Is there a reason why std::type_info
is specified to be polymorphic? The destructor is specified to be virtual (and there's a comment to the effect of "so that it's polymorphic" in The Design and Evolution of C++). I can't really see a compelling reason why. I don't have any specific use case, I was just wondering if there ever was a rationale or story behind it.
Here's some ideas that I've come up with and rejected:
- It's an extensibility point - implementations might define subclasses, and programs might then try to
dynamic_cast
astd::type_info
to another, implementation-defined derived type. This is possibly the reason, but it seems that it's just as easy for implementations to add an implementation-defined member, which could possibly be virtual. Programs wishing to test for these extensions would necessarily be non-portable anyway. - It's to ensure that derived types are destroyed properly when
delete
ing a base pointer. But there are no standard derived types, users can't define useful derived types, becausetype_info
has no standard public constructors, and sodelete
ing atype_info
pointer is never both legal and portable. And the derived types aren't useful because they can't be constructed - the only use I know for such non-constructible derived types is in the implementation of things like theis_polymorphic
type trait. - It leaves open the possibility of metaclasses with customized types - each real polymorphic
class A
would get a derived "metaclass"A__type_info
, which derives fromtype_info
. Perhaps such derived classes could expose members that callnew A
with various constructor arguments in a type-safe way, and things like that. But makingtype_info
polymorphic itself actually makes such an idea basically impossible to implement, because you'd have to have metaclasses for your metaclasses, ad infinitum, which is a p开发者_JAVA百科roblem if all thetype_info
objects have static storage duration. Maybe barring this is the reason for making it polymorphic. - There's some use for applying RTTI features (other than
dynamic_cast
) tostd::type_info
itself, or someone thought that it was cute, or embarrassing iftype_info
wasn't polymorphic. But given that there's no standard derived type, and no other classes in the standard hierarchy which one might reasonably try cross-cast to, the question is: what? Is there a use for expressions such astypeid(std::type_info) == typeid(typeid(A))
? - It's because implementers will create their own private derived type (as I believe GCC does). But, why bother specifying it? Even if the destructor wasn't specified as virtual and an implementer decided that it should be, surely that implementation could declare it virtual, because it doesn't change the set of allowed operations on
type_info
, so a portable program wouldn't be able to tell the difference. - It's something to do with compilers with partially compatible ABIs coexisting, possibly as a result of dynamic linking. Perhaps implementers could recognize their own
type_info
subclass (as opposed to one originating from another vendor) in a portable way iftype_info
was guaranteed to be virtual.
The last one is the most plausible to me at the moment, but it's pretty weak.
I assume it's there for the convenience of implementers. It allows them to define extended type_info
classes, and delete them through pointers to type_info
at program exit, without having to build in special compiler magic to call the correct destructor, or otherwise jump through hoops.
surely that implementation could declare it virtual, because it doesn't change the set of allowed operations on type_info, so a portable program wouldn't be able to tell the difference.
I don't think that's true. Consider the following:
#include <typeinfo>
struct A {
int x;
};
struct B {
int x;
};
int main() {
const A *a1 = dynamic_cast<const A*>(&typeid(int));
B b;
const A *a2 = dynamic_cast<const A*>(&b);
}
Whether it's reasonable or not, the first dynamic cast is allowed (and evaluates to a null pointer), whereas the second dynamic cast is not allowed. So, if type_info
was defined in the standard to have the default non-virtual destructor, but an implementation added a virtual destructor, then a portable program could tell the difference[*].
Seems simpler to me to put the virtual destructor in the standard, than to either:
a) put a note in the standard that, although the class definition implies that type_info
has no virtual functions, it is permitted to have a virtual destructor.
b) determine the set of programs which can distinguish whether type_info
is polymorphic or not, and ban them all. They may not be very useful or productive programs, I don't know, but to ban them you have to come up with some standard language that describes the specific exception you're making to the normal rules.
Therefore I think that the standard has to either mandate the virtual destructor, or ban it. Making it optional is too complex (or perhaps I should say, I think it would be judged unnecessarily complex. Complexity never stopped the standards committee in areas where it was considered worthwhile...)
If it was banned, though, then an implementation could:
- add a virtual destructor to some derived class of
type_info
- derive all of its typeinfo objects from that class
- use that internally as the polymorphic base class for everything
that would solve the situation I described at the top of the post, but the static type of a typeid
expression would still be const std::type_info
, so it would be difficult for implementations to define extensions where programs can dynamic_cast
to various targets to see what kind of type_info
object they have in a particular case. Perhaps the standard hoped to allow that, although an implementation could always offer a variant of typeid
with a different static type, or guarantee that a static_cast
to a certain extension class will work, and then let the program dynamic_cast
from there.
In summary, as far as I know the virtual destructor is potentially useful to implementers, and removing it doesn't gain anyone anything other than that we wouldn't be spending time wondering why it's there ;-)
[*] Actually, I haven't demonstrated that. I've demonstrated that an illegal program would, all else being equal, compile. But an implementation could perhaps work around that by ensuring that all isn't equal, and that it doesn't compile. Boost's is_polymorphic
isn't portable, so while it's possible for a program to test that a class is polymorphic, that should be, there may be no way for a conforming program to test that a class isn't polymorphic, that shouldn't be. I think though that even if it's impossible, proving that, in order to remove one line from the standard, is quite a lot of effort.
The C++ standard says that typeid
returns an object of type type_info, OR AN IMPLEMENTATION-DEFINED subclass thereof. So... I guess this is pretty much the answer. So I don't see why you reject your points 1 and 2.
Paragraph 5.2.8 Clause 1 of the current C++ standard reads:
The result of a typeid expression is an lvalue of static type const std::type_info (18.5.1) and dynamic type const std::type_info or const name where name is an implementation-defined class derived from std::type_info which preserves the behavior described in 18.5.1.61) The lifetime of the object referred to by the lvalue extends to the end of the program. Whether or not the destructor is called for the type_info object at the end of the program is unspecified.
Which in turn means that one could write the following code is legal and fine:
const type_info& x = typeid(expr);
which may require that type_info be polymorphic
3/ It leaves open the possibility of metaclasses with customized types - each real polymorphic
class A
would get a derived "metaclass"A__type_info
, which derives fromtype_info
. Perhaps such derived classes could expose members that callnew A
with various constructor arguments in a type-safe way, and things like that. But makingtype_info
polymorphic itself actually makes such an idea basically impossible to implement, because you'd have to have metaclasses for your metaclasses, ad infinitum, which is a problem if all thetype_info
objects have static storage duration. Maybe barring this is the reason for making it polymorphic.
Clever...
Anyway, I disagree with this reasoning: such implementation could easily rule-out meta classes for types derived from type_info
, including type_info
itself.
About the simplest "global" id you can have in C++ is a class name,and typeinfo
provides a way to compare such id's for equality. But the design is so awkward and limited that you then need to wrap typeinfo
in some wrapper class, e.g. to be able to put instances in collections. Andrei Alexandrescu did that in his "Modern C++ Design" and I think that that typeinfo
wrapper is part of the Loki library; there's probably one also in Boost; and it's pretty easy to roll your own, e.g. see my own wrapper.
But even for such a wrapper there's not in general any need for a virtual destructor in typeinfo
.
The question is therefore not so much "huh, why is there a virtual destructor" but rather, as I see it, "huh, why is the design so backward, awkward and not directly usable"? And I'd put that down to the standardization process. For example, iostreams are not exactly examples of superb design, either; not something to emulate.
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