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c8bcbc198bb15ea0a5050b75f0ea2df70dca702c
harbour-core/harbour/source/vm/macro.c
Przemyslaw Czerpak 88cda3200d 2007-03-22 12:55 UTC+0100 Przemyslaw Czerpak (druzus/at/priv.onet.pl) 
* harbour/common.mak
    * updated for new files - please check

  * harbour/harbour.spec
    * added compiler library

  * harbour/bin/pack_src.sh
  * harbour/bin/hb-func.sh
    * updated for new files and libraries

  * harbour/config/w32/mingw32.cf
  * harbour/config/w32/watcom.cf
  * harbour/config/w32/xcc.cf
    * added winsock libraries

  * harbour/include/hbapicdp.h
  * harbour/source/rtl/cdpapi.c
    + added hb_cdpicmp() - not case sensitive version of hb_cdpcmp()

  * harbour/include/hbapiitm.h
  * harbour/source/vm/itemapi.c
    + hb_itemStrICmp(), hb_itemCopyFromRef(), hb_itemMoveFromRef()

  * harbour/include/hbapi.h
  * harbour/include/hbcomp.h
  * harbour/include/hbcompdf.h
  * harbour/include/hbexpra.c
  * harbour/include/hbexprb.c
  * harbour/include/hbexprop.h
  * harbour/include/hbmacro.h
  * harbour/include/hbpcode.h
  * harbour/include/hbvmpub.h
  * harbour/include/hbxvm.h
  * harbour/source/common/expropt1.c
  * harbour/source/compiler/complex.c
  * harbour/source/compiler/genc.c
  * harbour/source/compiler/gencc.c
  * harbour/source/compiler/gencli.c
  * harbour/source/compiler/genhrb.c
  * harbour/source/compiler/genobj32.c
  * harbour/source/compiler/harbour.y
  * harbour/source/compiler/harbour.yyc
  * harbour/source/compiler/harbour.yyh
  * harbour/source/compiler/hbdead.c
  * harbour/source/compiler/hbfix.c
  * harbour/source/compiler/hblbl.c
  * harbour/source/compiler/hbmain.c
  * harbour/source/compiler/hbopt.c
  * harbour/source/compiler/hbpcode.c
  * harbour/source/compiler/hbstripl.c
  * harbour/source/macro/macro.y
  * harbour/source/macro/macro.yyc
  * harbour/source/macro/macro.yyh
  * harbour/source/macro/macrolex.c
  * harbour/source/vm/Makefile
  * harbour/source/vm/arrays.c
  * harbour/source/vm/asort.c
  * harbour/source/vm/classes.c
  * harbour/source/vm/eval.c
  * harbour/source/vm/garbage.c
  * harbour/source/vm/hvm.c
  * harbour/source/vm/itemapi.c
  * harbour/source/vm/macro.c
  + harbour/source/vm/hashes.c
  + harbour/source/vm/hashfunc.c
    + added hash items, f.e.:
         local h1 := {=>}, h2 := { "a"=>1.234, "b"=>2.345 }
         ? h2[ "a" ], h2[ "b ]
    + added support for DYNAMIC function declaration - it allow to define
      functions which are lately bound at runtime, f.e.:
         /*** t01.prg ***/
         dynamic func1
         proc main()
         local h:=__hrbload("t02.hrb")
         ? func1()
         return

         /*** t02.prg ***/
         func func1
         return "Hello!!!"

    % use new FUNCALL structure to hold EXTERNAL and DYNAMIC functions,
      it reduce memory usage, FUNCALL is much smaller then FUNCTION
    % use symbol scope bits when possible instead of making some linear scan
    + added new enumarator message: __ENUMKEY - it allow to access
      key value when hash item is base enumerator value, f.e.:
         proc main()
         local v, h:={"a"=>1.000,"b"=>2.000,"c"=>3.000}
         heval( h, { |k,v,i| qout( k, v, i ) } ); ?
         for each v in h
            ? v, "=>", v:__enumKey(), v:__enumValue(), v:__enumIndex(), ;
                       valtype(v:__enumBase())
            v += 0.123
         next
         ? ;heval( h, { |k,v,i| qout( k, v, i ) } )
         return
    + added C level hb_hash*() functions
    + added support for full HASH item cloning and updated array cloning
      to also clone nested hashes - please note that xHarbour does not do
      that, in xHarbour ACLONE() clones _ONLY_ nested arrays and HCLONE()
      _DOES_NOT_ clone _ANY_ nested items.

  * harbour/include/hbextern.ch
    + added hash functions HB_H*()
    * changed INET*() functions to HB_INET*()
    + added hash functions H*() and socket functions INET*() when
      HB_COMPAT_XHB is set

  * harbour/include/hbtypes.h
    + added missing HB_EXTERN_BEGIN / HB_EXTERN_END

  * harbour/include/hbpp.h
  * harbour/source/pp/ppcore.c
    ! added protection against automatic word concatenation in some cases
    ! fixed preprocessing expressions when match marker matches ';' token

  * harbour/source/rtl/Makefile
  + harbour/source/rtl/itemseri.c
    + added functions for item serialization: HB_SERIALIZE() and
      HB_DESERIALIZE() - these function are not binary compatible
      with xHarbour functions with the same names but make very
      similar job with the exception to serialization of codeblock
      and object variables - Harbour does not allow to serialize
      codeblocks and serialize objects as arrays.
      In most cases these functions can replace the xHarbour ones
    + added HB_DESERIALBEGIN() and HB_DESERIALIZE() functions covered
      by HB_COMPAT_XHB macro - this functions are only for compatibility
      with existing xHarbour code, In Harbour HB_DESERIALBEGIN() is
      dummy function which returns first parameter and HB_DESERIALNEXT()
      is a simple wrapper to HB_DESERIALIZE() so it's not necessary to
      use them.

  * harbour/source/rtl/hbinet.c
    * changed INET*() functions to HB_INET*() and enable them for default
      build
    + added INET*() functions wrappers covered by HB_COMPAT_XHB macro

  * harbour/source/rtl/hbrandom.c
    + added HB_RANDOMINT() - xHarbour compatible

  * harbour/source/rtl/len.c
    + added support for HASHes

  * harbour/source/rtl/valtype.c
    + added support for HASHes
    + added set of HB_IS*() functions - they are a little bit faster then
      calling VALTYPE( v ) == <cVal>
    - removed HB_ISBYREF() - this function cannot longer work, it was using
      a Clipper incompatible anomalies in passing variables by reference I
      fixed so it has to stop to work. If it will be realy necessary to
      implement HB_ISBYREF() function then please inform me - it will have
      to be done at compiler level or with some much deeper HVM stack
      checking.

  * harbour/source/vm/extend.c
    ! fixed hb_extIsArray() and hb_extIsObject() to work well with
      parameters passed by reference.
      Please note that now hb_extIsArray() return TRUE only for pure arrays
      not object values.

  * harbour/contrib/Makefile
  + harbour/contrib/tip/Changelog
  + harbour/contrib/tip/Makefile
  + harbour/contrib/tip/atokens.c
  + harbour/contrib/tip/base64x.c
  + harbour/contrib/tip/cgi.prg
  + harbour/contrib/tip/client.prg
  + harbour/contrib/tip/credent.prg
  + harbour/contrib/tip/cstr.prg
  + harbour/contrib/tip/encb64.prg
  + harbour/contrib/tip/encmthd.c
  + harbour/contrib/tip/encoder.prg
  + harbour/contrib/tip/encqp.prg
  + harbour/contrib/tip/encurl.prg
  + harbour/contrib/tip/ftpcln.prg
  + harbour/contrib/tip/hbhex2n.c
  + harbour/contrib/tip/httpcln.prg
  + harbour/contrib/tip/mail.prg
  + harbour/contrib/tip/popcln.prg
  + harbour/contrib/tip/smtpcln.prg
  + harbour/contrib/tip/tip.ch
  + harbour/contrib/tip/url.prg
  + harbour/contrib/tip/utils.c
    + added TIP library - code borrowed from xHarbour



