This is a basic question, but I did not find a previous post about it. The title of the following question sounds like it might be the same question as mine, but the question itself does not match the title: is it better to use shared_ptr.reset or operator =?

I am confused about the purpose of the reset() member function of std::shared_ptr: what does it contribute in addition to the assignment operator?

To be concrete, given the definition:

auto p = std::make_shared<int>(1);
  1. Are the following two lines equivalent:

    p = std::make_shared<int>(5);
    p.reset(new int(5));
  2. What about these:

    p = nullptr;

If the two lines are equivalent in both cases, then what is the purpose of reset()?

EDIT: Let me re-phrase the question to better emphasize its point. The question is: is there a case where reset() lets us achieve something that is not as easily achievable without it?

  • @MeirGoldenberg, calling reset on a shared_ptr changes the managed object to that supplied by the pointer and it shouldn't be owner by any other shared_ptr. Whereas operator= would imply sharing ownership with another shared_ptr (unless of course you're doing move-assign).
    – Alejandro
    Commented Jul 15, 2015 at 19:06
  • "Shouldn't be owned"? Is this enforced or it's just an agreement? It would be nice if this comment along with an example became a full-fledged reply. Commented Jul 15, 2015 at 19:10
  • 1
    This boils down to the difference between constructing a shared_ptr from a raw pointer and using make_shared, which should be trivial to find out. Hint: There is a difference and sometimes it can be significant. Commented Jul 15, 2015 at 19:15
  • @MeirGoldenberg, its enforced by undefined behavior (if you can consider that "enforced"). Consider what would happen if you newed up some memory and called reset on two different shared_ptrs passing in that block of memory. When the two go out of scope, they'll try deleting the same block - hence UB.
    – Alejandro
    Commented Jul 15, 2015 at 19:17
  • 3
    @UlrichEckhardt I could have used a raw pointer in both cases: p = std::shared_ptr<int>(new int(5)); and p.reset(new int(5)); as is. What is the difference now? Commented Jul 15, 2015 at 19:19

4 Answers 4


When using reset() the parameter passed to reset need not be a managed object (nor can it be); whereas with = the right hand side must be a managed object.

So these two lines give you the same end result:

p = std::make_shared<int>(5); // assign to a newly created shared pointer
p.reset(new int(5)); // take control of a newly created pointer

But we cannot do:

p = new int(5); // compiler error no suitable overload
p.reset(std::make_shared<int>(5).get()); // uh oh undefined behavior

Without reset() you would not be able to reassign a shared pointer to a different raw pointer without creating a shared pointer and assigning it. Without = you wouldn't be able to make a shared pointer point to another shared pointer.

  • 2
    I understand the different usage. My question is: is there a case where reset() lets me achieve something that is not easily achievable without it? Commented Jul 15, 2015 at 19:28
  • 2
    A shared ptr created by make_shared is different than one created by .reset(new T). Commented Jul 15, 2015 at 22:27
  • 1
    In what way is it different?
    – MaxNoe
    Commented Feb 18, 2020 at 15:38
  • 2
    @MaxNoe With make_shared the pointer, and the shared state can be allocated into a single object using a single call to new. When you do reset that has to be split into two separate allocations. Commented Feb 18, 2020 at 16:24

It's possible for reset to avoid a dynamic memory allocation in certain cases. Consider the code

std::shared_ptr<int> p{new int{}};  // 1
p.reset(new int{});                 // 2

On line 1 there are 2 dynamic memory allocations happening, one for the int object and a second one for the shared_ptr's control block that'll keep track of the number of strong/weak references to the managed object.

On line 2 there is again a dynamic memory allocation for a new int object. Within the body of reset the shared_ptr will determine that there are no other strong references to the previously managed int, so it must delete it. Since there aren't any weak references either, it could also deallocate the control block, but in this case it would be prudent for the implementation to reuse the same control block because it would otherwise have to allocate a new one anyway.

The above behavior would not be possible if you always had to use assignment.

std::shared_ptr<int> p{new int{}};    // 1
p = std::shared_ptr<int>{new int{}};  // 2

In this case, the second call to the shared_ptr constructor on line 2 has already allocated a control block, so p will have to deallocate its own existing control block.

