As @payne points out in his comment, this is really the same as the knapsack problem. The solution is therefore a simple dynamic programming algorithm.
Say the files are arranged one after another in some order in a list. At first, you have the choice of either choosing to include the first file or skipping it. If you choose to include it, the space you have available will decrease by the size of that file. If you choose to skip it, the space available remains unchanged. Now, you can arrive to the second file in two states. In one, you have chosen the first file and thus have less space, while in the other you have skipped the first file and have more space. For each of these scenarios, you can again choose to include or skip over the second file.
Notice you can define your state simply by the file which you are considering at the moment and the available space that you have. Once you have moved past the last file or the space has run out, you have come to the end of that line of choices.
This yields a simple recurrence:
o if space=0 # no more space available, so 0 wastage
space if index>=size(files) # no more files left, whatever is left is wasted
min_waste(index+1,space) if size(files[index])>space # current file is too large skip ahead
min( min_waste(index+1,space), min_waste(index+1,space-size(files[index])) ) otherwise
# minimum of choosing this one and skipping ahead
You can choose to implement this by filling up a table (i.e. 2D array) bottom up, or just write this up as a recursive function and memoize.
This gives you the minimum wastage, but not which files were selected to achieve it. But you can easily modify it to save information about the choice it makes in each state and use that to build up the series of choices from the starting state.