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author | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-27 16:51:28 +0000 |
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committer | Daniel Baumann <daniel.baumann@progress-linux.org> | 2024-04-27 16:51:28 +0000 |
commit | 940b4d1848e8c70ab7642901a68594e8016caffc (patch) | |
tree | eb72f344ee6c3d9b80a7ecc079ea79e9fba8676d /vcl/source/gdi/dibtools.cxx | |
parent | Initial commit. (diff) | |
download | libreoffice-940b4d1848e8c70ab7642901a68594e8016caffc.tar.xz libreoffice-940b4d1848e8c70ab7642901a68594e8016caffc.zip |
Adding upstream version 1:7.0.4.upstream/1%7.0.4upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'vcl/source/gdi/dibtools.cxx')
-rw-r--r-- | vcl/source/gdi/dibtools.cxx | 1904 |
1 files changed, 1904 insertions, 0 deletions
diff --git a/vcl/source/gdi/dibtools.cxx b/vcl/source/gdi/dibtools.cxx new file mode 100644 index 000000000..f2164b94d --- /dev/null +++ b/vcl/source/gdi/dibtools.cxx @@ -0,0 +1,1904 @@ +/* -*- 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 <sal/config.h> +#include <sal/log.hxx> + +#include <cassert> + +#include <o3tl/safeint.hxx> +#include <vcl/dibtools.hxx> +#include <comphelper/fileformat.h> +#include <tools/zcodec.hxx> +#include <tools/stream.hxx> +#include <tools/fract.hxx> +#include <tools/helpers.hxx> +#include <tools/GenericTypeSerializer.hxx> +#include <unotools/configmgr.hxx> +#include <vcl/bitmapex.hxx> +#include <vcl/bitmapaccess.hxx> +#include <vcl/outdev.hxx> +#include <bitmapwriteaccess.hxx> +#include <memory> + +#define DIBCOREHEADERSIZE ( 12UL ) +#define DIBINFOHEADERSIZE ( sizeof(DIBInfoHeader) ) +#define DIBV5HEADERSIZE ( sizeof(DIBV5Header) ) + +// - DIBInfoHeader and DIBV5Header + +typedef sal_Int32 FXPT2DOT30; + +namespace +{ + +struct CIEXYZ +{ + FXPT2DOT30 aXyzX; + FXPT2DOT30 aXyzY; + FXPT2DOT30 aXyzZ; + + CIEXYZ() + : aXyzX(0), + aXyzY(0), + aXyzZ(0) + {} +}; + +struct CIEXYZTriple +{ + CIEXYZ aXyzRed; + CIEXYZ aXyzGreen; + CIEXYZ aXyzBlue; + + CIEXYZTriple() + : aXyzRed(), + aXyzGreen(), + aXyzBlue() + {} +}; + +struct DIBInfoHeader +{ + sal_uInt32 nSize; + sal_Int32 nWidth; + sal_Int32 nHeight; + sal_uInt16 nPlanes; + sal_uInt16 nBitCount; + sal_uInt32 nCompression; + sal_uInt32 nSizeImage; + sal_Int32 nXPelsPerMeter; + sal_Int32 nYPelsPerMeter; + sal_uInt32 nColsUsed; + sal_uInt32 nColsImportant; + + DIBInfoHeader() + : nSize(0), + nWidth(0), + nHeight(0), + nPlanes(0), + nBitCount(0), + nCompression(0), + nSizeImage(0), + nXPelsPerMeter(0), + nYPelsPerMeter(0), + nColsUsed(0), + nColsImportant(0) + {} +}; + +struct DIBV5Header : public DIBInfoHeader +{ + sal_uInt32 nV5RedMask; + sal_uInt32 nV5GreenMask; + sal_uInt32 nV5BlueMask; + sal_uInt32 nV5AlphaMask; + sal_uInt32 nV5CSType; + CIEXYZTriple aV5Endpoints; + sal_uInt32 nV5GammaRed; + sal_uInt32 nV5GammaGreen; + sal_uInt32 nV5GammaBlue; + sal_uInt32 nV5Intent; + sal_uInt32 nV5ProfileData; + sal_uInt32 nV5ProfileSize; + sal_uInt32 nV5Reserved; + + DIBV5Header() + : DIBInfoHeader(), + nV5RedMask(0), + nV5GreenMask(0), + nV5BlueMask(0), + nV5AlphaMask(0), + nV5CSType(0), + aV5Endpoints(), + nV5GammaRed(0), + nV5GammaGreen(0), + nV5GammaBlue(0), + nV5Intent(0), + nV5ProfileData(0), + nV5ProfileSize(0), + nV5Reserved(0) + {} +}; + +sal_uInt16 discretizeBitcount( sal_uInt16 nInputCount ) +{ + return ( nInputCount <= 1 ) ? 1 : + ( nInputCount <= 4 ) ? 4 : + ( nInputCount <= 8 ) ? 8 : 24; +} + +bool isBitfieldCompression( ScanlineFormat nScanlineFormat ) +{ + return ScanlineFormat::N32BitTcMask == nScanlineFormat; +} + +bool ImplReadDIBInfoHeader(SvStream& rIStm, DIBV5Header& rHeader, bool& bTopDown, bool bMSOFormat) +{ + // BITMAPINFOHEADER or BITMAPCOREHEADER or BITMAPV5HEADER + sal_uInt64 const aStartPos(rIStm.Tell()); + rIStm.ReadUInt32( rHeader.nSize ); + + // BITMAPCOREHEADER + if ( rHeader.nSize == DIBCOREHEADERSIZE ) + { + sal_Int16 nTmp16; + + rIStm.ReadInt16( nTmp16 ); rHeader.nWidth = nTmp16; + rIStm.ReadInt16( nTmp16 ); rHeader.nHeight = nTmp16; + rIStm.ReadUInt16( rHeader.nPlanes ); + rIStm.ReadUInt16( rHeader.nBitCount ); + } + else if ( bMSOFormat && rHeader.nSize == DIBINFOHEADERSIZE ) + { + sal_Int16 nTmp16(0); + rIStm.ReadInt16(nTmp16); + rHeader.nWidth = nTmp16; + rIStm.ReadInt16(nTmp16); + rHeader.nHeight = nTmp16; + sal_uInt8 nTmp8(0); + rIStm.ReadUChar(nTmp8); + rHeader.nPlanes = nTmp8; + rIStm.ReadUChar(nTmp8); + rHeader.nBitCount = nTmp8; + rIStm.ReadInt16(nTmp16); + rHeader.nSizeImage = nTmp16; + rIStm.ReadInt16(nTmp16); + rHeader.nCompression = nTmp16; + if ( !rHeader.nSizeImage ) // uncompressed? + rHeader.nSizeImage = ((rHeader.nWidth * rHeader.nBitCount + 31) & ~31) / 8 * rHeader.nHeight; + rIStm.ReadInt32( rHeader.nXPelsPerMeter ); + rIStm.ReadInt32( rHeader.nYPelsPerMeter ); + rIStm.ReadUInt32( rHeader.nColsUsed ); + rIStm.ReadUInt32( rHeader.nColsImportant ); + } + else + { + // BITMAPCOREHEADER, BITMAPV5HEADER or unknown. Read as far as possible + std::size_t nUsed(sizeof(rHeader.nSize)); + + auto readUInt16 = [&nUsed, &rHeader, &rIStm](sal_uInt16 & v) { + if (nUsed < rHeader.nSize) { + rIStm.ReadUInt16(v); + nUsed += sizeof(v); + } + }; + auto readInt32 = [&nUsed, &rHeader, &rIStm](sal_Int32 & v) { + if (nUsed < rHeader.nSize) { + rIStm.ReadInt32(v); + nUsed += sizeof(v); + } + }; + auto readUInt32 = [&nUsed, &rHeader, &rIStm](sal_uInt32 & v) { + if (nUsed < rHeader.nSize) { + rIStm.ReadUInt32(v); + nUsed += sizeof(v); + } + }; + + // read DIBInfoHeader entries + readInt32( rHeader.nWidth ); + readInt32( rHeader.nHeight ); + readUInt16( rHeader.nPlanes ); + readUInt16( rHeader.nBitCount ); + readUInt32( rHeader.nCompression ); + readUInt32( rHeader.nSizeImage ); + readInt32( rHeader.nXPelsPerMeter ); + readInt32( rHeader.nYPelsPerMeter ); + readUInt32( rHeader.nColsUsed ); + readUInt32( rHeader.nColsImportant ); + + // read DIBV5HEADER members + readUInt32( rHeader.nV5RedMask ); + readUInt32( rHeader.nV5GreenMask ); + readUInt32( rHeader.nV5BlueMask ); + readUInt32( rHeader.nV5AlphaMask ); + readUInt32( rHeader.nV5CSType ); + + // read contained CIEXYZTriple's + readInt32( rHeader.aV5Endpoints.aXyzRed.aXyzX ); + readInt32( rHeader.aV5Endpoints.aXyzRed.aXyzY ); + readInt32( rHeader.aV5Endpoints.aXyzRed.aXyzZ ); + readInt32( rHeader.aV5Endpoints.aXyzGreen.aXyzX ); + readInt32( rHeader.aV5Endpoints.aXyzGreen.aXyzY ); + readInt32( rHeader.aV5Endpoints.aXyzGreen.aXyzZ ); + readInt32( rHeader.aV5Endpoints.aXyzBlue.aXyzX ); + readInt32( rHeader.aV5Endpoints.aXyzBlue.aXyzY ); + readInt32( rHeader.aV5Endpoints.aXyzBlue.aXyzZ ); + + readUInt32( rHeader.nV5GammaRed ); + readUInt32( rHeader.nV5GammaGreen ); + readUInt32( rHeader.nV5GammaBlue ); + readUInt32( rHeader.nV5Intent ); + readUInt32( rHeader.nV5ProfileData ); + readUInt32( rHeader.nV5ProfileSize ); + readUInt32( rHeader.nV5Reserved ); + + // seek to EndPos + if (!checkSeek(rIStm, aStartPos + rHeader.nSize)) + return false; + } + + if (rHeader.nHeight == SAL_MIN_INT32) + return false; + + if ( rHeader.nHeight < 0 ) + { + bTopDown = true; + rHeader.nHeight *= -1; + } + else + { + bTopDown = false; + } + + if ( rHeader.nWidth < 0 || rHeader.nXPelsPerMeter < 0 || rHeader.nYPelsPerMeter < 0 ) + { + rIStm.SetError( SVSTREAM_FILEFORMAT_ERROR ); + } + + // #144105# protect a little against damaged files + assert(rHeader.nHeight >= 0); + if (rHeader.nHeight != 0 && rHeader.nWidth >= 0 + && (rHeader.nSizeImage / 16 / static_cast<sal_uInt32>(rHeader.nHeight) + > o3tl::make_unsigned(rHeader.nWidth))) + { + rHeader.nSizeImage = 0; + } + + + if (rHeader.nPlanes != 1) + return false; + + if (rHeader.nBitCount != 0 && rHeader.nBitCount != 1 && + rHeader.nBitCount != 4 && rHeader.nBitCount != 8 && + rHeader.nBitCount != 16 && rHeader.nBitCount != 24 && + rHeader.nBitCount != 32) + { + return false; + } + + return rIStm.good(); +} + +bool ImplReadDIBPalette(SvStream& rIStm, BitmapPalette& rPal, bool bQuad) +{ + const sal_uInt16 nColors = rPal.GetEntryCount(); + const sal_uLong nPalSize = nColors * ( bQuad ? 4UL : 3UL ); + BitmapColor aPalColor; + + std::unique_ptr<sal_uInt8[]> pEntries(new sal_uInt8[ nPalSize ]); + if (rIStm.ReadBytes(pEntries.get(), nPalSize) != nPalSize) + { + return false; + } + + sal_uInt8* pTmpEntry = pEntries.get(); + for( sal_uInt16 i = 0; i < nColors; i++ ) + { + aPalColor.SetBlue( *pTmpEntry++ ); + aPalColor.SetGreen( *pTmpEntry++ ); + aPalColor.SetRed( *pTmpEntry++ ); + + if( bQuad ) + pTmpEntry++; + + rPal[i] = aPalColor; + } + + return rIStm.GetError() == ERRCODE_NONE; +} + +BitmapColor SanitizePaletteIndex(sal_uInt8 nIndex, BitmapPalette& rPalette, bool bForceToMonoWhileReading) +{ + const sal_uInt16 nPaletteEntryCount = rPalette.GetEntryCount(); + if (nPaletteEntryCount && nIndex >= nPaletteEntryCount) + { + auto nSanitizedIndex = nIndex % nPaletteEntryCount; + SAL_WARN_IF(nIndex != nSanitizedIndex, "vcl", "invalid colormap index: " + << static_cast<unsigned int>(nIndex) << ", colormap len is: " + << nPaletteEntryCount); + nIndex = nSanitizedIndex; + } + + if (nPaletteEntryCount && bForceToMonoWhileReading) + { + return BitmapColor(static_cast<sal_uInt8>(rPalette[nIndex].GetLuminance() >= 255)); + } + + return BitmapColor(nIndex); +} + +BitmapColor SanitizeColor(const BitmapColor &rColor, bool bForceToMonoWhileReading) +{ + if (!bForceToMonoWhileReading) + return rColor; + return BitmapColor(static_cast<sal_uInt8>(rColor.GetLuminance() >= 255)); +} + +bool ImplDecodeRLE(sal_uInt8* pBuffer, DIBV5Header const & rHeader, BitmapWriteAccess& rAcc, BitmapPalette& rPalette, bool bForceToMonoWhileReading, bool bRLE4) +{ + Scanline pRLE = pBuffer; + Scanline pEndRLE = pBuffer + rHeader.nSizeImage; + long nY = rHeader.nHeight - 1; + const sal_uLong nWidth = rAcc.Width(); + sal_uLong nCountByte; + sal_uLong nRunByte; + sal_uLong nX = 0; + sal_uInt8 cTmp; + bool bEndDecoding = false; + + do + { + if (pRLE == pEndRLE) + return false; + if( ( nCountByte = *pRLE++ ) == 0 ) + { + if (pRLE == pEndRLE) + return false; + nRunByte = *pRLE++; + + if( nRunByte > 2 ) + { + Scanline pScanline = rAcc.GetScanline(nY); + if( bRLE4 ) + { + nCountByte = nRunByte >> 1; + + for( sal_uLong i = 0; i < nCountByte; i++ ) + { + if (pRLE == pEndRLE) + return false; + + cTmp = *pRLE++; + + if( nX < nWidth ) + rAcc.SetPixelOnData(pScanline, nX++, SanitizePaletteIndex(cTmp >> 4, rPalette, bForceToMonoWhileReading)); + + if( nX < nWidth ) + rAcc.SetPixelOnData(pScanline, nX++, SanitizePaletteIndex(cTmp & 0x0f, rPalette, bForceToMonoWhileReading)); + } + + if( nRunByte & 1 ) + { + if (pRLE == pEndRLE) + return false; + + if( nX < nWidth ) + rAcc.SetPixelOnData(pScanline, nX++, SanitizePaletteIndex(*pRLE >> 4, rPalette, bForceToMonoWhileReading)); + + pRLE++; + } + + if( ( ( nRunByte + 1 ) >> 1 ) & 1 ) + { + if (pRLE == pEndRLE) + return false; + + pRLE++; + } + } + else + { + for( sal_uLong i = 0; i < nRunByte; i++ ) + { + if (pRLE == pEndRLE) + return false; + + if( nX < nWidth ) + rAcc.SetPixelOnData(pScanline, nX++, SanitizePaletteIndex(*pRLE, rPalette, bForceToMonoWhileReading)); + + pRLE++; + } + + if( nRunByte & 1 ) + { + if (pRLE == pEndRLE) + return false; + + pRLE++; + } + } + } + else if( !nRunByte ) + { + nY--; + nX = 0; + } + else if( nRunByte == 1 ) + bEndDecoding = true; + else + { + if (pRLE == pEndRLE) + return false; + + nX += *pRLE++; + + if (pRLE == pEndRLE) + return false; + + nY -= *pRLE++; + } + } + else + { + if (pRLE == pEndRLE) + return false; + cTmp = *pRLE++; + + Scanline pScanline = rAcc.GetScanline(nY); + if( bRLE4 ) + { + nRunByte = nCountByte >> 1; + + for (sal_uLong i = 0; i < nRunByte && nX < nWidth; ++i) + { + rAcc.SetPixelOnData(pScanline, nX++, SanitizePaletteIndex(cTmp >> 4, rPalette, bForceToMonoWhileReading)); + if( nX < nWidth ) + rAcc.SetPixelOnData(pScanline, nX++, SanitizePaletteIndex(cTmp & 0x0f, rPalette, bForceToMonoWhileReading)); + } + + if( ( nCountByte & 1 ) && ( nX < nWidth ) ) + rAcc.SetPixelOnData(pScanline, nX++, SanitizePaletteIndex(cTmp >> 4, rPalette, bForceToMonoWhileReading)); + } + else + { + for (sal_uLong i = 0; i < nCountByte && nX < nWidth; ++i) + rAcc.SetPixelOnData(pScanline, nX++, SanitizePaletteIndex(cTmp, rPalette, bForceToMonoWhileReading)); + } + } + } + while (!bEndDecoding && (nY >= 0)); + + return true; +} + +bool ImplReadDIBBits(SvStream& rIStm, DIBV5Header& rHeader, BitmapWriteAccess& rAcc, BitmapPalette& rPalette, BitmapWriteAccess* pAccAlpha, + bool bTopDown, bool& rAlphaUsed, const sal_uInt64 nAlignedWidth, + const bool bForceToMonoWhileReading) +{ + sal_uInt32 nRMask(( rHeader.nBitCount == 16 ) ? 