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/* -*- mode: C++; indent-tabs-mode: nil; -*-
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*
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* This file is a part of LEMON, a generic C++ optimization library.
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*
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* Copyright (C) 2003-2009
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* Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
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* (Egervary Research Group on Combinatorial Optimization, 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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*
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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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#ifndef LEMON_PREFLOW_H
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#define LEMON_PREFLOW_H
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#include <lemon/tolerance.h>
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#include <lemon/elevator.h>
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/// \file
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/// \ingroup max_flow
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/// \brief Implementation of the preflow algorithm.
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namespace lemon {
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/// \brief Default traits class of Preflow class.
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///
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/// Default traits class of Preflow class.
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/// \tparam GR Digraph type.
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/// \tparam CAP Capacity map type.
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template <typename GR, typename CAP>
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struct PreflowDefaultTraits {
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/// \brief The type of the digraph the algorithm runs on.
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typedef GR Digraph;
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/// \brief The type of the map that stores the arc capacities.
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///
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/// The type of the map that stores the arc capacities.
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/// It must meet the \ref concepts::ReadMap "ReadMap" concept.
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typedef CAP CapacityMap;
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/// \brief The type of the flow values.
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typedef typename CapacityMap::Value Value;
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/// \brief The type of the map that stores the flow values.
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///
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/// The type of the map that stores the flow values.
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/// It must meet the \ref concepts::ReadWriteMap "ReadWriteMap" concept.
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#ifdef DOXYGEN
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typedef GR::ArcMap<Value> FlowMap;
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#else
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typedef typename Digraph::template ArcMap<Value> FlowMap;
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#endif
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/// \brief Instantiates a FlowMap.
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///
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/// This function instantiates a \ref FlowMap.
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/// \param digraph The digraph for which we would like to define
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/// the flow map.
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static FlowMap* createFlowMap(const Digraph& digraph) {
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return new FlowMap(digraph);
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}
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/// \brief The elevator type used by Preflow algorithm.
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///
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/// The elevator type used by Preflow algorithm.
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///
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/// \sa Elevator, LinkedElevator
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#ifdef DOXYGEN
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typedef lemon::Elevator<GR, GR::Node> Elevator;
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#else
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typedef lemon::Elevator<Digraph, typename Digraph::Node> Elevator;
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#endif
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/// \brief Instantiates an Elevator.
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///
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/// This function instantiates an \ref Elevator.
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/// \param digraph The digraph for which we would like to define
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/// the elevator.
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/// \param max_level The maximum level of the elevator.
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static Elevator* createElevator(const Digraph& digraph, int max_level) {
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return new Elevator(digraph, max_level);
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}
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/// \brief The tolerance used by the algorithm
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///
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/// The tolerance used by the algorithm to handle inexact computation.
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typedef lemon::Tolerance<Value> Tolerance;
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};
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/// \ingroup max_flow
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///
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/// \brief %Preflow algorithm class.
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///
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/// This class provides an implementation of Goldberg-Tarjan's \e preflow
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/// \e push-relabel algorithm producing a \ref max_flow
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/// "flow of maximum value" in a digraph.
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/// The preflow algorithms are the fastest known maximum
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/// flow algorithms. The current implementation uses a mixture of the
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/// \e "highest label" and the \e "bound decrease" heuristics.
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/// The worst case time complexity of the algorithm is \f$O(n^2\sqrt{e})\f$.
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///
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/// The algorithm consists of two phases. After the first phase
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/// the maximum flow value and the minimum cut is obtained. The
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/// second phase constructs a feasible maximum flow on each arc.
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///
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/// \tparam GR The type of the digraph the algorithm runs on.
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/// \tparam CAP The type of the capacity map. The default map
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/// type is \ref concepts::Digraph::ArcMap "GR::ArcMap<int>".
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#ifdef DOXYGEN
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template <typename GR, typename CAP, typename TR>
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#else
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template <typename GR,
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typename CAP = typename GR::template ArcMap<int>,
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typename TR = PreflowDefaultTraits<GR, CAP> >
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#endif
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class Preflow {
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public:
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///The \ref PreflowDefaultTraits "traits class" of the algorithm.
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typedef TR Traits;
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///The type of the digraph the algorithm runs on.
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typedef typename Traits::Digraph Digraph;
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///The type of the capacity map.
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typedef typename Traits::CapacityMap CapacityMap;
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///The type of the flow values.
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typedef typename Traits::Value Value;
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///The type of the flow map.
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typedef typename Traits::FlowMap FlowMap;
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///The type of the elevator.
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typedef typename Traits::Elevator Elevator;
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///The type of the tolerance.
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typedef typename Traits::Tolerance Tolerance;
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private:
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TEMPLATE_DIGRAPH_TYPEDEFS(Digraph);
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const Digraph& _graph;
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const CapacityMap* _capacity;
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int _node_num;
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Node _source, _target;
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FlowMap* _flow;
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bool _local_flow;
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Elevator* _level;
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bool _local_level;
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typedef typename Digraph::template NodeMap<Value> ExcessMap;
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ExcessMap* _excess;
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Tolerance _tolerance;
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bool _phase;
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void createStructures() {
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_node_num = countNodes(_graph);
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if (!_flow) {
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_flow = Traits::createFlowMap(_graph);
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_local_flow = true;
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}
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if (!_level) {
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_level = Traits::createElevator(_graph, _node_num);
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_local_level = true;
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}
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if (!_excess) {
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_excess = new ExcessMap(_graph);
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}
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}
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void destroyStructures() {
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if (_local_flow) {
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delete _flow;
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}
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if (_local_level) {
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delete _level;
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}
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if (_excess) {
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delete _excess;
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}
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}
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public:
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typedef Preflow Create;
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///\name Named Template Parameters
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///@{
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template <typename T>
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struct SetFlowMapTraits : public Traits {
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typedef T FlowMap;
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static FlowMap *createFlowMap(const Digraph&) {
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alpar@390
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LEMON_ASSERT(false, "FlowMap is not initialized");
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return 0; // ignore warnings
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}
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};
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/// \brief \ref named-templ-param "Named parameter" for setting
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/// FlowMap type
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///
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/// \ref named-templ-param "Named parameter" for setting FlowMap
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/// type.
