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I was reading about parsers and parser generators and found this statement in wikipedia's LR parsing -page:

Many programming languages can be parsed using some variation of an LR parser. One notable exception is C++.

Why is it so? What particular property of C++ causes it to be impossible to parse with LR parsers?

Using google, I only found that C can be perfectly parsed with LR(1) but C++ requires LR(∞).

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Just like: you need to understand recursion to learn recursion ;-). – Toon Krijthe Oct 28 '08 at 13:56
"You'll understand parsers once you'll parse this phrase." – ilya n. Jun 17 '09 at 2:29

5 Answers 5

up vote 66 down vote accepted

There is an interesting thread on Lambda the Ultimate that discusses the LALR grammar for C++.

It includes a link to a PhD thesis that includes a discussion of C++ parsing, which states that:

"C++ grammar is ambiguous, context-dependent and potentially requires infinite lookahead to resolve some ambiguities".

It goes on to give a number of examples (see page 147 of the pdf).

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It'd be cool to have some summary about the page 147 on this page. I'm going to read that page though. (+1) – Cheery Oct 28 '08 at 14:11
The example is: int(x), y, *const z; //meaning: int x; int y; int *const z; (a sequence of declarations) int(x), y, new int; //meaning: (int(x)), (y), (new int)); (a comma-separated expression) The two token sequences have the same initial subsequence but different parse trees, which depend on the last element. There can be arbitrarily many tokens before the disambiguating one. – Blaisorblade Jan 6 '12 at 3:20
But not infinitely many. – Puppy Mar 9 '13 at 10:09
Well, in that context ∞ means "arbitrarily many" because the lookahead will always be bounded by the input length. – MauganRa May 12 '14 at 22:43

LR parsers can't handle ambiguous grammar rules, by design. (Made the theory easier back in the 1970s when the ideas were being worked out).

C and C++ both allow the following statement:

x * y ;

It has two different parses:

  1. It can be the declaration of y, as pointer to type x
  2. It can be a multiply of x and y, throwing away the answer.

Now, you might think the latter is stupid and should be ignored. Most would agree with you; however, there are cases where it might have a side effect (e.g., if multiply is overloaded). but that isn't the point. The point is there are two different parses, and therefore a program can mean different things depending on how this should have been parsed.

The compiler must accept the appropriate one under the appropriate circumstances, and in the absence of any other information (e.g., knowledge of the type of x) must collect both in order to decide later what to do. Thus a grammar must allow this. And that makes the grammer ambiguous.

Thus pure LR parsing can't handle this. Nor can many other widely available parser generators, such as Antlr, JavaCC, YACC, or traditional Bison, or even PEG-style parsers, used in a "pure" way.

There are lots of more complicated cases (parsing template syntax requires arbitrary lookahead, whereas LALR(k) can look ahead at most k tokens), but only it only takes counterexample to shoot down pure LR (or the others) parsing.

Most real C/C++ parsers handle this example by using some kind of deterministic parser with an extra hack: they intertwine parsing with symbol table collection... so that by the time "x" is encountered, the parser knows if x is a type or not, and can thus choose between the two potential parses. But a parser that does this isn't context free, and LR parsers (the pure ones, etc.) are (at best) context free.

One can cheat, and add checks in the reduction proposal to LR parsers to do this disambiguation. Most of the other parser types have some means to add semantic checks at various points in the parsing, that can be used to do this.

And if you cheat enough, you can make LR parsers work for C and C++. The GCC guys did for awhile, but gave it up for hand-coded parsing, I think because they wanted better error diagnostics.

There's another approach, though, which is nice and clean and parses C and C++ just fine without any symbol table hackery: GLR parsers. These are full context free parsers (having effectively infinite lookahead). GLR parsers simply accept both parses, producing a "tree" (actually a directed acyclic graph that is mostly tree like) that represents the ambiguous parse. A post-parsing pass can resolve the ambiguities.

We use this technique in the C and C++ front ends for our DMS Software Reengineering Tookit (as of Feb 2014 these handle full C++14 in MS and GNU dialects). They have been used to process millions of lines of large C and C++ systems, with complete, precise parses producing ASTs with complete details of the source code.

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While the 'x * y' example is interesting, the same can happen in C ('y' can be a typedef or a variable). But C can be parsed by a LR(1) parser, so what's the difference with C++? – Martin Cote Jun 17 '09 at 2:16
My answser had already observed that C had the same problem, I think you missed that. No, it can't be parsed by LR(1), for the same reason. Er, what do you mean 'y' can be a typedef? Perhaps you meant 'x'? That doesn't change anything. – Ira Baxter Jun 17 '09 at 6:06
Parse 2 is not necessarily stupid in C++, as * could be overridden to have side effects. – Dour High Arch Sep 9 '09 at 16:15
I looked at x * y and chuckled - it's amazing how little one thinks of nifty little ambiguities like this. – new123456 Jun 30 '11 at 20:33
@altie Surely no one would overload a bit-shift operator to make it write most variable types to a stream, right? – Troy Daniels Mar 12 '13 at 21:24

As you can see in my answer here, C++ contains syntax that cannot be deterministically parsed by an LL or LR parser due to the type resolution stage (typically post-parsing) changing the order of operations, and therefore the fundamental shape of the AST (typically expected to be provided by a first-stage parse).