   Please test - a lot of above code is not well tested, also some peaces
   were written over year ago for different things (f.e. serialization for
   NETRDD) and now I collected them and committed.
   The TIP library was not tested at all. It can be compiled but I cannot
   say if it works - I hope that people familiar with it can make necessary
   test and fixes.
   It's also not the final version of low level HASH item code. I'm working
   on more efficient structure which uses binary tries but I cannot say when
   I'll finish it (maybe in this weekend or maybe in next year) so I committed
   working version now even if I'm not happy with overall performance (BTW
   not worser then in xHarbour)
2007-03-22 12:28:14 +00:00

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/*
* $Id$
*/
/*
* Harbour Project source code:
* Macro compiler main file
*
* 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.
*
*/
/* this #define HAVE TO be placed before all #include directives
*/
#define HB_MACRO_SUPPORT
#include "hbvmopt.h"
#include "hbmacro.h"
#include "hbcomp.h"
#include "hbstack.h"
#ifdef HB_MACRO_STATEMENTS
#include "hbpp.h"
#endif
/* various flags for macro compiler */
#ifdef HB_C52_STRICT
static ULONG s_macroFlags = HB_SM_SHORTCUTS;
#else
static ULONG s_macroFlags = HB_SM_SHORTCUTS | HB_SM_HARBOUR;
#endif
/* ************************************************************************* */
/* Compile passed string into a pcode buffer
*
* 'pMacro' - pointer to HB_MACRO structure that will hold all information
* nedded for macro compilation and evaluation
* 'szString' - a string to compile
* 'iFlag' - specifies if compiled code should generate pcodes either for push
* operation (for example: var :=&macro) or for pop operation (&macro :=var)
*/
static int hb_macroParse( HB_MACRO_PTR pMacro )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroParse(%p)", pMacro));
/* initialize the output (pcode) buffer - it will be filled by yacc */
pMacro->pCodeInfo = (HB_PCODE_INFO_PTR ) hb_xgrab( sizeof( HB_PCODE_INFO ) );
pMacro->pCodeInfo->lPCodeSize = HB_PCODE_SIZE;
pMacro->pCodeInfo->lPCodePos = 0;
pMacro->pCodeInfo->fVParams = FALSE;
pMacro->pCodeInfo->pLocals = NULL;
pMacro->pCodeInfo->pPrev = NULL;
pMacro->pCodeInfo->pCode = ( BYTE * ) hb_xgrab( HB_PCODE_SIZE );
/* reset the type of compiled expression - this should be filled after
* successfully compilation
*/
pMacro->pError = NULL;
pMacro->uiListElements = 0;
pMacro->exprType = HB_ET_NONE;
return hb_macroYYParse( pMacro );
}
/* releases all memory allocated for macro evaluation
* NOTE:
* Only members of HB_MACRO structure are deallocated
* the 'pMacro' pointer is not released - it can be a pointer
* to a memory allocated on the stack.
*/
void hb_macroDelete( HB_MACRO_PTR pMacro )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroDelete(%p)", pMacro));
hb_xfree( (void *) pMacro->pCodeInfo->pCode );
hb_xfree( (void *) pMacro->pCodeInfo );
if( pMacro->pError )
hb_errRelease( pMacro->pError );
if( pMacro->Flags & HB_MACRO_DEALLOCATE )
hb_xfree( pMacro );
}
/* checks if a correct ITEM was passed from the virtual machine eval stack
*/
static BOOL hb_macroCheckParam( HB_ITEM_PTR pItem )
{
BOOL bValid = TRUE;
HB_TRACE(HB_TR_DEBUG, ("hb_macroCheckParam(%p)", pItem));
if( ! HB_IS_STRING(pItem) )
{
HB_ITEM_PTR pResult = hb_errRT_BASE_Subst( EG_ARG, 1065, NULL, "&", 0 );
bValid = FALSE;
if( pResult )
{
hb_stackPop();
hb_vmPush( pResult );
hb_itemRelease( pResult );
bValid = TRUE;
}
}
return bValid;
}
/* It handles an error generated during checking of expression type
*/
static HB_ERROR_HANDLE( hb_macroErrorType )
{
HB_MACRO_PTR pMacro = ( HB_MACRO_PTR ) ErrorInfo->Cargo;
/* copy error object for later diagnostic usage */
if( pMacro->pError )
hb_itemRelease( pMacro->pError );
pMacro->pError = hb_itemNew( ErrorInfo->Error );
pMacro->status &= ~HB_MACRO_CONT;
/* ignore rest of compiled code */
hb_vmRequestEndProc();
return NULL; /* ignore this error */
}
/* Executes pcode compiled by macro compiler
*
* pMacro is a pointer to HB_MACRO structure created by macro compiler
*
*/
void hb_macroRun( HB_MACRO_PTR pMacro )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroRun(%p)", pMacro));
hb_vmExecute( pMacro->pCodeInfo->pCode, NULL );
}
static void hb_macroSyntaxError( HB_MACRO_PTR pMacro )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroSyntaxError(%p)", pMacro));
if( pMacro && pMacro->pError )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroSyntaxError.(%s)", pMacro->string));
hb_errLaunch( pMacro->pError );
hb_errRelease( pMacro->pError );
pMacro->pError = NULL;
}
else
{
PHB_ITEM pResult = hb_errRT_BASE_Subst( EG_SYNTAX, 1449, NULL, "&", 0 );
if( pResult )
{
hb_vmPush( pResult );
hb_itemRelease( pResult );
}
}
}
/* Check if passed string is a valid function or variable name
*/
BOOL hb_macroIsIdent( char * szString )
{
char * pTmp = szString;
BOOL bIsIdent = FALSE;
/* NOTE: This uses _a-zA-Z0-9 pattern to check for a valid name
*/
if( *pTmp )
{
if( ! ( pTmp[ 0 ] == '_' && pTmp[ 1 ] == 0 ) )
{
/* this is not a "_" string
*/
if( *pTmp == '_' || (*pTmp >= 'A' && *pTmp <= 'Z') || (*pTmp >= 'a' && *pTmp <= 'z') )
{
++pTmp;
while( *pTmp && (*pTmp == '_' || (*pTmp >= 'A' && *pTmp <= 'Z') || (*pTmp >= 'a' && *pTmp <= 'z') || (*pTmp >= '0' && *pTmp <= '9')) )
++pTmp;
/* the name is valid if pTmp is at the end of a string
*/
bIsIdent = (*pTmp ? FALSE : TRUE );
}
}
}
return bIsIdent;
}
/* This replaces all '&var' or '&var.' occurences within a given string
* with the value of variable 'var' if this variable exists and contains
* a string value. The value of variable is also searched for
* occurences of macro operator and if it is found then it is expanded
* until there is no more macro operators.
* NOTE:
* this does not evaluate a macro expression - there is a simple text
* substitution only
* NOTE:
* hb_macroTextSubst returns either a pointer that points to the passed
* string if there was no macro operator in it or a pointer to a new
