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harbour-core/harbour/source/vm/memvars.c

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/*
* $Id$
*/
/*
* Harbour Project source code:
* Memvar (PRIVATE/PUBLIC) runtime support
*
* Copyright 1999 Ryszard Glab <rglab@imid.med.pl>
* www - http://www.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. 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.
*
*/
/*
* The following parts are Copyright of the individual authors.
* www - http://www.harbour-project.org
*
* Copyright 1999-2001 Viktor Szakats <viktor.szakats@syenar.hu>
* __MVSAVE()
* __MVRESTORE() (Thanks to Dave Pearson and Jo French for the original
* Clipper function (FReadMem()) to read .mem files)
*
* See doc/license.txt for licensing terms.
*
*/
#include <ctype.h> /* for toupper() function */
#include "hbapi.h"
#include "hbapiitm.h"
#include "hbapierr.h"
#include "hbapifs.h" /* for __MVSAVE()/__MVRESTORE() */
#include "hbdate.h" /* for __MVSAVE()/__MVRESTORE() */
#include "hbcomp.h" /* for VS_* macros */
#include "error.ch"
#include "hbmemvar.ch"
static PHB_DYNS * s_privateStack = NULL;
static ULONG s_privateStackSize = 0;
static ULONG s_privateStackCnt = 0;
static ULONG s_privateStackBase = 0;
static ULONG s_globalTableSize = 0;
static ULONG s_globalFirstFree = 0;
static ULONG s_globalLastFree = 0;
static ULONG s_globalFreeCnt = 0;
static HB_VALUE_PTR s_globalTable = NULL;
#define TABLE_INITHB_VALUE 100
#define TABLE_EXPANDHB_VALUE 50
struct mv_PUBLIC_var_info
{
int iPos;
BOOL bFound;
HB_DYNS_PTR pDynSym;
};
static void hb_memvarCreateFromDynSymbol( PHB_DYNS, BYTE, PHB_ITEM );
static void hb_memvarAddPrivate( PHB_DYNS );
static HB_DYNS_PTR hb_memvarFindSymbol( HB_ITEM_PTR );
void hb_memvarsInit( void )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarsInit()"));
s_globalTable = ( HB_VALUE_PTR ) hb_xgrab( sizeof( HB_VALUE ) * TABLE_INITHB_VALUE );
s_globalTableSize = TABLE_INITHB_VALUE;
s_globalFreeCnt = 0;
s_globalFirstFree = s_globalLastFree = 1;
s_privateStack = ( PHB_DYNS * ) hb_xgrab( sizeof( PHB_DYNS ) * TABLE_INITHB_VALUE );
s_privateStackSize = TABLE_INITHB_VALUE;
s_privateStackCnt = s_privateStackBase = 0;
}
/* clear all variables except the detached ones
* Should be called at application exit only
*/
void hb_memvarsRelease( void )
{
ULONG ulCnt = s_globalLastFree;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarsClear()"));
if( s_globalTable )
{
while( --ulCnt )
{
if( s_globalTable[ ulCnt ].counter && s_globalTable[ ulCnt ].hPrevMemvar != ( HB_HANDLE )-1 )
{
hb_itemClear( &s_globalTable[ ulCnt ].item );
s_globalTable[ ulCnt ].counter = 0;
}
}
}
}
void hb_memvarsFree( void )
{
if( s_globalTable )
hb_xfree( s_globalTable );
if( s_privateStack )
hb_xfree( s_privateStack );
}
/*
* This function base address of values table
*/
HB_VALUE_PTR *hb_memvarValueBaseAddress( void )
{
return &s_globalTable;
}
/*
* This function creates new global value.
*
* pSource = item value that have to be stored or NULL
* bTrueMemvar = TRUE | FALSE
* FALSE if function is called to create memvar variable for a codeblock
* (to store detached local variable) - in this case we have to do
* exact copy of passed item (without duplicating its value and
* without reference decrementing)
* TRUE if we are creating regular memvar variable (PUBLI or PRIVATE)
* In this case we have to do normal item coping.
*
* Returns:
* handle to variable memory or fails
*
*/
HB_HANDLE hb_memvarValueNew( HB_ITEM_PTR pSource, BOOL bTrueMemvar )
{
HB_VALUE_PTR pValue;
HB_HANDLE hValue; /* handle 0 is reserved */
/* = 1 removed, since it's initialized in all branches. Caused a warning with Borland C++ */
HB_TRACE(HB_TR_DEBUG, ("hb_memvarValueNew(%p, %d)", pSource, (int) bTrueMemvar));
if( s_globalFreeCnt )
{
/* There are holes in the table
* Get a first available hole
*/
hValue = s_globalFirstFree;
--s_globalFreeCnt;
/* Now find the next hole
*/
if( s_globalFreeCnt )
{
++s_globalFirstFree;
while( s_globalTable[ s_globalFirstFree ].counter )
++s_globalFirstFree;
}
else
/* No more holes
*/
s_globalFirstFree = s_globalLastFree;
}
else
{
/* Allocate the value from the end of table
*/
if( s_globalFirstFree < s_globalTableSize )
{
hValue = s_globalFirstFree;
s_globalFirstFree = ++s_globalLastFree;
}
else
{
/* No more free values in the table - expand the table
*/
hValue = s_globalTableSize;
s_globalFirstFree = s_globalLastFree = s_globalTableSize + 1;
s_globalTableSize += TABLE_EXPANDHB_VALUE;
s_globalTable = ( HB_VALUE_PTR ) hb_xrealloc( s_globalTable, sizeof( HB_VALUE ) * s_globalTableSize );
}
}
pValue = s_globalTable + hValue;
pValue->counter = 1;
pValue->item.type = HB_IT_NIL;
