/* -*- 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 using namespace ::osl; using namespace ::cppu; using namespace ::com::sun::star::uno; using namespace ::com::sun::star::io; using namespace ::com::sun::star::lang; #include "streamhelper.hxx" namespace com::sun::star::uno { class XComponentContext; } // Implementation and service names #define IMPLEMENTATION_NAME "com.sun.star.comp.io.stm.Pipe" namespace io_stm{ namespace { class OPipeImpl : public WeakImplHelper< XPipe , XConnectable , XServiceInfo > { public: OPipeImpl( ); public: // XInputStream virtual sal_Int32 SAL_CALL readBytes(Sequence< sal_Int8 >& aData, sal_Int32 nBytesToRead) override; virtual sal_Int32 SAL_CALL readSomeBytes(Sequence< sal_Int8 >& aData, sal_Int32 nMaxBytesToRead) override; virtual void SAL_CALL skipBytes(sal_Int32 nBytesToSkip) override; virtual sal_Int32 SAL_CALL available() override; virtual void SAL_CALL closeInput() override; public: // XOutputStream virtual void SAL_CALL writeBytes(const Sequence< sal_Int8 >& aData) override; virtual void SAL_CALL flush() override; virtual void SAL_CALL closeOutput() override; public: // XConnectable virtual void SAL_CALL setPredecessor(const Reference< XConnectable >& aPredecessor) override; virtual Reference< XConnectable > SAL_CALL getPredecessor() override; virtual void SAL_CALL setSuccessor(const Reference < XConnectable > & aSuccessor) override; virtual Reference < XConnectable > SAL_CALL getSuccessor() override ; public: // XServiceInfo OUString SAL_CALL getImplementationName() override; Sequence< OUString > SAL_CALL getSupportedServiceNames() override; sal_Bool SAL_CALL supportsService(const OUString& ServiceName) override; private: Reference < XConnectable > m_succ; Reference < XConnectable > m_pred; sal_Int32 m_nBytesToSkip; bool m_bOutputStreamClosed; bool m_bInputStreamClosed; osl::Condition m_conditionBytesAvail; Mutex m_mutexAccess; std::unique_ptr m_pFIFO; }; } OPipeImpl::OPipeImpl() : m_nBytesToSkip(0 ) , m_bOutputStreamClosed(false ) , m_bInputStreamClosed( false ) , m_pFIFO( new MemFIFO ) { } sal_Int32 OPipeImpl::readBytes(Sequence< sal_Int8 >& aData, sal_Int32 nBytesToRead) { while( true ) { { // start guarded section MutexGuard guard( m_mutexAccess ); if( m_bInputStreamClosed ) { throw NotConnectedException( "Pipe::readBytes NotConnectedException", *this ); } sal_Int32 nOccupiedBufferLen = m_pFIFO->getSize(); if( m_bOutputStreamClosed && nBytesToRead > nOccupiedBufferLen ) { nBytesToRead = nOccupiedBufferLen; } if( nOccupiedBufferLen < nBytesToRead ) { // wait outside guarded section m_conditionBytesAvail.reset(); } else { // necessary bytes are available m_pFIFO->read( aData , nBytesToRead ); return nBytesToRead; } } // end guarded section // wait for new data outside guarded section! m_conditionBytesAvail.wait(); } } sal_Int32 OPipeImpl::readSomeBytes(Sequence< sal_Int8 >& aData, sal_Int32 nMaxBytesToRead) { while( true ) { { MutexGuard guard( m_mutexAccess ); if( m_bInputStreamClosed ) { throw NotConnectedException( "Pipe::readSomeBytes NotConnectedException", *this ); } if( m_pFIFO->getSize() ) { sal_Int32 nSize = std::min( nMaxBytesToRead , m_pFIFO->getSize() ); aData.realloc( nSize ); m_pFIFO->read( aData , nSize ); return nSize; } if( m_bOutputStreamClosed ) { // no bytes in buffer anymore return 0; } } m_conditionBytesAvail.wait(); } } void OPipeImpl::skipBytes(sal_Int32 