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For example :


The above arithmetical expression may be abstracted by this BNF(there may be some difference from standard BNF,but lets ignore it for now):


AS = .ID ':=' EX1 ';' ;

EX1 = EX2 $( '+' EX2 / '-' EX2 ) ;

EX2 = EX3 $( '*' EX3 / '/' EX3 ) ;

EX3 = EX4 $( '^' EX3 ) ;

EX4 = '+' EX5 / '-' EX5 / EX5 ;

EX5 = .ID / .NUMBER / '(' EX1 ')' ;


But the EX1~EX5 abstraction is not so intuitive to me.(I don't quite understand how they are crafted in the first place)

Is there any steps to follow when normalizing such expressions?

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1 Answer 1

up vote 1 down vote accepted

You can translate this notation to EBNF directly.

Naming categories EX1 through EX5 is not an uncommon way of specifying operator precedence. In fact it is a good one, IMHO, especially in some languages that have 15 or more precedence levels, like C and C++ do. :)

You can rename them to expression, term, factor, primary, etc. (or whatever terms make sense to you).


If you need a translation of the above into more traditional EBNF, here is how I would do it:

AS   => id ':=' EX1 ';'
EX1  => EX2 (('+' | '-') EX2)*
EX2  => EX3 (('*' | '/') EX3)*
EX3  => EX4 ('^' EX3)*
EX4  => ('+'|'-')? EX5
EX5  => id | number | '(' EX1 ')'

I use '*' for zero or more, '+' for one or more, and '?' for optional. It is pretty cool how operator precedence is handled here, I think.


Please note: It appears that the rule for EX3 is wrong. The way it stands now you can get parse trees like this

     |   |    |    |    |    |    |
    EX4  ^   EX3   ^   EX3   ^   EX3
            / | \               / | \
         EX4  ^  EX3         EX4  ^  EX3

So writing a^b^c^d^e^f could mean a^(b^c)^d^(e^f). But in fact there are other ways to make this tree. The grammar is ambiguous.

It appears the designer of the grammar wanted to make the ^ operator right-associative. But to do so, the rule should have been

EX3 => EX4 ('^' EX3)?

Now the grammar is no longer ambiguous. Look how the derivation of a^b^c^d^e^f MUST now proceed:

         / | \
      EX4  ^  EX3
             / | \
          EX4  ^  EX3
                 / | \
              EX4  ^  EX3
                     / | \
                  EX4  ^  EX3
                         / | \
                      EX4  ^  EX3

Now a^b^c^d^e^f can ONLY parse as a^(b^(c^(d^(e^f))))

An alternative is to rewrite the rule as EX3 => EX4 ('^' EX4)* and have a side rule saying "OBTW the caret is right associative."

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Can you be more specific how to translate waldo:=fern+alpha/-beta^gamma; to EBNF? I'm at a loss when arriving at EX1.. –  Je Rog Jul 24 '11 at 5:57
@JeRog, added response in my answer. –  Ray Toal Jul 24 '11 at 6:42
Why is it EX3 => EX4 (('^' EX3)*, neither EX3 => EX4 (('^' EX4)* nor EX3 => EX4 (('^' EX1)*? I just wonder how can we derive the EBNF by observation.. –  Je Rog Jul 24 '11 at 6:57
The reason for the odd-looking EX3 rule is that the original designer of the grammar probably wanted to force the notion of right-associativity of ^ into the language. However, if he or she wanted to do so, then the rule should have been written like this: EX3 => EX4 ('^' EX3) -- that is, without the Kleene star. As to how we can write EBNF "by observation" the answer is you can do these things easily with experience. Once you start looking at a lot of grammars and you take a shot at designing your own, you will recognize common patterns and get pretty good at it. –  Ray Toal Jul 24 '11 at 7:06
How do you know ^ is right-associativity from EX4 ('^' EX3)*? I think that depends on the implementation and we can't infer it just from syntax.. –  Je Rog Jul 24 '11 at 7:20

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