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For a given array of real numbers, Kadane's dynamic programming algorithm can find the maximum sum subinterval in the array in linear time. However, suppose that we have done some preprocessing to obtain the optimal solution as well as any required auxilary information, and then we are given a transposition that swaps two elements in the array. Is there a scheme that will allow updating the optimal solution subinterval in sub-linear time, and allow future updates for subsequent transpositions as well? I'm looking for the preprocessing time and extra memory to be o(N^2) for an array of size N.

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How much memory are you allowing yourself to store preprocessed information? – Andrey M. Mishchenko Jan 10 '14 at 20:13
    
@Andrey It doesn't really matter, as long as the cost of preprocessing and doing N updates for an array of size N turns out to be faster than O(N^2). So the memory limit then would naturally be o(N^2) for an array of size N. – user2566092 Jan 10 '14 at 21:11
    
I'm thinking about the problem; meanwhile, I'll say that it might be easier to think about the question of, whether it is possible to solve the same problem but instead of a transposition of two elements, you just modify one of the elements in whatever way you like. Obviously a solution to this problem implies a solution to yours. – Andrey M. Mishchenko Jan 10 '14 at 21:18
    
I'm inclined to think that it may be impossible to find something that does everything you want in better than O(N^2) (for N updates in the list) in the worst case: the reason is that the more you pre-process, the more updates to the pre-proceeded data are required after a change in the list. However I think I have an idea for something that should work pretty well in an "average case." Will post soon, hopefully. – Andrey M. Mishchenko Jan 10 '14 at 21:23
    
Actually, if such a solution wouldn't be useful to you, I won't bother, so let me know if you are interested in seeing something along those lines. – Andrey M. Mishchenko Jan 10 '14 at 21:24

This is a way to pre-process the list to, in the average case, shrink the length of the list considerably. It is also not too hard to update the pre-processed information given a change in one of the entries of the original list.


The idea of the pre-processing procedure is that certain collections of elements can be combined and logically treated as a single element. For example, if there are two positive numbers next to each other in your list, as in

... -1 3 4 -2 ...

then you will never want to include 3 in your maximum subset sum unless you also include 4. So, you can logically treat this portion of your list as

... -1 7 -2 ...

The same thing is true of adjacent negative numbers. So, from now on, we can assume that the signs of the entries of our list alternate.

There are two other simplifications we'll need:

If there are two positive numbers with a negative number between them, and that negative number is smaller in magnitude than either of the two positive numbers, then you will never want to include either positive number in your maximum subset sum without including the other. For example:

... 8 -2 4 ...

can be treated as

... 10 ...

This is because if we are including 4, then we may as well include -2 + 8 = 6 as well, similarly from the other side.

The other simplification is the analog for negative numbers. If there are two negative numbers with a positive number between them, and the positive number is smaller in magnitude than either negative number, then we may treat the triple as a single number. For example:

... -10 4 -12 ...

can be treated as

... -18 ...

It is harder to see why this is valid. Let's say that our maximum subset sum does include one of these three numbers, say -12. Then certainly it includes 4, because that makes the subset sum bigger. But it certainly must include -10 as well, because if it doesn't, then we could cut 4 - 12 = -8 off of the end of the interval and make our subset sum bigger. Intuitively, if this triple lives in the maximum subset sum interval, it is somewhere in the middle of the interval.


You need to apply these three simplifications recursively, until none produces a change in the list. Potentially this can take a long time, but this can be shortened by tracking what tracts of the list have changed since the last iteration and only hitting those tracts with the repeated applications.

The advantage is that, after these modifications are applied, the maximum subset sum is exactly the largest positive entry remaining in the (reduced) list! Here's a proof:


Suppose our list is reduced as per the above simplifications (meaning that applying any one of the three does nothing to it). Suppose for the sake of contradiction that the maximum subset sum of this reduced list consists of more than a single entry. So, let's represent the interval with the maximum subset sum as:

... a1 -b1 a2 -b2 ... a(n-1) b(n-1) an ...

Where the ai are positive, and the bi are negative. (Note that neither end will be a negative number for obvious reasons.)

We will now produce our contradiction:

First, note that a1 < b1, because otherwise we could chop those two elements off that end and obtain a bigger subset sum. Also b1 > a2, because our list is reduced, and if b1 < a2 then a1 -b1 a2 would have been collapsed to a single entry (since we already know that b1 < a1.

Next, note that a2 > b2. This is because if a2 < b2, then this fact combined with b1 < a2 would have caused -b1 a2 -b2 to be collapsed to a single entry, as per the third simplification.

Applying these arguments over and over, we get the string of inequalities:

a1 > b1 > a2 > b2 > ... > a(n-1) > b(n-1) > an

but the last inequality is a contradiction, because if b(n-1) > an, then we can chop those two elements off of the interval and obtain a bigger subset sum.

(Note that I am ignoring the possibility that two adjacent ai and bj are equal. You have to be a little careful with the signs to take care of this case but it works out fine, and the argument is easier to follow with strict inequalities.)


You need to keep the copy of the original list, and when the value of an element changes, apply the simplification steps "centered around" that element to avoid resimplifying more of the list than you have to.

Note that the more simplification you have to (really, are able to) do initially, the smaller the final list you end up with, saving you run-time later. Probably the expected (aggregate) run-time of this is better than O(N^2) but I don't really want to think about it, this is a hairy algorithm to analyze.

It is probably fastest to keep a sorted list of the few highest maximum subset sum candidates, and to update that list selectively after new elements appear.

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