using for Enumeration Values
对比一下C++20前后的区别:
enum class State {
open,
progress,
done = 9
};
// Before C++20
void print(State s) {
switch (s) {
case State::open:
std::cout << "open\n";
break;
case State::done:
std::cout << "done\n";
break;
case State::progress:
std::cout << "progress\n";
break;
default:
assert(nullptr);
}
}
// Since C++20
void print1(State s) {
using enum State;
switch (s) {
case open:
std::cout << "open\n";
break;
case done:
std::cout << "done\n";
break;
case progress:
std::cout << "progress\n";
break;
default:
assert(nullptr);
}
}
void print2(State s) {
using State::open, State::done, State::progress;
switch (s) {
case open:
std::cout << "open\n";
break;
case done:
std::cout << "done\n";
break;
case progress:
std::cout << "progress\n";
break;
default:
assert(nullptr);
}
}
Range-Based for Loop with Initialization
基于范围的for循环是C++11引入的新特性,自C++20起,基于范围循环也可以进行初始化。
int main() {
std::vector v{1, 2, 3};
for (int i{1}; const auto& item : v)
std::cout << std::format("{}: {}\n", i++, item);
}
Feature Test Macros
特性测试宏,正如其名,是为了当前版本编译器是否支持某个语言特性。这个宏以__cpp为前缀。
#if __cpp_generic_lambdas >= 201707
// generic lambdas with template parameters can be used
#endif
#ifndef __cpp_lib_as_const
template <typename T>
const T& as_const(T& t) {
return t;
}
#endif
Attribute [[no_unique_address]]
#include <iostream>
struct Empty {};
struct I {
int i;
};
struct S {
Empty e;
int i;
};
int main() {
std::cout << "sizeof(Empty): " << sizeof(Empty) << '\n';
std::cout << "sizeof(I): " << sizeof(I) << '\n';
std::cout << "sizeof(S): " << sizeof(S) << '\n';
}
空类为了区分不同对象的地址,字节大小是1;而结构体S由于内存对齐的原因,所以字节大小是8。输出结果毫无疑问是1,4,8。
#include <iostream>
struct Empty {};
// EBCO
struct S : Empty {
int i;
};
// no_unique_address
struct S2 {
[[no_unique_address]] Empty e;
int i;
};
int main() {
std::cout << "sizeof(Empty): " << sizeof(Empty) << '\n';
std::cout << "sizeof(S): " << sizeof(S) << '\n';
std::cout << "sizeof(S2): " << sizeof(S2) << '\n';
}
注解标签no_unique_address能起到和空基类优化相同的效果。
Attributes [[likely]] and [[unlikely]]
在if/else,switch分支当中都可以使用,帮助编译器作分支预测的优化。
int f(int n) {
if (n <= 0) [[unlikely]] {
return n;
} else {
return n * n;
}
}
int g(int n) {
if (n <= 0) {
return n;
} else [[likely]] {
return n * n;
}
}
int h(int n) {
switch (n) {
case 1:
//
break;
[[likely]] case 2:
//
break;
}
return 0;
}
Attribute [[nodiscard]] with Parameter
nodiscard用于修饰函数,当被修饰的函数发生调用(仅仅调用而不作赋值或者强制转换操作),编译器会报警告信息。
[[nodiscard]]
int f(int n) {
return n;
}
int main() {
f(1); // Warning
int n = f(1); // OK
reinterpret_cast<int *>(f(1)); // OK
}
New Character Type char8_t
using namespace std::literals;
auto c = u8'c'; // char8_t
auto s = u8"Hello World"; // const char8_t *
auto str1 = u8"Hello World"s; // std::u8string
auto str2 = u8"Hello World"sv; // std::u8string_view
std::cout << u8'c' << '\n'; // OK in C++17, error in C++20
std::cout << u8"Hello World\n"; // OK in C++17, error in C++20
std::cout << u8"Hello World\n"s; // OK in C++17, error in C++20
std::cout << u8"Hello World\n"sv; // OK in C++17, error in C++20
std::cout << c << '\n'; // OK in C++17, error in C++20
std::cout << s << '\n'; // OK in C++ 17, error in C++20
std::cout << str1 << '\n'; // OK in C++17, error in C++20
std::cout << str2 << '\n'; // OK in C++17, error in C++20
更多的介绍将在下次带来,感谢支持😃