// Copyright 2014 PDFium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Original code copyright 2014 Foxit Software Inc. http://www.foxitsoftware.com #include #include #include #include #include "core/fxcrt/fx_codepage.h" #include "core/fxcrt/fx_memory.h" #include "core/fxcrt/fx_system.h" #include "core/fxcrt/maybe_owned.h" #include "core/fxge/cfx_folderfontinfo.h" #include "core/fxge/cfx_fontmgr.h" #include "core/fxge/cfx_gemodule.h" #include "core/fxge/cfx_windowsrenderdevice.h" #include "core/fxge/dib/cfx_dibextractor.h" #include "core/fxge/dib/cfx_imagerenderer.h" #include "core/fxge/dib/cstretchengine.h" #include "core/fxge/fx_font.h" #include "core/fxge/fx_freetype.h" #include "core/fxge/systemfontinfo_iface.h" #include "core/fxge/win32/cfx_windowsdib.h" #include "core/fxge/win32/win32_int.h" #include "third_party/base/ptr_util.h" #ifndef _SKIA_SUPPORT_ #include "core/fxge/agg/fx_agg_driver.h" #endif namespace { const struct { const char* m_pFaceName; const char* m_pVariantName; // Note: UTF16-LE terminator required. } g_VariantNames[] = { {"DFKai-SB", "\x19\x6A\x77\x69\xD4\x9A\x00\x00"}, }; const struct { const char* m_pName; const char* m_pWinName; bool m_bBold; bool m_bItalic; } g_Base14Substs[] = { {"Courier", "Courier New", false, false}, {"Courier-Bold", "Courier New", true, false}, {"Courier-BoldOblique", "Courier New", true, true}, {"Courier-Oblique", "Courier New", false, true}, {"Helvetica", "Arial", false, false}, {"Helvetica-Bold", "Arial", true, false}, {"Helvetica-BoldOblique", "Arial", true, true}, {"Helvetica-Oblique", "Arial", false, true}, {"Times-Roman", "Times New Roman", false, false}, {"Times-Bold", "Times New Roman", true, false}, {"Times-BoldItalic", "Times New Roman", true, true}, {"Times-Italic", "Times New Roman", false, true}, }; struct FontNameMap { const char* m_pSubFontName; const char* m_pSrcFontName; }; const FontNameMap g_JpFontNameMap[] = { {"MS Mincho", "Heiseimin-W3"}, {"MS Gothic", "Jun101-Light"}, }; bool GetSubFontName(ByteString* name) { for (size_t i = 0; i < FX_ArraySize(g_JpFontNameMap); ++i) { if (!FXSYS_stricmp(name->c_str(), g_JpFontNameMap[i].m_pSrcFontName)) { *name = g_JpFontNameMap[i].m_pSubFontName; return true; } } return false; } bool IsGDIEnabled() { // If GDI is disabled then GetDC for the desktop will fail. HDC hdc = ::GetDC(nullptr); if (!hdc) return false; ::ReleaseDC(nullptr, hdc); return true; } HPEN CreateExtPen(const CFX_GraphStateData* pGraphState, const CFX_Matrix* pMatrix, uint32_t argb) { ASSERT(pGraphState); float scale = 1.0f; if (pMatrix) { scale = fabs(pMatrix->a) > fabs(pMatrix->b) ? fabs(pMatrix->a) : fabs(pMatrix->b); } float width = std::max(scale * pGraphState->m_LineWidth, 1.0f); uint32_t PenStyle = PS_GEOMETRIC; if (!pGraphState->m_DashArray.empty()) PenStyle |= PS_USERSTYLE; else PenStyle |= PS_SOLID; switch (pGraphState->m_LineCap) { case 0: PenStyle |= PS_ENDCAP_FLAT; break; case 1: PenStyle |= PS_ENDCAP_ROUND; break; case 2: PenStyle |= PS_ENDCAP_SQUARE; break; } switch (pGraphState->m_LineJoin) { case 0: PenStyle |= PS_JOIN_MITER; break; case 1: PenStyle |= PS_JOIN_ROUND; break; case 2: PenStyle |= PS_JOIN_BEVEL; break; } FX_COLORREF colorref = ArgbToColorRef(argb); LOGBRUSH lb; lb.lbColor = colorref; lb.lbStyle = BS_SOLID; lb.lbHatch = 0; std::vector dashes; if (!pGraphState->m_DashArray.empty()) { dashes.resize(pGraphState->m_DashArray.size()); for (size_t i = 0; i < pGraphState->m_DashArray.size(); i++) { dashes[i] = FXSYS_round( pMatrix ? pMatrix->TransformDistance(pGraphState->m_DashArray[i]) : pGraphState->m_DashArray[i]); dashes[i] = std::max(dashes[i], 1U); } } return ExtCreatePen(PenStyle, (DWORD)ceil(width), &lb, pGraphState->m_DashArray.size(), reinterpret_cast(dashes.data())); } HBRUSH CreateBrush(uint32_t argb) { return CreateSolidBrush(ArgbToColorRef(argb)); } void SetPathToDC(HDC hDC, const CFX_PathData* pPathData, const CFX_Matrix* pMatrix) { BeginPath(hDC); const std::vector& pPoints = pPathData->GetPoints(); for (size_t i = 0; i < pPoints.size(); i++) { CFX_PointF pos = pPoints[i].m_Point; if (pMatrix) pos = pMatrix->Transform(pos); CFX_Point screen(FXSYS_round(pos.x), FXSYS_round(pos.y)); FXPT_TYPE point_type = pPoints[i].m_Type; if (point_type == FXPT_TYPE::MoveTo) { MoveToEx(hDC, screen.x, screen.y, nullptr); } else if (point_type == FXPT_TYPE::LineTo) { if (pPoints[i].m_Point == pPoints[i - 1].m_Point) screen.x++; LineTo(hDC, screen.x, screen.y); } else if (point_type == FXPT_TYPE::BezierTo) { POINT lppt[3]; lppt[0].x = screen.x; lppt[0].y = screen.y; pos = pPoints[i + 