2

When looking through the C++ grammar I discovered that postfixes are defined roughly like this:

Postfix ::=  Primary
        |    Postfix '['  Expression ']'
        |    Postfix '('  Expression ')'
        |    Postfix '.'  Identifier
        |    Postfix '->' Identifier
        |    Postfix '++'
        |    Postfix '--'

Meaning that foo.f++() would be syntactically valid--presumably because functions are pointers it would refer to the next function that was defined, but I would be shocked if it wasn't caught during the semantic parse as modifying a const object--as would foo.f()<true>; which doesn't seem to have any meaning at all, while foo.++f() wouldn't be allowed, even though it does more or less the same thing as the first one. Furthermore, unary expressions are defined so that ++*"hello world" would be syntactically valid because literals are considered the same way that identifiers are.

Conversely something like:

postfix0 ::= ScopeResolution
         |   postfix0 '.' postfix2
         |   postfix0 '->' postfix2

postfix1 ::= postfix0
         |   postfix1 '<' expression '>'

postfix2 ::= postfix1
         |   postfix2 '[' expression ']'
         |   postfix2 '(' expression ']'

postfix3 ::= postfix2
         |   Literal
         |   postfix3 '++'
         |   postfix3 '--'

Would appear catch such invalid expressions during the syntactic phase of the parse. At first I thought that it was just left in the standard as a legacy thing, but newer languages such as Java and D do the same thing, so is there some sort of meaning that those statements carry that leads to the grammar being defined that way?

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  • foo.f++ is parsed as (foo.f)++. foo.++f can't be parsed. What would it be, (foo.++)f? Commented Apr 10, 2014 at 1:36
  • 4
    The grammar doesn't know about the type system, and trying to make the grammar catch things the type system prohibits would make parsing even harder than it already is. Maybe foo has a function pointer member named f, and foo.f++() calls foo.f() and postincrements foo.f. It's much easier to determine whether it's valid outside the grammar. Commented Apr 10, 2014 at 1:43
  • 1
    There are things that can be parsed but are still invalid, e.g. 1 = 1;
    – M.M
    Commented Apr 10, 2014 at 1:51
  • 3
    @user2357112: You probably meant a functor, not a function pointer, since functor objects might have operator++ defined, but function pointers can't.
    – Ben Voigt
    Commented Jun 5, 2014 at 18:08
  • 1
    and for completeness sake, "The value of a postfix ++ expression is the value of its operand. [ Note: the value obtained is a copy of the original value — end note ] The operand shall be a modifiable lvalue. The type of the operand shall be an arithmetic type or a pointer to a complete object type.
    – Ben Voigt
    Commented Jun 5, 2014 at 19:39

3 Answers 3

10

C++ isn't actually defined by its grammar productions. The BNF grammar is provided as an accompaniment to the rules of the language to aid in understanding, but there is not, and cannot be, a distinction between syntax errors and semantic errors in C++, because it does not have a context-free grammar.

So the improvement you're trying to make in changing "syntactically valid... caught during the semantic parse" to "catch such invalid expressions during the syntactic phase of the parse" is completely meaningless, since these don't actually exist as independent phases.

The phases of C++ compilation are found in section 2.1, [lex.phases] of the Standard. Of particular interest to this topic is phase 7:

White-space characters separating tokens are no longer significant. Each preprocessing token is converted into a token. (2.7). The resulting tokens are syntactically and semantically analyzed and translated as a translation unit.

Syntactic and semantic analysis are performed together, inseparably. Semantic errors are caught during the syntactic phase of the parse, phase 7.

5

As another fun note, foo.f++() can be semantically valid. But it has nothing at all to do with "the next function defined".

#include <iostream>

struct CallMe {
    void operator()() const
    { std::cout << "Used as function call.\n"; }
};

struct F_Type {
    CallMe operator++(int)
    { std::cout << "f was incremented.\n"; return {}; }
};

struct Foo_Type {
    F_Type f;
} foo;

int main()
{
    foo.f++();
}

Output:

f was incremented.
Used as function call.
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  • Works, but would be much more realistic for operator++ to return its own type, and have operator()() in F_Type.
    – Ben Voigt
    Commented Jun 5, 2014 at 20:28
  • Awesome answer; “parses fine but isn't usually supported semantically by the types in question” is entirely reasonable. Commented Jun 7, 2014 at 16:12
2

Just tried to compile and run this little program with gcc and g++:

#include <stdio.h>

void foo() {
    printf("foo()\n");
}

int main(void) {
    void (*bar)() = foo;
    bar++();
    bar();
}

If interpreted as C code, there is no compiler error, the string "foo()\n" is printed two times, but it segfaults when it tries to return from foo() because part of the function prolog seems to have been skipped.

So, yes, at least gcc thinks that bar++() is valid C code, and expediently does nonsense.

Update:
As zwol points out (thank for that), this is due to a rather dangerous than useful gnu extension, which treats pointers to void and functions as pointers to objects of size 1, allowing pointer arithmetic on them. Compiling with gcc --pedantic -Werror yields the expected error, gcc -std=c99 doesn't.


Different story with g++: Here I get the compiler error

foo.c: In function ‘int main()’:
foo.c:9:5: error: ISO C++ forbids incrementing a pointer of type ‘void (*)()’ [-fpermissive]

This is a provision within the C++ standard (section 5.2.6, as pointed out by Ben Voigt, thanks): pointer arithmetic on function pointers is not defined in C++.

8
  • Did you happen to read the comments on the question, where "some provision" is spelled out?
    – Ben Voigt
    Commented Jun 5, 2014 at 20:30
  • @BenVoigt Ah, thanks. Updated my answer to include that information. Commented Jun 5, 2014 at 20:35
  • It's section 5.2.6 in the Standard if you decide to put that quote in your answer. (You should, comments get mass-deleted at times)
    – Ben Voigt
    Commented Jun 5, 2014 at 20:38
  • The effect in C is due to one of GCC's least useful extensions. In the absence of this extension, bar++ violates a constraint in C99 6.5.6p2 (pointer operands to + and - shall be pointers to object types), having been referred there from 6.5.2.4p2,3 (defining ++ and -- in terms of += and -=).
    – zwol
    Commented Jul 18, 2016 at 0:18
  • @zwol Thanks, didn't know that. I added a paragraph on that to the answer, hope you like it :-) Commented Jul 19, 2016 at 18:04

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