Luogu2482 [SDOI2010]猪国杀 ---- 模拟

Luogu2482 [SDOI2010]猪国杀

题意

......

https://www.luogu.org/problemnew/show/P2482

总结

首先说一下代码的构思：

首先确定了所有的状态表示（例如游戏中游戏结束，不管有没有用），然后确定了所有属性什么的。

然后构思结构体的表达，并且从全局代码考虑需不需要这样设计（因为这个重构了一次，一开始写的结构体内的表示方法代码量大）

然后在结构体内写函数

然后提前分配好一些会用的全局变量，保存状态

然后先把程序入口输入输出写了

然后按照回合分函数，有一个回合分配函数，有一个出牌函数，每张牌都分了主动和被动两种出牌方式，每个函数都带有返回值（后面删掉了一些）

例如无懈可击的发起方有一个Cal_J函数然后去寻找目标，然后在Pas_J中处理猪的关系

例如给扣血的猪“办手续”，从扣血到死亡判定等等

在这中间打好注释，写好调试函数（例如在我的头文件模板中有Debug多参数函数）同时打好assert防止一些不必要的小地方出错（可以用Debug宏）

然后写一些细节函数，例如献殷勤表敌意

然后就是调节代码顺序，调试代码

一些经验吧......

1. 提前分配好一些比较好的变量名
2. 建议先声明函数再定义函数
3. 打开Dev-C++的代码结构或者自己在草稿纸上写结构
4. 每次调试之前自己浏览一遍代码并手推一遍样例，特别是修改了之后注意自己修改的地方，不要编译了历史版本
5. 不要写的十分复杂，能简单写简单写
6. 善用assert
7. 善用注释

//Created By Creeper_LKF
//Caution::We used "pragma" in the code
#include <cstdio>
#include <cctype>
#include <cassert>
#include <cstdlib>
#include <cstring>
#include <iostream>

#ifdef __gnu_linux__

#include <fcntl.h>
#include <unistd.h>
#include <sys/mman.h>

#endif

#if __cplusplus < 201103L

#include <stdarg.h>

#endif

//Algorithm Heads

#include <list>
#include <queue>
#include <vector>

using namespace std;

//FILE_NAME DEFINATION

const char file_name[] = "b";

#define NAME_SPACE
#define USING

#ifdef NAME_SPACE
namespace LKF{
#endif
    #define SF_READ
    #define EOF_READ
    // #define NEED_FILE
    // #define WRITE_ENDL
    // #define FAST_WRITE
    const size_t MAX_BUF_SIZE = 50000000;

    #ifdef FAST_WRITE
    char outp[MAX_BUF_SIZE], *op = outp;
    #endif

    #ifdef DONLINE_JUDGE
    #undef NEED_FILE
    #endif    

    #ifdef FAST_WRITE
    #ifndef WRITE_ENDL
    #define WRITE_ENDL
    #endif
    #endif

    extern inline void FILE_OPT(){
        #ifdef NEED_FILE
        #define FILE_NAME file_name
        char IN_FILE[sizeof(FILE_NAME) + 5], OUT_FILE[sizeof(FILE_NAME) + 5];
        strcpy(IN_FILE, FILE_NAME), strcpy(OUT_FILE, FILE_NAME);
        strcat(IN_FILE, ".in"), strcat(OUT_FILE, ".out");
        freopen(IN_FILE, "r", stdin);
        freopen(OUT_FILE, "w", stdout);  
        #endif      
    }

    #ifdef __gnu_linux__

    char *pc;

    extern inline void Main_Init(){
        static bool INITED = false;
        if(INITED){
            #ifdef FAST_WRITE
            fwrite(outp, 1, op - outp - 1, stdout);
            #endif
            fclose(stdin), fclose(stdout);
        } else {
            FILE_OPT();
            pc = (char *) mmap(NULL, lseek(0, 0, SEEK_END), PROT_READ, MAP_PRIVATE, 0, 0);
            INITED = true;
        }
    }