1].m_Point; if (pMatrix) pos = pMatrix->Transform(pos); lppt[1].x = FXSYS_round(pos.x); lppt[1].y = FXSYS_round(pos.y); pos = pPoints[i + 2].m_Point; if (pMatrix) pos = pMatrix->Transform(pos); lppt[2].x = FXSYS_round(pos.x); lppt[2].y = FXSYS_round(pos.y); PolyBezierTo(hDC, lppt, 3); i += 2; } if (pPoints[i].m_CloseFigure) CloseFigure(hDC); } EndPath(hDC); } #ifdef _SKIA_SUPPORT_ // TODO(caryclark) This antigrain function is duplicated here to permit // removing the last remaining dependency. Eventually, this will be elminiated // altogether and replace by Skia code. struct rect_base { float x1; float y1; float x2; float y2; }; unsigned clip_liang_barsky(float x1, float y1, float x2, float y2, const rect_base& clip_box, float* x, float* y) { const float nearzero = 1e-30f; float deltax = x2 - x1; float deltay = y2 - y1; unsigned np = 0; if (deltax == 0) deltax = (x1 > clip_box.x1) ? -nearzero : nearzero; float xin, xout; if (deltax > 0) { xin = clip_box.x1; xout = clip_box.x2; } else { xin = clip_box.x2; xout = clip_box.x1; } float tinx = (xin - x1) / deltax; if (deltay == 0) deltay = (y1 > clip_box.y1) ? -nearzero : nearzero; float yin, yout; if (deltay > 0) { yin = clip_box.y1; yout = clip_box.y2; } else { yin = clip_box.y2; yout = clip_box.y1; } float tiny = (yin - y1) / deltay; float tin1, tin2; if (tinx < tiny) { tin1 = tinx; tin2 = tiny; } else { tin1 = tiny; tin2 = tinx; } if (tin1 <= 1.0f) { if (0 < tin1) { *x++ = xin; *y++ = yin; ++np; } if (tin2 <= 1.0f) { float toutx = (xout - x1) / deltax; float touty = (yout - y1) / deltay; float tout1 = (toutx < touty) ? toutx : touty; if (tin2 > 0 || tout1 > 0) { if (tin2 <= tout1) { if (tin2 > 0) { if (tinx > tiny) { *x++ = xin; *y++ = y1 + (deltay * tinx); } else { *x++ = x1 + (deltax * tiny); *y++ = yin; } ++np; } if (tout1 < 1.0f) { if (toutx < touty) { *x++ = xout; *y++ = y1 + (deltay * toutx); } else { *x++ = x1 + (deltax * touty); *y++ = yout; } } else { *x++ = x2; *y++ = y2; } ++np; } else { if (tinx > tiny) { *x++ = xin; *y++ = yout; } else { *x++ = xout; *y++ = yin; } ++np; } } } } return np; } #endif // _SKIA_SUPPORT_ class CFX_Win32FallbackFontInfo final : public CFX_FolderFontInfo { public: CFX_Win32FallbackFontInfo() {} ~CFX_Win32FallbackFontInfo() override {} // CFX_FolderFontInfo: void* MapFont(int weight, bool bItalic, int charset, int pitch_family, const char* family) override; }; class CFX_Win32FontInfo final : public SystemFontInfoIface { public: CFX_Win32FontInfo(); ~CFX_Win32FontInfo() override; // SystemFontInfoIface bool EnumFontList(CFX_FontMapper* pMapper) override; void* MapFont(int weight, bool bItalic, int charset, int pitch_family, const char* face) override; void* GetFont(const char* face) override { return nullptr; } uint32_t GetFontData(void* hFont, uint32_t table, uint8_t* buffer, uint32_t size) override; bool GetFaceName(void* hFont, ByteString* name) override; bool GetFontCharset(void* hFont, int* charset) override; void DeleteFont(void* hFont) override; bool IsOpenTypeFromDiv(const LOGFONTA* plf); bool IsSupportFontFormDiv(const LOGFONTA* plf); void AddInstalledFont(const LOGFONTA* plf, uint32_t FontType); void GetGBPreference(ByteString& face, int weight, int picth_family); void GetJapanesePreference(ByteString& face, int weight, int picth_family); ByteString FindFont(const ByteString& name); HDC m_hDC; UnownedPtr m_pMapper; ByteString m_LastFamily; ByteString m_KaiTi, m_FangSong; }; int CALLBACK FontEnumProc(const LOGFONTA* plf, const TEXTMETRICA* lpntme, uint32_t FontType, LPARAM lParam) { CFX_Win32FontInfo* pFontInfo = reinterpret_cast(lParam); pFontInfo->AddInstalledFont(plf, FontType); return 1; } CFX_Win32FontInfo::CFX_Win32FontInfo() : m_hDC(CreateCompatibleDC(nullptr)) {} CFX_Win32FontInfo::~CFX_Win32FontInfo() { DeleteDC(m_hDC); } bool CFX_Win32FontInfo::IsOpenTypeFromDiv(const LOGFONTA* plf) { HFONT hFont = CreateFontIndirectA(plf); bool ret = false; uint32_t font_size = GetFontData(hFont, 0, nullptr, 0); if (font_size != GDI_ERROR && font_size >= sizeof(uint32_t)) { uint32_t lVersion = 0; GetFontData(hFont, 0, (uint8_t*)(&lVersion), sizeof(uint32_t)); lVersion = (((uint32_t)(uint8_t)(lVersion)) << 24) | ((uint32_t)((uint8_t)(lVersion >> 8))) << 16 | ((uint32_t)((uint8_t)(lVersion >> 16))) << 8 | ((uint8_t)(lVersion >> 24)); if (lVersion == FXBSTR_ID('O', 'T', 'T', 'O') || lVersion == 0x00010000 || lVersion == FXBSTR_ID('t', 't', 'c', 'f') || lVersion == FXBSTR_ID('t', 'r', 'u', 'e') || lVersion == 0x00020000) { ret = true; } } DeleteFont(hFont); return ret; } bool CFX_Win32FontInfo::IsSupportFontFormDiv(const