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I understand that having a const method in C++ means that an object is read-only through that method, but that it may still change otherwise.

However, this code apparently changes an object through a const reference (i.e. through a const method).

Is this code legal in C++?

If so: Is it breaking the const-ness of the type system? Why/why not?

If not: Why not?

Note 1: I have edited the example a bit, so answers might be referring to older examples.

Edit 2: Apparently you don't even need C++11, so I removed that dependency.

#include <iostream>

using namespace std;

struct DoBadThings { int *p; void oops() const { ++*p; } };

struct BreakConst
{
    int n;
    DoBadThings bad;
    BreakConst() { n = 0; bad.p = &n; } 
    void oops() const { bad.oops(); }  // can't change itself... or can it?
};

int main()
{
    const BreakConst bc;
    cout << bc.n << endl;   // 0
    bc.oops();              // O:)
    cout << bc.n << endl;   // 1

    return 0;
}

Update:

I have migrated the lambda to the constructor's initialization list, since doing so allows me to subsequently say const BreakConst bc;, which -- because bc itself is now const (instead of merely the pointer) -- would seem to imply (by Stroustrup) that modifying bc in any way after construction should result in undefined behavior, even though the constructor and the caller would have no way of knowing this without seeing each others' definitions.

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This is somewhat off-topic, but void (void) is a deprecated construct since void () has done the same thing since C++98 and C99. –  moshbear Jun 18 '12 at 6:06
    
@moshbear: I have no idea what made me write that (backwards compatibility with C or something?!); fixed, thanks. :-) –  Mehrdad Jun 18 '12 at 6:07
3  
I like how your O:) smiley has a double meaning as a happy angel and a shocked horrified face, depending on which direction you read it from. –  Peter Olson Jun 18 '12 at 9:50
    
You may find more inputs here: stackoverflow.com/q/9939399/15161 (Similar kind of question that people doesn't like :) ) –  slashmais Jun 18 '12 at 10:48
    
Here is my question inspired by this stackoverflow.com/questions/11091385/… also it doesnt require another struct ;) –  acidzombie24 Jun 18 '12 at 21:33
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5 Answers

The oops() method isn't allowed to change the constness of the object. Furthermore it doesn't do it. Its your anonymous function that does it. This anonymous function isn't in the context of the object, but in the context of the main() method which is allowed to modify the object.

Your anonymous function doesn't change the this pointer of oops() (which is defined as const and therefore can't be changed) and also in no way derives some non-const variable from this this-pointer. Itself doesn't have any this-pointer. It just ignores the this-pointer and changes the bc variable of the main context (which is kind of passed as parameter to your closure). This variable is not const and therefore can be changed. You could also pass any anonymous function changing a completely unrelated object. This function doesn't know, that its changing the object that stores it.

If you would declare it as

const BreakConst bc = ...

then the main function also would handle it as const object and couldn't change it.

Edit: In other words: The const attribute is bound to the concrete l-value (reference) accessing the object. It's not bound to the object itself.

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1  
Would the same reasoning apply if, instead of making the anonymous method inside main, I said BreakConst() : fn([&]() { counter++; }), counter(0) { } in the constructor? In that case it looks like the method would be "in the context of the object", but I dunno... –  Mehrdad Jun 18 '12 at 6:29
1  
Heinzi: I would be interested to see some text from the Standard which supports your reasoning. –  Nawaz Jun 18 '12 at 6:31
1  
@Heinzi: I guess the problem I have with that reasoning is that if I migrate the lambda to the constructor, I could subsequently say const BreakConst bc;, which -- because bc itself is now const (instead of just the pointer) -- would seem to imply that modifying bc in any way after construction should result in UB, even though the constructor and the caller would have no way of knowing this without seeing each others' definitions. Is this correct? –  Mehrdad Jun 18 '12 at 6:38
1  
1  
@Heinzi Since no one else seems to have contradicted this: C++ very definitely does have const objects, and trying to modify one is undefined behavior (except for mutable members of the object). –  James Kanze Jun 18 '12 at 8:23
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You code is correct, because you don't use the const reference to modify the object. The lambda function uses completely different reference, which just happen to be pointing to the same object.

In the general, such cases does not subvert the type system, because the type system in C++ does not formally guarantee, that you can't modify the const object or the const reference. However modification of the const object is the undefined behaviour.

From [7.1.6.1] The cv-qualifiers:

A pointer or reference to a cv-qualified type need not actually point or refer to a cv-qualified object, but it is treated as if it does; a const-qualified access path cannot be used to modify an object even if the object referenced is a non-const object and can be modified through some other access path.

