There is a $$$n \times m$$$ grid. You are standing at cell $$$(1, 1)$$$ and your goal is to finish at cell $$$(n, m)$$$.
You can move to the neighboring cells to the right or down. In other words, suppose you are standing at cell $$$(x, y)$$$. You can:
Can you reach cell $$$(n, m)$$$ spending exactly $$$k$$$ burles?
The first line contains the single integer $$$t$$$ ($$$1 \le t \le 100$$$) — the number of test cases.
The first and only line of each test case contains three integers $$$n$$$, $$$m$$$, and $$$k$$$ ($$$1 \le n, m \le 100$$$; $$$0 \le k \le 10^4$$$) — the sizes of grid and the exact amount of money you need to spend.
For each test case, if you can reach cell $$$(n, m)$$$ spending exactly $$$k$$$ burles, print YES. Otherwise, print NO.
You may print every letter in any case you want (so, for example, the strings yEs, yes, Yes and YES are all recognized as positive answer).
6 1 1 0 2 2 2 2 2 3 2 2 4 1 4 3 100 100 10000
YES NO YES NO YES NO
In the first test case, you are already in the final cell, so you spend $$$0$$$ burles.
In the second, third and fourth test cases, there are two paths from $$$(1, 1)$$$ to $$$(2, 2)$$$: $$$(1, 1)$$$ $$$\rightarrow$$$ $$$(1, 2)$$$ $$$\rightarrow$$$ $$$(2, 2)$$$ or $$$(1, 1)$$$ $$$\rightarrow$$$ $$$(2, 1)$$$ $$$\rightarrow$$$ $$$(2, 2)$$$. Both costs $$$1 + 2 = 3$$$ burles, so it's the only amount of money you can spend.
In the fifth test case, there is the only way from $$$(1, 1)$$$ to $$$(1, 4)$$$ and it costs $$$1 + 1 + 1 = 3$$$ burles.
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