This looks like a classic Dynamic Programming problem (also indicated by other answers mentioning its similarity to 0-1 Knapsack and Subset Sum problems). The whole thing boils down to to one simple choice: for each element in the list, do we use it in our sum or not. We can write up a simple recursive function to compute the answer:
0 if target_sum<=0 (i.e. we don't need to add anymore)
infinity if target_sum>0 and index is past the length of n (i.e. we have run out of numbers to add)
min( f(index+1,target_sum), f(index+1,target_sum-n[index])+n[index] ) otherwise (i.e. we explore two choices - 1. take the current number 2. skip over the current number and take their minimum)
Since this function has overlapping subproblems (it explores the same sub-problems over and over again) , it is a good idea to memoize the function with a cache to hold values that were already computed before.
Here's the code in Python:
#! /usr/bin/env python
INF=10**9 # a large enough number of your choice
def min_sum(numbers,index,M, cache):
if M<=0: # we have reached or gone past our target, no need to add any more
elif len(numbers)==index: # we have run out of numbers, solution not possible
elif (index,M) in cache: # have been here before, just return the value we found earlier
min_sum(numbers,index+1,M,cache), # skip over this value
min_sum(numbers,index+1,M-numbers[index],cache)+numbers[index] # use this value
cache[(index,M)]=answer # store the answer so we can reuse it if needed
This solution only returns the minimum sum, not the actual elements used to make it. You can easily extend the idea to add that to your solution.