ss.str() temporary is destroyed after initialization of
cstr2 is complete. So when you print it with
cout, the c-string that was associated with that
std::string temporary has long been destoryed, and thus you will be lucky if it crashes and asserts, and not lucky if it prints garbage or does appear to work.
const char* cstr2 = ss.str().c_str();
The C-string where
cstr1 points to, however, is associated with a string that still exists at the time you do the
cout - so it correctly prints the result.
In the following code, the first
cstr is correct (i assume it is
cstr1 in the real code?). The second prints the c-string associated with the temporary string object
ss.str(). The object is destroyed at the end of evaluating the full-expression in which it appears. The full-expression is the entire
cout << ... expression - so while the c-string is output, the associated string object still exists. For
cstr2 - it is pure badness that it succeeds. It most possibly internally chooses the same storage location for the new temporary which it already chose for the temporary used to initialize
cstr2. It could aswell crash.
cout << cstr // Prints correctly
<< ss.str().c_str() // Prints correctly
<< cstr2; // Prints correctly (???)
The return of
c_str() will usually just point to the internal string buffer - but that's not a requirement. The string could make up a buffer if its internal implementation is not contiguous for example (that's well possible - but in the next C++ Standard, strings need to be contiguously stored).
In GCC, strings use reference counting and copy-on-write. Thus, you will find that the following holds true (it does, at least on my GCC version)
string a = "hello";
assert(a.c_str() == b.c_str());
The two strings share the same buffer here. At the time you change one of them, the buffer will be copied and each will hold its separate copy. Other string implementations do things different, though.