with starting point
|
hegyi@819
|
516 |
EdgeIt(const UndirPath &_p, int _idx = 0) :
|
hegyi@819
|
517 |
idx(_idx), p(&_p) { validate(); }
|
hegyi@819
|
518 |
|
hegyi@819
|
519 |
///Validity check
|
hegyi@819
|
520 |
bool valid() const { return idx!=-1; }
|
hegyi@819
|
521 |
|
hegyi@819
|
522 |
///Conversion to Graph::Edge
|
hegyi@819
|
523 |
operator GraphEdge () const {
|
hegyi@819
|
524 |
return valid() ? p->edges[idx] : INVALID;
|
hegyi@819
|
525 |
}
|
hegyi@819
|
526 |
/// Next edge
|
hegyi@819
|
527 |
EdgeIt& operator++() { ++idx; validate(); return *this; }
|
hegyi@819
|
528 |
|
hegyi@819
|
529 |
/// Comparison operator
|
hegyi@819
|
530 |
bool operator==(const EdgeIt& e) const { return idx==e.idx; }
|
hegyi@819
|
531 |
/// Comparison operator
|
hegyi@819
|
532 |
bool operator!=(const EdgeIt& e) const { return idx!=e.idx; }
|
hegyi@819
|
533 |
/// Comparison operator
|
hegyi@819
|
534 |
bool operator<(const EdgeIt& e) const { return idx<e.idx; }
|
hegyi@819
|
535 |
|
hegyi@819
|
536 |
private:
|
hegyi@819
|
537 |
// FIXME: comparison between signed and unsigned...
|
hegyi@819
|
538 |
// Jo ez igy? Vagy esetleg legyen a length() int?
|
hegyi@819
|
539 |
void validate() { if( size_t(idx) >= p->length() ) idx=-1; }
|
hegyi@819
|
540 |
};
|
hegyi@819
|
541 |
|
hegyi@819
|
542 |
/**
|
hegyi@819
|
543 |
* \brief Iterator class to iterate on the nodes of the paths
|
hegyi@837
|
544 |
*
|
hegyi@819
|
545 |
* \ingroup paths
|
hegyi@819
|
546 |
* This class is used to iterate on the nodes of the paths
|
hegyi@819
|
547 |
*
|
hegyi@819
|
548 |
* Of course it converts to Graph::Node
|
hegyi@837
|
549 |
*
|
hegyi@819
|
550 |
* \todo Its interface differs from the standard node iterator.
|
hegyi@819
|
551 |
* Yes, it shouldn't.
|
hegyi@819
|
552 |
*/
|
hegyi@819
|
553 |
class NodeIt {
|
hegyi@819
|
554 |
friend class UndirPath;
|
hegyi@819
|
555 |
|
hegyi@819
|
556 |
int idx;
|
hegyi@819
|
557 |
const UndirPath *p;
|
hegyi@819
|
558 |
public:
|
hegyi@819
|
559 |
/// Default constructor
|
hegyi@819
|
560 |
NodeIt() {}
|
hegyi@819
|
561 |
/// Invalid constructor
|
hegyi@819
|
562 |
NodeIt(Invalid) : idx(-1), p(0) {}
|
hegyi@819
|
563 |
/// Constructor with starting point
|
hegyi@819
|
564 |
NodeIt(const UndirPath &_p, int _idx = 0) :
|
hegyi@819
|
565 |
idx(_idx), p(&_p) { validate(); }
|
hegyi@819
|
566 |
|
hegyi@819
|
567 |
///Validity check
|
hegyi@819
|
568 |
bool valid() const { return idx!=-1; }
|
hegyi@819
|
569 |
|
hegyi@819
|
570 |
///Conversion to Graph::Node
|
hegyi@819
|
571 |
operator const GraphNode& () const {
|
hegyi@819
|
572 |
if(idx >= p->length())
|
hegyi@831
|
573 |
return p->head();
|
hegyi@819
|
574 |
else if(idx >= 0)
|
hegyi@819
|
575 |
return p->gr->tail(p->edges[idx]);
|
hegyi@819
|
576 |
else
|
hegyi@819
|
577 |
return INVALID;
|
hegyi@819
|
578 |
}
|
hegyi@819
|
579 |
/// Next node
|
hegyi@819
|
580 |
NodeIt& operator++() { ++idx; validate(); return *this; }
