The following fact is the key to answering this question:
$(*)$ if any two adjacent MPs vote in the same way, then all votes will eventually be locked in indefinitely.
Proof
An MP will only change his vote if both his neighbours vote differently from him. So if two adjacent MPs ($M_1$ and $M_2$) vote in the same way, then clearly their votes are both locked in indefinitely. WLOG, let's say they both vote 'yes'.
Now consider the MP adjacent to them, $M_3$. If he ever votes 'yes', then that vote too will be locked in indefinitely, by the same reasoning. Otherwise, he never votes 'yes', i.e. his vote is locked in as 'no' indefinitely.
Let $k$ be minimal such that the $k$th MP $M_k$ never votes 'yes'. We know $M_1$ and $M_2$'s votes get locked in as 'yes'; if $k>3$, then $M_3$'s vote also gets locked in as 'yes'; ; if $k>4$, then $M_4$'s vote also gets locked in as 'yes'; and so on by induction. The votes of $M_1,\dots,M_{k-1}$ all get locked in at 'yes' while $M_k$'s vote is always 'no'. (If there is no such $k$, then the same argument shows they all get locked in at 'yes' and we're done.)
Now $M_{k+1}$ can't ever vote 'yes' after $M_{k-1}$'s vote is locked in, since that would mean $M_k$'s vote would change to 'yes'. So $M_{k+1}$'s vote is eventually locked in at 'no'.
At this stage, the pattern repeats. Argue exactly as above with the adjacent 'yes'-voters $M_1,M_2$ replaced by the adjacent 'no'-voters $M_k,M_{k+1}$. This argument can carry on indefinitely, and since $n$ is finite, we eventually come to an end. So all votes end up being locked in.
The converse is also clear: if the MPs' votes alternate so that every adjacent pair of MPs vote differently from each other, then every yes-man is in between two no-men and vice versa, so in each round all votes are toggled, and no votes end up being locked in.
So voting continues forever iff the MPs' votes alternate all the way round the table, which can only happen if $n$ is even.
So the answers to the OP's two questions are:
what values of $n$ ensure a definite end?
Odd $n$.
if the voting is endless, how were votes cast in the initial round?
Alternating all the way round the table.
