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I'm making an LR(1) parser, and I've run across performance bottlenecks in various places.

I'd like to try optimizing the the data structures for the parser, but in order to do so, I need a rough idea of how many states, rules, and terminal symbols are reasonable for (possibly complicated) computer languages, like C++.

My guesses are that a typical grammar for a complicated language would have:

  • ≤ 100 terminal symbols
  • ≤ 50 symbols per production
  • ≤ 2,000 rules
  • ≤ 10,000 states

but I really don't know how correct they are.

Note that I assume each rule is of the form nonterminalsymbol symbol symbol..., so a single compound "rule" that looks like foo: (bar | baz)+ might actually consist of, say, 5 rules, instead of just 1 rule.

Are they reasonable? If not, where I find some numbers on these?

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I'd suggest talking about some other language in your question, since I don't think C++ can be parsed by LR(1) at all. –  Ben Voigt Jan 4 '13 at 4:52
    
@BenVoigt: I plan on making it a generalized LR parser (GLR), which I think can theoretically handle C++. If I understand correctly the problem with C++ is that the LR(1) grammar is ambiguous, not that it's nonexistent, right? So that should be fine. –  Mehrdad Jan 4 '13 at 4:53
    
Where is the bottleneck? The lookup tables/sets should only cost O(1) for the next state. –  leppie Jan 4 '13 at 4:56
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@leppie: Unfortunately (or fortunately?) the bottleneck is in the generation of the parser (figuring out all the states), not in the actual parser. –  Mehrdad Jan 4 '13 at 4:57
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@Mehrdad: Ahhh, that's makes a lot more sense. But generating the parser should only be a 'one-time' job. Personally, I would not worry. ;p –  leppie Jan 4 '13 at 5:00

1 Answer 1

up vote 6 down vote accepted

The DMS system I developed daily processes a production IBM Enterprise COBOL front end grammar in about 7 seconds on a crummy laptop (measured just now on that laptop).

The grammar has about 500 terminals and 2500 productions, averaging about 2.5 tokens per production. Our productions are exactly as you describe them (no EBNF, just doesn't buy enough to matter, and yes, we're big DSL fans. Sometimes the geegaws people put in a DSL aren't worth it). The parser generator produces 3800 states. (These values measured just now, too).

DMS has a full C++11 grammar with lots of extra stuff to handle GCC and MS dialects, as well as OpenMP. The grammar has 457 terminals, some 3000 productions, some 2.3 tokens per production average. The parser generator produces 5800 states. Takes somewhat longer to generate: 11 seconds, on an i7. What you might find surprising is that it takes some tens of seconds to generate the lexer (really multiple lexers); there's a lot more lexing weirdness in C++11 than you'd expect.

The generator is a GLR generator of our own implementation.

We didn't do a lot to optimize the generation time. It likely can be sped up by a factor of 10 or more; we don't do sophisticated cycle detection optimization as suggested in most papers on LR parser generation. The consequence is that it takes longer to generate the tables but nothing is lost in functionality. We've never had enough motivation to do that optimization, because there are so many other things to do with a language front end than worry about the parser table generation time.

I doubt the data structures matter a lot, if designed reasonably. We don't worry much about sizes of rules, item sets or states; we just use dynamic arrays and they take care of themselves. We do pack lookaheads into dense bit vectors.

As additional background data, you'll probably find this paper useful: Tiago Alves and Joost Visser, Metrication of SDF Grammars. Technical Report, DI-Research.PURe-05.05.01, Departamento de Informática, Universidade do Minho, May 2005.

The parser generator isn't where you have a difficult time with grammars. It is getting the grammar rules right for the specific implementations.

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Wow thanks for going through the trouble of measuring! And for the advice as well. This is an awesome answer, thanks so much! :) –  Mehrdad Jan 4 '13 at 6:44
    
It's also reassuring to know that my ~4s is in the right ballpark! –  Mehrdad Jan 4 '13 at 6:51
    
You said that was for a stripped down Python grammar, not a full production grammar. I suspect it is high, because you are generating LR(1) tables. There's a corresponding time cost to generating all those extra states. –  Ira Baxter Jan 4 '13 at 6:52
    
Ah yeah, it's for a stripped down Python grammar, so it's still definitely slow all right -- what I meant when I said it's in the right ballpark is that it seems to be on the right track, not that it's already reached its goal. :) –  Mehrdad Jan 4 '13 at 7:05
    
So I managed to get it down to ~2 seconds by putting all productions into a single contiguous array and representing each item core as an iterator into that array, and then using a bit vector for representing item sets in one place. The bottleneck is still in memory allocation (and some non-locality in the data). Using a hashtable (unordered_map instead of map) brings it down to ~1.4 seconds... and now I seem to be hitting a wall, unless I try to use a better allocator or something... the fact that I'm representing item sets as set<set<Item> > seems to be what's slowing it down. :\ –  Mehrdad Jan 4 '13 at 12:03

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