# Big O in Adjency List - remove vertex and remove edge(time complexity cost of performing various operations on graphs)

I have to prepare explanation of time complexity of removing vertex (`O(|V| + |E|)`) and edge (`O(|E|)`) in Adjency List.

When removing vertex from graph with V vertices and E edges we need to go through all the edges (`O(|E|)`), of course, to check if which ones need to be removed with the vertex, but why do we need to check all vertices?

I don't understand why in order to remove edge we need to go through all the edges. I think I might have bad understanding from the beginning, so would you kindly help with those two above?

• how are the adjency lists stored in your example? you have probably to actually remove the vertex from the graph (removing edges isnt all, since verticies without edges are still part of the graph) Commented Nov 6, 2014 at 14:05

To remove a vertex, you first need to find the vertex in your data structure. This time complexity of this find operation depends on the data structure you use; if you use a `HashMap`, it will be `O(1)`; if you use a `List`, it will be `O(V)`.

Once you have identified the vertex that needs to be removed, you now need to remove all the edges of that vertex. Since you are using an adjacency List, you simply need to iterate over the edge-list of the vertex you found in the previous step and update all those nodes. The run-time of this step is `O(Deg(V))`. Assuming a simple graph, the `maximum degree of a node is O(V)`. For sparse graphs it will be much lower.

Hence the run-time of `removeVertex` will only be `O(V)`.

• So it means that that the time complexity basically depends on the type of container we used. And the time complexity for removing Vertex - (O(|V| + |E|)) is a worst case scenario - we store edges and vertices in a list. To remove vertex we must go through all vertices to find it, and then go through all the edges to find those that need to be removed with it. And the time complexity for removing edge (O(|E|)) is when we have the edges stored in one list, is that correct? Commented Nov 9, 2014 at 21:31
• @Tomek Yes. As you have already noticed, the key point to pay attention to is "time complexity basically depends on the type of container we used" Commented Nov 9, 2014 at 21:36
• @navari, why it is O(Deg(V)) to remove all edges? , each time you remove an edge, you also need to go to the corresponding vertex, find V and delete V, ,which could be larger than O(Deg(V))? Commented May 7, 2017 at 2:36

Consider a graph like this:

``````A -> A
A -> B
A -> C
A -> D
B -> C
``````

The adjacency list will look like this.

``````A: A -> B -> C -> D -> NULL
B: C -> NULL
C: NULL
D: NULL
``````

Let's remove the vertex C, we have to go through all edges to see if we need to remove that edge, that's is O(|E|) Otherwise - how do you find A->C need to be removed?. After then, we need to remove the list C: NULL from the top level container. Depending on the top level container you may or may not need O(|V|) time for this. For example, if the top level container is an array and you don't allow holes, then you need to copy the array. Or the top level is a list, you will need to scan through the list to find the node representing C to delete.

From the original graph, let's removing the edge A->D, we have to go through the whole linked list A -> B -> C -> D to find out the node D and remove it. That's is why you need to go through all vertices. In the worse case, a vertex connects to all other vertices, so it need to go through all vertices to delete that element, or O(|V|). Depending on your top level container, again, you may or may not be able to find the list fast, that will cost you another O(|V|), but in no case I can imagine removing an edge that O(|E|) in an adjacency list representation.