According to http://www.boost.org/doc/libs/1_55_0/doc/html/boost_asio/overview/cpp2011/futures.html, we can use boost::asio with std::future. But I couldn't find any information about working with boost::unique_future, which has more functions, such as then(). How can I use?


Boost.Asio only provides first-class support for asynchronous operations to return a C++11 std::future or an actual value in stackful coroutines. Nevertheless, the requirements on asynchronous operations documents how to customize the return type for other types, such as Boost.Thread's boost::unique_future. It requires:

  • A specialization of the handler_type template. This template is used to determine the actual handler to use based on the asynchronous operation's signature.
  • A specialization of the async_result template. This template is used both to determine the return type and to extract the return value from the handler.

Below is a minimal complete example demonstrating deadline_timer::async_wait() returning boost:unique_future with a basic calculation being performed over a series of continuations composed with .then(). To keep the example simple, I have opted to only specialize handler_type for the asynchronous operation signatures used in the example. For a complete reference, I highly suggest reviewing use_future.hpp and impl/use_future.hpp.

#include <exception> // current_exception, make_exception_ptr
#include <memory> // make_shared, shared_ptr
#include <thread> // thread
#include <utility> // move


#include <boost/asio.hpp>
#include <boost/date_time/posix_time/posix_time.hpp>
#include <boost/thread/future.hpp>

/// @brief Class used to indicate an asynchronous operation should return
///        a boost::unique_future.
class use_unique_future_t {};

/// @brief A special value, similiar to std::nothrow.
constexpr use_unique_future_t use_unique_future;

namespace detail {

/// @brief Completion handler to adapt a boost::promise as a completion
///        handler.
template <typename T>
class unique_promise_handler;

/// @brief Completion handler to adapt a void boost::promise as a completion
///        handler.
template <>
class unique_promise_handler<void>
  /// @brief Construct from use_unique_future special value.
  explicit unique_promise_handler(use_unique_future_t)
    : promise_(std::make_shared<boost::promise<void> >())

  void operator()(const boost::system::error_code& error)
    // On error, convert the error code into an exception and set it on
    // the promise.
    if (error)
    // Otherwise, set the value.

  std::shared_ptr<boost::promise<void> > promise_;

// Ensure any exceptions thrown from the handler are propagated back to the
// caller via the future.
template <typename Function, typename T>
void asio_handler_invoke(
    Function function,
    unique_promise_handler<T>* handler)
  // Guarantee the promise lives for the duration of the function call.
  std::shared_ptr<boost::promise<T> > promise(handler->promise_);
  catch (...)

} // namespace detail

namespace boost {
namespace asio {

/// @brief Handler type specialization for use_unique_future.
template <typename ReturnType>
struct handler_type<
  typedef ::detail::unique_promise_handler<void> type;

/// @brief Handler traits specialization for unique_promise_handler.
template <typename T>
class async_result< ::detail::unique_promise_handler<T> >
  // The initiating function will return a boost::unique_future.
  typedef boost::unique_future<T> type;

  // Constructor creates a new promise for the async operation, and obtains the
  // corresponding future.
  explicit async_result(::detail::unique_promise_handler<T>& handler)
    value_ = handler.promise_->get_future();

  // Obtain the future to be returned from the initiating function.
  type get() { return std::move(value_); }

  type value_;

} // namespace asio
} // namespace boost

int main()
  boost::asio::io_service io_service;
  boost::asio::io_service::work work(io_service);

  // Run io_service in its own thread to demonstrate future usage.
  std::thread thread([&io_service](){ io_service.run(); });

  // Arm 3 second timer.
  boost::asio::deadline_timer timer(
      io_service, boost::posix_time::seconds(3));

  // Asynchronously wait on the timer, then perform basic calculations
  // within the future's continuations.
  boost::unique_future<int> result =
        .then([](boost::unique_future<void> future){
           std::cout << "calculation 1" << std::endl;
           return 21;
        .then([](boost::unique_future<int> future){
          std::cout << "calculation 2" << std::endl;
          return 2 * future.get();

  std::cout << "Waiting for result" << std::endl;
  // Wait for the timer to trigger and for its continuations to calculate
  // the result.
  std::cout << result.get() << std::endl;

  // Cleanup.


Waiting for result
calculation 1
calculation 2
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