LOGFONTA* plf) { HFONT hFont = CreateFontIndirectA(plf); bool ret = false; uint32_t font_size = GetFontData(hFont, 0, nullptr, 0); if (font_size != GDI_ERROR && font_size >= sizeof(uint32_t)) { uint32_t lVersion = 0; GetFontData(hFont, 0, (uint8_t*)(&lVersion), sizeof(uint32_t)); lVersion = (((uint32_t)(uint8_t)(lVersion)) << 24) | ((uint32_t)((uint8_t)(lVersion >> 8))) << 16 | ((uint32_t)((uint8_t)(lVersion >> 16))) << 8 | ((uint8_t)(lVersion >> 24)); if (lVersion == FXBSTR_ID('O', 'T', 'T', 'O') || lVersion == 0x00010000 || lVersion == FXBSTR_ID('t', 't', 'c', 'f') || lVersion == FXBSTR_ID('t', 'r', 'u', 'e') || lVersion == 0x00020000 || (lVersion & 0xFFFF0000) == FXBSTR_ID(0x80, 0x01, 0x00, 0x00) || (lVersion & 0xFFFF0000) == FXBSTR_ID('%', '!', 0, 0)) { ret = true; } } DeleteFont(hFont); return ret; } void CFX_Win32FontInfo::AddInstalledFont(const LOGFONTA* plf, uint32_t FontType) { ByteString name(plf->lfFaceName); if (name.GetLength() > 0 && name[0] == '@') return; if (name == m_LastFamily) { m_pMapper->AddInstalledFont(name, plf->lfCharSet); return; } if (!(FontType & TRUETYPE_FONTTYPE)) { if (!(FontType & DEVICE_FONTTYPE) || !IsSupportFontFormDiv(plf)) return; } m_pMapper->AddInstalledFont(name, plf->lfCharSet); m_LastFamily = name; } bool CFX_Win32FontInfo::EnumFontList(CFX_FontMapper* pMapper) { m_pMapper = pMapper; LOGFONTA lf; memset(&lf, 0, sizeof(LOGFONTA)); lf.lfCharSet = FX_CHARSET_Default; lf.lfFaceName[0] = 0; lf.lfPitchAndFamily = 0; EnumFontFamiliesExA(m_hDC, &lf, (FONTENUMPROCA)FontEnumProc, (uintptr_t) this, 0); return true; } ByteString CFX_Win32FontInfo::FindFont(const ByteString& name) { if (!m_pMapper) return name; for (size_t i = 0; i < m_pMapper->m_InstalledTTFonts.size(); ++i) { ByteString thisname = m_pMapper->m_InstalledTTFonts[i]; if (thisname.Left(name.GetLength()) == name) return m_pMapper->m_InstalledTTFonts[i]; } for (size_t i = 0; i < m_pMapper->m_LocalizedTTFonts.size(); ++i) { ByteString thisname = m_pMapper->m_LocalizedTTFonts[i].first; if (thisname.Left(name.GetLength()) == name) return m_pMapper->m_LocalizedTTFonts[i].second; } return ByteString(); } void* CFX_Win32FallbackFontInfo::MapFont(int weight, bool bItalic, int charset, int pitch_family, const char* cstr_face) { void* font = GetSubstFont(cstr_face); if (font) return font; bool bCJK = true; switch (charset) { case FX_CHARSET_ShiftJIS: case FX_CHARSET_ChineseSimplified: case FX_CHARSET_ChineseTraditional: case FX_CHARSET_Hangul: break; default: bCJK = false; break; } return FindFont(weight, bItalic, charset, pitch_family, cstr_face, !bCJK); } void CFX_Win32FontInfo::GetGBPreference(ByteString& face, int weight, int picth_family) { if (face.Contains("KaiTi") || face.Contains("\xbf\xac")) { if (m_KaiTi.IsEmpty()) { m_KaiTi = FindFont("KaiTi"); if (m_KaiTi.IsEmpty()) { m_KaiTi = "SimSun"; } } face = m_KaiTi; } else if (face.Contains("FangSong") || face.Contains("\xb7\xc2\xcb\xce")) { if (m_FangSong.IsEmpty()) { m_FangSong = FindFont("FangSong"); if (m_FangSong.IsEmpty()) { m_FangSong = "SimSun"; } } face = m_FangSong; } else if (face.Contains("SimSun") || face.Contains("\xcb\xce")) { face = "SimSun"; } else if (face.Contains("SimHei") || face.Contains("\xba\xda")) { face = "SimHei"; } else if (!(picth_family & FF_ROMAN) && weight > 550) { face = "SimHei"; } else { face = "SimSun"; } } void CFX_Win32FontInfo::GetJapanesePreference(ByteString& face, int weight, int picth_family) { if (face.Contains("Gothic") || face.Contains("\x83\x53\x83\x56\x83\x62\x83\x4e")) { if (face.Contains("PGothic") || face.Contains("\x82\x6f\x83\x53\x83\x56\x83\x62\x83\x4e")) { face = "MS PGothic"; } else if (face.Contains("UI Gothic")) { face = "MS UI Gothic"; } else { if (face.Contains("HGSGothicM") || face.Contains("HGMaruGothicMPRO")) { face = "MS PGothic"; } else { face = "MS Gothic"; } } return; } if (face.Contains("Mincho") || face.Contains("\x96\xbe\x92\xa9")) { if (face.Contains("PMincho") || face.Contains("\x82\x6f\x96\xbe\x92\xa9")) { face = "MS PMincho"; } else { face = "MS Mincho"; } return; } if (GetSubFontName(&face)) return; if (!