Can I achieve linear (or close to) complexity concatenating strings without allocation?

Question

{
   std::string s = "this is a string ";
   std::string res = std::string();
   int sLength = s.length();
   for(int i = 0; i < sLength; i++)
      res += s[i];
}

I would imagine this C++ is strictly linear in complexity (with regard to character allocation), as opposed to the quadratic complexity of the equivalent in C#.

However, the fact that in this case, memory is not allocated beforehand, are we actually looking at quadratic complexity as well ? If yes, would allocation of a char array help us to achieve linear complexity ?

Answer 1

You could achieve linear complexity by calling std::string::reserve. This would prevent re-allocations as the string grows:

std::string s = "this is a string ";
std::string res = "what is this? ";
res.reserve(s.length() + res.length());

for(int i = 0; i < s.length(); i++)
   res += s[i];

Obviously you wouldn't concatenate strings like that in real life.

Answer 2

According to cppr, adding a character to a string has constant complexity (although I think this carries an implicit "amortized", as for string::push_back).

So your code already has linear complexity.

If you care about the allocation cost and have an upper bound for the size beforehand, you can also just reserve enough space to avoid any reallocation and copying of the string. Then, not even a plain char buffer should beat your performance (significantly).