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template <typename T>
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struct SetFlowMap
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: public Preflow<Digraph, CapacityMap, SetFlowMapTraits<T> > {
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typedef Preflow<Digraph, CapacityMap,
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SetFlowMapTraits<T> > Create;
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};
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kpeter@559
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template <typename T>
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struct SetElevatorTraits : public Traits {
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kpeter@559
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typedef T Elevator;
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static Elevator *createElevator(const Digraph&, int) {
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alpar@390
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LEMON_ASSERT(false, "Elevator is not initialized");
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alpar@390
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return 0; // ignore warnings
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}
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};
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/// \brief \ref named-templ-param "Named parameter" for setting
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/// Elevator type
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///
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/// \ref named-templ-param "Named parameter" for setting Elevator
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kpeter@393
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/// type. If this named parameter is used, then an external
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kpeter@393
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/// elevator object must be passed to the algorithm using the
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kpeter@393
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/// \ref elevator(Elevator&) "elevator()" function before calling
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kpeter@393
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/// \ref run() or \ref init().
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kpeter@393
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/// \sa SetStandardElevator
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template <typename T>
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struct SetElevator
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: public Preflow<Digraph, CapacityMap, SetElevatorTraits<T> > {
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alpar@389
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typedef Preflow<Digraph, CapacityMap,
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SetElevatorTraits<T> > Create;
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};
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template <typename T>
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alpar@391
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struct SetStandardElevatorTraits : public Traits {
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kpeter@559
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typedef T Elevator;
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alpar@389
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static Elevator *createElevator(const Digraph& digraph, int max_level) {
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alpar@389
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return new Elevator(digraph, max_level);
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}
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};
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/// \brief \ref named-templ-param "Named parameter" for setting
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kpeter@393
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/// Elevator type with automatic allocation
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///
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/// \ref named-templ-param "Named parameter" for setting Elevator
|
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/// type with automatic allocation.
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kpeter@393
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/// The Elevator should have standard constructor interface to be
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/// able to automatically created by the algorithm (i.e. the
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/// digraph and the maximum level should be passed to it).
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/// However an external elevator object could also be passed to the
|
kpeter@393
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/// algorithm with the \ref elevator(Elevator&) "elevator()" function
|
kpeter@393
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/// before calling \ref run() or \ref init().
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/// \sa SetElevator
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271 |
template <typename T>
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alpar@391
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272 |
struct SetStandardElevator
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: public Preflow<Digraph, CapacityMap,
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SetStandardElevatorTraits<T> > {
|
alpar@389
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275 |
typedef Preflow<Digraph, CapacityMap,
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kpeter@559
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SetStandardElevatorTraits<T> > Create;
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277 |
};
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alpar@389
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278 |
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alpar@389
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279 |
/// @}
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280 |
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281 |
protected:
|
alpar@389
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282 |
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alpar@389
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283 |
Preflow() {}
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alpar@389
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284 |
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alpar@389
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public:
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alpar@389
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286 |
|
alpar@389
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|
alpar@389
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288 |
/// \brief The constructor of the class.
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alpar@389
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289 |
///
|
alpar@389
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290 |
/// The constructor of the class.
|
alpar@389
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291 |
/// \param digraph The digraph the algorithm runs on.
|
alpar@389
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292 |
/// \param capacity The capacity of the arcs.
|
alpar@389
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293 |
/// \param source The source node.
|
alpar@389
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294 |
/// \param target The target node.
|
alpar@389
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295 |
Preflow(const Digraph& digraph, const CapacityMap& capacity,
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kpeter@393
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296 |
Node source, Node target)
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alpar@389
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297 |
: _graph(digraph), _capacity(&capacity),
|
alpar@389
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298 |
_node_num(0), _source(source), _target(target),
|
alpar@389
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299 |
_flow(0), _local_flow(false),
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alpar@389
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300 |
_level(0), _local_level(false),
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alpar@389
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301 |
_excess(0), _tolerance(), _phase() {}
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alpar@389
|
302 |
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kpeter@393
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/// \brief Destructor.
|
alpar@389
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///
|
alpar@389
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305 |
/// Destructor.
|
alpar@389
|
306 |
~Preflow() {
|
alpar@389
|
307 |
destroyStructures();
|
alpar@389
|
308 |
}
|
alpar@389
|
309 |
|
alpar@389
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310 |
/// \brief Sets the capacity map.
|
alpar@389
|
311 |
///
|
alpar@389
|
312 |
/// Sets the capacity map.
|
kpeter@393
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313 |
/// \return <tt>(*this)</tt>
|
alpar@389
|
314 |
Preflow& capacityMap(const CapacityMap& map) {
|
alpar@389
|
315 |
_capacity = ↦
|
alpar@389
|
316 |
return *this;
|
alpar@389
|
317 |
}
|
alpar@389
|
318 |
|
alpar@389
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319 |
/// \brief Sets the flow map.
|
alpar@389
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320 |
///
|
alpar@389
|
321 |
/// Sets the flow map.
|
kpeter@393
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322 |
/// If you don't use this function before calling \ref run() or
|
kpeter@393
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323 |
/// \ref init(), an instance will be allocated automatically.
|
kpeter@393
|
324 |
/// The destructor deallocates this automatically allocated map,
|
kpeter@393
|
325 |
/// of course.
|
kpeter@393
|
326 |
/// \return <tt>(*this)</tt>
|
alpar@389
|
327 |
Preflow& flowMap(FlowMap& map) {
|
alpar@389
|
328 |
if (_local_flow) {
|
alpar@389
|
329 |
delete _flow;
|
alpar@389
|
330 |
_local_flow = false;
|
alpar@389
|
331 |
}
|
alpar@389
|
332 |
_flow = ↦
|
alpar@389
|
333 |
return *this;
|
alpar@389
|
334 |
}
|
alpar@389
|
335 |
|
kpeter@393
|
336 |
/// \brief Sets the source node.
|
alpar@389
|
337 |
///
|
kpeter@393
|
338 |
/// Sets the source node.
|
kpeter@393
|
339 |
/// \return <tt>(*this)</tt>
|
kpeter@393
|
340 |
Preflow& source(const Node& node) {
|
kpeter@393
|
341 |
_source = node;
|
kpeter@393
|
342 |
return *this;
|
alpar@389
|
343 |
}
|
alpar@389
|
344 |
|
kpeter@393
|
345 |
/// \brief Sets the target node.
|
alpar@389
|
346 |
///
|
kpeter@393
|
347 |
/// Sets the target node.
|
kpeter@393
|
348 |
/// \return <tt>(*this)</tt>
|
kpeter@393
|
349 |
Preflow& target(const Node& node) {
|
kpeter@393
|
350 |
_target = node;
|
kpeter@393
|
351 |
return *this;
|
kpeter@393
|
352 |
}
|
kpeter@393
|
353 |
|
kpeter@393
|
354 |
/// \brief Sets the elevator used by algorithm.
