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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?

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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.

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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          
                       IN THIS A=A A'=A'
                    REMOVING LEFT RECURSION  :   A=aA'
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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 ...
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