* allocated memory with expanded string if there was a macro operator
* in passed string.
* NOTE:
* Clipper restarts scanning of the text from the beginning of
* inserted text after macro expansion, for example:
* PRIVATE a:='&', b:='c'
* PRIVATE &a.b // this will create 'c' variable
*
* PRIVATE a:=0, b:='b', ab:='c'
* PRIVATE &a&b //this will cause syntax error '&'
*
*/
char * hb_macroTextSubst( char * szString, ULONG *pulStringLen )
{
char * szResult;
ULONG ulResStrLen;
ULONG ulResBufLen;
ULONG ulCharsLeft;
char * pHead;
char * pTail;
HB_TRACE(HB_TR_DEBUG, ("hb_macroTextSubst(%s, %li)", szString, *pulStringLen));
pHead = (char *)memchr( (void *)szString, '&', *pulStringLen );
if( pHead == NULL )
return szString; /* no more processing is required */
/* initial length of the string and the result buffer (it can contain null bytes) */
ulResBufLen = ulResStrLen = *pulStringLen;
/* initial buffer for return value */
szResult = (char *) hb_xgrab( ulResBufLen + 1 );
/* copy the input string with trailing zero byte
*/
memcpy( szResult, szString, ulResStrLen + 1 );
/* switch the pointer so it will point into the result buffer
*/
pHead = szResult + ( pHead - szString );
do
{
/* store the position where '&' was found so we can restart scanning
* from this point after macro expansion
*/
pTail = pHead;
/* check if the next character can start a valid identifier
* (only _a-zA-Z are allowed)
*/
++pHead; /* skip '&' character */
if( *pHead == '_' || (*pHead >= 'A' && *pHead <= 'Z') || (*pHead >= 'a' && *pHead <= 'z') )
{
/* extract a variable name */
/* NOTE: the extracted name can be longer then supported maximal
* length of identifiers (HB_SYMBOL_NAME_LEN) - only the max allowed
* are used for name lookup however the whole string is replaced
*/
ULONG ulNameLen = 0;
char * pName = pHead;
while( *pHead && (*pHead == '_' || (*pHead >= 'A' && *pHead <= 'Z') || (*pHead >= 'a' && *pHead <= 'z') || (*pHead >= '0' && *pHead <= '9')) )
{
++pHead;
++ulNameLen;
}
/* pHead points now at the character that terminated a variable name */
/* NOTE: '_' is invalid variable name
*/
if( ! ( *pName == '_' && ulNameLen == 1 ) )
{
/* this is not the "&_" string */
char * szValPtr;
ULONG ulValLen;
/* Get a pointer to the string value stored in this variable
* or NULL if variable doesn't exist or doesn't contain a string
* value.
* NOTE: This doesn't create a copy of the value then it
* shouldn't be released here.
*/
ulValLen = ulNameLen; /* the length of name */
szValPtr = hb_memvarGetStrValuePtr( pName, &ulValLen );
if( szValPtr )
{
if( *pHead == '.' )
{
/* we have stopped at the macro terminator '.' - skip it */
++pHead;
++ulNameLen;
}
++ulNameLen; /* count also the '&' character */
/* number of characters left on the right side of a variable name */
ulCharsLeft = ulResStrLen - ( pHead - szResult );
/* NOTE:
* if a replacement string is shorter then the variable
* name then we don't have to reallocate the result buffer:
* 'ulResStrLen' stores the current length of a string in the buffer
* 'ulResBufLen' stores the length of the buffer
*/
if( ulValLen > ulNameLen )
{
ulResStrLen += ( ulValLen - ulNameLen );
if( ulResStrLen > ulResBufLen )
{
ULONG ulHead = pHead - szResult;
ULONG ulTail = pTail - szResult;
ulResBufLen = ulResStrLen;
szResult = ( char * ) hb_xrealloc( szResult, ulResBufLen + 1 );
pHead = szResult + ulHead;
pTail = szResult + ulTail;
}
}
else
ulResStrLen -= ( ulNameLen - ulValLen );
/* move bytes located on the right side of a variable name */
memmove( pTail + ulValLen, pHead, ulCharsLeft + 1 );
/* copy substituted value */
memcpy( pTail, szValPtr, ulValLen );
/* restart scanning from the beginning of replaced string */
/* NOTE: This causes that the following code:
* a := '&a'
* var := '&a.b'
* is the same as:
* var := '&ab'
*/
pHead = pTail;
}
}
}
ulCharsLeft = ulResStrLen - ( pHead - szResult );
}
while( ulCharsLeft && ( pHead = (char *) memchr( (void *)pHead, '&', ulCharsLeft ) ) != NULL );
if( ulResStrLen < ulResBufLen )
{
/* result string is shorter then allocated buffer -
* cut it to a required length
*/
szResult = ( char * ) hb_xrealloc( szResult, ulResStrLen + 1 );
}
szResult[ ulResStrLen ] = 0; /* place terminating null character */
/* return a length of result string */
*pulStringLen = ulResStrLen;
return szResult; /* a new memory buffer was allocated */
}
/* NOTE:
* This will be called when macro variable or macro expression is
* placed on the right side of the assignment or when it is used as
* a parameter.
* PUSH operation
* iContext contains additional info when HB_SM_XBASE is enabled
* = 0 - in Clipper strict compatibility mode
* = HB_P_MACROPUSHLIST
* = HB_P_MACROPUSHPARE
*
* iContext contains HB_P_MACROPUSHPARE if a macro is used inside a codeblock
* EVAL( {|| &macro} )
*
*/
void hb_macroGetValue( HB_ITEM_PTR pItem, BYTE iContext, BYTE flags )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroGetValue(%p)", pItem));
if( hb_macroCheckParam( pItem ) )
{
HB_MACRO struMacro;
int iStatus;
#ifdef HB_MACRO_STATEMENTS
char * pText;
char * pOut;
#endif
struMacro.mode = HB_MODE_MACRO;
struMacro.supported = (flags & HB_SM_RT_MACRO) ? s_macroFlags : flags;
struMacro.Flags = HB_MACRO_GEN_PUSH;
struMacro.uiNameLen = HB_SYMBOL_NAME_LEN;
struMacro.status = HB_MACRO_CONT;
struMacro.string = pItem->item.asString.value;
struMacro.length = pItem->item.asString.length;
if( iContext != 0 )
{
/*
* If compiled in xbase compatibility mode:
* macro := "1,2"
* funCall( &macro ) ==> funCall( 1, 2 )
* { &macro } ==> { 1, 2 }
* var[ &macro ] ==> var[ 1, 2 ]
* var := (somevalue, &macro) ==> var := 2
*
* Always:
* macro := "1,2"
* EVAL( {|| &macro} )
*
*/
struMacro.Flags |= HB_MACRO_GEN_LIST;
if( iContext == HB_P_MACROPUSHPARE )
{
struMacro.Flags |= HB_MACRO_GEN_PARE;
}
}
#ifdef HB_MACRO_STATEMENTS
if( struMacro.supported & HB_SM_PREPROC )
{
char * ptr;
int slen;
pText = ( char * ) hb_xgrab( HB_PP_STR_SIZE );
pOut = ( char * ) hb_xgrab( HB_PP_STR_SIZE );
ptr = pText;
