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74c4b51266b8857b943590c4c8d5d181fedde8f4
harbour-core/src/vm/garbage.c
Przemysław Czerpak 74c4b51266 2015-03-05 20:46 UTC+0100 Przemyslaw Czerpak (druzus/at/poczta.onet.pl) 
* include/hbapi.h
  * src/vm/garbage.c
    + added hb_gcDummyClear() function

  * include/hbapirdd.h
  * include/hbusrrdd.ch
    + added DBTF_CPYCTR constant value - when set in dbTransInfo.uiFlags
      then after record transfer field counters should to be copied from
      source to destination area

  * include/hbapirdd.h
  * src/rdd/wafunc.c
    + added new C functions hb_dbTransInfoPut() and hb_dbTransInfoGet()
      which allow to store and retrieve pointer to DBTRANSINFO structure
      into/from HB_ITEM with strict type verification.

  * src/rdd/wafunc.c
    * pass pointer to DBTRANSINFO structure as argument of DBI_TRANSREC
      action. It allows RDD serving destination area to decide which
      fields and how should be transferred updating uiFlags, uiItemCount
      and lpTransItems members of DBTRANSINFO.
      If RDD removes all fields from DBTRANSINFO structure (uiItemCount==0)
      or does not return HB_SUCCESS for DBI_TRANSREC action (default WA
      implementation returns HB_SUCCESS so it's not necessary to overload
      it if RDD does not make any additional operations) then record
      transfer is interrupted.
    * copy field counters only when destination area asked about it setting
      DBTF_CPYCTR in dbTransInfo.uiFlags in DBI_TRANSREC action.

  * src/rdd/dbf1.c
    * do not copy automatically updated fields when destination area
      is not empty
    * set DBTF_CPYCTR to indicate that counters should be copied from
      source to destination area when original value of automatically
      updated fields are transferred
    ; Now DBF* RDDs in Harbour respects the following rules for record
      transfer operations (COPY TO / APPEND FROM) with automatically
      updated fields:
         - COPY TO transfers original values to destination table and
           finally copy counters from the source table to destination one
           so autoincrement fields in both tables after next append will be
           initialized with the same values regardless of number of copied
           records - even if only single record is copied then counters in
           destination table will inherit next values for new record from
           the source table. Also values of RowVer and ModTime fields are
           copied from source to destination table and not updated during
           transfer operation.
         - APPEND FROM works like COPY TO (original field values and then
           counters are copied to destination table) if the source table
           supports counters and destination table is empty and FLocked()
           or opened in exclusive mode.
           If source table does not support counters for given fields, i.e.
           it is processed by transfer RDD like DELIM or SDF (RDT_TRANSFER)
           or destination table is not empty or opened in shared mode and
           FLock is not set when APPEND FROM is executed then automatically
           updated fields (counters, RowVer, ModTime) are not copied and
           initialized with new values like for each new record added to
           destination table.

  * ChangeLog.txt
    ! typo in last ChangeLog entry
2015-03-05 20:46:23 +01:00

816 lines
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/*
* Harbour Project source code:
* The garbage collector for Harbour
*
* Copyright 1999 Ryszard Glab <rglab@imid.med.pl>
* www - http://harbour-project.org
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this software; see the file COPYING.txt. If not, write to
* the Free Software Foundation, Inc., 59 Temple Place, Suite 330,
* Boston, MA 02111-1307 USA (or visit the web site http://www.gnu.org/).
*
* As a special exception, the Harbour Project gives permission for
* additional uses of the text contained in its release of Harbour.
*
* The exception is that, if you link the Harbour libraries with other
* files to produce an executable, this does not by itself cause the
* resulting executable to be covered by the GNU General Public License.
* Your use of that executable is in no way restricted on account of
* linking the Harbour library code into it.
*
* This exception does not however invalidate any other reasons why
* the executable file might be covered by the GNU General Public License.
*
* This exception applies only to the code released by the Harbour
* Project under the name Harbour. If you copy code from other
* Harbour Project or Free Software Foundation releases into a copy of
* Harbour, as the General Public License permits, the exception does
* not apply to the code that you add in this way. To avoid misleading
* anyone as to the status of such modified files, you must delete
* this exception notice from them.
