# 重新安排行程

给你一份航线列表 tickets ，其中 tickets[i] = [from_i, to_i] 表示飞机出发和降落的机场地点。请你对该行程进行重新规划排序。

所有这些机票都属于一个从 JFK（肯尼迪国际机场）出发的先生，所以该行程必须从 JFK 开始。如果存在多种有效的行程，请你按字典排序返回最小的行程组合。

例如，行程 ["JFK", "LGA"] 与 ["JFK", "LGB"] 相比就更小，排序更靠前。

假定所有机票至少存在一种合理的行程。且所有的机票必须都用一次且只能用一次。

示例 1：

输入：tickets = [["MUC","LHR"],["JFK","MUC"],["SFO","SJC"],["LHR","SFO"]]
输出：["JFK","MUC","LHR","SFO","SJC"]

示例 2：

输入：tickets = [["JFK","SFO"],["JFK","ATL"],["SFO","ATL"],["ATL","JFK"],["ATL","SFO"]]
输出：["JFK","ATL","JFK","SFO","ATL","SFO"]
解释：另一种有效的行程是 ["JFK","SFO","ATL","JFK","ATL","SFO"] ，但是它字典排序更大更靠后。

提示：

1 <= tickets.length <= 300
tickets[i].length == 2
from_i.length == 3
to_i.length == 3
from_i 和 to_i 由大写英文字母组成
from_i != to_i

以下错误的选项是？

## aop ### before ```cpp #include using namespace std; ``` ### after ```cpp ``` ## 答案 ```cpp unordered_map rev; int cmp(pair x, pair y) { return rev[x.first] < rev[y.first]; } class Solution { public: unordered_map mp; int cnt = 0; int head[10005], nex[10005], to[10005], tot = 0; int vis[10005]; vector ans; void add(int x, int y) { to[++tot] = y; nex[tot] = head[x]; head[x] = tot; } void euler(int x) { vector> vec; for (int i = head[x]; i; i = nex[i]) { int v = to[i]; if (vis[i]) { continue; } vec.push_back({v, i}); } sort(vec.begin(), vec.end(), cmp); for (int i = 0; i < vec.size(); i++) { if (vis[vec[i].second]) continue; vis[vec[i].second] = 1; euler(vec[i].first); ans.push_back(rev[vec[i].first]); } } vector findItinerary(vector> &tickets) { mp["JFK"] = 1; rev[1] = "JFK"; cnt = 1; for (int i = 0; i < tickets.size(); i++) { string s1 = tickets[i][0], s2 = tickets[i][1]; if (mp[s1]) { mp[s1] = ++cnt; rev[cnt] = s1; } if (mp[s2]) { mp[s2] = ++cnt; rev[cnt] = s2; } add(mp[s1], mp[s2]); } euler(1); ans.push_back(rev[1]); reverse(ans.begin(), ans.end()); return ans; } }; ``` ## 选项 ### A ```cpp class Solution { public: vector ans; unordered_map> ticket; unordered_map> use; bool dfs(string &now, int begin, int n) { if (begin == n) { return true; } else { int size = ticket[now].size(); for (int i = 0; i < size; i++) { if (!use[now][i]) { ans.push_back(ticket[now][i]); use[now][i] = 1; if (dfs(ticket[now][i], begin + 1, n)) return true; ans.pop_back(); use[now][i] = 0; } } } return false; } vector findItinerary(vector> &tickets) { int n = tickets.size(); for (int i = 0; i < n; i++) { int j, n = ticket[tickets[i][0]].size(); for (j = 0; j < n; j++) if (ticket[tickets[i][0]][j] >= tickets[i][1]) break; ticket[tickets[i][0]].insert(ticket[tickets[i][0]].begin() + j, tickets[i][1]); use[tickets[i][0]].push_back(0); } string beginC = "JFK"; ans.push_back(beginC); dfs(beginC, 0, n); return ans; } }; ``` ### B ```cpp class Solution { unordered_map> m; vector ans; public: vector findItinerary(vector> &tickets) { for (auto &t : tickets) m[t[0]].insert(t[1]); dfs("JFK"); reverse(ans.begin(), ans.end()); return ans; } void dfs(string s) { while (m[s].size() != 0) { string to = *m[s].begin(); m[s].erase(m[s].begin()); dfs(to); } ans.push_back(s); } }; ``` ### C ```cpp class Solution { public: struct cmp { bool operator()(const string &a, const string &b) { return a > b; } }; vector findItinerary(vector> tickets) { map m; vector, cmp>> queues; for (auto p : tickets) { if (m.find(p.first) == m.end()) { priority_queue, cmp> newQueue; newQueue.push(p.second); queues.push_back(newQueue); m.insert(make_pair(p.first, queues.size() - 1)); } else { queues[m[p.first]].push(p.second); } } vector ans; stack visitedPlaces; visitedPlaces.push("JFK"); while (!visitedPlaces.empty()) { string current = visitedPlaces.top(); if (m.find(current) == m.end() || queues[m[current]].size() == 0) { ans.push_back(current); visitedPlaces.pop(); } else { visitedPlaces.push(queues[m[current]].top()); queues[m[current]].pop(); } } reverse(ans.begin(), ans.end()); return ans; } }; ```