list initialization (since C++11)

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C++
 
C++ language
 
Initialization
 

Initializes an object from braced-init-list

Syntax

direct-list-initialization

T object { arg1, arg2, ... }; (1)
T { arg1, arg2, ... } (2)
new T { arg1, arg2, ... } (3)
Class { T member { arg1, arg2, ... }; }; (4)
Class::Class() : member{arg1, arg2, ...} {... (5)

copy-list-initialization

T object = {arg1, arg2, ...}; (6)
function( { arg1, arg2, ... } ) (7)
return { arg1, arg2, ... } ; (8)
object[ { arg1, arg2, ... } ] (9)
object = { arg1, arg2, ... } (10)
U( { arg1, arg2, ... } ) (11)
Class { T member = { arg1, arg2, ... }; }; (12)

List initialization is performed in the following situations:

  • direct-list-initialization (both explicit and non-explicit constructors are considered)
1) initialization of a named variable with a braced-init-list (that is, a possibly empty brace-enclosed list of expressions or nested braced-init-lists)
2) initialization of an unnamed temporary with a braced-init-list
3) initialization of an object with dynamic storage duration with a new-expression, where the initializer is a brace-init-list
4) in a non-static data member initializer that does not use the equals sign
5) in a member initializer list of a constructor if braced-init-list is used
  • copy-list-initialization (both explicit and non-explicit constructors are considered, but only non-explicit constructors may be called)
6) initialization of a named variable with a braced-init-list after an equals sign
7) in a function call expression, with braced-init-list used as an argument and list-initialization initializes the function parameter
8) in a return statement with braced-init-list used as the return expression and list-initialization initializes the returned object
9) in a subscript expression with a user-defined operator[], where list-initialization initializes the parameter of the overloaded operator
10) in an assignment expression, where list-initialization initializes the parameter of the overloaded operator
11) functional cast expression or other constructor invocations, where braced-init-list is used in place of a constructor argument. Copy-list-initialization initializes the constructor's parameter (note; the type U in this example is not the type that's being list-initialized; U's constructor's parameter is)
12) in a non-static data member initializer that uses the equals sign

Explanation

The effects of list initialization of an object of type T are:

  • If T is an aggregate type and the initializer list has a single element of the same or derived type (possibly cv-qualified), the object is initialized from that element (by copy-initialization for copy-list-initialization, or by direct-initialization for direct-list-initialization).
  • Otherwise, if T is a character array and the initializer list has a single element that is an appropriately-typed string literal, the array is initialized from the string literal as usual.
(since C++14)
  • If the braced-init-list is empty and T is a class type with a default constructor, value-initialization is performed.
(until C++14)
  • Otherwise, If the braced-init-list is empty and T is a class type with a default constructor, value-initialization is performed.
(since C++14)
  • Otherwise, if T is a specialization of std::initializer_list, the T object is direct-initialized or copy-initialized, depending on context, from a prvalue of the same type initialized from (until C++17) the braced-init-list.
  • Otherwise, the constructors of T are considered, in two phases:
  • If the previous stage does not produce a match, all constructors of T participate in overload resolution against the set of arguments that consists of the elements of the braced-init-list, with the restriction that only non-narrowing conversions are allowed. If this stage produces an explicit constructor as the best match for a copy-list-initialization, compilation fails (note, in simple copy-initialization, explicit constructors are not considered at all).
  • Otherwise, if T is a enumeration type that is either scoped or unscoped with fixed underlying type, and if the braced-init-list has only one initializer, and if the conversion from the initializer to the underlying type is non-narrowing, and if the initialization is direct-list-initialization, then the enumeration is initialized with the result of converting the initializer to its underlying type.
(since C++17)
  • Otherwise (if T is not a class type), if the braced-init-list has only one element and either T isn't a reference type or is a reference type that is compatible with the type of the element, T is direct-initialized (in direct-list-initialization) or copy-initialized (in copy-list-initialization), except that narrowing conversions are not allowed.
  • Otherwise, if T is a reference type that isn't compatible with the type of the element, a temporary of the referenced type is list-initialized, and the reference is bound to that temporary. (this fails if the reference is a non-const lvalue reference)

Narrowing conversions

list-initialization limits the allowed implicit conversions by prohibiting the following:

  • conversion from a floating-point type to an integer type
  • conversion from a long double to double or to float and conversion from double to float, except where the source is a constant expression and overflow does not occur
  • conversion from an integer type to a floating-point type, except where the source is a constant expression whose value can be stored exactly in the target type
  • conversion from integer or unscoped enumeration type to integer type that cannot represent all values of the original, except where source is a constant expression whose value can be stored exactly in the target type

Notes

Every initializer clause is sequenced before any initializer clause that follows it in the braced-init-list. This is in contrast with the arguments of a function call expression, which are unsequenced.

