Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Time complexity of Prim's MST algorithm is O(|V|^2) if you use adjacency matrix representation.

I am trying to implement Prim's algorithm using adjacency matrix. I am using this as a reference.

V = {1,2...,n}
U = {1}
T = NULL
while V != U:

     /* 
         Now this implementation means that 
         I find lowest cost edge in O(n).
         How do I do that using adjacency list? 
     */

     let (u, v) be the lowest cost edge 
                such that u is in U and v is in V - U;

     T = T + {(u,v)}
     U = U + {v}

EDIT:

  1. I understand Prim's algorithm very well.
  2. I know how to implement it efficiently using heaps and priority queues.
  3. I also know about better algorithms.
  4. I want to use adjacency matrix representation of graph and get O(|V|^2) implementation.

I WANT THE INEFFICIENT IMPLEMENTATION

share|improve this question
2  
Here is V^2 implementation towards the end of page personal.kent.edu/~rmuhamma/Algorithms/MyAlgorithms/GraphAlgor/… –  Ankush Aug 22 '12 at 21:38
add comment

3 Answers

Finding the lowest cost edge (u,*v*), such that u is in U and v is in V-U, is done with a priority queue. More precisely, the priority queue contains each node v from V-U together with the lowest cost edge from v into the current tree U. In other words, the queue contains exactly |V-U| elements.

After adding a new node u to U, you have to update the priority queue by checking whether the neighboring nodes of u can now be reached by an edge of lower cost than previously.

The choice of priority queue determines the time complexity. You will get O(|V|^2) by implementing the priority queue as a simply array cheapest_edges[1..|V|]. That's because finding minimum in this queue takes O(|V|) time, and you repeat that |V| times.

In pseudo-code:

V = {2...,n}
U = {1}
T = NULL
P = array, for each v set P[v] = (1,v)

while V != U

    (u,v) = P[v] with v such that  length P[v]  is minimal

    T = T + {(u,v)}
    U = U + {v}

    for each w adjacent to v
        if length (v,w) < length P[w] then
            P[w] = (v,w)
share|improve this answer
    
Can you write little pseudocode? –  Pratik Deoghare Aug 6 '10 at 12:29
    
Sure. Edited my answer. –  Heinrich Apfelmus Aug 6 '10 at 15:43
add comment

You do it like in Dijkstra's algorithm, by selecting the node that is connected to your current partial tree with the minimum cost edge (that doesn't generate a cycle). I think wikipedia explains Prim better than that pseudocode you have. Give it a look and let me know if you have more questions.

share|improve this answer
    
Problem is not understanding algorithm. I understand it quite well. Problem is not efficient implementation. There are many using priority queues. Problem is how do I implement it with exactly O(|V|^2) complexity. –  Pratik Deoghare Aug 6 '10 at 10:44
add comment

You can sort the edges by the cost and then iterate the edges in the order of the cost, and if that edge joins two distinct subgraphs use that edge.

I have a implementation here. It reads the number of verticles (N), the number of edges (M) and the edges in order (A, B, Cost) and then outputs the edges. This is the Kruskal algorithm.

A implementation of the Prim's algorithm with a heap, using the same input can be found here.

share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.