# in Java, design linear algorithm that finds contiguous subsequence with highest sum

this is the question, and yes it is homework, so I don't necessarily want anyone to "do it" for me; I just need suggestions: Maximum sum: Design a linear algorithm that finds a contiguous subsequence of at most M in a sequence of N long integers that has the highest sum among all such subsequences. Implement your algorithm, and confirm that the order of growth of its running time is linear.

I think that the best way to design this program would be to use nested for loops, but because the algorithm must be linear, I cannot do that. So, I decided to approach the problem by making separate for loops (instead of nested ones).

However, I'm really not sure where to start. The values will range from -99 to 99 (as per the range of my random number generating program).

This is what I have so far (not much):

``````public class MaxSum {

public static void main(String[] args){
int M = Integer.parseInt(args[0]);
long[] a = new long[N];
for (int i = 0; i < N; i++) {
``````

if M were a constant, this wouldn't be so difficult. For example, if M==3:

``````public class MaxSum2 {

public static void main(String[] args){
long[] a = new long[N]; //create array of size N
for (int i = 0; i < N; i++) { //go through values of array
//array indices

long p = a[0] + a[1] + a[2]; //start off with first 3 indices

for (int i =0; i<N-4; i++)
{if ((a[i]+a[i+1]+a[1+2])>=p) {p=(a[i]+a[i+1]+a[1+2]);}}
//if sum of values is greater than p, p becomes that sum

for (int i =0; i<N-4; i++) //prints the subsequence that equals p
{if ((a[i]+a[i+1]+a[1+2])==p) {StdOut.println((a[i]+a[i+1]+a[1+2]));}}}}
``````

If I must, I think MaxSum2 will be acceptable for my lab report (sadly, they don't expect much). However, I'd really like to make a general program, one that takes into consideration the possibility that, say, there could be only one positive value for the array, meaning that adding the others to it would only reduce it's value; Or if M were to equal 5, but the highest sum is a subsequence of the length 3, then I would want it to print that smaller subsequence that has the actual maximum sum.

I also think as a novice programmer, this is something I Should learn to do. Oh and although it will probably be acceptable, I don't think I'm supposed to use stacks or queues because we haven't actually covered that in class yet.

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Look into this: en.wikipedia.org/wiki/Maximum_subarray_problem – Kuba Spatny Apr 6 '14 at 8:06
I would argue that the nested loops solution is in fact linear in `N`. – David Wallace Apr 6 '14 at 8:06
possible duplicate of Find Portion in a sequence with max sum – Lokesh Apr 6 '14 at 8:07
@Lokesh I don't think it's a duplicate. That question doesn't have `M`. – David Wallace Apr 6 '14 at 8:11
I am convinced that I need to rest my brain and come back to this, haha. It's a bit late where I am. But @PetarMinchev, you're code looks convincing and I've read the comments. However, I am going to try to sort of rewrite it "in my own words," so to speak. And I will update as soon as I do so (probably about 8-12 hours from now). – amaleemur Apr 6 '14 at 9:58

Each element is looked at most twice (one time in the outer loop, and one time in the while loop).

`O(2N) = O(N)`

Explanation: each element is added to the current sum. When the sum goes below zero, it is reset to zero. When we hit M length sequence, we try to remove elements from the beginning, until the sum is `> 0` and there are no negative elements in the beginning of it.

By the way, when all elements are `< 0` inside the array, you should take only the largest negative number. This is a special edge case which I haven't written below.

