# Use pumping lemma to prove grammar is not context free?

I'm trying to prove that `L={y#x|(y is a substring of x) ∧x,y∈{a,b}^* }` is not context free using the pumping lemma, but I can't seem to do that. If

``````|vy|≠ε ,|vxy|≤k , uv^n xy^n z∈L ,∀n≥0
``````

Then either `vxy` has both `a` and `b`, or only `b` or only `a`.

How can I pump it in order to show that?

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Isn't the pumping lemma only useful for showing a language isn't context free? ie: Even if it satisfies the conditions, it might still not be? –  cHao Jun 13 '12 at 5:02
This is off topic for SO. It belongs on cstheory.stackexchange.com. –  andand Jun 13 '12 at 5:06
@andand No, it does not; Theoretical Computer Science is only for research level TCS. This belongs to Computer Science which has in fact a good reference question on the matter. –  Raphael Apr 2 '13 at 15:57

`{y#x | y` is a subset of `x`} over the alphabet `{a, b}*` does not appear to be context free just with a quick look.
Let `s = (a|b)^p#(a|b)^(2p)` so this is the string where `p` characters precede the `#` and `2p` after to make this an easy subset.
We now need to decompose this string into `x y^i z` parts where `|y| > 0` and `|xy| = p`. So the `y` must be made of any string of characters before the `#`. We can "pump up" this string now s.t. the first string before the `#` is larger than the second. This is no longer a subset of the second half. This is a contradiction so this language is not context free.
The pumping lemma you use is for regular languages. The pumping lemma for context-free languages would involve a decomposition into `uvxyz`, where both `v` and `y` would be pumped. As presented, the form of the above proof would be applicable to other non-regular, context free languages, "proving" them to be non-context-free. Try it with `a^nb^n`, taking `s=a^pb^p`. Also, `|xy| ≤ p` in the regular version, and `vxy ≤ p` in the context-free version. –  outis May 12 '13 at 3:53