/* -*- 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 #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "currentcontextchecker.hxx" #include "multi.hxx" #include using namespace osl; using namespace cppu; using namespace com::sun::star::uno; using namespace com::sun::star::lang; using namespace com::sun::star::registry; using namespace com::sun::star::bridge; using namespace test::testtools::bridgetest; #define SERVICENAME "com.sun.star.test.bridge.BridgeTest" #define IMPLNAME "com.sun.star.comp.bridge.BridgeTest" #define STRING_TEST_CONSTANT "\" paco\' chorizo\\\' \"\'" namespace bridge_test { template static Sequence cloneSequence(const Sequence& val); static Sequence< OUString > getSupportedServiceNames() { return { SERVICENAME }; } static bool check( bool b , char const * message ) { if ( ! b ) fprintf( stderr, "%s failed\n" , message ); return b; } namespace { bool checkEmpty(OUString const & string, char const * message) { bool ok = string.isEmpty(); if (!ok) { fprintf( stderr, "%s failed: %s\n", message, OUStringToOString(string, RTL_TEXTENCODING_UTF8).getStr()); } return ok; } class TestBridgeImpl : public osl::DebugBase, public WeakImplHelper< XMain, XServiceInfo > { Reference< XComponentContext > m_xContext; public: explicit TestBridgeImpl( const Reference< XComponentContext > & xContext ) : m_xContext( xContext ) {} // XServiceInfo virtual OUString SAL_CALL getImplementationName() override; virtual sal_Bool SAL_CALL supportsService( const OUString & rServiceName ) override; virtual Sequence< OUString > SAL_CALL getSupportedServiceNames() override; // XMain virtual sal_Int32 SAL_CALL run( const Sequence< OUString > & rArgs ) override; }; } static bool equals( const TestElement & rData1, const TestElement & rData2 ) { check( rData1.Bool == rData2.Bool, "### bool does not match!" ); check( rData1.Char == rData2.Char, "### char does not match!" ); check( rData1.Byte == rData2.Byte, "### byte does not match!" ); check( rData1.Short == rData2.Short, "### short does not match!" ); check( rData1.UShort == rData2.UShort, "### unsigned short does not match!" ); check( rData1.Long == rData2.Long, "### long does not match!" ); check( rData1.ULong == rData2.ULong, "### unsigned long does not match!" ); check( rData1.Hyper == rData2.Hyper, "### hyper does not match!" ); check( rData1.UHyper == rData2.UHyper, "### unsigned hyper does not match!" ); check( rData1.Float == rData2.Float, "### float does not match!" ); check( rData1.Double == rData2.Double, "### double does not match!" ); check( rData1.Enum == rData2.Enum, "### enum does not match!" ); check( rData1.String == rData2.String, "### string does not match!" ); check( rData1.Interface == rData2.Interface, "### interface does not match!" ); check( rData1.Any == rData2.Any, "### any does not match!" ); return (rData1.Bool == rData2.Bool && rData1.Char == rData2.Char && rData1.Byte == rData2.Byte && rData1.Short == rData2.Short && rData1.UShort == rData2.UShort && rData1.Long == rData2.Long && rData1.ULong == rData2.ULong && rData1.Hyper == rData2.Hyper && rData1.UHyper == rData2.UHyper && rData1.Float == rData2.Float && rData1.Double == rData2.Double && rData1.Enum == rData2.Enum && rData1.String == rData2.String && rData1.Interface == rData2.Interface && rData1.Any == rData2.Any); } static bool equals( const TestData & rData1, const TestData & rData2 ) { sal_Int32 nLen; if (rData1.Sequence != rData2.Sequence) return false; if (!equals( static_cast(rData1), static_cast(rData2) )) return false; nLen = rData1.Sequence.getLength(); if (nLen == rData2.Sequence.getLength()) { // once again by hand sequence == const TestElement * pElements1 = rData1.Sequence.getConstArray(); const TestElement * pElements2 = rData2.Sequence.getConstArray(); for ( ; nLen--; ) { if (! equals( pElements1[nLen], pElements2[nLen] )) { check( false, "### sequence element did not match!" ); return false; } } return true; } return false; } static void assign( TestElement & rData, bool bBool, sal_Unicode cChar, sal_Int8 nByte, sal_Int16 nShort, sal_uInt16 nUShort, sal_Int32 nLong, sal_uInt32 nULong, sal_Int64 nHyper, sal_uInt64 nUHyper, float fFloat, double fDouble, TestEnum eEnum, const OUString& rStr, const css::uno::Reference< css::uno::XInterface >& xTest, const css::uno::Any& rAny ) { rData.Bool = bBool; rData.Char = cChar; rData.Byte = nByte; rData.Short = nShort; rData.UShort = nUShort; rData.Long = nLong; rData.ULong = nULong; rData.Hyper = nHyper; rData.UHyper = nUHyper; rData.Float = fFloat; rData.Double = fDouble; rData.Enum = eEnum; rData.String = rStr; rData.Interface = xTest; rData.Any = rAny; } namespace { template < typename T > bool testAny( T const & value, Reference< XBridgeTest > const & xLBT, char const * typeName = nullptr) { Any any; any <<= value; Any any2 = xLBT->transportAny(any); bool success = true; if (any != any2) { fprintf( stderr, "any is different after roundtrip: in %s, out %s\n", OUStringToOString( any.getValueType().getTypeName(), RTL_TEXTENCODING_ASCII_US).getStr(), OUStringToOString( any2.getValueType().getTypeName(), RTL_TEXTENCODING_ASCII_US).getStr()); success = false; } if (typeName != nullptr && !any2.getValueType().getTypeName().equalsAscii(typeName)) { fprintf( stderr, "any has wrong type after roundtrip: %s instead of %s\n", OUStringToOString( any2.getValueType().getTypeName(), RTL_TEXTENCODING_ASCII_US).getStr(), typeName); success = false; } return success; } } static bool performAnyTest( const Reference< XBridgeTest > &xLBT, const TestData &data) { bool bReturn = true; bReturn = testAny( data.Byte ,xLBT ) && bReturn; bReturn = testAny( data.Short,xLBT ) && bReturn; bReturn = testAny( data.UShort,xLBT ) && bReturn; bReturn = testAny( data.Long,xLBT ) && bReturn; bReturn = testAny( data.ULong,xLBT ) && bReturn; bReturn = testAny( data.Hyper,xLBT ) && bReturn; bReturn = testAny( data.UHyper,xLBT ) && bReturn; bReturn = testAny( data.Float,xLBT ) && bReturn; bReturn = testAny( data.Double,xLBT ) && bReturn; bReturn = testAny( data.Enum,xLBT ) && bReturn; bReturn = testAny( data.String,xLBT ) && bReturn; bReturn = testAny( data.Interface,xLBT ) && bReturn; bReturn = testAny( data, xLBT ) && bReturn; bReturn &= testAny( TestPolyStruct< sal_Unicode >(' '), xLBT, "test.testtools.bridgetest.TestPolyStruct"); Any a; { a <<= data.Bool; OSL_ASSERT( xLBT->transportAny( a ) == a ); } { a <<= data.Char; OSL_ASSERT( xLBT->transportAny( a ) == a ); } return bReturn; } static bool performSequenceOfCallTest( const Reference < XBridgeTest > &xLBT ) { sal_Int32 i,nRounds; sal_Int32 nGlobalIndex = 0; const sal_Int32 nWaitTimeSpanMUSec = 10000; for( nRounds = 0 ; nRounds < 10 ; nRounds ++ ) { for( i = 0 ; i < nRounds ; i ++ ) { // fire oneways xLBT->callOneway( nGlobalIndex , nWaitTimeSpanMUSec ); nGlobalIndex ++; } // call synchron xLBT->call( nGlobalIndex , nWaitTimeSpanMUSec ); nGlobalIndex ++; } return xLBT->sequenceOfCallTestPassed(); } namespace { class ORecursiveCall : public WeakImplHelper< XRecursiveCall > { private: Mutex m_mutex; public: void SAL_CALL callRecursivly( const css::uno::Reference< XRecursiveCall >& xCall, sal_Int32 nToCall ) override { MutexGuard guard( m_mutex ); if( nToCall ) { nToCall --; xCall->callRecursivly( this , nToCall ); } } }; } static bool performRecursiveCallTest( const Reference < XBridgeTest > & xLBT ) { xLBT->startRecursiveCall( new ORecursiveCall , 50 ); // on failure, the test would lock up or crash return true; } namespace { class MyClass : public osl::DebugBase, public OWeakObject { public: MyClass(); }; } MyClass::MyClass() { } static bool performTest( const Reference & xContext, const Reference & xLBT, bool noCurrentContext ) { check(xLBT.is(), "### no test interface!"); bool bRet = true; if (xLBT.is()) { // this data is never ever granted access to by calls other than // equals(), assign()! TestData aData; // test against this data Reference< XInterface > xI(new MyClass); assign( static_cast(aData), true, '@', 17, 0x1234, 0xFEDC, 0x12345678, 0xFEDCBA98, SAL_CONST_INT64(0x123456789ABCDEF0), SAL_CONST_UINT64(0xFEDCBA9876543210), 17.0815f, 3.1415926359, TestEnum_LOLA, STRING_TEST_CONSTANT, xI, Any(&xI, cppu::UnoType::get())); bRet &= check(aData.Any == xI, "### unexpected any!"); bRet &= check(!