slen = HB_MIN( strlen( struMacro.string ), HB_PP_STR_SIZE - 1 );
memcpy( pText, struMacro.string, slen );
pText[ slen ] = 0;
memset( pOut, 0, HB_PP_STR_SIZE );
HB_SKIPTABSPACES( ptr );
if( !hb_pp_topDefine )
{
hb_pp_Table();
}
hb_pp_ParseExpression( ptr, pOut );
struMacro.string = pText;
struMacro.length = strlen( pText );
}
#endif
iStatus = hb_macroParse( &struMacro );
#ifdef HB_MACRO_STATEMENTS
if( struMacro.supported & HB_SM_PREPROC )
{
hb_xfree( pText );
hb_xfree( pOut );
}
#endif
hb_stackPop(); /* remove compiled string */
if( iStatus == HB_MACRO_OK && ( struMacro.status & HB_MACRO_CONT ) )
{
hb_macroRun( &struMacro );
if( iContext == HB_P_MACROPUSHLIST )
hb_vmPushLong( struMacro.uiListElements + 1 );
}
else
hb_macroSyntaxError( &struMacro );
hb_macroDelete( &struMacro );
}
}
/* NOTE:
* This will be called when macro variable or macro expression is
* placed on the left side of the assignment
* POP operation
*/
void hb_macroSetValue( HB_ITEM_PTR pItem, BYTE flags )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroSetValue(%p)", pItem));
if( hb_macroCheckParam( pItem ) )
{
HB_MACRO struMacro;
int iStatus;
struMacro.mode = HB_MODE_MACRO;
struMacro.supported = (flags & HB_SM_RT_MACRO) ? s_macroFlags : flags;
struMacro.Flags = HB_MACRO_GEN_POP;
struMacro.uiNameLen = HB_SYMBOL_NAME_LEN;
struMacro.status = HB_MACRO_CONT;
struMacro.string = pItem->item.asString.value;
struMacro.length = pItem->item.asString.length;
iStatus = hb_macroParse( &struMacro );
hb_stackPop(); /* remove compiled string */
if( iStatus == HB_MACRO_OK && ( struMacro.status & HB_MACRO_CONT ) )
hb_macroRun( &struMacro );
else
hb_macroSyntaxError( &struMacro );
hb_macroDelete( &struMacro );
}
}
/*
* Compile and run:
* &alias->var or
* alias->&var
* NOTE:
* Clipper implements these two cases as: &( alias +'->' + variable )
* This causes some non expected behaviours, for example:
* A :="M + M"
* ? &A->&A
* is the same as:
* &( "M + M->M + M" )
* instead of
* &( "M + M" ) -> &( "M + M" )
*/
static void hb_macroUseAliased( HB_ITEM_PTR pAlias, HB_ITEM_PTR pVar, int iFlag, BYTE bSupported )
{
if( HB_IS_STRING( pAlias ) && HB_IS_STRING( pVar ) )
{
/* grab memory for "alias->var"
*/
ULONG ulLen = pAlias->item.asString.length + pVar->item.asString.length + 2;
char * szString = ( char * ) hb_xgrab( ulLen + 1 );
HB_MACRO struMacro;
int iStatus;
memcpy( szString, pAlias->item.asString.value, pAlias->item.asString.length );
szString[ pAlias->item.asString.length ] = '-';
szString[ pAlias->item.asString.length + 1 ] = '>';
memcpy( szString + pAlias->item.asString.length + 2, pVar->item.asString.value, pVar->item.asString.length );
szString[ ulLen ] = '\0';
struMacro.mode = HB_MODE_MACRO;
struMacro.supported = (bSupported & HB_SM_RT_MACRO) ? s_macroFlags : bSupported;
struMacro.Flags = iFlag;
struMacro.uiNameLen = HB_SYMBOL_NAME_LEN;
struMacro.status = HB_MACRO_CONT;
struMacro.string = szString;
struMacro.length = ulLen;
iStatus = hb_macroParse( &struMacro );
hb_xfree( szString );
struMacro.string = NULL;
hb_stackPop(); /* remove compiled variable name */
hb_stackPop(); /* remove compiled alias */
if( iStatus == HB_MACRO_OK && ( struMacro.status & HB_MACRO_CONT ) )
hb_macroRun( &struMacro );
else
hb_macroSyntaxError( &struMacro );
hb_macroDelete( &struMacro );
}
else if( hb_macroCheckParam( pVar ) )
{
/* only right side of alias operator is a string - macro-compile
* this part only
*/
HB_MACRO struMacro;
int iStatus;
struMacro.mode = HB_MODE_MACRO;
struMacro.supported = (bSupported & HB_SM_RT_MACRO) ? s_macroFlags : bSupported;
struMacro.Flags = iFlag | HB_MACRO_GEN_ALIASED;
struMacro.uiNameLen = HB_SYMBOL_NAME_LEN;
struMacro.status = HB_MACRO_CONT;
struMacro.string = pVar->item.asString.value;
struMacro.length = pVar->item.asString.length;
iStatus = hb_macroParse( &struMacro );
hb_stackPop(); /* remove compiled string */
if( iStatus == HB_MACRO_OK && ( struMacro.status & HB_MACRO_CONT ) )
hb_macroRun( &struMacro );
else
hb_macroSyntaxError( &struMacro );
hb_macroDelete( &struMacro );
}
}
/* Compiles and run an aliased macro expression - generated pcode
* pops a value from the stack
* &alias->var := any
* alias->&var := any
*/
void hb_macroPopAliasedValue( HB_ITEM_PTR pAlias, HB_ITEM_PTR pVar, BYTE flags )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroPopAliasedValue(%p, %p)", pAlias, pVar));
hb_macroUseAliased( pAlias, pVar, HB_MACRO_GEN_POP, flags );
}
/* Compiles and run an aliased macro expression - generated pcode
* pushes a value onto the stack
* any := &alias->var
* any := alias->&var
*/
void hb_macroPushAliasedValue( HB_ITEM_PTR pAlias, HB_ITEM_PTR pVar, BYTE flags )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroPushAliasedValue(%p, %p)", pAlias, pVar));
hb_macroUseAliased( pAlias, pVar, HB_MACRO_GEN_PUSH, flags );
}
/* Check for '&' operator and replace it with a macro variable value
* Returns: the passed string if there is no '&' operator (pbNewString:=FALSE)
* new string if a valid macro text substitution was found (and sets
* pbNewString to TRUE)
*/
char * hb_macroExpandString( char *szString, ULONG ulLength, BOOL *pbNewString )
{
char *szResultString;
HB_TRACE(HB_TR_DEBUG, ("hb_macroExpandString(%s)", szString));
if( szString )
szResultString = hb_macroTextSubst( szString, &ulLength );
else
szResultString = szString;
*pbNewString = ( szString != szResultString );
return szResultString;
}
/* compile a string and return a pcode to push a value of expression
* NOTE: it can be called to implement an index key evaluation
* use hb_macroRun() to evaluate a compiled pcode
*/
HB_MACRO_PTR hb_macroCompile( char * szString )
{
HB_MACRO_PTR pMacro;
int iStatus;
HB_TRACE(HB_TR_DEBUG, ("hb_macroCompile(%s)", szString));
pMacro = ( HB_MACRO_PTR ) hb_xgrab( sizeof( HB_MACRO ) );
pMacro->mode = HB_MODE_MACRO;
pMacro->supported = s_macroFlags;
pMacro->Flags = HB_MACRO_DEALLOCATE | HB_MACRO_GEN_PUSH |
HB_MACRO_GEN_LIST | HB_MACRO_GEN_PARE;
pMacro->uiNameLen = HB_SYMBOL_NAME_LEN;
pMacro->status = HB_MACRO_CONT;