*
* If you write modifications of your own for Harbour, it is your choice
* whether to permit this exception to apply to your modifications.
* If you do not wish that, delete this exception notice.
*
*/
/* NOTE: Need to have these before Harbour headers,
because in MT mode, they will automatically #include <os2.h>. */
#define INCL_DOSPROCESS
#include "hbvmopt.h"
#include "hbapi.h"
#include "hbstack.h"
#include "hbapicls.h"
#include "hbapiitm.h"
#include "hbapierr.h"
#include "hbapigt.h"
#include "hbvm.h"
#include "error.ch"
#if ! defined( HB_GC_PTR )
#if defined( HB_MT_VM )
# include "hbthread.h"
# include "hbatomic.h"
/* Use spinlock instead of mutex */
# if defined( HB_SPINLOCK_INIT ) && ! defined( HB_HELGRIND_FRIENDLY )
static HB_SPINLOCK_T s_gcSpinLock = HB_SPINLOCK_INIT;
# define HB_GC_LOCK() HB_SPINLOCK_ACQUIRE( &s_gcSpinLock )
# define HB_GC_UNLOCK() HB_SPINLOCK_RELEASE( &s_gcSpinLock )
# else
static HB_CRITICAL_NEW( s_gcMtx );
# define HB_GC_LOCK() hb_threadEnterCriticalSection( &s_gcMtx )
# define HB_GC_UNLOCK() hb_threadLeaveCriticalSection( &s_gcMtx )
#endif
#else
# define HB_GC_LOCK() do {} while( 0 )
# define HB_GC_UNLOCK() do {} while( 0 )
#endif /* HB_MT_VM */
/* holder of memory block information */
/* NOTE: HB_USHORT is used intentionally to fill up the structure to
* full 16 bytes (on 16/32 bit environment)
*/
typedef struct HB_GARBAGE_
{
struct HB_GARBAGE_ * pNext; /* next memory block */
struct HB_GARBAGE_ * pPrev; /* previous memory block */
const HB_GC_FUNCS * pFuncs; /* cleanup function called before memory releasing */
HB_USHORT locked; /* locking counter */
HB_USHORT used; /* used/unused block */
} HB_GARBAGE, * PHB_GARBAGE;
#ifdef HB_ALLOC_ALIGNMENT
# define HB_GARBAGE_SIZE ( ( sizeof( HB_GARBAGE ) + HB_ALLOC_ALIGNMENT - 1 ) - \
( sizeof( HB_GARBAGE ) + HB_ALLOC_ALIGNMENT - 1 ) % HB_ALLOC_ALIGNMENT )
#else
# define HB_GARBAGE_SIZE sizeof( HB_GARBAGE )
#endif
#define HB_GC_PTR( p ) ( ( PHB_GARBAGE ) ( ( HB_BYTE * ) ( p ) - HB_GARBAGE_SIZE ) )
#endif /* ! defined( HB_GC_PTR ) */
#define HB_BLOCK_PTR( p ) ( ( void * ) ( ( HB_BYTE * ) ( p ) + HB_GARBAGE_SIZE ) )
/* we may use a cache later */
#define HB_GARBAGE_NEW( nSize ) ( ( PHB_GARBAGE ) hb_xgrab( HB_GARBAGE_SIZE + ( nSize ) ) )
#define HB_GARBAGE_FREE( pAlloc ) hb_xfree( ( void * ) ( pAlloc ) )
/* status of memory block */
/* flags stored in 'used' slot */
#define HB_GC_USED_FLAG 1 /* the bit for used/unused flag */
#define HB_GC_DELETE 2 /* item marked to delete */
#define HB_GC_DELETELST 4 /* item will be deleted during finalization */
#ifdef HB_GC_AUTO
#define HB_GC_AUTO_MAX ( ( HB_PTRUINT ) ( -1 ) )
/* number of allocated memory blocks */
static HB_PTRUINT s_ulBlocks = 0;
/* number of allocated memory blocks after last GC activation */
static HB_PTRUINT s_ulBlocksMarked = 0;
/* number of memory blocks between automatic GC activation */
static HB_PTRUINT s_ulBlocksAuto = 0;
