**The problem statement**:

Give `n`

variables and `k`

pairs. The variables can be distinct by assigning a value from 1 to `n`

to each variable. Each pair `p`

contain 2 variables and let the absolute difference between 2 variables in `p`

is `abs(p)`

. Define the upper bound of difference is `U=max(Abs(p)|every p)`

.

Find an assignment that minimize `U`

.

```
Limit:
n<=100
k<=1000
```

Each variable appear at least 2 times in list of pairs.

```
A problem instance:
Input
n=9, k=12
1 2 (meaning pair x1 x2)
1 3
1 4
1 5
2 3
2 6
3 5
3 7
3 8
3 9
6 9
8 9
Output:
1 2 5 4 3 6 7 8 9
(meaning x1=1,x2=2,x3=5,...)
```

**Explaination:** An assignment of `x1=1,x2=2,x3=3,...`

will result in `U=6`

(3 9 has greastest abs value). The output assignment will get `U=4`

, the minimum value (changed pair: `3 7 => 5 7, 3 8 => 5 8`

, etc. and 3 5 isn't changed. In this case, `abs(p)<=4`

for every pair).

**There is an important point**: To achieve the best assignments, the variables in the pairs that have greatest abs must be change.

Base on this, I have thought of a greedy algorithm:

```
1)Assign every x to default assignment (x(i)=i)
2)Locate pairs that have largest abs and x(i)'s contained in them.
3)For every i,j: Calculate U. Swap value of x(i),x(j). Calculate U'. If U'<U, stop and repeat step 3. If U'>=U for every i,j, end and output the assignment.
```

However, this method has a major pitfall, if we need an assignment like this:

```
x(a)<<x(b), x(b)<<x(c), x(c)<<x(a)
```

, we have to swap in 2 steps, like: `x(a)<=>x(b)`

, then `x(b)<=>x(c)`

, then there is a possibility that `x(b)<<x(a)`

in first step has its abs become larger than U and the swap failed.

Is there any efficient algorithm to solve this problem?