    #else

    char buf[MAX_BUF_SIZE], *pc = buf;

    extern inline void Main_Init(){
        static bool INITED = false;
        if(INITED){
            #ifdef FAST_WRITE
            fwrite(outp, 1, op - outp - 1, stdout);
            #endif
            fclose(stdin), fclose(stdout);
        } else {
            FILE_OPT();
            fread(buf, 1, MAX_BUF_SIZE, stdin); 
            INITED = true;           
        }
    }

    #endif

    #ifdef EOF_READ

    #ifdef SF_READ

    template<typename T>
    static inline void read(T &num){
        num = 0;
        char c, sf = 1;
        while(isspace(c = *pc++));
        if(c == 45) sf = -1, c = *pc ++;
        while(num = num * 10 + c - 48, isdigit(c = *pc++));
        num *= sf;
    }

    static inline int read(){
        int num = 0;
        char c, sf = 1;
        while(isspace(c = *pc++));
        if(c == 45) sf = -1, c = *pc ++;
        while(num = num * 10 + c - 48, isdigit(c = *pc++));
        return num * sf;
    }

    #else

    template<typename T>
    static inline T read(T &num){
        num = 0;
        char c;
        while (isspace(c = *pc++));
        while (num = num * 10 + c - 48, isdigit(c = *pc++));
        return num;
    }

    static inline int read(){
        int num = 0;
        char c;
        while (isspace(c = *pc++));
        while (num = num * 10 + c - 48, isdigit(c = *pc++));
        return num;
    }

    #endif

    #else

    #ifdef SF_READ

    template<typename T>
    static inline void read(T &num){
        num = 0;
        char c, sf = 1;
        while((c = *pc++) < 45);
        if(c == 45) sf = -1, c = *pc ++;
        while(num = num * 10 + c - 48, (c = *pc++) >= 48);
        num *= sf;
    }

    static inline int read(){
        int num = 0;
        char c, sf = 1;
        while((c = *pc++) < 45);
        if(c == 45) sf = -1, c = *pc ++;
        while(num = num * 10 + c - 48, (c = *pc++) >= 48);
        return num * sf;
    }

    #else

    template<typename T>
    static inline T read(T &num){
        num = 0;
        char c;
        while ((c = *pc++) < 48);
        while (num = num * 10 + c - 48, (c = *pc++) >= 48);
        return num;
    }

    static inline int read(){
        int num = 0;
        char c;
        while ((c = *pc++) < 48);
        while (num = num * 10 + c - 48, (c = *pc++) >= 48);
        return num;
    }

    #endif

    #endif

    #ifdef FAST_WRITE
    template <typename T>
    inline void Call_Write(char Split, T tar){
        char buf[20];
        int top = 0;
        if(tar == 0) *op ++ = 48;
        else {
            if(tar < 0) *op ++ = '-';
            while(tar) buf[++top] = tar % 10, tar /= 10;
            while(top) *op ++ = buf[top --] ^ 48;
        }
        *op ++ = Split;
    }
    template <typename T>
    inline void Call_Write(T tar){
        char buf[20];
        int top = 0;
        if(tar == 0) *op ++ = 48;
        else {
            if(tar < 0) *op ++ = '-';
            while(tar) buf[++top] = tar % 10, tar /= 10;
            while(top) *op ++ = buf[top --] ^ 48;
        }
    }
    #endif

    #ifdef FAST_WRITE

    extern inline void write(){
        *op ++ = '\n';
    }

    template<typename T>
    extern inline void write(T tar){
        Call_Write(tar);
        #ifdef WRITE_ENDL
        write();
        #endif
    }

    #if __cplusplus >= 201103L

    # pragma GCC diagnostic push
    # pragma GCC diagnostic ignored "-Wunused-parameter"

    template<typename T>
    extern inline void write(char Split, T tar){
        Call_Write(tar);
        #ifdef WRITE_ENDL
        write();
        #endif
    }

