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The problem is simpler than knapsack (or a type of it, without values and only positive weights). The problem consists of checking whether a number can be a combination of others. The function should return true or false.

For example,

112 and a list with { 17, 100, 101 } should return false, 469 with the same list should return true, 35 should return false, 119 should return true, etc...

Edit: subset sum problem would be more accurate for this than knapsack.

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I'm pretty sure 119 should return false..! –  Tom Smith Jan 28 '10 at 8:31
Well, 119 is 17*7... ;) –  huff Jan 28 '10 at 8:40
Oh dear... it is quite early in the morning still. –  Tom Smith Jan 28 '10 at 8:41
7 isn't in the list. If you can multiply by numbers not in the list, why not multiply by 1.12 to get 112 from 100? –  Pete Kirkham Jan 31 '10 at 10:19
@Pete: 7 is not in the list, but 17 is, and seven times 17 is 119, so 119 shall return true!!!!!! grrr (slap) –  huff Feb 1 '10 at 8:45

4 Answers 4

up vote 2 down vote accepted

An observation that will help you is that if your list is {a, b, c...} and the number you want to test is x, then x can be written as a sum of a sublist only if either x or x-a can be written as a sum of the sublist {b, c, ...}. This lets you write a very simple recursive algorithm to solve the problem.

edit: here is some code, taking into account the comments below. Not tested so probably buggy; and not necessarily the fastest. But for a small dataset it will get the job done neatly.

bool is_subset_sum(int x, std::list::const_iterator start, std::list::const_iterator end)
  // for a 1-element list {a} we just need to test a|x
  if (start == end) return (x % *start == 0); 

  // if x is small enough  we don't need to bother testing x - a
  if (x<a) return is_subset_sum (x, start+1, end);

  // the default case. Note that the shortcut properties of || means the process ends as soon as we get a positive.
  return (is_subset_sum (x, start+1, end) || is_subset_sum (x-a, start, end));
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What about multiples of a? –  JXG Jan 28 '10 at 8:06
Well, if it has to sum x and there are no negative integers, maybe I can use a common (zero-sum) implementation with a subset like: { -x, a, b, c ... } –  huff Jan 28 '10 at 8:09
Ah, ok. I was interpreting the question as simply taking the sum of a subset of the list. If you're allowing positive multiples then you need to test x, x-a, x-2a, and so on. If you're allowing negative multiples then of course the test boils down to does gcd(a,b,c...) go into x. –  Tom Smith Jan 28 '10 at 8:12
The recursive step would be a little more complex: either a is part of the solution and then x-a can be calculated in terms of { a, b, c }, or a is not part of the solution and x can be written in terms of { b, c }. In any case you are reducing the size of the problem (either a smaller number or a smaller set). Now the search space may be greater than what you want to do with the naïve implementation... –  David Rodríguez - dribeas Jan 28 '10 at 8:16

This is a special case of the Subset Sum problem, with sets that only contain one negative number (i.e., express 112 and { 17, 100, 101 } as { -112, 17, 100, 101 }). There's a few algorithms on the Wikipedia page, http://en.wikipedia.org/wiki/Subset_sum_problem.

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Indeed......... –  huff Jan 28 '10 at 8:13
That still doesn't account for multiples of numbers in the set. Although subset sum with multiples would be applicable, since the negative number can be multiplied. –  Potatoswatter Jan 28 '10 at 8:13

Note that positive results become denser as the queried number becomes larger. For example, all numbers greater than 100^2 can be generated by { 17, 100, 101 }. So the optimal algorithm may depend upon whether the queried number is much greater than the set's members. You might look into field theory.

At the least, you know the result is always false if the greatest common divisor of the set is not in the query, and that can be checked in negligible time.

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If the number to reach is not too large, you can probably generate all the reachable numbers from the set that fall in the range [1,N].

Problem: Reach N using the elements in the list L, where N is small enough not to worry about a vector of size N elements' size.


  • Generate a vector V of size N
  • For each element l in the list L
    • For each reachable element v in V
      • mark all elements v + n*l in V as reachable
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I really like that approach, considering that the list doesn't change, and that the maximum number isn't quite big. –  huff Jan 28 '10 at 8:44
Also known as a sieve. It's the first thing that came to my mind, just in CS "this algorithm works for small numbers" is frowned upon. Don't forget to use a bitset to raise the upper limit by an order of magnitude. –  Potatoswatter Jan 28 '10 at 8:53

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