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|
/* -*- C++ -*- */
// $Id$
#include "ace/POSIX_Proactor.h"
#if defined (ACE_HAS_AIO_CALLS)
#if !defined (__ACE_INLINE__)
#include "ace/POSIX_Proactor.inl"
#endif /* __ACE_INLINE__ */
# if defined (ACE_HAS_SYSINFO)
# include /**/ <sys/systeminfo.h>
# endif /* ACE_HAS_SYS_INFO */
#include "ace/ACE.h"
#include "ace/Flag_Manip.h"
#include "ace/Task_T.h"
#include "ace/Log_Msg.h"
#include "ace/Object_Manager.h"
#include "ace/OS_NS_sys_socket.h"
#include "ace/OS_NS_signal.h"
#include "ace/OS_NS_unistd.h"
#if defined (sun)
# include "ace/OS_NS_strings.h"
#endif /* sun */
// *********************************************************************
/**
* @class ACE_POSIX_Wakeup_Completion
*
* This result object is used by the <end_event_loop> of the
* ACE_Proactor interface to wake up all the threads blocking
* for completions.
*/
class ACE_Export ACE_POSIX_Wakeup_Completion : public ACE_POSIX_Asynch_Result
{
public:
/// Constructor.
ACE_POSIX_Wakeup_Completion (ACE_Handler &handler,
const void *act = 0,
ACE_HANDLE event = ACE_INVALID_HANDLE,
int priority = 0,
int signal_number = ACE_SIGRTMIN);
/// Destructor.
virtual ~ACE_POSIX_Wakeup_Completion (void);
/// This method calls the <handler>'s <handle_wakeup> method.
virtual void complete (size_t bytes_transferred = 0,
int success = 1,
const void *completion_key = 0,
u_long error = 0);
};
// *********************************************************************
ACE_POSIX_Proactor::ACE_POSIX_Proactor (void)
: os_id_ (OS_UNDEFINED)
{
#if defined(sun)
os_id_ = OS_SUN; // set family
char Buf [32];
::memset(Buf,0,sizeof(Buf));
ACE_OS::sysinfo (SI_RELEASE , Buf, sizeof(Buf)-1);
if (ACE_OS::strcasecmp (Buf , "5.6") == 0)
os_id_ = OS_SUN_56;
else if (ACE_OS::strcasecmp (Buf , "5.7") == 0)
os_id_ = OS_SUN_57;
else if (ACE_OS::strcasecmp (Buf , "5.8") == 0)
os_id_ = OS_SUN_58;
#elif defined(HPUX)
os_id_ = OS_HPUX; // set family
#elif defined(__sgi)
os_id_ = OS_IRIX; // set family
#elif defined(__OpenBSD)
os_id_ = OS_OPENBSD; // set family
// do the same
//#else defined (LINUX, __FreeBSD__ ...)
//setup here os_id_
#endif
}
ACE_POSIX_Proactor::~ACE_POSIX_Proactor (void)
{
this->close ();
}
int
ACE_POSIX_Proactor::close (void)
{
return 0;
}
int
ACE_POSIX_Proactor::register_handle (ACE_HANDLE handle,
const void *completion_key)
{
ACE_UNUSED_ARG (handle);
ACE_UNUSED_ARG (completion_key);
return 0;
}
int
ACE_POSIX_Proactor::wake_up_dispatch_threads (void)
{
return 0;
}
int
ACE_POSIX_Proactor::close_dispatch_threads (int)
{
return 0;
}
size_t
ACE_POSIX_Proactor::number_of_threads (void) const
{
// @@ Implement it.
ACE_NOTSUP_RETURN (0);
}
void
ACE_POSIX_Proactor::number_of_threads (size_t threads)
{
// @@ Implement it.
ACE_UNUSED_ARG (threads);
}
ACE_HANDLE
ACE_POSIX_Proactor::get_handle (void) const
{
return ACE_INVALID_HANDLE;
}
ACE_Asynch_Read_Stream_Impl *
ACE_POSIX_Proactor::create_asynch_read_stream (void)
{
ACE_Asynch_Read_Stream_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Read_Stream (this),
0);
return implementation;
}
ACE_Asynch_Read_Stream_Result_Impl *
ACE_POSIX_Proactor::create_asynch_read_stream_result (ACE_Handler &handler,
ACE_HANDLE handle,
ACE_Message_Block &message_block,
size_t bytes_to_read,
const void* act,
ACE_HANDLE event,
int priority,
int signal_number)
{
ACE_Asynch_Read_Stream_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Read_Stream_Result (handler,
handle,
message_block,
bytes_to_read,
act,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Write_Stream_Impl *
ACE_POSIX_Proactor::create_asynch_write_stream (void)
{
ACE_Asynch_Write_Stream_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Write_Stream (this),
0);
return implementation;
}
ACE_Asynch_Write_Stream_Result_Impl *
ACE_POSIX_Proactor::create_asynch_write_stream_result (ACE_Handler &handler,
ACE_HANDLE handle,
ACE_Message_Block &message_block,
size_t bytes_to_write,
const void* act,
ACE_HANDLE event,
int priority,
int signal_number)
{
ACE_Asynch_Write_Stream_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Write_Stream_Result (handler,
handle,
message_block,
bytes_to_write,
act,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Read_File_Impl *
ACE_POSIX_Proactor::create_asynch_read_file (void)
{
ACE_Asynch_Read_File_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Read_File (this),
0);
return implementation;
}
ACE_Asynch_Read_File_Result_Impl *
ACE_POSIX_Proactor::create_asynch_read_file_result (ACE_Handler &handler,
ACE_HANDLE handle,
ACE_Message_Block &message_block,
size_t bytes_to_read,
const void* act,
u_long offset,
u_long offset_high,
ACE_HANDLE event,
int priority,
int signal_number)
{
ACE_Asynch_Read_File_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Read_File_Result (handler,
handle,
message_block,
bytes_to_read,
act,
offset,
offset_high,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Write_File_Impl *
ACE_POSIX_Proactor::create_asynch_write_file (void)
{
ACE_Asynch_Write_File_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Write_File (this),
0);
return implementation;
}
ACE_Asynch_Write_File_Result_Impl *
ACE_POSIX_Proactor::create_asynch_write_file_result (ACE_Handler &handler,
ACE_HANDLE handle,
ACE_Message_Block &message_block,
size_t bytes_to_write,
const void* act,
u_long offset,
u_long offset_high,
ACE_HANDLE event,
int priority,
int signal_number)
{
ACE_Asynch_Write_File_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Write_File_Result (handler,
handle,
message_block,
bytes_to_write,
act,
offset,
offset_high,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Read_Dgram_Impl *
ACE_POSIX_Proactor::create_asynch_read_dgram (void)
{
ACE_Asynch_Read_Dgram_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Read_Dgram (this),
0);
return implementation;
}
ACE_Asynch_Read_Dgram_Result_Impl *
ACE_POSIX_Proactor::create_asynch_read_dgram_result (ACE_Handler &handler,
ACE_HANDLE handle,
ACE_Message_Block *message_block,
size_t bytes_to_read,
int flags,
int protocol_family,
const void* act,
ACE_HANDLE event ,
int priority ,
int signal_number)
{
ACE_Asynch_Read_Dgram_Result_Impl *implementation=0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Read_Dgram_Result(handler,
handle,
message_block,
bytes_to_read,
flags,
protocol_family,
