Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have removed left-recursion from a left-recursive grammar given to me. The original grammar is as follows:

SPRIME::= Expr eof
Expr::= Term | Expr + Term | Expr - Term
Term::= Factor | Term * Factor | Term / Factor | Term mod Factor | Term div factor
Factor::= id | { Expr } | num | Funcall |
Funcall::= id [ Arglist ]
Arglist::= Expr | Expr , Arglist

When removing left-recursion, this is the grammar I produced:

SPRIME::= Expr eof
Expr::= Term Expr'
Expr'::= e | + Term Expr' | - Term Expr'
Term::= Factor Term'
Term'::= e | * Factor Term' | / Factor Term' | mod Factor Term' | div Factor Term'
Factor::= id | { Expr } | num | Funcall
Funcall::= id [ Arglist ]
Arglist::= Expr Arglist'
Arglist'::= , Arglist | e

My next task is to perform left-factoring on this grammar in order to make it LL(1). Having read the relevant chapter in the Dragon book, I'm unsure if I need to do anything to this grammar. My question is: is this grammar in LL(1) form already? And if not, where do I need to perform left-factoring in order to make it LL(1)?

EDIT: After taking @suddnely_me's answer into account, I have edited the Arglist non-terminal in order to left-factor it's productions. Is the grammar I have now an LL(1) grammar?

share|improve this question

3 Answers 3

up vote 2 down vote accepted

No, this grammar is not LL(1). At least, the last rules group is not left factored, since FIRST( Expr) and FIRST( Expr, Arglist) do interstect.

share|improve this answer
    
So would modifying the grammar in the following fashion transform it to LL(1)? –  Richard Stokes Apr 10 '11 at 11:39
    
At first glance, yes. As I remember from my academic years, the best way to check if the grammar is LL(1) is to build LL(1) analyzer of it. There are common algorythms to do it. –  suddnely_me Apr 10 '11 at 12:27
                     if it is in the form of     A->A.ALPHA|BETA 
                        REMOVING LEFT RECURSION     A->BETA A'|
                       A'->ALPHA A'|NULL          
                       EXAMPLE:::A->A+B|a
                       IN THIS A=A A'=A'
                        ALPHA=+B
                        BETA=a
                    REMOVING LEFT RECURSION  :   A=aA'
                        A'=+BA'|NULL
share|improve this answer
    
It'd be even better if you explained the code you posted. –  Alex Oct 28 '12 at 0:39

No, still (even a year later!) not LL(1). My oracle says:

Can't choose between two rules of 'Factor'
    -> id
    -> Funcall

'Funcall' can start with id.  For example:
    Funcall -> id ...
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.