if( pSource )
{
if( bTrueMemvar )
hb_itemCopy( &pValue->item, pSource );
else
memcpy( &pValue->item, pSource, sizeof(HB_ITEM) );
}
if( bTrueMemvar )
pValue->hPrevMemvar = 0;
else
pValue->hPrevMemvar = ( HB_HANDLE )-1; /* detached variable */
HB_TRACE(HB_TR_INFO, ("hb_memvarValueNew: memvar item created with handle %i", hValue));
return hValue;
}
/*
* This function pushes passed dynamic symbol that belongs to PRIVATE variable
* into the stack. The value will be popped from it if the variable falls
* outside the scope (either by using RELEASE, CLEAR ALL, CLEAR MEMORY or by
* an exit from the function/procedure)
*
*/
static void hb_memvarAddPrivate( PHB_DYNS pDynSym )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarAddPrivate(%p)", pDynSym));
/* Allocate the value from the end of table
*/
if( s_privateStackCnt == s_privateStackSize )
{
/* No more free values in the table - expand the table
*/
s_privateStackSize += TABLE_EXPANDHB_VALUE;
s_privateStack = ( PHB_DYNS * ) hb_xrealloc( s_privateStack, sizeof( PHB_DYNS ) * s_privateStackSize );
}
s_privateStack[ s_privateStackCnt++ ] = pDynSym;
}
/*
* This function returns current PRIVATE variables stack base
*/
ULONG hb_memvarGetPrivatesBase( void )
{
ULONG ulBase = s_privateStackBase;
s_privateStackBase = s_privateStackCnt;
return ulBase;
}
/*
* This function releases PRIVATE variables created after passed base
*
*/
void hb_memvarSetPrivatesBase( ULONG ulBase )
{
HB_HANDLE hVar, hOldValue;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarSetPrivatesBase(%lu)", ulBase));
while( s_privateStackCnt > s_privateStackBase )
{
--s_privateStackCnt;
hVar = s_privateStack[ s_privateStackCnt ]->hMemvar;
if( hVar )
{
hOldValue = s_globalTable[ hVar ].hPrevMemvar;
hb_memvarValueDecRef( hVar );
/*
* Restore previous value for variables that were overridden
*/
s_privateStack[ s_privateStackCnt ]->hMemvar = hOldValue;
}
}
s_privateStackBase = ulBase;
}
/*
* This function increases the number of references to passed global value
*
*/
void hb_memvarValueIncRef( HB_HANDLE hValue )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarValueIncRef(%lu)", hValue));
s_globalTable[ hValue ].counter++;
HB_TRACE(HB_TR_INFO, ("Memvar item (%i) increment refCounter=%li", hValue, s_globalTable[ hValue ].counter));
}
static void hb_memvarRecycle( HB_HANDLE hValue )
{
if( s_globalFirstFree > hValue )
{
if( ( s_globalLastFree - hValue ) == 1 )
s_globalFirstFree = s_globalLastFree = hValue; /* last item */
else
{
s_globalFirstFree = hValue;
++s_globalFreeCnt; /* middle item */
}
}
else if( ( s_globalLastFree - hValue ) == 1 )
{
s_globalLastFree = hValue; /* last item */
if( s_globalLastFree == s_globalFirstFree )
s_globalFreeCnt = 0;
}
else
++s_globalFreeCnt;
}
/*
* This function decreases the number of references to passed global value.
* If it is the last reference then this value is deleted.
*
*/
void hb_memvarValueDecRef( HB_HANDLE hValue )
{
HB_VALUE_PTR pValue;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarValueDecRef(%lu)", hValue));
pValue = s_globalTable + hValue;
HB_TRACE(HB_TR_INFO, ("Memvar item (%i) decrement refCounter=%li", hValue, pValue->counter-1));
if( pValue->counter > 0 )
{
/* Notice that Counter can be equal to 0.
* This can happen if for example PUBLIC variable holds a codeblock
* with detached variable. When hb_memvarsRelease() is called then
* detached variable can be released before the codeblock. So if
* the codeblock will be released later then it will try to release
* again this detached variable.
*/
if( --pValue->counter == 0 )
{
hb_itemClear( &pValue->item );
hb_memvarRecycle( hValue );
HB_TRACE(HB_TR_INFO, ("Memvar item (%i) deleted", hValue));
}
}
}
/* This function is called from releasing of detached local variables
* referenced in a codeblock that is wiped out by the Garbage Collector.
* Decrement the reference counter and clear a value stored in the memvar.
* Don't clear arrays or codeblocks to avoid loops - these values will be
* released by the garbage collector.
*/
void hb_memvarValueDecGarbageRef( HB_HANDLE hValue )
{
HB_VALUE_PTR pValue;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarValueDecRef(%lu)", hValue));
pValue = s_globalTable + hValue;
HB_TRACE(HB_TR_INFO, ("Memvar item (%i) decrement refCounter=%li", hValue, pValue->counter-1));
if( pValue->counter > 0 )
{
/* Notice that Counter can be equal to 0.
* This can happen if for example PUBLIC variable holds a codeblock
* with detached variable. When hb_memvarsRelease() is called then
* detached variable can be released before the codeblock. So if
* the codeblock will be released later then it will try to release
* again this detached variable.
