C++11 vectors have the new function emplace_back. Unlike push_back, which relies on compiler optimizations to avoid copies, emplace_back uses perfect forwarding to send the arguments directly to the constructor to create an object in-place. It seems to me that emplace_back does everything push_back can do, but some of the time it will do it better (but never worse).

What reason do I have to use push_back?


6 Answers 6


I have thought about this question quite a bit over the past four years. I have come to the conclusion that most explanations about push_back vs. emplace_back miss the full picture.

Last year, I gave a presentation at C++Now on Type Deduction in C++14. I start talking about push_back vs. emplace_back at 13:49, but there is useful information that provides some supporting evidence prior to that.

The real primary difference has to do with implicit vs. explicit constructors. Consider the case where we have a single argument that we want to pass to push_back or emplace_back.

std::vector<T> v;

After your optimizing compiler gets its hands on this, there is no difference between these two statements in terms of generated code. The traditional wisdom is that push_back will construct a temporary object, which will then get moved into v whereas emplace_back will forward the argument along and construct it directly in place with no copies or moves. This may be true based on the code as written in standard libraries, but it makes the mistaken assumption that the optimizing compiler's job is to generate the code you wrote. The optimizing compiler's job is actually to generate the code you would have written if you were an expert on platform-specific optimizations and did not care about maintainability, just performance.

The actual difference between these two statements is that the more powerful emplace_back will call any type of constructor out there, whereas the more cautious push_back will call only constructors that are implicit. Implicit constructors are supposed to be safe. If you can implicitly construct a U from a T, you are saying that U can hold all of the information in T with no loss. It is safe in pretty much any situation to pass a T and no one will mind if you make it a U instead. A good example of an implicit constructor is the conversion from std::uint32_t to std::uint64_t. A bad example of an implicit conversion is double to std::uint8_t.

We want to be cautious in our programming. We do not want to use powerful features because the more powerful the feature, the easier it is to accidentally do something incorrect or unexpected. If you intend to call explicit constructors, then you need the power of emplace_back. If you want to call only implicit constructors, stick with the safety of push_back.

An example

std::vector<std::unique_ptr<T>> v;
T a;
v.emplace_back(std::addressof(a)); // compiles
v.push_back(std::addressof(a)); // fails to compile

std::unique_ptr<T> has an explicit constructor from T *. Because emplace_back can call explicit constructors, passing a non-owning pointer compiles just fine. However, when v goes out of scope, the destructor will attempt to call delete on that pointer, which was not allocated by new because it is just a stack object. This leads to undefined behavior.

This is not just invented code. This was a real production bug I encountered. The code was std::vector<T *>, but it owned the contents. As part of the migration to C++11, I correctly changed T * to std::unique_ptr<T> to indicate that the vector owned its memory. However, I was basing these changes off my understanding in 2012, during which I thought "emplace_back does everything push_back can do and more, so why would I ever use push_back?", so I also changed the push_back to emplace_back.

Had I instead left the code as using the safer push_back, I would have instantly caught this long-standing bug and it would have been viewed as a success of upgrading to C++11. Instead, I masked the bug and didn't find it until months later.

  • 3
    It would help if you could elaborate on what exactly emplace does in your example, and why it's wrong.
    – eddi
    Commented Aug 9, 2016 at 21:50
  • 11
    @eddi: I added a section explaining this: std::unique_ptr<T> has an explicit constructor from T *. Because emplace_back can call explicit constructors, passing a non-owning pointer compiles just fine. However, when v goes out of scope, the destructor will attempt to call delete on that pointer, which was not allocated by new because it is just a stack object. This leads to undefined behavior. Commented Aug 10, 2016 at 0:47
  • 1
    @CaptainJacksparrow: It looks like I say implicit and explicit where I mean them. Which part has you confused? Commented Oct 31, 2017 at 22:22
  • 6
    @CaptainJacksparrow: An explicit constructor is a constructor that has the keyword explicit applied to it. An "implicit" constructor is any constructor that does not have that keyword. In the case of std::unique_ptr's constructor from T *, the implementor of std::unique_ptr wrote that constructor, but the issue here is that the user of that type called emplace_back, which called that explicit constructor. If it had been push_back, instead of calling that constructor, it would have relied on an implicit conversion, which can only call implicit constructors. Commented Nov 2, 2017 at 12:37
  • 3
    Excellent answer. For what it’s worth, Abseil’s Tip of the week #112 argues much the same. Commented Feb 4, 2021 at 11:26

push_back always allows the use of uniform initialization, which I'm very fond of. For instance:

struct aggregate {
    int foo;
    int bar;

std::vector<aggregate> v;
v.push_back({ 42, 121 });

On the other hand, v.emplace_back({ 42, 121 }); will not work.