act,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Write_Dgram_Impl *
ACE_POSIX_Proactor::create_asynch_write_dgram (void)
{
ACE_Asynch_Write_Dgram_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Write_Dgram (this),
0);
return implementation;
}
ACE_Asynch_Write_Dgram_Result_Impl *
ACE_POSIX_Proactor::create_asynch_write_dgram_result (ACE_Handler &handler,
ACE_HANDLE handle,
ACE_Message_Block *message_block,
size_t bytes_to_write,
int flags,
const void* act,
ACE_HANDLE event,
int priority ,
int signal_number)
{
ACE_Asynch_Write_Dgram_Result_Impl *implementation=0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Write_Dgram_Result(handler,
handle,
message_block,
bytes_to_write,
flags,
act,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Accept_Impl *
ACE_POSIX_Proactor::create_asynch_accept (void)
{
ACE_Asynch_Accept_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Accept (this),
0);
return implementation;
}
ACE_Asynch_Accept_Result_Impl *
ACE_POSIX_Proactor::create_asynch_accept_result (ACE_Handler &handler,
ACE_HANDLE listen_handle,
ACE_HANDLE accept_handle,
ACE_Message_Block &message_block,
size_t bytes_to_read,
const void* act,
ACE_HANDLE event,
int priority,
int signal_number)
{
ACE_Asynch_Accept_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Accept_Result (handler,
listen_handle,
accept_handle,
message_block,
bytes_to_read,
act,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Connect_Impl *
ACE_POSIX_Proactor::create_asynch_connect (void)
{
ACE_Asynch_Connect_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Connect (this),
0);
return implementation;
}
ACE_Asynch_Connect_Result_Impl *
ACE_POSIX_Proactor::create_asynch_connect_result (ACE_Handler &handler,
ACE_HANDLE connect_handle,
const void* act,
ACE_HANDLE event,
int priority,
int signal_number)
{
ACE_Asynch_Connect_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Connect_Result (handler,
connect_handle,
act,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Transmit_File_Impl *
ACE_POSIX_Proactor::create_asynch_transmit_file (void)
{
ACE_Asynch_Transmit_File_Impl *implementation = 0;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Transmit_File (this),
0);
return implementation;
}
ACE_Asynch_Transmit_File_Result_Impl *
ACE_POSIX_Proactor::create_asynch_transmit_file_result (ACE_Handler &handler,
ACE_HANDLE socket,
ACE_HANDLE file,
ACE_Asynch_Transmit_File::Header_And_Trailer *header_and_trailer,
size_t bytes_to_write,
u_long offset,
u_long offset_high,
size_t bytes_per_send,
u_long flags,
const void *act,
ACE_HANDLE event,
int priority,
int signal_number)
{
ACE_Asynch_Transmit_File_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Transmit_File_Result (handler,
socket,
file,
header_and_trailer,
bytes_to_write,
offset,
offset_high,
bytes_per_send,
flags,
act,
event,
priority,
signal_number),
0);
return implementation;
}
ACE_Asynch_Result_Impl *
ACE_POSIX_Proactor::create_asynch_timer (ACE_Handler &handler,
const void *act,
const ACE_Time_Value &tv,
ACE_HANDLE event,
int priority,
int signal_number)
{
ACE_Asynch_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Timer (handler,
act,
tv,
event,
priority,
signal_number),
0);
return implementation;
}
#if 0
int
ACE_POSIX_Proactor::handle_signal (int, siginfo_t *, ucontext_t *)
{
// Perform a non-blocking "poll" for all the I/O events that have
// completed in the I/O completion queue.
ACE_Time_Value timeout (0, 0);
int result = 0;
for (;;)
{
result = this->handle_events (timeout);
if (result != 0 || errno == ETIME)
break;
}
// If our handle_events failed, we'll report a failure to the
// Reactor.
return result == -1 ? -1 : 0;
}
int
ACE_POSIX_Proactor::handle_close (ACE_HANDLE handle,
ACE_Reactor_Mask close_mask)
{
ACE_UNUSED_ARG (close_mask);
ACE_UNUSED_ARG (handle);
return this->close ();
}
#endif /* 0 */
void
ACE_POSIX_Proactor::application_specific_code (ACE_POSIX_Asynch_Result *asynch_result,
size_t bytes_transferred,
const void */* completion_key*/,
u_long error)
{
ACE_SEH_TRY
{
// Call completion hook
asynch_result->complete (bytes_transferred,
error ? 0 : 1,
0, // No completion key.
error);
}
ACE_SEH_FINALLY
{
// This is crucial to prevent memory leaks
delete asynch_result;
}
}
int
ACE_POSIX_Proactor::post_wakeup_completions (int how_many)
{
ACE_POSIX_Wakeup_Completion *wakeup_completion = 0;
for (int ci = 0; ci < how_many; ci++)
{
ACE_NEW_RETURN (wakeup_completion,
ACE_POSIX_Wakeup_Completion (this->wakeup_handler_),
-1);
if (this->post_completion (wakeup_completion) == -1)
return -1;
}
return 0;
}
/**
* @class ACE_AIOCB_Notify_Pipe_Manager
*
* @brief This class manages the notify pipe of the AIOCB Proactor.
*
* This class acts as the Handler for the
* <Asynch_Read> operations issued on the notify pipe. This
* class is very useful in implementing <Asynch_Accept> operation
* class for the <AIOCB_Proactor>. This is also useful for
* implementing <post_completion> for <AIOCB_Proactor>.
* <AIOCB_Proactor> class issues a <Asynch_Read> on
* the pipe, using this class as the
* Handler. <POSIX_Asynch_Result *>'s are sent through the
* notify pipe. When <POSIX_Asynch_Result *>'s show up on the
* notify pipe, the <POSIX_AIOCB_Proactor> dispatches the
* completion of the <Asynch_Read_Stream> and calls the
* <handle_read_stream> of this class. This class calls
* <complete> on the <POSIX_Asynch_Result *> and thus calls the
* application handler.
* Handling the MessageBlock:
* We give this message block to read the result pointer through
* the notify pipe. We expect that to read 4 bytes from the
* notify pipe, for each <accept> call. Before giving this
* message block to another <accept>, we update <wr_ptr> and put
* it in its initial position.
*/
class ACE_Export ACE_AIOCB_Notify_Pipe_Manager : public ACE_Handler
{
public:
/// Constructor. You need the posix proactor because you need to call
/// <application_specific_code>
ACE_AIOCB_Notify_Pipe_Manager (ACE_POSIX_AIOCB_Proactor *posix_aiocb_proactor);
/// Destructor.
virtual ~ACE_AIOCB_Notify_Pipe_Manager (void);
/// Send the result pointer through the notification pipe.
int notify ();
/// This is the call back method when <Asynch_Read> from the pipe is
/// complete.
virtual void handle_read_stream (const ACE_Asynch_Read_Stream::Result &result);
private:
/// The implementation proactor class.
