问题
Can I break a valid C++03 program by replacing std::vector::push_back with emplace_back and compiling it with C++ 11 compiler? From reading emplace_back reference I gather it shouldn't happen, but I'll admit I don't fully get rvalue references.
回答1:
I constructed a short example that actually fails to compile when push_back is replaced by emplace_back:
#include <vector>
struct S {
S(double) {}
private:
explicit S(int) {}
};
int main() {
std::vector<S>().push_back(0); // OK
std::vector<S>().emplace_back(0); // error!
}
The call to push_back needs to convert its argument 0 from type int to type S. Since this is an implicit conversion, the explicit constructor S::S(int) is not considered, and S::S(double) is called. On the other hand, emplace_back performs direct initialization, so both S::S(double) and S::S(int) are considered. The latter is a better match, but it's private, so the program is ill-formed.
回答2:
Yes, you can change the behavior (more than just avoiding a copy constructor call), since emplace_back only sees imperfectly forwarded arguments.
#include <iostream>
#include <vector>
using namespace std;
struct Arg { Arg( int ) {} };
struct S
{
S( Arg ) { cout << "S(int)" << endl; }
S( void* ) { cout << "S(void*)" << endl; }
};
auto main()
-> int
{
vector<S>().ADD( 0 );
}
Example builds:
[H:\dev\test\0011] > g++ foo.cpp -D ADD=emplace_back && a S(int) [H:\dev\test\0011] > g++ foo.cpp -D ADD=push_back && a S(void*) [H:\dev\test\0011] > _
Addendum: as pointed out by Brian Bi in his answer, another difference that can lead to different behavior is that a push_back call involves an implicit conversion to T, which disregards explicit constructors and conversion operators, while emplace_back uses direct initialization, which does consider also explicit constructors and conversion operators.
回答3:
The emplace versions don't create an object of the desired type at all under exception circumstances. This can lead to a bug.
Consider the following example, which uses std::vector for simplicity (assume uptr behaves like std::unique_ptr, except the constructor is not explicit):
std::vector<uptr<T>> vec;
vec.push_back(new T());
It is exception-safe. A temporary uptr<T> is created to pass to push_back, which is moved into the vector. If reallocation of the vector fails, the allocated T is still owned by a smart pointer which correctly deletes it.
Compare to:
std::vector<uptr<T>> vec;
vec.emplace_back(new T());
emplace_back is not allowed to create a temporary object. The ptr will be created once, in-place in the vector. If reallocation fails, there is no location for in-place creation, and no smart pointer will ever be created. The T will be leaked.
Of course, the best alternative is:
std::vector<std::unique_ptr<T>> vec;
vec.push_back(make_unique<T>());
which is equivalent to the first, but makes the smart pointer creation explicit.
回答4:
If you don't have crazy side-effects in copy constructor of the objects that you hold in your vector, then no.
emplace_back was introduced to optimise-out unnecessary copying and moving.
回答5:
Suppose a user-defined class could be initialized from braced-initializer. e.g.
struct S {
int value;
};
then
std::vector<S> v;
v.push_back({0}); // fine
v.emplace_back({0}); // template type deduction fails
std::vector::emplace_back is template function but std::vector::push_back is non-template function. With a braced-initializer std::vector::emplace_back would fail because template argument deduction fails.
Non-deduced contexts
6) The parameter P, whose A is a braced-init-list, but P is not
std::initializer_listor a reference to one:
LIVE
回答6:
int main() {
std::vector<S>().push_back(0);
std::vector<S>().emplace_back(0);
}
Give struct constructor in emplace_back i.e The above code will be like this
int main() {
std::vector<S>().push_back(0);
std::vector<S>().emplace_back(S(0));
}
来源:https://stackoverflow.com/questions/22080290/are-there-any-cases-where-it-is-incorrect-to-replace-push-back-with-emplace-back