# Guess the number, with lying allowed

I am pretty sure you guys are aware of the Guess the Number game (there seem to be quite a few questions here already) where Alice thinks of a positive integer and Bob tries to guess it. Alice responds by either by saying "You got it", "Low", "High". The usual strategy which Bob can do, is to do a binary search which would guess the number in O(log n) guesses, where n is the number Alice was thinking about.

I have always wondered about the variant where Alice was allowed to lie.

Suppose now Alice was allowed to lie a constant number of times (known before hand both to Alice and Bob), but only was allowed to lie when responding "High", "Low" (i.e. if Bob guesses the number correctly, she has to admit that).

Is it still possible that Bob can guess the number in O(log n) guesses?

What if Bob was allowed additional queries like "How many times have you lied so far?" (which Alice has to respond truthfully)? Are O(log n) queries still possible?

EDIT: What if the number of lies was allowed to be O(logn) too, and the additional queries were: Have you lied more than x times? and Alice was allowed to lie about them...

Apologies for the EDIT.

-
If the number of allowed lies -- say k -- is fixed independent of n, Bob can simply ask each question 2k+1 times and will get away with O(log(n)). –  Sven Marnach Apr 15 '11 at 18:00
Just follow every "standard" question with the "how many times have you lied" one -- and switch the answer accordingly. Result: same number of questions asked as if Alice never lied. –  pmg Apr 15 '11 at 18:01
I love it. Two immediate thoughts (1) what about mapping the space based on probabilities (2) what would a scheme to try and identify the or incorrect answers look like? –  Jim Blackler Apr 15 '11 at 18:02
I was not sure how many questions I can ask in question. I have edited to make the number of lies non-constant and allowed Alice to lie about how many lies... Sorry if this is off-topic (I can see a close vote). –  user127.0.0.1 Apr 15 '11 at 18:41
@Jim: Yes that is interesting. Kind of like a Fault tolerant binary search :-) –  user127.0.0.1 Apr 15 '11 at 19:13

Run the usual binary search algorithm. Either you get the answer, or you get an inconsistency (an empty candidate set). If you get an inconsistency, Alice must have lied at least once. Restart the binary search. Unless I'm missing something, after O(k*log(n)) steps you will get the answer (plus a lower bound on how many times she lied). You don't need to know k a priori.

-
I guess that was silly: once you are done, you know exactly how many times she lied. As for optimizations, in the worst (deterministic) case, I don't think you can beat k*log(n), since Alice doesn't have to lie until the very last question on any given run. If you can beat this with a randomized algorithm, I don't know; it's a good question. –  foxcub Apr 15 '11 at 18:22
I think the key is to be able to select a better starting point (than the middle) for the next round once you get a null set. –  belisarius Apr 15 '11 at 18:34
Thanks! I wanted to keep it simple, turned out to be too simple :-) –  user127.0.0.1 Apr 15 '11 at 18:46
@Dante: I think it's still just a lower bound, since Alice could lie twice or more before you reach an inconsistency. –  j_random_hacker Apr 15 '11 at 23:15
For any future searchers, I found this page on math.stackexchange as well for a more in-depth solution: math.stackexchange.com/questions/172372/… –  kevmo314 Apr 25 '13 at 18:50

I think it's still O(log n), because you specified that Alice can only lie a constant number of times. This means she can at most multiply the amount of guesses Bob makes by a constant.

Imagine that Alice can lie 5 times. Now, no matter when alice lies, she'll end up having to contradict herself. Bob will notice this, and can start his binary search over. Alice is also restricted to lying within O(log n) guesses, or else Bob will guess the number correctly and Alice loses her chance.

So, in the worst case, where Alice lies five times, each /just before/ Bob gets the answer, she has simply caused Bob's binary search to take 6*(log n) guesses (five lies + one correct answer), which is still O(log n).

-
Thank you for the answer. –  user127.0.0.1 Apr 15 '11 at 18:46
most welcome :) –  Cephron Apr 15 '11 at 19:19