# Infinite loop scala code

``````object Prop {
def simplify(prop : Prop) : Prop = {
prop match {
case Not(Or(a,b)) => simplify(And(Not(a),Not(b)))
case Not(And(a,b)) => simplify(Or(Not(a),Not(b)))
case Not(Not(a)) => simplify(a)
case _ => {
if (simplify(prop) == prop) prop
else prop
}
}
}
}
``````

I'm pretty sure I've an infinite loop caused by my 'default' case. I'm using recursion in all cases. Which is meant to be, but, only if the Prop can be simplified. As soon as the Prop can't be simplified, it should return the whole thing.

I don't see how I can test for any further simplification. (I'm not allowed to use other libraries, as suggested in freenodes #scala channel).

Can someone explain whether it IS the 'case _' causing the loop, and how to solve it? How can I test for possible simplification without making a loop?

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The problem is that you're trying to do two things in one step that need to happen in sequence—applying De Morgan's law (and removing double negation) and recursively simplifying any children. This is why just dropping a `case And(a, b) => And(simplify(a), simplify(b))` into your `match` won't work.

Try the following:

``````val deMorganAndDoubleNegation: Prop => Prop = {
case Not(Or(a, b)) => And(Not(a), Not(b))
case Not(And(a, b)) => Or(Not(a), Not(b))
case Not(Not(a)) => a
case a => a
}

val simplify: Prop => Prop = deMorganAndDoubleNegation andThen {
case And(a, b) => And(simplify(a), simplify(b))
case Or(a, b) => Or(simplify(a), simplify(b))
case Not(a) => Not(simplify(a))
case a => a
}
``````
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I see what you mean. Though, my assignment tells me explicitly to use a companion object. `Prop.simplify(Prop):Prop that returns a simplified and equivalent Proposition by repeatedly applying de Morgan's law and double negation ellimination to the argument Proposition. The resulting proposition must meet the requirements outlined below.` Also, your suggestion doesn't completely match my lecturers answer. (we have a system to run our work against a test) See: pastebin.com/WDuQKreD (also for full code at the moment) Thanks anyway! –  Sander Feb 25 '12 at 23:32
@Sander: You just need to add cases to `simplify` for the other operations (also, I'm sorry I didn't understand that this is homework—I wouldn't have been quite so direct in my answer). –  Travis Brown Feb 25 '12 at 23:38
@Sander: Also, both inheriting from a case class and having a case class with an empty constructor are bad form. `trait Prop; case object True extends Prop` is better. –  Travis Brown Feb 25 '12 at 23:41
Do you have any documentation or some kind of example of how to implement the cases you're talking about into my `simplify`? (No need for apologies, I don't just copy/paste, I try to understand what it actually does). Thanks a lot! (: –  Sander Feb 25 '12 at 23:59
You can treat `Impl` and `Equiv` exactly the same as `And` and `Or`. –  Travis Brown Feb 26 '12 at 0:02
show 1 more comment

It is pretty obvious what happens and you are right with the default `case`. If your input `prop` does not match any of the cases you are invoking:

``````simplify(prop)
``````

with the same argument. Because previously it caused recursive call to `simplify()` and you are calling your function with the same input, it enters `simplify()` again. So this is not an infinite loop but rather never terminated recursive call:

``````...simplify(simplify(simplify(simplify(simplify(simplify(simplify(prop)))))))
``````

However the fix (based on your code) is simple:

``````if (simplify(prop) == prop) prop
else prop
``````

just replace it with...

`````` case _ => prop
``````

Both branches return the same value. This is actually correct if you think about if for a while. You have a set of optimizations. If none of them matched your expressions it means it can no longer be simplified. Hence you are returning it as-is.

BTW looks like you are doing boolean expressions simplification using case classes. You might by interested in my article where I do the same but with arithmetic expressions.

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Thanks for your answer. I tried to do so. (Sorry, pressed enter, and posted without wanting to). But in some cases the simplification result in a string containing a new Not(Not(a)) for example, so re-running simplify would eliminate these. But, I can't get it to run it again when their appears to be a new match on any of the previous cases.. :\ –  Sander Feb 25 '12 at 22:09
@Sander: can you show us the input that is not simplifying `Not(Not(a))`? This can fixed by calling `simplify()` on separate terms like, e.g: to simplify `And(Not(Not(a)), b)` you must return `And(simplify(Not(Not(a)), simplify(b))` (the simplification pattern is: `And(a, b) => And(simplify(a), simplify(b))`. –  Tomasz Nurkiewicz Feb 25 '12 at 22:20
@Thomasz `Not(And(Not(a),Not(b)))` This will first simplify to `Or(Not(Not(a)),Not(Not(b)))` as far as I can see. The code should re-run to eliminate the newly created Not(Not(a)) and Not(Not(b)). –  Sander Feb 25 '12 at 22:33
@Sander: this is a special case of De Morgan's laws and I think it is fair to write it explicitly at the beginning: `case Not(And(Not(a), Not(b)) => Or(simplify(a), simplify(b))`. Similar for `Not(Or(Not(a), Not(b))`. –  Tomasz Nurkiewicz Feb 25 '12 at 22:59
@Thomasz: That's another way around indeed. But somehow it seems like it's not working 100% either. (pastebin.com/rK28yn2J). Looking at the other answer given, I think it's fair to first use De Morgan's, and afterwards eliminate the double appearances of Not(). But is this possible this way? Thanks again. (: –  Sander Feb 25 '12 at 23:39
show 1 more comment

Yes, default case is causing the loop. `if (simplify(prop) == prop) prop` is problematic line. You don't need to test if it can be simplified further because when you are in the default case all possible simplifications are tried.

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