How much is the overhead of smart pointers compared to normal pointers in C++11? In other words, is my code going to be slower if I use smart pointers, and if so, how much slower?

Specifically, I'm asking about the C++11 std::shared_ptr and std::unique_ptr.

Obviously, the stuff pushed down the stack is going to be larger (at least I think so), because a smart pointer also needs to store its internal state (reference count, etc), the question really is, how much is this going to affect my performance, if at all?

For example, I return a smart pointer from a function instead of a normal pointer:

std::shared_ptr<const Value> getValue();
// versus
const Value *getValue();

Or, for example, when one of my functions accept a smart pointer as parameter instead of a normal pointer:

void setValue(std::shared_ptr<const Value> val);
// versus
void setValue(const Value *val);
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    The only way to know is to benchmark your code. – Basile Starynkevitch Mar 10 '14 at 8:54
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    Which one do you mean? std::unique_ptr or std::shared_ptr? – stefan Mar 10 '14 at 8:55
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    The answer is 42. (another words, who knows, you need to profile your code and understand on your hardware for your typical work load.) – Nim Mar 10 '14 at 8:56
  • Your application needs to make extreme use of smart pointers for it to be significant. – user2672165 Mar 10 '14 at 10:59
  • The cost of using a shared_ptr in a simple setter function is terrible and will add a multiple 100% overhead. – Lothar Dec 17 '17 at 9:40

std::unique_ptr has memory overhead only if you provide it with some non-trivial deleter.

std::shared_ptr always has memory overhead for reference counter, though it is very small.

std::unique_ptr has time overhead only during constructor (if it has to copy the provided deleter and/or null-initialize the pointer) and during destructor (to destroy the owned object).

std::shared_ptr has time overhead in constructor (to create the reference counter), in destructor (to decrement the reference counter and possibly destroy the object) and in assignment operator (to increment the reference counter). Due to thread-safety guarantees of std::shared_ptr, these increments/decrements are atomic, thus adding some more overhead.

Note that none of them has time overhead in dereferencing (in getting the reference to owned object), while this operation seems to be the most common for pointers.

To sum up, there is some overhead, but it shouldn't make the code slow unless you continuously create and destroy smart pointers.

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  • 11
    unique_ptr has no overhead in the destructor. It does exactly the same as you would with a raw pointer. – R. Martinho Fernandes Dec 15 '14 at 11:22
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    @R.MartinhoFernandes comparing to raw pointer itself, it does have time overhead in destructor, since raw pointer destructor does nothing. Comparing to how a raw pointer would probably be used, it surely has no overhead. – lisyarus Dec 15 '14 at 13:36
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    Worth noting that part of the shared_ptr construction/destruction/assignment cost is due to thread safety – Joe Mar 1 '16 at 17:25
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    Also, what about the default constructor of std::unique_ptr? If you construct a std::unique_ptr<int>, the internal int* gets initialized to nullptr whether you like it or not. – Martin Drozdik May 14 '16 at 17:57
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    @MartinDrozdik In most situations you'd null-initialize the raw pointer too, to check it's nullity later, or something like that. Nevertheless, added this to the answer, thank you. – lisyarus Mar 19 '17 at 11:37

My answer is different from the others and i really wonder if they ever profiled code.

shared_ptr has a significant overhead for creation because of it's memory allocation for the control block (which keeps the ref counter and a pointer list to all weak references). It has also a huge memory overhead because of this and the fact that std::shared_ptr is always a 2 pointer tuple (one to the object, one to the control block).

If you pass a shared_pointer to a function as a value parameter then it will be at least 10 times slower then a normal call and create lots of codes in the code segment for the stack unwinding. If you pass it by reference you get an additional indirection which can be also pretty worse in terms of performance.

Thats why you should not do this unless the function is really involved in ownership management. Otherwise use "shared_ptr.get()". It is not designed to make sure your object isn't killed during a normal function call.

If you go mad and use shared_ptr on small objects like an abstract syntax tree in a compiler or on small nodes in any other graph structure you will see a huge perfomance drop and a huge memory increase. I have seen a parser system which was rewritten soon after C++14 hit the market and before the programmer learned to use smart pointers correctly. The rewrite was a magnitude slower then the old code.

It is not a silver bullet and raw pointers aren't bad by definition either. Bad programmers are bad and bad design is bad. Design with care, design with clear ownership in mind and try to use the shared_ptr mostly on the subsystem API boundary.

If you want to learn more you can watch Nicolai M. Josuttis good talk about "The Real Price of Shared Pointers in C++" https://vimeo.com/131189627
It goes deep into the implementation details and CPU architecture for write barriers, atomic locks etc. once listening you will never talk about this feature being cheap. If you just want a proof of the magnitude slower, skip the first 48 minutes and watch him running example code which runs upto 180 times slower (compiled with -O3) when using shared pointer everywhere.

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  • Thanks for your answer! Which platform did you profile on? Can you back up your claims with some data? – Venemo Dec 18 '17 at 17:13
  • I have no number to show, but you can find some in Nico Josuttis talk vimeo.com/131189627 – Lothar Dec 20 '17 at 18:44
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    Ever heard of std::make_shared()? Also, I find demonstrations of blatant misuse being bad a bit boring... – Deduplicator Dec 23 '17 at 19:32
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    All "make_shared" can do is safe you from one additional allocation and give you a bit more cache locality if the control block is allocated in front of the object. It can't not help at all when you pass the pointer around. This is not the root of the problems. – Lothar Dec 24 '17 at 5:25

As with all code performance, the only really reliable means to obtain hard information is to measure and/or inspect machine code.

That said, simple reasoning says that

  • You can expect some overhead in debug builds, since e.g. operator-> must be executed as a function call so that you can step into it (this is in turn due to general lack of support for marking classes and functions as non-debug).

  • For shared_ptr you can expect some overhead in initial creation, since that involves dynamic allocation of a control block, and dynamic allocation is very much slower than any other basic operation in C++ (do use make_shared when practically possible, to minimize that overhead).

  • Also for shared_ptr there is some minimal overhead in maintaining a reference count, e.g. when passing a shared_ptr by value, but there's no such overhead for unique_ptr.

Keeping the first point above in mind, when you measure, do that both for debug and release builds.

The international C++ standardization committee has published a technical report on performance, but this was in 2006, before unique_ptr and shared_ptr were added to the standard library. Still, smart pointers were old hat at that point, so the report considered also that. Quoting the relevant part:

“if accessing a value through a trivial smart pointer is significantly slower than accessing it through an ordinary pointer, the compiler is inefficiently handling the abstraction. In the past, most compilers had significant abstraction penalties and several current compilers still do. However, at least two compilers have been reported to have abstraction penalties below 1% and another a penalty of 3%, so eliminating this kind of overhead is well within the state of the art”

As an informed guess, the “well within the state of the art” has been achieved with the most popular compilers today, as of early 2014.

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  • Could you please include some details in your answer about the cases I added to my question? – Venemo Mar 12 '14 at 10:03
  • This might have been true 10 or more years ago, but today, inspecting machine code is not as useful as the person above suggests. Depending on how instructions are pipelined, vectorized, ... and how the compiler/processor deals with speculation ultimately is how fast it is. Less code machine code doesn't necessarily mean faster code. The only way to determine the performance is to profile it. This can change on a processor basis and also per compiler. – Byron Jan 4 '19 at 17:58
  • An issue I've seen is that, once shared_ptrs are used in a server, then the usage of shared_ptrs begin to proliferate, and soon shared_ptrs become the default memory management technique. So now you have repeated 1-3% abstraction penalties which are taken over and over again. – Nathan Doromal Nov 27 '19 at 14:53
  • I think benchmarking a debug build is a complete and utter waste of time – Paul Childs Feb 24 at 3:02

In other words, is my code going to be slower if I use smart pointers, and if so, how much slower?

Slower? Most likely not, unless you are creating a huge index using shared_ptrs and you have not enough memory to the point that your computer starts wrinkling, like an old lady being plummeted to the ground by an unbearable force from afar.

What would make your code slower is sluggish searches, unnecessary loop processing, huge copies of data, and a lot of write operations to disk (like hundreds).

The advantages of a smart pointer are all related to management. But is the overhead necessary? This depends on your implementation. Let's say you are iterating over an array of 3 phases, each phase has an array of 1024 elements. Creating a smart_ptr for this process might be overkill, since once the iteration is done you'll know you have to erase it. So you could gain extra memory from not using a smart_ptr...

But do you really want to do that?

A single memory leak could make your product have a point of failure in time (let's say your program leaks 4 megabytes each hour, it would take months to break a computer, nevertheless, it will break, you know it because the leak is there).

Is like saying "you software is guaranteed for 3 months, then, call me for service."

So in the end it really is a matter of... can you handle this risk? does using a raw pointer to handle your indexing over hundreds of different objects is worth loosing control of the memory.

If the answer is yes, then use a raw pointer.

If you don't even want to consider it, a smart_ptr is a good, viable, and awesome solution.