Beware of bugs in the below code - it only illustrates the idea. I haven't run it.

``````int sum = 0;
int currentStart = 0;

int bestSum = 0;
int bestStart = 0;
int bestEnd = 0;

for (int i = 0; i < N; i++) {
sum += a[i];
if (sum > bestSum) {
bestSum = sum;
bestStart = currentStart;
bestEnd = i;
}

if (sum < 0) {
sum = 0;
currentStart = i + 1;
continue;
}

//Our sequence length has become equal to M
if (i - currentStart + 1 == M) {
do {
sum -= a[currentStart];
currentStart++;
} while ((sum < 0 || a[currentStart] < 0) && (currentStart <= i));
}
}
``````
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But why does it work? I can't follow your explanation. – David Wallace Apr 6 '14 at 8:30
So while it's sliding in that way, how do you know that you won't miss a case where there's a big number in the middle of the range, and negative numbers on each side of it? The correct answer might be of length one, but your window always includes one of the negatives, and never gets narrow enough to just have the single number. – David Wallace Apr 6 '14 at 8:58
I think I need to play with this more to be truly convinced. As I said, your argument just hasn't 100% convinced me yet. – David Wallace Apr 6 '14 at 9:07
It's OK. I might just cut and paste your solution into my IDE and try a few sequences myself. I'm just very glad that I'm not amaleemur's teacher, having to decide whether the algorithm is "correct" or not, in order to give her the right grade. – David Wallace Apr 6 '14 at 9:09
I've had a bit of a play. I think it's probably right, but I'm not sure. My best advice to amaleemur though would be to hand in a solution that she knows is correct, in case her teacher asks her to justify it. So unless you can come up with an argument that convinces her that this algorithm is correct, and which she can easily relay to her teacher, I would advise her to do it the "nested loops" way, even though that algorithm is very probably inferior to this one. – David Wallace Apr 6 '14 at 9:36

Here is my version, adapted from Petar Minchev's code and with an important addition that allows this program to work for an array of numbers with all negative values.

``````public class MaxSum4 {

public static void main(String[] args)
{Stopwatch banana = new Stopwatch(); //stopwatch object for runtime data.

long sum = 0;
int currentStart = 0;
long bestSum = 0;
int bestStart = 0;
int bestEnd = 0;

int M = Integer.parseInt(args[0]); // read in highest possible length of
//subsequence from command line argument.
long[] a = new long[N];
for (int i = 0; i < N; i++) {//read in values from standard input
a[i] = StdIn.readLong();}//and assign those values to array
long negBuff = a[0];

for (int i = 0; i < N; i++) { //go through values of array to find
//largest sum (bestSum)
sum += a[i];                  //and updates values. note bestSum, bestStart,
// and bestEnd updated
if (sum > bestSum) {          //only when sum>bestSum
bestSum = sum;
bestStart = currentStart;
bestEnd = i; }

if (sum < 0) { //in case sum<0, skip to next iteration, reseting sum=0
sum = 0;   //and update currentStart
currentStart = i + 1;
continue; }

if (i - currentStart + 1 == M) { //checks if sequence length becomes equal
//to M.
do {                          //updates sum and currentStart
sum -= a[currentStart];
currentStart++;
} while ((sum < 0 || a[currentStart] < 0) && (currentStart <= i));
//if sum or a[currentStart]
}                   //is less than 0 and currentStart<=i,
}                       //update sum and currentStart again

if(bestSum==0){ //checks to see if bestSum==0, which is the case if
//all values are negative
for (int i=0;i<N;i++){ //goes through values of array
//to find largest value
if (a[i] >= negBuff) {negBuff=a[i];
bestSum=negBuff; bestStart=i; bestEnd=i;}}}

StdOut.print("best subsequence is from
a[" + bestStart + "] to a[" + bestEnd + "]: ");
for (int i = bestStart; i<=bestEnd; i++)
{
StdOut.print(a[i]+ " "); //prints sequence
}
StdOut.println();
StdOut.println(banana.elapsedTime());}}//prints elapsed time
``````

