@ -1,12 +1,11 @@
# include <algorithm>
# include <algorithm>
# include <iostream>
# include <iostream>
# include <queue>
# include <queue>
# include <stack>
# include <sstream>
# include <sstream>
# include <climits>
# include "Graph.h"
# include "Graph.h"
# include "util/GraphParser.h"
# include "util/GraphParser.h"
namespace data {
namespace data {
Graph : : Graph ( bool stdout_output , bool file_output , std : : string output_filename , bool verbose_max_flow , bool min_cut , int verbosity )
Graph : : Graph ( bool stdout_output , bool file_output , std : : string output_filename , bool verbose_max_flow , bool min_cut , int verbosity )
: m_file_output ( file_output ) , m_output_file_name ( output_filename ) , m_verbose_max_flow ( verbose_max_flow ) , m_min_cut ( min_cut ) , m_verbosity ( verbosity ) {
: m_file_output ( file_output ) , m_output_file_name ( output_filename ) , m_verbose_max_flow ( verbose_max_flow ) , m_min_cut ( min_cut ) , m_verbosity ( verbosity ) {
@ -33,6 +32,7 @@ namespace data {
for ( auto const & arc : m_arc_list ) {
for ( auto const & arc : m_arc_list ) {
m_capapcities . at ( arc . start - 1 ) . at ( arc . end - 1 ) + = arc . capacity ;
m_capapcities . at ( arc . start - 1 ) . at ( arc . end - 1 ) + = arc . capacity ;
}
}
m_network = m_capapcities ;
}
}
void Graph : : initOstream ( ) {
void Graph : : initOstream ( ) {
@ -43,7 +43,7 @@ namespace data {
}
}
}
}
void Graph : : maxFlowDinic ( ) {
int Graph : : maxFlowDinic ( ) {
std : : chrono : : steady_clock : : time_point start = std : : chrono : : steady_clock : : now ( ) ;
std : : chrono : : steady_clock : : time_point start = std : : chrono : : steady_clock : : now ( ) ;
printInformation ( ) ;
printInformation ( ) ;
do {
do {
@ -53,6 +53,7 @@ namespace data {
if ( m_verbose_max_flow ) printMaxFlowInformation ( ) ;
if ( m_verbose_max_flow ) printMaxFlowInformation ( ) ;
if ( m_min_cut ) printMinCut ( ) ;
if ( m_min_cut ) printMinCut ( ) ;
if ( m_verbosity > = 1 ) printComputationStatistics ( start , std : : chrono : : steady_clock : : now ( ) ) ;
if ( m_verbosity > = 1 ) printComputationStatistics ( start , std : : chrono : : steady_clock : : now ( ) ) ;
return m_max_flow ;
}
}
int Graph : : findAugmentingPaths ( ) {
int Graph : : findAugmentingPaths ( ) {
@ -135,6 +136,108 @@ namespace data {
if ( m_verbosity > = 1 ) m_num_level_graphs_built + + ;
if ( m_verbosity > = 1 ) m_num_level_graphs_built + + ;
}
}
void Graph : : hasUniqueMaxFlow ( ) {
* m_ofstream < < " \n Checking uniqueness of maximum flow: \n " ;
CapacityMatrix residualGraph = m_capapcities ;
for ( uint row = 0 ; row < m_flow . size ( ) ; row + + ) {
for ( uint i = 0 ; i < m_flow . at ( 0 ) . size ( ) ; i + + ) {
residualGraph . at ( i ) . at ( row ) + = m_flow . at ( row ) . at ( i ) ;
}
}
int visited [ m_num_vertices ] ;
std : : stack < int > * recursive_stack = new std : : stack < int > ( ) ;
bool found_cycle = false ;
for ( uint i = 0 ; i < m_num_vertices ; i + + ) {
visited [ i ] = NOT_PROCESSED ;
}
for ( uint i = 0 ; i < m_num_vertices ; i + + ) {
if ( visited [ i ] = = NOT_PROCESSED ) {
visited [ i ] = ON_STACK ;
recursive_stack = new std : : stack < int > ( ) ;
recursive_stack - > push ( i ) ;
isResidualGraphCyclic ( residualGraph , visited , INVALID_VERTEX , recursive_stack , found_cycle ) ;
}
}
if ( ! found_cycle ) * m_ofstream < < " The max flow is unique! \n " ;
}
void Graph : : isResidualGraphCyclic ( const CapacityMatrix & residual_graph , int * visited , const int previous , std : : stack < int > * recursive_stack , bool & found_cycle ) {