/* number of allocated memory blocks which should force next GC activation */
static HB_PTRUINT s_ulBlocksCheck = 0;
# define HB_GC_AUTO_INC() ++s_ulBlocks
# define HB_GC_AUTO_DEC() --s_ulBlocks
#else
# define HB_GC_AUTO_INC() do {} while( 0 )
# define HB_GC_AUTO_DEC() do {} while( 0 )
#endif
/* pointer to memory block that will be checked in next step */
static PHB_GARBAGE s_pCurrBlock = NULL;
/* memory blocks are stored in linked list with a loop */
/* pointer to locked memory blocks */
static PHB_GARBAGE s_pLockedBlock = NULL;
/* pointer to memory blocks that will be deleted */
static PHB_GARBAGE s_pDeletedBlock = NULL;
/* marks if block releasing is requested during garbage collecting */
static HB_BOOL s_bCollecting = HB_FALSE;
/* flag for used/unused blocks - the meaning of the HB_GC_USED_FLAG bit
* is reversed on every collecting attempt
*/
static HB_USHORT s_uUsedFlag = HB_GC_USED_FLAG;
static void hb_gcLink( PHB_GARBAGE * pList, PHB_GARBAGE pAlloc )
{
if( *pList )
{
/* add new block at the logical end of list */
pAlloc->pNext = *pList;
pAlloc->pPrev = ( *pList )->pPrev;
pAlloc->pPrev->pNext = pAlloc;
( *pList )->pPrev = pAlloc;
}
else
{
*pList = pAlloc->pNext = pAlloc->pPrev = pAlloc;
}
}
static void hb_gcUnlink( PHB_GARBAGE * pList, PHB_GARBAGE pAlloc )
{
pAlloc->pPrev->pNext = pAlloc->pNext;
pAlloc->pNext->pPrev = pAlloc->pPrev;
if( *pList == pAlloc )
{
*pList = pAlloc->pNext;
if( *pList == pAlloc )
*pList = NULL; /* this was the last block */
}
}
/* allocates a memory block */
void * hb_gcAllocate( HB_SIZE nSize, const HB_GC_FUNCS * pFuncs )
{
PHB_GARBAGE pAlloc;
pAlloc = HB_GARBAGE_NEW( nSize );
pAlloc->pFuncs = pFuncs;
pAlloc->locked = 1;
pAlloc->used = s_uUsedFlag;
HB_GC_LOCK();
hb_gcLink( &s_pLockedBlock, pAlloc );
HB_GC_UNLOCK();
return HB_BLOCK_PTR( pAlloc ); /* hide the internal data */
}
/* allocates a memory block */
void * hb_gcAllocRaw( HB_SIZE nSize, const HB_GC_FUNCS * pFuncs )
{
PHB_GARBAGE pAlloc;
pAlloc = HB_GARBAGE_NEW( nSize );
pAlloc->pFuncs = pFuncs;
pAlloc->locked = 0;
pAlloc->used = s_uUsedFlag;
HB_GC_LOCK();
#ifdef HB_GC_AUTO
if( s_ulBlocks > s_ulBlocksCheck )
{
HB_GC_UNLOCK();
hb_gcCollectAll( HB_TRUE );
HB_GC_LOCK();
pAlloc->used = s_uUsedFlag;
}
HB_GC_AUTO_INC();
#endif
hb_gcLink( &s_pCurrBlock, pAlloc );
HB_GC_UNLOCK();
return HB_BLOCK_PTR( pAlloc ); /* hide the internal data */
}
/* release a memory block allocated with hb_gcAlloc*() */
void hb_gcFree( void * pBlock )
{
if( pBlock )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pBlock );
/* Don't release the block that will be deleted during finalization */
if( ! ( pAlloc->used & HB_GC_DELETE ) )
{
HB_GC_LOCK();
if( pAlloc->locked )
hb_gcUnlink( &s_pLockedBlock, pAlloc );
else
{
hb_gcUnlink( &s_pCurrBlock, pAlloc );
HB_GC_AUTO_DEC();
}
HB_GC_UNLOCK();
HB_GARBAGE_FREE( pAlloc );
}
}
else
{
hb_errInternal( HB_EI_XFREENULL, NULL, NULL, NULL );
}
}
