Queues and Priority Queues are data structures which are known to most computer scientists. The Team Queue, however, is not so well known, though it occurs often in everyday life. At lunch time the queue in front of the Mensa is a team queue, for example.
In a team queue each element belongs to a team. If an element
enters the queue, it first searches the queue from head to tail to
check if some of its teammates (elements of the same team) are
already in the queue. If yes, it enters the queue right behind
them. If not, it enters the queue at the tail and becomes the new
last element (bad luck). Dequeuing is done like in normal queues:
elements are processed from head to tail in the order they appear
in the team queue.
Your task is to write a program that simulates such a team
queue.
Input
The input file will contain one or more test cases. Each test case
begins with the number of teams t ( ). Then t team descriptions
follow, each one consisting of the number of elements belonging to
the team and the elements themselves. Elements are integers in the
range 0 - 999999. A team may consist of up to 1000 elements.
Finally, a list of commands follows. There are three different
kinds of commands:
ENQUEUE x - enter element x into the team queue
DEQUEUE - process the first element and remove it from the
queue
STOP - end of test case
The input will be terminated by a value of 0 for t.
Warning: A test case may contain up to 200000 (two hundred
thousand) commands, so the implementation of the team queue should
be efficient: both enqueing and dequeuing of an element should only
take constant time.
Output
For each test case, first print a line saying ``Scenario #k", where
k is the number of the test case. Then, for each DEQUEUE command,
print the element which is dequeued on a single line. Print a blank
line after each test case, even after the last one.
Sample Input
2
3 101 102 103
3 201 202 203
ENQUEUE 101
ENQUEUE 201
ENQUEUE 102
ENQUEUE 202
ENQUEUE 103
ENQUEUE 203
DEQUEUE
DEQUEUE
DEQUEUE
DEQUEUE
DEQUEUE
DEQUEUE
STOP
2
5 259001 259002 259003 259004 259005
6 260001 260002 260003 260004 260005 260006
ENQUEUE 259001
ENQUEUE 260001
ENQUEUE 259002
ENQUEUE 259003
ENQUEUE 259004
ENQUEUE 259005
DEQUEUE
DEQUEUE
ENQUEUE 260002
ENQUEUE 260003
DEQUEUE
DEQUEUE
DEQUEUE
DEQUEUE
STOP
0
Sample Output
Scenario #1
101
102
103
201
202
203
Scenario #2
259001
259002
259003
259004
259005
260001
题意:有n个队伍。 对于每个ENQUEUE x 命令。 如果x所在的队伍已经在队列中, 则x排在队列中它的队伍的尾巴, 否则排在队列的末尾。 可以理解为队列中的队列的味道。
这题有点蒙,但是弄懂后,感觉自己对队列似乎了解深了许多啊!
//Asimple //#include <bits/stdc++.h> #include <stdio.h> #include <iostream> #include <algorithm> #include <iterator> #include <deque> #include <string> #include <string.h> #include <vector> #include <stack> #include <ctype.h> #include <queue> #include <math.h> #include <stdlib.h> #include <map> #include <set> #include <time.h> #include <bitset> #include <list> using namespace std; #define INF 0xFFFFFFFF typedef long long ll ; typedef list<int>::iterator l_iter; typedef multimap<string,string>::iterator mss_iter; typedef map<string,string>::iterator m_iter; typedef set<int>::iterator s_iter; typedef vector<int>::iterator v_iter; multimap<string,string> mss; const int maxn = 1000; const int Max = 1000000; int n, T, num, cnt; string str; stack<set<int> > stk; map<set<int>, int> m; set<int> s1, s2; queue<int> q; queue<int> qq[maxn]; list<int> L; int a[Max]; int main() { int k = 1 ; while( cin >> T && T ) { while( !q.empty() ) q.pop(); for(int i=0; i<maxn; i++) while( !qq[i].empty() ) qq[i].pop(); memset(a,0,sizeof(a)); //入队 for(int i=0; scanf("%d",&n)==1; i++) { for(int j=0; j<n; j++) { scanf("%d%*c",&num); a[num] = i ; } } cout << "Scenario #" << k << endl ; while(true) { cin >> str ; if( str == "STOP" ) { cout << endl ; break; } if( str == "ENQUEUE" ) { scanf("%d%*c",&num); if( qq[a[num]].empty() ) q.push(a[num]); qq[a[num]].push(num); } if( str == "DEQUEUE" ) { int q_num = q.front(); cout << qq[q_num].front() << endl ; qq[q_num].pop(); if( qq[q_num].empty() ) q.pop(); } } k ++ ; } return 0; }