/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* * This file is part of the LibreOffice project. * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ #include #include #include #include #include #include #include #include #include #include "sbxconv.hxx" #include #include #include ///////////////////////////// constructors SbxValue::SbxValue() { aData.eType = SbxEMPTY; } SbxValue::SbxValue( SbxDataType t ) { int n = t & 0x0FFF; if( n == SbxVARIANT ) n = SbxEMPTY; else SetFlag( SbxFlagBits::Fixed ); aData.clear(SbxDataType( n )); } SbxValue::SbxValue( const SbxValue& r ) : SvRefBase( r ), SbxBase( r ) { if( !r.CanRead() ) { SetError( ERRCODE_BASIC_PROP_WRITEONLY ); if( !IsFixed() ) aData.eType = SbxNULL; } else { const_cast(&r)->Broadcast( SfxHintId::BasicDataWanted ); aData = r.aData; // Copy pointer, increment references switch( aData.eType ) { case SbxSTRING: if( aData.pOUString ) aData.pOUString = new OUString( *aData.pOUString ); break; case SbxOBJECT: if( aData.pObj ) aData.pObj->AddFirstRef(); break; case SbxDECIMAL: if( aData.pDecimal ) aData.pDecimal->addRef(); break; default: break; } } } SbxValue& SbxValue::operator=( const SbxValue& r ) { if( &r != this ) { if( !CanWrite() ) SetError( ERRCODE_BASIC_PROP_READONLY ); else { // string -> byte array if( IsFixed() && (aData.eType == SbxOBJECT) && aData.pObj && ( aData.pObj->GetType() == (SbxARRAY | SbxBYTE) ) && (r.aData.eType == SbxSTRING) ) { OUString aStr = r.GetOUString(); SbxArray* pArr = StringToByteArray(aStr); PutObject(pArr); return *this; } // byte array -> string if( r.IsFixed() && (r.aData.eType == SbxOBJECT) && r.aData.pObj && ( r.aData.pObj->GetType() == (SbxARRAY | SbxBYTE) ) && (aData.eType == SbxSTRING) ) { SbxBase* pObj = r.GetObject(); SbxArray* pArr = dynamic_cast( pObj ); if( pArr ) { OUString aStr = ByteArrayToString( pArr ); PutString(aStr); return *this; } } // Readout the content of the variables SbxValues aNew; if( IsFixed() ) // then the type has to match aNew.eType = aData.eType; else if( r.IsFixed() ) // Source fixed: copy the type aNew.eType = SbxDataType( r.aData.eType & 0x0FFF ); else // both variant: then don't care aNew.eType = SbxVARIANT; if( r.Get( aNew ) ) Put( aNew ); } } return *this; } SbxValue::~SbxValue() { SetFlag( SbxFlagBits::Write ); // cid#1486004 silence Uncaught exception suppress_fun_call_w_exception(SbxValue::Clear()); } void SbxValue::Clear() { switch( aData.eType ) { case SbxNULL: case SbxEMPTY: case SbxVOID: break; case SbxSTRING: delete aData.pOUString; aData.pOUString = nullptr; break; case SbxOBJECT: if( aData.pObj ) { if( aData.pObj != this ) { SAL_INFO("basic.sbx", "Not at Parent-Prop - otherwise CyclicRef"); SbxVariable *pThisVar = dynamic_cast( this ); bool bParentProp = pThisVar && (pThisVar->GetUserData() & 0xFFFF) == 5345; if ( !bParentProp ) aData.pObj->ReleaseRef(); } aData.pObj = nullptr; } break; case SbxDECIMAL: releaseDecimalPtr( aData.pDecimal ); break; case SbxDATAOBJECT: aData.pData = nullptr; break; default: { SbxValues aEmpty; aEmpty.clear(GetType()); Put( aEmpty ); } } } // Dummy void SbxValue::Broadcast( SfxHintId ) {} //////////////////////////// Readout data // Detect the "right" variables. If it is an object, will be addressed either // the object itself or its default property. // If the variable contain a variable or an object, this will be // addressed. SbxValue* SbxValue::TheRealValue( bool bObjInObjError ) const { SbxValue* p = const_cast(this); for( ;; ) { SbxDataType t = SbxDataType( p->aData.eType & 0x0FFF ); if( t == SbxOBJECT ) { // The block contains an object or a variable SbxObject* pObj = dynamic_cast( p->aData.pObj ); if( pObj ) { // Has the object a default property? SbxVariable* pDflt = pObj->GetDfltProperty(); // If this is an object and contains itself, // we cannot access on it // The old condition to set an error is not correct, // because e.g. a regular variant variable with an object // could be affected if another value should be assigned. // Therefore with flag. if( bObjInObjError && !pDflt && static_cast(pObj)->aData.eType == SbxOBJECT && static_cast(pObj)->aData.pObj == pObj ) { #if !HAVE_FEATURE_SCRIPTING const bool bSuccess = false; #else bool bSuccess = handleToStringForCOMObjects( pObj, p ); #endif if( !bSuccess ) { SetError( ERRCODE_BASIC_BAD_PROP_VALUE ); p = nullptr; } } else if( pDflt ) p = pDflt; break; } // Did we have an array? SbxArray* pArray = dynamic_cast( p->aData.pObj ); if( pArray ) { // When indicated get the parameter SbxArray* pPar = nullptr; SbxVariable* pVar = dynamic_cast( p ); if( pVar ) pPar = pVar->GetParameters(); if( pPar ) { // Did we have a dimensioned array? SbxDimArray* pDimArray = dynamic_cast( p->aData.pObj ); if( pDimArray ) p = pDimArray->Get( pPar ); else p = pArray->Get(pPar->Get(1)->GetInteger()); break; } } // Otherwise guess a SbxValue SbxValue* pVal = dynamic_cast( p->aData.pObj ); if( pVal ) p = pVal; else break; } else break; } return p; } bool SbxValue::Get( SbxValues& rRes ) const { bool bRes = false; ErrCode eOld = GetError(); if( eOld != ERRCODE_NONE ) ResetError(); if( !CanRead() ) { SetError( ERRCODE_BASIC_PROP_WRITEONLY ); rRes.pObj = nullptr; } else { // If an object or a VARIANT is requested, don't search the real values SbxValue* p = const_cast(this); if( rRes.eType != SbxOBJECT && rRes.eType != SbxVARIANT ) p = TheRealValue( true ); if( p ) { p->Broadcast( SfxHintId::BasicDataWanted ); switch( rRes.eType ) { case SbxEMPTY: case SbxVOID: case SbxNULL: break; case SbxVARIANT: rRes = p->aData; break; case SbxINTEGER: rRes.nInteger = ImpGetInteger( &p->aData ); break; case SbxLONG: rRes.nLong = ImpGetLong( &p->aData ); break; case SbxSALINT64: rRes.nInt64 = ImpGetInt64( &p->aData ); break; case SbxSALUINT64: rRes.uInt64 = ImpGetUInt64( &p->aData ); break; case SbxSINGLE: rRes.nSingle = ImpGetSingle( &p->aData ); break; case SbxDOUBLE: rRes.nDouble = ImpGetDouble( &p->aData ); break; case SbxCURRENCY:rRes.nInt64 = ImpGetCurrency( &p->aData ); break; case SbxDECIMAL: rRes.pDecimal = ImpGetDecimal( &p->aData ); break; case SbxDATE: rRes.nDouble = ImpGetDate( &p->aData ); break; case SbxBOOL: rRes.nUShort = sal::static_int_cast< sal_uInt16 >( ImpGetBool( &p->aData ) ); break; case SbxCHAR: rRes.nChar = ImpGetChar( &p->aData ); break; case SbxBYTE: rRes.nByte = ImpGetByte( &p->aData ); break; case SbxUSHORT: rRes.nUShort = ImpGetUShort( &p->aData ); break; case SbxULONG: rRes.nULong = ImpGetULong( &p->aData ); break; case SbxLPSTR: case SbxSTRING: p->aPic = ImpGetString( &p->aData ); rRes.pOUString = &p->aPic; break; case SbxCoreSTRING: p->aPic = ImpGetCoreString( &p->aData ); rRes.pOUString = &p->aPic; break; case SbxINT: rRes.nInt = static_cast(ImpGetLong( &p->aData )); break; case SbxUINT: rRes.nUInt = static_cast(ImpGetULong( &p->aData )); break; case SbxOBJECT: if( p->aData.eType == SbxOBJECT ) rRes.pObj = p->aData.pObj; else { SetError( ERRCODE_BASIC_NO_OBJECT ); rRes.pObj = nullptr; } break; default: if( p->aData.eType == rRes.eType ) rRes = p->aData; else { SetError( ERRCODE_BASIC_CONVERSION ); rRes.pObj = nullptr; } } } else { // Object contained itself SbxDataType eTemp = rRes.eType; rRes.clear(eTemp); } } if( !IsError() ) { bRes = true; if( eOld != ERRCODE_NONE ) SetError( eOld ); } return bRes; } SbxValues SbxValue::Get(SbxDataType t) const { SbxValues aRes(t); Get(aRes); return aRes; } const OUString& SbxValue::GetCoreString() const { SbxValues aRes(SbxCoreSTRING); if( Get( aRes ) ) { const_cast(this)->aToolString = *aRes.pOUString; } else { const_cast(this)->aToolString.clear(); } return aToolString; } OUString SbxValue::GetOUString() const { OUString aResult; SbxValues aRes(SbxSTRING); if( Get( aRes ) ) { aResult = *aRes.pOUString; } return aResult; } //////////////////////////// Write data bool SbxValue::Put( const SbxValues& rVal ) { bool bRes = false; ErrCode eOld = GetError(); if( eOld != ERRCODE_NONE ) ResetError(); if( !CanWrite() ) SetError( ERRCODE_BASIC_PROP_READONLY ); else if( rVal.eType & 0xF000 ) SetError( ERRCODE_BASIC_BAD_ARGUMENT ); else { // If an object is requested, don't search the real values SbxValue* p = this; if( rVal.eType != SbxOBJECT ) p = TheRealValue( false ); // Don't allow an error here if( p ) { if( !p->CanWrite() ) SetError( ERRCODE_BASIC_PROP_READONLY ); else if( p->IsFixed() || p->SetType( static_cast( rVal.eType & 0x0FFF ) ) ) switch( rVal.eType & 0x0FFF ) { case SbxEMPTY: case SbxVOID: case SbxNULL: break; case SbxINTEGER: ImpPutInteger( &p->aData, rVal.nInteger ); break; case SbxLONG: ImpPutLong( &p->aData, rVal.nLong ); break; case SbxSALINT64: ImpPutInt64( &p->aData, rVal.nInt64 ); break; case SbxSALUINT64: ImpPutUInt64( &p->aData, rVal.uInt64 ); break; case SbxSINGLE: ImpPutSingle( &p->aData, rVal.nSingle ); break; case SbxDOUBLE: ImpPutDouble( &p->aData, rVal.nDouble ); break; case SbxCURRENCY: ImpPutCurrency( &p->aData, rVal.nInt64 ); break; case SbxDECIMAL: ImpPutDecimal( &p->aData, rVal.pDecimal ); break; case SbxDATE: ImpPutDate( &p->aData, rVal.nDouble ); break; case SbxBOOL: ImpPutBool( &p->aData, rVal.nInteger ); break; case SbxCHAR: ImpPutChar( &p->aData, rVal.nChar ); break; case SbxBYTE: ImpPutByte( &p->aData, rVal.nByte ); break; case SbxUSHORT: ImpPutUShort( &p->aData, rVal.nUShort ); break; case SbxULONG: ImpPutULong( &p->aData, rVal.nULong ); break; case SbxLPSTR: case SbxSTRING: ImpPutString( &p->aData, rVal.pOUString ); break; case SbxINT: ImpPutLong( &p->aData, static_cast(rVal.nInt) ); break; case SbxUINT: ImpPutULong( &p->aData, static_cast(rVal.nUInt) ); break; case SbxOBJECT: if( !p->IsFixed() || p->aData.eType == SbxOBJECT ) { // is already inside if( p->aData.eType == SbxOBJECT && p->aData.pObj == rVal.pObj ) break; // Delete only the value part! p->SbxValue::Clear(); // real assignment p->aData.pObj = rVal.pObj; // if necessary increment Ref-Count if( p->aData.pObj && p->aData.pObj != p ) { if ( p != this ) { OSL_FAIL( "TheRealValue" ); } SAL_INFO("basic.sbx", "Not at Parent-Prop - otherwise CyclicRef"); SbxVariable *pThisVar = dynamic_cast( this ); bool bParentProp = pThisVar && (pThisVar->GetUserData() & 0xFFFF) == 5345; if ( !bParentProp ) p->aData.pObj->AddFirstRef(); } } else SetError( ERRCODE_BASIC_CONVERSION ); break; default: if( p->aData.eType == rVal.eType ) p->aData = rVal; else { SetError( ERRCODE_BASIC_CONVERSION ); if( !p->IsFixed() ) p->aData.eType = SbxNULL; } } if( !IsError() ) { p->SetModified( true ); p->Broadcast( SfxHintId::BasicDataChanged ); if( eOld != ERRCODE_NONE ) SetError( eOld ); bRes = true; } } } return bRes; } // From 1996-03-28: // Method to execute a pretreatment of the strings at special types. // In particular necessary for BASIC-IDE, so that // the output in the Watch-Window can be written back with PutStringExt, // if Float were declared with ',' as the decimal separator or BOOl // explicit with "TRUE" or "FALSE". // Implementation in ImpConvStringExt (SBXSCAN.CXX) void SbxValue::PutStringExt( const OUString& r ) { // Copy; if it is Unicode convert it immediately OUString aStr( r ); // Identify the own type (not as in Put() with TheRealValue(), // Objects are not handled anyway) SbxDataType eTargetType = SbxDataType( aData.eType & 0x0FFF ); // tinker a Source-Value SbxValues aRes(SbxSTRING); // Only if really something was converted, take the copy, // otherwise take the original (Unicode remains) if( ImpConvStringExt( aStr, eTargetType ) ) aRes.pOUString = &aStr; else aRes.pOUString = const_cast(&r); // #34939: For Strings which contain a number, and if this has a Num-Type, // set a Fixed flag so that the type will not be changed SbxFlagBits nFlags_ = GetFlags(); if( ( eTargetType >= SbxINTEGER && eTargetType <= SbxCURRENCY ) || ( eTargetType >= SbxCHAR && eTargetType <= SbxUINT ) || eTargetType == SbxBOOL ) { SbxValue aVal; aVal.Put( aRes ); if( aVal.IsNumeric() ) SetFlag( SbxFlagBits::Fixed ); } const bool bRet = Put(aRes); // If FIXED resulted in an error, set it back // (UI-Action should not result in an error, but simply fail) if( !bRet ) ResetError(); SetFlags( nFlags_ ); } bool SbxValue::PutBool( bool b ) { SbxValues aRes(SbxBOOL); aRes.nUShort = sal::static_int_cast< sal_uInt16 >(b ? SbxTRUE : SbxFALSE); return Put(aRes); } bool SbxValue::PutEmpty() { bool bRet = SetType( SbxEMPTY ); SetModified( true ); return bRet; } void SbxValue::PutNull() { bool bRet = SetType( SbxNULL ); if( bRet ) SetModified( true ); } // Special decimal methods void SbxValue::PutDecimal( css::bridge::oleautomation::Decimal const & rAutomationDec ) { SbxValue::Clear(); aData.pDecimal = new SbxDecimal( rAutomationDec ); aData.pDecimal->addRef(); aData.eType = SbxDECIMAL; } void SbxValue::fillAutomationDecimal ( css::bridge::oleautomation::Decimal& rAutomationDec ) const { SbxDecimal* pDecimal = GetDecimal(); if( pDecimal != nullptr ) { pDecimal->fillAutomationDecimal( rAutomationDec ); } } bool SbxValue::PutString( const OUString& r ) { SbxValues aRes(SbxSTRING); aRes.pOUString = const_cast(&r); return Put(aRes); } #define PUT( p, e, t, m ) \ bool SbxValue::p( t n ) \ { SbxValues aRes(e); aRes.m = n; return Put(aRes); } void SbxValue::PutDate( double n ) { SbxValues aRes(SbxDATE); aRes.nDouble = n; Put( aRes ); } void SbxValue::PutErr( sal_uInt16 n ) { SbxValues aRes(SbxERROR); aRes.nUShort = n; Put( aRes ); } PUT( PutByte, SbxBYTE, sal_uInt8, nByte ) PUT( PutChar, SbxCHAR, sal_Unicode, nChar ) PUT( PutCurrency, SbxCURRENCY, sal_Int64, nInt64 ) PUT( PutDouble, SbxDOUBLE, double, nDouble ) PUT( PutInteger, SbxINTEGER, sal_Int16, nInteger ) PUT( PutLong, SbxLONG, sal_Int32, nLong ) PUT( PutObject, SbxOBJECT, SbxBase*, pObj ) PUT( PutSingle, SbxSINGLE, float, nSingle ) PUT( PutULong, SbxULONG, sal_uInt32, nULong ) PUT( PutUShort, SbxUSHORT, sal_uInt16, nUShort ) PUT( PutInt64, SbxSALINT64, sal_Int64, nInt64 ) PUT( PutUInt64, SbxSALUINT64, sal_uInt64, uInt64 ) PUT( PutDecimal, SbxDECIMAL, SbxDecimal*, pDecimal ) ////////////////////////// Setting of the data type bool SbxValue::IsFixed() const { return (GetFlags() & SbxFlagBits::Fixed) || ((aData.eType & SbxBYREF) != 0); } // A variable is numeric, if it is EMPTY or really numeric // or if it contains a complete convertible String // #41692, implement it for RTL and Basic-Core separately bool SbxValue::IsNumeric() const { return ImpIsNumeric( /*bOnlyIntntl*/false ); } bool SbxValue::IsNumericRTL() const { return ImpIsNumeric( /*bOnlyIntntl*/true ); } bool SbxValue::ImpIsNumeric( bool bOnlyIntntl ) const { if( !CanRead() ) { SetError( ERRCODE_BASIC_PROP_WRITEONLY ); return false; } // Test downcast!!! if( auto pSbxVar = dynamic_cast( this) ) const_cast(pSbxVar)->Broadcast( SfxHintId::BasicDataWanted ); SbxDataType t = GetType(); if( t == SbxSTRING ) { if( aData.pOUString ) { OUString s( *aData.pOUString ); double n; SbxDataType t2; sal_uInt16 nLen = 0; if( ImpScan( s, n, t2, &nLen, bOnlyIntntl ) == ERRCODE_NONE ) return nLen == s.getLength(); } return false; } else return t == SbxEMPTY || ( t >= SbxINTEGER && t <= SbxCURRENCY ) || ( t >= SbxCHAR && t <= SbxUINT ); } SbxDataType SbxValue::GetType() const { return SbxDataType( aData.eType & 0x0FFF ); } bool SbxValue::SetType( SbxDataType t ) { DBG_ASSERT( !( t & 0xF000 ), "SetType of BYREF|ARRAY is forbidden!" ); if( ( t == SbxEMPTY && aData.eType == SbxVOID ) || ( aData.eType == SbxEMPTY && t == SbxVOID ) ) return true; if( ( t & 0x0FFF ) == SbxVARIANT ) { // Try to set the data type to Variant ResetFlag( SbxFlagBits::Fixed ); if( IsFixed() ) { SetError( ERRCODE_BASIC_CONVERSION ); return false; } t = SbxEMPTY; } if( ( t & 0x0FFF ) == ( aData.eType & 0x0FFF ) ) return true; if( !CanWrite() || IsFixed() ) { SetError( ERRCODE_BASIC_CONVERSION ); return false; } else { // De-allocate potential objects switch( aData.eType ) { case SbxSTRING: delete aData.pOUString; break; case SbxOBJECT: if( aData.pObj && aData.pObj != this ) { SAL_WARN("basic.sbx", "Not at Parent-Prop - otherwise CyclicRef"); SbxVariable *pThisVar = dynamic_cast( this ); sal_uInt32 nSlotId = pThisVar ? pThisVar->GetUserData() & 0xFFFF : 0; DBG_ASSERT( nSlotId != 5345 || pThisVar->GetName() == "Parent", "SID_PARENTOBJECT is not named 'Parent'" ); bool bParentProp = nSlotId == 5345; if ( !bParentProp ) aData.pObj->ReleaseRef(); } break; default: break; } aData.clear(t); } return true; } bool SbxValue::Convert( SbxDataType eTo ) { eTo = SbxDataType( eTo & 0x0FFF ); if( ( aData.eType & 0x0FFF ) == eTo ) return true; if( !CanWrite() ) return false; if( eTo == SbxVARIANT ) { // Trial to set the data type to Variant ResetFlag( SbxFlagBits::Fixed ); if( IsFixed() ) { SetError( ERRCODE_BASIC_CONVERSION ); return false; } else return true; } // Converting from null doesn't work. Once null, always null! if( aData.eType == SbxNULL ) { SetError( ERRCODE_BASIC_CONVERSION ); return false; } // Conversion of the data: SbxValues aNew(eTo); if( Get( aNew ) ) { // The data type could be converted. It ends here with fixed elements, // because the data had not to be taken over if( !IsFixed() ) { SetType( eTo ); Put( aNew ); SetModified( true ); } return true; } else return false; } ////////////////////////////////// Calculating bool SbxValue::Compute( SbxOperator eOp, const SbxValue& rOp ) { #if !HAVE_FEATURE_SCRIPTING const bool bVBAInterop = false; #else bool bVBAInterop = SbiRuntime::isVBAEnabled(); #endif SbxDataType eThisType = GetType(); SbxDataType eOpType = rOp.GetType(); ErrCode eOld = GetError(); if( eOld != ERRCODE_NONE ) ResetError(); if( !CanWrite() ) SetError( ERRCODE_BASIC_PROP_READONLY ); else if( !rOp.CanRead() ) SetError( ERRCODE_BASIC_PROP_WRITEONLY ); // Special rule 1: If one operand is null, the result is null else if( eThisType == SbxNULL || eOpType == SbxNULL ) SetType( SbxNULL ); else { SbxValues aL, aR; bool bDecimal = false; if( bVBAInterop && ( ( eThisType == SbxSTRING && eOpType != SbxSTRING && eOpType != SbxEMPTY ) || ( eThisType != SbxSTRING && eThisType != SbxEMPTY && eOpType == SbxSTRING ) ) && ( eOp == SbxMUL || eOp == SbxDIV || eOp == SbxPLUS || eOp == SbxMINUS ) ) { goto Lbl_OpIsDouble; } else if( eThisType == SbxSTRING || eOp == SbxCAT || ( bVBAInterop && ( eOpType == SbxSTRING ) && ( eOp == SbxPLUS ) ) ) { if( eOp == SbxCAT || eOp == SbxPLUS ) { // From 1999-11-5, keep OUString in mind aL.eType = aR.eType = SbxSTRING; rOp.Get( aR ); // From 1999-12-8, #70399: Here call GetType() again, Get() can change the type! if( rOp.GetType() == SbxEMPTY ) goto Lbl_OpIsEmpty; // concatenate empty, *this stays lhs as result Get( aL ); // #30576: To begin with test, if the conversion worked if( aL.pOUString != nullptr && aR.pOUString != nullptr ) { // tdf#108039: catch possible bad_alloc try { *aL.pOUString += *aR.pOUString; } catch (const std::bad_alloc&) { SetError(ERRCODE_BASIC_MATH_OVERFLOW); } } // Not even Left OK? else if( aL.pOUString == nullptr ) { aL.pOUString = new OUString(); } } else SetError( ERRCODE_BASIC_CONVERSION ); } else if( eOpType == SbxSTRING && rOp.IsFixed() ) { // Numeric: there is no String allowed on the right side SetError( ERRCODE_BASIC_CONVERSION ); // falls all the way out } else if( ( eOp >= SbxIDIV && eOp <= SbxNOT ) || eOp == SbxMOD ) { if( GetType() == eOpType ) { if( GetType() == SbxSALUINT64 || GetType() == SbxSALINT64 || GetType() == SbxCURRENCY || GetType() == SbxULONG ) aL.eType = aR.eType = GetType(); // tdf#145960 - return type of boolean operators should be of type boolean else if ( eOpType == SbxBOOL && eOp != SbxMOD && eOp != SbxIDIV ) aL.eType = aR.eType = SbxBOOL; else aL.eType = aR.eType = SbxLONG; } else aL.eType = aR.eType = SbxLONG; if( rOp.Get( aR ) ) // re-do Get after type assigns above { if( Get( aL ) ) switch( eOp ) { /* TODO: For SbxEMPTY operands with boolean operators use * the VBA Nothing definition of Comparing Nullable Types? * https://docs.microsoft.com/en-us/dotnet/visual-basic/programming-guide/language-features/data-types/nullable-value-types */ /* TODO: it is unclear yet whether this also should be done * for the non-bVBAInterop case or not, or at all, consider * user defined spreadsheet functions where an empty cell * is SbxEMPTY and usually is treated as 0 zero or "" empty * string. */ case SbxIDIV: if( aL.eType == SbxCURRENCY ) if( !aR.nInt64 ) SetError( ERRCODE_BASIC_ZERODIV ); else { aL.nInt64 /= aR.nInt64; aL.nInt64 *= CURRENCY_FACTOR; } else if( aL.eType == SbxSALUINT64 ) if( !aR.uInt64 ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.uInt64 /= aR.uInt64; else if( aL.eType == SbxSALINT64 ) if( !aR.nInt64 ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.nInt64 /= aR.nInt64; else if( aL.eType == SbxLONG ) if( !aR.nLong ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.nLong /= aR.nLong; else if( !aR.nULong ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.nULong /= aR.nULong; break; case SbxMOD: if( aL.eType == SbxCURRENCY || aL.eType == SbxSALINT64 ) if( !aR.nInt64 ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.nInt64 %= aR.nInt64; else if( aL.eType == SbxSALUINT64 ) if( !aR.uInt64 ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.uInt64 %= aR.uInt64; else if( aL.eType == SbxLONG ) if( !aR.nLong ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.nLong %= aR.nLong; else if( !aR.nULong ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.nULong %= aR.nULong; break; case SbxAND: if( aL.eType != SbxLONG && aL.eType != SbxULONG ) aL.nInt64 &= aR.nInt64; else aL.nLong &= aR.nLong; break; case SbxOR: if( aL.eType != SbxLONG && aL.eType != SbxULONG ) aL.nInt64 |= aR.nInt64; else aL.nLong |= aR.nLong; break; case SbxXOR: if( aL.eType != SbxLONG && aL.eType != SbxULONG ) aL.nInt64 ^= aR.nInt64; else aL.nLong ^= aR.nLong; break; case SbxEQV: if( aL.eType != SbxLONG && aL.eType != SbxULONG ) aL.nInt64 = (aL.nInt64 & aR.nInt64) | (~aL.nInt64 & ~aR.nInt64); else aL.nLong = (aL.nLong & aR.nLong) | (~aL.nLong & ~aR.nLong); break; case SbxIMP: if( aL.eType != SbxLONG && aL.eType != SbxULONG ) aL.nInt64 = ~aL.nInt64 | aR.nInt64; else aL.nLong = ~aL.nLong | aR.nLong; break; case SbxNOT: if( aL.eType != SbxLONG && aL.eType != SbxULONG ) { if ( aL.eType != SbxBOOL ) aL.nInt64 = ~aL.nInt64; else aL.nLong = ~aL.nLong; } else aL.nLong = ~aL.nLong; break; default: break; } } } else if( ( GetType() == SbxDECIMAL || rOp.GetType() == SbxDECIMAL ) && ( eOp == SbxMUL || eOp == SbxDIV || eOp == SbxPLUS || eOp == SbxMINUS || eOp == SbxNEG ) ) { aL.eType = aR.eType = SbxDECIMAL; bDecimal = true; if( rOp.Get( aR ) && Get( aL ) ) { if( aL.pDecimal && aR.pDecimal ) { bool bOk = true; switch( eOp ) { case SbxMUL: bOk = ( *(aL.pDecimal) *= *(aR.pDecimal) ); break; case SbxDIV: if( aR.pDecimal->isZero() ) SetError( ERRCODE_BASIC_ZERODIV ); else bOk = ( *(aL.pDecimal) /= *(aR.pDecimal) ); break; case SbxPLUS: bOk = ( *(aL.pDecimal) += *(aR.pDecimal) ); break; case SbxMINUS: bOk = ( *(aL.pDecimal) -= *(aR.pDecimal) ); break; case SbxNEG: bOk = ( aL.pDecimal->neg() ); break; default: SetError( ERRCODE_BASIC_BAD_ARGUMENT ); } if( !bOk ) SetError( ERRCODE_BASIC_MATH_OVERFLOW ); } else { SetError( ERRCODE_BASIC_CONVERSION ); } } } else if( GetType() == SbxCURRENCY || rOp.GetType() == SbxCURRENCY ) { aL.eType = SbxCURRENCY; aR.eType = SbxCURRENCY; if( rOp.Get( aR ) ) { if( Get( aL ) ) switch( eOp ) { case SbxMUL: { // first overflow check: see if product will fit - test real value of product (hence 2 curr factors) double dTest = static_cast(aL.nInt64) * static_cast(aR.nInt64) / double(CURRENCY_FACTOR_SQUARE); if( dTest < SbxMINCURR || SbxMAXCURR < dTest) { aL.nInt64 = SAL_MAX_INT64; if( dTest < SbxMINCURR ) aL.nInt64 = SAL_MIN_INT64; SetError( ERRCODE_BASIC_MATH_OVERFLOW ); break; } // second overflow check: see if unscaled product overflows - if so use doubles dTest = static_cast(aL.nInt64) * static_cast(aR.nInt64); if( !(o3tl::convertsToAtLeast(dTest, SAL_MIN_INT64) && o3tl::convertsToAtMost(dTest, SAL_MAX_INT64))) { aL.nInt64 = static_cast( dTest / double(CURRENCY_FACTOR) ); break; } // precise calc: multiply then scale back (move decimal pt) aL.nInt64 *= aR.nInt64; aL.nInt64 /= CURRENCY_FACTOR; break; } case SbxDIV: { if( !aR.nInt64 ) { SetError( ERRCODE_BASIC_ZERODIV ); break; } // first overflow check: see if quotient will fit - calc real value of quotient (curr factors cancel) double dTest = static_cast(aL.nInt64) / static_cast(aR.nInt64); if( dTest < SbxMINCURR || SbxMAXCURR < dTest) { SetError( ERRCODE_BASIC_MATH_OVERFLOW ); break; } // second overflow check: see if scaled dividend overflows - if so use doubles dTest = static_cast(aL.nInt64) * double(CURRENCY_FACTOR); if( !(o3tl::convertsToAtLeast(dTest, SAL_MIN_INT64) && o3tl::convertsToAtMost(dTest, SAL_MAX_INT64))) { aL.nInt64 = static_cast(dTest / static_cast(aR.nInt64)); break; } // precise calc: scale (move decimal pt) then divide aL.nInt64 *= CURRENCY_FACTOR; aL.nInt64 /= aR.nInt64; break; } case SbxPLUS: { double dTest = ( static_cast(aL.nInt64) + static_cast(aR.nInt64) ) / double(CURRENCY_FACTOR); if( dTest < SbxMINCURR || SbxMAXCURR < dTest) { SetError( ERRCODE_BASIC_MATH_OVERFLOW ); break; } aL.nInt64 += aR.nInt64; break; } case SbxMINUS: { double dTest = ( static_cast(aL.nInt64) - static_cast(aR.nInt64) ) / double(CURRENCY_FACTOR); if( dTest < SbxMINCURR || SbxMAXCURR < dTest) { SetError( ERRCODE_BASIC_MATH_OVERFLOW ); break; } aL.nInt64 -= aR.nInt64; break; } case SbxNEG: aL.nInt64 = -aL.nInt64; break; default: SetError( ERRCODE_BASIC_BAD_ARGUMENT ); } } } else Lbl_OpIsDouble: { // other types and operators including Date, Double and Single aL.eType = aR.eType = SbxDOUBLE; if( rOp.Get( aR ) ) { if( Get( aL ) ) { switch( eOp ) { case SbxEXP: aL.nDouble = pow( aL.nDouble, aR.nDouble ); break; case SbxMUL: aL.nDouble *= aR.nDouble; break; case SbxDIV: if( !aR.nDouble ) SetError( ERRCODE_BASIC_ZERODIV ); else aL.nDouble /= aR.nDouble; break; case SbxPLUS: aL.nDouble += aR.nDouble; break; case SbxMINUS: aL.nDouble -= aR.nDouble; break; case SbxNEG: aL.nDouble = -aL.nDouble; break; default: SetError( ERRCODE_BASIC_BAD_ARGUMENT ); } // Date with "+" or "-" needs special handling that // forces the Date type. If the operation is '+' the // result is always a Date, if '-' the result is only // a Date if one of lhs or rhs ( but not both ) is already // a Date if( GetType() == SbxDATE || rOp.GetType() == SbxDATE ) { if( eOp == SbxPLUS || ( ( eOp == SbxMINUS ) && ( GetType() != rOp.GetType() ) ) ) aL.eType = SbxDATE; } } } } if( !IsError() ) Put( aL ); if( bDecimal ) { releaseDecimalPtr( aL.pDecimal ); releaseDecimalPtr( aR.pDecimal ); } } Lbl_OpIsEmpty: bool bRes = !IsError(); if( bRes && eOld != ERRCODE_NONE ) SetError( eOld ); return bRes; } // The comparison routine deliver TRUE or FALSE. bool SbxValue::Compare( SbxOperator eOp, const SbxValue& rOp ) const { #if !HAVE_FEATURE_SCRIPTING const bool bVBAInterop = false; #else bool bVBAInterop = SbiRuntime::isVBAEnabled(); #endif bool bRes = false; ErrCode eOld = GetError(); if( eOld != ERRCODE_NONE ) ResetError(); if( !CanRead() || !rOp.CanRead() ) SetError( ERRCODE_BASIC_PROP_WRITEONLY ); else if( GetType() == SbxNULL && rOp.GetType() == SbxNULL && !bVBAInterop ) { bRes = true; } else if( GetType() == SbxEMPTY && rOp.GetType() == SbxEMPTY ) bRes = !bVBAInterop || ( eOp == SbxEQ ); // Special rule 1: If an operand is null, the result is FALSE else if( GetType() == SbxNULL || rOp.GetType() == SbxNULL ) bRes = false; // Special rule 2: If both are variant and one is numeric // and the other is a String, num is < str else if( !IsFixed() && !rOp.IsFixed() && ( rOp.GetType() == SbxSTRING && GetType() != SbxSTRING && IsNumeric() ) && !bVBAInterop ) bRes = eOp == SbxLT || eOp == SbxLE || eOp == SbxNE; else if( !IsFixed() && !rOp.IsFixed() && ( GetType() == SbxSTRING && rOp.GetType() != SbxSTRING && rOp.IsNumeric() ) && !bVBAInterop ) bRes = eOp == SbxGT || eOp == SbxGE || eOp == SbxNE; else { SbxValues aL, aR; // If one of the operands is a String, // a String comparing take place if( GetType() == SbxSTRING || rOp.GetType() == SbxSTRING ) { aL.eType = aR.eType = SbxSTRING; if( Get( aL ) && rOp.Get( aR ) ) switch( eOp ) { case SbxEQ: bRes = ( *aL.pOUString == *aR.pOUString ); break; case SbxNE: bRes = ( *aL.pOUString != *aR.pOUString ); break; case SbxLT: bRes = ( *aL.pOUString < *aR.pOUString ); break; case SbxGT: bRes = ( *aL.pOUString > *aR.pOUString ); break; case SbxLE: bRes = ( *aL.pOUString <= *aR.pOUString ); break; case SbxGE: bRes = ( *aL.pOUString >= *aR.pOUString ); break; default: SetError( ERRCODE_BASIC_BAD_ARGUMENT ); } } // From 1995-12-19: If SbxSINGLE participate, then convert to SINGLE, // otherwise it shows a numeric error else if( GetType() == SbxSINGLE || rOp.GetType() == SbxSINGLE ) { aL.eType = aR.eType = SbxSINGLE; if( Get( aL ) && rOp.Get( aR ) ) switch( eOp ) { case SbxEQ: bRes = ( aL.nSingle == aR.nSingle ); break; case SbxNE: bRes = ( aL.nSingle != aR.nSingle ); break; case SbxLT: bRes = ( aL.nSingle < aR.nSingle ); break; case SbxGT: bRes = ( aL.nSingle > aR.nSingle ); break; case SbxLE: bRes = ( aL.nSingle <= aR.nSingle ); break; case SbxGE: bRes = ( aL.nSingle >= aR.nSingle ); break; default: SetError( ERRCODE_BASIC_BAD_ARGUMENT ); } } else if( GetType() == SbxDECIMAL && rOp.GetType() == SbxDECIMAL ) { aL.eType = aR.eType = SbxDECIMAL; Get( aL ); rOp.Get( aR ); if( aL.pDecimal && aR.pDecimal ) { SbxDecimal::CmpResult eRes = compare( *aL.pDecimal, *aR.pDecimal ); switch( eOp ) { case SbxEQ: bRes = ( eRes == SbxDecimal::CmpResult::EQ ); break; case SbxNE: bRes = ( eRes != SbxDecimal::CmpResult::EQ ); break; case SbxLT: bRes = ( eRes == SbxDecimal::CmpResult::LT ); break; case SbxGT: bRes = ( eRes == SbxDecimal::CmpResult::GT ); break; case SbxLE: bRes = ( eRes != SbxDecimal::CmpResult::GT ); break; case SbxGE: bRes = ( eRes != SbxDecimal::CmpResult::LT ); break; default: SetError( ERRCODE_BASIC_BAD_ARGUMENT ); } } else { SetError( ERRCODE_BASIC_CONVERSION ); } releaseDecimalPtr( aL.pDecimal ); releaseDecimalPtr( aR.pDecimal ); } // Everything else comparing on a SbxDOUBLE-Basis else { aL.eType = aR.eType = SbxDOUBLE; bool bGetL = Get( aL ); bool bGetR = rOp.Get( aR ); if( bGetL && bGetR ) switch( eOp ) { case SbxEQ: bRes = ( aL.nDouble == aR.nDouble ); break; case SbxNE: bRes = ( aL.nDouble != aR.nDouble ); break; case SbxLT: bRes = ( aL.nDouble < aR.nDouble ); break; case SbxGT: bRes = ( aL.nDouble > aR.nDouble ); break; case SbxLE: bRes = ( aL.nDouble <= aR.nDouble ); break; case SbxGE: bRes = ( aL.nDouble >= aR.nDouble ); break; default: SetError( ERRCODE_BASIC_BAD_ARGUMENT ); } // at least one value was got // if this is VBA then a conversion error for one // side will yield a false result of an equality test else if ( bGetR || bGetL ) { if ( bVBAInterop && eOp == SbxEQ && GetError() == ERRCODE_BASIC_CONVERSION ) { #ifndef IOS ResetError(); bRes = false; #endif } } } } if( eOld != ERRCODE_NONE ) SetError( eOld ); return bRes; } ///////////////////////////// Reading/Writing bool SbxValue::LoadData( SvStream& r, sal_uInt16 ) { // #TODO see if these types are really dumped to any stream // more than likely this is functionality used in the binfilter alone SbxValue::Clear(); sal_uInt16 nType; r.ReadUInt16( nType ); aData.eType = SbxDataType( nType ); switch( nType ) { case SbxBOOL: case SbxINTEGER: r.ReadInt16( aData.nInteger ); break; case SbxLONG: r.ReadInt32( aData.nLong ); break; case SbxSINGLE: { // Floats as ASCII OUString aVal = read_uInt16_lenPrefixed_uInt8s_ToOUString(r, RTL_TEXTENCODING_ASCII_US); double d; SbxDataType t; if( ImpScan( aVal, d, t, nullptr, !LibreOffice6FloatingPointMode() ) != ERRCODE_NONE || t == SbxDOUBLE ) { aData.nSingle = 0.0F; return false; } aData.nSingle = static_cast(d); break; } case SbxDATE: case SbxDOUBLE: { // Floats as ASCII OUString aVal = read_uInt16_lenPrefixed_uInt8s_ToOUString(r, RTL_TEXTENCODING_ASCII_US); SbxDataType t; if( ImpScan( aVal, aData.nDouble, t, nullptr, !LibreOffice6FloatingPointMode() ) != ERRCODE_NONE ) { aData.nDouble = 0.0; return false; } break; } case SbxSALINT64: r.ReadInt64(aData.nInt64); break; case SbxSALUINT64: r.ReadUInt64( aData.uInt64 ); break; case SbxCURRENCY: { sal_uInt32 tmpHi = 0; sal_uInt32 tmpLo = 0; r.ReadUInt32( tmpHi ).ReadUInt32( tmpLo ); aData.nInt64 = (static_cast(tmpHi) << 32); aData.nInt64 |= static_cast(tmpLo); break; } case SbxSTRING: { OUString aVal = read_uInt16_lenPrefixed_uInt8s_ToOUString(r, RTL_TEXTENCODING_ASCII_US); if( !aVal.isEmpty() ) aData.pOUString = new OUString( aVal ); else aData.pOUString = nullptr; // JSM 1995-09-22 break; } case SbxERROR: case SbxUSHORT: r.ReadUInt16( aData.nUShort ); break; case SbxOBJECT: { sal_uInt8 nMode; r.ReadUChar( nMode ); switch( nMode ) { case 0: aData.pObj = nullptr; break; case 1: { auto ref = SbxBase::Load( r ); aData.pObj = ref.get(); // if necessary increment Ref-Count if (aData.pObj) aData.pObj->AddFirstRef(); return ( aData.pObj != nullptr ); } case 2: aData.pObj = this; break; } break; } case SbxCHAR: { char c; r.ReadChar( c ); aData.nChar = c; break; } case SbxBYTE: r.ReadUChar( aData.nByte ); break; case SbxULONG: r.ReadUInt32( aData.nULong ); break; case SbxINT: { sal_uInt8 n; r.ReadUChar( n ); // Match the Int on this system? if( n > SAL_TYPES_SIZEOFINT ) { r.ReadInt32( aData.nLong ); aData.eType = SbxLONG; } else { sal_Int32 nInt; r.ReadInt32( nInt ); aData.nInt = nInt; } break; } case SbxUINT: { sal_uInt8 n; r.ReadUChar( n ); // Match the UInt on this system? if( n > SAL_TYPES_SIZEOFINT ) { r.ReadUInt32( aData.nULong ); aData.eType = SbxULONG; } else { sal_uInt32 nUInt; r.ReadUInt32( nUInt ); aData.nUInt = nUInt; } break; } case SbxEMPTY: case SbxNULL: case SbxVOID: break; case SbxDATAOBJECT: r.ReadInt32( aData.nLong ); break; // #78919 For backwards compatibility case SbxWSTRING: case SbxWCHAR: break; default: aData.clear(SbxNULL); ResetFlag(SbxFlagBits::Fixed); SAL_WARN( "basic.sbx", "Loaded a non-supported data type" ); return false; } return true; } std::pair SbxValue::StoreData( SvStream& r ) const { sal_uInt16 nType = sal::static_int_cast< sal_uInt16 >(aData.eType); r.WriteUInt16( nType ); switch( nType & 0x0FFF ) { case SbxBOOL: case SbxINTEGER: r.WriteInt16( aData.nInteger ); break; case SbxLONG: r.WriteInt32( aData.nLong ); break; case SbxDATE: // #49935: Save as double, otherwise an error during the read in const_cast(this)->aData.eType = static_cast( ( nType & 0xF000 ) | SbxDOUBLE ); write_uInt16_lenPrefixed_uInt8s_FromOUString(r, GetCoreString(), RTL_TEXTENCODING_ASCII_US); const_cast(this)->aData.eType = static_cast(nType); break; case SbxSINGLE: case SbxDOUBLE: write_uInt16_lenPrefixed_uInt8s_FromOUString(r, GetCoreString(), RTL_TEXTENCODING_ASCII_US); break; case SbxSALUINT64: case SbxSALINT64: // see comment in SbxValue::StoreData r.WriteUInt64( aData.uInt64 ); break; case SbxCURRENCY: { sal_Int32 tmpHi = ( (aData.nInt64 >> 32) & 0xFFFFFFFF ); sal_Int32 tmpLo = static_cast(aData.nInt64); r.WriteInt32( tmpHi ).WriteInt32( tmpLo ); break; } case SbxSTRING: if( aData.pOUString ) { write_uInt16_lenPrefixed_uInt8s_FromOUString(r, *aData.pOUString, RTL_TEXTENCODING_ASCII_US); } else { write_uInt16_lenPrefixed_uInt8s_FromOUString(r, std::u16string_view(), RTL_TEXTENCODING_ASCII_US); } break; case SbxERROR: case SbxUSHORT: r.WriteUInt16( aData.nUShort ); break; case SbxOBJECT: // to save itself as Objectptr does not work! if( aData.pObj ) { if( dynamic_cast( aData.pObj) != this ) { r.WriteUChar( 1 ); return aData.pObj->Store( r ); } else r.WriteUChar( 2 ); } else r.WriteUChar( 0 ); break; case SbxCHAR: { char c = sal::static_int_cast< char >(aData.nChar); r.WriteChar( c ); break; } case SbxBYTE: r.WriteUChar( aData.nByte ); break; case SbxULONG: r.WriteUInt32( aData.nULong ); break; case SbxINT: { r.WriteUChar( SAL_TYPES_SIZEOFINT ).WriteInt32( aData.nInt ); break; } case SbxUINT: { r.WriteUChar( SAL_TYPES_SIZEOFINT ).WriteUInt32( aData.nUInt ); break; } case SbxEMPTY: case SbxNULL: case SbxVOID: break; case SbxDATAOBJECT: r.WriteInt32( aData.nLong ); break; // #78919 For backwards compatibility case SbxWSTRING: case SbxWCHAR: break; default: SAL_WARN( "basic.sbx", "Saving a non-supported data type" ); return { false, 0 }; } return { true, B_IMG_VERSION_12 }; } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */