/* * 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 #if defined _MSC_VER #undef min #undef max #endif WinSalBitmap::WinSalBitmap() : SalBitmap(), basegfx::SystemDependentDataHolder(), maSize(), mhDIB(nullptr), mhDDB(nullptr), mnBitCount(0) { } WinSalBitmap::~WinSalBitmap() { Destroy(); } void WinSalBitmap::Destroy() { if( mhDIB ) GlobalFree( mhDIB ); else if( mhDDB ) DeleteObject( mhDDB ); maSize = Size(); mnBitCount = 0; } namespace { class SystemDependentData_GdiPlusBitmap : public basegfx::SystemDependentData { private: std::shared_ptr mpGdiPlusBitmap; const WinSalBitmap* mpAssociatedAlpha; public: SystemDependentData_GdiPlusBitmap( const std::shared_ptr& rGdiPlusBitmap, const WinSalBitmap* pAssociatedAlpha); const WinSalBitmap* getAssociatedAlpha() const { return mpAssociatedAlpha; } const std::shared_ptr& getGdiPlusBitmap() const { return mpGdiPlusBitmap; } virtual sal_Int64 estimateUsageInBytes() const override; }; } SystemDependentData_GdiPlusBitmap::SystemDependentData_GdiPlusBitmap( const std::shared_ptr& rGdiPlusBitmap, const WinSalBitmap* pAssociatedAlpha) : basegfx::SystemDependentData(Application::GetSystemDependentDataManager()), mpGdiPlusBitmap(rGdiPlusBitmap), mpAssociatedAlpha(pAssociatedAlpha) { } sal_Int64 SystemDependentData_GdiPlusBitmap::estimateUsageInBytes() const { sal_Int64 nRetval(0); if(mpGdiPlusBitmap) { const UINT nWidth(mpGdiPlusBitmap->GetWidth()); const UINT nHeight(mpGdiPlusBitmap->GetHeight()); if(0 != nWidth && 0 != nHeight) { nRetval = nWidth * nHeight; switch(mpGdiPlusBitmap->GetPixelFormat()) { case PixelFormat1bppIndexed: nRetval /= 8; break; case PixelFormat4bppIndexed: nRetval /= 4; break; case PixelFormat16bppGrayScale: case PixelFormat16bppRGB555: case PixelFormat16bppRGB565: case PixelFormat16bppARGB1555: nRetval *= 2; break; case PixelFormat24bppRGB: nRetval *= 3; break; case PixelFormat32bppRGB: case PixelFormat32bppARGB: case PixelFormat32bppPARGB: case PixelFormat32bppCMYK: nRetval *= 4; break; case PixelFormat48bppRGB: nRetval *= 6; break; case PixelFormat64bppARGB: case PixelFormat64bppPARGB: nRetval *= 8; break; default: case PixelFormat8bppIndexed: break; } } } return nRetval; } std::shared_ptr< Gdiplus::Bitmap > WinSalBitmap::ImplGetGdiPlusBitmap(const WinSalBitmap* pAlphaSource) const { std::shared_ptr< Gdiplus::Bitmap > aRetval; // try to access buffered data std::shared_ptr pSystemDependentData_GdiPlusBitmap( getSystemDependentData()); if(pSystemDependentData_GdiPlusBitmap) { // check data validity if(pSystemDependentData_GdiPlusBitmap->getAssociatedAlpha() != pAlphaSource || 0 == maSize.Width() || 0 == maSize.Height()) { // #122350# if associated alpha with which the GDIPlus was constructed has changed // it is necessary to remove it from buffer, reset reference to it and reconstruct // data invalid, forget pSystemDependentData_GdiPlusBitmap.reset(); } } if(pSystemDependentData_GdiPlusBitmap) { // use from buffer aRetval = pSystemDependentData_GdiPlusBitmap->getGdiPlusBitmap(); } else if(!maSize.IsEmpty()) { // create and set data const WinSalBitmap* pAssociatedAlpha(nullptr); if(pAlphaSource) { aRetval = const_cast< WinSalBitmap* >(this)->ImplCreateGdiPlusBitmap(*pAlphaSource); pAssociatedAlpha = pAlphaSource; } else { aRetval = const_cast< WinSalBitmap* >(this)->ImplCreateGdiPlusBitmap(); pAssociatedAlpha = nullptr; } // add to buffering mechanism addOrReplaceSystemDependentData( aRetval, pAssociatedAlpha); } return aRetval; } std::shared_ptr WinSalBitmap::ImplCreateGdiPlusBitmap() { std::shared_ptr pRetval; WinSalBitmap* pSalRGB = this; std::unique_ptr pExtraWinSalRGB; if(!pSalRGB->ImplGethDIB()) { // we need DIB for success with AcquireBuffer, create a replacement WinSalBitmap pExtraWinSalRGB.reset(new WinSalBitmap()); pExtraWinSalRGB->Create(*pSalRGB, vcl::bitDepthToPixelFormat(pSalRGB->GetBitCount())); pSalRGB = pExtraWinSalRGB.get(); } BitmapBuffer* pRGB = pSalRGB->AcquireBuffer(BitmapAccessMode::Read); std::unique_ptr pExtraRGB; if(pRGB && ScanlineFormat::N24BitTcBgr != RemoveScanline(pRGB->mnFormat)) { // convert source bitmap to BMP_FORMAT_24BIT_TC_BGR format if not yet in that format SalTwoRect aSalTwoRect(0, 0, pRGB->mnWidth, pRGB->mnHeight, 0, 0, pRGB->mnWidth, pRGB->mnHeight); pExtraRGB = StretchAndConvert( *pRGB, aSalTwoRect, ScanlineFormat::N24BitTcBgr); pSalRGB->ReleaseBuffer(pRGB, BitmapAccessMode::Write); pRGB = pExtraRGB.get(); } if(pRGB && pRGB->mnWidth > 0 && pRGB->mnHeight > 0 && ScanlineFormat::N24BitTcBgr == RemoveScanline(pRGB->mnFormat)) { const sal_uInt32 nW(pRGB->mnWidth); const sal_uInt32 nH(pRGB->mnHeight); pRetval = std::make_shared(nW, nH, PixelFormat24bppRGB); if ( pRetval->GetLastStatus() == Gdiplus::Ok ) { sal_uInt8* pSrcRGB(pRGB->mpBits); const sal_uInt32 nExtraRGB(pRGB->mnScanlineSize - (nW * 3)); const bool bTopDown(pRGB->mnFormat & ScanlineFormat::TopDown); const Gdiplus::Rect aAllRect(0, 0, nW, nH); Gdiplus::BitmapData aGdiPlusBitmapData; pRetval->LockBits(&aAllRect, Gdiplus::ImageLockModeWrite, PixelFormat24bppRGB, &aGdiPlusBitmapData); // copy data to Gdiplus::Bitmap; format is BGR here in both cases, so memcpy is possible for(sal_uInt32 y(0); y < nH; y++) { const sal_uInt32 nYInsert(bTopDown ? y : nH - y - 1); sal_uInt8* targetPixels = static_cast(aGdiPlusBitmapData.Scan0) + (nYInsert * aGdiPlusBitmapData.Stride); memcpy(targetPixels, pSrcRGB, nW * 3); pSrcRGB += nW * 3 + nExtraRGB; } pRetval->UnlockBits(&aGdiPlusBitmapData); } else { pRetval.reset(); } } if(pExtraRGB) { // #i123478# shockingly, BitmapBuffer does not free the memory it is controlling // in its destructor, this *has to be done by hand*. Doing it here now delete[] pExtraRGB->mpBits; pExtraRGB.reset(); } else { pSalRGB->ReleaseBuffer(pRGB, BitmapAccessMode::Read); } return pRetval; } std::shared_ptr WinSalBitmap::ImplCreateGdiPlusBitmap(const WinSalBitmap& rAlphaSource) { std::shared_ptr pRetval; WinSalBitmap* pSalRGB = this; std::unique_ptr pExtraWinSalRGB; if(!pSalRGB->ImplGethDIB()) { // we need DIB for success with AcquireBuffer, create a replacement WinSalBitmap pExtraWinSalRGB.reset(new WinSalBitmap()); pExtraWinSalRGB->Create(*pSalRGB, vcl::bitDepthToPixelFormat(pSalRGB->GetBitCount())); pSalRGB = pExtraWinSalRGB.get(); } BitmapBuffer* pRGB = pSalRGB->AcquireBuffer(BitmapAccessMode::Read); std::unique_ptr pExtraRGB; if(pRGB && ScanlineFormat::N24BitTcBgr != RemoveScanline(pRGB->mnFormat)) { // convert source bitmap to canlineFormat::N24BitTcBgr format if not yet in that format SalTwoRect aSalTwoRect(0, 0, pRGB->mnWidth, pRGB->mnHeight, 0, 0, pRGB->mnWidth, pRGB->mnHeight); pExtraRGB = StretchAndConvert( *pRGB, aSalTwoRect, ScanlineFormat::N24BitTcBgr); pSalRGB->ReleaseBuffer(pRGB, BitmapAccessMode::Read); pRGB = pExtraRGB.get(); } WinSalBitmap* pSalA = const_cast< WinSalBitmap* >(&rAlphaSource); std::unique_ptr pExtraWinSalA; if(!pSalA->ImplGethDIB()) { // we need DIB for success with AcquireBuffer, create a replacement WinSalBitmap pExtraWinSalA.reset(new WinSalBitmap()); pExtraWinSalA->Create(*pSalA, vcl::bitDepthToPixelFormat(pSalA->GetBitCount())); pSalA = pExtraWinSalA.get(); } BitmapBuffer* pA = pSalA->AcquireBuffer(BitmapAccessMode::Read); std::unique_ptr pExtraA; if(pA && ScanlineFormat::N8BitPal != RemoveScanline(pA->mnFormat)) { // convert alpha bitmap to ScanlineFormat::N8BitPal format if not yet in that format SalTwoRect aSalTwoRect(0, 0, pA->mnWidth, pA->mnHeight, 0, 0, pA->mnWidth, pA->mnHeight); const BitmapPalette& rTargetPalette = Bitmap::GetGreyPalette(256); pExtraA = StretchAndConvert( *pA, aSalTwoRect, ScanlineFormat::N8BitPal, rTargetPalette); pSalA->ReleaseBuffer(pA, BitmapAccessMode::Read); pA = pExtraA.get(); } if(pRGB && pA && pRGB->mnWidth > 0 && pRGB->mnHeight > 0 && pRGB->mnWidth == pA->mnWidth && pRGB->mnHeight == pA->mnHeight && ScanlineFormat::N24BitTcBgr == RemoveScanline(pRGB->mnFormat) && ScanlineFormat::N8BitPal == RemoveScanline(pA->mnFormat)) { // we have alpha and bitmap in known formats, create GdiPlus Bitmap as 32bit ARGB const sal_uInt32 nW(pRGB->mnWidth); const sal_uInt32 nH(pRGB->mnHeight); pRetval = std::make_shared(nW, nH, PixelFormat32bppARGB); if ( pRetval->GetLastStatus() == Gdiplus::Ok ) // 2nd place to secure with new Gdiplus::Bitmap { sal_uInt8* pSrcRGB(pRGB->mpBits); sal_uInt8* pSrcA(pA->mpBits); const sal_uInt32 nExtraRGB(pRGB->mnScanlineSize - (nW * 3)); const sal_uInt32 nExtraA(pA->mnScanlineSize - nW); const bool bTopDown(pRGB->mnFormat & ScanlineFormat::TopDown); const Gdiplus::Rect aAllRect(0, 0, nW, nH); Gdiplus::BitmapData aGdiPlusBitmapData; pRetval->LockBits(&aAllRect, Gdiplus::ImageLockModeWrite, PixelFormat32bppARGB, &aGdiPlusBitmapData); // copy data to Gdiplus::Bitmap; format is BGRA; need to mix BGR from Bitmap and // A from alpha, so inner loop is needed (who invented BitmapEx..?) for(sal_uInt32 y(0); y < nH; y++) { const sal_uInt32 nYInsert(bTopDown ? y : nH - y - 1); sal_uInt8* targetPixels = static_cast(aGdiPlusBitmapData.Scan0) + (nYInsert * aGdiPlusBitmapData.Stride); for(sal_uInt32 x(0); x < nW; x++) { *targetPixels++ = *pSrcRGB++; *targetPixels++ = *pSrcRGB++; *targetPixels++ = *pSrcRGB++; *targetPixels++ = *pSrcA++; } pSrcRGB += nExtraRGB; pSrcA += nExtraA; } pRetval->UnlockBits(&aGdiPlusBitmapData); } else { pRetval.reset(); } } if(pExtraA) { // #i123478# shockingly, BitmapBuffer does not free the memory it is controlling // in its destructor, this *has to be done handish*. Doing it here now delete[] pExtraA->mpBits; pExtraA.reset(); } else { pSalA->ReleaseBuffer(pA, BitmapAccessMode::Read); } pExtraWinSalA.reset(); if(pExtraRGB) { // #i123478# shockingly, BitmapBuffer does not free the memory it is controlling // in its destructor, this *has to be done by hand*. Doing it here now delete[] pExtraRGB->mpBits; pExtraRGB.reset(); } else { pSalRGB->ReleaseBuffer(pRGB, BitmapAccessMode::Read); } pExtraWinSalRGB.reset(); return pRetval; } bool WinSalBitmap::Create( HANDLE hBitmap ) { bool bRet = true; mhDDB = static_cast( hBitmap ); if( mhDIB ) { PBITMAPINFOHEADER pBIH = static_cast(GlobalLock( mhDIB )); maSize = Size( pBIH->biWidth, pBIH->biHeight ); mnBitCount = pBIH->biBitCount; if( mnBitCount ) mnBitCount = ( mnBitCount <= 1 ) ? 1 : ( mnBitCount <= 4 ) ? 4 : ( mnBitCount <= 8 ) ? 8 : 24; GlobalUnlock( mhDIB ); } else if( mhDDB ) { BITMAP aDDBInfo; if( GetObjectW( mhDDB, sizeof( aDDBInfo ), &aDDBInfo ) ) { maSize = Size( aDDBInfo.bmWidth, aDDBInfo.bmHeight ); mnBitCount = aDDBInfo.bmPlanes * aDDBInfo.bmBitsPixel; if( mnBitCount ) { mnBitCount = ( mnBitCount <= 1 ) ? 1 : ( mnBitCount <= 4 ) ? 4 : ( mnBitCount <= 8 ) ? 8 : 24; } } else { mhDDB = nullptr; bRet = false; } } else bRet = false; return bRet; } bool WinSalBitmap::Create(const Size& rSize, vcl::PixelFormat ePixelFormat, const BitmapPalette& rPal) { bool bRet = false; mhDIB = ImplCreateDIB(rSize, ePixelFormat, rPal); if( mhDIB ) { maSize = rSize; mnBitCount = vcl::pixelFormatBitCount(ePixelFormat); bRet = true; } return bRet; } bool WinSalBitmap::Create( const SalBitmap& rSSalBitmap ) { bool bRet = false; const WinSalBitmap& rSalBitmap = static_cast(rSSalBitmap); if ( rSalBitmap.mhDIB || rSalBitmap.mhDDB ) { HANDLE hNewHdl = ImplCopyDIBOrDDB( rSalBitmap.mhDIB ? rSalBitmap.mhDIB : rSalBitmap.mhDDB, rSalBitmap.mhDIB != nullptr ); if ( hNewHdl ) { if( rSalBitmap.mhDIB ) mhDIB = static_cast(hNewHdl); else if( rSalBitmap.mhDDB ) mhDDB = static_cast(hNewHdl); maSize = rSalBitmap.maSize; mnBitCount = rSalBitmap.mnBitCount; bRet = true; } } return bRet; } bool WinSalBitmap::Create( const SalBitmap& rSSalBmp, SalGraphics* pSGraphics ) { bool bRet = false; const WinSalBitmap& rSalBmp = static_cast(rSSalBmp); WinSalGraphics* pGraphics = static_cast(pSGraphics); if( rSalBmp.mhDIB ) { PBITMAPINFO pBI = static_cast(GlobalLock( rSalBmp.mhDIB )); HDC hDC = pGraphics->getHDC(); HBITMAP hNewDDB; BITMAP aDDBInfo; PBYTE pBits = reinterpret_cast(pBI) + pBI->bmiHeader.biSize + ImplGetDIBColorCount( rSalBmp.mhDIB ) * sizeof( RGBQUAD ); if( pBI->bmiHeader.biBitCount == 1 ) { hNewDDB = CreateBitmap( pBI->bmiHeader.biWidth, pBI->bmiHeader.biHeight, 1, 1, nullptr ); if( hNewDDB ) SetDIBits( hDC, hNewDDB, 0, pBI->bmiHeader.biHeight, pBits, pBI, DIB_RGB_COLORS ); } else hNewDDB = CreateDIBitmap( hDC, &pBI->bmiHeader, CBM_INIT, pBits, pBI, DIB_RGB_COLORS ); GlobalUnlock( rSalBmp.mhDIB ); if( hNewDDB && GetObjectW( hNewDDB, sizeof( aDDBInfo ), &aDDBInfo ) ) { mhDDB = hNewDDB; maSize = Size( aDDBInfo.bmWidth, aDDBInfo.bmHeight ); mnBitCount = aDDBInfo.bmPlanes * aDDBInfo.bmBitsPixel; bRet = true; } else if( hNewDDB ) DeleteObject( hNewDDB ); } return bRet; } bool WinSalBitmap::Create(const SalBitmap& rSSalBmp, vcl::PixelFormat eNewPixelFormat) { bool bRet = false; const WinSalBitmap& rSalBmp = static_cast(rSSalBmp); if( rSalBmp.mhDDB ) { mhDIB = ImplCreateDIB( rSalBmp.maSize, eNewPixelFormat, BitmapPalette() ); if( mhDIB ) { PBITMAPINFO pBI = static_cast(GlobalLock( mhDIB )); const int nLines = static_cast(rSalBmp.maSize.Height()); HDC hDC = GetDC( nullptr ); PBYTE pBits = reinterpret_cast(pBI) + pBI->bmiHeader.biSize + ImplGetDIBColorCount( mhDIB ) * sizeof( RGBQUAD ); SalData* pSalData = GetSalData(); HPALETTE hOldPal = nullptr; if ( pSalData->mhDitherPal ) { hOldPal = SelectPalette( hDC, pSalData->mhDitherPal, TRUE ); RealizePalette( hDC ); } if( GetDIBits( hDC, rSalBmp.mhDDB, 0, nLines, pBits, pBI, DIB_RGB_COLORS ) == nLines ) { GlobalUnlock( mhDIB ); maSize = rSalBmp.maSize; mnBitCount = vcl::pixelFormatBitCount(eNewPixelFormat); bRet = true; } else { GlobalUnlock( mhDIB ); GlobalFree( mhDIB ); mhDIB = nullptr; } if( hOldPal ) SelectPalette( hDC, hOldPal, TRUE ); ReleaseDC( nullptr, hDC ); } } return bRet; } bool WinSalBitmap::Create( const css::uno::Reference< css::rendering::XBitmapCanvas >& rBitmapCanvas, Size& /*rSize*/, bool bMask ) { css::uno::Reference< css::beans::XFastPropertySet > xFastPropertySet( rBitmapCanvas, css::uno::UNO_QUERY ); if( xFastPropertySet ) { css::uno::Sequence< css::uno::Any > args; if( xFastPropertySet->getFastPropertyValue(bMask ? 2 : 1) >>= args ) { sal_Int64 aHBmp64; if( args[0] >>= aHBmp64 ) { return Create( reinterpret_cast(aHBmp64) ); } } } return false; } sal_uInt16 WinSalBitmap::ImplGetDIBColorCount( HGLOBAL hDIB ) { sal_uInt16 nColors = 0; if( hDIB ) { PBITMAPINFO pBI = static_cast(GlobalLock( hDIB )); if ( pBI->bmiHeader.biSize != sizeof( BITMAPCOREHEADER ) ) { if( pBI->bmiHeader.biBitCount <= 8 ) { if ( pBI->bmiHeader.biClrUsed ) nColors = static_cast(pBI->bmiHeader.biClrUsed); else nColors = 1 << pBI->bmiHeader.biBitCount; } } else if( reinterpret_cast(pBI)->bcBitCount <= 8 ) nColors = 1 << reinterpret_cast(pBI)->bcBitCount; GlobalUnlock( hDIB ); } return nColors; } HGLOBAL WinSalBitmap::ImplCreateDIB(const Size& rSize, vcl::PixelFormat ePixelFormat, const BitmapPalette& rPal) { HGLOBAL hDIB = nullptr; if( rSize.IsEmpty() ) return hDIB; const auto nBits = vcl::pixelFormatBitCount(ePixelFormat); // calculate bitmap size in Bytes const sal_uLong nAlignedWidth4Bytes = AlignedWidth4Bytes(nBits * rSize.Width()); const sal_uLong nImageSize = nAlignedWidth4Bytes * rSize.Height(); bool bOverflow = (nImageSize / nAlignedWidth4Bytes) != static_cast(rSize.Height()); if( bOverflow ) return hDIB; // allocate bitmap memory including header and palette sal_uInt16 nColors = 0; if (ePixelFormat <= vcl::PixelFormat::N8_BPP) nColors = vcl::numberOfColors(ePixelFormat); const sal_uLong nHeaderSize = sizeof( BITMAPINFOHEADER ) + nColors * sizeof( RGBQUAD ); bOverflow = (nHeaderSize + nImageSize) < nImageSize; if( bOverflow ) return hDIB; hDIB = GlobalAlloc( GHND, nHeaderSize + nImageSize ); if( !hDIB ) return hDIB; PBITMAPINFO pBI = static_cast( GlobalLock( hDIB ) ); PBITMAPINFOHEADER pBIH = reinterpret_cast( pBI ); pBIH->biSize = sizeof( BITMAPINFOHEADER ); pBIH->biWidth = rSize.Width(); pBIH->biHeight = rSize.Height(); pBIH->biPlanes = 1; pBIH->biBitCount = nBits; pBIH->biCompression = BI_RGB; pBIH->biSizeImage = nImageSize; pBIH->biXPelsPerMeter = 0; pBIH->biYPelsPerMeter = 0; pBIH->biClrUsed = 0; pBIH->biClrImportant = 0; if( nColors ) { // copy the palette entries if any const sal_uInt16 nMinCount = std::min( nColors, rPal.GetEntryCount() ); if( nMinCount ) memcpy( pBI->bmiColors, rPal.ImplGetColorBuffer(), nMinCount * sizeof(RGBQUAD) ); } GlobalUnlock( hDIB ); return hDIB; } HANDLE WinSalBitmap::ImplCopyDIBOrDDB( HANDLE hHdl, bool bDIB ) { HANDLE hCopy = nullptr; if ( bDIB && hHdl ) { const sal_uLong nSize = GlobalSize( hHdl ); if ( (hCopy = GlobalAlloc( GHND, nSize )) != nullptr ) { memcpy( GlobalLock( hCopy ), GlobalLock( hHdl ), nSize ); GlobalUnlock( hCopy ); GlobalUnlock( hHdl ); } } else if ( hHdl ) { BITMAP aBmp; // find out size of source bitmap GetObjectW( hHdl, sizeof( aBmp ), &aBmp ); // create destination bitmap if ( (hCopy = CreateBitmapIndirect( &aBmp )) != nullptr ) { HDC hBmpDC = CreateCompatibleDC( nullptr ); HBITMAP hBmpOld = static_cast(SelectObject( hBmpDC, hHdl )); HDC hCopyDC = CreateCompatibleDC( hBmpDC ); HBITMAP hCopyOld = static_cast(SelectObject( hCopyDC, hCopy )); BitBlt( hCopyDC, 0, 0, aBmp.bmWidth, aBmp.bmHeight, hBmpDC, 0, 0, SRCCOPY ); SelectObject( hCopyDC, hCopyOld ); DeleteDC( hCopyDC ); SelectObject( hBmpDC, hBmpOld ); DeleteDC( hBmpDC ); } } return hCopy; } BitmapBuffer* WinSalBitmap::AcquireBuffer( BitmapAccessMode /*nMode*/ ) { std::unique_ptr pBuffer; if( mhDIB ) { PBITMAPINFO pBI = static_cast(GlobalLock( mhDIB )); PBITMAPINFOHEADER pBIH = &pBI->bmiHeader; if( pBIH->biPlanes == 1 ) { pBuffer.reset(new BitmapBuffer); pBuffer->mnFormat = pBIH->biBitCount == 1 ? ScanlineFormat::N1BitMsbPal : pBIH->biBitCount == 8 ? ScanlineFormat::N8BitPal : pBIH->biBitCount == 24 ? ScanlineFormat::N24BitTcBgr : pBIH->biBitCount == 32 ? ScanlineFormat::N32BitTcMask : ScanlineFormat::NONE; if( RemoveScanline( pBuffer->mnFormat ) != ScanlineFormat::NONE ) { pBuffer->mnWidth = maSize.Width(); pBuffer->mnHeight = maSize.Height(); pBuffer->mnScanlineSize = AlignedWidth4Bytes( maSize.Width() * pBIH->biBitCount ); pBuffer->mnBitCount = static_cast(pBIH->biBitCount); if( pBuffer->mnBitCount <= 8 ) { const sal_uInt16 