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
g.addEdge(0,1,5) ;
g.addEdge(1,3,1) ;
g.addEdge(0,2,2) ;
g.addEdge(2,1,1) ;
g.addEdge(2,3,7) ;
```

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 ;
void addNode()
{
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