ACE_POSIX_AIOCB_Proactor *posix_aiocb_proactor_;
/// Message block to get ACE_POSIX_Asynch_Result pointer from the pipe.
ACE_Message_Block message_block_;
/// Pipe for the communication between Proactor and the
/// Asynch_Accept/Asynch_Connect and other post_completions
ACE_Pipe pipe_;
/// To do asynch_read on the pipe.
ACE_POSIX_Asynch_Read_Stream read_stream_;
/// Default constructor. Shouldnt be called.
ACE_AIOCB_Notify_Pipe_Manager (void);
};
ACE_AIOCB_Notify_Pipe_Manager::ACE_AIOCB_Notify_Pipe_Manager (ACE_POSIX_AIOCB_Proactor *posix_aiocb_proactor)
: posix_aiocb_proactor_ (posix_aiocb_proactor),
message_block_ (sizeof (2)),
read_stream_ (posix_aiocb_proactor)
{
// Open the pipe.
this->pipe_.open ();
// Set write side in NONBLOCK mode
ACE_Flag_Manip::set_flags (this->pipe_.write_handle (), ACE_NONBLOCK);
// Let AIOCB_Proactor know about our handle
posix_aiocb_proactor_->set_notify_handle (this->pipe_.read_handle ());
// Open the read stream.
if (this->read_stream_.open (*this,
this->pipe_.read_handle (),
0, // Completion Key
0) // Proactor
== -1)
ACE_ERROR ((LM_ERROR,
"%N:%l:%p\n",
"ACE_AIOCB_Notify_Pipe_Manager::ACE_AIOCB_Notify_Pipe_Manager:"
"Open on Read Stream failed"));
// Issue an asynch_read on the read_stream of the notify pipe.
if (this->read_stream_.read (this->message_block_,
1, // enough to read 1 byte
0, // ACT
0) // Priority
== -1)
ACE_ERROR ((LM_ERROR,
"%N:%l:%p\n",
"ACE_AIOCB_Notify_Pipe_Manager::ACE_AIOCB_Notify_Pipe_Manager:"
"Read from pipe failed"));
}
ACE_AIOCB_Notify_Pipe_Manager::~ACE_AIOCB_Notify_Pipe_Manager (void)
{
// 1. try to cancel pending aio
this->read_stream_.cancel ();
// 2. close both handles
// Destuctor of ACE_Pipe does not close handles.
// We can not use ACE_Pipe::close() as it
// closes read_handle and than write_handle.
// In some systems close() may wait for
// completion for all asynch. pending requests.
// So we should close write_handle firstly
// to force read completion ( if 1. does not help )
// and then read_handle and not vice versa
ACE_HANDLE h = this->pipe_.write_handle ();
if (h != ACE_INVALID_HANDLE)
ACE_OS::closesocket (h);
h = this->pipe_.read_handle ();
if ( h != ACE_INVALID_HANDLE)
ACE_OS::closesocket (h);
}
int
ACE_AIOCB_Notify_Pipe_Manager::notify ()
{
// Send the result pointer through the pipe.
char char_send = 0;
int ret_val = ACE::send (this->pipe_.write_handle (),
&char_send,
sizeof (char_send));
if (ret_val < 0)
{
if (errno != EWOULDBLOCK)
#if 0
ACE_ERROR ((LM_ERROR,
ACE_LIB_TEXT ("(%P %t):%p\n"),
ACE_LIB_TEXT ("ACE_AIOCB_Notify_Pipe_Manager::notify")
ACE_LIB_TEXT ("Error:Writing on to notify pipe failed")));
#endif /* 0 */
return -1;
}
return 0;
}
void
ACE_AIOCB_Notify_Pipe_Manager::handle_read_stream
(const ACE_Asynch_Read_Stream::Result & /*result*/)
{
// 1. Start new read to avoid pipe overflow
// Set the message block properly. Put the <wr_ptr> back in the
// initial position.
if (this->message_block_.length () > 0)
this->message_block_.wr_ptr (this->message_block_.rd_ptr ());
// One accept has completed. Issue a read to handle any
// <post_completion>s in the future.
if (-1 == this->read_stream_.read (this->message_block_,
1, // enough to read 1 byte
0, // ACT
0)) // Priority
ACE_ERROR ((LM_ERROR,
ACE_LIB_TEXT ("%N:%l:(%P | %t):%p\n"),
ACE_LIB_TEXT ("ACE_AIOCB_Notify_Pipe_Manager::handle_read_stream:")
ACE_LIB_TEXT ("Read from pipe failed")));
// 2. Do the upcalls
// this->posix_aiocb_proactor_->process_result_queue ();
}
// Public constructor for common use.
ACE_POSIX_AIOCB_Proactor::ACE_POSIX_AIOCB_Proactor (size_t max_aio_operations)
: aiocb_notify_pipe_manager_ (0),
aiocb_list_ (0),
result_list_ (0),
aiocb_list_max_size_ (max_aio_operations),
aiocb_list_cur_size_ (0),
notify_pipe_read_handle_ (ACE_INVALID_HANDLE),
num_deferred_aiocb_ (0),
num_started_aio_ (0)
{
// Check for correct value for max_aio_operations
check_max_aio_num ();
this->create_result_aiocb_list ();
this->create_notify_manager ();
// start pseudo-asynchronous accept task
// one per all future acceptors
this->get_asynch_pseudo_task().start ();
}
// Special protected constructor for ACE_SUN_Proactor
ACE_POSIX_AIOCB_Proactor::ACE_POSIX_AIOCB_Proactor (size_t max_aio_operations,
ACE_POSIX_Proactor::Proactor_Type)
: aiocb_notify_pipe_manager_ (0),
aiocb_list_ (0),
result_list_ (0),
aiocb_list_max_size_ (max_aio_operations),
aiocb_list_cur_size_ (0),
notify_pipe_read_handle_ (ACE_INVALID_HANDLE),
num_deferred_aiocb_ (0),
num_started_aio_ (0)
{
//check for correct value for max_aio_operations
this->check_max_aio_num ();
this->create_result_aiocb_list ();
// @@ We should create Notify_Pipe_Manager in the derived class to
// provide correct calls for virtual functions !!!
}
// Destructor.
