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A lot of websites states that packrat parsers can parse input in linear time.
So at the first look they me be faster than LALR parser contructed by the tools yacc or bison.

I wanted to know if the performance of packrat parsers is better/worse than the performance of LALR parser when tested with common input (like programming language source files) and not with any theoretical inputs.

Does anyone can explain the main differences between the two approaches.
Thanks!

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3 Answers 3

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I'm not an expert at packrat parsing, but you can learn more at Parsing expression grammar on Wikipedia.

I haven't dug into it so I'll assume the linear-time characterization of packrat parsing is correct.

L(AL)R parsers are linear time parsers too. So in theory, neither packrat nor L(AL)R parsers are "faster".

What matters, in practice, of course, is implementation. L(AL)R state transitions can be executed in very few machine instructions ("look token code up in vector, get next state and action") so they can be extremely fast in practice. By "compiling" L(AL)R parsing to machine code, you can end up with lightning fast parsers, as shown by this 1986 Tom Pennello paper on Very Fast LR parsing. (Machines are now 20 years faster than when he wrote the paper!).

If packrat parsers are storing/caching results as they go, they may be linear time, but I'd guess the constant overhead would be pretty high, and then L(AL)R parsers in practice would be much faster. The YACC and Bison implementations from what I hear are pretty good.

If you care about the answer, read the basic technical papers closely; if you really care, then implement one of each and check out the overhead constants. My money is strongly on L(AL)R.

An observation: most language front-ends don't spend most of their time "parsing"; rather, they spend a lot of time in lexical analysis. Optimize that (your bio says you are), and the parser speed won't matter much.

(I used to build LALR parser generators and corresponding parsers. I don't do that anymore; instead I use GLR parsers which are linear time in practice but handle arbitrary context-free grammmars. I give up some performance, but I can [and do, see bio] build dozens of parsers for many languages without a lot of trouble.).

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It is possible to read the document (1986 Tom Pennello paper on Very Fast LR parsing) for free? –  raisyn Sep 29 '10 at 15:39
    
Sure. Visit your local university's computer science library :-} I think the ACM will charge you only modest cost; IMHO its well worth it to make sure that ACM continues to make stuff like this available. –  Ira Baxter Sep 29 '10 at 15:43
    
@IraBaxter, are L(AL)R parsers scannerless the way packrat parsers are? –  Mike Samuel Apr 23 '12 at 21:46
    
LALR scanners can be scannerless: just define the "tokens" using grammar rules. If you define tokens using regular expressions as is typical of LEX/YACC, then you pretty much don't lose anything except performance. (You can define lexers that extend regular expressions in way that are not, e.g., character lookahead) and then you can't do this –  Ira Baxter Apr 24 '12 at 2:09
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@Gunther: You can see I managed to get Paul Mann to restore the LRStart site. –  Ira Baxter Aug 4 '12 at 16:17
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I am the author of LRSTAR, an open-source LALR(k) parser generator. Because people are showing interest in it, I have put the product back online at sourceforge.net/projects/lrstar/. It's also at LRSTAR.ORG the website, which has more information.

I have studied the speed of LALR parsers and DFA lexers for many years. Tom Pennello's paper is very interesting, but is more of an academic exercise than a real-world solution for compilers. However, if all you want is a pattern recognizer, then it may be the perfect solution for you.

The problem is that real-world compilers usually need to do more than pattern recognition, such as symbol-table look-up for incoming symbols, error recovery, provide an expecting list (statement completion information), and build an abstract-syntax tree while parsing.

In 1989, I compared the parsing speed of LRSTAR parsers to "yacc" and found that they are 2 times the speed of "yacc" parsers. LRSTAR parsers use the ideas published in the paper: "Optimization of Parser Tables for Portable Compilers".

For lexer (lexical analysis) speed I discovered in 2009 that "re2c" was generating the fastest lexers, about twice the speed of those generated by "flex". I was rewriting the LRSTAR lexer generator section at that time and found a way to make lexers that are 1% faster then "re2c" and about 25% smaller on average. However, I prefer the table-driven lexers that LRSTAR generates, because they are almost as fast and the code compiles much quicker.

BTW, compiler front-ends generated by LRSTAR can process source code at a speed of 850,000 lines per second or faster. The lexers generated by LRSTAR can process 30,000,000 tokens per second. The testing computer was a 3 GHz single-CPU machine (from 2004).

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Please update the provided links. "compilerware" is redirecting; "sourceforge" has no sourcecode and a failing download for the only file. –  Jens-André Koch Nov 12 '12 at 13:33
    
I fixed the links today. –  Paul Mann May 16 '13 at 19:57
    
As of today, they don't seem to be working anymore. :( –  Paulo Torrens Sep 25 '13 at 5:05
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Performance is mostly a matter of language design. For each language, there will be an approach, technology, or parser generator that will make best fit.

I can't prove it without more thought, but I think that nothing can beat a top-down descent parser in which the semantics drive the parser, and the parser drives the lexer, performance-wise. It would also be among the most versatile and easier to maintain among the implementations.

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LR parsing theory says that parsing speed is linear with respect to the length of the input. This applies to computer languages which are mostly context free. So the parsing speed has not much to do with the language design. The parsing speed has much to do with the parsing algorithms and the language the parser is written in. –  Paul Mann May 16 '13 at 20:01
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