# How to optimally divide an array into two subarrays so that sum of elements in both are same . otherwise give an error

How to optimally divide an array into two subarrays so that sum of elements in both are same . otherwise give an error

Example 1: 10, 20 , 30 , 5 , 40 , 50 , 40 , 15

array can be divided as 10, 20, 30, 5, 40 and 50, 40, 15 . sum = 105 each

Example 2: 10, 20, 30, 5, 40, 50, 40, 10

array can not be divided into 2 arrays of equal sum

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in which language do you want to write code? –  Serghei May 5 '11 at 13:05
Looks like homework... What have already you tried to do with it? –  Vladimir May 5 '11 at 13:05
The solutions here suggest a look at the partition problem, but this is a restricted kind of partition problem, wherein there exists a linear solution (if some constraints are imposed). See my answer below. –  DarkCthulhu Sep 21 '13 at 11:27

There exists a solution that run in O(n*TotalSum) where n is the number of elements in the array, and TotalSum is their total sum; it involves dynamic programming.

The first part, is you have to calculate the set of all numbers that can be created by adding elements in the array. For an array of size n, we will call this T(n), therefore: T(n) = T(n-1) UNION {Array[n]+k | k is in T(n-1)} (proof of correctness is inductive as in most cases of recursive functions). Also remember for each cell in the dynamic matrix the elements that were added in order to create it. Simple complexity analysis will show that this is done in O(n*TotalSum).

After calculating T(n), search the set for an element exactly the size of TotalSum / 2. (same time complexity at W.C.). If such an item exists, then the elements that created it, added together, equal TotalSum / 2, and the elements that were not part of its creation also equal TotalSum / 2 (TotalSum - TotalSum / 2 = TotalSum / 2).

This is obviously a pseuo-polinomial solution, but as mentioned above, this problem is in NP AFAIK.

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Finally GOOD description of how this method works. May be I'll remember it now. –  blaze Feb 9 '12 at 16:16

This is called Partition problem. There are optimal solutions for some special cases, otherwise it is NP-complete (exponential time complexity)

http://en.wikipedia.org/wiki/Partition_problem

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NP-Complete is not exponential time complexity –  Thomas Jungblut May 5 '11 at 14:07
@Thomas: P == NP? :) –  blaze May 5 '11 at 16:20
prove that first ;D –  Thomas Jungblut May 5 '11 at 16:34
@Thomas: that's your point :) Until proven, NP isn't polynomic! –  blaze May 6 '11 at 7:58
@blaze: I think Thomas is still right. NP != Non-Polynomial. There are Polynomial solutions for NP problems. They are just not deterministic. –  Nima Feb 8 '12 at 7:45

In its common variant, this problem imposes 2 constraints and it can be done in an easier way.

1. If the partition can only be done somewhere along the length of the array (we do not consider elements out of order)
2. There are no negative numbers.

The algorithm that then works could be:

1. Have 2 variables, leftSum and rightSum
2. Start incrementing leftSum from the left, and rightSum from the right of the array.
3. Try to correct any imbalance in it.

The following code does the above:

``````public boolean canBalance(int[] nums) {
int leftSum = 0, rightSum = 0, i, j;
if(nums.length == 1)
return false;
for(i=0, j=nums.length-1; i<=j ;){
if(leftSum <= rightSum){
leftSum+=nums[i];
i++;
}else{
rightSum+=nums[j];
j--;
}
}
return (rightSum == leftSum);
}
``````

The output:

``````canBalance({1, 1, 1, 2, 1})       → true    OK
canBalance({2, 1, 1, 2, 1})       → false   OK
canBalance({10, 10})              → true    OK
canBalance({1, 1, 1, 1, 4})       → true    OK
canBalance({2, 1, 1, 1, 4})       → false   OK
canBalance({2, 3, 4, 1, 2})       → false   OK
canBalance({1, 2, 3, 1, 0, 2, 3}) → true    OK
canBalance({1, 2, 3, 1, 0, 1, 3}) → false   OK
canBalance({1})                   → false   OK
canBalance({1, 1, 1, 2, 1})       → true    OK
``````

Ofcourse, if the elements can be combined out-of-order, it does turn into the partition problem with all its complexity.