nBytesToSkip) { MutexGuard guard( m_mutexAccess ); if( m_bInputStreamClosed ) { throw NotConnectedException( "Pipe::skipBytes NotConnectedException", *this ); } if( nBytesToSkip < 0 || (nBytesToSkip > std::numeric_limits< sal_Int32 >::max() - m_nBytesToSkip) ) { throw BufferSizeExceededException( "Pipe::skipBytes BufferSizeExceededException", *this ); } m_nBytesToSkip += nBytesToSkip; nBytesToSkip = std::min( m_pFIFO->getSize() , m_nBytesToSkip ); m_pFIFO->skip( nBytesToSkip ); m_nBytesToSkip -= nBytesToSkip; } sal_Int32 OPipeImpl::available() { MutexGuard guard( m_mutexAccess ); if( m_bInputStreamClosed ) { throw NotConnectedException( "Pipe::available NotConnectedException", *this ); } return m_pFIFO->getSize(); } void OPipeImpl::closeInput() { MutexGuard guard( m_mutexAccess ); m_bInputStreamClosed = true; m_pFIFO.reset(); // readBytes may throw an exception m_conditionBytesAvail.set(); setSuccessor( Reference< XConnectable > () ); } void OPipeImpl::writeBytes(const Sequence< sal_Int8 >& aData) { MutexGuard guard( m_mutexAccess ); if( m_bOutputStreamClosed ) { throw NotConnectedException( "Pipe::writeBytes NotConnectedException (outputstream)", *this ); } if( m_bInputStreamClosed ) { throw NotConnectedException( "Pipe::writeBytes NotConnectedException (inputstream)", *this ); } // check skipping sal_Int32 nLen = aData.getLength(); if( m_nBytesToSkip && m_nBytesToSkip >= nLen ) { // all must be skipped - forget whole call m_nBytesToSkip -= nLen; return; } // adjust buffersize if necessary if( m_nBytesToSkip ) { Sequence< sal_Int8 > seqCopy( nLen - m_nBytesToSkip ); memcpy( seqCopy.getArray() , &( aData.getConstArray()[m_nBytesToSkip] ) , nLen-m_nBytesToSkip ); m_pFIFO->write( seqCopy ); } else { m_pFIFO->write( aData ); } m_nBytesToSkip = 0; // readBytes may check again if enough bytes are available m_conditionBytesAvail.set(); } void OPipeImpl::flush() { // nothing to do for a pipe } void OPipeImpl::closeOutput() { MutexGuard guard( m_mutexAccess ); m_bOutputStreamClosed = true; m_conditionBytesAvail.set(); setPredecessor( Reference < XConnectable > () ); } void OPipeImpl::setSuccessor( const Reference < XConnectable > &r ) { /// if the references match, nothing needs to be done if( m_succ != r ) { /// store the reference for later use m_succ = r; if( m_succ.is() ) { m_succ->setPredecessor( Reference< XConnectable > ( static_cast< XConnectable * >(this) ) ); } } } Reference < XConnectable > OPipeImpl::getSuccessor() { return m_succ; } // XDataSource void OPipeImpl::setPredecessor( const Reference < XConnectable > &r ) { if( r != m_pred ) { m_pred = r; if( m_pred.is() ) { m_pred->setSuccessor( Reference < XConnectable > ( static_cast< XConnectable * >(this) ) ); } } } Reference < XConnectable > OPipeImpl::getPredecessor() { return m_pred; } // XServiceInfo OUString OPipeImpl::getImplementationName() { return IMPLEMENTATION_NAME; } // XServiceInfo sal_Bool OPipeImpl::supportsService(const OUString& ServiceName) { return cppu::supportsService(this, ServiceName); } // XServiceInfo Sequence< OUString > OPipeImpl::getSupportedServiceNames() { return { "com.sun.star.io.Pipe" }; } } extern "C" SAL_DLLPUBLIC_EXPORT css::uno::XInterface* io_OPipeImpl_get_implementation( css::uno::XComponentContext* , css::uno::Sequence const&) { return cppu::acquire(new io_stm::OPipeImpl()); } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */