/* -*- 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 . */ #ifndef INCLUDED_SOT_SOURCE_SDSTOR_STGSTRMS_HXX #define INCLUDED_SOT_SOURCE_SDSTOR_STGSTRMS_HXX #include #include #include #include class StgIo; class StgStrm; class StgPage; class StgDirEntry; // The FAT class performs FAT operations on an underlying storage stream. // This stream is either the physical FAT stream (bPhys == true ) or a normal // storage stream, which then holds the FAT for small data allocations. class StgFAT { // FAT allocator StgStrm& m_rStrm; // underlying stream sal_Int32 m_nMaxPage; // highest page allocated so far short m_nPageSize; // physical page size short m_nEntries; // FAT entries per page short m_nOffset; // current offset within page sal_Int32 m_nLimit; // search limit recommendation bool m_bPhys; // true: physical FAT rtl::Reference< StgPage > GetPhysPage( sal_Int32 nPage ); bool MakeChain( sal_Int32 nStart, sal_Int32 nPages ); bool InitNew( sal_Int32 nPage1 ); public: StgFAT( StgStrm& rStrm, bool bMark ); sal_Int32 FindBlock( sal_Int32& nPages ); sal_Int32 GetNextPage( sal_Int32 nPg ); sal_Int32 AllocPages( sal_Int32 nStart, sal_Int32 nPages ); bool FreePages( sal_Int32 nStart, bool bAll ); sal_Int32 GetMaxPage() { return m_nMaxPage; } void SetLimit( sal_Int32 n ) { m_nLimit = n; } }; // The base stream class provides basic functionality for seeking // and accessing the data on a physical basis. It uses the built-in // FAT class for the page allocations. class StgStrm { // base class for all streams protected: StgIo& m_rIo; // I/O system std::unique_ptr m_pFat; // FAT stream for allocations StgDirEntry* m_pEntry; // dir entry (for ownership) sal_Int32 m_nStart; // 1st data page sal_Int32 m_nSize; // stream size in bytes sal_Int32 m_nPos; // current byte position sal_Int32 m_nPage; // current logical page short m_nOffset; // offset into current page short m_nPageSize; // logical page size std::vector m_aPagesCache; void scanBuildPageChainCache(sal_Int32 *pOptionalCalcSize); bool Copy( sal_Int32 nFrom, sal_Int32 nBytes ); explicit StgStrm( StgIo& ); public: virtual ~StgStrm(); StgIo& GetIo() { return m_rIo; } sal_Int32 GetPos() const { return m_nPos; } sal_Int32 GetStart() const { return m_nStart; } sal_Int32 GetSize() const { return m_nSize; } sal_Int32 GetPage() const { return m_nPage; } sal_Int32 GetPages() const { return ( m_nSize + m_nPageSize - 1 ) / m_nPageSize;} short GetOffset() const { return m_nOffset;} void SetEntry( StgDirEntry& ); virtual bool SetSize( sal_Int32 ); virtual bool Pos2Page( sal_Int32 nBytePos ); virtual sal_Int32 Read( void*, sal_Int32 ) { return 0; } virtual sal_Int32 Write( const void*, sal_Int32 ) { return 0; } virtual bool IsSmallStrm() const { return false; } }; // The FAT stream class provides physical access to the master FAT. // Since this access is implemented as a StgStrm, we can use the // FAT allocator. class StgFATStrm : public StgStrm { // the master FAT stream virtual bool Pos2Page( sal_Int32 nBytePos ) override; bool SetPage( short, sal_Int32 ); public: explicit StgFATStrm(StgIo&, sal_Int32 nFatStrmSize); using StgStrm::GetPage; sal_Int32 GetPage( short, bool, sal_uInt16 *pnMasterAlloc = nullptr); virtual bool SetSize( sal_Int32 ) override; }; // The stream has a size increment which normally is 1, but which can be // set to any value is you want the size to be incremented by certain values. class StgDataStrm : public StgStrm // a physical data stream { short m_nIncr; // size adjust increment void Init( sal_Int32 nBgn, sal_Int32 nLen ); public: StgDataStrm( StgIo&, sal_Int32 nBgn, sal_Int32 nLen=-1 ); StgDataStrm( StgIo&, StgDirEntry& ); void* GetPtr( sal_Int32 nPos, bool bDirty ); void SetIncrement( short n ) { m_nIncr = n ; } virtual bool SetSize( sal_Int32 ) override; virtual sal_Int32 Read( void*, sal_Int32 ) override; virtual sal_Int32 Write( const void*, sal_Int32 ) override; }; // The small stream class provides access to streams with a size < 4096 bytes. // This stream is a StgStream containing small pages. The FAT for this stream // is also a StgStream. The start of the FAT is in the header at DataRootPage, // the stream itself is pointed to by the root entry (it holds start & size). class StgSmallStrm : public StgStrm // a logical data stream { StgStrm* m_pData; // the data stream void Init( sal_Int32 nBgn, sal_Int32 nLen ); public: StgSmallStrm( StgIo&, sal_Int32 nBgn ); StgSmallStrm( StgIo&, StgDirEntry& ); virtual sal_Int32 Read( void*, sal_Int32 ) override; virtual sal_Int32 Write( const void*, sal_Int32 ) override; virtual bool IsSmallStrm() const override { return true; } }; class StgTmpStrm : public SvMemoryStream { OUString m_aName; SvFileStream* m_pStrm; using SvMemoryStream::GetData; virtual std::size_t GetData( void* pData, std::size_t nSize ) override; virtual std::size_t PutData( const void* pData, std::size_t nSize ) override; virtual sal_uInt64 SeekPos( sal_uInt64 nPos ) override; virtual void FlushData() override; public: explicit StgTmpStrm( sal_uInt64=16 ); virtual ~StgTmpStrm() override; bool Copy( StgTmpStrm& ); virtual void SetSize( sal_uInt64 ) override; sal_uInt64 GetSize() const; }; #endif /* vim:set shiftwidth=4 softtabstop=4 expandtab: */