(picth_family & FF_ROMAN) && weight > 400) { face = "MS PGothic"; } else { face = "MS PMincho"; } } void* CFX_Win32FontInfo::MapFont(int weight, bool bItalic, int charset, int pitch_family, const char* cstr_face) { ByteString face = cstr_face; int iBaseFont; for (iBaseFont = 0; iBaseFont < 12; iBaseFont++) { if (face == ByteStringView(g_Base14Substs[iBaseFont].m_pName)) { face = g_Base14Substs[iBaseFont].m_pWinName; weight = g_Base14Substs[iBaseFont].m_bBold ? FW_BOLD : FW_NORMAL; bItalic = g_Base14Substs[iBaseFont].m_bItalic; break; } } if (charset == FX_CHARSET_ANSI || charset == FX_CHARSET_Symbol) charset = FX_CHARSET_Default; int subst_pitch_family = pitch_family; switch (charset) { case FX_CHARSET_ShiftJIS: subst_pitch_family = FF_ROMAN; break; case FX_CHARSET_ChineseTraditional: case FX_CHARSET_Hangul: case FX_CHARSET_ChineseSimplified: subst_pitch_family = 0; break; } HFONT hFont = ::CreateFontA(-10, 0, 0, 0, weight, bItalic, 0, 0, charset, OUT_TT_ONLY_PRECIS, 0, 0, subst_pitch_family, face.c_str()); char facebuf[100]; HFONT hOldFont = (HFONT)::SelectObject(m_hDC, hFont); ::GetTextFaceA(m_hDC, 100, facebuf); ::SelectObject(m_hDC, hOldFont); if (face.EqualNoCase(facebuf)) return hFont; WideString wsFace = WideString::FromLocal(facebuf); for (size_t i = 0; i < FX_ArraySize(g_VariantNames); ++i) { if (face != g_VariantNames[i].m_pFaceName) continue; const unsigned short* pName = reinterpret_cast( g_VariantNames[i].m_pVariantName); size_t len = WideString::WStringLength(pName); WideString wsName = WideString::FromUTF16LE(pName, len); if (wsFace == wsName) return hFont; } ::DeleteObject(hFont); if (charset == FX_CHARSET_Default) return nullptr; switch (charset) { case FX_CHARSET_ShiftJIS: GetJapanesePreference(face, weight, pitch_family); break; case FX_CHARSET_ChineseSimplified: GetGBPreference(face, weight, pitch_family); break; case FX_CHARSET_Hangul: face = "Gulim"; break; case FX_CHARSET_ChineseTraditional: if (face.Contains("MSung")) { face = "MingLiU"; } else { face = "PMingLiU"; } break; } hFont = ::CreateFontA(-10, 0, 0, 0, weight, bItalic, 0, 0, charset, OUT_TT_ONLY_PRECIS, 0, 0, subst_pitch_family, face.c_str()); return hFont; } void CFX_Win32FontInfo::DeleteFont(void* hFont) { ::DeleteObject(hFont); } uint32_t CFX_Win32FontInfo::GetFontData(void* hFont, uint32_t table, uint8_t* buffer, uint32_t size) { HFONT hOldFont = (HFONT)::SelectObject(m_hDC, (HFONT)hFont); table = FXDWORD_GET_MSBFIRST(reinterpret_cast(&table)); size = ::GetFontData(m_hDC, table, 0, buffer, size); ::SelectObject(m_hDC, hOldFont); if (size == GDI_ERROR) { return 0; } return size; } bool CFX_Win32FontInfo::GetFaceName(void* hFont, ByteString* name) { char facebuf[100]; HFONT hOldFont = (HFONT)::SelectObject(m_hDC, (HFONT)hFont); int ret = ::GetTextFaceA(m_hDC, 100, facebuf); ::SelectObject(m_hDC, hOldFont); if (ret == 0) { return false; } *name = facebuf; return true; } bool CFX_Win32FontInfo::GetFontCharset(void* hFont, int* charset) { TEXTMETRIC tm; HFONT hOldFont = (HFONT)::SelectObject(m_hDC, (HFONT)hFont); ::GetTextMetrics(m_hDC, &tm); ::SelectObject(m_hDC, hOldFont); *charset = tm.tmCharSet; return true; } } // namespace WindowsPrintMode g_pdfium_print_mode = WindowsPrintMode::kModeEmf; std::unique_ptr SystemFontInfoIface::CreateDefault( const char** pUnused) { if (IsGDIEnabled()) return std::unique_ptr(new CFX_Win32FontInfo); // Select the fallback font information class if GDI is disabled. CFX_Win32FallbackFontInfo* pInfoFallback = new CFX_Win32FallbackFontInfo; // Construct the font path manually, SHGetKnownFolderPath won't work under // a restrictive sandbox. CHAR windows_path[MAX_PATH] = {}; DWORD path_len = ::GetWindowsDirectoryA(windows_path, MAX_PATH); if (path_len > 0 && path_len < MAX_PATH) { ByteString fonts_path(windows_path); fonts_path += "\\Fonts"; pInfoFallback->AddPath(fonts_path); } return std::unique_ptr(pInfoFallback); } void CFX_GEModule::InitPlatform() { CWin32Platform* pPlatformData = new CWin32Platform; OSVERSIONINFO ver; ver.dwOSVersionInfoSize = sizeof(ver); GetVersionEx(&ver); pPlatformData->m_bHalfTone = ver.dwMajorVersion >= 5; if (IsGDIEnabled()) pPlatformData->m_GdiplusExt.Load(); m_pPlatformData = pPlatformData; m_pFontMgr->SetSystemFontInfo(SystemFontInfoIface::CreateDefault(nullptr)); } void CFX_GEModule::DestroyPlatform() { delete (CWin32Platform*)m_pPlatformData; m_pPlatformData = nullptr; } CGdiDeviceDriver::CGdiDeviceDriver(HDC hDC, int device_class) { m_hDC = hDC; m_DeviceClass = device_class; CWin32Platform* pPlatform = (CWin32Platform*)CFX_GEModule::Get()->GetPlatformData(); SetStretchBltMode(hDC, pPlatform->m_bHalfTone ? HALFTONE : COLORONCOLOR); DWORD obj_type = GetObjectType(m_hDC); m_bMetafileDCType = obj_type == OBJ_ENHMETADC || obj_type == OBJ_ENHMETAFILE; if (obj_type == OBJ_MEMDC) { HBITMAP hBitmap = CreateBitmap(1, 1, 1, 1, nullptr); hBitmap = (HBITMAP)SelectObject(m_hDC, hBitmap); BITMAP bitmap; GetObject(hBitmap, sizeof bitmap, &bitmap); m_nBitsPerPixel = bitmap.bmBitsPixel; m_Width = bitmap.bmWidth; m_Height = abs(bitmap.bmHeight); hBitmap = (HBITMAP)SelectObject(m_hDC, hBitmap); DeleteObject(hBitmap); } else { m_nBitsPerPixel = ::GetDeviceCaps(m_hDC, BITSPIXEL); m_Width = ::GetDeviceCaps(m_hDC, HORZRES); m_Height = ::GetDeviceCaps(m_hDC, VERTRES); } if (m_DeviceClass != FXDC_DISPLAY) { m_RenderCaps = FXRC_BIT_MASK; } else { m_RenderCaps = FXRC_GET_BITS | FXRC_BIT_MASK; } } CGdiDeviceDriver::~CGdiDeviceDriver() {} int CGdiDeviceDriver::GetDeviceCaps(int caps_id) const { switch (caps_id) { case FXDC_DEVICE_CLASS: return m_DeviceClass; case FXDC_PIXEL_WIDTH: return m_Width; case FXDC_PIXEL_HEIGHT: return m_Height; case FXDC_BITS_PIXEL: return m_nBitsPerPixel; case FXDC_RENDER_CAPS: return m_RenderCaps; } return 0; } void CGdiDeviceDriver::SaveState() { SaveDC(m_hDC); } void CGdiDeviceDriver::RestoreState(bool bKeepSaved) { RestoreDC(m_hDC, -1); if (bKeepSaved) SaveDC(m_hDC); } bool CGdiDeviceDriver::GDI_SetDIBits(const RetainPtr& pBitmap1, const FX_RECT* pSrcRect, int left, int top) { if (m_DeviceClass == FXDC_PRINTER) { RetainPtr pBitmap = pBitmap1->FlipImage(false, true); if (!pBitmap) return false; if (pBitmap->IsCmykImage() && !pBitmap->ConvertFormat(FXDIB_Rgb)) return false; int width = pSrcRect->Width(), height = pSrcRect->Height(); LPBYTE pBuffer = pBitmap->GetBuffer(); ByteString info = CFX_WindowsDIB::GetBitmapInfo(pBitmap); ((BITMAPINFOHEADER*)info.c_str())->biHeight *= -1; FX_RECT dst_rect(0, 0, width, height); dst_rect.Intersect(0, 0, pBitmap->GetWidth(), pBitmap->GetHeight()); int dst_width = dst_rect.Width(); int dst_height = dst_rect.Height(); ::StretchDIBits(m_hDC, left, top, dst_width, dst_height, 0, 0, dst_width, dst_height, pBuffer, (BITMAPINFO*)info.c_str(), DIB_RGB_COLORS, SRCCOPY); } else { RetainPtr pBitmap = pBitmap1; if (pBitmap->IsCmykImage()) { pBitmap = pBitmap->CloneConvert(FXDIB_Rgb); if (!pBitmap) return false; } int width = pSrcRect->Width(), height = pSrcRect->Height(); LPBYTE pBuffer = pBitmap->GetBuffer(); ByteString info = CFX_WindowsDIB::GetBitmapInfo(pBitmap); ::SetDIBitsToDevice(m_hDC, left, top, width, height, pSrcRect->left, pBitmap->GetHeight() - pSrcRect->bottom, 0, pBitmap->GetHeight(), pBuffer, (BITMAPINFO*)info.c_str(), DIB_RGB_COLORS); } return true; } bool CGdiDeviceDriver::GDI_StretchDIBits( const RetainPtr& pBitmap1, int dest_left, int dest_top, int dest_width, int dest_height, uint32_t flags) { RetainPtr pBitmap = pBitmap1; if (!pBitmap || dest_width == 0 || dest_height == 0) return false; if (pBitmap->IsCmykImage() && !pBitmap->ConvertFormat(FXDIB_Rgb)) return false; ByteString info = CFX_WindowsDIB::GetBitmapInfo(pBitmap); if ((int64_t)abs(dest_width) * abs(dest_height) < (int64_t)pBitmap1->GetWidth() * pBitmap1->GetHeight() * 4 || (flags & FXDIB_INTERPOL) || (flags & FXDIB_BICUBIC_INTERPOL)) { SetStretchBltMode(m_hDC, HALFTONE); } else { SetStretchBltMode(m_hDC, COLORONCOLOR); } RetainPtr pToStrechBitmap = pBitmap; if (m_DeviceClass == FXDC_PRINTER && ((int64_t)pBitmap->GetWidth() * pBitmap->GetHeight() > (int64_t)abs(dest_width) * abs(dest_height))) { pToStrechBitmap = pBitmap->StretchTo(dest_width, dest_height, 0, nullptr); } ByteString toStrechBitmapInfo = CFX_WindowsDIB::GetBitmapInfo(pToStrechBitmap); ::StretchDIBits(m_hDC, dest_left, dest_top, dest_width, dest_height, 0, 0, pToStrechBitmap->GetWidth(), pToStrechBitmap->GetHeight(), pToStrechBitmap->GetBuffer(), (BITMAPINFO*)toStrechBitmapInfo.c_str(), DIB_RGB_COLORS, SRCCOPY); return true; } bool CGdiDeviceDriver::GDI_StretchBitMask( const RetainPtr& pBitmap1, int dest_left, int dest_top, int dest_width, int dest_height, uint32_t bitmap_color, uint32_t flags) { RetainPtr pBitmap = pBitmap1; if (!pBitmap || dest_width == 0 || dest_height == 0) return false; int width = pBitmap->GetWidth(), height = pBitmap->GetHeight(); struct { BITMAPINFOHEADER bmiHeader; uint32_t bmiColors[2]; } bmi; memset(&bmi.bmiHeader, 0, sizeof(BITMAPINFOHEADER)); bmi.bmiHeader.biSize = sizeof(BITMAPINFOHEADER); bmi.bmiHeader.biBitCount = 1; bmi.bmiHeader.biCompression = BI_RGB; bmi.bmiHeader.biHeight = -height; bmi.bmiHeader.biPlanes = 1; bmi.bmiHeader.biWidth = width; if (m_nBitsPerPixel != 1) { SetStretchBltMode(m_hDC, HALFTONE); } bmi.bmiColors[0] = 0xffffff; bmi.bmiColors[1] = 0; HBRUSH hPattern = CreateBrush(bitmap_color); HBRUSH hOld = (HBRUSH)SelectObject(m_hDC, hPattern); // In PDF, when image mask is 1, use device bitmap; when mask is 0, use brush // bitmap. // A complete list of the boolen operations is as follows: /* P(bitmap_color) S(ImageMask) D(DeviceBitmap) Result * 0 0 0 0 * 0 0 1 0 * 0 1 0 0 * 0 1 1 1 * 1 0 0 1 * 1 0 1 1 * 1 1 0 0 * 1 1 1 1 */ // The boolen codes is B8. Based on // http://msdn.microsoft.com/en-us/library/aa932106.aspx, the ROP3 code is // 0xB8074A ::StretchDIBits(m_hDC, dest_left, dest_top, dest_width, dest_height, 0, 0, width, height, pBitmap->GetBuffer(), (BITMAPINFO*)&bmi, DIB_RGB_COLORS, 0xB8074A); SelectObject(m_hDC, hOld); DeleteObject(hPattern); return true; } bool CGdiDeviceDriver::GetClipBox(FX_RECT* pRect) { return !!