你有一个带有四个圆形拨轮的转盘锁。每个拨轮都有10个数字: '0', '1', '2', '3', '4', '5', '6', '7', '8', '9'
。每个拨轮可以自由旋转:例如把 '9'
变为 '0'
,'0'
变为 '9'
。每次旋转都只能旋转一个拨轮的一位数字。
锁的初始数字为 '0000'
,一个代表四个拨轮的数字的字符串。
列表 deadends
包含了一组死亡数字,一旦拨轮的数字和列表里的任何一个元素相同,这个锁将会被永久锁定,无法再被旋转。
字符串 target
代表可以解锁的数字,你需要给出解锁需要的最小旋转次数,如果无论如何不能解锁,返回 -1
。
示例 1:
**输入:** deadends = ["0201","0101","0102","1212","2002"], target = "0202"
**输出:** 6
**解释:**
可能的移动序列为 "0000" -> "1000" -> "1100" -> "1200" -> "1201" -> "1202" -> "0202"。
注意 "0000" -> "0001" -> "0002" -> "0102" -> "0202" 这样的序列是不能解锁的,
因为当拨动到 "0102" 时这个锁就会被锁定。
示例 2:
**输入:** deadends = ["8888"], target = "0009"
**输出:** 1
**解释:** 把最后一位反向旋转一次即可 "0000" -> "0009"。
示例 3:
**输入:** deadends = ["8887","8889","8878","8898","8788","8988","7888","9888"], target = "8888"
**输出:** -1
**解释:** 无法旋转到目标数字且不被锁定。
提示:
1 <= deadends.length <= 500
deadends[i].length == 4
target.length == 4
target
不在 deadends
之中
target
和 deadends[i]
仅由若干位数字组成
方法一:广度优先搜索 思路与算法
我们可以使用广度优先搜索,找出从初始数字 0000 到解锁数字 target 的最小旋转次数。
具体地,我们在一开始将 (0000, 0) 加入队列,并使用该队列进行广度优先搜索。在搜索的过程中,设当前搜索到的数字为 status,旋转的次数为 step,我们可以枚举 status 通过一次旋转得到的数字。设其中的某个数字为 next_status,如果其没有被搜索过,我们就将 (\textit{next_status}, \textit{step} + 1) 加入队列。如果搜索到了 target,我们就返回其对应的旋转次数。
为了避免搜索到死亡数字,我们可以使用哈希表存储 deadends 中的所有元素,这样在搜索的过程中,我们可以均摊 O(1) 地判断一个数字是否为死亡数字。同时,我们还需要一个哈希表存储所有搜索到的状态,避免重复搜索。
如果搜索完成后,我们仍没有搜索到 target,说明我们无法解锁,返回 -1。
细节
本题中需要注意如下两个细节:
代码
[sol1-C++] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 class Solution {public : int openLock (vector<string>& deadends, string target) { if (target == "0000" ) { return 0 ; } unordered_set<string> dead (deadends.begin(), deadends.end()) ; if (dead.count ("0000" )) { return -1 ; } auto num_prev = [](char x) -> char { return (x == '0' ? '9' : x - 1 ); }; auto num_succ = [](char x) -> char { return (x == '9' ? '0' : x + 1 ); }; auto get = [&](string& status) -> vector<string> { vector<string> ret; for (int i = 0 ; i < 4 ; ++i) { char num = status[i]; status[i] = num_prev (num); ret.push_back (status); status[i] = num_succ (num); ret.push_back (status); status[i] = num; } return ret; }; queue<pair<string, int >> q; q.emplace ("0000" , 0 ); unordered_set<string> seen = {"0000" }; while (!q.empty ()) { auto [status, step] = q.front (); q.pop (); for (auto && next_status: get (status)) { if (!seen.count (next_status) && !dead.count (next_status)) { if (next_status == target) { return step + 1 ; } q.emplace (next_status, step + 1 ); seen.insert (move (next_status)); } } } return -1 ; } };
[sol1-Java] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 class Solution { public int openLock (String[] deadends, String target) { if ("0000" .equals(target)) { return 0 ; } Set<String> dead = new HashSet <String>(); for (String deadend : deadends) { dead.add(deadend); } if (dead.contains("0000" )) { return -1 ; } int step = 0 ; Queue<String> queue = new LinkedList <String>(); queue.offer("0000" ); Set<String> seen = new HashSet <String>(); seen.add("0000" ); while (!queue.isEmpty()) { ++step; int size = queue.size(); for (int i = 0 ; i < size; ++i) { String status = queue.poll(); for (String nextStatus : get(status)) { if (!seen.contains(nextStatus) && !dead.contains(nextStatus)) { if (nextStatus.equals(target)) { return step; } queue.offer(nextStatus); seen.add(nextStatus); } } } } return -1 ; } public char numPrev (char x) { return x == '0' ? '9' : (char ) (x - 1 ); } public char numSucc (char x) { return x == '9' ? '0' : (char ) (x + 1 ); } public List<String> get (String status) { List<String> ret = new ArrayList <String>(); char [] array = status.toCharArray(); for (int i = 0 ; i < 4 ; ++i) { char num = array[i]; array[i] = numPrev(num); ret.add(new String (array)); array[i] = numSucc(num); ret.add(new String (array)); array[i] = num; } return ret; } }
