The practical answer is to store either a copy of your class, or a std::ref
wrapped pseudo-reference to your class, in a std::function<void()>
.
std::function
type erases things it stores down to 3 concepts: copy, destroy and invoke with a fixed signature. (also, cast-back-to-original-type and typeid, more obscurely)
What it does is it remembers, at construction, how to do these operations to the passed in type, and stores a copy in a way it can perform those operations on it, then forgets everything else about the type.
You cannot remember everything about a type this way. But almost any operation with a fixed signature, or which can be intermediaried via a fixed signature operation, can be type erased down to.
The first typical way to do this are to create a private pure interface with those operations, then create a template implementation (templated on the type passed to the ctor) that implements each operation for that particular type. The class that does the type erasure then stores a (smart) pointer to the private interface, and forwards its public operations to it.
A second typical way is to store a void*
, or a buffer of char, and a set of pointers to functions that implement the operations. The pointers to functions can be either stored locally in the type erasing class, or stored in a helper struct that is created statically for each type erased, and a pointer to the helper struct is stored in the type erasing class. The first way to store the function pointers is like C-style object properties: the second is like a manual vtable.
In any case, the function pointers usually take one (or more) void*
and know how to cast them back to the right type. They are created in the ctor that knows the type, either as instances of a template
function, or as local stateless lambdas, or the same indirectly.
You could even do a hybrid of the two: static pimpl instance pointers taking a void*
or whatever.
Often using std::function
is enough, manually writing type erasure is hard to get right compared to using std::function
.
std::function
orboost::function
, or watch Sean Parent's talkS at GoingNative 2013.boost::any
as the memberboost::any
and read through it in some detail (it's not tiny, but it's not very long either). It's relatively free of really annoying details, and quite clever. Once you fully "get"boost::any
, you will really take a significant step in understanding types and type erasure in C++. (note thatstd::function
does similar things, but is way more complicated in practice... so I recommend starting withany
).