(This is derived from a recently completed programming contest)

You are given G, a connected graph with N nodes and N-1 edges.

(Notice that this implies G forms a tree.)

Each edge of G is directed. (not necessarily upward to any root)

For each vertex v of G it is possible to invert zero or more edges such that there is a directed path from every other vertex w to v. Let the minimum possible number of edge inversions to achieve this be f(v).

By what linear or loglinear algorithm can we determine the subset of vertexes that have the minimal overall f(v) (including the value of f(v) of those vertexes)?

For example consider the 4 vertex graph with these edges:

```
A<--B
C<--B
D<--B
```

The value of f(A) = 2, f(B) = 3, f(C) = 2 and f(D) = 2...

..so therefore the desired output is {A,C,D} and 2

(note we only need to calculate the f(v) of vertexes that have a minimal f(v) - not all of them)

**Code:**

For posterity here is the code of solution:

```
int main()
{
struct Edge
{
bool fwd;
int dest;
};
int n;
cin >> n;
vector<vector<Edge>> V(n+1);
rep(i, n-1)
{
int src, dest;
scanf("%d %d", &src, &dest);
V[src].push_back(Edge{true, dest});
V[dest].push_back(Edge{false, src});
}
vector<int> F(n+1, -1);
vector<bool> done(n+1, false);
vector<int> todo;
todo.push_back(1);
done[1] = true;
F[1] = 0;
while (!todo.empty())
{
int next = todo.back();
todo.pop_back();
for (Edge e : V[next])
{
if (done[e.dest])
continue;
if (!e.fwd)
F[1]++;
done[e.dest] = true;
todo.push_back(e.dest);
}
}
todo.push_back(1);
while (!todo.empty())
{
int next = todo.back();
todo.pop_back();
for (Edge e : V[next])
{
if (F[e.dest] != -1)
continue;
if (e.fwd)
F[e.dest] = F[next] + 1;
else
F[e.dest] = F[next] - 1;
todo.push_back(e.dest);
}
}
int minf = INT_MAX;
rep(i,1,n)
chmin(minf, F[i]);
cout << minf << endl;
rep(i,1,n)
if (F[i] == minf)
cout << i << " ";
cout << endl;
}
```