A. Array Elimination
time limit per test
2 seconds
memory limit per test
512 megabytes
input
standard input
output
standard output

You are given array $$$a_1, a_2, \ldots, a_n$$$, consisting of non-negative integers.

Let's define operation of "elimination" with integer parameter $$$k$$$ ($$$1 \leq k \leq n$$$) as follows:

  • Choose $$$k$$$ distinct array indices $$$1 \leq i_1 < i_2 < \ldots < i_k \le n$$$.
  • Calculate $$$x = a_{i_1} ~ \& ~ a_{i_2} ~ \& ~ \ldots ~ \& ~ a_{i_k}$$$, where $$$\&$$$ denotes the bitwise AND operation (notes section contains formal definition).
  • Subtract $$$x$$$ from each of $$$a_{i_1}, a_{i_2}, \ldots, a_{i_k}$$$; all other elements remain untouched.

Find all possible values of $$$k$$$, such that it's possible to make all elements of array $$$a$$$ equal to $$$0$$$ using a finite number of elimination operations with parameter $$$k$$$. It can be proven that exists at least one possible $$$k$$$ for any array $$$a$$$.

Note that you firstly choose $$$k$$$ and only after that perform elimination operations with value $$$k$$$ you've chosen initially.

Input

Each test contains multiple test cases. The first line contains the number of test cases $$$t$$$ ($$$1 \leq t \leq 10^4$$$). Description of the test cases follows.

The first line of each test case contains one integer $$$n$$$ ($$$1 \leq n \leq 200\,000$$$) — the length of array $$$a$$$.

The second line of each test case contains $$$n$$$ integers $$$a_1, a_2, \ldots, a_n$$$ ($$$0 \leq a_i < 2^{30}$$$) — array $$$a$$$ itself.

It's guaranteed that the sum of $$$n$$$ over all test cases doesn't exceed $$$200\,000$$$.

Output

For each test case, print all values $$$k$$$, such that it's possible to make all elements of $$$a$$$ equal to $$$0$$$ in a finite number of elimination operations with the given parameter $$$k$$$.

Print them in increasing order.

Example
Input
5
4
4 4 4 4
4
13 7 25 19
6
3 5 3 1 7 1
1
1
5
0 0 0 0 0
Output
1 2 4
1 2
1
1
1 2 3 4 5
Note

In the first test case:

  • If $$$k = 1$$$, we can make four elimination operations with sets of indices $$$\{1\}$$$, $$$\{2\}$$$, $$$\{3\}$$$, $$$\{4\}$$$. Since $$$\&$$$ of one element is equal to the element itself, then for each operation $$$x = a_i$$$, so $$$a_i - x = a_i - a_i = 0$$$.
  • If $$$k = 2$$$, we can make two elimination operations with, for example, sets of indices $$$\{1, 3\}$$$ and $$$\{2, 4\}$$$: $$$x = a_1 ~ \& ~ a_3$$$ $$$=$$$ $$$a_2 ~ \& ~ a_4$$$ $$$=$$$ $$$4 ~ \& ~ 4 = 4$$$. For both operations $$$x = 4$$$, so after the first operation $$$a_1 - x = 0$$$ and $$$a_3 - x = 0$$$, and after the second operation — $$$a_2 - x = 0$$$ and $$$a_4 - x = 0$$$.
  • If $$$k = 3$$$, it's impossible to make all $$$a_i$$$ equal to $$$0$$$. After performing the first operation, we'll get three elements equal to $$$0$$$ and one equal to $$$4$$$. After that, all elimination operations won't change anything, since at least one chosen element will always be equal to $$$0$$$.
  • If $$$k = 4$$$, we can make one operation with set $$$\{1, 2, 3, 4\}$$$, because $$$x = a_1 ~ \& ~ a_2 ~ \& ~ a_3 ~ \& ~ a_4$$$ $$$= 4$$$.

In the second test case, if $$$k = 2$$$ then we can make the following elimination operations:

  • Operation with indices $$$\{1, 3\}$$$: $$$x = a_1 ~ \& ~ a_3$$$ $$$=$$$ $$$13 ~ \& ~ 25 = 9$$$. $$$a_1 - x = 13 - 9 = 4$$$ and $$$a_3 - x = 25 - 9 = 16$$$. Array $$$a$$$ will become equal to $$$[4, 7, 16, 19]$$$.
  • Operation with indices $$$\{3, 4\}$$$: $$$x = a_3 ~ \& ~ a_4$$$ $$$=$$$ $$$16 ~ \& ~ 19 = 16$$$. $$$a_3 - x = 16 - 16 = 0$$$ and $$$a_4 - x = 19 - 16 = 3$$$. Array $$$a$$$ will become equal to $$$[4, 7, 0, 3]$$$.
  • Operation with indices $$$\{2, 4\}$$$: $$$x = a_2 ~ \& ~ a_4$$$ $$$=$$$ $$$7 ~ \& ~ 3 = 3$$$. $$$a_2 - x = 7 - 3 = 4$$$ and $$$a_4 - x = 3 - 3 = 0$$$. Array $$$a$$$ will become equal to $$$[4, 4, 0, 0]$$$.
  • Operation with indices $$$\{1, 2\}$$$: $$$x = a_1 ~ \& ~ a_2$$$ $$$=$$$ $$$4 ~ \& ~ 4 = 4$$$. $$$a_1 - x = 4 - 4 = 0$$$ and $$$a_2 - x = 4 - 4 = 0$$$. Array $$$a$$$ will become equal to $$$[0, 0, 0, 0]$$$.

Formal definition of bitwise AND:

Let's define bitwise AND ($$$\&$$$) as follows. Suppose we have two non-negative integers $$$x$$$ and $$$y$$$, let's look at their binary representations (possibly, with leading zeroes): $$$x_k \dots x_2 x_1 x_0$$$ and $$$y_k \dots y_2 y_1 y_0$$$. Here, $$$x_i$$$ is the $$$i$$$-th bit of number $$$x$$$, and $$$y_i$$$ is the $$$i$$$-th bit of number $$$y$$$. Let $$$r = x ~ \& ~ y$$$ is a result of operation $$$\&$$$ on number $$$x$$$ and $$$y$$$. Then binary representation of $$$r$$$ will be $$$r_k \dots r_2 r_1 r_0$$$, where:

$$$$$$ r_i = \begin{cases} 1, ~ \text{if} ~ x_i = 1 ~ \text{and} ~ y_i = 1 \\ 0, ~ \text{if} ~ x_i = 0 ~ \text{or} ~ y_i = 0 \end{cases} $$$$$$