/* -*- C++ -*- */ // $Id$ // ============================================================================ // // = LIBRARY // ace // // = FILENAME // Reactor.h // // = AUTHOR // Doug Schmidt // // ============================================================================ #if !defined (ACE_REACTOR_H) #define ACE_REACTOR_H #include "ace/Handle_Set.h" #include "ace/Timer_Queue.h" #include "ace/Signal.h" #include "ace/Thread.h" #include "ace/Token.h" #include "ace/Pipe.h" #include "ace/SOCK_Stream.h" // Add useful typedefs to simplify the following code. typedef void (ACE_Handle_Set::*ACE_FDS_PTMF) (ACE_HANDLE); typedef int (ACE_Event_Handler::*ACE_EH_PTMF) (ACE_HANDLE); // Forward declaration. class ACE_Reactor; class ACE_Export ACE_Reactor_Handle_Set // = TITLE // Track handles we are interested for various events. { public: ACE_Handle_Set rd_mask_; // Read events (e.g., input pending, accept pending). ACE_Handle_Set wr_mask_; // Write events (e.g., flow control abated, non-blocking connection // complete). ACE_Handle_Set ex_mask_; // Exception events (e.g., SIG_URG). }; #if defined (ACE_MT_SAFE) && (ACE_MT_SAFE != 0) #if defined (ACE_REACTOR_HAS_DEADLOCK_DETECTION) #include "ace/Local_Tokens.h" typedef ACE_Local_Mutex ACE_REACTOR_MUTEX; #else typedef ACE_Token ACE_REACTOR_MUTEX; #endif /* ACE_REACTOR_HAS_DEADLOCK_DETECTION */ class ACE_Export ACE_Reactor_Token : public ACE_REACTOR_MUTEX // = TITLE // Used as a synchronization mechanism to coordinate concurrent // access to a Reactor object. { public: ACE_Reactor_Token (ACE_Reactor &r); virtual void sleep_hook (void); // Called just before the ACE_Event_Handler goes to sleep. void dump (void) const; // Dump the state of an object. ACE_ALLOC_HOOK_DECLARE; // Declare the dynamic allocation hooks. private: ACE_Reactor &reactor_; }; #else // If we're non-MT safe then this is just a no-op... typedef ACE_Null_Mutex ACE_Reactor_Token; #endif /* ACE_MT_SAFE */ // The following two classes have to be moved out here to keep the SGI // C++ compiler happy (it doesn't like nested classes). class ACE_Export ACE_Reactor_Notify : public ACE_Event_Handler // = TITLE // Unblock the from its event loop. // // = DESCRIPTION // This implementation is necessary for cases where the // is run in a multi-threaded program. In this // case, we need to be able to unblock select() or poll() when // updates occur other than in the main thread. // To do this, we signal an auto-reset event the // is listening on. If an and // is passed to , the appropriate // method is dispatched in the context of the // thread. { public: // = Initialization and termination methods. int open (ACE_Reactor *); int close (void); int dispatch_notifications (int &number_of_active_handles, const ACE_Handle_Set &rd_mask); // Handles pending threads (if any) that are waiting to unblock the // Reactor. ssize_t notify (ACE_Event_Handler * = 0, ACE_Reactor_Mask = ACE_Event_Handler::EXCEPT_MASK, ACE_Time_Value * = 0); // Called by a thread when it wants to unblock the Reactor. This // wakeups the if currently blocked in // select()/poll(). Pass over both the *and* the // to allow the caller to dictate which // method the will invoke. The indicates // how long to blocking trying to notify the . If // == 0, the caller will block until action is possible, // else will wait until the relative time specified in * // elapses). virtual int handle_input (ACE_HANDLE handle); // Called back by the Reactor when a thread wants to unblock us. void dump (void) const; // Dump the state of an object. ACE_ALLOC_HOOK_DECLARE; // Declare the dynamic allocation hooks. private: ACE_Reactor *reactor_; // Keep a back pointer to the Reactor. ACE_Pipe notification_pipe_; // Contains the HANDLE the Reactor is listening on, as well as the // HANDLE that threads wanting the attention of the Reactor will // write to. }; class ACE_Export ACE_Reactor_Handler_Repository // = TITLE // Used to map s onto the appropriate // *. // // = DESCRIPTION // This class is necessary to