# Algorithm for sum-up to 0 from 4 set

I have 4 arrays `A`, `B`, `C`, `D` of size `n`. `n` is at most 4000. The elements of each array are 30 bit (positive/negative) numbers. I want to know the number of ways, `A[i]+B[j]+C[k]+D[l] = 0` can be formed where `0 <= i,j,k,l < n`.

The best algorithm I derived is `O(n^2 lg n)`, is there a faster algorithm?

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Could you explain what this `O(n^2lgn)` algorithm is? –  quasiverse Sep 26 '11 at 10:46
For example I have array A,B,C,D all of them are have n zero (0) so the number of quads which some up to zero is O(n^4) how do you find algorithm which runs in O(n^2 log(n)) to find this quads? is permutation of same numbers ignored? –  Saeed Amiri Sep 26 '11 at 10:48
@Saeed: If you just need to find the number of ways rather than list them all, the runtime can be less than O(n^4). –  interjay Sep 26 '11 at 10:59
@russell: why is that n^2 lg n? You don't need to binary-search, you can hash, yes? n^2. (And of course you can hash for what I wrote earlier, too, now that I see it.) –  Tom Zych Sep 26 '11 at 11:01
@russell: please post your O(n^2logn) solution as an answer, so it can be upvoted and accessed more easily by future readers. –  amit Sep 26 '11 at 16:14

I disagree that your solution is in fact as efficient as you say. In your solution populating E[] and AUX[] is O(N^2) each, so 2.N^2. These will each have N^2 elements.

Generating x = O(N)

Sorting AUX = O((2N)*log((2N)))

The binary search for E[i] in AUX[] is based on N^2 elements to be found in N^2 elements.

Thus you are still doing N^4 work, plus extra work generating the intermediate arrays ans for sorting the N^2 elements in AUX[].

I have a solution (work in progress) but I find it very difficult to calculate how much work it is. I deleted my previous answer. I will post something when I am more sure of myself.

I need to find a way to compare O(X)+O(Z)+O(X^3)+O(X^2)+O(Z^3)+O(Z^2)+X.log(X)+Z.log(Z) to O(N^4) where X+Z = N.

It is clearly less than O(N^4) ... but by how much???? My math is failing me here....

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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.

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(+1) Can't say whether this is optimal, but at first blush it seems correct. Thanks for sharing. –  NPE Sep 27 '11 at 13:23
@aix, this is correct, i submitted this code to uva-online judge and the verdict is accepted. And the algorithm run time can be reduced using extra space But the overall complexity O(n^2lg(n)) can't be reduced. –  russell Sep 27 '11 at 13:33
Sorry, I overlooked one things, the complexity of the above solution is O(n^2 lg(n^2)). –  russell Sep 28 '11 at 9:00
Mathematically, `O(n^2 lg(n^2))` is the same as `O(n^2 lg(n))`, since `lg(n^2)==2*lg(n)`. –  NPE Sep 28 '11 at 9:23

The judgement is wrong. The supplied solution generates arrays with size N^2. It then operates on these arrays (sorting, etc).

Therefore the Order of work, which would normaly be O(n^2.log(n)) should have n substituted with n^2. The result is therefore O((n^2)^2.log(n^2))

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look at my explanation. –  russell Sep 28 '11 at 9:13
OK, I agree with that. –  Johan Hartzenberg Sep 28 '11 at 9:28