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In an interview one of my friends was asked to find the subarray of an array with maximum sum, this my solution to the problem , how can I improve the solution make it more optimal , should i rather consider doing in a recursive fashion ?

def get_max_sum_subset(x):
        max_subset_sum = 0
        max_subset_i = 0
        max_subset_j = 0
        for i in range(0,len(x)+1):
            for j in range(i+1,len(x)+1):
                current_sum = sum(x[i:j])
                if current_sum > max_subset_sum:
                    max_subset_sum = current_sum
                    max_subset_i = i
                    max_subset_j = j
        return max_subset_sum,max_subset_i,max_subset_j
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marked as duplicate by Dukeling Jun 13 at 6:29

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

2  
No, you should try to find an O(N) solution. –  n.m. Oct 30 '11 at 8:19

13 Answers 13

up vote 11 down vote accepted

Your solution is O(n^2). The optimal solution is linear. It works so that you scan the array from left to right, taking note of the best sum and the current sum:

def get_max_sum_subset(x):
    bestSoFar = 0
    bestNow = 0
    bestStartIndexSoFar = -1
    bestStopIndexSoFar = -1
    bestStartIndexNow = -1
    for i in xrange(len(x)):
        value = bestNow + x[i]
        if value > 0:
            if bestNow == 0:
                bestStartIndexNow = i
            bestNow = value
        else:
            bestNow = 0

        if bestNow > bestSoFar:
            bestSoFar = bestNow
            bestStopIndexSoFar = i
            bestStartIndexSoFar = bestStartIndexNow

    return bestSoFar, bestStartIndexSoFar, bestStopIndexSoFar

This problem was also discussed thourougly in Programming Pearls: Algorithm Design Techniques (highly recommended). There you can also find a recursive solution, which is not optimal (O(n log n)), but better than O(n^2).

share|improve this answer
    
What if the max array can contain negative values (and they aren't changed to 0)? I.e. [3, -1, 5, -6, -9] max is [3, -1, 5]. Same O(N) algorithm as above, or does it need tweaks? –  noahlz Jun 28 '12 at 21:47
    
This algorithm handles that case. –  Antti Jun 29 '12 at 15:25
    
Thanks, I put the C implementation here: gist.github.com/3019861 –  noahlz Jun 29 '12 at 18:32
    
there is an O(n) solution, I was asked to do this on an interview and I bombed it... –  Stan R. Mar 22 '13 at 0:37
    
Yep, this one is O(n) (=linear). –  Antti Mar 22 '13 at 16:31

This is a well-known problem that displays overlapping optimal substructure, which suggests a dynamic programming (DP) solution. Although DP solutions are usually quite tricky (I think so at least!), this one is a great example to get introduced to the whole concept.

The first thing to note is that the maximal subarray (which must be a contiguous portion of the given array A) ending at position j either consists of the maximimal subarray ending at position j-1 plus A[j], or is empty (this only occurs if A[j] < 0). In other words, we are asking whether the element A[j] is contributing positively to the current maximum sum ending at position j-1. If yes, include it in the maximal subarray so far; if not, don't. Thus, from solving smaller subproblems that overlap we can build up an optimal solution.

The sum of the maximal subarray ending at position j can then be given recursively by the following relation:

sum[0] = max(0, A[j])
sum[j] = max(0, sum[j-1] + A[j])

We can build up these answers in a bottom-up fashion by scanning A from left to right. We update sum[j] as we consider A[j]. We can keep track of the overall maximum value and the location of the maximal subarray through this process as well. Here is a quick solution I wrote up in Ruby:

def DP_solve(a)
    max, head, tail = 0, 0, 0
    cur_head = 0
    sum = [ [0, a[0]].max ] # base case
    (1...a.size).each do |j|
        sum[j] = [0, sum[j-1] + a[j]].max # bottom-up
        cur_head = j if sum[j-1] == 0 and sum[j] > 0
        if sum[j] > max
            head = cur_head
            tail = j
            max = sum[j]
        end
    end
    return max, head, tail
end

This is clearly a linear O(N) algorithm since only one pass through the list is required. Hope this helps!