*/
if( --pValue->counter == 0 )
{
if( HB_IS_STRING( &pValue->item ) )
hb_itemClear( &pValue->item );
hb_memvarRecycle( hValue );
HB_TRACE(HB_TR_INFO, ("Memvar item (%i) deleted", hValue));
}
}
}
/*
* This functions copies passed item value into the memvar pointed
* by symbol
*
* pMemvar - symbol associated with a variable
* pItem - value to store in memvar
*
*/
void hb_memvarSetValue( PHB_SYMB pMemvarSymb, HB_ITEM_PTR pItem )
{
PHB_DYNS pDyn;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarSetValue(%p, %p)", pMemvarSymb, pItem));
pDyn = ( PHB_DYNS ) pMemvarSymb->pDynSym;
if( pDyn )
{
HB_TRACE(HB_TR_INFO, ("Memvar item (%i)(%s) assigned", pDyn->hMemvar, pMemvarSymb->szName));
if( pDyn->hMemvar )
{
/* value is already created */
HB_ITEM_PTR pSetItem = &s_globalTable[ pDyn->hMemvar ].item;
if( HB_IS_BYREF( pSetItem ) )
hb_itemCopy( hb_itemUnRef( pSetItem ), pItem );
else
hb_itemCopy( pSetItem, pItem );
}
else
{
/* assignment to undeclared memvar - PRIVATE is assumed
*/
hb_memvarCreateFromDynSymbol( pDyn, VS_PRIVATE, pItem );
}
s_globalTable[ pDyn->hMemvar ].item.type &= ~HB_IT_MEMOFLAG;
}
else
hb_errInternal( HB_EI_MVBADSYMBOL, NULL, pMemvarSymb->szName, NULL );
}
ERRCODE hb_memvarGet( HB_ITEM_PTR pItem, PHB_SYMB pMemvarSymb )
{
PHB_DYNS pDyn;
ERRCODE bSuccess = FAILURE;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarGet(%p, %p)", pItem, pMemvarSymb));
pDyn = ( PHB_DYNS ) pMemvarSymb->pDynSym;
if( pDyn )
{
HB_TRACE(HB_TR_INFO, ("Memvar item (%i)(%s) queried", pDyn->hMemvar, pMemvarSymb->szName));
if( pDyn->hMemvar )
{
/* value is already created
*/
HB_ITEM_PTR pGetItem = &s_globalTable[ pDyn->hMemvar ].item;
if( HB_IS_BYREF( pGetItem ) )
hb_itemCopy( pItem, hb_itemUnRef( pGetItem ) );
else
hb_itemCopy( pItem, pGetItem );
bSuccess = SUCCESS;
}
}
else
hb_errInternal( HB_EI_MVBADSYMBOL, NULL, pMemvarSymb->szName, NULL );
return bSuccess;
}
void hb_memvarGetValue( HB_ITEM_PTR pItem, PHB_SYMB pMemvarSymb )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarGetValue(%p, %p)", pItem, pMemvarSymb));
if( hb_memvarGet( pItem, pMemvarSymb ) == FAILURE )
{
/* Generate an error with retry possibility
* (user created error handler can create this variable)
*/
USHORT uiAction = E_RETRY;
HB_ITEM_PTR pError;
pError = hb_errRT_New( ES_ERROR, NULL, EG_NOVAR, 1003,
NULL, pMemvarSymb->szName, 0, EF_CANRETRY );
while( uiAction == E_RETRY )
{
uiAction = hb_errLaunch( pError );
if( uiAction == E_RETRY )
{
if( hb_memvarGet( pItem, pMemvarSymb ) == SUCCESS )
uiAction = E_DEFAULT;
}
}
hb_errRelease( pError );
}
}
void hb_memvarGetRefer( HB_ITEM_PTR pItem, PHB_SYMB pMemvarSymb )
{
PHB_DYNS pDyn;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarGetRefer(%p, %p)", pItem, pMemvarSymb));
pDyn = ( PHB_DYNS ) pMemvarSymb->pDynSym;
if( pDyn )
{
HB_TRACE(HB_TR_INFO, ("Memvar item (%i)(%s) referenced", pDyn->hMemvar, pMemvarSymb->szName));
if( pDyn->hMemvar )
{
/* value is already created */
pItem->type = HB_IT_BYREF | HB_IT_MEMVAR;
pItem->item.asMemvar.offset = 0;
pItem->item.asMemvar.value = pDyn->hMemvar;
pItem->item.asMemvar.itemsbase = &s_globalTable;
++s_globalTable[ pDyn->hMemvar ].counter;
}
else
{
/* Generate an error with retry possibility
* (user created error handler can make this variable accessible)
*/
USHORT uiAction = E_RETRY;
HB_ITEM_PTR pError;
pError = hb_errRT_New( ES_ERROR, NULL, EG_NOVAR, 1003,
NULL, pMemvarSymb->szName, 0, EF_CANRETRY );
while( uiAction == E_RETRY )
{
uiAction = hb_errLaunch( pError );
if( uiAction == E_RETRY )
{
if( pDyn->hMemvar )
{
/* value is already created */
pItem->type = HB_IT_BYREF | HB_IT_MEMVAR;
pItem->item.asMemvar.offset = 0;
pItem->item.asMemvar.value = pDyn->hMemvar;
pItem->item.asMemvar.itemsbase = &s_globalTable;
++s_globalTable[ pDyn->hMemvar ].counter;
uiAction = E_DEFAULT;
}
}
}
hb_errRelease( pError );
}
}
else
hb_errInternal( HB_EI_MVBADSYMBOL, NULL, pMemvarSymb->szName, NULL );
}
/*
*/
void hb_memvarNewParameter( PHB_SYMB pSymbol, PHB_ITEM pValue )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarNewParameter(%p, %p)", pSymbol, pValue));
hb_memvarCreateFromDynSymbol( pSymbol->pDynSym, HB_MV_PRIVATE, pValue );
}
char * hb_memvarGetStrValuePtr( char * szVarName, ULONG *pulLen )
{
HB_ITEM itName;
HB_DYNS_PTR pDynVar;
char * szValue = NULL;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarGetStrValuePtr(%s, %li)", szVarName, pulLen));
itName.type = HB_IT_STRING;
itName.item.asString.value = szVarName;
itName.item.asString.length = *pulLen;
pDynVar = hb_memvarFindSymbol( &itName );
if( pDynVar )
{
/* there is dynamic symbol with the requested name - check if it is
* a memvar variable
*/
if( pDynVar->hMemvar )
{
/* variable contains some data
*/
HB_ITEM_PTR pItem = &s_globalTable[ pDynVar->hMemvar ].item;
if( HB_IS_BYREF( pItem ) )
pItem = hb_itemUnRef( pItem ); /* it is a PARAMETER variable */
if( HB_IS_STRING( pItem ) )
{
szValue = pItem->item.asString.value;
*pulLen = pItem->item.asString.length;
}
}
}
return szValue;
}
/*
* This function creates a value for memvar variable
*
* pMemvar - an item that stores the name of variable - it can be either
* the HB_IT_SYMBOL (if created by PUBLIC statement) or HB_IT_STRING
* (if created by direct call to __PUBLIC function)
* bScope - the scope of created variable - if a variable with the same name
* exists already then it's value is hidden by new variable with
* passed scope
* pValue - optional item used to initialize the value of created variable
* or NULL
*
*/
void hb_memvarCreateFromItem( PHB_ITEM pMemvar, BYTE bScope, PHB_ITEM pValue )
{
PHB_DYNS pDynVar = NULL;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarCreateFromItem(%p, %d, %p)", pMemvar, bScope, pValue));
/* find dynamic symbol or creeate one */
if( HB_IS_SYMBOL( pMemvar ) )
pDynVar = hb_dynsymGet( pMemvar->item.asSymbol.value->szName );
else if( HB_IS_STRING( pMemvar ) )
pDynVar = hb_dynsymGet( pMemvar->item.asString.value );
else
hb_errRT_BASE( EG_ARG, 3008, NULL, "&", 2, hb_paramError( 1 ), hb_paramError( 2 ) );
if( pDynVar )
hb_memvarCreateFromDynSymbol( pDynVar, bScope, pValue );
}
static void hb_memvarCreateFromDynSymbol( PHB_DYNS pDynVar, BYTE bScope, PHB_ITEM pValue )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarCreateFromDynSymbol(%p, %d, %p)", pDynVar, bScope, pValue));
if( bScope & VS_PUBLIC )
{
/* If the variable with the same name exists already
* then the current value have to be unchanged
*/
if( ! pDynVar->hMemvar )
{
pDynVar->hMemvar = hb_memvarValueNew( pValue, TRUE );
if( !pValue )
{
/* new PUBLIC variable - initialize it to .F.