[sol1-C#] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 public class Solution { public int OpenLock (string [] deadends, string target ) { if ("0000" .Equals(target)) { return 0 ; } ISet<string > dead = new HashSet<string >(); foreach (string deadend in deadends) { dead.Add(deadend); } if (dead.Contains("0000" )) { return -1 ; } int step = 0 ; Queue<string > queue = new Queue<string >(); queue.Enqueue("0000" ); ISet<string > seen = new HashSet<string >(); seen.Add("0000" ); while (queue.Count > 0 ) { ++step; int size = queue.Count; for (int i = 0 ; i < size; ++i) { string status = queue.Dequeue(); foreach (string nextStatus in Get (status )) { if (!seen.Contains(nextStatus) && !dead.Contains(nextStatus)) { if (nextStatus.Equals(target)) { return step; } queue.Enqueue(nextStatus); seen.Add(nextStatus); } } } } return -1 ; } public char NumPrev (char x ) { return x == '0' ? '9' : (char ) (x - 1 ); } public char NumSucc (char x ) { return x == '9' ? '0' : (char ) (x + 1 ); } public IList<string > Get (string status ) { IList<string > ret = new List<string >(); char [] array = status.ToCharArray(); for (int i = 0 ; i < 4 ; ++i) { char num = array[i]; array[i] = NumPrev(num); ret.Add(new string (array)); array[i] = NumSucc(num); ret.Add(new string (array)); array[i] = num; } return ret; } }
[sol1-Python3] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 class Solution : def openLock (self, deadends: List [str ], target: str ) -> int : if target == "0000" : return 0 dead = set (deadends) if "0000" in dead: return -1 def num_prev (x: str ) -> str : return "9" if x == "0" else str (int (x) - 1 ) def num_succ (x: str ) -> str : return "0" if x == "9" else str (int (x) + 1 ) def get (status: str ) -> Generator[str , None , None ]: s = list (status) for i in range (4 ): num = s[i] s[i] = num_prev(num) yield "" .join(s) s[i] = num_succ(num) yield "" .join(s) s[i] = num q = deque([("0000" , 0 )]) seen = {"0000" } while q: status, step = q.popleft() for next_status in get(status): if next_status not in seen and next_status not in dead: if next_status == target: return step + 1 q.append((next_status, step + 1 )) seen.add(next_status) return -1
[sol1-JavaScript] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 var openLock = function (deadends, target ) { if (target === '0000' ) { return 0 ; } const dead = new Set (deadends); if (dead.has ("0000" )) { return -1 ; } let step = 0 ; const queue = []; queue.push ("0000" ); const seen = new Set (); seen.add ("0000" ); while (queue.length ) { ++step; const size = queue.length ; for (let i = 0 ; i < size; ++i) { const status = queue.shift (); for (const nextStatus of get (status)) { if (!seen.has (nextStatus) && !dead.has (nextStatus)) { if (nextStatus === target) { return step; } queue.push (nextStatus); seen.add (nextStatus); } } } } return -1 ; }; const numPrev = (x ) => { return x === '0' ? '9' : (parseInt (x) - 1 ) + '' ; } const numSucc = (x ) => { return x === '9' ? '0' : (parseInt (x) + 1 ) + '' ; } const get = (status ) => { const ret = []; const array = Array .from (status); for (let i = 0 ; i < 4 ; ++i) { const num = array[i]; array[i] = numPrev (num); ret.push (array.join ('' )); array[i] = numSucc (num); ret.push (array.join ('' )); array[i] = num; } return ret; }