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let n - elements count, a(i) - your array f(i) - maximum sum of subarray that ends at position i (minimum length is 1). Then:

f(0) = a(i);
f(i) = max(f(i-1), 0) + a(i); //f(i-1) when we continue subarray, or 0 - when start at i position

max(0, f(1), f(2), ... , f(n-1)) - the answer

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There is a short video from MIT that helps you understand this dynamic programming problem. http://people.csail.mit.edu/bdean/6.046/dp/ Click on the first link under the 'problems' section and you will see it.

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A much better solution approach can be derived by thinking about what conditions must hold for a maximum-sum sub-array: the first item on either end that is not included (if any) must be negative and the last item on either end that is included must be non-negative. You don't need to consider any other end points for the sub-array except where these changes occur in the original data.

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1  
This is a useful observation but doesn't help to change it from an O(n^2) algorithm. –  Simon Nickerson Oct 30 '11 at 8:39

Unless I'm missing something important, if they are positive integers the subset would include the whole array, if they're integers, it would include only positive integers. Is there another constraint there?

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2  
Yes, consider -100, 100, -1, 100, -100. The maximum sum subarray will include -1. –  Simon Nickerson Oct 30 '11 at 8:23
3  
You are missing something important. The numbers are not necessarily positive. If you include two numbers, you must include everything in between. That's the meaning of subarray — arrays are contiguous. –  n.m. Oct 30 '11 at 8:25
    
So a subarray must have contiguous elements, right? –  jjmerelo Oct 30 '11 at 8:29
    
The elements must be contiguous, otherwise the problem is trivial (all positive elements). –  Ted Hopp Oct 30 '11 at 8:33

Here is a simple O(N) algorithm from http://en.wikipedia.org/wiki/Maximum_subarray_problem

int maxsofar=0;
int maxendinghere=0;
for i=[0 n] {
    maxendinghere=max(maxendinghere+x[i],0);
    maxsofar=max(maxsofar,maxendinghere);
}
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3  
Are you going to quote the wikipedia article you copied this from? Also, last statement belongs in the loop. –  Simon Nickerson Oct 30 '11 at 8:25
    
yes it includes in loop,as first question no copy,from nowhere,i had have dont it many times ,so i know it –  dato datuashvili Oct 30 '11 at 8:26
    
if it is not zero based,then he/she could create one based array,no problem –  dato datuashvili Oct 30 '11 at 8:30
    
This is the O(N) algorithm from en.wikipedia.org/wiki/Maximum_subarray_problem –  Simon Nickerson Oct 30 '11 at 8:33
    
@n.m is it incorrect?or why ignore it? –  dato datuashvili Oct 30 '11 at 8:33

Java solution:

Does not work for an array with all negatives.

public static int[] maxsubarray(int[] array) {

    //empty array check

    if (array.length == 0){
        return new int[]{}; 
    }

    int max = 0;
    int maxsofar = 0;

    //indices 

    int maxsofarstart = 0;
    int maxsofarend = 0;
    int maxstartindex = 0;

    for (int i = 0; i < array.length; i++) {
        if (array[i] > 0) {

            if (max == 0) {
                maxstartindex = i;
            }

            max = max + array[i];

            if (max > maxsofar) {

                maxsofar = max;
                maxsofarstart = maxstartindex;
                maxsofarend = i;

            }

    } else {
        max = 0;
    }

}

return Arrays.copyOfRange(array, maxsofarstart, maxsofarend + 1);

}
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here is one of most well-expained, tested, working solution - http://rerun.me/blog/2012/08/30/maximum-continuous-subarray-problem-kandanes-algorithm/

package me.rerun;

public class Kadane {

    public static void main(String[] args) {
        int[] intArr={3, -1, -1, -1, -1, -1, 2, 0, 0, 0 };
        //int[] intArr = {-1, 3, -5, 4, 6, -1, 2, -7, 13, -3};
        //int[] intArr={-6,-2,-3,-4,-1,-5,-5};
        findMaxSubArray(intArr);
    }



public static void findMaxSubArray(int[] inputArray){

    int maxStartIndex=0;
    int maxEndIndex=0;
    int maxSum = Integer.MIN_VALUE; 

