ACE Tutorial 001
A Beginners Guide to Using the ACE Toolkit
Now we begin to look at the acceptor object.
Kirthika has this analogy:
Reactor: Receptionist
Event_Handlers: various Departments catering to specific needs.
SERVER_PORT: door
Acceptor: Doorkeeper
Thus when a needy person (client) enters the open door (port) maintained by the doorkeeper (acceptor waiting for connection request), the receptionist(reactor) directs the person towards the appropriate section (event_handler) which would cater to his needs.
// page03.html,v 1.13 2000/03/19 20:09:19 jcej Exp #ifndef _CLIENT_ACCEPTOR_H #define _CLIENT_ACCEPTOR_H /* A SOCK_Acceptor knows how to accept socket connections. We'll use one of those at the heart of our Logging_Acceptor. */ #include "ace/SOCK_Acceptor.h" #if !defined (ACE_LACKS_PRAGMA_ONCE) # pragma once #endif /* ACE_LACKS_PRAGMA_ONCE */ /* An Event_Handler is what you register with ACE_Reactor. When events occur, the reactor will callback on the Event_Handler. More on that in a few lines. */ #include "ace/Event_Handler.h" /* When a client connects, we'll create a Logging_Handler to deal with the connection. Here, we bring in that declaration. */ #include "logger.h" /* Our Logging_Acceptor is derived from ACE_Event_Handler. That lets the reactor treat our acceptor just like every other handler. */ class Logging_Acceptor : public ACE_Event_Handler { public: /* For this simple case we won't bother with either constructor or destructor. In a real application you would certainly have them. */ /* Here's the open() method we called from main(). We have two things to accomplish here: (1) Open the acceptor so that we can hear client requests and (2) register ourselves with the reactor so that we can respond to those requests. */ int open (const ACE_INET_Addr &addr, ACE_Reactor *reactor) { /* Perform the open() on the acceptor. We pass through the address at which main() wants us to listen. The second parameter tells the acceptor it is OK to reuse the address. This is necessary sometimes to get around closed connections that haven't timed out. */ if (this->peer_acceptor_.open (addr, 1) == -1) return -1; /* Remember the reactor we're using. We'll need it later when we create a client connection handler. */ reactor_ = reactor; /* Now we can register with the reactor we were given. Since the reactor pointer is global, we could have just used that but it's gross enough already. Notice that we can pass 'this' right into the registration since we're derived from ACE_Event_Handler. We also provide ACCEPT_MASK to tell the reactor that we want to know about accept requests from clients. */ return reactor->register_handler (this, ACE_Event_Handler::ACCEPT_MASK); } private: /* To provide multi-OS abstraction, ACE uses the concept of "handles" for connection endpoints. In Unix, this is a traditional file descriptor (or integer). On other OS's, it may be something else. The reactor will need to get the handle (file descriptor) to satisfy it's own internal needs. Our relevant handle is the handle of the acceptor object, so that's what we provide. */ ACE_HANDLE get_handle (void) const { return this->peer_acceptor_.get_handle (); } /* When an accept request arrives, the reactor will invoke the handle_input() callback. This is where we deal with the connection request. */ virtual int handle_input (ACE_HANDLE handle) { /* The handle provided to us by the reactor is the one that triggered our up-call. In some advanced situations, you might actually register a single handler for multiple connections. The _handle parameter is a way to sort 'em out. Since we don't use that here, we simply ignore the parameter with the ACE_UNUSED_ARG() macro. */ ACE_UNUSED_ARG (handle); Logging_Handler *svc_handler; /* In response to the connection request, we create a new Logging_Handler. This new object will be used to interact with the client until it disconnects. Note how we use the ACE_NEW_RETURN macro, which returns -1 if operator new fails. */ ACE_NEW_RETURN (svc_handler, Logging_Handler, -1); /* To complete the connection, we invoke the accept() method call on the acceptor object and provide it with the connection handler instance. This transfers "ownership" of the connection from the acceptor to the connection handler. */ if (this->peer_acceptor_.accept (*svc_handler) == -1) ACE_ERROR_RETURN ((LM_ERROR, "%p", "accept failed"), -1); /* Again, most objects need to be open()ed before they are useful. We'll give the handler our reactor pointer so that it can register for events as well. If the open fails, we'll force a close(). */ if (svc_handler->open (reactor_) == -1) svc_handler->close (); return 0; } protected: /* Our acceptor object instance */ ACE_SOCK_Acceptor peer_acceptor_; /* A place to remember our reactor pointer */ ACE_Reactor *reactor_; }; #endif /* _CLIENT_ACCEPTOR_H */
Now that we know how to accept a connection request, let's move on to the next page where we learn how to handle the actual connection. Even though we just learned about this cool template thing, we will continue to use the "hand-written" acceptor developed above. As I mentioned, the only difference will be in the open function of the connection handler anyway.