|
kpeter@393
|
355 |
///
|
kpeter@393
|
356 |
/// Sets the elevator used by algorithm.
|
kpeter@393
|
357 |
/// If you don't use this function before calling \ref run() or
|
kpeter@393
|
358 |
/// \ref init(), an instance will be allocated automatically.
|
kpeter@393
|
359 |
/// The destructor deallocates this automatically allocated elevator,
|
kpeter@393
|
360 |
/// of course.
|
kpeter@393
|
361 |
/// \return <tt>(*this)</tt>
|
alpar@389
|
362 |
Preflow& elevator(Elevator& elevator) {
|
alpar@389
|
363 |
if (_local_level) {
|
alpar@389
|
364 |
delete _level;
|
alpar@389
|
365 |
_local_level = false;
|
alpar@389
|
366 |
}
|
alpar@389
|
367 |
_level = &elevator;
|
alpar@389
|
368 |
return *this;
|
alpar@389
|
369 |
}
|
alpar@389
|
370 |
|
kpeter@393
|
371 |
/// \brief Returns a const reference to the elevator.
|
alpar@389
|
372 |
///
|
kpeter@393
|
373 |
/// Returns a const reference to the elevator.
|
kpeter@393
|
374 |
///
|
kpeter@393
|
375 |
/// \pre Either \ref run() or \ref init() must be called before
|
kpeter@393
|
376 |
/// using this function.
|
kpeter@420
|
377 |
const Elevator& elevator() const {
|
alpar@389
|
378 |
return *_level;
|
alpar@389
|
379 |
}
|
alpar@389
|
380 |
|
kpeter@689
|
381 |
/// \brief Sets the tolerance used by the algorithm.
|
alpar@389
|
382 |
///
|
kpeter@689
|
383 |
/// Sets the tolerance object used by the algorithm.
|
kpeter@689
|
384 |
/// \return <tt>(*this)</tt>
|
kpeter@688
|
385 |
Preflow& tolerance(const Tolerance& tolerance) {
|
alpar@389
|
386 |
_tolerance = tolerance;
|
alpar@389
|
387 |
return *this;
|
alpar@389
|
388 |
}
|
alpar@389
|
389 |
|
kpeter@393
|
390 |
/// \brief Returns a const reference to the tolerance.
|
alpar@389
|
391 |
///
|
kpeter@689
|
392 |
/// Returns a const reference to the tolerance object used by
|
kpeter@689
|
393 |
/// the algorithm.
|
alpar@389
|
394 |
const Tolerance& tolerance() const {
|
kpeter@688
|
395 |
return _tolerance;
|
alpar@389
|
396 |
}
|
alpar@389
|
397 |
|
kpeter@393
|
398 |
/// \name Execution Control
|
kpeter@393
|
399 |
/// The simplest way to execute the preflow algorithm is to use
|
kpeter@393
|
400 |
/// \ref run() or \ref runMinCut().\n
|
kpeter@713
|
401 |
/// If you need better control on the initial solution or the execution,
|
kpeter@713
|
402 |
/// you have to call one of the \ref init() functions first, then
|
kpeter@393
|
403 |
/// \ref startFirstPhase() and if you need it \ref startSecondPhase().
|
alpar@389
|
404 |
|
alpar@389
|
405 |
///@{
|
alpar@389
|
406 |
|
alpar@389
|
407 |
/// \brief Initializes the internal data structures.
|
alpar@389
|
408 |
///
|
kpeter@393
|
409 |
/// Initializes the internal data structures and sets the initial
|
kpeter@393
|
410 |
/// flow to zero on each arc.
|
alpar@389
|
411 |
void init() {
|
alpar@389
|
412 |
createStructures();
|
alpar@389
|
413 |
|
alpar@389
|
414 |
_phase = true;
|
alpar@389
|
415 |
for (NodeIt n(_graph); n != INVALID; ++n) {
|
kpeter@581
|
416 |
(*_excess)[n] = 0;
|
alpar@389
|
417 |
}
|
alpar@389
|
418 |
|
alpar@389
|
419 |
for (ArcIt e(_graph); e != INVALID; ++e) {
|
alpar@389
|
420 |
_flow->set(e, 0);
|
alpar@389
|
421 |
}
|
alpar@389
|
422 |
|
alpar@389
|
423 |
typename Digraph::template NodeMap<bool> reached(_graph, false);
|
alpar@389
|
424 |
|
alpar@389
|
425 |
_level->initStart();
|
alpar@389
|
426 |
_level->initAddItem(_target);
|
alpar@389
|
427 |
|
alpar@389
|
428 |
std::vector<Node> queue;
|
kpeter@581
|
429 |
reached[_source] = true;
|
alpar@389
|
430 |
|
alpar@389
|
431 |
queue.push_back(_target);
|
kpeter@581
|
432 |
reached[_target] = true;
|
alpar@389
|
433 |
while (!queue.empty()) {
|
alpar@389
|
434 |
_level->initNewLevel();
|
alpar@389
|
435 |
std::vector<Node> nqueue;
|
alpar@389
|
436 |
for (int i = 0; i < int(queue.size()); ++i) {
|
alpar@389
|
437 |
Node n = queue[i];
|
alpar@389
|
438 |
for (InArcIt e(_graph, n); e != INVALID; ++e) {
|
alpar@389
|
439 |
Node u = _graph.source(e);
|
alpar@389
|
440 |
if (!reached[u] && _tolerance.positive((*_capacity)[e])) {
|
kpeter@581
|
441 |
reached[u] = true;
|
alpar@389
|
442 |
_level->initAddItem(u);
|
alpar@389
|
443 |
nqueue.push_back(u);
|
alpar@389
|
444 |
}
|
alpar@389
|
445 |
}
|
alpar@389
|
446 |
}
|
alpar@389
|
447 |
queue.swap(nqueue);
|
alpar@389
|
448 |
}
|
alpar@389
|
449 |
_level->initFinish();
|
alpar@389
|
450 |
|
alpar@389
|
451 |
for (OutArcIt e(_graph, _source); e != INVALID; ++e) {
|
alpar@389
|
452 |
if (_tolerance.positive((*_capacity)[e])) {
|
alpar@389
|
453 |
Node u = _graph.target(e);
|
alpar@389
|
454 |
if ((*_level)[u] == _level->maxLevel()) continue;
|
alpar@389
|
455 |
_flow->set(e, (*_capacity)[e]);
|
kpeter@581
|
456 |
(*_excess)[u] += (*_capacity)[e];
|
alpar@389
|
457 |
if (u != _target && !_level->active(u)) {
|
alpar@389
|
458 |
_level->activate(u);
|
alpar@389
|
459 |
}
|
alpar@389
|
460 |
}
|
alpar@389
|
461 |
}
|
alpar@389
|
462 |
}
|
alpar@389
|
463 |
|
kpeter@393
|
464 |
/// \brief Initializes the internal data structures using the
|
kpeter@393
|
465 |
/// given flow map.