  • 67
    Note that this only applies to aggregate initialization and initializer-list initialization. If you would be using {} syntax to call an actual constructor, then you can just remove the {}'s and use emplace_back. Commented Jun 5, 2012 at 2:30
  • 1
    @LucDanton: As I said, it only applies to aggregate and initializer-list initialization. You can use {} syntax to call actual constructors. You could give aggregate a constructor that takes 2 integers, and this constructor would be called when using {} syntax. The point being that if you're trying to call a constructor, emplace_back would be preferable, since it calls the constructor in-place. And therefore doesn't require the type to be copyable. Commented Jun 5, 2012 at 13:04
  • 15
    This was viewed as a defect in the standard, and has been resolved. See cplusplus.github.io/LWG/lwg-active.html#2089 Commented Apr 28, 2016 at 15:49
  • 4
    @DavidStone Had it been resolved, it wouldn't still be in the "active" list... no? It appears to remain an outstanding issue. The latest update, headed "[2018-08-23 Batavia Issues processing]", says that "P0960 (currently in flight) should resolve this." And I still can't compile code that tries to emplace aggregates without explicitly writing a boilerplate constructor. It's also unclear at this point whether it'll be treated as a defect and thus eligible for backporting, or whether users of C++ < 20 will remain SoL. Commented Jan 6, 2019 at 15:03
  • 2
    @underscore_d: Excellent point. I had misunderstood the status of the issue when I had posted that comment. Instead, this has been resolved in C++20 by open-std.org/jtc1/sc22/wg21/docs/papers/2019/p0960r3.html, which was voted into the standard. Commented Aug 28, 2020 at 19:50

Backwards compatibility with pre-C++11 compilers.

  • 24
    That seems to be the curse of C++. We get tons of cool features with each new release, but a lot of companies are either stuck using some old version for the sake of compatibility or discouraging (if not disallowing) use of certain features.
    – Dan Albert
    Commented Jul 6, 2013 at 10:37
  • 7
    @Mehrdad: Why settle for sufficient when you can have great? I sure wouldn't want to be programming in blub, even if it was sufficient. Not saying that's the case for this example in particular, but as someone who spends most of his time programming in C89 for the sake of compatibility, it's definitely a real problem.
    – Dan Albert
    Commented Nov 13, 2013 at 22:14
  • 3
    I don't think this is really an answer to the question. To me he's asking for use-cases where push_back is preferable.
    – Mr. Boy
    Commented Nov 3, 2015 at 16:12
  • 4
    @Mr.Boy: It's preferable when you want to be backward-compatible with pre-C++11 compilers. Was that unclear in my answer?
    – user541686
    Commented Jul 18, 2016 at 9:27
  • 9
    This has gotten way more attention than I've expected, so for all of you reading this: emplace_back is not a "great" version of push_back. It's a potentially dangerous version of it. Read the other answers.
    – user541686
    Commented Aug 19, 2017 at 20:51

Some library implementations of emplace_back do not behave as specified in the C++ standard including the version that ship with Visual Studio 2012, 2013 and 2015.

In order to accommodate known compiler bugs, prefer usingstd::vector::push_back() if the parameters reference iterators or other objects which will be invalid after the call.

std::vector<int> v;
v.emplace_back(v[0]); // Produces incorrect results in some compilers

On one compiler, v contains the values 123 and 21 instead of the expected 123 and 123. This is due to the fact that the 2nd call to emplace_back results in a resize at which point v[0] becomes invalid.

A working implementation of the above code would use push_back() instead of emplace_back() as follows:

std::vector<int> v;

Note: The use of a vector of ints is for demonstration purposes. I discovered this issue with a much more complex class which included dynamically allocated member variables and the call to emplace_back() resulted in a hard crash.

  • 15
    The call to emplace_back() uses perfect forwarding to perform construction in place and as such v[0] is not evaluated until after the vector has been resized (at which point v[0] is invalid). push_back constructs the new element and copies/moves the element as needed and v[0] is evaluated prior to any reallocation.
    – Marc
    Commented Mar 6, 2015 at 16:01
  • 1
    @David - Although the new space must exist before the old is destroyed, I don't think that there are any guarantees regarding when the parameter of emplace_back is evaluated. Perfect forwarding enables delayed evaluation. It is my observation that the old vector iterators become invalid before the parameter is evaluated in the compile on which I tested and the details are largely implementation dependent.
    – Marc
    Commented Aug 6, 2015 at 19:23
  • 1
    @Marc: It is guaranteed by the standard that emplace_back works even for elements inside the range. Commented Aug 7, 2015 at 0:28
  • 5
    @cameino: emplace_back exists to delay evaluation of its parameter to reduce unnecessary copying. The behavior is either undefined or a compiler bug (pending analysis of the standard). I recently ran the same test against Visual Studio 2015 and got 123,3 under Release x64, 123,40 under Release Win32 and 123,-572662307 under Debug x64 and Debug Win32.
    – Marc
    Commented Dec 11, 2015 at 21:38
  • 2
    @DavidStone: oh yeah, that does make sense. Thanks. Commented Sep 24, 2021 at 13:54

Consider what happens in Visual Studio 2019 with c++-17 compiler. We have emplace_back in a function with proper arguments set up. Then someone changes parameters of the constuctor called by emplace_back. There is no warning whatsover in VS, the code also compiles fine, then it crashes in runtime. I removed all emplace_back from the codebase after this.

  • 2
    I don't understand what your issue was. Commented Aug 28, 2020 at 19:46

Use push_back only for primitive/built-in types or raw pointers. Otherwise use emplace_back.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

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