0x00007c00UL : 0x00ff0000UL); + sal_uInt32 nGMask(( rHeader.nBitCount == 16 ) ? 0x000003e0UL : 0x0000ff00UL); + sal_uInt32 nBMask(( rHeader.nBitCount == 16 ) ? 0x0000001fUL : 0x000000ffUL); + bool bNative(false); + bool bTCMask(!pAccAlpha && ((16 == rHeader.nBitCount) || (32 == rHeader.nBitCount))); + bool bRLE((RLE_8 == rHeader.nCompression && 8 == rHeader.nBitCount) || (RLE_4 == rHeader.nCompression && 4 == rHeader.nBitCount)); + + // Is native format? + switch(rAcc.GetScanlineFormat()) + { + case ScanlineFormat::N1BitMsbPal: + case ScanlineFormat::N24BitTcBgr: + { + // we can't trust arbitrary-sourced index based formats to have correct indexes, so we exclude the pal formats + // from raw read and force checking their colormap indexes + bNative = ( ( rAcc.IsBottomUp() != bTopDown ) && !bRLE && !bTCMask && ( rAcc.GetScanlineSize() == nAlignedWidth ) ); + break; + } + + default: + { + break; + } + } + + // Read data + if (bNative) + { + if (nAlignedWidth + > std::numeric_limits<std::size_t>::max() / rHeader.nHeight) + { + return false; + } + std::size_t n = nAlignedWidth * rHeader.nHeight; + if (rIStm.ReadBytes(rAcc.GetBuffer(), n) != n) + { + return false; + } + } + else + { + // Read color mask + if(bTCMask && BITFIELDS == rHeader.nCompression) + { + rIStm.SeekRel( -12 ); + rIStm.ReadUInt32( nRMask ); + rIStm.ReadUInt32( nGMask ); + rIStm.ReadUInt32( nBMask ); + } + + const long nWidth(rHeader.nWidth); + const long nHeight(rHeader.nHeight); + long nResult = 0; + if (utl::ConfigManager::IsFuzzing() && (o3tl::checked_multiply(nWidth, nHeight, nResult) || nResult > 4000000)) + return false; + + if (bRLE) + { + if(!rHeader.nSizeImage) + { + rHeader.nSizeImage = rIStm.remainingSize(); + } + + if (rHeader.nSizeImage > rIStm.remainingSize()) + return false; + std::vector<sal_uInt8> aBuffer(rHeader.nSizeImage); + if (rIStm.ReadBytes(aBuffer.data(), rHeader.nSizeImage) != rHeader.nSizeImage) + return false; + if (!ImplDecodeRLE(aBuffer.data(), rHeader, rAcc, rPalette, bForceToMonoWhileReading, RLE_4 == rHeader.nCompression)) + return false; + } + else + { + if (nAlignedWidth > rIStm.remainingSize()) + { + // ofz#11188 avoid timeout + // all following paths will enter a case statement, and nCount + // is always at least 1, so we can check here before allocation + // if at least one row can be read + return false; + } + std::vector<sal_uInt8> aBuf(nAlignedWidth); + + const long nI(bTopDown ? 1 : -1); + long nY(bTopDown ? 0 : nHeight - 1); + long nCount(nHeight); + + switch(rHeader.nBitCount) + { + case 1: + { + for( ; nCount--; nY += nI ) + { + sal_uInt8 * pTmp = aBuf.data(); + if (rIStm.ReadBytes(pTmp, nAlignedWidth) + != nAlignedWidth) + { + return false; + } + sal_uInt8 cTmp = *pTmp++; + Scanline pScanline = rAcc.GetScanline(nY); + for( long nX = 0, nShift = 8; nX < nWidth; nX++ ) + { + if( !nShift ) + { + nShift = 8; + cTmp = *pTmp++; + } + + auto nIndex = (cTmp >> --nShift) & 1; + rAcc.SetPixelOnData(pScanline, nX, SanitizePaletteIndex(nIndex, rPalette, bForceToMonoWhileReading)); + } + } + } + break; + + case 4: + { + for( ; nCount--; nY += nI ) + { + sal_uInt8 * pTmp = aBuf.data(); + if (rIStm.ReadBytes(pTmp, nAlignedWidth) + != nAlignedWidth) + { + return false; + } + sal_uInt8 cTmp = *pTmp++; + Scanline pScanline = rAcc.GetScanline(nY); + for( long nX = 0, nShift = 2; nX < nWidth; nX++ ) + { + if( !nShift ) + { + nShift = 2; + cTmp = *pTmp++; + } + + auto nIndex = (cTmp >> ( --nShift << 2 ) ) & 0x0f; + rAcc.SetPixelOnData(pScanline, nX, SanitizePaletteIndex(nIndex, rPalette, bForceToMonoWhileReading)); + } + } + } + break; + + case 8: + { + for( ; nCount--; nY += nI ) + { + sal_uInt8 * pTmp = aBuf.data(); + if (rIStm.ReadBytes(pTmp, nAlignedWidth) + != nAlignedWidth) + { + return false; + } + + Scanline pScanline = rAcc.GetScanline(nY); + for( long nX = 0; nX < nWidth; nX++ ) + { + auto nIndex = *pTmp++; + rAcc.SetPixelOnData(pScanline, nX, SanitizePaletteIndex(nIndex, rPalette, bForceToMonoWhileReading)); + } + } + } + break; + + case 16: + { + ColorMaskElement aRedMask(nRMask); + if (!aRedMask.CalcMaskShift()) + return false; + ColorMaskElement aGreenMask(nGMask); + if (!aGreenMask.CalcMaskShift()) + return false; + ColorMaskElement aBlueMask(nBMask); + if (!aBlueMask.CalcMaskShift()) + return false; + + ColorMask aMask(aRedMask, aGreenMask, aBlueMask); + BitmapColor aColor; + + for( ; nCount--; nY += nI ) + { + sal_uInt16 * pTmp16 = reinterpret_cast<sal_uInt16*>(aBuf.data()); + if (rIStm.ReadBytes(pTmp16, nAlignedWidth) + != nAlignedWidth) + { + return false; + } + + Scanline pScanline = rAcc.GetScanline(nY); + for( long nX = 0; nX < nWidth; nX++ ) + { + aMask.GetColorFor16BitLSB( aColor, reinterpret_cast<sal_uInt8*>(pTmp16++) ); + rAcc.SetPixelOnData(pScanline, nX, SanitizeColor(aColor, bForceToMonoWhileReading)); + } + } + } + break; + + case 24: + { + BitmapColor aPixelColor; + + for( ; nCount--; nY += nI ) + { + sal_uInt8* pTmp = aBuf.data(); + if (rIStm.ReadBytes(pTmp, nAlignedWidth) + != nAlignedWidth) + { + return false; + } + + Scanline pScanline = rAcc.GetScanline(nY); + for( long nX = 0; nX < nWidth; nX++ ) + { + aPixelColor.SetBlue( *pTmp++ ); + aPixelColor.SetGreen( *pTmp++ ); + aPixelColor.SetRed( *pTmp++ ); + rAcc.SetPixelOnData(pScanline, nX, SanitizeColor(aPixelColor, bForceToMonoWhileReading)); + } + } + } + break; + + case 32: + { + ColorMaskElement aRedMask(nRMask); + if (!aRedMask.CalcMaskShift()) + return false; + ColorMaskElement aGreenMask(nGMask); + if (!aGreenMask.CalcMaskShift()) + return false; + ColorMaskElement aBlueMask(nBMask); + if (!aBlueMask.CalcMaskShift()) + return false; + ColorMask aMask(aRedMask, aGreenMask, aBlueMask); + + BitmapColor aColor; + sal_uInt32* pTmp32; + + if(pAccAlpha) + { + sal_uInt8 aAlpha; + + for( ; nCount--; nY += nI ) + { + pTmp32 = reinterpret_cast<sal_uInt32*>(aBuf.data()); + if (rIStm.ReadBytes(pTmp32, nAlignedWidth) + != nAlignedWidth) + { + return false; + } + + Scanline pScanline = rAcc.GetScanline(nY); + Scanline pAlphaScanline = pAccAlpha->GetScanline(nY); + for( long nX = 0; nX < nWidth; nX++ ) + { + aMask.GetColorAndAlphaFor32Bit( aColor, aAlpha, reinterpret_cast<sal_uInt8*>(pTmp32++) ); + rAcc.SetPixelOnData(pScanline, nX, SanitizeColor(aColor, bForceToMonoWhileReading)); + pAccAlpha->SetPixelOnData(pAlphaScanline, nX, BitmapColor(sal_uInt8(0xff) - aAlpha)); + rAlphaUsed |= 0xff != aAlpha; + } + } + } + else + { + for( ; nCount--; nY += nI ) + { + pTmp32 = reinterpret_cast<sal_uInt32*>(aBuf.data()); + if (rIStm.ReadBytes(pTmp32, nAlignedWidth) + != nAlignedWidth) + { + return false; + } + + Scanline pScanline = rAcc.GetScanline(nY); + for( long nX = 0; nX < nWidth; nX++ ) + { + aMask.GetColorFor32Bit( aColor, reinterpret_cast<sal_uInt8*>(pTmp32++) ); + rAcc.SetPixelOnData(pScanline, nX, SanitizeColor(aColor, bForceToMonoWhileReading)); + } + } + } + } + } + } + } + + return rIStm.GetError() == ERRCODE_NONE; +} + +bool ImplReadDIBBody(SvStream& rIStm, Bitmap& rBmp, AlphaMask* pBmpAlpha, sal_uLong nOffset, bool bIsMask, bool bMSOFormat) +{ + DIBV5Header aHeader; + const sal_uLong nStmPos = rIStm.Tell(); + bool bTopDown(false); + + if (!ImplReadDIBInfoHeader(rIStm, aHeader, bTopDown, bMSOFormat)) + return false; + + //BI_BITCOUNT_0 jpeg/png is unsupported + if (aHeader.nBitCount == 0) + return false; + + if (aHeader.nWidth <= 0 || aHeader.nHeight <= 0) + return false; + + // In case ImplReadDIB() didn't call ImplReadDIBFileHeader() before + // this method, nOffset is 0, that's OK. + if (nOffset && aHeader.nSize > nOffset) + { + // Header size claims to extend into the image data. + // Looks like an error. + return false; + } + + sal_uInt16 nColors(0); + SvStream* pIStm; + std::unique_ptr<SvMemoryStream> pMemStm; + std::vector<sal_uInt8> aData; + + if (aHeader.nBitCount <= 8) + { + if(aHeader.nColsUsed) + { + nColors = static_cast<sal_uInt16>(aHeader.nColsUsed); + } + else + { + nColors = ( 1 << aHeader.nBitCount ); + } + } + + if (ZCOMPRESS == aHeader.nCompression) + { + sal_uInt32 nCodedSize(0); + sal_uInt32 nUncodedSize(0); + + // read coding information + rIStm.ReadUInt32( nCodedSize ).ReadUInt32( nUncodedSize ).ReadUInt32( aHeader.nCompression ); + if (nCodedSize > rIStm.remainingSize()) + nCodedSize = sal_uInt32(rIStm.remainingSize()); + + pMemStm.reset(new SvMemoryStream); + // There may be bytes left over or the codec might read more than + // necessary. So to preserve the correctness of the source stream copy + // the encoded block + pMemStm->WriteStream(rIStm, nCodedSize); + pMemStm->Seek(0); + + size_t nSizeInc(4 * pMemStm->remainingSize()); + if (nUncodedSize < nSizeInc) + nSizeInc = nUncodedSize; + + if (nSizeInc > 0) + { + // decode buffer + ZCodec aCodec; + aCodec.BeginCompression(); + aData.resize(nSizeInc); + size_t nDataPos(0); + while (nUncodedSize > nDataPos) + { + assert(aData.size() > nDataPos); + const size_t nToRead(std::min<size_t>(nUncodedSize - nDataPos, aData.size() - nDataPos)); + assert(nToRead > 0); + assert(!aData.empty()); + const long nRead = aCodec.Read(*pMemStm, aData.data() + nDataPos, sal_uInt32(nToRead)); + if (nRead > 0) + { + nDataPos += static_cast<unsigned long>(nRead); + // we haven't read everything yet: resize buffer and continue + if (nDataPos < nUncodedSize) + aData.resize(aData.size() + nSizeInc); + } + else + { + break; + } + } + // truncate the data buffer to actually read size + aData.resize(nDataPos); + // set the real uncoded size + nUncodedSize = sal_uInt32(aData.size()); + aCodec.EndCompression(); + } + + if (aData.empty()) + { + // add something so we can take address of the first element + aData.resize(1); + nUncodedSize = 0; + } + + // set decoded bytes to memory stream, + // from which we will read the bitmap data + pMemStm.reset(new SvMemoryStream); + pIStm = pMemStm.get(); + assert(!aData.empty()); + pMemStm->SetBuffer(aData.data(), nUncodedSize, nUncodedSize); + nOffset = 0; + } + else + { + pIStm = &rIStm; + } + + // read palette + BitmapPalette aPalette; + if (nColors) + { + aPalette.SetEntryCount(nColors); + ImplReadDIBPalette(*pIStm, aPalette, aHeader.nSize != DIBCOREHEADERSIZE); + } + + if (pIStm->GetError()) + return false; + + if (nOffset) + { + pIStm->SeekRel(nOffset - (pIStm->Tell() - nStmPos)); + } + + const sal_Int64 nBitsPerLine (static_cast<sal_Int64>(aHeader.nWidth) * static_cast<sal_Int64>(aHeader.nBitCount)); + if (nBitsPerLine > SAL_MAX_UINT32) + return false; + const sal_uInt64 nAlignedWidth(AlignedWidth4Bytes(static_cast<sal_uLong>(nBitsPerLine))); + + switch (aHeader.nCompression) + { + case RLE_8: + { + if (aHeader.nBitCount != 8) + return false; + // (partially) check the image dimensions to avoid potential large bitmap allocation if the input is damaged + sal_uInt64 nMaxWidth = pIStm->remainingSize(); + nMaxWidth *= 256; //assume generous compression ratio + nMaxWidth /= aHeader.nHeight; + if (nMaxWidth < o3tl::make_unsigned(aHeader.nWidth)) + return false; + break; + } + case RLE_4: + { + if (aHeader.nBitCount != 4) + return false; + sal_uInt64 nMaxWidth = pIStm->remainingSize(); + nMaxWidth *= 512; //assume generous compression ratio + nMaxWidth /= aHeader.nHeight; + if (nMaxWidth < o3tl::make_unsigned(aHeader.nWidth)) + return false; + break; + } + default: + // tdf#122958 invalid compression value used + if (aHeader.nCompression & 0x000F) + { + // lets assume that there was an error in the generating application + // and allow through as COMPRESS_NONE if the bottom byte is 0 + SAL_WARN( "vcl", "bad bmp compression scheme: " << aHeader.nCompression << ", rejecting bmp"); + return false; + } + else + SAL_WARN( "vcl", "bad bmp compression scheme: " << aHeader.nCompression << ", assuming meant to be COMPRESS_NONE"); + [[fallthrough]]; + case BITFIELDS: + case ZCOMPRESS: + case COMPRESS_NONE: + { + // (partially) check the image dimensions to avoid potential large bitmap allocation if the input is damaged + sal_uInt64 nMaxWidth = pIStm->remainingSize(); + nMaxWidth /= aHeader.nHeight; + if (nMaxWidth < nAlignedWidth) + return false; + break; + } + } + + const Size aSizePixel(aHeader.nWidth, aHeader.nHeight); + AlphaMask aNewBmpAlpha; + AlphaScopedWriteAccess pAccAlpha; + bool bAlphaPossible(pBmpAlpha && aHeader.nBitCount == 32); + + if (bAlphaPossible) + { + const bool bRedSet(0 != aHeader.nV5RedMask); + const bool bGreenSet(0 != aHeader.nV5GreenMask); + const bool bBlueSet(0 != aHeader.nV5BlueMask); + + // some clipboard entries have alpha mask on zero to say that there is + // no alpha; do only use this when the other masks are set. The MS docu + // says that masks are only to be set when bV5Compression is set to + // BI_BITFIELDS, but there seem to exist a wild variety of usages... + if((bRedSet || bGreenSet || bBlueSet) && (0 == aHeader.nV5AlphaMask)) + { + bAlphaPossible = false; + } + } + + if (bAlphaPossible) + { + aNewBmpAlpha = AlphaMask(aSizePixel); + pAccAlpha = AlphaScopedWriteAccess(aNewBmpAlpha); + } + + sal_uInt16 nBitCount(discretizeBitcount(aHeader.nBitCount)); + const BitmapPalette* pPal = &aPalette; + //ofz#948 match the surrounding logic of case TransparentType::Bitmap of + //ReadDIBBitmapEx but do it while reading for performance + const bool bIsAlpha = (nBitCount == 8 && !!aPalette && aPalette.IsGreyPalette8Bit()); + const bool bForceToMonoWhileReading = (bIsMask && !bIsAlpha && nBitCount != 1); + if (bForceToMonoWhileReading) + { + pPal = nullptr; + nBitCount = 1; + SAL_WARN( "vcl", "forcing mask to monochrome"); + } + + Bitmap aNewBmp(aSizePixel, nBitCount, pPal); + BitmapScopedWriteAccess pAcc(aNewBmp); + if (!pAcc) + return false; + if (pAcc->Width() != aHeader.nWidth || pAcc->Height() != aHeader.nHeight) + { + return false; + } + + // read bits + bool bAlphaUsed(false); + bool bRet = ImplReadDIBBits(*pIStm, aHeader, *pAcc, aPalette, pAccAlpha.get(), bTopDown, bAlphaUsed, nAlignedWidth, bForceToMonoWhileReading); + + if (bRet && aHeader.nXPelsPerMeter && aHeader.nYPelsPerMeter) + { + MapMode aMapMode( + MapUnit::MapMM, + Point(), + Fraction(1000, aHeader.nXPelsPerMeter), + Fraction(1000, aHeader.nYPelsPerMeter)); + + aNewBmp.SetPrefMapMode(aMapMode); + aNewBmp.SetPrefSize(Size(aHeader.nWidth, aHeader.nHeight)); + } + + pAcc.reset(); + + if (bAlphaPossible) + { + pAccAlpha.reset(); + + if(!bAlphaUsed) + { + bAlphaPossible = false; + } + } + + if (bRet) + { + rBmp = aNewBmp; + + if(bAlphaPossible) + { + *pBmpAlpha = aNewBmpAlpha; + } + } + + return bRet; +} + +bool ImplReadDIBFileHeader( SvStream& rIStm, sal_uLong& rOffset ) +{ + bool bRet = false; + + const sal_uInt64 nStreamLength = rIStm.TellEnd(); + + sal_uInt16 nTmp16 = 0; + rIStm.ReadUInt16( nTmp16 ); + + if ( ( 0x4D42 == nTmp16 ) || ( 0x4142 == nTmp16 ) ) + { + sal_uInt32 nTmp32(0); + if ( 0x4142 == nTmp16 ) + { + rIStm.SeekRel( 12 ); + rIStm.ReadUInt16( nTmp16 ); + rIStm.SeekRel( 8 ); + rIStm.ReadUInt32( nTmp32 ); + rOffset = nTmp32 - 28; + bRet = ( 0x4D42 == nTmp16 ); + } + else // 0x4D42 == nTmp16, 'MB' from BITMAPFILEHEADER + { + rIStm.SeekRel( 8 ); // we are on bfSize member of BITMAPFILEHEADER, forward to bfOffBits + rIStm.ReadUInt32( nTmp32 ); // read bfOffBits + rOffset = nTmp32 - 14; // adapt offset by sizeof(BITMAPFILEHEADER) + bRet = rIStm.GetError() == ERRCODE_NONE; + } + + if ( rOffset >= nStreamLength ) + { + // Offset claims that image starts past the end of the + // stream. Unlikely. + rIStm.SetError( SVSTREAM_FILEFORMAT_ERROR ); + bRet = false; + } + } + else + rIStm.SetError( SVSTREAM_FILEFORMAT_ERROR ); + + return bRet; +} + +bool ImplWriteDIBPalette( SvStream& rOStm, BitmapReadAccess const & rAcc ) +{ + const sal_uInt16 nColors = rAcc.GetPaletteEntryCount(); + const sal_uLong nPalSize = nColors * 4UL; + std::unique_ptr<sal_uInt8[]> pEntries(new sal_uInt8[ nPalSize ]); + sal_uInt8* pTmpEntry = pEntries.get(); + + for( sal_uInt16 i = 0; i < nColors; i++ ) + { + const BitmapColor& rPalColor = rAcc.GetPaletteColor( i ); + + *pTmpEntry++ = rPalColor.GetBlue(); + *pTmpEntry++ = rPalColor.GetGreen(); + *pTmpEntry++ = rPalColor.GetRed(); + *pTmpEntry++ = 0; + } + + rOStm.WriteBytes( pEntries.get(), nPalSize ); + + return rOStm.GetError() == ERRCODE_NONE; +} + +bool ImplWriteRLE( SvStream& rOStm, BitmapReadAccess const & rAcc, bool bRLE4 ) +{ + const sal_uLong nWidth = rAcc.Width(); + const sal_uLong nHeight = rAcc.Height(); + sal_uLong nX; + sal_uLong nSaveIndex; + sal_uLong nCount; + sal_uLong nBufCount; + std::vector<sal_uInt8> aBuf(( nWidth << 1 ) + 2); + sal_uInt8 cPix; + sal_uInt8 cLast; + bool bFound; + + for ( long nY = nHeight - 1; nY >= 0; nY-- ) + { + sal_uInt8* pTmp = aBuf.data(); + nX = nBufCount = 0; + Scanline pScanline = rAcc.GetScanline( nY ); + + while( nX < nWidth ) + { + nCount = 1; + cPix = rAcc.GetIndexFromData( pScanline, nX++ ); + + while( ( nX < nWidth ) && ( nCount < 255 ) + && ( cPix == rAcc.GetIndexFromData( pScanline, nX ) ) ) + { + nX++; + nCount++; + } + + if ( nCount > 1 ) + { + *pTmp++ = static_cast<sal_uInt8>(nCount); + *pTmp++ = ( bRLE4 ? ( ( cPix << 4 ) | cPix ) : cPix ); + nBufCount += 2; + } + else + { + cLast = cPix; + nSaveIndex = nX - 1; + bFound = false; + + while( ( nX < nWidth ) && ( nCount < 256 ) ) + { + cPix = rAcc.GetIndexFromData( pScanline, nX ); + if (cPix == cLast) + break; + nX++; nCount++; + cLast = cPix; + bFound = true; + } + + if ( bFound ) + nX--; + + if ( nCount > 3 ) + { + *pTmp++ = 0; + *pTmp++ = static_cast<sal_uInt8>(--nCount); + + if( bRLE4 ) + { + for ( sal_uLong i = 0; i < nCount; i++, pTmp++ ) + { + *pTmp = rAcc.GetIndexFromData( pScanline, nSaveIndex++ ) << 4; + + if ( ++i < nCount ) + *pTmp |= rAcc.GetIndexFromData( pScanline, nSaveIndex++ ); + } + + nCount = ( nCount + 1 ) >> 1; + } + else + { + for( sal_uLong i = 0; i < nCount; i++ ) + *pTmp++ = rAcc.GetIndexFromData( pScanline, nSaveIndex++ ); + } + + if ( nCount & 1 ) + { + *pTmp++ = 0; + nBufCount += ( nCount + 3 ); + } + else + nBufCount += ( nCount + 2 ); + } + else + { + *pTmp++ = 1; + *pTmp++ = rAcc.GetIndexFromData( pScanline, nSaveIndex ) << (bRLE4 ? 