How to find the maximum contiguous SUM in an array (which contains positive and negative numbers)?

I want to write a function `ContigSum(i,j)` that calculates the sum of the contiguous elements `a[i]` through `a[j]`, where `i<=j` and `a[]` contains positive and negative numbers.

Could you please tell me a time efficient solution to find maximized contiguous SUM in the array?

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This is sometimes known as the "stock market problem" - how much money could you have made, with prescient investment decisions? –  Novelocrat Jun 15 '10 at 5:29

Well explained in the wikipedia entry about the subject. I find the Python code (i.e., executable pseudocode) they give for Kandane's Algorithm to be a little gem:

``````def max_subarray(A):
max_so_far = max_ending_here = 0
for x in A:
max_ending_here = max(0, max_ending_here + x)
max_so_far = max(max_so_far, max_ending_here)
return max_so_far
``````
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Alex, Thanks a lot. –  siva Jun 15 '10 at 14:57
That is indeed a pretty neat little algorithm. –  Nick Johnson Jun 15 '10 at 15:54

This is discussed in Column 7 of the 1st Edition or Column 8 of the 2nd Edition of 'Programming Pearls' by Jon Bentley.

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Alex, you have a very elegant algorithm but it needs correction for an array that contains a single element that is negative.

Of course, in the original algorithm of Kadane's, one can get the subarray start and end indexes which is useful for knowing the "path".

Here's an inelegant but I think correct Python function:

``````def max_subarray(A):
(maxSum, maxStartIndex, maxEndIndex) = (float("-inf"), 0, 0)
(currentMaxSum,currentStartIndex,currentEndIndex ) = (0,0,0)

for item in A:
currentMaxSum = currentMaxSum + item
if currentMaxSum > maxSum :
(maxSum, maxStartIndex, maxEndIndex) = (currentMaxSum, currentStartIndex, currentEndIndex)
if currentMaxSum < 0 :
currentMaxSum = 0
currentStartIndex = currentEndIndex + 1

# continue here.
currentEndIndex = currentEndIndex + 1

return (maxSum, maxStartIndex, maxEndIndex)
``````
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``````static void MaxContiguousSum(int[] x, int lb, int[] result)
{
int start, end, sum, testSum;

start = lb;
end = lb;

/* Empty vector has 0 sum*/
sum = 0;

testSum = 0;
for (int i=lb; i < x.length; i++)
{
if (sum + x[i] < 0)
{
/* Net contribution by current term is negative. So, contiguous sum lies in [start,i-1]
or [i+1, array upper bound]*/
MaxContiguousSum(x, i+1, result);

if (result[0] < sum)
{
result[0] = sum;
result[1] = start;
result[2] = end;
}
return;

}
else
{
testSum += x[i];

if (testSum > 0)
{
/* Move the end marker since incrementing range is beneficial. */
end = i;

/* update the sum*/
sum += testSum;

/* reset the testSum */
testSum = 0;
}
}

}

/* Update the results */
result[0] = sum;
result[1] = start;
result[2] = end;

return;

}
``````
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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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