    # pragma GCC diagnostic pop
    # pragma message "Warning : pragma used"

    template<typename Head, typename T, typename... Tail>
    extern inline void write(char Split, Head head, T mid, Tail... tail){
        Call_Write(Split, head);
        write(Split, mid, tail...);
    }

    #else

    template <typename T>
    extern inline void write(char Split, T tar){
        Call_Write(tar);
        #ifdef WRITE_ENDL
        write();
        #endif
    }

    #endif

    #else

    extern inline void write(){
        cout << endl;
    }

    template<typename T>
    extern inline void write(T tar){
        cout << tar;
        #ifdef WRITE_ENDL
        write();
        #endif
    }

    #if __cplusplus >= 201103L

    template<typename T>
    extern inline void write(char Split, T tar){
        cout << tar << Split;
    }

    template<typename Head, typename T, typename... Tail>
    extern inline void write(char Split, Head head, T mid, Tail... tail){
        cout << head;
        write(Split, mid, tail...);
    }

    #else

    template <typename T>
    extern inline void write(char Split, T tar){
        cout << tar << Split;
        #ifdef WRITE_ENDL
        write();
        #endif
    }

    #endif

    #endif

    template <typename T>
    extern inline void upmax(T &x, const T &y){
        if(x < y) x = y;
    }
    template <typename T>
    extern inline void upmin(T &x, const T &y){
        if(x > y) x = y;
    }

    #if __cplusplus >= 201103L

    template<typename T>
    extern inline T max(T tar){
        return tar;
    }

    template<typename T>
    extern inline T min(T tar){
        return tar;
    }

    template <typename Head, typename T, typename... Tail>
    extern inline Head max(Head head, T mid, Tail... tail){
        Head tmp = max(mid, tail...);
        return head > tmp ? head : tmp;
    }
    template <typename Head, typename T, typename... Tail>
    extern inline Head min(Head head, T mid, Tail... tail){
        Head tmp = min(mid, tail...);
        return head < tmp ? head : tmp;
    }

    #else

    template <typename T>
    extern inline T max(T a, T b){
        return a > b ? a : b;
    }
    template <typename T>
    extern inline T min(T a, T b){
        return a < b ? a : b;
    }    

    #endif

    template <typename T>
    extern inline T abs(T tar){
        return tar < 0 ? -tar : tar;
    }
    template <typename T>
    extern inline void swap(T &a, T &b){
        int t = a;
        a = b;
        b = t;
    }
#ifdef NAME_SPACE
}
#endif

//Algorithm

#ifdef NAME_SPACE
namespace LKF{
#endif

    template <typename T>
    struct Queue{
        size_t s, t;
        T *q;
        Queue(){
            s = 1, t = 0;
            q = NULL;
        }
        Queue(size_t siz){
            q = (T*)malloc(sizeof(T) * siz);
            assert(q != NULL);
        }
        ~Queue(){
            delete[] q;
        }
        inline void clear(){
            s = 1, t = 0;
        }
        inline bool empty(){
            return s > t;
        }
        inline size_t size(){
            return t - s + 1;
        }
        inline void push(T tar){
            q[++t] = tar;
        }
        inline void pop_front(){
            s++;
        }
        inline void pop_back(){
            t++;
        }
        inline T front(){
            return q[s];
        }
        inline T back(){
            return q[t];
        }
    };

#ifdef NAME_SPACE
}
#endif

#ifdef USING

#ifdef NAME_SPACE
using LKF::read;
using LKF::Main_Init;
using LKF::write;
using LKF::upmax;
using LKF::upmin;
using LKF::max;
using LKF::min;
using LKF::abs;
// using LKF::swap;
#else
using ::read;
using ::Main_Init;
using ::write;
using ::upmax;
using ::upmin;
using ::max;
using ::min;
using ::abs;
// using ::swap;
#endif

#endif

//Source Code

using namespace std;

typedef list<int> CARD;

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~Debug_Part~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
#if DEBUG