4 : 0); + + if ( nCount == 3 ) + { + *pTmp++ = 1; + *pTmp++ = rAcc.GetIndexFromData( pScanline, ++nSaveIndex ) << ( bRLE4 ? 4 : 0 ); + nBufCount += 4; + } + else + nBufCount += 2; + } + } + } + + aBuf[ nBufCount++ ] = 0; + aBuf[ nBufCount++ ] = 0; + + rOStm.WriteBytes(aBuf.data(), nBufCount); + } + + rOStm.WriteUChar( 0 ); + rOStm.WriteUChar( 1 ); + + return rOStm.GetError() == ERRCODE_NONE; +} + +bool ImplWriteDIBBits(SvStream& rOStm, BitmapReadAccess const & rAcc, BitmapReadAccess const * pAccAlpha, sal_uLong nCompression, sal_uInt32& rImageSize) +{ + if(!pAccAlpha && BITFIELDS == nCompression) + { + const ColorMask& rMask = rAcc.GetColorMask(); + SVBT32 aVal32; + + UInt32ToSVBT32( rMask.GetRedMask(), aVal32 ); + rOStm.WriteBytes( aVal32, 4UL ); + + UInt32ToSVBT32( rMask.GetGreenMask(), aVal32 ); + rOStm.WriteBytes( aVal32, 4UL ); + + UInt32ToSVBT32( rMask.GetBlueMask(), aVal32 ); + rOStm.WriteBytes( aVal32, 4UL ); + + rImageSize = rOStm.Tell(); + + if( rAcc.IsBottomUp() ) + rOStm.WriteBytes(rAcc.GetBuffer(), rAcc.Height() * rAcc.GetScanlineSize()); + else + { + for( long nY = rAcc.Height() - 1, nScanlineSize = rAcc.GetScanlineSize(); nY >= 0; nY-- ) + rOStm.WriteBytes( rAcc.GetScanline(nY), nScanlineSize ); + } + } + else if(!pAccAlpha && ((RLE_4 == nCompression) || (RLE_8 == nCompression))) + { + rImageSize = rOStm.Tell(); + ImplWriteRLE( rOStm, rAcc, RLE_4 == nCompression ); + } + else if(!nCompression) + { + // #i5xxx# Limit bitcount to 24bit, the 32 bit cases are not + // handled properly below (would have to set color masks, and + // nCompression=BITFIELDS - but color mask is not set for + // formats != *_TC_*). Note that this very problem might cause + // trouble at other places - the introduction of 32 bit RGBA + // bitmaps is relatively recent. + // #i59239# discretize bitcount for aligned width to 1,4,8,24 + // (other cases are not written below) + const sal_uInt16 nBitCount(pAccAlpha ? 32 : discretizeBitcount(rAcc.GetBitCount())); + const sal_uLong nAlignedWidth(AlignedWidth4Bytes(rAcc.Width() * nBitCount)); + bool bNative(false); + + switch(rAcc.GetScanlineFormat()) + { + case ScanlineFormat::N1BitMsbPal: + case ScanlineFormat::N4BitMsnPal: + case ScanlineFormat::N8BitPal: + case ScanlineFormat::N24BitTcBgr: + { + if(!pAccAlpha && rAcc.IsBottomUp() && (rAcc.GetScanlineSize() == nAlignedWidth)) + { + bNative = true; + } + + break; + } + + default: + { + break; + } + } + + rImageSize = rOStm.Tell(); + + if(bNative) + { + rOStm.WriteBytes(rAcc.GetBuffer(), nAlignedWidth * rAcc.Height()); + } + else + { + const long nWidth(rAcc.Width()); + const long nHeight(rAcc.Height()); + std::vector<sal_uInt8> aBuf(nAlignedWidth); + switch( nBitCount ) + { + case 1: + { + //valgrind, zero out the trailing unused alignment bytes + size_t nUnusedBytes = nAlignedWidth - ((nWidth+7) / 8); + memset(aBuf.data() + nAlignedWidth - nUnusedBytes, 0, nUnusedBytes); + + for( long nY = nHeight - 1; nY >= 0; nY-- ) + { + sal_uInt8* pTmp = aBuf.data(); + sal_uInt8 cTmp = 0; + Scanline pScanline = rAcc.GetScanline( nY ); + + for( long nX = 0, nShift = 8; nX < nWidth; nX++ ) + { + if( !nShift ) + { + nShift = 8; + *pTmp++ = cTmp; + cTmp = 0; + } + + cTmp |= rAcc.GetIndexFromData( pScanline, nX ) << --nShift; + } + + *pTmp = cTmp; + rOStm.WriteBytes(aBuf.data(), nAlignedWidth); + } + } + break; + + case 4: + { + //valgrind, zero out the trailing unused alignment bytes + size_t nUnusedBytes = nAlignedWidth - ((nWidth+1) / 2); + memset(aBuf.data() + nAlignedWidth - nUnusedBytes, 0, nUnusedBytes); + + for( long nY = nHeight - 1; nY >= 0; nY-- ) + { + sal_uInt8* pTmp = aBuf.data(); + sal_uInt8 cTmp = 0; + Scanline pScanline = rAcc.GetScanline( nY ); + + for( long nX = 0, nShift = 2; nX < nWidth; nX++ ) + { + if( !nShift ) + { + nShift = 2; + *pTmp++ = cTmp; + cTmp = 0; + } + + cTmp |= rAcc.GetIndexFromData( pScanline, nX ) << ( --nShift << 2 ); + } + *pTmp = cTmp; + rOStm.WriteBytes(aBuf.data(), nAlignedWidth); + } + } + break; + + case 8: + { + for( long nY = nHeight - 1; nY >= 0; nY-- ) + { + sal_uInt8* pTmp = aBuf.data(); + Scanline pScanline = rAcc.GetScanline( nY ); + + for( long nX = 0; nX < nWidth; nX++ ) + *pTmp++ = rAcc.GetIndexFromData( pScanline, nX ); + + rOStm.WriteBytes(aBuf.data(), nAlignedWidth); + } + } + break; + + case 24: + { + //valgrind, zero out the trailing unused alignment bytes + size_t nUnusedBytes = nAlignedWidth - nWidth * 3; + memset(aBuf.data() + nAlignedWidth - nUnusedBytes, 0, nUnusedBytes); + } + [[fallthrough]]; + // #i59239# fallback to 24 bit format, if bitcount is non-default + default: + { + BitmapColor aPixelColor; + const bool bWriteAlpha(32 == nBitCount && pAccAlpha); + + for( long nY = nHeight - 1; nY >= 0; nY-- ) + { + sal_uInt8* pTmp = aBuf.data(); + Scanline pScanlineAlpha = bWriteAlpha ? pAccAlpha->GetScanline( nY ) : nullptr; + + for( long nX = 0; nX < nWidth; nX++ ) + { + // when alpha is used, this may be non-24bit main bitmap, so use GetColor + // instead of GetPixel to ensure RGB value + aPixelColor = rAcc.GetColor( nY, nX ); + + *pTmp++ = aPixelColor.GetBlue(); + *pTmp++ = aPixelColor.GetGreen(); + *pTmp++ = aPixelColor.GetRed(); + + if(bWriteAlpha) + { + *pTmp++ = sal_uInt8(0xff) - pAccAlpha->GetIndexFromData( pScanlineAlpha, nX ); + } + } + + rOStm.WriteBytes(aBuf.data(), nAlignedWidth); + } + } + break; + } + } + } + + rImageSize = rOStm.Tell() - rImageSize; + + return (!rOStm.GetError()); +} + +bool ImplWriteDIBBody(const Bitmap& rBitmap, SvStream& rOStm, BitmapReadAccess const & rAcc, BitmapReadAccess const * pAccAlpha, bool