217
std::shared_ptr<Object> p1 = std::make_shared<Object>("foo");
std::shared_ptr<Object> p2(new Object("foo"));

Many google and stackoverflow posts are there on this, but I am not able to understand why make_shared is more efficient than directly using shared_ptr.

Can someone explain me step by step sequence of objects created and operations done by both so that I will be able to understand how make_shared is efficient. I have given one example above for reference.

  • 3
    It isn't more efficient. The reason to use it is for exception safety. – Yuushi Jan 3 '14 at 2:50
  • Some articles say, it avoids some construction overhead, can you please explain more on this? – Anup Buchke Jan 3 '14 at 2:52
  • 11
    @Yuushi: Exception safety is a good reason to use it, but it's also more efficient. – Mike Seymour Jan 3 '14 at 2:53
  • 3
    32:15 is where he starts in the video I linked to above, if that helps. – chris Jan 3 '14 at 3:02
  • 4
    Minor code style advantage: using make_shared you can write auto p1(std::make_shared<A>()) and p1 will have the correct type. – Ivan Vergiliev Jan 11 '14 at 0:25
274

The difference is that std::make_shared performs one heap-allocation, whereas calling the std::shared_ptr constructor performs two.

Where do the heap-allocations happen?

std::shared_ptr manages two entities:

  • the control block (stores meta data such as ref-counts, type-erased deleter, etc)
  • the object being managed

std::make_shared performs a single heap-allocation accounting for the space necessary for both the control block and the data. In the other case, new Obj("foo") invokes a heap-allocation for the managed data and the std::shared_ptr constructor performs another one for the control block.

For further information, check out the implementation notes at cppreference.

Update I: Exception-Safety

Since the OP seem to be wondering about the exception-safety side of things, I've updated my answer.

Consider this example,

void F(const std::shared_ptr<Lhs> &lhs, const std::shared_ptr<Rhs> &rhs) { /* ... */ }

F(std::shared_ptr<Lhs>(new Lhs("foo")),
  std::shared_ptr<Rhs>(new Rhs("bar")));

Because C++ allows arbitrary order of evaluation of subexpressions, one possible ordering is:

  1. new Lhs("foo"))
  2. new Rhs("bar"))
  3. std::shared_ptr<Lhs>
  4. std::shared_ptr<Rhs>

Now, suppose we get an exception thrown at step 2 (e.g., out of memory exception, Rhs constructor threw some exception). We then lose memory allocated at step 1, since nothing will have had a chance to clean it up. The core of the problem here is that the raw pointer didn't get passed to the std::shared_ptr constructor immediately.

One way to fix this is to do them on separate lines so that this arbitary ordering cannot occur.

auto lhs = std::shared_ptr<Lhs>(new Lhs("foo"));
auto rhs = std::shared_ptr<Rhs>(new Rhs("bar"));
F(lhs, rhs);

The preferred way to solve this of course is to use std::make_shared instead.

F(std::make_shared<Lhs>("foo"), std::make_shared<Rhs>("bar"));

Update II: Disadvantage of std::make_shared

Quoting Casey's comments:

Since there there's only one allocation, the pointee's memory cannot be deallocated until the control block is no longer in use. A weak_ptr can keep the control block alive indefinitely.

Why do instances of weak_ptrs keep the control block alive?

There must be a way for weak_ptrs to determine if the managed object is still valid (eg. for lock). They do this by checking the number of shared_ptrs that own the managed object, which is stored in the control block. The result is that the control blocks are alive until the shared_ptr count and the weak_ptr count both hit 0.

Back to std::make_shared

Since std::make_shared makes a single heap-allocation for both the control block and the managed object, there is no way to free the memory for control block and the managed object independently. We must wait until we can free both the control block and the managed object, which happens to be until there are no shared_ptrs or weak_ptrs alive.

Suppose we instead performed two heap-allocations for the control block and the managed object via new and shared_ptr constructor. Then we free the memory for the managed object (maybe earlier) when there are no shared_ptrs alive, and free the memory for the control block (maybe later) when there are no weak_ptrs alive.

  • 39
    It's a good idea to mention the small corner-case downside of make_shared as well: since there's only one allocation, the pointee's memory cannot be deallocated until the control block is no longer in use. A weak_ptr can keep the control block alive indefinitely. – Casey Jan 3 '14 at 21:01
  • 11
    Another, more stylistic, point is: If you use make_shared and make_unique consistently, you won't have owning raw pointers an can treat every occurrence of new as a code smell. – Philipp Jan 5 '14 at 22:04
  • 3
    If there is only one shared_ptr, and no weak_ptrs, calling reset() on the shared_ptr instance will delete the control block. But this is regardless or whether make_shared was used. Using make_shared makes a difference because it could prolong the life-time of the memory allocated for the managed object. When the shared_ptr count hits 0, the destructor for the managed object gets called regardless of make_shared, but freeing its memory can only be done if make_shared was not used. Hope this makes it more clear. – mpark Jan 6 '14 at 18:42
  • 4
    It would also be worth mentioning that make_shared can take advantage of the "We Know Where You Live" optimization that permits the control block to be a pointer smaller. (For details, see Stephan T. Lavavej's GN2012 presentation at about minute 12.) make_shared thus not only avoids an allocation, it also allocates less total memory. – KnowItAllWannabe Jan 28 '14 at 6:31
  • 1
    @HannaKhalil: Is this perhaps the realm of what you're looking for...? melpon.org/wandbox/permlink/b5EpsiSxDeEz8lGH – mpark Dec 20 '16 at 5:17
19

The shared pointer manages both the object itself, and a small object containing the reference count and other housekeeping data. make_shared can allocate a single block of memory to hold both of these; constructing a shared pointer from a pointer to an already-allocated object will need to allocate a second block to store the reference count.

As well as this efficiency, using make_shared means that you don't need to deal with new and raw pointers at all, giving better exception safety - there is no possibility of throwing an exception after allocating the object but before assigning it to the smart pointer.

  • 1
    I understood your first point correctly. Can you please elaborate or give some links on the second point about exception safety? – Anup Buchke Jan 3 '14 at 3:16
14

There is another case where the two possibilities differ, on top of those already mentioned: if you need to call a non-public constructor (protected or private), make_shared might not be able to access it, while the variant with the new works fine.

class A
{
public:

    A(): val(0){}

    std::shared_ptr<A> createNext(){ return std::make_shared<A>(val+1); }
    // Invalid because make_shared needs to call A(int) **internally**

    std::shared_ptr<A> createNext(){ return std::shared_ptr<A>(new A(val+1)); }
    // Works fine because A(int) is called explicitly

private:

    int val;

    A(int v): val(v){}
};
3

If you need special memory alignment on the object controlled by shared_ptr, you cannot rely on make_shared, but I think it's the only one good reason about not using it.

  • 1
    A second situation where make_shared is inappropriate is when you want to specify a custom deleter. – KnowItAllWannabe Jan 28 '14 at 6:22
2

Shared_ptr: Performs two heap allocation

  1. Control block(reference count)
  2. Object being managed

Make_shared: Performs only one heap allocation

  1. Control block and object data.
0

About efficiency and concernig time spent on allocation, I made this simple test below, I created many instances through these two ways (one at a time):

for (int k = 0 ; k < 30000000; ++k)
{
    // took more time than using new
    std::shared_ptr<int> foo = std::make_shared<int> (10);

    // was faster than using make_shared
    std::shared_ptr<int> foo2 = std::shared_ptr<int>(new int(10));
}

The thing is, using make_shared took the double time compared with using new. So, using new there are two heap allocations instead of one using make_shared. Maybe this is a stupid test but doesn't it show that using make_shared takes more time than using new? Of course, I'm talking about time used only.

  • 2
    That test is somewhat pointless. Was the test done in release configuration with optimisations turned out? Also all of your items are freed immediately so it is not realistic. – Phil1970 Jul 8 '17 at 12:51
0

I see one problem with std::make_shared, it doesn't support private/protected constructors

Your Answer

By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.