test/min_cost_flow_test.cc
author deba
Fri, 13 Jun 2008 09:51:45 +0000
changeset 2613 3d14a3449362
parent 2553 bfced05fa852
child 2621 814ba94d9989
permissions -rw-r--r--
Back porting hg commit 81563e019fa4
     1 /* -*- C++ -*-
     2  *
     3  * This file is a part of LEMON, a generic C++ optimization library
     4  *
     5  * Copyright (C) 2003-2008
     6  * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
     7  * (Egervary Research Group on Combinatorial Optimization, EGRES).
     8  *
     9  * Permission to use, modify and distribute this software is granted
    10  * provided that this copyright notice appears in all copies. For
    11  * precise terms see the accompanying LICENSE file.
    12  *
    13  * This software is provided "AS IS" with no warranty of any kind,
    14  * express or implied, and with no claim as to its suitability for any
    15  * purpose.
    16  *
    17  */
    18 
    19 #include <iostream>
    20 #include <fstream>
    21 
    22 #include <lemon/list_graph.h>
    23 #include <lemon/smart_graph.h>
    24 #include <lemon/graph_reader.h>
    25 #include <lemon/dimacs.h>
    26 #include <lemon/time_measure.h>
    27 
    28 #include <lemon/cycle_canceling.h>
    29 #include <lemon/capacity_scaling.h>
    30 #include <lemon/cost_scaling.h>
    31 #include <lemon/network_simplex.h>
    32 
    33 #include <lemon/min_cost_flow.h>
    34 #include <lemon/min_cost_max_flow.h>
    35 
    36 #include "test_tools.h"
    37 
    38 using namespace lemon;
    39 
    40 // Checks the feasibility of a flow
    41 template < typename Graph, typename LowerMap, typename CapacityMap,
    42            typename SupplyMap, typename FlowMap >
    43 bool checkFlow( const Graph& gr,
    44                 const LowerMap& lower, const CapacityMap& upper,
    45                 const SupplyMap& supply, const FlowMap& flow )
    46 {
    47   GRAPH_TYPEDEFS(typename Graph);
    48   for (EdgeIt e(gr); e != INVALID; ++e)
    49     if (flow[e] < lower[e] || flow[e] > upper[e]) return false;
    50 
    51   for (NodeIt n(gr); n != INVALID; ++n) {
    52     typename SupplyMap::Value sum = 0;
    53     for (OutEdgeIt e(gr, n); e != INVALID; ++e)
    54       sum += flow[e];
    55     for (InEdgeIt e(gr, n); e != INVALID; ++e)
    56       sum -= flow[e];
    57     if (sum != supply[n]) return false;
    58   }
    59 
    60   return true;
    61 }
    62 
    63 // Checks the optimalitiy of a flow
    64 template < typename Graph, typename LowerMap, typename CapacityMap,
    65            typename CostMap, typename FlowMap, typename PotentialMap >
    66 bool checkOptimality( const Graph& gr, const LowerMap& lower,
    67                       const CapacityMap& upper, const CostMap& cost,
    68                       const FlowMap& flow, const PotentialMap& pi )
    69 {
    70   GRAPH_TYPEDEFS(typename Graph);
    71   // Checking the Complementary Slackness optimality condition
    72   bool opt = true;
    73   for (EdgeIt e(gr); e != INVALID; ++e) {
    74     typename CostMap::Value red_cost =
    75       cost[e] + pi[gr.source(e)] - pi[gr.target(e)];
    76     opt = red_cost == 0 ||
    77           (red_cost > 0 && flow[e] == lower[e]) ||
    78           (red_cost < 0 && flow[e] == upper[e]);
    79     if (!opt) break;
    80   }
    81   return opt;
    82 }
    83 
    84 // Runs a minimum cost flow algorithm and checks the results
    85 template < typename MinCostFlowImpl, typename Graph,
    86            typename LowerMap, typename CapacityMap,
    87            typename CostMap, typename SupplyMap >
    88 void checkMcf( std::string test_id,
    89                const MinCostFlowImpl& mcf, const Graph& gr,
    90                const LowerMap& lower, const CapacityMap& upper,
    91                const CostMap& cost, const SupplyMap& supply,
    92                bool mcf_result, bool result,
    93                typename CostMap::Value total )
    94 {
    95   check(mcf_result == result, "Wrong result " + test_id);
    96   if (result) {
    97     check(checkFlow(gr, lower, upper, supply, mcf.flowMap()),
    98           "The flow is not feasible " + test_id);
    99     check(mcf.totalCost() == total, "The flow is not optimal " + test_id);
   100     check(checkOptimality(gr, lower, upper, cost, mcf.flowMap(), mcf.potentialMap()),
   101           "Wrong potentials " + test_id);
   102   }
   103 }
   104 
   105 int main()
   106 {
   107   // Various tests on a small graph
   108   {
   109     typedef ListGraph Graph;
   110     GRAPH_TYPEDEFS(ListGraph);
   111 
   112     // Reading the test graph
   113     Graph gr;
   114     Graph::EdgeMap<int> c(gr), l1(gr), l2(gr), u(gr);
   115     Graph::NodeMap<int> s1(gr), s2(gr), s3(gr);
   116     Node v, w;
   117 
   118     std::string fname;
   119     if(getenv("srcdir"))
   120       fname = std::string(getenv("srcdir"));
   121     else fname = ".";
   122     fname += "/test/min_cost_flow_test.lgf";
   123 
   124     std::ifstream input(fname.c_str());
   125     check(input, "Input file '" << fname << "' not found");
