std::coroutine_traits

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Defined in header <coroutine>
template< class R, class... Args >
struct coroutine_traits;
(since C++20)

Determines the promise type from the return type and parameter types of a coroutine. The standard library implementation provides a publicly accessible member type promise_type same as R::promise_type if the qualified-id is valid and denotes a type. Otherwise, it has no such member.

Program-defined specializations of coroutine_traits shall define a publicly accessible member type promise_type; otherwise, the behavior is undefined.

Template parameters

R - return type of the coroutine
Args - parameter types of the coroutine, including the implicit object parameter if the coroutine is a non-static member function

Member types

Type Definition
promise_type R::promise_type if it is valid, or provided by program-defined specializations

Possible implementation

template<class, class...>
struct coroutine_traits {};
 
template<class R, class... Args>
requires requires { typename R::promise_type; }
struct coroutine_traits<R, Args...>
{
    using promise_type = typename R::promise_type;
};

Notes

If the coroutine is a non-static member function, then the first type in Args... is the type of the implicit object parameter, and the rest are parameter types of the function (if any).

If std::coroutine_traits<R, Args...>::promise_type does not exist or is not a class type, the corresponding coroutine definition is ill-formed.

Users may define explicit or partial specializations of coroutine_traits dependent on program-defined types to avoid modification to return types.

Example

#include <chrono>
#include <coroutine>
#include <exception>
#include <future>
#include <iostream>
#include <thread>
#include <type_traits>
 
// A program-defined type on which the coroutine_traits specializations below depend
struct as_coroutine { };
 
// Enable the use of std::future<T> as a coroutine type
// by using a std::promise<T> as the promise type.
template <typename T, typename... Args>
    requires(!std::is_void_v<T> && !std::is_reference_v<T>)
struct std::coroutine_traits<std::future<T>, as_coroutine, Args...>
{
    struct promise_type : std::promise<T>
    {
        std::future<T> get_return_object() noexcept
        {
            return this->get_future();
        }
 
        std::suspend_never initial_suspend() const noexcept { return {}; }
        std::suspend_never final_suspend() const noexcept { return {}; }
 
        void return_value(const T& value)
            noexcept(std::is_nothrow_copy_constructible_v<T>)
        {
            this->set_value(value);
        }
 
        void return_value(T&& value) noexcept(std::is_nothrow_move_constructible_v<T>)
        {
            this->set_value(std::move(value));
        }
 
        void unhandled_exception() noexcept
        {
            this->set_exception(std::current_exception());
        }
    };
};
 
// Same for std::future<void>.
template <typename... Args>
struct std::coroutine_traits<std::future<void>, as_coroutine, Args...>
{
    struct promise_type : std::promise<void>
    {
        std::future<void> get_return_object() noexcept
        {
            return this->get_future();
        }
 
        std::suspend_never initial_suspend() const noexcept { return {}; }
        std::suspend_never final_suspend() const noexcept { return {}; }
 
        void return_void() noexcept
        {
            this->set_value();
        }
 
        void unhandled_exception() noexcept
        {
            this->set_exception(std::current_exception());
        }
    };
};
 
// Allow co_await'ing std::future<T> and std::future<void>
// by naively spawning a new thread for each co_await.
template <typename T>
auto operator co_await(std::future<T> future) noexcept
    requires(!std::is_reference_v<T>)
{
    struct awaiter : std::future<T>
    {
        bool await_ready() const noexcept
        {
            using namespace std::chrono_literals;
            return this->wait_for(0s) != std::future_status::timeout;
        }
 
        void await_suspend(std::coroutine_handle<> cont) const
        {
            std::thread([this, cont]
            {
                this->wait();
                cont();
            }).detach();
        }
 
        T await_resume() { return this->get(); }
    };
 
    return awaiter { std::move(future) };
}
 
// Utilize the infrastructure we have established.
std::future<int> compute(as_coroutine)
{
    int a = co_await std::async([] { return 6; });
    int b = co_await std::async([] { return 7; });
    co_return a * b;
}
 
std::future<void> fail(as_coroutine)
{
    throw std::runtime_error("bleah");
    co_return;
}
 
int main()
{
    std::cout << compute({}).get() << '\n';
 
    try
    {
        fail({}).get();
    }
    catch (const std::runtime_error& e)
    {
        std::cout << "error: " << e.what() << '\n';
    }
}

Output:

42
error: bleah