# adjacency-list representation of a directed graph

Given an adjacency-list representation of a directed graph, how long does it take to compute the out-degree of every vertex? How long does it take to compute the in-degrees?

Thanks

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Both are O(m + n) where m is the number of edges and n is the number of vertices.

Start a set of counters, one for each vertex, one for in-degree and out for out-degree.

Scan the edges. For the out vertex of each edge, add one to the out-degree counter for that vertex. For the in vertex of each edge, add one to the in-degree counter for that vertex. This is O(m) operation.

Output the out-degree and in-degree counters for each vertex, which is O(n).

That's how you get O(m + n).

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yea I seen that online before...would it be the same as far as O(V+E)...or would it be O(E+V) –  user2558869 Aug 6 '13 at 4:08
It's exactly the same. –  Jason Aug 6 '13 at 4:10
Which is correct O(V+E) or O(E+V) –  user2558869 Aug 6 '13 at 4:12
Sorry V is for vertex and E is for edges –  user2558869 Aug 6 '13 at 4:14
@user2558869 Consider looking up the definition: en.wikipedia.org/wiki/Big_O_notation#Formal_definition. If you are not familiar with the notation and can't figure it out despite your best efforts, feel free the post any notational issues in a separate math.stackexchange post –  rliu Aug 6 '13 at 4:42

Computing both the in-degree and out-degree takes theta(m + n) for a graph with m vertices and n edges. The reason that it is theta(m+n) and not O(m + n) because whatever may be the graph , it has to go through every vertex m and every edge n.

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