11

Suppose I have a struct definition:

struct thing
{
    thing* x;
    int z;

    thing() : x(this), z(0) {}
    void foo() const
    {
        this->x->z++;
    }
};

Note that I create a mutable pointer to myself (evil laugh)

And then I can use this later like this:

int main()
{
    const thing c;
    c.foo();
    assert(c.z == 1);
    c.foo();
    assert(c.z == 2);
    return c.z;
}

And as you can see it seems that I can change a constant value......is this UB?

2
  • 4
    Yes, it is UB, as c is const. – geza Oct 8 '18 at 21:44
  • There is no general rule that says you can't subvert const without a cast. – curiousguy Oct 21 '18 at 20:31
10

[dcl.type.cv]p4:

Except that any class member declared mutable ([dcl.stc]) can be modified, any attempt to modify ([expr.ass], [expr.post.incr], [expr.pre.incr]) a const object ([basic.type.qualifier]) during its lifetime ([basic.life]) results in undefined behavior.

[basic.type.qualifier]p1:

A const object is an object of type const T or a non-mutable subobject of such an object.

c.z is a const object, because it is a non-mutable subobject of c. Your code attempts to modify it during its lifetime. It follows that the code has undefined behavior.

0

The foo-function itself would be OK, as const member functions like T::foo() const just indicate that this is of type const *T; The fact that a (non-const) member points to the same object is irrelevant then.

The object c in first place, however, is declared as const. So it is UB to alter the contents of c through whatever code, including the (per se correct) member function foo.

7
  • 2
    What about the fact that c is const? – NathanOliver Oct 8 '18 at 21:23
  • @NathanOliver: yes; you may not change the value of c->x, but you may change the object referenced by c->x; so c->x->z++ is valid even if c is const. – Stephan Lechner Oct 8 '18 at 21:26
  • But since c->x->z++ is c.z++ isn't that UB? – NathanOliver Oct 8 '18 at 21:27
  • 1
    @NathanOliver: No, I'm quite sure that it is not UB. const does not mean that the object is immutable in general; it just declares that it must not be changed through the (const) pointer at hand. So you cannot change z through a (const*) this->z++, but through another path to that object, i.e. through this->x->z++ – Stephan Lechner Oct 8 '18 at 21:29
  • 1
    Your example is only valid because value was not declared const in the first place.. but his thing instance is declared const.. and if you attempted to const_cast<thing*>(this)->z++; it'd be undefined behaviour.. So why would he be able to modify it through a shallow copy of this.. *Note:( I did not downvote. – Brandon Oct 8 '18 at 21:39

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