#include <iostream>#include <vector>#include <stack>using namespace std;//定义一个魔方的结构体 typedef struct mf {	int up; //魔方上行数字 	int down; //魔方下行数字 	char op; //由该操作得到该魔方 	int pre; //记录该魔方的前一个魔方，即在三叉树中的父节点在队列中的下标，用于回溯输出最短到达该目的魔方所经过的变换，此设计很关键 } MF; //比较待插入的魔方是否已经在队列中存在 bool cmp(vector<MF> &mfs, MF mf, char op, int pre) {	for (int i = 0; i < mfs.size(); i++) {		if (mfs[i].up == mf.up && mfs[i].down == mf.down) { //如果队列中已经存在该待插入魔方，则不进行插入，即对三叉树进行剪枝 			return false;		}	}	//队列中不存在该魔方，插入 	mf.pre = pre;	mf.op = op;	mfs.push_back(mf);	return true;}//由于一共有三种操作，所以为三叉树 //操作A 1234 8765 -> 8765 1234 通过result引用来返回进行操作后的魔方 char opA(MF mf, int pre, MF &result) {	int m = mf.up;	int n = mf.down;	mf.up = n;	mf.down = m;	result = mf;	result.pre = pre;	result.op = ‘A‘;	return ‘A‘;}//操作B 1234 8765 -> 4123 5876 char opB(MF mf, int pre, MF &result) {	int up_first = (mf.up % 10) * 1000;	int down_first = (mf.down % 10) * 1000;	int up_last = ((mf.up - (mf.up / 1000) * 1000) - ((mf.up - (mf.up / 1000) * 1000) / 100) * 100) / 10;	int down_last = ((mf.down - (mf.down / 1000) * 1000) - ((mf.down - (mf.down / 1000) * 1000) / 100) * 100) / 10;	mf.up = up_first + (mf.up / 1000) * 100 + ((mf.up - (mf.up / 1000) * 1000) / 100) * 10 + up_last;	mf.down = down_first + (mf.down / 1000) * 100 + ((mf.down - (mf.down / 1000) * 1000) / 100) * 10 + down_last;		result = mf;	result.pre = pre;	result.op = ‘B‘;	return ‘B‘;}//操作C 1234 5678 -> 1624 5738 char opC(MF mf, int pre, MF &result) {	int i1 = (mf.up - (mf.up / 1000) * 1000) / 100;	int i2 = ((mf.up - (mf.up / 1000) * 1000) - i1 * 100) / 10;	int j1 = (mf.down - (mf.down / 1000) * 1000) / 100;	int j2 = ((mf.down - (mf.down / 1000) * 1000) - j1 * 100) / 10;	mf.up = (mf.up / 1000) * 1000 + j1 * 100 + i1 * 10 + mf.up % 10;	mf.down = (mf.down / 1000) * 1000 + j2 * 100 + i2 * 10 + mf.down % 10; 	result = mf;	result.pre = pre;	result.op = ‘C‘;	return ‘C‘;}int main () {	int max;	while(cin >> max && max != -1) {		int find_length = 0;		int target[8];		int value;				for (int i = 0; i < 8; i++) {			cin >> value;			target[i] = value;		}		vector<MF> mfs;		stack<char> ops;		int fp = 0, rp = 0;//fp为头指针，指向当前正在处理的节点，rp为队列尾指针，指向入队的节点		bool success = false;			int up = target[0] * 1000 + target[1] * 100 + target[2] * 10 + target[3]; //目标魔方的上行 		int down = target[7] + target[6] * 10 + target[5] * 100 + target[4] * 1000; //目标魔方的下行 					MF mf;		mf.up = 1234;		mf.down = 8765;		mf.op = ‘ ‘;		mf.pre = -1;		mfs.push_back(mf);		    	//若未找到，则循环查找 		while (mfs[fp].up != up || mfs[fp].down != down) {						//对魔方进行操作，头指针执行正在进行操作的魔方，尾指针执行操作后进入队列的魔方 			MF result;			char a = opA(mfs[fp], fp, result);			//每次进行一次变换后，查看是否为目标态 			if (result.up == up && result.down == down) {			//发现目标魔方，则根据pre来回溯得到操作序列 							while (result.pre != -1) {					ops.push(result.op);					find_length++;					result = mfs[result.pre];//回溯 				}				success = true;				break;			} else if (cmp(mfs, result, a, fp)) {//如果队列中没有该魔方，该魔方进队 				rp++; //尾指针递增 			}						char b = opB(mfs[fp], fp, result);			if (result.up == up && result.down == down) {			//发现目标魔方，则根据pre来回溯得到操作序列 							while (result.pre != -1) {					ops.push(result.op);					find_length++;					result = mfs[result.pre];//回溯 				}				success = true;				break;			} else if (cmp(mfs, result, b, fp)) {				rp++;			}						char c = opC(mfs[fp], fp, result);			if (result.up == up && result.down == down) {			//发现目标魔方，则根据pre来回溯得到操作序列 							while (result.pre != -1) {					ops.push(result.op);					find_length++;					result = mfs[result.pre];//回溯 				}				success = true;				break;			}else if (cmp(mfs, result, c, fp)) {				rp++;			}			fp++; //头指针递增 		}        //如果不能在指定步数内找到，则输出-1 		if (find_length > max) {			cout << -1 << endl;		} else {			cout << find_length << " ";			while (!ops.empty()) { //找到输出由初态变为目标态的过程 				cout << ops.top();				ops.pop();			}			cout << endl;		}	}		return 0;}