ACM-ICPC 2018 Xuzhou network Division Preliminary J. Maze Designer
J. Maze Designer
After the long vacation, the maze designer master has to do his job. A tour company gives him a map which is a rectangle. The map consists of N \times MN×M little squares. That is to say, the height of the rectangle is NN and the width of the rectangle is MM. The master knows exactly how the maze is going to use. The tour company will put a couple in two different squares in the maze and make them seek each other. Of course,the master will not make them find each other easily. The only thing the master does is building some wall between some little squares. He knows in that way, wherever the couple is put, there is only one path between them. It is not a difficult thing for him, but he is a considerate man. He also knows that the cost of building every wall between two adjacent squares is different(Nobody knows the reason). As a result, he designs the maze to make the tour company spend the least money to build it.
Now, here's your part. The tour company knows you're the apprentice of the master, so they give you a task. you're given QQ qustions which contain the information of where the couple will be put. You need to figure out the length of the shortest path between them.
However,the master doesn't tell you how he designs the maze, but he believes that you, the best student of himself, know the way. So he goes on vacation again.
Input
The first line of the input contains two integers NN and MM (1 \le N,M \le 5001≤N,M≤500), giving the number of rows and columns of the maze.
The next N \times MN×M lines of the input give the information of every little square in the maze, and their coordinates are in order of (1,1)(1,1) , (1,2)(1,2) \cdots⋯ (1,M)(1,M) , (2,1)(2,1) , (2,2)(2,2) , \cdots⋯ , (2,M)(2,M) , \cdots⋯ ,(N,M)(N,M).
Each line contains two characters DD and RR and two integers aa , bb (0 \le a,b \le 20000000000≤a,b≤2000000000 ), aa is the cost of building the wall between it and its lower adjacent square, and bb is the cost of building the wall between it and its right adjacent square. If the side is boundary, the lacking path will be replaced with X 00.
The next line contains an integer QQ (1 \le Q \le 1000001≤Q≤100000 ), which represents the number of questions.
The next QQ lines gives four integers, x_1x1, y_1y1, x_2x2, y_2y2 ( 1 \le x_11≤x1 , x_2 \le Nx2≤N , 1 \le y_11≤y1 , y_2 \le My2≤M ), which represent two squares and their coordinate are (x_1x1 , y_1y1) and (x_2x2 , y_2y2).
(xx,yy) means row xx and column yy.
It is guaranteed that there is only one kind of maze.
Output
For each question, output one line with one integer which represents the length of the shortest path between two given squares.
Sample input Copy
3 3
D 1 R 9
D 7 R 8
D 4 X 0
D 2 R 6
D 12 R 5
D 3 X 0
X 0 R 10
X 0 R 11
X 0 X 0
3
1 1 3 3
1 2 3 2
2 2 3 1Sample output copy
4
2
2Source title
ACM-ICPC 2018 Xuzhou Division preliminaries network
Questions surface:
There is a space of n * m, the wall can be built in a space between each of the plurality of interrogation, a point from the minimum Q to another point there is only one way and the total cost of construction of the wall and the path length
Ideas:
We began to assume all of the walls have been built, and now start tearing down walls, to ensure that the demolition of the wall must be the biggest, and then calculate the distance between two points
Solution: tearing down walls is to find the maximum spanning distance between two points count with a LCA, because the group asked how
Code:
#include <iostream>
#include <cstdio>
#include <cstring>
#include <algorithm>
#include <cmath>
#include <queue>
#include <stack>
#include <map>
#include <set>
#include <vector>
#include <iomanip>
#define ALL(x) (x).begin(), (x).end()
#define sz(a) int(a.size())
#define rep(i,x,n) for(int i=x;i<n;i++)
#define repd(i,x,n) for(int i=x;i<=n;i++)
