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I was working on some template code this morning where I used a BOOST_STATIC_ASSERT to ensure I wasn't creating a reference to the wrong type, as I thought it might be a clearer error message. However when I tried removing the static assert to take a look at the alternative compiler error I was shocked to discover that gcc doesn't even complain when you try to make a const double& referring to an int:

#include <iostream>

int main()
    int x = 5;
    const double& y = x;
    std::cout << y << std::endl;

    return 0;

Compiles, and doesn't even warn:

$ g++ ~/stuff/badRef.cpp -Wall -Wextra -pedantic
$ a.out

What's going on here? Is this undefined behaviour? If so why doesn't gcc complain? On my machine int is 4 bytes and a double is 8. That means that when printing a double& it should interpret 8 bytes at that address as a double and print it, yet there is actually a 4 byte int at that location.

Very confused. Help!

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Which version of GCC? – Milan Babuškov Feb 2 '12 at 23:13
It's version 4.3.3. – voltrevo Feb 2 '12 at 23:32
What happens when you add x = 42; after const double& y = x;? It might be curious/unexpected at first sight. – moala Feb 3 '12 at 10:10
up vote 21 down vote accepted

const double& y = x; creates a temporary double with the value static_cast<double>(x), then binds that temporary to y. The lifetime of the temporary is extended to match the lifetime of y.

This is completely legal C++ (03 and 11), hence the lack of warning/error.

share|improve this answer
Awesome. I actually figured it out just before your answer by looking at what happens when you increment x, then print y. It didn't change so I thought - "of course! it binds to a temporary!". Also, gcc accepts it with -std=c++98 too, so I'm guessing it's valid C++98 too? – voltrevo Feb 2 '12 at 23:31
@Mozza314 : "I'm guessing it's valid C++98 too?" Yes; I don't have a copy of that particular standard on hand, but I'm fairly certain that's not one of the things that was added in C++03. Keep in mind, though, that -std=c++98 actually enforces C++03 rules, not C++98 rules, argument name not withstanding. – ildjarn Feb 2 '12 at 23:32
I don't get it... why would you ever do const double& when binding to a temporary instead of const double? – Mehrdad Feb 2 '12 at 23:40
@Mehrdad : I don't believe there's any practical use for this, but it is legal. – ildjarn Feb 2 '12 at 23:41
@Mozza314 : Indeed, I was referring to the context of doing this with a local (non-argument) variable. Knowing how the behavior is defined in the more common scenarios (e.g. argument passing) is definitely a good thing. :-] – ildjarn Feb 2 '12 at 23:46

it's well defined and legal. y refers to a temporary. consider also when you pass parameters:

void foo(const int& p);

Note also that this is not valid C++ if the reference is not const. VS 6 got that wrong and allowed binding a mutable reference to a temporary. This applies only to const references.

share|improve this answer

const T& can bind to a temporary, so x is being converted to double and the copy is bound to y. If you check, you’ll see that &x != &y. The reason for this behaviour is to allow passing literals to functions that take their parameters by const reference.

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Well, not "copy is stored", y binds to the temporary resulting from the conversion, because it's a const lvalue reference. – Cat Plus Plus Feb 2 '12 at 23:15
@CatPlusPlus: Replaced “stored in” with “bound to” to—well, if not to clarify, then at least to be pedantically correct. :P – Jon Purdy Feb 2 '12 at 23:21

This is a good example for those who think that pointers and references are the same.

double const*const y2 = &x;

bad.cpp:7:30: error: cannot convert ‘int*’ to ‘const double* const’ in initialization

The reason it works for references is explained in the other posts.

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