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?