ACE_POSIX_AIOCB_Proactor::~ACE_POSIX_AIOCB_Proactor (void)
{
this->close();
}
int
ACE_POSIX_AIOCB_Proactor::close (void)
{
// stop asynch accept task
this->get_asynch_pseudo_task().stop ();
this->delete_notify_manager ();
this->clear_result_queue ();
return this->delete_result_aiocb_list ();
}
void ACE_POSIX_AIOCB_Proactor::set_notify_handle (ACE_HANDLE h)
{
notify_pipe_read_handle_ = h;
}
int ACE_POSIX_AIOCB_Proactor::create_result_aiocb_list (void)
{
if (aiocb_list_ != 0)
return 0;
ACE_NEW_RETURN (aiocb_list_, aiocb *[aiocb_list_max_size_], -1);
ACE_NEW_RETURN (result_list_,
ACE_POSIX_Asynch_Result *[aiocb_list_max_size_],
-1);
// Initialize the array.
for (size_t ai = 0; ai < this->aiocb_list_max_size_; ai++)
{
aiocb_list_[ai] = 0;
result_list_[ai] = 0;
}
return 0;
}
int ACE_POSIX_AIOCB_Proactor::delete_result_aiocb_list (void)
{
if (aiocb_list_ == 0) // already deleted
return 0;
size_t ai;
// Try to cancel all uncomlpeted operarion POSIX systems may have
// hidden system threads that still can work with our aiocb's!
for (ai = 0; ai < aiocb_list_max_size_; ai++)
if (this->aiocb_list_[ai] != 0) // active operation
this->cancel_aiocb (result_list_[ai]);
int num_pending = 0;
for (ai = 0; ai < aiocb_list_max_size_; ai++)
{
if (this->aiocb_list_[ai] == 0 ) // not active operation
continue;
// Get the error and return status of the aio_ operation.
int error_status = 0;
size_t transfer_count = 0;
int flg_completed = this->get_result_status (result_list_[ai],
error_status,
transfer_count);
//don't delete uncompleted AIOCB's
if (flg_completed == 0) // not completed !!!
{
num_pending++;
#if 0
char * errtxt = ACE_OS::strerror (error_status);
if (errtxt == 0)
errtxt ="?????????";
char * op = (aiocb_list_[ai]->aio_lio_opcode == LIO_WRITE )?
"WRITE":"READ" ;
ACE_ERROR ((LM_ERROR,
ACE_LIB_TEXT("slot=%d op=%s status=%d xfercnt=%d %s\n"),
ai,
op,
error_status,
transfer_count,
errtxt));
#endif /* 0 */
}
else // completed , OK
{
delete this->result_list_[ai];
this->result_list_[ai] = 0;
this->aiocb_list_[ai] = 0;
}
}
// If it is not possible cancel some operation (num_pending > 0 ),
// we can do only one thing -report about this
// and complain about POSIX implementation.
// We know that we have memory leaks, but it is better than
// segmentation fault!
ACE_DEBUG
((LM_DEBUG,
ACE_LIB_TEXT("ACE_POSIX_AIOCB_Proactor::delete_result_aiocb_list\n")
ACE_LIB_TEXT(" number pending AIO=%d\n"),
num_pending));
delete [] this->aiocb_list_;
this->aiocb_list_ = 0;
delete [] this->result_list_;
this->result_list_ = 0;
return (num_pending == 0 ? 0 : -1);
// ?? or just always return 0;
}
void ACE_POSIX_AIOCB_Proactor::check_max_aio_num ()
{
long max_os_aio_num = ACE_OS::sysconf (_SC_AIO_MAX);
// Define max limit AIO's for concrete OS
// -1 means that there is no limit, but it is not true
// (example, SunOS 5.6)
if (max_os_aio_num > 0 &&
aiocb_list_max_size_ > (unsigned long) max_os_aio_num)
aiocb_list_max_size_ = max_os_aio_num;
#if defined (HPUX) || defined (__FreeBSD__)
// Although HPUX 11.00 allows to start 2048 AIO's for all process in
// system it has a limit 256 max elements for aio_suspend () It is a
// pity, but ...
long max_os_listio_num = ACE_OS::sysconf (_SC_AIO_LISTIO_MAX);
if (max_os_listio_num > 0
&& aiocb_list_max_size_ > (unsigned long) max_os_listio_num)
aiocb_list_max_size_ = max_os_listio_num;
#endif /* HPUX || __FreeBSD__ */
// check for user-defined value
// ACE_AIO_MAX_SIZE if defined in POSIX_Proactor.h
if (aiocb_list_max_size_ <= 0
|| aiocb_list_max_size_ > ACE_AIO_MAX_SIZE)
aiocb_list_max_size_ = ACE_AIO_MAX_SIZE;
// check for max number files to open
int max_num_files = ACE::max_handles ();
if (max_num_files > 0
&& aiocb_list_max_size_ > (unsigned long) max_num_files)
{
ACE::set_handle_limit (aiocb_list_max_size_);
max_num_files = ACE::max_handles ();
}
if (max_num_files > 0
&& aiocb_list_max_size_ > (unsigned long) max_num_files)
aiocb_list_max_size_ = (unsigned long) max_num_files;
ACE_DEBUG ((LM_DEBUG,
"(%P | %t) ACE_POSIX_AIOCB_Proactor::Max Number of AIOs=%d\n",
aiocb_list_max_size_));
#if defined(__sgi)
ACE_DEBUG((LM_DEBUG,
ACE_LIB_TEXT( "SGI IRIX specific: aio_init!\n")));
//typedef struct aioinit {
// int aio_threads; /* The number of aio threads to start (5) */
// int aio_locks; /* Initial number of preallocated locks (3) */
// int aio_num; /* estimated total simultanious aiobc structs (1000) */
// int aio_usedba; /* Try to use DBA for raw I/O in lio_listio (0) */
// int aio_debug; /* turn on debugging (0) */
// int aio_numusers; /* max number of user sprocs making aio_* calls (5) */
// int aio_reserved[3];
//} aioinit_t;
aioinit_t aioinit;
aioinit.aio_threads = 10; /* The number of aio threads to start (5) */
aioinit.aio_locks = 20; /* Initial number of preallocated locks (3) */
/* estimated total simultaneous aiobc structs (1000) */
aioinit.aio_num = aiocb_list_max_size_;
aioinit.aio_usedba = 0; /* Try to use DBA for raw IO in lio_listio (0) */
aioinit.aio_debug = 0; /* turn on debugging (0) */
aioinit.aio_numusers = 100; /* max number of user sprocs making aio_* calls (5) */
aioinit.aio_reserved[0] = 0;
aioinit.aio_reserved[1] = 0;
aioinit.aio_reserved[2] = 0;
aio_sgi_init (&aioinit);
#endif
return;
}
void
ACE_POSIX_AIOCB_Proactor::create_notify_manager (void)
{
// Remember! this issues a Asynch_Read
// on the notify pipe for doing the Asynch_Accept/Connect.
