Gaussian Elimination is what you need.

For example : `3`

numbers `{9, 8, 5}`

First sort them in decreasing order and convert them into binary :

```
9 : 1001
8 : 1000
5 : 0101
```

Observe the 1st number. Highest bit is 4.

Now check `4th`

bit of the `1st`

number (9). As it is 1, xor the number with the rest of the numbers where 4th bit is 1.

```
9 : 1001
1 : 0001 > changed
5 : 0101
```

Now check `3rd`

bit of `2nd`

number (1). As it is 0, check rest of the below numbers where `3rd`

bit is 1.

Number 5 has 1 in `3rd`

bit. Swap them :

```
9 : 1001
5 : 0101 > swapped
1 : 0001 >
```

Now xor 5 with the rest of the numbers where `3rd`

bit is 1. Here none exists. So there will be no change.

Now check `2nd`

bit of `3rd`

number (1). As it is 0 and there is no other number below where 2nd bit is 1, so there will be no change.

Now check `1st`

bit of `3rd`

number (1). As it is 1, change the rest of the numbers where `1st`

bit is 1.

```
8 : 1000 > changed
4 : 0100 > changed
1 : 0001
```

No more bit left to consider :)

Now xor the whole remaining array `{8 ^ 4 ^ 1} = 13`

So `13`

is the solution :)

That's pretty much how you solve the problem using Gaussian Elimination :)

Here is my C++ implementation :

```
#include <bits/stdc++.h>
using namespace std;
typedef long long int ll;
typedef unsigned long long int ull;
ull check_bit(ull N,int POS){return (N & (1ULL<<POS));}
vector<ull>v;
ull gaussian_elimination()
{
int n=v.size();
int ind=0; // Array index
for(int bit=log2(v[0]);bit>=0;bit--)
{
int x=ind;
while(x<n&&check_bit(v[x],bit)==0)
x++;
if(x==n)
continue; // skip if there is no number below ind where current bit is 1
swap(v[ind],v[x]);
for(int j=0;j<n;j++)
{
if(j!=ind&&check_bit(v[j],bit))
v[j]^=v[ind];
}
ind++;
}
ull ans=v[0];
for(int i=1;i<n;i++)
ans=max(ans,ans^v[i]);
return ans;
}
int main()
{
int i,j,k,l,m,n,t,kase=1;
scanf("%d",&n);
ull x;
for(i=0;i<n;i++)
{
cin>>x;
v.push_back(x);
}
sort(v.rbegin(),v.rend());
cout<<gaussian_elimination()<<"\n";
return 0;
}
```