Except that any class member declared mutable (7.1.1) can be modified, any attempt to modify a const object during its lifetime (3.8) results in undefined behavior.

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A const object? Where'd that come from? I thought just the pointer/reference was const. –  Mehrdad Jun 18 '12 at 6:23
    
@Mehrdad: const Foo f; declares a const object –  Alexandre C. Jun 18 '12 at 6:23
    
As my quote from the standard says - the const reference is treated as it would point to a const object. –  Rafał Rawicki Jun 18 '12 at 6:25
    
@RafałRawicki: Hmm, that's interesting... so you're saying this is UB? I guess then my question is, why exactly is it UB? (i.e. at what part of the code, precisely, did I violate anything?) –  Mehrdad Jun 18 '12 at 6:25
    
I answered referring to the question about subverting the typesystem itself. On the second thought your code sample does not use the const reference, so it is correct. This is a good example of why formally proving that the function (or we should rather say a function call) is pure is very hard. –  Rafał Rawicki Jun 18 '12 at 6:32
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I already saw something similar. Basically you invoke a cost function that invoke something else that modifies the object without knowing it.

Consider this as well:

#include <iostream>
using namespace std;

class B;

class A
{
    friend class B;
    B* pb;
    int val;
public:
    A(B& b); 
    void callinc() const;
    friend ostream& operator<<(ostream& s, const A& a)
    { return s << "A value is " << a.val; }
};

class B
{
    friend class A;
    A* pa;
public:
    void incval() const { ++pa->val; }
};

inline A::A(B& b) :pb(&b), val() { pb->pa = this; }
inline void A::callinc() const { pb->incval(); }


int main()
{
    B b;
    const A a(b);  // EDIT: WAS `A a(b)`
    cout << a << endl;
    a.callinc();
    cout << a << endl;
}

This is not C++11, but does the same: The point is that const is not transitive.

callinc() doesn't change itself a and incval doesn't change b. Note that in main you can even declare const A a(b); instead of A a(b); and everything compile the same.

This works from decades, and in your sample you're just doing the same: simply you replaced class B with a lambda.

EDIT

Changed the main() to reflect the comment.

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Your example doesn't address the issue of a const object though (after my updates to the question, based on another answer). That's what's scaring me. –  Mehrdad Jun 18 '12 at 14:05
    
@Mehrdad: See my edit. Is that what you meant? It works! (Or ... It doesn't, since according to your conception, it shouldn't) –  Emilio Garavaglia Jun 18 '12 at 20:13
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The issue is one of logical const versus bitwise const. The compiler doesn't know anything about the logical meaning of your program, and only enforces bitwise const. It's up to you to implement logical const. This means that in cases like you show, if the pointed to memory is logically part of the object, you should refrain from modifying it in a const function, even if the compiler will let you (since it isn't part of the bitwise image of the object). This may also mean that if part of the bitwise image of the object isn't part of the logical value of the object (e.g. an embedded reference count, or cached values), you make it mutable, or even cast away const, in cases where you modify it without modifying the logical value of the object.

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The const feature merely helps against accidental misuse. It is not designed to prevent dedicated software hacking. It is the same as private and protected membership, someone could always take the address of the object and increment along the memory to access class internals, there is no way to stop it.

So, yes you can get around const. If nothing else you can simply change the object at the memory level but this does not mean const is broken.

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The const feature merely helps against accidental misuse -- I guess the question is, why doesn't this qualify as "accidental misuse"? –  Mehrdad Jun 18 '12 at 14:03
    
It comes more under my next sentence "It is not designed to prevent dedicated software hacking" ;-) There is no way to prevent data attacks at the memory level. –  Stefan Jun 18 '12 at 14:06
    
What do you mean by "at the memory level"? What other levels are there? –  Mehrdad Jun 18 '12 at 14:12
    
For example, if you declare a class and name a private member I cannot modify it with code from another class (unless you take steps to allow it e.g. make me a friend). It is safe at the code level. I can, however, take the address of your object and access your member at the memory level and change it. There is no way of stopping this. This does not mean that 'private' is broken, merely that it was intended to prevent casual misuse, not a dedicate attack. –  Stefan Jun 18 '12 at 14:16
    
Hmm... that's a great point, but it's a slightly different point. accessing something private does not cause undefined behavior, as far as I know -- but const does! So it seems reasonable to me that if something causes UB, you're supposed to be able to protect against it somehow, but I don't see how you can do that here. –  Mehrdad Jun 18 '12 at 14:35
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