// 面试题60:n个骰子的点数
// 题目:把n个骰子扔在地上,所有骰子朝上一面的点数之和为s。输入n,打印出s
// 的所有可能的值出现的概率。
#include <cstdio>
#include <math.h>
int g_maxValue = 6;
// ====================方法一====================
void Probability(int current, int sum, int* pProbabilities);
void PrintProbability_Solution1(int number)
{
if (number < 1)
return;
int maxSum = number * g_maxValue; //n个骰子的最大点数
//注意此时 + 1是因为数组从0计数
int* pProbabilities = new int[maxSum + 1]; //存放点数和s的出现次数
for (int i = number; i <= maxSum; ++i) //为了直观,数组的[0~number-1]没有用
pProbabilities[i] = 0;
for (int i = 1; i <= g_maxValue; ++i) //第一个骰子, i指该骰子的点数
Probability(number, i, pProbabilities);
int total = pow((double)g_maxValue, number); //点数所有可能总数
for (int i = number; i <= maxSum; ++i)
{
double ratio = (double)pProbabilities[i] / total;
printf("%d: %e\n", i, ratio);
}
delete[] pProbabilities;
}
void Probability(int current, int sum, int* pProbabilities) //更新current个骰子点数和
{
if (current == 1)
pProbabilities[sum]++;
else
{
//f(n,s) = f(n-1,s-1) + f(n-1,s-2) + f(n-1,s-3)
// + f(n-1,s-4) + f(n-1,s-5) + f(n-1,s-6)
for (int i = 1; i <= g_maxValue; ++i)
Probability(current - 1, i + sum, pProbabilities); //通过i+sum传递当前点数和
}
}
// ====================方法二====================
// 原理看懂了, 实现没咋看懂
void PrintProbability_Solution2(int number)
{
if (number < 1)
return;
int* pProbabilities[2];
pProbabilities[0] = new int[g_maxValue * number + 1];
pProbabilities[1] = new int[g_maxValue * number + 1];
for (int i = 0; i < g_maxValue * number + 1; ++i)
{
pProbabilities[0][i] = 0;
pProbabilities[1][i] = 0;
}
int flag = 0;
for (int i = 1; i <= g_maxValue; ++i) //第一个骰子, 每个值只出现一次, 第n个数字表示和为n出现的次数
pProbabilities[flag][i] = 1;
for (int k = 2; k <= number; ++k) //从第二个骰子开始
{
for (int i = 0; i < k; ++i) //清空另一个数组的前k项, 以前的统计结果
pProbabilities[1 - flag][i] = 0;
for (int i = k; i <= g_maxValue * k; ++i)
{
pProbabilities[1 - flag][i] = 0;
for (int j = 1; j <= i && j <= g_maxValue; ++j)
pProbabilities[1 - flag][i] += pProbabilities[flag][i - j]; //前一个数组 n-1 ~ n-6之和
}
flag = 1 - flag; //交换数组
}
double total = pow((double)g_maxValue, number);
for (int i = number; i <= g_maxValue * number; ++i)
{
double ratio = (double)pProbabilities[flag][i] / total;
printf("%d: %e\n", i, ratio);
}
delete[] pProbabilities[0];
delete[] pProbabilities[1];
}
// ====================测试代码====================
void Test(int n)
{
printf("Test for %d begins:\n", n);
printf("Test for solution1\n");
PrintProbability_Solution1(n);
printf("Test for solution2\n");
PrintProbability_Solution2(n);
printf("\n");
}
int main(int argc, char* argv[])
{
Test(1);
Test(2);
Test(3);
Test(4);
//Test(11);
Test(0);
return 0;
}
测试代码
分析:第一个解法实质上是动态规划,第二个解法看不懂实现过程。
动态规划:https://blog.csdn.net/whuqin/article/details/6639187
动态规划就是分阶段考虑问题,给出变量,找出相邻阶段间的关系。具体定义给忘了。
1.现在变量有:骰子个数,点数和。当有k个骰子,点数和为n时,出现次数记为f(k,n)。那与k-1个骰子阶段之间的关系是怎样的?
2.当我有k-1个骰子时,再增加一个骰子,这个骰子的点数只可能为1、2、3、4、5或6。那k个骰子得到点数和为n的情况有:
(k-1,n-1):第k个骰子投了点数1
(k-1,n-2):第k个骰子投了点数2
(k-1,n-3):第k个骰子投了点数3
....
(k-1,n-6):第k个骰子投了点数6
在k-1个骰子的基础上,再增加一个骰子出现点数和为n的结果只有这6种情况!
所以:f(k,n)=f(k-1,n-1)+f(k-1,n-2)+f(k-1,n-3)+f(k-1,n-4)+f(k-1,n-5)+f(k-1,n-6)
3.有1个骰子,f(1,1)=f(1,2)=f(1,3)=f(1,4)=f(1,5)=f(1,6)=1。
那代码就容易写了,递归函数,返回和为n出现的次数。所有的和出现次数总和为6^n。
原文地址:https://www.cnblogs.com/ZSY-blog/p/12686470.html
时间: 2024-10-12 17:18:04