if (aiocb_notify_pipe_manager_ == 0)
ACE_NEW (aiocb_notify_pipe_manager_,
ACE_AIOCB_Notify_Pipe_Manager (this));
}
void
ACE_POSIX_AIOCB_Proactor::delete_notify_manager (void)
{
// We are responsible for delete as all pointers set to 0 after
// delete, it is save to delete twice
delete aiocb_notify_pipe_manager_;
aiocb_notify_pipe_manager_ = 0;
}
int
ACE_POSIX_AIOCB_Proactor::handle_events (ACE_Time_Value &wait_time)
{
// Decrement <wait_time> with the amount of time spent in the method
ACE_Countdown_Time countdown (&wait_time);
return this->handle_events_i (wait_time.msec ());
}
int
ACE_POSIX_AIOCB_Proactor::handle_events (void)
{
return this->handle_events_i (ACE_INFINITE);
}
int
ACE_POSIX_AIOCB_Proactor::notify_completion(int sig_num)
{
ACE_UNUSED_ARG (sig_num);
return this->aiocb_notify_pipe_manager_->notify ();
}
int
ACE_POSIX_AIOCB_Proactor::post_completion (ACE_POSIX_Asynch_Result *result)
{
ACE_MT (ACE_GUARD_RETURN (ACE_SYNCH_MUTEX, ace_mon, this->mutex_, -1));
int ret_val = this->putq_result (result);
return ret_val;
}
int
ACE_POSIX_AIOCB_Proactor::putq_result (ACE_POSIX_Asynch_Result *result)
{
// this protected method should be called with locked mutex_
// we can't use GUARD as Proactor uses non-recursive mutex
if (!result)
return -1;
int sig_num = result->signal_number ();
int ret_val = this->result_queue_.enqueue_tail (result);
if (ret_val == -1)
ACE_ERROR_RETURN ((LM_ERROR,
"%N:%l:ACE_POSIX_AIOCB_Proactor::putq_result failed\n"),
-1);
this->notify_completion (sig_num);
return 0;
}
ACE_POSIX_Asynch_Result * ACE_POSIX_AIOCB_Proactor::getq_result (void)
{
ACE_MT (ACE_GUARD_RETURN (ACE_SYNCH_MUTEX, ace_mon, this->mutex_, 0));
ACE_POSIX_Asynch_Result* result = 0;
if (this->result_queue_.dequeue_head (result) != 0)
return 0;
// don;t waste time if queue is empty - it is normal
// or check queue size before dequeue_head
// ACE_ERROR_RETURN ((LM_ERROR,
// "%N:%l:(%P | %t):%p\n",
// "ACE_POSIX_AIOCB_Proactor::getq_result failed"),
// 0);
return result;
}
int ACE_POSIX_AIOCB_Proactor::clear_result_queue (void)
{
int ret_val = 0;
ACE_POSIX_Asynch_Result* result = 0;
while ((result = this->getq_result ()) != 0)
{
delete result;
ret_val++;
}
return ret_val;
}
int ACE_POSIX_AIOCB_Proactor::process_result_queue (void)
{
int ret_val = 0;
ACE_POSIX_Asynch_Result* result = 0;
while ((result = this->getq_result ()) != 0)
{
this->application_specific_code
(result,
result->bytes_transferred(), // 0, No bytes transferred.
0, // No completion key.
result->error()); //0, No error.
ret_val++;
}
return ret_val;
}
int
ACE_POSIX_AIOCB_Proactor::handle_events_i (u_long milli_seconds)
{
int result_suspend = 0;
int retval= 0;
if (milli_seconds == ACE_INFINITE)
// Indefinite blocking.
result_suspend = aio_suspend (aiocb_list_,
aiocb_list_max_size_,
0);
else
{
// Block on <aio_suspend> for <milli_seconds>
timespec timeout;
timeout.tv_sec = milli_seconds / 1000;
timeout.tv_nsec = (milli_seconds - (timeout.tv_sec * 1000)) * 1000000;
result_suspend = aio_suspend (aiocb_list_,
aiocb_list_max_size_,
&timeout);
}
// Check for errors
if (result_suspend == -1)
{
if (errno != EAGAIN && // Timeout
errno != EINTR ) // Interrupted call
ACE_ERROR ((LM_ERROR,
"%N:%l:(%P | %t)::%p\n",
"ACE_POSIX_AIOCB_Proactor::handle_events:"
"aio_suspend failed\n"));
// let continue work
// we should check "post_completed" queue
}
else
{
size_t index = 0;
size_t count = aiocb_list_max_size_; // max number to iterate
int error_status = 0;
size_t transfer_count = 0;
for (;; retval++)
{
ACE_POSIX_Asynch_Result *asynch_result =
find_completed_aio (error_status,
transfer_count,
index,
count);
if (asynch_result == 0)
break;
// Call the application code.
this->application_specific_code (asynch_result,
transfer_count,
0, // No completion key.
error_status);
}
}
// process post_completed results
retval += this->process_result_queue ();
return retval > 0 ? 1 : 0;
}
int
ACE_POSIX_AIOCB_Proactor::get_result_status (ACE_POSIX_Asynch_Result *asynch_result,
int &error_status,
size_t &transfer_count)
{
transfer_count = 0;
// Get the error status of the aio_ operation.
error_status = aio_error (asynch_result);
if (error_status == EINPROGRESS)
return 0; // not completed
ssize_t op_return = aio_return (asynch_result);
if (op_return > 0)
transfer_count = ACE_static_cast (size_t, op_return);
// else transfer_count is already 0, error_status reports the error.
return 1; // completed
}
ACE_POSIX_Asynch_Result *
ACE_POSIX_AIOCB_Proactor::find_completed_aio (int &error_status,
size_t &transfer_count,
size_t &index,
size_t &count)
{
// parameter index defines initial slot to scan
// parameter count tells us how many slots should we scan
ACE_MT (ACE_GUARD_RETURN (ACE_Thread_Mutex, ace_mon, this->mutex_, 0));
ACE_POSIX_Asynch_Result *asynch_result = 0;
if (num_started_aio_ == 0) // save time
return 0;
for (; count > 0; index++ , count--)
{
if (index >= aiocb_list_max_size_) // like a wheel
index = 0;
if (aiocb_list_[index] == 0) // Dont process null blocks.
continue;
if (0 != this->get_result_status (result_list_[index],
error_status,
transfer_count)) // completed
break;
} // end for
if (count == 0) // all processed , nothing found
return 0;
asynch_result = result_list_[index];
aiocb_list_[index] = 0;
result_list_[index] = 0;
aiocb_list_cur_size_--;
num_started_aio_--; // decrement count active aios
index++; // for next iteration
count--; // for next iteration
this->start_deferred_aio ();
//make attempt to start deferred AIO
//It is safe as we are protected by mutex_
return asynch_result;
}
int
ACE_POSIX_AIOCB_Proactor::start_aio (ACE_POSIX_Asynch_Result *result,
ACE_POSIX_Proactor::Opcode op)
{
ACE_TRACE ("ACE_POSIX_AIOCB_Proactor::start_aio");
ACE_MT (ACE_GUARD_RETURN (ACE_Thread_Mutex, ace_mon, this->mutex_, -1));
int ret_val = (aiocb_list_cur_size_ >= aiocb_list_max_size_) ? -1 : 0;
if (result == 0) // Just check the status of the list
return ret_val;
// Save operation code in the aiocb
switch (op)
{
case ACE_POSIX_Proactor::READ:
result->aio_lio_opcode = LIO_READ;
break;
case ACE_POSIX_Proactor::WRITE:
result->aio_lio_opcode = LIO_WRITE;
break;
default:
ACE_ERROR_RETURN ((LM_ERROR,
"%N:%l:(%P | %t)::\n"
"start_aio: Invalid operation code\n"),
-1);
}
if (ret_val != 0) // No free slot
{
errno = EAGAIN;
return -1;
}
// Find a free slot and store.
