// Copyright 2016 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 "core/fxge/cfx_renderdevice.h" #include <algorithm> #include <memory> #include <utility> #include <vector> #include "core/fxcrt/fx_safe_types.h" #include "core/fxge/cfx_defaultrenderdevice.h" #include "core/fxge/cfx_facecache.h" #include "core/fxge/cfx_font.h" #include "core/fxge/cfx_fontmgr.h" #include "core/fxge/cfx_gemodule.h" #include "core/fxge/cfx_graphstatedata.h" #include "core/fxge/cfx_pathdata.h" #include "core/fxge/dib/cfx_imagerenderer.h" #include "core/fxge/ifx_renderdevicedriver.h" #if defined _SKIA_SUPPORT_ || defined _SKIA_SUPPORT_PATHS_ #include "third_party/skia/include/core/SkTypes.h" #endif namespace { void AdjustGlyphSpace(std::vector<FXTEXT_GLYPHPOS>* pGlyphAndPos) { ASSERT(pGlyphAndPos->size() > 1); std::vector<FXTEXT_GLYPHPOS>& glyphs = *pGlyphAndPos; bool bVertical = glyphs.back().m_Origin.x == glyphs.front().m_Origin.x; if (!bVertical && (glyphs.back().m_Origin.y != glyphs.front().m_Origin.y)) return; for (size_t i = glyphs.size() - 1; i > 1; --i) { FXTEXT_GLYPHPOS& next = glyphs[i]; int next_origin = bVertical ? next.m_Origin.y : next.m_Origin.x; float next_origin_f = bVertical ? next.m_fOrigin.y : next.m_fOrigin.x; FXTEXT_GLYPHPOS& current = glyphs[i - 1]; int& current_origin = bVertical ? current.m_Origin.y : current.m_Origin.x; float current_origin_f = bVertical ? current.m_fOrigin.y : current.m_fOrigin.x; int space = next_origin - current_origin; float space_f = next_origin_f - current_origin_f; float error = fabs(space_f) - fabs(static_cast<float>(space)); if (error > 0.5f) current_origin += space > 0 ? -1 : 1; } } const uint8_t g_TextGammaAdjust[256] = { 0, 2, 3, 4, 6, 7, 8, 10, 11, 12, 13, 15, 16, 17, 18, 19, 21, 22, 23, 24, 25, 26, 27, 29, 30, 31, 32, 33, 34, 35, 36, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 150, 151, 152, 153, 154, 155, 156, 156, 157, 158, 159, 160, 161, 162, 163, 164, 165, 166, 167, 168, 169, 170, 171, 172, 173, 174, 174, 175, 176, 177, 178, 179, 180, 181, 182, 183, 184, 185, 186, 187, 188, 189, 190, 190, 191, 192, 193, 194, 195, 196, 197, 198, 199, 200, 201, 202, 203, 204, 204, 205, 206, 207, 208, 209, 210, 211, 212, 213, 214, 215, 216, 217, 217, 218, 219, 220, 221, 222, 223, 224, 225, 226, 227, 228, 228, 229, 230, 231, 232, 233, 234, 235, 236, 237, 238, 239, 239, 240, 241, 242, 243, 244, 245, 246, 247, 248, 249, 250, 250, 251, 252, 253, 254, 255, }; int TextGammaAdjust(int value) { ASSERT(value >= 0); ASSERT(value <= 255); return g_TextGammaAdjust[value]; } int CalcAlpha(int src, int alpha) { return src * alpha / 255; } void Merge(uint8_t src, int channel, int alpha, uint8_t* dest) { *dest = FXDIB_ALPHA_MERGE(*dest, channel, CalcAlpha(src, alpha)); } void MergeGammaAdjust(uint8_t src, int channel, int alpha, uint8_t* dest) { *dest = FXDIB_ALPHA_MERGE(*dest, channel, CalcAlpha(TextGammaAdjust(src), alpha)); } void MergeGammaAdjustBgr(const uint8_t* src, int r, int g, int b, int a, uint8_t* dest) { MergeGammaAdjust(src[0], b, a, &dest[0]); MergeGammaAdjust(src[1], g, a, &dest[1]); MergeGammaAdjust(src[2], r, a, &dest[2]); } void MergeGammaAdjustRgb(const uint8_t* src, int r, int g, int b, int a, uint8_t* dest) { MergeGammaAdjust(src[2], b, a, &dest[0]); MergeGammaAdjust(src[1], g, a, &dest[1]); MergeGammaAdjust(src[0], r, a, &dest[2]); } int AverageRgb(const uint8_t* src) { return (src[0] + src[1] + src[2]) / 3; } uint8_t CalculateDestAlpha(uint8_t back_alpha, int src_alpha) { return back_alpha + src_alpha - back_alpha * src_alpha / 255; } void ApplyAlpha(uint8_t* dest, int b, int g, int r, int alpha) { dest[0] = FXDIB_ALPHA_MERGE(dest[0], b, alpha); dest[1] = FXDIB_ALPHA_MERGE(dest[1], g, alpha); dest[2] = FXDIB_ALPHA_MERGE(dest[2], r, alpha); } void ApplyDestAlpha(uint8_t back_alpha, int src_alpha, int r, int g, int b, uint8_t* dest) { uint8_t dest_alpha = CalculateDestAlpha(back_alpha, src_alpha); ApplyAlpha(dest, b, g, r, src_alpha * 255 / dest_alpha); dest[3] = dest_alpha; } void NormalizeArgb(int src_value, int r, int g, int b, int a, uint8_t* dest, int src_alpha) { uint8_t back_alpha = dest[3]; if (back_alpha == 0) FXARGB_SETDIB(dest, FXARGB_MAKE(src_alpha, r, g, b)); else if (src_alpha != 0) ApplyDestAlpha(back_alpha, src_alpha, r, g, b, dest); } void NormalizeDest(bool has_alpha, int src_value, int r, int g, int b, int a, uint8_t* dest) { if (has_alpha) { NormalizeArgb(src_value, r, g, b, a, dest, CalcAlpha(TextGammaAdjust(src_value), a)); return; } int src_alpha = CalcAlpha(TextGammaAdjust(src_value), a); if (src_alpha == 0) return; ApplyAlpha(dest, b, g, r, src_alpha); } void NormalizeSrc(bool has_alpha, int src_value, int r, int g, int b, int a, uint8_t* dest) { if (!has_alpha) { ApplyAlpha(dest, b, g, r, CalcAlpha(TextGammaAdjust(src_value), a)); return; } int src_alpha = CalcAlpha(TextGammaAdjust(src_value), a); if (src_alpha != 0) NormalizeArgb(src_value, r, g, b, a, dest, src_alpha); } void NextPixel(uint8_t** src_scan, uint8_t** dst_scan, int bpp) { *src_scan += 3; *dst_scan += bpp; } void SetAlpha(bool has_alpha, uint8_t* alpha) { if (has_alpha) alpha[3] = 255; } void DrawNormalTextHelper(const RetainPtr<CFX_DIBitmap>& bitmap, const RetainPtr<CFX_DIBitmap>& pGlyph, int nrows, int left, int top, int start_col, int end_col, bool bNormal, bool bBGRStripe, int x_subpixel, int a, int r, int g, int b) { const bool has_alpha = bitmap->GetFormat() == FXDIB_Argb; uint8_t* src_buf = pGlyph->GetBuffer(); int src_pitch = pGlyph->GetPitch(); uint8_t* dest_buf = bitmap->GetBuffer(); int dest_pitch = bitmap->GetPitch(); const int Bpp = has_alpha ? 4 : bitmap->GetBPP() / 8; for (int row = 0; row < nrows; ++row) { int dest_row = row + top; if (dest_row < 0 || dest_row >= bitmap->GetHeight()) continue; uint8_t* src_scan = src_buf + row * src_pitch + (start_col - left) * 3; uint8_t* dest_scan = dest_buf + dest_row * dest_pitch + start_col * Bpp; if (bBGRStripe) { if (x_subpixel == 0) { for (int col = start_col; col < end_col; ++col) { if (has_alpha) { Merge(src_scan[2], r, a, &dest_scan[2]); Merge(src_scan[1], g, a, &dest_scan[1]); Merge(src_scan[0], b, a, &dest_scan[0]); } else { MergeGammaAdjustBgr(&src_scan[0], r, g, b, a, &dest_scan[0]); } SetAlpha(has_alpha, dest_scan); NextPixel(&src_scan, &dest_scan, Bpp); } continue; } if (x_subpixel == 1) { MergeGammaAdjust(src_scan[1], r, a, &dest_scan[2]); MergeGammaAdjust(src_scan[0], g, a, &dest_scan[1]); if (start_col > left) MergeGammaAdjust(src_scan[-1], b, a, &dest_scan[0]); SetAlpha(has_alpha, dest_scan); NextPixel(&src_scan, &dest_scan, Bpp); for (int col = start_col + 1; col < end_col - 1; ++col) { MergeGammaAdjustBgr(&src_scan[-1], r, g, b, a, &dest_scan[0]); SetAlpha(has_alpha, dest_scan); NextPixel(&src_scan, &dest_scan, Bpp); } continue; } MergeGammaAdjust(src_scan[0], r, a, &dest_scan[2]); if (start_col > left) { MergeGammaAdjust(src_scan[-1], g, a, &dest_scan[1]); MergeGammaAdjust(src_scan[-2], b, a, &dest_scan[0]); } SetAlpha(has_alpha, dest_scan); NextPixel(&src_scan, &dest_scan, Bpp); for (int col = start_col + 1; col < end_col - 1; ++col) { MergeGammaAdjustBgr(&src_scan[-2], r, g, b, a, &dest_scan[0]); SetAlpha(has_alpha, dest_scan); NextPixel(&src_scan, &dest_scan, Bpp); } continue; } if (x_subpixel == 0) { for (int col = start_col; col < end_col; ++col) { if (bNormal) { int src_value = AverageRgb(&src_scan[0]); NormalizeDest(has_alpha, src_value, r, g, b, a, dest_scan); } else { MergeGammaAdjustRgb(&src_scan[0], r, g, b, a, &dest_scan[0]); SetAlpha(has_alpha, dest_scan); } NextPixel(&src_scan, &dest_scan, Bpp); } continue; } if (x_subpixel == 1) { if (bNormal) { int src_value = start_col > left ? AverageRgb(&src_scan[-1]) : (src_scan[0] + src_scan[1]) / 3; NormalizeSrc(has_alpha, src_value, r, g, b, a, dest_scan); } else { if (start_col > left) MergeGammaAdjust(src_scan[-1], r, a, &dest_scan[2]); MergeGammaAdjust(src_scan[0], g, a, &dest_scan[1]); MergeGammaAdjust(src_scan[1], b, a, &dest_scan[0]); SetAlpha(has_alpha, dest_scan); } NextPixel(&src_scan, &dest_scan, Bpp); for (int col = start_col + 1; col < end_col; ++col) { if (bNormal) { int src_value = AverageRgb(&src_scan[-1]); NormalizeDest(has_alpha, src_value, r, g, b, a, dest_scan); } else { MergeGammaAdjustRgb(&src_scan[-1], r, g, b, a, &dest_scan[0]); SetAlpha(has_alpha, dest_scan); } NextPixel(&src_scan, &dest_scan, Bpp); } continue; } if (bNormal) { int src_value = start_col > left ? AverageRgb(&src_scan[-2]) : src_scan[0] / 3; NormalizeSrc(has_alpha, src_value, r, g, b, a, dest_scan); } else { if (start_col > left) { MergeGammaAdjust(src_scan[-2], r, a, &dest_scan[2]); MergeGammaAdjust(src_scan[-1], g, a, &dest_scan[1]); } MergeGammaAdjust(src_scan[0], b, a, &dest_scan[0]); SetAlpha(has_alpha, dest_scan); } NextPixel(&src_scan, &dest_scan, Bpp); for (int col = start_col + 1; col < end_col; ++col) { if (bNormal) { int src_value = AverageRgb(&src_scan[-2]); NormalizeDest(has_alpha, src_value, r, g, b, a, dest_scan); } else { MergeGammaAdjustRgb(&src_scan[-2], r, g, b, a, &dest_scan[0]); SetAlpha(has_alpha, dest_scan); } NextPixel(&src_scan, &dest_scan, Bpp); } } } bool ShouldDrawDeviceText(const CFX_Font* pFont, uint32_t text_flags) { #if _FX_PLATFORM_ == _FX_PLATFORM_APPLE_ if (text_flags & FXFONT_CIDFONT) return false; const ByteString bsPsName = pFont->GetPsName(); if (bsPsName.Contains("+ZJHL")) return false; if (bsPsName == "CNAAJI+cmex10") return false; #endif return true; } } // namespace FXTEXT_CHARPOS::FXTEXT_CHARPOS() : m_Unicode(0), m_GlyphIndex(0), m_FontCharWidth(0), #if _FX_PLATFORM_ == _FX_PLATFORM_APPLE_ m_ExtGID(0), #endif m_FallbackFontPosition(0), m_bGlyphAdjust(false), m_bFontStyle(false) { } FXTEXT_CHARPOS::FXTEXT_CHARPOS(const