Background
For years, computer scientists have been trying to find efficient solutions to different computing problems. For some of them efficient algorithms are already available, these are the "easy" problems like sorting, evaluating a polynomial or finding the shortest path in a graph. For the "hard" ones only exponential-time algorithms are known. The traveling-salesman problem belongs to this latter group. Given a set of N towns and roads between these towns, the problem is to compute the shortest path allowing a salesman to visit each of the towns once and only once and return to the starting point.
Problem
The president of Gridland has hired you to design a program that calculates the length of the shortest traveling-salesman tour for the towns in the country. In Gridland, there is one town at each of the points of a rectangular grid. Roads run from every town in the directions North, Northwest, West, Southwest, South, Southeast, East, and Northeast, provided that there is a neighbouring town in that direction. The distance between neighbouring towns in directions North-South or East-West is 1 unit. The length of the roads is measured by the Euclidean distance. For example, Figure 7 shows 2 * 3-Gridland, i.e., a rectangular grid of dimensions 2 by 3. In 2 * 3-Gridland, the shortest tour has length 6.
Figure 7: A traveling-salesman tour in 2 * 3-Gridland.
Input
The first line contains the number of scenarios.
For each scenario, the grid dimensions m and n will be given as two integer numbers in a single line, separated by a single blank, satisfying 1 < m < 50 and 1 < n < 50.
Output The output for each scenario begins with a line containing "Scenario #i:", where i is the number of the scenario starting at 1. In the next line, print the length of the shortest traveling-salesman tour rounded to two decimal digits. The output for every scenario ends with a blank line.
Sample Input
2 2 2 2 3
Sample Output
Scenario #1: 4.00
Scenario #2: 6.00
题意:给你一个网格,让从一个点出发,访问所有的城市回到起点,规律是如果两个数都是奇数要加0.41;即:a*b-1+sqrt(2.0);否则肯定可以回到起点,直接是a*b;
c代码:
#include<iostream>
#include<algorithm>
using namespace std;
#include<cstdio>
#include<cmath>
int main(){
int T,kase=0;
cin>>T;
while(T--){
int a,b;
double ans;
cin>>a>>b;
if(a&1&&b&1)ans=a*b+0.41;
else ans=(double)a*b;
printf("Scenario #%d:
%.2lf
",++kase,ans);
puts("");
}
return 0;
}
python:
import sys
an=sys.stdin.readline()
t=an.split();
n=int(t[0])
k=0
while n:
n-=1
k+=1
an=sys.stdin.readline()
t=an.split();
a=int(t[0])
b=int(t[1])
if (a%2) and (b%2):
sum=a*b+0.41
else:
sum=a*b
print('Scenario #%d:'%k)
print("%.2f
"%sum)
#真心无奈了,各种出问题,最终发现python的对齐方式这么重要。。。
__author__ = 'cuijunyong'
import math
T = int(raw_input(), 10);
i = 1
while i <= T:
a = raw_input().split();
print "Scenario #%d:" %i;
if((int(a[0]) & 1 == 1) and (int(a[1]) & 1 == 1)):
print "%.2f" %(round((float(a[0])*float(a[1]) + math.sqrt(2) - 1), 2));
else:
print "%.2f" %(round((float(a[0])*float(a[1])), 2));
i += 1;
print ;