[sol1-Golang] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 func openLock (deadends []string , target string ) int { const start = "0000" if target == start { return 0 } dead := map [string ]bool {} for _, s := range deadends { dead[s] = true } if dead[start] { return -1 } get := func (status string ) (ret []string ) { s := []byte (status) for i, b := range s { s[i] = b - 1 if s[i] < '0' { s[i] = '9' } ret = append (ret, string (s)) s[i] = b + 1 if s[i] > '9' { s[i] = '0' } ret = append (ret, string (s)) s[i] = b } return } type pair struct { status string step int } q := []pair{{start, 0 }} seen := map [string ]bool {start: true } for len (q) > 0 { p := q[0 ] q = q[1 :] for _, nxt := range get(p.status) { if !seen[nxt] && !dead[nxt] { if nxt == target { return p.step + 1 } seen[nxt] = true q = append (q, pair{nxt, p.step + 1 }) } } } return -1 }
[sol1-C] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 struct HashTable { char str[5 ]; UT_hash_handle hh; }; struct Node { char str[5 ]; int val; }; char num_prev (char x) { return (x == '0' ? '9' : x - 1 ); } char num_succ (char x) { return (x == '9' ? '0' : x + 1 ); } char ** getNextStatus (char * status, int * retSize) { char ** ret = malloc (sizeof (char *) * 8 ); *retSize = 0 ; for (int i = 0 ; i < 4 ; ++i) { char num = status[i]; status[i] = num_prev(num); ret[(*retSize)] = malloc (sizeof (char ) * 5 ); strcpy (ret[(*retSize)++], status); status[i] = num_succ(num); ret[(*retSize)] = malloc (sizeof (char ) * 5 ); strcpy (ret[(*retSize)++], status); status[i] = num; } return ret; } int openLock (char ** deadends, int deadendsSize, char * target) { char str_0[5 ] = "0000" ; if (strcmp (target, str_0) == 0 ) { return 0 ; } struct HashTable * dead = NULL ; struct HashTable * tmp ; for (int i = 0 ; i < deadendsSize; i++) { HASH_FIND(hh, dead, deadends[i], sizeof (char ) * 5 , tmp); if (tmp == NULL ) { tmp = malloc (sizeof (struct HashTable)); strcpy (tmp->str, deadends[i]); HASH_ADD(hh, dead, str, sizeof (char ) * 5 , tmp); } } HASH_FIND(hh, dead, str_0, sizeof (char ) * 5 , tmp); if (tmp != NULL ) { return -1 ; } struct Node q [10001]; int left = 0 , right = 0 ; strcpy (q[right].str, str_0); q[right++].val = 0 ; struct HashTable * seen = NULL ; tmp = malloc (sizeof (struct HashTable)); strcpy (tmp->str, str_0); HASH_ADD(hh, seen, str, sizeof (char ) * 5 , tmp); while (left < right) { char * status = q[left].str; int step = q[left++].val; int nextStatusSize; char ** nextStatus = getNextStatus(status, &nextStatusSize); for (int i = 0 ; i < nextStatusSize; i++) { struct HashTable *tmp1 , *tmp2 ; HASH_FIND(hh, dead, nextStatus[i], sizeof (char ) * 5 , tmp1); HASH_FIND(hh, seen, nextStatus[i], sizeof (char ) * 5 , tmp2); if (tmp1 == NULL && tmp2 == NULL ) { if (strcmp (nextStatus[i], target) == 0 ) { return step + 1 ; } strcpy (q[right].str, nextStatus[i]); q[right++].val = step + 1 ; tmp = malloc (sizeof (struct HashTable)); strcpy (tmp->str, nextStatus[i]); HASH_ADD(hh, seen, str, sizeof (char ) * 5 , tmp); } } } return -1 ; }
复杂度分析
方法二:启发式搜索 概念
我们可以使用启发式搜索更快地找到最小旋转次数。这里我们可以使用 A* 算法。
读者可以自行查阅资料学习关于 A* 算法的基础知识,例如 Wikipedia - A* search algorithm 或 oi-wiki - A* 。它不是本题解的重点,因此这里不再赘述。读者可以阅读下面的段落检验自己的学习成果:
在 A* 算法中,我们需要使用四个距离函数 F(x), G(x), H(x), H^*(x),其中 F(x), G(x), H(x) 是可以求出的,而 H^*(x) 是无法求出的,我们需要用 H(x) 近似 H^*(x)。设起点为 s,终点为 t,这些距离函数的意义如下:
G(x) 表示从起点 s 到节点 x 的「实际」路径长度,注意 G(x) 并不一定是最短的;
H(x) 表示从节点 x 到终点 t 的「估计」最短路径长度,称为启发函数 ;
H^*(x) 表示从节点 x 到终点 t 的「实际」最短路径长度,这是我们在广度优先搜索的过程中无法求出的,我们需要用 H(x) 近似 H^*(x);
F(x) 满足 F(x) = G(x) + H(x),即为从起点 s 到终点 t 的「估计」路径长度。我们总是挑选出最小的 F(x) 对应的 x 进行搜索,因此 A* 算法需要借助优先队列 来实现。
如果读者熟悉求解最短路的 Dijkstra 算法,就可以发现 Dijkstra 算法是 A* 算法在 H(x) \equiv 0 时的特殊情况。
A* 算法具有两个性质:
如果对于任意的节点 x,H(x) \leq H^*(x) 恒成立,即我们「估计」出的从节点 x 到终点 t 的最短路径长度总是不超过「实际」的最短路径长度,那么称启发函数 H(x) 是可接纳的(admissible heuristic)。在这种情况下,A* 算法一定能找到最短路,但同一节点可能需要加入优先队列并搜索多次,即当我们从优先队列中取出节点 x 时,G(x) 并不一定等于从起点到节点 x 的「实际」最短 路径的长度;
如果对于任意的两个节点 x 和 y,并且 x 到 y 有一条长度为 D(x, y) 的有向边,H(x) - H(y) \leq D(x, y) 恒成立,并且 H(t)=0,那么称启发函数 H(x) 是一致的(consistent heuristic)。可以证明,一致的启发函数一定也是可接纳的。在这种情况下,同一节点只会被加入优先队列一次,并搜索不超过一次,即当我们从优先队列中取出节点 x 时,G(x) 一定等于从起点到节点 x 的「实际」最短 路径的长度。
思路与算法
我们可以设计如下的启发函数:
H(\textit{status}) = \sum_{i=0}^3 \left( \begin{aligned} & 将 \textit{status} 的第 i 个数字旋转到与 \textit{target} 的第 i 个数字一致,\ & 最少需要的次数 \end{aligned} \right)
即 H(\textit{status}) 等于不存在死亡数字时最小的旋转次数。根据定义,对于数字 status 和其通过一次旋转得到的数字 next_status,H(\textit{status}) - H(\textit{next_status}) 要么为 1(旋转的那一个数位与 target 更近了),要么为 -1(旋转的那一个数位与 target 更远了),而 D(\textit{status}, \textit{next_status}) = 1,因此我们设计的启发函数是一致的。
我们在 A* 算法中使用该启发函数,即可得到最小的旋转次数。
代码
[sol2-C++] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 struct AStar { static int getH (const string& status, const string& target) { int ret = 0 ; for (int i = 0 ; i < 4 ; ++i) { int dist = abs (int (status[i]) - int (target[i])); ret += min (dist, 10 - dist); } return ret; }; AStar (const string& status, const string& target, int g): status_{status}, g_{g}, h_{getH (status, target)} { f_ = g_ + h_; } bool operator < (const AStar& that) const { return f_ > that.f_; } string status_; int f_, g_, h_; }; class Solution {public : int openLock (vector<string>& deadends, string target) { if (target == "0000" ) { return 0 ; } unordered_set<string> dead (deadends.begin(), deadends.end()) ; if (dead.count ("0000" )) { return -1 ; } auto num_prev = [](char x) -> char { return (x == '0' ? '9' : x - 1 ); }; auto num_succ = [](char x) -> char { return (x == '9' ? '0' : x + 1 ); }; auto get = [&](string& status) -> vector<string> { vector<string> ret; for (int i = 0 ; i < 4 ; ++i) { char num = status[i]; status[i] = num_prev (num); ret.push_back (status); status[i] = num_succ (num); ret.push_back (status); status[i] = num; } return ret; }; priority_queue<AStar> q; q.emplace ("0000" , target, 0 ); unordered_set<string> seen = {"0000" }; while (!q.empty ()) { AStar node = q.top (); q.pop (); for (auto && next_status: get (node.status_)) { if (!seen.count (next_status) && !dead.count (next_status)) { if (next_status == target) { return node.g_ + 1 ; } q.emplace (next_status, target, node.g_ + 1 ); seen.insert (move (next_status)); } } } return -1 ; } };
[sol2-Java] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 class Solution { public int openLock (String[] deadends, String target) { if ("0000" .equals(target)) { return 0 ; } Set<String> dead = new HashSet <String>(); for (String deadend : deadends) { dead.add(deadend); } if (dead.contains("0000" )) { return -1 ; } PriorityQueue<AStar> pq = new PriorityQueue <AStar>((a, b) -> a.f - b.f); pq.offer(new AStar ("0000" , target, 0 )); Set<String> seen = new HashSet <String>(); seen.add("0000" ); while (!pq.isEmpty()) { AStar node = pq.poll(); for (String nextStatus : get(node.status)) { if (!seen.contains(nextStatus) && !dead.contains(nextStatus)) { if (nextStatus.equals(target)) { return node.g + 1 ; } pq.offer(new AStar (nextStatus, target, node.g + 1 )); seen.add(nextStatus); } } } return -1 ; } public char numPrev (char x) { return x == '0' ? '9' : (char ) (x - 1 ); } public char numSucc (char x) { return x == '9' ? '0' : (char ) (x + 1 ); } public List<String> get (String status) { List<String> ret = new ArrayList <String>(); char [] array = status.toCharArray(); for (int i = 0 ; i < 4 ; ++i) { char num = array[i]; array[i] = numPrev(num); ret.add(new String (array)); array[i] = numSucc(num); ret.add(new String (array)); array[i] = num; } return ret; } } class AStar { String status; int f, g, h; public AStar (String status, String target, int g) { this .status = status; this .g = g; this .h = getH(status, target); this .f = this .g + this .h; } public static int getH (String status, String target) { int ret = 0 ; for (int i = 0 ; i < 4 ; ++i) { int dist = Math.abs(status.charAt(i) - target.charAt(i)); ret += Math.min(dist, 10 - dist); } return ret; } }
[sol2-Python3] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 class AStar : @staticmethod def getH (status: str , target: str ) -> int : ret = 0 for i in range (4 ): dist = abs (int (status[i]) - int (target[i])) ret += min (dist, 10 - dist) return ret def __init__ (self, status: str , target: str , g: str ) -> None : self.status = status self.g = g self.h = AStar.getH(status, target) self.f = self.g + self.h def __lt__ (self, other: "AStar" ) -> bool : return self.f < other.f class Solution : def openLock (self, deadends: List [str ], target: str ) -> int : if target == "0000" : return 0 dead = set (deadends) if "0000" in dead: return -1 def num_prev (x: str ) -> str : return "9" if x == "0" else str (int (x) - 1 ) def num_succ (x: str ) -> str : return "0" if x == "9" else str (int (x) + 1 ) def get (status: str ) -> Generator[str , None , None ]: s = list (status) for i in range (4 ): num = s[i] s[i] = num_prev(num) yield "" .join(s) s[i] = num_succ(num) yield "" .join(s) s[i] = num q = [AStar("0000" , target, 0 )] seen = {"0000" } while q: node = heapq.heappop(q) for next_status in get(node.status): if next_status not in seen and next_status not in dead: if next_status == target: return node.g + 1 heapq.heappush(q, AStar(next_status, target, node.g + 1 )) seen.add(next_status) return -1
[sol2-Golang] 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 type astar struct { g, h int status string } type hp []astarfunc (h hp) Len() int { return len (h) }func (h hp) Less(i, j int ) bool { return h[i].g+h[i].h < h[j].g+h[j].h }func (h hp) Swap(i, j int ) { h[i], h[j] = h[j], h[i] }func (h *hp) Push(v interface {}) { *h = append (*h, v.(astar)) }func (h *hp) Pop() interface {} { a := *h; v := a[len (a)-1 ]; *h = a[:len (a)-1 ]; return v }func getH (status, target string ) (ret int ) { for i := 0 ; i < 4 ; i++ { dist := abs(int (status[i]) - int (target[i])) ret += min(dist, 10 -dist) } return } func openLock (deadends []string , target string ) int { const start = "0000" if target == start { return 0 } dead := map [string ]bool {} for _, s := range deadends { dead[s] = true } if dead[start] { return -1 } get := func (status string ) (ret []string ) { s := []byte (status) for i, b := range s { s[i] = b - 1 if s[i] < '0' { s[i] = '9' } ret = append (ret, string (s)) s[i] = b + 1 if s[i] > '9' { s[i] = '0' } ret = append (ret, string (s)) s[i] = b } return } type pair struct { status string step int } h := hp{{0 , getH(start, target), start}} seen := map [string ]bool {start: true } for len (h) > 0 { node := heap.Pop(&h).(astar) for _, nxt := range get(node.status) { if !seen[nxt] && !dead[nxt] { if nxt == target { return node.g + 1 } seen[nxt] = true heap.Push(&h, astar{node.g + 1 , getH(nxt, target), nxt}) } } } return -1 } func abs (x int ) int { if x < 0 { return -x } return x } func min (a, b int ) int { if a < b { return a } return b }
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