|
alpar@389
|
466 |
///
|
alpar@389
|
467 |
/// Initializes the internal data structures and sets the initial
|
alpar@389
|
468 |
/// flow to the given \c flowMap. The \c flowMap should contain a
|
kpeter@393
|
469 |
/// flow or at least a preflow, i.e. at each node excluding the
|
kpeter@393
|
470 |
/// source node the incoming flow should greater or equal to the
|
alpar@389
|
471 |
/// outgoing flow.
|
kpeter@393
|
472 |
/// \return \c false if the given \c flowMap is not a preflow.
|
alpar@389
|
473 |
template <typename FlowMap>
|
kpeter@392
|
474 |
bool init(const FlowMap& flowMap) {
|
alpar@389
|
475 |
createStructures();
|
alpar@389
|
476 |
|
alpar@389
|
477 |
for (ArcIt e(_graph); e != INVALID; ++e) {
|
alpar@389
|
478 |
_flow->set(e, flowMap[e]);
|
alpar@389
|
479 |
}
|
alpar@389
|
480 |
|
alpar@389
|
481 |
for (NodeIt n(_graph); n != INVALID; ++n) {
|
kpeter@641
|
482 |
Value excess = 0;
|
alpar@389
|
483 |
for (InArcIt e(_graph, n); e != INVALID; ++e) {
|
alpar@389
|
484 |
excess += (*_flow)[e];
|
alpar@389
|
485 |
}
|
alpar@389
|
486 |
for (OutArcIt e(_graph, n); e != INVALID; ++e) {
|
alpar@389
|
487 |
excess -= (*_flow)[e];
|
alpar@389
|
488 |
}
|
alpar@389
|
489 |
if (excess < 0 && n != _source) return false;
|
kpeter@581
|
490 |
(*_excess)[n] = excess;
|
alpar@389
|
491 |
}
|
alpar@389
|
492 |
|
alpar@389
|
493 |
typename Digraph::template NodeMap<bool> reached(_graph, false);
|
alpar@389
|
494 |
|
alpar@389
|
495 |
_level->initStart();
|
alpar@389
|
496 |
_level->initAddItem(_target);
|
alpar@389
|
497 |
|
alpar@389
|
498 |
std::vector<Node> queue;
|
kpeter@581
|
499 |
reached[_source] = true;
|
alpar@389
|
500 |
|
alpar@389
|
501 |
queue.push_back(_target);
|
kpeter@581
|
502 |
reached[_target] = true;
|
alpar@389
|
503 |
while (!queue.empty()) {
|
alpar@389
|
504 |
_level->initNewLevel();
|
alpar@389
|
505 |
std::vector<Node> nqueue;
|
alpar@389
|
506 |
for (int i = 0; i < int(queue.size()); ++i) {
|
alpar@389
|
507 |
Node n = queue[i];
|
alpar@389
|
508 |
for (InArcIt e(_graph, n); e != INVALID; ++e) {
|
alpar@389
|
509 |
Node u = _graph.source(e);
|
alpar@389
|
510 |
if (!reached[u] &&
|
alpar@389
|
511 |
_tolerance.positive((*_capacity)[e] - (*_flow)[e])) {
|
kpeter@581
|
512 |
reached[u] = true;
|
alpar@389
|
513 |
_level->initAddItem(u);
|
alpar@389
|
514 |
nqueue.push_back(u);
|
alpar@389
|
515 |
}
|
alpar@389
|
516 |
}
|
alpar@389
|
517 |
for (OutArcIt e(_graph, n); e != INVALID; ++e) {
|
alpar@389
|
518 |
Node v = _graph.target(e);
|
alpar@389
|
519 |
if (!reached[v] && _tolerance.positive((*_flow)[e])) {
|
kpeter@581
|
520 |
reached[v] = true;
|
alpar@389
|
521 |
_level->initAddItem(v);
|
alpar@389
|
522 |
nqueue.push_back(v);
|
alpar@389
|
523 |
}
|
alpar@389
|
524 |
}
|
alpar@389
|
525 |
}
|
alpar@389
|
526 |
queue.swap(nqueue);
|
alpar@389
|
527 |
}
|
alpar@389
|
528 |
_level->initFinish();
|
alpar@389
|
529 |
|
alpar@389
|
530 |
for (OutArcIt e(_graph, _source); e != INVALID; ++e) {
|
kpeter@641
|
531 |
Value rem = (*_capacity)[e] - (*_flow)[e];
|
alpar@389
|
532 |
if (_tolerance.positive(rem)) {
|
alpar@389
|
533 |
Node u = _graph.target(e);
|
alpar@389
|
534 |
if ((*_level)[u] == _level->maxLevel()) continue;
|
alpar@389
|
535 |
_flow->set(e, (*_capacity)[e]);
|
kpeter@581
|
536 |
(*_excess)[u] += rem;
|
alpar@389
|
537 |
if (u != _target && !_level->active(u)) {
|
alpar@389
|
538 |
_level->activate(u);
|
alpar@389
|
539 |
}
|
alpar@389
|
540 |
}
|
alpar@389
|
541 |
}
|
alpar@389
|
542 |
for (InArcIt e(_graph, _source); e != INVALID; ++e) {
|
kpeter@641
|
543 |
Value rem = (*_flow)[e];
|
alpar@389
|
544 |
if (_tolerance.positive(rem)) {
|
alpar@389
|
545 |
Node v = _graph.source(e);
|
alpar@389
|
546 |
if ((*_level)[v] == _level->maxLevel()) continue;
|
alpar@389
|
547 |
_flow->set(e, 0);
|
kpeter@581
|
548 |
(*_excess)[v] += rem;
|
alpar@389
|
549 |
if (v != _target && !_level->active(v)) {
|
alpar@389
|
550 |
_level->activate(v);
|
alpar@389
|
551 |
}
|
alpar@389
|
552 |
}
|
alpar@389
|
553 |
}
|
alpar@389
|
554 |
return true;
|
alpar@389
|
555 |
}
|
alpar@389
|
556 |
|
alpar@389
|
557 |
/// \brief Starts the first phase of the preflow algorithm.
