# Verifying that a grammar is strong LL(2)

Problem 19.5 of Sudkamp's Languages and Machines asks the reader to verify that the grammar

``````G : S' -> S##
S  -> aSa | bSb | λ
``````

is strong `LL(2)`. The `FIRST` and `FOLLOW` sets for the variable `S` are computed using Algorithm 19.5.1 (p. 583, 3rd ed.):

``````FIRST(2)(S)   = {λ,aa,bb,ab,ba}

FOLLOW(2)(S)  = {##,a#,b#,aa,bb,ab,ba}
``````

It is clear that the length-2 lookahead sets for the `S` rules will not partition the length-2 lookahead set for `S`, due to the rule `S -> λ`, which gives rise to the length-2 lookahead set consisting of `FOLLOW(2)(S)`:

``````LA(2)(S)        = {##,a#,b#,aa,bb,ab,ba}

LA(2)(S -> aSa) = {a#,aa,ab}
LA(2)(S -> bSb) = {b#,bb,ba}
LA(2)(S -> λ)   = {##,a#,b#,aa,bb,ab,ba}
``````

Now it is possible that I have made an error in the computation of the `FIRST`, `FOLLOW`, or `LA(2)` sets for `G`. However, I'm fairly confident that I have executed the algorithm correctly. In particular, I can revert to their definitions:

``````FIRST(2)(S)  = trunc(2)({x : S =>* x AND x IN Σ*})
= trunc(2)({uu^R : u IN {a,b}^*})
= {λ,aa,bb,ab,ba}

FOLLOW(2)(S) = trunc(2)({x : S' =>* uSv AND x IN FIRST(2)(v)})
= trunc(2)({x : x IN FIRST(2)({a,b}^*{##})})
= trunc(2)({##,a#,b#,aa,bb,ab,ba})
= {##,a#,b#,aa,bb,ab,ba}
``````

Now the question is: why is the grammar strong `LL(2)`. If the length-2 lookahead sets for the `S` rules do not partition the length-2 lookahead set for `S`, then the grammar should not be strong `LL(2)`. But I can't reach the conclusion expected by the book. What am I not understanding?

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I did the calculations using the algorithms I gave to my students, and I obtained the same results you got. Find an errata or contact the author. –  Apalala Jun 19 '11 at 11:49
I might do that. The algorithms you gave to your students are similar to Sudkamp's. I found an alternative set of algorithms and obtained the same results again. I'll look at the definition later and see if I can prove that the grammar is or isn't LL(2). Thanks for checking, though. –  danportin Jun 19 '11 at 19:21

Here is a solution. The grammar `G` given above is not strong `LL(2)`. To see this, recall the definition of a strong `LL(k)` grammar. A grammar `G` is `LL(k)` for some `k > 0` if, whenever there are two leftmost derivations

``````S =>* u1Av1 => u1xv1 =>* uzw1          S =>* u2Av2 => u2yv2 =>* u2zw2
``````

where `ui,wi IN Σ*` for `i IN {1,2}`, and `|z| = k`, then `x = y`. Consider the following leftmost derivations in the grammar `G` above:

``````S =>* aaSaa##  (u1 = aa, v1 = aa##)    S =>* baSab##   (u2 = ba, v2 = ab##)
=>1 aaaa##   (x = λ)                   =>1 baaSaab## (y = aSa)
=>* aaaA##   (z = aa, w1 = aa##)       =>* baaaab##  (z = aa, w2 = ab##)
``````

The derivations satisfy the conditions of the definition of a strong `LL(2)` grammar. However, `λ \= aSa`, and consequently `G` is not strong `LL(2)`.

Clearly we can build many leftmost derivations that demonstrate that `G` is not strong `LL(2)`. But there are several other reasons that `G` is not strong `LL(2)`. For instance, it is obvious that `G` cannot be recongized by a deterministic pushdown automata, because there is no way to determine when to begin removing elements from the stack.

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I was debating whether to post this solution in the answers section, or edit the original post. If someone can provide a better solution, I'll accept their answer. –  danportin Jun 21 '11 at 22:08