/* return cleanup function pointer */
const HB_GC_FUNCS * hb_gcFuncs( void * pBlock )
{
return HB_GC_PTR( pBlock )->pFuncs;
}
/* increment reference counter */
#undef hb_gcRefInc
void hb_gcRefInc( void * pBlock )
{
hb_xRefInc( HB_GC_PTR( pBlock ) );
}
/* decrement reference counter and free the block when 0 reached */
#undef hb_gcRefFree
void hb_gcRefFree( void * pBlock )
{
if( pBlock )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pBlock );
if( hb_xRefDec( pAlloc ) )
{
/* Don't release the block that will be deleted during finalization */
if( ! ( pAlloc->used & HB_GC_DELETE ) )
{
pAlloc->used |= HB_GC_DELETE;
/* execute clean-up function */
pAlloc->pFuncs->clear( pBlock );
if( hb_xRefCount( pAlloc ) != 0 )
{
if( pAlloc->used & HB_GC_DELETE )
{
pAlloc->used = s_uUsedFlag;
if( hb_vmRequestQuery() == 0 )
hb_errRT_BASE( EG_DESTRUCTOR, 1301, NULL, "Reference to freed block", 0 );
}
}
else
{
HB_GC_LOCK();
if( pAlloc->locked )
hb_gcUnlink( &s_pLockedBlock, pAlloc );
else
{
hb_gcUnlink( &s_pCurrBlock, pAlloc );
HB_GC_AUTO_DEC();
}
HB_GC_UNLOCK();
HB_GARBAGE_FREE( pAlloc );
}
}
}
}
else
{
hb_errInternal( HB_EI_XFREENULL, NULL, NULL, NULL );
}
}
/* return number of references */
#undef hb_gcRefCount
HB_COUNTER hb_gcRefCount( void * pBlock )
{
return hb_xRefCount( HB_GC_PTR( pBlock ) );
}
HB_GARBAGE_FUNC( hb_gcDummyClear )
{
HB_SYMBOL_UNUSED( Cargo );
}
HB_GARBAGE_FUNC( hb_gcDummyMark )
{
HB_SYMBOL_UNUSED( Cargo );
}
HB_GARBAGE_FUNC( hb_gcGripMark )
{
hb_gcItemRef( ( PHB_ITEM ) Cargo );
}
static HB_GARBAGE_FUNC( hb_gcGripRelease )
{
if( HB_IS_COMPLEX( ( PHB_ITEM ) Cargo ) )
hb_itemClear( ( PHB_ITEM ) Cargo );
}
static const HB_GC_FUNCS s_gcGripFuncs =
{
hb_gcGripRelease,
hb_gcGripMark
};
PHB_ITEM hb_gcGripGet( PHB_ITEM pOrigin )
{
PHB_GARBAGE pAlloc = HB_GARBAGE_NEW( sizeof( HB_ITEM ) );
PHB_ITEM pItem = ( PHB_ITEM ) HB_BLOCK_PTR( pAlloc );
pAlloc->pFuncs = &s_gcGripFuncs;
pAlloc->locked = 1;
pAlloc->used = s_uUsedFlag;
pItem->type = HB_IT_NIL;
HB_GC_LOCK();
hb_gcLink( &s_pLockedBlock, pAlloc );
HB_GC_UNLOCK();
if( pOrigin )
hb_itemCopy( pItem, pOrigin );
return pItem;
}
void hb_gcGripDrop( PHB_ITEM pItem )
{
hb_gcRefFree( pItem );
}
/* Lock a memory pointer so it will not be released if stored
outside of harbour variables
*/
void * hb_gcLock( void * pBlock )
{
if( pBlock )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pBlock );
HB_GC_LOCK();
if( ! pAlloc->locked )
{
hb_gcUnlink( &s_pCurrBlock, pAlloc );
hb_gcLink( &s_pLockedBlock, pAlloc );
HB_GC_AUTO_DEC();
}
++pAlloc->locked;
HB_GC_UNLOCK();
}
return pBlock;
}
/* Unlock a memory pointer so it can be released if there is no
references inside of harbour variables
*/
void * hb_gcUnlock( void * pBlock )
{
if( pBlock )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pBlock );
if( pAlloc->locked )
{
HB_GC_LOCK();
if( pAlloc->locked )
{
if( --pAlloc->locked == 0 )
{
pAlloc->used = s_uUsedFlag;
