(pondering on a Sunday evening)
In the functions I write I tend to rely on both
const char* and templated inline
const std::basic_string<>& variants of the same string. But I'm really curious why the
c_str() of an empty string is not a
Most C++ coders now disregard
const char* pointers as C code but I see it very C++ as strings are
null terminated and continuous and will continue to be this way. But if you use custom allocators, then all the code you write with
const std::string& arguments is pointless (unless header only).
So your real choice (if you want to be versatile) is either old-school character pointers or inline templated functions that can support all sorts of
std::basic_string with custom allocators or traits. This forces you to inline the templated functions as you cannot predict the template arguments upfront correctly.
Now my question is: Why don't empty strings return nullptr for c_str()? As the lowest common denominator in string functions, especially for read-only access is the
const char* not the
const std::string& which is templated hence constrained. Returning a pointer to anything, especially when there's not string assignment made... seems to me as weird.
Or am I too much of a maniac to do this? Always worry about both
const char* and the templated
const std::basic_string<char, ..., ...>& counterpart. If
nullptr, I wouldn't worry. But I have to guard against empty strings myself as
c_str() is unreliable on
PS: I know that old school string functions crash when used with null pointers, but one can easily test for a valid pointer and a non-empty first char before using the string anywhere.
PPS: I'm talking here of sane null-terminated strings, not the null-containing pseudo-strings that the
std::basic_string peculiarly supports.
QUESTION REPHRASED: Why does
std::string().c_str() point to memory when it should not? It should be
std::string().c_str("") which is an empty string and requires a
\0 trailing it. So it actually points to valid memory. (If you don't understand how strings/pointers work, don't bother answering. This requires a bit of C-like understanding.)