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First, if the elements are integers, check that the total is evenly divisible by two- if it isn't success isn't possible.

I would set up the problem as a binary tree, with level 0 deciding which set element 0 goes into, level 1 deciding which set element 1 goes into, etc. At any time if the sum of one set is half the total, you're done- success. At any time if the sum of one set is more than half the total, that sub-tree is a failure and you have to back up. At that point it is a tree traversal problem.

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A BAD greedy heuristic to solve this problem: try sorting the list from least to greatest, and split that list into two by having list1 = the odd elements, and list2 = the even elements.

as it turns out, this problem is known as the partition problem. http://en.wikipedia.org/wiki/Partition_problem NP-Complete.

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indeed it seems NP-complete from first glance, though I didn't think of a proof for it yet. (a proof for it will get you a +1 from me) however, this heuristic seems terrible! probably a greedy solution (try to match every iteration) will outscore this heuristic in most cases. –  amit May 5 '11 at 13:14
Unless the odd and even set are exactly the same, element for element, this method is guaranteed to fail. –  Jim Clay May 5 '11 at 13:17
perhaps the knapsack problem is the wrong way to look at it. I think its may be better to look at it as a bin packing problem, where you instead of changing the number of bins, you change the size of your bins (and make the number of bins 2). it then becomes how do you pack it with least extra space (the point of the bin packing problem). if you can get the extra space in the bins to zero (or equal to each other, which is the same thing) then you have solved it. bin packing is NP-complete. en.wikipedia.org/wiki/Bin_packing_problem –  soandos May 5 '11 at 13:21
@sonados: the wikipedia page says it is even NP-hard. I'll look at this solution later (if it is indeed proves the problem is NPC/NP-Hard). at any case - a full proof that this problem is NPC/NP-Hard worthes to be in the answer body. –  amit May 5 '11 at 13:30
@amit: Apologies. moving it now –  soandos May 5 '11 at 13:33

This Problem says that if an array can have two subarrays with their sum of elements as same. So a boolean value should be returned. I have found an efficient algorithm : Algo: Procedure Step 1: Take an empty array as a container , sort the initial array and keep in the empty one. Step 2: now take two dynamically allocatable arrays and take out highest and 2nd highest from the auxilliary array and keep it in the two subarrays respectively , and delete from the auxiliary array. Step 3: Compare the sum of elements in the subarrays , the smaller sum one will have chance to fetch highest remaining element in the array and then delete from the container. Step 4: Loop thru Step 3 until the container is empty. Step 5: Compare the sum of two subarrays , if they are same return true else false.

// The complexity with this problem is that there may be many combinations possible but this algo has one unique way .

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Even though it is NP Complete , this way it is proving. For example the test case : Set S={3,19,17,8,16,1,2} . Initial check (sum%2)==0. –  Samarth2011 May 6 '11 at 4:46
``````public class Problem1 {

public static void main(String[] args) throws IOException{
Scanner scanner=new Scanner(System.in);
ArrayList<Integer> array=new ArrayList<Integer>();
int cases;
System.out.println("Enter the test cases");
cases=scanner.nextInt();

for(int i=0;i<cases;i++){
int size;

size=scanner.nextInt();
System.out.println("Enter the Initial array size : ");

for(int j=0;j<size;j++){
System.out.println("Enter elements in the array");
int element;
element=scanner.nextInt();
}
}

if(validate(array)){
System.out.println("Array can be Partitioned");}
else{
System.out.println("Error");}

}

public static boolean validate(ArrayList<Integer> array){
boolean flag=false;
Collections.sort(array);
System.out.println(array);
int index=array.size();

ArrayList<Integer> sub1=new ArrayList<Integer>();
ArrayList<Integer> sub2=new ArrayList<Integer>();

array.remove(index-1);

index=array.size();
array.remove(index-1);

while(!array.isEmpty()){

if(compareSum(sub1,sub2)){
index=array.size();
array.remove(index-1);
}
else{
index=array.size();
array.remove(index-1);
}
}

if(sumOfArray(sub1).equals(sumOfArray(sub2)))
flag=true;
else
flag=false;

return flag;
}

public static Integer sumOfArray(ArrayList<Integer> array){
Iterator<Integer> it=array.iterator();
Integer sum=0;
while(it.hasNext()){
sum +=it.next();
}

return sum;
}

public static boolean compareSum(ArrayList<Integer> sub1,ArrayList<Integer> sub2){
boolean flag=false;

int sum1=sumOfArray(sub1);
int sum2=sumOfArray(sub2);

if(sum1>sum2)
flag=true;
else
flag=false;

return flag;
}

}
``````

