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This is my problem. Given an array of integers and another integer k, find the sum of differences of each element of the array and k.

For example if the array is 2, 4, 6, 8, 10 and k is 3

Sum of difference
= abs(2 - 3) + abs(4-3) + abs(6 - 3) + abs(8 - 3) + abs(10 - 3)
= 1 + 1 + 3 + 5 + 7
= 17

The array remains the same throughout and can contain up to 100000 elements and there will be 100000 different values of k to be tested. k may or may not be an element of the array. This has to be done within 1s or about 100M operations. How do I achieve this?

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You mean the sum of absolute differences. Hint: Does it help to break the input into those numbers that are < k and those that are >= k? –  j_random_hacker Jul 11 '14 at 12:34
1  
Are there any assumptions for the dataset you will be working on? (i.e. the example set you show increase by 2 at each index) –  sherrellbc Jul 11 '14 at 12:35
4  
Since you have to do at least one pass through the data, an O(logn) or O(1) solution is infeasible. –  Alexander Gessler Jul 11 '14 at 12:36
    
I just saw that the required time complexity is o(N) (O(log N) or O(1)): this is impossible, unless there are other restrictions on the input that you're not telling us. Looking at each element requires Omega(N) time, and you have to look at each element to get the right answer! –  j_random_hacker Jul 11 '14 at 12:36

4 Answers 4

up vote 6 down vote accepted

You can run multiple queries for sums of absolute differences in O(log N) if you add a preprocessing step which costs O(N * log N).

Sort the array, then for each item in the array store the sum of all numbers that are smaller than or equal to the corresponding item. This can be done in O(N * log N) Now you have a pair of arrays that look like this:

2   4   6   8  10 // <<== Original data
2   6  12  20  30 // <<== Partial sums

In addition, store the total T of all numbers in the array.

Now you can get sums of absolute differences by running a binary search on the original array, and using the sums from the partial sums array to compute the answer: subtract the sum of all numbers to the left of the target k from the count of numbers to the left of the target times k, then subtract the count times k from the sum to the right of the number, and add the two numbers together. The partial sum of the numbers to the right of the number can be computed by subtracting the partial sum on the left from the total T.

For k=3 binary search gets you to position 1.

  • Partial sum on the left is 2
  • Count of items on the left is 1
  • Partial sum on the right is (30-2)=28
  • Count of items on the right is 4
  • You compute (1*3-2) + (28-4*3) = 1 + 16 = 17
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1  
Very clever solution, upvoted. –  CoryKramer Jul 11 '14 at 12:46

First sort the array and then compute an array that stores the sum of the prefixes of the resulting sorted array. Let's denote this array p, you can compute p in linear time so that p[i] = a[0] + a[1] + ... a[i]. Now having this array you can answer with constant complexity the question what is the sum of elements a[x] + a[x+1] + .... +a[y](i.e. with indices x to y). To do that you simply compute p[y] - p[x-1](Take special care when x is 1).

Now to answer a query of the type what is the sum of absolute differences with k, we will split the problem in two parts - what is the sum of the numbers greater than k and the numbers smaller than k. In order to compute these, perform a binary search to find the position of k in the sorted a(denote that idx), and compute the sum of the values in a before idx(denote that s) and after idx(denote that S). Now the sum of absolute differences with k is idx * k - s + S - (a.length - idx)* k. This of course is pseudo code and what I mean by a.length is the number of elements in a.

After performing a linearithmic precomputation, you will be able to answer a query with O(log(n)). Please note this approach only makes sense if you plan to perform multiple queries. If you are only going to perform a single query, you can not possibly go faster than O(n).

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But sorting the array would break the (impossible) complexity requirements. –  juanchopanza Jul 11 '14 at 12:42
    
As I said this approach only makes sense if there are multiple queries. If there is a single query, we can not improve O(n). My approach will fit into the time constraints easily. This sounds like a competition problem and I believe this is the indended solution. –  Ivaylo Strandjev Jul 11 '14 at 12:43

Just implementing dasblinkenlight's solution in "contest C++":

It does exactly as he says. Reads the values, sorts them, stores the accumulated sum in V[i].second, but here V[i] is the acumulated sum until i-1 (to simplify the algorithm). It also stores a sentinel in V[n] for cases when the query is greater than max(V).

Then, for each query, binary search for the value. In this case V[a].second is the sum of values lesser than query, V[n].second-V[a].second is the sum of values greater than it.

#include<iostream>
#include<algorithm>
#define pii pair<int, int>
using namespace std;

pii V[100001];

int main() {
    int n;

    while(cin >> n) {
        for(int i=0; i<n; i++)
            cin >> V[i].first;

        sort(V, V+n);
        V[0].second = 0;

        for(int i=1; i<=n; i++) 
            V[i].second = V[i-1].first + V[i-1].second;

        int k; cin >> k;
        for(int i=0; i<k; i++) {
            int query; cin >> query;
            pii* res = upper_bound(V, V+n, pii(query, 0));

            int a = res-V, b=n-(res-V);

            int left = query*a-V[a].second;
            int right = V[n].second-V[a].second-query*b;

            cout << left+right << endl;
        }

    }
}

It assumes a file with a format like this:

5
10 2 8 4 6
2
3 5

Then, for each query, it answers like this:

17
13
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abs(sum(elements)-(size(elements)*k)) in O(n).

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This will produce an incorrect result for the OP's data: sum=30, size=5, abs(30-5*3)=15, while the correct answer is 17. –  dasblinkenlight Jul 11 '14 at 13:25
    
This will only work if k<=min(elements) or max(elements)<=k. –  Teepeemm Jul 13 '14 at 21:24

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