6

I want to use boost's dijkstra algorithm (since I'm using boost in other parts of my program). The problem I'm having is adding custom objects (I believe they are referred to as property) to the adjacency_list.

Essentially I have a custom edge class that maintains all sorts of information regarding the edge and the vertices that are connected through it. I want to store my custom data object with the edge properties that are required by the adjaceny_list

I've successfully implemented the toy example that boost provides. I've tried to use custom properties to no avail (boost example, boost properties). I'm fine with just encapsulating my VEdge data structure in a struct or something, I just need to be able to retrieve it. But I haven't been able to figure out how to include my custom data structure into the boost adjaceny_list structure.

In my case I have the following program:

Main.cpp:

#include <iostream>
#include <fstream>
#include "dijkstra.h"
#include <vector>

int
main(int, char *[])
{
  // Generate the vector of edges from elsewhere in the program
  std::vector<VEdge*> edges; //someclass.get_edges();

  td* test = new td(edges);
  test->run_d();

  test->print_path();

  return EXIT_SUCCESS;
}

Dijkstra.cpp:

#include <iostream>
#include <fstream>
#include "dijkstra.h"

using namespace boost;

td::td() {
    kNumArcs = sizeof(kEdgeArray) / sizeof(Edge);
    kNumNodes = 5;
}

td::td(std::vector<VEdge*> edges) {
    // add edges to the edge property here
    for(VEdge* e : edges) {
        // for each edge, add to the kEdgeArray variable in some way
        // The boost example forces the input to be an array of edge_property type.  
        // So here is where I will convert my raw VEdge data structure to 
        // the custom edge_property that I am struggling to understand how to create.
    }
    kNumArcs = sizeof(kEdgeArray) / sizeof(Edge);
    kNumNodes = 5;
}

void td::run_d() {
    kGraph = graph_t(kEdgeArray, kEdgeArray + kNumArcs, kWeights, kNumNodes);

    kWeightMap = get(edge_weight, kGraph);
    kP = std::vector<vertex_descriptor >(num_vertices(kGraph));
    kD = std::vector<int>(num_vertices(kGraph));
    kS = vertex(A, kGraph);

    dijkstra_shortest_paths(kGraph, kS,
            predecessor_map(boost::make_iterator_property_map(kP.begin(), get(boost::vertex_index, kGraph))).
                    distance_map(boost::make_iterator_property_map(kD.begin(), get(boost::vertex_index, kGraph))));
}

void td::print_path() {
    std::cout << "distances and parents:" << std::endl;
    graph_traits < graph_t >::vertex_iterator vi, vend;
    for (boost::tie(vi, vend) = vertices(kGraph); vi != vend; ++vi) {
        std::cout << "distance(" << kName[*vi] << ") = " << kD[*vi] << ", ";
        std::cout << "parent(" << kName[*vi] << ") = " << kName[kP[*vi]] << std::
        endl;
    }
}

void td::generate_dot_file() {
    std::cout << std::endl;

    std::ofstream dot_file("figs/dijkstra-eg.dot");

    dot_file << "digraph D {\n"
            << "  rankdir=LR\n"
            << "  size=\"4,3\"\n"
            << "  ratio=\"fill\"\n"
            << "  edge[style=\"bold\"]\n" << "  node[shape=\"circle\"]\n";

    graph_traits < graph_t >::edge_iterator ei, ei_end;
    for (boost::tie(ei, ei_end) = edges(kGraph); ei != ei_end; ++ei) {
        graph_traits < graph_t >::edge_descriptor e = *ei;
        graph_traits < graph_t >::vertex_descriptor
                u = source(e, kGraph), v = target(e, kGraph);
        dot_file << kName[u] << " -> " << kName[v]
                << "[label=\"" << get(kWeightMap, e) << "\"";
        if (kP[v] == u)
            dot_file << ", color=\"black\"";
        else
            dot_file << ", color=\"grey\"";
        dot_file << "]";
    }
    dot_file << "}";
}

Dijkstra.h:

#ifndef _TEMPD_H_
#define _TEMPD_H_

#pragma once

#include <boost/config.hpp>
#include <boost/graph/graph_traits.hpp>
#include <boost/graph/adjacency_list.hpp>
#include <boost/graph/dijkstra_shortest_paths.hpp>
#include <boost/property_map/property_map.hpp>

using namespace boost;

typedef adjacency_list < listS, vecS, directedS,
        no_property, property < edge_weight_t, int > > graph_t;
typedef graph_traits < graph_t >::vertex_descriptor vertex_descriptor;
typedef std::pair<int, int> Edge;

struct VEdge{
    // custom variables here
    VNode start;
    VNode end;
    int weight;
    int id;
    // other irrelevant data pertinent to my program that must be preserved
};

struct VNode {
    // custom variables here
    int x;
    int y;
    int id;
    // other irrelevant data pertinent to my program that must be preserved
}

enum nodes { A, B, C, D, E };

class td {
public:
    td();
    td(std::vector<VEdge*>);
    ~td();

    void run_d();

    void print_path();
    void generate_dot_file();
private:
    Edge kEdgeArray[9] = { Edge(A, C), Edge(B, B), Edge(B, D), Edge(B, E),
            Edge(C, B), Edge(C, D), Edge(D, E), Edge(E, A), Edge(E, B)
    };
    char kName[5] = {'A','B','C','D','E'};
    int kWeights[9] = { 1, 2, 1, 2, 7, 3, 1, 1, 1 };
    int kNumArcs;
    int kNumNodes;
    vertex_descriptor kS;
    graph_t kGraph;
    std::vector<int> kD;
    std::vector<vertex_descriptor> kP;
    property_map<graph_t, edge_weight_t>::type kWeightMap;
};
#endif

I know my example is a bit contrived, but it communicates what I'm trying to accomplish. I know I need a custom data structure for my edge_descriptor which gets sent to the graph_t typedef.

So I'm looking to alter my Dijkstra.h file to look something like this:

struct vertex_label_t {vertex_property_tag kind;};
struct edge_label_t {edge_property_tag kind;};

typedef property <vertex_custom_t, VNode*>,
    property <vertex_label_t, string>,
        property <vertex_root_t, ing> > > vertex_p;

typedef property <edge_custom_t, VEdge*>,
    property <edge_label_t, string > > edge_p;

typedef adjacency_list < listS, vecS, directedS,
        vertex_p, edge_p > graph_t;
typedef graph_traits < graph_t >::vertex_descriptor vertex_descriptor;
9
  • you seem to suggest that edges are all you need to construct the graph. Wouldn't it be handy to include the way in which they do this? Currently VEdge is an empty struct, and not even the comments make it clear how they would refer to the vertices they connect.
    – sehe
    Commented Mar 10, 2015 at 22:43
  • I'm not suggesting that at all. I want to include my custom VEdge struct as part of the edge property that is required. The VEdge (and consequently VNode) are empty because what are in them are completely irrelevant. I only want to associate my VEdge struct with the edge property so that when I iterate the path that the is generated I can take my custom edges and move on to other parts of my program. So what I would look at doing is overriding the std::pair<int, int> property in a way that my VEdge struct would be part of that property that is passed to the adjacency_list.
    – lilott8
    Commented Mar 10, 2015 at 23:33
  • You can't really say you're not suggesting that "at all". It's the only constructor there. You're not really suggesting that the hardcoded demo edges are all there is, right? Also, there is zero correlation info between the edges and the VEdge* elements. Please, simply elaborate on that. Perhaps, remove the unrelated demo code.
    – sehe
    Commented Mar 10, 2015 at 23:37
  • Sure, we can be pedantic about this, I don't care. My apologies if I misspoke. Ultimately my question pertains to adding custom properties to the edge or vertex definitions needed for the adjacency_list typedef. See my second paragraph. I am having problems adding my struct/class/object to a custom property that defines an edge/vertex for the adjacency_list typedef. Correct, looking at links 2&3 that I provided, I know I can add a custom property to my adjacency_list.
    – lilott8
    Commented Mar 10, 2015 at 23:46
  • You can. So, what is the question? I gather your question is how you can connect the dots. You don't give enough information. Mind you, I can make up stuff, but I'm afraid it won't help you if it's not what you were looking for.
    – sehe
    Commented Mar 10, 2015 at 23:56

1 Answer 1

8

Okay. You've come a long ways since https://stackoverflow.com/questions/28889423/boost-adjacency-list-swap-errors-when-using-boost-dijkstra; the sample is self-contained and can compile¹

I figured I could just connect some dots and hope this would be helpful.

