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I'm trying to write a C parser, for my own education. I know that I could use tools like YACC to simplify the process, but I want to learn as much as possible from the experience, so I'm starting from scratch.

My question is how I should handle a line like this:

doSomethingWith((foo)(bar));

It could be that (foo)(bar) is a type cast, as in:

typedef int foo;

void doSomethingWith(foo aFoo) { ... }

int main() {
    float bar = 23.6;

    doSomethingWith((foo)(bar));

    return 0;
}

Or, it could be that (foo)(bar) is a function call, as in:

int foo(int bar) { return bar; }

void doSomethingWith(int anInt) { ... }

int main() {
    int bar = 10;

    doSomethingWith((foo)(bar));

    return 0;
}

It seems to me that the parser cannot determine which of the two cases it is dealing with solely by looking at the line doSomethingWith((foo)(bar)); This annoys me, because I was hoping to be able to separate the parsing stage from the "interpretation" stage where you actually determine that the line typedef int foo; means that foo is now a valid type. In my imagined scenario, Type a = b + c * d would parse just fine, even if Type, a, b, c, and d aren't defined anywhere, and problems would only arise later, when actually trying to "resolve" the identifiers.

So, my question is: how do "real" C parsers deal with this? Is the separation between the two stages that I was hoping for just a naive wish, or am I missing something?

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4  
Hint: It doesn't. C compilers generally have a symbol table with them that contains all symbols identified so far, making it possible to do such a distinction. –  FUZxxl Sep 7 '13 at 20:03
    
I don't know your experience and skills, so I may be barking at the wrong tree, but what you are trying to do is fairly difficult (a C parser written in C). If this is your first attempt to write a parser in general, I'd suggest to try with simpler languages first (both as targets and for the implementation). I'd suggest Lua, it is simple, dynamic, safe and fast. Moreover, it has been designed to be embedded into applications written in C. IIRC on its WIKI I saw a parser for Lua written in Lua, whose study may be worth for you. –  Lorenzo Donati Sep 7 '13 at 20:23
    
Unlike you may be thinking, C is really hard to parse... I recommend you start try a more simple language for start. Maybe a BASIC-like language is a good one. And then you add own features in the language. Was as I did it. –  Jack Sep 8 '13 at 0:25
1  
@Lorenzo and Jack - I realize that C is not easy to parse, and I recognize that I am undertaking a challenging project, but I'd like to try anyway. Maybe I don't understand the complete extent of the difficulties I'll encounter, but hey, live and learn. I have written some very trivial parsers in the past, so I'm not completely new to this. And I do have ulterior motives for choosing C - yes, I want to learn about parsers by writing one, but I also have a need for a customizable C parser in one of my other projects, so I thought I'd kill two birds with one stone. Thanks for your help! –  Ord Sep 8 '13 at 17:13

3 Answers 3

up vote 12 down vote accepted

Historically, typedefs were a relatively late addition to C. Before they were added to the language, type names consisted of keywords (int, char, double, struct, etc.) and punctuation characters (*, [], ()), and so were easy to recognize unambiguously. An identifier could never be a type name, so an identifier in parentheses followed by an expression could not be a cast expression.

Typedefs made it possible for a user-defined identifier to be a type name, which rather seriously messed up the grammar.

Take a look at the syntax of type-specifier in the C standard (I'll use the C90 version since it's slightly simpler):

type-specifier:
void
char
short
int
long
float
double
signed
unsigned
struct-or-union-specifier
enum-specifier
typedef-name

All but the last can be easily recognized because they either are keywords, or start with a keyword. But a typedef-name is just an identifier.

When a C compiler processes a typedef declaration, it needs to, in effect, introduce the typedef name as a new keyword. Which means that, unlike for a language with a context-free grammar, there needs to be feedback from the symbol table to the parser.

And even that's a bit of an oversimplification. A typedef name can still be redefined, either as another typedef or as something else, in an inner scope:

{
    typedef int foo; /* foo is a typedef name */
    {
        int foo;     /* foo is now an ordinary identifier, an object name */
    }
                     /* And now foo is a typedef name again */
}

So a typedef name is effectively a user-defined keyword if it's used in a context where a type name is valid, but is still an ordinary identifier if it's redeclared.

TL;DR: Parsing C is hard.

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7  
"TL;DR: Parsing C is hard.". Amen! :-) –  Lorenzo Donati Sep 7 '13 at 22:57

What you're talking about is a "context-free grammar", where you can parse everything without having to remember what's a type and what's a variable (or, in general, use any semantic attributes associated with an identifier). C, unfortunately, is not context-free, so you don't have that luxury.

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3  
Yep. And this is a relevant link. –  Lorenzo Donati Sep 7 '13 at 20:14
    
@LorenzoDonati Thanks for the link - that page and its follow-ups (eli.thegreenplace.net/2011/05/02/… and eli.thegreenplace.net/2012/07/05/…) really helped me to get a handle on things. –  Ord Sep 8 '13 at 17:04
    
@Ord You're welcome! –  Lorenzo Donati Sep 8 '13 at 17:08
    
This is why you have to declare things in header files in C - just checking at link time that all the right functions and types exist will not work. –  jwg Apr 23 at 12:39

Virtually no modern language is context free (e.g, can have the meaning of a phrase determined entirely locally).

The smart money is to build a context-free parser, and resolve context-dependencies later, isolating the two tasks.

Thus the question of "how does the parser know type cast from function call" becomes a non-topic; the only reason it exists is that people insist on tangling raw parsing with name and type resolution.

For a cleaner model, consider using a GLR parser. See this SO answer for more detail, using the problem of resolving what

 x*y;

means in C, the same problem for OP, if he hasn't tripped over it yet.

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