A braced-init-list is not an expression and therefore has no type, e.g. decltype({1,2}) is ill-formed. Having no type implies that template type deduction cannot deduce a type that matches a braced-init-list, so given the declaration template<class T> void f(T); the expression f({1,2,3}) is ill-formed. However, the template parameter can otherwise be deduced, as is the case for std::vector<int> v(std::istream_iterator<int>(std::cin), {}), where the iterator type is deduced by the first argument but also used in the second parameter position. A special exception is made for type deduction using the keyword auto , which deduces any braced-init-list as std::initializer_list.

Also because braced-init-list has no type, special rules for overload resolution apply when it is used as an argument to an overloaded function call.

Aggregates copy/move initialize directly from single-element braced-init-lists of the same type, but non-aggregates consider initializer_list constructors first: 

struct X {
    X() = default;
    X(const X&) = default;
};
 
struct Q {
    Q() = default;
    Q(Q const&) = default;
    Q(std::initializer_list<Q>) {}
};
 
int main() {
  X x;
  X x2 = X { x }; // copy-constructor (not aggregate initialization)
  Q q;
  Q q2 = Q { q }; // initializer-list constructor (not copy constructor)
}
 (since C++14)

Example

Run this code
#include <iostream>
#include <vector>
#include <map>
#include <string>
 
struct Foo {
    std::vector<int> mem = {1,2,3}; // list-initialization of a non-static member
    std::vector<int> mem2;
    Foo() : mem2{-1, -2, -3} {} // list-initialization of a member in constructor
};
 
std::pair<std::string, std::string> f(std::pair<std::string, std::string> p)
{
    return {p.second, p.first}; // list-initialization in return statement
}
 
int main()
{
    int n0{};     // value-initialization (to zero)
    int n1{1};    // direct-list-initialization
    std::string s1{'a', 'b', 'c', 'd'}; // initializer-list constructor call
    std::string s2{s1, 2, 2};           // regular constructor call
    std::string s3{0x61, 'a'}; // initializer-list ctor is preferred to (int, char)
 
    int n2 = {1}; // copy-list-initialization
    double d = double{1.2}; // list-initialization of a temporary, then copy-init
 
    std::map<int, std::string> m = { // nested list-initialization
           {1, "a"},
           {2, {'a', 'b', 'c'} },
           {3, s1}
    };
 
    std::cout << f({"hello", "world"}).first // list-initialization in function call
              << '\n';
 
    const int (&ar)[2] = {1,2}; // binds a lvalue reference to a temporary array
    int&& r1 = {1}; // binds a rvalue reference to a temporary int
//  int& r2 = {2}; // error: cannot bind rvalue to a non-const lvalue ref
 
//  int bad{1.0}; // error: narrowing conversion
    unsigned char uc1{10}; // okay
//  unsigned char uc2{-1}; // error: narrowing conversion
 
    Foo f;
 
    std::cout << n0 << ' ' << n1 << ' ' << n2 << '\n'
              << s1 << ' ' << s2 << ' ' << s3 << '\n';
    for(auto p: m)
        std::cout << p.first << ' ' << p.second << '\n';
    for(auto n: f.mem)
        std::cout << n << ' ';
    for(auto n: f.mem2)
        std::cout << n << ' ';
}

Output: 

world
0 1 1
abcd cd aa
1 a
2 abc
3 abcd
1 2 3 -1 -2 -3

Defect reports

The following behavior-changing defect reports were applied retroactively to previously published C++ standards.

DR Applied to Behavior as published Correct behavior
CWG 1467 C++14 same-type initialization of aggregates and char arrays was prohibited same-type initialization allowed
CWG 1467 C++14 std::initializer_list constructors had priority over copy constructors for single-element lists single-element lists initialize directly

See also

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