Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I've set myself a "simple" programming challenge in C# to optimise capacity. I didn't do to well on my first attempt (as described further down) so was looking to see if there is a standardised algorithm for doing this, without using AI/Heuristic techniques as i do not know them at all. I believe there is a known method for doing this as the problem would probably apply to common situations like load balancing of CPUs and other resources.

The problem I set myself. I have 3 containers.

  • Container 1 - Capacity 15
  • Container 2 - Capacity 30
  • Container 3 - Capacity 15

The containers all start empty, so have full capacity.

I also have 20 items. For the sake of a long list I will not list them all. But they are simple and can be like

  • Item 1 - Amount 3
  • Item 2 - Amount 8
  • Item 3 - Amount 1
  • Item 4 - Amount 1
  • Item 5 - Amount 5
  • and so on .........

What i want to do is to fit all the items in the fewest number of containers without breaking the constraints, i.e. overfilling the capacity.

  • Container 1 - Items 2, 1
  • Container 2 - Items 3, 4, 5
  • and so on ..............

I'm looking for a solution, although obviously the more efficient the solution the better. Eventually I'll make the containers and items auto generate, and probably even add more properties say (weight & amount). I know there are a finite amount of solutions even if you randomly generate them, the idea is to find the best, or close to the best is a reasonable time. My initial attempt was first to define container and item objects, then to randomly allocate items to containers, then try to optimise by finding available space in those close to capacity and fill them with items from containers that are not as full. But it didn't work out to well. The simplest solution i believe is to allocated items in order of those with the largest amount, then use small amounts to fill up the gaps. I stayed away from this initial as I feel this would have drawbacks if I added in more constraints, i.e. amount is high (20), but say weight a new constraint is only (1). I may then end up getting a container full with amount but barely as weight usage leading to over containers getting to heavy to hold any more.

Whilst I'm focusing on the problem more so than the language I'm using C# .Net 4.0, so if you have ideas feel free to use frameworks like LINQ etc.

If I've posted a problem with a well known solution I have missed, feel free to point me right to it. But I am interested in any solutions you can come up with. i look forward to reading the replies.

share|improve this question

1 Answer 1

up vote 7 down vote accepted

You've chosen a very hard challenge:

and this problem is NP-complete which means that the only known correct solution to the problem invokes examining all possible combinations.

You can try the Greedy approximation algorithm described in the first link if you can settle for a heuristic/approximate approach.

share|improve this answer
1  
Read the title, thought "classic knapsack", came here and found answer. +1 –  codekaizen Jun 2 '11 at 22:22
1  
Also note that while it is true that the only correct answer, meaning "best fit with no uncertainty" can only be found by testing the entire space of all combinations, you can get very, very good answers with a much smaller number of tests by using a number of combinatorial heuristic approaches, one of which you mention. –  codekaizen Jun 2 '11 at 22:24
    
Hi, Thanks for the first answer and comments. Just digging through the Wikipedia articles. I didn't realise I picked such a awkward problem. I think I need to pick my words carefully. Rather than going for best approach I would like a solution that matches the constraints with attempts to "improve" the efficiently. Ill look into Greedy approximation and see what I come up with. –  JonWillis Jun 2 '11 at 22:57
1  
@Jon: The problem manifests itself in many related forms and some of them are "real-world" problems like allocating students to classes or maximizing the utilization of telephone or network switches. These problems have to be solved, if imperfectly, so greedy algorithms are the rule. –  Rick Sladkey Jun 2 '11 at 23:05
    
Thanks Rick. The problem seems common to many situations. So i believed I had overlooked something simple and assumed there was an approach other than searching all combinations. I see greedy and AI are the way to go in order to get a near optimal result rather than the best. The wikipedia articles give me a few topics to research. –  JonWillis Jun 3 '11 at 13:29

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.