3

A while ago I asked about std::string constants correct idiom for std::string constants?.

What I took away from that was not to use std::string constants but to use char string constants. So what the best idiom for that

#define FOO "foo"

const char * const FOO = "foo";

const char FOO[] = "foo";

Desirable features

  • get length at compile time. 1 & 3 but not 2 (sizeof doesnt work on 2)
  • can be included in .h without linker complaining. all (I think)
  • no multiple copies in .o, in linked output. depends on compiler (probably)

So it seems like #3 is best but scott meyers says to use #2 (effective c++ item #1)

summary of answers

  1. use jolly complicated template code
  2. use #3

The template code feels like overkill. So for now I go with #3;

But I will ruminate on the template code, the macroized version makes it look OKish; but I dont like the fact that its not portable (who knows, maybe gcc will decide that its wrong too)

5 Answers 5

4

For the features that you want, ...

  • get length at compile time,
  • can be included in .h without linker complaining all,
  • no multiple copies in .o, in linked output,

... you can use the templated constant idiom, like

template< class Dummy >
struct Foo_
{
    static char const s[];
};

template< class Dummy >
char const Foo_<Dummy>::s[] = "Blah blah";

typedef Foo_<void> Foo;    // Now you can refer to Foo:s


#include <iostream>
using namespace std;
int main()
{
    cout << sizeof( Foo::s ) << " bytes: \"" << Foo::s << "\"\n";
}

You can wrap the generation in a macro.

However, as far as I know the only practical utility is to support char/wchar_t-agnostic code, and for that the pain may be larger than the gain.

EDIT:
MSVC versions 7.1 up through 10.0 incorrectly doesn't accept the sizeof. The following is a workaround that compiles nicely with g++ 4.4.1, Comeau Online 4.3.10.1, MSVC 7.1 and MSVC 10.0.

#include <stddef.h>

typedef ptrdiff_t   Size;

// Substitute a more general countOf
template< Size n >
struct SizedBuf { char sizer[n]; };

template< class Type, Size n >
SizedBuf< n > countOf_( Type (&)[n] ) { return n; }

#define COUNT_OF( array ) sizeof( countOf_( array ).sizer )

#define DEF_STRING( name, value )                               \
    template< class >                                           \
    struct name##_constant_                                     \
    {                                                           \
        static char const str[];                                \
        static Size const length    = COUNT_OF( value ) - 1;    \
    };                                                          \
                                                                \
    template< class Type >                                      \
    char const name##_constant_< Type >::str[] = value;         \
                                                                \
    template< class Type >                                      \
    Size const name##_constant_< Type >::length;                \
                                                                \
    typedef name##_constant_<void>  name;


DEF_STRING( a, "Argh, MSVC!" )
DEF_STRING( b, "Blah blah" )
DEF_STRING( c, "Currently there's no 'inline' for data in C++." )


#include <iostream>

template< char const* s >
void foo() { std::cout << "foo() says: " << s << std::endl; }

int main()
{
    using namespace std;

    int const x[a::length] = {};    // Showing off compile time constant.
    foo<a::str>();                  // Showing off external linkage.

    cout << a::length << " characters: \"" << a::str << "\"." << endl;
}

Cheers & hth.,

11
  • 1
    Care to explain exactly what benefit you get over the const char FOO[] = "foo"; syntax? I have a hard time going through both a weird template and a macro, as well as loosing support for easily changing from char to wchar_t and still generating a copy in each compilation unit... Oct 21, 2010 at 22:13
  • @André: your suggestion would not conform to the OP's 3rd requirement. The comment about "easily changing" is also meaningless, sorry. Cheers & hth., Oct 21, 2010 at 22:17
  • Thinking about it, tt does reduce the number of copies to only the compilation units where the value is used, just like the macro version. However, you still get a macro and a weird template :-) Oct 21, 2010 at 22:18
  • @André: "to only the compilation units where the value is used", no, it reduces the number of copies to 1, across the program (this was the OP's requirement). Cheers & hth., Oct 21, 2010 at 22:20
  • @Alf: your solution does not strictly conform the the 3rd requirement either. You still get a template instantiation in each compilation unit because of the typedef, hence a copy of the string in each compilation unit. Oct 21, 2010 at 22:21
0

Your desired features are contradictory.

  1. Length at compile time
  2. Defined in header file
  3. Single copy across compilation units

To get (1) and (2), you need to declare the variable as static or put it in an unnamed namespace. However, this will cause a definition in each compilation unit, which goes against (3).