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Parsing technology that handles ambiguity simply produces both AST variants as they parse, and simply eliminate the incorrect one depending on the type information. – Ira Baxter Sep 2 '09 at 16:51
@Ira: Yes, that is correct. The particular advantage of that is it allows you maintain the separation of the first-stage parse. While it's most commonly known in the GLR parser, there's no particular reason I see that you couldn't hit C++ with a "GLL?" parser as well. – Sam Harwell Sep 2 '09 at 17:50
"GLL"? Well, sure, but you'll have to go figure out the theory and write up a paper for the rest of to use. More likely, you could use a top down hand coded parser, or a backtracking LALR() parser (but keep the "rejected") parses, or run an Earley parser. GLR has the advantage of being a pretty damn good solution, is well documented and by now well proved. A GLL technology would have to have some pretty significant advantages to display GLR. – Ira Baxter Jan 28 '10 at 18:28
The Rascal project (Netherlands) is claiming they are building a scannerless GLL parser. Work in progress, might be hard to find any online information. – Ira Baxter Aug 21 '10 at 21:46
@IraBaxter There seems to be new developments on GLL: see this 2010 paper about GLL – Sjoerd Nov 19 '11 at 18:47

I think you are pretty close to the answer.

LR(1) means that parsing from left to right needs only one token to look-ahead for the context, whereas LR(∞) means an infinite look-ahead. That is, the parser would have to know everything that was coming in order to figure out where it is now.

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I recall from my compilers class that LR(n) for n > 0 is mathematically reducable to LR(1). Is that not true for n = infinity? – rmeador Oct 28 '08 at 14:41
No, there's an impassable mountain of a difference between n and infinity. – ephemient Oct 28 '08 at 14:53
Isn't the answer: Yes, given an infinite amount of time? :) – Steve Fallows Oct 28 '08 at 15:56
Actually, by my vague recollection of how LR(n) -> LR(1) takes place, it involves creating new intermediate states, so the runtime is some non-constant function of 'n'. Translating LR(inf) -> LR(1) would take infinite time. – Aaron Dec 5 '08 at 21:07
"Isn't the answer: Yes, given an infinite amount of time?" -- No: the phrase 'given an infinite amount of time' is just a non-sensical, short-hand way of saying "cannot be done given any finite amount of time". When you see "infinite", think: "not any finite". – ChrisW Jun 17 '09 at 2:10

The problem is never defined like this, whereas it should be interesting :

what is the smallest set of modifications to C++ grammar that would be necessary so that this new grammar could be perfectly parsed by a "non-context-free" yacc parser ? (making use only of one 'hack' : the typename/identifier disambiguation, the parser informing the lexer of every typedef/class/struct)

I see a few ones:

  1. Type Type; is forbidden. An identifier declared as a typename cannot become a non-typename identifier (note that struct Type Type is not ambiguous and could be still allowed).

    There are 3 types of names tokens :

    • types : builtin-type or because of a typedef/class/struct
    • template-functions
    • identifiers : functions/methods and variables/objects

    Considering template-functions as different tokens solves the func< ambiguity. If func is a template-function name, then < must be the beginning of a template parameter list, otherwise func is a function pointer and < is the comparison operator.

  2. Type a(2); is an object instantiation. Type a(); and Type a(int) are function prototypes.

  3. int (k); is completely forbidden, should be written int k;

  4. typedef int func_type(); and typedef int (func_type)(); are forbidden.

    A function typedef must be a function pointer typedef : typedef int (*func_ptr_type)();

  5. template recursion is limited to 1024, otherwise an increased maximum could be passed as an option to the compiler.

  6. int a,b,c[9],*d,(*f)(), (*g)()[9], h(char); could be forbidden too, replaced by int a,b,c[9],*d; int (*f)();

    int (*g)()[9];

    int h(char);

    one line per function prototype or function pointer declaration.

    An highly preferred alternative would be to change the awful function pointer syntax,

    int (MyClass::*MethodPtr)(char*);

    being resyntaxed as:

    int (MyClass::*)(char*) MethodPtr;

    this being coherent with the cast operator (int (MyClass::*)(char*))

  7. typedef int type, *type_ptr; could be forbidden too : one line per typedef. Thus it would become

    typedef int type;

    typedef int *type_ptr;

  8. sizeof int, sizeof char, sizeof long long and co. could be declared in each source file. Thus, each source file making use of the type int should begin with

    #type int : signed_integer(4)

    and unsigned_integer(4) would be forbidden outside of that #type directive this would be a big step into the stupid sizeof int ambiguity present in so many C++ headers

The compiler implementing the resyntaxed C++ would, if encountering a C++ source making use of ambiguous syntax, move source.cpp too an ambiguous_syntax folder, and would create automatically an unambiguous translated source.cpp before compiling it.

Please add your ambiguous C++ syntaxes if you know some!

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C++ is too well entrenched. Nobody will do this in practice. Those folks (like us) that build front ends simply bite the bullet and do the engineering to make the parsers work. And, as long as templates exist in the language, you're not going to get a pure context-free parser. – Ira Baxter Mar 9 '13 at 9:44

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