ssize_t slot = allocate_aio_slot (result);
if (slot < 0)
return -1;
size_t index = ACE_static_cast (size_t, slot);
result_list_[index] = result; //Store result ptr anyway
aiocb_list_cur_size_++;
ret_val = start_aio_i (result);
switch (ret_val)
{
case 0: // started OK
aiocb_list_[index] = result;
return 0;
case 1: // OS AIO queue overflow
num_deferred_aiocb_ ++;
return 0;
default: // Invalid request, there is no point
break; // to start it later
}
result_list_[index] = 0;
aiocb_list_cur_size_--;
return -1;
}
ssize_t
ACE_POSIX_AIOCB_Proactor::allocate_aio_slot (ACE_POSIX_Asynch_Result *result)
{
size_t i = 0;
// we reserve zero slot for ACE_AIOCB_Notify_Pipe_Manager
// so make check for ACE_AIOCB_Notify_Pipe_Manager request
if (notify_pipe_read_handle_ == result->aio_fildes) // Notify_Pipe ?
{ // should be free,
if (result_list_[i] != 0) // only 1 request
{ // is allowed
errno = EAGAIN;
ACE_ERROR_RETURN ((LM_ERROR,
"%N:%l:(%P | %t)::\n"
"ACE_POSIX_AIOCB_Proactor::allocate_aio_slot:"
"internal Proactor error 0\n"),
-1);
}
}
else //try to find free slot as usual, but starting from 1
{
for (i= 1; i < this->aiocb_list_max_size_; i++)
if (result_list_[i] == 0)
break;
}
if (i >= this->aiocb_list_max_size_)
ACE_ERROR_RETURN ((LM_ERROR,
"%N:%l:(%P | %t)::\n"
"ACE_POSIX_AIOCB_Proactor::allocate_aio_slot:"
"internal Proactor error 1\n"),
-1);
//setup OS notification methods for this aio
result->aio_sigevent.sigev_notify = SIGEV_NONE;
return ACE_static_cast (ssize_t, i);
}
// start_aio_i has new return codes
// 0 AIO was started successfully
// 1 AIO was not started, OS AIO queue overflow
// -1 AIO was not started, other errors
int
ACE_POSIX_AIOCB_Proactor::start_aio_i (ACE_POSIX_Asynch_Result *result)
{
ACE_TRACE ("ACE_POSIX_AIOCB_Proactor::start_aio_i");
int ret_val;
const ACE_TCHAR *ptype;
// Start IO
switch (result->aio_lio_opcode )
{
case LIO_READ :
ptype = ACE_LIB_TEXT ("read ");
ret_val = aio_read (result);
break;
case LIO_WRITE :
ptype = ACE_LIB_TEXT ("write");
ret_val = aio_write (result);
break;
default:
ptype = ACE_LIB_TEXT ("?????");
ret_val = -1;
break;
}
if (ret_val == 0)
this->num_started_aio_++;
else // if (ret_val == -1)
{
if (errno == EAGAIN || errno == ENOMEM) //Ok, it will be deferred AIO
ret_val = 1;
else
ACE_ERROR ((LM_ERROR,
ACE_LIB_TEXT ("%N:%l:(%P | %t)::start_aio_i: aio_%s %p\n"),
ptype,
ACE_LIB_TEXT ("queueing failed\n")));
}
return ret_val;
}
int
ACE_POSIX_AIOCB_Proactor::start_deferred_aio ()
{
ACE_TRACE ("ACE_POSIX_AIOCB_Proactor::start_deferred_aio");
// This protected method is called from
// find_completed_aio after any AIO completion
// We should call this method always with locked
// ACE_POSIX_AIOCB_Proactor::mutex_
//
// It tries to start the first deferred AIO
// if such exists
if (num_deferred_aiocb_ == 0)
return 0; // nothing to do
size_t i = 0;
for (i= 0; i < this->aiocb_list_max_size_; i++)
if (result_list_[i] !=0 // check for
&& aiocb_list_[i] ==0) // deferred AIO
break;
if (i >= this->aiocb_list_max_size_)
ACE_ERROR_RETURN ((LM_ERROR,
"%N:%l:(%P | %t)::\n"
"start_deferred_aio:"
"internal Proactor error 3\n"),
-1);
ACE_POSIX_Asynch_Result *result = result_list_[i];
int ret_val = start_aio_i (result);
switch (ret_val)
{
case 0 : //started OK , decrement count of deferred AIOs
aiocb_list_[i] = result;
num_deferred_aiocb_ --;
return 0;
case 1 :
return 0; //try again later
default : // Invalid Parameters , should never be
break;
}
//AL notify user
result_list_[i] = 0;
aiocb_list_cur_size_--;
num_deferred_aiocb_ --;
result->set_error (errno);
result->set_bytes_transferred (0);
this->putq_result (result); // we are with locked mutex_ here !
return -1;
}
int
ACE_POSIX_AIOCB_Proactor::cancel_aio (ACE_HANDLE handle)
{
// This new method should be called from
// ACE_POSIX_Asynch_Operation instead of usual ::aio_cancel
// It scans the result_list_ and defines all AIO requests
// that were issued for handle "handle"
//
// For all deferred AIO requests with handle "handle"
// it removes its from the lists and notifies user
//
// For all running AIO requests with handle "handle"
// it calls ::aio_cancel. According to the POSIX standards
// we will receive ECANCELED for all ::aio_canceled AIO requests
// later on return from ::aio_suspend
ACE_TRACE ("ACE_POSIX_AIOCB_Proactor::cancel_aio");
int num_total = 0;
int num_cancelled = 0;
{
ACE_MT (ACE_GUARD_RETURN (ACE_Thread_Mutex, ace_mon, this->mutex_, -1));
size_t ai = 0;
for (ai = 0; ai < this->aiocb_list_max_size_; ai++)
{
if (this->result_list_[ai] == 0) // Skip empty slot
continue;
if (this->result_list_[ai]->aio_fildes != handle) // Not ours
continue;
num_total++;
ACE_POSIX_Asynch_Result *asynch_result = this->result_list_[ai];
if (this->aiocb_list_[ai] == 0) // Canceling a deferred operation
{
num_cancelled++;
this->num_deferred_aiocb_--;
this->aiocb_list_[ai] = 0;
this->result_list_[ai] = 0;
this->aiocb_list_cur_size_--;
asynch_result->set_error (ECANCELED);
asynch_result->set_bytes_transferred (0);
this->putq_result (asynch_result);
// we are with locked mutex_ here !
}
else // Cancel started aio
{
int rc_cancel = this->cancel_aiocb (asynch_result);
if (rc_cancel == 0) //notification in the future
num_cancelled++; //it is OS responsiblity
}
}
} // release mutex_
if (num_total == 0)
return 1; // ALLDONE
if (num_cancelled == num_total)
return 0; // CANCELLED
return 2; // NOT CANCELLED
}
int
ACE_POSIX_AIOCB_Proactor::cancel_aiocb (ACE_POSIX_Asynch_Result * result)
{
// This method is called from cancel_aio
// to cancel a previously submitted AIO request
int rc = ::aio_cancel (0, result);
// Check the return value and return 0/1/2 appropriately.
if (rc == AIO_CANCELED)
return 0;
else if (rc == AIO_ALLDONE)
return 1;
else // (rc == AIO_NOTCANCELED)
return 2;
}
// *********************************************************************
#if defined(ACE_HAS_POSIX_REALTIME_SIGNALS)
ACE_POSIX_SIG_Proactor::ACE_POSIX_SIG_Proactor (size_t max_aio_operations)
: ACE_POSIX_AIOCB_Proactor (max_aio_operations,
ACE_POSIX_Proactor::PROACTOR_SIG)
{
// = Set up the mask we'll use to block waiting for SIGRTMIN. Use that
// to add it to the signal mask for this thread, and also set the process
// signal action to pass signal information when we want it.
// Clear the signal set.
ACE_OS::sigemptyset (&this->RT_completion_signals_);
// Add the signal number to the signal set.
if (ACE_OS::sigaddset (&this->RT_completion_signals_, ACE_SIGRTMIN) == -1)
ACE_ERROR ((LM_ERROR, ACE_LIB_TEXT ("ACE_POSIX_SIG_Proactor: %p\n"),
ACE_LIB_TEXT ("sigaddset")));
this->block_signals ();
// Set up the signal action for SIGRTMIN.
this->setup_signal_handler (ACE_SIGRTMIN);
// we do not have to create notify manager
// but we should start pseudo-asynchronous accept task
// one per all future acceptors
this->get_asynch_pseudo_task().start ();
return;
}
ACE_POSIX_SIG_Proactor::ACE_POSIX_SIG_Proactor (const sigset_t signal_set,
size_t max_aio_operations)
: ACE_POSIX_AIOCB_Proactor (max_aio_operations,
ACE_POSIX_Proactor::PROACTOR_SIG)
{
// = Keep <Signal_set> with the Proactor, mask all the signals and
// setup signal actions for the signals in the <signal_set>.
// = Keep <signal_set> with the Proactor.
// Empty the signal set first.
if (sigemptyset (&this->RT_completion_signals_) == -1)
ACE_ERROR ((LM_ERROR,
"Error:(%P | %t):%p\n",
"sigemptyset failed"));
// For each signal number present in the <signal_set>, add it to
// the signal set we use, and also set up its process signal action
// to allow signal info to be passed into sigwait/sigtimedwait.
int member = 0;
for (int si = ACE_SIGRTMIN; si <= ACE_SIGRTMAX; si++)
{
member = sigismember (&signal_set,
si);
if (member == -1)
ACE_ERROR ((LM_ERROR,
"%N:%l:(%P | %t)::%p\n",
"ACE_POSIX_SIG_Proactor::ACE_POSIX_SIG_Proactor:"
"sigismember failed"));
else if (member == 1)
{
sigaddset (&this->RT_completion_signals_, si);
this->setup_signal_handler (si);
}
}
// Mask all the signals.
this->block_signals ();
// we do not have to create notify manager
// but we should start pseudo-asynchronous accept task
// one per all future acceptors
this->get_asynch_pseudo_task().start ();
return;
}
ACE_POSIX_SIG_Proactor::~ACE_POSIX_SIG_Proactor (void)
{
this->close ();
// @@ Enable the masked signals again.
}
int
ACE_POSIX_SIG_Proactor::handle_events (ACE_Time_Value &wait_time)
{
// Decrement <wait_time> with the amount of time spent in the method
ACE_Countdown_Time countdown (&wait_time);
return this->handle_events_i (&wait_time);
}
int
ACE_POSIX_SIG_Proactor::handle_events (void)
{
return this->handle_events_i (0);
}
int
ACE_POSIX_SIG_Proactor::notify_completion (int sig_num)
{
// Get this process id.
pid_t pid = ACE_OS::getpid ();
if (pid == (pid_t) -1)
ACE_ERROR_RETURN ((LM_ERROR,
"Error:%N:%l(%P | %t):%p",
"<getpid> failed"),
-1);
// Set the signal information.
sigval value;
#if defined (__FreeBSD__)
value.sigval_int = -1;
#else
value.sival_int = -1;
#endif /* __FreeBSD__ */
// Queue the signal.
if (sigqueue (pid, sig_num, value) == 0)
return 0;
if (errno != EAGAIN)
ACE_ERROR_RETURN ((LM_ERROR,
"Error:%N:%l:(%P | %t):%p\n",
"<sigqueue> failed"),
-1);
return -1;
}
ACE_Asynch_Result_Impl *
ACE_POSIX_SIG_Proactor::create_asynch_timer (ACE_Handler &handler,
const void *act,
const ACE_Time_Value &tv,
ACE_HANDLE event,
int priority,
int signal_number)
{
int is_member = 0;
// Fix the signal number.
if (signal_number == -1)
{
int si;
for (si = ACE_SIGRTMAX;
(is_member == 0) && (si >= ACE_SIGRTMIN);
si--)
{
is_member = sigismember (&this->RT_completion_signals_,
si);
if (is_member == -1)
ACE_ERROR_RETURN ((LM_ERROR,
"%N:%l:(%P | %t)::%s\n",
"ACE_POSIX_SIG_Proactor::create_asynch_timer:"
"sigismember failed"),
0);
}
if (is_member == 0)
ACE_ERROR_RETURN ((LM_ERROR,
"Error:%N:%l:(%P | %t)::%s\n",
"ACE_POSIX_SIG_Proactor::ACE_POSIX_SIG_Proactor:"
"Signal mask set empty"),
0);
else
// + 1 to nullify loop increment.
signal_number = si + 1;
}
ACE_Asynch_Result_Impl *implementation;
ACE_NEW_RETURN (implementation,
ACE_POSIX_Asynch_Timer (handler,
act,
tv,
event,
priority,
signal_number),
0);
return implementation;
}
#if 0
static void
sig_handler (int sig_num, siginfo_t *, ucontext_t *)
{
// Should never be called
ACE_DEBUG ((LM_DEBUG,
"%N:%l:(%P | %t)::sig_handler received signal: %d\n",
sig_num));
}
#endif /*if 0*/
int
ACE_POSIX_SIG_Proactor::setup_signal_handler (int signal_number) const
{
// Set up the specified signal so that signal information will be
// passed to sigwaitinfo/sigtimedwait. Don't change the default
// signal handler - having a handler and waiting for the signal can
// produce undefined behavior.