|
hegyi@819
|
581 |
|
hegyi@819
|
582 |
/// Comparison operator
|
hegyi@819
|
583 |
bool operator==(const NodeIt& e) const { return idx==e.idx; }
|
hegyi@819
|
584 |
/// Comparison operator
|
hegyi@819
|
585 |
bool operator!=(const NodeIt& e) const { return idx!=e.idx; }
|
hegyi@819
|
586 |
/// Comparison operator
|
hegyi@819
|
587 |
bool operator<(const NodeIt& e) const { return idx<e.idx; }
|
hegyi@819
|
588 |
|
hegyi@819
|
589 |
private:
|
hegyi@819
|
590 |
void validate() { if( size_t(idx) > p->length() ) idx=-1; }
|
hegyi@819
|
591 |
};
|
hegyi@819
|
592 |
|
hegyi@837
|
593 |
friend class Builder;
|
hegyi@819
|
594 |
|
hegyi@819
|
595 |
/**
|
hegyi@819
|
596 |
* \brief Class to build paths
|
hegyi@837
|
597 |
*
|
hegyi@819
|
598 |
* \ingroup paths
|
hegyi@819
|
599 |
* This class is used to fill a path with edges.
|
hegyi@819
|
600 |
*
|
hegyi@819
|
601 |
* You can push new edges to the front and to the back of the path in
|
hegyi@819
|
602 |
* arbitrary order then you should commit these changes to the graph.
|
hegyi@819
|
603 |
*
|
hegyi@819
|
604 |
* Fundamentally, for most "Paths" (classes fulfilling the
|
hegyi@819
|
605 |
* PathConcept) while the builder is active (after the first modifying
|
hegyi@819
|
606 |
* operation and until the commit()) the original Path is in a
|
hegyi@819
|
607 |
* "transitional" state (operations ot it have undefined result). But
|
hegyi@819
|
608 |
* in the case of UndirPath the original path is unchanged until the
|
hegyi@819
|
609 |
* commit. However we don't recomend that you use this feature.
|
hegyi@819
|
610 |
*/
|
hegyi@819
|
611 |
class Builder {
|
hegyi@819
|
612 |
UndirPath &P;
|
hegyi@819
|
613 |
Container front, back;
|
hegyi@819
|
614 |
|
hegyi@819
|
615 |
public:
|
hegyi@819
|
616 |
///\param _P the path you want to fill in.
|
hegyi@819
|
617 |
///
|
hegyi@819
|
618 |
Builder(UndirPath &_P) : P(_P) {}
|
hegyi@819
|
619 |
|
hegyi@819
|
620 |
/// Sets the starting node of the path.
|
hegyi@837
|
621 |
|
hegyi@819
|
622 |
/// Sets the starting node of the path. Edge added to the path
|
hegyi@819
|
623 |
/// afterwards have to be incident to this node.
|
alpar@900
|
624 |
/// It should be called if and only if
|
alpar@900
|
625 |
/// the path is empty and before any call to
|
hegyi@819
|
626 |
/// \ref pushFront() or \ref pushBack()
|
hegyi@819
|
627 |
void setStartNode(const GraphNode &) {}
|
hegyi@819
|
628 |
|
hegyi@819
|
629 |
///Push a new edge to the front of the path
|
hegyi@819
|
630 |
|
hegyi@819
|
631 |
///Push a new edge to the front of the path.
|
hegyi@819
|
632 |
///\sa setStartNode
|
hegyi@819
|
633 |
void pushFront(const GraphEdge& e) {
|
hegyi@819
|
634 |
front.push_back(e);
|
hegyi@819
|
635 |
}
|
hegyi@819
|
636 |
|
hegyi@819
|
637 |
///Push a new edge to the back of the path
|
hegyi@819
|
638 |
|
hegyi@819
|
639 |
///Push a new edge to the back of the path.
