Because I find the question interesting, I decided to write down my thoughts on the subject:
Say we define
init xs as "the list, that, if you put
last xs on its end, is equal to xs. This is equivalent to:
init xs is the list without its last element. For
xs == , there exists no last element, so
init  has to be undefined.
You could add a special case for this, like in "if xs is the empty list, then
init xs is the empty list, otherwise
init xs is the list, that, if you put
last xs on its end, is equal to xs". Notice how this is much more verbose and less clean. We introduce additional complexity, but what for?
init [1,2,3,4] == [1,2,3]
init [1,2,3] == [1,2]
init [1,2] == 
init  == 
init  == ??
Note how the length of the lists on the right-hand side of the equations decreases along with the length of the left-hand side. To me, this series cannot be continued in a sensible way, because the list on the right side would have to have a negative size!
As others have pointed out, defining a special case handling for
tail for the empty list as an argument, can introduce hard-to-spot errors in situations where functions can have no sensible result for the empty list, but still don't produce an exception for it!
Furthermore, I can think of no algorithm were it would actually be of advantage to have
init  evaluate to
, so why introduce that extra complexity? Programming is all about simplicity and especially Haskell is all about purity, wouldn't you agree?