   126     GraphReader<Graph>(input, gr).
   127       readEdgeMap("cost", c).
   128       readEdgeMap("capacity", u).
   129       readEdgeMap("lower1", l1).
   130       readEdgeMap("lower2", l2).
   131       readNodeMap("supply1", s1).
   132       readNodeMap("supply2", s2).
   133       readNodeMap("supply3", s3).
   134       readNode("source", v).
   135       readNode("target", w).
   136       run();
   137     input.close();
   138 
   139     // Testing CapacityScaling (scaling enabled)
   140     {
   141       CapacityScaling<Graph> mcf1(gr,u,c,s1);        checkMcf("#A1",mcf1,gr,l1,u,c,s1,mcf1.run(),true,    0);
   142       CapacityScaling<Graph> mcf2(gr,u,c,s2);        checkMcf("#A2",mcf2,gr,l1,u,c,s2,mcf2.run(),true, 5240);
   143       CapacityScaling<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#A3",mcf3,gr,l1,u,c,s3,mcf3.run(),true, 7620);
   144       CapacityScaling<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#A4",mcf4,gr,l2,u,c,s1,mcf4.run(),false,   0);
   145       CapacityScaling<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#A5",mcf5,gr,l2,u,c,s2,mcf5.run(),true, 5970);
   146       CapacityScaling<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#A6",mcf6,gr,l2,u,c,s3,mcf6.run(),true, 8010);
   147     }
   148     // Testing CapacityScaling (scaling disabled)
   149     {
   150       CapacityScaling<Graph> mcf1(gr,u,c,s1);        checkMcf("#B1",mcf1,gr,l1,u,c,s1,mcf1.run(false),true,    0);
   151       CapacityScaling<Graph> mcf2(gr,u,c,s2);        checkMcf("#B2",mcf2,gr,l1,u,c,s2,mcf2.run(false),true, 5240);
   152       CapacityScaling<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#B3",mcf3,gr,l1,u,c,s3,mcf3.run(false),true, 7620);
   153       CapacityScaling<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#B4",mcf4,gr,l2,u,c,s1,mcf4.run(false),false,   0);
   154       CapacityScaling<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#B5",mcf5,gr,l2,u,c,s2,mcf5.run(false),true, 5970);
   155       CapacityScaling<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#B6",mcf6,gr,l2,u,c,s3,mcf6.run(false),true, 8010);
   156     }
   157 
   158     // Testing CostScaling
   159     {
   160       CostScaling<Graph> mcf1(gr,u,c,s1);        checkMcf("#C1",mcf1,gr,l1,u,c,s1,mcf1.run(),true,    0);
   161       CostScaling<Graph> mcf2(gr,u,c,s2);        checkMcf("#C2",mcf2,gr,l1,u,c,s2,mcf2.run(),true, 5240);
   162       CostScaling<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#C3",mcf3,gr,l1,u,c,s3,mcf3.run(),true, 7620);
   163       CostScaling<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#C4",mcf4,gr,l2,u,c,s1,mcf4.run(),false,   0);
   164       CostScaling<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#C5",mcf5,gr,l2,u,c,s2,mcf5.run(),true, 5970);
   165       CostScaling<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#C6",mcf6,gr,l2,u,c,s3,mcf6.run(),true, 8010);
   166     }
   167 
   168     // Testing NetworkSimplex (with the default pivot rule)
   169     {
   170       NetworkSimplex<Graph> mcf1(gr,u,c,s1);        checkMcf("#D1",mcf1,gr,l1,u,c,s1,mcf1.run(),true,    0);
   171       NetworkSimplex<Graph> mcf2(gr,u,c,s2);        checkMcf("#D2",mcf2,gr,l1,u,c,s2,mcf2.run(),true, 5240);
   172       NetworkSimplex<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#D3",mcf3,gr,l1,u,c,s3,mcf3.run(),true, 7620);
