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Is it possible to concat two string literals using a constexpr? Or rephrased can one eliminate macros in code like:

#define nl(str) str "\n"

int main()
{
  std::cout <<
      nl("usage: foo")
      nl("print a message")
      ;

  return 0;
}

Update: There is nothing wrong with using "\n", however I would like to know whether one can use constexpr to replace those type of macros.

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3  
What's wrong with "usage: foo\n" "print a message\n"? –  R. Martinho Fernandes Nov 8 '12 at 15:39
1  
Probably best to use std::endl rather than \n –  Douglas Leeder Nov 8 '12 at 15:42
1  
@R.MartinhoFernandes Or even "usage: foo\nprint a message\n"? –  James Kanze Nov 8 '12 at 15:43
11  
@Douglas probably not. If you want to print a newline, why would you print a newline and flush? –  R. Martinho Fernandes Nov 8 '12 at 15:43
5  
@DouglasLeeder: std::endl is overused when you just want '\n'. So I don't think std::endl should be used in place of '\n'. –  Nawaz Nov 8 '12 at 15:51

5 Answers 5

up vote 1 down vote accepted
  1. Yes, it is entirely possible to create compile-time constant strings, and manipulate them with constexpr functions and even operators. However,

  2. The compiler is not required to perform constant initialization of any object other than static- and thread-duration objects. In particular, temporary objects (which are not variables, and have something less than automatic storage duration) are not required to be constant initialized, and as far as I know no compiler does that for arrays. See 3.6.2/2-3, which define constant initialization, and 6.7.4 for some more wording with respect to block-level static duration variables. Neither of these apply to temporaries, whose lifetime is defined in 12.2/3 and following.

So you could achieve the desired compile-time concatenation with:

static const auto conc = <some clever constexpr thingy>;
std::cout << conc;

but you can't make it work with:

std::cout <<  <some clever constexpr thingy>;

Update:

But you can make it work with:

std::cout << *[]()-> const {
             static constexpr auto s = /* constexpr call */;
             return &s;}()
          << " some more text";

But the boilerplate punctuation is way too ugly to make it any more than an interesting little hack.


(Disclaimer: IANALL, although sometimes I like to play one on the internet. So there might be some dusty corners of the standard which contradicts the above.)

(Despite the disclaimer, and pushed by @DyP, I added some more language-lawyerly citations.)

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Could you point out for me where the Standard says temporaries have dynamic storage duration? Cannot find it.. –  dyp Nov 8 '12 at 19:32
    
I'd add 6.7/4, as we deal with block-scope variables here. And this only permits an implementation to do "early" init of local static-storage-duration variables (it's required to be initialized before first block entry). –  dyp Nov 8 '12 at 19:36
    
@DyP: 12.2/3 "Temporary objects are destroyed as the last step in evaluating the full-expression (1.9) that (lexically) contains the point where they were created." There are some exceptions following that, but nothing which would allow the temporary to become permanent. –  rici Nov 8 '12 at 19:40
    
For me, dynamic storage duration is (erroneously?) related to new and delete - where I would expect (effectively) all compilers to put a temporary on the stack. –  dyp Nov 8 '12 at 19:43
    
@DyP: quite right, I actually meant "automatic", but 12.2/3 seems to say that temporaries have even shorter lives than that. I can't find a phrase to describe temporary object lifetimes other than that, so I edited the response accordingly. Regardless of the standard, which probably does allow a compiler to constant initialize a constexpr temporary -- otherwise user-defined string literals would be a lot less interesting -- I'm pretty sure that compilers don't actually do it, except maybe for user-defined string literals, which are not yet widely implemented. –  rici Nov 8 '12 at 19:50

At first glance, C++11 user-defined string literals appear to be a much simpler approach. (If, for example, you're looking for a way to globally enable and disable newline injection at compile time)

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Wait, maybe not... literal concatenation won't preserve the boundaries :( –  Ben Voigt Nov 8 '12 at 15:56

Nope, for constexpr you need a legal function in the first place, and functions can't do pasting etc. of string literal arguments.

If you think about the equivalent expression in a regular function, it would be allocating memory and concatenating the strings - definitely not amenable to constexpr.

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  • You cannot return a (plain) array from a function.
  • You cannot create a new const char[n] inside a constexpr (§7.1.5/3 dcl.constexpr).
  • An address constant expression must refer to an object of static storage duration (§5.19/3 expr.const) - this disallows some tricks with objects of types having a constexpr ctor assembling the array for concatenation and your constexpr fct just converting it to a ptr.
  • The arguments passed to a constexpr are not considered to be compile-time constants so you can use the fct at runtime, too - this disallows some tricks with template metaprogramming.
  • You cannot get the single char's of a string literal passed to a function as template arguments - this disallows some other template metaprogramming tricks.

So (as far as I know), you cannot get a constexpr that is returning a char const* of a newly constructed string or a char const[n]. Note most of these restrictions don't hold for an std::array as pointed out by Xeo.

And even if you could return some char const*, a return value is not a literal, and only adjacent string literals are concatenated. This happens in translation phase 6 (§2.2), which I would still call a preprocessing phase. Constexpr are evaluated later (ref?). (f(x) f(y) where f is a function is a syntax error afaik)

But you can return from your constexpr fct an object of some other type (with a constexpr ctor or that is an aggregate) that contains both strings and can be inserted/printed into an basic_ostream.


Edit: here's the example. It's quite a bit long o.O Note you can streamline this in order just to get an additional "\n" add the end of a string. (This is more a generic approach I just wrote down from memory.)

Edit2: Actually, you cannot really streamline it. Creating the arr data member as an "array of const char_type" with the '\n' included (instead of an array of string literals) uses some fancy variadic template code that's actually a bit longer (but it works, see Xeo's answer).