nPalCount = ImplGetDIBColorCount( mhDIB ); pBuffer->maPalette.SetEntryCount( nPalCount ); memcpy( pBuffer->maPalette.ImplGetColorBuffer(), pBI->bmiColors, nPalCount * sizeof( RGBQUAD ) ); pBuffer->mpBits = reinterpret_cast(pBI) + pBI->bmiHeader.biSize + nPalCount * sizeof( RGBQUAD ); } else if( ( pBIH->biBitCount == 16 ) || ( pBIH->biBitCount == 32 ) ) { sal_uLong nOffset = 0; if( pBIH->biCompression == BI_BITFIELDS ) { nOffset = 3 * sizeof( RGBQUAD ); ColorMaskElement aRedMask(*reinterpret_cast(&pBI->bmiColors[ 0 ])); aRedMask.CalcMaskShift(); ColorMaskElement aGreenMask(*reinterpret_cast(&pBI->bmiColors[ 1 ])); aGreenMask.CalcMaskShift(); ColorMaskElement aBlueMask(*reinterpret_cast(&pBI->bmiColors[ 2 ])); aBlueMask.CalcMaskShift(); pBuffer->maColorMask = ColorMask(aRedMask, aGreenMask, aBlueMask); } else if( pBIH->biBitCount == 16 ) { ColorMaskElement aRedMask(0x00007c00UL); aRedMask.CalcMaskShift(); ColorMaskElement aGreenMask(0x000003e0UL); aGreenMask.CalcMaskShift(); ColorMaskElement aBlueMask(0x0000001fUL); aBlueMask.CalcMaskShift(); pBuffer->maColorMask = ColorMask(aRedMask, aGreenMask, aBlueMask); } else { ColorMaskElement aRedMask(0x00ff0000UL); aRedMask.CalcMaskShift(); ColorMaskElement aGreenMask(0x0000ff00UL); aGreenMask.CalcMaskShift(); ColorMaskElement aBlueMask(0x000000ffUL); aBlueMask.CalcMaskShift(); pBuffer->maColorMask = ColorMask(aRedMask, aGreenMask, aBlueMask); } pBuffer->mpBits = reinterpret_cast(pBI) + pBI->bmiHeader.biSize + nOffset; } else pBuffer->mpBits = reinterpret_cast(pBI) + pBI->bmiHeader.biSize; } else { GlobalUnlock( mhDIB ); pBuffer.reset(); } } else GlobalUnlock( mhDIB ); } return pBuffer.release(); } void WinSalBitmap::ReleaseBuffer( BitmapBuffer* pBuffer, BitmapAccessMode nMode ) { if( pBuffer ) { if( mhDIB ) { if( nMode == BitmapAccessMode::Write && !!pBuffer->maPalette ) { PBITMAPINFO pBI = static_cast(GlobalLock( mhDIB )); const sal_uInt16 nCount = pBuffer->maPalette.GetEntryCount(); const sal_uInt16 nDIBColorCount = ImplGetDIBColorCount( mhDIB ); memcpy( pBI->bmiColors, pBuffer->maPalette.ImplGetColorBuffer(), std::min( nDIBColorCount, nCount ) * sizeof( RGBQUAD ) ); GlobalUnlock( mhDIB ); } GlobalUnlock( mhDIB ); } delete pBuffer; } if( nMode == BitmapAccessMode::Write ) InvalidateChecksum(); } bool WinSalBitmap::GetSystemData( BitmapSystemData& rData ) { bool bRet = false; if( mhDIB || mhDDB ) { bRet = true; rData.pDIB = mhDIB; const Size& rSize = GetSize (); rData.mnWidth = rSize.Width(); rData.mnHeight = rSize.Height(); } return bRet; } bool WinSalBitmap::ScalingSupported() const { return false; } bool WinSalBitmap::Scale( const double& /*rScaleX*/, const double& /*rScaleY*/, BmpScaleFlag /*nScaleFlag*/ ) { return false; } bool WinSalBitmap::Replace( const Color& /*rSearchColor*/, const Color& /*rReplaceColor*/, sal_uInt8 /*nTol*/ ) { return false; } const basegfx::SystemDependentDataHolder* WinSalBitmap::accessSystemDependentDataHolder() const { return this; } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */