Why can I use operator= but not operator== with C++11 brace-initializers?

Question

See this example:

struct Foo
{
    int a;
    int b;

    bool operator == (const Foo & x)
    {
        return a == x.a && b == x.b;
    }
};

int main ()
{
    Foo a;

    a = {1, 2};

    if (a == {1, 2}) // error: expected primary-expression before ‘{’ token
    {
    }
}

The line a={1,2} is fine. The braces are convert to a Foo to match the argument type of the implicit operator= method. It still works if operator= is user-defined.

The line if (a=={1,2}}) errors as indicated.

Why does the expression {1,2} not convert to a Foo to match the user-defined operator== method?

Answer 1

List-initialization cannot be used as an argument to an operator in the general case. Per Paragraph 8.5.4/1 of the C++11 Standard:

[...] List-initialization can be used

— as the initializer in a variable definition (8.5)

— as the initializer in a new expression (5.3.4)

— in a return statement (6.6.3)

— as a for-range-initializer (6.5)

— as a function argument (5.2.2)

— as a subscript (5.2.1)

— as an argument to a constructor invocation (8.5, 5.2.3)

— as an initializer for a non-static data member (9.2)

— in a mem-initializer (12.6.2)

— on the right-hand side of an assignment (5.17)

The last item explains why list-initialization is allowed on the right side of operator =, even though it is not allowed in general for an arbitrary operator.

Because of the fifth item above, however, it can be used as an argument to a regular function call, this way:

if (a.operator == ({1, 2}))

Answer 2

It's just simply not supported.

Initializer lists are explicitly defined to be valid in initializations ([C++11: 8.5.4]), and assignments:

[C++11: 5.17/9]: A braced-init-list may appear on the right-hand side of

• an assignment to a scalar, in which case the initializer list shall have at most a single element. The meaning of x={v}, where T is the scalar type of the expression x, is that of x=T(v) except that no narrowing conversion (8.5.4) is allowed. The meaning of x={} is x=T().
• an assignment defined by a user-defined assignment operator, in which case the initializer list is passed as the argument to the operator function.

There is no standard wording to allow other, arbitrary cases.

If it were allowed, in this example, the type of {1,2} would be fairly ambiguous. It would be a complicated language feature to implement.

Answer 3

An explicit cast is required.

if (a == (Foo){1, 2})
{
}

Answer 4

When you are using the expression containing the user defined type a and == operator Overloaded operator function gets called which as per definition you have given requires an argument of a reference of an object of class Foo

so your expression should be like a==b

where b is an object of class Foo

Here with this expression you will be able to compare data members of b and a and hence know if they are equal or not

Answer 5

No real reason.

C++ is the result of a committee effort so sometimes strange but deliberate decisions may slip through because of complex political/sociological dynamics.

C++ syntax is hard. Very hard. Almost unbelievably hard. There are rules even go like "if you can parse this arbitrarily long sequence of tokens as both this or that, then it's this".

It took many years for compilers even to simply agree on what is C++ and what is not.

In this case my wild guess is that they didn't like the idea that cases that looked very similar:

MyClass x = {...};
MyClass y; y = {...};

would be handled differently so there is a special provision for assignment to allow the syntax.

From a technical point of view I don't see what are the problems of allowing it for other operators too, and on the other hand if there are problems (e.g. for overloading, template instantiation etc.) I don't see how assignment can hope to escape them.

EDIT

g++ allows using not only strict operator= but also operator+=, operator-= and similar "augmented assignment". May be the logical problems happens only if you allow non-member overloads (that are forbidden for assignment and augmented assignment operators).