In a line like this:
const char *some_file = load_file("some_file").c_str();
load_file() returns a temporary
std::string, and then
.c_str() is called on this temporary.
When the temporary is alive, the pointer returned by
.c_str() points to some meaningful string. But when the temporary "evaporates" (at the semicolon), then that same pointer is pointing to garbage.
The "garbage" may be the same string that the previous call to
load_file() returned, so you have the effect that both raw pointers point to the same string.
But this is just a coincidence.
And your code has a bug.
String classes like
std::string were invented as a convenient way to simplify the C++ programmer's life instead of using raw C string pointers. So, just use
std::strings if you want to safely manage strings in C++.
.c_str() just at the boundary with C functions (including
So, you can refactor your code like this:
// load_file() returns a std::string, so just keep using std::string.
// Note that returning std::string is efficient thanks to RVO/NRVO
// and C++11 move semantics.
std::string some_file = load_file("some_file");
// Idem for this:
std::string another_file = load_file("another_file");
// Convert from std::string to raw C string pointers at the C boundary
Even some code like this would work fine:
In fact, note that in this case, even if you are using a temporary (i.e. the strings returned by
load_file() are not copied to named
std::string variables), the temporary is valid during the
printf() call, so the raw pointer returned by
.c_str() points to a valid string while
printf() is doing its printing job.