Consider this code:
struct foo
{
int a;
};
foo q() { foo f; f.a =4; return f;}
int main()
{
foo i;
i.a = 5;
q() = i;
}
No compile
One interesting application of this:
void f(const std::string& x);
std::string g() { return "<tag>"; }
...
f(g() += "</tag>");
Here, g() +=
modifies the temporary, which may be faster that creating an additional temporary with +
because the heap allocated for g()'s return value may already have enough spare capacity to accommodate </tag>
.
See it run at ideone.com with GCC / C++11.
Now, which computing novice said something about optimisations and evil...? ;-].
Because structs can be assigned to, and your q()
returns a copy of struct foo
so its assigning the returned struct to the value provided.
This doesn't really do anything in this case thought because the struct falls out of scope afterwards and you don't keep a reference to it in the first place so you couldn't do anything with it anyway (in this specific code).
This makes more sense (though still not really a "best practice")
struct foo
{
int a;
};
foo* q() { foo *f = new malloc(sizeof(foo)); f->a = 4; return f; }
int main()
{
foo i;
i.a = 5;
//sets the contents of the newly created foo
//to the contents of your i variable
(*(q())) = i;
}
No, the return value of a function is an l-value if and only if it is a reference (C++03). (5.2.2 [expr.call] / 10)
If the type returned were a basic type then this would be a compile error. (5.17 [expr.ass] / 1)
The reason that this works is that you are allowed to call member functions (even non-const
member functions) on r-values of class type and the assignment of foo
is an implementation defined member function: foo& foo::operator=(const foo&)
. The restrictions for operators in clause 5 only apply to built-in operators, (5 [expr] / 3), if overload resolution selects an overloaded function call for an operator then the restrictions for that function call apply instead.
This is why it is sometimes recommended to return objects of class type as const
objects (e.g. const foo q();
), however this can have a negative impact in C++0x where it can inhibit move semantics from working as they should.