Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Is it possible to create a constructor (or function signature, for that matter) that only accepts a string literal, but not an e.g. char const *?

Is it possible to have two overloads that can distinguish between string literals and char const *?

C++ 0x would kind-of allow this with a custom suffix - but I'm looking for an "earlier" solution.

Rationale: avoiding heap copy of strings that won't be modified when given as string literals.

These strings directly go to an API expecting a const char * without any processing. Most calls do use literals requiring no additional processing, only in a few cases they are constructed. I am looking for a possibility to preserve the native call behavior.

Note: - since it comes up in the answers: the code in question does not use std::string at all, but a good example would be:

class foo
   std::string m_str;
   char const * m_cstr;      
   foo(<string literal> s) : m_cstr(p) {}
   foo(char const * s) : m_str(s) { m_cstr = s.c_str(); }
   foo(std::string const & s) : m_str(s) { m_cstr = s.c_str(); }

   operator char const *() const { return m_cstr; }


(1) it can't be done.
(2) I realized I am not even looking for a literal, but for a compile-time-constant (i.e. "anything that needs not be copied").

I will probably use the following pattern instead:

const literal str_Ophelia = "Ophelia";

void Foo()
  Hamlet(str_Ophelia, ...);  // can receive literal or string or const char *

with a simple

struct literal  
   char const * data; 
   literal(char const * p) : data(p) {} 
   operator const char *() const { return data; }

That doesn't stop anyone from abusing it (I should find a better name...), but it allows the required optimization but remains safe by default.

share|improve this question
I don't think so, since string has a constructor that takes a char const *. –  Dominic Rodger Jan 11 '10 at 11:06
Could you elaborate on the rationale? I can't quite see why you would wish to copy a string literal, but NOT copy a 'const char *' (or the other way around). You aren't allowed to change both in exactly the same way. –  Hexagon Jan 11 '10 at 11:28
You will also have to maintain a flag and have conditional code in your destructor. It seems you would have to create a lot more objects using string literals than I usually do to make this worthwhile. –  anon Jan 11 '10 at 11:34
Why not take a string&? –  ypnos Jan 11 '10 at 11:51
@Neil: I'm stumbling over this pattern repeatedly, in different scenarios. I agree that in most places, the copy doesn't matter - but when writing libraries, you don't know if you are called 10 times or 10 million times. –  peterchen Jan 11 '10 at 14:31

6 Answers 6

up vote 9 down vote accepted

No, you just can't do this - string literals and const char* are interchangeable. One workaround could be to introduce a special class to hold pointers to string literals and make a constructor only accepting that. This way whenever you need to pass a literal you call a constructor of that class and pass the temporary object. This doesn't completely prevent misuse, but makes code much more maintainable.

share|improve this answer
Is this still true for C++14? Hmm, maybe user defined literals could be used? en.cppreference.com/w/cpp/language/user_literal –  panzi May 12 '14 at 1:38

If you know exactly how your compiler and platform deal with string literals, it might be possible to write a solution that can do this. If you know that your compiler always puts string literals into a specific region of memory, you can check the pointer against the bounds of that memory. If it falls within that block, you've got a string literal; otherwise you've got a string stored on the heap or stack.

However, this solution would be platform/compiler-specific. It would not be portable.

share|improve this answer
probably the only "safe" way to do that, but I don't want to rely on that much unportable trickery. Anyway, thanks! –  peterchen Jan 11 '10 at 17:12

Working solution based on sbi idea:

struct char_wrapper
    char_wrapper(const char* val) : val(val) {};
    const char* val;

class MyClass {
  template< std::size_t N >
  explicit MyClass(const char (&str)[N])
      cout << "LITERAL" << endl;
  template< std::size_t N >
  explicit MyClass(char (&str)[N])
      cout << "pointer" << endl;
  MyClass(char_wrapper m)
     cout << "pointer" << endl;

