# Maximum xor among all subsets of an array

I have to find maximum value of exclusive xor among the elements of subsets of an array. I have to check every subset of the array and the subset which will yield maximum xor will be the answer.

For exapmle- let F(S) denote the fuction which takes xor over all elements of subset S of array P={1,2,3,4}

``````F({1,2}) = 3
F({1,3}) = 2
F({1,2,3}) = 0
F({1,4}) = 5
F({2,3}) = 1
F({2,4}) = 6
F({3,4}) = 7
F({2,3,4}) = 5
F({1,2,3,4}) = 4`
``````

Maximum of them is 7. Hence the answer is 7.(There are other subsets but they are not worth considering). If you are about to tell me about Gaussian Elimination method, I've read that somewhere on MSE but it was not at all clear to me. If gauss elimination is the only answer than please elaborate that to me or is there some method/algorithm I don't know of?

• subset {1,2,4} = 7 doesn't it has to be considered ? Dec 14, 2014 at 15:18
• Does the elements of array P have any special property? Dec 14, 2014 at 15:24
• @justmscs no special property. Dec 14, 2014 at 15:45
• @AliAkber you can consider that too. I meant that the answer will still be 7. Dec 14, 2014 at 15:46

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);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;
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;
}
``````
• How do you modify it to get minimum? Jul 1, 2017 at 9:43

I guess that you're referring to this question.

Gaussian Elimination is the algorithm description that I would expect from the math site. This is what the algorithm looks like in Python.

``````def max_xor(iterable):
array = list(iterable)  # make it a list so that we can iterate it twice
if not array:  # special case the empty array to avoid an empty max
return 0
x = 0
while True:
y = max(array)
if y == 0:
return x
# y has the leading 1 in the array
x = max(x, x ^ y)
# eliminate
array = [min(z, z ^ y) for z in array]
``````
• Yes, I was referring to that question. Can you tell me what is happening in this python implementation? Dec 14, 2014 at 15:50
• @johnkeets Look for the most significant one bit in the array. The max XOR has this bit set. Use XORs to set it in the max XOR and clear it in the rest of the array, then solve the smaller subproblem. Dec 14, 2014 at 16:24
• what this step is doing --> array = [min(z, z ^ y) for z in array] Dec 14, 2014 at 16:30
• @Ray After `array = list(iterable)` add the line `array = [(z << len(array)) | (1 << i) for (i, z) in enumerate(array)]`, which in essence adjoins an identity matrix as in en.wikipedia.org/wiki/…. Then at the end the indexes of the elements comprising `x` are indicated by the bottom `len(array)` bits of `x`. Oct 22, 2019 at 12:40
• @Ray When the inputs are limited to 64 bits, there are at most 64 pivot elements (choice of `y`). Instead of n low-order bits, we can use 64 low-order bits in much the same way, except instead of indexing into the original array, they index into the list of pivots. Instead of adjoining an identity matrix up front, we set the appropriate bit on `y` just before reducing the rest of the array with it. Oct 22, 2019 at 18:18