bCompressed) +{ + const MapMode aMapPixel(MapUnit::MapPixel); + DIBV5Header aHeader; + sal_uLong nImageSizePos(0); + sal_uLong nEndPos(0); + sal_uInt32 nCompression(COMPRESS_NONE); + bool bRet(false); + + aHeader.nSize = pAccAlpha ? DIBV5HEADERSIZE : DIBINFOHEADERSIZE; // size dependent on CF_DIB type to use + aHeader.nWidth = rAcc.Width(); + aHeader.nHeight = rAcc.Height(); + aHeader.nPlanes = 1; + + if(!pAccAlpha && isBitfieldCompression(rAcc.GetScanlineFormat())) + { + aHeader.nBitCount = 32; + aHeader.nSizeImage = rAcc.Height() * rAcc.GetScanlineSize(); + nCompression = BITFIELDS; + } + else + { + // #i5xxx# Limit bitcount to 24bit, the 32 bit cases are + // not handled properly below (would have to set color + // masks, and nCompression=BITFIELDS - but color mask is + // not set for formats != *_TC_*). Note that this very + // problem might cause trouble at other places - the + // introduction of 32 bit RGBA bitmaps is relatively + // recent. + // #i59239# discretize bitcount to 1,4,8,24 (other cases + // are not written below) + const sal_uInt16 nBitCount(pAccAlpha ? 32 : discretizeBitcount(rAcc.GetBitCount())); + aHeader.nBitCount = nBitCount; + aHeader.nSizeImage = rAcc.Height() * AlignedWidth4Bytes(rAcc.Width() * aHeader.nBitCount); + + if(bCompressed) + { + if(4 == nBitCount) + { + nCompression = RLE_4; + } + else if(8 == nBitCount) + { + nCompression = RLE_8; + } + } + } + + if((rOStm.GetCompressMode() & SvStreamCompressFlags::ZBITMAP) && (rOStm.GetVersion() >= SOFFICE_FILEFORMAT_40)) + { + aHeader.nCompression = ZCOMPRESS; + } + else + { + aHeader.nCompression = nCompression; + } + + if(rBitmap.GetPrefSize().Width() && rBitmap.GetPrefSize().Height() && (rBitmap.GetPrefMapMode() != aMapPixel)) + { + // #i48108# Try to recover xpels/ypels as previously stored on + // disk. The problem with just converting maPrefSize to 100th + // mm and then relating that to the bitmap pixel size is that + // MapMode is integer-based, and suffers from roundoffs, + // especially if maPrefSize is small. Trying to circumvent + // that by performing part of the math in floating point. + const Size aScale100000(OutputDevice::LogicToLogic(Size(100000, 100000), MapMode(MapUnit::Map100thMM), rBitmap.GetPrefMapMode())); + const double fBmpWidthM(static_cast<double>(rBitmap.GetPrefSize().Width()) / aScale100000.Width()); + const double fBmpHeightM(static_cast<double>(rBitmap.GetPrefSize().Height()) / aScale100000.Height()); + + if(!basegfx::fTools::equalZero(fBmpWidthM) && !basegfx::fTools::equalZero(fBmpHeightM)) + { + aHeader.nXPelsPerMeter = basegfx::fround(rAcc.Width() / fabs(fBmpWidthM)); + aHeader.nYPelsPerMeter = basegfx::fround(rAcc.Height() / fabs(fBmpHeightM)); + } + } + + aHeader.nColsUsed = ((!pAccAlpha && aHeader.nBitCount <= 8) ? rAcc.GetPaletteEntryCount() : 0); + aHeader.nColsImportant = 0; + + rOStm.WriteUInt32( aHeader.nSize ); + rOStm.WriteInt32( aHeader.nWidth ); + rOStm.WriteInt32( aHeader.nHeight ); + rOStm.WriteUInt16( aHeader.nPlanes ); + rOStm.WriteUInt16( aHeader.nBitCount ); + rOStm.WriteUInt32( aHeader.nCompression ); + + nImageSizePos = rOStm.Tell(); + rOStm.SeekRel( sizeof( aHeader.nSizeImage ) ); + + rOStm.WriteInt32( aHeader.nXPelsPerMeter ); + rOStm.WriteInt32( aHeader.nYPelsPerMeter ); + rOStm.WriteUInt32( aHeader.nColsUsed ); + rOStm.WriteUInt32( aHeader.nColsImportant ); + + if(pAccAlpha) // only write DIBV5 when asked to do so + { + aHeader.nV5CSType = 0x57696E20; // LCS_WINDOWS_COLOR_SPACE + aHeader.nV5Intent = 0x00000004; // LCS_GM_IMAGES + + rOStm.WriteUInt32( aHeader.nV5RedMask ); + rOStm.WriteUInt32( aHeader.nV5GreenMask ); + rOStm.WriteUInt32( aHeader.nV5BlueMask ); + rOStm.WriteUInt32( aHeader.nV5AlphaMask ); + rOStm.WriteUInt32( aHeader.nV5CSType ); + + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzRed.aXyzX ); + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzRed.aXyzY ); + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzRed.aXyzZ ); + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzGreen.aXyzX ); + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzGreen.aXyzY ); + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzGreen.aXyzZ ); + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzBlue.aXyzX ); + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzBlue.aXyzY ); + rOStm.WriteInt32( aHeader.aV5Endpoints.aXyzBlue.aXyzZ ); + + rOStm.WriteUInt32( aHeader.nV5GammaRed ); + rOStm.WriteUInt32( aHeader.nV5GammaGreen ); + rOStm.WriteUInt32( aHeader.nV5GammaBlue ); + rOStm.WriteUInt32( aHeader.nV5Intent ); + rOStm.WriteUInt32( aHeader.nV5ProfileData ); + rOStm.WriteUInt32( aHeader.nV5ProfileSize ); + rOStm.WriteUInt32( aHeader.nV5Reserved ); + } + + if(ZCOMPRESS == aHeader.nCompression) + { + ZCodec aCodec; + SvMemoryStream aMemStm(aHeader.nSizeImage + 4096, 65535); + sal_uLong nCodedPos(rOStm.Tell()); + sal_uLong nLastPos(0); + sal_uInt32 nCodedSize(0); + sal_uInt32 nUncodedSize(0); + + // write uncoded data palette + if(aHeader.nColsUsed) + { + ImplWriteDIBPalette(aMemStm, rAcc); + } + + // write uncoded bits + bRet = ImplWriteDIBBits(aMemStm, rAcc, pAccAlpha, nCompression, aHeader.nSizeImage); + + // get uncoded size + nUncodedSize = aMemStm.Tell(); + + // seek over compress info + rOStm.SeekRel(12); + + // write compressed data + aCodec.BeginCompression(3); + aCodec.Write(rOStm, static_cast<sal_uInt8 const *>(aMemStm.GetData()), nUncodedSize); + aCodec.EndCompression(); + + // update compress info ( coded size, uncoded size, uncoded compression ) + nLastPos = rOStm.Tell(); + nCodedSize = nLastPos - nCodedPos - 12; + rOStm.Seek(nCodedPos); + rOStm.WriteUInt32( nCodedSize ).WriteUInt32( nUncodedSize ).WriteUInt32( nCompression ); + rOStm.Seek(nLastPos); + + if(bRet) + { + bRet = (ERRCODE_NONE == rOStm.GetError()); + } + } + else + { + if(aHeader.nColsUsed) + { + ImplWriteDIBPalette(rOStm, rAcc); + } + + bRet = ImplWriteDIBBits(rOStm, rAcc, pAccAlpha, aHeader.nCompression, aHeader.nSizeImage); + } + + nEndPos = rOStm.Tell(); + rOStm.Seek(nImageSizePos); + rOStm.WriteUInt32( aHeader.nSizeImage ); + rOStm.Seek(nEndPos); + + return bRet; +} + +bool ImplWriteDIBFileHeader(SvStream& rOStm, BitmapReadAccess const & rAcc) +{ + const sal_uInt32 nPalCount((rAcc.HasPalette() ? rAcc.GetPaletteEntryCount() : isBitfieldCompression(rAcc.GetScanlineFormat()) ? 