Given the constraints at hand (that you're basically stuck walking the list in reverse), it's probably best to build the string in reverse as well, then when all the characters have been added, reverse the string.
The way you're doing things right now you're getting quadratic complexity -- every time you insert another character, put that character into a string, the copy all the existing characters to the new string, so each insertion is linear and N insertions is roughly O(N2).[Note: actually, I'd misread the code -- it's bad, but not quite this bad] As it is right now, we can expect every character to be copied at least twice -- once to the stack, and once to the destination string. The inefficiency is probably most apparent if you think in terms of memory bandwidth. At bare minimum, each call has to read a pointer, write the current character to the stack and write a return address, all to copy one byte from the linked list to the destination string. Assuming a 64-bit implementation, we're looking at a ratio of something like 18:1 in terms of reading and writing pointers (and other overhead) vs. copying the data we actually care about.
By building the string backward, then reversing it, you add new characters at the end of the string, where you can expect it to happen quickly. Then you do all that extra moving only once instead of once for every character you add.
If you were using
std::vector<char>, you could state categorically that adding a character at the end of the string was amortized constant complexity. With
std::string we don't (that I recall) get a complexity guarantee, but it would take an amazingly terrible implementation for it to be as bad as a recursive call just to copy one character.
Another possibility would be to use an
std::deque<char> instead of a
string. With a deque, you can insert characters at the front without moving all the other characters to make room. This does have two shortcomings: the result isn't (normally) a contiguous block of memory, and you typically get an extra level of indirection, so access to the data after it's built is marginally slower.