*/
s_globalTable[ pDynVar->hMemvar ].item.type = HB_IT_LOGICAL;
/* NOTE: PUBLIC variables named CLIPPER and HARBOUR are initialized */
/* to .T., this is normal Clipper behaviour. [vszakats] */
if( strcmp( pDynVar->pSymbol->szName, "HARBOUR" ) == 0 ||
strcmp( pDynVar->pSymbol->szName, "CLIPPER" ) == 0 )
s_globalTable[ pDynVar->hMemvar ].item.item.asLogical.value = TRUE;
else
s_globalTable[ pDynVar->hMemvar ].item.item.asLogical.value = FALSE;
}
}
}
else
{
/* We need to store the handle to the value of variable that is
* visible at this moment so later we can restore this value when
* the new variable will be released
*/
HB_HANDLE hCurrentValue = pDynVar->hMemvar;
pDynVar->hMemvar = hb_memvarValueNew( pValue, TRUE );
s_globalTable[ pDynVar->hMemvar ].hPrevMemvar = hCurrentValue;
/* Add this variable to the PRIVATE variables stack
*/
hb_memvarAddPrivate( pDynVar );
}
}
/* This function releases all memory occupied by a memvar variable
* It also restores the value that was hidden if there is another
* PRIVATE variable with the same name.
*/
static void hb_memvarRelease( HB_ITEM_PTR pMemvar )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarRelease(%p)", pMemvar));
if( HB_IS_STRING( pMemvar ) )
{
ULONG ulBase = s_privateStackCnt;
/* Find the variable with a requested name that is currently visible
* Start from the top of the stack.
*/
while( ulBase > 0 )
{
PHB_DYNS pDynVar;
--ulBase;
pDynVar = s_privateStack[ ulBase ];
/* reset current value to NIL - the overriden variables will be
* visible after exit from current procedure
*/
if( pDynVar->hMemvar )
{
if( hb_stricmp( pDynVar->pSymbol->szName, pMemvar->item.asString.value ) == 0 )
{
hb_itemClear( &s_globalTable[ pDynVar->hMemvar ].item );
ulBase = 0;
}
}
}
}
else
hb_errRT_BASE( EG_ARG, 3008, NULL, "RELEASE", 1, hb_paramError( 1 ) );
}
/* This function releases all memory occupied by a memvar variable and
* assigns NIL value - it releases variables created in current
* procedure only.
* The scope of released variables are specified using passed name's mask
*/
static void hb_memvarReleaseWithMask( char *szMask, BOOL bInclude )
{
ULONG ulBase = s_privateStackCnt;
PHB_DYNS pDynVar;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarReleaseWithMask(%s, %d)", szMask, (int) bInclude));
while( ulBase > s_privateStackBase )
{
--ulBase;
pDynVar = s_privateStack[ ulBase ];
/* reset current value to NIL - the overriden variables will be
* visible after exit from current procedure
*/
if( pDynVar->hMemvar )
{
if( bInclude )
{
if( ( szMask[ 0 ] == '*') || hb_strMatchRegExp( pDynVar->pSymbol->szName, szMask ) )
hb_itemClear( &s_globalTable[ pDynVar->hMemvar ].item );
}
else if( ! hb_strMatchRegExp( pDynVar->pSymbol->szName, szMask ) )
hb_itemClear( &s_globalTable[ pDynVar->hMemvar ].item );
}
}
}
/* Checks if passed dynamic symbol is a variable and returns its scope
*/
static int hb_memvarScopeGet( PHB_DYNS pDynVar )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarScopeGet(%p)", pDynVar));
if( pDynVar->hMemvar == 0 )
return HB_MV_UNKNOWN;
else
{
ULONG ulBase = s_privateStackCnt; /* start from the top of the stack */
int iMemvar = HB_MV_PUBLIC;
while( ulBase )
{
--ulBase;
if( pDynVar == s_privateStack[ ulBase ] )
{
if( ulBase >= s_privateStackBase )
iMemvar = HB_MV_PRIVATE_LOCAL;
else
iMemvar = HB_MV_PRIVATE_GLOBAL;
ulBase = 0;
}
}
return iMemvar;
}
}
/* This function checks the scope of passed variable name
*/
int hb_memvarScope( char * szVarName, ULONG ulLength )
{
int iMemvar = HB_MV_ERROR;
char * szName;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarScope(%s, %lu)", szVarName, ulLength));
szName = ( char * ) hb_xalloc( ulLength );
if( szName )
{
PHB_DYNS pDynVar;
memcpy( szName, szVarName, ulLength );
pDynVar = hb_dynsymFind( hb_strUpper( szName, ulLength - 1 ) );
if( pDynVar )
iMemvar = hb_memvarScopeGet( pDynVar );
else
iMemvar = HB_MV_NOT_FOUND;
hb_xfree( szName );
}
return iMemvar;
}
/* Releases memory occupied by a variable
*/
static HB_DYNS_FUNC( hb_memvarClear )
{
HB_SYMBOL_UNUSED( Cargo );
if( pDynSymbol->hMemvar )
{
s_globalTable[ pDynSymbol->hMemvar ].counter = 1;
hb_memvarValueDecRef( pDynSymbol->hMemvar );
pDynSymbol->hMemvar = 0;
}
return TRUE;
}
/* Checks passed dynamic symbol if it is a PUBLIC variable and
* increments the counter eventually
*/
static HB_DYNS_FUNC( hb_memvarCountPublics )
{
if( hb_memvarScopeGet( pDynSymbol ) == HB_MV_PUBLIC )
( * ( ( int * )Cargo ) )++;
return TRUE;
}
/* Count the number of variables with given scope
*/
static int hb_memvarCount( int iScope )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarCount(%d)", iScope));
if( iScope == HB_MV_PUBLIC )
{
int iPublicCnt = 0;
hb_dynsymEval( hb_memvarCountPublics, ( void * ) &iPublicCnt );
return iPublicCnt;
}
else
return s_privateStackCnt; /* number of PRIVATE variables */
}
/* Checks passed dynamic symbol if it is a PUBLIC variable and returns
* a pointer to its dynamic symbol
*/
static HB_DYNS_FUNC( hb_memvarFindPublicByPos )
{
BOOL bCont = TRUE;
if( hb_memvarScopeGet( pDynSymbol ) == HB_MV_PUBLIC )
{
struct mv_PUBLIC_var_info *pStruPub = (struct mv_PUBLIC_var_info *) Cargo;
if( pStruPub->iPos-- == 0 )
{
pStruPub->bFound = TRUE;
pStruPub->pDynSym = pDynSymbol;
bCont =FALSE;
}
}
return bCont;
}
/* Returns the pointer to item that holds a value of variable (or NULL if
* not found). It fills also the pointer to the variable name
* Both pointers points to existing and used data - they shouldn't be
* deallocated.
*/
static HB_ITEM_PTR hb_memvarDebugVariable( int iScope, int iPos, char * *pszName )
{
HB_ITEM_PTR pValue = NULL;
*pszName = NULL;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarDebugVariable(%d, %d, %p)", iScope, iPos, pszName));
if( iPos > 0 )
{
--iPos;
if( iScope == HB_MV_PUBLIC )
{
struct mv_PUBLIC_var_info struPub;
struPub.iPos = iPos;
struPub.bFound = FALSE;
/* enumerate existing dynamic symbols and fill this structure
* with info for requested PUBLIC variable
*/
hb_dynsymEval( hb_memvarFindPublicByPos, ( void * ) &struPub );
if( struPub.bFound )
{
pValue =&s_globalTable[ struPub.pDynSym->hMemvar ].item;
*pszName =struPub.pDynSym->pSymbol->szName;
}
}
else
{
if( ( ULONG ) iPos < s_privateStackCnt )
{
HB_DYNS_PTR pDynSym = s_privateStack[ iPos ];
pValue =&s_globalTable[ pDynSym->hMemvar ].item;
*pszName = pDynSym->pSymbol->szName;
}
}
}
return pValue;
}
static HB_DYNS_PTR hb_memvarFindSymbol( HB_ITEM_PTR pName )
{
HB_DYNS_PTR pDynSym = NULL;
HB_TRACE(HB_TR_DEBUG, ("hb_memvarFindSymbol(%p)", pName));
if( pName )
{
ULONG ulLen = pName->item.asString.length;
if( ulLen )
{
char * szName = ( char * ) hb_xgrab( ulLen + 1 );
char * szArg = pName->item.asString.value;
szName[ ulLen ] = '\0';
do
{
--ulLen;
szName[ ulLen ] = toupper( szArg[ ulLen ] );
} while( ulLen );
pDynSym = hb_dynsymFind( szName );
hb_xfree( szName );
}
}
return pDynSym;
}
/* ************************************************************************** */
HB_FUNC( __MVPUBLIC )
{
int iCount = hb_pcount();
if( iCount )
{
int i;
for( i = 1; i <= iCount; i++ )
{
PHB_ITEM pMemvar = hb_param( i, HB_IT_ANY );
if( pMemvar )
{
if( HB_IS_ARRAY( pMemvar ) )
{
/* we are accepting an one-dimensional array of strings only
*/
ULONG j, ulLen = hb_arrayLen( pMemvar );
HB_ITEM VarItem;
hb_itemInit( &VarItem );
for( j = 1; j <= ulLen; j++ )
{
hb_arrayGet( pMemvar, j, &VarItem );
hb_memvarCreateFromItem( &VarItem, VS_PUBLIC, NULL );
hb_itemClear( &VarItem );
}
}
else
hb_memvarCreateFromItem( pMemvar, VS_PUBLIC, NULL );
}
}
}
}
HB_FUNC( __MVPRIVATE )
{
int iCount = hb_pcount();
if( iCount )
{
int i;
for( i = 1; i <= iCount; i++ )
{
PHB_ITEM pMemvar = hb_param( i, HB_IT_ANY );
if( pMemvar )
{
if( HB_IS_ARRAY( pMemvar ) )
{
/* we are accepting an one-dimensional array of strings only
*/
ULONG j, ulLen = hb_arrayLen( pMemvar );
HB_ITEM VarItem;
hb_itemInit( &VarItem );
for( j = 1; j <= ulLen; j++ )
{
hb_arrayGet( pMemvar, j, &VarItem );
hb_memvarCreateFromItem( &VarItem, VS_PRIVATE, NULL );
hb_itemClear( &VarItem );
}
}
else
hb_memvarCreateFromItem( pMemvar, VS_PRIVATE, NULL );
}
}
}
}
HB_FUNC( __MVXRELEASE )
{
int iCount = hb_pcount();
if( iCount )
{
int i;
for( i = 1; i <= iCount; i++ )
{
PHB_ITEM pMemvar = hb_param( i, HB_IT_ANY );
if( pMemvar )
{
if( HB_IS_ARRAY( pMemvar ) )
{
/* we are accepting an one-dimensional array of strings only
*/
ULONG j, ulLen = hb_arrayLen( pMemvar );
HB_ITEM VarItem;
hb_itemInit( &VarItem );
for( j = 1; j <= ulLen; j++ )
{
hb_arrayGet( pMemvar, j, &VarItem );
hb_memvarRelease( &VarItem );
hb_itemClear( &VarItem );
}
}
else
hb_memvarRelease( pMemvar );
}
}
}
}
HB_FUNC( __MVRELEASE )
{
int iCount = hb_pcount();
if( iCount )
{
PHB_ITEM pMask = hb_param( 1, HB_IT_STRING );
if( pMask )
{
BOOL bIncludeVar;
if( iCount > 1 )
bIncludeVar = hb_parl( 2 );
else
bIncludeVar = TRUE;
if( pMask->item.asString.value[ 0 ] == '*' )
bIncludeVar = TRUE; /* delete all memvar variables */
hb_memvarReleaseWithMask( pMask->item.asString.value, bIncludeVar );
}
}
}
HB_FUNC( __MVSCOPE )
{
int iMemvar = HB_MV_ERROR;
if( hb_pcount() )
{
PHB_ITEM pVarName = hb_param( 1, HB_IT_STRING );
if( pVarName )
iMemvar = hb_memvarScope( pVarName->item.asString.value, pVarName->item.asString.length + 1 );
}
hb_retni( iMemvar );
}
HB_FUNC( __MVCLEAR )
{
hb_dynsymEval( hb_memvarClear, NULL );
}
HB_FUNC( __MVDBGINFO )
{
int iCount = hb_pcount();
if( iCount == 1 ) /* request for a number of variables */
hb_retni( hb_memvarCount( hb_parni( 1 ) ) );
else if( iCount >= 2 ) /* request for a value of variable */
{
HB_ITEM_PTR pValue;
char * szName;
pValue = hb_memvarDebugVariable( hb_parni( 1 ), hb_parni( 2 ), &szName );
if( pValue )
{
/*the requested variable was found
*/
if( iCount >= 3 && ISBYREF( 3 ) )
{
/* we have to use this variable regardless of its current value
*/
HB_ITEM_PTR pName = hb_param( 3, HB_IT_ANY );
hb_itemPutC( pName, szName ); /* clear an old value and copy a new one */
/* szName points directly to a symbol name - it cannot be released
*/
}
hb_itemReturn( pValue );
/* pValue points directly to the item structure used by this variable
* this item cannot be released
*/
}
else
{
hb_ret(); /* return NIL value */
if( iCount >= 3 && ISBYREF( 3 ) )
{
/* we have to use this variable regardless of its current value
*/
HB_ITEM_PTR pName = hb_param( 3, HB_IT_ANY );
hb_itemPutC( pName, "?" ); /* clear an old value and copy a new one */
}
}
}
}
HB_FUNC( __MVEXIST )
{
HB_ITEM_PTR pName = hb_param( 1, HB_IT_STRING );
PHB_DYNS pDyn;
hb_retl( pName && ( pDyn = hb_memvarFindSymbol( pName ) ) != NULL && pDyn->hMemvar );
}
HB_FUNC( __MVGET )
{
HB_ITEM_PTR pName = hb_param( 1, HB_IT_STRING );
if( pName )
{
HB_DYNS_PTR pDynVar = hb_memvarFindSymbol( pName );
if( pDynVar )
{
HB_ITEM retValue;
hb_itemInit( &retValue );
hb_memvarGetValue( &retValue, pDynVar->pSymbol );
hb_itemClear( hb_itemReturn( &retValue ) );
}
else
{
/* Generate an error with retry possibility
* (user created error handler can create this variable)
*/
USHORT uiAction = E_RETRY;
HB_ITEM_PTR pError;
pError = hb_errRT_New( ES_ERROR, NULL, EG_NOVAR, 1003,
NULL, pName->item.asString.value, 0, EF_CANRETRY );
while( uiAction == E_RETRY )
{
uiAction = hb_errLaunch( pError );
if( uiAction == E_RETRY )
{
pDynVar = hb_memvarFindSymbol( pName );
if( pDynVar )
{
HB_ITEM retValue;
hb_itemInit( &retValue );
hb_memvarGetValue( &retValue, pDynVar->pSymbol );
hb_itemClear( hb_itemReturn( &retValue ) );
uiAction = E_DEFAULT;
}
}
}
hb_errRelease( pError );
}
}
else
{
/* either the first parameter is not specified or it has a wrong type
* (it must be a string)
* This is not a critical error - we can continue normal processing
*/
/* TODO: This should be expanded a little to report a passed incorrect
* value to the error handler
*/
hb_errRT_BASE_SubstR( EG_ARG, 3009, NULL, NULL, 1, hb_paramError( 1 ) );
}
}
HB_FUNC( __MVPUT )
{
HB_ITEM_PTR pName = hb_param( 1, HB_IT_STRING );
HB_ITEM nil;
HB_ITEM_PTR pValue = &nil;
nil.type = HB_IT_NIL;
if( hb_pcount() >= 2 )
pValue = hb_param( 2, HB_IT_ANY );
if( pName )
{
/* the first parameter is a string with not empty variable name
*/
HB_DYNS_PTR pDynVar = hb_memvarFindSymbol( pName );
if( pDynVar )
{
/* variable was declared somwhere - assign a new value
*/
hb_memvarSetValue( pDynVar->pSymbol, pValue );
}
else
{
/* attempt to assign a value to undeclared variable
* create the PRIVATE one
*/
hb_memvarCreateFromDynSymbol( hb_dynsymGet( pName->item.asString.value ), VS_PRIVATE, pValue );
}
hb_itemReturn( pValue );
}
else
{