(aData.Any != xI), "### unexpected any!"); aData.Sequence.realloc(2); aData.Sequence[0] = *static_cast(&aData); // aData.Sequence[1] is empty // aSetData is a manually copy of aData for first setting: TestData aSetData; assign( static_cast(aSetData), aData.Bool, aData.Char, aData.Byte, aData.Short, aData.UShort, aData.Long, aData.ULong, aData.Hyper, aData.UHyper, aData.Float, aData.Double, aData.Enum, aData.String, xI, Any(&xI, cppu::UnoType::get())); aSetData.Sequence.realloc(2); aSetData.Sequence[0] = *static_cast(&aSetData); // aSetData.Sequence[1] is empty xLBT->setValues( aSetData.Bool, aSetData.Char, aSetData.Byte, aSetData.Short, aSetData.UShort, aSetData.Long, aSetData.ULong, aSetData.Hyper, aSetData.UHyper, aSetData.Float, aSetData.Double, aSetData.Enum, aSetData.String, aSetData.Interface, aSetData.Any, aSetData.Sequence, aSetData); { TestData aRet; TestData aRet2; xLBT->getValues( aRet.Bool, aRet.Char, aRet.Byte, aRet.Short, aRet.UShort, aRet.Long, aRet.ULong, aRet.Hyper, aRet.UHyper, aRet.Float, aRet.Double, aRet.Enum, aRet.String, aRet.Interface, aRet.Any, aRet.Sequence, aRet2); bRet &= check( equals(aData, aRet) && equals(aData, aRet2), "getValues test"); // Set last retrieved values: TestData aSV2ret( xLBT->setValues2( aRet.Bool, aRet.Char, aRet.Byte, aRet.Short, aRet.UShort, aRet.Long, aRet.ULong, aRet.Hyper, aRet.UHyper, aRet.Float, aRet.Double, aRet.Enum, aRet.String, aRet.Interface, aRet.Any, aRet.Sequence, aRet2)); // Check inout sequence order (=> inout sequence parameter was // switched by test objects): TestElement temp(aRet.Sequence[0]); aRet.Sequence[0] = aRet.Sequence[1]; aRet.Sequence[1] = temp; bRet &= check( equals(aData, aSV2ret) && equals(aData, aRet2), "getValues2 test"); } { TwoFloats aIn(1.1f, 2.2f); TwoFloats aOut = xLBT->echoTwoFloats(aIn); bRet = check( memcmp(&aIn, &aOut, sizeof(TwoFloats)) == 0, "two floats struct test" ) && bRet; } { FourFloats aIn(3.3f, 4.4f, 5.5f, 6.6f); FourFloats aOut = xLBT->echoFourFloats(aIn); bRet = check( memcmp(&aIn, &aOut, sizeof(FourFloats)) == 0, "four floats struct test" ) && bRet; } { MixedFloatAndInteger aIn(7.7f, 8); MixedFloatAndInteger aOut = xLBT->echoMixedFloatAndInteger(aIn); bRet = check( memcmp(&aIn, &aOut, sizeof(MixedFloatAndInteger)) == 0, "mixed float and integer struct test" ) && bRet; } { ThreeByteStruct aIn(9, 10, 11); ThreeByteStruct aOut = xLBT->echoThreeByteStruct(aIn); bRet = check( memcmp(&aIn, &aOut, sizeof(ThreeByteStruct)) == 0, "three byte struct test" ) && bRet; } { TestData aRet; TestData aRet2; TestData aGVret( xLBT->getValues( aRet.Bool, aRet.Char, aRet.Byte, aRet.Short, aRet.UShort, aRet.Long, aRet.ULong, aRet.Hyper, aRet.UHyper, aRet.Float, aRet.Double, aRet.Enum, aRet.String, aRet.Interface, aRet.Any, aRet.Sequence, aRet2)); bRet &= check( (equals(aData, aRet) && equals(aData, aRet2) && equals(aData, aGVret)), "getValues test"); // Set last retrieved values: xLBT->setBool(aRet.Bool); xLBT->setChar(aRet.Char); xLBT->setByte(aRet.Byte); xLBT->setShort(aRet.Short); xLBT->setUShort(aRet.UShort); xLBT->setLong(aRet.Long); xLBT->setULong(aRet.ULong); xLBT->setHyper(aRet.Hyper); xLBT->setUHyper(aRet.UHyper); xLBT->setFloat(aRet.Float); xLBT->setDouble(aRet.Double); xLBT->setEnum(aRet.Enum); xLBT->setString(aRet.String); xLBT->setInterface(aRet.Interface); xLBT->setAny(aRet.Any); xLBT->setSequence(aRet.Sequence); xLBT->setStruct(aRet2); } { TestData aRet; aRet.Hyper = xLBT->getHyper(); aRet.UHyper = xLBT->getUHyper(); aRet.Float = xLBT->getFloat(); aRet.Double = xLBT->getDouble(); aRet.Byte = xLBT->getByte(); aRet.Char = xLBT->getChar(); aRet.Bool = xLBT->getBool(); aRet.Short = xLBT->getShort(); aRet.UShort = xLBT->getUShort(); aRet.Long = xLBT->getLong(); aRet.ULong = xLBT->getULong(); aRet.Enum = xLBT->getEnum(); aRet.String = xLBT->getString(); aRet.Interface = xLBT->getInterface(); aRet.Any = xLBT->getAny(); aRet.Sequence = xLBT->getSequence(); TestData aRet2(xLBT->getStruct()); bRet &= check( equals(aData, aRet) && equals(aData, aRet2), "struct comparison test"); { SmallStruct aIn(1, 2); SmallStruct aOut(xLBT->echoSmallStruct(aIn)); bRet &= check( memcmp(&aIn, &aOut, sizeof(SmallStruct)) == 0, "small struct test"); } { MediumStruct aIn(1, 2, 3, 4); MediumStruct aOut(xLBT->echoMediumStruct(aIn)); bRet &= check( memcmp(&aIn, &aOut, sizeof(MediumStruct)) == 0, "medium struct test"); } { BigStruct aIn(1, 2, 3, 4, 5, 6, 7, 8); BigStruct aOut(xLBT->echoBigStruct(aIn)); bRet &= check( memcmp(&aIn, &aOut, sizeof(BigStruct)) == 0, "big struct test"); } { sal_Int32 i2 = xLBT->testPPCAlignment(0, 0, 0, 0, 0xBEAF); bRet &= check(i2 == 0xBEAF, "ppc-style alignment test"); } { sal_Int32 i1 = xLBT->testPPC64Alignment(1.0, 2.0, 3.0, 0xBEAF); bRet &= check(i1 == 0xBEAF, "ppc64-style alignment test"); } { double d1 = xLBT->testTenDoubles(0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.9, 1.0); bRet &= check(d1 == 5.5, "armhf doubles test"); } // Test extended attributes that raise exceptions: try { xLBT->getRaiseAttr1(); bRet &= check(false, "getRaiseAttr1 did not throw"); } catch (const RuntimeException &) { } catch (...) { bRet &= check(false, "getRaiseAttr1 threw wrong type"); } try { xLBT->setRaiseAttr1(0); bRet &= check(false, "setRaiseAttr1 did not throw"); } catch (const IllegalArgumentException &) { } catch (...) { bRet &= check(false, "setRaiseAttr1 threw wrong type"); } try { xLBT->getRaiseAttr2(); bRet &= check(false, "getRaiseAttr2 did not throw"); } catch (const IllegalArgumentException &) { } catch (...) { bRet &= check(false, "getRaiseAttr2 threw wrong type"); } // Test instantiated polymorphic struct types: { bRet &= check( (xLBT->transportPolyBoolean( TestPolyStruct< sal_Bool >(true)). member), "transportPolyBoolean"); TestPolyStruct< sal_Int64 > tps1(12345); xLBT->transportPolyHyper(tps1); bRet &= check(tps1.member == 12345, "transportPolyHyper"); Sequence< Any > seq(2); seq[0] <<= static_cast< sal_uInt32 >(33); seq[1] <<= OUString("ABC"); TestPolyStruct< Sequence< Any > > tps2(seq); TestPolyStruct< Sequence< Any > > tps3; xLBT->transportPolySequence(tps2, tps3); bRet &= check( tps3.member.getLength() == 2, "transportPolySequence, length"); sal_uInt32 v0 = sal_uInt32(); tps3.member[0] >>= v0; bRet &= check(v0 == 33, "transportPolySequence, element 0"); OUString v1; tps3.member[1] >>= v1; bRet &= check( v1 == "ABC", "transportPolySequence, element 1" ); bRet &= check( xLBT->getNullPolyLong().member == 0, "getNullPolyLong"); bRet &= check( xLBT->getNullPolyString().member.isEmpty(), "getNullPolyString"); bRet &= check( xLBT->getNullPolyType().member == Type(), "getNullPolyType"); Any nullAny(xLBT->getNullPolyAny().member); auto ifc = o3tl::tryAccess>(nullAny); bRet &= check( !nullAny.hasValue() || (ifc && !ifc->is()), "getNullPolyAny"); bRet &= check( !xLBT->getNullPolySequence().member.hasElements(), "getNullPolySequence"); bRet &= check( xLBT->getNullPolyEnum().member == TestEnum_TEST, "getNullPolyEnum"); bRet &= check( xLBT->getNullPolyBadEnum().member == TestBadEnum_M, "getNullPolyBadEnum"); bRet &= check( xLBT->getNullPolyStruct().member.member == 0, "getNullPolyStruct"); bRet &= check( !xLBT->getNullPolyInterface().member.is(), "getNullPolyInterface"); } // Any test: bRet &= check(performAnyTest(xLBT , aData), "any test"); // Sequence of call test: bRet &= check( performSequenceOfCallTest(xLBT), "sequence of call test"); // Recursive call test: bRet &= check(performRecursiveCallTest(xLBT), "recursive test"); bRet &= check( equals(aData, aRet) && equals(aData, aRet2), "recursive test results"); // Multiple inheritance test: bRet &= checkEmpty( testtools::bridgetest::testMulti(xLBT->getMulti()), "remote multi"); bRet &= checkEmpty( xLBT->testMulti(new testtools::bridgetest::Multi), "local multi"); } } { Reference< XBridgeTest2 > xBT2(xLBT, UNO_QUERY); if (!xBT2.is()) { return bRet; } // Perform sequence tests (XBridgeTest2); create the sequence which is // compared with the results: sal_Int32 _arLong[] = { static_cast< sal_Int32 >(0x80000000), 1, 0x7FFFFFFF }; sal_Int32 _aInt = 0xBABEBABE; float _aFloat = 3.14f; Any _any1(true); Any _any2(&_aInt, cppu::UnoType::get()); Any _any3(&_aFloat, cppu::UnoType::get()); Any _arAny[] = { _any1, _any2, _any3 }; Reference< XInterface > _arObj[3]; _arObj[0] = new OWeakObject(); _arObj[1] = new OWeakObject(); _arObj[2] = new OWeakObject(); TestElement _arStruct[3]; assign( _arStruct[0], true, '@', 17, 0x1234, 0xFEDC, 0x12345678, 0xFEDCBA98, SAL_CONST_INT64(0x123456789ABCDEF0), SAL_CONST_UINT64(0xFEDCBA9876543210), 17.0815f, 3.1415926359, TestEnum_LOLA, STRING_TEST_CONSTANT, _arObj[0], Any(&_arObj[0], cppu::UnoType::get())); assign( _arStruct[1], true, 'A', 17, 0x1234, 0xFEDC, 0x12345678, 0xFEDCBA98, SAL_CONST_INT64(0x123456789ABCDEF0), SAL_CONST_UINT64(0xFEDCBA9876543210), 17.0815f, 3.1415926359, TestEnum_TWO, STRING_TEST_CONSTANT, _arObj[1], Any(&_arObj[1], cppu::UnoType::get())); assign( _arStruct[2], true, 'B', 17, 0x1234, 0xFEDC, 0x12345678, 0xFEDCBA98, SAL_CONST_INT64(0x123456789ABCDEF0), SAL_CONST_UINT64(0xFEDCBA9876543210), 17.0815f, 3.1415926359, TestEnum_CHECK, STRING_TEST_CONSTANT, _arObj[2], Any(&_arObj[2], cppu::UnoType::get())); { Sequence