Prim's algorithm using priority_queue in STL

Given an undirected, connected and weighted graph, find Minimum Spanning Tree (MST) of the graph using Prim's algorithm.

Input : Adjacency List representation
 of above graph
Output : Edges in MST
 0 - 1
 1 - 2
 2 - 3
 3 - 4
 2 - 5
 5 - 6
 6 - 7
 2 - 8
Note:  There are two possible MSTs, the other
 MST includes edge 0-7 in place of 1-2. 

We have discussed below Prim's MST implementations. 

• Prim’s Algorithm for Adjacency Matrix Representation (In C/C++ with time complexity O(v²)
• Prim’s Algorithm for Adjacency List Representation (In C with Time Complexity O(ELogV))

The second implementation is time complexity wise better, but is really complex as we have implemented our own priority queue. STL provides priority_queue, but the provided priority queue doesn’t support decrease key operation. And in Prim’s algorithm, we need a priority queue and below operations on priority queue : 

• ExtractMin : from all those vertices which have not yet been included in MST, we need to get vertex with minimum key value.
• DecreaseKey : After extracting vertex we need to update keys of its adjacent vertices, and if new key is smaller, then update that in data structure.

The algorithm discussed here can be modified so that decrease key is never required. The idea is, not to insert all vertices in priority queue, but only those which are not MST and have been visited through a vertex that has included in MST. We keep track of vertices included in MST in a separate boolean array inMST[].

1) Initialize keys of all vertices as infinite and 
 parent of every vertex as -1.
2) Create an empty priority_queue pq. Every item
 of pq is a pair (weight, vertex). Weight (or 
 key) is used as first item of pair
 as first item is by default used to compare
 two pairs.
3) Initialize all vertices as not part of MST yet.
 We use boolean array inMST[] for this purpose.
 This array is required to make sure that an already
 considered vertex is not included in pq again. This
 is where Prim's implementation differs from Dijkstra.
 In Dijkstra's algorithm, we didn't need this array as
 distances always increase. We require this array here 
 because key value of a processed vertex may decrease
 if not checked.
4) Insert source vertex into pq and make its key as 0.
5) While either pq doesn't become empty 
 a) Extract minimum key vertex from pq. 
 Let the extracted vertex be u.
 b) Include u in MST using inMST[u] = true.
 c) Loop through all adjacent of u and do 
 following for every vertex v.
 // If weight of edge (u,v) is smaller than
 // key of v and v is not already in MST
 If inMST[v] = false && key[v] > weight(u, v)
 (i) Update key of v, i.e., do
 key[v] = weight(u, v)
 (ii) Insert v into the pq 
 (iv) parent[v] = u

6) Print MST edges using parent array.

Below is C++ implementation of above idea. 

0 - 1
1 - 2
2 - 3
3 - 4
2 - 5
5 - 6
6 - 7
2 - 8

Time complexity : O(E Log V))

Auxiliary Space :O(V)

A Quicker Implementation using array of vectors representation of a weighted graph : 

0 - 1
1 - 2
2 - 3
3 - 4
2 - 5
5 - 6
6 - 7
2 - 8

Note: Like Dijkstra's priority_queue implementation, we may have multiple entries for same vertex as we do not (and we can not) make isMST[v] = true in if condition. 

But as explained in Dijkstra's algorithm, time complexity remains O(E Log V) as there will be at most O(E) vertices in priority queue and O(Log E) is same as O(Log V).

Unlike Dijkstra's implementation, a boolean array inMST[] is mandatory here because the key values of newly inserted items can be less than the key values of extracted items. So we must not consider extracted items.

Please write comments if you find anything incorrect, or you want to share more information about the topic discussed above.