You should use `priority queue`

where the `vertex`

with the shortest distance from the starting `vertex`

will get the highest priority. Initially, all `vertices`

will have the shortest distance of infinity and the starting `vertex`

will have the shortest distance 0.

Start by inserting of all `vertices`

(with its `edges`

) from the graph inside the `PQ`

. Remove `vertex`

from the `PQ`

and explore all its `edges`

. Compare the shortest distances with all adjacent `vertices`

and if any distance is less than the shortest distance on the current `vertex`

, update adjacent `vertex`

shortest distance inside the `PQ`

. Continue while `PQ`

is not empty. `Vertices`

which got no `edges`

will finish with the shortest distance of infinity because it is not possible 'get to them' from the starting `vertex`

. However, they will be still removed from the `PQ`

.

**Pseudocode**

```
initialize graph
initialize pq
pq.insertAll(graph.getVertices())
while (pq is not empty) {
vertex = pq.remove()
edges = vertex.getEdges()
for all edges {
destination = edge.getDestination()
newDistance = edge.getLength() + vertex.getDistance()
if (newDistance < destination.getDistance()) {
destination.setShortestDistance(newDistance)
pq.update(destination)
}
}
}
```

**MIT OpenCourseWare Links:**

Path problems overview

Dijkstra

traversed to far. 2. Just like with BFS, if it's not adjacent to a visited node, then it can't be visited quite yet. If it's notreachablefrom a visited node, it won't ever be visited.