FXTEXT_CHARPOS&) = default; FXTEXT_CHARPOS::~FXTEXT_CHARPOS(){}; CFX_RenderDevice::CFX_RenderDevice() : m_pBitmap(nullptr), m_Width(0), m_Height(0), m_bpp(0), m_RenderCaps(0), m_DeviceClass(0) {} CFX_RenderDevice::~CFX_RenderDevice() { RestoreState(false); #if defined _SKIA_SUPPORT_ || defined _SKIA_SUPPORT_PATHS_ Flush(true); #endif } #if defined _SKIA_SUPPORT_ || defined _SKIA_SUPPORT_PATHS_ void CFX_RenderDevice::Flush(bool release) { if (release) m_pDeviceDriver.reset(); else m_pDeviceDriver->Flush(); } #endif void CFX_RenderDevice::SetDeviceDriver( std::unique_ptr<IFX_RenderDeviceDriver> pDriver) { m_pDeviceDriver = std::move(pDriver); InitDeviceInfo(); } void CFX_RenderDevice::InitDeviceInfo() { m_Width = m_pDeviceDriver->GetDeviceCaps(FXDC_PIXEL_WIDTH); m_Height = m_pDeviceDriver->GetDeviceCaps(FXDC_PIXEL_HEIGHT); m_bpp = m_pDeviceDriver->GetDeviceCaps(FXDC_BITS_PIXEL); m_RenderCaps = m_pDeviceDriver->GetDeviceCaps(FXDC_RENDER_CAPS); m_DeviceClass = m_pDeviceDriver->GetDeviceCaps(FXDC_DEVICE_CLASS); if (!m_pDeviceDriver->GetClipBox(&m_ClipBox)) { m_ClipBox.left = 0; m_ClipBox.top = 0; m_ClipBox.right = m_Width; m_ClipBox.bottom = m_Height; } } void CFX_RenderDevice::SaveState() { m_pDeviceDriver->SaveState(); } void CFX_RenderDevice::RestoreState(bool bKeepSaved) { if (m_pDeviceDriver) { m_pDeviceDriver->RestoreState(bKeepSaved); UpdateClipBox(); } } int CFX_RenderDevice::GetDeviceCaps(int caps_id) const { return m_pDeviceDriver->GetDeviceCaps(caps_id); } CFX_Matrix CFX_RenderDevice::GetCTM() const { return m_pDeviceDriver->GetCTM(); } RetainPtr<CFX_DIBitmap> CFX_RenderDevice::GetBitmap() const { return m_pBitmap; } void CFX_RenderDevice::SetBitmap(const RetainPtr<CFX_DIBitmap>& pBitmap) { m_pBitmap = pBitmap; } bool CFX_RenderDevice::CreateCompatibleBitmap( const RetainPtr<CFX_DIBitmap>& pDIB, int width, int height) const { if (m_RenderCaps & FXRC_CMYK_OUTPUT) { return pDIB->Create( width, height, m_RenderCaps & FXRC_ALPHA_OUTPUT ? FXDIB_Cmyka : FXDIB_Cmyk); } if (m_RenderCaps & FXRC_BYTEMASK_OUTPUT) return pDIB->Create(width, height, FXDIB_8bppMask); #if _FX_PLATFORM_ == _FX_PLATFORM_APPLE_ || defined _SKIA_SUPPORT_PATHS_ return pDIB->Create( width, height, m_RenderCaps & FXRC_ALPHA_OUTPUT ? FXDIB_Argb : FXDIB_Rgb32); #else return pDIB->Create( width, height, m_RenderCaps & FXRC_ALPHA_OUTPUT ? FXDIB_Argb : FXDIB_Rgb); #endif } bool CFX_RenderDevice::SetClip_PathFill(const CFX_PathData* pPathData, const CFX_Matrix* pObject2Device, int fill_mode) { if (!m_pDeviceDriver->SetClip_PathFill(pPathData, pObject2Device, fill_mode)) { return false; } UpdateClipBox(); return true; } bool CFX_RenderDevice::SetClip_PathStroke( const CFX_PathData* pPathData, const CFX_Matrix* pObject2Device, const CFX_GraphStateData* pGraphState) { if (!m_pDeviceDriver->SetClip_PathStroke(pPathData, pObject2Device, pGraphState)) { return false; } UpdateClipBox(); return true; } bool CFX_RenderDevice::SetClip_Rect(const CFX_RectF& rtClip) { return SetClip_Rect(FX_RECT(static_cast<int32_t>(floor(rtClip.left)), static_cast<int32_t>(floor(rtClip.top)), static_cast<int32_t>(ceil(rtClip.right())), static_cast<int32_t>(ceil(rtClip.bottom())))); } bool CFX_RenderDevice::SetClip_Rect(const FX_RECT& rect) { CFX_PathData path; path.AppendRect(rect.left, rect.bottom, rect.right, rect.top); if (!SetClip_PathFill(&path, nullptr, FXFILL_WINDING)) return false; UpdateClipBox(); return true; } void CFX_RenderDevice::UpdateClipBox() { if (m_pDeviceDriver->GetClipBox(&m_ClipBox)) return; m_ClipBox.left = 0; m_ClipBox.top = 0; m_ClipBox.right = m_Width; m_ClipBox.bottom = m_Height; } bool CFX_RenderDevice::DrawPathWithBlend(const CFX_PathData* pPathData, const CFX_Matrix* pObject2Device, const CFX_GraphStateData* pGraphState, uint32_t fill_color, uint32_t stroke_color, int fill_mode, int blend_type) { uint8_t stroke_alpha = pGraphState ? FXARGB_A(stroke_color) : 0; uint8_t fill_alpha = (fill_mode & 3) ? FXARGB_A(fill_color) : 0; const std::vector<FX_PATHPOINT>& pPoints = pPathData->GetPoints(); if (stroke_alpha == 0 && pPoints.size() == 2) { CFX_PointF pos1 = pPoints[0].m_Point; CFX_PointF pos2 = pPoints[1].m_Point; if (pObject2Device) { pos1 = pObject2Device->Transform(pos1); pos2 = pObject2Device->Transform(pos2); } DrawCosmeticLine(pos1, pos2, fill_color, fill_mode, blend_type); return true; } if ((pPoints.size() == 5 || pPoints.size() == 4) && stroke_alpha == 0) { CFX_FloatRect rect_f; if (!