At least in my experience, it's more common to implement
operator new and
operator delete than to actually use (i.e., call) them, at least directly.
Usually, you use
operator new and
operator delete indirectly -- you write a
new expression, like
A *a = new A;. To implement this, the compiler generates code that invokes
operator new to allocate raw memory, then invokes a
A::A to convert that raw memory into an
A object, much as if you'd written:
void *temp = operator new(sizeof A); // allocate raw memory with operator new
A *a = new(temp) A; // convert raw memory to object with placement new
When you're done with the object, you use
delete A;. To implement that, the compiler invokes the dtor for the object, and then frees the memory, roughly like you'd done:
There are also
operator  new and
operator  delete, which are used when/if you allocate/delete arrays -- but there isn't necessarily any real difference between the normal version and the array version -- they both just allocate a specified amount of raw memory (though you might guess that the array versions will allocate relatively large amounts of memory, and do some optimization on that basis).
In any case, if you want to optimize how memory is allocated for objects of a particular class you overload these to do it. There are a fair number of existing implementations that you can drop-in and use, especially for situations where you expect to allocate a large number of tiny objects so you need to minimize the overhead associated with each allocation (e.g., HeapLayers, Loki's small block allocator).
One interesting little tidbit:
operator  new,
operator delete and operator  delete
class members, even if you don't explicitly includestatic` in their declaration/definition.
There are also global versions of all four (
::operator  new,
::operator delete and
::operator  delete). These mark the "border" between the "internal" C++ memory management, and the outside world. Typically they allocate relatively large chunks of memory from the operating system, and then return smaller pieces to the rest of the program upon request. If you want to (try to) optimize memory management for your entire program, you typically do it by overloading (or, really, replacing) these. Again, the typical reason would be if you expect to allocate a lot of small objects (but not in just a few classes). One example of this is the Boost Pool library.
Direct use of any of the above is generally restricted to situations where you need a block of raw memory, not objects. One example would be implementing your own container classes. For example,
std::vector normally uses
::operator new (via an Allocator object) to allocate memory in which to store objects. Since it needs to be able to allocate storage, but only later (or perhaps never) create objects in that storage, it can't just use something like
data = new T[size]; -- it has to allocate raw memory, then use placement new to create objects in the memory as you add them to the collection (e.g., when you
push_back an object). The same is true with
std::deque. If you wanted (for example) to implement your own circular buffer "from the ground up", handling all the memory management directly instead of using something like
vector for storage, you'd probably need/want to do the same.