To get (2) and (3), you need to declare the variable as extern, but then you won't get (1).

Now, if your linker is smart, it might optimize away the multiple copies, but I'm not sure if the standard allows it...

I recommend the const char FOO[] = "foo"; syntax declared in an unnamed namespace or as static if it need to be found in a specific namespace. If the string is very large, then I go for an extern.

2
  • Uh, the features are not contradictory. Argh, now to explain that I'll have to add an answer. So be it. Cheers, Oct 21, 2010 at 21:54
  • @pm100: it behaves like static in that it gives you (1) and (2) at the expense of generating a copy in each compilation unit (although it is guaranteed not to be generated unless it is actually used). Oct 21, 2010 at 23:01
0

This is how I see it. I wouldn't use any of those as it is. First, I'm inclined by #2, but, take into account that you have to declare the variable as extern in the .h, and select some .cpp to actually store the string:

// .h
extern const char*const STR;

// .cpp
const  char*const STR = "abc";

The only drawback, not having the length at run-time, doesn't seem to me a real reason to move to other option. If you have several strings, you can always have a set of integer constants (or #defines) to specify each string's length, such as STR_LEN. If you have a lot of them, you won't write them at hand anyway, and you can then generate automatically the ..._LEN constants at the same time.

3
  • If the length is not needed at compile-time, then there is no more reason not to use std::string. Oct 21, 2010 at 22:16
  • @André: Maybe the overhead of the dynamic memory used by the std::sting. But yes, in general there is not much point on not using std::string. Oct 21, 2010 at 22:33
  • actually not - const * char const can safely be placed in multiple header files
    – pm100
    Oct 21, 2010 at 22:40
0

I think you took the wrong idea away from your previous question.
Strings tend to be sparse and not good for lookup, use numbers instead.

You still don't seem to get the difference between declaring in a .h and defining the storage in a .cpp thus avoiding multiple copies. Even if you had multiple copies (with different constant names) you would still have the issue you mentioned from your previous question.

has one fatal flaw. I cannot have static module level code that uses these strings since they might not have been constructed yet

The only way to avoid this is to bring the constants into the same scope with what you currently have at static module level.

Put all the related stuff in a class!

2
  • para 2- I understand precisely the differences. In some cases we are talking about harmless duplication of literals, in other cases we are talking about linker barfs. I know exactly what produces linker barfs and what does not. In my desirable feature list I have as a high need - no linker barfs, and as a nice to have ; no bloat
    – pm100
    Oct 21, 2010 at 22:45
  • second the issues regarding class has nothing to do with it. If I have global statics then the load order is not defined. I can rearrange my code so that I dont have global static, but thats not the point. I am observing that if you do have global static that the suggestion doesnt work
    – pm100
    Oct 21, 2010 at 22:47
0

This is just Alf's answer macro'd:

#include <iostream>

#define string_constant(pName, pLiteral)                    \
        template <typename = void>                          \
        struct pName##_detail                               \
        {                                                   \
            static const char value[];                      \
        };                                                  \
                                                            \
        template <typename T>                               \
        const char pName##_detail<T>::value[] = pLiteral;   \
                                                            \
        typedef pName##_detail<> pName

string_constant(my_constant, "this is a literal");

int main()
{
    std::cout << my_constant::value << std::endl;
    std::cout << sizeof my_constant::value << std::endl;
}

codepad. Doesn't seem to work in VS2010. :/

4
  • re "Doesn't seem to work in VS2010", I haven't checked but one difference between the above code and mine is that the above uses a default template parameter. Cheers & hth., Oct 21, 2010 at 22:32
  • @Alf: That shouldn't make a difference (it's just cleaner to me). But I changed it anyway just to be sure, same error. Looks like yet another case of non-compliance. (FFS)
    – GManNickG
    Oct 21, 2010 at 22:38
  • g++ and Comeau online accept the code, MSVC 10 (and I also checked with 7.1) do not. Checking template param matching it seems that MSVC incorrectly regards the array's type as incomplete in main. In C++0x draft N3092 §3.9/6 discusses the completion of an array type within a translation unit (going from incomplete to complete when size becomes known). I'm sorry, I don't know of an MSVC workaround. I tried a few things, none worked. :-( Oct 21, 2010 at 23:19
  • as long as its wrapped by a macro anyway, the macro can infer the length and define a length constant. I've added example code for that to my answer. Cheers, Oct 22, 2010 at 2:32

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