// The Greedy approach //

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I was asked this question in an interview, and I gave below simple solution, as I had NOT seen this problem in any websiteS earlier.

Lets say Array A = {45,10,10,10,10,5} Then, the split will be at index = 1 (0-based index) so that we have two equal sum set {45} and {10,10,10,10,5}

``````int leftSum = A[0], rightSum = A[A.length - 1];
int currentLeftIndex = 0; currentRightIndex = A.length - 1
``````

/* Move the two index pointers towards mid of the array untill currentRightIndex != currentLeftIndex. Increase leftIndex if sum of left elements is still less than or equal to sum of elements in right of 'rightIndex'.At the end,check if leftSum == rightSum. If true, we got the index as currentLeftIndex+1(or simply currentRightIndex, as currentRightIndex will be equal to currentLeftIndex+1 in this case). */

``````while (currentLeftIndex < currentRightIndex)
{
if ( currentLeftIndex+1 != currentRightIndex && (leftSum + A[currentLeftIndex + 1)     <=currentRightSum )
{
currentLeftIndex ++;
leftSum = leftSum + A[currentLeftIndex];
}

if ( currentRightIndex - 1 != currentLeftIndex && (rightSum + A[currentRightIndex - 1] <= currentLeftSum)
{
currentRightIndex --;
rightSum = rightSum + A[currentRightIndex];
}

}

if (CurrentLeftIndex == currentRightIndex - 1 && leftSum == rightSum)
PRINT("got split point at index "+currentRightIndex);
``````
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@Gal Subset-Sum problem is NP-Complete and has a O(n*TotalSum) pseudo-polynomial Dynamic Programming algorithm. But this problem is not NP-Complete. This is a special case and in fact this can be solved in linear time.

Here we are looking for an index where we can split the array into two parts with same sum. Check following code.

Analysis: O(n), as the algorithm only iterates through the array and does not use TotalSum.

``````public class EqualSumSplit {

public static int solution( int[] A ) {

int[] B = new int[A.length];
int[] C = new int[A.length];

int sum = 0;
for (int i=0; i< A.length; i++) {
sum += A[i];
B[i] = sum;
// System.out.print(B[i]+" ");
}
// System.out.println();

sum = 0;
for (int i=A.length-1; i>=0; i--) {
sum += A[i];
C[i] = sum;
// System.out.print(C[i]+" ");
}
// System.out.println();

for (int i=0; i< A.length-1; i++) {
if (B[i] == C[i+1]) {
System.out.println(i+" "+B[i]);
return i;
}
}

return -1;

}

public static void main(String args[] ) {
int[] A = {-7, 1, 2, 3, -4, 3, 0};
int[] B = {10, 20 , 30 , 5 , 40 , 50 , 40 , 15};
solution(A);
solution(B);
}

}
``````
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Algorithm:

Step 1) Split the array into two
Step 2) If the sum is equal, split is complete
Step 3) Swap one element from array1 with array2, guided by the four rules:
IF the sum of elements in array1 is less than sum of elements in array2
Rule1:
Find a number in array1 that is smaller than a number in array2 in such a way that swapping of          these elements, do not increase the sum of array1 beyond the expected sum. If found, swap the          elements and return.
Rule2:
If Rule1 is not is not satisfied, Find a number in array1 that is bigger than a number in array2 in          such a way that the difference between any two numbers in array1 and array2 is not smaller than          the difference between these two numbers.
ELSE
Rule3:
Find a number in array1 that is bigger than a number in array2 in such a way that swapping these          elements, do not decrease the sum of array1 beyond the expected sum. If found, swap the
elements and return.
Rule4:
If Rule3 is not is not satisfied, Find a number in array1 that is smaller than a number in array2 in          such a way that the difference between any two numbers in array1 and array2 is not smaller than          the difference between these two numbers.
Step 5) Go to Step2 until the swap results in an array with the same set of elements encountered already Setp 6) If a repetition occurs, this array cannot be split into two halves with equal sum. The current set of           arrays OR the set that was formed just before this repetition should be the best split of the array.

Note: The approach taken is to swap element from one array to another in such a way that the resultant sum is as close to the expected sum.

The java program is available at Java Code

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package PACKAGE1;

import java.io.*; import java.util.Arrays;

public class programToSplitAnArray {

``````public static void main(String args[]) throws NumberFormatException,
IOException {
System.out.println("enter the no. of elements to enter");
int n = Integer.parseInt(br.readLine());
int x[] = new int[n];
int half;
for (int i = 0; i < n; i++) {

}
int sum = 0;
for (int i = 0; i < n; i++) {
sum = sum + x[i];
}
if (sum % 2 != 0) {
System.out.println("the sum is odd and cannot be divided");
System.out.println("The sum is " + sum);
}

else {
boolean div = false;
half = sum / 2;
int sum1 = 0;
for (int i = 0; i < n; i++) {

sum1 = sum1 + x[i];
if (sum1 == half) {
System.out.println("array can be divided");
div = true;
break;
}

}
if (div == true) {
int t = 0;
int[] array1 = new int[n];
int count = 0;
for (int i = 0; i < n; i++) {
t = t + x[i];
if (t <= half) {
array1[i] = x[i];
count++;
}
}
array1 = Arrays.copyOf(array1, count);
int array2[] = new int[n - count];
int k = 0;
for (int i = count; i < n; i++) {
array2[k] = x[i];
k++;
}
System.out.println("The first array is ");
for (int m : array1) {

System.out.println(m);
}
System.out.println("The second array is ");
for (int m : array2) {

System.out.println(m);
}
} else {
System.out.println("array cannot be divided");
}
}
}
``````

}

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Tried a different solution . other than Wiki solutions (Partition Problem).

``````static void subSet(int array[]) {
System.out.println("Input elements  :" + Arrays.toString(array));

int sum = 0;
for (int element : array) {
sum = sum + element;
}
if (sum % 2 == 1) {
System.out.println("Invalid Pair");
return;
}

Arrays.sort(array);
System.out.println("Sorted elements :" + Arrays.toString(array));

int subSum = sum / 2;

int[] subSet = new int[array.length];
int tmpSum = 0;
boolean isFastpath = true;
int lastStopIndex = 0;
for (int j = array.length - 1; j >= 0; j--) {
tmpSum = tmpSum + array[j];
if (tmpSum == subSum) { // if Match found
if (isFastpath) { // if no skip required and straight forward
// method
System.out.println("Found SubSets 0..." + (j - 1) + " and "
+ j + "..." + (array.length - 1));
} else {
subSet[j] = array[j];
array[j] = 0;
System.out.println("Found..");
System.out.println("Set 1" + Arrays.toString(subSet));
System.out.println("Set 2" + Arrays.toString(array));
}
return;
} else {
// Either the tmpSum greater than subSum or less .
// if less , just look for next item
if (tmpSum < subSum && ((subSum - tmpSum) >= array[0])) {
if (lastStopIndex > j && subSet[lastStopIndex] == 0) {
subSet[lastStopIndex] = array[lastStopIndex];
array[lastStopIndex] = 0;
}
lastStopIndex = j;
continue;
}
isFastpath = false;
if (subSet[lastStopIndex] == 0) {
subSet[lastStopIndex] = array[lastStopIndex];
array[lastStopIndex] = 0;
}
tmpSum = tmpSum - array[j];
}
}

}
``````

I have tested. ( It works well with positive number greater than 0) please let me know if any one face issue.

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## protected by DarkCthulhuNov 11 '13 at 9:28

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