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After a debug session I realised that the next sample code compile with no warnings (g++-4.7.2 -Wextra and -Wall)

char *p;
char *q = std::move(p);
*p = 'p';
*q = 'q';

I'm a bit shocked, and I have three questions about it.

1- Am I missing something about move semantics and there is a reason for not issuing a warning in this situation, or is gcc's checking not good enough?

2- Should the next code throw a warning?

char c = 'c';
char *p = &c;
char *q = std::move(p);
*p = 'p';

As far I understand, after std::move(p) p can hold any value, therefore once p is moved is like an uninitialized variable.

3- Can other tools/compilers check these errors?

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2 Answers 2

up vote 1 down vote accepted

1- I'm missing something about move semantics and there is a reason for no throw a warning in this situation, or gcc checking is not good enough?

The code is wrong, so a warning would be good. G++ isn't smart enough to "see through" the call to std::move. It's valid to pass an uninitialized variable by reference to a function (that function might initialize the variable) so calling std::move itself doesn't trigger a warning. Because q gets assigned a value, it appears to be initialized to the compiler.

If I turn on optimization so that G++ inlines the call to std::move then I get an error from G++ 4.7:

f.cc: In function ‘int main()’:
f.cc:6:9: warning: ‘p’ is used uninitialized in this function [-Wuninitialized]

This is because the call to std::move is no longer "opaque" to the compiler, when it analyses the inlined code it can see that p never gets assigned a value. The compiler still isn't smart enough to see that q never gets a good value, the cast inside std::move probably confuses the compiler.

2- The next code should throw a warning?

No. std::move doesn't alter fundamental types such as pointers, so the value of p will not be changed. The standard library says that objects are left in a "valid but unspecified" state after being moved from, because the standard doesn't generally define the exact behaviour of a move constructor or move assignment operator, but for fundamental types such as int and char* there is no move constructor. std::move(p) just casts the object to an rvalue, it doesn't alter it, and initializing q with the value doesn't alter it either - it just copies the value.

3- Other tools/compilers can check these errors?

Clang and ICC fail to warn about the first example even with optimization on.

Note that although warnings are very useful, compilers are not perfect and it is impossible to warn about all unsafe code. You should not be totally surprised when unsafe code doesn't get a warning (maybe open a bug report for the compiler to request it be improved) -- it doesn't mean the code is OK. Absence of warnings does not imply absence of bugs.

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But in this case is a "rvalue reference", in what situation would you pass an uninitialized value? (For avoid calling a ctor when you know that pass a uninitialized is ok?) –  user1476999 Jan 19 '13 at 22:51
    
No, you cannot "avoid calling a constructor" for an object with a constructor. You might do int val; init(val); to give val a value. The compiler assumes after a call to a function that might modify the object it might have a good value. Not making that assumption would give false warnings in correct code. Also, in this case you do not pass an rvalue reference to std::move, you pass an lvalue. The return is an rvalue, not the argument. –  Jonathan Wakely Jan 19 '13 at 22:55

The move constructor of a pointer is trivial, which means it is the same as its copy constructor: copying the value. So as far as C++11 is concerned, this will copy pointers around. In your first case, it's copying uninitialized pointers around.

Now, if those were std::unique_ptr objects, it would not be correct code. But there's no reason to expect the compiler to warn about it, as there's no way for the compiler to be certain that a moved-from object cannot have operator* called on it.

In general, the standard library states that objects which have been moved-from are left in a valid but undefined state. For example, this is perfectly legal:

std::vector<int> src = ...;
std::vector<int> dest = std::move(src);
src.assign(...);

std::unique_ptr is different in that it specifies exactly what state the moved-from object is left it. But the compiler cannot assume that for any type. It can't assume that an object is left in an invalid state where any particular function call must fail.

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In the first example p is uninitialized –  Jonathan Wakely Jan 19 '13 at 22:43
1  
@JonathanWakely: Fair enough. –  Nicol Bolas Jan 19 '13 at 22:45

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