305

Using C++11, Ubuntu 14.04, GCC default toolchain.

This code fails:

constexpr std::string constString = "constString";

error: the type ‘const string {aka const std::basic_string}’ of constexpr variable ‘constString’ is not literal... because... ‘std::basic_string’ has a non-trivial destructor

Is it possible to use std::string in aconstexpr? (apparently not...) If so, how? Is there an alternative way to use a character string in a constexpr?

14
  • 7
    std::string is not a literal type Nov 25, 2014 at 9:47
  • 20
    @PiotrS - the question says that...
    – Gramps
    Nov 25, 2014 at 9:48
  • 6
    @Vector did I ask you what the constexpr is for or why do you want std::string to be constexpr? there are several compile-time string implementations on SO. what is the point in asking if you can make a non-literal type constexpr if you understand error message and know only literal types can be made constexpr? as well there are several reasons why one may want to have a constexpr instance, so I suggest you clarify your question Nov 25, 2014 at 10:25
  • 4
    Yes as @PiotrS. said, there are constexpr string implementations out there. std::string is not one of them.
    – tenfour
    Nov 25, 2014 at 11:12
  • 8
    @PiotrS - there are several compile-time string implementations on SO - OK, thanks, understood. That's not an option for me but it answers my question: no way std::string will work. As I remarked to tenfour, I was wondering if there was a way to use std::string in way that would work. There are many tricks that I certainly am not aware of.
    – Gramps
    Nov 25, 2014 at 11:17

5 Answers 5

294

As of C++20, yes, but only if the std::string is destroyed by the end of constant evaluation. So while your example will still not compile, something like this will:

constexpr std::size_t n = std::string("hello, world").size();

However, as of C++17, you can use string_view:

constexpr std::string_view sv = "hello, world";

A string_view is a string-like object that acts as an immutable, non-owning reference to any sequence of char objects.

10
  • 23
    Be aware that whenever you pass this constant to a function taking a const std::string& a new std::string has to be constructed. That is usually the opposite of what one had in mind when creating a constant. Therefore, I tend to say that this is not a good idea. At least you have to be careful. Apr 4, 2018 at 10:17
  • 58
    @RamboRamon string_view is not implicitly convertible to string, so there is little danger of accidentally constructing a string from a string_view. Conversely, char const* is implicitly convertible to string, so using string_view is actually safer in this sense. Apr 4, 2018 at 13:08
  • 13
    Thanks for the clarification. I totally agree and indeed forgot that string_view is not implicitly convertible to string. IMO the problem I brought up is still valid but does not apply to string_view specifically. In fact, as you mentioned, it is even safer in that regard. Apr 4, 2018 at 16:25
  • 8
    It would be great if this answer said more about what string_view is, instead of just a link.
    – eric
    Apr 25, 2018 at 13:47
  • 4
    Note that while a std::string has a .c_str() method, which returns a char* which is NULL terminated, string_view does not. Like std::string, it has a .data() method which returns a char* which is not guaranteed to be null terminated (and won't be the the string_view is a view into another string which has no internal NULLs). If you are initializing it from a compile-time constant char array, it will be NULL terminated, but be careful accepting string_view if you need to work with system calls.
    – Perkins
    Feb 24, 2021 at 21:58
249

No, and your compiler already gave you a comprehensive explanation.

But you could do this:

constexpr char constString[] = "constString";

At runtime, this can be used to construct a std::string when needed.

15
  • 115
    Why not constexpr auto constString = "constString";? No need to use that ugly array syntax ;-)
    – stefan
    Nov 25, 2014 at 10:19
  • 135
    In the context of this question, it's clearer. My point is about which string types you can choose from. char[] is more verbose / clear than auto when I'm trying to emphasize the data type to use.
    – tenfour
    Nov 25, 2014 at 11:07
  • 12
    @tenfour Right, that's a good point. I guess I'm sometimes a bit too focused on using auto ;-)
    – stefan
    Nov 25, 2014 at 12:15
  • 10
    Does it make sense to constexpr a char array in that context? If you use it to construct a string, it's going to be copied anyway. What's the difference between passing literal to the string's constructor and passing such a constexpr array to it?
    – KjMag
    Jul 21, 2017 at 22:31
  • 15
    @stefan usually I prefer auto. But there's a subtle difference: auto will be deduced as const char* const, hence sizeof(constString) will yield 8. However, with the char constString[]-syntax, sizeof(constString) yields the number of characters in the string literal, which is presumably what one expects.
    – pasbi
    Jan 31, 2019 at 16:36
49

C++20 will add constexpr strings and vectors

The following proposal has been accepted apparently: http://www.open-std.org/jtc1/sc22/wg21/docs/papers/2018/p0980r0.pdf and it adds constructors such as:

// 20.3.2.2, construct/copy/destroy
constexpr
basic_string() noexcept(noexcept(Allocator())) : basic_string(Allocator()) { }
constexpr
explicit basic_string(const Allocator& a) noexcept;
constexpr
basic_string(const basic_string& str);
constexpr
basic_string(basic_string&& str) noexcept;

in addition to constexpr versions of all / most methods.

