There is indeed a substantial difference between:
shared_ptr<T> sp(new T());
shared_ptr<T> sp = make_shared<T>();
The first version performs an allocation for the
T object, then performs a separate allocation to create the reference counter. The second version performs one single allocation for both the object and the reference counter, placing them in a contiguous region of memory, resulting in less memory overhead.
Also, some implementations are able to perform further space optimizations in the case of
make_shared<> (see the "We Know Where You Live" optimization done by MS's implementation).
However, that is not the only reason why
make_shared<> exists. The version based on explicit
new T() is not exception-safe in some situations, especially when invoking a function that accepts a
void f(shared_ptr<T> sp1, shared_ptr<T> sp2);
f(shared_ptr<T>(new T()), shared_ptr<T>(new T()))
Here, the compiler could evaluate the first
new T() expression, then evaluate the second
new T() expression, then construct the corresponding
shared_ptr<> objects. But what if the second allocation causes an exception before the first allocated object is bound to its
shared_ptr<>? It will be leaked. With
make_shared<>(), this is not possible:
Because allocated objects are bound to the respective
shared_ptr<> objects inside each function call to
make_shared<>(), this call is exception-safe. This is yet another reason why naked
new should never be used unless you really know what you are doing. (*)
Considering your remark about
reset(), you are right in observing that
reset(new T()) will perform separate allocations for the counter and the object, just as the construction of a new
shared_ptr<> will perform a separate allocation when a raw pointer is passed as an argument. Therefore, an assignment using
make_shared<> is preferable (or even a statement such as
Whether or not
reset() should support a variadic argument list, this is probably more of a kind of open discussion for which StackOverflow is not a good fit.
(*) There are a few situations that still require it. For instance, the fact that the C++ Standard Library lacks a corresponding
make_unique<> function for
unique_ptr, so you'll have to write one yourself. Another situation is when you do not want the object and the counter to be allocated on a single memory block, because the presence of weak pointers to the object will prevent the entire block from being deallocated, even though no more owning pointers to the object exist.