|
alpar@389
|
558 |
///
|
alpar@389
|
559 |
/// The preflow algorithm consists of two phases, this method runs
|
alpar@389
|
560 |
/// the first phase. After the first phase the maximum flow value
|
alpar@389
|
561 |
/// and a minimum value cut can already be computed, although a
|
alpar@389
|
562 |
/// maximum flow is not yet obtained. So after calling this method
|
alpar@389
|
563 |
/// \ref flowValue() returns the value of a maximum flow and \ref
|
alpar@389
|
564 |
/// minCut() returns a minimum cut.
|
kpeter@393
|
565 |
/// \pre One of the \ref init() functions must be called before
|
kpeter@393
|
566 |
/// using this function.
|
alpar@389
|
567 |
void startFirstPhase() {
|
alpar@389
|
568 |
_phase = true;
|
alpar@389
|
569 |
|
alpar@389
|
570 |
Node n = _level->highestActive();
|
alpar@389
|
571 |
int level = _level->highestActiveLevel();
|
alpar@389
|
572 |
while (n != INVALID) {
|
alpar@389
|
573 |
int num = _node_num;
|
alpar@389
|
574 |
|
alpar@389
|
575 |
while (num > 0 && n != INVALID) {
|
kpeter@641
|
576 |
Value excess = (*_excess)[n];
|
alpar@389
|
577 |
int new_level = _level->maxLevel();
|
alpar@389
|
578 |
|
alpar@389
|
579 |
for (OutArcIt e(_graph, n); e != INVALID; ++e) {
|
kpeter@641
|
580 |
Value rem = (*_capacity)[e] - (*_flow)[e];
|
alpar@389
|
581 |
if (!_tolerance.positive(rem)) continue;
|
alpar@389
|
582 |
Node v = _graph.target(e);
|
alpar@389
|
583 |
if ((*_level)[v] < level) {
|
alpar@389
|
584 |
if (!_level->active(v) && v != _target) {
|
alpar@389
|
585 |
_level->activate(v);
|
alpar@389
|
586 |
}
|
alpar@389
|
587 |
if (!_tolerance.less(rem, excess)) {
|
alpar@389
|
588 |
_flow->set(e, (*_flow)[e] + excess);
|
kpeter@581
|
589 |
(*_excess)[v] += excess;
|
alpar@389
|
590 |
excess = 0;
|
alpar@389
|
591 |
goto no_more_push_1;
|
alpar@389
|
592 |
} else {
|
alpar@389
|
593 |
excess -= rem;
|
kpeter@581
|
594 |
(*_excess)[v] += rem;
|
alpar@389
|
595 |
_flow->set(e, (*_capacity)[e]);
|
alpar@389
|
596 |
}
|
alpar@389
|
597 |
} else if (new_level > (*_level)[v]) {
|
alpar@389
|
598 |
new_level = (*_level)[v];
|
alpar@389
|
599 |
}
|
alpar@389
|
600 |
}
|
alpar@389
|
601 |
|
alpar@389
|
602 |
for (InArcIt e(_graph, n); e != INVALID; ++e) {
|
kpeter@641
|
603 |
Value rem = (*_flow)[e];
|
alpar@389
|
604 |
if (!_tolerance.positive(rem)) continue;
|
alpar@389
|
605 |
Node v = _graph.source(e);
|
alpar@389
|
606 |
if ((*_level)[v] < level) {
|
alpar@389
|
607 |
if (!_level->active(v) && v != _target) {
|
alpar@389
|
608 |
_level->activate(v);
|
alpar@389
|
609 |
}
|
alpar@389
|
610 |
if (!_tolerance.less(rem, excess)) {
|
alpar@389
|
611 |
_flow->set(e, (*_flow)[e] - excess);
|
kpeter@581
|
612 |
(*_excess)[v] += excess;
|
alpar@389
|
613 |
excess = 0;
|
alpar@389
|
614 |
goto no_more_push_1;
|
alpar@389
|
615 |
} else {
|
alpar@389
|
616 |
excess -= rem;
|
kpeter@581
|
617 |
(*_excess)[v] += rem;
|
alpar@389
|
618 |
_flow->set(e, 0);
|
alpar@389
|
619 |
}
|
alpar@389
|
620 |
} else if (new_level > (*_level)[v]) {
|
alpar@389
|
621 |
new_level = (*_level)[v];
|
alpar@389
|
622 |
}
|
alpar@389
|
623 |
}
|
alpar@389
|
624 |
|
alpar@389
|
625 |
no_more_push_1:
|
alpar@389
|
626 |
|
kpeter@581
|
627 |
(*_excess)[n] = excess;
|
alpar@389
|
628 |
|
alpar@389
|
629 |
if (excess != 0) {
|
alpar@389
|
630 |
if (new_level + 1 < _level->maxLevel()) {
|
alpar@389
|
631 |
_level->liftHighestActive(new_level + 1);
|
alpar@389
|
632 |
} else {
|
alpar@389
|
633 |
_level->liftHighestActiveToTop();
|
alpar@389
|
634 |
}
|
alpar@389
|
635 |
if (_level->emptyLevel(level)) {
|
alpar@389
|
636 |
_level->liftToTop(level);
|
alpar@389
|
637 |
}
|
alpar@389
|
638 |
} else {
|
alpar@389
|
639 |
_level->deactivate(n);
|
alpar@389
|
640 |
}
|
alpar@389
|
641 |
|
alpar@389
|
642 |
n = _level->highestActive();
|
alpar@389
|
643 |
level = _level->highestActiveLevel();
|
alpar@389
|
644 |
--num;
|
alpar@389
|
645 |
}
|
alpar@389
|
646 |
|
alpar@389
|
647 |
num = _node_num * 20;
|