//Caution: Do Not Inline
//Do Not Open In Dev_CPP

void Print_Array(int s, int t, int *arr, string Name){
    cout << Name << " Begin" << endl;
    for(int i = s; i < t; i++) cout << arr[i] << ' ';
    cout << Name << " End" << endl;
}

void Print_List(CARD::iterator B, CARD::iterator E, string Name){
    cout << Name << " Begin" << endl;
    for(CARD::iterator it = B; it != E; it++)
        cout << *it << ' ';
    cout << Name << " End" << endl;
}


#endif
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~Read_Part~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//This is SDOI2010 Killer of Pig Kingdom
//This is Release Version

inline char get_c(){
    char c;
    while(!isalpha(c = *LKF::pc ++));
    return c;
}

//Caution::
//Do not omit parentheses

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~Const_Part~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

const int MAXN = 15, MAXM = 2018;//数组大小
const int GA = 0, MA = 1;//献殷勤，表敌意
const int ING = 0, MPG = 1, FPG = 2;//游戏状态
const int MP = 1, ZP = 2, AP = 3;//人物身份类型IDF，主猪，忠猪，反猪（同时表示主猪位置）
const int NN = 0, NS = 1, BZ = 2, BF = 3;//表示状态，未跳，类反猪，跳忠，跳反
const int P = 1, K = 2, D = 3;//基础类：桃，杀，闪
const int F = 4, N = 5, W = 6, J = 7;//技能类：决斗，南蛮入侵，万箭齐发，无懈可击
const int Z = 8;//装备类：诸葛连弩
const int FAIL = 0, SUCCEED = 1, GAME_OVER = 2;

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~Variable_Part~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

int n, m, ReM, HP, FZ, Man_Now;
int Heap[MAXM];
int Game_State;

struct Pig{
    int IDF, Health, IDS;//身份，血量，表态
    int HC_CNT[MAXN], Dis[MAXN];//每种牌统计，距离
    bool Death, ST_Z, ST_K;//死亡标记，诸葛连弩装备状态，出杀状态
    CARD HC;//要求每次访问之前都有相应元素
    Pig(){
        Death = false;
        Health = 4;
        IDF = 0;
        HC.clear();
    }
    inline void Add(int tar){//摸牌
        HC.push_back(tar);
        HC_CNT[tar]++;
    }
    inline int Get(){//出牌
        int tar = HC.front();
        HC.pop_front();
        HC_CNT[tar]--;
        return tar;
    }
    inline int Card(int Knd, int Num){//要求严格存在这些牌
        CARD::iterator it;
        int tim = 0;
        for(it = HC.begin(); it != HC.end(); it++){
            if(*it == Knd){
                HC.erase(it);
                HC_CNT[Knd]--;
                tim++;
            }
            if(tim == Num) break;
        }
        #if DEBUG
        assert(tim == Num);
        #endif
        return tim;
    }
}pig[MAXN];

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~Mini_Function__Part~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

inline int CTI(char tar){
    switch(tar){
        case 'P' : return P;
        case 'K' : return K;
        case 'D' : return D;
        case 'F' : return F;
        case 'N' : return N;
        case 'W' : return W;
        case 'J' : return J;
        case 'Z' : return Z;
    }
    return 0;
}

inline char ITC(int tar){
    static char ret[10] = {0, 'P', 'K', 'D', 'F', 'N', 'W', 'J', 'Z', 0};
    return ret[tar];
}

inline int Deal_Card(){//不早说
    if(HP == m) return Heap[m];
    return Heap[++HP];
}

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~Declaring_Part~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

inline void Input();

inline void Solve();

inline void Output();

inline int New_Round(int);

inline void Reset_Dis();

inline int Kill(int, int);

inline int DeaD(int, int);

inline int Dec_Health(int, int);

inline void Gallant(int, int);

inline void Malicious(int, int);

//被调用出牌 开始

inline int Pas_P(int);
inline int Pas_K(int, int);
inline int Pas_D(int);
inline int Pas_F(int, int);
inline int Pas_N(int);
inline int Pas_W(int);
inline int Pas_J(int, int, int);
inline int Pas_Z(int);