hb_gcUnlink( &s_pLockedBlock, pAlloc );
hb_gcLink( &s_pCurrBlock, pAlloc );
HB_GC_AUTO_INC();
}
}
HB_GC_UNLOCK();
}
}
return pBlock;
}
void hb_gcAttach( void * pBlock )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pBlock );
if( pAlloc->locked )
{
HB_GC_LOCK();
if( pAlloc->locked )
{
if( --pAlloc->locked == 0 )
{
pAlloc->used = s_uUsedFlag;
hb_gcUnlink( &s_pLockedBlock, pAlloc );
hb_gcLink( &s_pCurrBlock, pAlloc );
HB_GC_AUTO_INC();
pAlloc = NULL;
}
}
HB_GC_UNLOCK();
}
if( pAlloc )
hb_xRefInc( pAlloc );
}
/* mark passed memory block as used so it will be not released by the GC */
void hb_gcMark( void * pBlock )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pBlock );
if( ( pAlloc->used & ~HB_GC_DELETE ) == s_uUsedFlag )
{
pAlloc->used ^= HB_GC_USED_FLAG; /* mark this codeblock as used */
pAlloc->pFuncs->mark( pBlock );
}
}
/* Mark a passed item as used so it will be not released by the GC
*/
void hb_gcItemRef( PHB_ITEM pItem )
{
while( HB_IS_BYREF( pItem ) )
{
if( HB_IS_ENUM( pItem ) )
return;
else if( HB_IS_EXTREF( pItem ) )
{
pItem->item.asExtRef.func->mark( pItem->item.asExtRef.value );
return;
}
else if( ! HB_IS_MEMVAR( pItem ) &&
pItem->item.asRefer.offset == 0 &&
pItem->item.asRefer.value >= 0 )
{
/* array item reference */
PHB_GARBAGE pAlloc = HB_GC_PTR( pItem->item.asRefer.BasePtr.array );
if( ( pAlloc->used & ~HB_GC_DELETE ) == s_uUsedFlag )
{
/* mark this array as used */
pAlloc->used ^= HB_GC_USED_FLAG;
/* mark also all array elements */
pAlloc->pFuncs->mark( HB_BLOCK_PTR( pAlloc ) );
}
return;
}
pItem = hb_itemUnRefOnce( pItem );
}
if( HB_IS_ARRAY( pItem ) )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pItem->item.asArray.value );
/* Check this array only if it was not checked yet */
if( ( pAlloc->used & ~HB_GC_DELETE ) == s_uUsedFlag )
{
/* mark this array as used so it will be no re-checked from
* other references
*/
pAlloc->used ^= HB_GC_USED_FLAG;
/* mark also all array elements */
pAlloc->pFuncs->mark( HB_BLOCK_PTR( pAlloc ) );
}
}
else if( HB_IS_HASH( pItem ) )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pItem->item.asHash.value );
/* Check this hash table only if it was not checked yet */
if( ( pAlloc->used & ~HB_GC_DELETE ) == s_uUsedFlag )
{
/* mark this hash table as used */
pAlloc->used ^= HB_GC_USED_FLAG;
/* mark also all hash elements */
pAlloc->pFuncs->mark( HB_BLOCK_PTR( pAlloc ) );
}
}
else if( HB_IS_BLOCK( pItem ) )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pItem->item.asBlock.value );
if( ( pAlloc->used & ~HB_GC_DELETE ) == s_uUsedFlag )
{
/* mark this codeblock as used */
pAlloc->used ^= HB_GC_USED_FLAG;
/* mark as used all detached variables in a codeblock */
pAlloc->pFuncs->mark( HB_BLOCK_PTR( pAlloc ) );
}
}
else if( HB_IS_POINTER( pItem ) )
{
if( pItem->item.asPointer.collect )
{
PHB_GARBAGE pAlloc = HB_GC_PTR( pItem->item.asPointer.value );
if( ( pAlloc->used & ~HB_GC_DELETE ) == s_uUsedFlag )
