• we can implement a graph by two methods:--

1. Adjacency matrix
2. Adjacency list

• Auxiliary Space complexity O(N^2)
• Time complexity O(E) to implement a graph.

• Auxiliary Space complexity O(N+E)
• Time complexity O(E) to implement a graph.
• I am using here Adjacency list for the implementation.

E denotes the number of connections or edges.

N denotes the number of vertices.

• Using *Queue Data structure to run the bfs via iteration.
• I have implemented both the BFS function void BFSvisit() for the connected graph and void NotconnBFS() for the not connected graph.

• red[] will keep track of visited and not visited vertix till now during BFS and DFS run.
• predecessor[] will keep track of the current visiting vertix parent in the BFS and DFS tree (will help to determine the shortest path location)
• pathlength[] will keep track of the shortest disytance from the root vertix in the BFS tree.
• vertices[] Original graph
• transposevertices[] Transpose graph
• runvertix the vertix from where i want to start

• To find the shortest distance and determine the shortest path between the Two vertices
• To compute the Diameter(Longest path among the shortest paths of any two vertices) of the BFS Tree.
• To check whether the graph is connected or not (Using a Transpose Graph)

• Using recursion to run the DFS over the graph void DFSvisit()

• start[] to store the entry time of any vertix in the dfs tree
• finish[] to store the recursion back tracking time for a node after deadend.
• heightvertix[] to store the height or distance of a vertix from the root vertix

• To check whether the graph has a cycle or not and determine all the cycles present in the Graph void DFScyclevisit() (Using the concept of backedge by computeing start and finish time of a vertix )

• To compute all the strongly connected components in the Graph void DFSforstronglyconnected()

• Implemented a Undirected Graph with the weighted Edges.
• Using Greedy Approach to compute the edge every time with the minimum weight.

minspantree[][3] will store all the edges and weights of the edges in my minimum spanning tree so that i can approach to all the vertices in my graph with the minimum total weight.