The question has a degree of uncertainty as if multiple
io_service objects are required. I could not locate anything in the reference documentation, or the overview for SSL and UNIX Domain Sockets that mandated separate
io_service objects. Regardless, here are a few options:
Try to use a single
If you do not have a direct handle to the
io_service object, but you have a handle to a Boost.Asio I/O object, such as a socket, then a handle to the associated
io_service object can be obtained by calling
Use a thread per
io_service objects are required, then dedicate a thread to each
io_service. This approach is used in Boost.Asio's HTTP Server 2 example.
One consequence of this approach is that the it may require thread-safety guarantees to be made by the application. For example, if
service2 both have completion handlers that invoke
message_processor.process() needs to either be thread-safe or called in a thread-safe manner.
io_service provides non-blocking alternatives to
run(). Where as
io_service::run() will block until all work has finished,
io_service::poll() will run handlers that are ready to run and will not block. This allows for a single thread to execute the event loop on multiple
while (!service1.stopped() &&
std::size_t ran = 0;
ran += service1.poll();
ran += service2.poll();
// If no handlers ran, then sleep.
if (0 == ran)
To prevent a tight-busy loop when there are no ready-to-run handlers, it may be worth adding in a sleep. Be aware that this sleep may introduce latency in the overall handling of events.
Transfer handlers to a single
One interesting approach is to use a
strand to transfer completion handlers to a single
io_service. This allows for a thread per
io_service, while preventing the need to have the application make thread-safety guarantees, as all completion handlers will post through a single service, whose event loop is only being processed by a single thread.
// strand2 will be used by service2 to post handlers to service1.
This approach does have some consequences:
- It requires handlers that are intended to by ran by the main
io_service to be wrapped via
- The asynchronous chain now runs through two
io_services, creating an additional level of complexity. It is important to account for the case where the secondary
io_service no longer has work, causing its
run() to return.
It is common for an asynchronous chains to occur within the same
io_service. Thus, the service never runs out of work, as a completion handler will post additional work onto the
V V |
socket.async_read_some(..., read_some_handler) --'
On the other hand, when a strand is used to transfer work to another
io_service, the wrapped handler is invoked within
service2, causing it to post the completion handler into
service1. If the wrapped handler was the only work in
service2 no longer has work, causing
servce2.run() to return.
read_some_handler NO WORK
To account for this, the example code uses an
service2 so that
run() remains blocked until explicitly told to