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/* -*- C++ -*- */
// $Id$
// ============================================================================
//
// = LIBRARY
// ace
//
// = FILENAME
// Reactor_Impl.h
//
// = AUTHOR
// Irfan Pyarali
//
// ============================================================================
#if !defined (ACE_REACTOR_IMPL_H)
#define ACE_REACTOR_IMPL_H
class ACE_Handle_Set;
// Timer Queue is a complicated template class. A simple forward
// declaration will not work
#include "ace/Timer_Queue.h"
// Event_Handler.h contains the definition of ACE_Reactor_Mask
#include "ace/Event_Handler.h"
// We are using 4 or 5 signal classes, we could forward declare
// them.... But Timer_Queue_T.h includes Signal.h, so I don't think
// forward declaration will be useful here
#include "ace/Signal.h"
class ACE_Export ACE_Reactor_Impl
// = TITLE
//
// An abstract class for implementing the Reactor Pattern.
{
public:
virtual ~ACE_Reactor_Impl (void) {};
// Close down and release all resources.
virtual int open (size_t size,
int restart = 0,
ACE_Sig_Handler * = 0,
ACE_Timer_Queue * = 0) = 0;
// Initialization.
virtual int close (void) = 0;
// Close down and release all resources.
// = Event loop drivers.
virtual int handle_events (ACE_Time_Value *max_wait_time = 0) = 0;
virtual int alertable_handle_events (ACE_Time_Value *max_wait_time = 0) = 0;
// This event loop driver blocks for up to <max_wait_time> before
// returning. It will return earlier if events occur. Note that
// <max_wait_time> can be 0, in which case this method blocks
// indefinitely until events occur.
//
// <max_wait_time> is decremented to reflect how much time this call
// took. For instance, if a time value of 3 seconds is passed to
// handle_events and an event occurs after 2 seconds,
// <max_wait_time> will equal 1 second. This can be used if an
// application wishes to handle events for some fixed amount of
// time.
//
// Returns the total number of <ACE_Event_Handler>s that were
// dispatched, 0 if the <max_wait_time> elapsed without dispatching
// any handlers, or -1 if an error occurs.
//
// The only difference between <alertable_handle_events> and
// <handle_events> is that in the alertable case, the eventloop will
// return when the system queues an I/O completion routine or an
// Asynchronous Procedure Call.
virtual int handle_events (ACE_Time_Value &max_wait_time) = 0;
virtual int alertable_handle_events (ACE_Time_Value &max_wait_time) = 0;
// This method is just like the one above, except the
// <max_wait_time> value is a reference and can therefore never be
// NULL.
//
// The only difference between <alertable_handle_events> and
// <handle_events> is that in the alertable case, the eventloop will
// return when the system queues an I/O completion routine or an
// Asynchronous Procedure Call.
// = Register and remove Handlers.
virtual int register_handler (ACE_Event_Handler *event_handler,
ACE_Reactor_Mask mask) = 0;
// Register <event_handler> with <mask>. The I/O handle will always
// come from <get_handle> on the <event_handler>.
virtual int register_handler (ACE_HANDLE io_handle,
ACE_Event_Handler *event_handler,
ACE_Reactor_Mask mask) = 0;
// Register <event_handler> with <mask>. The I/O handle is provided
// through the <io_handle> parameter.
#if defined (ACE_WIN32)
// Originally this interface was available for all platforms, but
// because ACE_HANDLE is an int on non-Win32 platforms, compilers
// are not able to tell the difference between
// register_handler(ACE_Event_Handler*,ACE_Reactor_Mask) and
// register_handler(ACE_Event_Handler*,ACE_HANDLE). Therefore, we
// have restricted this method to Win32 only.
virtual int register_handler (ACE_Event_Handler *event_handler,
ACE_HANDLE event_handle = ACE_INVALID_HANDLE) = 0;
// Register an <event_handler> that will be notified when
// <event_handle> is signaled. Since no event mask is passed
// through this interface, it is assumed that the <event_handle>
// being passed in is an event handle and not an I/O handle.
#endif /* ACE_WIN32 */
virtual int register_handler (ACE_HANDLE event_handle,
ACE_HANDLE io_handle,
ACE_Event_Handler *event_handler,
ACE_Reactor_Mask mask) = 0;
// Register an <event_handler> that will be notified when
// <event_handle> is signaled. <mask> specifies the network events
// that the <event_handler> is interested in.
virtual int register_handler (const ACE_Handle_Set &handles,
ACE_Event_Handler *event_handler,
ACE_Reactor_Mask mask) = 0;
// Register <event_handler> with all the <handles> in the <Handle_Set>.
