Ways to distinguish string literal and runtime generated string

Question

Suppose I have a function that takes a string as input:

SomeOutputType f_impl(const char* s);

Most call sites just use string literals as input, e.g. f("Hello, world"). Suppose I have implemented the following function to compute the result at compile time

template <char...> SomeOutputType f_impl();

My question is, is there a way to let the call sites like f("Hello, world") calls the templated form, while for general call sites like string s="Hello, world"; f(s.c_str()); calls the general form? For clarification, auto s = "Hello, world"; f(s); don't have to call the templated form because s is now a variable and no longer a compile time constant.

A useful case for this question is to optimize printf. In most cases the format will be string literals so a lot of things can be done at compile time to optimize things, instead of parsing the format at runtime.

Answer 1

No, a string literal like "foo" has the type const char[S + 1] where S is the number of characters you wrote. It behaves like an array of that type with no special rules.

In C++03, there was a special rule that said that a string literal could convert to char*. That allowed you to say

#define isStringLiteral(X) \
  isConvertibleToCharStar(X) && hasTypeConstCharArray(X)

For example isStringLiteral(+"foo") would yield false, and isStringLiteral("foo") would yield true. Even this possibiliy would not have allowed you to call a function with a string literal argument and behave differently.

C++11 removed that special conversion rule and string literals behave like any other arrays. In C++11 as a dirty hack you can compose some macros, matching some simple string literals without handling escape sequences

constexpr bool isStringLiteral(const char *x, int n = 0) {
  return *x == '"' ? 
           n == 0 ?
             isStringLiteral(x + 1, n + 1)
             : !*(x + 1) 
           : (*x && n != 0 && isStringLiteral(x + 1, n + 1));
}

#define FastFun(X) \
  (isStringLiteral(#X) ? fConstExpr(X, sizeof(X) - 1) : f(X))

Answer 2

While I haven't tested this, I think if you just declare the function constexpr and compile with high optimization, the compiler will compute at compile time whenever possible. As a bonus, you don't need to write the code twice. On the other hand, you have to write it once in constexpr style.

Answer 3

If I understand the question correctly, I actually think something like this is possible using a function overload. Here's an article that shows the basic idea. In your case I think it would be sufficient to have the following two overloads:

void f(char const *);

template<unsigned int N>
void f(char const (&)[N]);

The latter should be invoked when the string is a string literal, the latter at other times. If the compiler is sufficiently good at optimizing then calls to the latter may be evaluated at compile time.

EDIT:

Alright, it bothered me that the above solution didn't work, so I did some playing around and I think I came up with a solution:

#include <string>
#include <boost/utility/enable_if.hpp>

template<typename T>
struct is_string_literal {
  enum { value = false };
};

template<unsigned int N>
struct is_string_literal<char const (&)[N]> {
   enum { value = true };
};

template<typename T>
typename boost::disable_if<is_string_literal<T> >::type
foo(T) {
  std::cout << "foo1" << std::endl;
}

template<int N>
void foo(char const (&)[N]) {
  std::cout << "foo2" << std::endl;
}

int main( ) {
  std::string bar = "blah";
  char const str[] = "blah";

  foo(str);
  foo("blah");

  foo(bar.data());
}

The output (on GCC 4.4 with -O3) is:

foo2
foo2
foo1

I admit that I don't completely understand why this works when the previous solution didn't. Maybe there's something about overload resolution that I don't completely understand.