#AT2572. Ex - Difference of Distance
Ex - Difference of Distance
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Ex - Difference of Distance
Score : $625$ points
Problem Statement
We have a connected undirected graph with $N$ vertices numbered $1$ to $N$ and $M$ edges numbered $1$ to $M$. Edge $i$ connects vertex $U_i$ and vertex $V_i$, and has an integer weight of $W_i$. For $1\leq s,t \leq N,\ s\neq t$, let us define $d(s,t)$ as follows.
- For every path connecting vertex $s$ and vertex $t$, consider the maximum weight of an edge along that path. $d(s,t)$ is the minimum value of this weight.
Answer $Q$ queries. The $j$-th query is as follows.
- You are given $A_j,S_j,T_j$. By what value will $d(S_j,T_j)$ increase when the weight of edge $A_j$ is increased by $1$?
Note that each query does not actually change the weight of the edge.
Constraints
- $2\leq N \leq 2\times 10^5$
- $N-1\leq M \leq 2\times 10^5$
- $1 \leq U_i,V_i \leq N$
- $U_i \neq V_i$
- $1 \leq W_i \leq M$
- The given graph is connected.
- $1\leq Q \leq 2\times 10^5$
- $1 \leq A_j \leq M$
- $1 \leq S_j,T_j \leq N$
- $S_j\neq T_j$
- All values in the input are integers.
Input
The input is given from Standard Input in the following format:
Output
Print $Q$ lines. The $j$-th line $(1\leq j \leq Q)$ should contain the answer to the $j$-th query.
6 6
1 2 1
3 1 5
4 1 5
3 4 3
5 6 4
2 6 5
7
1 4 6
2 4 6
3 4 6
4 4 6
5 4 6
6 4 6
5 6 5
0
0
0
0
0
1
1
The above figure shows the edge numbers in black and the edge weights in blue.
Let us explain the first through sixth queries.
First, consider $d(4,6)$ in the given graph. The maximum weight of an edge along the path $4 \rightarrow 1 \rightarrow 2 \rightarrow 6$ is $5$, which is the minimum over all paths connecting vertex $4$ and vertex $6$, so $d(4,6)=5$.
Next, consider the increment of $d(4,6)$ when the weight of edge $x\ (1 \leq x \leq 6)$ increases by $1$. When $x=6$, we have $d(4,6)=6$, and the increment is $1$. On the other hand, when $x \neq 6$, we have $d(4,6)=5$, and the increment is $0$. For instance, when $x=3$, the maximum weight of an edge along the path $4 \rightarrow 1 \rightarrow 2 \rightarrow 6$ is $6$, but the maximum weight of an edge along the path $4 \rightarrow 3 \rightarrow 1 \rightarrow 2 \rightarrow 6$ is $5$, so $d(4,6)$ is still $5$.
2 2
1 2 1
1 2 1
1
1 1 2
0
The given graph may contain multi-edges.