# Find a pair of elements from an array whose sum equals a given number

Given array of n integers and given a number X, find all the unique pairs of elemens (a,b), whose summation is equal to X.

The following is my solution, it is O(nLog(n)+n), but I am not sure whether or not it is optimal. Thanks for comments.

int main(void)
{
int arr [10] = {1,2,3,4,5,6,7,8,9,0};
findpair(arr, 10, 7);
}
void findpair(int arr[], int len, int sum)
{
std::sort(arr, arr+len);
int i = 0;
int j = len -1;
while( i < j){
while((arr[i] + arr[j]) <= sum && i < j)
{
if((arr[i] + arr[j]) == sum)
cout << "(" << arr[i] << "," << arr[j] << ")" << endl;
i++;
}
j--;
while((arr[i] + arr[j]) >= sum && i < j)
{
if((arr[i] + arr[j]) == sum)
cout << "(" << arr[i] << "," << arr[j] << ")" << endl;
j--;
}
}
}

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An O(n) solution is possible if you chuck everything into an O(1) set of some kind instead of sorting the array. –  Anon. Jan 18 '11 at 3:46
@Anon Can u tell more details, how to build such a set? –  Gin Jan 18 '11 at 3:57
Use hashes. Most languages will have an amortized O(1) HashSet somewhere in their standard libraries. –  Anon. Jan 18 '11 at 3:59
A minor nit - O(nLog(n)+n) is O(nLog(n)). Big O notation retains only the dominant term and drops all lower order terms. –  pjs Jun 1 '13 at 14:40
Note short circuit evaluation and off-by-one addressing: while((arr[i] + arr[j]) <= sum && i < j) should be while( i < J && arr[i] + arr[j] <= sum ). (similar for the second subloop) –  wildplasser Aug 10 '13 at 12:40

Let arr be the given array.
And K be the give sum

for i=0 to arr.length - 1 do
hash(arr[i]) = i  // key is the element and value is its index.
end-for

for i=0 to arr.length - 1 do
if hash(K - arr[i]) != i  // if K - ele exists and is different we found a pair
print "pair i , hash(K - arr[i]) has sum K"
end-if
end-for

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You could even do it in one iteration through the array, by putting your if statement from the second loop, right after the hash assignment in the first loop. –  Alexander Kondratskiy Jan 18 '11 at 16:06
Minor note: This (as well as Alexander's suggestion) will double-print some pairs, whether uniqueness of a pair is determined by index (as could be implied from this answer) or by value (as it seems in the OP). There could be quite a few (O(n^2)) unique pairs by index, e.g. arr=[1,2,1,2,1,2,1,...]. For uniqueness by value, it seems like another hash table keyed by a value-pair would do the trick. Still a nice, compact, elegant answer. +1 –  AugR Feb 10 '11 at 18:49
@codaddict But what if array is very large ? I mean the range of values in it is very large ? So, the hash solution will be less practical then. Any alternate and optimal method for the same ? –  Prashant Singh Oct 22 '12 at 15:14
What if there are duplicates? –  zad Sep 11 '13 at 17:08

There are 3 approaches to this solution:

Let the sum be T and n be the size of array

Approach 1:
The naive way to do this would be to check all combinations (n choose 2). This exhaustive search is O(n2).

Approach 2:
A better way would be to sort the array. This takes O(n log n)
Then for each x in array A, use binary search to look for T-x. This will take O(nlogn).
So, overall search is  O(n log n)

Approach 3 :
The best way would be to insert every element into a hash table (without sorting). This takes O(n) as constant time insertion.
Then for every x, we can just look up its complement, T-x, which is O(1).
Overall it takes will be O(n).

You can refer more here.Thanks.

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How would you create hash table for the elements of the array? –  Satish Patel Dec 19 '13 at 16:13

I can do it in O(n). Let me know when you want the answer. Note it involves simply traversing the array once with no sorting, etc... I should mention too that it exploits commutativity of addition and doesn't use hashes but wastes memory.

using System; using System.Collections.Generic;

/* An O(n) approach exists by using a lookup table. The approach is to store the value in a "bin" that can easily be looked up(e.g., O(1)) if it is a candidate for an appropriate sum.

e.g.,

for each a[k] in the array we simply put the it in another array at the location x - a[k].

Suppose we have [0, 1, 5, 3, 6, 9, 8, 7] and x = 9

We create a new array,

indexes value

9 - 0 = 9     0
9 - 1 = 8     1
9 - 5 = 4     5
9 - 3 = 6     3
9 - 6 = 3     6
9 - 9 = 0     9
9 - 8 = 1     8
9 - 7 = 2     7


THEN the only values that matter are the ones who have an index into the new table.

So, say when we reach 9 we see if our new array has the index 9 - 9 = 0. Since it does we know that all the values it contains will add to 9. (note in this cause it's obvious there is only 1 possible one but it might have multiple index values in it which we need to store).

So effectively what we end up doing is only having to move through the array once. Because addition is commutative we will end up with all the possible results.

For example, when we get to 6 we get the index into our new table as 9 - 6 = 3. Since the table contains that index value we know the values.

This is essentially trading off speed for memory. */

namespace sum
{
class Program
{
static void Main(string[] args)
{
int num = 25;
int X = 10;
var arr = new List<int>();
for(int i = 0; i < num; i++) arr.Add((new Random((int)(DateTime.Now.Ticks + i*num))).Next(0, num*2));
Console.Write("["); for (int i = 0; i < num - 1; i++) Console.Write(arr[i] + ", "); Console.WriteLine(arr[arr.Count-1] + "] - " + X);
var arrbrute = new List<Tuple<int,int>>();
var arrfast = new List<Tuple<int,int>>();

for(int i = 0; i < num; i++)
for(int j = i+1; j < num; j++)
if (arr[i] + arr[j] == X)

int M = 500;
var lookup = new List<List<int>>();
for(int i = 0; i < 1000; i++) lookup.Add(new List<int>());
for(int i = 0; i < num; i++)
{
// Check and see if we have any "matches"
if (lookup[M + X - arr[i]].Count != 0)
{
foreach(var j in lookup[M + X - arr[i]])
}

}

for(int i = 0; i < arrbrute.Count; i++)
Console.WriteLine(arrbrute[i].Item1 + " + " + arrbrute[i].Item2 + " = " + X);
Console.WriteLine("---------");
for(int i = 0; i < arrfast.Count; i++)
Console.WriteLine(arrfast[i].Item1 + " + " + arrfast[i].Item2 + " = " + X);

}
}
}

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Basically to avoid hashes we have to create a table that can accept random insertions at somewhat arbitrary indices. Hence I use M to make sure that there is enough elements and pre-allocate a contiguous set even though most will not be used. A hash set would take care of this directly. –  AbstractDissonance Jan 18 '11 at 4:41
So, you're using a hash set with a simple hash function and size greater than the max value of your hash function? –  Chris Hopman Jan 18 '11 at 5:59
Also may as well use the identity function for your hash function at this point. That is, put a[k] at the a[k]-th "bin". –  Chris Hopman Jan 18 '11 at 6:02
Because a[k] and X - a[k] are used an indices and I'm using an array, it means that the minimum index cannot be 0. Hence I simply add a very large number to shift them up. If one could make a hash function that worked for arbitrary values then they could use a simple list without having to do this shifting. The shifting + preallocation helps avoid having to create a hash(or it could be thought of a very simple(and fast) hash). –  AbstractDissonance Jan 19 '11 at 22:40

Implemented in Python:

def addition_combination():
arr = [1,2,3,4,5,6,7,8,9,0]
numb = 5
result = False
for i in arr:
look = numb - i
if look > 0 and look in arr:
result = True
print str(i)+' + '+str(look)

if not result:
print 'No combnation found'



Output:

1 + 4

2 + 3

3 + 2

4 + 1

0 + 5

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This prints the pairs and avoids duplicates using bitwise manipulation.

public static void findSumHashMap(int[] arr, int key) {
Map<Integer, Integer> valMap = new HashMap<Integer, Integer>();
for(int i=0;i<arr.length;i++)
valMap.put(arr[i], i);

int indicesVisited = 0;
for(int i=0;i<arr.length;i++) {
if(valMap.containsKey(key - arr[i]) && valMap.get(key - arr[i]) != i) {
if(!((indicesVisited & ((1<<i) | (1<<valMap.get(key - arr[i])))) > 0)) {
int diff = key-arr[i];
System.out.println(arr[i] + " " +diff);
indicesVisited = indicesVisited | (1<<i) | (1<<valMap.get(key - arr[i]));
}
}
}
}

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I bypassed the bit manuplation and just compared the index values. This is less than the loop iteration value (i in this case). This will not print the duplicate pairs and duplicate array elements also.

public static void findSumHashMap(int[] arr, int key) {
Map<Integer, Integer> valMap = new HashMap<Integer, Integer>();
for (int i = 0; i < arr.length; i++) {
valMap.put(arr[i], i);
}
for (int i = 0; i < arr.length; i++) {
if (valMap.containsKey(key - arr[i])
&& valMap.get(key - arr[i]) != i) {
if (valMap.get(key - arr[i]) < i) {
int diff = key - arr[i];
System.out.println(arr[i] + " " + diff);
}
}
}
}

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Here is a solution witch takes into account duplicate entries. It is written in javascript and assumes array is sorted. The solution runs in O(n) time and does not use any extra memory aside from variable.

var count_pairs = function(_arr,x) {
if(!x) x = 0;
var pairs = 0;
var i = 0;
var k = _arr.length-1;
if((k+1)<2) return pairs;
var halfX = x/2;
while(i<k) {
var curK = _arr[k];
var curI = _arr[i];
var pairsThisLoop = 0;
if(curK+curI==x) {
// if midpoint and equal find combinations
if(curK==curI) {
var comb = 1;
while(--k>=i) pairs+=(comb++);
break;
}
// count pair and k duplicates
pairsThisLoop++;
while(_arr[--k]==curK) pairsThisLoop++;
// add k side pairs to running total for every i side pair found
pairs+=pairsThisLoop;
while(_arr[++i]==curI) pairs+=pairsThisLoop;
} else {
// if we are at a mid point
if(curK==curI) break;
var distK = Math.abs(halfX-curK);
var distI = Math.abs(halfX-curI);
if(distI > distK) while(_arr[++i]==curI);
else while(_arr[--k]==curK);
}
}
return pairs;
}


I solved this during an interview for a large corporation. They took it but not me. So here it is for everyone.

Start at both side of the array and slowly work your way inwards making sure to count duplicates if they exist.

It only counts pairs but can be reworked to

• find the pairs
• find pairs < x
• find pairs > x

Enjoy!

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What these lines do?: if(distI > distK) while(_arr[++i]==curI); else while(_arr[--k]==curK); –  Yuriy Chernyshov Jan 19 at 18:36

in C#:

        int[] array = new int[] { 1, 5, 7, 2, 9, 8, 4, 3, 6 }; // given array
int sum = 10; // given sum
for (int i = 0; i <= array.Count() - 1; i++)
if (array.Contains(sum - array[i]))
Console.WriteLine("{0}, {1}", array[i], sum - array[i]);

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this answer would be more useful if you describe the order of growth of your solution –  Thomas Jun 1 '13 at 9:32

this is the implementation of O(n*lg n) using binary search implementation inside a loop.

#include <iostream>

using namespace std;

bool *inMemory;

int pairSum(int arr[], int n, int k)
{
int count = 0;

if(n==0)
return count;
for (int i = 0; i < n; ++i)
{
int start = 0;
int end = n-1;
while(start <= end)
{
int mid = start + (end-start)/2;
if(i == mid)
break;
else if((arr[i] + arr[mid]) == k && !inMemory[i] && !inMemory[mid])
{
count++;
inMemory[i] = true;
inMemory[mid] = true;
}
else if(arr[i] + arr[mid] >= k)
{
end = mid-1;
}
else
start = mid+1;
}
}
return count;
}

int main()
{
int arr[] = {1, 2, 3, 4, 5, 6, 7, 8, 9, 10};
inMemory = new bool[10];
for (int i = 0; i < 10; ++i)
{
inMemory[i] = false;
}
cout << pairSum(arr, 10, 11) << endl;
return 0;
}

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Implementation in Java : Using codaddict's algorithm

import java.util.HashMap;

public class ArrayPairSum {

public static void main(String[] args) {

int []a = {2,45,7,3,5,1,8,9};
getSumPairs(a,10);

}

public static void getSumPairs(int []input, int k){
Map<Integer, Integer> pairs = new HashMap<Integer, Integer>();

for(int i=0;i<input.length;i++){

if(pairs.containsKey(input[i]))
System.out.println(input[i] +", "+ pairs.get(input[i]));
else
pairs.put(k-input[i], input[i]);
}

}
}


For input = {2,45,7,3,5,1,8,9} and if Sum is 10

Output pairs:

3,7
8,2
9,1


Some notes about the solution :

• We iterate only once through the array --> O(n) time
• Insertion and lookup time in Hash is O(1).
• Overall time is O(n), although it uses extra space in terms of hash.
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