(fill_mode & FXFILL_RECT_AA) && pPathData->IsRect(pObject2Device, &rect_f)) { FX_RECT rect_i = rect_f.GetOuterRect(); // Depending on the top/bottom, left/right values of the rect it's // possible to overflow the Width() and Height() calculations. Check that // the rect will have valid dimension before continuing. if (!rect_i.Valid()) return false; int width = static_cast<int>(ceil(rect_f.right - rect_f.left)); if (width < 1) { width = 1; if (rect_i.left == rect_i.right) ++rect_i.right; } int height = static_cast<int>(ceil(rect_f.top - rect_f.bottom)); if (height < 1) { height = 1; if (rect_i.bottom == rect_i.top) ++rect_i.bottom; } if (rect_i.Width() >= width + 1) { if (rect_f.left - static_cast<float>(rect_i.left) > static_cast<float>(rect_i.right) - rect_f.right) { ++rect_i.left; } else { --rect_i.right; } } if (rect_i.Height() >= height + 1) { if (rect_f.top - static_cast<float>(rect_i.top) > static_cast<float>(rect_i.bottom) - rect_f.bottom) { ++rect_i.top; } else { --rect_i.bottom; } } if (FillRectWithBlend(&rect_i, fill_color, blend_type)) return true; } } if ((fill_mode & 3) && stroke_alpha == 0 && !(fill_mode & FX_FILL_STROKE) && !(fill_mode & FX_FILL_TEXT_MODE)) { CFX_PathData newPath; bool bThin = false; bool setIdentity = false; if (pPathData->GetZeroAreaPath(pObject2Device, !!m_pDeviceDriver->GetDriverType(), &newPath, &bThin, &setIdentity)) { CFX_GraphStateData graphState; graphState.m_LineWidth = 0.0f; uint32_t strokecolor = fill_color; if (bThin) strokecolor = (((fill_alpha >> 2) << 24) | (strokecolor & 0x00ffffff)); const CFX_Matrix* pMatrix = nullptr; if (pObject2Device && !pObject2Device->IsIdentity() && !setIdentity) pMatrix = pObject2Device; int smooth_path = FX_ZEROAREA_FILL; if (fill_mode & FXFILL_NOPATHSMOOTH) smooth_path |= FXFILL_NOPATHSMOOTH; m_pDeviceDriver->DrawPath(&newPath, pMatrix, &graphState, 0, strokecolor, smooth_path, blend_type); } } if ((fill_mode & 3) && fill_alpha && stroke_alpha < 0xff && (fill_mode & FX_FILL_STROKE)) { if (m_RenderCaps & FXRC_FILLSTROKE_PATH) { return m_pDeviceDriver->DrawPath(pPathData, pObject2Device, pGraphState, fill_color, stroke_color, fill_mode, blend_type); } return DrawFillStrokePath(pPathData, pObject2Device, pGraphState, fill_color, stroke_color, fill_mode, blend_type); } return m_pDeviceDriver->DrawPath(pPathData, pObject2Device, pGraphState, fill_color, stroke_color, fill_mode, blend_type); } // This can be removed once PDFium entirely relies on Skia bool CFX_RenderDevice::DrawFillStrokePath(const CFX_PathData* pPathData, const CFX_Matrix* pObject2Device, const CFX_GraphStateData* pGraphState, uint32_t fill_color, uint32_t stroke_color, int fill_mode, int blend_type) { if (!(m_RenderCaps & FXRC_GET_BITS)) return false; CFX_FloatRect bbox; if (pGraphState) { bbox = pPathData->GetBoundingBox(pGraphState->m_LineWidth, pGraphState->m_MiterLimit); } else { bbox = pPathData->GetBoundingBox(); } if (pObject2Device) bbox = pObject2Device->TransformRect(bbox); CFX_Matrix ctm = GetCTM(); float fScaleX = fabs(ctm.a); float fScaleY = fabs(ctm.d); FX_RECT rect = bbox.GetOuterRect(); auto bitmap = pdfium::MakeRetain<CFX_DIBitmap>(); auto Backdrop = pdfium::MakeRetain<CFX_DIBitmap>(); if (!CreateCompatibleBitmap(bitmap, FXSYS_round(rect.Width() * fScaleX), FXSYS_round(rect.Height() * fScaleY))) { return false; } if (bitmap->HasAlpha()) { bitmap->Clear(0); Backdrop->Copy(bitmap); } else { if (!m_pDeviceDriver->GetDIBits(bitmap, rect.left, rect.top)) return false; Backdrop->Copy(bitmap); } CFX_DefaultRenderDevice bitmap_device; bitmap_device.Attach(bitmap, false, Backdrop, true); CFX_Matrix matrix; if (pObject2Device) matrix = *pObject2Device; matrix.Translate(-rect.left, -rect.top); matrix.Concat(CFX_Matrix(fScaleX, 0, 0, fScaleY, 0, 0)); if (!bitmap_device.GetDeviceDriver()->DrawPath( pPathData, &matrix, pGraphState, fill_color, stroke_color, fill_mode, blend_type)) { return false; } #if defined _SKIA_SUPPORT_ || defined _SKIA_SUPPORT_PATHS_ bitmap_device.GetDeviceDriver()->Flush(); #endif FX_RECT src_rect(0, 0, FXSYS_round(rect.Width() * fScaleX), FXSYS_round(rect.Height() * fScaleY)); return m_pDeviceDriver->SetDIBits(bitmap, 0, &src_rect, rect.left, rect.top, FXDIB_BLEND_NORMAL); } bool CFX_RenderDevice::FillRectWithBlend(const FX_RECT* pRect, uint32_t fill_color, int blend_type) { if (m_pDeviceDriver->FillRectWithBlend(pRect, fill_color, blend_type)) return true; if (!(m_RenderCaps & FXRC_GET_BITS)) return false; auto bitmap = pdfium::MakeRetain<CFX_DIBitmap>(); if (!CreateCompatibleBitmap(bitmap, pRect->Width(), pRect->Height())) return false; if (!m_pDeviceDriver->GetDIBits(bitmap, pRect->left, pRect->top)) return false; if (!bitmap->CompositeRect(0, 0, pRect->Width(), pRect->Height(), fill_color, 0)) { return false; } FX_RECT src_rect(0, 0, pRect->Width(), pRect->Height()); m_pDeviceDriver->SetDIBits(bitmap, 0, &src_rect, pRect->left, pRect->top, FXDIB_BLEND_NORMAL); return true; } bool CFX_RenderDevice::DrawCosmeticLine(const CFX_PointF& ptMoveTo, const CFX_PointF& ptLineTo, uint32_t color, int fill_mode, int blend_type) { if ((color >= 0xff000000) && m_pDeviceDriver->DrawCosmeticLine( ptMoveTo, ptLineTo, color, blend_type)) { return true; } CFX_GraphStateData graph_state; CFX_PathData