There is no support as of GCC 9.1.0, the following fails to compile:

#include <string>

int main() {
    constexpr std::string s("abc");
}

with:

g++-9 -std=c++2a main.cpp

with error:

error: the type ‘const string’ {aka ‘const std::__cxx11::basic_string<char>’} of ‘constexpr’ variable ‘s’ is not literal

std::vector discussed at: Cannot create constexpr std::vector

Tested in Ubuntu 19.04.

0
22

Since the problem is the non-trivial destructor so if the destructor is removed from the std::string, it's possible to define a constexpr instance of that type. Like this

struct constexpr_str {
    char const* str;
    std::size_t size;

    // can only construct from a char[] literal
    template <std::size_t N>
    constexpr constexpr_str(char const (&s)[N])
        : str(s)
        , size(N - 1) // not count the trailing nul
    {}
};

int main()
{
    constexpr constexpr_str s("constString");

    // its .size is a constexpr
    std::array<int, s.size> a;
    return 0;
}
2
  • 30
    This is basically what c++17 string_view is, except that string_view gives you most of the functionality that you know from std::string
    – wich
    May 11, 2017 at 13:54
  • 1
    This is a bit of a nit, but I just wanted to point out that "can only construct from a char[] literal" isn't quite true. You can construct a local array, like char test[6] { "hello" }; constexpr_str s(test);. I just ran into this so just wanted to point that out. If you really want to enforce literals, one alternative is to pass a "const char*" as a template non-type parameter, although that's a bit finicky as well, depending on c++ version. Oct 30, 2022 at 12:12
15

C++20 is a step toward making it possible to use std::string at compile time, but P0980 will not allow you to write code like in your question:

constexpr std::string constString = "constString";

the reason is that constexpr std::string is allowed only to be used in constexpr function (constant expression evaluation context). Memory allocated by constexpr std::string must be freed before such function returns - this is the so called transient allocation, and this memory cannot 'leak' outside to runtime to constexpr objects (stored in data segments) accessible at runtime . For example compilation of above line of code in current VS2022 preview (cl version : 19.30.30704) results in following error:

1> : error C2131: expression did not evaluate to a constant
1> : message : (sub-)object points to memory which was heap allocated during constant evaluation

this is because it tries to make a non-transient allocation which is not allowed - this would mean allocation into a data segment of the compiled binary.

In p0784r1, in "Non-transient allocation" paragraph, you can find that there is a plan to allow conversion of transient into static memory (emphasis mine):

What about storage that hasn't been deallocated by the time evaluation completes? We could just disallow that, but there are really compelling use cases where this might be desirable. E.g., this could be the basis for a more flexible kind of "string literal" class. We therefore propose that if a non-transient constexpr allocation is valid (to be described next), the allocated objects are promoted to static storage duration.

There is a way to export transient std::string data outside to make it usable at runtime. You must copy it to std::array, the problem is to compute the final size of std::array, you can either preset some large size or compute std::string twice - once to get size and then to get atual data. Following code successfully compiles and runs on current VS2022 preview 5. It basicly joins three words with a delimiter between words:

constexpr auto join_length(const std::vector<std::string>& vec, char delimiter) {
  std::size_t length = std::accumulate(vec.begin(), vec.end(), 0,
    [](std::size_t sum, const std::string& s) {
      return sum + s.size();
    });
  return length + vec.size();
}

template<size_t N>
constexpr std::array<char, N+1> join_to_array(const std::vector<std::string>& vec, char delimiter) {
  std::string result = std::accumulate(std::next(vec.begin()), vec.end(),
    vec[0],
    [&delimiter](const std::string& a, const std::string& b) {
      return a + delimiter + b;
    });
  std::array<char, N+1> arr = {};
  int i = 0;
  for (auto c : result) {
    arr[i++] = c;
  }
  return arr;
}
constexpr std::vector<std::string> getWords() {
  return { "one", "two", "three" };
}

int main()
{
  constexpr auto arr2 = join_to_array<join_length(getWords(), ';')>(getWords(), ';');
  static_assert(std::string(&arr2[0]) == "one;two;three");
  std::cout << &arr2[0] << "\n";
}

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