Preparando MOJI
For the New Year, Polycarp decided to send postcards to all his $$$n$$$ friends. He wants to make postcards with his own hands. For this purpose, he has a sheet of paper of size $$$w \times h$$$, which can be cut into pieces.
Polycarp can cut any sheet of paper $$$w \times h$$$ that he has in only two cases:
If $$$w$$$ and $$$h$$$ are even at the same time, then Polycarp can cut the sheet according to any of the rules above.
After cutting a sheet of paper, the total number of sheets of paper is increased by $$$1$$$.
Help Polycarp to find out if he can cut his sheet of size $$$w \times h$$$ at into $$$n$$$ or more pieces, using only the rules described above.
The first line contains one integer $$$t$$$ ($$$1 \le t \le 10^4$$$) — the number of test cases. Then $$$t$$$ test cases follow.
Each test case consists of one line containing three integers $$$w$$$, $$$h$$$, $$$n$$$ ($$$1 \le w, h \le 10^4, 1 \le n \le 10^9$$$) — the width and height of the sheet Polycarp has and the number of friends he needs to send a postcard to.
For each test case, output on a separate line:
You can output "YES" and "NO" in any case (for example, the strings yEs, yes, Yes and YES will be recognized as positive).
5 2 2 3 3 3 2 5 10 2 11 13 1 1 4 4
YES NO YES YES YES
In the first test case, you can first cut the $$$2 \times 2$$$ sheet into two $$$2 \times 1$$$ sheets, and then cut each of them into two more sheets. As a result, we get four sheets $$$1 \times 1$$$. We can choose any three of them and send them to our friends.
In the second test case, a $$$3 \times 3$$$ sheet cannot be cut, so it is impossible to get two sheets.
In the third test case, you can cut a $$$5 \times 10$$$ sheet into two $$$5 \times 5$$$ sheets.
In the fourth test case, there is no need to cut the sheet, since we only need one sheet.
In the fifth test case, you can first cut the $$$1 \times 4$$$ sheet into two $$$1 \times 2$$$ sheets, and then cut each of them into two more sheets. As a result, we get four sheets $$$1 \times 1$$$.