Civilization
题目链接:
http://acm.hust.edu.cn/vjudge/contest/121334#problem/B
Description
Andrew plays a game called "Civilization". Dima helps him.
The game has n cities and m bidirectional roads. The cities are numbered from 1 to n. Between any pair of cities there either is a single (unique) path, or there is no path at all. A path is such a sequence of distinct cities v1, v2, ..., vk, that there is a road between any contiguous cities vi and vi + 1 (1 ≤ i < k). The length of the described path equals to (k - 1). We assume that two cities lie in the same region if and only if, there is a path connecting these two cities.
During the game events of two types take place:
Andrew asks Dima about the length of the longest path in the region where city x lies.
Andrew asks Dima to merge the region where city x lies with the region where city y lies. If the cities lie in the same region, then no merging is needed. Otherwise, you need to merge the regions as follows: choose a city from the first region, a city from the second region and connect them by a road so as to minimize the length of the longest path in the resulting region. If there are multiple ways to do so, you are allowed to choose any of them.
Dima finds it hard to execute Andrew's queries, so he asks you to help him. Help Dima.
The first line contains three integers n, m, q (1 ≤ n ≤ 3·105; 0 ≤ m < n; 1 ≤ q ≤ 3·105) — the number of cities, the number of the roads we already have and the number of queries, correspondingly.
Each of the following m lines contains two integers, ai and bi (ai ≠ bi;1 ≤ ai, bi ≤ n). These numbers represent the road between cities ai and bi. There can be at most one road between two cities.
Each of the following q lines contains one of the two events in the following format:
1xi. It is the request Andrew gives to Dima to find the length of the maximum path in the region that contains city xi (1 ≤ xi ≤ n).
2xiyi. It is the request Andrew gives to Dima to merge the region that contains city xi and the region that contains city yi (1 ≤ xi, yi ≤ n). Note, that xi can be equal to yi.
Output
For each event of the first type print the answer on a separate line.
Input
6 0 6
2 1 2
2 3 4
2 5 6
2 3 2
2 5 3
1 1
Output
4
##题意:
给出n个城市和m条已建的双向道路, 其中互相联通的城市组成一个区域.
接着给出q个操作:
1. 查询城市x所在的区域中最长的简单路径.
2. 合并城市x和y所在的区域(新增一条连接两区域的道路),且要求合并后新区域中的最长的简单路径最短.
##题解:
首先很容易想到城市之间的连通性应该用并查集来维护.
第一次想到的思路是带权并查集(最近正在练):
对应每个点维护其到根节点的距离; 维护当前点作为端点时的最长边和次长边.
鉴于操作2的要求:合并区间时应比较两区域根节点(根节点相连一定是最短的)的最长简单路径,把短的合并到长的上.
(路径压缩时更新到根节点的距离; 合并时更新最长和次长边).
以上思路并没有错误,而且可以完美地处理两种操作.(附上代码:WA on test 2).
WA的原因是:对于原本已建的m条道路,不能按照上述合并操作来进行(因为已建道路的两端点是确定的).
所以对于先建的m条边,要想继续沿用上述思路,必须在操作前先处理每个联通块:找出根节点(尽量平衡),并正确建立其他点的父子关系.
很遗憾,上述操作实现上很繁琐.
实际上,对于每个根结点,要想满足上述限制,那么它的最长边和次长边的差值应该不大于1(尽量平衡).所以无需分别维护最长边和次长边.
此外,每个集合内除根节点以外的节点之间的关系并不重要,只需要知道某个点所在区域的根节点即可完成查询和合并操作.
那么对于先建的m条道路就很好处理了:
先前的思路(带权并查集)必须要找出根节点(即路径最长且尽量平衡的点)并维护各子节点之间的关系.
当忽略子节点之间的关系后:只需要任取联通块中的某个节点作为当前集合的“代表”即可(并将集合内的其余结点直接作为代表的子节点). 至于这个代表是否真的在最长路径上,是否平衡都不需要考虑了.
处理先建的m条边:对于每个联通块做两次dfs找出其直径(任取一点找到离它最远的点,然后以此为起点再找最远点).
dfs的过程中把所有子节点的父亲赋成同一个点.
##代码:
``` cpp
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