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
becomes
a = ((auto)(a) += b);
where (auto)
is the new c++20/c++23 "create a temporary copy of the argument" feature.
Fundamentally, 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.
Now, for std::string
specifically, 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.
fans
is an std::string ands[i]
is a char? Or is it another string containing a single character?fans
ands[i]
are, but actually it would be better if you edited your question and added a full program (minimal reproducible example) that we can copy and compile. Just check the links that you've been given. It won't take long, and it will improve your question significantly. Thank you!