arBool({true, false, true}); Sequence arChar({0x0065, 0x0066, 0x0067}); Sequence arByte({1, 2, -1}); Sequence arShort({-0x8000, 1, 0x7FFF}); Sequence arUShort({0 , 1, 0xFFFF}); Sequence arLong(_arLong, 3); Sequence arULong({0, 1, 0xFFFFFFFF}); Sequence arHyper({ static_cast(SAL_CONST_INT64(0x8000000000000000)), 1, SAL_CONST_INT64(0x7FFFFFFFFFFFFFFF)}); Sequence arUHyper({ 0, 1, SAL_CONST_UINT64(0xFFFFFFFFFFFFFFFF)}); Sequence arFloat({1.1f, 2.2f, 3.3f}); Sequence arDouble({1.11, 2.22, 3.33}); Sequence arString({ OUString("String 1"), OUString("String 2"), OUString("String 3")}); Sequence arAny(_arAny, 3); Sequence > arObject(_arObj, 3); Sequence arEnum({ TestEnum_ONE, TestEnum_TWO, TestEnum_CHECK}); Sequence arStruct(_arStruct, 3); Sequence > _arSeqLong2[3]; for (int j = 0; j != 3; ++j) { Sequence< sal_Int32 > _arSeqLong[3]; for (int i = 0; i != 3; ++i) { _arSeqLong[i] = Sequence< sal_Int32 >(_arLong, 3); } _arSeqLong2[j] = Sequence< Sequence< sal_Int32 > >( _arSeqLong, 3); } Sequence< Sequence< Sequence< sal_Int32> > > arLong3( _arSeqLong2, 3); Sequence< Sequence< sal_Int32 > > seqSeqRet( xBT2->setDim2(arLong3[0])); bRet &= check(seqSeqRet == arLong3[0], "sequence test"); Sequence< Sequence< Sequence< sal_Int32 > > > seqSeqRet2( xBT2->setDim3(arLong3)); bRet &= check(seqSeqRet2 == arLong3, "sequence test"); Sequence< Any > seqAnyRet(xBT2->setSequenceAny(arAny)); bRet &= check(seqAnyRet == arAny, "sequence test"); Sequence< sal_Bool > seqBoolRet(xBT2->setSequenceBool(arBool)); bRet &= check(seqBoolRet == arBool, "sequence test"); Sequence< sal_Int8 > seqByteRet(xBT2->setSequenceByte(arByte)); bRet &= check(seqByteRet == arByte, "sequence test"); Sequence< sal_Unicode > seqCharRet(xBT2->setSequenceChar(arChar)); bRet &= check(seqCharRet == arChar, "sequence test"); Sequence< sal_Int16 > seqShortRet(xBT2->setSequenceShort(arShort)); bRet &= check(seqShortRet == arShort, "sequence test"); Sequence< sal_Int32 > seqLongRet(xBT2->setSequenceLong(arLong)); bRet &= check(seqLongRet == arLong, "sequence test"); Sequence< sal_Int64 > seqHyperRet(xBT2->setSequenceHyper(arHyper)); bRet &= check(seqHyperRet == arHyper, "sequence test"); Sequence< float > seqFloatRet(xBT2->setSequenceFloat(arFloat)); bRet &= check(seqFloatRet == arFloat, "sequence test"); Sequence< double > seqDoubleRet(xBT2->setSequenceDouble(arDouble)); bRet &= check(seqDoubleRet == arDouble, "sequence test"); Sequence< TestEnum > seqEnumRet(xBT2->setSequenceEnum(arEnum)); bRet &= check(seqEnumRet == arEnum, "sequence test"); Sequence< sal_uInt16 > seqUShortRet( xBT2->setSequenceUShort(arUShort)); bRet &= check(seqUShortRet == arUShort, "sequence test"); Sequence< sal_uInt32 > seqULongRet(xBT2->setSequenceULong(arULong)); bRet &= check(seqULongRet == arULong, "sequence test"); Sequence< sal_uInt64 > seqUHyperRet( xBT2->setSequenceUHyper(arUHyper)); bRet &= check(seqUHyperRet == arUHyper, "sequence test"); Sequence< Reference< XInterface > > seqObjectRet( xBT2->setSequenceXInterface(arObject)); bRet &= check(seqObjectRet == arObject, "sequence test"); Sequence< OUString > seqStringRet( xBT2->setSequenceString(arString)); bRet &= check(seqStringRet == arString, "sequence test"); Sequence< TestElement > seqStructRet( xBT2->setSequenceStruct(arStruct)); bRet &= check(seqStructRet == arStruct, "sequence test"); Sequence< sal_Bool > arBoolTemp(cloneSequence(arBool)); Sequence< sal_Unicode > arCharTemp(cloneSequence(arChar)); Sequence< sal_Int8 > arByteTemp(cloneSequence(arByte)); Sequence< sal_Int16 > arShortTemp(cloneSequence(arShort)); Sequence< sal_uInt16 > arUShortTemp(cloneSequence(arUShort)); Sequence< sal_Int32 > arLongTemp(cloneSequence(arLong)); Sequence< sal_uInt32 > arULongTemp(cloneSequence(arULong)); Sequence< sal_Int64 > arHyperTemp(cloneSequence(arHyper)); Sequence< sal_uInt64 > arUHyperTemp(cloneSequence(arUHyper)); Sequence< float > arFloatTemp(cloneSequence(arFloat)); Sequence< double > arDoubleTemp(cloneSequence(arDouble)); Sequence< TestEnum > arEnumTemp(cloneSequence(arEnum)); Sequence< OUString > arStringTemp(cloneSequence(arString)); Sequence< Reference< XInterface > > arObjectTemp( cloneSequence(arObject)); Sequence< Any > arAnyTemp(cloneSequence(arAny)); Sequence< Sequence< sal_Int32 > > arLong2Temp(arLong3[0]); Sequence< Sequence< Sequence< sal_Int32 > > > arLong3Temp(arLong3); xBT2->setSequencesInOut( arBoolTemp, arCharTemp, arByteTemp, arShortTemp, arUShortTemp, arLongTemp,arULongTemp, arHyperTemp, arUHyperTemp, arFloatTemp, arDoubleTemp, arEnumTemp, arStringTemp, arObjectTemp, arAnyTemp, arLong2Temp, arLong3Temp); bRet &= check( (arBoolTemp == arBool && arCharTemp == arChar && arByteTemp == arByte && arShortTemp == arShort && arUShortTemp == arUShort && arLongTemp == arLong && arULongTemp == arULong && arHyperTemp == arHyper && arUHyperTemp == arUHyper && arFloatTemp == arFloat && arDoubleTemp == arDouble && arEnumTemp == arEnum && arStringTemp == arString && arObjectTemp == arObject && arAnyTemp == arAny && arLong2Temp == arLong3[0] && arLong3Temp == arLong3), "sequence test"); Sequence< sal_Bool > arBoolOut; Sequence< sal_Unicode > arCharOut; Sequence< sal_Int8 > arByteOut; Sequence< sal_Int16 > arShortOut; Sequence< sal_uInt16 > arUShortOut; Sequence< sal_Int32 > arLongOut; Sequence< sal_uInt32 > arULongOut; Sequence< sal_Int64 > arHyperOut; Sequence< sal_uInt64 > arUHyperOut; Sequence< float > arFloatOut; Sequence< double > arDoubleOut; Sequence< TestEnum > arEnumOut; Sequence< OUString > arStringOut; Sequence< Reference< XInterface > > arObjectOut; Sequence< Any > arAnyOut; Sequence< Sequence< sal_Int32 > > arLong2Out; Sequence< Sequence< Sequence< sal_Int32 > > > arLong3Out; xBT2->setSequencesOut( arBoolOut, arCharOut, arByteOut, arShortOut, arUShortOut, arLongOut,arULongOut, arHyperOut, arUHyperOut, arFloatOut, arDoubleOut, arEnumOut, arStringOut, arObjectOut, arAnyOut, arLong2Out, arLong3Out); bRet &= check( (arBoolOut == arBool && arCharOut == arChar && arByteOut == arByte && arShortOut == arShort && arUShortOut == arUShort && arLongOut == arLong && arULongOut == arULong && arHyperOut == arHyper && arUHyperOut == arUHyper && arFloatOut == arFloat && arDoubleOut == arDouble && arEnumOut == arEnum && arStringOut == arString && arObjectOut == arObject && arAnyOut == arAny && arLong2Out == arLong3[0] && arLong3Out == arLong3), "sequence test"); } { // Test with empty sequences: Sequence< Sequence< sal_Int32 > > arLong2; Sequence< Sequence< sal_Int32 > > seqSeqRet(xBT2->setDim2(arLong2)); bRet &= check(seqSeqRet == arLong2, "sequence test"); Sequence< Sequence< Sequence< sal_Int32 > > > arLong3; Sequence< Sequence< Sequence< sal_Int32 > > > seqSeqRet2( xBT2->setDim3(arLong3)); bRet &= check(seqSeqRet2 == arLong3, "sequence test"); Sequence< Any > arAny; Sequence< Any > seqAnyRet(xBT2->setSequenceAny(arAny)); bRet &= check(seqAnyRet == arAny, "sequence test"); Sequence< sal_Bool > arBool; Sequence< sal_Bool > seqBoolRet(xBT2->setSequenceBool(arBool)); bRet &= check(seqBoolRet == arBool, "sequence test"); Sequence< sal_Int8 > arByte; Sequence< sal_Int8 > seqByteRet(xBT2->setSequenceByte(arByte)); bRet &= check(seqByteRet == arByte, "sequence test"); Sequence< sal_Unicode > arChar; Sequence< sal_Unicode > seqCharRet(xBT2->setSequenceChar(arChar)); bRet &= check(seqCharRet == arChar, "sequence test"); Sequence< sal_Int16 > arShort; Sequence< sal_Int16 > seqShortRet(xBT2->setSequenceShort(arShort)); bRet &= check(seqShortRet == arShort, "sequence test"); Sequence< sal_Int32 > arLong; Sequence< sal_Int32 > seqLongRet(xBT2->setSequenceLong(arLong)); bRet &= check(seqLongRet == arLong, "sequence test"); Sequence< sal_Int64 > arHyper; Sequence< sal_Int64 > seqHyperRet(xBT2->setSequenceHyper(arHyper)); bRet &= check(seqHyperRet == arHyper, "sequence test"); Sequence< float > arFloat; Sequence< float > seqFloatRet(xBT2->setSequenceFloat(arFloat)); bRet &= check(seqFloatRet == arFloat, "sequence test"); Sequence< double > arDouble; Sequence< double > seqDoubleRet(xBT2->setSequenceDouble(arDouble)); bRet &= check(seqDoubleRet == arDouble, "sequence test"); Sequence< TestEnum > arEnum; Sequence< TestEnum > seqEnumRet(xBT2->setSequenceEnum(arEnum)); bRet &= check(seqEnumRet == arEnum, "sequence test"); Sequence< sal_uInt16 > arUShort; Sequence< sal_uInt16 > seqUShortRet( xBT2->setSequenceUShort(arUShort)); bRet &= check(seqUShortRet == arUShort, "sequence test"); Sequence< sal_uInt32 > arULong; Sequence< sal_uInt32 > seqULongRet(xBT2->setSequenceULong(arULong)); bRet &= check(seqULongRet == arULong, "sequence test"); Sequence< sal_uInt64 > arUHyper; Sequence< sal_uInt64 > seqUHyperRet( xBT2->setSequenceUHyper(arUHyper)); bRet &= check(seqUHyperRet == arUHyper, "sequence