I am going through this link for adjacency list representation.


I have a simple doubt in some part of a code as follows :

// A utility function to print the adjacenncy list representation of graph
void printGraph(struct Graph* graph)
    int v;
    for (v = 0; v < graph->V; ++v)
        struct AdjListNode* pCrawl = graph->array[v].head;
        printf("\n Adjacency list of vertex %d\n head ", v);
        while (pCrawl)
            printf("-> %d", pCrawl->dest);
            pCrawl = pCrawl->next;

Since, here for every V while loop is executed say d times where d is the degree of each vertex.

So, I think time complexity is like

d0 + d1 + d2 + d3 ....... +dV where di is the degree of each vertex.

All this sums up O(E), but the link says that time complexity is O(|V|+|E|)

Not sure what is the problem with the understanding. Some help needed here

  • 4
    Suppose the graph has no edges. How long does the algorithm take? – user2357112 supports Monica Jul 8 '17 at 6:57
  • @user2357112 We have to check or scan every vertex once, right ? But It is a nested loop so shouldn't time complexity be like that ? – Garrick Jul 8 '17 at 6:59

The important thing here is that for the time complexity to be valid, we need to cover every possible situation:

  • The outer loop is executed O(|V|) regardless of the graph structure.
    • Even if we had no edges at all, for every iteration of the outer loop, we would have to do a constant number of operations (O(1))
    • The inner loop is executed once for every edge, thus O(deg(v)) times, where deg(v) is the degree of the current node.
    • Thus the runtime of a single iteration of the outer loop is O(1 + deg(v)). Note that we cannot leave out the 1, because deg(v) might be 0 but we still need to do some work in that iteration
  • Summing it all up, we get a runtime of O(|V| * 1 + deg(v1) + deg(v2) + ...) = O(|V| + |E|).

As mentioned before, |E| could be rather small such that we still need to account for the work done exclusively in the outer loop. Thus, we cannot simply remove the |V| term.

  • Thanks !! This clears much ..... – Garrick Jul 9 '17 at 13:31

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