1. Using VEdge

For the simplest option, I'd use Bundled Properties, and define VEdge as follows:

struct VEdge {
    int id;
    int source, target;
    double weight;
    // custom variables here
};

Now, we define the graph as

using graph_t = boost::adjacency_list<boost::listS, boost::vecS, 
                    boost::directedS, boost::no_property, VEdge>;
using weight_map_t = boost::property_map<graph_t, double VEdge::*>::type;

As you can see the weight-map has a little more complicated type, as documented under Properties maps from bundled properties. You can get the actual map:

weight_map_t kWeightMap = boost::get(&VEdge::weight, kGraph);

Now, let's recreate the test data from your question in a vector of VEdge (A=0...E=4):

std::vector<VEdge> edges {
    { 2100, 0, 2, 1 },
    { 2101, 1, 1, 2 },
    { 2102, 1, 3, 1 },
    { 2103, 1, 4, 2 },
    { 2104, 2, 1, 7 },
    { 2105, 2, 3, 3 },
    { 2106, 3, 4, 1 },
    { 2107, 4, 0, 1 },
    { 2108, 4, 1, 1 },
};

test_dijkstra test(edges);

The constructor has a little bit of complication to find the number of vertices from just the edges. I used Boost Range algorithms to find the maximum vertex node id and pass that:

test_dijkstra::test_dijkstra(std::vector<VEdge> edges) {
    using namespace boost::adaptors;

    size_t max_node;

    boost::partial_sort_copy(
            edges | transformed([](VEdge const &e) -> size_t { return std::max(e.source, e.target); }),
            boost::make_iterator_range(&max_node, &max_node + 1),
            std::greater<size_t>());

    auto e = edges | transformed([](VEdge const &ve) { return std::make_pair(ve.source, ve.target); });
    kGraph = graph_t(e.begin(), e.end(), edges.begin(), max_node + 1);
}

Note how edges.begin() can be passed: it is not "forced to be a an array of edge_property type". An iterator will be fine.

Now the dijkstra needs to get the weight_map argument because it's no longer the default internal property:

void test_dijkstra::run_dijkstra() {

    weight_map_t kWeightMap = boost::get(&VEdge::weight, kGraph);

    vertex_descriptor kS    = vertex(0, kGraph);
    kP                      = std::vector<vertex_descriptor>(num_vertices(kGraph));
    kD                      = std::vector<int>(num_vertices(kGraph));

    dijkstra_shortest_paths(
        kGraph, kS,
            predecessor_map(boost::make_iterator_property_map(kP.begin(), get(boost::vertex_index, kGraph)))
        .distance_map(boost::make_iterator_property_map(kD.begin(), get(boost::vertex_index, kGraph)))
        .weight_map(kWeightMap));
}

For this sample, I translated A to 0 as the starting vertex. The result path is exactly the same as for the original²

enter image description here

Full Program

Live On Coliru

#include <boost/config.hpp>
#include <boost/graph/adjacency_list.hpp>
#include <boost/graph/dijkstra_shortest_paths.hpp>
#include <boost/graph/graph_traits.hpp>
#include <boost/property_map/property_map.hpp>
#include <boost/range/algorithm.hpp>
#include <boost/range/adaptors.hpp>
#include <fstream>
#include <iostream>

struct VEdge {
    int id;
    int source, target;
    double weight;
    // custom variables here
};

class test_dijkstra {
    using graph_t           = boost::adjacency_list<boost::listS, boost::vecS, boost::directedS, boost::no_property, VEdge>;
    using vertex_descriptor = boost::graph_traits<graph_t>::vertex_descriptor;
    using edge_descriptor   = boost::graph_traits<graph_t>::edge_descriptor;
    using weight_map_t      = boost::property_map<graph_t, double VEdge::*>::type;

  public:
    test_dijkstra(std::vector<VEdge>);
    ~test_dijkstra() {}

    void run_dijkstra();

    void print_path();
    void generate_dot_file();

  private:
    graph_t kGraph;

    std::vector<int> kD;
    std::vector<vertex_descriptor> kP;
};

test_dijkstra::test_dijkstra(std::vector<VEdge> edges) {
    using namespace boost::adaptors;

    size_t max_node;

    boost::partial_sort_copy(
            edges | transformed([](VEdge const &e) -> size_t { return std::max(e.source, e.target); }),
            boost::make_iterator_range(&max_node, &max_node + 1),
            std::greater<size_t>());

    auto e = edges | transformed([](VEdge const &ve) { return std::make_pair(ve.source, ve.target); });
    kGraph = graph_t(e.begin(), e.end(), edges.begin(), max_node + 1);
}

void test_dijkstra::run_dijkstra() {

    weight_map_t kWeightMap = boost::get(&VEdge::weight, kGraph);

    vertex_descriptor kS    = vertex(0, kGraph);
    kP                      = std::vector<vertex_descriptor>(num_vertices(kGraph));
    kD                      = std::vector<int>(num_vertices(kGraph));

    dijkstra_shortest_paths(
        kGraph, kS,
            predecessor_map(boost::make_iterator_property_map(kP.begin(), get(boost::vertex_index, kGraph)))
           .distance_map(boost::make_iterator_property_map(kD.begin(), get(boost::vertex_index, kGraph)))
           .weight_map(kWeightMap));
}

void test_dijkstra::print_path() {
    std::cout << "distances and parents:" << std::endl;
    boost::graph_traits<graph_t>::vertex_iterator vi, vend;

    for (boost::tie(vi, vend) = vertices(kGraph); vi != vend; ++vi) {
        std::cout << "distance(" << *vi << ") = " << kD[*vi] << ", ";
        std::cout << "parent(" << *vi << ") = " << kP[*vi] << "\n";
    }
}

void test_dijkstra::generate_dot_file() {
    weight_map_t kWeightMap = boost::get(&VEdge::weight, kGraph);

    std::ofstream dot_file("figs/dijkstra-eg.dot");

    dot_file << "digraph D {\n"
             << "  rankdir=LR\n"
             << "  size=\"4,3\"\n"
             << "  ratio=\"fill\"\n"
             << "  edge[style=\"bold\"]\n"
             << "  node[shape=\"circle\"]\n";

    boost::graph_traits<graph_t>::edge_iterator ei, ei_end;
    for (boost::tie(ei, ei_end) = edges(kGraph); ei != ei_end; ++ei) {
        boost::graph_traits<graph_t>::edge_descriptor e = *ei;
        boost::graph_traits<graph_t>::vertex_descriptor u = source(e, kGraph), v = target(e, kGraph);
        dot_file << u << " -> " << v << "[label=\"" << get(kWeightMap, e) << "\"";

        if (kP[v] == u)
            dot_file << ", color=\"black\"";
        else
            dot_file << ", color=\"grey\"";
        dot_file << "]";
    }
    dot_file << "}";
}

int main() {
    std::vector<VEdge> edges {
        { 2100, 0, 2, 1 },
        { 2101, 1, 1, 2 },
        { 2102, 1, 3, 1 },
        { 2103, 1, 4, 2 },
        { 2104, 2, 1, 7 },
        { 2105, 2, 3, 3 },
        { 2106, 3, 4, 1 },
        { 2107, 4, 0, 1 },
        { 2108, 4, 1, 1 },
    };

    test_dijkstra test(edges);
    test.run_dijkstra();

    test.print_path();
    test.generate_dot_file();
}

2. Using VEdge*

If you insist on using the pointers in the properties a few things become more complicated:

  • you'll need to manage the lifetime of the elements
  • you can't use the double VEdge::* weight_map_t. Instead, you'll need to adapt a custom propertymap for this:

    auto kWeightMap = boost::make_transform_value_property_map(
                [](VEdge* ve) { return ve->weight; },
                boost::get(boost::edge_bundle, kGraph)
            );
    
  • On the bright side, you can use the short-hand indexer notation to evaluate edge properties from an edge_descriptor as shown in generate_dot_file():

    dot_file << u << " -> " << v << "[label=\"" << kGraph[e]->weight << "\"";
    
  • Of course this approach avoids copying the VEdge objects into the bundle, so it could be more efficient

Without further ado (and without bothering about the memory leaks):

Live On Coliru

#include <boost/config.hpp>
#include <boost/graph/adjacency_list.hpp>
#include <boost/graph/dijkstra_shortest_paths.hpp>
#include <boost/graph/graph_traits.hpp>
#include <boost/property_map/property_map.hpp>
#include <boost/range/algorithm.hpp>
#include <boost/range/adaptors.hpp>

