# Zero sum SubArray

An array contains both positive and negative elements, find the subarray whose sum equals 0.

-
Empty subarray has zero sum. :) – Serge Dundich Apr 4 '11 at 2:47
Isn't the usual question to find the largest subarray? – highBandWidth Apr 4 '11 at 2:57

This algorithm will find all subarrays with sum 0 and it can be easily modified to find the minimal one or to keep track of the start and end indexes. This algorithm is O(n).

Given an `int[] input` array, you can create an `int[] tmp` array where `tmp[i] = tmp[i - 1] + input[i];` Each element of tmp will store the sum of the input up to that element.

Now if you check tmp, you'll notice that there might be values that are equal to each other. Let's say that this values are at indexes `j an k with j < k`, then the sum of the input till `j` is equal to the sum till `k` and this means that the sum of the portion of the array between `j` and `k` is 0! Specifically the 0 sum subarray will be from index j + 1 to k.

• NOTE: if `j + 1 == k`, then `k is 0` and that's it! ;)
• NOTE: The algorithm should consider a virtual `tmp[-1] = 0`;
• NOTE: An empty array has sum 0 and it's minimal and this special case should be brought up as well in an interview. Then the interviewer will say that doesn't count but that's another problem! ;)

The implementation can be done in different ways including using a HashMap with pairs but be careful with the special case in the NOTE section above.

Example:

``````int[] input = {4,  6,  3, -9, -5, 1, 3, 0, 2}
int[] tmp =   {4, 10, 13,  4, -1, 0, 3, 3, 5}
``````
• Value 4 in tmp at index 0 and 3 ==> sum tmp 1 to 3 = 0, length (3 - 1) + 1 = 4
• Value 0 in tmp at index 5 ==> sum tmp 0 to 5 = 0, length (5 - 0) + 1 = 6
• Value 3 in tmp at index 6 and 7 ==> sum tmp 7 to 7 = 0, length (7 - 7) + 1 = 1

UPDATE

Assuming that in our tmp array we end up with multiple element with the same value then you have to consider every identical pair in it! Example (keep in mind the virtual '0' at index '-1'):

``````int[] array = {0, 1, -1, 0}
int[] tmp = {0, 1, 0, 0}
``````

By applying the same algorithm described above the 0-sum subarrays are delimited by the following indexes (included):

`[0] [0-2] [0-3] [1-2] [1-3] [3]`

Although the presence of multiple entries with the same value might impact the complexity of the algorithm depending on the implementation, I believe that by using an inverted index on tmp (mapping a value to the indexes where it appears) we can keep the running time at O(n).

-
>> Consider this test-case: 0, 1, -1, 0 the temp array is 0, 1, 0, 0 So, according to you, how many sub-arrays are there whose sum is zero? – Sunny Mar 1 '13 at 21:13
Thanks for pointing this special case out, please see my update to the answer above. There should be 6 (+ the empty array if you want)! – Gevorg Mar 2 '13 at 21:48
why isn't this answer accepted? i can see it works just fine. – Yasser Apr 17 '13 at 13:05
can you elaborate how to keep O(n) running time when there are a considerable amount of duplicate entries? thanks – mintaka Sep 12 '13 at 3:20
@shreyasva you should accept this answer. Are you seeing any issues with it? – Trying Oct 4 '13 at 2:00

This is one the same lines as suggested by Gevorg but i have used a hash map for quick lookup. O(n) complexity used extra space though.

``````private static void subArraySumsZero() {
int [] seed = new int[] {1,2,3,4,-9,6,7,-8,1,9};
int currSum = 0;
HashMap<Integer, Integer> sumMap = new HashMap<Integer, Integer>();
for(int i = 0 ; i < seed.length ; i ++){
currSum += seed[i];
if(currSum == 0){
System.out.println("subset : { 0 - " + i + " }");
}else if(sumMap.get(currSum) != null){
System.out.println("subset : { " + (sumMap.get(currSum) + 1) + " - " + i + " }");
sumMap.put(currSum, i);
}else
sumMap.put(currSum, i);
}
System.out.println("HASH MAP HAS: " + sumMap);
}
``````

The output generated has index of elements (zero based):

``````subset : { 1 - 4 }
subset : { 3 - 7 }
subset : { 6 - 8 }
``````
-
Your implementation has a problem. For the array [4,10,-6,-4,0,2,3,-5,1,0,2] Your output will be - {1 3} {4}{5 7} {9} Actual answer should be {1 3}{4}{5 7}{9}{1 4}{1 5} {1 7} {4 7} – DJ' Aug 2 '13 at 3:05

Here's my implementation, it's the obvious approach so it's probably sub-optimized, but at least its clear. Please correct me if i'm wrong.

Starts from each index of the array and calculates and compares the individual sums (tempsum) with the desired sum (in this case, sum = 0). Since the integers are signed, we must calculate every possible combination.

If you don't need the full list of sub-arrays, you can always put conditions in the inner loop to break out of it. (Say you just want to know if such a sub-array exists, just return true when tempsum = sum).

``````    public static string[] SubArraySumList(int[] array, int sum)
{
int tempsum;
List<string> list = new List<string>();

for (int i = 0; i < array.Length; i++)
{
tempsum = 0;

for (int j = i; j < array.Length; j++)
{
tempsum += array[j];

if (tempsum == sum)
{
}
}
}

return list.ToArray();
}
``````

Calling the function:

int[] array = SubArraySumList(new int { 0, -1, 1, 0 }, 0));

Printing the contents of the output array:

[0-0], [0-2], [0-3], [1-2], [1-3], [3-3]

-
``````1. Given A[i]
A[i] | 2 |  1 | -1 | 0 | 2 | -1 | -1
-------+---|----|--------|---|----|---
sum[i] | 2 |  3 |  2 | 2 | 4 |  3 |  2

2. sum[i] = A[0] + A[1] + ...+ A[i]
3. build a map<Integer, Set>
4. loop through array sum, and lookup map to get the set and generate set, and push <sum[i], i> into map.

Complexity O(n)
``````
-

An array contains positive and negative numbers. Find the sub-array that has the maximum sum

``````public static int findMaxSubArray(int[] array)
{
int max=0,cumulativeSum=0,i=0,start=0,end=0,savepoint=0;
while(i<array.length)
{
if(cumulativeSum+array[i]<0)
{
cumulativeSum=0;
savepoint=start;
start=i+1;
}
else
cumulativeSum=cumulativeSum+array[i];
if(cumulativeSum>max)
{
max=cumulativeSum;
savepoint=start;
end=i;
}
i++;
}

System.out.println("Max : "+max+"  Start indices : "+savepoint+"  end indices : "+end);
return max;

}
``````
-

Below codes can find out every possible sub-array that has a sum being a given number, and (of course) it can find out the shortest and longest sub-array of that kind.

``````public static void findGivenSumSubarray(int arr[], int givenSum) {
int sum = 0;
int sStart = 0, sEnd = Integer.MAX_VALUE - 1;  // Start & end position of the shortest sub-array
int lStart = Integer.MAX_VALUE - 1, lEnd = 0;  // Start & end position of the longest  sub-array

HashMap<Integer, ArrayList<Integer>> sums = new HashMap<>();
ArrayList<Integer> indices = new ArrayList<>();

sums.put(0, indices);

for (int i = 0; i < arr.length; i++) {
sum += arr[i];
indices = sums.get(sum - givenSum);
if(indices != null) {
for(int index : indices) {
System.out.println("From #" + (index + 1) + " to #" + i);
}
if(i - indices.get(indices.size() - 1) < (sEnd - sStart + 1)) {
sStart = indices.get(indices.size() - 1) + 1;
sEnd = i;
}
if(i - indices.get(0) > (lEnd - lStart + 1)) {
lStart = indices.get(0) + 1;
lEnd = i;
}
}
indices = sums.get(sum);
if(indices == null) {
indices = new ArrayList<>();
}
sums.put(sum, indices);
}

System.out.println("Shortest sub-arry: Length = " + (sEnd - sStart + 1) + ", [" + sStart + " - " + sEnd + "]");
System.out.println("Longest  sub-arry: Length = " + (lEnd - lStart + 1) + ", [" + lStart + " - " + lEnd + "]");
}
``````
-

Hope this will help.

``````int v[DIM] = {2, -3,  1,  2,  3,  1,  4, -6,  7, -5, -1};
int i,j,sum=0,counter=0;

for (i=0; i<DIM; i++) {
sum = v[i];
counter=0;
for (j=i+1; j<DIM;j++) {
sum += v[j];
counter++;
if (sum == 0) {
printf("Sub-array starting from index %d, length %d.\n",(j-counter),counter +1);
}
}
}
``````
-