max_so_far = 0
    max_ending_here = 0

Loop for each element of the array
   (a) max_ending_here = max_ending_here + a[i]
   (b) if(max_ending_here < 0)
         max_ending_here = 0
   (c) if(max_so_far < max_ending_here)
          max_so_far = max_ending_here
 return max_so_far

Can anyone help me in understanding the optimal substructure and overlapping problem(bread and butter of DP) i the above algo?

  • 3
    Kadane's algorithm is greedy, IIRC. – nhahtdh May 1 '13 at 18:25
  • 2
    +1, I've been struggling with this myself. I can't decide if it counts as DP or not: we have optimal substructure, but no overlapping subproblems. I've seen it labeled as DP however, but strictly speaking, I'd say it isn't. – IVlad May 1 '13 at 18:26
  • Can't image someone has the same question as I have;) – Eric Z Oct 17 '15 at 3:03

According to this definition of overlapping subproblems, the recursive formulation of Kadane's algorithm (f[i] = max(f[i - 1] + a[i], a[i])) does not exhibit this property. Each subproblem would only be computed once in a naive recursive implementation.

It does however exhibit optimal substructure according to its definition here: we use the solution to smaller subproblems in order to find the solution to our given problem (f[i] uses f[i - 1]).

Consider the dynamic programming definition here:

In mathematics, computer science, and economics, dynamic programming is a method for solving complex problems by breaking them down into simpler subproblems. It is applicable to problems exhibiting the properties of overlapping subproblems1 and optimal substructure (described below). When applicable, the method takes far less time than naive methods that don't take advantage of the subproblem overlap (like depth-first search).

The idea behind dynamic programming is quite simple. In general, to solve a given problem, we need to solve different parts of the problem (subproblems), then combine the solutions of the subproblems to reach an overall solution. Often when using a more naive method, many of the subproblems are generated and solved many times. The dynamic programming approach seeks to solve each subproblem only once, thus reducing the number of computations

This leaves room for interpretation as to whether or not Kadane's algorithm can be considered a DP algorithm: it does solve the problem by breaking it down into easier subproblems, but its core recursive approach does not generate overlapping subproblems, which is what DP is meant to handle efficiently - so this would put it outside DP's specialty.

On the other hand, you could say that it is not necessary for the basic recursive approach to lead to overlapping subproblems, but this would make any recursive algorithm a DP algorithm, which would give DP a much too broad scope in my opinion. I am not aware of anything in the literature that definitely settles this however, so I wouldn't mark down a student or disconsider a book or article either way they labeled it.

So I would say that it is not a DP algorithm, just a greedy and / or recursive one, depending on the implementation. I would label it as greedy from an algorithmic point of view for the reasons listed above, but objectively I would consider other interpretations just as valid.

| improve this answer | |
  • 1
    It is also interesting that it only involves two elements of storage. This again makes it feel less like a typical DP algorithm. Do you know of any other algorithms that are thought of as DP with so little storage required? – Peter de Rivaz May 1 '13 at 20:58
  • 5
    @PeterdeRivaz - the fibonacci recurrence would count: it has optimal substructure and overlapping subproblems and can also be implemented with O(1) memory. – IVlad May 1 '13 at 21:56

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