pMacro->string = szString;
pMacro->length = strlen( szString );
iStatus = hb_macroParse( pMacro );
if( ! ( iStatus == HB_MACRO_OK && ( pMacro->status & HB_MACRO_CONT ) ) )
{
hb_macroDelete( pMacro );
pMacro = NULL;
}
return pMacro;
}
/* This function handles a macro function calls, e.g. var :=&macro()
* and creating memvar variables using PUBLIC/PRIVATE command
* PUBLIC &macro
*
* 'pItem' points to a ITEM that contains a string value which after
* text substitution will return a function name
*/
void hb_macroPushSymbol( HB_ITEM_PTR pItem )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroPushSymbol(%p)", pItem));
if( hb_macroCheckParam( pItem ) )
{
char * szString;
BOOL bNewBuffer;
ULONG ulLength = pItem->item.asString.length;
szString = hb_macroTextSubst( pItem->item.asString.value, &ulLength );
bNewBuffer = ( szString != pItem->item.asString.value );
if( hb_macroIsIdent( szString ) )
{
HB_DYNS_PTR pDynSym = hb_dynsymGet( szString );
hb_stackPop(); /* remove compiled string */
/* NOTE: checking for valid function name (valid pointer) is done
* in hb_vmDo()
*/
hb_vmPushSymbol( pDynSym->pSymbol ); /* push compiled symbol instead of a string */
}
else
{
hb_stackPop(); /* remove compiled string */
hb_macroSyntaxError( NULL );
}
if( bNewBuffer )
hb_xfree( szString ); /* free space allocated in hb_macroTextSubst */
}
}
/* Macro text substitution
*
* 'pItem' points to a ITEM that contains a string value which after
* text substitution will be returned
*/
void hb_macroTextValue( HB_ITEM_PTR pItem )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroTextValue(%p)", pItem));
if( hb_macroCheckParam( pItem ) )
{
char * szString;
ULONG ulLength = pItem->item.asString.length;
szString = hb_macroTextSubst( pItem->item.asString.value, &ulLength );
if( szString != pItem->item.asString.value )
{
/* replace the old value on the eval stack with the new one
*/
hb_itemPutCPtr( pItem, szString, ulLength );
}
/*
* else
* leave original value on the eval stack - there was no '&' operator
* inside a string
*/
}
}
char * hb_macroGetType( HB_ITEM_PTR pItem )
{
char * szType;
HB_TRACE(HB_TR_DEBUG, ("hb_macroGetType(%p)", pItem));
if( hb_macroCheckParam( pItem ) )
{
HB_MACRO struMacro;
int iStatus;
struMacro.mode = HB_MODE_MACRO;
struMacro.supported = s_macroFlags;
struMacro.Flags = HB_MACRO_GEN_PUSH | HB_MACRO_GEN_TYPE;
struMacro.uiNameLen = HB_SYMBOL_NAME_LEN;
struMacro.status = HB_MACRO_CONT;
struMacro.string = pItem->item.asString.value;
struMacro.length = pItem->item.asString.length;
iStatus = hb_macroParse( &struMacro );
if( iStatus == HB_MACRO_OK )
{
/* passed string was successfully compiled
*/
if( struMacro.exprType == HB_ET_CODEBLOCK )
{
/* Clipper ignores any undeclared symbols or UDFs if the
* compiled expression is a valid codeblock
*/
szType ="B";
}
else if( struMacro.status & HB_MACRO_UNKN_SYM )
{
/* request for a symbol that is not in a symbol table or
* for a variable that is not visible
*/
szType = "U";
}
else if( struMacro.status & HB_MACRO_UDF )
{
szType = "UI"; /* UDF function was used - cannot determine a type */
}
else if( struMacro.status & HB_MACRO_CONT )
{
/* OK - the pcode was generated and it can be evaluated
*/
HB_ERROR_INFO struErr;
HB_ERROR_INFO_PTR pOld;
/* Set our temporary error handler. We do not need any error
* messages here - we need to know only if evaluation was
* successfull. If evaluation was successfull then the data type
* of expression can be determined.
*/
struErr.Func = hb_macroErrorType;
struErr.Cargo = ( void * ) &struMacro;
pOld = hb_errorHandler( &struErr );
hb_macroRun( &struMacro );
hb_errorHandler( pOld );
if( struMacro.status & HB_MACRO_CONT )
{
/* Evaluation was successfull
* Now the value of expression is placed on the eval stack -
* check its type and pop it from the stack
*/
szType = hb_itemTypeStr( hb_stackItemFromTop( -1 ) );
hb_stackPop();
}
else
{
/* something unpleasant happened during macro evaluation */
if( struMacro.pError )
{
ULONG ulGenCode;
ulGenCode = hb_errGetGenCode( struMacro.pError );
if( ulGenCode == EG_NOVAR || ulGenCode == EG_NOALIAS )
{
/* Undeclared variable returns 'U' in Clipper */
szType = "U";
}
else
szType = "UE";
}
else
szType = "UE";
}
}
else
{
szType = "UE";
}
}
else
szType = "UE"; /* syntax error during compilation */
hb_macroDelete( &struMacro );
}
else
szType = "U";
return szType;
}
/*
* Set macro capabilities if flag > 0 or get current macro capabilities
* if flag == 0
*/
ULONG hb_macroSetMacro( BOOL bSet, ULONG flag )
{
ULONG ulCurrentFlags = s_macroFlags;
if( flag > 0 )
{
if( bSet )
s_macroFlags |= flag;
else
s_macroFlags &= ~flag;
}
return ulCurrentFlags;
}
HB_FUNC( HB_SETMACRO )
{
int iPrmCnt = hb_pcount();
if( iPrmCnt > 0 )
{
ULONG ulFlags = ( ULONG ) hb_parnl( 1 );
PHB_ITEM pValue;
switch( ulFlags )
{
case HB_SM_HARBOUR:
/* enable/disable extended Harbour compatibility */
hb_retl( s_macroFlags & ulFlags );
pValue = hb_param( 2, HB_IT_LOGICAL );
if( pValue )
hb_macroSetMacro( hb_itemGetL( pValue ), ulFlags );
break;
case HB_SM_XBASE:
/* enable/disable extended xbase compatibility */
hb_retl( s_macroFlags & ulFlags );
pValue = hb_param( 2, HB_IT_LOGICAL );
if( pValue )
hb_macroSetMacro( hb_itemGetL( pValue ), ulFlags );
break;
case HB_SM_PREPROC :
/* enable/disable preprocessing before compilation */
hb_retl( s_macroFlags & ulFlags );
pValue = hb_param( 2, HB_IT_LOGICAL );
if( pValue )
hb_macroSetMacro( hb_itemGetL( pValue ), ulFlags );
break;
case HB_SM_ARRSTR :
/* enable/disable processing of strings as an array of bytes */
hb_retl( s_macroFlags & ulFlags );
pValue = hb_param( 2, HB_IT_LOGICAL );
if( pValue )
hb_macroSetMacro( hb_itemGetL( pValue ) &&
hb_vmFlagEnabled(HB_VMFLAG_ARRSTR), ulFlags );
break;
case HB_SM_SHORTCUTS:
/* enable/disable support for shortcut logical operators */
hb_retl( s_macroFlags & ulFlags );
pValue = hb_param( 2, HB_IT_LOGICAL );
if( pValue )
hb_macroSetMacro( hb_itemGetL( pValue ), ulFlags );
break;
default:
;/* do nothing */
}
}
else
hb_ret(); /* return NIL */
