# Algorithm to find all addition combination of a number with specific number sets?

For example, i have a function which takes 2 integer parameters to find all addition combinations of given parameter.

To illustrate:

``````public List<List<int>> getcombinations(int numbercount, int target){
....
return List;
}
``````

Let's determine the arguments by making up:

``````numbercount=3 //it will be calculated with 3 integers
target=9 // final number to find
``````

The output of the function is supposed to be in this way:

``````{{1,1,7},{1,2,6},{1,3,5},{1,4,4},{2,2,5},{2,3,4},{3,3,3}}
``````

Our target number can be found with 7 possibilities when 3 integers is used in addition.

One more example:

``````numbercount=2
target=7
//Output should be like this:
{{1,6},{2,5},{3,4}} // 3 possibilities when 2 integers is used in addition.
``````

I tried to find a solution for this problem. But I could not find a way to solve it. What do you advise to search or learn about to solve it?

-
you have much to specify concerning the rules you must follow. I assume "numbers" means integers greater than 0. I assume result sets are un-ordered, i.e., {1,2} == {2,1}. This would imply your second parameter may never be less than your first. Do I understand your requirements right? – Les Apr 23 '14 at 18:48
If i assign to numbercount parameter as 3, algorithm finds the target integer with using 3 ints in addition process. In first example: 1+1+7, 1+2+6,1+3+5,1+4+4,2+2+5,2+3+4,3+3+3 (additions includes 3 ints) – T.Y. Kucuk Apr 23 '14 at 18:56

This should be a starting point, refine as necessary, read related link for awesome explanation about generating combinations.

`````` class Program
{
static void Main(string[] args)
{
foreach (var set in GetCombinations(3, 9))
{
Console.WriteLine("{{{0}}}", string.Join(",", set));
}
}

public static IEnumerable<IEnumerable<int>> GetCombinations(int length, int targetSum)
{
var combinations = Enumerable.Range(1, length)
.Select(x => Enumerable.Range(1, targetSum - length+1)).CartesianProduct();
combinations=combinations
.Where(x => x.Sum(y => y) == targetSum);

return combinations.Distinct(new Comparer()).ToList();
}

}

public class Comparer : IEqualityComparer<IEnumerable<int>>
{

public bool Equals(IEnumerable<int> x, IEnumerable<int> y)
{
var isEqual= x.OrderBy(a => a).SequenceEqual(y.OrderBy(b => b));
return isEqual;
}

public int GetHashCode(IEnumerable<int> obj)
{
return obj.Sum(); //lazy me, just indicate collection is same if their sum is same.
}
}

public static class Extensions
{
public static IEnumerable<IEnumerable<T>> CartesianProduct<T>(this IEnumerable<IEnumerable<T>> sequences)
{
IEnumerable<IEnumerable<T>> emptyProduct = new[] { Enumerable.Empty<T>() };
return sequences.Aggregate(
emptyProduct,
(accumulator, sequence) =>
from accseq in accumulator
from item in sequence
select accseq.Concat(new[] { item }));
}
}
``````

The extension method for generating combinations is a famous masterpiece from Eric Lippert.

-
This is excellent. Thank you a million man! – T.Y. Kucuk Apr 23 '14 at 20:05

This code is notably faster:

``````using System;
using System.Collections.Generic;

namespace konsol
{
class Program
{

private static List<List<int>> combinations = new List<List<int>>();

private static void Main(string[] args)
{

int length = 4
Generate(length , 10, 0, 1, 0, new int[length]);

foreach (var varibles in combinations)
{
Console.WriteLine(String.Join(",", variables));
}

}

private static void Generate(int length, int target, int k, int last, int sum, int[] a)
{

if (k == length- 1)
{

a[k] = target - sum;

}
else
{

for (int i = last; i < target - sum - i + 1; i++)
{

a[k] = i;
Generate(length, target, k + 1, i, sum + i, a);

}

}

}

}

}
``````
-
please comment your code... for what is "k" used? – leAthlon Oct 18 at 21:22