//被调用出牌 结束

//主动出牌 开始

inline int Cal_P(int);
inline int Cal_K(int);
inline int Cal_D(int, int);
inline int Cal_F(int);
inline int Cal_N(int);
inline int Cal_W(int);
inline int Cal_J(int, int, int);
inline int Cal_Z(int);

//主动出牌 结束

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~Main_Part~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

int main(){
    Main_Init();
    Input();
    Solve();
    Output();
    return 0;
}

//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~Function_Part~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

inline void Input(){
    ReM = n = read(), m = read();
    for(int i = 1; i <= n; i++){
        char idf = get_c();
        switch(idf){
            case 'M' : pig[i].IDF = MP; break;
            case 'Z' : pig[i].IDF = ZP; break;
            case 'F' : pig[i].IDF = AP, FZ++; break;
        }
        get_c();
        for(int j = 1; j <= 4; j++) pig[i].Add(CTI(get_c()));
    }
    for(int i = 1; i <= m; i++) Heap[i] = CTI(get_c());
}

inline void Solve(){
    if(FZ == 0){
        Game_State = MPG;
        return ;
    }
    Reset_Dis();
    while(Game_State == ING){
        Man_Now++;
        if(Man_Now == n + 1) Man_Now = 1;
        if(pig[Man_Now].Death) continue;
        New_Round(Man_Now);
    }
}

inline void Output(){
    write('\n', Game_State == MPG ? "MP" : "FP");
    for(int i = 1; i <= n; i++){
        if(pig[i].Death) write('\n', "DEAD");
        else {
            CARD::iterator it;
            for(it = pig[i].HC.begin(); it != pig[i].HC.end(); it++){
                write(' ', ITC(*it));
            }
            write();
        }
    }
}

inline int New_Round(int Man){//注意：每次都会重新刷新序列（从头开始）
    pig[Man].Add(Deal_Card()), pig[Man].Add(Deal_Card());
    pig[Man].ST_K = false;
    CARD::iterator it;
    int ret = 0, tar = 0;
//    Print_List(pig[3].HC.begin(), pig[3].HC.end(), "3");
    for(it = pig[Man].HC.begin(); !pig[Man].Death && Game_State == ING && it != pig[Man].HC.end(); ){
        tar = *it, ret = 0;
        switch(tar){
            case P : ret = Cal_P(Man); break;
            case K : if(!pig[Man].ST_K || pig[Man].ST_Z) ret = bool(Cal_K(Man)), pig[Man].ST_K = ret; break;
            // case D : ret = Cal_D(Man); break;
            case F : ret = Cal_F(Man); break;
            case N : ret = Cal_N(Man), ret = 1; break;
            case W : ret = Cal_W(Man), ret = 1; break;
            // case J : ret = Cal_J(Man); break;
            case Z : ret = Cal_Z(Man), ret = 1; break;
        }//要求在各函数内完成牌数统计
        if(ret == FAIL) it++;
        else it = pig[Man].HC.begin();
    }
    return SUCCEED;
}

inline void Reset_Dis(){
    for(int i = 1; i <= n; i++){
        if(pig[i].Death) continue;
        pig[i].Dis[i] = 0;
        for(int j = i - 1, dis_now = ReM; j >= 1; j--){
            if(pig[j].Death) pig[i].Dis[j] = 0;
            else pig[i].Dis[j] = --dis_now;
        }
        for(int j = i + 1, dis_now = 0; j <= n; j++){
            if(pig[j].Death) pig[i].Dis[j] = 0;
            else pig[i].Dis[j] = ++dis_now;
        }
    }
}

inline int Dead(int dst, int scr){//返回0表示未死亡，返回1表示死亡，返回2表示游戏结束
    if(pig[dst].HC_CNT[P] == 0) return bool(Kill(dst, scr)) + 1;
    Pas_P(dst);
    return FAIL;
}