}
/* ************************************************************************* */
/* returns the order + 1 of a variable if defined or zero */
static int hb_macroLocalVarGetPos( char * szVarName, HB_COMP_DECL )
{
int iVar = 1;
HB_CBVAR_PTR pVars = HB_PCODE_DATA->pLocals;
while( pVars )
{
if( pVars->szName && ! strcmp( pVars->szName, szVarName ) )
return iVar;
else
{
if( pVars->pNext )
{
pVars = pVars->pNext;
iVar++;
}
else
return 0;
}
}
return 0;
}
BOOL hb_macroIsValidMacroText( char * szText, ULONG ulLen )
{
if( ulLen )
{
while( --ulLen )
{
if( *szText++ == '&' )
{
char ch = *szText;
if( ( ch >= 'A' && ch <= 'Z' ) ||
( ch >= 'a' && ch <= 'z' ) || ch == '_' )
return TRUE;
}
}
}
return FALSE;
}
ULONG hb_macroGenJump( LONG lOffset, HB_COMP_DECL )
{
if( lOffset == 0 )
hb_macroGenPCode4( HB_P_JUMPFAR, 0, 0, 0, HB_COMP_PARAM );
else if( HB_LIM_INT8( lOffset ) )
hb_macroGenPCode2( HB_P_JUMPNEAR, HB_LOBYTE( lOffset ), HB_COMP_PARAM );
else if( HB_LIM_INT16( lOffset ) )
hb_macroGenPCode3( HB_P_JUMP, HB_LOBYTE( lOffset ), HB_HIBYTE( lOffset ), HB_COMP_PARAM );
else if( HB_LIM_INT24( lOffset ) )
hb_macroGenPCode4( HB_P_JUMPFAR, HB_LOBYTE( lOffset ), HB_HIBYTE( lOffset ), HB_ULBYTE( lOffset ), HB_COMP_PARAM );
else
hb_macroError( HB_MACRO_TOO_COMPLEX, HB_COMP_PARAM );
return HB_PCODE_DATA->lPCodePos - 3;
}
ULONG hb_macroGenJumpFalse( LONG lOffset, HB_COMP_DECL )
{
if( lOffset == 0 )
hb_macroGenPCode4( HB_P_JUMPFALSEFAR, 0, 0, 0, HB_COMP_PARAM );
else if( HB_LIM_INT8( lOffset ) )
hb_macroGenPCode2( HB_P_JUMPFALSENEAR, HB_LOBYTE( lOffset ), HB_COMP_PARAM );
else if( HB_LIM_INT16( lOffset ) )
hb_macroGenPCode3( HB_P_JUMPFALSE, HB_LOBYTE( lOffset ), HB_HIBYTE( lOffset ), HB_COMP_PARAM );
else if( HB_LIM_INT24( lOffset ) )
hb_macroGenPCode4( HB_P_JUMPFALSEFAR, HB_LOBYTE( lOffset ), HB_HIBYTE( lOffset ), HB_ULBYTE( lOffset ), HB_COMP_PARAM );
else
hb_macroError( HB_MACRO_TOO_COMPLEX, HB_COMP_PARAM );
return HB_PCODE_DATA->lPCodePos - 3;
}
ULONG hb_macroGenJumpTrue( LONG lOffset, HB_COMP_DECL )
{
if( lOffset == 0 )
hb_macroGenPCode4( HB_P_JUMPTRUEFAR, 0, 0, 0, HB_COMP_PARAM );
else if( HB_LIM_INT8( lOffset ) )
hb_macroGenPCode2( HB_P_JUMPTRUENEAR, HB_LOBYTE( lOffset ), HB_COMP_PARAM );
else if( HB_LIM_INT16( lOffset ) )
hb_macroGenPCode3( HB_P_JUMPTRUE, HB_LOBYTE( lOffset ), HB_HIBYTE( lOffset ), HB_COMP_PARAM );
else if( HB_LIM_INT24( lOffset ) )
hb_macroGenPCode4( HB_P_JUMPTRUEFAR, HB_LOBYTE( lOffset ), HB_HIBYTE( lOffset ), HB_ULBYTE( lOffset ), HB_COMP_PARAM );
else
hb_macroError( HB_MACRO_TOO_COMPLEX, HB_COMP_PARAM );
return HB_PCODE_DATA->lPCodePos - 3;
}
void hb_macroGenJumpThere( ULONG ulFrom, ULONG ulTo, HB_COMP_DECL )
{
BYTE * pCode = HB_PCODE_DATA->pCode;
LONG lOffset = ulTo - ulFrom + 1;
if( HB_LIM_INT24( lOffset ) )
HB_PUT_LE_UINT24( &pCode[ ulFrom ], lOffset );
else
hb_macroError( HB_MACRO_TOO_COMPLEX, HB_COMP_PARAM );
}
void hb_macroGenJumpHere( ULONG ulOffset, HB_COMP_DECL )
{
hb_macroGenJumpThere( ulOffset, HB_PCODE_DATA->lPCodePos, HB_COMP_PARAM );
}
/*
* Function generates pcode for passed memvar name
*/
static void hb_macroMemvarGenPCode( BYTE bPCode, char * szVarName, HB_COMP_DECL )
{
BYTE byBuf[ sizeof( HB_DYNS_PTR ) + 1 ];
HB_DYNS_PTR pSym;
if( HB_MACRO_DATA->Flags & HB_MACRO_GEN_TYPE )
{
/* we are determining the type of expression (called from TYPE() function)
* then we shouldn't create the requested variable if it doesn't exist
*/
pSym = hb_dynsymFind( szVarName );
if( !pSym )
{
HB_MACRO_DATA->status |= HB_MACRO_UNKN_VAR;
pSym = hb_dynsymGet( szVarName );
}
}
else
/* Find the address of passed symbol - create the symbol if doesn't exist
* (Clipper compatibility). */
pSym = hb_dynsymGet( szVarName );
byBuf[ 0 ] = bPCode;
HB_PUT_PTR( &byBuf[ 1 ], pSym );
hb_macroGenPCodeN( byBuf, sizeof( byBuf ), HB_COMP_PARAM );
}
/* generates the pcode to push a symbol on the virtual machine stack */
void hb_macroGenPushSymbol( char * szSymbolName, BOOL bFunction, HB_COMP_DECL )
{
BYTE byBuf[ sizeof( HB_DYNS_PTR ) + 1 ];
HB_DYNS_PTR pSym;
if( HB_MACRO_DATA->Flags & HB_MACRO_GEN_TYPE )
{
/* we are determining the type of expression (called from TYPE() function)
*/
pSym = hb_dynsymFind( szSymbolName );
if( ! pSym )
{
HB_MACRO_DATA->status |= HB_MACRO_UNKN_SYM;
HB_MACRO_DATA->status &= ~HB_MACRO_CONT; /* don't run this pcode */
/*
* NOTE: the compiled pcode will be not executed then we can ignore
* NULL value for pSym
*/
}
else if( bFunction )
{
if( pSym->pSymbol->value.pFunPtr == NULL )
{
/* static functions are not allowed in macro */
HB_MACRO_DATA->status |= HB_MACRO_UNKN_SYM;
HB_MACRO_DATA->status &= ~HB_MACRO_CONT; /* don't run this pcode */
}
}
}
else
pSym = hb_dynsymGet( szSymbolName );
byBuf[ 0 ] = HB_P_MPUSHSYM;
HB_PUT_PTR( &byBuf[ 1 ], pSym );
hb_macroGenPCodeN( byBuf, sizeof( byBuf ), HB_COMP_PARAM );
}
/* generates the pcode to push a long number on the virtual machine stack */
void hb_macroGenPushLong( HB_LONG lNumber, HB_COMP_DECL )
{
if( lNumber == 0 )
{
hb_macroGenPCode1( HB_P_ZERO, HB_COMP_PARAM );
}
else if( lNumber == 1 )
{
hb_macroGenPCode1( HB_P_ONE, HB_COMP_PARAM );
}
else if( HB_LIM_INT8( lNumber ) )
{
hb_macroGenPCode2( HB_P_PUSHBYTE, (BYTE) lNumber, HB_COMP_PARAM );
}
else if( HB_LIM_INT16( lNumber ) )
{
hb_macroGenPCode3( HB_P_PUSHINT, HB_LOBYTE( lNumber ), HB_HIBYTE( lNumber ), HB_COMP_PARAM );
}
else if( HB_LIM_INT32( lNumber ) )
{
BYTE pBuffer[ 5 ];
pBuffer[ 0 ] = HB_P_PUSHLONG;
HB_PUT_LE_UINT32( pBuffer + 1, lNumber );
hb_macroGenPCodeN( pBuffer, sizeof( pBuffer ), HB_COMP_PARAM );
}
else
{
BYTE pBuffer[ 9 ];
pBuffer[ 0 ] = HB_P_PUSHLONGLONG;
HB_PUT_LE_UINT64( pBuffer + 1, lNumber );
hb_macroGenPCodeN( pBuffer, sizeof( pBuffer ), HB_COMP_PARAM );
}
}
/* generates the pcode to push a date on the virtual machine stack */
void hb_macroGenPushDate( HB_LONG lNumber, HB_COMP_DECL )
{
BYTE pBuffer[ 5 ];
pBuffer[ 0 ] = HB_P_PUSHDATE;
HB_PUT_LE_UINT32( pBuffer + 1, lNumber );
hb_macroGenPCodeN( pBuffer, sizeof( pBuffer ), HB_COMP_PARAM );
}