int main()
    MyClass z("TEST1");     // LITERAL
    const char* b = "fff";
    MyClass a(b);           // pointer
    char tmp[256]; 
    strcpy(tmp, "hello"); 
    MyClass c(tmp);         // pointer
share|improve this answer
@Downvoter: Care to comment? Which bit do you disagree with? –  Kirill V. Lyadvinsky Jan 11 '10 at 13:19
Probably the fact that it doesn't work - it recognises character arrays as string literals for a start. –  Joe Gauterin Jan 11 '10 at 13:47
+1: Its not possible to differentiate between "const char []" and a string literal, so this is the optimal solution. –  Richard Corden Jan 12 '10 at 9:16
In C++03 you can keep them apart by checking whether they convert to both char* and const char[]: If they do, it's a string literal, if they don't, it's a plain array. But in C++0x, they removed the deprecated conversion from a string literal to char*, thus this hack won't work anymore then :) –  Johannes Schaub - litb Jan 14 '10 at 15:57
@Johannes: That's a use of that particular conversion I'm sure nobody ever envisaged! –  Richard Corden Jan 19 '10 at 18:46

On some platforms, I have had to declare string literals as static const char * in order for the program to access the text from Read-Only Memory. When declared as const char *, the assembly listing showed that the text was copied from ROM onto a stack variable.

Instead of worrying about the receiver, perhaps try declaring the string literals with static const char *.

share|improve this answer

With a new user-defined literals in C++14 (as for Clang 3.5 - it works with C++11 too), there is an elegant solution:

class Literal {
  explicit Literal(const char* literal) : literal_(literal) {}
  // The constructor is public to allow explicit conversion of external string
  // literals to `_L` literals. If there is no such need, then move constructor
  // to private section.

  operator const char* () { return literal_; }

  friend Literal operator"" _L (const char*, unsigned long);
  // Helps, when constructor is moved to private section.

  const char* literal_;

Literal operator"" _L (const char* str, unsigned long) {
  return Literal(str);

It may be used like this:

void f1(Literal) {}  // Accepts literals only.

int main() {
  auto str1 = "OMG! Teh Rey!"_L;
  std::cout << str1 << std::endl;

There is one drawback: you have to append _L to every literal - but it's not a big deal, really.

share|improve this answer

Yes, it can be done! I came up with a solution that works with C++03 and without a wrapper class (which breaks some implicit conversions in return statements).

First of all, you need a constructor template for the types const char (&)[N], since this is the original type of string literals. Then you also need another one for the types char (&)[N] - like char buffers for instance - so that they con't end up in the constructor for literals. And probably you also want a normal constructor for the type const char*.

template<int N> Foo(const char (&)[N]); // for string literals
template<int N> Foo(char (&)[N]);       // for non-const char arrays like buffers
Foo(const char*);                       // normal c strings

The problem now is, that for string literals the compiler still thinks, that the const char* constructor is a better choice than a template instance, since array-to-pointer conversions have exact-match rank. (

So, the trick is to lower the precedence of the const char* constructor. This can be done by changing it to a template as well and using SFINAE to match it only against the type const char*. The constructor has no return value and only one parameter, that is necessary for type deduction. Therefore another "dummy parameter" with default value is necessary, that uses the conditional type trait: template<typename T> Foo(T, typename IsCharPtr<T>::Type=0)


#include <iostream>

#define BARK std::cout << __PRETTY_FUNCTION__ << std::endl

struct Dummy {};
template<typename T> struct IsCharPtr {};
template<> struct IsCharPtr<const char *> { typedef Dummy* Type; };
template<> struct IsCharPtr<char *> { typedef Dummy* Type; };

struct Foo {
  template<int N> Foo(const char (&)[N]) { BARK; }
  template<int N> Foo(char (&)[N]) { BARK; }
  template<typename T> Foo(T, typename IsCharPtr<T>::Type=0) { BARK; }

const char a[] = "x";
const char* b = "x";
const char* f() { return b; }

int main() {
  char buffer[10] = "lkj";
  char* c = buffer;
  Foo l("x");     // Foo::Foo(const char (&)[N]) [N = 2]
  Foo aa(a);      // Foo::Foo(const char (&)[N]) [N = 2]
  Foo bb(b);      // Foo::Foo(T, typename IsCharPtr<T>::Type) [T = const char *]
  Foo cc(c);      // Foo::Foo(T, typename IsCharPtr<T>::Type) [T = char *]
  Foo ee(buffer); // Foo::Foo(char (&)[N]) [N = 10]
  Foo ff(f());    // Foo::Foo(T, typename IsCharPtr<T>::Type) [T = const char *]
  return 0;
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.