# What's the approach to solving this kind of logic problem?

What would be the approach to a kind of problem that sounds like this:

A says B lies

B says C lies

D says B lies

C says B lies

E says A and D lie

How many lie and how many tell the truth? I am not looking for the answer to the problem above, but the approach to this kind of problem. Thanks a lot.

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Do you mean the approach to solving this programatically? –  Jon Skeet May 14 '11 at 8:26
Are you looking for a programming solution or mathematical solution? In later case cstheory.stackexchange.com might be a better place to ask. –  taskinoor May 14 '11 at 8:27
Yes the approach to solve this type of problem using a programming language such as C, Java rather than prolog or clips –  DDD May 14 '11 at 8:29
@Task: No, it is not suited for cstheory as it is not reasearch level. This is well known enough to be homework, in fact. –  Aryabhatta May 14 '11 at 8:45
@Aryabhatta, I only though about cstheory as this can be solved by using discrete math/logic theory without programming. The OP has confirmed that he is looking for programming solution. I was not sure, that why I haven't casted any close vote, just commented. –  taskinoor May 14 '11 at 9:51

A -> !B
B -> !C
D -> !B
C -> !B
E -> !A & !D

Reminder:

X -> Y  <=>  !X | Y

Transform the 5 equations into logical propositions, and you will find answers.

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Wouldn't this approach allow liars to tell the truth? If the only condition was that X -> Y and we considered the logical equivalent !X | Y, that has a truthy value unless Y==0 and X==1, allowing X and Y to be simultaneously liars. But if X==Y==0 and they're liars, then X said Y is a truth-teller, and thus a liar told the truth. Maybe that's what the OP wanted, but other answers seem to assume that liars always lie... –  davin May 14 '11 at 9:52
I'm not quite sure if this is on topic with the above comments but liars always lie and those who tell the truth always tell the truth –  DDD May 14 '11 at 10:03
@DDD, in which case this answer won't lead to a valid solution. –  davin May 14 '11 at 10:09
In my answer, A -> !B means "if A says the truth, B lies". Now, if "A says B lies" means that "if A says the truth then B lies" AND "if A lies then B says the truth", then you should interpret "A says B lies" as A -> !B AND A <- !B which is equivalent to A == !B. –  Vincent May 14 '11 at 12:26
I am still not sure about how to interpret the question. Because in one case, the presence of both "B says C lies" and "C says B lies" is a suspect redondancy. –  Vincent May 14 '11 at 12:40

To solve equations of the form

X1 = NOT X 3

X5 = NOT X 2

etc

Form a graph with nodes as Xi and connecting Xi and X j iff the equation Xi = NOT X j appears.

Now try to 2-colour the graph using Breadth First Search.

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I would have thought "A says B and C both lie" is logically equivalent to "A --> !B" and "A --> !C", which is still 2-SAT. Am I missing something? –  davidg May 14 '11 at 9:04
@david: I made a mistake: I transformed A implies B to NOT A or NOT B, instead of NOT A or B. Corrected. Thanks for pointing that out. –  Aryabhatta May 14 '11 at 9:17
The comments above are for the previous answer to the previous question. –  Aryabhatta May 14 '11 at 16:48
@DDD: Yes that is correct. –  Aryabhatta May 14 '11 at 18:19

Assuming you're looking to solve this with a program... it's actually pretty easy to brute force, if you've got a reasonably small input set. For example, in this case you've basically got 5 Boolean variables - whether each person is a truth-teller or not.

Encode the statements as tests, and then run through every possible combination to see which ones are valid.

This is obviously a "dumb" solution and will fail for large input sets, but it's likely to be rather easier to code than a full "reasoning" engine. Often I find that you can get away with doing a lot less work by taking into account what size of problem you're actually going to encounter :)

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Isn't this the famed SAT-problem, though? –  csl May 14 '11 at 8:29
@csl: Not sure what you mean. Reference? –  Jon Skeet May 14 '11 at 8:31
Boolean satisfiability, which is known to be NP-complete: en.wikipedia.org/wiki/Boolean_satisfiability_problem –  csl May 14 '11 at 8:32
@csl: Ah, I thought you were talking about a high school SAT test. Yes, it's Boolean satisfiability. I'm not sure how that affects my answer though... for small inputs you can brute force it. For large inputs you may be able to write code to reason about it more efficiently... but in some cases it will simply be "hard". –  Jon Skeet May 14 '11 at 8:36
In its current form, it is only 2-SAT which is still solvable in polynomial time. To become 3-SAT (and hence NP-complete), the problem would need to have statements such as "A says 'B says C lies'". –  davidg May 14 '11 at 8:54