inline int Kill(int dst, int scr){//返回0表示游戏继续，返回1表示MP胜利（状态MPG），返回2表示AP胜利（状态FPG）
    pig[dst].Death = true;
    pig[dst].ST_Z = false;
    pig[dst].HC.clear();
    for(int i = 1; i < 10; i++) pig[dst].HC_CNT[i] = 0;    
    ReM--;
    if(pig[dst].IDF == MP) return Game_State = FPG;
    if(pig[dst].IDF == AP){
        FZ --;
        if(!FZ) return Game_State = MPG;
        pig[scr].Add(Deal_Card()), pig[scr].Add(Deal_Card()), pig[scr].Add(Deal_Card());
    }
    if(pig[dst].IDF == ZP && pig[scr].IDF == MP){
        pig[scr].ST_Z = false;
        pig[scr].HC.clear();
        for(int i = 1; i < 10; i++) pig[scr].HC_CNT[i] = 0;
    }
    Reset_Dis();
    return Game_State = ING;
}

inline int Dec_Health(int dst, int scr){//返回0表示未死亡，返回1表示已死亡，返回2表示游戏结束
    pig[dst].Health --;
    if(pig[dst].Health == 0) return Dead(dst, scr);
    return FAIL;
}

inline void Malicious(int dst, int scr){
    if(pig[scr].IDF == MP) return ;
    #if DEBUG
    if(pig[dst].IDF == MP || pig[dst].IDS == BZ){
        assert(pig[scr].IDF != ZP);
        pig[scr].IDS = BF;
    } else if(pig[dst].IDS == BF){
        assert(pig[scr].IDF != AP);
        pig[scr].IDS = BZ;
    }
    #endif
    #if !DEBUG
    if(pig[dst].IDF == MP || pig[dst].IDS == BZ) pig[scr].IDS = BF;
    else if(pig[dst].IDS == BF) pig[scr].IDS = BZ;
    #endif
}

inline void Gallant(int dst, int scr){
    if(pig[scr].IDF == MP) return ;
    #if DEBUG
    if(pig[dst].IDF == MP || pig[dst].IDS == BZ){
        assert(pig[scr].IDF != AP);
        pig[scr].IDS = BZ;
    } else if(pig[dst].IDS == BF){
        assert(pig[scr].IDF != ZP);
        pig[scr].IDS = BF;
    }
    #endif
    #if !DEBUG
    if(pig[dst].IDF == MP || pig[dst].IDS == BZ) pig[scr].IDS = BZ;
    else if(pig[dst].IDS == BF) pig[scr].IDS = BF;
    #endif
}

inline int Cal_P(int Man){
    if(Pas_P(Man)) return SUCCEED;
    return FAIL;
}

inline int Pas_P(int Man){//要求每次只加1血 
    if(pig[Man].Health == 4 || pig[Man].HC_CNT[P] == 0) return FAIL;
    pig[Man].Card(P, 1);
    pig[Man].Health ++;
    return SUCCEED;
}

inline int Cal_K(int Man){//主动杀部分
    if(pig[Man].IDF == MP){
        for(int i = 1; i < n; i++){
            int j = Man + i;
            if(j > n) j = j - n;
            if(pig[j].Death || pig[Man].Dis[j] > 1) continue;
            if(pig[j].IDS == BF || pig[j].IDS == NS){
                Pas_K(j, Man);
                return Cal_D(j, Man) == GAME_OVER ? GAME_OVER : SUCCEED;
            }
        }
        return FAIL;
    }
    if(pig[Man].IDF == ZP){
        for(int i = 1; i < n; i++){
            int j = Man + i;
            if(j > n) j = j - n;            
            if(pig[j].Death || pig[Man].Dis[j] > 1) continue;
            if(pig[j].IDS == BF){
                Pas_K(j, Man);
                return Cal_D(j, Man) == GAME_OVER ? GAME_OVER : SUCCEED;
            }
        }
        return FAIL;
    }
    if(pig[Man].IDF == AP){
        if(pig[Man].Dis[MP] <= 1){
            Pas_K(MP, Man);
            return Cal_D(MP, Man) == GAME_OVER ? GAME_OVER : SUCCEED;
        }
        for(int i = 1; i < n; i++){
            int j = Man + i;
            if(j > n) j = j - n;            
            if(pig[j].Death || pig[Man].Dis[j] > 1) continue;
            if(pig[j].IDF == MP || pig[j].IDS == BZ){
                Pas_K(j, Man);
                return Cal_D(j, Man) == GAME_OVER ? GAME_OVER : SUCCEED;
            }
        }
        return FAIL;
    }
    return FAIL;
}