(::GetClipBox(m_hDC, (RECT*)pRect)); } void CGdiDeviceDriver::DrawLine(float x1, float y1, float x2, float y2) { if (!m_bMetafileDCType) { // EMF drawing is not bound to the DC. int startOutOfBoundsFlag = (x1 < 0) | ((x1 > m_Width) << 1) | ((y1 < 0) << 2) | ((y1 > m_Height) << 3); int endOutOfBoundsFlag = (x2 < 0) | ((x2 > m_Width) << 1) | ((y2 < 0) << 2) | ((y2 > m_Height) << 3); if (startOutOfBoundsFlag & endOutOfBoundsFlag) return; if (startOutOfBoundsFlag || endOutOfBoundsFlag) { float x[2]; float y[2]; int np; #ifdef _SKIA_SUPPORT_ // TODO(caryclark) temporary replacement of antigrain in line function // to permit removing antigrain altogether rect_base rect = {0.0f, 0.0f, (float)(m_Width), (float)(m_Height)}; np = clip_liang_barsky(x1, y1, x2, y2, rect, x, y); #else agg::rect_base rect(0.0f, 0.0f, (float)(m_Width), (float)(m_Height)); np = agg::clip_liang_barsky(x1, y1, x2, y2, rect, x, y); #endif if (np == 0) return; if (np == 1) { x2 = x[0]; y2 = y[0]; } else { ASSERT(np == 2); x1 = x[0]; y1 = y[0]; x2 = x[1]; y2 = y[1]; } } } MoveToEx(m_hDC, FXSYS_round(x1), FXSYS_round(y1), nullptr); LineTo(m_hDC, FXSYS_round(x2), FXSYS_round(y2)); } bool CGdiDeviceDriver::DrawPath(const CFX_PathData* pPathData, const CFX_Matrix* pMatrix, const CFX_GraphStateData* pGraphState, uint32_t fill_color, uint32_t stroke_color, int fill_mode, BlendMode blend_type) { if (blend_type != BlendMode::kNormal) return false; CWin32Platform* pPlatform = (CWin32Platform*)CFX_GEModule::Get()->GetPlatformData(); if (!(pGraphState || stroke_color == 0) && !pPlatform->m_GdiplusExt.IsAvailable()) { CFX_FloatRect bbox_f = pPathData->GetBoundingBox(); if (pMatrix) bbox_f = pMatrix->TransformRect(bbox_f); FX_RECT bbox = bbox_f.GetInnerRect(); if (bbox.Width() <= 0) { return DrawCosmeticLine(CFX_PointF(bbox.left, bbox.top), CFX_PointF(bbox.left, bbox.bottom + 1), fill_color, BlendMode::kNormal); } if (bbox.Height() <= 0) { return DrawCosmeticLine(CFX_PointF(bbox.left, bbox.top), CFX_PointF(bbox.right + 1, bbox.top), fill_color, BlendMode::kNormal); } } int fill_alpha = FXARGB_A(fill_color); int stroke_alpha = FXARGB_A(stroke_color); bool bDrawAlpha = (fill_alpha > 0 && fill_alpha < 255) || (stroke_alpha > 0 && stroke_alpha < 255 && pGraphState); if (!pPlatform->m_GdiplusExt.IsAvailable() && bDrawAlpha) return false; if (pPlatform->m_GdiplusExt.IsAvailable()) { if (bDrawAlpha || ((m_DeviceClass != FXDC_PRINTER && !(fill_mode & FXFILL_FULLCOVER)) || (pGraphState && !pGraphState->m_DashArray.empty()))) { if (!((!pMatrix || !pMatrix->WillScale()) && pGraphState && pGraphState->m_LineWidth == 1.0f && (pPathData->GetPoints().size() == 5 || pPathData->GetPoints().size() == 4) && pPathData->IsRect())) { if (pPlatform->m_GdiplusExt.DrawPath(m_hDC, pPathData, pMatrix, pGraphState, fill_color, stroke_color, fill_mode)) { return true; } } } } int old_fill_mode = fill_mode; fill_mode &= 3; HPEN hPen = nullptr; HBRUSH hBrush = nullptr; if (pGraphState && stroke_alpha) { SetMiterLimit(m_hDC, pGraphState->m_MiterLimit, nullptr); hPen = CreateExtPen(pGraphState, pMatrix, stroke_color); hPen = (HPEN)SelectObject(m_hDC, hPen); } if (fill_mode && fill_alpha) { SetPolyFillMode(m_hDC, fill_mode); hBrush = CreateBrush(fill_color); hBrush = (HBRUSH)SelectObject(m_hDC, hBrush); } if (pPathData->GetPoints().size() == 2 && pGraphState && !pGraphState->m_DashArray.empty()) { CFX_PointF pos1 = pPathData->GetPoint(0); CFX_PointF pos2 = pPathData->GetPoint(1); if (pMatrix) { pos1 = pMatrix->Transform(pos1); pos2 = pMatrix->Transform(pos2); } DrawLine(pos1.x, pos1.y, pos2.x, pos2.y); } else { SetPathToDC(m_hDC, pPathData, pMatrix); if (pGraphState && stroke_alpha) { if (fill_mode && fill_alpha) { if (old_fill_mode & FX_FILL_TEXT_MODE) { StrokeAndFillPath(m_hDC); } else { FillPath(m_hDC); SetPathToDC(m_hDC, pPathData, pMatrix); StrokePath(m_hDC); } } else { StrokePath(m_hDC); } } else if (fill_mode && fill_alpha) { FillPath(m_hDC); } } if (hPen) { hPen = (HPEN)SelectObject(m_hDC, hPen); DeleteObject(hPen); } if (hBrush) { hBrush = (HBRUSH)SelectObject(m_hDC, hBrush); DeleteObject(hBrush); } return