shield differences between UNIX // and Win32. In UNIX, is an int, whereas in Win32 // it's a void *. This class hides all these details from the // bulk of the code. All of these methods are // called with the main token lock held. { public: friend class ACE_Reactor_Handler_Repository_Iterator; // = Initialization and termination methods. ACE_Reactor_Handler_Repository (ACE_Reactor &); // Default "do-nothing" constructor. int open (size_t size); // Initialize a repository of the appropriate . int close (void); // Close down the repository. // = Search structure operations. ACE_Event_Handler *find (ACE_HANDLE handle, size_t *index_p = 0); // Return the associated with . // If is non-0, then return the index location of the // , if found. int bind (ACE_HANDLE, ACE_Event_Handler *, ACE_Reactor_Mask); // Bind the to the with the // appropriate settings. int unbind (ACE_HANDLE, ACE_Reactor_Mask mask); // Remove the binding of in accordance with the . int unbind_all (void); // Remove all the tuples. // = Sanity checking. // Check the to make sure it's a valid ACE_HANDLE that // within the range of legal handles (i.e., >= 0 && < max_size_). int invalid_handle (ACE_HANDLE handle); // Check the to make sure it's a valid ACE_HANDLE that // within the range of currently registered handles (i.e., >= 0 && < // max_handlep1_). int handle_in_range (ACE_HANDLE handle); // = Accessors. size_t max_handlep1 (void); // Maximum ACE_HANDLE value, plus 1. void dump (void) const; // Dump the state of an object. ACE_ALLOC_HOOK_DECLARE; // Declare the dynamic allocation hooks. private: ACE_Reactor &reactor_; // Reference to our . ssize_t max_size_; // Maximum number of handles. int max_handlep1_; // The highest currently active handle, plus 1 (ranges between 0 and // . #if defined (ACE_WIN32) // = This structure maps to . struct ACE_NT_EH_Record { ACE_HANDLE handle_; ACE_Event_Handler *event_handler_; }; ACE_NT_EH_Record *event_handlers_; // The NT version implements this via a dynamically allocated // array of . Since NT implements ACE_HANDLE // as a void * we can't directly index into this array. Therefore, // we just do a linear search (for now). Next, we'll modify // things to use hashing or something faster... #else ACE_Event_Handler **event_handlers_; // The UNIX version implements this via a dynamically allocated // array of that is indexed directly using // the ACE_HANDLE value. #endif /* ACE_WIN32 */ }; class ACE_Export ACE_Reactor_Handler_Repository_Iterator // = TITLE // Iterate through the . { public: // = Initialization method. ACE_Reactor_Handler_Repository_Iterator (const ACE_Reactor_Handler_Repository *s); // = Iteration methods. int next (ACE_Event_Handler *&next_item); // Pass back the that hasn't been seen in the Set. // Returns 0 when all items have been seen, else 1. int done (void) const; // Returns 1 when all items have been seen, else 0. int advance (void); // Move forward by one element in the set. Returns 0 when all the // items in the set have been seen, else 1. void dump (void) const; // Dump the state of an object. ACE_ALLOC_HOOK_DECLARE; // Declare the dynamic allocation hooks. private: const ACE_Reactor_Handler_Repository *rep_; // Reference to the Handler_Repository we are iterating over. ssize_t current_; // Pointer to the current iteration level. }; class ACE_Export ACE_Reactor // = TITLE // An object oriented event demultiplexor and event handler // dispatcher. // // = DESCRIPTION // The ACE_Reactor is an object-oriented event demultiplexor // and event handler dispatcher. The sources of events that the // ACE_Reactor waits for and dispatches includes I/O events, // signals, and timer events. All public methods acquire the // main token lock and call down to private or // protected methods, which assume that the lock is held and so // therefore don't (re)acquire the lock. { public: enum { DEFAULT_SIZE = ACE_DEFAULT_REACTOR_SIZE, // Default size of the Reactor's handle table. // = Operations on the "ready" mask and the "dispatch" mask. GET_MASK = 1, // Retrieve current value of the the "ready" mask or the "dispatch" mask. SET_MASK = 2, // Set value of bits to new mask (changes the entire mask). ADD_MASK = 3, // Bitwise "or" the value into the mask (only changes enabled bits). CLR_MASK = 4 // Bitwise "and" the negation of the value out of the mask (only changes enabled bits). }; // = Initialization and termination methods. ACE_Reactor (ACE_Sig_Handler * = 0, ACE_Timer_Queue * = 0); // Initialize with the default size. ACE_Reactor (size_t size, int restart = 0, ACE_Sig_Handler * = 0, ACE_Timer_Queue * = 0); // Initialize with size . static ACE_Reactor *instance (size_t size = ACE_Reactor::DEFAULT_SIZE); // Get pointer to a process-wide . static ACE_Reactor *instance (ACE_Reactor *); // Set pointer to a process-wide and return existing // pointer. static void close_singleton (void); // Delete the dynamically allocated Singleton // = Reactor event loop management methods. static int run_event_loop (void); // Run the event loop until the method // returns -1 or the method is invoked. static int run_event_loop (ACE_Time_Value &tv); // Run the event loop until the method // returns -1, the method is invoked, or the // expires. static int end_event_loop (void); // Instruct the to terminate its event loop and // notifies the so that it can wake up // and close down gracefully. static sig_atomic_t event_loop_done (void); // Report if the 's event loop is finished. virtual int open (size_t size = DEFAULT_SIZE, int restart = 0, ACE_Sig_Handler * = 0, ACE_Timer_Queue * = 0); // Initialize with size . virtual void close (void); // Close down the reactor and release all of its resources. virtual ~ACE_Reactor (void); // Close down the reactor and release all of its resources. // = Event loop drivers. virtual int handle_events (ACE_Time_Value *max_wait_time = 0); // This event loop driver that blocks for before // returning. It will return earlier if timer events, I/O events, // or signal events occur. Note that can be 0, in // which case this method blocks indefinitely until events occur. // // 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, // 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 s that were // dispatched, 0 if the elapsed without dispatching // any handlers, or -1 if something goes wrong. virtual int handle_events (ACE_Time_Value &max_wait_time); // This method is just like the one above, except the // value is a reference and can therefore never be // NULL. // = Register and remove s. virtual int register_handler (ACE_Event_Handler *eh, ACE_Reactor_Mask mask); // Register a with a particular . Note that the // will call eh->get_handle() to extract the underlying // I/O handle. virtual int register_handler (ACE_HANDLE handle, ACE_Event_Handler *eh, ACE_Reactor_Mask mask); // Register a with a particular . Note that since the // is given the Reactor will *not* call eh->get_handle() to // extract the underlying I/O handle. virtual int register_handler (const ACE_Handle_Set &handles, ACE_Event_Handler *eh, ACE_Reactor_Mask mask); // Register with all the in the . 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); // Register to handle the signal using the // . Returns the that was previously registered // (if any), along with the of the signal handler. virtual int register_handler (const ACE_Sig_Set &sigset, ACE_Event_Handler *new_sh, ACE_Sig_Action *new_disp = 0); // Registers to handle a set of signals using the // . virtual int remove_handler (ACE_Event_Handler *eh, ACE_Reactor_Mask mask); // Removes the binding of from the Reactor. If there // are no more bindings for this then it is removed from the // Reactor. Note that the Reactor will call eh->get_handle() to // extract the underlying I/O handle. virtual int remove_handler (ACE_HANDLE handle, ACE_Reactor_Mask); // Removes the bind of whose handle is // from the Reactor. If there are no more bindings for // this then it is removed from the Reactor. virtual int remove_handler (const ACE_Handle_Set &handle_set, ACE_Reactor_Mask); // Removes all the bindings for handles in the // bind of . If there are no more bindings for any // of these handlers then they are removed from the Reactor. virtual int remove_handler (int signum, ACE_Sig_Action *new_disp, ACE_Sig_Action *old_disp = 0, int sigkey = -1); // Remove the ACE_Event_Handler currently associated with . // is ignored in this implementation since there is only // one instance of a signal handler. Install the new disposition // (if given) and return the previous disposition (if desired by the // caller). Returns 0 on success and -1 if is invalid. virtual int remove_handler (const ACE_Sig_Set &sigset); // Calls for every signal in . // = Suspend and resume Handlers. virtual int suspend_handler (ACE_Event_Handler *eh); // Temporarily suspend the associated with . virtual int suspend_handler (ACE_HANDLE handle); // Temporarily suspend the associated with . virtual int resume_handler (ACE_Event_Handler *eh); // Resume a temporarily suspend associated with // . virtual int resume_handler (ACE_HANDLE handle); // Resume a temporarily suspended associated with // . virtual int suspend_handlers (void); // Suspend all the in the Reactor. virtual int resume_handlers (void); // Resume all the in the Reactor. // = Timer management. virtual long schedule_timer (ACE_Event_Handler *, const void *arg, const ACE_Time_Value &delta_time, const ACE_Time_Value &interval = ACE_Time_Value::zero); // Schedule an that will expire after // amount of time. If it expires then is passed in as the // value to the 's callback method. // If is != to then it is used to // reschedule the automatically. This method // returns a that uniquely identifies the // in an internal list. This can be used to cancel an // before it expires. The cancellation ensures that // 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 . virtual int cancel_timer (ACE_Event_Handler *event_handler, int dont_call_handle_close = 1); // Cancel all that match the address of // . If is 0 then the // method of will be invoked. // Returns number of handler's cancelled. virtual int cancel_timer (long timer_id, const void **arg = 0, int dont_call_handle_close = 1); // Cancel the single that matches the // value (which was returned from the method). If arg is // non-NULL then it will be set to point to the ``magic cookie'' // argument passed in when the was registered. This // makes it possible to free up the memory and avoid memory leaks. // If is 0 then the method // of will be invoked. Returns 1 if cancellation // succeeded and 0 if the wasn't found. // = High-level Event_Handler scheduling operations virtual int schedule_wakeup (ACE_Event_Handler *eh, ACE_Reactor_Mask mask); // ADD the dispatch MASK "bit" bound with the and the . virtual int schedule_wakeup (ACE_HANDLE handle, ACE_Reactor_Mask mask); // ADD the dispatch MASK "bit" bound with the and the . virtual int cancel_wakeup (ACE_Event_Handler *eh, ACE_Reactor_Mask mask); // CLR the dispatch MASK "bit" bound with the and the . virtual int cancel_wakeup (ACE_HANDLE handle, ACE_Reactor_Mask mask); // CLR the dispatch MASK "bit" bound with the and the . // = Notification methods. virtual int notify (ACE_Event_Handler * = 0, ACE_Reactor_Mask = ACE_Event_Handler::EXCEPT_MASK, ACE_Time_Value * = 0); // Called by a thread when it wants to unblock the Reactor. This // wakeups the if currently blocked in // select()/poll(). Pass over both the *and* the // to allow the caller to dictate which // method the will invoke. The indicates // how long to blocking trying to notify the . If // == 0, the caller will block until action is possible, // else will wait until the relative time specified in * // elapses). void requeue_position (int); // Set position that the main ACE_Reactor thread is requeued in the // list of waiters during a notify() callback. int requeue_position (void); // Get position that the main ACE_Reactor thread is requeued in the // list of waiters during a