/* either the first parameter is not specified or it has a wrong type
* (it must be a string)
* This is not a critical error - we can continue normal processing
*/
/* TODO: This should be expanded a little to report a passed incorrect
* value to the error handler
*/
HB_ITEM_PTR pRetValue = hb_errRT_BASE_Subst( EG_ARG, 3010, NULL, NULL, 1, hb_paramError( 1 ) );
if( pRetValue )
hb_itemRelease( pRetValue );
hb_itemReturn( pValue );
}
}
#define HB_MEM_REC_LEN 32
#define HB_MEM_NUM_LEN 8
HB_FUNC( __MVSAVE )
{
/* Clipper also checks for the number of arguments here */
if( hb_pcount() == 3 && ISCHAR( 1 ) && ISCHAR( 2 ) && ISLOG( 3 ) )
{
PHB_FNAME pFileName;
char szFileName[ _POSIX_PATH_MAX + 1 ];
FHANDLE fhnd;
/* Generate filename */
pFileName = hb_fsFNameSplit( hb_parc( 1 ) );
if( pFileName->szExtension == NULL )
pFileName->szExtension = ".mem";
hb_fsFNameMerge( szFileName, pFileName );
hb_xfree( pFileName );
/* Create .MEM file */
while( ( fhnd = hb_fsCreate( ( BYTE * ) szFileName, FC_NORMAL ) ) == FS_ERROR )
{
USHORT uiAction = hb_errRT_BASE_Ext1( EG_CREATE, 2006, NULL, szFileName, hb_fsError(), EF_CANDEFAULT | EF_CANRETRY, 3, hb_paramError( 1 ), hb_paramError( 2 ), hb_paramError( 3 ) );
if( uiAction == E_DEFAULT || uiAction == E_BREAK )
break;
}
if( fhnd != FS_ERROR )
{
char * pszMask = hb_parc( 2 );
BOOL bIncludeMask = hb_parl( 3 );
BYTE buffer[ HB_MEM_REC_LEN ];
/* Walk through all visible memory variables */
ULONG ulBase = s_privateStackCnt;
while( ulBase > s_privateStackBase )
{
PHB_DYNS pDynVar;
--ulBase;
pDynVar = s_privateStack[ ulBase ];
/* NOTE: Harbour name lengths are not limited, but the .MEM file
structure is not flexible enough to allow for it.
[vszakats] */
if( pDynVar->hMemvar )
{
BOOL bMatch = ( pszMask[ 0 ] == '*' || hb_strMatchRegExp( pDynVar->pSymbol->szName, pszMask ) );
/* Process it if it matches the passed mask */
if( bIncludeMask ? bMatch : ! bMatch )
{
PHB_ITEM pItem = &s_globalTable[ pDynVar->hMemvar ].item;
/* NOTE: Clipper will not initialize the record buffer with
zeros, so they will look trashed. [vszakats] */
memset( buffer, 0, HB_MEM_REC_LEN );
/* NOTE: Save only the first 10 characters of the name */
strncpy( ( char * ) buffer, pDynVar->pSymbol->szName, 10 );
buffer[ 10 ] = '\0';
if( HB_IS_STRING( pItem ) && ( hb_itemGetCLen( pItem ) + 1 ) <= SHRT_MAX )
{
/* Store the closing zero byte, too */
USHORT uiLength = ( USHORT ) ( hb_itemGetCLen( pItem ) + 1 );
buffer[ 11 ] = 'C' + 128;
buffer[ 16 ] = HB_LOBYTE( uiLength );
buffer[ 17 ] = HB_HIBYTE( uiLength );
hb_fsWrite( fhnd, buffer, HB_MEM_REC_LEN );
hb_fsWrite( fhnd, ( BYTE * ) hb_itemGetCPtr( pItem ), uiLength );
}
else if( HB_IS_NUMERIC( pItem ) )
{
double dNumber = hb_itemGetND( pItem );
int iWidth;
int iDec;
hb_itemGetNLen( pItem, &iWidth, &iDec );
buffer[ 11 ] = 'N' + 128;
#ifdef HB_C52_STRICT
/* NOTE: This is the buggy, but fully CA-Cl*pper compatible method. [vszakats] */
buffer[ 16 ] = ( BYTE ) iWidth + ( HB_IS_DOUBLE( pItem ) ? iDec + 1 : 0 );
#else
/* NOTE: This would be the correct method, but Clipper is buggy here. [vszakats] */
buffer[ 16 ] = ( BYTE ) iWidth + ( iDec == 0 ? 0 : iDec + 1 );
#endif
buffer[ 17 ] = ( BYTE ) iDec;
hb_fsWrite( fhnd, buffer, HB_MEM_REC_LEN );
hb_fsWrite( fhnd, ( BYTE * ) &dNumber, sizeof( dNumber ) );
}
else if( HB_IS_DATE( pItem ) )
{
double dNumber = ( double ) hb_itemGetDL( pItem );
buffer[ 11 ] = 'D' + 128;
buffer[ 16 ] = 1;
buffer[ 17 ] = 0;
hb_fsWrite( fhnd, buffer, HB_MEM_REC_LEN );
hb_fsWrite( fhnd, ( BYTE * ) &dNumber, sizeof( dNumber ) );
}
else if( HB_IS_LOGICAL( pItem ) )
{
BYTE byLogical[ 1 ];
buffer[ 11 ] = 'L' + 128;
buffer[ 16 ] = sizeof( BYTE );
buffer[ 17 ] = 0;
byLogical[ 0 ] = hb_itemGetL( pItem ) ? 1 : 0;
hb_fsWrite( fhnd, buffer, HB_MEM_REC_LEN );
hb_fsWrite( fhnd, byLogical, sizeof( BYTE ) );
}
}
}
}
buffer[ 0 ] = '\x1A';
hb_fsWrite( fhnd, buffer, 1 );
hb_fsClose( fhnd );
}
}
else
hb_errRT_BASE( EG_ARG, 2008, NULL, "__MSAVE", 3, hb_paramError( 1 ), hb_paramError( 2 ), hb_paramError( 3 ) );
}
/* NOTE: There's an extension in Harbour, which makes it possible to only
load (or not load) variable names with a specific name mask.