inline int Pas_K(int dst, int scr){//允许对id=0的猪判断身份
    if(dst) Malicious(dst, scr);
    if(pig[scr].HC_CNT[K] == 0) return FAIL;
    pig[scr].Card(K, 1);
    return SUCCEED;
}

inline int Cal_D(int dst, int scr){
    if(Pas_D(dst) == FAIL) return Dec_Health(dst, scr);
    return FAIL;
}

inline int Pas_D(int dst){//注意要求dst的方向与K不同
    if(pig[dst].HC_CNT[D] == 0) return FAIL;
    pig[dst].Card(D, 1);
    return SUCCEED;
}

inline int Cal_F(int Man){//返回是否成功出牌
    if(pig[Man].IDF == MP){
        for(int i = 1; i < n; i++){
            int j = Man + i;
            if(j > n) j = j - n;
            if(pig[j].Death) continue;
            if(pig[j].IDS == BF || pig[j].IDS == NS){
                return Pas_F(j, Man), SUCCEED;
            }
        }
        return FAIL;
    }
    if(pig[Man].IDF == ZP){
        for(int i = 1; i < n; i++){
            int j = Man + i;
            if(j > n) j = j - n;            
            if(pig[j].Death) continue;
            if(pig[j].IDS == BF){
                return Pas_F(j, Man), SUCCEED;
            }
        }
        return FAIL;
    }
    if(pig[Man].IDF == AP){//直接表主猪
        return Pas_F(MP, Man), SUCCEED;
        /*for(int i = 1; i < n; i++){
            int j = Man + i;
            if(j > n) j = j - n;            
            if(pig[j].Death) continue;
            if(pig[j].IDF == MP || pig[j].IDS == BZ){
                return Pas_F(j, Man);
            }
        }
        return FAIL;*/
    }
    return FAIL;
}

inline int Pas_F(int dst, int scr){//返回scr出杀的数量
    Malicious(dst, scr);
    pig[scr].Card(F, 1);
    if(Cal_J(dst, scr, GA)) return FAIL;
    #if DEBUG
    assert(!(pig[dst].IDF == MP && pig[scr].IDF == ZP));
    #endif
    if(pig[dst].IDF == ZP && pig[scr].IDF == MP) return Dec_Health(dst, scr), 0;//主猪与忠猪的故事
    int ret = 0;
    while(true){
        if(Pas_K(0, dst) == FAIL) return Dec_Health(dst, scr), ret;
        if(Pas_K(0, scr) == FAIL) return Dec_Health(scr, dst), ret;//WTF???
        ret++;
    }
}

