@CornSmith please check out my slight edit. I made a mistake previously. You're not restricted to the current instance but to pointers/references of the current type. A type knows its own invariants so it can manipulate other instances of that type safely (modulo bugs). For example, this works ideone.com/8LvA3

Let's hope that child does not break stronger_child invariant.

@curiousguy I'm sorry, I don't understand. What do you mean by that? Isn't that what I show in my answer?

Let's hope that <del>child</del> parent does not break stronger_child invariant.

@curiousguy: If stronger_child's invariants are stronger than the parent's that means that all the parent's invariants still hold. There's no way to break anything, unless stronger_child's invariants are incompatible with parent's instead of stronger. And that's just bad subclassing.

But the base class parent does not know about the stronger invariant, so why do you expect that parent will not break it?

@curiousguy If the invariant is strictly stronger, it can't possibly break it. E.g., if parent said that a could be written the value 5, then stronger_child would not have a stronger invariant, but a conflicting one.

I guess I don't understand what you mean by "invariant".

@curiousguy en.wikipedia.org/wiki/Class_invariant

Now I am 100 % sure I don't understand what you mean by "invariant".

@curiousguy Really, I mean exactly what is described on the link I posted yesterday. The invariant of a certain class is a predicate that holds true before and after every call to member functions on objects of that class. A subclass must maintain the predicate that its base class has as invariant. It may add some additional ones using logical conjunction (strengthening the invariant).

Would you admit that True is the least class invariant?

@curiousguy Yes.

Hi.

Hi.

Let's have a class BaseTrue with the True invariant; it can have member variables, and they can take pretty much any value.

Go on.

You can have Der derived from BaseTrue.

Der must have a stronger invariant.

In fact, any invariant is stronger than True.

So any invariant is acceptable for Der.

BaseTrue has member variables, they can be protected.

Der can manipulate these protected members.

Say BaseTrue has a protected int member x.

Der invariant is that x > 0.

And how would the base break that?

Der must obviously set x to an appropriate value in the constructor.

Also, its interface does not break the invariant.

OTOH, BaseTrue can have public members allowing any changes to its member variables.

Keep in mind that the derived class must also maintain all postconditions of the base.

F.ex. it can have a negate() member which does x *= -1;

Sure, and that has a postcondition that says that x is now the symmetrical of the previous value. The derived class cannot break this either. If the base has such a member, you can't have x > 0 for the derived class's invariant.

Because Der derives publicly from BaseTrue, it cannot remove any base member from the public view.

Right, and that's why that invariant is not valid.

You can't hold it and the postconditions at the same time.

It is not true that BaseTrue invariant is still the minimal True invariant?

Yes.

The class invariant is a property about the state of a class instance.

Yes.

But I cannot accept your Der as a valid example. It is not even self-consistent. It has a member that guarantees x will switch sign (or be zero, if that's relevant here) and an invariant that says x > 0.

You can't complain the base class broke it if you designed it broken from the start.

@curiousguy It's lunch time for me now, I won't be around for a while.

I got "interrupted" too.

Hi.

Hi, again.

Example code:

You can use the "fixed font" button that shows to the right of the text box sometimes to format code.

class BaseTrue {
protected:
	int x;

public:
	BaseTrue () : x() {
	}

	void negate() {
		x *= -1;
	}
};

It works!

// invariant: x>0
class Der : public BaseTrue {
public:
	Der () {
		x = 1;
	}

	void increase() {
		x += 2;
	}
};

Clearly, this design is broken.

I agree.

I can use the negate function, and Der cannot "turn it off".

But I'd say it's Der that is breaking BaseTrue's guarantees (namely that negate() will change sign), not BaseTrue breaking Der.

But where is it broken?

Der promises an invariant it can't fulfill.

But the invariant of Der is stronger than the one of its base class.

But it's not consistent with the postcondition of negate().

Maybe I should have used "contract" instead of "invariant".

To consider the derived class invariant, you need to consider all the derived class functions and all its base class functions.

Right.

Is the set of member functions of a base class "frozen"?

@curiousguy Should be. Any change to a base class is a potential breaking change.

When designing a derived class, you need to consider the base class interface.

Right. And it does not help if that interface changes willy nilly.

But you also need to imagine what additional functions may be added in the future...

Even if these new functions don't break the class invariant.

But these new functions may break others expectations.

Well, like I said, every change you make to a base class is a potential breaking change. You have no idea what people wrote on their derived classes.

I supposed that proper "OOP" design would make sure that some "innocent" interface changes would be ok.

Yeah, I think that if you designed and documented your classes carefully you could make some changes without issue.

But it's certainly not easy in general.

Changing the behaviour of an existing function obviously is not ok, and breaking the documented invariant is not either.

There is an implicit promise about what the base class can do that isn't captured in the invariant.

Yes.

If the first version of BaseTrue didn't have negate() someone subclassing it would see no way to have a negative x and might assume it.

How is the promise called then?

The term I've heard thrown around is "contract", I think.

I see.

To me "contract" meant "description of each function", rather than "description of the class as a whole".

What would you use then?

Usually a class is not just a bunch of functions together, so a synthetic description is useful too.

I just don't know!

That's okay. I'm glad we could reach an agreement :)

A class is often associated to an abstract mathematical domain; I suppose one could describe "reachable abstract domain".

I am glad too. :D

Thank you for the conversation.

You're welcome.

I'm sorry for that jab I made at you in a comment the other day.

I was a bit angry at the time.

I think I have to go anyway.

Ok, good bye then.

Not being a native English speaker, "jab" is a word I am going to learn...

I hope you are not angry anymore.

Goodbye!

Bye.