caf's brilliant answer prints each number that appears k times in the array k-1 times. That's useful behaviour, but the question arguably calls for each duplicate to be printed once only, and he alludes to the possibility of doing this without blowing the linear time/constant space bounds. This can be done by replacing his second loop with the following pseudocode:
for (i = 0; i < N; ++i) {
if (A[i] != i && A[A[i]] == A[i]) {
print A[i];
A[A[i]] = i;
}
}
This exploits the property that after the first loop runs, if any value m
appears more than once, then one of those appearances is guaranteed to be in the correct position, namely A[m]
. If we are careful we can use that "home" location to store information about whether any duplicates have been printed yet or not.
In caf's version, as we went through the array, A[i] != i
implied that A[i]
is a duplicate. In my version, I rely on a slightly different invariant: that A[i] != i && A[A[i]] == A[i]
implies that A[i]
is a duplicate that we haven't seen before. (If you drop the "that we haven't seen before" part, the rest can be seen to be implied by the truth of caf's invariant, and the guarantee that all duplicates have some copy in a home location.) This property holds at the outset (after caf's 1st loop finishes) and I show below that it's maintained after each step.
As we go through the array, success on the A[i] != i
part of the test implies that A[i]
could be a duplicate that hasn't been seen before. If we haven't seen it before, then we expect A[i]
's home location to point to itself -- that's what's tested for by the second half of the if
condition. If that's the case, we print it and alter the home location to point back to this first found duplicate, creating a 2-step "cycle".
To see that this operation doesn't alter our invariant, suppose m = A[i]
for a particular position i
satisfying A[i] != i && A[A[i]] == A[i]
. It's obvious that the change we make (A[A[i]] = i
) will work to prevent other non-home occurrences of m
from being output as duplicates by causing the 2nd half of their if
conditions to fail, but will it work when i
arrives at the home location, m
? Yes it will, because now, even though at this new i
we find that the 1st half of the if
condition, A[i] != i
, is true, the 2nd half tests whether the location it points to is a home location and finds that it isn't. In this situation we no longer know whether m
or A[m]
was the duplicate value, but we know that either way, it has already been reported, because these 2-cycles are guaranteed not to appear in the result of caf's 1st loop. (Note that if m != A[m]
then exactly one of m
and A[m]
occurs more than once, and the other does not occur at all.)