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E. Weird LCM Operations
time limit per test
2 seconds
memory limit per test
256 megabytes
input
standard input
output
standard output

Given an integer $$$n$$$, you construct an array $$$a$$$ of $$$n$$$ integers, where $$$a_i = i$$$ for all integers $$$i$$$ in the range $$$[1, n]$$$. An operation on this array is defined as follows:

  • Select three distinct indices $$$i$$$, $$$j$$$, and $$$k$$$ from the array, and let $$$x = a_i$$$, $$$y = a_j$$$, and $$$z = a_k$$$.
  • Update the array as follows: $$$a_i = \operatorname{lcm}(y, z)$$$, $$$a_j = \operatorname{lcm}(x, z)$$$, and $$$a_k = \operatorname{lcm}(x, y)$$$, where $$$\operatorname{lcm}$$$ represents the least common multiple.
Your task is to provide a possible sequence of operations, containing at most $$$\lfloor \frac{n}{6} \rfloor + 5$$$ operations such that after executing these operations, if you create a set containing the greatest common divisors (GCDs) of all subsequences with a size greater than $$$1$$$, then all numbers from $$$1$$$ to $$$n$$$ should be present in this set.

After all the operations $$$a_i \le 10^{18}$$$ should hold for all $$$1 \le i \le n$$$.

We can show that an answer always exists.

Input

The first line contains one integer $$$t$$$ ($$$1 \le t \le 10^2$$$) — the number of test cases. The description of the test cases follows.

The first and only line of each test case contains an integer $$$n$$$ ($$$3 \leq n \leq 3 \cdot 10^{4}$$$) — the length of the array.

It is guaranteed that the sum of $$$n$$$ over all test cases does not exceed $$$3 \cdot 10^{4}$$$.

Output

The first line should contain an integer $$$k$$$ ($$$0 \leq k \leq \lfloor \frac{n}{6} \rfloor + 5$$$) — where $$$k$$$ is the number of operations.

The next $$$k$$$ lines should contain the description of each operation i.e. $$$3$$$ integers $$$i$$$, $$$j$$$ and $$$k$$$, where $$$1 \leq i, j, k \leq n$$$ and all must be distinct.

Example
Input
3
3
4
7
Output
1
1 2 3
1
1 3 4
3
3 5 7
5 6 7
2 3 4
Note

In the third test case, $$$a = [1, 2, 3, 4, 5, 6, 7]$$$.

First operation:

$$$i = 3$$$, $$$j = 5$$$, $$$k = 7$$$

$$$x = 3$$$, $$$y = 5$$$, $$$z = 7$$$.

$$$a = [1, 2, \operatorname{lcm}(y,z), 4, \operatorname{lcm}(x,z), 6, \operatorname{lcm}(x,y)]$$$ = $$$[1, 2, \color{red}{35}, 4, \color{red}{21}, 6, \color{red}{15}]$$$.

Second operation:

$$$i = 5$$$, $$$j = 6$$$, $$$k = 7$$$

$$$x = 21$$$, $$$y = 6$$$, $$$z = 15$$$.

$$$a = [1, 2, 35, 4, \operatorname{lcm}(y,z), \operatorname{lcm}(x,z), \operatorname{lcm}(x,y)]$$$ = $$$[1, 2, 35, 4, \color{red}{30}, \color{red}{105}, \color{red}{42}]$$$.

Third operation:

$$$i = 2$$$, $$$j = 3$$$, $$$k = 4$$$

$$$x = 2$$$, $$$y = 35$$$, $$$z = 4$$$.

$$$a = [1, \operatorname{lcm}(y,z), \operatorname{lcm}(x,z), \operatorname{lcm}(x,y), 30, 105, 42]$$$ = $$$[1, \color{red}{140}, \color{red}{4}, \color{red}{70}, 30, 105, 42]$$$.

Subsequences whose GCD equal to $$$i$$$ is as follows:

$$$\gcd(a_1, a_2) = \gcd(1, 140) = 1$$$

$$$\gcd(a_3, a_4) = \gcd(4, 70) = 2$$$

$$$\gcd(a_5, a_6, a_7) = \gcd(30, 105, 42) = 3$$$

$$$\gcd(a_2, a_3) = \gcd(140, 4) = 4$$$

$$$\gcd(a_2, a_4, a_5, a_6) = \gcd(140, 70, 30, 105) = 5$$$

$$$\gcd(a_5, a_7) = \gcd(30, 42) = 6$$$

$$$\gcd(a_2, a_4, a_6, a_7) = \gcd(140, 70, 105, 42) = 7$$$