Initializes an object from explicit set of constructor arguments.
T object ( arg ); T object | (1) | |
T object { arg }; | (2) | (since C++11) |
T ( other ) T | (3) | |
static_cast< T >( other ) | (4) | |
new T( args, ... ) | (5) | |
Class::Class() : member( args, ... ) { ... } | (6) | |
[arg]() { ... } | (7) | (since C++11) |
Direct initialization is performed in the following situations:
The effects of direct initialization are:
T is an array type,
| (until C++20) |
struct A
{
explicit A(int i = 0) {}
};
A a[2](A(1)); // OK: initializes a[0] with A(1) and a[1] with A()
A b[2]{A(1)}; // error: implicit copy-list-initialization of b[1]
// from {} selected explicit constructor | (since C++20) |
T is a class type,
| (since C++17) |
T are examined and the best match is selected by overload resolution. The constructor is then called to initialize the object.
struct B
{
int a;
int&& r;
};
int f();
int n = 10;
B b1{1, f()}; // OK, lifetime is extended
B b2(1, f()); // well-formed, but dangling reference
B b3{1.0, 1}; // error: narrowing conversion
B b4(1.0, 1); // well-formed, but dangling reference
B b5(1.0, std::move(n)); // OK | (since C++20) |
T is a non-class type but the source type is a class type, the conversion functions of the source type and its base classes, if any, are examined and the best match is selected by overload resolution. The selected user-defined conversion is then used to convert the initializer expression into the object being initialized. T is bool and the source type is std::nullptr_t, the value of the initialized object is false. T, and the initial value of the object being initialized is the (possibly converted) value. Direct-initialization is more permissive than copy-initialization: copy-initialization only considers non-explicit constructors and non-explicit user-defined conversion functions, while direct-initialization considers all constructors and all user-defined conversion functions.
In case of ambiguity between a variable declaration using the direct-initialization syntax (1) (with round parentheses) and a function declaration, the compiler always chooses function declaration. This disambiguation rule is sometimes counter-intuitive and has been called the most vexing parse.
#include <fstream>
#include <iterator>
#include <string>
int main()
{
std::ifstream file("data.txt");
// The following is a function declaration:
std::string foo1(std::istreambuf_iterator<char>(file),
std::istreambuf_iterator<char>());
// It declares a function called foo1, whose return type is std::string,
// first parameter has type std::istreambuf_iterator<char> and the name "file",
// second parameter has no name and has type std::istreambuf_iterator<char>(),
// which is rewritten to function pointer type std::istreambuf_iterator<char>(*)()
// Pre-C++11 fix (to declare a variable) - add extra parentheses around one
// of the arguments:
std::string str1((std::istreambuf_iterator<char>(file)),
std::istreambuf_iterator<char>());
// Post-C++11 fix (to declare a variable) - use list-initialization for any
// of the arguments:
std::string str2(std::istreambuf_iterator<char>{file}, {});
}#include <iostream>
#include <memory>
#include <string>
struct Foo
{
int mem;
explicit Foo(int n) : mem(n) {}
};
int main()
{
std::string s1("test"); // constructor from const char*
std::string s2(10, 'a');
std::unique_ptr<int> p(new int(1)); // OK: explicit constructors allowed
// std::unique_ptr<int> p = new int(1); // error: constructor is explicit
Foo f(2); // f is direct-initialized:
// constructor parameter n is copy-initialized from the rvalue 2
// f.mem is direct-initialized from the parameter n
// Foo f2 = 2; // error: constructor is explicit
std::cout << s1 << ' ' << s2 << ' ' << *p << ' ' << f.mem << '\n';
}Output:
test aaaaaaaaaa 1 2
explicit new
© cppreference.com
Licensed under the Creative Commons Attribution-ShareAlike Unported License v3.0.
https://en.cppreference.com/w/cpp/language/direct_initialization