alpar@389
|
648 |
while (num > 0 && n != INVALID) {
|
kpeter@641
|
649 |
Value excess = (*_excess)[n];
|
alpar@389
|
650 |
int new_level = _level->maxLevel();
|
alpar@389
|
651 |
|
alpar@389
|
652 |
for (OutArcIt e(_graph, n); e != INVALID; ++e) {
|
kpeter@641
|
653 |
Value rem = (*_capacity)[e] - (*_flow)[e];
|
alpar@389
|
654 |
if (!_tolerance.positive(rem)) continue;
|
alpar@389
|
655 |
Node v = _graph.target(e);
|
alpar@389
|
656 |
if ((*_level)[v] < level) {
|
alpar@389
|
657 |
if (!_level->active(v) && v != _target) {
|
alpar@389
|
658 |
_level->activate(v);
|
alpar@389
|
659 |
}
|
alpar@389
|
660 |
if (!_tolerance.less(rem, excess)) {
|
alpar@389
|
661 |
_flow->set(e, (*_flow)[e] + excess);
|
kpeter@581
|
662 |
(*_excess)[v] += excess;
|
alpar@389
|
663 |
excess = 0;
|
alpar@389
|
664 |
goto no_more_push_2;
|
alpar@389
|
665 |
} else {
|
alpar@389
|
666 |
excess -= rem;
|
kpeter@581
|
667 |
(*_excess)[v] += rem;
|
alpar@389
|
668 |
_flow->set(e, (*_capacity)[e]);
|
alpar@389
|
669 |
}
|
alpar@389
|
670 |
} else if (new_level > (*_level)[v]) {
|
alpar@389
|
671 |
new_level = (*_level)[v];
|
alpar@389
|
672 |
}
|
alpar@389
|
673 |
}
|
alpar@389
|
674 |
|
alpar@389
|
675 |
for (InArcIt e(_graph, n); e != INVALID; ++e) {
|
kpeter@641
|
676 |
Value rem = (*_flow)[e];
|
alpar@389
|
677 |
if (!_tolerance.positive(rem)) continue;
|
alpar@389
|
678 |
Node v = _graph.source(e);
|
alpar@389
|
679 |
if ((*_level)[v] < level) {
|
alpar@389
|
680 |
if (!_level->active(v) && v != _target) {
|
alpar@389
|
681 |
_level->activate(v);
|
alpar@389
|
682 |
}
|
alpar@389
|
683 |
if (!_tolerance.less(rem, excess)) {
|
alpar@389
|
684 |
_flow->set(e, (*_flow)[e] - excess);
|
kpeter@581
|
685 |
(*_excess)[v] += excess;
|
alpar@389
|
686 |
excess = 0;
|
alpar@389
|
687 |
goto no_more_push_2;
|
alpar@389
|
688 |
} else {
|
alpar@389
|
689 |
excess -= rem;
|
kpeter@581
|
690 |
(*_excess)[v] += rem;
|
alpar@389
|
691 |
_flow->set(e, 0);
|
alpar@389
|
692 |
}
|
alpar@389
|
693 |
} else if (new_level > (*_level)[v]) {
|
alpar@389
|
694 |
new_level = (*_level)[v];
|
alpar@389
|
695 |
}
|
alpar@389
|
696 |
}
|
alpar@389
|
697 |
|
alpar@389
|
698 |
no_more_push_2:
|
alpar@389
|
699 |
|
kpeter@581
|
700 |
(*_excess)[n] = excess;
|
alpar@389
|
701 |
|
alpar@389
|
702 |
if (excess != 0) {
|
alpar@389
|
703 |
if (new_level + 1 < _level->maxLevel()) {
|
alpar@389
|
704 |
_level->liftActiveOn(level, new_level + 1);
|
alpar@389
|
705 |
} else {
|
alpar@389
|
706 |
_level->liftActiveToTop(level);
|
alpar@389
|
707 |
}
|
alpar@389
|
708 |
if (_level->emptyLevel(level)) {
|
alpar@389
|
709 |
_level->liftToTop(level);
|
alpar@389
|
710 |
}
|
alpar@389
|
711 |
} else {
|
alpar@389
|
712 |
_level->deactivate(n);
|
alpar@389
|
713 |
}
|
alpar@389
|
714 |
|
alpar@389
|
715 |
while (level >= 0 && _level->activeFree(level)) {
|
alpar@389
|
716 |
--level;
|
alpar@389
|
717 |
}
|
alpar@389
|
718 |
if (level == -1) {
|
alpar@389
|
719 |
n = _level->highestActive();
|
alpar@389
|
720 |
level = _level->highestActiveLevel();
|
alpar@389
|
721 |
} else {
|
alpar@389
|
722 |
n = _level->activeOn(level);
|
alpar@389
|
723 |
}
|
alpar@389
|
724 |
--num;
|
alpar@389
|
725 |
}
|
alpar@389
|
726 |
}
|
alpar@389
|
727 |
}
|
alpar@389
|
728 |
|
alpar@389
|
729 |
/// \brief Starts the second phase of the preflow algorithm.
|
alpar@389
|
730 |
///
|
alpar@389
|
731 |
/// The preflow algorithm consists of two phases, this method runs
|
kpeter@393
|
732 |
/// the second phase. After calling one of the \ref init() functions
|
kpeter@393
|
733 |
/// and \ref startFirstPhase() and then \ref startSecondPhase(),
|
kpeter@393
|
734 |
/// \ref flowMap() returns a maximum flow, \ref flowValue() returns the
|
alpar@389
|
735 |
/// value of a maximum flow, \ref minCut() returns a minimum cut
|
kpeter@393
|
736 |
/// \pre One of the \ref init() functions and \ref startFirstPhase()
|
kpeter@393
|
737 |
/// must be called before using this function.
