On a strip of land of length $$$n$$$ there are $$$k$$$ air conditioners: the $$$i$$$-th air conditioner is placed in cell $$$a_i$$$ ($$$1 \le a_i \le n$$$). Two or more air conditioners cannot be placed in the same cell (i.e. all $$$a_i$$$ are distinct).

Each air conditioner is characterized by one parameter: temperature. The $$$i$$$-th air conditioner is set to the temperature $$$t_i$$$.

Example of strip of length $$$n=6$$$, where $$$k=2$$$, $$$a=[2,5]$$$ and $$$t=[14,16]$$$.

For each cell $$$i$$$ ($$$1 \le i \le n$$$) find it's temperature, that can be calculated by the formula $$$$$$\min_{1 \le j \le k}(t_j + |a_j - i|),$$$$$$

where $$$|a_j - i|$$$ denotes absolute value of the difference $$$a_j - i$$$.

In other words, the temperature in cell $$$i$$$ is equal to the minimum among the temperatures of air conditioners, increased by the distance from it to the cell $$$i$$$.

Let's look at an example. Consider that $$$n=6, k=2$$$, the first air conditioner is placed in cell $$$a_1=2$$$ and is set to the temperature $$$t_1=14$$$ and the second air conditioner is placed in cell $$$a_2=5$$$ and is set to the temperature $$$t_2=16$$$. In that case temperatures in cells are:

1. temperature in cell $$$1$$$ is: $$$\min(14 + |2 - 1|, 16 + |5 - 1|)=\min(14 + 1, 16 + 4)=\min(15, 20)=15$$$;
2. temperature in cell $$$2$$$ is: $$$\min(14 + |2 - 2|, 16 + |5 - 2|)=\min(14 + 0, 16 + 3)=\min(14, 19)=14$$$;
3. temperature in cell $$$3$$$ is: $$$\min(14 + |2 - 3|, 16 + |5 - 3|)=\min(14 + 1, 16 + 2)=\min(15, 18)=15$$$;
4. temperature in cell $$$4$$$ is: $$$\min(14 + |2 - 4|, 16 + |5 - 4|)=\min(14 + 2, 16 + 1)=\min(16, 17)=16$$$;
5. temperature in cell $$$5$$$ is: $$$\min(14 + |2 - 5|, 16 + |5 - 5|)=\min(14 + 3, 16 + 0)=\min(17, 16)=16$$$;
6. temperature in cell $$$6$$$ is: $$$\min(14 + |2 - 6|, 16 + |5 - 6|)=\min(14 + 4, 16 + 1)=\min(18, 17)=17$$$.

For each cell from $$$1$$$ to $$$n$$$ find the temperature in it.