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.
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.
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.)
Let T and N be the sets of terminal and non-terminal symbols.
Let the following hold
Note that a grammar is LL(1) if the following holds for every pair of productions A -> B and A -> C:
Consider a language with is LL(1), with
Suppose that the left derivation reaches
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
Case 3: Z non-empty, and either
Note the by rule 1 of LL(1) grammars, B and C cannot both derive empty. Suppose therefore that
This gives two sub-cases.
In 3a we must choose between
In 3b we must choose between
Thus in every case the derivation can only be expanded by one of the available productions. Therefore the grammar is not ambiguous.
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.