Note: as ct_string_vector (the name's not good) stores pointers, it should be used only with strings of static storage duration (such as literals or global variables). The advantage is that a string does not have to be copied & expanded by template mechanisms. If you use a constexpr to store the result (like in the example main), you compiler should complain if the passed parameters are not of static storage duration.

#include <cstddef>
#include <iostream>
#include <iterator>

template < typename T_Char, std::size_t t_len >
struct ct_string_vector
{
    using char_type = T_Char;
    using stringl_type = char_type const*;

private:
    stringl_type arr[t_len];

public:
    template < typename... TP >
    constexpr ct_string_vector(TP... pp)
        : arr{pp...}
    {}

    constexpr std::size_t length()
    {  return t_len;  }

    template < typename T_Traits >
    friend
    std::basic_ostream < char_type, T_Traits >&
    operator <<(std::basic_ostream < char_type, T_Traits >& o,
        ct_string_vector const& p)
    {
        std::copy( std::begin(p.arr), std::end(p.arr),
            std::ostream_iterator<stringl_type>(o) );
        return o;
    }
};

template < typename T_String >
using get_char_type =
    typename std::remove_const < 
    typename std::remove_pointer <
    typename std::remove_reference <
    typename std::remove_extent <
        T_String
    > :: type > :: type > :: type > :: type;

template < typename T_String, typename... TP >
constexpr
ct_string_vector < get_char_type<T_String>, 1+sizeof...(TP) >
make_ct_string_vector( T_String p, TP... pp )
{
    // can add an "\n" at the end of the {...}
    // but then have to change to 2+sizeof above
    return {p, pp...};
}

// better version of adding an '\n':
template < typename T_String, typename... TP >
constexpr auto
add_newline( T_String p, TP... pp )
-> decltype( make_ct_string_vector(p, pp..., "\n") )
{
    return make_ct_string_vector(p, pp..., "\n");
}

int main()
{
    // ??? (still confused about requirements of constant init, sry)
    static constexpr auto assembled = make_ct_string_vector("hello ", "world");
    enum{ dummy = assembled.length() }; // enforce compile-time evaluation
    std::cout << assembled << std::endl;
    std::cout << add_newline("first line") << "second line" << std::endl;
}
share|improve this answer
    
The enum isn't necessary; static constexpr auto will do it. In fact, static const auto will make it constant-initialized if possible. But neither of those will let the second std::cout line act in the same way as the macro in the OP, not even to the extent of optimizing add_newline("first line") into a compile-time literal. –  rici Nov 8 '12 at 19:56
    
@rici Sry, but I still don't get why static constexpr is sufficient. After all, this is a block-scope static variable and therefore, 6.7/4 holds ("An implementation is permitted.."). Maybe a chat (cannot figure out how to start it o.O)? –  dyp Nov 8 '12 at 20:02
    
@DyP: 6.7/4 says "Constant initialization (3.6.2) of a block-scope entity with static storage duration, if applicable, is performed before its block is first entered." So if constant initialization is applicable, it's applied. The "An implementation is permitted... of other block-scope variables..." statement applies to initializations for which the conditions in 3.6.2 do not apply. At least, that's my interpretation, but like I said in the disclaimer, IANALL. –  rici Nov 8 '12 at 23:05

A little bit of constexpr, sprinkled with some TMP and a topping of indices gives me this:

#include <array>

template<unsigned... Is> struct seq{};
template<unsigned N, unsigned... Is>
struct gen_seq : gen_seq<N-1, N-1, Is...>{};
template<unsigned... Is>
struct gen_seq<0, Is...> : seq<Is...>{};

template<unsigned N1, unsigned... I1, unsigned N2, unsigned... I2>
constexpr std::array<char const, N1+N2-1> concat(char const (&a1)[N1], char const (&a2)[N2], seq<I1...>, seq<I2...>){
  return {{ a1[I1]..., a2[I2]... }};
}

template<unsigned N1, unsigned N2>
constexpr std::array<char const, N1+N2-1> concat(char const (&a1)[N1], char const (&a2)[N2]){
  return concat(a1, a2, gen_seq<N1-1>{}, gen_seq<N2>{});
}

Live example.

I'd flesh this out some more, but I have to get going and wanted to drop it off before that. You should be able to work from that.

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I also considered this approach, but used another one because of the "implementation quantities" (Annex B). Though I'm not absolutely sure, I think this limits the length of strings you can work on to 256 (or 1024) chars, whereas a string literal itself can be >65k chars long. –  dyp Nov 8 '12 at 18:38
    
@Dyp (and Xeo): this suffers from the same problem as DyP's clever solution, which is that while it produces the expected output, it actually creates the strings at run-time. In order to get it not to do that, as far as I know, you have to do something like static const auto s = _call to clever constexpr_. I compiled both of these with clang 3.2 and g++ 4.7.2 (which 'sorry's on DyP's) to look at the assembly code generated. –  rici Nov 8 '12 at 19:03
    
@rici oh you're right, thanks (§3.6.2/2) –  dyp Nov 8 '12 at 19:13
    
@DyP, I was just rereading that section, in fact. Afaics, it allows compilers to do constant initialization of temporaries, but it certainly doesn't require them to do so, and neither clang nor gcc does. However, it is quite possible that other text in the standard would also get in the way of constant initialization (beyond just proving that the restrictions in 3.6.2/3 don't apply, which might in itself be tricky). –  rici Nov 8 '12 at 19:19
    
@Xeo when I turn the fcts constexpr and assign constexpr auto s = concat(...); it does not compile on clang 3.1 ("read of uninitialized object") but I don't understand why. When I add an constexpr ctor to gen_seq<0, Is...>, it compiles fine. –  dyp Nov 8 '12 at 20:57

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