{
/* mark this memory block as used */
pAlloc->used ^= HB_GC_USED_FLAG;
/* mark also all internal user blocks attached to this block */
pAlloc->pFuncs->mark( HB_BLOCK_PTR( pAlloc ) );
}
}
}
/* all other data types don't need the GC */
}
void hb_gcCollect( void )
{
/* TODO: decrease the amount of time spend collecting */
hb_gcCollectAll( HB_FALSE );
}
/* Check all memory block if they can be released
*/
void hb_gcCollectAll( HB_BOOL fForce )
{
/* MTNOTE: it's not necessary to protect s_bCollecting with mutex
* because it can be changed at RT only inside this procedure
* when all other threads are stoped by hb_vmSuspendThreads(),
* [druzus]
*/
if( ! s_bCollecting && hb_vmSuspendThreads( fForce ) )
{
PHB_GARBAGE pAlloc, pDelete;
if( ! s_pCurrBlock || s_bCollecting )
{
hb_vmResumeThreads();
return;
}
s_bCollecting = HB_TRUE;
/* Step 1 - mark */
/* All blocks are already marked because we are flipping
* the used/unused flag
*/
/* Step 2 - sweep */
/* check all known places for blocks they are referring */
hb_vmIsStackRef();
hb_vmIsStaticRef();
hb_clsIsClassRef();
/* check list of locked block for blocks referenced from
* locked block
*/
if( s_pLockedBlock )
{
pAlloc = s_pLockedBlock;
do
{
pAlloc->pFuncs->mark( HB_BLOCK_PTR( pAlloc ) );
pAlloc = pAlloc->pNext;
}
while( s_pLockedBlock != pAlloc );
}
/* Step 3 - finalize */
/* Release all blocks that are still marked as unused */
/*
* infinite loop can appear when we are executing clean-up functions
* scanning s_pCurrBlock. It's possible that one of them will free
* the GC block which we are using as stop condition. Only blocks
* for which we set HB_GC_DELETE flag are guarded against releasing.
* To avoid such situation first we are moving blocks which will be
* deleted to separate list. It's additional operation but it can
* even increase the speed when we are deleting only few percent
* of all allocated blocks because in next passes we will scan only
* deleted block list. [druzus]
*/
pAlloc = NULL; /* for stop condition */
do
{
if( s_pCurrBlock->used == s_uUsedFlag )
{
pDelete = s_pCurrBlock;
pDelete->used |= HB_GC_DELETE | HB_GC_DELETELST;
hb_gcUnlink( &s_pCurrBlock, pDelete );
hb_gcLink( &s_pDeletedBlock, pDelete );
HB_GC_AUTO_DEC();
}
else
{
/* at least one block will not be deleted, set new stop condition */
if( ! pAlloc )
pAlloc = s_pCurrBlock;
s_pCurrBlock = s_pCurrBlock->pNext;
}
}
while( pAlloc != s_pCurrBlock );
/* Step 4 - flip flag */
/* Reverse used/unused flag so we don't have to mark all blocks
* during next collecting
*/
s_uUsedFlag ^= HB_GC_USED_FLAG;
#ifdef HB_GC_AUTO
/* store number of marked blocks for automatic GC activation */
s_ulBlocksMarked = s_ulBlocks;
if( s_ulBlocksAuto == 0 )
s_ulBlocksCheck = HB_GC_AUTO_MAX;
else
{
s_ulBlocksCheck = s_ulBlocksMarked + s_ulBlocksAuto;
if( s_ulBlocksCheck <= s_ulBlocksMarked )
s_ulBlocksCheck = HB_GC_AUTO_MAX;
}
#endif
/* call memory manager cleanup function */
