# Finding sum of Absolute Difference of Every pair of integer from an array

Given an array, find the sum of the absolute difference of every pair of integers.

For example: Given `a[]= {2,3, 5, 7 };`

output would be `(3-2) + (5-2) + (7-2) + (5-3) + (7-3) + (7-5) = 17`.

It must be done better than `O(n^2)`.

The original array isn't necessarily sorted.

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What is your try? – Felix Kling May 2 '11 at 8:36
I know the obvious brute force solution. I was also thinking that, difference between successive numbers will appear exactly (n-1) times. But the result doesn't match with that of the brute-force solution. – Shamim Hafiz May 2 '11 at 8:38

note you add each number exactly k times (where k is its place if you sort the list)
also, you subtract each number exactly n-1-k times
you can sort the list (O(nlogn)) and then iterate over the sorted array, multiplying each element as mentioned above.

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Actually can't you do it in O(n) using radix or counting sort and then do the post processing as you mentioned it. – sumodds Feb 25 '12 at 19:53
@Sumod: If the numbers are from a limited range - yes, you could use radix sort/counting sort to optimize indeed. – amit Feb 25 '12 at 19:59

I think I have found the answer. I got it by looking into the result expression in my post.

Here is the code in C++.

``````int AbsDiff(int a[], int n)
{
if ( n < 2 ) return 0;
sort(a,a+n);
int sum = 0;
int i;
for(i=n-1;i>=0;i--)
{
sum += (a[i]*(i) - a[i]*(n-i-1));
}
return sum;
}
``````
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note that sorting will be needed before you iterate over the array, otherwise you might even get a negative answer. – amit May 2 '11 at 8:49

For example: Given a[]= {2,3, 5, 7 };
output would be (3-2) + (5-2) + (7-2) + (5-3) + (7-3) + (7-5) = 17.

I suppose you could

• Sum the multiplication of each number starting backwards with #count - 1 to get the total
• Sum the multiplication of each number starting up front with #count - 1 to get the total to subtract

This would then become `(7*3 + 5*2 +3*1) - (2*3 + 3*2 + 5*1) = 17`

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Yes, the answer is based on this. I have also posted the code in replying to this question myself. – Shamim Hafiz May 2 '11 at 8:44
@Gunner - typical case of finding the answer when trying to explain the problem :). +1 but I feel the accepted answer should got to amit. He beat both of us to it. – Lieven Keersmaekers May 2 '11 at 9:01

Just an alternative perspective on this. Here is Mathematica code:

``````With[{n = Length@# - 1}, Range[-n, n, 2].Sort[#]] &
``````

`n` = one less than the length of the list

`Range[-n, n, 2]` creates a list with numbers from `-n` to `n` in steps of `2`, e.g. `Range[-4, 4, 2]` = `{-4, -2, 0, 2, 4}`

`.` is vector dot product, e.g. `{a, b, c} . {x, y, z}` = `a x + b y + c z`

`Sort` is just sort.

So, for your example, we have: `{-3, -1, 1, 3} . {2, 3, 5, 7}` = `17`

Here is a plot of list length versus time:

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aren't creating the ranged list and dot product both omega(n)? sorting remains in both algorithms if I understood correctly, and you actually have 2 implicit iterations over an array of size n instead of one (dot product and creating the list) – amit May 2 '11 at 10:11
@amit I think Gunner is already doing what I was trying to illustrate, but I missed it because I don't like reading procedural code. You are probably correct in your observations, but this is the most natural way to do something like this in Mathematica. IMHO my graph shows that its complexity is not bad. – Mr.Wizard May 2 '11 at 10:16
@Mr.Wizard: of course not bad, it's O(nlogn) for sorting, but if any, it will be slower and not faster then the iterative approach. – amit May 2 '11 at 10:17
@amit I amended the post to correct that. I thought Gunner was doing something less efficient when I made that statement. – Mr.Wizard May 2 '11 at 10:21
@Mr.Wizard: no doubts, your alternative is much more elegant for math-based languages. – amit May 2 '11 at 10:24

The code below calculates a[0](-3) + a[1](-1) + a[2](1) + a[3](3), if size of array = 4.

``````result := 0
for i := 0 to sizeof(a)-1 do
begin
result := result + a[i] * (i*2 - sizeof(a) + 1)
end
``````

If you need to deal with sorted array, you can sort it at first by quick sort algorithm with O(n*log(n)) complexity.

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I think I am little late to post this but I guess this CPP program should work.

``````//JUST LIKE ANIMALS !!!!

#include<bits/stdc++.h>
using namespace std;
typedef long long int ll;

ll funcy(ll a[], ll n)
{

ll sum = 0;
ll i;
for(i=0;i<n;i++)
{
sum += (a[i]*(i) - a[i]*(n-i-1));
}
return sum;
}

int main(){
ios::sync_with_stdio(0);cin.tie(0);
ll i,n;cin>>n;ll v[n+1];
for(i=0;i<n;i++)cin>>v[i];
sort(&v[0],&v[n]);
cout<<AbsDiff(v,n);
return 0;
``````

}

P.s. Provided n>2. Please if there is something wrong in this , feel free to correct me.

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