test"); Sequence< Reference< XInterface > > arObject; Sequence< Reference< XInterface > > seqObjectRet( xBT2->setSequenceXInterface(arObject)); bRet &= check(seqObjectRet == arObject, "sequence test"); Sequence< OUString > arString; Sequence< OUString > seqStringRet( xBT2->setSequenceString(arString)); bRet &= check(seqStringRet == arString, "sequence test"); Sequence< TestElement > arStruct; Sequence< TestElement > seqStructRet( xBT2->setSequenceStruct(arStruct)); bRet &= check(seqStructRet == arStruct, "sequence test"); } // Issue #i60341# shows that the most interesting case is were Java // calls the constructors; however, since this client is currently not // available in Java, while the server is, the logic is reversed here: try { xBT2->testConstructorsService(xContext); } catch (const BadConstructorArguments &) { bRet = false; } if (!noCurrentContext) { if (!(new testtools::bridgetest::CurrentContextChecker)->perform( xBT2->getCurrentContextChecker(), 0, 1)) { bRet = false; } if (!(new testtools::bridgetest::CurrentContextChecker)->perform( xBT2->getCurrentContextChecker(), 0, 2)) { bRet = false; } if (!(new testtools::bridgetest::CurrentContextChecker)->perform( xBT2->getCurrentContextChecker(), 1, 2)) { bRet = false; } if (!(new testtools::bridgetest::CurrentContextChecker)->perform( xBT2->getCurrentContextChecker(), 1, 3)) { bRet = false; } } } return bRet; } static bool raiseOnewayException( const Reference < XBridgeTest > & xLBT ) { bool bReturn = true; Reference const x(xLBT->getInterface()); try { // Note : the exception may fly or not (e.g. remote scenario). // When it flies, it must contain the correct elements. xLBT->raiseRuntimeExceptionOneway( STRING_TEST_CONSTANT, x ); } catch( const RuntimeException & e ) { bReturn = ( #if OSL_DEBUG_LEVEL == 0 // java stack traces trash Message e.Message == STRING_TEST_CONSTANT && #endif xLBT->getInterface() == e.Context && x == e.Context ); } return bReturn; } static bool raiseException( const Reference< XBridgeTest > & xLBT ) { sal_Int32 nCount = 0; try { try { try { xLBT->raiseException( 5, STRING_TEST_CONSTANT, xLBT->getInterface() ); } catch (const IllegalArgumentException &rExc) { if (rExc.ArgumentPosition == 5 && #if OSL_DEBUG_LEVEL == 0 // java stack traces trash Message rExc.Message.startsWith(STRING_TEST_CONSTANT) && #endif rExc.Context == xLBT->getInterface()) { #ifdef COMPCHECK //When we check if a new compiler still works then we must not call //getRuntimeException because it uses cppu::getCaughtException which //does only work if all libs are build with the same runtime. return true; #else ++nCount; #endif } else { check( false, "### unexpected exception content!" ); } /** it is certain, that the RuntimeException testing will fail, if no */ xLBT->getRuntimeException(); } } catch (const RuntimeException & rExc) { if (rExc.Context == xLBT->getInterface() #if OSL_DEBUG_LEVEL == 0 // java stack traces trash Message && rExc.Message.startsWith(STRING_TEST_CONSTANT) #endif ) { ++nCount; } else { check( false, "### unexpected exception content!" ); } /** it is certain, that the RuntimeException testing will fail, if no */ xLBT->setRuntimeException( 0xcafebabe ); } } catch (const Exception & rExc) { if (rExc.Context == xLBT->getInterface() #if OSL_DEBUG_LEVEL == 0 // java stack traces trash Message && rExc.Message.startsWith(STRING_TEST_CONSTANT) #endif ) { ++nCount; } else { check( false, "### unexpected exception content!" ); } return (nCount == 3); } return false; } /* Returns an acquired sequence */ static uno_Sequence* cloneSequence(const uno_Sequence* val, const Type& type) { TypeDescription td(type); td.makeComplete(); typelib_TypeDescription* pTdRaw = td.get(); typelib_IndirectTypeDescription* pIndirectTd = reinterpret_cast(pTdRaw); typelib_TypeDescription* pTdElem = pIndirectTd->pType->pType; std::unique_ptr buf(new sal_Int8[pTdElem->nSize * val->nElements]); sal_Int8* pBufCur = buf.get(); uno_Sequence* retSeq = nullptr; switch (static_cast(pTdElem->eTypeClass)) { case TypeClass_SEQUENCE: { Type _tElem(pTdElem->pWeakRef); for (int i = 0; i < val->nElements; i++) { sal_Int8 const *pValBuf = reinterpret_cast(&val->elements + i * pTdElem->nSize); uno_Sequence* seq = cloneSequence( reinterpret_cast(pValBuf), _tElem); *reinterpret_cast(pBufCur) = seq; pBufCur += pTdElem->nSize; } break; } default: uno_type_sequence_construct( &retSeq, type.getTypeLibType(), const_cast(val->elements), val->nElements, reinterpret_cast< uno_AcquireFunc >(cpp_acquire)); break; } return retSeq; } template Sequence cloneSequence(const Sequence& val) { Sequence seq( cloneSequence(val.get(), cppu::UnoType>::get()), SAL_NO_ACQUIRE); return seq; } template< class T > static bool makeSurrogate( Reference< T > & rOut, Reference< T > const & rOriginal ) { rOut.clear(); if (! rOriginal.is()) return false; Environment aCppEnv_official; Environment aUnoEnv_ano; Environment aCppEnv_ano; OUString aCppEnvTypeName( CPPU_CURRENT_LANGUAGE_BINDING_NAME ); OUString aUnoEnvTypeName( UNO_LB_UNO ); // official: uno_getEnvironment( reinterpret_cast< uno_Environment ** >( &aCppEnv_official ), aCppEnvTypeName.pData, nullptr ); // anonymous: uno_createEnvironment( reinterpret_cast< uno_Environment ** >( &aCppEnv_ano ), aCppEnvTypeName.pData, nullptr ); uno_createEnvironment( reinterpret_cast< uno_Environment ** >( &aUnoEnv_ano ), aUnoEnvTypeName.pData, nullptr ); UnoInterfaceReference unoI; Mapping cpp2uno( aCppEnv_official.get(), aUnoEnv_ano.get() ); Mapping uno2cpp( aUnoEnv_ano.get(), aCppEnv_ano.get() ); if (!cpp2uno.is() || !uno2cpp.is()) { throw RuntimeException("cannot get C++-UNO mappings!" ); } cpp2uno.mapInterface( reinterpret_cast< void ** >( &unoI.m_pUnoI ), rOriginal.get(), cppu::UnoType::get() ); if (! unoI.is()) { throw RuntimeException( "mapping C++ to binary UNO failed!" ); } uno2cpp.mapInterface( reinterpret_cast< void ** >( &rOut ), unoI.get(), cppu::UnoType::get() ); if (! rOut.is()) { throw RuntimeException( "mapping binary UNO to C++ failed!" ); } return rOut.is(); } sal_Int32 TestBridgeImpl::run( const Sequence< OUString > & rArgs ) { bool bRet = false; try { if (! rArgs.hasElements()) { throw RuntimeException( "no test object specified!\n" "usage : ServiceName of test object | -u unourl of test object" ); } Reference< XInterface > xOriginal; bool remote; sal_Int32 i; if( rArgs.getLength() > 1 && rArgs[0] == "-u" ) { remote = true; i = 2; } else { remote = false; i = 1; } bool noCurrentContext = false; if ( i < rArgs.getLength() && rArgs[i] == "noCurrentContext" ) { noCurrentContext = true; ++i; } bool stress = false; if ( i < rArgs.getLength() && rArgs[i] == "stress" ) { stress = true; ++i; } for (;;) { Reference< XInterface > o; if (remote) { o = UnoUrlResolver::create(m_xContext)->resolve(rArgs[1]); } else { o = m_xContext->getServiceManager()->createInstanceWithContext( rArgs[0], m_xContext); } if (!stress) { xOriginal = o; break; } } if (! xOriginal.is()) { throw RuntimeException( "cannot get test object!" ); } Reference< XBridgeTest > xTest( xOriginal, UNO_QUERY_THROW ); Reference xLBT; bRet = check( makeSurrogate( xLBT, xTest ), "makeSurrogate" ); bRet = check( performTest( m_xContext, xLBT, noCurrentContext ), "standard test" ) && bRet; bRet = check( raiseException( xLBT ) , "exception test" )&& bRet; bRet = check( raiseOnewayException( xLBT ), "oneway exception test" ) && bRet; if (! bRet) { throw RuntimeException( "error: test failed!" ); } } catch (const Exception & exc) { OString cstr( OUStringToOString( exc.Message, RTL_TEXTENCODING_ASCII_US ) ); fprintf( stderr, "exception occurred: %s\n", cstr.getStr() ); throw; } return bRet ? 0 : 1; } // XServiceInfo OUString TestBridgeImpl::getImplementationName() { return IMPLNAME; } sal_Bool TestBridgeImpl::supportsService( const OUString & rServiceName ) { return cppu::supportsService(this, rServiceName); } Sequence< OUString > TestBridgeImpl::getSupportedServiceNames() { return bridge_test::getSupportedServiceNames(); } static Reference< XInterface > TestBridgeImpl_create( const Reference< XComponentContext > & xContext ) { return Reference< XInterface >( static_cast< OWeakObject * >( new TestBridgeImpl( xContext ) ) ); } } extern "C" { SAL_DLLPUBLIC_EXPORT void * component_getFactory( const char * pImplName, void * pServiceManager, SAL_UNUSED_PARAMETER void * ) { void * pRet = nullptr; if (pServiceManager && rtl_str_compare( pImplName, IMPLNAME ) == 0) { Reference< XInterface > xFactory( createSingleComponentFactory( bridge_test::TestBridgeImpl_create, IMPLNAME, bridge_test::getSupportedServiceNames() ) ); if (xFactory.is()) { xFactory->acquire(); pRet = xFactory.get(); } } return pRet; } } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */