/* -*- C++ -*- */ //============================================================================= /** * @file Token.h * * $Id$ * * @author Original author * @author Karl-Heinz Dorn (kdorn@erlh.siemens.de) * @author Ported to ACE by * @author Douglas C. Schmidt (schmidt@cs.wustl.edu) */ //============================================================================= #ifndef ACE_TOKEN_H #define ACE_TOKEN_H #include /**/ "ace/pre.h" #include "ace/ACE_export.h" #if !defined (ACE_LACKS_PRAGMA_ONCE) # pragma once #endif /* ACE_LACKS_PRAGMA_ONCE */ #include "ace/Null_Mutex.h" #if defined (ACE_HAS_THREADS) #include "ace/Thread_Mutex.h" #if (defined (ACE_WIN32) && !defined (ACE_HAS_WINCE)) || defined (VXWORKS) || defined (ACE_PSOS) // If platforms support semaphores with timed wait, then we use semaphores instead of c.v. # define ACE_TOKEN_USES_SEMAPHORE #endif /* (ACE_WIN32 && !ACE_HAS_WINCE) || VXWORKS || ACE_PSOS */ class ACE_Time_Value; #if defined (ACE_TOKEN_USES_SEMAPHORE) # include "ace/Semaphore.h" #endif /* ACE_TOKEN_USES_SEMAPHORE */ #include "ace/Condition_Thread_Mutex.h" /** * @class ACE_Token * * @brief Class that acquires, renews, and releases a synchronization * token that is serviced in strict FIFO/LIFO ordering and that also * supports (1) recursion and (2) readers/writer semantics. * * This class is a more general-purpose synchronization mechanism * than many native OS mutexes. For example, it implements * "recursive mutex" semantics, where a thread that owns the token * can reacquire it without deadlocking. If the same thread calls * multiple times, however, it must call an * equal number of times before the token is actually released. * Threads that are blocked awaiting the token are serviced in * strict FIFO/LIFO order as other threads release the token (Solaris * and Pthread mutexes don't strictly enforce an acquisition * order). There are two lists within the class. Write * acquires always have higher priority over read acquires. Which * means, if you use both write/read operations, care must be * taken to avoid starvation on the readers. Notice that the * read/write acquire operations do not have the usual semantic of * reader/writer locks. Only one reader can acquire the token at * a time (which is different from the usual reader/writer locks * where several readers can acquire a lock at the same time as * long as there is no writer waiting for the lock). We choose * the names to (1) borrow the semantic to give writers higher * priority and (2) support a common interface for all locking * classes in ACE. */ class ACE_Export ACE_Token { public: /** * Available queueing strategies. */ enum QUEUEING_STRATEGY { /// FIFO, First In, First Out. FIFO = -1, /// LIFO, Last In, First Out LIFO = 0 }; // = Initialization and termination. /// Constructor ACE_Token (const ACE_TCHAR *name = 0, void * = 0); /// Destructor virtual ~ACE_Token (void); // = Strategies /// Retrieve the current queueing strategy. int queueing_strategy (void); /// Set the queueing strategy. void queueing_strategy (int queueing_strategy); // = Synchronization operations. /** * Acquire the token, sleeping until it is obtained or until the * expiration of , which is treated as "absolute" time. If * some other thread currently holds the token then is * called before our thread goes to sleep. This can be * used by the requesting thread to unblock a token-holder that is * sleeping, e.g., by means of writing to a pipe (the ACE * ACE_Reactor uses this functionality). Return values: 0 if * acquires without calling 1 if is * called. 2 if the token is signaled. -1 if failure or timeout * occurs (if timeout occurs errno == ETIME) If == * <&ACE_Time_Value::zero> then acquire has polling semantics (and * does *not* call ). */ int acquire (void (*sleep_hook)(void *), void *arg = 0, ACE_Time_Value *timeout = 0); /** * This behaves just like the previous method, except that * it invokes the virtual function called that can be * overridden by a subclass of ACE_Token. */ int acquire (ACE_Time_Value *timeout = 0); /** * This should be overridden by a subclass to define the appropriate * behavior before goes to sleep. By default, this is a * no-op... */ virtual void sleep_hook (void); /** * An optimized method that efficiently reacquires the token if no * other threads are waiting. This is useful for situations where * you don't want to degrade the quality of service if there are * other threads waiting to get the token. If == * -1 and there are other threads waiting to obtain the token we are * queued according to the queueing strategy. If * > -1 then it indicates how many entries to skip over before * inserting our thread into the list of waiters (e.g., * == 0 means "insert at front of the queue"). * Renew has the rather odd semantics such that if there are other * waiting threads it will give up the token even if the * nesting_level_ > 1. I'm not sure if this is really the right * thing to do (since it makes it possible for shared data to be * changed unexpectedly) so use