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Given an array of integers, what is the maximum sum of a subset of the integers such that the integers in the subset were not originally next to each other?


[3, 8, 4] => max sum is 8, since 8 > (3+4)
[12, 8, 9, 10] => max sum is 12 + 10 = 22, since this is greater than 12 + 9 and 8 + 10

I'm interested in figuring out the algorithm for doing this. Methodology / thinking process = greatly appreciated.

EDIT: The integers range from 1 to 1000, inclusive. (Since this is entirely a learning exercise, I'd still be interested in learning about different methods if the integers ranged from, say, -1000 to 1000.)

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The integers can also have negative values? – pnezis Nov 4 '11 at 8:52
A very similar problem (with a solution) can be found by googling for "not the maximum segment sum". It's in the book called Pearls of Functional Algorithm Design. Try modifying the solution to solve your problem – n.m. Nov 4 '11 at 9:09
@webclectic I'm updating my answer. – dmonopoly Nov 4 '11 at 21:37
up vote 8 down vote accepted

Let you have array A {Ai, 1 <= i <= n }

F(i) - Maximum sum of subarray Aj { 1 <= j <= i }, then

F(0) = 0 - empty subarray

F(1) = A(1) - only first element

F(i) = max(F(i-2) + A(i), F(i-1)) , 2 <= i <= n

F(n) - answer

C++ implementation:

int GetMaximumSubarraySum(const vector<int>& a)
    // note that vector a have 1-based index
    vector<int> v(a.size());
    v[0] = 0;
    v[1] = a[1];
    for(int i =2; i < a.size(); i++)
        v[i] = max(v[i-2] + a[i], v[i-1]);

    return v.back();


First, main idea is to use dynamic programming. We try to solve task for array with N element by using known answer for array with N-1 and N-2 first elements. If N = 0 the answer is 0 and if N = 1 the answer is A[1]. It's clear. For N >= 2 we have 2 different ways:

  1. Use element A[N], then the answer is A[N] + F[N-2] (because we can't use A[N-1] element and F[N-2] is the best solution for subarray 1..N-2, we don't care about if F[N-2] element is used or not, this is just the best solution for subarray 1..N-2.

  2. Don't use element A[N], then the answer is F[N-1] (because we can use A[N-1] element and F[N-1] is the best solution for subarray 1..N-1, also we don't care about if F[N-1] element is used or not.

So we need to get max of this 2 situations. To solve the task you need calculate F[N] in increasing order and memorize answers.

Let see at your example:

[12, 8, 9, 10]

F[0] = 0

F[1] = 12 - use 1-st element

F[2] = max(F[0]+A[2], F[1]) = max(8, 12) = 12 - use 1-st element

F[3] = max(F[1]+A[3], F[2]) = max(21, 12) = 21 - use 1-st, 3-rd element

F[4] = max(F[2]+A[4], F[3]) = max(22, 21) = 22 - use 1-st, 4-th element

The answer is F[4] = 22.

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Could you add some more detail / commenting to explain this method? Is there an encompassing idea that can be applied to a variety of problems? – dmonopoly Nov 9 '11 at 7:53
@daze, See edited answer. I try to explain, but my English.. is not very good( – Ivan Bianko Nov 9 '11 at 8:20
Wow that's incredible - and really helpful. Thank you so much! I see the "algorithm trick" now... dynamic programming is neat. Basically, I need to think of creating a special array for storing max values, F[i] - which tells me the max value of a subarray of the given array, A, from A's 1st value to its ith value. :) I think I get this now... now I'll try writing the code for it in a variety of ways. The 1-based index thing is interesting, too. I'm used to indexes starting at 0. – dmonopoly Nov 10 '11 at 8:30

The only uniformly successful thinking process I know is to have seen the problem before. Looking at your question my first thought was "I need to maximise a sum subject to what seems to be a set of fairly simple boolean constraints". In Knuth Vol 4A section 7.1.4 Algorithm B Knuth describes how to solve such a problem, as long as the constraints can be expressed as a of manageable size. If you already have a BDD package, you can therefore solve a whole class of problems of this type just by constructing a BDD that describes your particular constraints.

My second thought was to note that later on in the same section, Knuth shows connections between BDDs and linear networks of boolean logic. Given this, there should be a tractable dynamic programming solution to your problem. If you are looking for a general methodology to learn, dynamic programming is a pretty good candidate. In this case it seems to lead to an algorithm pretty much like that presented by Ivan Benko, although he seems to be working under the assumption - supported by your example data - that the integers are all >= 0, and it could work for general integers with a few more if statements.

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Thanks! This is really helpful. – dmonopoly Nov 10 '11 at 21:31

Think recursively: Best result is maximum from cases- to use first element (first in recursion branch) or not to use it in sum

Best(i) = Max(A[i] + Best(i + 2), Best(i + 1))

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Here is a solution know as the kadane's Alogithme

Algorithm 1 Kadane’s algorithm
   M ← 0, t ← 0
   i ← 1
   for j ← 1 to n do          
      t ← t + a[j]
      if t > M then M ← t, (x1 , x2 ) ← (i, j)           
      if t ≤ 0 then t ← 0, i ← j + 1// reset the accumulation
   end for
   output M , (x1 , x2 )
share|improve this answer
Thank you - I'm not familiar with this notation, though... but knowing the term Kadane's algorithm is helpful – dmonopoly Nov 10 '11 at 21:32
Isn't Kadane's algorithm for a different kind of problem? – dmonopoly Nov 14 '11 at 3:36

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