I know that I'm kinda late, but I found this via google and someone else could do the same, so I'll post my answer: the obvious solution is
a) impossible, as well pointed out by Jon Skeet (and btw there are a lot of proofs all over the internet). I'm not questioning the impossibility to compress random data, just to be clear from the beginning; I understood the theory that lays behind it, and -if you ask me- I trust the math. : D
But, if we're allowed to think laterally, we could definitely take advantage of the fact that the question is not well-defined, meaning that it does not give a strict definition of "compression algorithm" and of the properties that it should have (but to reduce some files without expanding anyone else).
Also, it doesn't put whatsoever condition on the files to be compressed, the only thing it's interested in is "to make some files smaller and no files larger".
That said, we have now at least two ways to show that, in fact, it does exist such an algorithm:
We can exploit the name of the file to store some of the information of the file (or even the entire file, if the file system allows it, thus reducing every file to 0 bit).
Trivially, we could simply decide leave untouched every file but one, reducing it to 0 bit and renaming it with a predefined name.
I agree that this could be considered cheating, but then again, there are no restrictions in the initial question and this algorithm would effectively achieve the purpose (as long as no one renames the file, that's why this would be a very poor design choice besides being pointless).
We can limit the number of files to be compressed, say, to the ones at least
X bits long. Once again, a trivial solution would be to leave every file untouched but one, that we can reduce making it match to a file smaller than
Now we do have an algorithm which, quoting verbatim, makes some files smaller and no files larger; however, it performs a restriction on all its possible inputs (i.e. it cannot process all the files).
To those who argue that this wouldn't have any practical use, I say that I agree with you... but hey, this is theory, and this was just a theoretical dissertation. ;)
Obviously, if I were to do a test and face this question, I'd put a bold X on the
a), and then just go on without thinking too much about it.
Nevertheless, it is perfectly possible to show that, since natural language is intrinsically ambiguous and the question is not formally expressed, each of the other possible answers is not necessarily wrong: placing the right conditions and eventually specifying more clearly what is meant by certain concepts, we may legally be able to meet the goal of any of the other listed options, doing some sort of trickery and forcing the program to achieve the desired behavior.