I would like to use it to find the maximum cost of ways. What and how to rewrite to make it work?

This code finds the min cost, and I don't know, what to do. I've found it in the internet, but it can contains mistakes.

```
#include <iostream>
#include <vector>
#include <string>
#include <list>
#include <limits> // for numeric_limits
#include <set>
#include <utility> // for pair
#include <algorithm>
#include <iterator>
typedef int vertex_t;
typedef double weight_t;
const weight_t max_weight = std::numeric_limits<double>::infinity();
struct neighbor {
vertex_t target;
weight_t weight;
neighbor(vertex_t arg_target, weight_t arg_weight)
: target(arg_target), weight(arg_weight) { }
};
typedef std::vector<std::vector<neighbor> > adjacency_list_t;
void DijkstraComputePaths(vertex_t source,
const adjacency_list_t &adjacency_list,
std::vector<weight_t> &min_distance,
std::vector<vertex_t> &previous)
{
int n = adjacency_list.size();
min_distance.clear();
min_distance.resize(n, max_weight);
min_distance[source] = 0;
previous.clear();
previous.resize(n, -1);
std::set<std::pair<weight_t, vertex_t> > vertex_queue;
vertex_queue.insert(std::make_pair(min_distance[source], source));
while (!vertex_queue.empty())
{
weight_t dist = vertex_queue.begin()->first;
vertex_t u = vertex_queue.begin()->second;
vertex_queue.erase(vertex_queue.begin());
// Visit each edge exiting u
const std::vector<neighbor> &neighbors = adjacency_list[u];
for (std::vector<neighbor>::const_iterator neighbor_iter = neighbors.begin();
neighbor_iter != neighbors.end();
neighbor_iter++)
{
vertex_t v = neighbor_iter->target;
weight_t weight = neighbor_iter->weight;
weight_t distance_through_u = dist + weight;
if (distance_through_u < min_distance[v]) {
vertex_queue.erase(std::make_pair(min_distance[v], v));
min_distance[v] = distance_through_u;
previous[v] = u;
vertex_queue.insert(std::make_pair(min_distance[v], v));
}
}
}
}
std::list<vertex_t> DijkstraGetShortestPathTo(
vertex_t vertex, const std::vector<vertex_t> &previous)
{
std::list<vertex_t> path;
for ( ; vertex != -1; vertex = previous[vertex])
path.push_front(vertex);
return path;
}
int main()
{
// remember to insert edges both ways for an undirected graph
adjacency_list_t adjacency_list(6);
// 0 = a
adjacency_list[0].push_back(neighbor(1, 7));
adjacency_list[0].push_back(neighbor(2, 9));
adjacency_list[0].push_back(neighbor(5, 14));
adjacency_list[0].push_back(neighbor(4, 14));
adjacency_list[0].push_back(neighbor(4, 914));
// 1 = b
adjacency_list[1].push_back(neighbor(0, 7));
adjacency_list[1].push_back(neighbor(2, 10));
adjacency_list[1].push_back(neighbor(3, 15));
// 2 = c
adjacency_list[2].push_back(neighbor(0, 9));
adjacency_list[2].push_back(neighbor(1, 10));
adjacency_list[2].push_back(neighbor(3, 11));
adjacency_list[2].push_back(neighbor(5, 2));
// 3 = d
adjacency_list[3].push_back(neighbor(1, 15));
adjacency_list[3].push_back(neighbor(2, 11));
adjacency_list[3].push_back(neighbor(4, 6));
// 4 = e
adjacency_list[4].push_back(neighbor(3, 6));
adjacency_list[4].push_back(neighbor(5, 9));
// 5 = f
adjacency_list[5].push_back(neighbor(0, 14));
adjacency_list[5].push_back(neighbor(2, 2));
adjacency_list[5].push_back(neighbor(4, 9));
std::vector<weight_t> min_distance;
std::vector<vertex_t> previous;
DijkstraComputePaths(0, adjacency_list, min_distance, previous);
std::cout << "Distance from 0 to 4: " << min_distance[4] << std::endl;
std::list<vertex_t> path = DijkstraGetShortestPathTo(4, previous);
std::cout << "Path : ";
std::copy(path.begin(), path.end(), std::ostream_iterator<vertex_t>(std::cout, " "));
std::cout << std::endl;
return 0;
}
```