|
hegyi@819
|
640 |
///\sa setStartNode
|
hegyi@819
|
641 |
void pushBack(const GraphEdge& e) {
|
hegyi@819
|
642 |
back.push_back(e);
|
hegyi@819
|
643 |
}
|
hegyi@819
|
644 |
|
hegyi@819
|
645 |
///Commit the changes to the path.
|
hegyi@819
|
646 |
void commit() {
|
hegyi@819
|
647 |
if( !(front.empty() && back.empty()) ) {
|
hegyi@819
|
648 |
Container tmp;
|
hegyi@819
|
649 |
tmp.reserve(front.size()+back.size()+P.length());
|
hegyi@819
|
650 |
tmp.insert(tmp.end(), front.rbegin(), front.rend());
|
hegyi@819
|
651 |
tmp.insert(tmp.end(), P.edges.begin(), P.edges.end());
|
hegyi@819
|
652 |
tmp.insert(tmp.end(), back.begin(), back.end());
|
hegyi@819
|
653 |
P.edges.swap(tmp);
|
hegyi@819
|
654 |
front.clear();
|
hegyi@819
|
655 |
back.clear();
|
hegyi@819
|
656 |
}
|
hegyi@819
|
657 |
}
|
hegyi@819
|
658 |
|
hegyi@819
|
659 |
|
hegyi@819
|
660 |
///Reserve storage for the builder in advance.
|
hegyi@819
|
661 |
|
hegyi@837
|
662 |
///If you know a reasonable upper bound of the number of the edges
|
hegyi@837
|
663 |
///to add to the front, using this function you can speed up the building.
|
hegyi@819
|
664 |
|
hegyi@837
|
665 |
void reserveFront(size_t r) {front.reserve(r);}
|
hegyi@837
|
666 |
|
hegyi@837
|
667 |
///Reserve storage for the builder in advance.
|
hegyi@837
|
668 |
|
hegyi@837
|
669 |
///If you know a reasonable upper bound of the number of the edges
|
hegyi@837
|
670 |
///to add to the back, using this function you can speed up the building.
|
hegyi@837
|
671 |
|
hegyi@837
|
672 |
void reserveBack(size_t r) {back.reserve(r);}
|
hegyi@831
|
673 |
|
hegyi@819
|
674 |
private:
|
hegyi@819
|
675 |
bool empty() {
|
hegyi@819
|
676 |
return front.empty() && back.empty() && P.empty();
|
hegyi@819
|
677 |
}
|
hegyi@819
|
678 |
|
hegyi@831
|
679 |
GraphNode tail() const {
|
hegyi@819
|
680 |
if( ! front.empty() )
|
hegyi@819
|
681 |
return P.gr->tail(front[front.size()-1]);
|
hegyi@819
|
682 |
else if( ! P.empty() )
|
hegyi@819
|
683 |
return P.gr->tail(P.edges[0]);
|
hegyi@819
|
684 |
else if( ! back.empty() )
|
hegyi@819
|
685 |
return P.gr->tail(back[0]);
|
hegyi@819
|
686 |
else
|
hegyi@819
|
687 |
return INVALID;
|
hegyi@819
|
688 |
}
|
hegyi@831
|
689 |
GraphNode head() const {
|
hegyi@819
|
690 |
if( ! back.empty() )
|
hegyi@819
|
691 |
return P.gr->head(back[back.size()-1]);
|
hegyi@819
|
692 |
else if( ! P.empty() )
|
hegyi@819
|
693 |
return P.gr->head(P.edges[P.length()-1]);
|
hegyi@819
|
694 |
else if( ! front.empty() )
|
hegyi@819
|
695 |
return P.gr->head(front[0]);
|
hegyi@819
|
696 |
else
|
hegyi@819
|
697 |
return INVALID;
|
hegyi@819
|
698 |
}
|
hegyi@819
|
699 |
|
hegyi@819
|
700 |
};
|
hegyi@819
|
701 |
|
hegyi@819
|
702 |
};
|
hegyi@819
|
703 |
|
hegyi@819
|
704 |
|
hegyi@819
|
705 |
///@}
|
hegyi@819
|
706 |
|
alpar@921
|
707 |
} // namespace lemon
|
hegyi@819
|
708 |
|
alpar@921
|
709 |
#endif // LEMON_PATH_H
|