/* sends a message to an object */
void hb_macroGenMessage( char * szMsgName, BOOL bIsObject, HB_COMP_DECL )
{
BYTE byBuf[ sizeof( HB_DYNS_PTR ) + 1 ];
/* Find the address of passed symbol - create the symbol if doesn't exist
*/
HB_DYNS_PTR pSym = hb_dynsymGet( szMsgName );
byBuf[ 0 ] = HB_P_MMESSAGE;
HB_PUT_PTR( &byBuf[ 1 ], pSym );
hb_macroGenPCodeN( byBuf, sizeof( byBuf ), HB_COMP_PARAM );
HB_SYMBOL_UNUSED( bIsObject ); /* used in full compiler only */
}
/* generates an underscore-symbol name for a data assignment */
void hb_macroGenMessageData( char * szMsg, BOOL bIsObject, HB_COMP_DECL )
{
char * szResult;
HB_TRACE(HB_TR_DEBUG, ("hb_macroGenMessageData(%s)", szMsg));
szResult = hb_xstrcpy( NULL, "_", szMsg, NULL );
hb_macroGenMessage( szResult, bIsObject, HB_COMP_PARAM );
hb_xfree( szResult );
}
/* generates the pcode to pop a value from the virtual machine stack onto a variable */
void hb_macroGenPopVar( char * szVarName, HB_COMP_DECL )
{
int iVar;
iVar = hb_macroLocalVarGetPos( szVarName, HB_COMP_PARAM );
if( iVar )
{
/* this is a codeblock parameter */
hb_macroGenPCode3( HB_P_POPLOCAL, HB_LOBYTE( iVar ), HB_HIBYTE( iVar ), HB_COMP_PARAM );
}
else
{
/* TODO: memvars created inside TYPE() function should have PUBLIC scope */
hb_macroMemvarGenPCode( HB_P_MPOPMEMVAR, szVarName, HB_COMP_PARAM );
}
}
/* generates the pcode to pop a value from the virtual machine stack onto
* an aliased variable
*/
void hb_macroGenPopAliasedVar( char * szVarName,
BOOL bPushAliasValue,
char * szAlias,
long lWorkarea, HB_COMP_DECL )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroGenPopAliasedVar(%s->%s)",szAlias,szVarName));
if( bPushAliasValue )
{
if( szAlias )
{
int iLen = strlen( szAlias );
if( szAlias[ 0 ] == 'M' && ( iLen == 1 ||
( iLen >= 4 && iLen <= 6 && strncmp( szAlias, "MEMVAR", iLen ) == 0 ) ) )
{ /* M-> or MEMV-> or MEMVA-> or MEMVAR-> variable */
/* TODO: memvars created inside TYPE() function should have PUBLIC scope */
hb_macroMemvarGenPCode( HB_P_MPOPMEMVAR, szVarName, HB_COMP_PARAM );
}
else if( iLen >= 4 && iLen <= 5 && strncmp( szAlias, "FIELD", iLen ) == 0 )
{ /* FIELD-> */
hb_macroMemvarGenPCode( HB_P_MPOPFIELD, szVarName, HB_COMP_PARAM );
}
else
{ /* database alias */
hb_macroGenPushSymbol( szAlias, FALSE, HB_COMP_PARAM );
hb_macroMemvarGenPCode( HB_P_MPOPALIASEDFIELD, szVarName, HB_COMP_PARAM );
}
}
else
{
hb_macroGenPushLong( lWorkarea, HB_COMP_PARAM );
hb_macroMemvarGenPCode( HB_P_MPOPALIASEDFIELD, szVarName, HB_COMP_PARAM );
}
}
else
{
/* Alias is already placed on stack
* NOTE: An alias will be determined at runtime then we cannot decide
* here if passed name is either a field or a memvar
*/
/* TODO: memvars created inside TYPE() function should have PUBLIC scope */
hb_macroMemvarGenPCode( HB_P_MPOPALIASEDVAR, szVarName, HB_COMP_PARAM );
}
}
/* generates the pcode to push a nonaliased variable value to the virtual
* machine stack
*/
void hb_macroGenPushVar( char * szVarName, BOOL bMacroVar, HB_COMP_DECL )
{
int iVar;
HB_SYMBOL_UNUSED( bMacroVar );
iVar = hb_macroLocalVarGetPos( szVarName, HB_COMP_PARAM );
if( iVar )
{
/* this is a codeblock parameter */
hb_macroGenPCode3( HB_P_PUSHLOCAL, HB_LOBYTE( iVar ), HB_HIBYTE( iVar ), HB_COMP_PARAM );
}
else
{
hb_macroMemvarGenPCode( HB_P_MPUSHVARIABLE, szVarName, HB_COMP_PARAM );
}
}
/* generates the pcode to push a variable by reference to the virtual machine stack */
void hb_macroGenPushVarRef( char * szVarName, HB_COMP_DECL )
{
USHORT iVar;
iVar = hb_macroLocalVarGetPos( szVarName, HB_COMP_PARAM );
if( iVar )
hb_macroGenPCode3( HB_P_PUSHLOCALREF, HB_LOBYTE( iVar ), HB_HIBYTE( iVar ), HB_COMP_PARAM );
else
{
hb_macroMemvarGenPCode( HB_P_MPUSHMEMVARREF, szVarName, HB_COMP_PARAM );
}
}
/* generates the pcode to push a variable by reference to the virtual machine stack */
void hb_macroGenPushMemvarRef( char * szVarName, HB_COMP_DECL )
{
hb_macroMemvarGenPCode( HB_P_MPUSHMEMVARREF, szVarName, HB_COMP_PARAM );
}
/* generates the pcode to push an aliased variable value to the virtual
* machine stack
*/
void hb_macroGenPushAliasedVar( char * szVarName,
BOOL bPushAliasValue,
char * szAlias,
long lWorkarea, HB_COMP_DECL )
{
HB_TRACE(HB_TR_DEBUG, ("hb_macroGenPushAliasedVar(%s->%s)",szAlias,szVarName));
if( bPushAliasValue )
{
if( szAlias )
{
/* myalias->var
* FIELD->var
* MEMVAR->var
*/
int iLen = strlen( szAlias );
if( szAlias[ 0 ] == 'M' && ( iLen == 1 ||
( iLen >= 4 && iLen <= 6 && strncmp( szAlias, "MEMVAR", iLen ) == 0 ) ) )
{ /* M-> or MEMV-> or MEMVA-> or MEMVAR-> variable */
hb_macroMemvarGenPCode( HB_P_MPUSHMEMVAR, szVarName, HB_COMP_PARAM );
}
else if( iLen >= 4 && iLen <= 5 && strncmp( szAlias, "FIELD", iLen ) == 0 )
{ /* FIELD-> */
hb_macroMemvarGenPCode( HB_P_MPUSHFIELD, szVarName, HB_COMP_PARAM );
}
else
{ /* database alias */
hb_macroGenPushSymbol( szAlias, FALSE, HB_COMP_PARAM );
hb_macroMemvarGenPCode( HB_P_MPUSHALIASEDFIELD, szVarName, HB_COMP_PARAM );
}
}
else
{
hb_macroGenPushLong( lWorkarea, HB_COMP_PARAM );
hb_macroMemvarGenPCode( HB_P_MPUSHALIASEDFIELD, szVarName, HB_COMP_PARAM );
}
}
else
{
/* Alias is already placed on stack
* NOTE: An alias will be determined at runtime then we cannot decide
* here if passed name is either a field or a memvar
*/
hb_macroMemvarGenPCode( HB_P_MPUSHALIASEDVAR, szVarName, HB_COMP_PARAM );
}
}
/* pushes a logical value on the virtual machine stack , */
void hb_macroGenPushLogical( int iTrueFalse, HB_COMP_DECL )
{
if( iTrueFalse )
hb_macroGenPCode1( HB_P_TRUE, HB_COMP_PARAM );
else
hb_macroGenPCode1( HB_P_FALSE, HB_COMP_PARAM );
}
/* generates the pcode to push a double number on the virtual machine stack */
void hb_macroGenPushDouble( double dNumber, BYTE bWidth, BYTE bDec, HB_COMP_DECL )
{
BYTE pBuffer[ sizeof( double ) + sizeof( BYTE ) + sizeof( BYTE ) + 1 ];
pBuffer[ 0 ] = HB_P_PUSHDOUBLE;
HB_PUT_LE_DOUBLE( &( pBuffer[ 1 ] ), dNumber );
pBuffer[ 1 + sizeof( double ) ] = bWidth;
pBuffer[ 1 + sizeof( double ) + sizeof( BYTE ) ] = bDec;
hb_macroGenPCodeN( pBuffer, 1 + sizeof( double ) + sizeof( BYTE ) + sizeof( BYTE ), HB_COMP_PARAM );
}
void hb_macroGenPushFunSym( char * szFunName, HB_COMP_DECL )
{
char * szFunction;
szFunction = hb_compReservedName( szFunName );
if( szFunction )
{
/* Abbreviated function name was used - change it for whole name
*/
hb_macroGenPushSymbol( szFunction, TRUE, HB_COMP_PARAM );
}
else
{
HB_MACRO_DATA->status |= HB_MACRO_UDF; /* this is used in hb_macroGetType */
hb_macroGenPushSymbol( szFunName, TRUE, HB_COMP_PARAM );
}
}
void hb_macroGenPushFunCall( char * szFunName, HB_COMP_DECL )
{
hb_macroGenPushFunSym( szFunName, HB_COMP_PARAM );
hb_macroGenPCode1( HB_P_PUSHNIL, HB_COMP_PARAM );
}
void hb_macroGenPushFunRef( char * szFunName, HB_COMP_DECL )
{
char * szFunction;
/* if abbreviated function name was used - change it for whole name */
szFunction = hb_compReservedName( szFunName );
hb_macroGenPushSymbol( szFunction ? szFunction : szFunName, TRUE, HB_COMP_PARAM );
}
/* generates the pcode to push a string on the virtual machine stack */
void hb_macroGenPushString( char * szText, ULONG ulStrLen, HB_COMP_DECL )
{
if( ulStrLen <= UINT24_MAX )
{
if( ulStrLen <= USHRT_MAX )
hb_macroGenPCode3( HB_P_MPUSHSTR, HB_LOBYTE( ulStrLen ), HB_HIBYTE( ulStrLen ), HB_COMP_PARAM );
else
hb_macroGenPCode4( HB_P_MPUSHSTRLARGE, HB_LOBYTE( ulStrLen ), HB_HIBYTE( ulStrLen ), HB_ULBYTE( ulStrLen ), HB_COMP_PARAM );
hb_macroGenPCodeN( ( BYTE * ) szText, ulStrLen, HB_COMP_PARAM );
}
else
hb_macroError( HB_MACRO_TOO_COMPLEX, HB_COMP_PARAM );
}
void hb_macroGenPCode1( BYTE byte, HB_COMP_DECL )
{
HB_PCODE_INFO_PTR pFunc = HB_PCODE_DATA;
if( ( pFunc->lPCodeSize - pFunc->lPCodePos ) < 1 )
pFunc->pCode = ( BYTE * ) hb_xrealloc( pFunc->pCode, pFunc->lPCodeSize += HB_PCODE_SIZE );
pFunc->pCode[ pFunc->lPCodePos++ ] = byte;
}
void hb_macroGenPCode2( BYTE byte1, BYTE byte2, HB_COMP_DECL )
{
HB_PCODE_INFO_PTR pFunc = HB_PCODE_DATA;
if( ( pFunc->lPCodeSize - pFunc->lPCodePos ) < 2 )
pFunc->pCode = ( BYTE * ) hb_xrealloc( pFunc->pCode, pFunc->lPCodeSize += HB_PCODE_SIZE );
pFunc->pCode[ pFunc->lPCodePos++ ] = byte1;
pFunc->pCode[ pFunc->lPCodePos++ ] = byte2;
}
void hb_macroGenPCode3( BYTE byte1, BYTE byte2, BYTE byte3, HB_COMP_DECL )
{
HB_PCODE_INFO_PTR pFunc = HB_PCODE_DATA;
if( ( pFunc->lPCodeSize - pFunc->lPCodePos ) < 3 )
pFunc->pCode = ( BYTE * ) hb_xrealloc( pFunc->pCode, pFunc->lPCodeSize += HB_PCODE_SIZE );
pFunc->pCode[ pFunc->lPCodePos++ ] = byte1;
pFunc->pCode[ pFunc->lPCodePos++ ] = byte2;
pFunc->pCode[ pFunc->lPCodePos++ ] = byte3;
}
void hb_macroGenPCode4( BYTE byte1, BYTE byte2, BYTE byte3, BYTE byte4, HB_COMP_DECL )
{
HB_PCODE_INFO_PTR pFunc = HB_PCODE_DATA;
if( ( pFunc->lPCodeSize - pFunc->lPCodePos ) < 4 )
pFunc->pCode = ( BYTE * ) hb_xrealloc( pFunc->pCode, pFunc->lPCodeSize += HB_PCODE_SIZE );
pFunc->pCode[ pFunc->lPCodePos++ ] = byte1;
pFunc->pCode[ pFunc->lPCodePos++ ] = byte2;
pFunc->pCode[ pFunc->lPCodePos++ ] = byte3;
pFunc->pCode[ pFunc->lPCodePos++ ] = byte4;
}
void hb_macroGenPCodeN( BYTE * pBuffer, ULONG ulSize, HB_COMP_DECL )
{
HB_PCODE_INFO_PTR pFunc = HB_PCODE_DATA;
if( pFunc->lPCodePos + ulSize > pFunc->lPCodeSize )
{
/* not enough free space in pcode buffer - increase it */
pFunc->lPCodeSize += ( ( ( ulSize / HB_PCODE_SIZE ) + 1 ) * HB_PCODE_SIZE );
pFunc->pCode = ( BYTE * ) hb_xrealloc( pFunc->pCode, pFunc->lPCodeSize );
}
memcpy( pFunc->pCode + pFunc->lPCodePos, pBuffer, ulSize );
pFunc->lPCodePos += ulSize;
}
/* ************************************************************************* */
void hb_macroError( int iError, HB_COMP_DECL )
{
HB_MACRO_DATA->status |= iError;
HB_MACRO_DATA->status &= ~HB_MACRO_CONT; /* clear CONT bit */
}
/*
* Start a new pcode buffer for a codeblock
*/
void hb_macroCodeBlockStart( HB_COMP_DECL )
{
HB_PCODE_INFO_PTR pCB;
HB_TRACE(HB_TR_DEBUG, ("hb_macroCodeBlockStart(%p)", HB_COMP_PARAM));
pCB = ( HB_PCODE_INFO_PTR ) hb_xgrab( sizeof( HB_PCODE_INFO ) );
/* replace current pcode buffer with the new one
*/
pCB->pPrev = HB_PCODE_DATA;
HB_PCODE_DATA = pCB;
HB_TRACE(HB_TR_DEBUG, ("hb_macroCodeBlockStart.(%p)", HB_COMP_PARAM));
pCB->pCode = ( BYTE * ) hb_xgrab( HB_PCODE_SIZE );
pCB->lPCodeSize = HB_PCODE_SIZE;
pCB->lPCodePos = 0;
pCB->fVParams = FALSE;
pCB->pLocals = NULL;
}
void hb_macroCodeBlockEnd( HB_COMP_DECL )
{
HB_PCODE_INFO_PTR pCodeblock; /* pointer to the current codeblock */
ULONG ulSize;
USHORT wParms = 0; /* number of codeblock parameters */
HB_CBVAR_PTR pVar;
HB_TRACE(HB_TR_DEBUG, ("hb_macroCodeBlockEnd(%p)", HB_COMP_PARAM));
/* a currently processed codeblock */
pCodeblock = HB_PCODE_DATA;
/* return to pcode buffer of a codeblock in which the current
* codeblock was defined
*/
HB_PCODE_DATA = pCodeblock->pPrev;
/* generate a proper codeblock frame with a codeblock size and with
* a number of expected parameters
*/
/* Count the number of codeblock parameters */
pVar = pCodeblock->pLocals;
while( pVar )
{
pVar = pVar->pNext;
++wParms;
}
/*NOTE: 6 = HB_P_MPUSHBLOCK + USHORT( size ) + USHORT( wParams ) + _ENDBLOCK
* runtime compiled codeblock cannot reference local variables defined in a
* function
*/
ulSize = ( ULONG ) pCodeblock->lPCodePos + 6;
/*NOTE: HB_P_MPUSHBLOCK differs from HB_P_PUSHBLOCK - the pcode
* is stored in dynamic memory pool instead of static memory
*/
if( ulSize <= USHRT_MAX )
hb_macroGenPCode3( HB_P_MPUSHBLOCK, HB_LOBYTE( ulSize ), HB_HIBYTE( ulSize ), HB_COMP_PARAM );
else
{
++ulSize;
hb_macroGenPCode4( HB_P_MPUSHBLOCKLARGE, HB_LOBYTE( ulSize ), HB_HIBYTE( ulSize ), HB_ULBYTE( ulSize ), HB_COMP_PARAM );
}
hb_macroGenPCode2( HB_LOBYTE( wParms ), HB_HIBYTE( wParms ), HB_COMP_PARAM );
/* copy a codeblock pcode buffer */
hb_macroGenPCodeN( pCodeblock->pCode, pCodeblock->lPCodePos, HB_COMP_PARAM );
hb_macroGenPCode1( HB_P_ENDBLOCK, HB_COMP_PARAM ); /* finish the codeblock */
/* free memory allocated for a codeblock */
hb_xfree( ( void * ) pCodeblock->pCode );
hb_xfree( ( void * ) pCodeblock );
}
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