# Converting a language specification into production rules (not sure if it's a CFG or CSG)

I have to write a function that checks whether input strings are valid for a given language specification. I thought that this would be a standard CFG -> Chomsky Normal Form, then CYK parsing, but one of the rules in the language is preventing this from happening.

Some of the rules are straightforward, if we define terminals `{a,b,c,d,e,f,P,Q,R,S}`, then valid strings are

1) Any of the lowercase terminals in isolation
2) If 'x' is a valid string, then so is Sx

But the third rule is

3) If X and Y are valid input strings, then so are PXY, QXY, RXY

where `{P,Q,R}` are the remaining uppercase terminals and X and Y are nonterminals.

What would the production rule for this look like? I thought it would be something like

``````XY -> PXY (and QXY, RXY)
``````

but there are two problems with this. The first is that this is not a CFG rule -- does that mean this language defines a CSG instead?

And the second is that this doesn't work, because

XY -> PXY -> PPXY

would not be a valid message in all cases.

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Start asking such questions on CSTheory – bludger Jul 16 '12 at 18:50

I think that this grammar is context-free, unless I'm misinterpreting what you're saying.

First, let's let A be the nonterminal that expands out to some valid string made just using the first two rules, we get

``````A -> a | b | c | d | e | f
``````

Now, your second rule says that if you can build the string ω then you can build Sω. We could encode that as

``````A -> SA
``````

Finally, you've said that if you have two strings X and Y, then you can combine them together as

``````PXY
QXY
RXY
``````

One way to think about this would be to generate the string P, followed by any two valid strings (same for Q or R). Thus you could add the rules

``````A -> PAA | QAA | RAA
``````

This gives the final grammar

``````A -> a | b | c | d | e | f
A -> SA
A -> PAA | QAA | RAA
``````

Hope this helps!

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