inline int Cal_J(int dst, int scr, int State){//使用无懈可击的发起方（枚举）是对接收方献殷勤还是表敌意，scr用于枚举起点
    if(State == GA){//献殷勤，要求同边。注意逻辑不同，这里是枚举发起方，发起方知道自己的身份
        if(pig[dst].IDF == MP){
            for(int i = 0; i < n; i++){
                int j = scr + i;
                if(j > n) j = j - n;
                if(pig[j].Death) continue;
                if(pig[j].IDF == MP || pig[j].IDF == ZP){
                    if(Pas_J(dst, j, GA)) return Cal_J(j, j, MA) ? FAIL : SUCCEED;
                }
            }
            return FAIL;
        } else if(pig[dst].IDS == BZ){
            for(int i = 0; i < n; i++){
                int j = scr + i;
                if(j > n) j = j - n;
                if(pig[j].Death) continue;
                if(pig[j].IDF == ZP || pig[j].IDF == MP){
                    if(Pas_J(dst, j, GA)) return Cal_J(j, j, MA) ? FAIL : SUCCEED;
                }
            }
            return FAIL;
        } else if(pig[dst].IDS == BF){
            for(int i = 0; i < n; i++){
                int j = scr + i;
                if(j > n) j = j - n;
                if(pig[j].Death) continue;
                if(pig[j].IDF == AP){
                    if(Pas_J(dst, j, GA)) return Cal_J(j, j, MA) ? FAIL : SUCCEED;
                }
            }
            return FAIL;
        }
    } else {
        if(pig[dst].IDF == MP){
            for(int i = 0; i < n; i++){
                int j = scr + i;
                if(j > n) j = j - n;
                if(pig[j].Death) continue;
                if(pig[j].IDF == AP){
                    if(Pas_J(dst, j, MA)) return Cal_J(j, j, MA) ? FAIL : SUCCEED;
                }
            }
            return FAIL;
        } else if(pig[dst].IDS == BZ){
            for(int i = 0; i < n; i++){
                int j = scr + i;
                if(j > n) j = j - n;
                if(pig[j].Death) continue;
                if(pig[j].IDF == AP){
                    if(Pas_J(dst, j, MA)) return Cal_J(j, j, MA) ? FAIL : SUCCEED;
                }
            }
            return FAIL;
        } else if(pig[dst].IDS == BF){
            for(int i = 0; i < n; i++){
                int j = scr + i;
                if(j > n) j = j - n;
                if(pig[j].Death) continue;
                if(pig[j].IDF == MP || pig[j].IDF == ZP){
                    if(Pas_J(dst, j, MA)) return Cal_J(j, j, MA) ? FAIL : SUCCEED;
                }
            }
            return FAIL;
        } else if(pig[dst].IDS == NS){//主猪对类反猪表敌意
            if(Pas_J(dst, MP, MA)) return Cal_J(MP, MP, MA) ? FAIL : SUCCEED;
            return FAIL;
        }
    }
    return FAIL;
}

inline int Pas_J(int dst, int scr, int State){
    if(pig[scr].HC_CNT[J] == 0) return FAIL;
    if(State == GA) Gallant(dst, scr);
    else Malicious(dst, scr);
    pig[scr].Card(J, 1);
    return SUCCEED;
}

inline int Cal_N(int Man){
    assert(Pas_N(Man));
    for(int i = 1; i < n; i++){
        int j = Man + i;
        if(j > n) j = j - n;
        if(pig[j].Death) continue;
        if(Cal_J(j, Man, GA) == SUCCEED) continue;
        if(Pas_K(0, j) == FAIL){
            if(Dec_Health(j, Man) == GAME_OVER) return GAME_OVER;
            if(j == MP && pig[Man].IDS == NN) pig[Man].IDS = NS;
        }
    }
    return SUCCEED;
}

inline int Pas_N(int dst){
    if(pig[dst].HC_CNT[N] == 0) return FAIL;
    pig[dst].Card(N, 1);
    return SUCCEED;
}

inline int Cal_W(int Man){
    assert(Pas_W(Man));
    for(int i = 1; i < n; i++){
        int j = Man + i;
        if(j > n) j = j - n;
        if(pig[j].Death) continue;
        if(Cal_J(j, Man, GA) == SUCCEED) continue;
        if(Pas_D(j) == FAIL){
            if(Dec_Health(j, Man) == GAME_OVER) return GAME_OVER;
            if(j == MP && pig[Man].IDS == NN) pig[Man].IDS = NS;
        }
    }
    return SUCCEED;
}

inline int Pas_W(int dst){
    if(pig[dst].HC_CNT[W] == 0) return FAIL;
    pig[dst].Card(W, 1);
    return SUCCEED;
}

inline int Cal_Z(int Man){
    return Pas_Z(Man);
}

inline int Pas_Z(int dst){
    if(pig[dst].HC_CNT[Z] == 0) return FAIL;
    pig[dst].ST_Z = true;
    pig[dst].Card(Z, 1);
    return SUCCEED;
}