# Performance of Dijkstra's algorithm implementation

Below is an implementation of Dijkstra's algorithm I wrote from the pseudocode in the Wikipedia article. For a graph with about 40 000 nodes and 80 000 edges, it takes 3 or 4 minutes to run. Is that anything like the right order of magnitude? If not, what's wrong with my implementation?

``````struct DijkstraVertex {
int index;
vector<double> weights;
double dist;
int prev;
bool opt;
DijkstraVertex(int vertexIndex, vector<int> adjacentVertices, vector<double> edgeWeights) {
index = vertexIndex;
weights = edgeWeights;
dist = numeric_limits<double>::infinity();
prev = -1; // "undefined" node
opt = false; // unoptimized node
}
};

void dijsktra(vector<DijkstraVertex*> graph, int source, vector<double> &dist, vector<int> &prev) {
vector<DijkstraVertex*> Q(G); // set of unoptimized nodes
G[source]->dist = 0;
while (!Q.empty()) {
sort(Q.begin(), Q.end(), dijkstraDistComp); // sort nodes in Q by dist from source
DijkstraVertex* u = Q.front(); // u = node in Q with lowest dist
u->opt = true;
Q.erase(Q.begin());
if (u->dist == numeric_limits<double>::infinity()) {
break; // all remaining vertices are inaccessible from the source
}
for (int i = 0; i < (signed)u->adj.size(); i++) { // for each neighbour of u not in Q
if (!v->opt) {
double alt = u->dist + u->weights[i];
if (alt < v->dist) {
v->dist = alt;
v->prev = u->index;
}
}
}
}
for (int i = 0; i < (signed)G.size(); i++) {
assert(G[i] != NULL);
dist.push_back(G[i]->dist); // transfer data to dist for output
prev.push_back(G[i]->prev); // transfer data to prev for output
}
}
``````
-

There are several things you can improve on this:

• implementing the priority queue with sort and erase adds a factor of |E| to the runtime - use the heap functions of the STL to get a log(N) insertion and removal into the queue.
• do not put all the nodes in the queue at once but only those where you have discovered a path (which may or may not be the optimal, as you can find an indirect path through nodes in the queue).
• creating objects for every node creates unneccessary memory fragmentation. If you care about squeezing out the last 5-10%, you could think about a solution to represent the incidence matrix and other information directly as arrays.
-
Thanks for your reply. I'm getting the impression that my current implementation isn't outrageously bad, and that with your suggestions, I might expect an execution time of 1 to 3 minutes for a problem with 40 000 nodes. Executions times closer to 30 seconds or 1 second are not reasonable. Is this true? –  zoo Jun 12 '11 at 0:37

Use priority_queue.

My Dijkstra implementation:

``````struct edge
{
int v,w;
edge(int _w,int _v):w(_w),v(_v){}
};
vector<vector<edge> > g;
enum color {white,gray,black};
vector<int> dijkstra(int s)
{
int n=g.size();
vector<int> d(n,-1);
vector<color> c(n,white);
d[s]=0;
c[s]=gray;
priority_queue<pair<int,int>,vector<pair<int,int> >,greater<pair<int,int> > > q; // declare priority_queue
q.push(make_pair(d[s],s)); //push starting vertex
while(!q.empty())
{
int u=q.top().second;q.pop(); //pop vertex from queue
if(c[u]==black)continue;
c[u]=black;
for(int i=0;i<g[u].size();i++)
{
int v=g[u][i].v,w=g[u][i].w;
if(c[v]==white) //new vertex found
{
d[v]=d[u]+w;
c[v]=gray;
}
else if(c[v]==gray && d[v]>d[u]+w) //shorter path to gray vertex found
{
d[v]=d[u]+w;
q.push(make_pair(d[v],v)); //push this vertex to queue
}
}
}
return d;
}
``````
-
I know this post is a bit old. But I did not get what you are trying to achieve by g[u].size(). Are u trying to scan over g's adjacency list. –  user1354510 May 31 '12 at 4:39
g is adjanency list –  frp May 31 '12 at 18:45
g[u].size() is count of vertices that are connected with vertex u. –  frp May 31 '12 at 18:46