Problem Description
FSF is addicted to a stupid tower defense game. The goal of tower defense games is to try to stop enemies from crossing a map by building traps to slow them down and towers which shoot at them as they pass.
The map is a line, which has n unit length. We can build only one tower on each unit length. The enemy takes t seconds on each unit length. And there are 3 kinds of tower in this game: The red tower, the green tower and the blue tower.
The red tower damage on the enemy x points per second when he passes through the tower.
The green tower damage on the enemy y points per second after he passes through the tower.
The blue tower let the enemy go slower than before (that is, the enemy takes more z second to pass an unit length, also, after he passes through the tower.)
Of course, if you are already pass through m green towers, you should have got m*y damage per second. The same, if you are already pass through k blue towers, the enemy should have took t + k*z seconds every unit length.
FSF now wants to know the maximum damage the enemy can get.
The map is a line, which has n unit length. We can build only one tower on each unit length. The enemy takes t seconds on each unit length. And there are 3 kinds of tower in this game: The red tower, the green tower and the blue tower.
The red tower damage on the enemy x points per second when he passes through the tower.
The green tower damage on the enemy y points per second after he passes through the tower.
The blue tower let the enemy go slower than before (that is, the enemy takes more z second to pass an unit length, also, after he passes through the tower.)
Of course, if you are already pass through m green towers, you should have got m*y damage per second. The same, if you are already pass through k blue towers, the enemy should have took t + k*z seconds every unit length.
FSF now wants to know the maximum damage the enemy can get.
Input
There are multiply test cases.
The first line contains an integer T (T<=100), indicates the number of cases.
Each test only contain 5 integers n, x, y, z, t (2<=n<=1500,0<=x, y, z<=60000,1<=t<=3)
The first line contains an integer T (T<=100), indicates the number of cases.
Each test only contain 5 integers n, x, y, z, t (2<=n<=1500,0<=x, y, z<=60000,1<=t<=3)
Output
For each case, you should output "Case #C: " first,
where C indicates the case number and counts from 1. Then output the answer. For
each test only one line which have one integer, the answer to this
question.
Sample Input
1
2 4 3 2 1
Sample Output
Case #1: 12
#include"iostream" #include"cstdio" #include"cstring" using namespace std; typedef __int64 LL; const int ms=1600; LL dp[ms][ms]; LL max(LL a,LL b) { return a>b?a:b; } int main() { LL ans,b,c;//注意 b和c 要定义为LL,因为后面的计算中含有LL形的数。 int T,p=1; int n,x,y,z,t; scanf("%d",&T); //cin>>T; while(T--) { printf("Case #%d: ",p++); //cout<<"Case #"<<p++<<": "; scanf("%d%d%d%d%d",&n,&x,&y,&z,&t); //cin>>n>>x>>y>>z>>t; memset(dp,0,sizeof(dp)); ans=x*n*t; for(b=0;b<=n;b++) for(c=0;c+b<=n;c++) { dp[b+1][c]=max(dp[b+1][c],dp[b][c]+c*y*(t+b*z)); dp[b][c+1]=max(dp[b][c+1],dp[b][c]+c*y*(t+b*z)); ans=max(ans,dp[b][c]+(n-b-c)*x*(t+b*z)+(n-b-c)*y*c*(t+b*z)); } printf("%I64d ",ans); //cout<<ans<<endl; } return 0; }