uva10285 Longest Run on a Snowboard(dp之记忆化搜索 )

2024-08-30 20:58

本文主要是介绍uva10285 Longest Run on a Snowboard(dp之记忆化搜索 ),希望对大家解决编程问题提供一定的参考价值,需要的开发者们随着小编来一起学习吧!

10285 Longest Run on a Snowboard
Michael likes snowboarding. That’s not very surprising, since snowboarding is really great. The bad
thing is that in order to gain speed, the area must slide downwards. Another disadvantage is that when
you’ve reached the bottom of the hill you have to walk up again or wait for the ski-lift.
Michael would like to know how long the longest run in an area is. That area is given by a grid of
numbers, defining the heights at those points. Look at this example:
1 2 3 4 5
16 17 18 19 6
15 24 25 20 7
14 23 22 21 8
13 12 11 10 9
One can slide down from one point to a connected other one if and only if the height decreases. One
point is connected to another if it’s at left, at right, above or below it. In the sample map, a possible
slide would be 24-17-16-1 (start at 24, end at 1). Of course if you would go 25-24-23-…-3-2-1, it would
be a much longer run. In fact, it’s the longest possible.
Input
The first line contains the number of test cases N . Each test case starts with a line containing the
name (it’s a single string), the number of rows R and the number of columns C. After that follow R
lines with C numbers each, defining the heights. R and C won’t be bigger than 100, N not bigger than
15 and the heights are always in the range from 0 to 100.
Output
For each test case, print a line containing the name of the area, a colon, a space and the length of the
longest run one can slide down in that area.
Sample Input
2
Feldberg 10 5
56 14 51 58 88
26 94 24 39 41
24 16 8 51 51
76 72 77 43 10
38 50 59 84 81
5 23 37 71 77
96 10 93 53 82
94 15 96 69 9
74 0 62 38 96
37 54 55 82 38
Spiral 5 5
1 2 3 4 5
16 17 18 19 6
15 24 25 20 7
Universidad de Valladolid OJ: 10285 – Longest Run on a Snowboard 2/2
14 23 22 21 8
13 12 11 10 9
Sample Output
Feldberg: 7
Spiral: 25

记忆化搜索

/*
Solve:
*/
#include<iostream>
#include<algorithm>
#include<map>
#include<cstdio>
#include<cstdlib>
#include<vector>
#include<cmath>
#include<cstring>
#include<stack>
#include<string>
#include<set>
#include<fstream>
using namespace std;
#define pb push_back
#define cl(a,b) memset(a,b,sizeof(a))
#define bug printf("===\n");
#define rep(a,b) for(int i=a;i<b;i++)
#define rep_(a,b) for(int i=a;i<=b;i++)
#define P pair<int,int>
#define X first
#define Y second
#define vi vector<int>
const int maxn=105;
const int inf=999999999;
typedef long long LL;
void Max(int&a,int b){if(a<b)a=b;}
char name[50];
int a[maxn][maxn];
int dp[maxn][maxn];//end with (i,j) you can get the max length
int n,m;
int dx[]={0,0,1,-1};
int dy[]={1,-1,0,0};int dfs(int x,int y){//表示从(x,y)这个点出发,所能到达的最大长度if(dp[x][y]){return dp[x][y];}int ans=0;for(int i=0;i<4;i++){int xx=dx[i]+x;int yy=dy[i]+y;if(xx>=1&&xx<=n&&yy>=1&&yy<=m&&a[xx][yy]<a[x][y]){ans=max(ans,dfs(xx,yy));//记录下这个点出发的四个方向中最大的那个}}dp[x][y]+=ans+1;//最大值加上当前这个点return dp[x][y];
}int main(){int T;scanf("%d",&T);while(T--){scanf("%s%d%d",name,&n,&m);int mxv=0,pi,pj;for(int i=1;i<=n;i++){for(int j=1;j<=m;j++){scanf("%d",&a[i][j]);if(a[i][j]>mxv){mxv=a[i][j];pi=i;pj=j;}}}cl(dp,0);int mx=1;for(int i=1;i<=n;i++){for(int j=1;j<=m;j++){mx=max(mx,dfs(i,j));//遍历每一个点}}printf("%s: %d\n",name,mx);}return 0;
}
/*
2
Feldberg 10 5
56 14 51 58 88
26 94 24 39 41
24 16 8 51 51
76 72 77 43 10
38 50 59 84 81
5 23 37 71 77
96 10 93 53 82
94 15 96 69 9
74 0 62 38 96
37 54 55 82 38
Spiral 5 5
1 2 3 4 5
16 17 18 19 6
15 24 25 20 7
14 23 22 21 8
13 12 11 10 9
*/

