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According to C++ Standard it's okay to cast away const from the pointer and write to the object if the object is not originally const itself. So that this:

 const Type* object = new Type();
 const_cast<Type*>( object )->Modify();

is okay, but this:

 const Type object;
 const_cast<Type*>( &object )->Modify();

is UB. The reasoning is that when the object itself is const the compiler is allowed to optimize accesses to it, for example, not perform repeated reads because repeated reads make no sense on an object that doesn't change.

The question is how the compiler would know which objects are actually const. For example I have a function:

void function( const Type* object )
    const_cast<Type*>( object )->Modify();

and it is compiled into a static lib and the compiler has no idea for which objects it will be called.

Now the calling code can do this:

Type* object = new Type();
function( object );

and it will be fine, or it can do this:

const Type object;
function( &object );

and it will be undefined behavior.

How is compiler supposed to adhere to such requirements? How it is supposed to make the former work without making the latter work?

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Why do you make a promise if you intend to break it right away? const is a promise from the programmer to the compiler (and a contract that other programmers reusing the component agree on), no more and no less. The compiler may or may not do something differently according to that promise, but that is circumstantial. Now, the thing is, if something is not constant, you should not give that promise in the first place. –  Damon Dec 16 '11 at 10:28
@Damon: In real life one party writes the function, the other writes the calling code and they can't affect each other. –  sharptooth Dec 16 '11 at 10:37
@Daemon There are case where you do keep the promise -- that is, the object is unchanged when the function ends -- but you make temporary changes to it during execution, for various reasons. –  Paul Manta Dec 16 '11 at 10:46

4 Answers 4

up vote 1 down vote accepted

When you say "How it is supposed to make the former work without making the latter work?" an implementation is only required to make the former work, it needn't - unless it wants to help the programmer - make any extra effort in trying to make the latter not work in some particular way. The undefined behavior gives a freedom to the implementation, not an obligation.

Take a more concrete example. In this example, in f() the compiler may set up the return value to be 10 before it calls EvilMutate because cobj.member is const once cobj's constructor is complete and may not subsequently be written to. It cannot make the same assumption in g() even if only a const function is called. If EvilMutate attempts to mutate member when called on cobj in f() undefined behavior occurs and the implementation need not make any subsequent actions have any particular effect.

The compiler's ability to assume that a genuinely const object won't change is protected by the fact that doing so would cause undefined behavior; the fact that it does, doesn't impose additional requirements on the compiler, only on the programmer.

struct Type {
    int member;
    void Mutate();
    void EvilMutate() const;
    Type() : member(10) {}

int f()
    const Type cobj;
    return cobj.member; 

int g()
     Type obj;
     return obj.member; 
share|improve this answer

Undefined behavior means undefined behavior. The specification makes no guarantees what will happen.

That doesn't mean it won't do what you intend. Just that you're outside of the boundary of behavior that the specification states should work. The specification is there to say what will happen when you do certain things. Outside of the protection of the spec, all bets are off.

But just because you're off the edge of the map does not mean that you will encounter a dragon. Maybe it'll be a fluffy bunny.

Think of it like this:

class BaseClass {};
class Derived : public BaseClass {};

BaseClass *pDerived = new Derived();
BaseClass *pBase = new Base();

Derived *pLegal = static_cast<Derived*>(pDerived);
Derived *pIllegal = static_cast<Derived*>(pBase);

C++ defines one of these casts to be perfectly valid. The other yields undefined behavior. Does that mean that a C++ compiler actually checks the type and flips the "undefined behavior" switch? No.

It means is that the C++ compiler will more than likely assume that pBase is actually a Derived and therefore perform the pointer arithmetic needed to convert the pBase into a Derived*. If it isn't actually a Derived, then you get undefined results.

That pointer arithmetic may in fact be a no-op; it may do nothing. Or it may actually do something. It doesn't matter; you are now outside of the realm of behavior defined by the specification. If the pointer arithmetic is a no-op, then everything may appear to work perfectly.

It's not that the compiler "knows" that in one instance it's undefined and in another it's defined. It's that the specification does not say what will happen. It may appear to work. It may not. The only times that it will work are when it is done properly in accord with the specification.

The same goes for const casts. If the const cast is from an object that was not originally const, then the spec says that it will work. If it's not, then the spec says that anything can happen.

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I can't agree about "all cases" - it's okay to cast away const if the object is not originally const. –  sharptooth Dec 16 '11 at 6:44
Where does the specification say that? Where does it say that you can cast away const if the object wasn't "originally" const? –  Nicol Bolas Dec 16 '11 at 7:04
This answer has a Standard reference stackoverflow.com/a/1542272/57428 - –  sharptooth Dec 16 '11 at 7:08
If casting away const was always undefined behavior, do you think the language would provide const_cast? –  Luc Touraille Dec 16 '11 at 9:03
Fair enough. Edited. –  Nicol Bolas Dec 16 '11 at 9:56

The compiler can perform optimization only on const objects, not on references/pointers to const objects (see this question). In your example, there is no way the compiler can optimize function, but he can optimize the code using a const Type. Since this object is assumed by the compiler to be constant, modifying it (by calling function) can do anything, including crashing your program (for example if the object is stored in read-only memory) or working like the non-const version (if the modification does not interfere with the optimizations)

The non-const version has no problem and is perfectly defined, you just modify a non-const object so everything is fine.

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The compiler can optimize function if it inlines the call, or creates a separate definition that must only be called for objects defined as const. Both possibilities are becoming more and more likely, nowadays even if function is defined in a separate translation unit. –  hvd Dec 16 '11 at 12:28
@hvd: you are right, I overlooked inlining since it is not really an optimization of function per se, but the possibility of having two versions of a function depending on the constness of the object given did not come to my mind and is very interesting. –  Luc Touraille Dec 16 '11 at 13:40

In theory, const objects are allowed to be stored in read-only memory in some cases, which would cause obvious problems if you try to modify the object, but a more likely case is that if at any point the definition of the object is visible, so that the compiler can actually see that the object is defined as const, the compiler can optimise based on the assumption that members of that object do not change. If you call a non-const function on a const object to set a member, and then read that member, the compiler could bypass the read of that member if it already knows the value. After all, you defined the object as const: you promised that that value wouldn't change.

Undefined behaviour is tricky in that it often seems to work as you expect, until you make one slight modification.

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