I search the stack overflow and people say it's stupid to modify temporary object, so binding temporary object to non-const lvalue reference is not allowed, like you can't pass a temporary object to a function with non-const lvalue reference.

Then why is temporary objects allowed to call non-const member function which has the potential to modify the object and do "stupid" things? You may say, "ha, that's allowed because we want to provide the programmer with some flexibility to do "stupid" things that are in fact not that stupid", which is the reason I can hardly buy because if I buy this excuse, I think that "binding temporary to non-const lvalue reference" can be justified using the same reason.

Thanks! I hardly find any relevant question here. They just told me it's an exception, but why we allow that exception?

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    Hope those who down vote my question give me a brief reason for it. Really appreciate your kindly guidance and help.
    – Han XIAO
    Jul 14 '18 at 12:03
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    Instead of describing a possible situation, better show us some actual code. That might be one reason. Here's a list of other possible reasons. Jul 14 '18 at 12:04
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    @Someprogrammerdude: show some code? For a philosophical question? This is an absolutely valid question, and if there is no clear answer for this, it could mean this design decision cannot be justified strongly.
    – geza
    Jul 14 '18 at 12:16
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    @HanXIAO: I'd say this: if a function has a non-const reference parameter, it is usually because it is an output parameter. So it is meaningless to use a temporary for this parameter, as the output will be lost. So in a lot of cases, it would be an error to use a temporary for a non-const reference parameter.
    – geza
    Jul 14 '18 at 12:20
  • @geza some code would help illustrate what the question is asking. It seems to me that the asker has a clear example in mind, but I for one do not see it. Including an example in code would help make sure everyone is on the same page regarding what is being asked.
    – JaMiT
    Jul 14 '18 at 12:32

You cannot bind a temporary to a non-const reference, but the rationale here is not to avoid accidental modification of a temporary. The rationale is that you don't want to silently miss modifying something you wanted to modify.

Imagine it's allowed, then:

void foo(double& x);
int y;
foo(y); //user wants to modify y, but instead a temporary is modified

In and of itself, modifying a temporary object is perfectly OK and often useful. There's no reason to disallow it.

  • Thanks! This reason open up my horizon. The devil here is the built-in implicit conversions. As for user-defined types, we can use explicit to avoid that if temporary to non-const reference is allowed.
    – Han XIAO
    Jul 14 '18 at 13:58
  • What about things like std::string s; s + s = s;? This is also a silent miss of modification, and it is allowed Nov 18 '19 at 16:53
  • @RomanGolyshev I don't understand the example. What exactly did the user want to modify here? Nov 19 '19 at 4:39
  • @n.'pronouns'm. my concern here is more about this: we cannot bind temporary object to non-const reference, but in the same time we can modify temporary object using its non-const methods. In my example, we accidentally assign something into temporary object (s + s = s). It looks like we are actually able to bind temporary object to non-const reference, but only if this object is bound through this (with help of a non-const method). In this case I can also say that I do not want to modify the object that will be destroyed as soon as the expression is executed, but the language allows that Nov 19 '19 at 7:58
  • @RomanGolyshev "we can modify temporary object using its non-const methods". Yes we can, this is by design. "we accidentally assign something into temporary object". It is not accidentally, the temporary object is before your very eyes. What else "s+s" could possibly be? In foo(y) the temporary object is not apparent, and this is the essential difference Nov 19 '19 at 8:08

Imagine you have a factory method, that returns, as recommended, a unique_ptr

std::unique_ptr<MyClass> createObject();

However you need a shared pointer to created object. So you write

std::shared_ptr<MyClass> mySharedObject{createObject().release()};

And you have just called a non-const method on a temporary object. I find it quite useful.

OK. I forgot that shared_ptr constructor accepts unique_ptr. However why forbid for example quick reading of a first line of file?

std::array<char, 140> line;
std::istream{"MyFile.txt"}.readline(line, line.size()-1);

Maybe more interesting is why binding non-const lvalue reference to temporary is forbidden? Non-const reference to lvalue parameter means output parameter. Allowing binding to temporary would lead to subtle bugs due to conversions. For example

void readShort(short & out)
   out = 7;

long var;

There is a temporary short created to match function parameter type. Now binding it to reference is forbidden. If you allow it, function would assign to temporary and then the result would be thrown away.


Could you also explain why binding temporary object to local non-const lvalue reference is not allowed?

Now there is one set of rules for binding references to objects, no matter if it is done during function call or local reference definition. Creating two different sets of rules depending on context would complicate (already very complicated) language and requires some justification. I guess no one yet came with request for such change that would convince standard committee.

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    This does show the sort of general situation where it might be useful, but note that std::shared_ptr<MyClass> mySharedObject{createObject()}; would actually do the same thing, via the shared_ptr constructor taking an rvalue unique_ptr.
    – aschepler
    Jul 14 '18 at 12:21
  • @aschepler OK, I added some other example. Creating a real world case might be too long. Jul 14 '18 at 12:57
  • @TadeuszKopec Thanks! Could you also explain why binding temporary object to local non-const lvalue reference is not allowed? Like myclass& ref = myclass{}? Why the cpp designer does not allow this to prolong the object's lifetime just as const lvalue reference does? I really appreciate it if you can point out the reason for this prohibition.
    – Han XIAO
    Jul 14 '18 at 13:15
  • @TadeuszKopec Thanks! I think I may find a reason why binding temporary to local non-const reference is not allowed without the reason of consistency. Could you check my answer to see if that make sense? Thanks!
    – Han XIAO
    Jul 15 '18 at 2:55

Just some add-up : reason why binding temporary to local non-const lvalue reference is not allowed.

First, please read my accepted answer.

Then, if binding temporary to local non-const lvalue reference is allowed, you may write the code like this :

void foo(double& x);
int& ref = 1;

And that's problematic for the same reason that my accepted answer provided.


OK, I am putting some additional materials here. The following materials are quoted from David Vandevoorde, Nicolai M. Josuttis, Douglas Gregor-C++ Templates_ The Complete Guide-Addison-Wesley (2017), C.2.1 The Implied Argument For Member Functions.

“An old special-case permits an rvalue to be bound to an lvalue reference to non-const type when that reference is the traditional implicit *this parameter”

struct S{
    void f1() {}//the old rule
    void f2() && {}
    void f3() & {}
int main()
    S().f1();//Here, I THINK const this is bound to non-const, thus allowing calling non-const member functions.(the comment here is not quoted from the book.)
    S().f3();//not okay
    return 1;

Use -std=c++11 compilation option. So, this means C++ designers have realized that the old rule of allowing temporary objects, which have implicit const this*, to call non-const member function is not so good. So in C++11 they introduced & and && suffixing function declaration.

But when it comes to the design philosophy of the old rule of allowing temporary objects calling non-const member function, I think it's not worth diving into this. C++ 11 has make an effort to "emend" this.(Or let programmer control this.)

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