# Subsequence with maximum sum in array of ints [duplicate]

Given an array of integers, how can you find two indices, i and j, such that the sum of the elements in the subarray starting and ending at the indices is maximized, in linear time?

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## marked as duplicate by DukelingJun 13 at 6:39

You mean - between the indices? –  Vladimir Nov 10 '09 at 9:06
`i = 0` and `j = array.length-1` :) –  Bart Kiers Nov 10 '09 at 9:08
@Bart, who said that array elements are greater than zero? –  Pavel Shved Nov 10 '09 at 9:09
The answers so far seem to assume you meant "sum of the elements from index i to index j" but as far as I see you only ask for the sum of elements i and j, care to elaborate? (Also can i == j? the answer would be `2 * max(array values)` in that case :-) ) –  rsp Nov 10 '09 at 10:46
sum of the elements in between. and there are negative elements –  Claudiu Nov 10 '09 at 17:23

from my copy of programming pearls:

``````maxsofar = 0
maxendinghere = 0
for i = [0, n)
/* invariant: maxendinghere and maxsofar are accurate
are accurate for x[0..i-1] */
maxendinghere = max(maxendinghere + x[i], 0)
maxsofar = max(maxsofar, maxendinghere)
``````
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A correct and a succinct one. But it took you the same time to copy it down as for me to devise it :) –  Pavel Shved Nov 10 '09 at 9:39
Soooo, what's `i` and `j` then? –  Crescent Fresh Nov 10 '09 at 12:33
It's worth mentioning that this is actually called Kadane's algorithm; discovered (or invented, whichever floats your boat) in 1984 by Jay Kadane of Carnegie-Mellon. It is the only known linear time algorithm to solve this problem, which is more generally known as the Maximum Subarray Problem. –  Cory Gross Aug 2 '13 at 23:54
wont work when all the values of the input array are negative –  Vinisha Vyasa Mar 20 at 2:43
@jillesdewit , in subsequence the elements are not necessarily contiguous. for eg: in array [1,2,3,4,5] [2,3,4] is sub array and [1,3,5] is a subsequence –  hareendra reddy Jun 10 at 18:35

Simple. Assume you're given the array `a`. First, you calculate the array `s`, where `s[i] = a[0]+a[1]+...+a[i]`. You can do it in linear time:

``````s[0]=a[0];
for (i=1;i<N;i++) s[i]=s[i-1]+a[i];
``````

Now, the sum `a[i]+a[i+1]+..+a[j]` is equal to `s[j]-s[i-1]`. For a fixed `j`, to maximize the value of this difference, you should find a minimal `s[i-1]` in range of `0..(j-1)`.

Imagine a usual algorithm to find minimal value in the array.

``````min = x[0];
for (j=1; j<N; j++)
if (x[j] < min)
min = x[j];
``````

You iterate and compare each array element to `min`... But on each iteration this `min` is the lowest value in array, where index range is of `0..j`! And that's what we're looking for!

``````global_max = a[0];
max_i = max_j = 0;
local_min_index = 0;
for (j=1; j<N; j++){
// here local_min is the lowest value of s[i], where 0<=i<j
if (s[j] - s[local_min_index] > global_max) {
global_max = s[j] - s[local_min_index]
//update indices
max_i = local_min_index + 1;
max_j = j;
}
//update local_min_index for next iteration
if (s[j]<local_min){
local_min = s[j];
// update indices
local_min_index = j;
}
}
``````
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Thanks to an anonymous user for his lengthy post explaining the bugs in the code. I got rid of them, except for the failure if `N==0`. –  Pavel Shved Mar 29 '13 at 22:46

this python code returns the bounds of the sequence. in terms of the original question, `i=bestlo`, `j=besthi-1`.

``````#
# given a sequence X of signed integers,
# find a contiguous subsequence that has maximal sum.
# return the lo and hi indices that bound the subsequence.
# the subsequence is X[lo:hi] (exclusive of hi).
#
def max_subseq(X):
#
# initialize vars to establish invariants.
# 1: best subseq so far is [bestlo..besthi), and bestsum is its sum
# 2: cur subseq is [curlo..curhi), and cursum is its sum
#
bestlo,besthi,bestsum  =  0,0,0
curlo,curhi,cursum  =  0,0,0
for i in xrange(len(X)):
# extend current subseq and update vars
curhi = i+1
cursum += X[i]
if cursum <= 0:
#
# the current subseq went under water,
# so it can't be usefully extended.
# start fresh at next index.
#
curlo = curhi
cursum = 0
elif cursum > bestsum:
# adopt current subseq as the new best
bestlo,besthi,bestsum  =  curlo,curhi,cursum

return (bestlo,besthi)
``````

and here are some doctest examples that this code passes.

``````    r'''
doctest examples:
>>> print max_subseq([])
(0, 0)
>>> print max_subseq([10])
(0, 1)
>>> print max_subseq([-1])
(0, 0)
>>> print max_subseq(xrange(5))
(1, 5)
>>> print max_subseq([-1, 1, -1])
(1, 2)
>>> print max_subseq([-1, -1, 1, 1, -1, -1, 1, 2, -1])
(6, 8)
>>> print max_subseq([-2, 11, -4, 13, -5, -2])
(1, 4)
>>> print max_subseq([4, -3, 5, -2, -1, 2, 6,-4])
(0, 7)
'''
``````
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You actually need Kadane's algorithm modification that remembers lower and upper bounds for the sub-array, here's C++11 code:

``````#include <iostream>
#include <vector>

typedef std::pair<std::vector<int>::iterator, std::vector<int>::iterator> SubSeq;

SubSeq getMaxSubSeq(std::vector<int> &arr) {
SubSeq maxSequence{arr.begin(), arr.begin()};
auto tmpBegin = arr.begin();
int maxEndingHere = 0;
int maxSoFar = 0;

for(auto it = arr.begin(); it < arr.end(); ++it) {
int currentSum = maxEndingHere + *it;

if(currentSum > 0) {
if(maxEndingHere == 0) {
tmpBegin = it;
}
maxEndingHere = currentSum;
} else {
maxEndingHere = 0;
}

if(maxEndingHere > maxSoFar) {
maxSoFar = maxEndingHere;
maxSequence.first = tmpBegin;
maxSequence.second = it + 1;
}
}

return maxSequence;
}

int main()
{
std::vector<int> arr{-1, 2, 90, -50, 150, -300, 56, 12};

auto seq = getMaxSubSeq(arr);
while(seq.first != seq.second) {
std::cout << *(seq.first) << " ";
++(seq.first);
}

return 0;
}
``````
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