3UL : 0UL)); + const sal_uInt32 nOffset(14 + DIBINFOHEADERSIZE + nPalCount * 4UL); + + rOStm.WriteUInt16( 0x4D42 ); // 'MB' from BITMAPFILEHEADER + rOStm.WriteUInt32( nOffset + (rAcc.Height() * rAcc.GetScanlineSize()) ); + rOStm.WriteUInt16( 0 ); + rOStm.WriteUInt16( 0 ); + rOStm.WriteUInt32( nOffset ); + + return rOStm.GetError() == ERRCODE_NONE; +} + +bool ImplReadDIB( + Bitmap& rTarget, + AlphaMask* pTargetAlpha, + SvStream& rIStm, + bool bFileHeader, + bool bIsMask=false, + bool bMSOFormat=false) +{ + const SvStreamEndian nOldFormat(rIStm.GetEndian()); + const sal_uLong nOldPos(rIStm.Tell()); + sal_uLong nOffset(0); + bool bRet(false); + + rIStm.SetEndian(SvStreamEndian::LITTLE); + + if(bFileHeader) + { + if(ImplReadDIBFileHeader(rIStm, nOffset)) + { + bRet = ImplReadDIBBody(rIStm, rTarget, nOffset >= DIBV5HEADERSIZE ? pTargetAlpha : nullptr, nOffset, bIsMask, bMSOFormat); + } + } + else + { + bRet = ImplReadDIBBody(rIStm, rTarget, nullptr, nOffset, bIsMask, bMSOFormat); + } + + if(!bRet) + { + if(!rIStm.GetError()) + { + rIStm.SetError(SVSTREAM_GENERALERROR); + } + + rIStm.Seek(nOldPos); + } + + rIStm.SetEndian(nOldFormat); + + return bRet; +} + +bool ImplWriteDIB( + const Bitmap& rSource, + SvStream& rOStm, + bool bCompressed, + bool bFileHeader) +{ + const Size aSizePix(rSource.GetSizePixel()); + bool bRet(false); + + if(aSizePix.Width() && aSizePix.Height()) + { + Bitmap::ScopedReadAccess pAcc(const_cast< Bitmap& >(rSource)); + Bitmap::ScopedReadAccess pAccAlpha; + const SvStreamEndian nOldFormat(rOStm.GetEndian()); + const sal_uLong nOldPos(rOStm.Tell()); + + rOStm.SetEndian(SvStreamEndian::LITTLE); + + if (pAcc) + { + if(bFileHeader) + { + if(ImplWriteDIBFileHeader(rOStm, *pAcc)) + { + bRet = ImplWriteDIBBody(rSource, rOStm, *pAcc, pAccAlpha.get(), bCompressed); + } + } + else + { + bRet = ImplWriteDIBBody(rSource, rOStm, *pAcc, pAccAlpha.get(), bCompressed); + } + + pAcc.reset(); + } + + pAccAlpha.reset(); + + if(!bRet) + { + rOStm.SetError(SVSTREAM_GENERALERROR); + rOStm.Seek(nOldPos); + } + + rOStm.SetEndian(nOldFormat); + } + + return bRet; +} + +} // unnamed namespace + +bool ReadDIB( + Bitmap& rTarget, + SvStream& rIStm, + bool bFileHeader, + bool bMSOFormat) +{ + return ImplReadDIB(rTarget, nullptr, rIStm, bFileHeader, false, bMSOFormat); +} + +bool ReadDIBBitmapEx( + BitmapEx& rTarget, + SvStream& rIStm, + bool bFileHeader, + bool bMSOFormat) +{ + Bitmap aBmp; + bool bRetval(ImplReadDIB(aBmp, nullptr, rIStm, bFileHeader, /*bMask*/false, bMSOFormat) && !rIStm.GetError()); + + if(bRetval) + { + // base bitmap was read, set as return value and try to read alpha extra-data + const sal_uLong nStmPos(rIStm.Tell()); + sal_uInt32 nMagic1(0); + sal_uInt32 nMagic2(0); + + rTarget = BitmapEx(aBmp); + rIStm.ReadUInt32( nMagic1 ).ReadUInt32( nMagic2 ); + bRetval = (0x25091962 == nMagic1) && (0xACB20201 == nMagic2) && !rIStm.GetError(); + + if(bRetval) + { + sal_uInt8 tmp = 0; + rIStm.ReadUChar( tmp ); + TransparentType transparent = static_cast<TransparentType>(tmp); + bRetval = !rIStm.GetError(); + + if(bRetval) + { + switch (transparent) + { + case TransparentType::Bitmap: + { + Bitmap aMask; + + bRetval = ImplReadDIB(aMask, nullptr, rIStm, true, true); + + if(bRetval) + { + if(!!aMask) + { + // do we have an alpha mask? + if((8 == aMask.GetBitCount()) && aMask.HasGreyPalette8Bit()) + { + AlphaMask aAlpha; + + // create alpha mask quickly (without greyscale conversion) + aAlpha.ImplSetBitmap(aMask); + rTarget = BitmapEx(aBmp, aAlpha); + } + else + { + rTarget = BitmapEx(aBmp, aMask); + } + } + } + break; + } + case TransparentType::Color: + { + Color aTransparentColor; + + tools::GenericTypeSerializer aSerializer(rIStm); + aSerializer.readColor(aTransparentColor); + + bRetval = !rIStm.GetError(); + + if(bRetval) + { + rTarget = BitmapEx(aBmp, aTransparentColor); + } + break; + } + default: break; + } + } + } + + if(!bRetval) + { + // alpha extra data could not be read; reset, but use base bitmap as result + rIStm.ResetError(); + rIStm.Seek(nStmPos); + bRetval = true; + } + } + + return bRetval; +} + +bool ReadDIBV5( + Bitmap& rTarget, + AlphaMask& rTargetAlpha, + SvStream& rIStm) +{ + return ImplReadDIB(rTarget, &rTargetAlpha, rIStm, true); +} + +bool ReadRawDIB( + BitmapEx& rTarget, + const unsigned char* pBuf, + const ScanlineFormat nFormat, + const int nHeight, + const int nStride) +{ + BitmapScopedWriteAccess pWriteAccess(rTarget.maBitmap.AcquireWriteAccess(), rTarget.maBitmap); + for (int nRow = 0; nRow < nHeight; ++nRow) + { + pWriteAccess->CopyScanline(nRow, pBuf + (nStride * nRow), nFormat, nStride); + } + + return true; +} + +bool WriteDIB( + const Bitmap& rSource, + SvStream& rOStm, + bool bCompressed, + bool bFileHeader) +{ + return ImplWriteDIB(rSource, rOStm, bCompressed, bFileHeader); +} + +bool WriteDIB( + const BitmapEx& rSource, + SvStream& rOStm, + bool bCompressed) +{ + return ImplWriteDIB(rSource.GetBitmap(), rOStm, bCompressed, /*bFileHeader*/true); +} + +bool WriteDIBBitmapEx( + const BitmapEx& rSource, + SvStream& rOStm) +{ + if(ImplWriteDIB(rSource.GetBitmap(), rOStm, true, true)) + { + rOStm.WriteUInt32( 0x25091962 ); + rOStm.WriteUInt32( 0xACB20201 ); + rOStm.WriteUChar( static_cast<sal_uChar>(rSource.meTransparent) ); + + if(TransparentType::Bitmap == rSource.meTransparent) + { + return ImplWriteDIB(rSource.maMask, rOStm, true, true); + } + else if(TransparentType::Color == rSource.meTransparent) + { + tools::GenericTypeSerializer aSerializer(rOStm); + aSerializer.writeColor(rSource.maTransparentColor); + return true; + } + } + + return false; +} + +sal_uInt32 getDIBV5HeaderSize() +{ + return DIBV5HEADERSIZE; +} + +/* vim:set shiftwidth=4 softtabstop=4 expandtab: */ |