    int cumulativeSum= 0;
    int maxStartIndexUntilNow=0;

    for (int currentIndex = 0; currentIndex < inputArray.length; currentIndex++) {

        int eachArrayItem = inputArray[currentIndex];

        cumulativeSum+=eachArrayItem;

        if(cumulativeSum>maxSum){
            maxSum = cumulativeSum;
            maxStartIndex=maxStartIndexUntilNow;
            maxEndIndex = currentIndex;
        }
        else if (cumulativeSum<0){
            maxStartIndexUntilNow=currentIndex+1;
            cumulativeSum=0;
        }
    }

    System.out.println("Max sum         : "+maxSum);
    System.out.println("Max start index : "+maxStartIndex);
    System.out.println("Max end index   : "+maxEndIndex);
}

}
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This is the correct Java Code which will handle scenarios including all negative numbers.

public static long[] leftToISumMaximize(int N, long[] D) {
    long[] result = new long[N];
    result[0] = D[0];
    long currMax = D[0];
    for (int i = 1; i < N; i++) {
        currMax = Math.max(D[i], currMax + D[i]);
        result[i] = Math.max(result[i - 1], currMax);
    }
    return result;
}
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There is a simple dynamic programming algorithm for the maximum subarray problem that runs in O(N): Kadane's algorithm. Slight modifications to the basic algorithm will allow you to handle all negative numbers: whether the largest number or 0 should be returned.

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I have made a function for a little more general problem:

  • Find maximum sum subarray (meaning its bounds and sum, not only the sum)
  • If two subarrays have equal sums then pick the shorter one
  • If two equally long subarrays have equal sums then pick the one that appears first.

Function is based on Kadane's algorithm and it runs in O(n) time. Basically, this is it:

function MaxSumSubarray(a, n, start out, len out)
    -- a - Array
    -- n - Length of the array
    -- start - On output starting position of largest subarray
    -- len - On output length of largest subarray
    -- Returns sum of the largest subarray
begin

    start = 0
    len = 1
    int sum = a[0]

    curStart = 0
    curLen = 1
    curSum = a[0]

    for i = 2 to n
        begin
            if a[i] >= curSum + a[i] then
                begin
                    curStart = i
                    curLen = 1
                    curSum = a[i]
                end
            else
                begin
                    curLen = curLen + 1
                    curSum = curSum + a[i]
                end

            if (curSum > sum) OR
               (curSum = sum AND curLen < len) OR
               (curSum = sum AND curLen = len AND curStart < start) then
               begin
                    start = curStart
                    len = curLen
                    sum = curSum
                end

        end

    return sum

end

I've uploaded the whole solution in C#, with analysis and examples, in this article: Maximum Sum Subarray

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Not sure but Accepted Solution didn't for work me for all the scenarios (May be I misunderstood it) So I did small modification, instead of if(value > 0) I changed it yo if(value > bestNow)

.....(I wrote it in Scala)

And it is working for the all scenarios

def findMaxSubArray(list: List[Int]): (Int, Int, Int) = {

 var (bestNow,bestSoFar) = (0, 0)
 var ( startIndexNow, startIndexSoFar, endIndex) = (-1, -1, -1)

 for (i <- 0 until list.length) {
   var value = bestNow + list(i)
   if (value > bestNow) {
     if (bestNow == 0)
       startIndexNow = i
     bestNow = value
   } else
     bestNow = 0

  if (bestNow > bestSoFar) {
    bestSoFar = bestNow
    startIndexSoFar = startIndexNow
    endIndex = i
    } 
  }

  return (bestSoFar, startIndexSoFar, endIndex)
 }     

 def main(args: Array[String]) {
  println(findMaxSubArray(List(3, -1, 5, 3, -6, -9, 6, 1)).toString)
  println(findMaxSubArray(List(3, -1, 5, 3, -6, -9, 6, 3)).toString)
  println(findMaxSubArray(List(20, -1, 5, 3, -6, -9, 6)).toString)
}

   Output.....
    (max =8, start=2, end=3)
    (max=9, start=6, end=7)
    (max=20, start=0, end= 0)
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