I'm learning how parsers work by creating a simple recursive descent parser. However I'm having a problem defining my grammar to be LL(1). I want to be able to parse the following two statements:

a = 1
a + 1

To do this I've created the following grammar rules:

statement:  assignent | expression
assignment: NAME EQUALS expression
expression: term [(PLUS|MINUS) term]
term:       NAME | NUMBER

However, this leads to ambiguity when using a LL(1) parser as when a NAME token is encountered in the statement rule, it doesn't know whether it is an assignment or an expression without a look-ahead.

Python's grammar is LL(1) so I know this is possible to do but I can't figure out how to do it. I've looked at Python's grammar rules found here (https://docs.python.org/3/reference/grammar.html) but I'm still not sure how they implement this.

Any help would be greatly appreciated :)

  • LL(1) doesn't mean no look-ahead, it means you have a one-token look-ahead (that's where the 1 comes from). When you find a NAME token, look for the next token, it will be an EQUALS, PLUS or MINUS token, then you know which rule to follow based on this information. – Mephy Oct 29 '16 at 22:58
  • 1
    Correct me if I'm wrong but I thought the single look-ahead would be the NAME token? – soarjay Oct 29 '16 at 23:18
  • It's been some time since I've learned compilers and my terminology may be wrong, but I think NAME is the current token (the one yielded by the lexer) and EQUALS/PLUS would be the first look-ahead token (the one you "peek" but don't actually pop). – Mephy Oct 29 '16 at 23:20
  • Thanks for clarifying :) – soarjay Oct 29 '16 at 23:27
  • I'm currently working through the book Language Implementation Patterns which describes LL(1) parsers by saying "it only needs to look at the current input symbol to make parsing decisions", which disagrees with your comment. – soarjay Oct 29 '16 at 23:32
up vote 2 down vote accepted

Just treat = as an operator with very low precedence. However (unless you want a language like C where = really is an operator with very low precedence), you need to exclude it from internal (e.g. parenthetic) expressions.

If you had only multiplication and addition, you could use:

expression: factor ['+' factor]
factor:     term ['*' term]
term:       ID | NUMBER | '(' expression ')'

That is a guide for operator precedence: has higher precedence because the arguments to + can include s but not vice versa. So we could just add assignment:

statement: expression ['=' expression]

Unfortunately, that would allow, for example:

(a + 1) = b

which is undesirable. So it needs to be eliminated, but it is possible to eliminate it when the production is accepted (by a check of the form of the first expression), rather than in the grammar itself. As I understand it, that's what the Python parser does; see the long comment about test and keywords.

If you used an LR(1) parser instead, you wouldn't have this problem.

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