hb_xclean();
/* resume suspended threads */
hb_vmResumeThreads();
/* do we have any deleted blocks? */
if( s_pDeletedBlock )
{
/* call a cleanup function */
pAlloc = s_pDeletedBlock;
do
{
s_pDeletedBlock->pFuncs->clear( HB_BLOCK_PTR( s_pDeletedBlock ) );
s_pDeletedBlock = s_pDeletedBlock->pNext;
}
while( pAlloc != s_pDeletedBlock );
/* release all deleted blocks */
do
{
pDelete = s_pDeletedBlock;
hb_gcUnlink( &s_pDeletedBlock, pDelete );
if( hb_xRefCount( pDelete ) != 0 )
{
pDelete->used = s_uUsedFlag;
pDelete->locked = 0;
HB_GC_LOCK();
hb_gcLink( &s_pCurrBlock, pDelete );
HB_GC_AUTO_INC();
HB_GC_UNLOCK();
if( hb_vmRequestQuery() == 0 )
hb_errRT_BASE( EG_DESTRUCTOR, 1302, NULL, "Reference to freed block", 0 );
}
else
HB_GARBAGE_FREE( pDelete );
}
while( s_pDeletedBlock );
}
s_bCollecting = HB_FALSE;
}
}
/* MTNOTE: It's executed at the end of HVM cleanup code just before
* application exit when other threads are destroyed, so it
* does not need additional protection code for MT mode, [druzus]
*/
void hb_gcReleaseAll( void )
{
if( s_pCurrBlock )
{
PHB_GARBAGE pAlloc, pDelete;
s_bCollecting = HB_TRUE;
pAlloc = s_pCurrBlock;
do
{
/* call a cleanup function */
s_pCurrBlock->used |= HB_GC_DELETE | HB_GC_DELETELST;
s_pCurrBlock->pFuncs->clear( HB_BLOCK_PTR( s_pCurrBlock ) );
s_pCurrBlock = s_pCurrBlock->pNext;
}
while( s_pCurrBlock && pAlloc != s_pCurrBlock );
do
{
HB_TRACE( HB_TR_INFO, ( "Release %p", s_pCurrBlock ) );
pDelete = s_pCurrBlock;
hb_gcUnlink( &s_pCurrBlock, pDelete );
HB_GC_AUTO_DEC();
HB_GARBAGE_FREE( pDelete );
}
while( s_pCurrBlock );
}
s_bCollecting = HB_FALSE;
}
/* service a single garbage collector step
* Check a single memory block if it can be released
*/
HB_FUNC( HB_GCSTEP )
{
hb_gcCollect();
}
/* Check all memory blocks if they can be released
*/
HB_FUNC( HB_GCALL )
{
HB_STACK_TLS_PRELOAD
/* call hb_ret() to clear stack return item, HVM does not clean
* it before calling functions/procedures if caller does not
* try to retrieve returned value. It's safe and cost nearly
* nothing in whole GC scan process. It may help when previously
* called function returned complex item with cross references.
* It's quite common situation that people executes hb_gcAll()
* immediately after such function. [druzus]
*/
hb_ret();
hb_gcCollectAll( hb_pcount() < 1 || hb_parl( 1 ) );
}
#ifdef HB_GC_AUTO
HB_FUNC( HB_GCSETAUTO )
{
HB_STACK_TLS_PRELOAD
HB_PTRUINT nBlocks, nPrevBlocks;
HB_BOOL fSet = HB_ISNUM( 1 );
nBlocks = fSet ? hb_parnint( 1 ) * 1000 : 0;
HB_GC_LOCK();
nPrevBlocks = s_ulBlocksAuto;
if( fSet )
{
s_ulBlocksAuto = nBlocks;
if( s_ulBlocksAuto == 0 )
s_ulBlocksCheck = HB_GC_AUTO_MAX;
else
{
s_ulBlocksCheck = s_ulBlocksMarked + s_ulBlocksAuto;
if( s_ulBlocksCheck <= s_ulBlocksMarked )
s_ulBlocksCheck = HB_GC_AUTO_MAX;
}
}
HB_GC_UNLOCK();
hb_retnint( nPrevBlocks / 1000 );
}
#endif
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