The Harmonization of XOR
Description
You are given an array of exactly $n$ numbers $[1,2,3,\ldots,n]$ along with integers $k$ and $x$.
Partition the array in exactly $k$ non-empty disjoint subsequences such that the bitwise XOR of all numbers in each subsequence is $x$, and each number is in exactly one subsequence. Notice that there are no constraints on the length of each subsequence.
A sequence $a$ is a subsequence of a sequence $b$ if $a$ can be obtained from $b$ by the deletion of several (possibly, zero or all) elements.
For example, for $n = 15$, $k = 6$, $x = 7$, the following scheme is valid:
- $[6,10,11]$, $6 \oplus 10 \oplus 11 = 7$,
- $[5,12,14]$, $5 \oplus 12 \oplus 14 = 7$,
- $[3,9,13]$, $3 \oplus 9 \oplus 13 = 7$,
- $[1,2,4]$, $1 \oplus 2 \oplus 4 = 7$,
- $[8,15]$, $8 \oplus 15 = 7$,
- $[7]$, $7 = 7$,
The following scheme is invalid, since $8$, $15$ do not appear:
- $[6,10,11]$, $6 \oplus 10 \oplus 11 = 7$,
- $[5,12,14]$, $5 \oplus 12 \oplus 14 = 7$,
- $[3,9,13]$, $3 \oplus 9 \oplus 13 = 7$,
- $[1,2,4]$, $1 \oplus 2 \oplus 4 = 7$,
- $[7]$, $7 = 7$.
The following scheme is invalid, since $3$ appears twice, and $1$, $2$ do not appear:
- $[6,10,11]$, $6 \oplus 10 \oplus 11 = 7$,
- $[5,12,14]$, $5 \oplus 12 \oplus 14 = 7$,
- $[3,9,13]$, $3 \oplus 9 \oplus 13 = 7$,
- $[3,4]$, $3 \oplus 4 = 7$,
- $[8,15]$, $8 \oplus 15 = 7$,
- $[7]$, $7 = 7$.
Each test contains multiple test cases. The first line contains an integer $t$ ($1 \le t \le 10^4$) — the number of test cases.
The first and the only line of each test case contains three integers $n$, $k$, $x$ ($1 \le k \le n \le 2 \cdot 10^5$; $1\le x \le 10^9$) — the length of the array, the number of subsequences and the required XOR.
It's guaranteed that the sum of $n$ does not exceed $2 \cdot 10^5$.
For each test case, if it is possible to partition the sequence, print "YES" in the first line. In the $i$-th of the following $k$ lines first print the length $s_i$ of the $i$-th subsequence, then print $s_i$ integers, representing the elements in the $i$-th subsequence. If there are multiple answers, print any. Note that you can print a subsequence in any order.
If it is not possible to partition the sequence, print "NO".
Input
Each test contains multiple test cases. The first line contains an integer $t$ ($1 \le t \le 10^4$) — the number of test cases.
The first and the only line of each test case contains three integers $n$, $k$, $x$ ($1 \le k \le n \le 2 \cdot 10^5$; $1\le x \le 10^9$) — the length of the array, the number of subsequences and the required XOR.
It's guaranteed that the sum of $n$ does not exceed $2 \cdot 10^5$.
Output
For each test case, if it is possible to partition the sequence, print "YES" in the first line. In the $i$-th of the following $k$ lines first print the length $s_i$ of the $i$-th subsequence, then print $s_i$ integers, representing the elements in the $i$-th subsequence. If there are multiple answers, print any. Note that you can print a subsequence in any order.
If it is not possible to partition the sequence, print "NO".
7
15 6 7
11 4 5
5 3 2
4 1 4
6 1 7
11 5 5
11 6 5
YES
3 6 10 11
3 5 12 14
3 3 9 13
3 1 2 4
2 8 15
1 7
YES
2 1 4
2 2 7
2 3 6
5 5 8 9 10 11
NO
YES
4 1 2 3 4
YES
6 1 2 3 4 5 6
NO
NO
Note
In the first test case, we construct the following $6$ subsequences:
- $[6,10,11]$, $6 \oplus 10 \oplus 11 = 7$,
- $[5,12,14]$, $5 \oplus 12 \oplus 14 = 7$,
- $[3,9,13]$, $3 \oplus 9 \oplus 13 = 7$,
- $[1,2,4]$, $1 \oplus 2 \oplus 4 = 7$,
- $[8,15]$, $8 \oplus 15 = 7$,
- $[7]$, $7 = 7$.
In the second test case, we construct the following $4$ subsequences:
- $[1,4]$, $1 \oplus 4 = 5$,
- $[2,7]$, $2 \oplus 7 = 5$,
- $[3,6]$, $3 \oplus 6 = 5$,
- $[5,8,9,10,11]$, $5 \oplus 8 \oplus 9 \oplus 10 \oplus 11 = 5$.
The following solution is considered correct in this test case as well:
- $[1,4]$, $1 \oplus 4 = 5$,
- $[2,7]$, $2 \oplus 7 = 5$,
- $[5]$, $5 = 5$,
- $[3,6,8,9,10,11]$, $3 \oplus 6 \oplus 8 \oplus 9 \oplus 10 \oplus 11 = 5$.