Ok, Here is my O(n^2lg(n^2)) algorithm-

Suppose there is four array A[], B[], C[], D[]. we want to find the number of way A[i]+B[j]+C[k]+D[l] = 0 can be made where 0 <= i,j,k,l < n.

So sum up all possible arrangement of A[] and B[] and place them in another array E[] that contain n*n number of element.

```
int k=0;
for(i=0;i<n;i++)
{
for(j=0;j<n;j++)
{
E[k++]=A[i]+B[j];
}
}
```

The complexity of above code is O(n^2).

Do the same thing for C[] and D[].

```
int l=0;
for(i=0;i<n;i++)
{
for(j=0;j<n;j++)
{
AUX[l++]=C[i]+D[j];
}
}
```

The complexity of above code is O(n^2).

Now sort AUX[] so that you can find the number of occurrence of unique element in AUX[] easily.

Sorting complexity of AUX[] is O(n^2 lg(n^2)).

now declare a structure-

```
struct myHash
{
int value;
int valueOccuredNumberOfTimes;
}F[];
```

Now in structure F[] place the unique element of AUX[] and number of time they appeared.

It's complexity is O(n^2)

```
possibleQuardtupple=0;
```

Now for each item of E[], do the following

```
for(i=0;i<k;i++)
{
x=E[i];
find -x in structure F[] using binary search.
if(found in j'th position)
{
possibleQuardtupple+=number of occurrences of -x in F[j];
}
}
```

For loop i ,total n^2 number of iteration is performed and in each
iteration for binary search lg(n^2) comparison is done. So overall
complexity is O(n^2 lg(n^2)).

**The number of way 0 can be reached is = possibleQuardtupple.**

Now you can use stl map/ binary search. But stl map is slow, so its better to use binary search.

Hope my explanation is clear enough to understand.

`O(n^2lgn)`

algorithm is? – quasiverse Sep 26 '11 at 10:46