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I'm currently trying to write a (very) small interpreter/compiler for a programming language. I have set the syntax for the language, and I now need to write down the grammar for the language. I intend to use an LL(1) parser because, after a bit of research, it seems that it is the easiest to use.

I am new to this domain, but from what I gathered, formalising the syntax using BNF or EBNF is highly recommended. However, it seems that not all grammars are suitable for implementation using an LL(1) parser. Therefore, I was wondering what was the correct (or recommended) approach to writing grammars in LL(1) form.

Thank you for your help, Charlie.

PS: I intend to write the parser using Haskell's Parsec library.

EDIT: Also, according to SK-logic, Parsec can handle an infinite lookahead (LL(k) ?) - but I guess the question still stands for that type of grammar.

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Parsec is capable of an infinite lookahead. You don't need to limit yourself to LL(1) for reasons other than performance. –  SK-logic Feb 18 '11 at 14:00
    
And it is not necessarily LL(k), it can be context-sensitive. So, the only thing you have to worry about is avoiding the left recursion. –  SK-logic Feb 18 '11 at 14:09

2 Answers 2

I'm not an expert on this as I have only made a similar small project with an LR(0) parser. The general approach I would recommend:

  1. Get the arithmetics working. By this, make rules and derivations for +, -, /, * etc and be sure that the parser produces a working abstract syntax tree. Test and evaluate the tree on different input to ensure that it does the arithmetic correctly. Make things step by step. If you encounter any conflict, resolve it first before moving on.

  2. Get simper constructs working like if-then-else or case expressions working.

  3. Going further depends more on the language you're writing the grammar for.

Definetly check out other programming language grammars as an reference (unfortunately I did not find in 1 min any full LL grammar for any language online, but LR grammars should be useful as an reference too). For example:

ANSI C grammar

Python grammar

and of course some small examples in Wikipedia about LL grammars Wikipedia LL Parser that you probably have already checked out.

I hope you find some of this stuff useful

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There are algorithms both for determining if a grammar is LL(k). Parser generators implement them. There are also heuristics for converting a grammar to LL(k), if possible.

But you don't need to restrict your simple language to LL(1), because most modern parser generators (JavaCC, ANTLR, Pyparsing, and others) can handle any k in LL(k).

More importantly, it is very likely that the syntax you consider best for your language requires a k between 2 and 4, because several common programming constructs do.

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Can you elaborate more on which particular constructs require which k's and why? I'm just curious. –  SasQ Mar 5 '11 at 6:19
    
@SasQ Off the top of my head, the if-then-else with optional else and no end requires a k of 2. Any construct with optional parts and no closing token will require a lookeahead larger than 1. –  Apalala Mar 5 '11 at 17:30
    
Even when you factor out the if-then part as a common factor rule? After that, matching that rule will match the if-then part, which is in itself correct. Then it could try to parse the optional part with else as the first token, so it can decide if it's there or not by only looking at that single token. For me this is LL(1), or I missed something? –  SasQ Mar 7 '11 at 19:52
    
@SaasQ I did say "off the top of my head". See [1] for why the "dangling else" problem cannot be handled with just LL(1). \ [1] en.wikipedia.org/wiki/Dangling_else –  Apalala Mar 9 '11 at 21:45

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