4.5 ADDITIONAL EXERCISES
- Modify the PDA in 4.2.1.4 to accept {0n 1n : n ≥ 1} by ES.
- Modify the PDA in 4.2.1.4 to accept {0n 1n : n ≥ 3} by ES.
- Build a PDA over an input alphabet ∑ that accepts strings by ES, and (provably) accepts {xxR : x
∑*}. - Build a PDA for the language {0n15n : n ≥ 0}. You are free to choose the mode of acceptance.
- Repeat the above task, but now do it in this way: First get a CFG for the language, and then construct a PDA for the language that accepts by empty stack (cf. 4.3.0.5).
- Give a CFG G over ∑ = {0, 1} such that L(G) = {xxR : x ∑*}.
- Give a CFG G over ∑ = {(, )} such that L(G) is the full set of balanced brackets—that is, not only those of the form ((())) but also those like ((())) (()).
- Provide a complete proof for the claims in Example 4.3.0.7.
- By induction on regular expression length prove: “For every α, there is a CFG, G, such that L(G) = L(α)”.
- Prove that CFL are closed under union, that is, if L and L′ are CFL, then so is L ∪ L′.
- Prove that CFL are closed under concatenation, that is, if L and L′ are CFL, then so is LL′.
- Prove that CFL are closed under reversal, that is, if L is a CFL, then so is LR.
- Prove that CFL are not closed under complement. That is, if L is a CFL over ∑, then it is not necessarily the case that , that is, ∑* − L is a CFL. ...
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