notify() callback. void max_notify_iterations (int); // Set the maximum number of times that the // method will iterate and // dispatch the that are passed in via the // notify pipe before breaking out of its loop. By default, // this is set to -1, which means "iterate until the pipe 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. int max_notify_iterations (void); // Get the maximum number of times that the // method will iterate and // dispatch the that are passed in via the // notify pipe before breaking out of its loop. // = Low-level wait_set mask manipulation methods. virtual int mask_ops (ACE_Event_Handler *eh, ACE_Reactor_Mask mask, int ops); // GET/SET/ADD/CLR the dispatch mask "bit" bound with the and // . virtual int mask_ops (ACE_HANDLE handle, ACE_Reactor_Mask mask, int ops); // GET/SET/ADD/CLR the dispatch MASK "bit" bound with the // and . // = Low-level ready_set mask manipulation methods. virtual int ready_ops (ACE_Event_Handler *eh, ACE_Reactor_Mask mask, int ops); // GET/SET/ADD/CLR the ready "bit" bound with the and . virtual int ready_ops (ACE_HANDLE handle, ACE_Reactor_Mask, int ops); // GET/SET/ADD/CLR the ready "bit" bound with the and . // = Only the owner thread that can perform a . int owner (ACE_thread_t n_id, ACE_thread_t *o_id = 0); // Set the new owner of the thread and return the old owner. int owner (ACE_thread_t *); // Return the current owner of the thread. // = Miscellaneous Handler operations. virtual int handler (ACE_HANDLE handle, ACE_Reactor_Mask mask, ACE_Event_Handler **eh = 0); // Check to see if is associated with a valid Event_Handler // bound to . Return the associated with this // if != 0. virtual int handler (int signum, ACE_Event_Handler ** = 0); // Check to see if is associated with a valid Event_Handler // bound to a signal. Return the associated with this // if != 0. int initialized (void); // Returns true if we've been successfully initialized, else false. ACE_Reactor_Token &lock (void); // Returns a reference to the that is used to // serialize the internal Reactor's processing logic. This can be // useful for situations where you need to avoid deadlock // efficiently when are used in multiple // threads. void dump (void) const; // Dump the state of an object. ACE_ALLOC_HOOK_DECLARE; // Declare the dynamic allocation hooks. protected: // = Internal methods that do the actual work. // All of these methods assume that the 's token lock is // held by the public methods that call down to them. virtual int register_handler_i (ACE_HANDLE handle, ACE_Event_Handler *eh, ACE_Reactor_Mask mask); // Do the work of actually binding the and with the // . virtual int register_handler_i (const ACE_Handle_Set &handles, ACE_Event_Handler *handler, ACE_Reactor_Mask mask); // Register a set of . virtual int remove_handler_i (ACE_HANDLE handle, ACE_Reactor_Mask); // Do the work of actually unbinding the and with the // . virtual int remove_handler_i (const ACE_Handle_Set &handles, ACE_Reactor_Mask); // Remove a set of . virtual int suspend_i (ACE_HANDLE handle); // Suspend the associated with virtual int resume_i (ACE_HANDLE handle); // Resume the associated with virtual int handler_i (ACE_HANDLE handle, ACE_Reactor_Mask, ACE_Event_Handler ** = 0); // Implement the public method. virtual int handler_i (int signum, ACE_Event_Handler ** = 0); // Implement the public method. virtual int any_ready (ACE_Reactor_Handle_Set &handle_set); // Check if there are any HANDLEs enabled in the , and // if so, update the and return the number ready. If // there aren't any HANDLEs enabled return 0. virtual int handle_error (void); // Take corrective action when errors occur. virtual int check_handles (void); // Make sure the handles are all valid. virtual int bit_ops (ACE_HANDLE handle, ACE_Reactor_Mask mask, ACE_Reactor_Handle_Set &wait_Set, int ops); // Allow manipulation of the mask and mask. virtual int wait_for_multiple_events (ACE_Reactor_Handle_Set &, ACE_Time_Value *); // Wait for events to