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find_a_fake_coin.cpp
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//---------------------------------------------------------------------------
#include <iostream>
#include <vector>
#include <cstdio>
#include <conio.h>
#include <cstdlib>
#include <ctime >
#include <cmath >
#include <cassert>
#include <limits.h>
using namespace std;
/**
** 源文件: find_a_fake_coin.cpp
** 功能说明:
** 测试程序,假币问题:有若干金币【3-1000】,存有一假币,且不知假币较轻或较重,用一天枰找出其中的假币且知其轻重,
要求比较次数越少越好。
** 以下程序以分治法,递归的形式求解包括,二分法,三分法和四分法。程序逻辑有一定相似性,但效率不一。整体上效率:
** 三分法 >= 四分法 >= 二分法
** 具体实现,详见源码与注释说明。
** 作者:junkun huang e-mail:[email protected]
** 创建日期:2008-11 前 /
*/
#define WHICH_HEAVY_LEFT -1
#define WHICH_HEAVY_UNKNOWN 0
#define WHICH_HEAVY_RIGHT 1
#define FAKE_STATE_HEAVY 2
#define FAKE_STATE_UNKNOWN 1
#define FAKE_STATE_LIGHT 0
static int s_which_heavy = WHICH_HEAVY_UNKNOWN;//那一边比较重,初始化为0 ,即未确定
static int s_fake_state = FAKE_STATE_UNKNOWN;//假币轻重标志,初始化为1 ,即未确定
static int s_fake_coin = -1; //初始化假币位置
/// 统计不同解法的递归次数
static size_t s_find_2_comp_count = 0;
static size_t s_find_3_comp_count = 0;
static size_t s_find_4_comp_count = 0;
void init()
{
s_fake_coin = -1; //初始化假币位置
s_fake_state = FAKE_STATE_UNKNOWN;//轻重标志,初始化为1 ,即未确定
s_which_heavy = WHICH_HEAVY_UNKNOWN;//那一边比较重,初始化为0 ,即未确定
s_find_2_comp_count = 0;
s_find_3_comp_count = 0;
s_find_4_comp_count = 0;
}
void print_find_result()
{
cout << " 结果, 假币位置:" << s_fake_coin;
if (s_fake_state == FAKE_STATE_LIGHT)
cout << " 假币较轻!";
else if (s_fake_state == FAKE_STATE_HEAVY)
cout << " 假币较重!";
else
cout << " 无假币!";
cout << "比较次数:"<< s_find_2_comp_count+s_find_3_comp_count+s_find_4_comp_count << endl;
}
void uninit()
{
print_find_result();
}
//二分法求解
int sum_coins(const int A[], int from, int to)
{
int sum = 0;
for (int i=from; i <=to; i++)
{
sum += A[i];
}
return sum;
}
//---------------------------------------------------------------------------
bool calc_fake_coin(int A[], int c1, int c2)
{
//在确定真币A[0]的前提下,剩下2个硬币或一个(c1==c2),检测假币的所在位置和轻重。
if (c1 == c2)
{
if (A[0] != A[c1])
{
s_fake_coin = c1;
s_fake_state = (A[0] < A[c1] ? FAKE_STATE_HEAVY : FAKE_STATE_LIGHT);
}
else
return false;
}
if (A[0] == A[c1])
{
s_fake_coin = c2;
if (s_fake_state == FAKE_STATE_UNKNOWN)
s_fake_state = (A[0] < A[c2] ? FAKE_STATE_HEAVY : FAKE_STATE_LIGHT);
}
else
{
s_fake_coin = c1;
if (s_fake_state == FAKE_STATE_UNKNOWN)
s_fake_state = (A[0] < A[c1] ? FAKE_STATE_HEAVY : FAKE_STATE_LIGHT);
}
return true;
}
//---------------------------------------------------------------------------
bool find_a_fake_coin_2(const int A[], int from, int to)
{
// /*/*假币问题求解:二分法*/
++s_find_2_comp_count;
if (to == from)
{
return calc_fake_coin(const_cast<int*>(A), from, to);
}
else
{
if ((to-from+1)%2 == 0)
{
int mid = (from+to)/2;
if (sum_coins(A, from, mid) == sum_coins(A, mid+1, to))
return false;
else
{
if (find_a_fake_coin_2(A, from, mid))
return true;
else
find_a_fake_coin_2(A, mid+1, to);
}
}
else if (A[to] != A[0])
{
s_fake_coin = to;
s_fake_state = A[to] > A[0] ? FAKE_STATE_HEAVY : FAKE_STATE_LIGHT;
return true;
}
else
{
to = to-1;
int mid = (from+to)/2;
if (sum_coins(A, from, mid) == sum_coins(A, mid+1, to))
return false;
else
{
if (find_a_fake_coin_2(A, from, mid))
return true;
else
find_a_fake_coin_2(A, mid+1, to);
}
}
}
return false;
}
//---------------------------------------------------------------------------
void find_a_fake_coin_3(int A[], int from, int to)
{
++s_find_3_comp_count;
// /*假币问题求解:三分法*/
if ((to-from+1) < 3)
{
//
//确定真币的重量--币种
if (from > 1)
A[0] = A[1];
else
A[0] = A[to+1];
calc_fake_coin(A, from, to);
}
else
{
int i = (to-from+1)/3;
int mid1 = from+i-1;
int mid2 = mid1+i;
if (sum_coins(A, from, mid1) == sum_coins(A, mid1+1, mid2))
{
if (s_fake_state == FAKE_STATE_UNKNOWN)
{
//判断假币的轻重
if (s_which_heavy == WHICH_HEAVY_LEFT)
s_fake_state = FAKE_STATE_LIGHT;
if (s_which_heavy == WHICH_HEAVY_RIGHT)
s_fake_state = FAKE_STATE_HEAVY;
}
find_a_fake_coin_3(A, mid2+1, to);
}
else
{
if (s_fake_state == FAKE_STATE_UNKNOWN)
{
//记录轻重情况
if (sum_coins(A, from, mid1) > sum_coins(A, mid1+1, mid2))
s_which_heavy = WHICH_HEAVY_LEFT;
else
s_which_heavy = WHICH_HEAVY_RIGHT;
}
find_a_fake_coin_3(A, from, mid2);
}
}
}
//---------------------------------------------------------------------------
void find_a_fake_coin_4(int A[], int from, int to)
{
// /*/*假币问题求解:四分法*/
++s_find_4_comp_count;
if ((to-from+1) < 4)
{
find_a_fake_coin_3(A, from, to);
}
else
{
int i = (to-from+1)/4;
int mid1 = from+i-1;
int mid2 = mid1+i;
if (sum_coins(A, from, mid1) == sum_coins(A, mid1+1, mid2))
{
// /// 以下注释逻辑存在缺陷,仅适合于三分法。
// if (s_fake_state == FAKE_STATE_UNKNOWN)
// { //判断假币的轻重
// if (s_which_heavy == WHICH_HEAVY_LEFT)
// s_fake_state = FAKE_STATE_LIGHT;
// if (s_which_heavy == WHICH_HEAVY_RIGHT)
// s_fake_state = FAKE_STATE_HEAVY;
// }
find_a_fake_coin_4(A, mid2+1, to);
}
else
{
// /// 以下注释逻辑存在缺陷,仅适合于三分法。
// if (s_fake_state == FAKE_STATE_UNKNOWN)
// { //记录轻重情况
// if (sum_coins(A, from, mid1) > sum_coins(A, mid1+1, mid2))
// s_which_heavy = WHICH_HEAVY_LEFT;
// else
// s_which_heavy = WHICH_HEAVY_RIGHT;
// }
find_a_fake_coin_4(A, from, mid2);
}
}
}
void print_coins(const int pCoins[], int count)
{
cout << "[编号]轻重";
for (int i=1; i <=count; ++i)
{
cout << " [" << i << "]" << pCoins[i];
}
cout << endl;
}
int main()
{
time_t t;
srand((unsigned) time(&t));
char c;
const unsigned MAX_COIN_COUNT = 1000;
int pCoins[MAX_COIN_COUNT];
do
{
system("cls");
/// 至少需要有3个货币才有比较意义!
cout << "\n\n 请输入货币总数【3-1000】: ";
int coin_count = 100;
cin >> coin_count;
if (coin_count <= MAX_COIN_COUNT && coin_count > 2)
{
int fake_s = rand()%2;//随机值:1 假币较重, 0 假币较轻.
int fake_pos = (rand()%coin_count)+1;//随机值,假币出现的位置.
// 测试样例 2 * 100
// for (int fake_s = 0; fake_s < 2; ++fake_s)
// for (int fake_pos = 1; fake_pos <= 100; ++fake_pos)
{
// 初始化pCoins[0]存放真币,作为判断标准!
for (int i=0; i <=coin_count; ++i)
pCoins[i] = 1;
if (fake_s == 0)
pCoins[fake_pos] = 0;
else
pCoins[fake_pos] = 2;
int pos2, pos3, pos4;
int state2, state3, state4;
print_coins(pCoins, coin_count);
cout << "\n 二分法求解:\n";
init();
find_a_fake_coin_2(pCoins, 1, coin_count);
uninit();
pos2 = s_fake_coin;
state2 = s_fake_state;
cout << "\n 三分法求解:\n";
init();
find_a_fake_coin_3(pCoins, 1, coin_count);
uninit();
pos3 = s_fake_coin;
state3 = s_fake_state;
cout << "\n 四分法求解:\n";
init();
find_a_fake_coin_4(pCoins, 1, coin_count);
uninit();
pos4 = s_fake_coin;
state4 = s_fake_state;
cout << " pos:" << pos2 << " " << pos3 << " " << pos4
<< " state:" << state2 << " " << state3 << " " << state4 << "\n";
/// 检测程序结果是否正确!
if (!((pos2 == pos3 && pos3 == pos4) && (state2 == state3 && state3 == state4)))
{
cout << " --- ERROR ---\n";
print_coins(pCoins, coin_count);
}
}
}
else
cout << " 输入有误!";
cout << "\n\n !!!按任意键继续,Esc退出程序!!!" << endl;
}
while( (c=getch())!=27);
return 0;
}