with caution... This method * maintians the original token priority. As in , the * value is an absolute time. */ int renew (int requeue_position = 0, ACE_Time_Value *timeout = 0); /// Become interface-compliant with other lock mechanisms (implements /// a non-blocking ). int tryacquire (void); /// Shuts down the ACE_Token instance. int remove (void); /// Relinquish the token. If there are any waiters then the next one /// in line gets it. int release (void); /// Behaves like acquire() but at a lower priority. It should probably /// be called acquire_yield() since the semantics aren't really /// what's commonly expected for readers/writer locks. See the class /// documentation above for more details. int acquire_read (void); /// Behaves like acquire() but at a lower priority. It should probably /// be called acquire_yield() since the semantics aren't really /// what's commonly expected for readers/writer locks. See the class /// documentation above for more details. int acquire_read (void (*sleep_hook)(void *), void *arg = 0, ACE_Time_Value *timeout = 0); /// Calls acquire(). int acquire_write (void); /// Calls acquire(). int acquire_write (void (*sleep_hook)(void *), void *arg = 0, ACE_Time_Value *timeout = 0); /// Lower priority try_acquire(). int tryacquire_read (void); /// Just calls . int tryacquire_write (void); /// Assumes the caller has acquired the token and returns 0. int tryacquire_write_upgrade (void); // = Accessor methods. /// Return the number of threads that are currently waiting to get /// the token. int waiters (void); /// Return the id of the current thread that owns the token. ACE_thread_t current_owner (void); /// Dump the state of an object. void dump (void) const; /// Declare the dynamic allocation hooks. ACE_ALLOC_HOOK_DECLARE; /// The following structure implements a LIFO/FIFO queue of waiter threads /// that are asleep waiting to obtain the token. struct ACE_Token_Queue_Entry { /// Constructor ACE_Token_Queue_Entry (ACE_Thread_Mutex &m, ACE_thread_t t_id); /// Constructor using a pre-allocated attributes ACE_Token_Queue_Entry (ACE_Thread_Mutex &m, ACE_thread_t t_id, ACE_Condition_Attributes &attributes); /// Entry blocks on the token. int wait (ACE_Time_Value *timeout, ACE_Thread_Mutex &lock); /// Notify (unblock) the entry. int signal (void); /// Pointer to next waiter. ACE_Token_Queue_Entry *next_; /// ACE_Thread id of this waiter. ACE_thread_t thread_id_; #if defined (ACE_TOKEN_USES_SEMAPHORE) /// ACE_Semaphore object used to wake up waiter when it can run again. ACE_Semaphore cv_; #else /// ACE_Condition object used to wake up waiter when it can run again. ACE_Condition_Thread_Mutex cv_; #endif /* ACE_TOKEN_USES_SEMAPHORE */ /// Ok to run. int runable_; }; private: enum ACE_Token_Op_Type { READ_TOKEN = 1, WRITE_TOKEN }; struct ACE_Token_Queue { /// Constructor ACE_Token_Queue (void); /// Remove a waiter from the queue. void remove_entry (ACE_Token_Queue_Entry *); /// Insert a waiter into the queue. void insert_entry (ACE_Token_Queue_Entry &entry, int requeue_position = -1); /// Head of the list of waiting threads. ACE_Token_Queue_Entry *head_; /// Tail of the list of waiting threads. ACE_Token_Queue_Entry *tail_; }; /// Implements the and methods above. int shared_acquire (void (*sleep_hook_func)(void *), void *arg, ACE_Time_Value *timeout, ACE_Token_Op_Type op_type); /// Wake next in line for ownership. void wakeup_next_waiter (void); /// A queue of writer threads. ACE_Token_Queue writers_; /// A queue of reader threads. ACE_Token_Queue readers_; /// ACE_Thread_Mutex used to lock internal data structures. ACE_Thread_Mutex lock_; /// Current owner of the token. ACE_thread_t owner_; /// Some thread (i.e., ) is using the token. We need this /// extra variable to deal with POSIX pthreads madness... int in_use_; /// Number of waiters. int waiters_; /// Current nesting level. int nesting_level_; /// The attributes for the condition variables, optimizes lock time. ACE_Condition_Attributes attributes_; /// Queueing strategy, LIFO/FIFO. int queueing_strategy_; }; #else class ACE_Export ACE_Token { public: int queueing_strategy (void) { ACE_NOTSUP_RETURN (-1); } void queueing_strategy (int /*queueing_strategy*/) { } int acquire (ACE_Time_Value * = 0) { ACE_NOTSUP_RETURN (-1); } int tryacquire (void) { ACE_NOTSUP_RETURN (-1); } int remove (void) { ACE_NOTSUP_RETURN (-1); } int release (void) { ACE_NOTSUP_RETURN (-1); } }; #endif /* ACE_HAS_THREADS */ class ACE_Export ACE_Noop_Token : public ACE_Null_Mutex { public: /// Queueing strategy enum QUEUEING_STRATEGY { FIFO = -1, LIFO = 0 }; /// Get queueing strategy. int queueing_strategy (void); /// Set queueing strategy. void queueing_strategy (int queueing_strategy); int renew (int = 0, ACE_Time_Value * =0); /// Dump the state of an object. void dump (void) const; /// Declare the dynamic allocation hooks. ACE_ALLOC_HOOK_DECLARE; }; #if defined (__ACE_INLINE__) #include "ace/Token.inl" #endif /* __ACE_INLINE__ */ #include /**/ "ace/post.h" #endif /* ACE_TOKEN_H */