[vszakats] */
HB_FUNC( __MVRESTORE )
{
/* Clipper checks for the number of arguments here here, but we cannot
in Harbour since we have two optional parameters as an extension. */
if( ISCHAR( 1 ) && ISLOG( 2 ) )
{
PHB_FNAME pFileName;
char szFileName[ _POSIX_PATH_MAX + 1 ];
FHANDLE fhnd;
BOOL bAdditive = hb_parl( 2 );
/* Clear all memory variables if not ADDITIVE */
if( ! bAdditive )
hb_dynsymEval( hb_memvarClear, NULL );
/* Generate filename */
pFileName = hb_fsFNameSplit( hb_parc( 1 ) );
if( pFileName->szExtension == NULL )
pFileName->szExtension = ".mem";
hb_fsFNameMerge( szFileName, pFileName );
hb_xfree( pFileName );
/* Open .MEM file */
while( ( fhnd = hb_fsOpen( ( BYTE * ) szFileName, FO_READ | FO_DENYWRITE | FO_PRIVATE ) ) == FS_ERROR )
{
USHORT uiAction = hb_errRT_BASE_Ext1( EG_OPEN, 2005, NULL, szFileName, hb_fsError(), EF_CANDEFAULT | EF_CANRETRY, 2, hb_paramError( 1 ), hb_paramError( 2 ) );
if( uiAction == E_DEFAULT || uiAction == E_BREAK )
break;
}
if( fhnd != FS_ERROR )
{
char * pszMask = ISCHAR( 3 ) ? hb_parc( 3 ) : "*";
BOOL bIncludeMask = ISCHAR( 4 ) ? hb_parl( 4 ) : TRUE;
BYTE buffer[ HB_MEM_REC_LEN ];
while( hb_fsRead( fhnd, buffer, HB_MEM_REC_LEN ) == HB_MEM_REC_LEN )
{
PHB_ITEM pName = hb_itemPutC( NULL, ( char * ) buffer );
USHORT uiType = ( USHORT ) ( buffer[ 11 ] - 128 );
USHORT uiWidth = ( USHORT ) buffer[ 16 ];
USHORT uiDec = ( USHORT ) buffer[ 17 ];
PHB_ITEM pItem = NULL;
switch( uiType )
{
case 'C':
{
BYTE * pbyString;
uiWidth += uiDec * 256;
pbyString = ( BYTE * ) hb_xgrab( uiWidth );
if( hb_fsRead( fhnd, pbyString, uiWidth ) == uiWidth )
pItem = hb_itemPutCL( NULL, ( char * ) pbyString, uiWidth - 1 );
hb_xfree( pbyString );
break;
}
case 'N':
{
BYTE pbyNumber[ HB_MEM_NUM_LEN ];
if( hb_fsRead( fhnd, pbyNumber, HB_MEM_NUM_LEN ) == HB_MEM_NUM_LEN )
pItem = hb_itemPutNLen( NULL, * ( double * ) &pbyNumber, uiWidth - ( uiDec ? ( uiDec + 1 ) : 0 ), uiDec );
break;
}
case 'D':
{
BYTE pbyNumber[ HB_MEM_NUM_LEN ];
if( hb_fsRead( fhnd, pbyNumber, HB_MEM_NUM_LEN ) == HB_MEM_NUM_LEN )
pItem = hb_itemPutDL( NULL, ( long ) ( * ( double * ) &pbyNumber ) );
break;
}
case 'L':
{
BYTE pbyLogical[ 1 ];
if( hb_fsRead( fhnd, pbyLogical, 1 ) == 1 )
pItem = hb_itemPutL( NULL, pbyLogical[ 0 ] != 0 );
break;
}
}
if( pItem )
{
BOOL bMatch = ( pszMask[ 0 ] == '*' || hb_strMatchRegExp( hb_itemGetCPtr( pName ), pszMask ) );
/* Process it if it matches the passed mask */
if( bIncludeMask ? bMatch : ! bMatch )
{
/* the first parameter is a string with not empty variable name */
HB_DYNS_PTR pDynVar = hb_memvarFindSymbol( pName );
if( pDynVar )
/* variable was declared somwhere - assign a new value */
hb_memvarSetValue( pDynVar->pSymbol, pItem );
else
/* attempt to assign a value to undeclared variable create the PRIVATE one */
hb_memvarCreateFromDynSymbol( hb_dynsymGet( pName->item.asString.value ), VS_PRIVATE, pItem );
hb_itemReturn( pItem );
}
hb_itemRelease( pItem );
}
hb_itemRelease( pName );
}
hb_fsClose( fhnd );
}
else
hb_retl( FALSE );
}
else
hb_errRT_BASE( EG_ARG, 2007, NULL, "__MRESTORE", 2, hb_paramError( 1 ), hb_paramError( 2 ) );
}
/* ----------------------------------------------------------------------- */
/* The garbage collector interface */
/* ----------------------------------------------------------------------- */
/* Mark all memvars as used so they will not be released by the
* garbage collector
*/
void hb_memvarsIsMemvarRef( void )
{
HB_TRACE(HB_TR_DEBUG, ("hb_memvarsIsMemvarRef()"));
if( s_globalTable )
{
ULONG ulCnt = s_globalLastFree;
while( --ulCnt )
{
/* do not check detached variables - for these variables only
* references from the eval stack are meaningfull for the GC
*/
if( s_globalTable[ ulCnt ].counter && s_globalTable[ ulCnt ].hPrevMemvar != ( HB_HANDLE )-1 )
{
hb_gcItemRef( &s_globalTable[ ulCnt ].item );
}
}
}
}
HB_HANDLE hb_memvarGetVarHandle( char *szName )
{
PHB_DYNS pDyn;
if( ( pDyn = hb_dynsymFind( szName ) ) != NULL )
return pDyn->hMemvar;
else
return 0; /* invalid handle */
}
PHB_ITEM hb_memvarGetValueByHandle( HB_HANDLE hMemvar )
{
if( hMemvar && hMemvar < s_globalTableSize )
return &s_globalTable[ hMemvar ].item;
else
return NULL;
}
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