I use references. That allows the implementor to make and abstract the choice, without taxing the client heavily (some cases matter, some will not).
I also use them for consistent style - I don't like seeing public interfaces that pass by details of their implementation.
The transients and copies can be expensive - it varies greatly by the type you are passing. To return by value indicates the type should be trivially constructible, swappable, copyable, movable. The compiler can make some great optimizations in this area (RVO/move), but you can also make informed decisions to minimize expensive operations in your implementations. Once you're no longer using types everybody knows the copy characteristics for, then choosing how to return becomes very complex, so I just keep it simple and favor references.
Passing a reference has a few other benefits, such as when the client prefers to use a subclass of the type that is passed.
Another benefit if you need an optimized program: I will often delete the copy ctor and
operator= if they are not trivial or possible. Passing by mutable reference allows you to work with types which are not copy/assignable.
In the strict scope of
std::string used in this question: Returning a
std::string by value is quite common, and many optimizations have been made specifically for this case - RVO, COW, and moves are some notable ones. As Voo mentioned in the comments below, returning by value is often easier to read. In the case of
std::string and higher level programs, returning by value is not likely to be an issue, but it's important to measure in order to understand the costs involved for the standard library implementations you are using if performance is important (which your question suggests may be the case).
An important consideration is that if you are trying to improve upon an existing program, be sure you understand how the implementation executes, and learn how you can use the types most effectively when performance is important. Implementations may be written and optimized for actual use, which means that they may be pessimistic and second guessing you in some cases, and your attempts to improve performance may already be implemented or unconventional use of the type may degrade performance. Typical resizing behaviour of a
std::vector is an obvious example. Taking the high performance road does add a lot of time and complexity regarding what you need to know to achieve the best results, and this obviously varies by implementations you use and also by the types you are using. If performance is critical and worth nontrivial time investments, learning the operation of the types you use is a worthwhile endeavor which can lead to significant gains.
I should also add that I work in the low levels quite often - Where performance is critical and/or resources are limited. There can be many restrictions, including no exceptions, no locks (also implies no heap allocations), minimal abstraction costs, and even restricted use of dynamic polymorphism. It can be considered a fairly demanding domain, even for C++. I choose reference for the core low level pieces, but I will relax that rule if I know a program will be used only in higher level domains or unit tests.