/usr/include/ace/Svc_Handler.h is in libace-dev 6.3.3+dfsg-1.
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//=============================================================================
/**
* @file Svc_Handler.h
*
* @author Douglas Schmidt <schmidt@uci.edu>
* @author Irfan Pyarali <irfan@cs.wustl.edu>
*/
//=============================================================================
#ifndef ACE_SVC_HANDLER_H
#define ACE_SVC_HANDLER_H
#include /**/ "ace/pre.h"
#include "ace/Synch_Options.h"
#if !defined (ACE_LACKS_PRAGMA_ONCE)
# pragma once
#endif /* ACE_LACKS_PRAGMA_ONCE */
#include "ace/Task.h"
#include "ace/Recyclable.h"
#include "ace/Reactor.h"
ACE_BEGIN_VERSIONED_NAMESPACE_DECL
// Forward decls.
class ACE_Connection_Recycling_Strategy;
// This enum is used as the flags parameter when calling the close()
// method on the ACE_Svc_Handler.
enum ACE_Svc_Handler_Close { NORMAL_CLOSE_OPERATION = 0x00,
CLOSE_DURING_NEW_CONNECTION = 0x01
};
/**
* @class ACE_Svc_Handler
*
* @brief Defines the interface for a service that exchanges data with
* its connected peer.
*
* This class provides a well-defined interface that the ACE_Acceptor
* and ACE_Connector factories use as their target. Typically, client
* applications will subclass ACE_Svc_Handler and do all the
* interesting work in the subclass. An ACE_Svc_Handler is
* parameterized by concrete types that conform to the interfaces of
* PEER_ACCEPTOR and SYNCH_TRAITS described below.
*
* @tparam PEER_STREAM The name of the class that implements the
* PEER_STREAM endpoint (e.g., ACE_SOCK_Stream) that is
* contained in an ACE_Svc_Handler and initialized by an
* ACE_Acceptor or ACE_Connector when a connection is
* established successfully. A PEER_STREAM implementation
* must provide a PEER_ADDR trait (e.g., ACE_INET_Addr to
* identify the type of address used by the endpoint. This
* endpoint is used to exchange data between a ACE_Svc_Handler
* and the peer it is connected with.
*
* @tparam SYNCH_TRAITS The name of the synchronization traits class
* that will be used by the ACE_Svc_Handler (e.g.,
* ACE_NULL_SYNCH or ACE_MT_SYNCH). The synchronization traits
* class provides typedefs for the mutex, condition, and
* semaphore implementations the ACE_Svc_Handler will
* use. @see Synch_Traits.h.
*/
template <typename PEER_STREAM, typename SYNCH_TRAITS>
class ACE_Svc_Handler : public ACE_Task<SYNCH_TRAITS>
{
public:
// Useful STL-style traits.
typedef typename PEER_STREAM::PEER_ADDR addr_type;
typedef PEER_STREAM stream_type;
/**
* Constructor initializes the @a thr_mgr and @a mq by passing them
* down to the ACE_Task base class. The @a reactor is passed to
* the ACE_Event_Handler.
*/
ACE_Svc_Handler (ACE_Thread_Manager *thr_mgr = 0,
ACE_Message_Queue<SYNCH_TRAITS> *mq = 0,
ACE_Reactor *reactor = ACE_Reactor::instance ());
/// Destructor.
virtual ~ACE_Svc_Handler (void);
/// Activate the client handler. This is typically called by the
/// ACE_Acceptor or ACE_Connector, which passes "this" in as the
/// parameter to open. If this method returns -1 the Svc_Handler's
/// close() method is automatically called.
virtual int open (void *acceptor_or_connector = 0);
/**
* Object termination hook -- application-specific cleanup code goes
* here. This function is called by the idle() function if the object
* does not have a ACE_Connection_Recycling_Strategy associated with it.
* Also, due to this class's derivation from ACE_Task, close() is
* also called when a thread activated with this object exits. See
* ACE_Task::close() for further details. The default action of this
* function is to call handle_close() with the default arguments.
*/
virtual int close (u_long flags = 0);
/**
* Call this method if you want to recycling the @c Svc_Handler
* instead of closing it. If the object does not have a recycler,
* it will be closed.
*/
virtual int idle (u_long flags = 0);
/**
* Call this method if you want to get/set the state of the
* @c Svc_Handler. If the object does not have a recycler, this call
* will have no effect (and the accessor will return
* ACE_RECYCLABLE_UNKNOWN).
*/
virtual ACE_Recyclable_State recycle_state (void) const;
virtual int recycle_state (ACE_Recyclable_State new_state);
/**
* When the svc_handle is no longer needed around as a hint, call
* this method. In addition, reset @c *act_holder to zero if
* @a act_holder != 0.
*/
virtual void cleanup_hint (void **act_holder = 0);
// = Dynamic linking hooks.
/// Default version does no work and returns -1. Must be overloaded
/// by application developer to do anything meaningful.
virtual int init (int argc, ACE_TCHAR *argv[]);
/// Default version does no work and returns -1. Must be overloaded
/// by application developer to do anything meaningful.
virtual int fini (void);
/// Default version does no work and returns -1. Must be overloaded
/// by application developer to do anything meaningful.
virtual int info (ACE_TCHAR **info_string, size_t length) const;
// = Demultiplexing hooks.
/**
* Perform termination activities on the SVC_HANDLER. The default
* behavior is to close down the <peer_> (to avoid descriptor leaks)
* and to <destroy> this object (to avoid memory leaks)! If you
* don't want this behavior make sure you override this method...
*/
virtual int handle_close (ACE_HANDLE = ACE_INVALID_HANDLE,
ACE_Reactor_Mask = ACE_Event_Handler::ALL_EVENTS_MASK);
/// Default behavior when timeouts occur is to close down the
/// <Svc_Handler> by calling <handle_close>.
virtual int handle_timeout (const ACE_Time_Value &time,
const void *);
/// Get the underlying handle associated with the <peer_>.
virtual ACE_HANDLE get_handle (void) const;
/// Set the underlying handle associated with the <peer_>.
virtual void set_handle (ACE_HANDLE);
/// Returns the underlying PEER_STREAM. Used by
/// <ACE_Acceptor::accept> and <ACE_Connector::connect> factories.
PEER_STREAM &peer (void) const;
/// Overloaded new operator. This method unobtrusively records if a
/// <Svc_Handler> is allocated dynamically, which allows it to clean
/// itself up correctly whether or not it's allocated statically or
/// dynamically.
void *operator new (size_t n);
#if defined (ACE_HAS_NEW_NOTHROW)
/// Overloaded new operator, nothrow_t variant. Unobtrusively records if a
/// <Svc_Handler> is allocated dynamically, which allows it to clean
/// itself up correctly whether or not it's allocated statically or
/// dynamically.
void *operator new (size_t n, const ACE_nothrow_t&) throw();
#if !defined (ACE_LACKS_PLACEMENT_OPERATOR_DELETE)
void operator delete (void *p, const ACE_nothrow_t&) throw ();
#endif /* ACE_LACKS_PLACEMENT_OPERATOR_DELETE */
#endif
/// This operator permits "placement new" on a per-object basis.
void * operator new (size_t n, void *p);
/**
* Call this to free up dynamically allocated <Svc_Handlers>
* (otherwise you will get memory leaks). In general, you should
* call this method rather than <delete> since this method knows
* whether or not the object was allocated dynamically, and can act
* accordingly (i.e., deleting it if it was allocated dynamically).
*/
virtual void destroy (void);
/**
* This really should be private so that users are forced to call
* <destroy>. Unfortunately, the C++ standard doesn't allow there
* to be a public new and a private delete. It is a bad idea to
* call this method directly, so use <destroy> instead, unless you
* know for sure that you've allocated the object dynamically.
*/
void operator delete (void *);
#if !defined (ACE_LACKS_PLACEMENT_OPERATOR_DELETE)
/**
* This operator is necessary to complement the class-specific
* operator new above. Unfortunately, it's not portable to all C++
* compilers...
*/
void operator delete (void *, void *);
#endif /* ACE_LACKS_PLACEMENT_OPERATOR_DELETE */
/// Close down the descriptor and unregister from the Reactor
void shutdown (void);
/// Dump the state of an object.
void dump (void) const;
public:
// = The following methods are not suppose to be public.
// Because friendship is *not* inherited in C++, these methods have
// to be public.
// = Accessors to set/get the connection recycler.
/// Set the recycler and the @a recycling_act that is used during
/// purging and caching.
virtual void recycler (ACE_Connection_Recycling_Strategy *recycler,
const void *recycling_act);
/// Get the recycler.
virtual ACE_Connection_Recycling_Strategy *recycler (void) const;
/// Get the recycling act.
virtual const void *recycling_act (void) const;
/**
* Upcall made by the recycler when it is about to recycle the
* connection. This gives the object a chance to prepare itself for
* recycling. Return 0 if the object is ready for recycling, -1 on
* failures.
*/
virtual int recycle (void * = 0);
protected:
/// Maintain connection with client.
PEER_STREAM peer_;
/// Have we been dynamically created?
bool dynamic_;
/// Keeps track of whether we are in the process of closing (required
/// to avoid circular calls to <handle_close>).
bool closing_;
/// Pointer to the connection recycler.
ACE_Connection_Recycling_Strategy *recycler_;
/// Asynchronous Completion Token (ACT) to be used to when talking to
/// the recycler.
const void *recycling_act_;
};
/**
* @class ACE_Buffered_Svc_Handler
*
* @brief Defines the interface for a service that exchanges data with
* its connected peer and supports buffering.
*
* The buffering feature makes it possible to queue up
* ACE_Message_Blocks in an ACE_Message_Queue until (1) the
* queue is "full" or (2) a period of time elapses, at which
* point the queue is "flushed" via <sendv_n> to the peer.
*/
template <typename PEER_STREAM, typename SYNCH_TRAITS>
class ACE_Buffered_Svc_Handler : public ACE_Svc_Handler<PEER_STREAM, SYNCH_TRAITS>
{
public:
// = Initialization and termination methods.
/**
* Constructor initializes the @a thr_mgr and @a mq by passing them
* down to the ACE_Task base class. The @a reactor is passed to
* the ACE_Event_Handler. The @a max_buffer_size and
* @a relative_timeout are used to determine at what point to flush
* the @a mq. By default, there's no buffering at all. The
* @a relative_timeout value is interpreted to be in a unit that's
* relative to the current time returned by <ACE_OS::gettimeofday>.
*/
ACE_Buffered_Svc_Handler (ACE_Thread_Manager *thr_mgr = 0,
ACE_Message_Queue<SYNCH_TRAITS> *mq = 0,
ACE_Reactor *reactor = ACE_Reactor::instance (),
size_t max_buffer_size = 0,
ACE_Time_Value *relative_timeout = 0);
/// Destructor, which calls <flush>.
virtual ~ACE_Buffered_Svc_Handler (void);
/**
* Insert the ACE_Message_Block chain rooted at @a message_block
* into the ACE_Message_Queue with the designated @a timeout. The
* <flush> method will be called if this <put> causes the number of
* bytes to exceed the maximum buffer size or if the timeout period
* has elapsed.
*/
virtual int put (ACE_Message_Block *message_block,
ACE_Time_Value *timeout = 0);
/// Flush the ACE_Message_Queue, which writes all the queued
/// ACE_Message_Blocks to the <PEER_STREAM>.
virtual int flush (void);
/// This method is not currently implemented -- this is where the
/// integration with the <Reactor> would occur.
virtual int handle_timeout (const ACE_Time_Value &time,
const void *);
/// Dump the state of an object.
void dump (void) const;
protected:
/// Implement the flush operation on the ACE_Message_Queue, which
/// writes all the queued ACE_Message_Blocks to the <PEER_STREAM>.
/// Assumes that the caller holds the lock.
virtual int flush_i (void);
/// Maximum size the <Message_Queue> can be before we have to flush
/// the buffer.
size_t maximum_buffer_size_;
/// Current size in bytes of the <Message_Queue> contents.
size_t current_buffer_size_;
/// Timeout value used to control when the buffer is flushed.
ACE_Time_Value next_timeout_;
/// Interval of the timeout.
ACE_Time_Value interval_;
/// Timeout pointer.
ACE_Time_Value *timeoutp_;
};
ACE_END_VERSIONED_NAMESPACE_DECL
#if defined (ACE_TEMPLATES_REQUIRE_SOURCE)
#include "ace/Svc_Handler.cpp"
#endif /* ACE_TEMPLATES_REQUIRE_SOURCE */
#if defined (ACE_TEMPLATES_REQUIRE_PRAGMA)
#pragma implementation ("Svc_Handler.cpp")
#endif /* ACE_TEMPLATES_REQUIRE_PRAGMA */
#include /**/ "ace/post.h"
#endif /* ACE_SVC_HANDLER_H */
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