// But can not use SIG_DFL
// With SIG_DFL after delivering the first signal
// SIG_DFL handler resets SA_SIGINFO flags
// and we will lose all information sig_info
// At least all SunOS have such behavior
#if 0
struct sigaction reaction;
sigemptyset (&reaction.sa_mask); // Nothing else to mask.
reaction.sa_flags = SA_SIGINFO; // Realtime flag.
reaction.sa_sigaction = ACE_SIGNAL_C_FUNC (sig_handler); // (SIG_DFL);
int sigaction_return = ACE_OS::sigaction (signal_number,
&reaction,
0);
if (sigaction_return == -1)
ACE_ERROR_RETURN ((LM_ERROR,
"Error:%p\n",
"Proactor couldnt do sigaction for the RT SIGNAL"),
-1);
#else
ACE_UNUSED_ARG(signal_number);
#endif
return 0;
}
int
ACE_POSIX_SIG_Proactor::block_signals (void) const
{
return ACE_OS::pthread_sigmask (SIG_BLOCK, &this->RT_completion_signals_, 0);
}
ssize_t
ACE_POSIX_SIG_Proactor::allocate_aio_slot (ACE_POSIX_Asynch_Result *result)
{
size_t i = 0;
//try to find free slot as usual, starting from 0
for (i = 0; i < this->aiocb_list_max_size_; i++)
if (result_list_[i] == 0)
break;
if (i >= this->aiocb_list_max_size_)
ACE_ERROR_RETURN ((LM_ERROR,
"%N:%l:(%P | %t)::\n"
"ACE_POSIX_SIG_Proactor::allocate_aio_slot "
"internal Proactor error 1\n"),
-1);
// setup OS notification methods for this aio
// store index!!, not pointer in signal info
result->aio_sigevent.sigev_notify = SIGEV_SIGNAL;
result->aio_sigevent.sigev_signo = result->signal_number ();
#if defined (__FreeBSD__)
result->aio_sigevent.sigev_value.sigval_int = ACE_static_cast (int, i);
#else
result->aio_sigevent.sigev_value.sival_int = ACE_static_cast (int, i);
#endif /* __FreeBSD__ */
return ACE_static_cast (ssize_t, i);
}
int
ACE_POSIX_SIG_Proactor::handle_events_i (const ACE_Time_Value *timeout)
{
int result_sigwait = 0;
siginfo_t sig_info;
// Wait for the signals.
if (timeout == 0)
{
result_sigwait = ACE_OS::sigwaitinfo (&this->RT_completion_signals_,
&sig_info);
}
else
{
result_sigwait = ACE_OS::sigtimedwait (&this->RT_completion_signals_,
&sig_info,
timeout);
if (result_sigwait == -1 && errno == EAGAIN)
return 0;
}
// We should not get EINTR since ACE_OS methods restart the system call
// on EINTR. So -1 here is bad.
if (result_sigwait == -1)
return -1;
// Decide what to do. We always check the completion queue since it's an
// easy, quick check. What is decided here is whether to check for
// I/O completions and, if so, how completely to scan.
int flg_aio = 0; // 1 if AIO Completion possible
size_t index = 0; // start index to scan aiocb list
size_t count = 1; // max number of aiocbs to scan
int error_status = 0;
size_t transfer_count = 0;
if (sig_info.si_code == SI_ASYNCIO || this->os_id_ == OS_SUN_56)
{
flg_aio = 1; // AIO signal received
// define index to start
// nothing will happen if it contains garbage
#if defined (__FreeBSD__)
index = ACE_static_cast (size_t, sig_info.si_value.sigval_int);
#else
index = ACE_static_cast (size_t, sig_info.si_value.sival_int);
#endif
// Assume we have a correctly-functioning implementation, and that
// there is one I/O to process, and it's correctly specified in the
// siginfo received. There are, however, some special situations
// where this isn't true...
if (os_id_ == OS_SUN_56) // Solaris 6
{
// 1. Solaris 6 always loses any RT signal,
// if it has more SIGQUEMAX=32 pending signals
// so we should scan the whole aiocb list
// 2. Moreover,it has one more bad habit
// to notify aio completion
// with SI_QUEUE code instead of SI_ASYNCIO, hence the
// OS_SUN_56 addition to the si_code check, above.
count = aiocb_list_max_size_;
}
}
else if (sig_info.si_code != SI_QUEUE)
{
// Unknown signal code.
// may some other third-party libraries could send it
// or message queue could also generate it !
// So print the message and check our completions
ACE_ERROR ((LM_DEBUG,
ACE_LIB_TEXT ("%N:%l:(%P | %t): ")
ACE_LIB_TEXT ("ACE_POSIX_SIG_Proactor::handle_events: ")
ACE_LIB_TEXT ("Unexpected signal code (%d) returned ")
ACE_LIB_TEXT ("from sigwait; expecting %d\n"),
result_sigwait, sig_info.si_code));
flg_aio = 1;
}
int ret_aio = 0;
int ret_que = 0;
if (flg_aio)
for (;; ret_aio++)
{
ACE_POSIX_Asynch_Result *asynch_result =
find_completed_aio (error_status,
transfer_count,
index,
count);
if (asynch_result == 0)
break;
// Call the application code.
this->application_specific_code (asynch_result,
transfer_count,
0, // No completion key.
error_status); // Error
}
// process post_completed results
ret_que = this->process_result_queue ();
// Uncomment this if you want to test
// and research the behavior of you system
#if 0
ACE_DEBUG ((LM_DEBUG,
"(%t) NumAIO=%d NumQueue=%d\n",
ret_aio, ret_que));
#endif
return ret_aio + ret_que > 0 ? 1 : 0;
}
#endif /* ACE_HAS_POSIX_REALTIME_SIGNALS */
// *********************************************************************
ACE_POSIX_Asynch_Timer::ACE_POSIX_Asynch_Timer (ACE_Handler &handler,
const void *act,
const ACE_Time_Value &tv,
ACE_HANDLE event,
int priority,
int signal_number)
: ACE_Asynch_Result_Impl (),
ACE_POSIX_Asynch_Result (handler, act, event, 0, 0, priority, signal_number),
time_ (tv)
{
}
void
ACE_POSIX_Asynch_Timer::complete (size_t /* bytes_transferred */,
int /* success */,
const void * /* completion_key */,
u_long /* error */)
{
this->handler_.handle_time_out (this->time_, this->act ());
}
// *********************************************************************
ACE_POSIX_Wakeup_Completion::ACE_POSIX_Wakeup_Completion (ACE_Handler &handler,
const void *act,
ACE_HANDLE event,
int priority,
int signal_number)
: ACE_Asynch_Result_Impl (),
ACE_POSIX_Asynch_Result (handler, act, event, 0, 0, priority, signal_number)
{
}
ACE_POSIX_Wakeup_Completion::~ACE_POSIX_Wakeup_Completion (void)
{
}
void
ACE_POSIX_Wakeup_Completion::complete (size_t /* bytes_transferred */,
int /* success */,
const void * /* completion_key */,
u_long /* error */)
{
this->handler_.handle_wakeup ();
}
#endif /* ACE_HAS_AIO_CALLS */
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