int top = recursive_stack - > top ( ) ;
for ( uint next = 0 ; next < residual_graph . at ( top ) . size ( ) ; next + + ) {
if ( next = = previous ) continue ;
if ( residual_graph . at ( top ) . at ( next ) = = 0 ) continue ;
//std::cout << "prev, top, next, capacity: " << previous +1 << ", " << top +1 << ", " << next+1 << ", " << residual_graph.at(top).at(next) <<std::endl;
if ( visited [ next ] = = NOT_PROCESSED | | visited [ next ] = = PROCESSED ) {
recursive_stack - > push ( next ) ;
visited [ next ] = ON_STACK ;
isResidualGraphCyclic ( residual_graph , visited , top , recursive_stack , found_cycle ) ;
} else if ( visited [ next ] = = ON_STACK ) {
if ( recursive_stack - > size ( ) > = 3 ) {
found_cycle = true ;
printCycle ( residual_graph , recursive_stack ) ;
}
}
}
visited [ top ] = PROCESSED ;
recursive_stack - > pop ( ) ;
}
void Graph : : printCycle ( const CapacityMatrix residual_matrix , std : : stack < int > * stack ) {
int first , previous , current ;
std : : stack < int > print_stack ;
while ( stack - > size ( ) ! = 0 ) {
print_stack . push ( stack - > top ( ) ) ;
stack - > pop ( ) ;
}
previous = print_stack . top ( ) ;
first = previous ;
print_stack . pop ( ) ;
* m_ofstream < < previous + 1 ;
int min_capacity = INT_MAX ;
while ( print_stack . size ( ) ! = 0 ) {
current = print_stack . top ( ) ;
* m_ofstream < < " -> " < < current + 1 ;
if ( residual_matrix . at ( previous ) . at ( current ) < min_capacity ) min_capacity = residual_matrix . at ( previous ) . at ( current ) ;
print_stack . pop ( ) ;
stack - > push ( current ) ;
previous = current ;
}
* m_ofstream < < " -> " < < first + 1 ;
if ( residual_matrix . at ( current ) . at ( first ) < min_capacity ) min_capacity = residual_matrix . at ( current ) . at ( first ) ;
* m_ofstream < < " , where " < < min_capacity < < " unit " ;
if ( min_capacity > 1 ) * m_ofstream < < " s " ;
* m_ofstream < < " of flow could be shifted. " < < std : : endl ;
}
void Graph : : hasUniqueMinCut ( ) {
* m_ofstream < < " \n Checking uniqueness of minimum cut: \n " ;
std : : vector < Arc > * cut_edges = new std : : vector < Arc > ( ) ;
computeMinCut ( nullptr , nullptr , cut_edges ) ;
bool found_another_min_cut = false ;
for ( auto const & arc : * cut_edges ) {
Graph augmented_network = * this ;
augmented_network . incrementArcCapacity ( arc . start - 1 , arc . end - 1 ) ;
augmented_network . resetNetwork ( ) ;
augmented_network . disableOutput ( ) ;
int augmented_max_flow = augmented_network . maxFlowDinic ( ) ;
augmented_network . enableOutput ( ) ;
if ( augmented_max_flow = = m_max_flow ) {
found_another_min_cut = true ;
* m_ofstream < < " Found another minimum cut after incrementing ( " < < arc . start < < " , " < < arc . end < < " ) with a flow value of " < < augmented_max_flow < < " . " < < std : : endl ;
augmented_network . printMinCut ( ) ;
//augmented_network.hasUniqueMinCut();
}
}
if ( ! found_another_min_cut ) {
* m_ofstream < < " The minimum cut is unique! \n " ;
}
}
void Graph : : printInformation ( ) const {
void Graph : : printInformation ( ) const {
auto m_source = std : : find_if ( m_vertices . begin ( ) , m_vertices . end ( ) , [ this ] ( const Vertex & v ) { return ( v . getID ( ) = = m_source_id ) ; } ) ;
auto m_source = std : : find_if ( m_vertices . begin ( ) , m_vertices . end ( ) , [ this ] ( const Vertex & v ) { return ( v . getID ( ) = = m_source_id ) ; } ) ;
auto m_sink = std : : find_if ( m_vertices . begin ( ) , m_vertices . end ( ) , [ this ] ( const Vertex & v ) { return ( v . getID ( ) = = m_sink_id ) ; } ) ;
auto m_sink = std : : find_if ( m_vertices . begin ( ) , m_vertices . end ( ) , [ this ] ( const Vertex & v ) { return ( v . getID ( ) = = m_sink_id ) ; } ) ;
@ -162,15 +265,41 @@ namespace data {
}
}
}
}
void Graph : : printMinCut ( ) const {
std : : vector < std : : string > min_cut , complement ;
void Graph : : computeMinCut ( std : : vector < Vertex > * source_vertices , std : : vector < Vertex > * sink_vertices , std : : vector < Arc > * cut_edges ) const {
if ( ! source_vertices ) source_vertices = new std : : vector < Vertex > ( ) ;
if ( ! sink_vertices ) sink_vertices = new std : : vector < Vertex > ( ) ;
for ( auto const & vertex : m_vertices ) {
for ( auto const & vertex : m_vertices ) {
if ( vertex . getLevel ( ) ! = UNDEF_LEVEL ) {
if ( vertex . getLevel ( ) ! = UNDEF_LEVEL ) {
min_cut . push_back ( std : : to_string ( vertex . getID ( ) ) ) ;
source_vertices - > push_back ( vertex . getID ( ) ) ;
} else {
} else {
complement . push_back ( std : : to_string ( vertex . getID ( ) ) ) ;
sink_vertices - > push_back ( vertex . getID ( ) ) ;
}
}
}
}
if ( cut_edges ) {
for ( auto const source : * source_vertices ) {
for ( auto const sink : * sink_vertices ) {
int capacity = m_network . at ( source . getID ( ) - 1 ) . at ( sink . getID ( ) - 1 ) ;
if ( capacity > 0 ) {
cut_edges - > push_back ( { source . getID ( ) , sink . getID ( ) , capacity , capacity , 0 } ) ;
}
}
}
}
}
void Graph : : printMinCut ( ) const {
std : : vector < Arc > * arcs = new std : : vector < Arc > ( ) ;
std : : vector < Vertex > * source_vertices = new std : : vector < Vertex > ( ) ;
std : : vector < Vertex > * sink_vertices = new std : : vector < Vertex > ( ) ;
computeMinCut ( source_vertices , sink_vertices , arcs ) ;
std : : vector < std : : string > min_cut , complement ;
for ( auto const & vertex : * source_vertices ) {
min_cut . push_back ( std : : to_string ( vertex . getID ( ) ) ) ;
}
for ( auto const & vertex : * sink_vertices ) {
complement . push_back ( std : : to_string ( vertex . getID ( ) ) ) ;
}
* m_ofstream < < " Min Cut X: { " ;
* m_ofstream < < " Min Cut X: { " ;
bool first = true ;
bool first = true ;
for ( auto const & v : min_cut ) {
for ( auto const & v : min_cut ) {
@ -196,4 +325,42 @@ namespace data {
}
}
* m_ofstream < < " #recursive buildPath calls: " < < m_num_build_path_calls < < " \n " ;
* m_ofstream < < " #recursive buildPath calls: " < < m_num_build_path_calls < < " \n " ;
}
}
void Graph : : incrementArcCapacity ( const int source , const int sink ) {
m_network . at ( source ) . at ( sink ) + + ;
}
void Graph : : resetNetwork ( ) {
m_max_flow = 0 ;
m_capapcities = m_network ;
}
void Graph : : disableOutput ( ) {
m_ofstream - > setstate ( std : : ios_base : : badbit ) ;
}
void Graph : : enableOutput ( ) {
m_ofstream - > clear ( ) ;
}
void Graph : : printMatrices ( ) const {
//for(auto const row : m_flow) {
// for(auto const i : row) {
// std::cout << i << " ";
// } std::cout << std::endl;
//}
std : : cout < < std : : endl ;
for ( auto const row : m_network ) {
for ( auto const i : row ) {
std : : cout < < i < < " " ;
} std : : cout < < std : : endl ;
}
std : : cout < < std : : endl ;
for ( auto const row : m_capapcities ) {
for ( auto const i : row ) {
std : : cout < < i < < " " ;
} std : : cout < < std : : endl ;
}
std : : cout < < std : : endl ;
}
}
}