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I am given N numbers, n1, n2, n3, n4, …, nN (all being positive). Finally I am given a number K as input.

I am asked if it is possible to find some possible combination over n1, n2, …, nN such that the sum equals K, i.e. find coefficients a, b, c, …, n such that:

a·‍n1 + b·‍n2 + … + n·‍nN = K

where a, b, c, …, n may assume any integral value from 0 to K.

We just need to find out whether such a combination exist.

What I have been thinking is placing limits over the extreme values of a, b, …, n. For example, a can be bounded as: 0 ≤ a ≤ floor(K/‍a). Similarly, defining ranges for b, c, …, n. However, this algorithm eventually turns out to be O(nn-1) in the worst case. Is this problem similar to Bin Packing problem? Is it NP complete?

Please help me with a better algorithm (I am not even sure if my algorithm is correct!!).

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I even tried finding some discussions over problems of this kind, but couldnt find 1.. If this is a duplicate, please let me know! –  letsc Jul 13 '11 at 17:09
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Are n1, ..., nN all positive? –  Ted Hopp Jul 13 '11 at 17:11
    
Does “an1” mean a·n₁? –  Gumbo Jul 13 '11 at 17:12
    
@isbadawi - I don't think this is exactly the subset sum problem. That doesn't allow for multiplicities, and does allow for negative numbers. @Gumbo - I assume that "an1" means "a times (n sub 1)". –  Ted Hopp Jul 13 '11 at 17:15
    
Yeps @ted, thanks.. –  letsc Jul 13 '11 at 17:28

3 Answers 3

This is just another variant of the Knapsack problem (see the unbounded knapsack section) and is just as NP-complete and hard as the other versions.

Of course, if K is small you can use the dynamic programming solution and if N is small exaustive search works well also.

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In a reduction, how would you account for the upper bound on the weight/volume? –  Jacob Jul 13 '11 at 18:27
    
Well, since everything here is NP complete, there is bound to be a (not necessarily efficient) reduction :) But for the real problem, you can add extra numbers, in a power of 2 scheme for a direct reduction. So by using a combinations of {i, i*2, i*4, i*8, i*16} you can represent exactly all multiples of i up to 31*i - In the end you only need to add at most N*log(K) numbers. –  hugomg Jul 13 '11 at 18:34

This solution supposes that the numbers n1, n2, ... nN are integers (or that they have a "smallest common divisor")


I've got a O(K*N) algorithm (thanks to missingno for the correction). The idea is a bit of dynamic programming, a bit of the Sieve of Eratosthenes.

Begin by creating a list L of K+1 booleans. L[i] is true if you can "build" the number i (more on that later). All values of L are initialised as false, except L[0]==true

Begin with you first number n1. For every value of i between 1 and K, check if L[i-n1]==true. Of course, if i-n1<0, then do as if L[i-n1]==false. If L[i-n1]==true, then change L[i] to true. Now, you have L[n1]==true, L[2*n1]==true, L[3*n1]==true ...

What does L mean now? L represent the numbers in [0..K] that can be built with only n1. If L[K]==true, congratulations, there is a solution built with only n1!

Take the number n2, and do the same. For every value of i between 1 and K such that L[i]==false, check if L[i-n2]==true. If it's the case change L[i] to true.

What does L mean now? L represent the numbers in [0..K] that can be built with n1 and n2. If L[K]==true, congratulations, there is a solution built with only n1 and n2!

If after filling L with all you N values L[K]==false, there is no solution to your problem.


The problem with dynamic programming is that it's always a problem to retrieve the solution once you've proven that there exists one... You need another list S such that S[i] describes what are the coefficients needed to "build" i. (exists only if L[i]==true of course)

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This is not a polynomial algorithm, since K can be an exponentially big number. –  hugomg Jul 13 '11 at 17:50
    
@missingno : Oops, I corrected the complexity, it is O(KN)... In fact, it's even O(KM) where M is the smallest number of numbers n1..nM necessary to find a solution. –  Fezvez Jul 13 '11 at 17:54
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It is just as easy to retrieve a solution as it is to determine if it exists. Just remembeer to store the solutions as well instead of only storing booleans in the table. –  hugomg Jul 13 '11 at 18:00
    
@missingno : True! –  Fezvez Jul 13 '11 at 18:01

This is an integer program, so if you have access to a solver, I'd recommend you profile its performance and see if it works for you.

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