-
As mentioned,
std::make_sharedor its component parts don’t have access to private members. -
the
call_onceandonce_flagare un-necessary. They are implicit in c++11 static initialisation, -
You normally would not want to expose the shared pointer.
class MyClass
{
MyClass() {}
public:
static MyClass& GetInstance()
{
static auto instance = MyClass();
return instance;
}
};
However, there is one case I can imagine where you would want to expose a shared pointer to the impl – this is in the case where the class can choose to ‘break off’ or ‘reset’ the impl to a new one. In this case I would consider code like this:
class MyClass2
{
MyClass2() {};
static auto& InternalGetInstance()
{
static std::shared_ptr<MyClass2> instance { new MyClass2 };
return instance;
}
public:
static std::shared_ptr<MyClass2> GetInstance()
{
return std::atomic_load(std::addressof(InternalGetInstance()));
}
static void reset() {
std::atomic_store(std::addressof(InternalGetInstance()),
std::shared_ptr<MyClass2>(new MyClass2));
}
};
However, in the end, it is my view that ‘staticness’ of a class should be an implementation detail, and unimportant to the user of the class:
#include <memory>
#include <utility>
class MyClass
{
// internal mechanics
struct Impl {
auto doSomething() {
// actual implementation here.
}
};
// getImpl now becomes the customisation point if you wish to change the
// bahviour of the class later
static Impl& getImpl() {
static auto impl = Impl();
return impl;
}
// use value semantics - it makes for more readable and loosely-coupled code
public:
MyClass() {}
// public methods defer to internal implementation
auto doSomething() {
return getImpl().doSomething();
}
};
int main() {
// note: just create objects
auto mc = MyClass();
mc.doSomething();
// now we can pass the singleton as an object. Other functions don't even
// need to know it's a singlton:
extern void somethingElse(MyClass mc);
somethingElse(mc);
}
void somethingElse(MyClass mc)
{
}