# LL(1) cannot be ambiguous

How can it be shown that no LL(1) grammar can be ambiguous?

I know what is ambiguous grammar but could not prove the above theorem/lemma.

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I think it's nearly a direct result of the definition of LL(1). Try proof by contradiction; assume that you have an LL(1) grammar that is ambiguous and look for something you can show to be true and not true. As a starting point "what do you always know as you process input?"

As this seems like a homework problem and I actually haven't finished the problem any more than I sketched out above, I'll stop there.

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BTW, I'm not *sure the conjecture is correct, but it does seem reasonable. –  BCS Apr 17 '10 at 14:47

Here's my first draft at a proof. It might need some fine tuning, but I think it covers all the cases. I think many solutions are possible. This is a direct proof.

(Side note: it is a pity SO doesn't support math, such as in LaTeX.)

Proof

Let T and N be the sets of terminal and non-terminal symbols.

Let the following hold

``````MaybeEmpty(s) = true <=> s ->* empty
First(s) = X containing all x for which there exists Y such that s ->* xY
Follow(A) = X containing all x for which there exists Y,Z such that S ->* YAxZ
``````

Note that a grammar is LL(1) if the following holds for every pair of productions A -> B and A -> C:

``````1. (not MaybeEmpty(B)) or (not MaybeEmpty(C))
2. (First(B) intersect First(C)) = empty
3. MaybeEmpty(C) => (First(B) intersect Follow(A)) = empty
``````

Consider a language with is LL(1), with `A -> B` and `A -> C`. That is to say there is some string of terminals TZ which admits multiple derivations by distinct parse trees.

Suppose that the left derivation reaches `S ->* TAY ->* TZ`. The next step may be either `TAY -> TBY`, or `TAY -> TCY`. Thus the language is ambiguous if both `BY ->* Z` and `CY ->* Z`. (Note that since A is an arbitrary non-terminal, if no such case exists, the language is non-ambiguous.)

Case 1: Z = empty

By rule 1 of LL(1) grammars, at most one of B and C can derive empty (non-ambiguous case).

Case 2: Z non-empty, and neither B nor C derive empty

By rule 2 of LL(1) grammars, at most one of B and C can permit further derivation because the leading terminal of Z cannot be in both `First(B)` and `First(C)` (non-ambiguous case).

Case 3: Z non-empty, and either `MaybeEmpty(B)` or `MaybeEmpty(C)`

Note the by rule 1 of LL(1) grammars, B and C cannot both derive empty. Suppose therefore that `MaybeEmpty(C)` is true.

This gives two sub-cases.

Case 3a: `CY -> Y`; and Case 3b: `CY ->* DY`, where D is not empty.

In 3a we must choose between `BY ->* Z` and `CY -> Y ->* Z`, but notice that `First(Y) subset-of Follow(A)`. Since `Follow(A)` does not intersect `First(B)`, only one derivation can proceed (non-ambiguous).

In 3b we must choose between `BY ->* Z` and `CY ->* DY ->* Z`, but notice that `First(D) subset-of First(C)`. Since `First(C)` does not intersect `First(B)`, only one derivation can proceed (non-ambiguous).

Thus in every case the derivation can only be expanded by one of the available productions. Therefore the grammar is not ambiguous.

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Prove that no ambiguous grammar can be an LL(1) grammar. For hints, see http://www.cse.ohio-state.edu/~rountev/756/pdf/SyntaxAnalysis.pdf, slides 18-20. Also see http://seclab.cs.sunysb.edu/sekar/cse304/Parse.pdf, pg. 11 and preceding.

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