#P1450B. Balls of Steel
Balls of Steel
No submission language available for this problem.
Description
You have $n$ distinct points $(x_1, y_1),\ldots,(x_n,y_n)$ on the plane and a non-negative integer parameter $k$. Each point is a microscopic steel ball and $k$ is the attract power of a ball when it's charged. The attract power is the same for all balls.
In one operation, you can select a ball $i$ to charge it. Once charged, all balls with Manhattan distance at most $k$ from ball $i$ move to the position of ball $i$. Many balls may have the same coordinate after an operation.
More formally, for all balls $j$ such that $|x_i - x_j| + |y_i - y_j| \le k$, we assign $x_j:=x_i$ and $y_j:=y_i$.
Your task is to find the minimum number of operations to move all balls to the same position, or report that this is impossible.
The first line contains a single integer $t$ ($1 \le t \le 100$) — the number of test cases.
The first line of each test case contains two integers $n$, $k$ ($2 \le n \le 100$, $0 \le k \le 10^6$) — the number of balls and the attract power of all balls, respectively.
The following $n$ lines describe the balls' coordinates. The $i$-th of these lines contains two integers $x_i$, $y_i$ ($0 \le x_i, y_i \le 10^5$) — the coordinates of the $i$-th ball.
It is guaranteed that all points are distinct.
For each test case print a single integer — the minimum number of operations to move all balls to the same position, or $-1$ if it is impossible.
Input
The first line contains a single integer $t$ ($1 \le t \le 100$) — the number of test cases.
The first line of each test case contains two integers $n$, $k$ ($2 \le n \le 100$, $0 \le k \le 10^6$) — the number of balls and the attract power of all balls, respectively.
The following $n$ lines describe the balls' coordinates. The $i$-th of these lines contains two integers $x_i$, $y_i$ ($0 \le x_i, y_i \le 10^5$) — the coordinates of the $i$-th ball.
It is guaranteed that all points are distinct.
Output
For each test case print a single integer — the minimum number of operations to move all balls to the same position, or $-1$ if it is impossible.
Samples
3
3 2
0 0
3 3
1 1
3 3
6 7
8 8
6 9
4 1
0 0
0 1
0 2
0 3
-1
1
-1
Note
In the first test case, there are three balls at $(0, 0)$, $(3, 3)$, and $(1, 1)$ and the attract power is $2$. It is possible to move two balls together with one operation, but not all three balls together with any number of operations.
In the second test case, there are three balls at $(6, 7)$, $(8, 8)$, and $(6, 9)$ and the attract power is $3$. If we charge any ball, the other two will move to the same position, so we only require one operation.
In the third test case, there are four balls at $(0, 0)$, $(0, 1)$, $(0, 2)$, and $(0, 3)$, and the attract power is $1$. We can show that it is impossible to move all balls to the same position with a sequence of operations.