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// $Id$
// ============================================================================
//
// = LIBRARY
// TAO/orbsvcs/Concurrency_Service
//
// = FILENAME
// CC_Lock.cpp
//
// = DESCRIPTION
// This class implements a lock used by the lock set from the
// concurrency control service.
//
// = AUTHORS
// Torben Worm <tworm@cs.wustl.edu>
//
// ============================================================================
#include "CC_Lock.h"
#include "tao/corba.h"
ACE_RCSID(Concurrency, CC_Lock, "$Id$")
CC_Lock::CC_Lock (void)
: mode_ (CosConcurrencyControl::intention_read),
lock_held_ (0)
{
}
CC_Lock::CC_Lock (CosConcurrencyControl::lock_mode mode)
: mode_ (mode),
lock_held_ (0)
{
}
CC_Lock::~CC_Lock (void)
{
}
void
CC_Lock::lock (CORBA::Environment &_env)
{
ACE_DEBUG ((LM_DEBUG,
"CC_Lock::lock\n"));
lock_held_++;
// if (semaphore_.acquire () == -1)
// TAO_THROW (CORBA::INTERNAL (CORBA::COMPLETED_NO));
}
CORBA::Boolean
CC_Lock::try_lock (CORBA::Environment &_env)
{
ACE_DEBUG ((LM_DEBUG,
"CC_Lock::try_lock. "));
lock_held_++;
ACE_DEBUG ((LM_DEBUG,
"lock_held_: %i, ",
lock_held_));
int success = 0;//semaphore_.tryacquire ();
ACE_DEBUG ((LM_DEBUG,
"success: %i\n", success));
if (success == -1)
{
if (errno == EBUSY)
{
lock_held_--;
return CORBA::B_FALSE;
}
else
TAO_THROW_RETURN (CORBA::INTERNAL (CORBA::COMPLETED_NO),
CORBA::B_FALSE);
}
ACE_DEBUG ((LM_DEBUG,
"lock_held_: %i, ",
lock_held_));
return CORBA::B_TRUE;
}
void
CC_Lock::unlock (CORBA::Environment &_env)
{
ACE_DEBUG ((LM_DEBUG,
"CC_Lock::unlock\n"));
if (lock_held_ == 0)
TAO_THROW (CosConcurrencyControl::LockNotHeld);
int success = 0; //semaphore_.release ();
if (success == -1)
TAO_THROW (CORBA::INTERNAL (CORBA::COMPLETED_NO));
lock_held_--;
ACE_DEBUG ((LM_DEBUG,
"lock_held_: %i, ",
lock_held_));
}
void
CC_Lock::change_mode (CosConcurrencyControl::lock_mode new_mode,
CORBA::Environment &_env)
{
ACE_DEBUG ((LM_DEBUG,
"CC_Lock::change_mode\n"));
// @@TAO Hmmm, we cannot really do anything at present since there
// is only one lock per lock set and that lock is essentially a
// write lock
if (lock_held_ == 0)
TAO_THROW (CosConcurrencyControl::LockNotHeld);
this->mode_ = new_mode;
}
void
CC_Lock::set_mode (CosConcurrencyControl::lock_mode mode)
{
this->mode_ = mode;
}
CORBA::Boolean
CC_Lock::Compatible (const CC_Lock &other)
{
return this->Compatible (other.mode_);
}
CORBA::Boolean
CC_Lock::Compatible (CosConcurrencyControl::lock_mode mode)
{
return compatible_[this->mode_][mode];
}
CosConcurrencyControl::lock_mode
CC_Lock::GetMode (void)
{
return mode_;
}
int
CC_Lock::GetLocksHeld(void)
{
return this->lock_held_;
}
void
CC_Lock::DecLocksHeld(void)
{
this->lock_held_--;
}
void
CC_Lock::dump(void)
{
printf("mode_ %i, lock_held_: %i\n", mode_, lock_held_);
}
// The check of compatibility is a hard coded table statically
// allocated. This table must be changed if the number of lock modes
// or their compatibility are changed. The table here looks different
// from the table in the spec, this is due to the different ordering
// of the lock modes in the table and in the enum in the IDL. The
// first index in the array is the mode held by this lock and the
// second index is the requested mode.
// Requested mode
// Held mode R W U IR IW
// R X X
// W X X X X X
// U X X X X = conflict
// IR X
// IW X X X
//
CORBA::Boolean CC_Lock::compatible_[NUMBER_OF_LOCK_MODES][NUMBER_OF_LOCK_MODES] ={
{CORBA::B_TRUE, CORBA::B_FALSE, CORBA::B_TRUE, CORBA::B_TRUE, CORBA::B_FALSE},
{CORBA::B_FALSE, CORBA::B_FALSE, CORBA::B_FALSE, CORBA::B_FALSE, CORBA::B_FALSE},
{CORBA::B_TRUE, CORBA::B_FALSE, CORBA::B_FALSE, CORBA::B_TRUE, CORBA::B_FALSE},
{CORBA::B_TRUE, CORBA::B_FALSE, CORBA::B_TRUE, CORBA::B_TRUE, CORBA::B_TRUE},
{CORBA::B_FALSE, CORBA::B_FALSE, CORBA::B_FALSE, CORBA::B_TRUE, CORBA::B_TRUE}};
// CC_LockModeterator
CC_LockModeIterator::CC_LockModeIterator(void)
: current_ (CosConcurrencyControl::intention_read)
{
}
CC_LockModeIterator::~CC_LockModeIterator(void)
{
// Do nothing
}
void CC_LockModeIterator::First(void)
{
current_ = CosConcurrencyControl::intention_read;
}
void CC_LockModeIterator::Next(CORBA::Environment &_env)
{
switch(current_)
{
case CosConcurrencyControl::intention_read:
current_ = CosConcurrencyControl::read;
break;
case CosConcurrencyControl::read:
current_ = CosConcurrencyControl::upgrade;
break;
case CosConcurrencyControl::upgrade:
current_ = CosConcurrencyControl::intention_write;
break;
case CosConcurrencyControl::intention_write:
current_ = CosConcurrencyControl::write;
break;
case CosConcurrencyControl::write:
TAO_THROW(CORBA::INTERNAL (CORBA::COMPLETED_NO));
default:
TAO_THROW(CORBA::INTERNAL (CORBA::COMPLETED_NO));
}
}
CORBA::Boolean
CC_LockModeIterator::IsDone(void)
{
if(current_==CosConcurrencyControl::write)
return CORBA::B_TRUE;
else
return CORBA::B_FALSE;
}
CosConcurrencyControl::lock_mode
CC_LockModeIterator::GetLockMode(void)
{
return current_;
}
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