ACE Tutorial 015
Building a protocol stream
The Protocol_Task implementation takes care of the open(), close(),
put() and svc() methods so that derivatives can concentrate on the
send() and recv() methods. After a while you find that most
ACE_Task<> derivatives look very similar in the four basic methods and
only need one or two additional to do any real work.
// page13.html,v 1.13 1999/09/22 03:13:53 jcej Exp
#include "Protocol_Task.h"
// Construct the object and remember the thread count.
Protocol_Task::Protocol_Task(void)
{
;
}
Protocol_Task::~Protocol_Task(void)
{
;
}
int Protocol_Task::open(void *arg)
{
ACE_UNUSED_ARG(arg);
return(0);
}
int Protocol_Task::close(u_long flags)
{
return 0;
}
/* When a message is put() onto the task, it's time to process() some data.
*/
int Protocol_Task::put(ACE_Message_Block *message,ACE_Time_Value *timeout)
{
return this->process(message,timeout);
}
/* Return an error since we don't want the task to ever be activated.
*/
int Protocol_Task::svc(void)
{
return -1;
}
/* There's nothing really magic about process(). We just decide if
we're moving data upstream or downstream and invoke the appropriate
virtual function to handle it.
*/
int Protocol_Task::process(ACE_Message_Block * message, ACE_Time_Value *timeout)
{
if( this->is_writer() )
{
return this->send(message,timeout);
}
return this->recv(message,timeout);
}
/* We must insist that derivatives provide a meaningful overload for
these methods. It's fairly common for ACE object methods to return
an error when an overload is expected but the method cannot be
safely made pure virtual.
*/
int Protocol_Task::send(ACE_Message_Block *message,
ACE_Time_Value *timeout)
{
return -1;
}
int Protocol_Task::recv(ACE_Message_Block * message,
ACE_Time_Value *timeout)
{
return -1;
}
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