also, did this little trace for Petar's code:

``````trace for a small array

M=2

array: length 5

index value
0      -2
1       2
2       3
3       10
4       1

for the for-loop central to program:

i = 0   sum = 0 + -2 = -2
sum>bestSum? no
sum<0? yes so sum=0, currentStart = 0(i)+1 = 1,
and continue loop with next value of i

i = 1   sum = 0 + 2 = 2
sum>bestSum? yes so bestSum=2 and bestStart=currentStart=1 and bestEnd=1=1
sum<0? no
1(i)-1(currentStart)+1==M? 1-1+1=1 so no

i = 2   sum = 2+3 = 5
sum>bestSum? yes so bestSum=5, bestStart=currentStart=1, and bestEnd=2
sum<0? no
2(i)-1(currentStart)+1=M? 2-1+1=2 so yes:
sum = sum-a[1(curentstart)] =5-2=3. currentStart++=2.
(sum<0 || a[currentStart]<0)? no

i = 3   sum=3+10=13
sum>bestSum? yes so bestSum=13 and bestStart=currentStart=2 and bestEnd=3
sum<0? no
3(i)-2(currentStart)+1=M? 3-2+1=2 so yes:
sum = sum-a[1(curentstart)] =13-3=10. currentStart++=3.
(sum<0 || a[currentStart]<0)? no

i = 4   sum=10+1=11
sum>bestSum? no
sum<0? no
4(i)-3(currentStart)+1==M? yes but changes to sum and currentStart now are
irrelevent as loop terminates
``````

Thanks again! Just wanted to post a final answer and I was slightly proud for catching the all negative thing.

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oh, and if anyone cares: stopwatch values confirm that this is definitely linear! – amaleemur Apr 7 '14 at 5:18
Great :) But I think you have a small bug - `//checks to see if bestSum==0, which is the case if all values are negative`. This sentence is not entirely true. I think if the sequence is `-4,-3,0`, the answer is `0` not `-3`. – Petar Minchev Apr 7 '14 at 6:57
Also could you post here when your teacher gives the feedback? – Petar Minchev Apr 7 '14 at 6:57
@PetarMinchev, my code returns 0 for that array. bestSum==0 when all values <= 0, so then it just finds the maximum for the entire array. because 0>=-3, the values are updated and (in your example) a[2] is printed. I'm not sure why you think it would give -3 as the max value unless you are thinking in terms of absolute value. And of course, bestSum will in fact be 0 for your example, but the desired output is the location of that zero. – amaleemur Apr 7 '14 at 7:54
And yes, I will get my report back next Monday, the 14th. When I get it, I will post any relevant feedback. Or, if they give no feedback, I will assume everything worked out. – amaleemur Apr 7 '14 at 7:57

I still don't have enough reputation to comment on the other answers, so I will point out here that user David Wallace was right all along and the generally accepted solution to this question is wrong. As a counterexample, try using `a=[5, 0, -5, 6, -3, 9]` and `M=4` and you will get `9` as the answer, and not `12`.

A linear solution for this problem was described in `Efficient algorithms for locating the length-constrained heaviest segments with applications to biomolecular sequence analysis` (by Yaw-Ling Lin, Tao Jiang, and Kun-Mao Chaoc; Journal of Computer and System Sciences 65 (2002) 570--586). You can get it at the author's page. Here's my implementation (in python, sorry) where `L` holds the list and `k` is the maximum acceptable length of the sublist.

``````def mln_point(L):
n = len(L)
p = [0]*n
w = [0]*n
for i in range(n-1, -1, -1):
p[i] = i
w[i] = L[i]
while p[i]<n-1 and w[i] <= 0:
w[i] += w[p[i]+1]
p[i] = p[p[i]+1]

return p, w

n = len(L)
p, w = mln_point(L)
ms = j = i = 0
while i < n:
while i<n and L[i] <= 0:
i += 1
j = max(i, j)
while j < n-1 and p[j+1]<i+k and w[j+1] > 0:
j = p[j+1]
ms = max(ms, sum(L[i:j+1]))
i += 1

return ms
``````
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You are right, thanks for the link :) I have missed the left negative stuff. – Petar Minchev Jul 15 at 7:33

I think what you are looking for is discussed in detail here

Find the subsequence with largest sum of elements in an array

I have explained 2 different solutions to resolve this problem with O(N) - linear time.

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