这篇关于uva10285 Longest Run on a Snowboard(dp之记忆化搜索 )的文章就介绍到这儿,希望我们推荐的文章对编程师们有所帮助!



http://www.chinasem.cn/article/1121910

相关文章

认识、理解、分类——acm之搜索

普通搜索方法有两种:1、广度优先搜索;2、深度优先搜索; 更多搜索方法: 3、双向广度优先搜索; 4、启发式搜索(包括A*算法等); 搜索通常会用到的知识点:状态压缩(位压缩,利用hash思想压缩)。

hdu1240、hdu1253(三维搜索题)

1、从后往前输入,(x,y,z); 2、从下往上输入,(y , z, x); 3、从左往右输入,(z,x,y); hdu1240代码如下: #include<iostream>#include<algorithm>#include<string>#include<stack>#include<queue>#include<map>#include<stdio.h>#inc

hdu4826(三维DP)

这是一个百度之星的资格赛第四题 题目链接:http://acm.hdu.edu.cn/contests/contest_showproblem.php?pid=1004&cid=500 题意:从左上角的点到右上角的点,每个点只能走一遍,走的方向有三个:向上,向下,向右,求最大值。 咋一看像搜索题,先暴搜,TLE,然后剪枝,还是TLE.然后我就改方法,用DP来做,这题和普通dp相比,多个个向上

hdu1011(背包树形DP)

没有完全理解这题, m个人,攻打一个map,map的入口是1,在攻打某个结点之前要先攻打其他一个结点 dp[i][j]表示m个人攻打以第i个结点为根节点的子树得到的最优解 状态转移dp[i][ j ] = max(dp[i][j], dp[i][k]+dp[t][j-k]),其中t是i结点的子节点 代码如下: #include<iostream>#include<algorithm

hdu4865(概率DP)

题意:已知前一天和今天的天气概率,某天的天气概率和叶子的潮湿程度的概率,n天叶子的湿度,求n天最有可能的天气情况。 思路:概率DP,dp[i][j]表示第i天天气为j的概率,状态转移如下:dp[i][j] = max(dp[i][j, dp[i-1][k]*table2[k][j]*table1[j][col] )  代码如下: #include <stdio.h>#include

usaco 1.1 Broken Necklace(DP)

直接上代码 接触的第一道dp ps.大概的思路就是 先从左往右用一个数组在每个点记下蓝或黑的个数 再从右到左算一遍 最后取出最大的即可 核心语句在于: 如果 str[i] = 'r'  ,   rl[i]=rl[i-1]+1, bl[i]=0 如果 str[i] = 'b' ,  bl[i]=bl[i-1]+1, rl[i]=0 如果 str[i] = 'w',  bl[i]=b

uva 10154 DP 叠乌龟

题意: 给你几只乌龟,每只乌龟有自身的重量和力量。 每只乌龟的力量可以承受自身体重和在其上的几只乌龟的体重和内。 问最多能叠放几只乌龟。 解析: 先将乌龟按力量从小到大排列。 然后dp的时候从前往后叠,状态转移方程: dp[i][j] = dp[i - 1][j];if (dp[i - 1][j - 1] != inf && dp[i - 1][j - 1] <= t[i]

uva 10118 dP

题意: 给4列篮子,每次从某一列开始无放回拿蜡烛放入篮子里,并且篮子最多只能放5支蜡烛,数字代表蜡烛的颜色。 当拿出当前颜色的蜡烛在篮子里存在时,猪脚可以把蜡烛带回家。 问最多拿多少只蜡烛。 代码: #include <iostream>#include <cstdio>#include <cstdlib>#include <algorithm>#include <cs

uva 10069 DP + 大数加法

代码: #include <iostream>#include <cstdio>#include <cstdlib>#include <algorithm>#include <cstring>#include <cmath>#include <stack>#include <vector>#include <queue>#include <map>#include <cl

uva 10029 HASH + DP

题意: 给一个字典,里面有好多单词。单词可以由增加、删除、变换,变成另一个单词,问能变换的最长单词长度。 解析: HASH+dp 代码: #include <iostream>#include <cstdio>#include <cstdlib>#include <algorithm>#include <cstring>#include <cmath>#inc