codeforces#P1688C. Manipulating History

    ID: 32990 远端评测题 1000ms 256MiB 尝试: 0 已通过: 0 难度: (无) 上传者: 标签>constructive algorithmsgreedystrings*1700

Manipulating History

Description

As a human, she can erase history of its entirety. As a Bai Ze (Hakutaku), she can create history out of nothingness.
Perfect Memento in Strict Sense

Keine has the ability to manipulate history.

The history of Gensokyo is a string $s$ of length $1$ initially. To fix the chaos caused by Yukari, she needs to do the following operations $n$ times, for the $i$-th time:

  • She chooses a non-empty substring $t_{2i-1}$ of $s$.
  • She replaces $t_{2i-1}$ with a non-empty string, $t_{2i}$. Note that the lengths of strings $t_{2i-1}$ and $t_{2i}$ can be different.

Note that if $t_{2i-1}$ occurs more than once in $s$, exactly one of them will be replaced.

For example, let $s=$"marisa", $t_{2i-1}=$"a", and $t_{2i}=$"z". After the operation, $s$ becomes "mzrisa" or "marisz".

After $n$ operations, Keine got the final string and an operation sequence $t$ of length $2n$. Just as Keine thinks she has finished, Yukari appears again and shuffles the order of $t$. Worse still, Keine forgets the initial history.

Help Keine find the initial history of Gensokyo!

Recall that a substring is a sequence of consecutive characters of the string. For example, for string "abc" its substrings are: "ab", "c", "bc" and some others. But the following strings are not its substring: "ac", "cba", "acb".

Hacks

You cannot make hacks in this problem.

Each test contains multiple test cases. The first line contains a single integer $T$ ($1 \leq T \leq 10^3$) — the number of test cases. The description of the test cases follows.

The first line of each test case contains a single integer $n$ ($1 \le n < 10 ^ 5$) — the number of operations.

The next $2n$ lines contains one non-empty string $t_{i}$ — the $i$-th string of the shuffled sequence $t$.

The next line contains one non-empty string $s$ — the final string.

It is guaranteed that the total length of given strings (including $t_i$ and $s$) over all test cases does not exceed $2 \cdot 10 ^ 5$. All given strings consist of lowercase English letters only.

It is guaranteed that the initial string exists. It can be shown that the initial string is unique.

For each test case, print the initial string in one line.

Input

Each test contains multiple test cases. The first line contains a single integer $T$ ($1 \leq T \leq 10^3$) — the number of test cases. The description of the test cases follows.

The first line of each test case contains a single integer $n$ ($1 \le n < 10 ^ 5$) — the number of operations.

The next $2n$ lines contains one non-empty string $t_{i}$ — the $i$-th string of the shuffled sequence $t$.

The next line contains one non-empty string $s$ — the final string.

It is guaranteed that the total length of given strings (including $t_i$ and $s$) over all test cases does not exceed $2 \cdot 10 ^ 5$. All given strings consist of lowercase English letters only.

It is guaranteed that the initial string exists. It can be shown that the initial string is unique.

Output

For each test case, print the initial string in one line.

Samples

2
2
a
ab
b
cd
acd
3
z
a
a
aa
yakumo
ran
yakumoran
a
z

Note

Test case 1:

Initially $s$ is "a".

  • In the first operation, Keine chooses "a", and replaces it with "ab". $s$ becomes "ab".
  • In the second operation, Keine chooses "b", and replaces it with "cd". $s$ becomes "acd".

So the final string is "acd", and $t=[$"a", "ab", "b", "cd"$]$ before being shuffled.

Test case 2:

Initially $s$ is "z".

  • In the first operation, Keine chooses "z", and replaces it with "aa". $s$ becomes "aa".
  • In the second operation, Keine chooses "a", and replaces it with "ran". $s$ becomes "aran".
  • In the third operation, Keine chooses "a", and replaces it with "yakumo". $s$ becomes "yakumoran".

So the final string is "yakumoran", and $t=[$"z", "aa", "a", "ran", "a", "yakumo"$]$ before being shuffled.