occur. // = Dispatching methods. virtual int dispatch (int nfound, ACE_Reactor_Handle_Set &); // Template Method that dispatches s for time // events, I/O events, and signal events. Returns the total number // of s that were dispatched or -1 if something // goes wrong. virtual int dispatch_timer_handlers (void); // Dispatch any expired timer handlers. Returns -1 if the state of // the has changed, else returns number of timer // handlers dispatched. virtual int dispatch_notification_handlers (int &number_of_active_handles, ACE_Reactor_Handle_Set &dispatch_set); // Dispatch any notification handlers. Returns -1 if the state of // the has changed, else returns number of handlers // notified. virtual int dispatch_io_handlers (int &number_of_active_handles, ACE_Reactor_Handle_Set &dispatch_set); // Dispatch all the input/output/except handlers that are enabled in // the . Returns -1 if the state of the // has changed, else returns number of handlers dispatched. virtual void notify_handle (ACE_HANDLE handle, ACE_Reactor_Mask mask, ACE_Handle_Set &, ACE_Event_Handler *eh, ACE_EH_PTMF callback); // Notify the appropriate in the context of the // associated with that a particular event has occurred. ACE_Reactor_Handler_Repository handler_rep_; // Table that maps to 's. ACE_Timer_Queue *timer_queue_; // Defined as a pointer to allow overriding by derived classes... int delete_timer_queue_; // Keeps track of whether we should delete the timer queue (if we // didn't create it, then we don't delete it). ACE_Sig_Handler *signal_handler_; // Handle signals without requiring global/static variables. int delete_signal_handler_; // Keeps track of whether we should delete the signal handler (if we // didn't create it, then we don't delete it). ACE_Reactor_Handle_Set wait_set_; // Tracks handles that are waited for by select(). ACE_Reactor_Handle_Set ready_set_; // Track HANDLES we are interested in for various events that must // be dispatched *without* going through select(). int restart_; // Restart automatically when interrupted int requeue_position_; // Position that the main ACE_Reactor thread is requeued in the list // of waiters during a notify() callback. If this value == -1 we // are requeued at the end of the list. Else if it's 0 then we are // requeued at the front of the list. Else if it's > 1 then that // indicates the number of waiters to skip over. int max_notify_iterations_; // Keeps track of the maximum number of times that the // method will iterate and // dispatch the that are passed in via the // notify pipe before breaking out of its loop. By default, // this is set to -1, which means "iterate until the pipe is empty." int initialized_; // True if we've been initialized yet... ACE_thread_t owner_; // The original thread that created this Reactor. int state_changed_; // True if state has changed during dispatching of // , else false. This is used to determine // whether we need to make another trip through the 's // loop. ACE_Reactor_Token token_; // Synchronization token for the MT_SAFE ACE_Reactor. ACE_Reactor_Notify notify_handler_; // Callback object that unblocks the ACE_Reactor if it's sleeping. void renew (void); // Enqueue ourselves into the list of waiting threads at the // appropriate point specified by . friend class ACE_Reactor_Notify; friend class ACE_Reactor_Handler_Repository; private: int release_token (void); // Release the token lock when a Win32 structured exception occurs. int handle_events_i (ACE_Time_Value *max_wait_time = 0); // Stops the VC++ compiler from bitching about exceptions and destructors static ACE_Reactor *reactor_; // Pointer to a process-wide . static int delete_reactor_; // Must delete the if non-0. static sig_atomic_t end_event_loop_; // Terminate the event loop. ACE_Reactor (const ACE_Reactor &); ACE_Reactor &operator = (const ACE_Reactor &); // Deny access since member-wise won't work... }; #if defined (__ACE_INLINE__) #include "ace/Reactor.i" #endif /* __ACE_INLINE__ */ #endif /* ACE_REACTOR_H */