For fundamental types,
a = a + b and
a += b mean the same thing.
For arbitrary class types,
a = a + b and
a += b are unrelated; they look up different operators, and those operators can do arbitrary things. Them being actually unrelated is code smell, a sign of a design problem.
a = a + b becomes
operator=( a, operator+( a, b ) ) roughly; the actual lookup rules are a bit more complex (involving member operators and non-member operators, and the fact that
= doesn't have a non-member operator, etc), but that is the core of it.
a += b becomes
operator+=( a, b ) in a similar sense.
Now, it is a common pattern to implement
+ in terms of
+=; if you do this, you get:
a = a + b
a = ((auto)(a) += b);
(auto) is the new c++20/c++23 "create a temporary copy of the argument" feature.
a+=b can reuse the contents of
a directly, while
a = a + b cannot; at the moment
a+b is evaluated, it doesn't know that
a will be soon overwritten.
Some libraries deal with this using a technique known as "expression templates";
a+b isn't a value, but rather a compile-time description of the expression
a+b, which when assigned to
a is actually used to populate
a with data. With expression templates, the fundamental issue of
a+=b knowing more than
a=a+b is eliminated.
a+b creates a temporary string object, then
a=(a+b) moves that into
a (it can reuse the buffer of the temporary string object or the buffer of
a, the standard is silent on this matter).
a+=b must reuse any excess capacity in the
a buffer. So if you
a.reserve(1<<30) (1 billion),
a+=b cannot allocate more.