  • I assume this won't apply when you create the original shared_ptr with make_shared? Commented Jul 15, 2015 at 20:04
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    @NirFriedman Less likely, but maybe not totally unreasonable. You could imagine a library implementation making a decision based on sizeof(ControlBlock) + sizeof(T) that it would be more worthwhile to avoid the dynamic allocation. It could then destroy the object, but not deallocate the control block and take ownership of the new pointer.
    – Praetorian
    Commented Jul 15, 2015 at 21:33
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    Generally, I think the use of reset encourages bad practice and should be avoided but I think this is a correct answer. There may some cases where use of reset is a performance optimization but I would check the improvement is measurable before making the change.
    – Chris Drew
    Commented Jul 16, 2015 at 6:22
  • 2
    @ChrisDrew Yes measuring would be important, because it's not obvious that reset is faster at all, in the larger scope, because make_shared creates both the control-block and object in a single allocation, meaning upon usage cache-locality could cause make_shared to win over reset depending on how the resulting shared_ptr is actually used. In other words it's not sufficient too only look at the performance of modifying a shared_ptr but rather the combined performance impact of modify + usage. (Which rules out small generalized tests without any real usage scenario).
    – AnorZaken
    Commented Aug 30, 2016 at 15:51
  • 1
    it's worth noting that both libc++ and libstdc++ implement reset by constructing a new shared_ptr (along with a new control block) and swapping with *this Commented Apr 7, 2021 at 6:54

I won't include the rationale behind your first sub-question of the difference between construction via make_shared or from a pointer, as this difference is highlighted in several different locations, including this excellent question.

However, I think it is constructive to distinguish between using reset and operator=. The former relinquishes ownership of the resource managed by the shared_ptr, either by destroying it if the shared_ptr happened to be the sole owner, or by decrementing the reference count. The latter implies shared ownership with another shared_ptr (unless you're move constructing).

As I mentioned in the comments, it's important that the pointer passed in to reset not be owned by another shared or unique pointer, because it would yield undefined behavior upon the destruction of the two independent managers - they both would attempt to delete the resource.

One use case of reset could be lazy initialization of a shared resource. You only want the shared_ptr to manage some resource, memory for example, if you really need it. Doing an outright allocation, such as:

std::shared_ptr<resource> shared_resource(new resource(/*construct a resource*/));

might be wasteful if its never actually needed. To do this with lazy initialization, something like this may apply:

std::shared_ptr<resource> shared_resource;
void use_resource()
            shared_resource.reset(new resource(...));


Using reset in this case is more concise than doing a swap or assigning to a temporary shared_ptr.

  • "The latter [i.e. assignment] implies shared ownership with another shared_ptr ". I think you mean to contrast it with reset(), which makes p an owner on a non-managed resource, which by definition means sole ownership. The more I read the more I am wondering: who would ever use reset()? Is there an example where this is the tool to use? Commented Jul 15, 2015 at 19:39
  • @MeirGoldenberg, Updated with a potential example!
    – Alejandro
    Commented Jul 15, 2015 at 19:56
  • 2
    I'm not really sure why your example couldn't be done just as easily using the assignment operator. Commented Jul 15, 2015 at 19:58
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    shared_resource = std::make_shared<resource>(...); seems pretty concise to me.
    – Chris Drew
    Commented Jul 16, 2015 at 6:33

reset() changes the managed object of an existing shared_ptr.

p = std::shared_ptr(new int(5)); and p.reset(new int(5));

The former involves creating a new shared_ptr and moving it into a variable. The latter does not create a new object, it simply changes the underlying pointer in managed by the shared_ptr.

Put another way the two are meant to be used in different cases. Assignment is for when you have a shared_ptr and reset for when you have a raw pointer.

Another thing to keep in mind is that shared_ptr was available in boost before move assignment existed and influenced the latest version heavily. Without move assignment being able to change a shared_ptr without making a copy is beneficial as it saves you the bookkeeping of the extra object.

  • shared_ptr has only existed in the standard since C++11:en.cppreference.com/w/cpp/memory/shared_ptr. Boost does have a C++03 shared_ptr Commented Jul 15, 2015 at 19:51
  • @NathanOliver: Got my lines crossed, rephrased to avoid that statement but still mention that it could have had an influence. (although the general ability to make a logical modification without copying/moving is something that is common in either case)
    – Guvante
    Commented Jul 15, 2015 at 20:26

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