Finding the critical intersections of a road network [closed]

I am trying to solve this problem:

A intersection I is critical if there are two other intersections J and K such that any route from J to K must necessarily pass through I. Notice that if I is critical, then stopping all the traffic through it disconnects at least one pair of intersections from each other.
You may assume that the roads of Siruseri are such that if all the intersections are usable then one can get from any intersection to any other intersection. All the roads in Siruseri permit traffic in both directions (there are no one way streets). Politicians in Siruseri love to see their names on roads and so every road segment connecting a pair of intersections has a different name. Thus a road merely connects two intersections and never pass through any other intersections.
Road 1 connects I1 and I2
Road 2 connects I2 and I3
Road 3 connects I1 and I3
Road 4 connects I2 and I4
Road 5 connects I2 and I5
Road 6 connects I5 and I4
Then, I2 is a critical intersection because if all the traffic through I2 is blocked then there is no route from I4 to I1 (or I3). Similarly I5 is also cut off from I1 and I3. You can check that no other intersections is critical.
Given the description of the intersections and roads in Siruseri, your task is to determine the number of critical intersections in Siruseri and list them out.
Input format
The first line of the input contains two integers N and M. N is the number of intersections in Siruseri and M is the number of roads. You may assume that the intersections are numbered 1,2,...,N. The next M lines (lines 2,..., M+1) describe the roads in Siruseri. Line i+1 contains two integers in the range 1,...,N indicating the pair of intersections connected by road i.
Output format
The first line of the output must contain a single integer C indicating the number of critical intersections. The next C lines must list out the C critical intersections, one per line.
Test Data:
You may assume that N ≤ 300 and M ≤ 50000.

The only method I could think of is, to take each intersection, and test that every road is possible without it. If not, increment the counter of critical intersections.

This is very slow, so I need another algorithm to solve this problem. I only want an algorithm with explanation -- no code.

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These politicians sure have strange names: "Road 1, Road 2, ..." –  im so confused Oct 31 '12 at 14:50

closed as not a real question by DarkCthulhu, BlueRaja - Danny Pflughoeft, Blastfurnace, Nimit Dudani, chrisNov 1 '12 at 8:54

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As Dialecticus says, this problem is solved in linear time by the Tarjan algorithm (quoting from the wikipedia entry):

"Execute a depth-first search while maintaining the following information:

1. The depth of each vertex in the depth-first-search tree (once it gets visited)
2. For each vertex v, the lowest depth of neighbors of all descendants of v in the depth-first-search tree, called the lowpoint.

The lowpoint of v can be computed after visiting all descendants of v (i.e., just before v gets popped off the depth-first-search stack) as the minimum of the depth of v, the depth of all neighbors of v (other than the parent of v in the depth-first-search tree) and the lowpoint of all children of v in the depth-first-search tree.

A nonroot vertex v is a cut vertex (or articulation point) separating two biconnected components if and only if there is a child y of v such that lowpoint(y) ≥ depth(v). This property can be tested once the depth-first search returned from every child of v (i.e., just before v gets popped off the depth-first-search stack), and if true, v separates the graph into different biconnected components. This can be represented by computing one biconnected component out of every such y (a component which contains y will contain the subtree of y, plus v), and then erasing the subtree of y from the tree.

The root vertex must be handled separately: it is a cut vertex if and only if it has at least two children. Thus, it suffices to simply build one component out of each child subtree of the root (including the root)."

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