#define pii pair<int,int>
#define pll pair<long long ,long long>
#define gbtb ios::sync_with_stdio(false),cin.tie(0),cout.tie(0)
#define MS0(X) memset((X), 0, sizeof((X)))
#define MSC0(X) memset((X), '\0', sizeof((X)))
#define pb push_back
#define mp make_pair
#define fi first
#define se second
#define eps 1e-6
#define gg(x) getInt(&x)
#define chu(x) cout<<"["<<#x<<" "<<(x)<<"]"<<endl
#define du3(a,b,c) scanf("%d %d %d",&(a),&(b),&(c))
#define du2(a,b) scanf("%d %d",&(a),&(b))
#define du1(a) scanf("%d",&(a));
using namespace std;
typedef long long ll;
ll gcd(ll a, ll b) {return b ? gcd(b, a % b) : a;}
ll lcm(ll a, ll b) {return a / gcd(a, b) * b;}
ll powmod(ll a, ll b, ll MOD) {a %= MOD; if (a == 0ll) {return 0ll;} ll ans = 1; while (b) {if (b & 1) {ans = ans * a % MOD;} a = a * a % MOD; b >>= 1;} return ans;}
void Pv(const vector<int> &V) {int Len = sz(V); for (int i = 0; i < Len; ++i) {printf("%d", V[i] ); if (i != Len - 1) {printf(" ");} else {printf("\n");}}}
void Pvl(const vector<ll> &V) {int Len = sz(V); for (int i = 0; i < Len; ++i) {printf("%lld", V[i] ); if (i != Len - 1) {printf(" ");} else {printf("\n");}}}
inline void getInt(int* p);
const int maxn = 300010;
const int inf = 0x3f3f3f3f;
/*** TEMPLATE CODE * * STARTS HERE ***/
int n, m;
#define N maxn
int getid(int x, int y)
{
return m * (x - 1) + y;
}
struct NODE
{
int next;
int dis;
NODE() {
}
NODE(int nn, int dd)
{
next = nn;
dis = dd;
}
};
std::vector<NODE> son[N];
int depth[N], fa[N][21], in[N], a, b;
ll dist[N];
// depth[i] -> i 节点的深度
// fa[i][j] -> i 节点向上移动2^j个节点后的祖先
// fa[i][0] -> i 向上移动1个节点后的祖先,即父节点
// in[i] i节点的入度,用来找树根用的。
// a b 为读边用的。
void addegde(int a, int b, ll dis)
{
cout << a << " " << b << " " << dis << endl;
son[a].push_back(NODE(b, dis));
son[b].push_back(NODE(a, dis));
}
void dfs(int rt, int prev, int dis)
{
depth[rt] = depth[prev] + 1;
dist[rt] = dist[prev] + 1ll;
fa[rt][0] = prev;
for (int i = 1; i < 20; i++)
{
fa[rt][i] = fa[fa[rt][i - 1]][i - 1];
}
for (int i = 0; i < son[rt].size(); i++)
{
if (son[rt][i].next == prev)
continue;
dfs(son[rt][i].next, rt, son[rt][i].dis);
}
}
int LCA(int x, int y)
{
if (depth[x] < depth[y])
swap(x, y);
for (int i = 19; i >= 0; i--)
{
if (depth[x] - (1 << i) >= depth[y])
{
x = fa[x][i];
}
}
if (x == y)
{
return x;
}
for (int i = 19; i >= 0; i--)
{
if (fa[x][i] != fa[y][i])
{
x = fa[x][i];
y = fa[y][i];
}
}
return fa[x][0];
}
ll finddist(int a, int b)
{
ll u = LCA(a, b);
ll L = dist[a] + dist[b] - 2 * dist[u];
return L;
}
struct node
{
int f, t;
ll w;
node() {}
node(int ff, int tt, ll ww)
{
f = ff;
t = tt;
w = ww;
}
bool operator < (const node& b) const
{
return w > b.w;
}
};
std::vector<node> v;
int far[maxn];
void init(int N)
{
repd(i, 1, N)
{
far[i] = i;
}
depth[0] = -1;
}
int findpar(int x)
{
return far[x] == x ? x : far[x] = findpar(far[x]);
}
void mg(int a, int b, ll w)
{
int aa = a;
int bb = b;
a = findpar(a);
b = findpar(b);
if (a != b)
{
far[a] = b;
addegde(aa, bb, w);
}
}
void K()
{
init(n * m);
sort(ALL(v));
for (int i = 0; i < sz(v); ++i)
{
mg(v[i].f, v[i].t, v[i].w);
}
}
int main()
{
//freopen("D:\\code\\text\\input.txt","r",stdin);
//freopen("D:\\code\\text\\output.txt","w",stdout);
gbtb;
cin >> n >> m;
char op;
ll w;
repd(i, 1, n)
{
repd(j, 1, m)
{
cin >> op >> w;
if (op == 'D')
{
v.push_back(node(getid(i, j), getid(i + 1, j), w));
}
cin >> op >> w;
if (op == 'R')
{
v.push_back(node(getid(i, j), getid(i , j + 1), w));
}
}
}
K();
dfs(1, 0, 0ll);
int q;
cin >> q;
int x1, yy1, x2, y2;
while (q--)
{
cin >> x1 >> yy1 >> x2 >> y2;
cout << finddist(getid(x1, yy1), getid(x2, y2)) << endl;
}
return 0;
}
inline void getInt(int* p) {
char ch;
do {
ch = getchar();
} while (ch == ' ' || ch == '\n');
if (ch == '-') {
*p = -(getchar() - '0');
while ((ch = getchar()) >= '0' && ch <= '9') {
*p = *p * 10 - ch + '0';
}
}
else {
*p = ch - '0';
while ((ch = getchar()) >= '0' && ch <= '9') {
*p = *p * 10 + ch - '0';
}
}
}