   173       NetworkSimplex<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#D4",mcf4,gr,l2,u,c,s1,mcf4.run(),false,   0);
   174       NetworkSimplex<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#D5",mcf5,gr,l2,u,c,s2,mcf5.run(),true, 5970);
   175       NetworkSimplex<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#D6",mcf6,gr,l2,u,c,s3,mcf6.run(),true, 8010);
   176     }
   177     // Testing NetworkSimplex (with FIRST_ELIGIBLE_PIVOT)
   178     {
   179       NetworkSimplex<Graph>::PivotRuleEnum pr = NetworkSimplex<Graph>::FIRST_ELIGIBLE_PIVOT;
   180       NetworkSimplex<Graph> mcf1(gr,u,c,s1);        checkMcf("#E1",mcf1,gr,l1,u,c,s1,mcf1.run(pr),true,    0);
   181       NetworkSimplex<Graph> mcf2(gr,u,c,s2);        checkMcf("#E2",mcf2,gr,l1,u,c,s2,mcf2.run(pr),true, 5240);
   182       NetworkSimplex<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#E3",mcf3,gr,l1,u,c,s3,mcf3.run(pr),true, 7620);
   183       NetworkSimplex<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#E4",mcf4,gr,l2,u,c,s1,mcf4.run(pr),false,   0);
   184       NetworkSimplex<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#E5",mcf5,gr,l2,u,c,s2,mcf5.run(pr),true, 5970);
   185       NetworkSimplex<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#E6",mcf6,gr,l2,u,c,s3,mcf6.run(pr),true, 8010);
   186     }
   187     // Testing NetworkSimplex (with BEST_ELIGIBLE_PIVOT)
   188     {
   189       NetworkSimplex<Graph>::PivotRuleEnum pr = NetworkSimplex<Graph>::BEST_ELIGIBLE_PIVOT;
   190       NetworkSimplex<Graph> mcf1(gr,u,c,s1);        checkMcf("#F1",mcf1,gr,l1,u,c,s1,mcf1.run(pr),true,    0);
   191       NetworkSimplex<Graph> mcf2(gr,u,c,s2);        checkMcf("#F2",mcf2,gr,l1,u,c,s2,mcf2.run(pr),true, 5240);
   192       NetworkSimplex<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#F3",mcf3,gr,l1,u,c,s3,mcf3.run(pr),true, 7620);
   193       NetworkSimplex<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#F4",mcf4,gr,l2,u,c,s1,mcf4.run(pr),false,   0);
   194       NetworkSimplex<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#F5",mcf5,gr,l2,u,c,s2,mcf5.run(pr),true, 5970);
   195       NetworkSimplex<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#F6",mcf6,gr,l2,u,c,s3,mcf6.run(pr),true, 8010);
   196     }
   197     // Testing NetworkSimplex (with BLOCK_SEARCH_PIVOT)
   198     {
   199       NetworkSimplex<Graph>::PivotRuleEnum pr = NetworkSimplex<Graph>::BLOCK_SEARCH_PIVOT;
   200       NetworkSimplex<Graph> mcf1(gr,u,c,s1);        checkMcf("#G1",mcf1,gr,l1,u,c,s1,mcf1.run(pr),true,    0);
   201       NetworkSimplex<Graph> mcf2(gr,u,c,s2);        checkMcf("#G2",mcf2,gr,l1,u,c,s2,mcf2.run(pr),true, 5240);
   202       NetworkSimplex<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#G3",mcf3,gr,l1,u,c,s3,mcf3.run(pr),true, 7620);
   203       NetworkSimplex<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#G4",mcf4,gr,l2,u,c,s1,mcf4.run(pr),false,   0);
   204       NetworkSimplex<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#G5",mcf5,gr,l2,u,c,s2,mcf5.run(pr),true, 5970);
   205       NetworkSimplex<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#G6",mcf6,gr,l2,u,c,s3,mcf6.run(pr),true, 8010);
   206     }
   207     // Testing NetworkSimplex (with LIMITED_SEARCH_PIVOT)
   208     {
   209       NetworkSimplex<Graph>::PivotRuleEnum pr = NetworkSimplex<Graph>::LIMITED_SEARCH_PIVOT;
   210       NetworkSimplex<Graph> mcf1(gr,u,c,s1);        checkMcf("#H1",mcf1,gr,l1,u,c,s1,mcf1.run(pr),true,    0);
   211       NetworkSimplex<Graph> mcf2(gr,u,c,s2);        checkMcf("#H2",mcf2,gr,l1,u,c,s2,mcf2.run(pr),true, 5240);
   212       NetworkSimplex<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#H3",mcf3,gr,l1,u,c,s3,mcf3.run(pr),true, 7620);
   213       NetworkSimplex<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#H4",mcf4,gr,l2,u,c,s1,mcf4.run(pr),false,   0);
   214       NetworkSimplex<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#H5",mcf5,gr,l2,u,c,s2,mcf5.run(pr),true, 5970);
   215       NetworkSimplex<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#H6",mcf6,gr,l2,u,c,s3,mcf6.run(pr),true, 8010);
   216     }
   217     // Testing NetworkSimplex (with CANDIDATE_LIST_PIVOT)
   218     {
   219       NetworkSimplex<Graph>::PivotRuleEnum pr = NetworkSimplex<Graph>::CANDIDATE_LIST_PIVOT;
   220       NetworkSimplex<Graph> mcf1(gr,u,c,s1);        checkMcf("#I1",mcf1,gr,l1,u,c,s1,mcf1.run(pr),true,    0);
   221       NetworkSimplex<Graph> mcf2(gr,u,c,s2);        checkMcf("#I2",mcf2,gr,l1,u,c,s2,mcf2.run(pr),true, 5240);
   222       NetworkSimplex<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#I3",mcf3,gr,l1,u,c,s3,mcf3.run(pr),true, 7620);
   223       NetworkSimplex<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#I4",mcf4,gr,l2,u,c,s1,mcf4.run(pr),false,   0);
   224       NetworkSimplex<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#I5",mcf5,gr,l2,u,c,s2,mcf5.run(pr),true, 5970);
   225       NetworkSimplex<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#I6",mcf6,gr,l2,u,c,s3,mcf6.run(pr),true, 8010);
   226     }
   227 
   228     // Testing CycleCanceling (with BellmanFord)
   229     {
   230       CycleCanceling<Graph> mcf1(gr,u,c,s1);        checkMcf("#J1",mcf1,gr,l1,u,c,s1,mcf1.run(),true,    0);
   231       CycleCanceling<Graph> mcf2(gr,u,c,s2);        checkMcf("#J2",mcf2,gr,l1,u,c,s2,mcf2.run(),true, 5240);
   232       CycleCanceling<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#J3",mcf3,gr,l1,u,c,s3,mcf3.run(),true, 7620);
   233       CycleCanceling<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#J4",mcf4,gr,l2,u,c,s1,mcf4.run(),false,   0);
   234       CycleCanceling<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#J5",mcf5,gr,l2,u,c,s2,mcf5.run(),true, 5970);
   235       CycleCanceling<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#J6",mcf6,gr,l2,u,c,s3,mcf6.run(),true, 8010);
   236     }
   237     // Testing CycleCanceling (with MinMeanCycle)
   238     {
   239       CycleCanceling<Graph> mcf1(gr,u,c,s1);        checkMcf("#K1",mcf1,gr,l1,u,c,s1,mcf1.run(true),true,    0);
   240       CycleCanceling<Graph> mcf2(gr,u,c,s2);        checkMcf("#K2",mcf2,gr,l1,u,c,s2,mcf2.run(true),true, 5240);
   241       CycleCanceling<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#K3",mcf3,gr,l1,u,c,s3,mcf3.run(true),true, 7620);
   242       CycleCanceling<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#K4",mcf4,gr,l2,u,c,s1,mcf4.run(true),false,   0);
   243       CycleCanceling<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#K5",mcf5,gr,l2,u,c,s2,mcf5.run(true),true, 5970);
   244       CycleCanceling<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#K6",mcf6,gr,l2,u,c,s3,mcf6.run(true),true, 8010);
   245     }
   246 
   247     // Testing MinCostFlow
   248     {
   249       MinCostFlow<Graph> mcf1(gr,u,c,s1);        checkMcf("#L1",mcf1,gr,l1,u,c,s1,mcf1.run(),true,    0);
   250       MinCostFlow<Graph> mcf2(gr,u,c,s2);        checkMcf("#L2",mcf2,gr,l1,u,c,s2,mcf2.run(),true, 5240);
   251       MinCostFlow<Graph> mcf3(gr,u,c,v,w,27);    checkMcf("#L3",mcf3,gr,l1,u,c,s3,mcf3.run(),true, 7620);
   252       MinCostFlow<Graph> mcf4(gr,l2,u,c,s1);     checkMcf("#L4",mcf4,gr,l2,u,c,s1,mcf4.run(),false,   0);
   253       MinCostFlow<Graph> mcf5(gr,l2,u,c,s2);     checkMcf("#L5",mcf5,gr,l2,u,c,s2,mcf5.run(),true, 5970);
   254       MinCostFlow<Graph> mcf6(gr,l2,u,c,v,w,27); checkMcf("#L6",mcf6,gr,l2,u,c,s3,mcf6.run(),true, 8010);
   255     }
   256 
   257     // Testing MinCostMaxFlow
   258     {
   259       MinCostMaxFlow<Graph> mcmf(gr,u,c,v,w);
   260       mcmf.run();
   261       checkMcf("#M1",mcmf,gr,l1,u,c,s3,true,true,7620);
   262     }
   263   }
   264 
   265   // Benchmark test on a DIMACS network
   266   {
   267     typedef SmartGraph Graph;
   268     GRAPH_TYPEDEFS(SmartGraph);
   269 
   270     // Reading the test graph
   271     Graph graph;
   272     Graph::EdgeMap<int> lower(graph), capacity(graph), cost(graph);
   273     Graph::NodeMap<int> supply(graph);
   274 
   275     std::string fname;
   276     if(getenv("srcdir"))
   277       fname = std::string(getenv("srcdir"));
   278     else fname = ".";
   279     fname += "/test/min_cost_flow_test.net";
   280 
   281     std::ifstream input(fname.c_str());
   282     check(input, "Input file '" << fname << "' not found");
   283     readDimacs(input, graph, lower, capacity, cost, supply);
   284     input.close();
   285 
   286     // NetworkSimplex
   287     {
   288       Timer t;
   289       NetworkSimplex<Graph> mcf(graph, lower, capacity, cost, supply);
   290       bool res = mcf.run();
   291       t.stop();
   292       checkMcf("#T3", mcf, graph, lower, capacity, cost, supply, res, true, 196587626);
   293       std::cout << "NetworkSimplex";
   294       std::cout << std::endl << t << std::endl;
   295     }
   296     // CapacityScaling
   297     {
   298       Timer t;
   299       CapacityScaling<Graph> mcf(graph, lower, capacity, cost, supply);
   300       bool res = mcf.run();
   301       t.stop();
   302       checkMcf("#T1", mcf, graph, lower, capacity, cost, supply, res, true, 196587626);
   303       std::cout << "CapacityScaling";
   304       std::cout << std::endl << t << std::endl;
   305     }
   306     // CostScaling
   307     {
   308       Timer t;
   309       CostScaling<Graph> mcf(graph, lower, capacity, cost, supply);
   310       bool res = mcf.run();
   311       t.stop();
   312       checkMcf("#T2", mcf, graph, lower, capacity, cost, supply, res, true, 196587626);
   313       std::cout << "CostScaling";
   314       std::cout << std::endl << t << std::endl;
   315     }
   316     // CycleCanceling
   317     {
   318       Timer t;
   319       CycleCanceling<Graph> mcf(graph, lower, capacity, cost, supply);
   320       bool res = mcf.run();
   321       t.stop();
   322       checkMcf("#T4", mcf, graph, lower, capacity, cost, supply, res, true, 196587626);
   323       std::cout << "CycleCanceling";
   324       std::cout << std::endl << t << std::endl;
   325     }
   326   }
   327 
   328   return 0;
   329 }