# Why Dijkstra's Algorithm uses heap (priority queue)?

I have tried using Djikstra's Algorithm on Cyclic weighted graph without using Priority queue (Heap) and it worked.

Then I searched google that "why the hell do we need a priority queue to implement this??" As a result of the search I went through Wikipedia where I got to know that the original implementation does not uses Priority queue and runs in O(|V|2) i.e V square time .

now if we just remove priority queue and use normal queue the running time is linear i.e. O(V+E).

Please someone suggest then why do we need priority queue??

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no its the other way around with runtime. using priority queues it runs in O(|E| + |V|.|logV|), without priority queues it runs in O(V^2). it says so clearly on wikipedia. The best time is O(|E| + |V|.|logV|) using fib heaps. where did u read that you can get it in O(V+E)? – Moataz Elmasry Sep 18 '12 at 16:50
I did not read...I run the code just after removing the concept of priority queue and using normal queue.... and yes I know it will take O(E+ |V|log|V|) with priority queue. Therefore when we do not use priority queue the logV is not there anymore and hence the running time becomes O(E+V) Just see the code. There is only one for loop. – Anshu Kandhari Sep 18 '12 at 18:09
But how are you sorting the entries according to the minimal distance? Sorting will be done 'cheaply' via prio queue - are you explicitely sorting it - this will be more expensive. – Karussell Sep 20 '12 at 19:11
Not every loop happens in your code. I think you aren't considering the cost of maintaining and searching a queue. – Barry Fruitman Feb 28 '13 at 8:54

Like Moataz Elmasry said the best you can expect is O(|E| + |V|.|logV|) with a fib queue. At least when it comes to big oh values.

The idea behind it is, for every vertex(node) you are currently working on, you already found the shortest path to. If the vertex isn't the smallest one, (distance + edge weight) that isn't necessarily true. This is what allows you to stop the algorithm as soon as you have expanded(?) every vertex that is reachable from your initial vertex. If you aren't expanding the smallest vertex, you aren't guaranteed to be finding the shortest path, thus you would have to test every single path, not just one. So instead of having to go through every edge in just one path, you go through every edge in every path.

Your estimate for O(E + V) is probably correct, the path and cost you determined on the other hand, are incorrect. If I'm not mistaken the path would only be the shortest if by any chance the first edge you travel from every vertex just happens to be the smallest one.

So Dijkstra's shortest path algorithm without a queue with priority is just Dijkstra's path algorithm ;)

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A correct implementation of Dijksta's Algorithm always returns a shortest path regardless of a priority queue is used or not. – Mozoby Mar 12 '14 at 23:49

A heap is the best choice for this task as it guarantees O(log(n)) for adding edges to our queue and to remove the top element. Any other implementation of priority queue would sacrifice in either adding to our queue or removing from it to gain a performance boost somewhere else. Depending on how sparse the graph, then you might find better performance using a different implementation of priority queue, but generally speaking a min-heap is best since it balances the two.

Not the greatest source but: http://en.wikipedia.org/wiki/Heap_(data_structure)

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For sparse graph, if implement with binary min heap runtime is(E*logV), however if you implement it with Fibonacci heap, runtime would be(VlogV+E).

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Welcome to StackOverflow. Any source references? – cordialgerm Dec 13 '12 at 1:52
Please refer to Introduction to Algorithm 3rd Edition, chapter 23.2. – Linghua Jin Dec 13 '12 at 3:36

I had the exact same doubt and found a test case where the algorithm without a priority_queue would not work.

Let's say I have a Graph object g, a method addEdge(a,b,w) which adds edge from vertex a to vertex b with weight w.

Now, let me define the following graph :-

Graph g

Now, say our queue contains the nodes in the following order {0,1,2,3 } So, node 0 is visited first then node 1 is visited.

At this point of time the dist b/w 0 and 3 is computed as 6 using the path 0->1->3, and 1 is marked as visited.

Now node 2 is visited and dist b/w 0 and 1 is updated to the value 3 using the path 0->2->1, but since node 1 is marked visited, you cannot change the distance b/w 0 and 3 which (using the optimal path) (`0->2->1->3) is 4.

So, your algorithm fails without using the priority_queue.

It reports dist b/w 0 and 3 to be 6 while in reality it should be 4.

Now, here is the code which I used for implementing the algorithm :-

class Graph
{
public:
vector<int> nodes ;
vector<vector<pair<int,int> > > edges ;
{
nodes.push_back(nodes.size()) ;
vector<pair<int,int> > temp ; edges.push_back(temp);
}
void addEdge(int n1, int n2, int w)
{
edges[n1].push_back(make_pair(n2,w)) ;
}
pair<vector<int>, vector<int> > shortest(int source) // shortest path djkitra's
{
vector<int> dist(nodes.size()) ;
fill(dist.begin(), dist.end(), INF) ; dist[source] = 0 ;
vector<int> pred(nodes.size()) ;
fill(pred.begin(), pred.end(), -1) ;
for(int i=0; i<(int)edges[source].size(); i++)
{
dist[edges[source][i].first] = edges[source][i].second ;
pred[edges[source][i].first] = source  ;
}
set<pair<int,int> > pq ;
for(int i=0; i<(int)nodes.size(); i++)
pq.insert(make_pair(dist[i],i)) ;
while(!pq.empty())
{
pair<int,int> item = *pq.begin() ;
pq.erase(pq.begin()) ;
int v = item.second ;
for(int i=0; i<(int)edges[v].size(); i++)
{
if(dist[edges[v][i].first] > dist[v] + edges[v][i].second)
{
pq.erase(std::find(pq.begin(), pq.end(),make_pair(dist[edges[v][i].first],edges[v][i].first))) ;
pq.insert(make_pair(dist[v] + edges[v][i].second,edges[v][i].first)) ;
dist[edges[v][i].first] = dist[v] + edges[v][i].second ;
pred[i] = edges[v][i].first ;
}
}
}
return make_pair(dist,pred) ;
}

pair<vector<int>, vector<int> > shortestwpq(int source) // shortest path djkitra's without priority_queue
{
vector<int> dist(nodes.size()) ;
fill(dist.begin(), dist.end(), INF) ; dist[source] = 0 ;
vector<int> pred(nodes.size()) ;
fill(pred.begin(), pred.end(), -1) ;
for(int i=0; i<(int)edges[source].size(); i++)
{
dist[edges[source][i].first] = edges[source][i].second ;
pred[edges[source][i].first] = source  ;
}
vector<pair<int,int> > pq ;
for(int i=0; i<(int)nodes.size(); i++)
pq.push_back(make_pair(dist[i],i)) ;
while(!pq.empty())
{
pair<int,int> item = *pq.begin() ;
pq.erase(pq.begin()) ;
int v = item.second ;
for(int i=0; i<(int)edges[v].size(); i++)
{
if(dist[edges[v][i].first] > dist[v] + edges[v][i].second)
{
dist[edges[v][i].first] = dist[v] + edges[v][i].second ;
pred[i] = edges[v][i].first ;
}
}
}
return make_pair(dist,pred) ;
}

As expected the results were as follows :-

With priority_queue
0
3
2
4

Now using without priority queue
0
3
2
6

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