When using std::vectors, std::lists (or other STL containers), I happen to often write this, for code shortness (rather than putting explicit vec[index] every time) and memory allocation efficiency (avoiding a copy/move), and I suppose I'm not the only one to do such:

std::vector<A> vec;
A &element = vec[vec.size()-1];
element.prop = "value";

Why doesn't STL containers' emplace, emplace_back and emplace_front methods return a T&? It would allow one to write simply this rather than using a shady vec.size()-1:

std::vector<A> vec;
A &element = vec.emplace_back();
element.prop = "value";
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    There's vector::back()... – T.C. Jun 26 '14 at 14:23
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    I think the most likely rationale for emplace_back having a void return type is symmetry with the other value insertion methods, such as push_back. It wouldn't be too difficult to write a utility function that does the emplace_back and returns the reference you are looking for. – Niall Jun 26 '14 at 14:26
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    @Deduplicator. Good question, no idea. Legacy (and compatibility) I suppose; maybe it wasn't ever thought of. – Niall Jun 26 '14 at 14:30
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    Someone else is probably also wondering why you can't do: vec.emplace_back().emplace_back() – PeterSW Jun 26 '14 at 14:30
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    I really don't know why they should. Nothing about their name tells me that they should return a value. And it doesn't buy you anything efficiency-wise. – Benjamin Lindley Jun 26 '14 at 14:31

This has been fixed in C++17. Your example

std::vector<A> vec;
A &element = vec.emplace_back();
element.prop = "value";

is valid C++17 code.

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    Why a reference rather than an iterator? – akim May 24 '17 at 7:47
  • @akim Because in the case of a std::vector(-like) container, emplace_font/back() would always return front()/back(), and returning an iterator would require additional indirection to access the emplaced object. – ElementW Jul 1 '17 at 21:13
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    "fixed" is in the eye of the beholder, assuming we thought the lack was a bug and not a feature ;-) but I guess this should be innocuous enough, as it should be trivial to see that the reference is unused and optimise it away. +1 for the info anyway. – underscore_d Jul 17 '17 at 23:05

You have member methods to access those objects, since you know where they have been inserted. Namely front() and back().

Some other functions (e.g. map::insert) would return an iterator because you don't know how to access the inserted element in constant time. In the case of emplace, you do know.

Another reason for not returning anything might be performance (most of the time you would not use the returned value). And in C++ , you pay for what you use.

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    The chance of the compiler optimizing an emplace_back where the return value isn't used are high (since the chance of most of the function being inlined are high and the compiler can simply drop the dead code associated with the return). On the other hand, the chance of the compiler optimizing an emplace_back() followed by a back() are quite low since it would need to optimize across two different functions and "see into" the dynamically allocated to storage and be able to track the value of the size member and see than the just-inserted element is accessed. – BeeOnRope Dec 8 '17 at 5:33
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    This is further complicated by the fact that the emplace flow has a usually-not-lined "grow the vector" slow path, which pretty much means the chance of an optimization across those two functions is close to zero, even if the grow path doesn't usually occur. – BeeOnRope Dec 8 '17 at 5:34

You do not need it. Write this:

template<class C, class...Args>
auto emplace_back(C& c, Args&&...args)->decltype(c.back()){
  return c.back();

and you have the semantics you want without having to modify the container interface.


emplace_back(vec).prop = "foo";

Two arguments for choosing this signature:

  • API symmetry. These APIs are symmetric with pop_back, pop_front and push and pop as implemented for queues. These functions (the pop functions) have a situation where an element can be lost in the presence of an exception (i.e. the element is removed from the collection, but before it is returned an exception occurs (e.g. if the object's constructor can throw).

    By implementing this functionality (read element and pop element) as two separate functions, both can be implemented transactionally.

  • SRP. It is a good design guideline, that if you describe the behavior of a function and need to use the word "and", you have broken SRP and should probably split it in two (i.e. A function that "appends an element at the end and returns a reference to it" should probably be written as two functions "add an element at the end" and "return element at the end" - both of which can offer at least weak exception guarantees to client code).

I am not sure if these criteria were applied for the design, but I remember the exception guarantee argument given in a lecture on exception safety.

  • Beware that in shared data structures, the sequence of two actions "add an element at the end" and "return element at the end" is not the same as the single action "appends an element at the end and returns a reference to that newly added element". – Ben Voigt Mar 3 at 17:13

in c++ 11 you can use:

m.emplace(val1, val2).first

to get a reference to the returned iterator, then:

m.emplace(val1, val2).first->first


m.emplace(val1, val2).first->second

to access map's k and v


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