# Performance of Dijkstra's algorithm implementation

Facebook and Stack Exchange are now working together to support the Facebook developer community. Facebook engineers participate here along with the best Facebook developers in the world. If you have a technical question about Facebook, this is the best place to ask.

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;