virtual int register_handler (int signum,
ACE_Event_Handler *new_sh,
ACE_Sig_Action *new_disp = 0,
ACE_Event_Handler **old_sh = 0,
ACE_Sig_Action *old_disp = 0) = 0;
// Register <new_sh> to handle the signal <signum> using the
// <new_disp>. Returns the <old_sh> that was previously registered
// (if any), along with the <old_disp> of the signal handler.
virtual int register_handler (const ACE_Sig_Set &sigset,
ACE_Event_Handler *new_sh,
ACE_Sig_Action *new_disp = 0) = 0;
// Registers <new_sh> to handle a set of signals <sigset> using the
// <new_disp>.
virtual int remove_handler (ACE_Event_Handler *event_handler,
ACE_Reactor_Mask mask) = 0;
// Removes <event_handler>. Note that the I/O handle will be
// obtained using <get_handle> method of <event_handler> . If
// <mask> == <ACE_Event_Handler::DONT_CALL> then the <handle_close>
// method of the <event_handler> is not invoked.
virtual int remove_handler (ACE_HANDLE handle,
ACE_Reactor_Mask mask) = 0;
// Removes <handle>. If <mask> == <ACE_Event_Handler::DONT_CALL>
// then the <handle_close> method of the associated <event_handler>
// is not invoked.
virtual int remove_handler (const ACE_Handle_Set &handle_set,
ACE_Reactor_Mask mask) = 0;
// Removes all handles in <handle_set>. If <mask> ==
// <ACE_Event_Handler::DONT_CALL> then the <handle_close> method of
// the associated <event_handler>s is not invoked.
virtual int remove_handler (int signum,
ACE_Sig_Action *new_disp,
ACE_Sig_Action *old_disp = 0,
int sigkey = -1) = 0;
// Remove the ACE_Event_Handler currently associated with <signum>.
// Install the new disposition (if given) and return the previous
// disposition (if desired by the caller). Returns 0 on success and
// -1 if <signum> is invalid.
virtual int remove_handler (const ACE_Sig_Set &sigset) = 0;
// Calls <remove_handler> for every signal in <sigset>.
// = Suspend and resume Handlers.
virtual int suspend_handler (ACE_Event_Handler *event_handler) = 0;
// Suspend <event_handler> temporarily. Use
// <event_handler->get_handle()> to get the handle.
virtual int suspend_handler (ACE_HANDLE handle) = 0;
// Suspend <handle> temporarily.
virtual int suspend_handler (const ACE_Handle_Set &handles) = 0;
// Suspend all <handles> in handle set temporarily.
virtual int suspend_handlers (void) = 0;
// Suspend all <handles> temporarily.
virtual int resume_handler (ACE_Event_Handler *event_handler) = 0;
// Resume <event_handler>. Use <event_handler->get_handle()> to get
// the handle.
virtual int resume_handler (ACE_HANDLE handle) = 0;
// Resume <handle>.
virtual int resume_handler (const ACE_Handle_Set &handles) = 0;
// Resume all <handles> in handle set.
virtual int resume_handlers (void) = 0;
// Resume all <handles>.
virtual int uses_event_associations (void) = 0;
// Return 1 if we any event associations were made by the reactor
// for the handles that it waits on, 0 otherwise.
// If we need to reset handles returned from accept/connect.
// Timer management.
virtual long schedule_timer (ACE_Event_Handler *event_handler,
const void *arg,
const ACE_Time_Value &delta,
const ACE_Time_Value &interval = ACE_Time_Value::zero) = 0;
// Schedule an <event_handler> that will expire after <delay> amount
// of time. If it expires then <arg> is passed in as the value to
// the <event_handler>'s <handle_timeout> callback method. If
// <interval> is != to <ACE_Time_Value::zero> then it is used to
// reschedule the <event_handler> automatically. This method
// returns a <timer_id> that uniquely identifies the <event_handler>
// in an internal list. This <timer_id> can be used to cancel an
// <event_handler> before it expires. The cancellation ensures that
// <timer_ids> are unique up to values of greater than 2 billion
// timers. As long as timers don't stay around longer than this
// there should be no problems with accidentally deleting the wrong
// timer. Returns -1 on failure (which is guaranteed never to be a
// valid <timer_id>.
virtual int cancel_timer (ACE_Event_Handler *event_handler,
int dont_call_handle_close = 1) = 0;
// Cancel all Event_Handlers that match the address of
// <event_handler>. Returns number of handlers cancelled.
virtual int cancel_timer (long timer_id,
const void **arg = 0,
int dont_call_handle_close = 1) = 0;
// Cancel the single Event_Handler that matches the <timer_id> value
// (which was returned from the schedule method). If arg is
// non-NULL then it will be set to point to the ``magic cookie''
// argument passed in when the Event_Handler was registered. This
// makes it possible to free up the memory and avoid memory leaks.
// Returns 1 if cancellation succeeded and 0 if the <timer_id>
// wasn't found.
