Reactor pattern

The reactor design pattern is an event handling pattern for handling service requests delivered concurrently to a service handler by one or more inputs. The service handler then demultiplexes the incoming requests and dispatches them synchronously to the associated request handlers.[1]

Structure

Resources
Any resource that can provide input to or consume output from the system.
Synchronous Event Demultiplexer
Uses an event loop to block on all resources. The demultiplexer sends the resource to the dispatcher when it is possible to start a synchronous operation on a resource without blocking (Example: a synchronous call to read() will block if there is no data to read. The demultiplexer uses select() on the resource, which blocks until the resource is available for reading. In this case, a synchronous call to read() won't block, and the demultiplexer can send the resource to the dispatcher.)
Dispatcher
Handles registering and unregistering of request handlers. Dispatches resources from the demultiplexer to the associated request handler.
Request Handler
An application defined request handler and its associated resource.

Properties

All reactor systems are single-threaded by definition, but can exist in a multithreaded environment.

Benefits

The reactor pattern completely separates application-specific code from the reactor implementation, which means that application components can be divided into modular, reusable parts.

Limitations

The reactor pattern can be more difficult to debug[2] than a procedural pattern due to the inverted flow of control. Also, by only calling request handlers synchronously, the reactor pattern limits maximum concurrency, especially on symmetric multiprocessing hardware. The scalability of the reactor pattern is limited not only by calling request handlers synchronously, but also by the demultiplexer.[3]

See also

References

  1. Schmidt, Douglas et al. Pattern-Oriented Software Architecture Volume 2: Patterns for Concurrent and Networked Objects. Volume 2. Wiley, 2000.
  2. Schmidt, Douglas C., An Object Behavioral Pattern for Demultiplexing and Dispatching Handles for Synchronous Events (PDF)
  3. Kegel, Dan, The C10K problem, retrieved 2007-07-28
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