true; } bool CGdiDeviceDriver::FillRectWithBlend(const FX_RECT& rect, uint32_t fill_color, BlendMode blend_type) { if (blend_type != BlendMode::kNormal) return false; int alpha; FX_COLORREF colorref; std::tie(alpha, colorref) = ArgbToAlphaAndColorRef(fill_color); if (alpha == 0) return true; if (alpha < 255) return false; HBRUSH hBrush = CreateSolidBrush(colorref); const RECT* pRect = reinterpret_cast(&rect); ::FillRect(m_hDC, pRect, hBrush); DeleteObject(hBrush); return true; } bool CGdiDeviceDriver::SetClip_PathFill(const CFX_PathData* pPathData, const CFX_Matrix* pMatrix, int fill_mode) { if (pPathData->GetPoints().size() == 5) { CFX_FloatRect rectf; if (pPathData->IsRect(pMatrix, &rectf)) { FX_RECT rect = rectf.GetOuterRect(); IntersectClipRect(m_hDC, rect.left, rect.top, rect.right, rect.bottom); return true; } } SetPathToDC(m_hDC, pPathData, pMatrix); SetPolyFillMode(m_hDC, fill_mode & 3); SelectClipPath(m_hDC, RGN_AND); return true; } bool CGdiDeviceDriver::SetClip_PathStroke( const CFX_PathData* pPathData, const CFX_Matrix* pMatrix, const CFX_GraphStateData* pGraphState) { HPEN hPen = CreateExtPen(pGraphState, pMatrix, 0xff000000); hPen = (HPEN)SelectObject(m_hDC, hPen); SetPathToDC(m_hDC, pPathData, pMatrix); WidenPath(m_hDC); SetPolyFillMode(m_hDC, WINDING); bool ret = !!SelectClipPath(m_hDC, RGN_AND); hPen = (HPEN)SelectObject(m_hDC, hPen); DeleteObject(hPen); return ret; } bool CGdiDeviceDriver::DrawCosmeticLine(const CFX_PointF& ptMoveTo, const CFX_PointF& ptLineTo, uint32_t color, BlendMode blend_type) { if (blend_type != BlendMode::kNormal) return false; int alpha; FX_COLORREF colorref; std::tie(alpha, colorref) = ArgbToAlphaAndColorRef(color); if (alpha == 0) return true; HPEN hPen = CreatePen(PS_SOLID, 1, colorref); hPen = (HPEN)SelectObject(m_hDC, hPen); MoveToEx(m_hDC, FXSYS_round(ptMoveTo.x), FXSYS_round(ptMoveTo.y), nullptr); LineTo(m_hDC, FXSYS_round(ptLineTo.x), FXSYS_round(ptLineTo.y)); hPen = (HPEN)SelectObject(m_hDC, hPen); DeleteObject(hPen); return true; } CGdiDisplayDriver::CGdiDisplayDriver(HDC hDC) : CGdiDeviceDriver(hDC, FXDC_DISPLAY) { CWin32Platform* pPlatform = (CWin32Platform*)CFX_GEModule::Get()->GetPlatformData(); if (pPlatform->m_GdiplusExt.IsAvailable()) { m_RenderCaps |= FXRC_ALPHA_PATH | FXRC_ALPHA_IMAGE; } } CGdiDisplayDriver::~CGdiDisplayDriver() {} bool CGdiDisplayDriver::GetDIBits(const RetainPtr& pBitmap, int left, int top) { bool ret = false; int width = pBitmap->GetWidth(); int height = pBitmap->GetHeight(); HBITMAP hbmp = CreateCompatibleBitmap(m_hDC, width, height); HDC hDCMemory = CreateCompatibleDC(m_hDC); HBITMAP holdbmp = (HBITMAP)SelectObject(hDCMemory, hbmp); BitBlt(hDCMemory, 0, 0, width, height, m_hDC, left, top, SRCCOPY); SelectObject(hDCMemory, holdbmp); BITMAPINFO bmi; memset(&bmi, 0, sizeof bmi); bmi.bmiHeader.biSize = sizeof bmi.bmiHeader; bmi.bmiHeader.biBitCount = pBitmap->GetBPP(); bmi.bmiHeader.biHeight = -height; bmi.bmiHeader.biPlanes = 1; bmi.bmiHeader.biWidth = width; if (pBitmap->GetBPP() > 8 && !pBitmap->IsCmykImage()) { ret = ::GetDIBits(hDCMemory, hbmp, 0, height, pBitmap->GetBuffer(), &bmi, DIB_RGB_COLORS) == height; } else { auto bitmap = pdfium::MakeRetain(); if (bitmap->Create(width, height, FXDIB_Rgb)) { bmi.bmiHeader.biBitCount = 24; ::GetDIBits(hDCMemory, hbmp, 0, height, bitmap->GetBuffer(), &bmi, DIB_RGB_COLORS); ret = pBitmap->TransferBitmap(0, 0, width, height, bitmap, 0, 0); } else { ret = false; } } if (pBitmap->HasAlpha() && ret) pBitmap->LoadChannel(FXDIB_Alpha, 0xff); DeleteObject(hbmp); DeleteObject(hDCMemory); return ret; } bool CGdiDisplayDriver::SetDIBits(const RetainPtr& pSource, uint32_t color, const FX_RECT* pSrcRect, int left, int top, BlendMode blend_type) { ASSERT(blend_type == BlendMode::kNormal); if (pSource->IsAlphaMask()) { int width = pSource->GetWidth(), height = pSource->GetHeight(); int alpha = FXARGB_A(color); if (pSource->GetBPP() != 1 || alpha != 255) { auto background = pdfium::MakeRetain(); if (!background->Create(width, height, FXDIB_Rgb32) || !GetDIBits(background, left, top) || !background->CompositeMask(0, 0, width, height, pSource, color, 0, 0, BlendMode::kNormal, nullptr, false, 0)) { return false; } FX_RECT src_rect(0, 0, width, height); return SetDIBits(background, 0, &src_rect, left, top, BlendMode::kNormal); } FX_RECT clip_rect(left, top, left + pSrcRect->Width(), top + pSrcRect->Height()); return StretchDIBits(pSource, color, left - pSrcRect->left, top - pSrcRect->top, width, height, &clip_rect, 0, BlendMode::kNormal); } int width = pSrcRect->Width(), height = pSrcRect->Height(); if (pSource->HasAlpha()) { auto bitmap = pdfium::MakeRetain(); if (!bitmap->Create(width, height, FXDIB_Rgb) || !GetDIBits(bitmap, left, top) || !bitmap->CompositeBitmap(0, 0, width, height, pSource, pSrcRect->left, pSrcRect->top, BlendMode::kNormal, nullptr, false)) { return false; } FX_RECT src_rect(0, 0, width, height); return SetDIBits(bitmap, 0, &src_rect, left, top, BlendMode::kNormal); } CFX_DIBExtractor temp(pSource); RetainPtr pBitmap = temp.GetBitmap(); if (!pBitmap) return false; return GDI_SetDIBits(pBitmap, pSrcRect, left, top); } bool CGdiDisplayDriver::UseFoxitStretchEngine( const RetainPtr& pSource, uint32_t color, int dest_left, int dest_top, int dest_width, int dest_height, const FX_RECT* pClipRect, int render_flags) { FX_RECT bitmap_clip = *pClipRect; if (dest_width < 0) dest_left += dest_width; if (dest_height < 0) dest_top += dest_height; bitmap_clip.Offset(-dest_left, -dest_top); RetainPtr pStretched = pSource->StretchTo(dest_width, dest_height, render_flags, &bitmap_clip); if (!pStretched) return true; FX_RECT src_rect(0, 0, pStretched->GetWidth(), pStretched->GetHeight()); return SetDIBits(pStretched, color, &src_rect, pClipRect->left, pClipRect->top, BlendMode::kNormal); } bool CGdiDisplayDriver::StretchDIBits(const RetainPtr& pSource, uint32_t color, int dest_left, int dest_top, int dest_width, int dest_height, const FX_RECT* pClipRect, uint32_t flags, BlendMode blend_type) { ASSERT(pSource && pClipRect); if (flags || dest_width > 10000 || dest_width < -10000 || dest_height > 10000 || dest_height < -10000) { return UseFoxitStretchEngine(pSource, color, dest_left, dest_top, dest_width, dest_height, pClipRect, flags); } if (pSource->IsAlphaMask()) { FX_RECT image_rect; image_rect.left = dest_width > 0 ? dest_left : dest_left + dest_width; image_rect.right = dest_width > 0 ? dest_left + dest_width : dest_left; image_rect.top = dest_height > 0 ? dest_top : dest_top + dest_height; image_rect.bottom = dest_height > 0 ? dest_top + dest_height : dest_top; FX_RECT clip_rect = image_rect; clip_rect.Intersect(*pClipRect); clip_rect.Offset(-image_rect.left, -image_rect.top); int clip_width = clip_rect.Width(), clip_height = clip_rect.Height(); RetainPtr pStretched( pSource->StretchTo(dest_width, dest_height, flags, &clip_rect)); if (!pStretched) return true; auto background = pdfium::MakeRetain(); if (!background->Create(clip_width, clip_height, FXDIB_Rgb32) || !GetDIBits(background, image_rect.left + clip_rect.left, image_rect.top + clip_rect.top) || !background->CompositeMask(0, 0, clip_width, clip_height, pStretched, color, 0, 0, BlendMode::kNormal, nullptr, false, 0)) { return false; } FX_RECT src_rect(0, 0, clip_width, clip_height); return SetDIBits(background, 0, &src_rect, image_rect.left + clip_rect.left, image_rect.top + clip_rect.top, BlendMode::kNormal); } if (pSource->HasAlpha()) { CWin32Platform* pPlatform = (CWin32Platform*)CFX_GEModule::Get()->GetPlatformData(); if (pPlatform->m_GdiplusExt.IsAvailable() && !pSource->IsCmykImage()) { CFX_DIBExtractor temp(pSource); RetainPtr pBitmap = temp.GetBitmap(); if (!pBitmap) return false; return pPlatform->m_GdiplusExt.StretchDIBits( m_hDC, pBitmap, dest_left, dest_top, dest_width, dest_height, pClipRect, flags); } return UseFoxitStretchEngine(pSource, color, dest_left, dest_top, dest_width, dest_height, pClipRect, flags); } CFX_DIBExtractor temp(pSource); RetainPtr pBitmap = temp.GetBitmap(); if (!pBitmap) return false; return GDI_StretchDIBits(pBitmap, dest_left, dest_top, dest_width, dest_height, flags); } bool CGdiDisplayDriver::StartDIBits(const RetainPtr& pBitmap, int bitmap_alpha, uint32_t color, const CFX_Matrix& matrix, uint32_t render_flags, std::unique_ptr* handle, BlendMode blend_type) { return false; } CFX_WindowsRenderDevice::CFX_WindowsRenderDevice(HDC hDC) { SetDeviceDriver(pdfium::WrapUnique(CreateDriver(hDC))); } CFX_WindowsRenderDevice::~CFX_WindowsRenderDevice() {} // static RenderDeviceDriverIface* CFX_WindowsRenderDevice::CreateDriver(HDC hDC) { int device_type = ::GetDeviceCaps(hDC, TECHNOLOGY); int obj_type = ::GetObjectType(hDC); bool use_printer = device_type == DT_RASPRINTER || device_type == DT_PLOTTER || device_type == DT_CHARSTREAM || obj_type == OBJ_ENHMETADC; if (!use_printer) return new CGdiDisplayDriver(hDC); if (g_pdfium_print_mode == WindowsPrintMode::kModeEmf) return new CGdiPrinterDriver(hDC); if (g_pdfium_print_mode == WindowsPrintMode::kModeTextOnly) return new CTextOnlyPrinterDriver(hDC); return new CPSPrinterDriver(hDC, g_pdfium_print_mode, false); }