|
alpar@389
|
738 |
void startSecondPhase() {
|
alpar@389
|
739 |
_phase = false;
|
alpar@389
|
740 |
|
alpar@389
|
741 |
typename Digraph::template NodeMap<bool> reached(_graph);
|
alpar@389
|
742 |
for (NodeIt n(_graph); n != INVALID; ++n) {
|
kpeter@581
|
743 |
reached[n] = (*_level)[n] < _level->maxLevel();
|
alpar@389
|
744 |
}
|
alpar@389
|
745 |
|
alpar@389
|
746 |
_level->initStart();
|
alpar@389
|
747 |
_level->initAddItem(_source);
|
alpar@389
|
748 |
|
alpar@389
|
749 |
std::vector<Node> queue;
|
alpar@389
|
750 |
queue.push_back(_source);
|
kpeter@581
|
751 |
reached[_source] = true;
|
alpar@389
|
752 |
|
alpar@389
|
753 |
while (!queue.empty()) {
|
alpar@389
|
754 |
_level->initNewLevel();
|
alpar@389
|
755 |
std::vector<Node> nqueue;
|
alpar@389
|
756 |
for (int i = 0; i < int(queue.size()); ++i) {
|
alpar@389
|
757 |
Node n = queue[i];
|
alpar@389
|
758 |
for (OutArcIt e(_graph, n); e != INVALID; ++e) {
|
alpar@389
|
759 |
Node v = _graph.target(e);
|
alpar@389
|
760 |
if (!reached[v] && _tolerance.positive((*_flow)[e])) {
|
kpeter@581
|
761 |
reached[v] = true;
|
alpar@389
|
762 |
_level->initAddItem(v);
|
alpar@389
|
763 |
nqueue.push_back(v);
|
alpar@389
|
764 |
}
|
alpar@389
|
765 |
}
|
alpar@389
|
766 |
for (InArcIt e(_graph, n); e != INVALID; ++e) {
|
alpar@389
|
767 |
Node u = _graph.source(e);
|
alpar@389
|
768 |
if (!reached[u] &&
|
alpar@389
|
769 |
_tolerance.positive((*_capacity)[e] - (*_flow)[e])) {
|
kpeter@581
|
770 |
reached[u] = true;
|
alpar@389
|
771 |
_level->initAddItem(u);
|
alpar@389
|
772 |
nqueue.push_back(u);
|
alpar@389
|
773 |
}
|
alpar@389
|
774 |
}
|
alpar@389
|
775 |
}
|
alpar@389
|
776 |
queue.swap(nqueue);
|
alpar@389
|
777 |
}
|
alpar@389
|
778 |
_level->initFinish();
|
alpar@389
|
779 |
|
alpar@389
|
780 |
for (NodeIt n(_graph); n != INVALID; ++n) {
|
alpar@389
|
781 |
if (!reached[n]) {
|
alpar@389
|
782 |
_level->dirtyTopButOne(n);
|
alpar@389
|
783 |
} else if ((*_excess)[n] > 0 && _target != n) {
|
alpar@389
|
784 |
_level->activate(n);
|
alpar@389
|
785 |
}
|
alpar@389
|
786 |
}
|
alpar@389
|
787 |
|
alpar@389
|
788 |
Node n;
|
alpar@389
|
789 |
while ((n = _level->highestActive()) != INVALID) {
|
kpeter@641
|
790 |
Value excess = (*_excess)[n];
|
alpar@389
|
791 |
int level = _level->highestActiveLevel();
|
alpar@389
|
792 |
int new_level = _level->maxLevel();
|
alpar@389
|
793 |
|
alpar@389
|
794 |
for (OutArcIt e(_graph, n); e != INVALID; ++e) {
|
kpeter@641
|
795 |
Value rem = (*_capacity)[e] - (*_flow)[e];
|
alpar@389
|
796 |
if (!_tolerance.positive(rem)) continue;
|
alpar@389
|
797 |
Node v = _graph.target(e);
|
alpar@389
|
798 |
if ((*_level)[v] < level) {
|
alpar@389
|
799 |
if (!_level->active(v) && v != _source) {
|
alpar@389
|
800 |
_level->activate(v);
|
alpar@389
|
801 |
}
|
alpar@389
|
802 |
if (!_tolerance.less(rem, excess)) {
|
alpar@389
|
803 |
_flow->set(e, (*_flow)[e] + excess);
|
kpeter@581
|
804 |
(*_excess)[v] += excess;
|
alpar@389
|
805 |
excess = 0;
|
alpar@389
|
806 |
goto no_more_push;
|
alpar@389
|
807 |
} else {
|
alpar@389
|
808 |
excess -= rem;
|
kpeter@581
|
809 |
(*_excess)[v] += rem;
|
alpar@389
|
810 |
_flow->set(e, (*_capacity)[e]);
|
alpar@389
|
811 |
}
|
alpar@389
|
812 |
} else if (new_level > (*_level)[v]) {
|
alpar@389
|
813 |
new_level = (*_level)[v];
|
alpar@389
|
814 |
}
|
alpar@389
|
815 |
}
|
alpar@389
|
816 |
|
alpar@389
|
817 |
for (InArcIt e(_graph, n); e != INVALID; ++e) {
|
kpeter@641
|
818 |
Value rem = (*_flow)[e];
|
alpar@389
|
819 |
if (!_tolerance.positive(rem)) continue;
|
alpar@389
|
820 |
Node v = _graph.source(e);
|
alpar@389
|
821 |
if ((*_level)[v] < level) {
|
alpar@389
|
822 |
if (!_level->active(v) && v != _source) {
|
alpar@389
|
823 |
_level->activate(v);
|
alpar@389
|
824 |
}
|
alpar@389
|
825 |
if (!_tolerance.less(rem, excess)) {
|
alpar@389
|
826 |
_flow->set(e, (*_flow)[e] - excess);
|
kpeter@581
|
827 |
(*_excess)[v] += excess;
|
alpar@389
|
828 |
excess = 0;
|
alpar@389
|
829 |
goto no_more_push;
|
alpar@389
|
830 |
} else {
|
alpar@389
|
831 |
excess -= rem;
|
kpeter@581
|
832 |
(*_excess)[v] += rem;
|
alpar@389
|
833 |
_flow->set(e, 0);
|
alpar@389
|
834 |
}
|
alpar@389
|
835 |
} else if (new_level > (*_level)[v]) {
|
alpar@389
|
836 |
new_level = (*_level)[v];
|
alpar@389
|
837 |
}
|
alpar@389
|
838 |
}
|
alpar@389
|
839 |
|
alpar@389
|
840 |
no_more_push:
|
alpar@389
|
841 |
|
kpeter@581
|
842 |
(*_excess)[n] = excess;
|
alpar@389
|
843 |
|
alpar@389
|
844 |
if (excess != 0) {
|
alpar@389
|
845 |
if (new_level + 1 < _level->maxLevel()) {
|
alpar@389
|
846 |
_level->liftHighestActive(new_level + 1);
|
alpar@389
|
847 |
} else {
|
alpar@389
|
848 |
// Calculation error
|
alpar@389
|
849 |
_level->liftHighestActiveToTop();
|
alpar@389
|
850 |
}
|
alpar@389
|
851 |
if (_level->emptyLevel(level)) {
|
alpar@389
|
852 |
// Calculation error
|
alpar@389
|
853 |
_level->liftToTop(level);
|
alpar@389
|
854 |
}
|
alpar@389
|
855 |
} else {
|
alpar@389
|
856 |
_level->deactivate(n);
|
alpar@389
|
857 |
}
|
alpar@389
|
858 |
|
alpar@389
|
859 |
}
|
alpar@389
|
860 |
}
|
alpar@389
|
861 |
|
alpar@389
|
862 |
/// \brief Runs the preflow algorithm.
|
alpar@389
|
863 |
///
|
alpar@389
|
864 |
/// Runs the preflow algorithm.
|
alpar@389
|
865 |
/// \note pf.run() is just a shortcut of the following code.