// = High-level Event_Handler scheduling operations
virtual int schedule_wakeup (ACE_Event_Handler *event_handler,
ACE_Reactor_Mask masks_to_be_added) = 0;
// Add <masks_to_be_added> to the <event_handler>'s entry.
// <event_handler> must already have been registered.
virtual int schedule_wakeup (ACE_HANDLE handle,
ACE_Reactor_Mask masks_to_be_added) = 0;
// Add <masks_to_be_added> to the <handle>'s entry. <event_handler>
// associated with <handle> must already have been registered.
virtual int cancel_wakeup (ACE_Event_Handler *event_handler,
ACE_Reactor_Mask masks_to_be_cleared) = 0;
// Clear <masks_to_be_cleared> from the <event_handler>'s entry.
virtual int cancel_wakeup (ACE_HANDLE handle,
ACE_Reactor_Mask masks_to_be_cleared) = 0;
// Clear <masks_to_be_cleared> from the <handle>'s entry.
// = Notification methods.
virtual int notify (ACE_Event_Handler *event_handler = 0,
ACE_Reactor_Mask mask = ACE_Event_Handler::EXCEPT_MASK,
ACE_Time_Value * = 0) = 0;
// Notify <event_handler> of <mask> event. The <ACE_Time_Value>
// indicates how long to blocking trying to notify. If <timeout> ==
// 0, the caller will block until action is possible, else will wait
// until the relative time specified in <timeout> elapses).
virtual void max_notify_iterations (int) = 0;
// Set the maximum number of times that ACE_Reactor_Impl will
// iterate and dispatch the <ACE_Event_Handlers> that are passed in
// via the notify queue before breaking out of its
// <ACE_Message_Queue::dequeue> loop. By default, this is set to
// -1, which means "iterate until the queue is empty." Setting this
// to a value like "1 or 2" will increase "fairness" (and thus
// prevent starvation) at the expense of slightly higher dispatching
// overhead.
virtual int max_notify_iterations (void) = 0;
// Get the maximum number of times that the ACE_Reactor_Impl will
// iterate and dispatch the <ACE_Event_Handlers> that are passed in
// via the notify queue before breaking out of its
// <ACE_Message_Queue::dequeue> loop.
virtual int handler (ACE_HANDLE handle,
ACE_Reactor_Mask mask,
ACE_Event_Handler **event_handler = 0) = 0;
// Check to see if <handle> is associated with a valid Event_Handler
// bound to <mask>. Return the <event_handler> associated with this
// <handler> if <event_handler> != 0.
virtual int handler (int signum,
ACE_Event_Handler ** = 0) = 0;
// Check to see if <signum> is associated with a valid Event_Handler
// bound to a signal. Return the <event_handler> associated with
// this <handler> if <event_handler> != 0.
virtual int initialized (void) = 0;
// Returns true if Reactor has been successfully initialized, else
// false.
virtual size_t size (void) = 0;
// Returns the current size of the Reactor's internal descriptor
// table.
virtual ACE_Lock &lock (void) = 0;
// Returns a reference to the Reactor's internal lock.
virtual void wakeup_all_threads (void) = 0;
// Wake up all threads in waiting in the event loop
virtual int owner (ACE_thread_t new_owner, ACE_thread_t *old_owner = 0) = 0;
// Transfers ownership of Reactor_Impl to the <new_owner>.
virtual int owner (ACE_thread_t *owner) = 0;
// Return the ID of the "owner" thread.
virtual void requeue_position (int) = 0;
// Set position of the owner thread.
virtual int requeue_position (void) = 0;
// Get position of the owner thread.
// = Low-level wait_set mask manipulation methods.
virtual int mask_ops (ACE_Event_Handler *event_handler,
ACE_Reactor_Mask mask,
int ops) = 0;
// GET/SET/ADD/CLR the dispatch mask "bit" bound with the
// <event_handler> and <mask>.
virtual int mask_ops (ACE_HANDLE handle,
ACE_Reactor_Mask mask,
int ops) = 0;
// GET/SET/ADD/CLR the dispatch MASK "bit" bound with the <handle>
// and <mask>.
// = Low-level ready_set mask manipulation methods.
virtual int ready_ops (ACE_Event_Handler *event_handler,
ACE_Reactor_Mask mask,
int ops) = 0;
// GET/SET/ADD/CLR the ready "bit" bound with the <event_handler>
// and <mask>.
virtual int ready_ops (ACE_HANDLE handle,
ACE_Reactor_Mask,
int ops) = 0;
// GET/SET/ADD/CLR the ready "bit" bound with the <handle> and <mask>.
ACE_ALLOC_HOOK_DECLARE;
// Declare the dynamic allocation hooks.
};
#endif /* ACE_REACTOR_IMPL_H */
|