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  • 4
    ok, but valgrind is good in checking for possible memory leaks, so as long as you use it you should be safe™ – graywolf Mar 10 '14 at 12:43
  • @Paladin Yes, if you can handle your memory, smart_ptr are really useful for large teams – Claudiordgz Mar 10 '14 at 14:29
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    I use unique_ptr, it simplifies lot of things, but don't like shared_ptr, reference counting is not very efficient GC and its not perfect either – graywolf Mar 10 '14 at 14:33
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    @Paladin I try to use raw pointers if I can encapsulate everything. If it is something that I will be passing around all over the place like an argument then maybe I'll consider an smart_ptr. Most of my unique_ptrs are used in the big implementation, like a main or run method – Claudiordgz Mar 10 '14 at 15:38
  • @Lothar I see you paraphrased one of the things I said in your answer: Thats why you should not do this unless the function is really involved in ownership management... great answer, thanks, upvoted – Claudiordgz Dec 23 '17 at 2:11

Just for a glimpse and just for the [] operator,it is ~5X slower than the raw pointer as demonstrated in the following code, which was compiled using gcc -lstdc++ -std=c++14 -O0 and outputted this result:

malloc []:     414252610                                                 
unique []  is: 2062494135                                                
uq get []  is: 238801500                                                 
uq.get()[] is: 1505169542
new is:        241049490 

I'm beginning to learn c++, I got this in my mind: you always need to know what are you doing and take more time to know what others had done in your c++.


As methioned by @Mohan Kumar, I provided more details. The gcc version is 7.4.0 (Ubuntu 7.4.0-1ubuntu1~14.04~ppa1), The above result was obtained when the -O0 is used, however, when I use '-O2' flag, I got this:

malloc []:     223
unique []  is: 105586217
uq get []  is: 71129461
uq.get()[] is: 69246502
new is:        9683

Then shifted to clang version 3.9.0, -O0 was :

malloc []:     409765889
unique []  is: 1351714189
uq get []  is: 256090843
uq.get()[] is: 1026846852
new is:        255421307

-O2 was:

malloc []:     150
unique []  is: 124
uq get []  is: 83
uq.get()[] is: 83
new is:        54

The result of clang -O2 is amazing.

#include <memory>
#include <iostream>
#include <chrono>
#include <thread>

uint32_t n = 100000000;
void t_m(void){
    auto a  = (char*) malloc(n*sizeof(char));
    for(uint32_t i=0; i<n; i++) a[i] = 'A';
void t_u(void){
    auto a = std::unique_ptr<char[]>(new char[n]);
    for(uint32_t i=0; i<n; i++) a[i] = 'A';

void t_u2(void){
    auto a = std::unique_ptr<char[]>(new char[n]);
    auto tmp = a.get();
    for(uint32_t i=0; i<n; i++) tmp[i] = 'A';
void t_u3(void){
    auto a = std::unique_ptr<char[]>(new char[n]);
    for(uint32_t i=0; i<n; i++) a.get()[i] = 'A';
void t_new(void){
    auto a = new char[n];
    for(uint32_t i=0; i<n; i++) a[i] = 'A';

int main(){
    auto start = std::chrono::high_resolution_clock::now();
    auto end1 = std::chrono::high_resolution_clock::now();
    auto end2 = std::chrono::high_resolution_clock::now();
    auto end3 = std::chrono::high_resolution_clock::now();
    auto end4 = std::chrono::high_resolution_clock::now();
    auto end5 = std::chrono::high_resolution_clock::now();
    std::cout << "malloc []:     " <<  (end1 - start).count() << std::endl;
    std::cout << "unique []  is: " << (end2 - end1).count() << std::endl;
    std::cout << "uq get []  is: " << (end3 - end2).count() << std::endl;
    std::cout << "uq.get()[] is: " << (end4 - end3).count() << std::endl;
    std::cout << "new is:        " << (end5 - end4).count() << std::endl;

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  • I have tested the code now, it's just only 10% slow when using the unique pointer. – Mohan Kumar Jan 30 '19 at 22:11
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    never ever benchmark with -O0 or debug code. The output will be extremely inefficient. Always use at least -O2 (or -O3 nowadays because some vectorization aren't done in -O2) – phuclv Apr 6 '19 at 11:09
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    If you have time and want a coffee break take -O4 to get link time optimization and all the little tiny abstraction functions get inline and vanish. – Lothar Sep 3 '19 at 15:05
  • You should include a free call in the malloc test, and delete[] for new (or make variable a static), because the unique_ptrs are calling delete[] under the hood, in their destructors. – RnMss Jun 30 at 3:46

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