10760: ABC139 - F - Engines
[Creator : ]
Description
E869120 is initially standing at the origin $(0, 0)$ in a two-dimensional plane.
He has $N$ engines, which can be used as follows:
- When E869120 uses the $i$-th engine, his $X$- and $Y$-coordinate change by $x_i$ and $y_i$, respectively. In other words, if E869120 uses the $i$-th engine from coordinates $(X, Y)$, he will move to the coordinates $(X + x_i, Y + y_i)$.
- E869120 can use these engines in any order, but each engine can be used at most once. He may also choose not to use some of the engines.
He wants to go as far as possible from the origin. Let $(X, Y)$ be his final coordinates. Find the maximum possible value of $\sqrt{X^2 + Y^2}$, the distance from the origin.
He has $N$ engines, which can be used as follows:
- When E869120 uses the $i$-th engine, his $X$- and $Y$-coordinate change by $x_i$ and $y_i$, respectively. In other words, if E869120 uses the $i$-th engine from coordinates $(X, Y)$, he will move to the coordinates $(X + x_i, Y + y_i)$.
- E869120 can use these engines in any order, but each engine can be used at most once. He may also choose not to use some of the engines.
He wants to go as far as possible from the origin. Let $(X, Y)$ be his final coordinates. Find the maximum possible value of $\sqrt{X^2 + Y^2}$, the distance from the origin.
Input
Input is given from Standard Input in the following format:
```
$N$
$x_1$ $y_1$
$x_2$ $y_2$
$:$ $:$
$x_N$ $y_N$
```
```
$N$
$x_1$ $y_1$
$x_2$ $y_2$
$:$ $:$
$x_N$ $y_N$
```
Output
Print the maximum possible final distance from the origin, as a real value. Your output is considered correct when the relative or absolute error from the true answer is at most $10^{-10}$.
Constraints
- $1 \leq N \leq 100$
- $-1 \ 000 \ 000 \leq x_i \leq 1 \ 000 \ 000$
- $-1 \ 000 \ 000 \leq y_i \leq 1 \ 000 \ 000$
- All values in input are integers.
- $-1 \ 000 \ 000 \leq x_i \leq 1 \ 000 \ 000$
- $-1 \ 000 \ 000 \leq y_i \leq 1 \ 000 \ 000$
- All values in input are integers.
Sample 1 Input
3
0 10
5 -5
-5 -5
Sample 1 Output
10.000000000000000000000000000000000000000000000000
The final distance from the origin can be $10$ if we use the engines in one of the following three ways:
- Use Engine $1$ to move to $(0, 10)$.
- Use Engine $2$ to move to $(5, -5)$, and then use Engine $3$ to move to $(0, -10)$.
- Use Engine $3$ to move to $(-5, -5)$, and then use Engine $2$ to move to $(0, -10)$.
The distance cannot be greater than $10$, so the maximum possible distance is $10$.
Sample 2 Input
5
1 1
1 0
0 1
-1 0
0 -1
Sample 2 Output
2.828427124746190097603377448419396157139343750753
The maximum possible final distance is $2 \sqrt{2} = 2.82842...$. One of the ways to achieve it is:
- Use Engine $1$ to move to $(1, 1)$, and then use Engine $2$ to move to $(2, 1)$, and finally use Engine $3$ to move to $(2, 2)$.
Sample 3 Input
5
1 1
2 2
3 3
4 4
5 5
Sample 3 Output
21.213203435596425732025330863145471178545078130654
If we use all the engines in the order $1 \rightarrow 2 \rightarrow 3 \rightarrow 4 \rightarrow 5$, we will end up at $(15, 15)$, with the distance $15 \sqrt{2} = 21.2132...$ from the origin.
3
0 0
0 1
1 0
1.414213562373095048801688724209698078569671875376
There can be useless engines with $(x_i, y_i) = (0, 0)$.
Sample 4 Input
1
90447 91000
Sample 4 Output
128303.000000000000000000000000000000000000000000000000
Note that there can be only one engine.