Is it me or is this example bad internalpointers.com/post/…

I can modify the temporary string without &&

so what does he mean?

@LewsTherin Looks like he means if you bound the temp to a const (lvalue) reference, you couldn't modify it via that reference (duh! That's what const means).

Why are static variables in a function visible inside a lambda declared in that function, but automatic variables need to be captured?

@MangaD Static variables don't need to be captured, because they always have the same address. Automatic variables have to be captured because they don't always have the same address. Consider a recursive function. Each invocation creates a lambda that refers to a non-static local variable. So even though they all refer to that variable by the same name, each lambda is referring to a unique local variable different from that used by the other invocations.

@JerryCoffin but this is not a good example right? given that std::string is mutable

@LewsTherin Mmmm....I've seen worse, but I've also seen quite a lot better.

On a scale of 1-10, I'd give it about a 4 (but at least it has a beat and you can dance to it).

yeah true

this move semantics is so confusing

after a move is the formerly held object there or not.. gah

"So in a sense, we have drifted into the netherworld of non-deterministic destruction here: a variable has been assigned to, but the object formerly held by that variable is still out there somewhere. "

"That's fine as long as the destruction of that object does not have any side effects that are visible to the outside world. But sometimes destructors do have such side effects. An example would be the release of a lock inside a destructor. Therefore, any part of an object's destruction that has side effects should be performed explicitly in the rvalue reference overload of the copy assignment operator:""

If I understand what he is saying

a and b are potentially pointing to same object

but if there object formerly held is destructed then surely it means a copy must have been done if it doesn't have affect new variable

@LewsTherin In the case of ints, no, not really. But for move semantics, most of what you care about are things like string or vector that contain a pointer to the real data.

yea true.. but in which case if I did a std::move of those UDTs it's implementation could be a reference swap in which you shouldn't destruct the formerly held object

And if you do isn't the current object undefined?

And if it's not undefined, wasn't a copy done?

I hate all this 'might be or may not be' this is why C# > C++

In theory, maybe. In reality, when you use an object as the source of a move, you always leave it in a state where it can be destroyed safely.

Ok so Im keen to know what happens when the source object is destroyed

what exactly is destroyed if not the moved object?

In case of two variables move(a)->b, are there two destructions?

or just one?

The source object is destroyed when it goes out of scope, just like always. If it contains a pointer, that's likely to now be a null pointer, so when you do a delete on that pointer, it doesn't do anything.

@JerryCoffin so when we mean source object we actually mean variable

@LewsTherin Yeah, pretty much anyway. You can create an object with new as well, but in that case it's up to you to delete it when you no longer need it.

@JerryCoffin yeah if an object is created with new I suppose the new variable handling the actual sourced object should handle the destruction when it's out of scope

@LewsTherin If you create something with new, it's up to you to destroy it with delete (though honestly, you should hardly ever do that directly--usually you should be using something like a unique_ptr, which handles destruction automatically.

yeah I agree

I just didnt understand what the author meant by formerly held object being destructed from the sourced object

made no sense

@LewsTherin Fairly poor explanation. But a typical case is pretty simple: we have a string. The string object contains a pointer to some data that was allocated with new. When we move from that string to another, we copy just the pointer itself from the old string object to the new one, then set the pointer in the old string object to a null pointer (and set the length to 0, etc.) so the moved-from string is now basically just a normal empty string.

The data it used to own is now owned by the string we moved it to, so that data will be deleted when the string we moved it to gets destroyed.

Folks, how to make a function that cast input of type Parent to its Child?

template<typename T>
T* CastChecked(T* parent)
{
    return (T*) parent;
}

There can be many child classes. You cannot have a generic function for this.

#include <concepts>

template <typename D, typename B>
    requires std::derived_from<D, B>
D* CastChecked(B* parent) {
    return dynamic_cast<D*>(parent);
}

Problem solved.

In this example you must know what the base class and derived class are beforehand, so you may as well use dynamic_cast directly.

if you're 100% sure that B is a D then you can use static_cast

dynamic_cast should be used when it's ambiguous

oh yeah, that's absolutely right, so using a template with dynamic_cast is silly

@MangaD It's not a problem, as such, but it means that when the lambda starts executing, it has to capture the address of the local variable (whereas when you're dealing with a static variable, it can just encode the right address into the lambda ahead of time, since there is only one address for it).

@JerryCoffin But I do not understand why that has to be made explicit by the programmer.

@MangaD In theory it wouldn't have to be. I suppose it's kind of a variation of "You don't pay for what you don't use". It can/will cost a little bit to capture variables (especially by copy) so they want to assure you're aware of what's happening and the potential for some cost.

Why not just capture by reference by default? Use the address of the variable directly? If the programmer wants a copy he can explicitly make one.

@MangaD because of lifetimes, it then becomes at trap to capture with lambdas used in callbacks. It also then means using more syntax when the default should be copy because that's the best choice in most cases.

@Mgetz Certainly the safer choice, in any case.