/************************************************************************* * * OpenOffice.org - a multi-platform office productivity suite * * $RCSfile: tdmgr.cxx,v $ * * $Revision: 1.14 $ * * last change: $Author: kz $ $Date: 2007-05-09 13:26:19 $ * * The Contents of this file are made available subject to * the terms of GNU Lesser General Public License Version 2.1. * * * GNU Lesser General Public License Version 2.1 * ============================================= * Copyright 2005 by Sun Microsystems, Inc. * 901 San Antonio Road, Palo Alto, CA 94303, USA * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License version 2.1, as published by the Free Software Foundation. * * This library 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 for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, * MA 02111-1307 USA * ************************************************************************/ // MARKER(update_precomp.py): autogen include statement, do not remove #include "precompiled_cppuhelper.hxx" #ifndef INCLUDED_SAL_ALLOCA_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "com/sun/star/uno/RuntimeException.hpp" #include "boost/scoped_array.hpp" using namespace ::rtl; using namespace ::com::sun::star; using namespace ::com::sun::star::uno; using namespace ::com::sun::star::reflection; namespace cppu { static typelib_TypeDescription * createCTD( Reference< container::XHierarchicalNameAccess > const & access, const Reference< XTypeDescription > & xType ); //================================================================================================== inline static sal_Int64 coerceToInt64( const Any & rVal ) { switch (rVal.getValueTypeClass()) { case TypeClass_CHAR: return *(sal_Unicode *)rVal.getValue(); case TypeClass_BOOLEAN: return (*(sal_Bool *)rVal.getValue() ? 1 : 0); case TypeClass_BYTE: return *(sal_Int8 *)rVal.getValue(); case TypeClass_SHORT: return *(sal_Int16 *)rVal.getValue(); case TypeClass_UNSIGNED_SHORT: return *(sal_uInt16 *)rVal.getValue(); case TypeClass_LONG: return *(sal_Int32 *)rVal.getValue(); case TypeClass_UNSIGNED_LONG: return *(sal_uInt32 *)rVal.getValue(); case TypeClass_HYPER: return *(sal_Int64 *)rVal.getValue(); case TypeClass_UNSIGNED_HYPER: return *(sal_uInt64 *)rVal.getValue(); case TypeClass_ENUM: return *(int *)rVal.getValue(); default: OSL_ASSERT(false); return 0; } } //================================================================================================== inline static typelib_TypeDescription * createCTD( const Reference< XUnionTypeDescription > & xType ) { typelib_TypeDescription * pRet = 0; if (xType.is()) { OUString aTypeName( xType->getName() ); // discriminant type Reference< XTypeDescription > xDiscrTD( xType->getDiscriminantType() ); OUString aDiscrTypeName( xDiscrTD->getName() ); typelib_TypeDescriptionReference * pDiscrTypeRef = 0; typelib_typedescriptionreference_new( &pDiscrTypeRef, (typelib_TypeClass)xDiscrTD->getTypeClass(), aDiscrTypeName.pData ); // default member type Reference< XTypeDescription > xDefaultMemberTD( xType->getDefaultMemberType() ); OUString aDefMemberTypeName( xDefaultMemberTD->getName() ); typelib_TypeDescriptionReference * pDefMemberTypeRef = 0; typelib_typedescriptionreference_new( &pDefMemberTypeRef, (typelib_TypeClass)xDefaultMemberTD->getTypeClass(), aDefMemberTypeName.pData ); // init array Sequence< Any > aDiscriminants( xType->getDiscriminants() ); Sequence< Reference< XTypeDescription > > aMemberTypes( xType->getMemberTypes() ); Sequence< OUString > aMemberNames( xType->getMemberNames() ); sal_Int32 nMembers = aDiscriminants.getLength(); OSL_ASSERT( nMembers == aMemberNames.getLength() && nMembers == aMemberTypes.getLength() ); const Any * pDiscriminants = aDiscriminants.getConstArray(); const Reference< XTypeDescription > * pMemberTypes = aMemberTypes.getConstArray(); const OUString * pMemberNames = aMemberNames.getConstArray(); typelib_Union_Init * pMembers = (typelib_Union_Init *)alloca( nMembers * sizeof(typelib_Union_Init) ); sal_Int32 nPos; for ( nPos = nMembers; nPos--; ) { typelib_Union_Init & rEntry = pMembers[nPos]; // member discriminant rEntry.nDiscriminant = coerceToInt64( pDiscriminants[nPos] ); // member type OUString aMemberTypeName( pMemberTypes[nPos]->getName() ); rEntry.pTypeRef = 0; typelib_typedescriptionreference_new( &rEntry.pTypeRef, (typelib_TypeClass)pMemberTypes[nPos]->getTypeClass(), aMemberTypeName.pData ); // member name rEntry.pMemberName = pMemberNames[nPos].pData; } typelib_typedescription_newUnion( &pRet, aTypeName.pData, pDiscrTypeRef, coerceToInt64( xType->getDefaultDiscriminant() ), pDefMemberTypeRef, nMembers, pMembers ); for ( nPos = nMembers; nPos--; ) { typelib_typedescriptionreference_release( pMembers[nPos].pTypeRef ); } typelib_typedescriptionreference_release( pDiscrTypeRef ); typelib_typedescriptionreference_release( pDefMemberTypeRef ); } return pRet; } //================================================================================================== inline static typelib_TypeDescription * createCTD( const Reference< XCompoundTypeDescription > & xType ) { typelib_TypeDescription * pRet = 0; if (xType.is()) { typelib_TypeDescription * pBaseType = createCTD( Reference< XCompoundTypeDescription >::query( xType->getBaseType() ) ); if (pBaseType) typelib_typedescription_register( &pBaseType ); // construct member init array const Sequence > & rMemberTypes = xType->getMemberTypes(); const Sequence< OUString > & rMemberNames = xType->getMemberNames(); const Reference< XTypeDescription > * pMemberTypes = rMemberTypes.getConstArray(); const OUString * pMemberNames = rMemberNames.getConstArray(); sal_Int32 nMembers = rMemberTypes.getLength(); OSL_ENSURE( nMembers == rMemberNames.getLength(), "### lens differ!" ); OUString aTypeName( xType->getName() ); typelib_CompoundMember_Init * pMemberInits = (typelib_CompoundMember_Init *)alloca( sizeof(typelib_CompoundMember_Init) * nMembers ); sal_Int32 nPos; for ( nPos = nMembers; nPos--; ) { typelib_CompoundMember_Init & rInit = pMemberInits[nPos]; rInit.eTypeClass = (typelib_TypeClass)pMemberTypes[nPos]->getTypeClass(); OUString aMemberTypeName( pMemberTypes[nPos]->getName() ); rtl_uString_acquire( rInit.pTypeName = aMemberTypeName.pData ); // string is held by rMemberNames rInit.pMemberName = pMemberNames[nPos].pData; } typelib_typedescription_new( &pRet, (typelib_TypeClass)xType->getTypeClass(), aTypeName.pData, (pBaseType ? pBaseType->pWeakRef : 0), nMembers, pMemberInits ); // cleanup for ( nPos = nMembers; nPos--; ) { rtl_uString_release( pMemberInits[nPos].pTypeName ); } if (pBaseType) typelib_typedescription_release( pBaseType ); } return pRet; } //================================================================================================== inline static typelib_TypeDescription * createCTD( Reference< container::XHierarchicalNameAccess > const & access, const Reference< XStructTypeDescription > & xType ) { typelib_TypeDescription * pRet = 0; if (xType.is() && xType->getTypeParameters().getLength() == 0) { typelib_TypeDescription * pBaseType = createCTD( access, xType->getBaseType() ); if (pBaseType) typelib_typedescription_register( &pBaseType ); // construct member init array const Sequence > & rMemberTypes = xType->getMemberTypes(); const Sequence< OUString > & rMemberNames = xType->getMemberNames(); const Reference< XTypeDescription > * pMemberTypes = rMemberTypes.getConstArray(); const OUString * pMemberNames = rMemberNames.getConstArray(); sal_Int32 nMembers = rMemberTypes.getLength(); OSL_ENSURE( nMembers == rMemberNames.getLength(), "### lens differ!" ); OUString aTypeName( xType->getName() ); typelib_StructMember_Init * pMemberInits = (typelib_StructMember_Init *)alloca( sizeof(typelib_StructMember_Init) * nMembers ); Sequence< Reference< XTypeDescription > > templateMemberTypes; sal_Int32 i = aTypeName.indexOf('<'); if (i >= 0) { Reference< XStructTypeDescription > templateDesc( access->getByHierarchicalName(aTypeName.copy(0, i)), UNO_QUERY_THROW); OSL_ASSERT( templateDesc->getTypeParameters().getLength() == xType->getTypeArguments().getLength()); templateMemberTypes = templateDesc->getMemberTypes(); OSL_ASSERT(templateMemberTypes.getLength() == nMembers); } sal_Int32 nPos; for ( nPos = nMembers; nPos--; ) { typelib_StructMember_Init & rInit = pMemberInits[nPos]; rInit.aBase.eTypeClass = (typelib_TypeClass)pMemberTypes[nPos]->getTypeClass(); OUString aMemberTypeName( pMemberTypes[nPos]->getName() ); rtl_uString_acquire( rInit.aBase.pTypeName = aMemberTypeName.pData ); // string is held by rMemberNames rInit.aBase.pMemberName = pMemberNames[nPos].pData; rInit.bParameterizedType = templateMemberTypes.getLength() != 0 && (templateMemberTypes[nPos]->getTypeClass() == TypeClass_UNKNOWN); } typelib_typedescription_newStruct( &pRet, aTypeName.pData, (pBaseType ? pBaseType->pWeakRef : 0), nMembers, pMemberInits ); // cleanup for ( nPos = nMembers; nPos--; ) { rtl_uString_release( pMemberInits[nPos].aBase.pTypeName ); } if (pBaseType) typelib_typedescription_release( pBaseType ); } return pRet; } //================================================================================================== inline static typelib_TypeDescription * createCTD( const Reference< XInterfaceAttributeTypeDescription > & xAttribute ) { typelib_TypeDescription * pRet = 0; if (xAttribute.is()) { OUString aMemberName( xAttribute->getName() ); Reference< XTypeDescription > xType( xAttribute->getType() ); OUString aMemberTypeName( xType->getName() ); typelib_typedescription_newInterfaceAttribute( (typelib_InterfaceAttributeTypeDescription **)&pRet, xAttribute->getPosition(), aMemberName.pData, // name (typelib_TypeClass)xType->getTypeClass(), aMemberTypeName.pData, // type name xAttribute->isReadOnly() ); } return pRet; } //================================================================================================== static typelib_TypeDescription * createCTD( const Reference< XInterfaceMethodTypeDescription > & xMethod ) { typelib_TypeDescription * pRet = 0; if (xMethod.is()) { Reference< XTypeDescription > xReturnType( xMethod->getReturnType() ); // init all params const Sequence > & rParams = xMethod->getParameters(); const Reference< XMethodParameter > * pParams = rParams.getConstArray(); sal_Int32 nParams = rParams.getLength(); typelib_Parameter_Init * pParamInit = (typelib_Parameter_Init *)alloca( sizeof(typelib_Parameter_Init) * nParams ); sal_Int32 nPos; for ( nPos = nParams; nPos--; ) { const Reference< XMethodParameter > & xParam = pParams[nPos]; const Reference< XTypeDescription > & xType = xParam->getType(); typelib_Parameter_Init & rInit = pParamInit[xParam->getPosition()]; rInit.eTypeClass = (typelib_TypeClass)xType->getTypeClass(); OUString aParamTypeName( xType->getName() ); rtl_uString_acquire( rInit.pTypeName = aParamTypeName.pData ); OUString aParamName( xParam->getName() ); rtl_uString_acquire( rInit.pParamName = aParamName.pData ); rInit.bIn = xParam->isIn(); rInit.bOut = xParam->isOut(); } // init all exception strings const Sequence > & rExceptions = xMethod->getExceptions(); const Reference< XTypeDescription > * pExceptions = rExceptions.getConstArray(); sal_Int32 nExceptions = rExceptions.getLength(); rtl_uString ** ppExceptionNames = (rtl_uString **)alloca( sizeof(rtl_uString *) * nExceptions ); for ( nPos = nExceptions; nPos--; ) { OUString aExceptionTypeName( pExceptions[nPos]->getName() ); rtl_uString_acquire( ppExceptionNames[nPos] = aExceptionTypeName.pData ); } OUString aTypeName( xMethod->getName() ); OUString aReturnTypeName( xReturnType->getName() ); typelib_typedescription_newInterfaceMethod( (typelib_InterfaceMethodTypeDescription **)&pRet, xMethod->getPosition(), xMethod->isOneway(), aTypeName.pData, (typelib_TypeClass)xReturnType->getTypeClass(), aReturnTypeName.pData, nParams, pParamInit, nExceptions, ppExceptionNames ); for ( nPos = nParams; nPos--; ) { rtl_uString_release( pParamInit[nPos].pTypeName ); rtl_uString_release( pParamInit[nPos].pParamName ); } for ( nPos = nExceptions; nPos--; ) { rtl_uString_release( ppExceptionNames[nPos] ); } } return pRet; } //================================================================================================== inline static typelib_TypeDescription * createCTD( Reference< container::XHierarchicalNameAccess > const & access, const Reference< XInterfaceTypeDescription2 > & xType ) { typelib_TypeDescription * pRet = 0; if (xType.is()) { Sequence< Reference< XTypeDescription > > aBases(xType->getBaseTypes()); sal_Int32 nBases = aBases.getLength(); // Exploit the fact that a typelib_TypeDescription for an interface type // is also the typelib_TypeDescriptionReference for that type: boost::scoped_array< typelib_TypeDescription * > aBaseTypes( new typelib_TypeDescription *[nBases]); {for (sal_Int32 i = 0; i < nBases; ++i) { typelib_TypeDescription * p = createCTD(access, aBases[i]); OSL_ASSERT( !TYPELIB_TYPEDESCRIPTIONREFERENCE_ISREALLYWEAK(p->eTypeClass)); typelib_typedescription_register(&p); aBaseTypes[i] = p; }} typelib_TypeDescriptionReference ** pBaseTypeRefs = reinterpret_cast< typelib_TypeDescriptionReference ** >( aBaseTypes.get()); // construct all member refs const Sequence > & rMembers = xType->getMembers(); sal_Int32 nMembers = rMembers.getLength(); typelib_TypeDescriptionReference ** ppMemberRefs = (typelib_TypeDescriptionReference **)alloca( sizeof(typelib_TypeDescriptionReference *) * nMembers ); const Reference< XInterfaceMemberTypeDescription > * pMembers = rMembers.getConstArray(); OUString aTypeName( xType->getName() ); sal_Int32 nPos; for ( nPos = nMembers; nPos--; ) { OUString aMemberTypeName( pMembers[nPos]->getName() ); ppMemberRefs[nPos] = 0; typelib_typedescriptionreference_new( ppMemberRefs + nPos, (typelib_TypeClass)pMembers[nPos]->getTypeClass(), aMemberTypeName.pData ); } Uik uik = xType->getUik(); typelib_typedescription_newMIInterface( (typelib_InterfaceTypeDescription **)&pRet, aTypeName.pData, uik.m_Data1, uik.m_Data2, uik.m_Data3, uik.m_Data4, uik.m_Data5, nBases, pBaseTypeRefs, nMembers, ppMemberRefs ); // cleanup refs and base type {for (int i = 0; i < nBases; ++i) { typelib_typedescription_release(aBaseTypes[i]); }} for ( nPos = nMembers; nPos--; ) { typelib_typedescriptionreference_release( ppMemberRefs[nPos] ); } } return pRet; } //================================================================================================== inline static typelib_TypeDescription * createCTD( const Reference< XEnumTypeDescription > & xType ) { typelib_TypeDescription * pRet = 0; if (xType.is()) { OUString aTypeName( xType->getName() ); Sequence< OUString > aNames( xType->getEnumNames() ); OSL_ASSERT( sizeof(OUString) == sizeof(rtl_uString *) ); // !!! Sequence< sal_Int32 > aValues( xType->getEnumValues() ); typelib_typedescription_newEnum( &pRet, aTypeName.pData, xType->getDefaultEnumValue(), aNames.getLength(), (rtl_uString **)aNames.getConstArray(), const_cast< sal_Int32 * >( aValues.getConstArray() ) ); } return pRet; } //================================================================================================== inline static typelib_TypeDescription * createCTD( Reference< container::XHierarchicalNameAccess > const & access, const Reference< XIndirectTypeDescription > & xType ) { typelib_TypeDescription * pRet = 0; if (xType.is()) { typelib_TypeDescription * pRefType = createCTD( access, xType->getReferencedType() ); typelib_typedescription_register( &pRefType ); OUString aTypeName( xType->getName() ); typelib_typedescription_new( &pRet, (typelib_TypeClass)xType->getTypeClass(), aTypeName.pData, pRefType->pWeakRef, 0, 0 ); // cleanup if (pRefType) typelib_typedescription_release( pRefType ); } return pRet; } //================================================================================================== static typelib_TypeDescription * createCTD( Reference< container::XHierarchicalNameAccess > const & access, const Reference< XTypeDescription > & xType ) { typelib_TypeDescription * pRet = 0; if (xType.is()) { switch (xType->getTypeClass()) { // built in types case TypeClass_VOID: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("void") ); typelib_typedescription_new( &pRet, typelib_TypeClass_VOID, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_CHAR: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("char") ); typelib_typedescription_new( &pRet, typelib_TypeClass_CHAR, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_BOOLEAN: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("boolean") ); typelib_typedescription_new( &pRet, typelib_TypeClass_BOOLEAN, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_BYTE: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("byte") ); typelib_typedescription_new( &pRet, typelib_TypeClass_BYTE, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_SHORT: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("short") ); typelib_typedescription_new( &pRet, typelib_TypeClass_SHORT, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_UNSIGNED_SHORT: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("unsigned short") ); typelib_typedescription_new( &pRet, typelib_TypeClass_UNSIGNED_SHORT, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_LONG: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("long") ); typelib_typedescription_new( &pRet, typelib_TypeClass_LONG, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_UNSIGNED_LONG: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("unsigned long") ); typelib_typedescription_new( &pRet, typelib_TypeClass_UNSIGNED_LONG, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_HYPER: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("hyper") ); typelib_typedescription_new( &pRet, typelib_TypeClass_HYPER, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_UNSIGNED_HYPER: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("unsigned hyper") ); typelib_typedescription_new( &pRet, typelib_TypeClass_UNSIGNED_HYPER, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_FLOAT: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("float") ); typelib_typedescription_new( &pRet, typelib_TypeClass_FLOAT, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_DOUBLE: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("double") ); typelib_typedescription_new( &pRet, typelib_TypeClass_DOUBLE, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_STRING: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("string") ); typelib_typedescription_new( &pRet, typelib_TypeClass_STRING, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_TYPE: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("type") ); typelib_typedescription_new( &pRet, typelib_TypeClass_TYPE, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_ANY: { OUString aTypeName( RTL_CONSTASCII_USTRINGPARAM("any") ); typelib_typedescription_new( &pRet, typelib_TypeClass_ANY, aTypeName.pData, 0, 0, 0 ); break; } case TypeClass_UNION: pRet = createCTD( Reference< XUnionTypeDescription >::query( xType ) ); break; case TypeClass_EXCEPTION: pRet = createCTD( Reference< XCompoundTypeDescription >::query( xType ) ); break; case TypeClass_STRUCT: pRet = createCTD( access, Reference< XStructTypeDescription >::query( xType ) ); break; case TypeClass_ENUM: pRet = createCTD( Reference< XEnumTypeDescription >::query( xType ) ); break; case TypeClass_TYPEDEF: { Reference< XIndirectTypeDescription > xTypedef( xType, UNO_QUERY ); if (xTypedef.is()) pRet = createCTD( access, xTypedef->getReferencedType() ); break; } case TypeClass_SEQUENCE: pRet = createCTD( access, Reference< XIndirectTypeDescription >::query( xType ) ); break; case TypeClass_INTERFACE: pRet = createCTD( access, Reference< XInterfaceTypeDescription2 >::query( xType ) ); break; case TypeClass_INTERFACE_METHOD: pRet = createCTD( Reference< XInterfaceMethodTypeDescription >::query( xType ) ); break; case TypeClass_INTERFACE_ATTRIBUTE: pRet = createCTD( Reference< XInterfaceAttributeTypeDescription >::query( xType ) ); break; default: break; } } return pRet; } //================================================================================================== extern "C" { static void SAL_CALL typelib_callback( void * pContext, typelib_TypeDescription ** ppRet, rtl_uString * pTypeName ) { OSL_ENSURE( pContext && ppRet && pTypeName, "### null ptr!" ); if (ppRet) { if (*ppRet) { ::typelib_typedescription_release( *ppRet ); *ppRet = 0; } if (pContext && pTypeName) { Reference< container::XHierarchicalNameAccess > access( reinterpret_cast< container::XHierarchicalNameAccess * >( pContext)); try { OUString const & rTypeName = OUString::unacquired( &pTypeName ); Reference< XTypeDescription > xTD; if (access->getByHierarchicalName(rTypeName ) >>= xTD) { *ppRet = createCTD( access, xTD ); } } catch (container::NoSuchElementException & exc) { (void) exc; // avoid warning about unused variable OSL_ENSURE( 0, OUStringToOString( OUString( RTL_CONSTASCII_USTRINGPARAM( "typelibrary type not available: ") ) + exc.Message, RTL_TEXTENCODING_UTF8 ).getStr() ); } catch (Exception & exc) { (void) exc; // avoid warning about unused variable OSL_ENSURE( 0, OUStringToOString( exc.Message, RTL_TEXTENCODING_UTF8 ).getStr() ); } } } } } //================================================================================================== class EventListenerImpl : public WeakImplHelper1< lang::XEventListener > { Reference< container::XHierarchicalNameAccess > m_xTDMgr; public: inline EventListenerImpl( Reference< container::XHierarchicalNameAccess > const & xTDMgr ) SAL_THROW( () ) : m_xTDMgr( xTDMgr ) {} // XEventListener virtual void SAL_CALL disposing( lang::EventObject const & rEvt ) throw (RuntimeException); }; //__________________________________________________________________________________________________ void EventListenerImpl::disposing( lang::EventObject const & rEvt ) throw (RuntimeException) { if (rEvt.Source != m_xTDMgr) { OSL_ASSERT(false); } // deregister of c typelib callback ::typelib_typedescription_revokeCallback( m_xTDMgr.get(), typelib_callback ); } //================================================================================================== sal_Bool SAL_CALL installTypeDescriptionManager( Reference< container::XHierarchicalNameAccess > const & xTDMgr_c ) SAL_THROW( () ) { uno::Environment curr_env(Environment::getCurrent()); uno::Environment target_env(rtl::OUString(RTL_CONSTASCII_USTRINGPARAM(CPPU_STRINGIFY(CPPU_ENV)))); uno::Mapping curr2target(curr_env, target_env); Reference xTDMgr( reinterpret_cast( curr2target.mapInterface(xTDMgr_c.get(), ::getCppuType(&xTDMgr_c))), SAL_NO_ACQUIRE); Reference< lang::XComponent > xComp( xTDMgr, UNO_QUERY ); if (xComp.is()) { xComp->addEventListener( new EventListenerImpl( xTDMgr ) ); // register c typelib callback ::typelib_typedescription_registerCallback( xTDMgr.get(), typelib_callback ); return sal_True; } return sal_False; } } // end namespace cppu