/************************************************************************* * * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * Copyright 2000, 2010 Oracle and/or its affiliates. * * OpenOffice.org - a multi-platform office productivity suite * * This file is part of OpenOffice.org. * * OpenOffice.org is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License version 3 * only, as published by the Free Software Foundation. * * OpenOffice.org 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 Lesser General Public License version 3 for more details * (a copy is included in the LICENSE file that accompanied this code). * * You should have received a copy of the GNU Lesser General Public License * version 3 along with OpenOffice.org. If not, see * * for a copy of the LGPLv3 License. * ************************************************************************/ // MARKER(update_precomp.py): autogen include statement, do not remove #include "precompiled_basic.hxx" #include #include #include #include "runtime.hxx" #include "sbintern.hxx" #include "iosys.hxx" #include "image.hxx" #include "sbunoobj.hxx" #include "errobject.hxx" bool checkUnoObjectType( SbUnoObject* refVal, const String& aClass ); // Laden einer numerischen Konstanten (+ID) void SbiRuntime::StepLOADNC( sal_uInt32 nOp1 ) { SbxVariable* p = new SbxVariable( SbxDOUBLE ); // #57844 Lokalisierte Funktion benutzen String aStr = pImg->GetString( static_cast( nOp1 ) ); // Auch , zulassen !!! sal_uInt16 iComma = aStr.Search( ',' ); if( iComma != STRING_NOTFOUND ) { String aStr1 = aStr.Copy( 0, iComma ); String aStr2 = aStr.Copy( iComma + 1 ); aStr = aStr1; aStr += '.'; aStr += aStr2; } double n = ::rtl::math::stringToDouble( aStr, '.', ',', NULL, NULL ); p->PutDouble( n ); PushVar( p ); } // Laden einer Stringkonstanten (+ID) void SbiRuntime::StepLOADSC( sal_uInt32 nOp1 ) { SbxVariable* p = new SbxVariable; p->PutString( pImg->GetString( static_cast( nOp1 ) ) ); PushVar( p ); } // Immediate Load (+Wert) void SbiRuntime::StepLOADI( sal_uInt32 nOp1 ) { SbxVariable* p = new SbxVariable; p->PutInteger( static_cast( nOp1 ) ); PushVar( p ); } // Speichern eines named Arguments in Argv (+Arg-Nr ab 1!) void SbiRuntime::StepARGN( sal_uInt32 nOp1 ) { if( !refArgv ) StarBASIC::FatalError( SbERR_INTERNAL_ERROR ); else { String aAlias( pImg->GetString( static_cast( nOp1 ) ) ); SbxVariableRef pVal = PopVar(); refArgv->Put( pVal, nArgc ); refArgv->PutAlias( aAlias, nArgc++ ); } } // Konvertierung des Typs eines Arguments in Argv fuer DECLARE-Fkt. (+Typ) void SbiRuntime::StepARGTYP( sal_uInt32 nOp1 ) { if( !refArgv ) StarBASIC::FatalError( SbERR_INTERNAL_ERROR ); else { sal_Bool bByVal = (nOp1 & 0x8000) != 0; // Ist BYVAL verlangt? SbxDataType t = (SbxDataType) (nOp1 & 0x7FFF); SbxVariable* pVar = refArgv->Get( refArgv->Count() - 1 ); // letztes Arg // BYVAL prüfen if( pVar->GetRefCount() > 2 ) // 2 ist normal für BYVAL { // Parameter ist eine Referenz if( bByVal ) { // Call by Value ist verlangt -> Kopie anlegen pVar = new SbxVariable( *pVar ); pVar->SetFlag( SBX_READWRITE ); refExprStk->Put( pVar, refArgv->Count() - 1 ); } else pVar->SetFlag( SBX_REFERENCE ); // Ref-Flag für DllMgr } else { // Parameter ist KEINE Referenz if( bByVal ) pVar->ResetFlag( SBX_REFERENCE ); // Keine Referenz -> OK else Error( SbERR_BAD_PARAMETERS ); // Referenz verlangt } if( pVar->GetType() != t ) { // Variant, damit richtige Konvertierung // Ausserdem Fehler, wenn SbxBYREF pVar->Convert( SbxVARIANT ); pVar->Convert( t ); } } } // String auf feste Laenge bringen (+Laenge) void SbiRuntime::StepPAD( sal_uInt32 nOp1 ) { SbxVariable* p = GetTOS(); String& s = (String&)(const String&) *p; if( s.Len() > nOp1 ) s.Erase( static_cast( nOp1 ) ); else s.Expand( static_cast( nOp1 ), ' ' ); } // Sprung (+Target) void SbiRuntime::StepJUMP( sal_uInt32 nOp1 ) { #ifdef DBG_UTIL // #QUESTION shouln't this be // if( (sal_uInt8*)( nOp1+pImagGetCode() ) >= pImg->GetCodeSize() ) if( nOp1 >= pImg->GetCodeSize() ) StarBASIC::FatalError( SbERR_INTERNAL_ERROR ); #endif pCode = (const sal_uInt8*) pImg->GetCode() + nOp1; } // TOS auswerten, bedingter Sprung (+Target) void SbiRuntime::StepJUMPT( sal_uInt32 nOp1 ) { SbxVariableRef p = PopVar(); if( p->GetBool() ) StepJUMP( nOp1 ); } // TOS auswerten, bedingter Sprung (+Target) void SbiRuntime::StepJUMPF( sal_uInt32 nOp1 ) { SbxVariableRef p = PopVar(); if( !p->GetBool() ) StepJUMP( nOp1 ); } // TOS auswerten, Sprung in JUMP-Tabelle (+MaxVal) // Sieht so aus: // ONJUMP 2 // JUMP target1 // JUMP target2 // ... //Falls im Operanden 0x8000 gesetzt ist, Returnadresse pushen (ON..GOSUB) void SbiRuntime::StepONJUMP( sal_uInt32 nOp1 ) { SbxVariableRef p = PopVar(); sal_Int16 n = p->GetInteger(); if( nOp1 & 0x8000 ) { nOp1 &= 0x7FFF; //PushGosub( pCode + 3 * nOp1 ); PushGosub( pCode + 5 * nOp1 ); } if( n < 1 || static_cast(n) > nOp1 ) n = static_cast( nOp1 + 1 ); //nOp1 = (sal_uInt32) ( (const char*) pCode - pImg->GetCode() ) + 3 * --n; nOp1 = (sal_uInt32) ( (const char*) pCode - pImg->GetCode() ) + 5 * --n; StepJUMP( nOp1 ); } // UP-Aufruf (+Target) void SbiRuntime::StepGOSUB( sal_uInt32 nOp1 ) { PushGosub( pCode ); if( nOp1 >= pImg->GetCodeSize() ) StarBASIC::FatalError( SbERR_INTERNAL_ERROR ); pCode = (const sal_uInt8*) pImg->GetCode() + nOp1; } // UP-Return (+0 oder Target) void SbiRuntime::StepRETURN( sal_uInt32 nOp1 ) { PopGosub(); if( nOp1 ) StepJUMP( nOp1 ); } // FOR-Variable testen (+Endlabel) void SbiRuntime::StepTESTFOR( sal_uInt32 nOp1 ) { if( !pForStk ) { StarBASIC::FatalError( SbERR_INTERNAL_ERROR ); return; } bool bEndLoop = false; switch( pForStk->eForType ) { case FOR_TO: { SbxOperator eOp = ( pForStk->refInc->GetDouble() < 0 ) ? SbxLT : SbxGT; if( pForStk->refVar->Compare( eOp, *pForStk->refEnd ) ) bEndLoop = true; break; } case FOR_EACH_ARRAY: { SbiForStack* p = pForStk; if( p->pArrayCurIndices == NULL ) { bEndLoop = true; } else { SbxDimArray* pArray = (SbxDimArray*)(SbxVariable*)p->refEnd; short nDims = pArray->GetDims(); // Empty array? if( nDims == 1 && p->pArrayLowerBounds[0] > p->pArrayUpperBounds[0] ) { bEndLoop = true; break; } SbxVariable* pVal = pArray->Get32( p->pArrayCurIndices ); *(p->refVar) = *pVal; bool bFoundNext = false; for( short i = 0 ; i < nDims ; i++ ) { if( p->pArrayCurIndices[i] < p->pArrayUpperBounds[i] ) { bFoundNext = true; p->pArrayCurIndices[i]++; for( short j = i - 1 ; j >= 0 ; j-- ) p->pArrayCurIndices[j] = p->pArrayLowerBounds[j]; break; } } if( !bFoundNext ) { delete[] p->pArrayCurIndices; p->pArrayCurIndices = NULL; } } break; } case FOR_EACH_COLLECTION: { BasicCollection* pCollection = (BasicCollection*)(SbxVariable*)pForStk->refEnd; SbxArrayRef xItemArray = pCollection->xItemArray; sal_Int32 nCount = xItemArray->Count32(); if( pForStk->nCurCollectionIndex < nCount ) { SbxVariable* pRes = xItemArray->Get32( pForStk->nCurCollectionIndex ); pForStk->nCurCollectionIndex++; (*pForStk->refVar) = *pRes; } else { bEndLoop = true; } break; } case FOR_EACH_XENUMERATION: { SbiForStack* p = pForStk; if( p->xEnumeration->hasMoreElements() ) { Any aElem = p->xEnumeration->nextElement(); SbxVariableRef xVar = new SbxVariable( SbxVARIANT ); unoToSbxValue( (SbxVariable*)xVar, aElem ); (*pForStk->refVar) = *xVar; } else { bEndLoop = true; } break; } } if( bEndLoop ) { PopFor(); StepJUMP( nOp1 ); } } // Tos+1 <= Tos+2 <= Tos, 2xremove (+Target) void SbiRuntime::StepCASETO( sal_uInt32 nOp1 ) { if( !refCaseStk || !refCaseStk->Count() ) StarBASIC::FatalError( SbERR_INTERNAL_ERROR ); else { SbxVariableRef xTo = PopVar(); SbxVariableRef xFrom = PopVar(); SbxVariableRef xCase = refCaseStk->Get( refCaseStk->Count() - 1 ); if( *xCase >= *xFrom && *xCase <= *xTo ) StepJUMP( nOp1 ); } } // Fehler-Handler void SbiRuntime::StepERRHDL( sal_uInt32 nOp1 ) { const sal_uInt8* p = pCode; StepJUMP( nOp1 ); pError = pCode; pCode = p; pInst->aErrorMsg = String(); pInst->nErr = 0; pInst->nErl = 0; nError = 0; SbxErrObject::getUnoErrObject()->Clear(); } // Resume nach Fehlern (+0=statement, 1=next or Label) void SbiRuntime::StepRESUME( sal_uInt32 nOp1 ) { // AB #32714 Resume ohne Error? -> Fehler if( !bInError ) { Error( SbERR_BAD_RESUME ); return; } if( nOp1 ) { // Code-Zeiger auf naechstes Statement setzen sal_uInt16 n1, n2; pCode = pMod->FindNextStmnt( pErrCode, n1, n2, sal_True, pImg ); } else pCode = pErrStmnt; if ( pError ) // current in error handler ( and got a Resume Next statment ) SbxErrObject::getUnoErrObject()->Clear(); if( nOp1 > 1 ) StepJUMP( nOp1 ); pInst->aErrorMsg = String(); pInst->nErr = 0; pInst->nErl = 0; nError = 0; bInError = sal_False; // Error-Stack loeschen SbErrorStack*& rErrStack = GetSbData()->pErrStack; delete rErrStack; rErrStack = NULL; } // Kanal schliessen (+Kanal, 0=Alle) void SbiRuntime::StepCLOSE( sal_uInt32 nOp1 ) { SbError err; if( !nOp1 ) pIosys->Shutdown(); else { err = pIosys->GetError(); if( !err ) { pIosys->Close(); } } err = pIosys->GetError(); Error( err ); } // Zeichen ausgeben (+char) void SbiRuntime::StepPRCHAR( sal_uInt32 nOp1 ) { ByteString s( (char) nOp1 ); pIosys->Write( s ); Error( pIosys->GetError() ); } // Check, ob TOS eine bestimmte Objektklasse ist (+StringID) bool SbiRuntime::implIsClass( SbxObject* pObj, const String& aClass ) { bool bRet = true; if( aClass.Len() != 0 ) { bRet = pObj->IsClass( aClass ); if( !bRet ) bRet = aClass.EqualsIgnoreCaseAscii( String( RTL_CONSTASCII_USTRINGPARAM("object") ) ); if( !bRet ) { String aObjClass = pObj->GetClassName(); SbModule* pClassMod = pCLASSFAC->FindClass( aObjClass ); SbClassData* pClassData; if( pClassMod && (pClassData=pClassMod->pClassData) != NULL ) { SbxVariable* pClassVar = pClassData->mxIfaces->Find( aClass, SbxCLASS_DONTCARE ); bRet = (pClassVar != NULL); } } } return bRet; } bool SbiRuntime::checkClass_Impl( const SbxVariableRef& refVal, const String& aClass, bool bRaiseErrors, bool bDefault ) { bool bOk = bDefault; SbxDataType t = refVal->GetType(); if( t == SbxOBJECT ) { SbxObject* pObj; SbxVariable* pVal = (SbxVariable*)refVal; if( pVal->IsA( TYPE(SbxObject) ) ) pObj = (SbxObject*) pVal; else { pObj = (SbxObject*) refVal->GetObject(); if( pObj && !pObj->IsA( TYPE(SbxObject) ) ) pObj = NULL; } if( pObj ) { if( !implIsClass( pObj, aClass ) ) { if ( bVBAEnabled && pObj->IsA( TYPE(SbUnoObject) ) ) { SbUnoObject* pUnoObj = PTR_CAST(SbUnoObject,pObj); bOk = checkUnoObjectType( pUnoObj, aClass ); } else bOk = false; if ( !bOk ) { if( bRaiseErrors ) Error( SbERR_INVALID_USAGE_OBJECT ); } } else { bOk = true; SbClassModuleObject* pClassModuleObject = PTR_CAST(SbClassModuleObject,pObj); if( pClassModuleObject != NULL ) pClassModuleObject->triggerInitializeEvent(); } } } else { if ( !bVBAEnabled ) { if( bRaiseErrors ) Error( SbERR_NEEDS_OBJECT ); bOk = false; } } return bOk; } void SbiRuntime::StepSETCLASS_impl( sal_uInt32 nOp1, bool bHandleDflt ) { SbxVariableRef refVal = PopVar(); SbxVariableRef refVar = PopVar(); String aClass( pImg->GetString( static_cast( nOp1 ) ) ); bool bOk = checkClass_Impl( refVal, aClass, true ); if( bOk ) StepSET_Impl( refVal, refVar, bHandleDflt ); // don't do handle dflt prop for a "proper" set } void SbiRuntime::StepVBASETCLASS( sal_uInt32 nOp1 ) { StepSETCLASS_impl( nOp1, false ); } void SbiRuntime::StepSETCLASS( sal_uInt32 nOp1 ) { StepSETCLASS_impl( nOp1, true ); } void SbiRuntime::StepTESTCLASS( sal_uInt32 nOp1 ) { SbxVariableRef xObjVal = PopVar(); String aClass( pImg->GetString( static_cast( nOp1 ) ) ); bool bDefault = !bVBAEnabled; bool bOk = checkClass_Impl( xObjVal, aClass, false, bDefault ); SbxVariable* pRet = new SbxVariable; pRet->PutBool( bOk ); PushVar( pRet ); } // Library fuer anschliessenden Declare-Call definieren void SbiRuntime::StepLIB( sal_uInt32 nOp1 ) { aLibName = pImg->GetString( static_cast( nOp1 ) ); } // TOS wird um BASE erhoeht, BASE davor gepusht (+BASE) // Dieser Opcode wird vor DIM/REDIM-Anweisungen gepusht, // wenn nur ein Index angegeben wurde. void SbiRuntime::StepBASED( sal_uInt32 nOp1 ) { SbxVariable* p1 = new SbxVariable; SbxVariableRef x2 = PopVar(); // #109275 Check compatiblity mode bool bCompatible = ((nOp1 & 0x8000) != 0); sal_uInt16 uBase = static_cast(nOp1 & 1); // Can only be 0 or 1 p1->PutInteger( uBase ); if( !bCompatible ) x2->Compute( SbxPLUS, *p1 ); PushVar( x2 ); // erst die Expr PushVar( p1 ); // dann die Base }