I'll try to develop an intuitive understanding on how this algorithm works and also give commented pseudocode that outputs Bi-Components as well as bridges.
It's actually easy to develop a brute force algorithm for articulation points. Just take out a vertex, and run BFS or DFS on a graph. If it remains connected, then the vertex is not an articulation point, otherwise it is. This will run in
O(V(E+V)) = O(EV) time. The challenge is how to do this in linear time (i.e.
Articulation points connect two (or more) subgraphs. This means there are no edges from one subgraph to another. So imagine you are within one of these subgraphs and visiting its node. As you visit the node, you flag it and then move on to the next unflagged node using some available edge. While you are doing this, how do you know you are within still same subgraph? The insight here is that if you are within the same subgraph, you will eventually see a flagged node through an edge while visiting an unflagged node. This is called a back edge and indicates that you have a cycle. As soon as you find a back edge, you can be confident that all the nodes through that flagged node to the one you are visiting right now are all part of the same subgraph and there are no articulation points in between. If you didn't see any back edges then all the nodes you visited so far are all articulation points.
So we need an algorithm that visits vertices and marks all points between the target of back edges as currently-being-visited nodes as within the same subgraph. There may obviously be subgraphs within subgraphs so we need to select largest subgraph we have so far. These subgraphs are called Bi-Components. We can implement this algorithm by assigning each bi-component an ID which is initialized as just a count of the number of vertices we have visited so far. Later as we find back edges, we can reset the bi-compinent ID to lowest we have found so far.
We obviously need two passes. In the first pass, we want to figure out which vertex we can see from each vertex through back edges, if any. In the second pass we want to visit vertices in the opposite direction and collect the minimum bi-component ID (i.e. earliest ancestor accessible from any descendants). DFS naturally fits here. In DFS we go down first and then come back up so both of the above passes can be done in a single DFS traversal.
Now without further ado, here's the pseudocode:
time = 0
visited[i] = false for all i
visited[u] = true
u.st = time++
u.low = v.st //keeps track of highest ancestor reachable from any descendants
dfsChild = 0 //needed because if no child then removing this node doesn't decompose graph
for each ni in adj[i]
if not visited[ni]
parents[ni] = u
u.low = Min(u.low, ni.low) //while coming back up, get the lowest reachable ancestor from descendants
else if ni <> parent[u] //while going down, note down the back edges
u.low = Min(u.low, ni.st)
//For dfs root node, we can't mark it as articulation point because
//disconnecting it may not decompose graph. So we have extra check just for root node.
if (u.low = u.st and dfsChild > 0 and parent[u] != null) or (parent[u] = null and dfsChild > 1)
Output u as articulation point
Output edges of u with v.low >= u.low as bridges
output u.low as bicomponent ID