path; path.AppendPoint(ptMoveTo, FXPT_TYPE::MoveTo, false); path.AppendPoint(ptLineTo, FXPT_TYPE::LineTo, false); return m_pDeviceDriver->DrawPath(&path, nullptr, &graph_state, 0, color, fill_mode, blend_type); } bool CFX_RenderDevice::GetDIBits(const RetainPtr<CFX_DIBitmap>& pBitmap, int left, int top) { return (m_RenderCaps & FXRC_GET_BITS) && m_pDeviceDriver->GetDIBits(pBitmap, left, top); } RetainPtr<CFX_DIBitmap> CFX_RenderDevice::GetBackDrop() { return m_pDeviceDriver->GetBackDrop(); } bool CFX_RenderDevice::SetDIBitsWithBlend( const RetainPtr<CFX_DIBSource>& pBitmap, int left, int top, int blend_mode) { ASSERT(!pBitmap->IsAlphaMask()); CFX_Matrix ctm = GetCTM(); float fScaleX = fabs(ctm.a); float fScaleY = fabs(ctm.d); FX_RECT dest_rect(left, top, FXSYS_round(left + pBitmap->GetWidth() / fScaleX), FXSYS_round(top + pBitmap->GetHeight() / fScaleY)); dest_rect.Intersect(m_ClipBox); if (dest_rect.IsEmpty()) return true; FX_RECT src_rect(dest_rect.left - left, dest_rect.top - top, dest_rect.left - left + dest_rect.Width(), dest_rect.top - top + dest_rect.Height()); src_rect.left = FXSYS_round(src_rect.left * fScaleX); src_rect.top = FXSYS_round(src_rect.top * fScaleY); src_rect.right = FXSYS_round(src_rect.right * fScaleX); src_rect.bottom = FXSYS_round(src_rect.bottom * fScaleY); if ((blend_mode == FXDIB_BLEND_NORMAL || (m_RenderCaps & FXRC_BLEND_MODE)) && (!pBitmap->HasAlpha() || (m_RenderCaps & FXRC_ALPHA_IMAGE))) { return m_pDeviceDriver->SetDIBits(pBitmap, 0, &src_rect, dest_rect.left, dest_rect.top, blend_mode); } if (!(m_RenderCaps & FXRC_GET_BITS)) return false; int bg_pixel_width = FXSYS_round(dest_rect.Width() * fScaleX); int bg_pixel_height = FXSYS_round(dest_rect.Height() * fScaleY); auto background = pdfium::MakeRetain<CFX_DIBitmap>(); if (!background->Create( bg_pixel_width, bg_pixel_height, (m_RenderCaps & FXRC_CMYK_OUTPUT) ? FXDIB_Cmyk : FXDIB_Rgb32)) { return false; } if (!m_pDeviceDriver->GetDIBits(background, dest_rect.left, dest_rect.top)) { return false; } if (!background->CompositeBitmap(0, 0, bg_pixel_width, bg_pixel_height, pBitmap, src_rect.left, src_rect.top, blend_mode, nullptr, false)) { return false; } FX_RECT rect(0, 0, bg_pixel_width, bg_pixel_height); return m_pDeviceDriver->SetDIBits(background, 0, &rect, dest_rect.left, dest_rect.top, FXDIB_BLEND_NORMAL); } bool CFX_RenderDevice::StretchDIBitsWithFlagsAndBlend( const RetainPtr<CFX_DIBSource>& pBitmap, int left, int top, int dest_width, int dest_height, uint32_t flags, int blend_mode) { FX_RECT dest_rect(left, top, left + dest_width, top + dest_height); FX_RECT clip_box = m_ClipBox; clip_box.Intersect(dest_rect); return clip_box.IsEmpty() || m_pDeviceDriver->StretchDIBits( pBitmap, 0, left, top, dest_width, dest_height, &clip_box, flags, blend_mode); } bool CFX_RenderDevice::SetBitMask(const RetainPtr<CFX_DIBSource>& pBitmap, int left, int top, uint32_t argb) { FX_RECT src_rect(0, 0, pBitmap->GetWidth(), pBitmap->GetHeight()); return m_pDeviceDriver->SetDIBits(pBitmap, argb, &src_rect, left, top, FXDIB_BLEND_NORMAL); } bool CFX_RenderDevice::StretchBitMask(const RetainPtr<CFX_DIBSource>& pBitmap, int left, int top, int dest_width, int dest_height, uint32_t color) { return StretchBitMaskWithFlags(pBitmap, left, top, dest_width, dest_height, color, 0); } bool CFX_RenderDevice::StretchBitMaskWithFlags( const RetainPtr<CFX_DIBSource>& pBitmap, int left, int top, int dest_width, int dest_height, uint32_t argb, uint32_t flags) { FX_RECT dest_rect(left, top, left + dest_width, top + dest_height); FX_RECT clip_box = m_ClipBox; clip_box.Intersect(dest_rect); return m_pDeviceDriver->StretchDIBits(pBitmap, argb, left, top, dest_width, dest_height, &clip_box, flags, FXDIB_BLEND_NORMAL); } bool CFX_RenderDevice::StartDIBitsWithBlend( const RetainPtr<CFX_DIBSource>& pBitmap, int bitmap_alpha, uint32_t argb, const CFX_Matrix* pMatrix, uint32_t flags, std::unique_ptr<CFX_ImageRenderer>* handle, int blend_mode) { return m_pDeviceDriver->StartDIBits(pBitmap, bitmap_alpha, argb, pMatrix, flags, handle, blend_mode); } bool CFX_RenderDevice::ContinueDIBits(CFX_ImageRenderer* handle, IFX_PauseIndicator* pPause) { return m_pDeviceDriver->ContinueDIBits(handle, pPause); } #ifdef _SKIA_SUPPORT_ void CFX_RenderDevice::DebugVerifyBitmapIsPreMultiplied() const { SkASSERT(0); } bool CFX_RenderDevice::SetBitsWithMask(const RetainPtr<CFX_DIBSource>& pBitmap, const RetainPtr<CFX_DIBSource>& pMask, int left, int top, int bitmap_alpha, int blend_type) { return m_pDeviceDriver->SetBitsWithMask(pBitmap, pMask, left, top, bitmap_alpha, blend_type); } #endif bool CFX_RenderDevice::DrawNormalText(int nChars, const FXTEXT_CHARPOS* pCharPos, CFX_Font* pFont, float font_size, const CFX_Matrix* pText2Device, uint32_t fill_color, uint32_t text_flags) { int nativetext_flags = text_flags; if (m_DeviceClass != FXDC_DISPLAY) { if (!(text_flags & FXTEXT_PRINTGRAPHICTEXT)) { if (ShouldDrawDeviceText(pFont, text_flags) && m_pDeviceDriver->DrawDeviceText(nChars, pCharPos, pFont, pText2Device, font_size, fill_color)) { return true; } } if (FXARGB_A(fill_color) < 255) return false; } else if (!(text_flags & FXTEXT_NO_NATIVETEXT)) { if (ShouldDrawDeviceText(pFont, text_flags) && m_pDeviceDriver->DrawDeviceText(nChars, pCharPos, pFont, pText2Device, font_size, fill_color)) { return true; } } CFX_Matrix char2device; CFX_Matrix text2Device; if (pText2Device) { char2device = *pText2Device; text2Device = *pText2Device; } char2device.Scale(font_size, -font_size); if (fabs(char2device.a) + fabs(char2device.b) > 50 * 1.0f || ((m_DeviceClass == FXDC_PRINTER) && !(text_flags & FXTEXT_PRINTIMAGETEXT))) { if (pFont->GetFace()) { int nPathFlags = (text_flags & FXTEXT_NOSMOOTH) == 0 ? 0 : FXFILL_NOPATHSMOOTH; return DrawTextPath(nChars, pCharPos, pFont, font_size, pText2Device, nullptr, nullptr, fill_color, 0, nullptr, nPathFlags); } } int anti_alias = FXFT_RENDER_MODE_MONO; bool bNormal = false; if ((text_flags & FXTEXT_NOSMOOTH) == 0) { if (m_DeviceClass == FXDC_DISPLAY && m_bpp > 1) { if (!CFX_GEModule::Get()->GetFontMgr()->FTLibrarySupportsHinting()) { // Some Freetype implementations (like the one packaged with Fedora) do // not support hinting due to patents 6219025, 6239783, 6307566, // 6225973, 6243070, 6393145, 6421054, 6282327, and 6624828; the latest // one expires 10/7/19. This makes LCD antialiasing very ugly, so we // instead fall back on NORMAL antialiasing. anti_alias = FXFT_RENDER_MODE_NORMAL; } else if ((m_RenderCaps & (FXRC_ALPHA_OUTPUT | FXRC_CMYK_OUTPUT))) { anti_alias = FXFT_RENDER_MODE_LCD; bNormal = true; } else if (m_bpp < 16) { anti_alias = FXFT_RENDER_MODE_NORMAL; } else { anti_alias = FXFT_RENDER_MODE_LCD; bool bClearType = false; if (pFont->GetFace()) bClearType = !!(text_flags & FXTEXT_CLEARTYPE); bNormal = !bClearType; } } } std::vector<FXTEXT_GLYPHPOS> glyphs(nChars); CFX_Matrix matrixCTM = GetCTM(); float scale_x = fabs(matrixCTM.a); float scale_y = fabs(matrixCTM.d); CFX_Matrix deviceCtm = char2device; CFX_Matrix m(scale_x, 0, 0, scale_y, 0, 0); deviceCtm.Concat(m); text2Device.Concat(m); for (size_t i = 0; i < glyphs.size(); ++i) { FXTEXT_GLYPHPOS& glyph = glyphs[i]; const FXTEXT_CHARPOS& charpos = pCharPos[i]; glyph.m_fOrigin = text2Device.Transform(charpos.m_Origin); if (anti_alias < FXFT_RENDER_MODE_LCD) glyph.m_Origin.x = FXSYS_round(glyph.m_fOrigin.x); else glyph.m_Origin.x = static_cast<int>(floor(glyph.m_fOrigin.x)); glyph.m_Origin.y = FXSYS_round(glyph.m_fOrigin.y); if (charpos.m_bGlyphAdjust) { CFX_Matrix new_matrix( charpos.m_AdjustMatrix[0], charpos.m_AdjustMatrix[1], charpos.m_AdjustMatrix[2], charpos.m_AdjustMatrix[3], 0, 0); new_matrix.Concat(deviceCtm); glyph.m_pGlyph = pFont->LoadGlyphBitmap( charpos.m_GlyphIndex, charpos.m_bFontStyle, &new_matrix, charpos.m_FontCharWidth, anti_alias, nativetext_flags); } else { glyph.m_pGlyph = pFont->LoadGlyphBitmap( charpos.m_GlyphIndex, charpos.m_bFontStyle, &deviceCtm, charpos.m_FontCharWidth, anti_alias, nativetext_flags); } } if (anti_alias < FXFT_RENDER_MODE_LCD && glyphs.size() > 1) AdjustGlyphSpace(&glyphs); FX_RECT bmp_rect1 = FXGE_GetGlyphsBBox(glyphs, anti_alias, 1.0f, 1.0f); if (scale_x > 1 && scale_y > 1) { --bmp_rect1.left; --bmp_rect1.top; ++bmp_rect1.right; ++bmp_rect1.bottom; } FX_RECT bmp_rect(FXSYS_round((float)(bmp_rect1.left) / scale_x), FXSYS_round((float)(bmp_rect1.top) / scale_y), FXSYS_round((float)bmp_rect1.right / scale_x), FXSYS_round((float)bmp_rect1.bottom / scale_y)); bmp_rect.Intersect(m_ClipBox); if (bmp_rect.IsEmpty()) return true; int pixel_width = FXSYS_round(bmp_rect.Width() * scale_x); int pixel_height = FXSYS_round(bmp_rect.Height() * scale_y); int pixel_left = FXSYS_round(bmp_rect.left * scale_x); int pixel_top = FXSYS_round(bmp_rect.top * scale_y); if (anti_alias == FXFT_RENDER_MODE_MONO) { auto bitmap = pdfium::MakeRetain<CFX_DIBitmap>(); if (!bitmap->Create(pixel_width, pixel_height, FXDIB_1bppMask)) return false; bitmap->Clear(0); for (const FXTEXT_GLYPHPOS& glyph : glyphs) { if (!glyph.m_pGlyph) continue; RetainPtr<CFX_DIBitmap> pGlyph = glyph.m_pGlyph->m_pBitmap; bitmap->TransferBitmap( glyph.m_Origin.x + glyph.m_pGlyph->m_Left - pixel_left, glyph.m_Origin.y - glyph.m_pGlyph->m_Top - pixel_top, pGlyph->GetWidth(), pGlyph->GetHeight(), pGlyph, 0, 0); } return SetBitMask(bitmap, bmp_rect.left, bmp_rect.top, fill_color); } auto bitmap = pdfium::MakeRetain<CFX_DIBitmap>(); if (m_bpp == 8) { if (!bitmap->Create(pixel_width, pixel_height, FXDIB_8bppMask)) return false; } else { if (!CreateCompatibleBitmap(bitmap, pixel_width, pixel_height)) return false; } if (!bitmap->HasAlpha() && !bitmap->IsAlphaMask()) { bitmap->Clear(0xFFFFFFFF); if (!GetDIBits(bitmap, bmp_rect.left, bmp_rect.top)) return false; } else { bitmap->Clear(0); if (bitmap->m_pAlphaMask) bitmap->m_pAlphaMask->Clear(0); } int dest_width = pixel_width; int a = 0; int r = 0; int g = 0; int b = 0; if (anti_alias == FXFT_RENDER_MODE_LCD) std::tie(a, r, g, b) = ArgbDecode(fill_color); for (const FXTEXT_GLYPHPOS& glyph : glyphs) { if (!glyph.m_pGlyph) continue; pdfium::base::CheckedNumeric<int> left = glyph.m_Origin.x; left += glyph.m_pGlyph->m_Left; left -= pixel_left; if (!left.IsValid()) return false; pdfium::base::CheckedNumeric<int> top = glyph.m_Origin.y; top -= glyph.m_pGlyph->m_Top; top -= pixel_top; if (!top.IsValid()) return false; RetainPtr<CFX_DIBitmap> pGlyph = glyph.m_pGlyph->m_pBitmap; int ncols = pGlyph->GetWidth(); int nrows = pGlyph->GetHeight(); if (anti_alias == FXFT_RENDER_MODE_NORMAL) { if (!bitmap->CompositeMask(left.ValueOrDie(), top.ValueOrDie(), ncols, nrows, pGlyph, fill_color, 0, 0, FXDIB_BLEND_NORMAL, nullptr, false, 0)) { return false; } continue; } bool bBGRStripe = !!(text_flags & FXTEXT_BGR_STRIPE); ncols /= 3; int x_subpixel = static_cast<int>(glyph.m_fOrigin.x * 3) % 3; int start_col = pdfium::base::ValueOrDieForType<int>(pdfium::base::CheckMax(left, 0)); pdfium::base::CheckedNumeric<int> end_col_safe = left; end_col_safe += ncols; if (!end_col_safe.IsValid()) return false; int end_col = std::min(static_cast<int>(end_col_safe.ValueOrDie<int>()), dest_width); if (start_col >= end_col) continue; DrawNormalTextHelper(bitmap, pGlyph, nrows, left.ValueOrDie(), top.ValueOrDie(), start_col, end_col, bNormal, bBGRStripe, x_subpixel, a, r, g, b); } if (bitmap->IsAlphaMask()) SetBitMask(bitmap, bmp_rect.left, bmp_rect.top, fill_color); else SetDIBits(bitmap, bmp_rect.left, bmp_rect.top); return true; } bool CFX_RenderDevice::DrawTextPath(int nChars, const FXTEXT_CHARPOS* pCharPos, CFX_Font* pFont, float font_size, const CFX_Matrix* pText2User, const CFX_Matrix* pUser2Device, const CFX_GraphStateData* pGraphState, uint32_t fill_color, FX_ARGB stroke_color, CFX_PathData* pClippingPath, int nFlag) { for (int iChar = 0; iChar < nChars; ++iChar) { const FXTEXT_CHARPOS& charpos = pCharPos[iChar]; CFX_Matrix matrix; if (charpos.m_bGlyphAdjust) { matrix = CFX_Matrix(charpos.m_AdjustMatrix[0], charpos.m_AdjustMatrix[1], charpos.m_AdjustMatrix[2], charpos.m_AdjustMatrix[3], 0, 0); } matrix.Concat(CFX_Matrix(font_size, 0, 0, font_size, charpos.m_Origin.x, charpos.m_Origin.y)); const CFX_PathData* pPath = pFont->LoadGlyphPath(charpos.m_GlyphIndex, charpos.m_FontCharWidth); if (!pPath) continue; matrix.Concat(*pText2User); CFX_PathData TransformedPath(*pPath); TransformedPath.Transform(&matrix); if (fill_color || stroke_color) { int fill_mode = nFlag; if (fill_color) fill_mode |= FXFILL_WINDING; fill_mode |= FX_FILL_TEXT_MODE; if (!DrawPathWithBlend(&TransformedPath, pUser2Device, pGraphState, fill_color, stroke_color, fill_mode, FXDIB_BLEND_NORMAL)) { return false; } } if (pClippingPath) pClippingPath->Append(&TransformedPath, pUser2Device); } return true; } void CFX_RenderDevice::DrawFillRect(const CFX_Matrix* pUser2Device, const CFX_FloatRect& rect, const FX_COLORREF& color) { CFX_PathData path; CFX_FloatRect rcTemp(rect); path.AppendRect(rcTemp.left, rcTemp.bottom, rcTemp.right, rcTemp.top); DrawPath(&path, pUser2Device, nullptr, color, 0, FXFILL_WINDING); } void CFX_RenderDevice::DrawFillArea(const CFX_Matrix* pUser2Device, const CFX_PointF* pPts, int32_t nCount, const FX_COLORREF& color) { CFX_PathData path; path.AppendPoint(pPts[0], FXPT_TYPE::MoveTo, false); for (int32_t i = 1; i < nCount; i++) path.AppendPoint(pPts[i], FXPT_TYPE::LineTo, false); DrawPath(&path, pUser2Device, nullptr, color, 0, FXFILL_ALTERNATE); } void CFX_RenderDevice::DrawStrokeRect(const CFX_Matrix* pUser2Device, const CFX_FloatRect& rect, const FX_COLORREF& color, float fWidth) { CFX_PathData path; CFX_FloatRect rcTemp(rect); path.AppendRect(rcTemp.left, rcTemp.bottom, rcTemp.right, rcTemp.top); CFX_GraphStateData gsd; gsd.m_LineWidth = fWidth; DrawPath(&path, pUser2Device, &gsd, 0, color, FXFILL_ALTERNATE); } void CFX_RenderDevice::DrawStrokeLine(const CFX_Matrix* pUser2Device, const CFX_PointF& ptMoveTo, const CFX_PointF& ptLineTo, const FX_COLORREF& color, float fWidth) { CFX_PathData path; path.AppendPoint(ptMoveTo, FXPT_TYPE::MoveTo, false); path.AppendPoint(ptLineTo, FXPT_TYPE::LineTo, false); CFX_GraphStateData gsd; gsd.m_LineWidth = fWidth; DrawPath(&path, pUser2Device, &gsd, 0, color, FXFILL_ALTERNATE); } void CFX_RenderDevice::DrawFillRect(const CFX_Matrix* pUser2Device, const CFX_FloatRect& rect, const CFX_Color& color, int32_t nTransparency) { DrawFillRect(pUser2Device, rect, color.ToFXColor(nTransparency)); } void CFX_RenderDevice::DrawShadow(const CFX_Matrix* pUser2Device, bool bVertical, bool bHorizontal, CFX_FloatRect rect, int32_t nTransparency, int32_t nStartGray, int32_t nEndGray) { float fStepGray = 1.0f; if (bVertical) { fStepGray = (nEndGray - nStartGray) / rect.Height(); for (float fy = rect.bottom + 0.5f; fy <= rect.top - 0.5f; fy += 1.0f) { int32_t nGray = nStartGray + (int32_t)(fStepGray * (fy - rect.bottom)); DrawStrokeLine(pUser2Device, CFX_PointF(rect.left, fy), CFX_PointF(rect.right, fy), ArgbEncode(nTransparency, nGray, nGray, nGray), 1.5f); } } if (bHorizontal) { fStepGray = (nEndGray - nStartGray) / rect.Width(); for (float fx = rect.left + 0.5f; fx <= rect.right - 0.5f; fx += 1.0f) { int32_t nGray = nStartGray + (int32_t)(fStepGray * (fx - rect.left)); DrawStrokeLine(pUser2Device, CFX_PointF(fx, rect.bottom), CFX_PointF(fx, rect.top), ArgbEncode(nTransparency, nGray, nGray, nGray), 1.5f); } } } void CFX_RenderDevice::DrawBorder(const CFX_Matrix* pUser2Device, const CFX_FloatRect& rect, float fWidth, const CFX_Color& color, const CFX_Color& crLeftTop, const CFX_Color& crRightBottom, BorderStyle nStyle, int32_t nTransparency) { float fLeft = rect.left; float fRight = rect.right; float fTop = rect.top; float fBottom = rect.bottom; if (fWidth > 0.0f) { float fHalfWidth = fWidth / 2.0f; switch (nStyle) { default: case BorderStyle::SOLID: { CFX_PathData path; path.AppendRect(fLeft, fBottom, fRight, fTop); path.AppendRect(fLeft + fWidth, fBottom + fWidth, fRight - fWidth, fTop - fWidth); DrawPath(&path, pUser2Device, nullptr, color.ToFXColor(nTransparency), 0, FXFILL_ALTERNATE); break; } case BorderStyle::DASH: { CFX_PathData path; path.AppendPoint( CFX_PointF(fLeft + fWidth / 2.0f, fBottom + fWidth / 2.0f), FXPT_TYPE::MoveTo, false); path.AppendPoint( CFX_PointF(fLeft + fWidth / 2.0f, fTop - fWidth / 2.0f), FXPT_TYPE::LineTo, false); path.AppendPoint( CFX_PointF(fRight - fWidth / 2.0f, fTop - fWidth / 2.0f), FXPT_TYPE::LineTo, false); path.AppendPoint( CFX_PointF(fRight - fWidth / 2.0f, fBottom + fWidth / 2.0f), FXPT_TYPE::LineTo, false); path.AppendPoint( CFX_PointF(fLeft + fWidth / 2.0f, fBottom + fWidth / 2.0f), FXPT_TYPE::LineTo, false); CFX_GraphStateData gsd; gsd.SetDashCount(2); gsd.m_DashArray[0] = 3.0f; gsd.m_DashArray[1] = 3.0f; gsd.m_DashPhase = 0; gsd.m_LineWidth = fWidth; DrawPath(&path, pUser2Device, &gsd, 0, color.ToFXColor(nTransparency), FXFILL_WINDING); break; } case BorderStyle::BEVELED: case BorderStyle::INSET: { CFX_GraphStateData gsd; gsd.m_LineWidth = fHalfWidth; CFX_PathData pathLT; pathLT.AppendPoint(CFX_PointF(fLeft + fHalfWidth, fBottom + fHalfWidth), FXPT_TYPE::MoveTo, false); pathLT.AppendPoint(CFX_PointF(fLeft + fHalfWidth, fTop - fHalfWidth), FXPT_TYPE::LineTo, false); pathLT.AppendPoint(CFX_PointF(fRight - fHalfWidth, fTop - fHalfWidth), FXPT_TYPE::LineTo, false); pathLT.AppendPoint( CFX_PointF(fRight - fHalfWidth * 2, fTop - fHalfWidth * 2), FXPT_TYPE::LineTo, false); pathLT.AppendPoint( CFX_PointF(fLeft + fHalfWidth * 2, fTop - fHalfWidth * 2), FXPT_TYPE::LineTo, false); pathLT.AppendPoint( CFX_PointF(fLeft + fHalfWidth * 2, fBottom + fHalfWidth * 2), FXPT_TYPE::LineTo, false); pathLT.AppendPoint(CFX_PointF(fLeft + fHalfWidth, fBottom + fHalfWidth), FXPT_TYPE::LineTo, false); DrawPath(&pathLT, pUser2Device, &gsd, crLeftTop.ToFXColor(nTransparency), 0, FXFILL_ALTERNATE); CFX_PathData pathRB; pathRB.AppendPoint(CFX_PointF(fRight - fHalfWidth, fTop - fHalfWidth), FXPT_TYPE::MoveTo, false); pathRB.AppendPoint( CFX_PointF(fRight - fHalfWidth, fBottom + fHalfWidth), FXPT_TYPE::LineTo, false); pathRB.AppendPoint(CFX_PointF(fLeft + fHalfWidth, fBottom + fHalfWidth), FXPT_TYPE::LineTo, false); pathRB.AppendPoint( CFX_PointF(fLeft + fHalfWidth * 2, fBottom + fHalfWidth * 2), FXPT_TYPE::LineTo, false); pathRB.AppendPoint( CFX_PointF(fRight - fHalfWidth * 2, fBottom + fHalfWidth * 2), FXPT_TYPE::LineTo, false); pathRB.AppendPoint( CFX_PointF(fRight - fHalfWidth * 2, fTop - fHalfWidth * 2), FXPT_TYPE::LineTo, false); pathRB.AppendPoint(CFX_PointF(fRight - fHalfWidth, fTop - fHalfWidth), FXPT_TYPE::LineTo, false); DrawPath(&pathRB, pUser2Device, &gsd, crRightBottom.ToFXColor(nTransparency), 0, FXFILL_ALTERNATE); CFX_PathData path; path.AppendRect(fLeft, fBottom, fRight, fTop); path.AppendRect(fLeft + fHalfWidth, fBottom + fHalfWidth, fRight - fHalfWidth, fTop - fHalfWidth); DrawPath(&path, pUser2Device, &gsd, color.ToFXColor(nTransparency), 0, FXFILL_ALTERNATE); break; } case BorderStyle::UNDERLINE: { CFX_PathData path; path.AppendPoint(CFX_PointF(fLeft, fBottom + fWidth / 2), FXPT_TYPE::MoveTo, false); path.AppendPoint(CFX_PointF(fRight, fBottom + fWidth / 2), FXPT_TYPE::LineTo, false); CFX_GraphStateData gsd; gsd.m_LineWidth = fWidth; DrawPath(&path, pUser2Device, &gsd, 0, color.ToFXColor(nTransparency), FXFILL_ALTERNATE); break; } } } } CFX_RenderDevice::StateRestorer::StateRestorer(CFX_RenderDevice* pDevice) : m_pDevice(pDevice) { m_pDevice->SaveState(); } CFX_RenderDevice::StateRestorer::~StateRestorer() { m_pDevice->RestoreState(false); }