104. Little shop of flowers
time limit per test: 0.25 sec.
memory limit per test: 4096 KB
PROBLEM
You want to arrange the window of your flower shop in a most pleasant way. You have F bunches of flowers, each being of a different kind, and at least as many vases ordered in a row. The vases are glued onto the shelf and are numbered consecutively 1 through V, where V is the number of vases, from left to right so that the vase 1 is the leftmost, and the vase V is the rightmost vase. The bunches are moveable and are uniquely identified by integers between 1 and F. These id-numbers have a significance: They determine the required order of appearance of the flower bunches in the row of vases so that the bunch i must be in a vase to the left of the vase containing bunch j whenever i < j. Suppose, for example, you have bunch of azaleas (id-number=1), a bunch of begonias (id-number=2) and a bunch of carnations (id-number=3). Now, all the bunches must be put into the vases keeping their id-numbers in order. The bunch of azaleas must be in a vase to the left of begonias, and the bunch of begonias must be in a vase to the left of carnations. If there are more vases than bunches of flowers then the excess will be left empty. A vase can hold only one bunch of flowers.
Each vase has a distinct characteristic (just like flowers do). Hence, putting a bunch of flowers in a vase results in a certain aesthetic value, expressed by an integer. The aesthetic values are presented in a table as shown below. Leaving a vase empty has an aesthetic value of 0.
V A S E S |
||||||
1 |
2 |
3 |
4 |
5 |
||
Bunches |
1 (azaleas) |
7 |
23 |
-5 |
-24 |
16 |
2 (begonias) |
5 |
21 |
-4 |
10 |
23 |
|
3 (carnations) |
-21 |
5 |
-4 |
-20 |
20 |
According to the table, azaleas, for example, would look great in vase 2, but they would look awful in vase 4.
To achieve the most pleasant effect you have to maximize the sum of aesthetic values for the arrangement while keeping the required ordering of the flowers. If more than one arrangement has the maximal sum value, any one of them will be acceptable. You have to produce exactly one arrangement.
ASSUMPTIONS
Input
Output
Sample Input
3 5 7 23 -5 -24 16 5 21 -4 10 23 -21 5 -4 -20 20
Sample Output
53 2 4 5
思路:动态规划
AC代码:
#include <cstdio> #include <cstring> #include <algorithm> #define INF 0x3fffffff using namespace std; const int maxn = 105; int dp[maxn][maxn], m[maxn][maxn], pos[maxn][maxn]; //用dp[i][j]、pos[i][j]分别表示前i朵花放前j个瓶子时的最大值以及取得这个最大值时第i行的花放到了哪个瓶子中。 int F, V; void print(int i, int j) { if(i != 1) { print(i - 1, pos[i][j] - 1); printf(" %d", pos[i][j]); } else printf("%d", pos[i][j]); } int main() { while(scanf("%d %d", &F, &V) != EOF) { for(int i = 1; i <= F; i++) { for(int j = 1; j <= V; j++) { scanf("%d", &m[i][j]); } } memset(dp, 0xf3, sizeof(dp)); //初始化 for(int i = 1; i <= V; i++) { dp[1][i] = dp[1][i-1]; pos[1][i] = pos[1][i-1]; if(m[1][i] > dp[1][i]) { dp[1][i] = m[1][i]; pos[1][i] = i; } } for(int i = 2; i <= F; i++) { for(int j = i; j <= V; j++) { dp[i][j] = dp[i][j-1]; pos[i][j] = pos[i][j-1]; if(m[i][j] + dp[i-1][j-1] > dp[i][j]) { dp[i][j] = m[i][j] + dp[i-1][j-1]; pos[i][j] = j; } } } printf("%d\n", dp[F][V]); print(F, V); //递归打印路径 printf("\n"); } return 0; }