|
alpar@389
|
866 |
/// \code
|
alpar@389
|
867 |
/// pf.init();
|
alpar@389
|
868 |
/// pf.startFirstPhase();
|
alpar@389
|
869 |
/// pf.startSecondPhase();
|
alpar@389
|
870 |
/// \endcode
|
alpar@389
|
871 |
void run() {
|
alpar@389
|
872 |
init();
|
alpar@389
|
873 |
startFirstPhase();
|
alpar@389
|
874 |
startSecondPhase();
|
alpar@389
|
875 |
}
|
alpar@389
|
876 |
|
alpar@389
|
877 |
/// \brief Runs the preflow algorithm to compute the minimum cut.
|
alpar@389
|
878 |
///
|
alpar@389
|
879 |
/// Runs the preflow algorithm to compute the minimum cut.
|
alpar@389
|
880 |
/// \note pf.runMinCut() is just a shortcut of the following code.
|
alpar@389
|
881 |
/// \code
|
alpar@389
|
882 |
/// pf.init();
|
alpar@389
|
883 |
/// pf.startFirstPhase();
|
alpar@389
|
884 |
/// \endcode
|
alpar@389
|
885 |
void runMinCut() {
|
alpar@389
|
886 |
init();
|
alpar@389
|
887 |
startFirstPhase();
|
alpar@389
|
888 |
}
|
alpar@389
|
889 |
|
alpar@389
|
890 |
/// @}
|
alpar@389
|
891 |
|
alpar@389
|
892 |
/// \name Query Functions
|
kpeter@393
|
893 |
/// The results of the preflow algorithm can be obtained using these
|
alpar@389
|
894 |
/// functions.\n
|
kpeter@393
|
895 |
/// Either one of the \ref run() "run*()" functions or one of the
|
kpeter@393
|
896 |
/// \ref startFirstPhase() "start*()" functions should be called
|
kpeter@393
|
897 |
/// before using them.
|
alpar@389
|
898 |
|
alpar@389
|
899 |
///@{
|
alpar@389
|
900 |
|
alpar@389
|
901 |
/// \brief Returns the value of the maximum flow.
|
alpar@389
|
902 |
///
|
alpar@389
|
903 |
/// Returns the value of the maximum flow by returning the excess
|
kpeter@393
|
904 |
/// of the target node. This value equals to the value of
|
kpeter@393
|
905 |
/// the maximum flow already after the first phase of the algorithm.
|
kpeter@393
|
906 |
///
|
kpeter@393
|
907 |
/// \pre Either \ref run() or \ref init() must be called before
|
kpeter@393
|
908 |
/// using this function.
|
kpeter@641
|
909 |
Value flowValue() const {
|
alpar@389
|
910 |
return (*_excess)[_target];
|
alpar@389
|
911 |
}
|
alpar@389
|
912 |
|
kpeter@641
|
913 |
/// \brief Returns the flow value on the given arc.
|
alpar@389
|
914 |
///
|
kpeter@641
|
915 |
/// Returns the flow value on the given arc. This method can
|
kpeter@393
|
916 |
/// be called after the second phase of the algorithm.
|
kpeter@393
|
917 |
///
|
kpeter@393
|
918 |
/// \pre Either \ref run() or \ref init() must be called before
|
kpeter@393
|
919 |
/// using this function.
|
kpeter@641
|
920 |
Value flow(const Arc& arc) const {
|
kpeter@393
|
921 |
return (*_flow)[arc];
|
kpeter@393
|
922 |
}
|
kpeter@393
|
923 |
|
kpeter@393
|
924 |
/// \brief Returns a const reference to the flow map.
|
kpeter@393
|
925 |
///
|
kpeter@393
|
926 |
/// Returns a const reference to the arc map storing the found flow.
|
kpeter@393
|
927 |
/// This method can be called after the second phase of the algorithm.
|
kpeter@393
|
928 |
///
|
kpeter@393
|
929 |
/// \pre Either \ref run() or \ref init() must be called before
|
kpeter@393
|
930 |
/// using this function.
|
kpeter@420
|
931 |
const FlowMap& flowMap() const {
|
kpeter@393
|
932 |
return *_flow;
|
kpeter@393
|
933 |
}
|
kpeter@393
|
934 |
|
kpeter@393
|
935 |
/// \brief Returns \c true when the node is on the source side of the
|
kpeter@393
|
936 |
/// minimum cut.
|
kpeter@393
|
937 |
///
|
kpeter@393
|
938 |
/// Returns true when the node is on the source side of the found
|
kpeter@393
|
939 |
/// minimum cut. This method can be called both after running \ref
|
alpar@389
|
940 |
/// startFirstPhase() and \ref startSecondPhase().
|
kpeter@393
|
941 |
///
|
kpeter@393
|
942 |
/// \pre Either \ref run() or \ref init() must be called before
|
kpeter@393
|
943 |
/// using this function.
|
alpar@389
|
944 |
bool minCut(const Node& node) const {
|
alpar@389
|
945 |
return ((*_level)[node] == _level->maxLevel()) == _phase;
|
alpar@389
|
946 |
}
|
alpar@389
|
947 |
|
kpeter@393
|
948 |
/// \brief Gives back a minimum value cut.
|
alpar@389
|
949 |
///
|
kpeter@393
|
950 |
/// Sets \c cutMap to the characteristic vector of a minimum value
|
kpeter@393
|
951 |
/// cut. \c cutMap should be a \ref concepts::WriteMap "writable"
|
kpeter@393
|
952 |
/// node map with \c bool (or convertible) value type.
|
kpeter@393
|
953 |
///
|
kpeter@393
|
954 |
/// This method can be called both after running \ref startFirstPhase()
|
kpeter@393
|
955 |
/// and \ref startSecondPhase(). The result after the second phase
|
kpeter@393
|
956 |
/// could be slightly different if inexact computation is used.
|
kpeter@393
|
957 |
///
|
kpeter@393
|
958 |
/// \note This function calls \ref minCut() for each node, so it runs in
|
kpeter@559
|
959 |
/// O(n) time.
|
kpeter@393
|
960 |
///
|
kpeter@393
|
961 |
/// \pre Either \ref run() or \ref init() must be called before
|
kpeter@393
|
962 |
/// using this function.
|
alpar@389
|
963 |
template <typename CutMap>
|
alpar@389
|
964 |
void minCutMap(CutMap& cutMap) const {
|
alpar@389
|
965 |
for (NodeIt n(_graph); n != INVALID; ++n) {
|
alpar@389
|
966 |
cutMap.set(n, minCut(n));
|
alpar@389
|
967 |
}
|
alpar@389
|
968 |
}
|
alpar@389
|
969 |
|
alpar@389
|
970 |
/// @}
|
alpar@389
|
971 |
};
|
alpar@389
|
972 |
}
|
alpar@389
|
973 |
|
alpar@389
|
974 |
#endif
|