#include <boost/property_map/transform_value_property_map.hpp>

#include <fstream>
#include <iostream>

struct VEdge {
    int id;
    int source, target;
    double weight;
    // custom variables here
};

class test_dijkstra {
    using graph_t           = boost::adjacency_list<boost::listS, boost::vecS, boost::directedS, boost::no_property, VEdge*>;
    using vertex_descriptor = boost::graph_traits<graph_t>::vertex_descriptor;
    using edge_descriptor   = boost::graph_traits<graph_t>::edge_descriptor;

  public:
    test_dijkstra(std::vector<VEdge*>);
    ~test_dijkstra() {}

    void run_dijkstra();

    void print_path();
    void generate_dot_file();

  private:
    graph_t kGraph;

    std::vector<int> kD;
    std::vector<vertex_descriptor> kP;
};

test_dijkstra::test_dijkstra(std::vector<VEdge*> edges) {
    using namespace boost::adaptors;

    size_t max_node;

    boost::partial_sort_copy(
            edges | transformed([](VEdge const* e) -> size_t { return std::max(e->source, e->target); }),
            boost::make_iterator_range(&max_node, &max_node + 1),
            std::greater<size_t>());

    auto e = edges | transformed([](VEdge const *ve) { return std::make_pair(ve->source, ve->target); });
    kGraph = graph_t(e.begin(), e.end(), edges.begin(), max_node + 1);
}

void test_dijkstra::run_dijkstra() {

    auto kWeightMap = boost::make_transform_value_property_map(
                [](VEdge* ve) { return ve->weight; },
                boost::get(boost::edge_bundle, kGraph)
            );

    vertex_descriptor kS    = vertex(0, kGraph);
    kP                      = std::vector<vertex_descriptor>(num_vertices(kGraph));
    kD                      = std::vector<int>(num_vertices(kGraph));

    dijkstra_shortest_paths(
        kGraph, kS,
            predecessor_map(boost::make_iterator_property_map(kP.begin(), get(boost::vertex_index, kGraph)))
           .distance_map(boost::make_iterator_property_map(kD.begin(), get(boost::vertex_index, kGraph)))
           .weight_map(kWeightMap));
}

void test_dijkstra::print_path() {
    std::cout << "distances and parents:" << std::endl;
    boost::graph_traits<graph_t>::vertex_iterator vi, vend;

    for (boost::tie(vi, vend) = vertices(kGraph); vi != vend; ++vi) {
        std::cout << "distance(" << *vi << ") = " << kD[*vi] << ", ";
        std::cout << "parent(" << *vi << ") = " << kP[*vi] << "\n";
    }
}

void test_dijkstra::generate_dot_file() {

    std::ofstream dot_file("figs/dijkstra-eg.dot");

    dot_file << "digraph D {\n"
             << "  rankdir=LR\n"
             << "  size=\"4,3\"\n"
             << "  ratio=\"fill\"\n"
             << "  edge[style=\"bold\"]\n"
             << "  node[shape=\"circle\"]\n";

    boost::graph_traits<graph_t>::edge_iterator ei, ei_end;
    for (boost::tie(ei, ei_end) = edges(kGraph); ei != ei_end; ++ei) {
        boost::graph_traits<graph_t>::edge_descriptor e = *ei;
        boost::graph_traits<graph_t>::vertex_descriptor u = source(e, kGraph), v = target(e, kGraph);
        dot_file << u << " -> " << v << "[label=\"" << kGraph[e]->weight << "\"";

        if (kP[v] == u)
            dot_file << ", color=\"black\"";
        else
            dot_file << ", color=\"grey\"";
        dot_file << "]";
    }
    dot_file << "}";
}

int main() {
    std::vector<VEdge*> edges {
        new VEdge { 2100, 0, 2, 1 },
        new VEdge { 2101, 1, 1, 2 },
        new VEdge { 2102, 1, 3, 1 },
        new VEdge { 2103, 1, 4, 2 },
        new VEdge { 2104, 2, 1, 7 },
        new VEdge { 2105, 2, 3, 3 },
        new VEdge { 2106, 3, 4, 1 },
        new VEdge { 2107, 4, 0, 1 },
        new VEdge { 2108, 4, 1, 1 },
    };

    test_dijkstra test(edges);
    test.run_dijkstra();

    test.print_path();
    test.generate_dot_file();
}

¹ after swatting silly typos

² self-contained Live On Coliru

3
  • ...WOW. I'm not going to lie, I don't know that I would have ever pieced this together given the boost documentation. Thank you, very much!
    – lilott8
    Commented Mar 11, 2015 at 3:50
  • On a slightly related note, I would assume this would be pretty similar for the boost::kruskal approach, is that a correct assumption?
    – lilott8
    Commented Mar 11, 2015 at 3:58
  • Yes that is an assumption i would share
    – sehe
    Commented Mar 11, 2015 at 6:40

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